#ifndef slic3r_ExPolygon_hpp_ #define slic3r_ExPolygon_hpp_ #include "libslic3r.h" #include "Polygon.hpp" #include "Polyline.hpp" #include namespace Slic3r { class ExPolygon; typedef std::vector ExPolygons; class ExPolygon { public: ExPolygon() = default; ExPolygon(const ExPolygon &other) = default; ExPolygon(ExPolygon &&other) = default; explicit ExPolygon(const Polygon &contour) : contour(contour) {} explicit ExPolygon(Polygon &&contour) : contour(std::move(contour)) {} explicit ExPolygon(const Points &contour) : contour(contour) {} explicit ExPolygon(Points &&contour) : contour(std::move(contour)) {} explicit ExPolygon(const Polygon &contour, const Polygon &hole) : contour(contour) { holes.emplace_back(hole); } explicit ExPolygon(Polygon &&contour, Polygon &&hole) : contour(std::move(contour)) { holes.emplace_back(std::move(hole)); } explicit ExPolygon(const Points &contour, const Points &hole) : contour(contour) { holes.emplace_back(hole); } explicit ExPolygon(Points &&contour, Polygon &&hole) : contour(std::move(contour)) { holes.emplace_back(std::move(hole)); } ExPolygon(std::initializer_list contour) : contour(contour) {} ExPolygon(std::initializer_list contour, std::initializer_list hole) : contour(contour), holes({ hole }) {} ExPolygon& operator=(const ExPolygon &other) = default; ExPolygon& operator=(ExPolygon &&other) = default; Polygon contour; Polygons holes; operator Points() const; operator Polygons() const; operator Polylines() const; void clear() { contour.points.clear(); holes.clear(); } void scale(double factor); void translate(double x, double y) { this->translate(Point(coord_t(x), coord_t(y))); } void translate(const Point &vector); void rotate(double angle); void rotate(double angle, const Point ¢er); double area() const; bool empty() const { return contour.points.empty(); } bool is_valid() const; void douglas_peucker(double tolerance); // Contains the line / polyline / polylines etc COMPLETELY. bool contains(const Line &line) const; bool contains(const Polyline &polyline) const; bool contains(const Polylines &polylines) const; bool contains(const Point &point) const; bool contains_b(const Point &point) const; bool has_boundary_point(const Point &point) const; // Does this expolygon overlap another expolygon? // Either the ExPolygons intersect, or one is fully inside the other, // and it is not inside a hole of the other expolygon. bool overlaps(const ExPolygon &other) const; void simplify_p(double tolerance, Polygons* polygons) const; Polygons simplify_p(double tolerance) const; ExPolygons simplify(double tolerance) const; void simplify(double tolerance, ExPolygons* expolygons) const; void medial_axis(double max_width, double min_width, ThickPolylines* polylines) const; void medial_axis(double max_width, double min_width, Polylines* polylines) const; Lines lines() const; // Number of contours (outer contour with holes). size_t num_contours() const { return this->holes.size() + 1; } Polygon& contour_or_hole(size_t idx) { return (idx == 0) ? this->contour : this->holes[idx - 1]; } const Polygon& contour_or_hole(size_t idx) const { return (idx == 0) ? this->contour : this->holes[idx - 1]; } }; inline bool operator==(const ExPolygon &lhs, const ExPolygon &rhs) { return lhs.contour == rhs.contour && lhs.holes == rhs.holes; } inline bool operator!=(const ExPolygon &lhs, const ExPolygon &rhs) { return lhs.contour != rhs.contour || lhs.holes != rhs.holes; } // Count a nuber of polygons stored inside the vector of expolygons. // Useful for allocating space for polygons when converting expolygons to polygons. inline size_t number_polygons(const ExPolygons &expolys) { size_t n_polygons = 0; for (ExPolygons::const_iterator it = expolys.begin(); it != expolys.end(); ++ it) n_polygons += it->holes.size() + 1; return n_polygons; } inline Lines to_lines(const ExPolygon &src) { size_t n_lines = src.contour.points.size(); for (size_t i = 0; i < src.holes.size(); ++ i) n_lines += src.holes[i].points.size(); Lines lines; lines.reserve(n_lines); for (size_t i = 0; i <= src.holes.size(); ++ i) { const Polygon &poly = (i == 0) ? src.contour : src.holes[i - 1]; for (Points::const_iterator it = poly.points.begin(); it != poly.points.end()-1; ++it) lines.push_back(Line(*it, *(it + 1))); lines.push_back(Line(poly.points.back(), poly.points.front())); } return lines; } inline Lines to_lines(const ExPolygons &src) { size_t n_lines = 0; for (ExPolygons::const_iterator it_expoly = src.begin(); it_expoly != src.end(); ++ it_expoly) { n_lines += it_expoly->contour.points.size(); for (size_t i = 0; i < it_expoly->holes.size(); ++ i) n_lines += it_expoly->holes[i].points.size(); } Lines lines; lines.reserve(n_lines); for (ExPolygons::const_iterator it_expoly = src.begin(); it_expoly != src.end(); ++ it_expoly) { for (size_t i = 0; i <= it_expoly->holes.size(); ++ i) { const Points &points = ((i == 0) ? it_expoly->contour : it_expoly->holes[i - 1]).points; for (Points::const_iterator it = points.begin(); it != points.end()-1; ++it) lines.push_back(Line(*it, *(it + 1))); lines.push_back(Line(points.back(), points.front())); } } return lines; } inline Polylines to_polylines(const ExPolygon &src) { Polylines polylines; polylines.assign(src.holes.size() + 1, Polyline()); size_t idx = 0; Polyline &pl = polylines[idx ++]; pl.points = src.contour.points; pl.points.push_back(pl.points.front()); for (Polygons::const_iterator ith = src.holes.begin(); ith != src.holes.end(); ++ith) { Polyline &pl = polylines[idx ++]; pl.points = ith->points; pl.points.push_back(ith->points.front()); } assert(idx == polylines.size()); return polylines; } inline Polylines to_polylines(const ExPolygons &src) { Polylines polylines; polylines.assign(number_polygons(src), Polyline()); size_t idx = 0; for (ExPolygons::const_iterator it = src.begin(); it != src.end(); ++it) { Polyline &pl = polylines[idx ++]; pl.points = it->contour.points; pl.points.push_back(pl.points.front()); for (Polygons::const_iterator ith = it->holes.begin(); ith != it->holes.end(); ++ith) { Polyline &pl = polylines[idx ++]; pl.points = ith->points; pl.points.push_back(ith->points.front()); } } assert(idx == polylines.size()); return polylines; } inline Polylines to_polylines(ExPolygon &&src) { Polylines polylines; polylines.assign(src.holes.size() + 1, Polyline()); size_t idx = 0; Polyline &pl = polylines[idx ++]; pl.points = std::move(src.contour.points); pl.points.push_back(pl.points.front()); for (Polygons::const_iterator ith = src.holes.begin(); ith != src.holes.end(); ++ith) { Polyline &pl = polylines[idx ++]; pl.points = std::move(ith->points); pl.points.push_back(ith->points.front()); } assert(idx == polylines.size()); return polylines; } inline Polylines to_polylines(ExPolygons &&src) { Polylines polylines; polylines.assign(number_polygons(src), Polyline()); size_t idx = 0; for (ExPolygons::const_iterator it = src.begin(); it != src.end(); ++it) { Polyline &pl = polylines[idx ++]; pl.points = std::move(it->contour.points); pl.points.push_back(pl.points.front()); for (Polygons::const_iterator ith = it->holes.begin(); ith != it->holes.end(); ++ith) { Polyline &pl = polylines[idx ++]; pl.points = std::move(ith->points); pl.points.push_back(ith->points.front()); } } assert(idx == polylines.size()); return polylines; } inline Polygons to_polygons(const ExPolygon &src) { Polygons polygons; polygons.reserve(src.holes.size() + 1); polygons.push_back(src.contour); polygons.insert(polygons.end(), src.holes.begin(), src.holes.end()); return polygons; } inline Polygons to_polygons(const ExPolygons &src) { Polygons polygons; polygons.reserve(number_polygons(src)); for (ExPolygons::const_iterator it = src.begin(); it != src.end(); ++it) { polygons.push_back(it->contour); polygons.insert(polygons.end(), it->holes.begin(), it->holes.end()); } return polygons; } inline Polygons to_polygons(ExPolygon &&src) { Polygons polygons; polygons.reserve(src.holes.size() + 1); polygons.push_back(std::move(src.contour)); std::move(std::begin(src.holes), std::end(src.holes), std::back_inserter(polygons)); src.holes.clear(); return polygons; } inline Polygons to_polygons(ExPolygons &&src) { Polygons polygons; polygons.reserve(number_polygons(src)); for (ExPolygons::iterator it = src.begin(); it != src.end(); ++it) { polygons.push_back(std::move(it->contour)); std::move(std::begin(it->holes), std::end(it->holes), std::back_inserter(polygons)); it->holes.clear(); } return polygons; } inline ExPolygons to_expolygons(const Polygons &polys) { ExPolygons ex_polys; ex_polys.assign(polys.size(), ExPolygon()); for (size_t idx = 0; idx < polys.size(); ++idx) ex_polys[idx].contour = polys[idx]; return ex_polys; } inline ExPolygons to_expolygons(Polygons &&polys) { ExPolygons ex_polys; ex_polys.assign(polys.size(), ExPolygon()); for (size_t idx = 0; idx < polys.size(); ++idx) ex_polys[idx].contour = std::move(polys[idx]); return ex_polys; } inline void polygons_append(Polygons &dst, const ExPolygon &src) { dst.reserve(dst.size() + src.holes.size() + 1); dst.push_back(src.contour); dst.insert(dst.end(), src.holes.begin(), src.holes.end()); } inline void polygons_append(Polygons &dst, const ExPolygons &src) { dst.reserve(dst.size() + number_polygons(src)); for (ExPolygons::const_iterator it = src.begin(); it != src.end(); ++ it) { dst.push_back(it->contour); dst.insert(dst.end(), it->holes.begin(), it->holes.end()); } } inline void polygons_append(Polygons &dst, ExPolygon &&src) { dst.reserve(dst.size() + src.holes.size() + 