1 | #ifndef __FASTJET_NNFJN2TILED_HH__
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2 | #define __FASTJET_NNFJN2TILED_HH__
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3 |
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4 | //FJSTARTHEADER
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5 | // $Id: NNFJN2Tiled.hh 4056 2016-03-03 15:27:35Z soyez $
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6 | //
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7 | // Copyright (c) 2016, Matteo Cacciari, Gavin P. Salam and Gregory Soyez
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8 | //
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9 | //----------------------------------------------------------------------
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10 | // This file is part of FastJet.
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11 | //
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12 | // FastJet is free software; you can redistribute it and/or modify
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13 | // it under the terms of the GNU General Public License as published by
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14 | // the Free Software Foundation; either version 2 of the License, or
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15 | // (at your option) any later version.
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16 | //
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17 | // The algorithms that underlie FastJet have required considerable
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18 | // development. They are described in the original FastJet paper,
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19 | // hep-ph/0512210 and in the manual, arXiv:1111.6097. If you use
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20 | // FastJet as part of work towards a scientific publication, please
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21 | // quote the version you use and include a citation to the manual and
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22 | // optionally also to hep-ph/0512210.
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23 | //
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24 | // FastJet is distributed in the hope that it will be useful,
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25 | // but WITHOUT ANY WARRANTY; without even the implied warranty of
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26 | // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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27 | // GNU General Public License for more details.
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28 | //
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29 | // You should have received a copy of the GNU General Public License
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30 | // along with FastJet. If not, see <http://www.gnu.org/licenses/>.
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31 | //----------------------------------------------------------------------
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32 | //FJENDHEADER
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33 |
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34 | #include <fastjet/NNBase.hh>
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35 | #include <fastjet/internal/TilingExtent.hh>
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36 |
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37 | FASTJET_BEGIN_NAMESPACE // defined in fastjet/internal/base.hh
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38 |
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39 | //----------------------------------------------------------------------
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40 | /// @ingroup advanced_usage
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41 | /// \class NNFJN2Tiled
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42 | ///
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43 | /// Helps solve closest pair problems with factorised interparticle
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44 | /// and beam distances (ie satisfying the FastJet lemma) that are on
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45 | /// a cylindrical geometry and allow tiling.
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46 | ///
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47 | /// (see NNBase.hh for an introductory description)
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48 | ///
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49 | /// This variant provides an implementation based on the N2Tiled
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50 | /// clustering strategy in FastJet. As for the NNFJN2Plain case, the
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51 | /// interparticle and beam distances should be of the form
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52 | ///
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53 | /// \code
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54 | /// dij = min(mom_factor(i), mom_factor(j)) * geometrical_distance(i,j)
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55 | /// diB = mom_factor(i) * geometrical_beam_distance(i)
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56 | /// \endcode
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57 | ///
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58 | /// Additionally, the NNFJN2Tiled class takes a tile_size parameter
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59 | /// that controls the size of the tiles. It must be such that, for any
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60 | /// two points in non-neighbouring (and non-identical) tiles, the
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61 | /// geometrical distance between the 2 points is larger than the
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62 | /// geometrical beam distance of each of the 2 points.
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63 | ///
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64 | /// It is templated with a BJ (brief jet) class and can be used with or
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65 | /// without an extra "Information" template, i.e. NNFJN2Tiled<BJ> or
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66 | /// NNFJN2Tiled<BJ,I>
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67 | ///
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68 | /// For the NNFJN2Tiled<BJ> version of the class to function, BJ must provide
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69 | /// three member functions
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70 | ///
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71 | /// \code
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72 | /// void BJ::init(const PseudoJet & jet); // initialise with a PseudoJet
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73 | /// double BJ::geometrical_distance(const BJ * other_bj_jet); // distance between this and other_bj_jet (geometrical part)
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74 | /// double BJ::geometrical_beam_distance(); // distance to the beam (geometrical part)
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75 | /// double BJ::momentum_factor(); // extra momentum factor
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76 | /// \endcode
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77 | ///
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78 | /// For the NNFJN2Tiled<BJ,I> version to function, the BJ::init(...) member
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79 | /// must accept an extra argument
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80 | ///
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81 | /// \code
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82 | /// void BJ::init(const PseudoJet & jet, I * info); // initialise with a PseudoJet + info
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83 | /// \endcode
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84 | ///
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85 | /// NOTE: THE DISTANCE MUST BE SYMMETRIC I.E. SATISFY
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86 | /// \code
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87 | /// a.geometrical_distance(b) == b.geometrical_distance(a)
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88 | /// \endcode
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89 | ///
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90 | /// Finally, the BJ class needs to provide access to the variables used
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91 | /// for the rectangular tiling:
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92 | ///
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93 | /// \code
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94 | /// double BJ::rap(); // rapidity-like variable
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95 | /// double BJ::phi(); // azimutal-angle-like variable (should be > -2pi)
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96 | /// \endcode
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97 | ///
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98 | /// Note that you are strongly advised to add the following lines
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99 | /// to your BJ class to allow it to be used also with NNH:
