test/src/math/expm1f_test.cpp - llvm-project/libc - Git at Google

 //===-- Unittests for expm1f-----------------------------------------------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//

 #include "hdr/math_macros.h"
 #include "src/__support/FPUtil/FPBits.h"
 #include "src/errno/libc_errno.h"
 #include "src/math/expm1f.h"
 #include "test/UnitTest/FPMatcher.h"
 #include "test/UnitTest/Test.h"
 #include "utils/MPFRWrapper/MPFRUtils.h"

 #include <stdint.h>

 using LlvmLibcExpm1fTest = LIBC_NAMESPACE::testing::FPTest<float>;

 namespace mpfr = LIBC_NAMESPACE::testing::mpfr;

 TEST_F(LlvmLibcExpm1fTest, SpecialNumbers) {
   LIBC_NAMESPACE::libc_errno = 0;

   EXPECT_FP_EQ(aNaN, LIBC_NAMESPACE::expm1f(aNaN));
   EXPECT_MATH_ERRNO(0);

   EXPECT_FP_EQ(inf, LIBC_NAMESPACE::expm1f(inf));
   EXPECT_MATH_ERRNO(0);

   EXPECT_FP_EQ(-1.0f, LIBC_NAMESPACE::expm1f(neg_inf));
   EXPECT_MATH_ERRNO(0);

   EXPECT_FP_EQ(0.0f, LIBC_NAMESPACE::expm1f(0.0f));
   EXPECT_MATH_ERRNO(0);

   EXPECT_FP_EQ(-0.0f, LIBC_NAMESPACE::expm1f(-0.0f));
   EXPECT_MATH_ERRNO(0);
 }

 TEST_F(LlvmLibcExpm1fTest, Overflow) {
   LIBC_NAMESPACE::libc_errno = 0;
   EXPECT_FP_EQ_WITH_EXCEPTION(
       inf, LIBC_NAMESPACE::expm1f(FPBits(0x7f7fffffU).get_val()), FE_OVERFLOW);
   EXPECT_MATH_ERRNO(ERANGE);

   EXPECT_FP_EQ_WITH_EXCEPTION(
       inf, LIBC_NAMESPACE::expm1f(FPBits(0x42cffff8U).get_val()), FE_OVERFLOW);
   EXPECT_MATH_ERRNO(ERANGE);

   EXPECT_FP_EQ_WITH_EXCEPTION(
       inf, LIBC_NAMESPACE::expm1f(FPBits(0x42d00008U).get_val()), FE_OVERFLOW);
   EXPECT_MATH_ERRNO(ERANGE);
 }

 TEST_F(LlvmLibcExpm1fTest, Underflow) {
   LIBC_NAMESPACE::libc_errno = 0;
   EXPECT_FP_EQ(-1.0f, LIBC_NAMESPACE::expm1f(FPBits(0xff7fffffU).get_val()));

   float x = FPBits(0xc2cffff8U).get_val();
   EXPECT_FP_EQ(-1.0f, LIBC_NAMESPACE::expm1f(x));

   x = FPBits(0xc2d00008U).get_val();
   EXPECT_FP_EQ(-1.0f, LIBC_NAMESPACE::expm1f(x));
 }

 // Test with inputs which are the borders of underflow/overflow but still
 // produce valid results without setting errno.
 TEST_F(LlvmLibcExpm1fTest, Borderline) {
   float x;