1); dst.push_back(std::move(src.contour)); std::move(std::begin(src.holes), std::end(src.holes), std::back_inserter(dst)); src.holes.clear(); } inline void polygons_append(Polygons &dst, ExPolygons &&src) { dst.reserve(dst.size() + number_polygons(src)); for (ExPolygons::iterator it = src.begin(); it != src.end(); ++ it) { dst.push_back(std::move(it->contour)); std::move(std::begin(it->holes), std::end(it->holes), std::back_inserter(dst)); it->holes.clear(); } } inline void expolygons_append(ExPolygons &dst, const ExPolygons &src) { dst.insert(dst.end(), src.begin(), src.end()); } inline void expolygons_append(ExPolygons &dst, ExPolygons &&src) { if (dst.empty()) { dst = std::move(src); } else { std::move(std::begin(src), std::end(src), std::back_inserter(dst)); src.clear(); } } inline void expolygons_rotate(ExPolygons &expolys, double angle) { for (ExPolygons::iterator p = expolys.begin(); p != expolys.end(); ++p) p->rotate(angle); } inline bool expolygons_contain(ExPolygons &expolys, const Point &pt) { for (ExPolygons::iterator p = expolys.begin(); p != expolys.end(); ++p) if (p->contains(pt)) return true; return false; } inline ExPolygons expolygons_simplify(const ExPolygons &expolys, double tolerance) { ExPolygons out; out.reserve(expolys.size()); for (const ExPolygon &exp : expolys) exp.simplify(tolerance, &out); return out; } extern BoundingBox get_extents(const ExPolygon &expolygon); extern BoundingBox get_extents(const ExPolygons &expolygons); extern BoundingBox get_extents_rotated(const ExPolygon &poly, double angle); extern BoundingBox get_extents_rotated(const ExPolygons &polygons, double angle); extern std::vector get_extents_vector(const ExPolygons &polygons); extern bool remove_sticks(ExPolygon &poly); extern void keep_largest_contour_only(ExPolygons &polygons); inline double area(const ExPolygons &polys) { double s = 0.; for (auto &p : polys) s += p.area(); return s; } } // namespace Slic3r // start Boost #include namespace boost { namespace polygon { template <> struct polygon_traits { typedef coord_t coordinate_type; typedef Slic3r::Points::const_iterator iterator_type; typedef Slic3r::Point point_type; // Get the begin iterator static inline iterator_type begin_points(const Slic3r::ExPolygon& t) { return t.contour.points.begin(); } // Get the end iterator static inline iterator_type end_points(const Slic3r::ExPolygon& t) { return t.contour.points.end(); } // Get the number of sides of the polygon static inline std::size_t size(const Slic3r::ExPolygon& t) { return t.contour.points.size(); } // Get the winding direction of the polygon static inline winding_direction winding(const Slic3r::ExPolygon& /* t */) { return unknown_winding; } }; template <> struct polygon_mutable_traits { //expects stl style iterators template static inline Slic3r::ExPolygon& set_points(Slic3r::ExPolygon& expolygon, iT input_begin, iT input_end) { expolygon.contour.points.assign(input_begin, input_end); // skip last point since Boost will set last point = first point expolygon.contour.points.pop_back(); return expolygon; } }; template <> struct geometry_concept { typedef polygon_with_holes_concept type; }; template <> struct polygon_with_holes_traits { typedef Slic3r::Polygons::const_iterator iterator_holes_type; typedef Slic3r::Polygon hole_type; static inline iterator_holes_type begin_holes(const Slic3r::ExPolygon& t) { return t.holes.begin(); } static inline iterator_holes_type end_holes(const Slic3r::ExPolygon& t) { return t.holes.end(); } static inline unsigned int size_holes(const Slic3r::ExPolygon& t) { return (int)t.holes.size(); } }; template <> struct polygon_with_holes_mutable_traits { template static inline Slic3r::ExPolygon& set_holes(Slic3r::ExPolygon& t, iT inputBegin, iT inputEnd) { t.holes.assign(inputBegin, inputEnd); return t; } }; //first we register CPolygonSet as a polygon set template <> struct geometry_concept { typedef polygon_set_concept type; }; //next we map to the concept through traits template <> struct polygon_set_traits { typedef coord_t coordinate_type; typedef Slic3r::ExPolygons::const_iterator iterator_type; typedef Slic3r::ExPolygons operator_arg_type; static inline iterator_type begin(const Slic3r::ExPolygons& polygon_set) { return polygon_set.begin(); } static inline iterator_type end(const Slic3r::ExPolygons& polygon_set) { return polygon_set.end(); } //don't worry about these, just return false from them static inline bool clean(const Slic3r::ExPolygons& /* polygon_set */) { return false; } static inline bool sorted(const Slic3r::ExPolygons& /* polygon_set */) { return false; } }; template <> struct polygon_set_mutable_traits { template static inline void set(Slic3r::ExPolygons& expolygons, input_iterator_type input_begin, input_iterator_type input_end) { expolygons.assign(input_begin, input_end); } }; } } // end Boost #endif