Example #1
1
bool LZMADecodeFile ( const char *fromFile, const char *toFile, CProgressInfo7Zip *progress )
{
	CMyComPtr<ISequentialInStream> inStream;
	CInFileStream *inStreamSpec = new CInFileStream;
	inStream = inStreamSpec;

	if ( !inStreamSpec->Open ( GetSystemString(fromFile) ) )
		return false;

	CMyComPtr<ISequentialOutStream> outStream;
	COutFileStream *outStreamSpec = new COutFileStream;
	outStream = outStreamSpec;
	if ( !outStreamSpec->Create ( GetSystemString(toFile), true ) )
		return false;


	NCompress::NLZMA::CDecoder *decoderSpec = new NCompress::NLZMA::CDecoder;

	CMyComPtr<ICompressCoder> decoder = decoderSpec;

	const UInt32 kPropertiesSize = 5;
	Byte properties[kPropertiesSize];
	UInt32 processedSize;
	
	if ( ReadStream (inStream, properties, kPropertiesSize, &processedSize) != S_OK )
		return false;

	if ( processedSize != kPropertiesSize )
		return false;

	if ( decoderSpec->SetDecoderProperties2(properties, kPropertiesSize) != S_OK )
		return false;

	UInt64 fileSize = 0;
	for (int i = 0; i < 8; i++)
	{
	  Byte b;
	  if ( inStream->Read(&b, 1, &processedSize) != S_OK )
		  return false;

	  if ( processedSize != 1 )
		  return false;
	  fileSize |= ((UInt64)b) << (8 * i);
	}

	if ( progress )
	{
		progress->Init();
		progress->ApprovedStart = 1 << 21;
		progress->SetMax ( fileSize );
	}

	if ( decoder->Code(inStream, outStream, 0, &fileSize, progress) != S_OK )
		// decoder error
		return false;

	return true;
}
Example #2
0
void decode(NCompress::NLzma::CDecoder *decoderSpec,
		CMyComPtr<ISequentialInStream> inStream,
		CMyComPtr<ISequentialOutStream> outStream)
{
	const UInt32 kPropertiesSize = 5;
	Byte properties[kPropertiesSize];
	UInt32 processedSize;
	UInt64 fileSize = 0;

	if (inStream->Read(properties, kPropertiesSize, &processedSize) != S_OK)
		throw Exception("Read error");
	if (processedSize != kPropertiesSize)
		throw Exception("Read error");
	if (decoderSpec->SetDecoderProperties2(properties, kPropertiesSize) != S_OK)
		throw Exception("SetDecoderProperties() error");

	for (int i = 0; i < 8; i++)
	{
		Byte b;

		if (inStream->Read(&b, sizeof(b), &processedSize) != S_OK)
			throw Exception("Read error");
		if (processedSize != 1)
			throw Exception("Read error");

		fileSize |= ((UInt64)b) << (8 * i);
	}

	if (decoderSpec->Code(inStream, outStream, 0, &fileSize, 0) != S_OK)
		throw Exception("Decoder error");
}
Example #3
0
unsigned char *LZMADecodeData ( unsigned char *fromData, long fromSize, long &toSize, CProgressInfo7Zip *progress )
{
	CMyComPtr<ISequentialInStream> inStream;
	CInDataStream *inStreamSpec = new CInDataStream;
	inStream = inStreamSpec;

	inStreamSpec->LoadData ( fromData, fromSize );

	NCompress::NLZMA::CDecoder *decoderSpec = new NCompress::NLZMA::CDecoder;

	CMyComPtr<ICompressCoder> decoder = decoderSpec;

	const UInt32 kPropertiesSize = 5;
	Byte properties[kPropertiesSize];
	UInt32 processedSize;
	
	if ( ReadStream (inStream, properties, kPropertiesSize, &processedSize) != S_OK )
		return NULL;

	if ( processedSize != kPropertiesSize )
		return NULL;

	if ( decoderSpec->SetDecoderProperties2(properties, kPropertiesSize) != S_OK )
		return NULL;

	UInt64 fileSize = 0;
	for (int i = 0; i < 8; i++)
	{
	  Byte b;
	  if ( inStream->Read(&b, 1, &processedSize) != S_OK )
		  return NULL;

	  if ( processedSize != 1 )
		  return NULL;
	  fileSize |= ((UInt64)b) << (8 * i);
	}

