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

 /**
  *
  * Copyright (c) 2010 Matthias Walter (xammy@xammy.homelinux.net)
  *
  * Authors: Matthias Walter
  *
  * 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 <boost/graph/adjacency_list.hpp>
 #include <boost/graph/lookup_edge.hpp>
 #include <boost/test/minimal.hpp>
 #include <boost/graph/bipartite.hpp>

 /// Verifies a 2-coloring

 template <typename Graph, typename ColorMap>
 void check_two_coloring (const Graph& g, const ColorMap color_map)
 {
   typedef boost::graph_traits <Graph> traits;
   typename traits::edge_iterator edge_iter, edge_end;

   for (boost::tie (edge_iter, edge_end) = boost::edges (g); edge_iter != edge_end; ++edge_iter)
   {
     typename traits::vertex_descriptor source, target;
     source = boost::source (*edge_iter, g);
     target = boost::target (*edge_iter, g);
     BOOST_REQUIRE (boost::get(color_map, source) != boost::get(color_map, target));
   }
 }

 /// Tests for a vertex sequence to define an odd cycle

 template <typename Graph, typename RandomAccessIterator>
 void check_odd_cycle (const Graph& g, RandomAccessIterator first, RandomAccessIterator beyond)
 {
   typedef boost::graph_traits <Graph> traits;

   typename traits::vertex_descriptor first_vertex, current_vertex, last_vertex;

   BOOST_CHECK ((beyond - first) % 2 == 1);

   //  std::cout << "odd_cycle: " << int(*first) << std::endl;

   for (first_vertex = current_vertex = *first++; first != beyond; ++first)
   {
     //    std::cout << "odd_cycle: " << int(*first) << std::endl;

     last_vertex = current_vertex;
     current_vertex = *first;

     BOOST_REQUIRE (boost::lookup_edge (current_vertex, last_vertex, g).second);
   }

   BOOST_REQUIRE (boost::lookup_edge (first_vertex, current_vertex, g).second);
 }

 /// Call the is_bipartite and find_odd_cycle functions and verify their results.

 template <typename Graph, typename IndexMap>
 void check_bipartite (const Graph& g, IndexMap index_map, bool is_bipartite)
 {
   typedef boost::graph_traits <Graph> traits;
   typedef std::vector <boost::default_color_type> partition_t;
   typedef std::vector <typename traits::vertex_descriptor> vertex_vector_t;
   typedef boost::iterator_property_map <partition_t::iterator, IndexMap> partition_map_t;

   partition_t partition (boost::num_vertices (g));
   partition_map_t partition_map (partition.begin (), index_map);

   vertex_vector_t odd_cycle (boost::num_vertices (g));

   bool first_result = boost::is_bipartite (g, index_map, partition_map);

   BOOST_REQUIRE (first_result == boost::is_bipartite(g, index_map));

   if (first_result)
     check_two_coloring (g, partition_map);

   BOOST_CHECK (first_result == is_bipartite);

   typename vertex_vector_t::iterator second_first = odd_cycle.begin ();
   typename vertex_vector_t::iterator second_beyond = boost::find_odd_cycle (g, index_map, partition_map, second_first);

   if (is_bipartite)
   {
     BOOST_CHECK (second_beyond == second_first);
     check_two_coloring (g, partition_map);
   }
   else
   {
     check_odd_cycle (g, second_first, second_beyond);
   }

   second_beyond = boost::find_odd_cycle (g, index_map, second_first);
   if (is_bipartite)
   {
     BOOST_CHECK (second_beyond == second_first);
   }
   else
   {
     check_odd_cycle (g, second_first, second_beyond);
   }
 }

 int test_main (int argc, char **argv)
 {
   typedef boost::adjacency_list <boost::vecS, boost::vecS, boost::undirectedS> vector_graph_t;
   typedef boost::adjacency_list <boost::listS, boost::listS, boost::undirectedS> list_graph_t;
   typedef std::pair <int, int> E;

   typedef std::map <boost::graph_traits <list_graph_t>::vertex_descriptor, size_t> index_map_t;
   typedef boost::associative_property_map <index_map_t> index_property_map_t;

   /**
    * Create the graph drawn below.
    *
    *       0 - 1 - 2
    *       |       |
    *   3 - 4 - 5 - 6
    *  /      \   /
    *  |        7
    *  |        |
    *  8 - 9 - 10
    **/

   E bipartite_edges[] = { E (0, 1), E (0, 4), E (1, 2), E (2, 6), E (3, 4), E (3, 8), E (4, 5), E (4, 7), E (5, 6), E (
       6, 7), E (7, 10), E (8, 9), E (9, 10) };
   vector_graph_t bipartite_vector_graph (&bipartite_edges[0],
       &bipartite_edges[0] + sizeof(bipartite_edges) / sizeof(E), 11);
   list_graph_t
       bipartite_list_graph (&bipartite_edges[0], &bipartite_edges[0] + sizeof(bipartite_edges) / sizeof(E), 11);

