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setrefs.c
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1/*-------------------------------------------------------------------------
2 *
3 * setrefs.c
4 * Post-processing of a completed plan tree: fix references to subplan
5 * vars, compute regproc values for operators, etc
6 *
7 * Portions Copyright (c) 1996-2026, PostgreSQL Global Development Group
8 * Portions Copyright (c) 1994, Regents of the University of California
9 *
10 *
11 * IDENTIFICATION
12 * src/backend/optimizer/plan/setrefs.c
13 *
14 *-------------------------------------------------------------------------
15 */
16#include "postgres.h"
17
18#include "access/transam.h"
19#include "catalog/pg_type.h"
20#include "nodes/makefuncs.h"
21#include "nodes/nodeFuncs.h"
22#include "optimizer/optimizer.h"
23#include "optimizer/pathnode.h"
24#include "optimizer/planmain.h"
25#include "optimizer/planner.h"
26#include "optimizer/subselect.h"
27#include "optimizer/tlist.h"
28#include "parser/parse_relation.h"
29#include "rewrite/rewriteManip.h"
30#include "tcop/utility.h"
31#include "utils/syscache.h"
32
33
34typedef enum
35{
36 NRM_EQUAL, /* expect exact match of nullingrels */
37 NRM_SUBSET, /* actual Var may have a subset of input */
38 NRM_SUPERSET, /* actual Var may have a superset of input */
39} NullingRelsMatch;
40
41typedef struct
42{
43 int varno; /* RT index of Var */
44 AttrNumber varattno; /* attr number of Var */
45 AttrNumber resno; /* TLE position of Var */
46 Bitmapset *varnullingrels; /* Var's varnullingrels */
47} tlist_vinfo;
48
49typedef struct
50{
51 List *tlist; /* underlying target list */
52 int num_vars; /* number of plain Var tlist entries */
53 bool has_ph_vars; /* are there PlaceHolderVar entries? */
54 bool has_non_vars; /* are there other entries? */
55 tlist_vinfo vars[FLEXIBLE_ARRAY_MEMBER]; /* has num_vars entries */
56} indexed_tlist;
57
58typedef struct
59{
60 PlannerInfo *root;
61 int rtoffset;
62 double num_exec;
63} fix_scan_expr_context;
64
75
85
92
93/* Context info for flatten_rtes_walker() */
99
100/*
101 * Selecting the best alternative in an AlternativeSubPlan expression requires
102 * estimating how many times that expression will be evaluated. For an
103 * expression in a plan node's targetlist, the plan's estimated number of
104 * output rows is clearly what to use, but for an expression in a qual it's
105 * far less clear. Since AlternativeSubPlans aren't heavily used, we don't
106 * want to expend a lot of cycles making such estimates. What we use is twice
107 * the number of output rows. That's not entirely unfounded: we know that
108 * clause_selectivity() would fall back to a default selectivity estimate
109 * of 0.5 for any SubPlan, so if the qual containing the SubPlan is the last
110 * to be applied (which it likely would be, thanks to order_qual_clauses()),
111 * this matches what we could have estimated in a far more laborious fashion.
112 * Obviously there are many other scenarios, but it's probably not worth the
113 * trouble to try to improve on this estimate, especially not when we don't
114 * have a better estimate for the selectivity of the SubPlan qual itself.
115 */
116#define NUM_EXEC_TLIST(parentplan) ((parentplan)->plan_rows)
117#define NUM_EXEC_QUAL(parentplan) ((parentplan)->plan_rows * 2.0)
118
119/*
120 * Check if a Const node is a regclass value. We accept plain OID too,
121 * since a regclass Const will get folded to that type if it's an argument
122 * to oideq or similar operators. (This might result in some extraneous
123 * values in a plan's list of relation dependencies, but the worst result
124 * would be occasional useless replans.)
125 */
126#define ISREGCLASSCONST(con) \
127 (((con)->consttype == REGCLASSOID || (con)->consttype == OIDOID) && \
128 !(con)->constisnull)
129
130#define fix_scan_list(root, lst, rtoffset, num_exec) \
131 ((List *) fix_scan_expr(root, (Node *) (lst), rtoffset, num_exec))
132
133static void add_rtes_to_flat_rtable(PlannerInfo *root, bool recursing);
134static void flatten_unplanned_rtes(PlannerGlobal *glob, RangeTblEntry *rte);
135static bool flatten_rtes_walker(Node *node, flatten_rtes_walker_context *cxt);
136static void add_rte_to_flat_rtable(PlannerGlobal *glob, List *rteperminfos,
137 RangeTblEntry *rte);
138static Plan *set_plan_refs(PlannerInfo *root, Plan *plan, int rtoffset);
139static Plan *set_indexonlyscan_references(PlannerInfo *root,
140 IndexOnlyScan *plan,
141 int rtoffset);
142static Plan *set_subqueryscan_references(PlannerInfo *root,
143 SubqueryScan *plan,
144 int rtoffset);
145static Plan *clean_up_removed_plan_level(Plan *parent, Plan *child);
146static void set_foreignscan_references(PlannerInfo *root,
147 ForeignScan *fscan,
148 int rtoffset);
149static void set_customscan_references(PlannerInfo *root,
150 CustomScan *cscan,
151 int rtoffset);
152static Plan *set_append_references(PlannerInfo *root,
153 Append *aplan,
154 int rtoffset);
155static Plan *set_mergeappend_references(PlannerInfo *root,
156 MergeAppend *mplan,
157 int rtoffset);
158static void set_hash_references(PlannerInfo *root, Plan *plan, int rtoffset);
159static Relids offset_relid_set(Relids relids, int rtoffset);
160static Node *fix_scan_expr(PlannerInfo *root, Node *node,
161 int rtoffset, double num_exec);
162static Node *fix_scan_expr_mutator(Node *node, fix_scan_expr_context *context);
163static bool fix_scan_expr_walker(Node *node, fix_scan_expr_context *context);
164static void set_join_references(PlannerInfo *root, Join *join, int rtoffset);
165static void set_upper_references(PlannerInfo *root, Plan *plan, int rtoffset);
166static void set_param_references(PlannerInfo *root, Plan *plan);
167static Node *convert_combining_aggrefs(Node *node, void *context);
168static void set_dummy_tlist_references(Plan *plan, int rtoffset);
169static indexed_tlist *build_tlist_index(List *tlist);
170static Var *search_indexed_tlist_for_var(Var *var,
171 indexed_tlist *itlist,
172 int newvarno,
173 int rtoffset,
174 NullingRelsMatch nrm_match);
175static Var *search_indexed_tlist_for_phv(PlaceHolderVar *phv,
176 indexed_tlist *itlist,
177 int newvarno,
178 NullingRelsMatch nrm_match);
179static Var *search_indexed_tlist_for_non_var(Expr *node,
180 indexed_tlist *itlist,
181 int newvarno);
182static Var *search_indexed_tlist_for_sortgroupref(Expr *node,
183 Index sortgroupref,
184 indexed_tlist *itlist,
185 int newvarno);
186static List *fix_join_expr(PlannerInfo *root,
187 List *clauses,
188 indexed_tlist *outer_itlist,
189 indexed_tlist *inner_itlist,
190 Index acceptable_rel,
191 int rtoffset,
192 NullingRelsMatch nrm_match,
193 double num_exec);
194static Node *fix_join_expr_mutator(Node *node,
195 fix_join_expr_context *context);
196static Node *fix_upper_expr(PlannerInfo *root,
197 Node *node,
198 indexed_tlist *subplan_itlist,
199 int newvarno,
200 int rtoffset,
201 NullingRelsMatch nrm_match,
202 double num_exec);
203static Node *fix_upper_expr_mutator(Node *node,
204 fix_upper_expr_context *context);
205static List *set_returning_clause_references(PlannerInfo *root,
206 List *rlist,
207 Plan *topplan,
208 Index resultRelation,
209 int rtoffset);
210static List *set_windowagg_runcondition_references(PlannerInfo *root,
211 List *runcondition,
212 Plan *plan);
213
214static void record_elided_node(PlannerGlobal *glob, int plan_node_id,
215 NodeTag elided_type, Bitmapset *relids);
216
217
218/*****************************************************************************
219 *
220 * SUBPLAN REFERENCES
221 *
222 *****************************************************************************/
223
224/*
225 * set_plan_references
226 *
227 * This is the final processing pass of the planner/optimizer. The plan
228 * tree is complete; we just have to adjust some representational details
229 * for the convenience of the executor:
230 *
231 * 1. We flatten the various subquery rangetables into a single list, and
232 * zero out RangeTblEntry fields that are not useful to the executor.
233 *
234 * 2. We adjust Vars in scan nodes to be consistent with the flat rangetable.
235 *
236 * 3. We adjust Vars in upper plan nodes to refer to the outputs of their
237 * subplans.
238 *
239 * 4. Aggrefs in Agg plan nodes need to be adjusted in some cases involving
240 * partial aggregation or minmax aggregate optimization.
241 *
242 * 5. PARAM_MULTIEXPR Params are replaced by regular PARAM_EXEC Params,
243 * now that we have finished planning all MULTIEXPR subplans.
244 *
245 * 6. AlternativeSubPlan expressions are replaced by just one of their
246 * alternatives, using an estimate of how many times they'll be executed.
247 *
248 * 7. We compute regproc OIDs for operators (ie, we look up the function
249 * that implements each op).
250 *
251 * 8. We create lists of specific objects that the plan depends on.
252 * This will be used by plancache.c to drive invalidation of cached plans.
253 * Relation dependencies are represented by OIDs, and everything else by
254 * PlanInvalItems (this distinction is motivated by the shared-inval APIs).
255 * Currently, relations, user-defined functions, and domains are the only
256 * types of objects that are explicitly tracked this way.
257 *
258 * 9. We assign every plan node in the tree a unique ID.
259 *
260 * We also perform one final optimization step, which is to delete
261 * SubqueryScan, Append, and MergeAppend plan nodes that aren't doing
262 * anything useful. The reason for doing this last is that
263 * it can't readily be done before set_plan_references, because it would
264 * break set_upper_references: the Vars in the child plan's top tlist
265 * wouldn't match up with the Vars in the outer plan tree. A SubqueryScan
266 * serves a necessary function as a buffer between outer query and subquery
267 * variable numbering ... but after we've flattened the rangetable this is
268 * no longer a problem, since then there's only one rtindex namespace.
269 * Likewise, Append and MergeAppend buffer between the parent and child vars
270 * of an appendrel, but we don't need to worry about that once we've done
271 * set_plan_references.
272 *
273 * set_plan_references recursively traverses the whole plan tree.
274 *
275 * The return value is normally the same Plan node passed in, but can be
276 * different when the passed-in Plan is a node we decide isn't needed.
277 *
278 * The flattened rangetable entries are appended to root->glob->finalrtable.
279 * Also, rowmarks entries are appended to root->glob->finalrowmarks, and the
280 * RT indexes of ModifyTable result relations to root->glob->resultRelations,
281 * and flattened AppendRelInfos are appended to root->glob->appendRelations.
282 * Plan dependencies are appended to root->glob->relationOids (for relations)
283 * and root->glob->invalItems (for everything else).
284 *
285 * Notice that we modify Plan nodes in-place, but use expression_tree_mutator
286 * to process targetlist and qual expressions. We can assume that the Plan
287 * nodes were just built by the planner and are not multiply referenced, but
288 * it's not so safe to assume that for expression tree nodes.
289 */
290Plan *
291set_plan_references(PlannerInfo *root, Plan *plan)
292{
293 Plan *result;
294 PlannerGlobal *glob = root->glob;
295 int rtoffset = list_length(glob->finalrtable);
296 ListCell *lc;
297
298 /*
299 * Add all the query's RTEs to the flattened rangetable. The live ones
300 * will have their rangetable indexes increased by rtoffset. (Additional
301 * RTEs, not referenced by the Plan tree, might get added after those.)
302 */
303 add_rtes_to_flat_rtable(root, false);
304
305 /*
306 * Adjust RT indexes of PlanRowMarks and add to final rowmarks list
307 */
308 foreach(lc, root->rowMarks)
309 {
310 PlanRowMark *rc = lfirst_node(PlanRowMark, lc);
311 PlanRowMark *newrc;
312
313 /* sanity check on existing row marks */
314 Assert(root->simple_rel_array[rc->rti] != NULL &&
315 root->simple_rte_array[rc->rti] != NULL);
316
317 /* flat copy is enough since all fields are scalars */
318 newrc = palloc_object(PlanRowMark);
319 memcpy(newrc, rc, sizeof(PlanRowMark));
320
321 /* adjust indexes ... but *not* the rowmarkId */
322 newrc->rti += rtoffset;
323 newrc->prti += rtoffset;
324
325 glob->finalrowmarks = lappend(glob->finalrowmarks, newrc);
326 }
327
328 /*
329 * Adjust RT indexes of AppendRelInfos and add to final appendrels list.
330 * We assume the AppendRelInfos were built during planning and don't need
331 * to be copied.
332 */
333 foreach(lc, root->append_rel_list)
334 {
335 AppendRelInfo *appinfo = lfirst_node(AppendRelInfo, lc);
336
337 /* adjust RT indexes */
338 appinfo->parent_relid += rtoffset;
339 appinfo->child_relid += rtoffset;
340
341 /*
342 * Rather than adjust the translated_vars entries, just drop 'em.
343 * Neither the executor nor EXPLAIN currently need that data.
344 */
345 appinfo->translated_vars = NIL;
346
347 glob->appendRelations = lappend(glob->appendRelations, appinfo);
348 }
349
350 /* If needed, create workspace for processing AlternativeSubPlans */
351 if (root->hasAlternativeSubPlans)
352 {
353 root->isAltSubplan = (bool *)
354 palloc0(list_length(glob->subplans) * sizeof(bool));
355 root->isUsedSubplan = (bool *)
356 palloc0(list_length(glob->subplans) * sizeof(bool));
357 }
358
359 /* Now fix the Plan tree */
360 result = set_plan_refs(root, plan, rtoffset);
361
362 /*
363 * If we have AlternativeSubPlans, it is likely that we now have some
364 * unreferenced subplans in glob->subplans. To avoid expending cycles on
365 * those subplans later, get rid of them by setting those list entries to
366 * NULL. (Note: we can't do this immediately upon processing an
367 * AlternativeSubPlan, because there may be multiple copies of the
368 * AlternativeSubPlan, and they can get resolved differently.)
369 */
370 if (root->hasAlternativeSubPlans)
371 {
372 foreach(lc, glob->subplans)
373 {
374 int ndx = foreach_current_index(lc);
375
376 /*
377 * If it was used by some AlternativeSubPlan in this query level,
378 * but wasn't selected as best by any AlternativeSubPlan, then we
379 * don't need it. Do not touch subplans that aren't parts of
380 * AlternativeSubPlans.
381 */
382 if (root->isAltSubplan[ndx] && !root->isUsedSubplan[ndx])
383 lfirst(lc) = NULL;
384 }
385 }
386
387 return result;
388}
389
390/*
391 * Extract RangeTblEntries from the plan's rangetable, and add to flat rtable
392 *
393 * This can recurse into subquery plans; "recursing" is true if so.
394 *
395 * This also seems like a good place to add the query's RTEPermissionInfos to
396 * the flat rteperminfos.
397 */
398static void
399add_rtes_to_flat_rtable(PlannerInfo *root, bool recursing)
400{
401 PlannerGlobal *glob = root->glob;
402 Index rti;
403 ListCell *lc;
404
405 /*
406 * Record enough information to make it possible for code that looks at
407 * the final range table to understand how it was constructed. (If
408 * finalrtable is still NIL, then this is the very topmost PlannerInfo,
409 * which will always have plan_name == NULL and rtoffset == 0; we omit the
410 * degenerate list entry.)
411 */
412 if (root->glob->finalrtable != NIL)
413 {
414 SubPlanRTInfo *rtinfo = makeNode(SubPlanRTInfo);
415
416 rtinfo->plan_name = root->plan_name;
417 rtinfo->rtoffset = list_length(root->glob->finalrtable);
418
419 /* When recursing = true, it's an unplanned or dummy subquery. */
420 rtinfo->dummy = recursing;
421
422 root->glob->subrtinfos = lappend(root->glob->subrtinfos, rtinfo);
423 }
424
425 /*
426 * Add the query's own RTEs to the flattened rangetable.
427 *
428 * At top level, we must add all RTEs so that their indexes in the
429 * flattened rangetable match up with their original indexes. When
430 * recursing, we only care about extracting relation RTEs (and subquery
431 * RTEs that were once relation RTEs).
432 */
433 foreach(lc, root->parse->rtable)
434 {
435 RangeTblEntry *rte = (RangeTblEntry *) lfirst(lc);
436
437 if (!recursing || rte->rtekind == RTE_RELATION ||
438 (rte->rtekind == RTE_SUBQUERY && OidIsValid(rte->relid)))
439 add_rte_to_flat_rtable(glob, root->parse->rteperminfos, rte);
440 }
441
442 /*
443 * If there are any dead subqueries, they are not referenced in the Plan
444 * tree, so we must add RTEs contained in them to the flattened rtable
445 * separately. (If we failed to do this, the executor would not perform
446 * expected permission checks for tables mentioned in such subqueries.)
447 *
448 * Note: this pass over the rangetable can't be combined with the previous
449 * one, because that would mess up the numbering of the live RTEs in the
450 * flattened rangetable.
451 */
452 rti = 1;
453 foreach(lc, root->parse->rtable)
454 {
455 RangeTblEntry *rte = (RangeTblEntry *) lfirst(lc);
456
457 /*
458 * We should ignore inheritance-parent RTEs: their contents have been
459 * pulled up into our rangetable already. Also ignore any subquery
460 * RTEs without matching RelOptInfos, as they likewise have been
461 * pulled up.
462 */
463 if (rte->rtekind == RTE_SUBQUERY && !rte->inh &&
464 rti < root->simple_rel_array_size)
465 {
466 RelOptInfo *rel = root->simple_rel_array[rti];
467
468 if (rel != NULL)
469 {
470 Assert(rel->relid == rti); /* sanity check on array */
471
472 /*
473 * The subquery might never have been planned at all, if it
474 * was excluded on the basis of self-contradictory constraints
475 * in our query level. In this case apply
476 * flatten_unplanned_rtes.
477 *
478 * If it was planned but the result rel is dummy, we assume
479 * that it has been omitted from our plan tree (see
480 * set_subquery_pathlist), and recurse to pull up its RTEs.
481 *
482 * Otherwise, it should be represented by a SubqueryScan node
483 * somewhere in our plan tree, and we'll pull up its RTEs when
484 * we process that plan node.
485 *
486 * However, if we're recursing, then we should pull up RTEs
487 * whether the subquery is dummy or not, because we've found
488 * that some upper query level is treating this one as dummy,
489 * and so we won't scan this level's plan tree at all.
490 */
491 if (rel->subroot == NULL)
492 flatten_unplanned_rtes(glob, rte);
493 else if (recursing ||
494 IS_DUMMY_REL(fetch_upper_rel(rel->subroot,
495 UPPERREL_FINAL, NULL)))
496 add_rtes_to_flat_rtable(rel->subroot, true);
497 }
498 }
499 rti++;
500 }
501}
502
503/*
504 * Extract RangeTblEntries from a subquery that was never planned at all
505 */
506
507static void
508flatten_unplanned_rtes(PlannerGlobal *glob, RangeTblEntry *rte)
509{
510 flatten_rtes_walker_context cxt = {glob, rte->subquery};
511
512 /* Use query_tree_walker to find all RTEs in the parse tree */
513 (void) query_tree_walker(rte->subquery,
514 flatten_rtes_walker,
515 &cxt,
516 QTW_EXAMINE_RTES_BEFORE);
517}
518
519static bool
520flatten_rtes_walker(Node *node, flatten_rtes_walker_context *cxt)
521{
522 if (node == NULL)
523 return false;
524 if (IsA(node, RangeTblEntry))
525 {
526 RangeTblEntry *rte = (RangeTblEntry *) node;
527
528 /* As above, we need only save relation RTEs and former relations */
529 if (rte->rtekind == RTE_RELATION ||
530 (rte->rtekind == RTE_SUBQUERY && OidIsValid(rte->relid)))
531 add_rte_to_flat_rtable(cxt->glob, cxt->query->rteperminfos, rte);
532 return false;
533 }
534 if (IsA(node, Query))
535 {
536 /*
537 * Recurse into subselects. Must update cxt->query to this query so
538 * that the rtable and rteperminfos correspond with each other.
539 */
540 Query *save_query = cxt->query;
541 bool result;
542
543 cxt->query = (Query *) node;
544 result = query_tree_walker((Query *) node,
545 flatten_rtes_walker,
546 cxt,
547 QTW_EXAMINE_RTES_BEFORE);
548 cxt->query = save_query;
549 return result;
550 }
551 return expression_tree_walker(node, flatten_rtes_walker, cxt);
552}
553
554/*
555 * Add (a copy of) the given RTE to the final rangetable and also the
556 * corresponding RTEPermissionInfo, if any, to final rteperminfos.
557 *
558 * In the flat rangetable, we zero out substructure pointers that are not
559 * needed by the executor; this reduces the storage space and copying cost
560 * for cached plans. We keep only the ctename, alias, eref Alias fields,
561 * which are needed by EXPLAIN, and perminfoindex which is needed by the
562 * executor to fetch the RTE's RTEPermissionInfo.
