#include #include #include #include "libslic3r/TriangleMesh.hpp" using namespace Slic3r; TEST_CASE("Split empty mesh", "[its_split][its]") { using namespace Slic3r; indexed_triangle_set its; std::vector res = its_split(its); REQUIRE(res.empty()); } TEST_CASE("Split simple mesh consisting of one part", "[its_split][its]") { using namespace Slic3r; auto cube = its_make_cube(10., 10., 10.); std::vector res = its_split(cube); REQUIRE(res.size() == 1); REQUIRE(res.front().indices.size() == cube.indices.size()); REQUIRE(res.front().vertices.size() == cube.vertices.size()); } void debug_write_obj(const std::vector &res, const std::string &name) { #ifndef NDEBUG size_t part_idx = 0; for (auto &part_its : res) { its_write_obj(part_its, (name + std::to_string(part_idx++) + ".obj").c_str()); } #endif } TEST_CASE("Split two non-watertight mesh", "[its_split][its]") { using namespace Slic3r; auto cube1 = its_make_cube(10., 10., 10.); cube1.indices.pop_back(); auto cube2 = cube1; its_transform(cube1, identity3f().translate(Vec3f{-5.f, 0.f, 0.f})); its_transform(cube2, identity3f().translate(Vec3f{5.f, 0.f, 0.f})); its_merge(cube1, cube2); std::vector res = its_split(cube1); REQUIRE(res.size() == 2); REQUIRE(res[0].indices.size() == res[1].indices.size()); REQUIRE(res[0].indices.size() == cube2.indices.size()); REQUIRE(res[0].vertices.size() == res[1].vertices.size()); REQUIRE(res[0].vertices.size() == cube2.vertices.size()); debug_write_obj(res, "parts_non_watertight"); } TEST_CASE("Split non-manifold mesh", "[its_split][its]") { using namespace Slic3r; auto cube = its_make_cube(10., 10., 10.), cube_low = cube; its_transform(cube_low, identity3f().translate(Vec3f{10.f, 10.f, 10.f})); its_merge(cube, cube_low); its_merge_vertices(cube); std::vector res = its_split(cube); REQUIRE(res.size() == 2); REQUIRE(res[0].indices.size() == res[1].indices.size()); REQUIRE(res[0].indices.size() == cube_low.indices.size()); REQUIRE(res[0].vertices.size() == res[1].vertices.size()); REQUIRE(res[0].vertices.size() == cube_low.vertices.size()); debug_write_obj(res, "cubes_non_manifold"); } TEST_CASE("Split two watertight meshes", "[its_split][its]") { using namespace Slic3r; auto sphere1 = its_make_sphere(10., 2 * PI / 200.), sphere2 = sphere1; its_transform(sphere1, identity3f().translate(Vec3f{-5.f, 0.f, 0.f})); its_transform(sphere2, identity3f().translate(Vec3f{5.f, 0.f, 0.f})); its_merge(sphere1, sphere2); std::vector res = its_split(sphere1); REQUIRE(res.size() == 2); REQUIRE(res[0].indices.size() == res[1].indices.size()); REQUIRE(res[0].indices.size() == sphere2.indices.size()); REQUIRE(res[0].vertices.size() == res[1].vertices.size()); REQUIRE(res[0].vertices.size() == sphere2.vertices.size()); debug_write_obj(res, "parts_watertight"); } #include static float triangle_area(const Vec3f &v0, const Vec3f &v1, const Vec3f &v2) { Vec3f ab = v1 - v0; Vec3f ac = v2 - v0; return ab.cross(ac).norm() / 2.f; } static float triangle_area(const Vec3crd &triangle_inices, const std::vector &vertices) { return triangle_area(vertices[triangle_inices[0]], vertices[triangle_inices[1]], vertices[triangle_inices[2]]); } static std::mt19937 create_random_generator() { std::random_device rd; std::mt19937 gen(rd()); return gen; } std::vector its_sample_surface(const indexed_triangle_set &its, double sample_per_mm2, std::mt19937 random_generator = create_random_generator()) { std::vector samples; std::uniform_real_distribution rand01(0.f, 1.f); for (const auto &triangle_indices : its.indices) { float area = triangle_area(triangle_indices, its.vertices); float