src/third_party/glm/test/gtc/gtc_quaternion.cpp - cobalt - Git at Google

 #include <glm/gtc/quaternion.hpp>
 #include <glm/gtc/epsilon.hpp>
 #include <glm/vector_relational.hpp>
 #include <vector>

 int test_quat_angle()
 {
 	int Error = 0;

 	{
 		glm::quat Q = glm::angleAxis(glm::pi<float>() * 0.25f, glm::vec3(0, 0, 1));
 		glm::quat N = glm::normalize(Q);
 		float L = glm::length(N);
 		Error += glm::epsilonEqual(L, 1.0f, 0.01f) ? 0 : 1;
 		float A = glm::angle(N);
 		Error += glm::epsilonEqual(A, glm::pi<float>() * 0.25f, 0.01f) ? 0 : 1;
 	}
 	{
 		glm::quat Q = glm::angleAxis(glm::pi<float>() * 0.25f, glm::normalize(glm::vec3(0, 1, 1)));
 		glm::quat N = glm::normalize(Q);
 		float L = glm::length(N);
 		Error += glm::epsilonEqual(L, 1.0f, 0.01f) ? 0 : 1;
 		float A = glm::angle(N);
 		Error += glm::epsilonEqual(A, glm::pi<float>() * 0.25f, 0.01f) ? 0 : 1;
 	}
 	{
 		glm::quat Q = glm::angleAxis(glm::pi<float>() * 0.25f, glm::normalize(glm::vec3(1, 2, 3)));
 		glm::quat N = glm::normalize(Q);
 		float L = glm::length(N);
 		Error += glm::epsilonEqual(L, 1.0f, 0.01f) ? 0 : 1;
 		float A = glm::angle(N);
 		Error += glm::epsilonEqual(A, glm::pi<float>() * 0.25f, 0.01f) ? 0 : 1;
 	}

 	return Error;
 }

 int test_quat_angleAxis()
 {
 	int Error = 0;

 	glm::quat A = glm::angleAxis(0.0f, glm::vec3(0, 0, 1));
 	glm::quat B = glm::angleAxis(glm::pi<float>() * 0.5f, glm::vec3(0, 0, 1));
 	glm::quat C = glm::mix(A, B, 0.5f);
 	glm::quat D = glm::angleAxis(glm::pi<float>() * 0.25f, glm::vec3(0, 0, 1));

 	Error += glm::epsilonEqual(C.x, D.x, 0.01f) ? 0 : 1;
 	Error += glm::epsilonEqual(C.y, D.y, 0.01f) ? 0 : 1;
 	Error += glm::epsilonEqual(C.z, D.z, 0.01f) ? 0 : 1;
 	Error += glm::epsilonEqual(C.w, D.w, 0.01f) ? 0 : 1;

 	return Error;
 }

 int test_quat_mix()
 {
 	int Error = 0;

 	glm::quat A = glm::angleAxis(0.0f, glm::vec3(0, 0, 1));
 	glm::quat B = glm::angleAxis(glm::pi<float>() * 0.5f, glm::vec3(0, 0, 1));
 	glm::quat C = glm::mix(A, B, 0.5f);
 	glm::quat D = glm::angleAxis(glm::pi<float>() * 0.25f, glm::vec3(0, 0, 1));

 	Error += glm::epsilonEqual(C.x, D.x, 0.01f) ? 0 : 1;
 	Error += glm::epsilonEqual(C.y, D.y, 0.01f) ? 0 : 1;
 	Error += glm::epsilonEqual(C.z, D.z, 0.01f) ? 0 : 1;
 	Error += glm::epsilonEqual(C.w, D.w, 0.01f) ? 0 : 1;

 	return Error;
 }

 int test_quat_precision()
 {
 	int Error = 0;

 	Error += sizeof(glm::lowp_quat) <= sizeof(glm::mediump_quat) ? 0 : 1;
 	Error += sizeof(glm::mediump_quat) <= sizeof(glm::highp_quat) ? 0 : 1;

 	return Error;
 }

 int test_quat_normalize()
 {
 	int Error(0);

