Sindbad~EG File Manager
//=======================================================================
// Copyright 2002 Indiana University.
// 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)
//=======================================================================
#ifndef BOOST_GRAPH_ARCHETYPES_HPP
#define BOOST_GRAPH_ARCHETYPES_HPP
#include <boost/property_map/property_map.hpp>
#include <boost/concept_archetype.hpp>
#include <boost/graph/graph_traits.hpp>
#include <boost/graph/properties.hpp>
namespace boost
{ // should use a different namespace for this
namespace detail
{
struct null_graph_archetype : public null_archetype<>
{
struct traversal_category
{
};
};
}
//===========================================================================
template < typename Vertex, typename Directed, typename ParallelCategory,
typename Base = detail::null_graph_archetype >
struct incidence_graph_archetype : public Base
{
typedef typename Base::traversal_category base_trav_cat;
struct traversal_category : public incidence_graph_tag, public base_trav_cat
{
};
#if 0
typedef immutable_graph_tag mutability_category;
#endif
typedef Vertex vertex_descriptor;
typedef unsigned int degree_size_type;
typedef unsigned int vertices_size_type;
typedef unsigned int edges_size_type;
struct edge_descriptor
{
edge_descriptor() {}
edge_descriptor(const detail::dummy_constructor&) {}
bool operator==(const edge_descriptor&) const { return false; }
bool operator!=(const edge_descriptor&) const { return false; }
};
typedef input_iterator_archetype< edge_descriptor > out_edge_iterator;
typedef Directed directed_category;
typedef ParallelCategory edge_parallel_category;
typedef void adjacency_iterator;
typedef void in_edge_iterator;
typedef void vertex_iterator;
typedef void edge_iterator;
static vertex_descriptor null_vertex() { return vertex_descriptor(); }
};
template < typename V, typename D, typename P, typename B >
V source(
const typename incidence_graph_archetype< V, D, P, B >::edge_descriptor&,
const incidence_graph_archetype< V, D, P, B >&)
{
return V(static_object< detail::dummy_constructor >::get());
}
template < typename V, typename D, typename P, typename B >
V target(
const typename incidence_graph_archetype< V, D, P, B >::edge_descriptor&,
const incidence_graph_archetype< V, D, P, B >&)
{
return V(static_object< detail::dummy_constructor >::get());
}
template < typename V, typename D, typename P, typename B >
std::pair< typename incidence_graph_archetype< V, D, P, B >::out_edge_iterator,
typename incidence_graph_archetype< V, D, P, B >::out_edge_iterator >
out_edges(const V&, const incidence_graph_archetype< V, D, P, B >&)
{
typedef typename incidence_graph_archetype< V, D, P, B >::out_edge_iterator
Iter;
return std::make_pair(Iter(), Iter());
}
template < typename V, typename D, typename P, typename B >
typename incidence_graph_archetype< V, D, P, B >::degree_size_type out_degree(
const V&, const incidence_graph_archetype< V, D, P, B >&)
{
return 0;
}
//===========================================================================
template < typename Vertex, typename Directed, typename ParallelCategory,
typename Base = detail::null_graph_archetype >
struct adjacency_graph_archetype : public Base
{
typedef typename Base::traversal_category base_trav_cat;
struct traversal_category : public adjacency_graph_tag, public base_trav_cat
{
};
typedef Vertex vertex_descriptor;
typedef unsigned int degree_size_type;
typedef unsigned int vertices_size_type;
typedef unsigned int edges_size_type;
typedef void edge_descriptor;
typedef input_iterator_archetype< Vertex > adjacency_iterator;
typedef Directed directed_category;
typedef ParallelCategory edge_parallel_category;
typedef void in_edge_iterator;
typedef void out_edge_iterator;
typedef void vertex_iterator;
typedef void edge_iterator;
static vertex_descriptor null_vertex() { return vertex_descriptor(); }
};
template < typename V, typename D, typename P, typename B >
std::pair< typename adjacency_graph_archetype< V, D, P, B >::adjacency_iterator,
typename adjacency_graph_archetype< V, D, P, B >::adjacency_iterator >
adjacent_vertices(const V&, const adjacency_graph_archetype< V, D, P, B >&)
{
typedef typename adjacency_graph_archetype< V, D, P, B >::adjacency_iterator
Iter;
return std::make_pair(Iter(), Iter());
}
template < typename V, typename D, typename P, typename B >
typename adjacency_graph_archetype< V, D, P, B >::degree_size_type out_degree(
const V&, const adjacency_graph_archetype< V, D, P, B >&)
{
return 0;
}
//===========================================================================
template < typename Vertex, typename Directed, typename ParallelCategory,
typename Base = detail::null_graph_archetype >
struct vertex_list_graph_archetype : public Base
{
typedef incidence_graph_archetype< Vertex, Directed, ParallelCategory >
Incidence;
typedef adjacency_graph_archetype< Vertex, Directed, ParallelCategory >
Adjacency;
typedef typename Base::traversal_category base_trav_cat;
struct traversal_category : public vertex_list_graph_tag,
