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/*************************************************************************/
/* test_quaternion.h */
/*************************************************************************/
/* This file is part of: */
/* GODOT ENGINE */
/* https://godotengine.org */
/*************************************************************************/
/* Copyright (c) 2007-2022 Juan Linietsky, Ariel Manzur. */
/* Copyright (c) 2014-2022 Godot Engine contributors (cf. AUTHORS.md). */
/* */
/* Permission is hereby granted, free of charge, to any person obtaining */
/* a copy of this software and associated documentation files (the */
/* "Software"), to deal in the Software without restriction, including */
/* without limitation the rights to use, copy, modify, merge, publish, */
/* distribute, sublicense, and/or sell copies of the Software, and to */
/* permit persons to whom the Software is furnished to do so, subject to */
/* the following conditions: */
/* */
/* The above copyright notice and this permission notice shall be */
/* included in all copies or substantial portions of the Software. */
/* */
/* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */
/* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */
/* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.*/
/* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */
/* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */
/* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */
/* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */
/*************************************************************************/
#ifndef TEST_QUATERNION_H
#define TEST_QUATERNION_H
#include "core/math/math_defs.h"
#include "core/math/math_funcs.h"
#include "core/math/quaternion.h"
#include "core/math/vector3.h"
#include "tests/test_macros.h"
namespace TestQuaternion {
Quaternion quat_euler_yxz_deg(Vector3 angle) {
double yaw = Math::deg_to_rad(angle[1]);
double pitch = Math::deg_to_rad(angle[0]);
double roll = Math::deg_to_rad(angle[2]);
// Generate YXZ (Z-then-X-then-Y) Quaternion using single-axis Euler
// constructor and quaternion product, both tested separately.
Quaternion q_y(Vector3(0.0, yaw, 0.0));
Quaternion q_p(Vector3(pitch, 0.0, 0.0));
Quaternion q_r(Vector3(0.0, 0.0, roll));
// Roll-Z is followed by Pitch-X, then Yaw-Y.
Quaternion q_yxz = q_y * q_p * q_r;
return q_yxz;
}
TEST_CASE("[Quaternion] Default Construct") {
Quaternion q;
CHECK(q[0] == 0.0);
CHECK(q[1] == 0.0);
CHECK(q[2] == 0.0);
CHECK(q[3] == 1.0);
}
TEST_CASE("[Quaternion] Construct x,y,z,w") {
// Values are taken from actual use in another project & are valid (except roundoff error).
Quaternion q(0.2391, 0.099, 0.3696, 0.8924);
CHECK(q[0] == doctest::Approx(0.2391));
CHECK(q[1] == doctest::Approx(0.099));
CHECK(q[2] == doctest::Approx(0.3696));
CHECK(q[3] == doctest::Approx(0.8924));
}
TEST_CASE("[Quaternion] Construct AxisAngle 1") {
// Easy to visualize: 120 deg about X-axis.
Quaternion q(Vector3(1.0, 0.0, 0.0), Math::deg_to_rad(120.0));
// 0.866 isn't close enough; doctest::Approx doesn't cut much slack!
CHECK(q[0] == doctest::Approx(0.866025)); // Sine of half the angle.
CHECK(q[1] == doctest::Approx(0.0));
CHECK(q[2] == doctest::Approx(0.0));
CHECK(q[3] == doctest::Approx(0.5)); // Cosine of half the angle.
}
TEST_CASE("[Quaternion] Construct AxisAngle 2") {
// Easy to visualize: 30 deg about Y-axis.
Quaternion q(Vector3(0.0, 1.0, 0.0), Math::deg_to_rad(30.0));
CHECK(q[0] == doctest::Approx(0.0));
CHECK(q[1] == doctest::Approx(0.258819)); // Sine of half the angle.
CHECK(q[2] == doctest::Approx(0.0));
CHECK(q[3] == doctest::Approx(0.965926)); // Cosine of half the angle.
}
TEST_CASE("[Quaternion] Construct AxisAngle 3") {
// Easy to visualize: 60 deg about Z-axis.
Quaternion q(Vector3(0.0, 0.0, 1.0), Math::deg_to_rad(60.0));
CHECK(q[0] == doctest::Approx(0.0));
CHECK(q[1] == doctest::Approx(0.0));
CHECK(q[2] == doctest::Approx(0.5)); // Sine of half the angle.
