d8/d9b/VertexFinder_8cc_source.html

 #include "L1Trigger/VertexFinder/interface/VertexFinder.h"

 using namespace std;

 namespace l1tVertexFinder {

   void VertexFinder::computeAndSetVertexParameters(RecoVertex<>& vertex,
                                                    const std::vector<float>& bin_centers,
                                                    const std::vector<unsigned int>& counts) {
     double pt = 0.;
     double z0 = -999.;
     double z0width = 0.;
     bool highPt = false;
     double highestPt = 0.;
     unsigned int numHighPtTracks = 0;

     float SumZ = 0.;
     float z0square = 0.;
     float trackPt = 0.;

     std::vector<double> bin_pt(bin_centers.size(), 0.0);
     unsigned int ibin = 0;
     unsigned int itrack = 0;

     for (const L1Track* track : vertex.tracks()) {
       itrack++;
       trackPt = track->pt();

       // Skip the bins with no tracks
       while (ibin < counts.size() && counts[ibin] == 0)
         ibin++;

       if (trackPt > settings_->vx_TrackMaxPt()) {
         highPt = true;
         numHighPtTracks++;
         highestPt = (trackPt > highestPt) ? trackPt : highestPt;
         if (settings_->vx_TrackMaxPtBehavior() == 0)
           continue;  // ignore this track
         else if (settings_->vx_TrackMaxPtBehavior() == 1)
           trackPt = settings_->vx_TrackMaxPt();  // saturate
       }

       pt += std::pow(trackPt, settings_->vx_weightedmean());
       if (bin_centers.empty() && counts.empty()) {
         SumZ += track->z0() * std::pow(trackPt, settings_->vx_weightedmean());
         z0square += track->z0() * track->z0();
       } else {
         bin_pt[ibin] += std::pow(trackPt, settings_->vx_weightedmean());
         if (itrack == counts[ibin]) {
           SumZ += bin_centers[ibin] * bin_pt[ibin];
           z0square += bin_centers[ibin] * bin_centers[ibin];
           itrack = 0;
           ibin++;
         }
       }
     }

     z0 = SumZ / ((settings_->vx_weightedmean() > 0) ? pt : vertex.numTracks());
     z0square /= vertex.numTracks();
     z0width = sqrt(std::abs(z0 * z0 - z0square));

     vertex.setParameters(pt, z0, z0width, highPt, numHighPtTracks, highestPt);
   }

   void VertexFinder::GapClustering() {
     sort(fitTracks_.begin(), fitTracks_.end(), SortTracksByZ0());
     iterations_ = 0;
     RecoVertex Vertex;
     for (unsigned int i = 0; i < fitTracks_.size(); ++i) {
       Vertex.insert(&fitTracks_[i]);
       iterations_++;
       if ((i + 1 < fitTracks_.size() and fitTracks_[i + 1].z0() - fitTracks_[i].z0() > settings_->vx_distance()) or
           i == fitTracks_.size() - 1) {
         if (Vertex.numTracks() >= settings_->vx_minTracks()) {
           computeAndSetVertexParameters(Vertex, {}, {});
           vertices_.push_back(Vertex);
         }
         Vertex.clear();
       }
     }
   }

   float VertexFinder::maxDistance(RecoVertex<> cluster0, RecoVertex<> cluster1) {
     float distance = 0;
     for (const L1Track* track0 : cluster0.tracks()) {
       for (const L1Track* track1 : cluster1.tracks()) {
         if (std::abs(track0->z0() - track1->z0()) > distance) {
           distance = std::abs(track0->z0() - track1->z0());
         }
       }
     }

     return distance;
   }

   float VertexFinder::minDistance(RecoVertex<> cluster0, RecoVertex<> cluster1) {
     float distance = 9999;
     for (const L1Track* track0 : cluster0.tracks()) {
       for (const L1Track* track1 : cluster1.tracks()) {
         if (std::abs(track0->z0() - track1->z0()) < distance) {
           distance = std::abs(track0->z0() - track1->z0());
         }
       }
     }

     return distance;
   }

   float VertexFinder::meanDistance(RecoVertex<> cluster0, RecoVertex<> cluster1) {
     float distanceSum = 0;

     for (const L1Track* track0 : cluster0.tracks()) {
       for (const L1Track* track1 : cluster1.tracks()) {
         distanceSum += std::abs(track0->z0() - track1->z0());
       }
     }

     float distance = distanceSum / (cluster0.numTracks() * cluster1.numTracks());
     return distance;
   }

   float VertexFinder::centralDistance(RecoVertex<> cluster0, RecoVertex<> cluster1) {
     computeAndSetVertexParameters(cluster0, {}, {});
     computeAndSetVertexParameters(cluster1, {}, {});
     float distance = std::abs(cluster0.z0() - cluster1.z0());
     return distance;
   }

   void VertexFinder::agglomerativeHierarchicalClustering() {
     iterations_ = 0;

     sort(fitTracks_.begin(), fitTracks_.end(), SortTracksByZ0());

     RecoVertexCollection vClusters;
     vClusters.resize(fitTracks_.size());

     for (unsigned int i = 0; i < fitTracks_.size(); ++i) {
       vClusters[i].insert(&fitTracks_[i]);
       // iterations_++;
     }

     while (true) {
       float MinimumScore = 9999;

       unsigned int clusterId0 = 0;
       unsigned int clusterId1 = 0;
       for (unsigned int iClust = 0; iClust < vClusters.size() - 1; iClust++) {
         iterations_++;

         float M = 0;
         if (settings_->vx_distanceType() == 0)
           M = maxDistance(vClusters[iClust], vClusters[iClust + 1]);
         else if (settings_->vx_distanceType() == 1)
           M = minDistance(vClusters[iClust], vClusters[iClust + 1]);
         else if (settings_->vx_distanceType() == 2)
           M = meanDistance(vClusters[iClust], vClusters[iClust + 1]);
         else
           M = centralDistance(vClusters[iClust], vClusters[iClust + 1]);

         if (M < MinimumScore) {
           MinimumScore = M;
           clusterId0 = iClust;
           clusterId1 = iClust + 1;
         }
       }
       if (MinimumScore > settings_->vx_distance() or vClusters[clusterId1].tracks().empty())
         break;
       for (const L1Track* track : vClusters[clusterId0].tracks()) {
         vClusters[clusterId1].insert(track);
       }
       vClusters.erase(vClusters.begin() + clusterId0);
     }

     for (RecoVertex clust : vClusters) {
       if (clust.numTracks() >= settings_->vx_minTracks()) {
         computeAndSetVertexParameters(clust, {}, {});
         vertices_.push_back(clust);
       }
     }
   }

   void VertexFinder::DBSCAN() {
     // std::vector<RecoVertex> vClusters;
     std::vector<unsigned int> visited;
     std::vector<unsigned int> saved;

     sort(fitTracks_.begin(), fitTracks_.end(), SortTracksByPt());
     iterations_ = 0;

     for (unsigned int i = 0; i < fitTracks_.size(); ++i) {
       if (find(visited.begin(), visited.end(), i) != visited.end())
         continue;