563 */
564static void
565add_rte_to_flat_rtable(PlannerGlobal *glob, List *rteperminfos,
566 RangeTblEntry *rte)
567{
568 RangeTblEntry *newrte;
569
570 /* flat copy to duplicate all the scalar fields */
571 newrte = palloc_object(RangeTblEntry);
572 memcpy(newrte, rte, sizeof(RangeTblEntry));
573
574 /* zap unneeded sub-structure */
575 newrte->tablesample = NULL;
576 newrte->subquery = NULL;
577 newrte->joinaliasvars = NIL;
578 newrte->joinleftcols = NIL;
579 newrte->joinrightcols = NIL;
580 newrte->join_using_alias = NULL;
581 newrte->functions = NIL;
582 newrte->tablefunc = NULL;
583 newrte->values_lists = NIL;
584 newrte->coltypes = NIL;
585 newrte->coltypmods = NIL;
586 newrte->colcollations = NIL;
587 newrte->groupexprs = NIL;
588 newrte->securityQuals = NIL;
589
590 glob->finalrtable = lappend(glob->finalrtable, newrte);
591
592 /*
593 * If it's a plain relation RTE (or a subquery that was once a view
594 * reference), add the relation OID to relationOids. Also add its new RT
595 * index to the set of relations to be potentially accessed during
596 * execution.
597 *
598 * We do this even though the RTE might be unreferenced in the plan tree;
599 * this would correspond to cases such as views that were expanded, child
600 * tables that were eliminated by constraint exclusion, etc. Schema
601 * invalidation on such a rel must still force rebuilding of the plan.
602 *
603 * Note we don't bother to avoid making duplicate list entries. We could,
604 * but it would probably cost more cycles than it would save.
605 */
606 if (newrte->rtekind == RTE_RELATION ||
607 (newrte->rtekind == RTE_SUBQUERY && OidIsValid(newrte->relid)))
608 {
609 glob->relationOids = lappend_oid(glob->relationOids, newrte->relid);
610 glob->allRelids = bms_add_member(glob->allRelids,
611 list_length(glob->finalrtable));
612 }
613
614 /*
615 * Add a copy of the RTEPermissionInfo, if any, corresponding to this RTE
616 * to the flattened global list.
617 */
618 if (rte->perminfoindex > 0)
619 {
620 RTEPermissionInfo *perminfo;
621 RTEPermissionInfo *newperminfo;
622
623 /* Get the existing one from this query's rteperminfos. */
624 perminfo = getRTEPermissionInfo(rteperminfos, newrte);
625
626 /*
627 * Add a new one to finalrteperminfos and copy the contents of the
628 * existing one into it. Note that addRTEPermissionInfo() also
629 * updates newrte->perminfoindex to point to newperminfo in
630 * finalrteperminfos.
631 */
632 newrte->perminfoindex = 0; /* expected by addRTEPermissionInfo() */
633 newperminfo = addRTEPermissionInfo(&glob->finalrteperminfos, newrte);
634 memcpy(newperminfo, perminfo, sizeof(RTEPermissionInfo));
635 }
636}
637
638/*
639 * set_plan_refs: recurse through the Plan nodes of a single subquery level
640 */
641static Plan *
642set_plan_refs(PlannerInfo *root, Plan *plan, int rtoffset)
643{
644 ListCell *l;
645
646 if (plan == NULL)
647 return NULL;
648
649 /* Assign this node a unique ID. */
650 plan->plan_node_id = root->glob->lastPlanNodeId++;
651
652 /*
653 * Plan-type-specific fixes
654 */
655 switch (nodeTag(plan))
656 {
657 case T_SeqScan:
658 {
659 SeqScan *splan = (SeqScan *) plan;
660
661 splan->scan.scanrelid += rtoffset;
662 splan->scan.plan.targetlist =
663 fix_scan_list(root, splan->scan.plan.targetlist,
664 rtoffset, NUM_EXEC_TLIST(plan));
665 splan->scan.plan.qual =
666 fix_scan_list(root, splan->scan.plan.qual,
667 rtoffset, NUM_EXEC_QUAL(plan));
668 }
669 break;
670 case T_SampleScan:
671 {
672 SampleScan *splan = (SampleScan *) plan;
673
674 splan->scan.scanrelid += rtoffset;
675 splan->scan.plan.targetlist =
676 fix_scan_list(root, splan->scan.plan.targetlist,
677 rtoffset, NUM_EXEC_TLIST(plan));
678 splan->scan.plan.qual =
679 fix_scan_list(root, splan->scan.plan.qual,
680 rtoffset, NUM_EXEC_QUAL(plan));
681 splan->tablesample = (TableSampleClause *)
682 fix_scan_expr(root, (Node *) splan->tablesample,
683 rtoffset, 1);
684 }
685 break;
686 case T_IndexScan:
687 {
688 IndexScan *splan = (IndexScan *) plan;
689
690 splan->scan.scanrelid += rtoffset;
691 splan->scan.plan.targetlist =
692 fix_scan_list(root, splan->scan.plan.targetlist,
693 rtoffset, NUM_EXEC_TLIST(plan));
694 splan->scan.plan.qual =
695 fix_scan_list(root, splan->scan.plan.qual,
696 rtoffset, NUM_EXEC_QUAL(plan));
697 splan->indexqual =
698 fix_scan_list(root, splan->indexqual,
699 rtoffset, 1);
700 splan->indexqualorig =
701 fix_scan_list(root, splan->indexqualorig,
702 rtoffset, NUM_EXEC_QUAL(plan));
703 splan->indexorderby =
704 fix_scan_list(root, splan->indexorderby,
705 rtoffset, 1);
706 splan->indexorderbyorig =
707 fix_scan_list(root, splan->indexorderbyorig,
708 rtoffset, NUM_EXEC_QUAL(plan));
709 }
710 break;
711 case T_IndexOnlyScan:
712 {
713 IndexOnlyScan *splan = (IndexOnlyScan *) plan;
714
715 return set_indexonlyscan_references(root, splan, rtoffset);
716 }
717 break;
718 case T_BitmapIndexScan:
719 {
720 BitmapIndexScan *splan = (BitmapIndexScan *) plan;
721
722 splan->scan.scanrelid += rtoffset;
723 /* no need to fix targetlist and qual */
724 Assert(splan->scan.plan.targetlist == NIL);
725 Assert(splan->scan.plan.qual == NIL);
726 splan->indexqual =
727 fix_scan_list(root, splan->indexqual, rtoffset, 1);
728 splan->indexqualorig =
729 fix_scan_list(root, splan->indexqualorig,
730 rtoffset, NUM_EXEC_QUAL(plan));
731 }
732 break;
733 case T_BitmapHeapScan:
734 {
735 BitmapHeapScan *splan = (BitmapHeapScan *) plan;
736
737 splan->scan.scanrelid += rtoffset;
738 splan->scan.plan.targetlist =
739 fix_scan_list(root, splan->scan.plan.targetlist,
740 rtoffset, NUM_EXEC_TLIST(plan));
741 splan->scan.plan.qual =
742 fix_scan_list(root, splan->scan.plan.qual,
743 rtoffset, NUM_EXEC_QUAL(plan));
744 splan->bitmapqualorig =
745 fix_scan_list(root, splan->bitmapqualorig,
746 rtoffset, NUM_EXEC_QUAL(plan));
747 }
748 break;
749 case T_TidScan:
750 {
751 TidScan *splan = (TidScan *) plan;
752
753 splan->scan.scanrelid += rtoffset;
754 splan->scan.plan.targetlist =
755 fix_scan_list(root, splan->scan.plan.targetlist,
756 rtoffset, NUM_EXEC_TLIST(plan));
757 splan->scan.plan.qual =
758 fix_scan_list(root, splan->scan.plan.qual,
759 rtoffset, NUM_EXEC_QUAL(plan));
760 splan->tidquals =
761 fix_scan_list(root, splan->tidquals,
762 rtoffset, 1);
763 }
764 break;
765 case T_TidRangeScan:
766 {
767 TidRangeScan *splan = (TidRangeScan *) plan;
768
769 splan->scan.scanrelid += rtoffset;
770 splan->scan.plan.targetlist =
771 fix_scan_list(root, splan->scan.plan.targetlist,
772 rtoffset, NUM_EXEC_TLIST(plan));
773 splan->scan.plan.qual =
774 fix_scan_list(root, splan->scan.plan.qual,
775 rtoffset, NUM_EXEC_QUAL(plan));
776 splan->tidrangequals =
777 fix_scan_list(root, splan->tidrangequals,
778 rtoffset, 1);
779 }
780 break;
781 case T_SubqueryScan:
782 /* Needs special treatment, see comments below */
783 return set_subqueryscan_references(root,
784 (SubqueryScan *) plan,
785 rtoffset);
786 case T_FunctionScan:
787 {
788 FunctionScan *splan = (FunctionScan *) plan;
789
790 splan->scan.scanrelid += rtoffset;
791 splan->scan.plan.targetlist =
792 fix_scan_list(root, splan->scan.plan.targetlist,
793 rtoffset, NUM_EXEC_TLIST(plan));
794 splan->scan.plan.qual =
795 fix_scan_list(root, splan->scan.plan.qual,
796 rtoffset, NUM_EXEC_QUAL(plan));
797 splan->functions =
798 fix_scan_list(root, splan->functions, rtoffset, 1);
799 }
800 break;
801 case T_TableFuncScan:
802 {
803 TableFuncScan *splan = (TableFuncScan *) plan;
804
805 splan->scan.scanrelid += rtoffset;
806 splan->scan.plan.targetlist =
807 fix_scan_list(root, splan->scan.plan.targetlist,
808 rtoffset, NUM_EXEC_TLIST(plan));
809 splan->scan.plan.qual =
810 fix_scan_list(root, splan->scan.plan.qual,
811 rtoffset, NUM_EXEC_QUAL(plan));
812 splan->tablefunc = (TableFunc *)
813 fix_scan_expr(root, (Node *) splan->tablefunc,
814 rtoffset, 1);
815 }
816 break;
817 case T_ValuesScan:
818 {
819 ValuesScan *splan = (ValuesScan *) plan;
820
821 splan->scan.scanrelid += rtoffset;
822 splan->scan.plan.targetlist =
823 fix_scan_list(root, splan->scan.plan.targetlist,
824 rtoffset, NUM_EXEC_TLIST(plan));
825 splan->scan.plan.qual =
826 fix_scan_list(root, splan->scan.plan.qual,
827 rtoffset, NUM_EXEC_QUAL(plan));
828 splan->values_lists =
829 fix_scan_list(root, splan->values_lists,
830 rtoffset, 1);
831 }
832 break;
833 case T_CteScan:
834 {
835 CteScan *splan = (CteScan *) plan;
836
837 splan->scan.scanrelid += rtoffset;
838 splan->scan.plan.targetlist =
839 fix_scan_list(root, splan->scan.plan.targetlist,
840 rtoffset, NUM_EXEC_TLIST(plan));
841 splan->scan.plan.qual =
842 fix_scan_list(root, splan->scan.plan.qual,
843 rtoffset, NUM_EXEC_QUAL(plan));
844 }
845 break;
846 case T_NamedTuplestoreScan:
847 {
848 NamedTuplestoreScan *splan = (NamedTuplestoreScan *) plan;
849
850 splan->scan.scanrelid += rtoffset;
851 splan->scan.plan.targetlist =
852 fix_scan_list(root, splan->scan.plan.targetlist,
853 rtoffset, NUM_EXEC_TLIST(plan));
854 splan->scan.plan.qual =
855 fix_scan_list(root, splan->scan.plan.qual,
856 rtoffset, NUM_EXEC_QUAL(plan));
857 }
858 break;
859 case T_WorkTableScan:
860 {
861 WorkTableScan *splan = (WorkTableScan *) plan;
862
863 splan->scan.scanrelid += rtoffset;
864 splan->scan.plan.targetlist =
865 fix_scan_list(root, splan->scan.plan.targetlist,
866 rtoffset, NUM_EXEC_TLIST(plan));
867 splan->scan.plan.qual =
868 fix_scan_list(root, splan->scan.plan.qual,
869 rtoffset, NUM_EXEC_QUAL(plan));
870 }
871 break;
872 case T_ForeignScan:
873 set_foreignscan_references(root, (ForeignScan *) plan, rtoffset);
874 break;
875 case T_CustomScan:
876 set_customscan_references(root, (CustomScan *) plan, rtoffset);
877 break;
878
879 case T_NestLoop:
880 case T_MergeJoin:
881 case T_HashJoin:
882 set_join_references(root, (Join *) plan, rtoffset);
883 break;
884
885 case T_Gather:
886 case T_GatherMerge:
887 {
888 set_upper_references(root, plan, rtoffset);
889 set_param_references(root, plan);
890 }
891 break;
892
893 case T_Hash:
894 set_hash_references(root, plan, rtoffset);
895 break;
896
897 case T_Memoize:
898 {
899 Memoize *mplan = (Memoize *) plan;
900
901 /*
902 * Memoize does not evaluate its targetlist. It just uses the
903 * same targetlist from its outer subnode.
904 */
905 set_dummy_tlist_references(plan, rtoffset);
906
907 mplan->param_exprs = fix_scan_list(root, mplan->param_exprs,
908 rtoffset,
909 NUM_EXEC_TLIST(plan));
910 break;
911 }
912
913 case T_Material:
914 case T_Sort:
915 case T_IncrementalSort:
916 case T_Unique:
917 case T_SetOp:
918
919 /*
920 * These plan types don't actually bother to evaluate their
921 * targetlists, because they just return their unmodified input
922 * tuples. Even though the targetlist won't be used by the
923 * executor, we fix it up for possible use by EXPLAIN (not to
924 * mention ease of debugging --- wrong varnos are very confusing).
925 */
926 set_dummy_tlist_references(plan, rtoffset);
927
928 /*
929 * Since these plan types don't check quals either, we should not
930 * find any qual expression attached to them.
931 */
932 Assert(plan->qual == NIL);
933 break;
934 case T_LockRows:
935 {
936 LockRows *splan = (LockRows *) plan;
937
938 /*
939 * Like the plan types above, LockRows doesn't evaluate its
940 * tlist or quals. But we have to fix up the RT indexes in
941 * its rowmarks.
942 */
943 set_dummy_tlist_references(plan, rtoffset);
944 Assert(splan->plan.qual == NIL);
945
946 foreach(l, splan->rowMarks)
947 {
948 PlanRowMark *rc = (PlanRowMark *) lfirst(l);
949
950 rc->rti += rtoffset;
951 rc->prti += rtoffset;
952 }
953 }
954 break;
955 case T_Limit:
956 {
957 Limit *splan = (Limit *) plan;
958
959 /*
960 * Like the plan types above, Limit doesn't evaluate its tlist
961 * or quals. It does have live expressions for limit/offset,
962 * however; and those cannot contain subplan variable refs, so
963 * fix_scan_expr works for them.
964 */
965 set_dummy_tlist_references(plan, rtoffset);
966 Assert(splan->plan.qual == NIL);
967
968 splan->limitOffset =
969 fix_scan_expr(root, splan->limitOffset, rtoffset, 1);
970 splan->limitCount =
971 fix_scan_expr(root, splan->limitCount, rtoffset, 1);
972 }
973 break;
974 case T_Agg:
975 {
976 Agg *agg = (Agg *) plan;
977
978 /*
979 * If this node is combining partial-aggregation results, we
980 * must convert its Aggrefs to contain references to the
981 * partial-aggregate subexpressions that will be available
982 * from the child plan node.
983 */
984 if (DO_AGGSPLIT_COMBINE(agg->aggsplit))
985 {
986 plan->targetlist = (List *)
987 convert_combining_aggrefs((Node *) plan->targetlist,
988 NULL);
989 plan->qual = (List *)
990 convert_combining_aggrefs((Node *) plan->qual,
991 NULL);
992 }
993
994 set_upper_references(root, plan, rtoffset);
995 }
996 break;
997 case T_Group:
998 set_upper_references(root, plan, rtoffset);
999 break;
1000 case T_WindowAgg:
1001 {
1002 WindowAgg *wplan = (WindowAgg *) plan;
1003
1004 /*
1005 * Adjust the WindowAgg's run conditions by swapping the
1006 * WindowFuncs references out to instead reference the Var in
1007 * the scan slot so that when the executor evaluates the
1008 * runCondition, it receives the WindowFunc's value from the
1009 * slot that the result has just been stored into rather than
1010 * evaluating the WindowFunc all over again.
1011 */
1012 wplan->runCondition = set_windowagg_runcondition_references(root,
1013 wplan->runCondition,
1014 (Plan *) wplan);
1015
1016 set_upper_references(root, plan, rtoffset);
1017
1018 /*
1019 * Like Limit node limit/offset expressions, WindowAgg has
1020 * frame offset expressions, which cannot contain subplan
1021 * variable refs, so fix_scan_expr works for them.
1022 */
1023 wplan->startOffset =
1024 fix_scan_expr(root, wplan->startOffset, rtoffset, 1);
1025 wplan->endOffset =
1026 fix_scan_expr(root, wplan->endOffset, rtoffset, 1);
1027 wplan->runCondition = fix_scan_list(root,
1028 wplan->runCondition,
1029 rtoffset,
1030 NUM_EXEC_TLIST(plan));
1031 wplan->runConditionOrig = fix_scan_list(root,
1032 wplan->runConditionOrig,
1033 rtoffset,
1034 NUM_EXEC_TLIST(plan));
1035 }
1036 break;
1037 case T_Result:
1038 {
1039 Result *splan = (Result *) plan;
1040
1041 /*
1042 * Result may or may not have a subplan; if not, it's more
1043 * like a scan node than an upper node.
1044 */
1045 if (splan->plan.lefttree != NULL)
1046 set_upper_references(root, plan, rtoffset);
1047 else
1048 {
1049 /*
1050 * The tlist of a childless Result could contain
1051 * unresolved ROWID_VAR Vars, in case it's representing a
1052 * target relation which is completely empty because of
1053 * constraint exclusion. Replace any such Vars by null
1054 * constants, as though they'd been resolved for a leaf
1055 * scan node that doesn't support them. We could have
1056 * fix_scan_expr do this, but since the case is only
1057 * expected to occur here, it seems safer to special-case
1058 * it here and keep the assertions that ROWID_VARs
1059 * shouldn't be seen by fix_scan_expr.
1060 *
1061 * We also must handle the case where set operations have
1062 * been short-circuited resulting in a dummy Result node.
1063 * prepunion.c uses varno==0 for the set op targetlist.
1064 * See generate_setop_tlist() and generate_setop_tlist().
1065 * Here we rewrite these to use varno==1, which is the
1066 * varno of the first set-op child. Without this, EXPLAIN
1067 * will have trouble displaying targetlists of dummy set
1068 * operations.
1069 */
1070 foreach(l, splan->plan.targetlist)
1071 {
1072 TargetEntry *tle = (TargetEntry *) lfirst(l);
1073 Var *var = (Var *) tle->expr;
1074
1075 if (var && IsA(var, Var))
1076 {
1077 if (var->varno == ROWID_VAR)
1078 tle->expr = (Expr *) makeNullConst(var->vartype,
1079 var->vartypmod,
1080 var->varcollid);
1081 else if (var->varno == 0)
1082 tle->expr = (Expr *) makeVar(1,
1083 var->varattno,
1084 var->vartype,
1085 var->vartypmod,
1086 var->varcollid,
1087 var->varlevelsup);
1088 }
1089 }
1090
1091 splan->plan.targetlist =
1092 fix_scan_list(root, splan->plan.targetlist,
1093 rtoffset, NUM_EXEC_TLIST(plan));
1094 splan->plan.qual =
1095 fix_scan_list(root, splan->plan.qual,
1096 rtoffset, NUM_EXEC_QUAL(plan));
1097 }
1098 /* resconstantqual can't contain any subplan variable refs */
1099 splan->resconstantqual =
1100 fix_scan_expr(root, splan->resconstantqual, rtoffset, 1);
1101 /* adjust the relids set */
1102 splan->relids = offset_relid_set(splan->relids, rtoffset);
1103 }
1104 break;
1105 case T_ProjectSet:
1106 set_upper_references(root, plan, rtoffset);
1107 break;
1108 case T_ModifyTable:
1109 {
1110 ModifyTable *splan = (ModifyTable *) plan;
1111 Plan *subplan = outerPlan(splan);
1112
1113 Assert(splan->plan.targetlist == NIL);
1114 Assert(splan->plan.qual == NIL);
1115
1116 splan->withCheckOptionLists =
1117 fix_scan_list(root, splan->withCheckOptionLists,
1118 rtoffset, 1);
1119
1120 if (splan->returningLists)
1121 {
1122 List *newRL = NIL;
1123 ListCell *lcrl,
1124 *lcrr;
1125
1126 /*
1127 * Pass each per-resultrel returningList through
1128 * set_returning_clause_references().
1129 */
1130 Assert(list_length(splan->returningLists) == list_length(splan->resultRelations));
1131 forboth(lcrl, splan->returningLists,
1132 lcrr, splan->resultRelations)
1133 {
1134 List *rlist = (List *) lfirst(lcrl);
1135 Index resultrel = lfirst_int(lcrr);
1136
1137 rlist = set_returning_clause_references(root,
1138 rlist,
1139 subplan,
1140 resultrel,
1141 rtoffset);
1142 newRL = lappend(newRL, rlist);
1143 }
1144 splan->returningLists = newRL;
1145
1146 /*
1147 * Set up the visible plan targetlist as being the same as
1148 * the first RETURNING list. This is mostly for the use
1149 * of EXPLAIN; the executor won't execute that targetlist,
1150 * although it does use it to prepare the node's result
1151 * tuple slot. We postpone this step until here so that
1152 * we don't have to do set_returning_clause_references()
1153 * twice on identical targetlists.
1154 */
1155 splan->plan.targetlist = copyObject(linitial(newRL));
1156 }
1157
1158 /*
1159 * We treat ModifyTable with ON CONFLICT as a form of 'pseudo
1160 * join', where the inner side is the EXCLUDED tuple.
