获取网卡MAC硬盘序列号CPU_IDBIOS编号
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获取网卡MAC、硬盘序列号、CPU ID、Bios编号 本文中所有原理及思想均取自网络,有修改。其中获取硬盘序列号、获取CPU编号、获取BIOS编号的原始代码的著作权归各自作者所有。 以下代码可以取得系统特征码(网卡MAC、硬盘序列号、CPU ID、BIOS编号) BYTE szSystemInfo[4096]; // 在程序执行完毕后,此处存储取得的系统特征码 UINT uSystemInfoLen = 0; // 在程序执行完毕后,此处存储取得的系统特征码的长度 // 网卡 MAC 地址,注意: MAC 地址是可以在注册表中修改的 { UINT uErrorCode = 0; IP_ADAPTER_INFO iai; ULONG uSize = 0; DWORD dwResult = GetAdaptersInfo( &iai, &uSize ); if( dwResult == ERROR_BUFFER_OVERFLOW ) { IP_ADAPTER_INFO* piai = ( IP_ADAPTER_INFO* )HeapAlloc( GetProcessHeap( ), 0, uSize ); if( piai != NULL ) { dwResult = GetAdaptersInfo( piai, &uSize ); if( ERROR_SUCCESS == dwResult ) { IP_ADAPTER_INFO* piai2 = piai; while( piai2 != NULL && ( uSystemInfoLen + piai2->AddressLength ) < 4096U ) { CopyMemory( szSystemInfo + uSystemInfoLen, piai2->Address, piai2->AddressLength ); uSystemInfoLen += piai2->AddressLength; piai2 = piai2->Next; } } else { uErrorCode = 0xF0000000U + dwResult; } VERIFY( HeapFree( GetProcessHeap( ), 0, piai ) ); } else { return FALSE; } } else { uErrorCode = 0xE0000000U + dwResult; } if( uErrorCode != 0U ) { return FALSE; } } // 硬盘序列号,注意:有的硬盘没有序列号 { OSVERSIONINFO ovi = { 0 }; ovi.dwOSVersionInfoSize = sizeof( OSVERSIONINFO ); GetVersionEx( &ovi ); if( ovi.dwPlatformId != VER_PLATFORM_WIN32_NT ) { // Only Windows 2000, Windows XP, Windows Server 2003... return FALSE; } else { if( !WinNTHDSerialNumAsPhysicalRead( szSystemInfo, &uSystemInfoLen, 1024 ) ) { WinNTHDSerialNumAsScsiRead( szSystemInfo, &uSystemInfoLen, 1024 ); } } } // CPU ID { BOOL bException = FALSE; BYTE szCpu[16] = { 0 }; UINT uCpuID = 0U; __try { _asm { mov eax, 0 cpuid mov dword ptr szCpu[0], ebx mov dword ptr szCpu[4], edx mov dword ptr szCpu[8], ecx mov eax, 1 cpuid mov uCpuID, edx } } __except( EXCEPTION_EXECUTE_HANDLER ) { bException = TRUE; } if( !bException ) { CopyMemory( szSystemInfo + uSystemInfoLen, &uCpuID, sizeof( UINT ) ); uSystemInfoLen += sizeof( UINT ); uCpuID = strlen( ( char* )szCpu ); CopyMemory( szSystemInfo + uSystemInfoLen, szCpu, uCpuID ); uSystemInfoLen += uCpuID; } } // BIOS 编号,支持 AMI, AWARD, PHOENIX { SIZE_T ssize; LARGE_INTEGER so; so.LowPart=0x000f0000; so.HighPart=0x00000000; ssize=0xffff; wchar_t strPH[30]=L\device\physicalmemory; DWORD ba=0; UNICODE_STRING struniph; struniph.Buffer=strPH; struniph.Length=0x2c; struniph.MaximumLength =0x2e; OBJECT_ATTRIBUTES obj_ar; obj_ar.Attributes =64; obj_ar.Length =24; obj_ar.ObjectName=&struniph; obj_ar.RootDirectory=0; obj_ar.SecurityDescriptor=0; obj_ar.SecurityQualityOfService =0; HMODULE hinstLib = LoadLibrary("ntdll.dll"); ZWOS ZWopenS=(ZWOS)GetProcAddress(hinstLib,"ZwOpenSection"); ZWMV ZWmapV=(ZWMV)GetProcAddress(hinstLib,"ZwMapViewOfSection"); ZWUMV ZWunmapV=(ZWUMV)GetProcAddress(hinstLib,"ZwUnmapViewOfSection"); //调用函数,对物理内存进行映射 HANDLE hSection; if( 0 == ZWopenS(&hSection,4,&obj_ar) && 0 == ZWmapV( ( HANDLE )hSection, //打开Section时得到的句柄 ( HANDLE )0xFFFFFFFF, //将要映射进程的句柄, &ba, //映射的基址 