//===-- Add and subtract IEEE 754 floating-point numbers --------*- 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_SRC___SUPPORT_FPUTIL_GENERIC_ADD_SUB_H #define LLVM_LIBC_SRC___SUPPORT_FPUTIL_GENERIC_ADD_SUB_H #include "hdr/errno_macros.h" #include "hdr/fenv_macros.h" #include "src/__support/CPP/algorithm.h" #include "src/__support/CPP/bit.h" #include "src/__support/CPP/type_traits.h" #include "src/__support/FPUtil/BasicOperations.h" #include "src/__support/FPUtil/FEnvImpl.h" #include "src/__support/FPUtil/FPBits.h" #include "src/__support/FPUtil/cast.h" #include "src/__support/FPUtil/dyadic_float.h" #include "src/__support/FPUtil/rounding_mode.h" #include "src/__support/macros/attributes.h" #include "src/__support/macros/config.h" #include "src/__support/macros/optimization.h" namespace LIBC_NAMESPACE_DECL { namespace fputil::generic { template LIBC_INLINE cpp::enable_if_t && cpp::is_floating_point_v && sizeof(OutType) <= sizeof(InType), OutType> add_or_sub(InType x, InType y) { using OutFPBits = FPBits; using OutStorageType = typename OutFPBits::StorageType; using InFPBits = FPBits; using InStorageType = typename InFPBits::StorageType; constexpr int GUARD_BITS_LEN = 3; constexpr int RESULT_FRACTION_LEN = InFPBits::FRACTION_LEN + GUARD_BITS_LEN; constexpr int RESULT_MANTISSA_LEN = RESULT_FRACTION_LEN + 1; using DyadicFloat = DyadicFloat(RESULT_MANTISSA_LEN))>; InFPBits x_bits(x); InFPBits y_bits(y); bool is_effectively_add = (x_bits.sign() == y_bits.sign()) != IsSub; if (LIBC_UNLIKELY(x_bits.is_inf_or_nan() || y_bits.is_inf_or_nan() || x_bits.is_zero() || y_bits.is_zero())) { if (x_bits.is_nan() || y_bits.is_nan()) { if (x_bits.is_signaling_nan() || y_bits.is_signaling_nan()) raise_except_if_required(FE_INVALID); if (x_bits.is_quiet_nan()) { InStorageType x_payload = x_bits.get_mantissa(); x_payload >>= InFPBits::FRACTION_LEN - OutFPBits::FRACTION_LEN; return OutFPBits::quiet_nan(x_bits.sign(), static_cast(x_payload)) .get_val(); } if (y_bits.is_quiet_nan()) { InStorageType y_payload = y_bits.get_mantissa(); y_payload >>= InFPBits::FRACTION_LEN - OutFPBits::FRACTION_LEN; return OutFPBits::quiet_nan(y_bits.sign(), static_cast(y_payload)) .get_val(); } return OutFPBits::quiet_nan().get_val(); } if (x_bits.is_inf()) { if (y_bits.is_inf()) { if (!is_effectively_add) { raise_except_if_required(FE_INVALID); return OutFPBits::quiet_nan().get_val(); } return OutFPBits::inf(x_bits.sign()).get_val(); } return OutFPBits::inf(x_bits.sign()).get_val(); } if (y_bits.is_inf()) return OutFPBits::inf(y_bits.sign()).get_val(); if (x_bits.is_zero()) { if (y_bits.is_zero()) { switch (quick_get_round()) { case FE_DOWNWARD: return OutFPBits::zero(Sign::NEG).get_val(); default: return OutFPBits::zero(Sign::POS).get_val(); } } // volatile prevents Clang from converting tmp to OutType and then // immediately back to InType before negating it, resulting in double // rounding. volatile InType tmp = y; if constexpr (IsSub) tmp = -tmp; return cast(tmp); } if (y_bits.is_zero()) { volatile InType tmp = y; if constexpr (IsSub) tmp = -tmp; return cast(tmp); } } InType x_abs = x_bits.abs().get_val(); InType y_abs = y_bits.abs().get_val(); if (x_abs == y_abs && !is_effectively_add) { switch (quick_get_round()) { case FE_DOWNWARD: return OutFPBits::zero(Sign::NEG).get_val(); default: return OutFPBits::zero(Sign::POS).get_val(); } } Sign result_sign = Sign::POS; if (x_abs > y_abs) { result_sign = x_bits.sign(); } else if (x_abs < y_abs) { if (is_effectively_add) result_sign = y_bits.sign(); else if (y_bits.is_pos()) result_sign = Sign::NEG; } else if (is_effectively_add) { result_sign = x_bits.sign(); } InFPBits max_bits(cpp::max(x_abs, y_abs)); InFPBits min_bits(cpp::min(x_abs, y_abs)); InStorageType result_mant; if (max_bits.is_subnormal()) { // min_bits must be subnormal too. if (is_effectively_add) result_mant = max_bits.get_mantissa() + min_bits.get_mantissa(); else result_mant = max_bits.get_mantissa() - min_bits.get_mantissa(); result_mant <<= GUARD_BITS_LEN; } else { InStorageType max_mant = max_bits.get_explicit_mantissa() << GUARD_BITS_LEN; InStorageType min_mant = min_bits.get_explicit_mantissa() << GUARD_BITS_LEN; int alignment = max_bits.get_biased_exponent() - min_bits.get_biased_exponent(); InStorageType aligned_min_mant = min_mant >> cpp::min(alignment, RESULT_MANTISSA_LEN); bool aligned_min_mant_sticky; if (alignment <= 3) aligned_min_mant_sticky = false; else if (alignment <= InFPBits::FRACTION_LEN + 3) aligned_min_mant_sticky = (min_mant << (InFPBits::STORAGE_LEN - alignment)) != 0; else aligned_min_mant_sticky = true; InStorageType min_mant_sticky(static_cast(aligned_min_mant_sticky)); if (is_effectively_add) result_mant = max_mant + (aligned_min_mant | min_mant_sticky); else result_mant = max_mant - (aligned_min_mant | min_mant_sticky); } int result_exp = max_bits.get_exponent() - RESULT_FRACTION_LEN; DyadicFloat result(result_sign, result_exp, result_mant); return result.template as(); } template LIBC_INLINE cpp::enable_if_t && cpp::is_floating_point_v && sizeof(OutType) <= sizeof(InType), OutType> add(InType x, InType y) { return add_or_sub(x, y); } template LIBC_INLINE cpp::enable_if_t && cpp::is_floating_point_v && sizeof(OutType) <= sizeof(InType), OutType> sub(InType x, InType y) { return add_or_sub(x, y); } } // namespace fputil::generic } // namespace LIBC_NAMESPACE_DECL #endif // LLVM_LIBC_SRC___SUPPORT_FPUTIL_GENERIC_ADD_SUB_H