boost_1_45_0/libs/graph/example/dave.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 //=======================================================================
 // Copyright 1997, 1998, 1999, 2000 University of Notre Dame.
 // Authors: Andrew Lumsdaine, Lie-Quan Lee, Jeremy G. Siek
 //
 // 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/config.hpp>
 #include <iostream>
 #include <iterator>
 #include <vector>
 #include <list>
 // Use boost::queue instead of std::queue because std::queue doesn't
 // model Buffer; it has to top() function. -Jeremy
 #include <boost/pending/queue.hpp>

 #include <boost/graph/adjacency_list.hpp>
 #include <boost/graph/visitors.hpp>
 #include <boost/graph/breadth_first_search.hpp>
 #include <boost/graph/dijkstra_shortest_paths.hpp>
 #include <boost/graph/graph_utility.hpp>

 using namespace std;
 using namespace boost;
 /*
   This example does a best-first-search (using dijkstra's) and
   simultaneously makes a copy of the graph (assuming the graph is
   connected).

   Example Graph: (p. 90 "Data Structures and Network Algorithms", Tarjan)

               g
             3+ +2
             / 1 \
            e+----f
            |+0 5++
            | \ / |
          10|  d  |12
            |8++\7|
            +/ | +|
            b 4|  c
             \ | +
             6+|/3
               a

   Sample Output:
 a --> c d
 b --> a d
 c --> f
 d --> c e f
 e --> b g
 f --> e g
 g -->
 Starting graph:
 a(32767); c d
 c(32767); f
 d(32767); c e f
 f(32767); e g
 e(32767); b g
 g(32767);
 b(32767); a d
 Result:
 a(0); d c
 d(4); f e c
 c(3); f
 f(9); g e
 e(4); g b
 g(7);
 b(14); d a

 */

 typedef property<vertex_color_t, default_color_type,
          property<vertex_distance_t,int> > VProperty;
 typedef int weight_t;
 typedef property<edge_weight_t,weight_t> EProperty;

 typedef adjacency_list<vecS, vecS, directedS, VProperty, EProperty > Graph;


 template <class Tag>
 struct endl_printer
   : public boost::base_visitor< endl_printer<Tag> >
 {
   typedef Tag event_filter;
   endl_printer(std::ostream& os) : m_os(os) { }
   template <class T, class Graph>
   void operator()(T, Graph&) { m_os << std::endl; }
   std::ostream& m_os;
 };
 template <class Tag>
 endl_printer<Tag> print_endl(std::ostream& os, Tag) {
   return endl_printer<Tag>(os);
 }

 template <class PA, class Tag>
 struct edge_printer
  : public boost::base_visitor< edge_printer<PA, Tag> >
 {
   typedef Tag event_filter;

   edge_printer(PA pa, std::ostream& os) : m_pa(pa), m_os(os) { }

   template <class T, class Graph>
   void operator()(T x, Graph& g) {
     m_os << "(" << get(m_pa, source(x, g)) << ","
          << get(m_pa, target(x, g)) << ") ";
   }
   PA m_pa;
   std::ostream& m_os;
 };
 template <class PA, class Tag>
 edge_printer<PA, Tag>
 print_edge(PA pa, std::ostream& os, Tag) {
   return edge_printer<PA, Tag>(pa, os);
 }


 template <class NewGraph, class Tag>
 struct graph_copier
   : public boost::base_visitor<graph_copier<NewGraph, Tag> >
 {
   typedef Tag event_filter;

   graph_copier(NewGraph& graph) : new_g(graph) { }

   template <class Edge, class Graph>
   void operator()(Edge e, Graph& g) {
     add_edge(source(e, g), target(e, g), new_g);
   }
 private:
   NewGraph& new_g;
 };
 template <class NewGraph, class Tag>
 inline graph_copier<NewGraph, Tag>
 copy_graph(NewGraph& g, Tag) {
   return graph_copier<NewGraph, Tag>(g);
 }

 template <class Graph, class Name>
 void print(Graph& G, Name name)
 {
   typename boost::graph_traits<Graph>::vertex_iterator ui, uiend;
   for (boost::tie(ui, uiend) = vertices(G); ui != uiend; ++ui) {
     cout << name[*ui] << " --> ";
     typename boost::graph_traits<Graph>::adjacency_iterator vi, viend;
     for(boost::tie(vi, viend) = adjacent_vertices(*ui, G); vi != viend; ++vi)
       cout << name[*vi] << " ";
     cout << endl;
   }

 }


 int
 main(int , char* [])
 {
   // Name and ID numbers for the vertices
   char name[] = "abcdefg";
   enum { a, b, c, d, e, f, g, N};

   Graph G(N);
   boost::property_map<Graph, vertex_index_t>::type
     vertex_id = get(vertex_index, G);

   std::vector<weight_t> distance(N, (numeric_limits<weight_t>::max)());
   typedef boost::graph_traits<Graph>::vertex_descriptor Vertex;
   std::vector<Vertex> parent(N);

   typedef std::pair<int,int> E;

