FastPrunePlugin.cc

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//
// Implements the FastPrunePlugin class.  See FastPrunePlugin.hh for a
//   description.
//
 
#include "RecoJets/JetAlgorithms/interface/FastPrunePlugin.hh"
 
#include <sstream>
#include <cmath>
#include <vector>
#include <algorithm>
using namespace std;
 
using namespace fastjet;
 
FastPrunePlugin::FastPrunePlugin(const JetDefinition& find_definition,
                                 const JetDefinition& prune_definition,
                                 const double& zcut,
                                 const double& Rcut_factor)
    : _find_definition(find_definition),
      _prune_definition(prune_definition),
      _minpT(20.),
      _unpruned_seq(nullptr),
      _pruned_recombiner(nullptr),
      _cut_setter(new DefaultCutSetter(zcut, Rcut_factor)) {
  // If the passed prune_definition (copied into _prune_def) has an external
  // recombiner, use it.  Otherwise, create our own DefaultRecombiner.  We
  // could just point to _prune_definition's DefaultRecombiner, but FastJet
  // actually sets this to use external_scheme later when we set
  // _prune_definition's Recombiner to be a PrunedRecombiner.  (Calling
  // JetDefinition::set_recombiner() also calls jetdef._default_recombiner =
  // DefaultRecombiner(external_scheme) as a sanity check to keep you from
  // using it.)
  RecombinationScheme scheme = _prune_definition.recombination_scheme();
  if (scheme == external_scheme)
    _pruned_recombiner = new PrunedRecombiner(_prune_definition.recombiner(), zcut, 0.0);
  else
    _pruned_recombiner = new PrunedRecombiner(scheme, zcut, 0.0);
}
 
FastPrunePlugin::FastPrunePlugin(const JetDefinition& find_definition,
                                 const JetDefinition& prune_definition,
                                 const JetDefinition::Recombiner* recomb,
                                 const double& zcut,
                                 const double& Rcut_factor)
    : _find_definition(find_definition),
      _prune_definition(prune_definition),
      _minpT(20.),
      _unpruned_seq(nullptr),
      _pruned_recombiner(new PrunedRecombiner(recomb, zcut, 0.0)),
      _cut_setter(new DefaultCutSetter(zcut, Rcut_factor)) {}
 
FastPrunePlugin::FastPrunePlugin(const JetDefinition& find_definition,
                                 const JetDefinition& prune_definition,
                                 CutSetter* const cut_setter)
    : _find_definition(find_definition),
      _prune_definition(prune_definition),
      _minpT(20.),
      _unpruned_seq(nullptr),
      _pruned_recombiner(nullptr),
      _cut_setter(cut_setter) {
  // See comments in first constructor
  RecombinationScheme scheme = _prune_definition.recombination_scheme();
  if (scheme == external_scheme)
    _pruned_recombiner = new PrunedRecombiner(_prune_definition.recombiner());
  else
    _pruned_recombiner = new PrunedRecombiner(scheme);
}
 
FastPrunePlugin::FastPrunePlugin(const JetDefinition& find_definition,
                                 const JetDefinition& prune_definition,
                                 CutSetter* const cut_setter,
                                 const JetDefinition::Recombiner* recomb)
    : _find_definition(find_definition),
      _prune_definition(prune_definition),
      _minpT(20.),
      _unpruned_seq(nullptr),
      _pruned_recombiner(new PrunedRecombiner(recomb)),
      _cut_setter(cut_setter) {}
 
string FastPrunePlugin::description() const {
  ostringstream desc;
 
  desc << "Pruned jet algorithm \n"
       << "----------------------- \n"
       << "Jet finder: " << _find_definition.description() << "\n----------------------- \n"
       << "Prune jets with: " << _prune_definition.description() << "\n----------------------- \n"
       << "Pruning parameters: "
       << "zcut = " << _cut_setter->zcut << ", "
       << "Rcut_factor = ";
  if (DefaultCutSetter* cs = dynamic_cast<DefaultCutSetter*>(_cut_setter))
    desc << cs->Rcut_factor;
  else
    desc << "[dynamic]";
  desc << "\n"
       << "----------------------- \n";
 
  return desc.str();
}
 
// Meat of the plugin.  This function takes the input particles from input_seq
//   and calls plugin_record_{ij, iB}_recombination repeatedly such that
//   input_seq holds a cluster sequence corresponding to pruned jets
// This function first creates unpruned jets using _find_definition, then uses
//   the prune_definition, along with the PrunedRecombiner, on each jet to
//   produce a pruned jet.  For each of these jets, output_mergings() is called,
//   which reads the history of the pruned sequence and calls the
//   plugin_record functions of input_seq to match this history.
// Branches that are pruned appear in the history as PseudoJets with no
//   children.  For this reason, only inclusive_jets() is sensible to use with
//   the final ClusterSequence.  The substructure, e.g., constituents() of a
//   pruned jet will not include the pruned away branchings.
void FastPrunePlugin::run_clustering(ClusterSequence& input_seq) const {
  // this will be filled in the output_mergings() step
  _pruned_subjets.clear();
 
  vector<PseudoJet> inputs = input_seq.jets();
  // Record user_index's so we can match PJ's in pruned jets to PJ's in
  //   input_seq.
  // Use i+1 to distinguish from the default, which in some places appears to
  //   be 0.
  // Note that we're working with a local copy of the input jets, so we don't
  //   change the indices in input_seq.
  for (unsigned int i = 0; i < inputs.size(); i++)
    inputs[i].set_user_index(i + 1);
 
