// Copyright 2021 DeepMind Technologies Limited // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // Tests for user/user_objects.cc. #include #include #include #include #include #include #include #include #include #include #include #include #include #include "src/cc/array_safety.h" #include "test/fixture.h" namespace mujoco { namespace { using MjCMeshTest = MujocoTest; static const char* const kMeshPath = "user/testdata/mesh.xml"; static const char* const kDuplicateVerticesPath = "user/testdata/duplicate_vertices.xml"; static const char* const kCubePath = "user/testdata/cube.xml"; static const char* const kCubeCompletePath = "user/testdata/cube_complete.obj"; static const char* const kTorusPath = "user/testdata/torus.xml"; static const char* const kTorusMaxhullVertPath = "user/testdata/torus_maxhullvert.xml"; static const char* const kTorusDefaultMaxhullVertPath = "user/testdata/torus_maxhullvert_default.xml"; static const char* const kCompareInertiaPath = "user/testdata/inertia_compare.xml"; static const char* const kConvexInertiaPath = "user/testdata/inertia_convex.xml"; static const char* const kConcaveInertiaPath = "user/testdata/inertia_concave.xml"; static const char* const kShellInertiaPath = "user/testdata/inertia_shell.xml"; static const char* const kTorusQuadsPath = "user/testdata/torus_quads.xml"; static const char* const kTexturedTorusPath = "user/testdata/textured_torus.xml"; static const char* const kDuplicateOBJPath = "user/testdata/duplicate.xml"; static const char* const kMalformedFaceOBJPath = "user/testdata/malformed_face.xml"; static const char* const kCubeSkinPath = "user/testdata/cube_skin.xml"; using ::testing::ElementsAre; using ::testing::HasSubstr; using ::testing::IsNull; using ::testing::NotNull; static constexpr mjtNum kMaxAbsErr = std::numeric_limits::epsilon(); // ------------- test invalid filenames ---------------------------------------- TEST_F(MjCMeshTest, UnknownMeshFormat) { static constexpr char xml_format[] = R"( )"; std::vector invalid_names = { "noextension", "anobj", "f", "mesh.exe", "file%s" }; mjVFS vfs; mj_defaultVFS(&vfs); for (const auto& name : invalid_names) { mj_addBufferVFS(&vfs, name.c_str(), nullptr, 0); std::string xml = absl::StrFormat(xml_format, name); std::array error; mjModel* model = LoadModelFromString(xml.c_str(), error.data(), error.size(), &vfs); ASSERT_THAT(model, testing::IsNull()) << "Should fail to load a mesh named: " << name; EXPECT_THAT(error.data(), HasSubstr("unknown or unsupported mesh file: ")); EXPECT_THAT(error.data(), HasSubstr(name)); } mj_deleteVFS(&vfs); } // -------------------- test OS filesystem fallback ---------------------------- TEST_F(MjCMeshTest, LoadMSHWithVFS) { static constexpr char xml[] = R"( )"; char error[1024]; size_t error_sz = 1024; // load VFS on the heap auto vfs = std::make_unique(); mj_defaultVFS(vfs.get()); // should fallback to OS filesystem mjModel* model = LoadModelFromString(xml, error, error_sz, vfs.get()); EXPECT_THAT(model, IsNull()); EXPECT_THAT(error, HasSubstr("Error opening file")); mj_deleteVFS(vfs.get()); } TEST_F(MjCMeshTest, LoadOBJWithVFS) { static constexpr char xml[] = R"( )"; char error[1024]; size_t error_sz = 1024; // load VFS on the heap auto vfs = std::make_unique(); mj_defaultVFS(vfs.get()); // should fallback to OS filesystem mjModel* model = LoadModelFromString(xml, error, error_sz, vfs.get()); EXPECT_THAT(model, IsNull()); EXPECT_THAT(error, HasSubstr("Error