/* ** 2014 May 31 ** ** The author disclaims copyright to this source code. In place of ** a legal notice, here is a blessing: ** ** May you do good and not evil. ** May you find forgiveness for yourself and forgive others. ** May you share freely, never taking more than you give. ** ****************************************************************************** ** */ #include "fts5Int.h" #include "fts5parse.h" #ifndef SQLITE_FTS5_MAX_EXPR_DEPTH # define SQLITE_FTS5_MAX_EXPR_DEPTH 256 #endif /* ** All token types in the generated fts5parse.h file are greater than 0. */ #define FTS5_EOF 0 #define FTS5_LARGEST_INT64 (0xffffffff|(((i64)0x7fffffff)<<32)) typedef struct Fts5ExprTerm Fts5ExprTerm; /* ** Functions generated by lemon from fts5parse.y. */ void *sqlite3Fts5ParserAlloc(void *(*mallocProc)(u64)); void sqlite3Fts5ParserFree(void*, void (*freeProc)(void*)); void sqlite3Fts5Parser(void*, int, Fts5Token, Fts5Parse*); #ifndef NDEBUG #include void sqlite3Fts5ParserTrace(FILE*, char*); #endif int sqlite3Fts5ParserFallback(int); struct Fts5Expr { Fts5Index *pIndex; Fts5Config *pConfig; Fts5ExprNode *pRoot; int bDesc; /* Iterate in descending rowid order */ int nPhrase; /* Number of phrases in expression */ Fts5ExprPhrase **apExprPhrase; /* Pointers to phrase objects */ }; /* ** eType: ** Expression node type. Always one of: ** ** FTS5_AND (nChild, apChild valid) ** FTS5_OR (nChild, apChild valid) ** FTS5_NOT (nChild, apChild valid) ** FTS5_STRING (pNear valid) ** FTS5_TERM (pNear valid) ** ** iHeight: ** Distance from this node to furthest leaf. This is always 0 for nodes ** of type FTS5_STRING and FTS5_TERM. For all other nodes it is one ** greater than the largest child value. */ struct Fts5ExprNode { int eType; /* Node type */ int bEof; /* True at EOF */ int bNomatch; /* True if entry is not a match */ int iHeight; /* Distance to tree leaf nodes */ /* Next method for this node. */ int (*xNext)(Fts5Expr*, Fts5ExprNode*, int, i64); i64 iRowid; /* Current rowid */ Fts5ExprNearset *pNear; /* For FTS5_STRING - cluster of phrases */ /* Child nodes. For a NOT node, this array always contains 2 entries. For ** AND or OR nodes, it contains 2 or more entries. */ int nChild; /* Number of child nodes */ Fts5ExprNode *apChild[1]; /* Array of child nodes */ }; #define Fts5NodeIsString(p) ((p)->eType==FTS5_TERM || (p)->eType==FTS5_STRING) /* ** Invoke the xNext method of an Fts5ExprNode object. This macro should be ** used as if it has the same signature as the xNext() methods themselves. */ #define fts5ExprNodeNext(a,b,c,d) (b)->xNext((a), (b), (c), (d)) /* ** An instance of the following structure represents a single search term ** or term prefix. */ struct Fts5ExprTerm { u8 bPrefix; /* True for a prefix term */ u8 bFirst; /* True if token must be first in column */ char *pTerm; /* Term data */ int nQueryTerm; /* Effective size of term in bytes */ int nFullTerm; /* Size of term in bytes incl. tokendata */ Fts5IndexIter *pIter; /* Iterator for this term */ Fts5ExprTerm *pSynonym; /* Pointer to first in list of synonyms */ }; /* ** A phrase. One or more terms that must appear in a contiguous sequence ** within a document for it to match. */ struct Fts5ExprPhrase { Fts5ExprNode *pNode; /* FTS5_STRING node this phrase is part of */ Fts5Buffer poslist; /* Current position list */ int nTerm; /* Number of entries in aTerm[] */ Fts5ExprTerm aTerm[1]; /* Terms that make up this phrase */ }; /* ** One or more phrases that must appear within a certain token distance of ** each other within each matching document. */ struct Fts5ExprNearset { int nNear; /* NEAR parameter */ Fts5Colset *pColset; /* Columns to search (NULL -> all columns) */ int nPhrase; /* Number of entries in aPhrase[] array */ Fts5ExprPhrase *apPhrase[1]; /* Array of phrase pointers */ }; /* ** Parse context. */ struct Fts5Parse { Fts5Config *pConfig; char *zErr; int rc; int nPhrase; /* Size of apPhrase array */ Fts5ExprPhrase **apPhrase; /* Array of all phrases */ Fts5ExprNode *pExpr; /* Result of a successful parse */ int bPhraseToAnd; /* Convert "a+b" to "a AND b" */ }; /* ** Check that the Fts5ExprNode.iHeight variables are set correctly in ** the expression tree passed as the only argument. */ #ifndef NDEBUG static void assert_expr_depth_ok(int rc, Fts5ExprNode *p){ if( rc==SQLITE_OK ){ if( p->eType==FTS5_TERM || p->eType==FTS5_STRING || p->eType==0 ){ assert( p->iHeight==0 ); }else{ int ii; int iMaxChild = 0; for(ii=0; iinChild; ii++){ Fts5ExprNode *pChild = p->apChild[ii]; iMaxChild = MAX(iMaxChild, pChild->iHeight); assert_expr_depth_ok(SQLITE_OK, pChild); } assert( p->iHeight==iMaxChild+1 ); } } } #else # define assert_expr_depth_ok(rc, p) #endif void sqlite3Fts5ParseError(Fts5Parse *pParse, const char *zFmt, ...){ va_list ap; va_start(ap, zFmt); if( pParse->rc==SQLITE_OK ){ assert( pParse->zErr==0 ); pParse->zErr = sqlite3_vmprintf(zFmt, ap); pParse->rc = SQLITE_ERROR; } va_end(ap); } static int fts5ExprIsspace(char t){ return t==' ' || t=='\t' || t=='\n' || t=='\r'; } /* ** Read the first token from the nul-terminated string at *pz. */ static int fts5ExprGetToken( Fts5Parse *pParse, const char **pz, /* IN/OUT: Pointer into buffer */ Fts5Token *pToken ){ const char *z = *pz; int tok; /* Skip past any whitespace */ while( fts5ExprIsspace(*z) ) z++; pToken->p = z; pToken->n = 1; switch( *z ){ case '(': tok = FTS5_LP; break; case ')': tok = FTS5_RP; break; case '{': tok = FTS5_LCP; break; case '}': tok = FTS5_RCP; break; case ':': tok = FTS5_COLON; break; case ',': tok = FTS5_COMMA; break; case '+': tok = FTS5_PLUS; break; case '*': tok = FTS5_STAR; break; case '-': tok = FTS5_MINUS; break; case '^': tok = FTS5_CARET; break; case '\0': tok = FTS5_EOF; break; case '"': { const char *z2; tok = FTS5_STRING; for(z2=&z[1]; 1; z2++){ if( z2[0]=='"' ){ z2++; if( z2[0]!='"' ) break; } if( z2[0]=='\0' ){ sqlite3Fts5ParseError(pParse, "unterminated string"); return FTS5_EOF; } } pToken->n = (z2 - z); break; } default: { const char *z2; if( sqlite3Fts5IsBareword(z[0])==0 ){ sqlite3Fts5ParseError(pParse, "fts5: syntax error near \"%.1s\"", z); return FTS5_EOF; } tok = FTS5_STRING; for(z2=&z[1]; sqlite3Fts5IsBareword(*z2); z2++); pToken->n = (z2 - z); if( pToken->n==2 && memcmp(pToken->p, "OR", 2)==0 ) tok = FTS5_OR; if( pToken->n==3 && memcmp(pToken->p, "NOT", 3)==0 ) tok = FTS5_NOT; if( pToken->n==3 && memcmp(pToken->p, "AND", 3)==0 ) tok = FTS5_AND; break; } } *pz = &pToken->p[pToken->n]; return tok; } static void *fts5ParseAlloc(u64 t){ return sqlite3_malloc64((sqlite3_int64)t);} static void fts5ParseFree(void *p){ sqlite3_free(p); } int sqlite3Fts5ExprNew( Fts5Config *pConfig, /* FTS5 Configuration */ int bPhraseToAnd, int iCol, const char *zExpr, /* Expression text */ Fts5Expr **ppNew, char **pzErr ){ Fts5Parse sParse; Fts5Token token; const char *z = zExpr; int t; /* Next token type */ void *pEngine; Fts5Expr *pNew; *ppNew = 0; *pzErr = 0; memset(&sParse, 0, sizeof(sParse)); sParse.bPhraseToAnd = bPhraseToAnd; pEngine = sqlite3Fts5ParserAlloc(fts5ParseAlloc); if( pEngine==0 ){ return SQLITE_NOMEM; } sParse.pConfig = pConfig; do { t = fts5ExprGetToken(&sParse, &z, &token); sqlite3Fts5Parser(pEngine, t, token, &sParse); }while( sParse.rc==SQLITE_OK && t!=FTS5_EOF ); sqlite3Fts5ParserFree(pEngine, fts5ParseFree); assert_expr_depth_ok(sParse.rc, sParse.pExpr); /* If the LHS of the MATCH expression was a user column, apply the ** implicit column-filter. */ if( iColnCol && sParse.pExpr && sParse.rc==SQLITE_OK ){ int n = sizeof(Fts5Colset); Fts5Colset *pColset = (Fts5Colset*)sqlite3Fts5MallocZero(&sParse.rc, n); if( pColset ){ pColset->nCol = 1; pColset->aiCol[0] = iCol; sqlite3Fts5ParseSetColset(&sParse, sParse.pExpr, pColset); } } assert( sParse.rc!=SQLITE_OK || sParse.zErr==0 ); if( sParse.rc==SQLITE_OK ){ *ppNew = pNew = sqlite3_malloc(sizeof(Fts5Expr)); if( pNew==0 ){ sParse.rc = SQLITE_NOMEM; sqlite3Fts5ParseNodeFree(sParse.pExpr); }else{ if( !sParse.pExpr ){ const int nByte = sizeof(Fts5ExprNode); pNew->pRoot = (Fts5ExprNode*)sqlite3Fts5MallocZero(&sParse.rc, nByte); if( pNew->pRoot ){ pNew->pRoot->bEof = 1; } }else{ pNew->pRoot = sParse.pExpr; } pNew->pIndex = 0; pNew->pConfig = pConfig; pNew->apExprPhrase = sParse.apPhrase; pNew->nPhrase = sParse.nPhrase; pNew->bDesc = 0; sParse.apPhrase = 0; } }else{ sqlite3Fts5ParseNodeFree(sParse.pExpr); } sqlite3_free(sParse.apPhrase); *pzErr = sParse.zErr; return sParse.rc; } /* ** Assuming that buffer z is at least nByte bytes in size and contains a ** valid utf-8 string, return the number of characters in the string. */ static int fts5ExprCountChar(const char *z, int nByte){ int nRet = 0; int ii; for(ii=0; ii=3 ){ int jj; zExpr[iOut++] = '"'; for(jj=iFirst; jj0 ){ int bAnd = 0; if( pConfig->eDetail!