sravan/system76-edk2
1
0
Fork 0
Code Issues Pull Requests Packages Projects Releases Wiki Activity
system76-edk2/BaseTools/Source/C/LzmaCompress/Sdk/C/LzmaEnc.c
Yonghong Zhu b9da8fe0e3 BaseTools/LZMA: fix the format issue for last patch 
There are no functional changes in this patch. fixing the format base on
last commit.
The only change is 1) add back the blank line, which can help we better
compare with the original LZMA source code. 2) remove the indent of
#ifndef and #endif.

Contributed-under: TianoCore Contribution Agreement 1.0
Signed-off-by: Yonghong Zhu <yonghong.zhu@intel.com>
Reviewed-by: Liming Gao <liming.gao@intel.com>
2016-03-03 12:06:41 +08:00

2294 lines
64 KiB
C
Raw Blame History

/** @file
Based on LZMA SDK 4.65:
LzmaEnc.c -- LZMA Encoder
2009-02-02 : Igor Pavlov : Public domain
Copyright (c) 2011 - 2016, Intel Corporation. All rights reserved.<BR>
This program and the accompanying materials
are licensed and made available under the terms and conditions of the BSD License
which accompanies this distribution. The full text of the license may be found at
http://opensource.org/licenses/bsd-license.php
THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.
**/
#include <string.h>
/* #define SHOW_STAT */
/* #define SHOW_STAT2 */
#if defined(SHOW_STAT) || defined(SHOW_STAT2)
#include <stdio.h>
#endif
#include "LzmaEnc.h"
#include "LzFind.h"
#ifdef COMPRESS_MF_MT
#include "LzFindMt.h"
#endif
#ifdef SHOW_STAT
static int ttt = 0;
#endif
#define kBlockSizeMax ((1 << LZMA_NUM_BLOCK_SIZE_BITS) - 1)
#define kBlockSize (9 << 10)
#define kUnpackBlockSize (1 << 18)
#define kMatchArraySize (1 << 21)
#define kMatchRecordMaxSize ((LZMA_MATCH_LEN_MAX * 2 + 3) * LZMA_MATCH_LEN_MAX)
#define kNumMaxDirectBits (31)
#define kNumTopBits 24
#define kTopValue ((UInt32)1 << kNumTopBits)
#define kNumBitModelTotalBits 11
#define kBitModelTotal (1 << kNumBitModelTotalBits)
#define kNumMoveBits 5
#define kProbInitValue (kBitModelTotal >> 1)
#define kNumMoveReducingBits 4
#define kNumBitPriceShiftBits 4
#define kBitPrice (1 << kNumBitPriceShiftBits)
void LzmaEncProps_Init(CLzmaEncProps *p)
{
p->level = 5;
p->dictSize = p->mc = 0;
p->lc = p->lp = p->pb = p->algo = p->fb = p->btMode = p->numHashBytes = p->numThreads = -1;
p->writeEndMark = 0;
}
void LzmaEncProps_Normalize(CLzmaEncProps *p)
{
int level = p->level;
if (level < 0) level = 5;
p->level = level;
if (p->dictSize == 0) p->dictSize = (level <= 5 ? (1 << (level * 2 + 14)) : (level == 6 ? (1 << 25) : (1 << 26)));
if (p->lc < 0) p->lc = 3;
if (p->lp < 0) p->lp = 0;
if (p->pb < 0) p->pb = 2;
if (p->algo < 0) p->algo = (level < 5 ? 0 : 1);
if (p->fb < 0) p->fb = (level < 7 ? 32 : 64);
if (p->btMode < 0) p->btMode = (p->algo == 0 ? 0 : 1);
if (p->numHashBytes < 0) p->numHashBytes = 4;
if (p->mc == 0) p->mc = (16 + (p->fb >> 1)) >> (p->btMode ? 0 : 1);
if (p->numThreads < 0)
p->numThreads =
#ifdef COMPRESS_MF_MT
((p->btMode && p->algo) ? 2 : 1);
#else
1;
#endif
}
UInt32 LzmaEncProps_GetDictSize(const CLzmaEncProps *props2)
{
CLzmaEncProps props = *props2;
LzmaEncProps_Normalize(&props);
return props.dictSize;
}
/* #define LZMA_LOG_BSR */
/* Define it for Intel's CPU */
#ifdef LZMA_LOG_BSR
#define kDicLogSizeMaxCompress 30
#define BSR2_RET(pos, res) { unsigned long i; _BitScanReverse(&i, (pos)); res = (i + i) + ((pos >> (i - 1)) & 1); }
UInt32 GetPosSlot1(UInt32 pos)
{
UInt32 res;
BSR2_RET(pos, res);
return res;
}
#define GetPosSlot2(pos, res) { BSR2_RET(pos, res); }
#define GetPosSlot(pos, res) { if (pos < 2) res = pos; else BSR2_RET(pos, res); }
#else
#define kNumLogBits (9 + (int)sizeof(size_t) / 2)
#define kDicLogSizeMaxCompress ((kNumLogBits - 1) * 2 + 7)
void LzmaEnc_FastPosInit(Byte *g_FastPos)
{
int c = 2, slotFast;
g_FastPos[0] = 0;
g_FastPos[1] = 1;
for (slotFast = 2; slotFast < kNumLogBits * 2; slotFast++)
{
UInt32 k = (1 << ((slotFast >> 1) - 1));
UInt32 j;
for (j = 0; j < k; j++, c++)
g_FastPos[c] = (Byte)slotFast;
}
}
#define BSR2_RET(pos, res) { UInt32 ij = 6 + ((kNumLogBits - 1) & \
(0 - (((((UInt32)1 << (kNumLogBits + 6)) - 1) - pos) >> 31))); \
res = p->g_FastPos[pos >> ij] + (ij * 2); }
/*
#define BSR2_RET(pos, res) { res = (pos < (1 << (kNumLogBits + 6))) ? \
p->g_FastPos[pos >> 6] + 12 : \
p->g_FastPos[pos >> (6 + kNumLogBits - 1)] + (6 + (kNumLogBits - 1)) * 2; }
*/
#define GetPosSlot1(pos) p->g_FastPos[pos]
#define GetPosSlot2(pos, res) { BSR2_RET(pos, res); }
#define GetPosSlot(pos, res) { if (pos < kNumFullDistances) res = p->g_FastPos[pos]; else BSR2_RET(pos, res); }
#endif
#define LZMA_NUM_REPS 4
typedef unsigned CState;
typedef struct _COptimal
{
UInt32 price;
CState state;
int prev1IsChar;
int prev2;
UInt32 posPrev2;
UInt32 backPrev2;
UInt32 posPrev;
UInt32 backPrev;
UInt32 backs[LZMA_NUM_REPS];
} COptimal;
#define kNumOpts (1 << 12)
#define kNumLenToPosStates 4
#define kNumPosSlotBits 6
#define kDicLogSizeMin 0
#define kDicLogSizeMax 32
#define kDistTableSizeMax (kDicLogSizeMax * 2)
#define kNumAlignBits 4
#define kAlignTableSize (1 << kNumAlignBits)
#define kAlignMask (kAlignTableSize - 1)
#define kStartPosModelIndex 4
#define kEndPosModelIndex 14
#define kNumPosModels (kEndPosModelIndex - kStartPosModelIndex)
#define kNumFullDistances (1 << (kEndPosModelIndex / 2))
#ifdef _LZMA_PROB32
#define CLzmaProb UInt32
#else
#define CLzmaProb UInt16
#endif
#define LZMA_PB_MAX 4
#define LZMA_LC_MAX 8
#define LZMA_LP_MAX 4
#define LZMA_NUM_PB_STATES_MAX (1 << LZMA_PB_MAX)
#define kLenNumLowBits 3
#define kLenNumLowSymbols (1 << kLenNumLowBits)
#define kLenNumMidBits 3
#define kLenNumMidSymbols (1 << kLenNumMidBits)
#define kLenNumHighBits 8
#define kLenNumHighSymbols (1 << kLenNumHighBits)
#define kLenNumSymbolsTotal (kLenNumLowSymbols + kLenNumMidSymbols + kLenNumHighSymbols)
#define LZMA_MATCH_LEN_MIN 2
#define LZMA_MATCH_LEN_MAX (LZMA_MATCH_LEN_MIN + kLenNumSymbolsTotal - 1)
#define kNumStates 12
typedef struct
{
CLzmaProb choice;
CLzmaProb choice2;
CLzmaProb low[LZMA_NUM_PB_STATES_MAX << kLenNumLowBits];
CLzmaProb mid[LZMA_NUM_PB_STATES_MAX << kLenNumMidBits];
CLzmaProb high[kLenNumHighSymbols];
} CLenEnc;
typedef struct
{
CLenEnc p;
UInt32 prices[LZMA_NUM_PB_STATES_MAX][kLenNumSymbolsTotal];
UInt32 tableSize;
UInt32 counters[LZMA_NUM_PB_STATES_MAX];
} CLenPriceEnc;
typedef struct _CRangeEnc
{
UInt32 range;
Byte cache;
UInt64 low;
UInt64 cacheSize;
Byte *buf;
Byte *bufLim;
Byte *bufBase;
ISeqOutStream *outStream;
UInt64 processed;
SRes res;
} CRangeEnc;
typedef struct _CSeqInStreamBuf
{
ISeqInStream funcTable;
const Byte *data;
SizeT rem;
} CSeqInStreamBuf;
static SRes MyRead(void *pp, void *data, size_t *size)
{
size_t curSize = *size;
CSeqInStreamBuf *p = (CSeqInStreamBuf *)pp;
if (p->rem < curSize)
curSize = p->rem;
memcpy(data, p->data, curSize);
p->rem -= curSize;
p->data += curSize;
*size = curSize;
return SZ_OK;
}
typedef struct
{
CLzmaProb *litProbs;
CLzmaProb isMatch[kNumStates][LZMA_NUM_PB_STATES_MAX];
CLzmaProb isRep[kNumStates];
CLzmaProb isRepG0[kNumStates];
CLzmaProb isRepG1[kNumStates];
CLzmaProb isRepG2[kNumStates];
CLzmaProb isRep0Long[kNumStates][LZMA_NUM_PB_STATES_MAX];
CLzmaProb posSlotEncoder[kNumLenToPosStates][1 << kNumPosSlotBits];
CLzmaProb posEncoders[kNumFullDistances - kEndPosModelIndex];
CLzmaProb posAlignEncoder[1 << kNumAlignBits];
CLenPriceEnc lenEnc;
CLenPriceEnc repLenEnc;
UInt32 reps[LZMA_NUM_REPS];
UInt32 state;
} CSaveState;
typedef struct _CLzmaEnc
{
IMatchFinder matchFinder;
void *matchFinderObj;
#ifdef COMPRESS_MF_MT
Bool mtMode;
CMatchFinderMt matchFinderMt;
#endif
