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mujoco / data /test /user /user_objects_test.cc
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 // 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 <algorithm>
#include <array>
#include <cstddef>
#include <cstring>
#include <memory>
#include <string>
#include <gmock/gmock.h>
#include <gtest/gtest.h>
#include <mujoco/mjmodel.h>
#include <mujoco/mjtnum.h>
#include <mujoco/mujoco.h>
#include "test/fixture.h"
namespace mujoco {
namespace {
constexpr double kInertiaTol = 1e-6;
using std::string;
using ::testing::DoubleNear;
using ::testing::ElementsAre;
using ::testing::HasSubstr;
using ::testing::IsNull;
using ::testing::NotNull;
using ::testing::Pointwise;
// -------------------- test OS filesystem fallback ----------------------------
using VfsTest = MujocoTest;
TEST_F(VfsTest, HFieldPngWithVFS) {
static constexpr char xml[] = R"(
<mujoco>
<asset>
<hfield name="hfield" file="unknown_file.png" size="0.5 0.5 1 0.1"/>
</asset>
<worldbody>
<geom type="hfield" hfield="hfield" pos="-.4 .6 .05"/>
</worldbody>
</mujoco>
)";
char error[1024];
size_t error_sz = 1024;
// load VFS on the heap
auto vfs = std::make_unique<mjVFS>();
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(VfsTest, HFieldCustomWithVFS) {
static constexpr char xml[] = R"(
<mujoco>
<asset>
<hfield name="hfield" file="unknown_file" size="0.5 0.5 1 0.1"/>
</asset>
<worldbody>
<geom type="hfield" hfield="hfield" pos="-.4 .6 .05"/>
</worldbody>
</mujoco>
)";
char error[1024];
size_t error_sz = 1024;
// load VFS on the heap
auto vfs = std::make_unique<mjVFS>();
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(VfsTest, TexturePngWithVFS) {
static constexpr char xml[] = R"(
<mujoco>
<asset>
<texture name="texture" file="unknown_file.png" type="2d"/>
<material name="material" texture="texture"/>
</asset>
<worldbody>
<geom type="plane" material="material" size="4 4 4"/>
</worldbody>
</mujoco>
)";
char error[1024];
size_t error_sz = 1024;
// load VFS on the heap
auto vfs = std::make_unique<mjVFS>();
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(VfsTest, TextureCustomWithVFS) {
static constexpr char xml[] = R"(
<mujoco>
<asset>
<texture name="texture" file="unknown_file" type="2d"/>
<material name="material" texture="texture"/>
</asset>
<worldbody>
<geom type="plane" material="material" size="4 4 4"/>
</worldbody>
</mujoco>
)";
char error[1024];
size_t error_sz = 1024;
// load VFS on the heap
auto vfs = std::make_unique<mjVFS>();
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 attribute ------------------------
using ContentTypeTest = MujocoTest;
TEST_F(ContentTypeTest, HFieldPngWithContentType) {
static constexpr char xml[] = R"(
<mujoco>
<asset>
<hfield name="hfield" content_type="image/png"
file="some_file.png" size="0.5 0.5 1 0.1"/>
</asset>
<worldbody>
<geom type="hfield" hfield="hfield" pos="-.4 .6 .05"/>
</worldbody>
</mujoco>
)";
char error[1024];
size_t error_sz = 1024;
// load VFS on the heap
auto vfs = std::make_unique<mjVFS>();
mj_defaultVFS(vfs.get());
// should try loading the file
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(ContentTypeTest, HFieldCustomWithContentType) {
static constexpr char xml[] = R"(
<mujoco>
<asset>
<hfield name="hfield" content_type="image/vnd.mujoco.hfield"
file="some_file" size="0.5 0.5 1 0.1"/>
</asset>
<worldbody>
<geom type="hfield" hfield="hfield" pos="-.4 .6 .05"/>
</worldbody>
</mujoco>
)";
char error[1024];
size_t error_sz = 1024;
// load VFS on the heap
auto vfs = std::make_unique<mjVFS>();
mj_defaultVFS(vfs.get());
// should try loading the file
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(ContentTypeTest, HFieldWithContentTypeError) {
static constexpr char xml[] = R"(
<mujoco>
<asset>
<hfield name="hfield" content_type="image/jpeg"
file="some_file" size="0.5 0.5 1 0.1"/>
</asset>
<worldbody>
<geom type="hfield" hfield="hfield" pos="-.4 .6 .05"/>
</worldbody>
</mujoco>
)";
char error[1024];
size_t error_sz = 1024;
// load VFS on the heap
auto vfs = std::make_unique<mjVFS>();
mj_defaultVFS(vfs.get());
// should try loading the file
mjModel* model = LoadModelFromString(xml, error, error_sz, vfs.get());
EXPECT_THAT(model, IsNull());
EXPECT_THAT(error, HasSubstr("unsupported content type: 'image/jpeg'"));
mj_deleteVFS(vfs.get());
}
TEST_F(ContentTypeTest, TexturePngWithContentType) {
static constexpr char xml[] = R"(
<mujoco>
<asset>
<texture name="texture" content_type="image/png" file="some_file" type="2d"/>
<material name="material" texture="texture"/>
</asset>
<worldbody>
<geom type="plane" material="material" size="4 4 4"/>
</worldbody>
</mujoco>
)";
char error[1024];
size_t error_sz = 1024;
// load VFS on the heap
auto vfs = std::make_unique<mjVFS>();
mj_defaultVFS(vfs.get());
// should try loading the file
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(ContentTypeTest, TextureCustomWithContentType) {
static constexpr char xml[] = R"(
<mujoco>
<asset>
<texture name="texture" content_type="image/vnd.mujoco.texture"
file="some_file" type="2d"/>
<material name="material" texture="texture"/>
</asset>
<worldbody>
<geom type="plane" material="material" size="4 4 4"/>
</worldbody>
</mujoco>
)";
char error[1024];
size_t error_sz = 1024;
// load VFS on the heap
auto vfs = std::make_unique<mjVFS>();
mj_defaultVFS(vfs.get());
// should try loading the file
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(ContentTypeTest, TextureWithContentTypeError) {
static constexpr char xml[] = R"(
<mujoco>
<asset>
<texture name="texture" content_type="image/jpeg"
file="some_file" type="2d"/>
<material name="material" texture="texture"/>
</asset>
<worldbody>
<geom type="plane" material="material" size="4 4 4"/>
</worldbody>
</mujoco>
)";
char error[1024];
size_t error_sz = 1024;
// load VFS on the heap
auto vfs = std::make_unique<mjVFS>();
mj_defaultVFS(vfs.get());
// should try loading the file
mjModel* model = LoadModelFromString(xml, error, error_sz, vfs.get());
EXPECT_THAT(model, IsNull());
EXPECT_THAT(error, HasSubstr("unsupported content type: 'image/jpeg'"));
mj_deleteVFS(vfs.get());
}
TEST_F(ContentTypeTest, TextureLoadPng) {
static constexpr char filename[] = "tiny";
static constexpr char xml[] = R"(
<mujoco>
<asset>
<texture content_type="image/png" file="tiny" type="2d"/>
<material name="material" texture="tiny"/>
</asset>
<worldbody>
<geom type="plane" material="material" size="4 4 4"/>
</worldbody>
</mujoco>
)";
// tiny RGB 2 x 3 PNG file
static constexpr unsigned char tiny[] = {
0x89, 0x50, 0x4e, 0x47, 0x0d, 0x0a, 0x1a, 0x0a, 0x00, 0x00, 0x00, 0x0d,
0x49, 0x48, 0x44, 0x52, 0x00, 0x00, 0x00, 0x03, 0x00, 0x00, 0x00, 0x02,
0x08, 0x02, 0x00, 0x00, 0x00, 0x12, 0x16, 0xf1, 0x4d, 0x00, 0x00, 0x00,
0x1c, 0x49, 0x44, 0x41, 0x54, 0x08, 0xd7, 0x63, 0x78, 0xc1, 0xc0, 0xc0,
0xc0, 0xf0, 0xbf, 0xb8, 0xb8, 0x98, 0x81, 0xe1, 0x3f, 0xc3, 0xff, 0xff,
0xff, 0xc5, 0xc4, 0xc4, 0x00, 0x46, 0xd7, 0x07, 0x7f, 0xd2, 0x52, 0xa1,
0x41, 0x00, 0x00, 0x00, 0x00, 0x49, 0x45, 0x4e, 0x44, 0xae, 0x42, 0x60,
0x82
};
size_t tiny_sz = sizeof(tiny);
char error[1024];
size_t error_sz = 1024;
// load VFS on the heap
auto vfs = std::make_unique<mjVFS>();
mj_defaultVFS(vfs.get());
mj_addBufferVFS(vfs.get(), filename, tiny, tiny_sz);
// loading the file should be successful
mjModel* model = LoadModelFromString(xml, error, error_sz, vfs.get());
EXPECT_THAT(model, NotNull());
mj_deleteModel(model);
mj_deleteVFS(vfs.get());
}
// ------------------------ test keyframes -------------------------------------
using KeyframeTest = MujocoTest;
constexpr char kKeyframePath[] = "user/testdata/keyframe.xml";
TEST_F(KeyframeTest, CheckValues) {
const string xml_path = GetTestDataFilePath(kKeyframePath);
mjModel* model = mj_loadXML(xml_path.c_str(), nullptr, nullptr, 0);
ASSERT_THAT(model, NotNull());
EXPECT_EQ(model->nkey, 7);
EXPECT_EQ(model->key_time[0 * 1], 0.1);
EXPECT_EQ(model->key_qpos[1 * model->nq], 0.2);
EXPECT_EQ(model->key_qvel[2 * model->nv], 0.3);
EXPECT_EQ(model->key_act[3 * model->na], 0.4);
EXPECT_THAT(AsVector(model->key_ctrl + 4*model->nu, model->nu),
ElementsAre(0.5, 0.6));
EXPECT_THAT(AsVector(model->key_mpos + 3*model->nmocap*5, 3),
ElementsAre(.1, .2, .3));
EXPECT_THAT(AsVector(model->key_mquat + 4*model->nmocap*6, 4),
ElementsAre(.5, .5, .5, .5));
mj_deleteModel(model);
}
TEST_F(KeyframeTest, ResetDataKeyframe) {
