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plannodes.h
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1/*-------------------------------------------------------------------------
2 *
3 * plannodes.h
4 * definitions for query plan nodes
5 *
6 *
7 * Portions Copyright (c) 1996-2025, PostgreSQL Global Development Group
8 * Portions Copyright (c) 1994, Regents of the University of California
9 *
10 * src/include/nodes/plannodes.h
11 *
12 *-------------------------------------------------------------------------
13 */
14#ifndef PLANNODES_H
15#define PLANNODES_H
16
17#include "access/sdir.h"
18#include "access/stratnum.h"
19#include "common/relpath.h"
20#include "lib/stringinfo.h"
21#include "nodes/bitmapset.h"
22#include "nodes/lockoptions.h"
23#include "nodes/primnodes.h"
24
25
26/* ----------------------------------------------------------------
27 * node definitions
28 * ----------------------------------------------------------------
29 */
30
31/* ----------------
32 * PlannedStmt node
33 *
34 * The output of the planner is a Plan tree headed by a PlannedStmt node.
35 * PlannedStmt holds the "one time" information needed by the executor.
36 *
37 * For simplicity in APIs, we also wrap utility statements in PlannedStmt
38 * nodes; in such cases, commandType == CMD_UTILITY, the statement itself
39 * is in the utilityStmt field, and the rest of the struct is mostly dummy.
40 * (We do use canSetTag, stmt_location, stmt_len, and possibly queryId.)
41 *
42 * PlannedStmt, as well as all varieties of Plan, do not support equal(),
43 * not because it's not sensible but because we currently have no need.
44 * ----------------
45 */
46typedef struct PlannedStmt
47{
48 pg_node_attr(no_equal, no_query_jumble)
49
51
52 CmdType commandType; /* select|insert|update|delete|merge|utility */
53
54 uint64 queryId; /* query identifier (copied from Query) */
55
56 bool hasReturning; /* is it insert|update|delete|merge RETURNING? */
57
58 bool hasModifyingCTE; /* has insert|update|delete|merge in WITH? */
59
60 bool canSetTag; /* do I set the command result tag? */
61
62 bool transientPlan; /* redo plan when TransactionXmin changes? */
63
64 bool dependsOnRole; /* is plan specific to current role? */
65
66 bool parallelModeNeeded; /* parallel mode required to execute? */
67
68 int jitFlags; /* which forms of JIT should be performed */
69
70 struct Plan *planTree; /* tree of Plan nodes */
71
72 List *rtable; /* list of RangeTblEntry nodes */
73
74 List *permInfos; /* list of RTEPermissionInfo nodes for rtable
75 * entries needing one */
76
77 /* rtable indexes of target relations for INSERT/UPDATE/DELETE/MERGE */
78 List *resultRelations; /* integer list of RT indexes, or NIL */
79
80 List *appendRelations; /* list of AppendRelInfo nodes */
81
82 List *subplans; /* Plan trees for SubPlan expressions; note
83 * that some could be NULL */
84
85 Bitmapset *rewindPlanIDs; /* indices of subplans that require REWIND */
86
87 List *rowMarks; /* a list of PlanRowMark's */
88
89 List *relationOids; /* OIDs of relations the plan depends on */
90
91 List *invalItems; /* other dependencies, as PlanInvalItems */
92
93 List *paramExecTypes; /* type OIDs for PARAM_EXEC Params */
94
95 Node *utilityStmt; /* non-null if this is utility stmt */
96
97 /* statement location in source string (copied from Query) */
98 ParseLoc stmt_location; /* start location, or -1 if unknown */
99 ParseLoc stmt_len; /* length in bytes; 0 means "rest of string" */
101
102/* macro for fetching the Plan associated with a SubPlan node */
103#define exec_subplan_get_plan(plannedstmt, subplan) \
104 ((Plan *) list_nth((plannedstmt)->subplans, (subplan)->plan_id - 1))
105
106
107/* ----------------
108 * Plan node
109 *
110 * All plan nodes "derive" from the Plan structure by having the
111 * Plan structure as the first field. This ensures that everything works
112 * when nodes are cast to Plan's. (node pointers are frequently cast to Plan*
113 * when passed around generically in the executor)
114 *
115 * We never actually instantiate any Plan nodes; this is just the common
116 * abstract superclass for all Plan-type nodes.