public base_trav_cat
{
};
#if 0
typedef immutable_graph_tag mutability_category;
#endif
typedef Vertex vertex_descriptor;
typedef unsigned int degree_size_type;
typedef typename Incidence::edge_descriptor edge_descriptor;
typedef typename Incidence::out_edge_iterator out_edge_iterator;
typedef typename Adjacency::adjacency_iterator adjacency_iterator;
typedef input_iterator_archetype< Vertex > vertex_iterator;
typedef unsigned int vertices_size_type;
typedef unsigned int edges_size_type;
typedef Directed directed_category;
typedef ParallelCategory edge_parallel_category;
typedef void in_edge_iterator;
typedef void edge_iterator;
static vertex_descriptor null_vertex() { return vertex_descriptor(); }
};
template < typename V, typename D, typename P, typename B >
std::pair< typename vertex_list_graph_archetype< V, D, P, B >::vertex_iterator,
typename vertex_list_graph_archetype< V, D, P, B >::vertex_iterator >
vertices(const vertex_list_graph_archetype< V, D, P, B >&)
{
typedef typename vertex_list_graph_archetype< V, D, P, B >::vertex_iterator
Iter;
return std::make_pair(Iter(), Iter());
}
template < typename V, typename D, typename P, typename B >
typename vertex_list_graph_archetype< V, D, P, B >::vertices_size_type
num_vertices(const vertex_list_graph_archetype< V, D, P, B >&)
{
return 0;
}
// ambiguously inherited from incidence graph and adjacency graph
template < typename V, typename D, typename P, typename B >
typename vertex_list_graph_archetype< V, D, P, B >::degree_size_type out_degree(
const V&, const vertex_list_graph_archetype< V, D, P, B >&)
{
return 0;
}
//===========================================================================
struct property_graph_archetype_tag
{
};
template < typename GraphArchetype, typename Property, typename ValueArch >
struct property_graph_archetype : public GraphArchetype
{
typedef property_graph_archetype_tag graph_tag;
typedef ValueArch vertex_property_type;
typedef ValueArch edge_property_type;
};
struct choose_edge_property_map_archetype
{
template < typename Graph, typename Property, typename Tag > struct bind_
{
typedef mutable_lvalue_property_map_archetype<
typename Graph::edge_descriptor, Property >
type;
typedef lvalue_property_map_archetype< typename Graph::edge_descriptor,
Property >
const_type;
};
};
template <> struct edge_property_selector< property_graph_archetype_tag >
{
typedef choose_edge_property_map_archetype type;
};
struct choose_vertex_property_map_archetype
{
template < typename Graph, typename Property, typename Tag > struct bind_
{
typedef mutable_lvalue_property_map_archetype<
typename Graph::vertex_descriptor, Property >
type;
typedef lvalue_property_map_archetype<
typename Graph::vertex_descriptor, Property >
const_type;
};
};
template <> struct vertex_property_selector< property_graph_archetype_tag >
{
typedef choose_vertex_property_map_archetype type;
};
template < typename G, typename P, typename V >
typename property_map< property_graph_archetype< G, P, V >, P >::type get(
P, property_graph_archetype< G, P, V >&)
{
typename property_map< property_graph_archetype< G, P, V >, P >::type pmap;
return pmap;
}
template < typename G, typename P, typename V >
typename property_map< property_graph_archetype< G, P, V >, P >::const_type get(
P, const property_graph_archetype< G, P, V >&)
{
typename property_map< property_graph_archetype< G, P, V >, P >::const_type
pmap;
return pmap;
}
template < typename G, typename P, typename K, typename V >
typename property_traits< typename property_map<
property_graph_archetype< G, P, V >, P >::const_type >::value_type
get(P p, const property_graph_archetype< G, P, V >& g, K k)
{
return get(get(p, g), k);
}
template < typename G, typename P, typename V, typename Key >
void put(
P p, property_graph_archetype< G, P, V >& g, const Key& key, const V& value)
{
typedef typename boost::property_map< property_graph_archetype< G, P, V >,
P >::type Map;
Map pmap = get(p, g);
put(pmap, key, value);
}
struct color_value_archetype
{
color_value_archetype() {}
color_value_archetype(detail::dummy_constructor) {}
bool operator==(const color_value_archetype&) const { return true; }
bool operator!=(const color_value_archetype&) const { return true; }
};
template <> struct color_traits< color_value_archetype >
{
static color_value_archetype white()
{
return color_value_archetype(
static_object< detail::dummy_constructor >::get());
}
static color_value_archetype gray()
{
return color_value_archetype(
static_object< detail::dummy_constructor >::get());
}
static color_value_archetype black()
{
return color_value_archetype(
static_object< detail::dummy_constructor >::get());
}
};
template < typename T > class buffer_archetype
{
public:
void push(const T&) {}
void pop() {}
T& top() { return static_object< T >::get(); }
const T& top() const { return static_object< T >::get(); }
bool empty() const { return true; }
};
} // namespace boost
#endif // BOOST_GRAPH_ARCHETYPES_HPP
Sindbad File Manager Version 1.0, Coded By Sindbad EG ~ The Terrorists