third_party/boost/include/boost/graph/visitors.hpp - webm/webmlive - 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)
 //=======================================================================
 //
 // Revision History:
 //   01 April 2001: Modified to use new <boost/limits.hpp> header. (JMaddock)
 //
 #ifndef BOOST_GRAPH_GRAPH_SEARCH_VISITORS_HPP
 #define BOOST_GRAPH_GRAPH_SEARCH_VISITORS_HPP

 #include <iosfwd>
 #include <boost/config.hpp>
 #include <boost/type_traits/is_same.hpp>
 #include <boost/mpl/bool.hpp>
 #include <boost/property_map/property_map.hpp>
 #include <boost/graph/graph_traits.hpp>
 #include <boost/limits.hpp>

 #if BOOST_WORKAROUND(BOOST_MSVC, < 1300)
 // Stay out of the way of the concept checking class
 # define Graph Graph_
 #endif

 namespace boost {

   // This is a bit more convenient than std::numeric_limits because
   // you don't have to explicitly provide type T.
   template <class T>
   inline T numeric_limits_max(T) { return (std::numeric_limits<T>::max)(); }

   //========================================================================
   // Event Tags

   namespace detail {
     // For partial specialization workaround
     enum event_visitor_enum
     { on_no_event_num,
       on_initialize_vertex_num, on_start_vertex_num,
       on_discover_vertex_num, on_finish_vertex_num, on_examine_vertex_num,
       on_examine_edge_num, on_tree_edge_num, on_non_tree_edge_num,
       on_gray_target_num, on_black_target_num,
       on_forward_or_cross_edge_num, on_back_edge_num,
       on_edge_relaxed_num, on_edge_not_relaxed_num,
       on_edge_minimized_num, on_edge_not_minimized_num
     };

     template<typename Event, typename Visitor>
     struct functor_to_visitor : Visitor
     {
       typedef Event event_filter;
       functor_to_visitor(const Visitor& visitor) : Visitor(visitor) {}
     };

   } // namespace detail

   struct on_no_event { enum { num = detail::on_no_event_num }; };

   struct on_initialize_vertex {
     enum { num = detail::on_initialize_vertex_num }; };
   struct on_start_vertex { enum { num = detail::on_start_vertex_num }; };
   struct on_discover_vertex { enum { num = detail::on_discover_vertex_num }; };
   struct on_examine_vertex { enum { num = detail::on_examine_vertex_num }; };
   struct on_finish_vertex { enum { num = detail::on_finish_vertex_num }; };

   struct on_examine_edge { enum { num = detail::on_examine_edge_num }; };
   struct on_tree_edge { enum { num = detail::on_tree_edge_num }; };
   struct on_non_tree_edge { enum { num = detail::on_non_tree_edge_num }; };
   struct on_gray_target { enum { num = detail::on_gray_target_num }; };
   struct on_black_target { enum { num = detail::on_black_target_num }; };
   struct on_forward_or_cross_edge {
     enum { num = detail::on_forward_or_cross_edge_num }; };
   struct on_back_edge { enum { num = detail::on_back_edge_num }; };

   struct on_edge_relaxed { enum { num = detail::on_edge_relaxed_num }; };
   struct on_edge_not_relaxed {
     enum { num = detail::on_edge_not_relaxed_num }; };
   struct on_edge_minimized { enum { num = detail::on_edge_minimized_num }; };
   struct on_edge_not_minimized {
     enum { num = detail::on_edge_not_minimized_num }; };

   //========================================================================
   // base_visitor and null_visitor

   // needed for MSVC workaround
   template <class Visitor>
   struct base_visitor {
     typedef on_no_event event_filter;
     template <class T, class Graph>
     void operator()(T, Graph&) { }
   };

   struct null_visitor : public base_visitor<null_visitor> {
     typedef on_no_event event_filter;
     template <class T, class Graph>
     void operator()(T, Graph&) { }
   };

   //========================================================================
   // The invoke_visitors() function

   namespace detail {
     template <class Visitor, class T, class Graph>
     inline void invoke_dispatch(Visitor& v, T x, Graph& g, mpl::true_) {
        v(x, g);
     }

     template <class Visitor, class T, class Graph>
     inline void invoke_dispatch(Visitor&, T, Graph&, mpl::false_)
     { }
   } // namespace detail

