boost/graph/planar_detail/face_iterators.hpp
//======================================================================= // 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 __FACE_ITERATORS_HPP__ #define __FACE_ITERATORS_HPP__ #include <boost/iterator/iterator_facade.hpp> #include <boost/mpl/bool.hpp> #include <boost/graph/graph_traits.hpp> namespace boost { // tags for defining traversal properties // VisitorType struct lead_visitor { }; struct follow_visitor { }; // TraversalType struct single_side { }; struct both_sides { }; // TraversalSubType struct first_side { }; // for single_side struct second_side { }; // for single_side struct alternating { }; // for both_sides // Time struct current_iteration { }; struct previous_iteration { }; // Why TraversalType AND TraversalSubType? TraversalSubType is a function // template parameter passed in to the constructor of the face iterator, // whereas TraversalType is a class template parameter. This lets us decide // at runtime whether to move along the first or second side of a bicomp (by // assigning a face_iterator that has been constructed with TraversalSubType // = first_side or second_side to a face_iterator variable) without any of // the virtual function overhead that comes with implementing this // functionality as a more structured form of type erasure. It also allows // a single face_iterator to be the end iterator of two iterators traversing // both sides of a bicomp. // ValueType is either graph_traits<Graph>::vertex_descriptor // or graph_traits<Graph>::edge_descriptor // forward declaration (defining defaults) template < typename Graph, typename FaceHandlesMap, typename ValueType, typename BicompSideToTraverse = single_side, typename VisitorType = lead_visitor, typename Time = current_iteration > class face_iterator; template < typename Graph, bool StoreEdge > struct edge_storage { }; template < typename Graph > struct edge_storage< Graph, true > { typename graph_traits< Graph >::edge_descriptor value; }; // specialization for TraversalType = traverse_vertices template < typename Graph, typename FaceHandlesMap, typename ValueType, typename TraversalType, typename VisitorType, typename Time > class face_iterator : public boost::iterator_facade< face_iterator< Graph, FaceHandlesMap, ValueType, TraversalType, VisitorType, Time >, ValueType, boost::forward_traversal_tag, ValueType > { public: typedef typename graph_traits< Graph >::vertex_descriptor vertex_t; typedef typename graph_traits< Graph >::edge_descriptor edge_t; typedef face_iterator< Graph, FaceHandlesMap, ValueType, TraversalType, VisitorType, Time > self; typedef typename FaceHandlesMap::value_type face_handle_t; face_iterator() : m_lead(graph_traits< Graph >::null_vertex()) , m_follow(graph_traits< Graph >::null_vertex()) { } template < typename TraversalSubType > face_iterator(face_handle_t anchor_handle, FaceHandlesMap face_handles, TraversalSubType traversal_type) : m_follow(anchor_handle.get_anchor()), m_face_handles(face_handles) { set_lead_dispatch(anchor_handle, traversal_type); } template < typename TraversalSubType > face_iterator(vertex_t anchor, FaceHandlesMap face_handles, TraversalSubType traversal_type) : m_follow(anchor), m_face_handles(face_handles) { set_lead_dispatch(m_face_handles[anchor], traversal_type); } private: friend class boost::iterator_core_access; inline vertex_t get_first_vertex( face_handle_t anchor_handle, current_iteration) { return anchor_handle.first_vertex(); } inline vertex_t get_second_vertex( face_handle_t anchor_handle, current_iteration) { return anchor_handle.second_vertex(); } inline vertex_t get_first_vertex( face_handle_t anchor_handle, previous_iteration) { return anchor_handle.old_first_vertex(); } inline vertex_t get_second_vertex( face_handle_t anchor_handle, previous_iteration) { return anchor_handle.old_second_vertex(); } inline void set_lead_dispatch(face_handle_t anchor_handle, first_side) { m_lead = get_first_vertex(anchor_handle, Time()); set_edge_to_first_dispatch(anchor_handle, ValueType(), Time()); } inline void set_lead_dispatch(face_handle_t