/* 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 "Tcdefs.h" #include "Platform/Finally.h" #include "Platform/ForEach.h" #include <devguid.h> #include <io.h> #include <shlobj.h> #include <atlbase.h> #include "BootEncryption.h" #include "Boot/Windows/BootCommon.h" #include "Common/Resource.h" #include "Crc.h" #include "Crypto.h" #include "Dlgcode.h" #include "Endian.h" #include "Language.h" #include "Random.h" #include "Registry.h" #include "Volumes.h" #include "Xml.h" #include "zip.h" #ifdef VOLFORMAT #include "Format/FormatCom.h" #elif defined (TCMOUNT) #include "Mount/MainCom.h" #endif #include <Strsafe.h> bool ZipAdd (zip_t *z, const char* name, const unsigned char* pbData, DWORD cbData) { zip_error_t zerr; zip_source_t* zin = zip_source_buffer_create (pbData, cbData, 0, &zerr); if (!zin) return false; if (-1 == zip_file_add (z, name, zin, 0)) { zip_source_free (zin); return false; } return true; } namespace VeraCrypt { #if !defined (SETUP) class Elevator { public: static void AddReference () { ++ReferenceCount; } static void CallDriver (DWORD ioctl, void *input, DWORD inputSize, void *output, DWORD outputSize) { Elevate(); CComBSTR inputBstr; if (input && inputBstr.AppendBytes ((const char *) input, inputSize) != S_OK) throw ParameterIncorrect (SRC_POS); CComBSTR outputBstr; if (output && outputBstr.AppendBytes ((const char *) output, outputSize) != S_OK) throw ParameterIncorrect (SRC_POS); DWORD result = ElevatedComInstance->CallDriver (ioctl, inputBstr, &outputBstr); if (output) memcpy (output, *(void **) &outputBstr, outputSize); if (result != ERROR_SUCCESS) { SetLastError (result); throw SystemException(SRC_POS); } } static void CopyFile (const wstring &sourceFile, const wstring &destinationFile) { Elevate(); DWORD result; CComBSTR sourceFileBstr, destinationFileBstr; BSTR bstr = W2BSTR(sourceFile.c_str()); if (bstr) { sourceFileBstr.Attach (bstr); bstr = W2BSTR(destinationFile.c_str()); if (bstr) { destinationFileBstr.Attach (bstr); result = ElevatedComInstance->CopyFile (sourceFileBstr, destinationFileBstr); } else { result = ERROR_OUTOFMEMORY; } } else { result = ERROR_OUTOFMEMORY; } if (result != ERROR_SUCCESS) { SetLastError (result); throw SystemException(SRC_POS); } } static void DeleteFile (const wstring &file) { Elevate(); CComBSTR fileBstr; DWORD result; BSTR bstr = W2BSTR(file.c_str()); if (bstr) { fileBstr.Attach (bstr); result = ElevatedComInstance->DeleteFile (fileBstr); } else { result = ERROR_OUTOFMEMORY; } if (result != ERROR_SUCCESS) { SetLastError (result); throw SystemException(SRC_POS); } } static void ReadWriteFile (BOOL write, BOOL device, const wstring &filePath, byte *buffer, uint64 offset, uint32 size, DWORD *sizeDone) { Elevate(); DWORD result; CComBSTR bufferBstr, fileBstr; if (bufferBstr.AppendBytes ((const char *) buffer, size) != S_OK) throw ParameterIncorrect (SRC_POS); BSTR bstr = W2BSTR(filePath.c_str()); if (bstr) { fileBstr.Attach (bstr); result = ElevatedComInstance->ReadWriteFile (write, device, fileBstr, &bufferBstr, offset, size, sizeDone); } else { result = ERROR_OUTOFMEMORY; } if (result != ERROR_SUCCESS) { SetLastError (result); throw SystemException(SRC_POS); } if (!write) memcpy (buffer, (BYTE *) bufferBstr.m_str, size); } static void GetFileSize (const wstring &filePath, unsigned __int64* pSize) { Elevate(); DWORD result; CComBSTR fileBstr; BSTR bstr = W2BSTR(filePath.c_str()); if (bstr) { fileBstr.Attach (bstr); result = ElevatedComInstance->GetFileSize (fileBstr, pSize); } else { result = ERROR_OUTOFMEMORY; } if (result != ERROR_SUCCESS) { SetLastError (result); throw SystemException(SRC_POS); } } static BOOL DeviceIoControl (BOOL readOnly, BOOL device, const wstring &filePath, DWORD dwIoControlCode, LPVOID input, DWORD inputSize, LPVOID output, DWORD outputSize) { Elevate(); DWORD result; BSTR bstr = W2BSTR(filePath.c_str()); if (bstr) { CComBSTR inputBstr; CComBSTR fileBstr; fileBstr.Attach (bstr); if (input && inputBstr.AppendBytes ((const char *) input, inputSize) != S_OK) { SetLastError (ERROR_INVALID_PARAMETER); return FALSE; } CComBSTR outputBstr; if (output && outputBstr.AppendBytes ((const char *) output, outputSize) != S_OK) { SetLastError (ERROR_INVALID_PARAMETER); return FALSE; } result = ElevatedComInstance->DeviceIoControl (readOnly, device, fileBstr, dwIoControlCode, inputBstr, &outputBstr); if (output) memcpy (output, *(void **) &outputBstr, outputSize); } else { result = ERROR_OUTOFMEMORY; } if (result != ERROR_SUCCESS) { SetLastError (result); return FALSE; } else return TRUE; } static BOOL IsPagingFileActive (BOOL checkNonWindowsPartitionsOnly) { Elevate(); return ElevatedComInstance->IsPagingFileActive (checkNonWindowsPartitionsOnly); } static void WriteLocalMachineRegistryDwordValue (wchar_t *keyPath, wchar_t *valueName, DWORD value) { Elevate(); DWORD result; CComBSTR keyPathBstr, valueNameBstr; BSTR bstr = W2BSTR(keyPath); if (bstr) { keyPathBstr.Attach (bstr); bstr = W2BSTR(valueName); if (bstr) { valueNameBstr.Attach (bstr); result = ElevatedComInstance->WriteLocalMachineRegistryDwordValue (keyPathBstr, valueNameBstr, value); } else { result = ERROR_OUTOFMEMORY; } } else { result = ERROR_OUTOFMEMORY; } if (result != ERROR_SUCCESS) { SetLastError (result); throw SystemException(SRC_POS); } } static void RegisterFilterDriver (bool registerDriver, BootEncryption::FilterType filterType) { Elevate(); DWORD result = ElevatedComInstance->RegisterFilterDriver (registerDriver ? TRUE : FALSE, filterType); if (result != ERROR_SUCCESS) { SetLastError (result); throw SystemException(SRC_POS); } } static void RegisterSystemFavoritesService (BOOL registerService) { Elevate(); DWORD result = ElevatedComInstance->RegisterSystemFavoritesService (registerService); if (result != ERROR_SUCCESS) { SetLastError (result); throw SystemException(SRC_POS); } } static void InstallEfiBootLoader (bool preserveUserConfig, bool hiddenOSCreation, int pim, int hashAlg) { Elevate(); DWORD result = ElevatedComInstance->InstallEfiBootLoader (preserveUserConfig ? TRUE : FALSE, hiddenOSCreation ? TRUE : FALSE, pim, hashAlg); if (result != ERROR_SUCCESS) { SetLastError (result); throw SystemException(SRC_POS); } } static void BackupEfiSystemLoader () { Elevate(); DWORD result = ElevatedComInstance->BackupEfiSystemLoader (); if (result != ERROR_SUCCESS) { SetLastError (result); throw SystemException(SRC_POS); } } static void RestoreEfiSystemLoader () { Elevate(); DWORD result = ElevatedComInstance->RestoreEfiSystemLoader (); if (result != ERROR_SUCCESS) { SetLastError (result); throw SystemException(SRC_POS); } } static void GetEfiBootDeviceNumber (PSTORAGE_DEVICE_NUMBER pSdn) { Elevate(); CComBSTR outputBstr; if (pSdn && outputBstr.AppendBytes ((const char *) pSdn, sizeof (STORAGE_DEVICE_NUMBER)) != S_OK) { SetLastError (ERROR_INVALID_PARAMETER); throw SystemException(SRC_POS); } DWORD result = ElevatedComInstance->GetEfiBootDeviceNumber (&outputBstr); if (pSdn) memcpy (pSdn, *(void **) &outputBstr, sizeof (STORAGE_DEVICE_NUMBER)); if (result != ERROR_SUCCESS) { SetLastError (result); throw SystemException(SRC_POS); } } static void WriteEfiBootSectorUserConfig (byte userConfig, const string &customUserMessage, int pim, int hashAlg) { Elevate(); DWORD result; CComBSTR customUserMessageBstr; BSTR bstr = A2BSTR(customUserMessage.c_str()); if (bstr) { customUserMessageBstr.Attach (bstr); result = ElevatedComInstance->WriteEfiBootSectorUserConfig ((DWORD) userConfig, customUserMessageBstr, pim, hashAlg); } else { result = ERROR_OUTOFMEMORY; } if (result != ERROR_SUCCESS) { SetLastError (result); throw SystemException(SRC_POS); } } static void Release () { if (--ReferenceCount == 0 && ElevatedComInstance) { ElevatedComInstance->Release(); ElevatedComInstance = nullptr; CoUninitialize (); } } static void SetDriverServiceStartType (DWORD startType) { Elevate(); DWORD result = ElevatedComInstance->SetDriverServiceStartType (startType); if (result != ERROR_SUCCESS) { SetLastError (result); throw SystemException(SRC_POS); } } protected: static void Elevate () { if (IsAdmin()) { SetLastError (ERROR_ACCESS_DENIED); throw SystemException(SRC_POS); } if (!ElevatedComInstance || ElevatedComInstanceThreadId != GetCurrentThreadId()) { CoInitialize (NULL); ElevatedComInstance = GetElevatedInstance (GetActiveWindow() ? GetActiveWindow() : MainDlg); ElevatedComInstanceThreadId = GetCurrentThreadId(); } } #if defined (TCMOUNT) static ITrueCryptMainCom *ElevatedComInstance; #elif defined (VOLFORMAT) static ITrueCryptFormatCom *ElevatedComInstance; #endif static DWORD ElevatedComInstanceThreadId; static int ReferenceCount; }; #if defined (TCMOUNT) ITrueCryptMainCom *Elevator::ElevatedComInstance; #elif defined (VOLFORMAT) ITrueCryptFormatCom *Elevator::ElevatedComInstance; #endif DWORD Elevator::ElevatedComInstanceThreadId; int Elevator::ReferenceCount = 0; #else // SETUP class Elevator { public: static void AddReference () { } static void CallDriver (DWORD ioctl, void *input, DWORD inputSize, void *output, DWORD outputSize) { throw ParameterIncorrect (SRC_POS); } static void ReadWriteFile (BOOL write, BOOL device, const wstring &filePath, byte *buffer, uint64 offset, uint32 size, DWORD *sizeDone) { throw ParameterIncorrect (SRC_POS); } static void RegisterFilterDriver (bool registerDriver, BootEncryption::FilterType filterType) { throw ParameterIncorrect (SRC_POS); } static void Release () { } static void SetDriverServiceStartType (DWORD startType) { throw ParameterIncorrect (SRC_POS); } static void GetFileSize (const wstring &filePath, unsigned __int64 *pSize) { throw ParameterIncorrect (SRC_POS); } static BOOL DeviceIoControl (BOOL readOnly, BOOL device, const wstring &filePath, DWORD dwIoControlCode, LPVOID input, DWORD inputSize, LPVOID output, DWORD outputSize) { throw ParameterIncorrect (SRC_POS); } static void InstallEfiBootLoader (bool preserveUserConfig, bool hiddenOSCreation, int pim, int hashAlg) { throw ParameterIncorrect (SRC_POS); } static void BackupEfiSystemLoader () { throw ParameterIncorrect (SRC_POS); } static void RestoreEfiSystemLoader () { throw ParameterIncorrect (SRC_POS); } static void GetEfiBootDeviceNumber (PSTORAGE_DEVICE_NUMBER pSdn) { throw ParameterIncorrect (SRC_POS); } static void WriteEfiBootSectorUserConfig (byte userConfig, const string &customUserMessage, int pim, int hashAlg) { throw ParameterIncorrect (SRC_POS); } }; #endif // SETUP File::File (wstring path, bool readOnly, bool create) : Elevated (false), FileOpen (false), ReadOnly (readOnly), LastError(0) { Handle = CreateFile (path.c_str(), readOnly ? GENERIC_READ : GENERIC_READ | GENERIC_WRITE, FILE_SHARE_READ | FILE_SHARE_WRITE, NULL, create ? CREATE_ALWAYS : OPEN_EXISTING, FILE_FLAG_RANDOM_ACCESS | FILE_FLAG_WRITE_THROUGH, NULL); if (Handle != INVALID_HANDLE_VALUE) { FileOpen = true; } else { LastError = GetLastError(); if (LastError == ERROR_ACCESS_DENIED && IsUacSupported()) { Elevated = true; FileOpen = true; } } FilePointerPosition = 0; IsDevice = false; Path = path; } void File::Close () { if (Handle != INVALID_HANDLE_VALUE) { CloseHandle (Handle); Handle = INVALID_HANDLE_VALUE; } FileOpen = false; } DWORD File::Read (byte *buffer, DWORD size) { DWORD bytesRead; if (!FileOpen) { SetLastError (LastError); throw SystemException (SRC_POS); } if (Elevated) { DWORD bytesRead; Elevator::ReadWriteFile (false, IsDevice, Path, buffer, FilePointerPosition, size, &bytesRead); FilePointerPosition += bytesRead; return bytesRead; } throw_sys_if (!ReadFile (Handle, buffer, size, &bytesRead, NULL)); return bytesRead; } void File::SeekAt (int64 position) { if (!FileOpen) { SetLastError (LastError); throw SystemException (SRC_POS); } FilePointerPosition = position; if (!Elevated) { LARGE_INTEGER pos; pos.QuadPart = position; throw_sys_if (!SetFilePointerEx (Handle, pos, NULL, FILE_BEGIN)); } } void File::GetFileSize (unsigned __int64& size) { if (!FileOpen) { SetLastError (LastError); throw SystemException (SRC_POS); } if (Elevated) { Elevator::GetFileSize (Path, &size); } else { LARGE_INTEGER lSize; lSize.QuadPart = 0; throw_sys_if (!GetFileSizeEx (Handle, &lSize)); size = (unsigned __int64) lSize.QuadPart; } } void File::GetFileSize (DWORD& dwSize) { unsigned __int64 size64; GetFileSize (size64); dwSize = (DWORD) size64; } void File::Write (byte *buffer, DWORD size) { DWORD bytesWritten; if (!FileOpen) { SetLastError (LastError); throw SystemException (SRC_POS); } try { if (Elevated) { Elevator::ReadWriteFile (true, IsDevice, Path, buffer, FilePointerPosition, size, &bytesWritten); FilePointerPosition += bytesWritten; throw_sys_if (bytesWritten != size); } else { throw_sys_if (!WriteFile (Handle, buffer, size, &bytesWritten, NULL) || bytesWritten != size); } } catch (SystemException &e) { if (!IsDevice || e.ErrorCode != ERROR_WRITE_PROTECT) throw; BootEncryption bootEnc (NULL); while (size >= TC_SECTOR_SIZE_BIOS) { bootEnc.WriteBootDriveSector (FilePointerPosition, buffer); FilePointerPosition += TC_SECTOR_SIZE_BIOS; buffer += TC_SECTOR_SIZE_BIOS; size -= TC_SECTOR_SIZE_BIOS; } } } bool File::IoCtl(DWORD code, void* inBuf, DWORD inBufSize, void* outBuf, DWORD outBufSize) { if (!FileOpen) { SetLastError (LastError); throw SystemException (SRC_POS); } if (Elevated) { return TRUE == Elevator::DeviceIoControl (ReadOnly, IsDevice, Path, code, inBuf, inBufSize, outBuf, outBufSize); } else { DWORD bytesReturned = 0; return TRUE == DeviceIoControl(Handle, code, inBuf, inBufSize, outBuf, outBufSize, &bytesReturned, NULL); } } void Show (HWND parent, const wstring &str) { MessageBox (parent, str.c_str(), NULL, 0); } Device::Device (wstring path, bool readOnly) { FileOpen = false; Elevated = false; Handle = CreateFile ((wstring (L"\\\\.