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TrackingNtuple.cc
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1 // -*- C++ -*-
2 //
3 // Package: NtupleDump/TrackingNtuple
4 // Class: TrackingNtuple
5 //
13 //
14 // Original Author: Giuseppe Cerati
15 // Created: Tue, 25 Aug 2015 13:22:49 GMT
16 //
17 //
18 
19 // system include files
20 #include <memory>
21 
22 // user include files
25 
36 
39 
43 
47 
54 
57 
59 
67 
72 
75 
85 
88 
90 #include "HepPDT/ParticleID.hh"
91 
93 
95 
96 #include <set>
97 #include <map>
98 #include <unordered_set>
99 #include <unordered_map>
100 #include <tuple>
101 #include <utility>
102 
103 #include "TTree.h"
104 
105 /*
106 todo:
107 add refitted hit position after track/seed fit
108 add local angle, path length!
109 */
110 
111 namespace {
112  // This pattern is copied from QuickTrackAssociatorByHitsImpl. If
113  // further needs arises, it wouldn't hurt to abstract it somehow.
114  using TrackingParticleRefKeyToIndex = std::unordered_map<reco::RecoToSimCollection::index_type, size_t>;
115  using TrackingVertexRefKeyToIndex = TrackingParticleRefKeyToIndex;
116  using SimHitFullKey = std::pair<TrackPSimHitRef::key_type, edm::ProductID>;
117  using SimHitRefKeyToIndex = std::map<SimHitFullKey, size_t>;
118  using TrackingParticleRefKeyToCount = TrackingParticleRefKeyToIndex;
119 
120  std::string subdetstring(int subdet) {
121  switch (subdet) {
123  return "- TIB";
125  return "- TOB";
127  return "- TEC";
129  return "- TID";
131  return "- PixBar";
133  return "- PixFwd";
134  default:
135  return "UNKNOWN TRACKER HIT TYPE";
136  }
137  }
138 
139  struct ProductIDSetPrinter {
140  ProductIDSetPrinter(const std::set<edm::ProductID>& set) : set_(set) {}
141 
142  void print(std::ostream& os) const {
143  for (const auto& item : set_) {
144  os << item << " ";
145  }
146  }
147 
148  const std::set<edm::ProductID>& set_;
149  };
150  std::ostream& operator<<(std::ostream& os, const ProductIDSetPrinter& o) {
151  o.print(os);
152  return os;
153  }
154  template <typename T>
155  struct ProductIDMapPrinter {
156  ProductIDMapPrinter(const std::map<edm::ProductID, T>& map) : map_(map) {}
157 
158  void print(std::ostream& os) const {
159  for (const auto& item : map_) {
160  os << item.first << " ";
161  }
162  }
163 
164  const std::map<edm::ProductID, T>& map_;
165  };
166  template <typename T>
167  auto make_ProductIDMapPrinter(const std::map<edm::ProductID, T>& map) {
168  return ProductIDMapPrinter<T>(map);
169  }
170  template <typename T>
171  std::ostream& operator<<(std::ostream& os, const ProductIDMapPrinter<T>& o) {
172  o.print(os);
173  return os;
174  }
175 
176  template <typename T>
177  struct VectorPrinter {
178  VectorPrinter(const std::vector<T>& vec) : vec_(vec) {}
179 
180  void print(std::ostream& os) const {
181  for (const auto& item : vec_) {
182  os << item << " ";
183  }
184  }
185 
186  const std::vector<T>& vec_;
187  };
188  template <typename T>
189  auto make_VectorPrinter(const std::vector<T>& vec) {
190  return VectorPrinter<T>(vec);
191  }
192  template <typename T>
193  std::ostream& operator<<(std::ostream& os, const VectorPrinter<T>& o) {
194  o.print(os);
195  return os;
196  }
197 
198  void checkProductID(const std::set<edm::ProductID>& set, const edm::ProductID& id, const char* name) {
199  if (set.find(id) == set.end())
200  throw cms::Exception("Configuration")
201  << "Got " << name << " with a hit with ProductID " << id
202  << " which does not match to the set of ProductID's for the hits: " << ProductIDSetPrinter(set)
203  << ". Usually this is caused by a wrong hit collection in the configuration.";
204  }
205 
206  template <typename SimLink, typename Func>
207  void forEachMatchedSimLink(const edm::DetSet<SimLink>& digiSimLinks, uint32_t channel, Func func) {
208  for (const auto& link : digiSimLinks) {
209  if (link.channel() == channel) {
210  func(link);
211  }
212  }
213  }
214 
216  template <typename... Args>
217  void call_nop(Args&&... args) {}
218 
219  template <typename... Types>
220  class CombineDetId {
221  public:
222  CombineDetId() {}
223 
226  unsigned int operator[](size_t i) const { return std::get<0>(content_)[i]; }
227 
228  template <typename... Args>
229  void book(Args&&... args) {
230  impl([&](auto& vec) { vec.book(std::forward<Args>(args)...); });
231  }
232 
233  template <typename... Args>
234  void push_back(Args&&... args) {
235  impl([&](auto& vec) { vec.push_back(std::forward<Args>(args)...); });
236  }
237 
238  template <typename... Args>
239  void resize(Args&&... args) {
240  impl([&](auto& vec) { vec.resize(std::forward<Args>(args)...); });
241  }
242 
243  template <typename... Args>
244  void set(Args&&... args) {
245  impl([&](auto& vec) { vec.set(std::forward<Args>(args)...); });
246  }
247 
248  void clear() {
249  impl([&](auto& vec) { vec.clear(); });
250  }
251 
252  private:
253  // Trick to not repeate std::index_sequence_for in each of the methods above
254  template <typename F>
255  void impl(F&& func) {
256  impl2(std::index_sequence_for<Types...>{}, std::forward<F>(func));
257  }
258 
259  // Trick to exploit parameter pack expansion in function call
260  // arguments to call a member function for each tuple element
261  // (with the same signature). The comma operator is needed to
262  // return a value from the expression as an argument for the
263  // call_nop.
264  template <std::size_t... Is, typename F>
265  void impl2(std::index_sequence<Is...>, F&& func) {
266  call_nop((func(std::get<Is>(content_)), 0)...);
267  }
268 
269  std::tuple<Types...> content_;
270  };
271 
272  std::map<unsigned int, double> chargeFraction(const SiPixelCluster& cluster,
273  const DetId& detId,
274  const edm::DetSetVector<PixelDigiSimLink>& digiSimLink) {
275  std::map<unsigned int, double> simTrackIdToAdc;
276 
277  auto idetset = digiSimLink.find(detId);
278  if (idetset == digiSimLink.end())
279  return simTrackIdToAdc;
280 
281  double adcSum = 0;
283  for (int iPix = 0; iPix != cluster.size(); ++iPix) {
284  const SiPixelCluster::Pixel& pixel = cluster.pixel(iPix);
285  adcSum += pixel.adc;
286  uint32_t channel = PixelChannelIdentifier::pixelToChannel(pixel.x, pixel.y);
287  forEachMatchedSimLink(*idetset, channel, [&](const PixelDigiSimLink& simLink) {
288  double& adc = simTrackIdToAdc[simLink.SimTrackId()];
289  adc += pixel.adc * simLink.fraction();
290  });
291  }
292 
293  for (auto& pair : simTrackIdToAdc) {
294  if (adcSum == 0.)
295  pair.second = 0.;
296  else
297  pair.second /= adcSum;
298  }
299 
300  return simTrackIdToAdc;
301  }
302 
303  std::map<unsigned int, double> chargeFraction(const SiStripCluster& cluster,
304  const DetId& detId,
305  const edm::DetSetVector<StripDigiSimLink>& digiSimLink) {
306  std::map<unsigned int, double> simTrackIdToAdc;
307 
308  auto idetset = digiSimLink.find(detId);
309  if (idetset == digiSimLink.end())
310  return simTrackIdToAdc;
311 
312  double adcSum = 0;
314  int first = cluster.firstStrip();
315  for (size_t i = 0; i < cluster.amplitudes().size(); ++i) {
316  adcSum += cluster.amplitudes()[i];
317  forEachMatchedSimLink(*idetset, first + i, [&](const StripDigiSimLink& simLink) {
318  double& adc = simTrackIdToAdc[simLink.SimTrackId()];
319  adc += cluster.amplitudes()[i] * simLink.fraction();
320  });
321 
322  for (const auto& pair : simTrackIdToAdc) {
323  simTrackIdToAdc[pair.first] = (adcSum != 0. ? pair.second / adcSum : 0.);
324  }
325  }
326  return simTrackIdToAdc;
327  }
328 
329  std::map<unsigned int, double> chargeFraction(const Phase2TrackerCluster1D& cluster,
330  const DetId& detId,
331  const edm::DetSetVector<StripDigiSimLink>& digiSimLink) {
332  std::map<unsigned int, double> simTrackIdToAdc;
333  throw cms::Exception("LogicError") << "Not possible to use StripDigiSimLink with Phase2TrackerCluster1D! ";
334  return simTrackIdToAdc;
335  }
336 
337  //In the OT, there is no measurement of the charge, so no ADC value.
338  //Only in the SSA chip (so in PSs) you have one "threshold" flag that tells you if the charge of at least one strip in the cluster exceeded 1.2 MIPs.
339  std::map<unsigned int, double> chargeFraction(const Phase2TrackerCluster1D& cluster,
340  const DetId& detId,
341  const edm::DetSetVector<PixelDigiSimLink>& digiSimLink) {
342  std::map<unsigned int, double> simTrackIdToAdc;
343  return simTrackIdToAdc;
344  }
345 
346  struct TrackTPMatch {
347  int key = -1;
348  int countClusters = 0;
349  };
350 
351  template <typename HRange>
352  TrackTPMatch findBestMatchingTrackingParticle(const HRange& hits,
353  const ClusterTPAssociation& clusterToTPMap,
354  const TrackingParticleRefKeyToIndex& tpKeyToIndex) {
355  struct Count {
356  int clusters = 0;
357  size_t innermostHit = std::numeric_limits<size_t>::max();
358  };
359 
360  std::vector<OmniClusterRef> clusters = track_associator::hitsToClusterRefs(hits.begin(), hits.end());
361 
362  std::unordered_map<int, Count> count;
363  for (size_t iCluster = 0, end = clusters.size(); iCluster < end; ++iCluster) {
364  const auto& clusterRef = clusters[iCluster];
365 
366  auto range = clusterToTPMap.equal_range(clusterRef);
367  for (auto ip = range.first; ip != range.second; ++ip) {
368  const auto tpKey = ip->second.key();
369  if (tpKeyToIndex.find(tpKey) == tpKeyToIndex.end()) // filter out TPs not given as an input
370  continue;
371 
372  auto& elem = count[tpKey];
373  ++elem.clusters;
374  elem.innermostHit = std::min(elem.innermostHit, iCluster);
375  }
376  }
377 
378  // In case there are many matches with the same number of clusters,
379  // select the one with innermost hit
380  TrackTPMatch best;
381  int bestCount = 2; // require >= 3 cluster for the best match
382  size_t bestInnermostHit = std::numeric_limits<size_t>::max();
383  for (auto& keyCount : count) {
384  if (keyCount.second.clusters > bestCount ||
385  (keyCount.second.clusters == bestCount && keyCount.second.innermostHit < bestInnermostHit)) {
386  best.key = keyCount.first;
387  best.countClusters = bestCount = keyCount.second.clusters;
388  bestInnermostHit = keyCount.second.innermostHit;
389  }
390  }
391 
392  LogTrace("TrackingNtuple") << "findBestMatchingTrackingParticle key " << best.key;
393 
394  return best;
395  }
396 
397  template <typename HRange>
398  TrackTPMatch findMatchingTrackingParticleFromFirstHit(const HRange& hits,
399  const ClusterTPAssociation& clusterToTPMap,
400  const TrackingParticleRefKeyToIndex& tpKeyToIndex) {
401  TrackTPMatch best;
402 
403  std::vector<OmniClusterRef> clusters = track_associator::hitsToClusterRefs(hits.begin(), hits.end());
404  if (clusters.empty()) {
405  return best;
406  }
407 
408  auto operateCluster = [&](const auto& clusterRef, const auto& func) {
409  auto range = clusterToTPMap.equal_range(clusterRef);
410  for (auto ip = range.first; ip != range.second; ++ip) {
411  const auto tpKey = ip->second.key();
412  if (tpKeyToIndex.find(tpKey) == tpKeyToIndex.end()) // filter out TPs not given as an input
413  continue;
414  func(tpKey);
415  }
416  };
417 
418  std::vector<unsigned int>
419  validTPs; // first cluster can be associated to multiple TPs, use vector as set as this should be small
420  auto iCluster = clusters.begin();
421  operateCluster(*iCluster, [&](unsigned int tpKey) { validTPs.push_back(tpKey); });
422  if (validTPs.empty()) {
423  return best;
424  }
425  ++iCluster;
426  ++best.countClusters;
427 
428  std::vector<bool> foundTPs(validTPs.size(), false);
429  for (auto iEnd = clusters.end(); iCluster != iEnd; ++iCluster) {
430  const auto& clusterRef = *iCluster;
431 
432  // find out to which first-cluster TPs this cluster is matched to
433  operateCluster(clusterRef, [&](unsigned int tpKey) {
434  auto found = std::find(cbegin(validTPs), cend(validTPs), tpKey);
435  if (found != cend(validTPs)) {
436  foundTPs[std::distance(cbegin(validTPs), found)] = true;
437  }
438  });
439 
440  // remove the non-found TPs
441  auto iTP = validTPs.size();
442  do {
443  --iTP;
444 
445  if (!foundTPs[iTP]) {
446  validTPs.erase(validTPs.begin() + iTP);
447  foundTPs.erase(foundTPs.begin() + iTP);
448  }
449  } while (iTP > 0);
450  if (!validTPs.empty()) {
451  // for multiple TPs the "first one" is a bit arbitrary, but
452  // I hope it is rare that a track would have many
453  // consecutive hits matched to two TPs
454  best.key = validTPs[0];
455  } else {
456  break;
457  }
458 
459  std::fill(begin(foundTPs), end(foundTPs), false);
460  ++best.countClusters;
461  }
462 
463  // Reqquire >= 3 clusters for a match
464  return best.countClusters >= 3 ? best : TrackTPMatch();
465  }
466 } // namespace
467 
468 //
469 // class declaration
470 //
471 
472 class TrackingNtuple : public edm::one::EDAnalyzer<edm::one::SharedResources> {
473 public:
474  explicit TrackingNtuple(const edm::ParameterSet&);
475  ~TrackingNtuple() override;
476 
477  static void fillDescriptions(edm::ConfigurationDescriptions& descriptions);
478 
479 private:
480  void analyze(const edm::Event&, const edm::EventSetup&) override;
481 
482  void clearVariables();
483 
484  enum class HitType { Pixel = 0, Strip = 1, Glued = 2, Invalid = 3, Phase2OT = 4, Unknown = 99 };
485 
486  // This gives the "best" classification of a reco hit
487  // In case of reco hit mathing to multiple sim, smaller number is
488  // considered better
489  // To be kept in synch with class HitSimType in ntuple.py
490  enum class HitSimType { Signal = 0, ITPileup = 1, OOTPileup = 2, Noise = 3, Unknown = 99 };
491 
492  using MVACollection = std::vector<float>;
493  using QualityMaskCollection = std::vector<unsigned char>;
494 
498 
499  struct TPHitIndex {
500  TPHitIndex(unsigned int tp = 0, unsigned int simHit = 0, float to = 0, unsigned int id = 0)
501  : tpKey(tp), simHitIdx(simHit), tof(to), detId(id) {}
502  unsigned int tpKey;
503  unsigned int simHitIdx;
504  float tof;
505  unsigned int detId;
506  };
507  static bool tpHitIndexListLess(const TPHitIndex& i, const TPHitIndex& j) { return (i.tpKey < j.tpKey); }
508  static bool tpHitIndexListLessSort(const TPHitIndex& i, const TPHitIndex& j) {
509  if (i.tpKey == j.tpKey) {
510  if (edm::isNotFinite(i.tof) && edm::isNotFinite(j.tof)) {
511  return i.detId < j.detId;
512  }
513  return i.tof < j.tof; // works as intended if either one is NaN
514  }
515  return i.tpKey < j.tpKey;
516  }
517 
518  void fillBeamSpot(const reco::BeamSpot& bs);
519  void fillPixelHits(const edm::Event& iEvent,
520  const TrackerGeometry& tracker,
521  const ClusterTPAssociation& clusterToTPMap,
522  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
524  const edm::DetSetVector<PixelDigiSimLink>& digiSimLink,
525  const TrackerTopology& tTopo,
526  const SimHitRefKeyToIndex& simHitRefKeyToIndex,
527  std::set<edm::ProductID>& hitProductIds);
528 
530  const TrackerGeometry& tracker,
531  const ClusterTPAssociation& clusterToTPMap,
532  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
534  const edm::DetSetVector<StripDigiSimLink>& digiSimLink,
535  const TrackerTopology& tTopo,
536  const SimHitRefKeyToIndex& simHitRefKeyToIndex,
537  std::set<edm::ProductID>& hitProductIds);
538 
540  const TrackerGeometry& tracker,
541  const TrackerTopology& tTopo,
542  std::vector<std::pair<int, int>>& monoStereoClusterList);
543 
545  const TrackerGeometry& tracker,
546  const TrackerTopology& tTopo,
547  const std::vector<std::pair<uint64_t, StripMaskContainer const*>>& stripMasks,
548  std::vector<std::pair<int, int>>& monoStereoClusterList);
549 
550  void fillPhase2OTHits(const edm::Event& iEvent,
551  const ClusterTPAssociation& clusterToTPMap,
552  const TrackerGeometry& tracker,
553  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
555  const edm::DetSetVector<PixelDigiSimLink>& digiSimLink,
556  const TrackerTopology& tTopo,
557  const SimHitRefKeyToIndex& simHitRefKeyToIndex,
558  std::set<edm::ProductID>& hitProductIds);
559 
560  void fillSeeds(const edm::Event& iEvent,
561  const TrackingParticleRefVector& tpCollection,
562  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
563  const reco::BeamSpot& bs,
564  const TrackerGeometry& tracker,
565  const reco::TrackToTrackingParticleAssociator& associatorByHits,
566  const ClusterTPAssociation& clusterToTPMap,
567  const MagneticField& theMF,
568  const TrackerTopology& tTopo,
569  std::vector<std::pair<int, int>>& monoStereoClusterList,
570  const std::set<edm::ProductID>& hitProductIds,
571  std::map<edm::ProductID, size_t>& seedToCollIndex);
572 
574  const TrackerGeometry& tracker,
575  const TrackingParticleRefVector& tpCollection,
576  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
577  const TrackingParticleRefKeyToCount& tpKeyToClusterCount,
578  const MagneticField& mf,
579  const reco::BeamSpot& bs,
581  const reco::TrackToTrackingParticleAssociator& associatorByHits,
582  const ClusterTPAssociation& clusterToTPMap,
583  const TrackerTopology& tTopo,
584  const std::set<edm::ProductID>& hitProductIds,
585  const std::map<edm::ProductID, size_t>& seedToCollIndex,
586  const std::vector<const MVACollection*>& mvaColls,
587  const std::vector<const QualityMaskCollection*>& qualColls);
588 
590  int algo,
591  const TrackingParticleRefVector& tpCollection,
592  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
593  const TrackingParticleRefKeyToCount& tpKeyToClusterCount,
594  const MagneticField& mf,
595  const reco::BeamSpot& bs,
597  const reco::TrackToTrackingParticleAssociator& associatorByHits,
598  const ClusterTPAssociation& clusterToTPMap,
599  const TrackerGeometry& tracker,
600  const TrackerTopology& tTopo,
601  const std::set<edm::ProductID>& hitProductIds,
602  const std::map<edm::ProductID, size_t>& seedToCollIndex);
603 
604  void fillSimHits(const TrackerGeometry& tracker,
605  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
607  const TrackerTopology& tTopo,
608  SimHitRefKeyToIndex& simHitRefKeyToIndex,
609  std::vector<TPHitIndex>& tpHitList);
610 
612  const edm::EventSetup& iSetup,
614  const reco::BeamSpot& bs,
615  const TrackingParticleRefVector& tpCollection,
616  const TrackingVertexRefKeyToIndex& tvKeyToIndex,
617  const reco::TrackToTrackingParticleAssociator& associatorByHits,
618  const std::vector<TPHitIndex>& tpHitList,
619  const TrackingParticleRefKeyToCount& tpKeyToClusterCount);
620 
622  const reco::SimToRecoCollection& simRecColl,
623  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
624  const unsigned int seedOffset);
625 
627 
628  void fillTrackingVertices(const TrackingVertexRefVector& trackingVertices,
629  const TrackingParticleRefKeyToIndex& tpKeyToIndex);
630 
631  struct SimHitData {
632  std::vector<int> matchingSimHit;
633  std::vector<float> chargeFraction;
634  std::vector<float> xySignificance;
635  std::vector<int> bunchCrossing;
636  std::vector<int> event;
638  };
639 
640  template <typename SimLink>
641  SimHitData matchCluster(const OmniClusterRef& cluster,
642  DetId hitId,
643  int clusterKey,
644  const TrackingRecHit& hit,
645  const ClusterTPAssociation& clusterToTPMap,
646  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
649  const SimHitRefKeyToIndex& simHitRefKeyToIndex,
650  HitType hitType);
651 
652  // ----------member data ---------------------------
656 
657  std::vector<edm::EDGetTokenT<edm::View<reco::Track>>> seedTokens_;
658  std::vector<edm::EDGetTokenT<std::vector<SeedStopInfo>>> seedStopInfoTokens_;
659 
660  std::vector<edm::EDGetTokenT<TrackCandidateCollection>> candidateTokens_;
662  std::vector<std::tuple<edm::EDGetTokenT<MVACollection>, edm::EDGetTokenT<QualityMaskCollection>>>
684 
685  std::vector<std::pair<unsigned int, edm::EDGetTokenT<PixelMaskContainer>>> pixelUseMaskTokens_;
686  std::vector<std::pair<unsigned int, edm::EDGetTokenT<StripMaskContainer>>> stripUseMaskTokens_;
687  std::vector<std::pair<unsigned int, edm::EDGetTokenT<Phase2OTMaskContainer>>> ph2OTUseMaskTokens_;
688 
690  const bool includeSeeds_;
692  const bool addSeedCurvCov_;
693  const bool includeAllHits_;
695  const bool includeMVA_;
697  const bool includeOOT_;
698  const bool keepEleSimHits_;
699  const bool saveSimHitsP3_;
701 
704 
705  TTree* t;
706 
707  // DetId branches
708 #define BOOK(name) tree->Branch((prefix + "_" + #name).c_str(), &name);
709  class DetIdCommon {
710  public:
712 
713  unsigned int operator[](size_t i) const { return detId[i]; }
714 
715  void book(const std::string& prefix, TTree* tree) {
716  BOOK(detId);
717  BOOK(subdet);
718  BOOK(layer);
719  BOOK(side);
720  BOOK(module);
721  BOOK(moduleType);
722  }
723 
724  void push_back(const TrackerGeometry& tracker, const TrackerTopology& tTopo, const DetId& id) {
725  detId.push_back(id.rawId());
726  subdet.push_back(id.subdetId());
727  layer.push_back(tTopo.layer(id));
728  module.push_back(tTopo.module(id));
729  moduleType.push_back(static_cast<int>(tracker.getDetectorType(id)));
730 
731  unsigned short s = 0;
732  switch (id.subdetId()) {
734  s = tTopo.tibSide(id);
735  break;
737  s = tTopo.tobSide(id);
738  break;
739  default:
740  s = tTopo.side(id);
741  }
742  side.push_back(s);
743  }
744 
745  void resize(size_t size) {
746  detId.resize(size);
747  subdet.resize(size);
748  layer.resize(size);
749  side.resize(size);
750  module.resize(size);
751  moduleType.resize(size);
752  }
753 
754  void set(size_t index, const TrackerGeometry& tracker, const TrackerTopology& tTopo, const DetId& id) {
755  detId[index] = id.rawId();
756  subdet[index] = id.subdetId();
757  layer[index] = tTopo.layer(id);
758  side[index] = tTopo.side(id);
759  module[index] = tTopo.module(id);
760  moduleType[index] = static_cast<int>(tracker.getDetectorType(id));
761  }
762 
763  void clear() {
764  detId.clear();
765  subdet.clear();
766  layer.clear();
767  side.clear();
768  module.clear();
769  moduleType.clear();
770  }
771 
772  private:
773  std::vector<unsigned int> detId;
774  std::vector<unsigned short> subdet;
775  std::vector<unsigned short> layer; // or disk/wheel
776  std::vector<unsigned short> side;
777  std::vector<unsigned short> module;
778  std::vector<unsigned int> moduleType;
779  };
780 
782  public:
784 
785  void book(const std::string& prefix, TTree* tree) {
786  BOOK(ladder);
787  BOOK(blade);
788  BOOK(panel);
789  }
790 
791  void push_back(const TrackerGeometry& tracker, const TrackerTopology& tTopo, const DetId& id) {
792  const bool isBarrel = id.subdetId() == PixelSubdetector::PixelBarrel;
793  ladder.push_back(isBarrel ? tTopo.pxbLadder(id) : 0);
794  blade.push_back(isBarrel ? 0 : tTopo.pxfBlade(id));
795  panel.push_back(isBarrel ? 0 : tTopo.pxfPanel(id));
796  }
797 
798  void clear() {
799  ladder.clear();
800  blade.clear();
801  panel.clear();
802  }
803 
804  private:
805  std::vector<unsigned short> ladder;
806  std::vector<unsigned short> blade;
807  std::vector<unsigned short> panel;
808  };
809 
811  public:
813 
814  void book(const std::string& prefix, TTree* tree) {
815  BOOK(order);
816  BOOK(ring);
817  BOOK(rod);
818  }
819 
820  void push_back(const TrackerGeometry& tracker, const TrackerTopology& tTopo, const DetId& id) {
821  const auto parsed = parse(tTopo, id);
822  order.push_back(parsed.order);
823  ring.push_back(parsed.ring);
824  rod.push_back(parsed.rod);
825  }
826 
827  void resize(size_t size) {
828  order.resize(size);
829  ring.resize(size);
830  rod.resize(size);
831  }
832 
833  void set(size_t index, const TrackerGeometry& tracker, const TrackerTopology& tTopo, const DetId& id) {
834  const auto parsed = parse(tTopo, id);
835  order[index] = parsed.order;
836  ring[index] = parsed.ring;
837  rod[index] = parsed.rod;
838  }
839 
840  void clear() {
841  order.clear();
842  ring.clear();
843  rod.clear();
844  }
845 
846  private:
847  struct Parsed {
848  // use int here instead of short to avoid compilation errors due
849  // to narrowing conversion (less boilerplate than explicit static_casts)
850  unsigned int order = 0;
851  unsigned int ring = 0;
852  unsigned int rod = 0;
853  };
854  Parsed parse(const TrackerTopology& tTopo, const DetId& id) const {
855  switch (id.subdetId()) {
857  return Parsed{tTopo.tibOrder(id), 0, 0};
859  return Parsed{tTopo.tidOrder(id), tTopo.tidRing(id), 0};
861  return Parsed{0, 0, tTopo.tobRod(id)};
863  return Parsed{tTopo.tecOrder(id), tTopo.tecRing(id), 0};
864  default:
865  return Parsed{};
866  };
867  }
868 
869  std::vector<unsigned short> order;
870  std::vector<unsigned short> ring;
871  std::vector<unsigned short> rod;
872  };
873 
875  public:
877 
878  void book(const std::string& prefix, TTree* tree) {
879  BOOK(string);
880  BOOK(petalNumber);
881  BOOK(isStereo);
882  BOOK(isRPhi);
883  BOOK(isGlued);
884  }
885 
886  void push_back(const TrackerGeometry& tracker, const TrackerTopology& tTopo, const DetId& id) {
887  const auto parsed = parse(tTopo, id);
888  string.push_back(parsed.string);
889  petalNumber.push_back(parsed.petalNumber);
890  isStereo.push_back(tTopo.isStereo(id));
891  isRPhi.push_back(tTopo.isRPhi(id));
892  isGlued.push_back(parsed.glued);
893  }
894 
895  void resize(size_t size) {
896  string.resize(size);
897  petalNumber.resize(size);
898  isStereo.resize(size);
899  isRPhi.resize(size);
900  isGlued.resize(size);
901  }
902 
903  void set(size_t index, const TrackerGeometry& tracker, const TrackerTopology& tTopo, const DetId& id) {
904  const auto parsed = parse(tTopo, id);
905  string[index] = parsed.string;
906  petalNumber[index] = parsed.petalNumber;
907  isStereo[index] = tTopo.isStereo(id);
908  isRPhi[index] = tTopo.isRPhi(id);
909  isGlued[index] = parsed.glued;
910  }
911 
912  void clear() {
913  string.clear();
914  isStereo.clear();
915  isRPhi.clear();
916  isGlued.clear();
917  petalNumber.clear();
918  }
919 
920  private:
921  struct Parsed {
922  // use int here instead of short to avoid compilation errors due
923  // to narrowing conversion (less boilerplate than explicit static_casts)
924  unsigned int string = 0;
925  unsigned int petalNumber = 0;
926  bool glued = false;
927  };
928  Parsed parse(const TrackerTopology& tTopo, const DetId& id) const {
929  switch (id.subdetId()) {
931  return Parsed{tTopo.tibString(id), 0, tTopo.tibIsDoubleSide(id)};
933  return Parsed{0, 0, tTopo.tidIsDoubleSide(id)};
935  return Parsed{0, 0, tTopo.tobIsDoubleSide(id)};
937  return Parsed{0, tTopo.tecPetalNumber(id), tTopo.tecIsDoubleSide(id)};
938  default:
939  return Parsed{};
940  }
941  }
942 
943  std::vector<unsigned short> string;
944  std::vector<unsigned short> petalNumber;
945  std::vector<unsigned short> isStereo;
946  std::vector<unsigned short> isRPhi;
947  std::vector<unsigned short> isGlued;
948  };
949 
951  public:
953 
954  void book(const std::string& prefix, TTree* tree) {
955  BOOK(isLower);
956  BOOK(isUpper);
957  BOOK(isStack);
958  }
959 
960  void push_back(const TrackerGeometry& tracker, const TrackerTopology& tTopo, const DetId& id) {
961  isLower.push_back(tTopo.isLower(id));
962  isUpper.push_back(tTopo.isUpper(id));
963  isStack.push_back(tTopo.stack(id) ==
964  0); // equivalent to *IsDoubleSide() but without the hardcoded layer+ring requirements
965  }
966 
967  void clear() {
968  isLower.clear();
969  isUpper.clear();
970  isStack.clear();
971  }
972 
973  private:
974  std::vector<unsigned short> isLower;
975  std::vector<unsigned short> isUpper;
976  std::vector<unsigned short> isStack;
977  };
978 #undef BOOK
979 
980  using DetIdPixel = CombineDetId<DetIdCommon, DetIdPixelOnly>;
981  using DetIdStrip = CombineDetId<DetIdCommon, DetIdOTCommon, DetIdStripOnly>;
982  using DetIdPhase2OT = CombineDetId<DetIdCommon, DetIdOTCommon, DetIdPhase2OTOnly>;
983  using DetIdAll = CombineDetId<DetIdCommon, DetIdPixelOnly, DetIdOTCommon, DetIdStripOnly>;
984  using DetIdAllPhase2 = CombineDetId<DetIdCommon, DetIdPixelOnly, DetIdOTCommon, DetIdPhase2OTOnly>;
985 
986  // event
990 
992  // tracks
993  // (first) index runs through tracks
994  std::vector<float> trk_px;
