// Copyright 2020 Google LLC // SPDX-License-Identifier: Apache-2.0 // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #ifndef HIGHWAY_HWY_TARGETS_H_ #define HIGHWAY_HWY_TARGETS_H_ // Allows opting out of C++ standard library usage, which is not available in // some Compiler Explorer environments. #ifndef HWY_NO_LIBCXX #include #endif // For SIMD module implementations and their callers. Defines which targets to // generate and call. #include "hwy/base.h" #include "hwy/detect_targets.h" #include "hwy/highway_export.h" #if !defined(HWY_NO_LIBCXX) #include #endif namespace hwy { // Returns bitfield of enabled targets that are supported on this CPU; there is // always at least one such target, hence the return value is never 0. The // targets returned may change after calling DisableTargets. This function is // always defined, but the HWY_SUPPORTED_TARGETS wrapper may allow eliding // calls to it if there is only a single target enabled. HWY_DLLEXPORT int64_t SupportedTargets(); // Evaluates to a function call, or literal if there is a single target. #if (HWY_TARGETS & (HWY_TARGETS - 1)) == 0 #define HWY_SUPPORTED_TARGETS HWY_TARGETS #else #define HWY_SUPPORTED_TARGETS hwy::SupportedTargets() #endif // Subsequent SupportedTargets will not return targets whose bit(s) are set in // `disabled_targets`. Exception: if SupportedTargets would return 0, it will // instead return HWY_STATIC_TARGET (there must always be one target to call). // // This function is useful for disabling targets known to be buggy, or if the // best available target is undesirable (perhaps due to throttling or memory // bandwidth limitations). Use SetSupportedTargetsForTest instead of this // function for iteratively enabling specific targets for testing. HWY_DLLEXPORT void DisableTargets(int64_t disabled_targets); // Subsequent SupportedTargets will return the given set of targets, except // those disabled via DisableTargets. Call with a mask of 0 to disable the mock // and return to the normal SupportedTargets behavior. Used to run tests for // all targets. HWY_DLLEXPORT void SetSupportedTargetsForTest(int64_t targets); #ifndef HWY_NO_LIBCXX // Return the list of targets in HWY_TARGETS supported by the CPU as a list of // individual HWY_* target macros such as HWY_SCALAR or HWY_NEON. This list // is affected by the current SetSupportedTargetsForTest() mock if any. HWY_INLINE std::vector SupportedAndGeneratedTargets() { std::vector ret; for (int64_t targets = SupportedTargets() & HWY_TARGETS; targets != 0; targets = targets & (targets - 1)) { int64_t current_target = targets & ~(targets - 1); ret.push_back(current_target); } return ret; } #endif // HWY_NO_LIBCXX static inline HWY_MAYBE_UNUSED const char* TargetName(int64_t target) { switch (target) { #if HWY_ARCH_X86 case HWY_SSE2: return "SSE2"; case HWY_SSSE3: return "SSSE3"; case HWY_SSE4: return "SSE4"; case HWY_AVX2: return "AVX2"; case HWY_AVX3: return "AVX3"; case HWY_AVX3_DL: return "AVX3_DL"; case HWY_AVX3_ZEN4: return "AVX3_ZEN4"; case HWY_AVX3_SPR: return "AVX3_SPR"; #endif #if HWY_ARCH_ARM case HWY_SVE2_128: return "SVE2_128"; case HWY_SVE_256: return "SVE_256"; case HWY_SVE2: return "SVE2"; case HWY_SVE: return "SVE"; case HWY_NEON_BF16: return "NEON_BF16"; case HWY_NEON: return "NEON"; case HWY_NEON_WITHOUT_AES: return "NEON_WITHOUT_AES"; #endif #if HWY_ARCH_PPC case HWY_PPC8: return "PPC8"; case HWY_PPC9: return "PPC9"; case HWY_PPC10: return "PPC10"; #endif #if HWY_ARCH_S390X case HWY_Z14: return "Z14"; case HWY_Z15: return "Z15"; #endif #if HWY_ARCH_WASM case HWY_WASM: return "WASM"; case HWY_WASM_EMU256: return "WASM_EMU256"; #endif #if HWY_ARCH_RISCV case HWY_RVV: return "RVV"; #endif case HWY_EMU128: return "EMU128"; case HWY_SCALAR: return "SCALAR"; default: return "Unknown"; // must satisfy gtest IsValidParamName() } } // The maximum number of dynamic targets on any architecture is defined by // HWY_MAX_DYNAMIC_TARGETS and depends on the arch. // For the ChosenTarget mask and index we use a different bit arrangement than // in the HWY_TARGETS mask. Only the targets involved in the current // architecture are used in this mask, and therefore only the least significant // (HWY_MAX_DYNAMIC_TARGETS + 2) bits of the int64_t mask are used. The least // significant bit is set when the mask is not initialized, the next // HWY_MAX_DYNAMIC_TARGETS more significant bits are a range of bits from the // HWY_TARGETS or SupportedTargets() mask for the given architecture shifted to // that position and the next more significant bit is used for HWY_SCALAR (if // HWY_COMPILE_ONLY_SCALAR is defined) or HWY_EMU128. Because of this we need to // define equivalent values for HWY_TARGETS in this representation. // This mask representation allows to use ctz() on this mask and obtain a small // number that's used as an index of the table for dynamic dispatch. In this // way the first entry is used when the mask is uninitialized, the following // HWY_MAX_DYNAMIC_TARGETS are for dynamic dispatch and the last one is for // scalar. // The HWY_SCALAR/HWY_EMU128 bit in the ChosenTarget mask format. #define HWY_CHOSEN_TARGET_MASK_SCALAR (1LL << (HWY_MAX_DYNAMIC_TARGETS + 1)) // Converts from a HWY_TARGETS mask to a ChosenTarget mask format for the // current architecture. #define HWY_CHOSEN_TARGET_SHIFT(X) \ ((((X) >> (HWY_HIGHEST_TARGET_BIT + 1 - HWY_MAX_DYNAMIC_TARGETS)) & \ ((1LL << HWY_MAX_DYNAMIC_TARGETS) - 1)) \ << 1) // The HWY_TARGETS mask in the ChosenTarget mask format. #define HWY_CHOSEN_TARGET_MASK_TARGETS \ (HWY_CHOSEN_TARGET_SHIFT(HWY_TARGETS) | HWY_CHOSEN_TARGET_MASK_SCALAR | 1LL) #if HWY_ARCH_X86 // Maximum number of dynamic targets, changing this value is an ABI incompatible // change #define HWY_MAX_DYNAMIC_TARGETS 15 #define HWY_HIGHEST_TARGET_BIT HWY_HIGHEST_TARGET_BIT_X86 // These must match the order in which the HWY_TARGETS are defined // starting by the least significant (HWY_HIGHEST_TARGET_BIT + 1 - // HWY_MAX_DYNAMIC_TARGETS) bit. This list must contain exactly // HWY_MAX_DYNAMIC_TARGETS elements and does not include SCALAR. The first entry // corresponds to the best target. Don't include a "," at the end of the list. #define HWY_CHOOSE_TARGET_LIST(func_name) \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ HWY_CHOOSE_AVX3_SPR(func_name), /* AVX3_SPR */ \ nullptr, /* reserved */ \ HWY_CHOOSE_AVX3_ZEN4(func_name), /* AVX3_ZEN4 */ \ HWY_CHOOSE_AVX3_DL(func_name), /* AVX3_DL */ \ HWY_CHOOSE_AVX3(func_name), /* AVX3 */ \ HWY_CHOOSE_AVX2(func_name), /* AVX2 */ \ nullptr, /* AVX */ \ HWY_CHOOSE_SSE4(func_name), /* SSE4 */ \ HWY_CHOOSE_SSSE3(func_name), /* SSSE3 */ \ nullptr, /* reserved - SSE3? */ \ HWY_CHOOSE_SSE2(func_name) /* SSE2 */ #elif HWY_ARCH_ARM // See HWY_ARCH_X86 above for details. #define HWY_MAX_DYNAMIC_TARGETS 15 #define HWY_HIGHEST_TARGET_BIT HWY_HIGHEST_TARGET_BIT_ARM #define HWY_CHOOSE_TARGET_LIST(func_name) \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ HWY_CHOOSE_SVE2_128(func_name), /* SVE2 128-bit */ \ HWY_CHOOSE_SVE_256(func_name), /* SVE 256-bit */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ HWY_CHOOSE_SVE2(func_name), /* SVE2 */ \ HWY_CHOOSE_SVE(func_name), /* SVE */ \ nullptr, /* reserved */ \ HWY_CHOOSE_NEON_BF16(func_name), /* NEON + f16/dot/bf16 */ \ nullptr, /* reserved */ \ HWY_CHOOSE_NEON(func_name), /* NEON */ \ HWY_CHOOSE_NEON_WITHOUT_AES(func_name) /* NEON without AES */ #elif HWY_ARCH_RISCV // See HWY_ARCH_X86 above for details. #define HWY_MAX_DYNAMIC_TARGETS 9 #define HWY_HIGHEST_TARGET_BIT HWY_HIGHEST_TARGET_BIT_RVV #define HWY_CHOOSE_TARGET_LIST(func_name) \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ HWY_CHOOSE_RVV(func_name), /* RVV */ \ nullptr /* reserved */ #elif HWY_ARCH_PPC || HWY_ARCH_S390X // See HWY_ARCH_X86 above for details. #define HWY_MAX_DYNAMIC_TARGETS 9 #define HWY_HIGHEST_TARGET_BIT HWY_HIGHEST_TARGET_BIT_PPC #define HWY_CHOOSE_TARGET_LIST(func_name) \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ HWY_CHOOSE_PPC10(func_name), /* PPC10 */ \ HWY_CHOOSE_PPC9(func_name), /* PPC9 */ \ HWY_CHOOSE_PPC8(func_name), /* PPC8 */ \ HWY_CHOOSE_Z15(func_name), /* Z15 */ \ HWY_CHOOSE_Z14(func_name) /* Z14 */ #elif HWY_ARCH_WASM // See HWY_ARCH_X86 above for details. #define HWY_MAX_DYNAMIC_TARGETS 9 #define HWY_HIGHEST_TARGET_BIT HWY_HIGHEST_TARGET_BIT_WASM #define HWY_CHOOSE_TARGET_LIST(func_name) \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ nullptr, /* reserved */ \ HWY_CHOOSE_WASM_EMU256(func_name), /* WASM_EMU256 */ \ HWY_CHOOSE_WASM(func_name), /* WASM */ \ nullptr /* reserved */ #else // Unknown architecture, will use HWY_SCALAR without dynamic dispatch, though // still creating single-entry tables in HWY_EXPORT to ensure portability. #define HWY_MAX_DYNAMIC_TARGETS 1 #define HWY_HIGHEST_TARGET_BIT HWY_HIGHEST_TARGET_BIT_SCALAR #endif // Bitfield of supported and enabled targets. The format differs from that of // HWY_TARGETS; the lowest bit governs the first function pointer (which is // special in that it calls FunctionCache, then Update, then dispatches to the // actual implementation) in the tables created by HWY_EXPORT. Monostate (see // GetChosenTarget), thread-safe except on RVV. struct ChosenTarget { public: // Reset bits according to `targets` (typically the return value of // SupportedTargets()). Postcondition: IsInitialized() == true. void Update(int64_t targets) { // These are `targets` shifted downwards, see above. Also include SCALAR // (corresponds to the last entry in the function table) as fallback. StoreMask(HWY_CHOSEN_TARGET_SHIFT(targets) | HWY_CHOSEN_TARGET_MASK_SCALAR); } // Reset to the uninitialized state, so that FunctionCache will call Update // during the next HWY_DYNAMIC_DISPATCH, and IsInitialized returns false. void DeInit() { StoreMask(1); } // Whether Update was called. This indicates whether any HWY_DYNAMIC_DISPATCH // function was called, which we check in tests. bool IsInitialized() const { return LoadMask() != 1; } // Return the index in the dynamic dispatch table to be used by the current // CPU. Note that this method must be in the header file so it uses the value // of HWY_CHOSEN_TARGET_MASK_TARGETS defined in the translation unit that // calls it, which may be different from others. This means we only enable // those targets that were actually compiled in this module. size_t HWY_INLINE GetIndex() const { return hwy::Num0BitsBelowLS1Bit_Nonzero64( static_cast(LoadMask() & HWY_CHOSEN_TARGET_MASK_TARGETS)); } private: #if defined(HWY_NO_LIBCXX) int64_t LoadMask() const { return mask_; } void StoreMask(int64_t mask) { mask_ = mask; } int64_t mask_{1}; // Initialized to 1 so GetIndex() returns 0. #else int64_t LoadMask() const { return mask_.load(); } void StoreMask(int64_t mask) { mask_.store(mask); } std::atomic mask_{1}; // Initialized to 1 so GetIndex() returns 0. #endif // HWY_ARCH_RISCV }; // For internal use (e.g. by FunctionCache and DisableTargets). HWY_DLLEXPORT ChosenTarget& GetChosenTarget(); } // namespace hwy #endif // HIGHWAY_HWY_TARGETS_H_