       // if(fitTracks_[i]->pt()>10.){
       visited.push_back(i);
       std::set<unsigned int> neighbourTrackIds;
       unsigned int numDensityTracks = 0;
       if (fitTracks_[i].pt() > settings_->vx_dbscan_pt())
         numDensityTracks++;
       else
         continue;
       for (unsigned int k = 0; k < fitTracks_.size(); ++k) {
         iterations_++;
         if (k != i and std::abs(fitTracks_[k].z0() - fitTracks_[i].z0()) < settings_->vx_distance()) {
           neighbourTrackIds.insert(k);
           if (fitTracks_[k].pt() > settings_->vx_dbscan_pt()) {
             numDensityTracks++;
           }
         }
       }

       if (numDensityTracks < settings_->vx_dbscan_mintracks()) {
         // mark track as noise
       } else {
         RecoVertex vertex;
         vertex.insert(&fitTracks_[i]);
         saved.push_back(i);
         for (unsigned int id : neighbourTrackIds) {
           if (find(visited.begin(), visited.end(), id) == visited.end()) {
             visited.push_back(id);
             std::vector<unsigned int> neighbourTrackIds2;
             for (unsigned int k = 0; k < fitTracks_.size(); ++k) {
               iterations_++;
               if (std::abs(fitTracks_[k].z0() - fitTracks_[id].z0()) < settings_->vx_distance()) {
                 neighbourTrackIds2.push_back(k);
               }
             }

             // if (neighbourTrackIds2.size() >= settings_->vx_minTracks()) {
             for (unsigned int id2 : neighbourTrackIds2) {
               neighbourTrackIds.insert(id2);
             }
             // }
           }
           if (find(saved.begin(), saved.end(), id) == saved.end())
             vertex.insert(&fitTracks_[id]);
         }
         computeAndSetVertexParameters(vertex, {}, {});
         if (vertex.numTracks() >= settings_->vx_minTracks())
           vertices_.push_back(vertex);
       }
       // }
     }
   }

   void VertexFinder::PVR() {
     bool start = true;
     FitTrackCollection discardedTracks, acceptedTracks;
     iterations_ = 0;
     for (const L1Track& track : fitTracks_) {
       acceptedTracks.push_back(track);
     }

     while (discardedTracks.size() >= settings_->vx_minTracks() or start == true) {
       start = false;
       bool removing = true;
       discardedTracks.clear();
       while (removing) {
         float oldDistance = 0.;

         if (settings_->debug() > 2)
           edm::LogInfo("VertexFinder") << "PVR::AcceptedTracks " << acceptedTracks.size();

         float z0start = 0;
         for (const L1Track& track : acceptedTracks) {
           z0start += track.z0();
           iterations_++;
         }

         z0start /= acceptedTracks.size();
         if (settings_->debug() > 2)
           edm::LogInfo("VertexFinder") << "PVR::z0 vertex " << z0start;
         FitTrackCollection::iterator badTrackIt = acceptedTracks.end();
         removing = false;

         for (FitTrackCollection::iterator it = acceptedTracks.begin(); it < acceptedTracks.end(); ++it) {
           const L1Track* track = &*it;
           iterations_++;
           if (std::abs(track->z0() - z0start) > settings_->vx_distance() and
               std::abs(track->z0() - z0start) > oldDistance) {
             badTrackIt = it;
             oldDistance = std::abs(track->z0() - z0start);
             removing = true;
           }
         }

         if (removing) {
           const L1Track badTrack = *badTrackIt;
           if (settings_->debug() > 2)
             edm::LogInfo("VertexFinder") << "PVR::Removing track " << badTrack.z0() << " at distance " << oldDistance;
           discardedTracks.push_back(badTrack);
           acceptedTracks.erase(badTrackIt);
         }
       }

       if (acceptedTracks.size() >= settings_->vx_minTracks()) {
         RecoVertex vertex;
         for (const L1Track& track : acceptedTracks) {
           vertex.insert(&track);
         }
         computeAndSetVertexParameters(vertex, {}, {});
         vertices_.push_back(vertex);
       }
       if (settings_->debug() > 2)
         edm::LogInfo("VertexFinder") << "PVR::DiscardedTracks size " << discardedTracks.size();
       acceptedTracks.clear();
       acceptedTracks = discardedTracks;
     }
   }

   void VertexFinder::adaptiveVertexReconstruction() {
     bool start = true;
     iterations_ = 0;
     FitTrackCollection discardedTracks, acceptedTracks, discardedTracks2;

     for (const L1Track& track : fitTracks_) {
       discardedTracks.push_back(track);
     }

     while (discardedTracks.size() >= settings_->vx_minTracks() or start == true) {
       start = false;
       discardedTracks2.clear();
       FitTrackCollection::iterator it = discardedTracks.begin();
       const L1Track track = *it;
       acceptedTracks.push_back(track);
       float z0sum = track.z0();

       for (FitTrackCollection::iterator it2 = discardedTracks.begin(); it2 < discardedTracks.end(); ++it2) {
         if (it2 != it) {
           const L1Track secondTrack = *it2;
           // Calculate new vertex z0 adding this track
           z0sum += secondTrack.z0();
           float z0vertex = z0sum / (acceptedTracks.size() + 1);
           // Calculate chi2 of new vertex
           float chi2 = 0.;
           float dof = 0.;
           for (const L1Track& accTrack : acceptedTracks) {
             iterations_++;
             float Residual = accTrack.z0() - z0vertex;
             if (std::abs(accTrack.eta()) < 1.2)
               Residual /= 0.1812;  // Assumed z0 resolution
             else if (std::abs(accTrack.eta()) >= 1.2 && std::abs(accTrack.eta()) < 1.6)
               Residual /= 0.2912;
             else if (std::abs(accTrack.eta()) >= 1.6 && std::abs(accTrack.eta()) < 2.)
               Residual /= 0.4628;
             else
               Residual /= 0.65;

             chi2 += Residual * Residual;
             dof = (acceptedTracks.size() + 1) * 2 - 1;
           }
           if (chi2 / dof < settings_->vx_chi2cut()) {
             acceptedTracks.push_back(secondTrack);
           } else {
             discardedTracks2.push_back(secondTrack);
             z0sum -= secondTrack.z0();
           }
         }
       }

       if (acceptedTracks.size() >= settings_->vx_minTracks()) {
         RecoVertex vertex;
         for (const L1Track& track : acceptedTracks) {
           vertex.insert(&track);
         }
         computeAndSetVertexParameters(vertex, {}, {});
         vertices_.push_back(vertex);
       }

       acceptedTracks.clear();
       discardedTracks.clear();
       discardedTracks = discardedTracks2;
     }
   }

   void VertexFinder::HPV() {
     iterations_ = 0;
     sort(fitTracks_.begin(), fitTracks_.end(), SortTracksByPt());

