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glm/test/external/boost/graph/cuthill_mckee_ordering.hpp

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//=======================================================================
// Copyright 1997, 1998, 1999, 2000 University of Notre Dame.
// Copyright 2004, 2005 Trustees of Indiana University
// Authors: Andrew Lumsdaine, Lie-Quan Lee, Jeremy G. Siek,
// Doug Gregor, D. Kevin McGrath
//
// 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_CUTHILL_MCKEE_HPP
#define BOOST_GRAPH_CUTHILL_MCKEE_HPP
#include <boost/config.hpp>
#include <boost/graph/detail/sparse_ordering.hpp>
#include <boost/graph/graph_utility.hpp>
#include <algorithm>
/*
(Reverse) Cuthill-McKee Algorithm for matrix reordering
*/
namespace boost {
namespace detail {
template < typename OutputIterator, typename Buffer, typename DegreeMap >
class bfs_rcm_visitor:public default_bfs_visitor
{
public:
bfs_rcm_visitor(OutputIterator *iter, Buffer *b, DegreeMap deg):
permutation(iter), Qptr(b), degree(deg) { }
template <class Vertex, class Graph>
void examine_vertex(Vertex u, Graph&) {
*(*permutation)++ = u;
index_begin = Qptr->size();
}
template <class Vertex, class Graph>
void finish_vertex(Vertex, Graph&) {
using std::sort;
typedef typename property_traits<DegreeMap>::value_type ds_type;
typedef indirect_cmp<DegreeMap, std::less<ds_type> > Compare;
Compare comp(degree);
sort(Qptr->begin()+index_begin, Qptr->end(), comp);
}
protected:
OutputIterator *permutation;
int index_begin;
Buffer *Qptr;
DegreeMap degree;
};
} // namespace detail
// Reverse Cuthill-McKee algorithm with a given starting Vertex.
//
// If user provides a reverse iterator, this will be a reverse-cuthill-mckee
// algorithm, otherwise it will be a standard CM algorithm
template <class Graph, class OutputIterator,
class ColorMap, class DegreeMap>
OutputIterator
cuthill_mckee_ordering(const Graph& g,
std::deque< typename
graph_traits<Graph>::vertex_descriptor > vertex_queue,
OutputIterator permutation,
ColorMap color, DegreeMap degree)
{
//create queue, visitor...don't forget namespaces!
typedef typename property_traits<DegreeMap>::value_type ds_type;
typedef typename graph_traits<Graph>::vertex_descriptor Vertex;
typedef typename boost::sparse::sparse_ordering_queue<Vertex> queue;
typedef typename detail::bfs_rcm_visitor<OutputIterator, queue, DegreeMap> Visitor;
typedef typename property_traits<ColorMap>::value_type ColorValue;
typedef color_traits<ColorValue> Color;
queue Q;
//create a bfs_rcm_visitor as defined above
Visitor vis(&permutation, &Q, degree);
typename graph_traits<Graph>::vertex_iterator ui, ui_end;
// Copy degree to pseudo_degree
// initialize the color map
for (boost::tie(ui, ui_end) = vertices(g); ui != ui_end; ++ui){
put(color, *ui, Color::white());
}
while( !vertex_queue.empty() ) {
Vertex s = vertex_queue.front();
vertex_queue.pop_front();
//call BFS with visitor
breadth_first_visit(g, s, Q, vis, color);
}
return permutation;
}
// This is the case where only a single starting vertex is supplied.
template <class Graph, class OutputIterator,
class ColorMap, class DegreeMap>
OutputIterator
cuthill_mckee_ordering(const Graph& g,
typename graph_traits<Graph>::vertex_descriptor s,
OutputIterator permutation,
ColorMap color, DegreeMap degree)
{
std::deque< typename graph_traits<Graph>::vertex_descriptor > vertex_queue;
vertex_queue.push_front( s );
return cuthill_mckee_ordering(g, vertex_queue, permutation, color, degree);
}
// This is the version of CM which selects its own starting vertex
template < class Graph, class OutputIterator,
class ColorMap, class DegreeMap>
OutputIterator
cuthill_mckee_ordering(const Graph& G, OutputIterator permutation,
ColorMap color, DegreeMap degree)
{
if (boost::graph::has_no_vertices(G))
return permutation;
typedef typename boost::graph_traits<Graph>::vertex_descriptor Vertex;
typedef typename boost::graph_traits<Graph>::vertex_iterator VerIter;
typedef typename property_traits<ColorMap>::value_type ColorValue;
typedef color_traits<ColorValue> Color;
std::deque<Vertex> vertex_queue;
// Mark everything white
BGL_FORALL_VERTICES_T(v, G, Graph) put(color, v, Color::white());
// Find one vertex from each connected component
BGL_FORALL_VERTICES_T(v, G, Graph) {
if (get(color, v) == Color::white()) {
depth_first_visit(G, v, dfs_visitor<>(), color);
vertex_queue.push_back(v);
}
}
// Find starting nodes for all vertices
// TBD: How to do this with a directed graph?
for (typename std::deque<Vertex>::iterator i = vertex_queue.begin();
i != vertex_queue.end(); ++i)
*i = find_starting_node(G, *i, color, degree);
return cuthill_mckee_ordering(G, vertex_queue, permutation,
color, degree);
}
template<typename Graph, typename OutputIterator, typename VertexIndexMap>
OutputIterator
cuthill_mckee_ordering(const Graph& G, OutputIterator permutation,
VertexIndexMap index_map)
{
if (boost::graph::has_no_vertices(G))
return permutation;
typedef out_degree_property_map<Graph> DegreeMap;
std::vector<default_color_type> colors(num_vertices(G));
return cuthill_mckee_ordering(G, permutation,
make_iterator_property_map(&colors[0],
index_map,
colors[0]),
make_out_degree_map(G));
}
template<typename Graph, typename OutputIterator>
inline OutputIterator
cuthill_mckee_ordering(const Graph& G, OutputIterator permutation)
{ return cuthill_mckee_ordering(G, permutation, get(vertex_index, G)); }
} // namespace boost
#endif // BOOST_GRAPH_CUTHILL_MCKEE_HPP