boost_1_45_0/libs/graph/test/test_direction.hpp - nest-learning-thermostat/5.0/boost - Git at Google

 // (C) Copyright 2009 Andrew Sutton
 //
 // Use, modification and distribution are subject to the
 // Boost Software License, Version 1.0 (See accompanying file
 // LICENSE_1_0.txt or http://www.boost.org/LICENSE_1_0.txt)

 #ifndef TEST_DIRECTION_HPP
 #define TEST_DIRECTION_HPP

 #include <algorithm>
 #include <boost/range.hpp>

 /** @name Test Out-Directed Graph
  * Test all graphs that have directed out edges.
  */
 //@{
 template <typename Graph, typename VertexSet>
 void test_outdirected_graph(Graph const& g, VertexSet const& verts, boost::mpl::true_) {
     using namespace boost;
     BOOST_CONCEPT_ASSERT((IncidenceGraphConcept<Graph>));

     std::cout << "...test_outdirected_graph\n";
     typedef typename graph_traits<Graph>::out_edge_iterator OutIter;
     typedef std::pair<OutIter, OutIter> OutRange;
     typedef std::vector<OutRange> OutSet;

     // Collect all of the out edge ranges from the graph.
     OutSet outs(verts.size());
     for(size_t i = 0; i < verts.size(); ++i) {
         outs[i] = out_edges(verts[i], g);
     }

     BOOST_ASSERT(distance(outs[0]) == 0);
     BOOST_ASSERT(distance(outs[1]) == 1);
     BOOST_ASSERT(distance(outs[2]) == 1);
     BOOST_ASSERT(distance(outs[3]) == 2);
     BOOST_ASSERT(distance(outs[4]) == 2);
     BOOST_ASSERT(distance(outs[5]) == 1);

     // Verify that the edges are actually correct.
     // TODO: Find a better way of testing connectivity with multiple edges.
     BOOST_ASSERT(has_target(g, *outs[1].first, verts[0]));
     BOOST_ASSERT(has_target(g, *outs[2].first, verts[1]));
     // BOOST_ASSERT(has_target(g, *outs[3].first++, verts[4]));
     // BOOST_ASSERT(has_target(g, *outs[3].first, verts[2]));
     // BOOST_ASSERT(has_target(g, *outs[3].first++, verts[4]));
     // BOOST_ASSERT(has_target(g, *outs[3].first, verts[2]));
     BOOST_ASSERT(has_target(g, *outs[5].first, verts[3]));
 }

 template <typename Graph, typename VertexSet>
 void test_outdirected_graph(Graph const&, VertexSet const&, boost::mpl::false_)
 { }
 //@}

 /** @name Test In-Directed Graph
  * Test all graphs that support in-directed edges.
  */
 //@{
 template <typename Graph, typename VertexSet>
 void test_indirected_graph(Graph const& g, VertexSet const& verts, boost::mpl::true_) {
     using namespace boost;
     BOOST_CONCEPT_ASSERT((BidirectionalGraphConcept<Graph>));

     std::cout << "...test_indirected_graph\n";
     typedef typename graph_traits<Graph>::in_edge_iterator InIter;
     typedef std::pair<InIter, InIter> InRange;
     typedef std::vector<InRange> InSet;

     // Collect all of the in edges from the graph.
     InSet ins(verts.size());
     for(size_t i = 0; i < verts.size(); ++i) {
         ins[i] = in_edges(verts[i], g);
     }

     BOOST_ASSERT(distance(ins[0]) == 2);
     BOOST_ASSERT(distance(ins[1]) == 2);
     BOOST_ASSERT(distance(ins[2]) == 1);
     BOOST_ASSERT(distance(ins[3]) == 1);
     BOOST_ASSERT(distance(ins[4]) == 1);
     BOOST_ASSERT(distance(ins[5]) == 0);

     // Verify that the connected edges are correct.
     // TODO: Find a better way of testing connectivity with multiple edges.
     BOOST_ASSERT(has_source(g, *ins[2].first, verts[3]));
     BOOST_ASSERT(has_source(g, *ins[3].first, verts[5]));
     BOOST_ASSERT(has_source(g, *ins[4].first, verts[3]));
 }

 template <typename Graph, typename VertexSet>
 void test_indirected_graph(Graph const&, VertexSet const&, boost::mpl::false_)
 { }
 //@}

 /** @name Undirected Graphs
  * Test all graphs that have undirected edges.
  */
 template <typename Graph, typename VertexSet>
 void test_undirected_graph(Graph const& g, VertexSet const& verts, boost::mpl::true_) {
     using namespace boost;
     BOOST_CONCEPT_ASSERT((IncidenceGraphConcept<Graph>));

     std::cout << "...test_undirected_graph\n";
     typedef typename graph_traits<Graph>::out_edge_iterator OutIter;
     typedef std::pair<OutIter, OutIter> OutRange;
     typedef std::vector<OutRange> OutSet;

     // The set of out edges is the same as the set of incident edges.
     OutSet outs(verts.size());
     for(size_t i = 0; i < verts.size(); ++i) {
         outs[i] = out_edges(verts[i], g);
     }

     // TODO: Actually test the end connections to ensure that these are
     // definitely correct.
     BOOST_ASSERT(distance(outs[0]) == 2);
     BOOST_ASSERT(distance(outs[1]) == 3);
     BOOST_ASSERT(distance(outs[2]) == 2);
     BOOST_ASSERT(distance(outs[3]) == 3);
     BOOST_ASSERT(distance(outs[4]) == 3);
     BOOST_ASSERT(distance(outs[5]) == 1);
 }

 template <typename Graph, typename VertexSet>
 void test_undirected_graph(Graph const&, VertexSet const&, boost::mpl::false_)
 { }
 //@}

