| /* |
| ** 2001 September 15 |
| ** |
| ** 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. |
| ** |
| ************************************************************************* |
| ** This file contains C code routines that are called by the parser |
| ** to handle SELECT statements in SQLite. |
| ** |
| ** $Id: select.c,v 1.161.2.4 2004/07/20 01:45:49 drh Exp $ |
| */ |
| #include "sqliteInt.h" |
| |
| |
| /* |
| ** Allocate a new Select structure and return a pointer to that |
| ** structure. |
| */ |
| Select *sqliteSelectNew( |
| ExprList *pEList, /* which columns to include in the result */ |
| SrcList *pSrc, /* the FROM clause -- which tables to scan */ |
| Expr *pWhere, /* the WHERE clause */ |
| ExprList *pGroupBy, /* the GROUP BY clause */ |
| Expr *pHaving, /* the HAVING clause */ |
| ExprList *pOrderBy, /* the ORDER BY clause */ |
| int isDistinct, /* true if the DISTINCT keyword is present */ |
| int nLimit, /* LIMIT value. -1 means not used */ |
| int nOffset /* OFFSET value. 0 means no offset */ |
| ){ |
| Select *pNew; |
| pNew = sqliteMalloc( sizeof(*pNew) ); |
| if( pNew==0 ){ |
| sqliteExprListDelete(pEList); |
| sqliteSrcListDelete(pSrc); |
| sqliteExprDelete(pWhere); |
| sqliteExprListDelete(pGroupBy); |
| sqliteExprDelete(pHaving); |
| sqliteExprListDelete(pOrderBy); |
| }else{ |
| if( pEList==0 ){ |
| pEList = sqliteExprListAppend(0, sqliteExpr(TK_ALL,0,0,0), 0); |
| } |
| pNew->pEList = pEList; |
| pNew->pSrc = pSrc; |
| pNew->pWhere = pWhere; |
| pNew->pGroupBy = pGroupBy; |
| pNew->pHaving = pHaving; |
| pNew->pOrderBy = pOrderBy; |
| pNew->isDistinct = isDistinct; |
| pNew->op = TK_SELECT; |
| pNew->nLimit = nLimit; |
| pNew->nOffset = nOffset; |
| pNew->iLimit = -1; |
| pNew->iOffset = -1; |
| } |
| return pNew; |
| } |
| |
| /* |
| ** Given 1 to 3 identifiers preceeding the JOIN keyword, determine the |
| ** type of join. Return an integer constant that expresses that type |
| ** in terms of the following bit values: |
| ** |
| ** JT_INNER |
| ** JT_OUTER |
| ** JT_NATURAL |
| ** JT_LEFT |
| ** JT_RIGHT |
| ** |
| ** A full outer join is the combination of JT_LEFT and JT_RIGHT. |
| ** |
| ** If an illegal or unsupported join type is seen, then still return |
| ** a join type, but put an error in the pParse structure. |
| */ |
| int sqliteJoinType(Parse *pParse, Token *pA, Token *pB, Token *pC){ |
| int jointype = 0; |
| Token *apAll[3]; |
| Token *p; |
| static struct { |
| const char *zKeyword; |
| int nChar; |
| int code; |
| } keywords[] = { |
| { "natural", 7, JT_NATURAL }, |
| { "left", 4, JT_LEFT|JT_OUTER }, |
| { "right", 5, JT_RIGHT|JT_OUTER }, |
| { "full", 4, JT_LEFT|JT_RIGHT|JT_OUTER }, |
| { "outer", 5, JT_OUTER }, |
| { "inner", 5, JT_INNER }, |
| { "cross", 5, JT_INNER }, |
| }; |
| int i, j; |
| apAll[0] = pA; |
| apAll[1] = pB; |
| apAll[2] = pC; |
| for(i=0; i<3 && apAll[i]; i++){ |
| p = apAll[i]; |
| for(j=0; j<sizeof(keywords)/sizeof(keywords[0]); j++){ |
| if( p->n==keywords[j].nChar |
| && sqliteStrNICmp(p->z, keywords[j].zKeyword, p->n)==0 ){ |
| jointype |= keywords[j].code; |
| break; |
| } |
| } |
| if( j>=sizeof(keywords)/sizeof(keywords[0]) ){ |
| jointype |= JT_ERROR; |
| break; |
| } |
| } |
| if( |
| (jointype & (JT_INNER|JT_OUTER))==(JT_INNER|JT_OUTER) || |
| (jointype & JT_ERROR)!=0 |
| ){ |
| static Token dummy = { 0, 0 }; |
| char *zSp1 = " ", *zSp2 = " "; |
| if( pB==0 ){ pB = &dummy; zSp1 = 0; } |
| if( pC==0 ){ pC = &dummy; zSp2 = 0; } |
| sqliteSetNString(&pParse->zErrMsg, "unknown or unsupported join type: ", 0, |
| pA->z, pA->n, zSp1, 1, pB->z, pB->n, zSp2, 1, pC->z, pC->n, 0); |
| pParse->nErr++; |
| jointype = JT_INNER; |
| }else if( jointype & JT_RIGHT ){ |
| sqliteErrorMsg(pParse, |
| "RIGHT and FULL OUTER JOINs are not currently supported"); |
| jointype = JT_INNER; |
| } |
| return jointype; |
| } |
| |
| /* |
| ** Return the index of a column in a table. Return -1 if the column |
| ** is not contained in the table. |
| */ |
| static int columnIndex(Table *pTab, const char *zCol){ |
| int i; |
| for(i=0; i<pTab->nCol; i++){ |
| if( sqliteStrICmp(pTab->aCol[i].zName, zCol)==0 ) return i; |
| } |
| return -1; |
| } |
| |
| /* |
| ** Add a term to the WHERE expression in *ppExpr that requires the |
| ** zCol column to be equal in the two tables pTab1 and pTab2. |
| */ |
| static void addWhereTerm( |
| const char *zCol, /* Name of the column */ |
| const Table *pTab1, /* First table */ |
| const Table *pTab2, /* Second table */ |
| Expr **ppExpr /* Add the equality term to this expression */ |
| ){ |
| Token dummy; |
| Expr *pE1a, *pE1b, *pE1c; |
| Expr *pE2a, *pE2b, *pE2c; |
| Expr *pE; |
| |
| dummy.z = zCol; |
| dummy.n = strlen(zCol); |
| dummy.dyn = 0; |
| pE1a = sqliteExpr(TK_ID, 0, 0, &dummy); |
| pE2a = sqliteExpr(TK_ID, 0, 0, &dummy); |
| dummy.z = pTab1->zName; |
| dummy.n = strlen(dummy.z); |
| pE1b = sqliteExpr(TK_ID, 0, 0, &dummy); |
| dummy.z = pTab2->zName; |
| dummy.n = strlen(dummy.z); |
| pE2b = sqliteExpr(TK_ID, 0, 0, &dummy); |
| pE1c = sqliteExpr(TK_DOT, pE1b, pE1a, 0); |
| pE2c = sqliteExpr(TK_DOT, pE2b, pE2a, 0); |
| pE = sqliteExpr(TK_EQ, pE1c, pE2c, 0); |
| ExprSetProperty(pE, EP_FromJoin); |
| if( *ppExpr ){ |
| *ppExpr = sqliteExpr(TK_AND, *ppExpr, pE, 0); |
| }else{ |
| *ppExpr = pE; |
| } |
| } |
| |
| /* |
| ** Set the EP_FromJoin property on all terms of the given expression. |
| ** |
| ** The EP_FromJoin property is used on terms of an expression to tell |
| ** the LEFT OUTER JOIN processing logic that this term is part of the |
| ** join restriction specified in the ON or USING clause and not a part |
| ** of the more general WHERE clause. These terms are moved over to the |
| ** WHERE clause during join processing but we need to remember that they |
| ** originated in the ON or USING clause. |
| */ |
| static void setJoinExpr(Expr *p){ |
| while( p ){ |
| ExprSetProperty(p, EP_FromJoin); |
| setJoinExpr(p->pLeft); |
| p = p->pRight; |
| } |
| } |
| |
| /* |
| ** This routine processes the join information for a SELECT statement. |
| ** ON and USING clauses are converted into extra terms of the WHERE clause. |
| ** NATURAL joins also create extra WHERE clause terms. |
| ** |
| ** This routine returns the number of errors encountered. |
| */ |
| static int sqliteProcessJoin(Parse *pParse, Select *p){ |
| SrcList *pSrc; |
| int i, j; |
| pSrc = p->pSrc; |
| for(i=0; i<pSrc->nSrc-1; i++){ |
| struct SrcList_item *pTerm = &pSrc->a[i]; |
| struct SrcList_item *pOther = &pSrc->a[i+1]; |
| |
| if( pTerm->pTab==0 || pOther->pTab==0 ) continue; |
| |
| /* When the NATURAL keyword is present, add WHERE clause terms for |
| ** every column that the two tables have in common. |
| */ |
| if( pTerm->jointype & JT_NATURAL ){ |
| Table *pTab; |
| if( pTerm->pOn || pTerm->pUsing ){ |
| sqliteErrorMsg(pParse, "a NATURAL join may not have " |
| "an ON or USING clause", 0); |
| return 1; |
| } |
| pTab = pTerm->pTab; |
| for(j=0; j<pTab->nCol; j++){ |
| if( columnIndex(pOther->pTab, pTab->aCol[j].zName)>=0 ){ |
| addWhereTerm(pTab->aCol[j].zName, pTab, pOther->pTab, &p->pWhere); |
| } |
| } |
| } |
| |
| /* Disallow both ON and USING clauses in the same join |
| */ |
| if( pTerm->pOn && pTerm->pUsing ){ |
| sqliteErrorMsg(pParse, "cannot have both ON and USING " |
| "clauses in the same join"); |
| return 1; |
| } |
| |
| /* Add the ON clause to the end of the WHERE clause, connected by |
| ** and AND operator. |
| */ |
| if( pTerm->pOn ){ |
| setJoinExpr(pTerm->pOn); |
| if( p->pWhere==0 ){ |
| p->pWhere = pTerm->pOn; |
| }else{ |
| p->pWhere = sqliteExpr(TK_AND, p->pWhere, pTerm->pOn, 0); |
| } |
| pTerm->pOn = 0; |
| } |
| |
| /* Create extra terms on the WHERE clause for each column named |
| ** in the USING clause. Example: If the two tables to be joined are |
| ** A and B and the USING clause names X, Y, and Z, then add this |
| ** to the WHERE clause: A.X=B.X AND A.Y=B.Y AND A.Z=B.Z |
| ** Report an error if any column mentioned in the USING clause is |
| ** not contained in both tables to be joined. |
| */ |
| if( pTerm->pUsing ){ |
| IdList *pList; |
| int j; |
| assert( i<pSrc->nSrc-1 ); |
| pList = pTerm->pUsing; |
| for(j=0; j<pList->nId; j++){ |
| if( columnIndex(pTerm->pTab, pList->a[j].zName)<0 || |
| columnIndex(pOther->pTab, pList->a[j].zName)<0 ){ |
| sqliteErrorMsg(pParse, "cannot join using column %s - column " |
| "not present in both tables", pList->a[j].zName); |
| return 1; |
| } |
| addWhereTerm(pList->a[j].zName, pTerm->pTab, pOther->pTab, &p->pWhere); |
| } |
| } |
| } |
| return 0; |
| } |
| |
| /* |
| ** Delete the given Select structure and all of its substructures. |
| */ |
| void sqliteSelectDelete(Select *p){ |
| if( p==0 ) return; |
| sqliteExprListDelete(p->pEList); |
| sqliteSrcListDelete(p->pSrc); |
| sqliteExprDelete(p->pWhere); |
| sqliteExprListDelete(p->pGroupBy); |
| sqliteExprDelete(p->pHaving); |
| sqliteExprListDelete(p->pOrderBy); |
| sqliteSelectDelete(p->pPrior); |
| sqliteFree(p->zSelect); |
| sqliteFree(p); |
| } |
| |
| /* |
| ** Delete the aggregate information from the parse structure. |
| */ |
| static void sqliteAggregateInfoReset(Parse *pParse){ |
| sqliteFree(pParse->aAgg); |
| pParse->aAgg = 0; |
| pParse->nAgg = 0; |
| pParse->useAgg = 0; |
| } |
| |
| /* |
| ** Insert code into "v" that will push the record on the top of the |
| ** stack into the sorter. |
| */ |
| static void pushOntoSorter(Parse *pParse, Vdbe *v, ExprList *pOrderBy){ |
| char *zSortOrder; |
| int i; |
| zSortOrder = sqliteMalloc( pOrderBy->nExpr + 1 ); |
| if( zSortOrder==0 ) return; |
| for(i=0; i<pOrderBy->nExpr; i++){ |
| int order = pOrderBy->a[i].sortOrder; |
| int type; |
| int c; |
| if( (order & SQLITE_SO_TYPEMASK)==SQLITE_SO_TEXT ){ |
| type = SQLITE_SO_TEXT; |
| }else if( (order & SQLITE_SO_TYPEMASK)==SQLITE_SO_NUM ){ |
| type = SQLITE_SO_NUM; |
| }else if( pParse->db->file_format>=4 ){ |
| type = sqliteExprType(pOrderBy->a[i].pExpr); |
| }else{ |
| type = SQLITE_SO_NUM; |
| } |
| if( (order & SQLITE_SO_DIRMASK)==SQLITE_SO_ASC ){ |
