gzdoom/libraries/lzma/C/LzFind.c
Cacodemon345 4497d7fdaa Update LZMA SDK to 23.01
As a bonus, add support for XZ-compressed files in ZIP
2023-10-07 17:31:24 +02:00

1717 lines
42 KiB
C

/* LzFind.c -- Match finder for LZ algorithms
2023-03-14 : Igor Pavlov : Public domain */
#include "Precomp.h"
#include <string.h>
// #include <stdio.h>
#include "CpuArch.h"
#include "LzFind.h"
#include "LzHash.h"
#define kBlockMoveAlign (1 << 7) // alignment for memmove()
#define kBlockSizeAlign (1 << 16) // alignment for block allocation
#define kBlockSizeReserveMin (1 << 24) // it's 1/256 from 4 GB dictinary
#define kEmptyHashValue 0
#define kMaxValForNormalize ((UInt32)0)
// #define kMaxValForNormalize ((UInt32)(1 << 20) + 0xfff) // for debug
// #define kNormalizeAlign (1 << 7) // alignment for speculated accesses
#define GET_AVAIL_BYTES(p) \
Inline_MatchFinder_GetNumAvailableBytes(p)
// #define kFix5HashSize (kHash2Size + kHash3Size + kHash4Size)
#define kFix5HashSize kFix4HashSize
/*
HASH2_CALC:
if (hv) match, then cur[0] and cur[1] also match
*/
#define HASH2_CALC hv = GetUi16(cur);
// (crc[0 ... 255] & 0xFF) provides one-to-one correspondence to [0 ... 255]
/*
HASH3_CALC:
if (cur[0]) and (h2) match, then cur[1] also match
if (cur[0]) and (hv) match, then cur[1] and cur[2] also match
*/
#define HASH3_CALC { \
UInt32 temp = p->crc[cur[0]] ^ cur[1]; \
h2 = temp & (kHash2Size - 1); \
hv = (temp ^ ((UInt32)cur[2] << 8)) & p->hashMask; }
#define HASH4_CALC { \
UInt32 temp = p->crc[cur[0]] ^ cur[1]; \
h2 = temp & (kHash2Size - 1); \
temp ^= ((UInt32)cur[2] << 8); \
h3 = temp & (kHash3Size - 1); \
hv = (temp ^ (p->crc[cur[3]] << kLzHash_CrcShift_1)) & p->hashMask; }
#define HASH5_CALC { \
UInt32 temp = p->crc[cur[0]] ^ cur[1]; \
h2 = temp & (kHash2Size - 1); \
temp ^= ((UInt32)cur[2] << 8); \
h3 = temp & (kHash3Size - 1); \
temp ^= (p->crc[cur[3]] << kLzHash_CrcShift_1); \
/* h4 = temp & p->hash4Mask; */ /* (kHash4Size - 1); */ \
hv = (temp ^ (p->crc[cur[4]] << kLzHash_CrcShift_2)) & p->hashMask; }
#define HASH_ZIP_CALC hv = ((cur[2] | ((UInt32)cur[0] << 8)) ^ p->crc[cur[1]]) & 0xFFFF;
static void LzInWindow_Free(CMatchFinder *p, ISzAllocPtr alloc)
{
// if (!p->directInput)
{
ISzAlloc_Free(alloc, p->bufBase);
p->bufBase = NULL;
}
}
static int LzInWindow_Create2(CMatchFinder *p, UInt32 blockSize, ISzAllocPtr alloc)
{
if (blockSize == 0)
return 0;
if (!p->bufBase || p->blockSize != blockSize)
{
// size_t blockSizeT;
LzInWindow_Free(p, alloc);
p->blockSize = blockSize;
// blockSizeT = blockSize;
// printf("\nblockSize = 0x%x\n", blockSize);
/*
#if defined _WIN64
// we can allocate 4GiB, but still use UInt32 for (p->blockSize)
// we use UInt32 type for (p->blockSize), because
// we don't want to wrap over 4 GiB,
// when we use (p->streamPos - p->pos) that is UInt32.
if (blockSize >= (UInt32)0 - (UInt32)kBlockSizeAlign)
{
blockSizeT = ((size_t)1 << 32);
printf("\nchanged to blockSizeT = 4GiB\n");
}
#endif
*/
p->bufBase = (Byte *)ISzAlloc_Alloc(alloc, blockSize);
// printf("\nbufferBase = %p\n", p->bufBase);
// return 0; // for debug
}
return (p->bufBase != NULL);
}
static const Byte *MatchFinder_GetPointerToCurrentPos(CMatchFinder *p) { return p->buffer; }
static UInt32 MatchFinder_GetNumAvailableBytes(CMatchFinder *p) { return GET_AVAIL_BYTES(p); }
Z7_NO_INLINE
static void MatchFinder_ReadBlock(CMatchFinder *p)
{
if (p->streamEndWasReached || p->result != SZ_OK)
return;
/* We use (p->streamPos - p->pos) value.
(p->streamPos < p->pos) is allowed. */
if (p->directInput)
{
UInt32 curSize = 0xFFFFFFFF - GET_AVAIL_BYTES(p);
if (curSize > p->directInputRem)
curSize = (UInt32)p->directInputRem;
p->streamPos += curSize;
p->directInputRem -= curSize;
if (p->directInputRem == 0)
p->streamEndWasReached = 1;
return;
}
for (;;)
{
const Byte *dest = p->buffer + GET_AVAIL_BYTES(p);
size_t size = (size_t)(p->bufBase + p->blockSize - dest);
if (size == 0)
{
/* we call ReadBlock() after NeedMove() and MoveBlock().
NeedMove() and MoveBlock() povide more than (keepSizeAfter)
to the end of (blockSize).
So we don't execute this branch in normal code flow.
We can go here, if we will call ReadBlock() before NeedMove(), MoveBlock().
*/
// p->result = SZ_ERROR_FAIL; // we can show error here
return;
}
// #define kRead 3
// if (size > kRead) size = kRead; // for debug
/*
// we need cast (Byte *)dest.
#ifdef __clang__
#pragma GCC diagnostic ignored "-Wcast-qual"
#endif
*/
p->result = ISeqInStream_Read(p->stream,
p->bufBase + (dest - p->bufBase), &size);
if (p->result != SZ_OK)
return;
if (size == 0)
{
p->streamEndWasReached = 1;
return;
}
p->streamPos += (UInt32)size;
if (GET_AVAIL_BYTES(p) > p->keepSizeAfter)
return;
/* here and in another (p->keepSizeAfter) checks we keep on 1 byte more than was requested by Create() function
(GET_AVAIL_BYTES(p) >= p->keepSizeAfter) - minimal required size */
}
// on exit: (p->result != SZ_OK || p->streamEndWasReached || GET_AVAIL_BYTES(p) > p->keepSizeAfter)
}
Z7_NO_INLINE
void MatchFinder_MoveBlock(CMatchFinder *p)
{
const size_t offset = (size_t)(p->buffer - p->bufBase) - p->keepSizeBefore;
const size_t keepBefore = (offset & (kBlockMoveAlign - 1)) + p->keepSizeBefore;
p->buffer = p->bufBase + keepBefore;
memmove(p->bufBase,
p->bufBase + (offset & ~((size_t)kBlockMoveAlign - 1)),
keepBefore + (size_t)GET_AVAIL_BYTES(p));
}
/* We call MoveBlock() before ReadBlock().
