/** * @file llquaternion_tut.cpp * @author Adroit * @date 2007-03 * @brief Test cases of llquaternion.h * * $LicenseInfo:firstyear=2007&license=viewergpl$ * * Copyright (c) 2007-2009, Linden Research, Inc. * * Second Life Viewer Source Code * The source code in this file ("Source Code") is provided by Linden Lab * to you under the terms of the GNU General Public License, version 2.0 * ("GPL"), unless you have obtained a separate licensing agreement * ("Other License"), formally executed by you and Linden Lab. Terms of * the GPL can be found in doc/GPL-license.txt in this distribution, or * online at http://secondlifegrid.net/programs/open_source/licensing/gplv2 * * There are special exceptions to the terms and conditions of the GPL as * it is applied to this Source Code. View the full text of the exception * in the file doc/FLOSS-exception.txt in this software distribution, or * online at * http://secondlifegrid.net/programs/open_source/licensing/flossexception * * By copying, modifying or distributing this software, you acknowledge * that you have read and understood your obligations described above, * and agree to abide by those obligations. * * ALL LINDEN LAB SOURCE CODE IS PROVIDED "AS IS." LINDEN LAB MAKES NO * WARRANTIES, EXPRESS, IMPLIED OR OTHERWISE, REGARDING ITS ACCURACY, * COMPLETENESS OR PERFORMANCE. * $/LicenseInfo$ */ #include #include "linden_common.h" #include "lltut.h" #include "llquaternion.h" #include "v4math.h" #include "v3math.h" #include "v3dmath.h" #include "m4math.h" #include "m3math.h" #include "math.h" namespace tut { struct llquat_test { }; typedef test_group llquat_test_t; typedef llquat_test_t::object llquat_test_object_t; tut::llquat_test_t tut_llquat_test("llquat"); //test case for LLQuaternion::LLQuaternion(void) fn. template<> template<> void llquat_test_object_t::test<1>() { LLQuaternion llquat; ensure("LLQuaternion::LLQuaternion() failed", 0.f == llquat.mQ[0] && 0.f == llquat.mQ[1] && 0.f == llquat.mQ[2] && 1.f == llquat.mQ[3]); } //test case for explicit LLQuaternion(const LLMatrix4 &mat) fn. template<> template<> void llquat_test_object_t::test<2>() { LLMatrix4 llmat; LLVector4 vector1(2.0f, 1.0f, 3.0f, 6.0f); LLVector4 vector2(5.0f, 6.0f, 0.0f, 1.0f); LLVector4 vector3(2.0f, 1.0f, 2.0f, 9.0f); LLVector4 vector4(3.0f, 8.0f, 1.0f, 5.0f); llmat.initRows(vector1, vector2, vector3, vector4); ensure("explicit LLQuaternion(const LLMatrix4 &mat) failed", 2.0f == llmat.mMatrix[0][0] && 1.0f == llmat.mMatrix[0][1] && 3.0f == llmat.mMatrix[0][2] && 6.0f == llmat.mMatrix[0][3] && 5.0f == llmat.mMatrix[1][0] && 6.0f == llmat.mMatrix[1][1] && 0.0f == llmat.mMatrix[1][2] && 1.0f == llmat.mMatrix[1][3] && 2.0f == llmat.mMatrix[2][0] && 1.0f == llmat.mMatrix[2][1] && 2.0f == llmat.mMatrix[2][2] && 9.0f == llmat.mMatrix[2][3] && 3.0f == llmat.mMatrix[3][0] && 8.0f == llmat.mMatrix[3][1] && 1.0f == llmat.mMatrix[3][2] && 5.0f == llmat.mMatrix[3][3]); } template<> template<> void