boost_1_45_0/libs/graph/test/metric_tsp_approx.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 //=======================================================================
 // Copyright 2008
 // Author: Matyas W Egyhazy
 //
 // Distributed under the Boost Software License, Version 1.0. (See
 // accompanying file LICENSE_1_0.txt or copy at
 // http://www.boost.org/LICENSE_1_0.txt)
 //=======================================================================

 #include <iostream>
 #include <vector>
 #include <fstream>
 #include <set>
 #include <ctime>

 #include <boost/assert.hpp>
 #include <boost/lexical_cast.hpp>
 #include <boost/random.hpp>
 #include <boost/timer.hpp>
 #include <boost/integer_traits.hpp>
 #include <boost/graph/adjacency_matrix.hpp>
 #include <boost/graph/adjacency_list.hpp>
 #include <boost/graph/simple_point.hpp>
 #include <boost/graph/metric_tsp_approx.hpp>
 #include <boost/graph/graphviz.hpp>

 // TODO: Integrate this into the test system a little better. We need to run
 // the test with some kind of input file.

 template<typename PointType>
 struct cmpPnt
 {
     bool operator()(const boost::simple_point<PointType>& l,
                     const boost::simple_point<PointType>& r) const
     { return (l.x > r.x); }
 };

 //add edges to the graph (for each node connect it to all other nodes)
 template<typename VertexListGraph, typename PointContainer,
     typename WeightMap, typename VertexIndexMap>
 void connectAllEuclidean(VertexListGraph& g,
                         const PointContainer& points,
                         WeightMap wmap,            // Property maps passed by value
                         VertexIndexMap vmap,       // Property maps passed by value
                         int /*sz*/)
 {
     using namespace boost;
     using namespace std;
     typedef typename graph_traits<VertexListGraph>::edge_descriptor Edge;
     typedef typename graph_traits<VertexListGraph>::vertex_iterator VItr;

     Edge e;
     bool inserted;

     pair<VItr, VItr> verts(vertices(g));
     for (VItr src(verts.first); src != verts.second; src++)
     {
         for (VItr dest(src); dest != verts.second; dest++)
         {
             if (dest != src)
             {
                 double weight(sqrt(pow(
                     static_cast<double>(points[vmap[*src]].x -
                         points[vmap[*dest]].x), 2.0) +
                     pow(static_cast<double>(points[vmap[*dest]].y -
                         points[vmap[*src]].y), 2.0)));

                 boost::tie(e, inserted) = add_edge(*src, *dest, g);

                 wmap[e] = weight;
             }

         }

     }
 }

 // Create a randomly generated point
 // scatter time execution
 void testScalability(unsigned numpts)
 {
     using namespace boost;
     using namespace std;

     typedef adjacency_matrix<undirectedS, no_property,
         property <edge_weight_t, double,
         property<edge_index_t, int> > > Graph;
     typedef graph_traits<Graph>::vertex_descriptor Vertex;
     typedef graph_traits <Graph>::edge_descriptor Edge;
     typedef property_map<Graph, edge_weight_t>::type WeightMap;
     typedef set<simple_point<double>, cmpPnt<double> > PointSet;
     typedef vector< Vertex > Container;

     boost::mt19937 rng(time(0));
     uniform_real<> range(0.01, (numpts * 2));
     variate_generator<boost::mt19937&, uniform_real<> >
         pnt_gen(rng, range);

     PointSet points;
     simple_point<double> pnt;

     while (points.size() < numpts)
     {
         pnt.x = pnt_gen();
         pnt.y = pnt_gen();
         points.insert(pnt);
     }

     Graph g(numpts);
     WeightMap weight_map(get(edge_weight, g));
     vector<simple_point<double> > point_vec(points.begin(), points.end());

     connectAllEuclidean(g, point_vec, weight_map, get(vertex_index, g), numpts);

     Container c;
     timer t;
     double len = 0.0;

