#ifndef slic3r_Polyline_hpp_ #define slic3r_Polyline_hpp_ #include "libslic3r.h" #include "Line.hpp" #include "MultiPoint.hpp" #include #include //BBS: new necessary header file #include "ArcFitter.hpp" namespace Slic3r { class Polyline; class ThickPolyline; typedef std::vector Polylines; typedef std::vector ThickPolylines; class Polyline : public MultiPoint { public: Polyline() {}; Polyline(const Polyline& other) : MultiPoint(other.points), fitting_result(other.fitting_result) {} Polyline(Polyline &&other) : MultiPoint(std::move(other.points)), fitting_result(std::move(other.fitting_result)) {} Polyline(std::initializer_list list) : MultiPoint(list) { fitting_result.clear(); } explicit Polyline(const Point &p1, const Point &p2) { points.reserve(2); points.emplace_back(p1); points.emplace_back(p2); fitting_result.clear(); } explicit Polyline(const Points &points) : MultiPoint(points) { fitting_result.clear(); } explicit Polyline(Points &&points) : MultiPoint(std::move(points)) { fitting_result.clear(); } Polyline& operator=(const Polyline& other) { points = other.points; fitting_result = other.fitting_result; return *this; } Polyline& operator=(Polyline&& other) { points = std::move(other.points); fitting_result = std::move(other.fitting_result); return *this; } static Polyline new_scale(const std::vector &points) { Polyline pl; pl.points.reserve(points.size()); for (const Vec2d &pt : points) pl.points.emplace_back(Point::new_scale(pt(0), pt(1))); //BBS: new_scale doesn't support arc, so clean pl.fitting_result.clear(); return pl; } void append(const Point &point) { //BBS: don't need to append same point if (!this->empty() && this->last_point() == point) return; MultiPoint::append(point); append_fitting_result_after_append_points(); } void append_before(const Point& point) { //BBS: don't need to append same point if (!this->empty() && this->first_point() == point) return; if (this->size() == 1) { this->fitting_result.clear(); MultiPoint::append(point); MultiPoint::reverse(); } else { this->reverse(); this->append(point); this->reverse(); } } void append(const Points &src) { //BBS: don't need to append same point if (!this->empty() && !src.empty() && this->last_point() == src[0]) this->append(src.begin() + 1, src.end()); else this->append(src.begin(), src.end()); } void append(const Points::const_iterator &begin, const Points::const_iterator &end) { //BBS: don't need to append same point if (!this->empty() && begin != end && this->last_point() == *begin) MultiPoint::append(begin + 1, end); else MultiPoint::append(begin, end); append_fitting_result_after_append_points(); } void append(Points &&src) { MultiPoint::append(std::move(src)); append_fitting_result_after_append_points(); } void append(const Polyline& src); void append(Polyline&& src); Point& operator[](Points::size_type idx) { return this->points[idx]; } const Point& operator[](Points::size_type idx) const { return this->points[idx]; } const Point& last_point() const override { return this->points.back(); } //const Point& first_point() const override { return this->points.front(); } const Point& leftmost_point() const; Lines lines() const override; void clear() { MultiPoint::clear(); this->fitting_result.clear(); } void reverse(); void clip_end(double distance); void clip_start(double distance); void extend_end(double distance); void extend_start(double distance); Points equally_spaced_points(double distance) const; void simplify(double tolerance); // template void simplify_by_visibility(const T &area); void split_at(Point &point, Polyline* p1, Polyline* p2) const; bool split_at_index(const size_t index, Polyline* p1, Polyline* p2) const; bool split_at_length(const double length, Polyline *p1, Polyline *p2) const; bool is_straight() const; bool is_closed() const { return this->points.front() == this->points.back(); } //BBS: store arc fitting result std::vector fitting_result; //BBS: simplify points by arc fitting void simplify_by_fitting_arc(double tolerance); //BBS: Polylines equally_spaced_lines(double distance) const; private: void append_fitting_result_after_append_points(); void append_fitting_result_after_append_polyline(const Polyline& src); void reset_to_linear_move(); bool split_fitting_result_before_index(const size_t index, Point &new_endpoint, std::vector& data) const; bool split_fitting_result_after_index(const size_t index, Point &new_startpoint, std::vector& data) const; }; inline bool operator==(const Polyline &lhs, const Polyline &rhs) { return lhs.points == rhs.points; } inline bool operator!