src/third_party/glm/test/core/core_func_exponential.cpp - cobalt - Git at Google

 #include <glm/common.hpp>
 #include <glm/exponential.hpp>
 #include <glm/gtc/ulp.hpp>
 #include <glm/gtc/vec1.hpp>

 int test_pow()
 {
 	int Error(0);

 	float A = glm::pow(10.f, 10.f);
 	glm::vec1 B = glm::pow(glm::vec1(10.f), glm::vec1(10.f));
 	glm::vec2 C = glm::pow(glm::vec2(10.f), glm::vec2(10.f));
 	glm::vec3 D = glm::pow(glm::vec3(10.f), glm::vec3(10.f));
 	glm::vec4 E = glm::pow(glm::vec4(10.f), glm::vec4(10.f));

 	return Error;
 }

 int test_exp()
 {
 	int Error(0);

 	float A = glm::exp(10.f);
 	glm::vec1 B = glm::exp(glm::vec1(10.f));
 	glm::vec2 C = glm::exp(glm::vec2(10.f));
 	glm::vec3 D = glm::exp(glm::vec3(10.f));
 	glm::vec4 E = glm::exp(glm::vec4(10.f));

 	return Error;
 }

 int test_log()
 {
 	int Error(0);

 	float A = glm::log(10.f);
 	glm::vec1 B = glm::log(glm::vec1(10.f));
 	glm::vec2 C = glm::log(glm::vec2(10.f));
 	glm::vec3 D = glm::log(glm::vec3(10.f));
 	glm::vec4 E = glm::log(glm::vec4(10.f));

 	return Error;
 }

 int test_exp2()
 {
 	int Error(0);

 	float A = glm::exp2(10.f);
 	glm::vec1 B = glm::exp2(glm::vec1(10.f));
 	glm::vec2 C = glm::exp2(glm::vec2(10.f));
 	glm::vec3 D = glm::exp2(glm::vec3(10.f));
 	glm::vec4 E = glm::exp2(glm::vec4(10.f));

 	return Error;
 }

 int test_log2()
 {
 	int Error(0);

 	float A = glm::log2(10.f);
 	glm::vec1 B = glm::log2(glm::vec1(10.f));
 	glm::vec2 C = glm::log2(glm::vec2(10.f));
 	glm::vec3 D = glm::log2(glm::vec3(10.f));
 	glm::vec4 E = glm::log2(glm::vec4(10.f));

 	return Error;
 }

 int test_sqrt()
 {
 	int Error(0);

 #	if GLM_ARCH & GLM_ARCH_SSE2_BIT
 	for(float f = 0.1f; f < 30.0f; f += 0.1f)
 	{
 		float r = _mm_cvtss_f32(_mm_sqrt_ps(_mm_set1_ps(f)));
 		float s = std::sqrt(f);
 		Error += glm::abs(r - s) < 0.01f ? 0 : 1;
 		assert(!Error);
 	}
 #	endif//GLM_ARCH & GLM_ARCH_SSE2_BIT

 	float A = glm::sqrt(10.f);
 	glm::vec1 B = glm::sqrt(glm::vec1(10.f));
 	glm::vec2 C = glm::sqrt(glm::vec2(10.f));
 	glm::vec3 D = glm::sqrt(glm::vec3(10.f));
 	glm::vec4 E = glm::sqrt(glm::vec4(10.f));

 	return Error;
 }

 int test_inversesqrt()
 {
 	int Error(0);

 	glm::uint ulp(0);
 	float diff(0.0f);

 	for(float f = 0.001f; f < 10.f; f *= 1.001f)
 	{
 		glm::lowp_fvec1 u(f);
 		glm::lowp_fvec1 lowp_v = glm::inversesqrt(u);
 		float defaultp_v = glm::inversesqrt(f);

 		ulp = glm::max(glm::float_distance(lowp_v.x, defaultp_v), ulp);
 		diff = glm::abs(lowp_v.x - defaultp_v);
 	}

 	return Error;
 }

 int main()
 {
 	int Error(0);

