/* * Copyright (c) 2017-2023 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 ACL_SUPPORT_TOOLCHAINSUPPORT_H #define ACL_SUPPORT_TOOLCHAINSUPPORT_H #include "support/Bfloat16.h" #include "support/Half.h" #include #include #include #include #include #include #include #include #ifndef M_PI #define M_PI (3.14159265358979323846) #endif // M_PI namespace arm_compute { #ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC typedef __fp16 float16_t; #endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC namespace support { namespace cpp11 { #if (__ANDROID__ || BARE_METAL) template inline T nearbyint(T value) { return static_cast(::nearbyint(value)); } /** Round floating-point value with half value rounding away from zero. * * @note This function implements the same behaviour as std::round except that it doesn't * support Integral type. The latter is not in the namespace std in some Android toolchains. * * @param[in] value floating-point value to be rounded. * * @return Floating-point value of rounded @p value. */ template ::value>::type> inline T round(T value) { return ::round(value); } /** Round floating-point value with half value rounding away from zero and cast to long * * @note This function implements the same behaviour as std::lround except that it doesn't * support Integral type. The latter is not in the namespace std in some Android toolchains. * * @param[in] value floating-point value to be rounded. * * @return Floating-point value of rounded @p value casted to long */ template ::value>::type> inline long lround(T value) { return ::lround(value); } /** Truncate floating-point value. * * @note This function implements the same behaviour as std::truncate except that it doesn't * support Integral type. The latter is not in the namespace std in some Android toolchains. * * @param[in] value floating-point value to be truncated. * * @return Floating-point value of truncated @p value. */ template ::value>::type> inline T trunc(T value) { return ::trunc(value); } /** Composes a floating point value with the magnitude of @p x and the sign of @p y. * * @note This function implements the same behaviour as std::copysign except that it doesn't * support Integral type. The latter is not in the namespace std in some Android toolchains. * * @param[in] x value that contains the magnitude to be used in constructing the result. * @param[in] y value that contains the sign to be used in construct in the result. * * @return Floating-point value with magnitude of @p x and sign of @p y. */ template ::value>::type> inline T copysign(T x, T y) { return ::copysign(x, y); } /** Computes (x*y) + z as if to infinite precision and rounded only once to fit the result type. * * @note This function implements the same behaviour as std::fma except that it doesn't * support Integral type. The latter is not in the namespace std in some Android toolchains. * * @param[in] x floating-point value * @param[in] y floating-point value * @param[in] z floating-point value * * @return Result floating point value equal to (x*y) + z.c */ template ::value #ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC || std::is_same::value #endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC >::type> inline T fma(T x, T y, T z) { return ::fma(x, y, z); } /** Loads the data from the given location, converts them to character string equivalents * and writes the result to a character string buffer. * * @param[in] s Pointer to a character string to write to * @param[in] n Up to buf_size - 1 characters may be written, plus the null ending character * @param[in] fmt Pointer to a null-ended multibyte string specifying how to interpret the data. * @param[in] args Arguments forwarded to snprintf. * * @return Number of characters that would have been written for a sufficiently large buffer * if successful (not including the ending null character), or a negative value if an error occurred. */ template inline int snprintf(char *s, size_t n, const char *fmt, Ts &&...args) { return ::snprintf(s, n, fmt, std::forward(args)...); } #else /* (__ANDROID__ || BARE_METAL) */ /** Rounds the floating-point argument arg to an integer value in floating-point format, using the current rounding mode. * * @note This function acts as a convenience wrapper around std::nearbyint. The * latter is missing in some Android toolchains. * * @param[in] value Value to be rounded. * * @return The rounded value. */ template inline T nearbyint(T value) { return static_cast(std::nearbyint(value)); } /** Round floating-point value with half value rounding away from zero. * * @note This function implements the same behaviour as std::round except that it doesn't * support Integral type. The latter is not in the namespace std in some Android toolchains. * * @param[in] value floating-point value to be rounded. * * @return Floating-point value of rounded @p value. */ template ::value>::type> inline T round(T value) { return std::round(value); } /** Round floating-point value with half value rounding away from zero and cast to long * * @note This function implements the same behaviour as std::lround except that it doesn't * support Integral type. The latter is not in the namespace std in some Android toolchains. * * @param[in] value floating-point value to be rounded. * * @return Floating-point value of rounded @p value casted to long */ template ::value>::type> inline long lround(T value) { return std::lround(value); } /** Truncate floating-point value. * * @note This function implements the same behaviour as std::truncate except that it doesn't * support Integral type. The latter is not in the namespace std in some Android toolchains. * * @param[in] value floating-point value to be truncated. * * @return Floating-point value of truncated @p value. */ template ::value>::type> inline T trunc(T value) { return std::trunc(value); } /** Composes a floating point value with the magnitude of @p x and the sign of @p y. * * @note This function implements the same behaviour as std::copysign except that it doesn't * support Integral type. The latter is not in the namespace std in some Android toolchains. * * @param[in] x value that contains the magnitude to be used in constructing the result. * @param[in] y value that contains the sign to be used in construct in the result. * * @return Floating-point value with magnitude of @p x and sign of @p y. */ template ::value>::type> inline T copysign(T x, T y) { return std::copysign(x, y); } /** Computes (x*y) + z as if to infinite precision and rounded only once to fit the result type. * * @note This function implements the same behaviour as std::fma except that it doesn't * support Integral type. The latter is not in the namespace std in some Android toolchains. * * @param[in] x floating-point value * @param[in] y floating-point value * @param[in] z floating-point value * * @return Result floating point value equal to (x*y) + z. */ template ::value #ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC || std::is_same::value #endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC >::type> inline T fma(T x, T y, T z) { return std::fma(x, y, z); } /** Loads the data from the given location, converts them to character string equivalents * and writes the result to a character string buffer. * * @param[in] s Pointer to a character string to write to * @param[in] n Up to buf_size - 1 characters may be written, plus the null ending character * @param[in] fmt Pointer to a null-ended multibyte string specifying how to interpret the data. * @param[in] args Arguments forwarded to std::snprintf. * * @return Number of characters that would have been written for a sufficiently large buffer * if successful (not including the ending null character), or a negative value if an error occurred. */ template inline int snprintf(char *s, std::size_t n, const char *fmt, Ts &&...args) { return std::snprintf(s, n, fmt, std::forward(args)...); } #endif /* (__ANDROID__ || BARE_METAL) */ // std::numeric_limits::lowest template inline T lowest() { return std::numeric_limits::lowest(); } #ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC template <> inline __fp16 lowest<__fp16>() { return std::numeric_limits::lowest(); } #endif /* __ARM_FEATURE_FP16_VECTOR_ARITHMETIC */ template <> inline bfloat16 lowest() { return bfloat16::lowest(); } // std::isfinite template ::value>::type> inline bool isfinite(T value) { return std::isfinite(static_cast(value)); } inline bool isfinite(half_float::half value) { return half_float::isfinite(value); } inline bool isfinite(bfloat16 value) { return std::isfinite(float(value)); } // std::signbit template ::value>::type> inline bool signbit(T value) { return std::signbit(static_cast(value)); } inline bool signbit(half_float::half value) { return half_float::signbit(value); } inline bool signbit(bfloat16 value) { return std::signbit(float(value)); } } // namespace cpp11 } // namespace support } // namespace arm_compute #endif // ACL_SUPPORT_TOOLCHAINSUPPORT_H