//===-- 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 "utils/FPUtil/FPBits.h" #include "utils/FPUtil/TestHelpers.h" #include "utils/MPFRWrapper/MPFRUtils.h" #include "utils/UnitTest/Test.h" #include "utils/testutils/RandUtils.h" namespace mpfr = __llvm_libc::testing::mpfr; template class FmaTestTemplate : public __llvm_libc::testing::Test { private: using Func = T (*)(T, T, T); using FPBits = __llvm_libc::fputil::FPBits; using UIntType = typename FPBits::UIntType; const T nan = T(__llvm_libc::fputil::FPBits::buildNaN(1)); const T inf = T(__llvm_libc::fputil::FPBits::inf()); const T negInf = T(__llvm_libc::fputil::FPBits::negInf()); const T zero = T(__llvm_libc::fputil::FPBits::zero()); const T negZero = T(__llvm_libc::fputil::FPBits::negZero()); UIntType getRandomBitPattern() { UIntType bits{0}; for (UIntType i = 0; i < sizeof(UIntType) / 2; ++i) { bits = (bits << 2) + static_cast(__llvm_libc::testutils::rand()); } return bits; } public: void testSpecialNumbers(Func func) { EXPECT_FP_EQ(func(zero, zero, zero), zero); EXPECT_FP_EQ(func(zero, negZero, negZero), negZero); EXPECT_FP_EQ(func(inf, inf, zero), inf); EXPECT_FP_EQ(func(negInf, inf, negInf), negInf); EXPECT_FP_EQ(func(inf, zero, zero), nan); EXPECT_FP_EQ(func(inf, negInf, inf), nan); EXPECT_FP_EQ(func(nan, zero, inf), nan); EXPECT_FP_EQ(func(inf, negInf, nan), nan); // Test underflow rounding up. EXPECT_FP_EQ(func(T(0.5), T(FPBits(FPBits::minSubnormal)), T(FPBits(FPBits::minSubnormal))), T(FPBits(UIntType(2)))); // Test underflow rounding down. T v = T(FPBits(FPBits::minNormal + UIntType(1))); EXPECT_FP_EQ( func(T(1) / T(FPBits::minNormal << 1), v, T(FPBits(FPBits::minNormal))), v); // Test overflow. T z = T(FPBits(FPBits::maxNormal)); EXPECT_FP_EQ(func(T(1.75), z, -z), T(0.75) * z); } void testSubnormalRange(Func 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 = T(FPBits(getRandomBitPattern())), y = T(FPBits(v)), z = T(FPBits(w)); T result = func(x, y, z); mpfr::TernaryInput input{x, y, z}; ASSERT_MPFR_MATCH(mpfr::Operation::Fma, input, result, 0.5); } } void testNormalRange(Func 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 = T(FPBits(v)), y = T(FPBits(w)), z = T(FPBits(getRandomBitPattern())); T result = func(x, y, z); mpfr::TernaryInput input{x, y, z}; ASSERT_MPFR_MATCH(mpfr::Operation::Fma, input, result, 0.5); } } }; #endif // LLVM_LIBC_TEST_SRC_MATH_FMATEST_H