#include #include "catch.hpp" #include "sconvcol.h" using namespace std; TEST_CASE("simd4x4f_trans_inf", "[sconvcol]") { simd4x4f trans; simd4x4f_lookat(&trans, simd4f_create (1.f, 0.f, 1.f, 1.f), simd4f_create (0.f, 0.f, -1.f, 1.f), simd4f_create (0.f, 1.f, 0.f, 1.f)); simd4x4f inv; sch_simd4x4f_transform_inv(&trans, &inv); simd4x4f mul_res; simd4x4f_matrix_mul(&inv, &trans, &mul_res); simd4x4f identity; simd4x4f_identity(&identity); REQUIRE(sch_simd4f_close(identity.x, mul_res.x, 1.0e-5)); REQUIRE(sch_simd4f_close(identity.y, mul_res.y, 1.0e-5)); REQUIRE(sch_simd4f_close(identity.z, mul_res.z, 1.0e-5)); REQUIRE(sch_simd4f_close(identity.w, mul_res.w, 1.0e-5)); } TEST_CASE("Plane Distance", "[sconvcol]") { sch_plane plane = { simd4f_create(0.f, 0.f, 0.f, 0.f), simd4f_create(0.f, 1.f, 0.f, 0.f)}; simd4f point = simd4f_create(0.f, 0.23f, 0.f, 0.f); float dist = sch_plane_distance(&plane, &point); REQUIRE(dist == 0.23f); } TEST_CASE("Edge Get Direction", "[sconvcol]") { simd4f vertices[4] = { simd4f_create(-1.f, -1.f, 0.f, 0.f), simd4f_create(1.f, -1.f, 0.f, 0.f), simd4f_create(1.f, 1.f, 0.f, 0.f), simd4f_create(-1.f, 1.f, 0.f, 0.f)}; sch_face face = {nullptr}; sch_create_face(4, vertices, &face); simd4f dir; sch_edge_get_dir(face.edge, &dir); simd4f dir_ref = simd4f_create(1.f, 0.f, 0.f, 0.f); REQUIRE(1.f == simd4f_dot3_scalar(dir, dir_ref)); } TEST_CASE("HullBuilder", "[sconvcol]") { sch_hull_builder builder; builder.num_vertices = 3; GIVEN("A builder") { WHEN("is reset") { sch_builder_reset(&builder); THEN("number of vertices and faces is set to 0") { REQUIRE(builder.num_vertices == 0); REQUIRE(builder.num_faces == 0); } WHEN("adding a vertex") { int num_vertices = builder.num_vertices; simd4f vertex = simd4f_create(1.f, 0.f, 0.f, 1.f); sch_builder_face_begin(&builder); sch_builder_face_vertex(&builder, vertex); THEN("number of vertices increased") { REQUIRE(builder.num_vertices > num_vertices); } } } } GIVEN("An empty builder") { sch_builder_reset(&builder); simd4f vertex0 = simd4f_create(0.f, 0.f, 0.f, 1.f); simd4f vertex1 = simd4f_create(1.f, 0.f, 0.f, 1.f); simd4f vertex2 = simd4f_create(0.5f, 1.f, 0.f, 1.f); WHEN("adding two vertices ") { sch_builder_face_begin(&builder); sch_builder_face_vertex(&builder, vertex0); sch_builder_face_vertex(&builder, vertex1); WHEN("ending the face") { sch_builder_face_end(&builder); THEN("face idx range goes from 0 to 1") { REQUIRE(builder.num_faces == 1); REQUIRE(builder.num_vertices == 2); REQUIRE(builder.face_vert_idx_start[0] == 0); REQUIRE(builder.face_vert_idx_end[0] == 1); } } WHEN("creating a triangle") { sch_builder_face_vertex(&builder, vertex2); sch_builder_face_end(&builder); THEN("face idx range goes from 0 to 2") { REQUIRE(builder.num_faces == 1); REQUIRE(builder.num_vertices == 3); REQUIRE(builder.face_vert_idx_start[0] == 0); REQUIRE(builder.face_vert_idx_end[0] == 2); } WHEN("creating a hull") { sch_hull hull; SchHullResult result = sch_builder_create_hull(&builder, &hull); THEN("verify triangle hull") { REQUIRE(result == SchHullResultOpenHull); REQUIRE(hull.num_faces == 1); sch_face* face = &hull.faces[0]; sch_vert* hull_vert0 = face->edge->vert; sch_vert* hull_vert1 = face->edge->next->vert; sch_vert* hull_vert2 = face->edge->next->next->vert; REQUIRE(sch_simd4f_equal(hull_vert0->p, vertex0)); REQUIRE(sch_simd4f_equal(hull_vert1->p, vertex1)); REQUIRE(sch_simd4f_equal(hull_vert2->p, vertex2)); REQUIRE(face->edge->next->next->next == face->edge); } sch_hull_free_memory(&hull); } WHEN("adding concave face") { sch_hull hull; SchHullResult result = sch_builder_create_hull(&builder, &hull); simd4f vertex3 = simd4f_create(0.5f, 0.25f, 0.1337f, 1.f); sch_builder_face_begin(&builder); sch_builder_face_vertex(&builder, vertex0); sch_builder_face_vertex(&builder, vertex1); sch_builder_face_vertex(&builder, vertex3); sch_builder_face_end(&builder); THEN("check face and vertex definitions") { REQUIRE(builder.num_faces == 2); REQUIRE(builder.num_vertices == 4); REQUIRE(builder.face_vert_idx_start[0] == 0); REQUIRE(builder.face_vert_idx_end[0] == 2); REQUIRE(builder.face_vert_idx_start[1] == 3); REQUIRE(builder.face_vert_idx_end[1] == 5); } THEN("hull creation fails") { sch_hull concave_hull; SchHullResult result = sch_builder_create_hull(&builder, &concave_hull); REQUIRE(result == SchHullResultConcaveVertex); sch_hull_free_memory(&concave_hull); } sch_hull_free_memory(&hull); } WHEN("adding adjacent clockwise winded face") { simd4f vertex4 = simd4f_create(0.5f, -0.25f, 0, 1.f); sch_builder_face_begin(&builder); sch_builder_face_vertex(&builder, vertex0); sch_builder_face_vertex(&builder, vertex1); sch_builder_face_vertex(&builder, vertex4); sch_builder_face_end(&builder); THEN("hull creation fails") { sch_hull hull; SchHullResult result = sch_builder_create_hull(&builder, &hull); REQUIRE(result == SchHullResultWrongWinding); sch_hull_free_memory(&hull); } } WHEN("adding adjacent counter clockwise winded face") { simd4f vertex4 = simd4f_create(0.5f, -0.25f, 0, 1.f); sch_builder_face_begin(&builder); sch_builder_face_vertex(&builder, vertex0); sch_builder_face_vertex(&builder, vertex4); sch_builder_face_vertex(&builder, vertex1); sch_builder_face_end(&builder); THEN("edge v0-v1 has twin edge v1-v0") { sch_hull hull; SchHullResult result = sch_builder_create_hull(&builder, &hull); REQUIRE(result == SchHullResultOpenHull); sch_edge* edge_v0_v1 = sch_hull_find_edge(&hull, vertex0, vertex1); sch_edge* edge_v1_v0 = sch_hull_find_edge(&hull, vertex1, vertex0); REQUIRE (edge_v0_v1 != NULL); REQUIRE (edge_v1_v0->twin == edge_v0_v1); sch_hull_free_memory(&hull); } } } } WHEN("creating a tetrahedron ") { simd4f vertex3 = simd4f_create (0.5f, 0.f, -0.5f, 1.f); // +z facing triangle sch_builder_face_begin(&builder); sch_builder_face_vertex(&builder, vertex0); sch_builder_face_vertex(&builder, vertex1); sch_builder_face_vertex(&builder, vertex2); sch_builder_face_end(&builder); // +x,-z