MultiSource/Benchmarks/7zip/C/XzEnc.c - llvm-test-suite - Git at Google

 /* XzEnc.c -- Xz Encode
 2009-06-04 : Igor Pavlov : Public domain */

 #include <stdlib.h>
 #include <string.h>

 #include "7zCrc.h"
 #include "Alloc.h"
 #include "Bra.h"
 #include "CpuArch.h"
 #ifdef USE_SUBBLOCK
 #include "SbEnc.h"
 #endif

 #include "XzEnc.h"

 static void *SzBigAlloc(void *p, size_t size) { p = p; return BigAlloc(size); }
 static void SzBigFree(void *p, void *address) { p = p; BigFree(address); }
 static ISzAlloc g_BigAlloc = { SzBigAlloc, SzBigFree };

 static void *SzAlloc(void *p, size_t size) { p = p; return MyAlloc(size); }
 static void SzFree(void *p, void *address) { p = p; MyFree(address); }
 static ISzAlloc g_Alloc = { SzAlloc, SzFree };

 #define XzBlock_ClearFlags(p)       (p)->flags = 0;
 #define XzBlock_SetNumFilters(p, n) (p)->flags |= ((n) - 1);
 #define XzBlock_SetHasPackSize(p)   (p)->flags |= XZ_BF_PACK_SIZE;
 #define XzBlock_SetHasUnpackSize(p) (p)->flags |= XZ_BF_UNPACK_SIZE;

 static SRes WriteBytes(ISeqOutStream *s, const void *buf, UInt32 size)
 {
   return (s->Write(s, buf, size) == size) ? SZ_OK : SZ_ERROR_WRITE;
 }

 static SRes WriteBytesAndCrc(ISeqOutStream *s, const void *buf, UInt32 size, UInt32 *crc)
 {
   *crc = CrcUpdate(*crc, buf, size);
   return WriteBytes(s, buf, size);
 }

 SRes Xz_WriteHeader(CXzStreamFlags f, ISeqOutStream *s)
 {
   UInt32 crc;
   Byte header[XZ_STREAM_HEADER_SIZE];
   memcpy(header, XZ_SIG, XZ_SIG_SIZE);
   header[XZ_SIG_SIZE] = (Byte)(f >> 8);
   header[XZ_SIG_SIZE + 1] = (Byte)(f & 0xFF);
   crc = CrcCalc(header + XZ_SIG_SIZE, XZ_STREAM_FLAGS_SIZE);
   SetUi32(header + XZ_SIG_SIZE + XZ_STREAM_FLAGS_SIZE, crc);
   return WriteBytes(s, header, XZ_STREAM_HEADER_SIZE);
 }

 SRes XzBlock_WriteHeader(const CXzBlock *p, ISeqOutStream *s)
 {
   Byte header[XZ_BLOCK_HEADER_SIZE_MAX];

   unsigned pos = 1;
   int numFilters, i;
   header[pos++] = p->flags;

   if (XzBlock_HasPackSize(p)) pos += Xz_WriteVarInt(header + pos, p->packSize);
   if (XzBlock_HasUnpackSize(p)) pos += Xz_WriteVarInt(header + pos, p->unpackSize);
   numFilters = XzBlock_GetNumFilters(p);
   for (i = 0; i < numFilters; i++)
   {
     const CXzFilter *f = &p->filters[i];
     pos += Xz_WriteVarInt(header + pos, f->id);
     pos += Xz_WriteVarInt(header + pos, f->propsSize);
     memcpy(header + pos, f->props, f->propsSize);
     pos += f->propsSize;
   }
   while((pos & 3) != 0)
     header[pos++] = 0;
   header[0] = (Byte)(pos >> 2);
   SetUi32(header + pos, CrcCalc(header, pos));
   return WriteBytes(s, header, pos + 4);
 }

 SRes Xz_WriteFooter(CXzStream *p, ISeqOutStream *s)
 {
   Byte buf[32];
   UInt64 globalPos;
   {
     UInt32 crc = CRC_INIT_VAL;
     unsigned pos = 1 + Xz_WriteVarInt(buf + 1, p->numBlocks);
     size_t i;

     globalPos = pos;
     buf[0] = 0;
     RINOK(WriteBytesAndCrc(s, buf, pos, &crc));
     for (i = 0; i < p->numBlocks; i++)
     {
       const CXzBlockSizes *block = &p->blocks[i];
       pos = Xz_WriteVarInt(buf, block->totalSize);
       pos += Xz_WriteVarInt(buf + pos, block->unpackSize);
       globalPos += pos;
       RINOK(WriteBytesAndCrc(s, buf, pos, &crc));
     }
     pos = ((unsigned)globalPos & 3);
     if (pos != 0)
     {
       buf[0] = buf[1] = buf[2] = 0;
       RINOK(WriteBytesAndCrc(s, buf, 4 - pos, &crc));
       globalPos += 4 - pos;
     }
     {
       SetUi32(buf, CRC_GET_DIGEST(crc));
       RINOK(WriteBytes(s, buf, 4));
       globalPos += 4;
     }
   }

