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

 //=======================================================================
 // Copyright 2001 Jeremy G. Siek, Andrew Lumsdaine, Lie-Quan Lee,
 //
 // 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 <stdlib.h>
 #include <iostream>
 #include <stack>
 #include <queue>
 #include <boost/operators.hpp>
 #include <boost/graph/breadth_first_search.hpp>
 #include <boost/graph/visitors.hpp>
 #include <boost/property_map/property_map.hpp>

 using namespace boost;

 typedef
 std::pair < int, int >
   Position;
 Position
   knight_jumps[8] = {
     Position(2, -1),
     Position(1, -2),
   Position(-1, -2),
     Position(-2, -1),
     Position(-2, 1),
   Position(-1, 2),
     Position(1, 2),
   Position(2, 1)
 };


 Position
 operator + (const Position & p1, const Position & p2)
 {
   return Position(p1.first + p2.first, p1.second + p2.second);
 }

 struct knights_tour_graph;
 struct knight_adjacency_iterator:
   public
   boost::forward_iterator_helper <
   knight_adjacency_iterator,
   Position,
   std::ptrdiff_t,
   Position *,
   Position >
 {
   knight_adjacency_iterator()
   {
   }
   knight_adjacency_iterator(int ii, Position p, const knights_tour_graph & g)
     :
   m_pos(p),
   m_g(&g),
   m_i(ii)
   {
     valid_position();
   }
   Position operator *() const
   {
     return
       m_pos +
       knight_jumps[m_i];
   }
   void
   operator++ ()
   {
     ++m_i;
     valid_position();
   }
   bool
     operator == (const knight_adjacency_iterator & x) const {
       return
       m_i ==
       x.
       m_i;
   }
 protected:
   void
   valid_position();
   Position
     m_pos;
   const knights_tour_graph *
     m_g;
   int
     m_i;
 };

 struct knights_tour_graph
 {
   typedef Position
     vertex_descriptor;
   typedef
     std::pair <
     vertex_descriptor,
     vertex_descriptor >
     edge_descriptor;
   typedef knight_adjacency_iterator
     adjacency_iterator;
   typedef void
     out_edge_iterator;
   typedef void
     in_edge_iterator;
   typedef void
     edge_iterator;
   typedef void
     vertex_iterator;
   typedef int
     degree_size_type;
   typedef int
     vertices_size_type;
   typedef int
     edges_size_type;
   typedef directed_tag
     directed_category;
   typedef disallow_parallel_edge_tag
     edge_parallel_category;
   typedef adjacency_graph_tag
     traversal_category;
   knights_tour_graph(int n):
   m_board_size(n)
   {
   }
   int
     m_board_size;
 };
 int
 num_vertices(const knights_tour_graph & g)
 {
   return g.m_board_size * g.m_board_size;
 }

 void
 knight_adjacency_iterator::valid_position()
 {
   Position new_pos = m_pos + knight_jumps[m_i];
   while (m_i < 8 && (new_pos.first < 0 || new_pos.second < 0
                      || new_pos.first >= m_g->m_board_size
                      || new_pos.second >= m_g->m_board_size)) {
     ++m_i;
     new_pos = m_pos + knight_jumps[m_i];
   }
 }


 std::pair < knights_tour_graph::adjacency_iterator,
   knights_tour_graph::adjacency_iterator >
 adjacent_vertices(knights_tour_graph::vertex_descriptor v,
                   const knights_tour_graph & g)
 {
   typedef knights_tour_graph::adjacency_iterator Iter;
   return std::make_pair(Iter(0, v, g), Iter(8, v, g));
 }


 struct compare_first
 {
   template < typename P > bool operator() (const P & x, const P & y)
   {
     return x.first < y.first;
   }
 };

 template < typename Graph, typename TimePropertyMap >
   bool backtracking_search(Graph & g,
                            typename graph_traits <
                            Graph >::vertex_descriptor src,
                            TimePropertyMap time_map)
 {
   typedef typename graph_traits < Graph >::vertex_descriptor Vertex;
   typedef std::pair < int, Vertex > P;
   std::stack < P > S;
   int time_stamp = 0;