opening file")); mj_deleteVFS(vfs.get()); } TEST_F(MjCMeshTest, LoadSTLWithVFS) { static constexpr char xml[] = R"( )"; char error[1024]; size_t error_sz = 1024; // load VFS on the heap auto vfs = std::make_unique(); mj_defaultVFS(vfs.get()); // should fallback to OS filesystem mjModel* model = LoadModelFromString(xml, error, error_sz, vfs.get()); EXPECT_THAT(model, IsNull()); EXPECT_THAT(error, HasSubstr("Error opening file")); mj_deleteVFS(vfs.get()); } // ------------- test content_type attributes ---------------------------------- TEST_F(MjCMeshTest, LoadMSHWithContentType) { static constexpr char xml[] = R"( )"; char error[1024]; size_t error_sz = 1024; // load VFS on the heap auto vfs = std::make_unique(); mj_defaultVFS(vfs.get()); // should try opening the file (not found obviously) mjModel* model = LoadModelFromString(xml, error, error_sz, vfs.get()); EXPECT_THAT(model, IsNull()); EXPECT_THAT(error, HasSubstr("Error opening file")); mj_deleteVFS(vfs.get()); } TEST_F(MjCMeshTest, LoadOBJWithContentType) { static constexpr char xml[] = R"( )"; char error[1024]; size_t error_sz = 1024; // load VFS on the heap auto vfs = std::make_unique(); mj_defaultVFS(vfs.get()); // should try opening the file (not found obviously) mjModel* model = LoadModelFromString(xml, error, error_sz, vfs.get()); EXPECT_THAT(model, IsNull()); EXPECT_THAT(error, HasSubstr("Error opening file")); mj_deleteVFS(vfs.get()); } TEST_F(MjCMeshTest, LoadSTLWithContentType) { static constexpr char xml[] = R"( )"; char error[1024]; size_t error_sz = 1024; // load VFS on the heap auto vfs = std::make_unique(); mj_defaultVFS(vfs.get()); // should try opening the file (not found obviously) mjModel* model = LoadModelFromString(xml, error, error_sz, vfs.get()); EXPECT_THAT(model, IsNull()); EXPECT_THAT(error, HasSubstr("Error opening file")); mj_deleteVFS(vfs.get()); } TEST_F(MjCMeshTest, LoadMSHWithContentTypeError) { static constexpr char xml[] = R"( )"; char error[1024]; size_t error_sz = 1024; // load VFS on the heap mjVFS vfs; mj_defaultVFS(&vfs); mj_addBufferVFS(&vfs, "some_file", nullptr, 0); // should error with unknown file type mjModel* model = LoadModelFromString(xml, error, error_sz, &vfs); EXPECT_THAT(model, IsNull()); EXPECT_THAT(error, HasSubstr("unsupported mesh type: 'model/unknown'")); mj_deleteVFS(&vfs); } TEST_F(MjCMeshTest, LoadMSHWithInvalidContentType) { static constexpr char xml[] = R"( )"; char error[1024]; size_t error_sz = 1024; // load VFS on the heap mjVFS vfs; mj_defaultVFS(&vfs); mj_addBufferVFS(&vfs, "some_file", nullptr, 0); // should error with unknown file type mjModel* model = LoadModelFromString(xml, error, error_sz, &vfs); EXPECT_THAT(model, IsNull()); EXPECT_THAT(error, HasSubstr("invalid content type: 'model'")); mj_deleteVFS(&vfs); } TEST_F(MjCMeshTest, LoadMSHWithContentTypeParam) { static constexpr char xml[] = R"( )"; char error[1024]; size_t error_sz = 1024; // load VFS on the heap auto vfs = std::make_unique(); mj_defaultVFS(vfs.get()); // should try opening the file (not found obviously) mjModel* model = LoadModelFromString(xml, error, error_sz, vfs.get()); EXPECT_THAT(model, IsNull()); EXPECT_THAT(error, HasSubstr("Error opening file")); mj_deleteVFS(vfs.get()); } // ------------- test vertex deduplication (STL) ------------------------------ TEST_F(MjCMeshTest, DeduplicateSTLVertices) { const