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analyzejoins.c
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1/*-------------------------------------------------------------------------
2 *
3 * analyzejoins.c
4 * Routines for simplifying joins after initial query analysis
5 *
6 * While we do a great deal of join simplification in prep/prepjointree.c,
7 * certain optimizations cannot be performed at that stage for lack of
8 * detailed information about the query. The routines here are invoked
9 * after initsplan.c has done its work, and can do additional join removal
10 * and simplification steps based on the information extracted. The penalty
11 * is that we have to work harder to clean up after ourselves when we modify
12 * the query, since the derived data structures have to be updated too.
13 *
14 * Portions Copyright (c) 1996-2026, PostgreSQL Global Development Group
15 * Portions Copyright (c) 1994, Regents of the University of California
16 *
17 *
18 * IDENTIFICATION
19 * src/backend/optimizer/plan/analyzejoins.c
20 *
21 *-------------------------------------------------------------------------
22 */
23#include "postgres.h"
24
25#include "catalog/pg_class.h"
26#include "nodes/nodeFuncs.h"
27#include "optimizer/joininfo.h"
28#include "optimizer/optimizer.h"
29#include "optimizer/pathnode.h"
30#include "optimizer/paths.h"
32#include "optimizer/planmain.h"
34#include "parser/parse_agg.h"
36#include "utils/lsyscache.h"
37
38/*
39 * Utility structure. A sorting procedure is needed to simplify the search
40 * of SJE-candidate baserels referencing the same database relation. Having
41 * collected all baserels from the query jointree, the planner sorts them
42 * according to the reloid value, groups them with the next pass and attempts
43 * to remove self-joins.
44 *
45 * Preliminary sorting prevents quadratic behavior that can be harmful in the
46 * case of numerous joins.
47 */
48typedef struct
49{
50 int relid;
53
55
56/* local functions */
58static void remove_leftjoinrel_from_query(PlannerInfo *root, int relid,
59 SpecialJoinInfo *sjinfo);
60static void remove_rel_from_query(PlannerInfo *root, int relid,
61 int subst, SpecialJoinInfo *sjinfo,
64 int relid, int ojrelid);
66 int relid, int ojrelid);
68 int relid, int ojrelid);
69static Node *remove_rel_from_phvs(Node *node, int relid, int ojrelid);
71static List *remove_rel_from_joinlist(List *joinlist, int relid, int *nremoved);
74 List *clause_list, List **extra_clauses);
78 Relids outerrelids,
79 RelOptInfo *innerrel,
80 JoinType jointype,
81 List *restrictlist,
82 List **extra_clauses);
83static int self_join_candidates_cmp(const void *a, const void *b);
84static bool replace_relid_callback(Node *node,
85 ChangeVarNodes_context *context);
86
87
88/*
89 * remove_useless_joins
90 * Check for relations that don't actually need to be joined at all,
91 * and remove them from the query.
92 *
93 * We are passed the current joinlist and return the updated list. Other
94 * data structures that have to be updated are accessible via "root".
95 */
96List *
98{
99 ListCell *lc;
100
101 /*
102 * We are only interested in relations that are left-joined to, so we can
103 * scan the join_info_list to find them easily.
104 */
105restart:
106 foreach(lc, root->join_info_list)
107 {
109 int innerrelid;
110 int nremoved;
111
112 /* Skip if not removable */
113 if (!join_is_removable(root, sjinfo))
114 continue;
115
116 /*
117 * Currently, join_is_removable can only succeed when the sjinfo's
118 * righthand is a single baserel. Remove that rel from the query and
119 * joinlist.
120 */
122
124
125 /* We verify that exactly one reference gets removed from joinlist */
126 nremoved = 0;
128 if (nremoved != 1)
129 elog(ERROR, "failed to find relation %d in joinlist", innerrelid);
130
131 /*
132 * We can delete this SpecialJoinInfo from the list too, since it's no
133 * longer of interest. (Since we'll restart the foreach loop
134 * immediately, we don't bother with foreach_delete_current.)
135 */
136 root->join_info_list = list_delete_cell(root->join_info_list, lc);
137
138 /*
139 * Restart the scan. This is necessary to ensure we find all
140 * removable joins independently of ordering of the join_info_list
141 * (note that removal of attr_needed bits may make a join appear
142 * removable that did not before).
143 */
144 goto restart;
145 }
146
147 return joinlist;
148}
149
150/*
151 * join_is_removable
152 * Check whether we need not perform this special join at all, because
153 * it will just duplicate its left input.
154 *
155 * This is true for a left join for which the join condition cannot match
156 * more than one inner-side row. (There are other possibly interesting
157 * cases, but we don't have the infrastructure to prove them.) We also
158 * have to check that the inner side doesn't generate any variables needed
159 * above the join.
160 */
161static bool
163{
164 int innerrelid;
165 RelOptInfo *innerrel;
169 ListCell *l;
170 int attroff;
171
172 /*
173 * Must be a left join to a single baserel, else we aren't going to be
174 * able to do anything with it.
175 */
176 if (sjinfo->jointype != JOIN_LEFT)
177 return false;
178
180 return false;
181
182 /*
183 * Never try to eliminate a left join to the query result rel. Although
184 * the case is syntactically impossible in standard SQL, MERGE will build
185 * a join tree that looks exactly like that.
186 */
187 if (innerrelid == root->parse->resultRelation)
188 return false;
189
190 innerrel = find_base_rel(root, innerrelid);
191
192 /*
193 * Before we go to the effort of checking whether any innerrel variables
194 * are needed above the join, make a quick check to eliminate cases in
195 * which we will surely be unable to prove uniqueness of the innerrel.
196 */
197 if (!rel_supports_distinctness(root, innerrel))
198 return false;
199
200 /* Compute the relid set for the join we are considering */
202 Assert(sjinfo->ojrelid != 0);
205
206 /*
207 * We can't remove the join if any inner-rel attributes are used above the
208 * join. Here, "above" the join includes pushed-down conditions, so we
209 * should reject if attr_needed includes the OJ's own relid; therefore,
210 * compare to inputrelids not joinrelids.
211 *
212 * As a micro-optimization, it seems better to start with max_attr and
213 * count down rather than starting with min_attr and counting up, on the
214 * theory that the system attributes are somewhat less likely to be wanted
215 * and should be tested last.
216 */
217 for (attroff = innerrel->max_attr - innerrel->min_attr;
218 attroff >= 0;
219 attroff--)
220 {
221 if (!bms_is_subset(innerrel->attr_needed[attroff], inputrelids))
222 return false;
223 }
224
225 /*
226 * Similarly check that the inner rel isn't needed by any PlaceHolderVars
227 * that will be used above the join. The PHV case is a little bit more
228 * complicated, because PHVs may have been assigned a ph_eval_at location
229 * that includes the innerrel, yet their contained expression might not
230 * actually reference the innerrel (it could be just a constant, for
231 * instance). If such a PHV is due to be evaluated above the join then it
232 * needn't prevent join removal.
233 */
234 foreach(l, root->placeholder_list)
235 {
237
238 if (bms_overlap(phinfo->ph_lateral, innerrel->relids))
239 return false; /* it references innerrel laterally */
240 if (!bms_overlap(phinfo->ph_eval_at, innerrel->relids))
241 continue; /* it definitely doesn't reference innerrel */
242 if (bms_is_subset(phinfo->ph_needed, inputrelids))
243 continue; /* PHV is not used above the join */
244 if (!bms_is_member(sjinfo->ojrelid, phinfo->ph_eval_at))
245 return false; /* it has to be evaluated below the join */
246
247 /*
248 * We need to be sure there will still be a place to evaluate the PHV
249 * if we remove the join, ie that ph_eval_at wouldn't become empty.
250 */
251 if (!bms_overlap(sjinfo->min_lefthand, phinfo->ph_eval_at))
252 return false; /* there isn't any other place to eval PHV */
253 /* Check contained expression last, since this is a bit expensive */
254 if (bms_overlap(pull_varnos(root, (Node *) phinfo->ph_var->phexpr),
255 innerrel->relids))
256 return false; /* contained expression references innerrel */
257 }
258
259 /*
260 * Search for mergejoinable clauses that constrain the inner rel against
261 * either the outer rel or a pseudoconstant. If an operator is
262 * mergejoinable then it behaves like equality for some btree opclass, so
263 * it's what we want. The mergejoinability test also eliminates clauses
264 * containing volatile functions, which we couldn't depend on.
265 */
266 foreach(l, innerrel->joininfo)
267 {
269
270 /*
271 * If the current join commutes with some other outer join(s) via
272 * outer join identity 3, there will be multiple clones of its join
273 * clauses in the joininfo list. We want to consider only the
274 * has_clone form of such clauses. Processing more than one form
275 * would be wasteful, and also some of the others would confuse the
276 * RINFO_IS_PUSHED_DOWN test below.
277 */
278 if (restrictinfo->is_clone)
279 continue; /* ignore it */
280
281 /*
282 * If it's not a join clause for this outer join, we can't use it.
283 * Note that if the clause is pushed-down, then it is logically from
284 * above the outer join, even if it references no other rels (it might
285 * be from WHERE, for example).
286 */
288 continue; /* ignore; not useful here */
289
290 /* Ignore if it's not a mergejoinable clause */
291 if (!restrictinfo->can_join ||
292 restrictinfo->mergeopfamilies == NIL)
293 continue; /* not mergejoinable */
294
295 /*
296 * Check if the clause has the form "outer op inner" or "inner op
297 * outer", and if so mark which side is inner.
298 */
300 innerrel->relids))
301 continue; /* no good for these input relations */
302
303 /* OK, add to list */
305 }
306
307 /*
308 * Now that we have the relevant equality join clauses, try to prove the
309 * innerrel distinct.
310 */
311 if (rel_is_distinct_for(root, innerrel, clause_list, NULL))
312 return true;
313
314 /*
315 * Some day it would be nice to check for other methods of establishing
316 * distinctness.
317 */
318 return false;
319}
320
321/*
322 * Remove the target relid and references to the target join from the
323 * planner's data structures, having determined that there is no need
324 * to include them in the query.
325 *
326 * We are not terribly thorough here. We only bother to update parts of
327 * the planner's data structures that will actually be consulted later.
328 */
329static void
331 SpecialJoinInfo *sjinfo)
332{
333 RelOptInfo *rel = find_base_rel(root, relid);
334 int ojrelid = sjinfo->ojrelid;
338 ListCell *l;
339
340 /* Compute the relid set for the join we are considering */
342 Assert(ojrelid != 0);
344
345 remove_rel_from_query(root, relid, -1, sjinfo, joinrelids);
346
347 /*
348 * Remove any joinquals referencing the rel from the joininfo lists.
349 *
350 * In some cases, a joinqual has to be put back after deleting its
351 * reference to the target rel. This can occur for pseudoconstant and
352 * outerjoin-delayed quals, which can get marked as requiring the rel in
353 * order to force them to be evaluated at or above the join. We can't
354 * just discard them, though. Only quals that logically belonged to the
355 * outer join being discarded should be removed from the query.
356 *
357 * We might encounter a qual that is a clone of a deletable qual with some
358 * outer-join relids added (see deconstruct_distribute_oj_quals). To
359 * ensure we get rid of such clones as well, add the relids of all OJs
360 * commutable with this one to the set we test against for
361 * pushed-down-ness.
362 */
364 sjinfo->commute_above_r);
366 sjinfo->commute_below_l);
367
368 /*
369 * We must make a copy of the rel's old joininfo list before starting the
370 * loop, because otherwise remove_join_clause_from_rels would destroy the
371 * list while we're scanning it.
372 */
374 foreach(l, joininfos)
375 {
376 RestrictInfo *rinfo = (RestrictInfo *) lfirst(l);
377
379
381 {
382 /*
383 * There might be references to relid or ojrelid in the
384 * RestrictInfo's relid sets, as a consequence of PHVs having had
385 * ph_eval_at sets that include those. We already checked above
386 * that any such PHV is safe (and updated its ph_eval_at), so we
387 * can just drop those references.
388 */
389 remove_rel_from_restrictinfo(rinfo, relid, ojrelid);
390
391 /*
392 * Cross-check that the clause itself does not reference the
393 * target rel or join.
394 */
395#ifdef USE_ASSERT_CHECKING
396 {
398 (Node *) rinfo->clause);
399
402 }
403#endif
404 /* Now throw it back into the joininfo lists */
406 }
407 }
408
409 /*
410 * There may be references to the rel in root->fkey_list, but if so,
411 * match_foreign_keys_to_quals() will get rid of them.
412 */
413
414 /*
415 * Now remove the rel from the baserel array to prevent it from being
416 * referenced again. (We can't do this earlier because
417 * remove_join_clause_from_rels will touch it.)
418 */
419 root->simple_rel_array[relid] = NULL;
420 root->simple_rte_array[relid] = NULL;
421
422 /* And nuke the RelOptInfo, just in case there's another access path */
423 pfree(rel);
424
425 /*
426 * Now repeat construction of attr_needed bits coming from all other
427 * sources.