CMatchFinder matchFinderBase;
#ifdef COMPRESS_MF_MT
Byte pad[128];
#endif
UInt32 optimumEndIndex;
UInt32 optimumCurrentIndex;
UInt32 longestMatchLength;
UInt32 numPairs;
UInt32 numAvail;
COptimal opt[kNumOpts];
#ifndef LZMA_LOG_BSR
Byte g_FastPos[1 << kNumLogBits];
#endif
UInt32 ProbPrices[kBitModelTotal >> kNumMoveReducingBits];
UInt32 matches[LZMA_MATCH_LEN_MAX * 2 + 2 + 1];
UInt32 numFastBytes;
UInt32 additionalOffset;
UInt32 reps[LZMA_NUM_REPS];
UInt32 state;
UInt32 posSlotPrices[kNumLenToPosStates][kDistTableSizeMax];
UInt32 distancesPrices[kNumLenToPosStates][kNumFullDistances];
UInt32 alignPrices[kAlignTableSize];
UInt32 alignPriceCount;
UInt32 distTableSize;
unsigned lc, lp, pb;
unsigned lpMask, pbMask;
CLzmaProb *litProbs;
CLzmaProb isMatch[kNumStates][LZMA_NUM_PB_STATES_MAX];
CLzmaProb isRep[kNumStates];
CLzmaProb isRepG0[kNumStates];
CLzmaProb isRepG1[kNumStates];
CLzmaProb isRepG2[kNumStates];
CLzmaProb isRep0Long[kNumStates][LZMA_NUM_PB_STATES_MAX];
CLzmaProb posSlotEncoder[kNumLenToPosStates][1 << kNumPosSlotBits];
CLzmaProb posEncoders[kNumFullDistances - kEndPosModelIndex];
CLzmaProb posAlignEncoder[1 << kNumAlignBits];
CLenPriceEnc lenEnc;
CLenPriceEnc repLenEnc;
unsigned lclp;
Bool fastMode;
CRangeEnc rc;
Bool writeEndMark;
UInt64 nowPos64;
UInt32 matchPriceCount;
Bool finished;
Bool multiThread;
SRes result;
UInt32 dictSize;
UInt32 matchFinderCycles;
ISeqInStream *inStream;
CSeqInStreamBuf seqBufInStream;
CSaveState saveState;
} CLzmaEnc;
void LzmaEnc_SaveState(CLzmaEncHandle pp)
{
CLzmaEnc *p = (CLzmaEnc *)pp;
CSaveState *dest = &p->saveState;
int i;
dest->lenEnc = p->lenEnc;
dest->repLenEnc = p->repLenEnc;
dest->state = p->state;
for (i = 0; i < kNumStates; i++)
{
memcpy(dest->isMatch[i], p->isMatch[i], sizeof(p->isMatch[i]));
memcpy(dest->isRep0Long[i], p->isRep0Long[i], sizeof(p->isRep0Long[i]));
}
for (i = 0; i < kNumLenToPosStates; i++)
memcpy(dest->posSlotEncoder[i], p->posSlotEncoder[i], sizeof(p->posSlotEncoder[i]));
memcpy(dest->isRep, p->isRep, sizeof(p->isRep));
memcpy(dest->isRepG0, p->isRepG0, sizeof(p->isRepG0));
memcpy(dest->isRepG1, p->isRepG1, sizeof(p->isRepG1));
memcpy(dest->isRepG2, p->isRepG2, sizeof(p->isRepG2));
memcpy(dest->posEncoders, p->posEncoders, sizeof(p->posEncoders));
memcpy(dest->posAlignEncoder, p->posAlignEncoder, sizeof(p->posAlignEncoder));
memcpy(dest->reps, p->reps, sizeof(p->reps));
memcpy(dest->litProbs, p->litProbs, (0x300 << p->lclp) * sizeof(CLzmaProb));
}
void LzmaEnc_RestoreState(CLzmaEncHandle pp)
{
CLzmaEnc *dest = (CLzmaEnc *)pp;
const CSaveState *p = &dest->saveState;
int i;
dest->lenEnc = p->lenEnc;
dest->repLenEnc = p->repLenEnc;
dest->state = p->state;
for (i = 0; i < kNumStates; i++)
{
memcpy(dest->isMatch[i], p->isMatch[i], sizeof(p->isMatch[i]));
memcpy(dest->isRep0Long[i], p->isRep0Long[i], sizeof(p->isRep0Long[i]));
}
for (i = 0; i < kNumLenToPosStates; i++)
memcpy(dest->posSlotEncoder[i], p->posSlotEncoder[i], sizeof(p->posSlotEncoder[i]));
memcpy(dest->isRep, p->isRep, sizeof(p->isRep));
memcpy(dest->isRepG0, p->isRepG0, sizeof(p->isRepG0));
memcpy(dest->isRepG1, p->isRepG1, sizeof(p->isRepG1));
memcpy(dest->isRepG2, p->isRepG2, sizeof(p->isRepG2));
memcpy(dest->posEncoders, p->posEncoders, sizeof(p->posEncoders));
memcpy(dest->posAlignEncoder, p->posAlignEncoder, sizeof(p->posAlignEncoder));
memcpy(dest->reps, p->reps, sizeof(p->reps));
memcpy(dest->litProbs, p->litProbs, (0x300 << dest->lclp) * sizeof(CLzmaProb));
}
SRes LzmaEnc_SetProps(CLzmaEncHandle pp, const CLzmaEncProps *props2)
{
CLzmaEnc *p = (CLzmaEnc *)pp;
CLzmaEncProps props = *props2;
LzmaEncProps_Normalize(&props);
if (props.lc > LZMA_LC_MAX || props.lp > LZMA_LP_MAX || props.pb > LZMA_PB_MAX ||
props.dictSize > (1 << kDicLogSizeMaxCompress) || props.dictSize > (1 << 30))
return SZ_ERROR_PARAM;
p->dictSize = props.dictSize;
p->matchFinderCycles = props.mc;
{
unsigned fb = props.fb;
if (fb < 5)
fb = 5;
if (fb > LZMA_MATCH_LEN_MAX)
fb = LZMA_MATCH_LEN_MAX;
p->numFastBytes = fb;
}
p->lc = props.lc;
p->lp = props.lp;
p->pb = props.pb;
p->fastMode = (props.algo == 0);
p->matchFinderBase.btMode = props.btMode;
{
UInt32 numHashBytes = 4;
if (props.btMode)
{
if (props.numHashBytes < 2)
numHashBytes = 2;
else if (props.numHashBytes < 4)
numHashBytes = props.numHashBytes;
}
p->matchFinderBase.numHashBytes = numHashBytes;
}
p->matchFinderBase.cutValue = props.mc;
p->writeEndMark = props.writeEndMark;
#ifdef COMPRESS_MF_MT
/*
if (newMultiThread != _multiThread)
{
ReleaseMatchFinder();
_multiThread = newMultiThread;
}
*/
p->multiThread = (props.numThreads > 1);
#endif
return SZ_OK;
}
static const int kLiteralNextStates[kNumStates] = {0, 0, 0, 0, 1, 2, 3, 4, 5, 6, 4, 5};
static const int kMatchNextStates[kNumStates] = {7, 7, 7, 7, 7, 7, 7, 10, 10, 10, 10, 10};
static const int kRepNextStates[kNumStates] = {8, 8, 8, 8, 8, 8, 8, 11, 11, 11, 11, 11};
static const int kShortRepNextStates[kNumStates]= {9, 9, 9, 9, 9, 9, 9, 11, 11, 11, 11, 11};
#define IsCharState(s) ((s) < 7)
#define GetLenToPosState(len) (((len) < kNumLenToPosStates + 1) ? (len) - 2 : kNumLenToPosStates - 1)
#define kInfinityPrice (1 << 30)
static void RangeEnc_Construct(CRangeEnc *p)
{
p->outStream = 0;
p->bufBase = 0;
}
#define RangeEnc_GetProcessed(p) ((p)->processed + ((p)->buf - (p)->bufBase) + (p)->cacheSize)
#define RC_BUF_SIZE (1 << 16)
static int RangeEnc_Alloc(CRangeEnc *p, ISzAlloc *alloc)
{
if (p->bufBase == 0)
{
p->bufBase = (Byte *)alloc->Alloc(alloc, RC_BUF_SIZE);
if (p->bufBase == 0)
return 0;
p->bufLim = p->bufBase + RC_BUF_SIZE;
}
return 1;
}
static void RangeEnc_Free(CRangeEnc *p, ISzAlloc *alloc)
{
alloc->Free(alloc, p->bufBase);
p->bufBase = 0;
}
static void RangeEnc_Init(CRangeEnc *p)
{
/* Stream.Init(); */
p->low = 0;
p->range = 0xFFFFFFFF;
p->cacheSize = 1;
p->cache = 0;
p->buf = p->bufBase;
p->processed = 0;
p->res = SZ_OK;
}
static void RangeEnc_FlushStream(CRangeEnc *p)
{
size_t num;
if (p->res != SZ_OK)
return;
num = p->buf - p->bufBase;
if (num != p->outStream->Write(p->outStream, p->bufBase, num))
p->res = SZ_ERROR_WRITE;
p->processed += num;
p->buf = p->bufBase;
}
static void MY_FAST_CALL RangeEnc_ShiftLow(CRangeEnc *p)
{
if ((UInt32)p->low < (UInt32)0xFF000000 || (int)(p->low >> 32) != 0)
{
Byte temp = p->cache;
do
{
Byte *buf = p->buf;
*buf++ = (Byte)(temp + (Byte)(p->low >> 32));
p->buf = buf;
if (buf == p->bufLim)
RangeEnc_FlushStream(p);
temp = 0xFF;
}
while (--p->cacheSize != 0);
p->cache = (Byte)((UInt32)p->low >> 24);
}
p->cacheSize++;
p->low = (UInt32)p->low << 8;
}
static void RangeEnc_FlushData(CRangeEnc *p)
{
int i;
for (i = 0; i < 5; i++)
RangeEnc_ShiftLow(p);
}
static void RangeEnc_EncodeDirectBits(CRangeEnc *p, UInt32 value, int numBits)
{
do
{
p->range >>= 1;
p->low += p->range & (0 - ((value >> --numBits) & 1));
if (p->range < kTopValue)
{
p->range <<= 8;
RangeEnc_ShiftLow(p);
}
}
while (numBits != 0);
}
static void RangeEnc_EncodeBit(CRangeEnc *p, CLzmaProb *prob, UInt32 symbol)
{
UInt32 ttt = *prob;
UInt32 newBound = (p->range >> kNumBitModelTotalBits) * ttt;
if (symbol == 0)
{
p->range = newBound;
ttt += (kBitModelTotal - ttt) >> kNumMoveBits;
}
else
{
p->low += newBound;
p->range -= newBound;
ttt -= ttt >> kNumMoveBits;
}
*prob = (CLzmaProb)ttt;
if (p->range < kTopValue)
{
p->range <<= 8;
RangeEnc_ShiftLow(p);
}
}
static void LitEnc_Encode(CRangeEnc *p, CLzmaProb *probs, UInt32 symbol)
{
symbol |= 0x100;
do
{
RangeEnc_EncodeBit(p, probs + (symbol >> 8), (symbol >> 7) & 1);
symbol <<= 1;
}
while (symbol < 0x10000);
}