llquat_test_object_t::test<3>() { LLMatrix3 llmat; LLVector3 vect1(3.4028234660000000f , 234.56f, 4234.442234f); LLVector3 vect2(741.434f, 23.00034f, 6567.223423f); LLVector3 vect3(566.003034f, 12.98705f, 234.764423f); llmat.setRows(vect1, vect2, vect3); ensure("LLMatrix3::setRows fn failed.", 3.4028234660000000f == llmat.mMatrix[0][0] && 234.56f == llmat.mMatrix[0][1] && 4234.442234f == llmat.mMatrix[0][2] && 741.434f == llmat.mMatrix[1][0] && 23.00034f == llmat.mMatrix[1][1] && 6567.223423f == llmat.mMatrix[1][2] && 566.003034f == llmat.mMatrix[2][0] && 12.98705f == llmat.mMatrix[2][1] && 234.764423f == llmat.mMatrix[2][2]); } //test case for LLQuaternion(F32 x, F32 y, F32 z, F32 w), setQuatInit() and normQuat() fns. template<> template<> void llquat_test_object_t::test<4>() { F32 x_val = 3.0f; F32 y_val = 2.0f; F32 z_val = 6.0f; F32 w_val = 1.0f; LLQuaternion res_quat; res_quat.setQuatInit(x_val, y_val, z_val, w_val); res_quat.normQuat(); ensure("LLQuaternion::normQuat() fn failed", is_approx_equal(0.42426407f, res_quat.mQ[0]) && is_approx_equal(0.28284273f, res_quat.mQ[1]) && is_approx_equal(0.84852815f, res_quat.mQ[2]) && is_approx_equal(0.14142136f, res_quat.mQ[3])); x_val = 0.0f; y_val = 0.0f; z_val = 0.0f; w_val = 0.0f; res_quat.setQuatInit(x_val, y_val, z_val, w_val); res_quat.normQuat(); ensure("LLQuaternion::normQuat() fn. failed.", is_approx_equal(0.0f, res_quat.mQ[0]) && is_approx_equal(0.0f, res_quat.mQ[1]) && is_approx_equal(0.0f, res_quat.mQ[2]) && is_approx_equal(1.0f, res_quat.mQ[3])); ensure("LLQuaternion::normQuat() fn. failed.", is_approx_equal(0.0f, res_quat.mQ[0]) && is_approx_equal(0.0f, res_quat.mQ[1]) && is_approx_equal(0.0f, res_quat.mQ[2]) && is_approx_equal(1.0f, res_quat.mQ[3])); } //test case for conjQuat() and transQuat() fns. template<> template<> void llquat_test_object_t::test<5>() { F32 x_val = 3.0f; F32 y_val = 2.0f; F32 z_val = 6.0f; F32 w_val = 1.0f; LLQuaternion res_quat; LLQuaternion result, result1; result1 = result = res_quat.setQuatInit(x_val, y_val, z_val, w_val); result.conjQuat(); result1.transQuat(); ensure("LLQuaternion::conjQuat and LLQuaternion::transQuat failed ", is_approx_equal(result1.mQ[0], result.mQ[0]) && is_approx_equal(result1.mQ[1], result.mQ[1]) && is_approx_equal(result1.mQ[2], result.mQ[2])); } //test case for dot(const LLQuaternion &a, const LLQuaternion &b) fn. template<> template<> void llquat_test_object_t::test<6>() { LLQuaternion quat1(3.0f, 2.0f, 6.0f, 0.0f), quat2(1.0f, 1.0f, 1.0f, 1.0f); ensure("1. The two values are different", llround(12.000000f, 2) == llround(dot(quat1, quat2), 2)); LLQuaternion quat0(3.0f, 9.334f, 34.5f, 23.0f), quat(34.5f, 23.23f, 2.0f, 45.5f); ensure("2. The two values are different", llround(1435.828807f, 2) == llround(dot(quat0, quat), 2)); } //test case for LLQuaternion &LLQuaternion::constrain(F32 radians) fn. template<> template<> void llquat_test_object_t::test<7>() { F32 