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relcache.c
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1/*-------------------------------------------------------------------------
2 *
3 * relcache.c
4 * POSTGRES relation descriptor cache code
5 *
6 * Portions Copyright (c) 1996-2026, PostgreSQL Global Development Group
7 * Portions Copyright (c) 1994, Regents of the University of California
8 *
9 *
10 * IDENTIFICATION
11 * src/backend/utils/cache/relcache.c
12 *
13 *-------------------------------------------------------------------------
14 */
15/*
16 * INTERFACE ROUTINES
17 * RelationCacheInitialize - initialize relcache (to empty)
18 * RelationCacheInitializePhase2 - initialize shared-catalog entries
19 * RelationCacheInitializePhase3 - finish initializing relcache
20 * RelationIdGetRelation - get a reldesc by relation id
21 * RelationClose - close an open relation
22 *
23 * NOTES
24 * The following code contains many undocumented hacks. Please be
25 * careful....
26 */
27#include "postgres.h"
28
29#include <sys/file.h>
30#include <fcntl.h>
31#include <unistd.h>
32
33#include "access/htup_details.h"
34#include "access/multixact.h"
35#include "access/parallel.h"
36#include "access/reloptions.h"
37#include "access/sysattr.h"
38#include "access/table.h"
39#include "access/tableam.h"
41#include "access/xact.h"
43#include "catalog/catalog.h"
44#include "catalog/indexing.h"
45#include "catalog/namespace.h"
46#include "catalog/partition.h"
47#include "catalog/pg_am.h"
48#include "catalog/pg_amproc.h"
49#include "catalog/pg_attrdef.h"
51#include "catalog/pg_authid.h"
53#include "catalog/pg_database.h"
55#include "catalog/pg_opclass.h"
56#include "catalog/pg_proc.h"
58#include "catalog/pg_rewrite.h"
64#include "catalog/pg_trigger.h"
65#include "catalog/pg_type.h"
66#include "catalog/schemapg.h"
67#include "catalog/storage.h"
68#include "commands/policy.h"
70#include "commands/trigger.h"
71#include "common/int.h"
72#include "miscadmin.h"
73#include "nodes/makefuncs.h"
74#include "nodes/nodeFuncs.h"
75#include "optimizer/optimizer.h"
76#include "pgstat.h"
78#include "rewrite/rowsecurity.h"
79#include "storage/fd.h"
80#include "storage/lmgr.h"
81#include "storage/lock.h"
82#include "storage/smgr.h"
83#include "utils/array.h"
84#include "utils/builtins.h"
85#include "utils/catcache.h"
86#include "utils/datum.h"
87#include "utils/fmgroids.h"
88#include "utils/inval.h"
89#include "utils/lsyscache.h"
90#include "utils/memutils.h"
91#include "utils/relmapper.h"
92#include "utils/resowner.h"
93#include "utils/snapmgr.h"
94#include "utils/syscache.h"
95
96#define RELCACHE_INIT_FILEMAGIC 0x573266 /* version ID value */
97
98/*
99 * Whether to bother checking if relation cache memory needs to be freed
100 * eagerly. See also RelationBuildDesc() and pg_config_manual.h.
101 */
102#if defined(RECOVER_RELATION_BUILD_MEMORY) && (RECOVER_RELATION_BUILD_MEMORY != 0)
103#define MAYBE_RECOVER_RELATION_BUILD_MEMORY 1
104#else
105#define RECOVER_RELATION_BUILD_MEMORY 0
106#ifdef DISCARD_CACHES_ENABLED
107#define MAYBE_RECOVER_RELATION_BUILD_MEMORY 1
108#endif
109#endif
110
111/*
112 * hardcoded tuple descriptors, contents generated by genbki.pl
113 */
125
126/*
127 * Hash tables that index the relation cache
128 *
129 * We used to index the cache by both name and OID, but now there
130 * is only an index by OID.
131 */
137
139
140/*
141 * This flag is false until we have prepared the critical relcache entries
142 * that are needed to do indexscans on the tables read by relcache building.
143 */
145
146/*
147 * This flag is false until we have prepared the critical relcache entries
148 * for shared catalogs (which are the tables needed for login).
149 */
151
152/*
153 * This counter counts relcache inval events received since backend startup
154 * (but only for rels that are actually in cache). Presently, we use it only
155 * to detect whether data about to be written by write_relcache_init_file()
156 * might already be obsolete.
157 */
159
160/*
161 * in_progress_list is a stack of ongoing RelationBuildDesc() calls. CREATE
162 * INDEX CONCURRENTLY makes catalog changes under ShareUpdateExclusiveLock.
163 * It critically relies on each backend absorbing those changes no later than
164 * next transaction start. Hence, RelationBuildDesc() loops until it finishes
165 * without accepting a relevant invalidation. (Most invalidation consumers
166 * don't do this.)
167 */
168typedef struct inprogressent
169{
170 Oid reloid; /* OID of relation being built */
171 bool invalidated; /* whether an invalidation arrived for it */
173
177
178/*
179 * eoxact_list[] stores the OIDs of relations that (might) need AtEOXact
180 * cleanup work. This list intentionally has limited size; if it overflows,
181 * we fall back to scanning the whole hashtable. There is no value in a very
182 * large list because (1) at some point, a hash_seq_search scan is faster than
183 * retail lookups, and (2) the value of this is to reduce EOXact work for
184 * short transactions, which can't have dirtied all that many tables anyway.
185 * EOXactListAdd() does not bother to prevent duplicate list entries, so the
186 * cleanup processing must be idempotent.
187 */
188#define MAX_EOXACT_LIST 32
190static int eoxact_list_len = 0;
191static bool eoxact_list_overflowed = false;
192
193#define EOXactListAdd(rel) \
194 do { \
195 if (eoxact_list_len < MAX_EOXACT_LIST) \
196 eoxact_list[eoxact_list_len++] = (rel)->rd_id; \
197 else \
198 eoxact_list_overflowed = true; \
199 } while (0)
200
201/*
202 * EOXactTupleDescArray stores TupleDescs that (might) need AtEOXact
203 * cleanup work. The array expands as needed; there is no hashtable because
204 * we don't need to access individual items except at EOXact.
205 */
209
210/*
211 * macros to manipulate the lookup hashtable
212 */
213#define RelationCacheInsert(RELATION, replace_allowed) \
214do { \
215 RelIdCacheEnt *hentry; bool found; \
216 hentry = (RelIdCacheEnt *) hash_search(RelationIdCache, \
217 &((RELATION)->rd_id), \
218 HASH_ENTER, &found); \
219 if (found) \
220 { \
221 /* see comments in RelationBuildDesc and RelationBuildLocalRelation */ \
222 Relation _old_rel = hentry->reldesc; \
223 Assert(replace_allowed); \
224 hentry->reldesc = (RELATION); \
225 if (RelationHasReferenceCountZero(_old_rel)) \
226 RelationDestroyRelation(_old_rel, false); \
227 else if (!IsBootstrapProcessingMode()) \
228 elog(WARNING, "leaking still-referenced relcache entry for \"%s\"", \
229 RelationGetRelationName(_old_rel)); \
230 } \
231 else \
232 hentry->reldesc = (RELATION); \
233} while(0)
234
235#define RelationIdCacheLookup(ID, RELATION) \
236do { \
237 RelIdCacheEnt *hentry; \
238 hentry = (RelIdCacheEnt *) hash_search(RelationIdCache, \
239 &(ID), \
240 HASH_FIND, NULL); \
241 if (hentry) \
242 RELATION = hentry->reldesc; \
243 else \
244 RELATION = NULL; \
245} while(0)
246
247#define RelationCacheDelete(RELATION) \
248do { \
249 RelIdCacheEnt *hentry; \
250 hentry = (RelIdCacheEnt *) hash_search(RelationIdCache, \
251 &((RELATION)->rd_id), \
252 HASH_REMOVE, NULL); \
253 if (hentry == NULL) \
254 elog(WARNING, "failed to delete relcache entry for OID %u", \
255 (RELATION)->rd_id); \
256} while(0)
257
258
259/*
260 * Special cache for opclass-related information
261 *
262 * Note: only default support procs get cached, ie, those with
263 * lefttype = righttype = opcintype.
264 */
265typedef struct opclasscacheent
266{
267 Oid opclassoid; /* lookup key: OID of opclass */
268 bool valid; /* set true after successful fill-in */
269 StrategyNumber numSupport; /* max # of support procs (from pg_am) */
270 Oid opcfamily; /* OID of opclass's family */
271 Oid opcintype; /* OID of opclass's declared input type */
272 RegProcedure *supportProcs; /* OIDs of support procedures */
274
276
277
278/* non-export function prototypes */
279
280static void RelationCloseCleanup(Relation relation);
281static void RelationDestroyRelation(Relation relation, bool remember_tupdesc);
282static void RelationInvalidateRelation(Relation relation);
283static void RelationClearRelation(Relation relation);
284static void RelationRebuildRelation(Relation relation);
285
286static void RelationReloadIndexInfo(Relation relation);
287static void RelationReloadNailed(Relation relation);
288static void RelationFlushRelation(Relation relation);
290#ifdef USE_ASSERT_CHECKING
291static void AssertPendingSyncConsistency(Relation relation);
292#endif
293static void AtEOXact_cleanup(Relation relation, bool isCommit);
294static void AtEOSubXact_cleanup(Relation relation, bool isCommit,
296static bool load_relcache_init_file(bool shared);
297static void write_relcache_init_file(bool shared);
298static void write_item(const void *data, Size len, FILE *fp);
299
300static void formrdesc(const char *relationName, Oid relationReltype,
301 bool isshared, int natts, const FormData_pg_attribute *attrs);
302
305static void RelationParseRelOptions(Relation relation, HeapTuple tuple);
306static void RelationBuildTupleDesc(Relation relation);
308static void RelationInitPhysicalAddr(Relation relation);
309static void load_critical_index(Oid indexoid, Oid heapoid);
312static void AttrDefaultFetch(Relation relation, int ndef);
313static int AttrDefaultCmp(const void *a, const void *b);
314static void CheckNNConstraintFetch(Relation relation);
315static int CheckConstraintCmp(const void *a, const void *b);
316static void InitIndexAmRoutine(Relation relation);
319 Oid *opFamily,
320 Oid *opcInType,
324 StrategyNumber numSupport);
325static void RelationCacheInitFileRemoveInDir(const char *tblspcpath);
326static void unlink_initfile(const char *initfilename, int elevel);
327
328
329/*
330 * ScanPgRelation
331 *
332 * This is used by RelationBuildDesc to find a pg_class
333 * tuple matching targetRelId. The caller must hold at least
334 * AccessShareLock on the target relid to prevent concurrent-update
335 * scenarios; it isn't guaranteed that all scans used to build the
336 * relcache entry will use the same snapshot. If, for example,
337 * an attribute were to be added after scanning pg_class and before
338 * scanning pg_attribute, relnatts wouldn't match.
339 *
340 * NB: the returned tuple has been copied into palloc'd storage
341 * and must eventually be freed with heap_freetuple.
342 */
343static HeapTuple
345{
349 ScanKeyData key[1];
350 Snapshot snapshot = NULL;
351
352 /*
353 * If something goes wrong during backend startup, we might find ourselves
354 * trying to read pg_class before we've selected a database. That ain't
355 * gonna work, so bail out with a useful error message. If this happens,
356 * it probably means a relcache entry that needs to be nailed isn't.
357 */
359 elog(FATAL, "cannot read pg_class without having selected a database");
360
361 /*
362 * form a scan key
363 */
364 ScanKeyInit(&key[0],
368
369 /*
370 * Open pg_class and fetch a tuple. Force heap scan if we haven't yet
371 * built the critical relcache entries (this includes initdb and startup
372 * without a pg_internal.init file). The caller can also force a heap
373 * scan by setting indexOK == false.
374 */
376
377 /*
378 * The caller might need a tuple that's newer than what's visible to the
379 * historic snapshot; currently the only case requiring to do so is
380 * looking up the relfilenumber of non mapped system relations during
381 * decoding.
382 */
385
388 snapshot,
389 1, key);
390
392
393 /*
394 * Must copy tuple before releasing buffer.
395 */
398
399 /* all done */
401
402 if (snapshot)
403 UnregisterSnapshot(snapshot);
404
406
407 return pg_class_tuple;
408}
409
410/*
411 * AllocateRelationDesc
412 *
413 * This is used to allocate memory for a new relation descriptor
414 * and initialize the rd_rel field from the given pg_class tuple.
415 */
416static Relation
418{
419 Relation relation;
422
423 /* Relcache entries must live in CacheMemoryContext */
425
426 /*
427 * allocate and zero space for new relation descriptor
428 */
429 relation = palloc0_object(RelationData);
430
431 /* make sure relation is marked as having no open file yet */
432 relation->rd_smgr = NULL;
433
434 /*
435 * Copy the relation tuple form
436 *
437 * We only allocate space for the fixed fields, ie, CLASS_TUPLE_SIZE. The
438 * variable-length fields (relacl, reloptions) are NOT stored in the
439 * relcache --- there'd be little point in it, since we don't copy the
440 * tuple's nulls bitmap and hence wouldn't know if the values are valid.
441 * Bottom line is that relacl *cannot* be retrieved from the relcache. Get
442 * it from the syscache if you need it. The same goes for the original
443 * form of reloptions (however, we do store the parsed form of reloptions
444 * in rd_options).
445 */
447
449
450 /* initialize relation tuple form */
451 relation->rd_rel = relationForm;
452
453 /* and allocate attribute tuple form storage */
454 relation->rd_att = CreateTemplateTupleDesc(relationForm->relnatts);
455 /* which we mark as a reference-counted tupdesc */
456 relation->rd_att->tdrefcount = 1;
457
459
460 return relation;
461}
462
463/*
464 * RelationParseRelOptions
465 * Convert pg_class.reloptions into pre-parsed rd_options
466 *
467 * tuple is the real pg_class tuple (not rd_rel!) for relation
468 *
469 * Note: rd_rel and (if an index) rd_indam must be valid already
470 */
471static void
473{
474 bytea *options;
476
477 relation->rd_options = NULL;
478
479 /*
480 * Look up any AM-specific parse function; fall out if relkind should not
481 * have options.
482 */
483 switch (relation->rd_rel->relkind)
484 {
485 case RELKIND_RELATION:
487 case RELKIND_VIEW:
488 case RELKIND_MATVIEW:
490 amoptsfn = NULL;
491 break;
492 case RELKIND_INDEX:
494 amoptsfn = relation->rd_indam->amoptions;
495 break;
496 default:
497 return;
498 }
499
500 /*
501 * Fetch reloptions from tuple; have to use a hardwired descriptor because
502 * we might not have any other for pg_class yet (consider executing this
503 * code for pg_class itself)
504 */
506
507 /*
508 * Copy parsed data into CacheMemoryContext. To guard against the
509 * possibility of leaks in the reloptions code, we want to do the actual
510 * parsing in the caller's memory context and copy the results into
511 * CacheMemoryContext after the fact.
512 */
513 if (options)
514 {
518 pfree(options);
519 }
520}
521
522/*
523 * RelationBuildTupleDesc
524 *
525 * Form the relation's tuple descriptor from information in
526 * the pg_attribute, pg_attrdef & pg_constraint system catalogs.
527 */
528static void
530{
534 ScanKeyData skey[2];
535 int need;
536 TupleConstr *constr;
538 int ndef = 0;
539
540 /* fill rd_att's type ID fields (compare heap.c's AddNewRelationTuple) */
541 relation->rd_att->tdtypeid =
542 relation->rd_rel->reltype ? relation->rd_rel->reltype : RECORDOID;
543 relation->rd_att->tdtypmod = -1; /* just to be sure */
544
546 sizeof(TupleConstr));
547
548 /*
549 * Form a scan key that selects only user attributes (attnum > 0).
550 * (Eliminating system attribute rows at the index level is lots faster
551 * than fetching them.)
552 */
553 ScanKeyInit(&skey[0],
557 ScanKeyInit(&skey[1],
560 Int16GetDatum(0));
561
562 /*
563 * Open pg_attribute and begin a scan. Force heap scan if we haven't yet
564 * built the critical relcache entries (this includes initdb and startup
565 * without a pg_internal.init file).
566 */
571 NULL,
572 2, skey);
573
574 /*
575 * add attribute data to relation->rd_att
576 */
578
580 {
582 int attnum;
583
585
586 attnum = attp->attnum;
588 elog(ERROR, "invalid attribute number %d for relation \"%s\"",
589 attp->attnum, RelationGetRelationName(relation));
590
591 memcpy(TupleDescAttr(relation->rd_att, attnum - 1),
592 attp,
594
596
597 /* Update constraint/default info */
598 if (attp->attnotnull)
599 constr->has_not_null = true;
600 if (attp->attgenerated == ATTRIBUTE_GENERATED_STORED)
601 constr->has_generated_stored = true;
602 if (attp->attgenerated == ATTRIBUTE_GENERATED_VIRTUAL)
603 constr->has_generated_virtual = true;
604 if (attp->atthasdef)
605 ndef++;
606
607 /* If the column has a "missing" value, put it in the attrmiss array */
608 if (attp->atthasmissing)
609 {
611 bool missingNull;
612
613 /* Do we have a missing value? */
616 pg_attribute_desc->rd_att,
617 &missingNull);
618 if (!missingNull)
619 {
620 /* Yes, fetch from the array */
622 bool is_null;
623 int one = 1;
625
626 if (attrmiss == NULL)
629 relation->rd_rel->relnatts *
630 sizeof(AttrMissing));
631
633 1,
634 &one,
635 -1,
636 attp->attlen,
637 attp->attbyval,
638 attp->attalign,
639 &is_null);
640 Assert(!is_null);
641 if (attp->attbyval)
642 {
643 /* for copy by val just copy the datum direct */
644 attrmiss[attnum - 1].am_value = missval;
645 }
646 else
647 {
648 /* otherwise copy in the correct context */
650 attrmiss[attnum - 1].am_value = datumCopy(missval,
651 attp->attbyval,
652 attp->attlen);
654 }
655 attrmiss[attnum - 1].am_present = true;
656 }
657 }
658 need--;
659 if (need == 0)
660 break;
661 }
662
663 /*
664 * end the scan and close the attribute relation
665 */
668
669 if (need != 0)
670 elog(ERROR, "pg_attribute catalog is missing %d attribute(s) for relation OID %u",
671 need, RelationGetRelid(relation));
672
673 /*
674 * Set up constraint/default info
675 */
676 if (constr->has_not_null ||
677 constr->has_generated_stored ||
678 constr->has_generated_virtual ||
679 ndef > 0 ||
680 attrmiss ||
681 relation->rd_rel->relchecks > 0)
682 {
683 bool is_catalog = IsCatalogRelation(relation);
684
685 relation->rd_att->constr = constr;
686
687 if (ndef > 0) /* DEFAULTs */
688 AttrDefaultFetch(relation, ndef);
689 else
690 constr->num_defval = 0;
691
692 constr->missing = attrmiss;
693
694 /* CHECK and NOT NULLs */
695 if (relation->rd_rel->relchecks > 0 ||
696 (!is_catalog && constr->has_not_null))
697 CheckNNConstraintFetch(relation);
698
699 /*
700 * Any not-null constraint that wasn't marked invalid by
701 * CheckNNConstraintFetch must necessarily be valid; make it so in the
702 * CompactAttribute array.
703 */
704 if (!is_catalog)
705 {
706 for (int i = 0; i < relation->rd_rel->relnatts; i++)
707 {
708 CompactAttribute *attr;
709
710 attr = TupleDescCompactAttr(relation->rd_att, i);
711
714 else
717 }
718 }
719
720 if (relation->rd_rel->relchecks == 0)
721 constr->num_check = 0;
722 }
723 else
724 {
725 pfree(constr);
726 relation->rd_att->constr = NULL;
727 }
728
729 TupleDescFinalize(relation->rd_att);
730}
731
732/*
733 * RelationBuildRuleLock
734 *
735 * Form the relation's rewrite rules from information in
736 * the pg_rewrite system catalog.
737 *
738 * Note: The rule parsetrees are potentially very complex node structures.
739 * To allow these trees to be freed when the relcache entry is flushed,
740 * we make a private memory context to hold the RuleLock information for
741 * each relcache entry that has associated rules. The context is used
742 * just for rule info, not for any other subsidiary data of the relcache
743 * entry, because that keeps the update logic in RelationRebuildRelation()
744 * manageable. The other subsidiary data structures are simple enough
745 * to be easy to free explicitly, anyway.
746 *
747 * Note: The relation's reloptions must have been extracted first.
748 */
749static void
751{
758 ScanKeyData key;
760 int numlocks;
762 int maxlocks;
763
764 /*
765 * Make the private context. Assume it'll not contain much data.
766 */
768 "relation rules",
770 relation->rd_rulescxt = rulescxt;
772 RelationGetRelationName(relation));
773
774 /*
775 * allocate an array to hold the rewrite rules (the array is extended if
776 * necessary)
777 */
778 maxlocks = 4;
779 rules = (RewriteRule **)
780 MemoryContextAlloc(rulescxt, sizeof(RewriteRule *) * maxlocks);
781 numlocks = 0;
782
783 /*
784 * form a scan key
785 */
786 ScanKeyInit(&key,
790
791 /*
792 * open pg_rewrite and begin a scan
793 *
794 * Note: since we scan the rules using RewriteRelRulenameIndexId, we will
795 * be reading the rules in name order, except possibly during
796 * emergency-recovery operations (ie, IgnoreSystemIndexes). This in turn
797 * ensures that rules will be fired in name order.
798 */
803 true, NULL,
804 1, &key);
805
807 {
809 bool isnull;
811 char *rule_str;
813 Oid check_as_user;
814
816 sizeof(RewriteRule));
817
818 rule->ruleId = rewrite_form->oid;
819
820 rule->event = rewrite_form->ev_type - '0';
821 rule->enabled = rewrite_form->ev_enabled;
822 rule->isInstead = rewrite_form->is_instead;
823
824 /*
825 * Must use heap_getattr to fetch ev_action and ev_qual. Also, the
826 * rule strings are often large enough to be toasted. To avoid
827 * leaking memory in the caller's context, do the detoasting here so
828 * we can free the detoasted version.
829 */
833 &isnull);
834 Assert(!isnull);
837 rule->actions = (List *) stringToNode(rule_str);
840
844 &isnull);
845 Assert(!isnull);
848 rule->qual = (Node *) stringToNode(rule_str);
851
852 /*
853 * If this is a SELECT rule defining a view, and the view has
854 * "security_invoker" set, we must perform all permissions checks on
855 * relations referred to by the rule as the invoking user.
856 *
857 * In all other cases (including non-SELECT rules on security invoker
858 * views), perform the permissions checks as the relation owner.
859 */
860 if (rule->event == CMD_SELECT &&
861 relation->rd_rel->relkind == RELKIND_VIEW &&
863 check_as_user = InvalidOid;
864 else
865 check_as_user = relation->rd_rel->relowner;
866
867 /*
868 * Scan through the rule's actions and set the checkAsUser field on
869 * all RTEPermissionInfos. We have to look at the qual as well, in
870 * case it contains sublinks.
871 *
872 * The reason for doing this when the rule is loaded, rather than when
873 * it is stored, is that otherwise ALTER TABLE OWNER would have to
874 * grovel through stored rules to update checkAsUser fields. Scanning
875 * the rule tree during load is relatively cheap (compared to
876 * constructing it in the first place), so we do it here.
877 */
878 setRuleCheckAsUser((Node *) rule->actions, check_as_user);
879 setRuleCheckAsUser(rule->qual, check_as_user);
880
881 if (numlocks >= maxlocks)
882 {
883 maxlocks *= 2;
884 rules = (RewriteRule **)
885 repalloc(rules, sizeof(RewriteRule *) * maxlocks);
886 }
887 rules[numlocks++] = rule;
888 }
889
890 /*
891 * end the scan and close the attribute relation
892 */
895
896 /*
897 * there might not be any rules (if relhasrules is out-of-date)
898 */
899 if (numlocks == 0)
900 {
901 relation->rd_rules = NULL;
902 relation->rd_rulescxt = NULL;
904 return;
905 }
906
907 /*
908 * form a RuleLock and insert into relation
909 */
911 rulelock->numLocks = numlocks;
912 rulelock->rules = rules;
913
914 relation->rd_rules = rulelock;
915}
916
917/*
918 * equalRuleLocks
919 *
920 * Determine whether two RuleLocks are equivalent
921 *
922 * Probably this should be in the rules code someplace...
923 */
924static bool
926{
927 int i;
928
929 /*
930 * As of 7.3 we assume the rule ordering is repeatable, because
931 * RelationBuildRuleLock should read 'em in a consistent order. So just
932 * compare corresponding slots.
933 */
934 if (rlock1 != NULL)
935 {
936 if (rlock2 == NULL)
937 return false;
938 if (rlock1->numLocks != rlock2->numLocks)
939 return false;
940 for (i = 0; i < rlock1->numLocks; i++)
941 {
942 RewriteRule *rule1 = rlock1->rules[i];
943 RewriteRule *rule2 = rlock2->rules[i];
944
945 if (rule1->ruleId != rule2->ruleId)
946 return false;
947 if (rule1->event != rule2->event)
948 return false;
949 if (rule1->enabled != rule2->enabled)
950 return false;
951 if (rule1->isInstead != rule2->isInstead)
952 return false;
953 if (!equal(rule1->qual, rule2->qual))
954 return false;
955 if (!equal(rule1->actions, rule2->actions))
956 return false;
957 }
958 }
959 else if (rlock2 != NULL)
960 return false;
961 return true;
962}
963
964/*
965 * equalPolicy
966 *
967 * Determine whether two policies are equivalent
968 */
969static bool
971{
972 int i;
973 Oid *r1,
974 *r2;
975
976 if (policy1 != NULL)
977 {
978 if (policy2 == NULL)
979 return false;
980
981 if (policy1->polcmd != policy2->polcmd)
982 return false;
983 if (policy1->hassublinks != policy2->hassublinks)
984 return false;
985 if (strcmp(policy1->policy_name, policy2->policy_name) != 0)
986 return false;
987 if (ARR_DIMS(policy1->roles)[0] != ARR_DIMS(policy2->roles)[0])
988 return false;
989
990 r1 = (Oid *) ARR_DATA_PTR(policy1->roles);
991 r2 = (Oid *) ARR_DATA_PTR(policy2->roles);
992
993 for (i = 0; i < ARR_DIMS(policy1->roles)[0]; i++)
994 {
995 if (r1[i] != r2[i])
996 return false;
997 }
998
999 if (!equal(policy1->qual, policy2->qual))
1000 return false;
1001 if (!equal(policy1->with_check_qual, policy2->with_check_qual))
1002 return false;
1003 }
1004 else if (policy2 != NULL)
1005 return false;
1006
1007 return true;
1008}
1009
1010/*
1011 * equalRSDesc
1012 *
1013 * Determine whether two RowSecurityDesc's are equivalent
1014 */
1015static bool
1017{
1018 ListCell *lc,
1019 *rc;
1020
1021 if (rsdesc1 == NULL && rsdesc2 == NULL)
1022 return true;
1023
1024 if ((rsdesc1 != NULL && rsdesc2 == NULL) ||
1025 (rsdesc1 == NULL && rsdesc2 != NULL))
1026 return false;
1027
1028 if (list_length(rsdesc1->policies) != list_length(rsdesc2->policies))
1029 return false;
1030
1031 /* RelationBuildRowSecurity should build policies in order */
1032 forboth(lc, rsdesc1->policies, rc, rsdesc2->policies)
1033 {
1036
1037 if (!equalPolicy(l, r))
1038 return false;
1039 }
1040
1041 return true;
1042}
1043
1044/*
1045 * RelationBuildDesc
1046 *
1047 * Build a relation descriptor. The caller must hold at least
1048 * AccessShareLock on the target relid.
1049 *
1050 * The new descriptor is inserted into the hash table if insertIt is true.
1051 *
1052 * Returns NULL if no pg_class row could be found for the given relid
1053 * (suggesting we are trying to access a just-deleted relation).
1054 * Any other error is reported via elog.
1055 */
1056static Relation
1058{
1060 Relation relation;
1061 Oid relid;
1064
1065 /*
1066 * This function and its subroutines can allocate a good deal of transient
1067 * data in CurrentMemoryContext. Traditionally we've just leaked that
1068 * data, reasoning that the caller's context is at worst of transaction
1069 * scope, and relcache loads shouldn't happen so often that it's essential
1070 * to recover transient data before end of statement/transaction. However
1071 * that's definitely not true when debug_discard_caches is active, and
1072 * perhaps it's not true in other cases.
1073 *
1074 * When debug_discard_caches is active or when forced to by
1075 * RECOVER_RELATION_BUILD_MEMORY=1, arrange to allocate the junk in a
1076 * temporary context that we'll free before returning. Make it a child of
1077 * caller's context so that it will get cleaned up appropriately if we
1078 * error out partway through.
1079 */
1080#ifdef MAYBE_RECOVER_RELATION_BUILD_MEMORY
1083
1085 {
1087 "RelationBuildDesc workspace",
1090 }
1091#endif
1092
1093 /* Register to catch invalidation messages */
1095 {
1096 int allocsize;
1097
1098 allocsize = in_progress_list_maxlen * 2;
1100 allocsize * sizeof(*in_progress_list));
1101 in_progress_list_maxlen = allocsize;
1102 }
1105retry:
1107
1108 /*
1109 * find the tuple in pg_class corresponding to the given relation id
1110 */
1112
1113 /*
1114 * if no such tuple exists, return NULL
1115 */
1117 {
1118#ifdef MAYBE_RECOVER_RELATION_BUILD_MEMORY
1119 if (tmpcxt)
1120 {
1121 /* Return to caller's context, and blow away the temporary context */
1124 }
1125#endif
1128 return NULL;
1129 }
1130
1131 /*
1132 * get information from the pg_class_tuple
1133 */
1135 relid = relp->oid;
1136 Assert(relid == targetRelId);
1137
1138 /*
1139 * allocate storage for the relation descriptor, and copy pg_class_tuple
1140 * to relation->rd_rel.
1141 */
1142 relation = AllocateRelationDesc(relp);
1143
1144 /*
1145 * initialize the relation's relation id (relation->rd_id)
1146 */
1147 RelationGetRelid(relation) = relid;
1148
1149 /*
1150 * Normal relations are not nailed into the cache. Since we don't flush
1151 * new relations, it won't be new. It could be temp though.
1152 */
1153 relation->rd_refcnt = 0;
1154 relation->rd_isnailed = false;
1159 switch (relation->rd_rel->relpersistence)
1160 {
1163 relation->rd_backend = INVALID_PROC_NUMBER;
1164 relation->rd_islocaltemp = false;
1165 break;
1167 if (isTempOrTempToastNamespace(relation->rd_rel->relnamespace))
1168 {
1170 relation->rd_islocaltemp = true;
1171 }
1172 else
1173 {
1174 /*
1175 * If it's a temp table, but not one of ours, we have to use
1176 * the slow, grotty method to figure out the owning backend.
1177 *
1178 * Note: it's possible that rd_backend gets set to
1179 * MyProcNumber here, in case we are looking at a pg_class
1180 * entry left over from a crashed backend that coincidentally
1181 * had the same ProcNumber we're using. We should *not*
1182 * consider such a table to be "ours"; this is why we need the
1183 * separate rd_islocaltemp flag. The pg_class entry will get
1184 * flushed if/when we clean out the corresponding temp table
1185 * namespace in preparation for using it.
