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MultiTrackSelector.cc
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1 #include "MultiTrackSelector.h"
2 
8 
9 #include <Math/DistFunc.h>
10 #include <TMath.h>
11 #include <TFile.h>
12 
13 #include "powN.h"
14 
15 using namespace reco;
16 
18 {
19  useForestFromDB_ = true;
20 }
21 
23  src_( consumes<reco::TrackCollection>( cfg.getParameter<edm::InputTag>( "src" ) ) ),
24  hSrc_(consumes<TrackingRecHitCollection>( cfg.getParameter<edm::InputTag>( "src" ) ) ),
25  beamspot_( consumes<reco::BeamSpot>( cfg.getParameter<edm::InputTag>( "beamspot" ) ) ),
26  useVertices_( cfg.getParameter<bool>( "useVertices" ) ),
27  useVtxError_( cfg.getParameter<bool>( "useVtxError" ) )
28  // now get the pset for each selector
29 {
30  if (useVertices_) vertices_ = consumes<reco::VertexCollection>(cfg.getParameter<edm::InputTag>( "vertices" ));
31  if(useVtxError_){
32  edm::LogWarning("MultiTRackSelector") << "you are executing buggy code, if intentional please help to fix it";
33  }
34  useAnyMVA_ = false;
35  useForestFromDB_ = true;
36  dbFileName_ = "";
37 
38  if(cfg.exists("useAnyMVA")) useAnyMVA_ = cfg.getParameter<bool>("useAnyMVA");
39 
40  if(useAnyMVA_){
41  if(cfg.exists("GBRForestFileName")){
42  dbFileName_ = cfg.getParameter<std::string>("GBRForestFileName");
43  useForestFromDB_ = false;
44  }
45  }
46  std::vector<edm::ParameterSet> trkSelectors( cfg.getParameter<std::vector< edm::ParameterSet> >("trackSelectors") );
47  qualityToSet_.reserve(trkSelectors.size());
48  vtxNumber_.reserve(trkSelectors.size());
49  vertexCut_.reserve(trkSelectors.size());
50  res_par_.reserve(trkSelectors.size());
51  chi2n_par_.reserve(trkSelectors.size());
52  chi2n_no1Dmod_par_.reserve(trkSelectors.size());
53  d0_par1_.reserve(trkSelectors.size());
54  dz_par1_.reserve(trkSelectors.size());
55  d0_par2_.reserve(trkSelectors.size());
56  dz_par2_.reserve(trkSelectors.size());
57  applyAdaptedPVCuts_.reserve(trkSelectors.size());
58  max_d0_.reserve(trkSelectors.size());
59  max_z0_.reserve(trkSelectors.size());
60  nSigmaZ_.reserve(trkSelectors.size());
61  min_layers_.reserve(trkSelectors.size());
62  min_3Dlayers_.reserve(trkSelectors.size());
63  max_lostLayers_.reserve(trkSelectors.size());
64  min_hits_bypass_.reserve(trkSelectors.size());
65  applyAbsCutsIfNoPV_.reserve(trkSelectors.size());
66  max_d0NoPV_.reserve(trkSelectors.size());
67  max_z0NoPV_.reserve(trkSelectors.size());
68  preFilter_.reserve(trkSelectors.size());
69  max_relpterr_.reserve(trkSelectors.size());
70  min_nhits_.reserve(trkSelectors.size());
71  max_minMissHitOutOrIn_.reserve(trkSelectors.size());
72  max_lostHitFraction_.reserve(trkSelectors.size());
73  min_eta_.reserve(trkSelectors.size());
74  max_eta_.reserve(trkSelectors.size());
75  useMVA_.reserve(trkSelectors.size());
76  useMVAonly_.reserve(trkSelectors.size());
77  //mvaReaders_.reserve(trkSelectors.size());
78  min_MVA_.reserve(trkSelectors.size());
79  mvaType_.reserve(trkSelectors.size());
80  forestLabel_.reserve(trkSelectors.size());
81  forest_.reserve(trkSelectors.size());
82 
83  produces<edm::ValueMap<float> >("MVAVals");
84 
85  //foward compatibility
86  produces<MVACollection>("MVAValues");
87 
88 
89  for ( unsigned int i=0; i<trkSelectors.size(); i++) {
90 
91  qualityToSet_.push_back( TrackBase::undefQuality );
92  // parameters for vertex selection
93  vtxNumber_.push_back( useVertices_ ? trkSelectors[i].getParameter<int32_t>("vtxNumber") : 0 );
94  vertexCut_.push_back( useVertices_ ? trkSelectors[i].getParameter<std::string>("vertexCut") : nullptr);
95  // parameters for adapted optimal cuts on chi2 and primary vertex compatibility
96  res_par_.push_back(trkSelectors[i].getParameter< std::vector<double> >("res_par") );
97  chi2n_par_.push_back( trkSelectors[i].getParameter<double>("chi2n_par") );
98  chi2n_no1Dmod_par_.push_back( trkSelectors[i].getParameter<double>("chi2n_no1Dmod_par") );
99  d0_par1_.push_back(trkSelectors[i].getParameter< std::vector<double> >("d0_par1"));
100  dz_par1_.push_back(trkSelectors[i].getParameter< std::vector<double> >("dz_par1"));
101  d0_par2_.push_back(trkSelectors[i].getParameter< std::vector<double> >("d0_par2"));
102  dz_par2_.push_back(trkSelectors[i].getParameter< std::vector<double> >("dz_par2"));
103  // Boolean indicating if adapted primary vertex compatibility cuts are to be applied.
