267 lines
8.0 KiB
C++
267 lines
8.0 KiB
C++
#ifndef PROCESSORINFO_H
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#define PROCESSORINFO_H
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class CProcessorInfo
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{
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protected:
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SYSTEM_INFO m_sysInfo;
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public:
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CProcessorInfo(void)
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{
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::GetSystemInfo(&m_sysInfo);
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}
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virtual ~CProcessorInfo(void)
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{
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}
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CStdString GetProcessorName(void)
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{
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CStdString sRC;
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CStdString sSpeed;
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CStdString sVendor;
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// Get the processor speed info.
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HKEY hKey;
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LONG result = ::RegOpenKeyEx (HKEY_LOCAL_MACHINE, _T("Hardware\\Description\\System\\CentralProcessor\\0"), 0, KEY_QUERY_VALUE, &hKey);
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// Check if the function has succeeded.
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if (result == ERROR_SUCCESS)
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{
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DWORD data;
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DWORD dataSize = sizeof(data);
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result = ::RegQueryValueEx (hKey, _T("~MHz"), NULL, NULL, (LPBYTE)&data, &dataSize);
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if (result == ERROR_SUCCESS)
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{
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sSpeed.Format ( _T("Speed: %dMHz "), data);
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}
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else
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{
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sSpeed = _T("Speed: Unknown ");
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}
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TCHAR vendorData [64];
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dataSize = sizeof (vendorData);
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result = ::RegQueryValueEx (hKey, _T("VendorIdentifier"), NULL, NULL, (LPBYTE)vendorData, &dataSize);
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if (result == ERROR_SUCCESS)
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{
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sVendor.Format ( _T("Vendor: %s "), vendorData);
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}
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else
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{
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sVendor = _T("Vendor: Unknown ");
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}
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}
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// Make sure to close the reg key
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RegCloseKey (hKey);
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CStdString sType;
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switch (m_sysInfo.dwProcessorType)
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{
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case PROCESSOR_INTEL_386:
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sType = _T("Type: Intel 386 ");
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break;
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case PROCESSOR_INTEL_486:
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sType = _T("Type: Intel 486 ");
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break;
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case PROCESSOR_INTEL_PENTIUM:
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sType = _T("Type: Intel Pentium compatible");
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break;
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case PROCESSOR_MIPS_R4000:
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sType = _T("Type: MIPS ");
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break;
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case PROCESSOR_ALPHA_21064:
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sType = _T("Type: Alpha ");
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break;
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default:
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sType = _T("Type: Unknown ");
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break;
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}
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CStdString sProcessors;
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sProcessors.Format( _T("Number Of Processors: %lu "), m_sysInfo.dwNumberOfProcessors);
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CStdString sArchitecture;
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CStdString sProcessorLevel;
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CStdString sStepping;
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switch(m_sysInfo.wProcessorArchitecture)
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{
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case PROCESSOR_ARCHITECTURE_INTEL:
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sArchitecture = _T("Architecture: Intel ");
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switch (m_sysInfo.wProcessorLevel)
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{
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case 3:
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sProcessorLevel = _T("Level: 80386");
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{
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int iSteppingLevel = m_sysInfo.wProcessorRevision / 100;
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int iStepping = m_sysInfo.wProcessorRevision % 100;
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sStepping.Format( _T("Stepping: %c%u "), iSteppingLevel, iStepping);
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}
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break;
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case 4:
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sProcessorLevel = _T("Level: 80486");
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{
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int iSteppingLevel = m_sysInfo.wProcessorRevision / 100;
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int iStepping = m_sysInfo.wProcessorRevision % 100;
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sStepping.Format( _T("Stepping: %c%u "), iSteppingLevel, iStepping);
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}
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break;
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case 5:
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sProcessorLevel = _T("Level: Pentium");
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{
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typedef BOOL (*PIPFP)(DWORD);
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PIPFP lpfn = (PIPFP)::GetProcAddress(GetModuleHandle( _T("kernel32.dll") ), "IsProcessorFeaturePresentA");
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if (lpfn)
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{
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if ((lpfn)(PF_MMX_INSTRUCTIONS_AVAILABLE))
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{
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sProcessorLevel += _T (" MMX");
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}
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}
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int iModel = m_sysInfo.wProcessorRevision / 100;
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int iStepping = m_sysInfo.wProcessorRevision % 100;
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sStepping.Format( _T("Stepping: %u-%u "), iModel, iStepping);
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}
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break;
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case 6:
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sProcessorLevel = _T("Level: Pentium II/Pro");
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{
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int iModel = m_sysInfo.wProcessorRevision / 100;
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int iStepping = m_sysInfo.wProcessorRevision % 100;
