/*------------------------------------------------------------------------- * * parse_node.c * various routines that make nodes for querytrees * * Portions Copyright (c) 1996-2005, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * $PostgreSQL: pgsql/src/backend/parser/parse_node.c,v 1.88 2005/04/23 18:35:12 tgl Exp $ * *------------------------------------------------------------------------- */ #include "postgres.h" #include "catalog/pg_type.h" #include "nodes/makefuncs.h" #include "parser/parsetree.h" #include "parser/parse_coerce.h" #include "parser/parse_expr.h" #include "parser/parse_node.h" #include "parser/parse_relation.h" #include "utils/builtins.h" #include "utils/int8.h" #include "utils/syscache.h" #include "utils/varbit.h" /* make_parsestate() * Allocate and initialize a new ParseState. * The CALLER is responsible for freeing the ParseState* returned. */ ParseState * make_parsestate(ParseState *parentParseState) { ParseState *pstate; pstate = palloc0(sizeof(ParseState)); pstate->parentParseState = parentParseState; /* Fill in fields that don't start at null/false/zero */ pstate->p_next_resno = 1; if (parentParseState) pstate->p_variableparams = parentParseState->p_variableparams; return pstate; } /* * make_var * Build a Var node for an attribute identified by RTE and attrno */ Var * make_var(ParseState *pstate, RangeTblEntry *rte, int attrno) { int vnum, sublevels_up; Oid vartypeid; int32 type_mod; vnum = RTERangeTablePosn(pstate, rte, &sublevels_up); get_rte_attribute_type(rte, attrno, &vartypeid, &type_mod); return makeVar(vnum, attrno, vartypeid, type_mod, sublevels_up); } /* * transformArrayType() * Get the element type of an array type in preparation for subscripting */ Oid transformArrayType(Oid arrayType) { Oid elementType; HeapTuple type_tuple_array; Form_pg_type type_struct_array; /* Get the type tuple for the array */ type_tuple_array = SearchSysCache(TYPEOID, ObjectIdGetDatum(arrayType), 0, 0, 0); if (!HeapTupleIsValid(type_tuple_array)) elog(ERROR, "cache lookup failed for type %u", arrayType); type_struct_array = (Form_pg_type) GETSTRUCT(type_tuple_array); /* needn't check typisdefined since this will fail anyway */ elementType = type_struct_array->typelem; if (elementType == InvalidOid) ereport(ERROR, (errcode(ERRCODE_DATATYPE_MISMATCH), errmsg("cannot subscript type %s because it is not an array", format_type_be(arrayType)))); ReleaseSysCache(type_tuple_array); return elementType; } /* * transformArraySubscripts() * Transform array subscripting. This is used for both * array fetch and array assignment. * * In an array fetch, we are given a source array value and we produce an * expression that represents the result of extracting a single array element * or an array slice. * * In an array assignment, we are given a destination array value plus a * source value that is to be assigned to a single element or a slice of * that array. We produce an expression that represents the new array value * with the source data inserted into the right part of the array. * * pstate Parse state * arrayBase Already-transformed expression for the array as a whole * arrayType OID of array's datatype (should match type of arrayBase) * elementType OID of array's element type (fetch with transformArrayType, * or pass InvalidOid to do it here) * elementTypMod typmod to be applied to array elements (if storing) * indirection Untransformed list of subscripts (must not be NIL) * assignFrom NULL for array fetch, else transformed expression for source. */ ArrayRef * transformArraySubscripts(ParseState *pstate, Node *arrayBase, Oid arrayType, Oid elementType, int32 elementTypMod, List *indirection, Node *assignFrom) { Oid resultType; bool isSlice = false; List *upperIndexpr = NIL; List *lowerIndexpr = NIL; ListCell *idx; ArrayRef *aref; /* Caller may or may not have bothered to determine elementType */ if (!OidIsValid(elementType)) elementType = transformArrayType(arrayType); /* * A list containing only single subscripts refers to a single array * element. If any of the items are double subscripts (lower:upper), * then the subscript expression means an array slice operation. In * this case, we supply a default lower bound of 1 for any items that * contain only a single subscript. We have to prescan the * indirection list to see if there are any double subscripts. */ foreach(idx, indirection) { A_Indices *ai = (A_Indices *) lfirst(idx); if (ai->lidx != NULL) { isSlice = true; break; } } /* * The type represented by the subscript expression is the element * type if we are fetching a single element, but it is the same as the * array type if we are fetching a slice or