radian = 60.0f; LLQuaternion quat(3.0f, 2.0f, 6.0f, 0.0f); LLQuaternion quat1; quat1 = quat.constrain(radian); ensure("1. LLQuaternion::constrain(F32 radians) failed", is_approx_equal_fraction(-0.423442f, quat1.mQ[0], 8) && is_approx_equal_fraction(-0.282295f, quat1.mQ[1], 8) && is_approx_equal_fraction(-0.846884f, quat1.mQ[2], 8) && is_approx_equal_fraction(0.154251f, quat1.mQ[3], 8)); radian = 30.0f; LLQuaternion quat0(37.50f, 12.0f, 86.023f, 40.32f); quat1 = quat0.constrain(radian); ensure("2. LLQuaternion::constrain(F32 radians) failed", is_approx_equal_fraction(37.500000f, quat1.mQ[0], 8) && is_approx_equal_fraction(12.0000f, quat1.mQ[1], 8) && is_approx_equal_fraction(86.0230f, quat1.mQ[2], 8) && is_approx_equal_fraction(40.320000f, quat1.mQ[3], 8)); } template<> template<> void llquat_test_object_t::test<8>() { F32 value1 = 15.0f; LLQuaternion quat1(1.0f, 2.0f, 4.0f, 1.0f); LLQuaternion quat2(4.0f, 3.0f, 6.5f, 9.7f); LLQuaternion res_lerp, res_slerp, res_nlerp; //test case for lerp(F32 t, const LLQuaternion &q) fn. res_lerp = lerp(value1, quat1); ensure("1. LLQuaternion lerp(F32 t, const LLQuaternion &q) failed", is_approx_equal_fraction(0.181355f, res_lerp.mQ[0], 16) && is_approx_equal_fraction(0.362711f, res_lerp.mQ[1], 16) && is_approx_equal_fraction(0.725423f, res_lerp.mQ[2], 16) && is_approx_equal_fraction(0.556158f, res_lerp.mQ[3], 16)); //test case for lerp(F32 t, const LLQuaternion &p, const LLQuaternion &q) fn. res_lerp = lerp(value1, quat1, quat2); ensure("2. LLQuaternion lerp(F32 t, const LLQuaternion &p, const LLQuaternion &q) failed", is_approx_equal_fraction(0.314306f, res_lerp.mQ[0], 16) && is_approx_equal_fraction(0.116156f, res_lerp.mQ[1], 16) && is_approx_equal_fraction(0.283559f, res_lerp.mQ[2], 16) && is_approx_equal_fraction(0.898506f, res_lerp.mQ[3], 16)); //test case for slerp( F32 u, const LLQuaternion &a, const LLQuaternion &b ) fn. res_slerp = slerp(value1, quat1, quat2); ensure("3. LLQuaternion slerp( F32 u, const LLQuaternion &a, const LLQuaternion &b) failed", is_approx_equal_fraction(46.000f, res_slerp.mQ[0], 16) && is_approx_equal_fraction(17.00f, res_slerp.mQ[1], 16) && is_approx_equal_fraction(41.5f, res_slerp.mQ[2], 16) && is_approx_equal_fraction(131.5f, res_slerp.mQ[3], 16)); //test case for nlerp(F32 t, const LLQuaternion &a, const LLQuaternion &b) fn. res_nlerp = nlerp(value1, quat1, quat2); ensure("4. LLQuaternion nlerp(F32 t, const LLQuaternion &a, const LLQuaternion &b) failed", is_approx_equal_fraction(0.314306f, res_nlerp.mQ[0], 16) && is_approx_equal_fraction(0.116157f, res_nlerp.mQ[1], 16) && is_approx_equal_fraction(0.283559f, res_nlerp.mQ[2], 16) && is_approx_equal_fraction(0.898506f, res_nlerp.mQ[3], 16)); //test case for nlerp(F32 t, const LLQuaternion &q) fn. res_slerp = slerp(value1, quat1); ensure("5. LLQuaternion slerp(F32 t, const LLQuaternion &q) failed", is_approx_equal_fraction(1.0f, res_slerp.mQ[0], 