static void LitEnc_EncodeMatched(CRangeEnc *p, CLzmaProb *probs, UInt32 symbol, UInt32 matchByte)
{
UInt32 offs = 0x100;
symbol |= 0x100;
do
{
matchByte <<= 1;
RangeEnc_EncodeBit(p, probs + (offs + (matchByte & offs) + (symbol >> 8)), (symbol >> 7) & 1);
symbol <<= 1;
offs &= ~(matchByte ^ symbol);
}
while (symbol < 0x10000);
}
void LzmaEnc_InitPriceTables(UInt32 *ProbPrices)
{
UInt32 i;
for (i = (1 << kNumMoveReducingBits) / 2; i < kBitModelTotal; i += (1 << kNumMoveReducingBits))
{
const int kCyclesBits = kNumBitPriceShiftBits;
UInt32 w = i;
UInt32 bitCount = 0;
int j;
for (j = 0; j < kCyclesBits; j++)
{
w = w * w;
bitCount <<= 1;
while (w >= ((UInt32)1 << 16))
{
w >>= 1;
bitCount++;
}
}
ProbPrices[i >> kNumMoveReducingBits] = ((kNumBitModelTotalBits << kCyclesBits) - 15 - bitCount);
}
}
#define GET_PRICE(prob, symbol) \
p->ProbPrices[((prob) ^ (((-(int)(symbol))) & (kBitModelTotal - 1))) >> kNumMoveReducingBits];
#define GET_PRICEa(prob, symbol) \
ProbPrices[((prob) ^ ((-((int)(symbol))) & (kBitModelTotal - 1))) >> kNumMoveReducingBits];
#define GET_PRICE_0(prob) p->ProbPrices[(prob) >> kNumMoveReducingBits]
#define GET_PRICE_1(prob) p->ProbPrices[((prob) ^ (kBitModelTotal - 1)) >> kNumMoveReducingBits]
#define GET_PRICE_0a(prob) ProbPrices[(prob) >> kNumMoveReducingBits]
#define GET_PRICE_1a(prob) ProbPrices[((prob) ^ (kBitModelTotal - 1)) >> kNumMoveReducingBits]
static UInt32 LitEnc_GetPrice(const CLzmaProb *probs, UInt32 symbol, UInt32 *ProbPrices)
{
UInt32 price = 0;
symbol |= 0x100;
do
{
price += GET_PRICEa(probs[symbol >> 8], (symbol >> 7) & 1);
symbol <<= 1;
}
while (symbol < 0x10000);
return price;
}
static UInt32 LitEnc_GetPriceMatched(const CLzmaProb *probs, UInt32 symbol, UInt32 matchByte, UInt32 *ProbPrices)
{
UInt32 price = 0;
UInt32 offs = 0x100;
symbol |= 0x100;
do
{
matchByte <<= 1;
price += GET_PRICEa(probs[offs + (matchByte & offs) + (symbol >> 8)], (symbol >> 7) & 1);
symbol <<= 1;
offs &= ~(matchByte ^ symbol);
}
while (symbol < 0x10000);
return price;
}
static void RcTree_Encode(CRangeEnc *rc, CLzmaProb *probs, int numBitLevels, UInt32 symbol)
{
UInt32 m = 1;
int i;
for (i = numBitLevels; i != 0;)
{
UInt32 bit;
i--;
bit = (symbol >> i) & 1;
RangeEnc_EncodeBit(rc, probs + m, bit);
m = (m << 1) | bit;
}
}
static void RcTree_ReverseEncode(CRangeEnc *rc, CLzmaProb *probs, int numBitLevels, UInt32 symbol)
{
UInt32 m = 1;
int i;
for (i = 0; i < numBitLevels; i++)
{
UInt32 bit = symbol & 1;
RangeEnc_EncodeBit(rc, probs + m, bit);
m = (m << 1) | bit;
symbol >>= 1;
}
}
static UInt32 RcTree_GetPrice(const CLzmaProb *probs, int numBitLevels, UInt32 symbol, UInt32 *ProbPrices)
{
UInt32 price = 0;
symbol |= (1 << numBitLevels);
while (symbol != 1)
{
price += GET_PRICEa(probs[symbol >> 1], symbol & 1);
symbol >>= 1;
}
return price;
}
static UInt32 RcTree_ReverseGetPrice(const CLzmaProb *probs, int numBitLevels, UInt32 symbol, UInt32 *ProbPrices)
{
UInt32 price = 0;
UInt32 m = 1;
int i;
for (i = numBitLevels; i != 0; i--)
{
UInt32 bit = symbol & 1;
symbol >>= 1;
price += GET_PRICEa(probs[m], bit);
m = (m << 1) | bit;
}
return price;
}
static void LenEnc_Init(CLenEnc *p)
{
unsigned i;
p->choice = p->choice2 = kProbInitValue;
for (i = 0; i < (LZMA_NUM_PB_STATES_MAX << kLenNumLowBits); i++)
p->low[i] = kProbInitValue;
for (i = 0; i < (LZMA_NUM_PB_STATES_MAX << kLenNumMidBits); i++)
p->mid[i] = kProbInitValue;
for (i = 0; i < kLenNumHighSymbols; i++)
p->high[i] = kProbInitValue;
}
static void LenEnc_Encode(CLenEnc *p, CRangeEnc *rc, UInt32 symbol, UInt32 posState)
{
if (symbol < kLenNumLowSymbols)
{
RangeEnc_EncodeBit(rc, &p->choice, 0);
RcTree_Encode(rc, p->low + (posState << kLenNumLowBits), kLenNumLowBits, symbol);
}
else
{
RangeEnc_EncodeBit(rc, &p->choice, 1);
if (symbol < kLenNumLowSymbols + kLenNumMidSymbols)
{
RangeEnc_EncodeBit(rc, &p->choice2, 0);
RcTree_Encode(rc, p->mid + (posState << kLenNumMidBits), kLenNumMidBits, symbol - kLenNumLowSymbols);
}
else
{
RangeEnc_EncodeBit(rc, &p->choice2, 1);
RcTree_Encode(rc, p->high, kLenNumHighBits, symbol - kLenNumLowSymbols - kLenNumMidSymbols);
}
}
}
static void LenEnc_SetPrices(CLenEnc *p, UInt32 posState, UInt32 numSymbols, UInt32 *prices, UInt32 *ProbPrices)
{
UInt32 a0 = GET_PRICE_0a(p->choice);
UInt32 a1 = GET_PRICE_1a(p->choice);
UInt32 b0 = a1 + GET_PRICE_0a(p->choice2);
UInt32 b1 = a1 + GET_PRICE_1a(p->choice2);
UInt32 i = 0;
for (i = 0; i < kLenNumLowSymbols; i++)
{
if (i >= numSymbols)
return;
prices[i] = a0 + RcTree_GetPrice(p->low + (posState << kLenNumLowBits), kLenNumLowBits, i, ProbPrices);
}
for (; i < kLenNumLowSymbols + kLenNumMidSymbols; i++)
{
if (i >= numSymbols)
return;
prices[i] = b0 + RcTree_GetPrice(p->mid + (posState << kLenNumMidBits), kLenNumMidBits, i - kLenNumLowSymbols, ProbPrices);
}
for (; i < numSymbols; i++)
prices[i] = b1 + RcTree_GetPrice(p->high, kLenNumHighBits, i - kLenNumLowSymbols - kLenNumMidSymbols, ProbPrices);
}
static void MY_FAST_CALL LenPriceEnc_UpdateTable(CLenPriceEnc *p, UInt32 posState, UInt32 *ProbPrices)
{
LenEnc_SetPrices(&p->p, posState, p->tableSize, p->prices[posState], ProbPrices);
p->counters[posState] = p->tableSize;
}
static void LenPriceEnc_UpdateTables(CLenPriceEnc *p, UInt32 numPosStates, UInt32 *ProbPrices)
{
UInt32 posState;
for (posState = 0; posState < numPosStates; posState++)
LenPriceEnc_UpdateTable(p, posState, ProbPrices);
}
static void LenEnc_Encode2(CLenPriceEnc *p, CRangeEnc *rc, UInt32 symbol, UInt32 posState, Bool updatePrice, UInt32 *ProbPrices)
{
LenEnc_Encode(&p->p, rc, symbol, posState);
if (updatePrice)
if (--p->counters[posState] == 0)
LenPriceEnc_UpdateTable(p, posState, ProbPrices);
}
static void MovePos(CLzmaEnc *p, UInt32 num)
{
#ifdef SHOW_STAT
ttt += num;
printf("\n MovePos %d", num);
#endif
if (num != 0)
{
p->additionalOffset += num;
p->matchFinder.Skip(p->matchFinderObj, num);
}
}
static UInt32 ReadMatchDistances(CLzmaEnc *p, UInt32 *numDistancePairsRes)
{
UInt32 lenRes = 0, numPairs;
p->numAvail = p->matchFinder.GetNumAvailableBytes(p->matchFinderObj);
numPairs = p->matchFinder.GetMatches(p->matchFinderObj, p->matches);
#ifdef SHOW_STAT
printf("\n i = %d numPairs = %d ", ttt, numPairs / 2);
ttt++;
{
UInt32 i;
for (i = 0; i < numPairs; i += 2)
printf("%2d %6d | ", p->matches[i], p->matches[i + 1]);
}
#endif
if (numPairs > 0)
{
lenRes = p->matches[numPairs - 2];
if (lenRes == p->numFastBytes)
{
const Byte *pby = p->matchFinder.GetPointerToCurrentPos(p->matchFinderObj) - 1;
UInt32 distance = p->matches[numPairs - 1] + 1;
UInt32 numAvail = p->numAvail;
if (numAvail > LZMA_MATCH_LEN_MAX)
numAvail = LZMA_MATCH_LEN_MAX;
{
const Byte *pby2 = pby - distance;
for (; lenRes < numAvail && pby[lenRes] == pby2[lenRes]; lenRes++);
}
}
}
p->additionalOffset++;
*numDistancePairsRes = numPairs;
return lenRes;
}
#define MakeAsChar(p) (p)->backPrev = (UInt32)(-1); (p)->prev1IsChar = False;
#define MakeAsShortRep(p) (p)->backPrev = 0; (p)->prev1IsChar = False;
#define IsShortRep(p) ((p)->backPrev == 0)
static UInt32 GetRepLen1Price(CLzmaEnc *p, UInt32 state, UInt32 posState)
{
return
GET_PRICE_0(p->isRepG0[state]) +
GET_PRICE_0(p->isRep0Long[state][posState]);
}
static UInt32 GetPureRepPrice(CLzmaEnc *p, UInt32 repIndex, UInt32 state, UInt32 posState)
{
UInt32 price;
if (repIndex == 0)
{
price = GET_PRICE_0(p->isRepG0[state]);
price += GET_PRICE_1(p->isRep0Long[state][posState]);
}
else
{
price = GET_PRICE_1(p->isRepG0[state]);
if (repIndex == 1)
price += GET_PRICE_0(p->isRepG1[state]);
else
{
price += GET_PRICE_1(p->isRepG1[state]);
price += GET_PRICE(p->isRepG2[state], repIndex - 2);