So MoveBlock() can be wasteful operation, if the whole input data
can fit in current block even without calling MoveBlock().
in important case where (dataSize <= historySize)
condition (p->blockSize > dataSize + p->keepSizeAfter) is met
So there is no MoveBlock() in that case case.
*/
int MatchFinder_NeedMove(CMatchFinder *p)
{
if (p->directInput)
return 0;
if (p->streamEndWasReached || p->result != SZ_OK)
return 0;
return ((size_t)(p->bufBase + p->blockSize - p->buffer) <= p->keepSizeAfter);
}
void MatchFinder_ReadIfRequired(CMatchFinder *p)
{
if (p->keepSizeAfter >= GET_AVAIL_BYTES(p))
MatchFinder_ReadBlock(p);
}
static void MatchFinder_SetDefaultSettings(CMatchFinder *p)
{
p->cutValue = 32;
p->btMode = 1;
p->numHashBytes = 4;
p->numHashBytes_Min = 2;
p->numHashOutBits = 0;
p->bigHash = 0;
}
#define kCrcPoly 0xEDB88320
void MatchFinder_Construct(CMatchFinder *p)
{
unsigned i;
p->buffer = NULL;
p->bufBase = NULL;
p->directInput = 0;
p->stream = NULL;
p->hash = NULL;
p->expectedDataSize = (UInt64)(Int64)-1;
MatchFinder_SetDefaultSettings(p);
for (i = 0; i < 256; i++)
{
UInt32 r = (UInt32)i;
unsigned j;
for (j = 0; j < 8; j++)
r = (r >> 1) ^ (kCrcPoly & ((UInt32)0 - (r & 1)));
p->crc[i] = r;
}
}
#undef kCrcPoly
static void MatchFinder_FreeThisClassMemory(CMatchFinder *p, ISzAllocPtr alloc)
{
ISzAlloc_Free(alloc, p->hash);
p->hash = NULL;
}
void MatchFinder_Free(CMatchFinder *p, ISzAllocPtr alloc)
{
MatchFinder_FreeThisClassMemory(p, alloc);
LzInWindow_Free(p, alloc);
}
static CLzRef* AllocRefs(size_t num, ISzAllocPtr alloc)
{
const size_t sizeInBytes = (size_t)num * sizeof(CLzRef);
if (sizeInBytes / sizeof(CLzRef) != num)
return NULL;
return (CLzRef *)ISzAlloc_Alloc(alloc, sizeInBytes);
}
#if (kBlockSizeReserveMin < kBlockSizeAlign * 2)
#error Stop_Compiling_Bad_Reserve
#endif
static UInt32 GetBlockSize(CMatchFinder *p, UInt32 historySize)
{
UInt32 blockSize = (p->keepSizeBefore + p->keepSizeAfter);
/*
if (historySize > kMaxHistorySize)
return 0;
*/
// printf("\nhistorySize == 0x%x\n", historySize);
if (p->keepSizeBefore < historySize || blockSize < p->keepSizeBefore) // if 32-bit overflow
return 0;
{
const UInt32 kBlockSizeMax = (UInt32)0 - (UInt32)kBlockSizeAlign;
const UInt32 rem = kBlockSizeMax - blockSize;
const UInt32 reserve = (blockSize >> (blockSize < ((UInt32)1 << 30) ? 1 : 2))
+ (1 << 12) + kBlockMoveAlign + kBlockSizeAlign; // do not overflow 32-bit here
if (blockSize >= kBlockSizeMax
|| rem < kBlockSizeReserveMin) // we reject settings that will be slow
return 0;
if (reserve >= rem)
blockSize = kBlockSizeMax;
else
{
blockSize += reserve;
blockSize &= ~(UInt32)(kBlockSizeAlign - 1);
}
}
// printf("\n LzFind_blockSize = %x\n", blockSize);
// printf("\n LzFind_blockSize = %d\n", blockSize >> 20);
return blockSize;
}
// input is historySize
static UInt32 MatchFinder_GetHashMask2(CMatchFinder *p, UInt32 hs)
{
if (p->numHashBytes == 2)
return (1 << 16) - 1;
if (hs != 0)
hs--;
hs |= (hs >> 1);
hs |= (hs >> 2);
hs |= (hs >> 4);
hs |= (hs >> 8);
// we propagated 16 bits in (hs). Low 16 bits must be set later
if (hs >= (1 << 24))
{
if (p->numHashBytes == 3)
hs = (1 << 24) - 1;
/* if (bigHash) mode, GetHeads4b() in LzFindMt.c needs (hs >= ((1 << 24) - 1))) */
}
// (hash_size >= (1 << 16)) : Required for (numHashBytes > 2)
hs |= (1 << 16) - 1; /* don't change it! */
// bt5: we adjust the size with recommended minimum size
if (p->numHashBytes >= 5)
hs |= (256 << kLzHash_CrcShift_2) - 1;
return hs;
}
// input is historySize
static UInt32 MatchFinder_GetHashMask(CMatchFinder *p, UInt32 hs)
{
if (p->numHashBytes == 2)
return (1 << 16) - 1;
if (hs != 0)
hs--;
hs |= (hs >> 1);
hs |= (hs >> 2);
hs |= (hs >> 4);
hs |= (hs >> 8);
// we propagated 16 bits in (hs). Low 16 bits must be set later
hs >>= 1;
if (hs >= (1 << 24))
{
if (p->numHashBytes == 3)
hs = (1 << 24) - 1;
else
hs >>= 1;
/* if (bigHash) mode, GetHeads4b() in LzFindMt.c needs (hs >= ((1 << 24) - 1))) */
}
// (hash_size >= (1 << 16)) : Required for (numHashBytes > 2)
hs |= (1 << 16) - 1; /* don't change it! */
// bt5: we adjust the size with recommended minimum size
if (p->numHashBytes >= 5)
hs |= (256 << kLzHash_CrcShift_2) - 1;
return hs;
}
int MatchFinder_Create(CMatchFinder *p, UInt32 historySize,
UInt32 keepAddBufferBefore, UInt32 matchMaxLen, UInt32 keepAddBufferAfter,
ISzAllocPtr alloc)
{
/* we need one additional byte in (p->keepSizeBefore),
since we use MoveBlock() after (p->pos++) and before dictionary using */
// keepAddBufferBefore = (UInt32)0xFFFFFFFF - (1 << 22); // for debug
p->keepSizeBefore = historySize + keepAddBufferBefore + 1;
keepAddBufferAfter += matchMaxLen;
/* we need (p->keepSizeAfter >= p->numHashBytes) */
if (keepAddBufferAfter < p->numHashBytes)
keepAddBufferAfter = p->numHashBytes;
// keepAddBufferAfter -= 2; // for debug
p->keepSizeAfter = keepAddBufferAfter;
if (p->directInput)
p->blockSize = 0;
if (p->directInput || LzInWindow_Create2(p, GetBlockSize(p, historySize), alloc))
{
size_t hashSizeSum;
{
UInt32 hs;
UInt32 hsCur;
if (p->numHashOutBits != 0)
{
unsigned numBits = p->numHashOutBits;
const unsigned nbMax =
(p->numHashBytes == 2 ? 16 :
(p->numHashBytes == 3 ? 24 : 32));
if (numBits > nbMax)
numBits = nbMax;
if (numBits >= 32)
hs = (UInt32)0 - 1;
else
hs = ((UInt32)1 << numBits) - 1;
// (hash_size >= (1 << 16)) : Required for (numHashBytes > 2)
hs |= (1 << 16) - 1; /* don't change it! */
if (p->numHashBytes >= 5)
hs |= (256 << kLzHash_CrcShift_2) - 1;
{
const UInt32 hs2 = MatchFinder_GetHashMask2(p, historySize);
if (hs > hs2)
hs = hs2;
}
hsCur = hs;
if (p->expectedDataSize < historySize)
{
const UInt32 hs2 = MatchFinder_GetHashMask2(p, (UInt32)p->expectedDataSize);
if (hsCur > hs2)
hsCur = hs2;
}
}
else
{
hs = MatchFinder_GetHashMask(p, historySize);
hsCur = hs;
if (p->expectedDataSize < historySize)
{
hsCur = MatchFinder_GetHashMask(p, (UInt32)p->expectedDataSize);
if (hsCur > hs) // is it possible?