const string xml_path = GetTestDataFilePath(kKeyframePath);
mjModel* model = mj_loadXML(xml_path.c_str(), nullptr, nullptr, 0);
ASSERT_THAT(model, NotNull());
mjData* data = mj_makeData(model);
mj_resetDataKeyframe(model, data, 0);
EXPECT_EQ(data->time, 0.1);
mj_resetDataKeyframe(model, data, 1);
EXPECT_EQ(data->qpos[0], 0.2);
mj_resetDataKeyframe(model, data, 2);
EXPECT_EQ(data->qvel[0], 0.3);
mj_resetDataKeyframe(model, data, 3);
EXPECT_EQ(data->act[0], 0.4);
mj_resetDataKeyframe(model, data, 4);
EXPECT_EQ(data->ctrl[0], 0.5);
EXPECT_EQ(data->ctrl[1], 0.6);
mj_resetDataKeyframe(model, data, 5);
EXPECT_THAT(AsVector(data->mocap_pos, 3), ElementsAre(.1, .2, .3));
mj_resetDataKeyframe(model, data, 6);
EXPECT_THAT(AsVector(data->mocap_quat, 4), ElementsAre(.5, .5, .5, .5));
mj_deleteData(data);
mj_deleteModel(model);
}
TEST_F(KeyframeTest, ResetDataKeyframeAcceptsNegativeKeyframe) {
const string xml_path = GetTestDataFilePath(kKeyframePath);
mjModel* model = mj_loadXML(xml_path.c_str(), nullptr, nullptr, 0);
ASSERT_THAT(model, NotNull());
mjData* data = mj_makeData(model);
data->time = data->qpos[0] = data->qvel[0] = data->act[0] = data->ctrl[0] =
data->mocap_pos[0] = data->mocap_quat[0] = 1337.0;
mj_resetDataKeyframe(model, data, -1);
EXPECT_EQ(data->time, 0.0);
EXPECT_EQ(data->qpos[0], 0.0);
EXPECT_EQ(data->qvel[0], 0.0);
EXPECT_EQ(data->act[0], 0.0);
EXPECT_EQ(data->ctrl[0], 0.0);
EXPECT_EQ(data->mocap_pos[0], 0.0);
EXPECT_EQ(data->mocap_quat[0], 1.0);
mj_deleteData(data);
mj_deleteModel(model);
}
TEST_F(KeyframeTest, BadSize) {
static constexpr char xml[] = R"(
<mujoco>
<keyframe>
<key qpos="1"/>
</keyframe>
</mujoco>
)";
char error[1024];
size_t error_sz = 1024;
mjModel* model = LoadModelFromString(xml, error, error_sz);
EXPECT_THAT(model, IsNull());
EXPECT_THAT(error, HasSubstr("invalid qpos size, expected length 0"));
}
// ------------- test relative frame sensor compilation-------------------------
using RelativeFrameSensorParsingTest = MujocoTest;
TEST_F(RelativeFrameSensorParsingTest, RefTypeNotRequired) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body name="sensorized"/>
</worldbody>
<sensor>
<framepos objtype="body" objname="sensorized"/>
</sensor>
</mujoco>
)";
mjModel* model = LoadModelFromString(xml, 0, 0);
ASSERT_THAT(model, NotNull());
mj_deleteModel(model);
}
TEST_F(RelativeFrameSensorParsingTest, ReferenceBodyFound) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body name="reference"/>
<body name="sensorized"/>
</worldbody>
<sensor>
<framepos objtype="xbody" objname="sensorized"
reftype="xbody" refname="reference"/>
</sensor>
</mujoco>
)";
mjModel* model = LoadModelFromString(xml, 0, 0);
ASSERT_THAT(model, NotNull());
ASSERT_EQ(model->sensor_reftype[0], mjOBJ_XBODY);
ASSERT_EQ(model->sensor_refid[0], 1);
mj_deleteModel(model);
}
TEST_F(RelativeFrameSensorParsingTest, MissingRefname) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body name="reference"/>
<body name="sensorized"/>
</worldbody>
<sensor>
<framepos objtype="body" objname="sensorized"
reftype="body" refname=""/>
</sensor>
</mujoco>
)";
std::array<char, 1024> error;
LoadModelFromString(xml, error.data(), error.size());
EXPECT_THAT(error.data(), HasSubstr("missing name of reference frame"));
}
TEST_F(RelativeFrameSensorParsingTest, BadRefName) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body name="reference"/>
<body name="sensorized"/>
</worldbody>
<sensor>
<framepos objtype="body" objname="sensorized"
reftype="body" refname="wrong_name"/>
</sensor>
</mujoco>
)";
std::array<char, 1024> error;
LoadModelFromString(xml, error.data(), error.size());
EXPECT_THAT(error.data(),
HasSubstr("unrecognized name 'wrong_name' of object"));
EXPECT_THAT(error.data(), HasSubstr("line 8"));
}
TEST_F(RelativeFrameSensorParsingTest, BadRefType) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<light name="reference"/>
<body name="sensorized"/>
</worldbody>
<sensor>
<framepos objtype="body" objname="sensorized"
reftype="light" refname="reference"/>
</sensor>
</mujoco>
)";
std::array<char, 1024> error;
LoadModelFromString(xml, error.data(), error.size());
EXPECT_THAT(error.data(), HasSubstr("reference frame object must be"));
EXPECT_THAT(error.data(), HasSubstr("line 8"));
}
TEST_F(RelativeFrameSensorParsingTest, BadObjName) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<site name="a"/>
</worldbody>
<sensor>
<framepos name="tom" objtype="site" objname="alessio" reftype="site" refname="a"/>
</sensor>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(),
HasSubstr("unrecognized name 'alessio' of sensorized object"));
EXPECT_THAT(error.data(), HasSubstr("name 'tom'"));
EXPECT_THAT(error.data(), HasSubstr("line 7"));
}
TEST_F(RelativeFrameSensorParsingTest, BadObjRefName) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<site name="a"/>
</worldbody>
<sensor>
<framepos name="tom" objtype="site" objname="a" reftype="site" refname="alessio"/>
</sensor>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(
error.data(),
HasSubstr("unrecognized name 'alessio' of object"));
EXPECT_THAT(error.data(), HasSubstr("name 'tom'"));
EXPECT_THAT(error.data(), HasSubstr("line 7"));
}
// ------------- sensor compilation --------------------------------------------
using SensorTest = MujocoTest;
TEST_F(SensorTest, OjbtypeParsedButNotRequired) {
static constexpr char xml[] = R"(
<mujoco>
<sensor>
<user dim="3" needstage="vel" datatype="axis"/>
<user dim="2" needstage="pos" objtype="body" objname="world"/>
</sensor>
</mujoco>
)";
mjModel* model = LoadModelFromString(xml, 0, 0);
ASSERT_THAT(model, NotNull());
EXPECT_EQ(model->sensor_datatype[0], mjDATATYPE_AXIS);
EXPECT_EQ(model->sensor_objtype[0], mjOBJ_UNKNOWN);
EXPECT_EQ(model->sensor_dim[0], 3);
EXPECT_EQ(model->sensor_datatype[1], mjDATATYPE_REAL);
EXPECT_EQ(model->sensor_objtype[1], mjOBJ_BODY);
EXPECT_EQ(model->sensor_objid[1], 0);
mj_deleteModel(model);
}
// ------------- test capsule inertias -----------------------------------------
static const char* const kCapsuleInertiaPath =
"user/testdata/capsule_inertia.xml";
using MjCGeomTest = MujocoTest;
static constexpr int kSphereBodyId = 1, kCylinderBodyId = 2,
kCapsuleBodyId = 3, kCapsuleGeomId = 2;
TEST_F(MjCGeomTest, CapsuleMass) {
const string xml_path = GetTestDataFilePath(kCapsuleInertiaPath);
mjModel* model = mj_loadXML(xml_path.c_str(), nullptr, 0, 0);
// Mass of capsule should equal mass of cylinder + mass of sphere.
mjtNum sphere_cylinder_mass =
model->body_mass[kSphereBodyId] + model->body_mass[kCylinderBodyId];
mjtNum capsule_mass = model->body_mass[kCapsuleBodyId];
EXPECT_DOUBLE_EQ(sphere_cylinder_mass, capsule_mass);
mj_deleteModel(model);
}
TEST_F(MjCGeomTest, CapsuleInertiaZ) {
const string xml_path = GetTestDataFilePath(kCapsuleInertiaPath);
mjModel* model = mj_loadXML(xml_path.c_str(), nullptr, 0, 0);
// z-inertia of capsule should equal sphere + cylinder z-inertia.
mjtNum sphere_cylinder_z_inertia =
model->body_inertia[3*kSphereBodyId + 2] +
model->body_inertia[3*kCylinderBodyId + 2];
mjtNum capsule_z_inertia = model->body_inertia[3*kCapsuleBodyId + 2];
EXPECT_DOUBLE_EQ(sphere_cylinder_z_inertia, capsule_z_inertia);
mj_deleteModel(model);
}
TEST_F(MjCGeomTest, CapsuleInertiaX) {
const string xml_path = GetTestDataFilePath(kCapsuleInertiaPath);
mjModel* model = mj_loadXML(xml_path.c_str(), nullptr, 0, 0);
// The CoM of a solid hemisphere is 3/8*radius away from from the disk.
mjtNum hs_com = model->geom_size[3*kCapsuleGeomId] * 3 / 8;
// The mass of the two hemispherical end-caps is just the mass of the sphere.
mjtNum sphere_mass = model->body_mass[1];
// x-inertia of capsule should equal sphere + cylinder x-inertias, with
// corrections from shifting the hemispheres using parallel axis theorem.
mjtNum sphere_cylinder_x_inertia = model->body_inertia[3*kSphereBodyId] +
model->body_inertia[3*kCylinderBodyId];
// Parallel axis-theorem #1: translate the hemispheres in to the origin.
mjtNum translate_in = hs_com;
sphere_cylinder_x_inertia -= sphere_mass * translate_in*translate_in;
// Parallel axis-theorem #2: translate the hemispheres out to the end caps.
mjtNum cylinder_half_length = model->geom_size[3*kCapsuleGeomId + 1];
mjtNum translate_out = cylinder_half_length + hs_com;
sphere_cylinder_x_inertia += sphere_mass * translate_out*translate_out;
// Compare native capsule inertia and computed inertia.
