/* Cpudetection lib * Copyright (C) 2002-2021 PCSX2 Dev Team * * PCSX2 is free software: you can redistribute it and/or modify it under the terms * of the GNU Lesser General Public License as published by the Free Software Found- * ation, either version 3 of the License, or (at your option) any later version. * * PCSX2 is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; * without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR * PURPOSE. See the GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along with PCSX2. * If not, see . */ #include "common/MemcpyFast.h" #include "common/General.h" #include "common/emitter/cpudetect_internal.h" #include "common/emitter/internal.h" #include "common/emitter/x86_intrin.h" #include // CPU information support #if defined(_WIN32) #define cpuid __cpuid #define cpuidex __cpuidex #else #include static __inline__ __attribute__((always_inline)) void cpuidex(int CPUInfo[], const int InfoType, const int count) { __cpuid_count(InfoType, count, CPUInfo[0], CPUInfo[1], CPUInfo[2], CPUInfo[3]); } static __inline__ __attribute__((always_inline)) void cpuid(int CPUInfo[], const int InfoType) { __cpuid(InfoType, CPUInfo[0], CPUInfo[1], CPUInfo[2], CPUInfo[3]); } #endif using namespace x86Emitter; alignas(16) x86capabilities x86caps; x86capabilities::x86capabilities() : isIdentified(false) , VendorID(x86Vendor_Unknown) , FamilyID(0) , Model(0) , TypeID(0) , StepID(0) , Flags(0) , Flags2(0) , EFlags(0) , EFlags2(0) , SEFlag(0) , AllCapabilities(0) , PhysicalCores(0) , LogicalCores(0) { memzero(VendorName); memzero(FamilyName); } // Warning! We've had problems with the MXCSR detection code causing stack corruption in // MSVC PGO builds. The problem was fixed when I moved the MXCSR code to this function, and // moved the recSSE[] array to a global static (it was local to cpudetectInit). Commented // here in case the nutty crash ever re-surfaces. >_< // Note: recSSE was deleted void x86capabilities::SIMD_EstablishMXCSRmask() { if (!hasStreamingSIMDExtensions) return; MXCSR_Mask.bitmask = 0xFFBF; // MMX/SSE default if (hasStreamingSIMD2Extensions) { // This is generally safe assumption, but FXSAVE is the "correct" way to // detect MXCSR masking features of the cpu, so we use it's result below // and override this. MXCSR_Mask.bitmask = 0xFFFF; // SSE2 features added } alignas(16) u8 targetFXSAVE[512]; // Work for recent enough GCC/CLANG/MSVC 2012 _fxsave(&targetFXSAVE); u32 result; memcpy(&result, &targetFXSAVE[28], 4); // bytes 28->32 are the MXCSR_Mask. if (result != 0) MXCSR_Mask.bitmask = result; } // Counts the number of cpu cycles executed over the requested number of PerformanceCounter // ticks. Returns that exact count. // For best results you should pick a period of time long enough to get a reading that won't // be prone to rounding error; but short enough that it'll be highly unlikely to be interrupted // by the operating system task switches. s64 x86capabilities::_CPUSpeedHz(u64 time) const { u64 timeStart, timeStop; s64 startCycle, endCycle; if (!hasTimeStampCounter) return 0; SingleCoreAffinity affinity_lock; // Align the cpu execution to a cpuTick boundary. do { timeStart = GetCPUTicks(); startCycle = __rdtsc(); } while (GetCPUTicks() == timeStart); do { timeStop = GetCPUTicks(); endCycle = __rdtsc(); } while ((timeStop - timeStart) < time); s64 cycleCount = endCycle - startCycle; s64 timeCount = timeStop - timeStart; s64 overrun = timeCount - time; if (!overrun) return cycleCount; // interference could cause us to overshoot the target time, compensate: double cyclesPerTick = (double)cycleCount / (double)timeCount; double newCycleCount = (double)cycleCount - (cyclesPerTick * overrun); return (s64)newCycleCount; } const char* x86capabilities::GetTypeName() const { switch (TypeID) { case 0: return "Standard OEM"; case 1: return "Overdrive"; case 2: return "Dual"; case 3: return "Reserved"; default: return "Unknown"; } } void x86capabilities::CountCores() { Identify(); s32 regs[4]; u32 cmds; cpuid(regs, 0x80000000); cmds = regs[0]; // detect multicore for AMD cpu if ((cmds >= 0x80000008) && (VendorID == x86Vendor_AMD)) { // AMD note: they don't support hyperthreading, but they like to flag this true // anyway. Let's force-unflag it until we come up with a better solution. // (note: seems to affect some Phenom II's only? -- Athlon X2's and PhenomI's do // not seem to do this) --air hasMultiThreading = 0; } // This will assign values into LogicalCores and