561 lines
16 KiB
C
561 lines
16 KiB
C
/*
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** 2014 August 11
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**
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** The author disclaims copyright to this source code. In place of
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** a legal notice, here is a blessing:
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**
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** May you do good and not evil.
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** May you find forgiveness for yourself and forgive others.
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** May you share freely, never taking more than you give.
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**
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******************************************************************************
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**
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*/
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#include "fts5Int.h"
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typedef struct Fts5HashEntry Fts5HashEntry;
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/*
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** This file contains the implementation of an in-memory hash table used
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** to accumuluate "term -> doclist" content before it is flused to a level-0
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** segment.
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*/
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struct Fts5Hash {
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int eDetail; /* Copy of Fts5Config.eDetail */
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int *pnByte; /* Pointer to bytes counter */
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int nEntry; /* Number of entries currently in hash */
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int nSlot; /* Size of aSlot[] array */
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Fts5HashEntry *pScan; /* Current ordered scan item */
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Fts5HashEntry **aSlot; /* Array of hash slots */
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};
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/*
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** Each entry in the hash table is represented by an object of the
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** following type. Each object, its key (a nul-terminated string) and
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** its current data are stored in a single memory allocation. The
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** key immediately follows the object in memory. The position list
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** data immediately follows the key data in memory.
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**
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** The data that follows the key is in a similar, but not identical format
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** to the doclist data stored in the database. It is:
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**
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** * Rowid, as a varint
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** * Position list, without 0x00 terminator.
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** * Size of previous position list and rowid, as a 4 byte
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** big-endian integer.
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**
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** iRowidOff:
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** Offset of last rowid written to data area. Relative to first byte of
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** structure.
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**
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** nData:
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** Bytes of data written since iRowidOff.
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*/
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struct Fts5HashEntry {
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Fts5HashEntry *pHashNext; /* Next hash entry with same hash-key */
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Fts5HashEntry *pScanNext; /* Next entry in sorted order */
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int nAlloc; /* Total size of allocation */
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int iSzPoslist; /* Offset of space for 4-byte poslist size */
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int nData; /* Total bytes of data (incl. structure) */
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int nKey; /* Length of key in bytes */
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u8 bDel; /* Set delete-flag @ iSzPoslist */
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u8 bContent; /* Set content-flag (detail=none mode) */
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i16 iCol; /* Column of last value written */
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int iPos; /* Position of last value written */
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i64 iRowid; /* Rowid of last value written */
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};
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/*
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** Eqivalent to:
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**
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** char *fts5EntryKey(Fts5HashEntry *pEntry){ return zKey; }
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*/
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#define fts5EntryKey(p) ( ((char *)(&(p)[1])) )
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/*
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** Allocate a new hash table.
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*/
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int sqlite3Fts5HashNew(Fts5Config *pConfig, Fts5Hash **ppNew, int *pnByte){
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int rc = SQLITE_OK;
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Fts5Hash *pNew;
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*ppNew = pNew = (Fts5Hash*)sqlite3_malloc(sizeof(Fts5Hash));
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if( pNew==0 ){
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rc = SQLITE_NOMEM;
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}else{
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sqlite3_int64 nByte;
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memset(pNew, 0, sizeof(Fts5Hash));
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pNew->pnByte = pnByte;
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pNew->eDetail = pConfig->eDetail;
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pNew->nSlot = 1024;
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nByte = sizeof(Fts5HashEntry*) * pNew->nSlot;
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pNew->aSlot = (Fts5HashEntry**)sqlite3_malloc64(nByte);
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if( pNew->aSlot==0 ){
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sqlite3_free(pNew);
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*ppNew = 0;
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rc = SQLITE_NOMEM;
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}else{
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memset(pNew->aSlot, 0, (size_t)nByte);
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}
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}
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return rc;
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}
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/*
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** Free a hash table object.
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*/
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void sqlite3Fts5HashFree(Fts5Hash *pHash){
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if( pHash ){
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sqlite3Fts5HashClear(pHash);
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sqlite3_free(pHash->aSlot);
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sqlite3_free(pHash);
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}
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}
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/*
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** Empty (but do not delete) a hash table.
