mirror of
https://github.com/LongSoft/UEFITool.git
synced 2024-11-25 17:38:22 +08:00
685 lines
33 KiB
C++
Executable File
685 lines
33 KiB
C++
Executable File
/* meparser.cpp
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Copyright (c) 2019, Nikolaj Schlej. All rights reserved.
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This program and the accompanying materials
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are licensed and made available under the terms and conditions of the BSD License
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which accompanies this distribution. The full text of the license may be found at
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http://opensource.org/licenses/bsd-license.php.
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THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
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WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.
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*/
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#include <map>
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#include "ffs.h"
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#include "me.h"
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#include "meparser.h"
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#include "parsingdata.h"
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#include "utility.h"
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#ifdef U_ENABLE_ME_PARSING_SUPPORT
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struct FPT_PARTITION_INFO {
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FPT_HEADER_ENTRY ptEntry;
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UINT8 type;
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UModelIndex index;
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friend bool operator< (const FPT_PARTITION_INFO & lhs, const FPT_PARTITION_INFO & rhs){ return lhs.ptEntry.Offset < rhs.ptEntry.Offset; }
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};
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struct IFWI_PARTITION_INFO {
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IFWI_HEADER_ENTRY ptEntry;
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UINT8 type;
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UINT8 subtype;
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friend bool operator< (const IFWI_PARTITION_INFO & lhs, const IFWI_PARTITION_INFO & rhs){ return lhs.ptEntry.Offset < rhs.ptEntry.Offset; }
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};
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USTATUS MeParser::parseMeRegionBody(const UModelIndex & index)
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{
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// Sanity check
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if (!index.isValid())
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return U_INVALID_PARAMETER;
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// Obtain ME region
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UByteArray meRegion = model->body(index);
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// Check region size
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if ((UINT32)meRegion.size() < ME_ROM_BYPASS_VECTOR_SIZE + sizeof(UINT32)) {
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msg(usprintf("%s: ME region too small to fit ROM bypass vector", __FUNCTION__), index);
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return U_INVALID_ME_PARTITION_TABLE;
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}
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// Check ME signature to determine it's version
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// ME v11 and older layout
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if (*(UINT32*)meRegion.constData() == FPT_HEADER_SIGNATURE || *(UINT32*)(meRegion.constData() + ME_ROM_BYPASS_VECTOR_SIZE) == FPT_HEADER_SIGNATURE) {
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UModelIndex ptIndex;
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return parseFptRegion(meRegion, index, ptIndex);
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}
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// IFWI 1.6
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// Check region size
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if ((UINT32)meRegion.size() < sizeof(IFWI_16_LAYOUT_HEADER)) {
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msg(usprintf("%s: ME region too small to fit IFWI 1.6 layout header", __FUNCTION__), index);
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return U_INVALID_ME_PARTITION_TABLE;
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}
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const IFWI_16_LAYOUT_HEADER* ifwi16Header = (const IFWI_16_LAYOUT_HEADER*)meRegion.constData();
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// Check region size
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if ((UINT32)meRegion.size() < ifwi16Header->DataPartition.Offset + sizeof(UINT32)) {
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msg(usprintf("%s: ME region too small to fit IFWI 1.6 data partition", __FUNCTION__), index);
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return U_INVALID_ME_PARTITION_TABLE;
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}
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// Data partition always points to FPT header
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if (*(UINT32*)(meRegion.constData() + ifwi16Header->DataPartition.Offset) == FPT_HEADER_SIGNATURE) {
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UModelIndex ptIndex;
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return parseIfwi16Region(meRegion, index, ptIndex);