 	{
 		glm::quat Q = glm::angleAxis(glm::pi<float>() * 0.25f, glm::vec3(0, 0, 1));
 		glm::quat N = glm::normalize(Q);
 		float L = glm::length(N);
 		Error += glm::epsilonEqual(L, 1.0f, 0.000001f) ? 0 : 1;
 	}
 	{
 		glm::quat Q = glm::angleAxis(glm::pi<float>() * 0.25f, glm::vec3(0, 0, 2));
 		glm::quat N = glm::normalize(Q);
 		float L = glm::length(N);
 		Error += glm::epsilonEqual(L, 1.0f, 0.000001f) ? 0 : 1;
 	}
 	{
 		glm::quat Q = glm::angleAxis(glm::pi<float>() * 0.25f, glm::vec3(1, 2, 3));
 		glm::quat N = glm::normalize(Q);
 		float L = glm::length(N);
 		Error += glm::epsilonEqual(L, 1.0f, 0.000001f) ? 0 : 1;
 	}

 	return Error;
 }

 int test_quat_euler()
 {
 	int Error(0);

 	{
 		glm::quat q(1.0f, 0.0f, 0.0f, 1.0f);
 		float Roll = glm::roll(q);
 		float Pitch = glm::pitch(q);
 		float Yaw = glm::yaw(q);
 		glm::vec3 Angles = glm::eulerAngles(q);
 	}

 	{
 		glm::dquat q(1.0f, 0.0f, 0.0f, 1.0f);
 		double Roll = glm::roll(q);
 		double Pitch = glm::pitch(q);
 		double Yaw = glm::yaw(q);
 		glm::dvec3 Angles = glm::eulerAngles(q);
 	}

 	return Error;
 }

 int test_quat_slerp()
 {
 	int Error(0);

 	float const Epsilon = 0.0001f;//glm::epsilon<float>();

 	float sqrt2 = sqrt(2.0f)/2.0f;
 	glm::quat id;
 	glm::quat Y90rot(sqrt2, 0.0f, sqrt2, 0.0f);
 	glm::quat Y180rot(0.0f, 0.0f, 1.0f, 0.0f);

 	// Testing a == 0
 	// Must be id
 	glm::quat id2 = glm::slerp(id, Y90rot, 0.0f);
 	Error += glm::all(glm::epsilonEqual(id, id2, Epsilon)) ? 0 : 1;

 	// Testing a == 1
 	// Must be 90° rotation on Y : 0 0.7 0 0.7
 	glm::quat Y90rot2 = glm::slerp(id, Y90rot, 1.0f);
 	Error += glm::all(glm::epsilonEqual(Y90rot, Y90rot2, Epsilon)) ? 0 : 1;

 	// Testing standard, easy case
 	// Must be 45° rotation on Y : 0 0.38 0 0.92
 	glm::quat Y45rot1 = glm::slerp(id, Y90rot, 0.5f);

 	// Testing reverse case
 	// Must be 45° rotation on Y : 0 0.38 0 0.92
 	glm::quat Ym45rot2 = glm::slerp(Y90rot, id, 0.5f);

 	// Testing against full circle around the sphere instead of shortest path
 	// Must be 45° rotation on Y
 	// certainly not a 135° rotation
 	glm::quat Y45rot3 = glm::slerp(id , -Y90rot, 0.5f);
 	float Y45angle3 = glm::angle(Y45rot3);
 	Error += glm::epsilonEqual(Y45angle3, glm::pi<float>() * 0.25f, Epsilon) ? 0 : 1;
 	Error += glm::all(glm::epsilonEqual(Ym45rot2, Y45rot3, Epsilon)) ? 0 : 1;

 	// Same, but inverted
 	// Must also be 45° rotation on Y :  0 0.38 0 0.92
 	// -0 -0.38 -0 -0.92 is ok too
 	glm::quat Y45rot4 = glm::slerp(-Y90rot, id, 0.5f);
 	Error += glm::all(glm::epsilonEqual(Ym45rot2, -Y45rot4, Epsilon)) ? 0 : 1;

 	// Testing q1 = q2
 	// Must be 90° rotation on Y : 0 0.7 0 0.7
 	glm::quat Y90rot3 = glm::slerp(Y90rot, Y90rot, 0.5f);
 	Error += glm::all(glm::epsilonEqual(Y90rot, Y90rot3, Epsilon)) ? 0 : 1;

 	// Testing 180° rotation
 	// Must be 90° rotation on almost any axis that is on the XZ plane
 	glm::quat XZ90rot = glm::slerp(id, -Y90rot, 0.5f);
 	float XZ90angle = glm::angle(XZ90rot); // Must be PI/4 = 0.78;
 	Error += glm::epsilonEqual(XZ90angle, glm::pi<float>() * 0.25f, Epsilon) ? 0 : 1;