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*/
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void sqlite3Fts5HashClear(Fts5Hash *pHash){
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int i;
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for(i=0; i<pHash->nSlot; i++){
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Fts5HashEntry *pNext;
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Fts5HashEntry *pSlot;
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for(pSlot=pHash->aSlot[i]; pSlot; pSlot=pNext){
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pNext = pSlot->pHashNext;
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sqlite3_free(pSlot);
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}
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}
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memset(pHash->aSlot, 0, pHash->nSlot * sizeof(Fts5HashEntry*));
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pHash->nEntry = 0;
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}
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static unsigned int fts5HashKey(int nSlot, const u8 *p, int n){
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int i;
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unsigned int h = 13;
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for(i=n-1; i>=0; i--){
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h = (h << 3) ^ h ^ p[i];
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}
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return (h % nSlot);
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}
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static unsigned int fts5HashKey2(int nSlot, u8 b, const u8 *p, int n){
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int i;
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unsigned int h = 13;
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for(i=n-1; i>=0; i--){
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h = (h << 3) ^ h ^ p[i];
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}
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h = (h << 3) ^ h ^ b;
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return (h % nSlot);
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}
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/*
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** Resize the hash table by doubling the number of slots.
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*/
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static int fts5HashResize(Fts5Hash *pHash){
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int nNew = pHash->nSlot*2;
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int i;
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Fts5HashEntry **apNew;
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Fts5HashEntry **apOld = pHash->aSlot;
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apNew = (Fts5HashEntry**)sqlite3_malloc64(nNew*sizeof(Fts5HashEntry*));
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if( !apNew ) return SQLITE_NOMEM;
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memset(apNew, 0, nNew*sizeof(Fts5HashEntry*));
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for(i=0; i<pHash->nSlot; i++){
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while( apOld[i] ){
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unsigned int iHash;
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Fts5HashEntry *p = apOld[i];
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apOld[i] = p->pHashNext;
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iHash = fts5HashKey(nNew, (u8*)fts5EntryKey(p),
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(int)strlen(fts5EntryKey(p)));
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p->pHashNext = apNew[iHash];
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apNew[iHash] = p;
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}
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}
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sqlite3_free(apOld);
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pHash->nSlot = nNew;
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pHash->aSlot = apNew;
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return SQLITE_OK;
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}
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static int fts5HashAddPoslistSize(
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Fts5Hash *pHash,
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Fts5HashEntry *p,
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Fts5HashEntry *p2
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){
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int nRet = 0;
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if( p->iSzPoslist ){
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u8 *pPtr = p2 ? (u8*)p2 : (u8*)p;
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int nData = p->nData;
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if( pHash->eDetail==FTS5_DETAIL_NONE ){
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assert( nData==p->iSzPoslist );
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if( p->bDel ){
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pPtr[nData++] = 0x00;
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if( p->bContent ){
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pPtr[nData++] = 0x00;
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}
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}
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}else{
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int nSz = (nData - p->iSzPoslist - 1); /* Size in bytes */
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int nPos = nSz*2 + p->bDel; /* Value of nPos field */
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assert( p->bDel==0 || p->bDel==1 );
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if( nPos<=127 ){
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pPtr[p->iSzPoslist] = (u8)nPos;
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}else{
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int nByte = sqlite3Fts5GetVarintLen((u32)nPos);
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memmove(&pPtr[p->iSzPoslist + nByte], &pPtr[p->iSzPoslist + 1], nSz);
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sqlite3Fts5PutVarint(&pPtr[p->iSzPoslist], nPos);
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nData += (nByte-1);
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}
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}
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nRet = nData - p->nData;
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if( p2==0 ){
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p->iSzPoslist = 0;
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p->bDel = 0;
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p->bContent = 0;
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p->nData = nData;
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}
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}
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return nRet;
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}
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/*
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** Add an entry to the in-memory hash table. The key is the concatenation
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** of bByte and (pToken/nToken). The value is (iRowid/iCol/iPos).
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**
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** (bByte || pToken) -> (iRowid,iCol,iPos)
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**
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** Or, if iCol is negative, then the value is a delete marker.