1161 * Therefore use fix_join_expr to setup the relevant variables
1162 * to INNER_VAR. We explicitly don't create any OUTER_VARs as
1163 * those are already used by RETURNING and it seems better to
1164 * be non-conflicting.
1165 */
1166 if (splan->onConflictAction == ONCONFLICT_UPDATE ||
1167 splan->onConflictAction == ONCONFLICT_SELECT)
1168 {
1169 indexed_tlist *itlist;
1170
1171 itlist = build_tlist_index(splan->exclRelTlist);
1172
1173 splan->onConflictSet =
1174 fix_join_expr(root, splan->onConflictSet,
1175 NULL, itlist,
1176 linitial_int(splan->resultRelations),
1177 rtoffset, NRM_EQUAL, NUM_EXEC_QUAL(plan));
1178
1179 splan->onConflictWhere = (Node *)
1180 fix_join_expr(root, (List *) splan->onConflictWhere,
1181 NULL, itlist,
1182 linitial_int(splan->resultRelations),
1183 rtoffset, NRM_EQUAL, NUM_EXEC_QUAL(plan));
1184
1185 pfree(itlist);
1186
1187 splan->exclRelTlist =
1188 fix_scan_list(root, splan->exclRelTlist, rtoffset, 1);
1189 }
1190
1191 /*
1192 * The MERGE statement produces the target rows by performing
1193 * a right join between the target relation and the source
1194 * relation (which could be a plain relation or a subquery).
1195 * The INSERT and UPDATE actions of the MERGE statement
1196 * require access to the columns from the source relation. We
1197 * arrange things so that the source relation attributes are
1198 * available as INNER_VAR and the target relation attributes
1199 * are available from the scan tuple.
1200 */
1201 if (splan->mergeActionLists != NIL)
1202 {
1203 List *newMJC = NIL;
1204 ListCell *lca,
1205 *lcj,
1206 *lcr;
1207
1208 /*
1209 * Fix the targetList of individual action nodes so that
1210 * the so-called "source relation" Vars are referenced as
1211 * INNER_VAR. Note that for this to work correctly during
1212 * execution, the ecxt_innertuple must be set to the tuple
1213 * obtained by executing the subplan, which is what
1214 * constitutes the "source relation".
1215 *
1216 * We leave the Vars from the result relation (i.e. the
1217 * target relation) unchanged i.e. those Vars would be
1218 * picked from the scan slot. So during execution, we must
1219 * ensure that ecxt_scantuple is setup correctly to refer
1220 * to the tuple from the target relation.
1221 */
1222 indexed_tlist *itlist;
1223
1224 itlist = build_tlist_index(subplan->targetlist);
1225
1226 forthree(lca, splan->mergeActionLists,
1227 lcj, splan->mergeJoinConditions,
1228 lcr, splan->resultRelations)
1229 {
1230 List *mergeActionList = lfirst(lca);
1231 Node *mergeJoinCondition = lfirst(lcj);
1232 Index resultrel = lfirst_int(lcr);
1233
1234 foreach(l, mergeActionList)
1235 {
1236 MergeAction *action = (MergeAction *) lfirst(l);
1237
1238 /* Fix targetList of each action. */
1239 action->targetList = fix_join_expr(root,
1240 action->targetList,
1241 NULL, itlist,
1242 resultrel,
1243 rtoffset,
1244 NRM_EQUAL,
1245 NUM_EXEC_TLIST(plan));
1246
1247 /* Fix quals too. */
1248 action->qual = (Node *) fix_join_expr(root,
1249 (List *) action->qual,
1250 NULL, itlist,
1251 resultrel,
1252 rtoffset,
1253 NRM_EQUAL,
1254 NUM_EXEC_QUAL(plan));
1255 }
1256
1257 /* Fix join condition too. */
1258 mergeJoinCondition = (Node *)
1259 fix_join_expr(root,
1260 (List *) mergeJoinCondition,
1261 NULL, itlist,
1262 resultrel,
1263 rtoffset,
1264 NRM_EQUAL,
1265 NUM_EXEC_QUAL(plan));
1266 newMJC = lappend(newMJC, mergeJoinCondition);
1267 }
1268 splan->mergeJoinConditions = newMJC;
1269 }
1270
1271 splan->nominalRelation += rtoffset;
1272 if (splan->rootRelation)
1273 splan->rootRelation += rtoffset;
1274 splan->exclRelRTI += rtoffset;
1275
1276 foreach(l, splan->resultRelations)
1277 {
1278 lfirst_int(l) += rtoffset;
1279 }
1280 foreach(l, splan->rowMarks)
1281 {
1282 PlanRowMark *rc = (PlanRowMark *) lfirst(l);
1283
1284 rc->rti += rtoffset;
1285 rc->prti += rtoffset;
1286 }
1287
1288 /*
1289 * Append this ModifyTable node's final result relation RT
1290 * index(es) to the global list for the plan.
1291 */
1292 root->glob->resultRelations =
1293 list_concat(root->glob->resultRelations,
1294 splan->resultRelations);
1295 if (splan->rootRelation)
1296 {
1297 root->glob->resultRelations =
1298 lappend_int(root->glob->resultRelations,
1299 splan->rootRelation);
1300 }
1301 }
1302 break;
1303 case T_Append:
1304 /* Needs special treatment, see comments below */
1305 return set_append_references(root,
1306 (Append *) plan,
1307 rtoffset);
1308 case T_MergeAppend:
1309 /* Needs special treatment, see comments below */
1310 return set_mergeappend_references(root,
1311 (MergeAppend *) plan,
1312 rtoffset);
1313 case T_RecursiveUnion:
1314 /* This doesn't evaluate targetlist or check quals either */
1315 set_dummy_tlist_references(plan, rtoffset);
1316 Assert(plan->qual == NIL);
1317 break;
1318 case T_BitmapAnd:
1319 {
1320 BitmapAnd *splan = (BitmapAnd *) plan;
1321
1322 /* BitmapAnd works like Append, but has no tlist */
1323 Assert(splan->plan.targetlist == NIL);
1324 Assert(splan->plan.qual == NIL);
1325 foreach(l, splan->bitmapplans)
1326 {
1327 lfirst(l) = set_plan_refs(root,
1328 (Plan *) lfirst(l),
1329 rtoffset);
1330 }
1331 }
1332 break;
1333 case T_BitmapOr:
1334 {
1335 BitmapOr *splan = (BitmapOr *) plan;
1336
1337 /* BitmapOr works like Append, but has no tlist */
1338 Assert(splan->plan.targetlist == NIL);
1339 Assert(splan->plan.qual == NIL);
1340 foreach(l, splan->bitmapplans)
1341 {
1342 lfirst(l) = set_plan_refs(root,
1343 (Plan *) lfirst(l),
1344 rtoffset);
1345 }
1346 }
1347 break;
1348 default:
1349 elog(ERROR, "unrecognized node type: %d",
1350 (int) nodeTag(plan));
1351 break;
1352 }
1353
1354 /*
1355 * Now recurse into child plans, if any
1356 *
1357 * NOTE: it is essential that we recurse into child plans AFTER we set
1358 * subplan references in this plan's tlist and quals. If we did the
1359 * reference-adjustments bottom-up, then we would fail to match this
1360 * plan's var nodes against the already-modified nodes of the children.
1361 */
1362 plan->lefttree = set_plan_refs(root, plan->lefttree, rtoffset);
1363 plan->righttree = set_plan_refs(root, plan->righttree, rtoffset);
1364
1365 return plan;
1366}
1367
1368/*
1369 * set_indexonlyscan_references
1370 * Do set_plan_references processing on an IndexOnlyScan
1371 *
1372 * This is unlike the handling of a plain IndexScan because we have to
1373 * convert Vars referencing the heap into Vars referencing the index.
1374 * We can use the fix_upper_expr machinery for that, by working from a
1375 * targetlist describing the index columns.
1376 */
1377static Plan *
1378set_indexonlyscan_references(PlannerInfo *root,
1379 IndexOnlyScan *plan,
1380 int rtoffset)
1381{
1382 indexed_tlist *index_itlist;
1383 List *stripped_indextlist;
1384 ListCell *lc;
1385
1386 /*
1387 * Vars in the plan node's targetlist, qual, and recheckqual must only
1388 * reference columns that the index AM can actually return. To ensure
1389 * this, remove non-returnable columns (which are marked as resjunk) from
1390 * the indexed tlist. We can just drop them because the indexed_tlist
1391 * machinery pays attention to TLE resnos, not physical list position.
1392 */
1393 stripped_indextlist = NIL;
1394 foreach(lc, plan->indextlist)
1395 {
1396 TargetEntry *indextle = (TargetEntry *) lfirst(lc);
1397
1398 if (!indextle->resjunk)
1399 stripped_indextlist = lappend(stripped_indextlist, indextle);
1400 }
1401
1402 index_itlist = build_tlist_index(stripped_indextlist);
1403
1404 plan->scan.scanrelid += rtoffset;
1405 plan->scan.plan.targetlist = (List *)
1406 fix_upper_expr(root,
1407 (Node *) plan->scan.plan.targetlist,
1408 index_itlist,
1409 INDEX_VAR,
1410 rtoffset,
1411 NRM_EQUAL,
1412 NUM_EXEC_TLIST((Plan *) plan));
1413 plan->scan.plan.qual = (List *)
1414 fix_upper_expr(root,
1415 (Node *) plan->scan.plan.qual,
1416 index_itlist,
1417 INDEX_VAR,
1418 rtoffset,
1419 NRM_EQUAL,
1420 NUM_EXEC_QUAL((Plan *) plan));
1421 plan->recheckqual = (List *)
1422 fix_upper_expr(root,
1423 (Node *) plan->recheckqual,
1424 index_itlist,
1425 INDEX_VAR,
1426 rtoffset,
1427 NRM_EQUAL,
1428 NUM_EXEC_QUAL((Plan *) plan));
1429 /* indexqual is already transformed to reference index columns */
1430 plan->indexqual = fix_scan_list(root, plan->indexqual,
1431 rtoffset, 1);
1432 /* indexorderby is already transformed to reference index columns */
1433 plan->indexorderby = fix_scan_list(root, plan->indexorderby,
1434 rtoffset, 1);
1435 /* indextlist must NOT be transformed to reference index columns */
1436 plan->indextlist = fix_scan_list(root, plan->indextlist,
1437 rtoffset, NUM_EXEC_TLIST((Plan *) plan));
1438
1439 pfree(index_itlist);
1440
1441 return (Plan *) plan;
1442}
1443
1444/*
1445 * set_subqueryscan_references
1446 * Do set_plan_references processing on a SubqueryScan
1447 *
1448 * We try to strip out the SubqueryScan entirely; if we can't, we have
1449 * to do the normal processing on it.
1450 */
1451static Plan *
1452set_subqueryscan_references(PlannerInfo *root,
1453 SubqueryScan *plan,
1454 int rtoffset)
1455{
1456 RelOptInfo *rel;
1457 Plan *result;
1458
1459 /* Need to look up the subquery's RelOptInfo, since we need its subroot */
1460 rel = find_base_rel(root, plan->scan.scanrelid);
1461
1462 /* Recursively process the subplan */
1463 plan->subplan = set_plan_references(rel->subroot, plan->subplan);
1464
1465 if (trivial_subqueryscan(plan))
1466 {
1467 Index scanrelid;
1468
1469 /*
1470 * We can omit the SubqueryScan node and just pull up the subplan.
1471 */
1472 result = clean_up_removed_plan_level((Plan *) plan, plan->subplan);
1473
1474 /* Remember that we removed a SubqueryScan */
1475 scanrelid = plan->scan.scanrelid + rtoffset;
1476 record_elided_node(root->glob, plan->subplan->plan_node_id,
1477 T_SubqueryScan, bms_make_singleton(scanrelid));
1478 }
1479 else
1480 {
1481 /*
1482 * Keep the SubqueryScan node. We have to do the processing that
1483 * set_plan_references would otherwise have done on it. Notice we do
1484 * not do set_upper_references() here, because a SubqueryScan will
1485 * always have been created with correct references to its subplan's
1486 * outputs to begin with.
1487 */
1488 plan->scan.scanrelid += rtoffset;
1489 plan->scan.plan.targetlist =
1490 fix_scan_list(root, plan->scan.plan.targetlist,
1491 rtoffset, NUM_EXEC_TLIST((Plan *) plan));
1492 plan->scan.plan.qual =
1493 fix_scan_list(root, plan->scan.plan.qual,
1494 rtoffset, NUM_EXEC_QUAL((Plan *) plan));
1495
1496 result = (Plan *) plan;
1497 }
1498
1499 return result;
1500}
1501
1502/*
1503 * trivial_subqueryscan
1504 * Detect whether a SubqueryScan can be deleted from the plan tree.
1505 *
1506 * We can delete it if it has no qual to check and the targetlist just
1507 * regurgitates the output of the child plan.
1508 *
1509 * This can be called from mark_async_capable_plan(), a helper function for
1510 * create_append_plan(), before set_subqueryscan_references(), to determine
1511 * triviality of a SubqueryScan that is a child of an Append node. So we
1512 * cache the result in the SubqueryScan node to avoid repeated computation.
1513 *
1514 * Note: when called from mark_async_capable_plan(), we determine the result
1515 * before running finalize_plan() on the SubqueryScan node (if needed) and
1516 * set_plan_references() on the subplan tree, but this would be safe, because
1517 * 1) finalize_plan() doesn't modify the tlist or quals for the SubqueryScan
1518 * node (or that for any plan node in the subplan tree), and
1519 * 2) set_plan_references() modifies the tlist for every plan node in the
1520 * subplan tree, but keeps const/resjunk columns as const/resjunk ones and
1521 * preserves the length and order of the tlist, and
1522 * 3) set_plan_references() might delete the topmost plan node like an Append
1523 * or MergeAppend from the subplan tree and pull up the child plan node,
1524 * but in that case, the tlist for the child plan node exactly matches the
1525 * parent.
1526 */
1527bool
1528trivial_subqueryscan(SubqueryScan *plan)
1529{
1530 int attrno;
1531 ListCell *lp,
1532 *lc;
1533
1534 /* We might have detected this already; in which case reuse the result */
1535 if (plan->scanstatus == SUBQUERY_SCAN_TRIVIAL)
1536 return true;
1537 if (plan->scanstatus == SUBQUERY_SCAN_NONTRIVIAL)
1538 return false;
1539 Assert(plan->scanstatus == SUBQUERY_SCAN_UNKNOWN);
1540 /* Initially, mark the SubqueryScan as non-deletable from the plan tree */
1541 plan->scanstatus = SUBQUERY_SCAN_NONTRIVIAL;
1542
1543 if (plan->scan.plan.qual != NIL)
1544 return false;
1545
1546 if (list_length(plan->scan.plan.targetlist) !=
1547 list_length(plan->subplan->targetlist))
1548 return false; /* tlists not same length */
1549
1550 attrno = 1;
1551 forboth(lp, plan->scan.plan.targetlist, lc, plan->subplan->targetlist)
1552 {
1553 TargetEntry *ptle = (TargetEntry *) lfirst(lp);
1554 TargetEntry *ctle = (TargetEntry *) lfirst(lc);
1555
1556 if (ptle->resjunk != ctle->resjunk)
1557 return false; /* tlist doesn't match junk status */
1558
1559 /*
1560 * We accept either a Var referencing the corresponding element of the
1561 * subplan tlist, or a Const equaling the subplan element. See
1562 * generate_setop_tlist() for motivation.
1563 */
1564 if (ptle->expr && IsA(ptle->expr, Var))
1565 {
1566 Var *var = (Var *) ptle->expr;
1567
1568 Assert(var->varno == plan->scan.scanrelid);
1569 Assert(var->varlevelsup == 0);
1570 if (var->varattno != attrno)
1571 return false; /* out of order */
1572 }
1573 else if (ptle->expr && IsA(ptle->expr, Const))
1574 {
1575 if (!equal(ptle->expr, ctle->expr))
1576 return false;
1577 }
1578 else
1579 return false;
1580
1581 attrno++;
1582 }
1583
1584 /* Re-mark the SubqueryScan as deletable from the plan tree */
1585 plan->scanstatus = SUBQUERY_SCAN_TRIVIAL;
1586
1587 return true;
1588}
1589
1590/*
1591 * clean_up_removed_plan_level
1592 * Do necessary cleanup when we strip out a SubqueryScan, Append, etc
1593 *
1594 * We are dropping the "parent" plan in favor of returning just its "child".
1595 * A few small tweaks are needed.
1596 */
1597static Plan *
1598clean_up_removed_plan_level(Plan *parent, Plan *child)
1599{
1600 /*
1601 * We have to be sure we don't lose any initplans, so move any that were
1602 * attached to the parent plan to the child. If any are parallel-unsafe,
1603 * the child is no longer parallel-safe. As a cosmetic matter, also add
1604 * the initplans' run costs to the child's costs.
1605 */
1606 if (parent->initPlan)
1607 {
1608 Cost initplan_cost;
1609 bool unsafe_initplans;
1610
1611 SS_compute_initplan_cost(parent->initPlan,
1612 &initplan_cost, &unsafe_initplans);
1613 child->startup_cost += initplan_cost;
1614 child->total_cost += initplan_cost;
1615 if (unsafe_initplans)
1616 child->parallel_safe = false;
1617
1618 /*
1619 * Attach plans this way so that parent's initplans are processed
1620 * before any pre-existing initplans of the child. Probably doesn't
1621 * matter, but let's preserve the ordering just in case.
1622 */
1623 child->initPlan = list_concat(parent->initPlan,
1624 child->initPlan);
1625 }
1626
1627 /*
1628 * We also have to transfer the parent's column labeling info into the
1629 * child, else columns sent to client will be improperly labeled if this
1630 * is the topmost plan level. resjunk and so on may be important too.
1631 */
1632 apply_tlist_labeling(child->targetlist, parent->targetlist);
1633
1634 return child;
1635}
1636
1637/*
1638 * set_foreignscan_references
1639 * Do set_plan_references processing on a ForeignScan
1640 */
1641static void
1642set_foreignscan_references(PlannerInfo *root,
1643 ForeignScan *fscan,
1644 int rtoffset)
1645{
1646 /* Adjust scanrelid if it's valid */
1647 if (fscan->scan.scanrelid > 0)
1648 fscan->scan.scanrelid += rtoffset;
1649
1650 if (fscan->fdw_scan_tlist != NIL || fscan->scan.scanrelid == 0)
1651 {
1652 /*
1653 * Adjust tlist, qual, fdw_exprs, fdw_recheck_quals to reference
1654 * foreign scan tuple
1655 */
1656 indexed_tlist *itlist = build_tlist_index(fscan->fdw_scan_tlist);
1657
1658 fscan->scan.plan.targetlist = (List *)
1659 fix_upper_expr(root,
1660 (Node *) fscan->scan.plan.targetlist,
1661 itlist,
1662 INDEX_VAR,
1663 rtoffset,
1664 NRM_EQUAL,
1665 NUM_EXEC_TLIST((Plan *) fscan));
1666 fscan->scan.plan.qual = (List *)
1667 fix_upper_expr(root,
1668 (Node *) fscan->scan.plan.qual,
1669 itlist,
1670 INDEX_VAR,
1671 rtoffset,
1672 NRM_EQUAL,
1673 NUM_EXEC_QUAL((Plan *) fscan));
1674 fscan->fdw_exprs = (List *)
1675 fix_upper_expr(root,
1676 (Node *) fscan->fdw_exprs,
1677 itlist,
1678 INDEX_VAR,
1679 rtoffset,
1680 NRM_EQUAL,
1681 NUM_EXEC_QUAL((Plan *) fscan));
1682 fscan->fdw_recheck_quals = (List *)
1683 fix_upper_expr(root,
1684 (Node *) fscan->fdw_recheck_quals,
1685 itlist,
1686 INDEX_VAR,
1687 rtoffset,
1688 NRM_EQUAL,
1689 NUM_EXEC_QUAL((Plan *) fscan));
1690 pfree(itlist);
1691 /* fdw_scan_tlist itself just needs fix_scan_list() adjustments */
1692 fscan->fdw_scan_tlist =
1693 fix_scan_list(root, fscan->fdw_scan_tlist,
1694 rtoffset, NUM_EXEC_TLIST((Plan *) fscan));
1695 }
1696 else
1697 {
1698 /*
1699 * Adjust tlist, qual, fdw_exprs, fdw_recheck_quals in the standard
1700 * way
1701 */
1702 fscan->scan.plan.targetlist =
1703 fix_scan_list(root, fscan->scan.plan.targetlist,
1704 rtoffset, NUM_EXEC_TLIST((Plan *) fscan));
1705 fscan->scan.plan.qual =
1706 fix_scan_list(root, fscan->scan.plan.qual,
1707 rtoffset, NUM_EXEC_QUAL((Plan *) fscan));
1708 fscan->fdw_exprs =
1709 fix_scan_list(root, fscan->fdw_exprs,
1710 rtoffset, NUM_EXEC_QUAL((Plan *) fscan));
1711 fscan->fdw_recheck_quals =
1712 fix_scan_list(root, fscan->fdw_recheck_quals,
1713 rtoffset, NUM_EXEC_QUAL((Plan *) fscan));
1714 }
1715
1716 fscan->fs_relids = offset_relid_set(fscan->fs_relids, rtoffset);
1717 fscan->fs_base_relids = offset_relid_set(fscan->fs_base_relids, rtoffset);
1718
1719 /* Adjust resultRelation if it's valid */
1720 if (fscan->resultRelation > 0)
1721 fscan->resultRelation += rtoffset;
1722}
1723
1724/*
1725 * set_customscan_references
1726 * Do set_plan_references processing on a CustomScan
1727 */
1728static void
1729set_customscan_references(PlannerInfo *root,
1730 CustomScan *cscan,
1731 int rtoffset)
1732{
1733 ListCell *lc;
1734
1735 /* Adjust scanrelid if it's valid */
1736 if (cscan->scan.scanrelid > 0)
1737 cscan->scan.scanrelid += rtoffset;
1738
1739 if (cscan->custom_scan_tlist != NIL || cscan->scan.scanrelid == 0)
1740 {
1741 /* Adjust tlist, qual, custom_exprs to reference custom scan tuple */
1742 indexed_tlist *itlist = build_tlist_index(cscan->custom_scan_tlist);
1743
1744 cscan->scan.plan.targetlist = (List *)
1745 fix_upper_expr(root,
1746 (Node *) cscan->scan.plan.targetlist,
1747 itlist,
1748 INDEX_VAR,
1749 rtoffset,
1750 NRM_EQUAL,
1751 NUM_EXEC_TLIST((Plan *) cscan));
1752 cscan->scan.plan.qual = (List *)
1753 fix_upper_expr(root,
1754 (Node *) cscan->scan.plan.qual,
1755 itlist,
1756 INDEX_VAR,
1757 rtoffset,
1758 NRM_EQUAL,
1759 NUM_EXEC_QUAL((Plan *) cscan));
1760 cscan->custom_exprs = (List *)
1761 fix_upper_expr(root,
1762 (Node *) cscan->custom_exprs,
1763 itlist,
1764 INDEX_VAR,
1765 rtoffset,
1766 NRM_EQUAL,
1767 NUM_EXEC_QUAL((Plan *) cscan));
1768 pfree(itlist);
1769 /* custom_scan_tlist itself just needs fix_scan_list() adjustments */
1770 cscan->custom_scan_tlist =
1771 fix_scan_list(root, cscan->custom_scan_tlist,
1772 rtoffset, NUM_EXEC_TLIST((Plan *) cscan));
1773 }
1774 else
1775 {
1776 /* Adjust tlist, qual, custom_exprs in the standard way */
1777 cscan->scan.plan.targetlist =
1778 fix_scan_list(root, cscan->scan.plan.targetlist,
1779 rtoffset, NUM_EXEC_TLIST((Plan *) cscan));
1780 cscan->scan.plan.qual =
1781 fix_scan_list(root, cscan->scan.plan.qual,
1782 rtoffset, NUM_EXEC_QUAL((Plan *) cscan));
1783 cscan->custom_exprs =
1784 fix_scan_list(root, cscan->custom_exprs,
1785 rtoffset, NUM_EXEC_QUAL((Plan *) cscan));
1786 }
1787
1788 /* Adjust child plan-nodes recursively, if needed */
1789 foreach(lc, cscan->custom_plans)
1790 {
1791 lfirst(lc) = set_plan_refs(root, (Plan *) lfirst(lc), rtoffset);
1792 }
1793
1794 cscan->custom_relids = offset_relid_set(cscan->custom_relids, rtoffset);
1795}
1796
1797/*
1798 * register_partpruneinfo
1799 * Subroutine for set_append_references and set_mergeappend_references
1800 *
1801 * Add the PartitionPruneInfo from root->partPruneInfos at the given index
1802 * into PlannerGlobal->partPruneInfos and return its index there.