=FTS5_DETAIL_FULL ){ bAnd = 1; if( pConfig->eDetail==FTS5_DETAIL_NONE ){ iCol = pConfig->nCol; } } zExpr[iOut] = '\0'; rc = sqlite3Fts5ExprNew(pConfig, bAnd, iCol, zExpr, pp,pConfig->pzErrmsg); }else{ *pp = 0; } sqlite3_free(zExpr); } return rc; } /* ** Free the expression node object passed as the only argument. */ void sqlite3Fts5ParseNodeFree(Fts5ExprNode *p){ if( p ){ int i; for(i=0; inChild; i++){ sqlite3Fts5ParseNodeFree(p->apChild[i]); } sqlite3Fts5ParseNearsetFree(p->pNear); sqlite3_free(p); } } /* ** Free the expression object passed as the only argument. */ void sqlite3Fts5ExprFree(Fts5Expr *p){ if( p ){ sqlite3Fts5ParseNodeFree(p->pRoot); sqlite3_free(p->apExprPhrase); sqlite3_free(p); } } int sqlite3Fts5ExprAnd(Fts5Expr **pp1, Fts5Expr *p2){ Fts5Parse sParse; memset(&sParse, 0, sizeof(sParse)); if( *pp1 && p2 ){ Fts5Expr *p1 = *pp1; int nPhrase = p1->nPhrase + p2->nPhrase; p1->pRoot = sqlite3Fts5ParseNode(&sParse, FTS5_AND, p1->pRoot, p2->pRoot,0); p2->pRoot = 0; if( sParse.rc==SQLITE_OK ){ Fts5ExprPhrase **ap = (Fts5ExprPhrase**)sqlite3_realloc( p1->apExprPhrase, nPhrase * sizeof(Fts5ExprPhrase*) ); if( ap==0 ){ sParse.rc = SQLITE_NOMEM; }else{ int i; memmove(&ap[p2->nPhrase], ap, p1->nPhrase*sizeof(Fts5ExprPhrase*)); for(i=0; inPhrase; i++){ ap[i] = p2->apExprPhrase[i]; } p1->nPhrase = nPhrase; p1->apExprPhrase = ap; } } sqlite3_free(p2->apExprPhrase); sqlite3_free(p2); }else if( p2 ){ *pp1 = p2; } return sParse.rc; } /* ** Argument pTerm must be a synonym iterator. Return the current rowid ** that it points to. */ static i64 fts5ExprSynonymRowid(Fts5ExprTerm *pTerm, int bDesc, int *pbEof){ i64 iRet = 0; int bRetValid = 0; Fts5ExprTerm *p; assert( pTerm ); assert( pTerm->pSynonym ); assert( bDesc==0 || bDesc==1 ); for(p=pTerm; p; p=p->pSynonym){ if( 0==sqlite3Fts5IterEof(p->pIter) ){ i64 iRowid = p->pIter->iRowid; if( bRetValid==0 || (bDesc!=(iRowidpSynonym ); for(p=pTerm; p; p=p->pSynonym){ Fts5IndexIter *pIter = p->pIter; if( sqlite3Fts5IterEof(pIter)==0 && pIter->iRowid==iRowid ){ if( pIter->nData==0 ) continue; if( nIter==nAlloc ){ sqlite3_int64 nByte = sizeof(Fts5PoslistReader) * nAlloc * 2; Fts5PoslistReader *aNew = (Fts5PoslistReader*)sqlite3_malloc64(nByte); if( aNew==0 ){ rc = SQLITE_NOMEM; goto synonym_poslist_out; } memcpy(aNew, aIter, sizeof(Fts5PoslistReader) * nIter); nAlloc = nAlloc*2; if( aIter!=aStatic ) sqlite3_free(aIter); aIter = aNew; } sqlite3Fts5PoslistReaderInit(pIter->pData, pIter->nData, &aIter[nIter]); assert( aIter[nIter].bEof==0 ); nIter++; } } if( nIter==1 ){ *pa = (u8*)aIter[0].a; *pn = aIter[0].n; }else{ Fts5PoslistWriter writer = {0}; i64 iPrev = -1; fts5BufferZero(pBuf); while( 1 ){ int i; i64 iMin = FTS5_LARGEST_INT64; for(i=0; ip; *pn = pBuf->n; } } synonym_poslist_out: if( aIter!=aStatic ) sqlite3_free(aIter); return rc; } /* ** All individual term iterators in pPhrase are guaranteed to be valid and ** pointing to the same rowid when this function is called. This function ** checks if the current rowid really is a match, and if so populates ** the pPhrase->poslist buffer accordingly. Output parameter *pbMatch ** is set to true if this is really a match, or false otherwise. ** ** SQLITE_OK is returned if an error occurs, or an SQLite error code ** otherwise. It is not considered an error code if the current rowid is ** not a match. */ static int fts5ExprPhraseIsMatch( Fts5ExprNode *pNode, /* Node pPhrase belongs to */ Fts5ExprPhrase *pPhrase, /* Phrase object to initialize */ int *pbMatch /* OUT: Set to true if really a match */ ){ Fts5PoslistWriter writer = {0}; Fts5PoslistReader aStatic[4]; Fts5PoslistReader *aIter = aStatic; int i; int rc = SQLITE_OK; int bFirst = pPhrase->aTerm[0].bFirst; fts5BufferZero(&pPhrase->poslist); /* If the aStatic[] array is not large enough, allocate a large array ** using sqlite3_malloc(). This approach could be improved upon. */ if( pPhrase->nTerm>ArraySize(aStatic) ){ sqlite3_int64 nByte = sizeof(Fts5PoslistReader) * pPhrase->nTerm; aIter = (Fts5PoslistReader*)sqlite3_malloc64(nByte); if( !aIter ) return SQLITE_NOMEM; } memset(aIter, 0, sizeof(Fts5PoslistReader) * pPhrase->nTerm); /* Initialize a term iterator for each term in the phrase */ for(i=0; inTerm; i++){ Fts5ExprTerm *pTerm = &pPhrase->aTerm[i]; int n = 0; int bFlag = 0; u8 *a = 0; if( pTerm->pSynonym ){ Fts5Buffer buf = {0, 0, 0}; rc = fts5ExprSynonymList(pTerm, pNode->iRowid, &buf, &a, &n); if( rc ){ sqlite3_free(a); goto ismatch_out; } if( a==buf.p ) bFlag = 1; }else{ a = (u8*)pTerm->pIter->pData; n = pTerm->pIter->nData; } sqlite3Fts5PoslistReaderInit(a, n, &aIter[i]); aIter[i].bFlag = (u8)bFlag; if( aIter[i].bEof ) goto ismatch_out; } while( 1 ){ int bMatch; i64 iPos = aIter[0].iPos; do { bMatch = 1; for(i=0; inTerm; i++){ Fts5PoslistReader *pPos = &aIter[i]; i64 iAdj = iPos + i; if( pPos->iPos!=iAdj ){ bMatch = 0; while( pPos->iPosiPos>iAdj ) iPos = pPos->iPos-i; } } }while( bMatch==0 ); /* Append position iPos to the output */ if( bFirst==0 || FTS5_POS2OFFSET(iPos)==0 ){ rc = sqlite3Fts5PoslistWriterAppend(&pPhrase->poslist, &writer, iPos); if( rc!=SQLITE_OK ) goto ismatch_out; } for(i=0; inTerm; i++){ if( sqlite3Fts5PoslistReaderNext(&aIter[i]) ) goto ismatch_out; } } ismatch_out: *pbMatch = (pPhrase->poslist.n>0); for(i=0; inTerm; i++){ if( aIter[i].bFlag ) sqlite3_free((u8*)aIter[i].a); } if( aIter!=aStatic ) sqlite3_free(aIter); return rc; } typedef struct Fts5LookaheadReader Fts5LookaheadReader; struct Fts5LookaheadReader { const u8 *a; /* Buffer containing position list */ int n; /* Size of buffer a[] in bytes */ int i; /* Current offset in position list */ i64 iPos; /* Current position */ i64 iLookahead; /* Next position */ }; #define FTS5_LOOKAHEAD_EOF (((i64)1) << 62) static int fts5LookaheadReaderNext(Fts5LookaheadReader *p){ p->iPos = p->iLookahead; if( sqlite3Fts5PoslistNext64(p->a, p->n, &p->i, &p->iLookahead) ){ p->iLookahead = FTS5_LOOKAHEAD_EOF; } return (p->iPos==FTS5_LOOKAHEAD_EOF); } static int fts5LookaheadReaderInit( const u8 *a, int n, /* Buffer to read position list from */ Fts5LookaheadReader *p /* Iterator object to initialize */ ){ memset(p, 0, sizeof(Fts5LookaheadReader)); p->a = a; p->n = n; fts5LookaheadReaderNext(p); return fts5LookaheadReaderNext(p); } typedef struct Fts5NearTrimmer Fts5NearTrimmer; struct Fts5NearTrimmer { Fts5LookaheadReader reader; /* Input iterator */ Fts5PoslistWriter writer; /* Writer context */ Fts5Buffer *pOut; /* Output poslist */ }; /* ** The near-set object passed as the first argument contains more than ** one phrase. All phrases currently point to the same row. The ** Fts5ExprPhrase.poslist buffers are populated accordingly. This function ** tests if the current row contains instances of each phrase sufficiently ** close together to meet the NEAR constraint. Non-zero is returned if it ** does, or zero otherwise. ** ** If in/out parameter (*pRc) is set to other than SQLITE_OK when this ** function is called, it is a no-op. Or, if an error (e.g. SQLITE_NOMEM) ** occurs within this function (*pRc) is set accordingly before returning. ** The return value is undefined in both these cases. ** ** If no error occurs and non-zero (a match) is returned, the position-list ** of each phrase object is edited to contain only those entries that ** meet the constraint before returning. */ static int fts5ExprNearIsMatch(int *pRc, Fts5ExprNearset *pNear){ Fts5NearTrimmer aStatic[4]; Fts5NearTrimmer *a = aStatic; Fts5ExprPhrase **apPhrase = pNear->apPhrase; int i; int rc = *pRc; int bMatch; assert( pNear->nPhrase>1 ); /* If the aStatic[] array is not large enough, allocate a large array ** using sqlite3_malloc(). This approach could be improved upon. */ if( pNear->nPhrase>ArraySize(aStatic) ){ sqlite3_int64 nByte = sizeof(Fts5NearTrimmer) * pNear->nPhrase; a = (Fts5NearTrimmer*)sqlite3Fts5MallocZero(&rc, nByte); }else{ memset(aStatic, 0, sizeof(aStatic)); } if( rc!=SQLITE_OK ){ *pRc = rc; return 0; } /* Initialize a lookahead iterator for each phrase. After passing the ** buffer and buffer size to the lookaside-reader init function, zero ** the phrase poslist buffer. The new poslist for the phrase (containing ** the same entries as the original with some entries removed on account ** of the NEAR constraint) is written over the original even as it is ** being read. This is safe as the entries for the new poslist are a ** subset of the old, so it is not possible for data yet to be read to ** be overwritten. */ for(i=0; inPhrase; i++){ Fts5Buffer *pPoslist = &apPhrase[i]->poslist; fts5LookaheadReaderInit(pPoslist->p, pPoslist->n, &a[i].reader); pPoslist->n = 0; a[i].pOut = pPoslist; } while( 1 ){ int iAdv; i64 iMin; i64 iMax; /* This block advances the phrase iterators until they point to a set of ** entries that together comprise a match. */ iMax = a[0].reader.iPos; do { bMatch = 1; for(i=0; inPhrase; i++){ Fts5LookaheadReader *pPos = &a[i].reader; iMin = iMax - pNear->apPhrase[i]->nTerm - pNear->nNear; if( pPos->iPosiPos>iMax ){ bMatch = 0; while( pPos->iPosiPos>iMax ) iMax = pPos->iPos; } } }while( bMatch==0 ); /* Add an entry to each output position list */ for(i=0; inPhrase; i++){ i64 iPos = a[i].reader.iPos; Fts5PoslistWriter *pWriter = &a[i].writer; if( a[i].pOut->n==0 || iPos!=pWriter->iPrev ){ sqlite3Fts5PoslistWriterAppend(a[i].pOut, pWriter, iPos); } } iAdv = 0; iMin = a[0].reader.iLookahead; for(i=0; inPhrase; i++){ if( a[i].reader.iLookahead < iMin ){ iMin = a[i].reader.iLookahead; iAdv = i; } } if( fts5LookaheadReaderNext(&a[iAdv].reader) ) goto ismatch_out; } ismatch_out: { int bRet = a[0].pOut->n>0; *pRc = rc; if( a!