uint64 KaxInternalBlock::ReadInternalHead(IOCallback & input) { binary Buffer[5], *cursor = Buffer; uint64 Result = input.read(cursor, 4); if (Result != 4) return Result; // update internal values TrackNumber = *cursor++; if ((TrackNumber & 0x80) == 0) { // there is extra data if ((TrackNumber & 0x40) == 0) { // We don't support track numbers that large ! return Result; } Result += input.read(&Buffer[4], 1); TrackNumber = (TrackNumber & 0x3F) << 8; TrackNumber += *cursor++; } else { TrackNumber &= 0x7F; } big_int16 b16; b16.Eval(cursor); assert(ParentCluster != NULL); Timecode = ParentCluster->GetBlockGlobalTimecode(int16(b16)); bLocalTimecodeUsed = false; cursor += 2; return Result; }
filepos_t EbmlBinary::ReadData(IOCallback & input, ScopeMode ReadFully) { if (Data != NULL) free(Data); if (ReadFully == SCOPE_NO_DATA || !GetSize()) { Data = NULL; return GetSize(); } Data = (binary *)malloc(GetSize()); if (Data == NULL) throw CRTError(std::string("Error allocating data")); SetValueIsSet(); return input.read(Data, GetSize()); }
/*! \todo better zero copy handling */ filepos_t KaxInternalBlock::ReadData(IOCallback & input, ScopeMode ReadFully) { filepos_t Result; FirstFrameLocation = input.getFilePointer(); // will be updated accordingly below SetValueIsSet(false); try { if (ReadFully == SCOPE_ALL_DATA) { Result = EbmlBinary::ReadData(input, ReadFully); if (Result != GetSize()) throw SafeReadIOCallback::EndOfStreamX(GetSize() - Result); binary *BufferStart = EbmlBinary::GetBuffer(); SafeReadIOCallback Mem(*this); uint8 BlockHeadSize = 4; // update internal values TrackNumber = Mem.GetUInt8(); if ((TrackNumber & 0x80) == 0) { // there is extra data if ((TrackNumber & 0x40) == 0) { // We don't support track numbers that large ! throw SafeReadIOCallback::EndOfStreamX(0); } TrackNumber = (TrackNumber & 0x3F) << 8; TrackNumber += Mem.GetUInt8(); BlockHeadSize++; } else { TrackNumber &= 0x7F; } LocalTimecode = int16(Mem.GetUInt16BE()); bLocalTimecodeUsed = true; uint8 Flags = Mem.GetUInt8(); if (EbmlId(*this) == EBML_ID(KaxSimpleBlock)) { bIsKeyframe = (Flags & 0x80) != 0; bIsDiscardable = (Flags & 0x01) != 0; } mInvisible = (Flags & 0x08) >> 3; mLacing = LacingType((Flags & 0x06) >> 1); // put all Frames in the list if (mLacing == LACING_NONE) { FirstFrameLocation += Mem.GetPosition(); DataBuffer * soloFrame = new DataBuffer(BufferStart + Mem.GetPosition(), GetSize() - BlockHeadSize); myBuffers.push_back(soloFrame); SizeList.resize(1); SizeList[0] = GetSize() - BlockHeadSize; } else { // read the number of frames in the lace uint32 LastBufferSize = GetSize() - BlockHeadSize - 1; // 1 for number of frame uint8 FrameNum = Mem.GetUInt8(); // number of frames in the lace - 1 // read the list of frame sizes uint8 Index; int32 FrameSize; uint32 SizeRead; uint64 SizeUnknown; SizeList.resize(FrameNum + 1); switch (mLacing) { case LACING_XIPH: for (Index=0; Index<FrameNum; Index++) { // get the size of the frame FrameSize = 0; uint8 Value; do { Value = Mem.GetUInt8(); FrameSize += Value; LastBufferSize--; } while (Value == 0xFF); SizeList[Index] = FrameSize; LastBufferSize -= FrameSize; } SizeList[Index] = LastBufferSize; break; case LACING_EBML: SizeRead = LastBufferSize; FrameSize = ReadCodedSizeValue(BufferStart + Mem.GetPosition(), SizeRead, SizeUnknown); SizeList[0] = FrameSize; Mem.Skip(SizeRead); LastBufferSize -= FrameSize + SizeRead; for (Index=1; Index<FrameNum; Index++) { // get the size of the frame SizeRead = LastBufferSize; FrameSize += ReadCodedSizeSignedValue(BufferStart + Mem.GetPosition(), SizeRead, SizeUnknown); SizeList[Index] = FrameSize; Mem.Skip(SizeRead); LastBufferSize -= FrameSize + SizeRead; } if (Index <= FrameNum) // Safety check if FrameNum == 0 SizeList[Index] = LastBufferSize; break; case