1803 *
1804 * Also update the RT indexes present in PartitionedRelPruneInfos to add the
1805 * offset.
1806 *
1807 * Finally, if there are initial pruning steps, add the RT indexes of the
1808 * leaf partitions to the set of relations that are prunable at execution
1809 * startup time.
1810 */
1811static int
1812register_partpruneinfo(PlannerInfo *root, int part_prune_index, int rtoffset)
1813{
1814 PlannerGlobal *glob = root->glob;
1815 PartitionPruneInfo *pinfo;
1816 ListCell *l;
1817
1818 Assert(part_prune_index >= 0 &&
1819 part_prune_index < list_length(root->partPruneInfos));
1820 pinfo = list_nth_node(PartitionPruneInfo, root->partPruneInfos,
1821 part_prune_index);
1822
1823 pinfo->relids = offset_relid_set(pinfo->relids, rtoffset);
1824 foreach(l, pinfo->prune_infos)
1825 {
1826 List *prune_infos = lfirst(l);
1827 ListCell *l2;
1828
1829 foreach(l2, prune_infos)
1830 {
1831 PartitionedRelPruneInfo *prelinfo = lfirst(l2);
1832 int i;
1833
1834 prelinfo->rtindex += rtoffset;
1835 prelinfo->initial_pruning_steps =
1836 fix_scan_list(root, prelinfo->initial_pruning_steps,
1837 rtoffset, 1);
1838 prelinfo->exec_pruning_steps =
1839 fix_scan_list(root, prelinfo->exec_pruning_steps,
1840 rtoffset, 1);
1841
1842 for (i = 0; i < prelinfo->nparts; i++)
1843 {
1844 /*
1845 * Non-leaf partitions and partitions that do not have a
1846 * subplan are not included in this map as mentioned in
1847 * make_partitionedrel_pruneinfo().
1848 */
1849 if (prelinfo->leafpart_rti_map[i])
1850 {
1851 prelinfo->leafpart_rti_map[i] += rtoffset;
1852 if (prelinfo->initial_pruning_steps)
1853 glob->prunableRelids = bms_add_member(glob->prunableRelids,
1854 prelinfo->leafpart_rti_map[i]);
1855 }
1856 }
1857 }
1858 }
1859
1860 glob->partPruneInfos = lappend(glob->partPruneInfos, pinfo);
1861
1862 return list_length(glob->partPruneInfos) - 1;
1863}
1864
1865/*
1866 * set_append_references
1867 * Do set_plan_references processing on an Append
1868 *
1869 * We try to strip out the Append entirely; if we can't, we have
1870 * to do the normal processing on it.
1871 */
1872static Plan *
1873set_append_references(PlannerInfo *root,
1874 Append *aplan,
1875 int rtoffset)
1876{
1877 ListCell *l;
1878
1879 /*
1880 * Append, like Sort et al, doesn't actually evaluate its targetlist or
1881 * check quals. If it's got exactly one child plan, then it's not doing
1882 * anything useful at all, and we can strip it out.
1883 */
1884 Assert(aplan->plan.qual == NIL);
1885
1886 /* First, we gotta recurse on the children */
1887 foreach(l, aplan->appendplans)
1888 {
1889 lfirst(l) = set_plan_refs(root, (Plan *) lfirst(l), rtoffset);
1890 }
1891
1892 /*
1893 * See if it's safe to get rid of the Append entirely. For this to be
1894 * safe, there must be only one child plan and that child plan's parallel
1895 * awareness must match the Append's. The reason for the latter is that
1896 * if the Append is parallel aware and the child is not, then the calling
1897 * plan may execute the non-parallel aware child multiple times. (If you
1898 * change these rules, update create_append_path to match.)
1899 */
1900 if (list_length(aplan->appendplans) == 1)
1901 {
1902 Plan *p = (Plan *) linitial(aplan->appendplans);
1903
1904 if (p->parallel_aware == aplan->plan.parallel_aware)
1905 {
1906 Plan *result;
1907
1908 result = clean_up_removed_plan_level((Plan *) aplan, p);
1909
1910 /* Remember that we removed an Append */
1911 record_elided_node(root->glob, p->plan_node_id, T_Append,
1912 offset_relid_set(aplan->apprelids, rtoffset));
1913
1914 return result;
1915 }
1916 }
1917
1918 /*
1919 * Otherwise, clean up the Append as needed. It's okay to do this after
1920 * recursing to the children, because set_dummy_tlist_references doesn't
1921 * look at those.
1922 */
1923 set_dummy_tlist_references((Plan *) aplan, rtoffset);
1924
1925 aplan->apprelids = offset_relid_set(aplan->apprelids, rtoffset);
1926
1927 /*
1928 * Add PartitionPruneInfo, if any, to PlannerGlobal and update the index.
1929 * Also update the RT indexes present in it to add the offset.
1930 */
1931 if (aplan->part_prune_index >= 0)
1932 aplan->part_prune_index =
1933 register_partpruneinfo(root, aplan->part_prune_index, rtoffset);
1934
1935 /* We don't need to recurse to lefttree or righttree ... */
1936 Assert(aplan->plan.lefttree == NULL);
1937 Assert(aplan->plan.righttree == NULL);
1938
1939 return (Plan *) aplan;
1940}
1941
1942/*
1943 * set_mergeappend_references
1944 * Do set_plan_references processing on a MergeAppend
1945 *
1946 * We try to strip out the MergeAppend entirely; if we can't, we have
1947 * to do the normal processing on it.
1948 */
1949static Plan *
1950set_mergeappend_references(PlannerInfo *root,
1951 MergeAppend *mplan,
1952 int rtoffset)
1953{
1954 ListCell *l;
1955
1956 /*
1957 * MergeAppend, like Sort et al, doesn't actually evaluate its targetlist
1958 * or check quals. If it's got exactly one child plan, then it's not
1959 * doing anything useful at all, and we can strip it out.
1960 */
1961 Assert(mplan->plan.qual == NIL);
1962
1963 /* First, we gotta recurse on the children */
1964 foreach(l, mplan->mergeplans)
1965 {
1966 lfirst(l) = set_plan_refs(root, (Plan *) lfirst(l), rtoffset);
1967 }
1968
1969 /*
1970 * See if it's safe to get rid of the MergeAppend entirely. For this to
1971 * be safe, there must be only one child plan and that child plan's
1972 * parallel awareness must match the MergeAppend's. The reason for the
1973 * latter is that if the MergeAppend is parallel aware and the child is
1974 * not, then the calling plan may execute the non-parallel aware child
1975 * multiple times. (If you change these rules, update
1976 * create_merge_append_path to match.)
1977 */
1978 if (list_length(mplan->mergeplans) == 1)
1979 {
1980 Plan *p = (Plan *) linitial(mplan->mergeplans);
1981
1982 if (p->parallel_aware == mplan->plan.parallel_aware)
1983 {
1984 Plan *result;
1985
1986 result = clean_up_removed_plan_level((Plan *) mplan, p);
1987
1988 /* Remember that we removed a MergeAppend */
1989 record_elided_node(root->glob, p->plan_node_id, T_MergeAppend,
1990 offset_relid_set(mplan->apprelids, rtoffset));
1991
1992 return result;
1993 }
1994 }
1995
1996 /*
1997 * Otherwise, clean up the MergeAppend as needed. It's okay to do this
1998 * after recursing to the children, because set_dummy_tlist_references
1999 * doesn't look at those.
2000 */
2001 set_dummy_tlist_references((Plan *) mplan, rtoffset);
2002
2003 mplan->apprelids = offset_relid_set(mplan->apprelids, rtoffset);
2004
2005 /*
2006 * Add PartitionPruneInfo, if any, to PlannerGlobal and update the index.
2007 * Also update the RT indexes present in it to add the offset.
2008 */
2009 if (mplan->part_prune_index >= 0)
2010 mplan->part_prune_index =
2011 register_partpruneinfo(root, mplan->part_prune_index, rtoffset);
2012
2013 /* We don't need to recurse to lefttree or righttree ... */
2014 Assert(mplan->plan.lefttree == NULL);
2015 Assert(mplan->plan.righttree == NULL);
2016
2017 return (Plan *) mplan;
2018}
2019
2020/*
2021 * set_hash_references
2022 * Do set_plan_references processing on a Hash node
2023 */
2024static void
2025set_hash_references(PlannerInfo *root, Plan *plan, int rtoffset)
2026{
2027 Hash *hplan = (Hash *) plan;
2028 Plan *outer_plan = plan->lefttree;
2029 indexed_tlist *outer_itlist;
2030
2031 /*
2032 * Hash's hashkeys are used when feeding tuples into the hashtable,
2033 * therefore have them reference Hash's outer plan (which itself is the
2034 * inner plan of the HashJoin).
2035 */
2036 outer_itlist = build_tlist_index(outer_plan->targetlist);
2037 hplan->hashkeys = (List *)
2038 fix_upper_expr(root,
2039 (Node *) hplan->hashkeys,
2040 outer_itlist,
2041 OUTER_VAR,
2042 rtoffset,
2043 NRM_EQUAL,
2044 NUM_EXEC_QUAL(plan));
2045
2046 /* Hash doesn't project */
2047 set_dummy_tlist_references(plan, rtoffset);
2048
2049 /* Hash nodes don't have their own quals */
2050 Assert(plan->qual == NIL);
2051}
2052
2053/*
2054 * offset_relid_set
2055 * Apply rtoffset to the members of a Relids set.
2056 */
2057static Relids
2058offset_relid_set(Relids relids, int rtoffset)
2059{
2060 Relids result = NULL;
2061 int rtindex;
2062
2063 /* If there's no offset to apply, we needn't recompute the value */
2064 if (rtoffset == 0)
2065 return relids;
2066 rtindex = -1;
2067 while ((rtindex = bms_next_member(relids, rtindex)) >= 0)
2068 result = bms_add_member(result, rtindex + rtoffset);
2069 return result;
2070}
2071
2072/*
2073 * copyVar
2074 * Copy a Var node.
2075 *
2076 * fix_scan_expr and friends do this enough times that it's worth having
2077 * a bespoke routine instead of using the generic copyObject() function.
2078 */
2079static inline Var *
2080copyVar(Var *var)
2081{
2082 Var *newvar = palloc_object(Var);
2083
2084 *newvar = *var;
2085 return newvar;
2086}
2087
2088/*
2089 * fix_expr_common
2090 * Do generic set_plan_references processing on an expression node
2091 *
2092 * This is code that is common to all variants of expression-fixing.
2093 * We must look up operator opcode info for OpExpr and related nodes,
2094 * add OIDs from regclass Const nodes into root->glob->relationOids, and
2095 * add PlanInvalItems for user-defined functions into root->glob->invalItems.
2096 * We also fill in column index lists for GROUPING() expressions.
2097 *
2098 * We assume it's okay to update opcode info in-place. So this could possibly
2099 * scribble on the planner's input data structures, but it's OK.
2100 */
2101static void
2102fix_expr_common(PlannerInfo *root, Node *node)
2103{
2104 /* We assume callers won't call us on a NULL pointer */
2105 if (IsA(node, Aggref))
2106 {
2107 record_plan_function_dependency(root,
2108 ((Aggref *) node)->aggfnoid);
2109 }
2110 else if (IsA(node, WindowFunc))
2111 {
2112 record_plan_function_dependency(root,
2113 ((WindowFunc *) node)->winfnoid);
2114 }
2115 else if (IsA(node, FuncExpr))
2116 {
2117 record_plan_function_dependency(root,
2118 ((FuncExpr *) node)->funcid);
2119 }
2120 else if (IsA(node, OpExpr))
2121 {
2122 set_opfuncid((OpExpr *) node);
2123 record_plan_function_dependency(root,
2124 ((OpExpr *) node)->opfuncid);
2125 }
2126 else if (IsA(node, DistinctExpr))
2127 {
2128 set_opfuncid((OpExpr *) node); /* rely on struct equivalence */
2129 record_plan_function_dependency(root,
2130 ((DistinctExpr *) node)->opfuncid);
2131 }
2132 else if (IsA(node, NullIfExpr))
2133 {
2134 set_opfuncid((OpExpr *) node); /* rely on struct equivalence */
2135 record_plan_function_dependency(root,
2136 ((NullIfExpr *) node)->opfuncid);
2137 }
2138 else if (IsA(node, ScalarArrayOpExpr))
2139 {
2140 ScalarArrayOpExpr *saop = (ScalarArrayOpExpr *) node;
2141
2142 set_sa_opfuncid(saop);
2143 record_plan_function_dependency(root, saop->opfuncid);
2144
2145 if (OidIsValid(saop->hashfuncid))
2146 record_plan_function_dependency(root, saop->hashfuncid);
2147
2148 if (OidIsValid(saop->negfuncid))
2149 record_plan_function_dependency(root, saop->negfuncid);
2150 }
2151 else if (IsA(node, Const))
2152 {
2153 Const *con = (Const *) node;
2154
2155 /* Check for regclass reference */
2156 if (ISREGCLASSCONST(con))
2157 root->glob->relationOids =
2158 lappend_oid(root->glob->relationOids,
2159 DatumGetObjectId(con->constvalue));
2160 }
2161 else if (IsA(node, GroupingFunc))
2162 {
2163 GroupingFunc *g = (GroupingFunc *) node;
2164 AttrNumber *grouping_map = root->grouping_map;
2165
2166 /* If there are no grouping sets, we don't need this. */
2167
2168 Assert(grouping_map || g->cols == NIL);
2169
2170 if (grouping_map)
2171 {
2172 ListCell *lc;
2173 List *cols = NIL;
2174
2175 foreach(lc, g->refs)
2176 {
2177 cols = lappend_int(cols, grouping_map[lfirst_int(lc)]);
2178 }
2179
2180 Assert(!g->cols || equal(cols, g->cols));
2181
2182 if (!g->cols)
2183 g->cols = cols;
2184 }
2185 }
2186}
2187
2188/*
2189 * fix_param_node
2190 * Do set_plan_references processing on a Param
2191 *
2192 * If it's a PARAM_MULTIEXPR, replace it with the appropriate Param from
2193 * root->multiexpr_params; otherwise no change is needed.
2194 * Just for paranoia's sake, we make a copy of the node in either case.
2195 */
2196static Node *
2197fix_param_node(PlannerInfo *root, Param *p)
2198{
2199 if (p->paramkind == PARAM_MULTIEXPR)
2200 {
2201 int subqueryid = p->paramid >> 16;
2202 int colno = p->paramid & 0xFFFF;
2203 List *params;
2204
2205 if (subqueryid <= 0 ||
2206 subqueryid > list_length(root->multiexpr_params))
2207 elog(ERROR, "unexpected PARAM_MULTIEXPR ID: %d", p->paramid);
2208 params = (List *) list_nth(root->multiexpr_params, subqueryid - 1);
2209 if (colno <= 0 || colno > list_length(params))
2210 elog(ERROR, "unexpected PARAM_MULTIEXPR ID: %d", p->paramid);
2211 return copyObject(list_nth(params, colno - 1));
2212 }
2213 return (Node *) copyObject(p);
2214}
2215
2216/*
2217 * fix_alternative_subplan
2218 * Do set_plan_references processing on an AlternativeSubPlan
2219 *
2220 * Choose one of the alternative implementations and return just that one,
2221 * discarding the rest of the AlternativeSubPlan structure.
2222 * Note: caller must still recurse into the result!
2223 *
2224 * We don't make any attempt to fix up cost estimates in the parent plan
2225 * node or higher-level nodes.
2226 */
2227static Node *
2228fix_alternative_subplan(PlannerInfo *root, AlternativeSubPlan *asplan,
2229 double num_exec)
2230{
2231 SubPlan *bestplan = NULL;
2232 Cost bestcost = 0;
2233 ListCell *lc;
2234
2235 /*
2236 * Compute the estimated cost of each subplan assuming num_exec
2237 * executions, and keep the cheapest one. In event of exact equality of
2238 * estimates, we prefer the later plan; this is a bit arbitrary, but in
2239 * current usage it biases us to break ties against fast-start subplans.
2240 */
2241 Assert(asplan->subplans != NIL);
2242
2243 foreach(lc, asplan->subplans)
2244 {
2245 SubPlan *curplan = (SubPlan *) lfirst(lc);
2246 Cost curcost;
2247
2248 curcost = curplan->startup_cost + num_exec * curplan->per_call_cost;
2249 if (bestplan == NULL || curcost <= bestcost)
2250 {
2251 bestplan = curplan;
2252 bestcost = curcost;
2253 }
2254
2255 /* Also mark all subplans that are in AlternativeSubPlans */
2256 root->isAltSubplan[curplan->plan_id - 1] = true;
2257 }
2258
2259 /* Mark the subplan we selected */
2260 root->isUsedSubplan[bestplan->plan_id - 1] = true;
2261
2262 return (Node *) bestplan;
2263}
2264
2265/*
2266 * fix_scan_expr
2267 * Do set_plan_references processing on a scan-level expression
2268 *
2269 * This consists of incrementing all Vars' varnos by rtoffset,
2270 * replacing PARAM_MULTIEXPR Params, expanding PlaceHolderVars,
2271 * replacing Aggref nodes that should be replaced by initplan output Params,
2272 * choosing the best implementation for AlternativeSubPlans,
2273 * looking up operator opcode info for OpExpr and related nodes,
2274 * and adding OIDs from regclass Const nodes into root->glob->relationOids.
2275 *
2276 * 'node': the expression to be modified
2277 * 'rtoffset': how much to increment varnos by
2278 * 'num_exec': estimated number of executions of expression
2279 *
2280 * The expression tree is either copied-and-modified, or modified in-place
2281 * if that seems safe.
2282 */
2283static Node *
2284fix_scan_expr(PlannerInfo *root, Node *node, int rtoffset, double num_exec)
2285{
2286 fix_scan_expr_context context;
2287
2288 context.root = root;
2289 context.rtoffset = rtoffset;
2290 context.num_exec = num_exec;
2291
2292 if (rtoffset != 0 ||
2293 root->multiexpr_params != NIL ||
2294 root->glob->lastPHId != 0 ||
2295 root->minmax_aggs != NIL ||
2296 root->hasAlternativeSubPlans)
2297 {
2298 return fix_scan_expr_mutator(node, &context);
2299 }
2300 else
2301 {
2302 /*
2303 * If rtoffset == 0, we don't need to change any Vars, and if there
2304 * are no MULTIEXPR subqueries then we don't need to replace
2305 * PARAM_MULTIEXPR Params, and if there are no placeholders anywhere
2306 * we won't need to remove them, and if there are no minmax Aggrefs we
2307 * won't need to replace them, and if there are no AlternativeSubPlans
2308 * we won't need to remove them. Then it's OK to just scribble on the
2309 * input node tree instead of copying (since the only change, filling
2310 * in any unset opfuncid fields, is harmless). This saves just enough
2311 * cycles to be noticeable on trivial queries.
