/* Derived from source code of TrueCrypt 7.1a, which is Copyright (c) 2008-2012 TrueCrypt Developers Association and which is governed by the TrueCrypt License 3.0. Modifications and additions to the original source code (contained in this file) and all other portions of this file are Copyright (c) 2013-2017 IDRIX and are governed by the Apache License 2.0 the full text of which is contained in the file License.txt included in VeraCrypt binary and source code distribution packages. */ #include "Crc.h" #include "Crypto.h" #include "Password.h" #include "Volumes.h" #include "Platform.h" #include "Bios.h" #include "BootConfig.h" #include "BootMain.h" #include "BootDefs.h" #include "BootCommon.h" #include "BootConsoleIo.h" #include "BootDebug.h" #include "BootDiskIo.h" #include "BootEncryptedIo.h" #include "BootMemory.h" #include "BootStrings.h" #include "IntFilter.h" static void InitScreen () { ClearScreen(); const char *title = #ifndef TC_WINDOWS_BOOT_RESCUE_DISK_MODE " VeraCrypt Boot Loader " #else " VeraCrypt Rescue Disk " #endif VERSION_STRING "\r\n"; Print (title); PrintRepeatedChar ('\xDC', TC_BIOS_MAX_CHARS_PER_LINE); #ifndef TC_WINDOWS_BOOT_RESCUE_DISK_MODE if (CustomUserMessage[0]) { PrintEndl(); Print (CustomUserMessage); } #endif PrintEndl (2); } static void PrintMainMenu () { if (PreventBootMenu) return; Print (" Keyboard Controls:\r\n"); Print (" [F5] Hide/Show Password and PIM\r\n"); Print (" [Esc] "); #ifndef TC_WINDOWS_BOOT_RESCUE_DISK_MODE Print ((BootSectorFlags & TC_BOOT_CFG_MASK_HIDDEN_OS_CREATION_PHASE) != TC_HIDDEN_OS_CREATION_PHASE_NONE ? "Boot Non-Hidden System (Boot Manager)" : "Skip Authentication (Boot Manager)"); #else // TC_WINDOWS_BOOT_RESCUE_DISK_MODE Print ("Skip Authentication (Boot Manager)"); Print ("\r\n [F8] "); Print ("Repair Options"); #endif // TC_WINDOWS_BOOT_RESCUE_DISK_MODE PrintEndl (3); } static bool IsMenuKey (uint8 scanCode) { #ifdef TC_WINDOWS_BOOT_RESCUE_DISK_MODE return scanCode == TC_MENU_KEY_REPAIR; #else return false; #endif } static bool AskYesNo (const char *message) { Print (message); Print ("? (y/n): "); while (true) { switch (GetKeyboardChar()) { case 'y': case 'Y': case 'z': case 'Z': Print ("y\r\n"); return true; case 'n': case 'N': Print ("n\r\n"); return false; default: Beep(); } } } static int AskSelection (const char *options[], size_t optionCount) { for (int i = 0; i < optionCount; ++i) { Print ("["); Print (i + 1); Print ("] "); Print (options[i]); PrintEndl(); } Print ("[Esc] Cancel\r\n\r\n"); Print ("To select, press 1-9: "); char str; while (true) { if (GetString (&str, 1) == 0) return 0; if (str >= '1' && str <= optionCount + '0') return str - '0'; Beep(); PrintBackspace(); } } static uint8 AskPassword (Password &password, int& pim) { size_t pos = 0; uint8 scanCode; uint8 asciiCode; uint8 hidePassword = 1; pim = 0; Print ("Enter password"); Print (PreventNormalSystemBoot ? " for hidden system:\r\n" : ": "); while (true) { asciiCode = GetKeyboardChar (&scanCode); switch (scanCode) { case TC_BIOS_KEY_ENTER: password.Length = pos; Print ("\r"); if (!PreventNormalSystemBoot) Print ("Enter password: "); pos = 0; while (pos < MAX_PASSWORD) { pos++; if (pos < MAX_PASSWORD) PrintChar ('*'); else PrintCharAtCursor ('*'); } ClearBiosKeystrokeBuffer(); PrintEndl(); break; case TC_BIOS_KEY_BACKSPACE: if (pos > 0) { if (pos < MAX_PASSWORD) PrintBackspace(); else PrintCharAtCursor (' '); --pos; } continue; case TC_BIOS_KEY_F5: hidePassword ^= 0x01; continue; default: if (scanCode == TC_BIOS_KEY_ESC || IsMenuKey (scanCode)) { burn (password.Text, sizeof (password.Text)); ClearBiosKeystrokeBuffer(); PrintEndl(); return scanCode; } } if (TC_BIOS_KEY_ENTER == scanCode) break; if (!IsPrintable (asciiCode) || pos == MAX_PASSWORD) { Beep(); continue; } password.Text[pos++] = asciiCode; if (hidePassword) asciiCode = '*'; if (pos < MAX_PASSWORD) PrintChar (asciiCode); else PrintCharAtCursor (asciiCode); } #ifndef TC_WINDOWS_BOOT_RESCUE_DISK_MODE if (PimValueOrHiddenVolumeStartUnitNo.LowPart != -1) { pim = (int) PimValueOrHiddenVolumeStartUnitNo.LowPart; // reset stored PIM value to allow requesting PIM next time in case the stored value is wrong PimValueOrHiddenVolumeStartUnitNo.LowPart = -1; return TC_BIOS_KEY_ENTER; } else #endif { pos = 0; Print ("PIM: "); while (true) { asciiCode = GetKeyboardChar (&scanCode); switch (scanCode) { case TC_BIOS_KEY_ENTER: Print ("\rPIM: "); pos =0; while (pos < MAX_PIM) { PrintChar ('*'); pos++; } ClearBiosKeystrokeBuffer(); PrintEndl(); return TC_BIOS_KEY_ENTER; case TC_BIOS_KEY_BACKSPACE: if (pos > 0) { if (pos < MAX_PIM) PrintBackspace(); else PrintCharAtCursor (' '); --pos; pim /= 10; } continue; case TC_BIOS_KEY_F5: hidePassword ^= 0x01; continue; default: if (scanCode == TC_BIOS_KEY_ESC || IsMenuKey (scanCode)) { burn (password.Text, sizeof (password.Text)); ClearBiosKeystrokeBuffer(); PrintEndl(); return scanCode; } } if (!IsDigit (asciiCode) || pos == MAX_PIM) { Beep(); continue; } pim = 10*pim + (asciiCode - '0'); pos++; if (hidePassword) asciiCode = '*'; if (pos < MAX_PIM) PrintChar (asciiCode); else PrintCharAtCursor (asciiCode); } } } static void ExecuteBootSector (uint8 drive, uint8 *sectorBuffer) { Print ("Booting...\r\n"); CopyMemory (sectorBuffer, 0x0000, 0x7c00, TC_LB_SIZE); BootStarted = true; uint32 addr = 0x7c00; __asm { cli mov dl, drive // Boot drive mov dh, 0 xor ax, ax mov si, ax mov ds, ax mov es, ax mov ss, ax mov sp, 0x7c00 sti jmp cs:addr } } static bool OpenVolume (uint8 drive, Password &password, int pim, CRYPTO_INFO **cryptoInfo, uint32 *headerSaltCrc32, bool skipNormal, bool skipHidden) { int volumeType; bool hiddenVolume; uint64 headerSec; AcquireSectorBuffer(); for (volumeType = 1; volumeType <= 2; ++volumeType) { hiddenVolume = (volumeType == 2); if (hiddenVolume) { if (skipHidden || PartitionFollowingActive.Drive != drive || PartitionFollowingActive.SectorCount <= ActivePartition.SectorCount) continue; headerSec = PartitionFollowingActive.StartSector + TC_HIDDEN_VOLUME_HEADER_OFFSET / TC_LB_SIZE; } else { if (skipNormal) continue; headerSec.HighPart = 0; headerSec.LowPart = TC_BOOT_VOLUME_HEADER_SECTOR; } if (ReadSectors (SectorBuffer, drive, headerSec, 1) != BiosResultSuccess) continue; if (ReadVolumeHeader (!hiddenVolume, SectorBuffer, &password, pim, cryptoInfo, nullptr) == ERR_SUCCESS) { // Prevent opening a non-system hidden volume if (hiddenVolume && !((*cryptoInfo)->HeaderFlags & TC_HEADER_FLAG_ENCRYPTED_SYSTEM)) { crypto_close (*cryptoInfo); continue; } if (headerSaltCrc32) *headerSaltCrc32 = GetCrc32 (SectorBuffer, PKCS5_SALT_SIZE); break; } } ReleaseSectorBuffer(); return volumeType != 3; } static bool CheckMemoryRequirements () { uint16 codeSeg; __asm mov codeSeg, cs if (codeSeg == TC_BOOT_LOADER_LOWMEM_SEGMENT) { PrintErrorNoEndl ("BIOS reserved too much memory: "); uint16 memFree; __asm { push es xor ax, ax mov es, ax mov ax, es:[0x413] mov memFree, ax pop es } Print (memFree); PrintEndl(); Print (TC_BOOT_STR_UPGRADE_BIOS); return false; } return true; } static bool MountVolume (uint8 drive, uint8 &exitKey, bool skipNormal, bool skipHidden) { BootArguments *bootArguments = (BootArguments *) TC_BOOT_LOADER_ARGS_OFFSET; int incorrectPasswordCount = 0, pim = 0; EraseMemory (bootArguments, sizeof (*bootArguments)); // Open volume header while (true) { exitKey = AskPassword (bootArguments->BootPassword, pim); if (exitKey != TC_BIOS_KEY_ENTER) return false; Print ("Verifying password..."); if (OpenVolume (BootDrive, bootArguments->BootPassword, pim, &BootCryptoInfo, &bootArguments->HeaderSaltCrc32, skipNormal, skipHidden)) { Print ("OK\r\n"); break; } if (GetShiftFlags() & TC_BIOS_SHIFTMASK_CAPSLOCK) Print ("Warning: Caps Lock is on.