std::string xml_path = GetTestDataFilePath(kDuplicateVerticesPath); char error[1024]; size_t error_sz = 1024; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error, error_sz); ASSERT_THAT(model, NotNull()) << error; ASSERT_EQ(model->nmeshvert, 4); mj_deleteModel(model); } // -------------------- test Mesh loading (MSH) -------------------------------- TEST_F(MjCMeshTest, LoadMSH) { const std::string xml_path = GetTestDataFilePath(kMeshPath); char error[1024]; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; ASSERT_EQ(model->nmeshvert, 36); mj_deleteModel(model); } // ------------- test OBJ loading ---------------------------------------------- using MjCMeshTest = MujocoTest; TEST_F(MjCMeshTest, LoadCube) { const std::string xml_path = GetTestDataFilePath(kCubePath); mjModel* model = mj_loadXML(xml_path.c_str(), 0, nullptr, 0); ASSERT_GT(model->ngeom, 0); ASSERT_EQ(model->nmeshvert, 8); ASSERT_EQ(model->nmeshface, 12); mj_deleteModel(model); } TEST_F(MjCMeshTest, LoadTorus) { const std::string xml_path = GetTestDataFilePath(kTorusPath); std::array error; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error.data(), error.size()); ASSERT_GT(model->ngeom, 0); ASSERT_GT(model->nmeshvert, 0); mj_deleteModel(model); } TEST_F(MjCMeshTest, LoadTorusQuads) { const std::string xml_path = GetTestDataFilePath(kTorusQuadsPath); std::array error; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error.data(), error.size()); ASSERT_GT(model->ngeom, 0); ASSERT_GT(model->nmeshvert, 0); mj_deleteModel(model); } TEST_F(MjCMeshTest, LoadTexturedTorus) { const std::string xml_path = GetTestDataFilePath(kTexturedTorusPath); std::array error; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error.data(), error.size()); ASSERT_GT(model->ngeom, 0); ASSERT_GT(model->nmeshvert, 0); ASSERT_GT(model->ntex, 0); ASSERT_GT(model->ntexdata, 0); mj_deleteModel(model); } TEST_F(MjCMeshTest, KeepDuplicateOBJVertices) { const std::string xml_path = GetTestDataFilePath(kDuplicateOBJPath); char error[1024]; size_t error_sz = 1024; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error, error_sz); ASSERT_EQ(model->nmeshvert, 16); mj_deleteModel(model); } TEST_F(MjCMeshTest, SaveMeshOnce) { const std::string xml_path = GetTestDataFilePath(kCubePath); std::array error; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error.data(), error.size()); // Confirm the mesh file is loaded and stored in paths EXPECT_EQ( std::string(&model->paths[model->mesh_pathadr[0]]), "cube.obj"); std::string saved_xml = SaveAndReadXml(model); EXPECT_THAT(saved_xml, Not(testing::HasSubstr("vertex"))); mj_deleteModel(model); } TEST_F(MjCMeshTest, TinyMeshLoads) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; mj_deleteModel(model); } // ------------- test max hull vert ------------------------------------------- TEST_F(MjCMeshTest, MaxHullVert) { const std::string xml_path = GetTestDataFilePath(kTorusMaxhullVertPath); std::array error; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error.data(), error.size()); ASSERT_GT(model->ngeom, 0); ASSERT_EQ(model->mesh_graph[0], 4); mj_deleteModel(model); } TEST_F(MjCMeshTest, MaxHullVertDefault) { const std::string xml_path = GetTestDataFilePath(kTorusDefaultMaxhullVertPath); std::array error; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error.data(), error.size()); ASSERT_GT(model->ngeom, 