   {
     UInt32 indexSize = (UInt32)((globalPos >> 2) - 1);
     SetUi32(buf + 4, indexSize);
     buf[8] = (Byte)(p->flags >> 8);
     buf[9] = (Byte)(p->flags & 0xFF);
     SetUi32(buf, CrcCalc(buf + 4, 6));
     memcpy(buf + 10, XZ_FOOTER_SIG, XZ_FOOTER_SIG_SIZE);
     return WriteBytes(s, buf, 12);
   }
 }

 SRes Xz_AddIndexRecord(CXzStream *p, UInt64 unpackSize, UInt64 totalSize, ISzAlloc *alloc)
 {
   if (p->blocks == 0 || p->numBlocksAllocated == p->numBlocks)
   {
     size_t num = (p->numBlocks + 1) * 2;
     size_t newSize = sizeof(CXzBlockSizes) * num;
     CXzBlockSizes *blocks;
     if (newSize / sizeof(CXzBlockSizes) != num)
       return SZ_ERROR_MEM;
     blocks = alloc->Alloc(alloc, newSize);
     if (blocks == 0)
       return SZ_ERROR_MEM;
     if (p->numBlocks != 0)
     {
       memcpy(blocks, p->blocks, p->numBlocks * sizeof(CXzBlockSizes));
       Xz_Free(p, alloc);
     }
     p->blocks = blocks;
     p->numBlocksAllocated = num;
   }
   {
     CXzBlockSizes *block = &p->blocks[p->numBlocks++];
     block->totalSize = totalSize;
     block->unpackSize = unpackSize;
   }
   return SZ_OK;
 }

 /* ---------- CSeqCheckInStream ---------- */

 typedef struct
 {
   ISeqInStream p;
   ISeqInStream *realStream;
   UInt64 processed;
   CXzCheck check;
 } CSeqCheckInStream;

 void SeqCheckInStream_Init(CSeqCheckInStream *p, int mode)
 {
   p->processed = 0;
   XzCheck_Init(&p->check, mode);
 }

 void SeqCheckInStream_GetDigest(CSeqCheckInStream *p, Byte *digest)
 {
   XzCheck_Final(&p->check, digest);
 }

 static SRes SeqCheckInStream_Read(void *pp, void *data, size_t *size)
 {
   CSeqCheckInStream *p = (CSeqCheckInStream *)pp;
   SRes res = p->realStream->Read(p->realStream, data, size);
   XzCheck_Update(&p->check, data, *size);
   p->processed += *size;
   return res;
 }

 /* ---------- CSeqSizeOutStream ---------- */

 typedef struct
 {
   ISeqOutStream p;
   ISeqOutStream *realStream;
   UInt64 processed;
 } CSeqSizeOutStream;

 static size_t MyWrite(void *pp, const void *data, size_t size)
 {
   CSeqSizeOutStream *p = (CSeqSizeOutStream *)pp;
   size = p->realStream->Write(p->realStream, data, size);
   p->processed += size;
   return size;
 }

 /* ---------- CSeqInFilter ---------- */

 /*
 typedef struct _IFilter
 {
   void *p;
   void (*Free)(void *p, ISzAlloc *alloc);
   SRes (*SetProps)(void *p, const Byte *props, size_t propSize, ISzAlloc *alloc);
   void (*Init)(void *p);
   size_t (*Filter)(void *p, Byte *data, SizeT destLen);
 } IFilter;

 #define FILT_BUF_SIZE (1 << 19)

 typedef struct
 {
   ISeqInStream p;
   ISeqInStream *realStream;
   UInt32 x86State;
   UInt32 ip;
   UInt64 processed;
   CXzCheck check;
   Byte buf[FILT_BUF_SIZE];
   UInt32 bufferPos;
   UInt32 convertedPosBegin;
   UInt32 convertedPosEnd;
   IFilter *filter;
 } CSeqInFilter;

 static SRes SeqInFilter_Read(void *pp, void *data, size_t *size)
 {
   CSeqInFilter *p = (CSeqInFilter *)pp;
   size_t remSize = *size;
   *size = 0;

