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1 : : /*-------------------------------------------------------------------------
2 : : *
3 : : * execMain.c
4 : : * top level executor interface routines
5 : : *
6 : : * INTERFACE ROUTINES
7 : : * ExecutorStart()
8 : : * ExecutorRun()
9 : : * ExecutorFinish()
10 : : * ExecutorEnd()
11 : : *
12 : : * These four procedures are the external interface to the executor.
13 : : * In each case, the query descriptor is required as an argument.
14 : : *
15 : : * ExecutorStart must be called at the beginning of execution of any
16 : : * query plan and ExecutorEnd must always be called at the end of
17 : : * execution of a plan (unless it is aborted due to error).
18 : : *
19 : : * ExecutorRun accepts direction and count arguments that specify whether
20 : : * the plan is to be executed forwards, backwards, and for how many tuples.
21 : : * In some cases ExecutorRun may be called multiple times to process all
22 : : * the tuples for a plan. It is also acceptable to stop short of executing
23 : : * the whole plan (but only if it is a SELECT).
24 : : *
25 : : * ExecutorFinish must be called after the final ExecutorRun call and
26 : : * before ExecutorEnd. This can be omitted only in case of EXPLAIN,
27 : : * which should also omit ExecutorRun.
28 : : *
29 : : * Portions Copyright (c) 1996-2026, PostgreSQL Global Development Group
30 : : * Portions Copyright (c) 1994, Regents of the University of California
31 : : *
32 : : *
33 : : * IDENTIFICATION
34 : : * src/backend/executor/execMain.c
35 : : *
36 : : *-------------------------------------------------------------------------
37 : : */
38 : : #include "postgres.h"
39 : :
40 : : #include "access/sysattr.h"
41 : : #include "access/table.h"
42 : : #include "access/tableam.h"
43 : : #include "access/tupconvert.h"
44 : : #include "access/xact.h"
45 : : #include "catalog/namespace.h"
46 : : #include "catalog/partition.h"
47 : : #include "commands/matview.h"
48 : : #include "commands/trigger.h"
49 : : #include "executor/executor.h"
50 : : #include "executor/execPartition.h"
51 : : #include "executor/instrument.h"
52 : : #include "executor/nodeSubplan.h"
53 : : #include "foreign/fdwapi.h"
54 : : #include "mb/pg_wchar.h"
55 : : #include "miscadmin.h"
56 : : #include "nodes/queryjumble.h"
57 : : #include "parser/parse_relation.h"
58 : : #include "pgstat.h"
59 : : #include "rewrite/rewriteHandler.h"
60 : : #include "tcop/utility.h"
61 : : #include "utils/acl.h"
62 : : #include "utils/backend_status.h"
63 : : #include "utils/lsyscache.h"
64 : : #include "utils/partcache.h"
65 : : #include "utils/rls.h"
66 : : #include "utils/snapmgr.h"
67 : :
68 : :
69 : : /* Hooks for plugins to get control in ExecutorStart/Run/Finish/End */
70 : : ExecutorStart_hook_type ExecutorStart_hook = NULL;
71 : : ExecutorRun_hook_type ExecutorRun_hook = NULL;
72 : : ExecutorFinish_hook_type ExecutorFinish_hook = NULL;
73 : : ExecutorEnd_hook_type ExecutorEnd_hook = NULL;
74 : :
75 : : /* Hook for plugin to get control in ExecCheckPermissions() */
76 : : ExecutorCheckPerms_hook_type ExecutorCheckPerms_hook = NULL;
77 : :
78 : : /* decls for local routines only used within this module */
79 : : static void InitPlan(QueryDesc *queryDesc, int eflags);
80 : : static void CheckValidRowMarkRel(Relation rel, RowMarkType markType);
81 : : static void ExecPostprocessPlan(EState *estate);
82 : : static void ExecEndPlan(PlanState *planstate, EState *estate);
83 : : static void ExecutePlan(QueryDesc *queryDesc,
84 : : CmdType operation,
85 : : bool sendTuples,
86 : : uint64 numberTuples,
87 : : ScanDirection direction,
88 : : DestReceiver *dest);
89 : : static bool ExecCheckPermissionsModified(Oid relOid, Oid userid,
90 : : Bitmapset *modifiedCols,
91 : : AclMode requiredPerms);
92 : : static void ExecCheckXactReadOnly(PlannedStmt *plannedstmt);
93 : : static void EvalPlanQualStart(EPQState *epqstate, Plan *planTree);
94 : : static void ReportNotNullViolationError(ResultRelInfo *resultRelInfo,
95 : : TupleTableSlot *slot,
96 : : EState *estate, int attnum);
97 : :
98 : : /* end of local decls */
99 : :
100 : :
101 : : /* ----------------------------------------------------------------
102 : : * ExecutorStart
103 : : *
104 : : * This routine must be called at the beginning of any execution of any
105 : : * query plan
106 : : *
107 : : * Takes a QueryDesc previously created by CreateQueryDesc (which is separate
108 : : * only because some places use QueryDescs for utility commands). The tupDesc
109 : : * field of the QueryDesc is filled in to describe the tuples that will be
110 : : * returned, and the internal fields (estate and planstate) are set up.
111 : : *
112 : : * eflags contains flag bits as described in executor.h.
113 : : *
114 : : * NB: the CurrentMemoryContext when this is called will become the parent
115 : : * of the per-query context used for this Executor invocation.
116 : : *
117 : : * We provide a function hook variable that lets loadable plugins
118 : : * get control when ExecutorStart is called. Such a plugin would
119 : : * normally call standard_ExecutorStart().
120 : : *
121 : : * ----------------------------------------------------------------
122 : : */
123 : : void
124 : 356951 : ExecutorStart(QueryDesc *queryDesc, int eflags)
125 : : {
126 : : /*
127 : : * In some cases (e.g. an EXECUTE statement or an execute message with the
128 : : * extended query protocol) the query_id won't be reported, so do it now.
129 : : *
130 : : * Note that it's harmless to report the query_id multiple times, as the
131 : : * call will be ignored if the top level query_id has already been
132 : : * reported.
133 : : */
134 : 356951 : pgstat_report_query_id(queryDesc->plannedstmt->queryId, false);
135 : :
136 [ + + ]: 356951 : if (ExecutorStart_hook)
137 : 60843 : (*ExecutorStart_hook) (queryDesc, eflags);
138 : : else
139 : 296108 : standard_ExecutorStart(queryDesc, eflags);
140 : 355743 : }
141 : :
142 : : void
143 : 356951 : standard_ExecutorStart(QueryDesc *queryDesc, int eflags)
144 : : {
145 : : EState *estate;
146 : : MemoryContext oldcontext;
147 : :
148 : : /* sanity checks: queryDesc must not be started already */
149 : : Assert(queryDesc != NULL);
150 : : Assert(queryDesc->estate == NULL);
151 : :
152 : : /* caller must ensure the query's snapshot is active */
153 : : Assert(GetActiveSnapshot() == queryDesc->snapshot);
154 : :
155 : : /*
156 : : * If the transaction is read-only, we need to check if any writes are
157 : : * planned to non-temporary tables. EXPLAIN is considered read-only.
158 : : *
159 : : * Don't allow writes in parallel mode. Supporting UPDATE and DELETE
160 : : * would require (a) storing the combo CID hash in shared memory, rather
161 : : * than synchronizing it just once at the start of parallelism, and (b) an
162 : : * alternative to heap_update()'s reliance on xmax for mutual exclusion.
163 : : * INSERT may have no such troubles, but we forbid it to simplify the
164 : : * checks.
165 : : *
166 : : * We have lower-level defenses in CommandCounterIncrement and elsewhere
167 : : * against performing unsafe operations in parallel mode, but this gives a
168 : : * more user-friendly error message.
169 : : */
170 [ + + + + ]: 356951 : if ((XactReadOnly || IsInParallelMode()) &&
171 [ + - ]: 33506 : !(eflags & EXEC_FLAG_EXPLAIN_ONLY))
172 : 33506 : ExecCheckXactReadOnly(queryDesc->plannedstmt);
173 : :
174 : : /*
175 : : * Build EState, switch into per-query memory context for startup.
176 : : */
177 : 356933 : estate = CreateExecutorState();
178 : 356933 : queryDesc->estate = estate;
179 : :
180 : 356933 : oldcontext = MemoryContextSwitchTo(estate->es_query_cxt);
181 : :
182 : : /*
183 : : * Fill in external parameters, if any, from queryDesc; and allocate
184 : : * workspace for internal parameters
185 : : */
186 : 356933 : estate->es_param_list_info = queryDesc->params;
187 : :
188 [ + + ]: 356933 : if (queryDesc->plannedstmt->paramExecTypes != NIL)
189 : : {
190 : : int nParamExec;
191 : :
192 : 118687 : nParamExec = list_length(queryDesc->plannedstmt->paramExecTypes);
193 : 118687 : estate->es_param_exec_vals = (ParamExecData *)
194 : 118687 : palloc0_array(ParamExecData, nParamExec);
195 : : }
196 : :
197 : : /* We now require all callers to provide sourceText */
198 : : Assert(queryDesc->sourceText != NULL);
199 : 356933 : estate->es_sourceText = queryDesc->sourceText;
200 : :
201 : : /*
202 : : * Fill in the query environment, if any, from queryDesc.
203 : : */
204 : 356933 : estate->es_queryEnv = queryDesc->queryEnv;
205 : :
206 : : /*
207 : : * If non-read-only query, set the command ID to mark output tuples with
208 : : */
209 [ + + - ]: 356933 : switch (queryDesc->operation)
210 : : {
211 : 283496 : case CMD_SELECT:
212 : :
213 : : /*
214 : : * SELECT FOR [KEY] UPDATE/SHARE and modifying CTEs need to mark
215 : : * tuples
216 : : */
217 [ + + ]: 283496 : if (queryDesc->plannedstmt->rowMarks != NIL ||
218 [ + + ]: 277531 : queryDesc->plannedstmt->hasModifyingCTE)
219 : 6061 : estate->es_output_cid = GetCurrentCommandId(true);
220 : :
221 : : /*
222 : : * A SELECT without modifying CTEs can't possibly queue triggers,
223 : : * so force skip-triggers mode. This is just a marginal efficiency
224 : : * hack, since AfterTriggerBeginQuery/AfterTriggerEndQuery aren't
225 : : * all that expensive, but we might as well do it.
226 : : */
227 [ + + ]: 283496 : if (!queryDesc->plannedstmt->hasModifyingCTE)
228 : 283396 : eflags |= EXEC_FLAG_SKIP_TRIGGERS;
229 : 283496 : break;
230 : :
231 : 73437 : case CMD_INSERT:
232 : : case CMD_DELETE:
233 : : case CMD_UPDATE:
234 : : case CMD_MERGE:
235 : 73437 : estate->es_output_cid = GetCurrentCommandId(true);
236 : 73437 : break;
237 : :
238 : 0 : default:
239 [ # # ]: 0 : elog(ERROR, "unrecognized operation code: %d",
240 : : (int) queryDesc->operation);
241 : : break;
242 : : }
243 : :
244 : : /*
245 : : * Copy other important information into the EState
246 : : */
247 : 356933 : estate->es_snapshot = RegisterSnapshot(queryDesc->snapshot);
248 : 356933 : estate->es_crosscheck_snapshot = RegisterSnapshot(queryDesc->crosscheck_snapshot);
249 : 356933 : estate->es_top_eflags = eflags;
250 : 356933 : estate->es_instrument = queryDesc->instrument_options;
251 : 356933 : estate->es_jit_flags = queryDesc->plannedstmt->jitFlags;
252 : :
253 : : /*
254 : : * Set up query-level instrumentation if extensions have requested it via
255 : : * query_instr_options. Ensure an extension has not allocated query_instr
256 : : * itself.
257 : : */
258 : : Assert(queryDesc->query_instr == NULL);
259 [ + + ]: 356933 : if (queryDesc->query_instr_options)
260 : 41700 : queryDesc->query_instr = InstrAlloc(queryDesc->query_instr_options);
261 : :
262 : : /*
263 : : * Set up an AFTER-trigger statement context, unless told not to, or
264 : : * unless it's EXPLAIN-only mode (when ExecutorFinish won't be called).
265 : : */
266 [ + + ]: 356933 : if (!(eflags & (EXEC_FLAG_SKIP_TRIGGERS | EXEC_FLAG_EXPLAIN_ONLY)))
267 : 72466 : AfterTriggerBeginQuery();
268 : :
269 : : /*
270 : : * Initialize the plan state tree
271 : : */
272 : 356933 : InitPlan(queryDesc, eflags);
273 : :
274 : 355743 : MemoryContextSwitchTo(oldcontext);
275 : 355743 : }
276 : :
277 : : /* ----------------------------------------------------------------
278 : : * ExecutorRun
279 : : *
280 : : * This is the main routine of the executor module. It accepts
281 : : * the query descriptor from the traffic cop and executes the
282 : : * query plan.
283 : : *
284 : : * ExecutorStart must have been called already.
285 : : *
286 : : * If direction is NoMovementScanDirection then nothing is done
287 : : * except to start up/shut down the destination. Otherwise,
288 : : * we retrieve up to 'count' tuples in the specified direction.
289 : : *
290 : : * Note: count = 0 is interpreted as no portal limit, i.e., run to
291 : : * completion. Also note that the count limit is only applied to
292 : : * retrieved tuples, not for instance to those inserted/updated/deleted
293 : : * by a ModifyTable plan node.
294 : : *
295 : : * There is no return value, but output tuples (if any) are sent to
296 : : * the destination receiver specified in the QueryDesc; and the number
297 : : * of tuples processed at the top level can be found in
298 : : * estate->es_processed. The total number of tuples processed in all
299 : : * the ExecutorRun calls can be found in estate->es_total_processed.
300 : : *
301 : : * We provide a function hook variable that lets loadable plugins
302 : : * get control when ExecutorRun is called. Such a plugin would
303 : : * normally call standard_ExecutorRun().
304 : : *
305 : : * ----------------------------------------------------------------
306 : : */
307 : : void
308 : 349903 : ExecutorRun(QueryDesc *queryDesc,
309 : : ScanDirection direction, uint64 count)
310 : : {
311 [ + + ]: 349903 : if (ExecutorRun_hook)
312 : 59186 : (*ExecutorRun_hook) (queryDesc, direction, count);
313 : : else
314 : 290717 : standard_ExecutorRun(queryDesc, direction, count);
315 : 334319 : }
316 : :
317 : : void
318 : 349903 : standard_ExecutorRun(QueryDesc *queryDesc,
319 : : ScanDirection direction, uint64 count)
320 : : {
321 : : EState *estate;
322 : : CmdType operation;
323 : : DestReceiver *dest;
324 : : bool sendTuples;
325 : : MemoryContext oldcontext;
326 : :
327 : : /* sanity checks */
328 : : Assert(queryDesc != NULL);
329 : :
330 : 349903 : estate = queryDesc->estate;
331 : :
332 : : Assert(estate != NULL);
333 : : Assert(!(estate->es_top_eflags & EXEC_FLAG_EXPLAIN_ONLY));
334 : :
335 : : /* caller must ensure the query's snapshot is active */
336 : : Assert(GetActiveSnapshot() == estate->es_snapshot);
337 : :
338 : : /*
339 : : * Switch into per-query memory context
340 : : */
341 : 349903 : oldcontext = MemoryContextSwitchTo(estate->es_query_cxt);
342 : :
343 : : /* Allow instrumentation of Executor overall runtime */
344 [ + + ]: 349903 : if (queryDesc->query_instr)
345 : 41382 : InstrStart(queryDesc->query_instr);
346 : :
347 : : /*
348 : : * extract information from the query descriptor and the query feature.
349 : : */
350 : 349903 : operation = queryDesc->operation;
351 : 349903 : dest = queryDesc->dest;
352 : :
353 : : /*
354 : : * startup tuple receiver, if we will be emitting tuples
355 : : */
356 : 349903 : estate->es_processed = 0;
357 : :
358 [ + + ]: 421965 : sendTuples = (operation == CMD_SELECT ||
359 [ + + ]: 72062 : queryDesc->plannedstmt->hasReturning);
360 : :
361 [ + + ]: 349903 : if (sendTuples)
362 : 281109 : dest->rStartup(dest, operation, queryDesc->tupDesc);
363 : :
364 : : /*
365 : : * Run plan, unless direction is NoMovement.
366 : : *
367 : : * Note: pquery.c selects NoMovement if a prior call already reached
368 : : * end-of-data in the user-specified fetch direction. This is important
369 : : * because various parts of the executor can misbehave if called again
370 : : * after reporting EOF. For example, heapam.c would actually restart a
371 : : * heapscan and return all its data afresh. There is also some doubt
372 : : * about whether a parallel plan would operate properly if an additional,
373 : : * necessarily non-parallel execution request occurs after completing a
374 : : * parallel execution. (That case should work, but it's untested.)
375 : : */
376 [ + + ]: 349878 : if (!ScanDirectionIsNoMovement(direction))
377 : 349067 : ExecutePlan(queryDesc,
378 : : operation,
379 : : sendTuples,
380 : : count,
381 : : direction,
382 : : dest);
383 : :
384 : : /*
385 : : * Update es_total_processed to keep track of the number of tuples
386 : : * processed across multiple ExecutorRun() calls.
387 : : */
388 : 334319 : estate->es_total_processed += estate->es_processed;
389 : :
390 : : /*
391 : : * shutdown tuple receiver, if we started it
392 : : */
393 [ + + ]: 334319 : if (sendTuples)
394 : 267701 : dest->rShutdown(dest);
395 : :
396 [ + + ]: 334319 : if (queryDesc->query_instr)
397 : 39886 : InstrStop(queryDesc->query_instr);
398 : :
399 : 334319 : MemoryContextSwitchTo(oldcontext);
400 : 334319 : }
401 : :
402 : : /* ----------------------------------------------------------------
403 : : * ExecutorFinish
404 : : *
405 : : * This routine must be called after the last ExecutorRun call.
406 : : * It performs cleanup such as firing AFTER triggers. It is
407 : : * separate from ExecutorEnd because EXPLAIN ANALYZE needs to
408 : : * include these actions in the total runtime.
409 : : *
410 : : * We provide a function hook variable that lets loadable plugins
411 : : * get control when ExecutorFinish is called. Such a plugin would
412 : : * normally call standard_ExecutorFinish().
413 : : *
414 : : * ----------------------------------------------------------------
415 : : */
416 : : void
417 : 324651 : ExecutorFinish(QueryDesc *queryDesc)
418 : : {
419 [ + + ]: 324651 : if (ExecutorFinish_hook)
420 : 53704 : (*ExecutorFinish_hook) (queryDesc);
421 : : else
422 : 270947 : standard_ExecutorFinish(queryDesc);
423 : 323842 : }
424 : :
425 : : void
426 : 324651 : standard_ExecutorFinish(QueryDesc *queryDesc)
427 : : {
428 : : EState *estate;
429 : : MemoryContext oldcontext;
430 : :
431 : : /* sanity checks */
432 : : Assert(queryDesc != NULL);
433 : :
434 : 324651 : estate = queryDesc->estate;
435 : :
436 : : Assert(estate != NULL);
437 : : Assert(!(estate->es_top_eflags & EXEC_FLAG_EXPLAIN_ONLY));
438 : :
439 : : /* This should be run once and only once per Executor instance */
440 : : Assert(!estate->es_finished);
441 : :
442 : : /* Switch into per-query memory context */
443 : 324651 : oldcontext = MemoryContextSwitchTo(estate->es_query_cxt);
444 : :
445 : : /* Allow instrumentation of Executor overall runtime */
446 [ + + ]: 324651 : if (queryDesc->query_instr)
447 : 39884 : InstrStart(queryDesc->query_instr);
448 : :
449 : : /* Run ModifyTable nodes to completion */
450 : 324651 : ExecPostprocessPlan(estate);
451 : :
452 : : /* Execute queued AFTER triggers, unless told not to */
453 [ + + ]: 324651 : if (!(estate->es_top_eflags & EXEC_FLAG_SKIP_TRIGGERS))
454 : 69464 : AfterTriggerEndQuery(estate);
455 : :
456 [ + + ]: 323842 : if (queryDesc->query_instr)
457 : 39706 : InstrStop(queryDesc->query_instr);
458 : :
459 : 323842 : MemoryContextSwitchTo(oldcontext);
460 : :
461 : 323842 : estate->es_finished = true;
462 : 323842 : }
463 : :
464 : : /* ----------------------------------------------------------------
465 : : * ExecutorEnd
466 : : *
467 : : * This routine must be called at the end of execution of any
468 : : * query plan
469 : : *
470 : : * We provide a function hook variable that lets loadable plugins
471 : : * get control when ExecutorEnd is called. Such a plugin would
472 : : * normally call standard_ExecutorEnd().