104  applyAdaptedPVCuts_.push_back(trkSelectors[i].getParameter<bool>("applyAdaptedPVCuts"));
105  // Impact parameter absolute cuts.
106  max_d0_.push_back(trkSelectors[i].getParameter<double>("max_d0"));
107  max_z0_.push_back(trkSelectors[i].getParameter<double>("max_z0"));
108  nSigmaZ_.push_back(trkSelectors[i].getParameter<double>("nSigmaZ"));
109  // Cuts on numbers of layers with hits/3D hits/lost hits.
110  min_layers_.push_back(trkSelectors[i].getParameter<uint32_t>("minNumberLayers") );
111  min_3Dlayers_.push_back(trkSelectors[i].getParameter<uint32_t>("minNumber3DLayers") );
112  max_lostLayers_.push_back(trkSelectors[i].getParameter<uint32_t>("maxNumberLostLayers"));
113  min_hits_bypass_.push_back(trkSelectors[i].getParameter<uint32_t>("minHitsToBypassChecks"));
114  // Flag to apply absolute cuts if no PV passes the selection
115  applyAbsCutsIfNoPV_.push_back(trkSelectors[i].getParameter<bool>("applyAbsCutsIfNoPV"));
116  keepAllTracks_.push_back( trkSelectors[i].getParameter<bool>("keepAllTracks"));
117  max_relpterr_.push_back(trkSelectors[i].getParameter<double>("max_relpterr"));
118  min_nhits_.push_back(trkSelectors[i].getParameter<uint32_t>("min_nhits"));
119  max_minMissHitOutOrIn_.push_back(
120  trkSelectors[i].existsAs<int32_t>("max_minMissHitOutOrIn") ?
121  trkSelectors[i].getParameter<int32_t>("max_minMissHitOutOrIn") : 99);
122  max_lostHitFraction_.push_back(
123  trkSelectors[i].existsAs<double>("max_lostHitFraction") ?
124  trkSelectors[i].getParameter<double>("max_lostHitFraction") : 1.0);
125  min_eta_.push_back(trkSelectors[i].existsAs<double>("min_eta") ?
126  trkSelectors[i].getParameter<double>("min_eta"):-9999);
127  max_eta_.push_back(trkSelectors[i].existsAs<double>("max_eta") ?
128  trkSelectors[i].getParameter<double>("max_eta"):9999);
129 
130  setQualityBit_.push_back( false );
131  std::string qualityStr = trkSelectors[i].getParameter<std::string>("qualityBit");
132  if (qualityStr != "") {
133  setQualityBit_[i] = true;
134  qualityToSet_[i] = TrackBase::qualityByName(trkSelectors[i].getParameter<std::string>("qualityBit"));
135  }
136 
137  if (setQualityBit_[i] && (qualityToSet_[i] == TrackBase::undefQuality)) throw cms::Exception("Configuration") <<
138  "You can't set the quality bit " << trkSelectors[i].getParameter<std::string>("qualityBit") << " as it is 'undefQuality' or unknown.\n";
139 
140  if (applyAbsCutsIfNoPV_[i]) {
141  max_d0NoPV_.push_back(trkSelectors[i].getParameter<double>("max_d0NoPV"));
142  max_z0NoPV_.push_back(trkSelectors[i].getParameter<double>("max_z0NoPV"));
143  }
144  else{//dummy values
145  max_d0NoPV_.push_back(0.);
146  max_z0NoPV_.push_back(0.);
147  }
148 
149  name_.push_back( trkSelectors[i].getParameter<std::string>("name") );
150 
151  preFilter_[i]=trkSelectors.size(); // no prefilter
152 
153  std::string pfName=trkSelectors[i].getParameter<std::string>("preFilterName");
154  if (pfName!="") {
155  bool foundPF=false;
156  for ( unsigned int j=0; j<i; j++)
157  if (name_[j]==pfName ) {
158  foundPF=true;
159  preFilter_[i]=j;
160  }
161  if ( !foundPF)
162  throw cms::Exception("Configuration") << "Invalid prefilter name in MultiTrackSelector "
163  << trkSelectors[i].getParameter<std::string>("preFilterName");
164 
165  }
166 
167  // produces<std::vector<int> >(name_[i]).setBranchAlias( name_[i] + "TrackQuals");
168  produces<edm::ValueMap<int> >(name_[i]).setBranchAlias( name_[i] + "TrackQuals");
169  produces<QualityMaskCollection>(name_[i]).setBranchAlias( name_[i] + "QualityMasks");
170  if(useAnyMVA_){
171  bool thisMVA = false;
172  if(trkSelectors[i].exists("useMVA"))thisMVA = trkSelectors[i].getParameter<bool>("useMVA");
173  useMVA_.push_back(thisMVA);
174  if(thisMVA){
175  double minVal = -1;
