/*************************************************************************************************** * Copyright (c) 2017 - 2025 NVIDIA CORPORATION & AFFILIATES. All rights reserved. * SPDX-License-Identifier: BSD-3-Clause * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * 3. Neither the name of the copyright holder nor the names of its * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * **************************************************************************************************/ /*! \file \brief Defines a proxy class for storing Tensor Float 32 data type. */ #pragma once #if defined(__CUDACC_RTC__) #include "cutlass/floating_point_nvrtc.h" #else #include #include #include #include // std::memcpy #endif #include "cutlass/cutlass.h" namespace cutlass { /////////////////////////////////////////////////////////////////////////////////////////////////// /// Tensor Float 32 data type struct alignas(4) tfloat32_t { // // Data members // /// Storage type uint32_t storage; // // Methods // private: CUTLASS_HOST_DEVICE static uint32_t float_to_storage(float s) { #if defined(__CUDA_ARCH__) uint32_t result = reinterpret_cast(s); #else uint32_t result; std::memcpy(&result, &s, sizeof(float)); #endif return result; } public: /// Constructs from an unsigned int CUTLASS_HOST_DEVICE static tfloat32_t bitcast(uint32_t x) { tfloat32_t h; h.storage = x; return h; } /// Emulated rounding is fast in device code CUTLASS_HOST_DEVICE static tfloat32_t round_half_ulp_truncate(float const &s) { uint32_t x = float_to_storage(s); #if defined(__CUDA_ARCH__) if (::isfinite(s)) { x += 0x1000u; } #else if (std::isfinite(s)) { x += 0x1000u; } #endif return tfloat32_t::bitcast(x); } tfloat32_t() = default; /// Floating-point conversion - round toward nearest even CUTLASS_HOST_DEVICE explicit tfloat32_t(float x): storage(round_half_ulp_truncate(x).raw()) { } // Conversion from double (this rounds twice) CUTLASS_HOST_DEVICE explicit tfloat32_t(double x): tfloat32_t(float(x)) { } /// Integer conversion - round toward zero CUTLASS_HOST_DEVICE explicit tfloat32_t(int x) { float flt = static_cast(x); #if defined(__CUDA_ARCH__) storage = reinterpret_cast(flt); #else std::memcpy(&storage, &flt, sizeof(storage)); #endif } // Conversion to float CUTLASS_HOST_DEVICE operator float() const { // Conversions to IEEE single-precision requires clearing dont-care bits // of the mantissa. unsigned bits = (storage & ~0x1fffu); #if defined(__CUDA_ARCH__) return reinterpret_cast(bits); #else float flt; std::memcpy(&flt, &bits, sizeof(flt)); return flt; #endif } /// Converts to double CUTLASS_HOST_DEVICE explicit operator double() const { return double(float(*this)); } /// Converts to int CUTLASS_HOST_DEVICE explicit operator int() const { return int(float(*this)); } /// Casts to bool CUTLASS_HOST_DEVICE explicit operator bool() const { return (float(*this) != 0.0f); } /// Obtains raw bits CUTLASS_HOST_DEVICE uint32_t raw() const { return storage; } /// Returns the sign bit CUTLASS_HOST_DEVICE bool signbit() const { return ((raw() & 0x80000000) != 0); } /// Returns the biased exponent CUTLASS_HOST_DEVICE int exponent_biased() const { return int((raw() >> 23) & 0x0ff); } /// Returns the unbiased exponent CUTLASS_HOST_DEVICE int exponent() const { return exponent_biased() - 127; } /// Returns the mantissa CUTLASS_HOST_DEVICE int mantissa() const { return int(raw() & 0x7fffff); } }; /////////////////////////////////////////////////////////////////////////////////////////////////// CUTLASS_HOST_DEVICE bool signbit(cutlass::tfloat32_t const& h) { return h.signbit(); } CUTLASS_HOST_DEVICE