countf; float fractional = std::modf(area * sample_per_mm2, &countf); int count = static_cast(countf); float generate = rand01(random_generator); if (generate < fractional) ++count; if (count == 0) continue; const Vec3f &v0 = its.vertices[triangle_indices[0]]; const Vec3f &v1 = its.vertices[triangle_indices[1]]; const Vec3f &v2 = its.vertices[triangle_indices[2]]; for (int c = 0; c < count; c++) { // barycentric coordinate Vec3f b; b[0] = rand01(random_generator); b[1] = rand01(random_generator); if ((b[0] + b[1]) > 1.f) { b[0] = 1.f - b[0]; b[1] = 1.f - b[1]; } b[2] = 1.f - b[0] - b[1]; Vec3f pos; for (int i = 0; i < 3; i++) { pos[i] = b[0] * v0[i] + b[1] * v1[i] + b[2] * v2[i]; } samples.push_back(pos); } } return samples; } #include "libslic3r/AABBTreeIndirect.hpp" // return Average abs distance to original float compare(const indexed_triangle_set &original, const indexed_triangle_set &simplified, double sample_per_mm2) { // create ABBTree auto tree = AABBTreeIndirect::build_aabb_tree_over_indexed_triangle_set( original.vertices, original.indices); unsigned int init = 0; std::mt19937 rnd(init); auto samples = its_sample_surface(simplified, sample_per_mm2, rnd); float sumDistance = 0; for (const Vec3f &sample : samples) { size_t hit_idx; Vec3f hit_point; float distance2 = AABBTreeIndirect::squared_distance_to_indexed_triangle_set( original.vertices, original.indices, tree, sample, hit_idx, hit_point); sumDistance += sqrt(distance2); } return sumDistance / samples.size(); } TEST_CASE("Reduce one edge by Quadric Edge Collapse", "[its]") { indexed_triangle_set its; its.vertices = {Vec3f(-1.f, 0.f, 0.f), Vec3f(0.f, 1.f, 0.f), Vec3f(1.f, 0.f, 0.f), Vec3f(0.f, 0.f, 1.f), // vertex to be removed Vec3f(0.9f, .1f, -.1f)}; its.indices = {Vec3i(1, 0, 3), Vec3i(2, 1, 3), Vec3i(0, 2, 3), Vec3i(0, 1, 4), Vec3i(1, 2, 4), Vec3i(2, 0, 4)}; // edge to remove is between vertices 2 and 4 on trinagles 4 and 5 indexed_triangle_set its_ = its; // copy // its_write_obj(its, "tetrhedron_in.obj"); uint32_t wanted_count = its.indices.size() - 1; its_quadric_edge_collapse(its, wanted_count); // its_write_obj(its, "tetrhedron_out.obj"); CHECK(its.indices.size() == 4); CHECK(its.vertices.size() == 4); for (size_t i = 0; i < 3; i++) { CHECK(its.indices[i] == its_.indices[i]); } for (size_t i = 0; i < 4; i++) { if (i == 2) continue; CHECK(its.vertices[i] == its_.vertices[i]); } const Vec3f &v = its.vertices[2]; // new vertex const Vec3f &v2 = its_.vertices[2]; // moved vertex const Vec3f &v4 = its_.vertices[4]; // removed vertex for (size_t i = 0; i < 3; i++) { bool is_between = (v[i] < v4[i] && v[i] > v2[i]) || (v[i] > v4[i] && v[i] < v2[i]); CHECK(is_between); } float avg_distance = compare(its_, its, 10); CHECK(avg_distance < 8e-3f); } #include "test_utils.hpp" TEST_CASE("Simplify mesh by Quadric edge collapse to 5%", "[its]") { TriangleMesh mesh = load_model("frog_legs.obj"); //TriangleMesh mesh; load_obj("C:/Users/filip/Documents/models/scarecrow_torso.obj", &mesh); double original_volume = its_volume(mesh.its); uint32_t wanted_count = mesh.its.indices.size() * 0.05; REQUIRE_FALSE(mesh.empty()); indexed_triangle_set its = mesh.its; // copy float max_error = std::numeric_limits::max(); its_quadric_edge_collapse(its, wanted_count, &max_error); //its_write_obj(its, "frog_legs_qec.obj"); CHECK(its.indices.size() <= wanted_count); double volume = its_volume(its); CHECK(fabs(original_volume - volume) < 33.); float avg_distance = compare(mesh.its, its, 10); CHECK(avg_distance < 0.022f); // 0.02022 | 0.0199614074 }