   LIBC_NAMESPACE::libc_errno = 0;
   x = FPBits(0x42affff8U).get_val();
   ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
                                  LIBC_NAMESPACE::expm1f(x), 0.5);
   EXPECT_MATH_ERRNO(0);

   x = FPBits(0x42b00008U).get_val();
   ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
                                  LIBC_NAMESPACE::expm1f(x), 0.5);
   EXPECT_MATH_ERRNO(0);

   x = FPBits(0xc2affff8U).get_val();
   ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
                                  LIBC_NAMESPACE::expm1f(x), 0.5);
   EXPECT_MATH_ERRNO(0);

   x = FPBits(0xc2b00008U).get_val();
   ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
                                  LIBC_NAMESPACE::expm1f(x), 0.5);
   EXPECT_MATH_ERRNO(0);

   x = FPBits(0x3dc252ddU).get_val();
   ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
                                  LIBC_NAMESPACE::expm1f(x), 0.5);
   EXPECT_MATH_ERRNO(0);

   x = FPBits(0x3e35bec5U).get_val();
   ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
                                  LIBC_NAMESPACE::expm1f(x), 0.5);
   EXPECT_MATH_ERRNO(0);

   x = FPBits(0x942ed494U).get_val();
   ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
                                  LIBC_NAMESPACE::expm1f(x), 0.5);
   EXPECT_MATH_ERRNO(0);

   x = FPBits(0xbdc1c6cbU).get_val();
   ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
                                  LIBC_NAMESPACE::expm1f(x), 0.5);
   EXPECT_MATH_ERRNO(0);
 }

 TEST_F(LlvmLibcExpm1fTest, InFloatRange) {
   constexpr uint32_t COUNT = 100'000;
   constexpr uint32_t STEP = UINT32_MAX / COUNT;
   for (uint32_t i = 0, v = 0; i <= COUNT; ++i, v += STEP) {
     float x = FPBits(v).get_val();
     if (isnan(x) || isinf(x))
       continue;
     LIBC_NAMESPACE::libc_errno = 0;
     float result = LIBC_NAMESPACE::expm1f(x);

     // If the computation resulted in an error or did not produce valid result
     // in the single-precision floating point range, then ignore comparing with
     // MPFR result as MPFR can still produce valid results because of its
     // wider precision.
     if (isnan(result) || isinf(result) || LIBC_NAMESPACE::libc_errno != 0)
       continue;
     ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
                                    LIBC_NAMESPACE::expm1f(x), 0.5);
   }
 }
	//===-- Unittests for expm1f-----------------------------------------------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//

	#include "hdr/math_macros.h"
	#include "src/__support/FPUtil/FPBits.h"
	#include "src/errno/libc_errno.h"
	#include "src/math/expm1f.h"
	#include "test/UnitTest/FPMatcher.h"
	#include "test/UnitTest/Test.h"
	#include "utils/MPFRWrapper/MPFRUtils.h"

	#include <stdint.h>

	using LlvmLibcExpm1fTest = LIBC_NAMESPACE::testing::FPTest<float>;

	namespace mpfr = LIBC_NAMESPACE::testing::mpfr;

	TEST_F(LlvmLibcExpm1fTest, SpecialNumbers) {
	LIBC_NAMESPACE::libc_errno = 0;

	EXPECT_FP_EQ(aNaN, LIBC_NAMESPACE::expm1f(aNaN));
	EXPECT_MATH_ERRNO(0);

	EXPECT_FP_EQ(inf, LIBC_NAMESPACE::expm1f(inf));
	EXPECT_MATH_ERRNO(0);

	EXPECT_FP_EQ(-1.0f, LIBC_NAMESPACE::expm1f(neg_inf));
	EXPECT_MATH_ERRNO(0);

	EXPECT_FP_EQ(0.0f, LIBC_NAMESPACE::expm1f(0.0f));
	EXPECT_MATH_ERRNO(0);

	EXPECT_FP_EQ(-0.0f, LIBC_NAMESPACE::expm1f(-0.0f));
	EXPECT_MATH_ERRNO(0);
	}

	TEST_F(LlvmLibcExpm1fTest, Overflow) {
	LIBC_NAMESPACE::libc_errno = 0;
	EXPECT_FP_EQ_WITH_EXCEPTION(
	inf, LIBC_NAMESPACE::expm1f(FPBits(0x7f7fffffU).get_val()), FE_OVERFLOW);
	EXPECT_MATH_ERRNO(ERANGE);