cutlass::tfloat32_t abs(cutlass::tfloat32_t const& h) { return cutlass::tfloat32_t::bitcast(h.raw() & 0x7fffffff); } CUTLASS_HOST_DEVICE bool isnan(cutlass::tfloat32_t const& h) { return (h.exponent_biased() == 0x0ff) && h.mantissa(); } CUTLASS_HOST_DEVICE bool isfinite(cutlass::tfloat32_t const& h) { return (h.exponent_biased() != 0x0ff); } CUTLASS_HOST_DEVICE cutlass::tfloat32_t nan_tf32(const char*) { // NVIDIA canonical NaN return cutlass::tfloat32_t::bitcast(0x7fffffff); } CUTLASS_HOST_DEVICE bool isinf(cutlass::tfloat32_t const& h) { return (h.exponent_biased() == 0x0ff) && !h.mantissa(); } CUTLASS_HOST_DEVICE bool isnormal(cutlass::tfloat32_t const& h) { return h.exponent_biased() && h.exponent_biased() != 0x0ff; } CUTLASS_HOST_DEVICE int fpclassify(cutlass::tfloat32_t const& h) { int exp = h.exponent_biased(); int mantissa = h.mantissa(); if (exp == 0x0ff) { if (mantissa) { return FP_NAN; } else { return FP_INFINITE; } } else if (!exp) { if (mantissa) { return FP_SUBNORMAL; } else { return FP_ZERO; } } return FP_NORMAL; } CUTLASS_HOST_DEVICE cutlass::tfloat32_t sqrt(cutlass::tfloat32_t const& h) { #if defined(__CUDACC_RTC__) return cutlass::tfloat32_t(sqrtf(float(h))); #else return cutlass::tfloat32_t(std::sqrt(float(h))); #endif } CUTLASS_HOST_DEVICE tfloat32_t copysign(tfloat32_t const& a, tfloat32_t const& b) { uint32_t a_mag = (a.raw() & 0x7fffffff); uint32_t b_sign = (b.raw() & 0x80000000); uint32_t result = (a_mag | b_sign); return tfloat32_t::bitcast(result); } /////////////////////////////////////////////////////////////////////////////////////////////////// } // namespace cutlass /////////////////////////////////////////////////////////////////////////////////////////////////// // // Standard Library operations and definitions // /////////////////////////////////////////////////////////////////////////////////////////////////// namespace std { #if !defined(__CUDACC_RTC__) /// Numeric limits template <> struct numeric_limits { static bool const is_specialized = true; static bool const is_signed = true; static bool const is_integer = false; static bool const is_exact = false; static bool const has_infinity = true; static bool const has_quiet_NaN = true; static bool const has_signaling_NaN = false; static std::float_denorm_style const has_denorm = std::denorm_present; static bool const has_denorm_loss = true; static std::float_round_style const round_style = std::round_to_nearest; static bool const is_iec559 = false; static bool const is_bounded = true; static bool const is_modulo = false; static int const digits = 19; /// Least positive value static cutlass::tfloat32_t min() { return cutlass::tfloat32_t::bitcast(0x01); } /// Minimum finite value static cutlass::tfloat32_t lowest() { return cutlass::tfloat32_t::bitcast(0xff7fffff); } /// Maximum finite value static cutlass::tfloat32_t max() { return cutlass::tfloat32_t::bitcast(0x7f7fffff); } /// Returns smallest finite value static cutlass::tfloat32_t epsilon() { return cutlass::tfloat32_t::bitcast(0x1000); } /// Returns smallest finite value static cutlass::tfloat32_t round_error() { return cutlass::tfloat32_t(0.5f); } /// Returns smallest finite value static cutlass::tfloat32_t infinity() { return cutlass::tfloat32_t::bitcast(0x7f800000); } /// Returns smallest finite value static cutlass::tfloat32_t quiet_NaN() { return cutlass::tfloat32_t::bitcast(0x7fffffff); } /// Returns smallest finite value static cutlass::tfloat32_t signaling_NaN() { return cutlass::tfloat32_t::bitcast(0x7fffffff); } /// Returns smallest finite value static cutlass::tfloat32_t