   template <class Visitor, class Rest, class T, class Graph, class Tag>
   inline void
   invoke_visitors(std::pair<Visitor, Rest>& vlist, T x, Graph& g, Tag tag) {
     typedef typename Visitor::event_filter Category;
     typedef typename is_same<Category, Tag>::type IsSameTag;
     detail::invoke_dispatch(vlist.first, x, g, IsSameTag());
     invoke_visitors(vlist.second, x, g, tag);
   }
 #if defined(BOOST_MSVC) && BOOST_MSVC <= 1300
   template <class Visitor, class T, class Graph, class Tag>
   inline void
   invoke_visitors(base_visitor<Visitor>& vis, T x, Graph& g, Tag) {
     typedef typename Visitor::event_filter Category;
     typedef typename is_same<Category, Tag>::type IsSameTag;
     Visitor& v = static_cast<Visitor&>(vis);
     detail::invoke_dispatch(v, x, g, IsSameTag());
   }
 #else
   template <class Visitor, class T, class Graph, class Tag>
   inline void
   invoke_visitors(Visitor& v, T x, Graph& g, Tag) {
     typedef typename Visitor::event_filter Category;
     typedef typename is_same<Category, Tag>::type IsSameTag;
     detail::invoke_dispatch(v, x, g, IsSameTag());
   }
 #endif

   //========================================================================
   // predecessor_recorder

   template <class PredecessorMap, class Tag>
   struct predecessor_recorder
     : public base_visitor<predecessor_recorder<PredecessorMap, Tag> >
   {
     typedef Tag event_filter;
     predecessor_recorder(PredecessorMap pa) : m_predecessor(pa) { }
     template <class Edge, class Graph>
     void operator()(Edge e, const Graph& g) {
       put(m_predecessor, target(e, g), source(e, g));
     }
     PredecessorMap m_predecessor;
   };
   template <class PredecessorMap, class Tag>
   predecessor_recorder<PredecessorMap, Tag>
   record_predecessors(PredecessorMap pa, Tag) {
     return predecessor_recorder<PredecessorMap, Tag> (pa);
   }

   //========================================================================
   // edge_predecessor_recorder

   template <class PredEdgeMap, class Tag>
   struct edge_predecessor_recorder
     : public base_visitor<edge_predecessor_recorder<PredEdgeMap, Tag> >
   {
     typedef Tag event_filter;
     edge_predecessor_recorder(PredEdgeMap pa) : m_predecessor(pa) { }
     template <class Edge, class Graph>
     void operator()(Edge e, const Graph& g) {
       put(m_predecessor, target(e, g), e);
     }
     PredEdgeMap m_predecessor;
   };
   template <class PredEdgeMap, class Tag>
   edge_predecessor_recorder<PredEdgeMap, Tag>
   record_edge_predecessors(PredEdgeMap pa, Tag) {
     return edge_predecessor_recorder<PredEdgeMap, Tag> (pa);
   }

   //========================================================================
   // distance_recorder

   template <class DistanceMap, class Tag>
   struct distance_recorder
     : public base_visitor<distance_recorder<DistanceMap, Tag> >
   {
     typedef Tag event_filter;
     distance_recorder(DistanceMap pa) : m_distance(pa) { }
     template <class Edge, class Graph>
     void operator()(Edge e, const Graph& g) {
       typename graph_traits<Graph>::vertex_descriptor
         u = source(e, g), v = target(e, g);
       put(m_distance, v, get(m_distance, u) + 1);
     }
     DistanceMap m_distance;
   };
   template <class DistanceMap, class Tag>
   distance_recorder<DistanceMap, Tag>
   record_distances(DistanceMap pa, Tag) {
     return distance_recorder<DistanceMap, Tag> (pa);
   }

   //========================================================================
   // time_stamper


   template <class TimeMap, class TimeT, class Tag>
   struct time_stamper
     : public base_visitor<time_stamper<TimeMap, TimeT, Tag> >
   {
     typedef Tag event_filter;
     time_stamper(TimeMap pa, TimeT& t) : m_time_pa(pa), m_time(t) { }
     template <class Vertex, class Graph>
     void operator()(Vertex u, const Graph&) {
       put(m_time_pa, u, ++m_time);
     }
     TimeMap m_time_pa;
     TimeT& m_time;
   };
   template <class TimeMap, class TimeT, class Tag>
   time_stamper<TimeMap, TimeT, Tag>
   stamp_times(TimeMap pa, TimeT& time_counter, Tag) {
     return time_stamper<TimeMap, TimeT, Tag>(pa, time_counter);
   }

   //========================================================================
   // property_writer

   template <class PA, class OutputIterator, class Tag>
   struct property_writer
     : public base_visitor<property_writer<PA, OutputIterator, Tag> >
   {
     typedef Tag event_filter;

     property_writer(PA pa, OutputIterator out) : m_pa(pa), m_out(out) { }

     template <class T, class Graph>
     void operator()(T x, Graph&) { *m_out++ = get(m_pa, x); }
     PA m_pa;
     OutputIterator m_out;
   };
   template <class PA, class OutputIterator, class Tag>
   property_writer<PA, OutputIterator, Tag>
   write_property(PA pa, OutputIterator out, Tag) {
     return property_writer<PA, OutputIterator, Tag>(pa, out);
   }