473 : : *
474 : : * ----------------------------------------------------------------
475 : : */
476 : : void
477 : 337981 : ExecutorEnd(QueryDesc *queryDesc)
478 : : {
479 [ + + ]: 337981 : if (ExecutorEnd_hook)
480 : 56629 : (*ExecutorEnd_hook) (queryDesc);
481 : : else
482 : 281352 : standard_ExecutorEnd(queryDesc);
483 : 337980 : }
484 : :
485 : : void
486 : 337981 : standard_ExecutorEnd(QueryDesc *queryDesc)
487 : : {
488 : : EState *estate;
489 : : MemoryContext oldcontext;
490 : :
491 : : /* sanity checks */
492 : : Assert(queryDesc != NULL);
493 : :
494 : 337981 : estate = queryDesc->estate;
495 : :
496 : : Assert(estate != NULL);
497 : :
498 [ + + ]: 337981 : if (estate->es_parallel_workers_to_launch > 0)
499 : 499 : pgstat_update_parallel_workers_stats((PgStat_Counter) estate->es_parallel_workers_to_launch,
500 : 499 : (PgStat_Counter) estate->es_parallel_workers_launched);
501 : :
502 : : /*
503 : : * Check that ExecutorFinish was called, unless in EXPLAIN-only mode. This
504 : : * Assert is needed because ExecutorFinish is new as of 9.1, and callers
505 : : * might forget to call it.
506 : : */
507 : : Assert(estate->es_finished ||
508 : : (estate->es_top_eflags & EXEC_FLAG_EXPLAIN_ONLY));
509 : :
510 : : /*
511 : : * Switch into per-query memory context to run ExecEndPlan
512 : : */
513 : 337981 : oldcontext = MemoryContextSwitchTo(estate->es_query_cxt);
514 : :
515 : 337981 : ExecEndPlan(queryDesc->planstate, estate);
516 : :
517 : : /* do away with our snapshots */
518 : 337980 : UnregisterSnapshot(estate->es_snapshot);
519 : 337980 : UnregisterSnapshot(estate->es_crosscheck_snapshot);
520 : :
521 : : /*
522 : : * Must switch out of context before destroying it
523 : : */
524 : 337980 : MemoryContextSwitchTo(oldcontext);
525 : :
526 : : /*
527 : : * Release EState and per-query memory context. This should release
528 : : * everything the executor has allocated.
529 : : */
530 : 337980 : FreeExecutorState(estate);
531 : :
532 : : /* Reset queryDesc fields that no longer point to anything */
533 : 337980 : queryDesc->tupDesc = NULL;
534 : 337980 : queryDesc->estate = NULL;
535 : 337980 : queryDesc->planstate = NULL;
536 : 337980 : queryDesc->query_instr = NULL;
537 : 337980 : }
538 : :
539 : : /* ----------------------------------------------------------------
540 : : * ExecutorRewind
541 : : *
542 : : * This routine may be called on an open queryDesc to rewind it
543 : : * to the start.
544 : : * ----------------------------------------------------------------
545 : : */
546 : : void
547 : 67 : ExecutorRewind(QueryDesc *queryDesc)
548 : : {
549 : : EState *estate;
550 : : MemoryContext oldcontext;
551 : :
552 : : /* sanity checks */
553 : : Assert(queryDesc != NULL);
554 : :
555 : 67 : estate = queryDesc->estate;
556 : :
557 : : Assert(estate != NULL);
558 : :
559 : : /* It's probably not sensible to rescan updating queries */
560 : : Assert(queryDesc->operation == CMD_SELECT);
561 : :
562 : : /*
563 : : * Switch into per-query memory context
564 : : */
565 : 67 : oldcontext = MemoryContextSwitchTo(estate->es_query_cxt);
566 : :
567 : : /*
568 : : * rescan plan
569 : : */
570 : 67 : ExecReScan(queryDesc->planstate);
571 : :
572 : 67 : MemoryContextSwitchTo(oldcontext);
573 : 67 : }
574 : :
575 : :
576 : : /*
577 : : * ExecCheckPermissions
578 : : * Check access permissions of relations mentioned in a query
579 : : *
580 : : * Returns true if permissions are adequate. Otherwise, throws an appropriate
581 : : * error if ereport_on_violation is true, or simply returns false otherwise.
582 : : *
583 : : * Note that this does NOT address row-level security policies (aka: RLS). If
584 : : * rows will be returned to the user as a result of this permission check
585 : : * passing, then RLS also needs to be consulted (and check_enable_rls()).
586 : : *
587 : : * See rewrite/rowsecurity.c.
588 : : *
589 : : * NB: rangeTable is no longer used by us, but kept around for the hooks that
590 : : * might still want to look at the RTEs.
591 : : */
592 : : bool
593 : 363924 : ExecCheckPermissions(List *rangeTable, List *rteperminfos,
594 : : bool ereport_on_violation)
595 : : {
596 : : ListCell *l;
597 : 363924 : bool result = true;
598 : :
599 : : #ifdef USE_ASSERT_CHECKING
600 : : Bitmapset *indexset = NULL;
601 : :
602 : : /* Check that rteperminfos is consistent with rangeTable */
603 : : foreach(l, rangeTable)
604 : : {
605 : : RangeTblEntry *rte = lfirst_node(RangeTblEntry, l);
606 : :
607 : : if (rte->perminfoindex != 0)
608 : : {
609 : : /* Sanity checks */
610 : :
611 : : /*
612 : : * Only relation RTEs and subquery RTEs that were once relation
613 : : * RTEs (views, property graphs) have their perminfoindex set.
614 : : */
615 : : Assert(rte->rtekind == RTE_RELATION ||
616 : : (rte->rtekind == RTE_SUBQUERY &&
617 : : (rte->relkind == RELKIND_VIEW || rte->relkind == RELKIND_PROPGRAPH)));
618 : :
619 : : (void) getRTEPermissionInfo(rteperminfos, rte);
620 : : /* Many-to-one mapping not allowed */
621 : : Assert(!bms_is_member(rte->perminfoindex, indexset));
622 : : indexset = bms_add_member(indexset, rte->perminfoindex);
623 : : }
624 : : }
625 : :
626 : : /* All rteperminfos are referenced */
627 : : Assert(bms_num_members(indexset) == list_length(rteperminfos));
628 : : #endif
629 : :
630 [ + + + + : 733996 : foreach(l, rteperminfos)
+ + ]
631 : : {
632 : 370997 : RTEPermissionInfo *perminfo = lfirst_node(RTEPermissionInfo, l);
633 : :
634 : : Assert(OidIsValid(perminfo->relid));
635 : 370997 : result = ExecCheckOneRelPerms(perminfo);
636 [ + + ]: 370997 : if (!result)
637 : : {
638 [ + + ]: 925 : if (ereport_on_violation)
639 : 917 : aclcheck_error(ACLCHECK_NO_PRIV,
640 : 917 : get_relkind_objtype(get_rel_relkind(perminfo->relid)),
641 : 917 : get_rel_name(perminfo->relid));
642 : 8 : return false;
643 : : }
644 : : }
645 : :
646 [ + + ]: 362999 : if (ExecutorCheckPerms_hook)
647 : 6 : result = (*ExecutorCheckPerms_hook) (rangeTable, rteperminfos,
648 : : ereport_on_violation);
649 : 362999 : return result;
650 : : }
651 : :
652 : : /*
653 : : * ExecCheckOneRelPerms
654 : : * Check access permissions for a single relation.
655 : : */
656 : : bool
657 : 387377 : ExecCheckOneRelPerms(RTEPermissionInfo *perminfo)
658 : : {
659 : : AclMode requiredPerms;
660 : : AclMode relPerms;
661 : : AclMode remainingPerms;
662 : : Oid userid;
663 : 387377 : Oid relOid = perminfo->relid;
664 : :
665 : 387377 : requiredPerms = perminfo->requiredPerms;
666 : : Assert(requiredPerms != 0);
667 : :
668 : : /*
669 : : * userid to check as: current user unless we have a setuid indication.
670 : : *
671 : : * Note: GetUserId() is presently fast enough that there's no harm in
672 : : * calling it separately for each relation. If that stops being true, we
673 : : * could call it once in ExecCheckPermissions and pass the userid down
674 : : * from there. But for now, no need for the extra clutter.
675 : : */
676 : 774754 : userid = OidIsValid(perminfo->checkAsUser) ?
677 [ + + ]: 387377 : perminfo->checkAsUser : GetUserId();
678 : :
679 : : /*
680 : : * We must have *all* the requiredPerms bits, but some of the bits can be
681 : : * satisfied from column-level rather than relation-level permissions.
682 : : * First, remove any bits that are satisfied by relation permissions.
683 : : */
684 : 387377 : relPerms = pg_class_aclmask(relOid, userid, requiredPerms, ACLMASK_ALL);
685 : 387377 : remainingPerms = requiredPerms & ~relPerms;
686 [ + + ]: 387377 : if (remainingPerms != 0)
687 : : {
688 : 2063 : int col = -1;
689 : :
690 : : /*
691 : : * If we lack any permissions that exist only as relation permissions,
692 : : * we can fail straight away.
693 : : */
694 [ + + ]: 2063 : if (remainingPerms & ~(ACL_SELECT | ACL_INSERT | ACL_UPDATE))
695 : 104 : return false;
696 : :
697 : : /*
698 : : * Check to see if we have the needed privileges at column level.
699 : : *
700 : : * Note: failures just report a table-level error; it would be nicer
701 : : * to report a column-level error if we have some but not all of the
702 : : * column privileges.
703 : : */
704 [ + + ]: 1959 : if (remainingPerms & ACL_SELECT)
705 : : {
706 : : /*
707 : : * When the query doesn't explicitly reference any columns (for
708 : : * example, SELECT COUNT(*) FROM table), allow the query if we
709 : : * have SELECT on any column of the rel, as per SQL spec.
710 : : */
711 [ + + ]: 1115 : if (bms_is_empty(perminfo->selectedCols))
712 : : {
713 [ + + ]: 64 : if (pg_attribute_aclcheck_all(relOid, userid, ACL_SELECT,
714 : : ACLMASK_ANY) != ACLCHECK_OK)
715 : 24 : return false;
716 : : }
717 : :
718 [ + + ]: 1786 : while ((col = bms_next_member(perminfo->selectedCols, col)) >= 0)
719 : : {
720 : : /* bit #s are offset by FirstLowInvalidHeapAttributeNumber */
721 : 1378 : AttrNumber attno = col + FirstLowInvalidHeapAttributeNumber;
722 : :
723 [ + + ]: 1378 : if (attno == InvalidAttrNumber)
724 : : {
725 : : /* Whole-row reference, must have priv on all cols */
726 [ + + ]: 44 : if (pg_attribute_aclcheck_all(relOid, userid, ACL_SELECT,
727 : : ACLMASK_ALL) != ACLCHECK_OK)
728 : 28 : return false;
729 : : }
730 : : else
731 : : {
732 [ + + ]: 1334 : if (pg_attribute_aclcheck(relOid, attno, userid,
733 : : ACL_SELECT) != ACLCHECK_OK)
734 : 655 : return false;
735 : : }
736 : : }
737 : : }
738 : :
739 : : /*
740 : : * Basically the same for the mod columns, for both INSERT and UPDATE
741 : : * privilege as specified by remainingPerms.
742 : : */
743 [ + + ]: 1252 : if (remainingPerms & ACL_INSERT &&
744 [ + + ]: 220 : !ExecCheckPermissionsModified(relOid,
745 : : userid,
746 : : perminfo->insertedCols,
747 : : ACL_INSERT))
748 : 116 : return false;
749 : :
750 [ + + ]: 1136 : if (remainingPerms & ACL_UPDATE &&
751 [ + + ]: 829 : !ExecCheckPermissionsModified(relOid,
752 : : userid,
753 : : perminfo->updatedCols,
754 : : ACL_UPDATE))
755 : 264 : return false;
756 : : }
757 : 386186 : return true;
758 : : }
759 : :
760 : : /*
761 : : * ExecCheckPermissionsModified
762 : : * Check INSERT or UPDATE access permissions for a single relation (these
763 : : * are processed uniformly).
764 : : */
765 : : static bool
766 : 1049 : ExecCheckPermissionsModified(Oid relOid, Oid userid, Bitmapset *modifiedCols,
767 : : AclMode requiredPerms)
768 : : {
769 : 1049 : int col = -1;
770 : :
771 : : /*
772 : : * When the query doesn't explicitly update any columns, allow the query
773 : : * if we have permission on any column of the rel. This is to handle
774 : : * SELECT FOR UPDATE as well as possible corner cases in UPDATE.
775 : : */
776 [ + + ]: 1049 : if (bms_is_empty(modifiedCols))
777 : : {
778 [ + + ]: 49 : if (pg_attribute_aclcheck_all(relOid, userid, requiredPerms,
779 : : ACLMASK_ANY) != ACLCHECK_OK)
780 : 36 : return false;
781 : : }
782 : :
783 [ + + ]: 1784 : while ((col = bms_next_member(modifiedCols, col)) >= 0)
784 : : {
785 : : /* bit #s are offset by FirstLowInvalidHeapAttributeNumber */
786 : 1115 : AttrNumber attno = col + FirstLowInvalidHeapAttributeNumber;
787 : :
788 [ - + ]: 1115 : if (attno == InvalidAttrNumber)
789 : : {
790 : : /* whole-row reference can't happen here */
791 [ # # ]: 0 : elog(ERROR, "whole-row update is not implemented");
792 : : }
793 : : else
794 : : {
795 [ + + ]: 1115 : if (pg_attribute_aclcheck(relOid, attno, userid,
796 : : requiredPerms) != ACLCHECK_OK)
797 : 344 : return false;
798 : : }
799 : : }
800 : 669 : return true;
801 : : }
802 : :
803 : : /*
804 : : * Check that the query does not imply any writes to non-temp tables;
805 : : * unless we're in parallel mode, in which case don't even allow writes
806 : : * to temp tables.
807 : : *
808 : : * Note: in a Hot Standby this would need to reject writes to temp
809 : : * tables just as we do in parallel mode; but an HS standby can't have created
810 : : * any temp tables in the first place, so no need to check that.
811 : : */
812 : : static void
813 : 33506 : ExecCheckXactReadOnly(PlannedStmt *plannedstmt)
814 : : {
815 : : ListCell *l;
816 : :
817 : : /*
818 : : * Fail if write permissions are requested in parallel mode for table
819 : : * (temp or non-temp), otherwise fail for any non-temp table.
820 : : */
821 [ + + + + : 95306 : foreach(l, plannedstmt->permInfos)
+ + ]
822 : : {
823 : 61818 : RTEPermissionInfo *perminfo = lfirst_node(RTEPermissionInfo, l);
824 : :
825 [ + + ]: 61818 : if ((perminfo->requiredPerms & (~ACL_SELECT)) == 0)
826 : 61792 : continue;
827 : :
828 [ + + ]: 26 : if (isTempNamespace(get_rel_namespace(perminfo->relid)))
829 : 8 : continue;
830 : :
831 : 18 : PreventCommandIfReadOnly(CreateCommandName((Node *) plannedstmt));
832 : : }
833 : :
834 [ + + - + ]: 33488 : if (plannedstmt->commandType != CMD_SELECT || plannedstmt->hasModifyingCTE)
835 : 8 : PreventCommandIfParallelMode(CreateCommandName((Node *) plannedstmt));
836 : 33488 : }
837 : :
838 : :
839 : : /* ----------------------------------------------------------------
840 : : * InitPlan
841 : : *
842 : : * Initializes the query plan: open files, allocate storage
843 : : * and start up the rule manager
844 : : * ----------------------------------------------------------------
845 : : */
846 : : static void
847 : 356933 : InitPlan(QueryDesc *queryDesc, int eflags)
848 : : {
849 : 356933 : CmdType operation = queryDesc->operation;
850 : 356933 : PlannedStmt *plannedstmt = queryDesc->plannedstmt;
851 : 356933 : Plan *plan = plannedstmt->planTree;
852 : 356933 : List *rangeTable = plannedstmt->rtable;
853 : 356933 : EState *estate = queryDesc->estate;
854 : : PlanState *planstate;
855 : : TupleDesc tupType;
856 : : ListCell *l;
857 : : int i;
858 : :
859 : : /*
860 : : * Do permissions checks
861 : : */
862 : 356933 : ExecCheckPermissions(rangeTable, plannedstmt->permInfos, true);
863 : :
864 : : /*
865 : : * initialize the node's execution state
866 : : */
867 : 356072 : ExecInitRangeTable(estate, rangeTable, plannedstmt->permInfos,
868 : 356072 : bms_copy(plannedstmt->unprunableRelids));
869 : :
870 : 356072 : estate->es_plannedstmt = plannedstmt;
871 : 356072 : estate->es_part_prune_infos = plannedstmt->partPruneInfos;
872 : :
873 : : /*
874 : : * Perform runtime "initial" pruning to identify which child subplans,
875 : : * corresponding to the children of plan nodes that contain
876 : : * PartitionPruneInfo such as Append, will not be executed. The results,
877 : : * which are bitmapsets of indexes of the child subplans that will be
878 : : * executed, are saved in es_part_prune_results. These results correspond
879 : : * to each PartitionPruneInfo entry, and the es_part_prune_results list is
880 : : * parallel to es_part_prune_infos.
881 : : */
882 : 356072 : ExecDoInitialPruning(estate);
883 : :
884 : : /*
885 : : * Next, build the ExecRowMark array from the PlanRowMark(s), if any.
886 : : */
887 [ + + ]: 356072 : if (plannedstmt->rowMarks)
888 : : {
889 : 7368 : estate->es_rowmarks = (ExecRowMark **)
890 : 7368 : palloc0_array(ExecRowMark *, estate->es_range_table_size);
891 [ + - + + : 16970 : foreach(l, plannedstmt->rowMarks)
+ + ]
892 : : {
893 : 9610 : PlanRowMark *rc = (PlanRowMark *) lfirst(l);
894 : 9610 : RangeTblEntry *rte = exec_rt_fetch(rc->rti, estate);
895 : : Oid relid;
896 : : Relation relation;
897 : : ExecRowMark *erm;
898 : :
899 : : /* ignore "parent" rowmarks; they are irrelevant at runtime */
900 [ + + ]: 9610 : if (rc->isParent)
901 : 1278 : continue;
902 : :
903 : : /*
904 : : * Also ignore rowmarks belonging to child tables that have been
905 : : * pruned in ExecDoInitialPruning().