     RecoVertex vertex;
     bool first = true;
     float z = 99.;
     for (const L1Track& track : fitTracks_) {
       if (track.pt() < 50.) {
         if (first) {
           first = false;
           z = track.z0();
           vertex.insert(&track);
         } else {
           if (std::abs(track.z0() - z) < settings_->vx_distance())
             vertex.insert(&track);
         }
       }
     }

     computeAndSetVertexParameters(vertex, {}, {});
     vertex.setZ0(z);
     vertices_.push_back(vertex);
   }

   void VertexFinder::Kmeans() {
     unsigned int NumberOfClusters = settings_->vx_kmeans_nclusters();

     vertices_.resize(NumberOfClusters);
     float ClusterSeparation = 30. / NumberOfClusters;

     for (unsigned int i = 0; i < NumberOfClusters; ++i) {
       float ClusterCentre = -15. + ClusterSeparation * (i + 0.5);
       vertices_[i].setZ0(ClusterCentre);
     }
     unsigned int iterations = 0;
     // Initialise Clusters
     while (iterations < settings_->vx_kmeans_iterations()) {
       for (unsigned int i = 0; i < NumberOfClusters; ++i) {
         vertices_[i].clear();
       }

       for (const L1Track& track : fitTracks_) {
         float distance = 9999;
         if (iterations == settings_->vx_kmeans_iterations() - 3)
           distance = settings_->vx_distance() * 2;
         if (iterations > settings_->vx_kmeans_iterations() - 3)
           distance = settings_->vx_distance();
         unsigned int ClusterId;
         bool NA = true;
         for (unsigned int id = 0; id < NumberOfClusters; ++id) {
           if (std::abs(track.z0() - vertices_[id].z0()) < distance) {
             distance = std::abs(track.z0() - vertices_[id].z0());
             ClusterId = id;
             NA = false;
           }
         }
         if (!NA) {
           vertices_[ClusterId].insert(&track);
         }
       }
       for (unsigned int i = 0; i < NumberOfClusters; ++i) {
         if (vertices_[i].numTracks() >= settings_->vx_minTracks())
           computeAndSetVertexParameters(vertices_[i], {}, {});
       }
       iterations++;
     }
   }

   void VertexFinder::findPrimaryVertex() {
     if (settings_->vx_precision() == Precision::Emulation) {
       pv_index_ = std::distance(verticesEmulation_.begin(),
                                 std::max_element(verticesEmulation_.begin(),
                                                  verticesEmulation_.end(),
                                                  [](const l1t::VertexWord& vertex0, const l1t::VertexWord& vertex1) {
                                                    return (vertex0.pt() < vertex1.pt());
                                                  }));
     } else {
       pv_index_ = std::distance(
           vertices_.begin(),
           std::max_element(
               vertices_.begin(), vertices_.end(), [](const RecoVertex<>& vertex0, const RecoVertex<>& vertex1) {
                 return (vertex0.pt() < vertex1.pt());
               }));
     }
   }

   // Possible Formatting Codes: https://misc.flogisoft.com/bash/tip_colors_and_formatting
   template <class data_type, typename stream_type>
   void VertexFinder::printHistogram(stream_type& stream,
                                     std::vector<data_type> data,
                                     int width,
                                     int minimum,
                                     int maximum,
                                     std::string title,
                                     std::string color) {
     int tableSize = data.size();

     if (maximum == -1) {
       maximum = float(*std::max_element(std::begin(data), std::end(data))) * 1.05;
     } else if (maximum <= minimum) {
       maximum = float(*std::max_element(std::begin(data), std::end(data))) * 1.05;
       minimum = float(*std::min_element(std::begin(data), std::end(data)));
     }

     if (minimum < 0) {
       minimum *= 1.05;
     } else {
       minimum = 0;
     }

     std::vector<std::string> intervals(tableSize, "");
     std::vector<std::string> values(tableSize, "");
     char buffer[128];
     int intervalswidth = 0, valueswidth = 0, tmpwidth = 0;
     for (int i = 0; i < tableSize; i++) {
       //Format the bin labels
       tmpwidth = sprintf(buffer, "[%-.5g, %-.5g)", float(i), float(i + 1));
       intervals[i] = buffer;
       if (i == (tableSize - 1)) {
         intervals[i][intervals[i].size() - 1] = ']';
       }
       if (tmpwidth > intervalswidth)
         intervalswidth = tmpwidth;

       //Format the values
       tmpwidth = sprintf(buffer, "%-.5g", float(data[i]));
       values[i] = buffer;
       if (tmpwidth > valueswidth)
         valueswidth = tmpwidth;
     }

     sprintf(buffer, "%-.5g", float(minimum));
     std::string minimumtext = buffer;
     sprintf(buffer, "%-.5g", float(maximum));
     std::string maximumtext = buffer;

     int plotwidth =
         std::max(int(minimumtext.size() + maximumtext.size()), width - (intervalswidth + 1 + valueswidth + 1 + 2));
     std::string scale =
         minimumtext + std::string(plotwidth + 2 - minimumtext.size() - maximumtext.size(), ' ') + maximumtext;

     float norm = float(plotwidth) / float(maximum - minimum);
     int zero = std::round((0.0 - minimum) * norm);
     std::vector<char> line(plotwidth, '-');

     if ((minimum != 0) && (0 <= zero) && (zero < plotwidth)) {
       line[zero] = '+';
     }
     std::string capstone =
         std::string(intervalswidth + 1 + valueswidth + 1, ' ') + "+" + std::string(line.begin(), line.end()) + "+";