0, 0xFFFF, //分配的大小 &so, //物理内存的地址 &ssize, //指向读取内存块大小的指针 1, //子进程的可继承性设定 0, //分配类型 2 //保护类型 ) ) //执行后会在当前进程的空间开辟一段64k的空间,并把f000:0000到f000:ffff处的内容映射到这里 //映射的基址由ba返回,如果映射不再有用,应该用ZwUnmapViewOfSection断开映射 { BYTE* pBiosSerial = ( BYTE* )ba; UINT uBiosSerialLen = FindAwardBios( &pBiosSerial ); if( uBiosSerialLen == 0U ) { uBiosSerialLen = FindAmiBios( &pBiosSerial ); if( uBiosSerialLen == 0U ) { uBiosSerialLen = FindPhoenixBios( &pBiosSerial ); } } if( uBiosSerialLen != 0U ) { CopyMemory( szSystemInfo + uSystemInfoLen, pBiosSerial, uBiosSerialLen ); uSystemInfoLen += uBiosSerialLen; } ZWunmapV( ( HANDLE )0xFFFFFFFF, ( void* )ba ); } } // 完毕, 系统特征码已取得。 以下是其中用到的某些结构及函数的定义: #define FILE_DEVICE_SCSI 0x0000001b #define IOCTL_SCSI_MINIPORT_IDENTIFY ( ( FILE_DEVICE_SCSI << 16 ) + 0x0501 ) #define IOCTL_SCSI_MINIPORT 0x0004D008 // see NTDDSCSI.H for definition #define IDENTIFY_BUFFER_SIZE 512 #define SENDIDLENGTH ( sizeof( SENDCMDOUTPARAMS ) + IDENTIFY_BUFFER_SIZE ) #define IDE_ATAPI_IDENTIFY 0xA1 // Returns ID sector for ATAPI. #define IDE_ATA_IDENTIFY 0xEC // Returns ID sector for ATA. #define DFP_RECEIVE_DRIVE_DATA 0x0007c088 typedef struct _IDSECTOR { USHORT wGenConfig; USHORT wNumCyls; USHORT wReserved; USHORT wNumHeads; USHORT wBytesPerTrack; USHORT wBytesPerSector; USHORT wSectorsPerTrack; USHORT wVendorUnique[3]; CHAR sSerialNumber[20]; USHORT wBufferType; USHORT wBufferSize; USHORT wECCSize; CHAR sFirmwareRev[8]; CHAR sModelNumber[40]; USHORT wMoreVendorUnique; USHORT wDoubleWordIO; USHORT wCapabilities; USHORT wReserved1; USHORT wPIOTiming; USHORT wDMATiming; USHORT wBS; USHORT wNumCurrentCyls; USHORT wNumCurrentHeads; USHORT wNumCurrentSectorsPerTrack; ULONG ulCurrentSectorCapacity; USHORT wMultSectorStuff; ULONG ulTotalAddressableSectors; USHORT wSingleWordDMA; USHORT wMultiWordDMA; BYTE bReserved[128]; } IDSECTOR, *PIDSECTOR; typedef struct _DRIVERSTATUS { BYTE bDriverError; // Error code from driver, or 0 if no error. BYTE bIDEStatus; // Contents of IDE Error register. // Only valid when bDriverError is SMART_IDE_ERROR. BYTE bReserved[2]; // Reserved for future expansion. DWORD dwReserved[2]; // Reserved for future expansion. } DRIVERSTATUS, *PDRIVERSTATUS, *LPDRIVERSTATUS; typedef struct _SENDCMDOUTPARAMS { DWORD cBufferSize; // Size of bBuffer in bytes DRIVERSTATUS DriverStatus; // Driver status structure. BYTE bBuffer[1]; // Buffer of arbitrary length in which to store the data read from the // drive. } SENDCMDOUTPARAMS, *PSENDCMDOUTPARAMS, *LPSENDCMDOUTPARAMS; typedef struct _SRB_IO_CONTROL { ULONG HeaderLength; UCHAR Signature[8]; ULONG Timeout; ULONG ControlCode; ULONG ReturnCode; ULONG Length; } SRB_IO_CONTROL, *PSRB_IO_CONTROL; typedef struct _IDEREGS { BYTE bFeaturesReg; // Used for specifying SMART "commands". BYTE bSectorCountReg; // IDE sector count register BYTE bSectorNumberReg; // IDE sector number register BYTE bCylLowReg; // IDE low order cylinder value BYTE bCylHighReg; // IDE high order cylinder value