   S.push(std::make_pair(time_stamp, src));
   while (!S.empty()) {
     Vertex x;
     boost::tie(time_stamp, x) = S.top();
     put(time_map, x, time_stamp);
     // all vertices have been visited, success!
     if (time_stamp == num_vertices(g) - 1)
       return true;

     bool deadend = true;
     typename graph_traits < Graph >::adjacency_iterator i, end;
     for (boost::tie(i, end) = adjacent_vertices(x, g); i != end; ++i)
       if (get(time_map, *i) == -1) {
         S.push(std::make_pair(time_stamp + 1, *i));
         deadend = false;
       }

     if (deadend) {
       put(time_map, x, -1);
       S.pop();
       boost::tie(time_stamp, x) = S.top();
       while (get(time_map, x) != -1) {  // unwind stack to last unexplored vertex
         put(time_map, x, -1);
         S.pop();
         boost::tie(time_stamp, x) = S.top();
       }
     }

   }                             // while (!S.empty())
   return false;
 }

 template < typename Vertex, typename Graph, typename TimePropertyMap > int
 number_of_successors(Vertex x, Graph & g, TimePropertyMap time_map)
 {
   int s_x = 0;
   typename graph_traits < Graph >::adjacency_iterator i, end;
   for (boost::tie(i, end) = adjacent_vertices(x, g); i != end; ++i)
     if (get(time_map, *i) == -1)
       ++s_x;
   return s_x;
 }

 template < typename Graph, typename TimePropertyMap >
   bool warnsdorff(Graph & g,
                   typename graph_traits < Graph >::vertex_descriptor src,
                   TimePropertyMap time_map)
 {
   typedef typename graph_traits < Graph >::vertex_descriptor Vertex;
   typedef std::pair < int, Vertex > P;
   std::stack < P > S;
   int time_stamp = 0;

   S.push(std::make_pair(time_stamp, src));
   while (!S.empty()) {
     Vertex x;
     boost::tie(time_stamp, x) = S.top();
     put(time_map, x, time_stamp);
     // all vertices have been visited, success!
     if (time_stamp == num_vertices(g) - 1)
       return true;

     // Put adjacent vertices into a local priority queue
     std::priority_queue < P, std::vector < P >, compare_first > Q;
     typename graph_traits < Graph >::adjacency_iterator i, end;
     int num_succ;
     for (boost::tie(i, end) = adjacent_vertices(x, g); i != end; ++i)
       if (get(time_map, *i) == -1) {
         num_succ = number_of_successors(*i, g, time_map);
         Q.push(std::make_pair(num_succ, *i));
       }
     bool deadend = Q.empty();
     // move vertices from local priority queue to the stack
     for (; !Q.empty(); Q.pop()) {
       boost::tie(num_succ, x) = Q.top();
       S.push(std::make_pair(time_stamp + 1, x));
     }
     if (deadend) {
       put(time_map, x, -1);
       S.pop();
       boost::tie(time_stamp, x) = S.top();
       while (get(time_map, x) != -1) {  // unwind stack to last unexplored vertex
         put(time_map, x, -1);
         S.pop();
         boost::tie(time_stamp, x) = S.top();
       }
     }

   }                             // while (!S.empty())
   return false;
 }


 struct board_map
 {
   typedef int value_type;
   typedef Position key_type;
   typedef read_write_property_map_tag category;
     board_map(int *b, int n):m_board(b), m_size(n)
   {
   }
   friend int get(const board_map & ba, Position p);
   friend void put(const board_map & ba, Position p, int v);
   friend std::ostream & operator << (std::ostream & os, const board_map & ba);
 private:
   int *m_board;
   int m_size;
 };

 int
 get(const board_map & ba, Position p)
 {
   return ba.m_board[p.first * ba.m_size + p.second];
 }

 void
 put(const board_map & ba, Position p, int v)
 {
   ba.m_board[p.first * ba.m_size + p.second] = v;
 }

 std::ostream & operator << (std::ostream & os, const board_map & ba) {
   for (int i = 0; i < ba.m_size; ++i) {
     for (int j = 0; j < ba.m_size; ++j)
       os << get(ba, Position(i, j)) << "\t";
     os << std::endl;
   }
   return os;
 }

 int
 main(int argc, char *argv[])
 {
   int
     N;
   if (argc == 2)
     N = atoi(argv[1]);
   else
     N = 8;

   knights_tour_graph
   g(N);
   int *
     board =
     new int[num_vertices(g)];
   board_map
   chessboard(board, N);
   for (int i = 0; i < N; ++i)
     for (int j = 0; j < N; ++j)
       put(chessboard, Position(i, j), -1);

   bool
     ret =
     warnsdorff(g, Position(0, 0), chessboard);

