/* 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; }