428 */
433}
434
435/*
436 * Remove the target relid and references to the target join from the
437 * planner's data structures, having determined that there is no need
438 * to include them in the query. Optionally replace references to the
439 * removed relid with subst if this is a self-join removal.
440 *
441 * This function serves as the common infrastructure for left-join removal
442 * and self-join elimination. It is intentionally scoped to update only the
443 * shared planner data structures that are universally affected by relation
444 * removal. Each specific caller remains responsible for updating any
445 * remaining data structures required by its unique removal logic.
446 *
447 * The specific type of removal being performed is dictated by the combination
448 * of the sjinfo and subst parameters. A non-NULL sjinfo indicates left-join
449 * removal. When sjinfo is NULL, a positive subst value indicates self-join
450 * elimination (where references are replaced with subst).
451 */
452static void
454 int subst, SpecialJoinInfo *sjinfo,
456{
457 int ojrelid = sjinfo ? sjinfo->ojrelid : 0;
458 Index rti;
459 ListCell *l;
460 bool is_outer_join = (sjinfo != NULL);
461 bool is_self_join = (!is_outer_join && subst > 0);
463
465 Assert(!is_outer_join || ojrelid > 0);
467
468 /*
469 * Update all_baserels and related relid sets.
470 */
471 root->all_baserels = adjust_relid_set(root->all_baserels, relid, subst);
472 root->all_query_rels = adjust_relid_set(root->all_query_rels, relid, subst);
473
474 if (is_outer_join)
475 {
476 root->outer_join_rels = bms_del_member(root->outer_join_rels, ojrelid);
477 root->all_query_rels = bms_del_member(root->all_query_rels, ojrelid);
478 }
479
480 /*
481 * Likewise remove references from SpecialJoinInfo data structures.
482 *
483 * This is relevant in case the relation we're deleting is part of the
484 * relid sets of special joins: those sets have to be adjusted. If we are
485 * removing an outer join, the RHS of the target outer join will be made
486 * empty here, but that's OK since the caller will delete that
487 * SpecialJoinInfo entirely.
488 */
489 foreach(l, root->join_info_list)
490 {
492
493 /*
494 * initsplan.c is fairly cavalier about allowing SpecialJoinInfos'
495 * lefthand/righthand relid sets to be shared with other data
496 * structures. Ensure that we don't modify the original relid sets.
497 * (The commute_xxx sets are always per-SpecialJoinInfo though.)
498 */
499 sjinf->min_lefthand = bms_copy(sjinf->min_lefthand);
500 sjinf->min_righthand = bms_copy(sjinf->min_righthand);
501 sjinf->syn_lefthand = bms_copy(sjinf->syn_lefthand);
502 sjinf->syn_righthand = bms_copy(sjinf->syn_righthand);
503
504 /* Now adjust relid bit in the sets: */
505 sjinf->min_lefthand = adjust_relid_set(sjinf->min_lefthand, relid, subst);
506 sjinf->min_righthand = adjust_relid_set(sjinf->min_righthand, relid, subst);
507 sjinf->syn_lefthand = adjust_relid_set(sjinf->syn_lefthand, relid, subst);
508 sjinf->syn_righthand = adjust_relid_set(sjinf->syn_righthand, relid, subst);
509
510 if (is_outer_join)
511 {
512 /* Remove ojrelid bit from the sets: */
513 sjinf->min_lefthand = bms_del_member(sjinf->min_lefthand, ojrelid);
514 sjinf->min_righthand = bms_del_member(sjinf->min_righthand, ojrelid);
515 sjinf->syn_lefthand = bms_del_member(sjinf->syn_lefthand, ojrelid);
516 sjinf->syn_righthand = bms_del_member(sjinf->syn_righthand, ojrelid);
517 /* relid cannot appear in these fields, but ojrelid can: */
518 sjinf->commute_above_l = bms_del_member(sjinf->commute_above_l, ojrelid);
519 sjinf->commute_above_r = bms_del_member(sjinf->commute_above_r, ojrelid);
520 sjinf->commute_below_l = bms_del_member(sjinf->commute_below_l, ojrelid);
521 sjinf->commute_below_r = bms_del_member(sjinf->commute_below_r, ojrelid);
522 }
523 else
524 {
525 /*
526 * For self-join removal, replace relid references in
527 * semi_rhs_exprs.
528 */
529 ChangeVarNodesExtended((Node *) sjinf->semi_rhs_exprs, relid, subst,
531 }
532 }
533
534 /*
535 * Likewise remove references from PlaceHolderVar data structures,
536 * removing any no-longer-needed placeholders entirely. We only remove
537 * PHVs for left-join removal. With self-join elimination, PHVs already
538 * get moved to the remaining relation, where they might still be needed.
539 * It might also happen that we skip the removal of some PHVs that could
540 * be removed. However, the overhead of extra PHVs is small compared to
541 * the complexity of analysis needed to remove them.
542 *
543 * Removal is a bit trickier than it might seem: we can remove PHVs that
544 * are used at the target rel and/or in the join qual, but not those that
545 * are used at join partner rels or above the join. It's not that easy to
546 * distinguish PHVs used at partner rels from those used in the join qual,
547 * since they will both have ph_needed sets that are subsets of
548 * joinrelids. However, a PHV used at a partner rel could not have the
549 * target rel in ph_eval_at, so we check that while deciding whether to
550 * remove or just update the PHV. There is no corresponding test in
551 * join_is_removable because it doesn't need to distinguish those cases.
552 */
553 foreach(l, root->placeholder_list)
554 {
556
557 Assert(!is_outer_join || !bms_is_member(relid, phinfo->ph_lateral));
558
559 if (is_outer_join &&
560 bms_is_subset(phinfo->ph_needed, joinrelids) &&
561 bms_is_member(relid, phinfo->ph_eval_at) &&
562 !bms_is_member(ojrelid, phinfo->ph_eval_at))
563 {
564 root->placeholder_list = foreach_delete_current(root->placeholder_list,
565 l);
566 root->placeholder_array[phinfo->phid] = NULL;
567 }
568 else
569 {
570 PlaceHolderVar *phv = phinfo->ph_var;
571
572 phinfo->ph_eval_at = adjust_relid_set(phinfo->ph_eval_at, relid, subst);
573 if (is_outer_join)
574 phinfo->ph_eval_at = bms_del_member(phinfo->ph_eval_at, ojrelid);
575 Assert(!bms_is_empty(phinfo->ph_eval_at)); /* checked previously */
576
577 /* Reduce ph_needed to contain only "relation 0"; see below */
578 if (bms_is_member(0, phinfo->ph_needed))
579 phinfo->ph_needed = bms_make_singleton(0);
580 else
581 phinfo->ph_needed = NULL;
582
583 phv->phrels = adjust_relid_set(phv->phrels, relid, subst);
584 if (is_outer_join)
585 phv->phrels = bms_del_member(phv->phrels, ojrelid);
586 Assert(!bms_is_empty(phv->phrels));
587
588 /*
589 * For self-join removal, update Var nodes within the PHV's
590 * expression to reference the replacement relid, and adjust
591 * ph_lateral for the relid substitution. (For left-join removal,
592 * we're removing rather than replacing, and any surviving PHV
593 * shouldn't reference the removed rel in its expression. Also,
594 * relid can't appear in ph_lateral for outer joins.)
595 */
596 if (is_self_join)
597 {
598 ChangeVarNodesExtended((Node *) phv->phexpr, relid, subst, 0,
600 phinfo->ph_lateral = adjust_relid_set(phinfo->ph_lateral, relid, subst);
601
602 /*
603 * ph_lateral might contain rels mentioned in ph_eval_at after
604 * the replacement, remove them.
605 */
606 phinfo->ph_lateral = bms_difference(phinfo->ph_lateral, phinfo->ph_eval_at);
607 /* ph_lateral might or might not be empty */
608 }
609
610 Assert(phv->phnullingrels == NULL); /* no need to adjust */
611 }
612 }
613
614 /*
615 * Likewise remove references from EquivalenceClasses.
616 *
617 * For self-join removal, the caller has already updated the
618 * EquivalenceClasses, so we can skip this step.
619 */
620 if (is_outer_join)
621 {
622 foreach(l, root->eq_classes)
623 {
625
626 remove_rel_from_eclass(root, ec, relid, ojrelid);
627 }
628 }
629
630 /*
631 * Finally, we must prepare for the caller to recompute per-Var
632 * attr_needed and per-PlaceHolderVar ph_needed relid sets. These have to
633 * be known accurately, else we may fail to remove other now-removable
634 * joins. Because the caller removes the join clause(s) associated with
635 * the removed join, Vars that were formerly needed may no longer be.
636 *
637 * The actual reconstruction of these relid sets is performed by the
638 * specific caller. Here, we simply clear out the existing attr_needed
639 * sets (we already did this above for ph_needed) to ensure they are
640 * rebuilt from scratch. We can cheat to one small extent: we can avoid
641 * re-examining the targetlist and HAVING qual by preserving "relation 0"
642 * bits from the existing relid sets. This is safe because we'd never
643 * remove such references.
644 *
645 * Additionally, if we are performing self-join elimination, we must
646 * replace references to the removed relid with subst within the
647 * lateral_vars lists.
648 *
649 * Also, for left-join removal, we strip the removed rel and join from any
650 * PlaceHolderVar embedded in the surviving rels' restriction clauses and
651 * join clauses; we needn't bother with the rel being removed, nor when
652 * the query has no PlaceHolderVars.
653 */
654 for (rti = 1; rti < root->simple_rel_array_size; rti++)
655 {
656 RelOptInfo *otherrel = root->simple_rel_array[rti];
657 int attroff;
658
659 /* there may be empty slots corresponding to non-baserel RTEs */
660 if (otherrel == NULL)
661 continue;
662
663 Assert(otherrel->relid == rti); /* sanity check on array */
664
665 for (attroff = otherrel->max_attr - otherrel->min_attr;
666 attroff >= 0;
667 attroff--)
668 {
669 if (bms_is_member(0, otherrel->attr_needed[attroff]))
670 otherrel->attr_needed[attroff] = bms_make_singleton(0);
671 else
672 otherrel->attr_needed[attroff] = NULL;
673 }
674
675 if (is_self_join)
676 ChangeVarNodesExtended((Node *) otherrel->lateral_vars, relid,
677 subst, 0, replace_relid_callback);
678
679 if (is_outer_join && rti != relid && root->glob->lastPHId != 0)
680 {
681 foreach_node(RestrictInfo, rinfo, otherrel->baserestrictinfo)
682 remove_rel_from_restrictinfo_phvs(rinfo, relid, ojrelid);
683
684 /*
685 * Join clauses need the same treatment, but there's no value in
686 * processing any join clause more than once. So it's slightly
687 * annoying that we have to find them via the per-base-relation
688 * joininfo lists. Avoid duplicate processing by tracking the
689 * rinfo_serial numbers of join clauses we've already seen. (This
690 * doesn't work for is_clone clauses, so we must waste effort on
691 * them.)
692 */
693 foreach_node(RestrictInfo, rinfo, otherrel->joininfo)
694 {
695 if (!rinfo->is_clone) /* else serial number is not unique */
696 {
697 if (bms_is_member(rinfo->rinfo_serial, seen_serials))
698 continue; /* saw it already */
700 rinfo->rinfo_serial);
701 }
702 remove_rel_from_restrictinfo_phvs(rinfo, relid, ojrelid);
703 }
704 }
705 }
706}
707
708/*
709 * Remove any references to relid or ojrelid from the RestrictInfo.
710 *
711 * We only bother to clean out bits in the RestrictInfo's various relid sets,
712 * not nullingrel bits in contained Vars and PHVs. (This might have to be
713 * improved sometime.) However, if the RestrictInfo contains an OR clause
714 * we have to also clean up the sub-clauses.
715 */
716static void
717remove_rel_from_restrictinfo(RestrictInfo *rinfo, int relid, int ojrelid)
718{
719 /*
720 * initsplan.c is fairly cavalier about allowing RestrictInfos to share
721 * relid sets with other RestrictInfos, and SpecialJoinInfos too. Make
722 * sure this RestrictInfo has its own relid sets before we modify them.
723 * (In present usage, clause_relids is probably not shared, but
724 * required_relids could be; let's not assume anything.)
