test/src/math/RemQuoTest.h - llvm-project/libc - Git at Google

 //===-- Utility class to test different flavors of remquo -------*- C++ -*-===//
 //
 // 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_REMQUOTEST_H
 #define LLVM_LIBC_TEST_SRC_MATH_REMQUOTEST_H

 #include "utils/FPUtil/BasicOperations.h"
 #include "utils/FPUtil/FPBits.h"
 #include "utils/FPUtil/TestHelpers.h"
 #include "utils/MPFRWrapper/MPFRUtils.h"
 #include "utils/UnitTest/Test.h"
 #include <math.h>

 namespace mpfr = __llvm_libc::testing::mpfr;

 template <typename T>
 class RemQuoTestTemplate : public __llvm_libc::testing::Test {
   using FPBits = __llvm_libc::fputil::FPBits<T>;
   using UIntType = typename FPBits::UIntType;

   const T zero = __llvm_libc::fputil::FPBits<T>::zero();
   const T negZero = __llvm_libc::fputil::FPBits<T>::negZero();
   const T inf = __llvm_libc::fputil::FPBits<T>::inf();
   const T negInf = __llvm_libc::fputil::FPBits<T>::negInf();
   const T nan = __llvm_libc::fputil::FPBits<T>::buildNaN(1);

 public:
   typedef T (*RemQuoFunc)(T, T, int *);

   void testSpecialNumbers(RemQuoFunc func) {
     int quotient;
     T x, y;

     y = T(1.0);
     x = inf;
     EXPECT_FP_EQ(nan, func(x, y, &quotient));
     x = negInf;
     EXPECT_FP_EQ(nan, func(x, y, &quotient));

     x = T(1.0);
     y = zero;
     EXPECT_FP_EQ(nan, func(x, y, &quotient));
     y = negZero;
     EXPECT_FP_EQ(nan, func(x, y, &quotient));

     y = nan;
     x = T(1.0);
     EXPECT_FP_EQ(nan, func(x, y, &quotient));

     y = T(1.0);
     x = nan;
     EXPECT_FP_EQ(nan, func(x, y, &quotient));

     x = nan;
     y = nan;
     EXPECT_FP_EQ(nan, func(x, y, &quotient));

     x = zero;
     y = T(1.0);
     EXPECT_FP_EQ(func(x, y, &quotient), zero);

     x = negZero;
     y = T(1.0);
     EXPECT_FP_EQ(func(x, y, &quotient), negZero);

     x = T(1.125);
     y = inf;
     EXPECT_FP_EQ(func(x, y, &quotient), x);
     EXPECT_EQ(quotient, 0);
   }

   void testEqualNumeratorAndDenominator(RemQuoFunc func) {
     T x = T(1.125), y = T(1.125);
     int q;

     // When the remainder is zero, the standard requires it to
     // have the same sign as x.

     EXPECT_FP_EQ(func(x, y, &q), zero);
     EXPECT_EQ(q, 1);

     EXPECT_FP_EQ(func(x, -y, &q), zero);
     EXPECT_EQ(q, -1);

     EXPECT_FP_EQ(func(-x, y, &q), negZero);
     EXPECT_EQ(q, -1);

     EXPECT_FP_EQ(func(-x, -y, &q), negZero);
     EXPECT_EQ(q, 1);
   }

   void testSubnormalRange(RemQuoFunc func) {
     constexpr UIntType count = 1000001;
     constexpr UIntType step =
         (FPBits::maxSubnormal - FPBits::minSubnormal) / count;
     for (UIntType v = FPBits::minSubnormal, w = FPBits::maxSubnormal;
          v <= FPBits::maxSubnormal && w >= FPBits::minSubnormal;
          v += step, w -= step) {
       T x = FPBits(v), y = FPBits(w);
       mpfr::BinaryOutput<T> result;
       mpfr::BinaryInput<T> input{x, y};
       result.f = func(x, y, &result.i);
       ASSERT_MPFR_MATCH(mpfr::Operation::RemQuo, input, result, 0.0);
     }
   }

   void testNormalRange(RemQuoFunc func) {
     constexpr UIntType count = 1000001;
     constexpr UIntType step = (FPBits::maxNormal - FPBits::minNormal) / count;
     for (UIntType v = FPBits::minNormal, w = FPBits::maxNormal;
          v <= FPBits::maxNormal && w >= FPBits::minNormal;
          v += step, w -= step) {
       T x = FPBits(v), y = FPBits(w);
       mpfr::BinaryOutput<T> result;
       mpfr::BinaryInput<T> input{x, y};
       result.f = func(x, y, &result.i);

       // In normal range on x86 platforms, the long double implicit 1 bit can be
       // zero making the numbers NaN. Hence we test for them separately.
       if (isnan(x) || isnan(y)) {
         ASSERT_FP_EQ(result.f, nan);
         continue;
       }

       ASSERT_MPFR_MATCH(mpfr::Operation::RemQuo, input, result, 0.0);
     }
   }
 };

 #define LIST_REMQUO_TESTS(T, func)                                             \
   using LlvmLibcRemQuoTest = RemQuoTestTemplate<T>;                            \
   TEST_F(LlvmLibcRemQuoTest, SpecialNumbers) { testSpecialNumbers(&func); }    \
   TEST_F(LlvmLibcRemQuoTest, EqualNumeratorAndDenominator) {                   \
     testEqualNumeratorAndDenominator(&func);                                   \
   }                                                                            \
   TEST_F(LlvmLibcRemQuoTest, SubnormalRange) { testSubnormalRange(&func); }    \
   TEST_F(LlvmLibcRemQuoTest, NormalRange) { testNormalRange(&func); }

