/* nvramparser.cpp Copyright (c) 2016, Nikolaj Schlej. All rights reserved. This program and the accompanying materials are licensed and made available under the terms and conditions of the BSD License which accompanies this distribution. The full text of the license may be found at http://opensource.org/licenses/bsd-license.php. THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. */ //TODO: relax fixed restrictions once NVRAM builder is ready // A workaround for compilers not supporting c++11 and c11 // for using PRIX64. #define __STDC_FORMAT_MACROS #include #include #include "nvramparser.h" #include "parsingdata.h" #include "utility.h" #include "nvram.h" #include "ffs.h" #include "fit.h" #ifdef U_ENABLE_NVRAM_PARSING_SUPPORT USTATUS NvramParser::parseNvarStore(const UModelIndex & index) { // Sanity check if (!index.isValid()) return U_INVALID_PARAMETER; // Obtain required information from parent file UINT8 emptyByte = 0xFF; UModelIndex parentFileIndex = model->findParentOfType(index, Types::File); if (parentFileIndex.isValid() && model->hasEmptyParsingData(parentFileIndex) == false) { UByteArray data = model->parsingData(parentFileIndex); const FILE_PARSING_DATA* pdata = (const FILE_PARSING_DATA*)data.constData(); emptyByte = readUnaligned(pdata).emptyByte; } // Get local offset UINT32 localOffset = model->header(index).size(); // Get item data const UByteArray data = model->body(index); // Parse all entries UINT32 offset = 0; UINT32 guidsInStore = 0; while (1) { bool msgUnknownExtDataFormat = false; bool msgExtHeaderTooLong = false; bool msgExtDataTooShort = false; bool isInvalid = false; bool isInvalidLink = false; bool hasExtendedHeader = false; bool hasChecksum = false; bool hasTimestamp = false; bool hasHash = false; bool hasGuidIndex = false; UINT32 guidIndex = 0; UINT8 storedChecksum = 0; UINT8 calculatedChecksum = 0; UINT32 extendedHeaderSize = 0; UINT8 extendedAttributes = 0; UINT64 timestamp = 0; UByteArray hash; UINT8 subtype = Subtypes::FullNvarEntry; UString name; UString guid; UString text; UByteArray header; UByteArray body; UByteArray tail; UINT32 guidAreaSize = guidsInStore * sizeof(EFI_GUID); UINT32 unparsedSize = (UINT32)data.size() - offset - guidAreaSize; // Get entry header const NVAR_ENTRY_HEADER* entryHeader = (const NVAR_ENTRY_HEADER*)(data.constData() + offset); // Check header size and signature if (unparsedSize < sizeof(NVAR_ENTRY_HEADER) || entryHeader->Signature != NVRAM_NVAR_ENTRY_SIGNATURE || unparsedSize < entryHeader->Size) { // Check if the data left is a free space or a padding UByteArray padding = data.mid(offset, unparsedSize); // Get info UString info = usprintf("Full size: %Xh (%u)", padding.size(), padding.size()); if ((UINT32)padding.count(emptyByte) == unparsedSize) { // Free space // Add tree item model->addItem(localOffset + offset, Types::FreeSpace, 0, UString("Free space"), UString(), info, UByteArray(), padding, UByteArray(), Fixed, index); } else { // Nothing is parsed yet, but the file is not empty if (!offset) { msg(usprintf("%s: file can't be parsed as NVAR variables store", __FUNCTION__), index); return U_SUCCESS; } // Add tree item model->addItem(localOffset + offset, Types::Padding, getPaddingType(padding), UString("Padding"), UString(), info, UByteArray(), padding, UByteArray(), Fixed, index); } // Add GUID store area UByteArray guidArea = data.right(guidAreaSize); // Get info name = UString("GUID store"); info = usprintf("Full size: %Xh (%u)\nGUIDs in store: %u", guidArea.size(), guidArea.size(), guidsInStore); // Add tree item model->addItem(localOffset + offset + padding.size(), Types::Padding, getPaddingType(guidArea), name, UString(), info, UByteArray(), guidArea, UByteArray(), Fixed, index); return U_SUCCESS; } // Contruct generic header and body header = data.mid(offset, sizeof(NVAR_ENTRY_HEADER)); body = data.mid(offset + sizeof(NVAR_ENTRY_HEADER), entryHeader->Size - sizeof(NVAR_ENTRY_HEADER)); UINT32 lastVariableFlag = emptyByte ? 0xFFFFFF : 0; // Set default next to predefined last value NVAR_ENTRY_PARSING_DATA pdata; pdata.emptyByte = emptyByte; pdata.next = lastVariableFlag; // Entry is marked as invalid if ((entryHeader->Attributes & NVRAM_NVAR_ENTRY_VALID) == 0) { // Valid attribute is not set isInvalid = true; // Do not parse further goto parsing_done; } // Add next node information to parsing data if (entryHeader->Next != lastVariableFlag) { subtype = Subtypes::LinkNvarEntry; pdata.next = entryHeader->Next; } // Entry with extended header if (entryHeader->Attributes & NVRAM_NVAR_ENTRY_EXT_HEADER) { hasExtendedHeader = true; msgUnknownExtDataFormat = true; extendedHeaderSize = readUnaligned((UINT16*)(body.constData() + body.size() - sizeof(UINT16))); if (extendedHeaderSize > (UINT32)body.size()) { msgExtHeaderTooLong = true; isInvalid = true; // Do not parse further goto parsing_done; } extendedAttributes = *(UINT8*)(body.constData() + body.size() - extendedHeaderSize); // Variable with checksum if (extendedAttributes & NVRAM_NVAR_ENTRY_EXT_CHECKSUM) { // Get stored checksum storedChecksum = *(UINT8*)(body.constData() + body.size() - sizeof(UINT16) - sizeof(UINT8)); // Recalculate checksum for the variable calculatedChecksum = 0; // Include entry data UINT8* start = (UINT8*)(entryHeader + 1); for (UINT8* p = start; p < start + entryHeader->Size - sizeof(NVAR_ENTRY_HEADER); p++) { calculatedChecksum += *p; } // Include entry size and flags start = (UINT8*)&entryHeader->Size; for (UINT8*p = start; p < start + sizeof(UINT16); p++) { calculatedChecksum += *p; } // Include entry attributes calculatedChecksum += entryHeader->Attributes; hasChecksum = true; msgUnknownExtDataFormat = false; } tail = body.mid(body.size() - extendedHeaderSize); body = body.left(body.size() - extendedHeaderSize); // Entry with authenticated write (for SecureBoot) if (entryHeader->Attributes & NVRAM_NVAR_ENTRY_AUTH_WRITE) { if ((entryHeader->Attributes & NVRAM_NVAR_ENTRY_DATA_ONLY)) {// Data only auth. variables has no hash if ((UINT32)tail.size() < sizeof(UINT64)) { msgExtDataTooShort = true; isInvalid = true; // Do not parse further goto parsing_done; } timestamp = readUnaligned(tail.constData() + sizeof(UINT8)); hasTimestamp = true; msgUnknownExtDataFormat = false; } else { // Full or link variable have hash if ((UINT32)tail.size() < sizeof(UINT64) + SHA256_HASH_SIZE) { msgExtDataTooShort = true; isInvalid = true; // Do not parse further goto parsing_done; } timestamp = readUnaligned((UINT64*)(tail.constData() + sizeof(UINT8))); hash = tail.mid(sizeof(UINT64) + sizeof(UINT8), SHA256_HASH_SIZE); hasTimestamp = true; hasHash = true; msgUnknownExtDataFormat = false; } } } // Entry is data-only (nameless and GUIDless entry or link) if (entryHeader->Attributes & NVRAM_NVAR_ENTRY_DATA_ONLY) { // Data-only attribute is set isInvalidLink = true; UModelIndex nvarIndex; // Search previously added entries for a link to this variable // WARNING: O(n^2), may be very slow for (int i = model->rowCount(index) - 1; i >= 0; i--) { nvarIndex = index.child(i, 0); if (model->hasEmptyParsingData(nvarIndex) == false) { UByteArray nvarData = model->parsingData(nvarIndex); const NVAR_ENTRY_PARSING_DATA* nvarPdata = (const NVAR_ENTRY_PARSING_DATA*)nvarData.constData(); if (nvarPdata->isValid && nvarPdata->next + model->offset(nvarIndex) - localOffset == offset) { // Previous link is present and valid isInvalidLink = false; break; } } } // Check if the link is valid if (!isInvalidLink) { // Use the name and text of the previous link name = model->name(nvarIndex); text = model->text(nvarIndex); if (entryHeader->Next == lastVariableFlag) subtype = Subtypes::DataNvarEntry; } // Do not parse further goto parsing_done; } // Get entry name { UINT32 nameOffset = (entryHeader->Attributes & NVRAM_NVAR_ENTRY_GUID) ? sizeof(EFI_GUID) : sizeof(UINT8); // GUID can be stored with the variable or in a separate store, so there will only be an index of it CHAR8* namePtr = (CHAR8*)(entryHeader + 1) + nameOffset; UINT32 nameSize = 0; if (entryHeader->Attributes & NVRAM_NVAR_ENTRY_ASCII_NAME) { // Name is stored as ASCII string of CHAR8s text = UString(namePtr); nameSize = text.length() + 1; } else { // Name is stored as UCS2 string of CHAR16s text = UString::fromUtf16((CHAR16*)namePtr); nameSize = (text.length() + 1) * 2; } // Get entry GUID if (entryHeader->Attributes & NVRAM_NVAR_ENTRY_GUID) { // GUID is strored in the variable itself name = guidToUString(readUnaligned((EFI_GUID*)(entryHeader + 1))); guid = guidToUString(readUnaligned((EFI_GUID*)(entryHeader + 1)), false); } // GUID is stored in GUID list at the end of the store else { guidIndex = *(UINT8*)(entryHeader + 1); if (guidsInStore < guidIndex + 1) guidsInStore = guidIndex + 1; // The list begins at the end of the store and goes backwards const EFI_GUID* guidPtr = (const EFI_GUID*)(data.constData() + data.size()) - 