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100 | ///
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101 | /// \code
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102 | /// /// make this BJ class compatible with the use of NNH
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103 | /// double BJ::distance(const BJ * other_bj_jet){
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104 | /// double mom1 = momentum_factor();
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105 | /// double mom2 = other_bj_jet->momentum_factor();
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106 | /// return (mom1<mom2 ? mom1 : mom2) * geometrical_distance(other_bj_jet);
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107 | /// }
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108 | /// double BJ::beam_distance(){
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109 | /// return momentum_factor() * geometrical_beam_distance();
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110 | /// }
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111 | /// \endcode
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112 | ///
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113 | template<class BJ, class I = _NoInfo> class NNFJN2Tiled : public NNBase<I> {
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114 | public:
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115 |
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116 | /// constructor with an initial set of jets (which will be assigned indices
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117 | /// `0...jets.size()-1`)
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118 | NNFJN2Tiled(const std::vector<PseudoJet> & jets, double requested_tile_size)
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119 | : NNBase<I>(), _requested_tile_size(requested_tile_size) {start(jets);}
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120 | NNFJN2Tiled(const std::vector<PseudoJet> & jets, double requested_tile_size, I * info)
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121 | : NNBase<I>(info), _requested_tile_size(requested_tile_size) {start(jets);}
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122 |
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123 | void start(const std::vector<PseudoJet> & jets);
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124 |
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125 | /// return the dij_min and indices iA, iB, for the corresponding jets.
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126 | /// If iB < 0 then iA recombines with the beam
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127 | double dij_min(int & iA, int & iB);
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128 |
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129 | /// remove the jet pointed to by index iA
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130 | void remove_jet(int iA);
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131 |
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132 | /// merge the jets pointed to by indices A and B and replace them with
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133 | /// jet, assigning it an index jet_index.
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134 | void merge_jets(int iA, int iB, const PseudoJet & jet, int jet_index);
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135 |
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136 | /// a destructor
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137 | ~NNFJN2Tiled() {
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138 | delete[] briefjets;
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139 | delete[] diJ;
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140 | }
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141 |
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142 | private:
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143 | class TiledJet; // forward declaration
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144 | class Tile;
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145 | class diJ_plus_link;
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146 |
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147 | // Set up the tiles:
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148 | void _initialise_tiles(const std::vector<PseudoJet> & particles);
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149 |
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150 | // return the full distance of a particle to its NN
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151 | inline double _compute_diJ(const TiledJet * const jet) const {
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152 | double mom_fact = jet->momentum_factor();
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153 | if (jet->NN != NULL) {
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154 | double other_mom_fact = jet->NN->momentum_factor();
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155 | if (other_mom_fact < mom_fact) {mom_fact = other_mom_fact;}
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156 | }
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157 | return jet->NN_dist * mom_fact;
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158 | }
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159 |
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160 | // reasonably robust return of tile index given irap and iphi, in particular
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161 | // it works even if iphi is negative
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162 | inline int _tile_index (int irap, int iphi) const {
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163 | // note that (-1)%n = -1 so that we have to add _n_tiles_phi
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164 | // before performing modulo operation
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165 | return (irap-_tiles_irap_min)*_n_tiles_phi
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166 | + (iphi+_n_tiles_phi) % _n_tiles_phi;
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167 | }
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168 |
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169 | int _tile_index(const double rap, const double phi) const;
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170 | void _tiledjet_set_jetinfo ( TiledJet * const tiled_jet, const PseudoJet &jet, int index);
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171 | void _bj_remove_from_tiles(TiledJet * const jet);
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172 | void _initialise_tiles();
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173 | void _print_tiles(TiledJet * briefjets ) const;
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174 | void _add_neighbours_to_tile_union(const int tile_index, int & n_near_tiles) const;
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175 | void _add_untagged_neighbours_to_tile_union(const int tile_index, int & n_near_tiles);
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176 |
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177 |
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178 | /// contains the briefjets
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179 | TiledJet * briefjets;
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180 |
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181 | /// semaphores for the current extent of our structure
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182 | TiledJet * head;
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183 |
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184 | /// currently active number of jets
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185 | int n;
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186 |
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187 | /// where_is[i] contains a pointer to the jet with index i
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188 | std::vector<TiledJet *> where_is;
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189 |
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190 | /// helper to keep tracks of tiles to be checked for updates
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191 | std::vector<int> tile_union;
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192 |
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193 | /// a table containing all the (full) distances to each object's NN
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194 | diJ_plus_link * diJ;
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195 |
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196 | /// tiling information
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197 | std::vector<Tile> _tiles;
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198 | double _requested_tile_size;
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199 | double _tiles_rap_min, _tiles_rap_max;
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200 | double _tile_size_rap, _tile_size_phi;
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201 | int _n_tiles_phi,_tiles_irap_min,_tiles_irap_max;
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202 |
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203 | /// a class that wraps around the BJ, supplementing it with extra information
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204 | /// such as pointers to neighbours, etc.