}
}
return price;
}
static UInt32 GetRepPrice(CLzmaEnc *p, UInt32 repIndex, UInt32 len, UInt32 state, UInt32 posState)
{
return p->repLenEnc.prices[posState][len - LZMA_MATCH_LEN_MIN] +
GetPureRepPrice(p, repIndex, state, posState);
}
static UInt32 Backward(CLzmaEnc *p, UInt32 *backRes, UInt32 cur)
{
UInt32 posMem = p->opt[cur].posPrev;
UInt32 backMem = p->opt[cur].backPrev;
p->optimumEndIndex = cur;
do
{
if (p->opt[cur].prev1IsChar)
{
MakeAsChar(&p->opt[posMem])
p->opt[posMem].posPrev = posMem - 1;
if (p->opt[cur].prev2)
{
p->opt[posMem - 1].prev1IsChar = False;
p->opt[posMem - 1].posPrev = p->opt[cur].posPrev2;
p->opt[posMem - 1].backPrev = p->opt[cur].backPrev2;
}
}
{
UInt32 posPrev = posMem;
UInt32 backCur = backMem;
backMem = p->opt[posPrev].backPrev;
posMem = p->opt[posPrev].posPrev;
p->opt[posPrev].backPrev = backCur;
p->opt[posPrev].posPrev = cur;
cur = posPrev;
}
}
while (cur != 0);
*backRes = p->opt[0].backPrev;
p->optimumCurrentIndex = p->opt[0].posPrev;
return p->optimumCurrentIndex;
}
#define LIT_PROBS(pos, prevByte) (p->litProbs + ((((pos) & p->lpMask) << p->lc) + ((prevByte) >> (8 - p->lc))) * 0x300)
static UInt32 GetOptimum(CLzmaEnc *p, UInt32 position, UInt32 *backRes)
{
UInt32 numAvail, mainLen, numPairs, repMaxIndex, i, posState, lenEnd, len, cur;
UInt32 matchPrice, repMatchPrice, normalMatchPrice;
UInt32 reps[LZMA_NUM_REPS], repLens[LZMA_NUM_REPS];
UInt32 *matches;
const Byte *data;
Byte curByte, matchByte;
if (p->optimumEndIndex != p->optimumCurrentIndex)
{
const COptimal *opt = &p->opt[p->optimumCurrentIndex];
UInt32 lenRes = opt->posPrev - p->optimumCurrentIndex;
*backRes = opt->backPrev;
p->optimumCurrentIndex = opt->posPrev;
return lenRes;
}
p->optimumCurrentIndex = p->optimumEndIndex = 0;
if (p->additionalOffset == 0)
mainLen = ReadMatchDistances(p, &numPairs);
else
{
mainLen = p->longestMatchLength;
numPairs = p->numPairs;
}
numAvail = p->numAvail;
if (numAvail < 2)
{
*backRes = (UInt32)(-1);
return 1;
}
if (numAvail > LZMA_MATCH_LEN_MAX)
numAvail = LZMA_MATCH_LEN_MAX;
data = p->matchFinder.GetPointerToCurrentPos(p->matchFinderObj) - 1;
repMaxIndex = 0;
for (i = 0; i < LZMA_NUM_REPS; i++)
{
UInt32 lenTest;
const Byte *data2;
reps[i] = p->reps[i];
data2 = data - (reps[i] + 1);
if (data[0] != data2[0] || data[1] != data2[1])
{
repLens[i] = 0;
continue;
}
for (lenTest = 2; lenTest < numAvail && data[lenTest] == data2[lenTest]; lenTest++);
repLens[i] = lenTest;
if (lenTest > repLens[repMaxIndex])
repMaxIndex = i;
}
if (repLens[repMaxIndex] >= p->numFastBytes)
{
UInt32 lenRes;
*backRes = repMaxIndex;
lenRes = repLens[repMaxIndex];
MovePos(p, lenRes - 1);
return lenRes;
}
matches = p->matches;
if (mainLen >= p->numFastBytes)
{
*backRes = matches[numPairs - 1] + LZMA_NUM_REPS;
MovePos(p, mainLen - 1);
return mainLen;
}
curByte = *data;
matchByte = *(data - (reps[0] + 1));
if (mainLen < 2 && curByte != matchByte && repLens[repMaxIndex] < 2)
{
*backRes = (UInt32)-1;
return 1;
}
p->opt[0].state = (CState)p->state;
posState = (position & p->pbMask);
{
const CLzmaProb *probs = LIT_PROBS(position, *(data - 1));
p->opt[1].price = GET_PRICE_0(p->isMatch[p->state][posState]) +
(!IsCharState(p->state) ?
LitEnc_GetPriceMatched(probs, curByte, matchByte, p->ProbPrices) :
LitEnc_GetPrice(probs, curByte, p->ProbPrices));
}
MakeAsChar(&p->opt[1]);
matchPrice = GET_PRICE_1(p->isMatch[p->state][posState]);
repMatchPrice = matchPrice + GET_PRICE_1(p->isRep[p->state]);
if (matchByte == curByte)
{
UInt32 shortRepPrice = repMatchPrice + GetRepLen1Price(p, p->state, posState);
if (shortRepPrice < p->opt[1].price)
{
p->opt[1].price = shortRepPrice;
MakeAsShortRep(&p->opt[1]);
}
}
lenEnd = ((mainLen >= repLens[repMaxIndex]) ? mainLen : repLens[repMaxIndex]);
if (lenEnd < 2)
{
*backRes = p->opt[1].backPrev;
return 1;
}
p->opt[1].posPrev = 0;
for (i = 0; i < LZMA_NUM_REPS; i++)
p->opt[0].backs[i] = reps[i];
len = lenEnd;
do
p->opt[len--].price = kInfinityPrice;
while (len >= 2);
for (i = 0; i < LZMA_NUM_REPS; i++)
{
UInt32 repLen = repLens[i];
UInt32 price;
if (repLen < 2)
continue;
price = repMatchPrice + GetPureRepPrice(p, i, p->state, posState);
do
{
UInt32 curAndLenPrice = price + p->repLenEnc.prices[posState][repLen - 2];
COptimal *opt = &p->opt[repLen];
if (curAndLenPrice < opt->price)
{
opt->price = curAndLenPrice;
opt->posPrev = 0;
opt->backPrev = i;
opt->prev1IsChar = False;
}
}
while (--repLen >= 2);
}
normalMatchPrice = matchPrice + GET_PRICE_0(p->isRep[p->state]);
len = ((repLens[0] >= 2) ? repLens[0] + 1 : 2);
if (len <= mainLen)
{
UInt32 offs = 0;
while (len > matches[offs])
offs += 2;
for (; ; len++)
{
COptimal *opt;
UInt32 distance = matches[offs + 1];
UInt32 curAndLenPrice = normalMatchPrice + p->lenEnc.prices[posState][len - LZMA_MATCH_LEN_MIN];
UInt32 lenToPosState = GetLenToPosState(len);
if (distance < kNumFullDistances)
curAndLenPrice += p->distancesPrices[lenToPosState][distance];
else
{
UInt32 slot;
GetPosSlot2(distance, slot);
curAndLenPrice += p->alignPrices[distance & kAlignMask] + p->posSlotPrices[lenToPosState][slot];
}
opt = &p->opt[len];
if (curAndLenPrice < opt->price)
{
opt->price = curAndLenPrice;
opt->posPrev = 0;
opt->backPrev = distance + LZMA_NUM_REPS;
opt->prev1IsChar = False;
}
if (len == matches[offs])
{
offs += 2;
if (offs == numPairs)
break;
}
}
}
cur = 0;
#ifdef SHOW_STAT2
if (position >= 0)
{
unsigned ii;
printf("\n pos = %4X", position);
for (ii = cur; ii <= lenEnd; ii++)
printf("\nprice[%4X] = %d", position - cur + ii, p->opt[ii].price);
}
#endif
for (;;)
{
UInt32 numAvailFull, newLen, posPrev, state, startLen;
UInt32 curPrice, curAnd1Price;
Bool nextIsChar;
COptimal *curOpt;
COptimal *nextOpt;
cur++;
if (cur == lenEnd)
return Backward(p, backRes, cur);
newLen = ReadMatchDistances(p, &numPairs);
if (newLen >= p->numFastBytes)
{
p->numPairs = numPairs;
p->longestMatchLength = newLen;
return Backward(p, backRes, cur);
}
position++;
curOpt = &p->opt[cur];
posPrev = curOpt->posPrev;
if (curOpt->prev1IsChar)
{
posPrev--;
if (curOpt->prev2)
{
state = p->opt[curOpt->posPrev2].state;
if (curOpt->backPrev2 < LZMA_NUM_REPS)
state = kRepNextStates[state];
else
state = kMatchNextStates[state];
}
else
state = p->opt[posPrev].state;
state = kLiteralNextStates[state];
}
else
state = p->opt[posPrev].state;
if (posPrev == cur - 1)
{
if (IsShortRep(curOpt))
state = kShortRepNextStates[state];
else
state = kLiteralNextStates[state];
}
else
{
UInt32 pos;
const COptimal *prevOpt;
if (curOpt->prev1IsChar && curOpt->prev2)
{
posPrev = curOpt->posPrev2;
pos = curOpt->backPrev2;
state = kRepNextStates[state];
}
else
{
pos = curOpt->backPrev;
if (pos < LZMA_NUM_REPS)
state = kRepNextStates[state];
else
state = kMatchNextStates[state];
}
prevOpt = &p->opt[posPrev];
if (pos < LZMA_NUM_REPS)
{
reps[0] = prevOpt->backs[pos];
for (i = 1; i <= pos; i++)
reps[i] = prevOpt->backs[i - 1];
for (; i < LZMA_NUM_REPS; i++)
reps[i] = prevOpt->backs[i];
}
else
{
reps[0] = (pos - LZMA_NUM_REPS);
for (i = 1; i < LZMA_NUM_REPS; i++)
reps[i] = prevOpt->backs[i - 1];
}
}
curOpt->state = (CState)state;
curOpt->backs[0] = reps[0];
curOpt->backs[1] = reps[1];
curOpt->backs[2] = reps[2];
curOpt->backs[3] = reps[3];
curPrice = curOpt->price;
nextIsChar = False;
data = p->matchFinder.GetPointerToCurrentPos(p->matchFinderObj) - 1;
curByte = *data;
matchByte = *(data - (reps[0] + 1));
posState = (position & p->pbMask);
curAnd1Price = curPrice + GET_PRICE_0(p->isMatch[state][posState]);
{
const CLzmaProb *probs = LIT_PROBS(position, *(data - 1));
curAnd1Price +=
(!IsCharState(state) ?
