lemon/insertion_tsp.h
author Balazs Dezso <deba@google.com>
Tue, 15 May 2018 14:16:35 +0200
changeset 1174 1e5da3fc4fbc
parent 1076 97d978243703
permissions -rw-r--r--
Fix PlanarDrawing::run() function (#610)
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/* -*- mode: C++; indent-tabs-mode: nil; -*-
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 *
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 * This file is a part of LEMON, a generic C++ optimization library.
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 *
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 * Copyright (C) 2003-2013
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 * Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport
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 * (Egervary Research Group on Combinatorial Optimization, EGRES).
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 *
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 * Permission to use, modify and distribute this software is granted
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 * provided that this copyright notice appears in all copies. For
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 * precise terms see the accompanying LICENSE file.
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 *
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 * This software is provided "AS IS" with no warranty of any kind,
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 * express or implied, and with no claim as to its suitability for any
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 * purpose.
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 *
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 */
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#ifndef LEMON_INSERTION_TSP_H
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#define LEMON_INSERTION_TSP_H
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/// \ingroup tsp
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/// \file
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/// \brief Insertion algorithm for symmetric TSP
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#include <vector>
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#include <functional>
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#include <lemon/full_graph.h>
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#include <lemon/maps.h>
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#include <lemon/random.h>
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namespace lemon {
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  /// \ingroup tsp
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  ///
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  /// \brief Insertion algorithm for symmetric TSP.
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  ///
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  /// InsertionTsp implements the insertion heuristic for solving
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  /// symmetric \ref tsp "TSP".
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  ///
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  /// This is a fast and effective tour construction method that has
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  /// many variants.
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  /// It starts with a subtour containing a few nodes of the graph and it
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  /// iteratively inserts the other nodes into this subtour according to a
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  /// certain node selection rule.
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  ///
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  /// This method is among the fastest TSP algorithms, and it typically
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  /// provides quite good solutions (usually much better than
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  /// \ref NearestNeighborTsp and \ref GreedyTsp).
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  ///
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  /// InsertionTsp implements four different node selection rules,
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  /// from which the most effective one (\e farthest \e node \e selection)
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  /// is used by default.
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  /// With this choice, the algorithm runs in O(n<sup>2</sup>) time.
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  /// For more information, see \ref SelectionRule.
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  ///
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  /// \tparam CM Type of the cost map.
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  template <typename CM>
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  class InsertionTsp
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  {
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    public:
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      /// Type of the cost map
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      typedef CM CostMap;
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      /// Type of the edge costs
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      typedef typename CM::Value Cost;
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    private:
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      GRAPH_TYPEDEFS(FullGraph);
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      const FullGraph &_gr;
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      const CostMap &_cost;
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      std::vector<Node> _notused;
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      std::vector<Node> _tour;
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      Cost _sum;
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    public:
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      /// \brief Constants for specifying the node selection rule.
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      ///
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      /// Enum type containing constants for specifying the node selection
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      /// rule for the \ref run() function.
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      ///
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      /// During the algorithm, nodes are selected for addition to the current
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      /// subtour according to the applied rule.
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      /// The FARTHEST method is one of the fastest selection rules, and
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      /// it is typically the most effective, thus it is the default
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      /// option. The RANDOM rule usually gives slightly worse results,
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      /// but it is more robust.
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      ///
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      /// The desired selection rule can be specified as a parameter of the
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      /// \ref run() function.
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      enum SelectionRule {
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        /// An unvisited node having minimum distance from the current
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        /// subtour is selected at each step.
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        /// The algorithm runs in O(n<sup>2</sup>) time using this
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        /// selection rule.
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        NEAREST,
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        /// An unvisited node having maximum distance from the current
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        /// subtour is selected at each step.
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        /// The algorithm runs in O(n<sup>2</sup>) time using this
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        /// selection rule.
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        FARTHEST,
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        /// An unvisited node whose insertion results in the least
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        /// increase of the subtour's total cost is selected at each step.
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        /// The algorithm runs in O(n<sup>3</sup>) time using this
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        /// selection rule, but in most cases, it is almost as fast as
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        /// with other rules.
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        CHEAPEST,
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        /// An unvisited node is selected randomly without any evaluation
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        /// at each step.
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        /// The global \ref rnd "random number generator instance" is used.
