// Archive/ChmIn.cpp #include "StdAfx.h" #include "Common/IntToString.h" #include "Common/UTFConvert.h" #include "../../Common/LimitedStreams.h" #include "ChmIn.h" namespace NArchive { namespace NChm { // define CHM_LOW, if you want to see low level items // #define CHM_LOW static const GUID kChmLzxGuid = { 0x7FC28940, 0x9D31, 0x11D0, { 0x9B, 0x27, 0x00, 0xA0, 0xC9, 0x1E, 0x9C, 0x7C } }; static const GUID kHelp2LzxGuid = { 0x0A9007C6, 0x4076, 0x11D3, { 0x87, 0x89, 0x00, 0x00, 0xF8, 0x10, 0x57, 0x54 } }; static const GUID kDesGuid = { 0x67F6E4A2, 0x60BF, 0x11D3, { 0x85, 0x40, 0x00, 0xC0, 0x4F, 0x58, 0xC3, 0xCF } }; static bool AreGuidsEqual(REFGUID g1, REFGUID g2) { if (g1.Data1 != g2.Data1 || g1.Data2 != g2.Data2 || g1.Data3 != g2.Data3) return false; for (int i = 0; i < 8; i++) if (g1.Data4[i] != g2.Data4[i]) return false; return true; } static char GetHex(Byte value) { return (char)((value < 10) ? ('0' + value) : ('A' + (value - 10))); } static void PrintByte(Byte b, AString &s) { s += GetHex(b >> 4); s += GetHex(b & 0xF); } static void PrintUInt16(UInt16 v, AString &s) { PrintByte((Byte)(v >> 8), s); PrintByte((Byte)v, s); } static void PrintUInt32(UInt32 v, AString &s) { PrintUInt16((UInt16)(v >> 16), s); PrintUInt16((UInt16)v, s); } AString CMethodInfo::GetGuidString() const { AString s; s += '{'; PrintUInt32(Guid.Data1, s); s += '-'; PrintUInt16(Guid.Data2, s); s += '-'; PrintUInt16(Guid.Data3, s); s += '-'; PrintByte(Guid.Data4[0], s); PrintByte(Guid.Data4[1], s); s += '-'; for (int i = 2; i < 8; i++) PrintByte(Guid.Data4[i], s); s += '}'; return s; } bool CMethodInfo::IsLzx() const { if (AreGuidsEqual(Guid, kChmLzxGuid)) return true; return AreGuidsEqual(Guid, kHelp2LzxGuid); } bool CMethodInfo::IsDes() const { return AreGuidsEqual(Guid, kDesGuid); } UString CMethodInfo::GetName() const { UString s; if (IsLzx()) { s = L"LZX:"; wchar_t temp[16]; ConvertUInt32ToString(LzxInfo.GetNumDictBits(), temp); s += temp; } else { AString s2; if (IsDes()) s2 = "DES"; else { s2 = GetGuidString(); if (ControlData.GetCapacity() > 0) { s2 += ':'; for (size_t i = 0; i < ControlData.GetCapacity(); i++) PrintByte(ControlData[i], s2); } } ConvertUTF8ToUnicode(s2, s); } return s; } bool CSectionInfo::IsLzx() const { if (Methods.Size() != 1) return false; return Methods[0].IsLzx(); } UString CSectionInfo::GetMethodName() const { UString s; if (!IsLzx()) { UString temp; if (ConvertUTF8ToUnicode(Name, temp)) s += temp; s += L": "; } for (int i = 0; i < Methods.Size(); i++) { if (i != 0) s += L' '; s += Methods[i].GetName(); } return s; } Byte CInArchive::ReadByte() { Byte b; if (!_inBuffer.ReadByte(b)) throw 1; return b; } void CInArchive::Skip(size_t size) { while (size-- != 0) ReadByte(); } void CInArchive::ReadBytes(Byte *data, UInt32 size) { for (UInt32 i = 0; i < size; i++) data[i] = ReadByte(); } UInt16 CInArchive::ReadUInt16() { UInt16 value = 0; for (int i = 0; i < 2; i++) value |= ((UInt16)(ReadByte()) << (8 * i)); return value; } UInt32 CInArchive::ReadUInt32() { UInt32 value = 0; for (int i = 0; i < 4; i++) value |= ((UInt32)(ReadByte()) << (8 * i)); return value; } UInt64 CInArchive::ReadUInt64() { UInt64 value = 0; for (int i = 0; i < 8; i++) value |= ((UInt64)(ReadByte()) << (8 * i)); return value; } UInt64 CInArchive::ReadEncInt() { UInt64 val = 0;; for (int i = 0; i < 10; i++) { Byte b = ReadByte(); val |= (b & 0x7F); if (b < 0x80) return val; val <<= 7; } throw 1; } void CInArchive::ReadGUID(GUID &g) { g.Data1 = ReadUInt32(); g.Data2 = ReadUInt16(); g.Data3 = ReadUInt16(); ReadBytes(g.Data4, 8); } void CInArchive::ReadString(int size, AString &s) { s.Empty(); while(size-- != 0) { char c = (char)ReadByte(); if (c == 0) { Skip(size); return; } s += c; } } void CInArchive::ReadUString(int size, UString &s) { s.Empty(); while(size-- != 0) { wchar_t c = ReadUInt16(); if (c == 0) { Skip(2 * size); return; } s += c; } } HRESULT CInArchive::ReadChunk(IInStream *inStream, UInt64 pos, UInt64 size) { RINOK(inStream->Seek(pos, STREAM_SEEK_SET, NULL)); CLimitedSequentialInStream *streamSpec = new CLimitedSequentialInStream; CMyComPtr limitedStream(streamSpec); streamSpec->SetStream(inStream); streamSpec->Init(size); _inBuffer.SetStream(limitedStream); _inBuffer.Init(); return S_OK; } HRESULT CInArchive::ReadDirEntry(CDatabase &database) { CItem item; UInt64 nameLength = ReadEncInt(); if (nameLength == 0 || nameLength >= 0x10000000) return S_FALSE; ReadString((int)nameLength, item.Name); item.Section = ReadEncInt(); item.Offset = ReadEncInt(); item.Size = ReadEncInt(); database.Items.Add(item); return S_OK; } HRESULT CInArchive::OpenChm(IInStream *inStream, CDatabase &database) { UInt32 headerSize = ReadUInt32(); if (headerSize != 0x60) return S_FALSE; UInt32 unknown1 = ReadUInt32(); if (unknown1 != 0 && unknown1 != 1) // it's 0 in one .sll file return S_FALSE; /* UInt32 timeStamp = */ ReadUInt32(); // Considered as a big-endian DWORD, it appears to contain seconds (MSB) and // fractional seconds (second byte). // The third and fourth bytes may contain even more fractional bits. // The 4 least significant bits in the last byte are constant. /* UInt32 lang = */ ReadUInt32(); GUID g; ReadGUID(g); // {7C01FD10-7BAA-11D0-9E0C-00A0-C922-E6EC} ReadGUID(g); // {7C01FD11-7BAA-11D0-9E0C-00A0-C922-E6EC} const int kNumSections = 2; UInt64 sectionOffsets[kNumSections]; UInt64 sectionSizes[kNumSections]; int i; for (i = 0; i < kNumSections; i++) { sectionOffsets[i] = ReadUInt64(); sectionSizes[i] = ReadUInt64(); } // if (chmVersion == 3) database.ContentOffset = ReadUInt64(); /* else database.ContentOffset = _startPosition + 0x58 */ /* // Section 0 ReadChunk(inStream, sectionOffsets[0], sectionSizes[0]); if (sectionSizes[0] != 0x18) return S_FALSE; ReadUInt32(); // unknown: 01FE ReadUInt32(); // unknown: 0 UInt64 fileSize = ReadUInt64(); ReadUInt32(); // unknown: 0 ReadUInt32(); // unknown: 0 */ // Section 1: The Directory Listing ReadChunk(inStream, sectionOffsets[1], sectionSizes[1]); if (ReadUInt32() != NHeader::kItspSignature) return S_FALSE; if (ReadUInt32() != 1) // version return S_FALSE; /* UInt32 dirHeaderSize = */ ReadUInt32(); ReadUInt32(); // 0x0A (unknown) UInt32 dirChunkSize = ReadUInt32(); // $1000 if (dirChunkSize < 32) return S_FALSE; /* UInt32 density = */ ReadUInt32(); // "Density" of quickref section, usually 2. /* UInt32 depth = */ ReadUInt32(); // Depth of the index tree: 1 there is no index, // 2 if there is one level of PMGI chunks. /* UInt32 chunkNumber = */ ReadUInt32(); // Chunk number of root index chunk, -1 if there is none // (though at least one file has 0 despite there