anchor_handle, second_side) { m_lead = get_second_vertex(anchor_handle, Time()); set_edge_to_second_dispatch(anchor_handle, ValueType(), Time()); } inline void set_edge_to_first_dispatch( face_handle_t anchor_handle, edge_t, current_iteration) { m_edge.value = anchor_handle.first_edge(); } inline void set_edge_to_second_dispatch( face_handle_t anchor_handle, edge_t, current_iteration) { m_edge.value = anchor_handle.second_edge(); } inline void set_edge_to_first_dispatch( face_handle_t anchor_handle, edge_t, previous_iteration) { m_edge.value = anchor_handle.old_first_edge(); } inline void set_edge_to_second_dispatch( face_handle_t anchor_handle, edge_t, previous_iteration) { m_edge.value = anchor_handle.old_second_edge(); } template < typename T > inline void set_edge_to_first_dispatch(face_handle_t, vertex_t, T) { } template < typename T > inline void set_edge_to_second_dispatch(face_handle_t, vertex_t, T) { } void increment() { face_handle_t curr_face_handle(m_face_handles[m_lead]); vertex_t first = get_first_vertex(curr_face_handle, Time()); vertex_t second = get_second_vertex(curr_face_handle, Time()); if (first == m_follow) { m_follow = m_lead; set_edge_to_second_dispatch(curr_face_handle, ValueType(), Time()); m_lead = second; } else if (second == m_follow) { m_follow = m_lead; set_edge_to_first_dispatch(curr_face_handle, ValueType(), Time()); m_lead = first; } else m_lead = m_follow = graph_traits< Graph >::null_vertex(); } bool equal(self const& other) const { return m_lead == other.m_lead && m_follow == other.m_follow; } ValueType dereference() const { return dereference_dispatch(VisitorType(), ValueType()); } inline ValueType dereference_dispatch(lead_visitor, vertex_t) const { return m_lead; } inline ValueType dereference_dispatch(follow_visitor, vertex_t) const { return m_follow; } inline ValueType dereference_dispatch(lead_visitor, edge_t) const { return m_edge.value; } inline ValueType dereference_dispatch(follow_visitor, edge_t) const { return m_edge.value; } vertex_t m_lead; vertex_t m_follow; edge_storage< Graph, boost::is_same< ValueType, edge_t >::value > m_edge; FaceHandlesMap m_face_handles; }; template < typename Graph, typename FaceHandlesMap, typename ValueType, typename VisitorType, typename Time > class face_iterator< Graph, FaceHandlesMap, ValueType, both_sides, VisitorType, Time > : public boost::iterator_facade< face_iterator< Graph, FaceHandlesMap, ValueType, both_sides, VisitorType, Time >, ValueType, boost::forward_traversal_tag, ValueType > { public: typedef face_iterator< Graph, FaceHandlesMap, ValueType, both_sides, VisitorType, Time > self; typedef typename graph_traits< Graph >::vertex_descriptor vertex_t; typedef typename FaceHandlesMap::value_type face_handle_t; face_iterator() {} face_iterator(face_handle_t anchor_handle, FaceHandlesMap face_handles) : first_itr(anchor_handle, face_handles, first_side()) , second_itr(anchor_handle, face_handles, second_side()) , first_is_active(true) , first_increment(true) { } face_iterator(vertex_t anchor, FaceHandlesMap face_handles) : first_itr(face_handles[anchor], face_handles, first_side()) , second_itr(face_handles[anchor], face_handles, second_side()) , first_is_active(true) , first_increment(true) { } private: friend class boost::iterator_core_access; typedef face_iterator< Graph, FaceHandlesMap, ValueType, single_side, follow_visitor, Time > inner_itr_t; void increment() { if (first_increment) { ++first_itr; ++second_itr; first_increment = false; } else if (first_is_active) ++first_itr; else ++second_itr; first_is_active = !first_is_active; } bool equal(self const& other) const { // Want this iterator to be equal to the "end" iterator when at least // one of the iterators has reached the root of the current bicomp. // This isn't ideal, but it works. return (first_itr == other.first_itr || second_itr == other.second_itr); } ValueType dereference() const { return first_is_active ? *first_itr : *second_itr; } inner_itr_t first_itr; inner_itr_t second_itr; inner_itr_t face_end; bool first_is_active; bool first_increment; }; } /* namespace boost */ #endif //__FACE_ITERATORS_HPP__