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AreaSeededTrackingRegionsBuilder.cc
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2 
9 
10 #include <array>
11 #include <limits>
12 
13 namespace {
14  float perp2(const std::array<float, 2>& a) { return a[0] * a[0] + a[1] * a[1]; }
15 } // namespace
16 
19  : candidates_(regPSet, iC), token_field(iC.esConsumes()) {
20  m_extraPhi = regPSet.getParameter<double>("extraPhi");
21  m_extraEta = regPSet.getParameter<double>("extraEta");
22 
23  // RectangularEtaPhiTrackingRegion parameters:
24  m_ptMin = regPSet.getParameter<double>("ptMin");
25  m_originRadius = regPSet.getParameter<double>("originRadius");
26  m_precise = regPSet.getParameter<bool>("precise");
28  regPSet.getParameter<std::string>("whereToUseMeasurementTracker"));
31  iC.consumes<MeasurementTrackerEvent>(regPSet.getParameter<edm::InputTag>("measurementTrackerName"));
32  }
33  m_searchOpt = regPSet.getParameter<bool>("searchOpt");
34  if (m_precise) {
36  }
37 }
38 
40  desc.add<double>("extraPhi", 0.);
41  desc.add<double>("extraEta", 0.);
42 
43  desc.add<double>("ptMin", 0.9);
44  desc.add<double>("originRadius", 0.2);
45  desc.add<bool>("precise", true);
46 
47  desc.add<std::string>("whereToUseMeasurementTracker", "Never");
48  desc.add<edm::InputTag>("measurementTrackerName", edm::InputTag(""));
50  desc.add<bool>("searchOpt", false);
51 }
52 
54  const edm::Event& e, const edm::EventSetup& es) const {
55  const auto& field = es.getData(token_field);
56  const MultipleScatteringParametrisationMaker* msmaker = nullptr;
57  if (m_precise) {
58  msmaker = &es.getData(token_msmaker);
59  }
60  auto builder = Builder(this, &field, msmaker);
61 
64  e.getByToken(token_measurementTracker, hmte);
65  builder.setMeasurementTracker(hmte.product());
66  }
67  builder.setCandidates((candidates_.objects(e)));
68  return builder;
69 }
70 
71 std::vector<std::unique_ptr<TrackingRegion> > AreaSeededTrackingRegionsBuilder::Builder::regions(
72  const Origins& origins, const std::vector<Area>& areas) const {
73  std::vector<std::unique_ptr<TrackingRegion> > result;
74 
75  // create tracking regions in directions of the points of interest
76  int n_regions = 0;
77  for (const auto& origin : origins) {
78  auto reg = region(origin, areas);
79  if (!reg)
80  continue;
81  result.push_back(std::move(reg));
82  ++n_regions;
83  }
84  LogDebug("AreaSeededTrackingRegionsBuilder") << "produced " << n_regions << " regions";
85 
86  return result;
87 }
88 
89 std::unique_ptr<TrackingRegion> AreaSeededTrackingRegionsBuilder::Builder::region(
90  const Origin& origin, const std::vector<Area>& areas) const {
91  return regionImpl(origin, areas);
92 }
93 std::unique_ptr<TrackingRegion> AreaSeededTrackingRegionsBuilder::Builder::region(
94  const Origin& origin, const edm::VecArray<Area, 2>& areas) const {
95  return regionImpl(origin, areas);
96 }
97 
98 template <typename T>
99 std::unique_ptr<TrackingRegion> AreaSeededTrackingRegionsBuilder::Builder::regionImpl(const Origin& origin,
100  const T& areas) const {
101  float minEta = std::numeric_limits<float>::max(), maxEta = std::numeric_limits<float>::lowest();
102  float minPhi = std::numeric_limits<float>::max(), maxPhi = std::numeric_limits<float>::lowest();
103 
104  const auto& orig = origin.first;
105 
106  LogDebug("AreaSeededTrackingRegionsProducer") << "Origin x,y,z " << orig.x() << "," << orig.y() << "," << orig.z();
107 
108  auto vecFromOrigPlusRadius = [&](const std::array<float, 2>& vec) {
109  const auto invlen = 1.f / std::sqrt(perp2(vec));
110  const auto tmp = (1.f - m_conf->m_originRadius * invlen);
111  return std::array<float, 2>{{vec[0] * tmp, vec[1] * tmp}};
112  };
113  auto tangentVec = [&](const std::array<float, 2>& vec, int sign) {
114  const auto d = std::sqrt(perp2(vec));