being no // index chunk, probably a bug.) /* UInt32 firstPmglChunkNumber = */ ReadUInt32(); // Chunk number of first PMGL (listing) chunk /* UInt32 lastPmglChunkNumber = */ ReadUInt32(); // Chunk number of last PMGL (listing) chunk ReadUInt32(); // -1 (unknown) UInt32 numDirChunks = ReadUInt32(); // Number of directory chunks (total) /* UInt32 windowsLangId = */ ReadUInt32(); ReadGUID(g); // {5D02926A-212E-11D0-9DF9-00A0C922E6EC} ReadUInt32(); // 0x54 (This is the length again) ReadUInt32(); // -1 (unknown) ReadUInt32(); // -1 (unknown) ReadUInt32(); // -1 (unknown) for (UInt32 ci = 0; ci < numDirChunks; ci++) { UInt64 chunkPos = _inBuffer.GetProcessedSize(); if (ReadUInt32() == NHeader::kPmglSignature) { // The quickref area is written backwards from the end of the chunk. // One quickref entry exists for every n entries in the file, where n // is calculated as 1 + (1 << quickref density). So for density = 2, n = 5. UInt32 quickrefLength = ReadUInt32(); // Length of free space and/or quickref area at end of directory chunk if (quickrefLength > dirChunkSize || quickrefLength < 2) return S_FALSE; ReadUInt32(); // Always 0 ReadUInt32(); // Chunk number of previous listing chunk when reading // directory in sequence (-1 if this is the first listing chunk) ReadUInt32(); // Chunk number of next listing chunk when reading // directory in sequence (-1 if this is the last listing chunk) int numItems = 0; for (;;) { UInt64 offset = _inBuffer.GetProcessedSize() - chunkPos; UInt32 offsetLimit = dirChunkSize - quickrefLength; if (offset > offsetLimit) return S_FALSE; if (offset == offsetLimit) break; RINOK(ReadDirEntry(database)); numItems++; } Skip(quickrefLength - 2); if (ReadUInt16() != numItems) return S_FALSE; } else Skip(dirChunkSize - 4); } return S_OK; } HRESULT CInArchive::OpenHelp2(IInStream *inStream, CDatabase &database) { if (ReadUInt32() != 1) // version return S_FALSE; if (ReadUInt32() != 0x28) // Location of header section table return S_FALSE; UInt32 numHeaderSections = ReadUInt32(); const int kNumHeaderSectionsMax = 5; if (numHeaderSections != kNumHeaderSectionsMax) return S_FALSE; ReadUInt32(); // Length of post-header table GUID g; ReadGUID(g); // {0A9007C1-4076-11D3-8789-0000F8105754} // header section table UInt64 sectionOffsets[kNumHeaderSectionsMax]; UInt64 sectionSizes[kNumHeaderSectionsMax]; UInt32 i; for (i = 0; i < numHeaderSections; i++) { sectionOffsets[i] = ReadUInt64(); sectionSizes[i] = ReadUInt64(); } // Post-Header ReadUInt32(); // 2 ReadUInt32(); // 0x98: offset to CAOL from beginning of post-header) // ----- Directory information ReadUInt64(); // Chunk number of top-level AOLI chunk in directory, or -1 ReadUInt64(); // Chunk number of first AOLL chunk in directory ReadUInt64(); // Chunk number of last AOLL chunk in directory ReadUInt64(); // 0 (unknown) ReadUInt32(); // $2000 (Directory chunk size of directory) ReadUInt32(); // Quickref density for main directory, usually 2 ReadUInt32(); // 0 (unknown) ReadUInt32(); // Depth of main directory index tree // 1 there is no index, 2 if there is one level of AOLI chunks. ReadUInt64(); // 0 (unknown) UInt64 numDirEntries = ReadUInt64(); // Number of directory entries // ----- Directory Index Information ReadUInt64(); // -1 (unknown, probably chunk number of top-level AOLI in