/*------------------------------------------------------------------------- * * rewriteManip.c * * Portions Copyright (c) 1996-2025, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * src/backend/rewrite/rewriteManip.c * *------------------------------------------------------------------------- */ #include "postgres.h" #include "catalog/pg_type.h" #include "nodes/makefuncs.h" #include "nodes/nodeFuncs.h" #include "nodes/pathnodes.h" #include "nodes/plannodes.h" #include "parser/parse_coerce.h" #include "parser/parse_relation.h" #include "parser/parsetree.h" #include "rewrite/rewriteManip.h" #include "utils/lsyscache.h" typedef struct { int sublevels_up; } contain_aggs_of_level_context; typedef struct { int agg_location; int sublevels_up; } locate_agg_of_level_context; typedef struct { int win_location; } locate_windowfunc_context; typedef struct { const Bitmapset *target_relids; const Bitmapset *added_relids; int sublevels_up; } add_nulling_relids_context; typedef struct { const Bitmapset *removable_relids; const Bitmapset *except_relids; int sublevels_up; } remove_nulling_relids_context; static bool contain_aggs_of_level_walker(Node *node, contain_aggs_of_level_context *context); static bool locate_agg_of_level_walker(Node *node, locate_agg_of_level_context *context); static bool contain_windowfuncs_walker(Node *node, void *context); static bool locate_windowfunc_walker(Node *node, locate_windowfunc_context *context); static bool checkExprHasSubLink_walker(Node *node, void *context); static Relids offset_relid_set(Relids relids, int offset); static Node *add_nulling_relids_mutator(Node *node, add_nulling_relids_context *context); static Node *remove_nulling_relids_mutator(Node *node, remove_nulling_relids_context *context); /* * contain_aggs_of_level - * Check if an expression contains an aggregate function call of a * specified query level. * * The objective of this routine is to detect whether there are aggregates * belonging to the given query level. Aggregates belonging to subqueries * or outer queries do NOT cause a true result. We must recurse into * subqueries to detect outer-reference aggregates that logically belong to * the specified query level. */ bool contain_aggs_of_level(Node *node, int levelsup) { contain_aggs_of_level_context context; context.sublevels_up = levelsup; /* * Must be prepared to start with a Query or a bare expression tree; if * it's a Query, we don't want to increment sublevels_up. */ return query_or_expression_tree_walker(node, contain_aggs_of_level_walker, &context, 0); } static bool contain_aggs_of_level_walker(Node *node, contain_aggs_of_level_context *context) { if (node == NULL) return false; if (IsA(node, Aggref)) { if (((Aggref *) node)->agglevelsup == context->sublevels_up) return true; /* abort the tree traversal and return true */ /* else fall through to examine argument */ } if (IsA(node, GroupingFunc)) { if (((GroupingFunc *) node)->agglevelsup == context->sublevels_up) return true; /* else fall through to examine argument */ } if (IsA(node, Query)) { /* Recurse into subselects */ bool result; context->sublevels_up++; result = query_tree_walker((Query *) node, contain_aggs_of_level_walker, context, 0); context->sublevels_up--; return result; } return expression_tree_walker(node, contain_aggs_of_level_walker, context); } /* * locate_agg_of_level - * Find the parse location of any aggregate of the specified query level. * * Returns -1 if no such agg is in the querytree, or if they all have * unknown parse location. (The former case is probably caller error, * but we don't bother to distinguish it from the latter case.) * * Note: it might seem appropriate to merge this functionality into * contain_aggs_of_level, but that would complicate that function's API. * Currently, the only uses of this function are for error reporting, * and so shaving cycles probably isn't very important. */ int locate_agg_of_level(Node *node, int levelsup) { locate_agg_of_level_context context; context.agg_location = -1; /* in case we find nothing */ context.sublevels_up = levelsup; /* * Must be prepared to start with a Query or a bare expression tree; if * it's a Query, we don't want to increment sublevels_up. */ (void) query_or_expression_tree_walker(node, locate_agg_of_level_walker, &context, 0); return context.agg_location; } static bool locate_agg_of_level_walker(Node *node, locate_agg_of_level_context *context) { if (node == NULL) return false; if (IsA(node, Aggref)) { if (((Aggref *) node)->agglevelsup == context->sublevels_up && ((Aggref *) node)->location >= 0) { context->agg_location = ((Aggref *) node)->location; return true; /* abort the tree traversal and return true */ } /* else fall through to examine argument */ } if (IsA(node, GroupingFunc)) { if (((GroupingFunc *) node)->agglevelsup == context->sublevels_up && ((GroupingFunc *) node)->location >= 0) { context->agg_location = ((GroupingFunc *) node)->location; return true; /* abort the tree traversal and return true */ } } if (IsA(node, Query)) { /* Recurse into subselects */ bool result; context->sublevels_up++; result = query_tree_walker((Query *) node, locate_agg_of_level_walker, context, 0); context->sublevels_up--; return result; } return expression_tree_walker(node, locate_agg_of_level_walker, context); } /* * contain_windowfuncs - * Check if an expression contains a window function call of the * current query level. */ bool contain_windowfuncs(Node *node) { /* * Must be prepared to start with a Query or a bare expression tree; if * it's a Query, we don't want to increment sublevels_up. */ return query_or_expression_tree_walker(node, contain_windowfuncs_walker, NULL, 0); } static bool contain_windowfuncs_walker(Node *node, void *context) { if (node == NULL) return false; if (IsA(node, WindowFunc)) return true; /* abort the tree traversal and return true */ /* Mustn't recurse into subselects */ return expression_tree_walker(node, contain_windowfuncs_walker, context); } /* * locate_windowfunc - * Find the parse location of any windowfunc of the current query level. * * Returns -1 if no such windowfunc is in the querytree, or if they all have * unknown parse location. (The former case is probably caller error, * but we don't bother to distinguish it from the latter case.) * * Note: it might seem appropriate to merge this functionality into * contain_windowfuncs, but that would complicate that function's API. * Currently, the only uses of this function are for error reporting, * and so shaving cycles probably isn't very important. */ int locate_windowfunc(Node *node) { locate_windowfunc_context context; context.win_location = -1; /* in case we find nothing */ /* * Must be prepared to start with a Query or a bare expression tree; if * it's