   while (remSize > 0)
   {
     int i;
     if (p->convertedPosBegin != p->convertedPosEnd)
     {
       UInt32 sizeTemp = p->convertedPosEnd - p->convertedPosBegin;
       if (remSize < sizeTemp)
         sizeTemp = (UInt32)remSize;
       memmove(data, p->buf + p->convertedPosBegin, sizeTemp);
       p->convertedPosBegin += sizeTemp;
       data = (void *)((Byte *)data + sizeTemp);
       remSize -= sizeTemp;
       *size += sizeTemp;
       break;
     }
     for (i = 0; p->convertedPosEnd + i < p->bufferPos; i++)
       p->buf[i] = p->buf[i + p->convertedPosEnd];
     p->bufferPos = i;
     p->convertedPosBegin = p->convertedPosEnd = 0;
     {
       size_t processedSizeTemp = FILT_BUF_SIZE - p->bufferPos;
       RINOK(p->realStream->Read(p->realStream, p->buf + p->bufferPos, &processedSizeTemp));
       p->bufferPos = p->bufferPos + (UInt32)processedSizeTemp;
     }
     p->convertedPosEnd = (UInt32)p->filter->Filter(p->filter->p, p->buf, p->bufferPos);
     if (p->convertedPosEnd == 0)
     {
       if (p->bufferPos == 0)
         break;
       else
       {
         p->convertedPosEnd = p->bufferPos;
         continue;
       }
     }
     if (p->convertedPosEnd > p->bufferPos)
     {
       for (; p->bufferPos < p->convertedPosEnd; p->bufferPos++)
         p->buf[p->bufferPos] = 0;
       p->convertedPosEnd = (UInt32)p->filter->Filter(p->filter->p, p->buf, p->bufferPos);
     }
   }
   return SZ_OK;
 }
 */

 /*
 typedef struct
 {
   ISeqInStream p;
   ISeqInStream *realStream;
   CMixCoder mixCoder;
   Byte buf[FILT_BUF_SIZE];
   UInt32 bufPos;
   UInt32 bufSize;
 } CMixCoderSeqInStream;

 static SRes CMixCoderSeqInStream_Read(void *pp, void *data, size_t *size)
 {
   CMixCoderSeqInStream *p = (CMixCoderSeqInStream *)pp;
   SRes res = SZ_OK;
   size_t remSize = *size;
   *size = 0;
   while (remSize > 0)
   {
     if (p->bufPos == p->bufSize)
     {
       size_t curSize;
       p->bufPos = p->bufSize = 0;
       if (*size != 0)
         break;
       curSize = FILT_BUF_SIZE;
       RINOK(p->realStream->Read(p->realStream, p->buf, &curSize));
       p->bufSize = (UInt32)curSize;
     }
     {
       SizeT destLen = remSize;
       SizeT srcLen = p->bufSize - p->bufPos;
       res = MixCoder_Code(&p->mixCoder, data, &destLen, p->buf + p->bufPos, &srcLen, 0);
       data = (void *)((Byte *)data + destLen);
       remSize -= destLen;
       *size += destLen;
       p->bufPos += srcLen;
     }
   }
   return res;
 }
 */

 #ifdef USE_SUBBLOCK
 typedef struct
 {
   ISeqInStream p;
   CSubblockEnc sb;
   UInt64 processed;
 } CSbEncInStream;

 void SbEncInStream_Init(CSbEncInStream *p)
 {
   p->processed = 0;
   SubblockEnc_Init(&p->sb);
 }

 static SRes SbEncInStream_Read(void *pp, void *data, size_t *size)
 {
   CSbEncInStream *p = (CSbEncInStream *)pp;
   SRes res = SubblockEnc_Read(&p->sb, data, size);
   p->processed += *size;
   return res;
 }
 #endif

 typedef struct
 {
   /* CMixCoderSeqInStream inStream; */
   CLzma2EncHandle lzma2;
   #ifdef USE_SUBBLOCK
   CSbEncInStream sb;
   #endif
   ISzAlloc *alloc;
   ISzAlloc *bigAlloc;
 } CLzma2WithFilters;


 static void Lzma2WithFilters_Construct(CLzma2WithFilters *p, ISzAlloc *alloc, ISzAlloc *bigAlloc)
 {
   p->alloc = alloc;
   p->bigAlloc = bigAlloc;
   p->lzma2 = NULL;
   #ifdef USE_SUBBLOCK
   p->sb.p.Read = SbEncInStream_Read;
   SubblockEnc_Construct(&p->sb.sb, p->alloc);
   #endif
 }