facing triangle sch_builder_face_begin(&builder); sch_builder_face_vertex(&builder, vertex1); sch_builder_face_vertex(&builder, vertex3); sch_builder_face_vertex(&builder, vertex2); sch_builder_face_end(&builder); // -x,-z facing triangle sch_builder_face_begin(&builder); sch_builder_face_vertex(&builder, vertex0); sch_builder_face_vertex(&builder, vertex2); sch_builder_face_vertex(&builder, vertex3); sch_builder_face_end(&builder); // -y facing triangle sch_builder_face_begin(&builder); sch_builder_face_vertex(&builder, vertex0); sch_builder_face_vertex(&builder, vertex3); sch_builder_face_vertex(&builder, vertex1); sch_builder_face_end(&builder); THEN("results in a closed hull") { sch_hull hull; SchHullResult result = sch_builder_create_hull(&builder, &hull); REQUIRE (result == SchHullResultOK); sch_hull_free_memory(&hull); } } } } TEST_CASE("UnitCubeSupport", "[sconvcol]") { GIVEN("A unit cube hull") { sch_hull hull; sch_create_unitbox(&hull); WHEN("Querying support for 2, 2, 2") { simd4f support; simd4f normal = simd4f_create(2.f, 2.f, 2.f, 1.f); sch_hull_get_support(&hull, normal, &support); THEN ("support is 0.5, 0.5, 0.5") { simd4f reference = simd4f_create (0.5f, 0.5f, 0.5f, 1.f); REQUIRE (sch_simd4f_equal(reference, support)); } } WHEN("Querying support for -2, -2, -2") { simd4f support; simd4f normal = simd4f_create(-2.f, -2.f, -2.f, 1.f); sch_hull_get_support(&hull, normal, &support); THEN ("support is -0.5, -0.5, -0.5") { simd4f reference = simd4f_create (-0.5f, -0.5f, -0.5f, 1.f); REQUIRE (sch_simd4f_equal(reference, support)); } } WHEN("Querying support for 0, 1, 0") { simd4f support; simd4f normal = simd4f_create(0.f, 1.f, 0.f, 1.f); sch_hull_get_support(&hull, normal, &support); THEN ("y component of support is 0.5") { REQUIRE (simd4f_get_y(support) == 0.5); } } sch_hull_free_memory(&hull); } } TEST_CASE("UnitCubeTransform", "[sconvcol]") { GIVEN("A unit cube hull") { sch_hull hull; sch_create_unitbox(&hull); WHEN ("not transforming cube") { THEN ("center is at 0,0,0") { REQUIRE (sch_simd4f_equal(simd4f_create(0.f, 0.f, 0.f, 1.f), hull.center)); } } WHEN ("translating by 1, 2, 3") { sch_hull_translate(&hull, 1.f, 2.f, 3.f); THEN ("center is at 1, 2, 3") { REQUIRE (sch_simd4f_equal(simd4f_create(1.f, 2.f, 3.f, 1.f), hull.center)); } THEN ("is equivalent to transform by translation matrix") { sch_hull hull_trans_mat; sch_create_unitbox(&hull_trans_mat); simd4x4f trans_mat; simd4x4f_translation(&trans_mat, 1.f, 2.f, 3.f); sch_hull_transform(&hull_trans_mat, trans_mat); REQUIRE (sch_simd4f_equal(hull.center, hull_trans_mat.center)); sch_hull_free_memory(&hull_trans_mat); } } WHEN ("rotating around y by 90 degrees") { simd4f vert0 = simd4f_create (0.5f, -0.5f, 0.5f, 1.f); REQUIRE (sch_simd4f_equal(vert0, hull.vertices[0].p)); simd4f vert0_rot = simd4f_create (0.5f, -0.5f, -0.5f, 1.f); sch_hull_rotate(&hull, M_PI * 0.5, simd4f_create (1.f, 0.f, 0.f, 1.f)); THEN ("center is at 0, 0, 0") { REQUIRE (sch_simd4f_equal(simd4f_create(0.f, 0.f, 0.f, 1.f), hull.center)); REQUIRE (sch_simd4f_close(vert0_rot, hull.vertices[0].p, 1.0e-5f)); } } sch_hull_free_memory(&hull); } } TEST_CASE ("UnitCubeSAT", "[sconvcol]") { sch_hull hull_A; sch_create_unitbox(&hull_A); sch_hull hull_B; sch_create_unitbox(&hull_B); sch_manifold manifold; sch_manifold_alloc(&manifold, SCH_BUILDER_MAX_NUM_FACE_VERTICES); GIVEN ("Two unit boxes separated by 1.1 along x axis") { simd4x4f translation; simd4x4f_translation( &translation, 0.5f + 0.4f * sqrtf(2.), 0.f, 0.f); THEN("Boxes separated") { sch_hull_transform(&hull_B, translation); simd4x4f identity; simd4x4f_identity(&identity); bool separated = sch_hull_sat(&hull_A, &identity, &hull_B, &identity, &manifold); REQUIRE(separated); } THEN("Boxes separated when supplying trans_B") { simd4x4f identity; simd4x4f_identity(&identity); bool separated = sch_hull_sat(&hull_A, &identity, &hull_B, &translation, &manifold); REQUIRE(separated); } THEN("Boxes separated when supplying trans_A") { simd4f r = simd4f_create(-0.5f -0.51f * sqrtf(2.), 0.f, 0.f, 1.f); simd4x4f_translation( &translation, simd4f_get_x(r), simd4f_get_y(r), simd4f_get_z(r)); simd4x4f identity; simd4x4f_identity(&identity); bool separated = sch_hull_sat(&hull_A, &translation, &hull_B, &identity, &manifold); REQUIRE(separated); } THEN("Boxes separated when supplying rot_trans to B") { simd4x4f identity; simd4x4f_identity(&identity); simd4x4f rot; simd4x4f_axis_rotation(&rot, 0.4f, simd4f_create (0.f, 1.f, 0.f, 1.f)); simd4x4f translation; simd4x4f_translation(&translation, 0.5f + 0.51f * sqrtf(2.), 0.0f, 0.f); simd4x4f rot_trans; simd4x4f_matrix_mul(&translation, &rot, &rot_trans); bool separated = sch_hull_sat(&hull_A, &identity, &hull_B, &rot_trans, &manifold); REQUIRE(separated); } THEN("Boxes separated when supplying rot_trans to A") { simd4x4f identity; simd4x4f_identity(&identity); simd4x4f rot; simd4x4f_axis_rotation(&rot, 0.4f, simd4f_create (0.f, 1.f, 0.f, 1.f)); simd4x4f translation; simd4x4f_translation(&translation, -0.5f - 0.51f * sqrtf(2.), 0.0f, 0.f); simd4x4f rot_trans; simd4x4f_matrix_mul(&translation, &rot, &rot_trans); bool separated = sch_hull_sat(&hull_A, &rot_trans, &hull_B, &identity, &manifold); REQUIRE(separated); } } GIVEN ("Box B in edge-edge contact with A") { simd4x4f rot_y; simd4x4f_axis_rotation(&rot_y, 0.25f * M_PI, simd4f_create (0.f, 1.f, 0.f, 1.f)); simd4x4f rot_z; simd4x4f_axis_rotation(&rot_z, 0.25f * M_PI, simd4f_create (0.f, 0.f, 1.f, 1.f)); simd4x4f trans_rot; simd4x4f_matrix_mul(&rot_y, &rot_z, &trans_rot); simd4x4f translation; simd4x4f_translation(&translation, 0.98f, 0.f, -0.98f); simd4x4f identity; simd4x4f_identity(&identity); bool separated = sch_hull_sat(&hull_A, &identity, &hull_B, &trans_rot, &manifold); REQUIRE(!separated); } GIVEN("Box B rotated by 45 degrees around y and translated along x by 1.1") { sch_hull_rotate(&hull_B, M_PI / 180.0f * 45.f, simd4f_create(0.f, 1.f, 0.f, 