LitEnc_GetPriceMatched(probs, curByte, matchByte, p->ProbPrices) :
LitEnc_GetPrice(probs, curByte, p->ProbPrices));
}
nextOpt = &p->opt[cur + 1];
if (curAnd1Price < nextOpt->price)
{
nextOpt->price = curAnd1Price;
nextOpt->posPrev = cur;
MakeAsChar(nextOpt);
nextIsChar = True;
}
matchPrice = curPrice + GET_PRICE_1(p->isMatch[state][posState]);
repMatchPrice = matchPrice + GET_PRICE_1(p->isRep[state]);
if (matchByte == curByte && !(nextOpt->posPrev < cur && nextOpt->backPrev == 0))
{
UInt32 shortRepPrice = repMatchPrice + GetRepLen1Price(p, state, posState);
if (shortRepPrice <= nextOpt->price)
{
nextOpt->price = shortRepPrice;
nextOpt->posPrev = cur;
MakeAsShortRep(nextOpt);
nextIsChar = True;
}
}
numAvailFull = p->numAvail;
{
UInt32 temp = kNumOpts - 1 - cur;
if (temp < numAvailFull)
numAvailFull = temp;
}
if (numAvailFull < 2)
continue;
numAvail = (numAvailFull <= p->numFastBytes ? numAvailFull : p->numFastBytes);
if (!nextIsChar && matchByte != curByte) /* speed optimization */
{
/* try Literal + rep0 */
UInt32 temp;
UInt32 lenTest2;
const Byte *data2 = data - (reps[0] + 1);
UInt32 limit = p->numFastBytes + 1;
if (limit > numAvailFull)
limit = numAvailFull;
for (temp = 1; temp < limit && data[temp] == data2[temp]; temp++);
lenTest2 = temp - 1;
if (lenTest2 >= 2)
{
UInt32 state2 = kLiteralNextStates[state];
UInt32 posStateNext = (position + 1) & p->pbMask;
UInt32 nextRepMatchPrice = curAnd1Price +
GET_PRICE_1(p->isMatch[state2][posStateNext]) +
GET_PRICE_1(p->isRep[state2]);
/* for (; lenTest2 >= 2; lenTest2--) */
{
COptimal *opt;
UInt32 offset = cur + 1 + lenTest2;
while (lenEnd < offset)
p->opt[++lenEnd].price = kInfinityPrice;
UInt32 curAndLenPrice = nextRepMatchPrice + GetRepPrice(p, 0, lenTest2, state2, posStateNext);
opt = &p->opt[offset];
if (curAndLenPrice < opt->price)
{
opt->price = curAndLenPrice;
opt->posPrev = cur + 1;
opt->backPrev = 0;
opt->prev1IsChar = True;
opt->prev2 = False;
}
}
}
}
startLen = 2; /* speed optimization */
{
UInt32 repIndex;
for (repIndex = 0; repIndex < LZMA_NUM_REPS; repIndex++)
{
UInt32 lenTest;
UInt32 lenTestTemp;
UInt32 price;
const Byte *data2 = data - (reps[repIndex] + 1);
if (data[0] != data2[0] || data[1] != data2[1])
continue;
for (lenTest = 2; lenTest < numAvail && data[lenTest] == data2[lenTest]; lenTest++);
while (lenEnd < cur + lenTest)
p->opt[++lenEnd].price = kInfinityPrice;
lenTestTemp = lenTest;
price = repMatchPrice + GetPureRepPrice(p, repIndex, state, posState);
do
{
UInt32 curAndLenPrice = price + p->repLenEnc.prices[posState][lenTest - 2];
COptimal *opt = &p->opt[cur + lenTest];
if (curAndLenPrice < opt->price)
{
opt->price = curAndLenPrice;
opt->posPrev = cur;
opt->backPrev = repIndex;
opt->prev1IsChar = False;
}
}
while (--lenTest >= 2);
lenTest = lenTestTemp;
if (repIndex == 0)
startLen = lenTest + 1;
#ifndef _MSC_VER
if (1 /* _maxMode */)
#endif
{
UInt32 lenTest2 = lenTest + 1;
UInt32 limit = lenTest2 + p->numFastBytes;
UInt32 nextRepMatchPrice;
if (limit > numAvailFull)
limit = numAvailFull;
for (; lenTest2 < limit && data[lenTest2] == data2[lenTest2]; lenTest2++);
lenTest2 -= lenTest + 1;
if (lenTest2 >= 2)
{
UInt32 state2 = kRepNextStates[state];
UInt32 posStateNext = (position + lenTest) & p->pbMask;
UInt32 curAndLenCharPrice =
price + p->repLenEnc.prices[posState][lenTest - 2] +
GET_PRICE_0(p->isMatch[state2][posStateNext]) +
LitEnc_GetPriceMatched(LIT_PROBS(position + lenTest, data[lenTest - 1]),
data[lenTest], data2[lenTest], p->ProbPrices);
state2 = kLiteralNextStates[state2];
posStateNext = (position + lenTest + 1) & p->pbMask;
nextRepMatchPrice = curAndLenCharPrice +
GET_PRICE_1(p->isMatch[state2][posStateNext]) +
GET_PRICE_1(p->isRep[state2]);
/* for (; lenTest2 >= 2; lenTest2--) */
{
UInt32 curAndLenPrice;
COptimal *opt;
UInt32 offset = cur + lenTest + 1 + lenTest2;
while (lenEnd < offset)
p->opt[++lenEnd].price = kInfinityPrice;
curAndLenPrice = nextRepMatchPrice + GetRepPrice(p, 0, lenTest2, state2, posStateNext);
opt = &p->opt[offset];
if (curAndLenPrice < opt->price)
{
opt->price = curAndLenPrice;
opt->posPrev = cur + lenTest + 1;
opt->backPrev = 0;
opt->prev1IsChar = True;
opt->prev2 = True;
opt->posPrev2 = cur;
opt->backPrev2 = repIndex;
}
}
}
}
}
}
/* for (UInt32 lenTest = 2; lenTest <= newLen; lenTest++) */
if (newLen > numAvail)
{
newLen = numAvail;
for (numPairs = 0; newLen > matches[numPairs]; numPairs += 2);
matches[numPairs] = newLen;
numPairs += 2;
}
if (newLen >= startLen)
{
normalMatchPrice = matchPrice + GET_PRICE_0(p->isRep[state]);
UInt32 offs, curBack, posSlot;
UInt32 lenTest;
while (lenEnd < cur + newLen)
p->opt[++lenEnd].price = kInfinityPrice;
offs = 0;
while (startLen > matches[offs])
offs += 2;
curBack = matches[offs + 1];
GetPosSlot2(curBack, posSlot);
for (lenTest = /*2*/ startLen; ; lenTest++)
{
UInt32 curAndLenPrice;
curAndLenPrice = normalMatchPrice + p->lenEnc.prices[posState][lenTest - LZMA_MATCH_LEN_MIN];
UInt32 lenToPosState = GetLenToPosState(lenTest);
COptimal *opt;
if (curBack < kNumFullDistances)
curAndLenPrice += p->distancesPrices[lenToPosState][curBack];
else
curAndLenPrice += p->posSlotPrices[lenToPosState][posSlot] + p->alignPrices[curBack & kAlignMask];
opt = &p->opt[cur + lenTest];
if (curAndLenPrice < opt->price)
{
opt->price = curAndLenPrice;
opt->posPrev = cur;
opt->backPrev = curBack + LZMA_NUM_REPS;
opt->prev1IsChar = False;
}
if (/*_maxMode && */lenTest == matches[offs])
{
/* Try Match + Literal + Rep0 */
const Byte *data2 = data - (curBack + 1);
UInt32 lenTest2 = lenTest + 1;
UInt32 limit = lenTest2 + p->numFastBytes;
UInt32 nextRepMatchPrice;
if (limit > numAvailFull)
limit = numAvailFull;
for (; lenTest2 < limit && data[lenTest2] == data2[lenTest2]; lenTest2++);
lenTest2 -= lenTest + 1;
if (lenTest2 >= 2)
{
UInt32 state2 = kMatchNextStates[state];
UInt32 posStateNext = (position + lenTest) & p->pbMask;
UInt32 curAndLenCharPrice = curAndLenPrice +
GET_PRICE_0(p->isMatch[state2][posStateNext]) +
LitEnc_GetPriceMatched(LIT_PROBS(position + lenTest, data[lenTest - 1]),
data[lenTest], data2[lenTest], p->ProbPrices);
state2 = kLiteralNextStates[state2];
posStateNext = (posStateNext + 1) & p->pbMask;
nextRepMatchPrice = curAndLenCharPrice +
GET_PRICE_1(p->isMatch[state2][posStateNext]) +
GET_PRICE_1(p->isRep[state2]);
/* for (; lenTest2 >= 2; lenTest2--) */
{
UInt32 offset = cur + lenTest + 1 + lenTest2;
while (lenEnd < offset)
p->opt[++lenEnd].price = kInfinityPrice;
curAndLenPrice = nextRepMatchPrice + GetRepPrice(p, 0, lenTest2, state2, posStateNext);