\r\n"); Print ("Incorrect password.\r\n\r\n"); if (++incorrectPasswordCount == 4) { #ifdef TC_WINDOWS_BOOT_RESCUE_DISK_MODE Print ("If you are sure the password is correct, the key data may be damaged.\r\n" "If so, use 'Repair Options' > 'Restore key data'.\r\n\r\n"); #else Print ("If you are sure the password is correct, the key data may be damaged. Boot your\r\n" "VeraCrypt Rescue Disk and select 'Repair Options' > 'Restore key data'.\r\n\r\n"); #endif } } // Setup boot arguments bootArguments->BootLoaderVersion = VERSION_NUM; bootArguments->CryptoInfoOffset = (uint16) BootCryptoInfo; bootArguments->CryptoInfoLength = sizeof (*BootCryptoInfo); bootArguments->Flags = (((uint32)pim) << 16); if (BootCryptoInfo->hiddenVolume) bootArguments->HiddenSystemPartitionStart = PartitionFollowingActive.StartSector << TC_LB_SIZE_BIT_SHIFT_DIVISOR; if (ExtraBootPartitionPresent) bootArguments->Flags |= TC_BOOT_ARGS_FLAG_EXTRA_BOOT_PARTITION; TC_SET_BOOT_ARGUMENTS_SIGNATURE (bootArguments->Signature); // Setup virtual encrypted partition if (BootCryptoInfo->EncryptedAreaLength.HighPart != 0 || BootCryptoInfo->EncryptedAreaLength.LowPart != 0) { EncryptedVirtualPartition.Drive = BootDrive; EncryptedVirtualPartition.StartSector = BootCryptoInfo->EncryptedAreaStart >> TC_LB_SIZE_BIT_SHIFT_DIVISOR; PimValueOrHiddenVolumeStartUnitNo = EncryptedVirtualPartition.StartSector; HiddenVolumeStartSector = PartitionFollowingActive.StartSector; HiddenVolumeStartSector += EncryptedVirtualPartition.StartSector; EncryptedVirtualPartition.SectorCount = BootCryptoInfo->EncryptedAreaLength >> TC_LB_SIZE_BIT_SHIFT_DIVISOR; EncryptedVirtualPartition.EndSector = EncryptedVirtualPartition.SectorCount - 1; EncryptedVirtualPartition.EndSector += EncryptedVirtualPartition.StartSector; } else { // Drive not encrypted EncryptedVirtualPartition.Drive = TC_INVALID_BIOS_DRIVE; } return true; } static bool GetSystemPartitions (uint8 drive) { size_t partCount; if (!GetActivePartition (drive)) return false; // Find partition following the active one GetDrivePartitions (drive, &PartitionFollowingActive, 1, partCount, false, &ActivePartition); // If there is an extra boot partition, use the partitions following it. // The real boot partition is determined in BootEncryptedDrive(). if (ActivePartition.SectorCount.HighPart == 0 && ActivePartition.SectorCount.LowPart <= TC_MAX_EXTRA_BOOT_PARTITION_SIZE / TC_LB_SIZE && PartitionFollowingActive.Drive != TC_INVALID_BIOS_DRIVE) { ExtraBootPartitionPresent = true; ActivePartition = PartitionFollowingActive; GetDrivePartitions (drive, &PartitionFollowingActive, 1, partCount, false, &ActivePartition); } return true; } static uint8 BootEncryptedDrive () { BootArguments *bootArguments = (BootArguments *) TC_BOOT_LOADER_ARGS_OFFSET; uint8 exitKey; BootCryptoInfo = NULL; if (!GetSystemPartitions (BootDrive)) goto err; if (!MountVolume (BootDrive, exitKey, PreventNormalSystemBoot, false)) return exitKey; if (!CheckMemoryRequirements ()) goto err; if (BootCryptoInfo->hiddenVolume) { EncryptedVirtualPartition = ActivePartition; bootArguments->DecoySystemPartitionStart = ActivePartition.StartSector << TC_LB_SIZE_BIT_SHIFT_DIVISOR; } if (ExtraBootPartitionPresent && !GetActivePartition (BootDrive)) goto err; if (ReadWriteMBR (false, ActivePartition.Drive) != BiosResultSuccess) goto err; bootArguments->BootDriveSignature = *(uint32 *) (SectorBuffer + 0x1b8); if (!InstallInterruptFilters()) goto err; bootArguments->BootArgumentsCrc32 = GetCrc32 ((uint8 *) bootArguments, (uint8 *) &bootArguments->BootArgumentsCrc32 - (uint8 *) bootArguments); while (true) { // Execute boot sector of the active partition if (ReadSectors (SectorBuffer, ActivePartition.Drive, ActivePartition.StartSector, 1) == BiosResultSuccess) { if (*(uint16 *) (SectorBuffer + 510) != 0xaa55) { PrintError (TC_BOOT_STR_NO_BOOT_PARTITION); GetKeyboardChar(); } ExecuteBootSector (ActivePartition.Drive, SectorBuffer); } GetKeyboardChar(); } err: if (BootCryptoInfo) { crypto_close (BootCryptoInfo); BootCryptoInfo = NULL; } #ifndef TC_WINDOWS_BOOT_RESCUE_DISK_MODE PimValueOrHiddenVolumeStartUnitNo.LowPart = -1; #endif EncryptedVirtualPartition.Drive = TC_INVALID_BIOS_DRIVE; EraseMemory ((void *) TC_BOOT_LOADER_ARGS_OFFSET, sizeof (BootArguments)); uint8 scanCode; GetKeyboardChar (&scanCode); return scanCode; } static void BootMenu () { BiosResult result; Partition partitions[16]; Partition bootablePartitions[9]; size_t partitionCount; size_t bootablePartitionCount = 0; for (uint8 drive = TC_FIRST_BIOS_DRIVE; drive <= TC_LAST_BIOS_DRIVE; ++drive) { if (GetDrivePartitions (drive, partitions, array_capacity (partitions), partitionCount, false, nullptr, true) == BiosResultSuccess) { for (size_t i = 0; i < partitionCount; ++i) { const Partition &partition = partitions[i]; result = ReadSectors (SectorBuffer, drive, partition.StartSector, 1); if (result == BiosResultSuccess && *(uint16 *) (SectorBuffer + TC_LB_SIZE - 2) == 0xaa55) { // Windows writes boot loader on all NTFS/FAT filesytems it creates and, therefore, // NTFS/FAT partitions must have the boot indicator set to be considered bootable. if (!partition.Active && (*(uint32 *) (SectorBuffer + 3) == 0x5346544e // 'NTFS' || *(uint32 *) (SectorBuffer + 3) == 0x41465845 && SectorBuffer[7] == 'T' // 'exFAT' || *(uint16 *) (SectorBuffer + 54) == 0x4146 && SectorBuffer[56] == 'T' // 'FAT' || *(uint16 *) (SectorBuffer + 82) == 0x4146 && SectorBuffer[84] == 'T')) { continue; } // Bootable sector found if (bootablePartitionCount < array_capacity (bootablePartitions)) bootablePartitions[bootablePartitionCount++] = partition; } } } } if (bootablePartitionCount < 1) { PrintError (TC_BOOT_STR_NO_BOOT_PARTITION); GetKeyboardChar(); return; } char partChar; while (true) { InitScreen(); Print ("Bootable Partitions:\r\n"); PrintRepeatedChar ('\xC4', 20); Print ("\r\n"); for (size_t i = 0; i < bootablePartitionCount; ++i) { const Partition &partition = bootablePartitions[i]; Print ("["); Print (i + 1); Print ("] "); Print ("Drive: "); Print (partition.Drive - TC_FIRST_BIOS_DRIVE); Print (", Partition: "); Print (partition.Number + 1); Print (", Size: "); PrintSectorCountInMB (partition.SectorCount); PrintEndl(); } if (bootablePartitionCount == 1) { // There's only one bootable partition so we'll boot it directly instead of showing boot manager partChar = '1'; } else { Print ("[Esc] Cancel\r\n\r\n"); Print ("Press 1-9 to select partition: "); if (GetString (&partChar, 1) == 0) return; PrintEndl(); if (partChar < '1' || partChar > '0' + bootablePartitionCount) { Beep(); continue; } } const Partition &partition = bootablePartitions[partChar - '0' - 1]; if (ReadSectors (SectorBuffer, partition.Drive, partition.StartSector, 