16) && is_approx_equal_fraction(2.0f, res_slerp.mQ[1], 16) && is_approx_equal_fraction(4.0000f, res_slerp.mQ[2], 16) && is_approx_equal_fraction(1.000f, res_slerp.mQ[3], 16)); LLQuaternion quat3(2.0f, 1.0f, 5.5f, 10.5f); LLQuaternion res_nlerp1; value1 = 100.0f; res_nlerp1 = nlerp(value1, quat3); ensure("6. LLQuaternion nlerp(F32 t, const LLQuaternion &q) failed", is_approx_equal_fraction(0.268245f, res_nlerp1.mQ[0], 16) && is_approx_equal_fraction(0.134122f, res_nlerp1.mQ[1], 2) && is_approx_equal_fraction(0.737673f, res_nlerp1.mQ[2], 16) && is_approx_equal_fraction(0.604892f, res_nlerp1.mQ[3], 16)); //test case for lerp(F32 t, const LLQuaternion &q) fn. res_lerp = lerp(value1, quat2); ensure("7. LLQuaternion lerp(F32 t, const LLQuaternion &q) failed", is_approx_equal_fraction(0.404867f, res_lerp.mQ[0], 16) && is_approx_equal_fraction(0.303650f, res_lerp.mQ[1], 16) && is_approx_equal_fraction(0.657909f, res_lerp.mQ[2], 16) && is_approx_equal_fraction(0.557704f, res_lerp.mQ[3], 16)); } template<> template<> void llquat_test_object_t::test<9>() { //test case for LLQuaternion operator*(const LLQuaternion &a, const LLQuaternion &b) fn LLQuaternion quat1(1.0f, 2.5f, 3.5f, 5.5f); LLQuaternion quat2(4.0f, 3.0f, 5.0f, 1.0f); LLQuaternion result = quat1 * quat2; ensure("1. LLQuaternion Operator* failed", (21.0f == result.mQ[0]) && (10.0f == result.mQ[1]) && (38.0f == result.mQ[2]) && (-23.5f == result.mQ[3])); LLQuaternion quat3(2341.340f, 2352.345f, 233.25f, 7645.5f); LLQuaternion quat4(674.067f, 893.0897f, 578.0f, 231.0f); result = quat3 * quat4; ensure("2. LLQuaternion Operator* failed", (4543086.5f == result.mQ[0]) && (8567578.0f == result.mQ[1]) && (3967591.25f == result.mQ[2]) && is_approx_equal(-2047783.25f, result.mQ[3])); //inline LLQuaternion operator+(const LLQuaternion &a, const LLQuaternion &b)fn. result = quat1 + quat2; ensure("3. LLQuaternion operator+ failed", (5.0f == result.mQ[0]) && (5.5f == result.mQ[1]) && (8.5f == result.mQ[2]) && (6.5f == result.mQ[3])); result = quat3 + quat4; ensure( "4. LLQuaternion operator+ failed", is_approx_equal(3015.407227f, result.mQ[0]) && is_approx_equal(3245.434570f, result.mQ[1]) && (811.25f == result.mQ[2]) && (7876.5f == result.mQ[3])); //inline LLQuaternion operator-(const LLQuaternion &a, const LLQuaternion &b) fn result = quat1 - quat2; ensure( "5. LLQuaternion operator-(const LLQuaternion &a, const LLQuaternion &b) failed", (-3.0f == result.mQ[0]) && (-0.5f == result.mQ[1]) && (-1.5f == result.mQ[2]) && (4.5f == result.mQ[3])); result = quat3 - quat4; ensure( "6. LLQuaternion operator-(const LLQuaternion &a, const LLQuaternion &b) failed", is_approx_equal(1667.273071f, result.mQ[0]) && is_approx_equal(1459.255249f, result.mQ[1]) && (-344.75f == result.mQ[2]) && (7414.50f == result.mQ[3])); } //test case for LLVector4 operator*(const LLVector4 &a, const LLQuaternion &rot) fn. template<> template<> void llquat_test_object_t::test<10>() { LLVector4 