2312 */
2313 (void) fix_scan_expr_walker(node, &context);
2314 return node;
2315 }
2316}
2317
2318static Node *
2319fix_scan_expr_mutator(Node *node, fix_scan_expr_context *context)
2320{
2321 if (node == NULL)
2322 return NULL;
2323 if (IsA(node, Var))
2324 {
2325 Var *var = copyVar((Var *) node);
2326
2327 Assert(var->varlevelsup == 0);
2328
2329 /*
2330 * We should not see Vars marked INNER_VAR, OUTER_VAR, or ROWID_VAR.
2331 * But an indexqual expression could contain INDEX_VAR Vars.
2332 */
2333 Assert(var->varno != INNER_VAR);
2334 Assert(var->varno != OUTER_VAR);
2335 Assert(var->varno != ROWID_VAR);
2336 if (!IS_SPECIAL_VARNO(var->varno))
2337 var->varno += context->rtoffset;
2338 if (var->varnosyn > 0)
2339 var->varnosyn += context->rtoffset;
2340 return (Node *) var;
2341 }
2342 if (IsA(node, Param))
2343 return fix_param_node(context->root, (Param *) node);
2344 if (IsA(node, Aggref))
2345 {
2346 Aggref *aggref = (Aggref *) node;
2347 Param *aggparam;
2348
2349 /* See if the Aggref should be replaced by a Param */
2350 aggparam = find_minmax_agg_replacement_param(context->root, aggref);
2351 if (aggparam != NULL)
2352 {
2353 /* Make a copy of the Param for paranoia's sake */
2354 return (Node *) copyObject(aggparam);
2355 }
2356 /* If no match, just fall through to process it normally */
2357 }
2358 if (IsA(node, CurrentOfExpr))
2359 {
2360 CurrentOfExpr *cexpr = (CurrentOfExpr *) copyObject(node);
2361
2362 Assert(!IS_SPECIAL_VARNO(cexpr->cvarno));
2363 cexpr->cvarno += context->rtoffset;
2364 return (Node *) cexpr;
2365 }
2366 if (IsA(node, PlaceHolderVar))
2367 {
2368 /* At scan level, we should always just evaluate the contained expr */
2369 PlaceHolderVar *phv = (PlaceHolderVar *) node;
2370
2371 /* XXX can we assert something about phnullingrels? */
2372 return fix_scan_expr_mutator((Node *) phv->phexpr, context);
2373 }
2374 if (IsA(node, AlternativeSubPlan))
2375 return fix_scan_expr_mutator(fix_alternative_subplan(context->root,
2376 (AlternativeSubPlan *) node,
2377 context->num_exec),
2378 context);
2379 fix_expr_common(context->root, node);
2380 return expression_tree_mutator(node, fix_scan_expr_mutator, context);
2381}
2382
2383static bool
2384fix_scan_expr_walker(Node *node, fix_scan_expr_context *context)
2385{
2386 if (node == NULL)
2387 return false;
2388 Assert(!(IsA(node, Var) && ((Var *) node)->varno == ROWID_VAR));
2389 Assert(!IsA(node, PlaceHolderVar));
2390 Assert(!IsA(node, AlternativeSubPlan));
2391 fix_expr_common(context->root, node);
2392 return expression_tree_walker(node, fix_scan_expr_walker, context);
2393}
2394
2395/*
2396 * set_join_references
2397 * Modify the target list and quals of a join node to reference its
2398 * subplans, by setting the varnos to OUTER_VAR or INNER_VAR and setting
2399 * attno values to the result domain number of either the corresponding
2400 * outer or inner join tuple item. Also perform opcode lookup for these
2401 * expressions, and add regclass OIDs to root->glob->relationOids.
2402 */
2403static void
2404set_join_references(PlannerInfo *root, Join *join, int rtoffset)
2405{
2406 Plan *outer_plan = join->plan.lefttree;
2407 Plan *inner_plan = join->plan.righttree;
2408 indexed_tlist *outer_itlist;
2409 indexed_tlist *inner_itlist;
2410
2411 outer_itlist = build_tlist_index(outer_plan->targetlist);
2412 inner_itlist = build_tlist_index(inner_plan->targetlist);
2413
2414 /*
2415 * First process the joinquals (including merge or hash clauses). These
2416 * are logically below the join so they can always use all values
2417 * available from the input tlists. It's okay to also handle
2418 * NestLoopParams now, because those couldn't refer to nullable
2419 * subexpressions.
2420 */
2421 join->joinqual = fix_join_expr(root,
2422 join->joinqual,
2423 outer_itlist,
2424 inner_itlist,
2425 (Index) 0,
2426 rtoffset,
2427 NRM_EQUAL,
2428 NUM_EXEC_QUAL((Plan *) join));
2429
2430 /* Now do join-type-specific stuff */
2431 if (IsA(join, NestLoop))
2432 {
2433 NestLoop *nl = (NestLoop *) join;
2434 ListCell *lc;
2435
2436 foreach(lc, nl->nestParams)
2437 {
2438 NestLoopParam *nlp = (NestLoopParam *) lfirst(lc);
2439
2440 /*
2441 * Because we don't reparameterize parameterized paths to match
2442 * the outer-join level at which they are used, Vars seen in the
2443 * NestLoopParam expression may have nullingrels that are just a
2444 * subset of those in the Vars actually available from the outer
2445 * side. (Lateral references can also cause this, as explained in
2446 * the comments for identify_current_nestloop_params.) Not
2447 * checking this exactly is a bit grotty, but the work needed to
2448 * make things match up perfectly seems well out of proportion to
2449 * the value.
2450 */
2451 nlp->paramval = (Var *) fix_upper_expr(root,
2452 (Node *) nlp->paramval,
2453 outer_itlist,
2454 OUTER_VAR,
2455 rtoffset,
2456 NRM_SUBSET,
2457 NUM_EXEC_TLIST(outer_plan));
2458 /* Check we replaced any PlaceHolderVar with simple Var */
2459 if (!(IsA(nlp->paramval, Var) &&
2460 nlp->paramval->varno == OUTER_VAR))
2461 elog(ERROR, "NestLoopParam was not reduced to a simple Var");
2462 }
2463 }
2464 else if (IsA(join, MergeJoin))
2465 {
2466 MergeJoin *mj = (MergeJoin *) join;
2467
2468 mj->mergeclauses = fix_join_expr(root,
2469 mj->mergeclauses,
2470 outer_itlist,
2471 inner_itlist,
2472 (Index) 0,
2473 rtoffset,
2474 NRM_EQUAL,
2475 NUM_EXEC_QUAL((Plan *) join));
2476 }
2477 else if (IsA(join, HashJoin))
2478 {
2479 HashJoin *hj = (HashJoin *) join;
2480
2481 hj->hashclauses = fix_join_expr(root,
2482 hj->hashclauses,
2483 outer_itlist,
2484 inner_itlist,
2485 (Index) 0,
2486 rtoffset,
2487 NRM_EQUAL,
2488 NUM_EXEC_QUAL((Plan *) join));
2489
2490 /*
2491 * HashJoin's hashkeys are used to look for matching tuples from its
2492 * outer plan (not the Hash node!) in the hashtable.
2493 */
2494 hj->hashkeys = (List *) fix_upper_expr(root,
2495 (Node *) hj->hashkeys,
2496 outer_itlist,
2497 OUTER_VAR,
2498 rtoffset,
2499 NRM_EQUAL,
2500 NUM_EXEC_QUAL((Plan *) join));
2501 }
2502
2503 /*
2504 * Now we need to fix up the targetlist and qpqual, which are logically
2505 * above the join. This means that, if it's not an inner join, any Vars
2506 * and PHVs appearing here should have nullingrels that include the
2507 * effects of the outer join, ie they will have nullingrels equal to the
2508 * input Vars' nullingrels plus the bit added by the outer join. We don't
2509 * currently have enough info available here to identify what that should
2510 * be, so we just tell fix_join_expr to accept superset nullingrels
2511 * matches instead of exact ones.
2512 */
2513 join->plan.targetlist = fix_join_expr(root,
2514 join->plan.targetlist,
2515 outer_itlist,
2516 inner_itlist,
2517 (Index) 0,
2518 rtoffset,
2519 (join->jointype == JOIN_INNER ? NRM_EQUAL : NRM_SUPERSET),
2520 NUM_EXEC_TLIST((Plan *) join));
2521 join->plan.qual = fix_join_expr(root,
2522 join->plan.qual,
2523 outer_itlist,
2524 inner_itlist,
2525 (Index) 0,
2526 rtoffset,
2527 (join->jointype == JOIN_INNER ? NRM_EQUAL : NRM_SUPERSET),
2528 NUM_EXEC_QUAL((Plan *) join));
2529
2530 pfree(outer_itlist);
2531 pfree(inner_itlist);
2532}
2533
2534/*
2535 * set_upper_references
2536 * Update the targetlist and quals of an upper-level plan node
2537 * to refer to the tuples returned by its lefttree subplan.
2538 * Also perform opcode lookup for these expressions, and
2539 * add regclass OIDs to root->glob->relationOids.
2540 *
2541 * This is used for single-input plan types like Agg, Group, Result.
2542 *
2543 * In most cases, we have to match up individual Vars in the tlist and
2544 * qual expressions with elements of the subplan's tlist (which was
2545 * generated by flattening these selfsame expressions, so it should have all
2546 * the required variables). There is an important exception, however:
2547 * depending on where we are in the plan tree, sort/group columns may have
2548 * been pushed into the subplan tlist unflattened. If these values are also
2549 * needed in the output then we want to reference the subplan tlist element
2550 * rather than recomputing the expression.
2551 */
2552static void
2553set_upper_references(PlannerInfo *root, Plan *plan, int rtoffset)
2554{
2555 Plan *subplan = plan->lefttree;
2556 indexed_tlist *subplan_itlist;
2557 List *output_targetlist;
2558 ListCell *l;
2559
2560 subplan_itlist = build_tlist_index(subplan->targetlist);
2561
2562 /*
2563 * If it's a grouping node with grouping sets, any Vars and PHVs appearing
2564 * in the targetlist and quals should have nullingrels that include the
2565 * effects of the grouping step, ie they will have nullingrels equal to
2566 * the input Vars/PHVs' nullingrels plus the RT index of the grouping
2567 * step. In order to perform exact nullingrels matches, we remove the RT
2568 * index of the grouping step first.
2569 */
2570 if (IsA(plan, Agg) &&
2571 root->group_rtindex > 0 &&
2572 ((Agg *) plan)->groupingSets)
2573 {
2574 plan->targetlist = (List *)
2575 remove_nulling_relids((Node *) plan->targetlist,
2576 bms_make_singleton(root->group_rtindex),
2577 NULL);
2578 plan->qual = (List *)
2579 remove_nulling_relids((Node *) plan->qual,
2580 bms_make_singleton(root->group_rtindex),
2581 NULL);
2582 }
2583
2584 output_targetlist = NIL;
2585 foreach(l, plan->targetlist)
2586 {
2587 TargetEntry *tle = (TargetEntry *) lfirst(l);
2588 Node *newexpr;
2589
2590 /* If it's a sort/group item, first try to match by sortref */
2591 if (tle->ressortgroupref != 0)
2592 {
2593 newexpr = (Node *)
2594 search_indexed_tlist_for_sortgroupref(tle->expr,
2595 tle->ressortgroupref,
2596 subplan_itlist,
2597 OUTER_VAR);
2598 if (!newexpr)
2599 newexpr = fix_upper_expr(root,
2600 (Node *) tle->expr,
2601 subplan_itlist,
2602 OUTER_VAR,
2603 rtoffset,
2604 NRM_EQUAL,
2605 NUM_EXEC_TLIST(plan));
2606 }
2607 else
2608 newexpr = fix_upper_expr(root,
2609 (Node *) tle->expr,
2610 subplan_itlist,
2611 OUTER_VAR,
2612 rtoffset,
2613 NRM_EQUAL,
2614 NUM_EXEC_TLIST(plan));
2615 tle = flatCopyTargetEntry(tle);
2616 tle->expr = (Expr *) newexpr;
2617 output_targetlist = lappend(output_targetlist, tle);
2618 }
2619 plan->targetlist = output_targetlist;
2620
2621 plan->qual = (List *)
2622 fix_upper_expr(root,
2623 (Node *) plan->qual,
2624 subplan_itlist,
2625 OUTER_VAR,
2626 rtoffset,
2627 NRM_EQUAL,
2628 NUM_EXEC_QUAL(plan));
2629
2630 pfree(subplan_itlist);
2631}
2632
2633/*
2634 * set_param_references
2635 * Initialize the initParam list in Gather or Gather merge node such that
2636 * it contains reference of all the params that needs to be evaluated
2637 * before execution of the node. It contains the initplan params that are
2638 * being passed to the plan nodes below it.
2639 */
2640static void
2641set_param_references(PlannerInfo *root, Plan *plan)
2642{
2643 Assert(IsA(plan, Gather) || IsA(plan, GatherMerge));
2644
2645 if (plan->lefttree->extParam)
2646 {
2647 PlannerInfo *proot;
2648 Bitmapset *initSetParam = NULL;
2649 ListCell *l;
2650
2651 for (proot = root; proot != NULL; proot = proot->parent_root)
2652 {
2653 foreach(l, proot->init_plans)
2654 {
2655 SubPlan *initsubplan = (SubPlan *) lfirst(l);
2656 ListCell *l2;
2657
2658 foreach(l2, initsubplan->setParam)
2659 {
2660 initSetParam = bms_add_member(initSetParam, lfirst_int(l2));
2661 }
2662 }
2663 }
2664
2665 /*
2666 * Remember the list of all external initplan params that are used by
2667 * the children of Gather or Gather merge node.
2668 */
2669 if (IsA(plan, Gather))
2670 ((Gather *) plan)->initParam =
2671 bms_intersect(plan->lefttree->extParam, initSetParam);
2672 else
2673 ((GatherMerge *) plan)->initParam =
2674 bms_intersect(plan->lefttree->extParam, initSetParam);
2675 }
2676}
2677
2678/*
2679 * Recursively scan an expression tree and convert Aggrefs to the proper
2680 * intermediate form for combining aggregates. This means (1) replacing each
2681 * one's argument list with a single argument that is the original Aggref
2682 * modified to show partial aggregation and (2) changing the upper Aggref to
2683 * show combining aggregation.
2684 *
2685 * After this step, set_upper_references will replace the partial Aggrefs
2686 * with Vars referencing the lower Agg plan node's outputs, so that the final
2687 * form seen by the executor is a combining Aggref with a Var as input.
2688 *
2689 * It's rather messy to postpone this step until setrefs.c; ideally it'd be
2690 * done in createplan.c. The difficulty is that once we modify the Aggref
2691 * expressions, they will no longer be equal() to their original form and
2692 * so cross-plan-node-level matches will fail. So this has to happen after
2693 * the plan node above the Agg has resolved its subplan references.
2694 */
2695static Node *
2696convert_combining_aggrefs(Node *node, void *context)
2697{
2698 if (node == NULL)
2699 return NULL;
2700 if (IsA(node, Aggref))
2701 {
2702 Aggref *orig_agg = (Aggref *) node;
2703 Aggref *child_agg;
2704 Aggref *parent_agg;
2705
2706 /* Assert we've not chosen to partial-ize any unsupported cases */
2707 Assert(orig_agg->aggorder == NIL);
2708 Assert(orig_agg->aggdistinct == NIL);
2709
2710 /*
2711 * Since aggregate calls can't be nested, we needn't recurse into the
2712 * arguments. But for safety, flat-copy the Aggref node itself rather
2713 * than modifying it in-place.
2714 */
2715 child_agg = makeNode(Aggref);
2716 memcpy(child_agg, orig_agg, sizeof(Aggref));
2717
2718 /*
2719 * For the parent Aggref, we want to copy all the fields of the
2720 * original aggregate *except* the args list, which we'll replace
2721 * below, and the aggfilter expression, which should be applied only
2722 * by the child not the parent. Rather than explicitly knowing about
2723 * all the other fields here, we can momentarily modify child_agg to
2724 * provide a suitable source for copyObject.
2725 */
2726 child_agg->args = NIL;
2727 child_agg->aggfilter = NULL;
2728 parent_agg = copyObject(child_agg);
2729 child_agg->args = orig_agg->args;
2730 child_agg->aggfilter = orig_agg->aggfilter;
2731
2732 /*
2733 * Now, set up child_agg to represent the first phase of partial
2734 * aggregation. For now, assume serialization is required.
2735 */
2736 mark_partial_aggref(child_agg, AGGSPLIT_INITIAL_SERIAL);
2737
2738 /*
2739 * And set up parent_agg to represent the second phase.
2740 */
2741 parent_agg->args = list_make1(makeTargetEntry((Expr *) child_agg,
2742 1, NULL, false));
2743 mark_partial_aggref(parent_agg, AGGSPLIT_FINAL_DESERIAL);
2744
2745 return (Node *) parent_agg;
2746 }
2747 return expression_tree_mutator(node, convert_combining_aggrefs, context);
2748}
2749
2750/*
2751 * set_dummy_tlist_references
2752 * Replace the targetlist of an upper-level plan node with a simple
2753 * list of OUTER_VAR references to its child.
2754 *
2755 * This is used for plan types like Sort and Append that don't evaluate
2756 * their targetlists. Although the executor doesn't care at all what's in
2757 * the tlist, EXPLAIN needs it to be realistic.
2758 *
2759 * Note: we could almost use set_upper_references() here, but it fails for
2760 * Append for lack of a lefttree subplan. Single-purpose code is faster
2761 * anyway.
2762 */
2763static void
2764set_dummy_tlist_references(Plan *plan, int rtoffset)
2765{
2766 List *output_targetlist;
2767 ListCell *l;
2768
2769 output_targetlist = NIL;
2770 foreach(l, plan->targetlist)
2771 {
2772 TargetEntry *tle = (TargetEntry *) lfirst(l);
2773 Var *oldvar = (Var *) tle->expr;
2774 Var *newvar;
2775
2776 /*
2777 * As in search_indexed_tlist_for_non_var(), we prefer to keep Consts
2778 * as Consts, not Vars referencing Consts. Here, there's no speed
2779 * advantage to be had, but it makes EXPLAIN output look cleaner, and
2780 * again it avoids confusing the executor.
2781 */
2782 if (IsA(oldvar, Const))
2783 {
2784 /* just reuse the existing TLE node */
2785 output_targetlist = lappend(output_targetlist, tle);
2786 continue;
2787 }
2788
2789 newvar = makeVar(OUTER_VAR,
2790 tle->resno,
2791 exprType((Node *) oldvar),
2792 exprTypmod((Node *) oldvar),
2793 exprCollation((Node *) oldvar),
2794 0);
2795 if (IsA(oldvar, Var) &&
2796 oldvar->varnosyn > 0)
2797 {
2798 newvar->varnosyn = oldvar->varnosyn + rtoffset;
2799 newvar->varattnosyn = oldvar->varattnosyn;
2800 }
2801 else
2802 {
2803 newvar->varnosyn = 0; /* wasn't ever a plain Var */
2804 newvar->varattnosyn = 0;
2805 }
2806
2807 tle = flatCopyTargetEntry(tle);
2808 tle->expr = (Expr *) newvar;
2809 output_targetlist = lappend(output_targetlist, tle);
2810 }
2811 plan->targetlist = output_targetlist;
2812
2813 /* We don't touch plan->qual here */
2814}
2815
2816
2817/*
2818 * build_tlist_index --- build an index data structure for a child tlist
2819 *
2820 * In most cases, subplan tlists will be "flat" tlists with only Vars,
2821 * so we try to optimize that case by extracting information about Vars
2822 * in advance. Matching a parent tlist to a child is still an O(N^2)
2823 * operation, but at least with a much smaller constant factor than plain
2824 * tlist_member() searches.
2825 *
2826 * The result of this function is an indexed_tlist struct to pass to
2827 * search_indexed_tlist_for_var() and siblings.
2828 * When done, the indexed_tlist may be freed with a single pfree().
2829 */
2830static indexed_tlist *
2831build_tlist_index(List *tlist)
2832{
2833 indexed_tlist *itlist;
2834 tlist_vinfo *vinfo;
2835 ListCell *l;
2836
2837 /* Create data structure with enough slots for all tlist entries */
2838 itlist = (indexed_tlist *)
2839 palloc(offsetof(indexed_tlist, vars) +
2840 list_length(tlist) * sizeof(tlist_vinfo));
2841
2842 itlist->tlist = tlist;
2843 itlist->has_ph_vars = false;
2844 itlist->has_non_vars = false;
2845
2846 /* Find the Vars and fill in the index array */
2847 vinfo = itlist->vars;
2848 foreach(l, tlist)
2849 {
2850 TargetEntry *tle = (TargetEntry *) lfirst(l);
2851
2852 if (tle->expr && IsA(tle->expr, Var))
2853 {
2854 Var *var = (Var *) tle->expr;
2855
2856 vinfo->varno = var->varno;
2857 vinfo->varattno = var->varattno;
2858 vinfo->resno = tle->resno;
2859 vinfo->varnullingrels = var->varnullingrels;
2860 vinfo++;
2861 }
2862 else if (tle->expr && IsA(tle->expr, PlaceHolderVar))
2863 itlist->has_ph_vars = true;
2864 else
2865 itlist->has_non_vars = true;
2866 }
2867
2868 itlist->num_vars = (vinfo - itlist->vars);
2869
2870 return itlist;
2871}
2872
2873/*
2874 * build_tlist_index_other_vars --- build a restricted tlist index
2875 *
2876 * This is like build_tlist_index, but we only index tlist entries that
2877 * are Vars belonging to some rel other than the one specified. We will set
2878 * has_ph_vars (allowing PlaceHolderVars to be matched), but not has_non_vars
2879 * (so nothing other than Vars and PlaceHolderVars can be matched).