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}
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// IFWI 1.7
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if ((UINT32)meRegion.size() < sizeof(IFWI_17_LAYOUT_HEADER)) {
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msg(usprintf("%s: ME region too small to fit IFWI 1.7 layout header", __FUNCTION__), index);
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return U_INVALID_ME_PARTITION_TABLE;
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}
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const IFWI_17_LAYOUT_HEADER* ifwi17Header = (const IFWI_17_LAYOUT_HEADER*)meRegion.constData();
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// Check region size
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if ((UINT32)meRegion.size() < ifwi17Header->DataPartition.Offset + sizeof(UINT32)) {
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msg(usprintf("%s: ME region too small to fit IFWI 1.7 data partition", __FUNCTION__), index);
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return U_INVALID_ME_PARTITION_TABLE;
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}
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// Data partition always points to FPT header
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if (*(UINT32*)(meRegion.constData() + ifwi17Header->DataPartition.Offset)== FPT_HEADER_SIGNATURE) {
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UModelIndex ptIndex;
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return parseIfwi17Region(meRegion, index, ptIndex);
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}
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// Something else entirely
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msg(usprintf("%s: unknown ME region format", __FUNCTION__), index);
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return U_INVALID_ME_PARTITION_TABLE;
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}
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USTATUS MeParser::parseFptRegion(const UByteArray & region, const UModelIndex & parent, UModelIndex & index)
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{
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// Check region size
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if ((UINT32)region.size() < sizeof(FPT_HEADER)) {
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msg(usprintf("%s: region too small to fit the FPT partition table header", __FUNCTION__), parent);
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return U_INVALID_ME_PARTITION_TABLE;
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}
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// Populate partition table header
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const FPT_HEADER* ptHeader = (const FPT_HEADER*)region.constData();
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UINT32 romBypassVectorSize = 0;
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if (*(UINT32*)region.constData() != FPT_HEADER_SIGNATURE) {
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// Adjust the header to skip ROM bypass vector
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romBypassVectorSize = ME_ROM_BYPASS_VECTOR_SIZE;
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ptHeader = (const FPT_HEADER*)(region.constData() + romBypassVectorSize);
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}
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// Check region size again
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UINT32 ptBodySize = ptHeader->NumEntries * sizeof(FPT_HEADER_ENTRY);
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UINT32 ptSize = romBypassVectorSize + sizeof(FPT_HEADER) + ptBodySize;
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if ((UINT32)region.size() < ptSize) {
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msg(usprintf("%s: ME region too small to fit the FPT partition table", __FUNCTION__), parent);
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return U_INVALID_ME_PARTITION_TABLE;
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}
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// Get info
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UByteArray header = region.left(romBypassVectorSize + sizeof(FPT_HEADER));
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UByteArray body = region.mid(header.size(), ptBodySize);
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UString name = UString("FPT partition table");
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UString info;
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// Special case of FPT header version 2.1
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if (ptHeader->HeaderVersion == FPT_HEADER_VERSION_21) {
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const FPT_HEADER_21* ptHeader21 = (const FPT_HEADER_21*)ptHeader;
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info = usprintf("Full size: %Xh (%u)\nHeader size: %Xh (%u)\nBody size: %Xh (%u)\nROM bypass vector: %s\nNumber of entries: %u\nHeader version: %02Xh\nEntry version: %02Xh\n"
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"Header length: %02Xh\nFlags: %Xh\nTicks to add: %04Xh\nTokens to add: %04Xh\nSPS Flags: %Xh\nFITC version: %u.%u.%u.%u\nCRC32 Checksum: %08Xh",
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ptSize, ptSize,
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(UINT32)header.size(), (UINT32)header.size(),
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ptBodySize, ptBodySize,
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(romBypassVectorSize ? "present" : "absent"),
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ptHeader21->NumEntries,
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ptHeader21->HeaderVersion,