995  std::vector<float> trk_py;
996  std::vector<float> trk_pz;
997  std::vector<float> trk_pt;
998  std::vector<float> trk_inner_px;
999  std::vector<float> trk_inner_py;
1000  std::vector<float> trk_inner_pz;
1001  std::vector<float> trk_inner_pt;
1002  std::vector<float> trk_outer_px;
1003  std::vector<float> trk_outer_py;
1004  std::vector<float> trk_outer_pz;
1005  std::vector<float> trk_outer_pt;
1006  std::vector<float> trk_eta;
1007  std::vector<float> trk_lambda;
1008  std::vector<float> trk_cotTheta;
1009  std::vector<float> trk_phi;
1010  std::vector<float> trk_dxy;
1011  std::vector<float> trk_dz;
1012  std::vector<float> trk_dxyPV;
1013  std::vector<float> trk_dzPV;
1014  std::vector<float> trk_dxyClosestPV;
1015  std::vector<float> trk_dzClosestPV;
1016  std::vector<float> trk_ptErr;
1017  std::vector<float> trk_etaErr;
1018  std::vector<float> trk_lambdaErr;
1019  std::vector<float> trk_phiErr;
1020  std::vector<float> trk_dxyErr;
1021  std::vector<float> trk_dzErr;
1022  std::vector<float> trk_refpoint_x;
1023  std::vector<float> trk_refpoint_y;
1024  std::vector<float> trk_refpoint_z;
1025  std::vector<float> trk_nChi2;
1026  std::vector<float> trk_nChi2_1Dmod;
1027  std::vector<float> trk_ndof;
1028  std::vector<std::vector<float>> trk_mvas;
1029  std::vector<std::vector<unsigned short>> trk_qualityMasks;
1030  std::vector<int> trk_q;
1031  std::vector<unsigned int> trk_nValid;
1032  std::vector<unsigned int> trk_nLost;
1033  std::vector<unsigned int> trk_nInactive;
1034  std::vector<unsigned int> trk_nPixel;
1035  std::vector<unsigned int> trk_nStrip;
1036  std::vector<unsigned int> trk_nOuterLost;
1037  std::vector<unsigned int> trk_nInnerLost;
1038  std::vector<unsigned int> trk_nOuterInactive;
1039  std::vector<unsigned int> trk_nInnerInactive;
1040  std::vector<unsigned int> trk_nPixelLay;
1041  std::vector<unsigned int> trk_nStripLay;
1042  std::vector<unsigned int> trk_n3DLay;
1043  std::vector<unsigned int> trk_nLostLay;
1044  std::vector<unsigned int> trk_nCluster;
1045  std::vector<unsigned int> trk_algo;
1046  std::vector<unsigned int> trk_originalAlgo;
1047  std::vector<decltype(reco::TrackBase().algoMaskUL())> trk_algoMask;
1048  std::vector<unsigned short> trk_stopReason;
1049  std::vector<short> trk_isHP;
1050  std::vector<int> trk_seedIdx;
1051  std::vector<int> trk_vtxIdx;
1052  std::vector<short> trk_isTrue;
1053  std::vector<int> trk_bestSimTrkIdx;
1054  std::vector<float> trk_bestSimTrkShareFrac;
1057  std::vector<float> trk_bestSimTrkNChi2;
1063  std::vector<std::vector<float>> trk_simTrkShareFrac; // second index runs through matched TrackingParticles
1064  std::vector<std::vector<float>> trk_simTrkNChi2; // second index runs through matched TrackingParticles
1065  std::vector<std::vector<int>> trk_simTrkIdx; // second index runs through matched TrackingParticles
1066  std::vector<std::vector<int>> trk_hitIdx; // second index runs through hits
1067  std::vector<std::vector<int>> trk_hitType; // second index runs through hits
1069  // track candidates
1070  // (first) index runs through track candidates
1071  std::vector<short> tcand_pca_valid; // pca: propagated params at BS
1072  std::vector<float> tcand_pca_px;
1073  std::vector<float> tcand_pca_py;
1074  std::vector<float> tcand_pca_pz;
1075  std::vector<float> tcand_pca_pt;
1076  std::vector<float> tcand_pca_eta;
1077  std::vector<float> tcand_pca_phi;
1078  std::vector<float> tcand_pca_dxy;
1079  std::vector<float> tcand_pca_dz;
1080  std::vector<float> tcand_pca_ptErr;
1081  std::vector<float> tcand_pca_etaErr;
1082  std::vector<float> tcand_pca_lambdaErr;
1083  std::vector<float> tcand_pca_phiErr;
1084  std::vector<float> tcand_pca_dxyErr;
1085  std::vector<float> tcand_pca_dzErr;
1086  std::vector<float> tcand_px; // from PState
1087  std::vector<float> tcand_py;
1088  std::vector<float> tcand_pz;
1089  std::vector<float> tcand_pt;
1090  std::vector<float> tcand_x;
1091  std::vector<float> tcand_y;
1092  std::vector<float> tcand_z;
1093  std::vector<float> tcand_qbpErr;
1094  std::vector<float> tcand_lambdaErr;
1095  std::vector<float> tcand_phiErr;
1096  std::vector<float> tcand_xtErr;
1097  std::vector<float> tcand_ytErr;
1098  std::vector<float> tcand_ndof; // sum(hit.dimention) - 5
1099  std::vector<int> tcand_q;
1100  std::vector<unsigned int> tcand_nValid;
1101  std::vector<unsigned int> tcand_nPixel;
1102  std::vector<unsigned int> tcand_nStrip;
1103  std::vector<unsigned int> tcand_nCluster;
1104  std::vector<unsigned int> tcand_algo;
1105  std::vector<unsigned short> tcand_stopReason;
1106  std::vector<int> tcand_seedIdx;
1107  std::vector<int> tcand_vtxIdx;
1108  std::vector<short> tcand_isTrue;
1109  std::vector<int> tcand_bestSimTrkIdx;
1110  std::vector<float> tcand_bestSimTrkShareFrac;
1113  std::vector<float> tcand_bestSimTrkNChi2;
1119  std::vector<std::vector<float>> tcand_simTrkShareFrac; // second index runs through matched TrackingParticles
1120  std::vector<std::vector<float>> tcand_simTrkNChi2; // second index runs through matched TrackingParticles
1121  std::vector<std::vector<int>> tcand_simTrkIdx; // second index runs through matched TrackingParticles
1122  std::vector<std::vector<int>> tcand_hitIdx; // second index runs through hits
1123  std::vector<std::vector<int>> tcand_hitType; // second index runs through hits
1125  // sim tracks
1126  // (first) index runs through TrackingParticles
1127  std::vector<int> sim_event;
1128  std::vector<int> sim_bunchCrossing;
1129  std::vector<int> sim_pdgId;
1130  std::vector<std::vector<int>> sim_genPdgIds;
1131  std::vector<int> sim_isFromBHadron;
1132  std::vector<float> sim_px;
1133  std::vector<float> sim_py;
1134  std::vector<float> sim_pz;
1135  std::vector<float> sim_pt;
1136  std::vector<float> sim_eta;
1137  std::vector<float> sim_phi;
1138  std::vector<float> sim_pca_pt;
1139  std::vector<float> sim_pca_eta;
1140  std::vector<float> sim_pca_lambda;
1141  std::vector<float> sim_pca_cotTheta;
1142  std::vector<float> sim_pca_phi;
1143  std::vector<float> sim_pca_dxy;
1144  std::vector<float> sim_pca_dz;
1145  std::vector<int> sim_q;
1146  // numbers of sim hits/layers
1147  std::vector<unsigned int> sim_nValid;
1148  std::vector<unsigned int> sim_nPixel;
1149  std::vector<unsigned int> sim_nStrip;
1150  std::vector<unsigned int> sim_nLay;
1151  std::vector<unsigned int> sim_nPixelLay;
1152  std::vector<unsigned int> sim_n3DLay;
1153  // number of sim hits as calculated in TrackingTruthAccumulator
1154  std::vector<unsigned int> sim_nTrackerHits;
1155  // number of clusters associated to TP
1156  std::vector<unsigned int> sim_nRecoClusters;
1157  // links to other objects
1158  std::vector<std::vector<int>> sim_trkIdx; // second index runs through matched tracks
1159  std::vector<std::vector<float>> sim_trkShareFrac; // second index runs through matched tracks
1160  std::vector<std::vector<int>> sim_seedIdx; // second index runs through matched seeds
1161  std::vector<int> sim_parentVtxIdx;
1162  std::vector<std::vector<int>> sim_decayVtxIdx; // second index runs through decay vertices
1163  std::vector<std::vector<int>> sim_simHitIdx; // second index runs through SimHits
1165  // pixel hits
1166  // (first) index runs through hits
1167  std::vector<short> pix_isBarrel;
1169  std::vector<std::vector<int>> pix_trkIdx; // second index runs through tracks containing this hit
1170  std::vector<std::vector<float>> pix_onTrk_x; // second index runs through tracks containing this hit
1171  std::vector<std::vector<float>> pix_onTrk_y; // same for all pix_onTrk_*
1172  std::vector<std::vector<float>> pix_onTrk_z; //
1173  std::vector<std::vector<float>> pix_onTrk_xx; //
1174  std::vector<std::vector<float>> pix_onTrk_xy; //
1175  std::vector<std::vector<float>> pix_onTrk_yy; //
1176  std::vector<std::vector<float>> pix_onTrk_yz; //
1177  std::vector<std::vector<float>> pix_onTrk_zz; //
1178  std::vector<std::vector<float>> pix_onTrk_zx; //
1179  std::vector<std::vector<int>> pix_tcandIdx; // second index runs through candidates containing this hit
1180  std::vector<std::vector<int>> pix_seeIdx; // second index runs through seeds containing this hit
1181  std::vector<std::vector<int>> pix_simHitIdx; // second index runs through SimHits inducing this hit
1182  std::vector<std::vector<float>> pix_xySignificance; // second index runs through SimHits inducing this hit
1183  std::vector<std::vector<float>> pix_chargeFraction; // second index runs through SimHits inducing this hit
1184  std::vector<unsigned short> pix_simType;
1185  std::vector<float> pix_x;
1186  std::vector<float> pix_y;
1187  std::vector<float> pix_z;
1188  std::vector<float> pix_xx;
1189  std::vector<float> pix_xy;
1190  std::vector<float> pix_yy;
1191  std::vector<float> pix_yz;
1192  std::vector<float> pix_zz;
1193  std::vector<float> pix_zx;
1194  std::vector<float>
1195  pix_radL; //http://cmslxr.fnal.gov/lxr/source/DataFormats/GeometrySurface/interface/MediumProperties.h
1196  std::vector<float> pix_bbxi;
1197  std::vector<int> pix_clustSizeCol;
1198  std::vector<int> pix_clustSizeRow;
1199  std::vector<uint64_t> pix_usedMask;
1201  // strip hits
1202  // (first) index runs through hits
1203  std::vector<short> str_isBarrel;
1205  std::vector<std::vector<int>> str_trkIdx; // second index runs through tracks containing this hit
1206  std::vector<std::vector<float>> str_onTrk_x; // second index runs through tracks containing this hit
1207  std::vector<std::vector<float>> str_onTrk_y; // same for all pix_onTrk_*
1208  std::vector<std::vector<float>> str_onTrk_z; //
1209  std::vector<std::vector<float>> str_onTrk_xx; //
1210  std::vector<std::vector<float>> str_onTrk_xy; //
1211  std::vector<std::vector<float>> str_onTrk_yy; //
1212  std::vector<std::vector<float>> str_onTrk_yz; //
1213  std::vector<std::vector<float>> str_onTrk_zz; //
1214  std::vector<std::vector<float>> str_onTrk_zx; //
1215  std::vector<std::vector<int>> str_tcandIdx; // second index runs through candidates containing this hit
1216  std::vector<std::vector<int>> str_seeIdx; // second index runs through seeds containing this hit
1217  std::vector<std::vector<int>> str_simHitIdx; // second index runs through SimHits inducing this hit
1218  std::vector<std::vector<float>> str_xySignificance; // second index runs through SimHits inducing this hit
1219  std::vector<std::vector<float>> str_chargeFraction; // second index runs through SimHits inducing this hit
1220  std::vector<unsigned short> str_simType;
1221  std::vector<float> str_x;
1222  std::vector<float> str_y;
1223  std::vector<float> str_z;
1224  std::vector<float> str_xx;
1225  std::vector<float> str_xy;
1226  std::vector<float> str_yy;
1227  std::vector<float> str_yz;
1228  std::vector<float> str_zz;
1229  std::vector<float> str_zx;
1230  std::vector<float>
1231  str_radL; //http://cmslxr.fnal.gov/lxr/source/DataFormats/GeometrySurface/interface/MediumProperties.h
1232  std::vector<float> str_bbxi;
1233  std::vector<float> str_chargePerCM;
1234  std::vector<int> str_clustSize;
1235  std::vector<uint64_t> str_usedMask;
1237  // strip matched hits
1238  // (first) index runs through hits
1239  std::vector<short> glu_isBarrel;
1241  std::vector<int> glu_monoIdx;
1242  std::vector<int> glu_stereoIdx;
1243  std::vector<std::vector<int>> glu_seeIdx; // second index runs through seeds containing this hit
1244  std::vector<float> glu_x;
1245  std::vector<float> glu_y;
1246  std::vector<float> glu_z;
1247  std::vector<float> glu_xx;
1248  std::vector<float> glu_xy;
1249  std::vector<float> glu_yy;
1250  std::vector<float> glu_yz;
1251  std::vector<float> glu_zz;
1252  std::vector<float> glu_zx;
1253  std::vector<float>
1254  glu_radL; //http://cmslxr.fnal.gov/lxr/source/DataFormats/GeometrySurface/interface/MediumProperties.h
1255  std::vector<float> glu_bbxi;
1256  std::vector<float> glu_chargePerCM;
1257  std::vector<int> glu_clustSizeMono;
1258  std::vector<int> glu_clustSizeStereo;
1259  std::vector<uint64_t> glu_usedMaskMono;
1260  std::vector<uint64_t> glu_usedMaskStereo;
1262  // phase2 Outer Tracker hits
1263  // (first) index runs through hits
1264  std::vector<short> ph2_isBarrel;
1266  std::vector<std::vector<int>> ph2_trkIdx; // second index runs through tracks containing this hit
1267  std::vector<std::vector<float>> ph2_onTrk_x; // second index runs through tracks containing this hit
1268  std::vector<std::vector<float>> ph2_onTrk_y; // same for all pix_onTrk_*
1269  std::vector<std::vector<float>> ph2_onTrk_z; //
1270  std::vector<std::vector<float>> ph2_onTrk_xx; //
1271  std::vector<std::vector<float>> ph2_onTrk_xy; //
1272  std::vector<std::vector<float>> ph2_onTrk_yy; //
1273  std::vector<std::vector<float>> ph2_onTrk_yz; //
1274  std::vector<std::vector<float>> ph2_onTrk_zz; //
1275  std::vector<std::vector<float>> ph2_onTrk_zx; //
1276  std::vector<std::vector<int>> ph2_tcandIdx; // second index runs through candidates containing this hit
1277  std::vector<std::vector<int>> ph2_seeIdx; // second index runs through seeds containing this hit
1278  std::vector<std::vector<int>> ph2_simHitIdx; // second index runs through SimHits inducing this hit
1279  std::vector<std::vector<float>> ph2_xySignificance; // second index runs through SimHits inducing this hit
1280  //std::vector<std::vector<float>> ph2_chargeFraction; // Not supported at the moment for Phase2
1281  std::vector<unsigned short> ph2_simType;
1282  std::vector<float> ph2_x;
1283  std::vector<float> ph2_y;
1284  std::vector<float> ph2_z;
1285  std::vector<float> ph2_xx;
1286  std::vector<float> ph2_xy;
1287  std::vector<float> ph2_yy;
1288  std::vector<float> ph2_yz;
1289  std::vector<float> ph2_zz;
1290  std::vector<float> ph2_zx;
1291  std::vector<float>
1292  ph2_radL; //http://cmslxr.fnal.gov/lxr/source/DataFormats/GeometrySurface/interface/MediumProperties.h
1293  std::vector<float> ph2_bbxi;
1294  std::vector<uint64_t> ph2_usedMask;
1295 
1297  // invalid (missing/inactive/etc) hits
1298  // (first) index runs through hits
1299  std::vector<short> inv_isBarrel;
1302  std::vector<unsigned short> inv_type;
1304  // sim hits
1305  // (first) index runs through hits
1308  std::vector<float> simhit_x;
1309  std::vector<float> simhit_y;
1310  std::vector<float> simhit_z;
1311  std::vector<float> simhit_px;
1312  std::vector<float> simhit_py;
1313  std::vector<float> simhit_pz;
1314  std::vector<int> simhit_particle;
1315  std::vector<short> simhit_process;
1316  std::vector<float> simhit_eloss;
1317  std::vector<float> simhit_tof;
1318  //std::vector<unsigned int> simhit_simTrackId; // can be useful for debugging, but not much of general interest
1319  std::vector<int> simhit_simTrkIdx;
1320  std::vector<std::vector<int>> simhit_hitIdx; // second index runs through induced reco hits
1321  std::vector<std::vector<int>> simhit_hitType; // second index runs through induced reco hits
1323  // beam spot
1324  float bsp_x;
1325  float bsp_y;
1326  float bsp_z;
1327  float bsp_sigmax;
1328  float bsp_sigmay;
1329  float bsp_sigmaz;
1331  // seeds
1332  // (first) index runs through seeds
1333  std::vector<short> see_fitok;
1334  std::vector<float> see_px;
1335  std::vector<float> see_py;
1336  std::vector<float> see_pz;
1337  std::vector<float> see_pt;
1338  std::vector<float> see_eta;
1339  std::vector<float> see_phi;
1340  std::vector<float> see_dxy;
1341  std::vector<float> see_dz;
1342  std::vector<float> see_ptErr;
1343  std::vector<float> see_etaErr;
1344  std::vector<float> see_phiErr;
1345  std::vector<float> see_dxyErr;
1346  std::vector<float> see_dzErr;
1347  std::vector<float> see_chi2;
1348  std::vector<float> see_statePt;
1349  std::vector<float> see_stateTrajX;
1350  std::vector<float> see_stateTrajY;
1351  std::vector<float> see_stateTrajPx;
1352  std::vector<float> see_stateTrajPy;
1353  std::vector<float> see_stateTrajPz;
1354  std::vector<float> see_stateTrajGlbX;
1355  std::vector<float> see_stateTrajGlbY;
1356  std::vector<float> see_stateTrajGlbZ;
1357  std::vector<float> see_stateTrajGlbPx;
1358  std::vector<float> see_stateTrajGlbPy;
1359  std::vector<float> see_stateTrajGlbPz;
1360  std::vector<std::vector<float>> see_stateCurvCov;
1361  std::vector<int> see_q;
1362  std::vector<unsigned int> see_nValid;
1363  std::vector<unsigned int> see_nPixel;
1364  std::vector<unsigned int> see_nGlued;
1365  std::vector<unsigned int> see_nStrip;
1366  std::vector<unsigned int> see_nPhase2OT;
1367  std::vector<unsigned int> see_nCluster;
1368  std::vector<unsigned int> see_algo;
1369  std::vector<unsigned short> see_stopReason;
1370  std::vector<unsigned short> see_nCands;
1371  std::vector<int> see_trkIdx;
1372  std::vector<int> see_tcandIdx;
1373  std::vector<short> see_isTrue;
1374  std::vector<int> see_bestSimTrkIdx;
1375  std::vector<float> see_bestSimTrkShareFrac;
1378  std::vector<std::vector<float>> see_simTrkShareFrac; // second index runs through matched TrackingParticles
1379  std::vector<std::vector<int>> see_simTrkIdx; // second index runs through matched TrackingParticles
1380  std::vector<std::vector<int>> see_hitIdx; // second index runs through hits
1381  std::vector<std::vector<int>> see_hitType; // second index runs through hits
1382  //seed algo offset, index runs through iterations
1383  std::vector<unsigned int> see_offset;
1384 
1386  // Vertices
1387  // (first) index runs through vertices
1388  std::vector<float> vtx_x;
1389  std::vector<float> vtx_y;
1390  std::vector<float> vtx_z;
1391  std::vector<float> vtx_xErr;
1392  std::vector<float> vtx_yErr;
1393  std::vector<float> vtx_zErr;
1394  std::vector<float> vtx_ndof;
1395  std::vector<float> vtx_chi2;
1396  std::vector<short> vtx_fake;
1397  std::vector<short> vtx_valid;
1398  std::vector<std::vector<int>> vtx_trkIdx; // second index runs through tracks used in the vertex fit
1399 
1401  // Tracking vertices
1402  // (first) index runs through TrackingVertices
1403  std::vector<int> simvtx_event;
1404  std::vector<int> simvtx_bunchCrossing;
1405  std::vector<unsigned int> simvtx_processType; // only from first SimVertex of TrackingVertex
1406  std::vector<float> simvtx_x;
1407  std::vector<float> simvtx_y;
1408  std::vector<float> simvtx_z;
1409  std::vector<std::vector<int>> simvtx_sourceSimIdx; // second index runs through source TrackingParticles
1410  std::vector<std::vector<int>> simvtx_daughterSimIdx; // second index runs through daughter TrackingParticles
1411  std::vector<int> simpv_idx;
1412 };
1413 
1414 //
1415 // constructors and destructor
1416 //
1418  : mfToken_(esConsumes()),
1419  tTopoToken_(esConsumes()),
1420  tGeomToken_(esConsumes()),
1421  trackToken_(consumes<edm::View<reco::Track>>(iConfig.getUntrackedParameter<edm::InputTag>("tracks"))),
1422  clusterTPMapToken_(consumes<ClusterTPAssociation>(iConfig.getUntrackedParameter<edm::InputTag>("clusterTPMap"))),
1423  simHitTPMapToken_(consumes<SimHitTPAssociationProducer::SimHitTPAssociationList>(
1424  iConfig.getUntrackedParameter<edm::InputTag>("simHitTPMap"))),
1425  trackAssociatorToken_(consumes<reco::TrackToTrackingParticleAssociator>(
1426  iConfig.getUntrackedParameter<edm::InputTag>("trackAssociator"))),
1427  pixelSimLinkToken_(consumes<edm::DetSetVector<PixelDigiSimLink>>(
1428  iConfig.getUntrackedParameter<edm::InputTag>("pixelDigiSimLink"))),
1429  stripSimLinkToken_(consumes<edm::DetSetVector<StripDigiSimLink>>(
1430  iConfig.getUntrackedParameter<edm::InputTag>("stripDigiSimLink"))),
1431  siphase2OTSimLinksToken_(consumes<edm::DetSetVector<PixelDigiSimLink>>(
1432  iConfig.getUntrackedParameter<edm::InputTag>("phase2OTSimLink"))),
1433  includeStripHits_(!iConfig.getUntrackedParameter<edm::InputTag>("stripDigiSimLink").label().empty()),
1434  includePhase2OTHits_(!iConfig.getUntrackedParameter<edm::InputTag>("phase2OTSimLink").label().empty()),
1435  beamSpotToken_(consumes<reco::BeamSpot>(iConfig.getUntrackedParameter<edm::InputTag>("beamSpot"))),
1436  pixelRecHitToken_(
1437  consumes<SiPixelRecHitCollection>(iConfig.getUntrackedParameter<edm::InputTag>("pixelRecHits"))),
1438  stripRphiRecHitToken_(
1439  consumes<SiStripRecHit2DCollection>(iConfig.getUntrackedParameter<edm::InputTag>("stripRphiRecHits"))),
1440  stripStereoRecHitToken_(
1441  consumes<SiStripRecHit2DCollection>(iConfig.getUntrackedParameter<edm::InputTag>("stripStereoRecHits"))),
1442  stripMatchedRecHitToken_(consumes<SiStripMatchedRecHit2DCollection>(
1443  iConfig.getUntrackedParameter<edm::InputTag>("stripMatchedRecHits"))),
1444  phase2OTRecHitToken_(consumes<Phase2TrackerRecHit1DCollectionNew>(
1445  iConfig.getUntrackedParameter<edm::InputTag>("phase2OTRecHits"))),
1446  vertexToken_(consumes<reco::VertexCollection>(iConfig.getUntrackedParameter<edm::InputTag>("vertices"))),
1447  trackingVertexToken_(
1448  consumes<TrackingVertexCollection>(iConfig.getUntrackedParameter<edm::InputTag>("trackingVertices"))),
1449  tpNLayersToken_(consumes<edm::ValueMap<unsigned int>>(
1450  iConfig.getUntrackedParameter<edm::InputTag>("trackingParticleNlayers"))),
1451  tpNPixelLayersToken_(consumes<edm::ValueMap<unsigned int>>(
1452  iConfig.getUntrackedParameter<edm::InputTag>("trackingParticleNpixellayers"))),
1453  tpNStripStereoLayersToken_(consumes<edm::ValueMap<unsigned int>>(
1454  iConfig.getUntrackedParameter<edm::InputTag>("trackingParticleNstripstereolayers"))),
1455  includeSeeds_(iConfig.getUntrackedParameter<bool>("includeSeeds")),
1456  includeTrackCandidates_(iConfig.getUntrackedParameter<bool>("includeTrackCandidates")),
1457  addSeedCurvCov_(iConfig.getUntrackedParameter<bool>("addSeedCurvCov")),
1458  includeAllHits_(iConfig.getUntrackedParameter<bool>("includeAllHits")),
1459  includeOnTrackHitData_(iConfig.getUntrackedParameter<bool>("includeOnTrackHitData")),
1460  includeMVA_(iConfig.getUntrackedParameter<bool>("includeMVA")),
1461  includeTrackingParticles_(iConfig.getUntrackedParameter<bool>("includeTrackingParticles")),
1462  includeOOT_(iConfig.getUntrackedParameter<bool>("includeOOT")),
1463  keepEleSimHits_(iConfig.getUntrackedParameter<bool>("keepEleSimHits")),
1464  saveSimHitsP3_(iConfig.getUntrackedParameter<bool>("saveSimHitsP3")),
1465  simHitBySignificance_(iConfig.getUntrackedParameter<bool>("simHitBySignificance")),
1466  parametersDefiner_(iConfig.getUntrackedParameter<edm::InputTag>("beamSpot"), consumesCollector()) {
1467  if (includeSeeds_) {
1468  seedTokens_ =
1469  edm::vector_transform(iConfig.getUntrackedParameter<std::vector<edm::InputTag>>("seedTracks"),
1470  [&](const edm::InputTag& tag) { return consumes<edm::View<reco::Track>>(tag); });
1472  edm::vector_transform(iConfig.getUntrackedParameter<std::vector<edm::InputTag>>("trackCandidates"),
1473  [&](const edm::InputTag& tag) { return consumes<std::vector<SeedStopInfo>>(tag); });
1474  if (seedTokens_.size() != seedStopInfoTokens_.size()) {
1475  throw cms::Exception("Configuration") << "Got " << seedTokens_.size() << " seed collections, but "
1476  << seedStopInfoTokens_.size() << " track candidate collections";
1477  }
1478  }
1481  edm::vector_transform(iConfig.getUntrackedParameter<std::vector<edm::InputTag>>("trackCandidates"),
1482  [&](const edm::InputTag& tag) { return consumes<TrackCandidateCollection>(tag); });
1483 
1484  if (includeAllHits_) {
1486  throw cms::Exception("Configuration")
1487  << "Both stripDigiSimLink and phase2OTSimLink are set, please set only either one (this information is used "
1488  "to infer if you're running phase0/1 or phase2 detector)";
1489  }
1491  throw cms::Exception("Configuration")
1492  << "Neither stripDigiSimLink or phase2OTSimLink are set, please set either one.";
1493  }
1494 
1495  auto const& maskVPset = iConfig.getUntrackedParameterSetVector("clusterMasks");
1496  pixelUseMaskTokens_.reserve(maskVPset.size());
1497  stripUseMaskTokens_.reserve(maskVPset.size());
1498  ph2OTUseMaskTokens_.reserve(maskVPset.size());
1499  for (auto const& mask : maskVPset) {
1500  auto index = mask.getUntrackedParameter<unsigned int>("index");
1501  assert(index < 64);
1502  pixelUseMaskTokens_.emplace_back(index,
1503  consumes<PixelMaskContainer>(mask.getUntrackedParameter<edm::InputTag>("src")));
1504  if (includeStripHits_)
1505  stripUseMaskTokens_.emplace_back(
1506  index, consumes<StripMaskContainer>(mask.getUntrackedParameter<edm::InputTag>("src")));
1508  ph2OTUseMaskTokens_.emplace_back(
1509  index, consumes<Phase2OTMaskContainer>(mask.getUntrackedParameter<edm::InputTag>("src")));
1510  }
1511  }
1512 
1513  const bool tpRef = iConfig.getUntrackedParameter<bool>("trackingParticlesRef");
1514  const auto tpTag = iConfig.getUntrackedParameter<edm::InputTag>("trackingParticles");
1515  if (tpRef) {
1516  trackingParticleRefToken_ = consumes<TrackingParticleRefVector>(tpTag);
1517  } else {
1518  trackingParticleToken_ = consumes<TrackingParticleCollection>(tpTag);
1519  }
1520 
1521  tracer_.depth(-2); // as in SimTracker/TrackHistory/src/TrackClassifier.cc
1522 
1523  if (includeMVA_) {
1525  iConfig.getUntrackedParameter<std::vector<std::string>>("trackMVAs"), [&](const std::string& tag) {
1526  return std::make_tuple(consumes<MVACollection>(edm::InputTag(tag, "MVAValues")),
1527  consumes<QualityMaskCollection>(edm::InputTag(tag, "QualityMasks")));
1528  });
1529  }
1530 
1531  usesResource(TFileService::kSharedResource);
1533  t = fs->make<TTree>("tree", "tree");
1534 
1535  t->Branch("event", &ev_event);
1536  t->Branch("lumi", &ev_lumi);
1537  t->Branch("run", &ev_run);
1538 
1539  //tracks
1540  t->Branch("trk_px", &trk_px);
1541  t->Branch("trk_py", &trk_py);
1542  t->Branch("trk_pz", &trk_pz);
1543  t->Branch("trk_pt", &trk_pt);
1544  t->Branch("trk_inner_px", &trk_inner_px);
1545  t->Branch("trk_inner_py", &trk_inner_py);
1546  t->Branch("trk_inner_pz", &trk_inner_pz);
1547  t->Branch("trk_inner_pt", &trk_inner_pt);
1548  t->Branch("trk_outer_px", &trk_outer_px);
1549  t->Branch("trk_outer_py", &trk_outer_py);
1550  t->Branch("trk_outer_pz", &trk_outer_pz);
1551  t->Branch("trk_outer_pt", &trk_outer_pt);
1552  t->Branch("trk_eta", &trk_eta);
1553  t->Branch("trk_lambda", &trk_lambda);
1554  t->Branch("trk_cotTheta", &trk_cotTheta);
1555  t->Branch("trk_phi", &trk_phi);
1556  t->Branch("trk_dxy", &trk_dxy);
1557  t->Branch("trk_dz", &trk_dz);
1558  t->Branch("trk_dxyPV", &trk_dxyPV);
1559  t->Branch("trk_dzPV", &trk_dzPV);
1560  t->Branch("trk_dxyClosestPV", &trk_dxyClosestPV);
1561  t->Branch("trk_dzClosestPV", &trk_dzClosestPV);
1562  t->Branch("trk_ptErr", &trk_ptErr);
1563  t->Branch("trk_etaErr", &trk_etaErr);
1564  t->Branch("trk_lambdaErr", &trk_lambdaErr);
1565  t->Branch("trk_phiErr", &trk_phiErr);
1566  t->Branch("trk_dxyErr", &trk_dxyErr);
1567  t->Branch("trk_dzErr", &trk_dzErr);
1568  t->Branch("trk_refpoint_x", &trk_refpoint_x);
1569  t->Branch("trk_refpoint_y", &trk_refpoint_y);
1570  t->Branch("trk_refpoint_z", &trk_refpoint_z);
1571  t->Branch("trk_nChi2", &trk_nChi2);
1572  t->Branch("trk_nChi2_1Dmod", &trk_nChi2_1Dmod);
1573  t->Branch("trk_ndof", &trk_ndof);
1574  if (includeMVA_) {
1575  trk_mvas.resize(mvaQualityCollectionTokens_.size());
1577  if (!trk_mvas.empty()) {
1578  t->Branch("trk_mva", &(trk_mvas[0]));
1579  t->Branch("trk_qualityMask", &(trk_qualityMasks[0]));
1580  for (size_t i = 1; i < trk_mvas.size(); ++i) {
1581  t->Branch(("trk_mva" + std::to_string(i + 1)).c_str(), &(trk_mvas[i]));
1582  t->Branch(("trk_qualityMask" + std::to_string(i + 1)).c_str(), &(trk_qualityMasks[i]));
1583  }
1584  }
1585  }
1586  t->Branch("trk_q", &trk_q);
1587  t->Branch("trk_nValid", &trk_nValid);
1588  t->Branch("trk_nLost", &trk_nLost);
1589  t->Branch("trk_nInactive", &trk_nInactive);
1590  t->Branch("trk_nPixel", &trk_nPixel);
1591  t->Branch("trk_nStrip", &trk_nStrip);
1592  t->Branch("trk_nOuterLost", &trk_nOuterLost);
1593  t->Branch("trk_nInnerLost", &trk_nInnerLost);
1594  t->Branch("trk_nOuterInactive", &trk_nOuterInactive);
1595  t->Branch("trk_nInnerInactive", &trk_nInnerInactive);
1596  t->Branch("trk_nPixelLay", &trk_nPixelLay);