1186 */
1187 relation->rd_backend =
1188 GetTempNamespaceProcNumber(relation->rd_rel->relnamespace);
1190 relation->rd_islocaltemp = false;
1191 }
1192 break;
1193 default:
1194 elog(ERROR, "invalid relpersistence: %c",
1195 relation->rd_rel->relpersistence);
1196 break;
1197 }
1198
1199 /*
1200 * initialize the tuple descriptor (relation->rd_att).
1201 */
1202 RelationBuildTupleDesc(relation);
1203
1204 /* foreign key data is not loaded till asked for */
1205 relation->rd_fkeylist = NIL;
1206 relation->rd_fkeyvalid = false;
1207
1208 /* partitioning data is not loaded till asked for */
1209 relation->rd_partkey = NULL;
1210 relation->rd_partkeycxt = NULL;
1211 relation->rd_partdesc = NULL;
1212 relation->rd_partdesc_nodetached = NULL;
1214 relation->rd_pdcxt = NULL;
1215 relation->rd_pddcxt = NULL;
1216 relation->rd_partcheck = NIL;
1217 relation->rd_partcheckvalid = false;
1218 relation->rd_partcheckcxt = NULL;
1219
1220 /*
1221 * initialize access method information
1222 */
1223 if (relation->rd_rel->relkind == RELKIND_INDEX ||
1224 relation->rd_rel->relkind == RELKIND_PARTITIONED_INDEX)
1226 else if (RELKIND_HAS_TABLE_AM(relation->rd_rel->relkind) ||
1227 relation->rd_rel->relkind == RELKIND_SEQUENCE)
1229 else if (relation->rd_rel->relkind == RELKIND_PARTITIONED_TABLE)
1230 {
1231 /*
1232 * Do nothing: access methods are a setting that partitions can
1233 * inherit.
1234 */
1235 }
1236 else
1237 Assert(relation->rd_rel->relam == InvalidOid);
1238
1239 /* extract reloptions if any */
1241
1242 /*
1243 * Fetch rules and triggers that affect this relation.
1244 *
1245 * Note that RelationBuildRuleLock() relies on this being done after
1246 * extracting the relation's reloptions.
1247 */
1248 if (relation->rd_rel->relhasrules)
1249 RelationBuildRuleLock(relation);
1250 else
1251 {
1252 relation->rd_rules = NULL;
1253 relation->rd_rulescxt = NULL;
1254 }
1255
1256 if (relation->rd_rel->relhastriggers)
1257 RelationBuildTriggers(relation);
1258 else
1259 relation->trigdesc = NULL;
1260
1261 if (relation->rd_rel->relrowsecurity)
1262 RelationBuildRowSecurity(relation);
1263 else
1264 relation->rd_rsdesc = NULL;
1265
1266 /*
1267 * initialize the relation lock manager information
1268 */
1269 RelationInitLockInfo(relation); /* see lmgr.c */
1270
1271 /*
1272 * initialize physical addressing information for the relation
1273 */
1274 RelationInitPhysicalAddr(relation);
1275
1276 /* make sure relation is marked as having no open file yet */
1277 relation->rd_smgr = NULL;
1278
1279 /*
1280 * now we can free the memory allocated for pg_class_tuple
1281 */
1283
1284 /*
1285 * If an invalidation arrived mid-build, start over. Between here and the
1286 * end of this function, don't add code that does or reasonably could read
1287 * system catalogs. That range must be free from invalidation processing
1288 * for the !insertIt case. For the insertIt case, RelationCacheInsert()
1289 * will enroll this relation in ordinary relcache invalidation processing,
1290 */
1291 if (in_progress_list[in_progress_offset].invalidated)
1292 {
1293 RelationDestroyRelation(relation, false);
1294 goto retry;
1295 }
1298
1299 /*
1300 * Insert newly created relation into relcache hash table, if requested.
1301 *
1302 * There is one scenario in which we might find a hashtable entry already
1303 * present, even though our caller failed to find it: if the relation is a
1304 * system catalog or index that's used during relcache load, we might have
1305 * recursively created the same relcache entry during the preceding steps.
1306 * So allow RelationCacheInsert to delete any already-present relcache
1307 * entry for the same OID. The already-present entry should have refcount
1308 * zero (else somebody forgot to close it); in the event that it doesn't,
1309 * we'll elog a WARNING and leak the already-present entry.
1310 */
1311 if (insertIt)
1312 RelationCacheInsert(relation, true);
1313
1314 /* It's fully valid */
1315 relation->rd_isvalid = true;
1316
1317#ifdef MAYBE_RECOVER_RELATION_BUILD_MEMORY
1318 if (tmpcxt)
1319 {
1320 /* Return to caller's context, and blow away the temporary context */
1323 }
1324#endif
1325
1326 return relation;
1327}
1328
1329/*
1330 * Initialize the physical addressing info (RelFileLocator) for a relcache entry
1331 *
1332 * Note: at the physical level, relations in the pg_global tablespace must
1333 * be treated as shared, even if relisshared isn't set. Hence we do not
1334 * look at relisshared here.
1335 */
1336static void
1338{
1340
1341 /* these relations kinds never have storage */
1342 if (!RELKIND_HAS_STORAGE(relation->rd_rel->relkind))
1343 return;
1344
1345 if (relation->rd_rel->reltablespace)
1346 relation->rd_locator.spcOid = relation->rd_rel->reltablespace;
1347 else
1349 if (relation->rd_locator.spcOid == GLOBALTABLESPACE_OID)
1350 relation->rd_locator.dbOid = InvalidOid;
1351 else
1352 relation->rd_locator.dbOid = MyDatabaseId;
1353
1354 if (relation->rd_rel->relfilenode)
1355 {
1356 /*
1357 * Even if we are using a decoding snapshot that doesn't represent the
1358 * current state of the catalog we need to make sure the filenode
1359 * points to the current file since the older file will be gone (or
1360 * truncated). The new file will still contain older rows so lookups
1361 * in them will work correctly. This wouldn't work correctly if
1362 * rewrites were allowed to change the schema in an incompatible way,
1363 * but those are prevented both on catalog tables and on user tables
1364 * declared as additional catalog tables.
1365 */
1368 && IsTransactionState())
1369 {
1372
1374 RelationGetRelid(relation) != ClassOidIndexId,
1375 true);
1377 elog(ERROR, "could not find pg_class entry for %u",
1378 RelationGetRelid(relation));
1380
1381 relation->rd_rel->reltablespace = physrel->reltablespace;
1382 relation->rd_rel->relfilenode = physrel->relfilenode;
1384 }
1385
1386 relation->rd_locator.relNumber = relation->rd_rel->relfilenode;
1387 }
1388 else
1389 {
1390 /* Consult the relation mapper */
1391 relation->rd_locator.relNumber =
1393 relation->rd_rel->relisshared);
1395 elog(ERROR, "could not find relation mapping for relation \"%s\", OID %u",
1396 RelationGetRelationName(relation), relation->rd_id);
1397 }
1398
1399 /*
1400 * For RelationNeedsWAL() to answer correctly on parallel workers, restore
1401 * rd_firstRelfilelocatorSubid. No subtransactions start or end while in
1402 * parallel mode, so the specific SubTransactionId does not matter.
1403 */
1404 if (IsParallelWorker() && oldnumber != relation->rd_locator.relNumber)
1405 {
1408 else
1410 }
1411}
1412
1413/*
1414 * Fill in the IndexAmRoutine for an index relation.
1415 *
1416 * relation's rd_amhandler and rd_indexcxt must be valid already.
1417 */
1418static void
1420{
1422
1423 /*
1424 * We formerly specified that the amhandler should return a palloc'd
1425 * struct. That's now deprecated in favor of returning a pointer to a
1426 * static struct, but to avoid completely breaking old external AMs, run
1427 * the amhandler in the relation's rd_indexcxt.
1428 */
1430 relation->rd_indam = GetIndexAmRoutine(relation->rd_amhandler);
1432}
1433
1434/*
1435 * Initialize index-access-method support data for an index relation
1436 */
1437void
1439{
1440 HeapTuple tuple;
1445 bool isnull;
1450 MemoryContext oldcontext;
1451 int indnatts;
1452 int indnkeyatts;
1453 uint16 amsupport;
1454
1455 /*
1456 * Make a copy of the pg_index entry for the index. Since pg_index
1457 * contains variable-length and possibly-null fields, we have to do this
1458 * honestly rather than just treating it as a Form_pg_index struct.
1459 */
1462 if (!HeapTupleIsValid(tuple))
1463 elog(ERROR, "cache lookup failed for index %u",
1464 RelationGetRelid(relation));
1466 relation->rd_indextuple = heap_copytuple(tuple);
1467 relation->rd_index = (Form_pg_index) GETSTRUCT(relation->rd_indextuple);
1468 MemoryContextSwitchTo(oldcontext);
1469 ReleaseSysCache(tuple);
1470
1471 /*
1472 * Look up the index's access method, save the OID of its handler function
1473 */
1474 Assert(relation->rd_rel->relam != InvalidOid);
1475 tuple = SearchSysCache1(AMOID, ObjectIdGetDatum(relation->rd_rel->relam));
1476 if (!HeapTupleIsValid(tuple))
1477 elog(ERROR, "cache lookup failed for access method %u",
1478 relation->rd_rel->relam);
1479 aform = (Form_pg_am) GETSTRUCT(tuple);
1480 relation->rd_amhandler = aform->amhandler;
1481 ReleaseSysCache(tuple);
1482
1485 elog(ERROR, "relnatts disagrees with indnatts for index %u",
1486 RelationGetRelid(relation));
1488
1489 /*
1490 * Make the private context to hold index access info. The reason we need
1491 * a context, and not just a couple of pallocs, is so that we won't leak
1492 * any subsidiary info attached to fmgr lookup records.
1493 */
1495 "index info",
1497 relation->rd_indexcxt = indexcxt;
1499 RelationGetRelationName(relation));
1500
1501 /*
1502 * Now we can fetch the index AM's API struct
1503 */
1504 InitIndexAmRoutine(relation);
1505
1506 /*
1507 * Allocate arrays to hold data. Opclasses are not used for included
1508 * columns, so allocate them for indnkeyatts only.
1509 */
1510 relation->rd_opfamily = (Oid *)
1512 relation->rd_opcintype = (Oid *)
1514
1515 amsupport = relation->rd_indam->amsupport;
1516 if (amsupport > 0)
1517 {
1518 int nsupport = indnatts * amsupport;
1519
1520 relation->rd_support = (RegProcedure *)
1522 relation->rd_supportinfo = (FmgrInfo *)
1524 }
1525 else
1526 {
1527 relation->rd_support = NULL;
1528 relation->rd_supportinfo = NULL;
1529 }
1530
1531 relation->rd_indcollation = (Oid *)
1533
1534 relation->rd_indoption = (int16 *)
1536
1537 /*
1538 * indcollation cannot be referenced directly through the C struct,
1539 * because it comes after the variable-width indkey field. Must extract
1540 * the datum the hard way...
1541 */
1545 &isnull);
1546 Assert(!isnull);
1548 memcpy(relation->rd_indcollation, indcoll->values, indnkeyatts * sizeof(Oid));
1549
1550 /*
1551 * indclass cannot be referenced directly through the C struct, because it
1552 * comes after the variable-width indkey field. Must extract the datum
1553 * the hard way...
1554 */
1558 &isnull);
1559 Assert(!isnull);
1561
1562 /*
1563 * Fill the support procedure OID array, as well as the info about
1564 * opfamilies and opclass input types. (aminfo and supportinfo are left
1565 * as zeroes, and are filled on-the-fly when used)
1566 */
1568 relation->rd_opfamily, relation->rd_opcintype,
1569 amsupport, indnkeyatts);
1570
1571 /*
1572 * Similarly extract indoption and copy it to the cache entry
1573 */
1577 &isnull);
1578 Assert(!isnull);
1580 memcpy(relation->rd_indoption, indoption->values, indnkeyatts * sizeof(int16));
1581
1582 (void) RelationGetIndexAttOptions(relation, false);
1583
1584 /*
1585 * expressions, predicate, exclusion caches will be filled later
1586 */
1587 relation->rd_indexprs = NIL;
1588 relation->rd_indpred = NIL;
1589 relation->rd_exclops = NULL;
1590 relation->rd_exclprocs = NULL;
1591 relation->rd_exclstrats = NULL;
1592 relation->rd_amcache = NULL;
1593}
1594
1595/*
1596 * IndexSupportInitialize
1597 * Initializes an index's cached opclass information,
1598 * given the index's pg_index.indclass entry.
1599 *
1600 * Data is returned into *indexSupport, *opFamily, and *opcInType,
1601 * which are arrays allocated by the caller.
1602 *
1603 * The caller also passes maxSupportNumber and maxAttributeNumber, since these
1604 * indicate the size of the arrays it has allocated --- but in practice these
1605 * numbers must always match those obtainable from the system catalog entries
1606 * for the index and access method.
1607 */
1608static void
1611 Oid *opFamily,
1612 Oid *opcInType,
1615{
1616 int attIndex;
1617
1619 {
1621
1622 if (!OidIsValid(indclass->values[attIndex]))
1623 elog(ERROR, "bogus pg_index tuple");
1624
1625 /* look up the info for this opclass, using a cache */
1628
1629 /* copy cached data into relcache entry */
1630 opFamily[attIndex] = opcentry->opcfamily;
1631 opcInType[attIndex] = opcentry->opcintype;
1632 if (maxSupportNumber > 0)
1634 opcentry->supportProcs,
1635 maxSupportNumber * sizeof(RegProcedure));
1636 }
1637}
1638
1639/*
1640 * LookupOpclassInfo
1641 *
1642 * This routine maintains a per-opclass cache of the information needed
1643 * by IndexSupportInitialize(). This is more efficient than relying on
1644 * the catalog cache, because we can load all the info about a particular
1645 * opclass in a single indexscan of pg_amproc.
1646 *
1647 * The information from pg_am about expected range of support function
1648 * numbers is passed in, rather than being looked up, mainly because the
1649 * caller will have it already.
1650 *
1651 * Note there is no provision for flushing the cache. This is OK at the
1652 * moment because there is no way to ALTER any interesting properties of an
1653 * existing opclass --- all you can do is drop it, which will result in
1654 * a useless but harmless dead entry in the cache. To support altering
1655 * opclass membership (not the same as opfamily membership!), we'd need to
1656 * be able to flush this cache as well as the contents of relcache entries
1657 * for indexes.
1658 */
1659static OpClassCacheEnt *
1661 StrategyNumber numSupport)
1662{
1664 bool found;
1665 Relation rel;
1666 SysScanDesc scan;
1667 ScanKeyData skey[3];
1668 HeapTuple htup;
1669 bool indexOK;
1670
1671 if (OpClassCache == NULL)
1672 {
1673 /* First time through: initialize the opclass cache */
1674 HASHCTL ctl;
1675
1676 /* Also make sure CacheMemoryContext exists */
1677 if (!CacheMemoryContext)
1679
1680 ctl.keysize = sizeof(Oid);
1681 ctl.entrysize = sizeof(OpClassCacheEnt);
1682 OpClassCache = hash_create("Operator class cache", 64,
1684 }
1685
1688 HASH_ENTER, &found);
1689
1690 if (!found)
1691 {
1692 /* Initialize new entry */
1693 opcentry->valid = false; /* until known OK */
1694 opcentry->numSupport = numSupport;
1695 opcentry->supportProcs = NULL; /* filled below */
1696 }
1697 else
1698 {
1699 Assert(numSupport == opcentry->numSupport);
1700 }
1701
1702 /*
1703 * When aggressively testing cache-flush hazards, we disable the operator
1704 * class cache and force reloading of the info on each call. This models
1705 * no real-world behavior, since the cache entries are never invalidated
1706 * otherwise. However it can be helpful for detecting bugs in the cache
1707 * loading logic itself, such as reliance on a non-nailed index. Given
1708 * the limited use-case and the fact that this adds a great deal of
1709 * expense, we enable it only for high values of debug_discard_caches.
1710 */
1711#ifdef DISCARD_CACHES_ENABLED
1712 if (debug_discard_caches > 2)
1713 opcentry->valid = false;
1714#endif
1715
1716 if (opcentry->valid)
1717 return opcentry;
1718
1719 /*
1720 * Need to fill in new entry. First allocate space, unless we already did
1721 * so in some previous attempt.
1722 */
1723 if (opcentry->supportProcs == NULL && numSupport > 0)
1724 opcentry->supportProcs = (RegProcedure *)
1726 numSupport * sizeof(RegProcedure));
1727
1728 /*
1729 * To avoid infinite recursion during startup, force heap scans if we're
1730 * looking up info for the opclasses used by the indexes we would like to
1731 * reference here.
1732 */
1736
1737 /*
1738 * We have to fetch the pg_opclass row to determine its opfamily and
1739 * opcintype, which are needed to look up related operators and functions.
1740 * It'd be convenient to use the syscache here, but that probably doesn't
1741 * work while bootstrapping.
1742 */
1743 ScanKeyInit(&skey[0],
1749 NULL, 1, skey);
1750
1751 if (HeapTupleIsValid(htup = systable_getnext(scan)))
1752 {
1754
1755 opcentry->opcfamily = opclassform->opcfamily;
1756 opcentry->opcintype = opclassform->opcintype;
1757 }
1758 else
1759 elog(ERROR, "could not find tuple for opclass %u", operatorClassOid);
1760
1761 systable_endscan(scan);
1763
1764 /*
1765 * Scan pg_amproc to obtain support procs for the opclass. We only fetch
1766 * the default ones (those with lefttype = righttype = opcintype).
1767 */
1768 if (numSupport > 0)
1769 {
1770 ScanKeyInit(&skey[0],
1773 ObjectIdGetDatum(opcentry->opcfamily));
1774 ScanKeyInit(&skey[1],
1777 ObjectIdGetDatum(opcentry->opcintype));
1778 ScanKeyInit(&skey[2],
1781 ObjectIdGetDatum(opcentry->opcintype));
1784 NULL, 3, skey);
1785
1786 while (HeapTupleIsValid(htup = systable_getnext(scan)))
1787 {
1789
1790 if (amprocform->amprocnum <= 0 ||
1791 (StrategyNumber) amprocform->amprocnum > numSupport)
1792 elog(ERROR, "invalid amproc number %d for opclass %u",
1793 amprocform->amprocnum, operatorClassOid);
1794
1795 opcentry->supportProcs[amprocform->amprocnum - 1] =
1796 amprocform->amproc;
1797 }
1798
1799 systable_endscan(scan);
1801 }
1802
1803 opcentry->valid = true;
1804 return opcentry;
1805}
1806
1807/*
1808 * Fill in the TableAmRoutine for a relation
1809 *
1810 * relation's rd_amhandler must be valid already.
1811 */
1812static void
1814{
1815 relation->rd_tableam = GetTableAmRoutine(relation->rd_amhandler);
1816}
1817
1818/*
1819 * Initialize table access method support for a table like relation
1820 */
1821void
1823{
1824 HeapTuple tuple;
1826
1827 if (relation->rd_rel->relkind == RELKIND_SEQUENCE)
1828 {
1829 /*
1830 * Sequences are currently accessed like heap tables, but it doesn't
1831 * seem prudent to show that in the catalog. So just overwrite it
1832 * here.
1833 */
1834 Assert(relation->rd_rel->relam == InvalidOid);
1836 }
1837 else if (IsCatalogRelation(relation))
1838 {
1839 /*
1840 * Avoid doing a syscache lookup for catalog tables.
1841 */
1842 Assert(relation->rd_rel->relam == HEAP_TABLE_AM_OID);
1844 }
1845 else
1846 {
1847 /*
1848 * Look up the table access method, save the OID of its handler
1849 * function.
1850 */
1851 Assert(relation->rd_rel->relam != InvalidOid);
1852 tuple = SearchSysCache1(AMOID,
1853 ObjectIdGetDatum(relation->rd_rel->relam));
1854 if (!HeapTupleIsValid(tuple))
1855 elog(ERROR, "cache lookup failed for access method %u",
1856 relation->rd_rel->relam);
1857 aform = (Form_pg_am) GETSTRUCT(tuple);
1858 relation->rd_amhandler = aform->amhandler;
1859 ReleaseSysCache(tuple);
1860 }
1861
1862 /*
1863 * Now we can fetch the table AM's API struct
1864 */
1865 InitTableAmRoutine(relation);
1866}
1867
1868/*
1869 * formrdesc
1870 *
1871 * This is a special cut-down version of RelationBuildDesc(),
1872 * used while initializing the relcache.
1873 * The relation descriptor is built just from the supplied parameters,
1874 * without actually looking at any system table entries. We cheat
1875 * quite a lot since we only need to work for a few basic system
1876 * catalogs.
1877 *
1878 * The catalogs this is used for can't have constraints (except attnotnull),
1879 * default values, rules, or triggers, since we don't cope with any of that.
1880 * (Well, actually, this only matters for properties that need to be valid
1881 * during bootstrap or before RelationCacheInitializePhase3 runs, and none of
1882 * these properties matter then...)
1883 *
1884 * NOTE: we assume we are already switched into CacheMemoryContext.
1885 */
1886static void
1888 bool isshared,
1889 int natts, const FormData_pg_attribute *attrs)
1890{
1891 Relation relation;
1892 int i;
1893 bool has_not_null;
1894
1895 /*
1896 * allocate new relation desc, clear all fields of reldesc
1897 */
1898 relation = palloc0_object(RelationData);
1899
1900 /* make sure relation is marked as having no open file yet */
1901 relation->rd_smgr = NULL;
1902
1903 /*
1904 * initialize reference count: 1 because it is nailed in cache
1905 */
1906 relation->rd_refcnt = 1;
1907
1908 /*
1909 * all entries built with this routine are nailed-in-cache; none are for
1910 * new or temp relations.
1911 */
1912 relation->rd_isnailed = true;
1917 relation->rd_backend = INVALID_PROC_NUMBER;
1918 relation->rd_islocaltemp = false;
1919
1920 /*
1921 * initialize relation tuple form
1922 *
1923 * The data we insert here is pretty incomplete/bogus, but it'll serve to
1924 * get us launched. RelationCacheInitializePhase3() will read the real
1925 * data from pg_class and replace what we've done here. Note in
1926 * particular that relowner is left as zero; this cues
1927 * RelationCacheInitializePhase3 that the real data isn't there yet.
1928 */
1930
1931 namestrcpy(&relation->rd_rel->relname, relationName);
1932 relation->rd_rel->relnamespace = PG_CATALOG_NAMESPACE;
1933 relation->rd_rel->reltype = relationReltype;
1934
1935 /*
1936 * It's important to distinguish between shared and non-shared relations,
1937 * even at bootstrap time, to make sure we know where they are stored.
1938 */
1939 relation->rd_rel->relisshared = isshared;
1940 if (isshared)
1941 relation->rd_rel->reltablespace = GLOBALTABLESPACE_OID;
1942
1943 /* formrdesc is used only for permanent relations */
1944 relation->rd_rel->relpersistence = RELPERSISTENCE_PERMANENT;
1945
1946 /* ... and they're always populated, too */
1947 relation->rd_rel->relispopulated = true;
1948
1949 relation->rd_rel->relreplident = REPLICA_IDENTITY_NOTHING;
1950 relation->rd_rel->relpages = 0;
1951 relation->rd_rel->reltuples = -1;
1952 relation->rd_rel->relallvisible = 0;
1953 relation->rd_rel->relallfrozen = 0;
1954 relation->rd_rel->relkind = RELKIND_RELATION;
1955 relation->rd_rel->relnatts = (int16) natts;
1956
1957 /*
1958 * initialize attribute tuple form
1959 *
1960 * Unlike the case with the relation tuple, this data had better be right
1961 * because it will never be replaced. The data comes from
1962 * src/include/catalog/ headers via genbki.pl.
1963 */
1964 relation->rd_att = CreateTemplateTupleDesc(natts);
1965 relation->rd_att->tdrefcount = 1; /* mark as refcounted */
1966
1967 relation->rd_att->tdtypeid = relationReltype;
1968 relation->rd_att->tdtypmod = -1; /* just to be sure */
1969
1970 /*
1971 * initialize tuple desc info
1972 */
1973 has_not_null = false;
1974 for (i = 0; i < natts; i++)
1975 {
1976 memcpy(TupleDescAttr(relation->rd_att, i),
1977 &attrs[i],
1979 has_not_null |= attrs[i].attnotnull;
1980
1982 }
1983
1984 TupleDescFinalize(relation->rd_att);
1985
1986 /* mark not-null status */
1987 if (has_not_null)
1988 {
1990
1991 constr->has_not_null = true;
1992 relation->rd_att->constr = constr;
1993 }
1994
1995 /*
1996 * initialize relation id from info in att array (my, this is ugly)
1997 */
1998 RelationGetRelid(relation) = TupleDescAttr(relation->rd_att, 0)->attrelid;
1999
2000 /*
2001 * All relations made with formrdesc are mapped. This is necessarily so
2002 * because there is no other way to know what filenumber they currently
2003 * have. In bootstrap mode, add them to the initial relation mapper data,
2004 * specifying that the initial filenumber is the same as the OID.
2005 */
2006 relation->rd_rel->relfilenode = InvalidRelFileNumber;
2009 RelationGetRelid(relation),
2010 isshared, true);
2011
2012 /*
2013 * initialize the relation lock manager information
2014 */
2015 RelationInitLockInfo(relation); /* see lmgr.c */
2016
2017 /*
2018 * initialize physical addressing information for the relation
2019 */
2020 RelationInitPhysicalAddr(relation);
2021
2022 /*
2023 * initialize the table am handler
2024 */
2025 relation->rd_rel->relam = HEAP_TABLE_AM_OID;
2026 relation->rd_tableam = GetHeapamTableAmRoutine();
2027
2028 /*
2029 * initialize the rel-has-index flag, using hardwired knowledge
2030 */
2032 {
2033 /* In bootstrap mode, we have no indexes */
2034 relation->rd_rel->relhasindex = false;
2035 }
2036 else
2037 {
2038 /* Otherwise, all the rels formrdesc is used for have indexes */
2039 relation->rd_rel->relhasindex = true;
2040 }
2041
2042 /*
2043 * add new reldesc to relcache
2044 */
2045 RelationCacheInsert(relation, false);
2046
2047 /* It's fully valid */
2048 relation->rd_isvalid = true;
2049}
2050
2051#ifdef USE_ASSERT_CHECKING
2052/*
2053 * AssertCouldGetRelation
2054 *
2055 * Check safety of calling RelationIdGetRelation().
2056 *
2057 * In code that reads catalogs in the event of a cache miss, call this
2058 * before checking the cache.
2059 */
2060void
2062{
2065}
2066#endif
2067
2068
2069/* ----------------------------------------------------------------
2070 * Relation Descriptor Lookup Interface
2071 * ----------------------------------------------------------------
2072 */
2073
2074/*
2075 * RelationIdGetRelation
2076 *
2077 * Lookup a reldesc by OID; make one if not already in cache.
2078 *
2079 * Returns NULL if no pg_class row could be found for the given relid
2080 * (suggesting we are trying to access a just-deleted relation).
2081 * Any other error is reported via elog.
2082 *
2083 * NB: caller should already have at least AccessShareLock on the
2084 * relation ID, else there are nasty race conditions.
2085 *
2086 * NB: relation ref count is incremented, or set to 1 if new entry.
2087 * Caller should eventually decrement count. (Usually,
2088 * that happens by calling RelationClose().)
2089 */
2092{
2093 Relation rd;
2094
2096
2097 /*
2098 * first try to find reldesc in the cache
2099 */
2101
2102 if (RelationIsValid(rd))
2103 {
2104 /* return NULL for dropped relations */
2105 if (rd->rd_droppedSubid != InvalidSubTransactionId)
2106 {
2107 Assert(!rd->rd_isvalid);
2108 return NULL;
2109 }
2110
2112 /* revalidate cache entry if necessary */
2113 if (!rd->rd_isvalid)
2114 {
2116
2117 /*
2118 * Normally entries need to be valid here, but before the relcache
2119 * has been initialized, not enough infrastructure exists to
2120 * perform pg_class lookups. The structure of such entries doesn't
2121 * change, but we still want to update the rd_rel entry. So
2122 * rd_isvalid = false is left in place for a later lookup.
2123 */
2124 Assert(rd->rd_isvalid ||
2125 (rd->rd_isnailed && !criticalRelcachesBuilt));
2126 }
2127 return rd;
2128 }
2129
2130 /*
2131 * no reldesc in the cache, so have RelationBuildDesc() build one and add
2132 * it.
2133 */
2135 if (RelationIsValid(rd))
2137 return rd;
2138}
2139
2140/*
2141 * Returns a schema-qualified name of the relation.
2142 */
2143char *
2149
2150/* ----------------------------------------------------------------
2151 * cache invalidation support routines
2152 * ----------------------------------------------------------------
2153 */
2154
2155/* ResourceOwner callbacks to track relcache references */
2156static void ResOwnerReleaseRelation(Datum res);
2157static char *ResOwnerPrintRelCache(Datum res);
2158
2160{
2161 .name = "relcache reference",
2162 .release_phase = RESOURCE_RELEASE_BEFORE_LOCKS,
2163 .release_priority = RELEASE_PRIO_RELCACHE_REFS,
2164 .ReleaseResource = ResOwnerReleaseRelation,
2165 .DebugPrint = ResOwnerPrintRelCache
2166};
2167
2168/* Convenience wrappers over ResourceOwnerRemember/Forget */
2169static inline void
2174static inline void
2179
2180/*
2181 * RelationIncrementReferenceCount
2182 * Increments relation reference count.
2183 *
2184 * Note: bootstrap mode has its own weird ideas about relation refcount
2185 * behavior; we ought to fix it someday, but for now, just disable
2186 * reference count ownership tracking in bootstrap mode.
2187 */
2188void
2196
2197/*
2198 * RelationDecrementReferenceCount
2199 * Decrements relation reference count.
2200 */
2201void
2209
2210/*
2211 * RelationClose - close an open relation
2212 *
2213 * Actually, we just decrement the refcount.
2214 *
2215 * NOTE: if compiled with -DRELCACHE_FORCE_RELEASE then relcache entries
2216 * will be freed as soon as their refcount goes to zero. In combination
2217 * with aset.c's CLOBBER_FREED_MEMORY option, this provides a good test
2218 * to catch references to already-released relcache entries. It slows
2219 * things down quite a bit, however.
2220 */
2221void
2223{
2224 /* Note: no locking manipulations needed */
2226
2227 RelationCloseCleanup(relation);
2228}
2229
2230static void
2232{
2233 /*
2234 * If the relation is no longer open in this session, we can clean up any
2235 * stale partition descriptors it has. This is unlikely, so check to see
2236 * if there are child contexts before expending a call to mcxt.c.
2237 */
2238 if (RelationHasReferenceCountZero(relation))
2239 {
2240 if (relation->rd_pdcxt != NULL &&
2241 relation->rd_pdcxt->firstchild != NULL)
2243
2244 if (relation->rd_pddcxt != NULL &&
2245 relation->rd_pddcxt->firstchild != NULL)
2247 }
2248
2249#ifdef RELCACHE_FORCE_RELEASE
2250 if (RelationHasReferenceCountZero(relation) &&
2253 RelationClearRelation(relation);
2254#endif
2255}
2256
2257/*
2258 * RelationReloadIndexInfo - reload minimal information for an open index
2259 *
2260 * This function is used only for indexes. A relcache inval on an index
2261 * can mean that its pg_class or pg_index row changed. There are only
2262 * very limited changes that are allowed to an existing index's schema,
2263 * so we can update the relcache entry without a complete rebuild; which
2264 * is fortunate because we can't rebuild an index entry that is "nailed"
2265 * and/or in active use. We support full replacement of the pg_class row,
2266 * as well as updates of a few simple fields of the pg_index row.
