// //======================================================================= // Copyright 2002 Marc Wintermantel (wintermantel@imes.mavt.ethz.ch) // ETH Zurich, Center of Structure Technologies (www.imes.ethz.ch/st) // // 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) //======================================================================= // #include #include #include #include #include #include #include #include #include using std::cout; using std::endl; /* Sample Output ##################################### ### First light of sloan-ordering ### ##################################### original bandwidth: 8 original profile: 42 original max_wavefront: 7 original aver_wavefront: 4.2 original rms_wavefront: 4.58258 Starting vertex: 0 Pseudoperipheral vertex: 9 Pseudoperipheral radius: 4 Sloan ordering starting at: 0 0 8 3 7 5 2 4 6 1 9 bandwidth: 4 profile: 28 max_wavefront: 4 aver_wavefront: 2.8 rms_wavefront: 2.93258 Sloan ordering without a start-vertex: 8 0 3 7 5 2 4 6 1 9 bandwidth: 4 profile: 27 max_wavefront: 4 aver_wavefront: 2.7 rms_wavefront: 2.84605 ############################### ### sloan-ordering finished ### ############################### */ int main(int , char* []) { cout << endl; cout << "#####################################" << endl; cout << "### First light of sloan-ordering ###" << endl; cout << "#####################################" << endl << endl; using namespace boost; using namespace std; //Defining the graph type typedef adjacency_list< setS, vecS, undirectedS, property< vertex_color_t, default_color_type, property< vertex_degree_t, int, property< vertex_priority_t, double > > > > Graph; typedef graph_traits::vertex_descriptor Vertex; typedef graph_traits::vertices_size_type size_type; typedef std::pair Pair; Pair edges[14] = { Pair(0,3), //a-d Pair(0,5), //a-f Pair(1,2), //b-c Pair(1,4), //b-e Pair(1,6), //b-g Pair(1,9), //b-j Pair(2,3), //c-d Pair(2,4), //c-e Pair(3,5), //d-f Pair(3,8), //d-i Pair(4,6), //e-g Pair(5,6), //f-g Pair(5,7), //f-h Pair(6,7) }; //g-h //Creating a graph and adding the edges from above into it Graph G(10); for (int i = 0; i < 14; ++i) add_edge(edges[i].first, edges[i].second, G); //Creating two iterators over the vertices graph_traits::vertex_iterator ui, ui_end; //Creating a property_map with the degrees of the degrees of each vertex property_map::type deg = get(vertex_degree, G); for (boost::tie(ui, ui_end) = vertices(G); ui != ui_end; ++ui) deg[*ui] = degree(*ui, G); //Creating a property_map for the indices of a vertex property_map::type index_map = get(vertex_index, G); std::cout << "original bandwidth: " << bandwidth(G) << std::endl; std::cout << "original profile: " << profile(G) << std::endl; std::cout << "original max_wavefront: " << max_wavefront(G) << std::endl; std::cout << "original aver_wavefront: " << aver_wavefront(G) << std::endl; std::cout << "original rms_wavefront: " << rms_wavefront(G) << std::endl; //Creating a vector of vertices std::vector sloan_order(num_vertices(G)); //Creating a vector of size_type std::vector perm(num_vertices(G)); { //Setting the start node Vertex s = vertex(0, G); int ecc; //defining a variable for the pseudoperipheral radius //Calculating the pseudoeperipheral node and radius Vertex e = pseudo_peripheral_pair(G, s, ecc, get(vertex_color, G), get(vertex_degree, G) ); cout << endl; cout << "Starting vertex: " << s << endl; cout << "Pseudoperipheral vertex: " << e << endl; cout << "Pseudoperipheral radius: " << ecc << endl << endl; //Sloan ordering sloan_ordering(G, s, e, sloan_order.begin(), get(vertex_color, G), get(vertex_degree, G), get(vertex_priority, G)); cout << "Sloan ordering starting at: " << s << endl; cout << " "; for (std::vector::const_iterator i = sloan_order.begin(); i != sloan_order.end(); ++i) cout << index_map[*i] << " "; cout << endl; for (size_type c = 0; c != sloan_order.size(); ++c) perm[index_map[sloan_order[c]]] = c; std::cout << " bandwidth: " << bandwidth(G, make_iterator_property_map(&perm[0], index_map, perm[0])) << std::endl; std::cout << " profile: " << profile(G, make_iterator_property_map(&perm[0], index_map, perm[0])) << std::endl; std::cout << " max_wavefront: " << max_wavefront(G, make_iterator_property_map(&perm[0], index_map, perm[0])) << std::endl; std::cout << " aver_wavefront: " << aver_wavefront(G, make_iterator_property_map(&perm[0], index_map, perm[0])) << std::endl; std::cout << " rms_wavefront: " << rms_wavefront(G, make_iterator_property_map(&perm[0], index_map, perm[0])) << std::endl; } ///////////////////////////////////////////////// //Version including finding a good starting point ///////////////////////////////////////////////// { //sloan_ordering sloan_ordering(G, sloan_order.begin(), get(vertex_color, G), make_degree_map(G), get(vertex_priority, G) ); cout << endl << "Sloan ordering without a start-vertex:" << endl; cout << " "; for (std::vector::const_iterator i=sloan_order.begin(); i != sloan_order.end(); ++i) cout << index_map[*i] << " "; cout << endl; for (size_type c = 0; c != sloan_order.size(); ++c) perm[index_map[sloan_order[c]]] = c; std::cout << " bandwidth: " << bandwidth(G, make_iterator_property_map(&perm[0], index_map, perm[0])) << std::endl; std::cout << " profile: " << profile(G, make_iterator_property_map(&perm[0], index_map, perm[0])) << std::endl; std::cout << " max_wavefront: " << max_wavefront(G, make_iterator_property_map(&perm[0], index_map, perm[0])) << std::endl; std::cout << " aver_wavefront: " << aver_wavefront(G, make_iterator_property_map(&perm[0], index_map, perm[0])) << std::endl; std::cout << " rms_wavefront: " << rms_wavefront(G, make_iterator_property_map(&perm[0], index_map, perm[0])) << std::endl; } cout << endl; cout << "###############################" << endl; cout << "### sloan-ordering finished ###" << endl; cout << "###############################" << endl << endl; return 0; }