opt = &p->opt[offset];
if (curAndLenPrice < opt->price)
{
opt->price = curAndLenPrice;
opt->posPrev = cur + lenTest + 1;
opt->backPrev = 0;
opt->prev1IsChar = True;
opt->prev2 = True;
opt->posPrev2 = cur;
opt->backPrev2 = curBack + LZMA_NUM_REPS;
}
}
}
offs += 2;
if (offs == numPairs)
break;
curBack = matches[offs + 1];
if (curBack >= kNumFullDistances)
GetPosSlot2(curBack, posSlot);
}
}
}
}
}
#define ChangePair(smallDist, bigDist) (((bigDist) >> 7) > (smallDist))
static UInt32 GetOptimumFast(CLzmaEnc *p, UInt32 *backRes)
{
UInt32 numAvail, mainLen, mainDist, numPairs, repIndex, repLen, i;
const Byte *data;
const UInt32 *matches;
if (p->additionalOffset == 0)
mainLen = ReadMatchDistances(p, &numPairs);
else
{
mainLen = p->longestMatchLength;
numPairs = p->numPairs;
}
numAvail = p->numAvail;
*backRes = (UInt32)-1;
if (numAvail < 2)
return 1;
if (numAvail > LZMA_MATCH_LEN_MAX)
numAvail = LZMA_MATCH_LEN_MAX;
data = p->matchFinder.GetPointerToCurrentPos(p->matchFinderObj) - 1;
repLen = repIndex = 0;
for (i = 0; i < LZMA_NUM_REPS; i++)
{
UInt32 len;
const Byte *data2 = data - (p->reps[i] + 1);
if (data[0] != data2[0] || data[1] != data2[1])
continue;
for (len = 2; len < numAvail && data[len] == data2[len]; len++);
if (len >= p->numFastBytes)
{
*backRes = i;
MovePos(p, len - 1);
return len;
}
if (len > repLen)
{
repIndex = i;
repLen = len;
}
}
matches = p->matches;
if (mainLen >= p->numFastBytes)
{
*backRes = matches[numPairs - 1] + LZMA_NUM_REPS;
MovePos(p, mainLen - 1);
return mainLen;
}
mainDist = 0; /* for GCC */
if (mainLen >= 2)
{
mainDist = matches[numPairs - 1];
while (numPairs > 2 && mainLen == matches[numPairs - 4] + 1)
{
if (!ChangePair(matches[numPairs - 3], mainDist))
break;
numPairs -= 2;
mainLen = matches[numPairs - 2];
mainDist = matches[numPairs - 1];
}
if (mainLen == 2 && mainDist >= 0x80)
mainLen = 1;
}
if (repLen >= 2 && (
(repLen + 1 >= mainLen) ||
(repLen + 2 >= mainLen && mainDist >= (1 << 9)) ||
(repLen + 3 >= mainLen && mainDist >= (1 << 15))))
{
*backRes = repIndex;
MovePos(p, repLen - 1);
return repLen;
}
if (mainLen < 2 || numAvail <= 2)
return 1;
p->longestMatchLength = ReadMatchDistances(p, &p->numPairs);
if (p->longestMatchLength >= 2)
{
UInt32 newDistance = matches[p->numPairs - 1];
if ((p->longestMatchLength >= mainLen && newDistance < mainDist) ||
(p->longestMatchLength == mainLen + 1 && !ChangePair(mainDist, newDistance)) ||
(p->longestMatchLength > mainLen + 1) ||
(p->longestMatchLength + 1 >= mainLen && mainLen >= 3 && ChangePair(newDistance, mainDist)))
return 1;
}
data = p->matchFinder.GetPointerToCurrentPos(p->matchFinderObj) - 1;
for (i = 0; i < LZMA_NUM_REPS; i++)
{
UInt32 len, limit;
const Byte *data2 = data - (p->reps[i] + 1);
if (data[0] != data2[0] || data[1] != data2[1])
continue;
limit = mainLen - 1;
for (len = 2; len < limit && data[len] == data2[len]; len++);
if (len >= limit)
return 1;
}
*backRes = mainDist + LZMA_NUM_REPS;
MovePos(p, mainLen - 2);
return mainLen;
}
static void WriteEndMarker(CLzmaEnc *p, UInt32 posState)
{
UInt32 len;
RangeEnc_EncodeBit(&p->rc, &p->isMatch[p->state][posState], 1);
RangeEnc_EncodeBit(&p->rc, &p->isRep[p->state], 0);
p->state = kMatchNextStates[p->state];
len = LZMA_MATCH_LEN_MIN;
LenEnc_Encode2(&p->lenEnc, &p->rc, len - LZMA_MATCH_LEN_MIN, posState, !p->fastMode, p->ProbPrices);
RcTree_Encode(&p->rc, p->posSlotEncoder[GetLenToPosState(len)], kNumPosSlotBits, (1 << kNumPosSlotBits) - 1);
RangeEnc_EncodeDirectBits(&p->rc, (((UInt32)1 << 30) - 1) >> kNumAlignBits, 30 - kNumAlignBits);
RcTree_ReverseEncode(&p->rc, p->posAlignEncoder, kNumAlignBits, kAlignMask);
}
static SRes CheckErrors(CLzmaEnc *p)
{
if (p->result != SZ_OK)
return p->result;
if (p->rc.res != SZ_OK)
p->result = SZ_ERROR_WRITE;
if (p->matchFinderBase.result != SZ_OK)
p->result = SZ_ERROR_READ;
if (p->result != SZ_OK)
p->finished = True;
return p->result;
}
static SRes Flush(CLzmaEnc *p, UInt32 nowPos)
{
/* ReleaseMFStream(); */
p->finished = True;
if (p->writeEndMark)
WriteEndMarker(p, nowPos & p->pbMask);
RangeEnc_FlushData(&p->rc);
RangeEnc_FlushStream(&p->rc);
return CheckErrors(p);
}
static void FillAlignPrices(CLzmaEnc *p)
{
UInt32 i;
for (i = 0; i < kAlignTableSize; i++)
p->alignPrices[i] = RcTree_ReverseGetPrice(p->posAlignEncoder, kNumAlignBits, i, p->ProbPrices);
p->alignPriceCount = 0;
}
static void FillDistancesPrices(CLzmaEnc *p)
{
UInt32 tempPrices[kNumFullDistances];
UInt32 i, lenToPosState;
for (i = kStartPosModelIndex; i < kNumFullDistances; i++)
{
UInt32 posSlot = GetPosSlot1(i);
UInt32 footerBits = ((posSlot >> 1) - 1);
UInt32 base = ((2 | (posSlot & 1)) << footerBits);
tempPrices[i] = RcTree_ReverseGetPrice(p->posEncoders + base - posSlot - 1, footerBits, i - base, p->ProbPrices);
}
for (lenToPosState = 0; lenToPosState < kNumLenToPosStates; lenToPosState++)
{
UInt32 posSlot;
const CLzmaProb *encoder = p->posSlotEncoder[lenToPosState];
UInt32 *posSlotPrices = p->posSlotPrices[lenToPosState];
for (posSlot = 0; posSlot < p->distTableSize; posSlot++)
posSlotPrices[posSlot] = RcTree_GetPrice(encoder, kNumPosSlotBits, posSlot, p->ProbPrices);
for (posSlot = kEndPosModelIndex; posSlot < p->distTableSize; posSlot++)
posSlotPrices[posSlot] += ((((posSlot >> 1) - 1) - kNumAlignBits) << kNumBitPriceShiftBits);
{
UInt32 *distancesPrices = p->distancesPrices[lenToPosState];
for (i = 0; i < kStartPosModelIndex; i++)
distancesPrices[i] = posSlotPrices[i];
for (; i < kNumFullDistances; i++)
distancesPrices[i] = posSlotPrices[GetPosSlot1(i)] + tempPrices[i];
}
}
p->matchPriceCount = 0;
}
void LzmaEnc_Construct(CLzmaEnc *p)
{
RangeEnc_Construct(&p->rc);
MatchFinder_Construct(&p->matchFinderBase);
#ifdef COMPRESS_MF_MT
MatchFinderMt_Construct(&p->matchFinderMt);
p->matchFinderMt.MatchFinder = &p->matchFinderBase;
#endif
{
CLzmaEncProps props;
LzmaEncProps_Init(&props);
LzmaEnc_SetProps(p, &props);
}
#ifndef LZMA_LOG_BSR
LzmaEnc_FastPosInit(p->g_FastPos);
#endif
LzmaEnc_InitPriceTables(p->ProbPrices);
p->litProbs = 0;
p->saveState.litProbs = 0;
}
CLzmaEncHandle LzmaEnc_Create(ISzAlloc *alloc)
{
void *p;
p = alloc->Alloc(alloc, sizeof(CLzmaEnc));
if (p != 0)
LzmaEnc_Construct((CLzmaEnc *)p);
return p;
}
void LzmaEnc_FreeLits(CLzmaEnc *p, ISzAlloc *alloc)
{
alloc->Free(alloc, p->litProbs);
alloc->Free(alloc, p->saveState.litProbs);
p->litProbs = 0;
p->saveState.litProbs = 0;
}
void LzmaEnc_Destruct(CLzmaEnc *p, ISzAlloc *alloc, ISzAlloc *allocBig)
{
#ifdef COMPRESS_MF_MT
