graph/include/boost/graph/undirected_graph.hpp

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C++

// (C) Copyright 2007-2009 Andrew Sutton
//
// Use, modification and distribution are subject to the
// Boost Software License, Version 1.0 (See accompanying file
// LICENSE_1_0.txt or http://www.boost.org/LICENSE_1_0.txt)
#ifndef BOOST_GRAPH_UNDIRECTED_GRAPH_HPP
#define BOOST_GRAPH_UNDIRECTED_GRAPH_HPP
#include <boost/graph/adjacency_list.hpp>
#include <boost/graph/properties.hpp>
#include <boost/pending/property.hpp>
#include <boost/property_map/transform_value_property_map.hpp>
#include <boost/type_traits.hpp>
#include <boost/mpl/if.hpp>
namespace boost
{
struct undirected_graph_tag { };
/**
* The undirected_graph class template is a simplified version of the BGL
* adjacency list. This class is provided for ease of use, but may not
* perform as well as custom-defined adjacency list classes. Instances of
* this template model the VertexIndexGraph, and EdgeIndexGraph concepts. The
* graph is also fully mutable, supporting both insertions and removals of
* vertices and edges.
*
* @note Special care must be taken when removing vertices or edges since
* those operations can invalidate the numbering of vertices.
*/
template <
typename VertexProp = no_property,
typename EdgeProp = no_property,
typename GraphProp = no_property>
class undirected_graph
{
public:
typedef GraphProp graph_property_type;
typedef VertexProp vertex_property_type;
typedef EdgeProp edge_property_type;
typedef typename lookup_one_property<GraphProp, graph_bundle_t>::type graph_bundled;
typedef typename lookup_one_property<VertexProp, vertex_bundle_t>::type vertex_bundled;
typedef typename lookup_one_property<EdgeProp, edge_bundle_t>::type edge_bundled;
public:
// Embed indices into the vertex type.
typedef property<vertex_index_t, unsigned, vertex_property_type> internal_vertex_property;
typedef property<edge_index_t, unsigned, edge_property_type> internal_edge_property;
public:
typedef adjacency_list<listS,
listS,
undirectedS,
internal_vertex_property,
internal_edge_property,
GraphProp,
listS> graph_type;
private:
// storage selectors
typedef typename graph_type::vertex_list_selector vertex_list_selector;
typedef typename graph_type::edge_list_selector edge_list_selector;
typedef typename graph_type::out_edge_list_selector out_edge_list_selector;
typedef typename graph_type::directed_selector directed_selector;
public:
// more commonly used graph types
typedef typename graph_type::stored_vertex stored_vertex;
typedef typename graph_type::vertices_size_type vertices_size_type;
typedef typename graph_type::edges_size_type edges_size_type;
typedef typename graph_type::degree_size_type degree_size_type;
typedef typename graph_type::vertex_descriptor vertex_descriptor;
typedef typename graph_type::edge_descriptor edge_descriptor;
// iterator types
typedef typename graph_type::vertex_iterator vertex_iterator;
typedef typename graph_type::edge_iterator edge_iterator;
typedef typename graph_type::out_edge_iterator out_edge_iterator;
typedef typename graph_type::in_edge_iterator in_edge_iterator;
typedef typename graph_type::adjacency_iterator adjacency_iterator;
// miscellaneous types
typedef undirected_graph_tag graph_tag;
typedef typename graph_type::directed_category directed_category;
typedef typename graph_type::edge_parallel_category edge_parallel_category;
typedef typename graph_type::traversal_category traversal_category;
typedef std::size_t vertex_index_type;
typedef std::size_t edge_index_type;
inline undirected_graph(GraphProp const& p = GraphProp())
: m_graph(p), m_num_vertices(0), m_num_edges(0), m_max_vertex_index(0)
, m_max_edge_index(0)
{ }
inline undirected_graph(undirected_graph const& x)
: m_graph(x.m_graph), m_num_vertices(x.m_num_vertices), m_num_edges(x.m_num_edges)
, m_max_vertex_index(x.m_max_vertex_index), m_max_edge_index(x.m_max_edge_index)
{ }
inline undirected_graph(vertices_size_type n,
GraphProp const& p = GraphProp())
: m_graph(n, p), m_num_vertices(n), m_num_edges(0), m_max_vertex_index(n)
, m_max_edge_index(0)
{ renumber_vertex_indices(); }
template <typename EdgeIterator>
inline undirected_graph(EdgeIterator f,
EdgeIterator l,
vertices_size_type n,
edges_size_type m = 0,
GraphProp const& p = GraphProp())
: m_graph(f, l, n, m, p), m_num_vertices(n), m_num_edges(0)
, m_max_vertex_index(n), m_max_edge_index(0)
{
// Unfortunately, we have to renumber to ensure correct indexing.