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sStepping.Format( _T("Stepping: %u-%u "), iModel, iStepping);
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}
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break;
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default:
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sProcessorLevel.Format( _T("Level: Unknown %u "), m_sysInfo.wProcessorLevel);
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{
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int iModel = m_sysInfo.wProcessorRevision / 100;
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int iStepping = m_sysInfo.wProcessorRevision % 100;
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sStepping.Format( _T("Stepping: %u-%u "), iModel, iStepping);
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}
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break;
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}
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break;
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case PROCESSOR_ARCHITECTURE_MIPS:
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sArchitecture = "Architecture: MIPS ";
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switch(m_sysInfo.wProcessorLevel)
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{
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case 0004:
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sProcessorLevel = "Level: R4000 ";
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break;
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default:
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sProcessorLevel.Format( _T("Level: Unknown %u "), m_sysInfo.wProcessorLevel);
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break;
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}
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sStepping.Format( _T("Stepping: 00%u"), m_sysInfo.wProcessorRevision);
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break;
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case PROCESSOR_ARCHITECTURE_ALPHA:
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sArchitecture = "Architecture: Alpha ";
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sProcessorLevel.Format( _T("Level: %u "), m_sysInfo.wProcessorLevel);
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{
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int iModel = m_sysInfo.wProcessorRevision / 100;
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int iStepping = m_sysInfo.wProcessorRevision % 100;
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sStepping.Format( _T("Stepping: %c%u "), iModel, iStepping);
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}
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break;
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case PROCESSOR_ARCHITECTURE_PPC:
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sArchitecture = _T("Architecture: PowerPC ");
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switch(m_sysInfo.wProcessorLevel)
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{
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case 1:
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sProcessorLevel = _T("Level: 601 ");
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break;
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case 3:
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sProcessorLevel = _T("Level: 603 ");
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break;
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case 4:
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sProcessorLevel = _T("Level: 604 ");
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break;
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case 6:
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sProcessorLevel = _T("Level: 603+ ");
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break;
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case 9:
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sProcessorLevel = _T("Level: 604+ ");
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break;
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case 20:
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sProcessorLevel = _T("Level: 620 ");
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break;
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default:
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sProcessorLevel.Format( _T("Level: Unknown %u "), m_sysInfo.wProcessorLevel);
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break;
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}
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{
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int iModel = m_sysInfo.wProcessorRevision / 100;
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int iStepping = m_sysInfo.wProcessorRevision % 100;
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sStepping.Format( _T("Stepping: %u.%u "), iModel, iStepping);
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}
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break;
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case PROCESSOR_ARCHITECTURE_UNKNOWN:
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sArchitecture = "Architecture: Unknown ";
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sProcessorLevel.Format( _T("Level: Unknown %u "), m_sysInfo.wProcessorLevel);
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{
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int iModel = m_sysInfo.wProcessorRevision / 100;
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int iStepping = m_sysInfo.wProcessorRevision % 100;
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sStepping.Format( _T("Stepping: %u-%u "), iModel, iStepping);
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}
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break;
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default:
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sArchitecture.Format( _T("Architecture: Unknown %u "), m_sysInfo.wProcessorArchitecture);
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sProcessorLevel.Format( _T("Level: Unknown %u "), m_sysInfo.wProcessorLevel);
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{
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int iModel = m_sysInfo.wProcessorRevision / 100;
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int iStepping = m_sysInfo.wProcessorRevision % 100;
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sStepping.Format( _T("Stepping: %u-%u "), iModel, iStepping);
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}
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break;
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}
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sRC = sVendor + "," + sSpeed + "," + sType + "," + sProcessors + "," + sArchitecture + "," + sProcessorLevel + "," + sStepping;
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return sRC;
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}
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};
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class CMemoryInfo
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{
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protected:
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public:
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CMemoryInfo(void)
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{
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}
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CStdString GetMemoryInfo(void)
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{
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CStdString sRC;
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MEMORYSTATUS memoryStatus;
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memset (&memoryStatus, 0, sizeof(MEMORYSTATUS));
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memoryStatus.dwLength = sizeof (MEMORYSTATUS);
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GlobalMemoryStatus (&memoryStatus);
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DWORD dwMinWSSize;
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DWORD dwMaxWSSize;
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::GetProcessWorkingSetSize(GetCurrentProcess(), &dwMinWSSize, &dwMaxWSSize);
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sRC.Format( _T("Memory Used %lu%%, Total Physical Memory %luKB, Physical Memory Available %luKB, Total Virtual Memory %luKB, Available Virtual Memory %luKB, Working Set Min : %luKB Max : %luKB .\r\n"), memoryStatus.dwMemoryLoad, memoryStatus.dwTotalPhys / 1024, memoryStatus.dwAvailPhys / 1024, memoryStatus.dwTotalVirtual / 1024, memoryStatus.dwAvailVirtual / 1024, dwMinWSSize/1024, dwMaxWSSize/1024);
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return sRC;
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}
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};
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#endif
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