/*------------------------------------------------------------------------- * * parse_node.c-- * various routines that make nodes for query plans * * Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * $Header: /cvsroot/pgsql/src/backend/parser/parse_node.c,v 1.17 1998/07/12 21:29:20 momjian Exp $ * *------------------------------------------------------------------------- */ #include #include #include "postgres.h" #include "access/heapam.h" #include "catalog/pg_operator.h" #include "catalog/pg_type.h" #include "fmgr.h" #include "nodes/makefuncs.h" #include "parser/parse_expr.h" #include "parser/parse_node.h" #include "parser/parse_oper.h" #include "parser/parse_relation.h" #include "parser/parse_type.h" #include "parser/parse_coerce.h" #include "utils/builtins.h" #include "utils/syscache.h" #include "utils/lsyscache.h" static void disallow_setop(char *op, Type optype, Node *operand); static Node * make_operand(char *opname, Node *tree, Oid orig_typeId, Oid true_typeId); /* 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 = palloc(sizeof(ParseState)); MemSet(pstate, 0, sizeof(ParseState)); pstate->p_last_resno = 1; pstate->parentParseState = parentParseState; return (pstate); } /* make_operand() * Ensure argument type match by forcing conversion of constants. */ static Node * make_operand(char *opname, Node *tree, Oid orig_typeId, Oid true_typeId) { Node *result; Type true_type; #ifdef PARSEDEBUG printf("make_operand: constructing operand for '%s' %s->%s\n", opname, typeidTypeName(orig_typeId), typeidTypeName(true_typeId)); #endif if (tree != NULL) { result = tree; true_type = typeidType(true_typeId); disallow_setop(opname, true_type, result); /* must coerce? */ if (true_typeId != orig_typeId) { #ifdef PARSEDEBUG printf("make_operand: try to convert node from %s to %s\n", typeidTypeName(orig_typeId), typeidTypeName(true_typeId)); #endif result = coerce_type(NULL, tree, orig_typeId, true_typeId); } } /* otherwise, this is a NULL value */ else { Const *con = makeNode(Const); con->consttype = true_typeId; con->constlen = 0; con->constvalue = (Datum) (struct varlena *) NULL; con->constisnull = true; con->constbyval = true; con->constisset = false; result = (Node *) con; } return result; } /* make_operand() */ static void disallow_setop(char *op, Type optype, Node *operand) { if (operand == NULL) return; if (nodeTag(operand) == T_Iter) { elog(ERROR, "An operand to the '%s' operator returns a set of %s," "\n\tbut '%s' takes single values, not sets.", op, typeTypeName(optype), op); } } /* make_op() * Operator construction. * * Transform operator expression ensuring type compatibility. * This is where some type conversion happens. */ Expr * make_op(char *opname, Node *ltree, Node *rtree) { Oid ltypeId, rtypeId; Operator tup; OperatorTupleForm opform; Oper *newop; Node *left, *right; Expr *result; /* right operator? */ if (rtree == NULL) { ltypeId = (ltree == NULL) ? UNKNOWNOID : exprType(ltree); tup = right_oper(opname, ltypeId); opform = (OperatorTupleForm) GETSTRUCT(tup); left = make_operand(opname, ltree, ltypeId, opform->oprleft); right = NULL; } /* left operator? */ else if (ltree == NULL) { rtypeId = (rtree == NULL) ? UNKNOWNOID : exprType(rtree); tup = left_oper(opname, rtypeId); #ifdef PARSEDEBUG printf("make_op: returned from left_oper() with structure at %p\n", (void *)tup); #endif opform = (OperatorTupleForm) GETSTRUCT(tup); #ifdef PARSEDEBUG printf("make_op: calling make_operand()\n"); #endif right = make_operand(opname, rtree, rtypeId, opform->oprright); left = NULL; } /* otherwise, binary operator */ else { /* binary operator */ ltypeId = (ltree == NULL) ? UNKNOWNOID : exprType(ltree); rtypeId = (rtree == NULL) ? UNKNOWNOID : exprType(rtree); /* check for exact match on this operator... */ if (HeapTupleIsValid(tup = oper_exact(opname, ltypeId, rtypeId, <ree, &rtree, TRUE))) { ltypeId = exprType(ltree); rtypeId = exprType(rtree); } /* try to find a match on likely candidates... */ else if (!HeapTupleIsValid(tup = oper_inexact(opname, ltypeId, rtypeId, <ree, &rtree, FALSE))) { /* Won't return from oper_inexact() without a candidate... */ } opform = (OperatorTupleForm) GETSTRUCT(tup); left = make_operand(opname, ltree, ltypeId, opform->oprleft); right = make_operand(opname, rtree, rtypeId, opform->oprright); } newop = makeOper(oprid(tup), /* opno */ InvalidOid, /* opid */ opform->oprresult, /* operator result type */ 0, NULL); result = makeNode(Expr); result->typeOid = opform->oprresult; result->opType = OP_EXPR; result->oper = (Node *) newop; if (!left) result->args = lcons(right, NIL); else if (!right) result->args = lcons(left, NIL); else result->args = lcons(left, lcons(right, NIL)); return result; } /* make_op() */ Var * make_var(ParseState *pstate, Oid relid, char *refname, char *attrname) { Var *varnode; int vnum, attid; Oid vartypeid; int32 type_mod; int sublevels_up; vnum = refnameRangeTablePosn(pstate, refname, &sublevels_up); attid = get_attnum(relid, attrname); if (attid == InvalidAttrNumber) elog(ERROR, "Relation %s does not have attribute %s", refname, attrname); vartypeid = get_atttype(relid, attid); type_mod = get_atttypmod(relid, attid); varnode = makeVar(vnum, attid, vartypeid, type_mod, sublevels_up, vnum, attid); return varnode; } /* * make_array_ref() -- Make an array reference node. * * Array references can hang off of arbitrary nested dot (or * function invocation) expressions. This routine takes a * tree generated by ParseFunc() and an array index and * generates a new array reference tree. We do some simple * typechecking to be sure the dereference is valid in the * type system, but we don't do any bounds checking here. * * indirection is a list of A_Indices */ ArrayRef * make_array_ref(Node *expr, List *indirection) { Oid typearray; HeapTuple type_tuple; TypeTupleForm type_struct_array, type_struct_element; ArrayRef *aref; Oid reftype; List *upperIndexpr = NIL; List *lowerIndexpr = NIL; typearray = exprType(expr); type_tuple = SearchSysCacheTuple(TYPOID, ObjectIdGetDatum(typearray), 0, 0, 0); if (!HeapTupleIsValid(type_tuple)) elog(ERROR, "make_array_ref: Cache lookup failed for type %d\n", typearray); /* get the array type struct from the type tuple */ type_struct_array = (TypeTupleForm) GETSTRUCT(type_tuple); if (type_struct_array->typelem == InvalidOid) elog(ERROR, "make_array_ref: type %s is not an array", (Name) &(type_struct_array->typname.data[0])); /* get the type tuple for the element type */ type_tuple = SearchSysCacheTuple(TYPOID, ObjectIdGetDatum(type_struct_array->typelem), 0, 0, 0); if (!HeapTupleIsValid(type_tuple)) elog(ERROR, "make_array_ref: Cache lookup failed for type %d\n", typearray); type_struct_element = (TypeTupleForm) GETSTRUCT(type_tuple); while (indirection != NIL) { A_Indices *ind = lfirst(indirection); if (ind->lidx) /* * XXX assumes all lower indices non null in this case */ lowerIndexpr = lappend(lowerIndexpr, ind->lidx); upperIndexpr = lappend(upperIndexpr, ind->uidx); indirection = lnext(indirection); } aref = makeNode(ArrayRef); aref->refattrlength = type_struct_array->typlen; aref->refelemlength = type_struct_element->typlen; aref->refelemtype = type_struct_array->typelem; aref->refelembyval = type_struct_element->typbyval; aref->refupperindexpr = upperIndexpr; aref->reflowerindexpr = lowerIndexpr; aref->refexpr = expr; aref->refassgnexpr = NULL; if (lowerIndexpr == NIL) /* accessing a single array element */ reftype = aref->refelemtype; else /* request to clip a part of the array, the result is another array */ reftype = typearray; /* * we change it to reflect the true type; since the original * refelemtype doesn't seem to get used anywhere. - ay 10/94 */ aref->refelemtype = reftype; return aref; } /* make_array_set() */ ArrayRef * make_array_set(Expr *target_expr, List *upperIndexpr, List *lowerIndexpr, Expr *expr) { Oid typearray; HeapTuple type_tuple; TypeTupleForm type_struct_array; TypeTupleForm type_struct_element; ArrayRef *aref; Oid reftype; typearray = exprType((Node *) target_expr); type_tuple = SearchSysCacheTuple(TYPOID, ObjectIdGetDatum(typearray), 0, 0, 0); if (!HeapTupleIsValid(type_tuple)) elog(ERROR, "make_array_ref: Cache lookup failed for type %d\n", typearray); /* get the array type struct from the type tuple */ type_struct_array = (TypeTupleForm) GETSTRUCT(type_tuple); if (type_struct_array->typelem == InvalidOid) elog(ERROR, "make_array_ref: type %s is not an array", (Name) &(type_struct_array->typname.data[0])); /* get the type tuple for the element type */ type_tuple = SearchSysCacheTuple(TYPOID, ObjectIdGetDatum(type_struct_array->typelem), 0, 0, 0); if (!HeapTupleIsValid(type_tuple)) elog(ERROR, "make_array_ref: Cache lookup failed for type %d\n", typearray); type_struct_element = (TypeTupleForm) GETSTRUCT(type_tuple); aref = makeNode(ArrayRef); aref->refattrlength = type_struct_array->typlen; aref->refelemlength = type_struct_element->typlen; aref->refelemtype = type_struct_array->typelem; aref->refelembyval = type_struct_element->typbyval; aref->refupperindexpr = upperIndexpr; aref->reflowerindexpr = lowerIndexpr; aref->refexpr = (Node *) target_expr; aref->refassgnexpr = (Node *) expr; /* accessing a single array element? */ if (lowerIndexpr == NIL) reftype = aref->refelemtype; /* otherwise, request to set a part of the array, by another array */ else reftype = typearray; aref->refelemtype = reftype; return aref; } /* * * make_const - * * - takes a lispvalue, (as returned to the yacc routine by the lexer) * extracts the type, and makes the appropriate type constant * by invoking the (c-callable) lisp routine c-make-const * via the lisp_call() mechanism * * eventually, produces a "const" lisp-struct as per nodedefs.cl */ Const * make_const(Value *value) { Type tp; Datum val; Const *con; switch (nodeTag(value)) { case T_Integer: tp = typeidType(INT4OID); val = Int32GetDatum(intVal(value)); break; case T_Float: { float64 dummy; tp = typeidType(FLOAT8OID); dummy = (float64) palloc(sizeof(float64data)); *dummy = floatVal(value); val = Float64GetDatum(dummy); } break; case T_String: tp = typeidType(UNKNOWNOID); /* unknown for now, will * be type coerced */ val = PointerGetDatum(textin(strVal(value))); break; case T_Null: default: { if (nodeTag(value) != T_Null) elog(NOTICE, "make_const: unknown type %d\n", nodeTag(value)); /* null const */ con = makeConst(0, 0, (Datum) NULL, true, false, false, false); return con; } } con = makeConst(typeTypeId(tp), typeLen(tp), val, false, typeByVal(tp), false, /* not a set */ false); return (con); }