725 */
726 rinfo->clause_relids = bms_copy(rinfo->clause_relids);
727 rinfo->clause_relids = bms_del_member(rinfo->clause_relids, relid);
728 rinfo->clause_relids = bms_del_member(rinfo->clause_relids, ojrelid);
729 /* Likewise for required_relids */
731 rinfo->required_relids = bms_del_member(rinfo->required_relids, relid);
732 rinfo->required_relids = bms_del_member(rinfo->required_relids, ojrelid);
733 /* Likewise for incompatible_relids */
737 /* Likewise for outer_relids */
738 rinfo->outer_relids = bms_copy(rinfo->outer_relids);
739 rinfo->outer_relids = bms_del_member(rinfo->outer_relids, relid);
740 rinfo->outer_relids = bms_del_member(rinfo->outer_relids, ojrelid);
741 /* Likewise for left_relids */
742 rinfo->left_relids = bms_copy(rinfo->left_relids);
743 rinfo->left_relids = bms_del_member(rinfo->left_relids, relid);
744 rinfo->left_relids = bms_del_member(rinfo->left_relids, ojrelid);
745 /* Likewise for right_relids */
746 rinfo->right_relids = bms_copy(rinfo->right_relids);
747 rinfo->right_relids = bms_del_member(rinfo->right_relids, relid);
748 rinfo->right_relids = bms_del_member(rinfo->right_relids, ojrelid);
749
750 /* If it's an OR, recurse to clean up sub-clauses */
751 if (restriction_is_or_clause(rinfo))
752 {
753 ListCell *lc;
754
755 Assert(is_orclause(rinfo->orclause));
756 foreach(lc, ((BoolExpr *) rinfo->orclause)->args)
757 {
758 Node *orarg = (Node *) lfirst(lc);
759
760 /* OR arguments should be ANDs or sub-RestrictInfos */
761 if (is_andclause(orarg))
762 {
763 List *andargs = ((BoolExpr *) orarg)->args;
764 ListCell *lc2;
765
766 foreach(lc2, andargs)
767 {
769
770 remove_rel_from_restrictinfo(rinfo2, relid, ojrelid);
771 }
772 }
773 else
774 {
776
777 remove_rel_from_restrictinfo(rinfo2, relid, ojrelid);
778 }
779 }
780 }
781}
782
783/*
784 * Remove any references to relid or ojrelid from the EquivalenceClass.
785 *
786 * We fix the EC and EM relid sets to ensure that implied join equalities will
787 * be generated at the appropriate join level(s). We also strip the removed
788 * rel from PlaceHolderVars embedded in member expressions; a member's
789 * em_relids reflects ph_eval_at rather than the PHV's phrels, so the latter
790 * can still mention the removed rel even when em_relids does not. Like
791 * remove_rel_from_restrictinfo, we don't bother with nullingrel bits in
792 * contained plain Vars.
793 */
794static void
796 int relid, int ojrelid)
797{
798 ListCell *lc;
799
800 /*
801 * Strip the removed rel/join from PlaceHolderVars in member expressions.
802 * This is needed even when the EC's relids don't mention the removed rel.
803 * Plain Vars and Consts can't contain a PlaceHolderVar, so skip them.
804 */
805 if (root->glob->lastPHId != 0)
806 {
808 {
809 if (!IsA(em->em_expr, Var) && !IsA(em->em_expr, Const))
810 em->em_expr = (Expr *)
811 remove_rel_from_phvs((Node *) em->em_expr, relid, ojrelid);
812 }
813 }
814
815 if (!bms_is_member(relid, ec->ec_relids) &&
816 !bms_is_member(ojrelid, ec->ec_relids))
817 return;
818
819 /* Fix up the EC's overall relids */
820 ec->ec_relids = bms_del_member(ec->ec_relids, relid);
821 ec->ec_relids = bms_del_member(ec->ec_relids, ojrelid);
822
823 /*
824 * We don't expect any EC child members to exist at this point. Ensure
825 * that's the case, otherwise, we might be getting asked to do something
826 * this function hasn't been coded for.
827 */
829
830 /*
831 * Fix up the member expressions. Any non-const member that ends with
832 * empty em_relids must be a Var or PHV of the removed relation. We don't
833 * need it anymore, so we can drop it.
834 */
835 foreach(lc, ec->ec_members)
836 {
838
839 if (bms_is_member(relid, cur_em->em_relids) ||
840 bms_is_member(ojrelid, cur_em->em_relids))
841 {
842 Assert(!cur_em->em_is_const);
843 /* em_relids is likely to be shared with some RestrictInfo */
844 cur_em->em_relids = bms_copy(cur_em->em_relids);
845 cur_em->em_relids = bms_del_member(cur_em->em_relids, relid);
846 cur_em->em_relids = bms_del_member(cur_em->em_relids, ojrelid);
847 if (bms_is_empty(cur_em->em_relids))
849 }
850 }
851
852 /* Fix up the source clauses, in case we can re-use them later */
853 foreach(lc, ec->ec_sources)
854 {
855 RestrictInfo *rinfo = (RestrictInfo *) lfirst(lc);
856
857 remove_rel_from_restrictinfo(rinfo, relid, ojrelid);
858 }
859
860 /*
861 * Rather than expend code on fixing up any already-derived clauses, just
862 * drop them. (At this point, any such clauses would be base restriction
863 * clauses, which we'd not need anymore anyway.)
864 */
866}
867
868/*
869 * Remove any references to relid or ojrelid from the PlaceHolderVars embedded
870 * in a RestrictInfo's clause.
871 *
872 * If it's an OR clause, we must also fix up the orclause, which is a parallel
873 * representation built from its own sub-RestrictInfos. We recurse into the
874 * sub-clauses for that, mirroring remove_rel_from_restrictinfo.
875 */
876static void
877remove_rel_from_restrictinfo_phvs(RestrictInfo *rinfo, int relid, int ojrelid)
878{
879 rinfo->clause = (Expr *)
880 remove_rel_from_phvs((Node *) rinfo->clause, relid, ojrelid);
881
882 /* If it's an OR, recurse to clean up sub-clauses */
883 if (restriction_is_or_clause(rinfo))
884 {
885 ListCell *lc;
886
887 Assert(is_orclause(rinfo->orclause));
888 foreach(lc, ((BoolExpr *) rinfo->orclause)->args)
889 {
890 Node *orarg = (Node *) lfirst(lc);
891
892 /* OR arguments should be ANDs or sub-RestrictInfos */
893 if (is_andclause(orarg))
894 {
895 List *andargs = ((BoolExpr *) orarg)->args;
896 ListCell *lc2;
897
898 foreach(lc2, andargs)
899 {
901
903 }
904 }
905 else
906 {
908
910 }
911 }
912 }
913}
914
915/*
916 * Remove any references to the specified RT index(es) from the phrels (and
917 * phnullingrels) of every PlaceHolderVar in the given expression.
918 *
919 * remove_rel_from_query() fixes up the relid sets of RestrictInfos and
920 * EquivalenceMembers, but not the PlaceHolderVars embedded in their
921 * expressions. That's normally fine, but such an expression may later be
922 * translated for an appendrel child and have its relids recomputed by
923 * pull_varnos(). A leftover removed relid in phrels would then make
924 * pull_varnos() reference a nonexistent rel, so we strip it here to match the
925 * canonical PlaceHolderVar.
926 */
927static Node *
928remove_rel_from_phvs(Node *node, int relid, int ojrelid)
929{
931
933}
934
935static Node *
937{
938 if (node == NULL)
939 return NULL;
940 if (IsA(node, PlaceHolderVar))
941 {
944
945 /* Upper-level PlaceHolderVars should be long gone at this point */
946 Assert(phv->phlevelsup == 0);
947
948 /* Copy the PlaceHolderVar and mutate what's below ... */
949 phv = (PlaceHolderVar *)
952 removable);
953
954 /*
955 * ... then strip the removed rels from its relid sets.
956 *
957 * If stripping would empty phrels, the PHV is evaluated only at the
958 * removed relation(s); it then belongs to an EquivalenceMember that
959 * the caller drops immediately afterwards. Leave such a PHV
960 * untouched rather than build one with empty phrels, which the rest
961 * of the planner assumes never occurs.
962 */
965 {
966 phv->phrels = newphrels;
967 phv->phnullingrels = bms_difference(phv->phnullingrels,
968 removable);
969 }
970
971 return (Node *) phv;
972 }
973 return expression_tree_mutator(node,
975 removable);
976}
977
978/*
979 * Remove any occurrences of the target relid from a joinlist structure.
980 *
981 * It's easiest to build a whole new list structure, so we handle it that
982 * way. Efficiency is not a big deal here.
983 *
984 * *nremoved is incremented by the number of occurrences removed (there
985 * should be exactly one, but the caller checks that).
986 */
987static List *
989{
990 List *result = NIL;
991 ListCell *jl;
992
993 foreach(jl, joinlist)
994 {
995 Node *jlnode = (Node *) lfirst(jl);
996
997 if (IsA(jlnode, RangeTblRef))
998 {
999 int varno = ((RangeTblRef *) jlnode)->rtindex;
1000
1001 if (varno == relid)
1002 (*nremoved)++;
1003 else
1005 }
1006 else if (IsA(jlnode, List))
1007 {
1008 /* Recurse to handle subproblem */
1009 List *sublist;
1010
1012 relid, nremoved);
1013 /* Avoid including empty sub-lists in the result */
1014 if (sublist)
1016 }
1017 else
1018 {
1019 elog(ERROR, "unrecognized joinlist node type: %d",
1020 (int) nodeTag(jlnode));
1021 }
1022 }
1023
1024 return result;
1025}
1026
1027
1028/*
1029 * reduce_unique_semijoins
1030 * Check for semijoins that can be simplified to plain inner joins
1031 * because the inner relation is provably unique for the join clauses.
1032 *
1033 * Ideally this would happen during reduce_outer_joins, but we don't have
1034 * enough information at that point.
1035 *
1036 * To perform the strength reduction when applicable, we need only delete
1037 * the semijoin's SpecialJoinInfo from root->join_info_list. (We don't
1038 * bother fixing the join type attributed to it in the query jointree,
1039 * since that won't be consulted again.)
1040 */
1041void
1043{
1044 ListCell *lc;
1045
1046 /*
1047 * Scan the join_info_list to find semijoins.
1048 */
1049 foreach(lc, root->join_info_list)
1050 {
1052 int innerrelid;
1053 RelOptInfo *innerrel;
1055 List *restrictlist;
1056
1057 /*
1058 * Must be a semijoin to a single baserel, else we aren't going to be
1059 * able to do anything with it.
1060 */
1061 if (sjinfo->jointype != JOIN_SEMI)
1062 continue;
1063
1065 continue;
1066
1067 innerrel = find_base_rel(root, innerrelid);
1068
1069 /*
1070 * Before we trouble to run generate_join_implied_equalities, make a
1071 * quick check to eliminate cases in which we will surely be unable to
1072 * prove uniqueness of the innerrel.
1073 */
1074 if (!rel_supports_distinctness(root, innerrel))
1075 continue;
1076
1077 /* Compute the relid set for the join we are considering */
1078 joinrelids = bms_union(sjinfo->min_lefthand, sjinfo->min_righthand);
1079 Assert(sjinfo->ojrelid == 0); /* SEMI joins don't have RT indexes */
1080
1081 /*
1082 * Since we're only considering a single-rel RHS, any join clauses it
1083 * has must be clauses linking it to the semijoin's min_lefthand. We
1084 * can also consider EC-derived join clauses.
1085 */
1086 restrictlist =
1088 joinrelids,
1089 sjinfo->min_lefthand,
1090 innerrel,
1091 NULL),
1092 innerrel->joininfo);
1093
1094 /* Test whether the innerrel is unique for those clauses. */
1096 joinrelids, sjinfo->min_lefthand, innerrel,
1097 JOIN_SEMI, restrictlist, true))
1098 continue;
1099
1100 /* OK, remove the SpecialJoinInfo from the list. */
1101 root->join_info_list = foreach_delete_current(root->join_info_list, lc);
1102 }
1103}
1104
1105
1106/*
1107 * rel_supports_distinctness
1108 * Could the relation possibly be proven distinct on some set of columns?
1109 *
1110 * This is effectively a pre-checking function for rel_is_distinct_for().
1111 * It must return true if rel_is_distinct_for() could possibly return true
1112 * with this rel, but it should not expend a lot of cycles. The idea is
1113 * that callers can avoid doing possibly-expensive processing to compute
1114 * rel_is_distinct_for()'s argument lists if the call could not possibly
1115 * succeed.
1116 */
1117static bool
1119{
1120 /* We only know about baserels ... */
1121 if (rel->reloptkind != RELOPT_BASEREL)
1122 return false;
1123 if (rel->rtekind == RTE_RELATION)
1124 {
1125 /*
1126 * For a plain relation, we only know how to prove uniqueness by
1127 * reference to unique indexes. Make sure there's at least one
1128 * suitable unique index. It must be immediately enforced, and not a
1129 * partial index. (Keep these conditions in sync with
1130 * relation_has_unique_index_for!)
1131 */
1132 ListCell *lc;
1133
1134 foreach(lc, rel->indexlist)
1135 {
1137
1138 if (ind->unique && ind->immediate && ind->indpred == NIL)
1139 return true;
1140 }
1141 }
1142 else if (rel->rtekind == RTE_SUBQUERY)
1143 {
1144 Query *subquery = root->simple_rte_array[rel->relid]->subquery;
1145
1146 /* Check if the subquery has any qualities that support distinctness */
1147 if (query_supports_distinctness(subquery))
1148 return true;
1149 }
1150 /* We have no proof rules for any other rtekinds. */
1151 return false;
1152}
1153
1154/*
1155 * rel_is_distinct_for
1156 * Does the relation return only distinct rows according to clause_list?