=aStatic ) sqlite3_free(a); return bRet; } } /* ** Advance iterator pIter until it points to a value equal to or laster ** than the initial value of *piLast. If this means the iterator points ** to a value laster than *piLast, update *piLast to the new lastest value. ** ** If the iterator reaches EOF, set *pbEof to true before returning. If ** an error occurs, set *pRc to an error code. If either *pbEof or *pRc ** are set, return a non-zero value. Otherwise, return zero. */ static int fts5ExprAdvanceto( Fts5IndexIter *pIter, /* Iterator to advance */ int bDesc, /* True if iterator is "rowid DESC" */ i64 *piLast, /* IN/OUT: Lastest rowid seen so far */ int *pRc, /* OUT: Error code */ int *pbEof /* OUT: Set to true if EOF */ ){ i64 iLast = *piLast; i64 iRowid; iRowid = pIter->iRowid; if( (bDesc==0 && iLast>iRowid) || (bDesc && iLastiRowid; assert( (bDesc==0 && iRowid>=iLast) || (bDesc==1 && iRowid<=iLast) ); } *piLast = iRowid; return 0; } static int fts5ExprSynonymAdvanceto( Fts5ExprTerm *pTerm, /* Term iterator to advance */ int bDesc, /* True if iterator is "rowid DESC" */ i64 *piLast, /* IN/OUT: Lastest rowid seen so far */ int *pRc /* OUT: Error code */ ){ int rc = SQLITE_OK; i64 iLast = *piLast; Fts5ExprTerm *p; int bEof = 0; for(p=pTerm; rc==SQLITE_OK && p; p=p->pSynonym){ if( sqlite3Fts5IterEof(p->pIter)==0 ){ i64 iRowid = p->pIter->iRowid; if( (bDesc==0 && iLast>iRowid) || (bDesc && iLastpIter, iLast); } } } if( rc!=SQLITE_OK ){ *pRc = rc; bEof = 1; }else{ *piLast = fts5ExprSynonymRowid(pTerm, bDesc, &bEof); } return bEof; } static int fts5ExprNearTest( int *pRc, Fts5Expr *pExpr, /* Expression that pNear is a part of */ Fts5ExprNode *pNode /* The "NEAR" node (FTS5_STRING) */ ){ Fts5ExprNearset *pNear = pNode->pNear; int rc = *pRc; if( pExpr->pConfig->eDetail!=FTS5_DETAIL_FULL ){ Fts5ExprTerm *pTerm; Fts5ExprPhrase *pPhrase = pNear->apPhrase[0]; pPhrase->poslist.n = 0; for(pTerm=&pPhrase->aTerm[0]; pTerm; pTerm=pTerm->pSynonym){ Fts5IndexIter *pIter = pTerm->pIter; if( sqlite3Fts5IterEof(pIter)==0 ){ if( pIter->iRowid==pNode->iRowid && pIter->nData>0 ){ pPhrase->poslist.n = 1; } } } return pPhrase->poslist.n; }else{ int i; /* Check that each phrase in the nearset matches the current row. ** Populate the pPhrase->poslist buffers at the same time. If any ** phrase is not a match, break out of the loop early. */ for(i=0; rc==SQLITE_OK && inPhrase; i++){ Fts5ExprPhrase *pPhrase = pNear->apPhrase[i]; if( pPhrase->nTerm>1 || pPhrase->aTerm[0].pSynonym || pNear->pColset || pPhrase->aTerm[0].bFirst ){ int bMatch = 0; rc = fts5ExprPhraseIsMatch(pNode, pPhrase, &bMatch); if( bMatch==0 ) break; }else{ Fts5IndexIter *pIter = pPhrase->aTerm[0].pIter; fts5BufferSet(&rc, &pPhrase->poslist, pIter->nData, pIter->pData); } } *pRc = rc; if( i==pNear->nPhrase && (i==1 || fts5ExprNearIsMatch(pRc, pNear)) ){ return 1; } return 0; } } /* ** Initialize all term iterators in the pNear object. If any term is found ** to match no documents at all, return immediately without initializing any ** further iterators. ** ** If an error occurs, return an SQLite error code. Otherwise, return ** SQLITE_OK. It is not considered an error if some term matches zero ** documents. */ static int fts5ExprNearInitAll( Fts5Expr *pExpr, Fts5ExprNode *pNode ){ Fts5ExprNearset *pNear = pNode->pNear; int i; assert( pNode->bNomatch==0 ); for(i=0; inPhrase; i++){ Fts5ExprPhrase *pPhrase = pNear->apPhrase[i]; if( pPhrase->nTerm==0 ){ pNode->bEof = 1; return SQLITE_OK; }else{ int j; for(j=0; jnTerm; j++){ Fts5ExprTerm *pTerm = &pPhrase->aTerm[j]; Fts5ExprTerm *p; int bHit = 0; for(p=pTerm; p; p=p->pSynonym){ int rc; if( p->pIter ){ sqlite3Fts5IterClose(p->pIter); p->pIter = 0; } rc = sqlite3Fts5IndexQuery( pExpr->pIndex, p->pTerm, p->nQueryTerm, (pTerm->bPrefix ? FTS5INDEX_QUERY_PREFIX : 0) | (pExpr->bDesc ? FTS5INDEX_QUERY_DESC : 0), pNear->pColset, &p->pIter ); assert( (rc==SQLITE_OK)==(p->pIter!=0) ); if( rc!=SQLITE_OK ) return rc; if( 0==sqlite3Fts5IterEof(p->pIter) ){ bHit = 1; } } if( bHit==0 ){ pNode->bEof = 1; return SQLITE_OK; } } } } pNode->bEof = 0; return SQLITE_OK; } /* ** If pExpr is an ASC iterator, this function returns a value with the ** same sign as: ** ** (iLhs - iRhs) ** ** Otherwise, if this is a DESC iterator, the opposite is returned: ** ** (iRhs - iLhs) */ static int fts5RowidCmp( Fts5Expr *pExpr, i64 iLhs, i64 iRhs ){ assert( pExpr->bDesc==0 || pExpr->bDesc==1 ); if( pExpr->bDesc==0 ){ if( iLhs iRhs); }else{ if( iLhs>iRhs ) return -1; return (iLhs < iRhs); } } static void fts5ExprSetEof(Fts5ExprNode *pNode){ int i; pNode->bEof = 1; pNode->bNomatch = 0; for(i=0; inChild; i++){ fts5ExprSetEof(pNode->apChild[i]); } } static void fts5ExprNodeZeroPoslist(Fts5ExprNode *pNode){ if( pNode->eType==FTS5_STRING || pNode->eType==FTS5_TERM ){ Fts5ExprNearset *pNear = pNode->pNear; int i; for(i=0; inPhrase; i++){ Fts5ExprPhrase *pPhrase = pNear->apPhrase[i]; pPhrase->poslist.n = 0; } }else{ int i; for(i=0; inChild; i++){ fts5ExprNodeZeroPoslist(pNode->apChild[i]); } } } /* ** Compare the values currently indicated by the two nodes as follows: ** ** res = (*p1) - (*p2) ** ** Nodes that point to values that come later in the iteration order are ** considered to be larger. Nodes at EOF are the largest of all. ** ** This means that if the iteration order is ASC, then numerically larger ** rowids are considered larger. Or if it is the default DESC, numerically ** smaller rowids are larger. */ static int fts5NodeCompare( Fts5Expr *pExpr, Fts5ExprNode *p1, Fts5ExprNode *p2 ){ if( p2->bEof ) return -1; if( p1->bEof ) return +1; return fts5RowidCmp(pExpr, p1->iRowid, p2->iRowid); } /* ** All individual term iterators in pNear are guaranteed to be valid when ** this function is called. This function checks if all term iterators ** point to the same rowid, and if not, advances them until they do. ** If an EOF is reached before this happens, *pbEof is set to true before ** returning. ** ** SQLITE_OK is returned if an error occurs, or an SQLite error code ** otherwise. It is not considered an error code if an iterator reaches ** EOF. */ static int fts5ExprNodeTest_STRING( Fts5Expr *pExpr, /* Expression pPhrase belongs to */ Fts5ExprNode *pNode ){ Fts5ExprNearset *pNear = pNode->pNear; Fts5ExprPhrase *pLeft = pNear->apPhrase[0]; int rc = SQLITE_OK; i64 iLast; /* Lastest rowid any iterator points to */ int i, j; /* Phrase and token index, respectively */ int bMatch; /* True if all terms are at the same rowid */ const int bDesc = pExpr->bDesc; /* Check that this node should not be FTS5_TERM */ assert( pNear->nPhrase>1 || pNear->apPhrase[0]->nTerm>1 || pNear->apPhrase[0]->aTerm[0].pSynonym || pNear->apPhrase[0]->aTerm[0].bFirst ); /* Initialize iLast, the "lastest" rowid any iterator points to. If the ** iterator skips through rowids in the default ascending order, this means ** the maximum rowid. Or, if the iterator is "ORDER BY rowid DESC", then it ** means the minimum rowid. */ if( pLeft->aTerm[0].pSynonym ){ iLast = fts5ExprSynonymRowid(&pLeft->aTerm[0], bDesc, 0); }else{ iLast = pLeft->aTerm[0].pIter->iRowid; } do { bMatch = 1; for(i=0; inPhrase; i++){ Fts5ExprPhrase *pPhrase = pNear->apPhrase[i]; for(j=0; jnTerm; j++){ Fts5ExprTerm *pTerm = &pPhrase->aTerm[j]; if( pTerm->pSynonym ){ i64 iRowid = fts5ExprSynonymRowid(pTerm, bDesc, 0); if( iRowid==iLast ) continue; bMatch = 0; if( fts5ExprSynonymAdvanceto(pTerm, bDesc, &iLast, &rc) ){ pNode->bNomatch = 0; pNode->bEof = 1; return rc; } }else{ Fts5IndexIter *pIter = pPhrase->aTerm[j].pIter; if( pIter->iRowid==iLast || pIter->bEof ) continue; bMatch = 0; if( fts5ExprAdvanceto(pIter, bDesc, &iLast, &rc, &pNode->bEof) ){ return rc; } } } } }while( bMatch==0 ); pNode->iRowid = iLast; pNode->bNomatch = ((0==fts5ExprNearTest(&rc, pExpr, pNode)) && rc==SQLITE_OK); assert( pNode->bEof==0 || pNode->bNomatch==0 ); return rc; } /* ** Advance the first term iterator in the first phrase of pNear. Set output ** variable *pbEof to true if it reaches EOF or if an error occurs. ** ** Return SQLITE_OK if successful, or an SQLite error code if an error ** occurs. */ static int fts5ExprNodeNext_STRING( Fts5Expr *pExpr, /* Expression pPhrase belongs to */ Fts5ExprNode *pNode, /* FTS5_STRING or FTS5_TERM node */ int bFromValid, i64 iFrom ){ Fts5ExprTerm *pTerm = &pNode->pNear->apPhrase[0]->aTerm[0]; int rc = SQLITE_OK; pNode->bNomatch = 0; if( pTerm->pSynonym ){ int bEof = 1; Fts5ExprTerm *p; /* Find the firstest rowid any synonym points to. */ i64 iRowid = fts5ExprSynonymRowid(pTerm, pExpr->bDesc, 0); /* Advance each iterator that currently points to iRowid. Or, if iFrom ** is valid - each iterator that points to a rowid before iFrom. */ for(p=pTerm; p; p=p->pSynonym){ if( sqlite3Fts5IterEof(p->pIter)==0 ){ i64 ii = p->pIter->iRowid; if( ii==iRowid || (bFromValid && ii!=iFrom && (ii>iFrom)==pExpr->bDesc) ){ if( bFromValid ){ rc = sqlite3Fts5IterNextFrom(p->pIter, iFrom); }else{ rc = sqlite3Fts5IterNext(p->pIter); } if( rc!