	CMyComPtr<ISequentialOutStream> outStream;
	COutDataStream *outStreamSpec = new COutDataStream;
	outStream = outStreamSpec;
	outStreamSpec->Create ( fileSize );

//	CProgressInfo *progressInfoSpec = new CProgressInfo;
//	CMyComPtr<ICompressProgressInfo> progressInfo = progress;

	if ( progress )
	{
		progress->Init();
		progress->ApprovedStart = 1 << 21;
		progress->SetMax ( fileSize );
	}

	if ( decoder->Code(inStream, outStream, 0, &fileSize, progress) != S_OK )
		// decoder error
		return NULL;

	toSize = outStreamSpec->GetCurrentSize ();
	return outStreamSpec->GetData ();
}
Example #4
0
static bool ReadStream(CMyComPtr<IInStream> & inStream, Int64 offset, UINT32 seekOrigin, CByteBuffer & signature)
{
  UInt64 savedPosition = 0;
  UInt64 newPosition = 0;
#if MY_VER_MAJOR >= 15
  UInt32 readCount = signature.Size();
#else
  UInt32 readCount = signature.GetCapacity();
#endif
  unsigned char * buf = signature;

  if (S_OK != inStream->Seek(0, FILE_CURRENT, &savedPosition))
    return false;

  if (S_OK != inStream->Seek(offset, seekOrigin, &newPosition)) {
    inStream->Seek(savedPosition, FILE_BEGIN, &newPosition); //restore pos
    return false;
  }

  while (readCount > 0) {
    UInt32 processedCount = 0;

    if (S_OK != inStream->Read(buf, readCount, &processedCount)) {
      inStream->Seek(savedPosition, FILE_BEGIN, &newPosition); //restore pos
      return false;
    }

    if (processedCount == 0)
      break;

    readCount -= processedCount;
    buf += processedCount;
  }

  inStream->Seek(savedPosition, FILE_BEGIN, &newPosition); //restore pos

  return readCount == 0;
}
Example #5
0
int main2(int n, const char *args[])
{
  fprintf(stderr, "\nLZMA 4.27 Copyright (c) 1999-2005 Igor Pavlov  2005-08-07\n");

  if (n == 1)
  {
    PrintHelp();
    return 0;
  }

  if (sizeof(Byte) != 1 || sizeof(UInt32) < 4 || sizeof(UInt64) < 4)
  {
    fprintf(stderr, "Unsupported base types. Edit Common/Types.h and recompile");
    return 1;
  }   

  UStringVector commandStrings;
  WriteArgumentsToStringList(n, args, commandStrings);
  CParser parser(kNumSwitches);
  try
  {
    parser.ParseStrings(kSwitchForms, commandStrings);
  }
  catch(...) 
  {
    IncorrectCommand();
  }

  if(parser[NKey::kHelp1].ThereIs || parser[NKey::kHelp2].ThereIs)
  {
    PrintHelp();
    return 0;
  }
  const UStringVector &nonSwitchStrings = parser.NonSwitchStrings;

  int paramIndex = 0;
  if (paramIndex >= nonSwitchStrings.Size())
    IncorrectCommand();
  const UString &command = nonSwitchStrings[paramIndex++]; 

  bool dictionaryIsDefined = false;
  UInt32 dictionary = 1 << 21;
  if(parser[NKey::kDictionary].ThereIs)
  {
    UInt32 dicLog;
    if (!GetNumber(parser[NKey::kDictionary].PostStrings[0], dicLog))
      IncorrectCommand();
    dictionary = 1 << dicLog;
    dictionaryIsDefined = true;
  }
  UString mf = L"BT4";
  if (parser[NKey::kMatchFinder].ThereIs)
    mf = parser[NKey::kMatchFinder].PostStrings[0];

  if (command.CompareNoCase(L"b") == 0)
  {
    const UInt32 kNumDefaultItereations = 10;
    UInt32 numIterations = kNumDefaultItereations;
    {
      if (paramIndex < nonSwitchStrings.Size())
        if (!GetNumber(nonSwitchStrings[paramIndex++], numIterations))
          numIterations = kNumDefaultItereations;
    }
    return LzmaBenchmark(stderr, numIterations, dictionary, 
        mf.CompareNoCase(L"BT4") == 0);
  }

  bool encodeMode = false;
  if (command.CompareNoCase(L"e") == 0)
    encodeMode = true;
  else if (command.CompareNoCase(L"d") == 0)
    encodeMode = false;
  else
    IncorrectCommand();

  bool stdInMode = parser[NKey::kStdIn].ThereIs;
  bool stdOutMode = parser[NKey::kStdOut].ThereIs;