   E edges[] = { E(a,c), E(a,d),
                 E(b,a), E(b,d),
                 E(c,f),
                 E(d,c), E(d,e), E(d,f),
                 E(e,b), E(e,g),
                 E(f,e), E(f,g) };

   int weight[] = { 3, 4,
                    6, 8,
                    12,
                    7, 0, 5,
                    10, 3,
                    1, 2 };

   for (int i = 0; i < 12; ++i)
     add_edge(edges[i].first, edges[i].second, weight[i], G);

   print(G, name);

   adjacency_list<listS, vecS, directedS,
     property<vertex_color_t, default_color_type> > G_copy(N);

   cout << "Starting graph:" << endl;

   std::ostream_iterator<int> cout_int(std::cout, " ");
   std::ostream_iterator<char> cout_char(std::cout, " ");

   boost::queue<Vertex> Q;
   boost::breadth_first_search
     (G, vertex(a, G), Q,
      make_bfs_visitor(
      boost::make_list
       (write_property(make_iterator_property_map(name, vertex_id,
                                                 name[0]),
                       cout_char, on_examine_vertex()),
        write_property(make_iterator_property_map(distance.begin(),
                                                 vertex_id,
                                                 distance[0]),
                       cout_int, on_examine_vertex()),
        print_edge(make_iterator_property_map(name, vertex_id,
                                             name[0]),
                   std::cout, on_examine_edge()),
        print_endl(std::cout, on_finish_vertex()))),
      get(vertex_color, G));

   std::cout << "about to call dijkstra's" << std::endl;

   parent[vertex(a, G)] = vertex(a, G);
   boost::dijkstra_shortest_paths
     (G, vertex(a, G),
      distance_map(make_iterator_property_map(distance.begin(), vertex_id,
                                              distance[0])).
      predecessor_map(make_iterator_property_map(parent.begin(), vertex_id,
                                                 parent[0])).
      visitor(make_dijkstra_visitor(copy_graph(G_copy, on_examine_edge()))));

   cout << endl;
   cout << "Result:" << endl;
   boost::breadth_first_search
     (G, vertex(a, G),
      visitor(make_bfs_visitor(
      boost::make_list
      (write_property(make_iterator_property_map(name, vertex_id,
                                                 name[0]),
                      cout_char, on_examine_vertex()),
       write_property(make_iterator_property_map(distance.begin(),
                                                 vertex_id,
                                                 distance[0]),
                      cout_int, on_examine_vertex()),
       print_edge(make_iterator_property_map(name, vertex_id,
                                             name[0]),
                  std::cout, on_examine_edge()),
       print_endl(std::cout, on_finish_vertex())))));

   return 0;
 }
	//=======================================================================
	// Copyright 1997, 1998, 1999, 2000 University of Notre Dame.
	// Authors: Andrew Lumsdaine, Lie-Quan Lee, Jeremy G. Siek
	//
	// 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/config.hpp>
	#include <iostream>
	#include <iterator>
	#include <vector>
	#include <list>
	// Use boost::queue instead of std::queue because std::queue doesn't
	// model Buffer; it has to top() function. -Jeremy
	#include <boost/pending/queue.hpp>

	#include <boost/graph/adjacency_list.hpp>
	#include <boost/graph/visitors.hpp>
	#include <boost/graph/breadth_first_search.hpp>
	#include <boost/graph/dijkstra_shortest_paths.hpp>
	#include <boost/graph/graph_utility.hpp>

	using namespace std;
	using namespace boost;
	/*
	This example does a best-first-search (using dijkstra's) and
	simultaneously makes a copy of the graph (assuming the graph is
	connected).

	Example Graph: (p. 90 "Data Structures and Network Algorithms", Tarjan)

	g
	3+ +2
	/ 1 \
	e+----f
	\|+0 5++
	\| \ / \|
	10\| d \|12
	\|8++\7\|
	+/ \| +\|
	b 4\| c
	\ \| +
	6+\|/3
	a

	Sample Output:
	a --> c d
	b --> a d
	c --> f
	d --> c e f
	e --> b g
	f --> e g
	g -->
	Starting graph:
	a(32767); c d
	c(32767); f
	d(32767); c e f
	f(32767); e g
	e(32767); b g
	g(32767);
	b(32767); a d
	Result:
	a(0); d c
	d(4); f e c
	c(3); f
	f(9); g e
	e(4); g b
	g(7);
	b(14); d a

