p7zip-rar/CPP/7zip/Archive/LzmaHandler.cpp
2017-10-11 12:40:22 +02:00

574 lines
13 KiB
C++

// LzmaHandler.cpp
#include "StdAfx.h"
#include "../../../C/CpuArch.h"
#include "../../Common/ComTry.h"
#include "../../Common/IntToString.h"
#include "../../Windows/PropVariant.h"
#include "../Common/FilterCoder.h"
#include "../Common/ProgressUtils.h"
#include "../Common/RegisterArc.h"
#include "../Common/StreamUtils.h"
#include "../Compress/BcjCoder.h"
#include "../Compress/LzmaDecoder.h"
#include "Common/DummyOutStream.h"
using namespace NWindows;
namespace NArchive {
namespace NLzma {
static bool CheckDicSize(const Byte *p)
{
UInt32 dicSize = GetUi32(p);
if (dicSize == 1)
return true;
for (unsigned i = 0; i <= 30; i++)
if (dicSize == ((UInt32)2 << i) || dicSize == ((UInt32)3 << i))
return true;
return (dicSize == 0xFFFFFFFF);
}
static const Byte kProps[] =
{
kpidSize,
kpidPackSize,
kpidMethod
};
static const Byte kArcProps[] =
{
kpidNumStreams
};
struct CHeader
{
UInt64 Size;
Byte FilterID;
Byte LzmaProps[5];
UInt32 GetDicSize() const { return GetUi32(LzmaProps + 1); }
bool HasSize() const { return (Size != (UInt64)(Int64)-1); }
bool Parse(const Byte *buf, bool isThereFilter);
};
bool CHeader::Parse(const Byte *buf, bool isThereFilter)
{
FilterID = 0;
if (isThereFilter)
FilterID = buf[0];
const Byte *sig = buf + (isThereFilter ? 1 : 0);
for (int i = 0; i < 5; i++)
LzmaProps[i] = sig[i];
Size = GetUi64(sig + 5);
return
LzmaProps[0] < 5 * 5 * 9 &&
FilterID < 2 &&
(!HasSize() || Size < ((UInt64)1 << 56))
&& CheckDicSize(LzmaProps + 1);
}
class CDecoder
{
CMyComPtr<ISequentialOutStream> _bcjStream;
CFilterCoder *_filterCoder;
CMyComPtr<ICompressCoder> _lzmaDecoder;
public:
NCompress::NLzma::CDecoder *_lzmaDecoderSpec;
~CDecoder();
HRESULT Create(bool filtered, ISequentialInStream *inStream);
HRESULT Code(const CHeader &header, ISequentialOutStream *outStream, ICompressProgressInfo *progress);
UInt64 GetInputProcessedSize() const { return _lzmaDecoderSpec->GetInputProcessedSize(); }
void ReleaseInStream() { if (_lzmaDecoder) _lzmaDecoderSpec->ReleaseInStream(); }
HRESULT ReadInput(Byte *data, UInt32 size, UInt32 *processedSize)
{ return _lzmaDecoderSpec->ReadFromInputStream(data, size, processedSize); }
};
HRESULT CDecoder::Create(bool filteredMode, ISequentialInStream *inStream)
{
if (!_lzmaDecoder)
{
_lzmaDecoderSpec = new NCompress::NLzma::CDecoder;
_lzmaDecoderSpec->FinishStream = true;
_lzmaDecoder = _lzmaDecoderSpec;
}
if (filteredMode)
{
if (!_bcjStream)
{
_filterCoder = new CFilterCoder(false);
CMyComPtr<ICompressCoder> coder = _filterCoder;
_filterCoder->Filter = new NCompress::NBcj::CCoder(false);
_bcjStream = _filterCoder;
}
}
return _lzmaDecoderSpec->SetInStream(inStream);
}
CDecoder::~CDecoder()
{
ReleaseInStream();
}
HRESULT CDecoder::Code(const CHeader &header, ISequentialOutStream *outStream,
ICompressProgressInfo *progress)
{
if (header.FilterID > 1)
return E_NOTIMPL;
{
CMyComPtr<ICompressSetDecoderProperties2> setDecoderProperties;
_lzmaDecoder.QueryInterface(IID_ICompressSetDecoderProperties2, &setDecoderProperties);
