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// DeflateDecoder.cpp
#include "StdAfx.h"
#include "DeflateDecoder.h"
namespace NCompress {
namespace NDeflate {
namespace NDecoder {
static const int kLenIdFinished = -1;
static const int kLenIdNeedInit = -2;
CCoder::CCoder(bool deflate64Mode, bool deflateNSIS):
_deflate64Mode(deflate64Mode),
_deflateNSIS(deflateNSIS),
_keepHistory(false),
_needInitInStream(true),
ZlibMode(false) {}
UInt32 CCoder::ReadBits(int numBits)
{
return m_InBitStream.ReadBits(numBits);
}
bool CCoder::DeCodeLevelTable(Byte *values, int numSymbols)
{
int i = 0;
do
{
UInt32 number = m_LevelDecoder.DecodeSymbol(&m_InBitStream);
if (number < kTableDirectLevels)
values[i++] = (Byte)number;
else if (number < kLevelTableSize)
{
if (number == kTableLevelRepNumber)
{
if (i == 0)
return false;
int num = ReadBits(2) + 3;
for (; num > 0 && i < numSymbols; num--, i++)
values[i] = values[i - 1];
}
else
{
int num;
if (number == kTableLevel0Number)
num = ReadBits(3) + 3;
else
num = ReadBits(7) + 11;
for (;num > 0 && i < numSymbols; num--)
values[i++] = 0;
}
}
else
return false;
}
while(i < numSymbols);
return true;
}
#define RIF(x) { if (!(x)) return false; }
bool CCoder::ReadTables(void)
{
m_FinalBlock = (ReadBits(kFinalBlockFieldSize) == NFinalBlockField::kFinalBlock);
UInt32 blockType = ReadBits(kBlockTypeFieldSize);
if (blockType > NBlockType::kDynamicHuffman)
return false;
if (blockType == NBlockType::kStored)
{
m_StoredMode = true;
m_InBitStream.AlignToByte();
m_StoredBlockSize = ReadBits(kStoredBlockLengthFieldSize);
if (_deflateNSIS)
return true;
return (m_StoredBlockSize == (UInt16)~ReadBits(kStoredBlockLengthFieldSize));
}
m_StoredMode = false;
CLevels levels;
if (blockType == NBlockType::kFixedHuffman)
{
levels.SetFixedLevels();
_numDistLevels = _deflate64Mode ? kDistTableSize64 : kDistTableSize32;
}
else
{
int numLitLenLevels = ReadBits(kNumLenCodesFieldSize) + kNumLitLenCodesMin;
_numDistLevels = ReadBits(kNumDistCodesFieldSize) + kNumDistCodesMin;
int numLevelCodes = ReadBits(kNumLevelCodesFieldSize) + kNumLevelCodesMin;
if (!_deflate64Mode)
if (_numDistLevels > kDistTableSize32)
return false;
Byte levelLevels[kLevelTableSize];
for (int i = 0; i < kLevelTableSize; i++)
{
int position = kCodeLengthAlphabetOrder[i];
if(i < numLevelCodes)
levelLevels[position] = (Byte)ReadBits(kLevelFieldSize);
else
levelLevels[position] = 0;
}
RIF(m_LevelDecoder.SetCodeLengths(levelLevels));
Byte tmpLevels[kFixedMainTableSize + kFixedDistTableSize];
if (!DeCodeLevelTable(tmpLevels, numLitLenLevels + _numDistLevels))
return false;
levels.SubClear();
memcpy(levels.litLenLevels, tmpLevels, numLitLenLevels);
memcpy(levels.distLevels, tmpLevels + numLitLenLevels, _numDistLevels);
}
RIF(m_MainDecoder.SetCodeLengths(levels.litLenLevels));
return m_DistDecoder.SetCodeLengths(levels.distLevels);
}
HRESULT CCoder::CodeSpec(UInt32 curSize)
{
if (_remainLen == kLenIdFinished)
return S_OK;
if (_remainLen == kLenIdNeedInit)
{
if (!_keepHistory)
if (!m_OutWindowStream.Create(_deflate64Mode ? kHistorySize64: kHistorySize32))
return E_OUTOFMEMORY;
RINOK(InitInStream(_needInitInStream));
m_OutWindowStream.Init(_keepHistory);
m_FinalBlock = false;
_remainLen = 0;
_needReadTable = true;
}
if (curSize == 0)
return S_OK;
while(_remainLen > 0 && curSize > 0)
{
_remainLen--;
Byte b = m_OutWindowStream.GetByte(_rep0);
m_OutWindowStream.PutByte(b);
curSize--;
}
while(curSize > 0)
{
if (_needReadTable)
{
if (m_FinalBlock)
{
_remainLen = kLenIdFinished;
break;
}
if (!ReadTables())
return S_FALSE;
_needReadTable = false;
}
if(m_StoredMode)
{
for (; m_StoredBlockSize > 0 && curSize > 0; m_StoredBlockSize--, curSize--)
m_OutWindowStream.PutByte(m_InBitStream.ReadByte());
_needReadTable = (m_StoredBlockSize == 0);
continue;
}
while(curSize > 0)
{
if (m_InBitStream.NumExtraBytes > 4)
return S_FALSE;
UInt32 number = m_MainDecoder.DecodeSymbol(&m_InBitStream);