     std::vector<std::string> out;
     if (!title.empty()) {
       out.push_back(title);
       out.push_back(std::string(title.size(), '='));
     }
     out.push_back(std::string(intervalswidth + valueswidth + 2, ' ') + scale);
     out.push_back(capstone);
     for (int i = 0; i < tableSize; i++) {
       std::string interval = intervals[i];
       std::string value = values[i];
       data_type x = data[i];
       std::fill_n(line.begin(), plotwidth, ' ');

       int pos = std::round((float(x) - minimum) * norm);
       if (x < 0) {
         std::fill_n(line.begin() + pos, zero - pos, '*');
       } else {
         std::fill_n(line.begin() + zero, pos - zero, '*');
       }

       if ((minimum != 0) && (0 <= zero) && (zero < plotwidth)) {
         line[zero] = '|';
       }

       sprintf(buffer,
               "%-*s %-*s |%s|",
               intervalswidth,
               interval.c_str(),
               valueswidth,
               value.c_str(),
               std::string(line.begin(), line.end()).c_str());
       out.push_back(buffer);
     }
     out.push_back(capstone);
     if (!color.empty())
       stream << color;
     for (const auto& o : out) {
       stream << o << "\n";
     }
     if (!color.empty())
       stream << "\e[0m";
     stream << "\n";
   }

   void VertexFinder::sortVerticesInPt() {
     if (settings_->vx_precision() == Precision::Emulation) {
       std::sort(
           verticesEmulation_.begin(),
           verticesEmulation_.end(),
           [](const l1t::VertexWord& vertex0, const l1t::VertexWord& vertex1) { return (vertex0.pt() > vertex1.pt()); });
     } else {
       std::sort(vertices_.begin(), vertices_.end(), [](const RecoVertex<>& vertex0, const RecoVertex<>& vertex1) {
         return (vertex0.pt() > vertex1.pt());
       });
     }
   }

   void VertexFinder::sortVerticesInZ0() {
     if (settings_->vx_precision() == Precision::Emulation) {
       std::sort(
           verticesEmulation_.begin(),
           verticesEmulation_.end(),
           [](const l1t::VertexWord& vertex0, const l1t::VertexWord& vertex1) { return (vertex0.z0() < vertex1.z0()); });
     } else {
       std::sort(vertices_.begin(), vertices_.end(), [](const RecoVertex<>& vertex0, const RecoVertex<>& vertex1) {
         return (vertex0.z0() < vertex1.z0());
       });
     }
   }

   void VertexFinder::associatePrimaryVertex(double trueZ0) {
     double distance = 999.;
     for (unsigned int id = 0; id < vertices_.size(); ++id) {
       if (std::abs(trueZ0 - vertices_[id].z0()) < distance) {
         distance = std::abs(trueZ0 - vertices_[id].z0());
         pv_index_ = id;
       }
     }
   }

   void VertexFinder::fastHistoLooseAssociation() {
     float vxPt = 0.;
     RecoVertex leading_vertex;

     for (float z = settings_->vx_histogram_min(); z < settings_->vx_histogram_max();
          z += settings_->vx_histogram_binwidth()) {
       RecoVertex vertex;
       for (const L1Track& track : fitTracks_) {
         if (std::abs(z - track.z0()) < settings_->vx_width()) {
           vertex.insert(&track);
         }
       }
       computeAndSetVertexParameters(vertex, {}, {});
       vertex.setZ0(z);
       if (vertex.pt() > vxPt) {
         leading_vertex = vertex;
         vxPt = vertex.pt();
       }
     }

     vertices_.emplace_back(leading_vertex);
     pv_index_ = 0;  // by default fastHistoLooseAssociation algorithm finds only hard PV
   }                 // end of fastHistoLooseAssociation

   void VertexFinder::fastHisto(const TrackerTopology* tTopo) {
     // Create the histogram
     int nbins =
         std::ceil((settings_->vx_histogram_max() - settings_->vx_histogram_min()) / settings_->vx_histogram_binwidth());
     std::vector<RecoVertex<>> hist(nbins);
     std::vector<RecoVertex<>> sums(nbins - settings_->vx_windowSize() + 1);
     std::vector<float> bounds(nbins + 1);
     strided_iota(std::begin(bounds),
                  std::next(std::begin(bounds), nbins + 1),
                  settings_->vx_histogram_min(),
                  settings_->vx_histogram_binwidth());

     // Loop over the tracks and fill the histogram
     for (const L1Track& track : fitTracks_) {
       if ((track.z0() < settings_->vx_histogram_min()) || (track.z0() > settings_->vx_histogram_max()))
         continue;
       if (track.getTTTrackPtr()->chi2() > settings_->vx_TrackMaxChi2())
         continue;
       if (track.pt() < settings_->vx_TrackMinPt())
         continue;

       // Get the number of stubs and the number of stubs in PS layers
       float nPS = 0., nstubs = 0;

       // Get pointers to stubs associated to the L1 track
       const auto& theStubs = track.getTTTrackPtr()->getStubRefs();
       if (theStubs.empty()) {
         edm::LogWarning("VertexFinder") << "fastHisto::Could not retrieve the vector of stubs.";
         continue;
       }

       // Loop over the stubs
       for (const auto& stub : theStubs) {
         nstubs++;
         bool isPS = false;
         DetId detId(stub->getDetId());
         if (detId.det() == DetId::Detector::Tracker) {
           if (detId.subdetId() == StripSubdetector::TOB && tTopo->tobLayer(detId) <= 3)
             isPS = true;
           else if (detId.subdetId() == StripSubdetector::TID && tTopo->tidRing(detId) <= 9)
             isPS = true;
         }
         if (isPS)
           nPS++;
       }  // End loop over stubs
       if (nstubs < settings_->vx_NStubMin())
         continue;
       if (nPS < settings_->vx_NStubPSMin())
         continue;

       // Quality cuts, may need to be re-optimized
       int trk_nstub = (int)track.getTTTrackPtr()->getStubRefs().size();
       float chi2dof = track.getTTTrackPtr()->chi2() / (2 * trk_nstub - 4);

       if (settings_->vx_DoPtComp()) {
         float trk_consistency = track.getTTTrackPtr()->stubPtConsistency();
         if (trk_nstub == 4) {
           if (std::abs(track.eta()) < 2.2 && trk_consistency > 10)
             continue;
           else if (std::abs(track.eta()) > 2.2 && chi2dof > 5.0)
             continue;
         }
       }
       if (settings_->vx_DoTightChi2()) {
         if (track.pt() > 10.0 && chi2dof > 5.0)
           continue;
       }

