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KDTreeLinkerTrackEcal.cc
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2 
4 #include "TMath.h"
5 
8 {}
9 
11 {
12  clear();
13 }
14 
15 void
17 {
18  targetSet_.insert(track);
19 }
20 
21 
22 void
24 {
25  reco::PFClusterRef clusterref = ecalCluster->clusterRef();
26 
27  // This test is more or less done in PFBlockAlgo.h. In others cases, it should be switch on.
28  // if (!((clusterref->layer() == PFLayer::ECAL_ENDCAP) ||
29  // (clusterref->layer() == PFLayer::ECAL_BARREL)))
30  // return;
31 
32  const std::vector<reco::PFRecHitFraction> &fraction = clusterref->recHitFractions();
33 
34  // We create a list of ecalCluster
35  fieldClusterSet_.insert(ecalCluster);
36  for(size_t rhit = 0; rhit < fraction.size(); ++rhit) {
37  const reco::PFRecHitRef& rh = fraction[rhit].recHitRef();
38  double fract = fraction[rhit].fraction();
39 
40  if ((rh.isNull()) || (fract < 1E-4))
41  continue;
42 
43  const reco::PFRecHit& rechit = *rh;
44 
45  // We save the links rechit to EcalClusters
46  rechit2ClusterLinks_[&rechit].insert(ecalCluster);
47 
48  // We create a liste of rechits
49  rechitsSet_.insert(&rechit);
50  }
51 }
52 
53 void
55 {
56  // List of pseudo-rechits that will be used to create the KDTree
57  std::vector<KDTreeNodeInfo> eltList;
58 
59  // Filling of this list
60  for(RecHitSet::const_iterator it = rechitsSet_.begin();
61  it != rechitsSet_.end(); it++) {
62 
63  const reco::PFRecHit::REPPoint &posrep = (*it)->positionREP();
64 
65  KDTreeNodeInfo rh1 (*it, posrep.Eta(), posrep.Phi());
66  eltList.push_back(rh1);
67 
68  // Here we solve the problem of phi circular set by duplicating some rechits
69  // too close to -Pi (or to Pi) and adding (substracting) to them 2 * Pi.
70  if (rh1.dim2 > (M_PI - getPhiOffset())) {
71  double phi = rh1.dim2 - 2 * M_PI;
72  KDTreeNodeInfo rh2(*it, posrep.Eta(), phi);
73  eltList.push_back(rh2);
74  }
75 
76  if (rh1.dim2 < (M_PI * -1.0 + getPhiOffset())) {
77  double phi = rh1.dim2 + 2 * M_PI;
78  KDTreeNodeInfo rh3(*it, posrep.Eta(), phi);
79  eltList.push_back(rh3);
80  }
81  }
82 
83  // Here we define the upper/lower bounds of the 2D space (eta/phi).
84  double phimin = -1.0 * M_PI - getPhiOffset();
85  double phimax = M_PI + getPhiOffset();
86 
87  // etamin-etamax, phimin-phimax
88  KDTreeBox region(-3.0, 3.0, phimin, phimax);
89 
90  // We may now build the KDTree
91  tree_.build(eltList, region);
92 }
93 
94 void
96 {
97  // Must of the code has been taken from LinkByRecHit.cc
98 
99  // We iterate over the tracks.
100  for(BlockEltSet::iterator it = targetSet_.begin();
101  it != targetSet_.end(); it++) {
102 
103  reco::PFRecTrackRef trackref = (*it)->trackRefPF();
104 
105  // We set the multilinks flag of the track to true. It will allow us to
106  // use in an optimized way our algo results in the recursive linking algo.