117 * ----------------
118 */
119typedef struct Plan
120{
121 pg_node_attr(abstract, no_equal, no_query_jumble)
122
124
125 /*
126 * estimated execution costs for plan (see costsize.c for more info)
127 */
128 int disabled_nodes; /* count of disabled nodes */
129 Cost startup_cost; /* cost expended before fetching any tuples */
130 Cost total_cost; /* total cost (assuming all tuples fetched) */
131
132 /*
133 * planner's estimate of result size of this plan step
134 */
135 Cardinality plan_rows; /* number of rows plan is expected to emit */
136 int plan_width; /* average row width in bytes */
137
138 /*
139 * information needed for parallel query
140 */
141 bool parallel_aware; /* engage parallel-aware logic? */
142 bool parallel_safe; /* OK to use as part of parallel plan? */
143
144 /*
145 * information needed for asynchronous execution
146 */
147 bool async_capable; /* engage asynchronous-capable logic? */
148
149 /*
150 * Common structural data for all Plan types.
151 */
152 int plan_node_id; /* unique across entire final plan tree */
153 List *targetlist; /* target list to be computed at this node */
154 List *qual; /* implicitly-ANDed qual conditions */
155 struct Plan *lefttree; /* input plan tree(s) */
157 List *initPlan; /* Init Plan nodes (un-correlated expr
158 * subselects) */
159
160 /*
161 * Information for management of parameter-change-driven rescanning
162 *
163 * extParam includes the paramIDs of all external PARAM_EXEC params
164 * affecting this plan node or its children. setParam params from the
165 * node's initPlans are not included, but their extParams are.
166 *
167 * allParam includes all the extParam paramIDs, plus the IDs of local
168 * params that affect the node (i.e., the setParams of its initplans).
169 * These are _all_ the PARAM_EXEC params that affect this node.
170 */
174
175/* ----------------
176 * these are defined to avoid confusion problems with "left"
177 * and "right" and "inner" and "outer". The convention is that
178 * the "left" plan is the "outer" plan and the "right" plan is
179 * the inner plan, but these make the code more readable.
180 * ----------------
181 */
182#define innerPlan(node) (((Plan *)(node))->righttree)
183#define outerPlan(node) (((Plan *)(node))->lefttree)
184
185
186/* ----------------
187 * Result node -
188 * If no outer plan, evaluate a variable-free targetlist.
189 * If outer plan, return tuples from outer plan (after a level of
190 * projection as shown by targetlist).
191 *
192 * If resconstantqual isn't NULL, it represents a one-time qualification
193 * test (i.e., one that doesn't depend on any variables from the outer plan,
194 * so needs to be evaluated only once).
195 * ----------------
196 */
197typedef struct Result
198{
202
203/* ----------------
204 * ProjectSet node -
205 * Apply a projection that includes set-returning functions to the
206 * output tuples of the outer plan.
207 * ----------------
208 */
209typedef struct ProjectSet
210{
213
214/* ----------------
215 * ModifyTable node -
216 * Apply rows produced by outer plan to result table(s),
217 * by inserting, updating, or deleting.
218 *
219 * If the originally named target table is a partitioned table or inheritance
220 * tree, both nominalRelation and rootRelation contain the RT index of the
221 * partition root or appendrel RTE, which is not otherwise mentioned in the
222 * plan. Otherwise rootRelation is zero. However, nominalRelation will
223 * always be set, as it's the rel that EXPLAIN should claim is the
224 * INSERT/UPDATE/DELETE/MERGE target.
225 *
226 * Note that rowMarks and epqParam are presumed to be valid for all the
227 * table(s); they can't contain any info that varies across tables.
228 * ----------------
229 */
230typedef struct ModifyTable
231{
233 CmdType operation; /* INSERT, UPDATE, DELETE, or MERGE */
234 bool canSetTag; /* do we set the command tag/es_processed? */
235 Index nominalRelation; /* Parent RT index for use of EXPLAIN */
236 Index rootRelation; /* Root RT index, if partitioned/inherited */
237 bool partColsUpdated; /* some part key in hierarchy updated? */
238 List *resultRelations; /* integer list of RT indexes */
239 List *updateColnosLists; /* per-target-table update_colnos lists */
240 List *withCheckOptionLists; /* per-target-table WCO lists */
241 char *returningOldAlias; /* alias for OLD in RETURNING lists */
242 char *returningNewAlias; /* alias for NEW in RETURNING lists */
243 List *returningLists; /* per-target-table RETURNING tlists */
244 List *fdwPrivLists; /* per-target-table FDW private data lists */
245 Bitmapset *fdwDirectModifyPlans; /* indices of FDW DM plans */
246 List *rowMarks; /* PlanRowMarks (non-locking only) */
247 int epqParam; /* ID of Param for EvalPlanQual re-eval */
248 OnConflictAction onConflictAction; /* ON CONFLICT action */
249 List *arbiterIndexes; /* List of ON CONFLICT arbiter index OIDs */
250 List *onConflictSet; /* INSERT ON CONFLICT DO UPDATE targetlist */
251 List *onConflictCols; /* target column numbers for onConflictSet */
252 Node *onConflictWhere; /* WHERE for ON CONFLICT UPDATE */
253 Index exclRelRTI; /* RTI of the EXCLUDED pseudo relation */
254 List *exclRelTlist; /* tlist of the EXCLUDED pseudo relation */
255 List *mergeActionLists; /* per-target-table lists of actions for
256 * MERGE */
257 List *mergeJoinConditions; /* per-target-table join conditions
258 * for MERGE */
260
261struct PartitionPruneInfo; /* forward reference to struct below */
262
263/* ----------------
264 * Append node -
265 * Generate the concatenation of the results of sub-plans.