       // Assign the track to the correct vertex
       // The values are ordered with bounds [lower, upper)
       // Values below bounds.begin() return 0 as the index (underflow)
       // Values above bounds.end() will return the index of the last bin (overflow)
       auto upper_bound = std::upper_bound(bounds.begin(), bounds.end(), track.z0());
       int index = std::distance(bounds.begin(), upper_bound) - 1;
       if (index == -1)
         index = 0;
       hist.at(index).insert(&track);
     }  // end loop over tracks

     // Compute the sums
     // sliding windows ... sum_i_i+(w-1) where i in (0,nbins-w) and w is the window size
     std::vector<float> bin_centers(settings_->vx_windowSize(), 0.0);
     std::vector<unsigned int> counts(settings_->vx_windowSize(), 0);
     for (unsigned int i = 0; i < sums.size(); i++) {
       for (unsigned int j = 0; j < settings_->vx_windowSize(); j++) {
         bin_centers[j] = settings_->vx_histogram_min() + ((i + j) * settings_->vx_histogram_binwidth()) +
                          (0.5 * settings_->vx_histogram_binwidth());
         counts[j] = hist.at(i + j).numTracks();
         sums.at(i) += hist.at(i + j);
       }
       computeAndSetVertexParameters(sums.at(i), bin_centers, counts);
     }

     // Find the maxima of the sums
     float sigma_max = -999;
     int imax = -999;
     std::vector<int> found;
     found.reserve(settings_->vx_nvtx());
     for (unsigned int ivtx = 0; ivtx < settings_->vx_nvtx(); ivtx++) {
       sigma_max = -999;
       imax = -999;
       for (unsigned int i = 0; i < sums.size(); i++) {
         // Skip this window if it will already be returned
         if (find(found.begin(), found.end(), i) != found.end())
           continue;
         if (sums.at(i).pt() > sigma_max) {
           sigma_max = sums.at(i).pt();
           imax = i;
         }
       }
       found.push_back(imax);
       vertices_.emplace_back(sums.at(imax));
     }
     pv_index_ = 0;

     if (settings_->debug() >= 1) {
       edm::LogInfo log("VertexProducer");
       log << "fastHisto::Checking the output parameters ... \n";
       std::vector<double> tmp;
       std::transform(std::begin(sums), std::end(sums), std::back_inserter(tmp), [](const RecoVertex<>& v) -> double {
         return v.pt();
       });
       printHistogram<double, edm::LogInfo>(log, tmp, 80, 0, -1, "fastHisto::sums", "\e[92m");
       for (unsigned int i = 0; i < found.size(); i++) {
         log << "RecoVertex " << i << ": bin index = " << found[i] << "\tsumPt = " << sums.at(imax).pt()
             << "\tz0 = " << sums.at(imax).z0();
       }
     }
   }  // end of fastHisto

   void VertexFinder::fastHistoEmulation() {
     // Relevant constants for the track word
     enum TrackBitWidths {
       kZ0Size = 12,             // Width of z-position (40cm / 0.1)
       kZ0MagSize = 5,           // Width of z-position magnitude (signed)
       kPtSize = 14,             // Width of pt
       kPtMagSize = 9,           // Width of pt magnitude (unsigned)
       kReducedPrecisionPt = 7,  // Width of the reduced precision, integer only, pt
     };

     enum HistogramBitWidths {
       kBinSize = 8,                     // Width of a single bin in z
       kBinFixedSize = 8,                // Width of a single z0 bin in fixed point representation
       kBinFixedMagSize = 5,             // Width (magnitude) of a single z0 bin in fixed point representation
       kSlidingSumSize = 11,             // Width of the sum of a window of bins
       kInverseSize = 14,                // Width of the inverse sum
       kInverseMagSize = 1,              // Width of the inverse sum magnitude (unsigned)
       kWeightedSlidingSumSize = 20,     // Width of the pT weighted sliding sum
       kWeightedSlidingSumMagSize = 10,  // Width of the pT weighted sliding sum magnitude (signed)
       kWindowSize = 3,                  // Number of bins in the window used to sum histogram bins
       kSumPtLinkSize = 9,  // Number of bits used to represent the sum of track pts in a single bin from a single link

       kSumPtWindowBits = BitsToRepresent(HistogramBitWidths::kWindowSize * (1 << HistogramBitWidths::kSumPtLinkSize)),
       // Number of bits to represent the untruncated sum of track pts in a single bin from a single link
       kSumPtUntruncatedLinkSize = TrackBitWidths::kPtSize + 2,
       kSumPtUntruncatedLinkMagSize = TrackBitWidths::kPtMagSize + 2,
     };

     static constexpr unsigned int kTableSize =
         ((1 << HistogramBitWidths::kSumPtLinkSize) - 1) * HistogramBitWidths::kWindowSize;

     typedef ap_ufixed<TrackBitWidths::kPtSize, TrackBitWidths::kPtMagSize, AP_RND_CONV, AP_SAT> pt_t;
     // Same size as TTTrack_TrackWord::z0_t, but now taking into account the sign bit (i.e. 2's complement)
     typedef ap_int<TrackBitWidths::kZ0Size> z0_t;
     // 7 bits chosen to represent values between [0,127]
     // This is the next highest power of 2 value to our chosen track pt saturation value (100)
     typedef ap_ufixed<TrackBitWidths::kReducedPrecisionPt, TrackBitWidths::kReducedPrecisionPt, AP_RND_INF, AP_SAT>
         track_pt_fixed_t;
     // Histogram bin index
     typedef ap_uint<HistogramBitWidths::kBinSize> histbin_t;
     // Histogram bin in fixed point representation, before truncation
     typedef ap_ufixed<HistogramBitWidths::kBinFixedSize, HistogramBitWidths::kBinFixedMagSize, AP_RND_INF, AP_SAT>
         histbin_fixed_t;
     // This type is slightly arbitrary, but 2 bits larger than untruncated track pt to store sums in histogram bins
     // with truncation just before vertex-finding
     typedef ap_ufixed<HistogramBitWidths::kSumPtUntruncatedLinkSize,
                       HistogramBitWidths::kSumPtUntruncatedLinkMagSize,
                       AP_RND_INF,
                       AP_SAT>
         histbin_pt_sum_fixed_t;
     // This value is slightly arbitrary, but small enough that the windows sums aren't too big.
     typedef ap_ufixed<HistogramBitWidths::kSumPtLinkSize, HistogramBitWidths::kSumPtLinkSize, AP_RND_INF, AP_SAT>
         link_pt_sum_fixed_t;
     // Enough bits to store HistogramBitWidths::kWindowSize * (2**HistogramBitWidths::kSumPtLinkSize)
     typedef ap_ufixed<HistogramBitWidths::kSumPtWindowBits, HistogramBitWidths::kSumPtWindowBits, AP_RND_INF, AP_SAT>
         window_pt_sum_fixed_t;
     // pt weighted sum of bins in window
     typedef ap_fixed<HistogramBitWidths::kWeightedSlidingSumSize,
                      HistogramBitWidths::kWeightedSlidingSumMagSize,
                      AP_RND_INF,
                      AP_SAT>
         zsliding_t;
     // Sum of histogram bins in window
     typedef ap_uint<HistogramBitWidths::kSlidingSumSize> slidingsum_t;
     // Inverse of sum of bins in a given window
     typedef ap_ufixed<HistogramBitWidths::kInverseSize, HistogramBitWidths::kInverseMagSize, AP_RND_INF, AP_SAT>
         inverse_t;