2267 *
2268 * We assume that at the time we are called, we have at least AccessShareLock
2269 * on the target index.
2270 *
2271 * If the target index is an index on pg_class or pg_index, we'd better have
2272 * previously gotten at least AccessShareLock on its underlying catalog,
2273 * else we are at risk of deadlock against someone trying to exclusive-lock
2274 * the heap and index in that order. This is ensured in current usage by
2275 * only applying this to indexes being opened or having positive refcount.
2276 */
2277static void
2279{
2280 bool indexOK;
2283
2284 /* Should be called only for invalidated, live indexes */
2285 Assert((relation->rd_rel->relkind == RELKIND_INDEX ||
2286 relation->rd_rel->relkind == RELKIND_PARTITIONED_INDEX) &&
2287 !relation->rd_isvalid &&
2289
2290 /*
2291 * If it's a shared index, we might be called before backend startup has
2292 * finished selecting a database, in which case we have no way to read
2293 * pg_class yet. However, a shared index can never have any significant
2294 * schema updates, so it's okay to mostly ignore the invalidation signal.
2295 * Its physical relfilenumber might've changed, but that's all. Update
2296 * the physical relfilenumber, mark it valid and return without doing
2297 * anything more.
2298 */
2299 if (relation->rd_rel->relisshared && !criticalRelcachesBuilt)
2300 {
2301 RelationInitPhysicalAddr(relation);
2302 relation->rd_isvalid = true;
2303 return;
2304 }
2305
2306 /*
2307 * Read the pg_class row
2308 *
2309 * Don't try to use an indexscan of pg_class_oid_index to reload the info
2310 * for pg_class_oid_index ...
2311 */
2312 indexOK = (RelationGetRelid(relation) != ClassOidIndexId);
2315 elog(ERROR, "could not find pg_class tuple for index %u",
2316 RelationGetRelid(relation));
2318 memcpy(relation->rd_rel, relp, CLASS_TUPLE_SIZE);
2319 /* Reload reloptions in case they changed */
2320 if (relation->rd_options)
2321 pfree(relation->rd_options);
2323 /* done with pg_class tuple */
2325 /* We must recalculate physical address in case it changed */
2326 RelationInitPhysicalAddr(relation);
2327
2328 /*
2329 * For a non-system index, there are fields of the pg_index row that are
2330 * allowed to change, so re-read that row and update the relcache entry.
2331 * Most of the info derived from pg_index (such as support function lookup
2332 * info) cannot change, and indeed the whole point of this routine is to
2333 * update the relcache entry without clobbering that data; so wholesale
2334 * replacement is not appropriate.
2335 */
2336 if (!IsSystemRelation(relation))
2337 {
2338 HeapTuple tuple;
2340
2343 if (!HeapTupleIsValid(tuple))
2344 elog(ERROR, "cache lookup failed for index %u",
2345 RelationGetRelid(relation));
2346 index = (Form_pg_index) GETSTRUCT(tuple);
2347
2348 /*
2349 * Basically, let's just copy all the bool fields. There are one or
2350 * two of these that can't actually change in the current code, but
2351 * it's not worth it to track exactly which ones they are. None of
2352 * the array fields are allowed to change, though.
2353 */
2354 relation->rd_index->indisunique = index->indisunique;
2355 relation->rd_index->indnullsnotdistinct = index->indnullsnotdistinct;
2356 relation->rd_index->indisprimary = index->indisprimary;
2357 relation->rd_index->indisexclusion = index->indisexclusion;
2358 relation->rd_index->indimmediate = index->indimmediate;
2359 relation->rd_index->indisclustered = index->indisclustered;
2360 relation->rd_index->indisvalid = index->indisvalid;
2361 relation->rd_index->indcheckxmin = index->indcheckxmin;
2362 relation->rd_index->indisready = index->indisready;
2363 relation->rd_index->indislive = index->indislive;
2364 relation->rd_index->indisreplident = index->indisreplident;
2365
2366 /* Copy xmin too, as that is needed to make sense of indcheckxmin */
2369
2370 ReleaseSysCache(tuple);
2371 }
2372
2373 /* Okay, now it's valid again */
2374 relation->rd_isvalid = true;
2375}
2376
2377/*
2378 * RelationReloadNailed - reload minimal information for nailed relations.
2379 *
2380 * The structure of a nailed relation can never change (which is good, because
2381 * we rely on knowing their structure to be able to read catalog content). But
2382 * some parts, e.g. pg_class.relfrozenxid, are still important to have
2383 * accurate content for. Therefore those need to be reloaded after the arrival
2384 * of invalidations.
2385 */
2386static void
2388{
2389 /* Should be called only for invalidated, nailed relations */
2390 Assert(!relation->rd_isvalid);
2391 Assert(relation->rd_isnailed);
2392 /* nailed indexes are handled by RelationReloadIndexInfo() */
2393 Assert(relation->rd_rel->relkind == RELKIND_RELATION);
2395
2396 /*
2397 * Redo RelationInitPhysicalAddr in case it is a mapped relation whose
2398 * mapping changed.
2399 */
2400 RelationInitPhysicalAddr(relation);
2401
2402 /*
2403 * Reload a non-index entry. We can't easily do so if relcaches aren't
2404 * yet built, but that's fine because at that stage the attributes that
2405 * need to be current (like relfrozenxid) aren't yet accessed. To ensure
2406 * the entry will later be revalidated, we leave it in invalid state, but
2407 * allow use (cf. RelationIdGetRelation()).
2408 */
2410 {
2413
2414 /*
2415 * NB: Mark the entry as valid before starting to scan, to avoid
2416 * self-recursion when re-building pg_class.
2417 */
2418 relation->rd_isvalid = true;
2419
2421 true, false);
2423 memcpy(relation->rd_rel, relp, CLASS_TUPLE_SIZE);
2425
2426 /*
2427 * Again mark as valid, to protect against concurrently arriving
2428 * invalidations.
2429 */
2430 relation->rd_isvalid = true;
2431 }
2432}
2433
2434/*
2435 * RelationDestroyRelation
2436 *
2437 * Physically delete a relation cache entry and all subsidiary data.
2438 * Caller must already have unhooked the entry from the hash table.
2439 */
2440static void
2442{
2444
2445 /*
2446 * Make sure smgr and lower levels close the relation's files, if they
2447 * weren't closed already. (This was probably done by caller, but let's
2448 * just be real sure.)
2449 */
2450 RelationCloseSmgr(relation);
2451
2452 /* break mutual link with stats entry */
2453 pgstat_unlink_relation(relation);
2454
2455 /*
2456 * Free all the subsidiary data structures of the relcache entry, then the
2457 * entry itself.
2458 */
2459 if (relation->rd_rel)
2460 pfree(relation->rd_rel);
2461 /* can't use DecrTupleDescRefCount here */
2462 Assert(relation->rd_att->tdrefcount > 0);
2463 if (--relation->rd_att->tdrefcount == 0)
2464 {
2465 /*
2466 * If we Rebuilt a relcache entry during a transaction then its
2467 * possible we did that because the TupDesc changed as the result of
2468 * an ALTER TABLE that ran at less than AccessExclusiveLock. It's
2469 * possible someone copied that TupDesc, in which case the copy would
2470 * point to free'd memory. So if we rebuild an entry we keep the
2471 * TupDesc around until end of transaction, to be safe.
2472 */
2473 if (remember_tupdesc)
2475 else
2476 FreeTupleDesc(relation->rd_att);
2477 }
2478 FreeTriggerDesc(relation->trigdesc);
2479 list_free_deep(relation->rd_fkeylist);
2480 list_free(relation->rd_indexlist);
2481 list_free(relation->rd_statlist);
2482 bms_free(relation->rd_keyattr);
2483 bms_free(relation->rd_pkattr);
2484 bms_free(relation->rd_idattr);
2485 bms_free(relation->rd_hotblockingattr);
2486 bms_free(relation->rd_summarizedattr);
2487 if (relation->rd_pubdesc)
2488 pfree(relation->rd_pubdesc);
2489 if (relation->rd_options)
2490 pfree(relation->rd_options);
2491 if (relation->rd_indextuple)
2492 pfree(relation->rd_indextuple);
2493 if (relation->rd_amcache)
2494 pfree(relation->rd_amcache);
2495 if (relation->rd_fdwroutine)
2496 pfree(relation->rd_fdwroutine);
2497 if (relation->rd_indexcxt)
2499 if (relation->rd_rulescxt)
2501 if (relation->rd_rsdesc)
2503 if (relation->rd_partkeycxt)
2505 if (relation->rd_pdcxt)
2506 MemoryContextDelete(relation->rd_pdcxt);
2507 if (relation->rd_pddcxt)
2508 MemoryContextDelete(relation->rd_pddcxt);
2509 if (relation->rd_partcheckcxt)
2511 pfree(relation);
2512}
2513
2514/*
2515 * RelationInvalidateRelation - mark a relation cache entry as invalid
2516 *
2517 * An entry that's marked as invalid will be reloaded on next access.
2518 */
2519static void
2521{
2522 /*
2523 * Make sure smgr and lower levels close the relation's files, if they
2524 * weren't closed already. If the relation is not getting deleted, the
2525 * next smgr access should reopen the files automatically. This ensures
2526 * that the low-level file access state is updated after, say, a vacuum
2527 * truncation.
2528 */
2529 RelationCloseSmgr(relation);
2530
2531 /* Free AM cached data, if any */
2532 if (relation->rd_amcache)
2533 pfree(relation->rd_amcache);
2534 relation->rd_amcache = NULL;
2535
2536 relation->rd_isvalid = false;
2537}
2538
2539/*
2540 * RelationClearRelation - physically blow away a relation cache entry
2541 *
2542 * The caller must ensure that the entry is no longer needed, i.e. its
2543 * reference count is zero. Also, the rel or its storage must not be created
2544 * in the current transaction (rd_createSubid and rd_firstRelfilelocatorSubid
2545 * must not be set).
2546 */
2547static void
2549{
2551 Assert(!relation->rd_isnailed);
2552
2553 /*
2554 * Relations created in the same transaction must never be removed, see
2555 * RelationFlushRelation.
2556 */
2560
2561 /* first mark it as invalid */
2563
2564 /* Remove it from the hash table */
2565 RelationCacheDelete(relation);
2566
2567 /* And release storage */
2568 RelationDestroyRelation(relation, false);
2569}
2570
2571/*
2572 * RelationRebuildRelation - rebuild a relation cache entry in place
2573 *
2574 * Reset and rebuild a relation cache entry from scratch (that is, from
2575 * catalog entries). This is used when we are notified of a change to an open
2576 * relation (one with refcount > 0). The entry is reconstructed without
2577 * moving the physical RelationData record, so that the refcount holder's
2578 * pointer is still valid.
2579 *
2580 * NB: when rebuilding, we'd better hold some lock on the relation, else the
2581 * catalog data we need to read could be changing under us. Also, a rel to be
2582 * rebuilt had better have refcnt > 0. This is because a sinval reset could
2583 * happen while we're accessing the catalogs, and the rel would get blown away
2584 * underneath us by RelationCacheInvalidate if it has zero refcnt.
2585 */
2586static void
2588{
2591 /* there is no reason to ever rebuild a dropped relation */
2593
2594 /* Close and mark it as invalid until we've finished the rebuild */
2596
2597 /*
2598 * Indexes only have a limited number of possible schema changes, and we
2599 * don't want to use the full-blown procedure because it's a headache for
2600 * indexes that reload itself depends on.
2601 *
2602 * As an exception, use the full procedure if the index access info hasn't
2603 * been initialized yet. Index creation relies on that: it first builds
2604 * the relcache entry with RelationBuildLocalRelation(), creates the
2605 * pg_index tuple only after that, and then relies on
2606 * CommandCounterIncrement to load the pg_index contents.
2607 */
2608 if ((relation->rd_rel->relkind == RELKIND_INDEX ||
2609 relation->rd_rel->relkind == RELKIND_PARTITIONED_INDEX) &&
2610 relation->rd_indexcxt != NULL)
2611 {
2612 RelationReloadIndexInfo(relation);
2613 return;
2614 }
2615 /* Nailed relations are handled separately. */
2616 else if (relation->rd_isnailed)
2617 {
2618 RelationReloadNailed(relation);
2619 return;
2620 }
2621 else
2622 {
2623 /*
2624 * Our strategy for rebuilding an open relcache entry is to build a
2625 * new entry from scratch, swap its contents with the old entry, and
2626 * finally delete the new entry (along with any infrastructure swapped
2627 * over from the old entry). This is to avoid trouble in case an
2628 * error causes us to lose control partway through. The old entry
2629 * will still be marked !rd_isvalid, so we'll try to rebuild it again
2630 * on next access. Meanwhile it's not any less valid than it was
2631 * before, so any code that might expect to continue accessing it
2632 * isn't hurt by the rebuild failure. (Consider for example a
2633 * subtransaction that ALTERs a table and then gets canceled partway
2634 * through the cache entry rebuild. The outer transaction should
2635 * still see the not-modified cache entry as valid.) The worst
2636 * consequence of an error is leaking the necessarily-unreferenced new
2637 * entry, and this shouldn't happen often enough for that to be a big
2638 * problem.
2639 *
2640 * When rebuilding an open relcache entry, we must preserve ref count,
2641 * rd_*Subid, and rd_toastoid state. Also attempt to preserve the
2642 * pg_class entry (rd_rel), tupledesc, rewrite-rule, partition key,
2643 * and partition descriptor substructures in place, because various
2644 * places assume that these structures won't move while they are
2645 * working with an open relcache entry. (Note: the refcount
2646 * mechanism for tupledescs might someday allow us to remove this hack
2647 * for the tupledesc.)
2648 *
2649 * Note that this process does not touch CurrentResourceOwner; which
2650 * is good because whatever ref counts the entry may have do not
2651 * necessarily belong to that resource owner.
2652 */
2654 Oid save_relid = RelationGetRelid(relation);
2655 bool keep_tupdesc;
2656 bool keep_rules;
2657 bool keep_policies;
2658 bool keep_partkey;
2659
2660 /* Build temporary entry, but don't link it into hashtable */
2662
2663 /*
2664 * Between here and the end of the swap, don't add code that does or
2665 * reasonably could read system catalogs. That range must be free
2666 * from invalidation processing. See RelationBuildDesc() manipulation
2667 * of in_progress_list.
2668 */
2669
2670 if (newrel == NULL)
2671 {
2672 /*
2673 * We can validly get here, if we're using a historic snapshot in
2674 * which a relation, accessed from outside logical decoding, is
2675 * still invisible. In that case it's fine to just mark the
2676 * relation as invalid and return - it'll fully get reloaded by
2677 * the cache reset at the end of logical decoding (or at the next
2678 * access). During normal processing we don't want to ignore this
2679 * case as it shouldn't happen there, as explained below.
2680 */
2682 return;
2683
2684 /*
2685 * This shouldn't happen as dropping a relation is intended to be
2686 * impossible if still referenced (cf. CheckTableNotInUse()). But
2687 * if we get here anyway, we can't just delete the relcache entry,
2688 * as it possibly could get accessed later (as e.g. the error
2689 * might get trapped and handled via a subtransaction rollback).
2690 */
2691 elog(ERROR, "relation %u deleted while still in use", save_relid);
2692 }
2693
2694 /*
2695 * If we were to, again, have cases of the relkind of a relcache entry
2696 * changing, we would need to ensure that pgstats does not get
2697 * confused.
2698 */
2699 Assert(relation->rd_rel->relkind == newrel->rd_rel->relkind);
2700
2701 keep_tupdesc = equalTupleDescs(relation->rd_att, newrel->rd_att);
2702 keep_rules = equalRuleLocks(relation->rd_rules, newrel->rd_rules);
2703 keep_policies = equalRSDesc(relation->rd_rsdesc, newrel->rd_rsdesc);
2704 /* partkey is immutable once set up, so we can always keep it */
2705 keep_partkey = (relation->rd_partkey != NULL);
2706
2707 /*
2708 * Perform swapping of the relcache entry contents. Within this
2709 * process the old entry is momentarily invalid, so there *must* be no
2710 * possibility of CHECK_FOR_INTERRUPTS within this sequence. Do it in
2711 * all-in-line code for safety.
2712 *
2713 * Since the vast majority of fields should be swapped, our method is
2714 * to swap the whole structures and then re-swap those few fields we
2715 * didn't want swapped.
2716 */
2717#define SWAPFIELD(fldtype, fldname) \
2718 do { \
2719 fldtype _tmp = newrel->fldname; \
2720 newrel->fldname = relation->fldname; \
2721 relation->fldname = _tmp; \
2722 } while (0)
2723
2724 /* swap all Relation struct fields */
2725 {
2727
2728 memcpy(&tmpstruct, newrel, sizeof(RelationData));
2729 memcpy(newrel, relation, sizeof(RelationData));
2730 memcpy(relation, &tmpstruct, sizeof(RelationData));
2731 }
2732
2733 /* rd_smgr must not be swapped, due to back-links from smgr level */
2734 SWAPFIELD(SMgrRelation, rd_smgr);
2735 /* rd_refcnt must be preserved */
2736 SWAPFIELD(int, rd_refcnt);
2737 /* isnailed shouldn't change */
2738 Assert(newrel->rd_isnailed == relation->rd_isnailed);
2739 /* creation sub-XIDs must be preserved */
2740 SWAPFIELD(SubTransactionId, rd_createSubid);
2741 SWAPFIELD(SubTransactionId, rd_newRelfilelocatorSubid);
2742 SWAPFIELD(SubTransactionId, rd_firstRelfilelocatorSubid);
2743 SWAPFIELD(SubTransactionId, rd_droppedSubid);
2744 /* un-swap rd_rel pointers, swap contents instead */
2745 SWAPFIELD(Form_pg_class, rd_rel);
2746 /* ... but actually, we don't have to update newrel->rd_rel */
2747 memcpy(relation->rd_rel, newrel->rd_rel, CLASS_TUPLE_SIZE);
2748 /* preserve old tupledesc, rules, policies if no logical change */
2749 if (keep_tupdesc)
2750 SWAPFIELD(TupleDesc, rd_att);
2751 if (keep_rules)
2752 {
2753 SWAPFIELD(RuleLock *, rd_rules);
2754 SWAPFIELD(MemoryContext, rd_rulescxt);
2755 }
2756 if (keep_policies)
2757 SWAPFIELD(RowSecurityDesc *, rd_rsdesc);
2758 /* toast OID override must be preserved */
2759 SWAPFIELD(Oid, rd_toastoid);
2760 /* pgstat_info / enabled must be preserved */
2761 SWAPFIELD(struct PgStat_TableStatus *, pgstat_info);
2762 SWAPFIELD(bool, pgstat_enabled);
2763 /* preserve old partition key if we have one */
2764 if (keep_partkey)
2765 {
2766 SWAPFIELD(PartitionKey, rd_partkey);
2767 SWAPFIELD(MemoryContext, rd_partkeycxt);
2768 }
2769 if (newrel->rd_pdcxt != NULL || newrel->rd_pddcxt != NULL)
2770 {
2771 /*
2772 * We are rebuilding a partitioned relation with a non-zero
2773 * reference count, so we must keep the old partition descriptor
2774 * around, in case there's a PartitionDirectory with a pointer to
2775 * it. This means we can't free the old rd_pdcxt yet. (This is
2776 * necessary because RelationGetPartitionDesc hands out direct
2777 * pointers to the relcache's data structure, unlike our usual
2778 * practice which is to hand out copies. We'd have the same
2779 * problem with rd_partkey, except that we always preserve that
2780 * once created.)
2781 *
2782 * To ensure that it's not leaked completely, re-attach it to the
2783 * new reldesc, or make it a child of the new reldesc's rd_pdcxt
2784 * in the unlikely event that there is one already. (Compare hack
2785 * in RelationBuildPartitionDesc.) RelationClose will clean up
2786 * any such contexts once the reference count reaches zero.
2787 *
2788 * In the case where the reference count is zero, this code is not
2789 * reached, which should be OK because in that case there should
2790 * be no PartitionDirectory with a pointer to the old entry.
2791 *
2792 * Note that newrel and relation have already been swapped, so the
2793 * "old" partition descriptor is actually the one hanging off of
2794 * newrel.
2795 */
2796 relation->rd_partdesc = NULL; /* ensure rd_partdesc is invalid */
2797 relation->rd_partdesc_nodetached = NULL;
2799 if (relation->rd_pdcxt != NULL) /* probably never happens */
2800 MemoryContextSetParent(newrel->rd_pdcxt, relation->rd_pdcxt);
2801 else
2802 relation->rd_pdcxt = newrel->rd_pdcxt;
2803 if (relation->rd_pddcxt != NULL)
2804 MemoryContextSetParent(newrel->rd_pddcxt, relation->rd_pddcxt);
2805 else
2806 relation->rd_pddcxt = newrel->rd_pddcxt;
2807 /* drop newrel's pointers so we don't destroy it below */
2808 newrel->rd_partdesc = NULL;
2809 newrel->rd_partdesc_nodetached = NULL;
2810 newrel->rd_partdesc_nodetached_xmin = InvalidTransactionId;
2811 newrel->rd_pdcxt = NULL;
2812 newrel->rd_pddcxt = NULL;
2813 }
2814
2815#undef SWAPFIELD
2816
2817 /* And now we can throw away the temporary entry */
2819 }
2820}
2821
2822/*
2823 * RelationFlushRelation
2824 *
2825 * Rebuild the relation if it is open (refcount > 0), else blow it away.
2826 * This is used when we receive a cache invalidation event for the rel.
2827 */
2828static void
2830{
2831 if (relation->rd_createSubid != InvalidSubTransactionId ||
2833 {
2834 /*
2835 * New relcache entries are always rebuilt, not flushed; else we'd
2836 * forget the "new" status of the relation. Ditto for the
2837 * new-relfilenumber status.
2838 */
2840 {
2841 /*
2842 * The rel could have zero refcnt here, so temporarily increment
2843 * the refcnt to ensure it's safe to rebuild it. We can assume
2844 * that the current transaction has some lock on the rel already.
2845 */
2847 RelationRebuildRelation(relation);
2849 }
2850 else
2852 }
2853 else
2854 {
2855 /*
2856 * Pre-existing rels can be dropped from the relcache if not open.
2857 *
2858 * If the entry is in use, rebuild it if possible. If we're not
2859 * inside a valid transaction, we can't do any catalog access so it's
2860 * not possible to rebuild yet. Just mark it as invalid in that case,
2861 * so that the rebuild will occur when the entry is next opened.
2862 *
2863 * Note: it's possible that we come here during subtransaction abort,
2864 * and the reason for wanting to rebuild is that the rel is open in
2865 * the outer transaction. In that case it might seem unsafe to not
2866 * rebuild immediately, since whatever code has the rel already open
2867 * will keep on using the relcache entry as-is. However, in such a
2868 * case the outer transaction should be holding a lock that's
2869 * sufficient to prevent any significant change in the rel's schema,
2870 * so the existing entry contents should be good enough for its
2871 * purposes; at worst we might be behind on statistics updates or the
2872 * like. (See also CheckTableNotInUse() and its callers.)
2873 */
2874 if (RelationHasReferenceCountZero(relation))
2875 RelationClearRelation(relation);
2876 else if (!IsTransactionState())
2878 else if (relation->rd_isnailed && relation->rd_refcnt == 1)
2879 {
2880 /*
2881 * A nailed relation with refcnt == 1 is unused. We cannot clear
2882 * it, but there's also no need no need to rebuild it immediately.
2883 */
2885 }
2886 else
2887 RelationRebuildRelation(relation);
2888 }
2889}
2890
2891/*
2892 * RelationForgetRelation - caller reports that it dropped the relation
2893 */
2894void
2896{
2897 Relation relation;
2898
2899 RelationIdCacheLookup(rid, relation);
2900
2901 if (!relation)
2902 return; /* not in cache, nothing to do */
2903
2904 if (!RelationHasReferenceCountZero(relation))
2905 elog(ERROR, "relation %u is still open", rid);
2906
2908 if (relation->rd_createSubid != InvalidSubTransactionId ||
2910 {
2911 /*
2912 * In the event of subtransaction rollback, we must not forget
2913 * rd_*Subid. Mark the entry "dropped" and invalidate it, instead of
2914 * destroying it right away. (If we're in a top transaction, we could
2915 * opt to destroy the entry.)
2916 */
2919 }
2920 else
2921 RelationClearRelation(relation);
2922}
2923
2924/*
2925 * RelationCacheInvalidateEntry
2926 *
2927 * This routine is invoked for SI cache flush messages.
2928 *
2929 * Any relcache entry matching the relid must be flushed. (Note: caller has
2930 * already determined that the relid belongs to our database or is a shared
2931 * relation.)
2932 *
2933 * We used to skip local relations, on the grounds that they could
2934 * not be targets of cross-backend SI update messages; but it seems
2935 * safer to process them, so that our *own* SI update messages will
2936 * have the same effects during CommandCounterIncrement for both
2937 * local and nonlocal relations.
2938 */
2939void
2941{
2942 Relation relation;
2943
2945
2946 if (relation)
2947 {
2949 RelationFlushRelation(relation);
2950 }
2951 else
2952 {
2953 int i;
2954
2955 for (i = 0; i < in_progress_list_len; i++)
2956 if (in_progress_list[i].reloid == relationId)
2958 }
2959}
2960
2961/*
2962 * RelationCacheInvalidate
2963 * Blow away cached relation descriptors that have zero reference counts,
2964 * and rebuild those with positive reference counts. Also reset the smgr
2965 * relation cache and re-read relation mapping data.
2966 *
2967 * Apart from debug_discard_caches, this is currently used only to recover
2968 * from SI message buffer overflow, so we do not touch relations having
2969 * new-in-transaction relfilenumbers; they cannot be targets of cross-backend
2970 * SI updates (and our own updates now go through a separate linked list
2971 * that isn't limited by the SI message buffer size).
2972 *
2973 * We do this in two phases: the first pass deletes deletable items, and
2974 * the second one rebuilds the rebuildable items. This is essential for
2975 * safety, because hash_seq_search only copes with concurrent deletion of
2976 * the element it is currently visiting. If a second SI overflow were to
2977 * occur while we are walking the table, resulting in recursive entry to
2978 * this routine, we could crash because the inner invocation blows away
2979 * the entry next to be visited by the outer scan. But this way is OK,
2980 * because (a) during the first pass we won't process any more SI messages,
2981 * so hash_seq_search will complete safely; (b) during the second pass we
2982 * only hold onto pointers to nondeletable entries.
2983 *
2984 * The two-phase approach also makes it easy to update relfilenumbers for
2985 * mapped relations before we do anything else, and to ensure that the
2986 * second pass processes nailed-in-cache items before other nondeletable
2987 * items. This should ensure that system catalogs are up to date before
2988 * we attempt to use them to reload information about other open relations.
2989 *
2990 * After those two phases of work having immediate effects, we normally
2991 * signal any RelationBuildDesc() on the stack to start over. However, we
2992 * don't do this if called as part of debug_discard_caches. Otherwise,
2993 * RelationBuildDesc() would become an infinite loop.
2994 */
2995void
2997{
2998 HASH_SEQ_STATUS status;
3000 Relation relation;
3002 List *rebuildList = NIL;
3003 ListCell *l;
3004 int i;
3005
3006 /*
3007 * Reload relation mapping data before starting to reconstruct cache.
3008 */
3010
3011 /* Phase 1 */
3013
3014 while ((idhentry = (RelIdCacheEnt *) hash_seq_search(&status)) != NULL)
3015 {
3016 relation = idhentry->reldesc;
3017
3018 /*
3019 * Ignore new relations; no other backend will manipulate them before
3020 * we commit. Likewise, before replacing a relation's relfilelocator,
3021 * we shall have acquired AccessExclusiveLock and drained any
3022 * applicable pending invalidations.
3023 */
3024 if (relation->rd_createSubid != InvalidSubTransactionId ||
3026 continue;
3027
3029
3030 if (RelationHasReferenceCountZero(relation))
3031 {
3032 /* Delete this entry immediately */
3033 RelationClearRelation(relation);
3034 }
3035 else
3036 {
3037 /*
3038 * If it's a mapped relation, immediately update its rd_locator in
3039 * case its relfilenumber changed. We must do this during phase 1
3040 * in case the relation is consulted during rebuild of other
3041 * relcache entries in phase 2. It's safe since consulting the
3042 * map doesn't involve any access to relcache entries.
3043 */
3044 if (RelationIsMapped(relation))
3045 {
3046 RelationCloseSmgr(relation);
3047 RelationInitPhysicalAddr(relation);
3048 }
3049
3050 /*
3051 * Add this entry to list of stuff to rebuild in second pass.
3052 * pg_class goes to the front of rebuildFirstList while
3053 * pg_class_oid_index goes to the back of rebuildFirstList, so
3054 * they are done first and second respectively. Other nailed
3055 * relations go to the front of rebuildList, so they'll be done
3056 * next in no particular order; and everything else goes to the
3057 * back of rebuildList.
3058 */
3059 if (RelationGetRelid(relation) == RelationRelationId)
3061 else if (RelationGetRelid(relation) == ClassOidIndexId)
3063 else if (relation->rd_isnailed)
3064 rebuildList = lcons(relation, rebuildList);
3065 else
3066 rebuildList = lappend(rebuildList, relation);
3067 }
3068 }
3069
3070 /*
3071 * We cannot destroy the SMgrRelations as there might still be references
3072 * to them, but close the underlying file descriptors.
3073 */
3075
3076 /*
3077 * Phase 2: rebuild (or invalidate) the items found to need rebuild in
3078 * phase 1
3079 */
3080 foreach(l, rebuildFirstList)
3081 {
3082 relation = (Relation) lfirst(l);
3083 if (!IsTransactionState() || (relation->rd_isnailed && relation->rd_refcnt == 1))
3085 else
3086 RelationRebuildRelation(relation);
3087 }
3089 foreach(l, rebuildList)
3090 {
3091 relation = (Relation) lfirst(l);
3092 if (!IsTransactionState() || (relation->rd_isnailed && relation->rd_refcnt == 1))
3094 else
3095 RelationRebuildRelation(relation);
3096 }
3098
3099 if (!debug_discard)
3100 /* Any RelationBuildDesc() on the stack must start over. */
3101 for (i = 0; i < in_progress_list_len; i++)
3102 in_progress_list[i].invalidated = true;
3103}
3104
3105static void
3132
3133#ifdef USE_ASSERT_CHECKING
3134static void
3136{
3137 bool relcache_verdict =
3138 RelationIsPermanent(relation) &&
3139 ((relation->rd_createSubid != InvalidSubTransactionId &&
3140 RELKIND_HAS_STORAGE(relation->rd_rel->relkind)) ||
3142
3144
3146 Assert(!relation->rd_isvalid &&
3149}
3150
3151/*
3152 * AssertPendingSyncs_RelationCache
3153 *
3154 * Assert that relcache.c and storage.c agree on whether to skip WAL.