   if (ret)
     for (int i = 0; i < N; ++i) {
       for (int j = 0; j < N; ++j)
         std::cout << get(chessboard, Position(i, j)) << "\t";
       std::cout << std::endl;
   } else
     std::cout << "method failed" << std::endl;
   return 0;
 }
	//=======================================================================
	// Copyright 2001 Jeremy G. Siek, Andrew Lumsdaine, Lie-Quan Lee,
	//
	// 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 <stdlib.h>
	#include <iostream>
	#include <stack>
	#include <queue>
	#include <boost/operators.hpp>
	#include <boost/graph/breadth_first_search.hpp>
	#include <boost/graph/visitors.hpp>
	#include <boost/property_map/property_map.hpp>

	using namespace boost;

	typedef
	std::pair < int, int >
	Position;
	Position
	knight_jumps[8] = {
	Position(2, -1),
	Position(1, -2),
	Position(-1, -2),
	Position(-2, -1),
	Position(-2, 1),
	Position(-1, 2),
	Position(1, 2),
	Position(2, 1)
	};


	Position
	operator + (const Position & p1, const Position & p2)
	{
	return Position(p1.first + p2.first, p1.second + p2.second);
	}

	struct knights_tour_graph;
	struct knight_adjacency_iterator:
	public
	boost::forward_iterator_helper <
	knight_adjacency_iterator,
	Position,
	std::ptrdiff_t,
	Position *,
	Position >
	{
	knight_adjacency_iterator()
	{
	}
	knight_adjacency_iterator(int ii, Position p, const knights_tour_graph & g)
	:
	m_pos(p),
	m_g(&g),
	m_i(ii)
	{
	valid_position();
	}
	Position operator *() const
	{
	return
	m_pos +
	knight_jumps[m_i];
	}
	void
	operator++ ()
	{
	++m_i;
	valid_position();
	}
	bool
	operator == (const knight_adjacency_iterator & x) const {
	return
	m_i ==
	x.
	m_i;
	}
	protected:
	void
	valid_position();
	Position
	m_pos;
	const knights_tour_graph *
	m_g;
	int
	m_i;
	};

	struct knights_tour_graph
	{
	typedef Position
	vertex_descriptor;
	typedef
	std::pair <
	vertex_descriptor,
	vertex_descriptor >
	edge_descriptor;
	typedef knight_adjacency_iterator
	adjacency_iterator;
	typedef void
	out_edge_iterator;
	typedef void
	in_edge_iterator;
	typedef void
	edge_iterator;
	typedef void
	vertex_iterator;
	typedef int
	degree_size_type;
	typedef int
	vertices_size_type;
	typedef int
	edges_size_type;
	typedef directed_tag
	directed_category;
	typedef disallow_parallel_edge_tag
	edge_parallel_category;
	typedef adjacency_graph_tag
	traversal_category;
	knights_tour_graph(int n):
	m_board_size(n)
	{
	}
	int
	m_board_size;
	};
	int
	num_vertices(const knights_tour_graph & g)
	{
	return g.m_board_size * g.m_board_size;
	}

	void
	knight_adjacency_iterator::valid_position()
	{
	Position new_pos = m_pos + knight_jumps[m_i];
	while (m_i < 8 && (new_pos.first < 0 \|\| new_pos.second < 0
	\|\| new_pos.first >= m_g->m_board_size
	\|\| new_pos.second >= m_g->m_board_size)) {
	++m_i;
	new_pos = m_pos + knight_jumps[m_i];
	}
	}


	std::pair < knights_tour_graph::adjacency_iterator,
	knights_tour_graph::adjacency_iterator >
	adjacent_vertices(knights_tour_graph::vertex_descriptor v,
	const knights_tour_graph & g)
	{
	typedef knights_tour_graph::adjacency_iterator Iter;
	return std::make_pair(Iter(0, v, g), Iter(8, v, g));
	}


	struct compare_first
	{
	template < typename P > bool operator() (const P & x, const P & y)
	{
	return x.first < y.first;
	}
	};

	template < typename Graph, typename TimePropertyMap >
	bool backtracking_search(Graph & g,
	typename graph_traits <
	Graph >::vertex_descriptor src,
	TimePropertyMap time_map)
	{
	typedef typename graph_traits < Graph >::vertex_descriptor Vertex;
	typedef std::pair < int, Vertex > P;
	std::stack < P > S;
	int time_stamp = 0;