renumber_indices();
// Can't always guarantee that the number of edges is actually
// m if distance(f, l) != m (or is undefined).
m_num_edges = m_max_edge_index = boost::num_edges(m_graph);
}
undirected_graph& operator =(undirected_graph const& g) {
if(&g != this) {
m_graph = g.m_graph;
m_num_vertices = g.m_num_vertices;
m_num_edges = g.m_num_edges;
m_max_vertex_index = g.m_max_vertex_index;
}
return *this;
}
// The impl_() methods are not part of the public interface.
graph_type& impl()
{ return m_graph; }
graph_type const& impl() const
{ return m_graph; }
// The following methods are not part of the public interface
vertices_size_type num_vertices() const
{ return m_num_vertices; }
private:
// This helper function manages the attribution of vertex indices.
vertex_descriptor make_index(vertex_descriptor v) {
boost::put(vertex_index, m_graph, v, m_max_vertex_index);
m_num_vertices++;
m_max_vertex_index++;
return v;
}
public:
vertex_descriptor add_vertex()
{ return make_index(boost::add_vertex(m_graph)); }
vertex_descriptor add_vertex(vertex_property_type const& p)
{ return make_index(boost::add_vertex(internal_vertex_property(0u, p), m_graph)); }
void clear_vertex(vertex_descriptor v) {
std::pair<out_edge_iterator, out_edge_iterator>
p = boost::out_edges(v, m_graph);
m_num_edges -= std::distance(p.first, p.second);
boost::clear_vertex(v, m_graph);
}
void remove_vertex(vertex_descriptor v) {
boost::remove_vertex(v, m_graph);
--m_num_vertices;
}
edges_size_type num_edges() const
{ return m_num_edges; }
private:
// A helper fucntion for managing edge index attributes.
std::pair<edge_descriptor, bool> const&
make_index(std::pair<edge_descriptor, bool> const& x)
{
if(x.second) {
boost::put(edge_index, m_graph, x.first, m_max_edge_index);
++m_num_edges;
++m_max_edge_index;
}
return x;
}
public:
std::pair<edge_descriptor, bool>
add_edge(vertex_descriptor u, vertex_descriptor v)
{ return make_index(boost::add_edge(u, v, m_graph)); }
std::pair<edge_descriptor, bool>
add_edge(vertex_descriptor u, vertex_descriptor v,
edge_property_type const& p)
{ return make_index(boost::add_edge(u, v, internal_edge_property(0u, p), m_graph)); }
void remove_edge(vertex_descriptor u, vertex_descriptor v) {
// find all edges, (u, v)
std::vector<edge_descriptor> edges;
out_edge_iterator i, i_end;
for(boost::tie(i, i_end) = boost::out_edges(u, m_graph); i != i_end; ++i) {
if(boost::target(*i, m_graph) == v) {
edges.push_back(*i);
}
}
// remove all edges, (u, v)
typename std::vector<edge_descriptor>::iterator
j = edges.begin(), j_end = edges.end();
for( ; j != j_end; ++j) {
remove_edge(*j);
}
}
void remove_edge(edge_iterator i) {
remove_edge(*i);
}
void remove_edge(edge_descriptor e) {
boost::remove_edge(e, m_graph);
--m_num_edges;
}
vertex_index_type max_vertex_index() const
{ return m_max_vertex_index; }
void renumber_vertex_indices() {
vertex_iterator i, i_end;
boost::tie(i, i_end) = vertices(m_graph);
m_max_vertex_index = renumber_vertex_indices(i, i_end, 0);
}
void remove_vertex_and_renumber_indices(vertex_iterator i) {
