// Copyright 2022 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 ray casting. #include #include #include #include #include #include #include "src/engine/engine_ray.h" #include "test/fixture.h" namespace mujoco { namespace { static constexpr char kSingleGeomModel[] = R"( )"; static constexpr char kRayCastingModel[] = R"( )"; static constexpr char kCubeletModel[] = R"( )"; using ::testing::NotNull; using RayTest = MujocoTest; TEST_F(RayTest, NoExclusions) { mjModel* model = LoadModelFromString(kRayCastingModel); ASSERT_THAT(model, NotNull()); mjData* data = mj_makeData(model); ASSERT_THAT(data, NotNull()); mjtNum pnt[] = {0.0, 0.0, 0.0}; mjtNum vec[] = {1.0, 0.0, 0.0}; mjtByte* geomgroup = nullptr; mjtByte flg_static = 1; // Include static geoms int bodyexclude = -1; int geomid = -1; mj_kinematics(model, data); mjtNum distance = mj_ray(model, data, pnt, vec, geomgroup, flg_static, bodyexclude, &geomid); EXPECT_STREQ(mj_id2name(model, mjOBJ_GEOM, geomid), "static_group1"); EXPECT_FLOAT_EQ(distance, 0.9); mj_deleteData(data); mj_deleteModel(model); } TEST_F(RayTest, Exclusions) { mjModel* model = LoadModelFromString(kRayCastingModel); ASSERT_THAT(model, NotNull()); mjData* data = mj_makeData(model); ASSERT_THAT(data, NotNull()); mjtNum pnt[] = {0.0, 0.0, 0.0}; mjtNum vec[] = {1.0, 0.0, 0.0}; mjtByte geomgroup[] = {1, 1, 1}; mjtByte flg_static = 1; int bodyexclude = -1; int geomid = -1; mj_kinematics(model, data); mjtNum distance = mj_ray(model, data, pnt, vec, geomgroup, flg_static, bodyexclude, &geomid); EXPECT_STREQ(mj_id2name(model, mjOBJ_GEOM, geomid), "static_group1"); EXPECT_FLOAT_EQ(distance, 0.9); // Exclude nearest geom geomgroup[1] = 0; distance = mj_ray(model, data, pnt, vec, geomgroup, flg_static, bodyexclude, &geomid); EXPECT_STREQ(mj_id2name(model, mjOBJ_GEOM, geomid), "group0"); EXPECT_FLOAT_EQ(distance, 2.9); geomgroup[0] = 0; distance = mj_ray(model, data, pnt, vec, geomgroup, flg_static, bodyexclude, &geomid); EXPECT_STREQ(mj_id2name(model, mjOBJ_GEOM, geomid), "group2"); EXPECT_FLOAT_EQ(distance, 4.9); geomgroup[2] = 0; distance = mj_ray(model, data, pnt, vec, geomgroup, flg_static, bodyexclude, &geomid); EXPECT_EQ(geomid, -1); EXPECT_FLOAT_EQ(distance, -1); mj_deleteData(data); mj_deleteModel(model); } TEST_F(RayTest, ExcludeStatic) { mjModel* model = LoadModelFromString(kRayCastingModel); ASSERT_THAT(model, NotNull()); mjData* data = mj_makeData(model); ASSERT_THAT(data, NotNull()); mjtNum pnt[] = {0.0, 0.0, 0.0}; mjtNum vec[] = {1.0, 0.0, 0.0}; mjtByte geomgroup[] = {1, 1, 1}; mjtByte flg_static = 0; // Exclude static geoms int bodyexclude = -1; int geomid = -1; mj_kinematics(model, data); mjtNum distance = mj_ray(model, data, pnt, vec, geomgroup, flg_static, bodyexclude, &geomid); EXPECT_STREQ(mj_id2name(model, mjOBJ_GEOM, geomid), "group0"); EXPECT_FLOAT_EQ(distance, 2.9); mj_deleteData(data); mj_deleteModel(model); } // ------------------------------- mj_multiRay -------------------------------- TEST_F(RayTest, MultiRayEqualsSingleRay) { mjModel* m = LoadModelFromString(kRayCastingModel); ASSERT_THAT(m, NotNull()); mjData* d = mj_makeData(m); ASSERT_THAT(d, NotNull()); mj_forward(m, d); // create ray array constexpr int