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205 | class TiledJet : public BJ {
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206 | public:
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207 | void init(const PseudoJet & jet, int index_in) {
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208 | BJ::init(jet);
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209 | other_init(index_in);
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210 | }
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211 | void init(const PseudoJet & jet, int index_in, I * info) {
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212 | BJ::init(jet, info);
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213 | other_init(index_in);
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214 | }
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215 | void other_init(int index_in) {
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216 | _index = index_in;
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217 | NN_dist = BJ::geometrical_beam_distance();
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218 | NN = NULL;
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219 | }
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220 | int jet_index() const {return _index;}
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221 |
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222 | double NN_dist;
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223 | TiledJet * NN, *previous, * next;
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224 | int tile_index, diJ_posn;
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225 | // routines that are useful in the minheap version of tiled
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226 | // clustering ("misuse" the otherwise unused diJ_posn, so as
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227 | // to indicate whether jets need to have their minheap entries
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228 | // updated).
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229 | inline void label_minheap_update_needed() {diJ_posn = 1;}
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230 | inline void label_minheap_update_done() {diJ_posn = 0;}
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231 | inline bool minheap_update_needed() const {return diJ_posn==1;}
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232 |
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233 | private:
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234 | int _index;
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235 | };
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236 |
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237 | /// number of neighbours that a tile will have (rectangular geometry
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238 | /// gives 9 neighbours).
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239 | static const int n_tile_neighbours = 9;
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240 | //----------------------------------------------------------------------
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241 | /// The fundamental structures to be used for the tiled N^2 algorithm
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242 | /// (see CCN27-44 for some discussion of pattern of tiling)
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243 | class Tile {
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244 | public:
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245 | /// pointers to neighbouring tiles, including self
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246 | Tile * begin_tiles[n_tile_neighbours];
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247 | /// neighbouring tiles, excluding self
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248 | Tile ** surrounding_tiles;
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249 | /// half of neighbouring tiles, no self
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250 | Tile ** RH_tiles;
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251 | /// just beyond end of tiles
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252 | Tile ** end_tiles;
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253 | /// start of list of BriefJets contained in this tile
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254 | TiledJet * head;
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255 | /// sometimes useful to be able to tag a tile
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256 | bool tagged;
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257 | };
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258 |
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259 | // structure that holds the real, full, distance (as well as a pointer to the corresponding TiledJet)
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260 | struct diJ_plus_link {
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261 | double diJ; // the distance
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262 | TiledJet * jet; // the jet (i) for which we've found this distance
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263 | // (whose NN will the J).
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264 | };
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265 |
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266 | };
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267 |
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268 |
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269 |
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270 | //----------------------------------------------------------------------
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271 | template<class BJ, class I> void NNFJN2Tiled<BJ,I>::start(const std::vector<PseudoJet> & jets) {
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272 |
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273 | _initialise_tiles(jets);
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274 |
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275 | n = jets.size();
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276 |
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277 | briefjets = new TiledJet[n];
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278 | where_is.resize(2*n);
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279 |
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280 | TiledJet * jetA = briefjets, * jetB;
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281 |
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282 | // will be used quite deep inside loops, but declare it here so that
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283 | // memory (de)allocation gets done only once
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284 | tile_union.resize(3*n_tile_neighbours);
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285 |
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286 | // initialise the basic jet info
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287 | for (int i = 0; i< n; i++) {
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288 | _tiledjet_set_jetinfo(jetA, jets[i], i);
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289 | where_is[i] = jetA;
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290 | jetA++; // move on to next entry of briefjets
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291 | }
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292 |
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293 | head = briefjets; // a nicer way of naming start
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294 |
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295 | // set up the initial nearest neighbour information
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296 | typename std::vector<Tile>::const_iterator tile;
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297 | for (tile = _tiles.begin(); tile != _tiles.end(); tile++) {
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298 | // first do it on this tile
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299 | for (jetA = tile->head; jetA != NULL; jetA = jetA->next) {
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300 | for (jetB = tile->head; jetB != jetA; jetB = jetB->next) {
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301 | double dist = jetA->geometrical_distance(jetB);
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302 | if (dist < jetA->NN_dist) {jetA->NN_dist = dist; jetA->NN = jetB;}
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303 | if (dist < jetB->NN_dist) {jetB->NN_dist = dist; jetB->NN = jetA;}
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304 | }
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305 | }
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306 | // then do it for RH tiles
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307 | for (Tile ** RTile = tile->RH_tiles; RTile != tile->end_tiles; RTile++) {
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308 | for (jetA = tile->head; jetA != NULL; jetA = jetA->next) {
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309 | for (jetB = (*RTile)->head; jetB != NULL; jetB = jetB->next) {
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310 | double dist = jetA->geometrical_distance(jetB);
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311 | if (dist < jetA->NN_dist) {jetA->NN_dist = dist; jetA->NN = jetB;}
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312 | if (dist < jetB->NN_dist) {jetB->NN_dist = dist; jetB->NN = jetA;}
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313 | }
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314 | }
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315 | }
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316 | // no need to do it for LH tiles, since they are implicitly done
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317 | // when we set NN for both jetA and jetB on the RH tiles.