vect(12.0f, 5.0f, 60.0f, 75.1f); LLQuaternion quat(2323.034f, 23.5f, 673.23f, 57667.5f); LLVector4 result = vect * quat; ensure( "1. LLVector4 operator*(const LLVector4 &a, const LLQuaternion &rot) failed", is_approx_equal(39928406016.0f, result.mV[0]) && // gcc on x86 actually gives us more precision than we were expecting, verified with -ffloat-store - we forgive this (1457802240.0f >= result.mV[1]) && // gcc+x86+linux (1457800960.0f <= result.mV[1]) && // elsewhere is_approx_equal(200580612096.0f, result.mV[2]) && (75.099998f == result.mV[3])); LLVector4 vect1(22.0f, 45.0f, 40.0f, 78.1f); LLQuaternion quat1(2.034f, 45.5f, 37.23f, 7.5f); result = vect1 * quat1; ensure( "2. LLVector4 operator*(const LLVector4 &a, const LLQuaternion &rot) failed", is_approx_equal(-58153.5390f, result.mV[0]) && (183787.8125f == result.mV[1]) && (116864.164063f == result.mV[2]) && (78.099998f == result.mV[3])); } //test case for LLVector3 operator*(const LLVector3 &a, const LLQuaternion &rot) fn. template<> template<> void llquat_test_object_t::test<11>() { LLVector3 vect(12.0f, 5.0f, 60.0f); LLQuaternion quat(23.5f, 6.5f, 3.23f, 56.5f); LLVector3 result = vect * quat; ensure( "1. LLVector3 operator*(const LLVector3 &a, const LLQuaternion &rot) failed", is_approx_equal(97182.953125f,result.mV[0]) && is_approx_equal(-135405.640625f, result.mV[1]) && is_approx_equal(162986.140f, result.mV[2])); LLVector3 vect1(5.0f, 40.0f, 78.1f); LLQuaternion quat1(2.034f, 45.5f, 37.23f, 7.5f); result = vect1 * quat1; ensure( "2. LLVector3 operator*(const LLVector3 &a, const LLQuaternion &rot) failed", is_approx_equal(33217.703f, result.mV[0]) && is_approx_equal(295383.8125f, result.mV[1]) && is_approx_equal(84718.140f, result.mV[2])); } //test case for LLVector3d operator*(const LLVector3d &a, const LLQuaternion &rot) fn. template<> template<> void llquat_test_object_t::test<12>() { LLVector3d vect(-2.0f, 5.0f, -6.0f); LLQuaternion quat(-3.5f, 4.5f, 3.5f, 6.5f); LLVector3d result = vect * quat; ensure( "1. LLVector3d operator*(const LLVector3d &a, const LLQuaternion &rot) failed ", (-633.0f == result.mdV[0]) && (-300.0f == result.mdV[1]) && (-36.0f == result.mdV[2])); LLVector3d vect1(5.0f, -4.5f, 8.21f); LLQuaternion quat1(2.0f, 4.5f, -7.2f, 9.5f); result = vect1 * quat1; ensure( "2. LLVector3d operator*(const LLVector3d &a, const LLQuaternion &rot) failed", is_approx_equal_fraction(-120.29f, (F32) result.mdV[0], 8) && is_approx_equal_fraction(-1683.958f, (F32) result.mdV[1], 8) && is_approx_equal_fraction(516.56f, (F32) result.mdV[2], 8)); LLVector3d vect2(2.0f, 3.5f, 1.1f); LLQuaternion quat2(1.0f, 4.0f, 2.0f, 5.0f); result = vect2 * quat2; ensure( "3. LLVector3d operator*(const LLVector3d &a, const LLQuaternion &rot) failed", is_approx_equal_fraction(18.400001f, (F32) result.mdV[0], 8) && is_approx_equal_fraction(188.6f, (F32) result.mdV[1], 8) && is_approx_equal_fraction(32.20f, (F32) result.mdV[2], 8)); } //test