1597  t->Branch("trk_nStripLay", &trk_nStripLay);
1598  t->Branch("trk_n3DLay", &trk_n3DLay);
1599  t->Branch("trk_nLostLay", &trk_nLostLay);
1600  t->Branch("trk_nCluster", &trk_nCluster);
1601  t->Branch("trk_algo", &trk_algo);
1602  t->Branch("trk_originalAlgo", &trk_originalAlgo);
1603  t->Branch("trk_algoMask", &trk_algoMask);
1604  t->Branch("trk_stopReason", &trk_stopReason);
1605  t->Branch("trk_isHP", &trk_isHP);
1606  if (includeSeeds_) {
1607  t->Branch("trk_seedIdx", &trk_seedIdx);
1608  }
1609  t->Branch("trk_vtxIdx", &trk_vtxIdx);
1611  t->Branch("trk_simTrkIdx", &trk_simTrkIdx);
1612  t->Branch("trk_simTrkShareFrac", &trk_simTrkShareFrac);
1613  t->Branch("trk_simTrkNChi2", &trk_simTrkNChi2);
1614  t->Branch("trk_bestSimTrkIdx", &trk_bestSimTrkIdx);
1615  t->Branch("trk_bestFromFirstHitSimTrkIdx", &trk_bestFromFirstHitSimTrkIdx);
1616  } else {
1617  t->Branch("trk_isTrue", &trk_isTrue);
1618  }
1619  t->Branch("trk_bestSimTrkShareFrac", &trk_bestSimTrkShareFrac);
1620  t->Branch("trk_bestSimTrkShareFracSimDenom", &trk_bestSimTrkShareFracSimDenom);
1621  t->Branch("trk_bestSimTrkShareFracSimClusterDenom", &trk_bestSimTrkShareFracSimClusterDenom);
1622  t->Branch("trk_bestSimTrkNChi2", &trk_bestSimTrkNChi2);
1623  t->Branch("trk_bestFromFirstHitSimTrkShareFrac", &trk_bestFromFirstHitSimTrkShareFrac);
1624  t->Branch("trk_bestFromFirstHitSimTrkShareFracSimDenom", &trk_bestFromFirstHitSimTrkShareFracSimDenom);
1625  t->Branch("trk_bestFromFirstHitSimTrkShareFracSimClusterDenom", &trk_bestFromFirstHitSimTrkShareFracSimClusterDenom);
1626  t->Branch("trk_bestFromFirstHitSimTrkNChi2", &trk_bestFromFirstHitSimTrkNChi2);
1627  if (includeAllHits_) {
1628  t->Branch("trk_hitIdx", &trk_hitIdx);
1629  t->Branch("trk_hitType", &trk_hitType);
1630  }
1632  t->Branch("tcand_pca_valid", &tcand_pca_valid);
1633  t->Branch("tcand_pca_px", &tcand_pca_px);
1634  t->Branch("tcand_pca_py", &tcand_pca_py);
1635  t->Branch("tcand_pca_pz", &tcand_pca_pz);
1636  t->Branch("tcand_pca_pt", &tcand_pca_pt);
1637  t->Branch("tcand_pca_eta", &tcand_pca_eta);
1638  t->Branch("tcand_pca_phi", &tcand_pca_phi);
1639  t->Branch("tcand_pca_dxy", &tcand_pca_dxy);
1640  t->Branch("tcand_pca_dz", &tcand_pca_dz);
1641  t->Branch("tcand_pca_ptErr", &tcand_pca_ptErr);
1642  t->Branch("tcand_pca_etaErr", &tcand_pca_etaErr);
1643  t->Branch("tcand_pca_lambdaErr", &tcand_pca_lambdaErr);
1644  t->Branch("tcand_pca_phiErr", &tcand_pca_phiErr);
1645  t->Branch("tcand_pca_dxyErr", &tcand_pca_dxyErr);
1646  t->Branch("tcand_pca_dzErr", &tcand_pca_dzErr);
1647  t->Branch("tcand_px", &tcand_px);
1648  t->Branch("tcand_py", &tcand_py);
1649  t->Branch("tcand_pz", &tcand_pz);
1650  t->Branch("tcand_pt", &tcand_pt);
1651  t->Branch("tcand_x", &tcand_x);
1652  t->Branch("tcand_y", &tcand_y);
1653  t->Branch("tcand_z", &tcand_z);
1654  t->Branch("tcand_qbpErr", &tcand_qbpErr);
1655  t->Branch("tcand_lambdaErr", &tcand_lambdaErr);
1656  t->Branch("tcand_phiErr", &tcand_phiErr);
1657  t->Branch("tcand_xtErr", &tcand_xtErr);
1658  t->Branch("tcand_ytErr", &tcand_ytErr);
1659  t->Branch("tcand_q", &tcand_q);
1660  t->Branch("tcand_ndof", &tcand_ndof);
1661  t->Branch("tcand_nValid", &tcand_nValid);
1662  t->Branch("tcand_nPixel", &tcand_nPixel);
1663  t->Branch("tcand_nStrip", &tcand_nStrip);
1664  t->Branch("tcand_nCluster", &tcand_nCluster);
1665  t->Branch("tcand_algo", &tcand_algo);
1666  t->Branch("tcand_stopReason", &tcand_stopReason);
1667  if (includeSeeds_) {
1668  t->Branch("tcand_seedIdx", &tcand_seedIdx);
1669  }
1670  t->Branch("tcand_vtxIdx", &tcand_vtxIdx);
1672  t->Branch("tcand_simTrkIdx", &tcand_simTrkIdx);
1673  t->Branch("tcand_simTrkShareFrac", &tcand_simTrkShareFrac);
1674  t->Branch("tcand_simTrkNChi2", &tcand_simTrkNChi2);
1675  t->Branch("tcand_bestSimTrkIdx", &tcand_bestSimTrkIdx);
1676  t->Branch("tcand_bestFromFirstHitSimTrkIdx", &tcand_bestFromFirstHitSimTrkIdx);
1677  } else {
1678  t->Branch("tcand_isTrue", &tcand_isTrue);
1679  }
1680  t->Branch("tcand_bestSimTrkShareFrac", &tcand_bestSimTrkShareFrac);
1681  t->Branch("tcand_bestSimTrkShareFracSimDenom", &tcand_bestSimTrkShareFracSimDenom);
1682  t->Branch("tcand_bestSimTrkShareFracSimClusterDenom", &tcand_bestSimTrkShareFracSimClusterDenom);
1683  t->Branch("tcand_bestSimTrkNChi2", &tcand_bestSimTrkNChi2);
1684  t->Branch("tcand_bestFromFirstHitSimTrkShareFrac", &tcand_bestFromFirstHitSimTrkShareFrac);
1685  t->Branch("tcand_bestFromFirstHitSimTrkShareFracSimDenom", &tcand_bestFromFirstHitSimTrkShareFracSimDenom);
1686  t->Branch("tcand_bestFromFirstHitSimTrkShareFracSimClusterDenom",
1688  t->Branch("tcand_bestFromFirstHitSimTrkNChi2", &tcand_bestFromFirstHitSimTrkNChi2);
1689  if (includeAllHits_) {
1690  t->Branch("tcand_hitIdx", &tcand_hitIdx);
1691  t->Branch("tcand_hitType", &tcand_hitType);
1692  }
1693  }
1695  //sim tracks
1696  t->Branch("sim_event", &sim_event);
1697  t->Branch("sim_bunchCrossing", &sim_bunchCrossing);
1698  t->Branch("sim_pdgId", &sim_pdgId);
1699  t->Branch("sim_genPdgIds", &sim_genPdgIds);
1700  t->Branch("sim_isFromBHadron", &sim_isFromBHadron);
1701  t->Branch("sim_px", &sim_px);
1702  t->Branch("sim_py", &sim_py);
1703  t->Branch("sim_pz", &sim_pz);
1704  t->Branch("sim_pt", &sim_pt);
1705  t->Branch("sim_eta", &sim_eta);
1706  t->Branch("sim_phi", &sim_phi);
1707  t->Branch("sim_pca_pt", &sim_pca_pt);
1708  t->Branch("sim_pca_eta", &sim_pca_eta);
1709  t->Branch("sim_pca_lambda", &sim_pca_lambda);
1710  t->Branch("sim_pca_cotTheta", &sim_pca_cotTheta);
1711  t->Branch("sim_pca_phi", &sim_pca_phi);
1712  t->Branch("sim_pca_dxy", &sim_pca_dxy);
1713  t->Branch("sim_pca_dz", &sim_pca_dz);
1714  t->Branch("sim_q", &sim_q);
1715  t->Branch("sim_nValid", &sim_nValid);
1716  t->Branch("sim_nPixel", &sim_nPixel);
1717  t->Branch("sim_nStrip", &sim_nStrip);
1718  t->Branch("sim_nLay", &sim_nLay);
1719  t->Branch("sim_nPixelLay", &sim_nPixelLay);
1720  t->Branch("sim_n3DLay", &sim_n3DLay);
1721  t->Branch("sim_nTrackerHits", &sim_nTrackerHits);
1722  t->Branch("sim_nRecoClusters", &sim_nRecoClusters);
1723  t->Branch("sim_trkIdx", &sim_trkIdx);
1724  t->Branch("sim_trkShareFrac", &sim_trkShareFrac);
1725  if (includeSeeds_) {
1726  t->Branch("sim_seedIdx", &sim_seedIdx);
1727  }
1728  t->Branch("sim_parentVtxIdx", &sim_parentVtxIdx);
1729  t->Branch("sim_decayVtxIdx", &sim_decayVtxIdx);
1730  if (includeAllHits_) {
1731  t->Branch("sim_simHitIdx", &sim_simHitIdx);
1732  }
1733  }
1734  if (includeAllHits_) {
1735  //pixels
1736  t->Branch("pix_isBarrel", &pix_isBarrel);
1737  pix_detId.book("pix", t);
1738  t->Branch("pix_trkIdx", &pix_trkIdx);
1739  if (includeOnTrackHitData_) {
1740  t->Branch("pix_onTrk_x", &pix_onTrk_x);
1741  t->Branch("pix_onTrk_y", &pix_onTrk_y);
1742  t->Branch("pix_onTrk_z", &pix_onTrk_z);
1743  t->Branch("pix_onTrk_xx", &pix_onTrk_xx);
1744  t->Branch("pix_onTrk_xy", &pix_onTrk_xy);
1745  t->Branch("pix_onTrk_yy", &pix_onTrk_yy);
1746  t->Branch("pix_onTrk_yz", &pix_onTrk_yz);
1747  t->Branch("pix_onTrk_zz", &pix_onTrk_zz);
1748  t->Branch("pix_onTrk_zx", &pix_onTrk_zx);
1749  }
1751  t->Branch("pix_tcandIdx", &pix_tcandIdx);
1752  if (includeSeeds_) {
1753  t->Branch("pix_seeIdx", &pix_seeIdx);
1754  }
1756  t->Branch("pix_simHitIdx", &pix_simHitIdx);
1757  if (simHitBySignificance_) {
1758  t->Branch("pix_xySignificance", &pix_xySignificance);
1759  }
1760  t->Branch("pix_chargeFraction", &pix_chargeFraction);
1761  t->Branch("pix_simType", &pix_simType);
1762  }
1763  t->Branch("pix_x", &pix_x);
1764  t->Branch("pix_y", &pix_y);
1765  t->Branch("pix_z", &pix_z);
1766  t->Branch("pix_xx", &pix_xx);
1767  t->Branch("pix_xy", &pix_xy);
1768  t->Branch("pix_yy", &pix_yy);
1769  t->Branch("pix_yz", &pix_yz);
1770  t->Branch("pix_zz", &pix_zz);
1771  t->Branch("pix_zx", &pix_zx);
1772  t->Branch("pix_radL", &pix_radL);
1773  t->Branch("pix_bbxi", &pix_bbxi);
1774  t->Branch("pix_clustSizeCol", &pix_clustSizeCol);
1775  t->Branch("pix_clustSizeRow", &pix_clustSizeRow);
1776  t->Branch("pix_usedMask", &pix_usedMask);
1777  //strips
1778  if (includeStripHits_) {
1779  t->Branch("str_isBarrel", &str_isBarrel);
1780  str_detId.book("str", t);
1781  t->Branch("str_trkIdx", &str_trkIdx);
1782  if (includeOnTrackHitData_) {
1783  t->Branch("str_onTrk_x", &str_onTrk_x);
1784  t->Branch("str_onTrk_y", &str_onTrk_y);
1785  t->Branch("str_onTrk_z", &str_onTrk_z);
1786  t->Branch("str_onTrk_xx", &str_onTrk_xx);
1787  t->Branch("str_onTrk_xy", &str_onTrk_xy);
1788  t->Branch("str_onTrk_yy", &str_onTrk_yy);
1789  t->Branch("str_onTrk_yz", &str_onTrk_yz);
1790  t->Branch("str_onTrk_zz", &str_onTrk_zz);
1791  t->Branch("str_onTrk_zx", &str_onTrk_zx);
1792  }
1794  t->Branch("str_tcandIdx", &str_tcandIdx);
1795  if (includeSeeds_) {
1796  t->Branch("str_seeIdx", &str_seeIdx);
1797  }
1799  t->Branch("str_simHitIdx", &str_simHitIdx);
1800  if (simHitBySignificance_) {
1801  t->Branch("str_xySignificance", &str_xySignificance);
1802  }
1803  t->Branch("str_chargeFraction", &str_chargeFraction);
1804  t->Branch("str_simType", &str_simType);
1805  }
1806  t->Branch("str_x", &str_x);
1807  t->Branch("str_y", &str_y);
1808  t->Branch("str_z", &str_z);
1809  t->Branch("str_xx", &str_xx);
1810  t->Branch("str_xy", &str_xy);
1811  t->Branch("str_yy", &str_yy);
1812  t->Branch("str_yz", &str_yz);
1813  t->Branch("str_zz", &str_zz);
1814  t->Branch("str_zx", &str_zx);
1815  t->Branch("str_radL", &str_radL);
1816  t->Branch("str_bbxi", &str_bbxi);
1817  t->Branch("str_chargePerCM", &str_chargePerCM);
1818  t->Branch("str_clustSize", &str_clustSize);
1819  t->Branch("str_usedMask", &str_usedMask);
1820  //matched hits
1821  t->Branch("glu_isBarrel", &glu_isBarrel);
1822  glu_detId.book("glu", t);
1823  t->Branch("glu_monoIdx", &glu_monoIdx);
1824  t->Branch("glu_stereoIdx", &glu_stereoIdx);
1825  if (includeSeeds_) {
1826  t->Branch("glu_seeIdx", &glu_seeIdx);
1827  }
1828  t->Branch("glu_x", &glu_x);
1829  t->Branch("glu_y", &glu_y);
1830  t->Branch("glu_z", &glu_z);
1831  t->Branch("glu_xx", &glu_xx);
1832  t->Branch("glu_xy", &glu_xy);
1833  t->Branch("glu_yy", &glu_yy);
1834  t->Branch("glu_yz", &glu_yz);
1835  t->Branch("glu_zz", &glu_zz);
1836  t->Branch("glu_zx", &glu_zx);
1837  t->Branch("glu_radL", &glu_radL);
1838  t->Branch("glu_bbxi", &glu_bbxi);
1839  t->Branch("glu_chargePerCM", &glu_chargePerCM);
1840  t->Branch("glu_clustSizeMono", &glu_clustSizeMono);
1841  t->Branch("glu_clustSizeStereo", &glu_clustSizeStereo);
1842  t->Branch("glu_usedMaskMono", &glu_usedMaskMono);
1843  t->Branch("glu_usedMaskStereo", &glu_usedMaskStereo);
1844  }
1845  //phase2 OT
1846  if (includePhase2OTHits_) {
1847  t->Branch("ph2_isBarrel", &ph2_isBarrel);
1848  ph2_detId.book("ph2", t);
1849  t->Branch("ph2_trkIdx", &ph2_trkIdx);
1850  if (includeOnTrackHitData_) {
1851  t->Branch("ph2_onTrk_x", &ph2_onTrk_x);
1852  t->Branch("ph2_onTrk_y", &ph2_onTrk_y);
1853  t->Branch("ph2_onTrk_z", &ph2_onTrk_z);
1854  t->Branch("ph2_onTrk_xx", &ph2_onTrk_xx);
1855  t->Branch("ph2_onTrk_xy", &ph2_onTrk_xy);
1856  t->Branch("ph2_onTrk_yy", &ph2_onTrk_yy);
1857  t->Branch("ph2_onTrk_yz", &ph2_onTrk_yz);
1858  t->Branch("ph2_onTrk_zz", &ph2_onTrk_zz);
1859  t->Branch("ph2_onTrk_zx", &ph2_onTrk_zx);
1860  }
1862  t->Branch("ph2_tcandIdx", &ph2_tcandIdx);
1863  if (includeSeeds_) {
1864  t->Branch("ph2_seeIdx", &ph2_seeIdx);
1865  }
1867  t->Branch("ph2_simHitIdx", &ph2_simHitIdx);
1868  if (simHitBySignificance_) {
1869  t->Branch("ph2_xySignificance", &ph2_xySignificance);
1870  }
1871  t->Branch("ph2_simType", &ph2_simType);
1872  }
1873  t->Branch("ph2_x", &ph2_x);
1874  t->Branch("ph2_y", &ph2_y);
1875  t->Branch("ph2_z", &ph2_z);
1876  t->Branch("ph2_xx", &ph2_xx);
1877  t->Branch("ph2_xy", &ph2_xy);
1878  t->Branch("ph2_yy", &ph2_yy);
1879  t->Branch("ph2_yz", &ph2_yz);
1880  t->Branch("ph2_zz", &ph2_zz);
1881  t->Branch("ph2_zx", &ph2_zx);
1882  t->Branch("ph2_radL", &ph2_radL);
1883  t->Branch("ph2_bbxi", &ph2_bbxi);
1884  t->Branch("ph2_usedMask", &ph2_usedMask);
1885  }
1886  //invalid hits
1887  t->Branch("inv_isBarrel", &inv_isBarrel);
1888  if (includeStripHits_)
1889  inv_detId.book("inv", t);
1890  else
1891  inv_detId_phase2.book("inv", t);
1892  t->Branch("inv_type", &inv_type);
1893  //simhits
1895  if (includeStripHits_)
1896  simhit_detId.book("simhit", t);
1897  else
1898  simhit_detId_phase2.book("simhit", t);
1899  t->Branch("simhit_x", &simhit_x);
1900  t->Branch("simhit_y", &simhit_y);
1901  t->Branch("simhit_z", &simhit_z);
1902  if (saveSimHitsP3_) {
1903  t->Branch("simhit_px", &simhit_px);
1904  t->Branch("simhit_py", &simhit_py);
1905  t->Branch("simhit_pz", &simhit_pz);
1906  }
1907  t->Branch("simhit_particle", &simhit_particle);
1908  t->Branch("simhit_process", &simhit_process);
1909  t->Branch("simhit_eloss", &simhit_eloss);
1910  t->Branch("simhit_tof", &simhit_tof);
1911  t->Branch("simhit_simTrkIdx", &simhit_simTrkIdx);
1912  t->Branch("simhit_hitIdx", &simhit_hitIdx);
1913  t->Branch("simhit_hitType", &simhit_hitType);
1914  }
1915  }
1916  //beam spot
1917  t->Branch("bsp_x", &bsp_x, "bsp_x/F");
1918  t->Branch("bsp_y", &bsp_y, "bsp_y/F");
1919  t->Branch("bsp_z", &bsp_z, "bsp_z/F");
1920  t->Branch("bsp_sigmax", &bsp_sigmax, "bsp_sigmax/F");
1921  t->Branch("bsp_sigmay", &bsp_sigmay, "bsp_sigmay/F");
1922  t->Branch("bsp_sigmaz", &bsp_sigmaz, "bsp_sigmaz/F");
1923  if (includeSeeds_) {
1924  //seeds
1925  t->Branch("see_fitok", &see_fitok);
1926  t->Branch("see_px", &see_px);
1927  t->Branch("see_py", &see_py);
1928  t->Branch("see_pz", &see_pz);
1929  t->Branch("see_pt", &see_pt);
1930  t->Branch("see_eta", &see_eta);
1931  t->Branch("see_phi", &see_phi);
1932  t->Branch("see_dxy", &see_dxy);
1933  t->Branch("see_dz", &see_dz);
1934  t->Branch("see_ptErr", &see_ptErr);
1935  t->Branch("see_etaErr", &see_etaErr);
1936  t->Branch("see_phiErr", &see_phiErr);
1937  t->Branch("see_dxyErr", &see_dxyErr);
1938  t->Branch("see_dzErr", &see_dzErr);
1939  t->Branch("see_chi2", &see_chi2);
1940  t->Branch("see_statePt", &see_statePt);
1941  t->Branch("see_stateTrajX", &see_stateTrajX);
1942  t->Branch("see_stateTrajY", &see_stateTrajY);
1943  t->Branch("see_stateTrajPx", &see_stateTrajPx);
1944  t->Branch("see_stateTrajPy", &see_stateTrajPy);
1945  t->Branch("see_stateTrajPz", &see_stateTrajPz);
1946  t->Branch("see_stateTrajGlbX", &see_stateTrajGlbX);
1947  t->Branch("see_stateTrajGlbY", &see_stateTrajGlbY);
1948  t->Branch("see_stateTrajGlbZ", &see_stateTrajGlbZ);
1949  t->Branch("see_stateTrajGlbPx", &see_stateTrajGlbPx);
1950  t->Branch("see_stateTrajGlbPy", &see_stateTrajGlbPy);
1951  t->Branch("see_stateTrajGlbPz", &see_stateTrajGlbPz);
1952  if (addSeedCurvCov_) {
1953  t->Branch("see_stateCurvCov", &see_stateCurvCov);
1954  }
1955  t->Branch("see_q", &see_q);
1956  t->Branch("see_nValid", &see_nValid);
1957  t->Branch("see_nPixel", &see_nPixel);
1958  t->Branch("see_nGlued", &see_nGlued);
1959  t->Branch("see_nStrip", &see_nStrip);
1960  t->Branch("see_nPhase2OT", &see_nPhase2OT);
1961  t->Branch("see_nCluster", &see_nCluster);
1962  t->Branch("see_algo", &see_algo);
1963  t->Branch("see_stopReason", &see_stopReason);
1964  t->Branch("see_nCands", &see_nCands);
1965  t->Branch("see_trkIdx", &see_trkIdx);
1967  t->Branch("see_tcandIdx", &see_tcandIdx);
1969  t->Branch("see_simTrkIdx", &see_simTrkIdx);
1970  t->Branch("see_simTrkShareFrac", &see_simTrkShareFrac);
1971  t->Branch("see_bestSimTrkIdx", &see_bestSimTrkIdx);
1972  t->Branch("see_bestFromFirstHitSimTrkIdx", &see_bestFromFirstHitSimTrkIdx);
1973  } else {
1974  t->Branch("see_isTrue", &see_isTrue);
1975  }
1976  t->Branch("see_bestSimTrkShareFrac", &see_bestSimTrkShareFrac);
1977  t->Branch("see_bestFromFirstHitSimTrkShareFrac", &see_bestFromFirstHitSimTrkShareFrac);
1978  if (includeAllHits_) {
1979  t->Branch("see_hitIdx", &see_hitIdx);
1980  t->Branch("see_hitType", &see_hitType);
1981  }
1982  //seed algo offset
1983  t->Branch("see_offset", &see_offset);
1984  }
1985 
1986  //vertices
1987  t->Branch("vtx_x", &vtx_x);
1988  t->Branch("vtx_y", &vtx_y);
1989  t->Branch("vtx_z", &vtx_z);
1990  t->Branch("vtx_xErr", &vtx_xErr);
1991  t->Branch("vtx_yErr", &vtx_yErr);
1992  t->Branch("vtx_zErr", &vtx_zErr);
1993  t->Branch("vtx_ndof", &vtx_ndof);
1994  t->Branch("vtx_chi2", &vtx_chi2);
1995  t->Branch("vtx_fake", &vtx_fake);
1996  t->Branch("vtx_valid", &vtx_valid);
1997  t->Branch("vtx_trkIdx", &vtx_trkIdx);
1998 
1999  // tracking vertices
2000  t->Branch("simvtx_event", &simvtx_event);
2001  t->Branch("simvtx_bunchCrossing", &simvtx_bunchCrossing);
2002  t->Branch("simvtx_processType", &simvtx_processType);
2003  t->Branch("simvtx_x", &simvtx_x);
2004  t->Branch("simvtx_y", &simvtx_y);
2005  t->Branch("simvtx_z", &simvtx_z);
2006  t->Branch("simvtx_sourceSimIdx", &simvtx_sourceSimIdx);
2007  t->Branch("simvtx_daughterSimIdx", &simvtx_daughterSimIdx);
2008 
2009  t->Branch("simpv_idx", &simpv_idx);
2010 
2011  //t->Branch("" , &);
2012 }
2013 
2015  // do anything here that needs to be done at desctruction time
2016  // (e.g. close files, deallocate resources etc.)
2017 }
2018 
2019 //
2020 // member functions
2021 //
2023  ev_run = 0;
2024  ev_lumi = 0;
2025  ev_event = 0;
2026 
2027  //tracks
2028  trk_px.clear();
2029  trk_py.clear();
2030  trk_pz.clear();
2031  trk_pt.clear();
2032  trk_inner_px.clear();
2033  trk_inner_py.clear();
2034  trk_inner_pz.clear();
2035  trk_inner_pt.clear();
2036  trk_outer_px.clear();
2037  trk_outer_py.clear();
2038  trk_outer_pz.clear();
2039  trk_outer_pt.clear();
2040  trk_eta.clear();
2041  trk_lambda.clear();
2042  trk_cotTheta.clear();
2043  trk_phi.clear();
2044  trk_dxy.clear();
2045  trk_dz.clear();
2046  trk_dxyPV.clear();
2047  trk_dzPV.clear();
2048  trk_dxyClosestPV.clear();
2049  trk_dzClosestPV.clear();
2050  trk_ptErr.clear();
2051  trk_etaErr.clear();
2052  trk_lambdaErr.clear();
2053  trk_phiErr.clear();
2054  trk_dxyErr.clear();
2055  trk_dzErr.clear();
2056  trk_refpoint_x.clear();
2057  trk_refpoint_y.clear();
2058  trk_refpoint_z.clear();
2059  trk_nChi2.clear();
2060  trk_nChi2_1Dmod.clear();
2061  trk_ndof.clear();
2062  for (auto& mva : trk_mvas) {
2063  mva.clear();
2064  }
2065  for (auto& mask : trk_qualityMasks) {
2066  mask.clear();
2067  }
2068  trk_q.clear();
2069  trk_nValid.clear();
2070  trk_nLost.clear();
2071  trk_nInactive.clear();
2072  trk_nPixel.clear();
2073  trk_nStrip.clear();
2074  trk_nOuterLost.clear();
2075  trk_nInnerLost.clear();
2076  trk_nOuterInactive.clear();
2077  trk_nInnerInactive.clear();
2078  trk_nPixelLay.clear();
2079  trk_nStripLay.clear();
2080  trk_n3DLay.clear();
2081  trk_nLostLay.clear();
2082  trk_nCluster.clear();
2083  trk_algo.clear();
2084  trk_originalAlgo.clear();
2085  trk_algoMask.clear();
2086  trk_stopReason.clear();
2087  trk_isHP.clear();
2088  trk_seedIdx.clear();
2089  trk_vtxIdx.clear();
2090  trk_isTrue.clear();
2091  trk_bestSimTrkIdx.clear();
2092  trk_bestSimTrkShareFrac.clear();
2095  trk_bestSimTrkNChi2.clear();
2101  trk_simTrkIdx.clear();
2102  trk_simTrkShareFrac.clear();
2103  trk_simTrkNChi2.clear();
2104  trk_hitIdx.clear();
2105  trk_hitType.clear();
2106  //track candidates
2107  tcand_pca_valid.clear();
2108  tcand_pca_px.clear();
2109  tcand_pca_py.clear();
2110  tcand_pca_pz.clear();
2111  tcand_pca_pt.clear();
2112  tcand_pca_eta.clear();
2113  tcand_pca_phi.clear();
2114  tcand_pca_dxy.clear();
2115  tcand_pca_dz.clear();
2116  tcand_pca_ptErr.clear();
2117  tcand_pca_etaErr.clear();
2118  tcand_pca_lambdaErr.clear();
2119  tcand_pca_phiErr.clear();
2120  tcand_pca_dxyErr.clear();
2121  tcand_pca_dzErr.clear();
2122  tcand_px.clear();
2123  tcand_py.clear();
2124  tcand_pz.clear();
2125  tcand_pt.clear();
2126  tcand_x.clear();
2127  tcand_y.clear();
2128  tcand_z.clear();
2129  tcand_qbpErr.clear();
2130  tcand_lambdaErr.clear();
2131  tcand_phiErr.clear();
2132  tcand_xtErr.clear();
2133  tcand_ytErr.clear();
2134  tcand_ndof.clear();
2135  tcand_q.clear();
2136  tcand_nValid.clear();
2137  tcand_nPixel.clear();
2138  tcand_nStrip.clear();
2139  tcand_nCluster.clear();
2140  tcand_algo.clear();
2141  tcand_stopReason.clear();
2142  tcand_seedIdx.clear();
2143  tcand_vtxIdx.clear();
2144  tcand_isTrue.clear();
2145  tcand_bestSimTrkIdx.clear();
2146  tcand_bestSimTrkShareFrac.clear();
2149  tcand_bestSimTrkNChi2.clear();
2155  tcand_simTrkShareFrac.clear();
2156  tcand_simTrkNChi2.clear();
2157  tcand_simTrkIdx.clear();
2158  tcand_hitIdx.clear();
2159  tcand_hitType.clear();
2160  //sim tracks
2161  sim_event.clear();
2162  sim_bunchCrossing.clear();
2163  sim_pdgId.clear();
2164  sim_genPdgIds.clear();
2165  sim_isFromBHadron.clear();
2166  sim_px.clear();
2167  sim_py.clear();
2168  sim_pz.clear();
2169  sim_pt.clear();
2170  sim_eta.clear();
2171  sim_phi.clear();
2172  sim_pca_pt.clear();
2173  sim_pca_eta.clear();
2174  sim_pca_lambda.clear();
2175  sim_pca_cotTheta.clear();
2176  sim_pca_phi.clear();
2177  sim_pca_dxy.clear();
2178  sim_pca_dz.clear();
2179  sim_q.clear();
2180  sim_nValid.clear();
2181  sim_nPixel.clear();
2182  sim_nStrip.clear();
2183  sim_nLay.clear();
2184  sim_nPixelLay.clear();
2185  sim_n3DLay.clear();
2186  sim_nTrackerHits.clear();
2187  sim_nRecoClusters.clear();
2188  sim_trkIdx.clear();
2189  sim_seedIdx.clear();
2190  sim_trkShareFrac.clear();
2191  sim_parentVtxIdx.clear();
2192  sim_decayVtxIdx.clear();
2193  sim_simHitIdx.clear();
2194  //pixels
2195  pix_isBarrel.clear();
2196  pix_detId.clear();
2197  pix_trkIdx.clear();
2198  pix_onTrk_x.clear();
2199  pix_onTrk_y.clear();
2200  pix_onTrk_z.clear();
2201  pix_onTrk_xx.clear();
2202  pix_onTrk_xy.clear();
2203  pix_onTrk_yy.clear();
2204  pix_onTrk_yz.clear();
2205  pix_onTrk_zz.clear();
2206  pix_onTrk_zx.clear();
2207  pix_tcandIdx.clear();
2208  pix_seeIdx.clear();
2209  pix_simHitIdx.clear();
2210  pix_xySignificance.clear();
2211  pix_chargeFraction.clear();
2212  pix_simType.clear();
2213  pix_x.clear();
2214  pix_y.clear();
2215  pix_z.clear();
2216  pix_xx.clear();
2217  pix_xy.clear();
2218  pix_yy.clear();
2219  pix_yz.clear();
2220  pix_zz.clear();
2221  pix_zx.clear();
2222  pix_radL.clear();
2223  pix_bbxi.clear();
2224  pix_clustSizeCol.clear();
2225  pix_clustSizeRow.clear();
2226  pix_usedMask.clear();
2227  //strips
2228  str_isBarrel.clear();
2229  str_detId.clear();
2230  str_trkIdx.clear();
2231  str_onTrk_x.clear();
2232  str_onTrk_y.clear();
2233  str_onTrk_z.clear();
2234  str_onTrk_xx.clear();
2235  str_onTrk_xy.clear();
2236  str_onTrk_yy.clear();
2237  str_onTrk_yz.clear();
2238  str_onTrk_zz.clear();
2239  str_onTrk_zx.clear();
2240  str_tcandIdx.clear();
2241  str_seeIdx.clear();
2242  str_simHitIdx.clear();
2243  str_xySignificance.clear();
2244  str_chargeFraction.clear();
2245  str_simType.clear();
2246  str_x.clear();
2247  str_y.clear();
2248  str_z.clear();
2249  str_xx.clear();
2250  str_xy.clear();
2251  str_yy.clear();
2252  str_yz.clear();
2253  str_zz.clear();
2254  str_zx.clear();
2255  str_radL.clear();
2256  str_bbxi.clear();
2257  str_chargePerCM.clear();
2258  str_clustSize.clear();
2259  str_usedMask.clear();
2260  //matched hits
2261  glu_isBarrel.clear();
2262  glu_detId.clear();
2263  glu_monoIdx.clear();
2264  glu_stereoIdx.clear();
2265  glu_seeIdx.clear();
2266  glu_x.clear();
2267  glu_y.clear();
2268  glu_z.clear();
2269  glu_xx.clear();
2270  glu_xy.clear();
2271  glu_yy.clear();
2272  glu_yz.clear();
2273  glu_zz.clear();
2274  glu_zx.clear();
2275  glu_radL.clear();
2276  glu_bbxi.clear();
2277  glu_chargePerCM.clear();
2278  glu_clustSizeMono.clear();
2279  glu_clustSizeStereo.clear();
2280  glu_usedMaskMono.clear();
2281  glu_usedMaskStereo.clear();
2282  //phase2 OT
2283  ph2_isBarrel.clear();
2284  ph2_detId.clear();
2285  ph2_trkIdx.clear();
2286  ph2_onTrk_x.clear();
2287  ph2_onTrk_y.clear();
2288  ph2_onTrk_z.clear();
2289  ph2_onTrk_xx.clear();
2290  ph2_onTrk_xy.clear();
2291  ph2_onTrk_yy.clear();
2292  ph2_onTrk_yz.clear();
2293  ph2_onTrk_zz.clear();
2294  ph2_onTrk_zx.clear();
2295  ph2_tcandIdx.clear();
2296  ph2_seeIdx.clear();
2297  ph2_xySignificance.clear();
2298  ph2_simHitIdx.clear();
2299  ph2_simType.clear();
2300  ph2_x.clear();
2301  ph2_y.clear();
2302  ph2_z.clear();
2303  ph2_xx.clear();
2304  ph2_xy.clear();
2305  ph2_yy.clear();
2306  ph2_yz.clear();
2307  ph2_zz.clear();
2308  ph2_zx.clear();
2309  ph2_radL.clear();
2310  ph2_bbxi.clear();
2311  ph2_usedMask.clear();
2312  //invalid hits
2313  inv_isBarrel.clear();
2314  inv_detId.clear();
2315  inv_detId_phase2.clear();
2316  inv_type.clear();
2317  // simhits
2318  simhit_detId.clear();
2319  simhit_detId_phase2.clear();
2320  simhit_x.clear();
2321  simhit_y.clear();
2322  simhit_z.clear();
2323  simhit_px.clear();
2324  simhit_py.clear();
2325  simhit_pz.clear();
2326  simhit_particle.clear();
2327  simhit_process.clear();
2328  simhit_eloss.clear();
2329  simhit_tof.clear();
2330  //simhit_simTrackId.clear();
2331  simhit_simTrkIdx.clear();
2332  simhit_hitIdx.clear();
2333  simhit_hitType.clear();
2334  //beamspot
2335  bsp_x = -9999.;
2336  bsp_y = -9999.;
2337  bsp_z = -9999.;
2338  bsp_sigmax = -9999.;
2339  bsp_sigmay = -9999.;
2340  bsp_sigmaz = -9999.;
2341  //seeds
2342  see_fitok.clear();
2343  see_px.clear();
2344  see_py.clear();
2345  see_pz.clear();
2346  see_pt.clear();
2347  see_eta.clear();
2348  see_phi.clear();
2349  see_dxy.clear();
2350  see_dz.clear();
2351  see_ptErr.clear();
2352  see_etaErr.clear();
2353  see_phiErr.clear();
2354  see_dxyErr.clear();
2355  see_dzErr.clear();
2356  see_chi2.clear();
2357  see_statePt.clear();
2358  see_stateTrajX.clear();
2359  see_stateTrajY.clear();
2360  see_stateTrajPx.clear();
2361  see_stateTrajPy.clear();
2362  see_stateTrajPz.clear();
2363  see_stateTrajGlbX.clear();
2364  see_stateTrajGlbY.clear();
2365  see_stateTrajGlbZ.clear();
2366  see_stateTrajGlbPx.clear();
2367  see_stateTrajGlbPy.clear();
2368  see_stateTrajGlbPz.clear();
2369  see_stateCurvCov.clear();
2370  see_q.clear();
2371  see_nValid.clear();
2372  see_nPixel.clear();
2373  see_nGlued.clear();
2374  see_nStrip.clear();
2375  see_nPhase2OT.clear();
2376  see_nCluster.clear();
2377  see_algo.clear();
2378  see_stopReason.clear();
2379  see_nCands.clear();
2380  see_trkIdx.clear();
2381  see_tcandIdx.clear();
2382  see_isTrue.clear();
2383  see_bestSimTrkIdx.clear();
2384  see_bestSimTrkShareFrac.clear();
2387  see_simTrkIdx.clear();
2388  see_simTrkShareFrac.clear();
2389  see_hitIdx.clear();
2390  see_hitType.clear();
2391  //seed algo offset
2392  see_offset.clear();
2393 
2394  // vertices
2395  vtx_x.clear();
2396  vtx_y.clear();
2397  vtx_z.clear();
2398  vtx_xErr.clear();
2399  vtx_yErr.clear();
2400  vtx_zErr.clear();
2401  vtx_ndof.clear();
2402  vtx_chi2.clear();
2403  vtx_fake.clear();
2404  vtx_valid.clear();
2405  vtx_trkIdx.clear();
2406 
2407  // Tracking vertices
2408  simvtx_event.clear();
2409  simvtx_bunchCrossing.clear();
2410  simvtx_processType.clear();
2411  simvtx_x.clear();
2412  simvtx_y.clear();
2413  simvtx_z.clear();
2414  simvtx_sourceSimIdx.clear();
2415  simvtx_daughterSimIdx.clear();
2416  simpv_idx.clear();
2417 }
2418 
2419 // ------------ method called for each event ------------
2421  using namespace edm;
2422  using namespace reco;
2423  using namespace std;
2424 
2425  const auto& mf = iSetup.getData(mfToken_);
2426  const TrackerTopology& tTopo = iSetup.getData(tTopoToken_);
2427  const TrackerGeometry& tracker = iSetup.getData(tGeomToken_);
2428 
2430  iEvent.getByToken(trackAssociatorToken_, theAssociator);
2431  const reco::TrackToTrackingParticleAssociator& associatorByHits = *theAssociator;
2432 
2433  LogDebug("TrackingNtuple") << "Analyzing new event";
2434 
2435  //initialize tree variables
2436  clearVariables();
2437 
2438  // FIXME: we really need to move to edm::View for reading the
2439  // TrackingParticles... Unfortunately it has non-trivial
2440  // consequences on the associator/association interfaces etc.