0); ASSERT_EQ(model->mesh_graph[0], 64); mj_deleteModel(model); } // ------------- test inline loading ------------------------------------------ TEST_F(MjCMeshTest, FaceNormalAutogenerated) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; mj_deleteModel(model); } // ------------- test inertia ------------------------------------------------- TEST_F(MjCMeshTest, SmallInertiaLoads) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; mj_deleteModel(model); } TEST_F(MjCMeshTest, TinyInertiaFails) { static constexpr char xml[] = R"( )"; std::array error; LoadModelFromString(xml, error.data(), error.size()); EXPECT_THAT( error.data(), HasSubstr( "mass and inertia of moving bodies must be larger than mjMINVAL")); EXPECT_THAT(error.data(), HasSubstr("Element name 'tiny_body'")); } TEST_F(MjCMeshTest, FlippedFaceAllowedLegacyInertia) { const std::string xml_path = GetTestDataFilePath(kMalformedFaceOBJPath); char error[1024]; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; EXPECT_THAT(model->nmeshface, 4); mj_deleteModel(model); } TEST_F(MjCMeshTest, MissingFaceAllowedConvexInertia) { const std::string xml_path = GetTestDataFilePath(kCompareInertiaPath); char error[1024]; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; EXPECT_THAT(model->nmeshface, 7); EXPECT_NEAR(model->body_inertia[3], model->body_inertia[6], kMaxAbsErr); EXPECT_NEAR(model->body_inertia[4], model->body_inertia[7], kMaxAbsErr); EXPECT_NEAR(model->body_inertia[5], model->body_inertia[8], kMaxAbsErr); mj_deleteModel(model); } TEST_F(MjCMeshTest, FlippedFaceFailsExactInertia) { static constexpr char xml[] = R"( )"; std::array error; mjModel* model = LoadModelFromString(xml, error.data(), error.size()); EXPECT_THAT(model, testing::IsNull()); EXPECT_THAT(error.data(), HasSubstr( "Error: faces of mesh 'example_mesh' have inconsistent orientation. " "Please check the faces containing the vertices 1 and 2.")); } void CheckTetrahedronWasRescaled(mjModel* model) { // The rotated and rescaled positions of the tetrahedron // with vertices (0, 0, 0), (1, 0, 0), (0, 2, 0), (0, 0, 3) // after mesh preprocessing is performed std::vector vert = { -0.51610732078552246, -0.57402724027633667, -0.5283237099647522, 0.42337465286254883, -0.90627568960189819, -0.61189728975296021, 0.065528042614459991, 1.2306677103042603, -1.1645441055297852, 0.027204651385545731, 0.24963514506816864, 2.3047652244567871}; mjtNum tolerance = std::numeric_limits::epsilon(); for (int i=0; i < 12; ++i) { EXPECT_NEAR(model->mesh_vert[i], vert[i], tolerance); } } TEST_F(MjCMeshTest, FlippedFaceAllowedWorld) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; CheckTetrahedronWasRescaled(model); mj_deleteModel(model); } TEST_F(MjCMeshTest, FlippedFaceAllowedNoMass) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; CheckTetrahedronWasRescaled(model); mj_deleteModel(model); } TEST_F(MjCMeshTest, FlippedFaceAllowedInertial) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; CheckTetrahedronWasRescaled(model); mj_deleteModel(model); } TEST_F(MjCMeshTest, FlippedFaceAllowedNegligibleArea) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; CheckTetrahedronWasRescaled(model); mj_deleteModel(model); } TEST_F(MjCMeshTest, AreaTooSmall) { static constexpr char xml[] = R"( )"; std::array error; mjModel* model = LoadModelFromString(xml, error.data(), error.size()); EXPECT_THAT(model, testing::IsNull()); EXPECT_THAT(error.data(), HasSubstr("mesh