boost_1_45_0/libs/graph/test/test_graph.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_GRAPH_HPP
 #define TEST_GRAPH_HPP

 /** @file test_graph.hpp
  * This file houses the generic graph testing framework, which is essentially
  * run using the test_graph function. This function is called, passing a
  * graph object that be constructed and exercised according to the concepts
  * that the graph models. This test is extensively metaprogrammed in order to
  * differentiate testable features of graph instances.
  */

 #include "typestr.hpp"

 #include <utility>
 #include <vector>
 #include <boost/assert.hpp>
 #include <boost/graph/graph_concepts.hpp>
 #include <boost/graph/graph_traits.hpp>
 #include <boost/graph/graph_mutability_traits.hpp>
 #include <boost/graph/labeled_graph.hpp>

 #define BOOST_META_ASSERT(x) BOOST_ASSERT(x::value)

 typedef std::pair<std::size_t, std::size_t> Pair;

 static const std::size_t N = 6;
 static const std::size_t M = 7;

 // A helper function that globally defines the graph being constructed. Note
 // that this graph shown here: http://en.wikipedia.org/wiki/Graph_theory.
 std::pair<Pair*, Pair*> edge_pairs() {
     static Pair pairs[] = {
         Pair(5, 3), Pair(3, 4), Pair(3, 2), Pair(4, 0), Pair(4, 1),
         Pair(2, 1), Pair(1, 0)
     };
     Pair* f = &pairs[0];
     Pair* l = f + M;
     return std::make_pair(f, l);
 }

 // Return true if the vertex v is the target of the edge e.
 template <typename Graph, typename Edge, typename Vertex>
 bool has_target(Graph const& g, Edge e, Vertex v)
 { return boost::target(e, g) == v; }

 // Return true if the vertex v is the source of the edge e.
 template <typename Graph, typename Edge, typename Vertex>
 bool has_source(Graph const& g, Edge e, Vertex v)
 { return boost::source(e, g) == v; }

 /** @name Property Bundles
  * Support testing with bundled properties. Note that the vertex bundle and
  * edge bundle MAY NOT be the same if you want to use the property map type
  * generator to define property maps.
  */
 //@{
 // This is really just a place holder to make sure that bundled graph
 // properties actually work. There are no semantics to this type.
 struct GraphBundle {
   int value;
 };

 struct VertexBundle {
     VertexBundle() : value() { }
     VertexBundle(int n) : value(n) { }

     bool operator==(VertexBundle const& x) const { return value == x.value; }
     bool operator<(VertexBundle const& x) const { return value < x.value; }

     int value;
 };

 struct EdgeBundle {
     EdgeBundle() : value() { }
     EdgeBundle(int n) : value(n) { }

     bool operator==(EdgeBundle const& x) const { return value == x.value; }
     bool operator<(EdgeBundle const& x) const { return value < x.value; }

     int value;
 };
 //@}

 #include "test_construction.hpp"
 #include "test_destruction.hpp"
 #include "test_iteration.hpp"
 #include "test_direction.hpp"
 #include "test_properties.hpp"

 template <typename Graph>
 void test_graph(Graph& g) {
     using namespace boost;
     BOOST_CONCEPT_ASSERT((GraphConcept<Graph>));

     std::cout << typestr(g) << "\n";

     // Define a bunch of tags for the graph.
     typename graph_has_add_vertex<Graph>::type can_add_vertex;
     typename graph_has_remove_vertex<Graph>::type can_remove_vertex;
     typename is_labeled_graph<Graph>::type is_labeled;
     typename is_directed_unidirectional_graph<Graph>::type is_directed;
     typename is_directed_bidirectional_graph<Graph>::type is_bidirectional;
     typename is_undirected_graph<Graph>::type is_undirected;

     // Test constrution and vertex list.
     build_graph(g, can_add_vertex, is_labeled);
     build_property_graph(g, can_add_vertex, is_labeled);

     test_vertex_list_graph(g);

     // Collect the vertices for an easy method of "naming" them.
     typedef typename graph_traits<Graph>::vertex_descriptor Vertex;
     typedef typename graph_traits<Graph>::vertex_iterator VertexIterator;
     std::vector<Vertex> verts;
     std::pair<VertexIterator, VertexIterator> rng = vertices(g);
     for( ; rng.first != rng.second; ++rng.first) {
         verts.push_back(*rng.first);
     }

     // Test connection and edge list
     connect_graph(g, verts, is_labeled);
     // connect_property_graph(g, verts, is_labeld);
     test_edge_list_graph(g);

     // Test properties
     test_properties(g, verts);

     // Test directionality.
     test_outdirected_graph(g, verts, is_directed);
     test_indirected_graph(g, verts, is_bidirectional);
     test_undirected_graph(g, verts, is_undirected);

     // Test disconnection
     disconnect_graph(g, verts, is_labeled);
     destroy_graph(g, verts, can_remove_vertex, is_labeled);
 }