176  if(trkSelectors[i].exists("minMVA"))minVal = trkSelectors[i].getParameter<double>("minMVA");
177  min_MVA_.push_back(minVal);
178  mvaType_.push_back(trkSelectors[i].exists("mvaType") ? trkSelectors[i].getParameter<std::string>("mvaType") : "Detached");
179  forestLabel_.push_back(trkSelectors[i].exists("GBRForestLabel") ? trkSelectors[i].getParameter<std::string>("GBRForestLabel") : "MVASelectorIter0");
180  useMVAonly_.push_back(trkSelectors[i].exists("useMVAonly") ? trkSelectors[i].getParameter<bool>("useMVAonly") : false);
181  }else{
182  min_MVA_.push_back(-9999.0);
183  useMVAonly_.push_back(false);
184  mvaType_.push_back("Detached");
185  forestLabel_.push_back("MVASelectorIter0");
186  }
187  }else{
188  useMVA_.push_back(false);
189  useMVAonly_.push_back(false);
190  min_MVA_.push_back(-9999.0);
191  mvaType_.push_back("Detached");
192  forestLabel_.push_back("MVASelectorIter0");
193  }
194 
195  }
196 }
197 
199  for(auto forest : forest_)delete forest;
200 }
201 
202 
204  if(!useForestFromDB_){
205  TFile gbrfile(dbFileName_.c_str());
206  for(int i = 0; i < (int)forestLabel_.size(); i++){
207  forest_[i] = (GBRForest*)gbrfile.Get(forestLabel_[i].c_str());
208  }
209  }
210 
211 }
212 
213 
214 
216 {
217  using namespace std;
218  using namespace edm;
219  using namespace reco;
220 
221  // Get tracks
222  Handle<TrackCollection> hSrcTrack;
223  evt.getByToken(src_, hSrcTrack );
224 
225  const TrackCollection& srcTracks(*hSrcTrack);
226  if (hSrcTrack.failedToGet())
227  edm::LogWarning("MultiTrackSelector")<<"could not get Track collection";
228 
229  // get hits in track..
231  evt.getByToken(hSrc_, hSrcHits );
232  const TrackingRecHitCollection & srcHits(*hSrcHits);
233 
234 
235  // looking for the beam spot
237  evt.getByToken(beamspot_, hBsp);
238  const reco::BeamSpot& vertexBeamSpot(*hBsp);
239 
240  // Select good primary vertices for use in subsequent track selection
242  if (useVertices_) {
243  evt.getByToken(vertices_, hVtx);
244  if (hVtx.failedToGet())
245  edm::LogWarning("MultiTrackSelector")<<"could not get Vertex collection";
246  }
247 
248  unsigned int trkSize=srcTracks.size();
249  std::vector<int> selTracksSave( qualityToSet_.size()*trkSize,0);
250 
251  std::vector<Point> points;
252  std::vector<float> vterr, vzerr;
253  if (useVertices_) selectVertices(0,*hVtx, points, vterr, vzerr);
254  //auto vtxP = points.empty() ? vertexBeamSpot.position() : points[0]; // rare, very rare, still happens!
255  for (unsigned int i=0; i<qualityToSet_.size(); i++) {
256  std::vector<float> mvaVals_(srcTracks.size(),-99.f);
257  processMVA(evt,es,vertexBeamSpot,*(hVtx.product()), i, mvaVals_, i == 0 ? true : false);
258  std::vector<int> selTracks(trkSize,0);
259  auto selTracksValueMap = std::make_unique<edm::ValueMap<int>>();
260  edm::ValueMap<int>::Filler filler(*selTracksValueMap);
261 
262  if (useVertices_) selectVertices(i,*hVtx, points, vterr, vzerr);
263 
264  // Loop over tracks
265  size_t current = 0;
266  for (TrackCollection::const_iterator it = srcTracks.begin(), ed = srcTracks.end(); it != ed; ++it, ++current) {
267  const Track & trk = * it;
268  // Check if this track passes cuts
269 
270  LogTrace("TrackSelection") << "ready to check track with pt="<< trk.pt() ;
271 
272  //already removed
273  bool ok=true;
274  if (preFilter_[i]<i && selTracksSave[preFilter_[i]*trkSize+current] < 0) {
275  selTracks[current]=-1;
276  ok=false;
277  if ( !keepAllTracks_[i])
278  continue;
279  }
280  else {
281  float mvaVal = 0;
282  if(useAnyMVA_) mvaVal = mvaVals_[current];
283  ok = select(i,vertexBeamSpot, srcHits, trk, points, vterr, vzerr,mvaVal);
284  if (!ok) {
285  LogTrace("TrackSelection") << "track with pt="<< trk.pt() << " NOT selected";
286  if (!keepAllTracks_[i]) {