\\") + path).c_str(), readOnly ? GENERIC_READ : GENERIC_READ | GENERIC_WRITE, FILE_SHARE_READ | FILE_SHARE_WRITE, NULL, OPEN_EXISTING, FILE_FLAG_RANDOM_ACCESS | FILE_FLAG_WRITE_THROUGH, NULL); if (Handle != INVALID_HANDLE_VALUE) { FileOpen = true; } else { LastError = GetLastError (); if (LastError == ERROR_ACCESS_DENIED && IsUacSupported()) { Elevated = true; FileOpen = true; } } FilePointerPosition = 0; IsDevice = true; Path = path; ReadOnly = readOnly; } static EfiBoot EfiBootInst; BootEncryption::BootEncryption (HWND parent) : DriveConfigValid (false), ParentWindow (parent), RealSystemDriveSizeValid (false), RescueIsoImage (nullptr), RescueZipData (nullptr), RescueZipSize (0), RescueVolumeHeaderValid (false), SelectedEncryptionAlgorithmId (0), SelectedPrfAlgorithmId (0), VolumeHeaderValid (false) { HiddenOSCandidatePartition.IsGPT = FALSE; HiddenOSCandidatePartition.Number = (size_t) -1; DriveConfig.DriveNumber = -1; DriveConfig.ExtraBootPartitionPresent = false; DriveConfig.SystemLoaderPresent = false; DriveConfig.InitialUnallocatedSpace = 0; DriveConfig.TotalUnallocatedSpace = 0; Elevator::AddReference(); } BootEncryption::~BootEncryption () { if (RescueIsoImage) { burn (RescueIsoImage, RescueIsoImageSize); delete[] RescueIsoImage; } if (RescueZipData) { burn (RescueZipData, RescueZipSize); delete [] RescueZipData; } Elevator::Release(); } void BootEncryption::CallDriver (DWORD ioctl, void *input, DWORD inputSize, void *output, DWORD outputSize) { try { DWORD bytesReturned; throw_sys_if (!DeviceIoControl (hDriver, ioctl, input, inputSize, output, outputSize, &bytesReturned, NULL)); } catch (SystemException &) { if (GetLastError() == ERROR_ACCESS_DENIED && IsUacSupported()) Elevator::CallDriver (ioctl, input, inputSize, output, outputSize); else throw; } } // Finds the first partition physically located behind the active one and returns its properties Partition BootEncryption::GetPartitionForHiddenOS () { Partition candidatePartition; memset (&candidatePartition, 0, sizeof(candidatePartition)); // The user may have modified/added/deleted partitions since the time the partition table was last scanned InvalidateCachedSysDriveProperties(); SystemDriveConfiguration config = GetSystemDriveConfiguration (); bool activePartitionFound = false; bool candidateForHiddenOSFound = false; if (!config.SystemPartition.IsGPT) { // throw ParameterIncorrect (SRC_POS); // It is assumed that CheckRequirements() had been called // Find the first active partition on the system drive foreach (const Partition &partition, config.Partitions) { if (partition.Info.BootIndicator) { if (partition.Info.PartitionNumber != config.SystemPartition.Number) { // If there is an extra boot partition, the system partition must be located right behind it if (IsOSAtLeast (WIN_7) && config.ExtraBootPartitionPresent) { int64 minOffsetFound = config.DrivePartition.Info.PartitionLength.QuadPart; Partition bootPartition = partition; Partition partitionBehindBoot; foreach (const Partition &partition, config.Partitions) { if (partition.Info.StartingOffset.QuadPart > bootPartition.Info.StartingOffset.QuadPart && partition.Info.StartingOffset.QuadPart < minOffsetFound) { minOffsetFound = partition.Info.StartingOffset.QuadPart; partitionBehindBoot = partition; } } if (minOffsetFound != config.DrivePartition.Info.PartitionLength.QuadPart && partitionBehindBoot.Number == config.SystemPartition.Number) { activePartitionFound = true; break; } } throw ErrorException (wstring (GetString ("SYSTEM_PARTITION_NOT_ACTIVE")) + GetRemarksOnHiddenOS(), SRC_POS); } activePartitionFound = true; break; } } } else { // For GPT activePartitionFound = true; } /* WARNING: Note that the partition number at the end of a device path (\Device\HarddiskY\PartitionX) must NOT be used to find the first partition physically located behind the active one. The reason is that the user may have deleted and created partitions during this session and e.g. the second partition could have a higer number than the third one. */ // Find the first partition physically located behind the active partition if (activePartitionFound) { int64 minOffsetFound = config.DrivePartition.Info.PartitionLength.QuadPart; foreach (const Partition &partition, config.Partitions) { if (partition.Info.StartingOffset.QuadPart > config.SystemPartition.Info.StartingOffset.QuadPart && partition.Info.StartingOffset.QuadPart < minOffsetFound) { minOffsetFound = partition.Info.StartingOffset.QuadPart; candidatePartition = partition; candidateForHiddenOSFound = true; } } if (!candidateForHiddenOSFound) { throw ErrorException (wstring (GetString ("NO_PARTITION_FOLLOWS_BOOT_PARTITION")) + GetRemarksOnHiddenOS(), SRC_POS); } if (config.SystemPartition.Info.PartitionLength.QuadPart > TC_MAX_FAT_SECTOR_COUNT * TC_SECTOR_SIZE_BIOS) { if ((double) candidatePartition.Info.PartitionLength.QuadPart / config.SystemPartition.Info.PartitionLength.QuadPart < MIN_HIDDENOS_DECOY_PARTITION_SIZE_RATIO_NTFS) { throw ErrorException (wstring (GetString ("PARTITION_TOO_SMALL_FOR_HIDDEN_OS_NTFS")) + GetRemarksOnHiddenOS(), SRC_POS); } } else if ((double) candidatePartition.Info.PartitionLength.QuadPart / config.SystemPartition.Info.PartitionLength.QuadPart < MIN_HIDDENOS_DECOY_PARTITION_SIZE_RATIO_FAT) { throw ErrorException (wstring (GetString ("PARTITION_TOO_SMALL_FOR_HIDDEN_OS")) + GetRemarksOnHiddenOS(), SRC_POS); } } else { // No active partition on the system drive throw ErrorException ("SYSTEM_PARTITION_NOT_ACTIVE", SRC_POS); } HiddenOSCandidatePartition = candidatePartition; return candidatePartition; } DWORD BootEncryption::GetDriverServiceStartType () { DWORD startType; throw_sys_if (!ReadLocalMachineRegistryDword (L"SYSTEM\\CurrentControlSet\\Services\\veracrypt", L"Start", &startType)); return startType; } wstring BootEncryption::GetRemarksOnHiddenOS () { return (wstring (L"\n\n") + GetString ("TWO_SYSTEMS_IN_ONE_PARTITION_REMARK") + L"\n\n" + GetString ("FOR_MORE_INFO_ON_PARTITIONS")); } void BootEncryption::SetDriverServiceStartType (DWORD startType) { if (!IsAdmin() && IsUacSupported()) { Elevator::SetDriverServiceStartType (startType); return; } BOOL startOnBoot = (startType == SERVICE_BOOT_START); SC_HANDLE serviceManager = OpenSCManager (NULL, NULL, SC_MANAGER_ALL_ACCESS); throw_sys_if (!serviceManager); finally_do_arg (SC_HANDLE, serviceManager, { CloseServiceHandle (finally_arg); }); SC_HANDLE service = OpenService (serviceManager, L"veracrypt", SERVICE_CHANGE_CONFIG); throw_sys_if (!service); finally_do_arg (SC_HANDLE, service, { CloseServiceHandle (finally_arg); }); // Windows versions preceding Vista can be installed on FAT filesystem which does not // support long filenames during boot. Convert the driver path to short form if required. wstring driverPath; if (startOnBoot && !IsOSAtLeast (WIN_VISTA)) { wchar_t pathBuf[MAX_PATH]; wchar_t filesystem[128]; wstring path (GetWindowsDirectory()); path += L"\\drivers\\veracrypt.sys"; if (GetVolumePathName (path.c_str(), pathBuf, ARRAYSIZE (pathBuf)) && GetVolumeInformation (pathBuf, NULL, 0, NULL, NULL, NULL, filesystem, ARRAYSIZE(filesystem)) && wmemcmp (filesystem, L"FAT", 3) == 0) { throw_sys_if (GetShortPathName (path.c_str(), pathBuf, ARRAYSIZE (pathBuf)) == 0); // Convert absolute path to relative to the Windows directory driverPath = pathBuf; driverPath = driverPath.substr (driverPath.rfind (L"\\", driverPath.rfind (L"\\", driverPath.rfind (L"\\") - 1) - 1) + 1); } } throw_sys_if (!ChangeServiceConfig (service, SERVICE_NO_CHANGE, SERVICE_NO_CHANGE, startOnBoot ? SERVICE_ERROR_SEVERE : SERVICE_ERROR_NORMAL, driverPath.empty() ? NULL : driverPath.c_str(), startOnBoot ? L"Filter" : NULL, NULL, NULL, NULL, NULL, NULL)); // ChangeServiceConfig() rejects SERVICE_BOOT_START with ERROR_INVALID_PARAMETER throw_sys_if (!WriteLocalMachineRegistryDword (L"SYSTEM\\CurrentControlSet\\Services\\veracrypt", L"Start", startType)); } void BootEncryption::ProbeRealSystemDriveSize () { if (RealSystemDriveSizeValid) return; GetSystemDriveConfiguration(); ProbeRealDriveSizeRequest request; StringCchCopyW (request.DeviceName, ARRAYSIZE (request.DeviceName), DriveConfig.DrivePartition.DevicePath.c_str()); CallDriver (TC_IOCTL_PROBE_REAL_DRIVE_SIZE, &request, sizeof (request), &request, sizeof (request)); DriveConfig.DrivePartition.Info.PartitionLength = request.RealDriveSize; RealSystemDriveSizeValid = true; if (request.TimeOut) throw TimeOut (SRC_POS); } void BootEncryption::InvalidateCachedSysDriveProperties () { DriveConfigValid = false; RealSystemDriveSizeValid = false; } PartitionList BootEncryption::GetDrivePartitions (int driveNumber) { PartitionList partList; for (int partNumber = 0; partNumber < 64; ++partNumber) { wstringstream partPath; partPath << L"\\Device\\Harddisk" << driveNumber << L"\\Partition" << partNumber; DISK_PARTITION_INFO_STRUCT diskPartInfo = {0}; StringCchCopyW (diskPartInfo.deviceName, ARRAYSIZE (diskPartInfo.deviceName), partPath.str().c_str()); try { CallDriver (TC_IOCTL_GET_DRIVE_PARTITION_INFO, &diskPartInfo, sizeof (diskPartInfo), &diskPartInfo, sizeof (diskPartInfo)); } catch (...) { continue; } if ( (diskPartInfo.IsGPT == TRUE || diskPartInfo.IsGPT == FALSE) && (diskPartInfo.IsDynamic == TRUE || diskPartInfo.IsDynamic == FALSE) && (diskPartInfo.partInfo.BootIndicator == TRUE || diskPartInfo.partInfo.BootIndicator == FALSE) && (diskPartInfo.partInfo.RecognizedPartition == TRUE || diskPartInfo.partInfo.RecognizedPartition == FALSE) && (diskPartInfo.partInfo.RewritePartition == TRUE || diskPartInfo.partInfo.RewritePartition == FALSE) && (diskPartInfo.partInfo.StartingOffset.QuadPart >= 0) && (diskPartInfo.partInfo.PartitionLength.QuadPart >= 0) ) { Partition part; part.DevicePath = partPath.str(); part.Number = partNumber; part.Info = diskPartInfo.partInfo; part.IsGPT = diskPartInfo.IsGPT; // Mount point int driveNumber = GetDiskDeviceDriveLetter ((wchar_t *) partPath.str().c_str()); if (driveNumber >= 0) { part.MountPoint += (wchar_t) (driveNumber + L'A'); part.MountPoint += L":"; } // Volume ID wchar_t volumePath[TC_MAX_PATH]; if (ResolveSymbolicLink ((wchar_t *) partPath.str().c_str(), volumePath, sizeof(volumePath))) { wchar_t volumeName[TC_MAX_PATH]; HANDLE fh = FindFirstVolumeW (volumeName, array_capacity (volumeName)); if (fh != INVALID_HANDLE_VALUE) { do { wstring volumeNameStr = volumeName; wchar_t devicePath[TC_MAX_PATH]; if (QueryDosDeviceW (volumeNameStr.substr (4, volumeNameStr.size() - 1 - 4).c_str(), devicePath, array_capacity (devicePath)) != 0 && wcscmp (volumePath, devicePath) == 0) { part.VolumeNameId = volumeName; break; } } while (FindNextVolumeW (fh, volumeName, array_capacity (volumeName))); FindVolumeClose (fh); } } partList.push_back (part); } } return partList; } #ifndef SETUP DISK_GEOMETRY_EX BootEncryption::GetDriveGeometry (int driveNumber) { wstringstream devName; devName << L"\\Device\\Harddisk" << driveNumber << L"\\Partition0"; DISK_GEOMETRY_EX geometry; throw_sys_if (!::GetDriveGeometry (devName.str().c_str(), &geometry)); return geometry; } #endif // !SETUP wstring BootEncryption::GetWindowsDirectory () { wchar_t buf[MAX_PATH]; throw_sys_if (GetSystemDirectory (buf, ARRAYSIZE (buf)) == 0); return wstring (buf); } uint16 BootEncryption::GetInstalledBootLoaderVersion () { uint16 version; CallDriver (TC_IOCTL_GET_BOOT_LOADER_VERSION, NULL, 0, &version, sizeof (version)); return version; } void BootEncryption::GetInstalledBootLoaderFingerprint (byte fingerprint[WHIRLPOOL_DIGESTSIZE + SHA512_DIGESTSIZE]) { BootLoaderFingerprintRequest request; CallDriver (VC_IOCTL_GET_BOOT_LOADER_FINGERPRINT, NULL, 0, &request, sizeof (request)); memcpy (fingerprint, request.Fingerprint, sizeof (request.Fingerprint)); } #ifndef SETUP // Note that this does not require admin rights (it just requires the driver to be running) bool BootEncryption::IsBootLoaderOnDrive (wchar_t *devicePath) { try { OPEN_TEST_STRUCT openTestStruct; memset (&openTestStruct, 0, sizeof (openTestStruct)); DWORD dwResult; StringCchCopyW (&openTestStruct.wszFileName[0], ARRAYSIZE(openTestStruct.wszFileName),devicePath); openTestStruct.bDetectTCBootLoader = TRUE; return (DeviceIoControl (hDriver, TC_IOCTL_OPEN_TEST, &openTestStruct, sizeof (OPEN_TEST_STRUCT), &openTestStruct, sizeof (OPEN_TEST_STRUCT), &dwResult, NULL) && openTestStruct.TCBootLoaderDetected); } catch (...) { return false; } } #endif BootEncryptionStatus BootEncryption::GetStatus () { /* IMPORTANT: Do NOT add any potentially time-consuming operations to this function. */ BootEncryptionStatus status; CallDriver (TC_IOCTL_GET_BOOT_ENCRYPTION_STATUS, NULL, 0, &status, sizeof (status)); return status; } void BootEncryption::GetVolumeProperties (VOLUME_PROPERTIES_STRUCT *properties) { if (properties == NULL) throw ParameterIncorrect (SRC_POS); CallDriver (TC_IOCTL_GET_BOOT_DRIVE_VOLUME_PROPERTIES, NULL, 0, properties, sizeof (*properties)); } bool BootEncryption::IsHiddenSystemRunning () { int hiddenSystemStatus; CallDriver (TC_IOCTL_IS_HIDDEN_SYSTEM_RUNNING, nullptr, 0, &hiddenSystemStatus, sizeof (hiddenSystemStatus)); return hiddenSystemStatus != 0; } bool BootEncryption::SystemDriveContainsPartitionType (byte type) { Device device (GetSystemDriveConfiguration().DevicePath, true); device.CheckOpened (SRC_POS); byte mbrBuf[TC_SECTOR_SIZE_BIOS]; device.SeekAt (0); device.Read (mbrBuf, sizeof (mbrBuf)); MBR *mbr = reinterpret_cast <MBR *> (mbrBuf); if (mbr->Signature != 0xaa55) throw ParameterIncorrect (SRC_POS); for (size_t i = 0; i < array_capacity (mbr->Partitions); ++i) { if (mbr->Partitions[i].Type == type) return true; } return false; } bool BootEncryption::SystemDriveContainsExtendedPartition () { return SystemDriveContainsPartitionType (PARTITION_EXTENDED) || SystemDriveContainsPartitionType (PARTITION_XINT13_EXTENDED); } bool BootEncryption::SystemDriveContainsNonStandardPartitions () { for (int partitionType = 1; partitionType <= 0xff; ++partitionType) { switch (partitionType) { case PARTITION_FAT_12: case PARTITION_FAT_16: case PARTITION_EXTENDED: case PARTITION_HUGE: case PARTITION_IFS: case PARTITION_FAT32: case PARTITION_FAT32_XINT13: case PARTITION_XINT13: case PARTITION_XINT13_EXTENDED: continue; } if (SystemDriveContainsPartitionType ((byte) partitionType)) return true; } return false; } bool BootEncryption::SystemDriveIsDynamic () { GetSystemDriveConfigurationRequest request; StringCchCopyW (request.DevicePath, ARRAYSIZE (request.DevicePath), GetSystemDriveConfiguration().DeviceKernelPath.c_str()); CallDriver (TC_IOCTL_GET_SYSTEM_DRIVE_CONFIG, &request, sizeof (request), &request, sizeof (request)); return request.DriveIsDynamic ? true : false; } SystemDriveConfiguration BootEncryption::GetSystemDriveConfiguration () { if (DriveConfigValid) return DriveConfig; SystemDriveConfiguration config; wstring winDir = GetWindowsDirectory(); // Scan all drives for (int driveNumber = 0; driveNumber < 32; ++driveNumber) { bool windowsFound = false; bool activePartitionFound = false; config.ExtraBootPartitionPresent = false; config.SystemLoaderPresent = false; PartitionList partitions = GetDrivePartitions (driveNumber); foreach (const Partition &part, partitions) { if (!part.MountPoint.empty() && (_waccess ((part.MountPoint + L"\\bootmgr").c_str(), 0) == 0 || _waccess ((part.MountPoint + L"\\ntldr").c_str(), 0) == 0)) { config.SystemLoaderPresent = true; } else if (!part.VolumeNameId.empty() && (_waccess ((part.VolumeNameId + L"\\bootmgr").c_str(), 0) == 0 || _waccess ((part.VolumeNameId + L"\\ntldr").c_str(), 0) == 0)) { config.SystemLoaderPresent = true; } if (!windowsFound && !part.MountPoint.empty() && ToUpperCase (winDir).find (ToUpperCase (part.MountPoint)) == 0) { config.SystemPartition = part; windowsFound = true; } if (!activePartitionFound && part.Info.BootIndicator) { activePartitionFound = true; if (part.Info.PartitionLength.QuadPart > 0 && part.Info.PartitionLength.QuadPart <= TC_MAX_EXTRA_BOOT_PARTITION_SIZE) config.ExtraBootPartitionPresent = true; } } if (windowsFound) { config.DriveNumber = driveNumber; wstringstream ss; ss << L"PhysicalDrive" << driveNumber; config.DevicePath = ss.str(); wstringstream kernelPath; kernelPath << L"\\Device\\Harddisk" << driveNumber << L"\\Partition0"; config.DeviceKernelPath = kernelPath.str(); config.DrivePartition = partitions.front(); partitions.pop_front(); config.Partitions = partitions; config.InitialUnallocatedSpace = 0x7fffFFFFffffFFFFull; config.TotalUnallocatedSpace = config.DrivePartition.Info.PartitionLength.QuadPart; foreach (const Partition &part, config.Partitions) { if (part.Info.StartingOffset.QuadPart < config.InitialUnallocatedSpace) config.InitialUnallocatedSpace = part.Info.StartingOffset.QuadPart; config.TotalUnallocatedSpace -= part.Info.PartitionLength.QuadPart; } DriveConfig = config; DriveConfigValid = true; return DriveConfig; } } throw ParameterIncorrect (SRC_POS); } bool BootEncryption::SystemPartitionCoversWholeDrive () { SystemDriveConfiguration config = GetSystemDriveConfiguration(); if (IsOSAtLeast (WIN_7) && config.Partitions.size() == 2 && config.ExtraBootPartitionPresent && config.DrivePartition.Info.PartitionLength.QuadPart - config.SystemPartition.Info.PartitionLength.QuadPart < 164 * BYTES_PER_MB) { return true; } return config.Partitions.size() == 1 && config.DrivePartition.Info.PartitionLength.QuadPart - config.SystemPartition.Info.PartitionLength.QuadPart < 64 * BYTES_PER_MB; } uint32 BootEncryption::GetChecksum (byte *data, size_t size) { uint32 sum = 0; while (size-- > 0) { sum += *data++; sum = _rotl (sum, 1); } return sum; } void BootEncryption::CreateBootLoaderInMemory (byte *buffer, size_t bufferSize, bool rescueDisk, bool hiddenOSCreation) { if (bufferSize < TC_BOOT_LOADER_AREA_SIZE - TC_BOOT_ENCRYPTION_VOLUME_HEADER_SIZE) throw ParameterIncorrect (SRC_POS); ZeroMemory (buffer, bufferSize); int ea = 0; int pkcs5_prf = 0; BOOL bIsGPT = GetSystemDriveConfiguration().SystemPartition.IsGPT; if (GetStatus().DriveMounted) { try { GetBootEncryptionAlgorithmNameRequest request; // since we added new field to GetBootEncryptionAlgorithmNameRequest since version 1.0f // we zero all the structure so that if we are talking to an older driver, the field // BootPrfAlgorithmName will be an empty string ZeroMemory(&request, sizeof(request)); CallDriver (TC_IOCTL_GET_BOOT_ENCRYPTION_ALGORITHM_NAME, NULL, 0, &request, sizeof (request)); if (_stricmp (request.BootEncryptionAlgorithmName, "AES") == 0) ea = AES; else if (_stricmp (request.BootEncryptionAlgorithmName, "Serpent") == 0) ea = SERPENT; else if (_stricmp (request.BootEncryptionAlgorithmName, "Twofish") == 0) ea = TWOFISH; else if (_stricmp (request.BootEncryptionAlgorithmName, "Camellia") == 0) ea = CAMELLIA; #if defined(CIPHER_GOST89) else if (_stricmp (request.BootEncryptionAlgorithmName, "GOST89") == 0) ea = GOST89; #endif if (_stricmp(request.BootPrfAlgorithmName, "SHA-256") == 0) pkcs5_prf = SHA256; else if (_stricmp(request.BootPrfAlgorithmName, "RIPEMD-160") == 0) pkcs5_prf = RIPEMD160; else if (_stricmp(request.BootPrfAlgorithmName, "SHA-512") == 0) pkcs5_prf = SHA512; else if (_stricmp(request.BootPrfAlgorithmName, "Whirlpool") == 0) pkcs5_prf = WHIRLPOOL; else if (_stricmp(request.BootPrfAlgorithmName, "Streebog") == 0) pkcs5_prf = STREEBOG; else if (strlen(request.BootPrfAlgorithmName) == 0) // case of version < 1.0f pkcs5_prf = RIPEMD160; } catch (...) { try { VOLUME_PROPERTIES_STRUCT properties; GetVolumeProperties (&properties); ea = properties.ea; pkcs5_prf = properties.pkcs5; } catch (...) { } } if (pkcs5_prf == 0) throw ParameterIncorrect (SRC_POS); } else { if (SelectedEncryptionAlgorithmId == 0 || SelectedPrfAlgorithmId == 0) throw ParameterIncorrect (SRC_POS); ea = SelectedEncryptionAlgorithmId; pkcs5_prf = SelectedPrfAlgorithmId; } // Only RIPEMD160 and SHA-256 are supported for MBR boot loader if (!bIsGPT && pkcs5_prf != RIPEMD160 && pkcs5_prf != SHA256) throw ParameterIncorrect (SRC_POS); int bootSectorId = 0; int bootLoaderId = 0; if (pkcs5_prf == SHA256) { bootSectorId = rescueDisk ? IDR_RESCUE_BOOT_SECTOR_SHA2 : IDR_BOOT_SECTOR_SHA2; bootLoaderId = rescueDisk ? IDR_RESCUE_LOADER_SHA2 : IDR_BOOT_LOADER_SHA2; } else { bootSectorId = rescueDisk ? IDR_RESCUE_BOOT_SECTOR : IDR_BOOT_SECTOR; bootLoaderId = rescueDisk ? IDR_RESCUE_LOADER : IDR_BOOT_LOADER; } switch (ea) { case AES: if (pkcs5_prf == SHA256) { bootSectorId = rescueDisk ? IDR_RESCUE_BOOT_SECTOR_AES_SHA2 : IDR_BOOT_SECTOR_AES_SHA2; bootLoaderId = rescueDisk ? IDR_RESCUE_LOADER_AES_SHA2 : IDR_BOOT_LOADER_AES_SHA2; } else { bootSectorId = rescueDisk ? IDR_RESCUE_BOOT_SECTOR_AES : IDR_BOOT_SECTOR_AES; bootLoaderId = rescueDisk ? IDR_RESCUE_LOADER_AES : IDR_BOOT_LOADER_AES; } break; case SERPENT: if (pkcs5_prf == SHA256) { bootSectorId = rescueDisk ? IDR_RESCUE_BOOT_SECTOR_SERPENT_SHA2 : IDR_BOOT_SECTOR_SERPENT_SHA2; bootLoaderId = rescueDisk ? IDR_RESCUE_LOADER_SERPENT_SHA2 : IDR_BOOT_LOADER_SERPENT_SHA2; } else { bootSectorId = rescueDisk ? IDR_RESCUE_BOOT_SECTOR_SERPENT : IDR_BOOT_SECTOR_SERPENT; bootLoaderId = rescueDisk ? IDR_RESCUE_LOADER_SERPENT : IDR_BOOT_LOADER_SERPENT; } break; case TWOFISH: if (pkcs5_prf == SHA256) { bootSectorId = rescueDisk ? IDR_RESCUE_BOOT_SECTOR_TWOFISH_SHA2 : IDR_BOOT_SECTOR_TWOFISH_SHA2; bootLoaderId = rescueDisk ? IDR_RESCUE_LOADER_TWOFISH_SHA2 : IDR_BOOT_LOADER_TWOFISH_SHA2; } else { bootSectorId = rescueDisk ? IDR_RESCUE_BOOT_SECTOR_TWOFISH : IDR_BOOT_SECTOR_TWOFISH; bootLoaderId = rescueDisk ? IDR_RESCUE_LOADER_TWOFISH : IDR_BOOT_LOADER_TWOFISH; } break; case CAMELLIA: if (pkcs5_prf == SHA256) { bootSectorId = rescueDisk ? IDR_RESCUE_BOOT_SECTOR_CAMELLIA_SHA2 : IDR_BOOT_SECTOR_CAMELLIA_SHA2; bootLoaderId = rescueDisk ? IDR_RESCUE_LOADER_CAMELLIA_SHA2 : IDR_BOOT_LOADER_CAMELLIA_SHA2; } else { bootSectorId = rescueDisk ? IDR_RESCUE_BOOT_SECTOR_CAMELLIA : IDR_BOOT_SECTOR_CAMELLIA; bootLoaderId = rescueDisk ? IDR_RESCUE_LOADER_CAMELLIA : IDR_BOOT_LOADER_CAMELLIA; } break; } // Boot sector DWORD size; byte *bootSecResourceImg = MapResource (L"BIN", bootSectorId, &size); if (!bootSecResourceImg || size != TC_SECTOR_SIZE_BIOS) throw ParameterIncorrect (SRC_POS); memcpy (buffer, bootSecResourceImg, size); *(uint16 *) (buffer + TC_BOOT_SECTOR_VERSION_OFFSET) = BE16 (VERSION_NUM); if (IsOSAtLeast (WIN_VISTA)) buffer[TC_BOOT_SECTOR_CONFIG_OFFSET] |= TC_BOOT_CFG_FLAG_WINDOWS_VISTA_OR_LATER; if (rescueDisk && (ReadDriverConfigurationFlags() & TC_DRIVER_CONFIG_DISABLE_HARDWARE_ENCRYPTION)) buffer[TC_BOOT_SECTOR_CONFIG_OFFSET] |= TC_BOOT_CFG_FLAG_RESCUE_DISABLE_HW_ENCRYPTION; // Checksum of the backup header of the outer volume for the hidden system if (hiddenOSCreation) { Device device (GetSystemDriveConfiguration().DevicePath); device.CheckOpened (SRC_POS); byte headerSector[TC_SECTOR_SIZE_BIOS]; device.SeekAt (HiddenOSCandidatePartition.Info.StartingOffset.QuadPart + HiddenOSCandidatePartition.Info.PartitionLength.QuadPart - TC_VOLUME_HEADER_GROUP_SIZE + TC_VOLUME_HEADER_EFFECTIVE_SIZE); device.Read (headerSector, sizeof (headerSector)); *(uint32 *) (buffer + TC_BOOT_SECTOR_OUTER_VOLUME_BAK_HEADER_CRC_OFFSET) = GetCrc32 (headerSector, sizeof (headerSector)); } // Decompressor byte *decompressor = MapResource (L"BIN", IDR_BOOT_LOADER_DECOMPRESSOR, &size); if (!decompressor || size > TC_BOOT_LOADER_DECOMPRESSOR_SECTOR_COUNT * TC_SECTOR_SIZE_BIOS) throw ParameterIncorrect (SRC_POS); memcpy (buffer + TC_SECTOR_SIZE_BIOS, decompressor, size); // Compressed boot loader byte *bootLoader = MapResource (L"BIN", bootLoaderId, &size); if (!bootLoader || size > TC_MAX_BOOT_LOADER_SECTOR_COUNT * TC_SECTOR_SIZE_BIOS) throw ParameterIncorrect (SRC_POS); memcpy (buffer + TC_SECTOR_SIZE_BIOS + TC_BOOT_LOADER_DECOMPRESSOR_SECTOR_COUNT * TC_SECTOR_SIZE_BIOS, bootLoader, size); // Boot loader and decompressor checksum *(uint16 *) (buffer + TC_BOOT_SECTOR_LOADER_LENGTH_OFFSET) = static_cast <uint16> (size); *(uint32 *) (buffer + TC_BOOT_SECTOR_LOADER_CHECKSUM_OFFSET) = GetChecksum (buffer + TC_SECTOR_SIZE_BIOS, TC_BOOT_LOADER_DECOMPRESSOR_SECTOR_COUNT * TC_SECTOR_SIZE_BIOS + size); // Backup of decompressor and boot loader if (size + TC_BOOT_LOADER_DECOMPRESSOR_SECTOR_COUNT * TC_SECTOR_SIZE_BIOS <= TC_BOOT_LOADER_BACKUP_SECTOR_COUNT * TC_SECTOR_SIZE_BIOS) { memcpy (buffer + TC_SECTOR_SIZE_BIOS + TC_BOOT_LOADER_BACKUP_SECTOR_COUNT * TC_SECTOR_SIZE_BIOS, buffer + TC_SECTOR_SIZE_BIOS, TC_BOOT_LOADER_BACKUP_SECTOR_COUNT * TC_SECTOR_SIZE_BIOS); buffer[TC_BOOT_SECTOR_CONFIG_OFFSET] |= TC_BOOT_CFG_FLAG_BACKUP_LOADER_AVAILABLE; } else if (!rescueDisk && bootLoaderId != IDR_BOOT_LOADER && bootLoaderId != IDR_BOOT_LOADER_SHA2) { throw ParameterIncorrect (SRC_POS); } } // return false when the user cancel an elevation request bool BootEncryption::ReadBootSectorConfig (byte *config, size_t bufLength, byte *userConfig, string *customUserMessage, uint16 *bootLoaderVersion) { bool bCanceled = false, bExceptionOccured = false; try { if (GetSystemDriveConfiguration().SystemPartition.IsGPT) { // for now, we don't support any boot config flags, like hidden OS one if (config) memset (config, 0, bufLength); // call ReadESPFile only when needed since it requires elevation if (userConfig || customUserMessage || bootLoaderVersion) { std::string confContent = ReadESPFile (L"\\EFI\\VeraCrypt\\DcsProp", true); EfiBootConf conf; conf.Load ((char*) confContent.c_str()); if (userConfig) { *userConfig = 0; if (!conf.requestPim) *userConfig |= TC_BOOT_USER_CFG_FLAG_DISABLE_PIM; if (!conf.requestHash) *userConfig |= TC_BOOT_USER_CFG_FLAG_STORE_HASH; } if (customUserMessage) customUserMessage->clear(); if (bootLoaderVersion) { *bootLoaderVersion = GetStatus().BootLoaderVersion; } } } else { if (config && bufLength < TC_BOOT_CFG_FLAG_AREA_SIZE) throw ParameterIncorrect (SRC_POS); GetSystemDriveConfigurationRequest request; StringCchCopyW (request.DevicePath, ARRAYSIZE (request.DevicePath), GetSystemDriveConfiguration().DeviceKernelPath.c_str()); CallDriver (TC_IOCTL_GET_SYSTEM_DRIVE_CONFIG, &request, sizeof (request), &request, sizeof (request)); if (config) *config = request.Configuration; if (userConfig) *userConfig = request.UserConfiguration; if (customUserMessage) { request.CustomUserMessage[TC_BOOT_SECTOR_USER_MESSAGE_MAX_LENGTH] = 0; *customUserMessage = request.CustomUserMessage; } if (bootLoaderVersion) *bootLoaderVersion = request.BootLoaderVersion; } } catch (UserAbort&) { bCanceled = true; bExceptionOccured= true; } catch (...) { bExceptionOccured = true; } if (bExceptionOccured) { if (config) *config = 0; if (userConfig) *userConfig = 0; if (customUserMessage) customUserMessage->clear(); if (bootLoaderVersion) *bootLoaderVersion = 0; } return !bCanceled; } void BootEncryption::WriteBootSectorConfig (const byte newConfig[]) { Device device (GetSystemDriveConfiguration().DevicePath); device.CheckOpened (SRC_POS); byte mbr[TC_SECTOR_SIZE_BIOS]; device.SeekAt (0); device.Read (mbr, sizeof (mbr)); memcpy (mbr + TC_BOOT_SECTOR_CONFIG_OFFSET, newConfig, TC_BOOT_CFG_FLAG_AREA_SIZE); device.SeekAt (0); device.Write (mbr, sizeof (mbr)); byte mbrVerificationBuf[TC_SECTOR_SIZE_BIOS]; device.SeekAt (0); device.Read (mbrVerificationBuf, sizeof (mbr)); if (memcmp (mbr, mbrVerificationBuf, sizeof (mbr)) != 0) throw ErrorException ("ERROR_MBR_PROTECTED", SRC_POS); } void BootEncryption::WriteEfiBootSectorUserConfig (byte userConfig, const string &customUserMessage, int pim, int hashAlg) { if (!IsAdmin() && IsUacSupported()) { Elevator::WriteEfiBootSectorUserConfig (userConfig, customUserMessage, pim, hashAlg); } else { finally_do ({ EfiBootInst.DismountBootPartition(); }); EfiBootInst.MountBootPartition(0); if (! (userConfig & TC_BOOT_USER_CFG_FLAG_DISABLE_PIM)) pim = -1; if (! (userConfig & TC_BOOT_USER_CFG_FLAG_STORE_HASH)) hashAlg = -1; EfiBootInst.UpdateConfig (L"\\EFI\\VeraCrypt\\DcsProp", pim, hashAlg, ParentWindow); } } void BootEncryption::WriteBootSectorUserConfig (byte userConfig, const string &customUserMessage, int pim, int hashAlg) { if (GetSystemDriveConfiguration().SystemPartition.IsGPT) { WriteEfiBootSectorUserConfig (userConfig, customUserMessage, pim, hashAlg); } else { Device device (GetSystemDriveConfiguration().DevicePath); device.CheckOpened (SRC_POS); byte mbr[TC_SECTOR_SIZE_BIOS]; device.SeekAt (0); device.Read (mbr, sizeof (mbr)); if (!BufferContainsString (mbr, sizeof (mbr), TC_APP_NAME) || BE16 (*(uint16 *) (mbr + TC_BOOT_SECTOR_VERSION_OFFSET)) != VERSION_NUM) { return; } mbr[TC_BOOT_SECTOR_USER_CONFIG_OFFSET] = userConfig; memset (mbr + TC_BOOT_SECTOR_USER_MESSAGE_OFFSET, 0, TC_BOOT_SECTOR_USER_MESSAGE_MAX_LENGTH); if (!customUserMessage.empty()) { if (customUserMessage.size() > TC_BOOT_SECTOR_USER_MESSAGE_MAX_LENGTH) throw ParameterIncorrect (SRC_POS); memcpy (mbr + TC_BOOT_SECTOR_USER_MESSAGE_OFFSET, customUserMessage.c_str(), customUserMessage.size()); } if (userConfig & TC_BOOT_USER_CFG_FLAG_DISABLE_PIM) { // PIM for pre-boot authentication can be encoded on two bytes since its maximum // value is 65535 (0xFFFF) memcpy (mbr + TC_BOOT_SECTOR_PIM_VALUE_OFFSET, &pim, TC_BOOT_SECTOR_PIM_VALUE_SIZE); } else memset (mbr + TC_BOOT_SECTOR_PIM_VALUE_OFFSET, 0, TC_BOOT_SECTOR_PIM_VALUE_SIZE); device.SeekAt (0); device.Write (mbr, sizeof (mbr)); byte mbrVerificationBuf[TC_SECTOR_SIZE_BIOS]; device.SeekAt (0); device.Read (mbrVerificationBuf, sizeof (mbr)); if (memcmp (mbr, mbrVerificationBuf, sizeof (mbr)) != 0) throw ErrorException ("ERROR_MBR_PROTECTED", SRC_POS); } } unsigned int BootEncryption::GetHiddenOSCreationPhase () { byte configFlags [TC_BOOT_CFG_FLAG_AREA_SIZE]; ReadBootSectorConfig (configFlags, sizeof(configFlags)); return (configFlags[0] & TC_BOOT_CFG_MASK_HIDDEN_OS_CREATION_PHASE); } void BootEncryption::SetHiddenOSCreationPhase (unsigned int newPhase) { #if TC_BOOT_CFG_FLAG_AREA_SIZE != 1 # error TC_BOOT_CFG_FLAG_AREA_SIZE != 1; revise GetHiddenOSCreationPhase() and SetHiddenOSCreationPhase() #endif byte configFlags [TC_BOOT_CFG_FLAG_AREA_SIZE]; ReadBootSectorConfig (configFlags, sizeof(configFlags)); configFlags[0] &= (byte) ~TC_BOOT_CFG_MASK_HIDDEN_OS_CREATION_PHASE; configFlags[0] |= newPhase; WriteBootSectorConfig (configFlags); } #ifndef SETUP void BootEncryption::StartDecoyOSWipe (WipeAlgorithmId wipeAlgorithm) { if (!IsHiddenOSRunning()) throw ParameterIncorrect (SRC_POS); WipeDecoySystemRequest request; ZeroMemory (&request, sizeof (request)); request.WipeAlgorithm = wipeAlgorithm; if (Randinit() != ERR_SUCCESS) { if (CryptoAPILastError == ERROR_SUCCESS) throw RandInitFailed (SRC_POS, GetLastError ()); else throw CryptoApiFailed (SRC_POS, CryptoAPILastError); } /* force the display of the random enriching dialog */ SetRandomPoolEnrichedByUserStatus (FALSE); UserEnrichRandomPool (ParentWindow); if (!RandgetBytes (ParentWindow, request.WipeKey, sizeof (request.WipeKey), TRUE)) throw ParameterIncorrect (SRC_POS); CallDriver (TC_IOCTL_START_DECOY_SYSTEM_WIPE, &request, sizeof (request), NULL, 0); burn (&request, sizeof (request)); } void BootEncryption::AbortDecoyOSWipe () { CallDriver (TC_IOCTL_ABORT_DECOY_SYSTEM_WIPE); } DecoySystemWipeStatus BootEncryption::GetDecoyOSWipeStatus () { DecoySystemWipeStatus status; CallDriver (TC_IOCTL_GET_DECOY_SYSTEM_WIPE_STATUS, NULL, 0, &status, sizeof (status)); return status; } void BootEncryption::CheckDecoyOSWipeResult () { CallDriver (TC_IOCTL_GET_DECOY_SYSTEM_WIPE_RESULT); } void BootEncryption::WipeHiddenOSCreationConfig () { if (IsHiddenOSRunning()) throw ParameterIncorrect (SRC_POS); if (Randinit() != ERR_SUCCESS) { if (CryptoAPILastError == ERROR_SUCCESS) throw RandInitFailed (SRC_POS, GetLastError ()); else throw CryptoApiFailed (SRC_POS, CryptoAPILastError); } Device device (GetSystemDriveConfiguration().DevicePath); device.CheckOpened(SRC_POS); byte mbr[TC_SECTOR_SIZE_BIOS]; device.SeekAt (0); device.Read (mbr, sizeof (mbr)); finally_do_arg (BootEncryption *, this, { try { finally_arg->SetHiddenOSCreationPhase (TC_HIDDEN_OS_CREATION_PHASE_NONE); } catch (...) { } }); #if PRAND_DISK_WIPE_PASSES > RNG_POOL_SIZE # error PRAND_DISK_WIPE_PASSES > RNG_POOL_SIZE #endif byte randData[PRAND_DISK_WIPE_PASSES]; if (!RandgetBytes (ParentWindow, randData, sizeof (randData), FALSE)) throw ParameterIncorrect (SRC_POS); for (int wipePass = 0; wipePass < PRAND_DISK_WIPE_PASSES; wipePass++) { for (int i = 0; i < TC_BOOT_SECTOR_OUTER_VOLUME_BAK_HEADER_CRC_SIZE; ++i) { mbr[TC_BOOT_SECTOR_OUTER_VOLUME_BAK_HEADER_CRC_OFFSET + i] = randData[wipePass]; } mbr[TC_BOOT_SECTOR_CONFIG_OFFSET] &= (byte) ~TC_BOOT_CFG_MASK_HIDDEN_OS_CREATION_PHASE; mbr[TC_BOOT_SECTOR_CONFIG_OFFSET] |= randData[wipePass] & TC_BOOT_CFG_MASK_HIDDEN_OS_CREATION_PHASE; if (wipePass == PRAND_DISK_WIPE_PASSES - 1) memset (mbr + TC_BOOT_SECTOR_OUTER_VOLUME_BAK_HEADER_CRC_OFFSET, 0, TC_BOOT_SECTOR_OUTER_VOLUME_BAK_HEADER_CRC_SIZE); device.SeekAt (0); device.Write (mbr, sizeof (mbr)); } for (int wipePass = 0; wipePass < PRAND_DISK_WIPE_PASSES/4 + 1; wipePass++) { SetHiddenOSCreationPhase (TC_HIDDEN_OS_CREATION_PHASE_NONE); SetHiddenOSCreationPhase (TC_HIDDEN_OS_CREATION_PHASE_CLONING); SetHiddenOSCreationPhase (TC_HIDDEN_OS_CREATION_PHASE_WIPING); SetHiddenOSCreationPhase (TC_HIDDEN_OS_CREATION_PHASE_WIPED); } SetHiddenOSCreationPhase (TC_HIDDEN_OS_CREATION_PHASE_NONE); } #endif // !SETUP NtQuerySystemInformationFn NtQuerySystemInformationPtr = NULL; EfiBootConf::EfiBootConf() : passwordType (0), passwordMsg ("Enter Password: "), passwordPicture ("login.bmp"), hashMsg ("(0) TEST ALL (1) SHA512 (2) WHIRLPOOL (3) SHA256 (4) RIPEMD160 (5) STREEBOG\nHash: "), hashAlgo (0), requestHash (0), pimMsg ("PIM (Leave empty for default): "), pim (0), requestPim (1), authorizeVisible (0), authorizeRetry (10), bmlLockFlags (0), bmlDriverEnabled (0) { } BOOL EfiBootConf::ReadConfigValue (char* configContent, const char *configKey, char *configValue, int maxValueSize) { char *xml; xml = configContent; if (xml != NULL) { xml = XmlFindElementByAttributeValue (xml, "config", "key", configKey); if (xml != NULL) { XmlGetNodeText (xml, configValue, maxValueSize); return TRUE; } } return FALSE; } int EfiBootConf::ReadConfigInteger (char* configContent, const char *configKey, int defaultValue) { char s[32]; int iRet; if (ReadConfigValue (configContent, configKey, s, sizeof (s))) iRet = atoi (s); else iRet = defaultValue; burn (s, sizeof (s)); return iRet; } char* EfiBootConf::ReadConfigString (char* configContent, const char *configKey, char *defaultValue, char *str, int maxLen) { if (ReadConfigValue (configContent, configKey, str, maxLen)) return str; else { StringCbCopyA (str, maxLen, defaultValue); return defaultValue; } } BOOL EfiBootConf::WriteConfigString (FILE* configFile, char* configContent, const char *configKey, const char *configValue) { BOOL bRet = FALSE; if (configFile) { char *c; // Mark previous config value as updated if (configContent != NULL) { c = XmlFindElementByAttributeValue (configContent, "config", "key", configKey); if (c != NULL) c[1] = '!'; } if ( 0 != fwprintf ( configFile, L"\n\t\t<config key=\"%hs\">%hs</config>", configKey, configValue)) { bRet = TRUE; } } return bRet; } BOOL EfiBootConf::WriteConfigInteger (FILE* configFile, char* configContent, const char *configKey, int configValue) { BOOL bRet = FALSE; if (configFile) { char val[32]; StringCbPrintfA (val, sizeof(val), "%d", configValue); bRet = WriteConfigString (configFile, configContent, configKey, val); burn (val, sizeof (val)); } return bRet; } BOOL EfiBootConf::Load (const wchar_t* fileName) { DWORD size = 0; char* configContent = LoadFile (fileName, &size); if (configContent) { Load (configContent); burn (configContent, size); free (configContent); return TRUE; } else return FALSE; } void EfiBootConf::Load (char* configContent) { char buffer[1024]; passwordType = ReadConfigInteger (configContent, "PasswordType", 0); passwordMsg = ReadConfigString (configContent, "PasswordMsg", "Enter password: ", buffer, sizeof (buffer)); passwordPicture = ReadConfigString (configContent, "PasswordPicture", "\\EFI\\VeraCrypt\\login.bmp", buffer, sizeof (buffer)); //hashMsg = ReadConfigString (configContent, "HashMsg", "(0) TEST ALL (1) SHA512 (2) WHIRLPOOL (3) SHA256 (4) RIPEMD160 (5) STREEBOG\nHash: ", buffer, sizeof (buffer)); hashAlgo = ReadConfigInteger (configContent, "Hash", 0); requestHash = ReadConfigInteger (configContent, "HashRqt", 1); pimMsg = ReadConfigString (configContent, "PimMsg", "PIM: ", buffer, sizeof (buffer)); pim = ReadConfigInteger (configContent, "Pim", 0); requestPim = ReadConfigInteger (configContent, "PimRqt", 1); authorizeVisible = ReadConfigInteger (configContent, "AuthorizeVisible", 0); authorizeRetry = ReadConfigInteger (configContent, "AuthorizeRetry", 0); bmlLockFlags = ReadConfigInteger (configContent, "DcsBmlLockFlags", 0); bmlDriverEnabled = ReadConfigInteger (configContent, "DcsBmlDriver", 0); burn (buffer, sizeof (buffer)); } BOOL EfiBootConf::Save (const wchar_t* fileName, HWND hwnd) { BOOL bRet = FALSE; DWORD size = 0; char* configContent = LoadFile (fileName, &size); FILE *configFile = _wfopen (fileName, L"w,ccs=UTF-8"); if (configFile == NULL) { burn (configContent, size); free (configContent); return FALSE; } XmlWriteHeader (configFile); fputws (L"\n\t<configuration>", configFile); WriteConfigInteger (configFile, configContent, "PasswordType", passwordType); WriteConfigString (configFile, configContent, "PasswordMsg", passwordMsg.c_str()); WriteConfigString (configFile, configContent, "PasswordPicture", passwordPicture.c_str()); WriteConfigString (configFile, configContent, "HashMsg", hashMsg.c_str()); WriteConfigInteger (configFile, configContent, "Hash", hashAlgo); WriteConfigInteger (configFile, configContent, "HashRqt", requestHash); WriteConfigString (configFile, configContent, "PimMsg", pimMsg.c_str()); WriteConfigInteger (configFile, configContent, "Pim", pim); WriteConfigInteger (configFile, configContent, "PimRqt", requestPim); WriteConfigInteger (configFile, configContent, "AuthorizeVisible", authorizeVisible); WriteConfigInteger (configFile, configContent, "AuthorizeRetry", authorizeRetry); WriteConfigInteger (configFile, configContent, "DcsBmlLockFlags", bmlLockFlags); WriteConfigInteger (configFile, configContent, "DcsBmlDriver", bmlDriverEnabled); // Write unmodified values char* xml = configContent; char key[128], value[2048]; while (xml && (xml = XmlFindElement (xml, "config"))) { XmlGetAttributeText (xml, "key", key, sizeof (key)); XmlGetNodeText (xml, value, sizeof (value)); fwprintf (configFile, L"\n\t\t<config key=\"%hs\">%hs</config>", key, value); xml++; } fputws (L"\n\t</configuration>", configFile); XmlWriteFooter (configFile); TCFlushFile (configFile); bRet = CheckFileStreamWriteErrors (hwnd, configFile, fileName); fclose (configFile); if (configContent != NULL) { burn (configContent, size); free (configContent); } return bRet; } static const wchar_t* EfiVarGuid = L"{8BE4DF61-93CA-11D2-AA0D-00E098032B8C}"; void GetVolumeESP(wstring& path) { static wstring g_EspPath; static bool g_EspPathInitialized = false; if (!g_EspPathInitialized) { ULONG len; NTSTATUS res; WCHAR tempBuf[1024]; memset(tempBuf, 0, sizeof(tempBuf)); // Load NtQuerySystemInformation function point if (!NtQuerySystemInformationPtr) { NtQuerySystemInformationPtr = (NtQuerySystemInformationFn) GetProcAddress (GetModuleHandle (L"ntdll.dll"), "NtQuerySystemInformation"); if (!NtQuerySystemInformationPtr) throw SystemException (SRC_POS); } res = NtQuerySystemInformationPtr((SYSTEM_INFORMATION_CLASS)SYSPARTITIONINFORMATION, tempBuf, sizeof(tempBuf), &len); if (res != S_OK) { SetLastError (res); throw SystemException (SRC_POS); } PUNICODE_STRING pStr = (PUNICODE_STRING) tempBuf; g_EspPath = L"\\\\?"; g_EspPath += &pStr->Buffer[7]; g_EspPathInitialized = true; } path = g_EspPath; } std::string ReadESPFile (LPCWSTR szFilePath, bool bSkipUTF8BOM) { if (!szFilePath || !szFilePath[0]) throw ParameterIncorrect (SRC_POS); ByteArray fileContent; DWORD dwSize = 0, dwOffset = 0; std::wstring pathESP; GetVolumeESP(pathESP); if (szFilePath[0] != L'\\') pathESP += L"\\"; File f(pathESP + szFilePath, true); f.GetFileSize(dwSize); fileContent.resize(dwSize + 1); fileContent[dwSize] = 0; f.Read(fileContent.data(), dwSize); f.Close(); if (bSkipUTF8BOM) { // remove UTF-8 BOM if any if (0 == memcmp (fileContent.data(), "\xEF\xBB\xBF", 3)) { dwOffset = 3; } } return (const char*) &fileContent[dwOffset]; } void WriteESPFile (LPCWSTR szFilePath, LPBYTE pbData, DWORD dwDataLen, bool bAddUTF8BOM) { if (!szFilePath || !szFilePath[0] || !pbData || !dwDataLen) throw ParameterIncorrect (SRC_POS); ByteArray fileContent; DWORD dwSize = dwDataLen, dwOffset = 0; std::wstring pathESP; if (bAddUTF8BOM) { dwSize += 3; dwOffset = 3; } GetVolumeESP(pathESP); if (szFilePath[0] != L'\\') pathESP += L"\\"; File f(pathESP + szFilePath, false, true); fileContent.resize(dwSize); if (bAddUTF8BOM) memcpy (fileContent.data(), "\xEF\xBB\xBF", 3); memcpy (&fileContent[dwOffset], pbData, dwDataLen); f.Write(fileContent.data(), dwSize); f.Close(); } EfiBoot::EfiBoot() { ZeroMemory(EfiBootPartPath, sizeof(EfiBootPartPath)); ZeroMemory (BootVolumePath, sizeof (BootVolumePath)); ZeroMemory (&sdn, sizeof (sdn)); ZeroMemory (&partInfo, sizeof (partInfo)); m_bMounted = false; bBootVolumePathSelected = false; } void EfiBoot::SelectBootVolumeESP() { NTSTATUS res; ULONG len; memset(tempBuf, 0, sizeof(tempBuf)); // Load NtQuerySystemInformation function point if (!NtQuerySystemInformationPtr) { NtQuerySystemInformationPtr = (NtQuerySystemInformationFn) GetProcAddress (GetModuleHandle (L"ntdll.dll"), "NtQuerySystemInformation"); if (!NtQuerySystemInformationPtr) throw SystemException (SRC_POS); } res = NtQuerySystemInformationPtr((SYSTEM_INFORMATION_CLASS)SYSPARTITIONINFORMATION, tempBuf, sizeof(tempBuf), &len); if (res != S_OK) { SetLastError (res); throw SystemException (SRC_POS); } PUNICODE_STRING pStr = (PUNICODE_STRING) tempBuf; memcpy (BootVolumePath, pStr->Buffer, min (pStr->Length, (sizeof (BootVolumePath) - 2))); bBootVolumePathSelected = true; } void EfiBoot::SelectBootVolume(WCHAR* bootVolumePath) { wstring str; str = bootVolumePath; memcpy (BootVolumePath, &str[0], min (str.length() * 2, (sizeof (BootVolumePath) - 2))); bBootVolumePathSelected = true; } void EfiBoot::MountBootPartition(WCHAR letter) { if (!bBootVolumePathSelected) { SelectBootVolumeESP(); } if (!letter) { if (!GetFreeDriveLetter(&EfiBootPartPath[0])) { throw ErrorException(L"No free letter to mount EFI boot partition", SRC_POS); } } else { EfiBootPartPath[0] = letter; } EfiBootPartPath[1] = ':'; EfiBootPartPath[2] = 0; throw_sys_if(!DefineDosDevice(DDD_RAW_TARGET_PATH, EfiBootPartPath, BootVolumePath)); Device dev(EfiBootPartPath, TRUE); try { dev.CheckOpened(SRC_POS); } catch (...) { DefineDosDevice(DDD_REMOVE_DEFINITION, EfiBootPartPath, NULL); throw; } bool bSuccess = dev.IoCtl(IOCTL_STORAGE_GET_DEVICE_NUMBER, NULL, 0, &sdn, sizeof(sdn)) && dev.IoCtl(IOCTL_DISK_GET_PARTITION_INFO_EX, NULL, 0, &partInfo, sizeof(partInfo)); DWORD dwLastError = GetLastError (); dev.Close(); if (!bSuccess) { DefineDosDevice(DDD_REMOVE_DEFINITION, EfiBootPartPath, NULL); SetLastError (dwLastError); throw SystemException(SRC_POS); } m_bMounted = true; } void EfiBoot::DismountBootPartition() { if (m_bMounted) { DefineDosDevice(DDD_REMOVE_DEFINITION, EfiBootPartPath, NULL); m_bMounted = false; } } bool EfiBoot::IsEfiBoot() { DWORD BootOrderLen; BootOrderLen = GetFirmwareEnvironmentVariable(L"BootOrder", EfiVarGuid, tempBuf, sizeof(tempBuf)); return BootOrderLen != 0; } void EfiBoot::DeleteStartExec(uint16 statrtOrderNum, wchar_t* type) { RaisePrivileges(); // Check EFI if (!IsEfiBoot()) { throw ErrorException(L"can not detect EFI environment", SRC_POS); } wchar_t varName[256]; StringCchPrintfW(varName, ARRAYSIZE (varName), L"%s%04X", type == NULL ? L"Boot" : type, statrtOrderNum); SetFirmwareEnvironmentVariable(varName, EfiVarGuid, NULL, 0); wstring order = L"Order"; order.insert(0, type == NULL ? L"Boot" : type); uint32 startOrderLen = GetFirmwareEnvironmentVariable(order.c_str(), EfiVarGuid, tempBuf, sizeof(tempBuf)); uint32 startOrderNumPos = UINT_MAX; bool startOrderUpdate = false; uint16* startOrder = (uint16*)tempBuf; for (uint32 i = 0; i < startOrderLen / 2; i++) { if (startOrder[i] == statrtOrderNum) { startOrderNumPos = i; break; } } // delete entry if present if (startOrderNumPos != UINT_MAX) { for (uint32 i = startOrderNumPos; i < ((startOrderLen / 2) - 1); ++i) { startOrder[i] = startOrder[i + 1]; } startOrderLen -= 2; startOrderUpdate = true; } if (startOrderUpdate) { SetFirmwareEnvironmentVariable(order.c_str(), EfiVarGuid, startOrder, startOrderLen); // remove ourselves from BootNext value uint16 bootNextValue = 0; wstring next = L"Next"; next.insert(0, type == NULL ? L"Boot" : type); if ( (GetFirmwareEnvironmentVariable(next.c_str(), EfiVarGuid, &bootNextValue, 2) == 2) && (bootNextValue == statrtOrderNum) ) { SetFirmwareEnvironmentVariable(next.c_str(), EfiVarGuid, startOrder, 0); } } } void EfiBoot::SetStartExec(wstring description, wstring execPath, uint16 statrtOrderNum , wchar_t* type, uint32 attr) { RaisePrivileges(); // Check EFI if (!IsEfiBoot()) { throw ErrorException(L"can not detect EFI environment", SRC_POS); } uint32 varSize = 56; varSize += ((uint32) description.length()) * 2 + 2; varSize += ((uint32) execPath.length()) * 2 + 2; byte *startVar = new byte[varSize]; byte *pVar = startVar; // Attributes (1b Active, 1000b - Hidden) *(uint32 *)pVar = attr; pVar += sizeof(uint32); // Size Of device path + file path *(uint16 *)pVar = (uint16)(50 + execPath.length() * 2 + 2); pVar += sizeof(uint16); // description for (uint32 i = 0; i < description.length(); i++) { *(uint16 *)pVar = description[i]; pVar += sizeof(uint16); } *(uint16 *)pVar = 0; pVar += sizeof(uint16); /* EFI_DEVICE_PATH_PROTOCOL (HARDDRIVE_DEVICE_PATH \ FILE_PATH \ END) */ // Type *(byte *)pVar = 0x04; pVar += sizeof(byte); // SubType *(byte *)pVar = 0x01; pVar += sizeof(byte); // HDD dev path length *(uint16 *)pVar = 0x2A; // 42 pVar += sizeof(uint16); // PartitionNumber *(uint32 *)pVar = (uint32)partInfo.PartitionNumber; pVar += sizeof(uint32); // PartitionStart *(uint64 *)pVar = partInfo.StartingOffset.QuadPart >> 9; pVar += sizeof(uint64); // PartitiontSize *(uint64 *)pVar = partInfo.PartitionLength.QuadPart >> 9; pVar += sizeof(uint64); // GptGuid memcpy(pVar, &partInfo.Gpt.PartitionId, 16); pVar += 16; // MbrType *(byte *)pVar = 0x02; pVar += sizeof(byte); // SigType *(byte *)pVar = 0x02; pVar += sizeof(byte); // Type and sub type 04 04 (file path) *(uint16 *)pVar = 0x0404; pVar += sizeof(uint16); // SizeOfFilePath ((CHAR16)FullPath.length + sizeof(EndOfrecord marker) ) *(uint16 *)pVar = (uint16)(execPath.length() * 2 + 2 + sizeof(uint32)); pVar += sizeof(uint16); // FilePath for (uint32 i = 0; i < execPath.length(); i++) { *(uint16 *)pVar = execPath[i]; pVar += sizeof(uint16); } *(uint16 *)pVar = 0; pVar += sizeof(uint16); // EndOfrecord *(uint32 *)pVar = 0x04ff7f; pVar += sizeof(uint32); // Set variable wchar_t varName[256]; StringCchPrintfW(varName, ARRAYSIZE (varName), L"%s%04X", type == NULL ? L"Boot" : type, statrtOrderNum); SetFirmwareEnvironmentVariable(varName, EfiVarGuid, startVar, varSize); delete [] startVar; // Update order wstring order = L"Order"; order.insert(0, type == NULL ? L"Boot" : type); uint32 startOrderLen = GetFirmwareEnvironmentVariable(order.c_str(), EfiVarGuid, tempBuf, sizeof(tempBuf)); uint32 startOrderNumPos = UINT_MAX; bool startOrderUpdate = false; uint16* startOrder = (uint16*)tempBuf; for (uint32 i = 0; i < startOrderLen / 2; i++) { if (startOrder[i] == statrtOrderNum) { startOrderNumPos = i; break; } } // Create new entry if absent if (startOrderNumPos == UINT_MAX) { for (uint32 i = startOrderLen / 2; i > 0; --i) { startOrder[i] = startOrder[i - 1]; } startOrder[0] = statrtOrderNum; startOrderLen += 2; startOrderUpdate = true; } else if (startOrderNumPos > 0) { for (uint32 i = startOrderNumPos; i > 0; --i) { startOrder[i] = startOrder[i - 1]; } startOrder[0] = statrtOrderNum; startOrderUpdate = true; } if (startOrderUpdate) { SetFirmwareEnvironmentVariable(order.c_str(), EfiVarGuid, startOrder, startOrderLen); } // set BootNext value wstring next = L"Next"; next.insert(0, type == NULL ? L"Boot" : type); SetFirmwareEnvironmentVariable(next.c_str(), EfiVarGuid, &statrtOrderNum, 2); } void EfiBoot::SaveFile(const wchar_t* name, byte* data, DWORD size) { wstring path = EfiBootPartPath; path += name; File f(path, false, true); f.Write(data, size); f.Close(); } void EfiBoot::GetFileSize(const wchar_t* name, unsigned __int64& size) { wstring path = EfiBootPartPath; path += name; File f(path, true); f.GetFileSize(size); f.Close(); } void EfiBoot::ReadFile(const wchar_t* name, byte* data, DWORD size) { wstring path = EfiBootPartPath; path += name; File f(path, true); f.Read(data, size); f.Close(); } void EfiBoot::CopyFile(const wchar_t* name, const wchar_t* targetName) { wstring path = EfiBootPartPath; path += name; wstring targetPath; if (targetName[0] == L'\\') { targetPath = EfiBootPartPath; targetPath += targetName; } else