906 : : */
907 [ + + ]: 8332 : if (rte->rtekind == RTE_RELATION &&
908 [ + + ]: 7955 : !bms_is_member(rc->rti, estate->es_unpruned_relids))
909 : 48 : continue;
910 : :
911 : : /* get relation's OID (will produce InvalidOid if subquery) */
912 : 8284 : relid = rte->relid;
913 : :
914 : : /* open relation, if we need to access it for this mark type */
915 [ + + - ]: 8284 : switch (rc->markType)
916 : : {
917 : 7797 : case ROW_MARK_EXCLUSIVE:
918 : : case ROW_MARK_NOKEYEXCLUSIVE:
919 : : case ROW_MARK_SHARE:
920 : : case ROW_MARK_KEYSHARE:
921 : : case ROW_MARK_REFERENCE:
922 : 7797 : relation = ExecGetRangeTableRelation(estate, rc->rti, false);
923 : 7797 : break;
924 : 487 : case ROW_MARK_COPY:
925 : : /* no physical table access is required */
926 : 487 : relation = NULL;
927 : 487 : break;
928 : 0 : default:
929 [ # # ]: 0 : elog(ERROR, "unrecognized markType: %d", rc->markType);
930 : : relation = NULL; /* keep compiler quiet */
931 : : break;
932 : : }
933 : :
934 : : /* Check that relation is a legal target for marking */
935 [ + + ]: 8284 : if (relation)
936 : 7797 : CheckValidRowMarkRel(relation, rc->markType);
937 : :
938 : 8276 : erm = palloc_object(ExecRowMark);
939 : 8276 : erm->relation = relation;
940 : 8276 : erm->relid = relid;
941 : 8276 : erm->rti = rc->rti;
942 : 8276 : erm->prti = rc->prti;
943 : 8276 : erm->rowmarkId = rc->rowmarkId;
944 : 8276 : erm->markType = rc->markType;
945 : 8276 : erm->strength = rc->strength;
946 : 8276 : erm->waitPolicy = rc->waitPolicy;
947 : 8276 : erm->ermActive = false;
948 : 8276 : ItemPointerSetInvalid(&(erm->curCtid));
949 : 8276 : erm->ermExtra = NULL;
950 : :
951 : : Assert(erm->rti > 0 && erm->rti <= estate->es_range_table_size &&
952 : : estate->es_rowmarks[erm->rti - 1] == NULL);
953 : :
954 : 8276 : estate->es_rowmarks[erm->rti - 1] = erm;
955 : : }
956 : : }
957 : :
958 : : /*
959 : : * Initialize the executor's tuple table to empty.
960 : : */
961 : 356064 : estate->es_tupleTable = NIL;
962 : :
963 : : /* signal that this EState is not used for EPQ */
964 : 356064 : estate->es_epq_active = NULL;
965 : :
966 : : /*
967 : : * Initialize private state information for each SubPlan. We must do this
968 : : * before running ExecInitNode on the main query tree, since
969 : : * ExecInitSubPlan expects to be able to find these entries.
970 : : */
971 : : Assert(estate->es_subplanstates == NIL);
972 : 356064 : i = 1; /* subplan indices count from 1 */
973 [ + + + + : 384957 : foreach(l, plannedstmt->subplans)
+ + ]
974 : : {
975 : 28893 : Plan *subplan = (Plan *) lfirst(l);
976 : : PlanState *subplanstate;
977 : : int sp_eflags;
978 : :
979 : : /*
980 : : * A subplan will never need to do BACKWARD scan nor MARK/RESTORE. If
981 : : * it is a parameterless subplan (not initplan), we suggest that it be
982 : : * prepared to handle REWIND efficiently; otherwise there is no need.
983 : : */
984 : 28893 : sp_eflags = eflags
985 : : & ~(EXEC_FLAG_REWIND | EXEC_FLAG_BACKWARD | EXEC_FLAG_MARK);
986 [ + + ]: 28893 : if (bms_is_member(i, plannedstmt->rewindPlanIDs))
987 : 36 : sp_eflags |= EXEC_FLAG_REWIND;
988 : :
989 : 28893 : subplanstate = ExecInitNode(subplan, estate, sp_eflags);
990 : :
991 : 28893 : estate->es_subplanstates = lappend(estate->es_subplanstates,
992 : : subplanstate);
993 : :
994 : 28893 : i++;
995 : : }
996 : :
997 : : /*
998 : : * Initialize the private state information for all the nodes in the query
999 : : * tree. This opens files, allocates storage and leaves us ready to start
1000 : : * processing tuples.
1001 : : */
1002 : 356064 : planstate = ExecInitNode(plan, estate, eflags);
1003 : :
1004 : : /*
1005 : : * Get the tuple descriptor describing the type of tuples to return.
1006 : : */
1007 : 355743 : tupType = ExecGetResultType(planstate);
1008 : :
1009 : : /*
1010 : : * Initialize the junk filter if needed. SELECT queries need a filter if
1011 : : * there are any junk attrs in the top-level tlist.
1012 : : */
1013 [ + + ]: 355743 : if (operation == CMD_SELECT)
1014 : : {
1015 : 283030 : bool junk_filter_needed = false;
1016 : : ListCell *tlist;
1017 : :
1018 [ + + + + : 1038912 : foreach(tlist, plan->targetlist)
+ + ]
1019 : : {
1020 : 770713 : TargetEntry *tle = (TargetEntry *) lfirst(tlist);
1021 : :
1022 [ + + ]: 770713 : if (tle->resjunk)
1023 : : {
1024 : 14831 : junk_filter_needed = true;
1025 : 14831 : break;
1026 : : }
1027 : : }
1028 : :
1029 [ + + ]: 283030 : if (junk_filter_needed)
1030 : : {
1031 : : JunkFilter *j;
1032 : : TupleTableSlot *slot;
1033 : :
1034 : 14831 : slot = ExecInitExtraTupleSlot(estate, NULL, &TTSOpsVirtual);
1035 : 14831 : j = ExecInitJunkFilter(planstate->plan->targetlist,
1036 : : slot);
1037 : 14831 : estate->es_junkFilter = j;
1038 : :
1039 : : /* Want to return the cleaned tuple type */
1040 : 14831 : tupType = j->jf_cleanTupType;
1041 : : }
1042 : : }
1043 : :
1044 : 355743 : queryDesc->tupDesc = tupType;
1045 : 355743 : queryDesc->planstate = planstate;
1046 : 355743 : }
1047 : :
1048 : : /*
1049 : : * Check that a proposed result relation is a legal target for the operation
1050 : : *
1051 : : * Generally the parser and/or planner should have noticed any such mistake
1052 : : * already, but let's make sure.
1053 : : *
1054 : : * For INSERT ON CONFLICT, the result relation is required to support the
1055 : : * onConflictAction, regardless of whether a conflict actually occurs.
1056 : : *
1057 : : * For MERGE, mergeActions is the list of actions that may be performed. The
1058 : : * result relation is required to support every action, regardless of whether
1059 : : * or not they are all executed.
1060 : : *
1061 : : * Note: when changing this function, you probably also need to look at
1062 : : * CheckValidRowMarkRel.
1063 : : */
1064 : : void
1065 : 81159 : CheckValidResultRel(ResultRelInfo *resultRelInfo, CmdType operation,
1066 : : OnConflictAction onConflictAction, List *mergeActions,
1067 : : ModifyTable *mtnode)
1068 : : {
1069 : 81159 : Relation resultRel = resultRelInfo->ri_RelationDesc;
1070 : : FdwRoutine *fdwroutine;
1071 : :
1072 : : /* Expect a fully-formed ResultRelInfo from InitResultRelInfo(). */
1073 : : Assert(resultRelInfo->ri_needLockTagTuple ==
1074 : : IsInplaceUpdateRelation(resultRel));
1075 : :
1076 [ + - - + : 81159 : switch (resultRel->rd_rel->relkind)
+ + - - ]
1077 : : {
1078 : 80453 : case RELKIND_RELATION:
1079 : : case RELKIND_PARTITIONED_TABLE:
1080 : :
1081 : : /*
1082 : : * For MERGE, check that the target relation supports each action.
1083 : : * For other operations, just check the operation itself.
1084 : : */
1085 [ + + ]: 80453 : if (operation == CMD_MERGE)
1086 [ + - + + : 4349 : foreach_node(MergeAction, action, mergeActions)
+ + ]
1087 : 2029 : CheckCmdReplicaIdentity(resultRel, action->commandType);
1088 : : else
1089 : 79285 : CheckCmdReplicaIdentity(resultRel, operation);
1090 : :
1091 : : /*
1092 : : * For INSERT ON CONFLICT DO UPDATE, additionally check that the
1093 : : * target relation supports UPDATE.
1094 : : */
1095 [ + + ]: 80238 : if (onConflictAction == ONCONFLICT_UPDATE)
1096 : 801 : CheckCmdReplicaIdentity(resultRel, CMD_UPDATE);
1097 : 80230 : break;
1098 : 0 : case RELKIND_SEQUENCE:
1099 [ # # ]: 0 : ereport(ERROR,
1100 : : (errcode(ERRCODE_WRONG_OBJECT_TYPE),
1101 : : errmsg("cannot change sequence \"%s\"",
1102 : : RelationGetRelationName(resultRel))));
1103 : : break;
1104 : 0 : case RELKIND_TOASTVALUE:
1105 [ # # ]: 0 : ereport(ERROR,
1106 : : (errcode(ERRCODE_WRONG_OBJECT_TYPE),
1107 : : errmsg("cannot change TOAST relation \"%s\"",
1108 : : RelationGetRelationName(resultRel))));
1109 : : break;
1110 : 277 : case RELKIND_VIEW:
1111 : :
1112 : : /*
1113 : : * Okay only if there's a suitable INSTEAD OF trigger. Otherwise,
1114 : : * complain, but omit errdetail because we haven't got the
1115 : : * information handy (and given that it really shouldn't happen,
1116 : : * it's not worth great exertion to get).
1117 : : */
1118 [ - + ]: 277 : if (!view_has_instead_trigger(resultRel, operation, mergeActions))
1119 : 0 : error_view_not_updatable(resultRel, operation, mergeActions,
1120 : : NULL);
1121 : 277 : break;
1122 : 74 : case RELKIND_MATVIEW:
1123 [ - + ]: 74 : if (!MatViewIncrementalMaintenanceIsEnabled())
1124 [ # # ]: 0 : ereport(ERROR,
1125 : : (errcode(ERRCODE_WRONG_OBJECT_TYPE),
1126 : : errmsg("cannot change materialized view \"%s\"",
1127 : : RelationGetRelationName(resultRel))));
1128 : 74 : break;
1129 : 355 : case RELKIND_FOREIGN_TABLE:
1130 : : /* We don't support FOR PORTION OF FDW queries. */
1131 [ + + + + ]: 355 : if (mtnode && mtnode->forPortionOf)
1132 [ + - ]: 4 : ereport(ERROR,
1133 : : errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
1134 : : errmsg("foreign tables don't support FOR PORTION OF"),
1135 : : errdetail("\"%s\" is a foreign table.",
1136 : : RelationGetRelationName(resultRel)));
1137 : :
1138 : : /* Okay only if the FDW supports it */
1139 : 351 : fdwroutine = resultRelInfo->ri_FdwRoutine;
1140 [ + + + - ]: 351 : switch (operation)
1141 : : {
1142 : 157 : case CMD_INSERT:
1143 [ + + ]: 157 : if (fdwroutine->ExecForeignInsert == NULL)
1144 [ + - ]: 5 : ereport(ERROR,
1145 : : (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
1146 : : errmsg("cannot insert into foreign table \"%s\"",
1147 : : RelationGetRelationName(resultRel))));
1148 [ + - ]: 152 : if (fdwroutine->IsForeignRelUpdatable != NULL &&
1149 [ - + ]: 152 : (fdwroutine->IsForeignRelUpdatable(resultRel) & (1 << CMD_INSERT)) == 0)
1150 [ # # ]: 0 : ereport(ERROR,
1151 : : (errcode(ERRCODE_OBJECT_NOT_IN_PREREQUISITE_STATE),
1152 : : errmsg("foreign table \"%s\" does not allow inserts",
1153 : : RelationGetRelationName(resultRel))));
1154 : 152 : break;
1155 : 111 : case CMD_UPDATE:
1156 [ + + ]: 111 : if (fdwroutine->ExecForeignUpdate == NULL)
1157 [ + - ]: 2 : ereport(ERROR,
1158 : : (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
1159 : : errmsg("cannot update foreign table \"%s\"",
1160 : : RelationGetRelationName(resultRel))));
1161 [ + - ]: 109 : if (fdwroutine->IsForeignRelUpdatable != NULL &&
1162 [ - + ]: 109 : (fdwroutine->IsForeignRelUpdatable(resultRel) & (1 << CMD_UPDATE)) == 0)
1163 [ # # ]: 0 : ereport(ERROR,
1164 : : (errcode(ERRCODE_OBJECT_NOT_IN_PREREQUISITE_STATE),
1165 : : errmsg("foreign table \"%s\" does not allow updates",
1166 : : RelationGetRelationName(resultRel))));
1167 : 109 : break;
1168 : 83 : case CMD_DELETE:
1169 [ + + ]: 83 : if (fdwroutine->ExecForeignDelete == NULL)
1170 [ + - ]: 2 : ereport(ERROR,
1171 : : (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
1172 : : errmsg("cannot delete from foreign table \"%s\"",
1173 : : RelationGetRelationName(resultRel))));
1174 [ + - ]: 81 : if (fdwroutine->IsForeignRelUpdatable != NULL &&
1175 [ - + ]: 81 : (fdwroutine->IsForeignRelUpdatable(resultRel) & (1 << CMD_DELETE)) == 0)
1176 [ # # ]: 0 : ereport(ERROR,
1177 : : (errcode(ERRCODE_OBJECT_NOT_IN_PREREQUISITE_STATE),
1178 : : errmsg("foreign table \"%s\" does not allow deletes",
1179 : : RelationGetRelationName(resultRel))));
1180 : 81 : break;
1181 : 0 : default:
1182 [ # # ]: 0 : elog(ERROR, "unrecognized CmdType: %d", (int) operation);
1183 : : break;
1184 : : }
1185 : 342 : break;
1186 : 0 : case RELKIND_PROPGRAPH:
1187 [ # # ]: 0 : ereport(ERROR,
1188 : : (errcode(ERRCODE_WRONG_OBJECT_TYPE),
1189 : : errmsg("cannot change property graph \"%s\"",
1190 : : RelationGetRelationName(resultRel))));
1191 : : break;
1192 : 0 : default:
1193 [ # # ]: 0 : ereport(ERROR,
1194 : : (errcode(ERRCODE_WRONG_OBJECT_TYPE),
1195 : : errmsg("cannot change relation \"%s\"",
1196 : : RelationGetRelationName(resultRel))));
1197 : : break;
1198 : : }
1199 : :
1200 : : /*
1201 : : * Conflict log tables are managed by the system to record logical
1202 : : * replication conflicts. We allow DELETE and TRUNCATE to permit users to
1203 : : * manually prune these logs, but manual data insertion or modification
1204 : : * (INSERT, UPDATE, MERGE) is prohibited to maintain the integrity of the
1205 : : * system-generated logs.
1206 : : *
1207 : : * Since TRUNCATE is handled as a separate utility command, we only need
1208 : : * to explicitly permit CMD_DELETE here.
1209 : : */
1210 [ + + + + ]: 80923 : if (IsConflictLogTableNamespace(RelationGetNamespace(resultRel)) &&
1211 : : operation != CMD_DELETE)
1212 [ + - ]: 8 : ereport(ERROR,
1213 : : (errcode(ERRCODE_WRONG_OBJECT_TYPE),
1214 : : errmsg("cannot modify or insert data into conflict log table \"%s\"",
1215 : : RelationGetRelationName(resultRel)),
1216 : : errdetail("Conflict log tables are system-managed and only support cleanup using DELETE or TRUNCATE.")));
1217 : 80915 : }
1218 : :
1219 : : /*
1220 : : * Check that a proposed rowmark target relation is a legal target
1221 : : *
1222 : : * In most cases parser and/or planner should have noticed this already, but
1223 : : * they don't cover all cases.
1224 : : */
1225 : : static void
1226 : 7797 : CheckValidRowMarkRel(Relation rel, RowMarkType markType)
1227 : : {
1228 : : FdwRoutine *fdwroutine;
1229 : :
1230 [ + - - - : 7797 : switch (rel->rd_rel->relkind)
+ - - - ]
1231 : : {
1232 : 7789 : case RELKIND_RELATION:
1233 : : case RELKIND_PARTITIONED_TABLE:
1234 : : /* OK */
1235 : 7789 : break;
1236 : 0 : case RELKIND_SEQUENCE:
1237 : : /* Must disallow this because we don't vacuum sequences */
1238 [ # # ]: 0 : ereport(ERROR,
1239 : : (errcode(ERRCODE_WRONG_OBJECT_TYPE),
1240 : : errmsg("cannot lock rows in sequence \"%s\"",
1241 : : RelationGetRelationName(rel))));
1242 : : break;
1243 : 0 : case RELKIND_TOASTVALUE:
1244 : : /* We could allow this, but there seems no good reason to */
1245 [ # # ]: 0 : ereport(ERROR,
1246 : : (errcode(ERRCODE_WRONG_OBJECT_TYPE),
1247 : : errmsg("cannot lock rows in TOAST relation \"%s\"",
1248 : : RelationGetRelationName(rel))));
1249 : : break;
1250 : 0 : case RELKIND_VIEW:
1251 : : /* Should not get here; planner should have expanded the view */
1252 [ # # ]: 0 : ereport(ERROR,
1253 : : (errcode(ERRCODE_WRONG_OBJECT_TYPE),
1254 : : errmsg("cannot lock rows in view \"%s\"",
1255 : : RelationGetRelationName(rel))));
1256 : : break;
1257 : 8 : case RELKIND_MATVIEW:
1258 : : /* Allow referencing a matview, but not actual locking clauses */
1259 [ + + ]: 8 : if (markType != ROW_MARK_REFERENCE)
1260 [ + - ]: 4 : ereport(ERROR,
1261 : : (errcode(ERRCODE_WRONG_OBJECT_TYPE),
1262 : : errmsg("cannot lock rows in materialized view \"%s\"",
1263 : : RelationGetRelationName(rel))));
1264 : 4 : break;
1265 : 0 : case RELKIND_FOREIGN_TABLE:
1266 : : /* Okay only if the FDW supports it */
1267 : 0 : fdwroutine = GetFdwRoutineForRelation(rel, false);
1268 [ # # ]: 0 : if (fdwroutine->RefetchForeignRow == NULL)
1269 [ # # ]: 0 : ereport(ERROR,
1270 : : (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
1271 : : errmsg("cannot lock rows in foreign table \"%s\"",
1272 : : RelationGetRelationName(rel))));
1273 : 0 : break;
1274 : 0 : case RELKIND_PROPGRAPH:
1275 : : /* Should not get here; rewriter should have expanded the graph */
1276 [ # # ]: 0 : ereport(ERROR,
1277 : : (errcode(ERRCODE_WRONG_OBJECT_TYPE),
1278 : : errmsg_internal("cannot lock rows in property graph \"%s\"",
1279 : : RelationGetRelationName(rel))));
1280 : : break;
1281 : 0 : default:
1282 [ # # ]: 0 : ereport(ERROR,
1283 : : (errcode(ERRCODE_WRONG_OBJECT_TYPE),
1284 : : errmsg("cannot lock rows in relation \"%s\"",
1285 : : RelationGetRelationName(rel))));
1286 : : break;
1287 : : }
1288 : :
1289 : : /*
1290 : : * Conflict log tables are managed by the system to record logical
1291 : : * replication conflicts.