3155 */
3156void
3158{
3159 HASH_SEQ_STATUS status;
3161 Relation *rels;
3162 int maxrels;
3163 int nrels;
3165 int i;
3166
3167 /*
3168 * Open every relation that this transaction has locked. If, for some
3169 * relation, storage.c is skipping WAL and relcache.c is not skipping WAL,
3170 * a CommandCounterIncrement() typically yields a local invalidation
3171 * message that destroys the relcache entry. By recreating such entries
3172 * here, we detect the problem.
3173 */
3175 maxrels = 1;
3176 rels = palloc(maxrels * sizeof(*rels));
3177 nrels = 0;
3179 while ((locallock = (LOCALLOCK *) hash_seq_search(&status)) != NULL)
3180 {
3181 Oid relid;
3182 Relation r;
3183
3184 if (locallock->nLocks <= 0)
3185 continue;
3186 if ((LockTagType) locallock->tag.lock.locktag_type !=
3188 continue;
3189 relid = locallock->tag.lock.locktag_field2;
3190 r = RelationIdGetRelation(relid);
3191 if (!RelationIsValid(r))
3192 continue;
3193 if (nrels >= maxrels)
3194 {
3195 maxrels *= 2;
3196 rels = repalloc(rels, maxrels * sizeof(*rels));
3197 }
3198 rels[nrels++] = r;
3199 }
3200
3202 while ((idhentry = (RelIdCacheEnt *) hash_seq_search(&status)) != NULL)
3204
3205 for (i = 0; i < nrels; i++)
3206 RelationClose(rels[i]);
3208}
3209#endif
3210
3211/*
3212 * AtEOXact_RelationCache
3213 *
3214 * Clean up the relcache at main-transaction commit or abort.
3215 *
3216 * Note: this must be called *before* processing invalidation messages.
3217 * In the case of abort, we don't want to try to rebuild any invalidated
3218 * cache entries (since we can't safely do database accesses). Therefore
3219 * we must reset refcnts before handling pending invalidations.
3220 *
3221 * As of PostgreSQL 8.1, relcache refcnts should get released by the
3222 * ResourceOwner mechanism. This routine just does a debugging
3223 * cross-check that no pins remain. However, we also need to do special
3224 * cleanup when the current transaction created any relations or made use
3225 * of forced index lists.
3226 */
3227void
3229{
3230 HASH_SEQ_STATUS status;
3232 int i;
3233
3234 /*
3235 * Forget in_progress_list. This is relevant when we're aborting due to
3236 * an error during RelationBuildDesc().
3237 */
3240
3241 /*
3242 * Unless the eoxact_list[] overflowed, we only need to examine the rels
3243 * listed in it. Otherwise fall back on a hash_seq_search scan.
3244 *
3245 * For simplicity, eoxact_list[] entries are not deleted till end of
3246 * top-level transaction, even though we could remove them at
3247 * subtransaction end in some cases, or remove relations from the list if
3248 * they are cleared for other reasons. Therefore we should expect the
3249 * case that list entries are not found in the hashtable; if not, there's
3250 * nothing to do for them.
3251 */
3253 {
3255 while ((idhentry = (RelIdCacheEnt *) hash_seq_search(&status)) != NULL)
3256 {
3258 }
3259 }
3260 else
3261 {
3262 for (i = 0; i < eoxact_list_len; i++)
3263 {
3265 &eoxact_list[i],
3266 HASH_FIND,
3267 NULL);
3268 if (idhentry != NULL)
3270 }
3271 }
3272
3274 {
3276 for (i = 0; i < NextEOXactTupleDescNum; i++)
3280 }
3281
3282 /* Now we're out of the transaction and can clear the lists */
3283 eoxact_list_len = 0;
3284 eoxact_list_overflowed = false;
3287}
3288
3289/*
3290 * AtEOXact_cleanup
3291 *
3292 * Clean up a single rel at main-transaction commit or abort
3293 *
3294 * NB: this processing must be idempotent, because EOXactListAdd() doesn't
3295 * bother to prevent duplicate entries in eoxact_list[].
3296 */
3297static void
3299{
3300 bool clear_relcache = false;
3301
3302 /*
3303 * The relcache entry's ref count should be back to its normal
3304 * not-in-a-transaction state: 0 unless it's nailed in cache.
3305 *
3306 * In bootstrap mode, this is NOT true, so don't check it --- the
3307 * bootstrap code expects relations to stay open across start/commit
3308 * transaction calls. (That seems bogus, but it's not worth fixing.)
3309 *
3310 * Note: ideally this check would be applied to every relcache entry, not
3311 * just those that have eoxact work to do. But it's not worth forcing a
3312 * scan of the whole relcache just for this. (Moreover, doing so would
3313 * mean that assert-enabled testing never tests the hash_search code path
3314 * above, which seems a bad idea.)
3315 */
3316#ifdef USE_ASSERT_CHECKING
3318 {
3319 int expected_refcnt;
3320
3321 expected_refcnt = relation->rd_isnailed ? 1 : 0;
3322 Assert(relation->rd_refcnt == expected_refcnt);
3323 }
3324#endif
3325
3326 /*
3327 * Is the relation live after this transaction ends?
3328 *
3329 * During commit, clear the relcache entry if it is preserved after
3330 * relation drop, in order not to orphan the entry. During rollback,
3331 * clear the relcache entry if the relation is created in the current
3332 * transaction since it isn't interesting any longer once we are out of
3333 * the transaction.
3334 */
3336 (isCommit ?
3339
3340 /*
3341 * Since we are now out of the transaction, reset the subids to zero. That
3342 * also lets RelationClearRelation() drop the relcache entry.
3343 */
3348
3349 if (clear_relcache)
3350 {
3351 if (RelationHasReferenceCountZero(relation))
3352 {
3353 RelationClearRelation(relation);
3354 return;
3355 }
3356 else
3357 {
3358 /*
3359 * Hmm, somewhere there's a (leaked?) reference to the relation.
3360 * We daren't remove the entry for fear of dereferencing a
3361 * dangling pointer later. Bleat, and mark it as not belonging to
3362 * the current transaction. Hopefully it'll get cleaned up
3363 * eventually. This must be just a WARNING to avoid
3364 * error-during-error-recovery loops.
3365 */
3366 elog(WARNING, "cannot remove relcache entry for \"%s\" because it has nonzero refcount",
3367 RelationGetRelationName(relation));
3368 }
3369 }
3370}
3371
3372/*
3373 * AtEOSubXact_RelationCache
3374 *
3375 * Clean up the relcache at sub-transaction commit or abort.
3376 *
3377 * Note: this must be called *before* processing invalidation messages.
3378 */
3379void
3382{
3383 HASH_SEQ_STATUS status;
3385 int i;
3386
3387 /*
3388 * Forget in_progress_list. This is relevant when we're aborting due to
3389 * an error during RelationBuildDesc(). We don't commit subtransactions
3390 * during RelationBuildDesc().
3391 */
3394
3395 /*
3396 * Unless the eoxact_list[] overflowed, we only need to examine the rels
3397 * listed in it. Otherwise fall back on a hash_seq_search scan. Same
3398 * logic as in AtEOXact_RelationCache.
3399 */
3401 {
3403 while ((idhentry = (RelIdCacheEnt *) hash_seq_search(&status)) != NULL)
3404 {
3407 }
3408 }
3409 else
3410 {
3411 for (i = 0; i < eoxact_list_len; i++)
3412 {
3414 &eoxact_list[i],
3415 HASH_FIND,
3416 NULL);
3417 if (idhentry != NULL)
3420 }
3421 }
3422
3423 /* Don't reset the list; we still need more cleanup later */
3424}
3425
3426/*
3427 * AtEOSubXact_cleanup
3428 *
3429 * Clean up a single rel at subtransaction commit or abort
3430 *
3431 * NB: this processing must be idempotent, because EOXactListAdd() doesn't
3432 * bother to prevent duplicate entries in eoxact_list[].
3433 */
3434static void
3437{
3438 /*
3439 * Is it a relation created in the current subtransaction?
3440 *
3441 * During subcommit, mark it as belonging to the parent, instead, as long
3442 * as it has not been dropped. Otherwise simply delete the relcache entry.
3443 * --- it isn't interesting any longer.
3444 */
3445 if (relation->rd_createSubid == mySubid)
3446 {
3447 /*
3448 * Valid rd_droppedSubid means the corresponding relation is dropped
3449 * but the relcache entry is preserved for at-commit pending sync. We
3450 * need to drop it explicitly here not to make the entry orphan.
3451 */
3452 Assert(relation->rd_droppedSubid == mySubid ||
3455 relation->rd_createSubid = parentSubid;
3456 else if (RelationHasReferenceCountZero(relation))
3457 {
3458 /* allow the entry to be removed */
3463 RelationClearRelation(relation);
3464 return;
3465 }
3466 else
3467 {
3468 /*
3469 * Hmm, somewhere there's a (leaked?) reference to the relation.
3470 * We daren't remove the entry for fear of dereferencing a
3471 * dangling pointer later. Bleat, and transfer it to the parent
3472 * subtransaction so we can try again later. This must be just a
3473 * WARNING to avoid error-during-error-recovery loops.
3474 */
3475 relation->rd_createSubid = parentSubid;
3476 elog(WARNING, "cannot remove relcache entry for \"%s\" because it has nonzero refcount",
3477 RelationGetRelationName(relation));
3478 }
3479 }
3480
3481 /*
3482 * Likewise, update or drop any new-relfilenumber-in-subtransaction record
3483 * or drop record.
3484 */
3485 if (relation->rd_newRelfilelocatorSubid == mySubid)
3486 {
3487 if (isCommit)
3489 else
3491 }
3492
3493 if (relation->rd_firstRelfilelocatorSubid == mySubid)
3494 {
3495 if (isCommit)
3497 else
3499 }
3500
3501 if (relation->rd_droppedSubid == mySubid)
3502 {
3503 if (isCommit)
3504 relation->rd_droppedSubid = parentSubid;
3505 else
3507 }
3508}
3509
3510
3511/*
3512 * RelationBuildLocalRelation
3513 * Build a relcache entry for an about-to-be-created relation,
3514 * and enter it into the relcache.
3515 */
3518 Oid relnamespace,
3519 TupleDesc tupDesc,
3520 Oid relid,
3521 Oid accessmtd,
3522 RelFileNumber relfilenumber,
3523 Oid reltablespace,
3524 bool shared_relation,
3525 bool mapped_relation,
3526 char relpersistence,
3527 char relkind)
3528{
3529 Relation rel;
3531 int natts = tupDesc->natts;
3532 int i;
3533 bool has_not_null;
3534 bool nailit;
3535
3536 Assert(natts >= 0);
3537
3538 /*
3539 * check for creation of a rel that must be nailed in cache.
3540 *
3541 * XXX this list had better match the relations specially handled in
3542 * RelationCacheInitializePhase2/3.
3543 */
3544 switch (relid)
3545 {
3546 case DatabaseRelationId:
3547 case AuthIdRelationId:
3548 case AuthMemRelationId:
3549 case RelationRelationId:
3552 case TypeRelationId:
3553 nailit = true;
3554 break;
3555 default:
3556 nailit = false;
3557 break;
3558 }
3559
3560 /*
3561 * check that hardwired list of shared rels matches what's in the
3562 * bootstrap .bki file. If you get a failure here during initdb, you
3563 * probably need to fix IsSharedRelation() to match whatever you've done
3564 * to the set of shared relations.
3565 */
3566 if (shared_relation != IsSharedRelation(relid))
3567 elog(ERROR, "shared_relation flag for \"%s\" does not match IsSharedRelation(%u)",
3568 relname, relid);
3569
3570 /* Shared relations had better be mapped, too */
3572
3573 /*
3574 * switch to the cache context to create the relcache entry.
3575 */
3576 if (!CacheMemoryContext)
3578
3580
3581 /*
3582 * allocate a new relation descriptor and fill in basic state fields.
3583 */
3585
3586 /* make sure relation is marked as having no open file yet */
3587 rel->rd_smgr = NULL;
3588
3589 /* mark it nailed if appropriate */
3590 rel->rd_isnailed = nailit;
3591
3592 rel->rd_refcnt = nailit ? 1 : 0;
3593
3594 /* it's being created in this transaction */
3599
3600 /*
3601 * create a new tuple descriptor from the one passed in. We do this
3602 * partly to copy it into the cache context, and partly because the new
3603 * relation can't have any defaults or constraints yet; they have to be
3604 * added in later steps, because they require additions to multiple system
3605 * catalogs. We can copy attnotnull constraints here, however.
3606 */
3607 rel->rd_att = CreateTupleDescCopy(tupDesc);
3608 rel->rd_att->tdrefcount = 1; /* mark as refcounted */
3609 has_not_null = false;
3610 for (i = 0; i < natts; i++)
3611 {
3614
3615 datt->attidentity = satt->attidentity;
3616 datt->attgenerated = satt->attgenerated;
3617 datt->attnotnull = satt->attnotnull;
3618 has_not_null |= satt->attnotnull;
3620
3621 if (satt->attnotnull)
3622 {
3625
3626 dcatt->attnullability = scatt->attnullability;
3627 }
3628 }
3629
3630 if (has_not_null)
3631 {
3633
3634 constr->has_not_null = true;
3635 rel->rd_att->constr = constr;
3636 }
3637
3638 /*
3639 * initialize relation tuple form (caller may add/override data later)
3640 */
3642
3643 namestrcpy(&rel->rd_rel->relname, relname);
3644 rel->rd_rel->relnamespace = relnamespace;
3645
3646 rel->rd_rel->relkind = relkind;
3647 rel->rd_rel->relnatts = natts;
3648 rel->rd_rel->reltype = InvalidOid;
3649 /* needed when bootstrapping: */
3650 rel->rd_rel->relowner = BOOTSTRAP_SUPERUSERID;
3651
3652 /* set up persistence and relcache fields dependent on it */
3653 rel->rd_rel->relpersistence = relpersistence;
3654 switch (relpersistence)
3655 {
3659 rel->rd_islocaltemp = false;
3660 break;
3662 Assert(isTempOrTempToastNamespace(relnamespace));
3664 rel->rd_islocaltemp = true;
3665 break;
3666 default:
3667 elog(ERROR, "invalid relpersistence: %c", relpersistence);
3668 break;
3669 }
3670
3671 /* if it's a materialized view, it's not populated initially */
3672 if (relkind == RELKIND_MATVIEW)
3673 rel->rd_rel->relispopulated = false;
3674 else
3675 rel->rd_rel->relispopulated = true;
3676
3677 /* set replica identity -- system catalogs and non-tables don't have one */
3678 if (!IsCatalogNamespace(relnamespace) &&
3679 (relkind == RELKIND_RELATION ||
3680 relkind == RELKIND_MATVIEW ||
3681 relkind == RELKIND_PARTITIONED_TABLE))
3682 rel->rd_rel->relreplident = REPLICA_IDENTITY_DEFAULT;
3683 else
3684 rel->rd_rel->relreplident = REPLICA_IDENTITY_NOTHING;
3685
3686 /*
3687 * Insert relation physical and logical identifiers (OIDs) into the right
3688 * places. For a mapped relation, we set relfilenumber to zero and rely
3689 * on RelationInitPhysicalAddr to consult the map.
3690 */
3691 rel->rd_rel->relisshared = shared_relation;
3692
3693 RelationGetRelid(rel) = relid;
3694
3695 for (i = 0; i < natts; i++)
3696 TupleDescAttr(rel->rd_att, i)->attrelid = relid;
3697
3699
3700 rel->rd_rel->reltablespace = reltablespace;
3701
3702 if (mapped_relation)
3703 {
3704 rel->rd_rel->relfilenode = InvalidRelFileNumber;
3705 /* Add it to the active mapping information */
3706 RelationMapUpdateMap(relid, relfilenumber, shared_relation, true);
3707 }
3708 else
3709 rel->rd_rel->relfilenode = relfilenumber;
3710
3711 RelationInitLockInfo(rel); /* see lmgr.c */
3712
3714
3715 rel->rd_rel->relam = accessmtd;
3716
3717 /*
3718 * RelationInitTableAccessMethod will do syscache lookups, so we mustn't
3719 * run it in CacheMemoryContext. Fortunately, the remaining steps don't
3720 * require a long-lived current context.
3721 */
3723
3724 if (RELKIND_HAS_TABLE_AM(relkind) || relkind == RELKIND_SEQUENCE)
3726
3727 /*
3728 * Leave index access method uninitialized, because the pg_index row has
3729 * not been inserted at this stage of index creation yet. The cache
3730 * invalidation after pg_index row has been inserted will initialize it.
3731 */
3732
3733 /*
3734 * Okay to insert into the relcache hash table.
3735 *
3736 * Ordinarily, there should certainly not be an existing hash entry for
3737 * the same OID; but during bootstrap, when we create a "real" relcache
3738 * entry for one of the bootstrap relations, we'll be overwriting the
3739 * phony one created with formrdesc. So allow that to happen for nailed
3740 * rels.
3741 */
3743
3744 /*
3745 * Flag relation as needing eoxact cleanup (to clear rd_createSubid). We
3746 * can't do this before storing relid in it.
3747 */
3748 EOXactListAdd(rel);
3749
3750 /* It's fully valid */
3751 rel->rd_isvalid = true;
3752
3753 /*
3754 * Caller expects us to pin the returned entry.
3755 */
3757
3758 return rel;
3759}
3760
3761
3762/*
3763 * RelationSetNewRelfilenumber
3764 *
3765 * Assign a new relfilenumber (physical file name), and possibly a new
3766 * persistence setting, to the relation.
3767 *
3768 * This allows a full rewrite of the relation to be done with transactional
3769 * safety (since the filenumber assignment can be rolled back). Note however
3770 * that there is no simple way to access the relation's old data for the
3771 * remainder of the current transaction. This limits the usefulness to cases
3772 * such as TRUNCATE or rebuilding an index from scratch.
3773 *
3774 * Caller must already hold exclusive lock on the relation.
3775 */
3776void
3777RelationSetNewRelfilenumber(Relation relation, char persistence)
3778{
3782 HeapTuple tuple;
3787
3788 if (!IsBinaryUpgrade)
3789 {
3790 /* Allocate a new relfilenumber */
3791 newrelfilenumber = GetNewRelFileNumber(relation->rd_rel->reltablespace,
3792 NULL, persistence);
3793 }
3794 else if (relation->rd_rel->relkind == RELKIND_INDEX)
3795 {
3797 ereport(ERROR,
3799 errmsg("index relfilenumber value not set when in binary upgrade mode")));
3800
3803 }
3804 else if (relation->rd_rel->relkind == RELKIND_RELATION)
3805 {
3807 ereport(ERROR,
3809 errmsg("heap relfilenumber value not set when in binary upgrade mode")));
3810
3813 }
3814 else
3815 ereport(ERROR,
3817 errmsg("unexpected request for new relfilenumber in binary upgrade mode")));
3818
3819 /*
3820 * Get a writable copy of the pg_class tuple for the given relation.
3821 */
3823
3826 if (!HeapTupleIsValid(tuple))
3827 elog(ERROR, "could not find tuple for relation %u",
3828 RelationGetRelid(relation));
3829 otid = tuple->t_self;
3831
3832 /*
3833 * Schedule unlinking of the old storage at transaction commit, except
3834 * when performing a binary upgrade, when we must do it immediately.
3835 */
3836 if (IsBinaryUpgrade)
3837 {
3838 SMgrRelation srel;
3839
3840 /*
3841 * During a binary upgrade, we use this code path to ensure that
3842 * pg_largeobject and its index have the same relfilenumbers as in the
3843 * old cluster. This is necessary because pg_upgrade treats
3844 * pg_largeobject like a user table, not a system table. It is however
3845 * possible that a table or index may need to end up with the same
3846 * relfilenumber in the new cluster as what it had in the old cluster.
3847 * Hence, we can't wait until commit time to remove the old storage.
3848 *
3849 * In general, this function needs to have transactional semantics,
3850 * and removing the old storage before commit time surely isn't.
3851 * However, it doesn't really matter, because if a binary upgrade
3852 * fails at this stage, the new cluster will need to be recreated
3853 * anyway.
3854 */
3855 srel = smgropen(relation->rd_locator, relation->rd_backend);
3856 smgrdounlinkall(&srel, 1, false);
3857 smgrclose(srel);
3858 }
3859 else
3860 {
3861 /* Not a binary upgrade, so just schedule it to happen later. */
3862 RelationDropStorage(relation);
3863 }
3864
3865 /*
3866 * Create storage for the main fork of the new relfilenumber. If it's a
3867 * table-like object, call into the table AM to do so, which'll also
3868 * create the table's init fork if needed.
3869 *
3870 * NOTE: If relevant for the AM, any conflict in relfilenumber value will
3871 * be caught here, if GetNewRelFileNumber messes up for any reason.
3872 */
3873 newrlocator = relation->rd_locator;
3875
3876 if (RELKIND_HAS_TABLE_AM(relation->rd_rel->relkind))
3877 {
3879 persistence,
3880 &freezeXid, &minmulti);
3881 }
3882 else if (RELKIND_HAS_STORAGE(relation->rd_rel->relkind))
3883 {
3884 /* handle these directly, at least for now */
3885 SMgrRelation srel;
3886
3887 srel = RelationCreateStorage(newrlocator, persistence, true);
3888 smgrclose(srel);
3889 }
3890 else
3891 {
3892 /* we shouldn't be called for anything else */
3893 elog(ERROR, "relation \"%s\" does not have storage",
3894 RelationGetRelationName(relation));
3895 }
3896
3897 /*
3898 * If we're dealing with a mapped index, pg_class.relfilenode doesn't
3899 * change; instead we have to send the update to the relation mapper.
3900 *
3901 * For mapped indexes, we don't actually change the pg_class entry at all;
3902 * this is essential when reindexing pg_class itself. That leaves us with
3903 * possibly-inaccurate values of relpages etc, but those will be fixed up
3904 * later.
3905 */
3906 if (RelationIsMapped(relation))
3907 {
3908 /* This case is only supported for indexes */
3909 Assert(relation->rd_rel->relkind == RELKIND_INDEX);
3910
3911 /* Since we're not updating pg_class, these had better not change */
3912 Assert(classform->relfrozenxid == freezeXid);
3913 Assert(classform->relminmxid == minmulti);
3914 Assert(classform->relpersistence == persistence);
3915
3916 /*
3917 * In some code paths it's possible that the tuple update we'd
3918 * otherwise do here is the only thing that would assign an XID for
3919 * the current transaction. However, we must have an XID to delete
3920 * files, so make sure one is assigned.
3921 */
3923
3924 /* Do the deed */
3927 relation->rd_rel->relisshared,
3928 false);
3929
3930 /* Since we're not updating pg_class, must trigger inval manually */
3931 CacheInvalidateRelcache(relation);
3932 }
3933 else
3934 {
3935 /* Normal case, update the pg_class entry */
3936 classform->relfilenode = newrelfilenumber;
3937
3938 /* relpages etc. never change for sequences */
3939 if (relation->rd_rel->relkind != RELKIND_SEQUENCE)
3940 {
3941 classform->relpages = 0; /* it's empty until further notice */
3942 classform->reltuples = -1;
3943 classform->relallvisible = 0;
3944 classform->relallfrozen = 0;
3945 }
3946 classform->relfrozenxid = freezeXid;
3947 classform->relminmxid = minmulti;
3948 classform->relpersistence = persistence;
3949
3951 }
3952
3954 heap_freetuple(tuple);
3955
3957
3958 /*
3959 * Make the pg_class row change or relation map change visible. This will
3960 * cause the relcache entry to get updated, too.
3961 */
3963
3965}
3966
3967/*
3968 * RelationAssumeNewRelfilelocator
3969 *
3970 * Code that modifies pg_class.reltablespace or pg_class.relfilenode must call
3971 * this. The call shall precede any code that might insert WAL records whose
3972 * replay would modify bytes in the new RelFileLocator, and the call shall follow
3973 * any WAL modifying bytes in the prior RelFileLocator. See struct RelationData.
3974 * Ideally, call this as near as possible to the CommandCounterIncrement()
3975 * that makes the pg_class change visible (before it or after it); that
3976 * minimizes the chance of future development adding a forbidden WAL insertion
3977 * between RelationAssumeNewRelfilelocator() and CommandCounterIncrement().
3978 */
3979void
3981{
3985
3986 /* Flag relation as needing eoxact cleanup (to clear these fields) */
3987 EOXactListAdd(relation);
3988}
3989
3990
3991/*
3992 * RelationCacheInitialize
3993 *
3994 * This initializes the relation descriptor cache. At the time
3995 * that this is invoked, we can't do database access yet (mainly
3996 * because the transaction subsystem is not up); all we are doing
3997 * is making an empty cache hashtable. This must be done before
3998 * starting the initialization transaction, because otherwise
3999 * AtEOXact_RelationCache would crash if that transaction aborts
4000 * before we can get the relcache set up.
4001 */
4002
4003#define INITRELCACHESIZE 400
4004
4005void
4007{
4008 HASHCTL ctl;
4009 int allocsize;
4010
4011 /*
4012 * make sure cache memory context exists
4013 */
4014 if (!CacheMemoryContext)
4016
4017 /*
4018 * create hashtable that indexes the relcache
4019 */
4020 ctl.keysize = sizeof(Oid);
4021 ctl.entrysize = sizeof(RelIdCacheEnt);
4022 RelationIdCache = hash_create("Relcache by OID", INITRELCACHESIZE,
4024
4025 /*
4026 * reserve enough in_progress_list slots for many cases
4027 */
4028 allocsize = 4;
4031 allocsize * sizeof(*in_progress_list));
4032 in_progress_list_maxlen = allocsize;
4033
4034 /*
4035 * relation mapper needs to be initialized too
4036 */
4038}
4039
4040/*
4041 * RelationCacheInitializePhase2
4042 *
4043 * This is called to prepare for access to shared catalogs during startup.
4044 * We must at least set up nailed reldescs for pg_database, pg_authid,
4045 * pg_auth_members, and pg_shseclabel. Ideally we'd like to have reldescs
4046 * for their indexes, too. We attempt to load this information from the
4047 * shared relcache init file. If that's missing or broken, just make
4048 * phony entries for the catalogs themselves.
4049 * RelationCacheInitializePhase3 will clean up as needed.
4050 */
4051void
4053{
4055
4056 /*
4057 * relation mapper needs initialized too
4058 */
4060
4061 /*
4062 * In bootstrap mode, the shared catalogs aren't there yet anyway, so do
4063 * nothing.
4064 */
4066 return;
4067
4068 /*
4069 * switch to cache memory context
4070 */
4072
4073 /*
4074 * Try to load the shared relcache cache file. If unsuccessful, bootstrap
4075 * the cache with pre-made descriptors for the critical shared catalogs.
4076 */
4077 if (!load_relcache_init_file(true))
4078 {
4079 formrdesc("pg_database", DatabaseRelation_Rowtype_Id, true,
4081 formrdesc("pg_authid", AuthIdRelation_Rowtype_Id, true,
4083 formrdesc("pg_auth_members", AuthMemRelation_Rowtype_Id, true,
4085 formrdesc("pg_shseclabel", SharedSecLabelRelation_Rowtype_Id, true,
4087 formrdesc("pg_subscription", SubscriptionRelation_Rowtype_Id, true,
4089 formrdesc("pg_parameter_acl", ParameterAclRelation_Rowtype_Id, true,
4091
4092#define NUM_CRITICAL_SHARED_RELS 6 /* fix if you change list above */
4093 }
4094
4096}
4097
4098/*
4099 * RelationCacheInitializePhase3
4100 *
4101 * This is called as soon as the catcache and transaction system
4102 * are functional and we have determined MyDatabaseId. At this point
4103 * we can actually read data from the database's system catalogs.
4104 * We first try to read pre-computed relcache entries from the local
4105 * relcache init file. If that's missing or broken, make phony entries
4106 * for the minimum set of nailed-in-cache relations. Then (unless
4107 * bootstrapping) make sure we have entries for the critical system
4108 * indexes. Once we've done all this, we have enough infrastructure to
4109 * open any system catalog or use any catcache. The last step is to
4110 * rewrite the cache files if needed.
4111 */
4112void
4114{
4115 HASH_SEQ_STATUS status;
4119
4120 /*
4121 * relation mapper needs initialized too
4122 */
4124
4125 /*
4126 * switch to cache memory context
4127 */
4129
4130 /*
4131 * Try to load the local relcache cache file. If unsuccessful, bootstrap
4132 * the cache with pre-made descriptors for the critical "nailed-in" system
4133 * catalogs.
4134 */
4137 {
4138 needNewCacheFile = true;
4139
4140 formrdesc("pg_class", RelationRelation_Rowtype_Id, false,
4142 formrdesc("pg_attribute", AttributeRelation_Rowtype_Id, false,
4144 formrdesc("pg_proc", ProcedureRelation_Rowtype_Id, false,
4146 formrdesc("pg_type", TypeRelation_Rowtype_Id, false,
4148
4149#define NUM_CRITICAL_LOCAL_RELS 4 /* fix if you change list above */
4150 }
4151
4153
4154 /* In bootstrap mode, the faked-up formrdesc info is all we'll have */
4156 return;
4157
4158 /*
4159 * If we didn't get the critical system indexes loaded into relcache, do
4160 * so now. These are critical because the catcache and/or opclass cache
4161 * depend on them for fetches done during relcache load. Thus, we have an
4162 * infinite-recursion problem. We can break the recursion by doing
4163 * heapscans instead of indexscans at certain key spots. To avoid hobbling
4164 * performance, we only want to do that until we have the critical indexes
4165 * loaded into relcache. Thus, the flag criticalRelcachesBuilt is used to
4166 * decide whether to do heapscan or indexscan at the key spots, and we set
4167 * it true after we've loaded the critical indexes.
4168 *
4169 * The critical indexes are marked as "nailed in cache", partly to make it
4170 * easy for load_relcache_init_file to count them, but mainly because we
4171 * cannot flush and rebuild them once we've set criticalRelcachesBuilt to
4172 * true. (NOTE: perhaps it would be possible to reload them by
4173 * temporarily setting criticalRelcachesBuilt to false again. For now,
4174 * though, we just nail 'em in.)
4175 *
4176 * RewriteRelRulenameIndexId and TriggerRelidNameIndexId are not critical
4177 * in the same way as the others, because the critical catalogs don't
4178 * (currently) have any rules or triggers, and so these indexes can be
4179 * rebuilt without inducing recursion. However they are used during
4180 * relcache load when a rel does have rules or triggers, so we choose to
4181 * nail them for performance reasons.
4182 */
4184 {
4199
4200#define NUM_CRITICAL_LOCAL_INDEXES 7 /* fix if you change list above */
4201
4203 }
4204
4205 /*
4206 * Process critical shared indexes too.
4207 *
4208 * DatabaseNameIndexId isn't critical for relcache loading, but rather for
4209 * initial lookup of MyDatabaseId, without which we'll never find any
4210 * non-shared catalogs at all. Autovacuum calls InitPostgres with a
4211 * database OID, so it instead depends on DatabaseOidIndexId. We also
4212 * need to nail up some indexes on pg_authid and pg_auth_members for use
4213 * during client authentication. We need indexes on pg_parameter_acl for
4214 * ACL checks on settings specified in the startup packet for a physical
4215 * replication connection. SharedSecLabelObjectIndexId isn't critical for
4216 * the core system, but authentication hooks might be interested in it.