storing. */ if (isSlice || assignFrom != NULL) resultType = arrayType; else resultType = elementType; /* * Transform the subscript expressions. */ foreach(idx, indirection) { A_Indices *ai = (A_Indices *) lfirst(idx); Node *subexpr; Assert(IsA(ai, A_Indices)); if (isSlice) { if (ai->lidx) { subexpr = transformExpr(pstate, ai->lidx); /* If it's not int4 already, try to coerce */ subexpr = coerce_to_target_type(pstate, subexpr, exprType(subexpr), INT4OID, -1, COERCION_ASSIGNMENT, COERCE_IMPLICIT_CAST); if (subexpr == NULL) ereport(ERROR, (errcode(ERRCODE_DATATYPE_MISMATCH), errmsg("array subscript must have type integer"))); } else { /* Make a constant 1 */ subexpr = (Node *) makeConst(INT4OID, sizeof(int32), Int32GetDatum(1), false, true); /* pass by value */ } lowerIndexpr = lappend(lowerIndexpr, subexpr); } subexpr = transformExpr(pstate, ai->uidx); /* If it's not int4 already, try to coerce */ subexpr = coerce_to_target_type(pstate, subexpr, exprType(subexpr), INT4OID, -1, COERCION_ASSIGNMENT, COERCE_IMPLICIT_CAST); if (subexpr == NULL) ereport(ERROR, (errcode(ERRCODE_DATATYPE_MISMATCH), errmsg("array subscript must have type integer"))); upperIndexpr = lappend(upperIndexpr, subexpr); } /* * If doing an array store, coerce the source value to the right type. * (This should agree with the coercion done by * updateTargetListEntry.) */ if (assignFrom != NULL) { Oid typesource = exprType(assignFrom); Oid typeneeded = isSlice ? arrayType : elementType; assignFrom = coerce_to_target_type(pstate, assignFrom, typesource, typeneeded, elementTypMod, COERCION_ASSIGNMENT, COERCE_IMPLICIT_CAST); if (assignFrom == NULL) ereport(ERROR, (errcode(ERRCODE_DATATYPE_MISMATCH), errmsg("array assignment requires type %s" " but expression is of type %s", format_type_be(typeneeded), format_type_be(typesource)), errhint("You will need to rewrite or cast the expression."))); } /* * Ready to build the ArrayRef node. */ aref = makeNode(ArrayRef); aref->refrestype = resultType; aref->refarraytype = arrayType; aref->refelemtype = elementType; aref->refupperindexpr = upperIndexpr; aref->reflowerindexpr = lowerIndexpr; aref->refexpr = (Expr *) arrayBase; aref->refassgnexpr = (Expr *) assignFrom; return aref; } /* * make_const * * Convert a Value node (as returned by the grammar) to a Const node * of the "natural" type for the constant. Note that this routine is * only used when there is no explicit cast for the constant, so we * have to guess what type is wanted. * * For string literals we produce a constant of type UNKNOWN ---- whose * representation is the same as text, but it indicates to later type * resolution that we're not sure that it should be considered text. * Explicit "NULL" constants are also typed as UNKNOWN. * * For integers and floats we produce int4, int8, or numeric depending * on the value of the number. XXX We should produce int2 as well, * but additional cleanup is needed before we can do that; there are * too many examples that fail if we try. */ Const * make_const(Value *value) { Datum val; int64 val64; Oid typeid; int typelen; bool typebyval; Const *con; switch (nodeTag(value)) { case T_Integer: val = Int32GetDatum(intVal(value)); typeid = INT4OID; typelen = sizeof(int32); typebyval = true; break; case T_Float: /* could be an oversize integer as well as a float ... */ if (scanint8(strVal(value), true, &val64)) { /* * It might actually fit in int32. Probably only INT_MIN can * occur, but we'll code the test generally just to be sure. */ int32 val32 = (int32) val64; if (val64 == (int64) val32) { val = Int32GetDatum(val32); typeid = INT4OID; typelen = sizeof(int32); typebyval = true; } else { val = Int64GetDatum(val64); typeid = INT8OID; typelen = sizeof(int64); typebyval = false; /* XXX might change someday */ } } else { val = DirectFunctionCall3(numeric_in, CStringGetDatum(strVal(value)), ObjectIdGetDatum(InvalidOid), Int32GetDatum(-1)); typeid = NUMERICOID; typelen = -1; /* variable len */ typebyval = false; } break; case T_String: val = DirectFunctionCall1(unknownin, CStringGetDatum(strVal(value))); typeid = UNKNOWNOID; /* will be coerced later */ typelen = -1; /* variable len */ typebyval = false; break; case T_BitString: val = DirectFunctionCall3(bit_in, CStringGetDatum(strVal(value)), ObjectIdGetDatum(InvalidOid), Int32GetDatum(-1)); typeid = BITOID; typelen = -1; typebyval = false; break; case T_Null: /* return a null const */ con = makeConst(UNKNOWNOID, -1, (Datum) 0, true, false); return con; default: elog(ERROR, "unrecognized node type: %d", (int) nodeTag(value)); return NULL; /* keep compiler quiet */ } con = makeConst(typeid, typelen, val, false, typebyval); return con; }