1292 : : */
1293 [ + + ]: 7793 : if (IsConflictLogTableNamespace(RelationGetNamespace(rel)))
1294 [ + - ]: 4 : ereport(ERROR,
1295 : : (errcode(ERRCODE_WRONG_OBJECT_TYPE),
1296 : : errmsg("cannot lock rows in the conflict log table \"%s\"",
1297 : : RelationGetRelationName(rel))));
1298 : 7789 : }
1299 : :
1300 : : /*
1301 : : * Initialize ResultRelInfo data for one result relation
1302 : : *
1303 : : * Caution: before Postgres 9.1, this function included the relkind checking
1304 : : * that's now in CheckValidResultRel, and it also did ExecOpenIndices if
1305 : : * appropriate. Be sure callers cover those needs.
1306 : : */
1307 : : void
1308 : 256170 : InitResultRelInfo(ResultRelInfo *resultRelInfo,
1309 : : Relation resultRelationDesc,
1310 : : Index resultRelationIndex,
1311 : : ResultRelInfo *partition_root_rri,
1312 : : int instrument_options)
1313 : : {
1314 [ + - + - : 13320840 : MemSet(resultRelInfo, 0, sizeof(ResultRelInfo));
+ - + - +
+ ]
1315 : 256170 : resultRelInfo->type = T_ResultRelInfo;
1316 : 256170 : resultRelInfo->ri_RangeTableIndex = resultRelationIndex;
1317 : 256170 : resultRelInfo->ri_RelationDesc = resultRelationDesc;
1318 : 256170 : resultRelInfo->ri_NumIndices = 0;
1319 : 256170 : resultRelInfo->ri_IndexRelationDescs = NULL;
1320 : 256170 : resultRelInfo->ri_IndexRelationInfo = NULL;
1321 : 256170 : resultRelInfo->ri_needLockTagTuple =
1322 : 256170 : IsInplaceUpdateRelation(resultRelationDesc);
1323 : : /* make a copy so as not to depend on relcache info not changing... */
1324 : 256170 : resultRelInfo->ri_TrigDesc = CopyTriggerDesc(resultRelationDesc->trigdesc);
1325 [ + + ]: 256170 : if (resultRelInfo->ri_TrigDesc)
1326 : : {
1327 : 12825 : int n = resultRelInfo->ri_TrigDesc->numtriggers;
1328 : :
1329 : 12825 : resultRelInfo->ri_TrigFunctions = (FmgrInfo *)
1330 : 12825 : palloc0_array(FmgrInfo, n);
1331 : 12825 : resultRelInfo->ri_TrigWhenExprs = (ExprState **)
1332 : 12825 : palloc0_array(ExprState *, n);
1333 [ - + ]: 12825 : if (instrument_options)
1334 : 0 : resultRelInfo->ri_TrigInstrument = InstrAllocTrigger(n, instrument_options);
1335 : : }
1336 : : else
1337 : : {
1338 : 243345 : resultRelInfo->ri_TrigFunctions = NULL;
1339 : 243345 : resultRelInfo->ri_TrigWhenExprs = NULL;
1340 : 243345 : resultRelInfo->ri_TrigInstrument = NULL;
1341 : : }
1342 [ + + ]: 256170 : if (resultRelationDesc->rd_rel->relkind == RELKIND_FOREIGN_TABLE)
1343 : 368 : resultRelInfo->ri_FdwRoutine = GetFdwRoutineForRelation(resultRelationDesc, true);
1344 : : else
1345 : 255802 : resultRelInfo->ri_FdwRoutine = NULL;
1346 : :
1347 : : /* The following fields are set later if needed */
1348 : 256170 : resultRelInfo->ri_RowIdAttNo = 0;
1349 : 256170 : resultRelInfo->ri_extraUpdatedCols = NULL;
1350 : 256170 : resultRelInfo->ri_projectNew = NULL;
1351 : 256170 : resultRelInfo->ri_newTupleSlot = NULL;
1352 : 256170 : resultRelInfo->ri_oldTupleSlot = NULL;
1353 : 256170 : resultRelInfo->ri_projectNewInfoValid = false;
1354 : 256170 : resultRelInfo->ri_FdwState = NULL;
1355 : 256170 : resultRelInfo->ri_usesFdwDirectModify = false;
1356 : 256170 : resultRelInfo->ri_CheckConstraintExprs = NULL;
1357 : 256170 : resultRelInfo->ri_GenVirtualNotNullConstraintExprs = NULL;
1358 : 256170 : resultRelInfo->ri_GeneratedExprsI = NULL;
1359 : 256170 : resultRelInfo->ri_GeneratedExprsU = NULL;
1360 : 256170 : resultRelInfo->ri_projectReturning = NULL;
1361 : 256170 : resultRelInfo->ri_onConflictArbiterIndexes = NIL;
1362 : 256170 : resultRelInfo->ri_onConflict = NULL;
1363 : 256170 : resultRelInfo->ri_forPortionOf = NULL;
1364 : 256170 : resultRelInfo->ri_ReturningSlot = NULL;
1365 : 256170 : resultRelInfo->ri_TrigOldSlot = NULL;
1366 : 256170 : resultRelInfo->ri_TrigNewSlot = NULL;
1367 : 256170 : resultRelInfo->ri_AllNullSlot = NULL;
1368 : 256170 : resultRelInfo->ri_MergeActions[MERGE_WHEN_MATCHED] = NIL;
1369 : 256170 : resultRelInfo->ri_MergeActions[MERGE_WHEN_NOT_MATCHED_BY_SOURCE] = NIL;
1370 : 256170 : resultRelInfo->ri_MergeActions[MERGE_WHEN_NOT_MATCHED_BY_TARGET] = NIL;
1371 : 256170 : resultRelInfo->ri_MergeJoinCondition = NULL;
1372 : :
1373 : : /*
1374 : : * Only ExecInitPartitionInfo() and ExecInitPartitionDispatchInfo() pass
1375 : : * non-NULL partition_root_rri. For child relations that are part of the
1376 : : * initial query rather than being dynamically added by tuple routing,
1377 : : * this field is filled in ExecInitModifyTable().
1378 : : */
1379 : 256170 : resultRelInfo->ri_RootResultRelInfo = partition_root_rri;
1380 : : /* Set by ExecGetRootToChildMap */
1381 : 256170 : resultRelInfo->ri_RootToChildMap = NULL;
1382 : 256170 : resultRelInfo->ri_RootToChildMapValid = false;
1383 : : /* Set by ExecInitRoutingInfo */
1384 : 256170 : resultRelInfo->ri_PartitionTupleSlot = NULL;
1385 : 256170 : resultRelInfo->ri_ChildToRootMap = NULL;
1386 : 256170 : resultRelInfo->ri_ChildToRootMapValid = false;
1387 : 256170 : resultRelInfo->ri_CopyMultiInsertBuffer = NULL;
1388 : 256170 : }
1389 : :
1390 : : /*
1391 : : * ExecGetTriggerResultRel
1392 : : * Get a ResultRelInfo for a trigger target relation.
1393 : : *
1394 : : * Most of the time, triggers are fired on one of the result relations of the
1395 : : * query, and so we can just return a suitable one we already made and stored
1396 : : * in the es_opened_result_relations or es_tuple_routing_result_relations
1397 : : * Lists.
1398 : : *
1399 : : * However, it is sometimes necessary to fire triggers on other relations;
1400 : : * this happens mainly when an RI update trigger queues additional triggers
1401 : : * on other relations, which will be processed in the context of the outer
1402 : : * query. For efficiency's sake, we want to have a ResultRelInfo for those
1403 : : * triggers too; that can avoid repeated re-opening of the relation. (It
1404 : : * also provides a way for EXPLAIN ANALYZE to report the runtimes of such
1405 : : * triggers.) So we make additional ResultRelInfo's as needed, and save them
1406 : : * in es_trig_target_relations.
1407 : : */
1408 : : ResultRelInfo *
1409 : 5970 : ExecGetTriggerResultRel(EState *estate, Oid relid,
1410 : : ResultRelInfo *rootRelInfo)
1411 : : {
1412 : : ResultRelInfo *rInfo;
1413 : : ListCell *l;
1414 : : Relation rel;
1415 : : MemoryContext oldcontext;
1416 : :
1417 : : /*
1418 : : * Before creating a new ResultRelInfo, check if we've already made and
1419 : : * cached one for this relation. We must ensure that the given
1420 : : * 'rootRelInfo' matches the one stored in the cached ResultRelInfo as
1421 : : * trigger handling for partitions can result in mixed requirements for
1422 : : * what ri_RootResultRelInfo is set to.
1423 : : */
1424 : :
1425 : : /* Search through the query result relations */
1426 [ + + + + : 7847 : foreach(l, estate->es_opened_result_relations)
+ + ]
1427 : : {
1428 : 6526 : rInfo = lfirst(l);
1429 [ + + ]: 6526 : if (RelationGetRelid(rInfo->ri_RelationDesc) == relid &&
1430 [ + + ]: 4911 : rInfo->ri_RootResultRelInfo == rootRelInfo)
1431 : 4649 : return rInfo;
1432 : : }
1433 : :
1434 : : /*
1435 : : * Search through the result relations that were created during tuple
1436 : : * routing, if any.
1437 : : */
1438 [ + + + + : 2057 : foreach(l, estate->es_tuple_routing_result_relations)
+ + ]
1439 : : {
1440 : 756 : rInfo = (ResultRelInfo *) lfirst(l);
1441 [ + + ]: 756 : if (RelationGetRelid(rInfo->ri_RelationDesc) == relid &&
1442 [ + + ]: 491 : rInfo->ri_RootResultRelInfo == rootRelInfo)
1443 : 20 : return rInfo;
1444 : : }
1445 : :
1446 : : /* Nope, but maybe we already made an extra ResultRelInfo for it */
1447 [ + + + + : 1830 : foreach(l, estate->es_trig_target_relations)
+ + ]
1448 : : {
1449 : 541 : rInfo = (ResultRelInfo *) lfirst(l);
1450 [ + + ]: 541 : if (RelationGetRelid(rInfo->ri_RelationDesc) == relid &&
1451 [ + + ]: 24 : rInfo->ri_RootResultRelInfo == rootRelInfo)
1452 : 12 : return rInfo;
1453 : : }
1454 : : /* Nope, so we need a new one */
1455 : :
1456 : : /*
1457 : : * Open the target relation's relcache entry. We assume that an
1458 : : * appropriate lock is still held by the backend from whenever the trigger
1459 : : * event got queued, so we need take no new lock here. Also, we need not
1460 : : * recheck the relkind, so no need for CheckValidResultRel.
1461 : : */
1462 : 1289 : rel = table_open(relid, NoLock);
1463 : :
1464 : : /*
1465 : : * Make the new entry in the right context.
1466 : : */
1467 : 1289 : oldcontext = MemoryContextSwitchTo(estate->es_query_cxt);
1468 : 1289 : rInfo = makeNode(ResultRelInfo);
1469 : 1289 : InitResultRelInfo(rInfo,
1470 : : rel,
1471 : : 0, /* dummy rangetable index */
1472 : : rootRelInfo,
1473 : : estate->es_instrument);
1474 : 1289 : estate->es_trig_target_relations =
1475 : 1289 : lappend(estate->es_trig_target_relations, rInfo);
1476 : 1289 : MemoryContextSwitchTo(oldcontext);
1477 : :
1478 : : /*
1479 : : * Currently, we don't need any index information in ResultRelInfos used
1480 : : * only for triggers, so no need to call ExecOpenIndices.
1481 : : */
1482 : :
1483 : 1289 : return rInfo;
1484 : : }
1485 : :
1486 : : /*
1487 : : * Return the ancestor relations of a given leaf partition result relation
1488 : : * up to and including the query's root target relation.
1489 : : *
1490 : : * These work much like the ones opened by ExecGetTriggerResultRel, except
1491 : : * that we need to keep them in a separate list.
1492 : : *
1493 : : * These are closed by ExecCloseResultRelations.
1494 : : */
1495 : : List *
1496 : 202 : ExecGetAncestorResultRels(EState *estate, ResultRelInfo *resultRelInfo)
1497 : : {
1498 : 202 : ResultRelInfo *rootRelInfo = resultRelInfo->ri_RootResultRelInfo;
1499 : 202 : Relation partRel = resultRelInfo->ri_RelationDesc;
1500 : : Oid rootRelOid;
1501 : :
1502 [ - + ]: 202 : if (!partRel->rd_rel->relispartition)
1503 [ # # ]: 0 : elog(ERROR, "cannot find ancestors of a non-partition result relation");
1504 : : Assert(rootRelInfo != NULL);
1505 : 202 : rootRelOid = RelationGetRelid(rootRelInfo->ri_RelationDesc);
1506 [ + + ]: 202 : if (resultRelInfo->ri_ancestorResultRels == NIL)
1507 : : {
1508 : : ListCell *lc;
1509 : 158 : List *oids = get_partition_ancestors(RelationGetRelid(partRel));
1510 : 158 : List *ancResultRels = NIL;
1511 : :
1512 [ + - + - : 202 : foreach(lc, oids)
+ - ]
1513 : : {
1514 : 202 : Oid ancOid = lfirst_oid(lc);
1515 : : Relation ancRel;
1516 : : ResultRelInfo *rInfo;
1517 : :
1518 : : /*
1519 : : * Ignore the root ancestor here, and use ri_RootResultRelInfo
1520 : : * (below) for it instead. Also, we stop climbing up the
1521 : : * hierarchy when we find the table that was mentioned in the
1522 : : * query.
1523 : : */
1524 [ + + ]: 202 : if (ancOid == rootRelOid)
1525 : 158 : break;
1526 : :
1527 : : /*
1528 : : * All ancestors up to the root target relation must have been
1529 : : * locked by the planner or AcquireExecutorLocks().
1530 : : */
1531 : 44 : ancRel = table_open(ancOid, NoLock);
1532 : 44 : rInfo = makeNode(ResultRelInfo);
1533 : :
1534 : : /* dummy rangetable index */
1535 : 44 : InitResultRelInfo(rInfo, ancRel, 0, NULL,
1536 : : estate->es_instrument);
1537 : 44 : ancResultRels = lappend(ancResultRels, rInfo);
1538 : : }
1539 : 158 : ancResultRels = lappend(ancResultRels, rootRelInfo);
1540 : 158 : resultRelInfo->ri_ancestorResultRels = ancResultRels;
1541 : : }
1542 : :
1543 : : /* We must have found some ancestor */
1544 : : Assert(resultRelInfo->ri_ancestorResultRels != NIL);
1545 : :
1546 : 202 : return resultRelInfo->ri_ancestorResultRels;
1547 : : }
1548 : :
1549 : : /* ----------------------------------------------------------------
1550 : : * ExecPostprocessPlan
1551 : : *
1552 : : * Give plan nodes a final chance to execute before shutdown
1553 : : * ----------------------------------------------------------------
1554 : : */
1555 : : static void
1556 : 324651 : ExecPostprocessPlan(EState *estate)
1557 : : {
1558 : : ListCell *lc;
1559 : :
1560 : : /*
1561 : : * Make sure nodes run forward.
1562 : : */
1563 : 324651 : estate->es_direction = ForwardScanDirection;
1564 : :
1565 : : /*
1566 : : * Run any secondary ModifyTable nodes to completion, in case the main
1567 : : * query did not fetch all rows from them. (We do this to ensure that
1568 : : * such nodes have predictable results.)
1569 : : */
1570 [ + + + + : 325288 : foreach(lc, estate->es_auxmodifytables)
+ + ]
1571 : : {
1572 : 637 : PlanState *ps = (PlanState *) lfirst(lc);
1573 : :
1574 : : for (;;)
1575 : 100 : {
1576 : : TupleTableSlot *slot;
1577 : :
1578 : : /* Reset the per-output-tuple exprcontext each time */
1579 [ + + ]: 737 : ResetPerTupleExprContext(estate);
1580 : :
1581 : 737 : slot = ExecProcNode(ps);
1582 : :
1583 [ + + + - ]: 737 : if (TupIsNull(slot))
1584 : : break;
1585 : : }
1586 : : }
1587 : 324651 : }
1588 : :
1589 : : /* ----------------------------------------------------------------
1590 : : * ExecEndPlan
1591 : : *
1592 : : * Cleans up the query plan -- closes files and frees up storage
1593 : : *
1594 : : * NOTE: we are no longer very worried about freeing storage per se
1595 : : * in this code; FreeExecutorState should be guaranteed to release all
1596 : : * memory that needs to be released. What we are worried about doing
1597 : : * is closing relations and dropping buffer pins. Thus, for example,
1598 : : * tuple tables must be cleared or dropped to ensure pins are released.
1599 : : * ----------------------------------------------------------------
1600 : : */
1601 : : static void
1602 : 337981 : ExecEndPlan(PlanState *planstate, EState *estate)
1603 : : {
1604 : : ListCell *l;
1605 : :
1606 : : /*
1607 : : * shut down the node-type-specific query processing
1608 : : */
1609 : 337981 : ExecEndNode(planstate);
1610 : :
1611 : : /*
1612 : : * for subplans too
1613 : : */
1614 [ + + + + : 366458 : foreach(l, estate->es_subplanstates)
+ + ]
1615 : : {
1616 : 28478 : PlanState *subplanstate = (PlanState *) lfirst(l);
1617 : :
1618 : 28478 : ExecEndNode(subplanstate);
1619 : : }
1620 : :
1621 : : /*
1622 : : * destroy the executor's tuple table. Actually we only care about
1623 : : * releasing buffer pins and tupdesc refcounts; there's no need to pfree
1624 : : * the TupleTableSlots, since the containing memory context is about to go
1625 : : * away anyway.
1626 : : */
1627 : 337980 : ExecResetTupleTable(estate->es_tupleTable, false);
1628 : :
1629 : : /*
1630 : : * Close any Relations that have been opened for range table entries or
1631 : : * result relations.
1632 : : */
1633 : 337980 : ExecCloseResultRelations(estate);
1634 : 337980 : ExecCloseRangeTableRelations(estate);
1635 : 337980 : }
1636 : :
1637 : : /*
1638 : : * Close any relations that have been opened for ResultRelInfos.
1639 : : */
1640 : : void
1641 : 339251 : ExecCloseResultRelations(EState *estate)
1642 : : {
1643 : : ListCell *l;
1644 : :
1645 : : /*
1646 : : * close indexes of result relation(s) if any. (Rels themselves are
1647 : : * closed in ExecCloseRangeTableRelations())
1648 : : *
1649 : : * In addition, close the stub RTs that may be in each resultrel's
1650 : : * ri_ancestorResultRels.
1651 : : */
1652 [ + + + + : 413048 : foreach(l, estate->es_opened_result_relations)
+ + ]
1653 : : {
1654 : 73797 : ResultRelInfo *resultRelInfo = lfirst(l);
1655 : : ListCell *lc;
1656 : :
1657 : 73797 : ExecCloseIndices(resultRelInfo);
1658 [ + + + + : 73967 : foreach(lc, resultRelInfo->ri_ancestorResultRels)
+ + ]
1659 : : {
1660 : 170 : ResultRelInfo *rInfo = lfirst(lc);
1661 : :
1662 : : /*
1663 : : * Ancestors with RTI > 0 (should only be the root ancestor) are
1664 : : * closed by ExecCloseRangeTableRelations.
