boost/graph/graph_traits.hpp
//=======================================================================
// 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)
//=======================================================================
#ifndef BOOST_GRAPH_TRAITS_HPP
#define BOOST_GRAPH_TRAITS_HPP
#include <boost/config.hpp>
#include <iterator>
#include <utility> /* Primarily for std::pair */
#include <boost/tuple/tuple.hpp>
#include <boost/mpl/if.hpp>
#include <boost/mpl/eval_if.hpp>
#include <boost/mpl/bool.hpp>
#include <boost/mpl/not.hpp>
#include <boost/mpl/has_xxx.hpp>
#include <boost/mpl/void.hpp>
#include <boost/mpl/identity.hpp>
#include <boost/type_traits/is_same.hpp>
#include <boost/iterator/iterator_categories.hpp>
#include <boost/iterator/iterator_adaptor.hpp>
#include <boost/pending/property.hpp>
#include <boost/detail/workaround.hpp>
namespace boost
{
namespace detail
{
#define BOOST_GRAPH_MEMBER_OR_VOID(name) \
BOOST_MPL_HAS_XXX_TRAIT_DEF(name) \
template < typename T > struct BOOST_JOIN(get_member_, name) \
{ \
typedef typename T::name type; \
}; \
template < typename T > \
struct BOOST_JOIN(get_opt_member_, name) \
: boost::mpl::eval_if_c< BOOST_JOIN(has_, name) < T >::value, BOOST_JOIN(get_member_, name)< T >, boost::mpl::identity< void > >\
{ \
};
BOOST_GRAPH_MEMBER_OR_VOID(adjacency_iterator)
BOOST_GRAPH_MEMBER_OR_VOID(out_edge_iterator)
BOOST_GRAPH_MEMBER_OR_VOID(in_edge_iterator)
BOOST_GRAPH_MEMBER_OR_VOID(vertex_iterator)
BOOST_GRAPH_MEMBER_OR_VOID(edge_iterator)
BOOST_GRAPH_MEMBER_OR_VOID(vertices_size_type)
BOOST_GRAPH_MEMBER_OR_VOID(edges_size_type)
BOOST_GRAPH_MEMBER_OR_VOID(degree_size_type)
}
template < typename G > struct graph_traits
{
#define BOOST_GRAPH_PULL_OPT_MEMBER(name) \
typedef typename detail::BOOST_JOIN(get_opt_member_, name)< G >::type name;
typedef typename G::vertex_descriptor vertex_descriptor;
typedef typename G::edge_descriptor edge_descriptor;
BOOST_GRAPH_PULL_OPT_MEMBER(adjacency_iterator)
BOOST_GRAPH_PULL_OPT_MEMBER(out_edge_iterator)
BOOST_GRAPH_PULL_OPT_MEMBER(in_edge_iterator)
BOOST_GRAPH_PULL_OPT_MEMBER(vertex_iterator)
BOOST_GRAPH_PULL_OPT_MEMBER(edge_iterator)
typedef typename G::directed_category directed_category;
typedef typename G::edge_parallel_category edge_parallel_category;
typedef typename G::traversal_category traversal_category;
BOOST_GRAPH_PULL_OPT_MEMBER(vertices_size_type)
BOOST_GRAPH_PULL_OPT_MEMBER(edges_size_type)
BOOST_GRAPH_PULL_OPT_MEMBER(degree_size_type)
#undef BOOST_GRAPH_PULL_OPT_MEMBER
static inline vertex_descriptor null_vertex();
};
template < typename G >
inline typename graph_traits< G >::vertex_descriptor
graph_traits< G >::null_vertex()
{
return G::null_vertex();
}
// directed_category tags
struct directed_tag
{
};
struct undirected_tag
{
};
struct bidirectional_tag : public directed_tag
{
};
namespace detail
{
inline bool is_directed(directed_tag) { return true; }
inline bool is_directed(undirected_tag) { return false; }
}
/** Return true if the given graph is directed. */
template < typename Graph > bool is_directed(const Graph&)
{
typedef typename graph_traits< Graph >::directed_category Cat;
return detail::is_directed(Cat());
}
/** Return true if the given graph is undirected. */