CHECK(q[3] == doctest::Approx(0.866025)); // Cosine of half the angle.
}
TEST_CASE("[Quaternion] Construct AxisAngle 4") {
// More complex & hard to visualize, so test w/ data from online calculator.
Vector3 axis(1.0, 2.0, 0.5);
Quaternion q(axis.normalized(), Math::deg_to_rad(35.0));
CHECK(q[0] == doctest::Approx(0.131239));
CHECK(q[1] == doctest::Approx(0.262478));
CHECK(q[2] == doctest::Approx(0.0656194));
CHECK(q[3] == doctest::Approx(0.953717));
}
TEST_CASE("[Quaternion] Construct from Quaternion") {
Vector3 axis(1.0, 2.0, 0.5);
Quaternion q_src(axis.normalized(), Math::deg_to_rad(35.0));
Quaternion q(q_src);
CHECK(q[0] == doctest::Approx(0.131239));
CHECK(q[1] == doctest::Approx(0.262478));
CHECK(q[2] == doctest::Approx(0.0656194));
CHECK(q[3] == doctest::Approx(0.953717));
}
TEST_CASE("[Quaternion] Construct Euler SingleAxis") {
double yaw = Math::deg_to_rad(45.0);
double pitch = Math::deg_to_rad(30.0);
double roll = Math::deg_to_rad(10.0);
Vector3 euler_y(0.0, yaw, 0.0);
Quaternion q_y(euler_y);
CHECK(q_y[0] == doctest::Approx(0.0));
CHECK(q_y[1] == doctest::Approx(0.382684));
CHECK(q_y[2] == doctest::Approx(0.0));
CHECK(q_y[3] == doctest::Approx(0.923879));
Vector3 euler_p(pitch, 0.0, 0.0);
Quaternion q_p(euler_p);
CHECK(q_p[0] == doctest::Approx(0.258819));
CHECK(q_p[1] == doctest::Approx(0.0));
CHECK(q_p[2] == doctest::Approx(0.0));
CHECK(q_p[3] == doctest::Approx(0.965926));
Vector3 euler_r(0.0, 0.0, roll);
Quaternion q_r(euler_r);
CHECK(q_r[0] == doctest::Approx(0.0));
CHECK(q_r[1] == doctest::Approx(0.0));
CHECK(q_r[2] == doctest::Approx(0.0871558));
CHECK(q_r[3] == doctest::Approx(0.996195));
}
TEST_CASE("[Quaternion] Construct Euler YXZ dynamic axes") {
double yaw = Math::deg_to_rad(45.0);
double pitch = Math::deg_to_rad(30.0);
double roll = Math::deg_to_rad(10.0);
// Generate YXZ comparison data (Z-then-X-then-Y) using single-axis Euler
// constructor and quaternion product, both tested separately.
Vector3 euler_y(0.0, yaw, 0.0);
Quaternion q_y(euler_y);
Vector3 euler_p(pitch, 0.0, 0.0);
Quaternion q_p(euler_p);
Vector3 euler_r(0.0, 0.0, roll);
Quaternion q_r(euler_r);
// Roll-Z is followed by Pitch-X.
Quaternion check_xz = q_p * q_r;
// Then Yaw-Y follows both.
Quaternion check_yxz = q_y * check_xz;
// Test construction from YXZ Euler angles.
Vector3 euler_yxz(pitch, yaw, roll);
Quaternion q(euler_yxz);
CHECK(q[0] == doctest::Approx(check_yxz[0]));
CHECK(q[1] == doctest::Approx(check_yxz[1]));
CHECK(q[2] == doctest::Approx(check_yxz[2]));
CHECK(q[3] == doctest::Approx(check_yxz[3]));
// Sneak in a test of is_equal_approx.
CHECK(q.is_equal_approx(check_yxz));
}
TEST_CASE("[Quaternion] Construct Basis Euler") {
double yaw = Math::deg_to_rad(45.0);
double pitch = Math::deg_to_rad(30.0);
double roll = Math::deg_to_rad(10.0);
Vector3 euler_yxz(pitch, yaw, roll);
Quaternion q_yxz(euler_yxz);
Basis basis_axes(euler_yxz);
Quaternion q(basis_axes);
CHECK(q.is_equal_approx(q_yxz));
}
TEST_CASE("[Quaternion] Construct Basis Axes") {
// Arbitrary Euler angles.