surface area is too small")); } TEST_F(MjCMeshTest, VolumeTooSmall) { static constexpr char xml[] = R"( )"; std::array error; mjModel* model = LoadModelFromString(xml, error.data(), error.size()); EXPECT_THAT(model, testing::IsNull()); EXPECT_THAT(error.data(), HasSubstr("mesh volume is too small")); mj_deleteModel(model); } TEST_F(MjCMeshTest, VisualVolumeTooSmall) { static constexpr char xml[] = R"( )"; std::array error; mjModel* model = LoadModelFromString(xml, error.data(), error.size()); EXPECT_THAT(model, testing::IsNull()); EXPECT_THAT(error.data(), HasSubstr("mesh volume is too small")); mj_deleteModel(model); } TEST_F(MjCMeshTest, VisualVolumeSmallAllowedShell) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; EXPECT_LE(mju_abs(model->geom_size[0]), 1); EXPECT_LE(mju_abs(model->geom_size[1]), 1); EXPECT_LE(mju_abs(model->geom_size[2]), 1); mj_deleteModel(model); } TEST_F(MjCMeshTest, VolumeSmallAllowedShell) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; EXPECT_LE(mju_abs(model->geom_size[0]), 1); EXPECT_LE(mju_abs(model->geom_size[1]), 1); EXPECT_LE(mju_abs(model->geom_size[2]), 1); mj_deleteModel(model); } TEST_F(MjCMeshTest, VolumeNegativeThrowsError) { static constexpr char xml[] = R"( MESH_DEFINITIONS GEOM_DEFINITIONS )"; static constexpr char bad_mesh[] = R"( \n" )"; static constexpr char geom[] = R"(\n)"; for (int nmesh : {3, 16, 17, 50}) { std::string mesh_definitions = ""; for (int i = 1; i < nmesh+1; i++) { mesh_definitions += absl::StrFormat(bad_mesh, i); } std::string geom_definitions = ""; for (int i = 1; i < nmesh+1; i++) { geom_definitions += absl::StrFormat(geom, i); } std::string xml_str = xml; absl::StrReplaceAll({{"MESH_DEFINITIONS", mesh_definitions}, {"GEOM_DEFINITIONS", geom_definitions}}, &xml_str); std::array error; mjModel* model = LoadModelFromString(xml_str.c_str(), error.data(), error.size()); EXPECT_THAT(model, IsNull()); EXPECT_THAT(error.data(), HasSubstr("mesh volume is negative")); } } TEST_F(MjCMeshTest, MeshIgnoresDefaultDensity) { static constexpr char xml[] = R"( )"; char error[1024]; mjSpec* spec = mj_parseXMLString(xml, 0, error, sizeof(error)); EXPECT_THAT(spec, NotNull()) << error; mjModel* m1 = mj_compile(spec, nullptr); EXPECT_THAT(m1, NotNull()); mj_deleteModel(m1); mjModel* m2 = mj_compile(spec, nullptr); EXPECT_THAT(m2, NotNull()); mj_deleteModel(m2); mj_deleteSpec(spec); } // ------------- test concave and shell inertia -------------------------------- TEST_F(MjCMeshTest, ExactConcaveInertia) { const std::string xml_path = GetTestDataFilePath(kConcaveInertiaPath); std::array error; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error.data(), error.size()); // analytic computation of 1x1x1 cube with a .8x.8x.9 hole // see https://en.wikipedia.org/wiki/List_of_moments_of_inertia mjtNum density = 2.; mjtNum m_hole = .9 * .8 * .8 * density; mjtNum m_cube = 1. * density; mjtNum m_concave_cube = m_cube - m_hole; mjtNum I_cube = m_cube/6.; // due to the asymmetric hole, the com position has changed // so we need to use https://en.wikipedia.org/wiki/Parallel_axis_theorem mjtNum d_cube = .5 - model->body_ipos[5]; mjtNum d_hole = .55 - model->body_ipos[5]; mjtNum I1 = I_cube - m_hole*(.8*.8 + .8*.8)/12; mjtNum I2 = I_cube - m_hole*(.8*.8 + .9*.9)/12 + m_cube*d_cube*d_cube - m_hole*d_hole*d_hole; EXPECT_NEAR(model->body_mass[1], m_concave_cube, kMaxAbsErr); EXPECT_NEAR(model->body_mass[2], m_concave_cube, kMaxAbsErr); EXPECT_NEAR(model->body_mass[3], m_concave_cube, kMaxAbsErr); EXPECT_NEAR(model->body_mass[4], m_concave_cube, kMaxAbsErr); for (int i = 3; i < 15; i += 3) { EXPECT_NEAR(model->body_inertia[i], I1, kMaxAbsErr); EXPECT_NEAR(model->body_inertia[i+1], I2, kMaxAbsErr); EXPECT_NEAR(model->body_inertia[i+2], I2, kMaxAbsErr); } mj_deleteModel(model); } TEST_F(MjCMeshTest, ExactConvexInertia) { const std::string xml_path = GetTestDataFilePath(kConvexInertiaPath); std::array error; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error.data(), error.size()); // https://en.wikipedia.org/wiki/List_of_moments_of_inertia mjtNum m_solid_cube = 1.; mjtNum I_solid_cube = 1./6. * m_solid_cube; EXPECT_LE(mju_abs(model->body_mass[1] - m_solid_cube), kMaxAbsErr); EXPECT_LE(mju_abs(model->body_mass[2] - m_solid_cube), kMaxAbsErr); for (int i = 3; i < 9; i++) { EXPECT_LE(mju_abs(model->body_inertia[i] - I_solid_cube), kMaxAbsErr); } mj_deleteModel(model); } TEST_F(MjCMeshTest, ExactShellInertia) { const std::string xml_path = GetTestDataFilePath(kShellInertiaPath); std::array error; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error.data(), error.size()); // see https://en.wikipedia.org/wiki/List_of_moments_of_inertia mjtNum m_hollow_cube = 6.; mjtNum I_hollow_cube = 5./18. * m_hollow_cube; EXPECT_LE(mju_abs(model->body_mass[1] - m_hollow_cube), kMaxAbsErr); EXPECT_LE(mju_abs(model->body_inertia[3] - I_hollow_cube), kMaxAbsErr); EXPECT_LE(mju_abs(model->body_inertia[4] - I_hollow_cube), kMaxAbsErr); EXPECT_LE(mju_abs(model->body_inertia[5] - I_hollow_cube), kMaxAbsErr); mj_deleteModel(model); } TEST_F(MjCMeshTest, MeshPosQuat) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; // loading the mesh results in an offset of the geom's pos and quat due to the // fact that the geom's center is not the volumetric center of the mesh. To // recover the geom's originally specified pose, the offset used is stored in // mesh_pos and mesh_quat. In order to recover the originally specified pose // and orientation, first invert the specified mesh_pos and mesh_quat mjtNum inverse_mesh_pos[3]; mjtNum inverse_mesh_quat[4]; mju_negPose(inverse_mesh_pos, inverse_mesh_quat, &model->mesh_pos[0], &model->mesh_quat[0]); // apply the inverted mesh_pos and inverted mesh_quat to the geom's pos and // quat. It should match the originally specified values mjtNum recovered_pos[3]; mjtNum recovered_quat[4]; mju_mulPose(recovered_pos, recovered_quat, &model->geom_pos[0], &model->geom_quat[0], inverse_mesh_pos, inverse_mesh_quat); EXPECT_NEAR(recovered_pos[0], 0, 1e-12); EXPECT_NEAR(recovered_pos[1], 0, 1e-12); EXPECT_NEAR(recovered_pos[2], 0, 1e-12); EXPECT_NEAR(recovered_quat[0], 1, 1e-12); EXPECT_NEAR(recovered_quat[1], 0, 1e-12); EXPECT_NEAR(recovered_quat[2], 0, 1e-12); EXPECT_NEAR(recovered_quat[3], 0, 1e-12); // same test on the other geom mju_negPose(inverse_mesh_pos, inverse_mesh_quat, &model->mesh_pos[0], &model->mesh_quat[0]); mju_mulPose(recovered_pos, recovered_quat, &model->geom_pos[3], &model->geom_quat[4], inverse_mesh_pos, inverse_mesh_quat); EXPECT_NEAR(recovered_pos[0], 1, 1e-12); EXPECT_NEAR(recovered_pos[1], 2, 1e-12); EXPECT_NEAR(recovered_pos[2], 3, 1e-12); EXPECT_NEAR(recovered_quat[0], 0.5, 1e-12); EXPECT_NEAR(recovered_quat[1], 0.5, 1e-12); EXPECT_NEAR(recovered_quat[2], 0.5, 