 #endif
	// (C) Copyright 2009 Andrew Sutton
	//
	// Use, modification and distribution are subject to the
	// Boost Software License, Version 1.0 (See accompanying file
	// LICENSE_1_0.txt or http://www.boost.org/LICENSE_1_0.txt)

	#ifndef TEST_DIRECTION_HPP
	#define TEST_DIRECTION_HPP

	#include <algorithm>
	#include <boost/range.hpp>

	/** @name Test Out-Directed Graph
	* Test all graphs that have directed out edges.
	*/
	//@{
	template <typename Graph, typename VertexSet>
	void test_outdirected_graph(Graph const& g, VertexSet const& verts, boost::mpl::true_) {
	using namespace boost;
	BOOST_CONCEPT_ASSERT((IncidenceGraphConcept<Graph>));

	std::cout << "...test_outdirected_graph\n";
	typedef typename graph_traits<Graph>::out_edge_iterator OutIter;
	typedef std::pair<OutIter, OutIter> OutRange;
	typedef std::vector<OutRange> OutSet;

	// Collect all of the out edge ranges from the graph.
	OutSet outs(verts.size());
	for(size_t i = 0; i < verts.size(); ++i) {
	outs[i] = out_edges(verts[i], g);
	}

	BOOST_ASSERT(distance(outs[0]) == 0);
	BOOST_ASSERT(distance(outs[1]) == 1);
	BOOST_ASSERT(distance(outs[2]) == 1);
	BOOST_ASSERT(distance(outs[3]) == 2);
	BOOST_ASSERT(distance(outs[4]) == 2);
	BOOST_ASSERT(distance(outs[5]) == 1);

	// Verify that the edges are actually correct.
	// TODO: Find a better way of testing connectivity with multiple edges.
	BOOST_ASSERT(has_target(g, *outs[1].first, verts[0]));
	BOOST_ASSERT(has_target(g, *outs[2].first, verts[1]));
	// BOOST_ASSERT(has_target(g, *outs[3].first++, verts[4]));
	// BOOST_ASSERT(has_target(g, *outs[3].first, verts[2]));
	// BOOST_ASSERT(has_target(g, *outs[3].first++, verts[4]));
	// BOOST_ASSERT(has_target(g, *outs[3].first, verts[2]));
	BOOST_ASSERT(has_target(g, *outs[5].first, verts[3]));
	}

	template <typename Graph, typename VertexSet>
	void test_outdirected_graph(Graph const&, VertexSet const&, boost::mpl::false_)
	{ }
	//@}

	/** @name Test In-Directed Graph
	* Test all graphs that support in-directed edges.
	*/
	//@{
	template <typename Graph, typename VertexSet>
	void test_indirected_graph(Graph const& g, VertexSet const& verts, boost::mpl::true_) {
	using namespace boost;
	BOOST_CONCEPT_ASSERT((BidirectionalGraphConcept<Graph>));

	std::cout << "...test_indirected_graph\n";
	typedef typename graph_traits<Graph>::in_edge_iterator InIter;
	typedef std::pair<InIter, InIter> InRange;
	typedef std::vector<InRange> InSet;

	// Collect all of the in edges from the graph.
	InSet ins(verts.size());
	for(size_t i = 0; i < verts.size(); ++i) {
	ins[i] = in_edges(verts[i], g);
	}

	BOOST_ASSERT(distance(ins[0]) == 2);
	BOOST_ASSERT(distance(ins[1]) == 2);
	BOOST_ASSERT(distance(ins[2]) == 1);
	BOOST_ASSERT(distance(ins[3]) == 1);
	BOOST_ASSERT(distance(ins[4]) == 1);
	BOOST_ASSERT(distance(ins[5]) == 0);

	// Verify that the connected edges are correct.
	// TODO: Find a better way of testing connectivity with multiple edges.
	BOOST_ASSERT(has_source(g, *ins[2].first, verts[3]));
	BOOST_ASSERT(has_source(g, *ins[3].first, verts[5]));
	BOOST_ASSERT(has_source(g, *ins[4].first, verts[3]));
	}

	template <typename Graph, typename VertexSet>
	void test_indirected_graph(Graph const&, VertexSet const&, boost::mpl::false_)
	{ }
	//@}

	/** @name Undirected Graphs
	* Test all graphs that have undirected edges.
	*/
	template <typename Graph, typename VertexSet>
	void test_undirected_graph(Graph const& g, VertexSet const& verts, boost::mpl::true_) {
	using namespace boost;
	BOOST_CONCEPT_ASSERT((IncidenceGraphConcept<Graph>));

	std::cout << "...test_undirected_graph\n";
	typedef typename graph_traits<Graph>::out_edge_iterator OutIter;
	typedef std::pair<OutIter, OutIter> OutRange;
	typedef std::vector<OutRange> OutSet;

	// The set of out edges is the same as the set of incident edges.
	OutSet outs(verts.size());
	for(size_t i = 0; i < verts.size(); ++i) {
	outs[i] = out_edges(verts[i], g);
	}

	// TODO: Actually test the end connections to ensure that these are
	// definitely correct.
	BOOST_ASSERT(distance(outs[0]) == 2);
	BOOST_ASSERT(distance(outs[1]) == 3);
	BOOST_ASSERT(distance(outs[2]) == 2);
	BOOST_ASSERT(distance(outs[3]) == 3);
	BOOST_ASSERT(distance(outs[4]) == 3);
	BOOST_ASSERT(distance(outs[5]) == 1);
	}

	template <typename Graph, typename VertexSet>
	void test_undirected_graph(Graph const&, VertexSet const&, boost::mpl::false_)
	{ }
	//@}

	#endif