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ptHeader21->EntryVersion,
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ptHeader21->HeaderLength,
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ptHeader21->Flags,
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ptHeader21->TicksToAdd,
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ptHeader21->TokensToAdd,
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ptHeader21->SPSFlags,
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ptHeader21->FitcMajor, ptHeader21->FitcMinor, ptHeader21->FitcHotfix, ptHeader21->FitcBuild,
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ptHeader21->HeaderCrc32);
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// TODO: verify header crc32
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}
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// Default handling for all other versions, may be too generic in some corner cases
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else {
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info = usprintf("Full size: %Xh (%u)\nHeader size: %Xh (%u)\nBody size: %Xh (%u)\nROM bypass vector: %s\nNumber of entries: %u\nHeader version: %02Xh\nEntry version: %02Xh\n"
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"Header length: %02Xh\nFlash cycle life: %04Xh\nFlash cycle limit: %04Xh\nUMA size: %Xh\nFlags: %Xh\nFITC version: %u.%u.%u.%u\nChecksum: %02Xh",
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ptSize, ptSize,
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(UINT32)header.size(), (UINT32)header.size(),
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ptBodySize, ptBodySize,
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(romBypassVectorSize ? "present" : "absent"),
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ptHeader->NumEntries,
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ptHeader->HeaderVersion,
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ptHeader->EntryVersion,
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ptHeader->HeaderLength,
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ptHeader->FlashCycleLife,
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ptHeader->FlashCycleLimit,
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ptHeader->UmaSize,
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ptHeader->Flags,
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ptHeader->FitcMajor, ptHeader->FitcMinor, ptHeader->FitcHotfix, ptHeader->FitcBuild,
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ptHeader->HeaderChecksum);
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// TODO: verify header checksum8
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}
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// Add tree item
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index = model->addItem(0, Types::FptStore, 0, name, UString(), info, header, body, UByteArray(), Fixed, parent);
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// Add partition table entries
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std::vector<FPT_PARTITION_INFO> partitions;
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UINT32 offset = (UINT32)header.size();
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UINT32 numEntries = ptHeader->NumEntries;
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const FPT_HEADER_ENTRY* firstPtEntry = (const FPT_HEADER_ENTRY*)(region.constData() + offset);
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for (UINT32 i = 0; i < numEntries; i++) {
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// Populate entry header
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const FPT_HEADER_ENTRY* ptEntry = firstPtEntry + i;
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// Get info
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name = visibleAsciiOrHex((UINT8*)ptEntry->Name, 4);
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info = usprintf("Full size: %Xh (%u)\nPartition offset: %Xh\nPartition length: %Xh\nPartition type: %02Xh",
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(UINT32)sizeof(FPT_HEADER_ENTRY), (UINT32)sizeof(FPT_HEADER_ENTRY),
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ptEntry->Offset,
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ptEntry->Size,
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ptEntry->Type);
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// Add tree item
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const UINT8 type = (ptEntry->Offset != 0 && ptEntry->Offset != 0xFFFFFFFF && ptEntry->Size != 0 && ptEntry->EntryValid != 0xFF) ? Subtypes::ValidFptEntry : Subtypes::InvalidFptEntry;
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UModelIndex entryIndex = model->addItem(offset, Types::FptEntry, type, name, UString(), info, UByteArray(), UByteArray((const char*)ptEntry, sizeof(FPT_HEADER_ENTRY)), UByteArray(), Fixed, index);
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// Adjust offset
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offset += sizeof(FPT_HEADER_ENTRY);
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// Add valid partitions
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if (type == Subtypes::ValidFptEntry) { // Skip absent and invalid partitions
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// Add to partitions vector
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FPT_PARTITION_INFO partition = {};
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partition.type = Types::FptPartition;
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partition.ptEntry = *ptEntry;
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partition.index = entryIndex;
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partitions.push_back(partition);
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}
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}