4217 */
4219 {
4236
4237#define NUM_CRITICAL_SHARED_INDEXES 8 /* fix if you change list above */
4238
4240 }
4241
4242 /*
4243 * Now, scan all the relcache entries and update anything that might be
4244 * wrong in the results from formrdesc or the relcache cache file. If we
4245 * faked up relcache entries using formrdesc, then read the real pg_class
4246 * rows and replace the fake entries with them. Also, if any of the
4247 * relcache entries have rules, triggers, or security policies, load that
4248 * info the hard way since it isn't recorded in the cache file.
4249 *
4250 * Whenever we access the catalogs to read data, there is a possibility of
4251 * a shared-inval cache flush causing relcache entries to be removed.
4252 * Since hash_seq_search only guarantees to still work after the *current*
4253 * entry is removed, it's unsafe to continue the hashtable scan afterward.
4254 * We handle this by restarting the scan from scratch after each access.
4255 * This is theoretically O(N^2), but the number of entries that actually
4256 * need to be fixed is small enough that it doesn't matter.
4257 */
4259
4260 while ((idhentry = (RelIdCacheEnt *) hash_seq_search(&status)) != NULL)
4261 {
4262 Relation relation = idhentry->reldesc;
4263 bool restart = false;
4264
4265 /*
4266 * Make sure *this* entry doesn't get flushed while we work with it.
4267 */
4269
4270 /*
4271 * If it's a faked-up entry, read the real pg_class tuple.
4272 */
4273 if (relation->rd_rel->relowner == InvalidOid)
4274 {
4275 HeapTuple htup;
4277
4278 htup = SearchSysCache1(RELOID,
4280 if (!HeapTupleIsValid(htup))
4281 ereport(FATAL,
4283 errmsg_internal("cache lookup failed for relation %u",
4284 RelationGetRelid(relation)));
4285 relp = (Form_pg_class) GETSTRUCT(htup);
4286
4287 /*
4288 * Copy tuple to relation->rd_rel. (See notes in
4289 * AllocateRelationDesc())
4290 */
4291 memcpy((char *) relation->rd_rel, (char *) relp, CLASS_TUPLE_SIZE);
4292
4293 /* Update rd_options while we have the tuple */
4294 if (relation->rd_options)
4295 pfree(relation->rd_options);
4296 RelationParseRelOptions(relation, htup);
4297
4298 /*
4299 * Check the values in rd_att were set up correctly. (We cannot
4300 * just copy them over now: formrdesc must have set up the rd_att
4301 * data correctly to start with, because it may already have been
4302 * copied into one or more catcache entries.)
4303 */
4304 Assert(relation->rd_att->tdtypeid == relp->reltype);
4305 Assert(relation->rd_att->tdtypmod == -1);
4306
4307 ReleaseSysCache(htup);
4308
4309 /* relowner had better be OK now, else we'll loop forever */
4310 if (relation->rd_rel->relowner == InvalidOid)
4311 elog(ERROR, "invalid relowner in pg_class entry for \"%s\"",
4312 RelationGetRelationName(relation));
4313
4314 restart = true;
4315 }
4316
4317 /*
4318 * Fix data that isn't saved in relcache cache file.
4319 *
4320 * relhasrules or relhastriggers could possibly be wrong or out of
4321 * date. If we don't actually find any rules or triggers, clear the
4322 * local copy of the flag so that we don't get into an infinite loop
4323 * here. We don't make any attempt to fix the pg_class entry, though.
4324 */
4325 if (relation->rd_rel->relhasrules && relation->rd_rules == NULL)
4326 {
4327 RelationBuildRuleLock(relation);
4328 if (relation->rd_rules == NULL)
4329 relation->rd_rel->relhasrules = false;
4330 restart = true;
4331 }
4332 if (relation->rd_rel->relhastriggers && relation->trigdesc == NULL)
4333 {
4334 RelationBuildTriggers(relation);
4335 if (relation->trigdesc == NULL)
4336 relation->rd_rel->relhastriggers = false;
4337 restart = true;
4338 }
4339
4340 /*
4341 * Re-load the row security policies if the relation has them, since
4342 * they are not preserved in the cache. Note that we can never NOT
4343 * have a policy while relrowsecurity is true,
4344 * RelationBuildRowSecurity will create a single default-deny policy
4345 * if there is no policy defined in pg_policy.
4346 */
4347 if (relation->rd_rel->relrowsecurity && relation->rd_rsdesc == NULL)
4348 {
4349 RelationBuildRowSecurity(relation);
4350
4351 Assert(relation->rd_rsdesc != NULL);
4352 restart = true;
4353 }
4354
4355 /* Reload tableam data if needed */
4356 if (relation->rd_tableam == NULL &&
4357 (RELKIND_HAS_TABLE_AM(relation->rd_rel->relkind) || relation->rd_rel->relkind == RELKIND_SEQUENCE))
4358 {
4360 Assert(relation->rd_tableam != NULL);
4361
4362 restart = true;
4363 }
4364
4365 /* Release hold on the relation */
4367
4368 /* Now, restart the hashtable scan if needed */
4369 if (restart)
4370 {
4371 hash_seq_term(&status);
4373 }
4374 }
4375
4376 /*
4377 * Lastly, write out new relcache cache files if needed. We don't bother
4378 * to distinguish cases where only one of the two needs an update.
4379 */
4380 if (needNewCacheFile)
4381 {
4382 /*
4383 * Force all the catcaches to finish initializing and thereby open the
4384 * catalogs and indexes they use. This will preload the relcache with
4385 * entries for all the most important system catalogs and indexes, so
4386 * that the init files will be most useful for future backends.
4387 */
4389
4390 /* now write the files */
4393 }
4394}
4395
4396/*
4397 * Load one critical system index into the relcache
4398 *
4399 * indexoid is the OID of the target index, heapoid is the OID of the catalog
4400 * it belongs to.
4401 */
4402static void
4404{
4405 Relation ird;
4406
4407 /*
4408 * We must lock the underlying catalog before locking the index to avoid
4409 * deadlock, since RelationBuildDesc might well need to read the catalog,
4410 * and if anyone else is exclusive-locking this catalog and index they'll
4411 * be doing it in that order.
4412 */
4415 ird = RelationBuildDesc(indexoid, true);
4416 if (ird == NULL)
4417 ereport(PANIC,
4419 errmsg_internal("could not open critical system index %u", indexoid));
4420 ird->rd_isnailed = true;
4421 ird->rd_refcnt = 1;
4424
4426}
4427
4428/*
4429 * GetPgClassDescriptor -- get a predefined tuple descriptor for pg_class
4430 * GetPgIndexDescriptor -- get a predefined tuple descriptor for pg_index
4431 *
4432 * We need this kluge because we have to be able to access non-fixed-width
4433 * fields of pg_class and pg_index before we have the standard catalog caches
4434 * available. We use predefined data that's set up in just the same way as
4435 * the bootstrapped reldescs used by formrdesc(). The resulting tupdesc is
4436 * not 100% kosher: it does not have the correct rowtype OID in tdtypeid, nor
4437 * does it have a TupleConstr field. But it's good enough for the purpose of
4438 * extracting fields.
4439 */
4440static TupleDesc
4442{
4445 int i;
4446
4448
4450 result->tdtypeid = RECORDOID; /* not right, but we don't care */
4451 result->tdtypmod = -1;
4452
4453 for (i = 0; i < natts; i++)
4454 {
4456
4458 }
4459
4461
4462 /* Note: we don't bother to set up a TupleConstr entry */
4463
4465
4466 return result;
4467}
4468
4469static TupleDesc
4471{
4472 static TupleDesc pgclassdesc = NULL;
4473
4474 /* Already done? */
4475 if (pgclassdesc == NULL)
4478
4479 return pgclassdesc;
4480}
4481
4482static TupleDesc
4484{
4485 static TupleDesc pgindexdesc = NULL;
4486
4487 /* Already done? */
4488 if (pgindexdesc == NULL)
4491
4492 return pgindexdesc;
4493}
4494
4495/*
4496 * Load any default attribute value definitions for the relation.
4497 *
4498 * ndef is the number of attributes that were marked atthasdef.
4499 *
4500 * Note: we don't make it a hard error to be missing some pg_attrdef records.
4501 * We can limp along as long as nothing needs to use the default value. Code
4502 * that fails to find an expected AttrDefault record should throw an error.
4503 */
4504static void
4506{
4511 HeapTuple htup;
4512 int found = 0;
4513
4514 /* Allocate array with room for as many entries as expected */
4515 attrdef = (AttrDefault *)
4517 ndef * sizeof(AttrDefault));
4518
4519 /* Search pg_attrdef for relevant entries */
4524
4527 NULL, 1, &skey);
4528
4530 {
4532 Datum val;
4533 bool isnull;
4534
4535 /* protect limited size of array */
4536 if (found >= ndef)
4537 {
4538 elog(WARNING, "unexpected pg_attrdef record found for attribute %d of relation \"%s\"",
4539 adform->adnum, RelationGetRelationName(relation));
4540 break;
4541 }
4542
4543 val = fastgetattr(htup,
4545 adrel->rd_att, &isnull);
4546 if (isnull)
4547 elog(WARNING, "null adbin for attribute %d of relation \"%s\"",
4548 adform->adnum, RelationGetRelationName(relation));
4549 else
4550 {
4551 /* detoast and convert to cstring in caller's context */
4552 char *s = TextDatumGetCString(val);
4553
4554 attrdef[found].adnum = adform->adnum;
4556 pfree(s);
4557 found++;
4558 }
4559 }
4560
4563
4564 if (found != ndef)
4565 elog(WARNING, "%d pg_attrdef record(s) missing for relation \"%s\"",
4566 ndef - found, RelationGetRelationName(relation));
4567
4568 /*
4569 * Sort the AttrDefault entries by adnum, for the convenience of
4570 * equalTupleDescs(). (Usually, they already will be in order, but this
4571 * might not be so if systable_getnext isn't using an index.)
4572 */
4573 if (found > 1)
4574 qsort(attrdef, found, sizeof(AttrDefault), AttrDefaultCmp);
4575
4576 /* Install array only after it's fully valid */
4577 relation->rd_att->constr->defval = attrdef;
4578 relation->rd_att->constr->num_defval = found;
4579}
4580
4581/*
4582 * qsort comparator to sort AttrDefault entries by adnum
4583 */
4584static int
4585AttrDefaultCmp(const void *a, const void *b)
4586{
4587 const AttrDefault *ada = (const AttrDefault *) a;
4588 const AttrDefault *adb = (const AttrDefault *) b;
4589
4590 return pg_cmp_s16(ada->adnum, adb->adnum);
4591}
4592
4593/*
4594 * Load any check constraints for the relation, and update not-null validity
4595 * of invalid constraints.
4596 *
4597 * As with defaults, if we don't find the expected number of them, just warn
4598 * here. The executor should throw an error if an INSERT/UPDATE is attempted.
4599 */
4600static void
4602{
4603 ConstrCheck *check;
4604 int ncheck = relation->rd_rel->relchecks;
4607 ScanKeyData skey[1];
4608 HeapTuple htup;
4609 int found = 0;
4610
4611 /* Allocate array with room for as many entries as expected, if needed */
4612 if (ncheck > 0)
4613 check = (ConstrCheck *)
4615 ncheck * sizeof(ConstrCheck));
4616 else
4617 check = NULL;
4618
4619 /* Search pg_constraint for relevant entries */
4620 ScanKeyInit(&skey[0],
4624
4627 NULL, 1, skey);
4628
4630 {
4632 Datum val;
4633 bool isnull;
4634
4635 /*
4636 * If this is a not-null constraint, then only look at it if it's
4637 * invalid, and if so, mark the TupleDesc entry as known invalid.
4638 * Otherwise move on. We'll mark any remaining columns that are still
4639 * in UNKNOWN state as known valid later. This allows us not to have
4640 * to extract the attnum from this constraint tuple in the vast
4641 * majority of cases.
4642 */
4643 if (conform->contype == CONSTRAINT_NOTNULL)
4644 {
4645 if (!conform->convalidated)
4646 {
4648
4652 relation->rd_att->compact_attrs[attnum - 1].attnullability =
4654 }
4655
4656 continue;
4657 }
4658
4659 /* For what follows, consider check constraints only */
4660 if (conform->contype != CONSTRAINT_CHECK)
4661 continue;
4662
4663 /* protect limited size of array */
4664 if (found >= ncheck)
4665 {
4666 elog(WARNING, "unexpected pg_constraint record found for relation \"%s\"",
4667 RelationGetRelationName(relation));
4668 break;
4669 }
4670
4671 /* Grab and test conbin is actually set */
4672 val = fastgetattr(htup,
4674 conrel->rd_att, &isnull);
4675 if (isnull)
4676 elog(WARNING, "null conbin for relation \"%s\"",
4677 RelationGetRelationName(relation));
4678 else
4679 {
4680 /* detoast and convert to cstring in caller's context */
4681 char *s = TextDatumGetCString(val);
4682
4683 check[found].ccenforced = conform->conenforced;
4684 check[found].ccvalid = conform->convalidated;
4685 check[found].ccnoinherit = conform->connoinherit;
4687 NameStr(conform->conname));
4688 check[found].ccbin = MemoryContextStrdup(CacheMemoryContext, s);
4689
4690 pfree(s);
4691 found++;
4692 }
4693 }
4694
4697
4698 if (found != ncheck)
4699 elog(WARNING, "%d pg_constraint record(s) missing for relation \"%s\"",
4700 ncheck - found, RelationGetRelationName(relation));
4701
4702 /*
4703 * Sort the records by name. This ensures that CHECKs are applied in a
4704 * deterministic order, and it also makes equalTupleDescs() faster.
4705 */
4706 if (found > 1)
4707 qsort(check, found, sizeof(ConstrCheck), CheckConstraintCmp);
4708
4709 /* Install array only after it's fully valid */
4710 relation->rd_att->constr->check = check;
4711 relation->rd_att->constr->num_check = found;
4712}
4713
4714/*
4715 * qsort comparator to sort ConstrCheck entries by name
4716 */
4717static int
4718CheckConstraintCmp(const void *a, const void *b)
4719{
4720 const ConstrCheck *ca = (const ConstrCheck *) a;
4721 const ConstrCheck *cb = (const ConstrCheck *) b;
4722
4723 return strcmp(ca->ccname, cb->ccname);
4724}
4725
4726/*
4727 * RelationGetFKeyList -- get a list of foreign key info for the relation
4728 *
4729 * Returns a list of ForeignKeyCacheInfo structs, one per FK constraining
4730 * the given relation. This data is a direct copy of relevant fields from
4731 * pg_constraint. The list items are in no particular order.
4732 *
4733 * CAUTION: the returned list is part of the relcache's data, and could
4734 * vanish in a relcache entry reset. Callers must inspect or copy it
4735 * before doing anything that might trigger a cache flush, such as
4736 * system catalog accesses. copyObject() can be used if desired.
4737 * (We define it this way because current callers want to filter and
4738 * modify the list entries anyway, so copying would be a waste of time.)
4739 */
4740List *
4742{
4743 List *result;
4747 HeapTuple htup;
4748 List *oldlist;
4750
4751 /* Quick exit if we already computed the list. */
4752 if (relation->rd_fkeyvalid)
4753 return relation->rd_fkeylist;
4754
4755 /*
4756 * We build the list we intend to return (in the caller's context) while
4757 * doing the scan. After successfully completing the scan, we copy that
4758 * list into the relcache entry. This avoids cache-context memory leakage
4759 * if we get some sort of error partway through.
4760 */
4761 result = NIL;
4762
4763 /* Prepare to scan pg_constraint for entries having conrelid = this rel. */
4768
4771 NULL, 1, &skey);
4772
4774 {
4775 Form_pg_constraint constraint = (Form_pg_constraint) GETSTRUCT(htup);
4776 ForeignKeyCacheInfo *info;
4777
4778 /* consider only foreign keys */
4779 if (constraint->contype != CONSTRAINT_FOREIGN)
4780 continue;
4781
4783 info->conoid = constraint->oid;
4784 info->conrelid = constraint->conrelid;
4785 info->confrelid = constraint->confrelid;
4786 info->conenforced = constraint->conenforced;
4787
4788 DeconstructFkConstraintRow(htup, &info->nkeys,
4789 info->conkey,
4790 info->confkey,
4791 info->conpfeqop,
4792 NULL, NULL, NULL, NULL);
4793
4794 /* Add FK's node to the result list */
4795 result = lappend(result, info);
4796 }
4797
4800
4801 /* Now save a copy of the completed list in the relcache entry. */
4803 oldlist = relation->rd_fkeylist;
4804 relation->rd_fkeylist = copyObject(result);
4805 relation->rd_fkeyvalid = true;
4807
4808 /* Don't leak the old list, if there is one */
4810
4811 return result;
4812}
4813
4814/*
4815 * RelationGetIndexList -- get a list of OIDs of indexes on this relation
4816 *
4817 * The index list is created only if someone requests it. We scan pg_index
4818 * to find relevant indexes, and add the list to the relcache entry so that
4819 * we won't have to compute it again. Note that shared cache inval of a
4820 * relcache entry will delete the old list and set rd_indexvalid to false,
4821 * so that we must recompute the index list on next request. This handles
4822 * creation or deletion of an index.
4823 *
4824 * Indexes that are marked not indislive are omitted from the returned list.
4825 * Such indexes are expected to be dropped momentarily, and should not be
4826 * touched at all by any caller of this function.
4827 *
4828 * The returned list is guaranteed to be sorted in order by OID. This is
4829 * needed by the executor, since for index types that we obtain exclusive
4830 * locks on when updating the index, all backends must lock the indexes in
4831 * the same order or we will get deadlocks (see ExecOpenIndices()). Any
4832 * consistent ordering would do, but ordering by OID is easy.
4833 *
4834 * Since shared cache inval causes the relcache's copy of the list to go away,
4835 * we return a copy of the list palloc'd in the caller's context. The caller
4836 * may list_free() the returned list after scanning it. This is necessary
4837 * since the caller will typically be doing syscache lookups on the relevant
4838 * indexes, and syscache lookup could cause SI messages to be processed!
4839 *
4840 * In exactly the same way, we update rd_pkindex, which is the OID of the
4841 * relation's primary key index if any, else InvalidOid; and rd_replidindex,
4842 * which is the pg_class OID of an index to be used as the relation's
4843 * replication identity index, or InvalidOid if there is no such index.
4844 */
4845List *
4847{
4851 HeapTuple htup;
4852 List *result;
4853 List *oldlist;
4854 char replident = relation->rd_rel->relreplident;
4857 bool pkdeferrable = false;
4859
4860 /* Quick exit if we already computed the list. */
4861 if (relation->rd_indexvalid)
4862 return list_copy(relation->rd_indexlist);
4863
4864 /*
4865 * We build the list we intend to return (in the caller's context) while
4866 * doing the scan. After successfully completing the scan, we copy that
4867 * list into the relcache entry. This avoids cache-context memory leakage
4868 * if we get some sort of error partway through.
4869 */
4870 result = NIL;
4871
4872 /* Prepare to scan pg_index for entries having indrelid = this rel. */
4877
4880 NULL, 1, &skey);
4881
4883 {
4885
4886 /*
4887 * Ignore any indexes that are currently being dropped. This will
4888 * prevent them from being searched, inserted into, or considered in
4889 * HOT-safety decisions. It's unsafe to touch such an index at all
4890 * since its catalog entries could disappear at any instant.
4891 */
4892 if (!index->indislive)
4893 continue;
4894
4895 /* add index's OID to result list */
4896 result = lappend_oid(result, index->indexrelid);
4897
4898 /*
4899 * Non-unique or predicate indexes aren't interesting for either oid
4900 * indexes or replication identity indexes, so don't check them.
4901 * Deferred ones are not useful for replication identity either; but
4902 * we do include them if they are PKs.
4903 */
4904 if (!index->indisunique ||
4906 continue;
4907
4908 /*
4909 * Remember primary key index, if any. For regular tables we do this
4910 * only if the index is valid; but for partitioned tables, then we do
4911 * it even if it's invalid.
4912 *
4913 * The reason for returning invalid primary keys for partitioned
4914 * tables is that we need it to prevent drop of not-null constraints
4915 * that may underlie such a primary key, which is only a problem for
4916 * partitioned tables.
4917 */
4918 if (index->indisprimary &&
4919 (index->indisvalid ||
4920 relation->rd_rel->relkind == RELKIND_PARTITIONED_TABLE))
4921 {
4922 pkeyIndex = index->indexrelid;
4923 pkdeferrable = !index->indimmediate;
4924 }
4925
4926 if (!index->indimmediate)
4927 continue;
4928
4929 if (!index->indisvalid)
4930 continue;
4931
4932 /* remember explicitly chosen replica index */
4933 if (index->indisreplident)
4934 candidateIndex = index->indexrelid;
4935 }
4936
4938
4940
4941 /* Sort the result list into OID order, per API spec. */
4943
4944 /* Now save a copy of the completed list in the relcache entry. */
4946 oldlist = relation->rd_indexlist;
4947 relation->rd_indexlist = list_copy(result);
4948 relation->rd_pkindex = pkeyIndex;
4949 relation->rd_ispkdeferrable = pkdeferrable;
4951 relation->rd_replidindex = pkeyIndex;
4952 else if (replident == REPLICA_IDENTITY_INDEX && OidIsValid(candidateIndex))
4953 relation->rd_replidindex = candidateIndex;
4954 else
4955 relation->rd_replidindex = InvalidOid;
4956 relation->rd_indexvalid = true;
4958
4959 /* Don't leak the old list, if there is one */
4961
4962 return result;
4963}
4964
4965/*
4966 * RelationGetStatExtList
4967 * get a list of OIDs of statistics objects on this relation
4968 *
4969 * The statistics list is created only if someone requests it, in a way
4970 * similar to RelationGetIndexList(). We scan pg_statistic_ext to find
4971 * relevant statistics, and add the list to the relcache entry so that we
4972 * won't have to compute it again. Note that shared cache inval of a
4973 * relcache entry will delete the old list and set rd_statvalid to 0,
4974 * so that we must recompute the statistics list on next request. This
4975 * handles creation or deletion of a statistics object.
4976 *
4977 * The returned list is guaranteed to be sorted in order by OID, although
4978 * this is not currently needed.
4979 *
4980 * Since shared cache inval causes the relcache's copy of the list to go away,
4981 * we return a copy of the list palloc'd in the caller's context. The caller
4982 * may list_free() the returned list after scanning it. This is necessary
4983 * since the caller will typically be doing syscache lookups on the relevant
4984 * statistics, and syscache lookup could cause SI messages to be processed!
4985 */
4986List *
4988{
4992 HeapTuple htup;
4993 List *result;
4994 List *oldlist;
4996
4997 /* Quick exit if we already computed the list. */
4998 if (relation->rd_statvalid != 0)
4999 return list_copy(relation->rd_statlist);
5000
5001 /*
5002 * We build the list we intend to return (in the caller's context) while
5003 * doing the scan. After successfully completing the scan, we copy that
5004 * list into the relcache entry. This avoids cache-context memory leakage
5005 * if we get some sort of error partway through.
5006 */
5007 result = NIL;
5008
5009 /*
5010 * Prepare to scan pg_statistic_ext for entries having stxrelid = this
5011 * rel.
5012 */
5017
5020 NULL, 1, &skey);
5021
5023 {
5024 Oid oid = ((Form_pg_statistic_ext) GETSTRUCT(htup))->oid;
5025
5026 result = lappend_oid(result, oid);
5027 }
5028
5030
5032
5033 /* Sort the result list into OID order, per API spec. */
5035
5036 /* Now save a copy of the completed list in the relcache entry. */
5038 oldlist = relation->rd_statlist;
5039 relation->rd_statlist = list_copy(result);
5040
5041 relation->rd_statvalid = true;
5043
5044 /* Don't leak the old list, if there is one */
5046
5047 return result;
5048}
5049
5050/*
5051 * RelationGetPrimaryKeyIndex -- get OID of the relation's primary key index
5052 *
5053 * Returns InvalidOid if there is no such index, or if the primary key is
5054 * DEFERRABLE and the caller isn't OK with that.
5055 */
5056Oid
5058{
5059 List *ilist;
5060
5061 if (!relation->rd_indexvalid)
5062 {
5063 /* RelationGetIndexList does the heavy lifting. */
5064 ilist = RelationGetIndexList(relation);
5066 Assert(relation->rd_indexvalid);
5067 }
5068
5069 if (deferrable_ok)
5070 return relation->rd_pkindex;
5071 else if (relation->rd_ispkdeferrable)
5072 return InvalidOid;
5073 return relation->rd_pkindex;
5074}
5075
5076/*
5077 * RelationGetReplicaIndex -- get OID of the relation's replica identity index
5078 *
5079 * Returns InvalidOid if there is no such index.
5080 */
5081Oid
5083{
5084 List *ilist;
5085
5086 if (!relation->rd_indexvalid)
5087 {
5088 /* RelationGetIndexList does the heavy lifting. */
5089 ilist = RelationGetIndexList(relation);
5091 Assert(relation->rd_indexvalid);
5092 }
5093
5094 return relation->rd_replidindex;
5095}
5096
5097/*
5098 * RelationGetIndexExpressions -- get the index expressions for an index
5099 *
5100 * We cache the result of transforming pg_index.indexprs into a node tree.
5101 * If the rel is not an index or has no expressional columns, we return NIL.
5102 * Otherwise, the returned tree is copied into the caller's memory context.
5103 * (We don't want to return a pointer to the relcache copy, since it could
5104 * disappear due to relcache invalidation.)
5105 */
5106List *
5108{
5109 List *result;
5111 bool isnull;
5112 char *exprsString;
5114
5115 /* Quick exit if we already computed the result. */
5116 if (relation->rd_indexprs)
5117 return copyObject(relation->rd_indexprs);
5118
5119 /* Quick exit if there is nothing to do. */
5120 if (relation->rd_indextuple == NULL ||
5122 return NIL;
5123
5124 /*
5125 * We build the tree we intend to return in the caller's context. After
5126 * successfully completing the work, we copy it into the relcache entry.
5127 * This avoids problems if we get some sort of error partway through.
5128 */
5132 &isnull);
5133 Assert(!isnull);
5137
5138 /*
5139 * Run the expressions through eval_const_expressions. This is not just an
5140 * optimization, but is necessary, because the planner will be comparing
5141 * them to similarly-processed qual clauses, and may fail to detect valid
5142 * matches without this. We must not use canonicalize_qual, however,
5143 * since these aren't qual expressions.
5144 */
5146
5147 /* May as well fix opfuncids too */
5149
5150 /* Now save a copy of the completed tree in the relcache entry. */
5152 relation->rd_indexprs = copyObject(result);
5154
5155 return result;
5156}
5157
5158/*
5159 * RelationGetDummyIndexExpressions -- get dummy expressions for an index
5160 *
5161 * Return a list of dummy expressions (just Const nodes) with the same
5162 * types/typmods/collations as the index's real expressions. This is
5163 * useful in situations where we don't want to run any user-defined code.
5164 */
5165List *
5167{
5168 List *result;
5170 bool isnull;
5171 char *exprsString;
5172 List *rawExprs;
5173 ListCell *lc;
5174
5175 /* Quick exit if there is nothing to do. */
5176 if (relation->rd_indextuple == NULL ||
5178 return NIL;
5179
5180 /* Extract raw node tree(s) from index tuple. */
5184 &isnull);
5185 Assert(!isnull);
5189
5190 /* Construct null Consts; the typlen and typbyval are arbitrary. */
5191 result = NIL;
5192 foreach(lc, rawExprs)
5193 {
5194 Node *rawExpr = (Node *) lfirst(lc);
5195
5200 1,
5201 (Datum) 0,
5202 true,
5203 true));
5204 }
5205
5206 return result;
5207}
5208
5209/*
5210 * RelationGetIndexPredicate -- get the index predicate for an index
5211 *
5212 * We cache the result of transforming pg_index.indpred into an implicit-AND
5213 * node tree (suitable for use in planning).
5214 * If the rel is not an index or has no predicate, we return NIL.
5215 * Otherwise, the returned tree is copied into the caller's memory context.
5216 * (We don't want to return a pointer to the relcache copy, since it could
5217 * disappear due to relcache invalidation.)
5218 */
5219List *
5221{
5222 List *result;
5224 bool isnull;
5225 char *predString;
5227
5228 /* Quick exit if we already computed the result. */
5229 if (relation->rd_indpred)
5230 return copyObject(relation->rd_indpred);
5231
5232 /* Quick exit if there is nothing to do. */
5233 if (relation->rd_indextuple == NULL ||
5235 return NIL;
5236
5237 /*
5238 * We build the tree we intend to return in the caller's context. After
5239 * successfully completing the work, we copy it into the relcache entry.
5240 * This avoids problems if we get some sort of error partway through.
5241 */
5245 &isnull);
5246 Assert(!isnull);
5250
5251 /*
5252 * Run the expression through const-simplification and canonicalization.
5253 * This is not just an optimization, but is necessary, because the planner
5254 * will be comparing it to similarly-processed qual clauses, and may fail
5255 * to detect valid matches without this. This must match the processing
5256 * done to qual clauses in preprocess_expression()! (We can skip the
5257 * stuff involving subqueries, however, since we don't allow any in index
5258 * predicates.)
5259 */
5261
5262 result = (List *) canonicalize_qual((Expr *) result, false);
5263
5264 /* Also convert to implicit-AND format */
5266
5267 /* May as well fix opfuncids too */
5269
5270 /* Now save a copy of the completed tree in the relcache entry. */
5272 relation->rd_indpred = copyObject(result);
5274
5275 return result;
5276}
5277
5278/*
5279 * RelationGetIndexAttrBitmap -- get a bitmap of index attribute numbers
5280 *
5281 * The result has a bit set for each attribute used anywhere in the index
5282 * definitions of all the indexes on this relation. (This includes not only
5283 * simple index keys, but attributes used in expressions and partial-index
5284 * predicates.)
5285 *
5286 * Depending on attrKind, a bitmap covering attnums for certain columns is
5287 * returned:
5288 * INDEX_ATTR_BITMAP_KEY Columns in non-partial unique indexes not
5289 * in expressions (i.e., usable for FKs)
5290 * INDEX_ATTR_BITMAP_PRIMARY_KEY Columns in the table's primary key
5291 * (beware: even if PK is deferrable!)
5292 * INDEX_ATTR_BITMAP_IDENTITY_KEY Columns in the table's replica identity
5293 * index (empty if FULL)
5294 * INDEX_ATTR_BITMAP_HOT_BLOCKING Columns that block updates from being HOT
5295 * INDEX_ATTR_BITMAP_SUMMARIZED Columns included in summarizing indexes
5296 *
5297 * Attribute numbers are offset by FirstLowInvalidHeapAttributeNumber so that
5298 * we can include system attributes (e.g., OID) in the bitmap representation.
5299 *
5300 * Deferred indexes are considered for the primary key, but not for replica
5301 * identity.
5302 *
5303 * Caller had better hold at least RowExclusiveLock on the target relation
5304 * to ensure it is safe (deadlock-free) for us to take locks on the relation's
5305 * indexes. Note that since the introduction of CREATE INDEX CONCURRENTLY,
5306 * that lock level doesn't guarantee a stable set of indexes, so we have to
5307 * be prepared to retry here in case of a change in the set of indexes.
5308 *
5309 * The returned result is palloc'd in the caller's memory context and should
5310 * be bms_free'd when not needed anymore.