1.f)); sch_hull_translate(&hull_B, 1.1f, 0.f, 0.f); THEN("Boxes overlap") { simd4x4f identity; simd4x4f_identity(&identity); bool separated = sch_hull_sat(&hull_A, &identity, &hull_B, &identity, &manifold); REQUIRE(!separated); } } GIVEN("Box A rotated by 45 deg around z, Box B rotated by 45 degrees around y and translated along x by sqrt(2)") { sch_hull_rotate(&hull_A, M_PI / 180.0f * 45.f, simd4f_create(0.f, 0.f, 1.f, 1.f)); sch_hull_rotate(&hull_B, M_PI / 180.0f * 45.f, simd4f_create(0.f, 1.f, 0.f, 1.f)); sch_hull_translate(&hull_B, sqrt(2.f), 0.f, 0.f); THEN("Boxes overlap") { simd4x4f identity; simd4x4f_identity(&identity); bool separated = sch_hull_sat(&hull_A, &identity, &hull_B, &identity, &manifold); REQUIRE(!separated); } WHEN("Shifted by another 0.001 along x") { sch_hull_translate(&hull_B, 0.001f, 0.f, 0.f); THEN("Boxes are separated") { simd4x4f identity; simd4x4f_identity(&identity); bool separated = sch_hull_sat(&hull_A, &identity, &hull_B, &identity, &manifold); REQUIRE(separated); } } } GIVEN("Box B translated by 1z and rotated 45 degrees around z") { sch_hull_rotate(&hull_B, M_PI / 180.0f * 45.f, simd4f_create(0.f, 0.f, 1.f, 1.f)); sch_hull_translate(&hull_B, 0., 0.f, 0.97f); // THEN("Boxes overlap") { // simd4x4f identity; // simd4x4f_identity(&identity); // bool separated = sch_hull_sat(&hull_A, &identity, &hull_B, &identity, &manifold); // REQUIRE(!separated); // REQUIRE(manifold.num_points == 8); // } } GIVEN("Box B translated by 1x, 1.001z") { sch_hull_translate(&hull_B, 1., 0.f, 1.00f); // THEN("Boxes overlap") { // simd4x4f identity; // simd4x4f_identity(&identity); // bool separated = sch_hull_sat(&hull_A, &identity, &hull_B, &identity, &manifold); // REQUIRE(!separated); // REQUIRE(manifold.num_points == 8); // } } sch_manifold_free_memory(&manifold); sch_hull_free_memory(&hull_A); sch_hull_free_memory(&hull_B); } TEST_CASE("PlaneTests", "[sconvcol]") { GIVEN("Z=0 Plane") { sch_plane plane; plane.n = simd4f_create(0.f, 0.f, 1.f, 1.f); plane.p = simd4f_create(1.f, 1.2354f, 0.f, 1.f); WHEN("Querying point with z = -0.1") { simd4f p = simd4f_create (1231.3f, 552.2f, -0.1f, 1.f); float dist = sch_plane_distance (&plane, &p); THEN ("distance is -0.1") { REQUIRE (dist == -0.1f); } } WHEN ("Intersecting with line (5., 3., 2.) - (12., 332., SCH_EPS") { simd4f p0 = simd4f_create (5.f, 3.f, 1.f, 1.f); simd4f p1 = simd4f_create (12.f, 332.f, SCH_EPS, 1.f); simd4f result; bool is_intersecting = sch_plane_intersection(&plane, &p0, &p1, &result); THEN ("have intersection") { REQUIRE (is_intersecting); } WHEN ("Reversing the query") { simd4f result; bool is_intersecting = sch_plane_intersection(&plane, &p1, &p0, &result); THEN ("have intersection") { REQUIRE (is_intersecting); } } } WHEN ("Intersecting with line (5., 3., 2.) - (12., 332., SCH_EPS * 2") { simd4f p0 = simd4f_create (5.f, 3.f, 1.f, 1.f); simd4f p1 = simd4f_create (12.f, 332.f, SCH_EPS * 2.f, 1.f); simd4f result; bool is_intersecting = sch_plane_intersection(&plane, &p0, &p1, &result); THEN ("have no intersection") { REQUIRE (is_intersecting); } WHEN ("Reversing the query") { simd4f result; bool is_intersecting = sch_plane_intersection(&plane, &p1, &p0, &result); THEN ("have no intersection") { REQUIRE (is_intersecting); } } } WHEN("Projecting point (123.4, 332., 212.) onto plane") { simd4f p = simd4f_create (123.4f, 332.f, 212.f, 1.f); sch_plane_point_project(&plane, &p); THEN ("z component is 0.") { REQUIRE (simd4f_get_z(p) == 0.f); } WHEN("Using z = -212.0") { p = simd4f_create(123.4f, 332.f, -212.f, 1.f); sch_plane_point_project(&plane, &p); THEN("projected z component is 0.") { REQUIRE(simd4f_get_z(p) == 0.f); } } } } } TEST_CASE ("ClipFaces", "[sconvcol]") { sch_hull_builder builder; sch_hull triangle_hull; sch_hull quad_hull; // Build triangle sch_builder_reset(&builder); // top sch_builder_face_begin(&builder); sch_builder_face_vertex(&builder, simd4f_create (0.5f, -0.5f, 0.f, 1.f)); sch_builder_face_vertex(&builder, simd4f_create ( 0.0f, 0.5f, 0.f, 1.f)); sch_builder_face_vertex(&builder, simd4f_create ( -0.5f, -0.5f, 0.f, 1.f)); sch_builder_face_end(&builder); // bottom sch_builder_face_begin(&builder); sch_builder_face_vertex(&builder, simd4f_create (0.5f, -0.5f, 0.f, 1.f)); sch_builder_face_vertex(&builder, simd4f_create ( -0.5f, -0.5f, 0.f, 1.f)); sch_builder_face_vertex(&builder, simd4f_create ( 0.0f, 0.5f, 0.f, 1.f)); sch_builder_face_end(&builder); int hull_result = sch_builder_create_hull(&builder, &triangle_hull); triangle_hull.center = simd4f_create(0.f, 0.f, 0.f, 1.f); REQUIRE (hull_result == SchHullResultOK); // Build quad sch_builder_reset(&builder); // top sch_builder_face_begin(&builder); sch_builder_face_vertex(&builder, simd4f_create (-0.5f, -0.5f, 0.f, 1.f)); sch_builder_face_vertex(&builder, simd4f_create ( 0.5f, -0.5f, 0.f, 1.f)); sch_builder_face_vertex(&builder, simd4f_create ( 0.5f, 0.5f, 0.f, 1.f)); sch_builder_face_vertex(&builder, simd4f_create (-0.5f, 0.5f, 0.f, 1.f)); sch_builder_face_end(&builder); // bottom sch_builder_face_begin(&builder); sch_builder_face_vertex(&builder, simd4f_create(0.5f, -0.5f, 0.f, 1.f)); sch_builder_face_vertex(&builder, simd4f_create(-0.5f, -0.5f, 0.f, 1.f)); sch_builder_face_vertex(&builder, simd4f_create(-0.5f, 0.5f, 0.f, 1.f)); sch_builder_face_vertex(&builder, simd4f_create(0.5f, 0.5f, 0.f, 1.f)); sch_builder_face_end(&builder); hull_result = sch_builder_create_hull(&builder, &quad_hull); quad_hull.center = simd4f_create(0.f, 0.f, 0.f, 1.f); REQUIRE (hull_result == SchHullResultOK); GIVEN ("A Triangle and a Quad") { WHEN ("Translating the Quad along +Y") { sch_hull_translate(&quad_hull, 0.f, 0.5f, 0.f); sch_manifold manifold; sch_manifold_alloc(&manifold, SCH_BUILDER_MAX_NUM_FACE_VERTICES); sch_manifold_reset(&manifold); sch_clip_faces(&triangle_hull.faces[0], &quad_hull.faces[1], &manifold); REQUIRE (manifold.num_points == 3); sch_manifold_free_memory(&manifold); } } }