// Filename: Processor.h // ===================== // Author: Benjamin Jurke // File history: 27.02.2002 File created. /////////////////////////////////////////// // Options: /////////// #define PROCESSOR_FREQUENCY_MEASURE_AVAILABLE // Includes --> code gets os-dependend (Win32) typedef struct ProcessorExtensions { bool FPU_FloatingPointUnit; bool VME_Virtual8086ModeEnhancements; bool DE_DebuggingExtensions; bool PSE_PageSizeExtensions; bool TSC_TimeStampCounter; bool MSR_ModelSpecificRegisters; bool PAE_PhysicalAddressExtension; bool MCE_MachineCheckException; bool CX8_COMPXCHG8B_Instruction; bool APIC_AdvancedProgrammableInterruptController; unsigned int APIC_ID; bool SEP_FastSystemCall; bool MTRR_MemoryTypeRangeRegisters; bool PGE_PTE_GlobalFlag; bool MCA_MachineCheckArchitecture; bool CMOV_ConditionalMoveAndCompareInstructions; bool FGPAT_PageAttributeTable; bool PSE36_36bitPageSizeExtension; bool PN_ProcessorSerialNumber; bool CLFSH_CFLUSH_Instruction; unsigned int CLFLUSH_InstructionCacheLineSize; bool DS_DebugStore; bool ACPI_ThermalMonitorAndClockControl; bool EMMX_MultimediaExtensions; bool MMX_MultimediaExtensions; bool FXSR_FastStreamingSIMD_ExtensionsSaveRestore; bool SSE_StreamingSIMD_Extensions; bool SSE2_StreamingSIMD2_Extensions; bool SS_SelfSnoop; bool HT_HyperThreading; unsigned int HT_HyterThreadingSiblings; bool TM_ThermalMonitor; bool IA64_Intel64BitArchitecture; bool _3DNOW_InstructionExtensions; bool _E3DNOW_InstructionExtensions; bool AA64_AMD64BitArchitecture; } ProcessorExtensions; typedef struct ProcessorCache { bool bPresent; char strSize[32]; unsigned int uiAssociativeWays; unsigned int uiLineSize; bool bSectored; char strCache[128]; } ProcessorCache; typedef struct ProcessorL1Cache { ProcessorCache Instruction; ProcessorCache Data; } ProcessorL1Cache; typedef struct ProcessorTLB { bool bPresent; char strPageSize[32]; unsigned int uiAssociativeWays; unsigned int uiEntries; char strTLB[128]; } ProcessorTLB; typedef struct ProcessorInfo { char strVendor[16]; unsigned int uiFamily; unsigned int uiExtendedFamily; char strFamily[64]; unsigned int uiModel; unsigned int uiExtendedModel; char strModel[128]; unsigned int uiStepping; unsigned int uiType; char strType[64]; unsigned int uiBrandID; char strBrandID[64]; char strProcessorSerial[64]; unsigned long MaxSupportedLevel; unsigned long MaxSupportedExtendedLevel; ProcessorExtensions _Ext; ProcessorL1Cache _L1; ProcessorCache _L2; ProcessorCache _L3; ProcessorCache _Trace; ProcessorTLB _Instruction; ProcessorTLB _Data; } ProcessorInfo; // CProcessor // ========== // Class for detecting the processor name, type and available // extensions as long as it's speed. ///////////////////////////////////////////////////////////// class CProcessor { // Constructor / Destructor: //////////////////////////// public: CProcessor(); // Private vars: //////////////// private: __int64 uqwFrequency; char strCPUName[128]; ProcessorInfo CPUInfo; // Private functions: ///////////////////// private: bool AnalyzeIntelProcessor(); bool AnalyzeAMDProcessor(); bool AnalyzeUnknownProcessor(); bool CheckCPUIDPresence(); void DecodeProcessorConfiguration(unsigned int cfg); void TranslateProcessorConfiguration(); void GetStandardProcessorConfiguration(); void GetStandardProcessorExtensions(); // Public functions: //////////////////// public: __int64 GetCPUFrequency(unsigned int uiMeasureMSecs); const ProcessorInfo *GetCPUInfo(); bool CPUInfoToText(char *strBuffer, unsigned int uiMaxLen); bool WriteInfoTextFile(const char *strFilename); }; bool CPUInfoToText(char * /*strBuffer*/, unsigned int /*uiMaxLen*/) { CProcessor cpu; cpu.WriteInfoTextFile("D:\\cpu.txt"); return false; //return cpu.CPUInfoToText(strBuffer,uiMaxLen); } // Filename: Processor.cpp // ======================= // Author: Benjamin Jurke // File history: 27.02.2002 - File created. Support for Intel and AMD processors // 05.03.2002 - Fixed the CPUID bug: On Pre-Pentium CPUs the CPUID // command is not available // - The CProcessor::WriteInfoTextFile function do not // longer use Win32 file functions (-> os independend) // - Optional include of the windows.h header which is // still need for CProcessor::GetCPUFrequency. // 06.03.2002 - My birthday (18th :-)) // - Replaced the '\r\n' line endings in function // CProcessor::CPUInfoToText by '\n' // - Replaced unsigned __int64 by signed __int64 for // solving some compiler conversion problems // - Fixed a bug at family=6, model=6 (Celeron -> P2) ////////////////////////////////////////////////////////////////////////////////// #include #include #include #ifdef PROCESSOR_FREQUENCY_MEASURE_AVAILABLE #include // We need the QueryPerformanceCounter and Sleep functions #endif // Some macros we often need //////////////////////////// #define CheckBit(var, bit) ((var & (1 << bit)) ? true : false) // CProcessor::CProcessor // ====================== // Class constructor: ///////////////////////// CProcessor::CProcessor() { uqwFrequency = 0; memset(&CPUInfo, 0, sizeof(CPUInfo)); } // unsigned __int64 CProcessor::GetCPUFrequency(unsigned int uiMeasureMSecs) // ========================================================================= // Function to measure the current CPU frequency //////////////////////////////////////////////////////////////////////////// __int64 CProcessor::GetCPUFrequency(unsigned int uiMeasureMSecs) { #ifndef PROCESSOR_FREQUENCY_MEASURE_AVAILABLE return 0; #else // If there are invalid measure time parameters, zero msecs for example, // we've to exit the function if (uiMeasureMSecs < 1) { // If theres already a measured frequency available, we return it if (uqwFrequency > 0) return uqwFrequency; else return 0; } // Now we check if the CPUID command is available if (!CheckCPUIDPresence()) return 0; // First we get the CPUID standard level 0x00000001 unsigned long reg; __asm { mov eax, 1 cpuid mov reg, edx } // Then we check, if the RDTSC (Real Date Time Stamp Counter) is available. // This function is necessary for our measure process. if (!(reg & (1 << 4))) return 0; // After that we declare some vars and check the frequency of the high // resolution timer for the measure process. // If there's no high-res timer, we exit. __int64 starttime, endtime, timedif, freq, start, end, dif; if (!QueryPerformanceFrequency((LARGE_INTEGER *) &freq)) return 0; // Now we can init the measure process. We set the process and thread priority // to the highest available level (Realtime priority). Also we focus the // first processor in the multiprocessor system. HANDLE hProcess = GetCurrentProcess(); HANDLE hThread = GetCurrentThread(); unsigned long dwCurPriorityClass = GetPriorityClass(hProcess); int iCurThreadPriority = GetThreadPriority(hThread); unsigned long dwProcessMask, dwSystemMask, dwNewMask = 1; GetProcessAffinityMask(hProcess, &dwProcessMask, &dwSystemMask); SetPriorityClass(hProcess, REALTIME_PRIORITY_CLASS); SetThreadPriority(hThread, THREAD_PRIORITY_TIME_CRITICAL); SetProcessAffinityMask(hProcess, dwNewMask); // Now we call a CPUID to ensure, that all other prior called functions are // completed now (serialization) __asm cpuid // We ask the high-res timer for the start time QueryPerformanceCounter((LARGE_INTEGER *) &starttime); // Then we get the current cpu clock and store it __asm { rdtsc mov dword ptr [start+4], edx mov dword ptr [start], eax } // Now we wart for some msecs Sleep(uiMeasureMSecs); // We ask for the end time QueryPerformanceCounter((LARGE_INTEGER *) &endtime); // And also for the end cpu clock __asm { rdtsc mov dword ptr [end+4], edx mov dword ptr [end], eax } // Now we can restore the default process and thread priorities