template < typename Graph > bool is_undirected(const Graph& g)
{
return !is_directed(g);
}
/** @name Directed/Undirected Graph Traits */
//@{
namespace graph_detail
{
template < typename Tag >
struct is_directed_tag
: mpl::bool_< is_convertible< Tag, directed_tag >::value >
{
};
} // namespace graph_detail
template < typename Graph >
struct is_directed_graph
: graph_detail::is_directed_tag<
typename graph_traits< Graph >::directed_category >
{
};
template < typename Graph >
struct is_undirected_graph : mpl::not_< is_directed_graph< Graph > >
{
};
//@}
// edge_parallel_category tags
struct allow_parallel_edge_tag
{
};
struct disallow_parallel_edge_tag
{
};
namespace detail
{
inline bool allows_parallel(allow_parallel_edge_tag) { return true; }
inline bool allows_parallel(disallow_parallel_edge_tag) { return false; }
}
template < typename Graph > bool allows_parallel_edges(const Graph&)
{
typedef typename graph_traits< Graph >::edge_parallel_category Cat;
return detail::allows_parallel(Cat());
}
/** @name Parallel Edges Traits */
//@{
/**
* The is_multigraph metafunction returns true if the graph allows
* parallel edges. Technically, a multigraph is a simple graph that
* allows parallel edges, but since there are no traits for the allowance
* or disallowance of loops, this is a moot point.
*/
template < typename Graph >
struct is_multigraph
: mpl::bool_< is_same< typename graph_traits< Graph >::edge_parallel_category,
allow_parallel_edge_tag >::value >
{
};
//@}
// traversal_category tags
struct incidence_graph_tag
{
};
struct adjacency_graph_tag
{
};
struct bidirectional_graph_tag : virtual incidence_graph_tag
{
};
struct vertex_list_graph_tag
{
};
struct edge_list_graph_tag
{
};
struct adjacency_matrix_tag
{
};
// Parallel traversal_category tags
struct distributed_graph_tag
{
};
struct distributed_vertex_list_graph_tag
{
};
struct distributed_edge_list_graph_tag
{
};
#define BOOST_GRAPH_SEQUENTIAL_TRAITS_DEFINES_DISTRIBUTED_TAGS // Disable these
// from external
// versions of
// PBGL
/** @name Traversal Category Traits
* These traits classify graph types by their supported methods of
* vertex and edge traversal.
*/
//@{
template < typename Graph >
struct is_incidence_graph
: mpl::bool_<
is_convertible< typename graph_traits< Graph >::traversal_category,
incidence_graph_tag >::value >
{
};
template < typename Graph >
struct is_bidirectional_graph
: mpl::bool_<
is_convertible< typename graph_traits< Graph >::traversal_category,
bidirectional_graph_tag >::value >
{
};
template < typename Graph >
struct is_vertex_list_graph
: mpl::bool_<
is_convertible< typename graph_traits< Graph >::traversal_category,
vertex_list_graph_tag >::value >
{
};
template < typename Graph >
struct is_edge_list_graph
: mpl::bool_<
is_convertible< typename graph_traits< Graph >::traversal_category,
edge_list_graph_tag >::value >
{
};
template < typename Graph >
struct is_adjacency_matrix
: mpl::bool_<
is_convertible< typename graph_traits< Graph >::traversal_category,
adjacency_matrix_tag >::value >
{
};
//@}
/** @name Directed Graph Traits
* These metafunctions are used to fully classify directed vs. undirected
* graphs. Recall that an undirected graph is also bidirectional, but it
* cannot be both undirected and directed at the same time.