1 - guidIndex; name = guidToUString(readUnaligned(guidPtr)); guid = guidToUString(readUnaligned(guidPtr), false); hasGuidIndex = true; } // Include name and GUID into the header and remove them from body header = data.mid(offset, sizeof(NVAR_ENTRY_HEADER) + nameOffset + nameSize); body = body.mid(nameOffset + nameSize); } parsing_done: UString info; // Rename invalid entries according to their types pdata.isValid = TRUE; if (isInvalid) { name = UString("Invalid"); subtype = Subtypes::InvalidNvarEntry; pdata.isValid = FALSE; } else if (isInvalidLink) { name = UString("Invalid link"); subtype = Subtypes::InvalidLinkNvarEntry; pdata.isValid = FALSE; } else // Add GUID info for valid entries info += UString("Variable GUID: ") + guid + UString("\n"); // Add GUID index information if (hasGuidIndex) info += usprintf("GUID index: %u\n", guidIndex); // Add header, body and extended data info info += usprintf("Full size: %Xh (%u)\nHeader size: %Xh (%u)\nBody size: %Xh (%u)", entryHeader->Size, entryHeader->Size, header.size(), header.size(), body.size(), body.size()); // Add attributes info info += usprintf("\nAttributes: %02Xh", entryHeader->Attributes); // Translate attributes to text if (entryHeader->Attributes && entryHeader->Attributes != 0xFF) info += UString(" (") + nvarAttributesToUString(entryHeader->Attributes) + UString(")"); // Add next node info if (!isInvalid && entryHeader->Next != lastVariableFlag) info += usprintf("\nNext node at offset: %Xh", localOffset + offset + entryHeader->Next); // Add extended header info if (hasExtendedHeader) { info += usprintf("\nExtended header size: %Xh (%u)\nExtended attributes: %Xh (", extendedHeaderSize, extendedHeaderSize, extendedAttributes) + nvarExtendedAttributesToUString(extendedAttributes) + UString(")"); // Add checksum if (hasChecksum) info += usprintf("\nChecksum: %02Xh", storedChecksum) + (calculatedChecksum ? usprintf(", invalid, should be %02Xh", 0x100 - calculatedChecksum) : UString(", valid")); // Add timestamp if (hasTimestamp) info += usprintf("\nTimestamp: %" PRIX64 "h", timestamp); // Add hash if (hasHash) info += UString("\nHash: ") + UString(hash.toHex().constData()); } // Add tree item UModelIndex varIndex = model->addItem(localOffset + offset, Types::NvarEntry, subtype, name, text, info, header, body, tail, Fixed, index); // Set parsing data for created entry model->setParsingData(varIndex, UByteArray((const char*)&pdata, sizeof(pdata))); // Show messages if (msgUnknownExtDataFormat) msg(usprintf("%s: unknown extended data format", __FUNCTION__), varIndex); if (msgExtHeaderTooLong) msg(usprintf("%s: extended header size (%Xh) is greater than body size (%Xh)", __FUNCTION__, extendedHeaderSize, body.size()), varIndex); if (msgExtDataTooShort) msg(usprintf("%s: extended header size (%Xh) is too small for timestamp and hash", __FUNCTION__, tail.size()), varIndex); // Try parsing the entry data as NVAR storage if it begins with NVAR signature if ((subtype == Subtypes::DataNvarEntry || subtype == Subtypes::FullNvarEntry) && body.size() >= 4 && readUnaligned((const UINT32*)body.constData()) == NVRAM_NVAR_ENTRY_SIGNATURE) parseNvarStore(varIndex); // Move to next exntry offset += entryHeader->Size; } return U_SUCCESS; } USTATUS NvramParser::parseNvramVolumeBody(const UModelIndex & index) { // Sanity check if (!index.isValid()) return U_INVALID_PARAMETER; // Obtain required fields from parsing data UINT8 emptyByte = 0xFF; if (model->hasEmptyParsingData(index) == false) { UByteArray data = model->parsingData(index); const VOLUME_PARSING_DATA* pdata = (const VOLUME_PARSING_DATA*)data.constData(); emptyByte = pdata->emptyByte; } // Get local offset UINT32 localOffset = model->header(index).size(); // Get item data UByteArray data = model->body(index); // Search for first store USTATUS result; UINT32 prevStoreOffset; result = findNextStore(index, data, localOffset, 0, prevStoreOffset); if (result) return result; // First store is not at the beginning of volume body UString name; UString info; if (prevStoreOffset > 0) { // Get info UByteArray padding = data.left(prevStoreOffset); name = UString("Padding"); info = usprintf("Full size: %Xh (%u)", padding.size(), padding.size()); // Add tree item model->addItem(localOffset, Types::Padding, getPaddingType(padding), name, UString(), info, UByteArray(), padding, UByteArray(), Fixed, index); } // Search for and parse all stores UINT32 storeOffset = prevStoreOffset; UINT32 prevStoreSize = 0; while (!result) { // Padding between stores if (storeOffset > prevStoreOffset + prevStoreSize) { UINT32 paddingOffset = prevStoreOffset + prevStoreSize; UINT32 paddingSize = storeOffset - paddingOffset; UByteArray padding = data.mid(paddingOffset, paddingSize); // Get info name = UString("Padding"); info = usprintf("Full size: %Xh (%u)", padding.size(), padding.size()); // Add tree item model->addItem(localOffset + paddingOffset, Types::Padding, getPaddingType(padding), name, UString(), info, UByteArray(), padding, UByteArray(), Fixed, index); } // Get store size UINT32 storeSize = 0; result = getStoreSize(data, storeOffset, storeSize); if (result) { msg(usprintf("%s: getStoreSize failed with error ", __FUNCTION__) + errorCodeToUString(result), index); return result; } // Check that current store is fully present in input if (storeSize > (UINT32)data.size() || storeOffset + storeSize > (UINT32)data.size()) { // Mark the rest as padding and finish parsing UByteArray padding = data.mid(storeOffset); // Get info name = UString("Padding"); info = usprintf("Full size: %Xh (%u)", padding.size(), padding.size()); // Add tree item UModelIndex paddingIndex = model->addItem(localOffset + storeOffset, Types::Padding, getPaddingType(padding), name, UString(), info, UByteArray(), padding, UByteArray(), Fixed, index); msg(usprintf("%s: one of stores inside overlaps the end of data", __FUNCTION__), paddingIndex); // Update variables prevStoreOffset = storeOffset; prevStoreSize = padding.size(); break; } // Parse current store header UModelIndex storeIndex; UByteArray store = data.mid(storeOffset, storeSize); result = parseStoreHeader(store, localOffset + storeOffset, index, storeIndex); if (result) msg(usprintf("%s: store header parsing failed with error ", __FUNCTION__) + errorCodeToUString(result), index); // Go to next store prevStoreOffset = storeOffset; prevStoreSize = storeSize; result = findNextStore(index, data, localOffset, storeOffset + prevStoreSize, storeOffset); } // Padding/free space at the end storeOffset = prevStoreOffset + prevStoreSize; if ((UINT32)data.size() > storeOffset) { UByteArray padding = data.mid(storeOffset); // Add info info = usprintf("Full size: %Xh (%u)", padding.size(), padding.size()); if (padding.count(emptyByte) == padding.size()) { // Free space // Add tree item model->addItem(localOffset + storeOffset, Types::FreeSpace, 0, UString("Free space"), UString(), info, UByteArray(), padding, UByteArray(), Fixed, index); } else { // Nothing is parsed yet, but the file is not empty if (!storeOffset) { msg(usprintf("%s: can't be parsed as NVRAM volume", __FUNCTION__), index); return U_SUCCESS; } // Add tree item model->addItem(localOffset + storeOffset, Types::Padding, getPaddingType(padding), UString("Padding"), UString(), info, UByteArray(), padding, UByteArray(), Fixed, index); } } // Parse bodies for (int i = 0; i < model->rowCount(index); i++) { UModelIndex current = index.child(i, 0); switch (model->type(current)) { case Types::FdcStore: parseFdcStoreBody(current); break; case Types::VssStore: parseVssStoreBody(current, 0); break; case Types::Vss2Store: parseVssStoreBody(current, 4); break; case Types::FsysStore: parseFsysStoreBody(current); break; case Types::EvsaStore: parseEvsaStoreBody(current); break; case Types::FlashMapStore: parseFlashMapBody(current); break; default: // Ignore unknown! break; } } return U_SUCCESS; } USTATUS NvramParser::findNextStore(const UModelIndex & index, const UByteArray & volume, const UINT32 localOffset, const UINT32 storeOffset, UINT32 & nextStoreOffset) { UINT32 dataSize = volume.size(); if (dataSize < sizeof(UINT32)) return U_STORES_NOT_FOUND; UINT32 offset = storeOffset; for (; offset < dataSize - sizeof(UINT32); offset++) { const UINT32* currentPos = (const UINT32*)(volume.constData() + offset); if (*currentPos == NVRAM_VSS_STORE_SIGNATURE || *currentPos == NVRAM_APPLE_SVS_STORE_SIGNATURE) { // $VSS or $SVS signatures found, perform checks const VSS_VARIABLE_STORE_HEADER* vssHeader = (const VSS_VARIABLE_STORE_HEADER*)currentPos; if (vssHeader->Format != NVRAM_VSS_VARIABLE_STORE_FORMATTED) { msg(usprintf("%s: VSS store candidate at offset %Xh skipped, has invalid format %02Xh", __FUNCTION__, localOffset + offset, vssHeader->Format), index); continue; } if (vssHeader->Size == 0 || vssHeader->Size == 