 static SRes Lzma2WithFilters_Create(CLzma2WithFilters *p)
 {
   p->lzma2 = Lzma2Enc_Create(p->alloc, p->bigAlloc);
   if (p->lzma2 == 0)
     return SZ_ERROR_MEM;
   return SZ_OK;
 }

 static void Lzma2WithFilters_Free(CLzma2WithFilters *p)
 {
   #ifdef USE_SUBBLOCK
   SubblockEnc_Free(&p->sb.sb);
   #endif
   if (p->lzma2)
   {
     Lzma2Enc_Destroy(p->lzma2);
     p->lzma2 = NULL;
   }
 }

 static SRes Xz_Compress(CXzStream *xz,
     CLzma2WithFilters *lzmaf,
     ISeqOutStream *outStream,
     ISeqInStream *inStream,
     const CLzma2EncProps *lzma2Props,
     Bool useSubblock,
     ICompressProgress *progress)
 {
   xz->flags = XZ_CHECK_CRC32;

   RINOK(Lzma2Enc_SetProps(lzmaf->lzma2, lzma2Props));
   RINOK(Xz_WriteHeader(xz->flags, outStream));

   {
     CSeqCheckInStream checkInStream;
     CSeqSizeOutStream seqSizeOutStream;
     CXzBlock block;
     int filterIndex = 0;

     XzBlock_ClearFlags(&block);
     XzBlock_SetNumFilters(&block, 1 + (useSubblock ? 1 : 0));

     if (useSubblock)
     {
       CXzFilter *f = &block.filters[filterIndex++];
       f->id = XZ_ID_Subblock;
       f->propsSize = 0;
     }

     {
       CXzFilter *f = &block.filters[filterIndex++];
       f->id = XZ_ID_LZMA2;
       f->propsSize = 1;
       f->props[0] = Lzma2Enc_WriteProperties(lzmaf->lzma2);
     }

     seqSizeOutStream.p.Write = MyWrite;
     seqSizeOutStream.realStream = outStream;
     seqSizeOutStream.processed = 0;

     RINOK(XzBlock_WriteHeader(&block, &seqSizeOutStream.p));

     checkInStream.p.Read = SeqCheckInStream_Read;
     checkInStream.realStream = inStream;
     SeqCheckInStream_Init(&checkInStream, XzFlags_GetCheckType(xz->flags));

     #ifdef USE_SUBBLOCK
     if (useSubblock)
     {
       lzmaf->sb.sb.inStream = &checkInStream.p;
       SubblockEnc_Init(&lzmaf->sb.sb);
     }
     #endif

     {
       UInt64 packPos = seqSizeOutStream.processed;
       SRes res = Lzma2Enc_Encode(lzmaf->lzma2, &seqSizeOutStream.p,
         #ifdef USE_SUBBLOCK
         useSubblock ? &lzmaf->sb.p:
         #endif
         &checkInStream.p,
         progress);
       RINOK(res);
       block.unpackSize = checkInStream.processed;
       block.packSize = seqSizeOutStream.processed - packPos;
     }

     {
       unsigned padSize = 0;
       Byte buf[128];
       while((((unsigned)block.packSize + padSize) & 3) != 0)
         buf[padSize++] = 0;
       SeqCheckInStream_GetDigest(&checkInStream, buf + padSize);
       RINOK(WriteBytes(&seqSizeOutStream.p, buf, padSize + XzFlags_GetCheckSize(xz->flags)));
       RINOK(Xz_AddIndexRecord(xz, block.unpackSize, seqSizeOutStream.processed - padSize, &g_Alloc));
     }
   }
   return Xz_WriteFooter(xz, outStream);
 }

 SRes Xz_Encode(ISeqOutStream *outStream, ISeqInStream *inStream,
     const CLzma2EncProps *lzma2Props, Bool useSubblock,
     ICompressProgress *progress)
 {
   SRes res;
   CXzStream xz;
   CLzma2WithFilters lzmaf;
   Xz_Construct(&xz);
   Lzma2WithFilters_Construct(&lzmaf, &g_Alloc, &g_BigAlloc);
   res = Lzma2WithFilters_Create(&lzmaf);
   if (res == SZ_OK)
     res = Xz_Compress(&xz, &lzmaf, outStream, inStream,
         lzma2Props, useSubblock, progress);
   Lzma2WithFilters_Free(&lzmaf);
   Xz_Free(&xz, &g_Alloc);
   return res;
 }

 SRes Xz_EncodeEmpty(ISeqOutStream *outStream)
 {
   SRes res;
   CXzStream xz;
   Xz_Construct(&xz);
   res = Xz_WriteHeader(xz.flags, outStream);
   if (res == SZ_OK)
     res = Xz_WriteFooter(&xz, outStream);
   Xz_Free(&xz, &g_Alloc);
   return res;
 }
	/* XzEnc.c -- Xz Encode
	2009-06-04 : Igor Pavlov : Public domain */