case for inline LLQuaternion operator-(const LLQuaternion &a) fn. template<> template<> void llquat_test_object_t::test<13>() { LLQuaternion quat(23.5f, 34.5f, 16723.4f, 324.7f); LLQuaternion result = -quat; ensure( "1. LLQuaternion operator-(const LLQuaternion &a) failed", (-23.5f == result.mQ[0]) && (-34.5f == result.mQ[1]) && (-16723.4f == result.mQ[2]) && (-324.7f == result.mQ[3])); LLQuaternion quat1(-3.5f, -34.5f, -16.4f, -154.7f); result = -quat1; ensure( "2. LLQuaternion operator-(const LLQuaternion &a) failed.", (3.5f == result.mQ[0]) && (34.5f == result.mQ[1]) && (16.4f == result.mQ[2]) && (154.7f == result.mQ[3])); } //test case for inline LLQuaternion operator*(F32 a, const LLQuaternion &q) and //inline LLQuaternion operator*(F32 a, const LLQuaternion &q) fns. template<> template<> void llquat_test_object_t::test<14>() { LLQuaternion quat_value(9.0f, 8.0f, 7.0f, 6.0f); F32 a =3.5f; LLQuaternion result = a * quat_value; LLQuaternion result1 = quat_value * a; ensure( "1. LLQuaternion operator* failed", (result.mQ[0] == result1.mQ[0]) && (result.mQ[1] == result1.mQ[1]) && (result.mQ[2] == result1.mQ[2]) && (result.mQ[3] == result1.mQ[3])); LLQuaternion quat_val(9454.0f, 43568.3450f, 456343247.0343f, 2346.03434f); a =-3324.3445f; result = a * quat_val; result1 = quat_val * a; ensure( "2. LLQuaternion operator* failed", (result.mQ[0] == result1.mQ[0]) && (result.mQ[1] == result1.mQ[1]) && (result.mQ[2] == result1.mQ[2]) && (result.mQ[3] == result1.mQ[3])); } template<> template<> void llquat_test_object_t::test<15>() { // test cases for inline LLQuaternion operator~(const LLQuaternion &a) LLQuaternion quat_val(2323.634f, -43535.4f, 3455.88f, -32232.45f); LLQuaternion result = ~quat_val; ensure( "1. LLQuaternion operator~(const LLQuaternion &a) failed ", (-2323.634f == result.mQ[0]) && (43535.4f == result.mQ[1]) && (-3455.88f == result.mQ[2]) && (-32232.45f == result.mQ[3])); //test case for inline bool LLQuaternion::operator==(const LLQuaternion &b) const LLQuaternion quat_val1(2323.634f, -43535.4f, 3455.88f, -32232.45f); LLQuaternion quat_val2(2323.634f, -43535.4f, 3455.88f, -32232.45f); ensure( "2. LLQuaternion::operator==(const LLQuaternion &b) failed", quat_val1 == quat_val2); } template<> template<> void llquat_test_object_t::test<16>() { //test case for inline bool LLQuaternion::operator!=(const LLQuaternion &b) const LLQuaternion quat_val1(2323.634f, -43535.4f, 3455.88f, -32232.45f); LLQuaternion quat_val2(0, -43535.4f, 3455.88f, -32232.45f); ensure("LLQuaternion::operator!