Vector3 euler_yxz(Math::deg_to_rad(31.41), Math::deg_to_rad(-49.16), Math::deg_to_rad(12.34));
// Basis vectors from online calculation of rotation matrix.
Vector3 i_unit(0.5545787, 0.1823950, 0.8118957);
Vector3 j_unit(-0.5249245, 0.8337420, 0.1712555);
Vector3 k_unit(-0.6456754, -0.5211586, 0.5581192);
// Quaternion from online calculation.
Quaternion q_calc(0.2016913, -0.4245716, 0.206033, 0.8582598);
// Quaternion from local calculation.
Quaternion q_local = quat_euler_yxz_deg(Vector3(31.41, -49.16, 12.34));
// Quaternion from Euler angles constructor.
Quaternion q_euler(euler_yxz);
CHECK(q_calc.is_equal_approx(q_local));
CHECK(q_local.is_equal_approx(q_euler));
// Calculate Basis and construct Quaternion.
// When this is written, C++ Basis class does not construct from basis vectors.
// This is by design, but may be subject to change.
// Workaround by constructing Basis from Euler angles.
// basis_axes = Basis(i_unit, j_unit, k_unit);
Basis basis_axes(euler_yxz);
Quaternion q(basis_axes);
CHECK(basis_axes.get_column(0).is_equal_approx(i_unit));
CHECK(basis_axes.get_column(1).is_equal_approx(j_unit));
CHECK(basis_axes.get_column(2).is_equal_approx(k_unit));
CHECK(q.is_equal_approx(q_calc));
CHECK_FALSE(q.inverse().is_equal_approx(q_calc));
CHECK(q.is_equal_approx(q_local));
CHECK(q.is_equal_approx(q_euler));
CHECK(q[0] == doctest::Approx(0.2016913));
CHECK(q[1] == doctest::Approx(-0.4245716));
CHECK(q[2] == doctest::Approx(0.206033));
CHECK(q[3] == doctest::Approx(0.8582598));
}
TEST_CASE("[Quaternion] Product (book)") {
// Example from "Quaternions and Rotation Sequences" by Jack Kuipers, p. 108.
Quaternion p(1.0, -2.0, 1.0, 3.0);
Quaternion q(-1.0, 2.0, 3.0, 2.0);
Quaternion pq = p * q;
CHECK(pq[0] == doctest::Approx(-9.0));
CHECK(pq[1] == doctest::Approx(-2.0));
CHECK(pq[2] == doctest::Approx(11.0));
CHECK(pq[3] == doctest::Approx(8.0));
}
TEST_CASE("[Quaternion] Product") {
double yaw = Math::deg_to_rad(45.0);
double pitch = Math::deg_to_rad(30.0);
double roll = Math::deg_to_rad(10.0);
Vector3 euler_y(0.0, yaw, 0.0);
Quaternion q_y(euler_y);
CHECK(q_y[0] == doctest::Approx(0.0));
CHECK(q_y[1] == doctest::Approx(0.382684));
CHECK(q_y[2] == doctest::Approx(0.0));
CHECK(q_y[3] == doctest::Approx(0.923879));
Vector3 euler_p(pitch, 0.0, 0.0);
Quaternion q_p(euler_p);
CHECK(q_p[0] == doctest::Approx(0.258819));
CHECK(q_p[1] == doctest::Approx(0.0));
CHECK(q_p[2] == doctest::Approx(0.0));
CHECK(q_p[3] == doctest::Approx(0.965926));
Vector3 euler_r(0.0, 0.0, roll);
Quaternion q_r(euler_r);
CHECK(q_r[0] == doctest::Approx(0.0));
CHECK(q_r[1] == doctest::Approx(0.0));
CHECK(q_r[2] == doctest::Approx(0.0871558));
CHECK(q_r[3] == doctest::Approx(0.996195));
// Test ZYX dynamic-axes since test data is available online.
// Rotate first about X axis, then new Y axis, then new Z axis.
// (Godot uses YXZ Yaw-Pitch-Roll order).