1e-12); EXPECT_NEAR(recovered_quat[3], 0.5, 1e-12); mj_deleteModel(model); } TEST_F(MjCMeshTest, MeshPosQuatShellInertia) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; // loading the mesh results in an offset of the geom's pos and quat due to the // fact that the geom's center is not the volumetric center of the mesh. To // recover the geom's originally specified pose, the offset used is stored in // mesh_pos and mesh_quat. In order to recover the originally specified pose // and orientation, first invert the specified mesh_pos and mesh_quat mjtNum inverse_mesh_pos[3]; mjtNum inverse_mesh_quat[4]; mju_negPose(inverse_mesh_pos, inverse_mesh_quat, &model->mesh_pos[0], &model->mesh_quat[0]); // apply the inverted mesh_pos and inverted mesh_quat to the geom's pos and // quat. It should match the originally specified values mjtNum recovered_pos[3]; mjtNum recovered_quat[4]; mju_mulPose(recovered_pos, recovered_quat, &model->geom_pos[0], &model->geom_quat[0], inverse_mesh_pos, inverse_mesh_quat); EXPECT_NEAR(recovered_pos[0], 0, 1e-12); EXPECT_NEAR(recovered_pos[1], 0, 1e-12); EXPECT_NEAR(recovered_pos[2], 0, 1e-12); EXPECT_NEAR(recovered_quat[0], 1, 1e-12); EXPECT_NEAR(recovered_quat[1], 0, 1e-12); EXPECT_NEAR(recovered_quat[2], 0, 1e-12); EXPECT_NEAR(recovered_quat[3], 0, 1e-12); // same test on the other geom mju_negPose(inverse_mesh_pos, inverse_mesh_quat, &model->mesh_pos[0], &model->mesh_quat[0]); mju_mulPose(recovered_pos, recovered_quat, &model->geom_pos[3], &model->geom_quat[4], inverse_mesh_pos, inverse_mesh_quat); EXPECT_NEAR(recovered_pos[0], 1, 1e-12); EXPECT_NEAR(recovered_pos[1], 2, 1e-12); EXPECT_NEAR(recovered_pos[2], 3, 1e-12); EXPECT_NEAR(recovered_quat[0], 0.5, 1e-12); EXPECT_NEAR(recovered_quat[1], 0.5, 1e-12); EXPECT_NEAR(recovered_quat[2], 0.5, 1e-12); EXPECT_NEAR(recovered_quat[3], 0.5, 1e-12); mj_deleteModel(model); } TEST_F(MjCMeshTest, MeshScale) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; EXPECT_THAT(AsVector(model->mesh_scale + 0, 3), ElementsAre(1, 1, 1)); EXPECT_THAT(AsVector(model->mesh_scale + 3, 3), ElementsAre(0.9, 1, -1)); mj_deleteModel(model); } TEST_F(MjCMeshTest, ShellInertiaTest) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; EXPECT_THAT(AsVector(model->mesh_scale + 0, 3), ElementsAre(1, 1, 1)); EXPECT_THAT(AsVector(model->mesh_scale + 3, 3), ElementsAre(0.9, 1, -1)); mj_deleteModel(model); } // ----------------------------- texcoord ------------------------------------- TEST_F(MjCMeshTest, CreateFaceTexCoord) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, NotNull()) << error; mj_deleteModel(model); } TEST_F(MjCMeshTest, UseFaceTexCoord) { static constexpr char xml[] = R"( )"; std::array error; mjModel* model = LoadModelFromString(xml, error.data(), error.size()); EXPECT_THAT(model, NotNull()) << error.data(); EXPECT_FLOAT_EQ(model->mesh_texcoord[2*model->mesh_facetexcoord[ 0]], .0); EXPECT_FLOAT_EQ(model->mesh_texcoord[2*model->mesh_facetexcoord[ 1]], .2); EXPECT_FLOAT_EQ(model->mesh_texcoord[2*model->mesh_facetexcoord[ 2]], .1); EXPECT_FLOAT_EQ(model->mesh_texcoord[2*model->mesh_facetexcoord[ 3]], .0); EXPECT_FLOAT_EQ(model->mesh_texcoord[2*model->mesh_facetexcoord[ 4]], .1); EXPECT_FLOAT_EQ(model->mesh_texcoord[2*model->mesh_facetexcoord[ 5]], .3); EXPECT_FLOAT_EQ(model->mesh_texcoord[2*model->mesh_facetexcoord[ 6]], .2); EXPECT_FLOAT_EQ(model->mesh_texcoord[2*model->mesh_facetexcoord[ 