=(const LLQuaternion &b) failed", quat_val1 != quat_val2); } template<> template<> void llquat_test_object_t::test<17>() { //test case for LLQuaternion mayaQ(F32 xRot, F32 yRot, F32 zRot, LLQuaternion::Order order) F32 x = 2.0f; F32 y = 1.0f; F32 z = 3.0f; LLQuaternion result = mayaQ(x, y, z, LLQuaternion::XYZ); ensure( "1. LLQuaternion mayaQ(F32 xRot, F32 yRot, F32 zRot, LLQuaternion::Order order) failed for XYZ", is_approx_equal_fraction(0.0172174f, result.mQ[0], 16) && is_approx_equal_fraction(0.009179f, result.mQ[1], 16) && is_approx_equal_fraction(0.026020f, result.mQ[2], 16) && is_approx_equal_fraction(0.999471f, result.mQ[3], 16)); LLQuaternion result1 = mayaQ(x, y, z, LLQuaternion::YZX); ensure( "2. LLQuaternion mayaQ(F32 xRot, F32 yRot, F32 zRot, LLQuaternion::Order order) failed for XYZ", is_approx_equal_fraction(0.017217f, result1.mQ[0], 16) && is_approx_equal_fraction(0.008265f, result1.mQ[1], 16) && is_approx_equal_fraction(0.026324f, result1.mQ[2], 16) && is_approx_equal_fraction(0.999471f, result1.mQ[3], 16)); LLQuaternion result2 = mayaQ(x, y, z, LLQuaternion::ZXY); ensure( "3. LLQuaternion mayaQ(F32 xRot, F32 yRot, F32 zRot, LLQuaternion::Order order) failed for ZXY", is_approx_equal_fraction(0.017674f, result2.mQ[0], 16) && is_approx_equal_fraction(0.008265f, result2.mQ[1], 16) && is_approx_equal_fraction(0.026020f, result2.mQ[2], 16) && is_approx_equal_fraction(0.999471f, result2.mQ[3], 16)); LLQuaternion result3 = mayaQ(x, y, z, LLQuaternion::XZY); ensure( "4. TLLQuaternion mayaQ(F32 xRot, F32 yRot, F32 zRot, LLQuaternion::Order order) failed for XZY", is_approx_equal_fraction(0.017674f, result3.mQ[0], 16) && is_approx_equal_fraction(0.009179f, result3.mQ[1], 16) && is_approx_equal_fraction(0.026020f, result3.mQ[2], 16) && is_approx_equal_fraction(0.999463f, result3.mQ[3], 16)); LLQuaternion result4 = mayaQ(x, y, z, LLQuaternion::YXZ); ensure( "5. LLQuaternion mayaQ(F32 xRot, F32 yRot, F32 zRot, LLQuaternion::Order order) failed for YXZ", is_approx_equal_fraction(0.017217f, result4.mQ[0], 16) && is_approx_equal_fraction(0.009179f, result4.mQ[1], 16) && is_approx_equal_fraction(0.026324f, result4.mQ[2], 16) && is_approx_equal_fraction(0.999463f, result4.mQ[3], 16)); LLQuaternion result5 = mayaQ(x, y, z, LLQuaternion::ZYX); ensure( "6. LLQuaternion mayaQ(F32 xRot, F32 yRot, F32 zRot, LLQuaternion::Order order) failed for ZYX", is_approx_equal_fraction(0.017674f, result5.mQ[0], 16) && is_approx_equal_fraction(0.008265f, result5.mQ[1], 16) && is_approx_equal_fraction(0.026324f, result5.mQ[2], 16) && is_approx_equal_fraction(0.999463f, result5.mQ[3], 16)); } template<> template<> void llquat_test_object_t::test<18>() { // test case for friend std::ostream& operator<<(std::ostream &s, const LLQuaternion &a) fn LLQuaternion a(1.0f, 1.0f, 1.0f, 1.0f); std::ostringstream result_value; result_value << a; ensure_equals("1. Operator << failed", result_value.str(), "{ 1, 1, 1, 1 }"); LLQuaternion b(-31.034f, 231.2340f, 3451.344320f, -341.0f); std::ostringstream result_value1; result_value1 << b; ensure_equals("2. Operator << failed", result_value1.str(), "{ -31.034, 231.234, 3451.34, -341 }"); LLQuaternion c(1.0f, 2.2f, 3.3f, 4.4f); result_value << c; ensure_equals("3. Operator << failed", result_value.str(), "{ 1, 1, 1, 1 }{ 1, 2.2, 3.3, 4.4 }"); } template<> template<> void