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        /// You can seed it before executing the algorithm, if you
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        /// would like to.
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        /// The algorithm runs in O(n<sup>2</sup>) time using this
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        /// selection rule.
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        RANDOM
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      };
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    public:
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      /// \brief Constructor
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      ///
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      /// Constructor.
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      /// \param gr The \ref FullGraph "full graph" the algorithm runs on.
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      /// \param cost The cost map.
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      InsertionTsp(const FullGraph &gr, const CostMap &cost)
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        : _gr(gr), _cost(cost) {}
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      /// \name Execution Control
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      /// @{
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      /// \brief Runs the algorithm.
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      ///
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      /// This function runs the algorithm.
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      ///
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      /// \param rule The node selection rule. For more information, see
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      /// \ref SelectionRule.
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      ///
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      /// \return The total cost of the found tour.
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      Cost run(SelectionRule rule = FARTHEST) {
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        _tour.clear();
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        if (_gr.nodeNum() == 0) return _sum = 0;
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        else if (_gr.nodeNum() == 1) {
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          _tour.push_back(_gr(0));
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          return _sum = 0;
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        }
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        switch (rule) {
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          case NEAREST:
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            init(true);
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            start<ComparingSelection<std::less<Cost> >,
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                  DefaultInsertion>();
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            break;
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          case FARTHEST:
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            init(false);
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            start<ComparingSelection<std::greater<Cost> >,
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                  DefaultInsertion>();
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            break;
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          case CHEAPEST:
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            init(true);
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            start<CheapestSelection, CheapestInsertion>();
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            break;
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          case RANDOM:
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            init(true);
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            start<RandomSelection, DefaultInsertion>();
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            break;
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        }
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        return _sum;
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      }
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      /// @}
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      /// \name Query Functions
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      /// @{
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      /// \brief The total cost of the found tour.
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      ///
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      /// This function returns the total cost of the found tour.
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      ///
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      /// \pre run() must be called before using this function.
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      Cost tourCost() const {
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        return _sum;
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      }
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      /// \brief Returns a const reference to the node sequence of the
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      /// found tour.
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      ///
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      /// This function returns a const reference to a vector
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      /// that stores the node sequence of the found tour.
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      ///
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      /// \pre run() must be called before using this function.
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      const std::vector<Node>& tourNodes() const {
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        return _tour;
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      }
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      /// \brief Gives back the node sequence of the found tour.
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      ///
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      /// This function copies the node sequence of the found tour into
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      /// an STL container through the given output iterator. The
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      /// <tt>value_type</tt> of the container must be <tt>FullGraph::Node</tt>.
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      /// For example,
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      /// \code
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      /// std::vector<FullGraph::Node> nodes(countNodes(graph));
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      /// tsp.tourNodes(nodes.begin());
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      /// \endcode
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      /// or
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      /// \code
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      /// std::list<FullGraph::Node> nodes;
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      /// tsp.tourNodes(std::back_inserter(nodes));
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      /// \endcode
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      ///
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      /// \pre run() must be called before using this function.
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      template <typename Iterator>
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      void tourNodes(Iterator out) const {
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        std::copy(_tour.begin(), _tour.end(), out);
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      }
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      /// \brief Gives back the found tour as a path.
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      ///
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      /// This function copies the found tour as a list of arcs/edges into
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      /// the given \ref lemon::concepts::Path "path structure".
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      ///
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      /// \pre run() must be called before using this function.