107  (*it)->setIsValidMultilinks(true);
108 
109  const reco::PFTrajectoryPoint& atECAL =
110  trackref->extrapolatedPoint(reco::PFTrajectoryPoint::ECALShowerMax);
111 
112  // The track didn't reach ecal
113  if( ! atECAL.isValid() ) continue;
114 
115  const reco::PFTrajectoryPoint& atVertex =
116  trackref->extrapolatedPoint( reco::PFTrajectoryPoint::ClosestApproach );
117 
118  double trackPt = sqrt(atVertex.momentum().Vect().Perp2());
119  double tracketa = atECAL.positionREP().Eta();
120  double trackphi = atECAL.positionREP().Phi();
121  double trackx = atECAL.position().X();
122  double tracky = atECAL.position().Y();
123  double trackz = atECAL.position().Z();
124 
125  // Estimate the maximal envelope in phi/eta that will be used to find rechit candidates.
126  // Same envelope for cap et barrel rechits.
127  double range = getCristalPhiEtaMaxSize() * (2.0 + 1.0 / std::min(1., trackPt / 2.));
128 
129  // We search for all candidate recHits, ie all recHits contained in the maximal size envelope.
130  std::vector<KDTreeNodeInfo> recHits;
131  KDTreeBox trackBox(tracketa-range, tracketa+range, trackphi-range, trackphi+range);
132  tree_.search(trackBox, recHits);
133 
134  // Here we check all rechit candidates using the non-approximated method.
135  for(std::vector<KDTreeNodeInfo>::const_iterator rhit = recHits.begin();
136  rhit != recHits.end(); ++rhit) {
137 
138  const std::vector< math::XYZPoint >& cornersxyz = rhit->ptr->getCornersXYZ();
139  const math::XYZPoint& posxyz = rhit->ptr->position();
140  const reco::PFRecHit::REPPoint &rhrep = rhit->ptr->positionREP();
141  const std::vector<reco::PFRecHit::REPPoint>& corners = rhit->ptr->getCornersREP();
142  if(corners.size() != 4) continue;
143 
144  double rhsizeEta = fabs(corners[0].Eta() - corners[2].Eta());
145  double rhsizePhi = fabs(corners[0].Phi() - corners[2].Phi());
146  if ( rhsizePhi > M_PI ) rhsizePhi = 2.*M_PI - rhsizePhi;
147 
148  double deta = fabs(rhrep.Eta() - tracketa);
149  double dphi = fabs(rhrep.Phi() - trackphi);
150  if ( dphi > M_PI ) dphi = 2.*M_PI - dphi;
151 
152  // Find all clusters associated to given rechit
153  RecHit2BlockEltMap::iterator ret = rechit2ClusterLinks_.find(rhit->ptr);
154 
155  for(BlockEltSet::const_iterator clusterIt = ret->second.begin();
156  clusterIt != ret->second.end(); clusterIt++) {
157 
158  reco::PFClusterRef clusterref = (*clusterIt)->clusterRef();
159  double clusterz = clusterref->position().Z();
160  int fracsNbr = clusterref->recHitFractions().size();
161 
162  if (clusterref->layer() == PFLayer::ECAL_BARREL){ // BARREL
163  // Check if the track is in the barrel
164  if (fabs(trackz) > 300.) continue;
165 
166  double _rhsizeEta = rhsizeEta * (2.00 + 1.0 / (fracsNbr * std::min(1.,trackPt/2.)));
167  double _rhsizePhi = rhsizePhi * (2.00 + 1.0 / (fracsNbr * std::min(1.,trackPt/2.)));
168 
169  // Check if the track and the cluster are linked
170  if(deta < (_rhsizeEta / 2.) && dphi < (_rhsizePhi / 2.))