targetPath = targetName; throw_sys_if (!::CopyFileW (path.c_str(), targetPath.c_str(), FALSE)); } BOOL EfiBoot::RenameFile(const wchar_t* name, wchar_t* nameNew, BOOL bForce) { wstring path = EfiBootPartPath; path += name; wstring pathNew = EfiBootPartPath; pathNew += nameNew; return MoveFileExW(path.c_str(), pathNew.c_str(), bForce? MOVEFILE_REPLACE_EXISTING : 0); } BOOL EfiBoot::DelFile(const wchar_t* name) { wstring path = EfiBootPartPath; path += name; return DeleteFile(path.c_str()); } BOOL EfiBoot::MkDir(const wchar_t* name, bool& bAlreadyExists) { wstring path = EfiBootPartPath; path += name; bAlreadyExists = false; BOOL bRet = CreateDirectory(path.c_str(), NULL); if (!bRet && (GetLastError () == ERROR_ALREADY_EXISTS)) { bRet = TRUE; bAlreadyExists = true; } return bRet; } BOOL EfiBoot::DelDir(const wchar_t* name) { wstring path = EfiBootPartPath; path += name; return DeleteDirectory (path.c_str()); } BOOL EfiBoot::ReadConfig (const wchar_t* name, EfiBootConf& conf) { wstring path = EfiBootPartPath; path += name; return conf.Load (path.c_str()); } BOOL EfiBoot::UpdateConfig (const wchar_t* name, int pim, int hashAlgo, HWND hwndDlg) { BOOL bRet = FALSE; EfiBootConf conf; wstring path = EfiBootPartPath; path += name; if (conf.Load (path.c_str())) { if (pim >= 0) { conf.pim = pim; conf.requestPim = 0; } else { conf.pim = 0; conf.requestPim = 1; } if (hashAlgo >= 0) { conf.hashAlgo = hashAlgo; conf.requestHash = 0; } else { conf.hashAlgo = 0; conf.requestHash = 1; } return conf.Save (path.c_str(), hwndDlg); } return bRet; } BOOL EfiBoot::WriteConfig (const wchar_t* name, bool preserveUserConfig, int pim, int hashAlgo, const char* passPromptMsg, HWND hwndDlg) { EfiBootConf conf; wstring path = EfiBootPartPath; path += name; if (preserveUserConfig) { conf.Load (path.c_str()); if (pim >= 0 && (conf.requestPim == 0)) { conf.pim = pim; } if (hashAlgo >= 0 && (conf.requestHash == 0)) { conf.hashAlgo = hashAlgo; } } else { if (pim >= 0) { conf.pim = pim; conf.requestPim = 0; } else { conf.pim = 0; conf.requestPim = 1; } if (hashAlgo >= 0) { conf.hashAlgo = hashAlgo; conf.requestHash = 0; } else { conf.hashAlgo = 0; conf.requestHash = 1; } } if (passPromptMsg && strlen (passPromptMsg)) { conf.passwordMsg = passPromptMsg; } return conf.Save (path.c_str(), hwndDlg); } void BootEncryption::InstallBootLoader (bool preserveUserConfig, bool hiddenOSCreation, int pim, int hashAlg) { Device device (GetSystemDriveConfiguration().DevicePath); device.CheckOpened (SRC_POS); InstallBootLoader (device, preserveUserConfig, hiddenOSCreation, pim, hashAlg); } void BootEncryption::InstallBootLoader (Device& device, bool preserveUserConfig, bool hiddenOSCreation, int pim, int hashAlg) { SystemDriveConfiguration config = GetSystemDriveConfiguration(); if (config.SystemPartition.IsGPT) { if (!IsAdmin()) { if (IsUacSupported()) { Elevator::InstallEfiBootLoader (preserveUserConfig, hiddenOSCreation, pim, hashAlg); return; } else { Warning ("ADMIN_PRIVILEGES_WARN_DEVICES", ParentWindow); } } DWORD sizeDcsBoot; #ifdef _WIN64 byte *dcsBootImg = MapResource(L"BIN", IDR_EFI_DCSBOOT, &sizeDcsBoot); #else byte *dcsBootImg = MapResource(L"BIN", Is64BitOs()? IDR_EFI_DCSBOOT : IDR_EFI_DCSBOOT32, &sizeDcsBoot); #endif if (!dcsBootImg) throw ErrorException(L"Out of resource DcsBoot", SRC_POS); DWORD sizeDcsInt; #ifdef _WIN64 byte *dcsIntImg = MapResource(L"BIN", IDR_EFI_DCSINT, &sizeDcsInt); #else byte *dcsIntImg = MapResource(L"BIN", Is64BitOs()? IDR_EFI_DCSINT: IDR_EFI_DCSINT32, &sizeDcsInt); #endif if (!dcsIntImg) throw ErrorException(L"Out of resource DcsInt", SRC_POS); DWORD sizeDcsCfg; #ifdef _WIN64 byte *dcsCfgImg = MapResource(L"BIN", IDR_EFI_DCSCFG, &sizeDcsCfg); #else byte *dcsCfgImg = MapResource(L"BIN", Is64BitOs()? IDR_EFI_DCSCFG: IDR_EFI_DCSCFG32, &sizeDcsCfg); #endif if (!dcsCfgImg) throw ErrorException(L"Out of resource DcsCfg", SRC_POS); DWORD sizeLegacySpeaker; #ifdef _WIN64 byte *LegacySpeakerImg = MapResource(L"BIN", IDR_EFI_LEGACYSPEAKER, &sizeLegacySpeaker); #else byte *LegacySpeakerImg = MapResource(L"BIN", Is64BitOs()? IDR_EFI_LEGACYSPEAKER: IDR_EFI_LEGACYSPEAKER32, &sizeLegacySpeaker); #endif if (!LegacySpeakerImg) throw ErrorException(L"Out of resource LegacySpeaker", SRC_POS); DWORD sizeBootMenuLocker; #ifdef _WIN64 byte *BootMenuLockerImg = MapResource(L"BIN", IDR_EFI_DCSBML, &sizeBootMenuLocker); #else byte *BootMenuLockerImg = MapResource(L"BIN", Is64BitOs()? IDR_EFI_DCSBML: IDR_EFI_DCSBML32, &sizeBootMenuLocker); #endif if (!BootMenuLockerImg) throw ErrorException(L"Out of resource DcsBml", SRC_POS); DWORD sizeDcsInfo; #ifdef _WIN64 byte *DcsInfoImg = MapResource(L"BIN", IDR_EFI_DCSINFO, &sizeDcsInfo); #else byte *DcsInfoImg = MapResource(L"BIN", Is64BitOs()? IDR_EFI_DCSINFO: IDR_EFI_DCSINFO32, &sizeDcsInfo); #endif if (!DcsInfoImg) throw ErrorException(L"Out of resource DcsInfo", SRC_POS); finally_do ({ EfiBootInst.DismountBootPartition(); }); EfiBootInst.MountBootPartition(0); try { // Save modules bool bAlreadyExist; EfiBootInst.MkDir(L"\\EFI\\VeraCrypt", bAlreadyExist); EfiBootInst.SaveFile(L"\\EFI\\VeraCrypt\\DcsBoot.efi", dcsBootImg, sizeDcsBoot); EfiBootInst.SaveFile(Is64BitOs()? L"\\EFI\\Boot\\bootx64.efi": L"\\EFI\\Boot\\bootia32.efi", dcsBootImg, sizeDcsBoot); EfiBootInst.SaveFile(L"\\EFI\\VeraCrypt\\DcsInt.dcs", dcsIntImg, sizeDcsInt); EfiBootInst.SaveFile(L"\\EFI\\VeraCrypt\\DcsCfg.dcs", dcsCfgImg, sizeDcsCfg); EfiBootInst.SaveFile(L"\\EFI\\VeraCrypt\\LegacySpeaker.dcs", LegacySpeakerImg, sizeLegacySpeaker); EfiBootInst.SaveFile(L"\\EFI\\VeraCrypt\\DcsBml.dcs", BootMenuLockerImg, sizeBootMenuLocker); EfiBootInst.SaveFile(L"\\EFI\\VeraCrypt\\DcsInfo.dcs", DcsInfoImg, sizeDcsInfo); EfiBootInst.DelFile(L"\\EFI\\VeraCrypt\\PlatformInfo"); EfiBootInst.SetStartExec(L"VeraCrypt BootLoader (DcsBoot)", L"\\EFI\\VeraCrypt\\DcsBoot.efi"); // move configuration file from old location (if it exists) to new location // we don't force the move operation if the new location already exists EfiBootInst.RenameFile (L"\\DcsProp", L"\\EFI\\VeraCrypt\\DcsProp", FALSE); EfiBootInst.RenameFile (L"\\DcsBoot", L"\\EFI\\VeraCrypt\\DcsBoot", FALSE); // move the original bootloader backup from old location (if it exists) to new location // we don't force the move operation if the new location already exists if (Is64BitOs()) EfiBootInst.RenameFile (L"\\EFI\\Boot\\original_bootx64_vc_backup.efi", L"\\EFI\\Boot\\original_bootx64.vc_backup", FALSE); else EfiBootInst.RenameFile (L"\\EFI\\Boot\\original_bootia32_vc_backup.efi", L"\\EFI\\Boot\\original_bootia32.vc_backup", FALSE); // Clean beta9 EfiBootInst.DelFile(L"\\DcsBoot.efi"); EfiBootInst.DelFile(L"\\DcsInt.efi"); EfiBootInst.DelFile(L"\\DcsCfg.efi"); EfiBootInst.DelFile(L"\\LegacySpeaker.efi"); EfiBootInst.DelFile(L"\\DcsBoot"); EfiBootInst.DelFile(L"\\DcsProp"); } catch (...) { throw; } EfiBootInst.WriteConfig (L"\\EFI\\VeraCrypt\\DcsProp", preserveUserConfig, pim, hashAlg, NULL, ParentWindow); } else { byte bootLoaderBuf[TC_BOOT_LOADER_AREA_SIZE - TC_BOOT_ENCRYPTION_VOLUME_HEADER_SIZE] = {0}; CreateBootLoaderInMemory (bootLoaderBuf, sizeof (bootLoaderBuf), false, hiddenOSCreation); // Write MBR byte mbr[TC_SECTOR_SIZE_BIOS]; device.SeekAt (0); device.Read (mbr, sizeof (mbr)); if (preserveUserConfig && BufferContainsString (mbr, sizeof (mbr), TC_APP_NAME)) { uint16 version = BE16 (*(uint16 *) (mbr + TC_BOOT_SECTOR_VERSION_OFFSET)); if (version != 0) { bootLoaderBuf[TC_BOOT_SECTOR_USER_CONFIG_OFFSET] = mbr[TC_BOOT_SECTOR_USER_CONFIG_OFFSET]; memcpy (bootLoaderBuf + TC_BOOT_SECTOR_USER_MESSAGE_OFFSET, mbr + TC_BOOT_SECTOR_USER_MESSAGE_OFFSET, TC_BOOT_SECTOR_USER_MESSAGE_MAX_LENGTH); if (bootLoaderBuf[TC_BOOT_SECTOR_USER_CONFIG_OFFSET] & TC_BOOT_USER_CFG_FLAG_DISABLE_PIM) { if (pim >= 0) { memcpy (bootLoaderBuf + TC_BOOT_SECTOR_PIM_VALUE_OFFSET, &pim, TC_BOOT_SECTOR_PIM_VALUE_SIZE); } else memcpy (bootLoaderBuf + TC_BOOT_SECTOR_PIM_VALUE_OFFSET, mbr + TC_BOOT_SECTOR_PIM_VALUE_OFFSET, TC_BOOT_SECTOR_PIM_VALUE_SIZE); } } } memcpy (mbr, bootLoaderBuf, TC_MAX_MBR_BOOT_CODE_SIZE); device.SeekAt (0); device.Write (mbr, sizeof (mbr)); byte mbrVerificationBuf[TC_SECTOR_SIZE_BIOS]; device.SeekAt (0); device.Read (mbrVerificationBuf, sizeof (mbr)); if (memcmp (mbr, mbrVerificationBuf, sizeof (mbr)) != 0) throw ErrorException ("ERROR_MBR_PROTECTED", SRC_POS); // Write boot loader device.SeekAt (TC_SECTOR_SIZE_BIOS); device.Write (bootLoaderBuf + TC_SECTOR_SIZE_BIOS, sizeof (bootLoaderBuf) - TC_SECTOR_SIZE_BIOS); } } #ifndef SETUP bool BootEncryption::CheckBootloaderFingerprint (bool bSilent) { SystemDriveConfiguration config = GetSystemDriveConfiguration(); // return true for now when EFI system encryption is used until we implement // a dedicated EFI fingerprinting mechanism in VeraCrypt driver if (config.SystemPartition.IsGPT) return true; byte bootLoaderBuf[TC_BOOT_LOADER_AREA_SIZE - TC_BOOT_ENCRYPTION_VOLUME_HEADER_SIZE] = {0}; byte fingerprint[WHIRLPOOL_DIGESTSIZE + SHA512_DIGESTSIZE]; byte expectedFingerprint[WHIRLPOOL_DIGESTSIZE + SHA512_DIGESTSIZE]; bool bRet = false; try { // read bootloader fingerprint GetInstalledBootLoaderFingerprint (fingerprint); // compute expected fingerprint CreateBootLoaderInMemory (bootLoaderBuf, sizeof (bootLoaderBuf), false, false); ::ComputeBootloaderFingerprint (bootLoaderBuf, sizeof (bootLoaderBuf), expectedFingerprint); // compare values if (0 == memcmp (fingerprint, expectedFingerprint, sizeof (expectedFingerprint))) { bRet = true; } } catch (SystemException &e) { if (!bSilent && (GetLastError () != ERROR_INVALID_IMAGE_HASH)) e.Show (ParentWindow); } catch (Exception& e) { if (!bSilent) e.Show (ParentWindow); } return bRet; } #endif wstring BootEncryption::GetSystemLoaderBackupPath () { WCHAR pathBuf[MAX_PATH]; throw_sys_if (!SUCCEEDED (SHGetFolderPath (NULL, CSIDL_COMMON_APPDATA | CSIDL_FLAG_CREATE, NULL, 0, pathBuf))); wstring path = wstring (pathBuf) + L"\\" _T(TC_APP_NAME); CreateDirectory (path.c_str(), NULL); return path + L'\\' + TC_SYS_BOOT_LOADER_BACKUP_NAME; } void BootEncryption::RenameDeprecatedSystemLoaderBackup () { WCHAR pathBuf[MAX_PATH]; if (SUCCEEDED (SHGetFolderPath (NULL, CSIDL_COMMON_APPDATA, NULL, 0, pathBuf))) { wstring path = wstring (pathBuf) + L"\\" _T(TC_APP_NAME) + L'\\' + TC_SYS_BOOT_LOADER_BACKUP_NAME_LEGACY; if (FileExists (path.c_str()) && !FileExists (GetSystemLoaderBackupPath().c_str())) throw_sys_if (_wrename (path.c_str(), GetSystemLoaderBackupPath().c_str()) != 0); } } #ifndef SETUP void BootEncryption::CreateRescueIsoImage (bool initialSetup, const wstring &isoImagePath) { BootEncryptionStatus encStatus = GetStatus(); if (encStatus.SetupInProgress) throw ParameterIncorrect (SRC_POS); BOOL bIsGPT = GetSystemDriveConfiguration().SystemPartition.IsGPT; if (bIsGPT) { // create EFI disk structure DWORD sizeDcsBoot; #ifdef _WIN64 byte *dcsBootImg = MapResource(L"BIN", IDR_EFI_DCSBOOT, &sizeDcsBoot); #else byte *dcsBootImg = MapResource(L"BIN", Is64BitOs()? IDR_EFI_DCSBOOT : IDR_EFI_DCSBOOT32, &sizeDcsBoot); #endif if (!dcsBootImg) throw ParameterIncorrect (SRC_POS); DWORD sizeDcsInt; #ifdef _WIN64 byte *dcsIntImg = MapResource(L"BIN", IDR_EFI_DCSINT, &sizeDcsInt); #else byte *dcsIntImg = MapResource(L"BIN", Is64BitOs()? IDR_EFI_DCSINT: IDR_EFI_DCSINT32, &sizeDcsInt); #endif if (!dcsIntImg) throw ParameterIncorrect (SRC_POS); DWORD sizeDcsCfg; #ifdef _WIN64 byte *dcsCfgImg = MapResource(L"BIN", IDR_EFI_DCSCFG, &sizeDcsCfg); #else byte *dcsCfgImg = MapResource(L"BIN", Is64BitOs()? IDR_EFI_DCSCFG: IDR_EFI_DCSCFG32, &sizeDcsCfg); #endif if (!dcsCfgImg) throw ParameterIncorrect (SRC_POS); DWORD sizeLegacySpeaker; #ifdef _WIN64 byte *LegacySpeakerImg = MapResource(L"BIN", IDR_EFI_LEGACYSPEAKER, &sizeLegacySpeaker); #else byte *LegacySpeakerImg = MapResource(L"BIN", Is64BitOs()? IDR_EFI_LEGACYSPEAKER: IDR_EFI_LEGACYSPEAKER32, &sizeLegacySpeaker); #endif if (!LegacySpeakerImg) throw ParameterIncorrect (SRC_POS); DWORD sizeBootMenuLocker; #ifdef _WIN64 byte *BootMenuLockerImg = MapResource(L"BIN", IDR_EFI_DCSBML, &sizeBootMenuLocker); #else byte *BootMenuLockerImg = MapResource(L"BIN", Is64BitOs()? IDR_EFI_DCSBML: IDR_EFI_DCSBML32, &sizeBootMenuLocker); #endif if (!BootMenuLockerImg) throw ParameterIncorrect (SRC_POS); DWORD sizeDcsRescue; #ifdef _WIN64 byte *DcsRescueImg = MapResource(L"BIN", IDR_EFI_DCSRE, &sizeDcsRescue); #else byte *DcsRescueImg = MapResource(L"BIN", Is64BitOs()? IDR_EFI_DCSRE: IDR_EFI_DCSRE32, &sizeDcsRescue); #endif if (!DcsRescueImg) throw ParameterIncorrect (SRC_POS); DWORD sizeDcsInfo; #ifdef _WIN64 byte *DcsInfoImg = MapResource(L"BIN", IDR_EFI_DCSINFO, &sizeDcsInfo); #else byte *DcsInfoImg = MapResource(L"BIN", Is64BitOs()? IDR_EFI_DCSINFO: IDR_EFI_DCSINFO32, &sizeDcsInfo); #endif if (!DcsInfoImg) throw ParameterIncorrect (SRC_POS); char szTmpPath[MAX_PATH + 1], szTmpFilePath[MAX_PATH + 1]; if (!GetTempPathA (MAX_PATH, szTmpPath)) throw SystemException (SRC_POS); if (!GetTempFileNameA (szTmpPath, "_vrd", 0, szTmpFilePath)) throw SystemException (SRC_POS); finally_do_arg (char*, szTmpFilePath, { DeleteFileA (finally_arg);}); int ierr; zip_t* z = zip_open (szTmpFilePath, ZIP_CREATE | ZIP_TRUNCATE | ZIP_CHECKCONS, &ierr); if (!z) throw ParameterIncorrect (SRC_POS); finally_do_arg (zip_t**, &z, { if (*finally_arg) zip_discard (*finally_arg);}); if (!ZipAdd (z, Is64BitOs()? "EFI/Boot/bootx64.efi": "EFI/Boot/bootia32.efi", DcsRescueImg, sizeDcsRescue)) throw ParameterIncorrect (SRC_POS); if (!ZipAdd (z, "EFI/VeraCrypt/DcsBml.dcs", BootMenuLockerImg, sizeBootMenuLocker)) throw ParameterIncorrect (SRC_POS); if (!ZipAdd (z, "EFI/VeraCrypt/DcsBoot.efi", dcsBootImg, sizeDcsBoot)) throw ParameterIncorrect (SRC_POS); if (!ZipAdd (z, "EFI/VeraCrypt/DcsCfg.dcs", dcsCfgImg, sizeDcsCfg)) throw ParameterIncorrect (SRC_POS); if (!ZipAdd (z, "EFI/VeraCrypt/DcsInt.dcs", dcsIntImg, sizeDcsInt)) throw ParameterIncorrect (SRC_POS); if (!ZipAdd (z, "EFI/VeraCrypt/LegacySpeaker.dcs", LegacySpeakerImg, sizeLegacySpeaker)) throw ParameterIncorrect (SRC_POS); if (!ZipAdd (z, "EFI/VeraCrypt/DcsInfo.dcs", DcsInfoImg, sizeDcsInfo)) throw ParameterIncorrect (SRC_POS); Buffer volHeader(TC_BOOT_ENCRYPTION_VOLUME_HEADER_SIZE); // Volume header if (initialSetup) { if (!RescueVolumeHeaderValid) throw ParameterIncorrect (SRC_POS); memcpy (volHeader.Ptr (), RescueVolumeHeader, TC_BOOT_ENCRYPTION_VOLUME_HEADER_SIZE); } else { Device bootDevice (GetSystemDriveConfiguration().DevicePath, true); bootDevice.CheckOpened (SRC_POS); bootDevice.SeekAt (TC_BOOT_VOLUME_HEADER_SECTOR_OFFSET); bootDevice.Read (volHeader.Ptr (), TC_BOOT_ENCRYPTION_VOLUME_HEADER_SIZE); } if (!ZipAdd (z, "EFI/VeraCrypt/svh_bak", volHeader.Ptr (), TC_BOOT_ENCRYPTION_VOLUME_HEADER_SIZE)) throw ParameterIncorrect (SRC_POS); // Original system loader Buffer fileBuf (0); bool bLoadAdded = false; try { DWORD fileSize = 0; File sysBakFile (GetSystemLoaderBackupPath(), true); sysBakFile.CheckOpened (SRC_POS); sysBakFile.GetFileSize(fileSize); fileBuf.Resize ((DWORD) fileSize); DWORD sizeLoader = sysBakFile.Read (fileBuf.Ptr (), fileSize); bLoadAdded = ZipAdd (z, Is64BitOs()? "EFI/Boot/original_bootx64.vc_backup": "EFI/Boot/original_bootia32.vc_backup", fileBuf.Ptr (), sizeLoader); } catch (Exception &e) { e.Show (ParentWindow); Warning ("SYS_LOADER_UNAVAILABLE_FOR_RESCUE_DISK", ParentWindow); } if (!bLoadAdded) throw ParameterIncorrect (SRC_POS); EfiBootConf conf; Buffer propBuf (0); wstring dcsPropFileName = GetTempPathString() + L"_dcsproprescue"; finally_do_arg (wstring, dcsPropFileName, { DeleteFileW (finally_arg.c_str()); }); if (conf.Save(dcsPropFileName.c_str(), ParentWindow)) { DWORD fileSize = 0; File propFile (dcsPropFileName, true, false); propFile.CheckOpened (SRC_POS); propFile.GetFileSize(fileSize); propBuf.Resize (fileSize); DWORD sizeDcsProp = propFile.Read (propBuf.Ptr (), fileSize); if (!ZipAdd (z, "EFI/VeraCrypt/DcsProp", propBuf.Ptr (), sizeDcsProp)) throw ParameterIncorrect (SRC_POS); } else throw ParameterIncorrect (SRC_POS); // flush the zip content to the temporary file if (zip_close (z) < 0) throw ParameterIncorrect (SRC_POS); z = NULL; // read the zip data from the temporary file FILE* ftmpFile = fopen (szTmpFilePath, "rb"); if (!ftmpFile) throw ParameterIncorrect (SRC_POS); finally_do_arg (FILE*, ftmpFile, { fclose (finally_arg); }); unsigned long ulZipSize = (unsigned long) _filelength (_fileno (ftmpFile)); RescueZipData = new byte[ulZipSize]; if (!RescueZipData) throw bad_alloc(); if (ulZipSize != fread (RescueZipData, 1, ulZipSize, ftmpFile)) { delete [] RescueZipData; RescueZipData = NULL; throw ParameterIncorrect (SRC_POS); } RescueZipSize = ulZipSize; if (!isoImagePath.empty()) { File isoFile (isoImagePath, false, true); isoFile.Write (RescueZipData, RescueZipSize); } } else { Buffer imageBuf (RescueIsoImageSize); byte *image = imageBuf.Ptr(); memset (image, 0, RescueIsoImageSize); // Primary volume descriptor const char* szPrimVolDesc = "\001CD001\001"; const char* szPrimVolLabel = "VeraCrypt Rescue Disk "; memcpy (image + 0x8000, szPrimVolDesc, strlen(szPrimVolDesc) + 1); memcpy (image + 0x7fff + 41, szPrimVolLabel, strlen(szPrimVolLabel) + 1); *(uint32 *) (image + 0x7fff + 81) = RescueIsoImageSize / 2048; *(uint32 *) (image + 0x7fff + 85) = BE32 (RescueIsoImageSize / 2048); image[0x7fff + 121] = 1; image[0x7fff + 124] = 1; image[0x7fff + 125] = 1; image[0x7fff + 128] = 1; image[0x7fff + 130] = 8; image[0x7fff + 131] = 8; image[0x7fff + 133] = 10; image[0x7fff + 140] = 10; image[0x7fff + 141] = 0x14; image[0x7fff + 157] = 0x22; image[0x7fff + 159] = 0x18; // Boot record volume descriptor const char* szBootRecDesc = "CD001\001EL TORITO SPECIFICATION"; memcpy (image + 0x8801, szBootRecDesc, strlen(szBootRecDesc) + 1); image[0x8800 + 0x47] = 0x19; // Volume descriptor set terminator const char* szVolDescTerm = "\377CD001\001"; memcpy (image + 0x9000, szVolDescTerm, strlen(szVolDescTerm) + 1); // Path table image[0xA000 + 0] = 1; image[0xA000 + 2] = 0x18; image[0xA000 + 6] = 1; // Root directory image[0xc000 + 0] = 0x22; image[0xc000 + 2] = 0x18; image[0xc000 + 9] = 0x18; image[0xc000 + 11] = 0x08; image[0xc000 + 16] = 0x08; image[0xc000 + 25] = 0x02; image[0xc000 + 28] = 0x01; image[0xc000 + 31] = 0x01; image[0xc000 + 32] = 0x01; image[0xc000 + 34] = 0x22; image[0xc000 + 36] = 0x18; image[0xc000 + 43] = 0x18; image[0xc000 + 45] = 0x08; image[0xc000 + 50] = 0x08; image[0xc000 + 59] = 0x02; image[0xc000 + 62] = 0x01; *(uint32 *) (image + 0xc000 + 65) = 0x010101; // Validation entry image[0xc800] = 1; int offset = 0xc800 + 0x1c; image[offset++] = 0xaa; image[offset++] = 0x55; image[offset++] = 0x55; image[offset] = 0xaa; // Initial entry offset = 0xc820; image[offset++] = 0x88; image[offset++] = 2; image[0xc820 + 6] = 1; image[0xc820 + 8] = TC_CD_BOOT_LOADER_SECTOR; // TrueCrypt Boot Loader CreateBootLoaderInMemory (image + TC_CD_BOOTSECTOR_OFFSET, TC_BOOT_LOADER_AREA_SIZE, true); // Volume header if (initialSetup) { if (!RescueVolumeHeaderValid) throw ParameterIncorrect (SRC_POS); memcpy (image + TC_CD_BOOTSECTOR_OFFSET + TC_BOOT_VOLUME_HEADER_SECTOR_OFFSET, RescueVolumeHeader, TC_BOOT_ENCRYPTION_VOLUME_HEADER_SIZE); } else { Device bootDevice (GetSystemDriveConfiguration().DevicePath, true); bootDevice.CheckOpened (SRC_POS); bootDevice.SeekAt (TC_BOOT_VOLUME_HEADER_SECTOR_OFFSET); bootDevice.Read (image + TC_CD_BOOTSECTOR_OFFSET + TC_BOOT_VOLUME_HEADER_SECTOR_OFFSET, TC_BOOT_ENCRYPTION_VOLUME_HEADER_SIZE); } // Original system loader try { File sysBakFile (GetSystemLoaderBackupPath(), true); sysBakFile.CheckOpened (SRC_POS); sysBakFile.Read (image + TC_CD_BOOTSECTOR_OFFSET + TC_ORIG_BOOT_LOADER_BACKUP_SECTOR_OFFSET, TC_BOOT_LOADER_AREA_SIZE); image[TC_CD_BOOTSECTOR_OFFSET + TC_BOOT_SECTOR_CONFIG_OFFSET] |= TC_BOOT_CFG_FLAG_RESCUE_DISK_ORIG_SYS_LOADER; } catch (Exception &e) { e.Show (ParentWindow); Warning ("SYS_LOADER_UNAVAILABLE_FOR_RESCUE_DISK", ParentWindow); } // Boot loader backup CreateBootLoaderInMemory (image + TC_CD_BOOTSECTOR_OFFSET + TC_BOOT_LOADER_BACKUP_RESCUE_DISK_SECTOR_OFFSET, TC_BOOT_LOADER_AREA_SIZE, false); RescueIsoImage = new byte[RescueIsoImageSize]; if (!RescueIsoImage) throw bad_alloc(); memcpy (RescueIsoImage, image, RescueIsoImageSize); if (!isoImagePath.empty()) { File isoFile (isoImagePath, false, true); isoFile.Write (image, RescueIsoImageSize); } } } #endif bool BootEncryption::IsCDRecorderPresent () { ICDBurn* pICDBurn; BOOL bHasRecorder = FALSE; if (SUCCEEDED( CoCreateInstance (CLSID_CDBurn, NULL,CLSCTX_INPROC_SERVER,IID_ICDBurn,(LPVOID*)&pICDBurn))) { if (pICDBurn->HasRecordableDrive (&bHasRecorder) != S_OK) { bHasRecorder = FALSE; } pICDBurn->Release(); } return bHasRecorder? true : false; } bool BootEncryption::VerifyRescueDisk () { BOOL bIsGPT = GetSystemDriveConfiguration().SystemPartition.IsGPT; if ((bIsGPT && !RescueZipData) || (!bIsGPT && !RescueIsoImage)) throw ParameterIncorrect (SRC_POS); if (bIsGPT) { const wchar_t* efi64Files[] = { L"EFI/Boot/bootx64.efi", L"EFI/VeraCrypt/DcsBml.dcs", L"EFI/VeraCrypt/DcsBoot.efi", L"EFI/VeraCrypt/DcsCfg.dcs", L"EFI/VeraCrypt/DcsInt.dcs", L"EFI/VeraCrypt/LegacySpeaker.dcs", L"EFI/VeraCrypt/svh_bak", L"EFI/Boot/original_bootx64.vc_backup" }; const wchar_t* efi32Files[] = { L"EFI/Boot/bootia32.efi", L"EFI/VeraCrypt/DcsBml.dcs", L"EFI/VeraCrypt/DcsBoot.efi", L"EFI/VeraCrypt/DcsCfg.dcs", L"EFI/VeraCrypt/DcsInt.dcs", L"EFI/VeraCrypt/LegacySpeaker.dcs", L"EFI/VeraCrypt/svh_bak", L"EFI/Boot/original_bootia32.vc_backup" }; zip_error_t zerr; zip_source_t* zsrc = zip_source_buffer_create (RescueZipData, RescueZipSize, 0, &zerr); if (!zsrc) throw ParameterIncorrect (SRC_POS); zip_t* z = zip_open_from_source (zsrc, ZIP_CHECKCONS | ZIP_RDONLY, &zerr); if (!z) { zip_source_free (zsrc); throw ParameterIncorrect (SRC_POS); } finally_do_arg (zip_t*, z, { zip_close (finally_arg); }); for (WCHAR drive = L'Z'; drive >= L'C'; --drive) { try { WCHAR rootPath[4] = { drive, L':', L'\\', 0}; UINT driveType = GetDriveType (rootPath); if (DRIVE_REMOVABLE == driveType) { // check if it is FAT/FAT32 WCHAR szNameBuffer[TC_MAX_PATH]; if (GetVolumeInformationW (rootPath, NULL, 0, NULL, NULL, NULL, szNameBuffer, ARRAYSIZE(szNameBuffer)) && !wcsncmp (szNameBuffer, L"FAT", 3)) { int i; const wchar_t** efiFiles = Is64BitOs()? efi64Files: efi32Files; int efiFilesSize = Is64BitOs()? ARRAYSIZE(efi64Files): ARRAYSIZE(efi32Files); for (i = 0; i < efiFilesSize; i++) { bool bMatch = false; zip_int64_t index = zip_name_locate (z, WideToUtf8String (efiFiles[i]).c_str(), ZIP_FL_NOCASE); if (index >= 0) { zip_stat_t stat; if ((0 == zip_stat_index (z, index, ZIP_FL_NOCASE, &stat)) && (stat.valid & ZIP_STAT_SIZE)) { // check that the file exists on the disk and that it has the same content StringCbCopyW (szNameBuffer, sizeof (szNameBuffer), rootPath); StringCbCatW (szNameBuffer, sizeof (szNameBuffer), efiFiles[i]); try { DWORD dwSize = 0; File diskFile (szNameBuffer, true); diskFile.CheckOpened (SRC_POS); diskFile.GetFileSize (dwSize); if (dwSize == (DWORD) stat.size) { Buffer fileBuf (dwSize); if (dwSize == diskFile.Read (fileBuf.Ptr (), dwSize)) { Buffer efiBuf (dwSize); zip_file_t* zf = zip_fopen_index (z, index, 0); if (zf) { if (0 < zip_fread (zf, efiBuf.Ptr (), stat.size)) { bMatch = (memcmp (efiBuf.Ptr(), fileBuf.Ptr(), dwSize) == 0); } zip_fclose (zf); } } } } catch (...) { } } } else { // entry not found in our Rescue ZIP image. Skip it. bMatch = true; } if (!bMatch) break; } if (i == efiFilesSize) { // All entries processed return true; } } } } catch (...) { } } } else { size_t verifiedSectorCount = (TC_CD_BOOTSECTOR_OFFSET + TC_ORIG_BOOT_LOADER_BACKUP_SECTOR_OFFSET + TC_BOOT_LOADER_AREA_SIZE) / 2048; Buffer buffer ((verifiedSectorCount + 1) * 2048); for (WCHAR drive = L'Z'; drive >= L'C'; --drive) { try { WCHAR rootPath[4] = { drive, L':', L'\\', 0}; UINT driveType = GetDriveType (rootPath); // check that it is a CD/DVD drive or a removable media in case a bootable // USB key was created from the rescue disk ISO file if ((DRIVE_CDROM == driveType) || (DRIVE_REMOVABLE == driveType)) { rootPath[2] = 0; // remove trailing backslash Device driveDevice (rootPath, true); driveDevice.CheckOpened (SRC_POS); DWORD bytesRead = driveDevice.Read (buffer.Ptr(), (DWORD) buffer.Size()); if (bytesRead != buffer.Size()) continue; if (memcmp (buffer.Ptr(), RescueIsoImage, buffer.Size()) == 0) return true; } } catch (...) { } } } return false; } bool BootEncryption::VerifyRescueDiskImage (const wchar_t* imageFile) { BOOL bIsGPT = GetSystemDriveConfiguration().SystemPartition.IsGPT; if ((bIsGPT && !RescueZipData) || (!bIsGPT && !RescueIsoImage)) throw ParameterIncorrect (SRC_POS); if (bIsGPT) { try { DWORD dwSize = 0; File rescueFile (imageFile, true); rescueFile.CheckOpened (SRC_POS); rescueFile.GetFileSize (dwSize); Buffer rescueData (dwSize); if (dwSize == rescueFile.Read (rescueData.Ptr (), dwSize)) { zip_error_t zerr; zip_source_t* zsrc = zip_source_buffer_create (rescueData.Ptr (), dwSize, 0, &zerr); if (!zsrc) return false; zip_t* zFile = zip_open_from_source (zsrc, ZIP_CHECKCONS | ZIP_RDONLY, &zerr); if (!zFile) { zip_source_free (zsrc); throw ParameterIncorrect (SRC_POS); } finally_do_arg (zip_t*, zFile, { zip_close (finally_arg); }); zsrc = zip_source_buffer_create (RescueZipData, RescueZipSize, 0, &zerr); if (!zsrc) return false; zip_t* zMem = zip_open_from_source (zsrc, ZIP_CHECKCONS | ZIP_RDONLY, &zerr); if (!zMem) { zip_source_free (zsrc); throw ParameterIncorrect (SRC_POS); } finally_do_arg (zip_t*, zMem, { zip_close (finally_arg); }); const wchar_t* efi64Files[] = { L"EFI/Boot/bootx64.efi", L"EFI/VeraCrypt/DcsBml.dcs", L"EFI/VeraCrypt/DcsBoot.efi", L"EFI/VeraCrypt/DcsCfg.dcs", L"EFI/VeraCrypt/DcsInt.dcs", L"EFI/VeraCrypt/LegacySpeaker.dcs", L"EFI/VeraCrypt/svh_bak", L"EFI/Boot/original_bootx64.vc_backup" }; const wchar_t* efi32Files[] = { L"EFI/Boot/bootia32.efi", L"EFI/VeraCrypt/DcsBml.dcs", L"EFI/VeraCrypt/DcsBoot.efi", L"EFI/VeraCrypt/DcsCfg.dcs", L"EFI/VeraCrypt/DcsInt.dcs", L"EFI/VeraCrypt/LegacySpeaker.dcs", L"EFI/VeraCrypt/svh_bak", L"EFI/Boot/original_bootia32.vc_backup" }; int i; zip_stat_t statMem, statFile; zip_int64_t indexMem, indexFile; const wchar_t** efiFiles = Is64BitOs()? efi64Files: efi32Files; int efiFilesSize = Is64BitOs()? ARRAYSIZE(efi64Files): ARRAYSIZE(efi32Files); for (i = 0; i < efiFilesSize; i++) { bool bMatch = false; indexMem = zip_name_locate (zMem, WideToUtf8String (efiFiles[i]).c_str(), ZIP_FL_NOCASE); if (indexMem >= 0) { if ((0 == zip_stat_index (zMem, indexMem, ZIP_FL_NOCASE, &statMem)) && (statMem.valid & ZIP_STAT_SIZE)) { indexFile = zip_name_locate (zFile, WideToUtf8String (efiFiles[i]).c_str(), ZIP_FL_NOCASE); if (indexFile >= 0) { if ((0 == zip_stat_index (zFile, indexFile, ZIP_FL_NOCASE, &statFile)) && (statFile.valid & ZIP_STAT_SIZE)) { if (statMem.size == statFile.size) { Buffer fileBuf ((size_t) statFile.size); Buffer memBuf ((size_t) statMem.size); zip_file_t* zfMem = zip_fopen_index (zMem, indexMem, 0); if (zfMem) { if (0 < zip_fread (zfMem, memBuf.Ptr (), statMem.size)) { zip_file_t* zfFile = zip_fopen_index (zFile, indexFile, 0); if (zfFile) { if (0 < zip_fread (zfFile, fileBuf.Ptr (), statFile.size)) { bMatch = (memcmp (memBuf.Ptr(), fileBuf.Ptr(), (size_t) statFile.size) == 0); } zip_fclose (zfFile); } } zip_fclose (zfMem); } } } } } } else { // entry not found in our internal Rescue ZIP image. Skip it. bMatch = true; } if (!bMatch) break; } if (i == efiFilesSize) { // All entries processed return true; } } } catch (...) { } } else { try { File rescueFile (imageFile, true); rescueFile.CheckOpened (SRC_POS); size_t verifiedSectorCount = (TC_CD_BOOTSECTOR_OFFSET + TC_ORIG_BOOT_LOADER_BACKUP_SECTOR_OFFSET + TC_BOOT_LOADER_AREA_SIZE) / 2048; Buffer buffer ((verifiedSectorCount + 1) * 2048); DWORD bytesRead = rescueFile.Read (buffer.Ptr(), (DWORD) buffer.Size()); if ( (bytesRead == buffer.Size()) && (memcmp (buffer.Ptr(), RescueIsoImage, buffer.Size()) == 0) ) { return true; } } catch (...) { } } return false; } #ifndef SETUP void BootEncryption::CreateVolumeHeader (uint64 volumeSize, uint64 encryptedAreaStart, Password *password, int ea, int mode, int pkcs5, int pim) { PCRYPTO_INFO cryptoInfo = NULL; if (!IsRandomNumberGeneratorStarted()) throw ParameterIncorrect (SRC_POS); throw_sys_if (CreateVolumeHeaderInMemory (ParentWindow, TRUE, (char *) VolumeHeader, ea, mode, password, pkcs5, pim, NULL, &cryptoInfo, volumeSize, 0, encryptedAreaStart, 0, TC_SYSENC_KEYSCOPE_MIN_REQ_PROG_VERSION, TC_HEADER_FLAG_ENCRYPTED_SYSTEM, TC_SECTOR_SIZE_BIOS, FALSE) != 0); finally_do_arg (PCRYPTO_INFO*, &cryptoInfo, { crypto_close (*finally_arg); }); // Initial rescue disk assumes encryption of the drive has been completed (EncryptedAreaLength == volumeSize) memcpy (RescueVolumeHeader, VolumeHeader, sizeof (RescueVolumeHeader)); if (0 != ReadVolumeHeader (TRUE, (char *) RescueVolumeHeader, password, pkcs5, pim, FALSE, NULL, cryptoInfo)) throw ParameterIncorrect (SRC_POS); DecryptBuffer (RescueVolumeHeader + HEADER_ENCRYPTED_DATA_OFFSET, HEADER_ENCRYPTED_DATA_SIZE, cryptoInfo); if (GetHeaderField32 (RescueVolumeHeader, TC_HEADER_OFFSET_MAGIC) != 0x56455241) throw ParameterIncorrect (SRC_POS); byte *fieldPos = RescueVolumeHeader + TC_HEADER_OFFSET_ENCRYPTED_AREA_LENGTH; mputInt64 (fieldPos, volumeSize); // CRC of the header fields uint32 crc = GetCrc32 (RescueVolumeHeader + TC_HEADER_OFFSET_MAGIC, TC_HEADER_OFFSET_HEADER_CRC - TC_HEADER_OFFSET_MAGIC); fieldPos = RescueVolumeHeader + TC_HEADER_OFFSET_HEADER_CRC; mputLong (fieldPos, crc); EncryptBuffer (RescueVolumeHeader + HEADER_ENCRYPTED_DATA_OFFSET, HEADER_ENCRYPTED_DATA_SIZE, cryptoInfo); VolumeHeaderValid = true; RescueVolumeHeaderValid = true; } void BootEncryption::InstallVolumeHeader () { if (!VolumeHeaderValid) throw ParameterIncorrect (SRC_POS); Device device (GetSystemDriveConfiguration().DevicePath); device.CheckOpened (SRC_POS); device.SeekAt (TC_BOOT_VOLUME_HEADER_SECTOR_OFFSET); device.Write ((byte *) VolumeHeader, sizeof (VolumeHeader)); } // For synchronous operations use AbortSetupWait() void BootEncryption::AbortSetup () { CallDriver (TC_IOCTL_ABORT_BOOT_ENCRYPTION_SETUP); } // For asynchronous operations use AbortSetup() void BootEncryption::AbortSetupWait () { CallDriver (TC_IOCTL_ABORT_BOOT_ENCRYPTION_SETUP); BootEncryptionStatus encStatus = GetStatus(); while (encStatus.SetupInProgress) { Sleep (TC_ABORT_TRANSFORM_WAIT_INTERVAL); encStatus = GetStatus(); } } #define VC_EFI_BOOTLOADER_NAME L"DcsBoot" void BootEncryption::BackupSystemLoader () { if (GetSystemDriveConfiguration().SystemPartition.IsGPT) { if (!IsAdmin()) { if (IsUacSupported()) { Elevator::BackupEfiSystemLoader (); return; } else { Warning ("ADMIN_PRIVILEGES_WARN_DEVICES", ParentWindow); } } unsigned __int64 loaderSize = 0; finally_do ({ EfiBootInst.DismountBootPartition(); }); EfiBootInst.MountBootPartition(0); EfiBootInst.GetFileSize(Is64BitOs()? L"\\EFI\\Boot\\bootx64.efi" : L"\\EFI\\Boot\\bootia32.efi", loaderSize); std::vector<byte> bootLoaderBuf ((size_t) loaderSize); EfiBootInst.ReadFile(Is64BitOs()? L"\\EFI\\Boot\\bootx64.efi": L"\\EFI\\Boot\\bootia32.efi", &bootLoaderBuf[0], (DWORD) loaderSize); // Prevent VeraCrypt EFI loader from being backed up for (size_t i = 0; i < (size_t) loaderSize - (wcslen (VC_EFI_BOOTLOADER_NAME) * 2); ++i) { if (memcmp (&bootLoaderBuf[i], VC_EFI_BOOTLOADER_NAME, wcslen (VC_EFI_BOOTLOADER_NAME) * 