boost/polygon/detail/voronoi_structures.hpp
// Boost.Polygon library detail/voronoi_structures.hpp header file // Copyright Andrii Sydorchuk 2010-2012. // 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) // See http://www.boost.org for updates, documentation, and revision history. #ifndef BOOST_POLYGON_DETAIL_VORONOI_STRUCTURES #define BOOST_POLYGON_DETAIL_VORONOI_STRUCTURES #include <list> #include <queue> #include <vector> #include "boost/polygon/voronoi_geometry_type.hpp" namespace boost { namespace polygon { namespace detail { // Cartesian 2D point data structure. template <typename T> class point_2d { public: typedef T coordinate_type; point_2d() {} point_2d(coordinate_type x, coordinate_type y) : x_(x), y_(y) {} bool operator==(const point_2d& that) const { return (this->x_ == that.x()) && (this->y_ == that.y()); } bool operator!=(const point_2d& that) const { return (this->x_ != that.x()) || (this->y_ != that.y()); } coordinate_type x() const { return x_; } coordinate_type y() const { return y_; } point_2d& x(coordinate_type x) { x_ = x; return *this; } point_2d& y(coordinate_type y) { y_ = y; return *this; } private: coordinate_type x_; coordinate_type y_; }; // Site event type. // Occurs when the sweepline sweeps over one of the initial sites: // 1) point site // 2) start-point of the segment site // 3) endpoint of the segment site // Implicit segment direction is defined: the start-point of // the segment compares less than its endpoint. // Each input segment is divided onto two site events: // 1) One going from the start-point to the endpoint // (is_inverse() = false) // 2) Another going from the endpoint to the start-point // (is_inverse() = true) // In beach line data structure segment sites of the first // type precede sites of the second type for the same segment. // Members: // point0_ - point site or segment's start-point // point1_ - segment's endpoint if site is a segment // sorted_index_ - the last bit encodes information if the site is inverse; // the other bits encode site event index among the sorted site events // initial_index_ - site index among the initial input set // Note: for all sites is_inverse_ flag is equal to false by default. template <typename T> class site_event { public: typedef T coordinate_type; typedef point_2d<T> point_type; site_event() : point0_(0, 0), point1_(0, 0), sorted_index_(0), flags_(0) {} site_event(coordinate_type x, coordinate_type y) : point0_(x, y), point1_(x, y), sorted_index_(0), flags_(0) {} explicit site_event(const point_type& point) : point0_(point), point1_(point), sorted_index_(0), flags_(0) {} site_event(coordinate_type x1, coordinate_type y1, coordinate_type x2, coordinate_type y2): point0_(x1, y1), point1_(x2, y2), sorted_index_(0), flags_(0) {} site_event(const point_type& point1, const point_type& point2) : point0_(point1), point1_(point2), sorted_index_(0), flags_(0) {} bool operator==(const site_event& that) const { return (this->point0_ == that.point0_) && (this->point1_ == that.point1_); } bool operator!=(const site_event& that) const { return (this->point0_ != that.point0_) || (this->point1_ != that.point1_); } coordinate_type x() const { return point0_.x(); } coordinate_type y() const { return point0_.y(); } coordinate_type x0() const { return point0_.x(); } coordinate_type y0() const { return point0_.y(); } coordinate_type x1() const { return point1_.x(); } coordinate_type y1() const { return point1_.y(); } const point_type& point0() const { return point0_; } const point_type& point1() const { return point1_; } std::size_t sorted_index() const { return sorted_index_; } site_event& sorted_index(std::size_t index) { sorted_index_ = index; return *this; } std::size_t initial_index() const { return initial_index_; } site_event& initial_index(std::size_t index) { initial_index_ = index; return *this; } bool is_inverse() const { return (flags_ & IS_INVERSE) ? true : false; } site_event& inverse() { std::swap(point0_, point1_); flags_ ^= IS_INVERSE; return *this; } SourceCategory source_category() const { return static_cast<SourceCategory>(flags_ & SOURCE_CATEGORY_BITMASK); } site_event& source_category(SourceCategory source_category) { flags_ |= source_category; return *this; } bool is_point() const { return (point0_.x() == point1_.x()) && (point0_.y() == point1_.y()); } bool is_segment() const { return (point0_.x() != point1_.x()) || (point0_.y() != point1_.y()); } private: enum Bits { IS_INVERSE = 0x20 // 32 }; point_type point0_; point_type point1_; std::size_t sorted_index_; std::size_t initial_index_; std::size_t flags_; }; // Circle event type. // Occurs when the sweepline sweeps over the rightmost point of the Voronoi // circle (with the center at the intersection point of the bisectors). // Circle event is made of the two consecutive nodes in the beach line data // structure. In case another node was inserted during algorithm execution // between the given two nodes circle event becomes inactive. // Variables: // center_x_ - center x-coordinate; // center_y_ - center y-coordinate; // lower_x_ - leftmost x-coordinate; // is_active_ - states whether circle event is still active. // NOTE: lower_y coordinate is always equal to center_y. template <typename T> class circle_event { public: typedef T coordinate_type; circle_event() : is_active_(true) {} circle_event(coordinate_type c_x, coordinate_type c_y, coordinate_type lower_x) : center_x_(c_x), center_y_(c_y), lower_x_(lower_x), is_active_(true) {} coordinate_type x() const { return center_x_; } circle_event& x(coordinate_type center_x) { center_x_ = center_x; return *this; } coordinate_type y() const { return center_y_; } circle_event& y(coordinate_type center_y) { center_y_ = center_y; return *this; } coordinate_type lower_x() const { return lower_x_; } circle_event& lower_x(coordinate_type lower_x) { lower_x_ = lower_x; return *this; } coordinate_type lower_y() const { return center_y_; } bool is_active() const { return is_active_; } circle_event& deactivate() { is_active_ = false; return *this; } private: coordinate_type center_x_; coordinate_type center_y_; coordinate_type lower_x_; bool is_active_; }; // Event queue data structure, holds circle events. // During algorithm run, some of the circle events disappear (become // inactive). Priority queue data structure doesn't support // iterators (there is no direct ability to modify its elements). // Instead list is used to store all the circle events and priority queue // of the iterators to the list elements is used to keep the correct circle // events ordering. template <typename T, typename Predicate> class ordered_queue { public: ordered_queue() {} bool empty() const { return c_.empty(); } const T &top() const { return *c_.top(); } void pop() { list_iterator_type it = c_.top(); c_.pop(); c_list_.erase(it); } T &push(const T &e) { c_list_.push_front(e); c_.push(c_list_.begin()); return c_list_.front(); } void clear() { while (!c_.empty()) c_.pop(); c_list_.clear(); } private: typedef typename std::list<T>::iterator list_iterator_type; struct comparison { bool operator() (const list_iterator_type &it1, const list_iterator_type &it2) const { return cmp_(*it1, *it2); } Predicate cmp_; }; std::priority_queue< list_iterator_type, std::vector<list_iterator_type>, comparison > c_; std::list<T> c_list_; // Disallow copy constructor and operator= ordered_queue(const ordered_queue&); void operator=(const ordered_queue&); }; // Represents a bisector node made by two arcs that correspond to the left // and right sites. Arc is defined as a curve with points equidistant from // the site and from the sweepline. If the site is a point then arc is // a parabola, otherwise it's a line segment. A segment site event will // produce different bisectors based on its direction. // In general case two sites will create two opposite bisectors. That's // why the order of the sites is important to define the unique bisector. // The one site is considered to be newer than the other one if it was // processed by the algorithm later (has greater index). template <typename Site> class beach_line_node_key { public: typedef Site site_type; // Constructs degenerate bisector, used to search an arc that is above // the given site. The input to the constructor is the new site point. explicit beach_line_node_key(const site_type &new_site) : left_site_(new_site), right_site_(new_site) {} // Constructs a new bisector. The input to the constructor is the two // sites that create the bisector. The order of sites is important. beach_line_node_key(const site_type &left_site, const site_type &right_site) : left_site_(left_site), right_site_(right_site) {} const site_type &left_site() const { return left_site_; } site_type &left_site() { return left_site_; } beach_line_node_key& left_site(const site_type &site) { left_site_ = site; return *this; } const site_type &right_site() const { return right_site_; } site_type &right_site() { return right_site_; } beach_line_node_key& right_site(const site_type &site) { right_site_ = site; return *this; } private: site_type left_site_; site_type right_site_; }; // Represents edge data structure from the Voronoi output, that is // associated as a value with beach line bisector in the beach // line. Contains pointer to the circle event in the circle event // queue if the edge corresponds to the right bisector of the circle event. template <typename Edge, typename Circle> class beach_line_node_data { public: explicit beach_line_node_data(Edge* new_edge) : circle_event_(NULL), edge_(new_edge) {} Circle* circle_event() const { return circle_event_; } beach_line_node_data& circle_event(Circle* circle_event) { circle_event_ = circle_event; return *this; } Edge* edge() const { return edge_; } beach_line_node_data& edge(Edge* new_edge) { edge_ = new_edge; return *this; } private: Circle* circle_event_; Edge* edge_; }; } // detail } // polygon } // boost #endif // BOOST_POLYGON_DETAIL_VORONOI_STRUCTURES