     auto track_quality_check = [&](const track_pt_fixed_t& pt) -> bool {
       // Track quality cuts
       if (pt.to_double() < settings_->vx_TrackMinPt())
         return false;
       return true;
     };

     auto fetch_bin = [&](const z0_t& z0, int nbins) -> std::pair<histbin_t, bool> {
       // Increase the the number of bits in the word to allow for additional dynamic range
       ap_int<TrackBitWidths::kZ0Size + 1> z0_13 = z0;
       // Add a number equal to half of the range in z0, meaning that the range is now [0, 2*z0_max]
       ap_int<TrackBitWidths::kZ0Size + 1> absz0_13 = z0_13 + (1 << (TrackBitWidths::kZ0Size - 1));
       // Shift the bits down to truncate the dynamic range to the most significant HistogramBitWidths::kBinFixedSize bits
       ap_int<TrackBitWidths::kZ0Size + 1> absz0_13_reduced =
           absz0_13 >> (TrackBitWidths::kZ0Size - HistogramBitWidths::kBinFixedSize);
       // Put the relevant bits into the histbin_t container
       histbin_t bin = absz0_13_reduced.range(HistogramBitWidths::kBinFixedSize - 1, 0);

       if (settings_->debug() > 2) {
         edm::LogInfo("VertexProducer")
             << "fastHistoEmulation::fetchBin() Checking the mapping from z0 to bin index ... \n"
             << "histbin_fixed_t(1.0 / settings_->vx_histogram_binwidth()) = "
             << histbin_fixed_t(1.0 / settings_->vx_histogram_binwidth()) << "\n"
             << "histbin_t(std::floor(nbins / 2) = " << histbin_t(std::floor(nbins / 2.)) << "\n"
             << "z0 = " << z0 << "\n"
             << "bin = " << bin;
       }
       bool valid = true;
       if (bin < 0) {
         return std::make_pair(0, false);
       } else if (bin > (nbins - 1)) {
         return std::make_pair(0, false);
       }
       return std::make_pair(bin, valid);
     };

     // Replace with https://stackoverflow.com/questions/13313980/populate-an-array-using-constexpr-at-compile-time ?
     auto init_inversion_table = [&]() -> std::vector<inverse_t> {
       std::vector<inverse_t> table_out(kTableSize, 0.);
       for (unsigned int ii = 0; ii < kTableSize; ii++) {
         // Compute lookup table function. This matches the format of the GTT HLS code.
         // Biased generation f(x) = 1 / (x + 1) is inverted by g(y) = inversion(x - 1) = 1 / (x - 1 + 1) = 1 / y
         table_out.at(ii) = (1.0 / (ii + 1));
       }
       return table_out;
     };

     auto inversion = [&](slidingsum_t& data_den) -> inverse_t {
       std::vector<inverse_t> inversion_table = init_inversion_table();

       // Index into the lookup table based on data
       int index;
       if (data_den < 0)
         data_den = 0;
       if (data_den > (kTableSize - 1))
         data_den = kTableSize - 1;
       index = data_den;
       return inversion_table.at(index);
     };

     auto bin_center = [&](zsliding_t iz, int nbins) -> l1t::VertexWord::vtxz0_t {
       zsliding_t z = iz - histbin_t(std::floor(nbins / 2.));
       std::unique_ptr<edm::LogInfo> log;
       if (settings_->debug() >= 1) {
         log = std::make_unique<edm::LogInfo>("VertexProducer");
         *log << "bin_center information ...\n"
              << "iz = " << iz << "\n"
              << "histbin_t(std::floor(nbins / 2.)) = " << histbin_t(std::floor(nbins / 2.)) << "\n"
              << "binwidth = " << zsliding_t(settings_->vx_histogram_binwidth()) << "\n"
              << "z = " << z << "\n"
              << "zsliding_t(z * zsliding_t(binwidth)) = " << std::setprecision(7)
              << l1t::VertexWord::vtxz0_t(z * zsliding_t(settings_->vx_histogram_binwidth()));
       }
       return l1t::VertexWord::vtxz0_t(z * zsliding_t(settings_->vx_histogram_binwidth()));
     };

     auto weighted_position = [&](histbin_t b_max,
                                  const std::vector<link_pt_sum_fixed_t>& binpt,
                                  slidingsum_t maximums,
                                  int nbins) -> zsliding_t {
       zsliding_t zvtx_sliding = 0;
       slidingsum_t zvtx_sliding_sum = 0;
       inverse_t inv = 0;

       std::unique_ptr<edm::LogInfo> log;
       if (settings_->debug() >= 1) {
         log = std::make_unique<edm::LogInfo>("VertexProducer");
         *log << "Progression of weighted_position() ...\n"
              << "zvtx_sliding_sum = ";
       }

       // Find the weighted position within the window in index space (width = 1)
       for (ap_uint<BitsToRepresent(HistogramBitWidths::kWindowSize)> w = 0; w < HistogramBitWidths::kWindowSize; ++w) {
         zvtx_sliding_sum += (binpt.at(w) * w);
         if (settings_->debug() >= 1) {
           *log << "(" << w << " * " << binpt.at(w) << ")";
           if (w < HistogramBitWidths::kWindowSize - 1) {
             *log << " + ";
           }
         }
       }

       if (settings_->debug() >= 1) {
         *log << " = " << zvtx_sliding_sum << "\n";
       }

       if (maximums != 0) {
         //match F/W inversion_lut offset (inversion[x] = 1 / (x + 1); inversion[x - 1] = 1 / x;), for consistency
         slidingsum_t offsetmaximums = maximums - 1;
         inv = inversion(offsetmaximums);
         zvtx_sliding = zvtx_sliding_sum * inv;
       } else {
         zvtx_sliding = (settings_->vx_windowSize() / 2.0) + (((int(settings_->vx_windowSize()) % 2) != 0) ? 0.5 : 0.0);
       }
       if (settings_->debug() >= 1) {
         *log << "inversion(" << maximums << ") = " << inv << "\nzvtx_sliding = " << zvtx_sliding << "\n";
       }