SetProcessAffinityMask(hProcess, dwProcessMask); SetThreadPriority(hThread, iCurThreadPriority); SetPriorityClass(hProcess, dwCurPriorityClass); // Then we calculate the time and clock differences dif = end - start; timedif = endtime - starttime; // And finally the frequency is the clock difference divided by the time // difference. uqwFrequency = (__int64) (((double) dif) / (((double) timedif) / (__int64)freq)); // At last we just return the frequency that is also stored in the call // member var uqwFrequency return uqwFrequency; #endif } // bool CProcessor::AnalyzeIntelProcessor() // ======================================== // Private class function for analyzing an Intel processor ////////////////////////////////////////////////////////// bool CProcessor::AnalyzeIntelProcessor() { unsigned long eaxreg, ebxreg, edxreg; // First we check if the CPUID command is available if (!CheckCPUIDPresence()) return false; // Now we get the CPUID standard level 0x00000001 __asm { mov eax, 1 cpuid mov eaxreg, eax mov ebxreg, ebx mov edxreg, edx } // Then get the cpu model, family, type, stepping and brand id by masking // the eax and ebx register CPUInfo.uiStepping = eaxreg & 0xF; CPUInfo.uiModel = (eaxreg >> 4) & 0xF; CPUInfo.uiFamily = (eaxreg >> 8) & 0xF; CPUInfo.uiType = (eaxreg >> 12) & 0x3; CPUInfo.uiBrandID = ebxreg & 0xF; // Now we can translate the type number to a more understandable string format switch (CPUInfo.uiType) { case 0: // Type = 0: Original OEM processor strcpy(CPUInfo.strType, "Original OEM"); strcpy(strCPUName, CPUInfo.strType); strcat(strCPUName, " "); break; case 1: // Type = 1: Overdrive processor strcpy(CPUInfo.strType, "Overdrive"); strcpy(strCPUName, CPUInfo.strType); strcat(strCPUName, " "); break; case 2: // Type = 2: Dual-capable processor strcpy(CPUInfo.strType, "Dual-capable"); strcpy(strCPUName, CPUInfo.strType); strcat(strCPUName, " "); break; case 3: // Type = 3: Reserved for future use strcpy(CPUInfo.strType, "Reserved"); break; default: // This should be never called, cause we just mask 2 bits --> [0..3] strcpy(CPUInfo.strType, "Unknown"); break; } // Then we translate the brand id: switch (CPUInfo.uiBrandID) { case 0: // Brand id = 0: Brand id not supported on this processor strcpy(CPUInfo.strBrandID, "Not supported"); break; case 1: // Brand id = 1: Intel Celeron (0.18 µm) processor strcpy(CPUInfo.strBrandID, "0.18 µm Intel Celeron"); break; case 2: // Brand id = 2: Intel Pentium III (0.18 µm) processor strcpy(CPUInfo.strBrandID, "0.18 µm Intel Pentium III"); break; case 3: // Brand id = 3: Model dependent if (CPUInfo.uiModel == 6) // If the cpu model is Celeron (well, I'm NOT SURE!!!) strcpy(CPUInfo.strBrandID, "0.13 µm Intel Celeron"); else strcpy(CPUInfo.strBrandID, "0.18 µm Intel Pentium III Xeon"); break; case 4: // Brand id = 4: Intel Pentium III Tualatin (0.13 µm) processor strcpy(CPUInfo.strBrandID, "0.13 µm Intel Pentium III"); break; case 6: // Brand id = 6: Intel Pentium III mobile (0.13 µm) processor strcpy(CPUInfo.strBrandID, "0.13 µm Intel Pentium III mobile"); break; case 7: // Brand id = 7: Intel Celeron mobile (0.13 µm) processor strcpy(CPUInfo.strBrandID, "0.13 µm Intel Celeron mobile"); break; case 8: // Brand id = 8: Intel Pentium 4 Willamette (0.18 µm) processor strcpy(CPUInfo.strBrandID, "0.18 µm Intel Pentium 4"); break; case 9: // Brand id = 9: Intel Pentium 4 Northwood (0.13 µm) processor strcpy(CPUInfo.strBrandID, "0.13 µm Intel Pentium 4"); break; case 0xA: // Brand id = 0xA: Intel Pentium 4 Northwood (0.13 µm processor) strcpy(CPUInfo.strBrandID, "0.13 µm Intel Pentium 4"); break; // No idea, where the difference to id=9 is case 0xB: // Brand id = 0xB: Intel Pentium 4 Northwood Xeon (0.13 µm processor) strcpy(CPUInfo.strBrandID, "0.13 µm Intel Pentium 4 Xeon"); break; case 0xE: // Brand id = 0xE: Intel Pentium 4 Willamette Xeon (0.18 µm processor) strcpy(CPUInfo.strBrandID, "0.18 µm Intel Pentium 4 Xeon"); break; default: // Should be never called, but sure is sure strcpy(CPUInfo.strBrandID, "Unknown"); break; } // Then we translate the cpu family switch (CPUInfo.uiFamily) { case 3: // Family = 3: i386 (80386) processor family strcpy(CPUInfo.strFamily, "Intel i386"); break; case 4: // Family = 4: i486 (80486) processor family strcpy(CPUInfo.strFamily, "Intel i486"); break; case 5: // Family = 5: Pentium (80586) processor family strcpy(CPUInfo.strFamily, "Intel Pentium"); break; case 6: // Family = 6: Pentium Pro (80686) processor family strcpy(CPUInfo.strFamily, "Intel Pentium Pro"); break; case 15: // Family = 15: Extended family specific // Masking the extended family CPUInfo.uiExtendedFamily = (eaxreg >> 20) & 0xFF; switch (CPUInfo.uiExtendedFamily) { case 0: // Family = 15, Ext. Family = 0: Pentium 4 (80786 ??) processor family strcpy(CPUInfo.strFamily, "Intel Pentium 4"); break; case 1: // Family = 15, Ext. Family = 1: McKinley (64-bit) processor family strcpy(CPUInfo.strFamily, "Intel McKinley (IA-64)"); break; default: // Sure is sure strcpy(CPUInfo.strFamily, "Unknown Intel Pentium 4+"); break; } break; default: // Failsave strcpy(CPUInfo.strFamily, "Unknown"); break; } // Now we come to the big deal, the exact model name switch (CPUInfo.uiFamily) { case 3: // i386 (80386) processor family strcpy(CPUInfo.strModel, "Unknown Intel i386"); strcat(strCPUName, "Intel i386"); break; case 4: // i486 (80486) processor family switch (CPUInfo.uiModel) { case 0: // Model = 0: i486 DX-25/33 processor model strcpy(CPUInfo.strModel, "Intel i486 DX-25/33"); strcat(strCPUName, "Intel i486 DX-25/33"); break; case 1: // Model = 1: i486 DX-50 processor model strcpy(CPUInfo.strModel, "Intel i486 DX-50"); strcat(strCPUName, "Intel i486 DX-50"); break; case 2: // Model = 2: i486 SX processor model strcpy(CPUInfo.strModel, "Intel i486 SX"); strcat(strCPUName, "Intel i486 SX"); break; case 3: // Model = 3: i486 DX2 (with i487 numeric coprocessor) processor model strcpy(CPUInfo.strModel, "Intel i486 487/DX2"); strcat(strCPUName, "Intel i486 DX2 with i487 numeric coprocessor"); break; case 4: // Model = 4: i486 SL processor model (never heard ?!?) strcpy(CPUInfo.strModel, "Intel i486 SL"); strcat(strCPUName, "Intel i486 SL"); break; case 5: // Model = 5: i486 SX2 processor model strcpy(CPUInfo.strModel, "Intel i486 SX2"); strcat(strCPUName, "Intel i486 SX2"); break; case 7: // Model = 7: i486 write-back enhanced DX2 processor model strcpy(CPUInfo.strModel, "Intel i486 write-back enhanced DX2"); strcat(strCPUName, "Intel i486 write-back enhanced DX2"); break; case 8: // Model = 8: i486 DX4 processor model strcpy(CPUInfo.strModel, "Intel i486 DX4"); strcat(strCPUName, "Intel i486 DX4"); break; case 9: // Model = 9: i486 write-back enhanced DX4 processor model strcpy(CPUInfo.strModel, "Intel i486 write-back enhanced DX4"); strcat(strCPUName, "Intel i486 DX4"); break; default: // ... strcpy(CPUInfo.strModel, "Unknown Intel i486"); strcat(strCPUName, "Intel i486 (Unknown model)"); break; } break; case 5: // Pentium (80586) processor family switch (CPUInfo.uiModel) { case 0: // Model = 0: Pentium (P5 A-Step) processor model strcpy(CPUInfo.strModel, "Intel Pentium (P5 A-Step)"); strcat(strCPUName, "Intel Pentium (P5 A-Step core)"); break; // Famous for the DIV bug, as far as I know case 1: // Model = 1: Pentium 60/66 processor model strcpy(CPUInfo.strModel, "Intel Pentium 60/66 (P5)"); strcat(strCPUName, "Intel Pentium 60/66 (P5 core)"); break; case 2: // Model = 2: Pentium 75-200 (P54C) processor model strcpy(CPUInfo.strModel, "Intel Pentium 75-200 (P54C)"); strcat(strCPUName, "Intel Pentium 75-200 (P54C core)"); break; case 3: // Model = 3: Pentium overdrive for 486 systems processor model strcpy(CPUInfo.strModel, "Intel Pentium for 486 system (P24T Overdrive)"); strcat(strCPUName, "Intel