/* LzFindMt.c -- multithreaded Match finder for LZ algorithms 2008-10-04 : Igor Pavlov : Public domain */ #include "LzHash.h" #include "LzFindMt.h" void MtSync_Construct(CMtSync *p) { p->wasCreated = False; p->csWasInitialized = False; p->csWasEntered = False; Thread_Construct(&p->thread); Event_Construct(&p->canStart); Event_Construct(&p->wasStarted); Event_Construct(&p->wasStopped); Semaphore_Construct(&p->freeSemaphore); Semaphore_Construct(&p->filledSemaphore); } void MtSync_GetNextBlock(CMtSync *p) { if (p->needStart) { p->numProcessedBlocks = 1; p->needStart = False; p->stopWriting = False; p->exit = False; Event_Reset(&p->wasStarted); Event_Reset(&p->wasStopped); Event_Set(&p->canStart); Event_Wait(&p->wasStarted); } else { CriticalSection_Leave(&p->cs); p->csWasEntered = False; p->numProcessedBlocks++; Semaphore_Release1(&p->freeSemaphore); } Semaphore_Wait(&p->filledSemaphore); CriticalSection_Enter(&p->cs); p->csWasEntered = True; } /* MtSync_StopWriting must be called if Writing was started */ void MtSync_StopWriting(CMtSync *p) { UInt32 myNumBlocks = p->numProcessedBlocks; if (!Thread_WasCreated(&p->thread) || p->needStart) return; p->stopWriting = True; if (p->csWasEntered) { CriticalSection_Leave(&p->cs); p->csWasEntered = False; } Semaphore_Release1(&p->freeSemaphore); Event_Wait(&p->wasStopped); while (myNumBlocks++ != p->numProcessedBlocks) { Semaphore_Wait(&p->filledSemaphore); Semaphore_Release1(&p->freeSemaphore); } p->needStart = True; } void MtSync_Destruct(CMtSync *p) { if (Thread_WasCreated(&p->thread)) { MtSync_StopWriting(p); p->exit = True; if (p->needStart) Event_Set(&p->canStart); Thread_Wait(&p->thread); Thread_Close(&p->thread); } if (p->csWasInitialized) { CriticalSection_Delete(&p->cs); p->csWasInitialized = False; } Event_Close(&p->canStart); Event_Close(&p->wasStarted); Event_Close(&p->wasStopped); Semaphore_Close(&p->freeSemaphore); Semaphore_Close(&p->filledSemaphore); p->wasCreated = False; } #define RINOK_THREAD(x) { if ((x) != 0) return SZ_ERROR_THREAD; } static SRes MtSync_Create2(CMtSync *p, unsigned (MY_STD_CALL *startAddress)(void *), void *obj, UInt32 numBlocks) { if (p->wasCreated) return SZ_OK; RINOK_THREAD(CriticalSection_Init(&p->cs)); p->csWasInitialized = True; RINOK_THREAD(AutoResetEvent_CreateNotSignaled(&p->canStart)); RINOK_THREAD(AutoResetEvent_CreateNotSignaled(&p->wasStarted)); RINOK_THREAD(AutoResetEvent_CreateNotSignaled(&p->wasStopped)); RINOK_THREAD(Semaphore_Create(&p->freeSemaphore, numBlocks, numBlocks)); RINOK_THREAD(Semaphore_Create(&p->filledSemaphore, 0, numBlocks)); p->needStart = True; RINOK_THREAD(Thread_Create(&p->thread, startAddress, obj)); p->wasCreated = True; return SZ_OK; } static SRes MtSync_Create(CMtSync *p, unsigned (MY_STD_CALL *startAddress)(void *), void *obj, UInt32 numBlocks) { SRes res = MtSync_Create2(p, startAddress, obj, numBlocks); if (res != SZ_OK) MtSync_Destruct(p); return res; } void MtSync_Init(CMtSync *p) { p->needStart = True; } #define kMtMaxValForNormalize 0xFFFFFFFF #define DEF_GetHeads2(name, v, action) \ static void GetHeads ## name(const Byte *p, UInt32 pos, \ UInt32 *hash, UInt32 hashMask, UInt32 *heads, UInt32 numHeads, const UInt32 *crc) \ { action; for (; numHeads != 0; numHeads--) { \ const UInt32 value = (v); p++; *heads++ = pos - hash[value]; hash[value] = pos++; } } #define DEF_GetHeads(name, v) DEF_GetHeads2(name, v, ;) DEF_GetHeads2(2, (p[0] | ((UInt32)p[1] << 8)), hashMask = hashMask; crc = crc; ) DEF_GetHeads(3, (crc[p[0]] ^ p[1] ^ ((UInt32)p[2] << 8)) & hashMask) DEF_GetHeads(4, (crc[p[0]] ^ p[1] ^ ((UInt32)p[2] << 8) ^ (crc[p[3]] << 5)) & hashMask) DEF_GetHeads(4b, (crc[p[0]] ^ p[1] ^ ((UInt32)p[2] << 8) ^ ((UInt32)p[3] << 16)) & hashMask) DEF_GetHeads(5, (crc[p[0]] ^ p[1] ^ ((UInt32)p[2] << 8) ^ (crc[p[3]] << 5) ^ (crc[p[4]] << 3)) & hashMask) void HashThreadFunc(CMatchFinderMt *mt) { CMtSync *p = &mt->hashSync; for (;;) { UInt32 numProcessedBlocks = 0; Event_Wait(&p->canStart); Event_Set(&p->wasStarted); for (;;) { if (p->exit) return; if (p->stopWriting) { p->numProcessedBlocks = numProcessedBlocks; Event_Set(&p->wasStopped); break; } { CMatchFinder *mf = mt->MatchFinder; if (MatchFinder_NeedMove(mf)) { CriticalSection_Enter(&mt->btSync.cs); CriticalSection_Enter(&mt->hashSync.cs); { const Byte *beforePtr = MatchFinder_GetPointerToCurrentPos(mf); const Byte *afterPtr; MatchFinder_MoveBlock(mf); afterPtr = MatchFinder_GetPointerToCurrentPos(mf); mt->pointerToCurPos -= beforePtr - afterPtr; mt->buffer -= beforePtr - afterPtr; } CriticalSection_Leave(&mt->btSync.cs); CriticalSection_Leave(&mt->hashSync.cs); continue; } Semaphore_Wait(&p->freeSemaphore); MatchFinder_ReadIfRequired(mf); if (mf->pos > (kMtMaxValForNormalize - kMtHashBlockSize)) { UInt32 subValue = (mf->pos - mf->historySize - 1); MatchFinder_ReduceOffsets(mf, subValue); MatchFinder_Normalize3(subValue, mf->hash + mf->fixedHashSize, mf->hashMask + 1); } { UInt32 *heads = mt->hashBuf + ((numProcessedBlocks++) & kMtHashNumBlocksMask) * kMtHashBlockSize; UInt32 num = mf->streamPos - mf->pos; heads[0] = 2; heads[1] = num; if (num >= mf->numHashBytes) { num = num - mf->numHashBytes + 1; if (num > kMtHashBlockSize - 2) num = kMtHashBlockSize - 2; mt->GetHeadsFunc(mf->buffer, mf->pos, mf->hash + mf->fixedHashSize, mf->hashMask, heads + 2, num, mf->crc); heads[0] += num; } mf->pos += num; mf->buffer += num; } } Semaphore_Release1(&p->filledSemaphore); } } } void MatchFinderMt_GetNextBlock_Hash(CMatchFinderMt *p) { MtSync_GetNextBlock(&p->hashSync); p->hashBufPosLimit = p->hashBufPos = ((p->hashSync.numProcessedBlocks - 1) & kMtHashNumBlocksMask) * kMtHashBlockSize; p->hashBufPosLimit += p->hashBuf[p->hashBufPos++]; p->hashNumAvail = p->hashBuf[p->hashBufPos++]; } #define kEmptyHashValue 0 /* #define MFMT_GM_INLINE */ #ifdef MFMT_GM_INLINE #define NO_INLINE MY_FAST_CALL Int32 NO_INLINE GetMatchesSpecN(UInt32 lenLimit, UInt32 pos, const Byte *cur, CLzRef *son, UInt32 _cyclicBufferPos, UInt32 _cyclicBufferSize, UInt32 _cutValue, UInt32 *_distances, UInt32 _maxLen, const UInt32 *hash, Int32 limit, UInt32 size, UInt32 *posRes) { do { UInt32 *distances = _distances + 1; UInt32 curMatch = pos - *hash++; CLzRef *ptr0 = son + (_cyclicBufferPos << 1) + 1; CLzRef *ptr1 = son + (_cyclicBufferPos << 1); UInt32 len0 = 0, len1 = 0; UInt32 cutValue = _cutValue; UInt32 maxLen = _maxLen; for (;;) { UInt32 delta = pos - curMatch; if (cutValue-- == 0 || delta >= _cyclicBufferSize) { *ptr0 = *ptr1 = kEmptyHashValue; break; } { CLzRef *pair = son + ((_cyclicBufferPos - delta + ((delta > _cyclicBufferPos) ? _cyclicBufferSize : 0)) << 1); const Byte *pb = cur - delta; UInt32 len = (len0 < len1 ? len0 : len1); if (pb[len] == cur[len]) { if (++len != lenLimit && pb[len] == cur[len]) while (++len != lenLimit) if (pb[len] != cur[len]) break; if (maxLen < len) { *distances++ = maxLen = len; *distances++ = delta - 1; if (len == lenLimit) { *ptr1 = pair[0]; *ptr0 = pair[1]; break; } } } if (pb[len] < cur[len]) { *ptr1 = curMatch; ptr1 = pair + 1; curMatch = *ptr1; len1 = len; } else { *ptr0 = curMatch; ptr0 = pair; curMatch = *ptr0; len0 = len; } } } pos++; _cyclicBufferPos++; cur++; { UInt32 num = (UInt32)(distances - _distances); *_distances = num - 1; _distances += num; limit -= num; } } while (limit > 0 && --size != 0); *posRes = pos; return limit; } #endif void BtGetMatches(CMatchFinderMt *p, UInt32 *distances) { UInt32 numProcessed = 0; UInt32 curPos = 2; UInt32 limit = kMtBtBlockSize - (p->matchMaxLen * 2); distances[1] = p->hashNumAvail; while (curPos < limit) { if (p->hashBufPos == p->hashBufPosLimit) { MatchFinderMt_GetNextBlock_Hash(p); distances[1] = numProcessed + p->hashNumAvail; if (p->hashNumAvail >= p->numHashBytes) continue; for (; p->hashNumAvail != 0; p->hashNumAvail--) distances[curPos++] = 0; break; } { UInt32 size = p->hashBufPosLimit - p->hashBufPos; UInt32 lenLimit = p->matchMaxLen; UInt32 pos = p->pos; UInt32 cyclicBufferPos = p->cyclicBufferPos; if (lenLimit >= p->hashNumAvail) lenLimit = p->hashNumAvail; { UInt32 size2 = p->hashNumAvail - lenLimit + 1; if (size2 < size) size = size2; size2 = p->cyclicBufferSize - cyclicBufferPos; if (size2 < size) size = size2; } #ifndef MFMT_GM_INLINE while (curPos < limit && size-- != 0) { UInt32 *startDistances = distances + curPos; UInt32 num = (UInt32)(GetMatchesSpec1(lenLimit, pos - p->hashBuf[p->hashBufPos++], pos, p->buffer, p->son, cyclicBufferPos, p->cyclicBufferSize, p->cutValue, startDistances + 1, p->numHashBytes - 1) - startDistances); *startDistances = num - 1; curPos += num; cyclicBufferPos++; pos++; p->buffer++; } #else { UInt32 posRes; curPos = limit - GetMatchesSpecN(lenLimit, pos, p->buffer, p->son, cyclicBufferPos, p->cyclicBufferSize, p->cutValue, distances + curPos, p->numHashBytes - 1, p->hashBuf + p->hashBufPos, (Int32)(limit - curPos) , size, &posRes); p->hashBufPos += posRes - pos; cyclicBufferPos += posRes - pos; p->buffer += posRes - pos; pos = posRes; } #endif numProcessed += pos - p->pos; p->hashNumAvail -= pos - p->pos; p->pos = pos; if (cyclicBufferPos == p->cyclicBufferSize) cyclicBufferPos = 0; p->cyclicBufferPos = cyclicBufferPos; } } distances[0] = curPos; } void BtFillBlock(CMatchFinderMt *p, UInt32 globalBlockIndex) { CMtSync *sync = &p->hashSync; if (!sync->needStart) { CriticalSection_Enter(&sync->cs); sync->csWasEntered = True; } BtGetMatches(p, p->btBuf + (globalBlockIndex & kMtBtNumBlocksMask) * kMtBtBlockSize); if (p->pos > kMtMaxValForNormalize - kMtBtBlockSize) { UInt32 subValue = p->pos - p->cyclicBufferSize; MatchFinder_Normalize3(subValue, p->son, p->cyclicBufferSize * 2); p->pos -= subValue; } if (!sync->needStart) { CriticalSection_Leave(&sync->cs); sync->csWasEntered = False; } } void BtThreadFunc(CMatchFinderMt *mt) { CMtSync *p = &mt->btSync; for (;;) { UInt32 blockIndex = 0; Event_Wait(&p->canStart); Event_Set(&p->wasStarted); for (;;) { if (p->exit) return; if (p->stopWriting) { p->numProcessedBlocks = blockIndex; MtSync_StopWriting(&mt->hashSync); Event_Set(&p->wasStopped); break; } Semaphore_Wait(&p->freeSemaphore); BtFillBlock(mt, blockIndex++); Semaphore_Release1(&p->filledSemaphore); } } } void MatchFinderMt_Construct(CMatchFinderMt *p) { p->hashBuf = 0; MtSync_Construct(&p->hashSync); MtSync_Construct(&p->btSync); } void MatchFinderMt_FreeMem(CMatchFinderMt *p, ISzAlloc *alloc) { alloc->Free(alloc, p->hashBuf); p->hashBuf = 0; } void MatchFinderMt_Destruct(CMatchFinderMt *p, ISzAlloc *alloc) { MtSync_Destruct(&p->hashSync); MtSync_Destruct(&p->btSync); MatchFinderMt_FreeMem(p, alloc); } #define kHashBufferSize (kMtHashBlockSize * kMtHashNumBlocks) #define kBtBufferSize (kMtBtBlockSize * kMtBtNumBlocks) static unsigned MY_STD_CALL HashThreadFunc2(void *p) { HashThreadFunc((CMatchFinderMt *)p); return 0; } static unsigned MY_STD_CALL BtThreadFunc2(void *p) { Byte allocaDummy[0x180]; int i = 0; for (i = 0; i < 16; i++) allocaDummy[i] = (Byte)i; BtThreadFunc((CMatchFinderMt *)p); return 0; } SRes MatchFinderMt_Create(CMatchFinderMt *p, UInt32 historySize, UInt32 keepAddBufferBefore, UInt32 matchMaxLen, UInt32 