hsCur = hs;
}
}
p->hashMask = hsCur;
hashSizeSum = hs;
hashSizeSum++;
if (hashSizeSum < hs)
return 0;
{
UInt32 fixedHashSize = 0;
if (p->numHashBytes > 2 && p->numHashBytes_Min <= 2) fixedHashSize += kHash2Size;
if (p->numHashBytes > 3 && p->numHashBytes_Min <= 3) fixedHashSize += kHash3Size;
// if (p->numHashBytes > 4) p->fixedHashSize += hs4; // kHash4Size;
hashSizeSum += fixedHashSize;
p->fixedHashSize = fixedHashSize;
}
}
p->matchMaxLen = matchMaxLen;
{
size_t newSize;
size_t numSons;
const UInt32 newCyclicBufferSize = historySize + 1; // do not change it
p->historySize = historySize;
p->cyclicBufferSize = newCyclicBufferSize; // it must be = (historySize + 1)
numSons = newCyclicBufferSize;
if (p->btMode)
numSons <<= 1;
newSize = hashSizeSum + numSons;
if (numSons < newCyclicBufferSize || newSize < numSons)
return 0;
// aligned size is not required here, but it can be better for some loops
#define NUM_REFS_ALIGN_MASK 0xF
newSize = (newSize + NUM_REFS_ALIGN_MASK) & ~(size_t)NUM_REFS_ALIGN_MASK;
// 22.02: we don't reallocate buffer, if old size is enough
if (p->hash && p->numRefs >= newSize)
return 1;
MatchFinder_FreeThisClassMemory(p, alloc);
p->numRefs = newSize;
p->hash = AllocRefs(newSize, alloc);
if (p->hash)
{
p->son = p->hash + hashSizeSum;
return 1;
}
}
}
MatchFinder_Free(p, alloc);
return 0;
}
static void MatchFinder_SetLimits(CMatchFinder *p)
{
UInt32 k;
UInt32 n = kMaxValForNormalize - p->pos;
if (n == 0)
n = (UInt32)(Int32)-1; // we allow (pos == 0) at start even with (kMaxValForNormalize == 0)
k = p->cyclicBufferSize - p->cyclicBufferPos;
if (k < n)
n = k;
k = GET_AVAIL_BYTES(p);
{
const UInt32 ksa = p->keepSizeAfter;
UInt32 mm = p->matchMaxLen;
if (k > ksa)
k -= ksa; // we must limit exactly to keepSizeAfter for ReadBlock
else if (k >= mm)
{
// the limitation for (p->lenLimit) update
k -= mm; // optimization : to reduce the number of checks
k++;
// k = 1; // non-optimized version : for debug
}
else
{
mm = k;
if (k != 0)
k = 1;
}
p->lenLimit = mm;
}
if (k < n)
n = k;
p->posLimit = p->pos + n;
}
void MatchFinder_Init_LowHash(CMatchFinder *p)
{
size_t i;
CLzRef *items = p->hash;
const size_t numItems = p->fixedHashSize;
for (i = 0; i < numItems; i++)
items[i] = kEmptyHashValue;
}
void MatchFinder_Init_HighHash(CMatchFinder *p)
{
size_t i;
CLzRef *items = p->hash + p->fixedHashSize;
const size_t numItems = (size_t)p->hashMask + 1;
for (i = 0; i < numItems; i++)
items[i] = kEmptyHashValue;
}
void MatchFinder_Init_4(CMatchFinder *p)
{
if (!p->directInput)
p->buffer = p->bufBase;
{
/* kEmptyHashValue = 0 (Zero) is used in hash tables as NO-VALUE marker.
the code in CMatchFinderMt expects (pos = 1) */
p->pos =
p->streamPos =
1; // it's smallest optimal value. do not change it
// 0; // for debug
}
p->result = SZ_OK;
p->streamEndWasReached = 0;
}
// (CYC_TO_POS_OFFSET == 0) is expected by some optimized code
#define CYC_TO_POS_OFFSET 0
// #define CYC_TO_POS_OFFSET 1 // for debug
void MatchFinder_Init(CMatchFinder *p)
{
MatchFinder_Init_HighHash(p);
MatchFinder_Init_LowHash(p);
MatchFinder_Init_4(p);
// if (readData)
MatchFinder_ReadBlock(p);
/* if we init (cyclicBufferPos = pos), then we can use one variable
instead of both (cyclicBufferPos) and (pos) : only before (cyclicBufferPos) wrapping */
p->cyclicBufferPos = (p->pos - CYC_TO_POS_OFFSET); // init with relation to (pos)
// p->cyclicBufferPos = 0; // smallest value
// p->son[0] = p->son[1] = 0; // unused: we can init skipped record for speculated accesses.