287  selTracks[current]=-1;
288  continue;
289  }
290  }
291  else
292  LogTrace("TrackSelection") << "track with pt="<< trk.pt() << " selected";
293  }
294 
295  if (preFilter_[i]<i ) {
296  selTracks[current]=selTracksSave[preFilter_[i]*trkSize+current];
297  }
298  else {
299  selTracks[current]=trk.qualityMask();
300  }
301  if ( ok && setQualityBit_[i]) {
302  selTracks[current]= (selTracks[current] | (1<<qualityToSet_[i]));
303  if (qualityToSet_[i]==TrackBase::tight) {
304  selTracks[current]=(selTracks[current] | (1<<TrackBase::loose));
305  }
306  else if (qualityToSet_[i]==TrackBase::highPurity) {
307  selTracks[current]=(selTracks[current] | (1<<TrackBase::loose));
308  selTracks[current]=(selTracks[current] | (1<<TrackBase::tight));
309  }
310  if (!points.empty()) {
311  if (qualityToSet_[i]==TrackBase::loose) {
312  selTracks[current]=(selTracks[current] | (1<<TrackBase::looseSetWithPV));
313  }
314  else if (qualityToSet_[i]==TrackBase::highPurity) {
315  selTracks[current]=(selTracks[current] | (1<<TrackBase::looseSetWithPV));
316  selTracks[current]=(selTracks[current] | (1<<TrackBase::highPuritySetWithPV));
317  }
318  }
319  }
320  }
321  for ( unsigned int j=0; j< trkSize; j++ ) selTracksSave[j+i*trkSize]=selTracks[j];
322  filler.insert(hSrcTrack, selTracks.begin(),selTracks.end());
323  filler.fill();
324 
325  // evt.put(std::move(selTracks),name_[i]);
326  evt.put(std::move(selTracksValueMap),name_[i]);
327  for (auto & q : selTracks) q=std::max(q,0);
328  auto quals = std::make_unique<QualityMaskCollection>(selTracks.begin(),selTracks.end());
329  evt.put(std::move(quals),name_[i]);
330  }
331 }
332 
333 
334  bool MultiTrackSelector::select(unsigned int tsNum,
335  const reco::BeamSpot &vertexBeamSpot,
336  const TrackingRecHitCollection & recHits,
337  const reco::Track &tk,
338  const std::vector<Point> &points,
339  std::vector<float> &vterr,
340  std::vector<float> &vzerr,
341  double mvaVal) const {
342  // Decide if the given track passes selection cuts.
343 
344  using namespace std;
345 
346  //cuts on number of valid hits
347  auto nhits = tk.numberOfValidHits();
348  if(nhits>=min_hits_bypass_[tsNum]) return true;
349  if(nhits < min_nhits_[tsNum]) return false;
350 
351  if ( tk.ndof() < 1E-5 ) return false;
352 
353 
355  //Adding the MVA selection before any other cut//
357  if(useAnyMVA_ && useMVA_[tsNum]){
358  if (useMVAonly_[tsNum]) return mvaVal > min_MVA_[tsNum];
359  if(mvaVal < min_MVA_[tsNum])return false;
360  }
362  //End of MVA selection section//
364 
365 
366  // Cuts on numbers of layers with hits/3D hits/lost hits.
368  uint32_t nlayers3D = tk.hitPattern().pixelLayersWithMeasurement() +
371  LogDebug("TrackSelection") << "cuts on nlayers: " << nlayers << " " << nlayers3D << " " << nlayersLost << " vs "
372  << min_layers_[tsNum] << " " << min_3Dlayers_[tsNum] << " " << max_lostLayers_[tsNum];
373  if (nlayers < min_layers_[tsNum]) return false;
374  if (nlayers3D < min_3Dlayers_[tsNum]) return false;
375  if (nlayersLost > max_lostLayers_[tsNum]) return false;
376  LogTrace("TrackSelection") << "cuts on nlayers passed";
377 
378  float chi2n = tk.normalizedChi2();
379  float chi2n_no1Dmod = chi2n;
380 
381  int count1dhits = 0;
382  auto ith = tk.extra()->firstRecHit();
383  auto edh = ith + tk.recHitsSize();
384  for (; ith<edh; ++ith) {
385  const TrackingRecHit & hit = recHits[ith];
386  if (hit.dimension()==1) ++count1dhits;
387  }
388  if (count1dhits > 0) {
389  float chi2 = tk.chi2();
390  float ndof = tk.ndof();
391  chi2n = (chi2+count1dhits)/float(ndof+count1dhits);
392  }
393  // For each 1D rechit, the chi^2 and ndof is increased by one. This is a way of retaining approximately
394  // the same normalized chi^2 distribution as with 2D rechits.