1) == BiosResultSuccess) { ExecuteBootSector (partition.Drive, SectorBuffer); } } } #ifndef TC_WINDOWS_BOOT_RESCUE_DISK_MODE static bool CopySystemPartitionToHiddenVolume (uint8 drive, uint8 &exitKey) { bool status = false; uint64 sectorsRemaining; uint64 sectorOffset; sectorOffset.LowPart = 0; sectorOffset.HighPart = 0; int fragmentSectorCount = 0x7f; // Maximum safe value supported by BIOS int statCount = 0; if (!CheckMemoryRequirements ()) goto err; if (!GetSystemPartitions (drive)) goto err; if (PartitionFollowingActive.Drive == TC_INVALID_BIOS_DRIVE) TC_THROW_FATAL_EXCEPTION; // Check if BIOS can read the last sector of the hidden system AcquireSectorBuffer(); if (ReadSectors (SectorBuffer, PartitionFollowingActive.Drive, PartitionFollowingActive.EndSector - (TC_VOLUME_HEADER_GROUP_SIZE / TC_LB_SIZE - 2), 1) != BiosResultSuccess || GetCrc32 (SectorBuffer, sizeof (SectorBuffer)) != OuterVolumeBackupHeaderCrc) { PrintErrorNoEndl ("Your BIOS does not support large drives"); Print (IsLbaSupported (PartitionFollowingActive.Drive) ? " due to a bug" : "\r\n- Enable LBA in BIOS"); PrintEndl(); Print (TC_BOOT_STR_UPGRADE_BIOS); ReleaseSectorBuffer(); goto err; } ReleaseSectorBuffer(); if (!MountVolume (drive, exitKey, true, false)) return false; sectorsRemaining = EncryptedVirtualPartition.SectorCount; if (!(sectorsRemaining == ActivePartition.SectorCount)) TC_THROW_FATAL_EXCEPTION; InitScreen(); Print ("\r\nCopying system to hidden volume. To abort, press Esc.\r\n\r\n"); while (sectorsRemaining.HighPart != 0 || sectorsRemaining.LowPart != 0) { if (EscKeyPressed()) { Print ("\rIf aborted, copying will have to start from the beginning (if attempted again).\r\n"); if (AskYesNo ("Abort")) break; } if (sectorsRemaining.HighPart == 0 && sectorsRemaining.LowPart < fragmentSectorCount) fragmentSectorCount = (int) sectorsRemaining.LowPart; if (ReadWriteSectors (false, TC_BOOT_LOADER_BUFFER_SEGMENT, 0, drive, ActivePartition.StartSector + sectorOffset, fragmentSectorCount, false) != BiosResultSuccess) { Print ("To fix bad sectors: 1) Terminate 2) Encrypt and decrypt sys partition 3) Retry\r\n"); crypto_close (BootCryptoInfo); goto err; } AcquireSectorBuffer(); for (int i = 0; i < fragmentSectorCount; ++i) { CopyMemory (TC_BOOT_LOADER_BUFFER_SEGMENT, i * TC_LB_SIZE, SectorBuffer, TC_LB_SIZE); uint64 s = PimValueOrHiddenVolumeStartUnitNo + sectorOffset + i; EncryptDataUnits (SectorBuffer, &s, 1, BootCryptoInfo); CopyMemory (SectorBuffer, TC_BOOT_LOADER_BUFFER_SEGMENT, i * TC_LB_SIZE, TC_LB_SIZE); } ReleaseSectorBuffer(); if (ReadWriteSectors (true, TC_BOOT_LOADER_BUFFER_SEGMENT, 0, drive, HiddenVolumeStartSector + sectorOffset, fragmentSectorCount, false) != BiosResultSuccess) { crypto_close (BootCryptoInfo); goto err; } sectorsRemaining = sectorsRemaining - fragmentSectorCount; sectorOffset = sectorOffset + fragmentSectorCount; if (!(statCount++ & 0xf)) { Print ("\rRemaining: "); PrintSectorCountInMB (sectorsRemaining); } } crypto_close (BootCryptoInfo); if (sectorsRemaining.HighPart == 0 && sectorsRemaining.LowPart == 0) { status = true; Print ("\rCopying completed."); } PrintEndl (2); goto ret; err: exitKey = TC_BIOS_KEY_ESC; GetKeyboardChar(); ret: PimValueOrHiddenVolumeStartUnitNo.LowPart = -1; EraseMemory ((void *) TC_BOOT_LOADER_ARGS_OFFSET, sizeof (BootArguments)); return status; } #else // TC_WINDOWS_BOOT_RESCUE_DISK_MODE static void DecryptDrive (uint8 drive) { uint8 exitKey; if (!MountVolume (drive, exitKey, false, true)) return; BootArguments *bootArguments = (BootArguments *) TC_BOOT_LOADER_ARGS_OFFSET; bool headerUpdateRequired = false; uint64 sectorsRemaining = EncryptedVirtualPartition.EndSector + 1 - EncryptedVirtualPartition.StartSector; uint64 sector = EncryptedVirtualPartition.EndSector + 1; int fragmentSectorCount = 0x7f; // Maximum safe value supported by BIOS int statCount = 0; bool skipBadSectors = false; Print ("\r\nUse only if Windows cannot start. Decryption under Windows is much faster\r\n" "(in VeraCrypt, select 'System' > 'Permanently Decrypt').