7]], .0); EXPECT_FLOAT_EQ(model->mesh_texcoord[2*model->mesh_facetexcoord[ 8]], .3); EXPECT_FLOAT_EQ(model->mesh_texcoord[2*model->mesh_facetexcoord[ 9]], .1); EXPECT_FLOAT_EQ(model->mesh_texcoord[2*model->mesh_facetexcoord[10]], .2); EXPECT_FLOAT_EQ(model->mesh_texcoord[2*model->mesh_facetexcoord[11]], .3); mj_deleteModel(model); } TEST_F(MjCMeshTest, MissingTexCoord) { static constexpr char xml[] = R"( )"; std::array error; mjModel* model = LoadModelFromString(xml, error.data(), error.size()); EXPECT_THAT(model, testing::IsNull()); EXPECT_THAT(error.data(), HasSubstr("texcoord must be 2*nv")); } // ----------------------------- qhull ---------------------------------------- TEST_F(MjCMeshTest, NaNConvexHullDisallowed) { static constexpr char xml[] = R"( )"; static char warning[1024]; warning[0] = '\0'; mju_user_warning = [](const char* msg) { util::strcpy_arr(warning, msg); }; std::array error; mjModel* model = LoadModelFromString(xml, error.data(), error.size()); EXPECT_THAT(model, testing::IsNull()); EXPECT_THAT(error.data(), HasSubstr("vertex coordinate 0 is not finite")); mj_deleteModel(model); } TEST_F(MjCMeshTest, InvalidIndexInFace) { static constexpr char xml[] = R"( )"; char error[1024]; mjModel* model = LoadModelFromString(xml, error, sizeof(error)); ASSERT_THAT(model, IsNull()); EXPECT_THAT(error, HasSubstr("in face 0, vertex index 6 does not exist")); mj_deleteModel(model); } TEST_F(MjCMeshTest, QhullCache) { static constexpr char xml1[] = R"( )"; static constexpr char xml2[] = R"( )"; mjVFS vfs; mj_defaultVFS(&vfs); mj_addFileVFS(&vfs, "", GetTestDataFilePath(kCubeCompletePath).c_str()); std::array error; mjModel* model = LoadModelFromString(xml1, error.data(), error.size(), &vfs); ASSERT_THAT(model, NotNull()) << "Failed to load model: " << error.data(); EXPECT_THAT(model->mesh_graphadr[0], -1); mj_deleteModel(model); model = LoadModelFromString(xml2, error.data(), error.size(), &vfs); ASSERT_THAT(model, NotNull()) << "Failed to load model: " << error.data(); EXPECT_GT(model->mesh_graphadr[0], -1); mj_deleteModel(model); mj_deleteVFS(&vfs); } TEST_F(MjCMeshTest, LoadSkin) { const std::string xml_path = GetTestDataFilePath(kCubeSkinPath); std::array error; mjSpec* spec = mj_parseXML(xml_path.c_str(), 0, error.data(), error.size()); EXPECT_THAT(spec, NotNull()) << error.data(); mjModel* m1 = mj_compile(spec, 0); EXPECT_THAT(m1, NotNull()); mj_deleteModel(m1); mjModel* m2 = mj_compile(spec, 0); EXPECT_THAT(m2, NotNull()); mj_deleteModel(m2); mj_deleteSpec(spec); } // ------------- test octree --------------------------------------------------- TEST_F(MjCMeshTest, Octree) { const std::string xml_path = GetTestDataFilePath(kTorusPath); std::array error; mjSpec* spec = mj_parseXML(xml_path.c_str(), 0, error.data(), error.size()); mjsGeom* geom = mjs_asGeom(mjs_firstElement(spec, mjOBJ_GEOM)); geom->type = mjGEOM_SDF; mjModel* model = mj_compile(spec, 0); ASSERT_THAT(model, NotNull()) << error.data(); EXPECT_GT(model->mesh_octnum[0], 0); mj_deleteSpec(spec); mj_deleteModel(model); } TEST_F(MjCMeshTest, OctreeNotComputedForNonSDF) { const std::string xml_path = GetTestDataFilePath(kTorusPath); std::array error; mjModel* model = mj_loadXML(xml_path.c_str(), 0, error.data(), error.size()); ASSERT_THAT(model, NotNull()) << error.data(); EXPECT_EQ(model->noct, 0); mj_deleteModel(model); } } // namespace } // namespace mujoco