mjtNum capsule_x_inertia = model->body_inertia[3*kCapsuleBodyId];
EXPECT_DOUBLE_EQ(sphere_cylinder_x_inertia, capsule_x_inertia);
mj_deleteModel(model);
}
TEST_F(MjCGeomTest, ShellInertiaSphere) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<geom type="sphere"size="1.5" shellinertia="true"/>
</body>
<body>
<!-- mass is difference of body 4 and 3 masses -->
<geom type="sphere" size="1.5" mass="28.274333953857422" shellinertia="true"/>
</body>
<body>
<geom type="sphere" size="1.5" density="1e8"/>
</body>
<body>
<geom type="sphere" size="1.50000001" density="1e8"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1000> error;
mjModel* m = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(m, NotNull()) << error.data();
// radius
mjtNum r = 1.5;
mjtNum r2 = r * r;
// body 1: shell inertia
mjtNum mass1 = 4 * mjPI * r2 * 1000; // surface area * surface density
EXPECT_NEAR(m->body_mass[1], mass1, kInertiaTol);
mjtNum I1 = 2 * mass1 * r2 / 3;
EXPECT_NEAR(m->body_inertia[3], I1, kInertiaTol);
EXPECT_NEAR(m->body_inertia[4], I1, kInertiaTol);
EXPECT_NEAR(m->body_inertia[5], I1, kInertiaTol);
// body 2: shell inertia, with specified mass
mjtNum I2 = 2 * m->body_mass[2] * r2 / 3;
EXPECT_NEAR(m->body_inertia[6], I2, kInertiaTol);
EXPECT_NEAR(m->body_inertia[7], I2, kInertiaTol);
EXPECT_NEAR(m->body_inertia[8], I2, kInertiaTol);
mjtNum mass3 = m->body_mass[3];
mjtNum mass4 = m->body_mass[4];
EXPECT_FLOAT_EQ(mass4 - mass3, m->body_mass[2]);
// compute approximate shell inertia by subtracting inertias of massive bodies
// with small radius difference
mjtNum* inertia3 = m->body_inertia + 9;
mjtNum* inertia4 = m->body_inertia + 12;
mjtNum shell_inertia[3];
mju_sub3(shell_inertia, inertia4, inertia3);
EXPECT_NEAR(shell_inertia[0], m->body_inertia[6], kInertiaTol);
EXPECT_NEAR(shell_inertia[1], m->body_inertia[7], kInertiaTol);
EXPECT_NEAR(shell_inertia[2], m->body_inertia[8], kInertiaTol);
mj_deleteModel(m);
}
TEST_F(MjCGeomTest, ShellInertiaCapsule) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<geom type="capsule" size="0.1 0.25" shellinertia="true"/>
</body>
<!-- mass is difference of body 4 and 3 masses -->
<body>
<geom type="capsule" size="0.1 0.25" mass="4.3982325" shellinertia="true"/>
</body>
<body>
<geom type="capsule" size="0.1 0.25" density="1e8"/>
</body>
<body>
<geom type="capsule" size="0.1000001 0.25" density="1e8"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1000> error;
mjModel* m = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(m, NotNull()) << error.data();
// dimensions
mjtNum r = 0.1;
mjtNum r2 = r * r;
mjtNum hh = 0.25;
mjtNum h = 2 * hh;
mjtNum h2 = h * h;
// hemisphere
mjtNum hs_com = r / 2; // height of hemisphere center of mass
mjtNum hs_pos = hh + hs_com; // distance from origin to hemisphere com
// surface area
double Asphere = 4 * mjPI * r2; // sphere
double Acylinder = 2 * mjPI * r * h; // cylinder
double Atotal = Asphere + Acylinder;
// body 1: shell inertia
mjtNum mass1 = Atotal * 1000; // surface area * surface density
EXPECT_NEAR(m->body_mass[1], mass1, kInertiaTol);
mjtNum mass1_sphere = mass1 * Asphere / Atotal;
mjtNum mass1_cylinder = mass1 - mass1_sphere;
double sphere1_inertia = 2 * mass1_sphere * r2 / 3;
mjtNum I1x = mass1_cylinder * (6 * r2 + h2) / 12 + sphere1_inertia +
mass1_sphere * (hs_pos * hs_pos - hs_com * hs_com);
mjtNum I1z = mass1_cylinder * r2 + sphere1_inertia;
EXPECT_NEAR(m->body_inertia[3], I1x, kInertiaTol);
EXPECT_NEAR(m->body_inertia[4], I1x, kInertiaTol);
EXPECT_NEAR(m->body_inertia[5], I1z, kInertiaTol);
// body 2: shell inertia, with specified mass
mjtNum mass2 = 4.3982325;
EXPECT_NEAR(m->body_mass[2], mass2, kInertiaTol);
EXPECT_FLOAT_EQ(m->body_mass[4] - m->body_mass[3], m->body_mass[2]);
mjtNum mass2_sphere = mass2 * Asphere / Atotal;
mjtNum mass2_cylinder = mass2 - mass2_sphere;
double sphere2_inertia = 2 * mass2_sphere * r2 / 3;
mjtNum I2x = mass2_cylinder * (6 * r2 + h2) / 12 + sphere2_inertia +
mass2_sphere * (hs_pos * hs_pos - hs_com * hs_com);
mjtNum I2z = mass2_cylinder * r2 + sphere2_inertia;
EXPECT_NEAR(m->body_inertia[6], I2x, kInertiaTol);
EXPECT_NEAR(m->body_inertia[7], I2x, kInertiaTol);
EXPECT_NEAR(m->body_inertia[8], I2z, kInertiaTol);
// compute approximate shell inertia by subtracting inertias of massive bodies
// with small radius difference
mjtNum* inertia3 = m->body_inertia + 9;
mjtNum* inertia4 = m->body_inertia + 12;
mjtNum shell_inertia[3];
mju_sub3(shell_inertia, inertia4, inertia3);
EXPECT_NEAR(shell_inertia[0], m->body_inertia[6], kInertiaTol);
EXPECT_NEAR(shell_inertia[1], m->body_inertia[7], kInertiaTol);
EXPECT_NEAR(shell_inertia[2], m->body_inertia[8], kInertiaTol);
mj_deleteModel(m);
}
TEST_F(MjCGeomTest, ShellInertiaCylinder) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<geom type="cylinder" size="0.1 0.25" shellinertia="true"/>
</body>
<!-- mass is difference of body 4 and 3 masses -->
<body>
<geom type="cylinder" size="0.1 0.25" mass="3.7699139" shellinertia="true"/>
</body>
<body>
<geom type="cylinder" size="0.1 0.25" density="1e8"/>
</body>
<body>
<geom type="cylinder" size="0.1000001 0.2500001" density="1e8"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1000> error;
mjModel* m = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(m, NotNull()) << error.data();
// dimensions
mjtNum r = 0.1;
mjtNum hh = 0.25;
mjtNum r2 = r * r;
mjtNum h = 2 * hh;
mjtNum h2 = h * h;
// surface area
double Adisk = mjPI * r2; // disk
double Acylinder = 2 * mjPI * r * h; // cylinder
double Atotal = 2 * Adisk + Acylinder;
// body 1: shell inertia
mjtNum mass1 = Atotal * 1000; // surface area * surface density
EXPECT_NEAR(m->body_mass[1], mass1, kInertiaTol);
mjtNum mass1_disk = mass1 * Adisk / Atotal;
mjtNum mass1_cylinder = mass1 - 2 * mass1_disk;
mjtNum I1x = mass1_cylinder * (6 * r2 + h2) / 12 +
2 * (mass1_disk * r2 / 4 + mass1_disk * hh * hh);
mjtNum I1z = mass1_cylinder * r2 + mass1_disk * r2;
EXPECT_NEAR(m->body_inertia[3], I1x, kInertiaTol);
EXPECT_NEAR(m->body_inertia[4], I1x, kInertiaTol);
EXPECT_NEAR(m->body_inertia[5], I1z, kInertiaTol);
// body 2: shell inertia, with specified mass
mjtNum mass2 = 3.7699139;
EXPECT_NEAR(m->body_mass[2], mass2, kInertiaTol);
EXPECT_FLOAT_EQ(m->body_mass[4] - m->body_mass[3], m->body_mass[2]);
mjtNum mass2_disk = mass2 * Adisk / Atotal;
mjtNum mass2_cylinder = mass2 - 2 * mass2_disk;
mjtNum I2x = mass2_cylinder * (6 * r2 + h2) / 12 +
2 * (mass2_disk * r2 / 4 + mass2_disk * hh * hh);
mjtNum I2z = mass2_cylinder * r2 + mass2_disk * r2;
EXPECT_NEAR(m->body_inertia[6], I2x, kInertiaTol);
EXPECT_NEAR(m->body_inertia[7], I2x, kInertiaTol);
EXPECT_NEAR(m->body_inertia[8], I2z, kInertiaTol);
// compute approximate shell inertia by subtracting inertias of massive bodies
// with small radius difference
mjtNum* inertia3 = m->body_inertia + 9;
mjtNum* inertia4 = m->body_inertia + 12;
mjtNum shell_inertia[3];
mju_sub3(shell_inertia, inertia4, inertia3);
EXPECT_NEAR(shell_inertia[0], m->body_inertia[6], kInertiaTol);
EXPECT_NEAR(shell_inertia[1], m->body_inertia[7], kInertiaTol);
EXPECT_NEAR(shell_inertia[2], m->body_inertia[8], kInertiaTol);
mj_deleteModel(m);
}
TEST_F(MjCGeomTest, ShellInertiaEllipsoid) {
// test special case of ellipsoid with dimensions: a = b = c
// TODO(taylorhowell): add test for ellipsoid with dimensions: a != b != c
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<geom type="ellipsoid" size="0.1 0.1 0.1" shellinertia="true"/>
</body>
<body>
<!-- mass is difference of body 4 and 3 masses -->
<geom type="ellipsoid" size="0.1 0.1 0.1" mass="0.12566371" shellinertia="true"/>
</body>
<body>
<geom type="ellipsoid" size="0.1 0.1 0.1" density="1e8"/>
</body>
<body>
<geom type="ellipsoid" size="0.10000001 0.10000001 0.10000001" density="1e8"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1000> error;
mjModel* m = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(m, NotNull()) << error.data();
// dimensions
mjtNum r = 0.1;
mjtNum r2 = r * r;
// body 1: shell inertia
mjtNum mass1 = 4 * mjPI * r2 * 1000; // surface area * surface density
EXPECT_NEAR(m->body_mass[1], mass1, kInertiaTol);
mjtNum I1 = 2 * mass1 * r2 / 3;