MatchFinderMt_Destruct(&p->matchFinderMt, allocBig);
#endif
MatchFinder_Free(&p->matchFinderBase, allocBig);
LzmaEnc_FreeLits(p, alloc);
RangeEnc_Free(&p->rc, alloc);
}
void LzmaEnc_Destroy(CLzmaEncHandle p, ISzAlloc *alloc, ISzAlloc *allocBig)
{
LzmaEnc_Destruct((CLzmaEnc *)p, alloc, allocBig);
alloc->Free(alloc, p);
}
static SRes LzmaEnc_CodeOneBlock(CLzmaEnc *p, Bool useLimits, UInt32 maxPackSize, UInt32 maxUnpackSize)
{
UInt32 nowPos32, startPos32;
if (p->inStream != 0)
{
p->matchFinderBase.stream = p->inStream;
p->matchFinder.Init(p->matchFinderObj);
p->inStream = 0;
}
if (p->finished)
return p->result;
RINOK(CheckErrors(p));
nowPos32 = (UInt32)p->nowPos64;
startPos32 = nowPos32;
if (p->nowPos64 == 0)
{
UInt32 numPairs;
Byte curByte;
if (p->matchFinder.GetNumAvailableBytes(p->matchFinderObj) == 0)
return Flush(p, nowPos32);
ReadMatchDistances(p, &numPairs);
RangeEnc_EncodeBit(&p->rc, &p->isMatch[p->state][0], 0);
p->state = kLiteralNextStates[p->state];
curByte = p->matchFinder.GetIndexByte(p->matchFinderObj, 0 - p->additionalOffset);
LitEnc_Encode(&p->rc, p->litProbs, curByte);
p->additionalOffset--;
nowPos32++;
}
if (p->matchFinder.GetNumAvailableBytes(p->matchFinderObj) != 0)
for (;;)
{
UInt32 pos, len, posState;
if (p->fastMode)
len = GetOptimumFast(p, &pos);
else
len = GetOptimum(p, nowPos32, &pos);
#ifdef SHOW_STAT2
printf("\n pos = %4X, len = %d pos = %d", nowPos32, len, pos);
#endif
posState = nowPos32 & p->pbMask;
if (len == 1 && pos == (UInt32)-1)
{
Byte curByte;
CLzmaProb *probs;
const Byte *data;
RangeEnc_EncodeBit(&p->rc, &p->isMatch[p->state][posState], 0);
data = p->matchFinder.GetPointerToCurrentPos(p->matchFinderObj) - p->additionalOffset;
curByte = *data;
probs = LIT_PROBS(nowPos32, *(data - 1));
if (IsCharState(p->state))
LitEnc_Encode(&p->rc, probs, curByte);
else
LitEnc_EncodeMatched(&p->rc, probs, curByte, *(data - p->reps[0] - 1));
p->state = kLiteralNextStates[p->state];
}
else
{
RangeEnc_EncodeBit(&p->rc, &p->isMatch[p->state][posState], 1);
if (pos < LZMA_NUM_REPS)
{
RangeEnc_EncodeBit(&p->rc, &p->isRep[p->state], 1);
if (pos == 0)
{
RangeEnc_EncodeBit(&p->rc, &p->isRepG0[p->state], 0);
RangeEnc_EncodeBit(&p->rc, &p->isRep0Long[p->state][posState], ((len == 1) ? 0 : 1));
}
else
{
UInt32 distance = p->reps[pos];
RangeEnc_EncodeBit(&p->rc, &p->isRepG0[p->state], 1);
if (pos == 1)
RangeEnc_EncodeBit(&p->rc, &p->isRepG1[p->state], 0);
else
{
RangeEnc_EncodeBit(&p->rc, &p->isRepG1[p->state], 1);
RangeEnc_EncodeBit(&p->rc, &p->isRepG2[p->state], pos - 2);
if (pos == 3)
p->reps[3] = p->reps[2];
p->reps[2] = p->reps[1];
}
p->reps[1] = p->reps[0];
p->reps[0] = distance;
}
if (len == 1)
p->state = kShortRepNextStates[p->state];
else
{
LenEnc_Encode2(&p->repLenEnc, &p->rc, len - LZMA_MATCH_LEN_MIN, posState, !p->fastMode, p->ProbPrices);
p->state = kRepNextStates[p->state];
}
}
else
{
UInt32 posSlot;
RangeEnc_EncodeBit(&p->rc, &p->isRep[p->state], 0);
p->state = kMatchNextStates[p->state];
LenEnc_Encode2(&p->lenEnc, &p->rc, len - LZMA_MATCH_LEN_MIN, posState, !p->fastMode, p->ProbPrices);
pos -= LZMA_NUM_REPS;
GetPosSlot(pos, posSlot);
RcTree_Encode(&p->rc, p->posSlotEncoder[GetLenToPosState(len)], kNumPosSlotBits, posSlot);
if (posSlot >= kStartPosModelIndex)
{
UInt32 footerBits = ((posSlot >> 1) - 1);
UInt32 base = ((2 | (posSlot & 1)) << footerBits);
UInt32 posReduced = pos - base;
if (posSlot < kEndPosModelIndex)
RcTree_ReverseEncode(&p->rc, p->posEncoders + base - posSlot - 1, footerBits, posReduced);
else
{
RangeEnc_EncodeDirectBits(&p->rc, posReduced >> kNumAlignBits, footerBits - kNumAlignBits);
RcTree_ReverseEncode(&p->rc, p->posAlignEncoder, kNumAlignBits, posReduced & kAlignMask);
p->alignPriceCount++;
}
}
p->reps[3] = p->reps[2];
p->reps[2] = p->reps[1];
p->reps[1] = p->reps[0];
p->reps[0] = pos;
p->matchPriceCount++;
}
}
p->additionalOffset -= len;
nowPos32 += len;
if (p->additionalOffset == 0)
{
UInt32 processed;
if (!p->fastMode)
{
if (p->matchPriceCount >= (1 << 7))
FillDistancesPrices(p);
if (p->alignPriceCount >= kAlignTableSize)
FillAlignPrices(p);
}
if (p->matchFinder.GetNumAvailableBytes(p->matchFinderObj) == 0)
break;
processed = nowPos32 - startPos32;
if (useLimits)
{
if (processed + kNumOpts + 300 >= maxUnpackSize ||
RangeEnc_GetProcessed(&p->rc) + kNumOpts * 2 >= maxPackSize)
break;
}
else if (processed >= (1 << 15))
{
p->nowPos64 += nowPos32 - startPos32;
return CheckErrors(p);
}
}
}
p->nowPos64 += nowPos32 - startPos32;
return Flush(p, nowPos32);
}
#define kBigHashDicLimit ((UInt32)1 << 24)
static SRes LzmaEnc_Alloc(CLzmaEnc *p, UInt32 keepWindowSize, ISzAlloc *alloc, ISzAlloc *allocBig)
{
UInt32 beforeSize = kNumOpts;
#ifdef COMPRESS_MF_MT
Bool btMode;
#endif
if (!RangeEnc_Alloc(&p->rc, alloc))
return SZ_ERROR_MEM;
#ifdef COMPRESS_MF_MT
btMode = (p->matchFinderBase.btMode != 0);
p->mtMode = (p->multiThread && !p->fastMode && btMode);
#endif
{
unsigned lclp = p->lc + p->lp;
if (p->litProbs == 0 || p->saveState.litProbs == 0 || p->lclp != lclp)
{
LzmaEnc_FreeLits(p, alloc);
p->litProbs = (CLzmaProb *)alloc->Alloc(alloc, (0x300 << lclp) * sizeof(CLzmaProb));
p->saveState.litProbs = (CLzmaProb *)alloc->Alloc(alloc, (0x300 << lclp) * sizeof(CLzmaProb));
if (p->litProbs == 0 || p->saveState.litProbs == 0)
{
LzmaEnc_FreeLits(p, alloc);
return SZ_ERROR_MEM;
}
p->lclp = lclp;
}
}
p->matchFinderBase.bigHash = (p->dictSize > kBigHashDicLimit);
if (beforeSize + p->dictSize < keepWindowSize)
beforeSize = keepWindowSize - p->dictSize;
#ifdef COMPRESS_MF_MT
if (p->mtMode)
{
RINOK(MatchFinderMt_Create(&p->matchFinderMt, p->dictSize, beforeSize, p->numFastBytes, LZMA_MATCH_LEN_MAX, allocBig));
p->matchFinderObj = &p->matchFinderMt;
MatchFinderMt_CreateVTable(&p->matchFinderMt, &p->matchFinder);
}
else
#endif
{
if (!MatchFinder_Create(&p->matchFinderBase, p->dictSize, beforeSize, p->numFastBytes, LZMA_MATCH_LEN_MAX, allocBig))
return SZ_ERROR_MEM;
p->matchFinderObj = &p->matchFinderBase;
MatchFinder_CreateVTable(&p->matchFinderBase, &p->matchFinder);
}
return SZ_OK;
}
void LzmaEnc_Init(CLzmaEnc *p)
{
UInt32 i;
p->state = 0;
for (i = 0 ; i < LZMA_NUM_REPS; i++)
p->reps[i] = 0;
RangeEnc_Init(&p->rc);
for (i = 0; i < kNumStates; i++)
{
UInt32 j;
for (j = 0; j < LZMA_NUM_PB_STATES_MAX; j++)
{
p->isMatch[i][j] = kProbInitValue;
p->isRep0Long[i][j] = kProbInitValue;
}
p->isRep[i] = kProbInitValue;
p->isRepG0[i] = kProbInitValue;
p->isRepG1[i] = kProbInitValue;
p->isRepG2[i] = kProbInitValue;
}
{
UInt32 num = 0x300 << (p->lp + p->lc);
for (i = 0; i < num; i++)