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      template <typename Path>
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      void tour(Path &path) const {
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        path.clear();
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        for (int i = 0; i < int(_tour.size()) - 1; ++i) {
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          path.addBack(_gr.arc(_tour[i], _tour[i+1]));
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        }
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        if (int(_tour.size()) >= 2) {
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          path.addBack(_gr.arc(_tour.back(), _tour.front()));
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        }
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      }
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      /// @}
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    private:
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      // Initializes the algorithm
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      void init(bool min) {
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        Edge min_edge = min ? mapMin(_gr, _cost) : mapMax(_gr, _cost);
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        _tour.clear();
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        _tour.push_back(_gr.u(min_edge));
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        _tour.push_back(_gr.v(min_edge));
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        _notused.clear();
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        for (NodeIt n(_gr); n!=INVALID; ++n) {
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          if (n != _gr.u(min_edge) && n != _gr.v(min_edge)) {
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            _notused.push_back(n);
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          }
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        }
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        _sum = _cost[min_edge] * 2;
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      }
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      // Executes the algorithm
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      template <class SelectionFunctor, class InsertionFunctor>
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      void start() {
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        SelectionFunctor selectNode(_gr, _cost, _tour, _notused);
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        InsertionFunctor insertNode(_gr, _cost, _tour, _sum);
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        for (int i=0; i<_gr.nodeNum()-2; ++i) {
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          insertNode.insert(selectNode.select());
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        }
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        _sum = _cost[_gr.edge(_tour.back(), _tour.front())];
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        for (int i = 0; i < int(_tour.size())-1; ++i) {
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          _sum += _cost[_gr.edge(_tour[i], _tour[i+1])];
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        }
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      }
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      // Implementation of the nearest and farthest selection rule
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      template <typename Comparator>
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      class ComparingSelection {
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        public:
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          ComparingSelection(const FullGraph &gr, const CostMap &cost,
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                  std::vector<Node> &tour, std::vector<Node> &notused)
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            : _gr(gr), _cost(cost), _tour(tour), _notused(notused),
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              _dist(gr, 0), _compare()
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          {
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            // Compute initial distances for the unused nodes
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            for (unsigned int i=0; i<_notused.size(); ++i) {
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              Node u = _notused[i];
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              Cost min_dist = _cost[_gr.edge(u, _tour[0])];
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              for (unsigned int j=1; j<_tour.size(); ++j) {
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                Cost curr = _cost[_gr.edge(u, _tour[j])];
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                if (curr < min_dist) {
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                  min_dist = curr;
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                }
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              }
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              _dist[u] = min_dist;
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            }
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          }
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          Node select() {
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            // Select an used node with minimum distance
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            Cost ins_dist = 0;
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            int ins_node = -1;
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            for (unsigned int i=0; i<_notused.size(); ++i) {
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              Cost curr = _dist[_notused[i]];
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              if (_compare(curr, ins_dist) || ins_node == -1) {
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                ins_dist = curr;
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                ins_node = i;
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              }