=SQLITE_OK ) break; if( sqlite3Fts5IterEof(p->pIter)==0 ){ bEof = 0; } }else{ bEof = 0; } } } /* Set the EOF flag if either all synonym iterators are at EOF or an ** error has occurred. */ pNode->bEof = (rc || bEof); }else{ Fts5IndexIter *pIter = pTerm->pIter; assert( Fts5NodeIsString(pNode) ); if( bFromValid ){ rc = sqlite3Fts5IterNextFrom(pIter, iFrom); }else{ rc = sqlite3Fts5IterNext(pIter); } pNode->bEof = (rc || sqlite3Fts5IterEof(pIter)); } if( pNode->bEof==0 ){ assert( rc==SQLITE_OK ); rc = fts5ExprNodeTest_STRING(pExpr, pNode); } return rc; } static int fts5ExprNodeTest_TERM( Fts5Expr *pExpr, /* Expression that pNear is a part of */ Fts5ExprNode *pNode /* The "NEAR" node (FTS5_TERM) */ ){ /* As this "NEAR" object is actually a single phrase that consists ** of a single term only, grab pointers into the poslist managed by the ** fts5_index.c iterator object. This is much faster than synthesizing ** a new poslist the way we have to for more complicated phrase or NEAR ** expressions. */ Fts5ExprPhrase *pPhrase = pNode->pNear->apPhrase[0]; Fts5IndexIter *pIter = pPhrase->aTerm[0].pIter; assert( pNode->eType==FTS5_TERM ); assert( pNode->pNear->nPhrase==1 && pPhrase->nTerm==1 ); assert( pPhrase->aTerm[0].pSynonym==0 ); pPhrase->poslist.n = pIter->nData; if( pExpr->pConfig->eDetail==FTS5_DETAIL_FULL ){ pPhrase->poslist.p = (u8*)pIter->pData; } pNode->iRowid = pIter->iRowid; pNode->bNomatch = (pPhrase->poslist.n==0); return SQLITE_OK; } /* ** xNext() method for a node of type FTS5_TERM. */ static int fts5ExprNodeNext_TERM( Fts5Expr *pExpr, Fts5ExprNode *pNode, int bFromValid, i64 iFrom ){ int rc; Fts5IndexIter *pIter = pNode->pNear->apPhrase[0]->aTerm[0].pIter; assert( pNode->bEof==0 ); if( bFromValid ){ rc = sqlite3Fts5IterNextFrom(pIter, iFrom); }else{ rc = sqlite3Fts5IterNext(pIter); } if( rc==SQLITE_OK && sqlite3Fts5IterEof(pIter)==0 ){ rc = fts5ExprNodeTest_TERM(pExpr, pNode); }else{ pNode->bEof = 1; pNode->bNomatch = 0; } return rc; } static void fts5ExprNodeTest_OR( Fts5Expr *pExpr, /* Expression of which pNode is a part */ Fts5ExprNode *pNode /* Expression node to test */ ){ Fts5ExprNode *pNext = pNode->apChild[0]; int i; for(i=1; inChild; i++){ Fts5ExprNode *pChild = pNode->apChild[i]; int cmp = fts5NodeCompare(pExpr, pNext, pChild); if( cmp>0 || (cmp==0 && pChild->bNomatch==0) ){ pNext = pChild; } } pNode->iRowid = pNext->iRowid; pNode->bEof = pNext->bEof; pNode->bNomatch = pNext->bNomatch; } static int fts5ExprNodeNext_OR( Fts5Expr *pExpr, Fts5ExprNode *pNode, int bFromValid, i64 iFrom ){ int i; i64 iLast = pNode->iRowid; for(i=0; inChild; i++){ Fts5ExprNode *p1 = pNode->apChild[i]; assert( p1->bEof || fts5RowidCmp(pExpr, p1->iRowid, iLast)>=0 ); if( p1->bEof==0 ){ if( (p1->iRowid==iLast) || (bFromValid && fts5RowidCmp(pExpr, p1->iRowid, iFrom)<0) ){ int rc = fts5ExprNodeNext(pExpr, p1, bFromValid, iFrom); if( rc!=SQLITE_OK ){ pNode->bNomatch = 0; return rc; } } } } fts5ExprNodeTest_OR(pExpr, pNode); return SQLITE_OK; } /* ** Argument pNode is an FTS5_AND node. */ static int fts5ExprNodeTest_AND( Fts5Expr *pExpr, /* Expression pPhrase belongs to */ Fts5ExprNode *pAnd /* FTS5_AND node to advance */ ){ int iChild; i64 iLast = pAnd->iRowid; int rc = SQLITE_OK; int bMatch; assert( pAnd->bEof==0 ); do { pAnd->bNomatch = 0; bMatch = 1; for(iChild=0; iChildnChild; iChild++){ Fts5ExprNode *pChild = pAnd->apChild[iChild]; int cmp = fts5RowidCmp(pExpr, iLast, pChild->iRowid); if( cmp>0 ){ /* Advance pChild until it points to iLast or laster */ rc = fts5ExprNodeNext(pExpr, pChild, 1, iLast); if( rc!=SQLITE_OK ){ pAnd->bNomatch = 0; return rc; } } /* If the child node is now at EOF, so is the parent AND node. Otherwise, ** the child node is guaranteed to have advanced at least as far as ** rowid iLast. So if it is not at exactly iLast, pChild->iRowid is the ** new lastest rowid seen so far. */ assert( pChild->bEof || fts5RowidCmp(pExpr, iLast, pChild->iRowid)<=0 ); if( pChild->bEof ){ fts5ExprSetEof(pAnd); bMatch = 1; break; }else if( iLast!=pChild->iRowid ){ bMatch = 0; iLast = pChild->iRowid; } if( pChild->bNomatch ){ pAnd->bNomatch = 1; } } }while( bMatch==0 ); if( pAnd->bNomatch && pAnd!=pExpr->pRoot ){ fts5ExprNodeZeroPoslist(pAnd); } pAnd->iRowid = iLast; return SQLITE_OK; } static int fts5ExprNodeNext_AND( Fts5Expr *pExpr, Fts5ExprNode *pNode, int bFromValid, i64 iFrom ){ int rc = fts5ExprNodeNext(pExpr, pNode->apChild[0], bFromValid, iFrom); if( rc==SQLITE_OK ){ rc = fts5ExprNodeTest_AND(pExpr, pNode); }else{ pNode->bNomatch = 0; } return rc; } static int fts5ExprNodeTest_NOT( Fts5Expr *pExpr, /* Expression pPhrase belongs to */ Fts5ExprNode *pNode /* FTS5_NOT node to advance */ ){ int rc = SQLITE_OK; Fts5ExprNode *p1 = pNode->apChild[0]; Fts5ExprNode *p2 = pNode->apChild[1]; assert( pNode->nChild==2 ); while( rc==SQLITE_OK && p1->bEof==0 ){ int cmp = fts5NodeCompare(pExpr, p1, p2); if( cmp>0 ){ rc = fts5ExprNodeNext(pExpr, p2, 1, p1->iRowid); cmp = fts5NodeCompare(pExpr, p1, p2); } assert( rc!=SQLITE_OK || cmp<=0 ); if( cmp || p2->bNomatch ) break; rc = fts5ExprNodeNext(pExpr, p1, 0, 0); } pNode->bEof = p1->bEof; pNode->bNomatch = p1->bNomatch; pNode->iRowid = p1->iRowid; if( p1->bEof ){ fts5ExprNodeZeroPoslist(p2); } return rc; } static int fts5ExprNodeNext_NOT( Fts5Expr *pExpr, Fts5ExprNode *pNode, int bFromValid, i64 iFrom ){ int rc = fts5ExprNodeNext(pExpr, pNode->apChild[0], bFromValid, iFrom); if( rc==SQLITE_OK ){ rc = fts5ExprNodeTest_NOT(pExpr, pNode); } if( rc!=SQLITE_OK ){ pNode->bNomatch = 0; } return rc; } /* ** If pNode currently points to a match, this function returns SQLITE_OK ** without modifying it. Otherwise, pNode is advanced until it does point ** to a match or EOF is reached. */ static int fts5ExprNodeTest( Fts5Expr *pExpr, /* Expression of which pNode is a part */ Fts5ExprNode *pNode /* Expression node to test */ ){ int rc = SQLITE_OK; if( pNode->bEof==0 ){ switch( pNode->eType ){ case FTS5_STRING: { rc = fts5ExprNodeTest_STRING(pExpr, pNode); break; } case FTS5_TERM: { rc = fts5ExprNodeTest_TERM(pExpr, pNode); break; } case FTS5_AND: { rc = fts5ExprNodeTest_AND(pExpr, pNode); break; } case FTS5_OR: { fts5ExprNodeTest_OR(pExpr, pNode); break; } default: assert( pNode->eType==FTS5_NOT ); { rc = fts5ExprNodeTest_NOT(pExpr, pNode); break; } } } return rc; } /* ** Set node pNode, which is part of expression pExpr, to point to the first ** match. If there are no matches, set the Node.bEof flag to indicate EOF. ** ** Return an SQLite error code if an error occurs, or SQLITE_OK otherwise. ** It is not an error if there are no matches. */ static int fts5ExprNodeFirst(Fts5Expr *pExpr, Fts5ExprNode *pNode){ int rc = SQLITE_OK; pNode->bEof = 0; pNode->bNomatch = 0; if( Fts5NodeIsString(pNode) ){ /* Initialize all term iterators in the NEAR object. */ rc = fts5ExprNearInitAll(pExpr, pNode); }else if( pNode->xNext==0 ){ pNode->bEof = 1; }else{ int i; int nEof = 0; for(i=0; inChild && rc==SQLITE_OK; i++){ Fts5ExprNode *pChild = pNode->apChild[i]; rc = fts5ExprNodeFirst(pExpr, pNode->apChild[i]); assert( pChild->bEof==0 || pChild->bEof==1 ); nEof += pChild->bEof; } pNode->iRowid = pNode->apChild[0]->iRowid; switch( pNode->eType ){ case FTS5_AND: if( nEof>0 ) fts5ExprSetEof(pNode); break; case FTS5_OR: if( pNode->nChild==nEof ) fts5ExprSetEof(pNode); break; default: assert( pNode->eType==FTS5_NOT ); pNode->bEof = pNode->apChild[0]->bEof; break; } } if( rc==SQLITE_OK ){ rc = fts5ExprNodeTest(pExpr, pNode); } return rc; } /* ** Begin iterating through the set of documents in index pIdx matched by ** the MATCH expression passed as the first argument. If the "bDesc" ** parameter is passed a non-zero value, iteration is in descending rowid ** order. Or, if it is zero, in ascending order. ** ** If iterating in ascending rowid order (bDesc==0), the first document ** visited is that with the smallest rowid that is larger than or equal ** to parameter iFirst. Or, if iterating in ascending order (bDesc==1), ** then the first document visited must have a rowid smaller than or ** equal to iFirst. ** ** Return SQLITE_OK if successful, or an SQLite error code otherwise. It ** is not considered an error if the query does not match any documents. */ int sqlite3Fts5ExprFirst(Fts5Expr *p, Fts5Index *pIdx, i64 iFirst, int bDesc){ Fts5ExprNode *pRoot = p->pRoot; int rc; /* Return code */ p->pIndex = pIdx; p->bDesc = bDesc; rc = fts5ExprNodeFirst(p, pRoot); /* If not at EOF but the current rowid occurs earlier than iFirst in ** the iteration order, move to document iFirst or later. */ if( rc==SQLITE_OK && 0==pRoot->bEof && fts5RowidCmp(p, pRoot->iRowid, iFirst)<0 ){ rc = fts5ExprNodeNext(p, pRoot, 1, iFirst); } /* If the iterator is not at a real match, skip forward until it is. */ while( pRoot->bNomatch && rc==SQLITE_OK ){ assert( pRoot->bEof==0 ); rc = fts5ExprNodeNext(p, pRoot, 0, 0); } return rc; } /* ** Move to the next document ** ** Return SQLITE_OK if successful, or an SQLite error code otherwise. It ** is not considered an error if the query does not match any documents. */ int sqlite3Fts5ExprNext(Fts5Expr *p, i64 iLast){ int rc; Fts5ExprNode *pRoot = p->pRoot; assert( pRoot->bEof==0 && pRoot->bNomatch==0 ); do { rc = fts5ExprNodeNext(p, pRoot, 0, 0); assert( pRoot->bNomatch==0 || (rc==SQLITE_OK && pRoot->bEof==0) ); }while( pRoot->bNomatch ); if( fts5RowidCmp(p, pRoot->iRowid, iLast)>0 ){ pRoot->bEof = 1; } return rc; } int sqlite3Fts5ExprEof(Fts5Expr *p){ return p->pRoot->bEof; } i64 sqlite3Fts5ExprRowid(Fts5Expr *p){ return p->pRoot->iRowid; } static int fts5ParseStringFromToken(Fts5Token *pToken, char **pz){ int rc = SQLITE_OK; *pz = sqlite3Fts5Strndup(&rc, pToken->p, pToken->n); return rc; } /* ** Free the phrase object passed as the only argument. */ static void fts5ExprPhraseFree(Fts5ExprPhrase *pPhrase){ if( pPhrase ){ int i; for(i=0; inTerm; i++){ Fts5ExprTerm *pSyn; Fts5ExprTerm *pNext; Fts5ExprTerm *pTerm = &pPhrase->aTerm[i]; sqlite3_free(pTerm->pTerm); sqlite3Fts5IterClose(pTerm->pIter); for(pSyn=pTerm->pSynonym; pSyn; pSyn=pNext){ pNext = pSyn->pSynonym; sqlite3Fts5IterClose(pSyn->pIter); fts5BufferFree((Fts5Buffer*)&pSyn[1]); sqlite3_free(pSyn); } } if( pPhrase->poslist.nSpace>0 ) fts5BufferFree(&pPhrase->poslist); sqlite3_free(pPhrase); } } /* ** Set the "bFirst" flag on the first token of the phrase passed as the ** only argument. */ void sqlite3Fts5ParseSetCaret(Fts5ExprPhrase *pPhrase){ if( pPhrase && pPhrase->nTerm ){ pPhrase->aTerm[0].bFirst = 1; } } /* ** If argument pNear is NULL, then a new Fts5ExprNearset object is allocated ** and populated with pPhrase. Or, if pNear is not NULL, phrase pPhrase is ** appended to it and the results returned. ** ** If an OOM error occurs, both the pNear and pPhrase objects are freed and ** NULL returned. */ Fts5ExprNearset *sqlite3Fts5ParseNearset( Fts5Parse *pParse, /* Parse context */ Fts5ExprNearset *pNear, /* Existing nearset, or NULL */ Fts5ExprPhrase *pPhrase /* Recently parsed phrase */ ){ const int SZALLOC = 8; Fts5ExprNearset *pRet = 0; if( pParse->rc==SQLITE_OK ){ if( pPhrase==0 ){ return pNear; } if( pNear==0 ){ sqlite3_int64 nByte; nByte = sizeof(Fts5ExprNearset) + SZALLOC * sizeof(Fts5ExprPhrase*); pRet = sqlite3_malloc64(nByte); if( pRet==0 ){ pParse->rc = SQLITE_NOMEM; }else{ memset(pRet, 0, (size_t)nByte); } }else if( (pNear->nPhrase % SZALLOC)==0 ){ int nNew = pNear->nPhrase + SZALLOC; sqlite3_int64 nByte; nByte = sizeof(Fts5ExprNearset) + nNew * sizeof(Fts5ExprPhrase*); pRet = (Fts5ExprNearset*)sqlite3_realloc64(pNear, nByte); if( pRet==0 ){ pParse->rc = SQLITE_NOMEM; } }else{ pRet = pNear; } } if( pRet==0 ){ assert( pParse->rc!