   //========================================================================
   // property_put

     /**
      * Functor which just sets a given value to a vertex or edge in a property map.
      */

   template <typename PropertyMap, typename EventTag>
   struct property_put
   {
     typedef EventTag event_filter;

     property_put (PropertyMap property_map,
                   typename property_traits <PropertyMap>::value_type value) :
       property_map_ (property_map), value_ (value)
     {}

     template <typename VertexOrEdge, typename Graph>
     void operator() (VertexOrEdge v, const Graph& g)
     {
       put (property_map_, v, value_);
     }

   private:
     PropertyMap property_map_;
     typename property_traits <PropertyMap>::value_type value_;
   };

   /**
    * Creates a property_put functor which just sets a given value to a vertex or edge.
    *
    * @param property_map Given writeable property map
    * @param value Fixed value of the map
    * @param tag Event Filter
    * @return The functor.
    */

     template <typename PropertyMap, typename EventTag>
     inline property_put <PropertyMap, EventTag>
     put_property (PropertyMap property_map,
                   typename property_traits <PropertyMap>::value_type value,
                   EventTag tag)
     {
       return property_put <PropertyMap, EventTag> (property_map, value);
     }

 #define BOOST_GRAPH_EVENT_STUB(Event,Kind)                                 \
     typedef ::boost::Event Event##_type;                                   \
     template<typename Visitor>                                             \
     Kind##_visitor<std::pair<detail::functor_to_visitor<Event##_type,      \
                                                      Visitor>, Visitors> > \
     do_##Event(Visitor visitor)                                            \
     {                                                                      \
       typedef std::pair<detail::functor_to_visitor<Event##_type, Visitor>, \
                         Visitors> visitor_list;                            \
       typedef Kind##_visitor<visitor_list> result_type;                    \
       return result_type(visitor_list(visitor, m_vis));                    \
     }

 } /* namespace boost */

 #if BOOST_WORKAROUND(BOOST_MSVC, < 1300)
 // Stay out of the way of the concept checking class
 # undef Graph
 #endif

 #endif
	//=======================================================================
	// 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)
	//=======================================================================
	//
	// Revision History:
	// 01 April 2001: Modified to use new <boost/limits.hpp> header. (JMaddock)
	//
	#ifndef BOOST_GRAPH_GRAPH_SEARCH_VISITORS_HPP
	#define BOOST_GRAPH_GRAPH_SEARCH_VISITORS_HPP

	#include <iosfwd>
	#include <boost/config.hpp>
	#include <boost/type_traits/is_same.hpp>
	#include <boost/mpl/bool.hpp>
	#include <boost/property_map/property_map.hpp>
	#include <boost/graph/graph_traits.hpp>
	#include <boost/limits.hpp>

	#if BOOST_WORKAROUND(BOOST_MSVC, < 1300)
	// Stay out of the way of the concept checking class
	# define Graph Graph_
	#endif

	namespace boost {

	// This is a bit more convenient than std::numeric_limits because
	// you don't have to explicitly provide type T.
	template <class T>
	inline T numeric_limits_max(T) { return (std::numeric_limits<T>::max)(); }

	//========================================================================
	// Event Tags

	namespace detail {
	// For partial specialization workaround
	enum event_visitor_enum
	{ on_no_event_num,
	on_initialize_vertex_num, on_start_vertex_num,
	on_discover_vertex_num, on_finish_vertex_num, on_examine_vertex_num,
	on_examine_edge_num, on_tree_edge_num, on_non_tree_edge_num,
	on_gray_target_num, on_black_target_num,
	on_forward_or_cross_edge_num, on_back_edge_num,
	on_edge_relaxed_num, on_edge_not_relaxed_num,
	on_edge_minimized_num, on_edge_not_minimized_num
	};

	template<typename Event, typename Visitor>
	struct functor_to_visitor : Visitor
	{
	typedef Event event_filter;
	functor_to_visitor(const Visitor& visitor) : Visitor(visitor) {}
	};