if (number < 0x100)
{
m_OutWindowStream.PutByte((Byte)number);
curSize--;
continue;
}
else if (number == kSymbolEndOfBlock)
{
_needReadTable = true;
break;
}
else if (number < kMainTableSize)
{
number -= kSymbolMatch;
UInt32 len;
{
int numBits;
if (_deflate64Mode)
{
len = kLenStart64[number];
numBits = kLenDirectBits64[number];
}
else
{
len = kLenStart32[number];
numBits = kLenDirectBits32[number];
}
len += kMatchMinLen + m_InBitStream.ReadBits(numBits);
}
UInt32 locLen = len;
if (locLen > curSize)
locLen = (UInt32)curSize;
number = m_DistDecoder.DecodeSymbol(&m_InBitStream);
if (number >= _numDistLevels)
return S_FALSE;
UInt32 distance = kDistStart[number] + m_InBitStream.ReadBits(kDistDirectBits[number]);
if (!m_OutWindowStream.CopyBlock(distance, locLen))
return S_FALSE;
curSize -= locLen;
len -= locLen;
if (len != 0)
{
_remainLen = (Int32)len;
_rep0 = distance;
break;
}
}
else
return S_FALSE;
}
}
return S_OK;
}
#ifdef _NO_EXCEPTIONS
#define DEFLATE_TRY_BEGIN
#define DEFLATE_TRY_END
#else
#define DEFLATE_TRY_BEGIN try {
#define DEFLATE_TRY_END } \
catch(const CInBufferException &e) { return e.ErrorCode; } \
catch(const CLzOutWindowException &e) { return e.ErrorCode; } \
catch(...) { return S_FALSE; }
#endif
HRESULT CCoder::CodeReal(ISequentialOutStream *outStream,
const UInt64 *outSize, ICompressProgressInfo *progress)
{
DEFLATE_TRY_BEGIN
m_OutWindowStream.SetStream(outStream);
CCoderReleaser flusher(this);
const UInt64 inStart = _needInitInStream ? 0 : m_InBitStream.GetProcessedSize();
const UInt64 start = m_OutWindowStream.GetProcessedSize();
for (;;)
{
UInt32 curSize = 1 << 18;
if (outSize != 0)
{
const UInt64 rem = *outSize - (m_OutWindowStream.GetProcessedSize() - start);
if (curSize > rem)
curSize = (UInt32)rem;
}
if (curSize == 0)
break;
RINOK(CodeSpec(curSize));
if (_remainLen == kLenIdFinished)
break;
if (progress != NULL)
{
const UInt64 inSize = m_InBitStream.GetProcessedSize() - inStart;
const UInt64 nowPos64 = m_OutWindowStream.GetProcessedSize() - start;
RINOK(progress->SetRatioInfo(&inSize, &nowPos64));
}
}
if (_remainLen == kLenIdFinished && ZlibMode)
{
m_InBitStream.AlignToByte();
for (int i = 0; i < 4; i++)
ZlibFooter[i] = m_InBitStream.ReadByte();
}
flusher.NeedFlush = false;
HRESULT res = Flush();
if (res == S_OK && InputEofError())
return S_FALSE;
return res;
DEFLATE_TRY_END
}
HRESULT CCoder::Code(ISequentialInStream *inStream, ISequentialOutStream *outStream,
const UInt64 * /* inSize */, const UInt64 *outSize, ICompressProgressInfo *progress)
{
SetInStream(inStream);
SetOutStreamSize(outSize);
HRESULT res = CodeReal(outStream, outSize, progress);
ReleaseInStream();
return res;
}
STDMETHODIMP CCoder::GetInStreamProcessedSize(UInt64 *value)
{
if (value == NULL)
return E_INVALIDARG;
*value = m_InBitStream.GetProcessedSize();
return S_OK;
}
STDMETHODIMP CCoder::SetInStream(ISequentialInStream *inStream)
{
m_InBitStream.SetStream(inStream);
return S_OK;
}
STDMETHODIMP CCoder::ReleaseInStream()
{
m_InBitStream.ReleaseStream();
return S_OK;
}
STDMETHODIMP CCoder::SetOutStreamSize(const UInt64 * /* outSize */)
{
_remainLen = kLenIdNeedInit;
_needInitInStream = true;
m_OutWindowStream.Init(_keepHistory);
return S_OK;
}
#ifndef NO_READ_FROM_CODER
STDMETHODIMP CCoder::Read(void *data, UInt32 size, UInt32 *processedSize)
{
DEFLATE_TRY_BEGIN
if (processedSize)
*processedSize = 0;
const UInt64 startPos = m_OutWindowStream.GetProcessedSize();
m_OutWindowStream.SetMemStream((Byte *)data);
RINOK(CodeSpec(size));
if (processedSize)
*processedSize = (UInt32)(m_OutWindowStream.GetProcessedSize() - startPos);
return Flush();
DEFLATE_TRY_END
}
#endif
STDMETHODIMP CCoder::CodeResume(ISequentialOutStream *outStream, const UInt64 *outSize, ICompressProgressInfo *progress)
{
_remainLen = kLenIdNeedInit;
m_OutWindowStream.Init(_keepHistory);
return CodeReal(outStream, outSize, progress);
}
}}}
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