directory index) ReadUInt64(); // Chunk number of first AOLL chunk in directory index ReadUInt64(); // Chunk number of last AOLL chunk in directory index ReadUInt64(); // 0 (unknown) ReadUInt32(); // $200 (Directory chunk size of directory index) ReadUInt32(); // Quickref density for directory index, usually 2 ReadUInt32(); // 0 (unknown) ReadUInt32(); // Depth of directory index index tree. ReadUInt64(); // Possibly flags -- sometimes 1, sometimes 0. ReadUInt64(); // Number of directory index entries (same as number of AOLL // chunks in main directory) // (The obvious guess for the following two fields, which recur in a number // of places, is they are maximum sizes for the directory and directory index. // However, I have seen no direct evidence that this is the case.) ReadUInt32(); // $100000 (Same as field following chunk size in directory) ReadUInt32(); // $20000 (Same as field following chunk size in directory index) ReadUInt64(); // 0 (unknown) if (ReadUInt32() != NHeader::kCaolSignature) return S_FALSE; if (ReadUInt32() != 2) // (Most likely a version number) return S_FALSE; UInt32 caolLength = ReadUInt32(); // $50 (Length of the CAOL section, which includes the ITSF section) if (caolLength >= 0x2C) { /* UInt32 c7 = */ ReadUInt16(); // Unknown. Remains the same when identical files are built. // Does not appear to be a checksum. Many files have // 'HH' (HTML Help?) here, indicating this may be a compiler ID // field. But at least one ITOL/ITLS compiler does not set this // field to a constant value. ReadUInt16(); // 0 (Unknown. Possibly part of 00A4 field) ReadUInt32(); // Unknown. Two values have been seen -- $43ED, and 0. ReadUInt32(); // $2000 (Directory chunk size of directory) ReadUInt32(); // $200 (Directory chunk size of directory index) ReadUInt32(); // $100000 (Same as field following chunk size in directory) ReadUInt32(); // $20000 (Same as field following chunk size in directory index) ReadUInt32(); // 0 (unknown) ReadUInt32(); // 0 (Unknown) if (caolLength == 0x2C) { database.ContentOffset = 0; database.NewFormat = true; } else if (caolLength == 0x50) { ReadUInt32(); // 0 (Unknown) if (ReadUInt32() != NHeader::kItsfSignature) return S_FALSE; if (ReadUInt32() != 4) // $4 (Version number -- CHM uses 3) return S_FALSE; if (ReadUInt32() != 0x20) // $20 (length of ITSF) return S_FALSE; UInt32 unknown = ReadUInt32(); if (unknown != 0 && unknown != 1) // = 0 for some HxW files, 1 in other cases; return S_FALSE; database.ContentOffset = _startPosition + ReadUInt64(); /* UInt32 timeStamp = */ ReadUInt32(); // A timestamp of some sort. // Considered as a big-endian DWORD, it appears to contain // seconds (MSB) and fractional seconds (second byte). // The third and fourth bytes may contain even more fractional // bits. The 4 least significant bits in the last byte are constant. /* UInt32 lang = */ ReadUInt32(); // BE? } else return S_FALSE; } /* // Section 0 ReadChunk(inStream, _startPosition + sectionOffsets[0], sectionSizes[0]); if (sectionSizes[0] != 0x18) return S_FALSE; ReadUInt32(); // unknown: 01FE ReadUInt32(); // unknown: 0 UInt64 fileSize = ReadUInt64(); ReadUInt32(); // unknown: 0 ReadUInt32(); // unknown: 0 */ // Section 1: The Directory Listing ReadChunk(inStream, _startPosition + sectionOffsets[1], sectionSizes[1]); if (ReadUInt32() != NHeader::kIfcmSignature) return S_FALSE; if (ReadUInt32() != 1) // (probably a version number) return S_FALSE; UInt32 dirChunkSize = ReadUInt32(); // $2000 if (dirChunkSize < 64) return S_FALSE; ReadUInt32(); // $100000 (unknown) ReadUInt32(); // -1 (unknown) ReadUInt32(); // -1 (unknown) UInt32 numDirChunks = ReadUInt32(); ReadUInt32(); // 0 (unknown, probably high word of above) for (UInt32 ci = 0; ci < numDirChunks; ci++) { UInt64 chunkPos = _inBuffer.GetProcessedSize(); if (ReadUInt32() == NHeader::kAollSignature) { UInt32 quickrefLength = ReadUInt32(); // Length of quickref area at end of directory chunk if (quickrefLength > dirChunkSize || quickrefLength < 2) return S_FALSE; ReadUInt64(); // Directory chunk number // This must match physical position in file, that is // the chunk size times the chunk number must be the // offset from the end of the directory header. ReadUInt64(); // Chunk number of previous listing chunk when reading // directory in sequence (-1 if first listing chunk) ReadUInt64(); // Chunk number of next listing chunk when reading // directory in sequence (-1 if last listing chunk) ReadUInt64(); // Number of first listing entry in this chunk ReadUInt32(); // 1 (unknown -- other values have also been seen here) ReadUInt32(); // 0 (unknown) int numItems = 0; for (;;) { UInt64 offset = _inBuffer.GetProcessedSize() - chunkPos; UInt32 offsetLimit = dirChunkSize - quickrefLength; if (offset > offsetLimit) return S_FALSE; if (offset == offsetLimit) break; if (database.NewFormat) { UInt16 nameLength = ReadUInt16(); if (nameLength == 0) return S_FALSE; UString name; ReadUString((int)nameLength, name); AString s; ConvertUnicodeToUTF8(name, s); Byte b = ReadByte(); s += ' '; PrintByte(b, s); s += ' '; UInt64 len = ReadEncInt(); // then number of items ? // then length ? // then some data (binary encoding?) while (len-- != 0) { b = ReadByte(); PrintByte(b, s); } database.NewFormatString += s; database.NewFormatString += "\r\n"; } else { RINOK(ReadDirEntry(database)); } numItems++; } Skip(quickrefLength - 2); if (ReadUInt16() != numItems) return S_FALSE; if (numItems > numDirEntries) return S_FALSE; numDirEntries -= numItems; } else Skip(dirChunkSize - 4); } return numDirEntries == 0 ? S_OK : S_FALSE; } HRESULT CInArchive::DecompressStream(IInStream *inStream, const CDatabase &database, const AString &name) { int index = database.FindItem(name); if (index < 0) return S_FALSE; const CItem &item = database.Items[index]; _chunkSize = item.Size; return ReadChunk(inStream, database.ContentOffset + item.Offset, item.Size); } #define DATA_SPACE "::DataSpace/" static const char *kNameList = DATA_SPACE "NameList"; static const char *kStorage = DATA_SPACE "Storage/"; static const char *kContent = "Content"; static const char *kControlData = "ControlData"; static const char *kSpanInfo = "SpanInfo"; static const char *kTransform = "Transform/"; static const char *kResetTable = "/InstanceData/ResetTable"; static const char *kTransformList = "List"; static AString GetSectionPrefix(const AString &name) { return AString(kStorage) + name + AString("/"); } #define RINOZ(x) { int __tt = (x); if (__tt != 0) return __tt; } static int CompareFiles(const int *p1, const int *p2, void *param) { const CObjectVector &items = *(const