/*------------------------------------------------------------------------- * * setrefs.c * Post-processing of a completed plan tree: fix references to subplan * vars, and compute regproc values for operators * * Portions Copyright (c) 1996-2001, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * $Header: /cvsroot/pgsql/src/backend/optimizer/plan/setrefs.c,v 1.71 2001/03/22 03:59:37 momjian Exp $ * *------------------------------------------------------------------------- */ #include #include "postgres.h" #include "nodes/makefuncs.h" #include "nodes/nodeFuncs.h" #include "optimizer/clauses.h" #include "optimizer/planmain.h" #include "optimizer/tlist.h" typedef struct { List *outer_tlist; List *inner_tlist; Index acceptable_rel; } join_references_context; typedef struct { Index subvarno; List *subplanTargetList; } replace_vars_with_subplan_refs_context; static void fix_expr_references(Plan *plan, Node *node); static void set_join_references(Join *join); static void set_uppernode_references(Plan *plan, Index subvarno); static Node *join_references_mutator(Node *node, join_references_context *context); static Node *replace_vars_with_subplan_refs(Node *node, Index subvarno, List *subplanTargetList); static Node *replace_vars_with_subplan_refs_mutator(Node *node, replace_vars_with_subplan_refs_context *context); static bool fix_opids_walker(Node *node, void *context); /***************************************************************************** * * SUBPLAN REFERENCES * *****************************************************************************/ /* * set_plan_references * This is the final processing pass of the planner/optimizer. The plan * tree is complete; we just have to adjust some representational details * for the convenience of the executor. We update Vars in upper plan nodes * to refer to the outputs of their subplans, and we compute regproc OIDs * for operators (ie, we look up the function that implements each op). * We must also build lists of all the subplan nodes present in each * plan node's expression trees. * * set_plan_references recursively traverses the whole plan tree. * * Returns nothing of interest, but modifies internal fields of nodes. */ void set_plan_references(Plan *plan) { List *pl; if (plan == NULL) return; /* * We must rebuild the plan's list of subplan nodes, since we are * copying/mutating its expression trees. */ plan->subPlan = NIL; /* * Plan-type-specific fixes */ switch (nodeTag(plan)) { case T_SeqScan: fix_expr_references(plan, (Node *) plan->targetlist); fix_expr_references(plan, (Node *) plan->qual); break; case T_IndexScan: fix_expr_references(plan, (Node *) plan->targetlist); fix_expr_references(plan, (Node *) plan->qual); fix_expr_references(plan, (Node *) ((IndexScan *) plan)->indxqual); fix_expr_references(plan, (Node *) ((IndexScan *) plan)->indxqualorig); break; case T_TidScan: fix_expr_references(plan, (Node *) plan->targetlist); fix_expr_references(plan, (Node *) plan->qual); break; case T_SubqueryScan: /* * We do not do set_uppernode_references() here, because a * SubqueryScan will always have been created with correct * references to its subplan's outputs to begin with. */ fix_expr_references(plan, (Node *) plan->targetlist); fix_expr_references(plan, (Node *) plan->qual); /* Recurse into subplan too */ set_plan_references(((SubqueryScan *) plan)->subplan); break; case T_NestLoop: set_join_references((Join *) plan); fix_expr_references(plan, (Node *) plan->targetlist); fix_expr_references(plan, (Node *) plan->qual); fix_expr_references(plan, (Node *) ((Join *) plan)->joinqual); break; case T_MergeJoin: set_join_references((Join *) plan); fix_expr_references(plan, (Node *) plan->targetlist); fix_expr_references(plan, (Node *) plan->qual); fix_expr_references(plan, (Node *) ((Join *) plan)->joinqual); fix_expr_references(plan, (Node *) ((MergeJoin *) plan)->mergeclauses); break; case T_HashJoin: set_join_references((Join *) plan); fix_expr_references(plan, (Node *) plan->targetlist); fix_expr_references(plan, (Node *) plan->qual); fix_expr_references(plan, (Node *) ((Join *) plan)->joinqual); fix_expr_references(plan, (Node *) ((HashJoin *) plan)->hashclauses); break; case T_Material: case T_Sort: case T_Unique: case T_SetOp: case T_Limit: case T_Hash: /* * These plan types don't actually bother to evaluate their * targetlists or quals (because they just return their * unmodified input tuples). The optimizer is lazy about * creating really valid targetlists for them. Best to just * leave the targetlist alone. In particular, we do not want * to pull a subplan list for them, since we will likely end * up with duplicate list entries for subplans that also * appear in lower levels of the plan tree! */ break; case T_Agg: case T_Group: set_uppernode_references(plan, (Index) 0); fix_expr_references(plan, (Node *) plan->targetlist); fix_expr_references(plan, (Node *) plan->qual); break; case T_Result: /* * Result may or may not have a subplan; no need to fix up * subplan references if it hasn't got