1665 : : */
1666 [ + + ]: 170 : if (rInfo->ri_RangeTableIndex > 0)
1667 : 138 : continue;
1668 : :
1669 : 32 : table_close(rInfo->ri_RelationDesc, NoLock);
1670 : : }
1671 : : }
1672 : :
1673 : : /* Close any relations that have been opened by ExecGetTriggerResultRel(). */
1674 [ + + + + : 340173 : foreach(l, estate->es_trig_target_relations)
+ + ]
1675 : : {
1676 : 922 : ResultRelInfo *resultRelInfo = (ResultRelInfo *) lfirst(l);
1677 : :
1678 : : /*
1679 : : * Assert this is a "dummy" ResultRelInfo, see above. Otherwise we
1680 : : * might be issuing a duplicate close against a Relation opened by
1681 : : * ExecGetRangeTableRelation.
1682 : : */
1683 : : Assert(resultRelInfo->ri_RangeTableIndex == 0);
1684 : :
1685 : : /*
1686 : : * Since ExecGetTriggerResultRel doesn't call ExecOpenIndices for
1687 : : * these rels, we needn't call ExecCloseIndices either.
1688 : : */
1689 : : Assert(resultRelInfo->ri_NumIndices == 0);
1690 : :
1691 : 922 : table_close(resultRelInfo->ri_RelationDesc, NoLock);
1692 : : }
1693 : 339251 : }
1694 : :
1695 : : /*
1696 : : * Close all relations opened by ExecGetRangeTableRelation().
1697 : : *
1698 : : * We do not release any locks we might hold on those rels.
1699 : : */
1700 : : void
1701 : 338936 : ExecCloseRangeTableRelations(EState *estate)
1702 : : {
1703 : : int i;
1704 : :
1705 [ + + ]: 1043289 : for (i = 0; i < estate->es_range_table_size; i++)
1706 : : {
1707 [ + + ]: 704353 : if (estate->es_relations[i])
1708 : 347248 : table_close(estate->es_relations[i], NoLock);
1709 : : }
1710 : 338936 : }
1711 : :
1712 : : /* ----------------------------------------------------------------
1713 : : * ExecutePlan
1714 : : *
1715 : : * Processes the query plan until we have retrieved 'numberTuples' tuples,
1716 : : * moving in the specified direction.
1717 : : *
1718 : : * Runs to completion if numberTuples is 0
1719 : : * ----------------------------------------------------------------
1720 : : */
1721 : : static void
1722 : 349067 : ExecutePlan(QueryDesc *queryDesc,
1723 : : CmdType operation,
1724 : : bool sendTuples,
1725 : : uint64 numberTuples,
1726 : : ScanDirection direction,
1727 : : DestReceiver *dest)
1728 : : {
1729 : 349067 : EState *estate = queryDesc->estate;
1730 : 349067 : PlanState *planstate = queryDesc->planstate;
1731 : : bool use_parallel_mode;
1732 : : TupleTableSlot *slot;
1733 : : uint64 current_tuple_count;
1734 : :
1735 : : /*
1736 : : * initialize local variables
1737 : : */
1738 : 349067 : current_tuple_count = 0;
1739 : :
1740 : : /*
1741 : : * Set the direction.
1742 : : */
1743 : 349067 : estate->es_direction = direction;
1744 : :
1745 : : /*
1746 : : * Set up parallel mode if appropriate.
1747 : : *
1748 : : * Parallel mode only supports complete execution of a plan. If we've
1749 : : * already partially executed it, or if the caller asks us to exit early,
1750 : : * we must force the plan to run without parallelism.
1751 : : */
1752 [ + + + + ]: 349067 : if (queryDesc->already_executed || numberTuples != 0)
1753 : 72235 : use_parallel_mode = false;
1754 : : else
1755 : 276832 : use_parallel_mode = queryDesc->plannedstmt->parallelModeNeeded;
1756 : 349067 : queryDesc->already_executed = true;
1757 : :
1758 : 349067 : estate->es_use_parallel_mode = use_parallel_mode;
1759 [ + + ]: 349067 : if (use_parallel_mode)
1760 : 507 : EnterParallelMode();
1761 : :
1762 : : /*
1763 : : * Loop until we've processed the proper number of tuples from the plan.
1764 : : */
1765 : : for (;;)
1766 : : {
1767 : : /* Reset the per-output-tuple exprcontext */
1768 [ + + ]: 8822468 : ResetPerTupleExprContext(estate);
1769 : :
1770 : : /*
1771 : : * Execute the plan and obtain a tuple
1772 : : */
1773 : 8822468 : slot = ExecProcNode(planstate);
1774 : :
1775 : : /*
1776 : : * if the tuple is null, then we assume there is nothing more to
1777 : : * process so we just end the loop...
1778 : : */
1779 [ + + + + ]: 8806917 : if (TupIsNull(slot))
1780 : : break;
1781 : :
1782 : : /*
1783 : : * If we have a junk filter, then project a new tuple with the junk
1784 : : * removed.
1785 : : *
1786 : : * Store this new "clean" tuple in the junkfilter's resultSlot.
1787 : : * (Formerly, we stored it back over the "dirty" tuple, which is WRONG
1788 : : * because that tuple slot has the wrong descriptor.)
1789 : : */
1790 [ + + ]: 8525434 : if (estate->es_junkFilter != NULL)
1791 : 175633 : slot = ExecFilterJunk(estate->es_junkFilter, slot);
1792 : :
1793 : : /*
1794 : : * If we are supposed to send the tuple somewhere, do so. (In
1795 : : * practice, this is probably always the case at this point.)
1796 : : */
1797 [ + - ]: 8525434 : if (sendTuples)
1798 : : {
1799 : : /*
1800 : : * If we are not able to send the tuple, we assume the destination
1801 : : * has closed and no more tuples can be sent. If that's the case,
1802 : : * end the loop.
1803 : : */
1804 [ - + ]: 8525434 : if (!dest->receiveSlot(slot, dest))
1805 : 0 : break;
1806 : : }
1807 : :
1808 : : /*
1809 : : * Count tuples processed, if this is a SELECT. (For other operation
1810 : : * types, the ModifyTable plan node must count the appropriate
1811 : : * events.)
1812 : : */
1813 [ + + ]: 8525426 : if (operation == CMD_SELECT)
1814 : 8520718 : (estate->es_processed)++;
1815 : :
1816 : : /*
1817 : : * check our tuple count.. if we've processed the proper number then
1818 : : * quit, else loop again and process more tuples. Zero numberTuples
1819 : : * means no limit.
1820 : : */
1821 : 8525426 : current_tuple_count++;
1822 [ + + + + ]: 8525426 : if (numberTuples && numberTuples == current_tuple_count)
1823 : 52025 : break;
1824 : : }
1825 : :
1826 : : /*
1827 : : * If we know we won't need to back up, we can release resources at this
1828 : : * point.
1829 : : */
1830 [ + + ]: 333508 : if (!(estate->es_top_eflags & EXEC_FLAG_BACKWARD))
1831 : 329023 : ExecShutdownNode(planstate);
1832 : :
1833 [ + + ]: 333508 : if (use_parallel_mode)
1834 : 499 : ExitParallelMode();
1835 : 333508 : }
1836 : :
1837 : :
1838 : : /*
1839 : : * ExecRelCheck --- check that tuple meets check constraints for result relation
1840 : : *
1841 : : * Returns NULL if OK, else name of failed check constraint
1842 : : */
1843 : : static const char *
1844 : 1863 : ExecRelCheck(ResultRelInfo *resultRelInfo,
1845 : : TupleTableSlot *slot, EState *estate)
1846 : : {
1847 : 1863 : Relation rel = resultRelInfo->ri_RelationDesc;
1848 : 1863 : int ncheck = rel->rd_att->constr->num_check;
1849 : 1863 : ConstrCheck *check = rel->rd_att->constr->check;
1850 : : ExprContext *econtext;
1851 : : MemoryContext oldContext;
1852 : :
1853 : : /*
1854 : : * CheckNNConstraintFetch let this pass with only a warning, but now we
1855 : : * should fail rather than possibly failing to enforce an important
1856 : : * constraint.
1857 : : */
1858 [ - + ]: 1863 : if (ncheck != rel->rd_rel->relchecks)
1859 [ # # ]: 0 : elog(ERROR, "%d pg_constraint record(s) missing for relation \"%s\"",
1860 : : rel->rd_rel->relchecks - ncheck, RelationGetRelationName(rel));
1861 : :
1862 : : /*
1863 : : * If first time through for this result relation, build expression
1864 : : * nodetrees for rel's constraint expressions. Keep them in the per-query
1865 : : * memory context so they'll survive throughout the query.
1866 : : */
1867 [ + + ]: 1863 : if (resultRelInfo->ri_CheckConstraintExprs == NULL)
1868 : : {
1869 : 974 : oldContext = MemoryContextSwitchTo(estate->es_query_cxt);
1870 : 974 : resultRelInfo->ri_CheckConstraintExprs = palloc0_array(ExprState *, ncheck);
1871 [ + + ]: 2545 : for (int i = 0; i < ncheck; i++)
1872 : : {
1873 : : Expr *checkconstr;
1874 : :
1875 : : /* Skip not enforced constraint */
1876 [ + + ]: 1575 : if (!check[i].ccenforced)
1877 : 216 : continue;
1878 : :
1879 : 1359 : checkconstr = stringToNode(check[i].ccbin);
1880 : 1359 : checkconstr = (Expr *) expand_generated_columns_in_expr((Node *) checkconstr, rel, 1);
1881 : 1355 : resultRelInfo->ri_CheckConstraintExprs[i] =
1882 : 1359 : ExecPrepareExpr(checkconstr, estate);
1883 : : }
1884 : 970 : MemoryContextSwitchTo(oldContext);
1885 : : }
1886 : :
1887 : : /*
1888 : : * We will use the EState's per-tuple context for evaluating constraint
1889 : : * expressions (creating it if it's not already there).
1890 : : */
1891 [ + + ]: 1859 : econtext = GetPerTupleExprContext(estate);
1892 : :
1893 : : /* Arrange for econtext's scan tuple to be the tuple under test */
1894 : 1859 : econtext->ecxt_scantuple = slot;
1895 : :
1896 : : /* And evaluate the constraints */
1897 [ + + ]: 4283 : for (int i = 0; i < ncheck; i++)
1898 : : {
1899 : 2756 : ExprState *checkconstr = resultRelInfo->ri_CheckConstraintExprs[i];
1900 : :
1901 : : /*
1902 : : * NOTE: SQL specifies that a NULL result from a constraint expression
1903 : : * is not to be treated as a failure. Therefore, use ExecCheck not
1904 : : * ExecQual.
1905 : : */
1906 [ + + + + ]: 2756 : if (checkconstr && !ExecCheck(checkconstr, econtext))
1907 : 332 : return check[i].ccname;
1908 : : }
1909 : :
1910 : : /* NULL result means no error */
1911 : 1527 : return NULL;
1912 : : }
1913 : :
1914 : : /*
1915 : : * ExecPartitionCheck --- check that tuple meets the partition constraint.
1916 : : *
1917 : : * Returns true if it meets the partition constraint. If the constraint
1918 : : * fails and we're asked to emit an error, do so and don't return; otherwise
1919 : : * return false.
1920 : : */
1921 : : bool
1922 : 8713 : ExecPartitionCheck(ResultRelInfo *resultRelInfo, TupleTableSlot *slot,
1923 : : EState *estate, bool emitError)
1924 : : {
1925 : : ExprContext *econtext;
1926 : : bool success;
1927 : :
1928 : : /*
1929 : : * If first time through, build expression state tree for the partition
1930 : : * check expression. (In the corner case where the partition check
1931 : : * expression is empty, ie there's a default partition and nothing else,
1932 : : * we'll be fooled into executing this code each time through. But it's
1933 : : * pretty darn cheap in that case, so we don't worry about it.)
1934 : : */
1935 [ + + ]: 8713 : if (resultRelInfo->ri_PartitionCheckExpr == NULL)
1936 : : {
1937 : : /*
1938 : : * Ensure that the qual tree and prepared expression are in the
1939 : : * query-lifespan context.
1940 : : */
1941 : 2527 : MemoryContext oldcxt = MemoryContextSwitchTo(estate->es_query_cxt);
1942 : 2527 : List *qual = RelationGetPartitionQual(resultRelInfo->ri_RelationDesc);
1943 : :
1944 : 2527 : resultRelInfo->ri_PartitionCheckExpr = ExecPrepareCheck(qual, estate);
1945 : 2527 : MemoryContextSwitchTo(oldcxt);
1946 : : }
1947 : :
1948 : : /*
1949 : : * We will use the EState's per-tuple context for evaluating constraint
1950 : : * expressions (creating it if it's not already there).
1951 : : */
1952 [ + + ]: 8713 : econtext = GetPerTupleExprContext(estate);
1953 : :
1954 : : /* Arrange for econtext's scan tuple to be the tuple under test */
1955 : 8713 : econtext->ecxt_scantuple = slot;
1956 : :
1957 : : /*
1958 : : * As in case of the cataloged constraints, we treat a NULL result as
1959 : : * success here, not a failure.
1960 : : */
1961 : 8713 : success = ExecCheck(resultRelInfo->ri_PartitionCheckExpr, econtext);
1962 : :
1963 : : /* if asked to emit error, don't actually return on failure */
1964 [ + + + + ]: 8713 : if (!success && emitError)
1965 : 134 : ExecPartitionCheckEmitError(resultRelInfo, slot, estate);
1966 : :
1967 : 8579 : return success;
1968 : : }
1969 : :
1970 : : /*
1971 : : * ExecPartitionCheckEmitError - Form and emit an error message after a failed
1972 : : * partition constraint check.
1973 : : */
1974 : : void
1975 : 166 : ExecPartitionCheckEmitError(ResultRelInfo *resultRelInfo,
1976 : : TupleTableSlot *slot,
1977 : : EState *estate)
1978 : : {
1979 : : Oid root_relid;
1980 : : TupleDesc tupdesc;
1981 : : char *val_desc;
1982 : : Bitmapset *modifiedCols;
1983 : :
1984 : : /*
1985 : : * If the tuple has been routed, it's been converted to the partition's
1986 : : * rowtype, which might differ from the root table's. We must convert it
1987 : : * back to the root table's rowtype so that val_desc in the error message
1988 : : * matches the input tuple.
1989 : : */
1990 [ + + ]: 166 : if (resultRelInfo->ri_RootResultRelInfo)
1991 : : {
1992 : 13 : ResultRelInfo *rootrel = resultRelInfo->ri_RootResultRelInfo;
1993 : : TupleDesc old_tupdesc;
1994 : : AttrMap *map;
1995 : :
1996 : 13 : root_relid = RelationGetRelid(rootrel->ri_RelationDesc);
1997 : 13 : tupdesc = RelationGetDescr(rootrel->ri_RelationDesc);
1998 : :
1999 : 13 : old_tupdesc = RelationGetDescr(resultRelInfo->ri_RelationDesc);
2000 : : /* a reverse map */
2001 : 13 : map = build_attrmap_by_name_if_req(old_tupdesc, tupdesc, false);
2002 : :
2003 : : /*
2004 : : * Partition-specific slot's tupdesc can't be changed, so allocate a
2005 : : * new one.
2006 : : */
2007 [ + + ]: 13 : if (map != NULL)
2008 : 5 : slot = execute_attr_map_slot(map, slot,
2009 : : MakeTupleTableSlot(tupdesc, &TTSOpsVirtual, 0));
2010 : 13 : modifiedCols = bms_union(ExecGetInsertedCols(rootrel, estate),
2011 : 13 : ExecGetUpdatedCols(rootrel, estate));
2012 : : }
2013 : : else
2014 : : {
2015 : 153 : root_relid = RelationGetRelid(resultRelInfo->ri_RelationDesc);
2016 : 153 : tupdesc = RelationGetDescr(resultRelInfo->ri_RelationDesc);
2017 : 153 : modifiedCols = bms_union(ExecGetInsertedCols(resultRelInfo, estate),
2018 : 153 : ExecGetUpdatedCols(resultRelInfo, estate));
2019 : : }
2020 : :
2021 : 166 : val_desc = ExecBuildSlotValueDescription(root_relid,
2022 : : slot,
2023 : : tupdesc,
2024 : : modifiedCols,
2025 : : 64);
2026 [ + - + - ]: 166 : ereport(ERROR,
2027 : : (errcode(ERRCODE_CHECK_VIOLATION),
2028 : : errmsg("new row for relation \"%s\" violates partition constraint",
2029 : : RelationGetRelationName(resultRelInfo->ri_RelationDesc)),
2030 : : val_desc ? errdetail("Failing row contains %s.", val_desc) : 0,
2031 : : errtable(resultRelInfo->ri_RelationDesc)));
2032 : : }
2033 : :
2034 : : /*
2035 : : * ExecConstraints - check constraints of the tuple in 'slot'
2036 : : *
2037 : : * This checks the traditional NOT NULL and check constraints.
2038 : : *
2039 : : * The partition constraint is *NOT* checked.
2040 : : *
2041 : : * Note: 'slot' contains the tuple to check the constraints of, which may
2042 : : * have been converted from the original input tuple after tuple routing.
2043 : : * 'resultRelInfo' is the final result relation, after tuple routing.
2044 : : */
2045 : : void
2046 : 2979020 : ExecConstraints(ResultRelInfo *resultRelInfo,
2047 : : TupleTableSlot *slot, EState *estate)
2048 : : {
2049 : 2979020 : Relation rel = resultRelInfo->ri_RelationDesc;
2050 : 2979020 : TupleDesc tupdesc = RelationGetDescr(rel);
2051 : 2979020 : TupleConstr *constr = tupdesc->constr;
2052 : : Bitmapset *modifiedCols;
2053 : 2979020 : List *notnull_virtual_attrs = NIL;
2054 : :
2055 : : Assert(constr); /* we should not be called otherwise */
2056 : :
2057 : : /*
2058 : : * Verify not-null constraints.
2059 : : *
2060 : : * Not-null constraints on virtual generated columns are collected and
2061 : : * checked separately below.
2062 : : */
2063 [ + + ]: 2979020 : if (constr->has_not_null)
2064 : : {
2065 [ + + ]: 11012640 : for (AttrNumber attnum = 1; attnum <= tupdesc->natts; attnum++)
2066 : : {
2067 : 8038088 : Form_pg_attribute att = TupleDescAttr(tupdesc, attnum - 1);
2068 : :
2069 [ + + + + ]: 8038088 : if (att->attnotnull && att->attgenerated == ATTRIBUTE_GENERATED_VIRTUAL)
2070 : 72 : notnull_virtual_attrs = lappend_int(notnull_virtual_attrs, attnum);
2071 [ + + + + ]: 8038016 : else if (att->attnotnull && slot_attisnull(slot, attnum))
2072 : 229 : ReportNotNullViolationError(resultRelInfo, slot, estate, attnum);
2073 : : }
2074 : : }
2075 : :
2076 : : /*
2077 : : * Verify not-null constraints on virtual generated column, if any.
2078 : : */
2079 [ + + ]: 2978791 : if (notnull_virtual_attrs)
2080 : : {
2081 : : AttrNumber attnum;
2082 : :
2083 : 72 : attnum = ExecRelGenVirtualNotNull(resultRelInfo, slot, estate,
2084 : : notnull_virtual_attrs);
2085 [ + + ]: 72 : if (attnum != InvalidAttrNumber)
2086 : 28 : ReportNotNullViolationError(resultRelInfo, slot, estate, attnum);
2087 : : }
2088 : :
2089 : : /*
2090 : : * Verify check constraints.