Pentium for 486 (P24T overdrive core)"); break; case 4: // Model = 4: Pentium MMX processor model strcpy(CPUInfo.strModel, "Intel Pentium MMX (P55C)"); strcat(strCPUName, "Intel Pentium MMX (P55C core)"); break; case 7: // Model = 7: Pentium processor model (don't know difference to Model=2) strcpy(CPUInfo.strModel, "Intel Pentium (P54C)"); strcat(strCPUName, "Intel Pentium (P54C core)"); break; case 8: // Model = 8: Pentium MMX (0.25 µm) processor model strcpy(CPUInfo.strModel, "Intel Pentium MMX (P55C), 0.25 µm"); strcat(strCPUName, "Intel Pentium MMX (P55C core), 0.25 µm"); break; default: // ... strcpy(CPUInfo.strModel, "Unknown Intel Pentium"); strcat(strCPUName, "Intel Pentium (Unknown P5-model)"); break; } break; case 6: // Pentium Pro (80686) processor family switch (CPUInfo.uiModel) { case 0: // Model = 0: Pentium Pro (P6 A-Step) processor model strcpy(CPUInfo.strModel, "Intel Pentium Pro (P6 A-Step)"); strcat(strCPUName, "Intel Pentium Pro (P6 A-Step core)"); break; case 1: // Model = 1: Pentium Pro strcpy(CPUInfo.strModel, "Intel Pentium Pro (P6)"); strcat(strCPUName, "Intel Pentium Pro (P6 core)"); break; case 3: // Model = 3: Pentium II (66 MHz FSB, I think) processor model strcpy(CPUInfo.strModel, "Intel Pentium II Model 3, 0.28 µm"); strcat(strCPUName, "Intel Pentium II (Model 3 core, 0.28 µm process)"); break; case 5: // Model = 5: Pentium II/Xeon/Celeron (0.25 µm) processor model strcpy(CPUInfo.strModel, "Intel Pentium II Model 5/Xeon/Celeron, 0.25 µm"); strcat(strCPUName, "Intel Pentium II/Xeon/Celeron (Model 5 core, 0.25 µm process)"); break; case 6: // Model = 6: Pentium II with internal L2 cache strcpy(CPUInfo.strModel, "Intel Pentium II - internal L2 cache"); strcat(strCPUName, "Intel Pentium II with internal L2 cache"); break; case 7: // Model = 7: Pentium III/Xeon (extern L2 cache) processor model strcpy(CPUInfo.strModel, "Intel Pentium III/Pentium III Xeon - external L2 cache, 0.25 µm"); strcat(strCPUName, "Intel Pentium III/Pentium III Xeon (0.25 µm process) with external L2 cache"); break; case 8: // Model = 8: Pentium III/Xeon/Celeron (256 KB on-die L2 cache) processor model strcpy(CPUInfo.strModel, "Intel Pentium III/Celeron/Pentium III Xeon - internal L2 cache, 0.18 µm"); // We want to know it exactly: switch (CPUInfo.uiBrandID) { case 1: // Model = 8, Brand id = 1: Celeron (on-die L2 cache) processor model strcat(strCPUName, "Intel Celeron (0.18 µm process) with internal L2 cache"); break; case 2: // Model = 8, Brand id = 2: Pentium III (on-die L2 cache) processor model (my current cpu :-)) strcat(strCPUName, "Intel Pentium III (0.18 µm process) with internal L2 cache"); break; case 3: // Model = 8, Brand id = 3: Pentium III Xeon (on-die L2 cache) processor model strcat(strCPUName, "Intel Pentium III Xeon (0.18 µm process) with internal L2 cache"); break; default: // ...² strcat(strCPUName, "Intel Pentium III core (unknown model, 0.18 µm process) with internal L2 cache"); break; } break; case 0xA: // Model = 0xA: Pentium III/Xeon/Celeron (1 or 2 MB on-die L2 cache) processor model strcpy(CPUInfo.strModel, "Intel Pentium III/Celeron/Pentium III Xeon - internal L2 cache, 0.18 µm"); // Exact detection: switch (CPUInfo.uiBrandID) { case 1: // Model = 0xA, Brand id = 1: Celeron (1 or 2 MB on-die L2 cache (does it exist??)) processor model strcat(strCPUName, "Intel Celeron (0.18 µm process) with internal L2 cache"); break; case 2: // Model = 0xA, Brand id = 2: Pentium III (1 or 2 MB on-die L2 cache (never seen...)) processor model strcat(strCPUName, "Intel Pentium III (0.18 µm process) with internal L2 cache"); break; case 3: // Model = 0xA, Brand id = 3: Pentium III Xeon (1 or 2 MB on-die L2 cache) processor model strcat(strCPUName, "Intel Pentium III Xeon (0.18 µm process) with internal L2 cache"); break; default: // Getting bored of this............ strcat(strCPUName, "Intel Pentium III core (unknown model, 0.18 µm process) with internal L2 cache"); break; } break; case 0xB: // Model = 0xB: Pentium III/Xeon/Celeron (Tualatin core, on-die cache) processor model strcpy(CPUInfo.strModel, "Intel Pentium III/Celeron/Pentium III Xeon - internal L2 cache, 0.13 µm"); // Omniscient: ;-) switch (CPUInfo.uiBrandID) { case 3: // Model = 0xB, Brand id = 3: Celeron (Tualatin core) processor model strcat(strCPUName, "Intel Celeron (Tualatin core, 0.13 µm process) with internal L2 cache"); break; case 4: // Model = 0xB, Brand id = 4: Pentium III (Tualatin core) processor model strcat(strCPUName, "Intel Pentium III (Tualatin core, 0.13 µm process) with internal L2 cache"); break; case 7: // Model = 0xB, Brand id = 7: Celeron mobile (Tualatin core) processor model strcat(strCPUName, "Intel Celeron mobile (Tualatin core, 0.13 µm process) with internal L2 cache"); break; default: // *bored* strcat(strCPUName, "Intel Pentium III Tualatin core (unknown model, 0.13 µm process) with internal L2 cache"); break; } break; default: // *more bored* strcpy(CPUInfo.strModel, "Unknown Intel Pentium Pro"); strcat(strCPUName, "Intel Pentium Pro (Unknown model)"); break; } break; case 15: // Extended processor family // Masking the extended model CPUInfo.uiExtendedModel = (eaxreg >> 16) & 0xFF; switch (CPUInfo.uiModel) { case 0: // Model = 0: Pentium 4 Willamette (A-Step) core if ((CPUInfo.uiBrandID) == 8) // Brand id = 8: P4 Willamette { strcpy(CPUInfo.strModel, "Intel Pentium 4 Willamette (A-Step)"); strcat(strCPUName, "Intel Pentium 4 Willamette (A-Step)"); } else // else Xeon { strcpy(CPUInfo.strModel, "Intel Pentium 4 Willamette Xeon (A-Step)"); strcat(strCPUName, "Intel Pentium 4 Willamette Xeon (A-Step)"); } break; case 1: // Model = 1: Pentium 4 Willamette core if ((CPUInfo.uiBrandID) == 8) // Brand id = 8: P4 Willamette { strcpy(CPUInfo.strModel, "Intel Pentium 4 Willamette"); strcat(strCPUName, "Intel Pentium 4 Willamette"); } else // else Xeon { strcpy(CPUInfo.strModel, "Intel Pentium 4 Willamette Xeon"); strcat(strCPUName, "Intel Pentium 4 Willamette Xeon"); } break; case 2: // Model = 2: Pentium 4 Northwood core if (((CPUInfo.uiBrandID) == 9) || ((CPUInfo.uiBrandID) == 0xA)) // P4 Willamette { strcpy(CPUInfo.strModel, "Intel Pentium 4 Northwood"); strcat(strCPUName, "Intel Pentium 4 Northwood"); } else // Xeon { strcpy(CPUInfo.strModel, "Intel Pentium 4 Northwood Xeon"); strcat(strCPUName, "Intel Pentium 4 Northwood Xeon"); } break; default: // Silly stupid never used failsave option strcpy(CPUInfo.strModel, "Unknown Intel Pentium 4"); strcat(strCPUName, "Intel Pentium 4 (Unknown model)"); break; } break; default: // *grmpf* strcpy(CPUInfo.strModel, "Unknown Intel model"); strcat(strCPUName, "Intel (Unknown model)"); break; } // After the long processor model block we now come to the processors serial // number. // First of all we check if the processor supports the serial number if (CPUInfo.MaxSupportedLevel >= 3) { // If it supports the serial number CPUID level 0x00000003 we read the data unsigned long sig1, sig2, sig3; __asm { mov eax, 1 cpuid mov sig1, eax mov eax, 3 cpuid mov sig2, ecx mov sig3, edx } // Then we convert the data to an readable string sprintf(CPUInfo.strProcessorSerial, "%04lX-%04lX-%04lX-%04lX-%04lX-%04lX", sig1 >> 16, sig1 & 0xFFFF, sig3 >> 16, sig3 & 0xFFFF, sig2 >> 16, sig2 & 0xFFFF); } else { // If there's no serial number support we just mark put "No serial number" strcpy(CPUInfo.strProcessorSerial, "No Processor Serial Number"); } // Now we get the standard processor extensions GetStandardProcessorExtensions(); // And finally the processor configuration (caches, TLBs, ...) and translate // the data to readable strings GetStandardProcessorConfiguration(); TranslateProcessorConfiguration(); // At last... return