   /**
    * Create the graph drawn below.
    *
    *       2 - 1 - 0
    *       |       |
    *   3 - 6 - 5 - 4
    *  /      \   /
    *  |        7
    *  |       /
    *  8 ---- 9
    *
    **/

   E non_bipartite_edges[] = { E (0, 1), E (0, 4), E (1, 2), E (2, 6), E (3, 4), E (3, 8), E (4, 5), E (4, 7), E (5, 6),
       E (6, 7), E (7, 9), E (8, 9) };
   vector_graph_t non_bipartite_vector_graph (&non_bipartite_edges[0], &non_bipartite_edges[0]
       + sizeof(non_bipartite_edges) / sizeof(E), 10);
   list_graph_t non_bipartite_list_graph (&non_bipartite_edges[0], &non_bipartite_edges[0] + sizeof(non_bipartite_edges)
       / sizeof(E), 10);

   /// Create index maps

   index_map_t bipartite_index_map, non_bipartite_index_map;
   boost::graph_traits <list_graph_t>::vertex_iterator vertex_iter, vertex_end;
   size_t i = 0;
   for (boost::tie (vertex_iter, vertex_end) = boost::vertices (bipartite_list_graph); vertex_iter != vertex_end; ++vertex_iter)
   {
     bipartite_index_map[*vertex_iter] = i++;
   }
   index_property_map_t bipartite_index_property_map = index_property_map_t (bipartite_index_map);

   i = 0;
   for (boost::tie (vertex_iter, vertex_end) = boost::vertices (non_bipartite_list_graph); vertex_iter != vertex_end; ++vertex_iter)
   {
     non_bipartite_index_map[*vertex_iter] = i++;
   }
   index_property_map_t non_bipartite_index_property_map = index_property_map_t (non_bipartite_index_map);

   /// Call real checks

   check_bipartite (bipartite_vector_graph, boost::get (boost::vertex_index, bipartite_vector_graph), true);
   check_bipartite (bipartite_list_graph, bipartite_index_property_map, true);

   check_bipartite (non_bipartite_vector_graph, boost::get (boost::vertex_index, non_bipartite_vector_graph), false);
   check_bipartite (non_bipartite_list_graph, non_bipartite_index_property_map, false);

   /// Test some more interfaces

   BOOST_REQUIRE (is_bipartite (bipartite_vector_graph));
   BOOST_REQUIRE (!is_bipartite (non_bipartite_vector_graph));

   return 0;
 }
	/**
	*
	* Copyright (c) 2010 Matthias Walter (xammy@xammy.homelinux.net)
	*
	* Authors: Matthias Walter
	*
	* 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 <boost/graph/adjacency_list.hpp>
	#include <boost/graph/lookup_edge.hpp>
	#include <boost/test/minimal.hpp>
	#include <boost/graph/bipartite.hpp>

	/// Verifies a 2-coloring

	template <typename Graph, typename ColorMap>
	void check_two_coloring (const Graph& g, const ColorMap color_map)
	{
	typedef boost::graph_traits <Graph> traits;
	typename traits::edge_iterator edge_iter, edge_end;

	for (boost::tie (edge_iter, edge_end) = boost::edges (g); edge_iter != edge_end; ++edge_iter)
	{
	typename traits::vertex_descriptor source, target;
	source = boost::source (*edge_iter, g);
	target = boost::target (*edge_iter, g);
	BOOST_REQUIRE (boost::get(color_map, source) != boost::get(color_map, target));
	}
	}

	/// Tests for a vertex sequence to define an odd cycle

	template <typename Graph, typename RandomAccessIterator>
	void check_odd_cycle (const Graph& g, RandomAccessIterator first, RandomAccessIterator beyond)
	{
	typedef boost::graph_traits <Graph> traits;

	typename traits::vertex_descriptor first_vertex, current_vertex, last_vertex;

	BOOST_CHECK ((beyond - first) % 2 == 1);

	// std::cout << "odd_cycle: " << int(*first) << std::endl;

	for (first_vertex = current_vertex = *first++; first != beyond; ++first)
	{
	// std::cout << "odd_cycle: " << int(*first) << std::endl;

	last_vertex = current_vertex;
	current_vertex = *first;

	BOOST_REQUIRE (boost::lookup_edge (current_vertex, last_vertex, g).second);
	}

	BOOST_REQUIRE (boost::lookup_edge (first_vertex, current_vertex, g).second);
	}

	/// Call the is_bipartite and find_odd_cycle functions and verify their results.

	template <typename Graph, typename IndexMap>
	void check_bipartite (const Graph& g, IndexMap index_map, bool is_bipartite)
	{
	typedef boost::graph_traits <Graph> traits;
	typedef std::vector <boost::default_color_type> partition_t;
	typedef std::vector <typename traits::vertex_descriptor> vertex_vector_t;
	typedef boost::iterator_property_map <partition_t::iterator, IndexMap> partition_map_t;

	partition_t partition (boost::num_vertices (g));
	partition_map_t partition_map (partition.begin (), index_map);

	vertex_vector_t odd_cycle (boost::num_vertices (g));

	bool first_result = boost::is_bipartite (g, index_map, partition_map);