5311 */
5312Bitmapset *
5314{
5315 Bitmapset *uindexattrs; /* columns in unique indexes */
5316 Bitmapset *pkindexattrs; /* columns in the primary index */
5317 Bitmapset *idindexattrs; /* columns in the replica identity */
5318 Bitmapset *hotblockingattrs; /* columns with HOT blocking indexes */
5319 Bitmapset *summarizedattrs; /* columns with summarizing indexes */
5324 ListCell *l;
5326
5327 /* Quick exit if we already computed the result. */
5328 if (relation->rd_attrsvalid)
5329 {
5330 switch (attrKind)
5331 {
5333 return bms_copy(relation->rd_keyattr);
5335 return bms_copy(relation->rd_pkattr);
5337 return bms_copy(relation->rd_idattr);
5339 return bms_copy(relation->rd_hotblockingattr);
5341 return bms_copy(relation->rd_summarizedattr);
5342 default:
5343 elog(ERROR, "unknown attrKind %u", attrKind);
5344 }
5345 }
5346
5347 /* Fast path if definitely no indexes */
5348 if (!RelationGetForm(relation)->relhasindex)
5349 return NULL;
5350
5351 /*
5352 * Get cached list of index OIDs. If we have to start over, we do so here.
5353 */
5354restart:
5356
5357 /* Fall out if no indexes (but relhasindex was set) */
5358 if (indexoidlist == NIL)
5359 return NULL;
5360
5361 /*
5362 * Copy the rd_pkindex and rd_replidindex values computed by
5363 * RelationGetIndexList before proceeding. This is needed because a
5364 * relcache flush could occur inside index_open below, resetting the
5365 * fields managed by RelationGetIndexList. We need to do the work with
5366 * stable values of these fields.
5367 */
5368 relpkindex = relation->rd_pkindex;
5369 relreplindex = relation->rd_replidindex;
5370
5371 /*
5372 * For each index, add referenced attributes to indexattrs.
5373 *
5374 * Note: we consider all indexes returned by RelationGetIndexList, even if
5375 * they are not indisready or indisvalid. This is important because an
5376 * index for which CREATE INDEX CONCURRENTLY has just started must be
5377 * included in HOT-safety decisions (see README.HOT). If a DROP INDEX
5378 * CONCURRENTLY is far enough along that we should ignore the index, it
5379 * won't be returned at all by RelationGetIndexList.
5380 */
5381 uindexattrs = NULL;
5386 foreach(l, indexoidlist)
5387 {
5388 Oid indexOid = lfirst_oid(l);
5390 Datum datum;
5391 bool isnull;
5394 int i;
5395 bool isKey; /* candidate key */
5396 bool isPK; /* primary key */
5397 bool isIDKey; /* replica identity index */
5398 Bitmapset **attrs;
5399
5401
5402 /*
5403 * Extract index expressions and index predicate. Note: Don't use
5404 * RelationGetIndexExpressions()/RelationGetIndexPredicate(), because
5405 * those might run constant expressions evaluation, which needs a
5406 * snapshot, which we might not have here. (Also, it's probably more
5407 * sound to collect the bitmaps before any transformations that might
5408 * eliminate columns, but the practical impact of this is limited.)
5409 */
5410
5411 datum = heap_getattr(indexDesc->rd_indextuple, Anum_pg_index_indexprs,
5412 GetPgIndexDescriptor(), &isnull);
5413 if (!isnull)
5415 else
5417
5418 datum = heap_getattr(indexDesc->rd_indextuple, Anum_pg_index_indpred,
5419 GetPgIndexDescriptor(), &isnull);
5420 if (!isnull)
5422 else
5424
5425 /* Can this index be referenced by a foreign key? */
5426 isKey = indexDesc->rd_index->indisunique &&
5429
5430 /* Is this a primary key? */
5431 isPK = (indexOid == relpkindex);
5432
5433 /* Is this index the configured (or default) replica identity? */
5434 isIDKey = (indexOid == relreplindex);
5435
5436 /*
5437 * If the index is summarizing, it doesn't block HOT updates, but we
5438 * may still need to update it (if the attributes were modified). So
5439 * decide which bitmap we'll update in the following loop.
5440 */
5441 if (indexDesc->rd_indam->amsummarizing)
5443 else
5445
5446 /* Collect simple attribute references */
5447 for (i = 0; i < indexDesc->rd_index->indnatts; i++)
5448 {
5449 int attrnum = indexDesc->rd_index->indkey.values[i];
5450
5451 /*
5452 * Since we have covering indexes with non-key columns, we must
5453 * handle them accurately here. non-key columns must be added into
5454 * hotblockingattrs or summarizedattrs, since they are in index,
5455 * and update shouldn't miss them.
5456 *
5457 * Summarizing indexes do not block HOT, but do need to be updated
5458 * when the column value changes, thus require a separate
5459 * attribute bitmapset.
5460 *
5461 * Obviously, non-key columns couldn't be referenced by foreign
5462 * key or identity key. Hence we do not include them into
5463 * uindexattrs, pkindexattrs and idindexattrs bitmaps.
5464 */
5465 if (attrnum != 0)
5466 {
5469
5470 if (isKey && i < indexDesc->rd_index->indnkeyatts)
5473
5474 if (isPK && i < indexDesc->rd_index->indnkeyatts)
5477
5478 if (isIDKey && i < indexDesc->rd_index->indnkeyatts)
5481 }
5482 }
5483
5484 /* Collect all attributes used in expressions, too */
5486
5487 /* Collect all attributes in the index predicate, too */
5489
5491 }
5492
5493 /*
5494 * During one of the index_opens in the above loop, we might have received
5495 * a relcache flush event on this relcache entry, which might have been
5496 * signaling a change in the rel's index list. If so, we'd better start
5497 * over to ensure we deliver up-to-date attribute bitmaps.
5498 */
5501 relpkindex == relation->rd_pkindex &&
5502 relreplindex == relation->rd_replidindex)
5503 {
5504 /* Still the same index set, so proceed */
5507 }
5508 else
5509 {
5510 /* Gotta do it over ... might as well not leak memory */
5518
5519 goto restart;
5520 }
5521
5522 /* Don't leak the old values of these bitmaps, if any */
5523 relation->rd_attrsvalid = false;
5524 bms_free(relation->rd_keyattr);
5525 relation->rd_keyattr = NULL;
5526 bms_free(relation->rd_pkattr);
5527 relation->rd_pkattr = NULL;
5528 bms_free(relation->rd_idattr);
5529 relation->rd_idattr = NULL;
5530 bms_free(relation->rd_hotblockingattr);
5531 relation->rd_hotblockingattr = NULL;
5532 bms_free(relation->rd_summarizedattr);
5533 relation->rd_summarizedattr = NULL;
5534
5535 /*
5536 * Now save copies of the bitmaps in the relcache entry. We intentionally
5537 * set rd_attrsvalid last, because that's the one that signals validity of
5538 * the values; if we run out of memory before making that copy, we won't
5539 * leave the relcache entry looking like the other ones are valid but
5540 * empty.
5541 */
5543 relation->rd_keyattr = bms_copy(uindexattrs);
5544 relation->rd_pkattr = bms_copy(pkindexattrs);
5545 relation->rd_idattr = bms_copy(idindexattrs);
5548 relation->rd_attrsvalid = true;
5550
5551 /* We return our original working copy for caller to play with */
5552 switch (attrKind)
5553 {
5555 return uindexattrs;
5557 return pkindexattrs;
5559 return idindexattrs;
5561 return hotblockingattrs;
5563 return summarizedattrs;
5564 default:
5565 elog(ERROR, "unknown attrKind %u", attrKind);
5566 return NULL;
5567 }
5568}
5569
5570/*
5571 * RelationGetIdentityKeyBitmap -- get a bitmap of replica identity attribute
5572 * numbers
5573 *
5574 * A bitmap of index attribute numbers for the configured replica identity
5575 * index is returned.
5576 *
5577 * See also comments of RelationGetIndexAttrBitmap().
5578 *
5579 * This is a special purpose function used during logical replication. Here,
5580 * unlike RelationGetIndexAttrBitmap(), we don't acquire a lock on the required
5581 * index as we build the cache entry using a historic snapshot and all the
5582 * later changes are absorbed while decoding WAL. Due to this reason, we don't
5583 * need to retry here in case of a change in the set of indexes.
5584 */
5585Bitmapset *
5587{
5588 Bitmapset *idindexattrs = NULL; /* columns in the replica identity */
5590 int i;
5593
5594 /* Quick exit if we already computed the result */
5595 if (relation->rd_idattr != NULL)
5596 return bms_copy(relation->rd_idattr);
5597
5598 /* Fast path if definitely no indexes */
5599 if (!RelationGetForm(relation)->relhasindex)
5600 return NULL;
5601
5602 /* Historic snapshot must be set. */
5604
5606
5607 /* Fall out if there is no replica identity index */
5608 if (!OidIsValid(replidindex))
5609 return NULL;
5610
5611 /* Look up the description for the replica identity index */
5613
5615 elog(ERROR, "could not open relation with OID %u",
5616 relation->rd_replidindex);
5617
5618 /* Add referenced attributes to idindexattrs */
5619 for (i = 0; i < indexDesc->rd_index->indnatts; i++)
5620 {
5621 int attrnum = indexDesc->rd_index->indkey.values[i];
5622
5623 /*
5624 * We don't include non-key columns into idindexattrs bitmaps. See
5625 * RelationGetIndexAttrBitmap.
5626 */
5627 if (attrnum != 0)
5628 {
5629 if (i < indexDesc->rd_index->indnkeyatts)
5632 }
5633 }
5634
5636
5637 /* Don't leak the old values of these bitmaps, if any */
5638 bms_free(relation->rd_idattr);
5639 relation->rd_idattr = NULL;
5640
5641 /* Now save copy of the bitmap in the relcache entry */
5643 relation->rd_idattr = bms_copy(idindexattrs);
5645
5646 /* We return our original working copy for caller to play with */
5647 return idindexattrs;
5648}
5649
5650/*
5651 * RelationGetExclusionInfo -- get info about index's exclusion constraint
5652 *
5653 * This should be called only for an index that is known to have an associated
5654 * exclusion constraint or primary key/unique constraint using WITHOUT
5655 * OVERLAPS.
5656 *
5657 * It returns arrays (palloc'd in caller's context) of the exclusion operator
5658 * OIDs, their underlying functions' OIDs, and their strategy numbers in the
5659 * index's opclasses. We cache all this information since it requires a fair
5660 * amount of work to get.
5661 */
5662void
5664 Oid **operators,
5665 Oid **procs,
5667{
5668 int indnkeyatts;
5669 Oid *ops;
5670 Oid *funcs;
5671 uint16 *strats;
5674 ScanKeyData skey[1];
5675 HeapTuple htup;
5676 bool found;
5678 int i;
5679
5681
5682 /* Allocate result space in caller context */
5683 *operators = ops = palloc_array(Oid, indnkeyatts);
5684 *procs = funcs = palloc_array(Oid, indnkeyatts);
5686
5687 /* Quick exit if we have the data cached already */
5688 if (indexRelation->rd_exclstrats != NULL)
5689 {
5690 memcpy(ops, indexRelation->rd_exclops, sizeof(Oid) * indnkeyatts);
5691 memcpy(funcs, indexRelation->rd_exclprocs, sizeof(Oid) * indnkeyatts);
5692 memcpy(strats, indexRelation->rd_exclstrats, sizeof(uint16) * indnkeyatts);
5693 return;
5694 }
5695
5696 /*
5697 * Search pg_constraint for the constraint associated with the index. To
5698 * make this not too painfully slow, we use the index on conrelid; that
5699 * will hold the parent relation's OID not the index's own OID.
5700 *
5701 * Note: if we wanted to rely on the constraint name matching the index's
5702 * name, we could just do a direct lookup using pg_constraint's unique
5703 * index. For the moment it doesn't seem worth requiring that.
5704 */
5705 ScanKeyInit(&skey[0],
5708 ObjectIdGetDatum(indexRelation->rd_index->indrelid));
5709
5712 NULL, 1, skey);
5713 found = false;
5714
5716 {
5718 Datum val;
5719 bool isnull;
5720 ArrayType *arr;
5721 int nelem;
5722
5723 /* We want the exclusion constraint owning the index */
5724 if ((conform->contype != CONSTRAINT_EXCLUSION &&
5725 !(conform->conperiod && (conform->contype == CONSTRAINT_PRIMARY
5726 || conform->contype == CONSTRAINT_UNIQUE))) ||
5727 conform->conindid != RelationGetRelid(indexRelation))
5728 continue;
5729
5730 /* There should be only one */
5731 if (found)
5732 elog(ERROR, "unexpected exclusion constraint record found for rel %s",
5733 RelationGetRelationName(indexRelation));
5734 found = true;
5735
5736 /* Extract the operator OIDS from conexclop */
5737 val = fastgetattr(htup,
5739 conrel->rd_att, &isnull);
5740 if (isnull)
5741 elog(ERROR, "null conexclop for rel %s",
5742 RelationGetRelationName(indexRelation));
5743
5744 arr = DatumGetArrayTypeP(val); /* ensure not toasted */
5745 nelem = ARR_DIMS(arr)[0];
5746 if (ARR_NDIM(arr) != 1 ||
5747 nelem != indnkeyatts ||
5748 ARR_HASNULL(arr) ||
5749 ARR_ELEMTYPE(arr) != OIDOID)
5750 elog(ERROR, "conexclop is not a 1-D Oid array");
5751
5752 memcpy(ops, ARR_DATA_PTR(arr), sizeof(Oid) * indnkeyatts);
5753 }
5754
5757
5758 if (!found)
5759 elog(ERROR, "exclusion constraint record missing for rel %s",
5760 RelationGetRelationName(indexRelation));
5761
5762 /* We need the func OIDs and strategy numbers too */
5763 for (i = 0; i < indnkeyatts; i++)
5764 {
5765 funcs[i] = get_opcode(ops[i]);
5766 strats[i] = get_op_opfamily_strategy(ops[i],
5767 indexRelation->rd_opfamily[i]);
5768 /* shouldn't fail, since it was checked at index creation */
5769 if (strats[i] == InvalidStrategy)
5770 elog(ERROR, "could not find strategy for operator %u in family %u",
5771 ops[i], indexRelation->rd_opfamily[i]);
5772 }
5773
5774 /* Save a copy of the results in the relcache entry. */
5775 oldcxt = MemoryContextSwitchTo(indexRelation->rd_indexcxt);
5776 indexRelation->rd_exclops = palloc_array(Oid, indnkeyatts);
5777 indexRelation->rd_exclprocs = palloc_array(Oid, indnkeyatts);
5778 indexRelation->rd_exclstrats = palloc_array(uint16, indnkeyatts);
5779 memcpy(indexRelation->rd_exclops, ops, sizeof(Oid) * indnkeyatts);
5780 memcpy(indexRelation->rd_exclprocs, funcs, sizeof(Oid) * indnkeyatts);
5781 memcpy(indexRelation->rd_exclstrats, strats, sizeof(uint16) * indnkeyatts);
5783}
5784
5785/*
5786 * Get the publication information for the given relation.
5787 *
5788 * Traverse all the publications which the relation is in to get the
5789 * publication actions and validate:
5790 * 1. The row filter expressions for such publications if any. We consider the
5791 * row filter expression as invalid if it references any column which is not
5792 * part of REPLICA IDENTITY.
5793 * 2. The column list for such publication if any. We consider the column list
5794 * invalid if REPLICA IDENTITY contains any column that is not part of it.
5795 * 3. The generated columns of the relation for such publications. We consider
5796 * any reference of an unpublished generated column in REPLICA IDENTITY as
5797 * invalid.
5798 *
5799 * To avoid fetching the publication information repeatedly, we cache the
5800 * publication actions, row filter validation information, column list
5801 * validation information, and generated column validation information.
5802 */
5803void
5805{
5806 List *puboids = NIL;
5809 ListCell *lc;
5811 Oid schemaid;
5812 List *ancestors = NIL;
5813 Oid relid = RelationGetRelid(relation);
5814
5815 /*
5816 * If not publishable, it publishes no actions. (pgoutput_change() will
5817 * ignore it.)
5818 */
5819 if (!is_publishable_relation(relation))
5820 {
5821 memset(pubdesc, 0, sizeof(PublicationDesc));
5822 pubdesc->rf_valid_for_update = true;
5823 pubdesc->rf_valid_for_delete = true;
5824 pubdesc->cols_valid_for_update = true;
5825 pubdesc->cols_valid_for_delete = true;
5826 pubdesc->gencols_valid_for_update = true;
5827 pubdesc->gencols_valid_for_delete = true;
5828 return;
5829 }
5830
5831 if (relation->rd_pubdesc)
5832 {
5833 memcpy(pubdesc, relation->rd_pubdesc, sizeof(PublicationDesc));
5834 return;
5835 }
5836
5837 memset(pubdesc, 0, sizeof(PublicationDesc));
5838 pubdesc->rf_valid_for_update = true;
5839 pubdesc->rf_valid_for_delete = true;
5840 pubdesc->cols_valid_for_update = true;
5841 pubdesc->cols_valid_for_delete = true;
5842 pubdesc->gencols_valid_for_update = true;
5843 pubdesc->gencols_valid_for_delete = true;
5844
5845 /* Fetch the publication membership info. */
5847 schemaid = RelationGetNamespace(relation);
5849
5850 if (relation->rd_rel->relispartition)
5851 {
5853
5854 /* Add publications that the ancestors are in too. */
5855 ancestors = get_partition_ancestors(relid);
5856 last_ancestor_relid = llast_oid(ancestors);
5857
5858 foreach(lc, ancestors)
5859 {
5861
5867 }
5868
5869 /*
5870 * Only the top-most ancestor can appear in the EXCEPT clause.
5871 * Therefore, for a partition, exclusion must be evaluated at the
5872 * top-most ancestor.
5873 */
5875 }
5876 else
5877 {
5878 /*
5879 * For a regular table or a root partitioned table, check exclusion on
5880 * table itself.
5881 */
5883 }
5884
5888 exceptpuboids));
5889 foreach(lc, puboids)
5890 {
5891 Oid pubid = lfirst_oid(lc);
5892 HeapTuple tup;
5895 bool invalid_gen_col;
5896
5898
5899 if (!HeapTupleIsValid(tup))
5900 elog(ERROR, "cache lookup failed for publication %u", pubid);
5901
5903
5904 pubdesc->pubactions.pubinsert |= pubform->pubinsert;
5905 pubdesc->pubactions.pubupdate |= pubform->pubupdate;
5906 pubdesc->pubactions.pubdelete |= pubform->pubdelete;
5907 pubdesc->pubactions.pubtruncate |= pubform->pubtruncate;
5908
5909 /*
5910 * Check if all columns referenced in the filter expression are part
5911 * of the REPLICA IDENTITY index or not.
5912 *
5913 * If the publication is FOR ALL TABLES then it means the table has no
5914 * row filters and we can skip the validation.
5915 */
5916 if (!pubform->puballtables &&
5917 (pubform->pubupdate || pubform->pubdelete) &&
5918 pub_rf_contains_invalid_column(pubid, relation, ancestors,
5919 pubform->pubviaroot))
5920 {
5921 if (pubform->pubupdate)
5922 pubdesc->rf_valid_for_update = false;
5923 if (pubform->pubdelete)
5924 pubdesc->rf_valid_for_delete = false;
5925 }
5926
5927 /*
5928 * Check if all columns are part of the REPLICA IDENTITY index or not.
5929 *
5930 * Check if all generated columns included in the REPLICA IDENTITY are
5931 * published.
5932 */
5933 if ((pubform->pubupdate || pubform->pubdelete) &&
5934 pub_contains_invalid_column(pubid, relation, ancestors,
5935 pubform->pubviaroot,
5936 pubform->pubgencols,
5939 {
5940 if (pubform->pubupdate)
5941 {
5942 pubdesc->cols_valid_for_update = !invalid_column_list;
5943 pubdesc->gencols_valid_for_update = !invalid_gen_col;
5944 }
5945
5946 if (pubform->pubdelete)
5947 {
5948 pubdesc->cols_valid_for_delete = !invalid_column_list;
5949 pubdesc->gencols_valid_for_delete = !invalid_gen_col;
5950 }
5951 }
5952
5954
5955 /*
5956 * If we know everything is replicated and the row filter is invalid
5957 * for update and delete, there is no point to check for other
5958 * publications.
5959 */
5960 if (pubdesc->pubactions.pubinsert && pubdesc->pubactions.pubupdate &&
5961 pubdesc->pubactions.pubdelete && pubdesc->pubactions.pubtruncate &&
5962 !pubdesc->rf_valid_for_update && !pubdesc->rf_valid_for_delete)
5963 break;
5964
5965 /*
5966 * If we know everything is replicated and the column list is invalid
5967 * for update and delete, there is no point to check for other
5968 * publications.
5969 */
5970 if (pubdesc->pubactions.pubinsert && pubdesc->pubactions.pubupdate &&
5971 pubdesc->pubactions.pubdelete && pubdesc->pubactions.pubtruncate &&
5972 !pubdesc->cols_valid_for_update && !pubdesc->cols_valid_for_delete)
5973 break;
5974
5975 /*
5976 * If we know everything is replicated and replica identity has an
5977 * unpublished generated column, there is no point to check for other
5978 * publications.
5979 */
5980 if (pubdesc->pubactions.pubinsert && pubdesc->pubactions.pubupdate &&
5981 pubdesc->pubactions.pubdelete && pubdesc->pubactions.pubtruncate &&
5982 !pubdesc->gencols_valid_for_update &&
5983 !pubdesc->gencols_valid_for_delete)
5984 break;
5985 }
5986
5987 if (relation->rd_pubdesc)
5988 {
5989 pfree(relation->rd_pubdesc);
5990 relation->rd_pubdesc = NULL;
5991 }
5992
5993 /* Now save copy of the descriptor in the relcache entry. */
5996 memcpy(relation->rd_pubdesc, pubdesc, sizeof(PublicationDesc));
5998}
5999
6000static bytea **
6002{
6003 bytea **opts = palloc_array(bytea *, natts);
6004
6005 for (int i = 0; i < natts; i++)
6006 {
6007 bytea *opt = srcopts[i];
6008
6009 opts[i] = !opt ? NULL : (bytea *)
6010 DatumGetPointer(datumCopy(PointerGetDatum(opt), false, -1));
6011 }
6012
6013 return opts;
6014}
6015
6016/*
6017 * RelationGetIndexAttOptions
6018 * get AM/opclass-specific options for an index parsed into a binary form
6019 */
6020bytea **
6022{
6024 bytea **opts = relation->rd_opcoptions;
6025 Oid relid = RelationGetRelid(relation);
6026 int natts = RelationGetNumberOfAttributes(relation); /* XXX
6027 * IndexRelationGetNumberOfKeyAttributes */
6028 int i;
6029
6030 /* Try to copy cached options. */
6031 if (opts)
6032 return copy ? CopyIndexAttOptions(opts, natts) : opts;
6033
6034 /* Get and parse opclass options. */
6035 opts = palloc0_array(bytea *, natts);
6036
6037 for (i = 0; i < natts; i++)
6038 {
6040 {
6041 Datum attoptions = get_attoptions(relid, i + 1);
6042
6043 opts[i] = index_opclass_options(relation, i + 1, attoptions, false);
6044
6045 if (attoptions != (Datum) 0)
6046 pfree(DatumGetPointer(attoptions));
6047 }
6048 }
6049
6050 /* Copy parsed options to the cache. */
6052 relation->rd_opcoptions = CopyIndexAttOptions(opts, natts);
6054
6055 if (copy)
6056 return opts;
6057
6058 for (i = 0; i < natts; i++)
6059 {
6060 if (opts[i])
6061 pfree(opts[i]);
6062 }
6063
6064 pfree(opts);
6065
6066 return relation->rd_opcoptions;
6067}
6068
6069/*
6070 * Routines to support ereport() reports of relation-related errors
6071 *
6072 * These could have been put into elog.c, but it seems like a module layering
6073 * violation to have elog.c calling relcache or syscache stuff --- and we
6074 * definitely don't want elog.h including rel.h. So we put them here.
6075 */
6076
6077/*
6078 * errtable --- stores schema_name and table_name of a table
6079 * within the current errordata.
6080 */
6081int
6083{
6087
6088 return 0; /* return value does not matter */
6089}
6090
6091/*
6092 * errtablecol --- stores schema_name, table_name and column_name
6093 * of a table column within the current errordata.
6094 *
6095 * The column is specified by attribute number --- for most callers, this is
6096 * easier and less error-prone than getting the column name for themselves.
6097 */
6098int
6100{
6101 TupleDesc reldesc = RelationGetDescr(rel);
6102 const char *colname;
6103
6104 /* Use reldesc if it's a user attribute, else consult the catalogs */
6105 if (attnum > 0 && attnum <= reldesc->natts)
6106 colname = NameStr(TupleDescAttr(reldesc, attnum - 1)->attname);
6107 else
6108 colname = get_attname(RelationGetRelid(rel), attnum, false);
6109
6110 return errtablecolname(rel, colname);
6111}
6112
6113/*
6114 * errtablecolname --- stores schema_name, table_name and column_name
6115 * of a table column within the current errordata, where the column name is
6116 * given directly rather than extracted from the relation's catalog data.
6117 *
6118 * Don't use this directly unless errtablecol() is inconvenient for some
6119 * reason. This might possibly be needed during intermediate states in ALTER
6120 * TABLE, for instance.
6121 */
6122int
6123errtablecolname(Relation rel, const char *colname)
6124{
6125 errtable(rel);
6127
6128 return 0; /* return value does not matter */
6129}
6130
6131/*
6132 * errtableconstraint --- stores schema_name, table_name and constraint_name
6133 * of a table-related constraint within the current errordata.
6134 */
6135int
6136errtableconstraint(Relation rel, const char *conname)
6137{
6138 errtable(rel);
6140
6141 return 0; /* return value does not matter */
6142}
6143
6144
6145/*
6146 * load_relcache_init_file, write_relcache_init_file
6147 *
6148 * In late 1992, we started regularly having databases with more than
6149 * a thousand classes in them. With this number of classes, it became
6150 * critical to do indexed lookups on the system catalogs.
6151 *
6152 * Bootstrapping these lookups is very hard. We want to be able to
6153 * use an index on pg_attribute, for example, but in order to do so,
6154 * we must have read pg_attribute for the attributes in the index,
6155 * which implies that we need to use the index.
6156 *
6157 * In order to get around the problem, we do the following:
6158 *
6159 * + When the database system is initialized (at initdb time), we
6160 * don't use indexes. We do sequential scans.
6161 *
6162 * + When the backend is started up in normal mode, we load an image
6163 * of the appropriate relation descriptors, in internal format,
6164 * from an initialization file in the data/base/... directory.
6165 *
6166 * + If the initialization file isn't there, then we create the
6167 * relation descriptors using sequential scans and write 'em to
6168 * the initialization file for use by subsequent backends.
6169 *
6170 * As of Postgres 9.0, there is one local initialization file in each
6171 * database, plus one shared initialization file for shared catalogs.
6172 *
6173 * We could dispense with the initialization files and just build the
6174 * critical reldescs the hard way on every backend startup, but that
6175 * slows down backend startup noticeably.
6176 *
6177 * We can in fact go further, and save more relcache entries than
6178 * just the ones that are absolutely critical; this allows us to speed
6179 * up backend startup by not having to build such entries the hard way.
6180 * Presently, all the catalog and index entries that are referred to
6181 * by catcaches are stored in the initialization files.
6182 *
6183 * The same mechanism that detects when catcache and relcache entries
6184 * need to be invalidated (due to catalog updates) also arranges to
6185 * unlink the initialization files when the contents may be out of date.
6186 * The files will then be rebuilt during the next backend startup.
6187 */
6188
6189/*
6190 * load_relcache_init_file -- attempt to load cache from the shared
6191 * or local cache init file
6192 *
6193 * If successful, return true and set criticalRelcachesBuilt or
6194 * criticalSharedRelcachesBuilt to true.
6195 * If not successful, return false.
6196 *
6197 * NOTE: we assume we are already switched into CacheMemoryContext.
6198 */
6199static bool
6201{
6202 FILE *fp;
6203 char initfilename[MAXPGPATH];
6204 Relation *rels;
6205 int relno,
6206 num_rels,
6207 max_rels,
6210 magic;
6211 int i;
6212
6213 if (shared)
6214 snprintf(initfilename, sizeof(initfilename), "global/%s",
6216 else
6217 snprintf(initfilename, sizeof(initfilename), "%s/%s",
6219
6221 if (fp == NULL)
6222 return false;
6223
6224 /*
6225 * Read the index relcache entries from the file. Note we will not enter
6226 * any of them into the cache if the read fails partway through; this
6227 * helps to guard against broken init files.
6228 */
6229 max_rels = 100;
6230 rels = (Relation *) palloc(max_rels * sizeof(Relation));
6231 num_rels = 0;
6233
6234 /* check for correct magic number (compatible version) */
6235 if (fread(&magic, 1, sizeof(magic), fp) != sizeof(magic))
6236 goto read_failed;
6237 if (magic != RELCACHE_INIT_FILEMAGIC)
6238 goto read_failed;
6239
6240 for (relno = 0;; relno++)
6241 {
6242 Size len;
6243 size_t nread;
6244 Relation rel;
6246 bool has_not_null;
6247
6248 /* first read the relation descriptor length */
6249 nread = fread(&len, 1, sizeof(len), fp);
6250 if (nread != sizeof(len))
6251 {
6252 if (nread == 0)
6253 break; /* end of file */
6254 goto read_failed;
6255 }
6256
6257 /* safety check for incompatible relcache layout */
6258 if (len != sizeof(RelationData))
6259 goto read_failed;
6260
6261 /* allocate another relcache header */
6262 if (num_rels >= max_rels)
6263 {
6264 max_rels *= 2;
6265 rels = (Relation *) repalloc(rels, max_rels * sizeof(Relation));
6266 }
6267
6268 rel = rels[num_rels++] = (Relation) palloc(len);
6269
6270 /* then, read the Relation structure */
6271 if (fread(rel, 1, len, fp) != len)
6272 goto read_failed;
6273
6274 /* next read the relation tuple form */
6275 if (fread(&len, 1, sizeof(len), fp) != sizeof(len))
6276 goto read_failed;
6277
6279 if (fread(relform, 1, len, fp) != len)
6280 goto read_failed;
6281
6282 rel->rd_rel = relform;
6283
6284 /* initialize attribute tuple forms */
6285 rel->rd_att = CreateTemplateTupleDesc(relform->relnatts);
6286 rel->rd_att->tdrefcount = 1; /* mark as refcounted */
6287
6288 rel->rd_att->tdtypeid = relform->reltype ? relform->reltype : RECORDOID;
6289 rel->rd_att->tdtypmod = -1; /* just to be sure */
6290
6291 /* next read all the attribute tuple form data entries */
6292 has_not_null = false;
6293 for (i = 0; i < relform->relnatts; i++)
6294 {
6296
6297 if (fread(&len, 1, sizeof(len), fp) != sizeof(len))
6298 goto read_failed;
6300 goto read_failed;
6301 if (fread(attr, 1, len, fp) != len)
6302 goto read_failed;
6303
6304 has_not_null |= attr->attnotnull;
6305
6307 }
6308
6310
6311 /* next read the access method specific field */
6312 if (fread(&len, 1, sizeof(len), fp) != sizeof(len))
6313 goto read_failed;
6314 if (len > 0)
6315 {
6316 rel->rd_options = palloc(len);
6317 if (fread(rel->rd_options, 1, len, fp) != len)
6318 goto read_failed;
6319 if (len != VARSIZE(rel->rd_options))
6320 goto read_failed; /* sanity check */
6321 }
6322 else
6323 {
6324 rel->rd_options = NULL;
6325 }
6326
6327 /* mark not-null status */
6328 if (has_not_null)
6329 {
6331
6332 constr->has_not_null = true;
6333 rel->rd_att->constr = constr;
6334 }
6335
6336 /*
6337 * If it's an index, there's more to do. Note we explicitly ignore
6338 * partitioned indexes here.