1157 *
1158 * clause_list is a list of join restriction clauses involving this rel and
1159 * some other one. Return true if no two rows emitted by this rel could
1160 * possibly join to the same row of the other rel.
1161 *
1162 * The caller must have already determined that each condition is a
1163 * mergejoinable equality with an expression in this relation on one side, and
1164 * an expression not involving this relation on the other. The transient
1165 * outer_is_left flag is used to identify which side references this relation:
1166 * left side if outer_is_left is false, right side if it is true.
1167 *
1168 * Note that the passed-in clause_list may be destructively modified! This
1169 * is OK for current uses, because the clause_list is built by the caller for
1170 * the sole purpose of passing to this function.
1171 *
1172 * (*extra_clauses) to be set to the right sides of baserestrictinfo clauses,
1173 * looking like "x = const" if distinctness is derived from such clauses, not
1174 * joininfo clauses. Pass NULL to the extra_clauses if this value is not
1175 * needed.
1176 */
1177static bool
1179 List **extra_clauses)
1180{
1181 /*
1182 * We could skip a couple of tests here if we assume all callers checked
1183 * rel_supports_distinctness first, but it doesn't seem worth taking any
1184 * risk for.
1185 */
1186 if (rel->reloptkind != RELOPT_BASEREL)
1187 return false;
1188 if (rel->rtekind == RTE_RELATION)
1189 {
1190 /*
1191 * Examine the indexes to see if we have a matching unique index.
1192 * relation_has_unique_index_for automatically adds any usable
1193 * restriction clauses for the rel, so we needn't do that here.
1194 */
1195 if (relation_has_unique_index_for(root, rel, clause_list, extra_clauses))
1196 return true;
1197 }
1198 else if (rel->rtekind == RTE_SUBQUERY)
1199 {
1200 Index relid = rel->relid;
1201 Query *subquery = root->simple_rte_array[relid]->subquery;
1203 ListCell *l;
1204
1205 /*
1206 * Build the argument list for query_is_distinct_for: a list of
1207 * DistinctColInfo entries, each holding an output column number that
1208 * the query needs to be distinct over, the equality operator that the
1209 * column needs to be distinct according to, and that operator's input
1210 * collation. The collation matters because the subquery's own
1211 * DISTINCT / GROUP BY / set-op proves uniqueness under its own
1212 * collation, which need not agree with the operator's.
1213 *
1214 * (XXX we are not considering restriction clauses attached to the
1215 * subquery; is that worth doing?)
1216 */
1217 foreach(l, clause_list)
1218 {
1220 OpExpr *opexpr;
1221 Var *var;
1223
1224 /*
1225 * The caller's mergejoinability test should have selected only
1226 * OpExprs. The operator might be a cross-type operator and thus
1227 * not exactly the same operator the subquery would consider;
1228 * that's all right since query_is_distinct_for can resolve such
1229 * cases.
1230 */
1231 opexpr = castNode(OpExpr, rinfo->clause);
1232
1233 /* caller identified the inner side for us */
1234 if (rinfo->outer_is_left)
1235 var = (Var *) get_rightop(rinfo->clause);
1236 else
1237 var = (Var *) get_leftop(rinfo->clause);
1238
1239 /*
1240 * We may ignore any RelabelType node above the operand. (There
1241 * won't be more than one, since eval_const_expressions() has been
1242 * applied already.)
1243 */
1244 if (var && IsA(var, RelabelType))
1245 var = (Var *) ((RelabelType *) var)->arg;
1246
1247 /*
1248 * If inner side isn't a Var referencing a subquery output column,
1249 * this clause doesn't help us.
1250 */
1251 if (!var || !IsA(var, Var) ||
1252 var->varno != relid || var->varlevelsup != 0)
1253 continue;
1254
1255 dcinfo = palloc(sizeof(DistinctColInfo));
1256 dcinfo->colno = var->varattno;
1257 dcinfo->opid = opexpr->opno;
1258 dcinfo->collid = opexpr->inputcollid;
1260 }
1261
1262 if (query_is_distinct_for(subquery, distinct_cols))
1263 return true;
1264 }
1265 return false;
1266}
1267
1268
1269/*
1270 * query_supports_distinctness - could the query possibly be proven distinct
1271 * on some set of output columns?
1272 *
1273 * This is effectively a pre-checking function for query_is_distinct_for().
1274 * It must return true if query_is_distinct_for() could possibly return true
1275 * with this query, but it should not expend a lot of cycles. The idea is
1276 * that callers can avoid doing possibly-expensive processing to compute
1277 * query_is_distinct_for()'s argument lists if the call could not possibly
1278 * succeed.
1279 */
1280bool
1282{
1283 /* SRFs break distinctness except with DISTINCT, see below */
1284 if (query->hasTargetSRFs && query->distinctClause == NIL)
1285 return false;
1286
1287 /* check for features we can prove distinctness with */
1288 if (query->distinctClause != NIL ||
1289 query->groupClause != NIL ||
1290 query->groupingSets != NIL ||
1291 query->hasAggs ||
1292 query->havingQual ||
1293 query->setOperations)
1294 return true;
1295
1296 return false;
1297}
1298
1299/*
1300 * query_is_distinct_for - does query never return duplicates of the
1301 * specified columns?
1302 *
1303 * query is a not-yet-planned subquery (in current usage, it's always from
1304 * a subquery RTE, which the planner avoids scribbling on).
1305 *
1306 * distinct_cols is a list of DistinctColInfo, one per requested output column.
1307 * Each entry names the subquery output column number we want distinct, the
1308 * upper-level equality operator we'll compare values with, and that operator's
1309 * input collation. We are interested in whether rows consisting of just these
1310 * columns are certain to be distinct.
1311 *
1312 * "Distinctness" is defined according to whether the corresponding upper-level
1313 * equality operators would think the values are distinct. (Note: each opid
1314 * could be a cross-type operator, and thus not exactly the equality operator
1315 * that the subquery would use itself. We use equality_ops_are_compatible() to
1316 * check compatibility. That looks at opfamily membership for index AMs that
1317 * have declared that they support consistent equality semantics within an
1318 * opfamily, and so should give trustworthy answers for all operators that we
1319 * might need to deal with here.)
1320 *
1321 * The collid must also agree on equality with the collation the subquery's own
1322 * DISTINCT/GROUP BY/set-op uses to deduplicate the column, else the subquery's
1323 * distinctness does not carry over to the caller's equality semantics. Two
1324 * collations agree on equality if they match or if both are deterministic (in
1325 * which case both reduce equality to byte-equality; see CREATE COLLATION).
1326 */
1327bool
1329{
1330 ListCell *l;
1332
1333 /*
1334 * DISTINCT (including DISTINCT ON) guarantees uniqueness if all the
1335 * columns in the DISTINCT clause appear in colnos and operator semantics
1336 * match. This is true even if there are SRFs in the DISTINCT columns or
1337 * elsewhere in the tlist.
1338 */
1339 if (query->distinctClause)
1340 {
1341 foreach(l, query->distinctClause)
1342 {
1345 query->targetList);
1346
1348 if (dcinfo == NULL ||
1349 !equality_ops_are_compatible(dcinfo->opid, sgc->eqop) ||
1351 exprCollation((Node *) tle->expr)))
1352 break; /* exit early if no match */
1353 }
1354 if (l == NULL) /* had matches for all? */
1355 return true;
1356 }
1357
1358 /*
1359 * Otherwise, a set-returning function in the query's targetlist can
1360 * result in returning duplicate rows, despite any grouping that might
1361 * occur before tlist evaluation. (If all tlist SRFs are within GROUP BY
1362 * columns, it would be safe because they'd be expanded before grouping.
1363 * But it doesn't currently seem worth the effort to check for that.)
1364 */
1365 if (query->hasTargetSRFs)
1366 return false;
1367
1368 /*
1369 * Similarly, GROUP BY without GROUPING SETS guarantees uniqueness if all
1370 * the grouped columns appear in colnos and operator semantics match.
1371 */
1372 if (query->groupClause && !query->groupingSets)
1373 {
1374 foreach(l, query->groupClause)
1375 {
1378 query->targetList);
1379
1381 if (dcinfo == NULL ||
1382 !equality_ops_are_compatible(dcinfo->opid, sgc->eqop) ||
1384 exprCollation((Node *) tle->expr)))
1385 break; /* exit early if no match */
1386 }
1387 if (l == NULL) /* had matches for all? */
1388 return true;
1389 }
1390 else if (query->groupingSets)
1391 {
1392 List *gsets;
1393
1394 /*
1395 * If we have grouping sets with expressions, we probably don't have
1396 * uniqueness and analysis would be hard. Punt.
1397 */
1398 if (query->groupClause)
1399 return false;
1400
1401 /*
1402 * If we have no groupClause (therefore no grouping expressions), we
1403 * might have one or many empty grouping sets. If there's just one,
1404 * or if the DISTINCT clause is used on the GROUP BY, then we're
1405 * returning only one row and are certainly unique. But otherwise, we
1406 * know we're certainly not unique.
1407 */
1408 if (query->groupDistinct)
1409 return true;
1410
1411 gsets = expand_grouping_sets(query->groupingSets, false, -1);
1412
1413 return (list_length(gsets) == 1);
1414 }
1415 else
1416 {
1417 /*
1418 * If we have no GROUP BY, but do have aggregates or HAVING, then the
1419 * result is at most one row so it's surely unique, for any operators.
1420 */
1421 if (query->hasAggs || query->havingQual)
1422 return true;
1423 }
1424
1425 /*
1426 * UNION, INTERSECT, EXCEPT guarantee uniqueness of the whole output row,
1427 * except with ALL.
1428 */
1429 if (query->setOperations)
1430 {
1432
1433 Assert(topop->op != SETOP_NONE);
1434
1435 if (!topop->all)
1436 {
1437 ListCell *lg;
1438
1439 /* We're good if all the nonjunk output columns are in colnos */
1440 lg = list_head(topop->groupClauses);
1441 foreach(l, query->targetList)
1442 {
1445
1446 if (tle->resjunk)
1447 continue; /* ignore resjunk columns */
1448
1449 /* non-resjunk columns should have grouping clauses */
1450 Assert(lg != NULL);
1452 lg = lnext(topop->groupClauses, lg);
1453
1455 if (dcinfo == NULL ||
1456 !equality_ops_are_compatible(dcinfo->opid, sgc->eqop) ||
1458 exprCollation((Node *) tle->expr)))
1459 break; /* exit early if no match */
1460 }
1461 if (l == NULL) /* had matches for all? */
1462 return true;
1463 }
1464 }
1465
1466 /*
1467 * XXX Are there any other cases in which we can easily see the result
1468 * must be distinct?
1469 *
1470 * If you do add more smarts to this function, be sure to update
1471 * query_supports_distinctness() to match.
1472 */
1473
1474 return false;
1475}
1476
1477/*
1478 * distinct_col_search - subroutine for query_is_distinct_for
1479 *
1480 * If colno matches the colno field of an entry in distinct_cols, return a
1481 * pointer to that entry; else return NULL. (Ordinarily distinct_cols would
1482 * not contain duplicate colnos, but if it does, we arbitrarily select the
1483 * first match.)
1484 */
1485static DistinctColInfo *
1487{
1489 {
1490 if (dcinfo->colno == colno)
1491 return dcinfo;
1492 }
1493
1494 return NULL;
1495}
1496
1497
1498/*
1499 * innerrel_is_unique
1500 * Check if the innerrel provably contains at most one tuple matching any
1501 * tuple from the outerrel, based on join clauses in the 'restrictlist'.
1502 *
1503 * We need an actual RelOptInfo for the innerrel, but it's sufficient to
1504 * identify the outerrel by its Relids. This asymmetry supports use of this
1505 * function before joinrels have been built. (The caller is expected to
1506 * also supply the joinrelids, just to save recalculating that.)
1507 *
1508 * The proof must be made based only on clauses that will be "joinquals"
1509 * rather than "otherquals" at execution. For an inner join there's no
1510 * difference; but if the join is outer, we must ignore pushed-down quals,
1511 * as those will become "otherquals". Note that this means the answer might
1512 * vary depending on whether IS_OUTER_JOIN(jointype); since we cache the
1513 * answer without regard to that, callers must take care not to call this
1514 * with jointypes that would be classified differently by IS_OUTER_JOIN().
1515 *
1516 * The actual proof is undertaken by is_innerrel_unique_for(); this function
1517 * is a frontend that is mainly concerned with caching the answers.
1518 * In particular, the force_cache argument allows overriding the internal
1519 * heuristic about whether to cache negative answers; it should be "true"
1520 * if making an inquiry that is not part of the normal bottom-up join search
1521 * sequence.
1522 */
1523bool
1526 Relids outerrelids,
1527 RelOptInfo *innerrel,
1528 JoinType jointype,
1529 List *restrictlist,
1530 bool force_cache)
1531{
1532 return innerrel_is_unique_ext(root, joinrelids, outerrelids, innerrel,
1533 jointype, restrictlist, force_cache, NULL);
1534}
1535
1536/*
1537 * innerrel_is_unique_ext
1538 * Do the same as innerrel_is_unique(), but also set to (*extra_clauses)
1539 * additional clauses from a baserestrictinfo list used to prove the
1540 * uniqueness.