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*/
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int sqlite3Fts5HashWrite(
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Fts5Hash *pHash,
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i64 iRowid, /* Rowid for this entry */
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int iCol, /* Column token appears in (-ve -> delete) */
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int iPos, /* Position of token within column */
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char bByte, /* First byte of token */
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const char *pToken, int nToken /* Token to add or remove to or from index */
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){
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unsigned int iHash;
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Fts5HashEntry *p;
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u8 *pPtr;
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int nIncr = 0; /* Amount to increment (*pHash->pnByte) by */
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int bNew; /* If non-delete entry should be written */
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bNew = (pHash->eDetail==FTS5_DETAIL_FULL);
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/* Attempt to locate an existing hash entry */
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iHash = fts5HashKey2(pHash->nSlot, (u8)bByte, (const u8*)pToken, nToken);
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for(p=pHash->aSlot[iHash]; p; p=p->pHashNext){
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char *zKey = fts5EntryKey(p);
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if( zKey[0]==bByte
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&& p->nKey==nToken
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&& memcmp(&zKey[1], pToken, nToken)==0
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){
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break;
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}
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}
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/* If an existing hash entry cannot be found, create a new one. */
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if( p==0 ){
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/* Figure out how much space to allocate */
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char *zKey;
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sqlite3_int64 nByte = sizeof(Fts5HashEntry) + (nToken+1) + 1 + 64;
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if( nByte<128 ) nByte = 128;
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/* Grow the Fts5Hash.aSlot[] array if necessary. */
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if( (pHash->nEntry*2)>=pHash->nSlot ){
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int rc = fts5HashResize(pHash);
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if( rc!=SQLITE_OK ) return rc;
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iHash = fts5HashKey2(pHash->nSlot, (u8)bByte, (const u8*)pToken, nToken);
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}
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/* Allocate new Fts5HashEntry and add it to the hash table. */
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p = (Fts5HashEntry*)sqlite3_malloc64(nByte);
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if( !p ) return SQLITE_NOMEM;
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memset(p, 0, sizeof(Fts5HashEntry));
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p->nAlloc = (int)nByte;
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zKey = fts5EntryKey(p);
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zKey[0] = bByte;
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memcpy(&zKey[1], pToken, nToken);
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assert( iHash==fts5HashKey(pHash->nSlot, (u8*)zKey, nToken+1) );
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p->nKey = nToken;
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zKey[nToken+1] = '\0';
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p->nData = nToken+1 + 1 + sizeof(Fts5HashEntry);
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p->pHashNext = pHash->aSlot[iHash];
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pHash->aSlot[iHash] = p;
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pHash->nEntry++;
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/* Add the first rowid field to the hash-entry */
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p->nData += sqlite3Fts5PutVarint(&((u8*)p)[p->nData], iRowid);
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p->iRowid = iRowid;
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p->iSzPoslist = p->nData;
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if( pHash->eDetail!=FTS5_DETAIL_NONE ){
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p->nData += 1;
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p->iCol = (pHash->eDetail==FTS5_DETAIL_FULL ? 0 : -1);
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}
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}else{
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/* Appending to an existing hash-entry. Check that there is enough
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** space to append the largest possible new entry. Worst case scenario
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** is:
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**
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** + 9 bytes for a new rowid,
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** + 4 byte reserved for the "poslist size" varint.
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** + 1 byte for a "new column" byte,
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** + 3 bytes for a new column number (16-bit max) as a varint,
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** + 5 bytes for the new position offset (32-bit max).