vertex_iterator j = next(i), end = vertices(m_graph).second;
vertex_index_type n = get(vertex_index, m_graph, *i);
// remove the offending vertex and renumber everything after
remove_vertex(*i);
m_max_vertex_index = renumber_vertex_indices(j, end, n);
}
edge_index_type max_edge_index() const
{ return m_max_edge_index; }
void renumber_edge_indices() {
edge_iterator i, end;
boost::tie(i, end) = edges(m_graph);
m_max_edge_index = renumber_edge_indices(i, end, 0);
}
void remove_edge_and_renumber_indices(edge_iterator i) {
edge_iterator j = next(i), end = edges(m_graph.second);
edge_index_type n = get(edge_index, m_graph, *i);
// remove the edge and renumber everything after it
remove_edge(*i);
m_max_edge_index = renumber_edge_indices(j, end, n);
}
void renumber_indices() {
renumber_vertex_indices();
renumber_edge_indices();
}
// bundled property support
#ifndef BOOST_GRAPH_NO_BUNDLED_PROPERTIES
vertex_bundled& operator[](vertex_descriptor v)
{ return m_graph[v]; }
vertex_bundled const& operator[](vertex_descriptor v) const
{ return m_graph[v]; }
edge_bundled& operator[](edge_descriptor e)
{ return m_graph[e]; }
edge_bundled const& operator[](edge_descriptor e) const
{ return m_graph[e]; }
graph_bundled& operator[](graph_bundle_t)
{ return get_property(*this); }
graph_bundled const& operator[](graph_bundle_t) const
{ return get_property(*this); }
#endif
// Graph concepts
static vertex_descriptor null_vertex()
{ return graph_type::null_vertex(); }
void clear() {
m_graph.clear();
m_num_vertices = m_max_vertex_index = 0;
m_num_edges = m_max_edge_index = 0;
}
void swap(undirected_graph& g) {
m_graph.swap(g.m_graph);
std::swap(m_num_vertices, g.m_num_vertices);
std::swap(m_max_vertex_index, g.m_max_vertex_index);
std::swap(m_num_edges, g.m_num_edges);
std::swap(m_max_edge_index, g.m_max_edge_index);
}
private:
vertices_size_type renumber_vertex_indices(vertex_iterator i,
vertex_iterator end,
vertices_size_type n)
{
typedef typename property_map<graph_type, vertex_index_t>::type IndexMap;
IndexMap indices = get(vertex_index, m_graph);
for( ; i != end; ++i) {
indices[*i] = n++;
}
return n;
}
edges_size_type renumber_edge_indices(edge_iterator i,
edge_iterator end,
edges_size_type n)
{
typedef typename property_map<graph_type, edge_index_t>::type IndexMap;
IndexMap indices = get(edge_index, m_graph);
for( ; i != end; ++i) {
indices[*i] = n++;
}
return n;
}
graph_type m_graph;
vertices_size_type m_num_vertices;
edges_size_type m_num_edges;
vertex_index_type m_max_vertex_index;
edge_index_type m_max_edge_index;
};
#define UNDIRECTED_GRAPH_PARAMS typename VP, typename EP, typename GP
#define UNDIRECTED_GRAPH undirected_graph<VP,EP,GP>
// IncidenceGraph concepts
template <UNDIRECTED_GRAPH_PARAMS>
inline typename UNDIRECTED_GRAPH::vertex_descriptor
source(typename UNDIRECTED_GRAPH::edge_descriptor e,
UNDIRECTED_GRAPH const& g)
{ return source(e, g.impl()); }
template <UNDIRECTED_GRAPH_PARAMS>
inline typename UNDIRECTED_GRAPH::vertex_descriptor
target(typename UNDIRECTED_GRAPH::edge_descriptor e,