// note: increased tolerance, this is due to ellipsoid approximation
EXPECT_NEAR(m->body_inertia[3], I1, 10 * kInertiaTol);
EXPECT_NEAR(m->body_inertia[4], I1, 10 * kInertiaTol);
EXPECT_NEAR(m->body_inertia[5], I1, 10 * kInertiaTol);
// body 2: shell inertia, with specified mass
mjtNum mass2 = 0.12566371;
EXPECT_NEAR(m->body_mass[2], mass2, kInertiaTol);
EXPECT_FLOAT_EQ(m->body_mass[4] - m->body_mass[3], m->body_mass[2]);
mjtNum I2 = 2 * m->body_mass[2] * r2 / 3;
EXPECT_NEAR(m->body_inertia[6], I2, 10 * kInertiaTol);
EXPECT_NEAR(m->body_inertia[7], I2, 10 * kInertiaTol);
EXPECT_NEAR(m->body_inertia[8], I2, 10 * kInertiaTol);
// compute approximate shell inertia by subtracting inertias of massive bodies
// with small radius difference
mjtNum* inertia3 = m->body_inertia + 9;
mjtNum* inertia4 = m->body_inertia + 12;
mjtNum shell_inertia[3];
mju_sub3(shell_inertia, inertia4, inertia3);
EXPECT_NEAR(shell_inertia[0], m->body_inertia[6], 10 * kInertiaTol);
EXPECT_NEAR(shell_inertia[1], m->body_inertia[7], 10 * kInertiaTol);
EXPECT_NEAR(shell_inertia[2], m->body_inertia[8], 10 * kInertiaTol);
mj_deleteModel(m);
}
TEST_F(MjCGeomTest, ShellInertiaBox) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<geom type="box" size="0.1 0.2 0.3" shellinertia="true"/>
</body>
<!-- mass is difference of body 4 and 3 masses -->
<body>
<geom type="box" size="0.1 0.2 0.3" mass="8.800005" shellinertia="true"/>
</body>
<body>
<geom type="box" size="0.1 0.2 0.3" density="1e8"/>
</body>
<body>
<geom type="box" size="0.1000001 0.2000001 0.3000001" density="1e8"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1000> error;
mjModel* m = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(m, NotNull()) << error.data();
// dimensions
mjtNum dx = 0.1;
mjtNum dy = 0.2;
mjtNum dz = 0.3;
// length
mjtNum lx = 2 * dx;
mjtNum ly = 2 * dy;
mjtNum lz = 2 * dz;
// surface area
double A0 = lx * ly;
double A1 = ly * lz;
double A2 = lz * lx;
double Atotal = 2 * (A0 + A1 + A2);
// body 1: shell inertia
mjtNum mass1 = Atotal * 1000; // surface area * surface density
EXPECT_NEAR(m->body_mass[1], mass1, kInertiaTol);
mjtNum mass1_0 = mass1 * A0 / Atotal;
mjtNum mass1_1 = mass1 * A1 / Atotal;
mjtNum mass1_2 = mass1 * A2 / Atotal;
mjtNum I1x = 2 * (mass1_0 * ly * ly / 12 + mass1_0 * dz * dz +
mass1_1 * (ly * ly + lz * lz) / 12 +
mass1_2 * lz * lz / 12 + mass1_2 * dy * dy);
mjtNum I1y =
2 * (mass1_0 * lx * lx / 12 + mass1_0 * dz * dz + mass1_1 * lz * lz / 12 +
mass1_1 * dx * dx + mass1_2 * (lx * lx + lz * lz) / 12);
mjtNum I1z =
2 * (mass1_0 * (lx * lx + ly * ly) / 12 + mass1_1 * ly * ly / 12 +
mass1_1 * dx * dx + mass1_2 * lx * lx / 12 + mass1_2 * dy * dy);
EXPECT_NEAR(m->body_inertia[3], I1x, kInertiaTol);
EXPECT_NEAR(m->body_inertia[4], I1y, kInertiaTol);
EXPECT_NEAR(m->body_inertia[5], I1z, kInertiaTol);
// body 2: shell inertia, with specified mass
mjtNum mass2 = 8.800005;
EXPECT_NEAR(m->body_mass[2], mass2, 1e-6);
EXPECT_FLOAT_EQ(m->body_mass[4] - m->body_mass[3], m->body_mass[2]);
mjtNum mass2_0 = mass2 * A0 / Atotal;
mjtNum mass2_1 = mass2 * A1 / Atotal;
mjtNum mass2_2 = mass2 * A2 / Atotal;
mjtNum I2x = 2 * (mass2_0 * ly * ly / 12 + mass2_0 * dz * dz +
mass2_1 * (ly * ly + lz * lz) / 12 +
mass2_2 * lz * lz / 12 + mass2_2 * dy * dy);
mjtNum I2y =
2 * (mass2_0 * lx * lx / 12 + mass2_0 * dz * dz + mass2_1 * lz * lz / 12 +
mass2_1 * dx * dx + mass2_2 * (lx * lx + lz * lz) / 12);
mjtNum I2z =
2 * (mass2_0 * (lx * lx + ly * ly) / 12 + mass2_1 * ly * ly / 12 +
mass2_1 * dx * dx + mass2_2 * lx * lx / 12 + mass2_2 * dy * dy);
EXPECT_NEAR(m->body_inertia[6], I2x, kInertiaTol);
EXPECT_NEAR(m->body_inertia[7], I2y, kInertiaTol);
EXPECT_NEAR(m->body_inertia[8], I2z, kInertiaTol);
// compute approximate shell inertia by subtracting inertias of massive bodies
// with small radius difference
mjtNum* inertia3 = m->body_inertia + 9;
mjtNum* inertia4 = m->body_inertia + 12;
mjtNum shell_inertia[3];
mju_sub3(shell_inertia, inertia4, inertia3);
EXPECT_NEAR(shell_inertia[0], m->body_inertia[6], kInertiaTol);
EXPECT_NEAR(shell_inertia[1], m->body_inertia[7], kInertiaTol);
EXPECT_NEAR(shell_inertia[2], m->body_inertia[8], kInertiaTol);
mj_deleteModel(m);
}
// ------------- test inertiagrouprange ----------------------------------------
TEST_F(MjCGeomTest, IgnoreGeomOutsideInertiagrouprange) {
static constexpr char xml[] = R"(
<mujoco>
<compiler inertiagrouprange="0 1"/>
<worldbody>
<body>
<geom size="1" group="3"/>
</body>
</worldbody>
</mujoco>
)";
mjModel* m = LoadModelFromString(xml, nullptr, 0);
EXPECT_THAT(m->body_mass[1], 0);
mj_deleteModel(m);
}
TEST_F(MjCGeomTest, IgnoreBadGeomOutsideInertiagrouprange) {
static constexpr char xml[] = R"(
<mujoco>
<compiler inertiagrouprange="0 1"/>
<asset>
<mesh name="malformed_mesh"
vertex="0 0 0 1 0 0 0 1 0 0 0 1"
face="2 0 3 0 1 3 1 2 3 0 1 2" />
</asset>
<worldbody>
<body>
<geom type="mesh" mesh="malformed_mesh" group="3"/>
</body>
</worldbody>
</mujoco>
)";
mjModel* m = LoadModelFromString(xml, nullptr, 0);
EXPECT_THAT(m->body_mass[1], 0);
mj_deleteModel(m);
}
// ------------- test invalid size values --------------------------------------
TEST_F(MjCGeomTest, NanSize) {
// even if the caller ignores warnings, models shouldn't compile with NaN
// geom sizes
mju_user_warning = nullptr;
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<geom type="box" size="1 1 nan" mass="1" />
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1000> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, testing::IsNull());
ASSERT_THAT(error.data(), HasSubstr("nan"));
EXPECT_THAT(error.data(), HasSubstr("line 5"));
}
TEST_F(MjCGeomTest, BadMeshZeroMassDensityDoesntError) {
static constexpr char xml[] = R"(
<mujoco>
<asset>
<mesh name="bad_mesh"
vertex="0 0 0 1 0 0 0 1 0 0 0 1"
face="0 2 1" inertia="shell"/>
</asset>
<worldbody>
<body>
<geom type="mesh" mesh="bad_mesh" mass="0"/>
</body>
<body>
<geom type="mesh" mesh="bad_mesh" density="0"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, NotNull()) << error.data();
EXPECT_EQ(model->body_mass[1], 0);
EXPECT_EQ(model->body_mass[2], 0);
mj_deleteModel(model);
}
// ------------- test joints --------------------------------------------------
using MjCJointTest = MujocoTest;
TEST_F(MjCJointTest, AlignFree) {
const std::string xml_path =
GetTestDataFilePath("user/testdata/freejoint.xml");
std::array<char, 1024> err;
mjSpec* s = mj_parseXML(xml_path.c_str(), nullptr, err.data(), err.size());
ASSERT_THAT(s, NotNull()) << err.data();
s->compiler.alignfree = 1; // auto-aligned free joint
mjModel* m = mj_compile(s, nullptr);
ASSERT_THAT(m, NotNull());
// with alignfree the body has sameframe and simple and all dof are simple
EXPECT_EQ(m->body_sameframe[1], 1);
EXPECT_EQ(m->body_simple[1], 1);
EXPECT_EQ(m->dof_simplenum[0], 6);
// make unaligned model
s->compiler.alignfree = 0; // unaligned free joint
mjModel* m_u = mj_compile(s, nullptr);
ASSERT_THAT(m_u, NotNull());
// no sameframe or simple
EXPECT_EQ(m_u->body_sameframe[1], 0);
EXPECT_EQ(m_u->body_simple[1], 0);
// make datas for both models
mjData* d = mj_makeData(m);
mjData* d_u = mj_makeData(m_u);
// call mj_forward
mj_forward(m, d);
mj_forward(m_u, d_u);
// expect x-frames (sensors) to match to very high precision
double eps = 1e-10;
EXPECT_THAT(AsVector(d->sensordata, m->nsensordata),
Pointwise(DoubleNear(eps), AsVector(d_u->sensordata, m->nsensordata)));
// no frame sensors for lights, test separately
EXPECT_THAT(AsVector(d->light_xpos, 3),
Pointwise(DoubleNear(eps), AsVector(d_u->light_xpos, 3)));
EXPECT_THAT(AsVector(d->light_xdir, 3),
Pointwise(DoubleNear(eps), AsVector(d_u->light_xdir, 3)));
// reduce timestep to 0.1ms and use RK4, simulate for 1 second
m->opt.timestep = m_u->opt.timestep = 1e-4;
m->opt.integrator = m_u->opt.integrator = mjINT_RK4;
while (d->time < 1) {
mj_step(m, d);
mj_step(m_u, d_u);
}
// expect qpos to be significantly different, since the semantics are changed
mj_markStack(d);
int nq = m->nq;
mjtNum* dqpos = mj_stackAllocNum(d, nq);
mju_sub(dqpos, d->qpos, d_u->qpos, nq);
EXPECT_GT(mju_norm(dqpos, nq), 1.0);
mj_freeStack(d);
// expect x-frames to match to reasonable precision
eps = 1e-5;
EXPECT_THAT(AsVector(d->sensordata, m->nsensordata),