true; } // bool CProcessor::AnalyzeAMDProcessor() // ====================================== // Private class function for analyzing an AMD processor //////////////////////////////////////////////////////// bool CProcessor::AnalyzeAMDProcessor() { unsigned long eaxreg, ebxreg, ecxreg, edxreg; // First of all we check if the CPUID command is available if (!CheckCPUIDPresence()) return 0; // Now we get the CPUID standard level 0x00000001 __asm { mov eax, 1 cpuid mov eaxreg, eax mov ebxreg, ebx mov edxreg, edx } // Then we mask the model, family, stepping and type (AMD does not support brand id) CPUInfo.uiStepping = eaxreg & 0xF; CPUInfo.uiModel = (eaxreg >> 4) & 0xF; CPUInfo.uiFamily = (eaxreg >> 8) & 0xF; CPUInfo.uiType = (eaxreg >> 12) & 0x3; // After that, we translate the processor type (see CProcessor::AnalyzeIntelProcessor() // for further comments on this) switch (CPUInfo.uiType) { case 0: strcpy(CPUInfo.strType, "Original OEM"); strcpy(strCPUName, CPUInfo.strType); strcat(strCPUName, " "); break; case 1: strcpy(CPUInfo.strType, "Overdrive"); strcpy(strCPUName, CPUInfo.strType); strcat(strCPUName, " "); break; case 2: strcpy(CPUInfo.strType, "Dual-capable"); strcpy(strCPUName, CPUInfo.strType); strcat(strCPUName, " "); break; case 3: strcpy(CPUInfo.strType, "Reserved"); break; default: strcpy(CPUInfo.strType, "Unknown"); break; } // Now we check if the processor supports the brand id string extended CPUID level if (CPUInfo.MaxSupportedExtendedLevel >= 0x80000004) { // If it supports the extended CPUID level 0x80000004 we read the data char tmp[52]; memset(tmp, 0, sizeof(tmp)); __asm { mov eax, 0x80000002 cpuid mov dword ptr [tmp], eax mov dword ptr [tmp+4], ebx mov dword ptr [tmp+8], ecx mov dword ptr [tmp+12], edx mov eax, 0x80000003 cpuid mov dword ptr [tmp+16], eax mov dword ptr [tmp+20], ebx mov dword ptr [tmp+24], ecx mov dword ptr [tmp+28], edx mov eax, 0x80000004 cpuid mov dword ptr [tmp+32], eax mov dword ptr [tmp+36], ebx mov dword ptr [tmp+40], ecx mov dword ptr [tmp+44], edx } // And copy it to the brand id string strcpy(CPUInfo.strBrandID, tmp); } else { // Or just tell there is no brand id string support strcpy(CPUInfo.strBrandID, "Not supported"); } // After that we translate the processor family switch(CPUInfo.uiFamily) { case 4: // Family = 4: 486 (80486) or 5x86 (80486) processor family switch (CPUInfo.uiModel) { case 3: // Thanks to AMD for this nice form of family case 7: // detection.... *grmpf* case 8: case 9: strcpy(CPUInfo.strFamily, "AMD 80486"); break; case 0xE: case 0xF: strcpy(CPUInfo.strFamily, "AMD 5x86"); break; default: strcpy(CPUInfo.strFamily, "Unknown family"); break; } break; case 5: // Family = 5: K5 or K6 processor family switch (CPUInfo.uiModel) { case 0: case 1: case 2: case 3: strcpy(CPUInfo.strFamily, "AMD K5"); break; case 6: case 7: case 8: case 9: strcpy(CPUInfo.strFamily, "AMD K6"); break; default: strcpy(CPUInfo.strFamily, "Unknown family"); break; } break; case 6: // Family = 6: K7 (Athlon, ...) processor family strcpy(CPUInfo.strFamily, "AMD K7"); break; default: // For security strcpy(CPUInfo.strFamily, "Unknown family"); break; } // After the family detection we come to the specific processor model // detection switch (CPUInfo.uiFamily) { case 4: // Family = 4: 486 (80486) or 5x85 (80486) processor family switch (CPUInfo.uiModel) { case 3: // Model = 3: 80486 DX2 strcpy(CPUInfo.strModel, "AMD 80486 DX2"); strcat(strCPUName, "AMD 80486 DX2"); break; case 7: // Model = 7: 80486 write-back enhanced DX2 strcpy(CPUInfo.strModel, "AMD 80486 write-back enhanced DX2"); strcat(strCPUName, "AMD 80486 write-back enhanced DX2"); break; case 8: // Model = 8: 80486 DX4 strcpy(CPUInfo.strModel, "AMD 80486 DX4"); strcat(strCPUName, "AMD 80486 DX4"); break; case 9: // Model = 9: 80486 write-back enhanced DX4 strcpy(CPUInfo.strModel, "AMD 80486 write-back enhanced DX4"); strcat(strCPUName, "AMD 80486 write-back enhanced DX4"); break; case 0xE: // Model = 0xE: 5x86 strcpy(CPUInfo.strModel, "AMD 5x86"); strcat(strCPUName, "AMD 5x86"); break; case 0xF: // Model = 0xF: 5x86 write-back enhanced (oh my god.....) strcpy(CPUInfo.strModel, "AMD 5x86 write-back enhanced"); strcat(strCPUName, "AMD 5x86 write-back enhanced"); break; default: // ... strcpy(CPUInfo.strModel, "Unknown AMD 80486 or 5x86 model"); strcat(strCPUName, "AMD 80486 or 5x86 (Unknown model)"); break; } break; case 5: // Family = 5: K5 / K6 processor family switch (CPUInfo.uiModel) { case 0: // Model = 0: K5 SSA 5 (Pentium Rating *ggg* 75, 90 and 100 Mhz) strcpy(CPUInfo.strModel, "AMD K5 SSA5 (PR75, PR90, PR100)"); strcat(strCPUName, "AMD K5 SSA5 (PR75, PR90, PR100)"); break; case 1: // Model = 1: K5 5k86 (PR 120 and 133 MHz) strcpy(CPUInfo.strModel, "AMD K5 5k86 (PR120, PR133)"); strcat(strCPUName, "AMD K5 5k86 (PR120, PR133)"); break; case 2: // Model = 2: K5 5k86 (PR 166 MHz) strcpy(CPUInfo.strModel, "AMD K5 5k86 (PR166)"); strcat(strCPUName, "AMD K5 5k86 (PR166)"); break; case 3: // Model = 3: K5 5k86 (PR 200 MHz) strcpy(CPUInfo.strModel, "AMD K5 5k86 (PR200)"); strcat(strCPUName, "AMD K5 5k86 (PR200)"); break; case 6: // Model = 6: K6 strcpy(CPUInfo.strModel, "AMD K6 (0.30 µm)"); strcat(strCPUName, "AMD K6 (0.30 µm)"); break; case 7: // Model = 7: K6 (0.25 µm) strcpy(CPUInfo.strModel, "AMD K6 (0.25 µm)"); strcat(strCPUName, "AMD K6 (0.25 µm)"); break; case 8: // Model = 8: K6-2 strcpy(CPUInfo.strModel, "AMD K6-2"); strcat(strCPUName, "AMD K6-2"); break; case 9: // Model = 9: K6-III strcpy(CPUInfo.strModel, "AMD K6-III"); strcat(strCPUName, "AMD K6-III"); break; case 0xD: // Model = 0xD: K6-2+ / K6-III+ strcpy(CPUInfo.strModel, "AMD K6-2+ or K6-III+ (0.18 µm)"); strcat(strCPUName, "AMD K6-2+ or K6-III+ (0.18 µm)"); break; default: // ... strcpy(CPUInfo.strModel, "Unknown AMD K5 or K6 model"); strcat(strCPUName, "AMD K5 or K6 (Unknown model)"); break; } break; case 6: // Family = 6: K7 processor family (AMDs first good processors) switch (CPUInfo.uiModel) { case 1: // Athlon strcpy(CPUInfo.strModel, "AMD Athlon (0.25 µm)"); strcat(strCPUName, "AMD Athlon (0.25 µm)"); break; case 2: // Athlon (0.18 µm) strcpy(CPUInfo.strModel, "AMD Athlon (0.18 µm)"); strcat(strCPUName, "AMD Athlon (0.18 µm)"); break; case 3: // Duron (Spitfire core) strcpy(CPUInfo.strModel, "AMD Duron (Spitfire)"); strcat(strCPUName, "AMD Duron (Spitfire core)"); break; case 4: // Athlon (Thunderbird core) strcpy(CPUInfo.strModel, "AMD Athlon (Thunderbird)"); strcat(strCPUName, "AMD Athlon (Thunderbird core)"); break; case 6: // Athlon MP / Mobile Athlon (Palomino core) strcpy(CPUInfo.strModel, "AMD Athlon MP/Mobile Athlon (Palomino)"); strcat(strCPUName, "AMD Athlon MP/Mobile Athlon (Palomino core)"); break; case 7: // Mobile Duron (Morgan core) strcpy(CPUInfo.strModel, "AMD Mobile Duron (Morgan)"); strcat(strCPUName, "AMD Mobile Duron (Morgan core)"); break; default: // ... strcpy(CPUInfo.strModel, "Unknown AMD K7 model"); strcat(strCPUName, "AMD K7 (Unknown model)"); break; } break; default: // ... strcpy(CPUInfo.strModel, "Unknown AMD model"); strcat(strCPUName, "AMD (Unknown model)"); break; } // Now we read the standard processor extension that are stored in the same // way the Intel standard extensions are GetStandardProcessorExtensions(); // Then we check if theres an extended CPUID level support if (CPUInfo.MaxSupportedExtendedLevel >= 0x80000001) { // If we can access the extended CPUID level 0x80000001 we get the // edx register __asm { mov eax, 0x80000001 cpuid mov edxreg, edx } // Now we can mask some AMD specific cpu extensions CPUInfo._Ext.EMMX_MultimediaExtensions = CheckBit(edxreg, 22); CPUInfo._Ext.AA64_AMD64BitArchitecture = CheckBit(edxreg, 29); CPUInfo._Ext._E3DNOW_InstructionExtensions = CheckBit(edxreg, 30); CPUInfo._Ext._3DNOW_InstructionExtensions = CheckBit(edxreg, 31); } // After that we check if the processor supports the ext. CPUID level // 0x80000006 if (CPUInfo.MaxSupportedExtendedLevel >= 0x80000006) { // If it's present, we read it out __asm { mov eax, 0x80000005 cpuid mov eaxreg, eax mov ebxreg, ebx mov ecxreg, ecx mov edxreg, edx } // Then we mask the L1 Data TLB information if ((ebxreg >> 16) && (eaxreg >> 16)) { CPUInfo._Data.bPresent = true; strcpy(CPUInfo._Data.strPageSize, "4 KB / 2 MB / 4MB"); CPUInfo._Data.uiAssociativeWays = (eaxreg >> 24) & 0xFF; CPUInfo._Data.uiEntries = (eaxreg >> 16) & 0xFF; } else if (eaxreg >> 16) { CPUInfo._Data.bPresent = true; strcpy(CPUInfo._Data.strPageSize, "2 MB / 4MB"); CPUInfo._Data.uiAssociativeWays = (eaxreg >> 24) & 0xFF; CPUInfo._Data.uiEntries = (eaxreg >> 16) & 0xFF; } else if (ebxreg >> 16) { CPUInfo._Data.bPresent = true; strcpy(CPUInfo._Data.strPageSize, "4 KB"); CPUInfo._Data.uiAssociativeWays = (ebxreg >> 24) & 0xFF; CPUInfo._Data.uiEntries = (ebxreg >> 16) & 0xFF; } if (CPUInfo._Data.uiAssociativeWays == 0xFF) CPUInfo._Data.uiAssociativeWays = (unsigned int) -1; // Now the L1 Instruction/Code TLB information if ((ebxreg & 0xFFFF) && (eaxreg & 0xFFFF)) { CPUInfo._Instruction.bPresent = true; strcpy(CPUInfo._Instruction.strPageSize, "4 KB / 2 MB / 4MB"); CPUInfo._Instruction.uiAssociativeWays = (eaxreg >> 8) & 0xFF; CPUInfo._Instruction.uiEntries = eaxreg & 0xFF; } else if (eaxreg & 0xFFFF) { CPUInfo._Instruction.bPresent = true; strcpy(CPUInfo._Instruction.strPageSize, "2 MB / 4MB"); CPUInfo._Instruction.uiAssociativeWays = (eaxreg >> 8) & 0xFF; CPUInfo._Instruction.uiEntries = eaxreg & 0xFF; } else if (ebxreg & 0xFFFF) { CPUInfo._Instruction.bPresent = true; strcpy(CPUInfo._Instruction.strPageSize, "4 KB"); CPUInfo._Instruction.uiAssociativeWays = (ebxreg >> 8) & 0xFF; CPUInfo._Instruction.uiEntries = ebxreg & 0xFF; } if (CPUInfo._Instruction.uiAssociativeWays == 0xFF) CPUInfo._Instruction.uiAssociativeWays = (unsigned int) -1; // Then we read the L1 data cache information if ((ecxreg >> 24) > 0) { CPUInfo._L1.Data.bPresent = true; sprintf(CPUInfo._L1.Data.strSize, "%d KB", ecxreg >> 24); CPUInfo._L1.Data.uiAssociativeWays = (ecxreg >> 15) & 0xFF; CPUInfo._L1.Data.uiLineSize = ecxreg & 0xFF; } // After that we read the L2 instruction/code cache information if ((edxreg >> 24) > 0) { CPUInfo._L1.Instruction.bPresent = true; sprintf(CPUInfo._L1.Instruction.strSize, "%d KB", edxreg >> 24); CPUInfo._L1.Instruction.uiAssociativeWays = (edxreg >> 15) & 0xFF; CPUInfo._L1.Instruction.uiLineSize = edxreg & 0xFF; } // Note: I'm not absolutely sure that the L1 page size code (the // 'if/else if/else if' structs above) really detects the real page // size for the TLB. Somebody should check it.... // Now we read the ext. CPUID level 0x80000006 __asm { mov eax, 0x80000006 cpuid mov eaxreg, eax mov ebxreg, ebx mov ecxreg, ecx } // We only mask the unified L2 cache masks (never heard of an // L2 cache that is divided in data and code parts) if (((ecxreg >> 12) & 0xF) > 0) { CPUInfo._L2.bPresent = true; sprintf(CPUInfo._L2.strSize, "%d KB", ecxreg >> 16); switch ((ecxreg >> 12) & 0xF) { case 1: CPUInfo._L2.uiAssociativeWays = 1; break; case 2: CPUInfo._L2.uiAssociativeWays = 2; break; case 4: CPUInfo._L2.uiAssociativeWays = 4; break; case 6: CPUInfo._L2.uiAssociativeWays = 8; break; case 8: CPUInfo._L2.uiAssociativeWays = 16; break; case 0xF: CPUInfo._L2.uiAssociativeWays = (unsigned int) -1; break; default: CPUInfo._L2.uiAssociativeWays = 0; break; } CPUInfo._L2.uiLineSize = ecxreg & 0xFF; } } else { // If we could not detect the ext. CPUID level 0x80000006 we // try to read the standard processor configuration. GetStandardProcessorConfiguration(); } // After reading we translate the configuration to strings TranslateProcessorConfiguration(); // And finally exit return true; } // bool CProcessor::AnalyzeUnknownProcessor() // ========================================== // Private class function to analyze an unknown (No Intel or AMD) processor /////////////////////////////////////////////////////////////////////////// bool CProcessor::AnalyzeUnknownProcessor() { unsigned long eaxreg, ebxreg; // We check if the CPUID command is available if (!CheckCPUIDPresence()) return false; // First of all we read the standard CPUID level 0x00000001 // This level should be available on every x86-processor clone __asm { mov eax, 1 cpuid mov eaxreg, eax mov ebxreg, ebx } // Then we mask the processor model, family, type and stepping CPUInfo.uiStepping = eaxreg & 0xF; CPUInfo.uiModel = (eaxreg >> 4) & 0xF; CPUInfo.uiFamily = (eaxreg >> 8) & 0xF; CPUInfo.uiType = (eaxreg >> 12) & 0x3; // To have complete information we also mask the brand id CPUInfo.uiBrandID = ebxreg & 0xF; // Then we get the standard processor extensions GetStandardProcessorExtensions(); // Now we mark everything we do not know as unknown strcpy(strCPUName, "Unknown"); strcpy(CPUInfo._Data.strTLB, "Unknown"); strcpy(CPUInfo._Instruction.strTLB, "Unknown"); strcpy(CPUInfo._Trace.strCache, "Unknown"); strcpy(CPUInfo._L1.Data.strCache, "Unknown"); strcpy(CPUInfo._L1.Instruction.strCache, "Unknown"); strcpy(CPUInfo._L2.strCache, "Unknown"); strcpy(CPUInfo._L3.strCache, "Unknown"); strcpy(CPUInfo.strProcessorSerial, "Unknown / Not supported"); // For the family, model and brand id we can only print the numeric value sprintf(CPUInfo.strBrandID, "Brand-ID number %d", CPUInfo.uiBrandID); sprintf(CPUInfo.strFamily, "Family number %d", CPUInfo.uiFamily); sprintf(CPUInfo.strModel, "Model number %d", CPUInfo.uiModel); // Nevertheless we can determine the processor type switch (CPUInfo.uiType) { case 0: strcpy(CPUInfo.strType, "Original OEM"); break; case 1: strcpy(CPUInfo.strType, "Overdrive"); break; case 2: strcpy(CPUInfo.strType, "Dual-capable"); break; case 3: strcpy(CPUInfo.strType, "Reserved"); break; default: strcpy(CPUInfo.strType, "Unknown"); break; } // And thats it return true; } // bool CProcessor::CheckCPUIDPresence() // ===================================== // This function checks if the CPUID command is available on the current // processor //////////////////////////////////////////////////////////////////////// bool CProcessor::CheckCPUIDPresence() { unsigned long BitChanged; // We've to check if we can toggle the flag register bit 21 // If we can't the processor does not support the CPUID command __asm { pushfd pop eax mov ebx, eax xor eax, 0x00200000 push eax popfd pushfd pop eax xor eax,ebx mov BitChanged, eax } return ((BitChanged) ? true : false); } // void CProcessor::DecodeProcessorConfiguration(unsigned int cfg) // =============================================================== // This function (or switch ?!) just translates a one-byte processor configuration // byte to understandable values ////////////////////////////////////////////////////////////////////////////////// void CProcessor::DecodeProcessorConfiguration(unsigned int cfg) { // First we ensure that there's only one single byte cfg &= 0xFF; // Then we do a big switch switch(cfg) { case 0: // cfg = 0: Unused break; case 0x1: // cfg = 0x1: code TLB present, 4 KB pages, 4 ways, 32 entries CPUInfo._Instruction.bPresent = true; strcpy(CPUInfo._Instruction.strPageSize, "4 KB"); CPUInfo._Instruction.uiAssociativeWays = 4; CPUInfo._Instruction.uiEntries = 32; break; case 0x2: // cfg = 0x2: code TLB present, 4 MB pages, fully associative, 2 entries CPUInfo._Instruction.bPresent = true; strcpy(CPUInfo._Instruction.strPageSize, "4 MB"); CPUInfo._Instruction.uiAssociativeWays = 4; CPUInfo._Instruction.uiEntries = 2; break; case 0x3: // cfg = 0x3: data TLB present, 4 KB pages, 