a Query, we don't want to increment sublevels_up. */ (void) query_or_expression_tree_walker(node, locate_windowfunc_walker, &context, 0); return context.win_location; } static bool locate_windowfunc_walker(Node *node, locate_windowfunc_context *context) { if (node == NULL) return false; if (IsA(node, WindowFunc)) { if (((WindowFunc *) node)->location >= 0) { context->win_location = ((WindowFunc *) node)->location; return true; /* abort the tree traversal and return true */ } /* else fall through to examine argument */ } /* Mustn't recurse into subselects */ return expression_tree_walker(node, locate_windowfunc_walker, context); } /* * checkExprHasSubLink - * Check if an expression contains a SubLink. */ bool checkExprHasSubLink(Node *node) { /* * If a Query is passed, examine it --- but we should not recurse into * sub-Queries that are in its rangetable or CTE list. */ return query_or_expression_tree_walker(node, checkExprHasSubLink_walker, NULL, QTW_IGNORE_RC_SUBQUERIES); } static bool checkExprHasSubLink_walker(Node *node, void *context) { if (node == NULL) return false; if (IsA(node, SubLink)) return true; /* abort the tree traversal and return true */ return expression_tree_walker(node, checkExprHasSubLink_walker, context); } /* * Check for MULTIEXPR Param within expression tree * * We intentionally don't descend into SubLinks: only Params at the current * query level are of interest. */ static bool contains_multiexpr_param(Node *node, void *context) { if (node == NULL) return false; if (IsA(node, Param)) { if (((Param *) node)->paramkind == PARAM_MULTIEXPR) return true; /* abort the tree traversal and return true */ return false; } return expression_tree_walker(node, contains_multiexpr_param, context); } /* * CombineRangeTables * Adds the RTEs of 'src_rtable' into 'dst_rtable' * * This also adds the RTEPermissionInfos of 'src_perminfos' (belonging to the * RTEs in 'src_rtable') into *dst_perminfos and also updates perminfoindex of * the RTEs in 'src_rtable' to now point to the perminfos' indexes in * *dst_perminfos. * * Note that this changes both 'dst_rtable' and 'dst_perminfos' destructively, * so the caller should have better passed safe-to-modify copies. */ void CombineRangeTables(List **dst_rtable, List **dst_perminfos, List *src_rtable, List *src_perminfos) { ListCell *l; int offset = list_length(*dst_perminfos); if (offset > 0) { foreach(l, src_rtable) { RangeTblEntry *rte = lfirst_node(RangeTblEntry, l); if (rte->perminfoindex > 0) rte->perminfoindex += offset; } } *dst_perminfos = list_concat(*dst_perminfos, src_perminfos); *dst_rtable = list_concat(*dst_rtable, src_rtable); } /* * OffsetVarNodes - adjust Vars when appending one query's RT to another * * Find all Var nodes in the given tree with varlevelsup == sublevels_up, * and increment their varno fields (rangetable indexes) by 'offset'. * The varnosyn fields are adjusted similarly. Also, adjust other nodes * that contain rangetable indexes, such as RangeTblRef and JoinExpr. * * NOTE: although this has the form of a walker, we cheat and modify the * nodes in-place. The given expression tree should have been copied * earlier to ensure that no unwanted side-effects occur! */ typedef struct { int offset; int sublevels_up; } OffsetVarNodes_context; static bool OffsetVarNodes_walker(Node *node, OffsetVarNodes_context *context) { if (node == NULL) return false; if (IsA(node, Var)) { Var *var = (Var *) node; if (var->varlevelsup == context->sublevels_up) { var->varno += context->offset; var->varnullingrels = offset_relid_set(var->varnullingrels, context->offset); if (var->varnosyn > 0) var->varnosyn += context->offset; } return false; } if (IsA(node, CurrentOfExpr)) { CurrentOfExpr *cexpr = (CurrentOfExpr *) node; if (context->sublevels_up == 0) cexpr->cvarno += context->offset; return false; } if (IsA(node, RangeTblRef)) { RangeTblRef *rtr = (RangeTblRef *) node; if (context->sublevels_up == 0) rtr->rtindex += context->offset; /* the subquery itself is visited separately */ return false; } if (IsA(node, JoinExpr)) { JoinExpr *j = (JoinExpr *) node; if (j->rtindex && context->sublevels_up == 0) j->rtindex += context->offset; /* fall through to examine children */ } if (IsA(node, PlaceHolderVar)) { PlaceHolderVar *phv = (PlaceHolderVar *) node; if (phv->phlevelsup == context->sublevels_up) { phv->phrels = offset_relid_set(phv->phrels, context->offset); phv->phnullingrels = offset_relid_set(phv->phnullingrels, context->offset); } /* fall through to examine children */ } if (IsA(node, AppendRelInfo)) { AppendRelInfo *appinfo = (AppendRelInfo *) node; if (context->sublevels_up == 0) { appinfo->parent_relid += context->offset; appinfo->child_relid += context->offset; } /* fall through to examine children */ } /* Shouldn't need to handle other planner auxiliary nodes here */ Assert(!IsA(node, PlanRowMark)); Assert(!IsA(node, SpecialJoinInfo)); Assert(!IsA(node, PlaceHolderInfo)); Assert(!IsA(node, MinMaxAggInfo)); if (IsA(node, Query)) { /* Recurse into subselects */ bool result; context->sublevels_up++; result = query_tree_walker((Query *) node, OffsetVarNodes_walker, context, 0); context->sublevels_up--; return result; } return expression_tree_walker(node, OffsetVarNodes_walker, context); } void OffsetVarNodes(Node *node, int offset, int sublevels_up) { OffsetVarNodes_context context; context.offset = offset; context.sublevels_up = sublevels_up; /* * Must be prepared to start with a Query or a bare expression tree; if * it's a Query, go straight to query_tree_walker to make sure that * sublevels_up doesn't get incremented prematurely. */ if (node && IsA(node, Query)) { Query *qry = (Query *) node; /* * If we are starting at a Query, and sublevels_up is zero, then we * must also fix rangetable indexes in the Query itself --- namely * resultRelation, mergeTargetRelation, exclRelIndex and rowMarks * entries. sublevels_up cannot be zero when recursing into a * subquery, so there's no need to have the same logic inside * OffsetVarNodes_walker. */ if (sublevels_up == 0) { ListCell *l; if (qry->resultRelation) qry->resultRelation += offset; if (qry->mergeTargetRelation) qry->mergeTargetRelation += offset; if (qry->onConflict && qry->onConflict->exclRelIndex) qry->onConflict->exclRelIndex += offset; foreach(l, qry->rowMarks) { RowMarkClause *rc = (RowMarkClause *) lfirst(l); rc->rti += offset; } } query_tree_walker(qry, OffsetVarNodes_walker, &context, 0); } else OffsetVarNodes_walker(node, &context); } static Relids offset_relid_set(Relids relids, int offset) { Relids result = NULL; int rtindex; rtindex = -1; while ((rtindex = bms_next_member(relids, rtindex)) >= 0) result = bms_add_member(result, rtindex + offset); return result; } /* * ChangeVarNodes - adjust Var nodes for a