     // Run the TSP approx, creating the visitor on the fly.
     metric_tsp_approx(g, make_tsp_tour_len_visitor(g, back_inserter(c), len, weight_map));

     cout << "Number of points: " << num_vertices(g) << endl;
     cout << "Number of edges: " << num_edges(g) << endl;
     cout << "Length of tour: " << len << endl;
     cout << "Elapsed: " << t.elapsed() << endl;
 }

 template <typename PositionVec>
 void checkAdjList(PositionVec v)
 {
     using namespace std;
     using namespace boost;

     typedef adjacency_list<listS, listS, undirectedS> Graph;
     typedef graph_traits<Graph>::vertex_descriptor Vertex;
     typedef graph_traits <Graph>::edge_descriptor Edge;
     typedef vector<Vertex> Container;
     typedef map<Vertex, std::size_t> VertexIndexMap;
     typedef map<Edge, double> EdgeWeightMap;
     typedef associative_property_map<VertexIndexMap> VPropertyMap;
     typedef associative_property_map<EdgeWeightMap> EWeightPropertyMap;
     typedef graph_traits<Graph>::vertex_iterator VItr;

     Container c;
     EdgeWeightMap w_map;
     VertexIndexMap v_map;
     VPropertyMap v_pmap(v_map);
     EWeightPropertyMap w_pmap(w_map);

     Graph g(v.size());

     //create vertex index map
     VItr vi, ve;
     int idx(0);
     for (boost::tie(vi, ve) = vertices(g); vi != ve; ++vi)
     {
         Vertex v(*vi);
         v_pmap[v] = idx;
         idx++;
     }

     connectAllEuclidean(g, v, w_pmap,
         v_pmap, v.size());

     metric_tsp_approx_from_vertex(g,
         *vertices(g).first,
         w_pmap,
         v_pmap,
         tsp_tour_visitor<back_insert_iterator<Container > >
         (back_inserter(c)));

     cout << "adj_list" << endl;
     for (Container::iterator itr = c.begin(); itr != c.end(); ++itr) {
         cout << v_map[*itr] << " ";
     }
     cout << endl << endl;

     c.clear();
 }

 static void usage()
 {
     using namespace std;
     cerr << "To run this program properly please place a "
          << "file called graph.txt"
          << endl << "into the current working directory." << endl
          << "Each line of this file should be a coordinate specifying the"
          << endl << "location of a vertex" << endl
          << "For example: " << endl << "1,2" << endl << "20,4" << endl
          << "15,7" << endl << endl;
 }

 int main(int argc, char* argv[])
 {
    using namespace boost;
    using namespace std;

     typedef vector<simple_point<double> > PositionVec;
     typedef adjacency_matrix<undirectedS, no_property,
         property <edge_weight_t, double> > Graph;
     typedef graph_traits<Graph>::vertex_descriptor Vertex;
     typedef graph_traits <Graph>::edge_descriptor Edge;
     typedef vector<Vertex> Container;
     typedef property_map<Graph, edge_weight_t>::type WeightMap;
     typedef property_map<Graph, vertex_index_t>::type VertexMap;

     // Make sure that the the we can parse the given file.
     if(argc < 2) {
         usage();
         // return -1;
         return 0;
     }

     // Open the graph file, failing if one isn't given on the command line.
     ifstream fin(argv[1]);
     if (!fin)
     {
         usage();
         // return -1;
         return 0;
     }

    string line;
    PositionVec position_vec;

    int n(0);
    while (getline(fin, line))
    {
        simple_point<double> vertex;

        size_t idx(line.find(","));
        string xStr(line.substr(0, idx));
        string yStr(line.substr(idx + 1, line.size() - idx));

        vertex.x = lexical_cast<double>(xStr);
        vertex.y = lexical_cast<double>(yStr);

        position_vec.push_back(vertex);
        n++;
    }

    fin.close();