6339 */
6340 if (rel->rd_rel->relkind == RELKIND_INDEX)
6341 {
6343 Oid *opfamily;
6344 Oid *opcintype;
6346 int nsupport;
6349
6350 /* Count nailed indexes to ensure we have 'em all */
6351 if (rel->rd_isnailed)
6353
6354 /* read the pg_index tuple */
6355 if (fread(&len, 1, sizeof(len), fp) != sizeof(len))
6356 goto read_failed;
6357
6359 if (fread(rel->rd_indextuple, 1, len, fp) != len)
6360 goto read_failed;
6361
6362 /* Fix up internal pointers in the tuple -- see heap_copytuple */
6365
6366 /*
6367 * prepare index info context --- parameters should match
6368 * RelationInitIndexAccessInfo
6369 */
6371 "index info",
6373 rel->rd_indexcxt = indexcxt;
6376
6377 /*
6378 * Now we can fetch the index AM's API struct. (We can't store
6379 * that in the init file, since it contains function pointers that
6380 * might vary across server executions. Fortunately, it should be
6381 * safe to call the amhandler even while bootstrapping indexes.)
6382 */
6383 InitIndexAmRoutine(rel);
6384
6385 /* read the vector of opfamily OIDs */
6386 if (fread(&len, 1, sizeof(len), fp) != sizeof(len))
6387 goto read_failed;
6388
6389 opfamily = (Oid *) MemoryContextAlloc(indexcxt, len);
6390 if (fread(opfamily, 1, len, fp) != len)
6391 goto read_failed;
6392
6393 rel->rd_opfamily = opfamily;
6394
6395 /* read the vector of opcintype OIDs */
6396 if (fread(&len, 1, sizeof(len), fp) != sizeof(len))
6397 goto read_failed;
6398
6399 opcintype = (Oid *) MemoryContextAlloc(indexcxt, len);
6400 if (fread(opcintype, 1, len, fp) != len)
6401 goto read_failed;
6402
6403 rel->rd_opcintype = opcintype;
6404
6405 /* read the vector of support procedure OIDs */
6406 if (fread(&len, 1, sizeof(len), fp) != sizeof(len))
6407 goto read_failed;
6409 if (fread(support, 1, len, fp) != len)
6410 goto read_failed;
6411
6412 rel->rd_support = support;
6413
6414 /* read the vector of collation OIDs */
6415 if (fread(&len, 1, sizeof(len), fp) != sizeof(len))
6416 goto read_failed;
6417
6419 if (fread(indcollation, 1, len, fp) != len)
6420 goto read_failed;
6421
6423
6424 /* read the vector of indoption values */
6425 if (fread(&len, 1, sizeof(len), fp) != sizeof(len))
6426 goto read_failed;
6427
6429 if (fread(indoption, 1, len, fp) != len)
6430 goto read_failed;
6431
6432 rel->rd_indoption = indoption;
6433
6434 /* read the vector of opcoptions values */
6435 rel->rd_opcoptions = (bytea **)
6436 MemoryContextAllocZero(indexcxt, sizeof(*rel->rd_opcoptions) * relform->relnatts);
6437
6438 for (i = 0; i < relform->relnatts; i++)
6439 {
6440 if (fread(&len, 1, sizeof(len), fp) != sizeof(len))
6441 goto read_failed;
6442
6443 if (len > 0)
6444 {
6446 if (fread(rel->rd_opcoptions[i], 1, len, fp) != len)
6447 goto read_failed;
6448 }
6449 }
6450
6451 /* set up zeroed fmgr-info vector */
6452 nsupport = relform->relnatts * rel->rd_indam->amsupport;
6453 rel->rd_supportinfo = (FmgrInfo *)
6455 }
6456 else
6457 {
6458 /* Count nailed rels to ensure we have 'em all */
6459 if (rel->rd_isnailed)
6460 nailed_rels++;
6461
6462 /* Load table AM data */
6463 if (RELKIND_HAS_TABLE_AM(rel->rd_rel->relkind) || rel->rd_rel->relkind == RELKIND_SEQUENCE)
6465
6466 Assert(rel->rd_index == NULL);
6467 Assert(rel->rd_indextuple == NULL);
6468 Assert(rel->rd_indexcxt == NULL);
6469 Assert(rel->rd_indam == NULL);
6470 Assert(rel->rd_opfamily == NULL);
6471 Assert(rel->rd_opcintype == NULL);
6472 Assert(rel->rd_support == NULL);
6473 Assert(rel->rd_supportinfo == NULL);
6474 Assert(rel->rd_indoption == NULL);
6475 Assert(rel->rd_indcollation == NULL);
6476 Assert(rel->rd_opcoptions == NULL);
6477 }
6478
6479 /*
6480 * Rules and triggers are not saved (mainly because the internal
6481 * format is complex and subject to change). They must be rebuilt if
6482 * needed by RelationCacheInitializePhase3. This is not expected to
6483 * be a big performance hit since few system catalogs have such. Ditto
6484 * for RLS policy data, partition info, index expressions, predicates,
6485 * exclusion info, and FDW info.
6486 */
6487 rel->rd_rules = NULL;
6488 rel->rd_rulescxt = NULL;
6489 rel->trigdesc = NULL;
6490 rel->rd_rsdesc = NULL;
6491 rel->rd_partkey = NULL;
6492 rel->rd_partkeycxt = NULL;
6493 rel->rd_partdesc = NULL;
6496 rel->rd_pdcxt = NULL;
6497 rel->rd_pddcxt = NULL;
6498 rel->rd_partcheck = NIL;
6499 rel->rd_partcheckvalid = false;
6500 rel->rd_partcheckcxt = NULL;
6501 rel->rd_indexprs = NIL;
6502 rel->rd_indpred = NIL;
6503 rel->rd_exclops = NULL;
6504 rel->rd_exclprocs = NULL;
6505 rel->rd_exclstrats = NULL;
6506 rel->rd_fdwroutine = NULL;
6507
6508 /*
6509 * Reset transient-state fields in the relcache entry
6510 */
6511 rel->rd_smgr = NULL;
6512 if (rel->rd_isnailed)
6513 rel->rd_refcnt = 1;
6514 else
6515 rel->rd_refcnt = 0;
6516 rel->rd_indexvalid = false;
6517 rel->rd_indexlist = NIL;
6518 rel->rd_pkindex = InvalidOid;
6520 rel->rd_attrsvalid = false;
6521 rel->rd_keyattr = NULL;
6522 rel->rd_pkattr = NULL;
6523 rel->rd_idattr = NULL;
6524 rel->rd_pubdesc = NULL;
6525 rel->rd_statvalid = false;
6526 rel->rd_statlist = NIL;
6527 rel->rd_fkeyvalid = false;
6528 rel->rd_fkeylist = NIL;
6533 rel->rd_amcache = NULL;
6534 rel->pgstat_info = NULL;
6535
6536 /*
6537 * Recompute lock and physical addressing info. This is needed in
6538 * case the pg_internal.init file was copied from some other database
6539 * by CREATE DATABASE.
6540 */
6543 }
6544
6545 /*
6546 * We reached the end of the init file without apparent problem. Did we
6547 * get the right number of nailed items? This is a useful crosscheck in
6548 * case the set of critical rels or indexes changes. However, that should
6549 * not happen in a normally-running system, so let's bleat if it does.
6550 *
6551 * For the shared init file, we're called before client authentication is
6552 * done, which means that elog(WARNING) will go only to the postmaster
6553 * log, where it's easily missed. To ensure that developers notice bad
6554 * values of NUM_CRITICAL_SHARED_RELS/NUM_CRITICAL_SHARED_INDEXES, we put
6555 * an Assert(false) there.
6556 */
6557 if (shared)
6558 {
6561 {
6562 elog(WARNING, "found %d nailed shared rels and %d nailed shared indexes in init file, but expected %d and %d respectively",
6565 /* Make sure we get developers' attention about this */
6566 Assert(false);
6567 /* In production builds, recover by bootstrapping the relcache */
6568 goto read_failed;
6569 }
6570 }
6571 else
6572 {
6575 {
6576 elog(WARNING, "found %d nailed rels and %d nailed indexes in init file, but expected %d and %d respectively",
6579 /* We don't need an Assert() in this case */
6580 goto read_failed;
6581 }
6582 }
6583
6584 /*
6585 * OK, all appears well.
6586 *
6587 * Now insert all the new relcache entries into the cache.
6588 */
6589 for (relno = 0; relno < num_rels; relno++)
6590 {
6591 RelationCacheInsert(rels[relno], false);
6592 }
6593
6594 pfree(rels);
6595 FreeFile(fp);
6596
6597 if (shared)
6599 else
6601 return true;
6602
6603 /*
6604 * init file is broken, so do it the hard way. We don't bother trying to
6605 * free the clutter we just allocated; it's not in the relcache so it
6606 * won't hurt.
6607 */
6609 pfree(rels);
6610 FreeFile(fp);
6611
6612 return false;
6613}
6614
6615/*
6616 * Write out a new initialization file with the current contents
6617 * of the relcache (either shared rels or local rels, as indicated).
6618 */
6619static void
6621{
6622 FILE *fp;
6623 char tempfilename[MAXPGPATH];
6625 int magic;
6626 HASH_SEQ_STATUS status;
6628 int i;
6629
6630 /*
6631 * If we have already received any relcache inval events, there's no
6632 * chance of succeeding so we may as well skip the whole thing.
6633 */
6634 if (relcacheInvalsReceived != 0L)
6635 return;
6636
6637 /*
6638 * We must write a temporary file and rename it into place. Otherwise,
6639 * another backend starting at about the same time might crash trying to
6640 * read the partially-complete file.
6641 */
6642 if (shared)
6643 {
6644 snprintf(tempfilename, sizeof(tempfilename), "global/%s.%d",
6646 snprintf(finalfilename, sizeof(finalfilename), "global/%s",
6648 }
6649 else
6650 {
6651 snprintf(tempfilename, sizeof(tempfilename), "%s/%s.%d",
6653 snprintf(finalfilename, sizeof(finalfilename), "%s/%s",
6655 }
6656
6657 unlink(tempfilename); /* in case it exists w/wrong permissions */
6658
6660 if (fp == NULL)
6661 {
6662 /*
6663 * We used to consider this a fatal error, but we might as well
6664 * continue with backend startup ...
6665 */
6668 errmsg("could not create relation-cache initialization file \"%s\": %m",
6669 tempfilename),
6670 errdetail("Continuing anyway, but there's something wrong.")));
6671 return;
6672 }
6673
6674 /*
6675 * Write a magic number to serve as a file version identifier. We can
6676 * change the magic number whenever the relcache layout changes.
6677 */
6679 if (fwrite(&magic, 1, sizeof(magic), fp) != sizeof(magic))
6680 ereport(FATAL,
6682 errmsg_internal("could not write init file: %m"));
6683
6684 /*
6685 * Write all the appropriate reldescs (in no particular order).
6686 */
6688
6689 while ((idhentry = (RelIdCacheEnt *) hash_seq_search(&status)) != NULL)
6690 {
6691 Relation rel = idhentry->reldesc;
6693
6694 /* ignore if not correct group */
6695 if (relform->relisshared != shared)
6696 continue;
6697
6698 /*
6699 * Ignore if not supposed to be in init file. We can allow any shared
6700 * relation that's been loaded so far to be in the shared init file,
6701 * but unshared relations must be ones that should be in the local
6702 * file per RelationIdIsInInitFile. (Note: if you want to change the
6703 * criterion for rels to be kept in the init file, see also inval.c.
6704 * The reason for filtering here is to be sure that we don't put
6705 * anything into the local init file for which a relcache inval would
6706 * not cause invalidation of that init file.)
6707 */
6708 if (!shared && !RelationIdIsInInitFile(RelationGetRelid(rel)))
6709 {
6710 /* Nailed rels had better get stored. */
6711 Assert(!rel->rd_isnailed);
6712 continue;
6713 }
6714
6715 /* first write the relcache entry proper */
6716 write_item(rel, sizeof(RelationData), fp);
6717
6718 /* next write the relation tuple form */
6720
6721 /* next, do all the attribute tuple form data entries */
6722 for (i = 0; i < relform->relnatts; i++)
6723 {
6726 }
6727
6728 /* next, do the access method specific field */
6730 (rel->rd_options ? VARSIZE(rel->rd_options) : 0),
6731 fp);
6732
6733 /*
6734 * If it's an index, there's more to do. Note we explicitly ignore
6735 * partitioned indexes here.
6736 */
6737 if (rel->rd_rel->relkind == RELKIND_INDEX)
6738 {
6739 /* write the pg_index tuple */
6740 /* we assume this was created by heap_copytuple! */
6743 fp);
6744
6745 /* write the vector of opfamily OIDs */
6747 relform->relnatts * sizeof(Oid),
6748 fp);
6749
6750 /* write the vector of opcintype OIDs */
6752 relform->relnatts * sizeof(Oid),
6753 fp);
6754
6755 /* write the vector of support procedure OIDs */
6757 relform->relnatts * (rel->rd_indam->amsupport * sizeof(RegProcedure)),
6758 fp);
6759
6760 /* write the vector of collation OIDs */
6762 relform->relnatts * sizeof(Oid),
6763 fp);
6764
6765 /* write the vector of indoption values */
6767 relform->relnatts * sizeof(int16),
6768 fp);
6769
6770 Assert(rel->rd_opcoptions);
6771
6772 /* write the vector of opcoptions values */
6773 for (i = 0; i < relform->relnatts; i++)
6774 {
6775 bytea *opt = rel->rd_opcoptions[i];
6776
6777 write_item(opt, opt ? VARSIZE(opt) : 0, fp);
6778 }
6779 }
6780 }
6781
6782 if (FreeFile(fp))
6783 ereport(FATAL,
6785 errmsg_internal("could not write init file: %m"));
6786
6787 /*
6788 * Now we have to check whether the data we've so painstakingly
6789 * accumulated is already obsolete due to someone else's just-committed
6790 * catalog changes. If so, we just delete the temp file and leave it to
6791 * the next backend to try again. (Our own relcache entries will be
6792 * updated by SI message processing, but we can't be sure whether what we
6793 * wrote out was up-to-date.)
6794 *
6795 * This mustn't run concurrently with the code that unlinks an init file
6796 * and sends SI messages, so grab a serialization lock for the duration.
6797 */
6799
6800 /* Make sure we have seen all incoming SI messages */
6802
6803 /*
6804 * If we have received any SI relcache invals since backend start, assume
6805 * we may have written out-of-date data.
6806 */
6807 if (relcacheInvalsReceived == 0L)
6808 {
6809 /*
6810 * OK, rename the temp file to its final name, deleting any
6811 * previously-existing init file.
6812 *
6813 * Note: a failure here is possible under Cygwin, if some other
6814 * backend is holding open an unlinked-but-not-yet-gone init file. So
6815 * treat this as a noncritical failure; just remove the useless temp
6816 * file on failure.
6817 */
6820 }
6821 else
6822 {
6823 /* Delete the already-obsolete temp file */
6825 }
6826
6828}
6829
6830/* write a chunk of data preceded by its length */
6831static void
6832write_item(const void *data, Size len, FILE *fp)
6833{
6834 if (fwrite(&len, 1, sizeof(len), fp) != sizeof(len))
6835 ereport(FATAL,
6837 errmsg_internal("could not write init file: %m"));
6838 if (len > 0 && fwrite(data, 1, len, fp) != len)
6839 ereport(FATAL,
6841 errmsg_internal("could not write init file: %m"));
6842}
6843
6844/*
6845 * Determine whether a given relation (identified by OID) is one of the ones
6846 * we should store in a relcache init file.
6847 *
6848 * We must cache all nailed rels, and for efficiency we should cache every rel
6849 * that supports a syscache. The former set is almost but not quite a subset
6850 * of the latter. The special cases are relations where
6851 * RelationCacheInitializePhase2/3 chooses to nail for efficiency reasons, but
6852 * which do not support any syscache.
6853 */
6854bool
6856{
6861 {
6862 /*
6863 * If this Assert fails, we don't need the applicable special case
6864 * anymore.
6865 */
6867 return true;
6868 }
6870}
6871
6872/*
6873 * Invalidate (remove) the init file during commit of a transaction that
6874 * changed one or more of the relation cache entries that are kept in the
6875 * local init file.
6876 *
6877 * To be safe against concurrent inspection or rewriting of the init file,
6878 * we must take RelCacheInitLock, then remove the old init file, then send
6879 * the SI messages that include relcache inval for such relations, and then
6880 * release RelCacheInitLock. This serializes the whole affair against
6881 * write_relcache_init_file, so that we can be sure that any other process
6882 * that's concurrently trying to create a new init file won't move an
6883 * already-stale version into place after we unlink. Also, because we unlink
6884 * before sending the SI messages, a backend that's currently starting cannot
6885 * read the now-obsolete init file and then miss the SI messages that will
6886 * force it to update its relcache entries. (This works because the backend
6887 * startup sequence gets into the sinval array before trying to load the init
6888 * file.)
6889 *
6890 * We take the lock and do the unlink in RelationCacheInitFilePreInvalidate,
6891 * then release the lock in RelationCacheInitFilePostInvalidate. Caller must
6892 * send any pending SI messages between those calls.
6893 */
6894void
6896{
6899
6900 if (DatabasePath)
6901 snprintf(localinitfname, sizeof(localinitfname), "%s/%s",
6903 snprintf(sharedinitfname, sizeof(sharedinitfname), "global/%s",
6905
6907
6908 /*
6909 * The files might not be there if no backend has been started since the
6910 * last removal. But complain about failures other than ENOENT with
6911 * ERROR. Fortunately, it's not too late to abort the transaction if we
6912 * can't get rid of the would-be-obsolete init file.
6913 */
6914 if (DatabasePath)
6917}
6918
6919void
6924
6925/*
6926 * Remove the init files during postmaster startup.
6927 *
6928 * We used to keep the init files across restarts, but that is unsafe in PITR
6929 * scenarios, and even in simple crash-recovery cases there are windows for
6930 * the init files to become out-of-sync with the database. So now we just
6931 * remove them during startup and expect the first backend launch to rebuild
6932 * them. Of course, this has to happen in each database of the cluster.
6933 */
6934void
6936{
6937 const char *tblspcdir = PG_TBLSPC_DIR;
6938 DIR *dir;
6939 struct dirent *de;
6940 char path[MAXPGPATH + sizeof(PG_TBLSPC_DIR) + sizeof(TABLESPACE_VERSION_DIRECTORY)];
6941
6942 snprintf(path, sizeof(path), "global/%s",
6944 unlink_initfile(path, LOG);
6945
6946 /* Scan everything in the default tablespace */
6948
6949 /* Scan the tablespace link directory to find non-default tablespaces */
6950 dir = AllocateDir(tblspcdir);
6951
6952 while ((de = ReadDirExtended(dir, tblspcdir, LOG)) != NULL)
6953 {
6954 if (strspn(de->d_name, "0123456789") == strlen(de->d_name))
6955 {
6956 /* Scan the tablespace dir for per-database dirs */
6957 snprintf(path, sizeof(path), "%s/%s/%s",
6960 }
6961 }
6962
6963 FreeDir(dir);
6964}
6965
6966/* Process one per-tablespace directory for RelationCacheInitFileRemove */
6967static void
6969{
6970 DIR *dir;
6971 struct dirent *de;
6972 char initfilename[MAXPGPATH * 2];
6973
6974 /* Scan the tablespace directory to find per-database directories */
6975 dir = AllocateDir(tblspcpath);
6976
6977 while ((de = ReadDirExtended(dir, tblspcpath, LOG)) != NULL)
6978 {
6979 if (strspn(de->d_name, "0123456789") == strlen(de->d_name))
6980 {
6981 /* Try to remove the init file in each database */
6982 snprintf(initfilename, sizeof(initfilename), "%s/%s/%s",
6985 }
6986 }
6987
6988 FreeDir(dir);
6989}
6990
6991static void
6992unlink_initfile(const char *initfilename, int elevel)
6993{
6994 if (unlink(initfilename) < 0)
6995 {
6996 /* It might not be there, but log any error other than ENOENT */
6997 if (errno != ENOENT)
6998 ereport(elevel,
7000 errmsg("could not remove cache file \"%s\": %m",
7001 initfilename)));
7002 }
7003}
7004
7005/*
7006 * ResourceOwner callbacks
7007 */
7008static char *
7010{
7011 Relation rel = (Relation) DatumGetPointer(res);
7012
7013 return psprintf("relation \"%s\"", RelationGetRelationName(rel));
7014}
7015
7016static void
7018{
7019 Relation rel = (Relation) DatumGetPointer(res);
7020
7021 /*
7022 * This reference has already been removed from the resource owner, so
7023 * just decrement reference count without calling
7024 * ResourceOwnerForgetRelationRef.
7025 */
7026 Assert(rel->rd_refcnt > 0);
7027 rel->rd_refcnt -= 1;
7028
7030}
const IndexAmRoutine * GetIndexAmRoutine(Oid amhandler)
Definition amapi.c:33
bytea *(* amoptions_function)(Datum reloptions, bool validate)
Definition amapi.h:166
#define ARR_NDIM(a)
Definition array.h:290
#define ARR_DATA_PTR(a)
Definition array.h:322
#define DatumGetArrayTypeP(X)
Definition array.h:261
#define ARR_ELEMTYPE(a)
Definition array.h:292
#define ARR_DIMS(a)
Definition array.h:294
#define ARR_HASNULL(a)
Definition array.h:291
Datum array_get_element(Datum arraydatum, int nSubscripts, int *indx, int arraytyplen, int elmlen, bool elmbyval, char elmalign, bool *isNull)
int16 AttrNumber
Definition attnum.h:21
void bms_free(Bitmapset *a)
Definition bitmapset.c:239
Bitmapset * bms_add_member(Bitmapset *a, int x)
Definition bitmapset.c:799
Bitmapset * bms_copy(const Bitmapset *a)
Definition bitmapset.c:122
#define TextDatumGetCString(d)
Definition builtins.h:99
#define NameStr(name)
Definition c.h:835
#define TopSubTransactionId
Definition c.h:743
#define PG_BINARY_R
Definition c.h:1388
uint32 SubTransactionId
Definition c.h:740
#define InvalidSubTransactionId
Definition c.h:742
#define Assert(condition)
Definition c.h:943
TransactionId MultiXactId
Definition c.h:746
int16_t int16
Definition c.h:619
regproc RegProcedure
Definition c.h:734
int32_t int32
Definition c.h:620
uint16_t uint16
Definition c.h:623
#define PG_BINARY_W
Definition c.h:1389
uint32 TransactionId
Definition c.h:736
#define OidIsValid(objectId)
Definition c.h:858
size_t Size
Definition c.h:689
bool IsSystemRelation(Relation relation)
Definition catalog.c:74
RelFileNumber GetNewRelFileNumber(Oid reltablespace, Relation pg_class, char relpersistence)
Definition catalog.c:557
bool IsCatalogNamespace(Oid namespaceId)
Definition catalog.c:243
bool IsCatalogRelation(Relation relation)
Definition catalog.c:104
bool IsSharedRelation(Oid relationId)
Definition catalog.c:304
void CreateCacheMemoryContext(void)
Definition catcache.c:726
uint32 result
memcpy(sums, checksumBaseOffsets, sizeof(checksumBaseOffsets))
Node * eval_const_expressions(PlannerInfo *root, Node *node)
Definition clauses.c:2500
Datum datumCopy(Datum value, bool typByVal, int typLen)
Definition datum.c:132
void * hash_search(HTAB *hashp, const void *keyPtr, HASHACTION action, bool *foundPtr)
Definition dynahash.c:889
HTAB * hash_create(const char *tabname, int64 nelem, const HASHCTL *info, int flags)
Definition dynahash.c:360
void * hash_seq_search(HASH_SEQ_STATUS *status)
Definition dynahash.c:1352
void hash_seq_term(HASH_SEQ_STATUS *status)
Definition dynahash.c:1444
void hash_seq_init(HASH_SEQ_STATUS *status, HTAB *hashp)
Definition dynahash.c:1317
int errcode_for_file_access(void)
Definition elog.c:898
int errcode(int sqlerrcode)
Definition elog.c:875
#define LOG
Definition elog.h:32
int err_generic_string(int field, const char *str)
int errdetail(const char *fmt,...) pg_attribute_printf(1
#define FATAL
Definition elog.h:42
int int errmsg_internal(const char *fmt,...) pg_attribute_printf(1
#define WARNING
Definition elog.h:37
#define PANIC
Definition elog.h:44
#define ERROR
Definition elog.h:40
#define elog(elevel,...)
Definition elog.h:228
#define ereport(elevel,...)
Definition elog.h:152
bool equal(const void *a, const void *b)
Definition equalfuncs.c:223
int FreeDir(DIR *dir)
Definition fd.c:3009
int FreeFile(FILE *file)
Definition fd.c:2827
struct dirent * ReadDirExtended(DIR *dir, const char *dirname, int elevel)
Definition fd.c:2972
DIR * AllocateDir(const char *dirname)
Definition fd.c:2891
FILE * AllocateFile(const char *name, const char *mode)
Definition fd.c:2628
#define palloc_object(type)
Definition fe_memutils.h:89
#define palloc_array(type, count)
Definition fe_memutils.h:91
#define palloc0_array(type, count)
Definition fe_memutils.h:92
#define palloc0_object(type)
Definition fe_memutils.h:90
void systable_endscan(SysScanDesc sysscan)
Definition genam.c:604
HeapTuple systable_getnext(SysScanDesc sysscan)
Definition genam.c:515
SysScanDesc systable_beginscan(Relation heapRelation, Oid indexId, bool indexOK, Snapshot snapshot, int nkeys, ScanKey key)
Definition genam.c:388
struct RelationData * Relation
Definition genam.h:30
bool IsBinaryUpgrade
Definition globals.c:123
int MyProcPid
Definition globals.c:49
Oid MyDatabaseTableSpace
Definition globals.c:98
char * DatabasePath
Definition globals.c:106
Oid MyDatabaseId
Definition globals.c:96
RelFileNumber binary_upgrade_next_heap_pg_class_relfilenumber
Definition heap.c:83
const TableAmRoutine * GetHeapamTableAmRoutine(void)
HeapTuple heap_copytuple(HeapTuple tuple)
Definition heaptuple.c:686
bool heap_attisnull(HeapTuple tup, int attnum, TupleDesc tupleDesc)
Definition heaptuple.c:456
void heap_freetuple(HeapTuple htup)
Definition heaptuple.c:1372
@ HASH_FIND
Definition hsearch.h:108
@ HASH_ENTER
Definition hsearch.h:109
#define HASH_ELEM
Definition hsearch.h:90
#define HASH_BLOBS
Definition hsearch.h:92
#define HEAPTUPLESIZE
Definition htup.h:73
HeapTupleData * HeapTuple
Definition htup.h:71
HeapTupleHeaderData * HeapTupleHeader
Definition htup.h:23
#define HeapTupleIsValid(tuple)
Definition htup.h:78
static Datum heap_getattr(HeapTuple tup, int attnum, TupleDesc tupleDesc, bool *isnull)
static TransactionId HeapTupleHeaderGetXmin(const HeapTupleHeaderData *tup)
static void * GETSTRUCT(const HeapTupleData *tuple)
static void HeapTupleHeaderSetXmin(HeapTupleHeaderData *tup, TransactionId xid)
static Datum fastgetattr(HeapTuple tup, int attnum, TupleDesc tupleDesc, bool *isnull)
#define IsParallelWorker()
Definition parallel.h:62
RelFileNumber binary_upgrade_next_index_pg_class_relfilenumber
Definition index.c:87
bytea * index_opclass_options(Relation indrel, AttrNumber attnum, Datum attoptions, bool validate)
Definition indexam.c:1016
void index_close(Relation relation, LOCKMODE lockmode)
Definition indexam.c:178
Relation index_open(Oid relationId, LOCKMODE lockmode)
Definition indexam.c:134
void CatalogTupleUpdate(Relation heapRel, const ItemPointerData *otid, HeapTuple tup)
Definition indexing.c:313
long val
Definition informix.c:689
static int pg_cmp_s16(int16 a, int16 b)
Definition int.h:701
void AcceptInvalidationMessages(void)
Definition inval.c:930
void CacheInvalidateRelcache(Relation relation)
Definition inval.c:1632
int debug_discard_caches
Definition inval.c:260
int b
Definition isn.c:74
int a
Definition isn.c:73
int i
Definition isn.c:77
List * list_concat_unique_oid(List *list1, const List *list2)
Definition list.c:1469
List * lappend(List *list, void *datum)
Definition list.c:339
void list_sort(List *list, list_sort_comparator cmp)
Definition list.c:1674
List * list_difference_oid(const List *list1, const List *list2)
Definition list.c:1313
List * list_copy(const List *oldlist)
Definition list.c:1573
List * lappend_oid(List *list, Oid datum)
Definition list.c:375
List * lcons(void *datum, List *list)
Definition list.c:495
int list_oid_cmp(const ListCell *p1, const ListCell *p2)
Definition list.c:1703
void list_free(List *list)
Definition list.c:1546
void list_free_deep(List *list)
Definition list.c:1560
void UnlockTuple(Relation relation, const ItemPointerData *tid, LOCKMODE lockmode)
Definition lmgr.c:601
void UnlockRelationOid(Oid relid, LOCKMODE lockmode)
Definition lmgr.c:229
void RelationInitLockInfo(Relation relation)
Definition lmgr.c:70
void LockRelationOid(Oid relid, LOCKMODE lockmode)
Definition lmgr.c:107
#define AccessShareLock
Definition lockdefs.h:36
#define InplaceUpdateTupleLock
Definition lockdefs.h:48
#define RowExclusiveLock
Definition lockdefs.h:38
LockTagType
Definition locktag.h:36
@ LOCKTAG_RELATION
Definition locktag.h:37
Datum get_attoptions(Oid relid, int16 attnum)
Definition lsyscache.c:1188
Oid get_rel_namespace(Oid relid)
Definition lsyscache.c:2258
RegProcedure get_opcode(Oid opno)
Definition lsyscache.c:1577
int get_op_opfamily_strategy(Oid opno, Oid opfamily)
Definition lsyscache.c:87
char * get_attname(Oid relid, AttrNumber attnum, bool missing_ok)
Definition lsyscache.c:1045
char * get_qualified_objname(Oid nspid, char *objname)
Definition lsyscache.c:3712
char * get_namespace_name(Oid nspid)
Definition lsyscache.c:3674
bool LWLockAcquire(LWLock *lock, LWLockMode mode)
Definition lwlock.c:1150
void LWLockRelease(LWLock *lock)
Definition lwlock.c:1767
@ LW_EXCLUSIVE
Definition lwlock.h:104
Const * makeConst(Oid consttype, int32 consttypmod, Oid constcollid, int constlen, Datum constvalue, bool constisnull, bool constbyval)
Definition makefuncs.c:350
List * make_ands_implicit(Expr *clause)
Definition makefuncs.c:810
char * MemoryContextStrdup(MemoryContext context, const char *string)
Definition mcxt.c:1897
void * MemoryContextAlloc(MemoryContext context, Size size)
Definition mcxt.c:1235
void * MemoryContextAllocZero(MemoryContext context, Size size)
Definition mcxt.c:1269
void MemoryContextSetParent(MemoryContext context, MemoryContext new_parent)
Definition mcxt.c:689
void * repalloc(void *pointer, Size size)
Definition mcxt.c:1635
void pfree(void *pointer)
Definition mcxt.c:1619
void * palloc0(Size size)
Definition mcxt.c:1420
void MemoryContextDeleteChildren(MemoryContext context)
Definition mcxt.c:558
void * palloc(Size size)
Definition mcxt.c:1390
MemoryContext CurrentMemoryContext
Definition mcxt.c:161
MemoryContext CacheMemoryContext
Definition mcxt.c:170
void MemoryContextDelete(MemoryContext context)
Definition mcxt.c:475
#define AllocSetContextCreate
Definition memutils.h:129
#define ALLOCSET_DEFAULT_SIZES
Definition memutils.h:160
#define ALLOCSET_SMALL_SIZES
Definition memutils.h:170
#define MemoryContextCopyAndSetIdentifier(cxt, id)
Definition memutils.h:101
#define IsBootstrapProcessingMode()
Definition miscadmin.h:486
#define InvalidMultiXactId
Definition multixact.h:25
void namestrcpy(Name name, const char *str)
Definition name.c:233
bool isTempOrTempToastNamespace(Oid namespaceId)
Definition namespace.c:3745
ProcNumber GetTempNamespaceProcNumber(Oid namespaceId)
Definition namespace.c:3838
Oid exprType(const Node *expr)
Definition nodeFuncs.c:42
int32 exprTypmod(const Node *expr)
Definition nodeFuncs.c:304
Oid exprCollation(const Node *expr)
Definition nodeFuncs.c:826
void fix_opfuncids(Node *node)
Definition nodeFuncs.c:1859
#define copyObject(obj)
Definition nodes.h:230
@ CMD_SELECT
Definition nodes.h:273
#define makeNode(_type_)
Definition nodes.h:159
static char * errmsg
static MemoryContext MemoryContextSwitchTo(MemoryContext context)
Definition palloc.h:138
List * get_partition_ancestors(Oid relid)
Definition partition.c:134
END_CATALOG_STRUCT typedef FormData_pg_am * Form_pg_am
Definition pg_am.h:52
static AmcheckOptions opts
Definition pg_amcheck.c:112
END_CATALOG_STRUCT typedef FormData_pg_amproc * Form_pg_amproc
Definition pg_amproc.h:72
END_CATALOG_STRUCT typedef FormData_pg_attrdef * Form_pg_attrdef
Definition pg_attrdef.h:53
FormData_pg_attribute
NameData attname
#define ATTRIBUTE_FIXED_PART_SIZE
int16 attnum
FormData_pg_attribute * Form_pg_attribute
#define ERRCODE_DATA_CORRUPTED
NameData relname
Definition pg_class.h:40
FormData_pg_class * Form_pg_class
Definition pg_class.h:160
#define CLASS_TUPLE_SIZE
Definition pg_class.h:152
#define MAXPGPATH
void DeconstructFkConstraintRow(HeapTuple tuple, int *numfks, AttrNumber *conkey, AttrNumber *confkey, Oid *pf_eq_oprs, Oid *pp_eq_oprs, Oid *ff_eq_oprs, int *num_fk_del_set_cols, AttrNumber *fk_del_set_cols)
AttrNumber extractNotNullColumn(HeapTuple constrTup)
END_CATALOG_STRUCT typedef FormData_pg_constraint * Form_pg_constraint
const void size_t len
const void * data
END_CATALOG_STRUCT typedef FormData_pg_index * Form_pg_index
Definition pg_index.h:74
#define lfirst(lc)
Definition pg_list.h:172
static int list_length(const List *l)
Definition pg_list.h:152
#define NIL
Definition pg_list.h:68
#define forboth(cell1, list1, cell2, list2)
Definition pg_list.h:550
#define llast_oid(l)
Definition pg_list.h:200
#define lfirst_oid(lc)
Definition pg_list.h:174
END_CATALOG_STRUCT typedef FormData_pg_opclass * Form_pg_opclass
Definition pg_opclass.h:87
List * GetAllTablesPublications(void)
List * GetRelationIncludedPublications(Oid relid)
List * GetSchemaPublications(Oid schemaid)
List * GetRelationExcludedPublications(Oid relid)
bool is_publishable_relation(Relation rel)
END_CATALOG_STRUCT typedef FormData_pg_publication * Form_pg_publication
END_CATALOG_STRUCT typedef FormData_pg_rewrite * Form_pg_rewrite
Definition pg_rewrite.h:56
END_CATALOG_STRUCT typedef FormData_pg_statistic_ext * Form_pg_statistic_ext
void pgstat_unlink_relation(Relation rel)
void RelationBuildRowSecurity(Relation relation)
Definition policy.c:193
#define snprintf
Definition port.h:261
#define qsort(a, b, c, d)
Definition port.h:496
static Datum Int16GetDatum(int16 X)
Definition postgres.h:172
static Datum ObjectIdGetDatum(Oid X)
Definition postgres.h:252
uint64_t Datum
Definition postgres.h:70
static Pointer DatumGetPointer(Datum X)
Definition postgres.h:332
#define PointerGetDatum(X)
Definition postgres.h:354
#define InvalidOid
#define PG_DIAG_SCHEMA_NAME
#define PG_DIAG_CONSTRAINT_NAME
unsigned int Oid
#define PG_DIAG_TABLE_NAME
#define PG_DIAG_COLUMN_NAME
Expr * canonicalize_qual(Expr *qual, bool is_check)
Definition prepqual.c:293
static int fb(int x)
#define INVALID_PROC_NUMBER
Definition procnumber.h:26
#define ProcNumberForTempRelations()
Definition procnumber.h:53
char * psprintf(const char *fmt,...)