1541 *
1542 * A non-NULL extra_clauses indicates that we're checking for self-join and
1543 * correspondingly dealing with filtered clauses.
1544 */
1545bool
1548 Relids outerrelids,
1549 RelOptInfo *innerrel,
1550 JoinType jointype,
1551 List *restrictlist,
1552 bool force_cache,
1553 List **extra_clauses)
1554{
1556 ListCell *lc;
1558 List *outer_exprs = NIL;
1559 bool self_join = (extra_clauses != NULL);
1560
1561 /* Certainly can't prove uniqueness when there are no joinclauses */
1562 if (restrictlist == NIL)
1563 return false;
1564
1565 /*
1566 * Make a quick check to eliminate cases in which we will surely be unable
1567 * to prove uniqueness of the innerrel.
1568 */
1569 if (!rel_supports_distinctness(root, innerrel))
1570 return false;
1571
1572 /*
1573 * Query the cache to see if we've managed to prove that innerrel is
1574 * unique for any subset of this outerrel. For non-self-join search, we
1575 * don't need an exact match, as extra outerrels can't make the innerrel
1576 * any less unique (or more formally, the restrictlist for a join to a
1577 * superset outerrel must be a superset of the conditions we successfully
1578 * used before). For self-join search, we require an exact match of
1579 * outerrels because we need extra clauses to be valid for our case. Also,
1580 * for self-join checking we've filtered the clauses list. Thus, we can
1581 * match only the result cached for a self-join search for another
1582 * self-join check.
1583 */
1584 foreach(lc, innerrel->unique_for_rels)
1585 {
1587
1588 if ((!self_join && bms_is_subset(uniqueRelInfo->outerrelids, outerrelids)) ||
1589 (self_join && bms_equal(uniqueRelInfo->outerrelids, outerrelids) &&
1590 uniqueRelInfo->self_join))
1591 {
1592 if (extra_clauses)
1593 *extra_clauses = uniqueRelInfo->extra_clauses;
1594 return true; /* Success! */
1595 }
1596 }
1597
1598 /*
1599 * Conversely, we may have already determined that this outerrel, or some
1600 * superset thereof, cannot prove this innerrel to be unique.
1601 */
1602 foreach(lc, innerrel->non_unique_for_rels)
1603 {
1604 Relids unique_for_rels = (Relids) lfirst(lc);
1605
1606 if (bms_is_subset(outerrelids, unique_for_rels))
1607 return false;
1608 }
1609
1610 /* No cached information, so try to make the proof. */
1611 if (is_innerrel_unique_for(root, joinrelids, outerrelids, innerrel,
1612 jointype, restrictlist,
1613 self_join ? &outer_exprs : NULL))
1614 {
1615 /*
1616 * Cache the positive result for future probes, being sure to keep it
1617 * in the planner_cxt even if we are working in GEQO.
1618 *
1619 * Note: one might consider trying to isolate the minimal subset of
1620 * the outerrels that proved the innerrel unique. But it's not worth
1621 * the trouble, because the planner builds up joinrels incrementally
1622 * and so we'll see the minimally sufficient outerrels before any
1623 * supersets of them anyway.
1624 */
1625 old_context = MemoryContextSwitchTo(root->planner_cxt);
1627 uniqueRelInfo->outerrelids = bms_copy(outerrelids);
1628 uniqueRelInfo->self_join = self_join;
1629 uniqueRelInfo->extra_clauses = outer_exprs;
1630 innerrel->unique_for_rels = lappend(innerrel->unique_for_rels,
1633
1634 if (extra_clauses)
1635 *extra_clauses = outer_exprs;
1636 return true; /* Success! */
1637 }
1638 else
1639 {
1640 /*
1641 * None of the join conditions for outerrel proved innerrel unique, so
1642 * we can safely reject this outerrel or any subset of it in future
1643 * checks.
1644 *
1645 * However, in normal planning mode, caching this knowledge is totally
1646 * pointless; it won't be queried again, because we build up joinrels
1647 * from smaller to larger. It's only useful when using GEQO or
1648 * another planner extension that attempts planning multiple times.
1649 *
1650 * Also, allow callers to override that heuristic and force caching;
1651 * that's useful for reduce_unique_semijoins, which calls here before
1652 * the normal join search starts.
1653 */
1654 if (force_cache || root->assumeReplanning)
1655 {
1656 old_context = MemoryContextSwitchTo(root->planner_cxt);
1657 innerrel->non_unique_for_rels =
1658 lappend(innerrel->non_unique_for_rels,
1659 bms_copy(outerrelids));
1661 }
1662
1663 return false;
1664 }
1665}
1666
1667/*
1668 * is_innerrel_unique_for
1669 * Check if the innerrel provably contains at most one tuple matching any
1670 * tuple from the outerrel, based on join clauses in the 'restrictlist'.
1671 */
1672static bool
1675 Relids outerrelids,
1676 RelOptInfo *innerrel,
1677 JoinType jointype,
1678 List *restrictlist,
1679 List **extra_clauses)
1680{
1681 List *clause_list = NIL;
1682 ListCell *lc;
1683
1684 /*
1685 * Search for mergejoinable clauses that constrain the inner rel against
1686 * the outer rel. If an operator is mergejoinable then it behaves like
1687 * equality for some btree opclass, so it's what we want. The
1688 * mergejoinability test also eliminates clauses containing volatile
1689 * functions, which we couldn't depend on.
1690 */
1691 foreach(lc, restrictlist)
1692 {
1694
1695 /*
1696 * As noted above, if it's a pushed-down clause and we're at an outer
1697 * join, we can't use it.
1698 */
1699 if (IS_OUTER_JOIN(jointype) &&
1701 continue;
1702
1703 /* Ignore if it's not a mergejoinable clause */
1704 if (!restrictinfo->can_join ||
1705 restrictinfo->mergeopfamilies == NIL)
1706 continue; /* not mergejoinable */
1707
1708 /*
1709 * Check if the clause has the form "outer op inner" or "inner op
1710 * outer", and if so mark which side is inner.
1711 */
1712 if (!clause_sides_match_join(restrictinfo, outerrelids,
1713 innerrel->relids))
1714 continue; /* no good for these input relations */
1715
1716 /* OK, add to the list */
1718 }
1719
1720 /* Let rel_is_distinct_for() do the hard work */
1721 return rel_is_distinct_for(root, innerrel, clause_list, extra_clauses);
1722}
1723
1724/*
1725 * Update EC members to point to the remaining relation instead of the removed
1726 * one, removing duplicates.
1727 *
1728 * Restriction clauses for base relations are already distributed to
1729 * the respective baserestrictinfo lists (see
1730 * generate_implied_equalities_for_column). The above code has already processed
1731 * this list and updated these clauses to reference the remaining
1732 * relation, so that we can skip them here based on their relids.
1733 *
1734 * Likewise, we have already processed the join clauses that join the
1735 * removed relation to the remaining one.
1736 *
1737 * Finally, there might be join clauses tying the removed relation to
1738 * some third relation. We can't just delete the source clauses and
1739 * regenerate them from the EC because the corresponding equality
1740 * operators might be missing (see the handling of ec_broken).
1741 * Therefore, we will update the references in the source clauses.
1742 *
1743 * Derived clauses can be generated again, so it is simpler just to
1744 * delete them.
1745 */
1746static void
1747update_eclasses(EquivalenceClass *ec, int from, int to)
1748{
1749 List *new_members = NIL;
1750 List *new_sources = NIL;
1751
1752 /*
1753 * We don't expect any EC child members to exist at this point. Ensure
1754 * that's the case, otherwise, we might be getting asked to do something
1755 * this function hasn't been coded for.
1756 */
1757 Assert(ec->ec_childmembers == NULL);
1758
1760 {
1761 bool is_redundant = false;
1762
1763 if (!bms_is_member(from, em->em_relids))
1764 {
1766 continue;
1767 }
1768
1769 em->em_relids = adjust_relid_set(em->em_relids, from, to);
1770 em->em_jdomain->jd_relids = adjust_relid_set(em->em_jdomain->jd_relids, from, to);
1771
1772 /* We only process inner joins */
1773 ChangeVarNodesExtended((Node *) em->em_expr, from, to, 0,
1775
1777 {
1778 if (!equal(em->em_relids, other->em_relids))
1779 continue;
1780
1781 if (equal(em->em_expr, other->em_expr))
1782 {
1783 is_redundant = true;
1784 break;
1785 }
1786 }
1787
1788 if (!is_redundant)
1790 }
1791
1792 list_free(ec->ec_members);
1793 ec->ec_members = new_members;
1794
1796
1797 /* Update EC source expressions */
1799 {
1800 bool is_redundant = false;
1801
1802 if (!bms_is_member(from, rinfo->required_relids))
1803 {
1805 continue;
1806 }
1807
1808 ChangeVarNodesExtended((Node *) rinfo, from, to, 0,
1810
1811 /*
1812 * After switching the clause to the remaining relation, check it for
1813 * redundancy with existing ones. We don't have to check for
1814 * redundancy with derived clauses, because we've just deleted them.
1815 */
1817 {
1818 if (!equal(rinfo->clause_relids, other->clause_relids))
1819 continue;
1820
1821 if (equal(rinfo->clause, other->clause))
1822 {
1823 is_redundant = true;
1824 break;
1825 }
1826 }
1827
1828 if (!is_redundant)
1830 }
1831
1832 list_free(ec->ec_sources);
1833 ec->ec_sources = new_sources;
1834 ec->ec_relids = adjust_relid_set(ec->ec_relids, from, to);
1835}
1836
1837/*
1838 * "Logically" compares two RestrictInfo's ignoring the 'rinfo_serial' field,
1839 * which makes almost every RestrictInfo unique. This type of comparison is
1840 * useful when removing duplicates while moving RestrictInfo's from removed
1841 * relation to remaining relation during self-join elimination.
1842 *
1843 * XXX: In the future, we might remove the 'rinfo_serial' field completely and
1844 * get rid of this function.
1845 */
1846static bool
1848{
1849 int saved_rinfo_serial = a->rinfo_serial;
1850 bool result;
1851
1852 a->rinfo_serial = b->rinfo_serial;
1853 result = equal(a, b);
1854 a->rinfo_serial = saved_rinfo_serial;
1855
1856 return result;
1857}
1858
1859/*
1860 * This function adds all non-redundant clauses to the keeping relation
1861 * during self-join elimination. That is a contradictory operation. On the
1862 * one hand, we reduce the length of the `restrict` lists, which can
1863 * impact planning or executing time. Additionally, we improve the
1864 * accuracy of cardinality estimation. On the other hand, it is one more
1865 * place that can make planning time much longer in specific cases. It
1866 * would have been better to avoid calling the equal() function here, but
1867 * it's the only way to detect duplicated inequality expressions.
1868 *
1869 * (*keep_rinfo_list) is given by pointer because it might be altered by
1870 * distribute_restrictinfo_to_rels().
1871 */
1872static void
1877{
1879 {
1880 bool is_redundant = false;
1881
1882 Assert(!bms_is_member(removed_relid, rinfo->required_relids));
1883
1885 {
1886 if (!bms_equal(src->clause_relids, rinfo->clause_relids))
1887 /* Can't compare trivially different clauses */
1888 continue;
1889
1890 if (src == rinfo ||
1891 (rinfo->parent_ec != NULL &&
1892 src->parent_ec == rinfo->parent_ec) ||
1894 {
1895 is_redundant = true;
1896 break;
1897 }
1898 }
1899 if (!is_redundant)
1901 }
1902}
1903
1904/*
1905 * A custom callback for ChangeVarNodesExtended() providing Self-join
1906 * elimination (SJE) related functionality
1907 *
1908 * SJE needs to skip the RangeTblRef node type. During SJE's last
1909 * step, remove_rel_from_joinlist() removes remaining RangeTblRefs
1910 * with target relid. If ChangeVarNodes() replaces the target relid
1911 * before, remove_rel_from_joinlist() would fail to identify the nodes
1912 * to delete.
1913 *
1914 * SJE also needs to change the relids within RestrictInfo's.
1915 */
1916static bool
1918{
1919 if (IsA(node, RangeTblRef))
1920 {
1921 return true;
1922 }
1923 else if (IsA(node, RestrictInfo))
1924 {
1925 RestrictInfo *rinfo = (RestrictInfo *) node;
1926 int relid = -1;
1927 bool is_req_equal =
1928 (rinfo->required_relids == rinfo->clause_relids);
1930 (bms_membership(rinfo->clause_relids) == BMS_MULTIPLE);
1931
1932 /*
1933 * Recurse down into clauses if the target relation is present in
1934 * clause_relids or required_relids. We must check required_relids
1935 * because the relation not present in clause_relids might still be
1936 * present somewhere in orclause.
