#define NOMINMAX #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace Slic3r; static double area(const sla::RasterBase::PixelDim &pxd) { return pxd.w_mm * pxd.h_mm; } static Slic3r::sla::RasterGrayscaleAA create_raster( const sla::RasterBase::Resolution &res, double disp_w = 100., double disp_h = 100.) { sla::RasterBase::PixelDim pixdim{disp_w / res.width_px, disp_h / res.height_px}; auto bb = BoundingBox({0, 0}, {scaled(disp_w), scaled(disp_h)}); sla::RasterBase::Trafo trafo; trafo.center_x = bb.center().x(); trafo.center_y = bb.center().y(); return sla::RasterGrayscaleAA{res, pixdim, trafo, agg::gamma_threshold(.5)}; } static ExPolygon square(double a, Point center = {0, 0}) { ExPolygon poly; coord_t V = scaled(a / 2.); poly.contour.points = {{-V, -V}, {V, -V}, {V, V}, {-V, V}}; poly.translate(center.x(), center.y()); return poly; } static ExPolygon square_with_hole(double a, Point center = {0, 0}) { ExPolygon poly = square(a); poly.holes.emplace_back(); coord_t V = scaled(a / 4.); poly.holes.front().points = {{-V, V}, {V, V}, {V, -V}, {-V, -V}}; poly.translate(center.x(), center.y()); return poly; } static ExPolygons circle_with_hole(double r, Point center = {0, 0}) { ExPolygon poly; std::vector pis = linspace_vector(0., 2 * PI, 100); coord_t rs = scaled(r); for (double phi : pis) { poly.contour.points.emplace_back(rs * std::cos(phi), rs * std::sin(phi)); } poly.holes.emplace_back(poly.contour); poly.holes.front().reverse(); for (auto &p : poly.holes.front().points) p /= 2; poly.translate(center.x(), center.y()); return {poly}; } static const Vec2i W4x4 = {4, 4}; static const Vec2i W2x2 = {2, 2}; template static void test_expolys(Rst && rst, const ExPolygons & ref, Vec2i window, const std::string &name = "test") { for (const ExPolygon &expoly : ref) rst.draw(expoly); std::fstream out(name + ".png", std::ios::out); out << rst.encode(sla::PNGRasterEncoder{}); out.close(); ExPolygons extracted = sla::raster_to_polygons(rst, window); SVG svg(name + ".svg"); svg.draw(extracted); svg.draw(ref, "green"); svg.Close(); double max_rel_err = 0.1; sla::RasterBase::PixelDim pxd = rst.pixel_dimensions(); double max_abs_err = area(pxd) * scaled(1.) * scaled(1.); BoundingBox ref_bb; for (auto &expoly : ref) ref_bb.merge(expoly.contour.bounding_box()); double max_displacement = 4. * (std::pow(pxd.h_mm, 2) + std::pow(pxd.w_mm, 2)); max_displacement *= scaled(1.) * scaled(1.); REQUIRE(extracted.size() == ref.size()); for (size_t i = 0; i < ref.size(); ++i) { REQUIRE(extracted[i].contour.is_counter_clockwise()); REQUIRE(extracted[i].holes.size() == ref[i].holes.size()); for (auto &h : extracted[i].holes) REQUIRE(h.is_clockwise()); double refa = ref[i].area(); double abs_err = std::abs(extracted[i].area() - refa); double rel_err = abs_err / refa; REQUIRE((rel_err <= max_rel_err || abs_err <= max_abs_err)); BoundingBox bb; for (auto &expoly : extracted) bb.merge(expoly.contour.bounding_box()); Point d = bb.center() - ref_bb.center(); REQUIRE(double(d.transpose() * d) <= max_displacement); } } TEST_CASE("Empty raster should result in empty polygons", "[MarchingSquares]") { sla::RasterGrayscaleAAGammaPower rst{{}, {}, {}}; ExPolygons extracted = sla::raster_to_polygons(rst); REQUIRE(extracted.size() == 0); } TEST_CASE("Marching squares directions", "[MarchingSquares]") { marchsq::Coord crd{1, 1}; REQUIRE(step(crd, marchsq::__impl::Dir::left).r == 1); REQUIRE(step(crd, marchsq::__impl::Dir::left).c == 0); REQUIRE(step(crd, marchsq::__impl::Dir::down).r == 2); REQUIRE(step(crd, marchsq::__impl::Dir::down).c == 1); REQUIRE(step(crd, marchsq::__impl::Dir::right).r == 1); REQUIRE(step(crd, marchsq::__impl::Dir::right).c == 2); REQUIRE(step(crd, marchsq::__impl::Dir::up).r == 0); REQUIRE(step(crd, marchsq::__impl::Dir::up).c == 1); } TEST_CASE("Fully covered raster should result in a rectangle", "[MarchingSquares]") { auto rst = create_raster({4, 4}, 4., 4.); ExPolygon rect = square(4); SECTION("Full accuracy") { test_expolys(rst, {rect}, W2x2, "fully_covered_full_acc"); } SECTION("Half accuracy") { test_expolys(rst, {rect}, W4x4, "fully_covered_half_acc"); } } TEST_CASE("4x4 raster with one ring", "[MarchingSquares]") { sla::RasterBase::PixelDim pixdim{1, 1}; // We need one additional row and column to detect edges sla::RasterGrayscaleAA rst{{4, 4}, pixdim, {}, agg::gamma_threshold(.5)}; // Draw a triangle from individual pixels rst.draw(square(1., {0500000, 0500000})); rst.draw(square(1., {1500000, 0500000})); rst.draw(square(1., {2500000, 0500000})); rst.draw(square(1., {1500000, 1500000})); rst.draw(square(1., {2500000, 1500000})); rst.draw(square(1., {2500000, 2500000})); std::fstream out("4x4.png", std::ios::out); out << rst.encode(sla::PNGRasterEncoder{}); out.close(); ExPolygons extracted = sla::raster_to_polygons(rst); SVG svg("4x4.svg"); svg.draw(extracted); svg.Close(); REQUIRE(extracted.size() == 1); } TEST_CASE("4x4 raster with two rings", "[MarchingSquares]") { sla::RasterBase::PixelDim pixdim{1, 1}; // We need one additional row and column to detect edges sla::RasterGrayscaleAA rst{{5, 5}, pixdim, {}, agg::gamma_threshold(.5)}; SECTION("Ambiguous case with 'ac' square") { // Draw a triangle from individual pixels rst.draw(square(1., {3500000, 2500000})); rst.draw(square(1., {3500000, 3500000})); rst.draw(square(1., {2500000, 3500000})); rst.draw(square(1., {2500000, 1500000})); rst.draw(square(1., {1500000, 1500000})); rst.draw(square(1., {1500000, 2500000})); std::fstream out("4x4_ac.png", std::ios::out); out << rst.encode(sla::PNGRasterEncoder{}); out.close(); ExPolygons extracted = sla::raster_to_polygons(rst); SVG svg("4x4_ac.svg"); svg.draw(extracted); svg.Close(); REQUIRE(extracted.size() == 2); } SECTION("Ambiguous case with 'bd' square") { // Draw a triangle from individual pixels rst.draw(square(1., {3500000, 1500000})); rst.draw(square(1., {3500000, 2500000})); rst.draw(square(1., {2500000, 1500000})); rst.draw(square(1., {1500000, 2500000})); rst.draw(square(1., {1500000, 3500000})); rst.draw(square(1., {2500000, 3500000})); std::fstream out("4x4_bd.png", std::ios::out); out << rst.encode(sla::PNGRasterEncoder{}); out.close(); ExPolygons extracted = sla::raster_to_polygons(rst); SVG svg("4x4_bd.svg"); svg.draw(extracted); svg.Close(); REQUIRE(extracted.size() == 2); } } TEST_CASE("Square with hole in the middle", "[MarchingSquares]") { using namespace Slic3r; ExPolygons inp = {square_with_hole(50.)