	#include <stdlib.h>
	#include <string.h>

	#include "7zCrc.h"
	#include "Alloc.h"
	#include "Bra.h"
	#include "CpuArch.h"
	#ifdef USE_SUBBLOCK
	#include "SbEnc.h"
	#endif

	#include "XzEnc.h"

	static void SzBigAlloc(void p, size_t size) { p = p; return BigAlloc(size); }
	static void SzBigFree(void p, void address) { p = p; BigFree(address); }
	static ISzAlloc g_BigAlloc = { SzBigAlloc, SzBigFree };

	static void SzAlloc(void p, size_t size) { p = p; return MyAlloc(size); }
	static void SzFree(void p, void address) { p = p; MyFree(address); }
	static ISzAlloc g_Alloc = { SzAlloc, SzFree };

	#define XzBlock_ClearFlags(p) (p)->flags = 0;
	#define XzBlock_SetNumFilters(p, n) (p)->flags \|= ((n) - 1);
	#define XzBlock_SetHasPackSize(p) (p)->flags \|= XZ_BF_PACK_SIZE;
	#define XzBlock_SetHasUnpackSize(p) (p)->flags \|= XZ_BF_UNPACK_SIZE;

	static SRes WriteBytes(ISeqOutStream s, const void buf, UInt32 size)
	{
	return (s->Write(s, buf, size) == size) ? SZ_OK : SZ_ERROR_WRITE;
	}

	static SRes WriteBytesAndCrc(ISeqOutStream s, const void buf, UInt32 size, UInt32 *crc)
	{
	crc = CrcUpdate(crc, buf, size);
	return WriteBytes(s, buf, size);
	}

	SRes Xz_WriteHeader(CXzStreamFlags f, ISeqOutStream *s)
	{
	UInt32 crc;
	Byte header[XZ_STREAM_HEADER_SIZE];
	memcpy(header, XZ_SIG, XZ_SIG_SIZE);
	header[XZ_SIG_SIZE] = (Byte)(f >> 8);
	header[XZ_SIG_SIZE + 1] = (Byte)(f & 0xFF);
	crc = CrcCalc(header + XZ_SIG_SIZE, XZ_STREAM_FLAGS_SIZE);
	SetUi32(header + XZ_SIG_SIZE + XZ_STREAM_FLAGS_SIZE, crc);
	return WriteBytes(s, header, XZ_STREAM_HEADER_SIZE);
	}

	SRes XzBlock_WriteHeader(const CXzBlock p, ISeqOutStream s)
	{
	Byte header[XZ_BLOCK_HEADER_SIZE_MAX];

	unsigned pos = 1;
	int numFilters, i;
	header[pos++] = p->flags;

	if (XzBlock_HasPackSize(p)) pos += Xz_WriteVarInt(header + pos, p->packSize);
	if (XzBlock_HasUnpackSize(p)) pos += Xz_WriteVarInt(header + pos, p->unpackSize);
	numFilters = XzBlock_GetNumFilters(p);
	for (i = 0; i < numFilters; i++)
	{
	const CXzFilter *f = &p->filters[i];
	pos += Xz_WriteVarInt(header + pos, f->id);
	pos += Xz_WriteVarInt(header + pos, f->propsSize);
	memcpy(header + pos, f->props, f->propsSize);
	pos += f->propsSize;
	}
	while((pos & 3) != 0)
	header[pos++] = 0;
	header[0] = (Byte)(pos >> 2);
	SetUi32(header + pos, CrcCalc(header, pos));
	return WriteBytes(s, header, pos + 4);
	}

	SRes Xz_WriteFooter(CXzStream p, ISeqOutStream s)
	{
	Byte buf[32];
	UInt64 globalPos;
	{
	UInt32 crc = CRC_INIT_VAL;
	unsigned pos = 1 + Xz_WriteVarInt(buf + 1, p->numBlocks);
	size_t i;

	globalPos = pos;
	buf[0] = 0;
	RINOK(WriteBytesAndCrc(s, buf, pos, &crc));
	for (i = 0; i < p->numBlocks; i++)
	{
	const CXzBlockSizes *block = &p->blocks[i];
	pos = Xz_WriteVarInt(buf, block->totalSize);
	pos += Xz_WriteVarInt(buf + pos, block->unpackSize);
	globalPos += pos;
	RINOK(WriteBytesAndCrc(s, buf, pos, &crc));
	}
	pos = ((unsigned)globalPos & 3);
	if (pos != 0)
	{
	buf[0] = buf[1] = buf[2] = 0;
	RINOK(WriteBytesAndCrc(s, buf, 4 - pos, &crc));
	globalPos += 4 - pos;
	}
	{
	SetUi32(buf, CRC_GET_DIGEST(crc));
	RINOK(WriteBytes(s, buf, 4));
	globalPos += 4;
	}
	}

