/* 7zArcIn.c -- 7z Input functions 2014-06-16 : Igor Pavlov : Public domain */ #include "Precomp.h" #include #include "7z.h" #include "7zBuf.h" #include "7zCrc.h" #include "CpuArch.h" #define MY_ALLOC(T, p, size, alloc) { if ((size) == 0) p = 0; else \ if ((p = (T *)IAlloc_Alloc(alloc, (size) * sizeof(T))) == 0) return SZ_ERROR_MEM; } #define k7zMajorVersion 0 enum EIdEnum { k7zIdEnd, k7zIdHeader, k7zIdArchiveProperties, k7zIdAdditionalStreamsInfo, k7zIdMainStreamsInfo, k7zIdFilesInfo, k7zIdPackInfo, k7zIdUnpackInfo, k7zIdSubStreamsInfo, k7zIdSize, k7zIdCRC, k7zIdFolder, k7zIdCodersUnpackSize, k7zIdNumUnpackStream, k7zIdEmptyStream, k7zIdEmptyFile, k7zIdAnti, k7zIdName, k7zIdCTime, k7zIdATime, k7zIdMTime, k7zIdWinAttrib, k7zIdComment, k7zIdEncodedHeader, k7zIdStartPos, k7zIdDummy // k7zNtSecure, // k7zParent, // k7zIsReal }; Byte k7zSignature[k7zSignatureSize] = {'7', 'z', 0xBC, 0xAF, 0x27, 0x1C}; #define NUM_FOLDER_CODERS_MAX 32 #define NUM_CODER_STREAMS_MAX 32 /* static int SzFolder_FindBindPairForInStream(const CSzFolder *p, UInt32 inStreamIndex) { UInt32 i; for (i = 0; i < p->NumBindPairs; i++) if (p->BindPairs[i].InIndex == inStreamIndex) return i; return -1; } */ #define SzBitUi32s_Init(p) { (p)->Defs = 0; (p)->Vals = 0; } static SRes SzBitUi32s_Alloc(CSzBitUi32s *p, size_t num, ISzAlloc *alloc) { MY_ALLOC(Byte, p->Defs, (num + 7) >> 3, alloc); MY_ALLOC(UInt32, p->Vals, num, alloc); return SZ_OK; } void SzBitUi32s_Free(CSzBitUi32s *p, ISzAlloc *alloc) { IAlloc_Free(alloc, p->Defs); p->Defs = 0; IAlloc_Free(alloc, p->Vals); p->Vals = 0; } #define SzBitUi64s_Init(p) { (p)->Defs = 0; (p)->Vals = 0; } void SzBitUi64s_Free(CSzBitUi64s *p, ISzAlloc *alloc) { IAlloc_Free(alloc, p->Defs); p->Defs = 0; IAlloc_Free(alloc, p->Vals); p->Vals = 0; } static void SzAr_Init(CSzAr *p) { p->NumPackStreams = 0; p->NumFolders = 0; p->PackPositions = 0; SzBitUi32s_Init(&p->FolderCRCs); // p->Folders = 0; p->FoCodersOffsets = 0; p->FoSizesOffsets = 0; p->FoStartPackStreamIndex = 0; p->CodersData = 0; // p->CoderUnpackSizes = 0; p->UnpackSizesData = 0; } static void SzAr_Free(CSzAr *p, ISzAlloc *alloc) { IAlloc_Free(alloc, p->UnpackSizesData); IAlloc_Free(alloc, p->CodersData); // IAlloc_Free(alloc, p->CoderUnpackSizes); IAlloc_Free(alloc, p->PackPositions); // IAlloc_Free(alloc, p->Folders); IAlloc_Free(alloc, p->FoCodersOffsets); IAlloc_Free(alloc, p->FoSizesOffsets); IAlloc_Free(alloc, p->FoStartPackStreamIndex); SzBitUi32s_Free(&p->FolderCRCs, alloc); SzAr_Init(p); } void SzArEx_Init(CSzArEx *p) { SzAr_Init(&p->db); p->NumFiles = 0; p->dataPos = 0; // p->Files = 0; p->UnpackPositions = 0; // p->IsEmptyFiles = 0; p->IsDirs = 0; // p->FolderStartPackStreamIndex = 0; // p->PackStreamStartPositions = 0; p->FolderStartFileIndex = 0; p->FileIndexToFolderIndexMap = 0; p->FileNameOffsets = 0; p->FileNames = 0; SzBitUi32s_Init(&p->CRCs); SzBitUi32s_Init(&p->Attribs); // SzBitUi32s_Init(&p->Parents); SzBitUi64s_Init(&p->MTime); SzBitUi64s_Init(&p->CTime); } void SzArEx_Free(CSzArEx *p, ISzAlloc *alloc) { // IAlloc_Free(alloc, p->FolderStartPackStreamIndex); // IAlloc_Free(alloc, p->PackStreamStartPositions); IAlloc_Free(alloc, p->FolderStartFileIndex); IAlloc_Free(alloc, p->FileIndexToFolderIndexMap); IAlloc_Free(alloc, p->FileNameOffsets); IAlloc_Free(alloc, p->FileNames); SzBitUi64s_Free(&p->CTime, alloc); SzBitUi64s_Free(&p->MTime, alloc); SzBitUi32s_Free(&p->CRCs, alloc); // SzBitUi32s_Free(&p->Parents, alloc); SzBitUi32s_Free(&p->Attribs, alloc); IAlloc_Free(alloc, p->IsDirs); // IAlloc_Free(alloc, p->IsEmptyFiles); IAlloc_Free(alloc, p->UnpackPositions); // IAlloc_Free(alloc, p->Files); SzAr_Free(&p->db, alloc); SzArEx_Init(p); } static int TestSignatureCandidate(Byte *testBytes) { size_t i; for (i = 0; i < k7zSignatureSize; i++) if (testBytes[i] != k7zSignature[i]) return 0; return 1; } #define SzData_Clear(p) { (p)->Data = 0; (p)->Size = 0; } static SRes SzReadByte(CSzData *sd, Byte *b) { if (sd->Size == 0) return SZ_ERROR_ARCHIVE; sd->Size--; *b = *sd->Data++; return SZ_OK; } #define SZ_READ_BYTE_SD(_sd_, dest) if ((_sd_)->Size == 0) return SZ_ERROR_ARCHIVE; (_sd_)->Size--; dest = *(_sd_)->Data++; #define SZ_READ_BYTE(dest) SZ_READ_BYTE_SD(sd, dest) #define SZ_READ_BYTE_2(dest) if (sd.Size == 0) return SZ_ERROR_ARCHIVE; sd.Size--; dest = *sd.Data++; #define SKIP_DATA(sd, size) { sd->Size -= (size_t)(size); sd->Data += (size_t)(size); } #define SKIP_DATA2(sd, size) { sd.Size -= (size_t)(size); sd.Data += (size_t)(size); } #define SZ_READ_32(dest) if (sd.Size < 4) return SZ_ERROR_ARCHIVE; \ dest = GetUi32(sd.Data); SKIP_DATA2(sd, 4); static MY_NO_INLINE SRes ReadNumber(CSzData *sd, UInt64 *value) { Byte firstByte, mask; unsigned i; UInt32 v; SZ_READ_BYTE(firstByte); if ((firstByte & 0x80) == 0) { *value = firstByte; return SZ_OK; } SZ_READ_BYTE(v); if ((firstByte & 0x40) == 0) { *value = (((UInt32)firstByte & 0x3F) << 8) | v; return SZ_OK; } SZ_READ_BYTE(mask); *value = v | ((UInt32)mask << 8); mask = 0x20; for (i = 2; i < 8; i++) { Byte