specific change of RT index * * Find all Var nodes in the given tree belonging to a specific relation * (identified by sublevels_up and rt_index), and change their varno fields * to 'new_index'. The varnosyn fields are changed too. Also, adjust other * nodes that contain rangetable indexes, such as RangeTblRef and JoinExpr. * Specifying 'change_RangeTblRef' to false allows skipping RangeTblRef. * See ChangeVarNodesExtended for details. * * NOTE: although this has the form of a walker, we cheat and modify the * nodes in-place. The given expression tree should have been copied * earlier to ensure that no unwanted side-effects occur! */ static bool ChangeVarNodes_walker(Node *node, ChangeVarNodes_context *context) { if (node == NULL) return false; if (context->callback && context->callback(node, context)) return false; if (IsA(node, Var)) { Var *var = (Var *) node; if (var->varlevelsup == context->sublevels_up) { if (var->varno == context->rt_index) var->varno = context->new_index; var->varnullingrels = adjust_relid_set(var->varnullingrels, context->rt_index, context->new_index); if (var->varnosyn == context->rt_index) var->varnosyn = context->new_index; } return false; } if (IsA(node, CurrentOfExpr)) { CurrentOfExpr *cexpr = (CurrentOfExpr *) node; if (context->sublevels_up == 0 && cexpr->cvarno == context->rt_index) cexpr->cvarno = context->new_index; return false; } if (IsA(node, RangeTblRef)) { RangeTblRef *rtr = (RangeTblRef *) node; if (context->sublevels_up == 0 && rtr->rtindex == context->rt_index) rtr->rtindex = context->new_index; /* the subquery itself is visited separately */ return false; } if (IsA(node, JoinExpr)) { JoinExpr *j = (JoinExpr *) node; if (context->sublevels_up == 0 && j->rtindex == context->rt_index) j->rtindex = context->new_index; /* fall through to examine children */ } if (IsA(node, PlaceHolderVar)) { PlaceHolderVar *phv = (PlaceHolderVar *) node; if (phv->phlevelsup == context->sublevels_up) { phv->phrels = adjust_relid_set(phv->phrels, context->rt_index, context->new_index); phv->phnullingrels = adjust_relid_set(phv->phnullingrels, context->rt_index, context->new_index); } /* fall through to examine children */ } if (IsA(node, PlanRowMark)) { PlanRowMark *rowmark = (PlanRowMark *) node; if (context->sublevels_up == 0) { if (rowmark->rti == context->rt_index) rowmark->rti = context->new_index; if (rowmark->prti == context->rt_index) rowmark->prti = context->new_index; } return false; } if (IsA(node, AppendRelInfo)) { AppendRelInfo *appinfo = (AppendRelInfo *) node; if (context->sublevels_up == 0) { if (appinfo->parent_relid == context->rt_index) appinfo->parent_relid = context->new_index; if (appinfo->child_relid == context->rt_index) appinfo->child_relid = context->new_index; } /* fall through to examine children */ } /* Shouldn't need to handle other planner auxiliary nodes here */ Assert(!IsA(node, SpecialJoinInfo)); Assert(!IsA(node, PlaceHolderInfo)); Assert(!IsA(node, MinMaxAggInfo)); if (IsA(node, Query)) { /* Recurse into subselects */ bool result; context->sublevels_up++; result = query_tree_walker((Query *) node, ChangeVarNodes_walker, context, 0); context->sublevels_up--; return result; } return expression_tree_walker(node, ChangeVarNodes_walker, context); } /* * ChangeVarNodesExtended - similar to ChangeVarNodes, but with an additional * 'callback' param * * ChangeVarNodes changes a given node and all of its underlying nodes. * This version of function additionally takes a callback, which has a * chance to process a node before ChangeVarNodes_walker. A callback * returns a boolean value indicating if given node should be skipped from * further processing by ChangeVarNodes_walker. The callback is called * only for expressions and other children nodes of a Query processed by * a walker. Initial processing of the root Query doesn't involve the * callback. */ void ChangeVarNodesExtended(Node *node, int rt_index, int new_index, int sublevels_up, ChangeVarNodes_callback callback) { ChangeVarNodes_context context; context.rt_index = rt_index; context.new_index = new_index; context.sublevels_up = sublevels_up; context.callback = callback; /* * Must be prepared to start with a Query or a bare expression tree; if * it's a Query, go straight to query_tree_walker to make sure that * sublevels_up doesn't get incremented prematurely. */ if (node && IsA(node, Query)) { Query *qry = (Query *) node; /* * If we are starting at a Query, and sublevels_up is zero, then we * must also fix rangetable indexes in the Query itself --- namely * resultRelation, mergeTargetRelation, exclRelIndex and rowMarks * entries. sublevels_up cannot be zero when recursing into a * subquery, so there's no need to have the same logic inside * ChangeVarNodes_walker. */ if (sublevels_up == 0) { ListCell *l; if (qry->resultRelation == rt_index) qry->resultRelation = new_index; if (qry->mergeTargetRelation == rt_index) qry->mergeTargetRelation = new_index; /* this is unlikely to ever be used, but ... */ if (qry->onConflict && qry->onConflict->exclRelIndex == rt_index) qry->onConflict->exclRelIndex = new_index; foreach(l, qry->rowMarks) { RowMarkClause *rc = (RowMarkClause *) lfirst(l); if (rc->rti == rt_index) rc->rti = new_index; } } query_tree_walker(qry, ChangeVarNodes_walker, &context, 0); } else ChangeVarNodes_walker(node, &context); } void ChangeVarNodes(Node *node, int rt_index, int new_index, int sublevels_up) { ChangeVarNodesExtended(node, rt_index, new_index, sublevels_up, NULL); } /* * ChangeVarNodesWalkExpression - process expression within the custom * callback provided to the * ChangeVarNodesExtended. */ bool ChangeVarNodesWalkExpression(Node *node, ChangeVarNodes_context *context) { return expression_tree_walker(node, ChangeVarNodes_walker, (void *) context); } /* * adjust_relid_set - substitute newrelid for oldrelid in a Relid set * * Attempt to remove oldrelid from a Relid set (as long as it's not a special * varno). If oldrelid was found and removed, insert newrelid into a Relid * set (as long as it's not a special varno). Therefore, when oldrelid is * a special varno, this function does nothing. When newrelid is a special * varno, this function behaves as delete. */ Relids adjust_relid_set(Relids relids, int oldrelid, int newrelid) { if (!IS_SPECIAL_VARNO(oldrelid) && bms_is_member(oldrelid, relids)) { /* Ensure we have a modifiable copy */ relids = bms_copy(relids); /* Remove old, add new */ relids = bms_del_member(relids, oldrelid); if (!IS_SPECIAL_VARNO(newrelid)) relids = bms_add_member(relids, newrelid); } return relids; } /* * IncrementVarSublevelsUp - adjust Var nodes when pushing them down in tree * * Find all Var nodes in the given tree having varlevelsup >= min_sublevels_up, * and add delta_sublevels_up