1937 */
1938 if (bms_is_member(context->rt_index, rinfo->clause_relids) ||
1939 bms_is_member(context->rt_index, rinfo->required_relids))
1940 {
1942
1943 ChangeVarNodesWalkExpression((Node *) rinfo->clause, context);
1944 ChangeVarNodesWalkExpression((Node *) rinfo->orclause, context);
1945
1946 new_clause_relids = adjust_relid_set(rinfo->clause_relids,
1947 context->rt_index,
1948 context->new_index);
1949
1950 /*
1951 * Incrementally adjust num_base_rels based on the change of
1952 * clause_relids, which could contain both base relids and
1953 * outer-join relids. This operation is legal until we remove
1954 * only baserels.
1955 */
1956 rinfo->num_base_rels -= bms_num_members(rinfo->clause_relids) -
1958
1959 rinfo->clause_relids = new_clause_relids;
1960 rinfo->left_relids =
1961 adjust_relid_set(rinfo->left_relids, context->rt_index, context->new_index);
1962 rinfo->right_relids =
1963 adjust_relid_set(rinfo->right_relids, context->rt_index, context->new_index);
1964 }
1965
1966 if (is_req_equal)
1967 rinfo->required_relids = rinfo->clause_relids;
1968 else
1969 rinfo->required_relids =
1970 adjust_relid_set(rinfo->required_relids, context->rt_index, context->new_index);
1971
1972 rinfo->outer_relids =
1973 adjust_relid_set(rinfo->outer_relids, context->rt_index, context->new_index);
1974 rinfo->incompatible_relids =
1975 adjust_relid_set(rinfo->incompatible_relids, context->rt_index, context->new_index);
1976
1977 if (rinfo->mergeopfamilies &&
1978 bms_get_singleton_member(rinfo->clause_relids, &relid) &&
1980 relid == context->new_index && IsA(rinfo->clause, OpExpr))
1981 {
1982 Expr *leftOp;
1983 Expr *rightOp;
1984
1985 leftOp = (Expr *) get_leftop(rinfo->clause);
1986 rightOp = (Expr *) get_rightop(rinfo->clause);
1987
1988 /*
1989 * For self-join elimination, changing varnos could transform
1990 * "t1.a = t2.a" into "t1.a = t1.a". That is always true as long
1991 * as "t1.a" is not null. We use equal() to check for such a
1992 * case, and then we replace the qual with a check for not null
1993 * (NullTest).
1994 */
1995 if (leftOp != NULL && equal(leftOp, rightOp))
1996 {
1998
1999 ntest->arg = leftOp;
2000 ntest->nulltesttype = IS_NOT_NULL;
2001 ntest->argisrow = false;
2002 ntest->location = -1;
2003 rinfo->clause = (Expr *) ntest;
2004 rinfo->mergeopfamilies = NIL;
2005 rinfo->left_em = NULL;
2006 rinfo->right_em = NULL;
2007 }
2008 Assert(rinfo->orclause == NULL);
2009 }
2010 return true;
2011 }
2012
2013 return false;
2014}
2015
2016/*
2017 * Remove a relation after we have proven that it participates only in an
2018 * unneeded unique self-join.
2019 *
2020 * Replace any links in planner info structures.
2021 *
2022 * Transfer join and restriction clauses from the removed relation to the
2023 * remaining one. We change the Vars of the clause to point to the
2024 * remaining relation instead of the removed one. The clauses that require
2025 * a subset of joinrelids become restriction clauses of the remaining
2026 * relation, and others remain join clauses. We append them to
2027 * baserestrictinfo and joininfo, respectively, trying not to introduce
2028 * duplicates.
2029 *
2030 * We also have to process the 'joinclauses' list here, because it
2031 * contains EC-derived join clauses which must become filter clauses. It
2032 * is not enough to just correct the ECs because the EC-derived
2033 * restrictions are generated before join removal (see
2034 * generate_base_implied_equalities).
2035 *
2036 * NOTE: Remember to keep the code in sync with PlannerInfo to be sure all
2037 * cached relids and relid bitmapsets can be correctly cleaned during the
2038 * self-join elimination procedure.
2039 */
2040static void
2043 List *restrictlist)
2044{
2045 List *joininfos;
2046 ListCell *lc;
2047 int i;
2050
2051 Assert(toKeep->relid > 0);
2052 Assert(toRemove->relid > 0);
2053
2054 /*
2055 * Replace the index of the removing table with the keeping one. The
2056 * technique of removing/distributing restrictinfo is used here to attach
2057 * just appeared (for keeping relation) join clauses and avoid adding
2058 * duplicates of those that already exist in the joininfo list.
2059 */
2060 joininfos = list_copy(toRemove->joininfo);
2062 {
2063 remove_join_clause_from_rels(root, rinfo, rinfo->required_relids);
2064 ChangeVarNodesExtended((Node *) rinfo, toRemove->relid, toKeep->relid,
2066
2067 if (bms_membership(rinfo->required_relids) == BMS_MULTIPLE)
2069 else
2071 }
2072
2073 /*
2074 * Concatenate restrictlist to the list of base restrictions of the
2075 * removing table just to simplify the replacement procedure: all of them
2076 * weren't connected to any keeping relations and need to be added to some
2077 * rels.
2078 */
2079 toRemove->baserestrictinfo = list_concat(toRemove->baserestrictinfo,
2080 restrictlist);
2081 foreach_node(RestrictInfo, rinfo, toRemove->baserestrictinfo)
2082 {
2083 ChangeVarNodesExtended((Node *) rinfo, toRemove->relid, toKeep->relid,
2085
2086 if (bms_membership(rinfo->required_relids) == BMS_MULTIPLE)
2088 else
2090 }
2091
2092 /*
2093 * Now, add all non-redundant clauses to the keeping relation.
2094 */
2096 &toKeep->baserestrictinfo, toRemove->relid);
2098 &toKeep->joininfo, toRemove->relid);
2099
2102
2103 /*
2104 * Arrange equivalence classes, mentioned removing a table, with the
2105 * keeping one: varno of removing table should be replaced in members and
2106 * sources lists. Also, remove duplicated elements if this replacement
2107 * procedure created them.
2108 */
2109 i = -1;
2110 while ((i = bms_next_member(toRemove->eclass_indexes, i)) >= 0)
2111 {
2112 EquivalenceClass *ec = (EquivalenceClass *) list_nth(root->eq_classes, i);
2113
2114 update_eclasses(ec, toRemove->relid, toKeep->relid);
2115 toKeep->eclass_indexes = bms_add_member(toKeep->eclass_indexes, i);
2116 }
2117
2118 /*
2119 * Transfer the targetlist and attr_needed flags.
2120 */
2121
2122 foreach(lc, toRemove->reltarget->exprs)
2123 {
2124 Node *node = lfirst(lc);
2125
2126 ChangeVarNodesExtended(node, toRemove->relid, toKeep->relid, 0,
2128 if (!list_member(toKeep->reltarget->exprs, node))
2129 toKeep->reltarget->exprs = lappend(toKeep->reltarget->exprs, node);
2130 }
2131
2132 for (i = toKeep->min_attr; i <= toKeep->max_attr; i++)
2133 {
2134 int attno = i - toKeep->min_attr;
2135
2136 toRemove->attr_needed[attno] = adjust_relid_set(toRemove->attr_needed[attno],
2137 toRemove->relid, toKeep->relid);
2138 toKeep->attr_needed[attno] = bms_add_members(toKeep->attr_needed[attno],
2139 toRemove->attr_needed[attno]);
2140 }
2141
2142 /*
2143 * If the removed relation has a row mark, transfer it to the remaining
2144 * one.
2145 *
2146 * If both rels have row marks, just keep the one corresponding to the
2147 * remaining relation because we verified earlier that they have the same
2148 * strength.
2149 */
2150 if (rmark)
2151 {
2152 if (kmark)
2153 {
2154 Assert(kmark->markType == rmark->markType);
2155
2156 root->rowMarks = list_delete_ptr(root->rowMarks, rmark);
2157 }
2158 else
2159 {
2160 /* Shouldn't have inheritance children here. */
2161 Assert(rmark->rti == rmark->prti);
2162
2163 rmark->rti = rmark->prti = toKeep->relid;
2164 }
2165 }
2166
2167 /*
2168 * Replace varno in all the query structures, except nodes RangeTblRef
2169 * otherwise later remove_rel_from_joinlist will yield errors.
2170 */
2171 ChangeVarNodesExtended((Node *) root->parse, toRemove->relid, toKeep->relid,
2173
2174 /* Replace links in the planner info */
2176
2177 /* Replace varno in the fully-processed targetlist */
2178 ChangeVarNodesExtended((Node *) root->processed_tlist, toRemove->relid,
2179 toKeep->relid, 0, replace_relid_callback);
2180
2181 /*
2182 * No need to touch all_result_relids or leaf_result_relids: at this point
2183 * those sets contain only parse->resultRelation; inheritance children
2184 * have not been added yet; that happens later in add_other_rels_to_query.
2185 * And remove_self_joins_recurse rejects parse->resultRelation as an SJE
2186 * candidate to preserve the EPQ mechanism. So toRemove->relid cannot be
2187 * a member.
2188 */
2189 Assert(!bms_is_member(toRemove->relid, root->all_result_relids));
2190 Assert(!bms_is_member(toRemove->relid, root->leaf_result_relids));
2191
2192 /*
2193 * There may be references to the rel in root->fkey_list, but if so,
2194 * match_foreign_keys_to_quals() will get rid of them.
2195 */
2196
2197 /*
2198 * Finally, remove the rel from the baserel array to prevent it from being
2199 * referenced again. (We can't do this earlier because
2200 * remove_join_clause_from_rels will touch it.)
2201 */
2202 root->simple_rel_array[toRemove->relid] = NULL;
2203 root->simple_rte_array[toRemove->relid] = NULL;
2204
2205 /* And nuke the RelOptInfo, just in case there's another access path. */
2206 pfree(toRemove);
2207
2208
2209 /*
2210 * Now repeat construction of attr_needed bits coming from all other
2211 * sources.
2212 */
2217}
2218
2219/*
2220 * split_selfjoin_quals
2221 * Processes 'joinquals' by building two lists: one containing the quals
2222 * where the columns/exprs are on either side of the join match and
2223 * another one containing the remaining quals.
2224 *
2225 * 'joinquals' must only contain quals for a RTE_RELATION being joined to
2226 * itself.
2227 */
2228static void
2230 List **otherjoinquals, int from, int to)
2231{
2232 List *sjoinquals = NIL;
2233 List *ojoinquals = NIL;
2234
2236 {
2237 OpExpr *expr;
2238 Node *leftexpr;
2239 Node *rightexpr;
2240
2241 /* In general, clause looks like F(arg1) = G(arg2) */
2242 if (!rinfo->mergeopfamilies ||
2243 bms_num_members(rinfo->clause_relids) != 2 ||
2244 bms_membership(rinfo->left_relids) != BMS_SINGLETON ||
2245 bms_membership(rinfo->right_relids) != BMS_SINGLETON)
2246 {
2247 ojoinquals = lappend(ojoinquals, rinfo);
2248 continue;
2249 }
2250
2251 expr = (OpExpr *) rinfo->clause;
2252
2253 if (!IsA(expr, OpExpr) || list_length(expr->args) != 2)
2254 {
2255 ojoinquals = lappend(ojoinquals, rinfo);
2256 continue;
2257 }
2258
2259 leftexpr = get_leftop(rinfo->clause);
2260 rightexpr = copyObject(get_rightop(rinfo->clause));
2261
2263 leftexpr = (Node *) ((RelabelType *) leftexpr)->arg;
2265 rightexpr = (Node *) ((RelabelType *) rightexpr)->arg;
2266
2267 /*
2268 * Quite an expensive operation, narrowing the use case. For example,
2269 * when we have cast of the same var to different (but compatible)
2270 * types.
2271 */
2273 bms_singleton_member(rinfo->right_relids),
2274 bms_singleton_member(rinfo->left_relids), 0,
2276
2277 if (equal(leftexpr, rightexpr))
2278 sjoinquals = lappend(sjoinquals, rinfo);
2279 else
2280 ojoinquals = lappend(ojoinquals, rinfo);
2281 }
2282
2285}
2286
2287/*
2288 * Check for a case when uniqueness is at least partly derived from a
2289 * baserestrictinfo clause. In this case, we have a chance to return only
2290 * one row (if such clauses on both sides of SJ are equal) or nothing (if they
2291 * are different).
2292 */
2293static bool
2295 Index relid)
2296{
2298 {
2299 Expr *clause;
2300 Node *iclause;
2301 Node *c1;
2302 bool matched = false;
2303
2304 Assert(outer->relid > 0 && relid > 0);
2305
2306 /* Only filters like f(R.x1,...,R.xN) == expr we should consider. */
2307 Assert(bms_is_empty(rinfo->left_relids) ^
2308 bms_is_empty(rinfo->right_relids));
2309
2310 clause = (Expr *) copyObject(rinfo->clause);
2311 ChangeVarNodesExtended((Node *) clause, relid, outer->relid, 0,
2313
2314 iclause = bms_is_empty(rinfo->left_relids) ? get_rightop(clause) :
2315 get_leftop(clause);
2316 c1 = bms_is_empty(rinfo->left_relids) ? get_leftop(clause) :
2317 get_rightop(clause);
2318
2319 /*
2320 * Compare these left and right sides with the corresponding sides of
2321 * the outer's filters. If no one is detected - return immediately.