Pointwise(DoubleNear(eps), AsVector(d_u->sensordata, m->nsensordata)));
EXPECT_THAT(AsVector(d->light_xpos, 3),
Pointwise(DoubleNear(eps), AsVector(d_u->light_xpos, 3)));
EXPECT_THAT(AsVector(d->light_xdir, 3),
Pointwise(DoubleNear(eps), AsVector(d_u->light_xdir, 3)));
mj_deleteData(d_u);
mj_deleteData(d);
mj_deleteModel(m_u);
mj_deleteModel(m);
mj_deleteSpec(s);
}
// ------------- test height fields --------------------------------------------
using MjCHFieldTest = MujocoTest;
TEST_F(MjCHFieldTest, PngMap) {
const string xml_path =
GetTestDataFilePath("user/testdata/hfield_png.xml");
std::array<char, 1024> error;
mjModel* model =
mj_loadXML(xml_path.c_str(), nullptr, error.data(), error.size());
ASSERT_THAT(model, NotNull()) << error.data();
EXPECT_EQ(model->nhfield, 1);
EXPECT_EQ(model->geom_type[0], mjGEOM_HFIELD);
EXPECT_GT(model->nhfielddata, 0);
float min_hfield = 1e7;
float max_hfield = -1e7;
for (int i = 0; i < model->nhfielddata; i++) {
float v = model->hfield_data[i];
min_hfield = std::min(min_hfield, v);
max_hfield = std::max(max_hfield, v);
}
EXPECT_EQ(min_hfield, 0) << "hfield should be normalised to [0, 1]";
EXPECT_EQ(max_hfield, 1) << "hfield should be normalised to [0, 1]";
mj_deleteModel(model);
}
// ------------- test textures -------------------------------------------------
using MjCTextureTest = MujocoTest;
TEST_F(MjCTextureTest, TexturesLoad) {
static constexpr char xml[] = R"(
<mujoco>
<asset>
<texture name="body" type="cube" builtin="flat" mark="cross" width="8"
rgb1="0.8 0.6 0.4" rgb2="0.8 0.6 0.4" markrgb="1 1 1"/>
</asset>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* m = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(m, NotNull()) << error.data();
mj_deleteModel(m);
}
// ------------- test quaternion normalization----------------------------------
using QuatNorm = MujocoTest;
TEST_F(QuatNorm, QuatNotNormalized) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<site quat="1 2 2 4"/>
<camera quat="1 2 2 4"/>
<body quat="1 2 2 4">
<geom quat="1 2 2 4" size="1"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* m = LoadModelFromString(xml, error.data(), error.size());
EXPECT_THAT(AsVector(m->body_quat+4, 4), ElementsAre(1./5, 2./5, 2./5, 4./5));
EXPECT_THAT(AsVector(m->geom_quat, 4), ElementsAre(1./5, 2./5, 2./5, 4./5));
EXPECT_THAT(AsVector(m->site_quat, 4), ElementsAre(1./5, 2./5, 2./5, 4./5));
EXPECT_THAT(AsVector(m->cam_quat, 4), ElementsAre(1./5, 2./5, 2./5, 4./5));
mj_deleteModel(m);
}
// ------------- test camera specifications ------------------------------------
using CameraSpecTest = MujocoTest;
TEST_F(CameraSpecTest, FovyLimits) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<geom size="1"/>
<camera fovy="180"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* m = LoadModelFromString(xml, error.data(), error.size());
EXPECT_THAT(m, IsNull()) << error.data();
EXPECT_THAT(error.data(), HasSubstr("fovy too large"));
EXPECT_THAT(error.data(), HasSubstr("line 6"));
mj_deleteModel(m);
}
TEST_F(CameraSpecTest, DuplicatedFocalIgnorePixel) {
static constexpr char xml[] = R"(
<mujoco>
<visual>
<map znear="0.01"/>
</visual>
<worldbody>
<body>
<geom size="1"/>
<camera focal="8e-3 8e-3" focalpixel="100 100"
resolution="1920 1200" sensorsize="9.6e-3 6e-3"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* m = LoadModelFromString(xml, error.data(), error.size());
EXPECT_THAT(m, NotNull()) << error.data();
EXPECT_NEAR(m->cam_intrinsic[0], 5e-4, 1e-6); // focal length in meters (x)
EXPECT_NEAR(m->cam_intrinsic[1], 5e-4, 1e-6); // focal length in meters (y)
mj_deleteModel(m);
}
TEST_F(CameraSpecTest, FovyFromResolution) {
static constexpr char xml[] = R"(
<mujoco>
<visual>
<map znear="0.01"/>
</visual>
<worldbody>
<body>
<geom size="1"/>
<!-- 8mm focal length lenses -->
<camera focal="8e-3 8e-3" resolution="1920 1200" sensorsize="9.6e-3 6e-3"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* m = LoadModelFromString(xml, error.data(), error.size());
EXPECT_THAT(m, NotNull()) << error.data();
EXPECT_NEAR(m->cam_fovy[0], 41.112, 1e-3);
EXPECT_NEAR(m->cam_intrinsic[0], 8e-3, 1e-6); // focal length in meters (x)
EXPECT_NEAR(m->cam_intrinsic[1], 8e-3, 1e-6); // focal length in meters (y)
EXPECT_EQ(m->cam_intrinsic[2], 0); // principal point in meters (x)
EXPECT_EQ(m->cam_intrinsic[3], 0); // principal point in meters (y)
mj_deleteModel(m);
}
TEST_F(CameraSpecTest, FovyFromResolutionPixel) {
static constexpr char xml[] = R"(
<mujoco>
<visual>
<map znear="0.01"/>
</visual>
<worldbody>
<body>
<geom size="1"/>
<!-- 8mm focal length lenses -->
<camera focalpixel="1600 1600" resolution="1920 1200" sensorsize="9.6e-3 6e-3"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* m = LoadModelFromString(xml, error.data(), error.size());
EXPECT_THAT(m, NotNull()) << error.data();
EXPECT_NEAR(m->cam_fovy[0], 41.112, 1e-3);
EXPECT_NEAR(m->cam_intrinsic[0], 8e-3, 1e-6); // focal length in meters (x)
EXPECT_NEAR(m->cam_intrinsic[1], 8e-3, 1e-6); // focal length in meters (y)
EXPECT_EQ(m->cam_intrinsic[2], 0); // principal point in meters (x)
EXPECT_EQ(m->cam_intrinsic[3], 0); // principal point in meters (y)
mj_deleteModel(m);
}
TEST_F(CameraSpecTest, ParentTargetingNull) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<geom size="1"/>
<camera mode="targetbody" target="world"/>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
EXPECT_THAT(model, NotNull()) << error.data();
mjData* data = mj_makeData(model);
mj_forward(model, data);
// orientation can't be decided so we get an arbitrary but valid xmat
// (camera pointed towards the negative x-axis)
EXPECT_THAT(AsVector(data->cam_xmat, 9),
ElementsAre(0, 0, 1,
1, 0, 0,
0, 1, 0));
mj_deleteData(data);
mj_deleteModel(model);
}
TEST_F(CameraSpecTest, ParentTargeting) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<geom size="1"/>
<camera pos="1 1 0" mode="targetbody" target="world"/>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
EXPECT_THAT(model, NotNull()) << error.data();
mjData* data = mj_makeData(model);
mj_forward(model, data);
// expect negative z-axis to point from camera to world
EXPECT_FLOAT_EQ(data->cam_xmat[2], mju_sqrt(0.5));
EXPECT_FLOAT_EQ(data->cam_xmat[5], mju_sqrt(0.5));
EXPECT_FLOAT_EQ(data->cam_xmat[8], 0);
mj_deleteData(data);
mj_deleteModel(model);
}
// ------------- test actuator order -------------------------------------------
using ActuatorTest = MujocoTest;
TEST_F(ActuatorTest, ActuatorOrderDoesntMatter) {
static constexpr char xml1[] = R"(
<mujoco>
<worldbody>
<body>
<joint name="hinge"/>
<geom size="1"/>
</body>
</worldbody>
<actuator>
<general joint="hinge" dyntype="filter"/>
<general joint="hinge"/>
</actuator>
</mujoco>
)";
static constexpr char xml2[] = R"(
<mujoco>
<worldbody>
<body>
<joint name="hinge"/>
<geom size="1"/>
</body>
</worldbody>
<actuator>
<general joint="hinge"/>
<general joint="hinge" dyntype="filter"/>
</actuator>
</mujoco>
)";
mjModel* model1 = LoadModelFromString(xml1, nullptr, 0);
mjData* data1 = mj_makeData(model1);
mjModel* model2 = LoadModelFromString(xml2, nullptr, 0);
mjData* data2 = mj_makeData(model2);
// check activation indexing
EXPECT_EQ(model1->actuator_actadr[0], 0);
EXPECT_EQ(model1->actuator_actadr[1], -1);
EXPECT_EQ(model2->actuator_actadr[0], -1);
EXPECT_EQ(model2->actuator_actadr[1], 0);
// integrate both models, flipping the controls
while (data1->time < 1) {
data1->ctrl[0] = data1->time;
data1->ctrl[1] = -data1->time;
mj_step(model1, data1);
}
while (data2->time < 1) {
data2->ctrl[0] = -data2->time;
data2->ctrl[1] = data2->time;
mj_step(model2, data2);
}
// expect states to match exactly
EXPECT_EQ(data1->qpos[0], data2->qpos[0]);
EXPECT_EQ(data1->qvel[0], data2->qvel[0]);
EXPECT_EQ(data1->act[0], data2->act[0]);
mj_deleteData(data2);
mj_deleteModel(model2);
mj_deleteData(data1);
mj_deleteModel(model1);
}
// ------------- test inheritrange attribute ----------------------------------
using InheritrangeTest = MujocoTest;
TEST_F(InheritrangeTest, ErrorIfTargetMissingRange) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<joint name="jnt"/>
<geom size="1"/>
</body>
</worldbody>
<actuator>
<position joint="jnt" inheritrange="1"/>