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318 | }
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319 |
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320 | diJ = new diJ_plus_link[n];
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321 | jetA = head;
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322 | for (int i = 0; i < n; i++) {
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323 | diJ[i].diJ = _compute_diJ(jetA); // kt distance * R^2
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324 | diJ[i].jet = jetA; // our compact diJ table will not be in
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325 | jetA->diJ_posn = i; // one-to-one corresp. with non-compact jets,
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326 | // so set up bi-directional correspondence here.
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327 | jetA++; // have jetA follow i
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328 | }
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329 | }
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330 |
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331 |
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332 | //----------------------------------------------------------------------
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333 | template<class BJ, class I> double NNFJN2Tiled<BJ,I>::dij_min(int & iA, int & iB) {
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334 | // find the minimum of the diJ on this round
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335 | diJ_plus_link * best, *stop; // pointers a bit faster than indices
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336 | // could use best to keep track of diJ
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337 | // min, but it turns out to be
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338 | // marginally faster to have a separate
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339 | // variable (avoids n dereferences at
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340 | // the expense of n/2 assignments).
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341 | double diJ_min = diJ[0].diJ; // initialise the best one here.
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342 | best = diJ; // and here
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343 | stop = diJ+n;
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344 | for (diJ_plus_link * here = diJ+1; here != stop; here++) {
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345 | if (here->diJ < diJ_min) {best = here; diJ_min = here->diJ;}
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346 | }
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347 |
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348 | // return information to user about recombination
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349 | TiledJet * jetA = best->jet;
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350 | iA = jetA->jet_index();
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351 | iB = jetA->NN ? jetA->NN->jet_index() : -1;
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352 | return diJ_min;
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353 | }
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354 |
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355 |
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356 | //----------------------------------------------------------------------
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357 | // remove jetA from the list
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358 | template<class BJ, class I> void NNFJN2Tiled<BJ,I>::remove_jet(int iA) {
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359 | TiledJet * jetA = where_is[iA];
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360 |
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361 | _bj_remove_from_tiles(jetA);
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362 |
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363 | // first establish the set of tiles over which we are going to
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364 | // have to run searches for updated and new nearest-neighbours --
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365 | // basically a combination of vicinity of the tiles of the two old
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366 | // and one new jet.
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367 | int n_near_tiles = 0;
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368 | _add_untagged_neighbours_to_tile_union(jetA->tile_index, n_near_tiles);
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369 |
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370 | // now update our nearest neighbour info and diJ table
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371 | // first reduce size of table
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372 | n--;
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373 | // then compactify the diJ by taking the last of the diJ and copying
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374 | // it to the position occupied by the diJ for jetA
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375 | diJ[n].jet->diJ_posn = jetA->diJ_posn;
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376 | diJ[jetA->diJ_posn] = diJ[n];
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377 |
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378 | // updating other particles' NN.
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379 | // Run over all tiles in our union
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380 | for (int itile = 0; itile < n_near_tiles; itile++) {
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381 | Tile * tile_ptr = &_tiles[tile_union[itile]];
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382 | tile_ptr->tagged = false; // reset tag, since we're done with unions
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383 | // run over all jets in the current tile
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384 | for (TiledJet * jetI = tile_ptr->head; jetI != NULL; jetI = jetI->next) {
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385 | // see if jetI had jetA or jetB as a NN -- if so recalculate the NN
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386 | if (jetI->NN == jetA) {
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387 | jetI->NN_dist = jetI->geometrical_beam_distance();
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388 | jetI->NN = NULL;
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389 | // now go over tiles that are neighbours of I (include own tile)
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390 | for (Tile ** near_tile = tile_ptr->begin_tiles;
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391 | near_tile != tile_ptr->end_tiles; near_tile++) {
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392 | // and then over the contents of that tile
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393 | for (TiledJet * jetJ = (*near_tile)->head; jetJ != NULL; jetJ = jetJ->next) {
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394 | double dist = jetI->geometrical_distance(jetJ);
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395 | if (dist < jetI->NN_dist && jetJ != jetI) {
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396 | jetI->NN_dist = dist; jetI->NN = jetJ;
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397 | }
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398 | }
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399 | }
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400 | diJ[jetI->diJ_posn].diJ = _compute_diJ(jetI); // update diJ kt-dist
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401 | }
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402 | }
|
---|
403 | }
|
---|
404 |
|
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405 | }
|
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406 |
|
---|
407 |
|
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408 | //----------------------------------------------------------------------
|
---|
409 | template<class BJ, class I> void NNFJN2Tiled<BJ,I>::merge_jets(int iA, int iB,
|
---|
410 | const PseudoJet & jet, int index) {
|
---|
411 |
|
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412 | TiledJet * jetA = where_is[iA];
|
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413 | TiledJet * jetB = where_is[iB];
|
---|
414 |
|
---|
415 | // jet-jet recombination
|
---|
416 | // If necessary relabel A & B to ensure jetB < jetA, that way if
|
---|
417 | // the larger of them == newtail then that ends up being jetA and
|
---|
418 | // the new jet that is added as jetB is inserted in a position that
|
---|
419 | // has a future!