  CMyComPtr<ISequentialInStream> inStream;
  CInFileStream *inStreamSpec = 0;
  if (stdInMode)
  {
    inStream = new CStdInFileStream;
    MY_SET_BINARY_MODE(stdin);
  }
  else
  {
    if (paramIndex >= nonSwitchStrings.Size())
      IncorrectCommand();
    const UString &inputName = nonSwitchStrings[paramIndex++]; 
    inStreamSpec = new CInFileStream;
    inStream = inStreamSpec;
    if (!inStreamSpec->Open(GetSystemString(inputName)))
    {
      fprintf(stderr, "\nError: can not open input file %s\n", 
          (const char *)GetOemString(inputName));
      return 1;
    }
  }

  CMyComPtr<ISequentialOutStream> outStream;
  if (stdOutMode)
  {
    outStream = new CStdOutFileStream;
    MY_SET_BINARY_MODE(stdout);
  }
  else
  {
    if (paramIndex >= nonSwitchStrings.Size())
      IncorrectCommand();
    const UString &outputName = nonSwitchStrings[paramIndex++]; 
    COutFileStream *outStreamSpec = new COutFileStream;
    outStream = outStreamSpec;
    if (!outStreamSpec->Create(GetSystemString(outputName), true))
    {
      fprintf(stderr, "\nError: can not open output file %s\n", 
        (const char *)GetOemString(outputName));
      return 1;
    }
  }

  if (parser[NKey::kFilter86].ThereIs)
  {
    // -f86 switch is for x86 filtered mode: BCJ + LZMA.
    if (parser[NKey::kEOS].ThereIs || stdInMode)
      throw "Can not use stdin in this mode";
    UInt64 fileSize;
    inStreamSpec->File.GetLength(fileSize);
    if (fileSize > 0xF0000000)
      throw "File is too big";
    UInt32 inSize = (UInt32)fileSize;
    Byte *inBuffer = 0;
    if (inSize != 0)
    {
      inBuffer = (Byte *)MyAlloc((size_t)inSize); 
      if (inBuffer == 0)
        throw kCantAllocate;
    }
    
    UInt32 processedSize;
    if (inStream->Read(inBuffer, (UInt32)inSize, &processedSize) != S_OK)
      throw "Can not read";
    if ((UInt32)inSize != processedSize)
      throw "Read size error";

    Byte *outBuffer = 0;
    size_t outSizeProcessed;
    if (encodeMode)
    {
      // we allocate 105% of original size for output buffer
      size_t outSize = (size_t)fileSize / 20 * 21 + (1 << 16);
      if (outSize != 0)
      {
        outBuffer = (Byte *)MyAlloc((size_t)outSize); 
        if (outBuffer == 0)
          throw kCantAllocate;
      }
      if (!dictionaryIsDefined)
        dictionary = 1 << 23;
      int res = LzmaRamEncode(inBuffer, inSize, outBuffer, outSize, &outSizeProcessed, 
          dictionary, SZ_FILTER_AUTO);
      if (res != 0)
      {
        fprintf(stderr, "\nEncoder error = %d\n", (int)res);
        return 1;
      }
    }
    else
    {
      size_t outSize;
      if (LzmaRamGetUncompressedSize(inBuffer, inSize, &outSize) != 0)
        throw "data error";
      if (outSize != 0)
      {
        outBuffer = (Byte *)MyAlloc(outSize); 
        if (outBuffer == 0)
          throw kCantAllocate;
      }
      int res = LzmaRamDecompress(inBuffer, inSize, outBuffer, outSize, &outSizeProcessed, malloc, free);
      if (res != 0)
        throw "LzmaDecoder error";
    }
    if (outStream->Write(outBuffer, (UInt32)outSizeProcessed, &processedSize) != S_OK)
      throw "Can not write";
    MyFree(outBuffer);
    MyFree(inBuffer);
    return 0;
  }