MatchFinder_SetLimits(p);
}
#ifdef MY_CPU_X86_OR_AMD64
#if defined(__clang__) && (__clang_major__ >= 4) \
|| defined(Z7_GCC_VERSION) && (Z7_GCC_VERSION >= 40701)
// || defined(__INTEL_COMPILER) && (__INTEL_COMPILER >= 1900)
#define USE_LZFIND_SATUR_SUB_128
#define USE_LZFIND_SATUR_SUB_256
#define LZFIND_ATTRIB_SSE41 __attribute__((__target__("sse4.1")))
#define LZFIND_ATTRIB_AVX2 __attribute__((__target__("avx2")))
#elif defined(_MSC_VER)
#if (_MSC_VER >= 1600)
#define USE_LZFIND_SATUR_SUB_128
#endif
#if (_MSC_VER >= 1900)
#define USE_LZFIND_SATUR_SUB_256
#endif
#endif
// #elif defined(MY_CPU_ARM_OR_ARM64)
#elif defined(MY_CPU_ARM64)
#if defined(__clang__) && (__clang_major__ >= 8) \
|| defined(__GNUC__) && (__GNUC__ >= 8)
#define USE_LZFIND_SATUR_SUB_128
#ifdef MY_CPU_ARM64
// #define LZFIND_ATTRIB_SSE41 __attribute__((__target__("")))
#else
// #define LZFIND_ATTRIB_SSE41 __attribute__((__target__("fpu=crypto-neon-fp-armv8")))
#endif
#elif defined(_MSC_VER)
#if (_MSC_VER >= 1910)
#define USE_LZFIND_SATUR_SUB_128
#endif
#endif
#if defined(_MSC_VER) && defined(MY_CPU_ARM64)
#include <arm64_neon.h>
#else
#include <arm_neon.h>
#endif
#endif
#ifdef USE_LZFIND_SATUR_SUB_128
// #define Z7_SHOW_HW_STATUS
#ifdef Z7_SHOW_HW_STATUS
#include <stdio.h>
#define PRF(x) x
PRF(;)
#else
#define PRF(x)
#endif
#ifdef MY_CPU_ARM_OR_ARM64
#ifdef MY_CPU_ARM64
// #define FORCE_LZFIND_SATUR_SUB_128
#endif
typedef uint32x4_t LzFind_v128;
#define SASUB_128_V(v, s) \
vsubq_u32(vmaxq_u32(v, s), s)
#else // MY_CPU_ARM_OR_ARM64
#include <smmintrin.h> // sse4.1
typedef __m128i LzFind_v128;
// SSE 4.1
#define SASUB_128_V(v, s) \
_mm_sub_epi32(_mm_max_epu32(v, s), s)
#endif // MY_CPU_ARM_OR_ARM64
#define SASUB_128(i) \
*( LzFind_v128 *)( void *)(items + (i) * 4) = SASUB_128_V( \
*(const LzFind_v128 *)(const void *)(items + (i) * 4), sub2);
Z7_NO_INLINE
static
#ifdef LZFIND_ATTRIB_SSE41
LZFIND_ATTRIB_SSE41
#endif
void
Z7_FASTCALL
LzFind_SaturSub_128(UInt32 subValue, CLzRef *items, const CLzRef *lim)
{
const LzFind_v128 sub2 =
#ifdef MY_CPU_ARM_OR_ARM64
vdupq_n_u32(subValue);
#else
_mm_set_epi32((Int32)subValue, (Int32)subValue, (Int32)subValue, (Int32)subValue);
#endif
Z7_PRAGMA_OPT_DISABLE_LOOP_UNROLL_VECTORIZE
do
{
SASUB_128(0) SASUB_128(1) items += 2 * 4;
SASUB_128(0) SASUB_128(1) items += 2 * 4;
}
while (items != lim);
}
#ifdef USE_LZFIND_SATUR_SUB_256
#include <immintrin.h> // avx
/*
clang :immintrin.h uses
#if !(defined(_MSC_VER) || defined(__SCE__)) || __has_feature(modules) || \
defined(__AVX2__)
#include <avx2intrin.h>
#endif
so we need <avxintrin.h> for clang-cl */
#if defined(__clang__)
#include <avxintrin.h>
#include <avx2intrin.h>
#endif
// AVX2:
#define SASUB_256(i) \
*( __m256i *)( void *)(items + (i) * 8) = \
_mm256_sub_epi32(_mm256_max_epu32( \
*(const __m256i *)(const void *)(items + (i) * 8), sub2), sub2);
Z7_NO_INLINE
static
#ifdef LZFIND_ATTRIB_AVX2
LZFIND_ATTRIB_AVX2
#endif
void
Z7_FASTCALL
LzFind_SaturSub_256(UInt32 subValue, CLzRef *items, const CLzRef *lim)
{
const __m256i sub2 = _mm256_set_epi32(
(Int32)subValue, (Int32)subValue, (Int32)subValue, (Int32)subValue,
(Int32)subValue, (Int32)subValue, (Int32)subValue, (Int32)subValue);
Z7_PRAGMA_OPT_DISABLE_LOOP_UNROLL_VECTORIZE
do
{
SASUB_256(0) SASUB_256(1) items += 2 * 8;
SASUB_256(0) SASUB_256(1) items += 2 * 8;
}
while (items != lim);
}
#endif // USE_LZFIND_SATUR_SUB_256
#ifndef FORCE_LZFIND_SATUR_SUB_128
typedef void (Z7_FASTCALL *LZFIND_SATUR_SUB_CODE_FUNC)(
UInt32 subValue, CLzRef *items, const CLzRef *lim);
static LZFIND_SATUR_SUB_CODE_FUNC g_LzFind_SaturSub;
#endif // FORCE_LZFIND_SATUR_SUB_128
#endif // USE_LZFIND_SATUR_SUB_128
// kEmptyHashValue must be zero
// #define SASUB_32(i) { UInt32 v = items[i]; UInt32 m = v - subValue; if (v < subValue) m = kEmptyHashValue; items[i] = m; }
#define SASUB_32(i) { UInt32 v = items[i]; if (v < subValue) v = subValue; items[i] = v - subValue; }
#ifdef FORCE_LZFIND_SATUR_SUB_128
#define DEFAULT_SaturSub LzFind_SaturSub_128
#else
#define DEFAULT_SaturSub LzFind_SaturSub_32
Z7_NO_INLINE
static
void
Z7_FASTCALL
LzFind_SaturSub_32(UInt32 subValue, CLzRef *items, const CLzRef *lim)
{
Z7_PRAGMA_OPT_DISABLE_LOOP_UNROLL_VECTORIZE
do
{
SASUB_32(0) SASUB_32(1) items += 2;
SASUB_32(0) SASUB_32(1) items += 2;
SASUB_32(0) SASUB_32(1) items += 2;
SASUB_32(0) SASUB_32(1) items += 2;
}
while (items != lim);
}
#endif
Z7_NO_INLINE
void MatchFinder_Normalize3(UInt32 subValue, CLzRef *items, size_t numItems)
{
#define LZFIND_NORM_ALIGN_BLOCK_SIZE (1 << 7)
Z7_PRAGMA_OPT_DISABLE_LOOP_UNROLL_VECTORIZE
for (; numItems != 0 && ((unsigned)(ptrdiff_t)items & (LZFIND_NORM_ALIGN_BLOCK_SIZE - 1)) != 0; numItems--)
{
SASUB_32(0)
items++;
}
{
const size_t k_Align_Mask = (LZFIND_NORM_ALIGN_BLOCK_SIZE / 4 - 1);
CLzRef *lim = items + (numItems & ~(size_t)k_Align_Mask);
numItems &= k_Align_Mask;
if (items != lim)
{
#if defined(USE_LZFIND_SATUR_SUB_128) && !defined(FORCE_LZFIND_SATUR_SUB_128)
if (g_LzFind_SaturSub)
g_LzFind_SaturSub(subValue, items, lim);
else
#endif
DEFAULT_SaturSub(subValue, items, lim);
}
items = lim;
}
Z7_PRAGMA_OPT_DISABLE_LOOP_UNROLL_VECTORIZE
for (; numItems != 0; numItems--)
{
SASUB_32(0)
items++;
}
}
// call MatchFinder_CheckLimits() only after (p->pos++) update
Z7_NO_INLINE
static void MatchFinder_CheckLimits(CMatchFinder *p)
{
if (// !p->streamEndWasReached && p->result == SZ_OK &&
p->keepSizeAfter == GET_AVAIL_BYTES(p))
{
// we try to read only in exact state (p->keepSizeAfter == GET_AVAIL_BYTES(p))
if (MatchFinder_NeedMove(p))
MatchFinder_MoveBlock(p);
MatchFinder_ReadBlock(p);
}
if (p->pos == kMaxValForNormalize)
if (GET_AVAIL_BYTES(p) >= p->numHashBytes) // optional optimization for last bytes of data.