if (!setDecoderProperties)
return E_NOTIMPL;
RINOK(setDecoderProperties->SetDecoderProperties2(header.LzmaProps, 5));
}
bool filteredMode = (header.FilterID == 1);
if (filteredMode)
{
RINOK(_filterCoder->SetOutStream(outStream));
outStream = _bcjStream;
RINOK(_filterCoder->SetOutStreamSize(NULL));
}
const UInt64 *Size = header.HasSize() ? &header.Size : NULL;
HRESULT res = _lzmaDecoderSpec->CodeResume(outStream, Size, progress);
if (filteredMode)
{
{
HRESULT res2 = _filterCoder->OutStreamFinish();
if (res == S_OK)
res = res2;
}
HRESULT res2 = _filterCoder->ReleaseOutStream();
if (res == S_OK)
res = res2;
}
RINOK(res);
if (header.HasSize())
if (_lzmaDecoderSpec->GetOutputProcessedSize() != header.Size)
return S_FALSE;
return S_OK;
}
class CHandler:
public IInArchive,
public IArchiveOpenSeq,
public CMyUnknownImp
{
CHeader _header;
bool _lzma86;
CMyComPtr<IInStream> _stream;
CMyComPtr<ISequentialInStream> _seqStream;
bool _isArc;
bool _needSeekToStart;
bool _dataAfterEnd;
bool _needMoreInput;
bool _packSize_Defined;
bool _unpackSize_Defined;
bool _numStreams_Defined;
bool _unsupported;
bool _dataError;
UInt64 _packSize;
UInt64 _unpackSize;
UInt64 _numStreams;
public:
MY_UNKNOWN_IMP2(IInArchive, IArchiveOpenSeq)
INTERFACE_IInArchive(;)
STDMETHOD(OpenSeq)(ISequentialInStream *stream);
CHandler(bool lzma86) { _lzma86 = lzma86; }
unsigned GetHeaderSize() const { return 5 + 8 + (_lzma86 ? 1 : 0); }
};
IMP_IInArchive_Props
IMP_IInArchive_ArcProps
STDMETHODIMP CHandler::GetArchiveProperty(PROPID propID, PROPVARIANT *value)
{
NCOM::CPropVariant prop;
switch (propID)
{
case kpidPhySize: if (_packSize_Defined) prop = _packSize; break;
case kpidNumStreams: if (_numStreams_Defined) prop = _numStreams; break;
case kpidUnpackSize: if (_unpackSize_Defined) prop = _unpackSize; break;
case kpidErrorFlags:
{
UInt32 v = 0;
if (!_isArc) v |= kpv_ErrorFlags_IsNotArc;;
if (_needMoreInput) v |= kpv_ErrorFlags_UnexpectedEnd;
if (_dataAfterEnd) v |= kpv_ErrorFlags_DataAfterEnd;
if (_unsupported) v |= kpv_ErrorFlags_UnsupportedMethod;
if (_dataError) v |= kpv_ErrorFlags_DataError;
prop = v;
}
}
prop.Detach(value);
return S_OK;
}
STDMETHODIMP CHandler::GetNumberOfItems(UInt32 *numItems)
{
*numItems = 1;
return S_OK;
}
static void DictSizeToString(UInt32 value, char *s)
{
for (int i = 0; i <= 31; i++)
if (((UInt32)1 << i) == value)
{
::ConvertUInt32ToString(i, s);
return;
}
char c = 'b';
if ((value & ((1 << 20) - 1)) == 0) { value >>= 20; c = 'm'; }
else if ((value & ((1 << 10) - 1)) == 0) { value >>= 10; c = 'k'; }
::ConvertUInt32ToString(value, s);
s += MyStringLen(s);
*s++ = c;
*s = 0;
}
STDMETHODIMP CHandler::GetProperty(UInt32 /* index */, PROPID propID, PROPVARIANT *value)
{
NCOM::CPropVariant prop;
switch (propID)
{
case kpidSize: if (_stream && _header.HasSize()) prop = _header.Size; break;
case kpidPackSize: if (_packSize_Defined) prop = _packSize; break;
case kpidMethod:
if (_stream)
{
char sz[64];
char *s = sz;
if (_header.FilterID != 0)
s = MyStpCpy(s, "BCJ ");
s = MyStpCpy(s, "LZMA:");
DictSizeToString(_header.GetDicSize(), s);
