void evaluateGeodesicDist(GridSpecs grid_specs, std::vector<Polygon_2> polygons, std::vector<Point> ref_points, IOSpecs io_specs) { // -- grid definition -- // no. of rows and columns int no_rows, no_cols; no_rows = (int)grid_specs.getGridSpecs().at(0); no_cols = (int)grid_specs.getGridSpecs().at(1); // grid points int no_gpoints; no_gpoints = (no_rows*no_cols); // spatial locations of the grid points std::vector<Point_2> grid_points; // evaluating the spatial locations of the grid points initGrid(grid_specs, grid_points); //-- // -- graph definition -- // // note that two different graphs need to be considered: // // 1) effective graph - // graph associated with the complementary domain; // the nodes of this graph do not include the grid points // associated with the polygon(s); // // 2) BGL graph - // graph processed by the BGL library; // this graph coincides with the grid; // the nodes of this graph coincide the grid points; // the nodes associated with the polygon(s) are nodes // with no edges, i.e. they are nodes of degree zero; // // // no. of nodes (effective graph) < no. of nodes (BGL graph) // no. of edges (effective graph) = no. of edges (BGL graph) // // grid points IDs associated with the polygon(s) std::vector<Polygon_gp_id> gpoints_id_pgn; // grid points IDs associated with the graph std::vector<int> gpoints_id_graph; // project the data to the grid; // evaluate the grid points IDs associated with the polygon(s) and // those associated with the complementary domain (graph) projectDataToGrid(grid_points, polygons, gpoints_id_pgn, gpoints_id_graph); // no. of grid points associated with the polygon int no_gpoints_png = gpoints_id_pgn.at(0).size(); // no. of grid points associated with the graph int no_gpoints_graph = gpoints_id_graph.size(); // writing output file `Dreses.dat' std::string outfile_name_1("Dreses.dat"); OutputProcess_Dreses out1(io_specs.getAbsolutePathName(outfile_name_1)); out1.toOutput(ref_points, polygons, grid_specs, no_gpoints_png, no_gpoints_graph); grid_points.clear(); polygons.clear(); // names of the nodes (vertices) std::vector<std::string> node_names; // edges std::vector<Edge> edges; // evaluating the node names and the edges of the `effective graph' initGraph(grid_specs, gpoints_id_pgn, gpoints_id_graph, node_names, edges); gpoints_id_pgn.clear(); gpoints_id_graph.clear(); // number of edges int no_edges; no_edges = edges.size(); // weights float* weights = new float[no_edges]; for (int i=0; i<no_edges; i++) { weights[i] = grid_specs.getGridSpecs().at(2); } // BGL graph GridGraph g(edges.begin(), edges.end(), weights, no_gpoints); GridGraph g_copy(edges.begin(), edges.end(), weights, no_gpoints); //-- #ifdef DEBUG_GRAPH std::cout << "\n>> debug - graph" << std::endl; std::cout << "no. of nodes (effective graph): " << node_names.size() << std::endl; std::cout << "no. of nodes (BGL graph): " << no_gpoints << std::endl; std::cout << "no. of edges: " << edges.size() << std::endl; write_graphviz(std::cout, g); #endif // DEBUG_GRAPH //-- // parents of the nodes std::vector<vertex_descriptor> parents(num_vertices(g)); // source node ID // note that node ID = (grid point ID - 1) int s_node_id; s_node_id = (getGridPointID(ref_points.at(0).first, ref_points.at(0).second, grid_specs) - 1); // source node vertex_descriptor s_node = vertex(s_node_id, g); // the parent of `s_node' is `s_node' (distance = 0) parents[s_node] = s_node; // distances from the source to each node // (including the null distances - i.e. the distance from the source to itself // and the distances from the source to the nodes of degree zero) vertices_size_type distances[no_gpoints]; std::fill_n(distances, no_gpoints, 0); // evaluating the distances by using the Breadth-First Search (BFS) algorithm breadth_first_search(g, s_node, visitor(make_bfs_visitor(std::make_pair(record_distances(distances, on_tree_edge()), std::make_pair(record_predecessors(&parents[0], on_tree_edge()), copy_graph(g_copy, on_examine_edge()) ) ) ) ) ); // writing output file `distances.dat' std::string outfile_name_2("distances.dat"); OutputProcess_Distances out2(io_specs.getAbsolutePathName(outfile_name_2)); out2.toOutput(grid_specs, no_gpoints, s_node_id, node_names, distances); delete [] weights; }
void filesystem::g_copy_timeout(const char * p_src,const char * p_dst,double p_timeout,abort_callback & p_abort) { FB2K_RETRY_ON_SHARING_VIOLATION( g_copy(p_src, p_dst, p_abort), p_abort, p_timeout ); }