2442  const TrackingParticleRefVector* tmpTPptr = nullptr;
2444  edm::Handle<TrackingParticleRefVector> TPCollectionHRefVector;
2445 
2447  iEvent.getByToken(trackingParticleToken_, TPCollectionH);
2448  for (size_t i = 0, size = TPCollectionH->size(); i < size; ++i) {
2449  tmpTP.push_back(TrackingParticleRef(TPCollectionH, i));
2450  }
2451  tmpTPptr = &tmpTP;
2452  } else {
2453  iEvent.getByToken(trackingParticleRefToken_, TPCollectionHRefVector);
2454  tmpTPptr = TPCollectionHRefVector.product();
2455  }
2456  const TrackingParticleRefVector& tpCollection = *tmpTPptr;
2457 
2458  // Fill mapping from Ref::key() to index
2459  TrackingParticleRefKeyToIndex tpKeyToIndex;
2460  for (size_t i = 0; i < tpCollection.size(); ++i) {
2461  tpKeyToIndex[tpCollection[i].key()] = i;
2462  }
2463 
2464  // tracking vertices
2466  iEvent.getByToken(trackingVertexToken_, htv);
2467  const TrackingVertexCollection& tvs = *htv;
2468 
2469  // Fill mapping from Ref::key() to index
2470  TrackingVertexRefVector tvRefs;
2471  TrackingVertexRefKeyToIndex tvKeyToIndex;
2472  for (size_t i = 0; i < tvs.size(); ++i) {
2473  const TrackingVertex& v = tvs[i];
2474  if (!includeOOT_ && v.eventId().bunchCrossing() != 0) // Ignore OOTPU
2475  continue;
2476  tvKeyToIndex[i] = tvRefs.size();
2477  tvRefs.push_back(TrackingVertexRef(htv, i));
2478  }
2479 
2480  //get association maps, etc.
2481  Handle<ClusterTPAssociation> pCluster2TPListH;
2482  iEvent.getByToken(clusterTPMapToken_, pCluster2TPListH);
2483  const ClusterTPAssociation& clusterToTPMap = *pCluster2TPListH;
2485  iEvent.getByToken(simHitTPMapToken_, simHitsTPAssoc);
2486 
2487  // TP -> cluster count
2488  TrackingParticleRefKeyToCount tpKeyToClusterCount;
2489  for (const auto& clusterTP : clusterToTPMap) {
2490  tpKeyToClusterCount[clusterTP.second.key()] += 1;
2491  }
2492 
2493  // SimHit key -> index mapping
2494  SimHitRefKeyToIndex simHitRefKeyToIndex;
2495 
2496  //make a list to link TrackingParticles to its simhits
2497  std::vector<TPHitIndex> tpHitList;
2498 
2499  // Count the number of reco cluster per TP
2500 
2501  std::set<edm::ProductID> hitProductIds;
2502  std::map<edm::ProductID, size_t> seedCollToOffset;
2503 
2504  ev_run = iEvent.id().run();
2505  ev_lumi = iEvent.id().luminosityBlock();
2506  ev_event = iEvent.id().event();
2507 
2508  // Digi->Sim links for pixels and strips
2509  edm::Handle<edm::DetSetVector<PixelDigiSimLink>> pixelDigiSimLinksHandle;
2510  iEvent.getByToken(pixelSimLinkToken_, pixelDigiSimLinksHandle);
2511  const auto& pixelDigiSimLinks = *pixelDigiSimLinksHandle;
2512 
2513  edm::Handle<edm::DetSetVector<StripDigiSimLink>> stripDigiSimLinksHandle;
2514  iEvent.getByToken(stripSimLinkToken_, stripDigiSimLinksHandle);
2515 
2516  // Phase2 OT DigiSimLink
2517  edm::Handle<edm::DetSetVector<PixelDigiSimLink>> siphase2OTSimLinksHandle;
2518  iEvent.getByToken(siphase2OTSimLinksToken_, siphase2OTSimLinksHandle);
2519 
2520  //beamspot
2521  Handle<reco::BeamSpot> recoBeamSpotHandle;
2522  iEvent.getByToken(beamSpotToken_, recoBeamSpotHandle);
2523  BeamSpot const& bs = *recoBeamSpotHandle;
2524  fillBeamSpot(bs);
2525 
2526  //prapare list to link matched hits to collection
2527  vector<pair<int, int>> monoStereoClusterList;
2528  if (includeAllHits_) {
2529  // simhits, only if TPs are saved as well
2531  fillSimHits(tracker, tpKeyToIndex, *simHitsTPAssoc, tTopo, simHitRefKeyToIndex, tpHitList);
2532  }
2533 
2534  //pixel hits
2536  tracker,
2537  clusterToTPMap,
2538  tpKeyToIndex,
2539  *simHitsTPAssoc,
2540  pixelDigiSimLinks,
2541  tTopo,
2542  simHitRefKeyToIndex,
2543  hitProductIds);
2544 
2545  //strip hits
2546  if (includeStripHits_) {
2547  LogDebug("TrackingNtuple") << "foundStripSimLink";
2548  const auto& stripDigiSimLinks = *stripDigiSimLinksHandle;
2550  tracker,
2551  clusterToTPMap,
2552  tpKeyToIndex,
2553  *simHitsTPAssoc,
2554  stripDigiSimLinks,
2555  tTopo,
2556  simHitRefKeyToIndex,
2557  hitProductIds);
2558 
2559  //matched hits
2560  fillStripMatchedHits(iEvent, tracker, tTopo, monoStereoClusterList);
2561  }
2562 
2563  if (includePhase2OTHits_) {
2564  LogDebug("TrackingNtuple") << "foundPhase2OTSimLinks";
2565  const auto& phase2OTSimLinks = *siphase2OTSimLinksHandle;
2567  clusterToTPMap,
2568  tracker,
2569  tpKeyToIndex,
2570  *simHitsTPAssoc,
2571  phase2OTSimLinks,
2572  tTopo,
2573  simHitRefKeyToIndex,
2574  hitProductIds);
2575  }
2576  }
2577 
2578  //seeds
2579  if (includeSeeds_) {
2580  fillSeeds(iEvent,
2581  tpCollection,
2582  tpKeyToIndex,
2583  bs,
2584  tracker,
2585  associatorByHits,
2586  clusterToTPMap,
2587  mf,
2588  tTopo,
2589  monoStereoClusterList,
2590  hitProductIds,
2591  seedCollToOffset);
2592  }
2593 
2594  //tracks
2595  edm::Handle<edm::View<reco::Track>> tracksHandle;
2596  iEvent.getByToken(trackToken_, tracksHandle);
2597  const edm::View<reco::Track>& tracks = *tracksHandle;
2598  // The associator interfaces really need to be fixed...
2600  for (edm::View<Track>::size_type i = 0; i < tracks.size(); ++i) {
2601  trackRefs.push_back(tracks.refAt(i));
2602  }
2603  std::vector<const MVACollection*> mvaColls;
2604  std::vector<const QualityMaskCollection*> qualColls;
2605  if (includeMVA_) {
2608 
2609  for (const auto& tokenTpl : mvaQualityCollectionTokens_) {
2610  iEvent.getByToken(std::get<0>(tokenTpl), hmva);
2611  iEvent.getByToken(std::get<1>(tokenTpl), hqual);
2612 
2613  mvaColls.push_back(hmva.product());
2614  qualColls.push_back(hqual.product());
2615  if (mvaColls.back()->size() != tracks.size()) {
2616  throw cms::Exception("Configuration")
2617  << "Inconsistency in track collection and MVA sizes. Track collection has " << tracks.size()
2618  << " tracks, whereas the MVA " << (mvaColls.size() - 1) << " has " << mvaColls.back()->size()
2619  << " entries. Double-check your configuration.";
2620  }
2621  if (qualColls.back()->size() != tracks.size()) {
2622  throw cms::Exception("Configuration")
2623  << "Inconsistency in track collection and quality mask sizes. Track collection has " << tracks.size()
2624  << " tracks, whereas the quality mask " << (qualColls.size() - 1) << " has " << qualColls.back()->size()
2625  << " entries. Double-check your configuration.";
2626  }
2627  }
2628  }
2629 
2631  iEvent.getByToken(vertexToken_, vertices);
2632 
2633  fillTracks(trackRefs,
2634  tracker,
2635  tpCollection,
2636  tpKeyToIndex,
2637  tpKeyToClusterCount,
2638  mf,
2639  bs,
2640  *vertices,
2641  associatorByHits,
2642  clusterToTPMap,
2643  tTopo,
2644  hitProductIds,
2645  seedCollToOffset,
2646  mvaColls,
2647  qualColls);
2648 
2650  //candidates
2651  for (auto const& token : candidateTokens_) {
2652  auto const tCandsHandle = iEvent.getHandle(token);
2653 
2656  TString label = labels.module;
2657  label.ReplaceAll("TrackCandidates", "");
2658  label.ReplaceAll("muonSeeded", "muonSeededStep");
2659  int algo = reco::TrackBase::algoByName(label.Data());
2660 
2661  fillCandidates(tCandsHandle,
2662  algo,
2663  tpCollection,
2664  tpKeyToIndex,
2665  tpKeyToClusterCount,
2666  mf,
2667  bs,
2668  *vertices,
2669  associatorByHits,
2670  clusterToTPMap,
2671  tracker,
2672  tTopo,
2673  hitProductIds,
2674  seedCollToOffset);
2675  }
2676  }
2677 
2678  //tracking particles
2679  //sort association maps with simHits
2680  std::sort(tpHitList.begin(), tpHitList.end(), tpHitIndexListLessSort);
2682  iEvent, iSetup, trackRefs, bs, tpCollection, tvKeyToIndex, associatorByHits, tpHitList, tpKeyToClusterCount);
2683 
2684  // vertices
2685  fillVertices(*vertices, trackRefs);
2686 
2687  // tracking vertices
2688  fillTrackingVertices(tvRefs, tpKeyToIndex);
2689 
2690  t->Fill();
2691 }
2692 
2694  bsp_x = bs.x0();
2695  bsp_y = bs.y0();
2696  bsp_z = bs.x0();
2697  bsp_sigmax = bs.BeamWidthX();
2698  bsp_sigmay = bs.BeamWidthY();
2699  bsp_sigmaz = bs.sigmaZ();
2700 }
2701 
2702 namespace {
2703  template <typename SimLink>
2704  struct GetCluster;
2705  template <>
2706  struct GetCluster<PixelDigiSimLink> {
2707  static const SiPixelCluster& call(const OmniClusterRef& cluster) { return cluster.pixelCluster(); }
2708  };
2709  template <>
2710  struct GetCluster<StripDigiSimLink> {
2711  static const SiStripCluster& call(const OmniClusterRef& cluster) { return cluster.stripCluster(); }
2712  };
2713 } // namespace
2714 
2715 template <typename SimLink>
2717  const OmniClusterRef& cluster,
2718  DetId hitId,
2719  int clusterKey,
2720  const TrackingRecHit& hit,
2721  const ClusterTPAssociation& clusterToTPMap,
2722  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
2725  const SimHitRefKeyToIndex& simHitRefKeyToIndex,
2726  HitType hitType) {
2727  SimHitData ret;
2728 
2729  std::map<unsigned int, double> simTrackIdToChargeFraction;
2730  if (hitType == HitType::Phase2OT)
2731  simTrackIdToChargeFraction = chargeFraction(cluster.phase2OTCluster(), hitId, digiSimLinks);
2732  else
2733  simTrackIdToChargeFraction = chargeFraction(GetCluster<SimLink>::call(cluster), hitId, digiSimLinks);
2734 
2735  float h_x = 0, h_y = 0;
2736  float h_xx = 0, h_xy = 0, h_yy = 0;
2737  if (simHitBySignificance_) {
2738  h_x = hit.localPosition().x();
2739  h_y = hit.localPosition().y();
2740  h_xx = hit.localPositionError().xx();
2741  h_xy = hit.localPositionError().xy();
2742  h_yy = hit.localPositionError().yy();
2743  }
2744 
2745  ret.type = HitSimType::Noise;
2746  auto range = clusterToTPMap.equal_range(cluster);
2747  if (range.first != range.second) {
2748  for (auto ip = range.first; ip != range.second; ++ip) {
2749  const TrackingParticleRef& trackingParticle = ip->second;
2750 
2751  // Find out if the cluster is from signal/ITPU/OOTPU
2752  const auto event = trackingParticle->eventId().event();
2753  const auto bx = trackingParticle->eventId().bunchCrossing();
2755  if (bx == 0) {
2756  type = (event == 0 ? HitSimType::Signal : HitSimType::ITPileup);
2757  } else
2759  ret.type = static_cast<HitSimType>(std::min(static_cast<int>(ret.type), static_cast<int>(type)));
2760 
2761  // Limit to only input TrackingParticles (usually signal+ITPU)
2762  auto tpIndex = tpKeyToIndex.find(trackingParticle.key());
2763  if (tpIndex == tpKeyToIndex.end())
2764  continue;
2765 
2766  //now get the corresponding sim hit
2767  std::pair<TrackingParticleRef, TrackPSimHitRef> simHitTPpairWithDummyTP(trackingParticle, TrackPSimHitRef());
2768  //SimHit is dummy: for simHitTPAssociationListGreater sorting only the TP is needed
2769  auto range = std::equal_range(simHitsTPAssoc.begin(),
2770  simHitsTPAssoc.end(),
2771  simHitTPpairWithDummyTP,
2773  bool foundSimHit = false;
2774  bool foundElectron = false;
2775  int foundNonElectrons = 0;
2776  for (auto ip = range.first; ip != range.second; ++ip) {
2777  TrackPSimHitRef TPhit = ip->second;
2778  DetId dId = DetId(TPhit->detUnitId());
2779  if (dId.rawId() == hitId.rawId()) {
2780  // skip electron SimHits for non-electron TPs also here
2781  if (std::abs(TPhit->particleType()) == 11 && std::abs(trackingParticle->pdgId()) != 11) {
2782  continue; //electrons found
2783  } else {
2784  foundNonElectrons++;
2785  }
2786  }
2787  }
2788 
2789  float minSignificance = 1e12;
2790  if (simHitBySignificance_) { //save the best matching hit
2791 
2792  int simHitKey = -1;
2793  edm::ProductID simHitID;
2794  for (auto ip = range.first; ip != range.second; ++ip) {
2795  TrackPSimHitRef TPhit = ip->second;
2796  DetId dId = DetId(TPhit->detUnitId());
2797  if (dId.rawId() == hitId.rawId()) {
2798  // skip electron SimHits for non-electron TPs also here
2799  if (std::abs(TPhit->particleType()) == 11 && std::abs(trackingParticle->pdgId()) != 11) {
2800  foundElectron = true;
2801  if (!keepEleSimHits_)
2802  continue;
2803  }
2804 
2805  float sx = TPhit->localPosition().x();
2806  float sy = TPhit->localPosition().y();
2807  float dx = sx - h_x;
2808  float dy = sy - h_y;
2809  float sig = (dx * dx * h_yy - 2 * dx * dy * h_xy + dy * dy * h_xx) / (h_xx * h_yy - h_xy * h_xy);
2810 
2811  if (sig < minSignificance) {
2812  minSignificance = sig;
2813  foundSimHit = true;
2814  simHitKey = TPhit.key();
2815  simHitID = TPhit.id();
2816  }
2817  }
2818  } //loop over matching hits
2819 
2820  auto simHitIndex = simHitRefKeyToIndex.at(std::make_pair(simHitKey, simHitID));
2821  ret.matchingSimHit.push_back(simHitIndex);
2822 
2823  double chargeFraction = 0.;
2824  for (const SimTrack& simtrk : trackingParticle->g4Tracks()) {
2825  auto found = simTrackIdToChargeFraction.find(simtrk.trackId());
2826  if (found != simTrackIdToChargeFraction.end()) {
2827  chargeFraction += found->second;
2828  }
2829  }
2830  ret.xySignificance.push_back(minSignificance);
2831  ret.chargeFraction.push_back(chargeFraction);
2832 
2833  // only for debug prints
2834  ret.bunchCrossing.push_back(bx);
2835  ret.event.push_back(event);
2836 
2837  simhit_hitIdx[simHitIndex].push_back(clusterKey);
2838  simhit_hitType[simHitIndex].push_back(static_cast<int>(hitType));
2839 
2840  } else { //save all matching hits
2841  for (auto ip = range.first; ip != range.second; ++ip) {
2842  TrackPSimHitRef TPhit = ip->second;
2843  DetId dId = DetId(TPhit->detUnitId());
2844  if (dId.rawId() == hitId.rawId()) {
2845  // skip electron SimHits for non-electron TPs also here
2846  if (std::abs(TPhit->particleType()) == 11 && std::abs(trackingParticle->pdgId()) != 11) {
2847  foundElectron = true;
2848  if (!keepEleSimHits_)
2849  continue;
2850  if (foundNonElectrons > 0)
2851  continue; //prioritize: skip electrons if non-electrons are present
2852  }
2853 
2854  foundSimHit = true;
2855  auto simHitKey = TPhit.key();
2856  auto simHitID = TPhit.id();
2857 
2858  auto simHitIndex = simHitRefKeyToIndex.at(std::make_pair(simHitKey, simHitID));
2859  ret.matchingSimHit.push_back(simHitIndex);
2860 
2861  double chargeFraction = 0.;
2862  for (const SimTrack& simtrk : trackingParticle->g4Tracks()) {
2863  auto found = simTrackIdToChargeFraction.find(simtrk.trackId());
2864  if (found != simTrackIdToChargeFraction.end()) {
2865  chargeFraction += found->second;
2866  }
2867  }
2868  ret.xySignificance.push_back(minSignificance);
2869  ret.chargeFraction.push_back(chargeFraction);
2870 
2871  // only for debug prints
2872  ret.bunchCrossing.push_back(bx);
2873  ret.event.push_back(event);
2874 
2875  simhit_hitIdx[simHitIndex].push_back(clusterKey);
2876  simhit_hitType[simHitIndex].push_back(static_cast<int>(hitType));
2877  }
2878  }
2879  } //if/else simHitBySignificance_
2880  if (!foundSimHit) {
2881  // In case we didn't find a simhit because of filtered-out
2882  // electron SimHit, just ignore the missing SimHit.
2883  if (foundElectron && !keepEleSimHits_)
2884  continue;
2885 
2886  auto ex = cms::Exception("LogicError")
2887  << "Did not find SimHit for reco hit DetId " << hitId.rawId() << " for TP " << trackingParticle.key()
2888  << " bx:event " << bx << ":" << event << " PDGid " << trackingParticle->pdgId() << " q "
2889  << trackingParticle->charge() << " p4 " << trackingParticle->p4() << " nG4 "
2890  << trackingParticle->g4Tracks().size() << ".\nFound SimHits from detectors ";
2891  for (auto ip = range.first; ip != range.second; ++ip) {
2892  TrackPSimHitRef TPhit = ip->second;
2893  DetId dId = DetId(TPhit->detUnitId());
2894  ex << dId.rawId() << " ";
2895  }
2896  if (trackingParticle->eventId().event() != 0) {
2897  ex << "\nSince this is a TrackingParticle from pileup, check that you're running the pileup mixing in "
2898  "playback mode.";
2899  }
2900  throw ex;
2901  }
2902  }
2903  }
2904 
2905  return ret;
2906 }
2907 
2909  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
2911  const TrackerTopology& tTopo,
2912  SimHitRefKeyToIndex& simHitRefKeyToIndex,
2913  std::vector<TPHitIndex>& tpHitList) {
2914  for (const auto& assoc : simHitsTPAssoc) {
2915  auto tpKey = assoc.first.key();
2916 
2917  // SimHitTPAssociationList can contain more TrackingParticles than
2918  // what are given to this EDAnalyzer, so we can filter those out here.