2322 */
2324 {
2325 Node *oclause;
2326 Node *c2;
2327
2328 if (orinfo->mergeopfamilies == NIL)
2329 /* Don't consider clauses that aren't similar to 'F(X)=G(Y)' */
2330 continue;
2331
2332 Assert(is_opclause(orinfo->clause));
2333
2334 oclause = bms_is_empty(orinfo->left_relids) ?
2335 get_rightop(orinfo->clause) : get_leftop(orinfo->clause);
2336 c2 = (bms_is_empty(orinfo->left_relids) ?
2337 get_leftop(orinfo->clause) : get_rightop(orinfo->clause));
2338
2339 if (equal(iclause, oclause) && equal(c1, c2))
2340 {
2341 matched = true;
2342 break;
2343 }
2344 }
2345
2346 if (!matched)
2347 return false;
2348 }
2349
2350 return true;
2351}
2352
2353/*
2354 * Find and remove unique self-joins in a group of base relations that have
2355 * the same Oid.
2356 *
2357 * Returns a set of relids that were removed.
2358 */
2359static Relids
2361{
2362 Relids result = NULL;
2363 int k; /* Index of kept relation */
2364 int r = -1; /* Index of removed relation */
2365
2366 while ((r = bms_next_member(relids, r)) > 0)
2367 {
2368 RelOptInfo *rrel = root->simple_rel_array[r];
2369
2370 k = r;
2371
2372 while ((k = bms_next_member(relids, k)) > 0)
2373 {
2375 RelOptInfo *krel = root->simple_rel_array[k];
2376 List *restrictlist;
2379 ListCell *lc;
2380 bool jinfo_check = true;
2383 List *uclauses = NIL;
2384
2385 /* A sanity check: the relations have the same Oid. */
2386 Assert(root->simple_rte_array[k]->relid ==
2387 root->simple_rte_array[r]->relid);
2388
2389 /*
2390 * It is impossible to eliminate the join of two relations if they
2391 * belong to different rules of order. Otherwise, the planner
2392 * can't find any variants of the correct query plan.
2393 */
2394 foreach(lc, root->join_info_list)
2395 {
2397
2398 if ((bms_is_member(k, info->syn_lefthand) ^
2399 bms_is_member(r, info->syn_lefthand)) ||
2400 (bms_is_member(k, info->syn_righthand) ^
2401 bms_is_member(r, info->syn_righthand)))
2402 {
2403 jinfo_check = false;
2404 break;
2405 }
2406 }
2407 if (!jinfo_check)
2408 continue;
2409
2410 /*
2411 * Check Row Marks equivalence. We can't remove the join if the
2412 * relations have row marks of different strength (e.g., one is
2413 * locked FOR UPDATE, and another just has ROW_MARK_REFERENCE for
2414 * EvalPlanQual rechecking).
2415 */
2416 foreach(lc, root->rowMarks)
2417 {
2419
2420 if (rowMark->rti == r)
2421 {
2422 Assert(rmark == NULL);
2423 rmark = rowMark;
2424 }
2425 else if (rowMark->rti == k)
2426 {
2427 Assert(kmark == NULL);
2428 kmark = rowMark;
2429 }
2430
2431 if (kmark && rmark)
2432 break;
2433 }
2434 if (kmark && rmark && kmark->markType != rmark->markType)
2435 continue;
2436
2437 /*
2438 * We only deal with base rels here, so their relids bitset
2439 * contains only one member -- their relid.
2440 */
2443
2444 /*
2445 * PHVs should not impose any constraints on removing self-joins.
2446 */
2447
2448 /*
2449 * At this stage, joininfo lists of inner and outer can contain
2450 * only clauses required for a superior outer join that can't
2451 * influence this optimization. So, we can avoid to call the
2452 * build_joinrel_restrictlist() routine.
2453 */
2455 rrel->relids,
2456 krel, NULL);
2457 if (restrictlist == NIL)
2458 continue;
2459
2460 /*
2461 * Process restrictlist to separate the self-join quals from the
2462 * other quals. e.g., "x = x" goes to selfjoinquals and "a = b" to
2463 * otherjoinquals.
2464 */
2465 split_selfjoin_quals(root, restrictlist, &selfjoinquals,
2466 &otherjoinquals, rrel->relid, krel->relid);
2467
2468 Assert(list_length(restrictlist) ==
2470
2471 /*
2472 * To enable SJE for the only degenerate case without any self
2473 * join clauses at all, add baserestrictinfo to this list. The
2474 * degenerate case works only if both sides have the same clause.
2475 * So doesn't matter which side to add.
2476 */
2477 selfjoinquals = list_concat(selfjoinquals, krel->baserestrictinfo);
2478
2479 /*
2480 * Determine if the rrel can duplicate outer rows. We must bypass
2481 * the unique rel cache here since we're possibly using a subset
2482 * of join quals. We can use 'force_cache' == true when all join
2483 * quals are self-join quals. Otherwise, we could end up putting
2484 * false negatives in the cache.
2485 */
2489 &uclauses))
2490 continue;
2491
2492 /*
2493 * 'uclauses' is the copy of outer->baserestrictinfo that are
2494 * associated with an index. We proved by matching selfjoinquals
2495 * to a unique index that the outer relation has at most one
2496 * matching row for each inner row. Sometimes that is not enough.
2497 * e.g. "WHERE s1.b = s2.b AND s1.a = 1 AND s2.a = 2" when the
2498 * unique index is (a,b). Having non-empty uclauses, we must
2499 * validate that the inner baserestrictinfo contains the same
2500 * expressions, or we won't match the same row on each side of the
2501 * join.
2502 */
2503 if (!match_unique_clauses(root, rrel, uclauses, krel->relid))
2504 continue;
2505
2506 /*
2507 * Remove rrel RelOptInfo from the planner structures and the
2508 * corresponding row mark.
2509 */
2510 remove_self_join_rel(root, kmark, rmark, krel, rrel, restrictlist);
2511
2513
2514 /* We have removed the outer relation, try the next one. */
2515 break;
2516 }
2517 }
2518
2519 return result;
2520}
2521
2522/*
2523 * Gather indexes of base relations from the joinlist and try to eliminate self
2524 * joins.
2525 */
2526static Relids
2528{
2529 ListCell *jl;
2530 Relids relids = NULL;
2532 int i;
2533 int j;
2534 int numRels;
2535
2536 /* Collect indexes of base relations of the join tree */
2537 foreach(jl, joinlist)
2538 {
2539 Node *jlnode = (Node *) lfirst(jl);
2540
2541 if (IsA(jlnode, RangeTblRef))
2542 {
2543 int varno = ((RangeTblRef *) jlnode)->rtindex;
2544 RangeTblEntry *rte = root->simple_rte_array[varno];
2545
2546 /*
2547 * We only consider ordinary relations as candidates to be
2548 * removed, and these relations should not have TABLESAMPLE
2549 * clauses specified. Removing a relation with TABLESAMPLE clause
2550 * could potentially change the syntax of the query. Because of
2551 * UPDATE/DELETE EPQ mechanism, currently Query->resultRelation or
2552 * Query->mergeTargetRelation associated rel cannot be eliminated.
2553 */
2554 if (rte->rtekind == RTE_RELATION &&
2555 rte->relkind == RELKIND_RELATION &&
2556 rte->tablesample == NULL &&
2557 varno != root->parse->resultRelation &&
2558 varno != root->parse->mergeTargetRelation)
2559 {
2560 Assert(!bms_is_member(varno, relids));
2561 relids = bms_add_member(relids, varno);
2562 }
2563 }
2564 else if (IsA(jlnode, List))
2565 {
2566 /* Recursively go inside the sub-joinlist */
2568 toRemove);
2569 }
2570 else
2571 elog(ERROR, "unrecognized joinlist node type: %d",
2572 (int) nodeTag(jlnode));
2573 }
2574
2575 numRels = bms_num_members(relids);
2576
2577 /* Need at least two relations for the join */
2578 if (numRels < 2)
2579 return toRemove;
2580
2581 /*
2582 * In order to find relations with the same oid we first build an array of
2583 * candidates and then sort it by oid.
2584 */
2586 i = -1;
2587 j = 0;
2588 while ((i = bms_next_member(relids, i)) >= 0)
2589 {
2590 candidates[j].relid = i;
2591 candidates[j].reloid = root->simple_rte_array[i]->relid;
2592 j++;
2593 }
2594
2597
2598 /*
2599 * Iteratively form a group of relation indexes with the same oid and
2600 * launch the routine that detects self-joins in this group and removes
2601 * excessive range table entries.
2602 *
2603 * At the end of the iteration, exclude the group from the overall relids
2604 * list. So each next iteration of the cycle will involve less and less
2605 * value of relids.
2606 */
2607 i = 0;
2608 for (j = 1; j < numRels + 1; j++)
2609 {
2610 if (j == numRels || candidates[j].reloid != candidates[i].reloid)
2611 {
2612 if (j - i >= 2)
2613 {
2614 /* Create a group of relation indexes with the same oid */
2615 Relids group = NULL;
2617
2618 while (i < j)
2619 {
2620 group = bms_add_member(group, candidates[i].relid);
2621 i++;
2622 }
2623 relids = bms_del_members(relids, group);
2624
2625 /*
2626 * Try to remove self-joins from a group of identical entries.
2627 * Make the next attempt iteratively - if something is deleted
2628 * from a group, changes in clauses and equivalence classes
2629 * can give us a chance to find more candidates.
2630 */
2631 do
2632 {
2633 Assert(!bms_overlap(group, toRemove));
2636 group = bms_del_members(group, removed);
2637 } while (!bms_is_empty(removed) &&
2638 bms_membership(group) == BMS_MULTIPLE);
2640 bms_free(group);
2641 }
2642 else
2643 {
2644 /* Single relation, just remove it from the set */
2645 relids = bms_del_member(relids, candidates[i].relid);
2646 i = j;
2647 }
2648 }
2649 }
2650
2651 Assert(bms_is_empty(relids));
2652
2653 return toRemove;
2654}
2655
2656/*
2657 * Compare self-join candidates by their oids.
2658 */
2659static int
2660self_join_candidates_cmp(const void *a, const void *b)
2661{
2662 const SelfJoinCandidate *ca = (const SelfJoinCandidate *) a;
2663 const SelfJoinCandidate *cb = (const SelfJoinCandidate *) b;
2664
2665 if (ca->reloid != cb->reloid)
2666 return (ca->reloid < cb->reloid ? -1 : 1);
2667 else
2668 return 0;
2669}
2670
2671/*
2672 * Find and remove useless self joins.
2673 *
2674 * Search for joins where a relation is joined to itself. If the join clause
2675 * for each tuple from one side of the join is proven to match the same
2676 * physical row (or nothing) on the other side, that self-join can be
2677 * eliminated from the query. Suitable join clauses are assumed to be in the
2678 * form of X = X, and can be replaced with NOT NULL clauses.
2679 *
2680 * For the sake of simplicity, we don't apply this optimization to special
2681 * joins. Here is a list of what we could do in some particular cases:
2682 * 'a a1 semi join a a2': is reduced to inner by reduce_unique_semijoins,
2683 * and then removed normally.
2684 * 'a a1 anti join a a2': could simplify to a scan with 'outer quals AND
2685 * (IS NULL on join columns OR NOT inner quals)'.
2686 * 'a a1 left join a a2': could simplify to a scan like inner but without
2687 * NOT NULL conditions on join columns.
2688 * 'a a1 left join (a a2 join b)': can't simplify this, because join to b
2689 * can both remove rows and introduce duplicates.
2690 *
2691 * To search for removable joins, we order all the relations on their Oid,
2692 * go over each set with the same Oid, and consider each pair of relations
2693 * in this set.
2694 *
2695 * To remove the join, we mark one of the participating relations as dead
2696 * and rewrite all references to it to point to the remaining relation.
2697 * This includes modifying RestrictInfos, EquivalenceClasses, and
2698 * EquivalenceMembers. We also have to modify the row marks. The join clauses
2699 * of the removed relation become either restriction or join clauses, based on
2700 * whether they reference any relations not participating in the removed join.
2701 *
2702 * 'joinlist' is the top-level joinlist of the query. If it has any
2703 * references to the removed relations, we update them to point to the
2704 * remaining ones.
2705 */
2706List *
2708{
2710 int relid = -1;
2711
2714 return joinlist;
2715
2716 /*
2717 * Merge pairs of relations participated in self-join. Remove unnecessary
2718 * range table entries.