UNDIRECTED_GRAPH const& g)
{ return target(e, g.impl()); }
template <UNDIRECTED_GRAPH_PARAMS>
inline typename UNDIRECTED_GRAPH::degree_size_type
out_degree(typename UNDIRECTED_GRAPH::vertex_descriptor v,
UNDIRECTED_GRAPH const& g)
{ return out_degree(v, g.impl()); }
template <UNDIRECTED_GRAPH_PARAMS>
inline std::pair<
typename UNDIRECTED_GRAPH::out_edge_iterator,
typename UNDIRECTED_GRAPH::out_edge_iterator
>
out_edges(typename UNDIRECTED_GRAPH::vertex_descriptor v,
UNDIRECTED_GRAPH const& g)
{ return out_edges(v, g.impl()); }
// BidirectionalGraph concepts
template <UNDIRECTED_GRAPH_PARAMS>
inline typename UNDIRECTED_GRAPH::degree_size_type
in_degree(typename UNDIRECTED_GRAPH::vertex_descriptor v,
UNDIRECTED_GRAPH const& g)
{ return in_degree(v, g.impl()); }
template <UNDIRECTED_GRAPH_PARAMS>
inline std::pair<
typename UNDIRECTED_GRAPH::in_edge_iterator,
typename UNDIRECTED_GRAPH::in_edge_iterator
>
in_edges(typename UNDIRECTED_GRAPH::vertex_descriptor v,
UNDIRECTED_GRAPH const& g)
{ return in_edges(v, g.impl()); }
template <UNDIRECTED_GRAPH_PARAMS>
inline std::pair<
typename UNDIRECTED_GRAPH::out_edge_iterator,
typename UNDIRECTED_GRAPH::out_edge_iterator
>
incident_edges(typename UNDIRECTED_GRAPH::vertex_descriptor v,
UNDIRECTED_GRAPH const& g)
{ return out_edges(v, g.impl()); }
template <UNDIRECTED_GRAPH_PARAMS>
inline typename UNDIRECTED_GRAPH::degree_size_type
degree(typename UNDIRECTED_GRAPH::vertex_descriptor v,
UNDIRECTED_GRAPH const& g)
{ return degree(v, g.impl()); }
// AdjacencyGraph concepts
template <UNDIRECTED_GRAPH_PARAMS>
inline std::pair<
typename UNDIRECTED_GRAPH::adjacency_iterator,
typename UNDIRECTED_GRAPH::adjacency_iterator
>
adjacent_vertices(typename UNDIRECTED_GRAPH::vertex_descriptor v,
UNDIRECTED_GRAPH const& g)
{ return adjacent_vertices(v, g.impl()); }
template <UNDIRECTED_GRAPH_PARAMS>
typename UNDIRECTED_GRAPH::vertex_descriptor
vertex(typename UNDIRECTED_GRAPH::vertices_size_type n,
UNDIRECTED_GRAPH const& g)
{ return vertex(n, g.impl()); }
template <UNDIRECTED_GRAPH_PARAMS>
std::pair<typename UNDIRECTED_GRAPH::edge_descriptor, bool>
edge(typename UNDIRECTED_GRAPH::vertex_descriptor u,
typename UNDIRECTED_GRAPH::vertex_descriptor v,
UNDIRECTED_GRAPH const& g)
{ return edge(u, v, g.impl()); }
// VertexListGraph concepts
template <UNDIRECTED_GRAPH_PARAMS>
inline typename UNDIRECTED_GRAPH::vertices_size_type
num_vertices(UNDIRECTED_GRAPH const& g)
{ return g.num_vertices(); }
template <UNDIRECTED_GRAPH_PARAMS>
inline std::pair<
typename UNDIRECTED_GRAPH::vertex_iterator,
typename UNDIRECTED_GRAPH::vertex_iterator
>
vertices(UNDIRECTED_GRAPH const& g)
{ return vertices(g.impl()); }
// EdgeListGraph concepts
template <UNDIRECTED_GRAPH_PARAMS>
inline typename UNDIRECTED_GRAPH::edges_size_type
num_edges(UNDIRECTED_GRAPH const& g)
{ return g.num_edges(); }
template <UNDIRECTED_GRAPH_PARAMS>
inline std::pair<
typename UNDIRECTED_GRAPH::edge_iterator,
typename UNDIRECTED_GRAPH::edge_iterator
>
edges(UNDIRECTED_GRAPH const& g)