/*
if we disable normalization for last bytes of data, and
if (data_size == 4 GiB), we don't call wastfull normalization,
but (pos) will be wrapped over Zero (0) in that case.
And we cannot resume later to normal operation
*/
{
// MatchFinder_Normalize(p);
/* after normalization we need (p->pos >= p->historySize + 1); */
/* we can reduce subValue to aligned value, if want to keep alignment
of (p->pos) and (p->buffer) for speculated accesses. */
const UInt32 subValue = (p->pos - p->historySize - 1) /* & ~(UInt32)(kNormalizeAlign - 1) */;
// const UInt32 subValue = (1 << 15); // for debug
// printf("\nMatchFinder_Normalize() subValue == 0x%x\n", subValue);
MatchFinder_REDUCE_OFFSETS(p, subValue)
MatchFinder_Normalize3(subValue, p->hash, (size_t)p->hashMask + 1 + p->fixedHashSize);
{
size_t numSonRefs = p->cyclicBufferSize;
if (p->btMode)
numSonRefs <<= 1;
MatchFinder_Normalize3(subValue, p->son, numSonRefs);
}
}
if (p->cyclicBufferPos == p->cyclicBufferSize)
p->cyclicBufferPos = 0;
MatchFinder_SetLimits(p);
}
/*
(lenLimit > maxLen)
*/
Z7_FORCE_INLINE
static UInt32 * Hc_GetMatchesSpec(size_t lenLimit, UInt32 curMatch, UInt32 pos, const Byte *cur, CLzRef *son,
size_t _cyclicBufferPos, UInt32 _cyclicBufferSize, UInt32 cutValue,
UInt32 *d, unsigned maxLen)
{
/*
son[_cyclicBufferPos] = curMatch;
for (;;)
{
UInt32 delta = pos - curMatch;
if (cutValue-- == 0 || delta >= _cyclicBufferSize)
return d;
{
const Byte *pb = cur - delta;
curMatch = son[_cyclicBufferPos - delta + ((delta > _cyclicBufferPos) ? _cyclicBufferSize : 0)];
if (pb[maxLen] == cur[maxLen] && *pb == *cur)
{
UInt32 len = 0;
while (++len != lenLimit)
if (pb[len] != cur[len])
break;
if (maxLen < len)
{
maxLen = len;
*d++ = len;
*d++ = delta - 1;
if (len == lenLimit)
return d;
}
}
}
}
*/
const Byte *lim = cur + lenLimit;
son[_cyclicBufferPos] = curMatch;
do
{
UInt32 delta;
if (curMatch == 0)
break;
// if (curMatch2 >= curMatch) return NULL;
delta = pos - curMatch;
if (delta >= _cyclicBufferSize)
break;
{
ptrdiff_t diff;
curMatch = son[_cyclicBufferPos - delta + ((delta > _cyclicBufferPos) ? _cyclicBufferSize : 0)];
diff = (ptrdiff_t)0 - (ptrdiff_t)delta;
if (cur[maxLen] == cur[(ptrdiff_t)maxLen + diff])
{
const Byte *c = cur;
while (*c == c[diff])
{
if (++c == lim)
{
d[0] = (UInt32)(lim - cur);
d[1] = delta - 1;
return d + 2;
}
}
{
const unsigned len = (unsigned)(c - cur);
if (maxLen < len)
{
maxLen = len;
d[0] = (UInt32)len;
d[1] = delta - 1;
d += 2;
}
}
}
}
}
while (--cutValue);
return d;
}
Z7_FORCE_INLINE
UInt32 * GetMatchesSpec1(UInt32 lenLimit, UInt32 curMatch, UInt32 pos, const Byte *cur, CLzRef *son,
size_t _cyclicBufferPos, UInt32 _cyclicBufferSize, UInt32 cutValue,
UInt32 *d, UInt32 maxLen)
{
CLzRef *ptr0 = son + ((size_t)_cyclicBufferPos << 1) + 1;
CLzRef *ptr1 = son + ((size_t)_cyclicBufferPos << 1);
unsigned len0 = 0, len1 = 0;
UInt32 cmCheck;
// if (curMatch >= pos) { *ptr0 = *ptr1 = kEmptyHashValue; return NULL; }
cmCheck = (UInt32)(pos - _cyclicBufferSize);
if ((UInt32)pos <= _cyclicBufferSize)
cmCheck = 0;
if (cmCheck < curMatch)
do
{
const UInt32 delta = pos - curMatch;
{
CLzRef *pair = son + ((size_t)(_cyclicBufferPos - delta + ((delta > _cyclicBufferPos) ? _cyclicBufferSize : 0)) << 1);
const Byte *pb = cur - delta;
unsigned len = (len0 < len1 ? len0 : len1);
const UInt32 pair0 = pair[0];
if (pb[len] == cur[len])
{
if (++len != lenLimit && pb[len] == cur[len])
while (++len != lenLimit)
if (pb[len] != cur[len])
break;
if (maxLen < len)
{
maxLen = (UInt32)len;
*d++ = (UInt32)len;
*d++ = delta - 1;
if (len == lenLimit)
{
*ptr1 = pair0;
*ptr0 = pair[1];
return d;
}
}
}
if (pb[len] < cur[len])
{
*ptr1 = curMatch;
// const UInt32 curMatch2 = pair[1];
// if (curMatch2 >= curMatch) { *ptr0 = *ptr1 = kEmptyHashValue; return NULL; }
// curMatch = curMatch2;
curMatch = pair[1];
ptr1 = pair + 1;
len1 = len;
}
else
{
*ptr0 = curMatch;
curMatch = pair[0];
ptr0 = pair;
len0 = len;
}
}
}
while(--cutValue && cmCheck < curMatch);
*ptr0 = *ptr1 = kEmptyHashValue;
return d;
}
static void SkipMatchesSpec(UInt32 lenLimit, UInt32 curMatch, UInt32 pos, const Byte *cur, CLzRef *son,
size_t _cyclicBufferPos, UInt32 _cyclicBufferSize, UInt32 cutValue)
{