Quaternion q_yp = q_y * q_p;
CHECK(q_yp[0] == doctest::Approx(0.239118));
CHECK(q_yp[1] == doctest::Approx(0.369644));
CHECK(q_yp[2] == doctest::Approx(-0.099046));
CHECK(q_yp[3] == doctest::Approx(0.892399));
Quaternion q_ryp = q_r * q_yp;
CHECK(q_ryp[0] == doctest::Approx(0.205991));
CHECK(q_ryp[1] == doctest::Approx(0.389078));
CHECK(q_ryp[2] == doctest::Approx(-0.0208912));
CHECK(q_ryp[3] == doctest::Approx(0.897636));
}
TEST_CASE("[Quaternion] xform unit vectors") {
// Easy to visualize: 120 deg about X-axis.
// Transform the i, j, & k unit vectors.
Quaternion q(Vector3(1.0, 0.0, 0.0), Math::deg_to_rad(120.0));
Vector3 i_t = q.xform(Vector3(1.0, 0.0, 0.0));
Vector3 j_t = q.xform(Vector3(0.0, 1.0, 0.0));
Vector3 k_t = q.xform(Vector3(0.0, 0.0, 1.0));
//
CHECK(i_t.is_equal_approx(Vector3(1.0, 0.0, 0.0)));
CHECK(j_t.is_equal_approx(Vector3(0.0, -0.5, 0.866025)));
CHECK(k_t.is_equal_approx(Vector3(0.0, -0.866025, -0.5)));
CHECK(i_t.length_squared() == doctest::Approx(1.0));
CHECK(j_t.length_squared() == doctest::Approx(1.0));
CHECK(k_t.length_squared() == doctest::Approx(1.0));
// Easy to visualize: 30 deg about Y-axis.
q = Quaternion(Vector3(0.0, 1.0, 0.0), Math::deg_to_rad(30.0));
i_t = q.xform(Vector3(1.0, 0.0, 0.0));
j_t = q.xform(Vector3(0.0, 1.0, 0.0));
k_t = q.xform(Vector3(0.0, 0.0, 1.0));
//
CHECK(i_t.is_equal_approx(Vector3(0.866025, 0.0, -0.5)));
CHECK(j_t.is_equal_approx(Vector3(0.0, 1.0, 0.0)));
CHECK(k_t.is_equal_approx(Vector3(0.5, 0.0, 0.866025)));
CHECK(i_t.length_squared() == doctest::Approx(1.0));
CHECK(j_t.length_squared() == doctest::Approx(1.0));
CHECK(k_t.length_squared() == doctest::Approx(1.0));
// Easy to visualize: 60 deg about Z-axis.
q = Quaternion(Vector3(0.0, 0.0, 1.0), Math::deg_to_rad(60.0));
i_t = q.xform(Vector3(1.0, 0.0, 0.0));
j_t = q.xform(Vector3(0.0, 1.0, 0.0));
k_t = q.xform(Vector3(0.0, 0.0, 1.0));
//
CHECK(i_t.is_equal_approx(Vector3(0.5, 0.866025, 0.0)));
CHECK(j_t.is_equal_approx(Vector3(-0.866025, 0.5, 0.0)));
CHECK(k_t.is_equal_approx(Vector3(0.0, 0.0, 1.0)));
CHECK(i_t.length_squared() == doctest::Approx(1.0));
CHECK(j_t.length_squared() == doctest::Approx(1.0));
CHECK(k_t.length_squared() == doctest::Approx(1.0));
}
TEST_CASE("[Quaternion] xform vector") {
// Arbitrary quaternion rotates an arbitrary vector.
Vector3 euler_yzx(Math::deg_to_rad(31.41), Math::deg_to_rad(-49.16), Math::deg_to_rad(12.34));
Basis basis_axes(euler_yzx);
Quaternion q(basis_axes);
Vector3 v_arb(3.0, 4.0, 5.0);
Vector3 v_rot = q.xform(v_arb);
Vector3 v_compare = basis_axes.xform(v_arb);
CHECK(v_rot.length_squared() == doctest::Approx(v_arb.length_squared()));
CHECK(v_rot.is_equal_approx(v_compare));
}
// Test vector xform for a single combination of Quaternion and Vector.
void test_quat_vec_rotate(Vector3 euler_yzx, Vector3 v_in) {
Basis basis_axes(euler_yzx);
Quaternion q(basis_axes);
Vector3 v_rot = q.xform(v_in);
Vector3 v_compare = basis_axes.xform(v_in);
CHECK(v_rot.length_squared() == doctest::Approx(v_in.length_squared()));
CHECK(v_rot.is_equal_approx(v_compare));
}
TEST_CASE("[Stress][Quaternion] Many vector xforms") {
// Many arbitrary quaternions rotate many arbitrary vectors.