=SQLITE_OK ); sqlite3Fts5ParseNearsetFree(pNear); sqlite3Fts5ParsePhraseFree(pPhrase); }else{ if( pRet->nPhrase>0 ){ Fts5ExprPhrase *pLast = pRet->apPhrase[pRet->nPhrase-1]; assert( pParse!=0 ); assert( pParse->apPhrase!=0 ); assert( pParse->nPhrase>=2 ); assert( pLast==pParse->apPhrase[pParse->nPhrase-2] ); if( pPhrase->nTerm==0 ){ fts5ExprPhraseFree(pPhrase); pRet->nPhrase--; pParse->nPhrase--; pPhrase = pLast; }else if( pLast->nTerm==0 ){ fts5ExprPhraseFree(pLast); pParse->apPhrase[pParse->nPhrase-2] = pPhrase; pParse->nPhrase--; pRet->nPhrase--; } } pRet->apPhrase[pRet->nPhrase++] = pPhrase; } return pRet; } typedef struct TokenCtx TokenCtx; struct TokenCtx { Fts5ExprPhrase *pPhrase; Fts5Config *pConfig; int rc; }; /* ** Callback for tokenizing terms used by ParseTerm(). */ static int fts5ParseTokenize( void *pContext, /* Pointer to Fts5InsertCtx object */ int tflags, /* Mask of FTS5_TOKEN_* flags */ const char *pToken, /* Buffer containing token */ int nToken, /* Size of token in bytes */ int iUnused1, /* Start offset of token */ int iUnused2 /* End offset of token */ ){ int rc = SQLITE_OK; const int SZALLOC = 8; TokenCtx *pCtx = (TokenCtx*)pContext; Fts5ExprPhrase *pPhrase = pCtx->pPhrase; UNUSED_PARAM2(iUnused1, iUnused2); /* If an error has already occurred, this is a no-op */ if( pCtx->rc!=SQLITE_OK ) return pCtx->rc; if( nToken>FTS5_MAX_TOKEN_SIZE ) nToken = FTS5_MAX_TOKEN_SIZE; if( pPhrase && pPhrase->nTerm>0 && (tflags & FTS5_TOKEN_COLOCATED) ){ Fts5ExprTerm *pSyn; sqlite3_int64 nByte = sizeof(Fts5ExprTerm) + sizeof(Fts5Buffer) + nToken+1; pSyn = (Fts5ExprTerm*)sqlite3_malloc64(nByte); if( pSyn==0 ){ rc = SQLITE_NOMEM; }else{ memset(pSyn, 0, (size_t)nByte); pSyn->pTerm = ((char*)pSyn) + sizeof(Fts5ExprTerm) + sizeof(Fts5Buffer); pSyn->nFullTerm = pSyn->nQueryTerm = nToken; if( pCtx->pConfig->bTokendata ){ pSyn->nQueryTerm = (int)strlen(pSyn->pTerm); } memcpy(pSyn->pTerm, pToken, nToken); pSyn->pSynonym = pPhrase->aTerm[pPhrase->nTerm-1].pSynonym; pPhrase->aTerm[pPhrase->nTerm-1].pSynonym = pSyn; } }else{ Fts5ExprTerm *pTerm; if( pPhrase==0 || (pPhrase->nTerm % SZALLOC)==0 ){ Fts5ExprPhrase *pNew; int nNew = SZALLOC + (pPhrase ? pPhrase->nTerm : 0); pNew = (Fts5ExprPhrase*)sqlite3_realloc64(pPhrase, sizeof(Fts5ExprPhrase) + sizeof(Fts5ExprTerm) * nNew ); if( pNew==0 ){ rc = SQLITE_NOMEM; }else{ if( pPhrase==0 ) memset(pNew, 0, sizeof(Fts5ExprPhrase)); pCtx->pPhrase = pPhrase = pNew; pNew->nTerm = nNew - SZALLOC; } } if( rc==SQLITE_OK ){ pTerm = &pPhrase->aTerm[pPhrase->nTerm++]; memset(pTerm, 0, sizeof(Fts5ExprTerm)); pTerm->pTerm = sqlite3Fts5Strndup(&rc, pToken, nToken); pTerm->nFullTerm = pTerm->nQueryTerm = nToken; if( pCtx->pConfig->bTokendata && rc==SQLITE_OK ){ pTerm->nQueryTerm = (int)strlen(pTerm->pTerm); } } } pCtx->rc = rc; return rc; } /* ** Free the phrase object passed as the only argument. */ void sqlite3Fts5ParsePhraseFree(Fts5ExprPhrase *pPhrase){ fts5ExprPhraseFree(pPhrase); } /* ** Free the phrase object passed as the second argument. */ void sqlite3Fts5ParseNearsetFree(Fts5ExprNearset *pNear){ if( pNear ){ int i; for(i=0; inPhrase; i++){ fts5ExprPhraseFree(pNear->apPhrase[i]); } sqlite3_free(pNear->pColset); sqlite3_free(pNear); } } void sqlite3Fts5ParseFinished(Fts5Parse *pParse, Fts5ExprNode *p){ assert( pParse->pExpr==0 ); pParse->pExpr = p; } static int parseGrowPhraseArray(Fts5Parse *pParse){ if( (pParse->nPhrase % 8)==0 ){ sqlite3_int64 nByte = sizeof(Fts5ExprPhrase*) * (pParse->nPhrase + 8); Fts5ExprPhrase **apNew; apNew = (Fts5ExprPhrase**)sqlite3_realloc64(pParse->apPhrase, nByte); if( apNew==0 ){ pParse->rc = SQLITE_NOMEM; return SQLITE_NOMEM; } pParse->apPhrase = apNew; } return SQLITE_OK; } /* ** This function is called by the parser to process a string token. The ** string may or may not be quoted. In any case it is tokenized and a ** phrase object consisting of all tokens returned. */ Fts5ExprPhrase *sqlite3Fts5ParseTerm( Fts5Parse *pParse, /* Parse context */ Fts5ExprPhrase *pAppend, /* Phrase to append to */ Fts5Token *pToken, /* String to tokenize */ int bPrefix /* True if there is a trailing "*" */ ){ Fts5Config *pConfig = pParse->pConfig; TokenCtx sCtx; /* Context object passed to callback */ int rc; /* Tokenize return code */ char *z = 0; memset(&sCtx, 0, sizeof(TokenCtx)); sCtx.pPhrase = pAppend; sCtx.pConfig = pConfig; rc = fts5ParseStringFromToken(pToken, &z); if( rc==SQLITE_OK ){ int flags = FTS5_TOKENIZE_QUERY | (bPrefix ? FTS5_TOKENIZE_PREFIX : 0); int n; sqlite3Fts5Dequote(z); n = (int)strlen(z); rc = sqlite3Fts5Tokenize(pConfig, flags, z, n, &sCtx, fts5ParseTokenize); } sqlite3_free(z); if( rc || (rc = sCtx.rc) ){ pParse->rc = rc; fts5ExprPhraseFree(sCtx.pPhrase); sCtx.pPhrase = 0; }else{ if( pAppend==0 ){ if( parseGrowPhraseArray(pParse) ){ fts5ExprPhraseFree(sCtx.pPhrase); return 0; } pParse->nPhrase++; } if( sCtx.pPhrase==0 ){ /* This happens when parsing a token or quoted phrase that contains ** no token characters at all. (e.g ... MATCH '""'). */ sCtx.pPhrase = sqlite3Fts5MallocZero(&pParse->rc, sizeof(Fts5ExprPhrase)); }else if( sCtx.pPhrase->nTerm ){ sCtx.pPhrase->aTerm[sCtx.pPhrase->nTerm-1].bPrefix = (u8)bPrefix; } pParse->apPhrase[pParse->nPhrase-1] = sCtx.pPhrase; } return sCtx.pPhrase; } /* ** Create a new FTS5 expression by cloning phrase iPhrase of the ** expression passed as the second argument. */ int sqlite3Fts5ExprClonePhrase( Fts5Expr *pExpr, int iPhrase, Fts5Expr **ppNew ){ int rc = SQLITE_OK; /* Return code */ Fts5ExprPhrase *pOrig = 0; /* The phrase extracted from pExpr */ Fts5Expr *pNew = 0; /* Expression to return via *ppNew */ TokenCtx sCtx = {0,0,0}; /* Context object for fts5ParseTokenize */ if( iPhrase<0 || iPhrase>=pExpr->nPhrase ){ rc = SQLITE_RANGE; }else{ pOrig = pExpr->apExprPhrase[iPhrase]; pNew = (Fts5Expr*)sqlite3Fts5MallocZero(&rc, sizeof(Fts5Expr)); } if( rc==SQLITE_OK ){ pNew->apExprPhrase = (Fts5ExprPhrase**)sqlite3Fts5MallocZero(&rc, sizeof(Fts5ExprPhrase*)); } if( rc==SQLITE_OK ){ pNew->pRoot = (Fts5ExprNode*)sqlite3Fts5MallocZero(&rc, sizeof(Fts5ExprNode)); } if( rc==SQLITE_OK ){ pNew->pRoot->pNear = (Fts5ExprNearset*)sqlite3Fts5MallocZero(&rc, sizeof(Fts5ExprNearset) + sizeof(Fts5ExprPhrase*)); } if( rc==SQLITE_OK && ALWAYS(pOrig!=0) ){ Fts5Colset *pColsetOrig = pOrig->pNode->pNear->pColset; if( pColsetOrig ){ sqlite3_int64 nByte; Fts5Colset *pColset; nByte = sizeof(Fts5Colset) + (pColsetOrig->nCol-1) * sizeof(int); pColset = (Fts5Colset*)sqlite3Fts5MallocZero(&rc, nByte); if( pColset ){ memcpy(pColset, pColsetOrig, (size_t)nByte); } pNew->pRoot->pNear->pColset = pColset; } } if( rc==SQLITE_OK ){ if( pOrig->nTerm ){ int i; /* Used to iterate through phrase terms */ sCtx.pConfig = pExpr->pConfig; for(i=0; rc==SQLITE_OK && inTerm; i++){ int tflags = 0; Fts5ExprTerm *p; for(p=&pOrig->aTerm[i]; p && rc==SQLITE_OK; p=p->pSynonym){ rc = fts5ParseTokenize((void*)&sCtx,tflags,p->pTerm,p->nFullTerm,0,0); tflags = FTS5_TOKEN_COLOCATED; } if( rc==SQLITE_OK ){ sCtx.pPhrase->aTerm[i].bPrefix = pOrig->aTerm[i].bPrefix; sCtx.pPhrase->aTerm[i].bFirst = pOrig->aTerm[i].bFirst; } } }else{ /* This happens when parsing a token or quoted phrase that contains ** no token characters at all. (e.g ... MATCH '""'). */ sCtx.pPhrase = sqlite3Fts5MallocZero(&rc, sizeof(Fts5ExprPhrase)); } } if( rc==SQLITE_OK && ALWAYS(sCtx.pPhrase) ){ /* All the allocations succeeded. Put the expression object together. */ pNew->pIndex = pExpr->pIndex; pNew->pConfig = pExpr->pConfig; pNew->nPhrase = 1; pNew->apExprPhrase[0] = sCtx.pPhrase; pNew->pRoot->pNear->apPhrase[0] = sCtx.pPhrase; pNew->pRoot->pNear->nPhrase = 1; sCtx.pPhrase->pNode = pNew->pRoot; if( pOrig->nTerm==1 && pOrig->aTerm[0].pSynonym==0 && pOrig->aTerm[0].bFirst==0 ){ pNew->pRoot->eType = FTS5_TERM; pNew->pRoot->xNext = fts5ExprNodeNext_TERM; }else{ pNew->pRoot->eType = FTS5_STRING; pNew->pRoot->xNext = fts5ExprNodeNext_STRING; } }else{ sqlite3Fts5ExprFree(pNew); fts5ExprPhraseFree(sCtx.pPhrase); pNew = 0; } *ppNew = pNew; return rc; } /* ** Token pTok has appeared in a MATCH expression where the NEAR operator ** is expected. If token pTok does not contain "NEAR", store an error ** in the pParse object. */ void sqlite3Fts5ParseNear(Fts5Parse *pParse, Fts5Token *pTok){ if( pTok->n!=4 || memcmp("NEAR", pTok->p, 4) ){ sqlite3Fts5ParseError( pParse, "fts5: syntax error near \"%.