2) == 0) { if (AskWarnNoYes ("TC_BOOT_LOADER_ALREADY_INSTALLED", ParentWindow) == IDNO) throw UserAbort (SRC_POS); return; } } if (Is64BitOs()) { EfiBootInst.CopyFile(L"\\EFI\\Boot\\bootx64.efi", GetSystemLoaderBackupPath().c_str()); EfiBootInst.CopyFile(L"\\EFI\\Boot\\bootx64.efi", L"\\EFI\\Boot\\original_bootx64.vc_backup"); } else { EfiBootInst.CopyFile(L"\\EFI\\Boot\\bootia32.efi", GetSystemLoaderBackupPath().c_str()); EfiBootInst.CopyFile(L"\\EFI\\Boot\\bootia32.efi", L"\\EFI\\Boot\\original_bootia32.vc_backup"); } } else { Device device (GetSystemDriveConfiguration().DevicePath, true); device.CheckOpened (SRC_POS); byte bootLoaderBuf[TC_BOOT_LOADER_AREA_SECTOR_COUNT * TC_SECTOR_SIZE_BIOS]; device.SeekAt (0); device.Read (bootLoaderBuf, sizeof (bootLoaderBuf)); // Prevent TrueCrypt loader from being backed up for (size_t i = 0; i < sizeof (bootLoaderBuf) - strlen (TC_APP_NAME); ++i) { if (memcmp (bootLoaderBuf + i, TC_APP_NAME, strlen (TC_APP_NAME)) == 0) { if (AskWarnNoYes ("TC_BOOT_LOADER_ALREADY_INSTALLED", ParentWindow) == IDNO) throw UserAbort (SRC_POS); return; } } File backupFile (GetSystemLoaderBackupPath(), false, true); backupFile.Write (bootLoaderBuf, sizeof (bootLoaderBuf)); } } void BootEncryption::RestoreSystemLoader () { SystemDriveConfiguration config = GetSystemDriveConfiguration(); if (config.SystemPartition.IsGPT) { if (!IsAdmin()) { if (IsUacSupported()) { Elevator::RestoreEfiSystemLoader (); return; } else { Warning ("ADMIN_PRIVILEGES_WARN_DEVICES", ParentWindow); } } finally_do ({ EfiBootInst.DismountBootPartition(); }); EfiBootInst.MountBootPartition(0); EfiBootInst.DeleteStartExec(); EfiBootInst.DeleteStartExec(0xDC5B, L"Driver"); // remove DcsBml boot driver it was installed if (Is64BitOs()) EfiBootInst.RenameFile(L"\\EFI\\Boot\\original_bootx64.vc_backup", L"\\EFI\\Boot\\bootx64.efi", TRUE); else EfiBootInst.RenameFile(L"\\EFI\\Boot\\original_bootia32.vc_backup", L"\\EFI\\Boot\\bootia32.efi", TRUE); EfiBootInst.DelFile(L"\\DcsBoot.efi"); EfiBootInst.DelFile(L"\\DcsInt.efi"); EfiBootInst.DelFile(L"\\DcsCfg.efi"); EfiBootInst.DelFile(L"\\LegacySpeaker.efi"); EfiBootInst.DelFile(L"\\DcsBoot"); EfiBootInst.DelFile(L"\\DcsProp"); EfiBootInst.DelFile(L"\\EFI\\VeraCrypt\\DcsBoot.efi"); EfiBootInst.DelFile(L"\\EFI\\VeraCrypt\\DcsInt.dcs"); EfiBootInst.DelFile(L"\\EFI\\VeraCrypt\\DcsCfg.dcs"); EfiBootInst.DelFile(L"\\EFI\\VeraCrypt\\LegacySpeaker.dcs"); EfiBootInst.DelFile(L"\\EFI\\VeraCrypt\\DcsBml.dcs"); EfiBootInst.DelFile(L"\\EFI\\VeraCrypt\\DcsBoot"); EfiBootInst.DelFile(L"\\EFI\\VeraCrypt\\DcsInfo.dcs"); EfiBootInst.DelFile(L"\\EFI\\VeraCrypt\\PlatformInfo"); EfiBootInst.DelFile(L"\\EFI\\VeraCrypt\\DcsProp"); EfiBootInst.DelDir (L"\\EFI\\VeraCrypt"); } else { byte bootLoaderBuf[TC_BOOT_LOADER_AREA_SECTOR_COUNT * TC_SECTOR_SIZE_BIOS]; File backupFile (GetSystemLoaderBackupPath(), true); backupFile.CheckOpened(SRC_POS); if (backupFile.Read (bootLoaderBuf, sizeof (bootLoaderBuf)) != sizeof (bootLoaderBuf)) throw ParameterIncorrect (SRC_POS); Device device (GetSystemDriveConfiguration().DevicePath); device.CheckOpened (SRC_POS); // Preserve current partition table byte mbr[TC_SECTOR_SIZE_BIOS]; device.SeekAt (0); device.Read (mbr, sizeof (mbr)); memcpy (bootLoaderBuf + TC_MAX_MBR_BOOT_CODE_SIZE, mbr + TC_MAX_MBR_BOOT_CODE_SIZE, sizeof (mbr) - TC_MAX_MBR_BOOT_CODE_SIZE); device.SeekAt (0); device.Write (bootLoaderBuf, sizeof (bootLoaderBuf)); } } #endif // SETUP static bool CompareMultiString (const char* str1, const char* str2) { size_t l1, l2; if (!str1 || !str2) return false; while (true) { l1 = strlen (str1); l2 = strlen (str2); if (l1 == l2) { if (l1 == 0) break; // we reached the end if (_stricmp (str1, str2) == 0) { str1 += l1 + 1; str2 += l2 + 1; } else return false; } else return false; } return true; } static void AppendToMultiString (char* mszDest, DWORD dwMaxDesSize, DWORD& dwDestSize, const char* input) { // find the index of the end of the last string DWORD dwInputSize = (DWORD) strlen (input) + 1; DWORD index = dwDestSize; while (index > 0 && mszDest[index - 1] == 0) index--; if (dwMaxDesSize > (index + 1 + dwInputSize + 1)) { if (index == 0) { StringCchCopyA ((char *) mszDest, dwMaxDesSize, input); mszDest [dwInputSize] = 0; dwDestSize = dwInputSize + 1; } else { mszDest[index] = 0; StringCchCopyA ((char *) &mszDest[index + 1], dwMaxDesSize - index - 1, input); mszDest [index + 1 + dwInputSize] = 0; dwDestSize = index + 1 + dwInputSize + 1; } } } // mszDest is guaranteed to be double zero terminated static bool RemoveFromMultiString (char* mszDest, DWORD& dwDestSize, const char* input) { bool bRet = false; if (mszDest && input) { DWORD offset, remainingSize = dwDestSize; while (*mszDest) { if (_stricmp (mszDest, input) == 0) { offset = (DWORD) strlen (input) + 1; memmove (mszDest, mszDest + offset, remainingSize - offset); dwDestSize -= offset; bRet = true; break; } offset = (DWORD) strlen (mszDest) + 1; mszDest += offset; remainingSize -= offset; } } return bRet; } void BootEncryption::RegisterFilter (bool registerFilter, FilterType filterType, const GUID *deviceClassGuid) { string filter; string filterReg; HKEY regKey; switch (filterType) { case DriveFilter: case VolumeFilter: filter = "veracrypt"; filterReg = "UpperFilters"; regKey = OpenDeviceClassRegKey (deviceClassGuid); throw_sys_if (regKey == INVALID_HANDLE_VALUE); break; case DumpFilter: if (!IsOSAtLeast (WIN_VISTA)) return; filter = "veracrypt.sys"; filterReg = "DumpFilters"; SetLastError (RegOpenKeyEx (HKEY_LOCAL_MACHINE, L"SYSTEM\\CurrentControlSet\\Control\\CrashControl", 0, KEY_READ | KEY_WRITE, ®Key)); throw_sys_if (GetLastError() != ERROR_SUCCESS); break; default: throw ParameterIncorrect (SRC_POS); } finally_do_arg (HKEY, regKey, { RegCloseKey (finally_arg); }); if (registerFilter) { if (filterType != DumpFilter) { // Register class filter below all other filters in the stack size_t strSize = filter.size() + 1; byte regKeyBuf[65536]; DWORD size = (DWORD) (sizeof (regKeyBuf) - strSize); // SetupInstallFromInfSection() does not support prepending of values so we have to modify the registry directly StringCchCopyA ((char *) regKeyBuf, ARRAYSIZE(regKeyBuf), filter.c_str()); if (RegQueryValueExA (regKey, filterReg.c_str(), NULL, NULL, regKeyBuf + strSize, &size) != ERROR_SUCCESS) size = 1; SetLastError (RegSetValueExA (regKey, filterReg.c_str(), 0, REG_MULTI_SZ, regKeyBuf, (DWORD) strSize + size)); throw_sys_if (GetLastError() != ERROR_SUCCESS); } else { // workaround rare SetupInstallFromInfSection which overwrite value instead of appending new value // read initial value DWORD strSize = (DWORD) filter.size() + 1, expectedSize; Buffer expectedRegKeyBuf(65536), outputRegKeyBuf(65536); byte* pbExpectedRegKeyBuf = expectedRegKeyBuf.Ptr (); byte* pbOutputRegKeyBuf = outputRegKeyBuf.Ptr (); DWORD initialSize = (DWORD) (expectedRegKeyBuf.Size() - strSize - 2); if (RegQueryValueExA (regKey, filterReg.c_str(), NULL, NULL, pbExpectedRegKeyBuf, &initialSize) != ERROR_SUCCESS) { StringCchCopyA ((char *) pbExpectedRegKeyBuf, expectedRegKeyBuf.Size(), filter.c_str()); pbExpectedRegKeyBuf [strSize] = 0; expectedSize = strSize + 1; } else { expectedSize = initialSize; AppendToMultiString ((char *) pbExpectedRegKeyBuf, (DWORD) expectedRegKeyBuf.Size(), expectedSize, filter.c_str()); } RegisterDriverInf (registerFilter, filter, filterReg, ParentWindow, regKey); // check if operation successful initialSize = (DWORD) outputRegKeyBuf.Size() - 2; if (RegQueryValueExA (regKey, filterReg.c_str(), NULL, NULL, pbOutputRegKeyBuf, &initialSize) != ERROR_SUCCESS) { pbOutputRegKeyBuf [0] = 0; pbOutputRegKeyBuf [1] = 0; } else { // append two \0 at the end if they are missing if (pbOutputRegKeyBuf [initialSize - 1] != 0) { pbOutputRegKeyBuf [initialSize] = 0; pbOutputRegKeyBuf [initialSize + 1] = 0; } else if (pbOutputRegKeyBuf [initialSize - 2] != 0) { pbOutputRegKeyBuf [initialSize] = 0; } } if (!CompareMultiString ((char *) pbExpectedRegKeyBuf, (char *) pbOutputRegKeyBuf)) { // Set value manually SetLastError (RegSetValueExA (regKey, filterReg.c_str(), 0, REG_MULTI_SZ, pbExpectedRegKeyBuf, expectedSize)); throw_sys_if (GetLastError() != ERROR_SUCCESS); } } } else { RegisterDriverInf (registerFilter, filter, filterReg, ParentWindow, regKey); // remove value in case it was not done properly Buffer regKeyBuf(65536); byte* pbRegKeyBuf = regKeyBuf.Ptr (); DWORD initialSize = (DWORD) regKeyBuf.Size() - 2; if ( (RegQueryValueExA (regKey, filterReg.c_str(), NULL, NULL, pbRegKeyBuf, &initialSize) == ERROR_SUCCESS) && (initialSize >= ((DWORD) filter.size())) ) { // append two \0 at the end if they are missing if (pbRegKeyBuf [initialSize - 1] != 0) { pbRegKeyBuf [initialSize] = 0; pbRegKeyBuf [initialSize + 1] = 0; initialSize += 2; } else if (pbRegKeyBuf [initialSize - 2] != 0) { pbRegKeyBuf [initialSize] = 0; initialSize ++; } if (RemoveFromMultiString ((char*) pbRegKeyBuf, initialSize, filter.c_str())) { // Set value manually SetLastError (RegSetValueExA (regKey, filterReg.c_str(), 0, REG_MULTI_SZ, pbRegKeyBuf, initialSize)); throw_sys_if (GetLastError() != ERROR_SUCCESS); } } } } void BootEncryption::RegisterFilterDriver (bool registerDriver, FilterType filterType) { if (!IsAdmin() && IsUacSupported()) { Elevator::RegisterFilterDriver (registerDriver, filterType); return; } switch (filterType) { case DriveFilter: RegisterFilter (registerDriver, filterType, &GUID_DEVCLASS_DISKDRIVE); break; case VolumeFilter: RegisterFilter (registerDriver, filterType, &GUID_DEVCLASS_VOLUME); RegisterFilter (registerDriver, filterType, &GUID_DEVCLASS_FLOPPYDISK); break; case DumpFilter: RegisterFilter (registerDriver, filterType); break; default: throw ParameterIncorrect (SRC_POS); } } void BootEncryption::RegisterSystemFavoritesService (BOOL registerService, BOOL noFileHandling) { SC_HANDLE scm = OpenSCManager (NULL, NULL, SC_MANAGER_ALL_ACCESS); throw_sys_if (!scm); finally_do_arg (SC_HANDLE, scm, { CloseServiceHandle (finally_arg); }); wstring servicePath = GetServiceConfigPath (_T(TC_APP_NAME) L".exe", false); wstring serviceLegacyPath = GetServiceConfigPath (_T(TC_APP_NAME) L".exe", true); if (registerService) { try { RegisterSystemFavoritesService (FALSE, noFileHandling); } catch (...) { } if (!noFileHandling) { wchar_t appPath[TC_MAX_PATH]; throw_sys_if (!GetModuleFileName (NULL, appPath, ARRAYSIZE (appPath))); throw_sys_if (!CopyFile (appPath, servicePath.c_str(), FALSE)); } SC_HANDLE service = CreateService (scm, TC_SYSTEM_FAVORITES_SERVICE_NAME, _T(TC_APP_NAME) L" System Favorites", SERVICE_ALL_ACCESS, SERVICE_WIN32_OWN_PROCESS, SERVICE_AUTO_START, SERVICE_ERROR_NORMAL, (wstring (L"\"") + servicePath + L"\" " TC_SYSTEM_FAVORITES_SERVICE_CMDLINE_OPTION).c_str(), TC_SYSTEM_FAVORITES_SERVICE_LOAD_ORDER_GROUP, NULL, NULL, NULL, NULL); throw_sys_if (!service); SERVICE_DESCRIPTION description; description.lpDescription = L"Mounts VeraCrypt system favorite volumes."; ChangeServiceConfig2 (service, SERVICE_CONFIG_DESCRIPTION, &description); CloseServiceHandle (service); try { WriteLocalMachineRegistryString (L"SYSTEM\\CurrentControlSet\\Control\\SafeBoot\\Minimal\\" TC_SYSTEM_FAVORITES_SERVICE_NAME, NULL, L"Service", FALSE); WriteLocalMachineRegistryString (L"SYSTEM\\CurrentControlSet\\Control\\SafeBoot\\Network\\" TC_SYSTEM_FAVORITES_SERVICE_NAME, NULL, L"Service", FALSE); SetDriverConfigurationFlag (TC_DRIVER_CONFIG_CACHE_BOOT_PASSWORD_FOR_SYS_FAVORITES, true); } catch (...) { try { RegisterSystemFavoritesService (FALSE, noFileHandling); } catch (...) { } throw; } } else { SetDriverConfigurationFlag (TC_DRIVER_CONFIG_CACHE_BOOT_PASSWORD_FOR_SYS_FAVORITES, false); DeleteLocalMachineRegistryKey (L"SYSTEM\\CurrentControlSet\\Control\\SafeBoot\\Minimal", TC_SYSTEM_FAVORITES_SERVICE_NAME); DeleteLocalMachineRegistryKey (L"SYSTEM\\CurrentControlSet\\Control\\SafeBoot\\Network", TC_SYSTEM_FAVORITES_SERVICE_NAME); SC_HANDLE service = OpenService (scm, TC_SYSTEM_FAVORITES_SERVICE_NAME, SERVICE_ALL_ACCESS); throw_sys_if (!service); throw_sys_if (!DeleteService (service)); CloseServiceHandle (service); if (!noFileHandling) { DeleteFile (servicePath.c_str()); if (serviceLegacyPath != servicePath) DeleteFile (serviceLegacyPath.c_str()); } } } void BootEncryption::UpdateSystemFavoritesService () { SC_HANDLE scm = OpenSCManager (NULL, NULL, SC_MANAGER_ALL_ACCESS); throw_sys_if (!scm); finally_do_arg (SC_HANDLE, scm, { CloseServiceHandle (finally_arg); }); wstring servicePath = GetServiceConfigPath (_T(TC_APP_NAME) L".exe", false); // check if service exists SC_HANDLE service = OpenService (scm, TC_SYSTEM_FAVORITES_SERVICE_NAME, SERVICE_ALL_ACCESS); if (service) { finally_do_arg (SC_HANDLE, service, { CloseServiceHandle (finally_arg); }); // ensure that its parameters are correct throw_sys_if (!ChangeServiceConfig (service, SERVICE_WIN32_OWN_PROCESS, SERVICE_AUTO_START, SERVICE_ERROR_NORMAL, (wstring (L"\"") + servicePath + L"\" " TC_SYSTEM_FAVORITES_SERVICE_CMDLINE_OPTION).c_str(), TC_SYSTEM_FAVORITES_SERVICE_LOAD_ORDER_GROUP, NULL, NULL, NULL, NULL, _T(TC_APP_NAME) L" System Favorites")); } else { RegisterSystemFavoritesService (TRUE, TRUE); } } void BootEncryption::SetDriverConfigurationFlag (uint32 flag, bool state) { DWORD configMap = ReadDriverConfigurationFlags(); if (state) configMap |= flag; else configMap &= ~flag; #ifdef SETUP WriteLocalMachineRegistryDword (L"SYSTEM\\CurrentControlSet\\Services\\veracrypt", TC_DRIVER_CONFIG_REG_VALUE_NAME, configMap); #else WriteLocalMachineRegistryDwordValue (L"SYSTEM\\CurrentControlSet\\Services\\veracrypt", TC_DRIVER_CONFIG_REG_VALUE_NAME, configMap); #endif } #ifndef SETUP void BootEncryption::RegisterSystemFavoritesService (BOOL registerService) { if (!IsAdmin() && IsUacSupported()) { Elevator::RegisterSystemFavoritesService (registerService); return; } RegisterSystemFavoritesService (registerService, FALSE); } void BootEncryption::GetEfiBootDeviceNumber (PSTORAGE_DEVICE_NUMBER pSdn) { SystemDriveConfiguration config = GetSystemDriveConfiguration (); if (config.SystemPartition.IsGPT && pSdn) { if (!IsAdmin() && IsUacSupported()) { Elevator::GetEfiBootDeviceNumber (pSdn); } else { finally_do ({ EfiBootInst.DismountBootPartition(); }); EfiBootInst.MountBootPartition(0); memcpy (pSdn, EfiBootInst.GetStorageDeviceNumber(), sizeof (STORAGE_DEVICE_NUMBER)); } } else { SetLastError (ERROR_INVALID_PARAMETER); throw SystemException (SRC_POS); } } void BootEncryption::CheckRequirements () { if (nCurrentOS == WIN_2000) throw ErrorException ("SYS_ENCRYPTION_UNSUPPORTED_ON_CURRENT_OS", SRC_POS); if (CurrentOSMajor == 6 && CurrentOSMinor == 0 && CurrentOSServicePack < 1) throw ErrorException ("SYS_ENCRYPTION_UNSUPPORTED_ON_VISTA_SP0", SRC_POS); if (IsNonInstallMode()) throw ErrorException ("FEATURE_REQUIRES_INSTALLATION", SRC_POS); SystemDriveConfiguration config = GetSystemDriveConfiguration (); if (SystemDriveIsDynamic()) throw ErrorException ("SYSENC_UNSUPPORTED_FOR_DYNAMIC_DISK", SRC_POS); if (config.InitialUnallocatedSpace < TC_BOOT_LOADER_AREA_SIZE) throw ErrorException ("NO_SPACE_FOR_BOOT_LOADER", SRC_POS); DISK_GEOMETRY_EX geometry = GetDriveGeometry (config.DriveNumber); if (geometry.Geometry.BytesPerSector != TC_SECTOR_SIZE_BIOS) throw ErrorException ("SYSENC_UNSUPPORTED_SECTOR_SIZE_BIOS", SRC_POS); bool activePartitionFound = false; if (config.SystemPartition.IsGPT) { STORAGE_DEVICE_NUMBER sdn; GetEfiBootDeviceNumber (&sdn); activePartitionFound = (config.DriveNumber == (int) sdn.DeviceNumber); } else { // Determine whether there is an Active partition on the system drive foreach (const Partition &partition, config.Partitions) { if (partition.Info.BootIndicator) { activePartitionFound = true; break; } } } if ((!config.SystemLoaderPresent && !config.SystemPartition.IsGPT) || !activePartitionFound) { static bool confirmed = false; if (!confirmed && AskWarnNoYes ("WINDOWS_NOT_ON_BOOT_DRIVE_ERROR", ParentWindow) == IDNO) throw UserAbort (SRC_POS); confirmed = true; } } void BootEncryption::CheckRequirementsHiddenOS () { // It is assumed that CheckRequirements() had been called (so we don't check e.g. whether it's GPT). // The user may have modified/added/deleted partitions since the partition table was last scanned. InvalidateCachedSysDriveProperties (); GetPartitionForHiddenOS (); } void BootEncryption::InitialSecurityChecksForHiddenOS () { wchar_t windowsDrive = (wchar_t) towupper (GetWindowsDirectory()[0]); // Paging files bool pagingFilesOk = !IsPagingFileActive (TRUE); wchar_t pagingFileRegData[65536]; DWORD pagingFileRegDataSize = sizeof (pagingFileRegData); if (ReadLocalMachineRegistryMultiString (L"System\\CurrentControlSet\\Control\\Session Manager\\Memory Management", L"PagingFiles", pagingFileRegData, &pagingFileRegDataSize) && pagingFileRegDataSize > 8) { for (size_t i = 1; i < pagingFileRegDataSize/2 - 2; ++i) { if (wmemcmp (pagingFileRegData + i, L":\\", 2) == 0 && towupper (pagingFileRegData[i - 1]) != windowsDrive) { pagingFilesOk = false; break; } } } if (!pagingFilesOk) { if (AskWarnYesNoString ((wchar_t *) (wstring (GetString ("PAGING_FILE_NOT_ON_SYS_PARTITION")) + GetString ("LEAKS_OUTSIDE_SYSPART_UNIVERSAL_EXPLANATION") + L"\n\n\n" + GetString ("RESTRICT_PAGING_FILES_TO_SYS_PARTITION") ).c_str(), ParentWindow) == IDYES) { RestrictPagingFilesToSystemPartition(); RestartComputer(); AbortProcessSilent(); } throw ErrorException (wstring (GetString ("PAGING_FILE_NOT_ON_SYS_PARTITION")) + GetString ("LEAKS_OUTSIDE_SYSPART_UNIVERSAL_EXPLANATION"), SRC_POS); } // User profile wchar_t *configPath = GetConfigPath (L"dummy"); if (configPath && towupper (configPath[0]) != windowsDrive) { throw ErrorException (wstring (GetString ("USER_PROFILE_NOT_ON_SYS_PARTITION")) + GetString ("LEAKS_OUTSIDE_SYSPART_UNIVERSAL_EXPLANATION"), SRC_POS); } // Temporary files if (towupper (GetTempPathString()[0]) != windowsDrive) { throw ErrorException (wstring (GetString ("TEMP_NOT_ON_SYS_PARTITION")) + GetString ("LEAKS_OUTSIDE_SYSPART_UNIVERSAL_EXPLANATION"), SRC_POS); } } // This operation may take a long time when an antivirus is installed and its real-time protection enabled. // Therefore, if calling it without the wizard displayed, it should be called with displayWaitDialog set to true. void BootEncryption::Deinstall (bool displayWaitDialog) { BootEncryptionStatus encStatus = GetStatus(); if (encStatus.DriveEncrypted || encStatus.DriveMounted) throw ParameterIncorrect (SRC_POS); SystemDriveConfiguration config = GetSystemDriveConfiguration (); if (!config.SystemPartition.IsGPT) { if (encStatus.VolumeHeaderPresent) { // Verify CRC of header salt Device device(config.DevicePath, true); device.CheckOpened(SRC_POS); byte header[TC_BOOT_ENCRYPTION_VOLUME_HEADER_SIZE]; device.SeekAt(TC_BOOT_VOLUME_HEADER_SECTOR_OFFSET); device.Read(header, sizeof(header)); if (encStatus.VolumeHeaderSaltCrc32 != GetCrc32((byte *)header, PKCS5_SALT_SIZE)) throw ParameterIncorrect(SRC_POS); } } try { RegisterFilterDriver (false, DriveFilter); RegisterFilterDriver (false, VolumeFilter); RegisterFilterDriver (false, DumpFilter); SetDriverServiceStartType (SERVICE_SYSTEM_START); } catch (...) { try { RegisterBootDriver (IsHiddenSystemRunning()); } catch (...) { } throw; } SetHiddenOSCreationPhase (TC_HIDDEN_OS_CREATION_PHASE_NONE); // In case RestoreSystemLoader() fails try { RegisterSystemFavoritesService (false); } catch (...) { } try { if (displayWaitDialog) DisplayStaticModelessWaitDlg (ParentWindow); finally_do_arg (bool, displayWaitDialog, { if (finally_arg) CloseStaticModelessWaitDlg(); }); RestoreSystemLoader (); } catch (Exception &e) { e.Show (ParentWindow); throw ErrorException ("SYS_LOADER_RESTORE_FAILED", SRC_POS); } } int BootEncryption::ChangePassword (Password *oldPassword, int old_pkcs5, int old_pim, Password *newPassword, int pkcs5, int pim, int wipePassCount, HWND hwndDlg) { BootEncryptionStatus encStatus = GetStatus(); if (encStatus.SetupInProgress || (wipePassCount <= 0)) throw ParameterIncorrect (SRC_POS); SystemDriveConfiguration config = GetSystemDriveConfiguration (); char header[TC_BOOT_ENCRYPTION_VOLUME_HEADER_SIZE]; Device device (config.DevicePath); device.CheckOpened (SRC_POS); // Only one algorithm is currently supported if (pkcs5 != 0) throw ParameterIncorrect (SRC_POS); int64 headerOffset = TC_BOOT_VOLUME_HEADER_SECTOR_OFFSET; int64 backupHeaderOffset = -1; if (encStatus.HiddenSystem) { headerOffset = encStatus.HiddenSystemPartitionStart + TC_HIDDEN_VOLUME_HEADER_OFFSET; // Find hidden system partition foreach (const Partition &partition, config.Partitions) { if (partition.Info.StartingOffset.QuadPart == encStatus.HiddenSystemPartitionStart) { backupHeaderOffset = partition.Info.StartingOffset.QuadPart + partition.Info.PartitionLength.QuadPart - TC_VOLUME_HEADER_SIZE; break; } } if (backupHeaderOffset == -1) throw ParameterIncorrect (SRC_POS); } device.SeekAt (headerOffset); device.Read ((byte *) header, sizeof (header)); PCRYPTO_INFO cryptoInfo = NULL; int status = ReadVolumeHeader (!encStatus.HiddenSystem, header, oldPassword, old_pkcs5, old_pim, FALSE, &cryptoInfo, NULL); finally_do_arg (PCRYPTO_INFO, cryptoInfo, { if (finally_arg) crypto_close (finally_arg); }); if (status != 0) { handleError (hwndDlg, status, SRC_POS); return status; } // Change the PKCS-5 PRF if requested by user if (pkcs5 != 0) { cryptoInfo->pkcs5 = pkcs5; RandSetHashFunction (pkcs5); } if (Randinit() != 0) { if (CryptoAPILastError == ERROR_SUCCESS) throw RandInitFailed (SRC_POS, GetLastError ()); else throw CryptoApiFailed (SRC_POS, CryptoAPILastError); } finally_do ({ RandStop (FALSE); }); /* force the display of the random enriching dialog */ SetRandomPoolEnrichedByUserStatus (FALSE); NormalCursor(); UserEnrichRandomPool (hwndDlg); WaitCursor(); /* The header will be re-encrypted wipePassCount times to prevent adversaries from using techniques such as magnetic force microscopy or magnetic force scanning tunnelling microscopy to recover the overwritten header. According to Peter Gutmann, data should be overwritten 22 times (ideally, 35 times) using non-random patterns and pseudorandom data. However, as users might impatiently interupt the process (etc.) we will not use the Gutmann's patterns but will write the valid re-encrypted header, i.e. pseudorandom data, and there will be many more passes than Guttman recommends. During each pass we will write a valid working header. Each pass will use the same master key, and also the same header key, secondary key (XTS), etc., derived from the new password. The only item that will be different for each pass will be the salt. This is sufficient to cause each "version" of the header to differ substantially and in a random manner from the versions written during the other passes. */ bool headerUpdated = false; int result = ERR_SUCCESS; try { BOOL backupHeader = FALSE; while (TRUE) { for (int wipePass = 0; wipePass < wipePassCount; wipePass++) { PCRYPTO_INFO tmpCryptoInfo = NULL; status = CreateVolumeHeaderInMemory (hwndDlg, !encStatus.HiddenSystem, header, cryptoInfo->ea, cryptoInfo->mode, newPassword, cryptoInfo->pkcs5, pim, (char *) cryptoInfo->master_keydata, &tmpCryptoInfo, cryptoInfo->VolumeSize.Value, cryptoInfo->hiddenVolumeSize, cryptoInfo->EncryptedAreaStart.Value, cryptoInfo->EncryptedAreaLength.Value, cryptoInfo->RequiredProgramVersion, cryptoInfo->HeaderFlags | TC_HEADER_FLAG_ENCRYPTED_SYSTEM, cryptoInfo->SectorSize, wipePass < wipePassCount - 1); if (tmpCryptoInfo) crypto_close (tmpCryptoInfo); if (status != 0) { handleError (hwndDlg, status, SRC_POS); return status; } device.SeekAt (headerOffset); device.Write ((byte *) header, sizeof (header)); headerUpdated = true; } if (!encStatus.HiddenSystem || backupHeader) break; backupHeader = TRUE; headerOffset = backupHeaderOffset; } } catch (Exception &e) { e.Show (hwndDlg); result = ERR_OS_ERROR; } if (headerUpdated) { bool storedPimUpdateNeeded = false; ReopenBootVolumeHeaderRequest reopenRequest; reopenRequest.VolumePassword = *newPassword; reopenRequest.pkcs5_prf = cryptoInfo->pkcs5; reopenRequest.pim = pim; finally_do_arg (ReopenBootVolumeHeaderRequest*, &reopenRequest, { burn (finally_arg, sizeof (*finally_arg)); }); if (old_pim != pim) { try { // check if PIM is stored in MBR byte userConfig = 0; if ( ReadBootSectorConfig (nullptr, 0, &userConfig) && (userConfig & TC_BOOT_USER_CFG_FLAG_DISABLE_PIM) ) { storedPimUpdateNeeded = true; } } catch (...) { } } try { // force update of bootloader if fingerprint doesn't match or if the stored PIM changed if (storedPimUpdateNeeded || !CheckBootloaderFingerprint (true)) InstallBootLoader (device, true, false, pim, cryptoInfo->pkcs5); } catch (...) {} CallDriver (TC_IOCTL_REOPEN_BOOT_VOLUME_HEADER, &reopenRequest, sizeof (reopenRequest)); } return result; } void BootEncryption::CheckEncryptionSetupResult () { CallDriver (TC_IOCTL_GET_BOOT_ENCRYPTION_SETUP_RESULT); } void BootEncryption::Install (bool hiddenSystem, int hashAlgo) { BootEncryptionStatus encStatus = GetStatus(); if (encStatus.DriveMounted) throw ParameterIncorrect (SRC_POS); try { InstallBootLoader (false, hiddenSystem, -1, hashAlgo); if (!hiddenSystem) InstallVolumeHeader (); RegisterBootDriver (hiddenSystem); } catch (Exception &) { try { RestoreSystemLoader (); } catch (Exception &e) { e.Show (ParentWindow); } throw; } } void BootEncryption::PrepareHiddenOSCreation (int ea, int mode, int pkcs5) { BootEncryptionStatus encStatus = GetStatus(); if (encStatus.DriveMounted) throw ParameterIncorrect (SRC_POS); CheckRequirements(); BackupSystemLoader(); SelectedEncryptionAlgorithmId = ea; SelectedPrfAlgorithmId = pkcs5; } void BootEncryption::PrepareInstallation (bool systemPartitionOnly, Password &password, int ea, int mode, int pkcs5, int pim, const wstring &rescueIsoImagePath) { BootEncryptionStatus encStatus = GetStatus(); if (encStatus.DriveMounted) throw ParameterIncorrect (SRC_POS); CheckRequirements (); SystemDriveConfiguration config = GetSystemDriveConfiguration(); // Some chipset drivers may prevent access to the last sector of the drive if (!systemPartitionOnly) { DISK_GEOMETRY_EX geometry = GetDriveGeometry (config.DriveNumber); if ((geometry.Geometry.BytesPerSector > 0) && (geometry.Geometry.BytesPerSector < TC_MAX_VOLUME_SECTOR_SIZE)) { Buffer sector (geometry.Geometry.BytesPerSector); Device device (config.DevicePath); device.CheckOpened (SRC_POS); try { device.SeekAt (config.DrivePartition.Info.PartitionLength.QuadPart - geometry.Geometry.BytesPerSector); device.Read (sector.Ptr(), (DWORD) sector.Size()); } catch (SystemException &e) { if (e.ErrorCode != ERROR_CRC) { e.Show (ParentWindow); Error ("WHOLE_DRIVE_ENCRYPTION_PREVENTED_BY_DRIVERS", ParentWindow); throw UserAbort (SRC_POS); } } } } BackupSystemLoader (); uint64 volumeSize; uint64 encryptedAreaStart; if (systemPartitionOnly) { volumeSize = config.SystemPartition.Info.PartitionLength.QuadPart; encryptedAreaStart = config.SystemPartition.Info.StartingOffset.QuadPart; } else { volumeSize = config.DrivePartition.Info.PartitionLength.QuadPart - TC_BOOT_LOADER_AREA_SIZE; encryptedAreaStart = config.DrivePartition.Info.StartingOffset.QuadPart + TC_BOOT_LOADER_AREA_SIZE; } SelectedEncryptionAlgorithmId = ea; SelectedPrfAlgorithmId = pkcs5; CreateVolumeHeader (volumeSize, encryptedAreaStart, &password, ea, mode, pkcs5, pim); if (!rescueIsoImagePath.empty()) CreateRescueIsoImage (true, rescueIsoImagePath); } bool BootEncryption::IsPagingFileActive (BOOL checkNonWindowsPartitionsOnly) { if (!IsAdmin() && IsUacSupported()) return Elevator::IsPagingFileActive (checkNonWindowsPartitionsOnly) ? true : false; return ::IsPagingFileActive (checkNonWindowsPartitionsOnly) ? true : false; } void BootEncryption::RestrictPagingFilesToSystemPartition () { wchar_t pagingFiles[128] = {0}; StringCchCopyW (pagingFiles, ARRAYSIZE(pagingFiles), L"X:\\pagefile.sys 0 0"); pagingFiles[0] = GetWindowsDirectory()[0]; throw_sys_if (!WriteLocalMachineRegistryMultiString (L"System\\CurrentControlSet\\Control\\Session Manager\\Memory Management", L"PagingFiles", pagingFiles, (DWORD) (wcslen (pagingFiles) + 2) * sizeof (wchar_t))); } void BootEncryption::WriteLocalMachineRegistryDwordValue (wchar_t *keyPath, wchar_t *valueName, DWORD value) { if (!IsAdmin() && IsUacSupported()) { Elevator::WriteLocalMachineRegistryDwordValue (keyPath, valueName, value); return; } throw_sys_if (!WriteLocalMachineRegistryDword (keyPath, valueName, value)); } void BootEncryption::StartDecryption (BOOL discardUnreadableEncryptedSectors) { BootEncryptionStatus encStatus = GetStatus(); if (!encStatus.DeviceFilterActive || !encStatus.DriveMounted || encStatus.SetupInProgress) throw ParameterIncorrect (SRC_POS); BootEncryptionSetupRequest request; ZeroMemory (&request, sizeof (request)); request.SetupMode = SetupDecryption; request.DiscardUnreadableEncryptedSectors = discardUnreadableEncryptedSectors; CallDriver (TC_IOCTL_BOOT_ENCRYPTION_SETUP, &request, sizeof (request), NULL, 0); } void BootEncryption::StartEncryption (WipeAlgorithmId wipeAlgorithm, bool zeroUnreadableSectors) { BootEncryptionStatus encStatus = GetStatus(); if (!encStatus.DeviceFilterActive || !encStatus.DriveMounted || encStatus.SetupInProgress) throw ParameterIncorrect (SRC_POS); BootEncryptionSetupRequest request; ZeroMemory (&request, sizeof (request)); request.SetupMode = SetupEncryption; request.WipeAlgorithm = wipeAlgorithm; request.ZeroUnreadableSectors = zeroUnreadableSectors; CallDriver (TC_IOCTL_BOOT_ENCRYPTION_SETUP, &request, sizeof (request), NULL, 0); } void BootEncryption::CopyFileAdmin (const wstring &sourceFile, const wstring &destinationFile) { if (!IsAdmin()) { if (!IsUacSupported()) { SetLastError (ERROR_ACCESS_DENIED); throw SystemException(SRC_POS); } else Elevator::CopyFile (sourceFile, destinationFile); } else throw_sys_if (!::CopyFile (sourceFile.c_str(), destinationFile.c_str(), FALSE)); } void BootEncryption::DeleteFileAdmin (const wstring &file) { if (!IsAdmin() && IsUacSupported()) Elevator::DeleteFile (file); else throw_sys_if (!::DeleteFile (file.c_str())); } #endif // !SETUP uint32 BootEncryption::ReadDriverConfigurationFlags () { DWORD configMap; if (!ReadLocalMachineRegistryDword (L"SYSTEM\\CurrentControlSet\\Services\\veracrypt", TC_DRIVER_CONFIG_REG_VALUE_NAME, &configMap)) configMap = 0; return configMap; } void BootEncryption::WriteBootDriveSector (uint64 offset, byte *data) { WriteBootDriveSectorRequest request; request.Offset.QuadPart = offset; memcpy (request.Data, data, sizeof (request.Data)); CallDriver (TC_IOCTL_WRITE_BOOT_DRIVE_SECTOR, &request, sizeof (request), NULL, 0); } void BootEncryption::RegisterBootDriver (bool hiddenSystem) { SetDriverServiceStartType (SERVICE_BOOT_START); try { RegisterFilterDriver (false, DriveFilter); RegisterFilterDriver (false, VolumeFilter); RegisterFilterDriver (false, DumpFilter); } catch (...) { } try { RegisterFilterDriver (true, DriveFilter); if (hiddenSystem) RegisterFilterDriver (true, VolumeFilter); RegisterFilterDriver (true, DumpFilter); } catch (...) { try { RegisterFilterDriver (false, DriveFilter); } catch (...) { } try { RegisterFilterDriver (false, VolumeFilter); } catch (...) { } try { RegisterFilterDriver (false, DumpFilter); } catch (...) { } try { SetDriverServiceStartType (SERVICE_SYSTEM_START); } catch (...) { } throw; } } bool BootEncryption::RestartComputer (BOOL bShutdown) { return (::RestartComputer(bShutdown) != FALSE); } }