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// Check for empty set of partitions
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if (partitions.empty()) {
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// Add a single padding partition in this case
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FPT_PARTITION_INFO padding = {};
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padding.ptEntry.Offset = offset;
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padding.ptEntry.Size = (UINT32)(region.size() - padding.ptEntry.Offset);
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padding.type = Types::Padding;
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partitions.push_back(padding);
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}
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make_partition_table_consistent:
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// Sort partitions by offset
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std::sort(partitions.begin(), partitions.end());
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// Check for intersections and paddings between partitions
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FPT_PARTITION_INFO padding = {};
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// Check intersection with the partition table header
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if (partitions.front().ptEntry.Offset < ptSize) {
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msg(usprintf("%s: ME partition has intersection with ME partition table, skipped", __FUNCTION__),
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partitions.front().index);
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partitions.erase(partitions.begin());
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goto make_partition_table_consistent;
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}
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// Check for padding between partition table and the first partition
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else if (partitions.front().ptEntry.Offset > ptSize) {
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padding.ptEntry.Offset = ptSize;
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padding.ptEntry.Size = partitions.front().ptEntry.Offset - ptSize;
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padding.type = Types::Padding;
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partitions.insert(partitions.begin(), padding);
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}
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// Check for intersections/paddings between partitions
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for (size_t i = 1; i < partitions.size(); i++) {
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UINT32 previousPartitionEnd = partitions[i - 1].ptEntry.Offset + partitions[i - 1].ptEntry.Size;
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// Check that current region is fully present in the image
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if ((UINT32)partitions[i].ptEntry.Offset + (UINT32)partitions[i].ptEntry.Size > (UINT32)region.size()) {
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if ((UINT32)partitions[i].ptEntry.Offset >= (UINT32)region.size()) {
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msg(usprintf("%s: FPT partition is located outside of the opened image, skipped", __FUNCTION__), partitions[i].index);
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partitions.erase(partitions.begin() + i);
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goto make_partition_table_consistent;
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}
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else {
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msg(usprintf("%s: FPT partition can't fit into the region, truncated", __FUNCTION__), partitions[i].index);
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partitions[i].ptEntry.Size = (UINT32)region.size() - (UINT32)partitions[i].ptEntry.Offset;
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}
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}
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// Check for intersection with previous partition
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if (partitions[i].ptEntry.Offset < previousPartitionEnd) {
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// Check if current partition is located inside previous one
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if (partitions[i].ptEntry.Offset + partitions[i].ptEntry.Size <= previousPartitionEnd) {
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msg(usprintf("%s: FPT partition is located inside another FPT partition, skipped", __FUNCTION__),
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partitions[i].index);
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partitions.erase(partitions.begin() + i);
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goto make_partition_table_consistent;
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}
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else {
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msg(usprintf("%s: FPT partition intersects with previous one, skipped", __FUNCTION__),
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partitions[i].index);
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partitions.erase(partitions.begin() + i);
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goto make_partition_table_consistent;
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}
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}
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// Check for padding between current and previous partitions