 	Error += test_pow();
 	Error += test_exp();
 	Error += test_log();
 	Error += test_exp2();
 	Error += test_log2();
 	Error += test_sqrt();
 	Error += test_inversesqrt();

 	return Error;
 }
	#include <glm/common.hpp>
	#include <glm/exponential.hpp>
	#include <glm/gtc/ulp.hpp>
	#include <glm/gtc/vec1.hpp>

	int test_pow()
	{
	int Error(0);

	float A = glm::pow(10.f, 10.f);
	glm::vec1 B = glm::pow(glm::vec1(10.f), glm::vec1(10.f));
	glm::vec2 C = glm::pow(glm::vec2(10.f), glm::vec2(10.f));
	glm::vec3 D = glm::pow(glm::vec3(10.f), glm::vec3(10.f));
	glm::vec4 E = glm::pow(glm::vec4(10.f), glm::vec4(10.f));

	return Error;
	}

	int test_exp()
	{
	int Error(0);

	float A = glm::exp(10.f);
	glm::vec1 B = glm::exp(glm::vec1(10.f));
	glm::vec2 C = glm::exp(glm::vec2(10.f));
	glm::vec3 D = glm::exp(glm::vec3(10.f));
	glm::vec4 E = glm::exp(glm::vec4(10.f));

	return Error;
	}

	int test_log()
	{
	int Error(0);

	float A = glm::log(10.f);
	glm::vec1 B = glm::log(glm::vec1(10.f));
	glm::vec2 C = glm::log(glm::vec2(10.f));
	glm::vec3 D = glm::log(glm::vec3(10.f));
	glm::vec4 E = glm::log(glm::vec4(10.f));

	return Error;
	}

	int test_exp2()
	{
	int Error(0);

	float A = glm::exp2(10.f);
	glm::vec1 B = glm::exp2(glm::vec1(10.f));
	glm::vec2 C = glm::exp2(glm::vec2(10.f));
	glm::vec3 D = glm::exp2(glm::vec3(10.f));
	glm::vec4 E = glm::exp2(glm::vec4(10.f));

	return Error;
	}

	int test_log2()
	{
	int Error(0);

	float A = glm::log2(10.f);
	glm::vec1 B = glm::log2(glm::vec1(10.f));
	glm::vec2 C = glm::log2(glm::vec2(10.f));
	glm::vec3 D = glm::log2(glm::vec3(10.f));
	glm::vec4 E = glm::log2(glm::vec4(10.f));

	return Error;
	}

	int test_sqrt()
	{
	int Error(0);

	# if GLM_ARCH & GLM_ARCH_SSE2_BIT
	for(float f = 0.1f; f < 30.0f; f += 0.1f)
	{
	float r = _mm_cvtss_f32(_mm_sqrt_ps(_mm_set1_ps(f)));
	float s = std::sqrt(f);
	Error += glm::abs(r - s) < 0.01f ? 0 : 1;
	assert(!Error);
	}
	# endif//GLM_ARCH & GLM_ARCH_SSE2_BIT

	float A = glm::sqrt(10.f);
	glm::vec1 B = glm::sqrt(glm::vec1(10.f));
	glm::vec2 C = glm::sqrt(glm::vec2(10.f));
	glm::vec3 D = glm::sqrt(glm::vec3(10.f));
	glm::vec4 E = glm::sqrt(glm::vec4(10.f));

	return Error;
	}

	int test_inversesqrt()
	{
	int Error(0);

	glm::uint ulp(0);
	float diff(0.0f);

	for(float f = 0.001f; f < 10.f; f *= 1.001f)
	{
	glm::lowp_fvec1 u(f);
	glm::lowp_fvec1 lowp_v = glm::inversesqrt(u);
	float defaultp_v = glm::inversesqrt(f);

	ulp = glm::max(glm::float_distance(lowp_v.x, defaultp_v), ulp);
	diff = glm::abs(lowp_v.x - defaultp_v);
	}

	return Error;
	}

	int main()
	{
	int Error(0);

	Error += test_pow();
	Error += test_exp();
	Error += test_log();
	Error += test_exp2();
	Error += test_log2();
	Error += test_sqrt();
	Error += test_inversesqrt();

	return Error;
	}