/*** Copyright (C) 2022-2023 J Reece Wilson (a/k/a "Reece"). All rights reserved. File: AuCpuId.NT.cpp Date: 2022-1-25 Author: Reece ***/ #include #include "AuHWInfo.hpp" #include "AuCpuInfo.hpp" #include "AuCpuInfo.NT.hpp" #if defined(AURORA_IS_MODERNNT_DERIVED) #include #endif namespace Aurora::HWInfo { static bool SetWindows10CpuSetInfoSlow() { SYSTEM_CPU_SET_INFORMATION cpuSetInfo[128]; SYSTEM_LOGICAL_PROCESSOR_INFORMATION sysinfo[128]; DWORD dwLength {}; if (!pGetSystemCpuSetInformation) { return false; } if (!pGetSystemCpuSetInformation(cpuSetInfo, sizeof(cpuSetInfo), &dwLength, 0, 0)) { return false; } struct CpuInfo { AuList low; AuList> server; CpuBitId mask; }; AuBST cpuThreads; AuUInt8 uThreadCount = AuUInt8(dwLength / sizeof(decltype(*cpuSetInfo))); AuUInt8 uBestClass {}; bool bHasBestClass {}; if (uThreadCount) { AuUInt8 countTable[255] {}; for (AU_ITERATE_N(i, uThreadCount)) { countTable[cpuSetInfo[i].CpuSet.EfficiencyClass]++; } AuUInt8 uBestClassCounter {}; for (AU_ITERATE_N(i, AuArraySize(countTable))) { auto uCurrentCount = countTable[i]; if (uCurrentCount <= uBestClassCounter) { continue; } if (!i) { continue; } uBestClassCounter = uCurrentCount; bHasBestClass = true; uBestClass = i; } } for (AU_ITERATE_N(i, uThreadCount)) { auto &idx = cpuThreads[cpuSetInfo[i].CpuSet.CoreIndex]; // Win7 KAFFINITY = u64 affinity masks // Windows 10 + seems to be ((this->group + 1ul) * 0x100ul) + index // Windows internals says... // ULONG sets[] = { 0x100, 0x101, 0x102, 0x103 }; // ::SetProcessDefaultCpuSets/SetThreadSelectedCpuSets(::GetCurrentProcess(), sets, _countof(sets)); // (useless) // People generally isolate group and keep logical processors in a different set, kinda worthless for bitwise math SysAssert(cpuSetInfo[i].CpuSet.LogicalProcessorIndex < 64); #if defined(_AU_MASSIVE_CPUID) SysAssert(cpuSetInfo[i].CpuSet.Group < 4); #else SysAssert(cpuSetInfo[i].CpuSet.Group < 2); #endif AuUInt8 id = AuUInt8(cpuSetInfo[i].CpuSet.LogicalProcessorIndex /*no greater than 64*/ + (cpuSetInfo[i].CpuSet.Group * 64)); auto cpuId = CpuBitId(id); auto sets = cpuId.ToCpuSets(); SysAssert(sets.size() == 1); SysAssert(sets[0] == cpuSetInfo[i].CpuSet.Id); idx.server.push_back(AuMakePair(cpuSetInfo[i].CpuSet.EfficiencyClass, cpuId)); idx.low.push_back(id); idx.mask.Add(cpuId); gCpuInfo.maskAllCores.Add(cpuId); } for (const auto &[cpuId, coreIds] : cpuThreads) { AuUInt64 shortMask {}; for (const auto &[eClass, id] : coreIds.server) { if (bHasBestClass && eClass != uBestClass) { gCpuInfo.maskECores.Add(id); } else { gCpuInfo.maskPCores.Add(id); gCpuInfo.pCoreTopology.push_back(id); } } for (const auto &id : coreIds.low) { shortMask |= AuUInt64(1) << AuUInt64(id); } gCpuInfo.coreTopology.push_back(coreIds.mask); gCpuInfo.threadTopology.push_back(shortMask); } gCpuInfo.uSocket = 1; gCpuInfo.uThreads = uThreadCount; gCpuInfo.uCores = AuUInt8(cpuThreads.size()); if (!pGetLogicalProcessorInformation) { return true; } if (!pGetLogicalProcessorInformation(sysinfo, &dwLength)) { return true; } gCpuInfo.uSocket = 0; dwLength /= sizeof(*sysinfo); for (auto i = 0u; i < dwLength; i++) { if (sysinfo[i].Relationship == RelationProcessorPackage) { gCpuInfo.uSocket++; } if (sysinfo[i].Relationship == RelationCache) { switch (sysinfo[i].Cache.Level) { case 1: gCpuInfo.dwCacheLine = AuMax(gCpuInfo.dwCacheLine, sysinfo[i].Cache.LineSize); gCpuInfo.dwCacheL1 = AuMax(gCpuInfo.dwCacheL1, sysinfo[i].Cache.Size); break; case 2: gCpuInfo.dwCacheL2 = AuMax(gCpuInfo.dwCacheL2, sysinfo[i].Cache.Size); break; case 3: gCpuInfo.dwCacheL3 = AuMax(gCpuInfo.dwCacheL3, sysinfo[i].Cache.Size); break; } } } return true; } static bool SetWindowsXPSp3ExtendedInformation() { SYSTEM_LOGICAL_PROCESSOR_INFORMATION sysinfo[128]; DWORD dwLength = AuArraySize(sysinfo) * sizeof(*sysinfo); if (!pGetLogicalProcessorInformation) { return false; } if (!pGetLogicalProcessorInformation(sysinfo, &dwLength)) { return false; } dwLength /= sizeof(*sysinfo); gCpuInfo.uSocket = 0; gCpuInfo.uCores = 0; gCpuInfo.uThreads = 0; bool sparse = false; bool hasHTCores = false; for (auto i = 0u; i < dwLength; i++) { if (sysinfo[i].Relationship == RelationProcessorCore) { auto mask = sysinfo[i].ProcessorMask; gCpuInfo.uCores++; gCpuInfo.threadTopology.push_back(mask); CpuBitId serverId; serverId.lower = mask; gCpuInfo.coreTopology.push_back(serverId); gCpuInfo.maskAllCores.Add(serverId); auto uThreadsInCore = AuPopCnt(mask); gCpuInfo.uThreads += uThreadsInCore; hasHTCores |= (uThreadsInCore == 2); if (hasHTCores && (uThreadsInCore == 1)) { AuUInt8 idx {}; while (serverId.CpuBitScanForward(idx, idx)) { gCpuInfo.maskECores.Add(idx); idx++; } } else { AuUInt8 idx {}; while (serverId.CpuBitScanForward(idx, idx)) { gCpuInfo.maskPCores.Add(idx); idx++; } gCpuInfo.pCoreTopology.push_back(serverId); } } else if (sysinfo[i].Relationship == RelationProcessorPackage) { gCpuInfo.uSocket++; } else if (sysinfo[i].Relationship == RelationCache) { switch (sysinfo[i].Cache.Level) { case 1: gCpuInfo.dwCacheLine = AuMax(gCpuInfo.dwCacheLine, sysinfo[i].Cache.LineSize); gCpuInfo.dwCacheL1 = AuMax(gCpuInfo.dwCacheL1, sysinfo[i].Cache.Size); break; case 2: gCpuInfo.dwCacheL2 = AuMax(gCpuInfo.dwCacheL2, sysinfo[i].Cache.Size); break; case 3: gCpuInfo.dwCacheL3 = AuMax(gCpuInfo.dwCacheL3, sysinfo[i].Cache.Size); break; } } } gCpuInfo.bMaskMTContig = !sparse; gCpuInfo.bMaskMTHalf = sparse; return true; } static void SetBasicWindowsXPInformation() { SYSTEM_INFO sysinfo; GetSystemInfo(&sysinfo); gCpuInfo.uSocket = 1; gCpuInfo.uCores = 1; gCpuInfo.uThreads = sysinfo.dwNumberOfProcessors; if (sysinfo.dwNumberOfProcessors & 1) { for (AU_ITERATE_N(i, gCpuInfo.uThreads)) { auto mask = 1 << i; gCpuInfo.maskPCores.SetBit(i); gCpuInfo.threadTopology.push_back(mask); CpuBitId coreId; coreId.lower = mask; gCpuInfo.coreTopology.push_back(coreId); gCpuInfo.pCoreTopology.push_back(coreId); gCpuInfo.maskAllCores.Add(coreId); } gCpuInfo.uCores = gCpuInfo.uThreads; } else { for (AU_ITERATE_N(i, gCpuInfo.uThreads)) { if (i & 1) { continue; } gCpuInfo.maskPCores.SetBit(i); gCpuInfo.maskPCores.SetBit(i + 1); auto maskA = 1u << i; auto maskB = 1u << (i + 1); auto maskC = maskA | maskB; gCpuInfo.threadTopology.push_back(maskA); gCpuInfo.threadTopology.push_back(maskB); CpuBitId coreId; coreId.lower = maskC; gCpuInfo.coreTopology.push_back(coreId); gCpuInfo.pCoreTopology.push_back(coreId); gCpuInfo.maskAllCores.Add(coreId); } gCpuInfo.uCores = gCpuInfo.uThreads / 2; gCpuInfo.bMaskMTHalf = true; } } void SetCpuTopologyNT() { if (SetWindows10CpuSetInfoSlow()) { return; } if (SetWindowsXPSp3ExtendedInformation()) { return; } SetBasicWindowsXPInformation(); } }