2880 */
2881static indexed_tlist *
2882build_tlist_index_other_vars(List *tlist, int ignore_rel)
2883{
2884 indexed_tlist *itlist;
2885 tlist_vinfo *vinfo;
2886 ListCell *l;
2887
2888 /* Create data structure with enough slots for all tlist entries */
2889 itlist = (indexed_tlist *)
2890 palloc(offsetof(indexed_tlist, vars) +
2891 list_length(tlist) * sizeof(tlist_vinfo));
2892
2893 itlist->tlist = tlist;
2894 itlist->has_ph_vars = false;
2895 itlist->has_non_vars = false;
2896
2897 /* Find the desired Vars and fill in the index array */
2898 vinfo = itlist->vars;
2899 foreach(l, tlist)
2900 {
2901 TargetEntry *tle = (TargetEntry *) lfirst(l);
2902
2903 if (tle->expr && IsA(tle->expr, Var))
2904 {
2905 Var *var = (Var *) tle->expr;
2906
2907 if (var->varno != ignore_rel)
2908 {
2909 vinfo->varno = var->varno;
2910 vinfo->varattno = var->varattno;
2911 vinfo->resno = tle->resno;
2912 vinfo->varnullingrels = var->varnullingrels;
2913 vinfo++;
2914 }
2915 }
2916 else if (tle->expr && IsA(tle->expr, PlaceHolderVar))
2917 itlist->has_ph_vars = true;
2918 }
2919
2920 itlist->num_vars = (vinfo - itlist->vars);
2921
2922 return itlist;
2923}
2924
2925/*
2926 * search_indexed_tlist_for_var --- find a Var in an indexed tlist
2927 *
2928 * If a match is found, return a copy of the given Var with suitably
2929 * modified varno/varattno (to wit, newvarno and the resno of the TLE entry).
2930 * Also ensure that varnosyn is incremented by rtoffset.
2931 * If no match, return NULL.
2932 *
2933 * We cross-check the varnullingrels of the subplan output Var based on
2934 * nrm_match. Most call sites should pass NRM_EQUAL indicating we expect
2935 * an exact match. However, there are places where we haven't cleaned
2936 * things up completely, and we have to settle for allowing subset or
2937 * superset matches.
2938 */
2939static Var *
2940search_indexed_tlist_for_var(Var *var, indexed_tlist *itlist,
2941 int newvarno, int rtoffset,
2942 NullingRelsMatch nrm_match)
2943{
2944 int varno = var->varno;
2945 AttrNumber varattno = var->varattno;
2946 tlist_vinfo *vinfo;
2947 int i;
2948
2949 vinfo = itlist->vars;
2950 i = itlist->num_vars;
2951 while (i-- > 0)
2952 {
2953 if (vinfo->varno == varno && vinfo->varattno == varattno)
2954 {
2955 /* Found a match */
2956 Var *newvar = copyVar(var);
2957
2958 /*
2959 * Verify that we kept all the nullingrels machinations straight.
2960 *
2961 * XXX we skip the check for system columns and whole-row Vars.
2962 * That's because such Vars might be row identity Vars, which are
2963 * generated without any varnullingrels. It'd be hard to do
2964 * otherwise, since they're normally made very early in planning,
2965 * when we haven't looked at the jointree yet and don't know which
2966 * joins might null such Vars. Doesn't seem worth the expense to
2967 * make them fully valid. (While it's slightly annoying that we
2968 * thereby lose checking for user-written references to such
2969 * columns, it seems unlikely that a bug in nullingrels logic
2970 * would affect only system columns.)
2971 */
2972 if (!(varattno <= 0 ||
2973 (nrm_match == NRM_SUBSET ?
2974 bms_is_subset(var->varnullingrels, vinfo->varnullingrels) :
2975 nrm_match == NRM_SUPERSET ?
2976 bms_is_subset(vinfo->varnullingrels, var->varnullingrels) :
2977 bms_equal(vinfo->varnullingrels, var->varnullingrels))))
2978 elog(ERROR, "wrong varnullingrels %s (expected %s) for Var %d/%d",
2979 bmsToString(var->varnullingrels),
2980 bmsToString(vinfo->varnullingrels),
2981 varno, varattno);
2982
2983 newvar->varno = newvarno;
2984 newvar->varattno = vinfo->resno;
2985 if (newvar->varnosyn > 0)
2986 newvar->varnosyn += rtoffset;
2987 return newvar;
2988 }
2989 vinfo++;
2990 }
2991 return NULL; /* no match */
2992}
2993
2994/*
2995 * search_indexed_tlist_for_phv --- find a PlaceHolderVar in an indexed tlist
2996 *
2997 * If a match is found, return a Var constructed to reference the tlist item.
2998 * If no match, return NULL.
2999 *
3000 * Cross-check phnullingrels as in search_indexed_tlist_for_var.
3001 *
3002 * NOTE: it is a waste of time to call this unless itlist->has_ph_vars.
3003 */
3004static Var *
3005search_indexed_tlist_for_phv(PlaceHolderVar *phv,
3006 indexed_tlist *itlist, int newvarno,
3007 NullingRelsMatch nrm_match)
3008{
3009 ListCell *lc;
3010
3011 foreach(lc, itlist->tlist)
3012 {
3013 TargetEntry *tle = (TargetEntry *) lfirst(lc);
3014
3015 if (tle->expr && IsA(tle->expr, PlaceHolderVar))
3016 {
3017 PlaceHolderVar *subphv = (PlaceHolderVar *) tle->expr;
3018 Var *newvar;
3019
3020 /*
3021 * Analogously to search_indexed_tlist_for_var, we match on phid
3022 * only. We don't use equal(), partially for speed but mostly
3023 * because phnullingrels might not be exactly equal.
3024 */
3025 if (phv->phid != subphv->phid)
3026 continue;
3027
3028 /* Verify that we kept all the nullingrels machinations straight */
3029 if (!(nrm_match == NRM_SUBSET ?
3030 bms_is_subset(phv->phnullingrels, subphv->phnullingrels) :
3031 nrm_match == NRM_SUPERSET ?
3032 bms_is_subset(subphv->phnullingrels, phv->phnullingrels) :
3033 bms_equal(subphv->phnullingrels, phv->phnullingrels)))
3034 elog(ERROR, "wrong phnullingrels %s (expected %s) for PlaceHolderVar %d",
3035 bmsToString(phv->phnullingrels),
3036 bmsToString(subphv->phnullingrels),
3037 phv->phid);
3038
3039 /* Found a matching subplan output expression */
3040 newvar = makeVarFromTargetEntry(newvarno, tle);
3041 newvar->varnosyn = 0; /* wasn't ever a plain Var */
3042 newvar->varattnosyn = 0;
3043 return newvar;
3044 }
3045 }
3046 return NULL; /* no match */
3047}
3048
3049/*
3050 * search_indexed_tlist_for_non_var --- find a non-Var/PHV in an indexed tlist
3051 *
3052 * If a match is found, return a Var constructed to reference the tlist item.
3053 * If no match, return NULL.
3054 *
3055 * NOTE: it is a waste of time to call this unless itlist->has_non_vars.
3056 */
3057static Var *
3058search_indexed_tlist_for_non_var(Expr *node,
3059 indexed_tlist *itlist, int newvarno)
3060{
3061 TargetEntry *tle;
3062
3063 /*
3064 * If it's a simple Const, replacing it with a Var is silly, even if there
3065 * happens to be an identical Const below; a Var is more expensive to
3066 * execute than a Const. What's more, replacing it could confuse some
3067 * places in the executor that expect to see simple Consts for, eg,
3068 * dropped columns.
3069 */
3070 if (IsA(node, Const))
3071 return NULL;
3072
3073 tle = tlist_member(node, itlist->tlist);
3074 if (tle)
3075 {
3076 /* Found a matching subplan output expression */
3077 Var *newvar;
3078
3079 newvar = makeVarFromTargetEntry(newvarno, tle);
3080 newvar->varnosyn = 0; /* wasn't ever a plain Var */
3081 newvar->varattnosyn = 0;
3082 return newvar;
3083 }
3084 return NULL; /* no match */
3085}
3086
3087/*
3088 * search_indexed_tlist_for_sortgroupref --- find a sort/group expression
3089 *
3090 * If a match is found, return a Var constructed to reference the tlist item.
3091 * If no match, return NULL.
3092 *
3093 * This is needed to ensure that we select the right subplan TLE in cases
3094 * where there are multiple textually-equal()-but-volatile sort expressions.
3095 * And it's also faster than search_indexed_tlist_for_non_var.
3096 */
3097static Var *
3098search_indexed_tlist_for_sortgroupref(Expr *node,
3099 Index sortgroupref,
3100 indexed_tlist *itlist,
3101 int newvarno)
3102{
3103 ListCell *lc;
3104
3105 foreach(lc, itlist->tlist)
3106 {
3107 TargetEntry *tle = (TargetEntry *) lfirst(lc);
3108
3109 /*
3110 * Usually the equal() check is redundant, but in setop plans it may
3111 * not be, since prepunion.c assigns ressortgroupref equal to the
3112 * column resno without regard to whether that matches the topmost
3113 * level's sortgrouprefs and without regard to whether any implicit
3114 * coercions are added in the setop tree. We might have to clean that
3115 * up someday; but for now, just ignore any false matches.
3116 */
3117 if (tle->ressortgroupref == sortgroupref &&
3118 equal(node, tle->expr))
3119 {
3120 /* Found a matching subplan output expression */
3121 Var *newvar;
3122
3123 newvar = makeVarFromTargetEntry(newvarno, tle);
3124 newvar->varnosyn = 0; /* wasn't ever a plain Var */
3125 newvar->varattnosyn = 0;
3126 return newvar;
3127 }
3128 }
3129 return NULL; /* no match */
3130}
3131
3132/*
3133 * fix_join_expr
3134 * Create a new set of targetlist entries or join qual clauses by
3135 * changing the varno/varattno values of variables in the clauses
3136 * to reference target list values from the outer and inner join
3137 * relation target lists. Also perform opcode lookup and add
3138 * regclass OIDs to root->glob->relationOids.
3139 *
3140 * This is used in four different scenarios:
3141 * 1) a normal join clause, where all the Vars in the clause *must* be
3142 * replaced by OUTER_VAR or INNER_VAR references. In this case
3143 * acceptable_rel should be zero so that any failure to match a Var will be
3144 * reported as an error.
3145 * 2) RETURNING clauses, which may contain both Vars of the target relation
3146 * and Vars of other relations. In this case we want to replace the
3147 * other-relation Vars by OUTER_VAR references, while leaving target Vars
3148 * alone. Thus inner_itlist = NULL and acceptable_rel = the ID of the
3149 * target relation should be passed.
3150 * 3) ON CONFLICT SET and WHERE clauses. Here references to EXCLUDED are
3151 * to be replaced with INNER_VAR references, while leaving target Vars (the
3152 * to-be-updated relation) alone. Correspondingly inner_itlist is to be
3153 * EXCLUDED elements, outer_itlist = NULL and acceptable_rel the target
3154 * relation.
3155 * 4) MERGE. In this case, references to the source relation are to be
3156 * replaced with INNER_VAR references, leaving Vars of the target
3157 * relation (the to-be-modified relation) alone. So inner_itlist is to be
3158 * the source relation elements, outer_itlist = NULL and acceptable_rel
3159 * the target relation.
3160 *
3161 * 'clauses' is the targetlist or list of join clauses
3162 * 'outer_itlist' is the indexed target list of the outer join relation,
3163 * or NULL
3164 * 'inner_itlist' is the indexed target list of the inner join relation,
3165 * or NULL
3166 * 'acceptable_rel' is either zero or the rangetable index of a relation
3167 * whose Vars may appear in the clause without provoking an error
3168 * 'rtoffset': how much to increment varnos by
3169 * 'nrm_match': as for search_indexed_tlist_for_var()
3170 * 'num_exec': estimated number of executions of expression
3171 *
3172 * Returns the new expression tree. The original clause structure is
3173 * not modified.
3174 */
3175static List *
3176fix_join_expr(PlannerInfo *root,
3177 List *clauses,
3178 indexed_tlist *outer_itlist,
3179 indexed_tlist *inner_itlist,
3180 Index acceptable_rel,
3181 int rtoffset,
3182 NullingRelsMatch nrm_match,
3183 double num_exec)
3184{
3185 fix_join_expr_context context;
3186
3187 context.root = root;
3188 context.outer_itlist = outer_itlist;
3189 context.inner_itlist = inner_itlist;
3190 context.acceptable_rel = acceptable_rel;
3191 context.rtoffset = rtoffset;
3192 context.nrm_match = nrm_match;
3193 context.num_exec = num_exec;
3194 return (List *) fix_join_expr_mutator((Node *) clauses, &context);
3195}
3196
3197static Node *
3198fix_join_expr_mutator(Node *node, fix_join_expr_context *context)
3199{
3200 Var *newvar;
3201
3202 if (node == NULL)
3203 return NULL;
3204 if (IsA(node, Var))
3205 {
3206 Var *var = (Var *) node;
3207
3208 /*
3209 * Verify that Vars with non-default varreturningtype only appear in
3210 * the RETURNING list, and refer to the target relation.
3211 */
3212 if (var->varreturningtype != VAR_RETURNING_DEFAULT)
3213 {
3214 if (context->inner_itlist != NULL ||
3215 context->outer_itlist == NULL ||
3216 context->acceptable_rel == 0)
3217 elog(ERROR, "variable returning old/new found outside RETURNING list");
3218 if (var->varno != context->acceptable_rel)
3219 elog(ERROR, "wrong varno %d (expected %d) for variable returning old/new",
3220 var->varno, context->acceptable_rel);
3221 }
3222
3223 /* Look for the var in the input tlists, first in the outer */
3224 if (context->outer_itlist)
3225 {
3226 newvar = search_indexed_tlist_for_var(var,
3227 context->outer_itlist,
3228 OUTER_VAR,
3229 context->rtoffset,
3230 context->nrm_match);
3231 if (newvar)
3232 return (Node *) newvar;
3233 }
3234
3235 /* then in the inner. */
3236 if (context->inner_itlist)
3237 {
3238 newvar = search_indexed_tlist_for_var(var,
3239 context->inner_itlist,
3240 INNER_VAR,
3241 context->rtoffset,
3242 context->nrm_match);
3243 if (newvar)
3244 return (Node *) newvar;
3245 }
3246
3247 /* If it's for acceptable_rel, adjust and return it */
3248 if (var->varno == context->acceptable_rel)
3249 {
3250 var = copyVar(var);
3251 var->varno += context->rtoffset;
3252 if (var->varnosyn > 0)
3253 var->varnosyn += context->rtoffset;
3254 return (Node *) var;
3255 }
3256
3257 /* No referent found for Var */
3258 elog(ERROR, "variable not found in subplan target lists");
3259 }
3260 if (IsA(node, PlaceHolderVar))
3261 {
3262 PlaceHolderVar *phv = (PlaceHolderVar *) node;
3263
3264 /* See if the PlaceHolderVar has bubbled up from a lower plan node */
3265 if (context->outer_itlist && context->outer_itlist->has_ph_vars)
3266 {
3267 newvar = search_indexed_tlist_for_phv(phv,
3268 context->outer_itlist,
3269 OUTER_VAR,
3270 context->nrm_match);
3271 if (newvar)
3272 return (Node *) newvar;
3273 }
3274 if (context->inner_itlist && context->inner_itlist->has_ph_vars)
3275 {
3276 newvar = search_indexed_tlist_for_phv(phv,
3277 context->inner_itlist,
3278 INNER_VAR,
3279 context->nrm_match);
3280 if (newvar)
3281 return (Node *) newvar;
3282 }
3283
3284 /* If not supplied by input plans, evaluate the contained expr */
3285 /* XXX can we assert something about phnullingrels? */
3286 return fix_join_expr_mutator((Node *) phv->phexpr, context);
3287 }
3288 /* Try matching more complex expressions too, if tlists have any */
3289 if (context->outer_itlist && context->outer_itlist->has_non_vars)
3290 {
3291 newvar = search_indexed_tlist_for_non_var((Expr *) node,
3292 context->outer_itlist,
3293 OUTER_VAR);
3294 if (newvar)
3295 return (Node *) newvar;
3296 }
3297 if (context->inner_itlist && context->inner_itlist->has_non_vars)
3298 {
3299 newvar = search_indexed_tlist_for_non_var((Expr *) node,
3300 context->inner_itlist,
3301 INNER_VAR);
3302 if (newvar)
3303 return (Node *) newvar;
3304 }
3305 /* Special cases (apply only AFTER failing to match to lower tlist) */
3306 if (IsA(node, Param))
3307 return fix_param_node(context->root, (Param *) node);
3308 if (IsA(node, AlternativeSubPlan))
3309 return fix_join_expr_mutator(fix_alternative_subplan(context->root,
3310 (AlternativeSubPlan *) node,
3311 context->num_exec),
3312 context);
3313 fix_expr_common(context->root, node);
3314 return expression_tree_mutator(node, fix_join_expr_mutator, context);
3315}
3316
3317/*
3318 * fix_upper_expr
3319 * Modifies an expression tree so that all Var nodes reference outputs
3320 * of a subplan. Also looks for Aggref nodes that should be replaced
3321 * by initplan output Params. Also performs opcode lookup, and adds
3322 * regclass OIDs to root->glob->relationOids.
3323 *
3324 * This is used to fix up target and qual expressions of non-join upper-level
3325 * plan nodes, as well as index-only scan nodes.
3326 *
3327 * An error is raised if no matching var can be found in the subplan tlist
3328 * --- so this routine should only be applied to nodes whose subplans'
3329 * targetlists were generated by flattening the expressions used in the
3330 * parent node.
3331 *
3332 * If itlist->has_non_vars is true, then we try to match whole subexpressions
3333 * against elements of the subplan tlist, so that we can avoid recomputing
3334 * expressions that were already computed by the subplan. (This is relatively
3335 * expensive, so we don't want to try it in the common case where the
3336 * subplan tlist is just a flattened list of Vars.)
3337 *
3338 * 'node': the tree to be fixed (a target item or qual)
3339 * 'subplan_itlist': indexed target list for subplan (or index)
3340 * 'newvarno': varno to use for Vars referencing tlist elements
3341 * 'rtoffset': how much to increment varnos by
3342 * 'nrm_match': as for search_indexed_tlist_for_var()
3343 * 'num_exec': estimated number of executions of expression
3344 *
3345 * The resulting tree is a copy of the original in which all Var nodes have
3346 * varno = newvarno, varattno = resno of corresponding targetlist element.
3347 * The original tree is not modified.
3348 */
3349static Node *
3350fix_upper_expr(PlannerInfo *root,
3351 Node *node,
3352 indexed_tlist *subplan_itlist,
3353 int newvarno,
3354 int rtoffset,
3355 NullingRelsMatch nrm_match,
3356 double num_exec)
3357{
3358 fix_upper_expr_context context;
3359
3360 context.root = root;
3361 context.subplan_itlist = subplan_itlist;
3362 context.newvarno = newvarno;
3363 context.rtoffset = rtoffset;
3364 context.nrm_match = nrm_match;
3365 context.num_exec = num_exec;
3366 return fix_upper_expr_mutator(node, &context);
3367}
3368
3369static Node *
3370fix_upper_expr_mutator(Node *node, fix_upper_expr_context *context)
3371{
3372 Var *newvar;
3373
3374 if (node == NULL)
3375 return NULL;
3376 if (IsA(node, Var))
3377 {
3378 Var *var = (Var *) node;
3379
3380 newvar = search_indexed_tlist_for_var(var,
3381 context->subplan_itlist,
3382 context->newvarno,
3383 context->rtoffset,
3384 context->nrm_match);
3385 if (!newvar)
3386 elog(ERROR, "variable not found in subplan target list");
3387 return (Node *) newvar;
3388 }
3389 if (IsA(node, PlaceHolderVar))
3390 {
3391 PlaceHolderVar *phv = (PlaceHolderVar *) node;
3392
3393 /* See if the PlaceHolderVar has bubbled up from a lower plan node */
3394 if (context->subplan_itlist->has_ph_vars)
3395 {
3396 newvar = search_indexed_tlist_for_phv(phv,
3397 context->subplan_itlist,
3398 context->newvarno,
3399 context->nrm_match);
3400 if (newvar)
3401 return (Node *) newvar;
3402 }
3403 /* If not supplied by input plan, evaluate the contained expr */
3404 /* XXX can we assert something about phnullingrels? */
3405 return fix_upper_expr_mutator((Node *) phv->phexpr, context);
3406 }
3407 /* Try matching more complex expressions too, if tlist has any */
3408 if (context->subplan_itlist->has_non_vars)
3409 {
3410 newvar = search_indexed_tlist_for_non_var((Expr *) node,
3411 context->subplan_itlist,
3412 context->newvarno);
3413 if (newvar)
3414 return (Node *) newvar;
3415 }
3416 /* Special cases (apply only AFTER failing to match to lower tlist) */
3417 if (IsA(node, Param))
3418 return fix_param_node(context->root, (Param *) node);
3419 if (IsA(node, Aggref))
3420 {
3421 Aggref *aggref = (Aggref *) node;
3422 Param *aggparam;
3423
3424 /* See if the Aggref should be replaced by a Param */
3425 aggparam = find_minmax_agg_replacement_param(context->root, aggref);
3426 if (aggparam != NULL)
3427 {
3428 /* Make a copy of the Param for paranoia's sake */
3429 return (Node *) copyObject(aggparam);
3430 }
3431 /* If no match, just fall through to process it normally */
3432 }
3433 if (IsA(node, AlternativeSubPlan))
3434 return fix_upper_expr_mutator(fix_alternative_subplan(context->root,
3435 (AlternativeSubPlan *) node,
3436 context->num_exec),
3437 context);
3438 fix_expr_common(context->root, node);
3439 return expression_tree_mutator(node, fix_upper_expr_mutator, context);
3440}
3441
3442/*
3443 * set_returning_clause_references
3444 * Perform setrefs.c's work on a RETURNING targetlist
3445 *
3446 * If the query involves more than just the result table, we have to
3447 * adjust any Vars that refer to other tables to reference junk tlist
3448 * entries in the top subplan's targetlist. Vars referencing the result
3449 * table should be left alone, however (the executor will evaluate them
3450 * using the actual heap tuple, after firing triggers if any). In the
3451 * adjusted RETURNING list, result-table Vars will have their original
3452 * varno (plus rtoffset), but Vars for other rels will have varno OUTER_VAR.