\r\n\r\n"); if (!AskYesNo ("Decrypt now")) { crypto_close (BootCryptoInfo); goto ret; } if (EncryptedVirtualPartition.Drive == TC_INVALID_BIOS_DRIVE) { // Drive already decrypted sectorsRemaining.HighPart = 0; sectorsRemaining.LowPart = 0; } else { Print ("\r\nTo safely interrupt and defer decryption, press Esc.\r\n" "WARNING: You can turn off power only after you press Esc.\r\n\r\n"); } while (sectorsRemaining.HighPart != 0 || sectorsRemaining.LowPart != 0) { if (EscKeyPressed()) break; if (sectorsRemaining.HighPart == 0 && sectorsRemaining.LowPart < fragmentSectorCount) fragmentSectorCount = (int) sectorsRemaining.LowPart; sector = sector - fragmentSectorCount; if (!(statCount++ & 0xf)) { Print ("\rRemaining: "); PrintSectorCountInMB (sectorsRemaining); } if (ReadWriteSectors (false, TC_BOOT_LOADER_BUFFER_SEGMENT, 0, drive, sector, fragmentSectorCount, skipBadSectors) == BiosResultSuccess) { AcquireSectorBuffer(); for (int i = 0; i < fragmentSectorCount; ++i) { CopyMemory (TC_BOOT_LOADER_BUFFER_SEGMENT, i * TC_LB_SIZE, SectorBuffer, TC_LB_SIZE); uint64 s = sector + i; DecryptDataUnits (SectorBuffer, &s, 1, BootCryptoInfo); CopyMemory (SectorBuffer, TC_BOOT_LOADER_BUFFER_SEGMENT, i * TC_LB_SIZE, TC_LB_SIZE); } ReleaseSectorBuffer(); if (ReadWriteSectors (true, TC_BOOT_LOADER_BUFFER_SEGMENT, 0, drive, sector, fragmentSectorCount, skipBadSectors) != BiosResultSuccess && !skipBadSectors) goto askBadSectorSkip; } else if (!skipBadSectors) goto askBadSectorSkip; sectorsRemaining = sectorsRemaining - fragmentSectorCount; headerUpdateRequired = true; continue; askBadSectorSkip: if (!AskYesNo ("Skip all bad sectors")) break; skipBadSectors = true; sector = sector + fragmentSectorCount; fragmentSectorCount = 1; } crypto_close (BootCryptoInfo); if (headerUpdateRequired) { Print ("\rUpdating header..."); AcquireSectorBuffer(); uint64 headerSector; headerSector.HighPart = 0; headerSector.LowPart = TC_BOOT_VOLUME_HEADER_SECTOR; // Update encrypted area size in volume header CRYPTO_INFO *headerCryptoInfo = crypto_open(); while (ReadSectors (SectorBuffer, drive, headerSector, 1) != BiosResultSuccess); if (ReadVolumeHeader (TRUE, SectorBuffer, &bootArguments->BootPassword, (int) (bootArguments->Flags >> 16), NULL, headerCryptoInfo) == 0) { DecryptBuffer (SectorBuffer + HEADER_ENCRYPTED_DATA_OFFSET, HEADER_ENCRYPTED_DATA_SIZE, headerCryptoInfo); uint64 encryptedAreaLength = sectorsRemaining << TC_LB_SIZE_BIT_SHIFT_DIVISOR; for (int i = 7; i >= 0; --i) { SectorBuffer[TC_HEADER_OFFSET_ENCRYPTED_AREA_LENGTH + i] = (uint8) encryptedAreaLength.LowPart; encryptedAreaLength = encryptedAreaLength >> 8; } uint32 headerCrc32 = GetCrc32 (SectorBuffer + TC_HEADER_OFFSET_MAGIC, TC_HEADER_OFFSET_HEADER_CRC - TC_HEADER_OFFSET_MAGIC); for (i = 3; i >= 0; --i) { SectorBuffer[TC_HEADER_OFFSET_HEADER_CRC + i] = (uint8) headerCrc32; headerCrc32 >>= 8; } EncryptBuffer (SectorBuffer + HEADER_ENCRYPTED_DATA_OFFSET, HEADER_ENCRYPTED_DATA_SIZE, headerCryptoInfo); } crypto_close (headerCryptoInfo); while (WriteSectors (SectorBuffer, drive, headerSector, 1) != BiosResultSuccess); ReleaseSectorBuffer(); Print ("Done!