//===-- MPFRUtils.h ---------------------------------------------*- 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_UTILS_TESTUTILS_MPFRUTILS_H #define LLVM_LIBC_UTILS_TESTUTILS_MPFRUTILS_H #include "src/__support/CPP/type_traits.h" #include "test/UnitTest/RoundingModeUtils.h" #include "test/UnitTest/Test.h" #include namespace LIBC_NAMESPACE { namespace testing { namespace mpfr { enum class Operation : int { // Operations with take a single floating point number as input // and produce a single floating point number as output. The input // and output floating point numbers are of the same kind. BeginUnaryOperationsSingleOutput, Abs, Acos, Acosh, Asin, Asinh, Atan, Atanh, Ceil, Cos, Cosh, Erf, Exp, Exp2, Exp10, Expm1, Floor, Log, Log2, Log10, Log1p, Mod2PI, ModPIOver2, ModPIOver4, Round, Sin, Sinh, Sqrt, Tan, Tanh, Trunc, EndUnaryOperationsSingleOutput, // Operations which take a single floating point nubmer as input // but produce two outputs. The first ouput is a floating point // number of the same type as the input. The second output is of type // 'int'. BeginUnaryOperationsTwoOutputs, Frexp, // Floating point output, the first output, is the fractional part. EndUnaryOperationsTwoOutputs, // Operations wich take two floating point nubmers of the same type as // input and produce a single floating point number of the same type as // output. BeginBinaryOperationsSingleOutput, Fmod, Hypot, Pow, EndBinaryOperationsSingleOutput, // Operations which take two floating point numbers of the same type as // input and produce two outputs. The first output is a floating nubmer of // the same type as the inputs. The second output is af type 'int'. BeginBinaryOperationsTwoOutputs, RemQuo, // The first output, the floating point output, is the remainder. EndBinaryOperationsTwoOutputs, // Operations which take three floating point nubmers of the same type as // input and produce a single floating point number of the same type as // output. BeginTernaryOperationsSingleOuput, Fma, EndTernaryOperationsSingleOutput, }; using LIBC_NAMESPACE::fputil::testing::ForceRoundingMode; using LIBC_NAMESPACE::fputil::testing::RoundingMode; template struct BinaryInput { static_assert( LIBC_NAMESPACE::cpp::is_floating_point_v, "Template parameter of BinaryInput must be a floating point type."); using Type = T; T x, y; }; template struct TernaryInput { static_assert( LIBC_NAMESPACE::cpp::is_floating_point_v, "Template parameter of TernaryInput must be a floating point type."); using Type = T; T x, y, z; }; template struct BinaryOutput { T f; int i; }; namespace internal { template struct AreMatchingBinaryInputAndBinaryOutput { static constexpr bool VALUE = false; }; template struct AreMatchingBinaryInputAndBinaryOutput, BinaryOutput> { static constexpr bool VALUE = cpp::is_floating_point_v; }; template bool compare_unary_operation_single_output(Operation op, T input, T libc_output, double ulp_tolerance, RoundingMode rounding); template bool compare_unary_operation_two_outputs(Operation op, T input, const BinaryOutput &libc_output, double ulp_tolerance, RoundingMode rounding); template bool compare_binary_operation_two_outputs(Operation op, const BinaryInput &input, const BinaryOutput &libc_output, double ulp_tolerance, RoundingMode rounding); template bool compare_binary_operation_one_output(Operation op, const BinaryInput &input, T libc_output, double ulp_tolerance, RoundingMode rounding); template bool compare_ternary_operation_one_output(Operation op, const TernaryInput &input, T libc_output, double ulp_tolerance, RoundingMode rounding); template void explain_unary_operation_single_output_error(Operation op, T input, T match_value, double ulp_tolerance, RoundingMode rounding); template void explain_unary_operation_two_outputs_error( Operation op, T input, const BinaryOutput &match_value, double ulp_tolerance, RoundingMode rounding); template void explain_binary_operation_two_outputs_error( Operation op, const BinaryInput &input, const BinaryOutput &match_value, double ulp_tolerance, RoundingMode rounding); template void explain_binary_operation_one_output_error(Operation op, const BinaryInput &input, T match_value, double ulp_tolerance, RoundingMode rounding); template void explain_ternary_operation_one_output_error(Operation op, const TernaryInput &input, T match_value, double ulp_tolerance, RoundingMode rounding); template class MPFRMatcher : public testing::Matcher { InputType input; OutputType match_value; double ulp_tolerance; RoundingMode rounding; public: MPFRMatcher(InputType testInput, double ulp_tolerance, RoundingMode rounding) : input(testInput), ulp_tolerance(ulp_tolerance), rounding(rounding) {} bool match(OutputType libcResult) { match_value = libcResult; return match(input, match_value); } // This method is marked with NOLINT because the name `explainError` does not // conform to the coding style. void explainError() override { // NOLINT explain_error(input, match_value); } // Whether the `explainError` step is skipped or not. bool is_silent() const override { return silent; } private: template bool match(T in, T out) { return compare_unary_operation_single_output(op, in, out, ulp_tolerance, rounding); } template bool match(T in, const BinaryOutput &out) { return compare_unary_operation_two_outputs(op, in, out, ulp_tolerance, rounding); } template bool match(const BinaryInput &in, T out) { return compare_binary_operation_one_output(op, in, out, ulp_tolerance, rounding); } template bool match(BinaryInput in, const BinaryOutput &out) { return compare_binary_operation_two_outputs(op, in, out, ulp_tolerance, rounding); } template bool match(const TernaryInput &in, T out) { return compare_ternary_operation_one_output(op, in, out, ulp_tolerance, rounding); } template void explain_error(T in, T out) { explain_unary_operation_single_output_error(op, in, out, ulp_tolerance, rounding); } template void explain_error(T in, const BinaryOutput &out) { explain_unary_operation_two_outputs_error(op, in, out, ulp_tolerance, rounding); } template void explain_error(const BinaryInput &in, const BinaryOutput &out) { explain_binary_operation_two_outputs_error(op, in, out, ulp_tolerance, rounding); } template void explain_error(const BinaryInput &in, T out) { explain_binary_operation_one_output_error(op, in, out, ulp_tolerance, rounding); } template void explain_error(const TernaryInput &in, T out) { explain_ternary_operation_one_output_error(op, in, out, ulp_tolerance, rounding); } }; } // namespace internal // Return true if the input and ouput types for the operation op are valid // types. template constexpr bool is_valid_operation() { return (Operation::BeginUnaryOperationsSingleOutput < op && op < Operation::EndUnaryOperationsSingleOutput && cpp::is_same_v && cpp::is_floating_point_v) || (Operation::BeginUnaryOperationsTwoOutputs < op && op < Operation::EndUnaryOperationsTwoOutputs && cpp::is_floating_point_v && cpp::is_same_v>) || (Operation::BeginBinaryOperationsSingleOutput < op && op < Operation::EndBinaryOperationsSingleOutput && cpp::is_floating_point_v && cpp::is_same_v>) || (Operation::BeginBinaryOperationsTwoOutputs < op && op < Operation::EndBinaryOperationsTwoOutputs && internal::AreMatchingBinaryInputAndBinaryOutput::VALUE) || (Operation::BeginTernaryOperationsSingleOuput < op && op < Operation::EndTernaryOperationsSingleOutput && cpp::is_floating_point_v && cpp::is_same_v>); } template __attribute__((no_sanitize("address"))) cpp::enable_if_t< is_valid_operation(), internal::MPFRMatcher> get_mpfr_matcher(InputType input, OutputType output_unused, double ulp_tolerance, RoundingMode rounding) { return internal::MPFRMatcher( input, ulp_tolerance, rounding); } template __attribute__((no_sanitize("address"))) cpp::enable_if_t< is_valid_operation(), internal::MPFRMatcher> get_silent_mpfr_matcher(InputType input, OutputType output_unused, double ulp_tolerance, RoundingMode rounding) { return internal::MPFRMatcher( input, ulp_tolerance, rounding); } template T round(T x, RoundingMode mode); template bool round_to_long(T x, long &result); template bool round_to_long(T x, RoundingMode mode, long &result); } // namespace mpfr } // namespace testing } // namespace LIBC_NAMESPACE // GET_MPFR_DUMMY_ARG is going to be added to the end of GET_MPFR_MACRO as a // simple way to avoid the compiler warning `gnu-zero-variadic-macro-arguments`. #define GET_MPFR_DUMMY_ARG(...) 