b; if ((firstByte & mask) == 0) { UInt64 highPart = firstByte & (mask - 1); *value |= (highPart << (8 * i)); return SZ_OK; } SZ_READ_BYTE(b); *value |= ((UInt64)b << (8 * i)); mask >>= 1; } return SZ_OK; } /* static MY_NO_INLINE const Byte *SzReadNumbers(const Byte *data, const Byte *dataLim, UInt64 *values, UInt32 num) { for (; num != 0; num--) { Byte firstByte; Byte mask; unsigned i; UInt32 v; UInt64 value; if (data == dataLim) return NULL; firstByte = *data++; if ((firstByte & 0x80) == 0) { *values++ = firstByte; continue; } if (data == dataLim) return NULL; v = *data++; if ((firstByte & 0x40) == 0) { *values++ = (((UInt32)firstByte & 0x3F) << 8) | v; continue; } if (data == dataLim) return NULL; value = v | ((UInt32)*data++ << 8); mask = 0x20; for (i = 2; i < 8; i++) { if ((firstByte & mask) == 0) { UInt64 highPart = firstByte & (mask - 1); value |= (highPart << (8 * i)); break; } if (data == dataLim) return NULL; value |= ((UInt64)*data++ << (8 * i)); mask >>= 1; } *values++ = value; } return data; } */ static MY_NO_INLINE SRes SzReadNumber32(CSzData *sd, UInt32 *value) { Byte firstByte; UInt64 value64; if (sd->Size == 0) return SZ_ERROR_ARCHIVE; firstByte = *sd->Data; if ((firstByte & 0x80) == 0) { *value = firstByte; sd->Data++; sd->Size--; return SZ_OK; } RINOK(ReadNumber(sd, &value64)); if (value64 >= (UInt32)0x80000000 - 1) return SZ_ERROR_UNSUPPORTED; if (value64 >= ((UInt64)(1) << ((sizeof(size_t) - 1) * 8 + 4))) return SZ_ERROR_UNSUPPORTED; *value = (UInt32)value64; return SZ_OK; } #define ReadID(sd, value) ReadNumber(sd, value) static SRes SkipData(CSzData *sd) { UInt64 size; RINOK(ReadNumber(sd, &size)); if (size > sd->Size) return SZ_ERROR_ARCHIVE; SKIP_DATA(sd, size); return SZ_OK; } static SRes WaitId(CSzData *sd, UInt64 id) { for (;;) { UInt64 type; RINOK(ReadID(sd, &type)); if (type == id) return SZ_OK; if (type == k7zIdEnd) return SZ_ERROR_ARCHIVE; RINOK(SkipData(sd)); } } static SRes RememberBitVector(CSzData *sd, UInt32 numItems, const Byte **v) { UInt32 numBytes = (numItems + 7) >> 3; if (numBytes > sd->Size) return SZ_ERROR_ARCHIVE; *v = sd->Data; SKIP_DATA(sd, numBytes); return SZ_OK; } static UInt32 CountDefinedBits(const Byte *bits, UInt32 numItems) { Byte b = 0; unsigned m = 0; UInt32 sum = 0; for (; numItems != 0; numItems--) { if (m == 0) { b = *bits++; m = 8; } m--; sum += ((b >> m) & 1); } return sum ; } static MY_NO_INLINE SRes ReadBitVector(CSzData *sd, UInt32 numItems, Byte **v, ISzAlloc *alloc) { Byte allAreDefined; UInt32 i; Byte *v2; UInt32 numBytes = (numItems + 7) >> 3; RINOK(SzReadByte(sd, &allAreDefined)); if (allAreDefined == 0) { if (numBytes > sd->Size) return SZ_ERROR_ARCHIVE; MY_ALLOC(Byte, *v, numBytes, alloc); memcpy(*v, sd->Data, numBytes); SKIP_DATA(sd, numBytes); return SZ_OK; } MY_ALLOC(Byte, *v, numBytes, alloc); v2 = *v; for (i = 0; i < numBytes; i++) v2[i] = 0xFF; { unsigned numBits = (unsigned)numItems & 7; if (numBits != 0) v2[numBytes - 1] = (Byte)((((UInt32)1 << numBits) - 1) << (8 - numBits)); } return SZ_OK; } static MY_NO_INLINE SRes ReadUi32s(CSzData *sd2, UInt32 numItems, CSzBitUi32s *crcs, ISzAlloc *alloc) { UInt32 i; CSzData sd; UInt32 *vals; const Byte *defs; MY_ALLOC(UInt32, crcs->Vals, numItems, alloc); sd = *sd2; defs = crcs->Defs; vals = crcs->Vals; for (i = 0; i < numItems; i++) if (SzBitArray_Check(defs, i)) { SZ_READ_32(vals[i]); } else vals[i] = 0; *sd2 = sd; return SZ_OK; } static SRes ReadBitUi32s(CSzData *sd, UInt32 numItems, CSzBitUi32s *crcs, ISzAlloc *alloc) { SzBitUi32s_Free(crcs, alloc); RINOK(ReadBitVector(sd, numItems, &crcs->Defs, alloc)); return ReadUi32s(sd, numItems, crcs, alloc); } static SRes SkipBitUi32s(CSzData *sd, UInt32 numItems) { Byte allAreDefined; UInt32 numDefined = numItems; RINOK(SzReadByte(sd, &allAreDefined)); if (!allAreDefined) { size_t numBytes = (numItems + 7) >> 3; if (numBytes > sd->Size) return SZ_ERROR_ARCHIVE; numDefined = CountDefinedBits(sd->Data, numItems); SKIP_DATA(sd, numBytes); } if (numDefined > (sd->Size >> 2)) return SZ_ERROR_ARCHIVE; SKIP_DATA(sd, (size_t)numDefined * 4); return SZ_OK; } static SRes ReadPackInfo(CSzAr *p, CSzData *sd, ISzAlloc *alloc) { RINOK(SzReadNumber32(sd, &p->NumPackStreams)); RINOK(WaitId(sd, k7zIdSize)); MY_ALLOC(UInt64, p->PackPositions, (size_t)p->NumPackStreams + 1, alloc); { UInt64 sum = 0; UInt32 i; UInt32 numPackStreams = p->NumPackStreams; for (i = 0; i < numPackStreams; i++) { UInt64 packSize; p->PackPositions[i] = sum; RINOK(ReadNumber(sd, &packSize)); sum += packSize; if (sum < packSize) return SZ_ERROR_ARCHIVE; } p->PackPositions[i] = sum; } for (;;) { UInt64 type; RINOK(ReadID(sd, &type)); if (type == k7zIdEnd) return SZ_OK; if (type == k7zIdCRC) { /* CRC of packed streams is unused now */ RINOK(SkipBitUi32s(sd, p->NumPackStreams)); continue; } RINOK(SkipData(sd)); } } /* static SRes SzReadSwitch(CSzData *sd) { Byte external; RINOK(SzReadByte(sd, &external)); return (external == 0) ? SZ_OK: SZ_ERROR_UNSUPPORTED; } */ #define SZ_NUM_IN_STREAMS_IN_FOLDER_MAX 16 