</actuator>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("target 'jnt' has no range defined"));
}
TEST_F(InheritrangeTest, WorksForDegrees) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<joint name="jnt" range="90 180"/>
<geom size="1"/>
</body>
</worldbody>
<actuator>
<position joint="jnt" inheritrange="1"/>
</actuator>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, NotNull()) << error.data();
EXPECT_DOUBLE_EQ(model->actuator_ctrlrange[0], mjPI/2);
EXPECT_DOUBLE_EQ(model->actuator_ctrlrange[1], mjPI);
mj_deleteModel(model);
}
// ------------- test actlimited and actrange fields ---------------------------
using ActRangeTest = MujocoTest;
TEST_F(ActRangeTest, ActRangeParsed) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<joint name="hinge"/>
<geom size="1"/>
</body>
</worldbody>
<actuator>
<general dyntype="integrator" joint="hinge" actlimited="true" actrange="-1 1.5"/>
</actuator>
</mujoco>
)";
mjModel* m = LoadModelFromString(xml, nullptr, 0);
EXPECT_EQ(m->actuator_actlimited[0], 1);
EXPECT_EQ(m->actuator_actrange[0], -1);
EXPECT_EQ(m->actuator_actrange[1], 1.5);
mj_deleteModel(m);
}
TEST_F(ActRangeTest, ActRangeBad) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<joint name="hinge"/>
<geom size="1"/>
</body>
</worldbody>
<actuator>
<general dyntype="integrator" joint="hinge" actlimited="true" actrange="1 -1"/>
</actuator>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("invalid actrange"));
EXPECT_THAT(error.data(), HasSubstr("line 10"));
}
TEST_F(ActRangeTest, ActRangeUndefined) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<joint name="hinge"/>
<geom size="1"/>
</body>
</worldbody>
<actuator>
<general dyntype="integrator" joint="hinge" actlimited="true"/>
</actuator>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("invalid actrange"));
EXPECT_THAT(error.data(), HasSubstr("line 10"));
}
TEST_F(ActRangeTest, ActRangeNoDyntype) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<joint name="hinge"/>
<geom size="1"/>
</body>
</worldbody>
<actuator>
<general joint="hinge" actlimited="true" actrange="-1 1"/>
</actuator>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(),
HasSubstr("actrange specified but dyntype is 'none'"));
}
TEST_F(ActRangeTest, ActRangeDefaultsPropagate) {
static constexpr char xml[] = R"(
<mujoco>
<option timestep="0.01"/>
<default>
<general dyntype="integrator" actlimited="true" actrange="-1 1"/>
<default class="dclass">
<general actlimited="false" actrange="2 3"/>
</default>
</default>
<worldbody>
<body>
<joint name="slide" type="slide" axis="1 0 0"/>
<geom size=".1"/>
</body>
</worldbody>
<actuator>
<general joint="slide"/>
<general joint="slide" class="dclass"/>
</actuator>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
// first actuator
EXPECT_THAT(model->actuator_actlimited[0], 1);
EXPECT_THAT(model->actuator_actrange[0], -1);
EXPECT_THAT(model->actuator_actrange[1], 1);
// // second actuator
EXPECT_THAT(model->actuator_actlimited[1], 0);
EXPECT_THAT(model->actuator_actrange[2], 2);
EXPECT_THAT(model->actuator_actrange[3], 3);
mj_deleteModel(model);
}
// ---------------------------- test actdim ------------------------------------
using ActDimTest = MujocoTest;
TEST_F(ActDimTest, BiggerThanOneOnlyForUser) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<geom size="1"/>
<joint name="hinge"/>
</body>
</worldbody>
<actuator>
<general joint="hinge" actdim="2"/>
</actuator>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(),
HasSubstr("actdim > 1 is only allowed for dyntype 'user'"));
}
TEST_F(ActDimTest, NonzeroNotAllowedInStateless) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<geom size="1"/>
<joint name="hinge"/>
</body>
</worldbody>
<actuator>
<general joint="hinge" actdim="1"/>
</actuator>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("invalid actdim 1 in stateless"));
EXPECT_THAT(error.data(), HasSubstr("line 10"));
}
TEST_F(ActDimTest, ZeroNotAllowedInStateful) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<body>
<geom size="1"/>
<joint name="hinge"/>
</body>
</worldbody>
<actuator>
<general joint="hinge" dyntype="filter" actdim="0"/>
</actuator>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("invalid actdim 0 in stateful"));
EXPECT_THAT(error.data(), HasSubstr("line 10"));
}
// ------------- test nuser_xxx fields -----------------------------------------
using UserDataTest = MujocoTest;
TEST_F(UserDataTest, NBodyTooSmall) {
static constexpr char xml[] = R"(
<mujoco>
<size nuser_body="2"/>
<worldbody>
<body user="1 2 3"/>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("nuser_body"));
EXPECT_THAT(error.data(), HasSubstr("line 5"));
}
TEST_F(UserDataTest, NJointTooSmall) {
static constexpr char xml[] = R"(
<mujoco>
<size nuser_jnt="2"/>
<worldbody>
<body>
<geom size="1"/>
<joint user="1 2 3"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("nuser_jnt"));
EXPECT_THAT(error.data(), HasSubstr("line 7"));
}
TEST_F(UserDataTest, NGeomTooSmall) {
static constexpr char xml[] = R"(
<mujoco>
<size nuser_geom="2"/>
<worldbody>
<geom size="1" user="1 2 3"/>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("nuser_geom"));
EXPECT_THAT(error.data(), HasSubstr("line 5"));
}
TEST_F(UserDataTest, NSiteTooSmall) {
static constexpr char xml[] = R"(
<mujoco>
<size nuser_site="2"/>
<worldbody>
<site user="1 2 3"/>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("nuser_site"));
EXPECT_THAT(error.data(), HasSubstr("line 5"));
}
TEST_F(UserDataTest, NCameraTooSmall) {
static constexpr char xml[] = R"(
<mujoco>
<size nuser_cam="2"/>
<worldbody>
<camera user="1 2 3"/>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("nuser_cam"));
EXPECT_THAT(error.data(), HasSubstr("line 5"));
}
TEST_F(UserDataTest, NTendonTooSmall) {
static constexpr char xml[] = R"(
<mujoco>
<size nuser_tendon="2"/>
<worldbody>
<site name="a"/>
<site name="b"/>
</worldbody>
<tendon>
<spatial user="1 2 3">
<site site="a"/>
<site site="b"/>
</spatial>
</tendon>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("nuser_tendon"));
EXPECT_THAT(error.data(), HasSubstr("line 9"));
}
TEST_F(UserDataTest, NActuatorTooSmall) {
static constexpr char xml[] = R"(
<mujoco>
<size nuser_actuator="2"/>
<worldbody>
<body>
<geom size="1"/>
<joint name="a"/>
</body>
</worldbody>
<actuator>
<motor joint="a" user="1 2 3"/>
</actuator>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("nuser_actuator"));
EXPECT_THAT(error.data(), HasSubstr("line 11"));
}
TEST_F(UserDataTest, NSensorTooSmall) {
static constexpr char xml[] = R"(
<mujoco>
<size nuser_sensor="2"/>
<worldbody>
<site name="a"/>
</worldbody>
<sensor>
<accelerometer site="a" user="1 2 3"/>
</sensor>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("nuser_sensor"));
EXPECT_THAT(error.data(), HasSubstr("line 8"));
}
// ------------- test for auto parsing of *limited fields ----------------------
using LimitedTest = MujocoTest;
constexpr char kKeyAutoLimits[] = "user/testdata/auto_limits.xml";
// check joint limit values when automatically inferred based on range
TEST_F(LimitedTest, JointLimited) {
const string path = GetTestDataFilePath(kKeyAutoLimits);
std::array<char, 1024> err;
mjModel* model = mj_loadXML(path.c_str(), nullptr, err.data(), err.size());
ASSERT_THAT(model, NotNull()) << err.data();
// see `user/testdata/auto_limits.xml` for expected values
for (int i=0; i < model->njnt; i++) {
EXPECT_EQ(model->jnt_limited[i], (mjtByte)model->jnt_user[i])
<< i << " " << (int)model->jnt_limited[i] << " "
<< (int)model->jnt_user[i];
}
mj_deleteModel(model);
}
TEST_F(LimitedTest, ErrorIfLimitedMissingOnJoint) {
static constexpr char xml[] = R"(
<mujoco>
<compiler autolimits="false"/>
<worldbody>
<body>
<joint user="1" range="0 1"/>
<geom size="1"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("limited"));
EXPECT_THAT(error.data(), HasSubstr("line 6"));
}
TEST_F(LimitedTest, ExplicitLimitedFalseIsOk) {
static constexpr char xml[] = R"(
<mujoco>
<compiler autolimits="false"/>
<worldbody>
<body>
<joint user="1" limited="false" range="0 1"/>
<geom size="1"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, NotNull()) << error.data();
EXPECT_EQ(model->jnt_limited[0], 0);
mj_deleteModel(model);