2091 : : */
2092 [ + + ]: 2978763 : if (rel->rd_rel->relchecks > 0)
2093 : : {
2094 : : const char *failed;
2095 : :
2096 [ + + ]: 1863 : if ((failed = ExecRelCheck(resultRelInfo, slot, estate)) != NULL)
2097 : : {
2098 : : char *val_desc;
2099 : 332 : Relation orig_rel = rel;
2100 : :
2101 : : /*
2102 : : * If the tuple has been routed, it's been converted to the
2103 : : * partition's rowtype, which might differ from the root table's.
2104 : : * We must convert it back to the root table's rowtype so that
2105 : : * val_desc shown error message matches the input tuple.
2106 : : */
2107 [ + + ]: 332 : if (resultRelInfo->ri_RootResultRelInfo)
2108 : : {
2109 : 68 : ResultRelInfo *rootrel = resultRelInfo->ri_RootResultRelInfo;
2110 : 68 : TupleDesc old_tupdesc = RelationGetDescr(rel);
2111 : : AttrMap *map;
2112 : :
2113 : 68 : tupdesc = RelationGetDescr(rootrel->ri_RelationDesc);
2114 : : /* a reverse map */
2115 : 68 : map = build_attrmap_by_name_if_req(old_tupdesc,
2116 : : tupdesc,
2117 : : false);
2118 : :
2119 : : /*
2120 : : * Partition-specific slot's tupdesc can't be changed, so
2121 : : * allocate a new one.
2122 : : */
2123 [ + + ]: 68 : if (map != NULL)
2124 : 40 : slot = execute_attr_map_slot(map, slot,
2125 : : MakeTupleTableSlot(tupdesc, &TTSOpsVirtual, 0));
2126 : 68 : modifiedCols = bms_union(ExecGetInsertedCols(rootrel, estate),
2127 : 68 : ExecGetUpdatedCols(rootrel, estate));
2128 : 68 : rel = rootrel->ri_RelationDesc;
2129 : : }
2130 : : else
2131 : 264 : modifiedCols = bms_union(ExecGetInsertedCols(resultRelInfo, estate),
2132 : 264 : ExecGetUpdatedCols(resultRelInfo, estate));
2133 : 332 : val_desc = ExecBuildSlotValueDescription(RelationGetRelid(rel),
2134 : : slot,
2135 : : tupdesc,
2136 : : modifiedCols,
2137 : : 64);
2138 [ + - + - ]: 332 : ereport(ERROR,
2139 : : (errcode(ERRCODE_CHECK_VIOLATION),
2140 : : errmsg("new row for relation \"%s\" violates check constraint \"%s\"",
2141 : : RelationGetRelationName(orig_rel), failed),
2142 : : val_desc ? errdetail("Failing row contains %s.", val_desc) : 0,
2143 : : errtableconstraint(orig_rel, failed)));
2144 : : }
2145 : : }
2146 : 2978427 : }
2147 : :
2148 : : /*
2149 : : * Verify not-null constraints on virtual generated columns of the given
2150 : : * tuple slot.
2151 : : *
2152 : : * Return value of InvalidAttrNumber means all not-null constraints on virtual
2153 : : * generated columns are satisfied. A return value > 0 means a not-null
2154 : : * violation happened for that attribute.
2155 : : *
2156 : : * notnull_virtual_attrs is the list of the attnums of virtual generated column with
2157 : : * not-null constraints.
2158 : : */
2159 : : AttrNumber
2160 : 132 : ExecRelGenVirtualNotNull(ResultRelInfo *resultRelInfo, TupleTableSlot *slot,
2161 : : EState *estate, List *notnull_virtual_attrs)
2162 : : {
2163 : 132 : Relation rel = resultRelInfo->ri_RelationDesc;
2164 : : ExprContext *econtext;
2165 : : MemoryContext oldContext;
2166 : :
2167 : : /*
2168 : : * We implement this by building a NullTest node for each virtual
2169 : : * generated column, which we cache in resultRelInfo, and running those
2170 : : * through ExecCheck().
2171 : : */
2172 [ + + ]: 132 : if (resultRelInfo->ri_GenVirtualNotNullConstraintExprs == NULL)
2173 : : {
2174 : 100 : oldContext = MemoryContextSwitchTo(estate->es_query_cxt);
2175 : 100 : resultRelInfo->ri_GenVirtualNotNullConstraintExprs =
2176 : 100 : palloc0_array(ExprState *, list_length(notnull_virtual_attrs));
2177 : :
2178 [ + - + + : 320 : foreach_int(attnum, notnull_virtual_attrs)
+ + ]
2179 : : {
2180 : 120 : int i = foreach_current_index(attnum);
2181 : : NullTest *nnulltest;
2182 : :
2183 : : /* "generated_expression IS NOT NULL" check. */
2184 : 120 : nnulltest = makeNode(NullTest);
2185 : 120 : nnulltest->arg = (Expr *) build_generation_expression(rel, attnum);
2186 : 120 : nnulltest->nulltesttype = IS_NOT_NULL;
2187 : 120 : nnulltest->argisrow = false;
2188 : 120 : nnulltest->location = -1;
2189 : :
2190 : 120 : resultRelInfo->ri_GenVirtualNotNullConstraintExprs[i] =
2191 : 120 : ExecPrepareExpr((Expr *) nnulltest, estate);
2192 : : }
2193 : 100 : MemoryContextSwitchTo(oldContext);
2194 : : }
2195 : :
2196 : : /*
2197 : : * We will use the EState's per-tuple context for evaluating virtual
2198 : : * generated column not null constraint expressions (creating it if it's
2199 : : * not already there).
2200 : : */
2201 [ + + ]: 132 : econtext = GetPerTupleExprContext(estate);
2202 : :
2203 : : /* Arrange for econtext's scan tuple to be the tuple under test */
2204 : 132 : econtext->ecxt_scantuple = slot;
2205 : :
2206 : : /* And evaluate the check constraints for virtual generated column */
2207 [ + - + + : 336 : foreach_int(attnum, notnull_virtual_attrs)
+ + ]
2208 : : {
2209 : 168 : int i = foreach_current_index(attnum);
2210 : 168 : ExprState *exprstate = resultRelInfo->ri_GenVirtualNotNullConstraintExprs[i];
2211 : :
2212 : : Assert(exprstate != NULL);
2213 [ + + ]: 168 : if (!ExecCheck(exprstate, econtext))
2214 : 48 : return attnum;
2215 : : }
2216 : :
2217 : : /* InvalidAttrNumber result means no error */
2218 : 84 : return InvalidAttrNumber;
2219 : : }
2220 : :
2221 : : /*
2222 : : * Report a violation of a not-null constraint that was already detected.
2223 : : */
2224 : : static void
2225 : 257 : ReportNotNullViolationError(ResultRelInfo *resultRelInfo, TupleTableSlot *slot,
2226 : : EState *estate, int attnum)
2227 : : {
2228 : : Bitmapset *modifiedCols;
2229 : : char *val_desc;
2230 : 257 : Relation rel = resultRelInfo->ri_RelationDesc;
2231 : 257 : Relation orig_rel = rel;
2232 : 257 : TupleDesc tupdesc = RelationGetDescr(rel);
2233 : 257 : TupleDesc orig_tupdesc = RelationGetDescr(rel);
2234 : 257 : Form_pg_attribute att = TupleDescAttr(tupdesc, attnum - 1);
2235 : :
2236 : : Assert(attnum > 0);
2237 : :
2238 : : /*
2239 : : * If the tuple has been routed, it's been converted to the partition's
2240 : : * rowtype, which might differ from the root table's. We must convert it
2241 : : * back to the root table's rowtype so that val_desc shown error message
2242 : : * matches the input tuple.
2243 : : */
2244 [ + + ]: 257 : if (resultRelInfo->ri_RootResultRelInfo)
2245 : : {
2246 : 56 : ResultRelInfo *rootrel = resultRelInfo->ri_RootResultRelInfo;
2247 : : AttrMap *map;
2248 : :
2249 : 56 : tupdesc = RelationGetDescr(rootrel->ri_RelationDesc);
2250 : : /* a reverse map */
2251 : 56 : map = build_attrmap_by_name_if_req(orig_tupdesc,
2252 : : tupdesc,
2253 : : false);
2254 : :
2255 : : /*
2256 : : * Partition-specific slot's tupdesc can't be changed, so allocate a
2257 : : * new one.
2258 : : */
2259 [ + + ]: 56 : if (map != NULL)
2260 : 28 : slot = execute_attr_map_slot(map, slot,
2261 : : MakeTupleTableSlot(tupdesc, &TTSOpsVirtual, 0));
2262 : 56 : modifiedCols = bms_union(ExecGetInsertedCols(rootrel, estate),
2263 : 56 : ExecGetUpdatedCols(rootrel, estate));
2264 : 56 : rel = rootrel->ri_RelationDesc;
2265 : : }
2266 : : else
2267 : 201 : modifiedCols = bms_union(ExecGetInsertedCols(resultRelInfo, estate),
2268 : 201 : ExecGetUpdatedCols(resultRelInfo, estate));
2269 : :
2270 : 257 : val_desc = ExecBuildSlotValueDescription(RelationGetRelid(rel),
2271 : : slot,
2272 : : tupdesc,
2273 : : modifiedCols,
2274 : : 64);
2275 [ + - + - ]: 257 : ereport(ERROR,
2276 : : errcode(ERRCODE_NOT_NULL_VIOLATION),
2277 : : errmsg("null value in column \"%s\" of relation \"%s\" violates not-null constraint",
2278 : : NameStr(att->attname),
2279 : : RelationGetRelationName(orig_rel)),
2280 : : val_desc ? errdetail("Failing row contains %s.", val_desc) : 0,
2281 : : errtablecol(orig_rel, attnum));
2282 : : }
2283 : :
2284 : : /*
2285 : : * ExecWithCheckOptions -- check that tuple satisfies any WITH CHECK OPTIONs
2286 : : * of the specified kind.
2287 : : *
2288 : : * Note that this needs to be called multiple times to ensure that all kinds of
2289 : : * WITH CHECK OPTIONs are handled (both those from views which have the WITH
2290 : : * CHECK OPTION set and from row-level security policies). See ExecInsert()
2291 : : * and ExecUpdate().
2292 : : */
2293 : : void
2294 : 1609 : ExecWithCheckOptions(WCOKind kind, ResultRelInfo *resultRelInfo,
2295 : : TupleTableSlot *slot, EState *estate)
2296 : : {
2297 : 1609 : Relation rel = resultRelInfo->ri_RelationDesc;
2298 : 1609 : TupleDesc tupdesc = RelationGetDescr(rel);
2299 : : ExprContext *econtext;
2300 : : ListCell *l1,
2301 : : *l2;
2302 : :
2303 : : /*
2304 : : * We will use the EState's per-tuple context for evaluating constraint
2305 : : * expressions (creating it if it's not already there).
2306 : : */
2307 [ + + ]: 1609 : econtext = GetPerTupleExprContext(estate);
2308 : :
2309 : : /* Arrange for econtext's scan tuple to be the tuple under test */
2310 : 1609 : econtext->ecxt_scantuple = slot;
2311 : :
2312 : : /* Check each of the constraints */
2313 [ + - + + : 4438 : forboth(l1, resultRelInfo->ri_WithCheckOptions,
+ - + + +
+ + - +
+ ]
2314 : : l2, resultRelInfo->ri_WithCheckOptionExprs)
2315 : : {
2316 : 3179 : WithCheckOption *wco = (WithCheckOption *) lfirst(l1);
2317 : 3179 : ExprState *wcoExpr = (ExprState *) lfirst(l2);
2318 : :
2319 : : /*
2320 : : * Skip any WCOs which are not the kind we are looking for at this
2321 : : * time.
2322 : : */
2323 [ + + ]: 3179 : if (wco->kind != kind)
2324 : 1912 : continue;
2325 : :
2326 : : /*
2327 : : * WITH CHECK OPTION checks are intended to ensure that the new tuple
2328 : : * is visible (in the case of a view) or that it passes the
2329 : : * 'with-check' policy (in the case of row security). If the qual
2330 : : * evaluates to NULL or FALSE, then the new tuple won't be included in
2331 : : * the view or doesn't pass the 'with-check' policy for the table.
2332 : : */
2333 [ + + ]: 1267 : if (!ExecQual(wcoExpr, econtext))
2334 : : {
2335 : : char *val_desc;
2336 : : Bitmapset *modifiedCols;
2337 : :
2338 [ + + + + : 350 : switch (wco->kind)
- ]
2339 : : {
2340 : : /*
2341 : : * For WITH CHECK OPTIONs coming from views, we might be
2342 : : * able to provide the details on the row, depending on
2343 : : * the permissions on the relation (that is, if the user
2344 : : * could view it directly anyway). For RLS violations, we
2345 : : * don't include the data since we don't know if the user
2346 : : * should be able to view the tuple as that depends on the
2347 : : * USING policy.
2348 : : */
2349 : 150 : case WCO_VIEW_CHECK:
2350 : : /* See the comment in ExecConstraints(). */
2351 [ + + ]: 150 : if (resultRelInfo->ri_RootResultRelInfo)
2352 : : {
2353 : 27 : ResultRelInfo *rootrel = resultRelInfo->ri_RootResultRelInfo;
2354 : 27 : TupleDesc old_tupdesc = RelationGetDescr(rel);
2355 : : AttrMap *map;
2356 : :
2357 : 27 : tupdesc = RelationGetDescr(rootrel->ri_RelationDesc);
2358 : : /* a reverse map */
2359 : 27 : map = build_attrmap_by_name_if_req(old_tupdesc,
2360 : : tupdesc,
2361 : : false);
2362 : :
2363 : : /*
2364 : : * Partition-specific slot's tupdesc can't be changed,
2365 : : * so allocate a new one.
2366 : : */
2367 [ + + ]: 27 : if (map != NULL)
2368 : 16 : slot = execute_attr_map_slot(map, slot,
2369 : : MakeTupleTableSlot(tupdesc, &TTSOpsVirtual, 0));
2370 : :
2371 : 27 : modifiedCols = bms_union(ExecGetInsertedCols(rootrel, estate),
2372 : 27 : ExecGetUpdatedCols(rootrel, estate));
2373 : 27 : rel = rootrel->ri_RelationDesc;
2374 : : }
2375 : : else
2376 : 123 : modifiedCols = bms_union(ExecGetInsertedCols(resultRelInfo, estate),
2377 : 123 : ExecGetUpdatedCols(resultRelInfo, estate));
2378 : 150 : val_desc = ExecBuildSlotValueDescription(RelationGetRelid(rel),
2379 : : slot,
2380 : : tupdesc,
2381 : : modifiedCols,
2382 : : 64);
2383 : :
2384 [ + - + - ]: 150 : ereport(ERROR,
2385 : : (errcode(ERRCODE_WITH_CHECK_OPTION_VIOLATION),
2386 : : errmsg("new row violates check option for view \"%s\"",
2387 : : wco->relname),
2388 : : val_desc ? errdetail("Failing row contains %s.",
2389 : : val_desc) : 0));
2390 : : break;
2391 : 164 : case WCO_RLS_INSERT_CHECK:
2392 : : case WCO_RLS_UPDATE_CHECK:
2393 [ + + ]: 164 : if (wco->polname != NULL)
2394 [ + - ]: 39 : ereport(ERROR,
2395 : : (errcode(ERRCODE_INSUFFICIENT_PRIVILEGE),
2396 : : errmsg("new row violates row-level security policy \"%s\" for table \"%s\"",
2397 : : wco->polname, wco->relname)));
2398 : : else
2399 [ + - ]: 125 : ereport(ERROR,
2400 : : (errcode(ERRCODE_INSUFFICIENT_PRIVILEGE),
2401 : : errmsg("new row violates row-level security policy for table \"%s\"",
2402 : : wco->relname)));
2403 : : break;
2404 : 16 : case WCO_RLS_MERGE_UPDATE_CHECK:
2405 : : case WCO_RLS_MERGE_DELETE_CHECK:
2406 [ - + ]: 16 : if (wco->polname != NULL)
2407 [ # # ]: 0 : ereport(ERROR,
2408 : : (errcode(ERRCODE_INSUFFICIENT_PRIVILEGE),
2409 : : errmsg("target row violates row-level security policy \"%s\" (USING expression) for table \"%s\"",
2410 : : wco->polname, wco->relname)));
2411 : : else
2412 [ + - ]: 16 : ereport(ERROR,
2413 : : (errcode(ERRCODE_INSUFFICIENT_PRIVILEGE),
2414 : : errmsg("target row violates row-level security policy (USING expression) for table \"%s\"",
2415 : : wco->relname)));
2416 : : break;
2417 : 20 : case WCO_RLS_CONFLICT_CHECK:
2418 [ - + ]: 20 : if (wco->polname != NULL)
2419 [ # # ]: 0 : ereport(ERROR,
2420 : : (errcode(ERRCODE_INSUFFICIENT_PRIVILEGE),
2421 : : errmsg("new row violates row-level security policy \"%s\" (USING expression) for table \"%s\"",
2422 : : wco->polname, wco->relname)));
2423 : : else
2424 [ + - ]: 20 : ereport(ERROR,
2425 : : (errcode(ERRCODE_INSUFFICIENT_PRIVILEGE),
2426 : : errmsg("new row violates row-level security policy (USING expression) for table \"%s\"",
2427 : : wco->relname)));
2428 : : break;
2429 : 0 : default:
2430 [ # # ]: 0 : elog(ERROR, "unrecognized WCO kind: %u", wco->kind);
2431 : : break;
2432 : : }
2433 : : }
2434 : : }
2435 : 1259 : }
2436 : :
2437 : : /*
2438 : : * ExecBuildSlotValueDescription -- construct a string representing a tuple
2439 : : *
2440 : : * This is intentionally very similar to BuildIndexValueDescription, but
2441 : : * unlike that function, we truncate long field values (to at most maxfieldlen
2442 : : * bytes). That seems necessary here since heap field values could be very
2443 : : * long, whereas index entries typically aren't so wide.
2444 : : *
2445 : : * Also, unlike the case with index entries, we need to be prepared to ignore
2446 : : * dropped columns. We used to use the slot's tuple descriptor to decode the
2447 : : * data, but the slot's descriptor doesn't identify dropped columns, so we
2448 : : * now need to be passed the relation's descriptor.
2449 : : *
2450 : : * Note that, like BuildIndexValueDescription, if the user does not have
2451 : : * permission to view any of the columns involved, a NULL is returned. Unlike
2452 : : * BuildIndexValueDescription, if the user has access to view a subset of the
2453 : : * column involved, that subset will be returned with a key identifying which
2454 : : * columns they are.
2455 : : */
2456 : : char *
2457 : 1059 : ExecBuildSlotValueDescription(Oid reloid,
2458 : : TupleTableSlot *slot,
2459 : : TupleDesc tupdesc,
2460 : : Bitmapset *modifiedCols,
2461 : : int maxfieldlen)
2462 : : {
2463 : : StringInfoData buf;
2464 : : StringInfoData collist;
2465 : 1059 : bool write_comma = false;
2466 : 1059 : bool write_comma_collist = false;
2467 : : int i;
2468 : : AclResult aclresult;
2469 : 1059 : bool table_perm = false;
2470 : 1059 : bool any_perm = false;
2471 : :
2472 : : /*
2473 : : * Check if RLS is enabled and should be active for the relation; if so,
2474 : : * then don't return anything. Otherwise, go through normal permission
2475 : : * checks.