*s\"", pTok->n, pTok->p ); } } void sqlite3Fts5ParseSetDistance( Fts5Parse *pParse, Fts5ExprNearset *pNear, Fts5Token *p ){ if( pNear ){ int nNear = 0; int i; if( p->n ){ for(i=0; in; i++){ char c = (char)p->p[i]; if( c<'0' || c>'9' ){ sqlite3Fts5ParseError( pParse, "expected integer, got \"%.*s\"", p->n, p->p ); return; } nNear = nNear * 10 + (p->p[i] - '0'); } }else{ nNear = FTS5_DEFAULT_NEARDIST; } pNear->nNear = nNear; } } /* ** The second argument passed to this function may be NULL, or it may be ** an existing Fts5Colset object. This function returns a pointer to ** a new colset object containing the contents of (p) with new value column ** number iCol appended. ** ** If an OOM error occurs, store an error code in pParse and return NULL. ** The old colset object (if any) is not freed in this case. */ static Fts5Colset *fts5ParseColset( Fts5Parse *pParse, /* Store SQLITE_NOMEM here if required */ Fts5Colset *p, /* Existing colset object */ int iCol /* New column to add to colset object */ ){ int nCol = p ? p->nCol : 0; /* Num. columns already in colset object */ Fts5Colset *pNew; /* New colset object to return */ assert( pParse->rc==SQLITE_OK ); assert( iCol>=0 && iColpConfig->nCol ); pNew = sqlite3_realloc64(p, sizeof(Fts5Colset) + sizeof(int)*nCol); if( pNew==0 ){ pParse->rc = SQLITE_NOMEM; }else{ int *aiCol = pNew->aiCol; int i, j; for(i=0; iiCol ) break; } for(j=nCol; j>i; j--){ aiCol[j] = aiCol[j-1]; } aiCol[i] = iCol; pNew->nCol = nCol+1; #ifndef NDEBUG /* Check that the array is in order and contains no duplicate entries. */ for(i=1; inCol; i++) assert( pNew->aiCol[i]>pNew->aiCol[i-1] ); #endif } return pNew; } /* ** Allocate and return an Fts5Colset object specifying the inverse of ** the colset passed as the second argument. Free the colset passed ** as the second argument before returning. */ Fts5Colset *sqlite3Fts5ParseColsetInvert(Fts5Parse *pParse, Fts5Colset *p){ Fts5Colset *pRet; int nCol = pParse->pConfig->nCol; pRet = (Fts5Colset*)sqlite3Fts5MallocZero(&pParse->rc, sizeof(Fts5Colset) + sizeof(int)*nCol ); if( pRet ){ int i; int iOld = 0; for(i=0; i=p->nCol || p->aiCol[iOld]!=i ){ pRet->aiCol[pRet->nCol++] = i; }else{ iOld++; } } } sqlite3_free(p); return pRet; } Fts5Colset *sqlite3Fts5ParseColset( Fts5Parse *pParse, /* Store SQLITE_NOMEM here if required */ Fts5Colset *pColset, /* Existing colset object */ Fts5Token *p ){ Fts5Colset *pRet = 0; int iCol; char *z; /* Dequoted copy of token p */ z = sqlite3Fts5Strndup(&pParse->rc, p->p, p->n); if( pParse->rc==SQLITE_OK ){ Fts5Config *pConfig = pParse->pConfig; sqlite3Fts5Dequote(z); for(iCol=0; iColnCol; iCol++){ if( 0==sqlite3_stricmp(pConfig->azCol[iCol], z) ) break; } if( iCol==pConfig->nCol ){ sqlite3Fts5ParseError(pParse, "no such column: %s", z); }else{ pRet = fts5ParseColset(pParse, pColset, iCol); } sqlite3_free(z); } if( pRet==0 ){ assert( pParse->rc!=SQLITE_OK ); sqlite3_free(pColset); } return pRet; } /* ** If argument pOrig is NULL, or if (*pRc) is set to anything other than ** SQLITE_OK when this function is called, NULL is returned. ** ** Otherwise, a copy of (*pOrig) is made into memory obtained from ** sqlite3Fts5MallocZero() and a pointer to it returned. If the allocation ** fails, (*pRc) is set to SQLITE_NOMEM and NULL is returned. */ static Fts5Colset *fts5CloneColset(int *pRc, Fts5Colset *pOrig){ Fts5Colset *pRet; if( pOrig ){ sqlite3_int64 nByte = sizeof(Fts5Colset) + (pOrig->nCol-1) * sizeof(int); pRet = (Fts5Colset*)sqlite3Fts5MallocZero(pRc, nByte); if( pRet ){ memcpy(pRet, pOrig, (size_t)nByte); } }else{ pRet = 0; } return pRet; } /* ** Remove from colset pColset any columns that are not also in colset pMerge. */ static void fts5MergeColset(Fts5Colset *pColset, Fts5Colset *pMerge){ int iIn = 0; /* Next input in pColset */ int iMerge = 0; /* Next input in pMerge */ int iOut = 0; /* Next output slot in pColset */ while( iInnCol && iMergenCol ){ int iDiff = pColset->aiCol[iIn] - pMerge->aiCol[iMerge]; if( iDiff==0 ){ pColset->aiCol[iOut++] = pMerge->aiCol[iMerge]; iMerge++; iIn++; }else if( iDiff>0 ){ iMerge++; }else{ iIn++; } } pColset->nCol = iOut; } /* ** Recursively apply colset pColset to expression node pNode and all of ** its decendents. If (*ppFree) is not NULL, it contains a spare copy ** of pColset. This function may use the spare copy and set (*ppFree) to ** zero, or it may create copies of pColset using fts5CloneColset(). */ static void fts5ParseSetColset( Fts5Parse *pParse, Fts5ExprNode *pNode, Fts5Colset *pColset, Fts5Colset **ppFree ){ if( pParse->rc==SQLITE_OK ){ assert( pNode->eType==FTS5_TERM || pNode->eType==FTS5_STRING || pNode->eType==FTS5_AND || pNode->eType==FTS5_OR || pNode->eType==FTS5_NOT || pNode->eType==FTS5_EOF ); if( pNode->eType==FTS5_STRING || pNode->eType==FTS5_TERM ){ Fts5ExprNearset *pNear = pNode->pNear; if( pNear->pColset ){ fts5MergeColset(pNear->pColset, pColset); if( pNear->pColset->nCol==0 ){ pNode->eType = FTS5_EOF; pNode->xNext = 0; } }else if( *ppFree ){ pNear->pColset = pColset; *ppFree = 0; }else{ pNear->pColset = fts5CloneColset(&pParse->rc, pColset); } }else{ int i; assert( pNode->eType!=FTS5_EOF || pNode->nChild==0 ); for(i=0; inChild; i++){ fts5ParseSetColset(pParse, pNode->apChild[i], pColset, ppFree); } } } } /* ** Apply colset pColset to expression node pExpr and all of its descendents. */ void sqlite3Fts5ParseSetColset( Fts5Parse *pParse, Fts5ExprNode *pExpr, Fts5Colset *pColset ){ Fts5Colset *pFree = pColset; if( pParse->pConfig->eDetail==FTS5_DETAIL_NONE ){ sqlite3Fts5ParseError(pParse, "fts5: column queries are not supported (detail=none)" ); }else{ fts5ParseSetColset(pParse, pExpr, pColset, &pFree); } sqlite3_free(pFree); } static void fts5ExprAssignXNext(Fts5ExprNode *pNode){ switch( pNode->eType ){ case FTS5_STRING: { Fts5ExprNearset *pNear = pNode->pNear; if( pNear->nPhrase==1 && pNear->apPhrase[0]->nTerm==1 && pNear->apPhrase[0]->aTerm[0].pSynonym==0 && pNear->apPhrase[0]->aTerm[0].bFirst==0 ){ pNode->eType = FTS5_TERM; pNode->xNext = fts5ExprNodeNext_TERM; }else{ pNode->xNext = fts5ExprNodeNext_STRING; } break; }; case FTS5_OR: { pNode->xNext = fts5ExprNodeNext_OR; break; }; case FTS5_AND: { pNode->xNext = fts5ExprNodeNext_AND; break; }; default: assert( pNode->eType==FTS5_NOT ); { pNode->xNext = fts5ExprNodeNext_NOT; break; }; } } static void fts5ExprAddChildren(Fts5ExprNode *p, Fts5ExprNode *pSub){ int ii = p->nChild; if( p->eType!=FTS5_NOT && pSub->eType==p->eType ){ int nByte = sizeof(Fts5ExprNode*) * pSub->nChild; memcpy(&p->apChild[p->nChild], pSub->apChild, nByte); p->nChild += pSub->nChild; sqlite3_free(pSub); }else{ p->apChild[p->nChild++] = pSub; } for( ; iinChild; ii++){ p->iHeight = MAX(p->iHeight, p->apChild[ii]->iHeight + 1); } } /* ** This function is used when parsing LIKE or GLOB patterns against ** trigram indexes that specify either detail=column or detail=none. ** It converts a phrase: ** ** abc + def + ghi ** ** into an AND tree: ** ** abc AND def AND ghi */ static Fts5ExprNode *fts5ParsePhraseToAnd( Fts5Parse *pParse, Fts5ExprNearset *pNear ){ int nTerm = pNear->apPhrase[0]->nTerm; int ii; int nByte; Fts5ExprNode *pRet; assert( pNear->nPhrase==1 ); assert( pParse->bPhraseToAnd ); nByte = sizeof(Fts5ExprNode) + nTerm*sizeof(Fts5ExprNode*); pRet = (Fts5ExprNode*)sqlite3Fts5MallocZero(&pParse->rc, nByte); if( pRet ){ pRet->eType = FTS5_AND; pRet->nChild = nTerm; pRet->iHeight = 1; fts5ExprAssignXNext(pRet); pParse->nPhrase--; for(ii=0; iirc, sizeof(Fts5ExprPhrase) ); if( pPhrase ){ if( parseGrowPhraseArray(pParse) ){ fts5ExprPhraseFree(pPhrase); }else{ Fts5ExprTerm *p = &pNear->apPhrase[0]->aTerm[ii]; Fts5ExprTerm *pTo = &pPhrase->aTerm[0]; pParse->apPhrase[pParse->nPhrase++] = pPhrase; pPhrase->nTerm = 1; pTo->pTerm = sqlite3Fts5Strndup(&pParse->rc, p->pTerm, p->nFullTerm); pTo->nQueryTerm = p->nQueryTerm; pTo->nFullTerm = p->nFullTerm; pRet->apChild[ii] = sqlite3Fts5ParseNode(pParse, FTS5_STRING, 0, 0, sqlite3Fts5ParseNearset(pParse, 0, pPhrase) ); } } } if( pParse->rc ){ sqlite3Fts5ParseNodeFree(pRet); pRet = 0; }else{ sqlite3Fts5ParseNearsetFree(pNear); } } return pRet; } /* ** Allocate and return a new expression object. If anything goes wrong (i.e. ** OOM error), leave an error code in pParse and return NULL. */ Fts5ExprNode *sqlite3Fts5ParseNode( Fts5Parse *pParse, /* Parse context */ int eType, /* FTS5_STRING, AND, OR or NOT */ Fts5ExprNode *pLeft, /* Left hand child expression */ Fts5ExprNode *pRight, /* Right hand child expression */ Fts5ExprNearset *pNear /* For STRING expressions, the near cluster */ ){ Fts5ExprNode *pRet = 0; if( pParse->rc==SQLITE_OK ){ int nChild = 0; /* Number of children of returned node */ sqlite3_int64 nByte; /* Bytes of space to allocate for this node */ assert( (eType!=FTS5_STRING && !pNear) || (eType==FTS5_STRING && !pLeft && !pRight) ); if( eType==FTS5_STRING && pNear==0 ) return 0; if( eType!=FTS5_STRING && pLeft==0 ) return pRight; if( eType!=FTS5_STRING && pRight==0 ) return pLeft; if( eType==FTS5_STRING && pParse->bPhraseToAnd && pNear->apPhrase[0]->nTerm>1 ){ pRet = fts5ParsePhraseToAnd(pParse, pNear); }else{ if( eType==FTS5_NOT ){ nChild = 2; }else if( eType==FTS5_AND || eType==FTS5_OR ){ nChild = 2; if( pLeft->eType==eType ) nChild += pLeft->nChild-1; if( pRight->eType==eType ) nChild += pRight->nChild-1; } nByte = sizeof(Fts5ExprNode) + sizeof(Fts5ExprNode*)*(nChild-1); pRet = (Fts5ExprNode*)sqlite3Fts5MallocZero(&pParse->rc, nByte); if( pRet ){ pRet->eType = eType; pRet->pNear = pNear; fts5ExprAssignXNext(pRet); if( eType==FTS5_STRING ){ int iPhrase; for(iPhrase=0; iPhrasenPhrase; iPhrase++){ pNear->apPhrase[iPhrase]->pNode = pRet; if( pNear->apPhrase[iPhrase]->nTerm==0 ){ pRet->xNext = 0; pRet->eType = FTS5_EOF; } } if( pParse->pConfig->eDetail!