}
TEST_F(LimitedTest, ErrorIfLimitedMissingOnTendon) {
static constexpr char xml[] = R"(
<mujoco>
<compiler autolimits="false"/>
<worldbody>
<body>
<joint type="slide"/>
<geom size="1"/>
<site name="s1"/>
</body>
<site name="s2"/>
</worldbody>
<tendon>
<spatial range="-1 1">
<site site="s1"/>
<site site="s2"/>
</spatial>
</tendon>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("limited"));
EXPECT_THAT(error.data(), HasSubstr("tendon"));
EXPECT_THAT(error.data(), HasSubstr("line 13"));
}
TEST_F(LimitedTest, ErrorIfForceLimitedMissingOnActuator) {
static constexpr char xml[] = R"(
<mujoco>
<compiler autolimits="false"/>
<worldbody>
<body>
<joint type="slide" name="J1"/>
<geom size="1"/>
</body>
</worldbody>
<actuator>
<position joint="J1" forcerange="0 100"/>
</actuator>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("forcelimited"));
EXPECT_THAT(error.data(), HasSubstr("forcerange"));
EXPECT_THAT(error.data(), HasSubstr("actuator"));
EXPECT_THAT(error.data(), HasSubstr("line 11"));
}
// ------------- tests for tendon ----------------------------------------------
using TendonTest = MujocoTest;
TEST_F(TendonTest, SiteBetweenPulleyNotAllowed) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<site name="1"/>
<site name="2"/>
<site name="3"/>
</worldbody>
<tendon>
<spatial>
<site site="1"/>
<pulley divisor="1"/>
<site site="3"/>
</spatial>
</tendon>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
EXPECT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("needs a neighbor that is not a pulley"));
EXPECT_THAT(error.data(), HasSubstr("line 9"));
}
TEST_F(TendonTest, ActuatorForceRangeNotAllowed) {
std::string xml = R"(
<mujoco>
<worldbody>
<site name="site0"/>
<site name="site1"/>
</worldbody>
<tendon>
<spatial name="spatial" actuatorfrclimited="true" actuatorfrcrange="{}">
<site site="site0"/>
<site site="site1"/>
</spatial>
</tendon>
<actuator>
<motor tendon="spatial"/>
</actuator>
</mujoco>
)";
std::array<char, 1024> error;
std::string str_replace = "{}";
size_t rng_ind = xml.find(str_replace);
std::string xml0 = xml;
std::string range0 = "-2 -1";
xml0.replace(rng_ind, str_replace.length(), range0);
mjModel* m0 = LoadModelFromString(xml0.c_str(), error.data(), error.size());
EXPECT_THAT(m0, IsNull());
EXPECT_THAT(error.data(), HasSubstr("invalid actuatorfrcrange in tendon"));
std::string xml1 = xml;
std::string range1 = "1 2";
xml1.replace(rng_ind, str_replace.length(), range1);
mjModel* m1 = LoadModelFromString(xml1.c_str(), error.data(), error.size());
EXPECT_THAT(m1, IsNull());
EXPECT_THAT(error.data(), HasSubstr("invalid actuatorfrcrange in tendon"));
std::string xml2 = xml;
std::string range2 = "1 0";
xml2.replace(rng_ind, str_replace.length(), range2);
mjModel* m2 = LoadModelFromString(xml2.c_str(), error.data(), error.size());
EXPECT_THAT(m2, IsNull());
EXPECT_THAT(error.data(), HasSubstr("invalid actuatorfrcrange in tendon"));
}
// ------------- tests for tendon springrange ----------------------------------
using SpringrangeTest = MujocoTest;
TEST_F(SpringrangeTest, DefaultsPropagate) {
static constexpr char xml[] = R"(
<mujoco>
<default>
<tendon springlength=".2 .5"/>
</default>
<worldbody>
<site name="0"/>
<site name="1" pos="1 0 0"/>
</worldbody>
<tendon>
<spatial>
<site site="0"/>
<site site="1"/>
</spatial>
</tendon>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, NotNull()) << error.data();
EXPECT_EQ(model->tendon_lengthspring[0], .2);
EXPECT_EQ(model->tendon_lengthspring[1], .5);
mj_deleteModel(model);
}
TEST_F(SpringrangeTest, InvalidRange) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<site name="0"/>
<site name="1" pos="1 0 0"/>
</worldbody>
<tendon>
<spatial springlength="1 0">
<site site="0"/>
<site site="1"/>
</spatial>
</tendon>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* model = LoadModelFromString(xml, error.data(), error.size());
ASSERT_THAT(model, IsNull());
EXPECT_THAT(error.data(), HasSubstr("invalid springlength in tendon"));
EXPECT_THAT(error.data(), HasSubstr("line 9"));
}
using UserObjectsTest = MujocoTest;
// ------------- test frame ----------------------------------------------------
TEST_F(UserObjectsTest, Frame) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<frame euler="0 0 30">
<geom name="0" size=".1" euler="0 0 20"/>
</frame>
<frame axisangle="0 1 0 90">
<frame axisangle="0 0 1 90">
<geom name="1" size=".1"/>
</frame>
</frame>
<frame pos="0 1 0" euler="0 20 0">
<geom name="2" pos=".5 .6 .7" size=".1" euler="30 0 0"/>
</frame>
<body>
<frame pos="0 1 0">
<geom name="3" size=".1" pos="0 1 0"/>
<body pos="1 0 0">
<geom name="4" size=".1" pos="0 0 1"/>
</body>
</frame>
</body>
<body>
<geom name="5" size=".1"/>
<frame euler="90 0 0">
<joint type="hinge" axis="0 0 1"/>
</frame>
</body>
<body pos="0 1 0" euler="0 20 0">
<geom name="6" pos=".5 .6 .7" size=".1" euler="30 0 0"/>
</body>
</worldbody>
</mujoco>
)";
constexpr mjtNum eps = 1e-14;
std::array<char, 1024> error;
mjModel* m = LoadModelFromString(xml, error.data(), error.size());
EXPECT_THAT(m, testing::NotNull()) << error.data();
EXPECT_EQ(m->nbody, 5);
// geom quat transformed to euler = 0 0 50
EXPECT_NEAR(m->geom_quat[0], mju_cos(25. * mjPI / 180.), 1e-3);
EXPECT_NEAR(m->geom_quat[1], 0, 0);
EXPECT_NEAR(m->geom_quat[2], 0, 0);
EXPECT_NEAR(m->geom_quat[3], mju_sin(25. * mjPI / 180.), 1e-3);
// geom transformed to frame 0 1 0, 0 0 1, 1 0 0
EXPECT_NEAR(m->geom_quat[4], .5, eps);
EXPECT_NEAR(m->geom_quat[5], .5, eps);
EXPECT_NEAR(m->geom_quat[6], .5, eps);
EXPECT_NEAR(m->geom_quat[7], .5, eps);
// geom pos transformed from 0 1 0 to 0 2 0
EXPECT_EQ(m->geom_pos[ 9], 0);
EXPECT_EQ(m->geom_pos[10], 2);
EXPECT_EQ(m->geom_pos[11], 0);
// body pos transformed from 1 0 0 to 1 1 0
EXPECT_EQ(m->body_pos[6], 1);
EXPECT_EQ(m->body_pos[7], 1);
EXPECT_EQ(m->body_pos[8], 0);
// nested geom pos not transformed
EXPECT_EQ(m->geom_pos[12], 0);
EXPECT_EQ(m->geom_pos[13], 0);
EXPECT_EQ(m->geom_pos[14], 1);
// joint axis transformed to 0 -1 0
EXPECT_NEAR(m->jnt_axis[0], 0, eps);
EXPECT_NEAR(m->jnt_axis[1], -1, eps);
EXPECT_NEAR(m->jnt_axis[2], 0, eps);
mjData* d = mj_makeData(m);
mj_kinematics(m, d);
// body and frame equivalence geom 2 vs 6
EXPECT_NEAR(d->geom_xpos[6], d->geom_xpos[18], eps);
EXPECT_NEAR(d->geom_xpos[7], d->geom_xpos[19], eps);
EXPECT_NEAR(d->geom_xpos[8], d->geom_xpos[20], eps);
EXPECT_NEAR(d->geom_xmat[18], d->geom_xmat[54], eps);
EXPECT_NEAR(d->geom_xmat[19], d->geom_xmat[55], eps);
EXPECT_NEAR(d->geom_xmat[20], d->geom_xmat[56], eps);
EXPECT_NEAR(d->geom_xmat[21], d->geom_xmat[57], eps);
mj_deleteModel(m);
mj_deleteData(d);
}
TEST_F(UserObjectsTest, FrameTransformsLight) {
static constexpr char xml[] = R"(
<mujoco>
<worldbody>
<frame euler="0 45 0" pos="0 0 1">
<light pos="-1 0 0" dir="1 0 -1"/>
</frame>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* m = LoadModelFromString(xml, error.data(), error.size());
EXPECT_THAT(m, NotNull()) << error.data();
EXPECT_EQ(m->nlight, 1);
constexpr mjtNum eps = 1e-14;
EXPECT_NEAR(m->light_pos[0], -mju_sqrt(.5), eps);
EXPECT_NEAR(m->light_pos[1], 0, eps);
EXPECT_NEAR(m->light_pos[2], 1 + mju_sqrt(.5), eps);
EXPECT_NEAR(m->light_dir[0], 0, eps);
EXPECT_NEAR(m->light_dir[1], 0, eps);
EXPECT_NEAR(m->light_dir[2], -1, eps);
mj_deleteModel(m);
}
TEST_F(ContentTypeTest, ImageLightsReferenceTexture) {
static constexpr char xml[] = R"(
<mujoco>
<asset>
<texture name="texture" type="cube" builtin="flat" mark="cross" width="8"
rgb1="0.8 0.6 0.4" rgb2="0.8 0.6 0.4" markrgb="1 1 1"/>
</asset>
<worldbody>
<light type="image" texture="texture"/>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* m = LoadModelFromString(xml, error.data(), error.size());
EXPECT_THAT(m, NotNull());
EXPECT_EQ(m->ntex, 1);
EXPECT_EQ(m->nlight, 1);
EXPECT_THAT(m->light_texid[0], 0);
mj_deleteModel(m);
}
// ------------- test bvh ------------------------------------------------------
TEST_F(UserObjectsTest, RobustBVH) {
static constexpr char xml1[] = R"(
<mujoco>
<worldbody>
<body>
<geom size=".1" pos="0 0 0"/>
<geom size=".1" pos="0 1 0"/>
<geom size=".1" pos="1 0 0"/>
<geom size=".1" pos="1 1 0"/>
<geom size=".1" pos="2 0 0"/>
<geom size=".1" pos="2 1 0"/>