PhysicalCores CountLogicalCores(); } static const char* tbl_x86vendors[] = { "GenuineIntel", "AuthenticAMD", "Unknown ", }; // Performs all _cpuid-related activity. This fills *most* of the x86caps structure, except for // the cpuSpeed and the mxcsr masks. Those must be completed manually. void x86capabilities::Identify() { if (isIdentified) return; isIdentified = true; s32 regs[4]; u32 cmds; memzero(VendorName); cpuid(regs, 0); cmds = regs[0]; memcpy(&VendorName[0], ®s[1], 4); memcpy(&VendorName[4], ®s[3], 4); memcpy(&VendorName[8], ®s[2], 4); // Determine Vendor Specifics! // It's really not recommended that we base much (if anything) on CPU vendor names, // however it's currently necessary in order to gain a (pseudo)reliable count of cores // and threads used by the CPU (AMD and Intel can't agree on how to make this info available). int vid; for (vid = 0; vid < x86Vendor_Unknown; ++vid) { if (memcmp(VendorName, tbl_x86vendors[vid], 12) == 0) break; } VendorID = static_cast(vid); if (cmds >= 0x00000001) { cpuid(regs, 0x00000001); StepID = regs[0] & 0xf; Model = (regs[0] >> 4) & 0xf; FamilyID = (regs[0] >> 8) & 0xf; TypeID = (regs[0] >> 12) & 0x3; //u32 x86_64_8BITBRANDID = regs[1] & 0xff; Flags = regs[3]; Flags2 = regs[2]; } if (cmds >= 0x00000007) { // Note: ECX must be 0 for AVX2 detection. cpuidex(regs, 0x00000007, 0); SEFlag = regs[1]; } cpuid(regs, 0x80000000); cmds = regs[0]; if (cmds >= 0x80000001) { cpuid(regs, 0x80000001); //u32 x86_64_12BITBRANDID = regs[1] & 0xfff; EFlags2 = regs[2]; EFlags = regs[3]; } memzero(FamilyName); cpuid((int*)FamilyName, 0x80000002); cpuid((int*)(FamilyName + 16), 0x80000003); cpuid((int*)(FamilyName + 32), 0x80000004); hasFloatingPointUnit = (Flags >> 0) & 1; hasVirtual8086ModeEnhancements = (Flags >> 1) & 1; hasDebuggingExtensions = (Flags >> 2) & 1; hasPageSizeExtensions = (Flags >> 3) & 1; hasTimeStampCounter = (Flags >> 4) & 1; hasModelSpecificRegisters = (Flags >> 5) & 1; hasPhysicalAddressExtension = (Flags >> 6) & 1; hasMachineCheckArchitecture = (Flags >> 7) & 1; hasCOMPXCHG8BInstruction = (Flags >> 8) & 1; hasAdvancedProgrammableInterruptController = (Flags >> 9) & 1; hasSEPFastSystemCall = (Flags >> 11) & 1; hasMemoryTypeRangeRegisters = (Flags >> 12) & 1; hasPTEGlobalFlag = (Flags >> 13) & 1; hasMachineCheckArchitecture = (Flags >> 14) & 1; hasConditionalMoveAndCompareInstructions = (Flags >> 15) & 1; hasFGPageAttributeTable = (Flags >> 16) & 1; has36bitPageSizeExtension = (Flags >> 17) & 1; hasProcessorSerialNumber = (Flags >> 18) & 1; hasCFLUSHInstruction = (Flags >> 19) & 1; hasDebugStore = (Flags >> 21) & 1; hasACPIThermalMonitorAndClockControl = (Flags >> 22) & 1; hasFastStreamingSIMDExtensionsSaveRestore = (Flags >> 24) & 1; hasStreamingSIMDExtensions = (Flags >> 25) & 1; //sse hasStreamingSIMD2Extensions = (Flags >> 26) & 1; //sse2 hasSelfSnoop = (Flags >> 27) & 1; hasMultiThreading = (Flags >> 28) & 1; hasThermalMonitor = (Flags >> 29) & 1; hasIntel64BitArchitecture = (Flags >> 30) & 1; // ------------------------------------------------- // --> SSE3 / SSSE3 / SSE4.1 / SSE 4.2 detection <-- // ------------------------------------------------- hasStreamingSIMD3Extensions = (Flags2 >> 0) & 1; //sse3 hasSupplementalStreamingSIMD3Extensions = (Flags2 >> 9) & 1; //ssse3 hasStreamingSIMD4Extensions = (Flags2 >> 19) & 1; //sse4.1 hasStreamingSIMD4Extensions2 = (Flags2 >> 20) & 1; //sse4.2 if ((Flags2 >> 27) & 1) // OSXSAVE { // Note: In theory, we should use xgetbv to check OS support // but all OSes we officially run under support it // and its intrinsic requires extra compiler flags hasAVX = (Flags2 >> 28) & 1; //avx hasFMA = (Flags2 >> 12) & 1; //fma hasAVX2 = (SEFlag >> 5) & 1; //avx2 } hasBMI1 = (SEFlag >> 3) & 1; hasBMI2 = (SEFlag >> 8) & 1; // Ones only for AMDs: hasAMD64BitArchitecture = (EFlags >> 29) & 1; //64bit cpu hasStreamingSIMD4ExtensionsA = (EFlags2 >> 6) & 1; //INSERTQ / EXTRQ / MOVNT isIdentified = true; } u32 x86capabilities::CalculateMHz() const { InitCPUTicks(); u64 span = GetTickFrequency(); if ((span % 1000) < 400) // helps minimize rounding errors return (u32)(_CPUSpeedHz(span / 1000) / 1000); else return (u32)(_CPUSpeedHz(span / 500) / 2000); } u32 x86capabilities::CachedMHz() { static std::atomic cached{0}; u32 local = cached.load(std::memory_order_relaxed); if (unlikely(local == 0)) { x86capabilities caps; caps.Identify(); local = caps.CalculateMHz(); cached.store(local, std::memory_order_relaxed); } return local; }