	} // namespace detail

	struct on_no_event { enum { num = detail::on_no_event_num }; };

	struct on_initialize_vertex {
	enum { num = detail::on_initialize_vertex_num }; };
	struct on_start_vertex { enum { num = detail::on_start_vertex_num }; };
	struct on_discover_vertex { enum { num = detail::on_discover_vertex_num }; };
	struct on_examine_vertex { enum { num = detail::on_examine_vertex_num }; };
	struct on_finish_vertex { enum { num = detail::on_finish_vertex_num }; };

	struct on_examine_edge { enum { num = detail::on_examine_edge_num }; };
	struct on_tree_edge { enum { num = detail::on_tree_edge_num }; };
	struct on_non_tree_edge { enum { num = detail::on_non_tree_edge_num }; };
	struct on_gray_target { enum { num = detail::on_gray_target_num }; };
	struct on_black_target { enum { num = detail::on_black_target_num }; };
	struct on_forward_or_cross_edge {
	enum { num = detail::on_forward_or_cross_edge_num }; };
	struct on_back_edge { enum { num = detail::on_back_edge_num }; };

	struct on_edge_relaxed { enum { num = detail::on_edge_relaxed_num }; };
	struct on_edge_not_relaxed {
	enum { num = detail::on_edge_not_relaxed_num }; };
	struct on_edge_minimized { enum { num = detail::on_edge_minimized_num }; };
	struct on_edge_not_minimized {
	enum { num = detail::on_edge_not_minimized_num }; };

	//========================================================================
	// base_visitor and null_visitor

	// needed for MSVC workaround
	template <class Visitor>
	struct base_visitor {
	typedef on_no_event event_filter;
	template <class T, class Graph>
	void operator()(T, Graph&) { }
	};

	struct null_visitor : public base_visitor<null_visitor> {
	typedef on_no_event event_filter;
	template <class T, class Graph>
	void operator()(T, Graph&) { }
	};

	//========================================================================
	// The invoke_visitors() function

	namespace detail {
	template <class Visitor, class T, class Graph>
	inline void invoke_dispatch(Visitor& v, T x, Graph& g, mpl::true_) {
	v(x, g);
	}

	template <class Visitor, class T, class Graph>
	inline void invoke_dispatch(Visitor&, T, Graph&, mpl::false_)
	{ }
	} // namespace detail

	template <class Visitor, class Rest, class T, class Graph, class Tag>
	inline void
	invoke_visitors(std::pair<Visitor, Rest>& vlist, T x, Graph& g, Tag tag) {
	typedef typename Visitor::event_filter Category;
	typedef typename is_same<Category, Tag>::type IsSameTag;
	detail::invoke_dispatch(vlist.first, x, g, IsSameTag());
	invoke_visitors(vlist.second, x, g, tag);
	}
	#if defined(BOOST_MSVC) && BOOST_MSVC <= 1300
	template <class Visitor, class T, class Graph, class Tag>
	inline void
	invoke_visitors(base_visitor<Visitor>& vis, T x, Graph& g, Tag) {
	typedef typename Visitor::event_filter Category;
	typedef typename is_same<Category, Tag>::type IsSameTag;
	Visitor& v = static_cast<Visitor&>(vis);
	detail::invoke_dispatch(v, x, g, IsSameTag());
	}
	#else
	template <class Visitor, class T, class Graph, class Tag>
	inline void
	invoke_visitors(Visitor& v, T x, Graph& g, Tag) {
	typedef typename Visitor::event_filter Category;
	typedef typename is_same<Category, Tag>::type IsSameTag;
	detail::invoke_dispatch(v, x, g, IsSameTag());
	}
	#endif

	//========================================================================
	// predecessor_recorder

	template <class PredecessorMap, class Tag>
	struct predecessor_recorder
	: public base_visitor<predecessor_recorder<PredecessorMap, Tag> >
	{
	typedef Tag event_filter;
	predecessor_recorder(PredecessorMap pa) : m_predecessor(pa) { }
	template <class Edge, class Graph>
	void operator()(Edge e, const Graph& g) {
	put(m_predecessor, target(e, g), source(e, g));
	}
	PredecessorMap m_predecessor;
	};
	template <class PredecessorMap, class Tag>
	predecessor_recorder<PredecessorMap, Tag>
	record_predecessors(PredecessorMap pa, Tag) {
	return predecessor_recorder<PredecessorMap, Tag> (pa);
	}

	//========================================================================
	// edge_predecessor_recorder

	template <class PredEdgeMap, class Tag>
	struct edge_predecessor_recorder
	: public base_visitor<edge_predecessor_recorder<PredEdgeMap, Tag> >
	{
	typedef Tag event_filter;
	edge_predecessor_recorder(PredEdgeMap pa) : m_predecessor(pa) { }
	template <class Edge, class Graph>
	void operator()(Edge e, const Graph& g) {
	put(m_predecessor, target(e, g), e);
	}
	PredEdgeMap m_predecessor;
	};
	template <class PredEdgeMap, class Tag>
	edge_predecessor_recorder<PredEdgeMap, Tag>
	record_edge_predecessors(PredEdgeMap pa, Tag) {
	return edge_predecessor_recorder<PredEdgeMap, Tag> (pa);
	}