</body>
</worldbody>
</mujoco>
)";
static constexpr char xml2[] = R"(
<mujoco>
<worldbody>
<body>
<geom size=".1" pos="0 0 0"/>
<geom size=".1" pos="0 1 0"/>
<geom size=".1" pos="1.00000000000001 0 0"/>
<geom size=".1" pos="1 1.00000000000001 0"/>
<geom size=".1" pos="2 0 0"/>
<geom size=".1" pos="2 1 0"/>
</body>
</worldbody>
</mujoco>
)";
std::array<char, 1024> error;
mjModel* m1 = LoadModelFromString(xml1, error.data(), error.size());
EXPECT_THAT(m1, NotNull()) << error.data();
mjModel* m2 = LoadModelFromString(xml2, error.data(), error.size());
EXPECT_THAT(m2, NotNull()) << error.data();
EXPECT_EQ(m1->nbvh, m2->nbvh);
for (int i = 0; i < m1->nbvh; i++) {
EXPECT_EQ(m1->bvh_nodeid[i], m2->bvh_nodeid[i]);
}
mj_deleteModel(m1);
mj_deleteModel(m2);
}
// ------------- test equality compilation -------------------------------------
TEST_F(UserObjectsTest, BadConnect) {
string base = R"(
<mujoco>
<worldbody>
<site name="0" size="1"/>
<body name="1" pos="0 0 1">
<freejoint/>
<geom size="1"/>
<site name="1"/>
</body>
</worldbody>
<equality>
CONNECT
</equality>
</mujoco>
)";
int pos = base.find("CONNECT");
int len = 7;
// good model using body semantic
string xml = base.replace(pos, len, "<connect body1='1' anchor='0 0 1'/>");
char error[1024];
mjModel* m = LoadModelFromString(xml.c_str(), error, sizeof(error));
ASSERT_THAT(m, NotNull()) << error;
EXPECT_THAT(AsVector(m->eq_data, 6), ElementsAre(0, 0, 1, 0, 0, 2));
mj_deleteModel(m);
// good model using site semantic
xml = base.replace(pos, len, "<connect site1='0' site2='1'/>");
m = LoadModelFromString(xml.c_str(), error, sizeof(error));
ASSERT_THAT(m, NotNull()) << error;
EXPECT_THAT(AsVector(m->eq_data, 6), ElementsAre(0, 0, 0, 0, 0, 0));
mj_deleteModel(m);
char error_missing[] = "either both body1 and anchor must be defined,"
" or both site1 and site2 must be defined\nElement 'connect', line 12";
// bad model (missing anchor)
xml = base.replace(pos, len, "<connect body1='1'/>");
m = LoadModelFromString(xml.c_str(), error, sizeof(error));
ASSERT_THAT(m, IsNull());
EXPECT_THAT(error, HasSubstr(error_missing));
char error_mixed[] = "body and site semantics cannot be mixed"
"\nElement 'connect', line 12";
// bad model (mixing body and site)
xml = base.replace(pos, len, "<connect body1='1' site1='1'/>");
m = LoadModelFromString(xml.c_str(), error, sizeof(error));
ASSERT_THAT(m, IsNull());
EXPECT_THAT(error, HasSubstr(error_mixed));
// load spec with no constraints
xml = base.erase(pos, len);
mjSpec* s = mj_parseXMLString(xml.c_str(), nullptr, error, sizeof(error));
ASSERT_THAT(s, NotNull()) << error;
// add a connect but don't set objtype
mjsEquality* equality = mjs_addEquality(s, nullptr);
equality->type = mjEQ_CONNECT;
mjs_setString(equality->name1, "0");
mjs_setString(equality->name2, "1");
// expect compilation to fail
m = mj_compile(s, nullptr);
ASSERT_THAT(m, IsNull());
EXPECT_THAT(mjs_getError(s),
HasSubstr("connect constraint supports only sites and bodies"));
// set objtype, expect compilation to succeed
equality->objtype = mjOBJ_SITE;
m = mj_compile(s, nullptr);
ASSERT_THAT(m, NotNull()) << mjs_getError(s);
mj_deleteModel(m);
mj_deleteSpec(s);
}
TEST_F(UserObjectsTest, BadWeld) {
string base = R"(
<mujoco>
<worldbody>
<site name="0" size="1"/>
<body name="1" pos="0 0 1">
<freejoint/>
<geom size="1"/>
<site name="1"/>
</body>
</worldbody>
<equality>
WELD
</equality>
</mujoco>
)";
int pos = base.find("WELD");
int len = 4;
// good model using body semantic
string xml = base.replace(pos, len,
"<weld body1='1' anchor='0 0 1' torquescale='2'/>");
char error[1024];
mjModel* m = LoadModelFromString(xml.c_str(), error, sizeof(error));
ASSERT_THAT(m, NotNull()) << error;
EXPECT_THAT(AsVector(m->eq_data, 10),
ElementsAre(0, 0, 1, 0, 0, 0, 1, 0, 0, 0));
mj_deleteModel(m);
// good model using site semantic
xml = base.replace(pos, len, "<weld site1='0' site2='1' torquescale='2'/>");
m = LoadModelFromString(xml.c_str(), error, sizeof(error));
ASSERT_THAT(m, NotNull()) << error;
EXPECT_THAT(AsVector(m->eq_data, 10),
ElementsAre(0, 1, 0, 0, 0, 0, 0, 0, 0, 0));
mj_deleteModel(m);
char error_mixed[] =
"body and site semantics cannot be mixed"
"\nElement 'weld', line 12";
// bad model (mixing body and site)
xml = base.replace(pos, len, "<weld body1='1' site1='1'/>");
m = LoadModelFromString(xml.c_str(), error, sizeof(error));
ASSERT_THAT(m, IsNull());
EXPECT_THAT(error, HasSubstr(error_mixed));
// bad model (mixing site and anchor)
xml = base.replace(pos, len, "<weld anchor='0 0 1' site1='1'/>");
m = LoadModelFromString(xml.c_str(), error, sizeof(error));
ASSERT_THAT(m, IsNull());
EXPECT_THAT(error, HasSubstr(error_mixed));
// bad model (mixing site and relpose)
xml = base.replace(pos, len, "<weld relpose='0 0 0 1 0 0 0' site1='1'/>");
m = LoadModelFromString(xml.c_str(), error, sizeof(error));
ASSERT_THAT(m, IsNull());
EXPECT_THAT(error, HasSubstr(error_mixed));
// bad model (body and site semantics are valid, but both are specified)
xml = base.replace(pos, len, "<weld body1='1' site1='1' site2='1'/>");
m = LoadModelFromString(xml.c_str(), error, sizeof(error));
ASSERT_THAT(m, IsNull());
EXPECT_THAT(error, HasSubstr(error_mixed));
char error_underspecified[] =
"either body1 must be defined and optionally {body2, anchor, "
"relpose}, or site1 and site2 must be defined\nElement 'weld', line 12";
// bad model (underspecified body semantics)
xml = base.replace(pos, len, "<weld anchor='0 0 1'/>");
m = LoadModelFromString(xml.c_str(), error, sizeof(error));
ASSERT_THAT(m, IsNull());
EXPECT_THAT(error, HasSubstr(error_underspecified));
// bad model (underspecified site semantics)
xml = base.replace(pos, len, "<weld site2='1'/>");
m = LoadModelFromString(xml.c_str(), error, sizeof(error));
ASSERT_THAT(m, IsNull());
EXPECT_THAT(error, HasSubstr(error_underspecified));
// load spec with no constraints
xml = base.erase(pos, len);
mjSpec* s = mj_parseXMLString(xml.c_str(), nullptr, error, sizeof(error));
ASSERT_THAT(s, NotNull()) << error;
// add a weld but don't set objtype
mjsEquality* equality = mjs_addEquality(s, nullptr);
equality->type = mjEQ_WELD;
mjs_setString(equality->name1, "0");
mjs_setString(equality->name2, "1");
// expect compilation to fail
m = mj_compile(s, nullptr);
ASSERT_THAT(m, IsNull());
EXPECT_THAT(mjs_getError(s),
HasSubstr("weld constraint supports only sites and bodies"));
// set objtype, expect compilation to succeed
equality->objtype = mjOBJ_SITE;
m = mj_compile(s, nullptr);
ASSERT_THAT(m, NotNull()) << mjs_getError(s);
mj_deleteModel(m);
mj_deleteSpec(s);
}
TEST_F(UserObjectsTest, Inertial) {
string xml = R"(
<mujoco>
<compiler angle="radian"/>
<worldbody>
<body>
<inertial mass="1" pos="2 3 4" euler="3 4 5" diaginertia="4 5 6"/>
</body>
<body>
<inertial mass="2" pos="1 2 3" fullinertia="4 3 2 0 0 0"/>
</body>
</worldbody>
</mujoco>
)";
char error[1024];
mjModel* m = LoadModelFromString(xml.c_str(), error, sizeof(error));
ASSERT_THAT(m, NotNull()) << error;
EXPECT_EQ(m->body_mass[1], 1);
EXPECT_THAT(AsVector(m->body_ipos+3, 3), ElementsAre(2, 3, 4));
EXPECT_THAT(AsVector(m->body_inertia+3, 3), ElementsAre(4, 5, 6));
mjtNum quat[4];
const mjtNum euler[3] = {3, 4, 5};
mju_euler2Quat(quat, euler, "xyz");
EXPECT_THAT(AsVector(m->body_iquat+4, 4),
Pointwise(DoubleNear(1e-8), AsVector(quat, 4)));
EXPECT_EQ(m->body_mass[2], 2);
EXPECT_THAT(AsVector(m->body_ipos+6, 3), ElementsAre(1, 2, 3));
EXPECT_THAT(AsVector(m->body_inertia+6, 3), ElementsAre(4, 3, 2));
mj_deleteModel(m);
string bad_xml1 = R"(
<mujoco>
<worldbody>
<body>
<inertial mass="1" pos="0 0 0" diaginertia="4 5 6" fullinertia="4 3 2 0 0 0"/>
</body>
</worldbody>
</mujoco>
)";
m = LoadModelFromString(bad_xml1.c_str(), error, sizeof(error));
ASSERT_THAT(m, IsNull());
EXPECT_THAT(error, HasSubstr("fullinertia and diagonal inertia cannot both"));
string bad_xml2 = R"(
<mujoco>
<worldbody>
<body>
<inertial mass="1" pos="0 0 0" euler="4 5 6" fullinertia="4 3 2 0 0 0"/>
</body>
</worldbody>
</mujoco>
)";
m = LoadModelFromString(bad_xml2.c_str(), error, sizeof(error));
ASSERT_THAT(m, IsNull());
EXPECT_THAT(error, HasSubstr("fullinertia and inertial orientation cannot"));
}
} // namespace
} // namespace mujoco