{ return edges(g.impl()); }
// MutableGraph concepts
template <UNDIRECTED_GRAPH_PARAMS>
inline typename UNDIRECTED_GRAPH::vertex_descriptor
add_vertex(UNDIRECTED_GRAPH& g)
{ return g.add_vertex(); }
template <UNDIRECTED_GRAPH_PARAMS>
inline typename UNDIRECTED_GRAPH::vertex_descriptor
add_vertex(typename UNDIRECTED_GRAPH::vertex_property_type const& p,
UNDIRECTED_GRAPH& g)
{ return g.add_vertex(p); }
template <UNDIRECTED_GRAPH_PARAMS>
inline void
clear_vertex(typename UNDIRECTED_GRAPH::vertex_descriptor v,
UNDIRECTED_GRAPH& g)
{ return g.clear_vertex(v); }
template <UNDIRECTED_GRAPH_PARAMS>
inline void
remove_vertex(typename UNDIRECTED_GRAPH::vertex_descriptor v, UNDIRECTED_GRAPH& g)
{ return g.remove_vertex(v); }
template <UNDIRECTED_GRAPH_PARAMS>
inline std::pair<typename UNDIRECTED_GRAPH::edge_descriptor, bool>
add_edge(typename UNDIRECTED_GRAPH::vertex_descriptor u,
typename UNDIRECTED_GRAPH::vertex_descriptor v,
UNDIRECTED_GRAPH& g)
{ return g.add_edge(u, v); }
template <UNDIRECTED_GRAPH_PARAMS>
inline std::pair<typename UNDIRECTED_GRAPH::edge_descriptor, bool>
add_edge(typename UNDIRECTED_GRAPH::vertex_descriptor u,
typename UNDIRECTED_GRAPH::vertex_descriptor v,
typename UNDIRECTED_GRAPH::edge_property_type const& p,
UNDIRECTED_GRAPH& g)
{ return g.add_edge(u, v, p); }
template <UNDIRECTED_GRAPH_PARAMS>
inline void
remove_edge(typename UNDIRECTED_GRAPH::vertex_descriptor u,
typename UNDIRECTED_GRAPH::vertex_descriptor v,
UNDIRECTED_GRAPH& g)
{ return g.remove_edge(u, v); }
template <UNDIRECTED_GRAPH_PARAMS>
inline void
remove_edge(typename UNDIRECTED_GRAPH::edge_descriptor e, UNDIRECTED_GRAPH& g)
{ return g.remove_edge(e); }
template <UNDIRECTED_GRAPH_PARAMS>
inline void
remove_edge(typename UNDIRECTED_GRAPH::edge_iterator i, UNDIRECTED_GRAPH& g)
{ return g.remove_edge(i); }
template <UNDIRECTED_GRAPH_PARAMS, class Predicate>
inline void remove_edge_if(Predicate pred, UNDIRECTED_GRAPH& g)
{ return remove_edge_if(pred, g.impl()); }
template <UNDIRECTED_GRAPH_PARAMS, class Predicate>
inline void
remove_incident_edge_if(typename UNDIRECTED_GRAPH::vertex_descriptor v,
Predicate pred,
UNDIRECTED_GRAPH& g)
{ return remove_out_edge_if(v, pred, g.impl()); }
template <UNDIRECTED_GRAPH_PARAMS, class Predicate>
inline void
remove_out_edge_if(typename UNDIRECTED_GRAPH::vertex_descriptor v,
Predicate pred,
UNDIRECTED_GRAPH& g)
{ return remove_out_edge_if(v, pred, g.impl()); }
template <UNDIRECTED_GRAPH_PARAMS, class Predicate>
inline void
remove_in_edge_if(typename UNDIRECTED_GRAPH::vertex_descriptor v,
Predicate pred,
UNDIRECTED_GRAPH& g)
{ return remove_in_edge_if(v, pred, g.impl()); }
template <UNDIRECTED_GRAPH_PARAMS, typename Property>
struct property_map<UNDIRECTED_GRAPH, Property>: property_map<typename UNDIRECTED_GRAPH::graph_type, Property> {};
template <UNDIRECTED_GRAPH_PARAMS>
struct property_map<UNDIRECTED_GRAPH, vertex_all_t> {
typedef transform_value_property_map<
detail::remove_first_property,
typename property_map<typename UNDIRECTED_GRAPH::graph_type, vertex_all_t>::const_type>