115  const auto r = m_conf->m_originRadius;
116  const auto tmp = r / std::sqrt(d * d - r * r);
117  // sign+ for counterclockwise, sign- for clockwise
118  const auto orthvec = sign > 0 ? std::array<float, 2>{{-vec[1] * tmp, vec[0] * tmp}}
119  : std::array<float, 2>{{vec[1] * tmp, -vec[0] * tmp}};
120  return std::array<float, 2>{{vec[0] - orthvec[0], vec[1] - orthvec[1]}};
121  };
122 
123  for (const auto& area : areas) {
124  // straight line assumption is conservative, accounding for
125  // low-pT bending would only tighten the eta-phi window
126  LogTrace("AreaSeededTrackingRegionsBuilder")
127  << " area x,y points " << area.x_rmin_phimin() << "," << area.y_rmin_phimin() << " " // go around
128  << area.x_rmin_phimax() << "," << area.y_rmin_phimax() << " " << area.x_rmax_phimax() << ","
129  << area.y_rmax_phimax() << " " << area.x_rmax_phimin() << "," << area.y_rmax_phimin() << " "
130  << "z " << area.zmin() << "," << area.zmax();
131 
132  // some common variables
133  const float x_rmin_phimin = area.x_rmin_phimin() - orig.x();
134  const float x_rmin_phimax = area.x_rmin_phimax() - orig.x();
135  const float y_rmin_phimin = area.y_rmin_phimin() - orig.y();
136  const float y_rmin_phimax = area.y_rmin_phimax() - orig.y();
137 
138  const std::array<float, 2> p_rmin_phimin = {{x_rmin_phimin, y_rmin_phimin}};
139  const std::array<float, 2> p_rmin_phimax = {{x_rmin_phimax, y_rmin_phimax}};
140  const std::array<float, 2> p_rmax_phimin = {{area.x_rmax_phimin() - orig.x(), area.y_rmax_phimin() - orig.y()}};
141  const std::array<float, 2> p_rmax_phimax = {{area.x_rmax_phimax() - orig.x(), area.y_rmax_phimax() - orig.y()}};
142 
143  // eta
144  {
145  // find which of the two rmin points is closer to the origin
146  //
147  // closest point for p_rmin, farthest point for p_rmax
148  const std::array<float, 2> p_rmin = perp2(p_rmin_phimin) < perp2(p_rmin_phimax) ? p_rmin_phimin : p_rmin_phimax;
149  const std::array<float, 2> p_rmax = perp2(p_rmax_phimin) > perp2(p_rmax_phimax) ? p_rmax_phimin : p_rmax_phimax;
150 
151  // then calculate the xy vector from the point closest to p_rmin on
152  // the (origin,originRadius) circle to the p_rmin
153  // this will maximize the eta window
154  const auto p_min = vecFromOrigPlusRadius(p_rmin);
155  const auto p_max = vecFromOrigPlusRadius(p_rmax);
156 
157  // then we calculate the maximal eta window
158  const auto etamin = std::min(etaFromXYZ(p_min[0], p_min[1], area.zmin() - (orig.z() + origin.second)),
159  etaFromXYZ(p_max[0], p_max[1], area.zmin() - (orig.z() + origin.second)));
160  const auto etamax = std::max(etaFromXYZ(p_min[0], p_min[1], area.zmax() - (orig.z() - origin.second)),
161  etaFromXYZ(p_max[0], p_max[1], area.zmax() - (orig.z() - origin.second)));
162 
163  LogTrace("AreaSeededTrackingRegionBuilder") << " eta min,max " << etamin << "," << etamax;
164 
167  }
168 
169  // phi
170  {
171  // For phi we construct the tangent lines of (origin,
172  // originRadius) that go though each of the 4 points (in xy
173  // plane) of the area. Easiest is to make a vector orthogonal to
174  // origin->point vector which has a length of
175  //
176  // length = r*d/std::sqrt(d*d-r*r)
177  //
178  // where r is the originRadius and d is the distance from origin
179  // to the point (to derive draw the situation and start with
180  // definitions of sin/cos of one of the angles of the
181  // right-angled triangle.
182 
183  // But we start with a "reference phi" so that we can easily
184  // decide which phi is the largest/smallest without having too
185  // much of headache with the wrapping. The reference is in
186  // principle defined by the averages of y&x phimin/phimax at
187  // rmin, but the '0.5f*' factor is omitted here to reduce
188  // computations.