denorm_min() { return cutlass::tfloat32_t::bitcast(0x1); } }; #endif /////////////////////////////////////////////////////////////////////////////////////////////////// } // namespace std /////////////////////////////////////////////////////////////////////////////////////////////////// // // Arithmetic operators // /////////////////////////////////////////////////////////////////////////////////////////////////// namespace cutlass { /////////////////////////////////////////////////////////////////////////////////////////////////// CUTLASS_HOST_DEVICE bool operator==(tfloat32_t const& lhs, tfloat32_t const& rhs) { return float(lhs) == float(rhs); } CUTLASS_HOST_DEVICE bool operator!=(tfloat32_t const& lhs, tfloat32_t const& rhs) { return float(lhs) != float(rhs); } CUTLASS_HOST_DEVICE bool operator<(tfloat32_t const& lhs, tfloat32_t const& rhs) { return float(lhs) < float(rhs); } CUTLASS_HOST_DEVICE bool operator<=(tfloat32_t const& lhs, tfloat32_t const& rhs) { return float(lhs) <= float(rhs); } CUTLASS_HOST_DEVICE bool operator>(tfloat32_t const& lhs, tfloat32_t const& rhs) { return float(lhs) > float(rhs); } CUTLASS_HOST_DEVICE bool operator>=(tfloat32_t const& lhs, tfloat32_t const& rhs) { return float(lhs) >= float(rhs); } CUTLASS_HOST_DEVICE tfloat32_t operator+(tfloat32_t const& lhs, tfloat32_t const& rhs) { return tfloat32_t(float(lhs) + float(rhs)); } CUTLASS_HOST_DEVICE tfloat32_t operator-(tfloat32_t const& lhs) { return tfloat32_t::bitcast(0x80000000 ^ lhs.raw()); } CUTLASS_HOST_DEVICE tfloat32_t operator-(tfloat32_t const& lhs, tfloat32_t const& rhs) { return tfloat32_t(float(lhs) - float(rhs)); } CUTLASS_HOST_DEVICE tfloat32_t operator*(tfloat32_t const& lhs, tfloat32_t const& rhs) { return tfloat32_t(float(lhs) * float(rhs)); } CUTLASS_HOST_DEVICE tfloat32_t operator/(tfloat32_t const& lhs, tfloat32_t const& rhs) { return tfloat32_t(float(lhs) / float(rhs)); } CUTLASS_HOST_DEVICE tfloat32_t& operator+=(tfloat32_t & lhs, tfloat32_t const& rhs) { lhs = tfloat32_t(float(lhs) + float(rhs)); return lhs; } CUTLASS_HOST_DEVICE tfloat32_t& operator-=(tfloat32_t & lhs, tfloat32_t const& rhs) { lhs = tfloat32_t(float(lhs) - float(rhs)); return lhs; } CUTLASS_HOST_DEVICE tfloat32_t& operator*=(tfloat32_t & lhs, tfloat32_t const& rhs) { lhs = tfloat32_t(float(lhs) * float(rhs)); return lhs; } CUTLASS_HOST_DEVICE tfloat32_t& operator/=(tfloat32_t & lhs, tfloat32_t const& rhs) { lhs = tfloat32_t(float(lhs) / float(rhs)); return lhs; } CUTLASS_HOST_DEVICE tfloat32_t& operator++(tfloat32_t & lhs) { float tmp(lhs); ++tmp; lhs = tfloat32_t(tmp); return lhs; } CUTLASS_HOST_DEVICE tfloat32_t& operator--(tfloat32_t & lhs) { float tmp(lhs); --tmp; lhs = tfloat32_t(tmp); return lhs; } CUTLASS_HOST_DEVICE tfloat32_t operator++(tfloat32_t & lhs, int) { tfloat32_t ret(lhs); float tmp(lhs); tmp++; lhs = tfloat32_t(tmp); return ret; } CUTLASS_HOST_DEVICE tfloat32_t operator--(tfloat32_t & lhs, int) { tfloat32_t ret(lhs); float tmp(lhs); tmp--; lhs = tfloat32_t(tmp); return ret; } /////////////////////////////////////////////////////////////////////////////////////////////////// } // namespace cutlass /////////////////////////////////////////////////////////////////////////////////////////////////// // // User-defined literals // CUTLASS_HOST_DEVICE cutlass::tfloat32_t operator "" _tf32(long double x) { return cutlass::tfloat32_t(float(x)); } CUTLASS_HOST_DEVICE cutlass::tfloat32_t operator "" _tf32(unsigned long long int x) { return cutlass::tfloat32_t(int(x)); } /////////////////////////////////////////////////////////////////////////////////////////////////