| c = type==SQLITE_SO_TEXT ? 'A' : '+'; |
| }else{ |
| c = type==SQLITE_SO_TEXT ? 'D' : '-'; |
| } |
| zSortOrder[i] = c; |
| sqliteExprCode(pParse, pOrderBy->a[i].pExpr); |
| } |
| zSortOrder[pOrderBy->nExpr] = 0; |
| sqliteVdbeOp3(v, OP_SortMakeKey, pOrderBy->nExpr, 0, zSortOrder, P3_DYNAMIC); |
| sqliteVdbeAddOp(v, OP_SortPut, 0, 0); |
| } |
| |
| /* |
| ** This routine adds a P3 argument to the last VDBE opcode that was |
| ** inserted. The P3 argument added is a string suitable for the |
| ** OP_MakeKey or OP_MakeIdxKey opcodes. The string consists of |
| ** characters 't' or 'n' depending on whether or not the various |
| ** fields of the key to be generated should be treated as numeric |
| ** or as text. See the OP_MakeKey and OP_MakeIdxKey opcode |
| ** documentation for additional information about the P3 string. |
| ** See also the sqliteAddIdxKeyType() routine. |
| */ |
| void sqliteAddKeyType(Vdbe *v, ExprList *pEList){ |
| int nColumn = pEList->nExpr; |
| char *zType = sqliteMalloc( nColumn+1 ); |
| int i; |
| if( zType==0 ) return; |
| for(i=0; i<nColumn; i++){ |
| zType[i] = sqliteExprType(pEList->a[i].pExpr)==SQLITE_SO_NUM ? 'n' : 't'; |
| } |
| zType[i] = 0; |
| sqliteVdbeChangeP3(v, -1, zType, P3_DYNAMIC); |
| } |
| |
| /* |
| ** Add code to implement the OFFSET and LIMIT |
| */ |
| static void codeLimiter( |
| Vdbe *v, /* Generate code into this VM */ |
| Select *p, /* The SELECT statement being coded */ |
| int iContinue, /* Jump here to skip the current record */ |
| int iBreak, /* Jump here to end the loop */ |
| int nPop /* Number of times to pop stack when jumping */ |
| ){ |
| if( p->iOffset>=0 ){ |
| int addr = sqliteVdbeCurrentAddr(v) + 2; |
| if( nPop>0 ) addr++; |
| sqliteVdbeAddOp(v, OP_MemIncr, p->iOffset, addr); |
| if( nPop>0 ){ |
| sqliteVdbeAddOp(v, OP_Pop, nPop, 0); |
| } |
| sqliteVdbeAddOp(v, OP_Goto, 0, iContinue); |
| } |
| if( p->iLimit>=0 ){ |
| sqliteVdbeAddOp(v, OP_MemIncr, p->iLimit, iBreak); |
| } |
| } |
| |
| /* |
| ** This routine generates the code for the inside of the inner loop |
| ** of a SELECT. |
| ** |
| ** If srcTab and nColumn are both zero, then the pEList expressions |
| ** are evaluated in order to get the data for this row. If nColumn>0 |
| ** then data is pulled from srcTab and pEList is used only to get the |
| ** datatypes for each column. |
| */ |
| static int selectInnerLoop( |
| Parse *pParse, /* The parser context */ |
| Select *p, /* The complete select statement being coded */ |
| ExprList *pEList, /* List of values being extracted */ |
| int srcTab, /* Pull data from this table */ |
| int nColumn, /* Number of columns in the source table */ |
| ExprList *pOrderBy, /* If not NULL, sort results using this key */ |
| int distinct, /* If >=0, make sure results are distinct */ |
| int eDest, /* How to dispose of the results */ |
| int iParm, /* An argument to the disposal method */ |
| int iContinue, /* Jump here to continue with next row */ |
| int iBreak /* Jump here to break out of the inner loop */ |
| ){ |
| Vdbe *v = pParse->pVdbe; |
| int i; |
| int hasDistinct; /* True if the DISTINCT keyword is present */ |
| |
| if( v==0 ) return 0; |
| assert( pEList!=0 ); |
| |
| /* If there was a LIMIT clause on the SELECT statement, then do the check |
| ** to see if this row should be output. |
| */ |
| hasDistinct = distinct>=0 && pEList && pEList->nExpr>0; |
| if( pOrderBy==0 && !hasDistinct ){ |
| codeLimiter(v, p, iContinue, iBreak, 0); |
| } |
| |
| /* Pull the requested columns. |
| */ |
| if( nColumn>0 ){ |
| for(i=0; i<nColumn; i++){ |
| sqliteVdbeAddOp(v, OP_Column, srcTab, i); |
| } |
| }else{ |
| nColumn = pEList->nExpr; |
| for(i=0; i<pEList->nExpr; i++){ |
| sqliteExprCode(pParse, pEList->a[i].pExpr); |
| } |
| } |
| |
| /* If the DISTINCT keyword was present on the SELECT statement |
| ** and this row has been seen before, then do not make this row |
| ** part of the result. |
| */ |
| if( hasDistinct ){ |
| #if NULL_ALWAYS_DISTINCT |
| sqliteVdbeAddOp(v, OP_IsNull, -pEList->nExpr, sqliteVdbeCurrentAddr(v)+7); |
| #endif |
| sqliteVdbeAddOp(v, OP_MakeKey, pEList->nExpr, 1); |
| if( pParse->db->file_format>=4 ) sqliteAddKeyType(v, pEList); |
| sqliteVdbeAddOp(v, OP_Distinct, distinct, sqliteVdbeCurrentAddr(v)+3); |
| sqliteVdbeAddOp(v, OP_Pop, pEList->nExpr+1, 0); |
| sqliteVdbeAddOp(v, OP_Goto, 0, iContinue); |
| sqliteVdbeAddOp(v, OP_String, 0, 0); |
| sqliteVdbeAddOp(v, OP_PutStrKey, distinct, 0); |
| if( pOrderBy==0 ){ |
| codeLimiter(v, p, iContinue, iBreak, nColumn); |
| } |
| } |
| |
| switch( eDest ){ |
| /* In this mode, write each query result to the key of the temporary |
| ** table iParm. |
| */ |
| case SRT_Union: { |
| sqliteVdbeAddOp(v, OP_MakeRecord, nColumn, NULL_ALWAYS_DISTINCT); |
| sqliteVdbeAddOp(v, OP_String, 0, 0); |
| sqliteVdbeAddOp(v, OP_PutStrKey, iParm, 0); |
| break; |
| } |
| |
| /* Store the result as data using a unique key. |
| */ |
| case SRT_Table: |
| case SRT_TempTable: { |
| sqliteVdbeAddOp(v, OP_MakeRecord, nColumn, 0); |
| if( pOrderBy ){ |
| pushOntoSorter(pParse, v, pOrderBy); |
| }else{ |
| sqliteVdbeAddOp(v, OP_NewRecno, iParm, 0); |
| sqliteVdbeAddOp(v, OP_Pull, 1, 0); |
| sqliteVdbeAddOp(v, OP_PutIntKey, iParm, 0); |
| } |
| break; |
| } |
| |
| /* Construct a record from the query result, but instead of |
| ** saving that record, use it as a key to delete elements from |
| ** the temporary table iParm. |
| */ |
| case SRT_Except: { |
| int addr; |
| addr = sqliteVdbeAddOp(v, OP_MakeRecord, nColumn, NULL_ALWAYS_DISTINCT); |
| sqliteVdbeAddOp(v, OP_NotFound, iParm, addr+3); |
| sqliteVdbeAddOp(v, OP_Delete, iParm, 0); |
| break; |
| } |
| |
| /* If we are creating a set for an "expr IN (SELECT ...)" construct, |
| ** then there should be a single item on the stack. Write this |
| ** item into the set table with bogus data. |
| */ |
| case SRT_Set: { |
| int addr1 = sqliteVdbeCurrentAddr(v); |
| int addr2; |
| assert( nColumn==1 ); |
| sqliteVdbeAddOp(v, OP_NotNull, -1, addr1+3); |
| sqliteVdbeAddOp(v, OP_Pop, 1, 0); |
| addr2 = sqliteVdbeAddOp(v, OP_Goto, 0, 0); |
| if( pOrderBy ){ |
| pushOntoSorter(pParse, v, pOrderBy); |
| }else{ |
| sqliteVdbeAddOp(v, OP_String, 0, 0); |
| sqliteVdbeAddOp(v, OP_PutStrKey, iParm, 0); |
| } |
| sqliteVdbeChangeP2(v, addr2, sqliteVdbeCurrentAddr(v)); |
| break; |
| } |
| |
| /* If this is a scalar select that is part of an expression, then |
| ** store the results in the appropriate memory cell and break out |
| ** of the scan loop. |
| */ |
| case SRT_Mem: { |
| assert( nColumn==1 ); |
| if( pOrderBy ){ |
| pushOntoSorter(pParse, v, pOrderBy); |
| }else{ |
| sqliteVdbeAddOp(v, OP_MemStore, iParm, 1); |
| sqliteVdbeAddOp(v, OP_Goto, 0, iBreak); |
| } |
| break; |
| } |
| |
| /* Send the data to the callback function. |
| */ |
| case SRT_Callback: |
| case SRT_Sorter: { |
| if( pOrderBy ){ |
| sqliteVdbeAddOp(v, OP_SortMakeRec, nColumn, 0); |
| pushOntoSorter(pParse, v, pOrderBy); |
| }else{ |
| assert( eDest==SRT_Callback ); |
| sqliteVdbeAddOp(v, OP_Callback, nColumn, 0); |
| } |
| break; |
| } |
| |
| /* Invoke a subroutine to handle the results. The subroutine itself |
| ** is responsible for popping the results off of the stack. |
| */ |
| case SRT_Subroutine: { |
| if( pOrderBy ){ |
| sqliteVdbeAddOp(v, OP_MakeRecord, nColumn, 0); |
| pushOntoSorter(pParse, v, pOrderBy); |
| }else{ |
| sqliteVdbeAddOp(v, OP_Gosub, 0, iParm); |
| } |
| break; |
| } |
| |
| /* Discard the results. This is used for SELECT statements inside |
| ** the body of a TRIGGER. The purpose of such selects is to call |
| ** user-defined functions that have side effects. We do not care |
| ** about the actual results of the select. |
| */ |
| default: { |
| assert( eDest==SRT_Discard ); |
| sqliteVdbeAddOp(v, OP_Pop, nColumn, 0); |
| break; |
| } |
| } |
| return 0; |
| } |
| |
| /* |
| ** If the inner loop was generated using a non-null pOrderBy argument, |
| ** then the results were placed in a sorter. After the loop is terminated |
| ** we need to run the sorter and output the results. The following |
| ** routine generates the code needed to do that. |
| */ |
| static void generateSortTail( |
| Select *p, /* The SELECT statement */ |
| Vdbe *v, /* Generate code into this VDBE */ |
| int nColumn, /* Number of columns of data */ |
| int eDest, /* Write the sorted results here */ |
| int iParm /* Optional parameter associated with eDest */ |
| ){ |
| int end1 = sqliteVdbeMakeLabel(v); |
| int end2 = sqliteVdbeMakeLabel(v); |
| int addr; |
| if( eDest==SRT_Sorter ) return; |
| sqliteVdbeAddOp(v, OP_Sort, 0, 0); |
| addr = sqliteVdbeAddOp(v, OP_SortNext, 0, end1); |
| codeLimiter(v, p, addr, end2, 1); |
| switch( eDest ){ |
| case SRT_Callback: { |
| sqliteVdbeAddOp(v, OP_SortCallback, nColumn, 0); |
| break; |
| } |
| case SRT_Table: |
| case SRT_TempTable: { |
| sqliteVdbeAddOp(v, OP_NewRecno, iParm, 0); |
| sqliteVdbeAddOp(v, OP_Pull, 1, 0); |
| sqliteVdbeAddOp(v, OP_PutIntKey, iParm, 0); |
| break; |
| } |
| case SRT_Set: { |
| assert( nColumn==1 ); |
| sqliteVdbeAddOp(v, OP_NotNull, -1, sqliteVdbeCurrentAddr(v)+3); |
| sqliteVdbeAddOp(v, OP_Pop, 1, 0); |
| sqliteVdbeAddOp(v, OP_Goto, 0, sqliteVdbeCurrentAddr(v)+3); |
| sqliteVdbeAddOp(v, OP_String, 0, 0); |
| sqliteVdbeAddOp(v, OP_PutStrKey, iParm, 0); |
| break; |
| } |
| case SRT_Mem: { |
| assert( nColumn==1 ); |
| sqliteVdbeAddOp(v, OP_MemStore, iParm, 1); |
| sqliteVdbeAddOp(v, OP_Goto, 0, end1); |
| break; |
| } |
| case SRT_Subroutine: { |
| int i; |
| for(i=0; i<nColumn; i++){ |
| sqliteVdbeAddOp(v, OP_Column, -1-i, i); |
| } |
| sqliteVdbeAddOp(v, OP_Gosub, 0, iParm); |
| sqliteVdbeAddOp(v, OP_Pop, 1, 0); |
| break; |
| } |
| default: { |
| /* Do nothing */ |
| break; |
| } |
| } |
| sqliteVdbeAddOp(v, OP_Goto, 0, addr); |
| sqliteVdbeResolveLabel(v, end2); |
| sqliteVdbeAddOp(v, OP_Pop, 1, 0); |
| sqliteVdbeResolveLabel(v, end1); |
| sqliteVdbeAddOp(v, OP_SortReset, 0, 0); |
| } |
| |
| /* |
| ** Generate code that will tell the VDBE the datatypes of |