 #endif // LLVM_LIBC_TEST_SRC_MATH_REMQUOTEST_H
	//===-- Utility class to test different flavors of remquo -------- C++ --===//
	//
	// 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_REMQUOTEST_H
	#define LLVM_LIBC_TEST_SRC_MATH_REMQUOTEST_H

	#include "utils/FPUtil/BasicOperations.h"
	#include "utils/FPUtil/FPBits.h"
	#include "utils/FPUtil/TestHelpers.h"
	#include "utils/MPFRWrapper/MPFRUtils.h"
	#include "utils/UnitTest/Test.h"
	#include <math.h>

	namespace mpfr = __llvm_libc::testing::mpfr;

	template <typename T>
	class RemQuoTestTemplate : public __llvm_libc::testing::Test {
	using FPBits = __llvm_libc::fputil::FPBits<T>;
	using UIntType = typename FPBits::UIntType;

	const T zero = __llvm_libc::fputil::FPBits<T>::zero();
	const T negZero = __llvm_libc::fputil::FPBits<T>::negZero();
	const T inf = __llvm_libc::fputil::FPBits<T>::inf();
	const T negInf = __llvm_libc::fputil::FPBits<T>::negInf();
	const T nan = __llvm_libc::fputil::FPBits<T>::buildNaN(1);

	public:
	typedef T (RemQuoFunc)(T, T, int );

	void testSpecialNumbers(RemQuoFunc func) {
	int quotient;
	T x, y;

	y = T(1.0);
	x = inf;
	EXPECT_FP_EQ(nan, func(x, y, &quotient));
	x = negInf;
	EXPECT_FP_EQ(nan, func(x, y, &quotient));

	x = T(1.0);
	y = zero;
	EXPECT_FP_EQ(nan, func(x, y, &quotient));
	y = negZero;
	EXPECT_FP_EQ(nan, func(x, y, &quotient));

	y = nan;
	x = T(1.0);
	EXPECT_FP_EQ(nan, func(x, y, &quotient));

	y = T(1.0);
	x = nan;
	EXPECT_FP_EQ(nan, func(x, y, &quotient));

	x = nan;
	y = nan;
	EXPECT_FP_EQ(nan, func(x, y, &quotient));

	x = zero;
	y = T(1.0);
	EXPECT_FP_EQ(func(x, y, &quotient), zero);

	x = negZero;
	y = T(1.0);
	EXPECT_FP_EQ(func(x, y, &quotient), negZero);

	x = T(1.125);
	y = inf;
	EXPECT_FP_EQ(func(x, y, &quotient), x);
	EXPECT_EQ(quotient, 0);
	}

	void testEqualNumeratorAndDenominator(RemQuoFunc func) {
	T x = T(1.125), y = T(1.125);
	int q;

	// When the remainder is zero, the standard requires it to
	// have the same sign as x.

	EXPECT_FP_EQ(func(x, y, &q), zero);
	EXPECT_EQ(q, 1);

	EXPECT_FP_EQ(func(x, -y, &q), zero);
	EXPECT_EQ(q, -1);

	EXPECT_FP_EQ(func(-x, y, &q), negZero);
	EXPECT_EQ(q, -1);

	EXPECT_FP_EQ(func(-x, -y, &q), negZero);
	EXPECT_EQ(q, 1);
	}

	void testSubnormalRange(RemQuoFunc func) {
	constexpr UIntType count = 1000001;
	constexpr UIntType step =
	(FPBits::maxSubnormal - FPBits::minSubnormal) / count;
	for (UIntType v = FPBits::minSubnormal, w = FPBits::maxSubnormal;
	v <= FPBits::maxSubnormal && w >= FPBits::minSubnormal;
	v += step, w -= step) {
	T x = FPBits(v), y = FPBits(w);
	mpfr::BinaryOutput<T> result;
	mpfr::BinaryInput<T> input{x, y};
	result.f = func(x, y, &result.i);
	ASSERT_MPFR_MATCH(mpfr::Operation::RemQuo, input, result, 0.0);
	}
	}

	void testNormalRange(RemQuoFunc func) {
	constexpr UIntType count = 1000001;
	constexpr UIntType step = (FPBits::maxNormal - FPBits::minNormal) / count;
	for (UIntType v = FPBits::minNormal, w = FPBits::maxNormal;
	v <= FPBits::maxNormal && w >= FPBits::minNormal;
	v += step, w -= step) {
	T x = FPBits(v), y = FPBits(w);
	mpfr::BinaryOutput<T> result;
	mpfr::BinaryInput<T> input{x, y};
	result.f = func(x, y, &result.i);

	// In normal range on x86 platforms, the long double implicit 1 bit can be
	// zero making the numbers NaN. Hence we test for them separately.
	if (isnan(x) \|\| isnan(y)) {
	ASSERT_FP_EQ(result.f, nan);
	continue;
	}

	ASSERT_MPFR_MATCH(mpfr::Operation::RemQuo, input, result, 0.0);
	}
	}
	};

	#define LIST_REMQUO_TESTS(T, func) \
	using LlvmLibcRemQuoTest = RemQuoTestTemplate<T>; \
	TEST_F(LlvmLibcRemQuoTest, SpecialNumbers) { testSpecialNumbers(&func); } \
	TEST_F(LlvmLibcRemQuoTest, EqualNumeratorAndDenominator) { \
	testEqualNumeratorAndDenominator(&func); \
	} \
	TEST_F(LlvmLibcRemQuoTest, SubnormalRange) { testSubnormalRange(&func); } \
	TEST_F(LlvmLibcRemQuoTest, NormalRange) { testNormalRange(&func); }

	#endif // LLVM_LIBC_TEST_SRC_MATH_REMQUOTEST_H