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            }
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            // Remove the selected node from the unused vector
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            Node sn = _notused[ins_node];
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            _notused[ins_node] = _notused.back();
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            _notused.pop_back();
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            // Update the distances of the remaining nodes
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            for (unsigned int i=0; i<_notused.size(); ++i) {
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              Node u = _notused[i];
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              Cost nc = _cost[_gr.edge(sn, u)];
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              if (nc < _dist[u]) {
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                _dist[u] = nc;
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              }
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            }
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            return sn;
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          }
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        private:
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          const FullGraph &_gr;
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          const CostMap &_cost;
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          std::vector<Node> &_tour;
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          std::vector<Node> &_notused;
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          FullGraph::NodeMap<Cost> _dist;
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          Comparator _compare;
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      };
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      // Implementation of the cheapest selection rule
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      class CheapestSelection {
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        private:
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          Cost costDiff(Node u, Node v, Node w) const {
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            return
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              _cost[_gr.edge(u, w)] +
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              _cost[_gr.edge(v, w)] -
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              _cost[_gr.edge(u, v)];
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          }
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        public:
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          CheapestSelection(const FullGraph &gr, const CostMap &cost,
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                            std::vector<Node> &tour, std::vector<Node> &notused)
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            : _gr(gr), _cost(cost), _tour(tour), _notused(notused),
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              _ins_cost(gr, 0), _ins_pos(gr, -1)
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          {
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            // Compute insertion cost and position for the unused nodes
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            for (unsigned int i=0; i<_notused.size(); ++i) {
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              Node u = _notused[i];
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              Cost min_cost = costDiff(_tour.back(), _tour.front(), u);
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              int min_pos = 0;
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              for (unsigned int j=1; j<_tour.size(); ++j) {
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                Cost curr_cost = costDiff(_tour[j-1], _tour[j], u);
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                if (curr_cost < min_cost) {
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                  min_cost = curr_cost;
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                  min_pos = j;
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                }
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              }
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              _ins_cost[u] = min_cost;
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              _ins_pos[u] = min_pos;
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            }
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          }
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          Cost select() {
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            // Select an used node with minimum insertion cost
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            Cost min_cost = 0;
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            int min_node = -1;
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            for (unsigned int i=0; i<_notused.size(); ++i) {
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              Cost curr_cost = _ins_cost[_notused[i]];
kpeter@1036
   383
              if (curr_cost < min_cost || min_node == -1) {
kpeter@1036
   384
                min_cost = curr_cost;
kpeter@1036
   385
                min_node = i;
f4c3@1031
   386
              }
f4c3@1031
   387
            }
f4c3@1031
   388
kpeter@1036
   389
            // Remove the selected node from the unused vector
kpeter@1036
   390
            Node sn = _notused[min_node];
kpeter@1036
   391
            _notused[min_node] = _notused.back();
kpeter@1036
   392
            _notused.pop_back();
alpar@1092
   393
kpeter@1036
   394
            // Insert the selected node into the tour
kpeter@1036
   395
            const int ipos = _ins_pos[sn];
kpeter@1036
   396
            _tour.insert(_tour.begin() + ipos, sn);
f4c3@1031
   397
kpeter@1036
   398
            // Update the insertion cost and position of the remaining nodes
kpeter@1036
   399
            for (unsigned int i=0; i<_notused.size(); ++i) {
kpeter@1036
   400