=FTS5_DETAIL_FULL ){ Fts5ExprPhrase *pPhrase = pNear->apPhrase[0]; if( pNear->nPhrase!=1 || pPhrase->nTerm>1 || (pPhrase->nTerm>0 && pPhrase->aTerm[0].bFirst) ){ sqlite3Fts5ParseError(pParse, "fts5: %s queries are not supported (detail!=full)", pNear->nPhrase==1 ? "phrase": "NEAR" ); sqlite3_free(pRet); pRet = 0; } } }else{ fts5ExprAddChildren(pRet, pLeft); fts5ExprAddChildren(pRet, pRight); if( pRet->iHeight>SQLITE_FTS5_MAX_EXPR_DEPTH ){ sqlite3Fts5ParseError(pParse, "fts5 expression tree is too large (maximum depth %d)", SQLITE_FTS5_MAX_EXPR_DEPTH ); sqlite3_free(pRet); pRet = 0; } } } } } if( pRet==0 ){ assert( pParse->rc!=SQLITE_OK ); sqlite3Fts5ParseNodeFree(pLeft); sqlite3Fts5ParseNodeFree(pRight); sqlite3Fts5ParseNearsetFree(pNear); } return pRet; } Fts5ExprNode *sqlite3Fts5ParseImplicitAnd( Fts5Parse *pParse, /* Parse context */ Fts5ExprNode *pLeft, /* Left hand child expression */ Fts5ExprNode *pRight /* Right hand child expression */ ){ Fts5ExprNode *pRet = 0; Fts5ExprNode *pPrev; if( pParse->rc ){ sqlite3Fts5ParseNodeFree(pLeft); sqlite3Fts5ParseNodeFree(pRight); }else{ assert( pLeft->eType==FTS5_STRING || pLeft->eType==FTS5_TERM || pLeft->eType==FTS5_EOF || pLeft->eType==FTS5_AND ); assert( pRight->eType==FTS5_STRING || pRight->eType==FTS5_TERM || pRight->eType==FTS5_EOF ); if( pLeft->eType==FTS5_AND ){ pPrev = pLeft->apChild[pLeft->nChild-1]; }else{ pPrev = pLeft; } assert( pPrev->eType==FTS5_STRING || pPrev->eType==FTS5_TERM || pPrev->eType==FTS5_EOF ); if( pRight->eType==FTS5_EOF ){ assert( pParse->apPhrase[pParse->nPhrase-1]==pRight->pNear->apPhrase[0] ); sqlite3Fts5ParseNodeFree(pRight); pRet = pLeft; pParse->nPhrase--; } else if( pPrev->eType==FTS5_EOF ){ Fts5ExprPhrase **ap; if( pPrev==pLeft ){ pRet = pRight; }else{ pLeft->apChild[pLeft->nChild-1] = pRight; pRet = pLeft; } ap = &pParse->apPhrase[pParse->nPhrase-1-pRight->pNear->nPhrase]; assert( ap[0]==pPrev->pNear->apPhrase[0] ); memmove(ap, &ap[1], sizeof(Fts5ExprPhrase*)*pRight->pNear->nPhrase); pParse->nPhrase--; sqlite3Fts5ParseNodeFree(pPrev); } else{ pRet = sqlite3Fts5ParseNode(pParse, FTS5_AND, pLeft, pRight, 0); } } return pRet; } #if defined(SQLITE_TEST) || defined(SQLITE_FTS5_DEBUG) static char *fts5ExprTermPrint(Fts5ExprTerm *pTerm){ sqlite3_int64 nByte = 0; Fts5ExprTerm *p; char *zQuoted; /* Determine the maximum amount of space required. */ for(p=pTerm; p; p=p->pSynonym){ nByte += pTerm->nQueryTerm * 2 + 3 + 2; } zQuoted = sqlite3_malloc64(nByte); if( zQuoted ){ int i = 0; for(p=pTerm; p; p=p->pSynonym){ char *zIn = p->pTerm; char *zEnd = &zIn[p->nQueryTerm]; zQuoted[i++] = '"'; while( zInpSynonym ) zQuoted[i++] = '|'; } if( pTerm->bPrefix ){ zQuoted[i++] = ' '; zQuoted[i++] = '*'; } zQuoted[i++] = '\0'; } return zQuoted; } static char *fts5PrintfAppend(char *zApp, const char *zFmt, ...){ char *zNew; va_list ap; va_start(ap, zFmt); zNew = sqlite3_vmprintf(zFmt, ap); va_end(ap); if( zApp && zNew ){ char *zNew2 = sqlite3_mprintf("%s%s", zApp, zNew); sqlite3_free(zNew); zNew = zNew2; } sqlite3_free(zApp); return zNew; } /* ** Compose a tcl-readable representation of expression pExpr. Return a ** pointer to a buffer containing that representation. It is the ** responsibility of the caller to at some point free the buffer using ** sqlite3_free(). */ static char *fts5ExprPrintTcl( Fts5Config *pConfig, const char *zNearsetCmd, Fts5ExprNode *pExpr ){ char *zRet = 0; if( pExpr->eType==FTS5_STRING || pExpr->eType==FTS5_TERM ){ Fts5ExprNearset *pNear = pExpr->pNear; int i; int iTerm; zRet = fts5PrintfAppend(zRet, "%s ", zNearsetCmd); if( zRet==0 ) return 0; if( pNear->pColset ){ int *aiCol = pNear->pColset->aiCol; int nCol = pNear->pColset->nCol; if( nCol==1 ){ zRet = fts5PrintfAppend(zRet, "-col %d ", aiCol[0]); }else{ zRet = fts5PrintfAppend(zRet, "-col {%d", aiCol[0]); for(i=1; ipColset->nCol; i++){ zRet = fts5PrintfAppend(zRet, " %d", aiCol[i]); } zRet = fts5PrintfAppend(zRet, "} "); } if( zRet==0 ) return 0; } if( pNear->nPhrase>1 ){ zRet = fts5PrintfAppend(zRet, "-near %d ", pNear->nNear); if( zRet==0 ) return 0; } zRet = fts5PrintfAppend(zRet, "--"); if( zRet==0 ) return 0; for(i=0; inPhrase; i++){ Fts5ExprPhrase *pPhrase = pNear->apPhrase[i]; zRet = fts5PrintfAppend(zRet, " {"); for(iTerm=0; zRet && iTermnTerm; iTerm++){ Fts5ExprTerm *p = &pPhrase->aTerm[iTerm]; zRet = fts5PrintfAppend(zRet, "%s%.*s", iTerm==0?"":" ", p->nQueryTerm, p->pTerm ); if( pPhrase->aTerm[iTerm].bPrefix ){ zRet = fts5PrintfAppend(zRet, "*"); } } if( zRet ) zRet = fts5PrintfAppend(zRet, "}"); if( zRet==0 ) return 0; } }else if( pExpr->eType==0 ){ zRet = sqlite3_mprintf("{}"); }else{ char const *zOp = 0; int i; switch( pExpr->eType ){ case FTS5_AND: zOp = "AND"; break; case FTS5_NOT: zOp = "NOT"; break; default: assert( pExpr->eType==FTS5_OR ); zOp = "OR"; break; } zRet = sqlite3_mprintf("%s", zOp); for(i=0; zRet && inChild; i++){ char *z = fts5ExprPrintTcl(pConfig, zNearsetCmd, pExpr->apChild[i]); if( !z ){ sqlite3_free(zRet); zRet = 0; }else{ zRet = fts5PrintfAppend(zRet, " [%z]", z); } } } return zRet; } static char *fts5ExprPrint(Fts5Config *pConfig, Fts5ExprNode *pExpr){ char *zRet = 0; if( pExpr->eType==0 ){ return sqlite3_mprintf("\"\""); }else if( pExpr->eType==FTS5_STRING || pExpr->eType==FTS5_TERM ){ Fts5ExprNearset *pNear = pExpr->pNear; int i; int iTerm; if( pNear->pColset ){ int ii; Fts5Colset *pColset = pNear->pColset; if( pColset->nCol>1 ) zRet = fts5PrintfAppend(zRet, "{"); for(ii=0; iinCol; ii++){ zRet = fts5PrintfAppend(zRet, "%s%s", pConfig->azCol[pColset->aiCol[ii]], ii==pColset->nCol-1 ? "" : " " ); } if( zRet ){ zRet = fts5PrintfAppend(zRet, "%s : ", pColset->nCol>1 ? "}" : ""); } if( zRet==0 ) return 0; } if( pNear->nPhrase>1 ){ zRet = fts5PrintfAppend(zRet, "NEAR("); if( zRet==0 ) return 0; } for(i=0; inPhrase; i++){ Fts5ExprPhrase *pPhrase = pNear->apPhrase[i]; if( i!=0 ){ zRet = fts5PrintfAppend(zRet, " "); if( zRet==0 ) return 0; } for(iTerm=0; iTermnTerm; iTerm++){ char *zTerm = fts5ExprTermPrint(&pPhrase->aTerm[iTerm]); if( zTerm ){ zRet = fts5PrintfAppend(zRet, "%s%s", iTerm==0?"":" + ", zTerm); sqlite3_free(zTerm); } if( zTerm==0 || zRet==0 ){ sqlite3_free(zRet); return 0; } } } if( pNear->nPhrase>1 ){ zRet = fts5PrintfAppend(zRet, ", %d)", pNear->nNear); if( zRet==0 ) return 0; } }else{ char const *zOp = 0; int i; switch( pExpr->eType ){ case FTS5_AND: zOp = " AND "; break; case FTS5_NOT: zOp = " NOT "; break; default: assert( pExpr->eType==FTS5_OR ); zOp = " OR "; break; } for(i=0; inChild; i++){ char *z = fts5ExprPrint(pConfig, pExpr->apChild[i]); if( z==0 ){ sqlite3_free(zRet); zRet = 0; }else{ int e = pExpr->apChild[i]->eType; int b = (e!=FTS5_STRING && e!=FTS5_TERM && e!=FTS5_EOF); zRet = fts5PrintfAppend(zRet, "%s%s%z%s", (i==0 ? "" : zOp), (b?"(":""), z, (b?")":"") ); } if( zRet==0 ) break; } } return zRet; } /* ** The implementation of user-defined scalar functions fts5_expr() (bTcl==0) ** and fts5_expr_tcl() (bTcl!=0). */ static void fts5ExprFunction( sqlite3_context *pCtx, /* Function call context */ int nArg, /* Number of args */ sqlite3_value **apVal, /* Function arguments */ int bTcl ){ Fts5Global *pGlobal = (Fts5Global*)sqlite3_user_data(pCtx); sqlite3 *db = sqlite3_context_db_handle(pCtx); const char *zExpr = 0; char *zErr = 0; Fts5Expr *pExpr = 0; int rc; int i; const char **azConfig; /* Array of arguments for Fts5Config */ const char *zNearsetCmd = "nearset"; int nConfig; /* Size of azConfig[] */ Fts5Config *pConfig = 0; int iArg = 1; if( nArg<1 ){ zErr = sqlite3_mprintf("wrong number of arguments to function %s", bTcl ? "fts5_expr_tcl" : "fts5_expr" ); sqlite3_result_error(pCtx, zErr, -1); sqlite3_free(zErr); return; } if( bTcl && nArg>1 ){ zNearsetCmd = (const char*)sqlite3_value_text(apVal[1]); iArg = 2; } nConfig = 3 + (nArg-iArg); azConfig = (const char**)sqlite3_malloc64(sizeof(char*) * nConfig); if( azConfig==0 ){ sqlite3_result_error_nomem(pCtx); return; } azConfig[0] = 0; azConfig[1] = "main"; azConfig[2] = "tbl"; for(i=3; iArgnCol, zExpr, &pExpr, &zErr); } if( rc==SQLITE_OK ){ char *zText; if( pExpr->pRoot->xNext==0 ){ zText = sqlite3_mprintf(""); }else if( bTcl ){ zText = fts5ExprPrintTcl(pConfig, zNearsetCmd, pExpr->pRoot); }else{ zText = fts5ExprPrint(pConfig, pExpr->pRoot); } if( zText==0 ){ rc = SQLITE_NOMEM; }else{ sqlite3_result_text(pCtx, zText, -1, SQLITE_TRANSIENT); sqlite3_free(zText); } } if( rc!=SQLITE_OK ){ if( zErr ){ sqlite3_result_error(pCtx, zErr, -1); sqlite3_free(zErr); }else{ sqlite3_result_error_code(pCtx, rc); } } sqlite3_free((void *)azConfig); sqlite3Fts5ConfigFree(pConfig); sqlite3Fts5ExprFree(pExpr); } static void fts5ExprFunctionHr( sqlite3_context *pCtx, /* Function call context */ int nArg, /* Number of args */ sqlite3_value **apVal /* Function arguments */ ){ fts5ExprFunction(pCtx, nArg, apVal, 0); } static void fts5ExprFunctionTcl( sqlite3_context *pCtx, /* Function call context */ int nArg, /* Number of args */ sqlite3_value **apVal /* Function arguments */ ){ fts5ExprFunction(pCtx, nArg, apVal, 1); } /* ** The implementation of an SQLite user-defined-function that accepts a ** single integer as an argument. If the integer is an alpha-numeric ** unicode code point, 1 is returned. Otherwise 0. */ static void fts5ExprIsAlnum( sqlite3_context *pCtx, /* Function call context */ int nArg, /* Number of args */ sqlite3_value **apVal /* Function arguments */ ){ int iCode; u8 aArr[32]; if( nArg!