| ** columns in the result set. |
| ** |
| ** This routine only generates code if the "PRAGMA show_datatypes=on" |
| ** has been executed. The datatypes are reported out in the azCol |
| ** parameter to the callback function. The first N azCol[] entries |
| ** are the names of the columns, and the second N entries are the |
| ** datatypes for the columns. |
| ** |
| ** The "datatype" for a result that is a column of a type is the |
| ** datatype definition extracted from the CREATE TABLE statement. |
| ** The datatype for an expression is either TEXT or NUMERIC. The |
| ** datatype for a ROWID field is INTEGER. |
| */ |
| static void generateColumnTypes( |
| Parse *pParse, /* Parser context */ |
| SrcList *pTabList, /* List of tables */ |
| ExprList *pEList /* Expressions defining the result set */ |
| ){ |
| Vdbe *v = pParse->pVdbe; |
| int i, j; |
| for(i=0; i<pEList->nExpr; i++){ |
| Expr *p = pEList->a[i].pExpr; |
| char *zType = 0; |
| if( p==0 ) continue; |
| if( p->op==TK_COLUMN && pTabList ){ |
| Table *pTab; |
| int iCol = p->iColumn; |
| for(j=0; j<pTabList->nSrc && pTabList->a[j].iCursor!=p->iTable; j++){} |
| assert( j<pTabList->nSrc ); |
| pTab = pTabList->a[j].pTab; |
| if( iCol<0 ) iCol = pTab->iPKey; |
| assert( iCol==-1 || (iCol>=0 && iCol<pTab->nCol) ); |
| if( iCol<0 ){ |
| zType = "INTEGER"; |
| }else{ |
| zType = pTab->aCol[iCol].zType; |
| } |
| }else{ |
| if( sqliteExprType(p)==SQLITE_SO_TEXT ){ |
| zType = "TEXT"; |
| }else{ |
| zType = "NUMERIC"; |
| } |
| } |
| sqliteVdbeOp3(v, OP_ColumnName, i + pEList->nExpr, 0, zType, 0); |
| } |
| } |
| |
| /* |
| ** Generate code that will tell the VDBE the names of columns |
| ** in the result set. This information is used to provide the |
| ** azCol[] values in the callback. |
| */ |
| static void generateColumnNames( |
| Parse *pParse, /* Parser context */ |
| SrcList *pTabList, /* List of tables */ |
| ExprList *pEList /* Expressions defining the result set */ |
| ){ |
| Vdbe *v = pParse->pVdbe; |
| int i, j; |
| sqlite *db = pParse->db; |
| int fullNames, shortNames; |
| |
| assert( v!=0 ); |
| if( pParse->colNamesSet || v==0 || sqlite_malloc_failed ) return; |
| pParse->colNamesSet = 1; |
| fullNames = (db->flags & SQLITE_FullColNames)!=0; |
| shortNames = (db->flags & SQLITE_ShortColNames)!=0; |
| for(i=0; i<pEList->nExpr; i++){ |
| Expr *p; |
| int p2 = i==pEList->nExpr-1; |
| p = pEList->a[i].pExpr; |
| if( p==0 ) continue; |
| if( pEList->a[i].zName ){ |
| char *zName = pEList->a[i].zName; |
| sqliteVdbeOp3(v, OP_ColumnName, i, p2, zName, 0); |
| continue; |
| } |
| if( p->op==TK_COLUMN && pTabList ){ |
| Table *pTab; |
| char *zCol; |
| int iCol = p->iColumn; |
| for(j=0; j<pTabList->nSrc && pTabList->a[j].iCursor!=p->iTable; j++){} |
| assert( j<pTabList->nSrc ); |
| pTab = pTabList->a[j].pTab; |
| if( iCol<0 ) iCol = pTab->iPKey; |
| assert( iCol==-1 || (iCol>=0 && iCol<pTab->nCol) ); |
| if( iCol<0 ){ |
| zCol = "_ROWID_"; |
| }else{ |
| zCol = pTab->aCol[iCol].zName; |
| } |
| if( !shortNames && !fullNames && p->span.z && p->span.z[0] ){ |
| int addr = sqliteVdbeOp3(v,OP_ColumnName, i, p2, p->span.z, p->span.n); |
| sqliteVdbeCompressSpace(v, addr); |
| }else if( fullNames || (!shortNames && pTabList->nSrc>1) ){ |
| char *zName = 0; |
| char *zTab; |
| |
| zTab = pTabList->a[j].zAlias; |
| if( fullNames || zTab==0 ) zTab = pTab->zName; |
| sqliteSetString(&zName, zTab, ".", zCol, 0); |
| sqliteVdbeOp3(v, OP_ColumnName, i, p2, zName, P3_DYNAMIC); |
| }else{ |
| sqliteVdbeOp3(v, OP_ColumnName, i, p2, zCol, 0); |
| } |
| }else if( p->span.z && p->span.z[0] ){ |
| int addr = sqliteVdbeOp3(v,OP_ColumnName, i, p2, p->span.z, p->span.n); |
| sqliteVdbeCompressSpace(v, addr); |
| }else{ |
| char zName[30]; |
| assert( p->op!=TK_COLUMN || pTabList==0 ); |
| sprintf(zName, "column%d", i+1); |
| sqliteVdbeOp3(v, OP_ColumnName, i, p2, zName, 0); |
| } |
| } |
| } |
| |
| /* |
| ** Name of the connection operator, used for error messages. |
| */ |
| static const char *selectOpName(int id){ |
| char *z; |
| switch( id ){ |
| case TK_ALL: z = "UNION ALL"; break; |
| case TK_INTERSECT: z = "INTERSECT"; break; |
| case TK_EXCEPT: z = "EXCEPT"; break; |
| default: z = "UNION"; break; |
| } |
| return z; |
| } |
| |
| /* |
| ** Forward declaration |
| */ |
| static int fillInColumnList(Parse*, Select*); |
| |
| /* |
| ** Given a SELECT statement, generate a Table structure that describes |
| ** the result set of that SELECT. |
| */ |
| Table *sqliteResultSetOfSelect(Parse *pParse, char *zTabName, Select *pSelect){ |
| Table *pTab; |
| int i, j; |
| ExprList *pEList; |
| Column *aCol; |
| |
| if( fillInColumnList(pParse, pSelect) ){ |
| return 0; |
| } |
| pTab = sqliteMalloc( sizeof(Table) ); |
| if( pTab==0 ){ |
| return 0; |
| } |
| pTab->zName = zTabName ? sqliteStrDup(zTabName) : 0; |
| pEList = pSelect->pEList; |
| pTab->nCol = pEList->nExpr; |
| assert( pTab->nCol>0 ); |
| pTab->aCol = aCol = sqliteMalloc( sizeof(pTab->aCol[0])*pTab->nCol ); |
| for(i=0; i<pTab->nCol; i++){ |
| Expr *p, *pR; |
| if( pEList->a[i].zName ){ |
| aCol[i].zName = sqliteStrDup(pEList->a[i].zName); |
| }else if( (p=pEList->a[i].pExpr)->op==TK_DOT |
| && (pR=p->pRight)!=0 && pR->token.z && pR->token.z[0] ){ |
| int cnt; |
| sqliteSetNString(&aCol[i].zName, pR->token.z, pR->token.n, 0); |
| for(j=cnt=0; j<i; j++){ |
| if( sqliteStrICmp(aCol[j].zName, aCol[i].zName)==0 ){ |
| int n; |
| char zBuf[30]; |
| sprintf(zBuf,"_%d",++cnt); |
| n = strlen(zBuf); |
| sqliteSetNString(&aCol[i].zName, pR->token.z, pR->token.n, zBuf, n,0); |
| j = -1; |
| } |
| } |
| }else if( p->span.z && p->span.z[0] ){ |
| sqliteSetNString(&pTab->aCol[i].zName, p->span.z, p->span.n, 0); |
| }else{ |
| char zBuf[30]; |
| sprintf(zBuf, "column%d", i+1); |
| aCol[i].zName = sqliteStrDup(zBuf); |
| } |
| sqliteDequote(aCol[i].zName); |
| } |
| pTab->iPKey = -1; |
| return pTab; |
| } |
| |
| /* |
| ** For the given SELECT statement, do three things. |
| ** |
| ** (1) Fill in the pTabList->a[].pTab fields in the SrcList that |
| ** defines the set of tables that should be scanned. For views, |
| ** fill pTabList->a[].pSelect with a copy of the SELECT statement |
| ** that implements the view. A copy is made of the view's SELECT |
| ** statement so that we can freely modify or delete that statement |
| ** without worrying about messing up the presistent representation |
| ** of the view. |
| ** |
| ** (2) Add terms to the WHERE clause to accomodate the NATURAL keyword |
| ** on joins and the ON and USING clause of joins. |
| ** |
| ** (3) Scan the list of columns in the result set (pEList) looking |
| ** for instances of the "*" operator or the TABLE.* operator. |
| ** If found, expand each "*" to be every column in every table |
| ** and TABLE.* to be every column in TABLE. |
| ** |
| ** Return 0 on success. If there are problems, leave an error message |
| ** in pParse and return non-zero. |
| */ |
| static int fillInColumnList(Parse *pParse, Select *p){ |
| int i, j, k, rc; |
| SrcList *pTabList; |
| ExprList *pEList; |
| Table *pTab; |
| |
| if( p==0 || p->pSrc==0 ) return 1; |
| pTabList = p->pSrc; |
| pEList = p->pEList; |
| |
| /* Look up every table in the table list. |
| */ |
| for(i=0; i<pTabList->nSrc; i++){ |
| if( pTabList->a[i].pTab ){ |
| /* This routine has run before! No need to continue */ |
| return 0; |
| } |
| if( pTabList->a[i].zName==0 ){ |
| /* A sub-query in the FROM clause of a SELECT */ |
| assert( pTabList->a[i].pSelect!=0 ); |
| if( pTabList->a[i].zAlias==0 ){ |
| char zFakeName[60]; |
| sprintf(zFakeName, "sqlite_subquery_%p_", |
| (void*)pTabList->a[i].pSelect); |
| sqliteSetString(&pTabList->a[i].zAlias, zFakeName, 0); |
| } |
| pTabList->a[i].pTab = pTab = |
| sqliteResultSetOfSelect(pParse, pTabList->a[i].zAlias, |
| pTabList->a[i].pSelect); |
| if( pTab==0 ){ |
| return 1; |
| } |
| /* The isTransient flag indicates that the Table structure has been |
| ** dynamically allocated and may be freed at any time. In other words, |
| ** pTab is not pointing to a persistent table structure that defines |
| ** part of the schema. */ |
| pTab->isTransient = 1; |
| }else{ |
| /* An ordinary table or view name in the FROM clause */ |
| pTabList->a[i].pTab = pTab = |
| sqliteLocateTable(pParse,pTabList->a[i].zName,pTabList->a[i].zDatabase); |
| if( pTab==0 ){ |
| return 1; |
| } |
| if( pTab->pSelect ){ |
| /* We reach here if the named table is a really a view */ |
| if( sqliteViewGetColumnNames(pParse, pTab) ){ |
| return 1; |
| } |
| /* If pTabList->a[i].pSelect!=0 it means we are dealing with a |
| ** view within a view. The SELECT structure has already been |
| ** copied by the outer view so we can skip the copy step here |
| ** in the inner view. |
| */ |
| if( pTabList->a[i].pSelect==0 ){ |
| pTabList->a[i].pSelect = sqliteSelectDup(pTab->pSelect); |
| } |
| } |
| } |
| } |
| |
| /* Process NATURAL keywords, and ON and USING clauses of joins. |
| */ |
| if( sqliteProcessJoin(pParse, p) ) return 1; |
| |
| /* For every "*" that occurs in the column list, insert the names of |
| ** all columns in all tables. And for every TABLE.* insert the names |
| ** of all columns in TABLE. The parser inserted a special expression |
| ** with the TK_ALL operator for each "*" that it found in the column list. |
| ** The following code just has to locate the TK_ALL expressions and expand |
| ** each one to the list of all columns in all tables. |
| ** |
| ** The first loop just checks to see if there are any "*" operators |
| ** that need expanding. |
| */ |
| for(k=0; k<pEList->nExpr; k++){ |
| Expr *pE = pEList->a[k].pExpr; |
| if( pE->op==TK_ALL ) break; |
| if( pE->op==TK_DOT && pE->pRight && pE->pRight->op==TK_ALL |
| && pE->pLeft && pE->pLeft->op==TK_ID ) break; |
| } |
| rc = 0; |
| if( k<pEList->nExpr ){ |
| /* |
| ** If we get here it means the result set contains one or more "*" |
| ** operators that need to be expanded. Loop through each expression |
| ** in the result set and expand them one by one. |