|
---|
420 | if (jetA < jetB) {std::swap(jetA,jetB);}
|
---|
421 |
|
---|
422 | // what was jetB will now become the new jet
|
---|
423 | _bj_remove_from_tiles(jetA);
|
---|
424 | TiledJet oldB = * jetB; // take a copy because we will need it...
|
---|
425 | _bj_remove_from_tiles(jetB);
|
---|
426 | _tiledjet_set_jetinfo(jetB, jet, index); // cause jetB to become _jets[nn]
|
---|
427 | // (also registers the jet in the tiling)
|
---|
428 | where_is[index] = jetB;
|
---|
429 |
|
---|
430 | // first establish the set of tiles over which we are going to
|
---|
431 | // have to run searches for updated and new nearest-neighbours --
|
---|
432 | // basically a combination of vicinity of the tiles of the two old
|
---|
433 | // and one new jet.
|
---|
434 | int n_near_tiles = 0;
|
---|
435 | _add_untagged_neighbours_to_tile_union(jetA->tile_index, n_near_tiles);
|
---|
436 | if (jetB->tile_index != jetA->tile_index) {
|
---|
437 | _add_untagged_neighbours_to_tile_union(jetB->tile_index, n_near_tiles);
|
---|
438 | }
|
---|
439 | if (oldB.tile_index != jetA->tile_index &&
|
---|
440 | oldB.tile_index != jetB->tile_index) {
|
---|
441 | _add_untagged_neighbours_to_tile_union(oldB.tile_index, n_near_tiles);
|
---|
442 | }
|
---|
443 |
|
---|
444 | // now update our nearest neighbour info and diJ table
|
---|
445 | // first reduce size of table
|
---|
446 | n--;
|
---|
447 | // then compactify the diJ by taking the last of the diJ and copying
|
---|
448 | // it to the position occupied by the diJ for jetA
|
---|
449 | diJ[n].jet->diJ_posn = jetA->diJ_posn;
|
---|
450 | diJ[jetA->diJ_posn] = diJ[n];
|
---|
451 |
|
---|
452 | // Initialise jetB's NN distance as well as updating it for
|
---|
453 | // other particles.
|
---|
454 | // Run over all tiles in our union
|
---|
455 | for (int itile = 0; itile < n_near_tiles; itile++) {
|
---|
456 | Tile * tile_ptr = &_tiles[tile_union[itile]];
|
---|
457 | tile_ptr->tagged = false; // reset tag, since we're done with unions
|
---|
458 | // run over all jets in the current tile
|
---|
459 | for (TiledJet * jetI = tile_ptr->head; jetI != NULL; jetI = jetI->next) {
|
---|
460 | // see if jetI had jetA or jetB as a NN -- if so recalculate the NN
|
---|
461 | if ((jetI->NN == jetA) || (jetI->NN == jetB)) {
|
---|
462 | jetI->NN_dist = jetI->geometrical_beam_distance();
|
---|
463 | jetI->NN = NULL;
|
---|
464 | // now go over tiles that are neighbours of I (include own tile)
|
---|
465 | for (Tile ** near_tile = tile_ptr->begin_tiles; near_tile != tile_ptr->end_tiles; near_tile++) {
|
---|
466 | // and then over the contents of that tile
|
---|
467 | for (TiledJet * jetJ = (*near_tile)->head; jetJ != NULL; jetJ = jetJ->next) {
|
---|
468 | double dist = jetI->geometrical_distance(jetJ);
|
---|
469 | if (dist < jetI->NN_dist && jetJ != jetI) {
|
---|
470 | jetI->NN_dist = dist; jetI->NN = jetJ;
|
---|
471 | }
|
---|
472 | }
|
---|
473 | }
|
---|
474 | diJ[jetI->diJ_posn].diJ = _compute_diJ(jetI); // update diJ kt-dist
|
---|
475 | }
|
---|
476 | // check whether new jetB is closer than jetI's current NN and
|
---|
477 | // if jetI is closer than jetB's current (evolving) nearest
|
---|
478 | // neighbour. Where relevant update things
|
---|
479 | double dist = jetI->geometrical_distance(jetB);
|
---|
480 | if (dist < jetI->NN_dist) {
|
---|
481 | if (jetI != jetB) {
|
---|
482 | jetI->NN_dist = dist;
|
---|
483 | jetI->NN = jetB;
|
---|
484 | diJ[jetI->diJ_posn].diJ = _compute_diJ(jetI); // update diJ...