4 ways, 64 entries CPUInfo._Data.bPresent = true; strcpy(CPUInfo._Data.strPageSize, "4 KB"); CPUInfo._Data.uiAssociativeWays = 4; CPUInfo._Data.uiEntries = 64; break; case 0x4: // cfg = 0x4: data TLB present, 4 MB pages, 4 ways, 8 entries CPUInfo._Data.bPresent = true; strcpy(CPUInfo._Data.strPageSize, "4 MB"); CPUInfo._Data.uiAssociativeWays = 4; CPUInfo._Data.uiEntries = 8; break; case 0x6: // cfg = 0x6: code L1 cache present, 8 KB, 4 ways, 32 byte lines CPUInfo._L1.Instruction.bPresent = true; strcpy(CPUInfo._L1.Instruction.strSize, "8 KB"); CPUInfo._L1.Instruction.uiAssociativeWays = 4; CPUInfo._L1.Instruction.uiLineSize = 32; break; case 0x8: // cfg = 0x8: code L1 cache present, 16 KB, 4 ways, 32 byte lines CPUInfo._L1.Instruction.bPresent = true; strcpy(CPUInfo._L1.Instruction.strSize, "16 KB"); CPUInfo._L1.Instruction.uiAssociativeWays = 4; CPUInfo._L1.Instruction.uiLineSize = 32; break; case 0xA: // cfg = 0xA: data L1 cache present, 8 KB, 2 ways, 32 byte lines CPUInfo._L1.Data.bPresent = true; strcpy(CPUInfo._L1.Data.strSize, "8 KB"); CPUInfo._L1.Data.uiAssociativeWays = 2; CPUInfo._L1.Data.uiLineSize = 32; break; case 0xC: // cfg = 0xC: data L1 cache present, 16 KB, 4 ways, 32 byte lines CPUInfo._L1.Data.bPresent = true; strcpy(CPUInfo._L1.Data.strSize, "16 KB"); CPUInfo._L1.Data.uiAssociativeWays = 4; CPUInfo._L1.Data.uiLineSize = 32; break; case 0x22: // cfg = 0x22: code and data L3 cache present, 512 KB, 4 ways, 64 byte lines, sectored CPUInfo._L3.bPresent = true; strcpy(CPUInfo._L3.strSize, "512 KB"); CPUInfo._L3.uiAssociativeWays = 4; CPUInfo._L3.uiLineSize = 64; CPUInfo._L3.bSectored = true; break; case 0x23: // cfg = 0x23: code and data L3 cache present, 1024 KB, 8 ways, 64 byte lines, sectored CPUInfo._L3.bPresent = true; strcpy(CPUInfo._L3.strSize, "1024 KB"); CPUInfo._L3.uiAssociativeWays = 8; CPUInfo._L3.uiLineSize = 64; CPUInfo._L3.bSectored = true; break; case 0x25: // cfg = 0x25: code and data L3 cache present, 2048 KB, 8 ways, 64 byte lines, sectored CPUInfo._L3.bPresent = true; strcpy(CPUInfo._L3.strSize, "2048 KB"); CPUInfo._L3.uiAssociativeWays = 8; CPUInfo._L3.uiLineSize = 64; CPUInfo._L3.bSectored = true; break; case 0x29: // cfg = 0x29: code and data L3 cache present, 4096 KB, 8 ways, 64 byte lines, sectored CPUInfo._L3.bPresent = true; strcpy(CPUInfo._L3.strSize, "4096 KB"); CPUInfo._L3.uiAssociativeWays = 8; CPUInfo._L3.uiLineSize = 64; CPUInfo._L3.bSectored = true; break; case 0x40: // cfg = 0x40: no integrated L2 cache (P6 core) or L3 cache (P4 core) break; case 0x41: // cfg = 0x41: code and data L2 cache present, 128 KB, 4 ways, 32 byte lines CPUInfo._L2.bPresent = true; strcpy(CPUInfo._L2.strSize, "128 KB"); CPUInfo._L2.uiAssociativeWays = 4; CPUInfo._L2.uiLineSize = 32; break; case 0x42: // cfg = 0x42: code and data L2 cache present, 256 KB, 4 ways, 32 byte lines CPUInfo._L2.bPresent = true; strcpy(CPUInfo._L2.strSize, "256 KB"); CPUInfo._L2.uiAssociativeWays = 4; CPUInfo._L2.uiLineSize = 32; break; case 0x43: // cfg = 0x43: code and data L2 cache present, 512 KB, 4 ways, 32 byte lines CPUInfo._L2.bPresent = true; strcpy(CPUInfo._L2.strSize, "512 KB"); CPUInfo._L2.uiAssociativeWays = 4; CPUInfo._L2.uiLineSize = 32; break; case 0x44: // cfg = 0x44: code and data L2 cache present, 1024 KB, 4 ways, 32 byte lines CPUInfo._L2.bPresent = true; strcpy(CPUInfo._L2.strSize, "1 MB"); CPUInfo._L2.uiAssociativeWays = 4; CPUInfo._L2.uiLineSize = 32; break; case 0x45: // cfg = 0x45: code and data L2 cache present, 2048 KB, 4 ways, 32 byte lines CPUInfo._L2.bPresent = true; strcpy(CPUInfo._L2.strSize, "2 MB"); CPUInfo._L2.uiAssociativeWays = 4; CPUInfo._L2.uiLineSize = 32; break; case 0x50: // cfg = 0x50: code TLB present, 4 KB / 4 MB / 2 MB pages, fully associative, 64 entries CPUInfo._Instruction.bPresent = true; strcpy(CPUInfo._Instruction.strPageSize, "4 KB / 2 MB / 4 MB"); CPUInfo._Instruction.uiAssociativeWays = (unsigned int) -1; CPUInfo._Instruction.uiEntries = 64; break; case 0x51: // cfg = 0x51: code TLB present, 4 KB / 4 MB / 2 MB pages, fully associative, 128 entries CPUInfo._Instruction.bPresent = true; strcpy(CPUInfo._Instruction.strPageSize, "4 KB / 2 MB / 4 MB"); CPUInfo._Instruction.uiAssociativeWays = (unsigned int) -1; CPUInfo._Instruction.uiEntries = 128; break; case 0x52: // cfg = 0x52: code TLB present, 4 KB / 4 MB / 2 MB pages, fully associative, 256 entries CPUInfo._Instruction.bPresent = true; strcpy(CPUInfo._Instruction.strPageSize, "4 KB / 2 MB / 4 MB"); CPUInfo._Instruction.uiAssociativeWays = (unsigned int) -1; CPUInfo._Instruction.uiEntries = 256; break; case 0x5B: // cfg = 0x5B: data TLB present, 4 KB / 4 MB pages, fully associative, 64 entries CPUInfo._Data.bPresent = true; strcpy(CPUInfo._Data.strPageSize, "4 KB / 4 MB"); CPUInfo._Data.uiAssociativeWays = (unsigned int) -1; CPUInfo._Data.uiEntries = 64; break; case 0x5C: // cfg = 0x5C: data TLB present, 4 KB / 4 MB pages, fully associative, 128 entries CPUInfo._Data.bPresent = true; strcpy(CPUInfo._Data.strPageSize, "4 KB / 4 MB"); CPUInfo._Data.uiAssociativeWays = (unsigned int) -1; CPUInfo._Data.uiEntries = 128; break; case 0x5d: // cfg = 0x5D: data TLB present, 4 KB / 4 MB pages, fully associative, 256 entries CPUInfo._Data.bPresent = true; strcpy(CPUInfo._Data.strPageSize, "4 KB / 4 MB"); CPUInfo._Data.uiAssociativeWays = (unsigned int) -1; CPUInfo._Data.uiEntries = 256; break; case 0x66: // cfg = 0x66: data L1 cache present, 8 KB, 4 ways, 64 byte lines, sectored CPUInfo._L1.Data.bPresent = true; strcpy(CPUInfo._L1.Data.strSize, "8 KB"); CPUInfo._L1.Data.uiAssociativeWays = 4; CPUInfo._L1.Data.uiLineSize = 64; break; case 0x67: // cfg = 0x67: data L1 cache present, 16 KB, 4 ways, 64 byte lines, sectored CPUInfo._L1.Data.bPresent = true; strcpy(CPUInfo._L1.Data.strSize, "16 KB"); CPUInfo._L1.Data.uiAssociativeWays = 4; CPUInfo._L1.Data.uiLineSize = 64; break; case 0x68: // cfg = 0x68: data L1 cache present, 32 KB, 4 ways, 64 byte lines, sectored CPUInfo._L1.Data.bPresent = true; strcpy(CPUInfo._L1.Data.strSize, "32 KB"); CPUInfo._L1.Data.uiAssociativeWays = 4; CPUInfo._L1.Data.uiLineSize = 64; break; case 0x70: // cfg = 0x70: trace L1 cache present, 12 KµOPs, 4 ways CPUInfo._Trace.bPresent = true; strcpy(CPUInfo._Trace.strSize, "12 K-micro-ops"); CPUInfo._Trace.uiAssociativeWays = 4; break; case 0x71: // cfg = 0x71: trace L1 cache present, 16 KµOPs, 4 ways CPUInfo._Trace.bPresent = true; strcpy(CPUInfo._Trace.strSize, "16 K-micro-ops"); CPUInfo._Trace.uiAssociativeWays = 4; break; case 0x72: // cfg = 0x72: trace L1 cache present, 32 KµOPs, 4 ways CPUInfo._Trace.bPresent = true; strcpy(CPUInfo._Trace.strSize, "32 K-micro-ops"); CPUInfo._Trace.uiAssociativeWays = 4; break; case 0x79: // cfg = 0x79: code and data L2 cache present, 128 KB, 8 ways, 64 byte lines, sectored CPUInfo._L2.bPresent = true; strcpy(CPUInfo._L2.strSize, "128 KB"); CPUInfo._L2.uiAssociativeWays = 8; CPUInfo._L2.uiLineSize = 64; CPUInfo._L2.bSectored = true; break; case 0x7A: // cfg = 0x7A: code and data L2 cache present, 256 KB, 8 ways, 64 byte lines, sectored CPUInfo._L2.bPresent = true; strcpy(CPUInfo._L2.strSize, "256 KB"); CPUInfo._L2.uiAssociativeWays = 8; CPUInfo._L2.uiLineSize = 64; CPUInfo._L2.bSectored = true; break; case 0x7B: // cfg = 0x7B: code and data L2 cache present, 512 KB, 8 ways, 64 byte lines, sectored CPUInfo._L2.bPresent = true; strcpy(CPUInfo._L2.strSize, "512 KB"); CPUInfo._L2.uiAssociativeWays = 8; CPUInfo._L2.uiLineSize = 64; CPUInfo._L2.bSectored = true; break; case 0x7C: // cfg = 0x7C: code and data L2 cache present, 1024 KB, 8 ways, 64 byte lines, sectored CPUInfo._L2.bPresent = true; strcpy(CPUInfo._L2.strSize, "1 MB"); CPUInfo._L2.uiAssociativeWays = 