| */ |
| struct ExprList_item *a = pEList->a; |
| ExprList *pNew = 0; |
| for(k=0; k<pEList->nExpr; k++){ |
| Expr *pE = a[k].pExpr; |
| if( pE->op!=TK_ALL && |
| (pE->op!=TK_DOT || pE->pRight==0 || pE->pRight->op!=TK_ALL) ){ |
| /* This particular expression does not need to be expanded. |
| */ |
| pNew = sqliteExprListAppend(pNew, a[k].pExpr, 0); |
| pNew->a[pNew->nExpr-1].zName = a[k].zName; |
| a[k].pExpr = 0; |
| a[k].zName = 0; |
| }else{ |
| /* This expression is a "*" or a "TABLE.*" and needs to be |
| ** expanded. */ |
| int tableSeen = 0; /* Set to 1 when TABLE matches */ |
| char *zTName; /* text of name of TABLE */ |
| if( pE->op==TK_DOT && pE->pLeft ){ |
| zTName = sqliteTableNameFromToken(&pE->pLeft->token); |
| }else{ |
| zTName = 0; |
| } |
| for(i=0; i<pTabList->nSrc; i++){ |
| Table *pTab = pTabList->a[i].pTab; |
| char *zTabName = pTabList->a[i].zAlias; |
| if( zTabName==0 || zTabName[0]==0 ){ |
| zTabName = pTab->zName; |
| } |
| if( zTName && (zTabName==0 || zTabName[0]==0 || |
| sqliteStrICmp(zTName, zTabName)!=0) ){ |
| continue; |
| } |
| tableSeen = 1; |
| for(j=0; j<pTab->nCol; j++){ |
| Expr *pExpr, *pLeft, *pRight; |
| char *zName = pTab->aCol[j].zName; |
| |
| if( i>0 && (pTabList->a[i-1].jointype & JT_NATURAL)!=0 && |
| columnIndex(pTabList->a[i-1].pTab, zName)>=0 ){ |
| /* In a NATURAL join, omit the join columns from the |
| ** table on the right */ |
| continue; |
| } |
| if( i>0 && sqliteIdListIndex(pTabList->a[i-1].pUsing, zName)>=0 ){ |
| /* In a join with a USING clause, omit columns in the |
| ** using clause from the table on the right. */ |
| continue; |
| } |
| pRight = sqliteExpr(TK_ID, 0, 0, 0); |
| if( pRight==0 ) break; |
| pRight->token.z = zName; |
| pRight->token.n = strlen(zName); |
| pRight->token.dyn = 0; |
| if( zTabName && pTabList->nSrc>1 ){ |
| pLeft = sqliteExpr(TK_ID, 0, 0, 0); |
| pExpr = sqliteExpr(TK_DOT, pLeft, pRight, 0); |
| if( pExpr==0 ) break; |
| pLeft->token.z = zTabName; |
| pLeft->token.n = strlen(zTabName); |
| pLeft->token.dyn = 0; |
| sqliteSetString((char**)&pExpr->span.z, zTabName, ".", zName, 0); |
| pExpr->span.n = strlen(pExpr->span.z); |
| pExpr->span.dyn = 1; |
| pExpr->token.z = 0; |
| pExpr->token.n = 0; |
| pExpr->token.dyn = 0; |
| }else{ |
| pExpr = pRight; |
| pExpr->span = pExpr->token; |
| } |
| pNew = sqliteExprListAppend(pNew, pExpr, 0); |
| } |
| } |
| if( !tableSeen ){ |
| if( zTName ){ |
| sqliteErrorMsg(pParse, "no such table: %s", zTName); |
| }else{ |
| sqliteErrorMsg(pParse, "no tables specified"); |
| } |
| rc = 1; |
| } |
| sqliteFree(zTName); |
| } |
| } |
| sqliteExprListDelete(pEList); |
| p->pEList = pNew; |
| } |
| return rc; |
| } |
| |
| /* |
| ** This routine recursively unlinks the Select.pSrc.a[].pTab pointers |
| ** in a select structure. It just sets the pointers to NULL. This |
| ** routine is recursive in the sense that if the Select.pSrc.a[].pSelect |
| ** pointer is not NULL, this routine is called recursively on that pointer. |
| ** |
| ** This routine is called on the Select structure that defines a |
| ** VIEW in order to undo any bindings to tables. This is necessary |
| ** because those tables might be DROPed by a subsequent SQL command. |
| ** If the bindings are not removed, then the Select.pSrc->a[].pTab field |
| ** will be left pointing to a deallocated Table structure after the |
| ** DROP and a coredump will occur the next time the VIEW is used. |
| */ |
| void sqliteSelectUnbind(Select *p){ |
| int i; |
| SrcList *pSrc = p->pSrc; |
| Table *pTab; |
| if( p==0 ) return; |
| for(i=0; i<pSrc->nSrc; i++){ |
| if( (pTab = pSrc->a[i].pTab)!=0 ){ |
| if( pTab->isTransient ){ |
| sqliteDeleteTable(0, pTab); |
| } |
| pSrc->a[i].pTab = 0; |
| if( pSrc->a[i].pSelect ){ |
| sqliteSelectUnbind(pSrc->a[i].pSelect); |
| } |
| } |
| } |
| } |
| |
| /* |
| ** This routine associates entries in an ORDER BY expression list with |
| ** columns in a result. For each ORDER BY expression, the opcode of |
| ** the top-level node is changed to TK_COLUMN and the iColumn value of |
| ** the top-level node is filled in with column number and the iTable |
| ** value of the top-level node is filled with iTable parameter. |
| ** |
| ** If there are prior SELECT clauses, they are processed first. A match |
| ** in an earlier SELECT takes precedence over a later SELECT. |
| ** |
| ** Any entry that does not match is flagged as an error. The number |
| ** of errors is returned. |
| ** |
| ** This routine does NOT correctly initialize the Expr.dataType field |
| ** of the ORDER BY expressions. The multiSelectSortOrder() routine |
| ** must be called to do that after the individual select statements |
| ** have all been analyzed. This routine is unable to compute Expr.dataType |
| ** because it must be called before the individual select statements |
| ** have been analyzed. |
| */ |
| static int matchOrderbyToColumn( |
| Parse *pParse, /* A place to leave error messages */ |
| Select *pSelect, /* Match to result columns of this SELECT */ |
| ExprList *pOrderBy, /* The ORDER BY values to match against columns */ |
| int iTable, /* Insert this value in iTable */ |
| int mustComplete /* If TRUE all ORDER BYs must match */ |
| ){ |
| int nErr = 0; |
| int i, j; |
| ExprList *pEList; |
| |
| if( pSelect==0 || pOrderBy==0 ) return 1; |
| if( mustComplete ){ |
| for(i=0; i<pOrderBy->nExpr; i++){ pOrderBy->a[i].done = 0; } |
| } |
| if( fillInColumnList(pParse, pSelect) ){ |
| return 1; |
| } |
| if( pSelect->pPrior ){ |
| if( matchOrderbyToColumn(pParse, pSelect->pPrior, pOrderBy, iTable, 0) ){ |
| return 1; |
| } |
| } |
| pEList = pSelect->pEList; |
| for(i=0; i<pOrderBy->nExpr; i++){ |
| Expr *pE = pOrderBy->a[i].pExpr; |
| int iCol = -1; |
| if( pOrderBy->a[i].done ) continue; |
| if( sqliteExprIsInteger(pE, &iCol) ){ |
| if( iCol<=0 || iCol>pEList->nExpr ){ |
| sqliteErrorMsg(pParse, |
| "ORDER BY position %d should be between 1 and %d", |
| iCol, pEList->nExpr); |
| nErr++; |
| break; |
| } |
| if( !mustComplete ) continue; |
| iCol--; |
| } |
| for(j=0; iCol<0 && j<pEList->nExpr; j++){ |
| if( pEList->a[j].zName && (pE->op==TK_ID || pE->op==TK_STRING) ){ |
| char *zName, *zLabel; |
| zName = pEList->a[j].zName; |
| assert( pE->token.z ); |
| zLabel = sqliteStrNDup(pE->token.z, pE->token.n); |
| sqliteDequote(zLabel); |
| if( sqliteStrICmp(zName, zLabel)==0 ){ |
| iCol = j; |
| } |
| sqliteFree(zLabel); |
| } |
| if( iCol<0 && sqliteExprCompare(pE, pEList->a[j].pExpr) ){ |
| iCol = j; |
| } |
| } |
| if( iCol>=0 ){ |
| pE->op = TK_COLUMN; |
| pE->iColumn = iCol; |
| pE->iTable = iTable; |
| pOrderBy->a[i].done = 1; |
| } |
| if( iCol<0 && mustComplete ){ |
| sqliteErrorMsg(pParse, |
| "ORDER BY term number %d does not match any result column", i+1); |
| nErr++; |
| break; |
| } |
| } |
| return nErr; |
| } |
| |
| /* |
| ** Get a VDBE for the given parser context. Create a new one if necessary. |
| ** If an error occurs, return NULL and leave a message in pParse. |
| */ |
| Vdbe *sqliteGetVdbe(Parse *pParse){ |
| Vdbe *v = pParse->pVdbe; |
| if( v==0 ){ |
| v = pParse->pVdbe = sqliteVdbeCreate(pParse->db); |
| } |
| return v; |
| } |
| |
| /* |
| ** This routine sets the Expr.dataType field on all elements of |
| ** the pOrderBy expression list. The pOrderBy list will have been |
| ** set up by matchOrderbyToColumn(). Hence each expression has |
| ** a TK_COLUMN as its root node. The Expr.iColumn refers to a |
| ** column in the result set. The datatype is set to SQLITE_SO_TEXT |
| ** if the corresponding column in p and every SELECT to the left of |
| ** p has a datatype of SQLITE_SO_TEXT. If the cooressponding column |
| ** in p or any of the left SELECTs is SQLITE_SO_NUM, then the datatype |
| ** of the order-by expression is set to SQLITE_SO_NUM. |
| ** |
| ** Examples: |
| ** |
| ** CREATE TABLE one(a INTEGER, b TEXT); |
| ** CREATE TABLE two(c VARCHAR(5), d FLOAT); |
| ** |
| ** SELECT b, b FROM one UNION SELECT d, c FROM two ORDER BY 1, 2; |
| ** |
| ** The primary sort key will use SQLITE_SO_NUM because the "d" in |
| ** the second SELECT is numeric. The 1st column of the first SELECT |
| ** is text but that does not matter because a numeric always overrides |
| ** a text. |
| ** |
| ** The secondary key will use the SQLITE_SO_TEXT sort order because |
| ** both the (second) "b" in the first SELECT and the "c" in the second |
| ** SELECT have a datatype of text. |
| */ |
| static void multiSelectSortOrder(Select *p, ExprList *pOrderBy){ |
| int i; |
| ExprList *pEList; |
| if( pOrderBy==0 ) return; |
| if( p==0 ){ |
| for(i=0; i<pOrderBy->nExpr; i++){ |
| pOrderBy->a[i].pExpr->dataType = SQLITE_SO_TEXT; |
| } |
| return; |
| } |
| multiSelectSortOrder(p->pPrior, pOrderBy); |
| pEList = p->pEList; |
| for(i=0; i<pOrderBy->nExpr; i++){ |
| Expr *pE = pOrderBy->a[i].pExpr; |
| if( pE->dataType==SQLITE_SO_NUM ) continue; |
| assert( pE->iColumn>=0 ); |
| if( pEList->nExpr>pE->iColumn ){ |
| pE->dataType = sqliteExprType(pEList->a[pE->iColumn].pExpr); |
| } |
| } |
| } |
| |
| /* |
| ** Compute the iLimit and iOffset fields of the SELECT based on the |
| ** nLimit and nOffset fields. nLimit and nOffset hold the integers |
| ** that appear in the original SQL statement after the LIMIT and OFFSET |
| ** keywords. Or that hold -1 and 0 if those keywords are omitted. |
| ** iLimit and iOffset are the integer memory register numbers for |
| ** counters used to compute the limit and offset. If there is no |
| ** limit and/or offset, then iLimit and iOffset are negative. |
| ** |
| ** This routine changes the values if iLimit and iOffset only if |
| ** a limit or offset is defined by nLimit and nOffset. iLimit and |
| ** iOffset should have been preset to appropriate default values |
| ** (usually but not always -1) prior to calling this routine. |
| ** Only if nLimit>=0 or nOffset>0 do the limit registers get |
| ** redefined. The UNION ALL operator uses this property to force |
| ** the reuse of the same limit and offset registers across multiple |