 	// Testing almost equal quaternions (this test should pass through the linear interpolation)
 	// Must be 0 0.00X 0 0.99999
 	glm::quat almostid = glm::slerp(id, glm::angleAxis(0.1f, glm::vec3(0.0f, 1.0f, 0.0f)), 0.5f);

 	// Testing quaternions with opposite sign
 	{
 		glm::quat a(-1, 0, 0, 0);

 		glm::quat result = glm::slerp(a, id, 0.5f);

 		Error += glm::epsilonEqual(glm::pow(glm::dot(id, result), 2.f), 1.f, 0.01f) ? 0 : 1;
 	}

 	return Error;
 }

 int test_quat_mul()
 {
 	int Error(0);

 	glm::quat temp1 = glm::normalize(glm::quat(1.0f, glm::vec3(0.0, 1.0, 0.0)));
 	glm::quat temp2 = glm::normalize(glm::quat(0.5f, glm::vec3(1.0, 0.0, 0.0)));

 	glm::vec3 transformed0 = (temp1 * glm::vec3(0.0, 1.0, 0.0) * glm::inverse(temp1));
 	glm::vec3 temp4 = temp2 * transformed0 * glm::inverse(temp2);

 	glm::quat temp5 = glm::normalize(temp1 * temp2);
 	glm::vec3 temp6 = temp5 * glm::vec3(0.0, 1.0, 0.0) * glm::inverse(temp5);

 #	ifndef GLM_FORCE_NO_CTOR_INIT
 	{
 		glm::quat temp7;

 		temp7 *= temp5;
 		temp7 *= glm::inverse(temp5);

 		Error += temp7 != glm::quat();
 	}
 #	endif

 	return Error;
 }

 int test_quat_two_axis_ctr()
 {
 	int Error(0);

 	glm::quat q1(glm::vec3(1, 0, 0), glm::vec3(0, 1, 0));
 	glm::vec3 v1 = q1 * glm::vec3(1, 0, 0);
 	Error += glm::all(glm::epsilonEqual(v1, glm::vec3(0, 1, 0), 0.0001f)) ? 0 : 1;

 	glm::quat q2 = q1 * q1;
 	glm::vec3 v2 = q2 * glm::vec3(1, 0, 0);
 	Error += glm::all(glm::epsilonEqual(v2, glm::vec3(-1, 0, 0), 0.0001f)) ? 0 : 1;

 	return Error;
 }

 int test_quat_type()
 {
 	glm::quat A;
 	glm::dquat B;

 	return 0;
 }

 int test_quat_mul_vec()
 {
 	int Error(0);

 	glm::quat q = glm::angleAxis(glm::pi<float>() * 0.5f, glm::vec3(0, 0, 1));
 	glm::vec3 v(1, 0, 0);
 	glm::vec3 u(q * v);
 	glm::vec3 w(u * q);

 	Error += glm::all(glm::epsilonEqual(v, w, 0.01f)) ? 0 : 1;

 	return Error;
 }

 int test_quat_ctr()
 {
 	int Error(0);

 #	if GLM_HAS_TRIVIAL_QUERIES
 	//	Error += std::is_trivially_default_constructible<glm::quat>::value ? 0 : 1;
 	//	Error += std::is_trivially_default_constructible<glm::dquat>::value ? 0 : 1;
 	//	Error += std::is_trivially_copy_assignable<glm::quat>::value ? 0 : 1;
 	//	Error += std::is_trivially_copy_assignable<glm::dquat>::value ? 0 : 1;
 		Error += std::is_trivially_copyable<glm::quat>::value ? 0 : 1;
 		Error += std::is_trivially_copyable<glm::dquat>::value ? 0 : 1;

 		Error += std::is_copy_constructible<glm::quat>::value ? 0 : 1;
 		Error += std::is_copy_constructible<glm::dquat>::value ? 0 : 1;
 #	endif

 #	if GLM_HAS_INITIALIZER_LISTS
 	{
 		glm::quat A{0, 1, 2, 3};

 		std::vector<glm::quat> B{
 			{0, 1, 2, 3},
 			{0, 1, 2, 3}};
 	}
 #	endif//GLM_HAS_INITIALIZER_LISTS

 	return Error;
 }

 int main()
 {
 	int Error(0);