one... * * XXX why does Result use a different subvarno from Agg/Group? */ if (plan->lefttree != NULL) set_uppernode_references(plan, (Index) OUTER); fix_expr_references(plan, (Node *) plan->targetlist); fix_expr_references(plan, (Node *) plan->qual); fix_expr_references(plan, ((Result *) plan)->resconstantqual); break; case T_Append: /* * Append, like Sort et al, doesn't actually evaluate its * targetlist or quals, and we haven't bothered to give it its * own tlist copy. So, don't fix targetlist/qual. But do * recurse into subplans. */ foreach(pl, ((Append *) plan)->appendplans) set_plan_references((Plan *) lfirst(pl)); break; default: elog(ERROR, "set_plan_references: unknown plan type %d", nodeTag(plan)); break; } /* * Now recurse into subplans, if any * * NOTE: it is essential that we recurse into subplans AFTER we set * subplan references in this plan's tlist and quals. If we did the * reference-adjustments bottom-up, then we would fail to match this * plan's var nodes against the already-modified nodes of the * subplans. */ set_plan_references(plan->lefttree); set_plan_references(plan->righttree); foreach(pl, plan->initPlan) { SubPlan *sp = (SubPlan *) lfirst(pl); Assert(IsA(sp, SubPlan)); set_plan_references(sp->plan); } foreach(pl, plan->subPlan) { SubPlan *sp = (SubPlan *) lfirst(pl); Assert(IsA(sp, SubPlan)); set_plan_references(sp->plan); } } /* * fix_expr_references * Do final cleanup on expressions (targetlists or quals). * * This consists of looking up operator opcode info for Oper nodes * and adding subplans to the Plan node's list of contained subplans. */ static void fix_expr_references(Plan *plan, Node *node) { fix_opids(node); plan->subPlan = nconc(plan->subPlan, pull_subplans(node)); } /* * set_join_references * Modifies the target list of a join node to reference its subplans, * by setting the varnos to OUTER or INNER and setting attno values to the * result domain number of either the corresponding outer or inner join * tuple item. * * Note: this same transformation has already been applied to the quals * of the join by createplan.c. It's a little odd to do it here for the * targetlist and there for the quals, but it's easier that way. (Look * at switch_outer() and the handling of nestloop inner indexscans to * see why.) * * Because the quals are reference-adjusted sooner, we cannot do equal() * comparisons between qual and tlist var nodes during the time between * creation of a plan node by createplan.c and its fixing by this module. * Fortunately, there doesn't seem to be any need to do that. * * 'join' is a join plan node */ static void set_join_references(Join *join) { Plan *outer = join->plan.lefttree; Plan *inner = join->plan.righttree; List *outer_tlist = ((outer == NULL) ? NIL : outer->targetlist); List *inner_tlist = ((inner == NULL) ? NIL : inner->targetlist); join->plan.targetlist = join_references(join->plan.targetlist, outer_tlist, inner_tlist, (Index) 0); } /* * set_uppernode_references * Update the targetlist and quals of an upper-level plan node * to refer to the tuples returned by its lefttree subplan. * * This is used for single-input plan types like Agg, Group, Result. * * In most cases, we have to match up individual Vars in the tlist and * qual expressions with elements of the subplan's tlist (which was * generated by flatten_tlist() from these selfsame expressions, so it * should have all the required variables). There is an important exception, * however: a GROUP BY expression that is also an output expression will * have been pushed into the subplan tlist unflattened. We want to detect * this case and reference the subplan output directly. Therefore, check * for equality of the whole tlist expression to any subplan element before * we resort to picking the expression apart for individual Vars. */ static void set_uppernode_references(Plan *plan, Index subvarno) { Plan *subplan = plan->lefttree; List *subplanTargetList, *outputTargetList, *l; if (subplan != NULL) subplanTargetList = subplan->targetlist; else subplanTargetList = NIL; outputTargetList = NIL; foreach(l, plan->targetlist) { TargetEntry *tle = (TargetEntry *) lfirst(l); TargetEntry *subplantle; Node *newexpr; subplantle = tlistentry_member(tle->expr, subplanTargetList); if (subplantle) { /* Found a matching subplan output expression */ Resdom *resdom = subplantle->resdom; Var *newvar; newvar = makeVar(subvarno, resdom->resno, resdom->restype, resdom->restypmod, 0); /* If we're just copying a simple Var, copy up original info */ if (subplantle->expr && IsA(subplantle->expr, Var)) { Var *subvar = (Var *) subplantle->expr; newvar->varnoold = subvar->varnoold; newvar->varoattno = subvar->varoattno; } else { newvar->varnoold = 0; newvar->varoattno = 0; } newexpr = (Node *) newvar; } else { /* No matching expression, so replace individual Vars */ newexpr = replace_vars_with_subplan_refs(tle->expr, subvarno, subplanTargetList); } outputTargetList = lappend(outputTargetList, makeTargetEntry(tle->resdom, newexpr)); } plan->targetlist = outputTargetList; plan->qual = (List *) replace_vars_with_subplan_refs((Node *) plan->qual, subvarno, subplanTargetList); } /* * join_references * Creates a new set of targetlist entries or join qual clauses by * changing the varno/varattno values of variables in the clauses * to reference target list values from the outer and inner join * relation target lists. * * This is used in two different scenarios: a normal join clause, where * all the Vars in the clause *must* be replaced by OUTER or INNER references; * and an indexscan being used on the inner side of a nestloop join. * In the latter case we want to replace the outer-relation Vars by OUTER * references, but not touch the Vars of the inner relation. * * For a normal join, acceptable_rel should be zero so that any failure to * match a Var will be reported as an error. For the indexscan case, * pass inner_tlist = NIL and acceptable_rel = the ID of the inner relation. * * 'clauses' is the targetlist or list of join clauses * 'outer_tlist' is the target list of the outer join relation * 'inner_tlist' is the target list of the inner join relation, or NIL * 'acceptable_rel' is either zero or the rangetable index of a relation * whose Vars may appear in the clause without provoking an error. * * Returns the new expression tree. The original clause structure is * not modified. */ List * join_references(List *clauses, List *outer_tlist, List *inner_tlist, Index acceptable_rel) { join_references_context context; context.outer_tlist = outer_tlist; context.inner_tlist = inner_tlist; context.acceptable_rel = acceptable_rel; return (List *) join_references_mutator((Node *) clauses, &context); } static Node * join_references_mutator(Node *node, join_references_context *context) { if (node == NULL) return NULL; if (IsA(node, Var)) { Var *var = (Var *) node; Var *newvar = (Var *) copyObject(var); Resdom *resdom; resdom = tlist_member((Node *) var, context->outer_tlist); if (resdom) { newvar->varno = OUTER; newvar->varattno = resdom->resno; return (Node *) newvar; } resdom = tlist_member((Node *) var, context->inner_tlist); if (resdom) { newvar->varno = INNER; newvar->varattno = resdom->resno; return (Node *) newvar; } /* * Var not in either tlist --- either raise an error, or return * the Var unmodified. */ if (var->varno != context->acceptable_rel) elog(ERROR, "join_references: variable not in subplan target lists"); return (Node *) newvar; } return expression_tree_mutator(node, join_references_mutator, (void *) context); } /* * replace_vars_with_subplan_refs * This routine modifies an expression tree so that all Var nodes * reference target nodes of a subplan. It is used to fix up * target and qual expressions of non-join upper-level plan nodes. * * An error is raised if no matching var can be found in the subplan tlist * --- so this routine should only be applied to nodes whose subplans' * targetlists were generated via flatten_tlist() or some such method. * * 'node': the tree to be fixed (a targetlist or qual list) * 'subvarno': varno to be assigned to all Vars * 'subplanTargetList': target list for subplan * * The resulting tree is a copy of the original in which all Var nodes have * varno = subvarno, varattno = resno of corresponding subplan target. * The original tree is not modified. */ static Node * replace_vars_with_subplan_refs(Node *node, Index subvarno, List *subplanTargetList) { replace_vars_with_subplan_refs_context context; context.subvarno = subvarno; context.subplanTargetList = subplanTargetList; return replace_vars_with_subplan_refs_mutator(node, &context); } static Node * replace_vars_with_subplan_refs_mutator(Node *node, replace_vars_with_subplan_refs_context *context) { if (node == NULL) return NULL; if (IsA(node, Var)) { Var *var = (Var *) node; Var *newvar = (Var *) copyObject(var); Resdom *resdom; resdom = tlist_member((Node *) var, context->subplanTargetList); if (!resdom) elog(ERROR, "replace_vars_with_subplan_refs: variable not in subplan target list"); newvar->varno = context->subvarno; newvar->varattno = resdom->resno; return (Node *) newvar; } return expression_tree_mutator(node, replace_vars_with_subplan_refs_mutator, (void *) context); } /***************************************************************************** * OPERATOR REGPROC LOOKUP *****************************************************************************/ /* * fix_opids * Calculate opid field from opno for each Oper node in given tree. * The given tree can be anything expression_tree_walker handles. * * The argument is modified in-place. (This is OK since we'd want the * same change for any node, even if it gets visited more than once due to * shared structure.) */ void fix_opids(Node *node) { /* This tree walk requires no special setup, so away we go... */ fix_opids_walker(node, NULL); } static bool fix_opids_walker(Node *node, void *context) { if (node == NULL) return false; if (is_opclause(node)) replace_opid((Oper *) ((Expr *) node)->oper); return expression_tree_walker(node, fix_opids_walker, context); }