|
---|
485 | }
|
---|
486 | }
|
---|
487 | if (dist < jetB->NN_dist) {
|
---|
488 | if (jetI != jetB) {
|
---|
489 | jetB->NN_dist = dist;
|
---|
490 | jetB->NN = jetI;}
|
---|
491 | }
|
---|
492 | }
|
---|
493 | }
|
---|
494 |
|
---|
495 | // finally, register the updated kt distance for B
|
---|
496 | diJ[jetB->diJ_posn].diJ = _compute_diJ(jetB);
|
---|
497 | }
|
---|
498 |
|
---|
499 |
|
---|
500 | //----------------------------------------------------------------------
|
---|
501 | /// Set up the tiles:
|
---|
502 | /// - decide the range in eta
|
---|
503 | /// - allocate the tiles
|
---|
504 | /// - set up the cross-referencing info between tiles
|
---|
505 | ///
|
---|
506 | /// The neighbourhood of a tile is set up as follows
|
---|
507 | ///
|
---|
508 | /// LRR
|
---|
509 | /// LXR
|
---|
510 | /// LLR
|
---|
511 | ///
|
---|
512 | /// such that tiles is an array containing XLLLLRRRR with pointers
|
---|
513 | /// | \ RH_tiles
|
---|
514 | /// \ surrounding_tiles
|
---|
515 | ///
|
---|
516 | /// with appropriate precautions when close to the edge of the tiled
|
---|
517 | /// region.
|
---|
518 | ///
|
---|
519 | template <class BJ, class I>
|
---|
520 | void NNFJN2Tiled<BJ,I>::_initialise_tiles(const std::vector<PseudoJet> &particles) {
|
---|
521 |
|
---|
522 | // first decide tile sizes (with a lower bound to avoid huge memory use with
|
---|
523 | // very small R)
|
---|
524 | double default_size = _requested_tile_size>0.1 ? _requested_tile_size : 0.1;
|
---|
525 | _tile_size_rap = default_size;
|
---|
526 | // it makes no sense to go below 3 tiles in phi -- 3 tiles is
|
---|
527 | // sufficient to make sure all pair-wise combinations up to pi in
|
---|
528 | // phi are possible
|
---|
529 | _n_tiles_phi = int(floor(twopi/default_size));
|
---|
530 | if (_n_tiles_phi<3) _n_tiles_phi = 3;
|
---|
531 | _tile_size_phi = twopi / _n_tiles_phi; // >= _Rparam and fits in 2pi
|
---|
532 |
|
---|
533 | TilingExtent tiling_analysis(particles);
|
---|
534 | _tiles_rap_min = tiling_analysis.minrap();
|
---|
535 | _tiles_rap_max = tiling_analysis.maxrap();
|
---|
536 |
|
---|
537 | // now adjust the values
|
---|
538 | _tiles_irap_min = int(floor(_tiles_rap_min/_tile_size_rap));
|
---|
539 | _tiles_irap_max = int(floor( _tiles_rap_max/_tile_size_rap));
|
---|
540 | _tiles_rap_min = _tiles_irap_min * _tile_size_rap;
|
---|
541 | _tiles_rap_max = _tiles_irap_max * _tile_size_rap;
|
---|
542 |
|
---|
543 | // allocate the tiles
|
---|
544 | _tiles.resize((_tiles_irap_max-_tiles_irap_min+1)*_n_tiles_phi);
|
---|
545 |
|
---|
546 | // now set up the cross-referencing between tiles
|
---|
547 | for (int irap = _tiles_irap_min; irap <= _tiles_irap_max; irap++) {
|
---|
548 | for (int iphi = 0; iphi < _n_tiles_phi; iphi++) {
|
---|
549 | Tile * tile = & _tiles[_tile_index(irap,iphi)];
|
---|
550 | // no jets in this tile yet
|
---|
551 | tile->head = NULL; // first element of tiles points to itself
|
---|
552 | tile->begin_tiles[0] = tile;
|
---|
553 | Tile ** pptile = & (tile->begin_tiles[0]);
|
---|
554 | pptile++;
|
---|
555 | //
|
---|
556 | // set up L's in column to the left of X
|
---|
557 | tile->surrounding_tiles = pptile;
|
---|
558 | if (irap > _tiles_irap_min) {
|
---|
559 | // with the itile subroutine, we can safely run tiles from
|
---|
560 | // idphi=-1 to idphi=+1, because it takes care of
|
---|
561 | // negative and positive boundaries
|
---|
562 | for (int idphi = -1; idphi <=+1; idphi++) {
|
---|
563 | *pptile = & _tiles[_tile_index(irap-1,iphi+idphi)];
|
---|
564 | pptile++;
|
---|
565 | }
|
---|
566 | }
|
---|