\r\n"); } if (sectorsRemaining.HighPart == 0 && sectorsRemaining.LowPart == 0) Print ("\rDrive decrypted.\r\n"); else Print ("\r\nDecryption deferred.\r\n"); GetKeyboardChar(); ret: EraseMemory (bootArguments, sizeof (*bootArguments)); } static void RepairMenu () { DriveGeometry bootLoaderDriveGeometry; if (GetDriveGeometry (BootLoaderDrive, bootLoaderDriveGeometry, true) != BiosResultSuccess) { // Some BIOSes may fail to get the geometry of an emulated floppy drive bootLoaderDriveGeometry.Cylinders = 80; bootLoaderDriveGeometry.Heads = 2; bootLoaderDriveGeometry.Sectors = 18; } while (true) { InitScreen(); Print ("Available "); Print ("Repair Options"); Print (":\r\n"); PrintRepeatedChar ('\xC4', 25); PrintEndl(); enum { RestoreNone = 0, DecryptVolume, RestoreTrueCryptLoader, RestoreVolumeHeader, RestoreOriginalSystemLoader }; static const char *options[] = { "Permanently decrypt system partition/drive", "Restore VeraCrypt Boot Loader", "Restore key data (volume header)", "Restore original system loader" }; int selection = AskSelection (options, (BootSectorFlags & TC_BOOT_CFG_FLAG_RESCUE_DISK_ORIG_SYS_LOADER) ? array_capacity (options) : array_capacity (options) - 1); PrintEndl(); switch (selection) { case RestoreNone: return; case DecryptVolume: DecryptDrive (BootDrive); continue; case RestoreOriginalSystemLoader: if (!AskYesNo ("Is the system partition/drive decrypted")) { Print ("Please decrypt it first.\r\n"); GetKeyboardChar(); continue; } break; } bool writeConfirmed = false; BiosResult result; uint64 sector; sector.HighPart = 0; ChsAddress chs; uint8 mbrPartTable[TC_LB_SIZE - TC_MAX_MBR_BOOT_CODE_SIZE]; AcquireSectorBuffer(); for (int i = (selection == RestoreVolumeHeader ? TC_BOOT_VOLUME_HEADER_SECTOR : TC_MBR_SECTOR); i < TC_BOOT_LOADER_AREA_SECTOR_COUNT; ++i) { sector.LowPart = i; if (selection == RestoreOriginalSystemLoader) sector.LowPart += TC_ORIG_BOOT_LOADER_BACKUP_SECTOR; else if (selection == RestoreTrueCryptLoader) sector.LowPart += TC_BOOT_LOADER_BACKUP_RESCUE_DISK_SECTOR; // The backup medium may be a floppy-emulated bootable CD. The emulation may fail if LBA addressing is used. // Therefore, only CHS addressing can be used. LbaToChs (bootLoaderDriveGeometry, sector, chs); sector.LowPart = i; if (i == TC_MBR_SECTOR) { // Read current partition table result = ReadSectors (SectorBuffer, TC_FIRST_BIOS_DRIVE, sector, 1); if (result != BiosResultSuccess) goto err; memcpy (mbrPartTable, SectorBuffer + TC_MAX_MBR_BOOT_CODE_SIZE, sizeof (mbrPartTable)); } result = ReadSectors (SectorBuffer, BootLoaderDrive, chs, 1); if (result != BiosResultSuccess) goto err; if (i == TC_MBR_SECTOR) { // Preserve current partition table memcpy (SectorBuffer + TC_MAX_MBR_BOOT_CODE_SIZE, mbrPartTable, sizeof (mbrPartTable)); } // Volume header if (i == TC_BOOT_VOLUME_HEADER_SECTOR) { if (selection == RestoreTrueCryptLoader) continue; if (selection == RestoreVolumeHeader) { while (true) { bool validHeaderPresent = false; uint32 masterKeyScheduleCrc; Password password; int pim; uint8 exitKey = AskPassword (password, pim); if (exitKey != TC_BIOS_KEY_ENTER) goto abort; CRYPTO_INFO *cryptoInfo; CopyMemory (SectorBuffer, TC_BOOT_LOADER_BUFFER_SEGMENT, 0, TC_LB_SIZE); ReleaseSectorBuffer(); // Restore volume header only if the current one cannot be used if (OpenVolume (TC_FIRST_BIOS_DRIVE, password, pim, &cryptoInfo, nullptr, false, true)) { validHeaderPresent = true; masterKeyScheduleCrc = GetCrc32 (cryptoInfo->ks, sizeof (cryptoInfo->ks)); crypto_close (cryptoInfo); } AcquireSectorBuffer(); CopyMemory (TC_BOOT_LOADER_BUFFER_SEGMENT, 0, SectorBuffer, TC_LB_SIZE); if (ReadVolumeHeader (TRUE, SectorBuffer, &password, pim, &cryptoInfo, nullptr) == 0) { if (validHeaderPresent) { if (masterKeyScheduleCrc == GetCrc32 (cryptoInfo->ks, sizeof (cryptoInfo->ks))) { Print ("Original header preserved.