3453 *
3454 * We also must perform opcode lookup and add regclass OIDs to
3455 * root->glob->relationOids.
3456 *
3457 * 'rlist': the RETURNING targetlist to be fixed
3458 * 'topplan': the top subplan node that will be just below the ModifyTable
3459 * node (note it's not yet passed through set_plan_refs)
3460 * 'resultRelation': RT index of the associated result relation
3461 * 'rtoffset': how much to increment varnos by
3462 *
3463 * Note: the given 'root' is for the parent query level, not the 'topplan'.
3464 * This does not matter currently since we only access the dependency-item
3465 * lists in root->glob, but it would need some hacking if we wanted a root
3466 * that actually matches the subplan.
3467 *
3468 * Note: resultRelation is not yet adjusted by rtoffset.
3469 */
3470static List *
3471set_returning_clause_references(PlannerInfo *root,
3472 List *rlist,
3473 Plan *topplan,
3474 Index resultRelation,
3475 int rtoffset)
3476{
3477 indexed_tlist *itlist;
3478
3479 /*
3480 * We can perform the desired Var fixup by abusing the fix_join_expr
3481 * machinery that formerly handled inner indexscan fixup. We search the
3482 * top plan's targetlist for Vars of non-result relations, and use
3483 * fix_join_expr to convert RETURNING Vars into references to those tlist
3484 * entries, while leaving result-rel Vars as-is.
3485 *
3486 * PlaceHolderVars will also be sought in the targetlist, but no
3487 * more-complex expressions will be. Note that it is not possible for a
3488 * PlaceHolderVar to refer to the result relation, since the result is
3489 * never below an outer join. If that case could happen, we'd have to be
3490 * prepared to pick apart the PlaceHolderVar and evaluate its contained
3491 * expression instead.
3492 */
3493 itlist = build_tlist_index_other_vars(topplan->targetlist, resultRelation);
3494
3495 rlist = fix_join_expr(root,
3496 rlist,
3497 itlist,
3498 NULL,
3499 resultRelation,
3500 rtoffset,
3501 NRM_EQUAL,
3502 NUM_EXEC_TLIST(topplan));
3503
3504 pfree(itlist);
3505
3506 return rlist;
3507}
3508
3509/*
3510 * fix_windowagg_condition_expr_mutator
3511 * Mutator function for replacing WindowFuncs with the corresponding Var
3512 * in the targetlist which references that WindowFunc.
3513 */
3514static Node *
3515fix_windowagg_condition_expr_mutator(Node *node,
3516 fix_windowagg_cond_context *context)
3517{
3518 if (node == NULL)
3519 return NULL;
3520
3521 if (IsA(node, WindowFunc))
3522 {
3523 Var *newvar;
3524
3525 newvar = search_indexed_tlist_for_non_var((Expr *) node,
3526 context->subplan_itlist,
3527 context->newvarno);
3528 if (newvar)
3529 return (Node *) newvar;
3530 elog(ERROR, "WindowFunc not found in subplan target lists");
3531 }
3532
3533 return expression_tree_mutator(node,
3534 fix_windowagg_condition_expr_mutator,
3535 context);
3536}
3537
3538/*
3539 * fix_windowagg_condition_expr
3540 * Converts references in 'runcondition' so that any WindowFunc
3541 * references are swapped out for a Var which references the matching
3542 * WindowFunc in 'subplan_itlist'.
3543 */
3544static List *
3545fix_windowagg_condition_expr(PlannerInfo *root,
3546 List *runcondition,
3547 indexed_tlist *subplan_itlist)
3548{
3549 fix_windowagg_cond_context context;
3550
3551 context.root = root;
3552 context.subplan_itlist = subplan_itlist;
3553 context.newvarno = 0;
3554
3555 return (List *) fix_windowagg_condition_expr_mutator((Node *) runcondition,
3556 &context);
3557}
3558
3559/*
3560 * set_windowagg_runcondition_references
3561 * Converts references in 'runcondition' so that any WindowFunc
3562 * references are swapped out for a Var which references the matching
3563 * WindowFunc in 'plan' targetlist.
3564 */
3565static List *
3566set_windowagg_runcondition_references(PlannerInfo *root,
3567 List *runcondition,
3568 Plan *plan)
3569{
3570 List *newlist;
3571 indexed_tlist *itlist;
3572
3573 itlist = build_tlist_index(plan->targetlist);
3574
3575 newlist = fix_windowagg_condition_expr(root, runcondition, itlist);
3576
3577 pfree(itlist);
3578
3579 return newlist;
3580}
3581
3582/*
3583 * find_minmax_agg_replacement_param
3584 * If the given Aggref is one that we are optimizing into a subquery
3585 * (cf. planagg.c), then return the Param that should replace it.
3586 * Else return NULL.
3587 *
3588 * This is exported so that SS_finalize_plan can use it before setrefs.c runs.
3589 * Note that it will not find anything until we have built a Plan from a
3590 * MinMaxAggPath, as root->minmax_aggs will never be filled otherwise.
3591 */
3592Param *
3593find_minmax_agg_replacement_param(PlannerInfo *root, Aggref *aggref)
3594{
3595 if (root->minmax_aggs != NIL &&
3596 list_length(aggref->args) == 1)
3597 {
3598 TargetEntry *curTarget = (TargetEntry *) linitial(aggref->args);
3599 ListCell *lc;
3600
3601 foreach(lc, root->minmax_aggs)
3602 {
3603 MinMaxAggInfo *mminfo = (MinMaxAggInfo *) lfirst(lc);
3604
3605 if (mminfo->aggfnoid == aggref->aggfnoid &&
3606 equal(mminfo->target, curTarget->expr))
3607 return mminfo->param;
3608 }
3609 }
3610 return NULL;
3611}
3612
3613
3614/*****************************************************************************
3615 * QUERY DEPENDENCY MANAGEMENT
3616 *****************************************************************************/
3617
3618/*
3619 * record_plan_function_dependency
3620 * Mark the current plan as depending on a particular function.
3621 *
3622 * This is exported so that the function-inlining code can record a
3623 * dependency on a function that it's removed from the plan tree.
3624 */
3625void
3626record_plan_function_dependency(PlannerInfo *root, Oid funcid)
3627{
3628 /*
3629 * For performance reasons, we don't bother to track built-in functions;
3630 * we just assume they'll never change (or at least not in ways that'd
3631 * invalidate plans using them). For this purpose we can consider a
3632 * built-in function to be one with OID less than FirstUnpinnedObjectId.
3633 * Note that the OID generator guarantees never to generate such an OID
3634 * after startup, even at OID wraparound.
3635 */
3636 if (funcid >= (Oid) FirstUnpinnedObjectId)
3637 {
3638 PlanInvalItem *inval_item = makeNode(PlanInvalItem);
3639
3640 /*
3641 * It would work to use any syscache on pg_proc, but the easiest is
3642 * PROCOID since we already have the function's OID at hand. Note
3643 * that plancache.c knows we use PROCOID.
3644 */
3645 inval_item->cacheId = PROCOID;
3646 inval_item->hashValue = GetSysCacheHashValue1(PROCOID,
3647 ObjectIdGetDatum(funcid));
3648
3649 root->glob->invalItems = lappend(root->glob->invalItems, inval_item);
3650 }
3651}
3652
3653/*
3654 * record_plan_type_dependency
3655 * Mark the current plan as depending on a particular type.
3656 *
3657 * This is exported so that eval_const_expressions can record a
3658 * dependency on a domain that it's removed a CoerceToDomain node for.
3659 *
3660 * We don't currently need to record dependencies on domains that the
3661 * plan contains CoerceToDomain nodes for, though that might change in
3662 * future. Hence, this isn't actually called in this module, though
3663 * someday fix_expr_common might call it.
3664 */
3665void
3666record_plan_type_dependency(PlannerInfo *root, Oid typid)
3667{
3668 /*
3669 * As in record_plan_function_dependency, ignore the possibility that
3670 * someone would change a built-in domain.
3671 */
3672 if (typid >= (Oid) FirstUnpinnedObjectId)
3673 {
3674 PlanInvalItem *inval_item = makeNode(PlanInvalItem);
3675
3676 /*
3677 * It would work to use any syscache on pg_type, but the easiest is
3678 * TYPEOID since we already have the type's OID at hand. Note that
3679 * plancache.c knows we use TYPEOID.
3680 */
3681 inval_item->cacheId = TYPEOID;
3682 inval_item->hashValue = GetSysCacheHashValue1(TYPEOID,
3683 ObjectIdGetDatum(typid));
3684
3685 root->glob->invalItems = lappend(root->glob->invalItems, inval_item);
3686 }
3687}
3688
3689/*
3690 * extract_query_dependencies
3691 * Given a rewritten, but not yet planned, query or queries
3692 * (i.e. a Query node or list of Query nodes), extract dependencies
3693 * just as set_plan_references would do. Also detect whether any
3694 * rewrite steps were affected by RLS.
3695 *
3696 * This is needed by plancache.c to handle invalidation of cached unplanned
3697 * queries.
3698 *
3699 * Note: this does not go through eval_const_expressions, and hence doesn't
3700 * reflect its additions of inlined functions and elided CoerceToDomain nodes
3701 * to the invalItems list. This is obviously OK for functions, since we'll
3702 * see them in the original query tree anyway. For domains, it's OK because
3703 * we don't care about domains unless they get elided. That is, a plan might
3704 * have domain dependencies that the query tree doesn't.
3705 */
3706void
3707extract_query_dependencies(Node *query,
3708 List **relationOids,
3709 List **invalItems,
3710 bool *hasRowSecurity)
3711{
3712 PlannerGlobal glob;
3713 PlannerInfo root;
3714
3715 /* Make up dummy planner state so we can use this module's machinery */
3716 MemSet(&glob, 0, sizeof(glob));
3717 glob.type = T_PlannerGlobal;
3718 glob.relationOids = NIL;
3719 glob.invalItems = NIL;
3720 /* Hack: we use glob.dependsOnRole to collect hasRowSecurity flags */
3721 glob.dependsOnRole = false;
3722
3723 MemSet(&root, 0, sizeof(root));
3724 root.type = T_PlannerInfo;
3725 root.glob = &glob;
3726
3727 (void) extract_query_dependencies_walker(query, &root);
3728
3729 *relationOids = glob.relationOids;
3730 *invalItems = glob.invalItems;
3731 *hasRowSecurity = glob.dependsOnRole;
3732}
3733
3734/*
3735 * Tree walker for extract_query_dependencies.
3736 *
3737 * This is exported so that expression_planner_with_deps can call it on
3738 * simple expressions (post-planning, not before planning, in that case).
3739 * In that usage, glob.dependsOnRole isn't meaningful, but the relationOids
3740 * and invalItems lists are added to as needed.
3741 */
3742bool
3743extract_query_dependencies_walker(Node *node, PlannerInfo *context)
3744{
3745 if (node == NULL)
3746 return false;
3747 Assert(!IsA(node, PlaceHolderVar));
3748 if (IsA(node, Query))
3749 {
3750 Query *query = (Query *) node;
3751 ListCell *lc;
3752
3753 if (query->commandType == CMD_UTILITY)
3754 {
3755 /*
3756 * This logic must handle any utility command for which parse
3757 * analysis was nontrivial (cf. stmt_requires_parse_analysis).
3758 *
3759 * Notably, CALL requires its own processing.
3760 */
3761 if (IsA(query->utilityStmt, CallStmt))
3762 {
3763 CallStmt *callstmt = (CallStmt *) query->utilityStmt;
3764
3765 /* We need not examine funccall, just the transformed exprs */
3766 (void) extract_query_dependencies_walker((Node *) callstmt->funcexpr,
3767 context);
3768 (void) extract_query_dependencies_walker((Node *) callstmt->outargs,
3769 context);
3770 return false;
3771 }
3772
3773 /*
3774 * Ignore other utility statements, except those (such as EXPLAIN)
3775 * that contain a parsed-but-not-planned query. For those, we
3776 * just need to transfer our attention to the contained query.
3777 */
3778 query = UtilityContainsQuery(query->utilityStmt);
3779 if (query == NULL)
3780 return false;
3781 }
3782
3783 /* Remember if any Query has RLS quals applied by rewriter */
3784 if (query->hasRowSecurity)
3785 context->glob->dependsOnRole = true;
3786
3787 /* Collect relation OIDs in this Query's rtable */
3788 foreach(lc, query->rtable)
3789 {
3790 RangeTblEntry *rte = (RangeTblEntry *) lfirst(lc);
3791
3792 if (rte->rtekind == RTE_RELATION ||
3793 (rte->rtekind == RTE_SUBQUERY && OidIsValid(rte->relid)) ||
3794 (rte->rtekind == RTE_NAMEDTUPLESTORE && OidIsValid(rte->relid)))
3795 context->glob->relationOids =
3796 lappend_oid(context->glob->relationOids, rte->relid);
3797 }
3798
3799 /* And recurse into the query's subexpressions */
3800 return query_tree_walker(query, extract_query_dependencies_walker,
3801 context, 0);
3802 }
3803 /* Extract function dependencies and check for regclass Consts */
3804 fix_expr_common(context, node);
3805 return expression_tree_walker(node, extract_query_dependencies_walker,
3806 context);
3807}
3808
3809/*
3810 * Record some details about a node removed from the plan during setrefs
3811 * processing, for the benefit of code trying to reconstruct planner decisions
3812 * from examination of the final plan tree.
3813 */
3814static void
3815record_elided_node(PlannerGlobal *glob, int plan_node_id,
3816 NodeTag elided_type, Bitmapset *relids)
3817{
3818 ElidedNode *n = makeNode(ElidedNode);
3819
3820 n->plan_node_id = plan_node_id;
3821 n->elided_type = elided_type;
3822 n->relids = relids;
3823
3824 glob->elidedNodes = lappend(glob->elidedNodes, n);
3825}
AttrNumber
int16 AttrNumber
Definition attnum.h:21
bms_make_singleton
Bitmapset * bms_make_singleton(int x)
Definition bitmapset.c:216
bms_intersect
Bitmapset * bms_intersect(const Bitmapset *a, const Bitmapset *b)
Definition bitmapset.c:292
bms_equal
bool bms_equal(const Bitmapset *a, const Bitmapset *b)
Definition bitmapset.c:142
bms_next_member
int bms_next_member(const Bitmapset *a, int prevbit)
Definition bitmapset.c:1290
bms_is_subset
bool bms_is_subset(const Bitmapset *a, const Bitmapset *b)
Definition bitmapset.c:412
bms_add_member
Bitmapset * bms_add_member(Bitmapset *a, int x)
Definition bitmapset.c:799
Assert
#define Assert(condition)
Definition c.h:885
FLEXIBLE_ARRAY_MEMBER
#define FLEXIBLE_ARRAY_MEMBER
Definition c.h:492
Index
unsigned int Index
Definition c.h:640
MemSet
#define MemSet(start, val, len)
Definition c.h:1035
OidIsValid
#define OidIsValid(objectId)
Definition c.h:800
ERROR
#define ERROR
Definition elog.h:39
elog
#define elog(elevel,...)