N = 80; constexpr int M = 60; mjtNum vec[3*N*M]; mjtNum pnt[3] = {1, 2, 3}; mjtNum cone[4][3] = {{1, 1, -1}, {1, 1, 1}, {1, -1, -1}, {1, -1, 1}}; memset(vec, 0, 3*N*M*sizeof(mjtNum)); for (int i = 0; i < N; ++i) { for (int j = 0; j < M; ++j) { for (int k = 0; k < 3; ++k) { vec[3 * (i * M + j) + k] = i * cone[0][k] / (N - 1) + j * cone[1][1] / (M - 1) + (N - i - 1) * cone[2][k] / (N - 1) + (M - j - 1) * cone[3][k] / (M - 1); } } } // compute intersections with multiray functions mjtNum dist_multiray[N*M]; int rgeomid_multiray[N*M]; mj_multiRay(m, d, pnt, vec, NULL, 1, -1, rgeomid_multiray, dist_multiray, N * M, mjMAXVAL); // compare results with single ray function mjtNum dist; int rgeomid; for (int i = 0; i < N; ++i) { for (int j = 0; j < M; ++j) { int idx = i * M + j; dist = mj_ray(m, d, pnt, vec + 3 * idx, NULL, 1, -1, &rgeomid); EXPECT_FLOAT_EQ(dist, dist_multiray[idx]); EXPECT_EQ(rgeomid, rgeomid_multiray[idx]); } } mj_deleteData(d); mj_deleteModel(m); } TEST_F(RayTest, EdgeCases) { mjModel* m = LoadModelFromString(kSingleGeomModel); ASSERT_THAT(m, NotNull()); ASSERT_THAT(m->nbvh, 1); mjData* d = mj_makeData(m); ASSERT_THAT(d, NotNull()); mj_forward(m, d); // spherical bounding box and result arrays mjtNum geom_ba[4]; mjtNum dist; int rgeomid; int flags[1] = {0}; // pnt contained in bounding box mjtNum pnt1[] = {-1, 0, 0}; mju_multiRayPrepare(m, d, pnt1, NULL, NULL, 1, -1, mjMAXVAL, geom_ba, flags); EXPECT_FLOAT_EQ(geom_ba[0], -mjPI); EXPECT_FLOAT_EQ(geom_ba[1], 0); EXPECT_FLOAT_EQ(geom_ba[2], mjPI); EXPECT_FLOAT_EQ(geom_ba[3], mjPI); mjtNum vec1[] = {1, 0, 0}; mj_multiRay(m, d, pnt1, vec1, NULL, 1, -1, &rgeomid, &dist, 1, mjMAXVAL); EXPECT_FLOAT_EQ(dist, 0.1); // pnt at phi = Pi, -Pi mjtNum pnt2[] = {-.5, 0, 0}; mju_multiRayPrepare(m, d, pnt2, NULL, NULL, 1, -1, mjMAXVAL, geom_ba, flags); EXPECT_FLOAT_EQ(geom_ba[0], -mjPI); // atan(y<0, x<0) EXPECT_FLOAT_EQ(geom_ba[2], mjPI); // atan(y>0, x<0) mjtNum vec2[] = {-1, 0, 0}; mj_multiRay(m, d, pnt2, vec2, NULL, 1, -1, &rgeomid, &dist, 1, mjMAXVAL); EXPECT_FLOAT_EQ(dist, 0.4); // with cutoff mjtNum cutoff1 = 0.41, cutoff2 = 0.39; mju_multiRayPrepare(m, d, pnt2, NULL, NULL, 1, -1, cutoff1, geom_ba, flags); EXPECT_EQ(flags[0], 0); mju_multiRayPrepare(m, d, pnt2, NULL, NULL, 1, -1, cutoff2, geom_ba, flags); EXPECT_EQ(flags[0], 1); mj_multiRay(m, d, pnt2, vec2, NULL, 1, -1, &rgeomid, &dist, 1, cutoff2); EXPECT_FLOAT_EQ(dist, -1); // pnt on the boundary of the box mjtNum pnt3[] = {.1, .1, .05}; mju_multiRayPrepare(m, d, pnt3, NULL, NULL, 1, -1, mjMAXVAL, geom_ba, flags); EXPECT_FLOAT_EQ(geom_ba[1], 0); EXPECT_FLOAT_EQ(geom_ba[3], mjPI); mjtNum vec3[] = {1, 1, 0}; mj_multiRay(m, d, pnt3, vec3, NULL, 1, -1, &rgeomid, &dist, 1, mjMAXVAL); EXPECT_FLOAT_EQ(dist, -1); // size 0 geom mjtNum pnt4[] = {-2, 0, 0}; m->geom_aabb[0] = m->geom_aabb[1] = m->geom_aabb[2] = 0; m->geom_aabb[3] = m->geom_aabb[4] = m->geom_aabb[5] = 0; mju_multiRayPrepare(m, d, pnt4, NULL, NULL, 1, -1, mjMAXVAL, geom_ba, flags); EXPECT_FLOAT_EQ(geom_ba[0], 0); EXPECT_FLOAT_EQ(geom_ba[1], mjPI/2); EXPECT_FLOAT_EQ(geom_ba[2], 0); EXPECT_FLOAT_EQ(geom_ba[3], mjPI/2); mjtNum vec4[] = {1, 0, 0}; mj_multiRay(m, d, pnt4, vec4, NULL, 