keepAddBufferAfter, ISzAlloc *alloc) { CMatchFinder *mf = p->MatchFinder; p->historySize = historySize; if (kMtBtBlockSize <= matchMaxLen * 4) return SZ_ERROR_PARAM; if (p->hashBuf == 0) { p->hashBuf = (UInt32 *)alloc->Alloc(alloc, (kHashBufferSize + kBtBufferSize) * sizeof(UInt32)); if (p->hashBuf == 0) return SZ_ERROR_MEM; p->btBuf = p->hashBuf + kHashBufferSize; } keepAddBufferBefore += (kHashBufferSize + kBtBufferSize); keepAddBufferAfter += kMtHashBlockSize; if (!MatchFinder_Create(mf, historySize, keepAddBufferBefore, matchMaxLen, keepAddBufferAfter, alloc)) return SZ_ERROR_MEM; RINOK(MtSync_Create(&p->hashSync, HashThreadFunc2, p, kMtHashNumBlocks)); RINOK(MtSync_Create(&p->btSync, BtThreadFunc2, p, kMtBtNumBlocks)); return SZ_OK; } /* Call it after ReleaseStream / SetStream */ void MatchFinderMt_Init(CMatchFinderMt *p) { CMatchFinder *mf = p->MatchFinder; p->btBufPos = p->btBufPosLimit = 0; p->hashBufPos = p->hashBufPosLimit = 0; MatchFinder_Init(mf); p->pointerToCurPos = MatchFinder_GetPointerToCurrentPos(mf); p->btNumAvailBytes = 0; p->lzPos = p->historySize + 1; p->hash = mf->hash; p->fixedHashSize = mf->fixedHashSize; p->crc = mf->crc; p->son = mf->son; p->matchMaxLen = mf->matchMaxLen; p->numHashBytes = mf->numHashBytes; p->pos = mf->pos; p->buffer = mf->buffer; p->cyclicBufferPos = mf->cyclicBufferPos; p->cyclicBufferSize = mf->cyclicBufferSize; p->cutValue = mf->cutValue; } /* ReleaseStream is required to finish multithreading */ void MatchFinderMt_ReleaseStream(CMatchFinderMt *p) { MtSync_StopWriting(&p->btSync); /* p->MatchFinder->ReleaseStream(); */ } void MatchFinderMt_Normalize(CMatchFinderMt *p) { MatchFinder_Normalize3(p->lzPos - p->historySize - 1, p->hash, p->fixedHashSize); p->lzPos = p->historySize + 1; } void MatchFinderMt_GetNextBlock_Bt(CMatchFinderMt *p) { UInt32 blockIndex; MtSync_GetNextBlock(&p->btSync); blockIndex = ((p->btSync.numProcessedBlocks - 1) & kMtBtNumBlocksMask); p->btBufPosLimit = p->btBufPos = blockIndex * kMtBtBlockSize; p->btBufPosLimit += p->btBuf[p->btBufPos++]; p->btNumAvailBytes = p->btBuf[p->btBufPos++]; if (p->lzPos >= kMtMaxValForNormalize - kMtBtBlockSize) MatchFinderMt_Normalize(p); } const Byte * MatchFinderMt_GetPointerToCurrentPos(CMatchFinderMt *p) { return p->pointerToCurPos; } #define GET_NEXT_BLOCK_IF_REQUIRED if (p->btBufPos == p->btBufPosLimit) MatchFinderMt_GetNextBlock_Bt(p); UInt32 MatchFinderMt_GetNumAvailableBytes(CMatchFinderMt *p) { GET_NEXT_BLOCK_IF_REQUIRED; return p->btNumAvailBytes; } Byte MatchFinderMt_GetIndexByte(CMatchFinderMt *p, Int32 index) { return p->pointerToCurPos[index]; } UInt32 * MixMatches2(CMatchFinderMt *p, UInt32 matchMinPos, UInt32 *distances) { UInt32 hash2Value, curMatch2; UInt32 *hash = p->hash; const Byte *cur = p->pointerToCurPos; UInt32 