	{
	UInt32 indexSize = (UInt32)((globalPos >> 2) - 1);
	SetUi32(buf + 4, indexSize);
	buf[8] = (Byte)(p->flags >> 8);
	buf[9] = (Byte)(p->flags & 0xFF);
	SetUi32(buf, CrcCalc(buf + 4, 6));
	memcpy(buf + 10, XZ_FOOTER_SIG, XZ_FOOTER_SIG_SIZE);
	return WriteBytes(s, buf, 12);
	}
	}

	SRes Xz_AddIndexRecord(CXzStream p, UInt64 unpackSize, UInt64 totalSize, ISzAlloc alloc)
	{
	if (p->blocks == 0 \|\| p->numBlocksAllocated == p->numBlocks)
	{
	size_t num = (p->numBlocks + 1) * 2;
	size_t newSize = sizeof(CXzBlockSizes) * num;
	CXzBlockSizes *blocks;
	if (newSize / sizeof(CXzBlockSizes) != num)
	return SZ_ERROR_MEM;
	blocks = alloc->Alloc(alloc, newSize);
	if (blocks == 0)
	return SZ_ERROR_MEM;
	if (p->numBlocks != 0)
	{
	memcpy(blocks, p->blocks, p->numBlocks * sizeof(CXzBlockSizes));
	Xz_Free(p, alloc);
	}
	p->blocks = blocks;
	p->numBlocksAllocated = num;
	}
	{
	CXzBlockSizes *block = &p->blocks[p->numBlocks++];
	block->totalSize = totalSize;
	block->unpackSize = unpackSize;
	}
	return SZ_OK;
	}

	/* ---------- CSeqCheckInStream ---------- */

	typedef struct
	{
	ISeqInStream p;
	ISeqInStream *realStream;
	UInt64 processed;
	CXzCheck check;
	} CSeqCheckInStream;

	void SeqCheckInStream_Init(CSeqCheckInStream *p, int mode)
	{
	p->processed = 0;
	XzCheck_Init(&p->check, mode);
	}

	void SeqCheckInStream_GetDigest(CSeqCheckInStream p, Byte digest)
	{
	XzCheck_Final(&p->check, digest);
	}

	static SRes SeqCheckInStream_Read(void pp, void data, size_t *size)
	{
	CSeqCheckInStream p = (CSeqCheckInStream )pp;
	SRes res = p->realStream->Read(p->realStream, data, size);
	XzCheck_Update(&p->check, data, *size);
	p->processed += *size;
	return res;
	}

	/* ---------- CSeqSizeOutStream ---------- */

	typedef struct
	{
	ISeqOutStream p;
	ISeqOutStream *realStream;
	UInt64 processed;
	} CSeqSizeOutStream;

	static size_t MyWrite(void pp, const void data, size_t size)
	{
	CSeqSizeOutStream p = (CSeqSizeOutStream )pp;
	size = p->realStream->Write(p->realStream, data, size);
	p->processed += size;
	return size;
	}

	/* ---------- CSeqInFilter ---------- */

	/*
	typedef struct _IFilter
	{
	void *p;
	void (Free)(void p, ISzAlloc *alloc);
	SRes (SetProps)(void p, const Byte props, size_t propSize, ISzAlloc alloc);
	void (Init)(void p);
	size_t (Filter)(void p, Byte *data, SizeT destLen);
	} IFilter;

	#define FILT_BUF_SIZE (1 << 19)

	typedef struct
	{
	ISeqInStream p;
	ISeqInStream *realStream;
	UInt32 x86State;
	UInt32 ip;
	UInt64 processed;
	CXzCheck check;
	Byte buf[FILT_BUF_SIZE];
	UInt32 bufferPos;
	UInt32 convertedPosBegin;
	UInt32 convertedPosEnd;
	IFilter *filter;
	} CSeqInFilter;

	static SRes SeqInFilter_Read(void pp, void data, size_t *size)
	{
	CSeqInFilter p = (CSeqInFilter )pp;
	size_t remSize = *size;
	*size = 0;