BYTE bDriveHeadReg; // IDE drive/head register BYTE bCommandReg; // Actual IDE command. BYTE bReserved; // reserved for future use. Must be zero. } IDEREGS, *PIDEREGS, *LPIDEREGS; typedef struct _SENDCMDINPARAMS { DWORD cBufferSize; // Buffer size in bytes IDEREGS irDriveRegs; // Structure with drive register values. BYTE bDriveNumber; // Physical drive number to send // command to (0,1,2,3). BYTE bReserved[3]; // Reserved for future expansion. DWORD dwReserved[4]; // For future use. BYTE bBuffer[1]; // Input buffer. } SENDCMDINPARAMS, *PSENDCMDINPARAMS, *LPSENDCMDINPARAMS; typedef struct _GETVERSIONOUTPARAMS { BYTE bVersion; // Binary driver version. BYTE bRevision; // Binary driver revision. BYTE bReserved; // Not used. BYTE bIDEDeviceMap; // Bit map of IDE devices. DWORD fCapabilities; // Bit mask of driver capabilities. DWORD dwReserved[4]; // For future use. } GETVERSIONOUTPARAMS, *PGETVERSIONOUTPARAMS, *LPGETVERSIONOUTPARAMS; ////////////////////////////////////////////////////////////////////// //结构定义 typedef struct _UNICODE_STRING { USHORT Length;//长度 USHORT MaximumLength;//最大长度 PWSTR Buffer;//缓存指针 } UNICODE_STRING,*PUNICODE_STRING; typedef struct _OBJECT_ATTRIBUTES { ULONG Length;//长度 18h HANDLE RootDirectory;// 00000000 PUNICODE_STRING ObjectName;//指向对象名的指针 ULONG Attributes;//对象属性00000040h PVOID SecurityDescriptor; // Points to type SECURITY_DESCRIPTOR,0 PVOID SecurityQualityOfService; // Points to type SECURITY_QUALITY_OF_SERVICE,0 } OBJECT_ATTRIBUTES; typedef OBJECT_ATTRIBUTES *POBJECT_ATTRIBUTES; //函数指针变量类型 typedef DWORD (__stdcall *ZWOS )( PHANDLE,ACCESS_MASK,POBJECT_ATTRIBUTES); typedef DWORD (__stdcall *ZWMV )( HANDLE,HANDLE,PVOID,ULONG,ULONG,PLARGE_INTEGER,PSIZE_T,DWORD,ULONG,ULONG); typedef DWORD (__stdcall *ZWUMV )( HANDLE,PVOID); BOOL WinNTHDSerialNumAsScsiRead( BYTE* dwSerial, UINT* puSerialLen, UINT uMaxSerialLen ) { BOOL bInfoLoaded = FALSE; for( int iController = 0; iController < 2; ++ iController ) { HANDLE hScsiDriveIOCTL = 0; char szDriveName[256]; // Try to get a handle to PhysicalDrive IOCTL, report failure // and exit if can‘t. sprintf( szDriveName, "\\.\Scsi%d:", iController ); // Windows NT, Windows 2000, any rights should do hScsiDriveIOCTL = CreateFile( szDriveName, GENERIC_READ | GENERIC_WRITE, FILE_SHARE_READ | FILE_SHARE_WRITE, NULL, OPEN_EXISTING, 0, NULL); // if (hScsiDriveIOCTL == INVALID_HANDLE_VALUE) // printf ("Unable to open SCSI controller %d, error code: 0x%lX ", // controller, GetLastError ()); if( hScsiDriveIOCTL != INVALID_HANDLE_VALUE ) { int iDrive = 0; for( iDrive = 0; iDrive < 2; ++ iDrive ) { char szBuffer[sizeof( SRB_IO_CONTROL ) + SENDIDLENGTH] = { 0 }; SRB_IO_CONTROL* p = ( SRB_IO_CONTROL* )szBuffer; SENDCMDINPARAMS* pin = ( SENDCMDINPARAMS* )( szBuffer + sizeof( SRB_IO_CONTROL ) ); DWORD dwResult; p->HeaderLength = sizeof( SRB_IO_CONTROL ); p->Timeout = 10000; p->Length = SENDIDLENGTH; p->ControlCode = IOCTL_SCSI_MINIPORT_IDENTIFY; strncpy( ( char* )p->Signature, "SCSIDISK", 