| ** SELECT statements. |
| */ |
| static void computeLimitRegisters(Parse *pParse, Select *p){ |
| /* |
| ** If the comparison is p->nLimit>0 then "LIMIT 0" shows |
| ** all rows. It is the same as no limit. If the comparision is |
| ** p->nLimit>=0 then "LIMIT 0" show no rows at all. |
| ** "LIMIT -1" always shows all rows. There is some |
| ** contraversy about what the correct behavior should be. |
| ** The current implementation interprets "LIMIT 0" to mean |
| ** no rows. |
| */ |
| if( p->nLimit>=0 ){ |
| int iMem = pParse->nMem++; |
| Vdbe *v = sqliteGetVdbe(pParse); |
| if( v==0 ) return; |
| sqliteVdbeAddOp(v, OP_Integer, -p->nLimit, 0); |
| sqliteVdbeAddOp(v, OP_MemStore, iMem, 1); |
| p->iLimit = iMem; |
| } |
| if( p->nOffset>0 ){ |
| int iMem = pParse->nMem++; |
| Vdbe *v = sqliteGetVdbe(pParse); |
| if( v==0 ) return; |
| sqliteVdbeAddOp(v, OP_Integer, -p->nOffset, 0); |
| sqliteVdbeAddOp(v, OP_MemStore, iMem, 1); |
| p->iOffset = iMem; |
| } |
| } |
| |
| /* |
| ** This routine is called to process a query that is really the union |
| ** or intersection of two or more separate queries. |
| ** |
| ** "p" points to the right-most of the two queries. the query on the |
| ** left is p->pPrior. The left query could also be a compound query |
| ** in which case this routine will be called recursively. |
| ** |
| ** The results of the total query are to be written into a destination |
| ** of type eDest with parameter iParm. |
| ** |
| ** Example 1: Consider a three-way compound SQL statement. |
| ** |
| ** SELECT a FROM t1 UNION SELECT b FROM t2 UNION SELECT c FROM t3 |
| ** |
| ** This statement is parsed up as follows: |
| ** |
| ** SELECT c FROM t3 |
| ** | |
| ** `-----> SELECT b FROM t2 |
| ** | |
| ** `------> SELECT a FROM t1 |
| ** |
| ** The arrows in the diagram above represent the Select.pPrior pointer. |
| ** So if this routine is called with p equal to the t3 query, then |
| ** pPrior will be the t2 query. p->op will be TK_UNION in this case. |
| ** |
| ** Notice that because of the way SQLite parses compound SELECTs, the |
| ** individual selects always group from left to right. |
| */ |
| static int multiSelect(Parse *pParse, Select *p, int eDest, int iParm){ |
| int rc; /* Success code from a subroutine */ |
| Select *pPrior; /* Another SELECT immediately to our left */ |
| Vdbe *v; /* Generate code to this VDBE */ |
| |
| /* Make sure there is no ORDER BY or LIMIT clause on prior SELECTs. Only |
| ** the last SELECT in the series may have an ORDER BY or LIMIT. |
| */ |
| if( p==0 || p->pPrior==0 ) return 1; |
| pPrior = p->pPrior; |
| if( pPrior->pOrderBy ){ |
| sqliteErrorMsg(pParse,"ORDER BY clause should come after %s not before", |
| selectOpName(p->op)); |
| return 1; |
| } |
| if( pPrior->nLimit>=0 || pPrior->nOffset>0 ){ |
| sqliteErrorMsg(pParse,"LIMIT clause should come after %s not before", |
| selectOpName(p->op)); |
| return 1; |
| } |
| |
| /* Make sure we have a valid query engine. If not, create a new one. |
| */ |
| v = sqliteGetVdbe(pParse); |
| if( v==0 ) return 1; |
| |
| /* Create the destination temporary table if necessary |
| */ |
| if( eDest==SRT_TempTable ){ |
| sqliteVdbeAddOp(v, OP_OpenTemp, iParm, 0); |
| eDest = SRT_Table; |
| } |
| |
| /* Generate code for the left and right SELECT statements. |
| */ |
| switch( p->op ){ |
| case TK_ALL: { |
| if( p->pOrderBy==0 ){ |
| pPrior->nLimit = p->nLimit; |
| pPrior->nOffset = p->nOffset; |
| rc = sqliteSelect(pParse, pPrior, eDest, iParm, 0, 0, 0); |
| if( rc ) return rc; |
| p->pPrior = 0; |
| p->iLimit = pPrior->iLimit; |
| p->iOffset = pPrior->iOffset; |
| p->nLimit = -1; |
| p->nOffset = 0; |
| rc = sqliteSelect(pParse, p, eDest, iParm, 0, 0, 0); |
| p->pPrior = pPrior; |
| if( rc ) return rc; |
| break; |
| } |
| /* For UNION ALL ... ORDER BY fall through to the next case */ |
| } |
| case TK_EXCEPT: |
| case TK_UNION: { |
| int unionTab; /* Cursor number of the temporary table holding result */ |
| int op; /* One of the SRT_ operations to apply to self */ |
| int priorOp; /* The SRT_ operation to apply to prior selects */ |
| int nLimit, nOffset; /* Saved values of p->nLimit and p->nOffset */ |
| ExprList *pOrderBy; /* The ORDER BY clause for the right SELECT */ |
| |
| priorOp = p->op==TK_ALL ? SRT_Table : SRT_Union; |
| if( eDest==priorOp && p->pOrderBy==0 && p->nLimit<0 && p->nOffset==0 ){ |
| /* We can reuse a temporary table generated by a SELECT to our |
| ** right. |
| */ |
| unionTab = iParm; |
| }else{ |
| /* We will need to create our own temporary table to hold the |
| ** intermediate results. |
| */ |
| unionTab = pParse->nTab++; |
| if( p->pOrderBy |
| && matchOrderbyToColumn(pParse, p, p->pOrderBy, unionTab, 1) ){ |
| return 1; |
| } |
| if( p->op!=TK_ALL ){ |
| sqliteVdbeAddOp(v, OP_OpenTemp, unionTab, 1); |
| sqliteVdbeAddOp(v, OP_KeyAsData, unionTab, 1); |
| }else{ |
| sqliteVdbeAddOp(v, OP_OpenTemp, unionTab, 0); |
| } |
| } |
| |
| /* Code the SELECT statements to our left |
| */ |
| rc = sqliteSelect(pParse, pPrior, priorOp, unionTab, 0, 0, 0); |
| if( rc ) return rc; |
| |
| /* Code the current SELECT statement |
| */ |
| switch( p->op ){ |
| case TK_EXCEPT: op = SRT_Except; break; |
| case TK_UNION: op = SRT_Union; break; |
| case TK_ALL: op = SRT_Table; break; |
| } |
| p->pPrior = 0; |
| pOrderBy = p->pOrderBy; |
| p->pOrderBy = 0; |
| nLimit = p->nLimit; |
| p->nLimit = -1; |
| nOffset = p->nOffset; |
| p->nOffset = 0; |
| rc = sqliteSelect(pParse, p, op, unionTab, 0, 0, 0); |
| p->pPrior = pPrior; |
| p->pOrderBy = pOrderBy; |
| p->nLimit = nLimit; |
| p->nOffset = nOffset; |
| if( rc ) return rc; |
| |
| /* Convert the data in the temporary table into whatever form |
| ** it is that we currently need. |
| */ |
| if( eDest!=priorOp || unionTab!=iParm ){ |
| int iCont, iBreak, iStart; |
| assert( p->pEList ); |
| if( eDest==SRT_Callback ){ |
| generateColumnNames(pParse, 0, p->pEList); |
| generateColumnTypes(pParse, p->pSrc, p->pEList); |
| } |
| iBreak = sqliteVdbeMakeLabel(v); |
| iCont = sqliteVdbeMakeLabel(v); |
| sqliteVdbeAddOp(v, OP_Rewind, unionTab, iBreak); |
| computeLimitRegisters(pParse, p); |
| iStart = sqliteVdbeCurrentAddr(v); |
| multiSelectSortOrder(p, p->pOrderBy); |
| rc = selectInnerLoop(pParse, p, p->pEList, unionTab, p->pEList->nExpr, |
| p->pOrderBy, -1, eDest, iParm, |
| iCont, iBreak); |
| if( rc ) return 1; |
| sqliteVdbeResolveLabel(v, iCont); |
| sqliteVdbeAddOp(v, OP_Next, unionTab, iStart); |
| sqliteVdbeResolveLabel(v, iBreak); |
| sqliteVdbeAddOp(v, OP_Close, unionTab, 0); |
| if( p->pOrderBy ){ |
| generateSortTail(p, v, p->pEList->nExpr, eDest, iParm); |
| } |
| } |
| break; |
| } |
| case TK_INTERSECT: { |
| int tab1, tab2; |
| int iCont, iBreak, iStart; |
| int nLimit, nOffset; |
| |
| /* INTERSECT is different from the others since it requires |
| ** two temporary tables. Hence it has its own case. Begin |
| ** by allocating the tables we will need. |
| */ |
| tab1 = pParse->nTab++; |
| tab2 = pParse->nTab++; |
| if( p->pOrderBy && matchOrderbyToColumn(pParse,p,p->pOrderBy,tab1,1) ){ |
| return 1; |
| } |
| sqliteVdbeAddOp(v, OP_OpenTemp, tab1, 1); |
| sqliteVdbeAddOp(v, OP_KeyAsData, tab1, 1); |
| |
| /* Code the SELECTs to our left into temporary table "tab1". |
| */ |
| rc = sqliteSelect(pParse, pPrior, SRT_Union, tab1, 0, 0, 0); |
| if( rc ) return rc; |
| |
| /* Code the current SELECT into temporary table "tab2" |
| */ |
| sqliteVdbeAddOp(v, OP_OpenTemp, tab2, 1); |
| sqliteVdbeAddOp(v, OP_KeyAsData, tab2, 1); |
| p->pPrior = 0; |
| nLimit = p->nLimit; |
| p->nLimit = -1; |
| nOffset = p->nOffset; |
| p->nOffset = 0; |
| rc = sqliteSelect(pParse, p, SRT_Union, tab2, 0, 0, 0); |
| p->pPrior = pPrior; |
| p->nLimit = nLimit; |
| p->nOffset = nOffset; |
| if( rc ) return rc; |
| |
| /* Generate code to take the intersection of the two temporary |
| ** tables. |
| */ |
| assert( p->pEList ); |
| if( eDest==SRT_Callback ){ |
| generateColumnNames(pParse, 0, p->pEList); |
| generateColumnTypes(pParse, p->pSrc, p->pEList); |
| } |
| iBreak = sqliteVdbeMakeLabel(v); |
| iCont = sqliteVdbeMakeLabel(v); |
| sqliteVdbeAddOp(v, OP_Rewind, tab1, iBreak); |
| computeLimitRegisters(pParse, p); |
| iStart = sqliteVdbeAddOp(v, OP_FullKey, tab1, 0); |
| sqliteVdbeAddOp(v, OP_NotFound, tab2, iCont); |
| multiSelectSortOrder(p, p->pOrderBy); |
| rc = selectInnerLoop(pParse, p, p->pEList, tab1, p->pEList->nExpr, |
| p->pOrderBy, -1, eDest, iParm, |
| iCont, iBreak); |
| if( rc ) return 1; |
| sqliteVdbeResolveLabel(v, iCont); |
| sqliteVdbeAddOp(v, OP_Next, tab1, iStart); |
| sqliteVdbeResolveLabel(v, iBreak); |
| sqliteVdbeAddOp(v, OP_Close, tab2, 0); |
| sqliteVdbeAddOp(v, OP_Close, tab1, 0); |
| if( p->pOrderBy ){ |
| generateSortTail(p, v, p->pEList->nExpr, eDest, iParm); |
| } |
| break; |
| } |
| } |
| assert( p->pEList && pPrior->pEList ); |
| if( p->pEList->nExpr!=pPrior->pEList->nExpr ){ |
| sqliteErrorMsg(pParse, "SELECTs to the left and right of %s" |
| " do not have the same number of result columns", selectOpName(p->op)); |
| return 1; |
| } |
| return 0; |
| } |
| |
| /* |
| ** Scan through the expression pExpr. Replace every reference to |
| ** a column in table number iTable with a copy of the iColumn-th |
| ** entry in pEList. (But leave references to the ROWID column |
| ** unchanged.) |
| ** |
| ** This routine is part of the flattening procedure. A subquery |
| ** whose result set is defined by pEList appears as entry in the |
| ** FROM clause of a SELECT such that the VDBE cursor assigned to that |
| ** FORM clause entry is iTable. This routine make the necessary |
| ** changes to pExpr so that it refers directly to the source table |
| ** of the subquery rather the result set of the subquery. |
| */ |
| static void substExprList(ExprList*,int,ExprList*); /* Forward Decl */ |
| static void substExpr(Expr *pExpr, int iTable, ExprList *pEList){ |
| if( pExpr==0 ) return; |
| if( pExpr->op==TK_COLUMN && pExpr->iTable==iTable ){ |
| if( pExpr->iColumn<0 ){ |