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*/
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if( (p->nAlloc - p->nData) < (9 + 4 + 1 + 3 + 5) ){
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sqlite3_int64 nNew = p->nAlloc * 2;
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Fts5HashEntry *pNew;
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Fts5HashEntry **pp;
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pNew = (Fts5HashEntry*)sqlite3_realloc64(p, nNew);
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if( pNew==0 ) return SQLITE_NOMEM;
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pNew->nAlloc = (int)nNew;
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for(pp=&pHash->aSlot[iHash]; *pp!=p; pp=&(*pp)->pHashNext);
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*pp = pNew;
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p = pNew;
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}
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nIncr -= p->nData;
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}
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assert( (p->nAlloc - p->nData) >= (9 + 4 + 1 + 3 + 5) );
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pPtr = (u8*)p;
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/* If this is a new rowid, append the 4-byte size field for the previous
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** entry, and the new rowid for this entry. */
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if( iRowid!=p->iRowid ){
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u64 iDiff = (u64)iRowid - (u64)p->iRowid;
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fts5HashAddPoslistSize(pHash, p, 0);
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p->nData += sqlite3Fts5PutVarint(&pPtr[p->nData], iDiff);
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p->iRowid = iRowid;
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bNew = 1;
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p->iSzPoslist = p->nData;
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if( pHash->eDetail!=FTS5_DETAIL_NONE ){
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p->nData += 1;
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p->iCol = (pHash->eDetail==FTS5_DETAIL_FULL ? 0 : -1);
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p->iPos = 0;
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}
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}
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if( iCol>=0 ){
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if( pHash->eDetail==FTS5_DETAIL_NONE ){
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p->bContent = 1;
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}else{
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/* Append a new column value, if necessary */
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assert( iCol>=p->iCol );
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if( iCol!=p->iCol ){
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if( pHash->eDetail==FTS5_DETAIL_FULL ){
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pPtr[p->nData++] = 0x01;
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p->nData += sqlite3Fts5PutVarint(&pPtr[p->nData], iCol);
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p->iCol = (i16)iCol;
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p->iPos = 0;
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}else{
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bNew = 1;
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p->iCol = (i16)(iPos = iCol);
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}
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}
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/* Append the new position offset, if necessary */
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if( bNew ){
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p->nData += sqlite3Fts5PutVarint(&pPtr[p->nData], iPos - p->iPos + 2);
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p->iPos = iPos;
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}
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}
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}else{
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/* This is a delete. Set the delete flag. */
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p->bDel = 1;
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}
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nIncr += p->nData;
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*pHash->pnByte += nIncr;
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return SQLITE_OK;
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}
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/*
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** Arguments pLeft and pRight point to linked-lists of hash-entry objects,
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** each sorted in key order. This function merges the two lists into a
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** single list and returns a pointer to its first element.
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*/
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static Fts5HashEntry *fts5HashEntryMerge(
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Fts5HashEntry *pLeft,
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Fts5HashEntry *pRight
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){
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Fts5HashEntry *p1 = pLeft;
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Fts5HashEntry *p2 = pRight;
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Fts5HashEntry *pRet = 0;
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Fts5HashEntry **ppOut = &pRet;
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while( p1 || p2 ){
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if( p1==0 ){
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*ppOut = p2;
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p2 = 0;
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}else if( p2==0 ){
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*ppOut = p1;
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p1 = 0;
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}else{
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int i = 0;
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char *zKey1 = fts5EntryKey(p1);
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char *zKey2 = fts5EntryKey(p2);
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while( zKey1[i]==zKey2[i] ) i++;
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if( ((u8)zKey1[i])>((u8)zKey2[i]) ){
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/* p2 is smaller */
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*ppOut = p2;
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ppOut = &p2->pScanNext;
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p2 = p2->pScanNext;
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}else{
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/* p1 is smaller */
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*ppOut = p1;
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ppOut = &p1->pScanNext;
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p1 = p1->pScanNext;
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}
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*ppOut = 0;
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}
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}
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return pRet;
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}
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/*
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** Extract all tokens from hash table iHash and link them into a list
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** in sorted order. The hash table is cleared before returning. It is
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** the responsibility of the caller to free the elements of the returned
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** list.
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*/
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static int fts5HashEntrySort(
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Fts5Hash *pHash,
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const char *pTerm, int nTerm, /* Query prefix, if any */
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Fts5HashEntry **ppSorted
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){
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const int nMergeSlot = 32;
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Fts5HashEntry **ap;
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Fts5HashEntry *pList;
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int iSlot;
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int i;
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*ppSorted = 0;
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ap = sqlite3_malloc64(sizeof(Fts5HashEntry*) * nMergeSlot);
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if( !ap ) return SQLITE_NOMEM;
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memset(ap, 0, sizeof(Fts5HashEntry*) * nMergeSlot);
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for(iSlot=0; iSlot<pHash->nSlot; iSlot++){
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Fts5HashEntry *pIter;
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for(pIter=pHash->aSlot[iSlot]; pIter; pIter=pIter->pHashNext){
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if( pTerm==0
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|| (pIter->nKey+1>=nTerm && 0==memcmp(fts5EntryKey(pIter), pTerm, nTerm))
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){
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Fts5HashEntry *pEntry = pIter;
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pEntry->pScanNext = 0;
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for(i=0; ap[i]; i++){
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pEntry = fts5HashEntryMerge(pEntry, ap[i]);
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ap[i] = 0;
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}
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ap[i] = pEntry;
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}
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}
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}
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pList = 0;
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for(i=0; i<nMergeSlot; i++){
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pList = fts5HashEntryMerge(pList, ap[i]);
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}
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pHash->nEntry = 0;
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sqlite3_free(ap);
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*ppSorted = pList;
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return SQLITE_OK;
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}
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/*
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** Query the hash table for a doclist associated with term pTerm/nTerm.