Definition elog.h:226
equal
bool equal(const void *a, const void *b)
Definition equalfuncs.c:223
palloc_object
#define palloc_object(type)
Definition fe_memutils.h:74
i
int i
Definition isn.c:77
lappend
List * lappend(List *list, void *datum)
Definition list.c:339
list_concat
List * list_concat(List *list1, const List *list2)
Definition list.c:561
lappend_int
List * lappend_int(List *list, int datum)
Definition list.c:357
lappend_oid
List * lappend_oid(List *list, Oid datum)
Definition list.c:375
lca
Datum lca(PG_FUNCTION_ARGS)
Definition ltree_op.c:563
makeVarFromTargetEntry
Var * makeVarFromTargetEntry(int varno, TargetEntry *tle)
Definition makefuncs.c:107
makeVar
Var * makeVar(int varno, AttrNumber varattno, Oid vartype, int32 vartypmod, Oid varcollid, Index varlevelsup)
Definition makefuncs.c:66
makeNullConst
Const * makeNullConst(Oid consttype, int32 consttypmod, Oid constcollid)
Definition makefuncs.c:388
makeTargetEntry
TargetEntry * makeTargetEntry(Expr *expr, AttrNumber resno, char *resname, bool resjunk)
Definition makefuncs.c:289
flatCopyTargetEntry
TargetEntry * flatCopyTargetEntry(TargetEntry *src_tle)
Definition makefuncs.c:322
pfree
void pfree(void *pointer)
Definition mcxt.c:1616
palloc0
void * palloc0(Size size)
Definition mcxt.c:1417
palloc
void * palloc(Size size)
Definition mcxt.c:1387
exprType
Oid exprType(const Node *expr)
Definition nodeFuncs.c:42
exprTypmod
int32 exprTypmod(const Node *expr)
Definition nodeFuncs.c:301
exprCollation
Oid exprCollation(const Node *expr)
Definition nodeFuncs.c:821
set_sa_opfuncid
void set_sa_opfuncid(ScalarArrayOpExpr *opexpr)
Definition nodeFuncs.c:1882
set_opfuncid
void set_opfuncid(OpExpr *opexpr)
Definition nodeFuncs.c:1871
expression_tree_mutator
#define expression_tree_mutator(n, m, c)
Definition nodeFuncs.h:155
query_tree_walker
#define query_tree_walker(q, w, c, f)
Definition nodeFuncs.h:158
expression_tree_walker
#define expression_tree_walker(n, w, c)
Definition nodeFuncs.h:153
QTW_EXAMINE_RTES_BEFORE
#define QTW_EXAMINE_RTES_BEFORE
Definition nodeFuncs.h:27
IsA
#define IsA(nodeptr, _type_)
Definition nodes.h:164
copyObject
#define copyObject(obj)
Definition nodes.h:232
Cost
double Cost
Definition nodes.h:261
nodeTag
#define nodeTag(nodeptr)
Definition nodes.h:139
DO_AGGSPLIT_COMBINE
#define DO_AGGSPLIT_COMBINE(as)
Definition nodes.h:395
ONCONFLICT_SELECT
@ ONCONFLICT_SELECT
Definition nodes.h:431
ONCONFLICT_UPDATE
@ ONCONFLICT_UPDATE
Definition nodes.h:430
CMD_UTILITY
@ CMD_UTILITY
Definition nodes.h:280
NodeTag
NodeTag
Definition nodes.h:27
AGGSPLIT_FINAL_DESERIAL
@ AGGSPLIT_FINAL_DESERIAL
Definition nodes.h:391
AGGSPLIT_INITIAL_SERIAL
@ AGGSPLIT_INITIAL_SERIAL
Definition nodes.h:389
makeNode
#define makeNode(_type_)
Definition nodes.h:161
JOIN_INNER
@ JOIN_INNER
Definition nodes.h:303
bmsToString
char * bmsToString(const Bitmapset *bms)
Definition outfuncs.c:819
getRTEPermissionInfo
RTEPermissionInfo * getRTEPermissionInfo(List *rteperminfos, RangeTblEntry *rte)
Definition parse_relation.c:3950
addRTEPermissionInfo
RTEPermissionInfo * addRTEPermissionInfo(List **rteperminfos, RangeTblEntry *rte)
Definition parse_relation.c:3921
parse_relation.h
RTE_NAMEDTUPLESTORE
@ RTE_NAMEDTUPLESTORE
Definition parsenodes.h:1077
RTE_SUBQUERY
@ RTE_SUBQUERY
Definition parsenodes.h:1071
RTE_RELATION
@ RTE_RELATION
Definition parsenodes.h:1070
IS_DUMMY_REL
#define IS_DUMMY_REL(r)
Definition pathnodes.h:2285
UPPERREL_FINAL
@ UPPERREL_FINAL
Definition pathnodes.h:152
lfirst
#define lfirst(lc)
Definition pg_list.h:172
lfirst_node
#define lfirst_node(type, lc)
Definition pg_list.h:176
list_length
static int list_length(const List *l)
Definition pg_list.h:152
NIL
#define NIL
Definition pg_list.h:68
forboth
#define forboth(cell1, list1, cell2, list2)
Definition pg_list.h:518
foreach_current_index
#define foreach_current_index(var_or_cell)
Definition pg_list.h:403
lfirst_int
#define lfirst_int(lc)
Definition pg_list.h:173
list_make1
#define list_make1(x1)
Definition pg_list.h:212
linitial_int
#define linitial_int(l)
Definition pg_list.h:179
forthree
#define forthree(cell1, list1, cell2, list2, cell3, list3)
Definition pg_list.h:563
list_nth
static void * list_nth(const List *list, int n)
Definition pg_list.h:299
linitial
#define linitial(l)
Definition pg_list.h:178
list_nth_node
#define list_nth_node(type, list, n)
Definition pg_list.h:327
plan
#define plan(x)
Definition pg_regress.c:161
pg_type.h
mark_partial_aggref
void mark_partial_aggref(Aggref *agg, AggSplit aggsplit)
Definition planner.c:5818
SUBQUERY_SCAN_NONTRIVIAL
@ SUBQUERY_SCAN_NONTRIVIAL
Definition plannodes.h:768
SUBQUERY_SCAN_UNKNOWN
@ SUBQUERY_SCAN_UNKNOWN
Definition plannodes.h:766
SUBQUERY_SCAN_TRIVIAL
@ SUBQUERY_SCAN_TRIVIAL
Definition plannodes.h:767
outerPlan
#define outerPlan(node)
Definition plannodes.h:267
DatumGetObjectId
static Oid DatumGetObjectId(Datum X)
Definition postgres.h:252
ObjectIdGetDatum
static Datum ObjectIdGetDatum(Oid X)
Definition postgres.h:262
Oid
unsigned int Oid
Definition postgres_ext.h:32
fb
static int fb(int x)
Definition preproc-init.c:92
ROWID_VAR
#define ROWID_VAR
Definition primnodes.h:246
PARAM_MULTIEXPR
@ PARAM_MULTIEXPR
Definition primnodes.h:388
IS_SPECIAL_VARNO
#define IS_SPECIAL_VARNO(varno)
Definition primnodes.h:248
VAR_RETURNING_DEFAULT
@ VAR_RETURNING_DEFAULT
Definition primnodes.h:257
OUTER_VAR
#define OUTER_VAR
Definition primnodes.h:244
INNER_VAR
#define INNER_VAR
Definition primnodes.h:243
INDEX_VAR
#define INDEX_VAR
Definition primnodes.h:245
root
tree ctl root
Definition radixtree.h:1857
find_base_rel
RelOptInfo * find_base_rel(PlannerInfo *root, int relid)
Definition relnode.c:533
fetch_upper_rel
RelOptInfo * fetch_upper_rel(PlannerInfo *root, UpperRelationKind kind, Relids relids)
Definition relnode.c:1606
remove_nulling_relids
Node * remove_nulling_relids(Node *node, const Bitmapset *removable_relids, const Bitmapset *except_relids)
Definition rewriteManip.c:1328
NullingRelsMatch
NullingRelsMatch
Definition setrefs.c:35
NRM_EQUAL
@ NRM_EQUAL
Definition setrefs.c:36
NRM_SUPERSET
@ NRM_SUPERSET
Definition setrefs.c:38
NRM_SUBSET
@ NRM_SUBSET
Definition setrefs.c:37
record_plan_type_dependency
void record_plan_type_dependency(PlannerInfo *root, Oid typid)
Definition setrefs.c:3666
NUM_EXEC_QUAL
#define NUM_EXEC_QUAL(parentplan)
Definition setrefs.c:117
set_hash_references
static void set_hash_references(PlannerInfo *root, Plan *plan, int rtoffset)
Definition setrefs.c:2025
fix_expr_common
static void fix_expr_common(PlannerInfo *root, Node *node)
Definition setrefs.c:2102
record_elided_node
static void record_elided_node(PlannerGlobal *glob, int plan_node_id, NodeTag elided_type, Bitmapset *relids)
Definition setrefs.c:3815
add_rtes_to_flat_rtable
static void add_rtes_to_flat_rtable(PlannerInfo *root, bool recursing)
Definition setrefs.c:399
fix_join_expr_mutator
static Node * fix_join_expr_mutator(Node *node, fix_join_expr_context *context)
Definition setrefs.c:3198
add_rte_to_flat_rtable
static void add_rte_to_flat_rtable(PlannerGlobal *glob, List *rteperminfos, RangeTblEntry *rte)
Definition setrefs.c:565
set_append_references
static Plan * set_append_references(PlannerInfo *root, Append *aplan, int rtoffset)
Definition setrefs.c:1873
set_plan_references
Plan * set_plan_references(PlannerInfo *root, Plan *plan)
Definition setrefs.c:291
set_mergeappend_references
static Plan * set_mergeappend_references(PlannerInfo *root, MergeAppend *mplan, int rtoffset)
Definition setrefs.c:1950
set_returning_clause_references
static List * set_returning_clause_references(PlannerInfo *root, List *rlist, Plan *topplan, Index resultRelation, int rtoffset)
Definition setrefs.c:3471
fix_param_node
static Node * fix_param_node(PlannerInfo *root, Param *p)
Definition setrefs.c:2197
record_plan_function_dependency
void record_plan_function_dependency(PlannerInfo *root, Oid funcid)
Definition setrefs.c:3626
offset_relid_set
static Relids offset_relid_set(Relids relids, int rtoffset)
Definition setrefs.c:2058
flatten_rtes_walker
static bool flatten_rtes_walker(Node *node, flatten_rtes_walker_context *cxt)
Definition setrefs.c:520
build_tlist_index
static indexed_tlist * build_tlist_index(List *tlist)
Definition setrefs.c:2831
set_windowagg_runcondition_references
static List * set_windowagg_runcondition_references(PlannerInfo *root, List *runcondition, Plan *plan)
Definition setrefs.c:3566
trivial_subqueryscan
bool trivial_subqueryscan(SubqueryScan *plan)
Definition setrefs.c:1528
set_upper_references
static void set_upper_references(PlannerInfo *root, Plan *plan, int rtoffset)
Definition setrefs.c:2553
search_indexed_tlist_for_sortgroupref
static Var * search_indexed_tlist_for_sortgroupref(Expr *node, Index sortgroupref, indexed_tlist *itlist, int newvarno)
Definition setrefs.c:3098
flatten_unplanned_rtes
static void flatten_unplanned_rtes(PlannerGlobal *glob, RangeTblEntry *rte)
Definition setrefs.c:508
fix_upper_expr
static Node * fix_upper_expr(PlannerInfo *root, Node *node, indexed_tlist *subplan_itlist, int newvarno, int rtoffset, NullingRelsMatch nrm_match, double num_exec)
Definition setrefs.c:3350
set_param_references
static void set_param_references(PlannerInfo *root, Plan *plan)
Definition setrefs.c:2641
search_indexed_tlist_for_non_var
static Var * search_indexed_tlist_for_non_var(Expr *node, indexed_tlist *itlist, int newvarno)
Definition setrefs.c:3058
fix_upper_expr_mutator
static Node * fix_upper_expr_mutator(Node *node, fix_upper_expr_context *context)
Definition setrefs.c:3370
find_minmax_agg_replacement_param
Param * find_minmax_agg_replacement_param(PlannerInfo *root, Aggref *aggref)
Definition setrefs.c:3593
fix_scan_expr_mutator
static Node * fix_scan_expr_mutator(Node *node, fix_scan_expr_context *context)
Definition setrefs.c:2319
set_foreignscan_references
static void set_foreignscan_references(PlannerInfo *root, ForeignScan *fscan, int rtoffset)
Definition setrefs.c:1642
set_subqueryscan_references
static Plan * set_subqueryscan_references(PlannerInfo *root, SubqueryScan *plan, int rtoffset)
Definition setrefs.c:1452
search_indexed_tlist_for_phv
static Var * search_indexed_tlist_for_phv(PlaceHolderVar *phv, indexed_tlist *itlist, int newvarno, NullingRelsMatch nrm_match)
Definition setrefs.c:3005
set_indexonlyscan_references
static Plan * set_indexonlyscan_references(PlannerInfo *root, IndexOnlyScan *plan, int rtoffset)
Definition setrefs.c:1378
fix_join_expr
static List * fix_join_expr(PlannerInfo *root, List *clauses, indexed_tlist *outer_itlist, indexed_tlist *inner_itlist, Index acceptable_rel, int rtoffset, NullingRelsMatch nrm_match, double num_exec)
Definition setrefs.c:3176
convert_combining_aggrefs
static Node * convert_combining_aggrefs(Node *node, void *context)
Definition setrefs.c:2696
set_dummy_tlist_references
static void set_dummy_tlist_references(Plan *plan, int rtoffset)
Definition setrefs.c:2764
register_partpruneinfo
static int register_partpruneinfo(PlannerInfo *root, int part_prune_index, int rtoffset)
Definition setrefs.c:1812
set_customscan_references
static void set_customscan_references(PlannerInfo *root, CustomScan *cscan, int rtoffset)
Definition setrefs.c:1729
ISREGCLASSCONST
#define ISREGCLASSCONST(con)
Definition setrefs.c:126
extract_query_dependencies
void extract_query_dependencies(Node *query, List **relationOids, List **invalItems, bool *hasRowSecurity)
Definition setrefs.c:3707
fix_windowagg_condition_expr_mutator
static Node * fix_windowagg_condition_expr_mutator(Node *node, fix_windowagg_cond_context *context)
Definition setrefs.c:3515
copyVar
static Var * copyVar(Var *var)
Definition setrefs.c:2080
extract_query_dependencies_walker
bool extract_query_dependencies_walker(Node *node, PlannerInfo *context)
Definition setrefs.c:3743
fix_windowagg_condition_expr
static List * fix_windowagg_condition_expr(PlannerInfo *root, List *runcondition, indexed_tlist *subplan_itlist)
Definition setrefs.c:3545
NUM_EXEC_TLIST
#define NUM_EXEC_TLIST(parentplan)
Definition setrefs.c:116
fix_alternative_subplan
static Node * fix_alternative_subplan(PlannerInfo *root, AlternativeSubPlan *asplan, double num_exec)
Definition setrefs.c:2228
set_join_references
static void set_join_references(PlannerInfo *root, Join *join, int rtoffset)
Definition setrefs.c:2404
build_tlist_index_other_vars
static indexed_tlist * build_tlist_index_other_vars(List *tlist, int ignore_rel)
Definition setrefs.c:2882
clean_up_removed_plan_level
static Plan * clean_up_removed_plan_level(Plan *parent, Plan *child)
Definition setrefs.c:1598
fix_scan_expr
static Node * fix_scan_expr(PlannerInfo *root, Node *node, int rtoffset, double num_exec)
Definition setrefs.c:2284
set_plan_refs
static Plan * set_plan_refs(PlannerInfo *root, Plan *plan, int rtoffset)
Definition setrefs.c:642
fix_scan_expr_walker
static bool fix_scan_expr_walker(Node *node, fix_scan_expr_context *context)
Definition setrefs.c:2384
search_indexed_tlist_for_var
static Var * search_indexed_tlist_for_var(Var *var, indexed_tlist *itlist, int newvarno, int rtoffset, NullingRelsMatch nrm_match)
Definition setrefs.c:2940
fix_scan_list
#define fix_scan_list(root, lst, rtoffset, num_exec)
Definition setrefs.c:130
Aggref::aggfnoid
Oid aggfnoid
Definition primnodes.h:464
Aggref::args
List * args
Definition primnodes.h:488
BitmapAnd::plan
Plan plan
Definition plannodes.h:510
BitmapAnd::bitmapplans
List * bitmapplans
Definition plannodes.h:511
BitmapHeapScan::bitmapqualorig
List * bitmapqualorig
Definition plannodes.h:712
BitmapIndexScan::indexqualorig
List * indexqualorig
Definition plannodes.h:696
BitmapOr::bitmapplans
List * bitmapplans
Definition plannodes.h:526
BitmapOr::plan
Plan plan
Definition plannodes.h:524
CteScan::scan
Scan scan
Definition plannodes.h:819
ElidedNode::elided_type
NodeTag elided_type
Definition plannodes.h:1870
ElidedNode::plan_node_id
int plan_node_id
Definition plannodes.h:1869
ElidedNode::relids
Bitmapset * relids
Definition plannodes.h:1871
FunctionScan::functions
List * functions
Definition plannodes.h:786
IndexScan::indexorderby
List * indexorderby
Definition plannodes.h:612
IndexScan::scan
Scan scan
Definition plannodes.h:604
IndexScan::indexqualorig
List * indexqualorig
Definition plannodes.h:610
IndexScan::indexqual
List * indexqual
Definition plannodes.h:608
IndexScan::indexorderbyorig
List * indexorderbyorig
Definition plannodes.h:614
Join::joinqual
List * joinqual
Definition plannodes.h:990
Join::jointype
JoinType jointype
Definition plannodes.h:987
Limit::plan
Plan plan
Definition plannodes.h:1498
Limit::limitCount
Node * limitCount
Definition plannodes.h:1504
Limit::limitOffset
Node * limitOffset
Definition plannodes.h:1501
List
Definition pg_list.h:54
LockRows::rowMarks
List * rowMarks
Definition plannodes.h:1484
LockRows::plan
Plan plan
Definition plannodes.h:1482
MinMaxAggInfo::param
Param * param
Definition pathnodes.h:3450
ModifyTable::nominalRelation
Index nominalRelation
Definition plannodes.h:344
ModifyTable::mergeJoinConditions
List * mergeJoinConditions
Definition plannodes.h:386
ModifyTable::resultRelations
List * resultRelations
Definition plannodes.h:348
ModifyTable::onConflictSet
List * onConflictSet
Definition plannodes.h:374
ModifyTable::exclRelTlist
List * exclRelTlist
Definition plannodes.h:382
ModifyTable::mergeActionLists
List * mergeActionLists
Definition plannodes.h:384
ModifyTable::returningLists
List * returningLists
Definition plannodes.h:358
ModifyTable::withCheckOptionLists
List * withCheckOptionLists
Definition plannodes.h:352
ModifyTable::rootRelation
Index rootRelation
Definition plannodes.h:346
ModifyTable::onConflictWhere
Node * onConflictWhere
Definition plannodes.h:378
ModifyTable::rowMarks
List * rowMarks
Definition plannodes.h:364
ModifyTable::onConflictAction
OnConflictAction onConflictAction
Definition plannodes.h:368
ModifyTable::exclRelRTI
Index exclRelRTI
Definition plannodes.h:380
Node
Definition nodes.h:135
Param::paramid
int paramid
Definition primnodes.h:397
Param::paramkind
ParamKind paramkind
Definition primnodes.h:396
PartitionPruneInfo::relids
Bitmapset * relids
Definition plannodes.h:1666
Plan::lefttree
struct Plan * lefttree
Definition plannodes.h:239
Plan::total_cost
Cost total_cost
Definition plannodes.h:205
Plan::parallel_aware
bool parallel_aware
Definition plannodes.h:219
Plan::startup_cost
Cost startup_cost
Definition plannodes.h:203
Plan::qual
List * qual
Definition plannodes.h:237
Plan::parallel_safe
bool parallel_safe
Definition plannodes.h:221
Plan::plan_node_id
int plan_node_id
Definition plannodes.h:233
Plan::targetlist
List * targetlist
Definition plannodes.h:235
Plan::initPlan
List * initPlan
Definition plannodes.h:242
PlannerGlobal::prunableRelids
Bitmapset * prunableRelids
Definition pathnodes.h:206
PlannerGlobal::subplans
List * subplans
Definition pathnodes.h:178
PlannerGlobal::dependsOnRole
bool dependsOnRole
Definition pathnodes.h:251
PlannerGlobal::allRelids
Bitmapset * allRelids
Definition pathnodes.h:199
PlannerGlobal::appendRelations
List * appendRelations
Definition pathnodes.h:221
PlannerGlobal::finalrowmarks
List * finalrowmarks
Definition pathnodes.h:215
PlannerGlobal::invalItems
List * invalItems
Definition pathnodes.h:230
PlannerGlobal::relationOids
List * relationOids
Definition pathnodes.h:227
PlannerGlobal::finalrteperminfos
List * finalrteperminfos
Definition pathnodes.h:209
PlannerGlobal::partPruneInfos
List * partPruneInfos
Definition pathnodes.h:224
PlannerGlobal::finalrtable
List * finalrtable
Definition pathnodes.h:193
PlannerGlobal::elidedNodes
List * elidedNodes
Definition pathnodes.h:236
PlannerInfo::glob
PlannerGlobal * glob
Definition pathnodes.h:312
Query::rtable
List * rtable
Definition parsenodes.h:175
Query::commandType
CmdType commandType
Definition parsenodes.h:121
Query::utilityStmt
Node * utilityStmt
Definition parsenodes.h:141
RelOptInfo::relid
Index relid
Definition pathnodes.h:1057
RelOptInfo::subroot
PlannerInfo * subroot
Definition pathnodes.h:1088
Result::resconstantqual
Node * resconstantqual
Definition plannodes.h:305
Result::relids
Bitmapset * relids
Definition plannodes.h:306
Result::plan
Plan plan
Definition plannodes.h:303
SampleScan::tablesample
struct TableSampleClause * tablesample
Definition plannodes.h:562
Scan::scanrelid
Index scanrelid
Definition plannodes.h:542
SeqScan::scan
Scan scan
Definition plannodes.h:551
SubPlan::startup_cost
Cost startup_cost
Definition primnodes.h:1127
TableFuncScan::tablefunc
TableFunc * tablefunc
Definition plannodes.h:810
TidRangeScan::tidrangequals
List * tidrangequals
Definition plannodes.h:741
TidScan::scan
Scan scan
Definition plannodes.h:725
TidScan::tidquals
List * tidquals
Definition plannodes.h:727
ValuesScan::values_lists
List * values_lists
Definition plannodes.h:799
Var::varattno
AttrNumber varattno
Definition primnodes.h:275
Var::varno
int varno
Definition primnodes.h:270
Var::varreturningtype
VarReturningType varreturningtype
Definition primnodes.h:298
Var::varlevelsup
Index varlevelsup
Definition primnodes.h:295
WindowAgg::runCondition
List * runCondition
Definition plannodes.h:1293
fix_join_expr_context
Definition setrefs.c:66
fix_join_expr_context::acceptable_rel
Index acceptable_rel
Definition setrefs.c:70
fix_join_expr_context::num_exec
double num_exec
Definition setrefs.c:73
fix_join_expr_context::nrm_match
NullingRelsMatch nrm_match
Definition setrefs.c:72
fix_join_expr_context::outer_itlist
indexed_tlist * outer_itlist
Definition setrefs.c:68
fix_join_expr_context::root
PlannerInfo * root
Definition setrefs.c:67
fix_join_expr_context::rtoffset
int rtoffset
Definition setrefs.c:71
fix_join_expr_context::inner_itlist
indexed_tlist * inner_itlist
Definition setrefs.c:69
fix_scan_expr_context
Definition setrefs.c:59
fix_scan_expr_context::rtoffset
int rtoffset
Definition setrefs.c:61
fix_scan_expr_context::root
PlannerInfo * root
Definition setrefs.c:60
fix_scan_expr_context::num_exec
double num_exec
Definition setrefs.c:62
fix_upper_expr_context
Definition setrefs.c:77
fix_upper_expr_context::newvarno
int newvarno
Definition setrefs.c:80
fix_upper_expr_context::subplan_itlist
indexed_tlist * subplan_itlist
Definition setrefs.c:79
fix_upper_expr_context::num_exec
double num_exec
Definition setrefs.c:83
fix_upper_expr_context::rtoffset
int rtoffset
Definition setrefs.c:81
fix_upper_expr_context::root
PlannerInfo * root
Definition setrefs.c:78
fix_upper_expr_context::nrm_match
NullingRelsMatch nrm_match
Definition setrefs.c:82
fix_windowagg_cond_context
Definition setrefs.c:87
fix_windowagg_cond_context::subplan_itlist
indexed_tlist * subplan_itlist
Definition setrefs.c:89
fix_windowagg_cond_context::root
PlannerInfo * root
Definition setrefs.c:88
fix_windowagg_cond_context::newvarno
int newvarno
Definition setrefs.c:90
flatten_rtes_walker_context
Definition setrefs.c:95
flatten_rtes_walker_context::glob
PlannerGlobal * glob
Definition setrefs.c:96
flatten_rtes_walker_context::query
Query * query
Definition setrefs.c:97
indexed_tlist
Definition setrefs.c:50
indexed_tlist::has_ph_vars
bool has_ph_vars
Definition setrefs.c:53
indexed_tlist::has_non_vars
bool has_non_vars
Definition setrefs.c:54
indexed_tlist::num_vars
int num_vars
Definition setrefs.c:52
indexed_tlist::tlist
List * tlist
Definition setrefs.c:51
tlist_vinfo
Definition setrefs.c:42
tlist_vinfo::resno
AttrNumber resno
Definition setrefs.c:45
tlist_vinfo::varnullingrels
Bitmapset * varnullingrels
Definition setrefs.c:46
tlist_vinfo::varno
int varno
Definition setrefs.c:43
tlist_vinfo::varattno
AttrNumber varattno
Definition setrefs.c:44
SS_compute_initplan_cost
void SS_compute_initplan_cost(List *init_plans, Cost *initplan_cost_p, bool *unsafe_initplans_p)
Definition subselect.c:2354
GetSysCacheHashValue1
#define GetSysCacheHashValue1(cacheId, key1)
Definition syscache.h:118
tlist_member
TargetEntry * tlist_member(Expr *node, List *targetlist)
Definition tlist.c:88
apply_tlist_labeling
void apply_tlist_labeling(List *dest_tlist, List *src_tlist)
Definition tlist.c:327
FirstUnpinnedObjectId
#define FirstUnpinnedObjectId
Definition transam.h:196
UtilityContainsQuery
Query * UtilityContainsQuery(Node *parsetree)
Definition utility.c:2186