    Container c;
    Graph g(position_vec.size());
    WeightMap weight_map(get(edge_weight, g));
    VertexMap v_map = get(vertex_index, g);

    connectAllEuclidean(g, position_vec, weight_map, v_map, n);

    metric_tsp_approx_tour(g, back_inserter(c));

    for (vector<Vertex>::iterator itr = c.begin(); itr != c.end(); ++itr)
    {
        cout << *itr << " ";
    }
    cout << endl << endl;

    c.clear();

    checkAdjList(position_vec);

    metric_tsp_approx_from_vertex(g, *vertices(g).first,
        get(edge_weight, g), get(vertex_index, g),
        tsp_tour_visitor<back_insert_iterator<vector<Vertex> > >
        (back_inserter(c)));

    for (vector<Vertex>::iterator itr = c.begin(); itr != c.end(); ++itr)
    {
        cout << *itr << " ";
    }
    cout << endl << endl;

    c.clear();

    double len(0.0);
    try {
        metric_tsp_approx(g, make_tsp_tour_len_visitor(g, back_inserter(c), len, weight_map));
    }
    catch (const bad_graph& e) {
        cerr << "bad_graph: " << e.what() << endl;
        return -1;
    }

    cout << "Number of points: " << num_vertices(g) << endl;
    cout << "Number of edges: " << num_edges(g) << endl;
    cout << "Length of Tour: " << len << endl;

    int cnt(0);
    pair<Vertex,Vertex> triangleEdge;
    for (vector<Vertex>::iterator itr = c.begin(); itr != c.end();
        ++itr, ++cnt)
    {
        cout << *itr << " ";

        if (cnt == 2)
        {
            triangleEdge.first = *itr;
        }
        if (cnt == 3)
        {
            triangleEdge.second = *itr;
        }
    }
    cout << endl << endl;
    c.clear();

    testScalability(1000);

    // if the graph is not fully connected then some of the
    // assumed triangle-inequality edges may not exist
    remove_edge(edge(triangleEdge.first, triangleEdge.second, g).first, g);

     // Make sure that we can actually trap incomplete graphs.
     bool caught = false;
     try {
         double len = 0.0;
         metric_tsp_approx(g, make_tsp_tour_len_visitor(g, back_inserter(c), len, weight_map));
     }
     catch (const bad_graph& e) { caught = true; }
     BOOST_ASSERT(caught);

    return 0;
 }
	//=======================================================================
	// Copyright 2008
	// Author: Matyas W Egyhazy
	//
	// Distributed under the Boost Software License, Version 1.0. (See
	// accompanying file LICENSE_1_0.txt or copy at
	// http://www.boost.org/LICENSE_1_0.txt)
	//=======================================================================

	#include <iostream>
	#include <vector>
	#include <fstream>
	#include <set>
	#include <ctime>

	#include <boost/assert.hpp>
	#include <boost/lexical_cast.hpp>
	#include <boost/random.hpp>
	#include <boost/timer.hpp>
	#include <boost/integer_traits.hpp>
	#include <boost/graph/adjacency_matrix.hpp>
	#include <boost/graph/adjacency_list.hpp>
	#include <boost/graph/simple_point.hpp>
	#include <boost/graph/metric_tsp_approx.hpp>
	#include <boost/graph/graphviz.hpp>

	// TODO: Integrate this into the test system a little better. We need to run
	// the test with some kind of input file.

	template<typename PointType>
	struct cmpPnt
	{
	bool operator()(const boost::simple_point<PointType>& l,
	const boost::simple_point<PointType>& r) const
	{ return (l.x > r.x); }
	};

	//add edges to the graph (for each node connect it to all other nodes)
	template<typename VertexListGraph, typename PointContainer,
	typename WeightMap, typename VertexIndexMap>
	void connectAllEuclidean(VertexListGraph& g,
	const PointContainer& points,
	WeightMap wmap, // Property maps passed by value
	VertexIndexMap vmap, // Property maps passed by value
	int /sz/)
	{
	using namespace boost;
	using namespace std;
	typedef typename graph_traits<VertexListGraph>::edge_descriptor Edge;
	typedef typename graph_traits<VertexListGraph>::vertex_iterator VItr;