	EXPECT_FP_EQ_WITH_EXCEPTION(
	inf, LIBC_NAMESPACE::expm1f(FPBits(0x42cffff8U).get_val()), FE_OVERFLOW);
	EXPECT_MATH_ERRNO(ERANGE);

	EXPECT_FP_EQ_WITH_EXCEPTION(
	inf, LIBC_NAMESPACE::expm1f(FPBits(0x42d00008U).get_val()), FE_OVERFLOW);
	EXPECT_MATH_ERRNO(ERANGE);
	}

	TEST_F(LlvmLibcExpm1fTest, Underflow) {
	LIBC_NAMESPACE::libc_errno = 0;
	EXPECT_FP_EQ(-1.0f, LIBC_NAMESPACE::expm1f(FPBits(0xff7fffffU).get_val()));

	float x = FPBits(0xc2cffff8U).get_val();
	EXPECT_FP_EQ(-1.0f, LIBC_NAMESPACE::expm1f(x));

	x = FPBits(0xc2d00008U).get_val();
	EXPECT_FP_EQ(-1.0f, LIBC_NAMESPACE::expm1f(x));
	}

	// Test with inputs which are the borders of underflow/overflow but still
	// produce valid results without setting errno.
	TEST_F(LlvmLibcExpm1fTest, Borderline) {
	float x;

	LIBC_NAMESPACE::libc_errno = 0;
	x = FPBits(0x42affff8U).get_val();
	ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
	LIBC_NAMESPACE::expm1f(x), 0.5);
	EXPECT_MATH_ERRNO(0);

	x = FPBits(0x42b00008U).get_val();
	ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
	LIBC_NAMESPACE::expm1f(x), 0.5);
	EXPECT_MATH_ERRNO(0);

	x = FPBits(0xc2affff8U).get_val();
	ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
	LIBC_NAMESPACE::expm1f(x), 0.5);
	EXPECT_MATH_ERRNO(0);

	x = FPBits(0xc2b00008U).get_val();
	ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
	LIBC_NAMESPACE::expm1f(x), 0.5);
	EXPECT_MATH_ERRNO(0);

	x = FPBits(0x3dc252ddU).get_val();
	ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
	LIBC_NAMESPACE::expm1f(x), 0.5);
	EXPECT_MATH_ERRNO(0);

	x = FPBits(0x3e35bec5U).get_val();
	ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
	LIBC_NAMESPACE::expm1f(x), 0.5);
	EXPECT_MATH_ERRNO(0);

	x = FPBits(0x942ed494U).get_val();
	ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
	LIBC_NAMESPACE::expm1f(x), 0.5);
	EXPECT_MATH_ERRNO(0);

	x = FPBits(0xbdc1c6cbU).get_val();
	ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
	LIBC_NAMESPACE::expm1f(x), 0.5);
	EXPECT_MATH_ERRNO(0);
	}

	TEST_F(LlvmLibcExpm1fTest, InFloatRange) {
	constexpr uint32_t COUNT = 100'000;
	constexpr uint32_t STEP = UINT32_MAX / COUNT;
	for (uint32_t i = 0, v = 0; i <= COUNT; ++i, v += STEP) {
	float x = FPBits(v).get_val();
	if (isnan(x) \|\| isinf(x))
	continue;
	LIBC_NAMESPACE::libc_errno = 0;
	float result = LIBC_NAMESPACE::expm1f(x);

	// If the computation resulted in an error or did not produce valid result
	// in the single-precision floating point range, then ignore comparing with
	// MPFR result as MPFR can still produce valid results because of its
	// wider precision.
	if (isnan(result) \|\| isinf(result) \|\| LIBC_NAMESPACE::libc_errno != 0)
	continue;
	ASSERT_MPFR_MATCH_ALL_ROUNDING(mpfr::Operation::Expm1, x,
	LIBC_NAMESPACE::expm1f(x), 0.5);
	}
	}