1, -1, &rgeomid, &dist, 1, mjMAXVAL); EXPECT_FLOAT_EQ(dist, 0.9); mj_deleteData(d); mj_deleteModel(m); } // ------------------------------- mj_rayMesh --------------------------------- // old ray mesh intersection mjtNum _rayMesh(const mjModel* m, const mjData* d, int geomid, const mjtNum* pnt, const mjtNum* vec) { // check geom type if (m->geom_type[geomid] != mjGEOM_MESH) { mju_error("mj_rayMesh: geom with mesh type expected"); } // map to local frame mjtNum lpnt[3], lvec[3]; const mjtNum* pos = d->geom_xpos+3*geomid; const mjtNum dif[3] = {pnt[0]-pos[0], pnt[1]-pos[1], pnt[2]-pos[2]}; mju_mulMatTVec3(lpnt, d->geom_xmat+9*geomid, dif); mju_mulMatTVec3(lvec, d->geom_xmat+9*geomid, vec); // construct basis vectors of normal plane mjtNum b0[3] = {1, 1, 1}, b1[3]; if (mju_abs(lvec[0]) >= mju_abs(lvec[1]) && mju_abs(lvec[0]) >= mju_abs(lvec[2])) { b0[0] = 0; } else if (mju_abs(lvec[1]) >= mju_abs(lvec[2])) { b0[1] = 0; } else { b0[2] = 0; } mju_addScl3(b1, b0, lvec, -mju_dot3(lvec, b0)/mju_dot3(lvec, lvec)); mju_normalize3(b1); mju_cross(b0, b1, lvec); mju_normalize3(b0); // init solution mjtNum x = -1, sol; // process all triangles int face, meshid = m->geom_dataid[geomid]; for (face = m->mesh_faceadr[meshid]; face < m->mesh_faceadr[meshid] + m->mesh_facenum[meshid]; face++) { // get float vertices float* vf[3]; vf[0] = m->mesh_vert + 3*(m->mesh_face[3*face] + m->mesh_vertadr[meshid]); vf[1] = m->mesh_vert + 3*(m->mesh_face[3*face+1] + m->mesh_vertadr[meshid]); vf[2] = m->mesh_vert + 3*(m->mesh_face[3*face+2] + m->mesh_vertadr[meshid]); // convert to mjtNum mjtNum v[3][3]; for (int i=0; i < 3; i++) { for (int j=0; j < 3; j++) { v[i][j] = (mjtNum)vf[i][j]; } } // solve sol = ray_triangle(v, lpnt, lvec, b0, b1); // update if (sol >= 0 && (x < 0 || sol < x)) { x = sol; } } return x; } // performs a ray mesh test using a given mjModel void _rayMeshTest(const mjModel* m) { mjData* d = mj_makeData(m); ASSERT_THAT(d, NotNull()); mj_forward(m, d); // create ray array constexpr int N = 80; constexpr int M = 60; mjtNum vec[3*N*M]; mjtNum pnt[3] = {1, .2, 0}; mjtNum cone[4][3] = {{-1, -1, -1}, {-1, -1, 1}, {1, -1, 1}, {1, -1, -1}}; memset(vec, 0, 3*N*M*sizeof(mjtNum)); for (int i = 0; i < N; ++i) { for (int j = 0; j < M; ++j) { for (int k = 0; k < 3; ++k) { vec[3 * (i * M + j) + k] = i * cone[0][k] / (N - 1) + j * cone[1][1] / (M - 1) + (N - i - 1) * cone[2][k] / (N - 1) + (M - j - 1) * cone[3][k] / (M - 1); } } } // compare results with single ray function mjtNum dist_new, dist_old; for (int i = 0; i < N; ++i) { for (int j = 0; j < M; ++j) { int idx = i * M + j; dist_old = _rayMesh(m, d, /*geomid=*/0, pnt, vec + 3 * idx); dist_new = mj_rayMesh(m, d, /*geomid=*/0, pnt, vec + 3 * idx); EXPECT_FLOAT_EQ(dist_new, dist_old); } } mj_deleteData(d); } TEST_F(RayTest, RayMeshPruning) { char error[1024] = {0}; const std::string xml_path = GetTestDataFilePath("engine/testdata/ray/stanford_bunny.xml"); mjModel* m = mj_loadXML(xml_path.c_str(), NULL, error, sizeof(error)); ASSERT_THAT(m, NotNull()) << error; _rayMeshTest(m); mj_deleteModel(m); m = LoadModelFromString(kCubeletModel); ASSERT_THAT(m, NotNull()); _rayMeshTest(m); mj_deleteModel(m); } } // namespace } // namespace mujoco