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else if (partitions[i].ptEntry.Offset > previousPartitionEnd) {
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padding.ptEntry.Offset = previousPartitionEnd;
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padding.ptEntry.Size = partitions[i].ptEntry.Offset - previousPartitionEnd;
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padding.type = Types::Padding;
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std::vector<FPT_PARTITION_INFO>::iterator iter = partitions.begin();
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std::advance(iter, i);
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partitions.insert(iter, padding);
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}
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}
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// Check for padding after the last region
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if ((UINT32)partitions.back().ptEntry.Offset + (UINT32)partitions.back().ptEntry.Size < (UINT32)region.size()) {
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padding.ptEntry.Offset = partitions.back().ptEntry.Offset + partitions.back().ptEntry.Size;
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padding.ptEntry.Size = (UINT32)(region.size() - padding.ptEntry.Offset);
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padding.type = Types::Padding;
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partitions.push_back(padding);
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}
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// Partition map is consistent
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for (size_t i = 0; i < partitions.size(); i++) {
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UByteArray partition = region.mid(partitions[i].ptEntry.Offset, partitions[i].ptEntry.Size);
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if (partitions[i].type == Types::FptPartition) {
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UModelIndex partitionIndex;
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// Get info
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name = visibleAsciiOrHex((UINT8*) partitions[i].ptEntry.Name, 4);
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info = usprintf("Full size: %Xh (%u)\nPartition type: %02Xh\n",
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(UINT32)partition.size(), (UINT32)partition.size(),
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partitions[i].ptEntry.Type);
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// Add tree item
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UINT8 type = Subtypes::CodeFptPartition + partitions[i].ptEntry.Type;
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partitionIndex = model->addItem(partitions[i].ptEntry.Offset, Types::FptPartition, type, name, UString(), info, UByteArray(), partition, UByteArray(), Fixed, parent);
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if (type == Subtypes::CodeFptPartition && partition.size() >= (int) sizeof(UINT32) && readUnaligned((const UINT32*)partition.constData()) == CPD_SIGNATURE) {
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// Parse code partition contents
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UModelIndex cpdIndex;
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ffsParser->parseCpdRegion(partition, partitions[i].ptEntry.Offset, partitionIndex, cpdIndex);
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}
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}
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else if (partitions[i].type == Types::Padding) {
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// Get info
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name = UString("Padding");
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info = usprintf("Full size: %Xh (%u)", (UINT32)partition.size(), (UINT32)partition.size());
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// Add tree item
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model->addItem(partitions[i].ptEntry.Offset, Types::Padding, getPaddingType(partition), name, UString(), info, UByteArray(), partition, UByteArray(), Fixed, parent);
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}
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}
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return U_SUCCESS;
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}
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USTATUS MeParser::parseIfwi16Region(const UByteArray & region, const UModelIndex & parent, UModelIndex & index)
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{
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// Check region size again
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if ((UINT32)region.size() < sizeof(IFWI_16_LAYOUT_HEADER)) {
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msg(usprintf("%s: ME region too small to fit IFWI 1.6 layout header", __FUNCTION__), parent);
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return U_INVALID_ME_PARTITION_TABLE;
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}
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const IFWI_16_LAYOUT_HEADER* ifwiHeader = (const IFWI_16_LAYOUT_HEADER*)region.constData();
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// Add header
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UINT32 ptSize = sizeof(IFWI_16_LAYOUT_HEADER);
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UByteArray header = region.left(ptSize);
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UString name = UString("IFWI 1.6 header");
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UString info = usprintf("Full size: %Xh (%u)\n"
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"Data partition offset: %Xh\nData partition size: %Xh\n"