189  const auto phi_ref = std::atan2(y_rmin_phimin + y_rmin_phimax, x_rmin_phimin + x_rmin_phimax);
190 
191  // for maximum phi we need the orthogonal vector to the left
192  const auto tan_rmin_phimax = tangentVec(p_rmin_phimax, +1);
193  const auto tan_rmax_phimax = tangentVec(p_rmax_phimax, +1);
194  const auto phi_rmin_phimax = std::atan2(tan_rmin_phimax[1], tan_rmin_phimax[0]);
195  const auto phi_rmax_phimax = std::atan2(tan_rmax_phimax[1], tan_rmax_phimax[0]);
196 
197  auto phimax =
198  std::abs(reco::deltaPhi(phi_rmin_phimax, phi_ref)) > std::abs(reco::deltaPhi(phi_rmax_phimax, phi_ref))
199  ? phi_rmin_phimax
200  : phi_rmax_phimax;
201 
202  LogTrace("AreaSeededTrackingRegionBuilder")
203  << " rmin_phimax vec " << p_rmin_phimax[0] << "," << p_rmin_phimax[1] << " tangent " << tan_rmin_phimax[0]
204  << "," << tan_rmin_phimax[1] << " phi " << phi_rmin_phimax << "\n"
205  << " rmax_phimax vec " << p_rmax_phimax[0] << "," << p_rmax_phimax[1] << " tangent " << tan_rmax_phimax[0]
206  << "," << tan_rmax_phimax[1] << " phi " << phi_rmax_phimax << "\n"
207  << " phimax " << phimax;
208 
209  // for minimum phi we need the orthogonal vector to the right
210  const auto tan_rmin_phimin = tangentVec(p_rmin_phimin, -1);
211  const auto tan_rmax_phimin = tangentVec(p_rmax_phimin, -1);
212  const auto phi_rmin_phimin = std::atan2(tan_rmin_phimin[1], tan_rmin_phimin[0]);
213  const auto phi_rmax_phimin = std::atan2(tan_rmax_phimin[1], tan_rmax_phimin[0]);
214 
215  auto phimin =
216  std::abs(reco::deltaPhi(phi_rmin_phimin, phi_ref)) > std::abs(reco::deltaPhi(phi_rmax_phimin, phi_ref))
217  ? phi_rmin_phimin
218  : phi_rmax_phimin;
219 
220  LogTrace("AreaSeededTrackingRegionBuilder")
221  << " rmin_phimin vec " << p_rmin_phimin[0] << "," << p_rmin_phimin[1] << " tangent " << tan_rmin_phimin[0]
222  << "," << tan_rmin_phimin[1] << " phi " << phi_rmin_phimin << "\n"
223  << " rmax_phimin vec " << p_rmax_phimin[0] << "," << p_rmax_phimin[1] << " tangent " << tan_rmax_phimin[0]
224  << "," << tan_rmax_phimin[1] << " phi " << phi_rmax_phimin << "\n"
225  << " phimin " << phimin;
226 
227  // wrapped around, need to decide which one to wrap
228  if (phimax < phimin) {
229  if (phimax < 0)
230  phimax += 2 * M_PI;
231  else
232  phimin -= 2 * M_PI;
233  }
234 
235  LogTrace("AreaSeededTrackingRegionBuilder") << " phi min,max " << phimin << "," << phimax;
236 
239  }
240 
241  LogTrace("AreaSeededTrackingRegionBuilder")
242  << " windows after this area eta " << minEta << "," << maxEta << " phi " << minPhi << "," << maxPhi;
243  }
244 
245  const auto meanEta = (minEta + maxEta) / 2.f;
246  const auto meanPhi = (minPhi + maxPhi) / 2.f;
247  const auto dEta = maxEta - meanEta + m_conf->m_extraEta;
248  const auto dPhi = maxPhi - meanPhi + m_conf->m_extraPhi;
249 
250  auto useCandidates = false;
251  if (candidates.first)
252  useCandidates = true;
253 
254  if (useCandidates) {
255  // If we have objects used for seeding, loop over objects and find overlap with the found region. Return overlaps as tracking regions to use
256  for (const auto& object : *candidates.first) {
257  float dEta_Cand = candidates.second.first;
258  float dPhi_Cand = candidates.second.second;
259  float eta_Cand = object.eta();
260  float phi_Cand = object.phi();
261  float dEta_Cand_Point = std::abs(eta_Cand - meanEta);
262  float dPhi_Cand_Point = std::abs(deltaPhi(phi_Cand, meanPhi));
263 
264  if (dEta_Cand_Point > (dEta_Cand + dEta) || dPhi_Cand_Point > (dPhi_Cand + dPhi))
265  continue;
266 
267  float etaMin_RoI = std::max(eta_Cand - dEta_Cand, meanEta - dEta);
268  float etaMax_RoI = std::min(eta_Cand + dEta_Cand, meanEta + dEta);
269 
270  float phi_Cand_minus = normalizedPhi(phi_Cand - dPhi_Cand);
271  float phi_Point_minus = normalizedPhi(meanPhi - dPhi);
272  float phi_Cand_plus = normalizedPhi(phi_Cand + dPhi_Cand);
273  float phi_Point_plus = normalizedPhi(meanPhi + dPhi);
274 
275  float phiMin_RoI = deltaPhi(phi_Cand_minus, phi_Point_minus) > 0. ? phi_Cand_minus : phi_Point_minus;