0 #define GET_MPFR_MACRO(__1, __2, __3, __4, __5, __NAME, ...) __NAME #define EXPECT_MPFR_MATCH_DEFAULT(op, input, match_value, ulp_tolerance) \ EXPECT_THAT(match_value, \ LIBC_NAMESPACE::testing::mpfr::get_mpfr_matcher( \ input, match_value, ulp_tolerance, \ LIBC_NAMESPACE::testing::mpfr::RoundingMode::Nearest)) #define EXPECT_MPFR_MATCH_ROUNDING(op, input, match_value, ulp_tolerance, \ rounding) \ EXPECT_THAT(match_value, \ LIBC_NAMESPACE::testing::mpfr::get_mpfr_matcher( \ input, match_value, ulp_tolerance, rounding)) #define EXPECT_MPFR_MATCH(...) \ GET_MPFR_MACRO(__VA_ARGS__, EXPECT_MPFR_MATCH_ROUNDING, \ EXPECT_MPFR_MATCH_DEFAULT, GET_MPFR_DUMMY_ARG) \ (__VA_ARGS__) #define TEST_MPFR_MATCH_ROUNDING(op, input, match_value, ulp_tolerance, \ rounding) \ LIBC_NAMESPACE::testing::mpfr::get_mpfr_matcher(input, match_value, \ ulp_tolerance, rounding) \ .match(match_value) #define TEST_MPFR_MATCH(...) \ GET_MPFR_MACRO(__VA_ARGS__, TEST_MPFR_MATCH_ROUNDING, \ EXPECT_MPFR_MATCH_DEFAULT, GET_MPFR_DUMMY_ARG) \ (__VA_ARGS__) #define EXPECT_MPFR_MATCH_ALL_ROUNDING(op, input, match_value, ulp_tolerance) \ { \ namespace mpfr = LIBC_NAMESPACE::testing::mpfr; \ mpfr::ForceRoundingMode __r1(mpfr::RoundingMode::Nearest); \ if (__r1.success) { \ EXPECT_MPFR_MATCH(op, input, match_value, ulp_tolerance, \ mpfr::RoundingMode::Nearest); \ } \ mpfr::ForceRoundingMode __r2(mpfr::RoundingMode::Upward); \ if (__r2.success) { \ EXPECT_MPFR_MATCH(op, input, match_value, ulp_tolerance, \ mpfr::RoundingMode::Upward); \ } \ mpfr::ForceRoundingMode __r3(mpfr::RoundingMode::Downward); \ if (__r3.success) { \ EXPECT_MPFR_MATCH(op, input, match_value, ulp_tolerance, \ mpfr::RoundingMode::Downward); \ } \ mpfr::ForceRoundingMode __r4(mpfr::RoundingMode::TowardZero); \ if (__r4.success) { \ EXPECT_MPFR_MATCH(op, input, match_value, ulp_tolerance, \ mpfr::RoundingMode::TowardZero); \ } \ } #define TEST_MPFR_MATCH_ROUNDING_SILENTLY(op, input, match_value, \ ulp_tolerance, rounding) \ LIBC_NAMESPACE::testing::mpfr::get_silent_mpfr_matcher( \ input, match_value, ulp_tolerance, rounding) \ .match(match_value) #define ASSERT_MPFR_MATCH_DEFAULT(op, input, match_value, ulp_tolerance) \ ASSERT_THAT(match_value, \ LIBC_NAMESPACE::testing::mpfr::get_mpfr_matcher( \ input, match_value, ulp_tolerance, \ LIBC_NAMESPACE::testing::mpfr::RoundingMode::Nearest)) #define ASSERT_MPFR_MATCH_ROUNDING(op, input, match_value, ulp_tolerance, \ rounding) \ ASSERT_THAT(match_value, \ LIBC_NAMESPACE::testing::mpfr::get_mpfr_matcher( \ input, match_value, ulp_tolerance, rounding)) #define ASSERT_MPFR_MATCH(...) \ GET_MPFR_MACRO(__VA_ARGS__, ASSERT_MPFR_MATCH_ROUNDING, \ ASSERT_MPFR_MATCH_DEFAULT, GET_MPFR_DUMMY_ARG) \ (__VA_ARGS__) #define ASSERT_MPFR_MATCH_ALL_ROUNDING(op, input, match_value, ulp_tolerance) \ { \ namespace mpfr = LIBC_NAMESPACE::testing::mpfr; \ mpfr::ForceRoundingMode __r1(mpfr::RoundingMode::Nearest); \ if (__r1.success) { \ ASSERT_MPFR_MATCH(op, input, match_value, ulp_tolerance, \ mpfr::RoundingMode::Nearest); \ } \ mpfr::ForceRoundingMode __r2(mpfr::RoundingMode::Upward); \ if (__r2.success) { \ ASSERT_MPFR_MATCH(op, input, match_value, ulp_tolerance, \ mpfr::RoundingMode::Upward); \ } \ mpfr::ForceRoundingMode __r3(mpfr::RoundingMode::Downward); \ if (__r3.success) { \ ASSERT_MPFR_MATCH(op, input, match_value, ulp_tolerance, \ mpfr::RoundingMode::Downward); \ } \ mpfr::ForceRoundingMode __r4(mpfr::RoundingMode::TowardZero); \ if (__r4.success) { \ ASSERT_MPFR_MATCH(op, input, match_value, ulp_tolerance, \ mpfr::RoundingMode::TowardZero); \ } \ } #endif // LLVM_LIBC_UTILS_TESTUTILS_MPFRUTILS_H