\r\n"); goto err; } Print ("WARNING: Drive 0 contains a valid header!\r\n"); } crypto_close (cryptoInfo); break; } Print ("Incorrect password.\r\n\r\n"); } } } if (!writeConfirmed && !AskYesNo ("Modify drive 0")) goto abort; writeConfirmed = true; if (WriteSectors (SectorBuffer, TC_FIRST_BIOS_DRIVE, sector, 1) != BiosResultSuccess) goto err; } done: switch (selection) { case RestoreTrueCryptLoader: Print ("VeraCrypt Boot Loader"); break; case RestoreVolumeHeader: Print ("Header"); break; case RestoreOriginalSystemLoader: Print ("System loader"); break; } Print (" restored.\r\n"); err: GetKeyboardChar(); abort: ReleaseSectorBuffer(); } } #endif // TC_WINDOWS_BOOT_RESCUE_DISK_MODE #ifndef DEBUG extern "C" void _acrtused () { } // Required by linker #endif void main () { __asm mov BootLoaderDrive, dl __asm mov BootSectorFlags, dh #ifdef TC_BOOT_TRACING_ENABLED InitDebugPort(); #endif #ifdef TC_BOOT_STACK_CHECKING_ENABLED InitStackChecker(); #endif #ifndef TC_WINDOWS_BOOT_RESCUE_DISK_MODE ReadBootSectorUserConfiguration(); #elif defined (TC_WINDOWS_BOOT_AES) EnableHwEncryption (!(BootSectorFlags & TC_BOOT_CFG_FLAG_RESCUE_DISABLE_HW_ENCRYPTION)); #endif InitVideoMode(); InitScreen(); // Determine boot drive BootDrive = BootLoaderDrive; if (BootDrive < TC_FIRST_BIOS_DRIVE) BootDrive = TC_FIRST_BIOS_DRIVE; // Query boot drive geometry if (GetDriveGeometry (BootDrive, BootDriveGeometry) != BiosResultSuccess) { BootDrive = TC_FIRST_BIOS_DRIVE; if (GetDriveGeometry (BootDrive, BootDriveGeometry) != BiosResultSuccess) { #ifdef TC_WINDOWS_BOOT_RESCUE_DISK_MODE Print ("- Connect system drive to (SATA) port 1\r\n"); #endif GetKeyboardChar(); } else BootDriveGeometryValid = true; } else BootDriveGeometryValid = true; #ifdef TC_WINDOWS_BOOT_RESCUE_DISK_MODE // Check whether the user is not using the Rescue Disk to create a hidden system if (ReadWriteMBR (false, BootDrive, true) == BiosResultSuccess && *(uint32 *) (SectorBuffer + 6) == 0x61726556 && *(uint32 *) (SectorBuffer + 10) == 0x70797243 && (SectorBuffer[TC_BOOT_SECTOR_CONFIG_OFFSET] & TC_BOOT_CFG_MASK_HIDDEN_OS_CREATION_PHASE) != TC_HIDDEN_OS_CREATION_PHASE_NONE) { PrintError ("It appears you are creating a hidden OS."); if (AskYesNo ("Is this correct")) { Print ("Please remove the Rescue Disk from the drive and restart."); while (true); } } #endif // TC_WINDOWS_BOOT_RESCUE_DISK_MODE // Main menu while (true) { uint8 exitKey; InitScreen(); #ifndef TC_WINDOWS_BOOT_RESCUE_DISK_MODE // Hidden system setup uint8 hiddenSystemCreationPhase = BootSectorFlags & TC_BOOT_CFG_MASK_HIDDEN_OS_CREATION_PHASE; if (hiddenSystemCreationPhase != TC_HIDDEN_OS_CREATION_PHASE_NONE) { PreventNormalSystemBoot = true; PrintMainMenu(); if (hiddenSystemCreationPhase == TC_HIDDEN_OS_CREATION_PHASE_CLONING) { if (CopySystemPartitionToHiddenVolume (BootDrive, exitKey)) { BootSectorFlags = (BootSectorFlags & ~TC_BOOT_CFG_MASK_HIDDEN_OS_CREATION_PHASE) | TC_HIDDEN_OS_CREATION_PHASE_WIPING; UpdateBootSectorConfiguration (BootLoaderDrive); } else if (exitKey == TC_BIOS_KEY_ESC) goto bootMenu; else continue; } } else PrintMainMenu(); exitKey = BootEncryptedDrive(); #else // TC_WINDOWS_BOOT_RESCUE_DISK_MODE PrintMainMenu(); exitKey = BootEncryptedDrive(); if (exitKey == TC_MENU_KEY_REPAIR) { RepairMenu(); continue; } #endif // TC_WINDOWS_BOOT_RESCUE_DISK_MODE bootMenu: if (!PreventBootMenu) BootMenu(); } }