395  if (chi2n > chi2n_par_[tsNum]*nlayers) return false;
396 
397  if (chi2n_no1Dmod > chi2n_no1Dmod_par_[tsNum]*nlayers) return false;
398 
399  // Get track parameters
400  float pt = std::max(float(tk.pt()),0.000001f);
401  float eta = tk.eta();
402  if (eta<min_eta_[tsNum] || eta>max_eta_[tsNum]) return false;
403 
404  //cuts on relative error on pt
405  float relpterr = float(tk.ptError())/pt;
406  if(relpterr > max_relpterr_[tsNum]) return false;
407 
410  int minLost = std::min(lostIn,lostOut);
411  if (minLost > max_minMissHitOutOrIn_[tsNum]) return false;
412  float lostMidFrac = tk.numberOfLostHits() / (tk.numberOfValidHits() + tk.numberOfLostHits());
413  if (lostMidFrac > max_lostHitFraction_[tsNum]) return false;
414 
415 
416 
417  //other track parameters
418  float d0 = -tk.dxy(vertexBeamSpot.position()), d0E = tk.d0Error(),
419  dz = tk.dz(vertexBeamSpot.position()), dzE = tk.dzError();
420 
421  // parametrized d0 resolution for the track pt
422  float nomd0E = sqrt(res_par_[tsNum][0]*res_par_[tsNum][0]+(res_par_[tsNum][1]/pt)*(res_par_[tsNum][1]/pt));
423  // parametrized z0 resolution for the track pt and eta
424  float nomdzE = nomd0E*(std::cosh(eta));
425 
426  float dzCut = std::min( powN(dz_par1_[tsNum][0]*nlayers,int(dz_par1_[tsNum][1]+0.5))*nomdzE,
427  powN(dz_par2_[tsNum][0]*nlayers,int(dz_par2_[tsNum][1]+0.5))*dzE );
428  float d0Cut = std::min( powN(d0_par1_[tsNum][0]*nlayers,int(d0_par1_[tsNum][1]+0.5))*nomd0E,
429  powN(d0_par2_[tsNum][0]*nlayers,int(d0_par2_[tsNum][1]+0.5))*d0E );
430 
431 
432  // ---- PrimaryVertex compatibility cut
433  bool primaryVertexZCompatibility(false);
434  bool primaryVertexD0Compatibility(false);
435 
436  if (points.empty()) { //If not primaryVertices are reconstructed, check just the compatibility with the BS
437  //z0 within (n sigma + dzCut) of the beam spot z, if no good vertex is found
438  if ( abs(dz) < hypot(vertexBeamSpot.sigmaZ()*nSigmaZ_[tsNum],dzCut) ) primaryVertexZCompatibility = true;
439  // d0 compatibility with beam line
440  if (abs(d0) < d0Cut) primaryVertexD0Compatibility = true;
441  }
442 
443  int iv=0;
444  for (std::vector<Point>::const_iterator point = points.begin(), end = points.end(); point != end; ++point) {
445  LogTrace("TrackSelection") << "Test track w.r.t. vertex with z position " << point->z();
446  if(primaryVertexZCompatibility && primaryVertexD0Compatibility) break;
447  float dzPV = tk.dz(*point); //re-evaluate the dz with respect to the vertex position
448  float d0PV = tk.dxy(*point); //re-evaluate the dxy with respect to the vertex position
449  if(useVtxError_){
450  float dzErrPV = std::sqrt(dzE*dzE+vzerr[iv]*vzerr[iv]); // include vertex error in z
451  float d0ErrPV = std::sqrt(d0E*d0E+vterr[iv]*vterr[iv]); // include vertex error in xy
452  iv++;
453  if (abs(dzPV) < dz_par1_[tsNum][0]*pow(nlayers,dz_par1_[tsNum][1])*nomdzE &&
454  abs(dzPV) < dz_par2_[tsNum][0]*pow(nlayers,dz_par2_[tsNum][1])*dzErrPV &&
455  abs(dzPV) < max_z0_[tsNum]) primaryVertexZCompatibility = true;
456  if (abs(d0PV) < d0_par1_[tsNum][0]*pow(nlayers,d0_par1_[tsNum][1])*nomd0E &&
457  abs(d0PV) < d0_par2_[tsNum][0]*pow(nlayers,d0_par2_[tsNum][1])*d0ErrPV &&
458  abs(d0PV) < max_d0_[tsNum]) primaryVertexD0Compatibility = true;
459  }else{
460  if (abs(dzPV) < dzCut) primaryVertexZCompatibility = true;
461  if (abs(d0PV) < d0Cut) primaryVertexD0Compatibility = true;
462  }
463  LogTrace("TrackSelection") << "distances " << dzPV << " " << d0PV << " vs " << dzCut << " " << d0Cut;
464  }
465 
466  if (points.empty() && applyAbsCutsIfNoPV_[tsNum]) {
467  if ( abs(dz) > max_z0NoPV_[tsNum] || abs(d0) > max_d0NoPV_[tsNum]) return false;
468  } else {
469  // Absolute cuts on all tracks impact parameters with respect to beam-spot.