prop = sz;
}
break;
}
prop.Detach(value);
return S_OK;
}
API_FUNC_static_IsArc IsArc_Lzma(const Byte *p, size_t size)
{
const UInt32 kHeaderSize = 1 + 4 + 8;
if (size < kHeaderSize)
return k_IsArc_Res_NEED_MORE;
if (p[0] >= 5 * 5 * 9)
return k_IsArc_Res_NO;
UInt64 unpackSize = GetUi64(p + 1 + 4);
if (unpackSize != (UInt64)(Int64)-1)
{
if (size >= ((UInt64)1 << 56))
return k_IsArc_Res_NO;
}
if (unpackSize != 0)
{
if (size < kHeaderSize + 2)
return k_IsArc_Res_NEED_MORE;
if (p[kHeaderSize] != 0)
return k_IsArc_Res_NO;
if (unpackSize != (UInt64)(Int64)-1)
{
if ((p[kHeaderSize + 1] & 0x80) != 0)
return k_IsArc_Res_NO;
}
}
if (!CheckDicSize(p + 1))
// return k_IsArc_Res_YES_LOW_PROB;
return k_IsArc_Res_NO;
return k_IsArc_Res_YES;
}
}
API_FUNC_static_IsArc IsArc_Lzma86(const Byte *p, size_t size)
{
if (size < 1)
return k_IsArc_Res_NEED_MORE;
Byte filterID = p[0];
if (filterID != 0 && filterID != 1)
return k_IsArc_Res_NO;
return IsArc_Lzma(p + 1, size - 1);
}
}
STDMETHODIMP CHandler::Open(IInStream *inStream, const UInt64 *, IArchiveOpenCallback *)
{
Close();
const UInt32 kBufSize = 1 + 5 + 8 + 2;
Byte buf[kBufSize];
RINOK(ReadStream_FALSE(inStream, buf, kBufSize));
if (!_header.Parse(buf, _lzma86))
return S_FALSE;
const Byte *start = buf + GetHeaderSize();
if (start[0] != 0 /* || (start[1] & 0x80) != 0 */ ) // empty stream with EOS is not 0x80
return S_FALSE;
RINOK(inStream->Seek(0, STREAM_SEEK_END, &_packSize));
if (_packSize >= 24 && _header.Size == 0 && _header.FilterID == 0 && _header.LzmaProps[0] == 0)
return S_FALSE;
_isArc = true;
_stream = inStream;
_seqStream = inStream;
_needSeekToStart = true;
return S_OK;
}
STDMETHODIMP CHandler::OpenSeq(ISequentialInStream *stream)
{
Close();
_isArc = true;
_seqStream = stream;
return S_OK;
}
STDMETHODIMP CHandler::Close()
{
_isArc = false;
_packSize_Defined = false;
_unpackSize_Defined = false;
_numStreams_Defined = false;
_dataAfterEnd = false;
_needMoreInput = false;
_unsupported = false;
_dataError = false;
_packSize = 0;
_needSeekToStart = false;
_stream.Release();
_seqStream.Release();
return S_OK;
}
class CCompressProgressInfoImp:
public ICompressProgressInfo,
public CMyUnknownImp
{
CMyComPtr<IArchiveOpenCallback> Callback;
public:
UInt64 Offset;
MY_UNKNOWN_IMP1(ICompressProgressInfo)
STDMETHOD(SetRatioInfo)(const UInt64 *inSize, const UInt64 *outSize);
void Init(IArchiveOpenCallback *callback) { Callback = callback; }
};
STDMETHODIMP CCompressProgressInfoImp::SetRatioInfo(const UInt64 *inSize, const UInt64 * /* outSize */)
{
if (Callback)
{
UInt64 files = 0;
UInt64 value = Offset + *inSize;
return Callback->SetCompleted(&files, &value);
}
return S_OK;
}
STDMETHODIMP CHandler::Extract(const UInt32 *indices, UInt32 numItems,
Int32 testMode, IArchiveExtractCallback *extractCallback)
{
COM_TRY_BEGIN
if (numItems == 0)
return S_OK;
if (numItems != (UInt32)(Int32)-1 && (numItems != 1 || indices[0] != 0))
return E_INVALIDARG;
if (_packSize_Defined)
extractCallback->SetTotal(_packSize);
CMyComPtr<ISequentialOutStream> realOutStream;
Int32 askMode = testMode ?