8; CPUInfo._L2.uiLineSize = 64; CPUInfo._L2.bSectored = true; break; case 0x81: // cfg = 0x81: code and data L2 cache present, 128 KB, 8 ways, 32 byte lines CPUInfo._L2.bPresent = true; strcpy(CPUInfo._L2.strSize, "128 KB"); CPUInfo._L2.uiAssociativeWays = 8; CPUInfo._L2.uiLineSize = 32; break; case 0x82: // cfg = 0x82: code and data L2 cache present, 256 KB, 8 ways, 32 byte lines CPUInfo._L2.bPresent = true; strcpy(CPUInfo._L2.strSize, "256 KB"); CPUInfo._L2.uiAssociativeWays = 8; CPUInfo._L2.uiLineSize = 32; break; case 0x83: // cfg = 0x83: code and data L2 cache present, 512 KB, 8 ways, 32 byte lines CPUInfo._L2.bPresent = true; strcpy(CPUInfo._L2.strSize, "512 KB"); CPUInfo._L2.uiAssociativeWays = 8; CPUInfo._L2.uiLineSize = 32; break; case 0x84: // cfg = 0x84: code and data L2 cache present, 1024 KB, 8 ways, 32 byte lines CPUInfo._L2.bPresent = true; strcpy(CPUInfo._L2.strSize, "1 MB"); CPUInfo._L2.uiAssociativeWays = 8; CPUInfo._L2.uiLineSize = 32; break; case 0x85: // cfg = 0x85: code and data L2 cache present, 2048 KB, 8 ways, 32 byte lines CPUInfo._L2.bPresent = true; strcpy(CPUInfo._L2.strSize, "2 MB"); CPUInfo._L2.uiAssociativeWays = 8; CPUInfo._L2.uiLineSize = 32; break; } } __forceinline static char *TranslateAssociativeWays(unsigned int uiWays, char *buf) { // We define 0xFFFFFFFF (= -1) as fully associative if (uiWays == ((unsigned int) -1)) strcpy(buf, "fully associative"); else { if (uiWays == 1) // A one way associative cache is just direct mapped strcpy(buf, "direct mapped"); else if (uiWays == 0) // This should not happen... strcpy(buf, "unknown associative ways"); else // The x-way associative cache sprintf(buf, "%d ways associative", uiWays); } // To ease the function use we return the buffer return buf; } __forceinline static void TranslateTLB(ProcessorTLB *tlb) { char buf[64]; // We just check if the TLB is present if (tlb->bPresent) sprintf(tlb->strTLB, "%s page size, %s, %d entries", tlb->strPageSize, TranslateAssociativeWays(tlb->uiAssociativeWays, buf), tlb->uiEntries); else strcpy(tlb->strTLB, "Not present"); } __forceinline static void TranslateCache(ProcessorCache *cache) { char buf[64]; // We just check if the cache is present if (cache->bPresent) { // If present we construct the string sprintf(cache->strCache, "%s cache size, %s, %d bytes line size", cache->strSize, TranslateAssociativeWays(cache->uiAssociativeWays, buf), cache->uiLineSize); if (cache->bSectored) strcat(cache->strCache, ", sectored"); } else { // Else we just say "Not present" strcpy(cache->strCache, "Not present"); } } // void CProcessor::TranslateProcessorConfiguration() // ================================================== // Private class function to translate the processor configuration values // to strings ///////////////////////////////////////////////////////////////////////// void CProcessor::TranslateProcessorConfiguration() { // We just call the small functions defined above TranslateTLB(&CPUInfo._Data); TranslateTLB(&CPUInfo._Instruction); TranslateCache(&CPUInfo._Trace); TranslateCache(&CPUInfo._L1.Instruction); TranslateCache(&CPUInfo._L1.Data); TranslateCache(&CPUInfo._L2); TranslateCache(&CPUInfo._L3); } // void CProcessor::GetStandardProcessorConfiguration() // ==================================================== // Private class function to read the standard processor configuration ////////////////////////////////////////////////////////////////////// void CProcessor::GetStandardProcessorConfiguration() { unsigned long eaxreg, ebxreg, ecxreg, edxreg; // We check if the CPUID function is available if (!CheckCPUIDPresence()) return; // First we check if the processor supports the standard // CPUID level 0x00000002 if (CPUInfo.MaxSupportedLevel >= 2) { // Now we go read the std. CPUID level 0x00000002 the first time unsigned long count, num = 255; for (count = 0; count < num; count++) { __asm { mov eax, 2 cpuid mov eaxreg, eax mov ebxreg, ebx mov ecxreg, ecx mov edxreg, edx } // We have to repeat this reading for 'num' times num = eaxreg & 0xFF; // Then we call the big decode switch function DecodeProcessorConfiguration(eaxreg >> 8); DecodeProcessorConfiguration(eaxreg >> 16); DecodeProcessorConfiguration(eaxreg >> 24); // If ebx contains additional data we also decode it if ((ebxreg & 0x80000000) == 0) { DecodeProcessorConfiguration(ebxreg); DecodeProcessorConfiguration(ebxreg >> 8); DecodeProcessorConfiguration(ebxreg >> 16); DecodeProcessorConfiguration(ebxreg >> 24); } // And also the ecx register if ((ecxreg & 0x80000000) == 0) { DecodeProcessorConfiguration(ecxreg); DecodeProcessorConfiguration(ecxreg >> 8); DecodeProcessorConfiguration(ecxreg >> 16); DecodeProcessorConfiguration(ecxreg >> 24); } // At last the edx processor register if ((edxreg & 0x80000000) == 0) { DecodeProcessorConfiguration(edxreg); DecodeProcessorConfiguration(edxreg >> 8); DecodeProcessorConfiguration(edxreg >> 16); DecodeProcessorConfiguration(edxreg >> 24); } } } } // void CProcessor::GetStandardProcessorExtensions() // ================================================= // Private class function to read the standard processor extensions /////////////////////////////////////////////////////////////////// void CProcessor::GetStandardProcessorExtensions() { unsigned long ebxreg, edxreg; // We check if the CPUID command is available if (!CheckCPUIDPresence()) return; // We just get the standard CPUID level 0x00000001 which should be // available on every x86 processor __asm { mov eax, 1 cpuid mov ebxreg, ebx mov edxreg, edx } // Then we mask some bits CPUInfo._Ext.FPU_FloatingPointUnit = CheckBit(edxreg, 0); CPUInfo._Ext.VME_Virtual8086ModeEnhancements = CheckBit(edxreg, 1); CPUInfo._Ext.DE_DebuggingExtensions = CheckBit(edxreg, 2); CPUInfo._Ext.PSE_PageSizeExtensions = CheckBit(edxreg, 3); CPUInfo._Ext.TSC_TimeStampCounter = CheckBit(edxreg, 4); CPUInfo._Ext.MSR_ModelSpecificRegisters = CheckBit(edxreg, 5); CPUInfo._Ext.PAE_PhysicalAddressExtension = CheckBit(edxreg, 6); CPUInfo._Ext.MCE_MachineCheckException = CheckBit(edxreg, 7); CPUInfo._Ext.CX8_COMPXCHG8B_Instruction = CheckBit(edxreg, 8); CPUInfo._Ext.APIC_AdvancedProgrammableInterruptController = CheckBit(edxreg, 9); CPUInfo._Ext.APIC_ID = (ebxreg >> 24) & 0xFF; CPUInfo._Ext.SEP_FastSystemCall = CheckBit(edxreg, 11); CPUInfo._Ext.MTRR_MemoryTypeRangeRegisters = CheckBit(edxreg, 12); CPUInfo._Ext.PGE_PTE_GlobalFlag = CheckBit(edxreg, 13); CPUInfo._Ext.MCA_MachineCheckArchitecture = CheckBit(edxreg, 14); CPUInfo._Ext.CMOV_ConditionalMoveAndCompareInstructions = CheckBit(edxreg, 15); CPUInfo._Ext.FGPAT_PageAttributeTable = CheckBit(edxreg, 16); CPUInfo._Ext.PSE36_36bitPageSizeExtension = CheckBit(edxreg, 17); CPUInfo._Ext.PN_ProcessorSerialNumber = CheckBit(edxreg, 18); CPUInfo._Ext.CLFSH_CFLUSH_Instruction = CheckBit(edxreg, 19); CPUInfo._Ext.CLFLUSH_InstructionCacheLineSize = (ebxreg >> 8) & 0xFF; CPUInfo._Ext.DS_DebugStore = CheckBit(edxreg, 21); CPUInfo._Ext.ACPI_ThermalMonitorAndClockControl = CheckBit(edxreg, 22); CPUInfo._Ext.MMX_MultimediaExtensions = CheckBit(edxreg, 23); CPUInfo._Ext.FXSR_FastStreamingSIMD_ExtensionsSaveRestore = CheckBit(edxreg, 24); CPUInfo._Ext.SSE_StreamingSIMD_Extensions = CheckBit(edxreg, 25); CPUInfo._Ext.SSE2_StreamingSIMD2_Extensions = CheckBit(edxreg, 26); CPUInfo._Ext.SS_SelfSnoop = CheckBit(edxreg, 27); CPUInfo._Ext.HT_HyperThreading = CheckBit(edxreg, 28); CPUInfo._Ext.HT_HyterThreadingSiblings = (ebxreg >> 16) & 0xFF; CPUInfo._Ext.TM_ThermalMonitor = CheckBit(edxreg, 29); CPUInfo._Ext.IA64_Intel64BitArchitecture = CheckBit(edxreg, 30); } // const ProcessorInfo *CProcessor::GetCPUInfo() // ============================================= // Calls all the other detection function