470  // If BS is not compatible, verify if at least the reco-vertex is compatible (useful for incorrect BS settings)
471  if (abs(d0) > max_d0_[tsNum] && !primaryVertexD0Compatibility) return false;
472  LogTrace("TrackSelection") << "absolute cuts on d0 passed";
473  if (abs(dz) > max_z0_[tsNum] && !primaryVertexZCompatibility) return false;
474  LogTrace("TrackSelection") << "absolute cuts on dz passed";
475  }
476 
477  LogTrace("TrackSelection") << "cuts on PV: apply adapted PV cuts? " << applyAdaptedPVCuts_[tsNum]
478  << " d0 compatibility? " << primaryVertexD0Compatibility
479  << " z compatibility? " << primaryVertexZCompatibility ;
480 
481  if (applyAdaptedPVCuts_[tsNum]) {
482  return (primaryVertexD0Compatibility && primaryVertexZCompatibility);
483  } else {
484  return true;
485  }
486 
487 }
488 
489  void MultiTrackSelector::selectVertices(unsigned int tsNum,
490  const reco::VertexCollection &vtxs,
491  std::vector<Point> &points,
492  std::vector<float> &vterr,
493  std::vector<float> &vzerr) const {
494  // Select good primary vertices
495  using namespace reco;
496  int32_t toTake = vtxNumber_[tsNum];
497  for (VertexCollection::const_iterator it = vtxs.begin(), ed = vtxs.end(); it != ed; ++it) {
498 
499  LogDebug("SelectVertex") << " select vertex with z position " << it->z() << " "
500  << it->chi2() << " " << it->ndof() << " " << TMath::Prob(it->chi2(), static_cast<int32_t>(it->ndof()));
501  Vertex vtx = *it;
502  bool pass = vertexCut_[tsNum]( vtx );
503  if( pass ) {
504  points.push_back(it->position());
505  vterr.push_back(sqrt(it->yError()*it->xError()));
506  vzerr.push_back(it->zError());
507  LogTrace("SelectVertex") << " SELECTED vertex with z position " << it->z();
508  toTake--; if (toTake == 0) break;
509  }
510  }
511 }
512 
513 void MultiTrackSelector::processMVA(edm::Event& evt, const edm::EventSetup& es, const reco::BeamSpot& beamspot,const reco::VertexCollection& vertices, int selIndex, std::vector<float> & mvaVals_, bool writeIt) const
514 {
515 
516  using namespace std;
517  using namespace edm;
518  using namespace reco;
519 
520  // Get tracks
521  Handle<TrackCollection> hSrcTrack;
522  evt.getByToken( src_, hSrcTrack );
523  const TrackCollection& srcTracks(*hSrcTrack);
524  RefToBaseProd<Track> rtbpTrackCollection(hSrcTrack);
525  assert(mvaVals_.size()==srcTracks.size());
526 
527  // get hits in track..
529  evt.getByToken( hSrc_, hSrcHits );
530  const TrackingRecHitCollection & srcHits(*hSrcHits);
531 
532 
533  auto mvaValValueMap = std::make_unique<edm::ValueMap<float>>();
534  edm::ValueMap<float>::Filler mvaFiller(*mvaValValueMap);
535 
536 
537  if(!useAnyMVA_ && writeIt){
538  // mvaVals_ already initalized...
539  mvaFiller.insert(hSrcTrack,mvaVals_.begin(),mvaVals_.end());
540  mvaFiller.fill();
541  evt.put(std::move(mvaValValueMap),"MVAVals");
542  auto mvas = std::make_unique<MVACollection>(mvaVals_.begin(),mvaVals_.end());
543  evt.put(std::move(mvas),"MVAValues");
544  return;
545  }
546 
547  if(!useMVA_[selIndex] && !writeIt)return;
548 
549 
550  size_t current = 0;
551  for (TrackCollection::const_iterator it = srcTracks.begin(), ed = srcTracks.end(); it != ed; ++it, ++current) {
552  const Track & trk = * it;
553  RefToBase<Track> trackRef(rtbpTrackCollection,current);
554  auto tmva_ndof_ = trk.ndof();
555  auto tmva_nlayers_ = trk.hitPattern().trackerLayersWithMeasurement();
556  auto tmva_nlayers3D_ = trk.hitPattern().pixelLayersWithMeasurement()
559  float chi2n = trk.normalizedChi2();
560  float chi2n_no1Dmod = chi2n;
561 
562  int count1dhits = 0;
563  auto ith = trk.extra()->firstRecHit();
564  auto edh = ith + trk.recHitsSize();
565  for (; ith<edh; ++ith) {
566  const TrackingRecHit & hit = srcHits[ith];
567  if (hit.dimension()==1) ++count1dhits;
568  }
569  if (count1dhits > 0) {
570  float chi2 = trk.chi2();
571  float ndof = trk.ndof();
572  chi2n = (chi2+count1dhits)/float(ndof+count1dhits);
573  }
574  auto tmva_chi2n_ = chi2n;
575  auto tmva_chi2n_no1dmod_ = chi2n_no1Dmod;
576  auto tmva_eta_ = trk.eta();
577  auto tmva_relpterr_ = float(trk.ptError())/std::max(float(trk.pt()),0.000001f);
578  auto tmva_nhits_ = trk.numberOfValidHits();
581  auto tmva_minlost_ = std::min(lostIn,lostOut);
582  auto tmva_lostmidfrac_ = trk.numberOfLostHits() / (trk.numberOfValidHits() + trk.numberOfLostHits());
583  auto tmva_absd0_ = fabs(-trk.dxy(beamspot.position()));