276  float phiMax_RoI = deltaPhi(phi_Cand_plus, phi_Point_plus) < 0. ? phi_Cand_plus : phi_Point_plus;
277 
278  const auto meanEtaTemp = (etaMin_RoI + etaMax_RoI) / 2.f;
279  auto meanPhiTemp = (phiMin_RoI + phiMax_RoI) / 2.f;
280  if (phiMax_RoI < phiMin_RoI)
281  meanPhiTemp -= M_PI;
282  meanPhiTemp = normalizedPhi(meanPhiTemp);
283 
284  const auto dPhiTemp = deltaPhi(phiMax_RoI, meanPhiTemp);
285  const auto dEtaTemp = etaMax_RoI - meanEtaTemp;
286 
287  const auto x = std::cos(meanPhiTemp);
288  const auto y = std::sin(meanPhiTemp);
289  const auto z = 1. / std::tan(2.f * std::atan(std::exp(-meanEtaTemp)));
290 
291  LogTrace("AreaSeededTrackingRegionsBuilder")
292  << "Direction x,y,z " << x << "," << y << "," << z << " eta,phi " << meanEtaTemp << "," << meanPhiTemp
293  << " window eta " << (meanEtaTemp - dEtaTemp) << "," << (meanEtaTemp + dEtaTemp) << " phi "
294  << (meanPhiTemp - dPhiTemp) << "," << (meanPhiTemp + dPhiTemp);
295 
296  return std::make_unique<RectangularEtaPhiTrackingRegion>(GlobalVector(x, y, z),
297  origin.first, // GlobalPoint
298  m_conf->m_ptMin,
299  m_conf->m_originRadius,
300  origin.second,
301  dEtaTemp,
302  dPhiTemp,
303  *m_field,
304  m_msmaker,
305  m_conf->m_precise,
306  m_conf->m_whereToUseMeasurementTracker,
307  m_measurementTracker,
308  m_conf->m_searchOpt);
309  }
310  // Have to retun nullptr here to ensure that we always return something
311  return nullptr;
312 
313  } else {
314  const auto x = std::cos(meanPhi);
315  const auto y = std::sin(meanPhi);
316  const auto z = 1. / std::tan(2.f * std::atan(std::exp(-meanEta)));
317 
318  LogTrace("AreaSeededTrackingRegionsBuilder")
319  << "Direction x,y,z " << x << "," << y << "," << z << " eta,phi " << meanEta << "," << meanPhi << " window eta "
320  << (meanEta - dEta) << "," << (meanEta + dEta) << " phi " << (meanPhi - dPhi) << "," << (meanPhi + dPhi);
321 
322  return std::make_unique<RectangularEtaPhiTrackingRegion>(GlobalVector(x, y, z),
323  origin.first, // GlobalPoint
324  m_conf->m_ptMin,
325  m_conf->m_originRadius,
326  origin.second,
327  dEta,
328  dPhi,
329  *m_field,
330  m_msmaker,
331  m_conf->m_precise,
332  m_conf->m_whereToUseMeasurementTracker,
333  m_measurementTracker,
334  m_conf->m_searchOpt);
335  }
336 }
constexpr double deltaPhi(double phi1, double phi2)
Definition: deltaPhi.h:26
EDGetTokenT< ProductType > consumes(edm::InputTag const &tag)
static void fillDescriptions(edm::ParameterSetDescription &desc)
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Definition: DeDxTools.cc:283
T getParameter(std::string const &) const
Definition: ParameterSet.h:307
std::vector< std::unique_ptr< TrackingRegion > > regions(const Origins &origins, const std::vector< Area > &areas) const
Builder beginEvent(const edm::Event &e, const edm::EventSetup &es) const
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Definition: normalizedPhi.h:8
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T perp2() const
Squared magnitude of transverse component.
T sqrt(T t)
Definition: SSEVec.h:19
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
Tan< T >::type tan(const T &t)
Definition: Tan.h:22
Abs< T >::type abs(const T &t)
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Definition: EventSetup.h:122
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Definition: ztail.py:151
#define M_PI
std::unique_ptr< TrackingRegion > regionImpl(const Origin &origin, const T &areas) const
std::unique_ptr< TrackingRegion > region(const Origin &origin, const std::vector< Area > &areas) const
static void fillDescriptions(edm::ParameterSetDescription &desc)
double a
Definition: hdecay.h:119
edm::EDGetTokenT< MeasurementTrackerEvent > token_measurementTracker
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align.sh
Definition: createJobs.py:716
long double T
Objects objects(const edm::Event &iEvent) const
AreaSeededTrackingRegionsBuilder(const edm::ParameterSet &regPSet, edm::ConsumesCollector &&iC)
def move(src, dest)
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Definition: GlobalVector.h:10
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