 	Error += test_quat_ctr();
 	Error += test_quat_mul_vec();
 	Error += test_quat_two_axis_ctr();
 	Error += test_quat_mul();
 	Error += test_quat_precision();
 	Error += test_quat_type();
 	Error += test_quat_angle();
 	Error += test_quat_angleAxis();
 	Error += test_quat_mix();
 	Error += test_quat_normalize();
 	Error += test_quat_euler();
 	Error += test_quat_slerp();

 	return Error;
 }
	#include <glm/gtc/quaternion.hpp>
	#include <glm/gtc/epsilon.hpp>
	#include <glm/vector_relational.hpp>
	#include <vector>

	int test_quat_angle()
	{
	int Error = 0;

	{
	glm::quat Q = glm::angleAxis(glm::pi<float>() * 0.25f, glm::vec3(0, 0, 1));
	glm::quat N = glm::normalize(Q);
	float L = glm::length(N);
	Error += glm::epsilonEqual(L, 1.0f, 0.01f) ? 0 : 1;
	float A = glm::angle(N);
	Error += glm::epsilonEqual(A, glm::pi<float>() * 0.25f, 0.01f) ? 0 : 1;
	}
	{
	glm::quat Q = glm::angleAxis(glm::pi<float>() * 0.25f, glm::normalize(glm::vec3(0, 1, 1)));
	glm::quat N = glm::normalize(Q);
	float L = glm::length(N);
	Error += glm::epsilonEqual(L, 1.0f, 0.01f) ? 0 : 1;
	float A = glm::angle(N);
	Error += glm::epsilonEqual(A, glm::pi<float>() * 0.25f, 0.01f) ? 0 : 1;
	}
	{
	glm::quat Q = glm::angleAxis(glm::pi<float>() * 0.25f, glm::normalize(glm::vec3(1, 2, 3)));
	glm::quat N = glm::normalize(Q);
	float L = glm::length(N);
	Error += glm::epsilonEqual(L, 1.0f, 0.01f) ? 0 : 1;
	float A = glm::angle(N);
	Error += glm::epsilonEqual(A, glm::pi<float>() * 0.25f, 0.01f) ? 0 : 1;
	}

	return Error;
	}

	int test_quat_angleAxis()
	{
	int Error = 0;

	glm::quat A = glm::angleAxis(0.0f, glm::vec3(0, 0, 1));
	glm::quat B = glm::angleAxis(glm::pi<float>() * 0.5f, glm::vec3(0, 0, 1));
	glm::quat C = glm::mix(A, B, 0.5f);
	glm::quat D = glm::angleAxis(glm::pi<float>() * 0.25f, glm::vec3(0, 0, 1));

	Error += glm::epsilonEqual(C.x, D.x, 0.01f) ? 0 : 1;
	Error += glm::epsilonEqual(C.y, D.y, 0.01f) ? 0 : 1;
	Error += glm::epsilonEqual(C.z, D.z, 0.01f) ? 0 : 1;
	Error += glm::epsilonEqual(C.w, D.w, 0.01f) ? 0 : 1;

	return Error;
	}

	int test_quat_mix()
	{
	int Error = 0;

	glm::quat A = glm::angleAxis(0.0f, glm::vec3(0, 0, 1));
	glm::quat B = glm::angleAxis(glm::pi<float>() * 0.5f, glm::vec3(0, 0, 1));
	glm::quat C = glm::mix(A, B, 0.5f);
	glm::quat D = glm::angleAxis(glm::pi<float>() * 0.25f, glm::vec3(0, 0, 1));

	Error += glm::epsilonEqual(C.x, D.x, 0.01f) ? 0 : 1;
	Error += glm::epsilonEqual(C.y, D.y, 0.01f) ? 0 : 1;
	Error += glm::epsilonEqual(C.z, D.z, 0.01f) ? 0 : 1;
	Error += glm::epsilonEqual(C.w, D.w, 0.01f) ? 0 : 1;

	return Error;
	}

	int test_quat_precision()
	{
	int Error = 0;

	Error += sizeof(glm::lowp_quat) <= sizeof(glm::mediump_quat) ? 0 : 1;
	Error += sizeof(glm::mediump_quat) <= sizeof(glm::highp_quat) ? 0 : 1;

	return Error;
	}

	int test_quat_normalize()
	{
	int Error(0);