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"Boot1 partition offset: %Xh\nBoot1 partition size: %Xh\n"
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"Boot2 partition offset: %Xh\nBoot2 partition size: %Xh\n"
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"Boot3 partition offset: %Xh\nBoot3 partition size: %Xh\n"
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"Boot4 partition offset: %Xh\nBoot4 partition size: %Xh\n"
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"Boot5 partition offset: %Xh\nBoot5 partition size: %Xh\n"
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"Checksum: %" PRIX64 "h",
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(UINT32)header.size(), (UINT32)header.size(),
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ifwiHeader->DataPartition.Offset, ifwiHeader->DataPartition.Size,
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ifwiHeader->BootPartition[0].Offset, ifwiHeader->BootPartition[0].Size,
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ifwiHeader->BootPartition[1].Offset, ifwiHeader->BootPartition[1].Size,
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ifwiHeader->BootPartition[2].Offset, ifwiHeader->BootPartition[2].Size,
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ifwiHeader->BootPartition[3].Offset, ifwiHeader->BootPartition[3].Size,
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ifwiHeader->BootPartition[4].Offset, ifwiHeader->BootPartition[4].Size,
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ifwiHeader->Checksum);
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// Add tree item
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index = model->addItem(0, Types::IfwiHeader, 0, name, UString(), info, UByteArray(), header, UByteArray(), Fixed, parent);
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std::vector<IFWI_PARTITION_INFO> partitions;
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// Add data partition
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{
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IFWI_PARTITION_INFO partition = {};
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partition.type = Types::IfwiPartition;
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partition.subtype = Subtypes::DataIfwiPartition;
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partition.ptEntry = ifwiHeader->DataPartition;
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partitions.push_back(partition);
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}
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// Add boot partitions
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for (UINT8 i = 0 ; i < 4; i++) {
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if (ifwiHeader->BootPartition[i].Offset != 0 && ifwiHeader->BootPartition[i].Offset != 0xFFFFFFFF) {
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IFWI_PARTITION_INFO partition = {};
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partition.type = Types::IfwiPartition;
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partition.subtype = Subtypes::BootIfwiPartition;
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partition.ptEntry = ifwiHeader->BootPartition[i];
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partitions.push_back(partition);
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}
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}
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make_partition_table_consistent:
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// Sort partitions by offset
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std::sort(partitions.begin(), partitions.end());
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// Check for intersections and paddings between partitions
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IFWI_PARTITION_INFO padding = {};
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// Check intersection with the partition table header
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if (partitions.front().ptEntry.Offset < ptSize) {
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msg(usprintf("%s: IFWI partition has intersection with IFWI layout header, skipped", __FUNCTION__), index);
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partitions.erase(partitions.begin());
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goto make_partition_table_consistent;
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}
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// Check for padding between partition table and the first partition
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else if (partitions.front().ptEntry.Offset > ptSize) {
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padding.ptEntry.Offset = ptSize;
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padding.ptEntry.Size = partitions.front().ptEntry.Offset - ptSize;
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padding.type = Types::Padding;
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partitions.insert(partitions.begin(), padding);
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}
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// Check for intersections/paddings between partitions
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for (size_t i = 1; i < partitions.size(); i++) {
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UINT32 previousPartitionEnd = partitions[i - 1].ptEntry.Offset + partitions[i - 1].ptEntry.Size;
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// Check that current region is fully present in the image
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if ((UINT32)partitions[i].ptEntry.Offset + (UINT32)partitions[i].ptEntry.Size > (UINT32)region.size()) {
|
|
if ((UINT32)partitions[i].ptEntry.Offset >= (UINT32)region.size()) {
|
|