=1 ){ sqlite3_result_error(pCtx, "wrong number of arguments to function fts5_isalnum", -1 ); return; } memset(aArr, 0, sizeof(aArr)); sqlite3Fts5UnicodeCatParse("L*", aArr); sqlite3Fts5UnicodeCatParse("N*", aArr); sqlite3Fts5UnicodeCatParse("Co", aArr); iCode = sqlite3_value_int(apVal[0]); sqlite3_result_int(pCtx, aArr[sqlite3Fts5UnicodeCategory((u32)iCode)]); } static void fts5ExprFold( sqlite3_context *pCtx, /* Function call context */ int nArg, /* Number of args */ sqlite3_value **apVal /* Function arguments */ ){ if( nArg!=1 && nArg!=2 ){ sqlite3_result_error(pCtx, "wrong number of arguments to function fts5_fold", -1 ); }else{ int iCode; int bRemoveDiacritics = 0; iCode = sqlite3_value_int(apVal[0]); if( nArg==2 ) bRemoveDiacritics = sqlite3_value_int(apVal[1]); sqlite3_result_int(pCtx, sqlite3Fts5UnicodeFold(iCode, bRemoveDiacritics)); } } #endif /* if SQLITE_TEST || SQLITE_FTS5_DEBUG */ /* ** This is called during initialization to register the fts5_expr() scalar ** UDF with the SQLite handle passed as the only argument. */ int sqlite3Fts5ExprInit(Fts5Global *pGlobal, sqlite3 *db){ #if defined(SQLITE_TEST) || defined(SQLITE_FTS5_DEBUG) struct Fts5ExprFunc { const char *z; void (*x)(sqlite3_context*,int,sqlite3_value**); } aFunc[] = { { "fts5_expr", fts5ExprFunctionHr }, { "fts5_expr_tcl", fts5ExprFunctionTcl }, { "fts5_isalnum", fts5ExprIsAlnum }, { "fts5_fold", fts5ExprFold }, }; int i; int rc = SQLITE_OK; void *pCtx = (void*)pGlobal; for(i=0; rc==SQLITE_OK && iz, -1, SQLITE_UTF8, pCtx, p->x, 0, 0); } #else int rc = SQLITE_OK; UNUSED_PARAM2(pGlobal,db); #endif /* Avoid warnings indicating that sqlite3Fts5ParserTrace() and ** sqlite3Fts5ParserFallback() are unused */ #ifndef NDEBUG (void)sqlite3Fts5ParserTrace; #endif (void)sqlite3Fts5ParserFallback; return rc; } /* ** Return the number of phrases in expression pExpr. */ int sqlite3Fts5ExprPhraseCount(Fts5Expr *pExpr){ return (pExpr ? pExpr->nPhrase : 0); } /* ** Return the number of terms in the iPhrase'th phrase in pExpr. */ int sqlite3Fts5ExprPhraseSize(Fts5Expr *pExpr, int iPhrase){ if( iPhrase<0 || iPhrase>=pExpr->nPhrase ) return 0; return pExpr->apExprPhrase[iPhrase]->nTerm; } /* ** This function is used to access the current position list for phrase ** iPhrase. */ int sqlite3Fts5ExprPoslist(Fts5Expr *pExpr, int iPhrase, const u8 **pa){ int nRet; Fts5ExprPhrase *pPhrase = pExpr->apExprPhrase[iPhrase]; Fts5ExprNode *pNode = pPhrase->pNode; if( pNode->bEof==0 && pNode->iRowid==pExpr->pRoot->iRowid ){ *pa = pPhrase->poslist.p; nRet = pPhrase->poslist.n; }else{ *pa = 0; nRet = 0; } return nRet; } struct Fts5PoslistPopulator { Fts5PoslistWriter writer; int bOk; /* True if ok to populate */ int bMiss; }; /* ** Clear the position lists associated with all phrases in the expression ** passed as the first argument. Argument bLive is true if the expression ** might be pointing to a real entry, otherwise it has just been reset. ** ** At present this function is only used for detail=col and detail=none ** fts5 tables. This implies that all phrases must be at most 1 token ** in size, as phrase matches are not supported without detail=full. */ Fts5PoslistPopulator *sqlite3Fts5ExprClearPoslists(Fts5Expr *pExpr, int bLive){ Fts5PoslistPopulator *pRet; pRet = sqlite3_malloc64(sizeof(Fts5PoslistPopulator)*pExpr->nPhrase); if( pRet ){ int i; memset(pRet, 0, sizeof(Fts5PoslistPopulator)*pExpr->nPhrase); for(i=0; inPhrase; i++){ Fts5Buffer *pBuf = &pExpr->apExprPhrase[i]->poslist; Fts5ExprNode *pNode = pExpr->apExprPhrase[i]->pNode; assert( pExpr->apExprPhrase[i]->nTerm<=1 ); if( bLive && (pBuf->n==0 || pNode->iRowid!=pExpr->pRoot->iRowid || pNode->bEof) ){ pRet[i].bMiss = 1; }else{ pBuf->n = 0; } } } return pRet; } struct Fts5ExprCtx { Fts5Expr *pExpr; Fts5PoslistPopulator *aPopulator; i64 iOff; }; typedef struct Fts5ExprCtx Fts5ExprCtx; /* ** TODO: Make this more efficient! */ static int fts5ExprColsetTest(Fts5Colset *pColset, int iCol){ int i; for(i=0; inCol; i++){ if( pColset->aiCol[i]==iCol ) return 1; } return 0; } /* ** pToken is a buffer nToken bytes in size that may or may not contain ** an embedded 0x00 byte. If it does, return the number of bytes in ** the buffer before the 0x00. If it does not, return nToken. */ static int fts5QueryTerm(const char *pToken, int nToken){ int ii; for(ii=0; iipExpr; int i; int nQuery = nToken; i64 iRowid = pExpr->pRoot->iRowid; UNUSED_PARAM2(iUnused1, iUnused2); if( nQuery>FTS5_MAX_TOKEN_SIZE ) nQuery = FTS5_MAX_TOKEN_SIZE; if( pExpr->pConfig->bTokendata ){ nQuery = fts5QueryTerm(pToken, nQuery); } if( (tflags & FTS5_TOKEN_COLOCATED)==0 ) p->iOff++; for(i=0; inPhrase; i++){ Fts5ExprTerm *pT; if( p->aPopulator[i].bOk==0 ) continue; for(pT=&pExpr->apExprPhrase[i]->aTerm[0]; pT; pT=pT->pSynonym){ if( (pT->nQueryTerm==nQuery || (pT->nQueryTermbPrefix)) && memcmp(pT->pTerm, pToken, pT->nQueryTerm)==0 ){ int rc = sqlite3Fts5PoslistWriterAppend( &pExpr->apExprPhrase[i]->poslist, &p->aPopulator[i].writer, p->iOff ); if( rc==SQLITE_OK && pExpr->pConfig->bTokendata && !pT->bPrefix ){ int iCol = p->iOff>>32; int iTokOff = p->iOff & 0x7FFFFFFF; rc = sqlite3Fts5IndexIterWriteTokendata( pT->pIter, pToken, nToken, iRowid, iCol, iTokOff ); } if( rc ) return rc; break; } } } return SQLITE_OK; } int sqlite3Fts5ExprPopulatePoslists( Fts5Config *pConfig, Fts5Expr *pExpr, Fts5PoslistPopulator *aPopulator, int iCol, const char *z, int n ){ int i; Fts5ExprCtx sCtx; sCtx.pExpr = pExpr; sCtx.aPopulator = aPopulator; sCtx.iOff = (((i64)iCol) << 32) - 1; for(i=0; inPhrase; i++){ Fts5ExprNode *pNode = pExpr->apExprPhrase[i]->pNode; Fts5Colset *pColset = pNode->pNear->pColset; if( (pColset && 0==fts5ExprColsetTest(pColset, iCol)) || aPopulator[i].bMiss ){ aPopulator[i].bOk = 0; }else{ aPopulator[i].bOk = 1; } } return sqlite3Fts5Tokenize(pConfig, FTS5_TOKENIZE_DOCUMENT, z, n, (void*)&sCtx, fts5ExprPopulatePoslistsCb ); } static void fts5ExprClearPoslists(Fts5ExprNode *pNode){ if( pNode->eType==FTS5_TERM || pNode->eType==FTS5_STRING ){ pNode->pNear->apPhrase[0]->poslist.n = 0; }else{ int i; for(i=0; inChild; i++){ fts5ExprClearPoslists(pNode->apChild[i]); } } } static int fts5ExprCheckPoslists(Fts5ExprNode *pNode, i64 iRowid){ pNode->iRowid = iRowid; pNode->bEof = 0; switch( pNode->eType ){ case FTS5_TERM: case FTS5_STRING: return (pNode->pNear->apPhrase[0]->poslist.n>0); case FTS5_AND: { int i; for(i=0; inChild; i++){ if( fts5ExprCheckPoslists(pNode->apChild[i], iRowid)==0 ){ fts5ExprClearPoslists(pNode); return 0; } } break; } case FTS5_OR: { int i; int bRet = 0; for(i=0; inChild; i++){ if( fts5ExprCheckPoslists(pNode->apChild[i], iRowid) ){ bRet = 1; } } return bRet; } default: { assert( pNode->eType==FTS5_NOT ); if( 0==fts5ExprCheckPoslists(pNode->apChild[0], iRowid) || 0!=fts5ExprCheckPoslists(pNode->apChild[1], iRowid) ){ fts5ExprClearPoslists(pNode); return 0; } break; } } return 1; } void sqlite3Fts5ExprCheckPoslists(Fts5Expr *pExpr, i64 iRowid){ fts5ExprCheckPoslists(pExpr->pRoot, iRowid); } /* ** This function is only called for detail=columns tables. */ int sqlite3Fts5ExprPhraseCollist( Fts5Expr *pExpr, int iPhrase, const u8 **ppCollist, int *pnCollist ){ Fts5ExprPhrase *pPhrase = pExpr->apExprPhrase[iPhrase]; Fts5ExprNode *pNode = pPhrase->pNode; int rc = SQLITE_OK; assert( iPhrase>=0 && iPhrasenPhrase ); assert( pExpr->pConfig->eDetail==FTS5_DETAIL_COLUMNS ); if( pNode->bEof==0 && pNode->iRowid==pExpr->pRoot->iRowid && pPhrase->poslist.n>0 ){ Fts5ExprTerm *pTerm = &pPhrase->aTerm[0]; if( pTerm->pSynonym ){ Fts5Buffer *pBuf = (Fts5Buffer*)&pTerm->pSynonym[1]; rc = fts5ExprSynonymList( pTerm, pNode->iRowid, pBuf, (u8**)ppCollist, pnCollist ); }else{ *ppCollist = pPhrase->aTerm[0].pIter->pData; *pnCollist = pPhrase->aTerm[0].pIter->nData; } }else{ *ppCollist = 0; *pnCollist = 0; } return rc; } /* ** Does the work of the fts5_api.xQueryToken() API method. */ int sqlite3Fts5ExprQueryToken( Fts5Expr *pExpr, int iPhrase, int iToken, const char **ppOut, int *pnOut ){ Fts5ExprPhrase *pPhrase = 0; if( iPhrase<0 || iPhrase>=pExpr->nPhrase ){ return SQLITE_RANGE; } pPhrase = pExpr->apExprPhrase[iPhrase]; if( iToken<0 || iToken>=pPhrase->nTerm ){ return SQLITE_RANGE; } *ppOut = pPhrase->aTerm[iToken].pTerm; *pnOut = pPhrase->aTerm[iToken].nFullTerm; return SQLITE_OK; } /* ** Does the work of the fts5_api.xInstToken() API method. */ int sqlite3Fts5ExprInstToken( Fts5Expr *pExpr, i64 iRowid, int iPhrase, int iCol, int iOff, int iToken, const char **ppOut, int *pnOut ){ Fts5ExprPhrase *pPhrase = 0; Fts5ExprTerm *pTerm = 0; int rc = SQLITE_OK; if( iPhrase<0 || iPhrase>=pExpr->nPhrase ){ return SQLITE_RANGE; } pPhrase = pExpr->apExprPhrase[iPhrase]; if( iToken<0 || iToken>=pPhrase->nTerm ){ return SQLITE_RANGE; } pTerm = &pPhrase->aTerm[iToken]; if( pTerm->bPrefix==0 ){ if( pExpr->pConfig->bTokendata ){ rc = sqlite3Fts5IterToken( pTerm->pIter, iRowid, iCol, iOff+iToken, ppOut, pnOut ); }else{ *ppOut = pTerm->pTerm; *pnOut = pTerm->nFullTerm; } } return rc; } /* ** Clear the token mappings for all Fts5IndexIter objects mannaged by ** the expression passed as the only argument. */ void sqlite3Fts5ExprClearTokens(Fts5Expr *pExpr){ int ii; for(ii=0; iinPhrase; ii++){ Fts5ExprTerm *pT; for(pT=&pExpr->apExprPhrase[ii]->aTerm[0]; pT; pT=pT->pSynonym){ sqlite3Fts5IndexIterClearTokendata(pT->pIter); } } }