const_type;
typedef transform_value_property_map<
detail::remove_first_property,
typename property_map<typename UNDIRECTED_GRAPH::graph_type, vertex_all_t>::type>
type;
};
template <UNDIRECTED_GRAPH_PARAMS>
struct property_map<UNDIRECTED_GRAPH, edge_all_t> {
typedef transform_value_property_map<
detail::remove_first_property,
typename property_map<typename UNDIRECTED_GRAPH::graph_type, edge_all_t>::const_type>
const_type;
typedef transform_value_property_map<
detail::remove_first_property,
typename property_map<typename UNDIRECTED_GRAPH::graph_type, edge_all_t>::type>
type;
};
// PropertyGraph concepts
template <UNDIRECTED_GRAPH_PARAMS, typename Property>
inline typename property_map<UNDIRECTED_GRAPH, Property>::type
get(Property p, UNDIRECTED_GRAPH& g)
{ return get(p, g.impl()); }
template <UNDIRECTED_GRAPH_PARAMS, typename Property>
inline typename property_map<UNDIRECTED_GRAPH, Property>::const_type
get(Property p, UNDIRECTED_GRAPH const& g)
{ return get(p, g.impl()); }
template <UNDIRECTED_GRAPH_PARAMS>
inline typename property_map<UNDIRECTED_GRAPH, vertex_all_t>::type
get(vertex_all_t, UNDIRECTED_GRAPH& g)
{ return typename property_map<UNDIRECTED_GRAPH, vertex_all_t>::type(detail::remove_first_property(), get(vertex_all, g.impl())); }
template <UNDIRECTED_GRAPH_PARAMS>
inline typename property_map<UNDIRECTED_GRAPH, vertex_all_t>::const_type
get(vertex_all_t, UNDIRECTED_GRAPH const& g)
{ return typename property_map<UNDIRECTED_GRAPH, vertex_all_t>::const_type(detail::remove_first_property(), get(vertex_all, g.impl())); }
template <UNDIRECTED_GRAPH_PARAMS>
inline typename property_map<UNDIRECTED_GRAPH, edge_all_t>::type
get(edge_all_t, UNDIRECTED_GRAPH& g)
{ return typename property_map<UNDIRECTED_GRAPH, edge_all_t>::type(detail::remove_first_property(), get(edge_all, g.impl())); }
template <UNDIRECTED_GRAPH_PARAMS>
inline typename property_map<UNDIRECTED_GRAPH, edge_all_t>::const_type
get(edge_all_t, UNDIRECTED_GRAPH const& g)
{ return typename property_map<UNDIRECTED_GRAPH, edge_all_t>::const_type(detail::remove_first_property(), get(edge_all, g.impl())); }
template <UNDIRECTED_GRAPH_PARAMS, typename Property, typename Key>
inline typename property_traits<
typename property_map<
typename UNDIRECTED_GRAPH::graph_type, Property
>::const_type
>::value_type
get(Property p, UNDIRECTED_GRAPH const& g, Key const& k)
{ return get(p, g.impl(), k); }
template <UNDIRECTED_GRAPH_PARAMS, typename Key>
inline typename property_traits<
typename property_map<
typename UNDIRECTED_GRAPH::graph_type, vertex_all_t
>::const_type
>::value_type
get(vertex_all_t, UNDIRECTED_GRAPH const& g, Key const& k)
{ return get(vertex_all, g.impl(), k).m_base; }
template <UNDIRECTED_GRAPH_PARAMS, typename Key>
inline typename property_traits<
typename property_map<
typename UNDIRECTED_GRAPH::graph_type, edge_all_t
>::const_type
>::value_type
get(edge_all_t, UNDIRECTED_GRAPH const& g, Key const& k)
{ return get(edge_all, g.impl(), k).m_base; }
template <UNDIRECTED_GRAPH_PARAMS, typename Property, typename Key, typename Value>