	{
	glm::quat Q = glm::angleAxis(glm::pi<float>() * 0.25f, glm::vec3(0, 0, 1));
	glm::quat N = glm::normalize(Q);
	float L = glm::length(N);
	Error += glm::epsilonEqual(L, 1.0f, 0.000001f) ? 0 : 1;
	}
	{
	glm::quat Q = glm::angleAxis(glm::pi<float>() * 0.25f, glm::vec3(0, 0, 2));
	glm::quat N = glm::normalize(Q);
	float L = glm::length(N);
	Error += glm::epsilonEqual(L, 1.0f, 0.000001f) ? 0 : 1;
	}
	{
	glm::quat Q = glm::angleAxis(glm::pi<float>() * 0.25f, glm::vec3(1, 2, 3));
	glm::quat N = glm::normalize(Q);
	float L = glm::length(N);
	Error += glm::epsilonEqual(L, 1.0f, 0.000001f) ? 0 : 1;
	}

	return Error;
	}

	int test_quat_euler()
	{
	int Error(0);

	{
	glm::quat q(1.0f, 0.0f, 0.0f, 1.0f);
	float Roll = glm::roll(q);
	float Pitch = glm::pitch(q);
	float Yaw = glm::yaw(q);
	glm::vec3 Angles = glm::eulerAngles(q);
	}

	{
	glm::dquat q(1.0f, 0.0f, 0.0f, 1.0f);
	double Roll = glm::roll(q);
	double Pitch = glm::pitch(q);
	double Yaw = glm::yaw(q);
	glm::dvec3 Angles = glm::eulerAngles(q);
	}

	return Error;
	}

	int test_quat_slerp()
	{
	int Error(0);

	float const Epsilon = 0.0001f;//glm::epsilon<float>();

	float sqrt2 = sqrt(2.0f)/2.0f;
	glm::quat id;
	glm::quat Y90rot(sqrt2, 0.0f, sqrt2, 0.0f);
	glm::quat Y180rot(0.0f, 0.0f, 1.0f, 0.0f);

	// Testing a == 0
	// Must be id
	glm::quat id2 = glm::slerp(id, Y90rot, 0.0f);
	Error += glm::all(glm::epsilonEqual(id, id2, Epsilon)) ? 0 : 1;

	// Testing a == 1
	// Must be 90° rotation on Y : 0 0.7 0 0.7
	glm::quat Y90rot2 = glm::slerp(id, Y90rot, 1.0f);
	Error += glm::all(glm::epsilonEqual(Y90rot, Y90rot2, Epsilon)) ? 0 : 1;

	// Testing standard, easy case
	// Must be 45° rotation on Y : 0 0.38 0 0.92
	glm::quat Y45rot1 = glm::slerp(id, Y90rot, 0.5f);

	// Testing reverse case
	// Must be 45° rotation on Y : 0 0.38 0 0.92
	glm::quat Ym45rot2 = glm::slerp(Y90rot, id, 0.5f);

	// Testing against full circle around the sphere instead of shortest path
	// Must be 45° rotation on Y
	// certainly not a 135° rotation
	glm::quat Y45rot3 = glm::slerp(id , -Y90rot, 0.5f);
	float Y45angle3 = glm::angle(Y45rot3);
	Error += glm::epsilonEqual(Y45angle3, glm::pi<float>() * 0.25f, Epsilon) ? 0 : 1;
	Error += glm::all(glm::epsilonEqual(Ym45rot2, Y45rot3, Epsilon)) ? 0 : 1;

	// Same, but inverted
	// Must also be 45° rotation on Y : 0 0.38 0 0.92
	// -0 -0.38 -0 -0.92 is ok too
	glm::quat Y45rot4 = glm::slerp(-Y90rot, id, 0.5f);
	Error += glm::all(glm::epsilonEqual(Ym45rot2, -Y45rot4, Epsilon)) ? 0 : 1;

	// Testing q1 = q2
	// Must be 90° rotation on Y : 0 0.7 0 0.7
	glm::quat Y90rot3 = glm::slerp(Y90rot, Y90rot, 0.5f);
	Error += glm::all(glm::epsilonEqual(Y90rot, Y90rot3, Epsilon)) ? 0 : 1;

	// Testing 180° rotation
	// Must be 90° rotation on almost any axis that is on the XZ plane
	glm::quat XZ90rot = glm::slerp(id, -Y90rot, 0.5f);
	float XZ90angle = glm::angle(XZ90rot); // Must be PI/4 = 0.78;
	Error += glm::epsilonEqual(XZ90angle, glm::pi<float>() * 0.25f, Epsilon) ? 0 : 1;