0xFFFFFFFF) { msg(usprintf("%s: VSS store candidate at offset %Xh skipped, has invalid size %Xh", __FUNCTION__, localOffset + offset, vssHeader->Size), index); continue; } // All checks passed, store found break; } else if (*currentPos == NVRAM_VSS2_AUTH_VAR_KEY_DATABASE_GUID_PART1 || *currentPos == NVRAM_VSS2_STORE_GUID_PART1) { // VSS2 store signatures found, perform checks UByteArray guid = UByteArray(volume.constData() + offset, sizeof(EFI_GUID)); if (guid != NVRAM_VSS2_AUTH_VAR_KEY_DATABASE_GUID && guid != NVRAM_VSS2_STORE_GUID) // Check the whole signature continue; const VSS2_VARIABLE_STORE_HEADER* vssHeader = (const VSS2_VARIABLE_STORE_HEADER*)currentPos; if (vssHeader->Format != NVRAM_VSS_VARIABLE_STORE_FORMATTED) { msg(usprintf("%s: VSS2 store candidate at offset %Xh skipped, has invalid format %02Xh", __FUNCTION__, localOffset + offset, vssHeader->Format), index); continue; } if (vssHeader->Size == 0 || vssHeader->Size == 0xFFFFFFFF) { msg(usprintf("%s: VSS2 store candidate at offset %Xh skipped, has invalid size %Xh", __FUNCTION__, localOffset + offset, vssHeader->Size), index); continue; } // All checks passed, store found break; } else if (*currentPos == NVRAM_FDC_VOLUME_SIGNATURE) { // FDC signature found const FDC_VOLUME_HEADER* fdcHeader = (const FDC_VOLUME_HEADER*)currentPos; if (fdcHeader->Size == 0 || fdcHeader->Size == 0xFFFFFFFF) { msg(usprintf("%s: FDC store candidate at offset %Xh skipped, has invalid size %Xh", __FUNCTION__, localOffset + offset, fdcHeader->Size), index); continue; } // All checks passed, store found break; } else if (*currentPos == NVRAM_APPLE_FSYS_STORE_SIGNATURE || *currentPos == NVRAM_APPLE_GAID_STORE_SIGNATURE) { // Fsys or Gaid signature found const APPLE_FSYS_STORE_HEADER* fsysHeader = (const APPLE_FSYS_STORE_HEADER*)currentPos; if (fsysHeader->Size == 0 || fsysHeader->Size == 0xFFFF) { msg(usprintf("%s: Fsys store candidate at offset %Xh skipped, has invalid size %Xh", __FUNCTION__, localOffset + offset, fsysHeader->Size), index); continue; } // All checks passed, store found break; } else if (*currentPos == NVRAM_EVSA_STORE_SIGNATURE) { //EVSA signature found if (offset < sizeof(UINT32)) continue; const EVSA_STORE_ENTRY* evsaHeader = (const EVSA_STORE_ENTRY*)(currentPos - 1); if (evsaHeader->Header.Type != NVRAM_EVSA_ENTRY_TYPE_STORE) { msg(usprintf("%s: EVSA store candidate at offset %Xh skipped, has invalid type %02Xh", __FUNCTION__, localOffset + offset - 4, evsaHeader->Header.Type), index); continue; } if (evsaHeader->StoreSize == 0 || evsaHeader->StoreSize == 0xFFFFFFFF) { msg(usprintf("%s: EVSA store candidate at offset %Xh skipped, has invalid size %Xh", __FUNCTION__, localOffset + offset, evsaHeader->StoreSize), index); continue; } // All checks passed, store found offset -= sizeof(UINT32); break; } else if (*currentPos == NVRAM_MAIN_STORE_VOLUME_GUID_DATA1 || *currentPos == EDKII_WORKING_BLOCK_SIGNATURE_GUID_DATA1) { // Possible FTW block signature found UByteArray guid = UByteArray(volume.constData() + offset, sizeof(EFI_GUID)); if (guid != NVRAM_MAIN_STORE_VOLUME_GUID && guid != EDKII_WORKING_BLOCK_SIGNATURE_GUID && guid != VSS2_WORKING_BLOCK_SIGNATURE_GUID) // Check the whole signature continue; // Detect header variant based on WriteQueueSize const EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER32* ftwHeader = (const EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER32*)currentPos; if (ftwHeader->WriteQueueSize % 0x10 == 0x04) { // Header with 32 bit WriteQueueSize if (ftwHeader->WriteQueueSize == 0 || ftwHeader->WriteQueueSize == 0xFFFFFFFF) { msg(usprintf("%s: FTW block candidate at offset %Xh skipped, has invalid body size %Xh", __FUNCTION__, localOffset + offset, ftwHeader->WriteQueueSize), index); continue; } } else if (ftwHeader->WriteQueueSize % 0x10 == 0x00) { // Header with 64 bit WriteQueueSize const EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER64* ftw64Header = (const EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER64*)currentPos; if (ftw64Header->WriteQueueSize == 0 || ftw64Header->WriteQueueSize >= 0xFFFFFFFF) { msg(usprintf("%s: FTW block candidate at offset %Xh skipped, has invalid body size %Xh", __FUNCTION__, localOffset + offset, ftw64Header->WriteQueueSize), index); continue; } } else // Unknown header continue; // All checks passed, store found break; } else if (*currentPos == NVRAM_PHOENIX_FLASH_MAP_SIGNATURE_PART1) {// Phoenix SCT flash map UByteArray signature = UByteArray(volume.constData() + offset, NVRAM_PHOENIX_FLASH_MAP_SIGNATURE_LENGTH); if (signature != NVRAM_PHOENIX_FLASH_MAP_SIGNATURE) // Check the whole signature continue; // All checks passed, store found break; } else if (*currentPos == NVRAM_PHOENIX_CMDB_HEADER_SIGNATURE) { // Phoenix SCT CMDB store const PHOENIX_CMDB_HEADER* cmdbHeader = (const PHOENIX_CMDB_HEADER*)currentPos; // Check size if (cmdbHeader->HeaderSize != sizeof(PHOENIX_CMDB_HEADER)) continue; // All checks passed, store found break; } else if (*currentPos == INTEL_MICROCODE_HEADER_VERSION) {// Intel microcode if (!INTEL_MICROCODE_HEADER_SIZES_VALID(currentPos)) // Check header sizes continue; // Check reserved bytes const INTEL_MICROCODE_HEADER* ucodeHeader = (const INTEL_MICROCODE_HEADER*)currentPos; bool reservedBytesValid = true; for (UINT32 i = 0; i < sizeof(ucodeHeader->Reserved); i++) if (ucodeHeader->Reserved[i] != INTEL_MICROCODE_HEADER_RESERVED_BYTE) { reservedBytesValid = false; break; } if (!reservedBytesValid) continue; // All checks passed, store found break; } else if (*currentPos == OEM_ACTIVATION_PUBKEY_MAGIC) { // SLIC pubkey if (offset < 4 * sizeof(UINT32)) continue; const OEM_ACTIVATION_PUBKEY* pubkeyHeader = (const OEM_ACTIVATION_PUBKEY*)(currentPos - 4); // Check type if (pubkeyHeader->Type != OEM_ACTIVATION_PUBKEY_TYPE) continue; // All checks passed, store found offset -= 4 * sizeof(UINT32); break; } else if (*currentPos == OEM_ACTIVATION_MARKER_WINDOWS_FLAG_PART1) { // SLIC marker if (offset >= dataSize - sizeof(UINT64) || *(const UINT64*)currentPos != OEM_ACTIVATION_MARKER_WINDOWS_FLAG || offset < 26) // Check full windows flag and structure size continue; const OEM_ACTIVATION_MARKER* markerHeader = (const OEM_ACTIVATION_MARKER*)(volume.constData() + offset - 26); // Check reserved bytes bool reservedBytesValid = true; for (UINT32 i = 0; i < sizeof(markerHeader->Reserved); i++) if (markerHeader->Reserved[i] != OEM_ACTIVATION_MARKER_RESERVED_BYTE) { reservedBytesValid = false; break; } if (!reservedBytesValid) continue; // All checks passed, store found offset -= 26; break; } } // No more stores found if (offset >= dataSize - sizeof(UINT32)) return U_STORES_NOT_FOUND; nextStoreOffset = offset; return U_SUCCESS; } USTATUS NvramParser::getStoreSize(const UByteArray & data, const UINT32 storeOffset, UINT32 & storeSize) { const UINT32* signature = (const UINT32*)(data.constData() + storeOffset); if (*signature == NVRAM_VSS_STORE_SIGNATURE || *signature == NVRAM_APPLE_SVS_STORE_SIGNATURE) { const VSS_VARIABLE_STORE_HEADER* vssHeader = (const VSS_VARIABLE_STORE_HEADER*)signature; storeSize = vssHeader->Size; } else if (*signature == NVRAM_VSS2_AUTH_VAR_KEY_DATABASE_GUID_PART1 || *signature == NVRAM_VSS2_STORE_GUID_PART1) { const VSS2_VARIABLE_STORE_HEADER* vssHeader = (const VSS2_VARIABLE_STORE_HEADER*)signature; storeSize = vssHeader->Size; } else if (*signature == NVRAM_FDC_VOLUME_SIGNATURE) { const FDC_VOLUME_HEADER* fdcHeader = (const FDC_VOLUME_HEADER*)signature; storeSize = fdcHeader->Size; } else if (*signature == NVRAM_APPLE_FSYS_STORE_SIGNATURE || *signature == NVRAM_APPLE_GAID_STORE_SIGNATURE) { const APPLE_FSYS_STORE_HEADER* fsysHeader = (const APPLE_FSYS_STORE_HEADER*)signature; storeSize = fsysHeader->Size; } else if (*(signature + 1) == NVRAM_EVSA_STORE_SIGNATURE) { const EVSA_STORE_ENTRY* evsaHeader = (const EVSA_STORE_ENTRY*)signature; storeSize = evsaHeader->StoreSize; } else if (*signature == NVRAM_MAIN_STORE_VOLUME_GUID_DATA1 || *signature == EDKII_WORKING_BLOCK_SIGNATURE_GUID_DATA1) { const EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER32* ftwHeader = (const EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER32*)signature; if (ftwHeader->WriteQueueSize % 0x10 == 0x04) { // Header with 32 bit WriteQueueSize storeSize = sizeof(EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER32) + ftwHeader->WriteQueueSize; } else { // Header with 64 bit WriteQueueSize const EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER64* ftw64Header = (const EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER64*)signature; storeSize = sizeof(EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER64) + (UINT32)ftw64Header->WriteQueueSize; } } else if (*signature == NVRAM_PHOENIX_FLASH_MAP_SIGNATURE_PART1) { // Phoenix SCT flash map const PHOENIX_FLASH_MAP_HEADER* flashMapHeader = (const PHOENIX_FLASH_MAP_HEADER*)signature; storeSize = sizeof(PHOENIX_FLASH_MAP_HEADER) + sizeof(PHOENIX_FLASH_MAP_ENTRY) * flashMapHeader->NumEntries; } else if (*signature == NVRAM_PHOENIX_CMDB_HEADER_SIGNATURE) { // Phoenix SCT CMDB store storeSize = NVRAM_PHOENIX_CMDB_SIZE; // It's a predefined max size, no need to calculate } else if (*(signature + 4) == OEM_ACTIVATION_PUBKEY_MAGIC) { // SLIC pubkey const OEM_ACTIVATION_PUBKEY* pubkeyHeader = (const OEM_ACTIVATION_PUBKEY*)signature; storeSize = pubkeyHeader->Size; } else if (*(const UINT64*)(data.constData() + storeOffset + 26) == OEM_ACTIVATION_MARKER_WINDOWS_FLAG) { // SLIC marker const OEM_ACTIVATION_MARKER* markerHeader = (const OEM_ACTIVATION_MARKER*)signature; storeSize = markerHeader->Size; } else if (*signature == INTEL_MICROCODE_HEADER_VERSION) { // Intel microcode, must be checked after SLIC marker because of the same *signature values const INTEL_MICROCODE_HEADER* ucodeHeader = (const INTEL_MICROCODE_HEADER*)signature; storeSize = ucodeHeader->TotalSize; } else { return U_INVALID_PARAMETER; // Unreachable } return U_SUCCESS; } USTATUS NvramParser::parseVssStoreHeader(const UByteArray & store, const UINT32 localOffset, const bool sizeOverride, const UModelIndex & parent, UModelIndex & index) { const UINT32 dataSize = (const UINT32)store.size(); // Check store size if (dataSize < sizeof(VSS_VARIABLE_STORE_HEADER)) { msg(usprintf("%s: volume body is too small even for VSS store header", __FUNCTION__), parent); return U_SUCCESS; } // Get VSS store header const VSS_VARIABLE_STORE_HEADER* vssStoreHeader = (const VSS_VARIABLE_STORE_HEADER*)store.constData(); // Check for size override UINT32 storeSize = vssStoreHeader->Size; if (sizeOverride) { storeSize = dataSize; } // Check store size if (dataSize < storeSize) { msg(usprintf("%s: VSS store size %Xh (%u) is greater than volume body size %Xh (%u)", __FUNCTION__, storeSize, storeSize, dataSize, dataSize), parent); return U_SUCCESS; } // Construct header and body UByteArray header = store.left(sizeof(VSS_VARIABLE_STORE_HEADER)); UByteArray body = store.mid(sizeof(VSS_VARIABLE_STORE_HEADER), storeSize - sizeof(VSS_VARIABLE_STORE_HEADER)); // Add info bool isSvsStore = (vssStoreHeader->Signature == NVRAM_APPLE_SVS_STORE_SIGNATURE); UString name = isSvsStore ? UString("SVS store") : UString("VSS store"); UString info = usprintf("Signature: %s\nFull size: %Xh (%u)\nHeader size: %Xh (%u)\nBody size: %Xh (%u)\nFormat: %02Xh\nState: %02Xh\nUnknown: %04Xh", isSvsStore ? "$SVS" : "$VSS", storeSize, storeSize, header.size(), header.size(), body.size(), body.size(), vssStoreHeader->Format, vssStoreHeader->State, vssStoreHeader->Unknown); // Add tree item index = model->addItem(localOffset, Types::VssStore, 0, name, UString(), info, header, body, UByteArray(), Fixed, parent); return U_SUCCESS; } USTATUS NvramParser::parseVss2StoreHeader(const UByteArray & store, const UINT32 localOffset, const bool sizeOverride, const UModelIndex & parent, UModelIndex & index) { const UINT32 dataSize = (const UINT32)store.size(); // Check store size if (dataSize < sizeof(VSS2_VARIABLE_STORE_HEADER)) { msg(usprintf("%s: volume body is too small even for VSS2 store header", __FUNCTION__), parent); return U_SUCCESS; } // Get VSS2 store header const VSS2_VARIABLE_STORE_HEADER* vssStoreHeader = (const VSS2_VARIABLE_STORE_HEADER*)store.constData(); // Check for size override UINT32 storeSize = vssStoreHeader->Size; if (sizeOverride) { storeSize = dataSize; } // Check store size if (dataSize < storeSize) { msg(usprintf("%s: VSS2 store size %Xh (%u) is greater than volume body size %Xh (%u)", __FUNCTION__, storeSize, storeSize, dataSize, dataSize), parent); return U_SUCCESS; } // Construct header and body UByteArray header = store.left(sizeof(VSS2_VARIABLE_STORE_HEADER)); UByteArray body = store.mid(sizeof(VSS2_VARIABLE_STORE_HEADER), storeSize - sizeof(VSS2_VARIABLE_STORE_HEADER)); // Add info UString name = UString("VSS2 store"); UString info = UString("Signature: ") + guidToUString(vssStoreHeader->Signature, false) + usprintf("\nFull size: %Xh (%u)\nHeader size: %Xh (%u)\nBody size: %Xh (%u)\nFormat: %02Xh\nState: %02Xh\nUnknown: %04Xh", storeSize, storeSize, header.size(), header.size(), body.size(), body.size(), vssStoreHeader->Format, vssStoreHeader->State, vssStoreHeader->Unknown); // Add tree item index = model->addItem(localOffset, Types::Vss2Store, 0, name, UString(), info, header, body, UByteArray(), Fixed, parent); return U_SUCCESS; } USTATUS NvramParser::parseFtwStoreHeader(const UByteArray & store, const UINT32 localOffset, const UModelIndex & parent, UModelIndex & index) { const UINT32 dataSize = (const UINT32)store.size(); // Check store size if (dataSize < sizeof(EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER64)) { msg(usprintf("%s: volume body is too small even for FTW store header", __FUNCTION__), parent); return U_SUCCESS; } // Obtain required information from parent volume UINT8 emptyByte = 0xFF; UModelIndex parentVolumeIndex = model->findParentOfType(parent, Types::Volume); if (parentVolumeIndex.isValid() && model->hasEmptyParsingData(parentVolumeIndex) == false) { UByteArray data = model->parsingData(parentVolumeIndex); const VOLUME_PARSING_DATA* pdata = (const VOLUME_PARSING_DATA*)data.constData(); emptyByte = pdata->emptyByte; } // Get FTW block headers const EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER32* ftw32BlockHeader = (const EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER32*)store.constData(); const EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER64* ftw64BlockHeader = (const EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER64*)store.constData(); // Check store size UINT32 ftwBlockSize; bool has32bitHeader; if (ftw32BlockHeader->WriteQueueSize % 0x10 == 0x04) { // Header with 32 bit WriteQueueSize ftwBlockSize = sizeof(EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER32) + ftw32BlockHeader->WriteQueueSize; has32bitHeader = true; } else { // Header with 64 bit WriteQueueSize ftwBlockSize = sizeof(EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER64) + (UINT32)ftw64BlockHeader->WriteQueueSize; has32bitHeader = false; } if (dataSize < ftwBlockSize) { msg(usprintf("%s: FTW store size %Xh (%u) is greater than volume body size %Xh (%u)", __FUNCTION__, ftwBlockSize, ftwBlockSize, dataSize, dataSize), parent); return U_SUCCESS; } // Construct header and body UINT32 headerSize = has32bitHeader ? sizeof(EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER32) : sizeof(EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER64); UByteArray header = store.left(headerSize); UByteArray body = store.mid(headerSize, ftwBlockSize - headerSize); // Check block header checksum UByteArray crcHeader = header; EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER32* crcFtwBlockHeader = (EFI_FAULT_TOLERANT_WORKING_BLOCK_HEADER32*)header.data(); crcFtwBlockHeader->Crc = emptyByte ? 0xFFFFFFFF : 0; crcFtwBlockHeader->State = emptyByte ? 0xFF : 0; UINT32 calculatedCrc = crc32(0, (const UINT8*)crcFtwBlockHeader, headerSize); // Add info UString name("FTW store"); UString info = UString("Signature: ") + guidToUString(ftw32BlockHeader->Signature, false) + usprintf("\nFull size: %Xh (%u)\nHeader size: %Xh (%u)\nBody size: %Xh (%u)\nState: %02Xh\nHeader CRC32: %08Xh", ftwBlockSize, ftwBlockSize, headerSize, headerSize, body.size(), body.size(), ftw32BlockHeader->State, ftw32BlockHeader->Crc) + (ftw32BlockHeader->Crc != calculatedCrc ? usprintf(", invalid, should be %08Xh", calculatedCrc) : UString(", valid")); // Add tree item index = model->addItem(localOffset, Types::FtwStore, 0, name, UString(), info, header, body, UByteArray(), Fixed, parent); return U_SUCCESS; } USTATUS NvramParser::parseFdcStoreHeader(const UByteArray & store, const UINT32 localOffset, const UModelIndex & parent, UModelIndex & index) { const UINT32 dataSize = (const UINT32)store.size(); // Check store size if (dataSize < sizeof(FDC_VOLUME_HEADER)) { msg(usprintf("%s: volume body is too small even for FDC store header", __FUNCTION__), parent); return U_SUCCESS; } // Get Fdc store header const FDC_VOLUME_HEADER* fdcStoreHeader = (const FDC_VOLUME_HEADER*)store.constData(); // Check store size if (dataSize < fdcStoreHeader->Size) { msg(usprintf("%s: FDC store size %Xh (%u) is greater than volume body size %Xh (%u)", __FUNCTION__, fdcStoreHeader->Size, fdcStoreHeader->Size, dataSize, dataSize), parent); return U_SUCCESS; } // Construct header and body UByteArray header = store.left(sizeof(FDC_VOLUME_HEADER)); UByteArray body = store.mid(sizeof(FDC_VOLUME_HEADER), fdcStoreHeader->Size - sizeof(FDC_VOLUME_HEADER)); // Add info UString name("FDC store"); UString info = usprintf("Signature: _FDC\nFull size: %Xh (%u)\nHeader size: %Xh (%u)\nBody size: %Xh (%u)", fdcStoreHeader->Size, fdcStoreHeader->Size, header.size(), header.size(), body.size(), body.size()); // Add tree item index = model->addItem(localOffset, Types::FdcStore, 0, name, UString(), info, header, body, UByteArray(), Fixed, parent); return U_SUCCESS; } USTATUS NvramParser::parseFsysStoreHeader(const UByteArray & store, const UINT32 localOffset, const UModelIndex & parent, UModelIndex & index) { const UINT32 dataSize = (const UINT32)store.size(); // Check store size if (dataSize < sizeof(APPLE_FSYS_STORE_HEADER)) { msg(usprintf("%s: volume body is too small even for Fsys store header", __FUNCTION__), parent); return U_SUCCESS; } // Get Fsys store header const APPLE_FSYS_STORE_HEADER* fsysStoreHeader = (const APPLE_FSYS_STORE_HEADER*)store.constData(); // Check store size if (dataSize < fsysStoreHeader->Size) { msg(usprintf("%s: Fsys store size %Xh (%u) is greater than volume body size %Xh (%u)", __FUNCTION__, fsysStoreHeader->Size, fsysStoreHeader->Size, dataSize, dataSize), parent); return U_SUCCESS; } // Construct header and body UByteArray header = store.left(sizeof(APPLE_FSYS_STORE_HEADER)); UByteArray body = store.mid(sizeof(APPLE_FSYS_STORE_HEADER), fsysStoreHeader->Size - sizeof(APPLE_FSYS_STORE_HEADER) - sizeof(UINT32)); // Check store checksum UINT32 storedCrc = *(UINT32*)store.right(sizeof(UINT32)).constData(); UINT32 calculatedCrc = crc32(0, (const UINT8*)store.constData(), (const UINT32)store.size() - sizeof(UINT32)); // Add info bool isGaidStore = (fsysStoreHeader->Signature == NVRAM_APPLE_GAID_STORE_SIGNATURE); UString name = isGaidStore ? UString("Gaid store") : UString("Fsys store"); UString info = usprintf("Signature: %s\nFull size: %Xh (%u)\nHeader size: %Xh (%u)\nBody size: %Xh (%u)\nUnknown0: %02Xh\nUnknown1: %08Xh\nCRC32: %08Xh", isGaidStore ? "Gaid" : "Fsys", fsysStoreHeader->Size, fsysStoreHeader->Size, header.size(), header.size(), body.size(), body.size(), fsysStoreHeader->Unknown0, fsysStoreHeader->Unknown1) + (storedCrc != calculatedCrc ? usprintf(", invalid, should be %08Xh", calculatedCrc) : UString(", valid")); // Add tree item index = model->addItem(localOffset, Types::FsysStore, 0, name, UString(), info, header, body, UByteArray(), Fixed, parent); return U_SUCCESS; } USTATUS NvramParser::parseEvsaStoreHeader(const UByteArray & store, const UINT32 localOffset, const UModelIndex & parent, UModelIndex & index) { const UINT32 dataSize = (const UINT32)store.size(); // Check dataSize if (dataSize < sizeof(EVSA_STORE_ENTRY)) { msg(usprintf("%s: volume body is too small even for EVSA store header", __FUNCTION__), parent); return U_SUCCESS; } // Get EVSA store header const EVSA_STORE_ENTRY* evsaStoreHeader = (const EVSA_STORE_ENTRY*)store.constData(); // Check store size if (dataSize < evsaStoreHeader->StoreSize) { msg(usprintf("%s: EVSA store size %Xh (%u) is greater than volume body size %Xh (%u)", __FUNCTION__, evsaStoreHeader->StoreSize, evsaStoreHeader->StoreSize, dataSize, dataSize), parent); return U_SUCCESS; } // Construct header and body UByteArray header = store.left(evsaStoreHeader->Header.Size); UByteArray body = store.mid(evsaStoreHeader->Header.Size, evsaStoreHeader->StoreSize - evsaStoreHeader->Header.Size); // Recalculate checksum UINT8 calculated = calculateChecksum8(((const UINT8*)evsaStoreHeader) + 2, evsaStoreHeader->Header.Size - 2); // Add info UString name("EVSA store"); UString info = usprintf("Signature: EVSA\nFull size: %Xh (%u)\nHeader size: %Xh (%u)\nBody size: %Xh (%u)\nType: %02Xh\nAttributes: %08Xh\nChecksum: %02Xh", evsaStoreHeader->StoreSize, evsaStoreHeader->StoreSize, header.size(), header.size(), body.size(), body.size(), evsaStoreHeader->Header.Type, evsaStoreHeader->Attributes, evsaStoreHeader->Header.Checksum) + (evsaStoreHeader->Header.Checksum != calculated ? usprintf("%, invalid, should be %02Xh", calculated) : UString(", valid")); // Add tree item index = model->addItem(localOffset, Types::EvsaStore, 0, name, UString(), info, header, body, UByteArray(), Fixed, parent); return U_SUCCESS; } USTATUS NvramParser::parseFlashMapStoreHeader(const UByteArray & store, const UINT32 localOffset, const UModelIndex & parent, UModelIndex & index) { const UINT32 dataSize = (const UINT32)store.size(); // Check data size if (dataSize < sizeof(PHOENIX_FLASH_MAP_HEADER)) { msg(usprintf("%s: volume body is too small even for FlashMap block header", __FUNCTION__), parent); return U_SUCCESS; } // Get FlashMap block header const PHOENIX_FLASH_MAP_HEADER* flashMapHeader = (const PHOENIX_FLASH_MAP_HEADER*)store.constData(); // Check store size UINT32 flashMapSize = sizeof(PHOENIX_FLASH_MAP_HEADER) + flashMapHeader->NumEntries * sizeof(PHOENIX_FLASH_MAP_ENTRY); if (dataSize < flashMapSize) { msg(usprintf("%s: FlashMap block size %Xh (%u) is greater than volume body size %Xh (%u)", __FUNCTION__, flashMapSize, flashMapSize, dataSize, dataSize), parent); return U_SUCCESS; } // Construct header and body UByteArray header = store.left(sizeof(PHOENIX_FLASH_MAP_HEADER)); UByteArray body = store.mid(sizeof(PHOENIX_FLASH_MAP_HEADER), flashMapSize - sizeof(PHOENIX_FLASH_MAP_HEADER)); // Add info UString name("Phoenix SCT flash map"); UString info = usprintf("Signature: _FLASH_MAP\nFull size: %Xh (%u)\nHeader size: %Xh (%u)\nBody size: %Xh (%u)\nNumber of entries: %u", flashMapSize, flashMapSize, header.size(), header.size(), body.size(), body.size(), flashMapHeader->NumEntries); // Add tree item index = model->addItem(localOffset, Types::FlashMapStore, 0, name, UString(), info, header, body, UByteArray(), Fixed, parent); return U_SUCCESS; } USTATUS NvramParser::parseCmdbStoreHeader(const UByteArray & store, const UINT32 localOffset, const UModelIndex & parent, UModelIndex & index) { const UINT32 dataSize = (const UINT32)store.size(); // Check store size if (dataSize < sizeof(PHOENIX_CMDB_HEADER)) { msg(usprintf("%s: volume body is too small even for CMDB store header", __FUNCTION__), parent); return U_SUCCESS; } UINT32 cmdbSize = NVRAM_PHOENIX_CMDB_SIZE; if (dataSize < cmdbSize) { msg(usprintf("%s: CMDB store size %Xh (%u) is greater than volume body size %Xh (%u)", __FUNCTION__, cmdbSize, cmdbSize, dataSize, dataSize), parent); return U_SUCCESS; } // Get store header const PHOENIX_CMDB_HEADER* cmdbHeader = (const PHOENIX_CMDB_HEADER*)store.constData(); // Construct header and body UByteArray header = store.left(cmdbHeader->TotalSize); UByteArray body = store.mid(cmdbHeader->TotalSize, cmdbSize - cmdbHeader->TotalSize); // Add info UString name("CMDB store"); UString info = usprintf("Signature: CMDB\nFull size: %Xh (%u)\nHeader size: %Xh (%u)\nBody size: %Xh (%u)", cmdbSize, cmdbSize, header.size(), header.size(), body.size(), body.size()); // Add tree item index = model->addItem(localOffset, Types::CmdbStore, 0, name, UString(), info, header, body, UByteArray(), Fixed, parent); return U_SUCCESS; } USTATUS NvramParser::parseSlicPubkeyHeader(const UByteArray & store, const UINT32 localOffset, const UModelIndex & parent, UModelIndex & index) { const UINT32 dataSize = (const UINT32)store.size(); // Check data size if (dataSize < sizeof(OEM_ACTIVATION_PUBKEY)) { msg(usprintf("%s: volume body is too small even for SLIC pubkey header", __FUNCTION__), parent); return U_SUCCESS; } // Get SLIC pubkey header const OEM_ACTIVATION_PUBKEY* pubkeyHeader = (const OEM_ACTIVATION_PUBKEY*)store.constData(); // Check store size if (dataSize < pubkeyHeader->Size) { msg(usprintf("%s: SLIC pubkey size %Xh (%u) is greater than volume body size %Xh (%u)", __FUNCTION__, pubkeyHeader->Size, pubkeyHeader->Size, dataSize, dataSize), parent); return U_SUCCESS; } // Construct header and body UByteArray header = store.left(sizeof(OEM_ACTIVATION_PUBKEY)); // Add info UString name("SLIC pubkey"); UString info = usprintf("Type: 0h\nFull size: %Xh (%u)\nHeader size: %Xh (%u)\nBody size: 0h (0)\n" "Key type: %02Xh\nVersion: %02Xh\nAlgorithm: %08Xh\nMagic: RSA1\nBit length: %08Xh\nExponent: %08Xh", pubkeyHeader->Size, pubkeyHeader->Size, header.size(), header.size(), pubkeyHeader->KeyType, pubkeyHeader->Version, pubkeyHeader->Algorithm, pubkeyHeader->BitLength, pubkeyHeader->Exponent); // Add tree item index = model->addItem(localOffset, Types::SlicData, Subtypes::PubkeySlicData, name, UString(), info, header, UByteArray(), UByteArray(), Fixed, parent); return U_SUCCESS; } USTATUS NvramParser::parseSlicMarkerHeader(const UByteArray & store, const UINT32 localOffset, const UModelIndex & parent, UModelIndex & index) { const UINT32 dataSize = (const UINT32)store.size(); // Check data size if (dataSize < sizeof(OEM_ACTIVATION_MARKER)) { msg(usprintf("%s: volume body is too small even for SLIC marker header", __FUNCTION__), parent); return U_SUCCESS; } // Get SLIC marker header const OEM_ACTIVATION_MARKER* markerHeader = (const OEM_ACTIVATION_MARKER*)store.constData(); // Check