msg(usprintf("%s: IFWI partition is located outside of the opened image, skipped", __FUNCTION__), index);
|
|
partitions.erase(partitions.begin() + i);
|
|
goto make_partition_table_consistent;
|
|
}
|
|
else {
|
|
msg(usprintf("%s: IFWI partition can't fit into the region, truncated", __FUNCTION__), index);
|
|
partitions[i].ptEntry.Size = (UINT32)region.size() - (UINT32)partitions[i].ptEntry.Offset;
|
|
}
|
|
}
|
|
|
|
// Check for intersection with previous partition
|
|
if (partitions[i].ptEntry.Offset < previousPartitionEnd) {
|
|
// Check if current partition is located inside previous one
|
|
if (partitions[i].ptEntry.Offset + partitions[i].ptEntry.Size <= previousPartitionEnd) {
|
|
msg(usprintf("%s: IFWI partition is located inside another IFWI partition, skipped", __FUNCTION__), index);
|
|
partitions.erase(partitions.begin() + i);
|
|
goto make_partition_table_consistent;
|
|
}
|
|
else {
|
|
msg(usprintf("%s: IFWI partition intersects with previous one, skipped", __FUNCTION__), index);
|
|
partitions.erase(partitions.begin() + i);
|
|
goto make_partition_table_consistent;
|
|
}
|
|
}
|
|
|
|
// Check for padding between current and previous partitions
|
|
else if (partitions[i].ptEntry.Offset > previousPartitionEnd) {
|
|
padding.ptEntry.Offset = previousPartitionEnd;
|
|
padding.ptEntry.Size = partitions[i].ptEntry.Offset - previousPartitionEnd;
|
|
padding.type = Types::Padding;
|
|
std::vector<IFWI_PARTITION_INFO>::iterator iter = partitions.begin();
|
|
std::advance(iter, i);
|
|
partitions.insert(iter, padding);
|
|
}
|
|
}
|
|
// Check for padding after the last region
|
|
if ((UINT32)partitions.back().ptEntry.Offset + (UINT32)partitions.back().ptEntry.Size < (UINT32)region.size()) {
|
|
padding.ptEntry.Offset = partitions.back().ptEntry.Offset + partitions.back().ptEntry.Size;
|
|
padding.ptEntry.Size = (UINT32)(region.size() - padding.ptEntry.Offset);
|
|
padding.type = Types::Padding;
|
|
partitions.push_back(padding);
|
|
}
|
|
|
|
// Partition map is consistent
|
|
for (size_t i = 0; i < partitions.size(); i++) {
|
|
UByteArray partition = region.mid(partitions[i].ptEntry.Offset, partitions[i].ptEntry.Size);
|
|
if (partitions[i].type == Types::IfwiPartition) {
|
|
UModelIndex partitionIndex;
|
|
if (partitions[i].subtype == Subtypes::DataIfwiPartition) {
|
|
name = "Data partition";
|
|
}
|
|
else if (partitions[i].subtype == Subtypes::BootIfwiPartition) {
|
|
name = "Boot partition";
|
|
}
|
|
|
|
// Get info
|
|
info = usprintf("Full size: %Xh (%u)\n", (UINT32)partition.size(), (UINT32)partition.size());
|
|
|
|
// Add tree item
|
|
partitionIndex = model->addItem(partitions[i].ptEntry.Offset, partitions[i].type, partitions[i].subtype, name, UString(), info, UByteArray(), partition, UByteArray(), Fixed, parent);
|
|
|
|
// Parse partition further
|
|
if (partitions[i].subtype == Subtypes::DataIfwiPartition) {
|
|
UModelIndex dataPartitionFptRegionIndex;
|
|
parseFptRegion(partition, partitionIndex, dataPartitionFptRegionIndex);
|
|
}
|
|
else if (partitions[i].subtype == Subtypes::BootIfwiPartition) {
|
|
// Parse code partition contents
|
|
UModelIndex bootPartitionBpdtRegionIndex;
|
|
ffsParser->parseBpdtRegion(partition, 0, 0, partitionIndex, bootPartitionBpdtRegionIndex);
|
|
}
|
|
}
|
|
else if (partitions[i].type == Types::Padding) {
|
|
// Get info
|
|
name = UString("Padding");
|
|
info = usprintf("Full size: %Xh (%u)", (UINT32)partition.size(), (UINT32)partition.size());
|
|
|
|
// Add tree item
|
|
model->addItem(partitions[i].ptEntry.Offset, Types::Padding, getPaddingType(partition), name, UString(), info, UByteArray(), partition, UByteArray(), Fixed, parent);
|
|
}
|
|
}
|
|
|
|
return U_SUCCESS;
|
|
}
|
|
|
|
USTATUS MeParser::parseIfwi17Region(const UByteArray & region, const UModelIndex & parent, UModelIndex & index)
|
|
{
|
|
// Check region size again
|
|
if ((UINT32)region.size() < sizeof(IFWI_17_LAYOUT_HEADER)) {
|
|
msg(usprintf("%s: ME region too small to fit IFWI 1.7 layout header", __FUNCTION__), parent);
|
|
return U_INVALID_ME_PARTITION_TABLE;
|
|
}
|
|
|
|
const IFWI_17_LAYOUT_HEADER* ifwiHeader = (const IFWI_17_LAYOUT_HEADER*)region.constData();
|
|
// TODO: add check for HeaderSize to be 0x40
|
|
|
|
// Add header
|
|
UINT32 ptSize = sizeof(IFWI_17_LAYOUT_HEADER);
|
|
UByteArray header = region.left(ptSize);
|
|
|
|
UString name = UString("IFWI 1.7 header");
|
|
UString info = usprintf("Full size: %Xh (%u)\n"
|
|
"Flags: %02Xh\n"
|
|
"Reserved: %02Xh\n"
|
|
"Checksum: %Xh\n"
|
|
"Data partition offset: %Xh\nData partition size: %Xh\n"
|
|
"Boot1 partition offset: %Xh\nBoot1 partition size: %Xh\n"
|
|
"Boot2 partition offset: %Xh\nBoot2 partition size: %Xh\n"
|
|
"Boot3 partition offset: %Xh\nBoot3 partition size: %Xh\n"
|
|
"Boot4 partition offset: %Xh\nBoot4 partition size: %Xh\n"
|
|
"Boot5 partition offset: %Xh\nBoot5 partition size: %Xh\n"
|
|
"Temp page offset: %Xh\nTemp page size: %Xh\n",
|
|
(UINT32)header.size(), (UINT32)header.size(),
|
|
ifwiHeader->Flags,
|
|
ifwiHeader->Reserved,
|
|
ifwiHeader->Checksum,
|
|
ifwiHeader->DataPartition.Offset, ifwiHeader->DataPartition.Size,
|
|
ifwiHeader->BootPartition[0].Offset, ifwiHeader->BootPartition[0].Size,
|
|
ifwiHeader->BootPartition[1].Offset, ifwiHeader->BootPartition[1].Size,
|
|
ifwiHeader->BootPartition[2].Offset, ifwiHeader->BootPartition[2].Size,
|
|
ifwiHeader->BootPartition[3].Offset, ifwiHeader->BootPartition[3].Size,
|
|
ifwiHeader->BootPartition[4].Offset, ifwiHeader->BootPartition[4].Size,
|
|
ifwiHeader->TempPage.Offset, ifwiHeader->TempPage.Size);
|
|
// Add tree item
|
|
index = model->addItem(0, Types::IfwiHeader, 0, name, UString(), info, UByteArray(), header, UByteArray(), Fixed, parent);
|
|
|
|
std::vector<IFWI_PARTITION_INFO> partitions;
|
|
// Add data partition
|
|
{
|
|
IFWI_PARTITION_INFO partition = {};
|
|
partition.type = Types::IfwiPartition;
|
|
partition.subtype = Subtypes::DataIfwiPartition;
|
|
partition.ptEntry = ifwiHeader->DataPartition;