	S.push(std::make_pair(time_stamp, src));
	while (!S.empty()) {
	Vertex x;
	boost::tie(time_stamp, x) = S.top();
	put(time_map, x, time_stamp);
	// all vertices have been visited, success!
	if (time_stamp == num_vertices(g) - 1)
	return true;

	bool deadend = true;
	typename graph_traits < Graph >::adjacency_iterator i, end;
	for (boost::tie(i, end) = adjacent_vertices(x, g); i != end; ++i)
	if (get(time_map, *i) == -1) {
	S.push(std::make_pair(time_stamp + 1, *i));
	deadend = false;
	}

	if (deadend) {
	put(time_map, x, -1);
	S.pop();
	boost::tie(time_stamp, x) = S.top();
	while (get(time_map, x) != -1) { // unwind stack to last unexplored vertex
	put(time_map, x, -1);
	S.pop();
	boost::tie(time_stamp, x) = S.top();
	}
	}

	} // while (!S.empty())
	return false;
	}

	template < typename Vertex, typename Graph, typename TimePropertyMap > int
	number_of_successors(Vertex x, Graph & g, TimePropertyMap time_map)
	{
	int s_x = 0;
	typename graph_traits < Graph >::adjacency_iterator i, end;
	for (boost::tie(i, end) = adjacent_vertices(x, g); i != end; ++i)
	if (get(time_map, *i) == -1)
	++s_x;
	return s_x;
	}

	template < typename Graph, typename TimePropertyMap >
	bool warnsdorff(Graph & g,
	typename graph_traits < Graph >::vertex_descriptor src,
	TimePropertyMap time_map)
	{
	typedef typename graph_traits < Graph >::vertex_descriptor Vertex;
	typedef std::pair < int, Vertex > P;
	std::stack < P > S;
	int time_stamp = 0;

	S.push(std::make_pair(time_stamp, src));
	while (!S.empty()) {
	Vertex x;
	boost::tie(time_stamp, x) = S.top();
	put(time_map, x, time_stamp);
	// all vertices have been visited, success!
	if (time_stamp == num_vertices(g) - 1)
	return true;

	// Put adjacent vertices into a local priority queue
	std::priority_queue < P, std::vector < P >, compare_first > Q;
	typename graph_traits < Graph >::adjacency_iterator i, end;
	int num_succ;
	for (boost::tie(i, end) = adjacent_vertices(x, g); i != end; ++i)
	if (get(time_map, *i) == -1) {
	num_succ = number_of_successors(*i, g, time_map);
	Q.push(std::make_pair(num_succ, *i));
	}
	bool deadend = Q.empty();
	// move vertices from local priority queue to the stack
	for (; !Q.empty(); Q.pop()) {
	boost::tie(num_succ, x) = Q.top();
	S.push(std::make_pair(time_stamp + 1, x));
	}
	if (deadend) {
	put(time_map, x, -1);
	S.pop();
	boost::tie(time_stamp, x) = S.top();
	while (get(time_map, x) != -1) { // unwind stack to last unexplored vertex
	put(time_map, x, -1);
	S.pop();
	boost::tie(time_stamp, x) = S.top();
	}
	}

	} // while (!S.empty())
	return false;
	}


	struct board_map
	{
	typedef int value_type;
	typedef Position key_type;
	typedef read_write_property_map_tag category;
	board_map(int *b, int n):m_board(b), m_size(n)
	{
	}
	friend int get(const board_map & ba, Position p);
	friend void put(const board_map & ba, Position p, int v);
	friend std::ostream & operator << (std::ostream & os, const board_map & ba);
	private:
	int *m_board;
	int m_size;
	};

	int
	get(const board_map & ba, Position p)
	{
	return ba.m_board[p.first * ba.m_size + p.second];
	}

	void
	put(const board_map & ba, Position p, int v)
	{
	ba.m_board[p.first * ba.m_size + p.second] = v;
	}

	std::ostream & operator << (std::ostream & os, const board_map & ba) {
	for (int i = 0; i < ba.m_size; ++i) {
	for (int j = 0; j < ba.m_size; ++j)
	os << get(ba, Position(i, j)) << "\t";
	os << std::endl;
	}
	return os;
	}

	int
	main(int argc, char *argv[])
	{
	int
	N;
	if (argc == 2)
	N = atoi(argv[1]);
	else
	N = 8;

	knights_tour_graph
	g(N);
	int *
	board =
	new int[num_vertices(g)];
	board_map
	chessboard(board, N);
	for (int i = 0; i < N; ++i)
	for (int j = 0; j < N; ++j)
	put(chessboard, Position(i, j), -1);

	bool
	ret =
	warnsdorff(g, Position(0, 0), chessboard);

	if (ret)
	for (int i = 0; i < N; ++i) {
	for (int j = 0; j < N; ++j)
	std::cout << get(chessboard, Position(i, j)) << "\t";
	std::cout << std::endl;
	} else
	std::cout << "method failed" << std::endl;
	return 0;
	}