171  target2ClusterLinks_[*it].insert(*clusterIt);
172 
173 
174  } else { // ENDCAP
175 
176  // Check if the track is in the cap
177  if (fabs(trackz) < 300.) continue;
178  if (trackz * clusterz < 0.) continue;
179 
180  double x[5];
181  double y[5];
182  for ( unsigned jc=0; jc<4; ++jc ) {
183  math::XYZPoint cornerposxyz = cornersxyz[jc];
184  x[jc] = cornerposxyz.X() + (cornerposxyz.X()-posxyz.X())
185  * (1.00+0.50/fracsNbr /std::min(1.,trackPt/2.));
186  y[jc] = cornerposxyz.Y() + (cornerposxyz.Y()-posxyz.Y())
187  * (1.00+0.50/fracsNbr /std::min(1.,trackPt/2.));
188  }
189 
190  x[4] = x[0];
191  y[4] = y[0];
192 
193  bool isinside = TMath::IsInside(trackx,
194  tracky,
195  5,x,y);
196 
197  // Check if the track and the cluster are linked
198  if( isinside )
199  target2ClusterLinks_[*it].insert(*clusterIt);
200  }
201  }
202  }
203  }
204 }
205 
206 void
208 {
209  //TODO YG : Check if cluster positionREP() is valid ?
210 
211  // Here we save in each track the list of phi/eta values of linked clusters.
212  for (BlockElt2BlockEltMap::iterator it = target2ClusterLinks_.begin();
213  it != target2ClusterLinks_.end(); ++it) {
214  reco::PFMultiLinksTC multitracks(true);
215 
216  for (BlockEltSet::iterator jt = it->second.begin();
217  jt != it->second.end(); ++jt) {
218 
219  double clusterPhi = (*jt)->clusterRef()->positionREP().Phi();
220  double clusterEta = (*jt)->clusterRef()->positionREP().Eta();
221 
222  multitracks.linkedClusters.push_back(std::make_pair(clusterPhi, clusterEta));
223  }
224 
225  it->first->setMultilinks(multitracks);
226  }
227 }
228 
229 void
231 {
232  targetSet_.clear();
233  fieldClusterSet_.clear();
234 
235  rechitsSet_.clear();
236 
237  rechit2ClusterLinks_.clear();
238  target2ClusterLinks_.clear();
239 
240  tree_.clear();
241 }
const REPPoint & positionREP() const
trajectory position in (rho, eta, phi) base
Abstract base class for a PFBlock element (track, cluster...)
void build(std::vector< KDTreeNodeInfo > &eltList, const KDTreeBox &region)
ROOT::Math::PositionVector3D< ROOT::Math::CylindricalEta3D< Double32_t > > REPPoint
Definition: PFRecHit.h:39
tuple trackPt
Definition: listHistos.py:120
const math::XYZPoint & position() const
cartesian position (x, y, z)
#define min(a, b)
Definition: mlp_lapack.h:161
void search(const KDTreeBox &searchBox, std::vector< KDTreeNodeInfo > &resRecHitList)
bool isNull() const
Checks for null.
Definition: Ref.h:247
Particle flow rechit (rechit + geometry and topology information). See clustering algorithm in PFClus...
Definition: PFRecHit.h:31
Point of closest approach from beam axis (initial point in the case of PFSimParticle) ...
T sqrt(T t)
Definition: SSEVec.h:48
PFMultilinksType linkedClusters
virtual PFClusterRef clusterRef() const
void insertFieldClusterElt(reco::PFBlockElement *ecalCluster)
const Fraction< n, m >::type & fract()
Definition: Fraction.h:38
const math::XYZTLorentzVector & momentum() const
4-momenta quadrivector
#define M_PI
Definition: BFit3D.cc:3
bool isValid() const
is this point valid ?
XYZPointD XYZPoint
point in space with cartesian internal representation
Definition: Point3D.h:13
void insertTargetElt(reco::PFBlockElement *track)
float getCristalPhiEtaMaxSize() const
RecHit2BlockEltMap rechit2ClusterLinks_
BlockElt2BlockEltMap target2ClusterLinks_
A PFTrack holds several trajectory points, which basically contain the position and momentum of a tra...
Definition: DDAxes.h:10
float getPhiOffset() const
Definition: DDAxes.h:10