|
|
partitions.push_back(partition);
|
|
}
|
|
// Add boot partitions
|
|
for (UINT8 i = 0 ; i < 4; i++) {
|
|
if (ifwiHeader->BootPartition[i].Offset != 0 && ifwiHeader->BootPartition[i].Offset != 0xFFFFFFFF) {
|
|
IFWI_PARTITION_INFO partition = {};
|
|
partition.type = Types::IfwiPartition;
|
|
partition.subtype = Subtypes::BootIfwiPartition;
|
|
partition.ptEntry = ifwiHeader->BootPartition[i];
|
|
partitions.push_back(partition);
|
|
}
|
|
}
|
|
// Add temp page
|
|
if (ifwiHeader->TempPage.Offset != 0 && ifwiHeader->TempPage.Offset != 0xFFFFFFFF) {
|
|
IFWI_PARTITION_INFO partition = {};
|
|
partition.type = Types::IfwiPartition;
|
|
partition.subtype = Subtypes::DataPadding;
|
|
partition.ptEntry = ifwiHeader->TempPage;
|
|
partitions.push_back(partition);
|
|
}
|
|
|
|
make_partition_table_consistent:
|
|
// Sort partitions by offset
|
|
std::sort(partitions.begin(), partitions.end());
|
|
|
|
// Check for intersections and paddings between partitions
|
|
IFWI_PARTITION_INFO padding = {};
|
|
|
|
// Check intersection with the partition table header
|
|
if (partitions.front().ptEntry.Offset < ptSize) {
|
|
msg(usprintf("%s: IFWI partition has intersection with IFWI layout header, skipped", __FUNCTION__), index);
|
|
partitions.erase(partitions.begin());
|
|
goto make_partition_table_consistent;
|
|
}
|
|
// Check for padding between partition table and the first partition
|
|
else if (partitions.front().ptEntry.Offset > ptSize) {
|
|
padding.ptEntry.Offset = ptSize;
|
|
padding.ptEntry.Size = partitions.front().ptEntry.Offset - ptSize;
|
|
padding.type = Types::Padding;
|
|
partitions.insert(partitions.begin(), padding);
|
|
}
|
|
// Check for intersections/paddings between partitions
|
|
for (size_t i = 1; i < partitions.size(); i++) {
|
|
UINT32 previousPartitionEnd = partitions[i - 1].ptEntry.Offset + partitions[i - 1].ptEntry.Size;
|
|
|
|
// Check that current region is fully present in the image
|
|
if ((UINT32)partitions[i].ptEntry.Offset + (UINT32)partitions[i].ptEntry.Size > (UINT32)region.size()) {
|
|
if ((UINT32)partitions[i].ptEntry.Offset >= (UINT32)region.size()) {
|
|
msg(usprintf("%s: IFWI partition is located outside of the opened image, skipped", __FUNCTION__), index);
|
|
partitions.erase(partitions.begin() + i);
|
|
goto make_partition_table_consistent;
|
|
}
|
|
else {
|
|
msg(usprintf("%s: IFWI partition can't fit into the region, truncated", __FUNCTION__), index);
|
|
partitions[i].ptEntry.Size = (UINT32)region.size() - (UINT32)partitions[i].ptEntry.Offset;
|
|
}
|
|
}
|
|
|
|
// Check for intersection with previous partition
|
|
if (partitions[i].ptEntry.Offset < previousPartitionEnd) {
|
|
// Check if current partition is located inside previous one
|
|
if (partitions[i].ptEntry.Offset + partitions[i].ptEntry.Size <= previousPartitionEnd) {
|
|
msg(usprintf("%s: IFWI partition is located inside another IFWI partition, skipped", __FUNCTION__), index);
|
|
partitions.erase(partitions.begin() + i);
|
|
goto make_partition_table_consistent;
|
|
}
|
|
else {
|
|
msg(usprintf("%s: IFWI partition intersects with previous one, skipped", __FUNCTION__), index);
|
|
partitions.erase(partitions.begin() + i);
|
|
goto make_partition_table_consistent;
|
|
}
|
|
}
|
|
|
|
// Check for padding between current and previous partitions
|
|
else if (partitions[i].ptEntry.Offset > previousPartitionEnd) {
|
|
padding.ptEntry.Offset = previousPartitionEnd;
|
|
padding.ptEntry.Size = partitions[i].ptEntry.Offset - previousPartitionEnd;
|
|
padding.type = Types::Padding;
|
|
std::vector<IFWI_PARTITION_INFO>::iterator iter = partitions.begin();
|
|
std::advance(iter, i);
|
|
partitions.insert(iter, padding);
|
|
}
|
|
}
|
|
// Check for padding after the last region
|
|
if ((UINT32)partitions.back().ptEntry.Offset + (UINT32)partitions.back().ptEntry.Size < (UINT32)region.size()) {
|
|
padding.ptEntry.Offset = partitions.back().ptEntry.Offset + partitions.back().ptEntry.Size;
|
|
padding.ptEntry.Size = (UINT32)(region.size() - padding.ptEntry.Offset);
|
|
padding.type = Types::Padding;
|
|
partitions.push_back(padding);
|
|
}
|
|
|
|
// Partition map is consistent
|
|
for (size_t i = 0; i < partitions.size(); i++) {
|
|
UByteArray partition = region.mid(partitions[i].ptEntry.Offset, partitions[i].ptEntry.Size);
|
|
if (partitions[i].type == Types::IfwiPartition) {
|
|
UModelIndex partitionIndex;
|
|
if (partitions[i].subtype == Subtypes::DataIfwiPartition) {
|
|
name = "Data partition";
|
|
|
|
}
|
|
else if (partitions[i].subtype == Subtypes::BootIfwiPartition){
|
|
name = "Boot partition";
|
|
}
|
|
else {
|
|
name = "Temp page";
|
|
}
|
|
|
|
// Get info
|
|
info = usprintf("Full size: %Xh (%u)\n", (UINT32)partition.size(), (UINT32)partition.size());
|
|
|
|
// Add tree item
|
|
partitionIndex = model->addItem(partitions[i].ptEntry.Offset, partitions[i].type, partitions[i].subtype, name, UString(), info, UByteArray(), partition, UByteArray(), Fixed, parent);
|
|
|
|
// Parse partition further
|
|
if (partitions[i].subtype == Subtypes::DataIfwiPartition) {
|
|
UModelIndex dataPartitionFptRegionIndex;
|
|
parseFptRegion(partition, partitionIndex, dataPartitionFptRegionIndex);
|
|
}
|
|
else if (partitions[i].subtype == Subtypes::BootIfwiPartition) {
|
|
// Parse code partition contents
|
|
UModelIndex bootPartitionBpdtRegionIndex;
|
|
ffsParser->parseBpdtRegion(partition, 0, 0, partitionIndex, bootPartitionBpdtRegionIndex);
|
|
}
|
|
}
|
|
else if (partitions[i].type == Types::Padding) {
|
|
// Get info
|
|
name = UString("Padding");
|
|
info = usprintf("Full size: %Xh (%u)", (UINT32)partition.size(), (UINT32)partition.size());
|
|
|
|
// Add tree item
|
|
model->addItem(partitions[i].ptEntry.Offset, Types::Padding, getPaddingType(partition), name, UString(), info, UByteArray(), partition, UByteArray(), Fixed, parent);
|
|
}
|
|
}
|
|
|
|
return U_SUCCESS;
|
|
}
|
|
|
|
#endif // U_ENABLE_ME_PARSING_SUPPORT
|
|
|