#ifndef slic3r_Surface_hpp_ #define slic3r_Surface_hpp_ #include "libslic3r.h" #include "ExPolygon.hpp" namespace Slic3r { enum SurfaceType { // Top horizontal surface, visible from the top. stTop, // Bottom horizontal surface, visible from the bottom, printed with a normal extrusion flow. stBottom, // Bottom horizontal surface, visible from the bottom, unsupported, printed with a bridging extrusion flow. stBottomBridge, // Normal sparse infill. stInternal, // Full infill, supporting the top surfaces and/or defining the verticall wall thickness. stInternalSolid, // 1st layer of dense infill over sparse infill, printed with a bridging extrusion flow. stInternalBridge, // stInternal turns into void surfaces if the sparse infill is used for supports only, // or if sparse infill layers get combined into a single layer. stInternalVoid, // Inner/outer perimeters. stPerimeter, // Last surface type, if the SurfaceType is used as an index into a vector. stLast, stCount = stLast + 1 }; class Surface { public: SurfaceType surface_type; ExPolygon expolygon; double thickness; // in mm unsigned short thickness_layers; // in layers double bridge_angle; // in radians, ccw, 0 = East, only 0+ (negative means undefined) unsigned short extra_perimeters; Surface(const Slic3r::Surface &rhs) : surface_type(rhs.surface_type), expolygon(rhs.expolygon), thickness(rhs.thickness), thickness_layers(rhs.thickness_layers), bridge_angle(rhs.bridge_angle), extra_perimeters(rhs.extra_perimeters) {}; Surface(SurfaceType _surface_type, const ExPolygon &_expolygon) : surface_type(_surface_type), expolygon(_expolygon), thickness(-1), thickness_layers(1), bridge_angle(-1), extra_perimeters(0) {}; Surface(const Surface &other, const ExPolygon &_expolygon) : surface_type(other.surface_type), expolygon(_expolygon), thickness(other.thickness), thickness_layers(other.thickness_layers), bridge_angle(other.bridge_angle), extra_perimeters(other.extra_perimeters) {}; Surface(Surface &&rhs) : surface_type(rhs.surface_type), expolygon(std::move(rhs.expolygon)), thickness(rhs.thickness), thickness_layers(rhs.thickness_layers), bridge_angle(rhs.bridge_angle), extra_perimeters(rhs.extra_perimeters) {}; Surface(SurfaceType _surface_type, const ExPolygon &&_expolygon) : surface_type(_surface_type), expolygon(std::move(_expolygon)), thickness(-1), thickness_layers(1), bridge_angle(-1), extra_perimeters(0) {}; Surface(const Surface &other, const ExPolygon &&_expolygon) : surface_type(other.surface_type), expolygon(std::move(_expolygon)), thickness(other.thickness), thickness_layers(other.thickness_layers), bridge_angle(other.bridge_angle), extra_perimeters(other.extra_perimeters) {}; Surface& operator=(const Surface &rhs) { surface_type = rhs.surface_type; expolygon = rhs.expolygon; thickness = rhs.thickness; thickness_layers = rhs.thickness_layers; bridge_angle = rhs.bridge_angle; extra_perimeters = rhs.extra_perimeters; return *this; } Surface& operator=(Surface &&rhs) { surface_type = rhs.surface_type; expolygon = std::move(rhs.expolygon); thickness = rhs.thickness; thickness_layers = rhs.thickness_layers; bridge_angle = rhs.bridge_angle; extra_perimeters = rhs.extra_perimeters; return *this; } operator Polygons() const; double area() const; bool empty() const { return expolygon.empty(); } void clear() { expolygon.clear(); } bool is_solid() const; bool is_external() const; bool is_internal() const; bool is_top() const; bool is_bottom() const; bool is_bridge() const; }; typedef std::vector Surfaces; typedef std::vector SurfacesPtr; inline Polygons to_polygons(const Surfaces &src) { size_t num = 0; for (Surfaces::const_iterator it = src.begin(); it != src.end(); ++it) num += it->expolygon.holes.size() + 1; Polygons polygons; polygons.reserve(num); for (Surfaces::const_iterator it = src.begin(); it != src.end(); ++it) { polygons.emplace_back(it->expolygon.contour); for (Polygons::const_iterator ith = it->expolygon.holes.begin(); ith != it->expolygon.holes.end(); ++ith) polygons.emplace_back(*ith); } return polygons; } inline Polygons to_polygons(const SurfacesPtr &src) { size_t num = 0; for (SurfacesPtr::const_iterator it = src.begin(); it != src.end(); ++it) num += (*it)->expolygon.holes.size() + 1; Polygons polygons; polygons.reserve(num); for (SurfacesPtr::const_iterator it = src.begin(); it != src.end(); ++it) { polygons.emplace_back((*it)->expolygon.contour); for (Polygons::const_iterator ith = (*it)->expolygon.holes.begin(); ith != (*it)->expolygon.holes.end(); ++ith) polygons.emplace_back(*ith); } return polygons; } inline ExPolygons to_expolygons(const Surfaces &src) { ExPolygons expolygons; expolygons.reserve(src.size()); for (Surfaces::const_iterator it = src.begin(); it != src.end(); ++it) expolygons.emplace_back(it->expolygon); return expolygons; } inline ExPolygons to_expolygons(Surfaces &&src) { ExPolygons expolygons; expolygons.reserve(src.size()); for (Surfaces::const_iterator it = src.begin(); it != src.end(); ++it) expolygons.emplace_back(ExPolygon(std::move(it->expolygon))); src.clear(); return expolygons; } inline ExPolygons to_expolygons(const SurfacesPtr &src) { ExPolygons expolygons; expolygons.reserve(src.size()); for (SurfacesPtr::const_iterator it = src.begin(); it != src.end(); ++it) expolygons.emplace_back((*it)->expolygon); return expolygons; } // 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 Surfaces &surfaces) { size_t n_polygons = 0; for (Surfaces::const_iterator it = surfaces.begin(); it != surfaces.end(); ++ it) n_polygons += it->expolygon.holes.size() + 1; return n_polygons; } inline size_t number_polygons(const SurfacesPtr &surfaces) { size_t n_polygons = 0; for (SurfacesPtr::const_iterator it = surfaces.begin(); it != surfaces.end(); ++ it) n_polygons += (*it)->expolygon.holes.size() + 1; return n_polygons; } // Append a vector of Surfaces at the end of another vector of polygons. inline void polygons_append(Polygons &dst, const Surfaces &src) { dst.reserve(dst.size() + number_polygons(src)); for (Surfaces::const_iterator it = src.begin(); it != src.end(); ++ it) { dst.emplace_back(it->expolygon.contour); dst.insert(dst.end(), it->expolygon.holes.begin(), it->expolygon.holes.end()); } } inline void polygons_append(Polygons &dst, Surfaces &&src) { dst.reserve(dst.size() + number_polygons(src)); for (Surfaces::iterator it = src.begin(); it != src.end(); ++ it) { dst.emplace_back(std::move(it->expolygon.contour)); std::move(std::begin(it->expolygon.holes), std::end(it->expolygon.holes), std::back_inserter(dst)); it->expolygon.holes.clear(); } } // Append a vector of Surfaces at the end of another vector of polygons. inline void polygons_append(Polygons &dst, const SurfacesPtr &src) { dst.reserve(dst.size() + number_polygons(src)); for (SurfacesPtr::const_iterator it = src.begin(); it != src.end(); ++ it) { dst.emplace_back((*it)->expolygon.contour); dst.insert(dst.end(), (*it)->expolygon.holes.begin(), (*it)->expolygon.holes.end()); } } inline void polygons_append(Polygons &dst, SurfacesPtr &&src) { dst.reserve(dst.size() + number_polygons(src)); for (SurfacesPtr::const_iterator it = src.begin(); it != src.end(); ++ it) { dst.emplace_back(std::move((*it)->expolygon.contour)); std::move(std::begin((*it)->expolygon.holes), std::end((*it)->expolygon.holes), std::back_inserter(dst)); (*it)->expolygon.holes.clear(); } } // Append a vector of Surfaces at the end of another vector of polygons. inline void surfaces_append(Surfaces &dst, const ExPolygons &src, SurfaceType surfaceType) { dst.reserve(dst.size() + src.size()); for (const ExPolygon &expoly : src) dst.emplace_back(Surface(surfaceType, expoly)); } inline void surfaces_append(Surfaces &dst, const ExPolygons &src, const Surface &surfaceTempl) { dst.reserve(dst.size() + number_polygons(src)); for (const ExPolygon &expoly : src) dst.emplace_back(Surface(surfaceTempl, expoly)); } inline void surfaces_append(Surfaces &dst, const Surfaces &src) { dst.insert(dst.end(), src.begin(), src.end()); } inline void surfaces_append(Surfaces &dst, ExPolygons &&src, SurfaceType surfaceType) { dst.reserve(dst.size() + src.size()); for (ExPolygon &expoly : src) dst.emplace_back(Surface(surfaceType, std::move(expoly))); src.clear(); } inline void surfaces_append(Surfaces &dst, ExPolygons &&src, const Surface &surfaceTempl) { dst.reserve(dst.size() + number_polygons(src)); for (ExPolygons::const_iterator it = src.begin(); it != src.end(); ++ it) dst.emplace_back(Surface(surfaceTempl, std::move(*it))); src.clear(); } inline void surfaces_append(Surfaces &dst, Surfaces &&src) { if (dst.empty()) { dst = std::move(src); } else { std::move(std::begin(src), std::end(src), std::back_inserter(dst)); src.clear(); } } extern BoundingBox get_extents(const Surface &surface); extern BoundingBox get_extents(const Surfaces &surfaces); extern BoundingBox get_extents(const SurfacesPtr &surfaces); inline bool surfaces_could_merge(const Surface &s1, const Surface &s2) { return s1.surface_type == s2.surface_type && s1.thickness == s2.thickness && s1.thickness_layers == s2.thickness_layers && s1.bridge_angle == s2.bridge_angle; } class SVG; extern const char* surface_type_to_color_name(const SurfaceType surface_type); extern void export_surface_type_legend_to_svg(SVG &svg, const Point &pos); extern Point export_surface_type_legend_to_svg_box_size(); extern bool export_to_svg(const char *path, const Surfaces &surfaces, const float transparency = 1.f); } #endif