584  auto tmva_absdz_ = fabs(trk.dz(beamspot.position()));
585  Point bestVertex = getBestVertex(trackRef,vertices);
586  auto tmva_absd0PV_ = fabs(trk.dxy(bestVertex));
587  auto tmva_absdzPV_ = fabs(trk.dz(bestVertex));
588  auto tmva_pt_ = trk.pt();
589 
590  GBRForest const * forest = forest_[selIndex];
591  if(useForestFromDB_){
592  edm::ESHandle<GBRForest> forestHandle;
593  es.get<GBRWrapperRcd>().get(forestLabel_[selIndex],forestHandle);
594  forest = forestHandle.product();
595  }
596 
597  float gbrVals_[16];
598  gbrVals_[0] = tmva_pt_;
599  gbrVals_[1] = tmva_lostmidfrac_;
600  gbrVals_[2] = tmva_minlost_;
601  gbrVals_[3] = tmva_nhits_;
602  gbrVals_[4] = tmva_relpterr_;
603  gbrVals_[5] = tmva_eta_;
604  gbrVals_[6] = tmva_chi2n_no1dmod_;
605  gbrVals_[7] = tmva_chi2n_;
606  gbrVals_[8] = tmva_nlayerslost_;
607  gbrVals_[9] = tmva_nlayers3D_;
608  gbrVals_[10] = tmva_nlayers_;
609  gbrVals_[11] = tmva_ndof_;
610  gbrVals_[12] = tmva_absd0PV_;
611  gbrVals_[13] = tmva_absdzPV_;
612  gbrVals_[14] = tmva_absdz_;
613  gbrVals_[15] = tmva_absd0_;
614 
615  if (mvaType_[selIndex] == "Prompt"){
616  auto gbrVal = forest->GetClassifier(gbrVals_);
617  mvaVals_[current] = gbrVal;
618  }else{
619  float detachedGbrVals_[12];
620  for(int jjj = 0; jjj < 12; jjj++)detachedGbrVals_[jjj] = gbrVals_[jjj];
621  auto gbrVal = forest->GetClassifier(detachedGbrVals_);
622  mvaVals_[current] = gbrVal;
623  }
624  }
625 
626  if(writeIt){
627  mvaFiller.insert(hSrcTrack,mvaVals_.begin(),mvaVals_.end());
628  mvaFiller.fill();
629  evt.put(std::move(mvaValValueMap),"MVAVals");
630  auto mvas = std::make_unique<MVACollection>(mvaVals_.begin(),mvaVals_.end());
631  evt.put(std::move(mvas),"MVAValues");
632  }
633 
634 }
635 
637  Point p(0,0,-99999);
638  Point p_dz(0,0,-99999);
639  float bestWeight = 0;
640  float dzmin = 10000;
641  bool weightMatch = false;
642  for(auto const & vertex : vertices){
643  float w = vertex.trackWeight(track);
644  const Point& v_pos = vertex.position();
645  if(w > bestWeight){
646  p = v_pos;
647  bestWeight = w;
648  weightMatch = true;
649  }
650  float dz = fabs(track.get()->dz(v_pos));
651  if(dz < dzmin){
652  p_dz = v_pos;
653  dzmin = dz;
654  }
655  }
656  if(weightMatch)return p;
657  else return p_dz;
658 }
659 
660 
663 
665 
#define LogDebug(id)
std::vector< double > chi2n_no1Dmod_par_
value_type const * get() const
Definition: RefToBase.h:234
T getParameter(std::string const &) const
std::vector< uint32_t > min_nhits_
std::vector< double > chi2n_par_
std::vector< std::vector< double > > d0_par1_
std::vector< double > max_d0NoPV_
double d0Error() const
error on d0
Definition: TrackBase.h:847
std::vector< double > max_z0_
OrphanHandle< PROD > put(std::unique_ptr< PROD > product)
Put a new product.
Definition: Event.h:137
std::vector< uint32_t > min_layers_
Cuts on numbers of layers with hits/3D hits/lost hits.
~MultiTrackSelector() override
destructor
std::vector< std::string > name_
std::vector< double > max_z0NoPV_
MultiTrackSelector()
constructor
const double w
Definition: UKUtility.cc:23
const TrackExtraRef & extra() const
reference to "extra" object
Definition: Track.h:191
std::vector< bool > useMVA_
double normalizedChi2() const
chi-squared divided by n.d.o.f. (or chi-squared * 1e6 if n.d.o.f. is zero)
Definition: TrackBase.h:594
bool getByToken(EDGetToken token, Handle< PROD > &result) const
Definition: Event.h:579
std::vector< bool > keepAllTracks_
#define DEFINE_FWK_MODULE(type)
Definition: MakerMacros.h:17
size_t recHitsSize() const
Get number of RecHits. (Warning, this includes invalid hits, which are not physical hits)...
Definition: Track.h:121
Point getBestVertex(const reco::TrackBaseRef, const reco::VertexCollection) const
std::vector< uint32_t > min_hits_bypass_
bool select(unsigned tsNum, const reco::BeamSpot &vertexBeamSpot, const TrackingRecHitCollection &recHits, const reco::Track &tk, const std::vector< Point > &points, std::vector< float > &vterr, std::vector< float > &vzerr, double mvaVal) const
return class, or -1 if rejected
std::vector< Track > TrackCollection
collection of Tracks
Definition: TrackFwd.h:14
bool exists(std::string const &parameterName) const
checks if a parameter exists
std::vector< bool > applyAdaptedPVCuts_
unsigned short numberOfLostHits() const
number of cases where track crossed a layer without getting a hit.