CLzRef *ptr0 = son + ((size_t)_cyclicBufferPos << 1) + 1;
CLzRef *ptr1 = son + ((size_t)_cyclicBufferPos << 1);
unsigned len0 = 0, len1 = 0;
UInt32 cmCheck;
cmCheck = (UInt32)(pos - _cyclicBufferSize);
if ((UInt32)pos <= _cyclicBufferSize)
cmCheck = 0;
if (// curMatch >= pos || // failure
cmCheck < curMatch)
do
{
const UInt32 delta = pos - curMatch;
{
CLzRef *pair = son + ((size_t)(_cyclicBufferPos - delta + ((delta > _cyclicBufferPos) ? _cyclicBufferSize : 0)) << 1);
const Byte *pb = cur - delta;
unsigned len = (len0 < len1 ? len0 : len1);
if (pb[len] == cur[len])
{
while (++len != lenLimit)
if (pb[len] != cur[len])
break;
{
if (len == lenLimit)
{
*ptr1 = pair[0];
*ptr0 = pair[1];
return;
}
}
}
if (pb[len] < cur[len])
{
*ptr1 = curMatch;
curMatch = pair[1];
ptr1 = pair + 1;
len1 = len;
}
else
{
*ptr0 = curMatch;
curMatch = pair[0];
ptr0 = pair;
len0 = len;
}
}
}
while(--cutValue && cmCheck < curMatch);
*ptr0 = *ptr1 = kEmptyHashValue;
return;
}
#define MOVE_POS \
++p->cyclicBufferPos; \
p->buffer++; \
{ const UInt32 pos1 = p->pos + 1; p->pos = pos1; if (pos1 == p->posLimit) MatchFinder_CheckLimits(p); }
#define MOVE_POS_RET MOVE_POS return distances;
Z7_NO_INLINE
static void MatchFinder_MovePos(CMatchFinder *p)
{
/* we go here at the end of stream data, when (avail < num_hash_bytes)
We don't update sons[cyclicBufferPos << btMode].
So (sons) record will contain junk. And we cannot resume match searching
to normal operation, even if we will provide more input data in buffer.
p->sons[p->cyclicBufferPos << p->btMode] = 0; // kEmptyHashValue
if (p->btMode)
p->sons[(p->cyclicBufferPos << p->btMode) + 1] = 0; // kEmptyHashValue
*/
MOVE_POS
}
#define GET_MATCHES_HEADER2(minLen, ret_op) \
unsigned lenLimit; UInt32 hv; const Byte *cur; UInt32 curMatch; \
lenLimit = (unsigned)p->lenLimit; { if (lenLimit < minLen) { MatchFinder_MovePos(p); ret_op; }} \
cur = p->buffer;
#define GET_MATCHES_HEADER(minLen) GET_MATCHES_HEADER2(minLen, return distances)
#define SKIP_HEADER(minLen) do { GET_MATCHES_HEADER2(minLen, continue)
#define MF_PARAMS(p) lenLimit, curMatch, p->pos, p->buffer, p->son, p->cyclicBufferPos, p->cyclicBufferSize, p->cutValue
#define SKIP_FOOTER SkipMatchesSpec(MF_PARAMS(p)); MOVE_POS } while (--num);
#define GET_MATCHES_FOOTER_BASE(_maxLen_, func) \
distances = func(MF_PARAMS(p), \
distances, (UInt32)_maxLen_); MOVE_POS_RET
#define GET_MATCHES_FOOTER_BT(_maxLen_) \
GET_MATCHES_FOOTER_BASE(_maxLen_, GetMatchesSpec1)
#define GET_MATCHES_FOOTER_HC(_maxLen_) \
GET_MATCHES_FOOTER_BASE(_maxLen_, Hc_GetMatchesSpec)
#define UPDATE_maxLen { \
const ptrdiff_t diff = (ptrdiff_t)0 - (ptrdiff_t)d2; \
const Byte *c = cur + maxLen; \
const Byte *lim = cur + lenLimit; \
for (; c != lim; c++) if (*(c + diff) != *c) break; \
maxLen = (unsigned)(c - cur); }
static UInt32* Bt2_MatchFinder_GetMatches(CMatchFinder *p, UInt32 *distances)
{
GET_MATCHES_HEADER(2)
HASH2_CALC
curMatch = p->hash[hv];
p->hash[hv] = p->pos;
GET_MATCHES_FOOTER_BT(1)
}
UInt32* Bt3Zip_MatchFinder_GetMatches(CMatchFinder *p, UInt32 *distances)
{
GET_MATCHES_HEADER(3)
HASH_ZIP_CALC
curMatch = p->hash[hv];
p->hash[hv] = p->pos;
GET_MATCHES_FOOTER_BT(2)
}
#define SET_mmm \
mmm = p->cyclicBufferSize; \
if (pos < mmm) \
mmm = pos;
static UInt32* Bt3_MatchFinder_GetMatches(CMatchFinder *p, UInt32 *distances)
{
UInt32 mmm;
UInt32 h2, d2, pos;
unsigned maxLen;
UInt32 *hash;
GET_MATCHES_HEADER(3)
HASH3_CALC
hash = p->hash;
pos = p->pos;
d2 = pos - hash[h2];
curMatch = (hash + kFix3HashSize)[hv];
hash[h2] = pos;
(hash + kFix3HashSize)[hv] = pos;
SET_mmm
maxLen = 2;
if (d2 < mmm && *(cur - d2) == *cur)
{
UPDATE_maxLen
distances[0] = (UInt32)maxLen;
distances[1] = d2 - 1;
distances += 2;
if (maxLen == lenLimit)
{
SkipMatchesSpec(MF_PARAMS(p));
MOVE_POS_RET
}
}
GET_MATCHES_FOOTER_BT(maxLen)
}
static UInt32* Bt4_MatchFinder_GetMatches(CMatchFinder *p, UInt32 *distances)
{
UInt32 mmm;
UInt32 h2, h3, d2, d3, pos;
unsigned maxLen;
UInt32 *hash;
GET_MATCHES_HEADER(4)
HASH4_CALC
hash = p->hash;
pos = p->pos;
d2 = pos - hash [h2];
d3 = pos - (hash + kFix3HashSize)[h3];
curMatch = (hash + kFix4HashSize)[hv];
hash [h2] = pos;
(hash + kFix3HashSize)[h3] = pos;
(hash + kFix4HashSize)[hv] = pos;