LACING_FIXED: for (Index=0; Index<=FrameNum; Index++) { // get the size of the frame SizeList[Index] = LastBufferSize / (FrameNum + 1); } break; default: // other lacing not supported assert(0); } FirstFrameLocation += Mem.GetPosition(); for (Index=0; Index<=FrameNum; Index++) { DataBuffer * lacedFrame = new DataBuffer(BufferStart + Mem.GetPosition(), SizeList[Index]); myBuffers.push_back(lacedFrame); Mem.Skip(SizeList[Index]); } } binary *BufferEnd = BufferStart + GetSize(); size_t NumFrames = myBuffers.size(); // Sanity checks for frame pointers and boundaries. for (size_t Index = 0; Index < NumFrames; ++Index) { binary *FrameStart = myBuffers[Index]->Buffer(); binary *FrameEnd = FrameStart + myBuffers[Index]->Size(); binary *ExpectedEnd = (Index + 1) < NumFrames ? myBuffers[Index + 1]->Buffer() : BufferEnd; if ((FrameStart < BufferStart) || (FrameEnd > BufferEnd) || (FrameEnd != ExpectedEnd)) throw SafeReadIOCallback::EndOfStreamX(0); } SetValueIsSet(); } else if (ReadFully == SCOPE_PARTIAL_DATA) { binary _TempHead[5]; Result = input.read(_TempHead, 5); if (Result != 5) throw SafeReadIOCallback::EndOfStreamX(0); binary *cursor = _TempHead; binary *_tmpBuf; uint8 BlockHeadSize = 4; // update internal values TrackNumber = *cursor++; if ((TrackNumber & 0x80) == 0) { // there is extra data if ((TrackNumber & 0x40) == 0) { // We don't support track numbers that large ! return Result; } TrackNumber = (TrackNumber & 0x3F) << 8; TrackNumber += *cursor++; BlockHeadSize++; } else { TrackNumber &= 0x7F; } big_int16 b16; b16.Eval(cursor); LocalTimecode = int16(b16); bLocalTimecodeUsed = true; cursor += 2; if (EbmlId(*this) == EBML_ID(KaxSimpleBlock)) { bIsKeyframe = (*cursor & 0x80) != 0; bIsDiscardable = (*cursor & 0x01) != 0; } mInvisible = (*cursor & 0x08) >> 3; mLacing = LacingType((*cursor++ & 0x06) >> 1); if (cursor == &_TempHead[4]) { _TempHead[0] = _TempHead[4]; } else { Result += input.read(_TempHead, 1); } FirstFrameLocation += cursor - _TempHead; // put all Frames in the list if (mLacing != LACING_NONE) { // read the number of frames in the lace uint32 LastBufferSize = GetSize() - BlockHeadSize - 1; // 1 for number of frame uint8 FrameNum = _TempHead[0]; // number of frames in the lace - 1 // read the list of frame sizes uint8 Index; int32 FrameSize; uint32 SizeRead; uint64 SizeUnknown; SizeList.resize(FrameNum + 1); switch (mLacing) { case LACING_XIPH: for (Index=0; Index<FrameNum; Index++) { // get the size of the frame FrameSize = 0; do { Result += input.read(_TempHead, 1); FrameSize += uint8(_TempHead[0]); LastBufferSize--; FirstFrameLocation++; } while (_TempHead[0] == 0xFF); FirstFrameLocation++; SizeList[Index] = FrameSize; LastBufferSize -= FrameSize; } SizeList[Index] = LastBufferSize; break; case LACING_EBML: SizeRead = LastBufferSize; cursor = _tmpBuf = new binary[FrameNum*4]; /// \warning assume the mean size will be coded in less than 4 bytes Result += input.read(cursor, FrameNum*4); FrameSize = ReadCodedSizeValue(cursor, SizeRead, SizeUnknown); SizeList[0] = FrameSize; cursor += SizeRead; LastBufferSize -= FrameSize + SizeRead; for (Index=1; Index<FrameNum; Index++) { // get the size of the frame SizeRead = LastBufferSize; FrameSize += ReadCodedSizeSignedValue(cursor, SizeRead, SizeUnknown); SizeList[Index] = FrameSize; cursor += SizeRead; LastBufferSize -= FrameSize + SizeRead; } FirstFrameLocation += cursor - _tmpBuf; SizeList[Index] = LastBufferSize; delete [] _tmpBuf; break; case LACING_FIXED: for (Index=0; Index<=FrameNum; Index++) { // get the size of the frame SizeList[Index] = LastBufferSize / (FrameNum + 1); } break; default: // other lacing not supported assert(0); } } else { SizeList.resize(1); SizeList[0] = GetSize() - BlockHeadSize; } SetValueIsSet(false); Result = GetSize(); } else {