libc/test/src/math/FmaTest.h - external/github.com/llvm/llvm-project.git - Git at Google

 //===-- Utility class to test different flavors of fma --------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_LIBC_TEST_SRC_MATH_FMATEST_H
 #define LLVM_LIBC_TEST_SRC_MATH_FMATEST_H

 #include "src/__support/FPUtil/FPBits.h"
 #include "src/stdlib/rand.h"
 #include "src/stdlib/srand.h"
 #include "test/UnitTest/FPMatcher.h"
 #include "test/UnitTest/Test.h"
 #include "utils/MPFRWrapper/MPFRUtils.h"

 namespace mpfr = LIBC_NAMESPACE::testing::mpfr;

 template <typename T>
 class FmaTestTemplate : public LIBC_NAMESPACE::testing::Test {
 private:
   using Func = T (*)(T, T, T);
   using FPBits = LIBC_NAMESPACE::fputil::FPBits<T>;
   using StorageType = typename FPBits::StorageType;

   const T min_subnormal = FPBits::min_subnormal(Sign::POS).get_val();
   const T min_normal = FPBits::min_normal(Sign::POS).get_val();
   const T max_normal = FPBits::max_normal(Sign::POS).get_val();
   const T inf = FPBits::inf(Sign::POS).get_val();
   const T neg_inf = FPBits::inf(Sign::NEG).get_val();
   const T zero = FPBits::zero(Sign::POS).get_val();
   const T neg_zero = FPBits::zero(Sign::NEG).get_val();
   const T nan = FPBits::quiet_nan().get_val();

   static constexpr StorageType MAX_NORMAL = FPBits::max_normal().uintval();
   static constexpr StorageType MIN_NORMAL = FPBits::min_normal().uintval();
   static constexpr StorageType MAX_SUBNORMAL =
       FPBits::max_subnormal().uintval();
   static constexpr StorageType MIN_SUBNORMAL =
       FPBits::min_subnormal().uintval();

   StorageType get_random_bit_pattern() {
     StorageType bits{0};
     for (StorageType i = 0; i < sizeof(StorageType) / 2; ++i) {
       bits = (bits << 2) + static_cast<uint16_t>(LIBC_NAMESPACE::rand());
     }
     return bits;
   }

 public:
   void test_special_numbers(Func func) {
     EXPECT_FP_EQ(func(zero, zero, zero), zero);
     EXPECT_FP_EQ(func(zero, neg_zero, neg_zero), neg_zero);
     EXPECT_FP_EQ(func(inf, inf, zero), inf);
     EXPECT_FP_EQ(func(neg_inf, inf, neg_inf), neg_inf);
     EXPECT_FP_EQ(func(inf, zero, zero), nan);
     EXPECT_FP_EQ(func(inf, neg_inf, inf), nan);
     EXPECT_FP_EQ(func(nan, zero, inf), nan);
     EXPECT_FP_EQ(func(inf, neg_inf, nan), nan);

     // Test underflow rounding up.
     EXPECT_FP_EQ(func(T(0.5), min_subnormal, min_subnormal),
                  FPBits(StorageType(2)).get_val());
     // Test underflow rounding down.
     T v = FPBits(MIN_NORMAL + StorageType(1)).get_val();
     EXPECT_FP_EQ(func(T(1) / T(MIN_NORMAL << 1), v, min_normal), v);
     // Test overflow.
     T z = max_normal;
     EXPECT_FP_EQ(func(T(1.75), z, -z), T(0.75) * z);
     // Exact cancellation.
     EXPECT_FP_EQ(func(T(3.0), T(5.0), -T(15.0)), T(0.0));
     EXPECT_FP_EQ(func(T(-3.0), T(5.0), T(15.0)), T(0.0));
   }

   void test_subnormal_range(Func func) {
     constexpr StorageType COUNT = 100'001;
     constexpr StorageType STEP = (MAX_SUBNORMAL - MIN_SUBNORMAL) / COUNT;
     LIBC_NAMESPACE::srand(1);
     for (StorageType v = MIN_SUBNORMAL, w = MAX_SUBNORMAL;
          v <= MAX_SUBNORMAL && w >= MIN_SUBNORMAL; v += STEP, w -= STEP) {
       T x = FPBits(get_random_bit_pattern()).get_val(), y = FPBits(v).get_val(),
         z = FPBits(w).get_val();
       mpfr::TernaryInput<T> input{x, y, z};
       ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Fma, input, func(x, y, z),
                                      0.5);
     }
   }

   void test_normal_range(Func func) {
     constexpr StorageType COUNT = 100'001;
     constexpr StorageType STEP = (MAX_NORMAL - MIN_NORMAL) / COUNT;
     LIBC_NAMESPACE::srand(1);
     for (StorageType v = MIN_NORMAL, w = MAX_NORMAL;
          v <= MAX_NORMAL && w >= MIN_NORMAL; v += STEP, w -= STEP) {
       T x = FPBits(v).get_val(), y = FPBits(w).get_val(),
         z = FPBits(get_random_bit_pattern()).get_val();
       mpfr::TernaryInput<T> input{x, y, z};
       ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Fma, input, func(x, y, z),
                                      0.5);
     }
   }
 };

