//======================================================================= // Copyright (c) Aaron Windsor 2007 // // 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 __CHROBAK_PAYNE_DRAWING_HPP__ #define __CHROBAK_PAYNE_DRAWING_HPP__ #include #include #include #include #include #include namespace boost { namespace graph { namespace detail { template < typename Graph, typename VertexToVertexMap, typename VertexTo1DCoordMap > void accumulate_offsets( typename graph_traits< Graph >::vertex_descriptor v, std::size_t offset, const Graph& g, VertexTo1DCoordMap x, VertexTo1DCoordMap delta_x, VertexToVertexMap left, VertexToVertexMap right) { typedef typename graph_traits< Graph >::vertex_descriptor vertex_descriptor; // Suggestion of explicit stack from Aaron Windsor to avoid system // stack overflows. typedef std::pair< vertex_descriptor, std::size_t > stack_entry; std::stack< stack_entry > st; st.push(stack_entry(v, offset)); while (!st.empty()) { vertex_descriptor v = st.top().first; std::size_t offset = st.top().second; st.pop(); if (v != graph_traits< Graph >::null_vertex()) { x[v] += delta_x[v] + offset; st.push(stack_entry(left[v], x[v])); st.push(stack_entry(right[v], x[v])); } } } } /*namespace detail*/ } /*namespace graph*/ template < typename Graph, typename PlanarEmbedding, typename ForwardIterator, typename GridPositionMap, typename VertexIndexMap > void chrobak_payne_straight_line_drawing(const Graph& g, PlanarEmbedding embedding, ForwardIterator ordering_begin, ForwardIterator ordering_end, GridPositionMap drawing, VertexIndexMap vm) { typedef typename graph_traits< Graph >::vertex_descriptor vertex_t; typedef typename graph_traits< Graph >::vertex_iterator vertex_iterator_t; typedef typename PlanarEmbedding::value_type::const_iterator edge_permutation_iterator_t; typedef typename graph_traits< Graph >::vertices_size_type v_size_t; typedef std::vector< vertex_t > vertex_vector_t; typedef std::vector< v_size_t > vsize_vector_t; typedef std::vector< bool > bool_vector_t; typedef boost::iterator_property_map< typename vertex_vector_t::iterator, VertexIndexMap > vertex_to_vertex_map_t; typedef boost::iterator_property_map< typename vsize_vector_t::iterator, VertexIndexMap > vertex_to_vsize_map_t; typedef boost::iterator_property_map< typename bool_vector_t::iterator, VertexIndexMap > vertex_to_bool_map_t; vertex_vector_t left_vector( num_vertices(g), graph_traits< Graph >::null_vertex()); vertex_vector_t right_vector( num_vertices(g), graph_traits< Graph >::null_vertex()); vsize_vector_t seen_as_right_vector(num_vertices(g), 0); vsize_vector_t seen_vector(num_vertices(g), 0); vsize_vector_t delta_x_vector(num_vertices(g), 0); vsize_vector_t y_vector(num_vertices(g)); vsize_vector_t x_vector(num_vertices(g), 0); bool_vector_t installed_vector(num_vertices(g), false); vertex_to_vertex_map_t left(left_vector.begin(), vm); vertex_to_vertex_map_t right(right_vector.begin(), vm); vertex_to_vsize_map_t seen_as_right(seen_as_right_vector.begin(), vm); vertex_to_vsize_map_t seen(seen_vector.begin(), vm); vertex_to_vsize_map_t delta_x(delta_x_vector.begin(), vm); vertex_to_vsize_map_t y(y_vector.begin(), vm); vertex_to_vsize_map_t x(x_vector.begin(), vm); vertex_to_bool_map_t installed(installed_vector.begin(), vm); v_size_t timestamp = 1; vertex_vector_t installed_neighbors; ForwardIterator itr = ordering_begin; vertex_t v1 = *itr; ++itr; vertex_t v2 = *itr; ++itr; vertex_t v3 = *itr; ++itr; delta_x[v2] = 1; delta_x[v3] = 1; y[v1] = 0; y[v2] = 0; y[v3] = 1; right[v1] = v3; right[v3] = v2; installed[v1] = installed[v2] = installed[v3] = true; for (ForwardIterator itr_end = ordering_end; itr != itr_end; ++itr) { vertex_t v = *itr; // First, find the leftmost and rightmost neighbor of v on the outer // cycle of the embedding. // Note: since we're moving clockwise through the edges adjacent to v, // we're actually moving from right to left among v's neighbors on the // outer face (since v will be installed above them all) looking for // the leftmost and rightmost installed neigbhors vertex_t leftmost = graph_traits< Graph >::null_vertex(); vertex_t rightmost = graph_traits< Graph >::null_vertex(); installed_neighbors.clear(); vertex_t prev_vertex = graph_traits< Graph >::null_vertex(); edge_permutation_iterator_t pi, pi_end; pi_end = embedding[v].end(); for (pi = embedding[v].begin(); pi != pi_end; ++pi) { vertex_t curr_vertex = source(*pi, g) == v ? target(*pi, g) : source(*pi, g); // Skip any self-loops or parallel edges if (curr_vertex == v || curr_vertex == prev_vertex) continue; if (installed[curr_vertex]) { seen[curr_vertex] = timestamp; if (right[curr_vertex] != graph_traits< Graph >::null_vertex()) { seen_as_right[right[curr_vertex]] = timestamp; } installed_neighbors.push_back(curr_vertex); } prev_vertex = curr_vertex; } typename vertex_vector_t::iterator vi, vi_end; vi_end = installed_neighbors.end(); for (vi = installed_neighbors.begin(); vi != vi_end; ++vi) { if (right[*vi] == graph_traits< Graph >::null_vertex() || seen[right[*vi]] != timestamp) rightmost = *vi; if (seen_as_right[*vi] != timestamp) leftmost = *vi; } ++timestamp; // stretch gaps ++delta_x[right[leftmost]]; ++delta_x[rightmost]; // adjust offsets std::size_t delta_p_q = 0; vertex_t stopping_vertex = right[rightmost]; for (vertex_t temp = right[leftmost]; temp != stopping_vertex; temp = right[temp]) { delta_p_q += delta_x[temp]; } delta_x[v] = ((y[rightmost] + delta_p_q) - y[leftmost]) / 2; y[v] = y[leftmost] + delta_x[v]; delta_x[rightmost] = delta_p_q - delta_x[v]; bool leftmost_and_rightmost_adjacent = right[leftmost] == rightmost; if (!leftmost_and_rightmost_adjacent) delta_x[right[leftmost]] -= delta_x[v]; // install v if (!leftmost_and_rightmost_adjacent) { left[v] = right[leftmost]; vertex_t next_to_rightmost; for (vertex_t temp = leftmost; temp != rightmost; temp = right[temp]) { next_to_rightmost = temp; } right[next_to_rightmost] = graph_traits< Graph >::null_vertex(); } else { left[v] = graph_traits< Graph >::null_vertex(); } right[leftmost] = v; right[v] = rightmost; installed[v] = true; } graph::detail::accumulate_offsets( *ordering_begin, 0, g, x, delta_x, left, right); vertex_iterator_t vi, vi_end; for (boost::tie(vi, vi_end) = vertices(g); vi != vi_end; ++vi) { vertex_t v(*vi); drawing[v].x = x[v]; drawing[v].y = y[v]; } } template < typename Graph, typename PlanarEmbedding, typename ForwardIterator, typename GridPositionMap > inline void chrobak_payne_straight_line_drawing(const Graph& g, PlanarEmbedding embedding, ForwardIterator ord_begin, ForwardIterator ord_end, GridPositionMap drawing) { chrobak_payne_straight_line_drawing( g, embedding, ord_begin, ord_end, drawing, get(vertex_index, g)); } } // namespace boost #endif //__CHROBAK_PAYNE_DRAWING_HPP__