SRes SzGetNextFolderItem(CSzFolder *f, CSzData *sd, CSzData *sdSizes) { UInt32 numCoders, numBindPairs, numPackStreams, i; UInt32 numInStreams = 0, numOutStreams = 0; const Byte *dataStart = sd->Data; Byte inStreamUsed[SZ_NUM_IN_STREAMS_IN_FOLDER_MAX]; RINOK(SzReadNumber32(sd, &numCoders)); if (numCoders > SZ_NUM_CODERS_IN_FOLDER_MAX) return SZ_ERROR_UNSUPPORTED; f->NumCoders = numCoders; for (i = 0; i < numCoders; i++) { Byte mainByte; CSzCoderInfo *coder = f->Coders + i; unsigned idSize, j; UInt64 id; RINOK(SzReadByte(sd, &mainByte)); if ((mainByte & 0xC0) != 0) return SZ_ERROR_UNSUPPORTED; idSize = (unsigned)(mainByte & 0xF); if (idSize > sizeof(id)) return SZ_ERROR_UNSUPPORTED; if (idSize > sd->Size) return SZ_ERROR_ARCHIVE; id = 0; for (j = 0; j < idSize; j++) { id = ((id << 8) | *sd->Data); sd->Data++; sd->Size--; } if (id > (UInt32)0xFFFFFFFF) return SZ_ERROR_UNSUPPORTED; coder->MethodID = (UInt32)id; coder->NumInStreams = 1; coder->NumOutStreams = 1; coder->PropsOffset = 0; coder->PropsSize = 0; if ((mainByte & 0x10) != 0) { UInt32 numStreams; RINOK(SzReadNumber32(sd, &numStreams)); if (numStreams > NUM_CODER_STREAMS_MAX) return SZ_ERROR_UNSUPPORTED; coder->NumInStreams = (Byte)numStreams; RINOK(SzReadNumber32(sd, &numStreams)); if (numStreams > NUM_CODER_STREAMS_MAX) return SZ_ERROR_UNSUPPORTED; coder->NumOutStreams = (Byte)numStreams; } if ((mainByte & 0x20) != 0) { UInt32 propsSize = 0; RINOK(SzReadNumber32(sd, &propsSize)); if (propsSize >= 0x40) return SZ_ERROR_UNSUPPORTED; if (propsSize > sd->Size) return SZ_ERROR_ARCHIVE; coder->PropsOffset = sd->Data - dataStart; coder->PropsSize = (Byte)propsSize; sd->Data += (size_t)propsSize; sd->Size -= (size_t)propsSize; } numInStreams += coder->NumInStreams; numOutStreams += coder->NumOutStreams; } if (numOutStreams == 0) return SZ_ERROR_UNSUPPORTED; f->NumBindPairs = numBindPairs = numOutStreams - 1; if (numInStreams < numBindPairs) return SZ_ERROR_ARCHIVE; if (numInStreams > SZ_NUM_IN_STREAMS_IN_FOLDER_MAX) return SZ_ERROR_UNSUPPORTED; f->MainOutStream = 0; f->NumPackStreams = numPackStreams = numInStreams - numBindPairs; if (numPackStreams > SZ_NUM_PACK_STREAMS_IN_FOLDER_MAX) return SZ_ERROR_UNSUPPORTED; for (i = 0; i < numInStreams; i++) inStreamUsed[i] = False; if (numBindPairs != 0) { Byte outStreamUsed[SZ_NUM_CODERS_OUT_STREAMS_IN_FOLDER_MAX]; if (numBindPairs > SZ_NUM_BINDS_IN_FOLDER_MAX) return SZ_ERROR_UNSUPPORTED; for (i = 0; i < numOutStreams; i++) outStreamUsed[i] = False; for (i = 0; i < numBindPairs; i++) { CSzBindPair *bp = f->BindPairs + i; RINOK(SzReadNumber32(sd, &bp->InIndex)); if (bp->InIndex >= numInStreams) return SZ_ERROR_ARCHIVE; inStreamUsed[bp->InIndex] = True; RINOK(SzReadNumber32(sd, &bp->OutIndex)); if (bp->OutIndex >= numInStreams) return SZ_ERROR_ARCHIVE; outStreamUsed[bp->OutIndex] = True; } for (i = 0; i < numOutStreams; i++) if (!outStreamUsed[i]) { f->MainOutStream = i; break; } if (i == numOutStreams) return SZ_ERROR_ARCHIVE; } if (numPackStreams == 1) { for (i = 0; i < numInStreams; i++) if (!inStreamUsed[i]) break; if (i == numInStreams) return SZ_ERROR_ARCHIVE; f->PackStreams[0] = i; } else for (i = 0; i < numPackStreams; i++) { RINOK(SzReadNumber32(sd, f->PackStreams + i)); } for (i = 0; i < numOutStreams; i++) { RINOK(ReadNumber(sdSizes, f->CodersUnpackSizes + i)); } return SZ_OK; } static MY_NO_INLINE SRes SkipNumbers(CSzData *sd2, UInt32 num) { CSzData sd; sd = *sd2; for (; num != 0; num--) { Byte firstByte, mask; unsigned i; SZ_READ_BYTE_2(firstByte); if ((firstByte & 0x80) == 0) continue; if ((firstByte & 0x40) == 0) { if (sd.Size == 0) return SZ_ERROR_ARCHIVE; sd.Size--; sd.Data++; continue; } mask = 0x20; for (i = 2; i < 8 && (firstByte & mask) != 0; i++) mask >>= 1; if (i > sd.Size) return SZ_ERROR_ARCHIVE; SKIP_DATA2(sd, i); } *sd2 = sd; return SZ_OK; } #define k_InStreamUsed_MAX 64 #define k_OutStreamUsed_MAX 64 static SRes ReadUnpackInfo(CSzAr *p, CSzData *sd2, UInt32 numFoldersMax, const CBuf *tempBufs, UInt32 numTempBufs, ISzAlloc *alloc) { CSzData sd; Byte inStreamUsed[k_InStreamUsed_MAX]; Byte outStreamUsed[k_OutStreamUsed_MAX]; UInt32 fo, numFolders, numCodersOutStreams, packStreamIndex; const Byte *startBufPtr; Byte external; RINOK(WaitId(sd2, k7zIdFolder)); RINOK(SzReadNumber32(sd2, &numFolders)); if (p->NumFolders > numFoldersMax) return SZ_ERROR_UNSUPPORTED; p->NumFolders = numFolders; SZ_READ_BYTE_SD(sd2, external); if (external == 0) sd = *sd2; else { UInt32 index; SzReadNumber32(sd2, &index); if (index >= numTempBufs) return SZ_ERROR_ARCHIVE; sd.Data = tempBufs[index].data; sd.Size = tempBufs[index].size; } MY_ALLOC(size_t, p->FoCodersOffsets, (size_t)numFolders + 1, alloc); MY_ALLOC(size_t, p->FoSizesOffsets, (size_t)numFolders + 1, alloc); MY_ALLOC(UInt32, p->FoStartPackStreamIndex, (size_t)numFolders + 1, alloc); startBufPtr = sd.Data; packStreamIndex = 0; numCodersOutStreams = 0; for (fo = 0; fo < numFolders; fo++) { UInt32 numCoders, ci, numInStreams = 0, numOutStreams = 0; p->FoCodersOffsets[fo] = sd.Data - startBufPtr; RINOK(SzReadNumber32(&sd, &numCoders)); if (numCoders > NUM_FOLDER_CODERS_MAX) return SZ_ERROR_UNSUPPORTED; for (ci = 0; ci < numCoders; ci++) { Byte mainByte; unsigned idSize; UInt32 coderInStreams, coderOutStreams; SZ_READ_BYTE_2(mainByte); if ((mainByte & 0xC0) != 0) return SZ_ERROR_UNSUPPORTED; idSize = (mainByte & 0xF); if (idSize > 8) return SZ_ERROR_UNSUPPORTED; if (idSize > sd.Size) return SZ_ERROR_ARCHIVE; SKIP_DATA2(sd, idSize); coderInStreams = 1; coderOutStreams = 1; if ((mainByte & 0x10) != 0) { RINOK(SzReadNumber32(&sd, &coderInStreams)); RINOK(SzReadNumber32(&sd, &coderOutStreams)); if (coderInStreams > NUM_CODER_STREAMS_MAX || coderOutStreams > NUM_CODER_STREAMS_MAX) return SZ_ERROR_UNSUPPORTED; } numInStreams += coderInStreams; numOutStreams += coderOutStreams; if ((mainByte & 0x20) != 0) { UInt32 propsSize; RINOK(SzReadNumber32(&sd, &propsSize)); if (propsSize > sd.Size) return SZ_ERROR_ARCHIVE; SKIP_DATA2(sd, propsSize); } } { UInt32 indexOfMainStream = 0; UInt32 numPackStreams = 1; if (numOutStreams != 1 || numInStreams != 1) { UInt32 i; UInt32 numBindPairs = numOutStreams - 1; if (numOutStreams == 0 || numInStreams < numBindPairs) return SZ_ERROR_ARCHIVE; if (numInStreams > k_InStreamUsed_MAX || numOutStreams > k_OutStreamUsed_MAX) return SZ_ERROR_UNSUPPORTED; for (i = 0; i < numInStreams; i++) inStreamUsed[i] = False; for (i = 0; i < numOutStreams; i++) outStreamUsed[i] = False; for (i = 0; i < numBindPairs; i++) { UInt32 index; RINOK(SzReadNumber32(&sd, &index)); if (index >= numInStreams || inStreamUsed[index]) return SZ_ERROR_ARCHIVE; inStreamUsed[index] = True; RINOK(SzReadNumber32(&sd, &index)); if (index >= numInStreams || outStreamUsed[index]) return SZ_ERROR_ARCHIVE; outStreamUsed[index] = True; } numPackStreams = numInStreams - numBindPairs; if (numPackStreams != 1) for (i = 0; i < numPackStreams; i++) { UInt32 temp; RINOK(SzReadNumber32(&sd, &temp)); if (temp >= numInStreams) return SZ_ERROR_ARCHIVE; } for (i = 0; i < numOutStreams; i++) if (!outStreamUsed[i]) { indexOfMainStream = i; break; } if (i == numOutStreams) return SZ_ERROR_ARCHIVE; } p->FoStartPackStreamIndex[fo] = packStreamIndex; p->FoSizesOffsets[fo] = (numOutStreams << 8) | indexOfMainStream; numCodersOutStreams += numOutStreams; if (numCodersOutStreams < numOutStreams) return SZ_ERROR_UNSUPPORTED; packStreamIndex += numPackStreams; if (packStreamIndex < numPackStreams) return SZ_ERROR_UNSUPPORTED; if (packStreamIndex > p->NumPackStreams) return SZ_ERROR_ARCHIVE; } } { size_t dataSize = sd.Data - startBufPtr; p->FoStartPackStreamIndex[fo] = packStreamIndex; p->FoCodersOffsets[fo] = dataSize; MY_ALLOC(Byte, p->CodersData, dataSize, alloc); memcpy(p->CodersData, startBufPtr, dataSize); } if (external != 0) { if (sd.Size != 0) return SZ_ERROR_ARCHIVE; sd = *sd2; } RINOK(WaitId(&sd, k7zIdCodersUnpackSize)); // MY_ALLOC(UInt64, p->CoderUnpackSizes, (size_t)numCodersOutStreams, alloc); { size_t dataSize = sd.Size; /* UInt32 i; for (i = 0; i < numCodersOutStreams; i++) { RINOK(ReadNumber(&sd, p->CoderUnpackSizes + i)); } */ RINOK(SkipNumbers(&sd, numCodersOutStreams)); dataSize -= sd.Size; MY_ALLOC(Byte, p->UnpackSizesData, dataSize, alloc); memcpy(p->UnpackSizesData, sd.Data - dataSize, dataSize); p->UnpackSizesDataSize = dataSize; /* const Byte *data = SzReadNumbers(sd.Data, sd.Data + sd.Size, p->CoderUnpackSizes, numCodersOutStreams); if (data == NULL) return SZ_ERROR_ARCHIVE; sd.Size = sd.Data + sd.Size - data; sd.Data = data; */ } for (;;) { UInt64 type; RINOK(ReadID(&sd, &type)); if (type == k7zIdEnd) { *sd2 = sd; return SZ_OK; } if (type == k7zIdCRC) { RINOK(ReadBitUi32s(&sd, numFolders, &p->FolderCRCs, alloc)); continue; } RINOK(SkipData(&sd)); } } typedef struct { UInt32 NumTotalSubStreams; UInt32 NumSubDigests; CSzData sdNumSubStreams; CSzData sdSizes; CSzData sdCRCs; } CSubStreamInfo; #define SzUi32IndexMax (((UInt32)1 << 31) - 2) static SRes ReadSubStreamsInfo(CSzAr *p, CSzData *sd, CSubStreamInfo *ssi) { UInt64 type = 0; UInt32 i; UInt32 numSubDigests = 0; UInt32 numFolders = p->NumFolders; UInt32 numUnpackStreams = numFolders; UInt32 numUnpackSizesInData = 0; for (;;) { RINOK(ReadID(sd, &type)); if (type == k7zIdNumUnpackStream) { ssi->sdNumSubStreams.Data = sd->Data; numUnpackStreams = 0; numSubDigests = 0; for (i = 0; i < numFolders; i++) { UInt32 numStreams; RINOK(SzReadNumber32(sd, &numStreams)); if (numUnpackStreams > numUnpackStreams + numStreams) return SZ_ERROR_UNSUPPORTED; numUnpackStreams += numStreams; if (numStreams != 0) numUnpackSizesInData += (numStreams - 1); if (numStreams != 1 || !SzBitWithVals_Check(&p->FolderCRCs, i)) numSubDigests += numStreams; } ssi->sdNumSubStreams.Size = sd->Data - ssi->sdNumSubStreams.Data; continue; } if (type == k7zIdCRC || type == k7zIdSize || type == k7zIdEnd) break; RINOK(SkipData(sd)); } if (!ssi->sdNumSubStreams.Data) { numSubDigests = numFolders; if (p->FolderCRCs.Defs) numSubDigests = numFolders - CountDefinedBits(p->FolderCRCs.Defs, numFolders); } ssi->NumTotalSubStreams = numUnpackStreams; ssi->NumSubDigests = numSubDigests; if (type == k7zIdSize) { ssi->sdSizes.Data = sd->Data; RINOK(SkipNumbers(sd, numUnpackSizesInData)); ssi->sdSizes.Size = sd->Data - ssi->sdSizes.Data; RINOK(ReadID(sd, &type)); } for (;;) { if (type == k7zIdEnd) return SZ_OK; if (type == k7zIdCRC) { ssi->sdCRCs.Data = sd->Data; RINOK(SkipBitUi32s(sd, numSubDigests)); ssi->sdCRCs.Size = sd->Data - ssi->sdCRCs.Data; } else { RINOK(SkipData(sd)); } RINOK(ReadID(sd, &type)); } } static SRes SzReadStreamsInfo(CSzAr *p, CSzData *sd, UInt32 numFoldersMax, const CBuf *tempBufs, UInt32 numTempBufs, UInt64 *dataOffset, CSubStreamInfo *ssi, ISzAlloc *alloc) { UInt64 type; SzData_Clear(&ssi->sdSizes); SzData_Clear(&ssi->sdCRCs); SzData_Clear(&ssi->sdNumSubStreams); *dataOffset = 0; RINOK(ReadID(sd, &type)); if (type == k7zIdPackInfo) { RINOK(ReadNumber(sd, dataOffset)); RINOK(ReadPackInfo(p, sd, alloc)); RINOK(ReadID(sd, &type)); } if (type == k7zIdUnpackInfo) { RINOK(ReadUnpackInfo(p, sd, numFoldersMax, tempBufs, numTempBufs, alloc)); RINOK(ReadID(sd, &type)); } if (type == k7zIdSubStreamsInfo) { RINOK(ReadSubStreamsInfo(p, sd, ssi)); RINOK(ReadID(sd, &type)); } else { ssi->NumTotalSubStreams = p->NumFolders; // ssi->NumSubDigests = 0; } return (type == k7zIdEnd ? SZ_OK : SZ_ERROR_UNSUPPORTED); } static SRes SzReadAndDecodePackedStreams( ILookInStream *inStream, CSzData *sd, CBuf *tempBufs, UInt32 numFoldersMax, UInt64 baseOffset, CSzAr *p, ISzAlloc *allocTemp) { UInt64 dataStartPos; UInt32 fo; CSubStreamInfo ssi; CSzData sdCodersUnpSizes; RINOK(SzReadStreamsInfo(p, sd, numFoldersMax, NULL, 0, &dataStartPos, &ssi, allocTemp)); dataStartPos += baseOffset; if (p->NumFolders == 0) return SZ_ERROR_ARCHIVE; sdCodersUnpSizes.Data = p->UnpackSizesData; sdCodersUnpSizes.Size = p->UnpackSizesDataSize; for (fo = 0; fo < p->NumFolders; fo++) Buf_Init(tempBufs + fo); for (fo = 0; fo < p->NumFolders; fo++) { CBuf *tempBuf = tempBufs + fo; // folder = p->Folders; // unpackSize = SzAr_GetFolderUnpackSize(p, 0); UInt32 mix = (UInt32)p->FoSizesOffsets[fo]; UInt32 mainIndex = mix & 0xFF; UInt32 numOutStreams = mix >> 8; UInt32 si; UInt64 unpackSize = 0; p->FoSizesOffsets[fo] = sdCodersUnpSizes.Data - p->UnpackSizesData; for (si = 0; si < numOutStreams; si++) { UInt64 curSize; RINOK(ReadNumber(&sdCodersUnpSizes, &curSize)); if (si == mainIndex) { unpackSize = curSize; break; } } if (si == numOutStreams) return SZ_ERROR_FAIL; if ((size_t)unpackSize != unpackSize) return SZ_ERROR_MEM; if (!Buf_Create(tempBuf, (size_t)unpackSize, allocTemp)) return SZ_ERROR_MEM; } p->FoSizesOffsets[fo] = sdCodersUnpSizes.Data - p->UnpackSizesData; for (fo = 0; fo < p->NumFolders; fo++) { const CBuf *tempBuf = tempBufs + fo; RINOK(LookInStream_SeekTo(inStream, dataStartPos)); RINOK(SzAr_DecodeFolder(p, fo, inStream, dataStartPos, tempBuf->data, tempBuf->size, allocTemp)); if (SzBitWithVals_Check(&p->FolderCRCs, fo)) if (CrcCalc(tempBuf->data, tempBuf->size) != p->FolderCRCs.Vals[fo]) return SZ_ERROR_CRC; } return SZ_OK; } static SRes SzReadFileNames(const Byte *data, size_t size, UInt32 numFiles, size_t *offsets) { size_t pos = 0; *offsets++ = 0; if (numFiles == 0) return (size == 0) ? SZ_OK : SZ_ERROR_ARCHIVE; if (data[size - 2] != 0 || data[size - 1] != 0) return SZ_ERROR_ARCHIVE; do { const Byte *p; if (pos == size) return SZ_ERROR_ARCHIVE; for (p = data + pos; #ifdef _WIN32 *(const UInt16 *)p != 0 #else p[0] != 0 || p[1] != 0 #endif ; p += 2); pos = p - data + 2; *offsets++ = (pos >> 1); } while (--numFiles); return (pos == size) ? SZ_OK : SZ_ERROR_ARCHIVE; } static MY_NO_INLINE SRes ReadTime(CSzBitUi64s *p, UInt32 num, CSzData *sd2, const CBuf *tempBufs, UInt32 numTempBufs, ISzAlloc *alloc) { CSzData sd; UInt32 i; CNtfsFileTime *vals; Byte *defs; Byte external; RINOK(ReadBitVector(sd2, num, &p->Defs, alloc)); RINOK(SzReadByte(sd2, &external)); if (external == 0) sd = *sd2; else { UInt32 index; SzReadNumber32(sd2, &index); if (index >= numTempBufs) return SZ_ERROR_ARCHIVE; sd.Data = tempBufs[index].data; sd.Size = tempBufs[index].size; } MY_ALLOC(CNtfsFileTime, p->Vals, num, alloc); vals = p->Vals; defs = p->Defs; for (i = 0; i < num; i++) if (SzBitArray_Check(defs, i)) { if (sd.Size < 8) return SZ_ERROR_ARCHIVE; vals[i].Low = GetUi32(sd.Data); vals[i].High = GetUi32(sd.Data + 4); SKIP_DATA2(sd, 8); } else vals[i].High = vals[i].Low = 0; if (external == 0) *sd2 = sd; return SZ_OK; } #define NUM_ADDITIONAL_STREAMS_MAX 8 static SRes SzReadHeader2( CSzArEx *p, /* allocMain */ CSzData *sd, // Byte **emptyStreamVector, /* allocTemp */ // Byte **emptyFileVector, /* allocTemp */ // Byte **lwtVector, /* allocTemp */ ILookInStream *inStream, CBuf *tempBufs, UInt32 *numTempBufs, ISzAlloc *allocMain, ISzAlloc *allocTemp ) { UInt64 type; UInt32 numFiles = 0; UInt32 numEmptyStreams = 0; UInt32 i; CSubStreamInfo ssi; const Byte *emptyStreams = 0; const Byte *emptyFiles = 0; SzData_Clear(&ssi.sdSizes); SzData_Clear(&ssi.sdCRCs); SzData_Clear(&ssi.sdNumSubStreams); ssi.NumSubDigests = 0; ssi.NumTotalSubStreams = 0; RINOK(ReadID(sd, &type)); if (type == k7zIdArchiveProperties) { for (;;) { UInt64 type; RINOK(ReadID(sd, &type)); if (type == k7zIdEnd) break; RINOK(SkipData(sd)); } RINOK(ReadID(sd, &type)); } // if (type == k7zIdAdditionalStreamsInfo) return SZ_ERROR_UNSUPPORTED; if (type == k7zIdAdditionalStreamsInfo) { CSzAr tempAr; SRes res; UInt32 numTempFolders; SzAr_Init(&tempAr); res = SzReadAndDecodePackedStreams(inStream, sd, tempBufs, NUM_ADDITIONAL_STREAMS_MAX, p->startPosAfterHeader, &tempAr, allocTemp); numTempFolders = tempAr.NumFolders; SzAr_Free(&tempAr, allocTemp); if (res != SZ_OK) return res; *numTempBufs = numTempFolders; RINOK(ReadID(sd, &type)); } if (type == k7zIdMainStreamsInfo) { RINOK(SzReadStreamsInfo(&p->db, sd, (UInt32)1 << 30, tempBufs, *numTempBufs, &p->dataPos, &ssi, allocMain)); p->dataPos += p->startPosAfterHeader; RINOK(ReadID(sd, &type)); } if (type == k7zIdEnd) { // *sd2 = sd; return SZ_OK; } if (type != k7zIdFilesInfo) return SZ_ERROR_ARCHIVE; RINOK(SzReadNumber32(sd, &numFiles)); p->NumFiles = numFiles; for (;;) { UInt64 type; UInt64 size; RINOK(ReadID(sd, &type)); if (type == k7zIdEnd) break; RINOK(ReadNumber(sd, &size)); if (size > sd->Size) return SZ_ERROR_ARCHIVE; if ((UInt64)(int)type != type) { SKIP_DATA(sd, size); } else switch((int)type) { case k7zIdName: { size_t namesSize; const Byte *namesData; Byte external; SZ_READ_BYTE(external); if (external == 0) { namesSize = (size_t)size - 1; namesData = sd->Data; } else { UInt32 index; SzReadNumber32(sd, &index); if (index >= *numTempBufs) return SZ_ERROR_ARCHIVE; namesData = (tempBufs)[index].data; namesSize = (tempBufs)[index].size; } if ((namesSize & 1) != 0) return SZ_ERROR_ARCHIVE; MY_ALLOC(Byte, p->FileNames, namesSize, allocMain); MY_ALLOC(size_t, p->FileNameOffsets, numFiles + 1, allocMain); memcpy(p->FileNames, namesData, namesSize); RINOK(SzReadFileNames(p->FileNames, namesSize, numFiles, p->FileNameOffsets)) if (external == 0) { SKIP_DATA(sd, namesSize); } break; } case k7zIdEmptyStream: { RINOK(RememberBitVector(sd, numFiles, &emptyStreams)); numEmptyStreams = CountDefinedBits(emptyStreams, numFiles); break; } case k7zIdEmptyFile: { RINOK(RememberBitVector(sd, numEmptyStreams, &emptyFiles)); break; } case k7zIdWinAttrib: { Byte external; CSzData sdSwitch; CSzData *sdPtr; SzBitUi32s_Free(&p->Attribs, allocMain); RINOK(ReadBitVector(sd, numFiles, &p->Attribs.Defs, allocMain)); SZ_READ_BYTE(external); if (external == 0) sdPtr = sd; else { UInt32 index; SzReadNumber32(sd, &index); if (index >= *numTempBufs) return SZ_ERROR_ARCHIVE; sdSwitch.Data = (tempBufs)[index].data; sdSwitch.Size = (tempBufs)[index].size; sdPtr = &sdSwitch; } RINOK(ReadUi32s(sdPtr, numFiles, &p->Attribs, allocMain)); break; } /* case k7zParent: { SzBitUi32s_Free(&p->Parents, allocMain); RINOK(ReadBitVector(sd, numFiles, &p->Parents.Defs, allocMain)); RINOK(SzReadSwitch(sd)); RINOK(ReadUi32s(sd, numFiles, &p->Parents, allocMain)); break; } */ case k7zIdMTime: RINOK(ReadTime(&p->MTime, numFiles, sd, tempBufs, *numTempBufs, allocMain)); break; case k7zIdCTime: RINOK(ReadTime(&p->CTime, numFiles, sd, tempBufs, *numTempBufs, allocMain)); break; default: { SKIP_DATA(sd, size); } } } if (numFiles - numEmptyStreams != ssi.NumTotalSubStreams) return SZ_ERROR_ARCHIVE; for (;;) { UInt64 type; RINOK(ReadID(sd, &type)); if (type == k7zIdEnd) break; RINOK(SkipData(sd)); } { UInt32 emptyFileIndex = 0; UInt32 folderIndex = 0; UInt32 indexInFolder = 0; UInt64 unpackPos = 0; const Byte *digestsDefs = 0; const Byte *digestsVals = 0; UInt32 digestsValsIndex = 0; UInt32 digestIndex; Byte allDigestsDefined = 0; UInt32 curNumSubStreams = (UInt32)(Int32)-1; Byte isDirMask = 0; Byte crcMask = 0; Byte mask = 0x80; // size_t unpSizesOffset = 0; CSzData sdCodersUnpSizes; sdCodersUnpSizes.Data = p->db.UnpackSizesData; sdCodersUnpSizes.Size = p->db.UnpackSizesDataSize; MY_ALLOC(UInt32, p->FolderStartFileIndex, p->db.NumFolders + 1, allocMain); MY_ALLOC(UInt32, p->FileIndexToFolderIndexMap, p->NumFiles, allocMain); MY_ALLOC(UInt64, p->UnpackPositions, p->NumFiles + 1, allocMain); MY_ALLOC(Byte, p->IsDirs, (p->NumFiles + 7) >> 3, allocMain); RINOK(SzBitUi32s_Alloc(&p->CRCs, p->NumFiles, allocMain)); if (ssi.sdCRCs.Size != 0) { RINOK(SzReadByte(&ssi.sdCRCs, &allDigestsDefined)); if (allDigestsDefined) digestsVals = ssi.sdCRCs.Data; else { size_t numBytes = (ssi.NumSubDigests + 7) >> 3; digestsDefs = ssi.sdCRCs.Data; digestsVals = digestsDefs + numBytes; } } digestIndex = 0; for (i = 0; i < numFiles; i++, mask >>= 1) { if (mask == 0) { UInt32 byteIndex = (i - 1) >> 3; p->IsDirs[byteIndex] = isDirMask; p->CRCs.Defs[byteIndex] = crcMask; isDirMask = 0; crcMask = 0; mask = 0x80; } p->UnpackPositions[i] = unpackPos; p->CRCs.Vals[i] = 0; // p->CRCs.Defs[i] = 0; if (emptyStreams && SzBitArray_Check(emptyStreams , i)) { if (!emptyFiles || !SzBitArray_Check(emptyFiles, emptyFileIndex)) isDirMask |= mask; emptyFileIndex++; if (indexInFolder == 