to their varlevelsup value. This is needed when * an expression that's correct for some nesting level is inserted into a * subquery. Ordinarily the initial call has min_sublevels_up == 0 so that * all Vars are affected. The point of min_sublevels_up is that we can * increment it when we recurse into a sublink, so that local variables in * that sublink are not affected, only outer references to vars that belong * to the expression's original query level or parents thereof. * * Likewise for other nodes containing levelsup fields, such as Aggref. * * NOTE: although this has the form of a walker, we cheat and modify the * Var nodes in-place. The given expression tree should have been copied * earlier to ensure that no unwanted side-effects occur! */ typedef struct { int delta_sublevels_up; int min_sublevels_up; } IncrementVarSublevelsUp_context; static bool IncrementVarSublevelsUp_walker(Node *node, IncrementVarSublevelsUp_context *context) { if (node == NULL) return false; if (IsA(node, Var)) { Var *var = (Var *) node; if (var->varlevelsup >= context->min_sublevels_up) var->varlevelsup += context->delta_sublevels_up; return false; /* done here */ } if (IsA(node, CurrentOfExpr)) { /* this should not happen */ if (context->min_sublevels_up == 0) elog(ERROR, "cannot push down CurrentOfExpr"); return false; } if (IsA(node, Aggref)) { Aggref *agg = (Aggref *) node; if (agg->agglevelsup >= context->min_sublevels_up) agg->agglevelsup += context->delta_sublevels_up; /* fall through to recurse into argument */ } if (IsA(node, GroupingFunc)) { GroupingFunc *grp = (GroupingFunc *) node; if (grp->agglevelsup >= context->min_sublevels_up) grp->agglevelsup += context->delta_sublevels_up; /* fall through to recurse into argument */ } if (IsA(node, PlaceHolderVar)) { PlaceHolderVar *phv = (PlaceHolderVar *) node; if (phv->phlevelsup >= context->min_sublevels_up) phv->phlevelsup += context->delta_sublevels_up; /* fall through to recurse into argument */ } if (IsA(node, ReturningExpr)) { ReturningExpr *rexpr = (ReturningExpr *) node; if (rexpr->retlevelsup >= context->min_sublevels_up) rexpr->retlevelsup += context->delta_sublevels_up; /* fall through to recurse into argument */ } if (IsA(node, RangeTblEntry)) { RangeTblEntry *rte = (RangeTblEntry *) node; if (rte->rtekind == RTE_CTE) { if (rte->ctelevelsup >= context->min_sublevels_up) rte->ctelevelsup += context->delta_sublevels_up; } return false; /* allow range_table_walker to continue */ } if (IsA(node, Query)) { /* Recurse into subselects */ bool result; context->min_sublevels_up++; result = query_tree_walker((Query *) node, IncrementVarSublevelsUp_walker, context, QTW_EXAMINE_RTES_BEFORE); context->min_sublevels_up--; return result; } return expression_tree_walker(node, IncrementVarSublevelsUp_walker, context); } void IncrementVarSublevelsUp(Node *node, int delta_sublevels_up, int min_sublevels_up) { IncrementVarSublevelsUp_context context; context.delta_sublevels_up = delta_sublevels_up; context.min_sublevels_up = min_sublevels_up; /* * Must be prepared to start with a Query or a bare expression tree; if * it's a Query, we don't want to increment sublevels_up. */ query_or_expression_tree_walker(node, IncrementVarSublevelsUp_walker, &context, QTW_EXAMINE_RTES_BEFORE); } /* * IncrementVarSublevelsUp_rtable - * Same as IncrementVarSublevelsUp, but to be invoked on a range table. */ void IncrementVarSublevelsUp_rtable(List *rtable, int delta_sublevels_up, int min_sublevels_up) { IncrementVarSublevelsUp_context context; context.delta_sublevels_up = delta_sublevels_up; context.min_sublevels_up = min_sublevels_up; range_table_walker(rtable, IncrementVarSublevelsUp_walker, &context, QTW_EXAMINE_RTES_BEFORE); } /* * SetVarReturningType - adjust Var nodes for a specified varreturningtype. * * Find all Var nodes referring to the specified result relation in the given * expression and set their varreturningtype to the specified value. * * NOTE: although this has the form of a walker, we cheat and modify the * Var nodes in-place. The given expression tree should have been copied * earlier to ensure that no unwanted side-effects occur! */ typedef struct { int result_relation; int sublevels_up; VarReturningType returning_type; } SetVarReturningType_context; static bool SetVarReturningType_walker(Node *node, SetVarReturningType_context *context) { if (node == NULL) return false; if (IsA(node, Var)) { Var *var = (Var *) node; if (var->varno == context->result_relation && var->varlevelsup == context->sublevels_up) var->varreturningtype = context->returning_type; return false; } if (IsA(node, Query)) { /* Recurse into subselects */ bool result; context->sublevels_up++; result = query_tree_walker((Query *) node, SetVarReturningType_walker, context, 0); context->sublevels_up--; return result; } return expression_tree_walker(node, SetVarReturningType_walker, context); } static void SetVarReturningType(Node *node, int result_relation, int sublevels_up, VarReturningType returning_type) { SetVarReturningType_context context; context.result_relation = result_relation; context.sublevels_up = sublevels_up; context.returning_type = returning_type; /* Expect to start with an expression */ SetVarReturningType_walker(node, &context); } /* * rangeTableEntry_used - detect whether an RTE is referenced somewhere * in var nodes or join or setOp trees of a query or expression. */ typedef struct { int rt_index; int sublevels_up; } rangeTableEntry_used_context; static bool rangeTableEntry_used_walker(Node *node, rangeTableEntry_used_context *context) { if (node == NULL) return false; if (IsA(node, Var)) { Var *var = (Var *) node; if (var->varlevelsup == context->sublevels_up && (var->varno == context->rt_index || bms_is_member(context->rt_index, var->varnullingrels))) return true; return false; } if (IsA(node, CurrentOfExpr)) { CurrentOfExpr *cexpr = (CurrentOfExpr *) node; if (context->sublevels_up == 0 && cexpr->cvarno == context->rt_index) return true; return false; } if (IsA(node, RangeTblRef)) { RangeTblRef *rtr = (RangeTblRef *) node; if (rtr->rtindex == context->rt_index && context->sublevels_up == 0) return true; /* the subquery itself is visited separately */ return false; } if (IsA(node, JoinExpr)) { JoinExpr *j = (JoinExpr *) node; if (j->rtindex == context->rt_index && context->sublevels_up == 0) return true; /* fall through to examine children */ } /* Shouldn't need to handle planner auxiliary nodes here */ Assert(!IsA(node, PlaceHolderVar)); Assert(!IsA(node, PlanRowMark)); Assert(!IsA(node, SpecialJoinInfo)); Assert(!IsA(node, AppendRelInfo)); Assert(!IsA(node, PlaceHolderInfo)); Assert(!IsA(node, MinMaxAggInfo)); if (IsA(node, Query)) { /* Recurse into subselects */ bool result; context->sublevels_up++; result = query_tree_walker((Query *) node, rangeTableEntry_used_walker, context, 0); context->sublevels_up--; return result; } return expression_tree_walker(node, rangeTableEntry_used_walker, context); } bool rangeTableEntry_used(Node *node, int rt_index, int sublevels_up) { rangeTableEntry_used_context context; context.rt_index = rt_index; context.sublevels_up = sublevels_up; /* * Must be prepared to start with a Query or a bare expression tree; if * it's a Query, we don't want to increment sublevels_up. */ return query_or_expression_tree_walker(node, rangeTableEntry_used_walker, &context, 0); } /* * If the given Query is an INSERT ... SELECT construct, extract and * return the sub-Query node that represents the SELECT part. Otherwise * return the given Query. * * If subquery_ptr is not NULL, then *subquery_ptr is set to the location * of the link to the SELECT subquery inside parsetree, or NULL if not an * INSERT ... SELECT. * * This is a hack needed because transformations on INSERT ... SELECTs that * appear in rule actions should be applied to the source SELECT, not to the * INSERT part. Perhaps this can be cleaned up with redesigned querytrees. */ Query * getInsertSelectQuery(Query *parsetree, Query ***subquery_ptr) { Query *selectquery; RangeTblEntry *selectrte; RangeTblRef *rtr; if (subquery_ptr) *subquery_ptr = NULL; if (parsetree == NULL) return parsetree; if (parsetree->commandType != CMD_INSERT) return parsetree; /* * Currently, this is ONLY applied to rule-action queries, and so we * expect to find the OLD and NEW placeholder entries in the given query. * If they're not there, it must be an INSERT/SELECT in which they've been * pushed down to the SELECT. */ if (list_length(parsetree->rtable) >= 2 && strcmp(rt_fetch(PRS2_OLD_VARNO, parsetree->rtable)->eref->aliasname, "old") == 0 && strcmp(rt_fetch(PRS2_NEW_VARNO, parsetree->rtable)->eref->aliasname, "new") == 0) return parsetree; Assert(parsetree->jointree && IsA(parsetree->jointree, FromExpr)); if (list_length(parsetree->jointree->fromlist) != 1) elog(ERROR, "expected to find SELECT subquery"); rtr = (RangeTblRef *) linitial(parsetree->jointree->fromlist); if (!IsA(rtr, RangeTblRef)) elog(ERROR, "expected to find SELECT subquery"); selectrte = rt_fetch(rtr->rtindex, parsetree->rtable); if (!(selectrte->rtekind == RTE_SUBQUERY && selectrte->subquery && IsA(selectrte->subquery, Query) && selectrte->subquery->commandType == CMD_SELECT)) elog(ERROR, "expected to find SELECT subquery"); selectquery = selectrte->subquery; if (list_length(selectquery->rtable) >= 2 && strcmp(rt_fetch(PRS2_OLD_VARNO, selectquery->rtable)->eref->aliasname, "old") == 0 && strcmp(rt_fetch(PRS2_NEW_VARNO, selectquery->rtable)->eref->aliasname, "new") == 0) { if (subquery_ptr) *subquery_ptr = &(selectrte->subquery); return selectquery; } elog(ERROR, "could not find rule placeholders"); return NULL; /* not reached */ } /* * Add the given qualifier condition to the query's WHERE clause */ void AddQual(Query *parsetree, Node *qual) { Node *copy; if (qual == NULL) return; if (parsetree->commandType == CMD_UTILITY) { /* * There's noplace to put the qual on a utility statement. * * If it's a NOTIFY, silently ignore the qual; this means that the * NOTIFY will execute, whether or not there are any qualifying rows. * While clearly wrong, this is much more useful than refusing to * execute the rule at all, and extra NOTIFY events are harmless for * typical uses of NOTIFY. * * If it isn't a NOTIFY, error out, since unconditional execution of * other utility stmts is unlikely to be wanted. (This case is not * currently allowed anyway, but keep the test for safety.) */ if (parsetree->utilityStmt && IsA(parsetree->utilityStmt, NotifyStmt)) return; else ereport(ERROR, (errcode(ERRCODE_FEATURE_NOT_SUPPORTED), errmsg("conditional utility statements are not implemented"))); } if (parsetree->setOperations != NULL) { /* * There's noplace to put the qual on a setop statement, either. (This * could be fixed, but right now the planner simply ignores any qual * condition on a setop query.) */ ereport(ERROR, (errcode(ERRCODE_FEATURE_NOT_SUPPORTED), errmsg("conditional UNION/INTERSECT/EXCEPT statements are not implemented"))); } /* INTERSECT wants the original, but we need to copy - Jan */ copy = copyObject(qual); parsetree->jointree->quals = make_and_qual(parsetree->jointree->quals, copy); /* * We had better not have stuck an aggregate into the WHERE clause. */ Assert(!contain_aggs_of_level(copy, 0)); /* * Make sure query is marked correctly if added qual has sublinks. Need * not search qual when query is already marked. */ if (!parsetree->hasSubLinks) parsetree->hasSubLinks = checkExprHasSubLink(copy); } /* * Invert the given clause and add it to the WHERE qualifications of the * given querytree. Inversion means "x IS NOT TRUE", not just "NOT x", * else we will do the wrong thing when x evaluates to NULL. */ void AddInvertedQual(Query *parsetree, Node *qual) { BooleanTest *invqual; if (qual == NULL) return; /* Need not copy input qual, because AddQual will... */ invqual = makeNode(BooleanTest); invqual->arg = (Expr *) qual; invqual->booltesttype = IS_NOT_TRUE; invqual->location = -1; AddQual(parsetree, (Node *) invqual); } /* * add_nulling_relids() finds Vars and PlaceHolderVars that belong to any * of the target_relids, and adds added_relids to their varnullingrels * and phnullingrels fields. If target_relids is NULL, all level-zero * Vars and PHVs are modified. */ Node * add_nulling_relids(Node *node, const Bitmapset *target_relids, const Bitmapset *added_relids) { add_nulling_relids_context context; context.target_relids = target_relids; context.added_relids = added_relids; context.sublevels_up = 0; return query_or_expression_tree_mutator(node, add_nulling_relids_mutator, &context, 0); } static Node * add_nulling_relids_mutator(Node *node, add_nulling_relids_context *context) { if (node == NULL) return NULL; if (IsA(node, Var)) { Var *var = (Var *) node; if (var->varlevelsup == context->sublevels_up && (context->target_relids == NULL || bms_is_member(var->varno, context->target_relids))) { Relids newnullingrels = bms_union(var->varnullingrels, context->added_relids); /* Copy the Var ... */ var = copyObject(var); /* ... and replace the copy's varnullingrels field */ var->varnullingrels = newnullingrels; return (Node *) var; } /* Otherwise fall through to copy the Var normally */ } else if (IsA(node, PlaceHolderVar)) { PlaceHolderVar *phv = (PlaceHolderVar *) node; if (phv->phlevelsup == context->sublevels_up && (context->target_relids == NULL || bms_overlap(phv->phrels, context->target_relids))) { Relids newnullingrels = bms_union(phv->phnullingrels, context->added_relids); /* * We don't modify the contents of the PHV's