| pExpr->op = TK_NULL; |
| }else{ |
| Expr *pNew; |
| assert( pEList!=0 && pExpr->iColumn<pEList->nExpr ); |
| assert( pExpr->pLeft==0 && pExpr->pRight==0 && pExpr->pList==0 ); |
| pNew = pEList->a[pExpr->iColumn].pExpr; |
| assert( pNew!=0 ); |
| pExpr->op = pNew->op; |
| pExpr->dataType = pNew->dataType; |
| assert( pExpr->pLeft==0 ); |
| pExpr->pLeft = sqliteExprDup(pNew->pLeft); |
| assert( pExpr->pRight==0 ); |
| pExpr->pRight = sqliteExprDup(pNew->pRight); |
| assert( pExpr->pList==0 ); |
| pExpr->pList = sqliteExprListDup(pNew->pList); |
| pExpr->iTable = pNew->iTable; |
| pExpr->iColumn = pNew->iColumn; |
| pExpr->iAgg = pNew->iAgg; |
| sqliteTokenCopy(&pExpr->token, &pNew->token); |
| sqliteTokenCopy(&pExpr->span, &pNew->span); |
| } |
| }else{ |
| substExpr(pExpr->pLeft, iTable, pEList); |
| substExpr(pExpr->pRight, iTable, pEList); |
| substExprList(pExpr->pList, iTable, pEList); |
| } |
| } |
| static void |
| substExprList(ExprList *pList, int iTable, ExprList *pEList){ |
| int i; |
| if( pList==0 ) return; |
| for(i=0; i<pList->nExpr; i++){ |
| substExpr(pList->a[i].pExpr, iTable, pEList); |
| } |
| } |
| |
| /* |
| ** This routine attempts to flatten subqueries in order to speed |
| ** execution. It returns 1 if it makes changes and 0 if no flattening |
| ** occurs. |
| ** |
| ** To understand the concept of flattening, consider the following |
| ** query: |
| ** |
| ** SELECT a FROM (SELECT x+y AS a FROM t1 WHERE z<100) WHERE a>5 |
| ** |
| ** The default way of implementing this query is to execute the |
| ** subquery first and store the results in a temporary table, then |
| ** run the outer query on that temporary table. This requires two |
| ** passes over the data. Furthermore, because the temporary table |
| ** has no indices, the WHERE clause on the outer query cannot be |
| ** optimized. |
| ** |
| ** This routine attempts to rewrite queries such as the above into |
| ** a single flat select, like this: |
| ** |
| ** SELECT x+y AS a FROM t1 WHERE z<100 AND a>5 |
| ** |
| ** The code generated for this simpification gives the same result |
| ** but only has to scan the data once. And because indices might |
| ** exist on the table t1, a complete scan of the data might be |
| ** avoided. |
| ** |
| ** Flattening is only attempted if all of the following are true: |
| ** |
| ** (1) The subquery and the outer query do not both use aggregates. |
| ** |
| ** (2) The subquery is not an aggregate or the outer query is not a join. |
| ** |
| ** (3) The subquery is not the right operand of a left outer join, or |
| ** the subquery is not itself a join. (Ticket #306) |
| ** |
| ** (4) The subquery is not DISTINCT or the outer query is not a join. |
| ** |
| ** (5) The subquery is not DISTINCT or the outer query does not use |
| ** aggregates. |
| ** |
| ** (6) The subquery does not use aggregates or the outer query is not |
| ** DISTINCT. |
| ** |
| ** (7) The subquery has a FROM clause. |
| ** |
| ** (8) The subquery does not use LIMIT or the outer query is not a join. |
| ** |
| ** (9) The subquery does not use LIMIT or the outer query does not use |
| ** aggregates. |
| ** |
| ** (10) The subquery does not use aggregates or the outer query does not |
| ** use LIMIT. |
| ** |
| ** (11) The subquery and the outer query do not both have ORDER BY clauses. |
| ** |
| ** (12) The subquery is not the right term of a LEFT OUTER JOIN or the |
| ** subquery has no WHERE clause. (added by ticket #350) |
| ** |
| ** In this routine, the "p" parameter is a pointer to the outer query. |
| ** The subquery is p->pSrc->a[iFrom]. isAgg is true if the outer query |
| ** uses aggregates and subqueryIsAgg is true if the subquery uses aggregates. |
| ** |
| ** If flattening is not attempted, this routine is a no-op and returns 0. |
| ** If flattening is attempted this routine returns 1. |
| ** |
| ** All of the expression analysis must occur on both the outer query and |
| ** the subquery before this routine runs. |
| */ |
| static int flattenSubquery( |
| Parse *pParse, /* The parsing context */ |
| Select *p, /* The parent or outer SELECT statement */ |
| int iFrom, /* Index in p->pSrc->a[] of the inner subquery */ |
| int isAgg, /* True if outer SELECT uses aggregate functions */ |
| int subqueryIsAgg /* True if the subquery uses aggregate functions */ |
| ){ |
| Select *pSub; /* The inner query or "subquery" */ |
| SrcList *pSrc; /* The FROM clause of the outer query */ |
| SrcList *pSubSrc; /* The FROM clause of the subquery */ |
| ExprList *pList; /* The result set of the outer query */ |
| int iParent; /* VDBE cursor number of the pSub result set temp table */ |
| int i; |
| Expr *pWhere; |
| |
| /* Check to see if flattening is permitted. Return 0 if not. |
| */ |
| if( p==0 ) return 0; |
| pSrc = p->pSrc; |
| assert( pSrc && iFrom>=0 && iFrom<pSrc->nSrc ); |
| pSub = pSrc->a[iFrom].pSelect; |
| assert( pSub!=0 ); |
| if( isAgg && subqueryIsAgg ) return 0; |
| if( subqueryIsAgg && pSrc->nSrc>1 ) return 0; |
| pSubSrc = pSub->pSrc; |
| assert( pSubSrc ); |
| if( pSubSrc->nSrc==0 ) return 0; |
| if( (pSub->isDistinct || pSub->nLimit>=0) && (pSrc->nSrc>1 || isAgg) ){ |
| return 0; |
| } |
| if( (p->isDistinct || p->nLimit>=0) && subqueryIsAgg ) return 0; |
| if( p->pOrderBy && pSub->pOrderBy ) return 0; |
| |
| /* Restriction 3: If the subquery is a join, make sure the subquery is |
| ** not used as the right operand of an outer join. Examples of why this |
| ** is not allowed: |
| ** |
| ** t1 LEFT OUTER JOIN (t2 JOIN t3) |
| ** |
| ** If we flatten the above, we would get |
| ** |
| ** (t1 LEFT OUTER JOIN t2) JOIN t3 |
| ** |
| ** which is not at all the same thing. |
| */ |
| if( pSubSrc->nSrc>1 && iFrom>0 && (pSrc->a[iFrom-1].jointype & JT_OUTER)!=0 ){ |
| return 0; |
| } |
| |
| /* Restriction 12: If the subquery is the right operand of a left outer |
| ** join, make sure the subquery has no WHERE clause. |
| ** An examples of why this is not allowed: |
| ** |
| ** t1 LEFT OUTER JOIN (SELECT * FROM t2 WHERE t2.x>0) |
| ** |
| ** If we flatten the above, we would get |
| ** |
| ** (t1 LEFT OUTER JOIN t2) WHERE t2.x>0 |
| ** |
| ** But the t2.x>0 test will always fail on a NULL row of t2, which |
| ** effectively converts the OUTER JOIN into an INNER JOIN. |
| */ |
| if( iFrom>0 && (pSrc->a[iFrom-1].jointype & JT_OUTER)!=0 |
| && pSub->pWhere!=0 ){ |
| return 0; |
| } |
| |
| /* If we reach this point, it means flattening is permitted for the |
| ** iFrom-th entry of the FROM clause in the outer query. |
| */ |
| |
| /* Move all of the FROM elements of the subquery into the |
| ** the FROM clause of the outer query. Before doing this, remember |
| ** the cursor number for the original outer query FROM element in |
| ** iParent. The iParent cursor will never be used. Subsequent code |
| ** will scan expressions looking for iParent references and replace |
| ** those references with expressions that resolve to the subquery FROM |
| ** elements we are now copying in. |
| */ |
| iParent = pSrc->a[iFrom].iCursor; |
| { |
| int nSubSrc = pSubSrc->nSrc; |
| int jointype = pSrc->a[iFrom].jointype; |
| |
| if( pSrc->a[iFrom].pTab && pSrc->a[iFrom].pTab->isTransient ){ |
| sqliteDeleteTable(0, pSrc->a[iFrom].pTab); |
| } |
| sqliteFree(pSrc->a[iFrom].zDatabase); |
| sqliteFree(pSrc->a[iFrom].zName); |
| sqliteFree(pSrc->a[iFrom].zAlias); |
| if( nSubSrc>1 ){ |
| int extra = nSubSrc - 1; |
| for(i=1; i<nSubSrc; i++){ |
| pSrc = sqliteSrcListAppend(pSrc, 0, 0); |
| } |
| p->pSrc = pSrc; |
| for(i=pSrc->nSrc-1; i-extra>=iFrom; i--){ |
| pSrc->a[i] = pSrc->a[i-extra]; |
| } |
| } |
| for(i=0; i<nSubSrc; i++){ |
| pSrc->a[i+iFrom] = pSubSrc->a[i]; |
| memset(&pSubSrc->a[i], 0, sizeof(pSubSrc->a[i])); |
| } |
| pSrc->a[iFrom+nSubSrc-1].jointype = jointype; |
| } |
| |
| /* Now begin substituting subquery result set expressions for |
| ** references to the iParent in the outer query. |
| ** |
| ** Example: |
| ** |
| ** SELECT a+5, b*10 FROM (SELECT x*3 AS a, y+10 AS b FROM t1) WHERE a>b; |
| ** \ \_____________ subquery __________/ / |
| ** \_____________________ outer query ______________________________/ |
| ** |
| ** We look at every expression in the outer query and every place we see |
| ** "a" we substitute "x*3" and every place we see "b" we substitute "y+10". |
| */ |
| substExprList(p->pEList, iParent, pSub->pEList); |
| pList = p->pEList; |
| for(i=0; i<pList->nExpr; i++){ |
| Expr *pExpr; |
| if( pList->a[i].zName==0 && (pExpr = pList->a[i].pExpr)->span.z!=0 ){ |
| pList->a[i].zName = sqliteStrNDup(pExpr->span.z, pExpr->span.n); |
| } |
| } |
| if( isAgg ){ |
| substExprList(p->pGroupBy, iParent, pSub->pEList); |
| substExpr(p->pHaving, iParent, pSub->pEList); |
| } |
| if( pSub->pOrderBy ){ |
| assert( p->pOrderBy==0 ); |
| p->pOrderBy = pSub->pOrderBy; |
| pSub->pOrderBy = 0; |
| }else if( p->pOrderBy ){ |
| substExprList(p->pOrderBy, iParent, pSub->pEList); |
| } |
| if( pSub->pWhere ){ |
| pWhere = sqliteExprDup(pSub->pWhere); |
| }else{ |
| pWhere = 0; |
| } |
| if( subqueryIsAgg ){ |
| assert( p->pHaving==0 ); |
| p->pHaving = p->pWhere; |
| p->pWhere = pWhere; |
| substExpr(p->pHaving, iParent, pSub->pEList); |
| if( pSub->pHaving ){ |
| Expr *pHaving = sqliteExprDup(pSub->pHaving); |
| if( p->pHaving ){ |
| p->pHaving = sqliteExpr(TK_AND, p->pHaving, pHaving, 0); |
| }else{ |
| p->pHaving = pHaving; |
| } |
| } |
| assert( p->pGroupBy==0 ); |
| p->pGroupBy = sqliteExprListDup(pSub->pGroupBy); |
| }else if( p->pWhere==0 ){ |
| p->pWhere = pWhere; |
| }else{ |
| substExpr(p->pWhere, iParent, pSub->pEList); |
| if( pWhere ){ |
| p->pWhere = sqliteExpr(TK_AND, p->pWhere, pWhere, 0); |
| } |
| } |
| |
| /* The flattened query is distinct if either the inner or the |
| ** outer query is distinct. |
| */ |
| p->isDistinct = p->isDistinct || pSub->isDistinct; |
| |
| /* Transfer the limit expression from the subquery to the outer |
| ** query. |
| */ |
| if( pSub->nLimit>=0 ){ |
| if( p->nLimit<0 ){ |
| p->nLimit = pSub->nLimit; |
