// Copyright (c) 2019 PaddlePaddle Authors. All Rights Reserved. // // 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. #include "lite/backends/x86/cpu_info.h" #ifdef PADDLE_WITH_XBYAK #include "xbyak/xbyak.h" #include "xbyak/xbyak_util.h" #endif #ifdef __APPLE__ #include #include #elif defined(_WIN32) #define NOMINMAX // msvc max/min macro conflict with std::min/max #include #else #include #endif // _WIN32 #include #include "lite/utils/cp_logging.h" #include "lite/utils/env.h" // DEFINE_double(fraction_of_cpu_memory_to_use, // 1, // "Default use 100% of CPU memory for PaddlePaddle," // "reserve the rest for page tables, etc"); double fraction_of_cpu_memory_to_use = paddle::lite::GetDoubleFromEnv("fraction_of_cpu_memory_to_use", 1); // DEFINE_uint64(initial_cpu_memory_in_mb, // 500ul, // "Initial CPU memory for PaddlePaddle, in MD unit."); uint64_t initial_cpu_memory_in_mb = paddle::lite::GetUInt64FromEnv("initial_cpu_memory_in_mb", 500ul); // DEFINE_double( // fraction_of_cuda_pinned_memory_to_use, // 0.5, // "Default use 50% of CPU memory as the pinned_memory for PaddlePaddle," // "reserve the rest for page tables, etc"); double fraction_of_cuda_pinned_memory_to_use = paddle::lite::GetDoubleFromEnv( "fraction_of_cuda_pinned_memory_to_use", 0.5); // If use_pinned_memory is true, CPUAllocator calls mlock, which // returns pinned and locked memory as staging areas for data exchange // between host and device. Allocates too much would reduce the amount // of memory available to the system for paging. So, by default, we // should set false to use_pinned_memory. // DEFINE_bool(use_pinned_memory, true, "If set, allocate cpu pinned memory."); bool use_pinned_memory = paddle::lite::GetBoolFromEnv("use_pinned_memory", true); namespace paddle { namespace lite { namespace x86 { size_t CpuTotalPhysicalMemory() { #ifdef __APPLE__ int mib[2]; mib[0] = CTL_HW; mib[1] = HW_MEMSIZE; int64_t size = 0; size_t len = sizeof(size); if (sysctl(mib, 2, &size, &len, NULL, 0) == 0) return (size_t)size; return 0L; #elif defined(_WIN32) MEMORYSTATUSEX sMeminfo; sMeminfo.dwLength = sizeof(sMeminfo); GlobalMemoryStatusEx(&sMeminfo); return sMeminfo.ullTotalPhys; #else int64_t pages = sysconf(_SC_PHYS_PAGES); int64_t page_size = sysconf(_SC_PAGE_SIZE); return pages * page_size; #endif } size_t CpuMaxAllocSize() { // For distributed systems, it requires configuring and limiting // the fraction of memory to use. return fraction_of_cpu_memory_to_use * CpuTotalPhysicalMemory(); } size_t CpuMinChunkSize() { // Allow to allocate the minimum chunk size is 4 KB. return 1 << 12; } size_t CpuMaxChunkSize() { // Allow to allocate the maximum chunk size is roughly 3% of CPU memory, // or the initial_cpu_memory_in_mb. return std::min(static_cast(CpuMaxAllocSize() / 32), static_cast(initial_cpu_memory_in_mb * 1 << 20)); } size_t CUDAPinnedMaxAllocSize() { // For distributed systems, it requires configuring and limiting // the fraction of memory to use. return fraction_of_cuda_pinned_memory_to_use * CpuTotalPhysicalMemory(); } size_t CUDAPinnedMinChunkSize() { // Allow to allocate the minimum chunk size is 64 KB. return 1 << 16; } size_t CUDAPinnedMaxChunkSize() { // Allow to allocate the maximum chunk size is roughly 1/256 of CUDA_PINNED // memory. return CUDAPinnedMaxAllocSize() / 256; } #ifdef PADDLE_WITH_XBYAK static Xbyak::util::Cpu cpu; bool MayIUse(const cpu_isa_t cpu_isa) { using namespace Xbyak::util; // NOLINT switch (cpu_isa) { case sse42: return cpu.has(Cpu::tSSE42); case avx: return cpu.has(Cpu::tAVX); case avx2: return cpu.has(Cpu::tAVX2); case avx512f: return cpu.has(Cpu::tAVX512F); case avx512_core: return true && cpu.has(Cpu::tAVX512F) && cpu.has(Cpu::tAVX512BW) && cpu.has(Cpu::tAVX512VL) && cpu.has(Cpu::tAVX512DQ); case avx512_core_vnni: return true && cpu.has(Cpu::tAVX512F) && cpu.has(Cpu::tAVX512BW) && cpu.has(Cpu::tAVX512VL) && cpu.has(Cpu::tAVX512DQ) && cpu.has(Cpu::tAVX512_VNNI); case avx512_mic: return true && cpu.has(Cpu::tAVX512F) && cpu.has(Cpu::tAVX512CD) && cpu.has(Cpu::tAVX512ER) && cpu.has(Cpu::tAVX512PF); case avx512_mic_4ops: return true && MayIUse(avx512_mic) && cpu.has(Cpu::tAVX512_4FMAPS) && cpu.has(Cpu::tAVX512_4VNNIW); case isa_any: return true; } return false; } #else bool MayIUse(const cpu_isa_t cpu_isa) { if (cpu_isa == isa_any) { return true; } else { return false; } } #endif } // namespace x86 } // namespace lite } // namespace paddle