llquat_test_object_t::test<19>() { //test case for const char *OrderToString( const LLQuaternion::Order order ) fn const char* result = OrderToString(LLQuaternion::XYZ); ensure("1. OrderToString failed for XYZ", (0 == strcmp("XYZ", result))); result = OrderToString(LLQuaternion::YZX); ensure("2. OrderToString failed for YZX", (0 == strcmp("YZX", result))); result = OrderToString(LLQuaternion::ZXY); ensure( "3. OrderToString failed for ZXY", (0 == strcmp("ZXY", result)) && (0 != strcmp("XYZ", result)) && (0 != strcmp("YXZ", result)) && (0 != strcmp("ZYX", result)) && (0 != strcmp("XYZ", result))); result = OrderToString(LLQuaternion::XZY); ensure("4. OrderToString failed for XZY", (0 == strcmp("XZY", result))); result = OrderToString(LLQuaternion::ZYX); ensure("5. OrderToString failed for ZYX", (0 == strcmp("ZYX", result))); result = OrderToString(LLQuaternion::YXZ); ensure("6.OrderToString failed for YXZ", (0 == strcmp("YXZ", result))); } template<> template<> void llquat_test_object_t::test<20>() { //test case for LLQuaternion::Order StringToOrder( const char *str ) fn int result = StringToOrder("XYZ"); ensure("1. LLQuaternion::Order StringToOrder(const char *str ) failed for XYZ", 0 == result); result = StringToOrder("YZX"); ensure("2. LLQuaternion::Order StringToOrder(const char *str) failed for YZX", 1 == result); result = StringToOrder("ZXY"); ensure("3. LLQuaternion::Order StringToOrder(const char *str) failed for ZXY", 2 == result); result = StringToOrder("XZY"); ensure("4. LLQuaternion::Order StringToOrder(const char *str) failed for XZY", 3 == result); result = StringToOrder("YXZ"); ensure("5. LLQuaternion::Order StringToOrder(const char *str) failed for YXZ", 4 == result); result = StringToOrder("ZYX"); ensure("6. LLQuaternion::Order StringToOrder(const char *str) failed for ZYX", 5 == result); } template<> template<> void llquat_test_object_t::test<21>() { //void LLQuaternion::getAngleAxis(F32* angle, LLVector3 &vec) const fn F32 angle_value = 90.0f; LLVector3 vect(12.0f, 4.0f, 1.0f); LLQuaternion llquat(angle_value, vect); llquat.getAngleAxis(&angle_value, vect); ensure( "LLQuaternion::getAngleAxis(F32* angle, LLVector3 &vec) failed", is_approx_equal_fraction(2.035406f, angle_value, 16) && is_approx_equal_fraction(0.315244f, vect.mV[1], 16) && is_approx_equal_fraction(0.078811f, vect.mV[2], 16) && is_approx_equal_fraction(0.945733f, vect.mV[0], 16)); } template<> template<> void llquat_test_object_t::test<22>() { //test case for void LLQuaternion::getEulerAngles(F32 *roll, F32 *pitch, F32 *yaw) const fn F32 roll = -12.0f; F32 pitch = -22.43f; F32 yaw = 11.0f; LLQuaternion llquat; llquat.getEulerAngles(&roll, &pitch, &yaw); ensure( "LLQuaternion::getEulerAngles(F32 *roll, F32 *pitch, F32 *yaw) failed", is_approx_equal(0.000f, llquat.mQ[0]) && is_approx_equal(0.000f, llquat.mQ[1]) && is_approx_equal(0.000f, llquat.mQ[2]) && is_approx_equal(1.000f, llquat.mQ[3])); } }