| }else if( p->nLimit+p->nOffset > pSub->nLimit+pSub->nOffset ){ |
| p->nLimit = pSub->nLimit + pSub->nOffset - p->nOffset; |
| } |
| } |
| p->nOffset += pSub->nOffset; |
| |
| /* Finially, delete what is left of the subquery and return |
| ** success. |
| */ |
| sqliteSelectDelete(pSub); |
| return 1; |
| } |
| |
| /* |
| ** Analyze the SELECT statement passed in as an argument to see if it |
| ** is a simple min() or max() query. If it is and this query can be |
| ** satisfied using a single seek to the beginning or end of an index, |
| ** then generate the code for this SELECT and return 1. If this is not a |
| ** simple min() or max() query, then return 0; |
| ** |
| ** A simply min() or max() query looks like this: |
| ** |
| ** SELECT min(a) FROM table; |
| ** SELECT max(a) FROM table; |
| ** |
| ** The query may have only a single table in its FROM argument. There |
| ** can be no GROUP BY or HAVING or WHERE clauses. The result set must |
| ** be the min() or max() of a single column of the table. The column |
| ** in the min() or max() function must be indexed. |
| ** |
| ** The parameters to this routine are the same as for sqliteSelect(). |
| ** See the header comment on that routine for additional information. |
| */ |
| static int simpleMinMaxQuery(Parse *pParse, Select *p, int eDest, int iParm){ |
| Expr *pExpr; |
| int iCol; |
| Table *pTab; |
| Index *pIdx; |
| int base; |
| Vdbe *v; |
| int seekOp; |
| int cont; |
| ExprList *pEList, *pList, eList; |
| struct ExprList_item eListItem; |
| SrcList *pSrc; |
| |
| |
| /* Check to see if this query is a simple min() or max() query. Return |
| ** zero if it is not. |
| */ |
| if( p->pGroupBy || p->pHaving || p->pWhere ) return 0; |
| pSrc = p->pSrc; |
| if( pSrc->nSrc!=1 ) return 0; |
| pEList = p->pEList; |
| if( pEList->nExpr!=1 ) return 0; |
| pExpr = pEList->a[0].pExpr; |
| if( pExpr->op!=TK_AGG_FUNCTION ) return 0; |
| pList = pExpr->pList; |
| if( pList==0 || pList->nExpr!=1 ) return 0; |
| if( pExpr->token.n!=3 ) return 0; |
| if( sqliteStrNICmp(pExpr->token.z,"min",3)==0 ){ |
| seekOp = OP_Rewind; |
| }else if( sqliteStrNICmp(pExpr->token.z,"max",3)==0 ){ |
| seekOp = OP_Last; |
| }else{ |
| return 0; |
| } |
| pExpr = pList->a[0].pExpr; |
| if( pExpr->op!=TK_COLUMN ) return 0; |
| iCol = pExpr->iColumn; |
| pTab = pSrc->a[0].pTab; |
| |
| /* If we get to here, it means the query is of the correct form. |
| ** Check to make sure we have an index and make pIdx point to the |
| ** appropriate index. If the min() or max() is on an INTEGER PRIMARY |
| ** key column, no index is necessary so set pIdx to NULL. If no |
| ** usable index is found, return 0. |
| */ |
| if( iCol<0 ){ |
| pIdx = 0; |
| }else{ |
| for(pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext){ |
| assert( pIdx->nColumn>=1 ); |
| if( pIdx->aiColumn[0]==iCol ) break; |
| } |
| if( pIdx==0 ) return 0; |
| } |
| |
| /* Identify column types if we will be using the callback. This |
| ** step is skipped if the output is going to a table or a memory cell. |
| ** The column names have already been generated in the calling function. |
| */ |
| v = sqliteGetVdbe(pParse); |
| if( v==0 ) return 0; |
| if( eDest==SRT_Callback ){ |
| generateColumnTypes(pParse, p->pSrc, p->pEList); |
| } |
| |
| /* If the output is destined for a temporary table, open that table. |
| */ |
| if( eDest==SRT_TempTable ){ |
| sqliteVdbeAddOp(v, OP_OpenTemp, iParm, 0); |
| } |
| |
| /* Generating code to find the min or the max. Basically all we have |
| ** to do is find the first or the last entry in the chosen index. If |
| ** the min() or max() is on the INTEGER PRIMARY KEY, then find the first |
| ** or last entry in the main table. |
| */ |
| sqliteCodeVerifySchema(pParse, pTab->iDb); |
| base = pSrc->a[0].iCursor; |
| computeLimitRegisters(pParse, p); |
| if( pSrc->a[0].pSelect==0 ){ |
| sqliteVdbeAddOp(v, OP_Integer, pTab->iDb, 0); |
| sqliteVdbeOp3(v, OP_OpenRead, base, pTab->tnum, pTab->zName, 0); |
| } |
| cont = sqliteVdbeMakeLabel(v); |
| if( pIdx==0 ){ |
| sqliteVdbeAddOp(v, seekOp, base, 0); |
| }else{ |
| sqliteVdbeAddOp(v, OP_Integer, pIdx->iDb, 0); |
| sqliteVdbeOp3(v, OP_OpenRead, base+1, pIdx->tnum, pIdx->zName, P3_STATIC); |
| if( seekOp==OP_Rewind ){ |
| sqliteVdbeAddOp(v, OP_String, 0, 0); |
| sqliteVdbeAddOp(v, OP_MakeKey, 1, 0); |
| sqliteVdbeAddOp(v, OP_IncrKey, 0, 0); |
| seekOp = OP_MoveTo; |
| } |
| sqliteVdbeAddOp(v, seekOp, base+1, 0); |
| sqliteVdbeAddOp(v, OP_IdxRecno, base+1, 0); |
| sqliteVdbeAddOp(v, OP_Close, base+1, 0); |
| sqliteVdbeAddOp(v, OP_MoveTo, base, 0); |
| } |
| eList.nExpr = 1; |
| memset(&eListItem, 0, sizeof(eListItem)); |
| eList.a = &eListItem; |
| eList.a[0].pExpr = pExpr; |
| selectInnerLoop(pParse, p, &eList, 0, 0, 0, -1, eDest, iParm, cont, cont); |
| sqliteVdbeResolveLabel(v, cont); |
| sqliteVdbeAddOp(v, OP_Close, base, 0); |
| |
| return 1; |
| } |
| |
| /* |
| ** Generate code for the given SELECT statement. |
| ** |
| ** The results are distributed in various ways depending on the |
| ** value of eDest and iParm. |
| ** |
| ** eDest Value Result |
| ** ------------ ------------------------------------------- |
| ** SRT_Callback Invoke the callback for each row of the result. |
| ** |
| ** SRT_Mem Store first result in memory cell iParm |
| ** |
| ** SRT_Set Store results as keys of a table with cursor iParm |
| ** |
| ** SRT_Union Store results as a key in a temporary table iParm |
| ** |
| ** SRT_Except Remove results from the temporary table iParm. |
| ** |
| ** SRT_Table Store results in temporary table iParm |
| ** |
| ** The table above is incomplete. Additional eDist value have be added |
| ** since this comment was written. See the selectInnerLoop() function for |
| ** a complete listing of the allowed values of eDest and their meanings. |
| ** |
| ** This routine returns the number of errors. If any errors are |
| ** encountered, then an appropriate error message is left in |
| ** pParse->zErrMsg. |
| ** |
| ** This routine does NOT free the Select structure passed in. The |
| ** calling function needs to do that. |
| ** |
| ** The pParent, parentTab, and *pParentAgg fields are filled in if this |
| ** SELECT is a subquery. This routine may try to combine this SELECT |
| ** with its parent to form a single flat query. In so doing, it might |
| ** change the parent query from a non-aggregate to an aggregate query. |
| ** For that reason, the pParentAgg flag is passed as a pointer, so it |
| ** can be changed. |
| ** |
| ** Example 1: The meaning of the pParent parameter. |
| ** |
| ** SELECT * FROM t1 JOIN (SELECT x, count(*) FROM t2) JOIN t3; |
| ** \ \_______ subquery _______/ / |
| ** \ / |
| ** \____________________ outer query ___________________/ |
| ** |
| ** This routine is called for the outer query first. For that call, |
| ** pParent will be NULL. During the processing of the outer query, this |
| ** routine is called recursively to handle the subquery. For the recursive |
| ** call, pParent will point to the outer query. Because the subquery is |
| ** the second element in a three-way join, the parentTab parameter will |
| ** be 1 (the 2nd value of a 0-indexed array.) |
| */ |
| int sqliteSelect( |
| Parse *pParse, /* The parser context */ |
| Select *p, /* The SELECT statement being coded. */ |
| int eDest, /* How to dispose of the results */ |
| int iParm, /* A parameter used by the eDest disposal method */ |
| Select *pParent, /* Another SELECT for which this is a sub-query */ |
| int parentTab, /* Index in pParent->pSrc of this query */ |
| int *pParentAgg /* True if pParent uses aggregate functions */ |
| ){ |
| int i; |
| WhereInfo *pWInfo; |
| Vdbe *v; |
| int isAgg = 0; /* True for select lists like "count(*)" */ |
| ExprList *pEList; /* List of columns to extract. */ |
| SrcList *pTabList; /* List of tables to select from */ |
| Expr *pWhere; /* The WHERE clause. May be NULL */ |
| ExprList *pOrderBy; /* The ORDER BY clause. May be NULL */ |
| ExprList *pGroupBy; /* The GROUP BY clause. May be NULL */ |
| Expr *pHaving; /* The HAVING clause. May be NULL */ |
| int isDistinct; /* True if the DISTINCT keyword is present */ |
| int distinct; /* Table to use for the distinct set */ |
| int rc = 1; /* Value to return from this function */ |
| |
| if( sqlite_malloc_failed || pParse->nErr || p==0 ) return 1; |
| if( sqliteAuthCheck(pParse, SQLITE_SELECT, 0, 0, 0) ) return 1; |
| |
| /* If there is are a sequence of queries, do the earlier ones first. |
| */ |
| if( p->pPrior ){ |
| return multiSelect(pParse, p, eDest, iParm); |
| } |
| |
| /* Make local copies of the parameters for this query. |
| */ |
| pTabList = p->pSrc; |
| pWhere = p->pWhere; |
| pOrderBy = p->pOrderBy; |
| pGroupBy = p->pGroupBy; |
| pHaving = p->pHaving; |
| isDistinct = p->isDistinct; |
| |
| /* Allocate VDBE cursors for each table in the FROM clause |
| */ |
| sqliteSrcListAssignCursors(pParse, pTabList); |
| |
| /* |
| ** Do not even attempt to generate any code if we have already seen |
| ** errors before this routine starts. |
| */ |
| if( pParse->nErr>0 ) goto select_end; |
| |
| /* Expand any "*" terms in the result set. (For example the "*" in |
| ** "SELECT * FROM t1") The fillInColumnlist() routine also does some |
| ** other housekeeping - see the header comment for details. |
| */ |
| if( fillInColumnList(pParse, p) ){ |
| goto select_end; |
| } |
| pWhere = p->pWhere; |
| pEList = p->pEList; |
| if( pEList==0 ) goto select_end; |
| |
| /* If writing to memory or generating a set |
| ** only a single column may be output. |
| */ |
| if( (eDest==SRT_Mem || eDest==SRT_Set) && pEList->nExpr>1 ){ |
| sqliteErrorMsg(pParse, "only a single result allowed for " |
| "a SELECT that is part of an expression"); |
| goto select_end; |
| } |
| |
| /* ORDER BY is ignored for some destinations. |
| */ |
| switch( eDest ){ |
| case SRT_Union: |
| case SRT_Except: |
| case SRT_Discard: |
| pOrderBy = 0; |
| break; |
| default: |
| break; |
| } |
| |
| /* At this point, we should have allocated all the cursors that we |