to create an detailed // processor information /////////////////////////////////////////////////////////////// const ProcessorInfo *CProcessor::GetCPUInfo() { unsigned long eaxreg, ebxreg, ecxreg, edxreg; // First of all we check if the CPUID command is available if (!CheckCPUIDPresence()) return NULL; // We read the standard CPUID level 0x00000000 which should // be available on every x86 processor __asm { mov eax, 0 cpuid mov eaxreg, eax mov ebxreg, ebx mov edxreg, edx mov ecxreg, ecx } // Then we connect the single register values to the vendor string *((unsigned long *) CPUInfo.strVendor) = ebxreg; *((unsigned long *) (CPUInfo.strVendor+4)) = edxreg; *((unsigned long *) (CPUInfo.strVendor+8)) = ecxreg; // We can also read the max. supported standard CPUID level CPUInfo.MaxSupportedLevel = eaxreg & 0xFFFF; // Then we read the ext. CPUID level 0x80000000 __asm { mov eax, 0x80000000 cpuid mov eaxreg, eax } // ...to check the max. supportted extended CPUID level CPUInfo.MaxSupportedExtendedLevel = eaxreg; // Then we switch to the specific processor vendors switch (ebxreg) { case 0x756E6547: // GenuineIntel AnalyzeIntelProcessor(); break; case 0x68747541: // AuthenticAMD AnalyzeAMDProcessor(); break; case 0x69727943: // CyrixInstead // I really do not know anyone owning such a piece of crab // So we analyze it as an unknown processor *ggggg* default: AnalyzeUnknownProcessor(); break; } // After all we return the class CPUInfo member var return (&CPUInfo); } // bool CProcessor::CPUInfoToText(char *strBuffer, unsigned int uiMaxLen) // ====================================================================== // Gets the frequency and processor information and writes it to a string ///////////////////////////////////////////////////////////////////////// bool CProcessor::CPUInfoToText(char *strBuffer, unsigned int uiMaxLen) { #define LENCHECK len = (unsigned int) strlen(buf); if (len >= uiMaxLen) return false; strcpy(strBuffer, buf); strBuffer += len; #define COPYADD(str) strcpy(buf, str); LENCHECK; #define FORMATADD(format, var) sprintf(buf, format, var); LENCHECK; #define BOOLADD(str, boolvar) COPYADD(str); if (boolvar) { COPYADD(" Yes\n"); } else { COPYADD(" No\n"); } char buf[1024]; unsigned int len; // First we have to get the frequency GetCPUFrequency(50); // Then we get the processor information GetCPUInfo(); // Now we construct the string (see the macros at function beginning) strBuffer[0] = 0; COPYADD("// CPU General Information\n//////////////////////////\n"); FORMATADD("Processor name: %s\n", strCPUName); FORMATADD("Frequency: %.2f MHz\n\n", (float) uqwFrequency / 1000000.0f); FORMATADD("Vendor: %s\n", CPUInfo.strVendor); FORMATADD("Family: %s\n", CPUInfo.strFamily); FORMATADD("Extended family: %d\n", CPUInfo.uiExtendedFamily); FORMATADD("Model: %s\n", CPUInfo.strModel); FORMATADD("Extended model: %d\n", CPUInfo.uiExtendedModel); FORMATADD("Type: %s\n", CPUInfo.strType); FORMATADD("Brand ID: %s\n", CPUInfo.strBrandID); if (CPUInfo._Ext.PN_ProcessorSerialNumber) { FORMATADD("Processor Serial: %s\n", CPUInfo.strProcessorSerial); } else { COPYADD("Processor Serial: Disabled\n"); } COPYADD("\n\n// CPU Configuration\n////////////////////\n"); FORMATADD("L1 instruction cache: %s\n", CPUInfo._L1.Instruction.strCache); FORMATADD("L1 data cache: %s\n", CPUInfo._L1.Data.strCache); FORMATADD("L2 cache: %s\n", CPUInfo._L2.strCache); FORMATADD("L3 cache: %s\n", CPUInfo._L3.strCache); FORMATADD("Trace cache: %s\n", CPUInfo._Trace.strCache); FORMATADD("Instruction TLB: %s\n", CPUInfo._Instruction.strTLB); FORMATADD("Data TLB: %s\n", CPUInfo._Data.strTLB); FORMATADD("Max Supported CPUID-Level: 0x%08lX\n", CPUInfo.MaxSupportedLevel); FORMATADD("Max Supported Ext. CPUID-Level: 0x%08lX\n", CPUInfo.MaxSupportedExtendedLevel); COPYADD("\n\n// CPU Extensions\n/////////////////\n"); BOOLADD("AA64 AMD 64-bit Architecture: ", CPUInfo._Ext.AA64_AMD64BitArchitecture); BOOLADD("ACPI Thermal Monitor And Clock Control: ", CPUInfo._Ext.ACPI_ThermalMonitorAndClockControl); BOOLADD("APIC Advanced Programmable Interrupt Controller: ", CPUInfo._Ext.APIC_AdvancedProgrammableInterruptController); FORMATADD(" APIC-ID: %d\n", CPUInfo._Ext.APIC_ID); BOOLADD("CLFSH CLFLUSH Instruction Presence: ", CPUInfo._Ext.CLFSH_CFLUSH_Instruction); FORMATADD(" CLFLUSH Instruction Cache Line Size: %d\n", CPUInfo._Ext.CLFLUSH_InstructionCacheLineSize); BOOLADD("CMOV Conditional Move And Compare Instructions: ", CPUInfo._Ext.CMOV_ConditionalMoveAndCompareInstructions); BOOLADD("CX8 COMPXCHG8B Instruction: ", CPUInfo._Ext.CX8_COMPXCHG8B_Instruction); BOOLADD("DE Debugging Extensions: ", CPUInfo._Ext.DE_DebuggingExtensions); BOOLADD("DS Debug Store: ", CPUInfo._Ext.DS_DebugStore); BOOLADD("FGPAT Page Attribute Table: ", CPUInfo._Ext.FGPAT_PageAttributeTable); BOOLADD("FPU Floating Point Unit: ", CPUInfo._Ext.FPU_FloatingPointUnit); BOOLADD("FXSR Fast Streaming SIMD Extensions Save/Restore:", CPUInfo._Ext.FXSR_FastStreamingSIMD_ExtensionsSaveRestore); BOOLADD("HT Hyper Threading: ", CPUInfo._Ext.HT_HyperThreading); BOOLADD("IA64 Intel 64-Bit Architecture: ", CPUInfo._Ext.IA64_Intel64BitArchitecture); BOOLADD("MCA Machine Check Architecture: ", CPUInfo._Ext.MCA_MachineCheckArchitecture); BOOLADD("MCE Machine Check Exception: ", CPUInfo._Ext.MCE_MachineCheckException); BOOLADD("MMX Multimedia Extensions: ", CPUInfo._Ext.MMX_MultimediaExtensions); BOOLADD("MMX+ Multimedia Extensions: ", CPUInfo._Ext.EMMX_MultimediaExtensions); BOOLADD("MSR Model Specific Registers: ", CPUInfo._Ext.MSR_ModelSpecificRegisters); BOOLADD("MTRR Memory Type Range Registers: ", CPUInfo._Ext.MTRR_MemoryTypeRangeRegisters); BOOLADD("PAE Physical Address Extension: ", CPUInfo._Ext.PAE_PhysicalAddressExtension); BOOLADD("PGE PTE Global Flag: ", CPUInfo._Ext.PGE_PTE_GlobalFlag); if (CPUInfo._Ext.PN_ProcessorSerialNumber) { FORMATADD("PN Processor Serial Number: %s\n", CPUInfo.strProcessorSerial); } else { COPYADD("PN Processor Serial Number: Disables\n"); } BOOLADD("PSE Page Size Extensions: ", CPUInfo._Ext.PSE_PageSizeExtensions); BOOLADD("PSE36 36-bit Page Size Extension: ", CPUInfo._Ext.PSE36_36bitPageSizeExtension); BOOLADD("SEP Fast System Call: ", CPUInfo._Ext.SEP_FastSystemCall); BOOLADD("SS Self Snoop: ", CPUInfo._Ext.SS_SelfSnoop); BOOLADD("SSE Streaming SIMD Extensions: ", CPUInfo._Ext.SSE_StreamingSIMD_Extensions); BOOLADD("SSE2 Streaming SIMD 2 Extensions: ", CPUInfo._Ext.SSE2_StreamingSIMD2_Extensions); BOOLADD("TM Thermal Monitor: ", CPUInfo._Ext.TM_ThermalMonitor); BOOLADD("TSC Time Stamp Counter: ", CPUInfo._Ext.TSC_TimeStampCounter); BOOLADD("VME Virtual 8086 Mode Enhancements: ", CPUInfo._Ext.VME_Virtual8086ModeEnhancements); BOOLADD("3DNow! Instructions: ", CPUInfo._Ext._3DNOW_InstructionExtensions); BOOLADD("Enhanced 3DNow! Instructions: ", CPUInfo._Ext._E3DNOW_InstructionExtensions); // Yippie!!! return true; } // bool CProcessor::WriteInfoTextFile(const char *strFilename) // =========================================================== // Takes use of CProcessor::CPUInfoToText and saves the string to a // file /////////////////////////////////////////////////////////////////// bool CProcessor::WriteInfoTextFile(const char *strFilename) { char buf[16384]; // First we get the string if (!CPUInfoToText(buf, 16383)) return false; // Then we create a new file (CREATE_ALWAYS) FILE *file = fopen(strFilename, "w"); if (!file) return false; // After that we write the string to the file unsigned long dwBytesToWrite, dwBytesWritten; dwBytesToWrite = (unsigned long) strlen(buf); dwBytesWritten = (unsigned long) fwrite(buf, 1, dwBytesToWrite, file); fclose(file); if (dwBytesToWrite != dwBytesWritten) return false; // Done return true; }