	// Testing almost equal quaternions (this test should pass through the linear interpolation)
	// Must be 0 0.00X 0 0.99999
	glm::quat almostid = glm::slerp(id, glm::angleAxis(0.1f, glm::vec3(0.0f, 1.0f, 0.0f)), 0.5f);

	// Testing quaternions with opposite sign
	{
	glm::quat a(-1, 0, 0, 0);

	glm::quat result = glm::slerp(a, id, 0.5f);

	Error += glm::epsilonEqual(glm::pow(glm::dot(id, result), 2.f), 1.f, 0.01f) ? 0 : 1;
	}

	return Error;
	}

	int test_quat_mul()
	{
	int Error(0);

	glm::quat temp1 = glm::normalize(glm::quat(1.0f, glm::vec3(0.0, 1.0, 0.0)));
	glm::quat temp2 = glm::normalize(glm::quat(0.5f, glm::vec3(1.0, 0.0, 0.0)));

	glm::vec3 transformed0 = (temp1 * glm::vec3(0.0, 1.0, 0.0) * glm::inverse(temp1));
	glm::vec3 temp4 = temp2 * transformed0 * glm::inverse(temp2);

	glm::quat temp5 = glm::normalize(temp1 * temp2);
	glm::vec3 temp6 = temp5 * glm::vec3(0.0, 1.0, 0.0) * glm::inverse(temp5);

	# ifndef GLM_FORCE_NO_CTOR_INIT
	{
	glm::quat temp7;

	temp7 *= temp5;
	temp7 *= glm::inverse(temp5);

	Error += temp7 != glm::quat();
	}
	# endif

	return Error;
	}

	int test_quat_two_axis_ctr()
	{
	int Error(0);

	glm::quat q1(glm::vec3(1, 0, 0), glm::vec3(0, 1, 0));
	glm::vec3 v1 = q1 * glm::vec3(1, 0, 0);
	Error += glm::all(glm::epsilonEqual(v1, glm::vec3(0, 1, 0), 0.0001f)) ? 0 : 1;

	glm::quat q2 = q1 * q1;
	glm::vec3 v2 = q2 * glm::vec3(1, 0, 0);
	Error += glm::all(glm::epsilonEqual(v2, glm::vec3(-1, 0, 0), 0.0001f)) ? 0 : 1;

	return Error;
	}

	int test_quat_type()
	{
	glm::quat A;
	glm::dquat B;

	return 0;
	}

	int test_quat_mul_vec()
	{
	int Error(0);

	glm::quat q = glm::angleAxis(glm::pi<float>() * 0.5f, glm::vec3(0, 0, 1));
	glm::vec3 v(1, 0, 0);
	glm::vec3 u(q * v);
	glm::vec3 w(u * q);

	Error += glm::all(glm::epsilonEqual(v, w, 0.01f)) ? 0 : 1;

	return Error;
	}

	int test_quat_ctr()
	{
	int Error(0);

	# if GLM_HAS_TRIVIAL_QUERIES
	// Error += std::is_trivially_default_constructible<glm::quat>::value ? 0 : 1;
	// Error += std::is_trivially_default_constructible<glm::dquat>::value ? 0 : 1;
	// Error += std::is_trivially_copy_assignable<glm::quat>::value ? 0 : 1;
	// Error += std::is_trivially_copy_assignable<glm::dquat>::value ? 0 : 1;
	Error += std::is_trivially_copyable<glm::quat>::value ? 0 : 1;
	Error += std::is_trivially_copyable<glm::dquat>::value ? 0 : 1;

	Error += std::is_copy_constructible<glm::quat>::value ? 0 : 1;
	Error += std::is_copy_constructible<glm::dquat>::value ? 0 : 1;
	# endif

	# if GLM_HAS_INITIALIZER_LISTS
	{
	glm::quat A{0, 1, 2, 3};

	std::vector<glm::quat> B{
	{0, 1, 2, 3},
	{0, 1, 2, 3}};
	}
	# endif//GLM_HAS_INITIALIZER_LISTS

	return Error;
	}

	int main()
	{
	int Error(0);

	Error += test_quat_ctr();
	Error += test_quat_mul_vec();
	Error += test_quat_two_axis_ctr();
	Error += test_quat_mul();
	Error += test_quat_precision();
	Error += test_quat_type();
	Error += test_quat_angle();
	Error += test_quat_angleAxis();
	Error += test_quat_mix();
	Error += test_quat_normalize();
	Error += test_quat_euler();
	Error += test_quat_slerp();

	return Error;
	}