}; SECTION("Proportional raster, 1x1 mm pixel size, full accuracy") { test_expolys(create_raster({100, 100}, 100., 100.), inp, W2x2, "square_with_hole_proportional_1x1_mm_px_full"); } SECTION("Proportional raster, 1x1 mm pixel size, half accuracy") { test_expolys(create_raster({100, 100}, 100., 100.), inp, W4x4, "square_with_hole_proportional_1x1_mm_px_half"); } SECTION("Landscape raster, 1x1 mm pixel size, full accuracy") { test_expolys(create_raster({150, 100}, 150., 100.), inp, W2x2, "square_with_hole_landsc_1x1_mm_px_full"); } SECTION("Landscape raster, 1x1 mm pixel size, half accuracy") { test_expolys(create_raster({150, 100}, 150., 100.), inp, W4x4, "square_with_hole_landsc_1x1_mm_px_half"); } SECTION("Portrait raster, 1x1 mm pixel size, full accuracy") { test_expolys(create_raster({100, 150}, 100., 150.), inp, W2x2, "square_with_hole_portrait_1x1_mm_px_full"); } SECTION("Portrait raster, 1x1 mm pixel size, half accuracy") { test_expolys(create_raster({100, 150}, 100., 150.), inp, W4x4, "square_with_hole_portrait_1x1_mm_px_half"); } SECTION("Proportional raster, 2x2 mm pixel size, full accuracy") { test_expolys(create_raster({200, 200}, 100., 100.), inp, W2x2, "square_with_hole_proportional_2x2_mm_px_full"); } SECTION("Proportional raster, 2x2 mm pixel size, half accuracy") { test_expolys(create_raster({200, 200}, 100., 100.), inp, W4x4, "square_with_hole_proportional_2x2_mm_px_half"); } SECTION("Proportional raster, 0.5x0.5 mm pixel size, full accuracy") { test_expolys(create_raster({50, 50}, 100., 100.), inp, W2x2, "square_with_hole_proportional_0.5x0.5_mm_px_full"); } SECTION("Proportional raster, 0.5x0.5 mm pixel size, half accuracy") { test_expolys(create_raster({50, 50}, 100., 100.), inp, W4x4, "square_with_hole_proportional_0.5x0.5_mm_px_half"); } } TEST_CASE("Circle with hole in the middle", "[MarchingSquares]") { using namespace Slic3r; test_expolys(create_raster({1000, 1000}), circle_with_hole(25.), W2x2, "circle_with_hole"); } static void recreate_object_from_rasters(const std::string &objname, float lh) { TriangleMesh mesh = load_model(objname); auto bb = mesh.bounding_box(); Vec3f tr = -bb.center().cast(); mesh.translate(tr.x(), tr.y(), tr.z()); bb = mesh.bounding_box(); assert(mesh.has_shared_vertices()); std::vector layers = slice_mesh_ex(mesh.its, grid(float(bb.min.z()) + lh, float(bb.max.z()), lh)); sla::RasterBase::Resolution res{2560, 1440}; double disp_w = 120.96; double disp_h = 68.04; #ifndef NDEBUG size_t cntr = 0; #endif for (ExPolygons &layer : layers) { auto rst = create_raster(res, disp_w, disp_h); for (ExPolygon &island : layer) { rst.draw(island); } #ifndef NDEBUG std::fstream out(objname + std::to_string(cntr) + ".png", std::ios::out); out << rst.encode(sla::PNGRasterEncoder{}); out.close(); #endif ExPolygons layer_ = sla::raster_to_polygons(rst); // float delta = scaled(std::min(rst.pixel_dimensions().h_mm, // rst.pixel_dimensions().w_mm)) / 2; // layer_ = expolygons_simplify(layer_, delta); #ifndef NDEBUG SVG svg(objname + std::to_string(cntr) + ".svg", BoundingBox(Point{0, 0}, Point{scaled(disp_w), scaled(disp_h)})); svg.draw(layer_); svg.draw(layer, "green"); svg.Close(); #endif double layera = 0., layera_ = 0.; for (auto &p : layer) layera += p.area(); for (auto &p : layer_) layera_ += p.area(); #ifndef NDEBUG std::cout << cntr++ << std::endl; #endif double diff = std::abs(layera_ - layera); REQUIRE((diff <= 0.1 * layera || diff < scaled(1.) * scaled(1.))); layer = std::move(layer_); } indexed_triangle_set out = slices_to_mesh(layers, bb.min.z(), double(lh), double(lh)); its_write_obj(out, "out_from_rasters.obj"); } TEST_CASE("Recreate object from rasters", "[SL1Import]") { recreate_object_from_rasters("frog_legs.obj", 0.05f); }