567 | // now set up last L (below X)
|
---|
568 | *pptile = & _tiles[_tile_index(irap,iphi-1)];
|
---|
569 | pptile++;
|
---|
570 | // set up first R (above X)
|
---|
571 | tile->RH_tiles = pptile;
|
---|
572 | *pptile = & _tiles[_tile_index(irap,iphi+1)];
|
---|
573 | pptile++;
|
---|
574 | // set up remaining R's, to the right of X
|
---|
575 | if (irap < _tiles_irap_max) {
|
---|
576 | for (int idphi = -1; idphi <= +1; idphi++) {
|
---|
577 | *pptile = & _tiles[_tile_index(irap+1,iphi+idphi)];
|
---|
578 | pptile++;
|
---|
579 | }
|
---|
580 | }
|
---|
581 | // now put semaphore for end tile
|
---|
582 | tile->end_tiles = pptile;
|
---|
583 | // finally make sure tiles are untagged
|
---|
584 | tile->tagged = false;
|
---|
585 | }
|
---|
586 | }
|
---|
587 |
|
---|
588 | }
|
---|
589 |
|
---|
590 | //----------------------------------------------------------------------
|
---|
591 | /// return the tile index corresponding to the given rap,phi point
|
---|
592 | template <class BJ, class I>
|
---|
593 | int NNFJN2Tiled<BJ,I>::_tile_index(const double rap, const double phi) const {
|
---|
594 | int irap, iphi;
|
---|
595 | if (rap <= _tiles_rap_min) {irap = 0;}
|
---|
596 | else if (rap >= _tiles_rap_max) {irap = _tiles_irap_max-_tiles_irap_min;}
|
---|
597 | else {
|
---|
598 | //irap = int(floor((rap - _tiles_rap_min) / _tile_size_rap));
|
---|
599 | irap = int(((rap - _tiles_rap_min) / _tile_size_rap));
|
---|
600 | // following needed in case of rare but nasty rounding errors
|
---|
601 | if (irap > _tiles_irap_max-_tiles_irap_min) {
|
---|
602 | irap = _tiles_irap_max-_tiles_irap_min;}
|
---|
603 | }
|
---|
604 | // allow for some extent of being beyond range in calculation of phi
|
---|
605 | // as well
|
---|
606 | //iphi = (int(floor(phi/_tile_size_phi)) + _n_tiles_phi) % _n_tiles_phi;
|
---|
607 | // with just int and no floor, things run faster but beware
|
---|
608 | iphi = int((phi+twopi)/_tile_size_phi) % _n_tiles_phi;
|
---|
609 | return (iphi + irap * _n_tiles_phi);
|
---|
610 | }
|
---|
611 |
|
---|
612 | //----------------------------------------------------------------------
|
---|
613 | template <class BJ, class I>
|
---|
614 | void NNFJN2Tiled<BJ,I>::_bj_remove_from_tiles(TiledJet * const jet) {
|
---|
615 | Tile * tile = & _tiles[jet->tile_index];
|
---|
616 |
|
---|
617 | if (jet->previous == NULL) {
|
---|
618 | // we are at head of the tile, so reset it.
|
---|
619 | // If this was the only jet on the tile then tile->head will now be NULL
|
---|
620 | tile->head = jet->next;
|
---|
621 | } else {
|
---|
622 | // adjust link from previous jet in this tile
|
---|
623 | jet->previous->next = jet->next;
|
---|
624 | }
|
---|
625 | if (jet->next != NULL) {
|
---|
626 | // adjust backwards-link from next jet in this tile
|
---|
627 | jet->next->previous = jet->previous;
|
---|
628 | }
|
---|
629 | }
|
---|
630 |
|
---|
631 |
|
---|
632 | //----------------------------------------------------------------------
|
---|
633 | // overloaded version which additionally sets up information regarding the
|
---|
634 | // tiling
|
---|
635 | template <class BJ, class I>
|
---|
636 | inline void NNFJN2Tiled<BJ,I>::_tiledjet_set_jetinfo(TiledJet * const tile_jet,
|
---|
637 | const PseudoJet &jet,
|
---|
638 | int index) {
|
---|
639 | // the this-> in the next line is required by standard compiler
|
---|
640 | // see e.g. http://stackoverflow.com/questions/10639053/name-lookups-in-c-templates
|
---|
641 | this->init_jet(tile_jet, jet, index);
|
---|
642 |
|
---|
643 | // Then do the setup specific to the tiled case.