	BOOST_REQUIRE (first_result == boost::is_bipartite(g, index_map));

	if (first_result)
	check_two_coloring (g, partition_map);

	BOOST_CHECK (first_result == is_bipartite);

	typename vertex_vector_t::iterator second_first = odd_cycle.begin ();
	typename vertex_vector_t::iterator second_beyond = boost::find_odd_cycle (g, index_map, partition_map, second_first);

	if (is_bipartite)
	{
	BOOST_CHECK (second_beyond == second_first);
	check_two_coloring (g, partition_map);
	}
	else
	{
	check_odd_cycle (g, second_first, second_beyond);
	}

	second_beyond = boost::find_odd_cycle (g, index_map, second_first);
	if (is_bipartite)
	{
	BOOST_CHECK (second_beyond == second_first);
	}
	else
	{
	check_odd_cycle (g, second_first, second_beyond);
	}
	}

	int test_main (int argc, char **argv)
	{
	typedef boost::adjacency_list <boost::vecS, boost::vecS, boost::undirectedS> vector_graph_t;
	typedef boost::adjacency_list <boost::listS, boost::listS, boost::undirectedS> list_graph_t;
	typedef std::pair <int, int> E;

	typedef std::map <boost::graph_traits <list_graph_t>::vertex_descriptor, size_t> index_map_t;
	typedef boost::associative_property_map <index_map_t> index_property_map_t;

	/**
	* Create the graph drawn below.
	*
	* 0 - 1 - 2
	* \| \|
	* 3 - 4 - 5 - 6
	* / \ /
	* \| 7
	* \| \|
	* 8 - 9 - 10
	**/

	E bipartite_edges[] = { E (0, 1), E (0, 4), E (1, 2), E (2, 6), E (3, 4), E (3, 8), E (4, 5), E (4, 7), E (5, 6), E (
	6, 7), E (7, 10), E (8, 9), E (9, 10) };
	vector_graph_t bipartite_vector_graph (&bipartite_edges[0],
	&bipartite_edges[0] + sizeof(bipartite_edges) / sizeof(E), 11);
	list_graph_t
	bipartite_list_graph (&bipartite_edges[0], &bipartite_edges[0] + sizeof(bipartite_edges) / sizeof(E), 11);

	/**
	* Create the graph drawn below.
	*
	* 2 - 1 - 0
	* \| \|
	* 3 - 6 - 5 - 4
	* / \ /
	* \| 7
	* \| /
	* 8 ---- 9
	*
	**/

	E non_bipartite_edges[] = { E (0, 1), E (0, 4), E (1, 2), E (2, 6), E (3, 4), E (3, 8), E (4, 5), E (4, 7), E (5, 6),
	E (6, 7), E (7, 9), E (8, 9) };
	vector_graph_t non_bipartite_vector_graph (&non_bipartite_edges[0], &non_bipartite_edges[0]
	+ sizeof(non_bipartite_edges) / sizeof(E), 10);
	list_graph_t non_bipartite_list_graph (&non_bipartite_edges[0], &non_bipartite_edges[0] + sizeof(non_bipartite_edges)
	/ sizeof(E), 10);

	/// Create index maps

	index_map_t bipartite_index_map, non_bipartite_index_map;
	boost::graph_traits <list_graph_t>::vertex_iterator vertex_iter, vertex_end;
	size_t i = 0;
	for (boost::tie (vertex_iter, vertex_end) = boost::vertices (bipartite_list_graph); vertex_iter != vertex_end; ++vertex_iter)
	{
	bipartite_index_map[*vertex_iter] = i++;
	}
	index_property_map_t bipartite_index_property_map = index_property_map_t (bipartite_index_map);

	i = 0;
	for (boost::tie (vertex_iter, vertex_end) = boost::vertices (non_bipartite_list_graph); vertex_iter != vertex_end; ++vertex_iter)
	{
	non_bipartite_index_map[*vertex_iter] = i++;
	}
	index_property_map_t non_bipartite_index_property_map = index_property_map_t (non_bipartite_index_map);

	/// Call real checks

	check_bipartite (bipartite_vector_graph, boost::get (boost::vertex_index, bipartite_vector_graph), true);
	check_bipartite (bipartite_list_graph, bipartite_index_property_map, true);

	check_bipartite (non_bipartite_vector_graph, boost::get (boost::vertex_index, non_bipartite_vector_graph), false);
	check_bipartite (non_bipartite_list_graph, non_bipartite_index_property_map, false);

	/// Test some more interfaces

	BOOST_REQUIRE (is_bipartite (bipartite_vector_graph));
	BOOST_REQUIRE (!is_bipartite (non_bipartite_vector_graph));

	return 0;
	}