 #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_GRAPH_HPP
	#define TEST_GRAPH_HPP

	/** @file test_graph.hpp
	* This file houses the generic graph testing framework, which is essentially
	* run using the test_graph function. This function is called, passing a
	* graph object that be constructed and exercised according to the concepts
	* that the graph models. This test is extensively metaprogrammed in order to
	* differentiate testable features of graph instances.
	*/

	#include "typestr.hpp"

	#include <utility>
	#include <vector>
	#include <boost/assert.hpp>
	#include <boost/graph/graph_concepts.hpp>
	#include <boost/graph/graph_traits.hpp>
	#include <boost/graph/graph_mutability_traits.hpp>
	#include <boost/graph/labeled_graph.hpp>

	#define BOOST_META_ASSERT(x) BOOST_ASSERT(x::value)

	typedef std::pair<std::size_t, std::size_t> Pair;

	static const std::size_t N = 6;
	static const std::size_t M = 7;

	// A helper function that globally defines the graph being constructed. Note
	// that this graph shown here: http://en.wikipedia.org/wiki/Graph_theory.
	std::pair<Pair, Pair> edge_pairs() {
	static Pair pairs[] = {
	Pair(5, 3), Pair(3, 4), Pair(3, 2), Pair(4, 0), Pair(4, 1),
	Pair(2, 1), Pair(1, 0)
	};
	Pair* f = &pairs[0];
	Pair* l = f + M;
	return std::make_pair(f, l);
	}

	// Return true if the vertex v is the target of the edge e.
	template <typename Graph, typename Edge, typename Vertex>
	bool has_target(Graph const& g, Edge e, Vertex v)
	{ return boost::target(e, g) == v; }

	// Return true if the vertex v is the source of the edge e.
	template <typename Graph, typename Edge, typename Vertex>
	bool has_source(Graph const& g, Edge e, Vertex v)
	{ return boost::source(e, g) == v; }

	/** @name Property Bundles
	* Support testing with bundled properties. Note that the vertex bundle and
	* edge bundle MAY NOT be the same if you want to use the property map type
	* generator to define property maps.
	*/
	//@{
	// This is really just a place holder to make sure that bundled graph
	// properties actually work. There are no semantics to this type.
	struct GraphBundle {
	int value;
	};

	struct VertexBundle {
	VertexBundle() : value() { }
	VertexBundle(int n) : value(n) { }

	bool operator==(VertexBundle const& x) const { return value == x.value; }
	bool operator<(VertexBundle const& x) const { return value < x.value; }

	int value;
	};

	struct EdgeBundle {
	EdgeBundle() : value() { }
	EdgeBundle(int n) : value(n) { }

	bool operator==(EdgeBundle const& x) const { return value == x.value; }
	bool operator<(EdgeBundle const& x) const { return value < x.value; }

	int value;
	};
	//@}

	#include "test_construction.hpp"
	#include "test_destruction.hpp"
	#include "test_iteration.hpp"
	#include "test_direction.hpp"
	#include "test_properties.hpp"

	template <typename Graph>
	void test_graph(Graph& g) {
	using namespace boost;
	BOOST_CONCEPT_ASSERT((GraphConcept<Graph>));

	std::cout << typestr(g) << "\n";

	// Define a bunch of tags for the graph.
	typename graph_has_add_vertex<Graph>::type can_add_vertex;
	typename graph_has_remove_vertex<Graph>::type can_remove_vertex;
	typename is_labeled_graph<Graph>::type is_labeled;
	typename is_directed_unidirectional_graph<Graph>::type is_directed;
	typename is_directed_bidirectional_graph<Graph>::type is_bidirectional;
	typename is_undirected_graph<Graph>::type is_undirected;

	// Test constrution and vertex list.
	build_graph(g, can_add_vertex, is_labeled);
	build_property_graph(g, can_add_vertex, is_labeled);

	test_vertex_list_graph(g);

	// Collect the vertices for an easy method of "naming" them.
	typedef typename graph_traits<Graph>::vertex_descriptor Vertex;
	typedef typename graph_traits<Graph>::vertex_iterator VertexIterator;
	std::vector<Vertex> verts;
	std::pair<VertexIterator, VertexIterator> rng = vertices(g);
	for( ; rng.first != rng.second; ++rng.first) {
	verts.push_back(*rng.first);
	}

	// Test connection and edge list
	connect_graph(g, verts, is_labeled);
	// connect_property_graph(g, verts, is_labeld);
	test_edge_list_graph(g);

	// Test properties
	test_properties(g, verts);

	// Test directionality.
	test_outdirected_graph(g, verts, is_directed);
	test_indirected_graph(g, verts, is_bidirectional);
	test_undirected_graph(g, verts, is_undirected);

	// Test disconnection
	disconnect_graph(g, verts, is_labeled);
	destroy_graph(g, verts, can_remove_vertex, is_labeled);
	}


	#endif