2476 : : */
2477 [ - + ]: 1059 : if (check_enable_rls(reloid, InvalidOid, true) == RLS_ENABLED)
2478 : 0 : return NULL;
2479 : :
2480 : 1059 : initStringInfo(&buf);
2481 : :
2482 : 1059 : appendStringInfoChar(&buf, '(');
2483 : :
2484 : : /*
2485 : : * Check if the user has permissions to see the row. Table-level SELECT
2486 : : * allows access to all columns. If the user does not have table-level
2487 : : * SELECT then we check each column and include those the user has SELECT
2488 : : * rights on. Additionally, we always include columns the user provided
2489 : : * data for.
2490 : : */
2491 : 1059 : aclresult = pg_class_aclcheck(reloid, GetUserId(), ACL_SELECT);
2492 [ + + ]: 1059 : if (aclresult != ACLCHECK_OK)
2493 : : {
2494 : : /* Set up the buffer for the column list */
2495 : 40 : initStringInfo(&collist);
2496 : 40 : appendStringInfoChar(&collist, '(');
2497 : : }
2498 : : else
2499 : 1019 : table_perm = any_perm = true;
2500 : :
2501 : : /* Make sure the tuple is fully deconstructed */
2502 : 1059 : slot_getallattrs(slot);
2503 : :
2504 [ + + ]: 3816 : for (i = 0; i < tupdesc->natts; i++)
2505 : : {
2506 : 2757 : bool column_perm = false;
2507 : : char *val;
2508 : : int vallen;
2509 : 2757 : Form_pg_attribute att = TupleDescAttr(tupdesc, i);
2510 : :
2511 : : /* ignore dropped columns */
2512 [ + + ]: 2757 : if (att->attisdropped)
2513 : 25 : continue;
2514 : :
2515 [ + + ]: 2732 : if (!table_perm)
2516 : : {
2517 : : /*
2518 : : * No table-level SELECT, so need to make sure they either have
2519 : : * SELECT rights on the column or that they have provided the data
2520 : : * for the column. If not, omit this column from the error
2521 : : * message.
2522 : : */
2523 : 156 : aclresult = pg_attribute_aclcheck(reloid, att->attnum,
2524 : : GetUserId(), ACL_SELECT);
2525 [ + + ]: 156 : if (bms_is_member(att->attnum - FirstLowInvalidHeapAttributeNumber,
2526 [ + + ]: 92 : modifiedCols) || aclresult == ACLCHECK_OK)
2527 : : {
2528 : 96 : column_perm = any_perm = true;
2529 : :
2530 [ + + ]: 96 : if (write_comma_collist)
2531 : 56 : appendStringInfoString(&collist, ", ");
2532 : : else
2533 : 40 : write_comma_collist = true;
2534 : :
2535 : 96 : appendStringInfoString(&collist, NameStr(att->attname));
2536 : : }
2537 : : }
2538 : :
2539 [ + + + + ]: 2732 : if (table_perm || column_perm)
2540 : : {
2541 [ + + ]: 2672 : if (att->attgenerated == ATTRIBUTE_GENERATED_VIRTUAL)
2542 : 40 : val = "virtual";
2543 [ + + ]: 2632 : else if (slot->tts_isnull[i])
2544 : 440 : val = "null";
2545 : : else
2546 : : {
2547 : : Oid foutoid;
2548 : : bool typisvarlena;
2549 : :
2550 : 2192 : getTypeOutputInfo(att->atttypid,
2551 : : &foutoid, &typisvarlena);
2552 : 2192 : val = OidOutputFunctionCall(foutoid, slot->tts_values[i]);
2553 : : }
2554 : :
2555 [ + + ]: 2672 : if (write_comma)
2556 : 1613 : appendStringInfoString(&buf, ", ");
2557 : : else
2558 : 1059 : write_comma = true;
2559 : :
2560 : : /* truncate if needed */
2561 : 2672 : vallen = strlen(val);
2562 [ + + ]: 2672 : if (vallen <= maxfieldlen)
2563 : 2663 : appendBinaryStringInfo(&buf, val, vallen);
2564 : : else
2565 : : {
2566 : 9 : vallen = pg_mbcliplen(val, vallen, maxfieldlen);
2567 : 9 : appendBinaryStringInfo(&buf, val, vallen);
2568 : 9 : appendStringInfoString(&buf, "...");
2569 : : }
2570 : : }
2571 : : }
2572 : :
2573 : : /* If we end up with zero columns being returned, then return NULL. */
2574 [ - + ]: 1059 : if (!any_perm)
2575 : 0 : return NULL;
2576 : :
2577 : 1059 : appendStringInfoChar(&buf, ')');
2578 : :
2579 [ + + ]: 1059 : if (!table_perm)
2580 : : {
2581 : 40 : appendStringInfoString(&collist, ") = ");
2582 : 40 : appendBinaryStringInfo(&collist, buf.data, buf.len);
2583 : :
2584 : 40 : return collist.data;
2585 : : }
2586 : :
2587 : 1019 : return buf.data;
2588 : : }
2589 : :
2590 : :
2591 : : /*
2592 : : * ExecUpdateLockMode -- find the appropriate UPDATE tuple lock mode for a
2593 : : * given ResultRelInfo
2594 : : */
2595 : : LockTupleMode
2596 : 4375 : ExecUpdateLockMode(EState *estate, ResultRelInfo *relinfo)
2597 : : {
2598 : : Bitmapset *keyCols;
2599 : : Bitmapset *updatedCols;
2600 : :
2601 : : /*
2602 : : * Compute lock mode to use. If columns that are part of the key have not
2603 : : * been modified, then we can use a weaker lock, allowing for better
2604 : : * concurrency.
2605 : : */
2606 : 4375 : updatedCols = ExecGetAllUpdatedCols(relinfo, estate);
2607 : 4375 : keyCols = RelationGetIndexAttrBitmap(relinfo->ri_RelationDesc,
2608 : : INDEX_ATTR_BITMAP_KEY);
2609 : :
2610 [ + + ]: 4375 : if (bms_overlap(keyCols, updatedCols))
2611 : 179 : return LockTupleExclusive;
2612 : :
2613 : 4196 : return LockTupleNoKeyExclusive;
2614 : : }
2615 : :
2616 : : /*
2617 : : * ExecFindRowMark -- find the ExecRowMark struct for given rangetable index
2618 : : *
2619 : : * If no such struct, either return NULL or throw error depending on missing_ok
2620 : : */
2621 : : ExecRowMark *
2622 : 8258 : ExecFindRowMark(EState *estate, Index rti, bool missing_ok)
2623 : : {
2624 [ + - + - ]: 8258 : if (rti > 0 && rti <= estate->es_range_table_size &&
2625 [ + - ]: 8258 : estate->es_rowmarks != NULL)
2626 : : {
2627 : 8258 : ExecRowMark *erm = estate->es_rowmarks[rti - 1];
2628 : :
2629 [ + - ]: 8258 : if (erm)
2630 : 8258 : return erm;
2631 : : }
2632 [ # # ]: 0 : if (!missing_ok)
2633 [ # # ]: 0 : elog(ERROR, "failed to find ExecRowMark for rangetable index %u", rti);
2634 : 0 : return NULL;
2635 : : }
2636 : :
2637 : : /*
2638 : : * ExecBuildAuxRowMark -- create an ExecAuxRowMark struct
2639 : : *
2640 : : * Inputs are the underlying ExecRowMark struct and the targetlist of the
2641 : : * input plan node (not planstate node!). We need the latter to find out
2642 : : * the column numbers of the resjunk columns.
2643 : : */
2644 : : ExecAuxRowMark *
2645 : 8258 : ExecBuildAuxRowMark(ExecRowMark *erm, List *targetlist)
2646 : : {
2647 : 8258 : ExecAuxRowMark *aerm = palloc0_object(ExecAuxRowMark);
2648 : : char resname[32];
2649 : :
2650 : 8258 : aerm->rowmark = erm;
2651 : :
2652 : : /* Look up the resjunk columns associated with this rowmark */
2653 [ + + ]: 8258 : if (erm->markType != ROW_MARK_COPY)
2654 : : {
2655 : : /* need ctid for all methods other than COPY */
2656 : 7791 : snprintf(resname, sizeof(resname), "ctid%u", erm->rowmarkId);
2657 : 7791 : aerm->ctidAttNo = ExecFindJunkAttributeInTlist(targetlist,
2658 : : resname);
2659 [ - + ]: 7791 : if (!AttributeNumberIsValid(aerm->ctidAttNo))
2660 [ # # ]: 0 : elog(ERROR, "could not find junk %s column", resname);
2661 : : }
2662 : : else
2663 : : {
2664 : : /* need wholerow if COPY */
2665 : 467 : snprintf(resname, sizeof(resname), "wholerow%u", erm->rowmarkId);
2666 : 467 : aerm->wholeAttNo = ExecFindJunkAttributeInTlist(targetlist,
2667 : : resname);
2668 [ - + ]: 467 : if (!AttributeNumberIsValid(aerm->wholeAttNo))
2669 [ # # ]: 0 : elog(ERROR, "could not find junk %s column", resname);
2670 : : }
2671 : :
2672 : : /* if child rel, need tableoid */
2673 [ + + ]: 8258 : if (erm->rti != erm->prti)
2674 : : {
2675 : 1308 : snprintf(resname, sizeof(resname), "tableoid%u", erm->rowmarkId);
2676 : 1308 : aerm->toidAttNo = ExecFindJunkAttributeInTlist(targetlist,
2677 : : resname);
2678 [ - + ]: 1308 : if (!AttributeNumberIsValid(aerm->toidAttNo))
2679 [ # # ]: 0 : elog(ERROR, "could not find junk %s column", resname);
2680 : : }
2681 : :
2682 : 8258 : return aerm;
2683 : : }
2684 : :
2685 : :
2686 : : /*
2687 : : * EvalPlanQual logic --- recheck modified tuple(s) to see if we want to
2688 : : * process the updated version under READ COMMITTED rules.
2689 : : *
2690 : : * See backend/executor/README for some info about how this works.
2691 : : */
2692 : :
2693 : :
2694 : : /*
2695 : : * Check the updated version of a tuple to see if we want to process it under
2696 : : * READ COMMITTED rules.
2697 : : *
2698 : : * epqstate - state for EvalPlanQual rechecking
2699 : : * relation - table containing tuple
2700 : : * rti - rangetable index of table containing tuple
2701 : : * inputslot - tuple for processing - this can be the slot from
2702 : : * EvalPlanQualSlot() for this rel, for increased efficiency.
2703 : : *
2704 : : * This tests whether the tuple in inputslot still matches the relevant
2705 : : * quals. For that result to be useful, typically the input tuple has to be
2706 : : * last row version (otherwise the result isn't particularly useful) and
2707 : : * locked (otherwise the result might be out of date). That's typically
2708 : : * achieved by using table_tuple_lock() with the
2709 : : * TUPLE_LOCK_FLAG_FIND_LAST_VERSION flag.
2710 : : *
2711 : : * Returns a slot containing the new candidate update/delete tuple, or
2712 : : * NULL if we determine we shouldn't process the row.
2713 : : */
2714 : : TupleTableSlot *
2715 : 151 : EvalPlanQual(EPQState *epqstate, Relation relation,
2716 : : Index rti, TupleTableSlot *inputslot)
2717 : : {
2718 : : TupleTableSlot *slot;
2719 : : TupleTableSlot *testslot;
2720 : :
2721 : : Assert(rti > 0);
2722 : :
2723 : : /*
2724 : : * Need to run a recheck subquery. Initialize or reinitialize EPQ state.
2725 : : */
2726 : 151 : EvalPlanQualBegin(epqstate);
2727 : :
2728 : : /*
2729 : : * Callers will often use the EvalPlanQualSlot to store the tuple to avoid
2730 : : * an unnecessary copy.
2731 : : */
2732 : 151 : testslot = EvalPlanQualSlot(epqstate, relation, rti);
2733 [ + + ]: 151 : if (testslot != inputslot)
2734 : 6 : ExecCopySlot(testslot, inputslot);
2735 : :
2736 : : /*
2737 : : * Mark that an EPQ tuple is available for this relation. (If there is
2738 : : * more than one result relation, the others remain marked as having no
2739 : : * tuple available.)
2740 : : */
2741 : 151 : epqstate->relsubs_done[rti - 1] = false;
2742 : 151 : epqstate->relsubs_blocked[rti - 1] = false;
2743 : :
2744 : : /*
2745 : : * Run the EPQ query. We assume it will return at most one tuple.
2746 : : */
2747 : 151 : slot = EvalPlanQualNext(epqstate);
2748 : :
2749 : : /*
2750 : : * If we got a tuple, force the slot to materialize the tuple so that it
2751 : : * is not dependent on any local state in the EPQ query (in particular,
2752 : : * it's highly likely that the slot contains references to any pass-by-ref
2753 : : * datums that may be present in copyTuple). As with the next step, this
2754 : : * is to guard against early re-use of the EPQ query.
2755 : : */
2756 [ + + + + ]: 151 : if (!TupIsNull(slot))
2757 : 113 : ExecMaterializeSlot(slot);
2758 : :
2759 : : /*
2760 : : * Clear out the test tuple, and mark that no tuple is available here.
2761 : : * This is needed in case the EPQ state is re-used to test a tuple for a
2762 : : * different target relation.
2763 : : */
2764 : 151 : ExecClearTuple(testslot);
2765 : 151 : epqstate->relsubs_blocked[rti - 1] = true;
2766 : :
2767 : 151 : return slot;
2768 : : }
2769 : :
2770 : : /*
2771 : : * EvalPlanQualInit -- initialize during creation of a plan state node
2772 : : * that might need to invoke EPQ processing.
2773 : : *
2774 : : * If the caller intends to use EvalPlanQual(), resultRelations should be
2775 : : * a list of RT indexes of potential target relations for EvalPlanQual(),
2776 : : * and we will arrange that the other listed relations don't return any
2777 : : * tuple during an EvalPlanQual() call. Otherwise resultRelations
2778 : : * should be NIL.
2779 : : *
2780 : : * Note: subplan/auxrowmarks can be NULL/NIL if they will be set later
2781 : : * with EvalPlanQualSetPlan.
2782 : : */
2783 : : void
2784 : 151624 : EvalPlanQualInit(EPQState *epqstate, EState *parentestate,
2785 : : Plan *subplan, List *auxrowmarks,
2786 : : int epqParam, List *resultRelations)
2787 : : {
2788 : 151624 : Index rtsize = parentestate->es_range_table_size;
2789 : :
2790 : : /* initialize data not changing over EPQState's lifetime */
2791 : 151624 : epqstate->parentestate = parentestate;
2792 : 151624 : epqstate->epqParam = epqParam;
2793 : 151624 : epqstate->resultRelations = resultRelations;
2794 : :
2795 : : /*
2796 : : * Allocate space to reference a slot for each potential rti - do so now
2797 : : * rather than in EvalPlanQualBegin(), as done for other dynamically
2798 : : * allocated resources, so EvalPlanQualSlot() can be used to hold tuples
2799 : : * that *may* need EPQ later, without forcing the overhead of
2800 : : * EvalPlanQualBegin().
2801 : : */
2802 : 151624 : epqstate->tuple_table = NIL;
2803 : 151624 : epqstate->relsubs_slot = palloc0_array(TupleTableSlot *, rtsize);
2804 : :
2805 : : /* ... and remember data that EvalPlanQualBegin will need */
2806 : 151624 : epqstate->plan = subplan;
2807 : 151624 : epqstate->arowMarks = auxrowmarks;
2808 : :
2809 : : /* ... and mark the EPQ state inactive */
2810 : 151624 : epqstate->origslot = NULL;
2811 : 151624 : epqstate->recheckestate = NULL;
2812 : 151624 : epqstate->recheckplanstate = NULL;
2813 : 151624 : epqstate->relsubs_rowmark = NULL;
2814 : 151624 : epqstate->relsubs_done = NULL;
2815 : 151624 : epqstate->relsubs_blocked = NULL;
2816 : 151624 : }
2817 : :
2818 : : /*
2819 : : * EvalPlanQualSetPlan -- set or change subplan of an EPQState.
2820 : : *
2821 : : * We used to need this so that ModifyTable could deal with multiple subplans.
2822 : : * It could now be refactored out of existence.
2823 : : */
2824 : : void
2825 : 72941 : EvalPlanQualSetPlan(EPQState *epqstate, Plan *subplan, List *auxrowmarks)
2826 : : {
2827 : : /* If we have a live EPQ query, shut it down */
2828 : 72941 : EvalPlanQualEnd(epqstate);
2829 : : /* And set/change the plan pointer */
2830 : 72941 : epqstate->plan = subplan;
2831 : : /* The rowmarks depend on the plan, too */
2832 : 72941 : epqstate->arowMarks = auxrowmarks;
2833 : 72941 : }
2834 : :
2835 : : /*
2836 : : * Return, and create if necessary, a slot for an EPQ test tuple.
2837 : : *
2838 : : * Note this only requires EvalPlanQualInit() to have been called,
2839 : : * EvalPlanQualBegin() is not necessary.
2840 : : */
2841 : : TupleTableSlot *
2842 : 81509 : EvalPlanQualSlot(EPQState *epqstate,
2843 : : Relation relation, Index rti)
2844 : : {
2845 : : TupleTableSlot **slot;
2846 : :
2847 : : Assert(relation);
2848 : : Assert(rti > 0 && rti <= epqstate->parentestate->es_range_table_size);
2849 : 81509 : slot = &epqstate->relsubs_slot[rti - 1];
2850 : :
2851 [ + + ]: 81509 : if (*slot == NULL)
2852 : : {
2853 : : MemoryContext oldcontext;
2854 : :
2855 : 4967 : oldcontext = MemoryContextSwitchTo(epqstate->parentestate->es_query_cxt);
2856 : 4967 : *slot = table_slot_create(relation, &epqstate->tuple_table);
2857 : 4967 : MemoryContextSwitchTo(oldcontext);
2858 : : }
2859 : :
2860 : 81509 : return *slot;
2861 : : }
2862 : :
2863 : : /*
2864 : : * Fetch the current row value for a non-locked relation, identified by rti,
2865 : : * that needs to be scanned by an EvalPlanQual operation. origslot must have
2866 : : * been set to contain the current result row (top-level row) that we need to
2867 : : * recheck. Returns true if a substitution tuple was found, false if not.