  UInt64 fileSize;
  if (encodeMode)
  {
    NCompress::NLZMA::CEncoder *encoderSpec = 
      new NCompress::NLZMA::CEncoder;
    CMyComPtr<ICompressCoder> encoder = encoderSpec;

    if (!dictionaryIsDefined)
      dictionary = 1 << 23;

    UInt32 posStateBits = 2;
    UInt32 litContextBits = 3; // for normal files
    // UInt32 litContextBits = 0; // for 32-bit data
    UInt32 litPosBits = 0;
    // UInt32 litPosBits = 2; // for 32-bit data
    UInt32 algorithm = 2;
    UInt32 numFastBytes = 128;

    bool eos = parser[NKey::kEOS].ThereIs || stdInMode;
 
    if(parser[NKey::kMode].ThereIs)
      if (!GetNumber(parser[NKey::kMode].PostStrings[0], algorithm))
        IncorrectCommand();

    if(parser[NKey::kFastBytes].ThereIs)
      if (!GetNumber(parser[NKey::kFastBytes].PostStrings[0], numFastBytes))
        IncorrectCommand();
    if(parser[NKey::kLitContext].ThereIs)
      if (!GetNumber(parser[NKey::kLitContext].PostStrings[0], litContextBits))
        IncorrectCommand();
    if(parser[NKey::kLitPos].ThereIs)
      if (!GetNumber(parser[NKey::kLitPos].PostStrings[0], litPosBits))
        IncorrectCommand();
    if(parser[NKey::kPosBits].ThereIs)
      if (!GetNumber(parser[NKey::kPosBits].PostStrings[0], posStateBits))
        IncorrectCommand();

    PROPID propIDs[] = 
    {
      NCoderPropID::kDictionarySize,
      NCoderPropID::kPosStateBits,
      NCoderPropID::kLitContextBits,
      NCoderPropID::kLitPosBits,
      NCoderPropID::kAlgorithm,
      NCoderPropID::kNumFastBytes,
      NCoderPropID::kMatchFinder,
      NCoderPropID::kEndMarker
    };
    const int kNumProps = sizeof(propIDs) / sizeof(propIDs[0]);
    /*
    NWindows::NCOM::CPropVariant properties[kNumProps];
    properties[0] = UInt32(dictionary);
    properties[1] = UInt32(posStateBits);
    properties[2] = UInt32(litContextBits);
   
    properties[3] = UInt32(litPosBits);
    properties[4] = UInt32(algorithm);
    properties[5] = UInt32(numFastBytes);
    properties[6] = mf;
    properties[7] = eos;
    */
    PROPVARIANT properties[kNumProps];
    for (int p = 0; p < 6; p++)
      properties[p].vt = VT_UI4;
    properties[0].ulVal = UInt32(dictionary);
    properties[1].ulVal = UInt32(posStateBits);
    properties[2].ulVal = UInt32(litContextBits);
    properties[3].ulVal = UInt32(litPosBits);
    properties[4].ulVal = UInt32(algorithm);
    properties[5].ulVal = UInt32(numFastBytes);
    
    properties[6].vt = VT_BSTR;
    properties[6].bstrVal = (BSTR)(const wchar_t *)mf;

    properties[7].vt = VT_BOOL;
    properties[7].boolVal = eos ? VARIANT_TRUE : VARIANT_FALSE;

    if (encoderSpec->SetCoderProperties(propIDs, properties, kNumProps) != S_OK)
      IncorrectCommand();
    encoderSpec->WriteCoderProperties(outStream);

    if (eos || stdInMode)
      fileSize = (UInt64)(Int64)-1;
    else
      inStreamSpec->File.GetLength(fileSize);

    for (int i = 0; i < 8; i++)
    {
      Byte b = Byte(fileSize >> (8 * i));
      if (outStream->Write(&b, sizeof(b), 0) != S_OK)
      {
        fprintf(stderr, "Write error");
        return 1;
      }
    }
    HRESULT result = encoder->Code(inStream, outStream, 0, 0, 0);
    if (result == E_OUTOFMEMORY)
    {
      fprintf(stderr, "\nError: Can not allocate memory\n");
      return 1;
    }   
    else if (result != S_OK)
    {
      fprintf(stderr, "\nEncoder error = %X\n", (unsigned int)result);
      return 1;
    }   
  }
  else
  {