CObjectVector *)param; const CItem &item1 = items[*p1]; const CItem &item2 = items[*p2]; bool isDir1 = item1.IsDir(); bool isDir2 = item2.IsDir(); if (isDir1 && !isDir2) return -1; if (isDir2) { if (isDir1) return MyCompare(*p1, *p2); return 1; } RINOZ(MyCompare(item1.Section, item2.Section)); RINOZ(MyCompare(item1.Offset, item2.Offset)); RINOZ(MyCompare(item1.Size, item2.Size)); return MyCompare(*p1, *p2); } void CFilesDatabase::SetIndices() { for (int i = 0; i < Items.Size(); i++) { const CItem &item = Items[i]; if (item.IsUserItem() && item.Name.Length() != 1) Indices.Add(i); } } void CFilesDatabase::Sort() { Indices.Sort(CompareFiles, (void *)&Items); } bool CFilesDatabase::Check() { UInt64 maxPos = 0; UInt64 prevSection = 0; for(int i = 0; i < Indices.Size(); i++) { const CItem &item = Items[Indices[i]]; if (item.Section == 0 || item.IsDir()) continue; if (item.Section != prevSection) { prevSection = item.Section; maxPos = 0; continue; } if (item.Offset < maxPos) return false; maxPos = item.Offset + item.Size; if (maxPos < item.Offset) return false; } return true; } HRESULT CInArchive::OpenHighLevel(IInStream *inStream, CFilesDatabase &database) { { // The NameList file RINOK(DecompressStream(inStream, database, kNameList)); /* UInt16 length = */ ReadUInt16(); UInt16 numSections = ReadUInt16(); for (int i = 0; i < numSections; i++) { CSectionInfo section; UInt16 nameLength = ReadUInt16(); UString name; ReadUString(nameLength, name); if (ReadUInt16() != 0) return S_FALSE; if (!ConvertUnicodeToUTF8(name, section.Name)) return S_FALSE; database.Sections.Add(section); } } int i; for (i = 1; i < database.Sections.Size(); i++) { CSectionInfo §ion = database.Sections[i]; AString sectionPrefix = GetSectionPrefix(section.Name); { // Content int index = database.FindItem(sectionPrefix + kContent); if (index < 0) return S_FALSE; const CItem &item = database.Items[index]; section.Offset = item.Offset; section.CompressedSize = item.Size; } AString transformPrefix = sectionPrefix + kTransform; if (database.Help2Format) { // Transform List RINOK(DecompressStream(inStream, database, transformPrefix + kTransformList)); if ((_chunkSize & 0xF) != 0) return S_FALSE; int numGuids = (int)(_chunkSize / 0x10); if (numGuids < 1) return S_FALSE; for (int i = 0; i < numGuids; i++) { CMethodInfo method; ReadGUID(method.Guid); section.Methods.Add(method); } } else { CMethodInfo method; method.Guid = kChmLzxGuid; section.Methods.Add(method); } { // Control Data RINOK(DecompressStream(inStream, database, sectionPrefix + kControlData)); for (int mi = 0; mi < section.Methods.Size(); mi++) { CMethodInfo &method = section.Methods[mi]; UInt32 numDWORDS = ReadUInt32(); if (method.IsLzx()) { if (numDWORDS < 5) return S_FALSE; if (ReadUInt32() != NHeader::kLzxcSignature) return S_FALSE; CLzxInfo &li = method.LzxInfo; li.Version = ReadUInt32(); if (li.Version != 2 && li.Version != 3) return S_FALSE; li.ResetInterval = ReadUInt32(); li.WindowSize = ReadUInt32(); li.CacheSize = ReadUInt32(); if ( li.ResetInterval != 1 && li.ResetInterval != 2 && li.ResetInterval != 4 && li.ResetInterval != 8 && li.ResetInterval != 16 && li.ResetInterval != 32 && li.ResetInterval != 64) return S_FALSE; if ( li.WindowSize != 1 && li.WindowSize != 2 && li.WindowSize != 4 && li.WindowSize != 8 && li.WindowSize != 16 && li.WindowSize != 32 && li.WindowSize != 64) return S_FALSE; numDWORDS -= 5; while (numDWORDS-- != 0) ReadUInt32(); } else { UInt32 numBytes = numDWORDS * 4; method.ControlData.SetCapacity(numBytes); ReadBytes(method.ControlData, numBytes); } } } { // SpanInfo RINOK(DecompressStream(inStream, database, sectionPrefix + kSpanInfo)); section.UncompressedSize = ReadUInt64(); } // read ResetTable for LZX for (int mi = 0; mi < section.Methods.Size(); mi++) { CMethodInfo &method = section.Methods[mi]; if (method.IsLzx()) { // ResetTable; RINOK(DecompressStream(inStream, database, transformPrefix + method.GetGuidString() + kResetTable)); CResetTable &rt = method.LzxInfo.ResetTable; if (_chunkSize < 4) { if (_chunkSize != 0) return S_FALSE; // ResetTable is empty in .chw files if (section.UncompressedSize != 0) return S_FALSE; rt.UncompressedSize = 0; rt.CompressedSize = 0; rt.BlockSize = 0; } else { UInt32 ver = ReadUInt32(); // 2 unknown (possibly a version number) if (ver != 2 && ver != 3) return S_FALSE; UInt32 numEntries = ReadUInt32(); if (ReadUInt32() != 8) // Size of table entry (bytes) return S_FALSE; if (ReadUInt32() != 0x28) // Length of table header return S_FALSE; rt.UncompressedSize = ReadUInt64(); rt.CompressedSize = ReadUInt64(); rt.BlockSize = ReadUInt64(); // 0x8000 block size for locations below if (rt.BlockSize != 0x8000) return S_FALSE; rt.ResetOffsets.Reserve(numEntries); for (UInt32 i = 0; i < numEntries; i++) rt.ResetOffsets.Add(ReadUInt64()); } } } } database.SetIndices(); database.Sort(); return database.Check() ? S_OK : S_FALSE; } HRESULT CInArchive::Open2(IInStream *inStream, const UInt64 *searchHeaderSizeLimit, CFilesDatabase &database) { database.Clear(); RINOK(inStream->Seek(0, STREAM_SEEK_CUR, &_startPosition)); database.Help2Format = false; const UInt32 chmVersion = 3; { if (!_inBuffer.Create(1 << 14)) return E_OUTOFMEMORY; _inBuffer.SetStream(inStream); _inBuffer.Init(); UInt64 value = 0; const int kSignatureSize = 8; UInt64 hxsSignature = NHeader::GetHxsSignature(); UInt64 chmSignature = ((UInt64)chmVersion << 32)| NHeader::kItsfSignature; UInt64 limit = 1 << 18; if (searchHeaderSizeLimit) if (limit > *searchHeaderSizeLimit) limit = *searchHeaderSizeLimit; for (;;) { Byte b; if (!_inBuffer.ReadByte(b)) return S_FALSE; value >>= 8; value |= ((UInt64)b) << ((kSignatureSize - 1) * 8); if (_inBuffer.GetProcessedSize() >= kSignatureSize) { if (value == chmSignature) break; if (value == hxsSignature) { database.Help2Format = true; break; } if (_inBuffer.GetProcessedSize() > limit) return S_FALSE; } } _startPosition += _inBuffer.GetProcessedSize() - kSignatureSize; } if (database.Help2Format) { RINOK(OpenHelp2(inStream, database)); if (database.NewFormat) return S_OK; } else { RINOK(OpenChm(inStream, database)); } #ifndef CHM_LOW try { HRESULT res = OpenHighLevel(inStream, database); if (res == S_FALSE) { database.HighLevelClear(); return S_OK; } RINOK(res); database.LowLevel = false; } catch(...) { return S_OK; } #endif return S_OK; } HRESULT CInArchive::Open(IInStream *inStream, const UInt64 *searchHeaderSizeLimit, CFilesDatabase &database) { try { HRESULT res = Open2(inStream, searchHeaderSizeLimit, database); _inBuffer.ReleaseStream(); return res; } catch(...) { _inBuffer.ReleaseStream(); throw; } } }}