0) { p->FileIndexToFolderIndexMap[i] = (UInt32)-1; continue; } } if (indexInFolder == 0) { /* v3.13 incorrectly worked with empty folders v4.07: Loop for skipping empty folders */ for (;;) { if (folderIndex >= p->db.NumFolders) return SZ_ERROR_ARCHIVE; p->FolderStartFileIndex[folderIndex] = i; if (curNumSubStreams == (UInt32)(Int32)-1); { curNumSubStreams = 1; if (ssi.sdNumSubStreams.Data != 0) { RINOK(SzReadNumber32(&ssi.sdNumSubStreams, &curNumSubStreams)); } } if (curNumSubStreams != 0) break; curNumSubStreams = (UInt32)(Int32)-1; folderIndex++; // check it } } p->FileIndexToFolderIndexMap[i] = folderIndex; if (emptyStreams && SzBitArray_Check(emptyStreams , i)) continue; indexInFolder++; if (indexInFolder >= curNumSubStreams) { UInt64 folderUnpackSize = 0; UInt64 startFolderUnpackPos; { UInt32 mix = (UInt32)p->db.FoSizesOffsets[folderIndex]; UInt32 mainIndex = mix & 0xFF; UInt32 numOutStreams = mix >> 8; UInt32 si; p->db.FoSizesOffsets[folderIndex] = sdCodersUnpSizes.Data - p->db.UnpackSizesData; for (si = 0; si < numOutStreams; si++) { UInt64 curSize; RINOK(ReadNumber(&sdCodersUnpSizes, &curSize)); if (si == mainIndex) { folderUnpackSize = curSize; break; } } if (si == numOutStreams) return SZ_ERROR_FAIL; } // UInt64 folderUnpackSize = SzAr_GetFolderUnpackSize(&p->db, folderIndex); startFolderUnpackPos = p->UnpackPositions[p->FolderStartFileIndex[folderIndex]]; if (folderUnpackSize < unpackPos - startFolderUnpackPos) return SZ_ERROR_ARCHIVE; unpackPos = startFolderUnpackPos + folderUnpackSize; if (curNumSubStreams == 1 && SzBitWithVals_Check(&p->db.FolderCRCs, i)) { p->CRCs.Vals[i] = p->db.FolderCRCs.Vals[folderIndex]; crcMask |= mask; } else if (allDigestsDefined || (digestsDefs && SzBitArray_Check(digestsDefs, digestIndex))) { p->CRCs.Vals[i] = GetUi32(digestsVals + (size_t)digestsValsIndex * 4); digestsValsIndex++; crcMask |= mask; } folderIndex++; indexInFolder = 0; } else { UInt64 v; RINOK(ReadNumber(&ssi.sdSizes, &v)); unpackPos += v; if (allDigestsDefined || (digestsDefs && SzBitArray_Check(digestsDefs, digestIndex))) { p->CRCs.Vals[i] = GetUi32(digestsVals + (size_t)digestsValsIndex * 4); digestsValsIndex++; crcMask |= mask; } } } if (mask != 0x80) { UInt32 byteIndex = (i - 1) >> 3; p->IsDirs[byteIndex] = isDirMask; p->CRCs.Defs[byteIndex] = crcMask; } p->UnpackPositions[i] = unpackPos; p->FolderStartFileIndex[folderIndex] = i; p->db.FoSizesOffsets[folderIndex] = sdCodersUnpSizes.Data - p->db.UnpackSizesData; } return SZ_OK; } static SRes SzReadHeader( CSzArEx *p, CSzData *sd, ILookInStream *inStream, ISzAlloc *allocMain ,ISzAlloc *allocTemp ) { // Byte *emptyStreamVector = 0; // Byte *emptyFileVector = 0; // Byte *lwtVector = 0; UInt32 i; UInt32 numTempBufs = 0; SRes res; CBuf tempBufs[NUM_ADDITIONAL_STREAMS_MAX]; for (i = 0; i < NUM_ADDITIONAL_STREAMS_MAX; i++) Buf_Init(tempBufs + i); // SzBitUi32s_Init(&digests); res = SzReadHeader2(p, sd, // &emptyStreamVector, // &emptyFileVector, // &lwtVector, inStream, tempBufs, &numTempBufs, allocMain, allocTemp ); for (i = 0; i < numTempBufs; i++) Buf_Free(tempBufs + i, allocTemp); // IAlloc_Free(allocTemp, emptyStreamVector); // IAlloc_Free(allocTemp, emptyFileVector); // IAlloc_Free(allocTemp, lwtVector); RINOK(res); { if (sd->Size != 0) return SZ_ERROR_FAIL; } return res; } /* static UInt64 SzAr_GetFolderUnpackSize(const CSzAr *p, UInt32 folderIndex) { const CSzFolder2 *f = p->Folders + folderIndex; // return p->CoderUnpackSizes[f->StartCoderUnpackSizesIndex + f->IndexOfMainOutStream]; UInt32 si; CSzData sdCodersUnpSizes; sdCodersUnpSizes.Data = p->UnpackSizesData + f->UnpackSizeDataOffset; sdCodersUnpSizes.Size = p->UnpackSizesDataSize - f->UnpackSizeDataOffset; for (si = 0; si < numOutStreams; si++) { UInt64 curSize; ReadNumber(&sdCodersUnpSizes, &curSize); if (si == mainIndex) return curSize; } return 0; } */ static SRes SzArEx_Open2( CSzArEx *p, ILookInStream *inStream, ISzAlloc *allocMain, ISzAlloc *allocTemp) { Byte header[k7zStartHeaderSize]; Int64 startArcPos; UInt64 nextHeaderOffset, nextHeaderSize; size_t nextHeaderSizeT; UInt32 nextHeaderCRC; CBuf buf; SRes res; startArcPos = 0; RINOK(inStream->Seek(inStream, &startArcPos, SZ_SEEK_CUR)); RINOK(LookInStream_Read2(inStream, header, k7zStartHeaderSize, SZ_ERROR_NO_ARCHIVE)); if (!TestSignatureCandidate(header)) return SZ_ERROR_NO_ARCHIVE; if (header[6] != k7zMajorVersion) return SZ_ERROR_UNSUPPORTED; nextHeaderOffset = GetUi64(header + 12); nextHeaderSize = GetUi64(header + 20); nextHeaderCRC = GetUi32(header + 28); p->startPosAfterHeader = startArcPos + k7zStartHeaderSize; if (CrcCalc(header + 12, 20) != GetUi32(header + 8)) return SZ_ERROR_CRC; nextHeaderSizeT = (size_t)nextHeaderSize; if (nextHeaderSizeT != nextHeaderSize) return SZ_ERROR_MEM; if (nextHeaderSizeT == 0) return SZ_OK; if (nextHeaderOffset > nextHeaderOffset + nextHeaderSize || nextHeaderOffset > nextHeaderOffset + nextHeaderSize + k7zStartHeaderSize) return SZ_ERROR_NO_ARCHIVE; { Int64 pos = 0; RINOK(inStream->Seek(inStream, &pos, SZ_SEEK_END)); if ((UInt64)pos < startArcPos + nextHeaderOffset || (UInt64)pos < startArcPos + k7zStartHeaderSize + nextHeaderOffset || (UInt64)pos < startArcPos + k7zStartHeaderSize + nextHeaderOffset + nextHeaderSize) return SZ_ERROR_INPUT_EOF; } RINOK(LookInStream_SeekTo(inStream, startArcPos + k7zStartHeaderSize + nextHeaderOffset)); if (!Buf_Create(&buf, nextHeaderSizeT, allocTemp)) return SZ_ERROR_MEM; res = LookInStream_Read(inStream, buf.data, nextHeaderSizeT); if (res == SZ_OK) { res = SZ_ERROR_ARCHIVE; if (CrcCalc(buf.data, nextHeaderSizeT) == nextHeaderCRC) { CSzData sd; UInt64 type; sd.Data = buf.data; sd.Size = buf.size; res = ReadID(&sd, &type); if (res == SZ_OK && type == k7zIdEncodedHeader) { CSzAr tempAr; CBuf tempBuf; Buf_Init(&tempBuf); SzAr_Init(&tempAr); res = SzReadAndDecodePackedStreams(inStream, &sd, &tempBuf, 1, p->startPosAfterHeader, &tempAr, allocTemp); SzAr_Free(&tempAr, allocTemp); if (res != SZ_OK) { Buf_Free(&tempBuf, allocTemp); } else { Buf_Free(&buf, allocTemp); buf.data = tempBuf.data; buf.size = tempBuf.size; sd.Data = buf.data; sd.Size = buf.size; res = ReadID(&sd, &type); } } if (res == SZ_OK) { if (type == k7zIdHeader) { CSzData sd2; int ttt; for (ttt = 0; ttt < 1; ttt++) // for (ttt = 0; ttt < 40000; ttt++) { SzArEx_Free(p, allocMain); sd2 = sd; res = SzReadHeader(p, &sd2, inStream, allocMain, allocTemp ); if (res != SZ_OK) break; } // res = SzReadHeader(p, &sd, allocMain, allocTemp); } else res = SZ_ERROR_UNSUPPORTED; } } } Buf_Free(&buf, allocTemp); return res; } // #include SRes SzArEx_Open(CSzArEx *p, ILookInStream *inStream, ISzAlloc *allocMain, ISzAlloc *allocTemp) { SRes res = SzArEx_Open2(p, inStream, allocMain, allocTemp); if (res != SZ_OK) SzArEx_Free(p, allocMain); // printf ("\nrrr=%d\n", rrr); return res; } SRes SzArEx_Extract( const CSzArEx *p, ILookInStream *inStream, UInt32 fileIndex, UInt32 *blockIndex, Byte **tempBuf, size_t *outBufferSize, size_t *offset, size_t *outSizeProcessed, ISzAlloc *allocMain, ISzAlloc *allocTemp) { UInt32 folderIndex = p->FileIndexToFolderIndexMap[fileIndex]; SRes res = SZ_OK; *offset = 0; *outSizeProcessed = 0; if (folderIndex == (UInt32)-1) { IAlloc_Free(allocMain, *tempBuf); *blockIndex = folderIndex; *tempBuf = 0; *outBufferSize = 0; return SZ_OK; } if (*tempBuf == 0 || *blockIndex != folderIndex) { // UInt64 unpackSizeSpec = SzAr_GetFolderUnpackSize(&p->db, folderIndex); UInt64 unpackSizeSpec = p->UnpackPositions[p->FolderStartFileIndex[folderIndex + 1]] - p->UnpackPositions[p->FolderStartFileIndex[folderIndex]]; size_t unpackSize = (size_t)unpackSizeSpec; if (unpackSize != unpackSizeSpec) return SZ_ERROR_MEM; *blockIndex = folderIndex; IAlloc_Free(allocMain, *tempBuf); *tempBuf = 0; // RINOK(LookInStream_SeekTo(inStream, startOffset)); if (res == SZ_OK) { *outBufferSize = unpackSize; if (unpackSize != 0) { *tempBuf = (Byte *)IAlloc_Alloc(allocMain, unpackSize); if (*tempBuf == 0) res = SZ_ERROR_MEM; } if (res == SZ_OK) { res = SzAr_DecodeFolder(&p->db, folderIndex, inStream, p->dataPos, *tempBuf, unpackSize, allocTemp); if (res == SZ_OK) { if (SzBitWithVals_Check(&p->db.FolderCRCs, folderIndex)) { if (CrcCalc(*tempBuf, unpackSize) != p->db.FolderCRCs.Vals[folderIndex]) res = SZ_ERROR_CRC; } } } } } if (res == SZ_OK) { UInt64 unpackPos = p->UnpackPositions[fileIndex]; *offset = (size_t)(unpackPos - p->UnpackPositions[p->FolderStartFileIndex[folderIndex]]); *outSizeProcessed = (size_t)(p->UnpackPositions[fileIndex + 1] - unpackPos); if (*offset + *outSizeProcessed > *outBufferSize) return SZ_ERROR_FAIL; if (SzBitWithVals_Check(&p->CRCs, fileIndex) && CrcCalc(*tempBuf + *offset, *outSizeProcessed) != p->CRCs.Vals[fileIndex]) res = SZ_ERROR_CRC; } return res; } size_t SzArEx_GetFileNameUtf16(const CSzArEx *p, size_t fileIndex, UInt16 *dest) { size_t offs = p->FileNameOffsets[fileIndex]; size_t len = p->FileNameOffsets[fileIndex + 1] - offs; if (dest != 0) { size_t i; const Byte *src = p->FileNames + offs * 2; for (i = 0; i < len; i++) dest[i] = GetUi16(src + i * 2); } return len; } /* size_t SzArEx_GetFullNameLen(const CSzArEx *p, size_t fileIndex) { size_t len; if (!p->FileNameOffsets) return 1; len = 0; for (;;) { UInt32 parent = (UInt32)(Int32)-1; len += p->FileNameOffsets[fileIndex + 1] - p->FileNameOffsets[fileIndex]; if SzBitWithVals_Check(&p->Parents, fileIndex) parent = p->Parents.Vals[fileIndex]; if (parent == (UInt32)(Int32)-1) return len; fileIndex = parent; } } UInt16 *SzArEx_GetFullNameUtf16_Back(const CSzArEx *p, size_t fileIndex, UInt16 *dest) { Bool needSlash; if (!p->FileNameOffsets) { *(--dest) = 0; return dest; } needSlash = False; for (;;) { UInt32 parent = (UInt32)(Int32)-1; size_t curLen = p->FileNameOffsets[fileIndex + 1] - p->FileNameOffsets[fileIndex]; SzArEx_GetFileNameUtf16(p, fileIndex, dest - curLen); if (needSlash) *(dest - 1) = '/'; needSlash = True; dest -= curLen; if SzBitWithVals_Check(&p->Parents, fileIndex) parent = p->Parents.Vals[fileIndex]; if (parent == (UInt32)(Int32)-1) return dest; fileIndex = parent; } } */