	Edge e;
	bool inserted;

	pair<VItr, VItr> verts(vertices(g));
	for (VItr src(verts.first); src != verts.second; src++)
	{
	for (VItr dest(src); dest != verts.second; dest++)
	{
	if (dest != src)
	{
	double weight(sqrt(pow(
	static_cast<double>(points[vmap[*src]].x -
	points[vmap[*dest]].x), 2.0) +
	pow(static_cast<double>(points[vmap[*dest]].y -
	points[vmap[*src]].y), 2.0)));

	boost::tie(e, inserted) = add_edge(src, dest, g);

	wmap[e] = weight;
	}

	}

	}
	}

	// Create a randomly generated point
	// scatter time execution
	void testScalability(unsigned numpts)
	{
	using namespace boost;
	using namespace std;

	typedef adjacency_matrix<undirectedS, no_property,
	property <edge_weight_t, double,
	property<edge_index_t, int> > > Graph;
	typedef graph_traits<Graph>::vertex_descriptor Vertex;
	typedef graph_traits <Graph>::edge_descriptor Edge;
	typedef property_map<Graph, edge_weight_t>::type WeightMap;
	typedef set<simple_point<double>, cmpPnt<double> > PointSet;
	typedef vector< Vertex > Container;

	boost::mt19937 rng(time(0));
	uniform_real<> range(0.01, (numpts * 2));
	variate_generator<boost::mt19937&, uniform_real<> >
	pnt_gen(rng, range);

	PointSet points;
	simple_point<double> pnt;

	while (points.size() < numpts)
	{
	pnt.x = pnt_gen();
	pnt.y = pnt_gen();
	points.insert(pnt);
	}

	Graph g(numpts);
	WeightMap weight_map(get(edge_weight, g));
	vector<simple_point<double> > point_vec(points.begin(), points.end());

	connectAllEuclidean(g, point_vec, weight_map, get(vertex_index, g), numpts);

	Container c;
	timer t;
	double len = 0.0;

	// Run the TSP approx, creating the visitor on the fly.
	metric_tsp_approx(g, make_tsp_tour_len_visitor(g, back_inserter(c), len, weight_map));

	cout << "Number of points: " << num_vertices(g) << endl;
	cout << "Number of edges: " << num_edges(g) << endl;
	cout << "Length of tour: " << len << endl;
	cout << "Elapsed: " << t.elapsed() << endl;
	}

	template <typename PositionVec>
	void checkAdjList(PositionVec v)
	{
	using namespace std;
	using namespace boost;

	typedef adjacency_list<listS, listS, undirectedS> Graph;
	typedef graph_traits<Graph>::vertex_descriptor Vertex;
	typedef graph_traits <Graph>::edge_descriptor Edge;
	typedef vector<Vertex> Container;
	typedef map<Vertex, std::size_t> VertexIndexMap;
	typedef map<Edge, double> EdgeWeightMap;
	typedef associative_property_map<VertexIndexMap> VPropertyMap;
	typedef associative_property_map<EdgeWeightMap> EWeightPropertyMap;
	typedef graph_traits<Graph>::vertex_iterator VItr;

	Container c;
	EdgeWeightMap w_map;
	VertexIndexMap v_map;
	VPropertyMap v_pmap(v_map);
	EWeightPropertyMap w_pmap(w_map);

	Graph g(v.size());

	//create vertex index map
	VItr vi, ve;
	int idx(0);
	for (boost::tie(vi, ve) = vertices(g); vi != ve; ++vi)
	{
	Vertex v(*vi);
	v_pmap[v] = idx;
	idx++;
	}

	connectAllEuclidean(g, v, w_pmap,
	v_pmap, v.size());

	metric_tsp_approx_from_vertex(g,
	*vertices(g).first,
	w_pmap,
	v_pmap,
	tsp_tour_visitor<back_insert_iterator<Container > >
	(back_inserter(c)));

	cout << "adj_list" << endl;
	for (Container::iterator itr = c.begin(); itr != c.end(); ++itr) {
	cout << v_map[*itr] << " ";
	}
	cout << endl << endl;