266 * ----------------
267 */
268typedef struct Append
269{
271 Bitmapset *apprelids; /* RTIs of appendrel(s) formed by this node */
273 int nasyncplans; /* # of asynchronous plans */
274
275 /*
276 * All 'appendplans' preceding this index are non-partial plans. All
277 * 'appendplans' from this index onwards are partial plans.
278 */
280
281 /* Info for run-time subplan pruning; NULL if we're not doing that */
284
285/* ----------------
286 * MergeAppend node -
287 * Merge the results of pre-sorted sub-plans to preserve the ordering.
288 * ----------------
289 */
290typedef struct MergeAppend
291{
293
294 /* RTIs of appendrel(s) formed by this node */
296
298
299 /* these fields are just like the sort-key info in struct Sort: */
300
301 /* number of sort-key columns */
303
304 /* their indexes in the target list */
305 AttrNumber *sortColIdx pg_node_attr(array_size(numCols));
306
307 /* OIDs of operators to sort them by */
308 Oid *sortOperators pg_node_attr(array_size(numCols));
309
310 /* OIDs of collations */
311 Oid *collations pg_node_attr(array_size(numCols));
312
313 /* NULLS FIRST/LAST directions */
314 bool *nullsFirst pg_node_attr(array_size(numCols));
315
316 /* Info for run-time subplan pruning; NULL if we're not doing that */
319
320/* ----------------
321 * RecursiveUnion node -
322 * Generate a recursive union of two subplans.
323 *
324 * The "outer" subplan is always the non-recursive term, and the "inner"
325 * subplan is the recursive term.
326 * ----------------
327 */
328typedef struct RecursiveUnion
329{
331
332 /* ID of Param representing work table */
334
335 /* Remaining fields are zero/null in UNION ALL case */
336
337 /* number of columns to check for duplicate-ness */
339
340 /* their indexes in the target list */
341 AttrNumber *dupColIdx pg_node_attr(array_size(numCols));
342
343 /* equality operators to compare with */
344 Oid *dupOperators pg_node_attr(array_size(numCols));
345 Oid *dupCollations pg_node_attr(array_size(numCols));
346
347 /* estimated number of groups in input */
350
351/* ----------------
352 * BitmapAnd node -
353 * Generate the intersection of the results of sub-plans.
354 *
355 * The subplans must be of types that yield tuple bitmaps. The targetlist
356 * and qual fields of the plan are unused and are always NIL.
357 * ----------------
358 */
359typedef struct BitmapAnd
360{
364
365/* ----------------
366 * BitmapOr node -
367 * Generate the union of the results of sub-plans.
368 *
369 * The subplans must be of types that yield tuple bitmaps. The targetlist
370 * and qual fields of the plan are unused and are always NIL.
371 * ----------------
372 */
373typedef struct BitmapOr
374{
379
380/*
381 * ==========
382 * Scan nodes
383 *
384 * Scan is an abstract type that all relation scan plan types inherit from.
385 * ==========
386 */
387typedef struct Scan
388{
389 pg_node_attr(abstract)
390
391 Plan plan;
392 Index scanrelid; /* relid is index into the range table */
394
395/* ----------------
396 * sequential scan node
397 * ----------------
398 */
399typedef struct SeqScan
400{
403
404/* ----------------
405 * table sample scan node
406 * ----------------
407 */
408typedef struct SampleScan
409{
411 /* use struct pointer to avoid including parsenodes.h here */
414
415/* ----------------
416 * index scan node
417 *
418 * indexqualorig is an implicitly-ANDed list of index qual expressions, each
419 * in the same form it appeared in the query WHERE condition. Each should
420 * be of the form (indexkey OP comparisonval) or (comparisonval OP indexkey).
421 * The indexkey is a Var or expression referencing column(s) of the index's
422 * base table. The comparisonval might be any expression, but it won't use
423 * any columns of the base table. The expressions are ordered by index
424 * column position (but items referencing the same index column can appear
425 * in any order). indexqualorig is used at runtime only if we have to recheck
426 * a lossy indexqual.
427 *
428 * indexqual has the same form, but the expressions have been commuted if
429 * necessary to put the indexkeys on the left, and the indexkeys are replaced
430 * by Var nodes identifying the index columns (their varno is INDEX_VAR and
431 * their varattno is the index column number).