              Node u = _notused[i];
kpeter@1036
   401
              Cost curr_cost = _ins_cost[u];
kpeter@1036
   402
              int curr_pos = _ins_pos[u];
kpeter@1036
   403
kpeter@1036
   404
              int ipos_prev = ipos == 0 ? _tour.size()-1 : ipos-1;
kpeter@1036
   405
              int ipos_next = ipos == int(_tour.size())-1 ? 0 : ipos+1;
kpeter@1036
   406
              Cost nc1 = costDiff(_tour[ipos_prev], _tour[ipos], u);
kpeter@1036
   407
              Cost nc2 = costDiff(_tour[ipos], _tour[ipos_next], u);
alpar@1092
   408
kpeter@1036
   409
              if (nc1 <= curr_cost || nc2 <= curr_cost) {
kpeter@1036
   410
                // A new position is better than the old one
kpeter@1036
   411
                if (nc1 <= nc2) {
kpeter@1036
   412
                  curr_cost = nc1;
kpeter@1036
   413
                  curr_pos = ipos;
kpeter@1036
   414
                } else {
kpeter@1036
   415
                  curr_cost = nc2;
kpeter@1036
   416
                  curr_pos = ipos_next;
kpeter@1036
   417
                }
kpeter@1036
   418
              }
kpeter@1036
   419
              else {
kpeter@1036
   420
                if (curr_pos == ipos) {
kpeter@1036
   421
                  // The minimum should be found again
kpeter@1036
   422
                  curr_cost = costDiff(_tour.back(), _tour.front(), u);
alpar@1092
   423
                  curr_pos = 0;
kpeter@1036
   424
                  for (unsigned int j=1; j<_tour.size(); ++j) {
kpeter@1036
   425
                    Cost tmp_cost = costDiff(_tour[j-1], _tour[j], u);
kpeter@1036
   426
                    if (tmp_cost < curr_cost) {
kpeter@1036
   427
                      curr_cost = tmp_cost;
kpeter@1036
   428
                      curr_pos = j;
kpeter@1036
   429
                    }
kpeter@1036
   430
                  }
kpeter@1036
   431
                }
kpeter@1036
   432
                else if (curr_pos > ipos) {
kpeter@1036
   433
                  ++curr_pos;
kpeter@1036
   434
                }
kpeter@1036
   435
              }
alpar@1092
   436
kpeter@1036
   437
              _ins_cost[u] = curr_cost;
kpeter@1036
   438
              _ins_pos[u] = curr_pos;
kpeter@1036
   439
            }
kpeter@1036
   440
kpeter@1036
   441
            return min_cost;
f4c3@1031
   442
          }
kpeter@1033
   443
f4c3@1031
   444
        private:
f4c3@1031
   445
          const FullGraph &_gr;
f4c3@1031
   446
          const CostMap &_cost;
kpeter@1036
   447
          std::vector<Node> &_tour;
f4c3@1031
   448
          std::vector<Node> &_notused;
kpeter@1036
   449
          FullGraph::NodeMap<Cost> _ins_cost;
kpeter@1036
   450
          FullGraph::NodeMap<int> _ins_pos;
f4c3@1031
   451
      };
f4c3@1031
   452
kpeter@1033
   453
      // Implementation of the random selection rule
f4c3@1031
   454
      class RandomSelection {
f4c3@1031
   455
        public:
f4c3@1031
   456
          RandomSelection(const FullGraph &, const CostMap &,
kpeter@1033
   457
                          std::vector<Node> &, std::vector<Node> &notused)
kpeter@1033
   458
            : _notused(notused) {}
kpeter@1033
   459
f4c3@1031
   460
          Node select() const {
f4c3@1031
   461
            const int index = rnd[_notused.size()];
f4c3@1031
   462
            Node n = _notused[index];
kpeter@1036
   463
            _notused[index] = _notused.back();
kpeter@1036
   464
            _notused.pop_back();
f4c3@1031
   465
            return n;
f4c3@1031
   466
          }
kpeter@1036
   467
f4c3@1031
   468
        private:
f4c3@1031
   469
          std::vector<Node> &_notused;
f4c3@1031
   470
      };
f4c3@1031
   471
f4c3@1031
   472
kpeter@1033
   473
      // Implementation of the default insertion method
kpeter@1033
   474
      class DefaultInsertion {
f4c3@1031
   475
        private:
f4c3@1031
   476
          Cost costDiff(Node u, Node v, Node w) const {
kpeter@1033
   477
            return
f4c3@1031
   478
              _cost[_gr.edge(u, w)] +
f4c3@1031
   479
              _cost[_gr.edge(v, w)] -
f4c3@1031
   480
              _cost[_gr.edge(u, v)];
f4c3@1031
   481
          }
kpeter@1033
   482
f4c3@1031
   483
        public:
kpeter@1033
   484
          DefaultInsertion(const FullGraph &gr, const CostMap &cost,
kpeter@1036
   485
                           std::vector<Node> &tour, Cost &total_cost) :
kpeter@1036
   486
            _gr(gr), _cost(cost), _tour(tour), _total(total_cost) {}
kpeter@1033
   487
f4c3@1031
   488
          void insert(Node n) const {
f4c3@1031
   489
            int min = 0;
f4c3@1031
   490
            Cost min_val =
kpeter@1036
   491
              costDiff(_tour.front(), _tour.back(), n);
kpeter@1033
   492
kpeter@1036
   493
            for (unsigned int i=1; i<_tour.size(); ++i) {
kpeter@1036
   494
              Cost tmp = costDiff(_tour[i-1], _tour[i], n);
f4c3@1031
   495
              if (tmp < min_val) {
f4c3@1031
   496
                min = i;
f4c3@1031
   497
                min_val = tmp;
f4c3@1031
   498
              }
f4c3@1031
   499
            }
kpeter@1033
   500
kpeter@1036
   501
            _tour.insert(_tour.begin()+min, n);
kpeter@1033
   502
            _total += min_val;
f4c3@1031
   503
          }
kpeter@1033
   504
f4c3@1031
   505
        private:
f4c3@1031
   506
          const FullGraph &_gr;
f4c3@1031
   507
          const CostMap &_cost;
kpeter@1036
   508
          std::vector<Node> &_tour;
kpeter@1033
   509
          Cost &_total;
f4c3@1031
   510
      };
kpeter@1033
   511
kpeter@1033
   512
      // Implementation of a special insertion method for the cheapest
kpeter@1033
   513
      // selection rule
kpeter@1033
   514
      class CheapestInsertion {
f4c3@1031
   515
        TEMPLATE_GRAPH_TYPEDEFS(FullGraph);
f4c3@1031
   516
        public:
kpeter@1033
   517
          CheapestInsertion(const FullGraph &, const CostMap &,
kpeter@1033
   518
                            std::vector<Node> &, Cost &total_cost) :
kpeter@1033
   519
            _total(total_cost) {}
kpeter@1033
   520
f4c3@1031
   521
          void insert(Cost diff) const {
kpeter@1033
   522
            _total += diff;
f4c3@1031
   523
          }
f4c3@1031
   524
f4c3@1031
   525
        private:
kpeter@1033
   526
          Cost &_total;
kpeter@1033
   527
      };
kpeter@1033
   528
f4c3@1031
   529
  };
kpeter@1033
   530
f4c3@1031
   531
}; // namespace lemon
f4c3@1031
   532
f4c3@1031
   533
#endif