Definition: TrackBase.h:895
std::vector< Vertex > VertexCollection
collection of Vertex objects
Definition: VertexFwd.h:9
virtual void run(edm::Event &evt, const edm::EventSetup &es) const
std::vector< double > nSigmaZ_
std::vector< std::string > mvaType_
std::vector< unsigned int > preFilter_
int pixelLayersWithMeasurement() const
Definition: HitPattern.cc:538
edm::EDGetTokenT< TrackingRecHitCollection > hSrc_
int trackerLayersWithMeasurement() const
Definition: HitPattern.cc:557
edm::EDGetTokenT< reco::VertexCollection > vertices_
std::vector< uint32_t > min_3Dlayers_
int numberOfLostTrackerHits(HitCategory category) const
Definition: HitPattern.h:987
std::vector< uint32_t > max_lostLayers_
double eta() const
pseudorapidity of momentum vector
Definition: TrackBase.h:684
int numberOfValidStripLayersWithMonoAndStereo(uint16_t stripdet, uint16_t layer) const
Definition: HitPattern.cc:379
std::vector< int32_t > max_lostHitFraction_
edm::EDGetTokenT< reco::BeamSpot > beamspot_
std::vector< double > min_eta_
double chi2() const
chi-squared of the fit
Definition: TrackBase.h:582
double ndof() const
number of degrees of freedom of the fit
Definition: TrackBase.h:588
T sqrt(T t)
Definition: SSEVec.h:18
virtual int dimension() const =0
std::vector< bool > setQualityBit_
do I have to set a quality bit?
double pt() const
track transverse momentum
Definition: TrackBase.h:654
double ptError() const
error on Pt (set to 1000 TeV if charge==0 for safety)
Definition: TrackBase.h:808
int qualityMask() const
Definition: TrackBase.h:931
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
std::vector< std::vector< double > > dz_par1_
double f[11][100]
unsigned short numberOfValidHits() const
number of valid hits found
Definition: TrackBase.h:889
#define end
Definition: vmac.h:39
std::vector< std::vector< double > > dz_par2_
std::vector< std::vector< double > > res_par_
T min(T a, T b)
Definition: MathUtil.h:58
#define LogTrace(id)
std::vector< double > max_relpterr_
void beginStream(edm::StreamID) final
double dz() const
dz parameter (= dsz/cos(lambda)). This is the track z0 w.r.t (0,0,0) only if the refPoint is close to...
Definition: TrackBase.h:642
double dzError() const
error on dz
Definition: TrackBase.h:859
bool failedToGet() const
Definition: HandleBase.h:78
std::vector< int32_t > vtxNumber_
vertex cuts
void selectVertices(unsigned int tsNum, const reco::VertexCollection &vtxs, std::vector< Point > &points, std::vector< float > &vterr, std::vector< float > &vzerr) const
T const * product() const
Definition: Handle.h:81
std::vector< reco::TrackBase::TrackQuality > qualityToSet_
const HitPattern & hitPattern() const
Access the hit pattern, indicating in which Tracker layers the track has hits.
Definition: TrackBase.h:479
double sigmaZ() const
sigma z
Definition: BeamSpot.h:80
std::vector< std::string > forestLabel_
int trackerLayersWithoutMeasurement(HitCategory category) const
Definition: HitPattern.cc:574
fixed size matrix
HLT enums.
T get() const
Definition: EventSetup.h:68
std::vector< StringCutObjectSelector< reco::Vertex > > vertexCut_
std::vector< bool > applyAbsCutsIfNoPV_
const Point & position() const
position
Definition: BeamSpot.h:62
std::vector< int32_t > max_minMissHitOutOrIn_
std::vector< double > min_MVA_
math::XYZPoint Point
edm::EDGetTokenT< reco::TrackCollection > src_
source collection label
double dxy() const
dxy parameter. (This is the transverse impact parameter w.r.t. to (0,0,0) ONLY if refPoint is close t...
Definition: TrackBase.h:624
std::vector< std::vector< double > > d0_par2_
double GetClassifier(const float *vector) const
Definition: GBRForest.h:36
std::vector< double > max_d0_
Impact parameter absolute cuts.
std::vector< bool > useMVAonly_
T const * product() const
Definition: ESHandle.h:84
void processMVA(edm::Event &evt, const edm::EventSetup &es, const reco::BeamSpot &beamspot, const reco::VertexCollection &vertices, int selIndex, std::vector< float > &mvaVals_, bool writeIt=false) const
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:40
def move(src, dest)
Definition: eostools.py:511
*vegas h *****************************************************used in the default bin number in original ***version of VEGAS is ***a higher bin number might help to derive a more precise ***grade subtle point
Definition: invegas.h:5
std::vector< double > max_eta_
std::vector< GBRForest * > forest_