Definition psprintf.c:43
bool pub_contains_invalid_column(Oid pubid, Relation relation, List *ancestors, bool pubviaroot, char pubgencols_type, bool *invalid_column_list, bool *invalid_gen_col)
bool pub_rf_contains_invalid_column(Oid pubid, Relation relation, List *ancestors, bool pubviaroot)
tree ctl
Definition radixtree.h:1838
void * stringToNode(const char *str)
Definition read.c:90
#define RelationGetForm(relation)
Definition rel.h:510
#define RelationHasReferenceCountZero(relation)
Definition rel.h:500
#define RelationGetRelid(relation)
Definition rel.h:516
#define RelationHasSecurityInvoker(relation)
Definition rel.h:449
#define RelationGetDescr(relation)
Definition rel.h:542
#define RelationIsMapped(relation)
Definition rel.h:565
#define RelationGetNumberOfAttributes(relation)
Definition rel.h:522
#define RelationGetRelationName(relation)
Definition rel.h:550
#define RelationIsAccessibleInLogicalDecoding(relation)
Definition rel.h:704
#define RelationIsValid(relation)
Definition rel.h:491
#define RelationGetNamespace(relation)
Definition rel.h:557
#define IndexRelationGetNumberOfAttributes(relation)
Definition rel.h:528
#define IndexRelationGetNumberOfKeyAttributes(relation)
Definition rel.h:535
#define RelationIsPermanent(relation)
Definition rel.h:628
static void RelationCloseSmgr(Relation relation)
Definition rel.h:593
#define RECOVER_RELATION_BUILD_MEMORY
Definition relcache.c:105
List * RelationGetIndexList(Relation relation)
Definition relcache.c:4846
static int NextEOXactTupleDescNum
Definition relcache.c:207
static bool load_relcache_init_file(bool shared)
Definition relcache.c:6200
static void RelationClearRelation(Relation relation)
Definition relcache.c:2548
void RelationBuildPublicationDesc(Relation relation, PublicationDesc *pubdesc)
Definition relcache.c:5804
static void RelationParseRelOptions(Relation relation, HeapTuple tuple)
Definition relcache.c:472
void RelationCacheInvalidate(bool debug_discard)
Definition relcache.c:2996
#define NUM_CRITICAL_LOCAL_RELS
#define NUM_CRITICAL_SHARED_INDEXES
#define RelationCacheInsert(RELATION, replace_allowed)
Definition relcache.c:213
void RelationDecrementReferenceCount(Relation rel)
Definition relcache.c:2202
static Relation RelationBuildDesc(Oid targetRelId, bool insertIt)
Definition relcache.c:1057
bool criticalRelcachesBuilt
Definition relcache.c:144
static TupleDesc BuildHardcodedDescriptor(int natts, const FormData_pg_attribute *attrs)
Definition relcache.c:4441
static const FormData_pg_attribute Desc_pg_shseclabel[Natts_pg_shseclabel]
Definition relcache.c:122
bool criticalSharedRelcachesBuilt
Definition relcache.c:150
static Oid eoxact_list[MAX_EOXACT_LIST]
Definition relcache.c:189
Oid RelationGetPrimaryKeyIndex(Relation relation, bool deferrable_ok)
Definition relcache.c:5057
static bytea ** CopyIndexAttOptions(bytea **srcopts, int natts)
Definition relcache.c:6001
static void formrdesc(const char *relationName, Oid relationReltype, bool isshared, int natts, const FormData_pg_attribute *attrs)
Definition relcache.c:1887
List * RelationGetDummyIndexExpressions(Relation relation)
Definition relcache.c:5166
static void ResOwnerReleaseRelation(Datum res)
Definition relcache.c:7017
static Relation AllocateRelationDesc(Form_pg_class relp)
Definition relcache.c:417
static const FormData_pg_attribute Desc_pg_database[Natts_pg_database]
Definition relcache.c:118
static void unlink_initfile(const char *initfilename, int elevel)
Definition relcache.c:6992
int errtableconstraint(Relation rel, const char *conname)
Definition relcache.c:6136
int errtablecol(Relation rel, int attnum)
Definition relcache.c:6099
void RelationInitIndexAccessInfo(Relation relation)
Definition relcache.c:1438
List * RelationGetIndexPredicate(Relation relation)
Definition relcache.c:5220
static void InitIndexAmRoutine(Relation relation)
Definition relcache.c:1419
static void write_item(const void *data, Size len, FILE *fp)
Definition relcache.c:6832
static const FormData_pg_attribute Desc_pg_attribute[Natts_pg_attribute]
Definition relcache.c:115
static bool equalRuleLocks(RuleLock *rlock1, RuleLock *rlock2)
Definition relcache.c:925
static int in_progress_list_maxlen
Definition relcache.c:176
static void CheckNNConstraintFetch(Relation relation)
Definition relcache.c:4601
#define INITRELCACHESIZE
Definition relcache.c:4003
static int CheckConstraintCmp(const void *a, const void *b)
Definition relcache.c:4718
Bitmapset * RelationGetIndexAttrBitmap(Relation relation, IndexAttrBitmapKind attrKind)
Definition relcache.c:5313
void AtEOSubXact_RelationCache(bool isCommit, SubTransactionId mySubid, SubTransactionId parentSubid)
Definition relcache.c:3380
static void ResourceOwnerRememberRelationRef(ResourceOwner owner, Relation rel)
Definition relcache.c:2170
static void RelationRebuildRelation(Relation relation)
Definition relcache.c:2587
static const FormData_pg_attribute Desc_pg_class[Natts_pg_class]
Definition relcache.c:114
static void RelationReloadNailed(Relation relation)
Definition relcache.c:2387
static const FormData_pg_attribute Desc_pg_authid[Natts_pg_authid]
Definition relcache.c:119
static TupleDesc GetPgClassDescriptor(void)
Definition relcache.c:4470
static void AttrDefaultFetch(Relation relation, int ndef)
Definition relcache.c:4505
static HTAB * OpClassCache
Definition relcache.c:275
static const ResourceOwnerDesc relref_resowner_desc
Definition relcache.c:2159
static void IndexSupportInitialize(oidvector *indclass, RegProcedure *indexSupport, Oid *opFamily, Oid *opcInType, StrategyNumber maxSupportNumber, AttrNumber maxAttributeNumber)
Definition relcache.c:1609
List * RelationGetStatExtList(Relation relation)
Definition relcache.c:4987
void RelationIncrementReferenceCount(Relation rel)
Definition relcache.c:2189
#define RelationCacheDelete(RELATION)
Definition relcache.c:247
void RelationCacheInitFilePostInvalidate(void)
Definition relcache.c:6920
void RelationCacheInitializePhase3(void)
Definition relcache.c:4113
#define NUM_CRITICAL_SHARED_RELS
static void RelationDestroyRelation(Relation relation, bool remember_tupdesc)
Definition relcache.c:2441
#define EOXactListAdd(rel)
Definition relcache.c:193
#define RelationIdCacheLookup(ID, RELATION)
Definition relcache.c:235
void RelationInitTableAccessMethod(Relation relation)
Definition relcache.c:1822
static const FormData_pg_attribute Desc_pg_subscription[Natts_pg_subscription]
Definition relcache.c:123
static void RelationFlushRelation(Relation relation)
Definition relcache.c:2829
static void RelationBuildRuleLock(Relation relation)
Definition relcache.c:750
static void ResourceOwnerForgetRelationRef(ResourceOwner owner, Relation rel)
Definition relcache.c:2175
static int in_progress_list_len
Definition relcache.c:175
static const FormData_pg_attribute Desc_pg_proc[Natts_pg_proc]
Definition relcache.c:116
void RelationSetNewRelfilenumber(Relation relation, char persistence)
Definition relcache.c:3777
static const FormData_pg_attribute Desc_pg_index[Natts_pg_index]
Definition relcache.c:121
static int EOXactTupleDescArrayLen
Definition relcache.c:208
List * RelationGetFKeyList(Relation relation)
Definition relcache.c:4741
Oid RelationGetReplicaIndex(Relation relation)
Definition relcache.c:5082
Relation RelationIdGetRelation(Oid relationId)
Definition relcache.c:2091
static TupleDesc GetPgIndexDescriptor(void)
Definition relcache.c:4483
static void RelationCloseCleanup(Relation relation)
Definition relcache.c:2231
#define NUM_CRITICAL_LOCAL_INDEXES
static const FormData_pg_attribute Desc_pg_auth_members[Natts_pg_auth_members]
Definition relcache.c:120
static void RelationCacheInitFileRemoveInDir(const char *tblspcpath)
Definition relcache.c:6968
static char * ResOwnerPrintRelCache(Datum res)
Definition relcache.c:7009
void AtEOXact_RelationCache(bool isCommit)
Definition relcache.c:3228
void RelationForgetRelation(Oid rid)
Definition relcache.c:2895
static void AtEOSubXact_cleanup(Relation relation, bool isCommit, SubTransactionId mySubid, SubTransactionId parentSubid)
Definition relcache.c:3435
void RelationCacheInitialize(void)
Definition relcache.c:4006
void RelationCacheInitFilePreInvalidate(void)
Definition relcache.c:6895
List * RelationGetIndexExpressions(Relation relation)
Definition relcache.c:5107
static void write_relcache_init_file(bool shared)
Definition relcache.c:6620
Relation RelationBuildLocalRelation(const char *relname, Oid relnamespace, TupleDesc tupDesc, Oid relid, Oid accessmtd, RelFileNumber relfilenumber, Oid reltablespace, bool shared_relation, bool mapped_relation, char relpersistence, char relkind)
Definition relcache.c:3517
static const FormData_pg_attribute Desc_pg_parameter_acl[Natts_pg_parameter_acl]
Definition relcache.c:124
void RelationAssumeNewRelfilelocator(Relation relation)
Definition relcache.c:3980
static void RememberToFreeTupleDescAtEOX(TupleDesc td)
Definition relcache.c:3106
static HeapTuple ScanPgRelation(Oid targetRelId, bool indexOK, bool force_non_historic)
Definition relcache.c:344
static void RelationInitPhysicalAddr(Relation relation)
Definition relcache.c:1337
static void RelationBuildTupleDesc(Relation relation)
Definition relcache.c:529
static bool equalRSDesc(RowSecurityDesc *rsdesc1, RowSecurityDesc *rsdesc2)
Definition relcache.c:1016
void RelationCacheInitFileRemove(void)
Definition relcache.c:6935
static void AtEOXact_cleanup(Relation relation, bool isCommit)
Definition relcache.c:3298
int errtablecolname(Relation rel, const char *colname)
Definition relcache.c:6123
struct relidcacheent RelIdCacheEnt
static const FormData_pg_attribute Desc_pg_type[Natts_pg_type]
Definition relcache.c:117
void RelationCacheInitializePhase2(void)
Definition relcache.c:4052
static InProgressEnt * in_progress_list
Definition relcache.c:174
bool RelationIdIsInInitFile(Oid relationId)
Definition relcache.c:6855
static void RelationReloadIndexInfo(Relation relation)
Definition relcache.c:2278
static long relcacheInvalsReceived
Definition relcache.c:158
static void load_critical_index(Oid indexoid, Oid heapoid)
Definition relcache.c:4403
static void InitTableAmRoutine(Relation relation)
Definition relcache.c:1813
int errtable(Relation rel)
Definition relcache.c:6082
void RelationCacheInvalidateEntry(Oid relationId)
Definition relcache.c:2940
static bool equalPolicy(RowSecurityPolicy *policy1, RowSecurityPolicy *policy2)
Definition relcache.c:970
#define MAX_EOXACT_LIST
Definition relcache.c:188
bytea ** RelationGetIndexAttOptions(Relation relation, bool copy)
Definition relcache.c:6021
Bitmapset * RelationGetIdentityKeyBitmap(Relation relation)
Definition relcache.c:5586
static int eoxact_list_len
Definition relcache.c:190
struct opclasscacheent OpClassCacheEnt
static OpClassCacheEnt * LookupOpclassInfo(Oid operatorClassOid, StrategyNumber numSupport)
Definition relcache.c:1660
static TupleDesc * EOXactTupleDescArray
Definition relcache.c:206
static bool eoxact_list_overflowed
Definition relcache.c:191
void RelationGetExclusionInfo(Relation indexRelation, Oid **operators, Oid **procs, uint16 **strategies)
Definition relcache.c:5663
static int AttrDefaultCmp(const void *a, const void *b)
Definition relcache.c:4585
#define SWAPFIELD(fldtype, fldname)
char * RelationGetQualifiedRelationName(Relation rel)
Definition relcache.c:2144
#define RELCACHE_INIT_FILEMAGIC
Definition relcache.c:96
static HTAB * RelationIdCache
Definition relcache.c:138
struct inprogressent InProgressEnt
static void RelationInvalidateRelation(Relation relation)
Definition relcache.c:2520
void RelationClose(Relation relation)
Definition relcache.c:2222
#define RELCACHE_INIT_FILENAME
Definition relcache.h:25
IndexAttrBitmapKind
Definition relcache.h:69
@ INDEX_ATTR_BITMAP_KEY
Definition relcache.h:70
@ INDEX_ATTR_BITMAP_HOT_BLOCKING
Definition relcache.h:73
@ INDEX_ATTR_BITMAP_PRIMARY_KEY
Definition relcache.h:71
@ INDEX_ATTR_BITMAP_SUMMARIZED
Definition relcache.h:74
@ INDEX_ATTR_BITMAP_IDENTITY_KEY
Definition relcache.h:72
#define AssertPendingSyncs_RelationCache()
Definition relcache.h:144
static void AssertCouldGetRelation(void)
Definition relcache.h:44
void RelationMapInvalidateAll(void)
Definition relmapper.c:491
void RelationMapInitialize(void)
Definition relmapper.c:652
void RelationMapInitializePhase2(void)
Definition relmapper.c:672
RelFileNumber RelationMapOidToFilenumber(Oid relationId, bool shared)
Definition relmapper.c:166
void RelationMapUpdateMap(Oid relationId, RelFileNumber fileNumber, bool shared, bool immediate)
Definition relmapper.c:326
void RelationMapInitializePhase3(void)
Definition relmapper.c:693
bytea * extractRelOptions(HeapTuple tuple, TupleDesc tupdesc, amoptions_function amoptions)
Oid RelFileNumber
Definition relpath.h:25
#define InvalidRelFileNumber
Definition relpath.h:26
#define PG_TBLSPC_DIR
Definition relpath.h:41
#define TABLESPACE_VERSION_DIRECTORY
Definition relpath.h:33
#define RelFileNumberIsValid(relnumber)
Definition relpath.h:27
ResourceOwner CurrentResourceOwner
Definition resowner.c:173
void ResourceOwnerForget(ResourceOwner owner, Datum value, const ResourceOwnerDesc *kind)
Definition resowner.c:571
void ResourceOwnerRemember(ResourceOwner owner, Datum value, const ResourceOwnerDesc *kind)
Definition resowner.c:531
void ResourceOwnerEnlarge(ResourceOwner owner)
Definition resowner.c:459
@ RESOURCE_RELEASE_BEFORE_LOCKS
Definition resowner.h:54
#define RELEASE_PRIO_RELCACHE_REFS
Definition resowner.h:64
void setRuleCheckAsUser(Node *node, Oid userid)
void ScanKeyInit(ScanKey entry, AttrNumber attributeNumber, StrategyNumber strategy, RegProcedure procedure, Datum argument)
Definition scankey.c:76
SMgrRelation smgropen(RelFileLocator rlocator, ProcNumber backend)
Definition smgr.c:240
void smgrreleaseall(void)
Definition smgr.c:412
void smgrclose(SMgrRelation reln)
Definition smgr.c:374
void smgrdounlinkall(SMgrRelation *rels, int nrels, bool isRedo)
Definition smgr.c:538
Snapshot GetTransactionSnapshot(void)
Definition snapmgr.c:272
void UnregisterSnapshot(Snapshot snapshot)
Definition snapmgr.c:866
void PushActiveSnapshot(Snapshot snapshot)
Definition snapmgr.c:682
bool HistoricSnapshotActive(void)
Definition snapmgr.c:1692
Snapshot RegisterSnapshot(Snapshot snapshot)
Definition snapmgr.c:824
void PopActiveSnapshot(void)
Definition snapmgr.c:775
Snapshot GetNonHistoricCatalogSnapshot(Oid relid)
Definition snapmgr.c:407
bool RelFileLocatorSkippingWAL(RelFileLocator rlocator)
Definition storage.c:573
SMgrRelation RelationCreateStorage(RelFileLocator rlocator, char relpersistence, bool register_delete)
Definition storage.c:122
void RelationDropStorage(Relation rel)
Definition storage.c:207
uint16 StrategyNumber
Definition stratnum.h:22
#define BTGreaterStrategyNumber
Definition stratnum.h:33
#define InvalidStrategy
Definition stratnum.h:24
#define BTEqualStrategyNumber
Definition stratnum.h:31
char attnullability
Definition tupdesc.h:80
char * ccname
Definition tupdesc.h:30
bool ccenforced
Definition tupdesc.h:32
bool ccnoinherit
Definition tupdesc.h:34
bool ccvalid
Definition tupdesc.h:33
char * ccbin
Definition tupdesc.h:31
Definition dirent.c:26
ItemPointerData t_self
Definition htup.h:65
uint32 t_len
Definition htup.h:64
HeapTupleHeader t_data
Definition htup.h:68
amoptions_function amoptions
Definition amapi.h:305
uint16 amsupport
Definition amapi.h:243
Definition pg_list.h:54
MemoryContext firstchild
Definition memnodes.h:128
Definition nodes.h:133
RelFileNumber relNumber
List * rd_partcheck
Definition rel.h:147
Bitmapset * rd_keyattr
Definition rel.h:162
ProcNumber rd_backend
Definition rel.h:60
bool rd_ispkdeferrable
Definition rel.h:154
bool rd_partcheckvalid
Definition rel.h:148
MemoryContext rd_pdcxt
Definition rel.h:131
const struct IndexAmRoutine * rd_indam
Definition rel.h:206
MemoryContext rd_partkeycxt
Definition rel.h:127
const struct TableAmRoutine * rd_tableam
Definition rel.h:189
TransactionId rd_partdesc_nodetached_xmin
Definition rel.h:144
bool rd_indexvalid
Definition rel.h:64
List * rd_indpred
Definition rel.h:213
List * rd_fkeylist
Definition rel.h:122
Oid * rd_exclprocs
Definition rel.h:215
SubTransactionId rd_firstRelfilelocatorSubid
Definition rel.h:106
uint16 * rd_exclstrats
Definition rel.h:216
List * rd_indexlist
Definition rel.h:152
struct RowSecurityDesc * rd_rsdesc
Definition rel.h:119
PartitionDesc rd_partdesc
Definition rel.h:130
Oid rd_replidindex
Definition rel.h:155
int rd_refcnt
Definition rel.h:59
RegProcedure * rd_support
Definition rel.h:209
PartitionDesc rd_partdesc_nodetached
Definition rel.h:134
bytea ** rd_opcoptions
Definition rel.h:218
PublicationDesc * rd_pubdesc
Definition rel.h:168
struct FdwRoutine * rd_fdwroutine
Definition rel.h:240
TriggerDesc * trigdesc
Definition rel.h:117
Bitmapset * rd_idattr
Definition rel.h:164
bool rd_isvalid
Definition rel.h:63
bool rd_islocaltemp
Definition rel.h:61
List * rd_indexprs
Definition rel.h:212
bool rd_attrsvalid
Definition rel.h:161
Oid * rd_exclops
Definition rel.h:214
Oid * rd_opcintype
Definition rel.h:208
struct HeapTupleData * rd_indextuple
Definition rel.h:194
MemoryContext rd_partcheckcxt
Definition rel.h:149
int16 * rd_indoption
Definition rel.h:211
TupleDesc rd_att
Definition rel.h:112
Form_pg_index rd_index
Definition rel.h:192
Bitmapset * rd_hotblockingattr
Definition rel.h:165
void * rd_amcache
Definition rel.h:229
bool rd_isnailed
Definition rel.h:62
Oid rd_id
Definition rel.h:113
Oid rd_pkindex
Definition rel.h:153
SubTransactionId rd_newRelfilelocatorSubid
Definition rel.h:104
bool rd_fkeyvalid
Definition rel.h:123
Oid rd_amhandler
Definition rel.h:184
SMgrRelation rd_smgr
Definition rel.h:58
SubTransactionId rd_createSubid
Definition rel.h:103
bool rd_statvalid
Definition rel.h:66
MemoryContext rd_indexcxt
Definition rel.h:204
List * rd_statlist
Definition rel.h:158
MemoryContext rd_pddcxt
Definition rel.h:135
RelFileLocator rd_locator
Definition rel.h:57
RuleLock * rd_rules
Definition rel.h:115
struct FmgrInfo * rd_supportinfo
Definition rel.h:210
Oid * rd_opfamily
Definition rel.h:207
SubTransactionId rd_droppedSubid
Definition rel.h:109
MemoryContext rd_rulescxt
Definition rel.h:116
Bitmapset * rd_summarizedattr
Definition rel.h:166
Bitmapset * rd_pkattr
Definition rel.h:163
PartitionKey rd_partkey
Definition rel.h:126
bytea * rd_options
Definition rel.h:175
Oid * rd_indcollation
Definition rel.h:217
Form_pg_class rd_rel
Definition rel.h:111
struct PgStat_TableStatus * pgstat_info
Definition rel.h:255
const char * name
Definition resowner.h:93
MemoryContext rscxt
Definition rowsecurity.h:33
bool has_generated_virtual
Definition tupdesc.h:47
bool has_not_null
Definition tupdesc.h:45
AttrDefault * defval
Definition tupdesc.h:40
bool has_generated_stored
Definition tupdesc.h:46
struct AttrMissing * missing
Definition tupdesc.h:42
ConstrCheck * check
Definition tupdesc.h:41
uint16 num_defval
Definition tupdesc.h:43
uint16 num_check
Definition tupdesc.h:44
CompactAttribute compact_attrs[FLEXIBLE_ARRAY_MEMBER]
Definition tupdesc.h:161
TupleConstr * constr
Definition tupdesc.h:159
int32 tdtypmod
Definition tupdesc.h:152
Definition type.h:97
bool invalidated
Definition relcache.c:171
Definition c.h:815
StrategyNumber numSupport
Definition relcache.c:269
RegProcedure * supportProcs
Definition relcache.c:272
Relation reldesc
Definition relcache.c:135
Definition c.h:776
#define FirstLowInvalidHeapAttributeNumber
Definition sysattr.h:27
HeapTuple SearchSysCacheLockedCopy1(SysCacheIdentifier cacheId, Datum key1)
Definition syscache.c:400
void ReleaseSysCache(HeapTuple tuple)
Definition syscache.c:265
bool RelationSupportsSysCache(Oid relid)
Definition syscache.c:763
void InitCatalogCachePhase2(void)
Definition syscache.c:181
HeapTuple SearchSysCache1(SysCacheIdentifier cacheId, Datum key1)
Definition syscache.c:221
void table_close(Relation relation, LOCKMODE lockmode)
Definition table.c:126
Relation table_open(Oid relationId, LOCKMODE lockmode)
Definition table.c:40
static void table_relation_set_new_filelocator(Relation rel, const RelFileLocator *newrlocator, char persistence, TransactionId *freezeXid, MultiXactId *minmulti)
Definition tableam.h:1687
const TableAmRoutine * GetTableAmRoutine(Oid amhandler)
Definition tableamapi.c:27
#define InvalidTransactionId
Definition transam.h:31
void FreeTriggerDesc(TriggerDesc *trigdesc)
Definition trigger.c:2147
void RelationBuildTriggers(Relation relation)
Definition trigger.c:1863
void FreeTupleDesc(TupleDesc tupdesc)
Definition tupdesc.c:569
TupleDesc CreateTemplateTupleDesc(int natts)
Definition tupdesc.c:165
void TupleDescFinalize(TupleDesc tupdesc)
Definition tupdesc.c:511
TupleDesc CreateTupleDescCopy(TupleDesc tupdesc)
Definition tupdesc.c:242
void populate_compact_attribute(TupleDesc tupdesc, int attnum)
Definition tupdesc.c:100
bool equalTupleDescs(TupleDesc tupdesc1, TupleDesc tupdesc2)
Definition tupdesc.c:657
#define ATTNULLABLE_UNKNOWN
Definition tupdesc.h:85
#define ATTNULLABLE_VALID
Definition tupdesc.h:86
static FormData_pg_attribute * TupleDescAttr(TupleDesc tupdesc, int i)
Definition tupdesc.h:178
static CompactAttribute * TupleDescCompactAttr(TupleDesc tupdesc, int i)
Definition tupdesc.h:195
#define ATTNULLABLE_INVALID
Definition tupdesc.h:87
#define ATTNULLABLE_UNRESTRICTED
Definition tupdesc.h:84
void pull_varattnos(Node *node, Index varno, Bitmapset **varattnos)
Definition var.c:296
static Size VARSIZE(const void *PTR)
Definition varatt.h:298
SubTransactionId GetCurrentSubTransactionId(void)
Definition xact.c:793
bool IsTransactionState(void)
Definition xact.c:389
void CommandCounterIncrement(void)
Definition xact.c:1130
TransactionId GetCurrentTransactionId(void)
Definition xact.c:456
static struct rule * rules
Definition zic.c:290