2719 */
2721
2722 if (unlikely(toRemove != NULL))
2723 {
2724 /* At the end, remove orphaned relation links */
2725 while ((relid = bms_next_member(toRemove, relid)) >= 0)
2726 {
2727 int nremoved = 0;
2728
2730 if (nremoved != 1)
2731 elog(ERROR, "failed to find relation %d in joinlist", relid);
2732 }
2733 }
2734
2735 return joinlist;
2736}
static int self_join_candidates_cmp(const void *a, const void *b)
static bool match_unique_clauses(PlannerInfo *root, RelOptInfo *outer, List *uclauses, Index relid)
static bool replace_relid_callback(Node *node, ChangeVarNodes_context *context)
static void split_selfjoin_quals(PlannerInfo *root, List *joinquals, List **selfjoinquals, List **otherjoinquals, int from, int to)
static void add_non_redundant_clauses(PlannerInfo *root, List *rinfo_candidates, List **keep_rinfo_list, Index removed_relid)
static Node * remove_rel_from_phvs_mutator(Node *node, Relids removable)
static Node * remove_rel_from_phvs(Node *node, int relid, int ojrelid)
bool innerrel_is_unique(PlannerInfo *root, Relids joinrelids, Relids outerrelids, RelOptInfo *innerrel, JoinType jointype, List *restrictlist, bool force_cache)
static List * remove_rel_from_joinlist(List *joinlist, int relid, int *nremoved)
static void remove_rel_from_restrictinfo_phvs(RestrictInfo *rinfo, int relid, int ojrelid)
static void remove_leftjoinrel_from_query(PlannerInfo *root, int relid, SpecialJoinInfo *sjinfo)
static Relids remove_self_joins_one_group(PlannerInfo *root, Relids relids)
List * remove_useless_joins(PlannerInfo *root, List *joinlist)
static bool is_innerrel_unique_for(PlannerInfo *root, Relids joinrelids, Relids outerrelids, RelOptInfo *innerrel, JoinType jointype, List *restrictlist, List **extra_clauses)
static bool rel_is_distinct_for(PlannerInfo *root, RelOptInfo *rel, List *clause_list, List **extra_clauses)
bool innerrel_is_unique_ext(PlannerInfo *root, Relids joinrelids, Relids outerrelids, RelOptInfo *innerrel, JoinType jointype, List *restrictlist, bool force_cache, List **extra_clauses)
static DistinctColInfo * distinct_col_search(int colno, List *distinct_cols)
List * remove_useless_self_joins(PlannerInfo *root, List *joinlist)
bool query_supports_distinctness(Query *query)
static void update_eclasses(EquivalenceClass *ec, int from, int to)
static bool restrict_infos_logically_equal(RestrictInfo *a, RestrictInfo *b)
static Relids remove_self_joins_recurse(PlannerInfo *root, List *joinlist, Relids toRemove)
static bool join_is_removable(PlannerInfo *root, SpecialJoinInfo *sjinfo)
static void remove_rel_from_query(PlannerInfo *root, int relid, int subst, SpecialJoinInfo *sjinfo, Relids joinrelids)
void reduce_unique_semijoins(PlannerInfo *root)
bool enable_self_join_elimination
static void remove_rel_from_restrictinfo(RestrictInfo *rinfo, int relid, int ojrelid)
static bool rel_supports_distinctness(PlannerInfo *root, RelOptInfo *rel)
static void remove_self_join_rel(PlannerInfo *root, PlanRowMark *kmark, PlanRowMark *rmark, RelOptInfo *toKeep, RelOptInfo *toRemove, List *restrictlist)
static void remove_rel_from_eclass(PlannerInfo *root, EquivalenceClass *ec, int relid, int ojrelid)
bool query_is_distinct_for(Query *query, List *distinct_cols)
Bitmapset * bms_difference(const Bitmapset *a, const Bitmapset *b)
Definition bitmapset.c:347
Bitmapset * bms_make_singleton(int x)
Definition bitmapset.c:217
bool bms_equal(const Bitmapset *a, const Bitmapset *b)
Definition bitmapset.c:143
int bms_next_member(const Bitmapset *a, int prevbit)
Definition bitmapset.c:1425
Bitmapset * bms_del_members(Bitmapset *a, const Bitmapset *b)
Definition bitmapset.c:1280
Bitmapset * bms_del_member(Bitmapset *a, int x)
Definition bitmapset.c:987
bool bms_is_subset(const Bitmapset *a, const Bitmapset *b)
Definition bitmapset.c:547
int bms_singleton_member(const Bitmapset *a)
Definition bitmapset.c:800
void bms_free(Bitmapset *a)
Definition bitmapset.c:240
int bms_num_members(const Bitmapset *a)
Definition bitmapset.c:879
bool bms_is_member(int x, const Bitmapset *a)
Definition bitmapset.c:645
Bitmapset * bms_add_member(Bitmapset *a, int x)
Definition bitmapset.c:934
Bitmapset * bms_add_members(Bitmapset *a, const Bitmapset *b)
Definition bitmapset.c:1036
Bitmapset * bms_union(const Bitmapset *a, const Bitmapset *b)
Definition bitmapset.c:252
BMS_Membership bms_membership(const Bitmapset *a)
Definition bitmapset.c:900
bool bms_overlap(const Bitmapset *a, const Bitmapset *b)
Definition bitmapset.c:710
bool bms_get_singleton_member(const Bitmapset *a, int *member)
Definition bitmapset.c:843
Bitmapset * bms_copy(const Bitmapset *a)
Definition bitmapset.c:123
#define bms_is_empty(a)
Definition bitmapset.h:119
@ BMS_SINGLETON
Definition bitmapset.h:72
@ BMS_MULTIPLE
Definition bitmapset.h:73
#define Assert(condition)
Definition c.h:1002
#define unlikely(x)
Definition c.h:497
unsigned int Index
Definition c.h:757
uint32 result
Datum arg
Definition elog.c:1323
#define ERROR
Definition elog.h:40
#define elog(elevel,...)
Definition elog.h:228
bool equal(const void *a, const void *b)
Definition equalfuncs.c:223
void rebuild_eclass_attr_needed(PlannerInfo *root)
void ec_clear_derived_clauses(EquivalenceClass *ec)
List * generate_join_implied_equalities(PlannerInfo *root, Relids join_relids, Relids outer_relids, RelOptInfo *inner_rel, SpecialJoinInfo *sjinfo)
#define palloc_array(type, count)
Definition fe_memutils.h:91
bool relation_has_unique_index_for(PlannerInfo *root, RelOptInfo *rel, List *restrictlist, List **extra_clauses)
Definition indxpath.c:4144
void rebuild_lateral_attr_needed(PlannerInfo *root)
Definition initsplan.c:1245
void distribute_restrictinfo_to_rels(PlannerInfo *root, RestrictInfo *restrictinfo)
Definition initsplan.c:3629
void rebuild_joinclause_attr_needed(PlannerInfo *root)
Definition initsplan.c:3961
int b
Definition isn.c:74
int a
Definition isn.c:73
int j
Definition isn.c:78
int i
Definition isn.c:77
void remove_join_clause_from_rels(PlannerInfo *root, RestrictInfo *restrictinfo, Relids join_relids)
Definition joininfo.c:161
List * list_delete_ptr(List *list, void *datum)
Definition list.c:872
List * lappend(List *list, void *datum)
Definition list.c:339
List * list_concat(List *list1, const List *list2)
Definition list.c:561
List * list_delete_cell(List *list, ListCell *cell)
Definition list.c:841
List * list_copy(const List *oldlist)
Definition list.c:1573
void list_free(List *list)
Definition list.c:1546
bool list_member(const List *list, const void *datum)
Definition list.c:661
bool collations_agree_on_equality(Oid coll1, Oid coll2)
Definition lsyscache.c:954
bool equality_ops_are_compatible(Oid opno1, Oid opno2)
Definition lsyscache.c:841
void pfree(void *pointer)
Definition mcxt.c:1619
void * palloc(Size size)
Definition mcxt.c:1390
Oid exprCollation(const Node *expr)
Definition nodeFuncs.c:826
#define expression_tree_mutator(n, m, c)
Definition nodeFuncs.h:155
static bool is_andclause(const void *clause)
Definition nodeFuncs.h:107
static bool is_orclause(const void *clause)
Definition nodeFuncs.h:116
static Node * get_rightop(const void *clause)
Definition nodeFuncs.h:95
static bool is_opclause(const void *clause)
Definition nodeFuncs.h:76
static Node * get_leftop(const void *clause)
Definition nodeFuncs.h:83
#define IsA(nodeptr, _type_)
Definition nodes.h:162
#define copyObject(obj)
Definition nodes.h:230
#define nodeTag(nodeptr)
Definition nodes.h:137
#define IS_OUTER_JOIN(jointype)
Definition nodes.h:346
#define makeNode(_type_)
Definition nodes.h:159
#define castNode(_type_, nodeptr)
Definition nodes.h:180
JoinType
Definition nodes.h:296
@ JOIN_SEMI
Definition nodes.h:315
@ JOIN_INNER
Definition nodes.h:301
@ JOIN_LEFT
Definition nodes.h:302
static MemoryContext MemoryContextSwitchTo(MemoryContext context)
Definition palloc.h:138
List * expand_grouping_sets(List *groupingSets, bool groupDistinct, int limit)
Definition parse_agg.c:2019
@ SETOP_NONE
@ RTE_SUBQUERY
@ RTE_RELATION
#define RINFO_IS_PUSHED_DOWN(rinfo, joinrelids)
Definition pathnodes.h:3058
Bitmapset * Relids
Definition pathnodes.h:103
@ RELOPT_BASEREL
Definition pathnodes.h:977
#define lfirst(lc)
Definition pg_list.h:172
#define lfirst_node(type, lc)
Definition pg_list.h:176
static int list_length(const List *l)
Definition pg_list.h:152
#define NIL
Definition pg_list.h:68
#define foreach_delete_current(lst, var_or_cell)
Definition pg_list.h:423
#define foreach_ptr(type, var, lst)
Definition pg_list.h:501
static void * list_nth(const List *list, int n)
Definition pg_list.h:331
#define linitial(l)
Definition pg_list.h:178
#define foreach_node(type, var, lst)
Definition pg_list.h:528
static ListCell * list_head(const List *l)
Definition pg_list.h:128
static ListCell * lnext(const List *l, const ListCell *c)
Definition pg_list.h:375
void rebuild_placeholder_attr_needed(PlannerInfo *root)
#define qsort(a, b, c, d)
Definition port.h:496
unsigned int Oid
static int fb(int x)
@ IS_NOT_NULL
Definition primnodes.h:1975
tree ctl root
Definition radixtree.h:1857
RelOptInfo * find_base_rel(PlannerInfo *root, int relid)
Definition relnode.c:544
bool restriction_is_or_clause(RestrictInfo *restrictinfo)
static bool clause_sides_match_join(RestrictInfo *rinfo, Relids outerrelids, Relids innerrelids)
bool ChangeVarNodesWalkExpression(Node *node, ChangeVarNodes_context *context)
Relids adjust_relid_set(Relids relids, int oldrelid, int newrelid)
void ChangeVarNodesExtended(Node *node, int rt_index, int new_index, int sublevels_up, ChangeVarNodes_callback callback)
List ** ec_childmembers
Definition pathnodes.h:1663
Definition pg_list.h:54
Definition nodes.h:133
Oid opno
Definition primnodes.h:835
List * args
Definition primnodes.h:853
bool groupDistinct
Definition parsenodes.h:222
Node * setOperations
Definition parsenodes.h:240
List * groupClause
Definition parsenodes.h:221
Node * havingQual
Definition parsenodes.h:226
List * targetList
Definition parsenodes.h:203
List * groupingSets
Definition parsenodes.h:224
List * distinctClause
Definition parsenodes.h:230
List * baserestrictinfo
Definition pathnodes.h:1142
List * joininfo
Definition pathnodes.h:1148
Relids relids
Definition pathnodes.h:1021
Index relid
Definition pathnodes.h:1069
List * unique_for_rels
Definition pathnodes.h:1124
RelOptKind reloptkind
Definition pathnodes.h:1015
List * indexlist
Definition pathnodes.h:1091
List * non_unique_for_rels
Definition pathnodes.h:1126
AttrNumber max_attr
Definition pathnodes.h:1077
AttrNumber min_attr
Definition pathnodes.h:1075
RTEKind rtekind
Definition pathnodes.h:1073
Relids required_relids
Definition pathnodes.h:2932
Relids outer_relids
Definition pathnodes.h:2938
Relids incompatible_relids
Definition pathnodes.h:2935
Expr * clause
Definition pathnodes.h:2901
Relids commute_above_r
Definition pathnodes.h:3233
Relids syn_lefthand
Definition pathnodes.h:3228
Relids min_righthand
Definition pathnodes.h:3227
JoinType jointype
Definition pathnodes.h:3230
Relids commute_below_l
Definition pathnodes.h:3234
Relids min_lefthand
Definition pathnodes.h:3226
Relids syn_righthand
Definition pathnodes.h:3229
AttrNumber varattno
Definition primnodes.h:275
int varno
Definition primnodes.h:270
Index varlevelsup
Definition primnodes.h:295
TargetEntry * get_sortgroupclause_tle(SortGroupClause *sgClause, List *targetList)
Definition tlist.c:376
Relids pull_varnos(PlannerInfo *root, Node *node)
Definition var.c:114