// Rar2Decoder.cpp // According to unRAR license, this code may not be used to develop // a program that creates RAR archives #include "StdAfx.h" #include "Rar2Decoder.h" namespace NCompress { namespace NRar2 { namespace NMultimedia { Byte CFilter::Decode(int &channelDelta, Byte deltaByte) { D4 = D3; D3 = D2; D2 = LastDelta - D1; D1 = LastDelta; int predictedValue = ((8 * LastChar + K1 * D1 + K2 * D2 + K3 * D3 + K4 * D4 + K5 * channelDelta) >> 3); Byte realValue = (Byte)(predictedValue - deltaByte); { int i = ((int)(signed char)deltaByte) << 3; Dif[0] += abs(i); Dif[1] += abs(i - D1); Dif[2] += abs(i + D1); Dif[3] += abs(i - D2); Dif[4] += abs(i + D2); Dif[5] += abs(i - D3); Dif[6] += abs(i + D3); Dif[7] += abs(i - D4); Dif[8] += abs(i + D4); Dif[9] += abs(i - channelDelta); Dif[10] += abs(i + channelDelta); } channelDelta = LastDelta = (signed char)(realValue - LastChar); LastChar = realValue; if (((++ByteCount) & 0x1F) == 0) { UInt32 minDif = Dif[0]; UInt32 numMinDif = 0; Dif[0] = 0; for (unsigned i = 1; i < ARRAY_SIZE(Dif); i++) { if (Dif[i] < minDif) { minDif = Dif[i]; numMinDif = i; } Dif[i] = 0; } switch (numMinDif) { case 1: if (K1 >= -16) K1--; break; case 2: if (K1 < 16) K1++; break; case 3: if (K2 >= -16) K2--; break; case 4: if (K2 < 16) K2++; break; case 5: if (K3 >= -16) K3--; break; case 6: if (K3 < 16) K3++; break; case 7: if (K4 >= -16) K4--; break; case 8: if (K4 < 16) K4++; break; case 9: if (K5 >= -16) K5--; break; case 10:if (K5 < 16) K5++; break; } } return realValue; } } static const UInt32 kHistorySize = 1 << 20; static const UInt32 kWindowReservSize = (1 << 22) + 256; CDecoder::CDecoder(): m_IsSolid(false) { } void CDecoder::InitStructures() { m_MmFilter.Init(); for (unsigned i = 0; i < kNumRepDists; i++) m_RepDists[i] = 0; m_RepDistPtr = 0; m_LastLength = 0; memset(m_LastLevels, 0, kMaxTableSize); } UInt32 CDecoder::ReadBits(unsigned numBits) { return m_InBitStream.ReadBits(numBits); } #define RIF(x) { if (!(x)) return false; } bool CDecoder::ReadTables(void) { Byte levelLevels[kLevelTableSize]; Byte newLevels[kMaxTableSize]; m_AudioMode = (ReadBits(1) == 1); if (ReadBits(1) == 0) memset(m_LastLevels, 0, kMaxTableSize); unsigned numLevels; if (m_AudioMode) { m_NumChannels = ReadBits(2) + 1; if (m_MmFilter.CurrentChannel >= m_NumChannels) m_MmFilter.CurrentChannel = 0; numLevels = m_NumChannels * kMMTableSize; } else numLevels = kHeapTablesSizesSum; unsigned i; for (i = 0; i < kLevelTableSize; i++) levelLevels[i] = (Byte)ReadBits(4); RIF(m_LevelDecoder.Build(levelLevels)); i = 0; while (i < numLevels) { UInt32 sym = m_LevelDecoder.Decode(&m_InBitStream); if (sym < kTableDirectLevels) { newLevels[i] = (Byte)((sym + m_LastLevels[i]) & kLevelMask); i++; } else { if (sym == kTableLevelRepNumber) { unsigned t = ReadBits(2) + 3; for (unsigned reps = t; reps > 0 && i < numLevels; reps--, i++) newLevels[i] = newLevels[i - 1]; } else { unsigned num; if (sym == kTableLevel0Number) num = ReadBits(3) + 3; else if (sym == kTableLevel0Number2) num = ReadBits(7) + 11; else return false; for (; num > 0 && i < numLevels; num--) newLevels[i++] = 0; } } } if (m_AudioMode) for (i = 0; i < m_NumChannels; i++) { RIF(m_MMDecoders[i].Build(&newLevels[i * kMMTableSize])); } else { RIF(m_MainDecoder.Build(&newLevels[0])); RIF(m_DistDecoder.Build(&newLevels[kMainTableSize])); RIF(m_LenDecoder.Build(&newLevels[kMainTableSize + kDistTableSize])); } memcpy(m_LastLevels, newLevels, kMaxTableSize); return true; } bool CDecoder::ReadLastTables() { // it differs a little from pure RAR sources; // UInt64 ttt = m_InBitStream.GetProcessedSize() + 2; // + 2 works for: return 0xFF; in CInBuffer::ReadByte. if (m_InBitStream.GetProcessedSize() + 7 <= m_PackSize) // test it: probably incorrect; // if (m_InBitStream.GetProcessedSize() + 2 <= m_PackSize) // test it: probably incorrect; if (m_AudioMode) { UInt32 symbol = m_MMDecoders[m_MmFilter.CurrentChannel].Decode(&m_InBitStream); if (symbol == 256) return ReadTables(); if (symbol >= kMMTableSize) return false; } else { UInt32 sym = m_MainDecoder.Decode(&m_InBitStream); if (sym == kReadTableNumber) return ReadTables(); if (sym >= kMainTableSize) return false; } return true; } /* class CCoderReleaser { CDecoder *m_Coder; public: CCoderReleaser(CDecoder *coder): m_Coder(coder) {} ~CCoderReleaser() { m_Coder->ReleaseStreams(); } }; */ bool CDecoder::DecodeMm(UInt32 pos) { while (pos-- > 0) { UInt32 symbol = m_MMDecoders[m_MmFilter.CurrentChannel].Decode(&m_InBitStream); if (symbol == 256) return true; if (symbol >= kMMTableSize) return false; /* Byte byPredict = m_Predictor.Predict(); Byte byReal = (Byte)(byPredict - (Byte)symbol); m_Predictor.Update(byReal, byPredict); */ Byte byReal = m_MmFilter.Decode((Byte)symbol); m_OutWindowStream.PutByte(byReal); if (++m_MmFilter.CurrentChannel == m_NumChannels) m_MmFilter.CurrentChannel = 0; } return true; } bool CDecoder::DecodeLz(Int32 pos) { while (pos > 0) { UInt32 sym = m_MainDecoder.Decode(&m_InBitStream); UInt32 length, distance; if (sym < 256) { m_OutWindowStream.PutByte(Byte(sym)); pos--; continue; } else if (sym >= kMatchNumber) { sym -= kMatchNumber; length = kNormalMatchMinLen + UInt32(kLenStart[sym]) + m_InBitStream.ReadBits(kLenDirectBits[sym]); sym = m_DistDecoder.Decode(&m_InBitStream); if (sym >= kDistTableSize) return false; distance = kDistStart[sym] + m_InBitStream.ReadBits(kDistDirectBits[sym]); if (distance >= kDistLimit3) { length += 2 - ((distance - kDistLimit4) >> 31); // length++; // if (distance >= kDistLimit4) // length++; } } else if (sym == kRepBothNumber) { length = m_LastLength; if (length == 0) return false; distance = m_RepDists[(m_RepDistPtr + 4 - 1) & 3]; } else if (sym < kLen2Number) { distance = m_RepDists[(m_RepDistPtr - (sym - kRepNumber + 1)) & 3]; sym = m_LenDecoder.Decode(&m_InBitStream); if (sym >= kLenTableSize) return false; length = 2 + kLenStart[sym] + m_InBitStream.ReadBits(kLenDirectBits[sym]); if (distance >= kDistLimit2) { length++; if (distance >= kDistLimit3) { length += 2 - ((distance - kDistLimit4) >> 31); // length++; // if (distance >= kDistLimit4) // length++; } } } else if (sym < kReadTableNumber) { sym -= kLen2Number; distance = kLen2DistStarts[sym] + m_InBitStream.ReadBits(kLen2DistDirectBits[sym]); length = 2; } else if (sym == kReadTableNumber) return true; else return false; m_RepDists[m_RepDistPtr++ & 3] = distance; m_LastLength = length; if (!m_OutWindowStream.CopyBlock(distance, length)) return false; pos -= length; } return true; } HRESULT CDecoder::CodeReal(ISequentialInStream *inStream, ISequentialOutStream *outStream, const UInt64 *inSize, const UInt64 *outSize, ICompressProgressInfo *progress) { if (inSize == NULL || outSize == NULL) return E_INVALIDARG; if (!m_OutWindowStream.Create(kHistorySize)) return E_OUTOFMEMORY; if (!m_InBitStream.Create(1 << 20)) return E_OUTOFMEMORY; m_PackSize = *inSize; UInt64 pos = 0, unPackSize = *outSize; m_OutWindowStream.SetStream(outStream); m_OutWindowStream.Init(m_IsSolid); m_InBitStream.SetStream(inStream); m_InBitStream.Init(); // CCoderReleaser coderReleaser(this); if (!m_IsSolid) { InitStructures(); if (unPackSize == 0) { if (m_InBitStream.GetProcessedSize() + 2 <= m_PackSize) // test it: probably incorrect; if (!ReadTables()) return S_FALSE; return S_OK; } if (!ReadTables()) return S_FALSE; } UInt64 startPos = m_OutWindowStream.GetProcessedSize(); while (pos < unPackSize) { UInt32 blockSize = 1 << 20; if (blockSize > unPackSize - pos) blockSize = (UInt32)(unPackSize - pos); UInt64 blockStartPos = m_OutWindowStream.GetProcessedSize(); if (m_AudioMode) { if (!DecodeMm(blockSize)) return S_FALSE; } else { if (!DecodeLz((Int32)blockSize)) return S_FALSE; } UInt64 globalPos = m_OutWindowStream.GetProcessedSize(); pos = globalPos - blockStartPos; if (pos < blockSize) if (!ReadTables()) return S_FALSE; pos = globalPos - startPos; if (progress != 0) { UInt64 packSize = m_InBitStream.GetProcessedSize(); RINOK(progress->SetRatioInfo(&packSize, &pos)); } } if (pos > unPackSize) return S_FALSE; if (!ReadLastTables()) return S_FALSE; return m_OutWindowStream.Flush(); } STDMETHODIMP CDecoder::Code(ISequentialInStream *inStream, ISequentialOutStream *outStream, const UInt64 *inSize, const UInt64 *outSize, ICompressProgressInfo *progress) { try { return CodeReal(inStream, outStream, inSize, outSize, progress); } catch(const CInBufferException &e) { return e.ErrorCode; } catch(const CLzOutWindowException &e) { return e.ErrorCode; } catch(...) { return S_FALSE; } } STDMETHODIMP CDecoder::SetDecoderProperties2(const Byte *data, UInt32 size) { if (size < 1) return E_INVALIDARG; m_IsSolid = ((data[0] & 1) != 0); return S_OK; } }}