p->litProbs[i] = kProbInitValue;
}
{
for (i = 0; i < kNumLenToPosStates; i++)
{
CLzmaProb *probs = p->posSlotEncoder[i];
UInt32 j;
for (j = 0; j < (1 << kNumPosSlotBits); j++)
probs[j] = kProbInitValue;
}
}
{
for (i = 0; i < kNumFullDistances - kEndPosModelIndex; i++)
p->posEncoders[i] = kProbInitValue;
}
LenEnc_Init(&p->lenEnc.p);
LenEnc_Init(&p->repLenEnc.p);
for (i = 0; i < (1 << kNumAlignBits); i++)
p->posAlignEncoder[i] = kProbInitValue;
p->optimumEndIndex = 0;
p->optimumCurrentIndex = 0;
p->additionalOffset = 0;
p->pbMask = (1 << p->pb) - 1;
p->lpMask = (1 << p->lp) - 1;
}
void LzmaEnc_InitPrices(CLzmaEnc *p)
{
if (!p->fastMode)
{
FillDistancesPrices(p);
FillAlignPrices(p);
}
p->lenEnc.tableSize =
p->repLenEnc.tableSize =
p->numFastBytes + 1 - LZMA_MATCH_LEN_MIN;
LenPriceEnc_UpdateTables(&p->lenEnc, 1 << p->pb, p->ProbPrices);
LenPriceEnc_UpdateTables(&p->repLenEnc, 1 << p->pb, p->ProbPrices);
}
static SRes LzmaEnc_AllocAndInit(CLzmaEnc *p, UInt32 keepWindowSize, ISzAlloc *alloc, ISzAlloc *allocBig)
{
UInt32 i;
for (i = 0; i < (UInt32)kDicLogSizeMaxCompress; i++)
if (p->dictSize <= ((UInt32)1 << i))
break;
p->distTableSize = i * 2;
p->finished = False;
p->result = SZ_OK;
RINOK(LzmaEnc_Alloc(p, keepWindowSize, alloc, allocBig));
LzmaEnc_Init(p);
LzmaEnc_InitPrices(p);
p->nowPos64 = 0;
return SZ_OK;
}
static SRes LzmaEnc_Prepare(CLzmaEncHandle pp, ISeqInStream *inStream, ISeqOutStream *outStream,
ISzAlloc *alloc, ISzAlloc *allocBig)
{
CLzmaEnc *p = (CLzmaEnc *)pp;
p->inStream = inStream;
p->rc.outStream = outStream;
return LzmaEnc_AllocAndInit(p, 0, alloc, allocBig);
}
SRes LzmaEnc_PrepareForLzma2(CLzmaEncHandle pp,
ISeqInStream *inStream, UInt32 keepWindowSize,
ISzAlloc *alloc, ISzAlloc *allocBig)
{
CLzmaEnc *p = (CLzmaEnc *)pp;
p->inStream = inStream;
return LzmaEnc_AllocAndInit(p, keepWindowSize, alloc, allocBig);
}
static void LzmaEnc_SetInputBuf(CLzmaEnc *p, const Byte *src, SizeT srcLen)
{
p->seqBufInStream.funcTable.Read = MyRead;
p->seqBufInStream.data = src;
p->seqBufInStream.rem = srcLen;
}
SRes LzmaEnc_MemPrepare(CLzmaEncHandle pp, const Byte *src, SizeT srcLen,
UInt32 keepWindowSize, ISzAlloc *alloc, ISzAlloc *allocBig)
{
CLzmaEnc *p = (CLzmaEnc *)pp;
LzmaEnc_SetInputBuf(p, src, srcLen);
p->inStream = &p->seqBufInStream.funcTable;
return LzmaEnc_AllocAndInit(p, keepWindowSize, alloc, allocBig);
}
void LzmaEnc_Finish(CLzmaEncHandle pp)
{
#ifdef COMPRESS_MF_MT
CLzmaEnc *p = (CLzmaEnc *)pp;
if (p->mtMode)
MatchFinderMt_ReleaseStream(&p->matchFinderMt);
#else
(void)pp;
#endif
}
typedef struct _CSeqOutStreamBuf
{
ISeqOutStream funcTable;
Byte *data;
SizeT rem;
Bool overflow;
} CSeqOutStreamBuf;
static size_t MyWrite(void *pp, const void *data, size_t size)
{
CSeqOutStreamBuf *p = (CSeqOutStreamBuf *)pp;
if (p->rem < size)
{
size = p->rem;
p->overflow = True;
}
memcpy(p->data, data, size);
p->rem -= size;
p->data += size;
return size;
}
UInt32 LzmaEnc_GetNumAvailableBytes(CLzmaEncHandle pp)
{
const CLzmaEnc *p = (CLzmaEnc *)pp;
return p->matchFinder.GetNumAvailableBytes(p->matchFinderObj);
}
const Byte *LzmaEnc_GetCurBuf(CLzmaEncHandle pp)
{
const CLzmaEnc *p = (CLzmaEnc *)pp;
return p->matchFinder.GetPointerToCurrentPos(p->matchFinderObj) - p->additionalOffset;
}
SRes LzmaEnc_CodeOneMemBlock(CLzmaEncHandle pp, Bool reInit,
Byte *dest, size_t *destLen, UInt32 desiredPackSize, UInt32 *unpackSize)
{
CLzmaEnc *p = (CLzmaEnc *)pp;
UInt64 nowPos64;
SRes res;
CSeqOutStreamBuf outStream;
outStream.funcTable.Write = MyWrite;
outStream.data = dest;
outStream.rem = *destLen;
outStream.overflow = False;
p->writeEndMark = False;
p->finished = False;
p->result = SZ_OK;
if (reInit)
LzmaEnc_Init(p);
LzmaEnc_InitPrices(p);
nowPos64 = p->nowPos64;
RangeEnc_Init(&p->rc);
p->rc.outStream = &outStream.funcTable;
res = LzmaEnc_CodeOneBlock(p, True, desiredPackSize, *unpackSize);
*unpackSize = (UInt32)(p->nowPos64 - nowPos64);
*destLen -= outStream.rem;
if (outStream.overflow)
return SZ_ERROR_OUTPUT_EOF;
return res;
}
SRes LzmaEnc_Encode(CLzmaEncHandle pp, ISeqOutStream *outStream, ISeqInStream *inStream, ICompressProgress *progress,
ISzAlloc *alloc, ISzAlloc *allocBig)
{
CLzmaEnc *p = (CLzmaEnc *)pp;
SRes res = SZ_OK;
#ifdef COMPRESS_MF_MT
Byte allocaDummy[0x300];
int i = 0;
for (i = 0; i < 16; i++)
allocaDummy[i] = (Byte)i;
#endif
RINOK(LzmaEnc_Prepare(pp, inStream, outStream, alloc, allocBig));
for (;;)
{
res = LzmaEnc_CodeOneBlock(p, False, 0, 0);
if (res != SZ_OK || p->finished != 0)
break;
if (progress != 0)
{
res = progress->Progress(progress, p->nowPos64, RangeEnc_GetProcessed(&p->rc));
if (res != SZ_OK)
{
res = SZ_ERROR_PROGRESS;
break;
}
}
}
LzmaEnc_Finish(pp);
return res;
}
SRes LzmaEnc_WriteProperties(CLzmaEncHandle pp, Byte *props, SizeT *size)
{
CLzmaEnc *p = (CLzmaEnc *)pp;
int i;
UInt32 dictSize = p->dictSize;
if (*size < LZMA_PROPS_SIZE)
return SZ_ERROR_PARAM;
*size = LZMA_PROPS_SIZE;
props[0] = (Byte)((p->pb * 5 + p->lp) * 9 + p->lc);
for (i = 11; i <= 30; i++)
{
if (dictSize <= ((UInt32)2 << i))
{
dictSize = (2 << i);
break;
}
if (dictSize <= ((UInt32)3 << i))
{
dictSize = (3 << i);
break;
}
}
for (i = 0; i < 4; i++)
props[1 + i] = (Byte)(dictSize >> (8 * i));
return SZ_OK;
}
SRes LzmaEnc_MemEncode(CLzmaEncHandle pp, Byte *dest, SizeT *destLen, const Byte *src, SizeT srcLen,
int writeEndMark, ICompressProgress *progress, ISzAlloc *alloc, ISzAlloc *allocBig)
{
SRes res;
CLzmaEnc *p = (CLzmaEnc *)pp;
CSeqOutStreamBuf outStream;
LzmaEnc_SetInputBuf(p, src, srcLen);
outStream.funcTable.Write = MyWrite;
outStream.data = dest;
outStream.rem = *destLen;
outStream.overflow = False;
p->writeEndMark = writeEndMark;
res = LzmaEnc_Encode(pp, &outStream.funcTable, &p->seqBufInStream.funcTable,
progress, alloc, allocBig);
*destLen -= outStream.rem;
if (outStream.overflow)
return SZ_ERROR_OUTPUT_EOF;
return res;
}
SRes LzmaEncode(Byte *dest, SizeT *destLen, const Byte *src, SizeT srcLen,
const CLzmaEncProps *props, Byte *propsEncoded, SizeT *propsSize, int writeEndMark,
ICompressProgress *progress, ISzAlloc *alloc, ISzAlloc *allocBig)
{
CLzmaEnc *p = (CLzmaEnc *)LzmaEnc_Create(alloc);
SRes res;
if (p == 0)
return SZ_ERROR_MEM;
res = LzmaEnc_SetProps(p, props);
if (res == SZ_OK)
{
res = LzmaEnc_WriteProperties(p, propsEncoded, propsSize);
if (res == SZ_OK)
res = LzmaEnc_MemEncode(p, dest, destLen, src, srcLen,
writeEndMark, progress, alloc, allocBig);
}
LzmaEnc_Destroy(p, alloc, allocBig);
return res;
}
Reference in New Issue View Git Blame Copy Permalink