  // ClusterSequence for initial (unpruned) jet finding
  if (_unpruned_seq)
    delete _unpruned_seq;
  _unpruned_seq = new ClusterSequence(inputs, _find_definition);
 
  // now, for each jet, construct a pruned version:
  vector<PseudoJet> unpruned_jets = sorted_by_pt(_unpruned_seq->inclusive_jets(_minpT));
 
  for (unsigned int i = 0; i < unpruned_jets.size(); i++) {
    _cut_setter->SetCuts(unpruned_jets[i], *_unpruned_seq);
    _pruned_recombiner->reset(_cut_setter->zcut, _cut_setter->Rcut);
    _prune_definition.set_recombiner(_pruned_recombiner);
 
    // temp way to get constituents, to compare to new version
    vector<PseudoJet> constituents;
    for (size_t j = 0; j < inputs.size(); ++j)
      if (_unpruned_seq->object_in_jet(inputs[j], unpruned_jets[i])) {
        constituents.push_back(inputs[j]);
      }
    ClusterSequence pruned_seq(constituents, _prune_definition);
 
    vector<int> pruned_PJs = _pruned_recombiner->pruned_pseudojets();
    _output_mergings(pruned_seq, pruned_PJs, input_seq);
  }
}
 
// Takes the merging structure of "in_seq" and feeds this into "out_seq" using
//   _plugin_record_{ij,iB}_recombination().
// PJ's in the input CS should have user_index's that are their (index+1) in
//    _jets() in the output CS (the output CS should be the input CS to
//    run_clustering()).
// This allows us to build up the same jet in out_seq as already exists in
//   in_seq.
void FastPrunePlugin::_output_mergings(ClusterSequence& in_seq,
                                       vector<int>& pruned_pseudojets,
                                       ClusterSequence& out_seq) const {
  // vector to store the pruned subjets for this jet
  vector<PseudoJet> temp_pruned_subjets;
 
  vector<PseudoJet> p = in_seq.jets();
 
  // sort this vector so we can binary search it
  sort(pruned_pseudojets.begin(), pruned_pseudojets.end());
 
  // get the history from in_seq
  const vector<ClusterSequence::history_element>& hist = in_seq.history();
  vector<ClusterSequence::history_element>::const_iterator iter = hist.begin();
 
  // skip particle input elements
  while (iter->parent1 == ClusterSequence::InexistentParent)
    iter++;
 
  // Walk through history.  PseudoJets in in_seq should have a user_index
  //   corresponding to their index in out_seq.  Note that when we create a
  //   new PJ via record_ij we need to set the user_index of our local copy.
  for (; iter != hist.end(); iter++) {
    int new_jet_index = -1;
    int jet_index = iter->jetp_index;
    int parent1 = iter->parent1;
    int parent2 = iter->parent2;
    int parent1_index = p[hist[iter->parent1].jetp_index].user_index() - 1;
 
    if (parent2 == ClusterSequence::BeamJet) {
      out_seq.plugin_record_iB_recombination(parent1_index, iter->dij);
    } else {
      int parent2_index = p[hist[parent2].jetp_index].user_index() - 1;
 
      // Check if either parent is stored in pruned_pseudojets
      //   Note that it is the history index that is stored
      if (binary_search(pruned_pseudojets.begin(), pruned_pseudojets.end(), parent2)) {
        // pruned away parent2 -- just give child parent1's index
        p[jet_index].set_user_index(p[hist[parent1].jetp_index].user_index());
        temp_pruned_subjets.push_back(out_seq.jets()[parent2_index]);
      } else if (binary_search(pruned_pseudojets.begin(), pruned_pseudojets.end(), parent1)) {
        // pruned away parent1 -- just give child parent2's index
        p[jet_index].set_user_index(p[hist[parent2].jetp_index].user_index());
        temp_pruned_subjets.push_back(out_seq.jets()[parent1_index]);
      } else {
        // no pruning -- record combination and index for child
        out_seq.plugin_record_ij_recombination(parent1_index, parent2_index, iter->dij, new_jet_index);
        p[jet_index].set_user_index(new_jet_index + 1);
      }
    }
  }
 
  _pruned_subjets.push_back(temp_pruned_subjets);
}