	while (remSize > 0)
	{
	int i;
	if (p->convertedPosBegin != p->convertedPosEnd)
	{
	UInt32 sizeTemp = p->convertedPosEnd - p->convertedPosBegin;
	if (remSize < sizeTemp)
	sizeTemp = (UInt32)remSize;
	memmove(data, p->buf + p->convertedPosBegin, sizeTemp);
	p->convertedPosBegin += sizeTemp;
	data = (void )((Byte )data + sizeTemp);
	remSize -= sizeTemp;
	*size += sizeTemp;
	break;
	}
	for (i = 0; p->convertedPosEnd + i < p->bufferPos; i++)
	p->buf[i] = p->buf[i + p->convertedPosEnd];
	p->bufferPos = i;
	p->convertedPosBegin = p->convertedPosEnd = 0;
	{
	size_t processedSizeTemp = FILT_BUF_SIZE - p->bufferPos;
	RINOK(p->realStream->Read(p->realStream, p->buf + p->bufferPos, &processedSizeTemp));
	p->bufferPos = p->bufferPos + (UInt32)processedSizeTemp;
	}
	p->convertedPosEnd = (UInt32)p->filter->Filter(p->filter->p, p->buf, p->bufferPos);
	if (p->convertedPosEnd == 0)
	{
	if (p->bufferPos == 0)
	break;
	else
	{
	p->convertedPosEnd = p->bufferPos;
	continue;
	}
	}
	if (p->convertedPosEnd > p->bufferPos)
	{
	for (; p->bufferPos < p->convertedPosEnd; p->bufferPos++)
	p->buf[p->bufferPos] = 0;
	p->convertedPosEnd = (UInt32)p->filter->Filter(p->filter->p, p->buf, p->bufferPos);
	}
	}
	return SZ_OK;
	}
	*/

	/*
	typedef struct
	{
	ISeqInStream p;
	ISeqInStream *realStream;
	CMixCoder mixCoder;
	Byte buf[FILT_BUF_SIZE];
	UInt32 bufPos;
	UInt32 bufSize;
	} CMixCoderSeqInStream;

	static SRes CMixCoderSeqInStream_Read(void pp, void data, size_t *size)
	{
	CMixCoderSeqInStream p = (CMixCoderSeqInStream )pp;
	SRes res = SZ_OK;
	size_t remSize = *size;
	*size = 0;
	while (remSize > 0)
	{
	if (p->bufPos == p->bufSize)
	{
	size_t curSize;
	p->bufPos = p->bufSize = 0;
	if (*size != 0)
	break;
	curSize = FILT_BUF_SIZE;
	RINOK(p->realStream->Read(p->realStream, p->buf, &curSize));
	p->bufSize = (UInt32)curSize;
	}
	{
	SizeT destLen = remSize;
	SizeT srcLen = p->bufSize - p->bufPos;
	res = MixCoder_Code(&p->mixCoder, data, &destLen, p->buf + p->bufPos, &srcLen, 0);
	data = (void )((Byte )data + destLen);
	remSize -= destLen;
	*size += destLen;
	p->bufPos += srcLen;
	}
	}
	return res;
	}
	*/

	#ifdef USE_SUBBLOCK
	typedef struct
	{
	ISeqInStream p;
	CSubblockEnc sb;
	UInt64 processed;
	} CSbEncInStream;

	void SbEncInStream_Init(CSbEncInStream *p)
	{
	p->processed = 0;
	SubblockEnc_Init(&p->sb);
	}

	static SRes SbEncInStream_Read(void pp, void data, size_t *size)
	{
	CSbEncInStream p = (CSbEncInStream )pp;
	SRes res = SubblockEnc_Read(&p->sb, data, size);
	p->processed += *size;
	return res;
	}
	#endif

	typedef struct
	{
	/* CMixCoderSeqInStream inStream; */
	CLzma2EncHandle lzma2;
	#ifdef USE_SUBBLOCK
	CSbEncInStream sb;
	#endif
	ISzAlloc *alloc;
	ISzAlloc *bigAlloc;
	} CLzma2WithFilters;


	static void Lzma2WithFilters_Construct(CLzma2WithFilters p, ISzAlloc alloc, ISzAlloc *bigAlloc)
	{
	p->alloc = alloc;
	p->bigAlloc = bigAlloc;
	p->lzma2 = NULL;
	#ifdef USE_SUBBLOCK
	p->sb.p.Read = SbEncInStream_Read;
	SubblockEnc_Construct(&p->sb.sb, p->alloc);
	#endif
	}

	static SRes Lzma2WithFilters_Create(CLzma2WithFilters *p)
	{
	p->lzma2 = Lzma2Enc_Create(p->alloc, p->bigAlloc);
	if (p->lzma2 == 0)
	return SZ_ERROR_MEM;
	return SZ_OK;
	}

