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fastjet 2.4.3
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00001 //STARTHEADER 00002 // $Id: CDFMidPointPlugin.cc 1394 2009-01-17 05:08:31Z soyez $ 00003 // 00004 // Copyright (c) 2005-2006, Matteo Cacciari and Gavin Salam 00005 // 00006 //---------------------------------------------------------------------- 00007 // This file is part of FastJet. 00008 // 00009 // FastJet is free software; you can redistribute it and/or modify 00010 // it under the terms of the GNU General Public License as published by 00011 // the Free Software Foundation; either version 2 of the License, or 00012 // (at your option) any later version. 00013 // 00014 // The algorithms that underlie FastJet have required considerable 00015 // development and are described in hep-ph/0512210. If you use 00016 // FastJet as part of work towards a scientific publication, please 00017 // include a citation to the FastJet paper. 00018 // 00019 // FastJet is distributed in the hope that it will be useful, 00020 // but WITHOUT ANY WARRANTY; without even the implied warranty of 00021 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 00022 // GNU General Public License for more details. 00023 // 00024 // You should have received a copy of the GNU General Public License 00025 // along with FastJet; if not, write to the Free Software 00026 // Foundation, Inc.: 00027 // 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA 00028 //---------------------------------------------------------------------- 00029 //ENDHEADER 00030 00031 #include "fastjet/CDFMidPointPlugin.hh" 00032 #include "fastjet/ClusterSequence.hh" 00033 #include "fastjet/Error.hh" 00034 #include <sstream> 00035 00036 // CDF stuff 00037 #include "MidPointAlgorithm.hh" 00038 #include "PhysicsTower.hh" 00039 #include "Cluster.hh" 00040 00041 FASTJET_BEGIN_NAMESPACE // defined in fastjet/internal/base.hh 00042 00043 using namespace std; 00044 using namespace cdf; 00045 00046 string CDFMidPointPlugin::description () const { 00047 ostringstream desc; 00048 00049 string sm_scale_string = "split-merge uses "; 00050 switch(_sm_scale) { 00051 case SM_pt: 00052 sm_scale_string += "pt"; 00053 break; 00054 case SM_Et: 00055 sm_scale_string += "Et"; 00056 break; 00057 case SM_mt: 00058 sm_scale_string += "mt"; 00059 break; 00060 case SM_pttilde: 00061 sm_scale_string += "pttilde (scalar sum of pts)"; 00062 break; 00063 default: 00064 ostringstream err; 00065 err << "Unrecognized split-merge scale choice = " << _sm_scale; 00066 throw Error(err.str()); 00067 } 00068 00069 00070 if (cone_area_fraction() == 1) { 00071 desc << "CDF MidPoint jet algorithm, with " ; 00072 } else { 00073 desc << "CDF MidPoint+Searchcone jet algorithm, with "; 00074 } 00075 desc << "seed_threshold = " << seed_threshold () << ", " 00076 << "cone_radius = " << cone_radius () << ", " 00077 << "cone_area_fraction = " << cone_area_fraction () << ", " 00078 << "max_pair_size = " << max_pair_size () << ", " 00079 << "max_iterations = " << max_iterations () << ", " 00080 << "overlap_threshold = " << overlap_threshold () << ", " 00081 << sm_scale_string ; 00082 00083 return desc.str(); 00084 } 00085 00086 00087 void CDFMidPointPlugin::run_clustering(ClusterSequence & clust_seq) const { 00088 00089 // create the physics towers needed by the CDF code 00090 vector<PhysicsTower> towers; 00091 towers.reserve(clust_seq.jets().size()); 00092 for (unsigned i = 0; i < clust_seq.jets().size(); i++) { 00093 LorentzVector fourvect(clust_seq.jets()[i].px(), 00094 clust_seq.jets()[i].py(), 00095 clust_seq.jets()[i].pz(), 00096 clust_seq.jets()[i].E()); 00097 PhysicsTower tower(fourvect); 00098 // misuse one of the indices for tracking, since the MidPoint 00099 // implementation doesn't seem to make use of these indices 00100 tower.calTower.iEta = i; 00101 towers.push_back(tower); 00102 } 00103 00104 // prepare the CDF algorithm 00105 MidPointAlgorithm m(_seed_threshold,_cone_radius,_cone_area_fraction, 00106 _max_pair_size,_max_iterations,_overlap_threshold, 00107 MidPointAlgorithm::SplitMergeScale(_sm_scale)); 00108 00109 // run the CDF algorithm 00110 std::vector<Cluster> jets; 00111 m.run(towers,jets); 00112 00113 00114 // now transfer the jets back into our own structure -- we will 00115 // mimic the cone code with a sequential recombination sequence in 00116 // which the jets are built up by adding one particle at a time 00117 for(vector<Cluster>::const_iterator jetIter = jets.begin(); 00118 jetIter != jets.end(); jetIter++) { 00119 const vector<PhysicsTower> & tower_list = jetIter->towerList; 00120 int jet_k = tower_list[0].calTower.iEta; 00121 00122 int ntow = int(jetIter->towerList.size()); 00123 for (int itow = 1; itow < ntow; itow++) { 00124 int jet_i = jet_k; 00125 // retrieve our misappropriated index for the jet 00126 int jet_j = tower_list[itow].calTower.iEta; 00127 // do a fake recombination step with dij=0 00128 double dij = 0.0; 00129 clust_seq.plugin_record_ij_recombination(jet_i, jet_j, dij, jet_k); 00130 } 00131 00132 // NB: put a sensible looking d_iB just to be nice... 00133 double d_iB = clust_seq.jets()[jet_k].perp2(); 00134 clust_seq.plugin_record_iB_recombination(jet_k, d_iB); 00135 } 00136 00137 00138 // following code is for testing only 00139 //cout << endl; 00140 //for(vector<Cluster>::const_iterator jetIter = jets.begin(); 00141 // jetIter != jets.end(); jetIter++) { 00142 // cout << jetIter->fourVector.pt() << " " << jetIter->fourVector.y() << endl; 00143 //} 00144 //cout << "-----------------------------------------------------\n"; 00145 //vector<PseudoJet> ourjets(clust_seq.inclusive_jets()); 00146 //for (vector<PseudoJet>::const_reverse_iterator ourjet = ourjets.rbegin(); 00147 // ourjet != ourjets.rend(); ourjet++) { 00148 // cout << ourjet->perp() << " " << ourjet->rap() << endl; 00149 //} 00150 //cout << endl; 00151 } 00152 00153 FASTJET_END_NAMESPACE // defined in fastjet/internal/base.hh
1.7.3