       // Add the starting index plus half an index to shift the z position to its weighted position (still in inxex space) within all of the bins
       zvtx_sliding += b_max;
       zvtx_sliding += ap_ufixed<1, 0>(0.5);
       if (settings_->debug() >= 1) {
         *log << "b_max = " << b_max << "\n";
         *log << "zvtx_sliding + b_max + 0.5 = " << zvtx_sliding << "\n";
       }

       // Shift the z position from index space into z [cm] space
       zvtx_sliding = bin_center(zvtx_sliding, nbins);
       if (settings_->debug() >= 1) {
         *log << "bin_center(zvtx_sliding + b_max + 0.5, nbins) = " << std::setprecision(7) << zvtx_sliding;
         log.reset();
       }
       return zvtx_sliding;
     };

     // Create the histogram
     unsigned int nbins = std::round((settings_->vx_histogram_max() - settings_->vx_histogram_min()) /
                                     settings_->vx_histogram_binwidth());
     unsigned int nsums = nbins - settings_->vx_windowSize() + 1;
     std::vector<link_pt_sum_fixed_t> hist(nbins, 0);
     std::vector<histbin_pt_sum_fixed_t> hist_untruncated(nbins, 0);

     // Loop over the tracks and fill the histogram
     if (settings_->debug() > 2) {
       edm::LogInfo("VertexProducer") << "fastHistoEmulation::Processing " << fitTracks_.size() << " tracks";
     }
     for (const L1Track& track : fitTracks_) {
       // Get the track pt and z0
       // Convert them to an appropriate data format
       // Truncation and saturation taken care of by the data type specification, now delayed to end of histogramming
       pt_t tkpt = 0;
       tkpt.V = track.getTTTrackPtr()->getTrackWord()(TTTrack_TrackWord::TrackBitLocations::kRinvMSB - 1,
                                                      TTTrack_TrackWord::TrackBitLocations::kRinvLSB);
       z0_t tkZ0 = track.getTTTrackPtr()->getZ0Word();

       if ((settings_->vx_DoQualityCuts() && track_quality_check(tkpt)) || (!settings_->vx_DoQualityCuts())) {
         //
         // Check bin validity of bin found for the current track
         //
         std::pair<histbin_t, bool> bin = fetch_bin(tkZ0, nbins);
         assert(bin.first >= 0 && bin.first < nbins);

         //
         // If the bin is valid then sum the tracks
         //
         if (settings_->debug() > 2) {
           edm::LogInfo("VertexProducer") << "fastHistoEmulation::Checking the track word ... \n"
                                          << "track word = " << track.getTTTrackPtr()->getTrackWord().to_string(2)
                                          << "\n"
                                          << "tkZ0 = " << tkZ0.to_double() << "(" << tkZ0.to_string(2)
                                          << ")\ttkpt = " << tkpt.to_double() << "(" << tkpt.to_string(2)
                                          << ")\tbin = " << bin.first.to_int() << "\n"
                                          << "pt sum in bin " << bin.first.to_int()
                                          << " BEFORE adding track = " << hist_untruncated.at(bin.first).to_double();
         }
         if (bin.second) {
           hist_untruncated.at(bin.first) = hist_untruncated.at(bin.first) + tkpt;
         }
         if (settings_->debug() > 2) {
           edm::LogInfo("VertexProducer") << "fastHistoEmulation::\npt sum in bin " << bin.first.to_int()
                                          << " AFTER adding track = " << hist_untruncated.at(bin.first).to_double();
         }
       } else {
         if (settings_->debug() > 2) {
           edm::LogInfo("VertexProducer") << "fastHistoEmulation::Did not add the following track ... \n"
                                          << "track word = " << track.getTTTrackPtr()->getTrackWord().to_string(2)
                                          << "\n"
                                          << "tkZ0 = " << tkZ0.to_double() << "(" << tkZ0.to_string(2)
                                          << ")\ttkpt = " << tkpt.to_double() << "(" << tkpt.to_string(2) << ")";
         }
       }
     }  // end loop over tracks

     // HLS histogramming used to truncate track pt before adding, using
     // track_pt_fixed_t pt_tmp = tkpt;
     // Now, truncation should happen after histograms are filled but prior to the vertex-finding part of the algo
     for (unsigned int hb = 0; hb < hist.size(); ++hb) {
       link_pt_sum_fixed_t bin_trunc = hist_untruncated.at(hb).range(
           HistogramBitWidths::kSumPtUntruncatedLinkSize - 1,
           HistogramBitWidths::kSumPtUntruncatedLinkSize - HistogramBitWidths::kSumPtUntruncatedLinkMagSize);
       hist.at(hb) = bin_trunc;
       if (settings_->debug() > 2) {
         edm::LogInfo("VertexProducer") << "fastHistoEmulation::truncating histogram bin pt once filling is complete \n"
                                        << "hist_untruncated.at(" << hb << ") = " << hist_untruncated.at(hb).to_double()
                                        << "(" << hist_untruncated.at(hb).to_string(2)
                                        << ")\tbin_trunc = " << bin_trunc.to_double() << "(" << bin_trunc.to_string(2)
                                        << ")\n\thist.at(" << hb << ") = " << hist.at(hb).to_double() << "("
                                        << hist.at(hb).to_string(2) << ")";
       }
     }

     // Loop through all bins, taking into account the fact that the last bin is nbins-window_width+1,
     // and compute the sums using sliding windows ... sum_i_i+(w-1) where i in (0,nbins-w) and w is the window size
     std::vector<window_pt_sum_fixed_t> hist_window_sums(nsums, 0);
     for (unsigned int b = 0; b < nsums; ++b) {
       for (unsigned int w = 0; w < HistogramBitWidths::kWindowSize; ++w) {
         unsigned int index = b + w;
         hist_window_sums.at(b) += hist.at(index);
       }
     }

     // Find the top N vertices
     std::vector<int> found;
     found.reserve(settings_->vx_nvtx());
     for (unsigned int ivtx = 0; ivtx < settings_->vx_nvtx(); ivtx++) {
       histbin_t b_max = 0;
       window_pt_sum_fixed_t max_pt = 0;
       zsliding_t zvtx_sliding = -999;
       std::vector<link_pt_sum_fixed_t> binpt_max(HistogramBitWidths::kWindowSize, 0);