	static void Lzma2WithFilters_Free(CLzma2WithFilters *p)
	{
	#ifdef USE_SUBBLOCK
	SubblockEnc_Free(&p->sb.sb);
	#endif
	if (p->lzma2)
	{
	Lzma2Enc_Destroy(p->lzma2);
	p->lzma2 = NULL;
	}
	}

	static SRes Xz_Compress(CXzStream *xz,
	CLzma2WithFilters *lzmaf,
	ISeqOutStream *outStream,
	ISeqInStream *inStream,
	const CLzma2EncProps *lzma2Props,
	Bool useSubblock,
	ICompressProgress *progress)
	{
	xz->flags = XZ_CHECK_CRC32;

	RINOK(Lzma2Enc_SetProps(lzmaf->lzma2, lzma2Props));
	RINOK(Xz_WriteHeader(xz->flags, outStream));

	{
	CSeqCheckInStream checkInStream;
	CSeqSizeOutStream seqSizeOutStream;
	CXzBlock block;
	int filterIndex = 0;

	XzBlock_ClearFlags(&block);
	XzBlock_SetNumFilters(&block, 1 + (useSubblock ? 1 : 0));

	if (useSubblock)
	{
	CXzFilter *f = &block.filters[filterIndex++];
	f->id = XZ_ID_Subblock;
	f->propsSize = 0;
	}

	{
	CXzFilter *f = &block.filters[filterIndex++];
	f->id = XZ_ID_LZMA2;
	f->propsSize = 1;
	f->props[0] = Lzma2Enc_WriteProperties(lzmaf->lzma2);
	}

	seqSizeOutStream.p.Write = MyWrite;
	seqSizeOutStream.realStream = outStream;
	seqSizeOutStream.processed = 0;

	RINOK(XzBlock_WriteHeader(&block, &seqSizeOutStream.p));

	checkInStream.p.Read = SeqCheckInStream_Read;
	checkInStream.realStream = inStream;
	SeqCheckInStream_Init(&checkInStream, XzFlags_GetCheckType(xz->flags));

	#ifdef USE_SUBBLOCK
	if (useSubblock)
	{
	lzmaf->sb.sb.inStream = &checkInStream.p;
	SubblockEnc_Init(&lzmaf->sb.sb);
	}
	#endif

	{
	UInt64 packPos = seqSizeOutStream.processed;
	SRes res = Lzma2Enc_Encode(lzmaf->lzma2, &seqSizeOutStream.p,
	#ifdef USE_SUBBLOCK
	useSubblock ? &lzmaf->sb.p:
	#endif
	&checkInStream.p,
	progress);
	RINOK(res);
	block.unpackSize = checkInStream.processed;
	block.packSize = seqSizeOutStream.processed - packPos;
	}

	{
	unsigned padSize = 0;
	Byte buf[128];
	while((((unsigned)block.packSize + padSize) & 3) != 0)
	buf[padSize++] = 0;
	SeqCheckInStream_GetDigest(&checkInStream, buf + padSize);
	RINOK(WriteBytes(&seqSizeOutStream.p, buf, padSize + XzFlags_GetCheckSize(xz->flags)));
	RINOK(Xz_AddIndexRecord(xz, block.unpackSize, seqSizeOutStream.processed - padSize, &g_Alloc));
	}
	}
	return Xz_WriteFooter(xz, outStream);
	}

	SRes Xz_Encode(ISeqOutStream outStream, ISeqInStream inStream,
	const CLzma2EncProps *lzma2Props, Bool useSubblock,
	ICompressProgress *progress)
	{
	SRes res;
	CXzStream xz;
	CLzma2WithFilters lzmaf;
	Xz_Construct(&xz);
	Lzma2WithFilters_Construct(&lzmaf, &g_Alloc, &g_BigAlloc);
	res = Lzma2WithFilters_Create(&lzmaf);
	if (res == SZ_OK)
	res = Xz_Compress(&xz, &lzmaf, outStream, inStream,
	lzma2Props, useSubblock, progress);
	Lzma2WithFilters_Free(&lzmaf);
	Xz_Free(&xz, &g_Alloc);
	return res;
	}

	SRes Xz_EncodeEmpty(ISeqOutStream *outStream)
	{
	SRes res;
	CXzStream xz;
	Xz_Construct(&xz);
	res = Xz_WriteHeader(xz.flags, outStream);
	if (res == SZ_OK)
	res = Xz_WriteFooter(&xz, outStream);
	Xz_Free(&xz, &g_Alloc);
	return res;
	}