NExtract::NAskMode::kTest :
NExtract::NAskMode::kExtract;
RINOK(extractCallback->GetStream(0, &realOutStream, askMode));
if (!testMode && !realOutStream)
return S_OK;
extractCallback->PrepareOperation(askMode);
CDummyOutStream *outStreamSpec = new CDummyOutStream;
CMyComPtr<ISequentialOutStream> outStream(outStreamSpec);
outStreamSpec->SetStream(realOutStream);
outStreamSpec->Init();
realOutStream.Release();
CLocalProgress *lps = new CLocalProgress;
CMyComPtr<ICompressProgressInfo> progress = lps;
lps->Init(extractCallback, true);
if (_needSeekToStart)
{
if (!_stream)
return E_FAIL;
RINOK(_stream->Seek(0, STREAM_SEEK_SET, NULL));
}
else
_needSeekToStart = true;
CDecoder decoder;
HRESULT result = decoder.Create(_lzma86, _seqStream);
RINOK(result);
bool firstItem = true;
UInt64 packSize = 0;
UInt64 unpackSize = 0;
UInt64 numStreams = 0;
bool dataAfterEnd = false;
for (;;)
{
lps->InSize = packSize;
lps->OutSize = unpackSize;
RINOK(lps->SetCur());
const UInt32 kBufSize = 1 + 5 + 8;
Byte buf[kBufSize];
const UInt32 headerSize = GetHeaderSize();
UInt32 processed;
RINOK(decoder.ReadInput(buf, headerSize, &processed));
if (processed != headerSize)
{
if (processed != 0)
dataAfterEnd = true;
break;
}
CHeader st;
if (!st.Parse(buf, _lzma86))
{
dataAfterEnd = true;
break;
}
numStreams++;
firstItem = false;
result = decoder.Code(st, outStream, progress);
packSize = decoder.GetInputProcessedSize();
unpackSize = outStreamSpec->GetSize();
if (result == E_NOTIMPL)
{
_unsupported = true;
result = S_FALSE;
break;
}
if (result == S_FALSE)
break;
RINOK(result);
}
if (firstItem)
{
_isArc = false;
result = S_FALSE;
}
else if (result == S_OK || result == S_FALSE)
{
if (dataAfterEnd)
_dataAfterEnd = true;
else if (decoder._lzmaDecoderSpec->NeedMoreInput)
_needMoreInput = true;
_packSize = packSize;
_unpackSize = unpackSize;
_numStreams = numStreams;
_packSize_Defined = true;
_unpackSize_Defined = true;
_numStreams_Defined = true;
}
Int32 opResult = NExtract::NOperationResult::kOK;
if (!_isArc)
opResult = NExtract::NOperationResult::kIsNotArc;
else if (_needMoreInput)
opResult = NExtract::NOperationResult::kUnexpectedEnd;
else if (_unsupported)
opResult = NExtract::NOperationResult::kUnsupportedMethod;
else if (_dataAfterEnd)
opResult = NExtract::NOperationResult::kDataAfterEnd;
else if (result == S_FALSE)
opResult = NExtract::NOperationResult::kDataError;
else if (result == S_OK)
opResult = NExtract::NOperationResult::kOK;
else
return result;
outStream.Release();
return extractCallback->SetOperationResult(opResult);
COM_TRY_END
}
namespace NLzmaAr {
// 2, { 0x5D, 0x00 },
REGISTER_ARC_I_CLS_NO_SIG(
CHandler(false),
"lzma", "lzma", 0, 0xA,
0,
NArcInfoFlags::kStartOpen |
NArcInfoFlags::kKeepName,
IsArc_Lzma)
}
namespace NLzma86Ar {
REGISTER_ARC_I_CLS_NO_SIG(
CHandler(true),
"lzma86", "lzma86", 0, 0xB,
0,
NArcInfoFlags::kKeepName,
IsArc_Lzma86)
}
}}