	c.clear();
	}

	static void usage()
	{
	using namespace std;
	cerr << "To run this program properly please place a "
	<< "file called graph.txt"
	<< endl << "into the current working directory." << endl
	<< "Each line of this file should be a coordinate specifying the"
	<< endl << "location of a vertex" << endl
	<< "For example: " << endl << "1,2" << endl << "20,4" << endl
	<< "15,7" << endl << endl;
	}

	int main(int argc, char* argv[])
	{
	using namespace boost;
	using namespace std;

	typedef vector<simple_point<double> > PositionVec;
	typedef adjacency_matrix<undirectedS, no_property,
	property <edge_weight_t, double> > Graph;
	typedef graph_traits<Graph>::vertex_descriptor Vertex;
	typedef graph_traits <Graph>::edge_descriptor Edge;
	typedef vector<Vertex> Container;
	typedef property_map<Graph, edge_weight_t>::type WeightMap;
	typedef property_map<Graph, vertex_index_t>::type VertexMap;

	// Make sure that the the we can parse the given file.
	if(argc < 2) {
	usage();
	// return -1;
	return 0;
	}

	// Open the graph file, failing if one isn't given on the command line.
	ifstream fin(argv[1]);
	if (!fin)
	{
	usage();
	// return -1;
	return 0;
	}

	string line;
	PositionVec position_vec;

	int n(0);
	while (getline(fin, line))
	{
	simple_point<double> vertex;

	size_t idx(line.find(","));
	string xStr(line.substr(0, idx));
	string yStr(line.substr(idx + 1, line.size() - idx));

	vertex.x = lexical_cast<double>(xStr);
	vertex.y = lexical_cast<double>(yStr);

	position_vec.push_back(vertex);
	n++;
	}

	fin.close();

	Container c;
	Graph g(position_vec.size());
	WeightMap weight_map(get(edge_weight, g));
	VertexMap v_map = get(vertex_index, g);

	connectAllEuclidean(g, position_vec, weight_map, v_map, n);

	metric_tsp_approx_tour(g, back_inserter(c));

	for (vector<Vertex>::iterator itr = c.begin(); itr != c.end(); ++itr)
	{
	cout << *itr << " ";
	}
	cout << endl << endl;

	c.clear();

	checkAdjList(position_vec);

	metric_tsp_approx_from_vertex(g, *vertices(g).first,
	get(edge_weight, g), get(vertex_index, g),
	tsp_tour_visitor<back_insert_iterator<vector<Vertex> > >
	(back_inserter(c)));

	for (vector<Vertex>::iterator itr = c.begin(); itr != c.end(); ++itr)
	{
	cout << *itr << " ";
	}
	cout << endl << endl;

	c.clear();

	double len(0.0);
	try {
	metric_tsp_approx(g, make_tsp_tour_len_visitor(g, back_inserter(c), len, weight_map));
	}
	catch (const bad_graph& e) {
	cerr << "bad_graph: " << e.what() << endl;
	return -1;
	}

	cout << "Number of points: " << num_vertices(g) << endl;
	cout << "Number of edges: " << num_edges(g) << endl;
	cout << "Length of Tour: " << len << endl;

	int cnt(0);
	pair<Vertex,Vertex> triangleEdge;
	for (vector<Vertex>::iterator itr = c.begin(); itr != c.end();
	++itr, ++cnt)
	{
	cout << *itr << " ";

	if (cnt == 2)
	{
	triangleEdge.first = *itr;
	}
	if (cnt == 3)
	{
	triangleEdge.second = *itr;
	}
	}
	cout << endl << endl;
	c.clear();

	testScalability(1000);

	// if the graph is not fully connected then some of the
	// assumed triangle-inequality edges may not exist
	remove_edge(edge(triangleEdge.first, triangleEdge.second, g).first, g);

	// Make sure that we can actually trap incomplete graphs.
	bool caught = false;
	try {
	double len = 0.0;
	metric_tsp_approx(g, make_tsp_tour_len_visitor(g, back_inserter(c), len, weight_map));
	}
	catch (const bad_graph& e) { caught = true; }
	BOOST_ASSERT(caught);

	return 0;
	}