       // Find the maxima of the sums
       for (unsigned int i = 0; i < hist_window_sums.size(); i++) {
         // Skip this window if it will already be returned
         if (find(found.begin(), found.end(), i) != found.end())
           continue;
         if (hist_window_sums.at(i) > max_pt) {
           b_max = i;
           max_pt = hist_window_sums.at(b_max);
           std::copy(std::begin(hist) + b_max,
                     std::begin(hist) + b_max + HistogramBitWidths::kWindowSize,
                     std::begin(binpt_max));

           // Find the weighted position only for the highest sum pt window
           zvtx_sliding = weighted_position(b_max, binpt_max, max_pt, nbins);
         }
       }
       if (settings_->debug() >= 1) {
         edm::LogInfo log("VertexProducer");
         log << "fastHistoEmulation::Checking the output parameters ... \n";
         if (found.empty()) {
           printHistogram<link_pt_sum_fixed_t, edm::LogInfo>(log, hist, 80, 0, -1, "fastHistoEmulation::hist", "\e[92m");
           printHistogram<window_pt_sum_fixed_t, edm::LogInfo>(
               log, hist_window_sums, 80, 0, -1, "fastHistoEmulation::hist_window_sums", "\e[92m");
         }
         printHistogram<link_pt_sum_fixed_t, edm::LogInfo>(
             log, binpt_max, 80, 0, -1, "fastHistoEmulation::binpt_max", "\e[92m");
         log << "bin index (not a VertexWord parameter) = " << b_max << "\n"
             << "sumPt = " << max_pt.to_double() << "\n"
             << "z0 = " << zvtx_sliding.to_double();
       }
       found.push_back(b_max);
       verticesEmulation_.emplace_back(l1t::VertexWord::vtxvalid_t(1),
                                       l1t::VertexWord::vtxz0_t(zvtx_sliding),
                                       l1t::VertexWord::vtxmultiplicity_t(0),
                                       l1t::VertexWord::vtxsumpt_t(max_pt),
                                       l1t::VertexWord::vtxquality_t(0),
                                       l1t::VertexWord::vtxinversemult_t(0),
                                       l1t::VertexWord::vtxunassigned_t(0));
     }
     pv_index_ = 0;
   }  // end of fastHistoEmulation

 }  // namespace l1tVertexFinder
start
Definition: start.py:1

writeEcalDQMStatus.interval
interval
Definition: writeEcalDQMStatus.py:27

reco::ceil
constexpr int32_t ceil(float num)
Definition: constexpr_cmath.h:7

l1tVertexFinder::RecoVertex::pt
double pt() const
Sum of fitted tracks transverse momentum [GeV].
Definition: RecoVertex.h:55

jetUpdater_cfi.sort
sort
Definition: jetUpdater_cfi.py:30

TrackerTopology::tobLayer
unsigned int tobLayer(const DetId &id) const
Definition: TrackerTopology.h:149

ecal::multifit::data_type
::ecal::reco::ComputationScalarType data_type
Definition: EigenMatrixTypes_gpu.h:17

bphysicsOniaDQM_cfi.vertex
vertex
Definition: bphysicsOniaDQM_cfi.py:7

RecoVertex
Definition: ConvertError.h:7

mps_fire.i
i
Definition: mps_fire.py:429

l1t::VertexWord::vtxunassigned_t
ap_uint< VertexBitWidths::kUnassignedSize > vtxunassigned_t
Definition: VertexWord.h:73

HLT_2024v13_cff.track
track
Definition: HLT_2024v13_cff.py:9664

dqmiolumiharvest.j
j
Definition: dqmiolumiharvest.py:66

w
T w() const
Definition: extBasic3DVector.h:225

l1t::VertexWord::vtxmultiplicity_t
ap_ufixed< VertexBitWidths::kNTrackInPVSize, VertexBitWidths::kNTrackInPVSize, AP_RND_CONV, AP_SAT > vtxmultiplicity_t
Definition: VertexWord.h:67

nano_mu_local_reco_cff.chi2
chi2
Definition: nano_mu_local_reco_cff.py:193

edmScanValgrind.buffer
buffer
Definition: edmScanValgrind.py:171

LaserClient_cfi.nbins
nbins
Definition: LaserClient_cfi.py:53

TrackerTopology
Definition: TrackerTopology.h:16

l1tVertexFinder::FitTrackCollection
std::vector< L1Track > FitTrackCollection
Definition: VertexFinder.h:23

std
Definition: JetResolutionObject.h:76

HltBtagValidation_cff.Vertex
Vertex
Definition: HltBtagValidation_cff.py:34

l1tVertexFinder::RecoVertex::z0
double z0() const
Vertex z0 position [cm].
Definition: RecoVertex.h:75

particleFlowClusterHGC_cfi.maxDistance
maxDistance
Definition: particleFlowClusterHGC_cfi.py:23

align::Tracker
Definition: StructureType.h:70

findQualityFiles.v
v
Definition: findQualityFiles.py:179

l1ctLayer2EG_cff.id
id
Definition: l1ctLayer2EG_cff.py:85

cms::cuda::stream
uint32_t T const  *__restrict__ uint32_t const  *__restrict__ int32_t int Histo::index_type cudaStream_t stream
Definition: HistoContainer.h:51

ALPAKA_ACCELERATOR_NAMESPACE::brokenline::constexpr
if constexpr(n > 3)
Definition: BrokenLine.h:164

spr::find
void find(edm::Handle< EcalRecHitCollection > &hits, DetId thisDet, std::vector< EcalRecHitCollection::const_iterator > &hit, bool debug=false)
Definition: FindCaloHit.cc:19

cms::cuda::assert
assert(be >=bs)

GetRecoTauVFromDQM_MC_cff.next
next
Definition: GetRecoTauVFromDQM_MC_cff.py:31

bounds
bounds
Definition: SiStripHitEfficiencyHelpers.h:25

VertexFinder.h

l1tVertexFinder::RecoVertex::tracks
const std::vector< const T * > & tracks() const
Tracks in the vertex.
Definition: RecoVertex.h:57

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string string
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The Signals That Services Can Subscribe To This is based on ActivityRegistry and is current per Services can connect to the signals distributed by the ActivityRegistry in order to monitor the activity of the application Each possible callback has some defined which we here list in angle e< void, edm::EventID const  &, edm::Timestamp const  & > We also list in braces which AR_WATCH_USING_METHOD_ is used for those or
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