2919  auto found = tpKeyToIndex.find(tpKey);
2920  if (found == tpKeyToIndex.end())
2921  continue;
2922  const auto tpIndex = found->second;
2923 
2924  // skip non-tracker simhits (mostly muons)
2925  const auto& simhit = *(assoc.second);
2926  auto detId = DetId(simhit.detUnitId());
2927  if (detId.det() != DetId::Tracker)
2928  continue;
2929 
2930  // Skip electron SimHits for non-electron TrackingParticles to
2931  // filter out delta rays. The delta ray hits just confuse. If we
2932  // need them later, let's add them as a separate "collection" of
2933  // hits of a TP
2934  const TrackingParticle& tp = *(assoc.first);
2935  if (!keepEleSimHits_ && std::abs(simhit.particleType()) == 11 && std::abs(tp.pdgId()) != 11)
2936  continue;
2937 
2938  auto simHitKey = std::make_pair(assoc.second.key(), assoc.second.id());
2939 
2940  if (simHitRefKeyToIndex.find(simHitKey) != simHitRefKeyToIndex.end()) {
2941  for (const auto& assoc2 : simHitsTPAssoc) {
2942  if (std::make_pair(assoc2.second.key(), assoc2.second.id()) == simHitKey) {
2943 #ifdef EDM_ML_DEBUG
2944  auto range1 = std::equal_range(simHitsTPAssoc.begin(),
2945  simHitsTPAssoc.end(),
2946  std::make_pair(assoc.first, TrackPSimHitRef()),
2948  auto range2 = std::equal_range(simHitsTPAssoc.begin(),
2949  simHitsTPAssoc.end(),
2950  std::make_pair(assoc2.first, TrackPSimHitRef()),
2952 
2953  LogTrace("TrackingNtuple") << "Earlier TP " << assoc2.first.key() << " SimTrack Ids";
2954  for (const auto& simTrack : assoc2.first->g4Tracks()) {
2955  edm::LogPrint("TrackingNtuple") << " SimTrack " << simTrack.trackId() << " BX:event "
2956  << simTrack.eventId().bunchCrossing() << ":" << simTrack.eventId().event();
2957  }
2958  for (auto iHit = range2.first; iHit != range2.second; ++iHit) {
2959  LogTrace("TrackingNtuple") << " SimHit " << iHit->second.key() << " " << iHit->second.id() << " tof "
2960  << iHit->second->tof() << " trackId " << iHit->second->trackId() << " BX:event "
2961  << iHit->second->eventId().bunchCrossing() << ":"
2962  << iHit->second->eventId().event();
2963  }
2964  LogTrace("TrackingNtuple") << "Current TP " << assoc.first.key() << " SimTrack Ids";
2965  for (const auto& simTrack : assoc.first->g4Tracks()) {
2966  edm::LogPrint("TrackingNtuple") << " SimTrack " << simTrack.trackId() << " BX:event "
2967  << simTrack.eventId().bunchCrossing() << ":" << simTrack.eventId().event();
2968  }
2969  for (auto iHit = range1.first; iHit != range1.second; ++iHit) {
2970  LogTrace("TrackingNtuple") << " SimHit " << iHit->second.key() << " " << iHit->second.id() << " tof "
2971  << iHit->second->tof() << " trackId " << iHit->second->trackId() << " BX:event "
2972  << iHit->second->eventId().bunchCrossing() << ":"
2973  << iHit->second->eventId().event();
2974  }
2975 #endif
2976 
2977  throw cms::Exception("LogicError")
2978  << "Got second time the SimHit " << simHitKey.first << " of " << simHitKey.second
2979  << ", first time with TrackingParticle " << assoc2.first.key() << ", now with " << tpKey;
2980  }
2981  }
2982  throw cms::Exception("LogicError") << "Got second time the SimHit " << simHitKey.first << " of "
2983  << simHitKey.second << ", now with TrackingParticle " << tpKey
2984  << ", but I didn't find the first occurrance!";
2985  }
2986 
2987  auto det = tracker.idToDetUnit(detId);
2988  if (!det)
2989  throw cms::Exception("LogicError") << "Did not find a det unit for DetId " << simhit.detUnitId()
2990  << " from tracker geometry";
2991 
2992  const auto pos = det->surface().toGlobal(simhit.localPosition());
2993  const float tof = simhit.timeOfFlight();
2994 
2995  const auto simHitIndex = simhit_x.size();
2996  simHitRefKeyToIndex[simHitKey] = simHitIndex;
2997 
2998  if (includeStripHits_)
2999  simhit_detId.push_back(tracker, tTopo, detId);
3000  else
3001  simhit_detId_phase2.push_back(tracker, tTopo, detId);
3002  simhit_x.push_back(pos.x());
3003  simhit_y.push_back(pos.y());
3004  simhit_z.push_back(pos.z());
3005  if (saveSimHitsP3_) {
3006  const auto mom = det->surface().toGlobal(simhit.momentumAtEntry());
3007  simhit_px.push_back(mom.x());
3008  simhit_py.push_back(mom.y());
3009  simhit_pz.push_back(mom.z());
3010  }
3011  simhit_particle.push_back(simhit.particleType());
3012  simhit_process.push_back(simhit.processType());
3013  simhit_eloss.push_back(simhit.energyLoss());
3014  simhit_tof.push_back(tof);
3015  //simhit_simTrackId.push_back(simhit.trackId());
3016 
3017  simhit_simTrkIdx.push_back(tpIndex);
3018 
3019  simhit_hitIdx.emplace_back(); // filled in matchCluster
3020  simhit_hitType.emplace_back(); // filled in matchCluster
3021 
3022  tpHitList.emplace_back(tpKey, simHitIndex, tof, simhit.detUnitId());
3023  }
3024 }
3025 
3027  const TrackerGeometry& tracker,
3028  const ClusterTPAssociation& clusterToTPMap,
3029  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
3031  const edm::DetSetVector<PixelDigiSimLink>& digiSimLink,
3032  const TrackerTopology& tTopo,
3033  const SimHitRefKeyToIndex& simHitRefKeyToIndex,
3034  std::set<edm::ProductID>& hitProductIds) {
3035  std::vector<std::pair<uint64_t, PixelMaskContainer const*>> pixelMasks;
3036  pixelMasks.reserve(pixelUseMaskTokens_.size());
3037  for (const auto& itoken : pixelUseMaskTokens_) {
3039  iEvent.getByToken(itoken.second, aH);
3040  pixelMasks.emplace_back(1 << itoken.first, aH.product());
3041  }
3042  auto pixUsedMask = [&pixelMasks](size_t key) {
3043  uint64_t mask = 0;
3044  for (auto const& m : pixelMasks) {
3045  if (m.second->mask(key))
3046  mask |= m.first;
3047  }
3048  return mask;
3049  };
3050 
3052  iEvent.getByToken(pixelRecHitToken_, pixelHits);
3053  for (auto it = pixelHits->begin(); it != pixelHits->end(); it++) {
3054  const DetId hitId = it->detId();
3055  for (auto hit = it->begin(); hit != it->end(); hit++) {
3056  hitProductIds.insert(hit->cluster().id());
3057 
3058  const int key = hit->cluster().key();
3059  const int lay = tTopo.layer(hitId);
3060 
3061  pix_isBarrel.push_back(hitId.subdetId() == 1);
3062  pix_detId.push_back(tracker, tTopo, hitId);
3063  pix_trkIdx.emplace_back(); // filled in fillTracks
3064  pix_onTrk_x.emplace_back();
3065  pix_onTrk_y.emplace_back();
3066  pix_onTrk_z.emplace_back();
3067  pix_onTrk_xx.emplace_back();
3068  pix_onTrk_xy.emplace_back();
3069  pix_onTrk_yy.emplace_back();
3070  pix_onTrk_yz.emplace_back();
3071  pix_onTrk_zz.emplace_back();
3072  pix_onTrk_zx.emplace_back();
3073  pix_tcandIdx.emplace_back(); // filled in fillCandidates
3074  pix_seeIdx.emplace_back(); // filled in fillSeeds
3075  pix_x.push_back(hit->globalPosition().x());
3076  pix_y.push_back(hit->globalPosition().y());
3077  pix_z.push_back(hit->globalPosition().z());
3078  pix_xx.push_back(hit->globalPositionError().cxx());
3079  pix_xy.push_back(hit->globalPositionError().cyx());
3080  pix_yy.push_back(hit->globalPositionError().cyy());
3081  pix_yz.push_back(hit->globalPositionError().czy());
3082  pix_zz.push_back(hit->globalPositionError().czz());
3083  pix_zx.push_back(hit->globalPositionError().czx());
3084  pix_radL.push_back(hit->surface()->mediumProperties().radLen());
3085  pix_bbxi.push_back(hit->surface()->mediumProperties().xi());
3086  pix_clustSizeCol.push_back(hit->cluster()->sizeY());
3087  pix_clustSizeRow.push_back(hit->cluster()->sizeX());
3088  pix_usedMask.push_back(pixUsedMask(hit->firstClusterRef().key()));
3089 
3090  LogTrace("TrackingNtuple") << "pixHit cluster=" << key << " subdId=" << hitId.subdetId() << " lay=" << lay
3091  << " rawId=" << hitId.rawId() << " pos =" << hit->globalPosition();
3093  SimHitData simHitData = matchCluster(hit->firstClusterRef(),
3094  hitId,
3095  key,
3096  *hit,
3097  clusterToTPMap,
3098  tpKeyToIndex,
3099  simHitsTPAssoc,
3100  digiSimLink,
3101  simHitRefKeyToIndex,
3102  HitType::Pixel);
3103  pix_simHitIdx.push_back(simHitData.matchingSimHit);
3104  pix_simType.push_back(static_cast<int>(simHitData.type));
3105  pix_xySignificance.push_back(simHitData.xySignificance);
3106  pix_chargeFraction.push_back(simHitData.chargeFraction);
3107  LogTrace("TrackingNtuple") << " nMatchingSimHit=" << simHitData.matchingSimHit.size();
3108  if (!simHitData.matchingSimHit.empty()) {
3109  const auto simHitIdx = simHitData.matchingSimHit[0];
3110  LogTrace("TrackingNtuple") << " firstMatchingSimHit=" << simHitIdx << " simHitPos="
3111  << GlobalPoint(simhit_x[simHitIdx], simhit_y[simHitIdx], simhit_z[simHitIdx])
3112  << " energyLoss=" << simhit_eloss[simHitIdx]
3113  << " particleType=" << simhit_particle[simHitIdx]
3114  << " processType=" << simhit_process[simHitIdx]
3115  << " bunchCrossing=" << simHitData.bunchCrossing[0]
3116  << " event=" << simHitData.event[0];
3117  }
3118  }
3119  }
3120  }
3121 }
3122 
3124  const TrackerGeometry& tracker,
3125  const ClusterTPAssociation& clusterToTPMap,
3126  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
3128  const edm::DetSetVector<StripDigiSimLink>& digiSimLink,
3129  const TrackerTopology& tTopo,
3130  const SimHitRefKeyToIndex& simHitRefKeyToIndex,
3131  std::set<edm::ProductID>& hitProductIds) {
3132  std::vector<std::pair<uint64_t, StripMaskContainer const*>> stripMasks;
3133  stripMasks.reserve(stripUseMaskTokens_.size());
3134  for (const auto& itoken : stripUseMaskTokens_) {
3136  iEvent.getByToken(itoken.second, aH);
3137  stripMasks.emplace_back(1 << itoken.first, aH.product());
3138  }
3139  auto strUsedMask = [&stripMasks](size_t key) {
3140  uint64_t mask = 0;
3141  for (auto const& m : stripMasks) {
3142  if (m.second->mask(key))
3143  mask |= m.first;
3144  }
3145  return mask;
3146  };
3147 
3148  //index strip hit branches by cluster index
3150  iEvent.getByToken(stripRphiRecHitToken_, rphiHits);
3152  iEvent.getByToken(stripStereoRecHitToken_, stereoHits);
3153  int totalStripHits = rphiHits->dataSize() + stereoHits->dataSize();
3154  str_isBarrel.resize(totalStripHits);
3155  str_detId.resize(totalStripHits);
3156  str_trkIdx.resize(totalStripHits); // filled in fillTracks
3157  str_onTrk_x.resize(totalStripHits);
3158  str_onTrk_y.resize(totalStripHits);
3159  str_onTrk_z.resize(totalStripHits);
3160  str_onTrk_xx.resize(totalStripHits);
3161  str_onTrk_xy.resize(totalStripHits);
3162  str_onTrk_yy.resize(totalStripHits);
3163  str_onTrk_yz.resize(totalStripHits);
3164  str_onTrk_zz.resize(totalStripHits);
3165  str_onTrk_zx.resize(totalStripHits);
3166  str_tcandIdx.resize(totalStripHits); // filled in fillCandidates
3167  str_seeIdx.resize(totalStripHits); // filled in fillSeeds
3168  str_simHitIdx.resize(totalStripHits);
3169  str_simType.resize(totalStripHits);
3170  str_chargeFraction.resize(totalStripHits);
3171  str_x.resize(totalStripHits);
3172  str_y.resize(totalStripHits);
3173  str_z.resize(totalStripHits);
3174  str_xx.resize(totalStripHits);
3175  str_xy.resize(totalStripHits);
3176  str_yy.resize(totalStripHits);
3177  str_yz.resize(totalStripHits);
3178  str_zz.resize(totalStripHits);
3179  str_zx.resize(totalStripHits);
3180  str_xySignificance.resize(totalStripHits);
3181  str_chargeFraction.resize(totalStripHits);
3182  str_radL.resize(totalStripHits);
3183  str_bbxi.resize(totalStripHits);
3184  str_chargePerCM.resize(totalStripHits);
3185  str_clustSize.resize(totalStripHits);
3186  str_usedMask.resize(totalStripHits);
3187 
3188  auto fill = [&](const SiStripRecHit2DCollection& hits, const char* name) {
3189  for (const auto& detset : hits) {
3190  const DetId hitId = detset.detId();
3191  for (const auto& hit : detset) {
3192  hitProductIds.insert(hit.cluster().id());
3193 
3194  const int key = hit.cluster().key();
3195  const int lay = tTopo.layer(hitId);
3197  str_detId.set(key, tracker, tTopo, hitId);
3198  str_x[key] = hit.globalPosition().x();
3199  str_y[key] = hit.globalPosition().y();
3200  str_z[key] = hit.globalPosition().z();
3201  str_xx[key] = hit.globalPositionError().cxx();
3202  str_xy[key] = hit.globalPositionError().cyx();
3203  str_yy[key] = hit.globalPositionError().cyy();
3204  str_yz[key] = hit.globalPositionError().czy();
3205  str_zz[key] = hit.globalPositionError().czz();
3206  str_zx[key] = hit.globalPositionError().czx();
3207  str_radL[key] = hit.surface()->mediumProperties().radLen();
3208  str_bbxi[key] = hit.surface()->mediumProperties().xi();
3209  str_chargePerCM[key] = siStripClusterTools::chargePerCM(hitId, hit.firstClusterRef().stripCluster());
3210  str_clustSize[key] = hit.cluster()->amplitudes().size();
3211  str_usedMask[key] = strUsedMask(key);
3212  LogTrace("TrackingNtuple") << name << " cluster=" << key << " subdId=" << hitId.subdetId() << " lay=" << lay
3213  << " rawId=" << hitId.rawId() << " pos =" << hit.globalPosition();
3214 
3216  SimHitData simHitData = matchCluster(hit.firstClusterRef(),
3217  hitId,
3218  key,
3219  hit,
3220  clusterToTPMap,
3221  tpKeyToIndex,
3222  simHitsTPAssoc,
3223  digiSimLink,
3224  simHitRefKeyToIndex,
3225  HitType::Strip);
3226  str_simHitIdx[key] = simHitData.matchingSimHit;
3227  str_simType[key] = static_cast<int>(simHitData.type);
3228  str_xySignificance[key] = simHitData.xySignificance;
3229  str_chargeFraction[key] = simHitData.chargeFraction;
3230  LogTrace("TrackingNtuple") << " nMatchingSimHit=" << simHitData.matchingSimHit.size();
3231  if (!simHitData.matchingSimHit.empty()) {
3232  const auto simHitIdx = simHitData.matchingSimHit[0];
3233  LogTrace("TrackingNtuple") << " firstMatchingSimHit=" << simHitIdx << " simHitPos="
3234  << GlobalPoint(simhit_x[simHitIdx], simhit_y[simHitIdx], simhit_z[simHitIdx])
3235  << " simHitPos="
3236  << GlobalPoint(simhit_x[simHitIdx], simhit_y[simHitIdx], simhit_z[simHitIdx])
3237  << " energyLoss=" << simhit_eloss[simHitIdx]
3238  << " particleType=" << simhit_particle[simHitIdx]
3239  << " processType=" << simhit_process[simHitIdx]
3240  << " bunchCrossing=" << simHitData.bunchCrossing[0]
3241  << " event=" << simHitData.event[0];
3242  }
3243  }
3244  }
3245  }
3246  };
3247 
3248  fill(*rphiHits, "stripRPhiHit");
3249  fill(*stereoHits, "stripStereoHit");
3250 }
3251 
3253  const TrackerGeometry& tracker,
3254  const TrackerTopology& tTopo,
3255  const std::vector<std::pair<uint64_t, StripMaskContainer const*>>& stripMasks,
3256  std::vector<std::pair<int, int>>& monoStereoClusterList) {
3257  auto strUsedMask = [&stripMasks](size_t key) {
3258  uint64_t mask = 0;
3259  for (auto const& m : stripMasks) {
3260  if (m.second->mask(key))
3261  mask |= m.first;
3262  }
3263  return mask;
3264  };
3265 
3266  const auto hitId = hit.geographicalId();
3267  const int lay = tTopo.layer(hitId);
3268  monoStereoClusterList.emplace_back(hit.monoHit().cluster().key(), hit.stereoHit().cluster().key());
3269  glu_isBarrel.push_back((hitId.subdetId() == StripSubdetector::TIB || hitId.subdetId() == StripSubdetector::TOB));
3270  glu_detId.push_back(tracker, tTopo, hitId);
3271  glu_monoIdx.push_back(hit.monoHit().cluster().key());
3272  glu_stereoIdx.push_back(hit.stereoHit().cluster().key());
3273  glu_seeIdx.emplace_back(); // filled in fillSeeds
3274  glu_x.push_back(hit.globalPosition().x());
3275  glu_y.push_back(hit.globalPosition().y());
3276  glu_z.push_back(hit.globalPosition().z());
3277  glu_xx.push_back(hit.globalPositionError().cxx());
3278  glu_xy.push_back(hit.globalPositionError().cyx());
3279  glu_yy.push_back(hit.globalPositionError().cyy());
3280  glu_yz.push_back(hit.globalPositionError().czy());
3281  glu_zz.push_back(hit.globalPositionError().czz());
3282  glu_zx.push_back(hit.globalPositionError().czx());
3283  glu_radL.push_back(hit.surface()->mediumProperties().radLen());
3284  glu_bbxi.push_back(hit.surface()->mediumProperties().xi());
3285  glu_chargePerCM.push_back(siStripClusterTools::chargePerCM(hitId, hit.firstClusterRef().stripCluster()));
3286  glu_clustSizeMono.push_back(hit.monoHit().cluster()->amplitudes().size());
3287  glu_clustSizeStereo.push_back(hit.stereoHit().cluster()->amplitudes().size());
3288  glu_usedMaskMono.push_back(strUsedMask(hit.monoHit().cluster().key()));
3289  glu_usedMaskStereo.push_back(strUsedMask(hit.stereoHit().cluster().key()));
3290  LogTrace("TrackingNtuple") << "stripMatchedHit"
3291  << " cluster0=" << hit.stereoHit().cluster().key()
3292  << " cluster1=" << hit.monoHit().cluster().key() << " subdId=" << hitId.subdetId()
3293  << " lay=" << lay << " rawId=" << hitId.rawId() << " pos =" << hit.globalPosition();
3294  return glu_isBarrel.size() - 1;
3295 }
3296 
3298  const TrackerGeometry& tracker,
3299  const TrackerTopology& tTopo,
3300  std::vector<std::pair<int, int>>& monoStereoClusterList) {
3301  std::vector<std::pair<uint64_t, StripMaskContainer const*>> stripMasks;
3302  stripMasks.reserve(stripUseMaskTokens_.size());
3303  for (const auto& itoken : stripUseMaskTokens_) {
3305  iEvent.getByToken(itoken.second, aH);
3306  stripMasks.emplace_back(1 << itoken.first, aH.product());
3307  }
3308 
3310  iEvent.getByToken(stripMatchedRecHitToken_, matchedHits);
3311  for (auto it = matchedHits->begin(); it != matchedHits->end(); it++) {
3312  for (auto hit = it->begin(); hit != it->end(); hit++) {
3313  addStripMatchedHit(*hit, tracker, tTopo, stripMasks, monoStereoClusterList);
3314  }
3315  }
3316 }
3317 
3319  const ClusterTPAssociation& clusterToTPMap,
3320  const TrackerGeometry& tracker,
3321  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
3323  const edm::DetSetVector<PixelDigiSimLink>& digiSimLink,
3324  const TrackerTopology& tTopo,
3325  const SimHitRefKeyToIndex& simHitRefKeyToIndex,
3326  std::set<edm::ProductID>& hitProductIds) {
3327  std::vector<std::pair<uint64_t, Phase2OTMaskContainer const*>> phase2OTMasks;
3328  phase2OTMasks.reserve(ph2OTUseMaskTokens_.size());
3329  for (const auto& itoken : ph2OTUseMaskTokens_) {
3331  iEvent.getByToken(itoken.second, aH);
3332  phase2OTMasks.emplace_back(1 << itoken.first, aH.product());
3333  }
3334  auto ph2OTUsedMask = [&phase2OTMasks](size_t key) {
3335  uint64_t mask = 0;
3336  for (auto const& m : phase2OTMasks) {
3337  if (m.second->mask(key))
3338  mask |= m.first;
3339  }
3340  return mask;
3341  };
3342 
3344  iEvent.getByToken(phase2OTRecHitToken_, phase2OTHits);
3345  for (auto it = phase2OTHits->begin(); it != phase2OTHits->end(); it++) {
3346  const DetId hitId = it->detId();
3347  for (auto hit = it->begin(); hit != it->end(); hit++) {
3348  hitProductIds.insert(hit->cluster().id());
3349 
3350  const int key = hit->cluster().key();
3351  const int lay = tTopo.layer(hitId);
3352 
3353  ph2_isBarrel.push_back(hitId.subdetId() == 1);
3354  ph2_detId.push_back(tracker, tTopo, hitId);
3355  ph2_trkIdx.emplace_back(); // filled in fillTracks
3356  ph2_onTrk_x.emplace_back();
3357  ph2_onTrk_y.emplace_back();
3358  ph2_onTrk_z.emplace_back();
3359  ph2_onTrk_xx.emplace_back();
3360  ph2_onTrk_xy.emplace_back();
3361  ph2_onTrk_yy.emplace_back();
3362  ph2_onTrk_yz.emplace_back();
3363  ph2_onTrk_zz.emplace_back();
3364  ph2_onTrk_zx.emplace_back();
3365  ph2_tcandIdx.emplace_back(); // filled in fillCandidates
3366  ph2_seeIdx.emplace_back(); // filled in fillSeeds
3367  ph2_x.push_back(hit->globalPosition().x());
3368  ph2_y.push_back(hit->globalPosition().y());
3369  ph2_z.push_back(hit->globalPosition().z());
3370  ph2_xx.push_back(hit->globalPositionError().cxx());
3371  ph2_xy.push_back(hit->globalPositionError().cyx());
3372  ph2_yy.push_back(hit->globalPositionError().cyy());
3373  ph2_yz.push_back(hit->globalPositionError().czy());
3374  ph2_zz.push_back(hit->globalPositionError().czz());
3375  ph2_zx.push_back(hit->globalPositionError().czx());
3376  ph2_radL.push_back(hit->surface()->mediumProperties().radLen());
3377  ph2_bbxi.push_back(hit->surface()->mediumProperties().xi());
3378  ph2_usedMask.push_back(ph2OTUsedMask(hit->firstClusterRef().key()));
3379 
3380  LogTrace("TrackingNtuple") << "phase2 OT cluster=" << key << " subdId=" << hitId.subdetId() << " lay=" << lay
3381  << " rawId=" << hitId.rawId() << " pos =" << hit->globalPosition();
3382 
3384  SimHitData simHitData = matchCluster(hit->firstClusterRef(),
3385  hitId,
3386  key,
3387  *hit,
3388  clusterToTPMap,
3389  tpKeyToIndex,
3390  simHitsTPAssoc,
3391  digiSimLink,
3392  simHitRefKeyToIndex,
3394  ph2_xySignificance.push_back(simHitData.xySignificance);
3395  ph2_simHitIdx.push_back(simHitData.matchingSimHit);
3396  ph2_simType.push_back(static_cast<int>(simHitData.type));
3397  LogTrace("TrackingNtuple") << " nMatchingSimHit=" << simHitData.matchingSimHit.size();
3398  if (!simHitData.matchingSimHit.empty()) {
3399  const auto simHitIdx = simHitData.matchingSimHit[0];
3400  LogTrace("TrackingNtuple") << " firstMatchingSimHit=" << simHitIdx << " simHitPos="
3401  << GlobalPoint(simhit_x[simHitIdx], simhit_y[simHitIdx], simhit_z[simHitIdx])
3402  << " energyLoss=" << simhit_eloss[simHitIdx]
3403  << " particleType=" << simhit_particle[simHitIdx]
3404  << " processType=" << simhit_process[simHitIdx]
3405  << " bunchCrossing=" << simHitData.bunchCrossing[0]
3406  << " event=" << simHitData.event[0];
3407  }
3408  }
3409  }
3410  }
3411 }
3412 
3414  const TrackingParticleRefVector& tpCollection,
3415  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
3416  const reco::BeamSpot& bs,
3417  const TrackerGeometry& tracker,
3418  const reco::TrackToTrackingParticleAssociator& associatorByHits,
3419  const ClusterTPAssociation& clusterToTPMap,
3420  const MagneticField& theMF,
3421  const TrackerTopology& tTopo,
3422  std::vector<std::pair<int, int>>& monoStereoClusterList,
3423  const std::set<edm::ProductID>& hitProductIds,
3424  std::map<edm::ProductID, size_t>& seedCollToOffset) {
3425  TSCBLBuilderNoMaterial tscblBuilder;
3426  for (size_t iColl = 0; iColl < seedTokens_.size(); ++iColl) {
3427  const auto& seedToken = seedTokens_[iColl];
3428 
3429  edm::Handle<edm::View<reco::Track>> seedTracksHandle;
3430  iEvent.getByToken(seedToken, seedTracksHandle);
3431  const auto& seedTracks = *seedTracksHandle;
3432 
3433  if (seedTracks.empty())
3434  continue;
3435 
3437  labelsForToken(seedToken, labels);
3438 
3439  const auto& seedStopInfoToken = seedStopInfoTokens_[iColl];
3440  edm::Handle<std::vector<SeedStopInfo>> seedStopInfoHandle;
3441  iEvent.getByToken(seedStopInfoToken, seedStopInfoHandle);
3442  const auto& seedStopInfos = *seedStopInfoHandle;
3443  if (seedTracks.size() != seedStopInfos.size()) {
3445  labelsForToken(seedStopInfoToken, labels2);
3446 
3447  throw cms::Exception("LogicError") << "Got " << seedTracks.size() << " seeds, but " << seedStopInfos.size()
3448  << " seed stopping infos for collections " << labels.module << ", "
3449  << labels2.module;
3450  }
3451 
3452  std::vector<std::pair<uint64_t, StripMaskContainer const*>> stripMasks;
3453  stripMasks.reserve(stripUseMaskTokens_.size());
3454  for (const auto& itoken : stripUseMaskTokens_) {
3456  iEvent.getByToken(itoken.second, aH);
3457  stripMasks.emplace_back(1 << itoken.first, aH.product());
3458  }
3459 
3460  // The associator interfaces really need to be fixed...
3461  edm::RefToBaseVector<reco::Track> seedTrackRefs;
3462  for (edm::View<reco::Track>::size_type i = 0; i < seedTracks.size(); ++i) {
3463  seedTrackRefs.push_back(seedTracks.refAt(i));
3464  }
3465  reco::RecoToSimCollection recSimColl = associatorByHits.associateRecoToSim(seedTrackRefs, tpCollection);
3466  reco::SimToRecoCollection simRecColl = associatorByHits.associateSimToReco(seedTrackRefs, tpCollection);
3467 
3468  TString label = labels.module;
3469  //format label to match algoName
3470  label.ReplaceAll("seedTracks", "");
3471  label.ReplaceAll("Seeds", "");
3472  label.ReplaceAll("muonSeeded", "muonSeededStep");
3473  //for HLT seeds
3474  label.ReplaceAll("FromPixelTracks", "");
3475  label.ReplaceAll("PFLowPixel", "");
3476  label.ReplaceAll("hltDoubletRecovery", "pixelPairStep"); //random choice
3477  int algo = reco::TrackBase::algoByName(label.Data());
3478 
3479  edm::ProductID id = seedTracks[0].seedRef().id();
3480  const auto offset = see_fitok.size();
3481  auto inserted = seedCollToOffset.emplace(id, offset);
3482  if (!inserted.second)
3483  throw cms::Exception("Configuration")
3484  << "Trying to add seeds with ProductID " << id << " for a second time from collection " << labels.module
3485  << ", seed algo " << label << ". Typically this is caused by a configuration problem.";
3486  see_offset.push_back(offset);
3487 
3488  LogTrace("TrackingNtuple") << "NEW SEED LABEL: " << label << " size: " << seedTracks.size() << " algo=" << algo
3489  << " ProductID " << id;
3490 
3491  for (size_t iSeed = 0; iSeed < seedTrackRefs.size(); ++iSeed) {
3492  const auto& seedTrackRef = seedTrackRefs[iSeed];
3493  const auto& seedTrack = *seedTrackRef;
3494  const auto& seedRef = seedTrack.seedRef();
3495  const auto& seed = *seedRef;
3496 
3497  const auto seedStopInfo = seedStopInfos[iSeed];
3498 
3499  if (seedRef.id() != id)
3500  throw cms::Exception("LogicError")
3501  << "All tracks in 'TracksFromSeeds' collection should point to seeds in the same collection. Now the "
3502  "element 0 had ProductID "
3503  << id << " while the element " << seedTrackRef.key() << " had " << seedTrackRef.id()
3504  << ". The source collection is " << labels.module << ".";
3505 
3506  std::vector<int> tpIdx;
3507  std::vector<float> sharedFraction;
3508  auto foundTPs = recSimColl.find(seedTrackRef);
3509  if (foundTPs != recSimColl.end()) {
3510  for (const auto& tpQuality : foundTPs->val) {
3511  tpIdx.push_back(tpKeyToIndex.at(tpQuality.first.key()));
3512  sharedFraction.push_back(tpQuality.second);
3513  }
3514  }
3515 
3516  // Search for a best-matching TrackingParticle for a seed
3517  const int nHits = seedTrack.numberOfValidHits();
3519  seedTrack.recHitsBegin(),
3520  seedTrack.recHitsEnd()); // TODO: this function is called 3 times per track, try to reduce
3521  const int nClusters = clusters.size();
3522  const auto bestKeyCount = findBestMatchingTrackingParticle(seedTrack.recHits(), clusterToTPMap, tpKeyToIndex);
3523  const float bestShareFrac =
3524  nClusters > 0 ? static_cast<float>(bestKeyCount.countClusters) / static_cast<float>(nClusters) : 0;
3525  // Another way starting from the first hit of the seed
3526  const auto bestFirstHitKeyCount =
3527  findMatchingTrackingParticleFromFirstHit(seedTrack.recHits(), clusterToTPMap, tpKeyToIndex);
3528  const float bestFirstHitShareFrac =
3529  nClusters > 0 ? static_cast<float>(bestFirstHitKeyCount.countClusters) / static_cast<float>(nClusters) : 0;
3530 
3531  const bool seedFitOk = !trackFromSeedFitFailed(seedTrack);
3532  const int charge = seedTrack.charge();
3533  const float pt = seedFitOk ? seedTrack.pt() : 0;
3534  const float eta = seedFitOk ? seedTrack.eta() : 0;
3535  const float phi = seedFitOk ? seedTrack.phi() : 0;
3536 
3537  const auto seedIndex = see_fitok.size();
3538 
3539  see_fitok.push_back(seedFitOk);
3540 
3541  see_px.push_back(seedFitOk ? seedTrack.px() : 0);
3542  see_py.push_back(seedFitOk ? seedTrack.py() : 0);
3543  see_pz.push_back(seedFitOk ? seedTrack.pz() : 0);
3544  see_pt.push_back(pt);
3545  see_eta.push_back(eta);
3546  see_phi.push_back(phi);
3547  see_q.push_back(charge);
3548  see_nValid.push_back(nHits);
3549 
3550  see_dxy.push_back(seedFitOk ? seedTrack.dxy(bs.position()) : 0);
3551  see_dz.push_back(seedFitOk ? seedTrack.dz(bs.position()) : 0);
3552  see_ptErr.push_back(seedFitOk ? seedTrack.ptError() : 0);
3553  see_etaErr.push_back(seedFitOk ? seedTrack.etaError() : 0);
3554  see_phiErr.push_back(seedFitOk ? seedTrack.phiError() : 0);
3555  see_dxyErr.push_back(seedFitOk ? seedTrack.dxyError() : 0);
3556  see_dzErr.push_back(seedFitOk ? seedTrack.dzError() : 0);
3557  see_algo.push_back(algo);
3558  see_stopReason.push_back(seedStopInfo.stopReasonUC());
3559  see_nCands.push_back(seedStopInfo.candidatesPerSeed());
3560 
3561  const auto& state = seedTrack.seedRef()->startingState();
3562  const auto& pos = state.parameters().position();
3563  const auto& mom = state.parameters().momentum();
3564  see_statePt.push_back(state.pt());
3565  see_stateTrajX.push_back(pos.x());
3566  see_stateTrajY.push_back(pos.y());
3567  see_stateTrajPx.push_back(mom.x());
3568  see_stateTrajPy.push_back(mom.y());
3569  see_stateTrajPz.push_back(mom.z());
3570 
3572  const TrackingRecHit* lastRecHit = &*(seed.recHits().end() - 1);
3574  trajectoryStateTransform::transientState(seed.startingState(), lastRecHit->surface(), &theMF);
3575  auto const& stateGlobal = tsos.globalParameters();
3576  see_stateTrajGlbX.push_back(stateGlobal.position().x());
3577  see_stateTrajGlbY.push_back(stateGlobal.position().y());
3578  see_stateTrajGlbZ.push_back(stateGlobal.position().z());
3579  see_stateTrajGlbPx.push_back(stateGlobal.momentum().x());
3580  see_stateTrajGlbPy.push_back(stateGlobal.momentum().y());
3581  see_stateTrajGlbPz.push_back(stateGlobal.momentum().z());
3582  if (addSeedCurvCov_) {
3583  auto const& stateCcov = tsos.curvilinearError().matrix();
3584  std::vector<float> cov(15);
3585  auto covP = cov.begin();
3586  for (auto const val : stateCcov)
3587  *(covP++) = val; //row-major
3588  see_stateCurvCov.push_back(std::move(cov));
3589  }
3590 
3591  see_trkIdx.push_back(-1); // to be set correctly in fillTracks
3592  see_tcandIdx.push_back(-1); // to be set correctly in fillCandidates
3594  see_simTrkIdx.push_back(tpIdx);
3595  see_simTrkShareFrac.push_back(sharedFraction);
3596  see_bestSimTrkIdx.push_back(bestKeyCount.key >= 0 ? tpKeyToIndex.at(bestKeyCount.key) : -1);
3598  bestFirstHitKeyCount.key >= 0 ? tpKeyToIndex.at(bestFirstHitKeyCount.key) : -1);
3599  } else {
3600  see_isTrue.push_back(!tpIdx.empty());
3601  }
3602  see_bestSimTrkShareFrac.push_back(bestShareFrac);
3603  see_bestFromFirstHitSimTrkShareFrac.push_back(bestFirstHitShareFrac);
3604 
3606  /*
3607  const TrackingRecHit* lastRecHit = &*(seed.recHits().second-1);
3608  TrajectoryStateOnSurface state = trajectoryStateTransform::transientState( itSeed->startingState(), lastRecHit->surface(), &theMF);
3609  float pt = state.globalParameters().momentum().perp();
3610  float eta = state.globalParameters().momentum().eta();
3611  float phi = state.globalParameters().momentum().phi();
3612  see_px .push_back( state.globalParameters().momentum().x() );
3613  see_py .push_back( state.globalParameters().momentum().y() );
3614  see_pz .push_back( state.globalParameters().momentum().z() );
3615  */
3616 
3617  std::vector<int> hitIdx;
3618  std::vector<int> hitType;
3619 
3620  for (auto const& hit : seed.recHits()) {
3621  int subid = hit.geographicalId().subdetId();
3622  if (subid == (int)PixelSubdetector::PixelBarrel || subid == (int)PixelSubdetector::PixelEndcap) {
3623  const BaseTrackerRecHit* bhit = dynamic_cast<const BaseTrackerRecHit*>(&hit);
3624  const auto& clusterRef = bhit->firstClusterRef();
3625  const auto clusterKey = clusterRef.cluster_pixel().key();
3626  if (includeAllHits_) {
3627  checkProductID(hitProductIds, clusterRef.id(), "seed");
3628  pix_seeIdx[clusterKey].push_back(seedIndex);
3629  }
3630  hitIdx.push_back(clusterKey);
3631  hitType.push_back(static_cast<int>(HitType::Pixel));
3632  } else if (subid == (int)StripSubdetector::TOB || subid == (int)StripSubdetector::TID ||
3633  subid == (int)StripSubdetector::TIB || subid == (int)StripSubdetector::TEC) {
3635  const SiStripMatchedRecHit2D* matchedHit = dynamic_cast<const SiStripMatchedRecHit2D*>(&hit);
3636  if (includeAllHits_) {
3637  checkProductID(hitProductIds, matchedHit->monoClusterRef().id(), "seed");
3638  checkProductID(hitProductIds, matchedHit->stereoClusterRef().id(), "seed");
3639  }
3640  int monoIdx = matchedHit->monoClusterRef().key();
3641  int stereoIdx = matchedHit->stereoClusterRef().key();
3642 
3643  std::vector<std::pair<int, int>>::iterator pos =
3644  find(monoStereoClusterList.begin(), monoStereoClusterList.end(), std::make_pair(monoIdx, stereoIdx));
3645  size_t gluedIndex = -1;
3646  if (pos != monoStereoClusterList.end()) {
3647  gluedIndex = std::distance(monoStereoClusterList.begin(), pos);
3648  } else {
3649  // We can encounter glued hits not in the input
3650  // SiStripMatchedRecHit2DCollection, e.g. via muon
3651  // outside-in seeds (or anything taking hits from
3652  // MeasurementTrackerEvent). So let's add them here.