// For each trial, check that rotation by Quaternion yields same result as
// rotation by Basis.
const int STEPS = 100; // Number of test steps in each dimension
const double delta = 2.0 * Math_PI / STEPS; // Angle increment per step
const double delta_vec = 20.0 / STEPS; // Vector increment per step
Vector3 vec_arb(1.0, 1.0, 1.0);
double x_angle = -Math_PI;
double y_angle = -Math_PI;
double z_angle = -Math_PI;
for (double i = 0; i < STEPS; ++i) {
vec_arb[0] = -10.0 + i * delta_vec;
x_angle = i * delta - Math_PI;
for (double j = 0; j < STEPS; ++j) {
vec_arb[1] = -10.0 + j * delta_vec;
y_angle = j * delta - Math_PI;
for (double k = 0; k < STEPS; ++k) {
vec_arb[2] = -10.0 + k * delta_vec;
z_angle = k * delta - Math_PI;
Vector3 euler_yzx(x_angle, y_angle, z_angle);
test_quat_vec_rotate(euler_yzx, vec_arb);
}
}
}
}
TEST_CASE("[Quaternion] Finite number checks") {
const real_t x = NAN;
CHECK_MESSAGE(
Quaternion(0, 1, 2, 3).is_finite(),
"Quaternion with all components finite should be finite");
CHECK_FALSE_MESSAGE(
Quaternion(x, 1, 2, 3).is_finite(),
"Quaternion with one component infinite should not be finite.");
CHECK_FALSE_MESSAGE(
Quaternion(0, x, 2, 3).is_finite(),
"Quaternion with one component infinite should not be finite.");
CHECK_FALSE_MESSAGE(
Quaternion(0, 1, x, 3).is_finite(),
"Quaternion with one component infinite should not be finite.");
CHECK_FALSE_MESSAGE(
Quaternion(0, 1, 2, x).is_finite(),
"Quaternion with one component infinite should not be finite.");
CHECK_FALSE_MESSAGE(
Quaternion(x, x, 2, 3).is_finite(),
"Quaternion with two components infinite should not be finite.");
CHECK_FALSE_MESSAGE(
Quaternion(x, 1, x, 3).is_finite(),
"Quaternion with two components infinite should not be finite.");
CHECK_FALSE_MESSAGE(
Quaternion(x, 1, 2, x).is_finite(),
"Quaternion with two components infinite should not be finite.");
CHECK_FALSE_MESSAGE(
Quaternion(0, x, x, 3).is_finite(),
"Quaternion with two components infinite should not be finite.");
CHECK_FALSE_MESSAGE(
Quaternion(0, x, 2, x).is_finite(),
"Quaternion with two components infinite should not be finite.");
CHECK_FALSE_MESSAGE(
Quaternion(0, 1, x, x).is_finite(),
"Quaternion with two components infinite should not be finite.");
CHECK_FALSE_MESSAGE(
Quaternion(0, x, x, x).is_finite(),
"Quaternion with three components infinite should not be finite.");
CHECK_FALSE_MESSAGE(
Quaternion(x, 1, x, x).is_finite(),
"Quaternion with three components infinite should not be finite.");
CHECK_FALSE_MESSAGE(
Quaternion(x, x, 2, x).is_finite(),
"Quaternion with three components infinite should not be finite.");
CHECK_FALSE_MESSAGE(
Quaternion(x, x, x, 3).is_finite(),
"Quaternion with three components infinite should not be finite.");
CHECK_FALSE_MESSAGE(
Quaternion(x, x, x, x).is_finite(),
"Quaternion with four components infinite should not be finite.");
}
} // namespace TestQuaternion
#endif // TEST_QUATERNION_H
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