store size if (dataSize < markerHeader->Size) { msg(usprintf("%s: SLIC marker size %Xh (%u) is greater than volume body size %Xh (%u)", __FUNCTION__, markerHeader->Size, markerHeader->Size, dataSize, dataSize), parent); return U_SUCCESS; } // Construct header and body UByteArray header = store.left(sizeof(OEM_ACTIVATION_MARKER)); // Add info UString name("SLIC marker"); UString info = usprintf("Type: 1h\nFull size: %Xh (%u)\nHeader size: %Xh (%u)\nBody size: 0h (0)\n" "Version: %08Xh\nOEM ID: %s\nOEM table ID: %s\nWindows flag: WINDOWS\nSLIC version: %08Xh", markerHeader->Size, markerHeader->Size, header.size(), header.size(), markerHeader->Version, (const char*)UString((const char*)&(markerHeader->OemId)).left(6).toLocal8Bit(), (const char*)UString((const char*)&(markerHeader->OemTableId)).left(8).toLocal8Bit(), markerHeader->SlicVersion); // Add tree item index = model->addItem(localOffset, Types::SlicData, Subtypes::MarkerSlicData, name, UString(), info, header, UByteArray(), UByteArray(), Fixed, parent); return U_SUCCESS; } USTATUS NvramParser::parseStoreHeader(const UByteArray & store, const UINT32 localOffset, const UModelIndex & parent, UModelIndex & index) { const UINT32 dataSize = (const UINT32)store.size(); const UINT32* signature = (const UINT32*)store.constData(); // Check store size if (dataSize < sizeof(UINT32)) { msg(usprintf("%s: volume body is too small even for a store signature", __FUNCTION__), parent); return U_SUCCESS; } // Check signature and run parser function needed // VSS/SVS store if (*signature == NVRAM_VSS_STORE_SIGNATURE || *signature == NVRAM_APPLE_SVS_STORE_SIGNATURE) return parseVssStoreHeader(store, localOffset, false, parent, index); // VSS2 store if (*signature == NVRAM_VSS2_AUTH_VAR_KEY_DATABASE_GUID_PART1 || *signature == NVRAM_VSS2_STORE_GUID_PART1) return parseVss2StoreHeader(store, localOffset, false, parent, index); // FTW store else if (*signature == NVRAM_MAIN_STORE_VOLUME_GUID_DATA1 || *signature == EDKII_WORKING_BLOCK_SIGNATURE_GUID_DATA1) return parseFtwStoreHeader(store, localOffset, parent, index); // FDC store else if (*signature == NVRAM_FDC_VOLUME_SIGNATURE) return parseFdcStoreHeader(store, localOffset, parent, index); // Apple Fsys/Gaid store else if (*signature == NVRAM_APPLE_FSYS_STORE_SIGNATURE || *signature == NVRAM_APPLE_GAID_STORE_SIGNATURE) return parseFsysStoreHeader(store, localOffset, parent, index); // EVSA store else if (dataSize >= 2 * sizeof(UINT32) && *(signature + 1) == NVRAM_EVSA_STORE_SIGNATURE) return parseEvsaStoreHeader(store, localOffset, parent, index); // Phoenix SCT flash map else if (*signature == NVRAM_PHOENIX_FLASH_MAP_SIGNATURE_PART1) return parseFlashMapStoreHeader(store, localOffset, parent, index); // Phoenix CMDB store else if (*signature == NVRAM_PHOENIX_CMDB_HEADER_SIGNATURE) return parseCmdbStoreHeader(store, localOffset, parent, index); // SLIC pubkey else if (dataSize >= 5 * sizeof(UINT32) && *(signature + 4) == OEM_ACTIVATION_PUBKEY_MAGIC) return parseSlicPubkeyHeader(store, localOffset, parent, index); // SLIC marker else if (dataSize >= 34 && *(const UINT64*)(store.constData() + 26) == OEM_ACTIVATION_MARKER_WINDOWS_FLAG) return parseSlicMarkerHeader(store, localOffset, parent, index); // Intel microcode // Must be checked after SLIC marker because of the same *signature values else if (*signature == INTEL_MICROCODE_HEADER_VERSION) return ffsParser->parseIntelMicrocodeHeader(store, localOffset, parent, index); msg(usprintf("parseStoreHeader: don't know how to parse a header with signature %08Xh", *signature), parent); return U_SUCCESS; } USTATUS NvramParser::parseFdcStoreBody(const UModelIndex & index) { // Sanity check if (!index.isValid()) return U_INVALID_PARAMETER; // Get item data const UByteArray data = model->body(index); // Get local offset UINT32 localOffset = model->header(index).size(); // The body is a firmware volume with either a VSS or VSS2 store UModelIndex volumeIndex; USTATUS status = ffsParser->parseVolumeHeader(data, localOffset, index, volumeIndex); if (status || !volumeIndex.isValid()) { msg(usprintf("%s: store can't be parsed as FDC store", __FUNCTION__), index); return U_SUCCESS; } // Determine if it's a VSS or VSS2 store inside UByteArray store = model->body(volumeIndex); if ((UINT32)store.size() >= sizeof(UINT32) && *(const UINT32*)store.constData() == NVRAM_VSS_STORE_SIGNATURE) { UModelIndex vssIndex; status = parseVssStoreHeader(store, localOffset + model->header(volumeIndex).size(), true, volumeIndex, vssIndex); if (status) return status; return parseVssStoreBody(vssIndex, 0); } else if ((UINT32)store.size() >= sizeof(EFI_GUID) && store.left(sizeof(EFI_GUID)) == NVRAM_FDC_STORE_GUID) { UModelIndex vss2Index; status = parseVss2StoreHeader(store, localOffset + model->header(volumeIndex).size(), true, volumeIndex, vss2Index); if (status) return status; return parseVssStoreBody(vss2Index, 0); } else { msg(usprintf("%s: internal volume can't be parsed as VSS/VSS2 store", __FUNCTION__), index); return U_SUCCESS; } } USTATUS NvramParser::parseVssStoreBody(const UModelIndex & index, UINT8 alignment) { // Sanity check if (!index.isValid()) return U_INVALID_PARAMETER; // Obtain required information from parent volume UINT8 emptyByte = 0xFF; UModelIndex parentVolumeIndex = model->findParentOfType(index, Types::Volume); if (parentVolumeIndex.isValid() && model->hasEmptyParsingData(parentVolumeIndex) == false) { UByteArray data = model->parsingData(parentVolumeIndex); const VOLUME_PARSING_DATA* pdata = (const VOLUME_PARSING_DATA*)data.constData(); emptyByte = pdata->emptyByte; } // Get local offset UINT32 localOffset = model->header(index).size(); // Get item data const UByteArray data = model->body(index); // Check that the is enough space for variable header const UINT32 dataSize = (UINT32)data.size(); if (dataSize < sizeof(VSS_VARIABLE_HEADER)) { msg(usprintf("%s: store body is too small even for VSS variable header", __FUNCTION__), index); return U_SUCCESS; } UINT32 offset = 0; // Parse all variables while (1) { bool isInvalid = true; bool isAuthenticated = false; bool isAppleCrc32 = false; bool isIntelSpecial = false; UINT32 storedCrc32 = 0; UINT32 calculatedCrc32 = 0; UINT64 monotonicCounter = 0; EFI_TIME timestamp = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; UINT32 pubKeyIndex = 0; UINT8 subtype = 0; UString name; UString text; EFI_GUID* variableGuid = NULL; CHAR16* variableName = (CHAR16*)L""; UByteArray header; UByteArray body; UINT32 unparsedSize = dataSize - offset; // Get variable header const VSS_VARIABLE_HEADER* variableHeader = (const VSS_VARIABLE_HEADER*)(data.constData() + offset); // Check variable header to fit in still unparsed data UINT32 variableSize = 0; if (unparsedSize >= sizeof(VSS_VARIABLE_HEADER) && variableHeader->StartId == NVRAM_VSS_VARIABLE_START_ID) { // Apple VSS variable with CRC32 of the data if (variableHeader->Attributes & NVRAM_VSS_VARIABLE_APPLE_DATA_CHECKSUM) { isAppleCrc32 = true; if (unparsedSize < sizeof(VSS_APPLE_VARIABLE_HEADER)) { variableSize = 0; } else { const VSS_APPLE_VARIABLE_HEADER* appleVariableHeader = (const VSS_APPLE_VARIABLE_HEADER*)variableHeader; variableSize = sizeof(VSS_APPLE_VARIABLE_HEADER) + appleVariableHeader->NameSize + appleVariableHeader->DataSize; variableGuid = (EFI_GUID*)&appleVariableHeader->VendorGuid; variableName = (CHAR16*)(appleVariableHeader + 1); header = data.mid(offset, sizeof(VSS_APPLE_VARIABLE_HEADER) + appleVariableHeader->NameSize); body = data.mid(offset + header.size(), appleVariableHeader->DataSize); // Calculate CRC32 of the variable data storedCrc32 = appleVariableHeader->DataCrc32; calculatedCrc32 = crc32(0, (const UINT8*)body.constData(), body.size()); } } // Authenticated variable else if ((variableHeader->Attributes & NVRAM_VSS_VARIABLE_AUTHENTICATED_WRITE_ACCESS) || (variableHeader->Attributes & NVRAM_VSS_VARIABLE_TIME_BASED_AUTHENTICATED_WRITE_ACCESS) || (variableHeader->Attributes & NVRAM_VSS_VARIABLE_APPEND_WRITE) || (variableHeader->NameSize == 0 && variableHeader->DataSize == 0)) { // If both NameSize and DataSize are zeros, it's auth variable with zero montonic counter isAuthenticated = true; if (unparsedSize < sizeof(VSS_AUTH_VARIABLE_HEADER)) { variableSize = 0; } else { const VSS_AUTH_VARIABLE_HEADER* authVariableHeader = (const VSS_AUTH_VARIABLE_HEADER*)variableHeader; variableSize = sizeof(VSS_AUTH_VARIABLE_HEADER) + authVariableHeader->NameSize + authVariableHeader->DataSize; variableGuid = (EFI_GUID*)&authVariableHeader->VendorGuid; variableName = (CHAR16*)(authVariableHeader + 1); header = data.mid(offset, sizeof(VSS_AUTH_VARIABLE_HEADER) + authVariableHeader->NameSize); body = data.mid(offset + header.size(), authVariableHeader->DataSize); monotonicCounter = authVariableHeader->MonotonicCounter; timestamp = authVariableHeader->Timestamp; pubKeyIndex = authVariableHeader->PubKeyIndex; } } // Intel special variable else if (variableHeader->State == NVRAM_VSS_INTEL_VARIABLE_VALID || variableHeader->State == NVRAM_VSS_INTEL_VARIABLE_INVALID) { isIntelSpecial = true; const VSS_INTEL_VARIABLE_HEADER* intelVariableHeader = (const VSS_INTEL_VARIABLE_HEADER*)variableHeader; variableSize = intelVariableHeader->TotalSize; variableGuid = (EFI_GUID*)&intelVariableHeader->VendorGuid; variableName = (CHAR16*)(intelVariableHeader + 1); UINT32 i = 0; while (variableName[i] != 0) ++i; i = sizeof(VSS_INTEL_VARIABLE_HEADER) + 2 * (i + 1); i = i < variableSize ? i : variableSize; header = data.mid(offset, i); body = data.mid(offset + header.size(), variableSize - i); } // Normal VSS variable else { variableSize = sizeof(VSS_VARIABLE_HEADER) + variableHeader->NameSize + variableHeader->DataSize; variableGuid = (EFI_GUID*)&variableHeader->VendorGuid; variableName = (CHAR16*)(variableHeader + 1); header = data.mid(offset, sizeof(VSS_VARIABLE_HEADER) + variableHeader->NameSize); body = data.mid(offset + header.size(), variableHeader->DataSize); } // Check variable state if (variableHeader->State == NVRAM_VSS_INTEL_VARIABLE_VALID || variableHeader->State == NVRAM_VSS_VARIABLE_ADDED || variableHeader->State == NVRAM_VSS_VARIABLE_HEADER_VALID) { isInvalid = false; } // Check variable size if (variableSize > unparsedSize) { variableSize = 0; } } // Can't parse further, add the last element and break the loop if (!variableSize) { // Check if the data left is a free space or a padding UByteArray padding = data.mid(offset, unparsedSize); // Get info UString info = usprintf("Full size: %Xh (%u)", padding.size(), padding.size()); if (padding.count(emptyByte) == padding.size()) { // Free space // Add tree item model->addItem(localOffset + offset, Types::FreeSpace, 0, UString("Free space"), UString(), info, UByteArray(), padding, UByteArray(), Fixed, index); } else { // Padding // Nothing is parsed yet, but the store is not empty if (!offset) { msg(usprintf("%s: store can't be parsed as VSS store", __FUNCTION__), index); return U_SUCCESS; } // Add tree item model->addItem(localOffset + offset, Types::Padding, getPaddingType(padding), UString("Padding"), UString(), info, UByteArray(), padding, UByteArray(), Fixed, index); } return U_SUCCESS; } UString info; // Rename invalid variables if (isInvalid || !variableGuid) { isInvalid = true; name = UString("Invalid"); } else { // Add GUID and text for valid variables name = guidToUString(readUnaligned(variableGuid)); info += UString("Variable GUID: ") + guidToUString(readUnaligned(variableGuid), false) + UString("\n"); text = UString::fromUtf16(variableName); } // Add info info += usprintf("Full size: %Xh (%u)\nHeader size %Xh (%u)\nBody size: %Xh (%u)\nState: %02Xh\nReserved: %02Xh\nAttributes: %08Xh (", variableSize, variableSize, header.size(), header.size(), body.size(), body.size(), variableHeader->State, variableHeader->Reserved, variableHeader->Attributes) + vssAttributesToUString(variableHeader->Attributes) + UString(")"); // Set subtype and add related info if (isInvalid) subtype = Subtypes::InvalidVssEntry; else if (isAuthenticated) { subtype = Subtypes::AuthVssEntry; info += usprintf("\nMonotonic counter: %" PRIX64 "h\nTimestamp: ", monotonicCounter) + efiTimeToUString(timestamp) + usprintf("\nPubKey index: %u", pubKeyIndex); } else if (isAppleCrc32) { subtype = Subtypes::AppleVssEntry; info += usprintf("\nData checksum: %08Xh", storedCrc32) + (storedCrc32 != calculatedCrc32 ? usprintf(", invalid, should be %08Xh", calculatedCrc32) : UString(", valid")); } else if (isIntelSpecial) { subtype = Subtypes::IntelVssEntry; } else { subtype = Subtypes::StandardVssEntry; } // Add tree item model->addItem(localOffset + offset, Types::VssEntry, subtype, name, text, info, header, body, UByteArray(), Fixed, index); // Apply alignment, if needed if (alignment) { variableSize = ((variableSize + alignment - 1) & (~(alignment - 1))); } // Move to next variable offset += variableSize; } return U_SUCCESS; } USTATUS NvramParser::parseFsysStoreBody(const UModelIndex & index) { // Sanity check if (!index.isValid()) return U_INVALID_PARAMETER; // Get local offset UINT32 localOffset = model->header(index).size(); // Get item data const UByteArray data = model->body(index); // Check that the is enough space for variable header const UINT32 storeDataSize = (UINT32)data.size(); UINT32 offset = 0; // Parse all variables while (1) { UINT32 unparsedSize = storeDataSize - offset; UINT32 variableSize = 0; // Get nameSize and name of the variable UINT8 nameSize = *(UINT8*)(data.constData() + offset); bool valid = !(nameSize & 0x80); // Last bit is a validity bit, 0 means valid nameSize &= 0x7F; // Check sanity if (unparsedSize >= nameSize + sizeof(UINT8)) { variableSize = nameSize + sizeof(UINT8); } UByteArray name; if (variableSize) { name = data.mid(offset + sizeof(UINT8), nameSize); // Check for EOF variable if (nameSize == 3 && name[0] == 'E' && name[1] == 'O' && name[2] == 'F') { // There is no data afterward, add EOF variable and free space and return UByteArray header = data.mid(offset, sizeof(UINT8) + nameSize); UString info = usprintf("Full size: %Xh (%u)", header.size(), header.size()); // Add EOF tree item model->addItem(localOffset + offset, Types::FsysEntry, Subtypes::NormalFsysEntry, UString("EOF"), UString(), info, header, UByteArray(), UByteArray(), Fixed, index); // Add free space offset += header.size(); UByteArray body = data.mid(offset); info = usprintf("Full size: %Xh (%u)", body.size(), body.size()); // Add free space tree item model->addItem(localOffset + offset, Types::FreeSpace, 0, UString("Free space"), UString(), info, UByteArray(), body, UByteArray(), Fixed, index); return U_SUCCESS; } } // Get dataSize and data of the variable const UINT16 dataSize = *(UINT16*)(data.constData() + offset + sizeof(UINT8) + nameSize); if (unparsedSize >= sizeof(UINT8) + nameSize + sizeof(UINT16) + dataSize) { variableSize = sizeof(UINT8) + nameSize + sizeof(UINT16) + dataSize; } else { // Last variable is bad, add the rest as padding and return UByteArray body = data.mid(offset); UString info = usprintf("Full size: %Xh (%u)", body.size(), body.size()); // Add padding tree item model->addItem(localOffset + offset, Types::Padding, getPaddingType(body), UString("Padding"), UString(), info, UByteArray(), body, UByteArray(), Fixed, index); // Show message msg(usprintf("%s: next variable appears too big, added as padding", __FUNCTION__), index); return U_SUCCESS; } // Construct header and body UByteArray header = data.mid(offset, sizeof(UINT8) + nameSize + sizeof(UINT16)); UByteArray body = data.mid(offset + sizeof(UINT8) + nameSize + sizeof(UINT16), dataSize); // Add info UString info = usprintf("Full size: %Xh (%u)\nHeader size %Xh (%u)\nBody size: %Xh (%u)", variableSize, variableSize, header.size(), header.size(), body.size(), body.size()); // Add tree item model->addItem(localOffset + offset, Types::FsysEntry, valid ? Subtypes::NormalFsysEntry : Subtypes::InvalidFsysEntry, UString(name.constData()), UString(), info, header, body, UByteArray(), Fixed, index); // Move to next variable offset += variableSize; } return U_SUCCESS; } USTATUS NvramParser::parseEvsaStoreBody(const UModelIndex & index) { // Sanity check if (!index.isValid()) return U_INVALID_PARAMETER; // Obtain required information from parent volume UINT8 emptyByte = 0xFF; UModelIndex parentVolumeIndex = model->findParentOfType(index, Types::Volume); if (parentVolumeIndex.isValid() && model->hasEmptyParsingData(parentVolumeIndex) == false) { UByteArray data = model->parsingData(parentVolumeIndex); const VOLUME_PARSING_DATA* pdata = (const VOLUME_PARSING_DATA*)data.constData(); emptyByte = pdata->emptyByte; } // Get local offset UINT32 localOffset = model->header(index).size(); // Get item data const UByteArray data = model->body(index); // Check that the is enough space for entry header const UINT32 storeDataSize = (UINT32)data.size(); UINT32 offset = 0; std::map guidMap; std::map nameMap; // Parse all entries UINT32 unparsedSize = storeDataSize; while (unparsedSize) { UINT32 variableSize = 0; UString name; UString info; UByteArray header; UByteArray body; UINT8 subtype; UINT8 calculated; const EVSA_ENTRY_HEADER* entryHeader = (const EVSA_ENTRY_HEADER*)(data.constData() + offset); // Check entry size variableSize = sizeof(EVSA_ENTRY_HEADER); if (unparsedSize < variableSize || unparsedSize < entryHeader->Size) { body = data.mid(offset); info = usprintf("Full size: %Xh (%u)", body.size(), body.size()); if (body.count(emptyByte) == body.size()) { // Free space // Add free space tree item model->addItem(localOffset + offset, Types::FreeSpace, 0, UString("Free space"), UString(), info, UByteArray(), body, UByteArray(), Fixed, index); } else { // Add padding tree item UModelIndex itemIndex = model->addItem(localOffset + offset, Types::Padding, getPaddingType(body), UString("Padding"), UString(), info, UByteArray(), body, UByteArray(), Fixed, index); // Show message msg(usprintf("%s: variable parsing failed, the rest of unparsed store added as padding", __FUNCTION__), itemIndex); } break; } variableSize = entryHeader->Size; // Recalculate entry checksum calculated = calculateChecksum8(((const UINT8*)entryHeader) + 2, entryHeader->Size - 2); // GUID entry if (entryHeader->Type == NVRAM_EVSA_ENTRY_TYPE_GUID1 || entryHeader->Type == NVRAM_EVSA_ENTRY_TYPE_GUID2) { const EVSA_GUID_ENTRY* guidHeader = (const EVSA_GUID_ENTRY*)entryHeader; header = data.mid(offset, sizeof(EVSA_GUID_ENTRY)); body = data.mid(offset + sizeof(EVSA_GUID_ENTRY), guidHeader->Header.Size - sizeof(EVSA_GUID_ENTRY)); EFI_GUID guid = *(EFI_GUID*)body.constData(); name = guidToUString(guid); info = UString("GUID: ") + guidToUString(guid, false) + usprintf("\nFull size: %Xh (%u)\nHeader size %Xh (%u)\nBody size: %Xh (%u)\nType: %02Xh\nChecksum: %02Xh", variableSize, variableSize, header.size(), header.size(), body.size(), body.size(), guidHeader->Header.Type, guidHeader->Header.Checksum) + (guidHeader->Header.Checksum != calculated ? usprintf(", invalid, should be %02Xh", calculated) : UString(", valid")) + usprintf("\nGuidId: %04Xh", guidHeader->GuidId); subtype = Subtypes::GuidEvsaEntry; guidMap.insert(std::pair(guidHeader->GuidId, guid)); } // Name entry else if (entryHeader->Type == NVRAM_EVSA_ENTRY_TYPE_NAME1 || entryHeader->Type == NVRAM_EVSA_ENTRY_TYPE_NAME2) { const EVSA_NAME_ENTRY* nameHeader = (const EVSA_NAME_ENTRY*)entryHeader; header = data.mid(offset, sizeof(EVSA_NAME_ENTRY)); body = data.mid(offset + sizeof(EVSA_NAME_ENTRY), nameHeader->Header.Size - sizeof(EVSA_NAME_ENTRY)); name = UString::fromUtf16((const CHAR16*)body.constData()); info = UString("Name: ") + name + usprintf("\nFull size: %Xh (%u)\nHeader size %Xh (%u)\nBody size: %Xh (%u)\nType: %02Xh\nChecksum: %02Xh", variableSize, variableSize, header.size(), header.size(), body.size(), body.size(), nameHeader->Header.Type, nameHeader->Header.Checksum) + (nameHeader->Header.Checksum != calculated ? usprintf(", invalid, should be %02Xh", calculated) : UString(", valid")) + usprintf("\nVarId: %04Xh", nameHeader->VarId); subtype = Subtypes::NameEvsaEntry; nameMap.insert(std::pair(nameHeader->VarId, name)); } // Data entry else if (entryHeader->Type == NVRAM_EVSA_ENTRY_TYPE_DATA1 || entryHeader->Type == NVRAM_EVSA_ENTRY_TYPE_DATA2 || entryHeader->Type == NVRAM_EVSA_ENTRY_TYPE_DATA_INVALID) { const EVSA_DATA_ENTRY* dataHeader = (const EVSA_DATA_ENTRY*)entryHeader; // Check for extended header UINT32 headerSize = sizeof(EVSA_DATA_ENTRY); UINT32 dataSize = dataHeader->Header.Size - sizeof(EVSA_DATA_ENTRY); if (dataHeader->Attributes & NVRAM_EVSA_DATA_EXTENDED_HEADER) { const EVSA_DATA_ENTRY_EXTENDED* dataHeaderExtended = (const EVSA_DATA_ENTRY_EXTENDED*)entryHeader; headerSize = sizeof(EVSA_DATA_ENTRY_EXTENDED); dataSize = dataHeaderExtended->DataSize; variableSize = headerSize + dataSize; } header = data.mid(offset, headerSize); body = data.mid(offset + headerSize, dataSize); name = UString("Data"); info = usprintf("Full size: %Xh (%u)\nHeader size %Xh (%u)\nBody size: %Xh (%u)\nType: %02Xh\nChecksum: %02Xh", variableSize, variableSize, headerSize, headerSize, dataSize, dataSize, dataHeader->Header.Type, dataHeader->Header.Checksum) + (dataHeader->Header.Checksum != calculated ? usprintf(", invalid, should be %02Xh", calculated) : UString(", valid")) + usprintf("\nVarId: %04Xh\nGuidId: %04Xh\nAttributes: %08Xh (", dataHeader->VarId, dataHeader->GuidId, dataHeader->Attributes) + evsaAttributesToUString(dataHeader->Attributes) + UString(")"); subtype = Subtypes::DataEvsaEntry; } // Unknown entry or free space else { body = data.mid(offset); info = usprintf("Full size: %Xh (%u)", body.size(), body.size()); if (body.count(emptyByte) == body.size()) { // Free space // Add free space tree item model->addItem(localOffset + offset, Types::FreeSpace, 0, UString("Free space"), UString(), info, UByteArray(), body, UByteArray(), Fixed, index); } else { // Add padding tree item UModelIndex itemIndex = model->addItem(localOffset + offset, Types::Padding, getPaddingType(body), UString("Padding"), UString(), info, UByteArray(), body, UByteArray(), Fixed, index); // Show message msg(usprintf("%s: unknown variable of type %02Xh found at offset %Xh, the rest of unparsed store added as padding", __FUNCTION__, entryHeader->Type, offset), itemIndex); } break; } // Add tree item model->addItem(localOffset + offset, Types::EvsaEntry, subtype, name, UString(), info, header, body, UByteArray(), Fixed, index); // Move to next variable offset += variableSize; unparsedSize = storeDataSize - offset; } // Reparse all data variables to detect invalid ones and assign name and test to valid ones for (int i = 0; i < model->rowCount(index); i++) { UModelIndex current = index.child(i, 0); if (model->subtype(current) == Subtypes::DataEvsaEntry) { UByteArray header = model->header(current); const EVSA_DATA_ENTRY* dataHeader = (const EVSA_DATA_ENTRY*)header.constData(); UString guid; if (guidMap.count(dataHeader->GuidId)) guid = guidToUString(guidMap[dataHeader->GuidId], false); UString name; if (nameMap.count(dataHeader->VarId)) name = nameMap[dataHeader->VarId]; // Check for variable validity if (guid.isEmpty() && name.isEmpty()) { // Both name and guid aren't found model->setSubtype(current, Subtypes::InvalidEvsaEntry); model->setName(current, UString("Invalid")); msg(usprintf("%s: data variable with invalid GuidId and invalid VarId", __FUNCTION__), current); } else if (guid.isEmpty()) { // Guid not found model->setSubtype(current, Subtypes::InvalidEvsaEntry); model->setName(current, UString("Invalid")); msg(usprintf("%s: data variable with invalid GuidId", __FUNCTION__), current); } else if (name.isEmpty()) { // Name not found model->setSubtype(current, Subtypes::InvalidEvsaEntry); model->setName(current, UString("Invalid")); msg(usprintf("%s: data variable with invalid VarId", __FUNCTION__), current); } else { // Variable is OK, rename it if (dataHeader->Header.Type == NVRAM_EVSA_ENTRY_TYPE_DATA_INVALID) { model->setSubtype(current, Subtypes::InvalidEvsaEntry); model->setName(current, UString("Invalid")); } else { model->setName(current, guid); } model->setText(current, name); model->addInfo(current, UString("GUID: ") + guid + UString("\nName: ") + name + UString("\n"), false); } } } return U_SUCCESS; } USTATUS NvramParser::parseFlashMapBody(const UModelIndex & index) { // Sanity check if (!index.isValid()) return U_INVALID_PARAMETER; // Get parsing data for the current item UINT32 localOffset = model->header(index).size(); const UByteArray data = model->body(index); const UINT32 dataSize = (UINT32)data.size(); UINT32 offset = 0; UINT32 unparsedSize = dataSize; // Parse all entries while (unparsedSize) { const PHOENIX_FLASH_MAP_ENTRY* entryHeader = (const PHOENIX_FLASH_MAP_ENTRY*)(data.constData() + offset); // Check entry size if (unparsedSize < sizeof(PHOENIX_FLASH_MAP_ENTRY)) { // Last variable is bad, add the rest as padding and return UByteArray body = data.mid(offset); UString info = usprintf("Full size: %Xh (%u)", body.size(), body.size()); // Add padding tree item model->addItem(localOffset + offset, Types::Padding, getPaddingType(body), UString("Padding"), UString(), info, UByteArray(), body, UByteArray(), Fixed, index); // Show message if (unparsedSize < entryHeader->Size) msg(usprintf("%s: next entry appears too big, added as padding", __FUNCTION__), index); break; } UString name = guidToUString(entryHeader->Guid); // Construct header UByteArray header = data.mid(offset, sizeof(PHOENIX_FLASH_MAP_ENTRY)); // Add info UString info = UString("Entry GUID: ") + guidToUString(entryHeader->Guid, false) + usprintf("\nFull size: 24h (36)\nHeader size: 24h (36)\nBody size: 0h (0)\n" "Entry type: %04Xh\nData type: %04Xh\nMemory address: %08Xh\nSize: %08Xh\nOffset: %08Xh", entryHeader->EntryType, entryHeader->DataType, entryHeader->PhysicalAddress, entryHeader->Size, entryHeader->Offset); // Determine subtype UINT8 subtype = 0; switch (entryHeader->DataType) { case NVRAM_PHOENIX_FLASH_MAP_ENTRY_TYPE_VOLUME: subtype = Subtypes::VolumeFlashMapEntry; break; case NVRAM_PHOENIX_FLASH_MAP_ENTRY_TYPE_DATA_BLOCK: subtype = Subtypes::DataFlashMapEntry; break; } // Add tree item model->addItem(localOffset + offset, Types::FlashMapEntry, subtype, name, flashMapGuidToUString(entryHeader->Guid), info, header, UByteArray(), UByteArray(), Fixed, index); // Move to next variable offset += sizeof(PHOENIX_FLASH_MAP_ENTRY); unparsedSize = dataSize - offset; } return U_SUCCESS; } #endif // U_ENABLE_NVRAM_PARSING_SUPPORT