3653  gluedIndex = addStripMatchedHit(*matchedHit, tracker, tTopo, stripMasks, monoStereoClusterList);
3654  }
3655 
3656  if (includeAllHits_)
3657  glu_seeIdx[gluedIndex].push_back(seedIndex);
3658  hitIdx.push_back(gluedIndex);
3659  hitType.push_back(static_cast<int>(HitType::Glued));
3660  } else {
3661  const BaseTrackerRecHit* bhit = dynamic_cast<const BaseTrackerRecHit*>(&hit);
3662  const auto& clusterRef = bhit->firstClusterRef();
3663  unsigned int clusterKey;
3664  if (clusterRef.isPhase2()) {
3665  clusterKey = clusterRef.cluster_phase2OT().key();
3666  } else {
3667  clusterKey = clusterRef.cluster_strip().key();
3668  }
3669 
3670  if (includeAllHits_) {
3671  checkProductID(hitProductIds, clusterRef.id(), "seed");
3672  if (clusterRef.isPhase2()) {
3673  ph2_seeIdx[clusterKey].push_back(seedIndex);
3674  } else {
3675  str_seeIdx[clusterKey].push_back(seedIndex);
3676  }
3677  }
3678 
3679  hitIdx.push_back(clusterKey);
3680  if (clusterRef.isPhase2()) {
3681  hitType.push_back(static_cast<int>(HitType::Phase2OT));
3682  } else {
3683  hitType.push_back(static_cast<int>(HitType::Strip));
3684  }
3685  }
3686  } else {
3687  LogTrace("TrackingNtuple") << " not pixel and not Strip detector";
3688  }
3689  }
3690  see_hitIdx.push_back(hitIdx);
3691  see_hitType.push_back(hitType);
3692  see_nPixel.push_back(std::count(hitType.begin(), hitType.end(), static_cast<int>(HitType::Pixel)));
3693  see_nGlued.push_back(std::count(hitType.begin(), hitType.end(), static_cast<int>(HitType::Glued)));
3694  see_nStrip.push_back(std::count(hitType.begin(), hitType.end(), static_cast<int>(HitType::Strip)));
3695  see_nPhase2OT.push_back(std::count(hitType.begin(), hitType.end(), static_cast<int>(HitType::Phase2OT)));
3696  see_nCluster.push_back(nClusters);
3697  //the part below is not strictly needed
3698  float chi2 = -1;
3699  if (nHits == 2) {
3700  auto const recHit0 = seed.recHits().begin();
3701  auto const recHit1 = seed.recHits().begin() + 1;
3702  std::vector<GlobalPoint> gp(2);
3703  std::vector<GlobalError> ge(2);
3704  gp[0] = recHit0->globalPosition();
3705  ge[0] = recHit0->globalPositionError();
3706  gp[1] = recHit1->globalPosition();
3707  ge[1] = recHit1->globalPositionError();
3708  LogTrace("TrackingNtuple")
3709  << "seed " << seedTrackRef.key() << " pt=" << pt << " eta=" << eta << " phi=" << phi << " q=" << charge
3710  << " - PAIR - ids: " << recHit0->geographicalId().rawId() << " " << recHit1->geographicalId().rawId()
3711  << " hitpos: " << gp[0] << " " << gp[1] << " trans0: "
3712  << (recHit0->transientHits().size() > 1 ? recHit0->transientHits()[0]->globalPosition()
3713  : GlobalPoint(0, 0, 0))
3714  << " "
3715  << (recHit0->transientHits().size() > 1 ? recHit0->transientHits()[1]->globalPosition()
3716  : GlobalPoint(0, 0, 0))
3717  << " trans1: "
3718  << (recHit1->transientHits().size() > 1 ? recHit1->transientHits()[0]->globalPosition()
3719  : GlobalPoint(0, 0, 0))
3720  << " "
3721  << (recHit1->transientHits().size() > 1 ? recHit1->transientHits()[1]->globalPosition()
3722  : GlobalPoint(0, 0, 0))
3723  << " eta,phi: " << gp[0].eta() << "," << gp[0].phi();
3724  } else if (nHits == 3) {
3725  auto const recHit0 = seed.recHits().begin();
3726  auto const recHit1 = seed.recHits().begin() + 1;
3727  auto const recHit2 = seed.recHits().begin() + 2;
3729  declareDynArray(GlobalError, 4, ge);
3730  declareDynArray(bool, 4, bl);
3731  gp[0] = recHit0->globalPosition();
3732  ge[0] = recHit0->globalPositionError();
3733  int subid0 = recHit0->geographicalId().subdetId();
3734  bl[0] = (subid0 == StripSubdetector::TIB || subid0 == StripSubdetector::TOB ||
3735  subid0 == (int)PixelSubdetector::PixelBarrel);
3736  gp[1] = recHit1->globalPosition();
3737  ge[1] = recHit1->globalPositionError();
3738  int subid1 = recHit1->geographicalId().subdetId();
3739  bl[1] = (subid1 == StripSubdetector::TIB || subid1 == StripSubdetector::TOB ||
3740  subid1 == (int)PixelSubdetector::PixelBarrel);
3741  gp[2] = recHit2->globalPosition();
3742  ge[2] = recHit2->globalPositionError();
3743  int subid2 = recHit2->geographicalId().subdetId();
3744  bl[2] = (subid2 == StripSubdetector::TIB || subid2 == StripSubdetector::TOB ||
3745  subid2 == (int)PixelSubdetector::PixelBarrel);
3746  RZLine rzLine(gp, ge, bl);
3747  float seed_chi2 = rzLine.chi2();
3748  //float seed_pt = state.globalParameters().momentum().perp();
3749  float seed_pt = pt;
3750  LogTrace("TrackingNtuple")
3751  << "seed " << seedTrackRef.key() << " pt=" << pt << " eta=" << eta << " phi=" << phi << " q=" << charge
3752  << " - TRIPLET - ids: " << recHit0->geographicalId().rawId() << " " << recHit1->geographicalId().rawId()
3753  << " " << recHit2->geographicalId().rawId() << " hitpos: " << gp[0] << " " << gp[1] << " " << gp[2]
3754  << " trans0: "
3755  << (recHit0->transientHits().size() > 1 ? recHit0->transientHits()[0]->globalPosition()
3756  : GlobalPoint(0, 0, 0))
3757  << " "
3758  << (recHit0->transientHits().size() > 1 ? recHit0->transientHits()[1]->globalPosition()
3759  : GlobalPoint(0, 0, 0))
3760  << " trans1: "
3761  << (recHit1->transientHits().size() > 1 ? recHit1->transientHits()[0]->globalPosition()
3762  : GlobalPoint(0, 0, 0))
3763  << " "
3764  << (recHit1->transientHits().size() > 1 ? recHit1->transientHits()[1]->globalPosition()
3765  : GlobalPoint(0, 0, 0))
3766  << " trans2: "
3767  << (recHit2->transientHits().size() > 1 ? recHit2->transientHits()[0]->globalPosition()
3768  : GlobalPoint(0, 0, 0))
3769  << " "
3770  << (recHit2->transientHits().size() > 1 ? recHit2->transientHits()[1]->globalPosition()
3771  : GlobalPoint(0, 0, 0))
3772  << " local: "
3773  << recHit2->localPosition()
3774  //<< " tsos pos, mom: " << state.globalPosition()<<" "<<state.globalMomentum()
3775  << " eta,phi: " << gp[0].eta() << "," << gp[0].phi() << " pt,chi2: " << seed_pt << "," << seed_chi2;
3776  chi2 = seed_chi2;
3777  }
3778  see_chi2.push_back(chi2);
3779  }
3780 
3781  fillTrackingParticlesForSeeds(tpCollection, simRecColl, tpKeyToIndex, offset);
3782  }
3783 }
3784 
3786  const TrackerGeometry& tracker,
3787  const TrackingParticleRefVector& tpCollection,
3788  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
3789  const TrackingParticleRefKeyToCount& tpKeyToClusterCount,
3790  const MagneticField& mf,
3791  const reco::BeamSpot& bs,
3793  const reco::TrackToTrackingParticleAssociator& associatorByHits,
3794  const ClusterTPAssociation& clusterToTPMap,
3795  const TrackerTopology& tTopo,
3796  const std::set<edm::ProductID>& hitProductIds,
3797  const std::map<edm::ProductID, size_t>& seedCollToOffset,
3798  const std::vector<const MVACollection*>& mvaColls,
3799  const std::vector<const QualityMaskCollection*>& qualColls) {
3800  reco::RecoToSimCollection recSimColl = associatorByHits.associateRecoToSim(tracks, tpCollection);
3803  LogTrace("TrackingNtuple") << "NEW TRACK LABEL: " << labels.module;
3804 
3805  auto pvPosition = vertices[0].position();
3806 
3807  for (size_t iTrack = 0; iTrack < tracks.size(); ++iTrack) {
3808  const auto& itTrack = tracks[iTrack];
3809  int charge = itTrack->charge();
3810  float pt = itTrack->pt();
3811  float eta = itTrack->eta();
3812  const double lambda = itTrack->lambda();
3813  float chi2 = itTrack->normalizedChi2();
3814  float ndof = itTrack->ndof();
3815  float phi = itTrack->phi();
3816  int nHits = itTrack->numberOfValidHits();
3817  const reco::HitPattern& hp = itTrack->hitPattern();
3818 
3819  const auto& tkParam = itTrack->parameters();
3820  auto tkCov = itTrack->covariance();
3821  tkCov.Invert();
3822 
3823  // Standard track-TP matching
3824  int nSimHits = 0;
3825  bool isSimMatched = false;
3826  std::vector<int> tpIdx;
3827  std::vector<float> sharedFraction;
3828  std::vector<float> tpChi2;
3829  auto foundTPs = recSimColl.find(itTrack);
3830  if (foundTPs != recSimColl.end()) {
3831  if (!foundTPs->val.empty()) {
3832  nSimHits = foundTPs->val[0].first->numberOfTrackerHits();
3833  isSimMatched = true;
3834  }
3835  for (const auto& tpQuality : foundTPs->val) {
3836  tpIdx.push_back(tpKeyToIndex.at(tpQuality.first.key()));
3837  sharedFraction.push_back(tpQuality.second);
3838  tpChi2.push_back(track_associator::trackAssociationChi2(tkParam, tkCov, *(tpCollection[tpIdx.back()]), mf, bs));
3839  }
3840  }
3841 
3842  // Search for a best-matching TrackingParticle for a track
3844  itTrack->recHitsBegin(),
3845  itTrack->recHitsEnd()); // TODO: this function is called 3 times per track, try to reduce
3846  const int nClusters = clusters.size();
3847 
3848  const auto bestKeyCount = findBestMatchingTrackingParticle(itTrack->recHits(), clusterToTPMap, tpKeyToIndex);
3849  const float bestShareFrac = static_cast<float>(bestKeyCount.countClusters) / static_cast<float>(nClusters);
3850  float bestShareFracSimDenom = 0;
3851  float bestShareFracSimClusterDenom = 0;
3852  float bestChi2 = -1;
3853  if (bestKeyCount.key >= 0) {
3854  bestShareFracSimDenom =
3855  static_cast<float>(bestKeyCount.countClusters) /
3856  static_cast<float>(tpCollection[tpKeyToIndex.at(bestKeyCount.key)]->numberOfTrackerHits());
3857  bestShareFracSimClusterDenom =
3858  static_cast<float>(bestKeyCount.countClusters) / static_cast<float>(tpKeyToClusterCount.at(bestKeyCount.key));
3860  tkParam, tkCov, *(tpCollection[tpKeyToIndex.at(bestKeyCount.key)]), mf, bs);
3861  }
3862  // Another way starting from the first hit of the track
3863  const auto bestFirstHitKeyCount =
3864  findMatchingTrackingParticleFromFirstHit(itTrack->recHits(), clusterToTPMap, tpKeyToIndex);
3865  const float bestFirstHitShareFrac =
3866  static_cast<float>(bestFirstHitKeyCount.countClusters) / static_cast<float>(nClusters);
3867  float bestFirstHitShareFracSimDenom = 0;
3868  float bestFirstHitShareFracSimClusterDenom = 0;
3869  float bestFirstHitChi2 = -1;
3870  if (bestFirstHitKeyCount.key >= 0) {
3871  bestFirstHitShareFracSimDenom =
3872  static_cast<float>(bestFirstHitKeyCount.countClusters) /
3873  static_cast<float>(tpCollection[tpKeyToIndex.at(bestFirstHitKeyCount.key)]->numberOfTrackerHits());
3874  bestFirstHitShareFracSimClusterDenom = static_cast<float>(bestFirstHitKeyCount.countClusters) /
3875  static_cast<float>(tpKeyToClusterCount.at(bestFirstHitKeyCount.key));
3876  bestFirstHitChi2 = track_associator::trackAssociationChi2(
3877  tkParam, tkCov, *(tpCollection[tpKeyToIndex.at(bestFirstHitKeyCount.key)]), mf, bs);
3878  }
3879 
3880  float chi2_1Dmod = chi2;
3881  int count1dhits = 0;
3882  for (auto iHit = itTrack->recHitsBegin(), iEnd = itTrack->recHitsEnd(); iHit != iEnd; ++iHit) {
3883  const TrackingRecHit& hit = **iHit;
3884  if (hit.isValid() && typeid(hit) == typeid(SiStripRecHit1D))
3885  ++count1dhits;
3886  }
3887  if (count1dhits > 0) {
3888  chi2_1Dmod = (chi2 + count1dhits) / (ndof + count1dhits);
3889  }
3890 
3891  Point bestPV = getBestVertex(*itTrack, vertices);
3892 
3893  trk_px.push_back(itTrack->px());
3894  trk_py.push_back(itTrack->py());
3895  trk_pz.push_back(itTrack->pz());
3896  trk_pt.push_back(pt);
3897  trk_inner_px.push_back(itTrack->innerMomentum().x());
3898  trk_inner_py.push_back(itTrack->innerMomentum().y());
3899  trk_inner_pz.push_back(itTrack->innerMomentum().z());
3900  trk_inner_pt.push_back(itTrack->innerMomentum().rho());
3901  trk_outer_px.push_back(itTrack->outerMomentum().x());
3902  trk_outer_py.push_back(itTrack->outerMomentum().y());
3903  trk_outer_pz.push_back(itTrack->outerMomentum().z());
3904  trk_outer_pt.push_back(itTrack->outerMomentum().rho());
3905  trk_eta.push_back(eta);
3906  trk_lambda.push_back(lambda);
3907  trk_cotTheta.push_back(1 / tan(M_PI * 0.5 - lambda));
3908  trk_phi.push_back(phi);
3909  trk_dxy.push_back(itTrack->dxy(bs.position()));
3910  trk_dz.push_back(itTrack->dz(bs.position()));
3911  trk_dxyPV.push_back(itTrack->dxy(pvPosition));
3912  trk_dzPV.push_back(itTrack->dz(pvPosition));
3913  trk_dxyClosestPV.push_back(itTrack->dxy(bestPV));
3914  trk_dzClosestPV.push_back(itTrack->dz(bestPV));
3915  trk_ptErr.push_back(itTrack->ptError());
3916  trk_etaErr.push_back(itTrack->etaError());
3917  trk_lambdaErr.push_back(itTrack->lambdaError());
3918  trk_phiErr.push_back(itTrack->phiError());
3919  trk_dxyErr.push_back(itTrack->dxyError());
3920  trk_dzErr.push_back(itTrack->dzError());
3921  trk_refpoint_x.push_back(itTrack->vx());
3922  trk_refpoint_y.push_back(itTrack->vy());
3923  trk_refpoint_z.push_back(itTrack->vz());
3924  trk_nChi2.push_back(chi2);
3925  trk_nChi2_1Dmod.push_back(chi2_1Dmod);
3926  trk_ndof.push_back(ndof);
3927  trk_q.push_back(charge);
3928  trk_nValid.push_back(hp.numberOfValidHits());
3929  trk_nLost.push_back(hp.numberOfLostHits(reco::HitPattern::TRACK_HITS));
3930  trk_nInactive.push_back(hp.trackerLayersTotallyOffOrBad(reco::HitPattern::TRACK_HITS));
3931  trk_nPixel.push_back(hp.numberOfValidPixelHits());
3932  trk_nStrip.push_back(hp.numberOfValidStripHits());
3933  trk_nOuterLost.push_back(hp.numberOfLostTrackerHits(reco::HitPattern::MISSING_OUTER_HITS));
3934  trk_nInnerLost.push_back(hp.numberOfLostTrackerHits(reco::HitPattern::MISSING_INNER_HITS));
3935  trk_nOuterInactive.push_back(hp.trackerLayersTotallyOffOrBad(reco::HitPattern::MISSING_OUTER_HITS));
3936  trk_nInnerInactive.push_back(hp.trackerLayersTotallyOffOrBad(reco::HitPattern::MISSING_INNER_HITS));
3937  trk_nPixelLay.push_back(hp.pixelLayersWithMeasurement());
3938  trk_nStripLay.push_back(hp.stripLayersWithMeasurement());
3939  trk_n3DLay.push_back(hp.numberOfValidStripLayersWithMonoAndStereo() + hp.pixelLayersWithMeasurement());
3940  trk_nLostLay.push_back(hp.trackerLayersWithoutMeasurement(reco::HitPattern::TRACK_HITS));
3941  trk_nCluster.push_back(nClusters);
3942  trk_algo.push_back(itTrack->algo());
3943  trk_originalAlgo.push_back(itTrack->originalAlgo());
3944  trk_algoMask.push_back(itTrack->algoMaskUL());
3945  trk_stopReason.push_back(itTrack->stopReason());
3946  trk_isHP.push_back(itTrack->quality(reco::TrackBase::highPurity));
3947  if (includeMVA_) {
3948  for (size_t i = 0; i < trk_mvas.size(); ++i) {
3949  trk_mvas[i].push_back((*(mvaColls[i]))[iTrack]);
3950  trk_qualityMasks[i].push_back((*(qualColls[i]))[iTrack]);
3951  }
3952  }
3953  if (includeSeeds_) {
3954  auto offset = seedCollToOffset.find(itTrack->seedRef().id());
3955  if (offset == seedCollToOffset.end()) {
3956  throw cms::Exception("Configuration")
3957  << "Track algo '" << reco::TrackBase::algoName(itTrack->algo()) << "' originalAlgo '"
3958  << reco::TrackBase::algoName(itTrack->originalAlgo()) << "' refers to seed collection "
3959  << itTrack->seedRef().id()
3960  << ", but that seed collection is not given as an input. The following collections were given as an input "
3961  << make_ProductIDMapPrinter(seedCollToOffset);
3962  }
3963 
3964  const auto seedIndex = offset->second + itTrack->seedRef().key();
3965  trk_seedIdx.push_back(seedIndex);
3966  if (see_trkIdx[seedIndex] != -1) {
3967  throw cms::Exception("LogicError") << "Track index has already been set for seed " << seedIndex << " to "
3968  << see_trkIdx[seedIndex] << "; was trying to set it to " << iTrack;
3969  }
3970  see_trkIdx[seedIndex] = iTrack;
3971  }
3972  trk_vtxIdx.push_back(-1); // to be set correctly in fillVertices
3974  trk_simTrkIdx.push_back(tpIdx);
3975  trk_simTrkShareFrac.push_back(sharedFraction);
3976  trk_simTrkNChi2.push_back(tpChi2);
3977  trk_bestSimTrkIdx.push_back(bestKeyCount.key >= 0 ? tpKeyToIndex.at(bestKeyCount.key) : -1);
3978  trk_bestFromFirstHitSimTrkIdx.push_back(bestFirstHitKeyCount.key >= 0 ? tpKeyToIndex.at(bestFirstHitKeyCount.key)
3979  : -1);
3980  } else {
3981  trk_isTrue.push_back(!tpIdx.empty());
3982  }
3983  trk_bestSimTrkShareFrac.push_back(bestShareFrac);
3984  trk_bestSimTrkShareFracSimDenom.push_back(bestShareFracSimDenom);
3985  trk_bestSimTrkShareFracSimClusterDenom.push_back(bestShareFracSimClusterDenom);
3986  trk_bestSimTrkNChi2.push_back(bestChi2);
3987  trk_bestFromFirstHitSimTrkShareFrac.push_back(bestFirstHitShareFrac);
3988  trk_bestFromFirstHitSimTrkShareFracSimDenom.push_back(bestFirstHitShareFracSimDenom);
3989  trk_bestFromFirstHitSimTrkShareFracSimClusterDenom.push_back(bestFirstHitShareFracSimClusterDenom);
3990  trk_bestFromFirstHitSimTrkNChi2.push_back(bestFirstHitChi2);
3991 
3992  LogTrace("TrackingNtuple") << "Track #" << itTrack.key() << " with q=" << charge << ", pT=" << pt
3993  << " GeV, eta: " << eta << ", phi: " << phi << ", chi2=" << chi2 << ", Nhits=" << nHits
3994  << ", algo=" << itTrack->algoName(itTrack->algo()).c_str()
3995  << " hp=" << itTrack->quality(reco::TrackBase::highPurity)
3996  << " seed#=" << itTrack->seedRef().key() << " simMatch=" << isSimMatched
3997  << " nSimHits=" << nSimHits
3998  << " sharedFraction=" << (sharedFraction.empty() ? -1 : sharedFraction[0])
3999  << " tpIdx=" << (tpIdx.empty() ? -1 : tpIdx[0]);
4000  std::vector<int> hitIdx;
4001  std::vector<int> hitType;
4002 
4003  for (auto i = itTrack->recHitsBegin(); i != itTrack->recHitsEnd(); i++) {
4004  auto hit = *i;
4005  DetId hitId = hit->geographicalId();
4006  LogTrace("TrackingNtuple") << "hit #" << std::distance(itTrack->recHitsBegin(), i)
4007  << " subdet=" << hitId.subdetId();
4008  if (hitId.det() != DetId::Tracker)
4009  continue;
4010 
4011  LogTrace("TrackingNtuple") << " " << subdetstring(hitId.subdetId()) << " " << tTopo.layer(hitId);
4012 
4013  if (hit->isValid()) {
4014  //ugly... but works
4015  const BaseTrackerRecHit* bhit = dynamic_cast<const BaseTrackerRecHit*>(&*hit);
4016  const auto& clusterRef = bhit->firstClusterRef();
4017  unsigned int clusterKey;
4018  if (clusterRef.isPixel()) {
4019  clusterKey = clusterRef.cluster_pixel().key();
4020  } else if (clusterRef.isPhase2()) {
4021  clusterKey = clusterRef.cluster_phase2OT().key();
4022  } else {
4023  clusterKey = clusterRef.cluster_strip().key();
4024  }
4025 
4026  LogTrace("TrackingNtuple") << " id: " << hitId.rawId() << " - globalPos =" << hit->globalPosition()
4027  << " cluster=" << clusterKey << " clusterRef ID=" << clusterRef.id()
4028  << " eta,phi: " << hit->globalPosition().eta() << "," << hit->globalPosition().phi();
4029  if (includeAllHits_) {
4030  checkProductID(hitProductIds, clusterRef.id(), "track");
4031  if (clusterRef.isPixel()) {
4032  pix_trkIdx[clusterKey].push_back(iTrack);
4033  pix_onTrk_x[clusterKey].push_back(hit->globalPosition().x());
4034  pix_onTrk_y[clusterKey].push_back(hit->globalPosition().y());
4035  pix_onTrk_z[clusterKey].push_back(hit->globalPosition().z());
4036  pix_onTrk_xx[clusterKey].push_back(hit->globalPositionError().cxx());
4037  pix_onTrk_xy[clusterKey].push_back(hit->globalPositionError().cyx());
4038  pix_onTrk_yy[clusterKey].push_back(hit->globalPositionError().cyy());
4039  pix_onTrk_yz[clusterKey].push_back(hit->globalPositionError().czy());
4040  pix_onTrk_zz[clusterKey].push_back(hit->globalPositionError().czz());
4041  pix_onTrk_zx[clusterKey].push_back(hit->globalPositionError().czx());
4042  } else if (clusterRef.isPhase2()) {
4043  ph2_trkIdx[clusterKey].push_back(iTrack);
4044  ph2_onTrk_x[clusterKey].push_back(hit->globalPosition().x());
4045  ph2_onTrk_y[clusterKey].push_back(hit->globalPosition().y());
4046  ph2_onTrk_z[clusterKey].push_back(hit->globalPosition().z());
4047  ph2_onTrk_xx[clusterKey].push_back(hit->globalPositionError().cxx());
4048  ph2_onTrk_xy[clusterKey].push_back(hit->globalPositionError().cyx());
4049  ph2_onTrk_yy[clusterKey].push_back(hit->globalPositionError().cyy());
4050  ph2_onTrk_yz[clusterKey].push_back(hit->globalPositionError().czy());
4051  ph2_onTrk_zz[clusterKey].push_back(hit->globalPositionError().czz());
4052  ph2_onTrk_zx[clusterKey].push_back(hit->globalPositionError().czx());
4053  } else {
4054  str_trkIdx[clusterKey].push_back(iTrack);
4055  str_onTrk_x[clusterKey].push_back(hit->globalPosition().x());
4056  str_onTrk_y[clusterKey].push_back(hit->globalPosition().y());
4057  str_onTrk_z[clusterKey].push_back(hit->globalPosition().z());
4058  str_onTrk_xx[clusterKey].push_back(hit->globalPositionError().cxx());
4059  str_onTrk_xy[clusterKey].push_back(hit->globalPositionError().cyx());
4060  str_onTrk_yy[clusterKey].push_back(hit->globalPositionError().cyy());
4061  str_onTrk_yz[clusterKey].push_back(hit->globalPositionError().czy());
4062  str_onTrk_zz[clusterKey].push_back(hit->globalPositionError().czz());
4063  str_onTrk_zx[clusterKey].push_back(hit->globalPositionError().czx());
4064  }
4065  }
4066 
4067  hitIdx.push_back(clusterKey);
4068  if (clusterRef.isPixel()) {
4069  hitType.push_back(static_cast<int>(HitType::Pixel));
4070  } else if (clusterRef.isPhase2()) {
4071  hitType.push_back(static_cast<int>(HitType::Phase2OT));
4072  } else {
4073  hitType.push_back(static_cast<int>(HitType::Strip));
4074  }
4075  } else {
4076  LogTrace("TrackingNtuple") << " - invalid hit";
4077 
4078  hitIdx.push_back(inv_isBarrel.size());
4079  hitType.push_back(static_cast<int>(HitType::Invalid));
4080 
4081  inv_isBarrel.push_back(hitId.subdetId() == 1);
4082  if (includeStripHits_)
4083  inv_detId.push_back(tracker, tTopo, hitId);
4084  else
4085  inv_detId_phase2.push_back(tracker, tTopo, hitId);
4086  inv_type.push_back(hit->getType());
4087  }
4088  }
4089 
4090  trk_hitIdx.push_back(hitIdx);
4091  trk_hitType.push_back(hitType);
4092  }
4093 }
4094 
4096  int algo,
4097  const TrackingParticleRefVector& tpCollection,
4098  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
4099  const TrackingParticleRefKeyToCount& tpKeyToClusterCount,
4100  const MagneticField& mf,
4101  const reco::BeamSpot& bs,
4103  const reco::TrackToTrackingParticleAssociator& associatorByHits,
4104  const ClusterTPAssociation& clusterToTPMap,
4105  const TrackerGeometry& tracker,
4106  const TrackerTopology& tTopo,
4107  const std::set<edm::ProductID>& hitProductIds,
4108  const std::map<edm::ProductID, size_t>& seedCollToOffset) {
4109  reco::RecoToSimCollectionTCandidate recSimColl = associatorByHits.associateRecoToSim(candsHandle, tpCollection);
4110 
4111  TSCBLBuilderNoMaterial tscblBuilder;
4112 
4113  auto const& cands = *candsHandle;
4114  for (size_t iCand = 0; iCand < cands.size(); ++iCand) {
4115  const auto& aCand = cands[iCand];
4116  const edm::Ref<TrackCandidateCollection> aCandRef(candsHandle, iCand);
4117 
4118  //get parameters and errors from the candidate state
4119  auto const& pState = aCand.trajectoryStateOnDet();
4121  trajectoryStateTransform::transientState(pState, &(tracker.idToDet(pState.detId())->surface()), &mf);
4122  TrajectoryStateClosestToBeamLine tbStateAtPCA = tscblBuilder(*state.freeState(), bs);
4123  if (!tbStateAtPCA.isValid()) {
4124  edm::LogVerbatim("TrackBuilding") << "TrajectoryStateClosestToBeamLine not valid";
4125  }
4126 
4127  auto const& stateAtPCA = tbStateAtPCA.trackStateAtPCA();
4128  auto v0 = stateAtPCA.position();
4129  auto p = stateAtPCA.momentum();
4130  math::XYZPoint pos(v0.x(), v0.y(), v0.z());
4131  math::XYZVector mom(p.x(), p.y(), p.z());
4132 
4133  //pseduo track for access to easy methods
4134  static const reco::Track::CovarianceMatrix dummyCov = AlgebraicMatrixID();
4135  reco::Track trk(
4136  0, 0, pos, mom, stateAtPCA.charge(), tbStateAtPCA.isValid() ? stateAtPCA.curvilinearError().matrix() : dummyCov);
4137 
4138  const auto& tkParam = trk.parameters();
4139  auto tkCov = trk.covariance();
4140  tkCov.Invert();
4141 
4142  // Standard track-TP matching
4143  int nSimHits = 0;
4144  bool isSimMatched = false;
4145  std::vector<int> tpIdx;
4146  std::vector<float> sharedFraction;
4147  std::vector<float> tpChi2;
4148  auto foundTPs = recSimColl.find(aCandRef);
4149  if (foundTPs != recSimColl.end()) {
4150  if (!foundTPs->val.empty()) {
4151  nSimHits = foundTPs->val[0].first->numberOfTrackerHits();
4152  isSimMatched = true;
4153  }
4154  for (const auto& tpQuality : foundTPs->val) {
4155  tpIdx.push_back(tpKeyToIndex.at(tpQuality.first.key()));
4156  sharedFraction.push_back(tpQuality.second);
4157  tpChi2.push_back(track_associator::trackAssociationChi2(tkParam, tkCov, *(tpCollection[tpIdx.back()]), mf, bs));
4158  }
4159  }
4160 
4161  // Search for a best-matching TrackingParticle for a track
4162  const auto clusters = track_associator::hitsToClusterRefs(aCand.recHits().begin(), aCand.recHits().end());
4163  const int nClusters = clusters.size();
4164 
4165  const auto bestKeyCount = findBestMatchingTrackingParticle(aCand.recHits(), clusterToTPMap, tpKeyToIndex);
4166  const float bestCountF = bestKeyCount.countClusters;
4167  const float bestShareFrac = bestCountF / nClusters;
4168  float bestShareFracSimDenom = 0;
4169  float bestShareFracSimClusterDenom = 0;
4170  float bestChi2 = -1;
4171  if (bestKeyCount.key >= 0) {
4172  bestShareFracSimDenom = bestCountF / tpCollection[tpKeyToIndex.at(bestKeyCount.key)]->numberOfTrackerHits();
4173  bestShareFracSimClusterDenom = bestCountF / tpKeyToClusterCount.at(bestKeyCount.key);
4175  tkParam, tkCov, *(tpCollection[tpKeyToIndex.at(bestKeyCount.key)]), mf, bs);
4176  }
4177  // Another way starting from the first hit of the track
4178  const auto bestFirstHitKeyCount =
4179  findMatchingTrackingParticleFromFirstHit(aCand.recHits(), clusterToTPMap, tpKeyToIndex);