inline void put(Property p, UNDIRECTED_GRAPH& g, Key const& k, Value const& v)
{ put(p, g.impl(), k, v); }
template <UNDIRECTED_GRAPH_PARAMS, typename Key, typename Value>
inline void put(vertex_all_t, UNDIRECTED_GRAPH& g, Key const& k, Value const& v)
{ put(vertex_all, g.impl(), k,
typename UNDIRECTED_GRAPH::internal_vertex_property(get(vertex_index, g.impl(), k), v));
}
template <UNDIRECTED_GRAPH_PARAMS, typename Key, typename Value>
inline void put(edge_all_t, UNDIRECTED_GRAPH& g, Key const& k, Value const& v)
{ put(edge_all, g.impl(), k,
typename UNDIRECTED_GRAPH::internal_vertex_property(get(edge_index, g.impl(), k), v));
}
template <UNDIRECTED_GRAPH_PARAMS, class Property>
inline typename graph_property<UNDIRECTED_GRAPH, Property>::type&
get_property(UNDIRECTED_GRAPH& g, Property p)
{ return get_property(g.impl(), p); }
template <UNDIRECTED_GRAPH_PARAMS, class Property>
inline typename graph_property<UNDIRECTED_GRAPH, Property>::type const&
get_property(UNDIRECTED_GRAPH const& g, Property p)
{ return get_property(g.impl(), p); }
template <UNDIRECTED_GRAPH_PARAMS, class Property, class Value>
inline void set_property(UNDIRECTED_GRAPH& g, Property p, Value v)
{ return set_property(g.impl(), p, v); }
// Indexed Vertex graph
template <UNDIRECTED_GRAPH_PARAMS>
inline typename UNDIRECTED_GRAPH::vertex_index_type
get_vertex_index(typename UNDIRECTED_GRAPH::vertex_descriptor v,
UNDIRECTED_GRAPH const& g)
{ return get(vertex_index, g, v); }
template <UNDIRECTED_GRAPH_PARAMS>
typename UNDIRECTED_GRAPH::vertex_index_type
max_vertex_index(UNDIRECTED_GRAPH const& g)
{ return g.max_vertex_index(); }
template <UNDIRECTED_GRAPH_PARAMS>
inline void
renumber_vertex_indices(UNDIRECTED_GRAPH& g)
{ g.renumber_vertex_indices(); }
template <UNDIRECTED_GRAPH_PARAMS>
inline void
remove_vertex_and_renumber_indices(typename UNDIRECTED_GRAPH::vertex_iterator i,
UNDIRECTED_GRAPH& g)
{ g.remove_vertex_and_renumber_indices(i); }
// Edge index management
template <UNDIRECTED_GRAPH_PARAMS>
inline typename UNDIRECTED_GRAPH::edge_index_type
get_edge_index(typename UNDIRECTED_GRAPH::edge_descriptor v,
UNDIRECTED_GRAPH const& g)
{ return get(edge_index, g, v); }
template <UNDIRECTED_GRAPH_PARAMS>
typename UNDIRECTED_GRAPH::edge_index_type
max_edge_index(UNDIRECTED_GRAPH const& g)
{ return g.max_edge_index(); }
template <UNDIRECTED_GRAPH_PARAMS>
inline void
renumber_edge_indices(UNDIRECTED_GRAPH& g)
{ g.renumber_edge_indices(); }
template <UNDIRECTED_GRAPH_PARAMS>
inline void
remove_edge_and_renumber_indices(typename UNDIRECTED_GRAPH::edge_iterator i,
UNDIRECTED_GRAPH& g)
{ g.remove_edge_and_renumber_indices(i); }
// Index management
template <UNDIRECTED_GRAPH_PARAMS>
inline void
renumber_indices(UNDIRECTED_GRAPH& g)
{ g.renumber_indices(); }
// Mutability Traits
template <UNDIRECTED_GRAPH_PARAMS>
struct graph_mutability_traits<UNDIRECTED_GRAPH> {
typedef mutable_property_graph_tag category;
};
#undef UNDIRECTED_GRAPH_PARAMS
#undef UNDIRECTED_GRAPH
} /* namespace boost */
#endif