// Copyright 2004-5 The Trustees of Indiana University. // Copyright 2002 Brad King and Douglas Gregor // 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) // Authors: Douglas Gregor // Andrew Lumsdaine #ifndef BOOST_GRAPH_PAGE_RANK_HPP #define BOOST_GRAPH_PAGE_RANK_HPP #include #include #include #include #include #include namespace boost { namespace graph { struct n_iterations { explicit n_iterations(std::size_t n) : n(n) { } template bool operator()(const RankMap&, const Graph&) { return n-- == 0; } private: std::size_t n; }; namespace detail { template void page_rank_step(const Graph& g, RankMap from_rank, RankMap2 to_rank, typename property_traits::value_type damping, incidence_graph_tag) { typedef typename property_traits::value_type rank_type; // Set new rank maps BGL_FORALL_VERTICES_T(v, g, Graph) put(to_rank, v, rank_type(1 - damping)); BGL_FORALL_VERTICES_T(u, g, Graph) { rank_type u_rank_out = damping * get(from_rank, u) / out_degree(u, g); BGL_FORALL_ADJ_T(u, v, g, Graph) put(to_rank, v, get(to_rank, v) + u_rank_out); } } template void page_rank_step(const Graph& g, RankMap from_rank, RankMap2 to_rank, typename property_traits::value_type damping, bidirectional_graph_tag) { typedef typename property_traits::value_type damping_type; BGL_FORALL_VERTICES_T(v, g, Graph) { typename property_traits::value_type rank(0); BGL_FORALL_INEDGES_T(v, e, g, Graph) rank += get(from_rank, source(e, g)) / out_degree(source(e, g), g); put(to_rank, v, (damping_type(1) - damping) + damping * rank); } } } // end namespace detail template void page_rank(const Graph& g, RankMap rank_map, Done done, typename property_traits::value_type damping, typename graph_traits::vertices_size_type n, RankMap2 rank_map2 BOOST_GRAPH_ENABLE_IF_MODELS_PARM(Graph, vertex_list_graph_tag)) { typedef typename property_traits::value_type rank_type; rank_type initial_rank = rank_type(rank_type(1) / n); BGL_FORALL_VERTICES_T(v, g, Graph) put(rank_map, v, initial_rank); bool to_map_2 = true; while ((to_map_2 && !done(rank_map, g)) || (!to_map_2 && !done(rank_map2, g))) { typedef typename graph_traits::traversal_category category; if (to_map_2) { detail::page_rank_step(g, rank_map, rank_map2, damping, category()); } else { detail::page_rank_step(g, rank_map2, rank_map, damping, category()); } to_map_2 = !to_map_2; } if (!to_map_2) { BGL_FORALL_VERTICES_T(v, g, Graph) put(rank_map, v, get(rank_map2, v)); } } template void page_rank(const Graph& g, RankMap rank_map, Done done, typename property_traits::value_type damping, typename graph_traits::vertices_size_type n) { typedef typename property_traits::value_type rank_type; std::vector ranks2(num_vertices(g)); page_rank(g, rank_map, done, damping, n, make_iterator_property_map(ranks2.begin(), get(vertex_index, g))); } template inline void page_rank(const Graph& g, RankMap rank_map, Done done, typename property_traits::value_type damping = 0.85) { page_rank(g, rank_map, done, damping, num_vertices(g)); } template inline void page_rank(const Graph& g, RankMap rank_map) { page_rank(g, rank_map, n_iterations(20)); } // TBD: this could be _much_ more efficient, using a queue to store // the vertices that should be reprocessed and keeping track of which // vertices are in the queue with a property map. Baah, this only // applies when we have a bidirectional graph. template void remove_dangling_links(MutableGraph& g BOOST_GRAPH_ENABLE_IF_MODELS_PARM(MutableGraph, vertex_list_graph_tag)) { typename graph_traits::vertices_size_type old_n; do { old_n = num_vertices(g); typename graph_traits::vertex_iterator vi, vi_end; for (boost::tie(vi, vi_end) = vertices(g); vi != vi_end; /* in loop */) { typename graph_traits::vertex_descriptor v = *vi++; if (out_degree(v, g) == 0) { clear_vertex(v, g); remove_vertex(v, g); } } } while (num_vertices(g) < old_n); } } } // end namespace boost::graph #ifdef BOOST_GRAPH_USE_MPI # include #endif #endif // BOOST_GRAPH_PAGE_RANK_HPP