8 ); pin->irDriveRegs.bCommandReg = IDE_ATA_IDENTIFY; pin->bDriveNumber = iDrive; if( DeviceIoControl( hScsiDriveIOCTL, IOCTL_SCSI_MINIPORT, szBuffer, sizeof( SRB_IO_CONTROL ) + sizeof( SENDCMDINPARAMS ) - 1, szBuffer, sizeof( SRB_IO_CONTROL ) + SENDIDLENGTH, &dwResult, NULL ) ) { SENDCMDOUTPARAMS* pOut = ( SENDCMDOUTPARAMS* )( szBuffer + sizeof( SRB_IO_CONTROL ) ); IDSECTOR* pId = ( IDSECTOR* )( pOut->bBuffer ); if( pId->sModelNumber[0] ) { if( * puSerialLen + 20U <= uMaxSerialLen ) { // 序列号 CopyMemory( dwSerial + * puSerialLen, ( ( USHORT* )pId ) + 10, 20 ); // Cut off the trailing blanks for( UINT i = 20; i != 0U && ‘ ‘ == dwSerial[* puSerialLen + i - 1]; -- i ) {} * puSerialLen += i; // 型号 CopyMemory( dwSerial + * puSerialLen, ( ( USHORT* )pId ) + 27, 40 ); // Cut off the trailing blanks for( i = 40; i != 0U && ‘ ‘ == dwSerial[* puSerialLen + i - 1]; -- i ) {} * puSerialLen += i; bInfoLoaded = TRUE; } else { ::CloseHandle( hScsiDriveIOCTL ); return bInfoLoaded; } } } } ::CloseHandle( hScsiDriveIOCTL ); } } return bInfoLoaded; } BOOL DoIdentify( HANDLE hPhysicalDriveIOCTL, PSENDCMDINPARAMS pSCIP, PSENDCMDOUTPARAMS pSCOP, BYTE bIDCmd, BYTE bDriveNum, PDWORD lpcbBytesReturned ) { // Set up data structures for IDENTIFY command. pSCIP->cBufferSize = IDENTIFY_BUFFER_SIZE; pSCIP->irDriveRegs.bFeaturesReg = 0; pSCIP->irDriveRegs.bSectorCountReg = 1; pSCIP->irDriveRegs.bSectorNumberReg = 1; pSCIP->irDriveRegs.bCylLowReg = 0; pSCIP->irDriveRegs.bCylHighReg = 0; // calc the drive number. pSCIP->irDriveRegs.bDriveHeadReg = 0xA0 | ( ( bDriveNum & 1 ) << 4 ); // The command can either be IDE identify or ATAPI identify. pSCIP->irDriveRegs.bCommandReg = bIDCmd; pSCIP->bDriveNumber = bDriveNum; pSCIP->cBufferSize = IDENTIFY_BUFFER_SIZE; return DeviceIoControl( hPhysicalDriveIOCTL, DFP_RECEIVE_DRIVE_DATA, ( LPVOID ) pSCIP, sizeof( SENDCMDINPARAMS ) - 1, ( LPVOID ) pSCOP, sizeof( SENDCMDOUTPARAMS ) + IDENTIFY_BUFFER_SIZE - 1, lpcbBytesReturned, NULL ); } BOOL WinNTHDSerialNumAsPhysicalRead( BYTE* dwSerial, UINT* puSerialLen, UINT uMaxSerialLen ) { #define DFP_GET_VERSION 0x00074080 BOOL bInfoLoaded = FALSE; for( UINT uDrive = 0; uDrive < 4; ++ uDrive ) { HANDLE hPhysicalDriveIOCTL = 0; // Try to get a handle to PhysicalDrive IOCTL, report failure // and exit if can‘t. char szDriveName [256]; sprintf( szDriveName, "\\.\PhysicalDrive%d", uDrive ); // Windows NT, Windows 2000, must have admin rights hPhysicalDriveIOCTL = CreateFile( szDriveName, GENERIC_READ | GENERIC_WRITE, FILE_SHARE_READ | FILE_SHARE_WRITE, NULL, OPEN_EXISTING, 0, NULL); if( hPhysicalDriveIOCTL != INVALID_HANDLE_VALUE ) { GETVERSIONOUTPARAMS VersionParams = { 0 }; DWORD cbBytesReturned = 0; // Get the version, etc of PhysicalDrive IOCTL if( DeviceIoControl( hPhysicalDriveIOCTL, DFP_GET_VERSION, NULL, 0, &VersionParams, sizeof( GETVERSIONOUTPARAMS ), &cbBytesReturned, NULL ) ) { // If there is a IDE device at number "i" issue commands // to the device if( VersionParams.bIDEDeviceMap != 0 ) { BYTE bIDCmd = 0; // IDE or ATAPI IDENTIFY cmd SENDCMDINPARAMS scip = { 0 }; // Now, get the ID sector for all IDE devices in the system. // If the device is ATAPI use the IDE_ATAPI_IDENTIFY command, // otherwise use the IDE_ATA_IDENTIFY command bIDCmd = ( VersionParams.bIDEDeviceMap >> uDrive & 0x10 ) ? IDE_ATAPI_IDENTIFY : IDE_ATA_IDENTIFY; BYTE IdOutCmd[sizeof( SENDCMDOUTPARAMS ) + IDENTIFY_BUFFER_SIZE - 1] = { 0 }; if( DoIdentify( hPhysicalDriveIOCTL, &scip, ( PSENDCMDOUTPARAMS )&IdOutCmd, ( BYTE )bIDCmd, ( BYTE )uDrive, &cbBytesReturned ) ) { if( * puSerialLen + 20U <= uMaxSerialLen ) { CopyMemory( dwSerial + * puSerialLen, ( ( USHORT* )( ( ( PSENDCMDOUTPARAMS )IdOutCmd )->bBuffer ) ) + 10, 20 ); // 序列号 // Cut off the trailing blanks for( UINT i = 20; i != 0U && ‘ ‘ == dwSerial[* puSerialLen + i - 1]; -- i ) {} * puSerialLen += i; CopyMemory( dwSerial + * puSerialLen, ( ( USHORT* )( ( ( PSENDCMDOUTPARAMS )IdOutCmd )->bBuffer ) ) + 27, 40 ); // 型号 // Cut off the trailing blanks for( i = 40; i != 0U && ‘ ‘ == dwSerial[* puSerialLen + i - 1]; -- i ) {} * puSerialLen += i; bInfoLoaded = TRUE; } else { ::CloseHandle( hPhysicalDriveIOCTL ); return bInfoLoaded; } } } } CloseHandle( hPhysicalDriveIOCTL ); } } return bInfoLoaded; } UINT FindAwardBios( BYTE** ppBiosAddr ) { BYTE* pBiosAddr = * ppBiosAddr + 0xEC71; BYTE szBiosData[128]; CopyMemory( szBiosData, pBiosAddr, 127 ); szBiosData[127] = 0; int iLen = lstrlen( ( char* )szBiosData ); if( iLen > 0 && iLen < 128 ) { //AWard: 07/08/2002-i845G-ITE8712-JF69VD0CC-00 //Phoenix-Award: 03/12/2002-sis645-p4s333 if( szBiosData[2] == ‘/‘ && szBiosData[5] == ‘/‘ ) { BYTE* p = szBiosData; while( * p ) { if( * p < ‘ ‘ || * p >= 127 ) { break; } ++ p; } if( * p == 0 ) { * ppBiosAddr = pBiosAddr; return ( UINT )iLen; } } } return 0; } UINT FindAmiBios( BYTE** ppBiosAddr ) { BYTE* pBiosAddr = * ppBiosAddr + 0xF478; BYTE szBiosData[128]; CopyMemory( szBiosData, pBiosAddr, 127 ); szBiosData[127] = 0; int iLen = lstrlen( ( char* )szBiosData ); if( iLen > 0 && iLen < 128 ) { // Example: "AMI: 51-2300-000000-00101111-030199-" if( szBiosData[2] == ‘-‘ && szBiosData[7] == ‘-‘ ) { BYTE* p = szBiosData; while( * p ) { if( * p < ‘ ‘ || * p >= 127 ) { break; } ++ p; } if( * p == 0 ) { * ppBiosAddr = pBiosAddr; return ( UINT )iLen; } } } return 0; } UINT FindPhoenixBios( BYTE** ppBiosAddr ) { UINT uOffset[3] = { 0x6577, 0x7196, 0x7550 }; for( UINT i = 0; i < 3; ++ i ) { BYTE* pBiosAddr = * ppBiosAddr + uOffset[i]; BYTE szBiosData[128]; CopyMemory( szBiosData, pBiosAddr, 127 ); szBiosData[127] = 0; int iLen = lstrlen( ( char* )szBiosData ); if( iLen > 0 && iLen < 128 ) { // Example: Phoenix "NITELT0.86B.0044.P11.9910111055" if( szBiosData[7] == ‘.‘ && szBiosData[11] == ‘.‘ ) { BYTE* p = szBiosData; while( * p ) { if( * p < ‘ ‘ || * p >= 127 ) { break; } ++ p; } if( * p == 0 ) { * ppBiosAddr = pBiosAddr; return ( UINT )iLen; } } } } return 0; }
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