|
---|
644 |
|
---|
645 | // Find out which tile it belonds to
|
---|
646 | tile_jet->tile_index = _tile_index(tile_jet->rap(), tile_jet->phi());
|
---|
647 |
|
---|
648 | // Insert it into the tile's linked list of jets
|
---|
649 | Tile * tile = &_tiles[tile_jet->tile_index];
|
---|
650 | tile_jet->previous = NULL;
|
---|
651 | tile_jet->next = tile->head;
|
---|
652 | if (tile_jet->next != NULL) {tile_jet->next->previous = tile_jet;}
|
---|
653 | tile->head = tile_jet;
|
---|
654 | }
|
---|
655 |
|
---|
656 | //----------------------------------------------------------------------
|
---|
657 | /// Add to the vector tile_union the tiles that are in the neighbourhood
|
---|
658 | /// of the specified tile_index, including itself -- start adding
|
---|
659 | /// from position n_near_tiles-1, and increase n_near_tiles as
|
---|
660 | /// you go along (could have done it more C++ like with vector with reserved
|
---|
661 | /// space, but fear is that it would have been slower, e.g. checking
|
---|
662 | /// for end of vector at each stage to decide whether to resize it)
|
---|
663 | template <class BJ, class I>
|
---|
664 | void NNFJN2Tiled<BJ,I>::_add_neighbours_to_tile_union(const int tile_index,
|
---|
665 | int & n_near_tiles) const {
|
---|
666 | for (Tile * const * near_tile = _tiles[tile_index].begin_tiles;
|
---|
667 | near_tile != _tiles[tile_index].end_tiles; near_tile++){
|
---|
668 | // get the tile number
|
---|
669 | tile_union[n_near_tiles] = *near_tile - & _tiles[0];
|
---|
670 | n_near_tiles++;
|
---|
671 | }
|
---|
672 | }
|
---|
673 |
|
---|
674 | //----------------------------------------------------------------------
|
---|
675 | /// Like _add_neighbours_to_tile_union, but only adds neighbours if
|
---|
676 | /// their "tagged" status is false; when a neighbour is added its
|
---|
677 | /// tagged status is set to true.
|
---|
678 | ///
|
---|
679 | /// Note that with a high level of warnings (-pedantic -Wextra -ansi,
|
---|
680 | /// gcc complains about tile_index maybe being used uninitialised for
|
---|
681 | /// oldB in ClusterSequence::_minheap_faster_tiled_N2_cluster(). We
|
---|
682 | /// have explicitly checked that it was harmless so we could disable
|
---|
683 | /// the gcc warning by hand using the construct below
|
---|
684 | ///
|
---|
685 | /// #pragma GCC diagnostic push
|
---|
686 | /// #pragma GCC diagnostic ignored "-Wpragmas"
|
---|
687 | /// #pragma GCC diagnostic ignored "-Wuninitialized"
|
---|
688 | /// #pragma GCC diagnostic ignored "-Wmaybe-uninitialized"
|
---|
689 | /// ...
|
---|
690 | /// #pragma GCC diagnostic pop
|
---|
691 | ///
|
---|
692 | /// the @GCC diagnostic push/pop directive was only introduced in
|
---|
693 | /// gcc-4.6, so for broader usage, we'd need to insert #pragma GCC
|
---|
694 | /// diagnostic ignored "-Wpragmas" at the top of this file
|
---|
695 | template <class BJ, class I>
|
---|
696 | inline void NNFJN2Tiled<BJ,I>::_add_untagged_neighbours_to_tile_union(
|
---|
697 | const int tile_index,
|
---|
698 | int & n_near_tiles) {
|
---|
699 | for (Tile ** near_tile = _tiles[tile_index].begin_tiles;
|
---|
700 | near_tile != _tiles[tile_index].end_tiles; near_tile++){
|
---|
701 | if (! (*near_tile)->tagged) {
|
---|
702 | (*near_tile)->tagged = true;
|
---|
703 | // get the tile number
|
---|
704 | tile_union[n_near_tiles] = *near_tile - & _tiles[0];
|
---|
705 | n_near_tiles++;
|
---|
706 | }
|
---|
707 | }
|
---|
708 | }
|
---|
709 |
|
---|
710 |
|
---|
711 |
|
---|
712 | FASTJET_END_NAMESPACE // defined in fastjet/internal/base.hh
|
---|
713 |
|
---|
714 |
|
---|
715 | #endif // __FASTJET_NNFJN2TILED_HH__
|
---|