 #endif // LLVM_LIBC_TEST_SRC_MATH_FMATEST_H
	//===-- Utility class to test different flavors of fma --------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_LIBC_TEST_SRC_MATH_FMATEST_H
	#define LLVM_LIBC_TEST_SRC_MATH_FMATEST_H

	#include "src/__support/FPUtil/FPBits.h"
	#include "src/stdlib/rand.h"
	#include "src/stdlib/srand.h"
	#include "test/UnitTest/FPMatcher.h"
	#include "test/UnitTest/Test.h"
	#include "utils/MPFRWrapper/MPFRUtils.h"

	namespace mpfr = LIBC_NAMESPACE::testing::mpfr;

	template <typename T>
	class FmaTestTemplate : public LIBC_NAMESPACE::testing::Test {
	private:
	using Func = T (*)(T, T, T);
	using FPBits = LIBC_NAMESPACE::fputil::FPBits<T>;
	using StorageType = typename FPBits::StorageType;

	const T min_subnormal = FPBits::min_subnormal(Sign::POS).get_val();
	const T min_normal = FPBits::min_normal(Sign::POS).get_val();
	const T max_normal = FPBits::max_normal(Sign::POS).get_val();
	const T inf = FPBits::inf(Sign::POS).get_val();
	const T neg_inf = FPBits::inf(Sign::NEG).get_val();
	const T zero = FPBits::zero(Sign::POS).get_val();
	const T neg_zero = FPBits::zero(Sign::NEG).get_val();
	const T nan = FPBits::quiet_nan().get_val();

	static constexpr StorageType MAX_NORMAL = FPBits::max_normal().uintval();
	static constexpr StorageType MIN_NORMAL = FPBits::min_normal().uintval();
	static constexpr StorageType MAX_SUBNORMAL =
	FPBits::max_subnormal().uintval();
	static constexpr StorageType MIN_SUBNORMAL =
	FPBits::min_subnormal().uintval();

	StorageType get_random_bit_pattern() {
	StorageType bits{0};
	for (StorageType i = 0; i < sizeof(StorageType) / 2; ++i) {
	bits = (bits << 2) + static_cast<uint16_t>(LIBC_NAMESPACE::rand());
	}
	return bits;
	}

	public:
	void test_special_numbers(Func func) {
	EXPECT_FP_EQ(func(zero, zero, zero), zero);
	EXPECT_FP_EQ(func(zero, neg_zero, neg_zero), neg_zero);
	EXPECT_FP_EQ(func(inf, inf, zero), inf);
	EXPECT_FP_EQ(func(neg_inf, inf, neg_inf), neg_inf);
	EXPECT_FP_EQ(func(inf, zero, zero), nan);
	EXPECT_FP_EQ(func(inf, neg_inf, inf), nan);
	EXPECT_FP_EQ(func(nan, zero, inf), nan);
	EXPECT_FP_EQ(func(inf, neg_inf, nan), nan);

	// Test underflow rounding up.
	EXPECT_FP_EQ(func(T(0.5), min_subnormal, min_subnormal),
	FPBits(StorageType(2)).get_val());
	// Test underflow rounding down.
	T v = FPBits(MIN_NORMAL + StorageType(1)).get_val();
	EXPECT_FP_EQ(func(T(1) / T(MIN_NORMAL << 1), v, min_normal), v);
	// Test overflow.
	T z = max_normal;
	EXPECT_FP_EQ(func(T(1.75), z, -z), T(0.75) * z);
	// Exact cancellation.
	EXPECT_FP_EQ(func(T(3.0), T(5.0), -T(15.0)), T(0.0));
	EXPECT_FP_EQ(func(T(-3.0), T(5.0), T(15.0)), T(0.0));
	}

	void test_subnormal_range(Func func) {
	constexpr StorageType COUNT = 100'001;
	constexpr StorageType STEP = (MAX_SUBNORMAL - MIN_SUBNORMAL) / COUNT;
	LIBC_NAMESPACE::srand(1);
	for (StorageType v = MIN_SUBNORMAL, w = MAX_SUBNORMAL;
	v <= MAX_SUBNORMAL && w >= MIN_SUBNORMAL; v += STEP, w -= STEP) {
	T x = FPBits(get_random_bit_pattern()).get_val(), y = FPBits(v).get_val(),
	z = FPBits(w).get_val();
	mpfr::TernaryInput<T> input{x, y, z};
	ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Fma, input, func(x, y, z),
	0.5);
	}
	}

	void test_normal_range(Func func) {
	constexpr StorageType COUNT = 100'001;
	constexpr StorageType STEP = (MAX_NORMAL - MIN_NORMAL) / COUNT;
	LIBC_NAMESPACE::srand(1);
	for (StorageType v = MIN_NORMAL, w = MAX_NORMAL;
	v <= MAX_NORMAL && w >= MIN_NORMAL; v += STEP, w -= STEP) {
	T x = FPBits(v).get_val(), y = FPBits(w).get_val(),
	z = FPBits(get_random_bit_pattern()).get_val();
	mpfr::TernaryInput<T> input{x, y, z};
	ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Fma, input, func(x, y, z),
	0.5);
	}
	}
	};

	#endif // LLVM_LIBC_TEST_SRC_MATH_FMATEST_H