SET_mmm
maxLen = 3;
for (;;)
{
if (d2 < mmm && *(cur - d2) == *cur)
{
distances[0] = 2;
distances[1] = d2 - 1;
distances += 2;
if (*(cur - d2 + 2) == cur[2])
{
// distances[-2] = 3;
}
else if (d3 < mmm && *(cur - d3) == *cur)
{
d2 = d3;
distances[1] = d3 - 1;
distances += 2;
}
else
break;
}
else if (d3 < mmm && *(cur - d3) == *cur)
{
d2 = d3;
distances[1] = d3 - 1;
distances += 2;
}
else
break;
UPDATE_maxLen
distances[-2] = (UInt32)maxLen;
if (maxLen == lenLimit)
{
SkipMatchesSpec(MF_PARAMS(p));
MOVE_POS_RET
}
break;
}
GET_MATCHES_FOOTER_BT(maxLen)
}
static UInt32* Bt5_MatchFinder_GetMatches(CMatchFinder *p, UInt32 *distances)
{
UInt32 mmm;
UInt32 h2, h3, d2, d3, maxLen, pos;
UInt32 *hash;
GET_MATCHES_HEADER(5)
HASH5_CALC
hash = p->hash;
pos = p->pos;
d2 = pos - hash [h2];
d3 = pos - (hash + kFix3HashSize)[h3];
// d4 = pos - (hash + kFix4HashSize)[h4];
curMatch = (hash + kFix5HashSize)[hv];
hash [h2] = pos;
(hash + kFix3HashSize)[h3] = pos;
// (hash + kFix4HashSize)[h4] = pos;
(hash + kFix5HashSize)[hv] = pos;
SET_mmm
maxLen = 4;
for (;;)
{
if (d2 < mmm && *(cur - d2) == *cur)
{
distances[0] = 2;
distances[1] = d2 - 1;
distances += 2;
if (*(cur - d2 + 2) == cur[2])
{
}
else if (d3 < mmm && *(cur - d3) == *cur)
{
distances[1] = d3 - 1;
distances += 2;
d2 = d3;
}
else
break;
}
else if (d3 < mmm && *(cur - d3) == *cur)
{
distances[1] = d3 - 1;
distances += 2;
d2 = d3;
}
else
break;
distances[-2] = 3;
if (*(cur - d2 + 3) != cur[3])
break;
UPDATE_maxLen
distances[-2] = (UInt32)maxLen;
if (maxLen == lenLimit)
{
SkipMatchesSpec(MF_PARAMS(p));
MOVE_POS_RET
}
break;
}
GET_MATCHES_FOOTER_BT(maxLen)
}
static UInt32* Hc4_MatchFinder_GetMatches(CMatchFinder *p, UInt32 *distances)
{
UInt32 mmm;
UInt32 h2, h3, d2, d3, pos;
unsigned maxLen;
UInt32 *hash;
GET_MATCHES_HEADER(4)
HASH4_CALC
hash = p->hash;
pos = p->pos;
d2 = pos - hash [h2];
d3 = pos - (hash + kFix3HashSize)[h3];
curMatch = (hash + kFix4HashSize)[hv];
hash [h2] = pos;
(hash + kFix3HashSize)[h3] = pos;
(hash + kFix4HashSize)[hv] = pos;
SET_mmm
maxLen = 3;
for (;;)
{
if (d2 < mmm && *(cur - d2) == *cur)
{
distances[0] = 2;
distances[1] = d2 - 1;
distances += 2;
if (*(cur - d2 + 2) == cur[2])
{
// distances[-2] = 3;
}
else if (d3 < mmm && *(cur - d3) == *cur)
{
d2 = d3;
distances[1] = d3 - 1;
distances += 2;
}
else
break;
}
else if (d3 < mmm && *(cur - d3) == *cur)
{
d2 = d3;
distances[1] = d3 - 1;
distances += 2;
}
else
break;
UPDATE_maxLen
distances[-2] = (UInt32)maxLen;
if (maxLen == lenLimit)
{
p->son[p->cyclicBufferPos] = curMatch;
MOVE_POS_RET
}
break;
}
GET_MATCHES_FOOTER_HC(maxLen)
}
static UInt32 * Hc5_MatchFinder_GetMatches(CMatchFinder *p, UInt32 *distances)
{
UInt32 mmm;
UInt32 h2, h3, d2, d3, maxLen, pos;
UInt32 *hash;
GET_MATCHES_HEADER(5)
HASH5_CALC
hash = p->hash;
pos = p->pos;
d2 = pos - hash [h2];
d3 = pos - (hash + kFix3HashSize)[h3];
// d4 = pos - (hash + kFix4HashSize)[h4];
curMatch = (hash + kFix5HashSize)[hv];
hash [h2] = pos;
(hash + kFix3HashSize)[h3] = pos;
// (hash + kFix4HashSize)[h4] = pos;
(hash + kFix5HashSize)[hv] = pos;
SET_mmm
maxLen = 4;
for (;;)
{
if (d2 < mmm && *(cur - d2) == *cur)
{
distances[0] = 2;
distances[1] = d2 - 1;
distances += 2;
if (*(cur - d2 + 2) == cur[2])
{
}
else if (d3 < mmm && *(cur - d3) == *cur)
{
distances[1] = d3 - 1;
distances += 2;
d2 = d3;
}
else
break;
}
else if (d3 < mmm && *(cur - d3) == *cur)
{
distances[1] = d3 - 1;
distances += 2;
d2 = d3;
}
else
break;
distances[-2] = 3;
if (*(cur - d2 + 3) != cur[3])
break;
UPDATE_maxLen
distances[-2] = maxLen;
if (maxLen == lenLimit)
{
p->son[p->cyclicBufferPos] = curMatch;
MOVE_POS_RET
}
break;
}
GET_MATCHES_FOOTER_HC(maxLen)
}
UInt32* Hc3Zip_MatchFinder_GetMatches(CMatchFinder *p, UInt32 *distances)
{
GET_MATCHES_HEADER(3)
HASH_ZIP_CALC
curMatch = p->hash[hv];
p->hash[hv] = p->pos;
GET_MATCHES_FOOTER_HC(2)
}
static void Bt2_MatchFinder_Skip(CMatchFinder *p, UInt32 num)
{
SKIP_HEADER(2)
{
HASH2_CALC
curMatch = p->hash[hv];
p->hash[hv] = p->pos;
}
SKIP_FOOTER
}
void Bt3Zip_MatchFinder_Skip(CMatchFinder *p, UInt32 num)
{
SKIP_HEADER(3)
{
HASH_ZIP_CALC
curMatch = p->hash[hv];
p->hash[hv] = p->pos;
}
SKIP_FOOTER
}
static void Bt3_MatchFinder_Skip(CMatchFinder *p, UInt32 num)