*/
//@{
template < typename Graph >
struct is_directed_unidirectional_graph
: mpl::and_< is_directed_graph< Graph >,
mpl::not_< is_bidirectional_graph< Graph > > >
{
};
template < typename Graph >
struct is_directed_bidirectional_graph
: mpl::and_< is_directed_graph< Graph >, is_bidirectional_graph< Graph > >
{
};
//@}
//?? not the right place ?? Lee
typedef boost::forward_traversal_tag multi_pass_input_iterator_tag;
namespace detail
{
BOOST_MPL_HAS_XXX_TRAIT_DEF(graph_property_type)
BOOST_MPL_HAS_XXX_TRAIT_DEF(edge_property_type)
BOOST_MPL_HAS_XXX_TRAIT_DEF(vertex_property_type)
template < typename G > struct get_graph_property_type
{
typedef typename G::graph_property_type type;
};
template < typename G > struct get_edge_property_type
{
typedef typename G::edge_property_type type;
};
template < typename G > struct get_vertex_property_type
{
typedef typename G::vertex_property_type type;
};
}
template < typename G >
struct graph_property_type
: boost::mpl::eval_if< detail::has_graph_property_type< G >,
detail::get_graph_property_type< G >, no_property >
{
};
template < typename G >
struct edge_property_type
: boost::mpl::eval_if< detail::has_edge_property_type< G >,
detail::get_edge_property_type< G >, no_property >
{
};
template < typename G >
struct vertex_property_type
: boost::mpl::eval_if< detail::has_vertex_property_type< G >,
detail::get_vertex_property_type< G >, no_property >
{
};
template < typename G > struct graph_bundle_type
{
typedef typename G::graph_bundled type;
};
template < typename G > struct vertex_bundle_type
{
typedef typename G::vertex_bundled type;
};
template < typename G > struct edge_bundle_type
{
typedef typename G::edge_bundled type;
};
namespace graph
{
namespace detail
{
template < typename Graph, typename Descriptor > class bundled_result
{
typedef typename graph_traits< Graph >::vertex_descriptor Vertex;
typedef typename mpl::if_c< (is_same< Descriptor, Vertex >::value),
vertex_bundle_type< Graph >, edge_bundle_type< Graph > >::type
bundler;
public:
typedef typename bundler::type type;
};
template < typename Graph >
class bundled_result< Graph, graph_bundle_t >
{
typedef typename graph_traits< Graph >::vertex_descriptor Vertex;
typedef graph_bundle_type< Graph > bundler;
public:
typedef typename bundler::type type;
};
}
} // namespace graph::detail
namespace graph_detail
{
// A helper metafunction for determining whether or not a type is
// bundled.
template < typename T >
struct is_no_bundle : mpl::bool_< is_same< T, no_property >::value >
{
};
} // namespace graph_detail
/** @name Graph Property Traits
* These metafunctions (along with those above), can be used to access the
* vertex and edge properties (bundled or otherwise) of vertices and
* edges.
*/
//@{
template < typename Graph >
struct has_graph_property
: mpl::not_< typename detail::is_no_property<
typename graph_property_type< Graph >::type >::type >::type
{
};
template < typename Graph >
struct has_bundled_graph_property
: mpl::not_<
graph_detail::is_no_bundle< typename graph_bundle_type< Graph >::type > >
{
};
template < typename Graph >
struct has_vertex_property
: mpl::not_< typename detail::is_no_property<
typename vertex_property_type< Graph >::type > >::type
{
};
template < typename Graph >
struct has_bundled_vertex_property
: mpl::not_<
graph_detail::is_no_bundle< typename vertex_bundle_type< Graph >::type > >
{
};
template < typename Graph >
struct has_edge_property
: mpl::not_< typename detail::is_no_property<
typename edge_property_type< Graph >::type > >::type
{
};
template < typename Graph >
struct has_bundled_edge_property
: mpl::not_<
graph_detail::is_no_bundle< typename edge_bundle_type< Graph >::type > >
{
};
//@}
} // namespace boost
// Since pair is in namespace std, Koenig lookup will find source and
// target if they are also defined in namespace std. This is illegal,
// but the alternative is to put source and target in the global
// namespace which causes name conflicts with other libraries (like
// SUIF).
namespace std
{
/* Some helper functions for dealing with pairs as edges */
template < class T, class G > T source(pair< T, T > p, const G&)
{
return p.first;
}
template < class T, class G > T target(pair< T, T > p, const G&)
{
return p.second;
}
}
#if defined(__GNUC__) && defined(__SGI_STL_PORT)
// For some reason g++ with STLport does not see the above definition
// of source() and target() unless we bring them into the boost
// namespace.
namespace boost
{
using std::source;
using std::target;
}
#endif
#endif // BOOST_GRAPH_TRAITS_HPP