=(const Polyline &lhs, const Polyline &rhs) { return lhs.points != rhs.points; } // Don't use this class in production code, it is used exclusively by the Perl binding for unit tests! #ifdef PERL_UCHAR_MIN class PolylineCollection { public: Polylines polylines; }; #endif /* PERL_UCHAR_MIN */ extern BoundingBox get_extents(const Polyline &polyline); extern BoundingBox get_extents(const Polylines &polylines); inline double total_length(const Polylines &polylines) { double total = 0; for (const Polyline &pl : polylines) total += pl.length(); return total; } inline Lines to_lines(const Polyline &poly) { Lines lines; if (poly.points.size() >= 2) { lines.reserve(poly.points.size() - 1); for (Points::const_iterator it = poly.points.begin(); it != poly.points.end()-1; ++it) lines.push_back(Line(*it, *(it + 1))); } return lines; } inline Lines to_lines(const Polylines &polys) { size_t n_lines = 0; for (size_t i = 0; i < polys.size(); ++ i) if (polys[i].points.size() > 1) n_lines += polys[i].points.size() - 1; Lines lines; lines.reserve(n_lines); for (size_t i = 0; i < polys.size(); ++ i) { const Polyline &poly = polys[i]; for (Points::const_iterator it = poly.points.begin(); it != poly.points.end()-1; ++it) lines.push_back(Line(*it, *(it + 1))); } return lines; } inline Polylines to_polylines(const std::vector &paths) { Polylines out; out.reserve(paths.size()); for (const Points &path : paths) out.emplace_back(path); return out; } inline Polylines to_polylines(std::vector &&paths) { Polylines out; out.reserve(paths.size()); for (const Points &path : paths) out.emplace_back(std::move(path)); return out; } inline void polylines_append(Polylines &dst, const Polylines &src) { dst.insert(dst.end(), src.begin(), src.end()); } inline void polylines_append(Polylines &dst, Polylines &&src) { if (dst.empty()) { dst = std::move(src); } else { std::move(std::begin(src), std::end(src), std::back_inserter(dst)); src.clear(); } } // Merge polylines at their respective end points. // dst_first: the merge point is at dst.begin() or dst.end()? // src_first: the merge point is at src.begin() or src.end()? // The orientation of the resulting polyline is unknown, the output polyline may start // either with src piece or dst piece. template inline void polylines_merge(PointsType &dst, bool dst_first, PointsType &&src, bool src_first) { if (dst_first) { if (src_first) std::reverse(dst.begin(), dst.end()); else std::swap(dst, src); } else if (! src_first) std::reverse(src.begin(), src.end()); // Merge src into dst. append(dst, std::move(src)); } const Point& leftmost_point(const Polylines &polylines); bool remove_degenerate(Polylines &polylines); // Returns index of a segment of a polyline and foot point of pt on polyline. std::pair foot_pt(const Points &polyline, const Point &pt); class ThickPolyline : public Polyline { public: ThickPolyline() : endpoints(std::make_pair(false, false)) {} ThickLines thicklines() const; void reverse() { Polyline::reverse(); std::reverse(this->width.begin(), this->width.end()); std::swap(this->endpoints.first, this->endpoints.second); } void clear() { Polyline::clear(); width.clear(); } std::vector width; std::pair endpoints; }; inline ThickPolylines to_thick_polylines(Polylines&& polylines, const coordf_t width) { ThickPolylines out; out.reserve(polylines.size()); for (Polyline& polyline : polylines) { out.emplace_back(); out.back().width.assign((polyline.points.size() - 1) * 2, width); out.back().points = std::move(polyline.points); } return out; } class Polyline3 : public MultiPoint3 { public: virtual Lines3 lines() const; }; typedef std::vector Polylines3; } #endif