2868 : : */
2869 : : bool
2870 : 22 : EvalPlanQualFetchRowMark(EPQState *epqstate, Index rti, TupleTableSlot *slot)
2871 : : {
2872 : 22 : ExecAuxRowMark *earm = epqstate->relsubs_rowmark[rti - 1];
2873 : : ExecRowMark *erm;
2874 : : Datum datum;
2875 : : bool isNull;
2876 : :
2877 : : Assert(earm != NULL);
2878 : : Assert(epqstate->origslot != NULL);
2879 : :
2880 : 22 : erm = earm->rowmark;
2881 : :
2882 [ - + ]: 22 : if (RowMarkRequiresRowShareLock(erm->markType))
2883 [ # # ]: 0 : elog(ERROR, "EvalPlanQual doesn't support locking rowmarks");
2884 : :
2885 : : /* if child rel, must check whether it produced this row */
2886 [ - + ]: 22 : if (erm->rti != erm->prti)
2887 : : {
2888 : : Oid tableoid;
2889 : :
2890 : 0 : datum = ExecGetJunkAttribute(epqstate->origslot,
2891 : 0 : earm->toidAttNo,
2892 : : &isNull);
2893 : : /* non-locked rels could be on the inside of outer joins */
2894 [ # # ]: 0 : if (isNull)
2895 : 0 : return false;
2896 : :
2897 : 0 : tableoid = DatumGetObjectId(datum);
2898 : :
2899 : : Assert(OidIsValid(erm->relid));
2900 [ # # ]: 0 : if (tableoid != erm->relid)
2901 : : {
2902 : : /* this child is inactive right now */
2903 : 0 : return false;
2904 : : }
2905 : : }
2906 : :
2907 [ + + ]: 22 : if (erm->markType == ROW_MARK_REFERENCE)
2908 : : {
2909 : : Assert(erm->relation != NULL);
2910 : :
2911 : : /* fetch the tuple's ctid */
2912 : 13 : datum = ExecGetJunkAttribute(epqstate->origslot,
2913 : 13 : earm->ctidAttNo,
2914 : : &isNull);
2915 : : /* non-locked rels could be on the inside of outer joins */
2916 [ - + ]: 13 : if (isNull)
2917 : 0 : return false;
2918 : :
2919 : : /* fetch requests on foreign tables must be passed to their FDW */
2920 [ - + ]: 13 : if (erm->relation->rd_rel->relkind == RELKIND_FOREIGN_TABLE)
2921 : : {
2922 : : FdwRoutine *fdwroutine;
2923 : 0 : bool updated = false;
2924 : :
2925 : 0 : fdwroutine = GetFdwRoutineForRelation(erm->relation, false);
2926 : : /* this should have been checked already, but let's be safe */
2927 [ # # ]: 0 : if (fdwroutine->RefetchForeignRow == NULL)
2928 [ # # ]: 0 : ereport(ERROR,
2929 : : (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
2930 : : errmsg("cannot lock rows in foreign table \"%s\"",
2931 : : RelationGetRelationName(erm->relation))));
2932 : :
2933 : 0 : fdwroutine->RefetchForeignRow(epqstate->recheckestate,
2934 : : erm,
2935 : : datum,
2936 : : slot,
2937 : : &updated);
2938 [ # # # # ]: 0 : if (TupIsNull(slot))
2939 [ # # ]: 0 : elog(ERROR, "failed to fetch tuple for EvalPlanQual recheck");
2940 : :
2941 : : /*
2942 : : * Ideally we'd insist on updated == false here, but that assumes
2943 : : * that FDWs can track that exactly, which they might not be able
2944 : : * to. So just ignore the flag.
2945 : : */
2946 : 0 : return true;
2947 : : }
2948 : : else
2949 : : {
2950 : : /* ordinary table, fetch the tuple */
2951 [ - + ]: 13 : if (!table_tuple_fetch_row_version(erm->relation,
2952 : 13 : (ItemPointer) DatumGetPointer(datum),
2953 : : SnapshotAny, slot))
2954 [ # # ]: 0 : elog(ERROR, "failed to fetch tuple for EvalPlanQual recheck");
2955 : 13 : return true;
2956 : : }
2957 : : }
2958 : : else
2959 : : {
2960 : : Assert(erm->markType == ROW_MARK_COPY);
2961 : :
2962 : : /* fetch the whole-row Var for the relation */
2963 : 9 : datum = ExecGetJunkAttribute(epqstate->origslot,
2964 : 9 : earm->wholeAttNo,
2965 : : &isNull);
2966 : : /* non-locked rels could be on the inside of outer joins */
2967 [ - + ]: 9 : if (isNull)
2968 : 0 : return false;
2969 : :
2970 : 9 : ExecStoreHeapTupleDatum(datum, slot);
2971 : 9 : return true;
2972 : : }
2973 : : }
2974 : :
2975 : : /*
2976 : : * Fetch the next row (if any) from EvalPlanQual testing
2977 : : *
2978 : : * (In practice, there should never be more than one row...)
2979 : : */
2980 : : TupleTableSlot *
2981 : 191 : EvalPlanQualNext(EPQState *epqstate)
2982 : : {
2983 : : MemoryContext oldcontext;
2984 : : TupleTableSlot *slot;
2985 : :
2986 : 191 : oldcontext = MemoryContextSwitchTo(epqstate->recheckestate->es_query_cxt);
2987 : 191 : slot = ExecProcNode(epqstate->recheckplanstate);
2988 : 191 : MemoryContextSwitchTo(oldcontext);
2989 : :
2990 : 191 : return slot;
2991 : : }
2992 : :
2993 : : /*
2994 : : * Initialize or reset an EvalPlanQual state tree
2995 : : */
2996 : : void
2997 : 228 : EvalPlanQualBegin(EPQState *epqstate)
2998 : : {
2999 : 228 : EState *parentestate = epqstate->parentestate;
3000 : 228 : EState *recheckestate = epqstate->recheckestate;
3001 : :
3002 [ + + ]: 228 : if (recheckestate == NULL)
3003 : : {
3004 : : /* First time through, so create a child EState */
3005 : 146 : EvalPlanQualStart(epqstate, epqstate->plan);
3006 : : }
3007 : : else
3008 : : {
3009 : : /*
3010 : : * We already have a suitable child EPQ tree, so just reset it.
3011 : : */
3012 : 82 : Index rtsize = parentestate->es_range_table_size;
3013 : 82 : PlanState *rcplanstate = epqstate->recheckplanstate;
3014 : :
3015 : : /*
3016 : : * Reset the relsubs_done[] flags to equal relsubs_blocked[], so that
3017 : : * the EPQ run will never attempt to fetch tuples from blocked target
3018 : : * relations.
3019 : : */
3020 : 82 : memcpy(epqstate->relsubs_done, epqstate->relsubs_blocked,
3021 : : rtsize * sizeof(bool));
3022 : :
3023 : : /* Recopy current values of parent parameters */
3024 [ + - ]: 82 : if (parentestate->es_plannedstmt->paramExecTypes != NIL)
3025 : : {
3026 : : int i;
3027 : :
3028 : : /*
3029 : : * Force evaluation of any InitPlan outputs that could be needed
3030 : : * by the subplan, just in case they got reset since
3031 : : * EvalPlanQualStart (see comments therein).
3032 : : */
3033 : 82 : ExecSetParamPlanMulti(rcplanstate->plan->extParam,
3034 [ + - ]: 82 : GetPerTupleExprContext(parentestate));
3035 : :
3036 : 82 : i = list_length(parentestate->es_plannedstmt->paramExecTypes);
3037 : :
3038 [ + + ]: 175 : while (--i >= 0)
3039 : : {
3040 : : /* copy value if any, but not execPlan link */
3041 : 93 : recheckestate->es_param_exec_vals[i].value =
3042 : 93 : parentestate->es_param_exec_vals[i].value;
3043 : 93 : recheckestate->es_param_exec_vals[i].isnull =
3044 : 93 : parentestate->es_param_exec_vals[i].isnull;
3045 : : }
3046 : : }
3047 : :
3048 : : /*
3049 : : * Mark child plan tree as needing rescan at all scan nodes. The
3050 : : * first ExecProcNode will take care of actually doing the rescan.
3051 : : */
3052 : 82 : rcplanstate->chgParam = bms_add_member(rcplanstate->chgParam,
3053 : : epqstate->epqParam);
3054 : : }
3055 : 228 : }
3056 : :
3057 : : /*
3058 : : * Start execution of an EvalPlanQual plan tree.
3059 : : *
3060 : : * This is a cut-down version of ExecutorStart(): we copy some state from
3061 : : * the top-level estate rather than initializing it fresh.
3062 : : */
3063 : : static void
3064 : 146 : EvalPlanQualStart(EPQState *epqstate, Plan *planTree)
3065 : : {
3066 : 146 : EState *parentestate = epqstate->parentestate;
3067 : 146 : Index rtsize = parentestate->es_range_table_size;
3068 : : EState *rcestate;
3069 : : MemoryContext oldcontext;
3070 : : ListCell *l;
3071 : :
3072 : 146 : epqstate->recheckestate = rcestate = CreateExecutorState();
3073 : :
3074 : 146 : oldcontext = MemoryContextSwitchTo(rcestate->es_query_cxt);
3075 : :
3076 : : /* signal that this is an EState for executing EPQ */
3077 : 146 : rcestate->es_epq_active = epqstate;
3078 : :
3079 : : /*
3080 : : * Child EPQ EStates share the parent's copy of unchanging state such as
3081 : : * the snapshot, rangetable, and external Param info. They need their own
3082 : : * copies of local state, including a tuple table, es_param_exec_vals,
3083 : : * result-rel info, etc.
3084 : : */
3085 : 146 : rcestate->es_direction = ForwardScanDirection;
3086 : 146 : rcestate->es_snapshot = parentestate->es_snapshot;
3087 : 146 : rcestate->es_crosscheck_snapshot = parentestate->es_crosscheck_snapshot;
3088 : 146 : rcestate->es_range_table = parentestate->es_range_table;
3089 : 146 : rcestate->es_range_table_size = parentestate->es_range_table_size;
3090 : 146 : rcestate->es_relations = parentestate->es_relations;
3091 : 146 : rcestate->es_rowmarks = parentestate->es_rowmarks;
3092 : 146 : rcestate->es_rteperminfos = parentestate->es_rteperminfos;
3093 : 146 : rcestate->es_plannedstmt = parentestate->es_plannedstmt;
3094 : 146 : rcestate->es_junkFilter = parentestate->es_junkFilter;
3095 : 146 : rcestate->es_output_cid = parentestate->es_output_cid;
3096 : 146 : rcestate->es_queryEnv = parentestate->es_queryEnv;
3097 : :
3098 : : /*
3099 : : * ResultRelInfos needed by subplans are initialized from scratch when the
3100 : : * subplans themselves are initialized.
3101 : : */
3102 : 146 : rcestate->es_result_relations = NULL;
3103 : : /* es_trig_target_relations must NOT be copied */
3104 : 146 : rcestate->es_top_eflags = parentestate->es_top_eflags;
3105 : 146 : rcestate->es_instrument = parentestate->es_instrument;
3106 : : /* es_auxmodifytables must NOT be copied */
3107 : :
3108 : : /*
3109 : : * The external param list is simply shared from parent. The internal
3110 : : * param workspace has to be local state, but we copy the initial values
3111 : : * from the parent, so as to have access to any param values that were
3112 : : * already set from other parts of the parent's plan tree.
3113 : : */
3114 : 146 : rcestate->es_param_list_info = parentestate->es_param_list_info;
3115 [ + - ]: 146 : if (parentestate->es_plannedstmt->paramExecTypes != NIL)
3116 : : {
3117 : : int i;
3118 : :
3119 : : /*
3120 : : * Force evaluation of any InitPlan outputs that could be needed by
3121 : : * the subplan. (With more complexity, maybe we could postpone this
3122 : : * till the subplan actually demands them, but it doesn't seem worth
3123 : : * the trouble; this is a corner case already, since usually the
3124 : : * InitPlans would have been evaluated before reaching EvalPlanQual.)
3125 : : *
3126 : : * This will not touch output params of InitPlans that occur somewhere
3127 : : * within the subplan tree, only those that are attached to the
3128 : : * ModifyTable node or above it and are referenced within the subplan.
3129 : : * That's OK though, because the planner would only attach such
3130 : : * InitPlans to a lower-level SubqueryScan node, and EPQ execution
3131 : : * will not descend into a SubqueryScan.
3132 : : *
3133 : : * The EState's per-output-tuple econtext is sufficiently short-lived
3134 : : * for this, since it should get reset before there is any chance of
3135 : : * doing EvalPlanQual again.
3136 : : */
3137 : 146 : ExecSetParamPlanMulti(planTree->extParam,
3138 [ + + ]: 146 : GetPerTupleExprContext(parentestate));
3139 : :
3140 : : /* now make the internal param workspace ... */
3141 : 146 : i = list_length(parentestate->es_plannedstmt->paramExecTypes);
3142 : 146 : rcestate->es_param_exec_vals = palloc0_array(ParamExecData, i);
3143 : : /* ... and copy down all values, whether really needed or not */
3144 [ + + ]: 347 : while (--i >= 0)
3145 : : {
3146 : : /* copy value if any, but not execPlan link */
3147 : 201 : rcestate->es_param_exec_vals[i].value =
3148 : 201 : parentestate->es_param_exec_vals[i].value;
3149 : 201 : rcestate->es_param_exec_vals[i].isnull =
3150 : 201 : parentestate->es_param_exec_vals[i].isnull;
3151 : : }
3152 : : }
3153 : :
3154 : : /*
3155 : : * Copy es_unpruned_relids so that pruned relations are ignored by
3156 : : * ExecInitLockRows() and ExecInitModifyTable() when initializing the plan
3157 : : * trees below.
3158 : : */
3159 : 146 : rcestate->es_unpruned_relids = parentestate->es_unpruned_relids;
3160 : :
3161 : : /*
3162 : : * Also make the PartitionPruneInfo and the results of pruning available.
3163 : : * These need to match exactly so that we initialize all the same Append
3164 : : * and MergeAppend subplans as the parent did.
3165 : : */
3166 : 146 : rcestate->es_part_prune_infos = parentestate->es_part_prune_infos;
3167 : 146 : rcestate->es_part_prune_states = parentestate->es_part_prune_states;
3168 : 146 : rcestate->es_part_prune_results = parentestate->es_part_prune_results;
3169 : :
3170 : : /* We'll also borrow the es_partition_directory from the parent state */
3171 : 146 : rcestate->es_partition_directory = parentestate->es_partition_directory;
3172 : :
3173 : : /*
3174 : : * Initialize private state information for each SubPlan. We must do this
3175 : : * before running ExecInitNode on the main query tree, since
3176 : : * ExecInitSubPlan expects to be able to find these entries. Some of the
3177 : : * SubPlans might not be used in the part of the plan tree we intend to
3178 : : * run, but since it's not easy to tell which, we just initialize them
3179 : : * all.
3180 : : */
3181 : : Assert(rcestate->es_subplanstates == NIL);
3182 [ + + + + : 178 : foreach(l, parentestate->es_plannedstmt->subplans)
+ + ]
3183 : : {
3184 : 32 : Plan *subplan = (Plan *) lfirst(l);
3185 : : PlanState *subplanstate;
3186 : :
3187 : 32 : subplanstate = ExecInitNode(subplan, rcestate, 0);
3188 : 32 : rcestate->es_subplanstates = lappend(rcestate->es_subplanstates,
3189 : : subplanstate);
3190 : : }
3191 : :
3192 : : /*
3193 : : * Build an RTI indexed array of rowmarks, so that
3194 : : * EvalPlanQualFetchRowMark() can efficiently access the to be fetched
3195 : : * rowmark.
3196 : : */
3197 : 146 : epqstate->relsubs_rowmark = palloc0_array(ExecAuxRowMark *, rtsize);
3198 [ + + + + : 163 : foreach(l, epqstate->arowMarks)
+ + ]
3199 : : {
3200 : 17 : ExecAuxRowMark *earm = (ExecAuxRowMark *) lfirst(l);
3201 : :
3202 : 17 : epqstate->relsubs_rowmark[earm->rowmark->rti - 1] = earm;
3203 : : }
3204 : :
3205 : : /*
3206 : : * Initialize per-relation EPQ tuple states. Result relations, if any,
3207 : : * get marked as blocked; others as not-fetched.
3208 : : */
3209 : 146 : epqstate->relsubs_done = palloc_array(bool, rtsize);
3210 : 146 : epqstate->relsubs_blocked = palloc0_array(bool, rtsize);
3211 : :
3212 [ + + + + : 286 : foreach(l, epqstate->resultRelations)
+ + ]
3213 : : {
3214 : 140 : int rtindex = lfirst_int(l);
3215 : :
3216 : : Assert(rtindex > 0 && rtindex <= rtsize);
3217 : 140 : epqstate->relsubs_blocked[rtindex - 1] = true;
3218 : : }
3219 : :
3220 : 146 : memcpy(epqstate->relsubs_done, epqstate->relsubs_blocked,
3221 : : rtsize * sizeof(bool));
3222 : :
3223 : : /*
3224 : : * Initialize the private state information for all the nodes in the part
3225 : : * of the plan tree we need to run. This opens files, allocates storage
3226 : : * and leaves us ready to start processing tuples.
3227 : : */
3228 : 146 : epqstate->recheckplanstate = ExecInitNode(planTree, rcestate, 0);
3229 : :
3230 : 146 : MemoryContextSwitchTo(oldcontext);
3231 : 146 : }
3232 : :
3233 : : /*
3234 : : * EvalPlanQualEnd -- shut down at termination of parent plan state node,
3235 : : * or if we are done with the current EPQ child.
3236 : : *
3237 : : * This is a cut-down version of ExecutorEnd(); basically we want to do most
3238 : : * of the normal cleanup, but *not* close result relations (which we are
3239 : : * just sharing from the outer query). We do, however, have to close any
3240 : : * result and trigger target relations that got opened, since those are not
3241 : : * shared. (There probably shouldn't be any of the latter, but just in
3242 : : * case...)
3243 : : */
3244 : : void
3245 : 225872 : EvalPlanQualEnd(EPQState *epqstate)
3246 : : {
3247 : 225872 : EState *estate = epqstate->recheckestate;
3248 : : Index rtsize;
3249 : : MemoryContext oldcontext;
3250 : : ListCell *l;
3251 : :
3252 : 225872 : rtsize = epqstate->parentestate->es_range_table_size;
3253 : :
3254 : : /*
3255 : : * We may have a tuple table, even if EPQ wasn't started, because we allow
3256 : : * use of EvalPlanQualSlot() without calling EvalPlanQualBegin().
3257 : : */
3258 [ + + ]: 225872 : if (epqstate->tuple_table != NIL)
3259 : : {
3260 : 4808 : memset(epqstate->relsubs_slot, 0,
3261 : : rtsize * sizeof(TupleTableSlot *));
3262 : 4808 : ExecResetTupleTable(epqstate->tuple_table, true);
3263 : 4808 : epqstate->tuple_table = NIL;
3264 : : }
3265 : :
3266 : : /* EPQ wasn't started, nothing further to do */
3267 [ + + ]: 225872 : if (estate == NULL)
3268 : 225734 : return;
3269 : :
3270 : 138 : oldcontext = MemoryContextSwitchTo(estate->es_query_cxt);
3271 : :
3272 : 138 : ExecEndNode(epqstate->recheckplanstate);
3273 : :
3274 [ + + + + : 167 : foreach(l, estate->es_subplanstates)
+ + ]
3275 : : {
3276 : 29 : PlanState *subplanstate = (PlanState *) lfirst(l);
3277 : :
3278 : 29 : ExecEndNode(subplanstate);
3279 : : }
3280 : :
3281 : : /* throw away the per-estate tuple table, some node may have used it */
3282 : 138 : ExecResetTupleTable(estate->es_tupleTable, false);
3283 : :
3284 : : /* Close any result and trigger target relations attached to this EState */
3285 : 138 : ExecCloseResultRelations(estate);
3286 : :
3287 : 138 : MemoryContextSwitchTo(oldcontext);
3288 : :
3289 : : /*
3290 : : * NULLify the partition directory before freeing the executor state.
3291 : : * Since EvalPlanQualStart() just borrowed the parent EState's directory,
3292 : : * we'd better leave it up to the parent to delete it.
3293 : : */
3294 : 138 : estate->es_partition_directory = NULL;
3295 : :
3296 : 138 : FreeExecutorState(estate);
3297 : :
3298 : : /* Mark EPQState idle */
3299 : 138 : epqstate->origslot = NULL;
3300 : 138 : epqstate->recheckestate = NULL;
3301 : 138 : epqstate->recheckplanstate = NULL;
3302 : 138 : epqstate->relsubs_rowmark = NULL;
3303 : 138 : epqstate->relsubs_done = NULL;
3304 : 138 : epqstate->relsubs_blocked = NULL;
3305 : : }
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