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*/
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int sqlite3Fts5HashQuery(
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Fts5Hash *pHash, /* Hash table to query */
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int nPre,
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|
const char *pTerm, int nTerm, /* Query term */
|
|
void **ppOut, /* OUT: Pointer to new object */
|
|
int *pnDoclist /* OUT: Size of doclist in bytes */
|
|
){
|
|
unsigned int iHash = fts5HashKey(pHash->nSlot, (const u8*)pTerm, nTerm);
|
|
char *zKey = 0;
|
|
Fts5HashEntry *p;
|
|
|
|
for(p=pHash->aSlot[iHash]; p; p=p->pHashNext){
|
|
zKey = fts5EntryKey(p);
|
|
assert( p->nKey+1==(int)strlen(zKey) );
|
|
if( nTerm==p->nKey+1 && memcmp(zKey, pTerm, nTerm)==0 ) break;
|
|
}
|
|
|
|
if( p ){
|
|
int nHashPre = sizeof(Fts5HashEntry) + nTerm + 1;
|
|
int nList = p->nData - nHashPre;
|
|
u8 *pRet = (u8*)(*ppOut = sqlite3_malloc64(nPre + nList + 10));
|
|
if( pRet ){
|
|
Fts5HashEntry *pFaux = (Fts5HashEntry*)&pRet[nPre-nHashPre];
|
|
memcpy(&pRet[nPre], &((u8*)p)[nHashPre], nList);
|
|
nList += fts5HashAddPoslistSize(pHash, p, pFaux);
|
|
*pnDoclist = nList;
|
|
}else{
|
|
*pnDoclist = 0;
|
|
return SQLITE_NOMEM;
|
|
}
|
|
}else{
|
|
*ppOut = 0;
|
|
*pnDoclist = 0;
|
|
}
|
|
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
int sqlite3Fts5HashScanInit(
|
|
Fts5Hash *p, /* Hash table to query */
|
|
const char *pTerm, int nTerm /* Query prefix */
|
|
){
|
|
return fts5HashEntrySort(p, pTerm, nTerm, &p->pScan);
|
|
}
|
|
|
|
void sqlite3Fts5HashScanNext(Fts5Hash *p){
|
|
assert( !sqlite3Fts5HashScanEof(p) );
|
|
p->pScan = p->pScan->pScanNext;
|
|
}
|
|
|
|
int sqlite3Fts5HashScanEof(Fts5Hash *p){
|
|
return (p->pScan==0);
|
|
}
|
|
|
|
void sqlite3Fts5HashScanEntry(
|
|
Fts5Hash *pHash,
|
|
const char **pzTerm, /* OUT: term (nul-terminated) */
|
|
const u8 **ppDoclist, /* OUT: pointer to doclist */
|
|
int *pnDoclist /* OUT: size of doclist in bytes */
|
|
){
|
|
Fts5HashEntry *p;
|
|
if( (p = pHash->pScan) ){
|
|
char *zKey = fts5EntryKey(p);
|
|
int nTerm = (int)strlen(zKey);
|
|
fts5HashAddPoslistSize(pHash, p, 0);
|
|
*pzTerm = zKey;
|
|
*ppDoclist = (const u8*)&zKey[nTerm+1];
|
|
*pnDoclist = p->nData - (sizeof(Fts5HashEntry) + nTerm + 1);
|
|
}else{
|
|
*pzTerm = 0;
|
|
*ppDoclist = 0;
|
|
*pnDoclist = 0;
|
|
}
|
|
}
|