4180  const float bestFirstCountF = bestFirstHitKeyCount.countClusters;
4181  const float bestFirstHitShareFrac = bestFirstCountF / nClusters;
4182  float bestFirstHitShareFracSimDenom = 0;
4183  float bestFirstHitShareFracSimClusterDenom = 0;
4184  float bestFirstHitChi2 = -1;
4185  if (bestFirstHitKeyCount.key >= 0) {
4186  bestFirstHitShareFracSimDenom =
4187  bestFirstCountF / tpCollection[tpKeyToIndex.at(bestFirstHitKeyCount.key)]->numberOfTrackerHits();
4188  bestFirstHitShareFracSimClusterDenom = bestFirstCountF / tpKeyToClusterCount.at(bestFirstHitKeyCount.key);
4189  bestFirstHitChi2 = track_associator::trackAssociationChi2(
4190  tkParam, tkCov, *(tpCollection[tpKeyToIndex.at(bestFirstHitKeyCount.key)]), mf, bs);
4191  }
4192 
4193  auto iglobCand = tcand_pca_valid.size(); //global cand index
4194  tcand_pca_valid.push_back(tbStateAtPCA.isValid());
4195  tcand_pca_px.push_back(trk.px());
4196  tcand_pca_py.push_back(trk.py());
4197  tcand_pca_pz.push_back(trk.pz());
4198  tcand_pca_pt.push_back(trk.pt());
4199  tcand_pca_eta.push_back(trk.eta());
4200  tcand_pca_phi.push_back(trk.phi());
4201  tcand_pca_dxy.push_back(trk.dxy());
4202  tcand_pca_dz.push_back(trk.dz());
4203  tcand_pca_ptErr.push_back(trk.ptError());
4204  tcand_pca_etaErr.push_back(trk.etaError());
4205  tcand_pca_lambdaErr.push_back(trk.lambdaError());
4206  tcand_pca_phiErr.push_back(trk.phiError());
4207  tcand_pca_dxyErr.push_back(trk.dxyError());
4208  tcand_pca_dzErr.push_back(trk.dzError());
4209  tcand_px.push_back(state.globalMomentum().x());
4210  tcand_py.push_back(state.globalMomentum().y());
4211  tcand_pz.push_back(state.globalMomentum().z());
4212  tcand_pt.push_back(state.globalMomentum().perp());
4213  tcand_x.push_back(state.globalPosition().x());
4214  tcand_y.push_back(state.globalPosition().y());
4215  tcand_z.push_back(state.globalPosition().z());
4216 
4217  auto const& pStateCov = state.curvilinearError().matrix();
4218  tcand_qbpErr.push_back(sqrt(pStateCov(0, 0)));
4219  tcand_lambdaErr.push_back(sqrt(pStateCov(1, 1)));
4220  tcand_phiErr.push_back(sqrt(pStateCov(2, 2)));
4221  tcand_xtErr.push_back(sqrt(pStateCov(3, 3)));
4222  tcand_ytErr.push_back(sqrt(pStateCov(4, 4)));
4223 
4224  int ndof = -5;
4225  int nValid = 0;
4226  int nPixel = 0;
4227  int nStrip = 0;
4228  for (auto const& hit : aCand.recHits()) {
4229  if (hit.isValid()) {
4230  ndof += hit.dimension();
4231  nValid++;
4232 
4233  auto const subdet = hit.geographicalId().subdetId();
4235  nPixel++;
4236  else
4237  nStrip++;
4238  }
4239  }
4240  tcand_ndof.push_back(ndof);
4241  tcand_q.push_back(trk.charge());
4242  tcand_nValid.push_back(nValid);
4243  tcand_nPixel.push_back(nPixel);
4244  tcand_nStrip.push_back(nStrip);
4245  tcand_nCluster.push_back(nClusters);
4246  tcand_algo.push_back(algo);
4247  tcand_stopReason.push_back(aCand.stopReason());
4248  if (includeSeeds_) {
4249  auto offset = seedCollToOffset.find(aCand.seedRef().id());
4250  if (offset == seedCollToOffset.end()) {
4251  throw cms::Exception("Configuration")
4252  << "Track candidate refers to seed collection " << aCand.seedRef().id()
4253  << ", but that seed collection is not given as an input. The following collections were given as an input "
4254  << make_ProductIDMapPrinter(seedCollToOffset);
4255  }
4256 
4257  const auto seedIndex = offset->second + aCand.seedRef().key();
4258  tcand_seedIdx.push_back(seedIndex);
4259  if (see_tcandIdx[seedIndex] != -1) {
4260  throw cms::Exception("LogicError")
4261  << "Track cand index has already been set for seed " << seedIndex << " to " << see_tcandIdx[seedIndex]
4262  << "; was trying to set it to " << iglobCand << " current " << iCand;
4263  }
4264  see_tcandIdx[seedIndex] = iglobCand;
4265  }
4266  tcand_vtxIdx.push_back(-1); // to be set correctly in fillVertices
4268  tcand_simTrkIdx.push_back(tpIdx);
4269  tcand_simTrkShareFrac.push_back(sharedFraction);
4270  tcand_simTrkNChi2.push_back(tpChi2);
4271  tcand_bestSimTrkIdx.push_back(bestKeyCount.key >= 0 ? tpKeyToIndex.at(bestKeyCount.key) : -1);
4273  bestFirstHitKeyCount.key >= 0 ? tpKeyToIndex.at(bestFirstHitKeyCount.key) : -1);
4274  } else {
4275  tcand_isTrue.push_back(!tpIdx.empty());
4276  }
4277  tcand_bestSimTrkShareFrac.push_back(bestShareFrac);
4278  tcand_bestSimTrkShareFracSimDenom.push_back(bestShareFracSimDenom);
4279  tcand_bestSimTrkShareFracSimClusterDenom.push_back(bestShareFracSimClusterDenom);
4280  tcand_bestSimTrkNChi2.push_back(bestChi2);
4281  tcand_bestFromFirstHitSimTrkShareFrac.push_back(bestFirstHitShareFrac);
4282  tcand_bestFromFirstHitSimTrkShareFracSimDenom.push_back(bestFirstHitShareFracSimDenom);
4283  tcand_bestFromFirstHitSimTrkShareFracSimClusterDenom.push_back(bestFirstHitShareFracSimClusterDenom);
4284  tcand_bestFromFirstHitSimTrkNChi2.push_back(bestFirstHitChi2);
4285 
4286  LogTrace("TrackingNtuple") << "Track cand #" << iCand << " glob " << iglobCand << " with q=" << trk.charge()
4287  << ", pT=" << trk.pt() << " GeV, eta: " << trk.eta() << ", phi: " << trk.phi()
4288  << ", nValid=" << nValid << " seed#=" << aCand.seedRef().key()
4289  << " simMatch=" << isSimMatched << " nSimHits=" << nSimHits
4290  << " sharedFraction=" << (sharedFraction.empty() ? -1 : sharedFraction[0])
4291  << " tpIdx=" << (tpIdx.empty() ? -1 : tpIdx[0]);
4292  std::vector<int> hitIdx;
4293  std::vector<int> hitType;
4294 
4295  for (auto i = aCand.recHits().begin(); i != aCand.recHits().end(); i++) {
4296  const TrackingRecHit* hit = &*i;
4297  DetId hitId = hit->geographicalId();
4298  LogTrace("TrackingNtuple") << "hit #" << std::distance(aCand.recHits().begin(), i)
4299  << " subdet=" << hitId.subdetId();
4300  if (hitId.det() != DetId::Tracker)
4301  continue;
4302 
4303  LogTrace("TrackingNtuple") << " " << subdetstring(hitId.subdetId()) << " " << tTopo.layer(hitId);
4304 
4305  if (hit->isValid()) {
4306  //ugly... but works
4307  const BaseTrackerRecHit* bhit = dynamic_cast<const BaseTrackerRecHit*>(&*hit);
4308  const auto& clusterRef = bhit->firstClusterRef();
4309  unsigned int clusterKey;
4310  if (clusterRef.isPixel()) {
4311  clusterKey = clusterRef.cluster_pixel().key();
4312  } else if (clusterRef.isPhase2()) {
4313  clusterKey = clusterRef.cluster_phase2OT().key();
4314  } else {
4315  clusterKey = clusterRef.cluster_strip().key();
4316  }
4317 
4318  LogTrace("TrackingNtuple") << " id: " << hitId.rawId() << " - globalPos =" << hit->globalPosition()
4319  << " cluster=" << clusterKey << " clusterRef ID=" << clusterRef.id()
4320  << " eta,phi: " << hit->globalPosition().eta() << "," << hit->globalPosition().phi();
4321  if (includeAllHits_) {
4322  checkProductID(hitProductIds, clusterRef.id(), "track");
4323  if (clusterRef.isPixel()) {
4324  pix_tcandIdx[clusterKey].push_back(iglobCand);
4325  } else if (clusterRef.isPhase2()) {
4326  ph2_tcandIdx[clusterKey].push_back(iglobCand);
4327  } else {
4328  str_tcandIdx[clusterKey].push_back(iglobCand);
4329  }
4330  }
4331 
4332  hitIdx.push_back(clusterKey);
4333  if (clusterRef.isPixel()) {
4334  hitType.push_back(static_cast<int>(HitType::Pixel));
4335  } else if (clusterRef.isPhase2()) {
4336  hitType.push_back(static_cast<int>(HitType::Phase2OT));
4337  } else {
4338  hitType.push_back(static_cast<int>(HitType::Strip));
4339  }
4340  }
4341  }
4342 
4343  tcand_hitIdx.push_back(hitIdx);
4344  tcand_hitType.push_back(hitType);
4345  }
4346 }
4347 
4349  const edm::EventSetup& iSetup,
4351  const reco::BeamSpot& bs,
4352  const TrackingParticleRefVector& tpCollection,
4353  const TrackingVertexRefKeyToIndex& tvKeyToIndex,
4354  const reco::TrackToTrackingParticleAssociator& associatorByHits,
4355  const std::vector<TPHitIndex>& tpHitList,
4356  const TrackingParticleRefKeyToCount& tpKeyToClusterCount) {
4357  // Number of 3D layers for TPs
4359  iEvent.getByToken(tpNLayersToken_, tpNLayersH);
4360  const auto& nLayers_tPCeff = *tpNLayersH;
4361 
4362  iEvent.getByToken(tpNPixelLayersToken_, tpNLayersH);
4363  const auto& nPixelLayers_tPCeff = *tpNLayersH;
4364 
4365  iEvent.getByToken(tpNStripStereoLayersToken_, tpNLayersH);
4366  const auto& nStripMonoAndStereoLayers_tPCeff = *tpNLayersH;
4367 
4368  reco::SimToRecoCollection simRecColl = associatorByHits.associateSimToReco(tracks, tpCollection);
4369 
4370  for (const TrackingParticleRef& tp : tpCollection) {
4371  LogTrace("TrackingNtuple") << "tracking particle pt=" << tp->pt() << " eta=" << tp->eta() << " phi=" << tp->phi();
4372  bool isRecoMatched = false;
4373  std::vector<int> tkIdx;
4374  std::vector<float> sharedFraction;
4375  auto foundTracks = simRecColl.find(tp);
4376  if (foundTracks != simRecColl.end()) {
4377  isRecoMatched = true;
4378  for (const auto& trackQuality : foundTracks->val) {
4379  sharedFraction.push_back(trackQuality.second);
4380  tkIdx.push_back(trackQuality.first.key());
4381  }
4382  }
4383 
4384  sim_genPdgIds.emplace_back();
4385  for (const auto& genRef : tp->genParticles()) {
4386  if (genRef.isNonnull())
4387  sim_genPdgIds.back().push_back(genRef->pdgId());
4388  }
4389 
4390  bool isFromBHadron = false;
4391  // Logic is similar to SimTracker/TrackHistory
4392  if (tracer_.evaluate(tp)) { // ignore TP if history can not be traced
4393  // following is from TrackClassifier::processesAtGenerator()
4394  HistoryBase::RecoGenParticleTrail const& recoGenParticleTrail = tracer_.recoGenParticleTrail();
4395  for (const auto& particle : recoGenParticleTrail) {
4396  HepPDT::ParticleID particleID(particle->pdgId());
4397  if (particleID.hasBottom()) {
4398  isFromBHadron = true;
4399  break;
4400  }
4401  }
4402  }
4403 
4404  LogTrace("TrackingNtuple") << "matched to tracks = " << make_VectorPrinter(tkIdx)
4405  << " isRecoMatched=" << isRecoMatched;
4406  sim_event.push_back(tp->eventId().event());
4407  sim_bunchCrossing.push_back(tp->eventId().bunchCrossing());
4408  sim_pdgId.push_back(tp->pdgId());
4409  sim_isFromBHadron.push_back(isFromBHadron);
4410  sim_px.push_back(tp->px());
4411  sim_py.push_back(tp->py());
4412  sim_pz.push_back(tp->pz());
4413  sim_pt.push_back(tp->pt());
4414  sim_eta.push_back(tp->eta());
4415  sim_phi.push_back(tp->phi());
4416  sim_q.push_back(tp->charge());
4417  sim_trkIdx.push_back(tkIdx);
4418  sim_trkShareFrac.push_back(sharedFraction);
4419  sim_parentVtxIdx.push_back(tvKeyToIndex.at(tp->parentVertex().key()));
4420  std::vector<int> decayIdx;
4421  for (const auto& v : tp->decayVertices())
4422  decayIdx.push_back(tvKeyToIndex.at(v.key()));
4423  sim_decayVtxIdx.push_back(decayIdx);
4424 
4425  //Calcualte the impact parameters w.r.t. PCA
4428  auto dxySim = TrackingParticleIP::dxy(vertex, momentum, bs.position());
4429  auto dzSim = TrackingParticleIP::dz(vertex, momentum, bs.position());
4430  const double lambdaSim = M_PI / 2 - momentum.theta();
4431  sim_pca_pt.push_back(std::sqrt(momentum.perp2()));
4432  sim_pca_eta.push_back(momentum.Eta());
4433  sim_pca_lambda.push_back(lambdaSim);
4434  sim_pca_cotTheta.push_back(1 / tan(M_PI * 0.5 - lambdaSim));
4435  sim_pca_phi.push_back(momentum.phi());
4436  sim_pca_dxy.push_back(dxySim);
4437  sim_pca_dz.push_back(dzSim);
4438 
4439  std::vector<int> hitIdx;
4440  int nPixel = 0, nStrip = 0;
4441  auto rangeHit = std::equal_range(tpHitList.begin(), tpHitList.end(), TPHitIndex(tp.key()), tpHitIndexListLess);
4442  for (auto ip = rangeHit.first; ip != rangeHit.second; ++ip) {
4443  auto type = HitType::Unknown;
4444  if (!simhit_hitType[ip->simHitIdx].empty())
4445  type = static_cast<HitType>(simhit_hitType[ip->simHitIdx][0]);
4446  LogTrace("TrackingNtuple") << "simhit=" << ip->simHitIdx << " type=" << static_cast<int>(type);
4447  hitIdx.push_back(ip->simHitIdx);
4448  const auto detid = DetId(includeStripHits_ ? simhit_detId[ip->simHitIdx] : simhit_detId_phase2[ip->simHitIdx]);
4449  if (detid.det() != DetId::Tracker) {
4450  throw cms::Exception("LogicError") << "Encountered SimHit for TP " << tp.key() << " with DetId "
4451  << detid.rawId() << " whose det() is not Tracker but " << detid.det();
4452  }
4453  const auto subdet = detid.subdetId();
4454  switch (subdet) {
4457  ++nPixel;
4458  break;
4459  case StripSubdetector::TIB:
4460  case StripSubdetector::TID:
4461  case StripSubdetector::TOB:
4462  case StripSubdetector::TEC:
4463  ++nStrip;
4464  break;
4465  default:
4466  throw cms::Exception("LogicError") << "Encountered SimHit for TP " << tp.key() << " with DetId "
4467  << detid.rawId() << " whose subdet is not recognized, is " << subdet;
4468  };
4469  }
4470  sim_nValid.push_back(hitIdx.size());
4471  sim_nPixel.push_back(nPixel);
4472  sim_nStrip.push_back(nStrip);
4473 
4474  const auto nSimLayers = nLayers_tPCeff[tp];
4475  const auto nSimPixelLayers = nPixelLayers_tPCeff[tp];
4476  const auto nSimStripMonoAndStereoLayers = nStripMonoAndStereoLayers_tPCeff[tp];
4477  sim_nLay.push_back(nSimLayers);
4478  sim_nPixelLay.push_back(nSimPixelLayers);
4479  sim_n3DLay.push_back(nSimPixelLayers + nSimStripMonoAndStereoLayers);
4480 
4481  sim_nTrackerHits.push_back(tp->numberOfTrackerHits());
4482  auto found = tpKeyToClusterCount.find(tp.key());
4483  sim_nRecoClusters.push_back(found != cend(tpKeyToClusterCount) ? found->second : 0);
4484 
4485  sim_simHitIdx.push_back(hitIdx);
4486  }
4487 }
4488 
4489 // called from fillSeeds
4491  const reco::SimToRecoCollection& simRecColl,
4492  const TrackingParticleRefKeyToIndex& tpKeyToIndex,
4493  const unsigned int seedOffset) {
4494  if (sim_seedIdx.empty()) // first call
4495  sim_seedIdx.resize(tpCollection.size());
4496 
4497  for (const auto& keyVal : simRecColl) {
4498  const auto& tpRef = keyVal.key;
4499  auto found = tpKeyToIndex.find(tpRef.key());
4500  if (found == tpKeyToIndex.end())
4501  throw cms::Exception("Assert") << __FILE__ << ":" << __LINE__ << " fillTrackingParticlesForSeeds: tpRef.key() "
4502  << tpRef.key() << " not found from tpKeyToIndex. tpKeyToIndex size "
4503  << tpKeyToIndex.size();
4504  const auto tpIndex = found->second;
4505  for (const auto& pair : keyVal.val) {
4506  const auto& seedRef = pair.first->seedRef();
4507  sim_seedIdx[tpIndex].push_back(seedOffset + seedRef.key());
4508  }
4509  }
4510 }
4511 
4514  for (size_t iVertex = 0, size = vertices.size(); iVertex < size; ++iVertex) {
4515  const reco::Vertex& vertex = vertices[iVertex];
4516  vtx_x.push_back(vertex.x());
4517  vtx_y.push_back(vertex.y());
4518  vtx_z.push_back(vertex.z());
4519  vtx_xErr.push_back(vertex.xError());
4520  vtx_yErr.push_back(vertex.yError());
4521  vtx_zErr.push_back(vertex.zError());
4522  vtx_chi2.push_back(vertex.chi2());
4523  vtx_ndof.push_back(vertex.ndof());
4524  vtx_fake.push_back(vertex.isFake());
4525  vtx_valid.push_back(vertex.isValid());
4526 
4527  std::vector<int> trkIdx;
4528  for (auto iTrack = vertex.tracks_begin(); iTrack != vertex.tracks_end(); ++iTrack) {
4529  // Ignore link if vertex was fit from a track collection different from the input
4530  if (iTrack->id() != tracks.id())
4531  continue;
4532 
4533  trkIdx.push_back(iTrack->key());
4534 
4535  if (trk_vtxIdx[iTrack->key()] != -1) {
4536  throw cms::Exception("LogicError") << "Vertex index has already been set for track " << iTrack->key() << " to "
4537  << trk_vtxIdx[iTrack->key()] << "; was trying to set it to " << iVertex;
4538  }
4539  trk_vtxIdx[iTrack->key()] = iVertex;
4540  }
4541  vtx_trkIdx.push_back(trkIdx);
4542  }
4543 }
4544 
4546  const TrackingParticleRefKeyToIndex& tpKeyToIndex) {
4547  int current_event = -1;
4548  for (const auto& ref : trackingVertices) {
4549  const TrackingVertex v = *ref;
4550  if (v.eventId().event() != current_event) {
4551  // next PV
4552  current_event = v.eventId().event();
4553  simpv_idx.push_back(simvtx_x.size());
4554  }
4555 
4556  unsigned int processType = std::numeric_limits<unsigned int>::max();
4557  if (!v.g4Vertices().empty()) {
4558  processType = v.g4Vertices()[0].processType();
4559  }
4560 
4561  simvtx_event.push_back(v.eventId().event());
4562  simvtx_bunchCrossing.push_back(v.eventId().bunchCrossing());
4563  simvtx_processType.push_back(processType);
4564 
4565  simvtx_x.push_back(v.position().x());
4566  simvtx_y.push_back(v.position().y());
4567  simvtx_z.push_back(v.position().z());
4568 
4569  auto fill = [&](const TrackingParticleRefVector& tps, std::vector<int>& idx) {
4570  for (const auto& tpRef : tps) {
4571  auto found = tpKeyToIndex.find(tpRef.key());
4572  if (found != tpKeyToIndex.end()) {
4573  idx.push_back(found->second);
4574  }
4575  }
4576  };
4577 
4578  std::vector<int> sourceIdx;
4579  std::vector<int> daughterIdx;
4580  fill(v.sourceTracks(), sourceIdx);
4581  fill(v.daughterTracks(), daughterIdx);
4582 
4583  simvtx_sourceSimIdx.push_back(sourceIdx);
4584  simvtx_daughterSimIdx.push_back(daughterIdx);
4585  }
4586 }
4587 
4588 // ------------ method fills 'descriptions' with the allowed parameters for the module ------------
4590  //The following says we do not know what parameters are allowed so do no validation
4591  // Please change this to state exactly what you do use, even if it is no parameters
4593  desc.addUntracked<std::vector<edm::InputTag>>(
4594  "seedTracks",
4595  std::vector<edm::InputTag>{edm::InputTag("seedTracksinitialStepSeeds"),
4596  edm::InputTag("seedTracksdetachedTripletStepSeeds"),
4597  edm::InputTag("seedTrackspixelPairStepSeeds"),
4598  edm::InputTag("seedTrackslowPtTripletStepSeeds"),
4599  edm::InputTag("seedTracksmixedTripletStepSeeds"),
4600  edm::InputTag("seedTrackspixelLessStepSeeds"),
4601  edm::InputTag("seedTrackstobTecStepSeeds"),
4602  edm::InputTag("seedTracksjetCoreRegionalStepSeeds"),
4603  edm::InputTag("seedTracksmuonSeededSeedsInOut"),
4604  edm::InputTag("seedTracksmuonSeededSeedsOutIn")});
4605  desc.addUntracked<std::vector<edm::InputTag>>(
4606  "trackCandidates",
4607  std::vector<edm::InputTag>{edm::InputTag("initialStepTrackCandidates"),
4608  edm::InputTag("detachedTripletStepTrackCandidates"),
4609  edm::InputTag("pixelPairStepTrackCandidates"),
4610  edm::InputTag("lowPtTripletStepTrackCandidates"),
4611  edm::InputTag("mixedTripletStepTrackCandidates"),
4612  edm::InputTag("pixelLessStepTrackCandidates"),
4613  edm::InputTag("tobTecStepTrackCandidates"),
4614  edm::InputTag("jetCoreRegionalStepTrackCandidates"),
4615  edm::InputTag("muonSeededTrackCandidatesInOut"),
4616  edm::InputTag("muonSeededTrackCandidatesOutIn")});
4617  desc.addUntracked<edm::InputTag>("tracks", edm::InputTag("generalTracks"));
4618  desc.addUntracked<std::vector<std::string>>("trackMVAs", std::vector<std::string>{{"generalTracks"}});
4619 
4620  edm::ParameterSetDescription cMaskDesc;
4621  cMaskDesc.addUntracked<unsigned int>("index");
4622  cMaskDesc.addUntracked<edm::InputTag>("src");
4623  std::vector<edm::ParameterSet> cMasks;
4624  auto addMask = [&cMasks](reco::Track::TrackAlgorithm algo) {
4625  edm::ParameterSet ps;
4626  ps.addUntrackedParameter<unsigned int>("index", static_cast<unsigned int>(algo));
4627  ps.addUntrackedParameter<edm::InputTag>("src", {reco::Track::algoName(algo) + "Clusters"});
4628  cMasks.push_back(ps);
4629  };
4633  addMask(reco::Track::lowPtQuadStep);
4636  addMask(reco::Track::pixelLessStep);
4637  addMask(reco::Track::pixelPairStep);
4638  addMask(reco::Track::tobTecStep);
4639  desc.addVPSetUntracked("clusterMasks", cMaskDesc, cMasks);
4640 
4641  desc.addUntracked<edm::InputTag>("trackingParticles", edm::InputTag("mix", "MergedTrackTruth"));
4642  desc.addUntracked<bool>("trackingParticlesRef", false);
4643  desc.addUntracked<edm::InputTag>("clusterTPMap", edm::InputTag("tpClusterProducer"));
4644  desc.addUntracked<edm::InputTag>("simHitTPMap", edm::InputTag("simHitTPAssocProducer"));
4645  desc.addUntracked<edm::InputTag>("trackAssociator", edm::InputTag("quickTrackAssociatorByHits"));
4646  desc.addUntracked<edm::InputTag>("pixelDigiSimLink", edm::InputTag("simSiPixelDigis"));
4647  desc.addUntracked<edm::InputTag>("stripDigiSimLink", edm::InputTag("simSiStripDigis"));
4648  desc.addUntracked<edm::InputTag>("phase2OTSimLink", edm::InputTag(""));
4649  desc.addUntracked<edm::InputTag>("beamSpot", edm::InputTag("offlineBeamSpot"));
4650  desc.addUntracked<edm::InputTag>("pixelRecHits", edm::InputTag("siPixelRecHits"));
4651  desc.addUntracked<edm::InputTag>("stripRphiRecHits", edm::InputTag("siStripMatchedRecHits", "rphiRecHit"));
4652  desc.addUntracked<edm::InputTag>("stripStereoRecHits", edm::InputTag("siStripMatchedRecHits", "stereoRecHit"));
4653  desc.addUntracked<edm::InputTag>("stripMatchedRecHits", edm::InputTag("siStripMatchedRecHits", "matchedRecHit"));
4654  desc.addUntracked<edm::InputTag>("phase2OTRecHits", edm::InputTag("siPhase2RecHits"));
4655  desc.addUntracked<edm::InputTag>("vertices", edm::InputTag("offlinePrimaryVertices"));
4656  desc.addUntracked<edm::InputTag>("trackingVertices", edm::InputTag("mix", "MergedTrackTruth"));
4657  desc.addUntracked<edm::InputTag>("trackingParticleNlayers",
4658  edm::InputTag("trackingParticleNumberOfLayersProducer", "trackerLayers"));
4659  desc.addUntracked<edm::InputTag>("trackingParticleNpixellayers",
4660  edm::InputTag("trackingParticleNumberOfLayersProducer", "pixelLayers"));
4661  desc.addUntracked<edm::InputTag>("trackingParticleNstripstereolayers",
4662  edm::InputTag("trackingParticleNumberOfLayersProducer", "stripStereoLayers"));
4663  desc.addUntracked<std::string>("TTRHBuilder", "WithTrackAngle")
4664  ->setComment("currently not used: keep for possible future use");
4665  desc.addUntracked<bool>("includeSeeds", false);
4666  desc.addUntracked<bool>("includeTrackCandidates", false);
4667  desc.addUntracked<bool>("addSeedCurvCov", false);
4668  desc.addUntracked<bool>("includeAllHits", false);
4669  desc.addUntracked<bool>("includeOnTrackHitData", false);
4670  desc.addUntracked<bool>("includeMVA", true);
4671  desc.addUntracked<bool>("includeTrackingParticles", true);
4672  desc.addUntracked<bool>("includeOOT", false);
4673  desc.addUntracked<bool>("keepEleSimHits", false);
4674  desc.addUntracked<bool>("saveSimHitsP3", false);
4675  desc.addUntracked<bool>("simHitBySignificance", false);
4676  descriptions.add("trackingNtuple", desc);
4677 }
4678 
4679 //define this as a plug-in
std::vector< unsigned int > sim_nTrackerHits
std::vector< int > trk_bestSimTrkIdx
std::vector< std::vector< float > > ph2_onTrk_yz
reco::SimToRecoCollection associateSimToReco(const edm::Handle< edm::View< reco::Track >> &tCH, const edm::Handle< TrackingParticleCollection > &tPCH) const
size
Write out results.
unsigned int tecPetalNumber(const DetId &id) const
std::vector< float > sim_pca_dz
edm::LuminosityBlockNumber_t ev_lumi
std::vector< float > trk_nChi2_1Dmod
static const std::string kSharedResource
Definition: TFileService.h:76
std::vector< unsigned int > simvtx_processType
edm::EDGetTokenT< TrackingParticleRefVector > trackingParticleRefToken_
std::vector< unsigned int > sim_nLay
Log< level::Info, true > LogVerbatim
std::vector< float > ph2_radL
bool isUpper(const DetId &id) const
std::vector< float > tcand_pca_phiErr
std::vector< float > trk_dxyPV
static constexpr auto TEC
unsigned int size_type
Definition: View.h:92
void fillTrackingVertices(const TrackingVertexRefVector &trackingVertices, const TrackingParticleRefKeyToIndex &tpKeyToIndex)
std::vector< float > see_bestSimTrkShareFrac
bool tibIsDoubleSide(const DetId &id) const
std::vector< std::vector< float > > see_simTrkShareFrac
edm::EDGetTokenT< SiStripMatchedRecHit2DCollection > stripMatchedRecHitToken_
std::vector< short > see_fitok
std::vector< short > vtx_fake
std::vector< float > simvtx_z
std::vector< std::vector< float > > trk_simTrkNChi2
bool tecIsDoubleSide(const DetId &id) const
std::vector< std::vector< int > > see_hitType
size_type dataSize() const
std::vector< float > trk_dzClosestPV
bool tidIsDoubleSide(const DetId &id) const
edm::EDGetTokenT< SiStripRecHit2DCollection > stripRphiRecHitToken_
std::vector< short > ph2_isBarrel
TrackAssociatorByHitsImpl::SimHitTPAssociationList SimHitTPAssociationList
ESGetTokenH3DDVariant esConsumes(std::string const &Record, edm::ConsumesCollector &)
Definition: DeDxTools.cc:283
DetIdStrip str_detId
std::vector< std::vector< float > > pix_onTrk_x
std::vector< float > trk_phi
void push_back(const TrackerGeometry &tracker, const TrackerTopology &tTopo, const DetId &id)
std::vector< float > sim_pca_cotTheta
unsigned int tibSide(const DetId &id) const
const bool simHitBySignificance_
std::vector< float > sim_pca_dxy
uint16_t firstStrip() const
void book(const std::string &prefix, TTree *tree)
std::vector< float > see_stateTrajX
std::vector< unsigned int > trk_nOuterLost
std::vector< float > glu_xy
std::vector< short > trk_isTrue
std::vector< std::vector< int > > ph2_seeIdx
std::vector< float > glu_radL
std::vector< float > trk_inner_pz
std::vector< float > see_stateTrajPy
std::vector< float > pix_y
std::vector< int > trk_vtxIdx
Pixel pixel(int i) const
std::vector< std::vector< int > > str_trkIdx
std::vector< unsigned int > see_nValid
std::vector< float > str_yy
unsigned int tobSide(const DetId &id) const
iterator find(det_id_type id)
Definition: DetSetVector.h:255
ProductID id() const
Accessor for product ID.