expression, only add * to phnullingrels. This corresponds to assuming that the PHV * will be evaluated at the same level as before, then perhaps be * nulled as it bubbles up. Hence, just flat-copy the node ... */ phv = makeNode(PlaceHolderVar); memcpy(phv, node, sizeof(PlaceHolderVar)); /* ... and replace the copy's phnullingrels field */ phv->phnullingrels = newnullingrels; return (Node *) phv; } /* Otherwise fall through to copy the PlaceHolderVar normally */ } else if (IsA(node, Query)) { /* Recurse into RTE or sublink subquery */ Query *newnode; context->sublevels_up++; newnode = query_tree_mutator((Query *) node, add_nulling_relids_mutator, context, 0); context->sublevels_up--; return (Node *) newnode; } return expression_tree_mutator(node, add_nulling_relids_mutator, context); } /* * remove_nulling_relids() removes mentions of the specified RT index(es) * in Var.varnullingrels and PlaceHolderVar.phnullingrels fields within * the given expression, except in nodes belonging to rels listed in * except_relids. */ Node * remove_nulling_relids(Node *node, const Bitmapset *removable_relids, const Bitmapset *except_relids) { remove_nulling_relids_context context; context.removable_relids = removable_relids; context.except_relids = except_relids; context.sublevels_up = 0; return query_or_expression_tree_mutator(node, remove_nulling_relids_mutator, &context, 0); } static Node * remove_nulling_relids_mutator(Node *node, remove_nulling_relids_context *context) { if (node == NULL) return NULL; if (IsA(node, Var)) { Var *var = (Var *) node; if (var->varlevelsup == context->sublevels_up && !bms_is_member(var->varno, context->except_relids) && bms_overlap(var->varnullingrels, context->removable_relids)) { /* Copy the Var ... */ var = copyObject(var); /* ... and replace the copy's varnullingrels field */ var->varnullingrels = bms_difference(var->varnullingrels, context->removable_relids); return (Node *) var; } /* Otherwise fall through to copy the Var normally */ } else if (IsA(node, PlaceHolderVar)) { PlaceHolderVar *phv = (PlaceHolderVar *) node; if (phv->phlevelsup == context->sublevels_up && !bms_overlap(phv->phrels, context->except_relids)) { /* * Note: it might seem desirable to remove the PHV altogether if * phnullingrels goes to empty. Currently we dare not do that * because we use PHVs in some cases to enforce separate identity * of subexpressions; see wrap_option usages in prepjointree.c. */ /* Copy the PlaceHolderVar and mutate what's below ... */ phv = (PlaceHolderVar *) expression_tree_mutator(node, remove_nulling_relids_mutator, context); /* ... and replace the copy's phnullingrels field */ phv->phnullingrels = bms_difference(phv->phnullingrels, context->removable_relids); /* We must also update phrels, if it contains a removable RTI */ phv->phrels = bms_difference(phv->phrels, context->removable_relids); Assert(!bms_is_empty(phv->phrels)); return (Node *) phv; } /* Otherwise fall through to copy the PlaceHolderVar normally */ } else if (IsA(node, Query)) { /* Recurse into RTE or sublink subquery */ Query *newnode; context->sublevels_up++; newnode = query_tree_mutator((Query *) node, remove_nulling_relids_mutator, context, 0); context->sublevels_up--; return (Node *) newnode; } return expression_tree_mutator(node, remove_nulling_relids_mutator, context); } /* * replace_rte_variables() finds all Vars in an expression tree * that reference a particular RTE, and replaces them with substitute * expressions obtained from a caller-supplied callback function. * * When invoking replace_rte_variables on a portion of a Query, pass the * address of the containing Query's hasSubLinks field as outer_hasSubLinks. * Otherwise, pass NULL, but inserting a SubLink into a non-Query expression * will then cause an error. * * Note: the business with inserted_sublink is needed to update hasSubLinks * in subqueries when the replacement adds a subquery inside a subquery. * Messy, isn't it? We do not need to do similar pushups for hasAggs, * because it isn't possible for this transformation to insert a level-zero * aggregate reference into a subquery --- it could only insert outer aggs. * Likewise for hasWindowFuncs. * * Note: usually, we'd not expose the mutator function or context struct * for a function like this. We do so because callbacks often find it * convenient to recurse directly to the mutator on sub-expressions of * what they will return. */ Node * replace_rte_variables(Node *node, int target_varno, int sublevels_up, replace_rte_variables_callback callback, void *callback_arg, bool *outer_hasSubLinks) { Node *result; replace_rte_variables_context context; context.callback = callback; context.callback_arg = callback_arg; context.target_varno = target_varno; context.sublevels_up = sublevels_up; /* * We try to initialize inserted_sublink to true if there is no need to * detect new sublinks because the query already has some. */ if (node && IsA(node, Query)) context.inserted_sublink = ((Query *) node)->hasSubLinks; else if (outer_hasSubLinks) context.inserted_sublink = *outer_hasSubLinks; else context.inserted_sublink = false; /* * Must be prepared to start with a Query or a bare expression tree; if * it's a Query, we don't want to increment sublevels_up. */ result = query_or_expression_tree_mutator(node, replace_rte_variables_mutator, &context, 0); if (context.inserted_sublink) { if (result && IsA(result, Query)) ((Query *) result)->hasSubLinks = true; else if (outer_hasSubLinks) *outer_hasSubLinks = true; else elog(ERROR, "replace_rte_variables inserted a SubLink, but has noplace to record it"); } return result; } Node * replace_rte_variables_mutator(Node *node, replace_rte_variables_context *context) { if (node == NULL) return NULL; if (IsA(node, Var)) { Var *var = (Var *) node; if (var->varno == context->target_varno && var->varlevelsup == context->sublevels_up) { /* Found a matching variable, make the substitution */ Node *newnode; newnode = context->callback(var, context); /* Detect if we are adding a sublink to query */ if (!context->inserted_sublink) context->inserted_sublink = checkExprHasSubLink(newnode); return newnode; } /* otherwise fall through to copy the var normally */ } else if (IsA(node, CurrentOfExpr)) { CurrentOfExpr *cexpr = (CurrentOfExpr *) node; if (cexpr->cvarno == context->target_varno && context->sublevels_up == 0) { /* * We get here if a WHERE CURRENT OF expression turns out to apply * to a view. Someday we might be able to translate the * expression to apply to an underlying table of the view, but * right now it's not implemented. */ ereport(ERROR, (errcode(ERRCODE_FEATURE_NOT_SUPPORTED), errmsg("WHERE CURRENT OF on a view is not implemented"))); } /* otherwise fall through to copy the expr normally */ } else if (IsA(node, Query)) { /* Recurse into RTE subquery or not-yet-planned sublink subquery */ Query *newnode; bool save_inserted_sublink; context->sublevels_up++; save_inserted_sublink = context->inserted_sublink; context->inserted_sublink = ((Query *) node)->hasSubLinks; newnode = query_tree_mutator((Query *) node, replace_rte_variables_mutator, context, 0); newnode->hasSubLinks |= context->inserted_sublink; context->inserted_sublink = save_inserted_sublink; context->sublevels_up--; return (Node *) newnode; } return expression_tree_mutator(node, replace_rte_variables_mutator, context); } /* * map_variable_attnos() finds all user-column Vars in an expression tree * that reference a particular RTE, and adjusts their varattnos according * to the given mapping array (varattno n is replaced by attno_map[n-1]). * Vars for system columns are not modified. * * A zero in the mapping array represents a dropped column, which should not * appear in the expression. * * If the expression tree contains a whole-row Var for the target RTE, * *found_whole_row is set to true. In addition, if to_rowtype is * not InvalidOid, we replace the Var with a Var of that vartype, inserting * a ConvertRowtypeExpr to map back to the rowtype expected by the expression. * (Therefore, to_rowtype had better be a child rowtype of the rowtype of the * RTE we're changing references to.) Callers that don't provide to_rowtype * should report an error if *found_whole_row is true; we don't do that here * because we don't know exactly what wording for the error message would * be most appropriate. The caller will be aware of the context. * * This could be built using replace_rte_variables and a callback function, * but since we don't ever need to insert sublinks, replace_rte_variables is * overly complicated. */ typedef struct { int target_varno; /* RTE index to search for */ int sublevels_up; /* (current) nesting depth */ const AttrMap *attno_map; /* map array for user attnos */ Oid to_rowtype; /* change whole-row Vars to this type */ bool *found_whole_row; /* output flag */ } map_variable_attnos_context; static Node * map_variable_attnos_mutator(Node *node, map_variable_attnos_context *context) { if (node == NULL) return NULL; if (IsA(node, Var)) { Var *var = (Var *) node; if (var->varno == context->target_varno && var->varlevelsup == context->sublevels_up) { /* Found a matching variable, make the substitution */ Var *newvar = (Var *) palloc(sizeof(Var)); int attno = var->varattno; *newvar = *var; /* initially copy all fields of the Var */ if (attno > 0) { /* user-defined column, replace attno */ if (attno > context->attno_map->maplen || context->attno_map->attnums[attno - 1] == 0) elog(ERROR, "unexpected varattno %d in expression to be mapped", attno); newvar->varattno = context->attno_map->attnums[attno - 1]; /* If the syntactic referent is same RTE, fix it too */ if (newvar->varnosyn == context->target_varno) newvar->varattnosyn = newvar->varattno; } else if (attno == 0) { /* whole-row variable, warn caller */ *(context->found_whole_row) = true; /* If the caller expects us to convert the Var, do so. */ if (OidIsValid(context->to_rowtype) && context->to_rowtype != var->vartype) { ConvertRowtypeExpr *r; /* This certainly won't work for a RECORD variable. */ Assert(var->vartype != RECORDOID); /* Var itself is changed to the requested type. */ newvar->vartype = context->to_rowtype; /* * Add a conversion node on top to convert back to the * original type expected by the expression. */ r = makeNode(ConvertRowtypeExpr); r->arg = (Expr *) newvar; r->resulttype = var->vartype; r->convertformat = COERCE_IMPLICIT_CAST; r->location = -1; return (Node *) r; } } return (Node *) newvar; } /* otherwise fall through to copy the var normally */ } else if (IsA(node, ConvertRowtypeExpr)) { ConvertRowtypeExpr *r = (ConvertRowtypeExpr *) node; Var *var = (Var *) r->arg; /* * If this is coercing a whole-row Var that we need to convert, then * just convert the Var without adding an extra ConvertRowtypeExpr. * Effectively we're simplifying var::parenttype::grandparenttype into * just var::grandparenttype. This avoids building stacks of CREs if * this function is applied repeatedly. */ if (IsA(var, Var) && var->varno == context->target_varno && var->varlevelsup == context->sublevels_up && var->varattno == 0 && OidIsValid(context->to_rowtype) && context->to_rowtype != var->vartype) { ConvertRowtypeExpr *newnode; Var *newvar = (Var *) palloc(sizeof(Var)); /* whole-row variable, warn caller */ *(context->found_whole_row) = true; *newvar = *var; /* initially copy all fields of the Var */ /* This certainly won't work for a RECORD variable. */ Assert(var->vartype != RECORDOID); /* Var itself is changed to the requested type. */ newvar->vartype = context->to_rowtype; newnode = (ConvertRowtypeExpr *) palloc(sizeof(ConvertRowtypeExpr)); *newnode = *r; /* initially copy all fields of the CRE */ newnode->arg = (Expr *) newvar; return (Node *) newnode; } /* otherwise fall through to process the expression normally */ } else if (IsA(node, Query)) { /* Recurse into RTE subquery or not-yet-planned sublink subquery */ Query *newnode; context->sublevels_up++; newnode = query_tree_mutator((Query *) node, map_variable_attnos_mutator, context, 0); context->sublevels_up--; return (Node *) newnode; } return expression_tree_mutator(node, map_variable_attnos_mutator, context); } Node * map_variable_attnos(Node *node, int target_varno, int sublevels_up, const AttrMap *attno_map, Oid to_rowtype, bool *found_whole_row) { map_variable_attnos_context context; context.target_varno = target_varno; context.sublevels_up = sublevels_up; context.attno_map = attno_map; context.to_rowtype = to_rowtype; context.found_whole_row = found_whole_row; *found_whole_row = false; /* * Must be prepared to start with a Query or a bare expression tree; if * it's a Query, we don't want to increment sublevels_up. */ return query_or_expression_tree_mutator(node, map_variable_attnos_mutator, &context, 0); } /* * ReplaceVarsFromTargetList - replace Vars with items from a targetlist * * Vars matching target_varno and sublevels_up are replaced by the * entry with matching resno from targetlist, if there is one. * * If there is no matching resno for such a Var, the action depends on the * nomatch_option: * REPLACEVARS_REPORT_ERROR: throw an error * REPLACEVARS_CHANGE_VARNO: change Var's varno to nomatch_varno * REPLACEVARS_SUBSTITUTE_NULL: replace Var with a NULL Const of same type * * The caller must also provide target_rte, the RTE describing the target * relation. This is needed to handle whole-row Vars referencing the target. * We expand such Vars into RowExpr constructs. * * In addition, for INSERT/UPDATE/DELETE/MERGE queries, the caller must * provide result_relation, the index of the result relation in the rewritten * query. This is needed to handle OLD/NEW RETURNING list Vars referencing * target_varno. When such Vars are expanded, their varreturningtype is * copied onto any replacement Vars referencing result_relation. In addition, * if the replacement expression from the targetlist is not simply a Var * referencing result_relation, it is wrapped in a ReturningExpr node (causing * the executor to return NULL if the OLD/NEW row doesn't exist). * * Note that ReplaceVarFromTargetList always generates the replacement * expression with varlevelsup = 0. The caller is responsible for adjusting * the varlevelsup if needed. This simplifies the caller's life if it wants to * cache the replacement expressions. * * outer_hasSubLinks works the same as for replace_rte_variables(). */ typedef struct { RangeTblEntry *target_rte; List *targetlist; int result_relation; ReplaceVarsNoMatchOption nomatch_option; int nomatch_varno; } ReplaceVarsFromTargetList_context; static Node * ReplaceVarsFromTargetList_callback(Var *var, replace_rte_variables_context *context) { ReplaceVarsFromTargetList_context *rcon = (ReplaceVarsFromTargetList_context *) context->callback_arg; Node *newnode; newnode = ReplaceVarFromTargetList(var, rcon->target_rte, rcon->targetlist, rcon->result_relation, rcon->nomatch_option, rcon->nomatch_varno); /* Must adjust varlevelsup if replaced Var is within a subquery */ if (var->varlevelsup > 0) IncrementVarSublevelsUp(newnode, var->varlevelsup, 0); return newnode; } Node * ReplaceVarFromTargetList(Var *var, RangeTblEntry *target_rte, List *targetlist, int result_relation, ReplaceVarsNoMatchOption nomatch_option, int nomatch_varno) { TargetEntry *tle; if (var->varattno == InvalidAttrNumber) { /* Must expand whole-tuple reference into RowExpr */ RowExpr *rowexpr; List *colnames; List *fields; ListCell *lc; /* * If generating an expansion for a var of a named rowtype (ie, this * is a plain relation RTE), then we must include dummy items for * dropped columns. If the var is RECORD (ie, this is a JOIN), then * omit dropped columns. In the latter case, attach column names to * the RowExpr for use of the executor and ruleutils.c. * * In order to be able to cache the results, we always generate the * expansion with varlevelsup = 0. The caller is responsible for * adjusting it if needed. * * The varreturningtype is copied onto each individual field Var, so * that it is handled correctly when we recurse. */ expandRTE(target_rte, var->varno, 0 /* not varlevelsup */ , var->varreturningtype, var->location, (var->vartype != RECORDOID), &colnames, &fields); rowexpr = makeNode(RowExpr); /* the fields will be set below */ rowexpr->args = NIL; rowexpr->row_typeid = var->vartype; rowexpr->row_format = COERCE_IMPLICIT_CAST; rowexpr->colnames = (var->vartype == RECORDOID) ? colnames : NIL; rowexpr->location = var->location; /* Adjust the generated per-field Vars... */ foreach(lc, fields) { Node *field = lfirst(lc); if (field && IsA(field, Var)) field = ReplaceVarFromTargetList((Var *) field, target_rte, targetlist, result_relation, nomatch_option, nomatch_varno); rowexpr->args = lappend(rowexpr->args, field); } /* Wrap it in a ReturningExpr, if needed, per comments above */ if (var->varreturningtype != VAR_RETURNING_DEFAULT) { ReturningExpr *rexpr = makeNode(ReturningExpr); rexpr->retlevelsup = 0; rexpr->retold = (var->varreturningtype == VAR_RETURNING_OLD); rexpr->retexpr = (Expr *) rowexpr; return (Node *) rexpr; } return (Node *) rowexpr; } /* Normal case referencing one targetlist element */ tle = get_tle_by_resno(targetlist, var->varattno); if (tle == NULL || tle->resjunk) { /* Failed to find column in targetlist */ switch (nomatch_option) { case REPLACEVARS_REPORT_ERROR: /* fall through, throw error below */ break; case REPLACEVARS_CHANGE_VARNO: var = copyObject(var); var->varno = nomatch_varno; var->varlevelsup = 0; /* we leave the syntactic referent alone */ return (Node *) var; case REPLACEVARS_SUBSTITUTE_NULL: { /* * If Var is of domain type, we must add a CoerceToDomain * node, in case there is a NOT NULL domain constraint. */ int16 vartyplen; bool vartypbyval; get_typlenbyval(var->vartype, &vartyplen, &vartypbyval); return coerce_null_to_domain(var->vartype, var->vartypmod, var->varcollid, vartyplen, vartypbyval); } } elog(ERROR, "could not find replacement targetlist entry for attno %d", var->varattno); return NULL; /* keep compiler quiet */ } else { /* Make a copy of the tlist item to return */ Expr *newnode = copyObject(tle->expr); /* * Check to see if the tlist item contains a PARAM_MULTIEXPR Param, * and throw error if so. This case could only happen when expanding * an ON UPDATE rule's NEW variable and the referenced tlist item in * the original UPDATE command is part of a multiple assignment. There * seems no practical way to handle such cases without multiple * evaluation of the multiple assignment's sub-select, which would * create semantic oddities that users of rules would probably prefer * not to cope with. So treat it as an unimplemented feature. */ if (contains_multiexpr_param((Node *) newnode, NULL)) ereport(ERROR, (errcode(ERRCODE_FEATURE_NOT_SUPPORTED), errmsg("NEW variables in ON UPDATE rules cannot reference columns that are part of a multiple assignment in the subject UPDATE command"))); /* Handle any OLD/NEW RETURNING list Vars */ if (var->varreturningtype != VAR_RETURNING_DEFAULT) { /* * Copy varreturningtype onto any Vars in the tlist item that * refer to result_relation (which had better be non-zero). */ if (result_relation == 0) elog(ERROR, "variable returning old/new found outside RETURNING list"); SetVarReturningType((Node *) newnode, result_relation, 0, var->varreturningtype); /* Wrap it in a ReturningExpr, if needed, per comments above */ if (!IsA(newnode, Var) || ((Var *) newnode)->varno != result_relation || ((Var *) newnode)->varlevelsup != 0) { ReturningExpr *rexpr = makeNode(ReturningExpr); rexpr->retlevelsup = 0; rexpr->retold = (var->varreturningtype == VAR_RETURNING_OLD); rexpr->retexpr = newnode; newnode = (Expr *) rexpr; } } return (Node *) newnode; } } Node * ReplaceVarsFromTargetList(Node *node, int target_varno, int sublevels_up, RangeTblEntry *target_rte, List *targetlist, int result_relation, ReplaceVarsNoMatchOption nomatch_option, int nomatch_varno, bool *outer_hasSubLinks) { ReplaceVarsFromTargetList_context context; context.target_rte = target_rte; context.targetlist = targetlist; context.result_relation = result_relation; context.nomatch_option = nomatch_option; context.nomatch_varno = nomatch_varno; return replace_rte_variables(node, target_varno, sublevels_up, ReplaceVarsFromTargetList_callback, &context, outer_hasSubLinks); }