/* * Copyright (c) 2018-2021, 2023 Arm Limited. * * SPDX-License-Identifier: MIT * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to * deal in the Software without restriction, including without limitation the * rights to use, copy, modify, merge, publish, distribute, sublicense, and/or * sell copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in all * copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. */ #ifndef ARM_COMPUTE_UTILS_ROUNDING_H #define ARM_COMPUTE_UTILS_ROUNDING_H #include "arm_compute/core/Error.h" #include "arm_compute/core/utils/misc/Traits.h" #include "support/AclRequires.h" #include "support/ToolchainSupport.h" #include namespace arm_compute { namespace utils { namespace rounding { /** Rounding mode */ enum class RoundingMode { TO_ZERO, /**< Round towards zero */ AWAY_FROM_ZERO, /**< Round away from zero */ HALF_TO_ZERO, /**< Round half towards from zero */ HALF_AWAY_FROM_ZERO, /**< Round half away from zero */ HALF_UP, /**< Round half towards positive infinity */ HALF_DOWN, /**< Round half towards negative infinity */ HALF_EVEN /**< Round half towards nearest even */ }; /** Round floating-point value with round to zero * * @tparam T Parameter type. Should be of floating point type. * * @param[in] value floating-point value to be rounded. * * @return Floating-point value of rounded @p value. */ template ::value)> inline T round_to_zero(T value) { T res = std::floor(std::fabs(value)); return (value < 0.f) ? -res : res; } /** Round floating-point value with round away from zero * * @tparam T Parameter type. Should be of floating point type. * * @param[in] value floating-point value to be rounded. * * @return Floating-point value of rounded @p value. */ template ::value)> inline T round_away_from_zero(T value) { T res = std::ceil(std::fabs(value)); return (value < 0.f) ? -res : res; } /** Round floating-point value with half value rounding towards zero. * * @tparam T Parameter type. Should be of floating point type. * * @param[in] value floating-point value to be rounded. * * @return Floating-point value of rounded @p value. */ template ::value)> inline T round_half_to_zero(T value) { T res = T(std::ceil(std::fabs(value) - 0.5f)); return (value < 0.f) ? -res : res; } /** Round floating-point value with half value rounding away from zero. * * @tparam T Parameter type. Should be of floating point type. * * @param[in] value floating-point value to be rounded. * * @return Floating-point value of rounded @p value. */ template ::value)> inline T round_half_away_from_zero(T value) { T res = T(std::floor(std::fabs(value) + 0.5f)); return (value < 0.f) ? -res : res; } /** Round floating-point value with half value rounding to positive infinity. * * @tparam T Parameter type. Should be of floating point type. * * @param[in] value floating-point value to be rounded. * * @return Floating-point value of rounded @p value. */ template ::value)> inline T round_half_up(T value) { return std::floor(value + 0.5f); } /** Round floating-point value with half value rounding to negative infinity. * * @tparam T Parameter type. Should be of floating point type. * * @param[in] value floating-point value to be rounded. * * @return Floating-point value of rounded @p value. */ template ::value)> inline T round_half_down(T value) { return std::ceil(value - 0.5f); } /** Round floating-point value with half value rounding to nearest even. * * @tparam T Parameter type. Should be of floating point type. * * @param[in] value floating-point value to be rounded. * @param[in] epsilon precision. * * @return Floating-point value of rounded @p value. */ template ::value)> inline T round_half_even(T value, T epsilon = std::numeric_limits::epsilon()) { T positive_value = std::abs(value); T ipart = 0; std::modf(positive_value, &ipart); // If 'value' is exactly halfway between two integers if (std::abs(positive_value - (ipart + 0.5f)) < epsilon) { // If 'ipart' is even then return 'ipart' if (std::fmod(ipart, 2.f) < epsilon) { return support::cpp11::copysign(ipart, value); } // Else return the nearest even integer return support::cpp11::copysign(std::ceil(ipart + 0.5f), value); } // Otherwise use the usual round to closest return support::cpp11::copysign(support::cpp11::round(positive_value), value); } /** Round floating-point value given a rounding mode * * @tparam T Parameter type. Should be of floating point type. * * @param[in] value floating-point value to be rounded. * @param[in] rounding_mode Rounding mode to use. * * @return Floating-point value of rounded @p value. */ template ::value)> inline T round(T value, RoundingMode rounding_mode) { switch (rounding_mode) { case RoundingMode::TO_ZERO: return round_to_zero(value); case RoundingMode::AWAY_FROM_ZERO: return round_away_from_zero(value); case RoundingMode::HALF_TO_ZERO: return round_half_to_zero(value); case RoundingMode::HALF_AWAY_FROM_ZERO: return round_half_away_from_zero(value); case RoundingMode::HALF_UP: return round_half_up(value); case RoundingMode::HALF_DOWN: return round_half_down(value); case RoundingMode::HALF_EVEN: return round_half_even(value); default: ARM_COMPUTE_ERROR("Unsupported rounding mode!"); } } } // namespace rounding } // namespace utils } // namespace arm_compute #endif /*ARM_COMPUTE_UTILS_ROUNDING_H */