{
SKIP_HEADER(3)
{
UInt32 h2;
UInt32 *hash;
HASH3_CALC
hash = p->hash;
curMatch = (hash + kFix3HashSize)[hv];
hash[h2] =
(hash + kFix3HashSize)[hv] = p->pos;
}
SKIP_FOOTER
}
static void Bt4_MatchFinder_Skip(CMatchFinder *p, UInt32 num)
{
SKIP_HEADER(4)
{
UInt32 h2, h3;
UInt32 *hash;
HASH4_CALC
hash = p->hash;
curMatch = (hash + kFix4HashSize)[hv];
hash [h2] =
(hash + kFix3HashSize)[h3] =
(hash + kFix4HashSize)[hv] = p->pos;
}
SKIP_FOOTER
}
static void Bt5_MatchFinder_Skip(CMatchFinder *p, UInt32 num)
{
SKIP_HEADER(5)
{
UInt32 h2, h3;
UInt32 *hash;
HASH5_CALC
hash = p->hash;
curMatch = (hash + kFix5HashSize)[hv];
hash [h2] =
(hash + kFix3HashSize)[h3] =
// (hash + kFix4HashSize)[h4] =
(hash + kFix5HashSize)[hv] = p->pos;
}
SKIP_FOOTER
}
#define HC_SKIP_HEADER(minLen) \
do { if (p->lenLimit < minLen) { MatchFinder_MovePos(p); num--; continue; } { \
const Byte *cur; \
UInt32 *hash; \
UInt32 *son; \
UInt32 pos = p->pos; \
UInt32 num2 = num; \
/* (p->pos == p->posLimit) is not allowed here !!! */ \
{ const UInt32 rem = p->posLimit - pos; if (num2 > rem) num2 = rem; } \
num -= num2; \
{ const UInt32 cycPos = p->cyclicBufferPos; \
son = p->son + cycPos; \
p->cyclicBufferPos = cycPos + num2; } \
cur = p->buffer; \
hash = p->hash; \
do { \
UInt32 curMatch; \
UInt32 hv;
#define HC_SKIP_FOOTER \
cur++; pos++; *son++ = curMatch; \
} while (--num2); \
p->buffer = cur; \
p->pos = pos; \
if (pos == p->posLimit) MatchFinder_CheckLimits(p); \
}} while(num); \
static void Hc4_MatchFinder_Skip(CMatchFinder *p, UInt32 num)
{
HC_SKIP_HEADER(4)
UInt32 h2, h3;
HASH4_CALC
curMatch = (hash + kFix4HashSize)[hv];
hash [h2] =
(hash + kFix3HashSize)[h3] =
(hash + kFix4HashSize)[hv] = pos;
HC_SKIP_FOOTER
}
static void Hc5_MatchFinder_Skip(CMatchFinder *p, UInt32 num)
{
HC_SKIP_HEADER(5)
UInt32 h2, h3;
HASH5_CALC
curMatch = (hash + kFix5HashSize)[hv];
hash [h2] =
(hash + kFix3HashSize)[h3] =
// (hash + kFix4HashSize)[h4] =
(hash + kFix5HashSize)[hv] = pos;
HC_SKIP_FOOTER
}
void Hc3Zip_MatchFinder_Skip(CMatchFinder *p, UInt32 num)
{
HC_SKIP_HEADER(3)
HASH_ZIP_CALC
curMatch = hash[hv];
hash[hv] = pos;
HC_SKIP_FOOTER
}
void MatchFinder_CreateVTable(CMatchFinder *p, IMatchFinder2 *vTable)
{
vTable->Init = (Mf_Init_Func)MatchFinder_Init;
vTable->GetNumAvailableBytes = (Mf_GetNumAvailableBytes_Func)MatchFinder_GetNumAvailableBytes;
vTable->GetPointerToCurrentPos = (Mf_GetPointerToCurrentPos_Func)MatchFinder_GetPointerToCurrentPos;
if (!p->btMode)
{
if (p->numHashBytes <= 4)
{
vTable->GetMatches = (Mf_GetMatches_Func)Hc4_MatchFinder_GetMatches;
vTable->Skip = (Mf_Skip_Func)Hc4_MatchFinder_Skip;
}
else
{
vTable->GetMatches = (Mf_GetMatches_Func)Hc5_MatchFinder_GetMatches;
vTable->Skip = (Mf_Skip_Func)Hc5_MatchFinder_Skip;
}
}
else if (p->numHashBytes == 2)
{
vTable->GetMatches = (Mf_GetMatches_Func)Bt2_MatchFinder_GetMatches;
vTable->Skip = (Mf_Skip_Func)Bt2_MatchFinder_Skip;
}
else if (p->numHashBytes == 3)
{
vTable->GetMatches = (Mf_GetMatches_Func)Bt3_MatchFinder_GetMatches;
vTable->Skip = (Mf_Skip_Func)Bt3_MatchFinder_Skip;
}
else if (p->numHashBytes == 4)
{
vTable->GetMatches = (Mf_GetMatches_Func)Bt4_MatchFinder_GetMatches;
vTable->Skip = (Mf_Skip_Func)Bt4_MatchFinder_Skip;
}
else
{
vTable->GetMatches = (Mf_GetMatches_Func)Bt5_MatchFinder_GetMatches;
vTable->Skip = (Mf_Skip_Func)Bt5_MatchFinder_Skip;
}
}
void LzFindPrepare(void)
{
#ifndef FORCE_LZFIND_SATUR_SUB_128
#ifdef USE_LZFIND_SATUR_SUB_128
LZFIND_SATUR_SUB_CODE_FUNC f = NULL;
#ifdef MY_CPU_ARM_OR_ARM64
{
if (CPU_IsSupported_NEON())
{
// #pragma message ("=== LzFind NEON")
PRF(printf("\n=== LzFind NEON\n"));
f = LzFind_SaturSub_128;
}
// f = 0; // for debug
}
#else // MY_CPU_ARM_OR_ARM64
if (CPU_IsSupported_SSE41())
{
// #pragma message ("=== LzFind SSE41")
PRF(printf("\n=== LzFind SSE41\n"));
f = LzFind_SaturSub_128;
#ifdef USE_LZFIND_SATUR_SUB_256
if (CPU_IsSupported_AVX2())
{
// #pragma message ("=== LzFind AVX2")
PRF(printf("\n=== LzFind AVX2\n"));
f = LzFind_SaturSub_256;
}
#endif
}
#endif // MY_CPU_ARM_OR_ARM64
g_LzFind_SaturSub = f;
#endif // USE_LZFIND_SATUR_SUB_128
#endif // FORCE_LZFIND_SATUR_SUB_128
}
#undef MOVE_POS
#undef MOVE_POS_RET
#undef PRF