Definition: Ref.h:244
bool trackFromSeedFitFailed(const reco::Track &track)
std::vector< float > trk_outer_py
T const & getData(const ESGetToken< T, R > &iToken) const noexcept(false)
Definition: EventSetup.h:119
std::vector< float > glu_chargePerCM
std::vector< float > pix_zz
std::vector< unsigned short > layer
ParameterDescriptionBase * addUntracked(U const &iLabel, T const &value)
std::vector< float > ph2_bbxi
reco::RecoToSimCollection associateRecoToSim(const edm::Handle< edm::View< reco::Track >> &tCH, const edm::Handle< TrackingParticleCollection > &tPCH) const
std::vector< float > tcand_ytErr
void fillPixelHits(const edm::Event &iEvent, const TrackerGeometry &tracker, const ClusterTPAssociation &clusterToTPMap, const TrackingParticleRefKeyToIndex &tpKeyToIndex, const SimHitTPAssociationProducer::SimHitTPAssociationList &simHitsTPAssoc, const edm::DetSetVector< PixelDigiSimLink > &digiSimLink, const TrackerTopology &tTopo, const SimHitRefKeyToIndex &simHitRefKeyToIndex, std::set< edm::ProductID > &hitProductIds)
std::vector< uint64_t > str_usedMask
std::vector< int > glu_monoIdx
std::vector< float > trk_eta
std::vector< short > glu_isBarrel
const bool includeOOT_
std::vector< unsigned short > order
std::vector< std::vector< float > > ph2_onTrk_y
std::vector< std::vector< float > > str_onTrk_yz
std::vector< int > sim_bunchCrossing
std::vector< float > see_phiErr
std::vector< int > trk_bestFromFirstHitSimTrkIdx
std::vector< std::vector< int > > simhit_hitIdx
unsigned int pxfBlade(const DetId &id) const
static bool simHitTPAssociationListGreater(SimHitTPPair i, SimHitTPPair j)
std::vector< float > tcand_pca_pz
std::vector< float > str_x
std::vector< float > see_dzErr
std::vector< unsigned int > sim_n3DLay
unsigned int tibOrder(const DetId &id) const
std::vector< float > trk_cotTheta
std::vector< unsigned int > moduleType
std::vector< float > trk_bestSimTrkNChi2
CombineDetId< DetIdCommon, DetIdOTCommon, DetIdStripOnly > DetIdStrip
void push_back(const TrackerGeometry &tracker, const TrackerTopology &tTopo, const DetId &id)
std::vector< unsigned int > see_nStrip
std::vector< float > trk_px
constexpr bool isNotFinite(T x)
Definition: isFinite.h:9
range equal_range(const OmniClusterRef &key) const
std::vector< unsigned short > pix_simType
void push_back(const TrackerGeometry &tracker, const TrackerTopology &tTopo, const DetId &id)
std::vector< unsigned short > inv_type
std::vector< float > see_stateTrajPz
SiPixelCluster const & pixelCluster() const
std::vector< float > pix_zx
std::vector< std::vector< float > > ph2_onTrk_zx
SimHitData matchCluster(const OmniClusterRef &cluster, DetId hitId, int clusterKey, const TrackingRecHit &hit, const ClusterTPAssociation &clusterToTPMap, const TrackingParticleRefKeyToIndex &tpKeyToIndex, const SimHitTPAssociationProducer::SimHitTPAssociationList &simHitsTPAssoc, const edm::DetSetVector< SimLink > &digiSimLinks, const SimHitRefKeyToIndex &simHitRefKeyToIndex, HitType hitType)
ret
prodAgent to be discontinued
TPHitIndex(unsigned int tp=0, unsigned int simHit=0, float to=0, unsigned int id=0)
std::vector< float > sim_phi
std::vector< unsigned int > tcand_algo
std::vector< std::vector< int > > trk_simTrkIdx
std::vector< float > trk_dzPV
ROOT::Math::SMatrixIdentity AlgebraicMatrixID
edm::EDGetTokenT< reco::TrackToTrackingParticleAssociator > trackAssociatorToken_
edm::EDGetTokenT< SiStripRecHit2DCollection > stripStereoRecHitToken_
std::vector< float > trk_dxyErr
std::vector< float > str_yz
std::vector< float > trk_pt
std::vector< float > glu_x
std::vector< float > tcand_bestFromFirstHitSimTrkShareFracSimDenom
std::vector< float > trk_inner_py
std::vector< float > see_px
std::vector< float > see_chi2
void fillStripRphiStereoHits(const edm::Event &iEvent, const TrackerGeometry &tracker, const ClusterTPAssociation &clusterToTPMap, const TrackingParticleRefKeyToIndex &tpKeyToIndex, const SimHitTPAssociationProducer::SimHitTPAssociationList &simHitsTPAssoc, const edm::DetSetVector< StripDigiSimLink > &digiSimLink, const TrackerTopology &tTopo, const SimHitRefKeyToIndex &simHitRefKeyToIndex, std::set< edm::ProductID > &hitProductIds)
T const * product() const
Definition: Handle.h:70
std::vector< float > simhit_px
std::vector< float > glu_z
std::vector< float > see_stateTrajY
edm::EDGetTokenT< edm::View< reco::Track > > trackToken_
float chargePerCM(DetId detid, Iter a, Iter b)
const GlobalTrajectoryParameters & globalParameters() const
constexpr bool isUninitialized() const noexcept
Definition: EDGetToken.h:104
const bool includeOnTrackHitData_
CombineDetId< DetIdCommon, DetIdPixelOnly, DetIdOTCommon, DetIdPhase2OTOnly > DetIdAllPhase2
CombineDetId< DetIdCommon, DetIdPixelOnly > DetIdPixel
Global3DPoint GlobalPoint
Definition: GlobalPoint.h:10
void fillCandidates(const edm::Handle< TrackCandidateCollection > &candsHandle, int algo, const TrackingParticleRefVector &tpCollection, const TrackingParticleRefKeyToIndex &tpKeyToIndex, const TrackingParticleRefKeyToCount &tpKeyToClusterCount, const MagneticField &mf, const reco::BeamSpot &bs, const reco::VertexCollection &vertices, const reco::TrackToTrackingParticleAssociator &associatorByHits, const ClusterTPAssociation &clusterToTPMap, const TrackerGeometry &tracker, const TrackerTopology &tTopo, const std::set< edm::ProductID > &hitProductIds, const std::map< edm::ProductID, size_t > &seedToCollIndex)
void fillBeamSpot(const reco::BeamSpot &bs)
std::vector< unsigned short > see_stopReason
std::vector< float > tcand_pca_ptErr
std::vector< float > trk_outer_px
std::vector< std::vector< int > > trk_hitType
OmniClusterRef const & stereoClusterRef() const
void fillTracks(const edm::RefToBaseVector< reco::Track > &tracks, const TrackerGeometry &tracker, const TrackingParticleRefVector &tpCollection, const TrackingParticleRefKeyToIndex &tpKeyToIndex, const TrackingParticleRefKeyToCount &tpKeyToClusterCount, const MagneticField &mf, const reco::BeamSpot &bs, const reco::VertexCollection &vertices, const reco::TrackToTrackingParticleAssociator &associatorByHits, const ClusterTPAssociation &clusterToTPMap, const TrackerTopology &tTopo, const std::set< edm::ProductID > &hitProductIds, const std::map< edm::ProductID, size_t > &seedToCollIndex, const std::vector< const MVACollection *> &mvaColls, const std::vector< const QualityMaskCollection *> &qualColls)
std::vector< unsigned int > trk_nCluster
DetIdPixel pix_detId
std::vector< float > ph2_xx
unsigned int tibString(const DetId &id) const
std::vector< std::vector< float > > pix_onTrk_z
unsigned long long EventNumber_t
std::vector< std::vector< int > > ph2_trkIdx
#define BOOK(name)
edm::EDGetTokenT< Phase2TrackerRecHit1DCollectionNew > phase2OTRecHitToken_
void push_back(const TrackerGeometry &tracker, const TrackerTopology &tTopo, const DetId &id)
std::vector< OmniClusterRef > hitsToClusterRefs(iter begin, iter end)
std::vector< unsigned int > see_algo
std::vector< unsigned int > tcand_nStrip
const bool addSeedCurvCov_
const edm::ESGetToken< TrackerTopology, TrackerTopologyRcd > tTopoToken_
std::vector< Vertex > VertexCollection
collection of Vertex objects
Definition: VertexFwd.h:9
std::vector< float > tcand_bestSimTrkShareFrac
std::vector< float > trk_inner_pt
std::vector< short > simhit_process
std::vector< unsigned short > module
std::vector< float > trk_bestSimTrkShareFracSimClusterDenom
CombineDetId< DetIdCommon, DetIdOTCommon, DetIdPhase2OTOnly > DetIdPhase2OT
std::vector< std::vector< float > > str_onTrk_xx
std::vector< float > tcand_pca_dxy
std::vector< std::vector< int > > str_seeIdx
std::vector< std::vector< int > > see_simTrkIdx
std::vector< int > simvtx_event
std::vector< float > str_radL
void fillSeeds(const edm::Event &iEvent, const TrackingParticleRefVector &tpCollection, const TrackingParticleRefKeyToIndex &tpKeyToIndex, const reco::BeamSpot &bs, const TrackerGeometry &tracker, const reco::TrackToTrackingParticleAssociator &associatorByHits, const ClusterTPAssociation &clusterToTPMap, const MagneticField &theMF, const TrackerTopology &tTopo, std::vector< std::pair< int, int >> &monoStereoClusterList, const std::set< edm::ProductID > &hitProductIds, std::map< edm::ProductID, size_t > &seedToCollIndex)
bool isStereo(const DetId &id) const
std::vector< int > simhit_simTrkIdx
bool isRPhi(const DetId &id) const
std::vector< unsigned short > trk_stopReason
value_type const at(size_type idx) const
Retrieve an element of the RefVector.
Definition: RefVector.h:83
std::vector< uint64_t > glu_usedMaskStereo
unsigned int pxbLadder(const DetId &id) const
std::vector< unsigned short > ladder
static bool tpHitIndexListLess(const TPHitIndex &i, const TPHitIndex &j)
TrackingNtuple(const edm::ParameterSet &)
std::vector< float > tcand_pca_eta
auto vector_transform(std::vector< InputType > const &input, Function predicate) -> std::vector< typename std::remove_cv< typename std::remove_reference< decltype(predicate(input.front()))>::type >::type >
Definition: transform.h:11
std::ostream & operator<<(std::ostream &out, const ALILine &li)
Definition: ALILine.cc:167
std::vector< float > sim_py
unsigned int side(const DetId &id) const
void find(edm::Handle< EcalRecHitCollection > &hits, DetId thisDet, std::vector< EcalRecHitCollection::const_iterator > &hit, bool debug=false)
Definition: FindCaloHit.cc:19
std::vector< Vertex > VertexCollection
Definition: Vertex.h:31
size_type size() const
assert(be >=bs)
std::vector< float > sim_px
constexpr Detector det() const
get the detector field from this detid
Definition: DetId.h:46
unsigned int LuminosityBlockNumber_t
std::vector< float > pix_xx
unsigned int tecRing(const DetId &id) const
ring id
std::vector< std::vector< int > > sim_decayVtxIdx
std::vector< float > trk_refpoint_x
std::vector< float > pix_radL
std::vector< float > xySignificance
std::vector< float > pix_bbxi
std::vector< std::vector< float > > sim_trkShareFrac
OmniClusterRef const & monoClusterRef() const
std::vector< std::vector< float > > trk_mvas
key_type key() const
Accessor for product key.
Definition: Ref.h:250
bool tobIsDoubleSide(const DetId &id) const
std::vector< float > ph2_zx
std::vector< float > tcand_pca_dzErr
std::vector< int > simpv_idx
std::vector< unsigned char > QualityMaskCollection
const_iterator find(const key_type &k) const
find element with specified reference key
static std::string to_string(const XMLCh *ch)
edm::EDGetTokenT< edm::DetSetVector< PixelDigiSimLink > > pixelSimLinkToken_
unsigned int layer(const DetId &id) const
TrackAlgorithm
track algorithm
Definition: TrackBase.h:89
#define LogTrace(id)
edm::ProductID id() const
CombineDetId< DetIdCommon, DetIdPixelOnly, DetIdOTCommon, DetIdStripOnly > DetIdAll
std::vector< std::vector< float > > str_xySignificance
Parsed parse(const TrackerTopology &tTopo, const DetId &id) const
const_iterator end(bool update=false) const
std::vector< std::vector< int > > pix_seeIdx
std::vector< unsigned short > str_simType
std::vector< int > sim_q
std::vector< short > see_isTrue
const_iterator end() const
last iterator over the map (read only)
std::vector< short > inv_isBarrel
T getUntrackedParameter(std::string const &, T const &) const
std::vector< SimHitTPPair > SimHitTPAssociationList
std::vector< float > trk_bestSimTrkShareFracSimDenom
std::vector< unsigned short > ring
std::vector< float > trk_bestFromFirstHitSimTrkNChi2
math::XYZPointD Point
point in the space
std::vector< float > see_etaErr
std::vector< std::vector< float > > trk_simTrkShareFrac
ClusterPixelRef cluster_pixel() const
unsigned int module(const DetId &id) const
std::vector< float > simhit_z
std::vector< float > tcand_qbpErr
std::vector< float > ph2_z
std::vector< float > ph2_yy
std::vector< float > tcand_pz
std::vector< float > tcand_phiErr
std::vector< unsigned int > tcand_nPixel
std::vector< float > tcand_pca_etaErr
std::vector< float > trk_refpoint_y
std::vector< unsigned int > trk_nLostLay
std::vector< float > MVACollection
std::vector< int > sim_event
char const * label
std::vector< unsigned int > trk_nStrip
std::vector< unsigned int > tcand_nCluster
std::vector< const reco::GenParticle * > RecoGenParticleTrail
reco::GenParticle trail type.
Definition: HistoryBase.h:18
std::vector< int > see_bestSimTrkIdx
std::vector< float > chargeFraction
edm::EDGetTokenT< edm::ValueMap< unsigned int > > tpNStripStereoLayersToken_
std::vector< float > see_stateTrajGlbPz
std::vector< unsigned int > trk_nPixel
std::vector< float > glu_y
VParameterSet getUntrackedParameterSetVector(std::string const &name, VParameterSet const &defaultValue) const
std::vector< std::vector< float > > pix_xySignificance
std::vector< unsigned short > panel
std::vector< float > trk_pz
std::vector< std::vector< float > > pix_onTrk_yz
int iEvent
Definition: GenABIO.cc:224
std::vector< float > tcand_z
std::vector< float > trk_dzErr
std::vector< unsigned short > isStereo
std::vector< unsigned short > tcand_stopReason
std::vector< float > tcand_pca_pt
std::vector< float > trk_lambdaErr
std::vector< unsigned short > isUpper
std::vector< std::vector< float > > pix_onTrk_zz
void push_back(const TrackerGeometry &tracker, const TrackerTopology &tTopo, const DetId &id)
std::vector< std::vector< float > > see_stateCurvCov
std::vector< unsigned int > see_nCluster
edm::EDGetTokenT< SiPixelRecHitCollection > pixelRecHitToken_
std::vector< float > ph2_y
std::vector< std::tuple< edm::EDGetTokenT< MVACollection >, edm::EDGetTokenT< QualityMaskCollection > > > mvaQualityCollectionTokens_
unsigned int tidOrder(const DetId &id) const
std::vector< std::vector< int > > simvtx_sourceSimIdx
std::vector< int > tcand_vtxIdx
std::vector< float > trk_bestFromFirstHitSimTrkShareFracSimDenom
std::vector< float > trk_etaErr
void fillPhase2OTHits(const edm::Event &iEvent, const ClusterTPAssociation &clusterToTPMap, const TrackerGeometry &tracker, const TrackingParticleRefKeyToIndex &tpKeyToIndex, const SimHitTPAssociationProducer::SimHitTPAssociationList &simHitsTPAssoc, const edm::DetSetVector< PixelDigiSimLink > &digiSimLink, const TrackerTopology &tTopo, const SimHitRefKeyToIndex &simHitRefKeyToIndex, std::set< edm::ProductID > &hitProductIds)
std::vector< short > pix_isBarrel
std::vector< std::vector< float > > str_onTrk_z
edm::EDGetTokenT< edm::DetSetVector< PixelDigiSimLink > > siphase2OTSimLinksToken_
std::vector< float > tcand_xtErr
std::vector< float > glu_yz
std::vector< float > sim_pca_phi
virtual const Surface * surface() const
std::vector< int > pix_clustSizeCol
auto dz(const T_Vertex &vertex, const T_Momentum &momentum, const T_Point &point)
SiStripCluster const & amplitudes() const
std::vector< unsigned int > trk_algo
std::vector< unsigned int > sim_nRecoClusters
std::vector< int > see_tcandIdx
std::vector< float > tcand_y
void fillTrackingParticlesForSeeds(const TrackingParticleRefVector &tpCollection, const reco::SimToRecoCollection &simRecColl, const TrackingParticleRefKeyToIndex &tpKeyToIndex, const unsigned int seedOffset)
std::vector< float > ph2_xy
T sqrt(T t)
Definition: SSEVec.h:23
auto size() const
std::vector< float > trk_bestFromFirstHitSimTrkShareFracSimClusterDenom
std::vector< float > vtx_y
std::vector< float > pix_z
std::vector< int > see_bestFromFirstHitSimTrkIdx
std::vector< int > bunchCrossing
std::vector< float > sim_eta
std::vector< unsigned short > blade
std::vector< unsigned int > trk_originalAlgo
std::vector< unsigned int > trk_nInnerLost
std::vector< float > str_y
std::vector< std::pair< unsigned int, edm::EDGetTokenT< Phase2OTMaskContainer > > > ph2OTUseMaskTokens_
std::vector< int > sim_pdgId
std::vector< int > see_q
std::vector< std::vector< float > > pix_onTrk_zx
std::vector< std::vector< int > > simhit_hitType
std::vector< float > trk_refpoint_z
std::vector< unsigned int > trk_nInactive
std::vector< edm::EDGetTokenT< edm::View< reco::Track > > > seedTokens_
edm::EDGetTokenT< SimHitTPAssociationProducer::SimHitTPAssociationList > simHitTPMapToken_
std::vector< unsigned int > trk_nOuterInactive
std::vector< float > pix_yz
std::vector< std::vector< int > > sim_genPdgIds
std::vector< int > trk_seedIdx
std::vector< std::vector< float > > pix_chargeFraction
edm::RunNumber_t ev_run
std::vector< std::vector< int > > tcand_hitType
std::vector< float > vtx_yErr
std::vector< std::vector< int > > pix_trkIdx
Phase2TrackerCluster1D const & phase2OTCluster() const
void print(TMatrixD &m, const char *label=nullptr, bool mathematicaFormat=false)
Definition: Utilities.cc:47
Tan< T >::type tan(const T &t)
Definition: Tan.h:22
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
std::vector< unsigned int > sim_nValid
std::vector< float > glu_yy
std::vector< float > vtx_ndof
std::vector< std::vector< int > > ph2_simHitIdx
std::vector< float > simvtx_x
std::vector< std::vector< float > > ph2_onTrk_x
unsigned int operator[](size_t i) const
std::vector< float > str_zz
std::vector< std::vector< int > > tcand_simTrkIdx
DetIdAllPhase2 inv_detId_phase2
std::vector< float > tcand_pca_lambdaErr
std::vector< std::vector< float > > str_onTrk_y
std::vector< std::vector< float > > pix_onTrk_xx
std::vector< float > sim_pca_pt
key
prepare the HTCondor submission files and eventually submit them
DetIdPhase2OT ph2_detId
std::vector< float > see_dxyErr
std::vector< float > tcand_bestFromFirstHitSimTrkShareFrac
bool isMatched(TrackingRecHit const &hit)
std::vector< float > trk_bestFromFirstHitSimTrkShareFrac
std::vector< short > tcand_pca_valid
uint32_t stack(const DetId &id) const
#define DEFINE_FWK_MODULE(type)
Definition: MakerMacros.h:16
std::vector< float > see_pt
std::vector< unsigned int > see_nPhase2OT
constexpr int subdetId() const
get the contents of the subdetector field (not cast into any detector&#39;s numbering enum) ...
Definition: DetId.h:48
edm::EDGetTokenT< TrackingVertexCollection > trackingVertexToken_
std::vector< float > see_dxy
std::vector< std::vector< int > > glu_seeIdx
std::vector< unsigned int > trk_n3DLay
std::vector< std::vector< int > > sim_trkIdx
Definition: Types.py:1
std::vector< float > trk_outer_pt
void fillStripMatchedHits(const edm::Event &iEvent, const TrackerGeometry &tracker, const TrackerTopology &tTopo, std::vector< std::pair< int, int >> &monoStereoClusterList)
static bool tpHitIndexListLessSort(const TPHitIndex &i, const TPHitIndex &j)
std::vector< int > matchingSimHit
unsigned int tecOrder(const DetId &id) const
std::vector< float > str_chargePerCM
const bool includeSeeds_
const bool includeTrackingParticles_
std::vector< float > trk_dz
static constexpr auto TOB
size_t addStripMatchedHit(const SiStripMatchedRecHit2D &hit, const TrackerGeometry &tracker, const TrackerTopology &tTopo, const std::vector< std::pair< uint64_t, StripMaskContainer const *>> &stripMasks, std::vector< std::pair< int, int >> &monoStereoClusterList)
std::vector< float > trk_ptErr
std::vector< unsigned int > trk_nStripLay
void fillSimHits(const TrackerGeometry &tracker, const TrackingParticleRefKeyToIndex &tpKeyToIndex, const SimHitTPAssociationProducer::SimHitTPAssociationList &simHitsTPAssoc, const TrackerTopology &tTopo, SimHitRefKeyToIndex &simHitRefKeyToIndex, std::vector< TPHitIndex > &tpHitList)
std::vector< float > see_phi
const edm::ESGetToken< TrackerGeometry, TrackerDigiGeometryRecord > tGeomToken_
std::vector< float > vtx_z
char const * module
Definition: ProductLabels.h:5
Log< level::Warning, true > LogPrint
std::vector< float > see_pz
void fillTrackingParticles(const edm::Event &iEvent, const edm::EventSetup &iSetup, const edm::RefToBaseVector< reco::Track > &tracks, const reco::BeamSpot &bs, const TrackingParticleRefVector &tpCollection, const TrackingVertexRefKeyToIndex &tvKeyToIndex, const reco::TrackToTrackingParticleAssociator &associatorByHits, const std::vector< TPHitIndex > &tpHitList, const TrackingParticleRefKeyToCount &tpKeyToClusterCount)
void book(const std::string &prefix, TTree *tree)
std::vector< float > trk_phiErr
std::vector< unsigned int > sim_nPixelLay
std::vector< float > trk_lambda
std::vector< edm::EDGetTokenT< std::vector< SeedStopInfo > > > seedStopInfoTokens_
iterator end()
Return the off-the-end iterator.
Definition: DetSetVector.h:316
std::vector< float > glu_zz
std::vector< float > tcand_bestSimTrkNChi2
std::vector< float > sim_pca_lambda
virtual TrackingParticle::Vector momentum(const edm::Event &iEvent, const edm::EventSetup &iSetup, const Charge ch, const Point &vtx, const LorentzVector &lv) const
std::vector< float > see_stateTrajPx
std::vector< float > glu_zx
std::vector< std::vector< float > > str_onTrk_zx
std::string algoName() const
Definition: TrackBase.h:550
std::vector< int > tcand_seedIdx
#define M_PI
const bool saveSimHitsP3_
std::vector< std::vector< float > > str_onTrk_x
Definition: RZLine.h:12
std::vector< float > vtx_xErr
std::vector< float > tcand_bestSimTrkShareFracSimDenom
std::vector< std::vector< float > > tcand_simTrkShareFrac
static void fillDescriptions(edm::ConfigurationDescriptions &descriptions)
std::vector< float > tcand_pt
std::vector< uint64_t > ph2_usedMask
unsigned int id
std::vector< float > sim_pz
std::vector< float > see_stateTrajGlbY
std::vector< int > event
std::vector< std::vector< int > > sim_simHitIdx
unsigned int pxfPanel(const DetId &id) const
edm::Ref< TrackingVertexCollection > TrackingVertexRef
std::vector< unsigned short > isGlued
const edm::ESGetToken< MagneticField, IdealMagneticFieldRecord > mfToken_
edm::EventNumber_t ev_event
std::vector< float > tcand_bestFromFirstHitSimTrkShareFracSimClusterDenom
Definition: DetId.h:17
std::vector< unsigned short > isRPhi
std::vector< float > ph2_x
edm::EDGetTokenT< reco::VertexCollection > vertexToken_
edm::EDGetTokenT< TrackingParticleCollection > trackingParticleToken_
std::vector< uint64_t > pix_usedMask
bool isLower(const DetId &id) const
std::vector< uint64_t > glu_usedMaskMono
std::vector< int > glu_stereoIdx
Phase2Cluster1DRef cluster_phase2OT() const
std::vector< float > trk_py
static constexpr auto TIB
const_iterator begin(bool update=false) const
std::vector< std::vector< int > > pix_simHitIdx
size_type size() const
Size of the RefVector.
Definition: RefVector.h:102
std::vector< float > trk_nChi2
TrajectoryStateOnSurface transientState(const PTrajectoryStateOnDet &ts, const Surface *surface, const MagneticField *field)
const CurvilinearTrajectoryError & curvilinearError() const
std::vector< std::vector< unsigned short > > trk_qualityMasks
void book(const std::string &prefix, TTree *tree)
unsigned long long uint64_t
Definition: Time.h:13
std::vector< unsigned int > see_nGlued
std::vector< float > see_py
std::vector< float > pix_x
std::vector< unsigned int > detId
std::vector< int > sim_parentVtxIdx
std::vector< float > see_ptErr
const bool includeMVA_
std::vector< float > str_z
std::vector< unsigned short > isStack
XYZVectorD XYZVector
spatial vector with cartesian internal representation
Definition: Vector3D.h:31
void addUntrackedParameter(std::string const &name, T const &value)
Definition: ParameterSet.h:193
std::vector< short > tcand_isTrue
std::vector< float > str_zx
const bool includeTrackCandidates_
std::vector< std::vector< int > > tcand_hitIdx
constexpr uint32_t rawId() const
get the raw id
Definition: DetId.h:57
XYZPointD XYZPoint
point in space with cartesian internal representation
Definition: Point3D.h:12
int size() const
virtual OmniClusterRef const & firstClusterRef() const =0
std::vector< float > tcand_pca_dz
const AlgebraicSymMatrix55 & matrix() const
std::vector< TrackingVertex > TrackingVertexCollection
HistoryBase tracer_
std::vector< int > glu_clustSizeStereo
std::vector< float > tcand_bestSimTrkShareFracSimClusterDenom
std::vector< short > trk_isHP
std::vector< float > str_xy
virtual TrackingParticle::Point vertex(const edm::Event &iEvent, const edm::EventSetup &iSetup, const Charge ch, const Point &vtx, const LorentzVector &lv) const
std::vector< std::vector< float > > str_chargeFraction
float chi2() const
Definition: RZLine.h:95
void add(std::string const &label, ParameterSetDescription const &psetDescription)
~TrackingNtuple() override
std::vector< unsigned int > trk_nInnerInactive
std::vector< float > tcand_pca_py
std::vector< float > tcand_pca_dxyErr
std::vector< unsigned short > isLower
std::vector< std::pair< unsigned int, edm::EDGetTokenT< StripMaskContainer > > > stripUseMaskTokens_
unsigned int tobRod(const DetId &id) const
Base class to all the history types.
Definition: HistoryBase.h:12
std::vector< std::vector< float > > ph2_xySignificance
std::vector< std::vector< int > > trk_hitIdx
deadvectors [0] push_back({0.0175431, 0.538005, 6.80997, 13.29})
std::vector< std::vector< int > > str_tcandIdx
std::vector< int > trk_q
std::vector< unsigned int > sim_nPixel
std::vector< std::vector< float > > pix_onTrk_xy
const bool includeAllHits_
std::vector< short > vtx_valid
std::vector< float > see_stateTrajGlbX
bool evaluate(TrackingParticleRef tpr)
Evaluate track history using a TrackingParticleRef.
Definition: HistoryBase.h:96
edm::EDGetTokenT< ClusterTPAssociation > clusterTPMapToken_
std::vector< std::vector< float > > ph2_onTrk_xy
Pixel cluster – collection of neighboring pixels above threshold.
std::vector< unsigned int > tcand_nValid
fixed size matrix
std::vector< int > tcand_q
std::vector< std::vector< int > > vtx_trkIdx
HLT enums.
std::vector< short > str_isBarrel
auto dxy(const T_Vertex &vertex, const T_Momentum &momentum, const T_Point &point)
void analyze(const edm::Event &, const edm::EventSetup &) override
void depth(int d)
Set the depth of the history.
Definition: HistoryBase.h:49
Structure Point Contains parameters of Gaussian fits to DMRs.
std::vector< int > str_clustSize
std::vector< float > glu_bbxi
std::vector< int > simhit_particle
std::vector< float > tcand_ndof
SiStripCluster const & stripCluster() const
std::vector< float > trk_outer_pz
edm::EDGetTokenT< edm::ValueMap< unsigned int > > tpNLayersToken_
std::vector< unsigned short > ph2_simType
std::vector< std::pair< unsigned int, edm::EDGetTokenT< PixelMaskContainer > > > pixelUseMaskTokens_
std::vector< std::vector< float > > ph2_onTrk_z
std::vector< float > sim_pca_eta
void push_back(const RefToBase< T > &)
std::vector< float > ph2_yz
std::vector< unsigned short > string
Point getBestVertex(reco::Track const &trk, reco::VertexCollection const &vertices, const size_t minNtracks=2)
Definition: getBestVertex.h:8
std::vector< int > glu_clustSizeMono
static int pixelToChannel(int row, int col)
ParametersDefinerForTP parametersDefiner_
edm::EDGetTokenT< reco::BeamSpot > beamSpotToken_
std::vector< unsigned short > rod
static TrackAlgorithm algoByName(const std::string &name)
Definition: TrackBase.cc:137
std::vector< float > simhit_y
void push_back(value_type const &ref)
Add a Ref<C, T> to the RefVector.
Definition: RefVector.h:67
std::vector< float > trk_dxyClosestPV
std::vector< float > see_stateTrajGlbPx
edm::Ref< edm::PSimHitContainer > TrackPSimHitRef
std::vector< std::vector< int > > str_simHitIdx
unsigned int tidRing(const DetId &id) const
std::vector< float > see_statePt
std::string builderName_
std::vector< float > tcand_lambdaErr
std::vector< float > trk_ndof
std::vector< float > glu_xx
Monte Carlo truth information used for tracking validation.
const bool keepEleSimHits_
edm::EDGetTokenT< edm::ValueMap< unsigned int > > tpNPixelLayersToken_
std::vector< std::vector< float > > pix_onTrk_yy
std::vector< std::vector< int > > ph2_tcandIdx
ParameterVector parameters() const
Track parameters with one-to-one correspondence to the covariance matrix.
Definition: TrackBase.h:711
std::vector< unsigned int > trk_nPixelLay
std::vector< float > see_stateTrajGlbZ
std::vector< std::vector< float > > str_onTrk_xy
std::vector< float > simhit_x
std::vector< float > tcand_pca_px
std::vector< int > tcand_bestFromFirstHitSimTrkIdx
std::vector< float > simvtx_y
std::vector< unsigned short > see_nCands
std::vector< std::vector< int > > simvtx_daughterSimIdx
std::vector< float > str_xx
#define declareDynArray(T, n, x)
Definition: DynArray.h:91
unsigned int RunNumber_t
std::vector< float > trk_bestSimTrkShareFrac
std::vector< float > simhit_py
std::vector< unsigned int > see_offset
RecoGenParticleTrail const & recoGenParticleTrail() const
Return all reco::GenParticle in the history.
Definition: HistoryBase.h:64
unsigned int key() const
Definition: tree.py:1
std::vector< std::vector< float > > pix_onTrk_y
std::vector< float > ph2_zz
void clear(EGIsoObj &c)
Definition: egamma.h:82
void book(const std::string &prefix, TTree *tree)
std::vector< float > tcand_bestFromFirstHitSimTrkNChi2
Parsed parse(const TrackerTopology &tTopo, const DetId &id) const
std::vector< int > see_trkIdx
static uInt32 F(BLOWFISH_CTX *ctx, uInt32 x)
Definition: blowfish.cc:163
math::XYZVectorD Vector
point in the space
TupleMultiplicity< TrackerTraits > const *__restrict__ uint32_t nHits
std::vector< int > tcand_bestSimTrkIdx
std::vector< float > tcand_x
std::vector< unsigned short > side
std::vector< std::vector< float > > ph2_onTrk_zz
std::vector< std::vector< int > > pix_tcandIdx
std::vector< float > simhit_tof
std::vector< std::vector< int > > sim_seedIdx
void fillVertices(const reco::VertexCollection &vertices, const edm::RefToBaseVector< reco::Track > &tracks)
T operator[](int i) const
std::vector< float > see_stateTrajGlbPy
std::vector< float > pix_xy
std::vector< unsigned short > subdet
std::vector< float > trk_dxy
void book(const std::string &prefix, TTree *tree)
std::vector< float > sim_pt
std::vector< float > pix_yy
double trackAssociationChi2(const reco::TrackBase::ParameterVector &rParameters, const reco::TrackBase::CovarianceMatrix &recoTrackCovMatrix, const reco::TrackBase::ParameterVector &sParameters)
basic method where chi2 is computed
std::vector< float > tcand_pca_phi
static constexpr auto TID
std::vector< decltype(reco::TrackBase().algoMaskUL())> trk_algoMask
std::vector< std::vector< int > > see_hitIdx
std::vector< std::vector< float > > str_onTrk_zz
std::vector< float > tcand_px
std::vector< float > vtx_x
std::vector< std::vector< float > > str_onTrk_yy
std::vector< float > simhit_pz
std::vector< std::vector< float > > tcand_simTrkNChi2
std::vector< unsigned int > see_nPixel
edm::Ref< TrackingParticleCollection > TrackingParticleRef
std::vector< unsigned short > petalNumber
std::vector< float > see_eta
DetIdAllPhase2 simhit_detId_phase2
std::vector< unsigned int > trk_nValid
std::vector< unsigned int > trk_nLost
std::vector< float > trk_inner_px
DetIdStrip glu_detId
def move(src, dest)
Definition: eostools.py:511
std::vector< float > vtx_zErr
std::vector< float > simhit_eloss
std::vector< float > see_bestFromFirstHitSimTrkShareFrac
std::vector< std::vector< float > > ph2_onTrk_yy
Definition: event.py:1
void labelsForToken(EDGetToken iToken, Labels &oLabels) const
std::vector< int > sim_isFromBHadron
std::vector< std::vector< float > > ph2_onTrk_xx
edm::EDGetTokenT< edm::DetSetVector< StripDigiSimLink > > stripSimLinkToken_
math::Error< dimension >::type CovarianceMatrix
5 parameter covariance matrix
Definition: TrackBase.h:74
uint16_t *__restrict__ uint16_t const *__restrict__ adc
std::vector< float > tcand_py
std::vector< int > pix_clustSizeRow
std::vector< edm::EDGetTokenT< TrackCandidateCollection > > candidateTokens_
std::vector< float > vtx_chi2
std::vector< int > simvtx_bunchCrossing
std::vector< float > str_bbxi
std::vector< float > see_dz
#define LogDebug(id)
std::vector< unsigned int > sim_nStrip