lzPos = p->lzPos; MT_HASH2_CALC curMatch2 = hash[hash2Value]; hash[hash2Value] = lzPos; if (curMatch2 >= matchMinPos) if (cur[(ptrdiff_t)curMatch2 - lzPos] == cur[0]) { *distances++ = 2; *distances++ = lzPos - curMatch2 - 1; } return distances; } UInt32 * MixMatches3(CMatchFinderMt *p, UInt32 matchMinPos, UInt32 *distances) { UInt32 hash2Value, hash3Value, curMatch2, curMatch3; UInt32 *hash = p->hash; const Byte *cur = p->pointerToCurPos; UInt32 lzPos = p->lzPos; MT_HASH3_CALC curMatch2 = hash[ hash2Value]; curMatch3 = hash[kFix3HashSize + hash3Value]; hash[ hash2Value] = hash[kFix3HashSize + hash3Value] = lzPos; if (curMatch2 >= matchMinPos && cur[(ptrdiff_t)curMatch2 - lzPos] == cur[0]) { distances[1] = lzPos - curMatch2 - 1; if (cur[(ptrdiff_t)curMatch2 - lzPos + 2] == cur[2]) { distances[0] = 3; return distances + 2; } distances[0] = 2; distances += 2; } if (curMatch3 >= matchMinPos && cur[(ptrdiff_t)curMatch3 - lzPos] == cur[0]) { *distances++ = 3; *distances++ = lzPos - curMatch3 - 1; } return distances; } /* UInt32 *MixMatches4(CMatchFinderMt *p, UInt32 matchMinPos, UInt32 *distances) { UInt32 hash2Value, hash3Value, hash4Value, curMatch2, curMatch3, curMatch4; UInt32 *hash = p->hash; const Byte *cur = p->pointerToCurPos; UInt32 lzPos = p->lzPos; MT_HASH4_CALC curMatch2 = hash[ hash2Value]; curMatch3 = hash[kFix3HashSize + hash3Value]; curMatch4 = hash[kFix4HashSize + hash4Value]; hash[ hash2Value] = hash[kFix3HashSize + hash3Value] = hash[kFix4HashSize + hash4Value] = lzPos; if (curMatch2 >= matchMinPos && cur[(ptrdiff_t)curMatch2 - lzPos] == cur[0]) { distances[1] = lzPos - curMatch2 - 1; if (cur[(ptrdiff_t)curMatch2 - lzPos + 2] == cur[2]) { distances[0] = (cur[(ptrdiff_t)curMatch2 - lzPos + 3] == cur[3]) ? 4 : 3; return distances + 2; } distances[0] = 2; distances += 2; } if (curMatch3 >= matchMinPos && cur[(ptrdiff_t)curMatch3 - lzPos] == cur[0]) { distances[1] = lzPos - curMatch3 - 1; if (cur[(ptrdiff_t)curMatch3 - lzPos + 3] == cur[3]) { distances[0] = 4; return distances + 2; } distances[0] = 3; distances += 2; } if (curMatch4 >= matchMinPos) if ( cur[(ptrdiff_t)curMatch4 - lzPos] == cur[0] && cur[(ptrdiff_t)curMatch4 - lzPos + 3] == cur[3] ) { *distances++ = 4; *distances++ = lzPos - curMatch4 - 1; } return distances; } */ #define INCREASE_LZ_POS p->lzPos++; p->pointerToCurPos++; UInt32 MatchFinderMt2_GetMatches(CMatchFinderMt *p, UInt32 *distances) { const UInt32 *btBuf = p->btBuf + p->btBufPos; UInt32 len = *btBuf++; p->btBufPos += 1 + len; p->btNumAvailBytes--; { UInt32 i; for (i = 0; i < len; i += 2) { *distances++ = *btBuf++; *distances++ = *btBuf++; } } INCREASE_LZ_POS return len; } UInt32 MatchFinderMt_GetMatches(CMatchFinderMt *p, UInt32 *distances) { const UInt32 *btBuf = p->btBuf + p->btBufPos; UInt32 len = *btBuf++; p->btBufPos += 1 + len; if (len == 0) { if (p->btNumAvailBytes-- >= 4) len = (UInt32)(p->MixMatchesFunc(p, p->lzPos - p->historySize, distances) - (distances)); } else { /* Condition: there are matches in btBuf with length < p->numHashBytes */ UInt32 *distances2; p->btNumAvailBytes--; distances2 = p->MixMatchesFunc(p, p->lzPos - btBuf[1], distances); do { *distances2++ = *btBuf++; *distances2++ = *btBuf++; } while ((len -= 2) != 0); len = (UInt32)(distances2 - (distances)); } INCREASE_LZ_POS return len; } #define SKIP_HEADER2 do { GET_NEXT_BLOCK_IF_REQUIRED #define SKIP_HEADER(n) SKIP_HEADER2 if (p->btNumAvailBytes-- >= (n)) { const Byte *cur = p->pointerToCurPos; UInt32 *hash = p->hash; #define SKIP_FOOTER } INCREASE_LZ_POS p->btBufPos += p->btBuf[p->btBufPos] + 1; } while (--num != 0); void MatchFinderMt0_Skip(CMatchFinderMt *p, UInt32 num) { SKIP_HEADER2 { p->btNumAvailBytes--; SKIP_FOOTER } void MatchFinderMt2_Skip(CMatchFinderMt *p, UInt32 num) { SKIP_HEADER(2) UInt32 hash2Value; MT_HASH2_CALC hash[hash2Value] = p->lzPos; SKIP_FOOTER } void MatchFinderMt3_Skip(CMatchFinderMt *p, UInt32 num) { SKIP_HEADER(3) UInt32 hash2Value, hash3Value; MT_HASH3_CALC hash[kFix3HashSize + hash3Value] = hash[ hash2Value] = p->lzPos; SKIP_FOOTER } /* void MatchFinderMt4_Skip(CMatchFinderMt *p, UInt32 num) { SKIP_HEADER(4) UInt32 hash2Value, hash3Value, hash4Value; MT_HASH4_CALC hash[kFix4HashSize + hash4Value] = hash[kFix3HashSize + hash3Value] = hash[ hash2Value] = p->lzPos; SKIP_FOOTER } */ void MatchFinderMt_CreateVTable(CMatchFinderMt *p, IMatchFinder *vTable) { vTable->Init = (Mf_Init_Func)MatchFinderMt_Init; vTable->GetIndexByte = (Mf_GetIndexByte_Func)MatchFinderMt_GetIndexByte; vTable->GetNumAvailableBytes = (Mf_GetNumAvailableBytes_Func)MatchFinderMt_GetNumAvailableBytes; vTable->GetPointerToCurrentPos = (Mf_GetPointerToCurrentPos_Func)MatchFinderMt_GetPointerToCurrentPos; vTable->GetMatches = (Mf_GetMatches_Func)MatchFinderMt_GetMatches; switch(p->MatchFinder->numHashBytes) { case 2: p->GetHeadsFunc = GetHeads2; p->MixMatchesFunc = (Mf_Mix_Matches)0; vTable->Skip = (Mf_Skip_Func)MatchFinderMt0_Skip; vTable->GetMatches = (Mf_GetMatches_Func)MatchFinderMt2_GetMatches; break; case 3: p->GetHeadsFunc = GetHeads3; p->MixMatchesFunc = (Mf_Mix_Matches)MixMatches2; vTable->Skip = (Mf_Skip_Func)MatchFinderMt2_Skip; break; default: /* case 4: */ p->GetHeadsFunc = p->MatchFinder->bigHash ? GetHeads4b : GetHeads4; /* p->GetHeadsFunc = GetHeads4; */ p->MixMatchesFunc = (Mf_Mix_Matches)MixMatches3; vTable->Skip = (Mf_Skip_Func)MatchFinderMt3_Skip; break; /* default: p->GetHeadsFunc = GetHeads5; p->MixMatchesFunc = (Mf_Mix_Matches)MixMatches4; vTable->Skip = (Mf_Skip_Func)MatchFinderMt4_Skip; break; */ } }