	//========================================================================
	// distance_recorder

	template <class DistanceMap, class Tag>
	struct distance_recorder
	: public base_visitor<distance_recorder<DistanceMap, Tag> >
	{
	typedef Tag event_filter;
	distance_recorder(DistanceMap pa) : m_distance(pa) { }
	template <class Edge, class Graph>
	void operator()(Edge e, const Graph& g) {
	typename graph_traits<Graph>::vertex_descriptor
	u = source(e, g), v = target(e, g);
	put(m_distance, v, get(m_distance, u) + 1);
	}
	DistanceMap m_distance;
	};
	template <class DistanceMap, class Tag>
	distance_recorder<DistanceMap, Tag>
	record_distances(DistanceMap pa, Tag) {
	return distance_recorder<DistanceMap, Tag> (pa);
	}

	//========================================================================
	// time_stamper


	template <class TimeMap, class TimeT, class Tag>
	struct time_stamper
	: public base_visitor<time_stamper<TimeMap, TimeT, Tag> >
	{
	typedef Tag event_filter;
	time_stamper(TimeMap pa, TimeT& t) : m_time_pa(pa), m_time(t) { }
	template <class Vertex, class Graph>
	void operator()(Vertex u, const Graph&) {
	put(m_time_pa, u, ++m_time);
	}
	TimeMap m_time_pa;
	TimeT& m_time;
	};
	template <class TimeMap, class TimeT, class Tag>
	time_stamper<TimeMap, TimeT, Tag>
	stamp_times(TimeMap pa, TimeT& time_counter, Tag) {
	return time_stamper<TimeMap, TimeT, Tag>(pa, time_counter);
	}

	//========================================================================
	// property_writer

	template <class PA, class OutputIterator, class Tag>
	struct property_writer
	: public base_visitor<property_writer<PA, OutputIterator, Tag> >
	{
	typedef Tag event_filter;

	property_writer(PA pa, OutputIterator out) : m_pa(pa), m_out(out) { }

	template <class T, class Graph>
	void operator()(T x, Graph&) { *m_out++ = get(m_pa, x); }
	PA m_pa;
	OutputIterator m_out;
	};
	template <class PA, class OutputIterator, class Tag>
	property_writer<PA, OutputIterator, Tag>
	write_property(PA pa, OutputIterator out, Tag) {
	return property_writer<PA, OutputIterator, Tag>(pa, out);
	}

	//========================================================================
	// property_put

	/**
	* Functor which just sets a given value to a vertex or edge in a property map.
	*/

	template <typename PropertyMap, typename EventTag>
	struct property_put
	{
	typedef EventTag event_filter;

	property_put (PropertyMap property_map,
	typename property_traits <PropertyMap>::value_type value) :
	property_map_ (property_map), value_ (value)
	{}

	template <typename VertexOrEdge, typename Graph>
	void operator() (VertexOrEdge v, const Graph& g)
	{
	put (property_map_, v, value_);
	}

	private:
	PropertyMap property_map_;
	typename property_traits <PropertyMap>::value_type value_;
	};

	/**
	* Creates a property_put functor which just sets a given value to a vertex or edge.
	*
	* @param property_map Given writeable property map
	* @param value Fixed value of the map
	* @param tag Event Filter
	* @return The functor.
	*/

	template <typename PropertyMap, typename EventTag>
	inline property_put <PropertyMap, EventTag>
	put_property (PropertyMap property_map,
	typename property_traits <PropertyMap>::value_type value,
	EventTag tag)
	{
	return property_put <PropertyMap, EventTag> (property_map, value);
	}

	#define BOOST_GRAPH_EVENT_STUB(Event,Kind) \
	typedef ::boost::Event Event##_type; \
	template<typename Visitor> \
	Kind##_visitor<std::pair<detail::functor_to_visitor<Event##_type, \
	Visitor>, Visitors> > \
	do_##Event(Visitor visitor) \
	{ \
	typedef std::pair<detail::functor_to_visitor<Event##_type, Visitor>, \
	Visitors> visitor_list; \
	typedef Kind##_visitor<visitor_list> result_type; \
	return result_type(visitor_list(visitor, m_vis)); \
	}

	} /* namespace boost */

	#if BOOST_WORKAROUND(BOOST_MSVC, < 1300)
	// Stay out of the way of the concept checking class
	# undef Graph
	#endif

	#endif