	*/

	typedef property<vertex_color_t, default_color_type,
	property<vertex_distance_t,int> > VProperty;
	typedef int weight_t;
	typedef property<edge_weight_t,weight_t> EProperty;

	typedef adjacency_list<vecS, vecS, directedS, VProperty, EProperty > Graph;



	template <class Tag>
	struct endl_printer
	: public boost::base_visitor< endl_printer<Tag> >
	{
	typedef Tag event_filter;
	endl_printer(std::ostream& os) : m_os(os) { }
	template <class T, class Graph>
	void operator()(T, Graph&) { m_os << std::endl; }
	std::ostream& m_os;
	};
	template <class Tag>
	endl_printer<Tag> print_endl(std::ostream& os, Tag) {
	return endl_printer<Tag>(os);
	}

	template <class PA, class Tag>
	struct edge_printer
	: public boost::base_visitor< edge_printer<PA, Tag> >
	{
	typedef Tag event_filter;

	edge_printer(PA pa, std::ostream& os) : m_pa(pa), m_os(os) { }

	template <class T, class Graph>
	void operator()(T x, Graph& g) {
	m_os << "(" << get(m_pa, source(x, g)) << ","
	<< get(m_pa, target(x, g)) << ") ";
	}
	PA m_pa;
	std::ostream& m_os;
	};
	template <class PA, class Tag>
	edge_printer<PA, Tag>
	print_edge(PA pa, std::ostream& os, Tag) {
	return edge_printer<PA, Tag>(pa, os);
	}


	template <class NewGraph, class Tag>
	struct graph_copier
	: public boost::base_visitor<graph_copier<NewGraph, Tag> >
	{
	typedef Tag event_filter;

	graph_copier(NewGraph& graph) : new_g(graph) { }

	template <class Edge, class Graph>
	void operator()(Edge e, Graph& g) {
	add_edge(source(e, g), target(e, g), new_g);
	}
	private:
	NewGraph& new_g;
	};
	template <class NewGraph, class Tag>
	inline graph_copier<NewGraph, Tag>
	copy_graph(NewGraph& g, Tag) {
	return graph_copier<NewGraph, Tag>(g);
	}

	template <class Graph, class Name>
	void print(Graph& G, Name name)
	{
	typename boost::graph_traits<Graph>::vertex_iterator ui, uiend;
	for (boost::tie(ui, uiend) = vertices(G); ui != uiend; ++ui) {
	cout << name[*ui] << " --> ";
	typename boost::graph_traits<Graph>::adjacency_iterator vi, viend;
	for(boost::tie(vi, viend) = adjacent_vertices(*ui, G); vi != viend; ++vi)
	cout << name[*vi] << " ";
	cout << endl;
	}

	}


	int
	main(int , char* [])
	{
	// Name and ID numbers for the vertices
	char name[] = "abcdefg";
	enum { a, b, c, d, e, f, g, N};

	Graph G(N);
	boost::property_map<Graph, vertex_index_t>::type
	vertex_id = get(vertex_index, G);

	std::vector<weight_t> distance(N, (numeric_limits<weight_t>::max)());
	typedef boost::graph_traits<Graph>::vertex_descriptor Vertex;
	std::vector<Vertex> parent(N);

	typedef std::pair<int,int> E;

	E edges[] = { E(a,c), E(a,d),
	E(b,a), E(b,d),
	E(c,f),
	E(d,c), E(d,e), E(d,f),
	E(e,b), E(e,g),
	E(f,e), E(f,g) };

	int weight[] = { 3, 4,
	6, 8,
	12,
	7, 0, 5,
	10, 3,
	1, 2 };

	for (int i = 0; i < 12; ++i)
	add_edge(edges[i].first, edges[i].second, weight[i], G);

	print(G, name);

	adjacency_list<listS, vecS, directedS,
	property<vertex_color_t, default_color_type> > G_copy(N);

	cout << "Starting graph:" << endl;

	std::ostream_iterator<int> cout_int(std::cout, " ");
	std::ostream_iterator<char> cout_char(std::cout, " ");

	boost::queue<Vertex> Q;
	boost::breadth_first_search
	(G, vertex(a, G), Q,
	make_bfs_visitor(
	boost::make_list
	(write_property(make_iterator_property_map(name, vertex_id,
	name[0]),
	cout_char, on_examine_vertex()),
	write_property(make_iterator_property_map(distance.begin(),
	vertex_id,
	distance[0]),
	cout_int, on_examine_vertex()),
	print_edge(make_iterator_property_map(name, vertex_id,
	name[0]),
	std::cout, on_examine_edge()),
	print_endl(std::cout, on_finish_vertex()))),
	get(vertex_color, G));

	std::cout << "about to call dijkstra's" << std::endl;

	parent[vertex(a, G)] = vertex(a, G);
	boost::dijkstra_shortest_paths
	(G, vertex(a, G),
	distance_map(make_iterator_property_map(distance.begin(), vertex_id,
	distance[0])).
	predecessor_map(make_iterator_property_map(parent.begin(), vertex_id,
	parent[0])).
	visitor(make_dijkstra_visitor(copy_graph(G_copy, on_examine_edge()))));

	cout << endl;
	cout << "Result:" << endl;
	boost::breadth_first_search
	(G, vertex(a, G),
	visitor(make_bfs_visitor(
	boost::make_list
	(write_property(make_iterator_property_map(name, vertex_id,
	name[0]),
	cout_char, on_examine_vertex()),
	write_property(make_iterator_property_map(distance.begin(),
	vertex_id,
	distance[0]),
	cout_int, on_examine_vertex()),
	print_edge(make_iterator_property_map(name, vertex_id,
	name[0]),
	std::cout, on_examine_edge()),
	print_endl(std::cout, on_finish_vertex())))));

	return 0;
	}