| ** need to handle subquerys and temporary tables. |
| ** |
| ** Resolve the column names and do a semantics check on all the expressions. |
| */ |
| for(i=0; i<pEList->nExpr; i++){ |
| if( sqliteExprResolveIds(pParse, pTabList, 0, pEList->a[i].pExpr) ){ |
| goto select_end; |
| } |
| if( sqliteExprCheck(pParse, pEList->a[i].pExpr, 1, &isAgg) ){ |
| goto select_end; |
| } |
| } |
| if( pWhere ){ |
| if( sqliteExprResolveIds(pParse, pTabList, pEList, pWhere) ){ |
| goto select_end; |
| } |
| if( sqliteExprCheck(pParse, pWhere, 0, 0) ){ |
| goto select_end; |
| } |
| } |
| if( pHaving ){ |
| if( pGroupBy==0 ){ |
| sqliteErrorMsg(pParse, "a GROUP BY clause is required before HAVING"); |
| goto select_end; |
| } |
| if( sqliteExprResolveIds(pParse, pTabList, pEList, pHaving) ){ |
| goto select_end; |
| } |
| if( sqliteExprCheck(pParse, pHaving, 1, &isAgg) ){ |
| goto select_end; |
| } |
| } |
| if( pOrderBy ){ |
| for(i=0; i<pOrderBy->nExpr; i++){ |
| int iCol; |
| Expr *pE = pOrderBy->a[i].pExpr; |
| if( sqliteExprIsInteger(pE, &iCol) && iCol>0 && iCol<=pEList->nExpr ){ |
| sqliteExprDelete(pE); |
| pE = pOrderBy->a[i].pExpr = sqliteExprDup(pEList->a[iCol-1].pExpr); |
| } |
| if( sqliteExprResolveIds(pParse, pTabList, pEList, pE) ){ |
| goto select_end; |
| } |
| if( sqliteExprCheck(pParse, pE, isAgg, 0) ){ |
| goto select_end; |
| } |
| if( sqliteExprIsConstant(pE) ){ |
| if( sqliteExprIsInteger(pE, &iCol)==0 ){ |
| sqliteErrorMsg(pParse, |
| "ORDER BY terms must not be non-integer constants"); |
| goto select_end; |
| }else if( iCol<=0 || iCol>pEList->nExpr ){ |
| sqliteErrorMsg(pParse, |
| "ORDER BY column number %d out of range - should be " |
| "between 1 and %d", iCol, pEList->nExpr); |
| goto select_end; |
| } |
| } |
| } |
| } |
| if( pGroupBy ){ |
| for(i=0; i<pGroupBy->nExpr; i++){ |
| int iCol; |
| Expr *pE = pGroupBy->a[i].pExpr; |
| if( sqliteExprIsInteger(pE, &iCol) && iCol>0 && iCol<=pEList->nExpr ){ |
| sqliteExprDelete(pE); |
| pE = pGroupBy->a[i].pExpr = sqliteExprDup(pEList->a[iCol-1].pExpr); |
| } |
| if( sqliteExprResolveIds(pParse, pTabList, pEList, pE) ){ |
| goto select_end; |
| } |
| if( sqliteExprCheck(pParse, pE, isAgg, 0) ){ |
| goto select_end; |
| } |
| if( sqliteExprIsConstant(pE) ){ |
| if( sqliteExprIsInteger(pE, &iCol)==0 ){ |
| sqliteErrorMsg(pParse, |
| "GROUP BY terms must not be non-integer constants"); |
| goto select_end; |
| }else if( iCol<=0 || iCol>pEList->nExpr ){ |
| sqliteErrorMsg(pParse, |
| "GROUP BY column number %d out of range - should be " |
| "between 1 and %d", iCol, pEList->nExpr); |
| goto select_end; |
| } |
| } |
| } |
| } |
| |
| /* Begin generating code. |
| */ |
| v = sqliteGetVdbe(pParse); |
| if( v==0 ) goto select_end; |
| |
| /* Identify column names if we will be using them in a callback. This |
| ** step is skipped if the output is going to some other destination. |
| */ |
| if( eDest==SRT_Callback ){ |
| generateColumnNames(pParse, pTabList, pEList); |
| } |
| |
| /* Generate code for all sub-queries in the FROM clause |
| */ |
| for(i=0; i<pTabList->nSrc; i++){ |
| const char *zSavedAuthContext; |
| int needRestoreContext; |
| |
| if( pTabList->a[i].pSelect==0 ) continue; |
| if( pTabList->a[i].zName!=0 ){ |
| zSavedAuthContext = pParse->zAuthContext; |
| pParse->zAuthContext = pTabList->a[i].zName; |
| needRestoreContext = 1; |
| }else{ |
| needRestoreContext = 0; |
| } |
| sqliteSelect(pParse, pTabList->a[i].pSelect, SRT_TempTable, |
| pTabList->a[i].iCursor, p, i, &isAgg); |
| if( needRestoreContext ){ |
| pParse->zAuthContext = zSavedAuthContext; |
| } |
| pTabList = p->pSrc; |
| pWhere = p->pWhere; |
| if( eDest!=SRT_Union && eDest!=SRT_Except && eDest!=SRT_Discard ){ |
| pOrderBy = p->pOrderBy; |
| } |
| pGroupBy = p->pGroupBy; |
| pHaving = p->pHaving; |
| isDistinct = p->isDistinct; |
| } |
| |
| /* Check for the special case of a min() or max() function by itself |
| ** in the result set. |
| */ |
| if( simpleMinMaxQuery(pParse, p, eDest, iParm) ){ |
| rc = 0; |
| goto select_end; |
| } |
| |
| /* Check to see if this is a subquery that can be "flattened" into its parent. |
| ** If flattening is a possiblity, do so and return immediately. |
| */ |
| if( pParent && pParentAgg && |
| flattenSubquery(pParse, pParent, parentTab, *pParentAgg, isAgg) ){ |
| if( isAgg ) *pParentAgg = 1; |
| return rc; |
| } |
| |
| /* Set the limiter. |
| */ |
| computeLimitRegisters(pParse, p); |
| |
| /* Identify column types if we will be using a callback. This |
| ** step is skipped if the output is going to a destination other |
| ** than a callback. |
| ** |
| ** We have to do this separately from the creation of column names |
| ** above because if the pTabList contains views then they will not |
| ** have been resolved and we will not know the column types until |
| ** now. |
| */ |
| if( eDest==SRT_Callback ){ |
| generateColumnTypes(pParse, pTabList, pEList); |
| } |
| |
| /* If the output is destined for a temporary table, open that table. |
| */ |
| if( eDest==SRT_TempTable ){ |
| sqliteVdbeAddOp(v, OP_OpenTemp, iParm, 0); |
| } |
| |
| /* Do an analysis of aggregate expressions. |
| */ |
| sqliteAggregateInfoReset(pParse); |
| if( isAgg || pGroupBy ){ |
| assert( pParse->nAgg==0 ); |
| isAgg = 1; |
| for(i=0; i<pEList->nExpr; i++){ |
| if( sqliteExprAnalyzeAggregates(pParse, pEList->a[i].pExpr) ){ |
| goto select_end; |
| } |
| } |
| if( pGroupBy ){ |
| for(i=0; i<pGroupBy->nExpr; i++){ |
| if( sqliteExprAnalyzeAggregates(pParse, pGroupBy->a[i].pExpr) ){ |
| goto select_end; |
| } |
| } |
| } |
| if( pHaving && sqliteExprAnalyzeAggregates(pParse, pHaving) ){ |
| goto select_end; |
| } |
| if( pOrderBy ){ |
| for(i=0; i<pOrderBy->nExpr; i++){ |
| if( sqliteExprAnalyzeAggregates(pParse, pOrderBy->a[i].pExpr) ){ |
| goto select_end; |
| } |
| } |
| } |
| } |
| |
| /* Reset the aggregator |
| */ |
| if( isAgg ){ |
| sqliteVdbeAddOp(v, OP_AggReset, 0, pParse->nAgg); |
| for(i=0; i<pParse->nAgg; i++){ |
| FuncDef *pFunc; |
| if( (pFunc = pParse->aAgg[i].pFunc)!=0 && pFunc->xFinalize!=0 ){ |
| sqliteVdbeOp3(v, OP_AggInit, 0, i, (char*)pFunc, P3_POINTER); |
| } |
| } |
| if( pGroupBy==0 ){ |
| sqliteVdbeAddOp(v, OP_String, 0, 0); |
| sqliteVdbeAddOp(v, OP_AggFocus, 0, 0); |
| } |
| } |
| |
| /* Initialize the memory cell to NULL |
| */ |
| if( eDest==SRT_Mem ){ |
| sqliteVdbeAddOp(v, OP_String, 0, 0); |
| sqliteVdbeAddOp(v, OP_MemStore, iParm, 1); |
| } |
| |
| /* Open a temporary table to use for the distinct set. |
| */ |
| if( isDistinct ){ |
| distinct = pParse->nTab++; |
| sqliteVdbeAddOp(v, OP_OpenTemp, distinct, 1); |
| }else{ |
| distinct = -1; |
| } |
| |
| /* Begin the database scan |
| */ |
| pWInfo = sqliteWhereBegin(pParse, pTabList, pWhere, 0, |
| pGroupBy ? 0 : &pOrderBy); |
| if( pWInfo==0 ) goto select_end; |
| |
| /* Use the standard inner loop if we are not dealing with |
| ** aggregates |
| */ |
| if( !isAgg ){ |
| if( selectInnerLoop(pParse, p, pEList, 0, 0, pOrderBy, distinct, eDest, |
| iParm, pWInfo->iContinue, pWInfo->iBreak) ){ |
| goto select_end; |
| } |
| } |
| |
| /* If we are dealing with aggregates, then do the special aggregate |
| ** processing. |
| */ |
| else{ |
| AggExpr *pAgg; |
| if( pGroupBy ){ |
| int lbl1; |
| for(i=0; i<pGroupBy->nExpr; i++){ |
| sqliteExprCode(pParse, pGroupBy->a[i].pExpr); |
| } |
| sqliteVdbeAddOp(v, OP_MakeKey, pGroupBy->nExpr, 0); |
| if( pParse->db->file_format>=4 ) sqliteAddKeyType(v, pGroupBy); |
| lbl1 = sqliteVdbeMakeLabel(v); |
| sqliteVdbeAddOp(v, OP_AggFocus, 0, lbl1); |
| for(i=0, pAgg=pParse->aAgg; i<pParse->nAgg; i++, pAgg++){ |
| if( pAgg->isAgg ) continue; |
| sqliteExprCode(pParse, pAgg->pExpr); |
| sqliteVdbeAddOp(v, OP_AggSet, 0, i); |
| } |
| sqliteVdbeResolveLabel(v, lbl1); |
| } |
| for(i=0, pAgg=pParse->aAgg; i<pParse->nAgg; i++, pAgg++){ |
| Expr *pE; |
| int nExpr; |
| FuncDef *pDef; |
| if( !pAgg->isAgg ) continue; |
| assert( pAgg->pFunc!=0 ); |
| assert( pAgg->pFunc->xStep!=0 ); |
| pDef = pAgg->pFunc; |
| pE = pAgg->pExpr; |
| assert( pE!=0 ); |
| assert( pE->op==TK_AGG_FUNCTION ); |
| nExpr = sqliteExprCodeExprList(pParse, pE->pList, pDef->includeTypes); |
| sqliteVdbeAddOp(v, OP_Integer, i, 0); |
| sqliteVdbeOp3(v, OP_AggFunc, 0, nExpr, (char*)pDef, P3_POINTER); |
| } |
| } |
| |
| /* End the database scan loop. |
| */ |
| sqliteWhereEnd(pWInfo); |
| |
| /* If we are processing aggregates, we need to set up a second loop |
| ** over all of the aggregate values and process them. |
| */ |
| if( isAgg ){ |
| int endagg = sqliteVdbeMakeLabel(v); |
| int startagg; |
| startagg = sqliteVdbeAddOp(v, OP_AggNext, 0, endagg); |
| pParse->useAgg = 1; |
| if( pHaving ){ |
| sqliteExprIfFalse(pParse, pHaving, startagg, 1); |
| } |
| if( selectInnerLoop(pParse, p, pEList, 0, 0, pOrderBy, distinct, eDest, |
| iParm, startagg, endagg) ){ |
| goto select_end; |
| } |
| sqliteVdbeAddOp(v, OP_Goto, 0, startagg); |
| sqliteVdbeResolveLabel(v, endagg); |
| sqliteVdbeAddOp(v, OP_Noop, 0, 0); |
| pParse->useAgg = 0; |
| } |
| |
| /* If there is an ORDER BY clause, then we need to sort the results |
| ** and send them to the callback one by one. |
| */ |
| if( pOrderBy ){ |
| generateSortTail(p, v, pEList->nExpr, eDest, iParm); |
| } |
| |
| /* If this was a subquery, we have now converted the subquery into a |
| ** temporary table. So delete the subquery structure from the parent |
| ** to prevent this subquery from being evaluated again and to force the |
| ** the use of the temporary table. |
| */ |
| if( pParent ){ |
| assert( pParent->pSrc->nSrc>parentTab ); |
| assert( pParent->pSrc->a[parentTab].pSelect==p ); |
| sqliteSelectDelete(p); |
| pParent->pSrc->a[parentTab].pSelect = 0; |
| } |
| |
| /* The SELECT was successfully coded. Set the return code to 0 |
| ** to indicate no errors. |
| */ |
| rc = 0; |
| |
| /* Control jumps to here if an error is encountered above, or upon |
| ** successful coding of the SELECT. |
| */ |
| select_end: |
| sqliteAggregateInfoReset(pParse); |
| return rc; |
| } |