432 *
433 * indexorderbyorig is similarly the original form of any ORDER BY expressions
434 * that are being implemented by the index, while indexorderby is modified to
435 * have index column Vars on the left-hand side. Here, multiple expressions
436 * must appear in exactly the ORDER BY order, and this is not necessarily the
437 * index column order. Only the expressions are provided, not the auxiliary
438 * sort-order information from the ORDER BY SortGroupClauses; it's assumed
439 * that the sort ordering is fully determinable from the top-level operators.
440 * indexorderbyorig is used at runtime to recheck the ordering, if the index
441 * cannot calculate an accurate ordering. It is also needed for EXPLAIN.
442 *
443 * indexorderbyops is a list of the OIDs of the operators used to sort the
444 * ORDER BY expressions. This is used together with indexorderbyorig to
445 * recheck ordering at run time. (Note that indexorderby, indexorderbyorig,
446 * and indexorderbyops are used for amcanorderbyop cases, not amcanorder.)
447 *
448 * indexorderdir specifies the scan ordering, for indexscans on amcanorder
449 * indexes (for other indexes it should be "don't care").
450 * ----------------
451 */
452typedef struct IndexScan
453{
455 Oid indexid; /* OID of index to scan */
456 List *indexqual; /* list of index quals (usually OpExprs) */
457 List *indexqualorig; /* the same in original form */
458 List *indexorderby; /* list of index ORDER BY exprs */
459 List *indexorderbyorig; /* the same in original form */
460 List *indexorderbyops; /* OIDs of sort ops for ORDER BY exprs */
461 ScanDirection indexorderdir; /* forward or backward or don't care */
463
464/* ----------------
465 * index-only scan node
466 *
467 * IndexOnlyScan is very similar to IndexScan, but it specifies an
468 * index-only scan, in which the data comes from the index not the heap.
469 * Because of this, *all* Vars in the plan node's targetlist, qual, and
470 * index expressions reference index columns and have varno = INDEX_VAR.
471 *
472 * We could almost use indexqual directly against the index's output tuple
473 * when rechecking lossy index operators, but that won't work for quals on
474 * index columns that are not retrievable. Hence, recheckqual is needed
475 * for rechecks: it expresses the same condition as indexqual, but using
476 * only index columns that are retrievable. (We will not generate an
477 * index-only scan if this is not possible. An example is that if an
478 * index has table column "x" in a retrievable index column "ind1", plus
479 * an expression f(x) in a non-retrievable column "ind2", an indexable
480 * query on f(x) will use "ind2" in indexqual and f(ind1) in recheckqual.
481 * Without the "ind1" column, an index-only scan would be disallowed.)
482 *
483 * We don't currently need a recheckable equivalent of indexorderby,
484 * because we don't support lossy operators in index ORDER BY.
485 *
486 * To help EXPLAIN interpret the index Vars for display, we provide
487 * indextlist, which represents the contents of the index as a targetlist
488 * with one TLE per index column. Vars appearing in this list reference
489 * the base table, and this is the only field in the plan node that may
490 * contain such Vars. Also, for the convenience of setrefs.c, TLEs in
491 * indextlist are marked as resjunk if they correspond to columns that
492 * the index AM cannot reconstruct.
493 * ----------------
494 */
495typedef struct IndexOnlyScan
496{
498 Oid indexid; /* OID of index to scan */
499 List *indexqual; /* list of index quals (usually OpExprs) */
500 List *recheckqual; /* index quals in recheckable form */
501 List *indexorderby; /* list of index ORDER BY exprs */
502 List *indextlist; /* TargetEntry list describing index's cols */
503 ScanDirection indexorderdir; /* forward or backward or don't care */
505
506/* ----------------
507 * bitmap index scan node
508 *
509 * BitmapIndexScan delivers a bitmap of potential tuple locations;
510 * it does not access the heap itself. The bitmap is used by an
511 * ancestor BitmapHeapScan node, possibly after passing through
512 * intermediate BitmapAnd and/or BitmapOr nodes to combine it with
513 * the results of other BitmapIndexScans.
514 *
515 * The fields have the same meanings as for IndexScan, except we don't
516 * store a direction flag because direction is uninteresting.
517 *
518 * In a BitmapIndexScan plan node, the targetlist and qual fields are
519 * not used and are always NIL. The indexqualorig field is unused at
520 * run time too, but is saved for the benefit of EXPLAIN.
521 * ----------------
522 */
523typedef struct BitmapIndexScan
524{
526 Oid indexid; /* OID of index to scan */
527 bool isshared; /* Create shared bitmap if set */
528 List *indexqual; /* list of index quals (OpExprs) */
529 List *indexqualorig; /* the same in original form */
531
532/* ----------------
533 * bitmap sequential scan node
534 *
535 * This needs a copy of the qual conditions being used by the input index
536 * scans because there are various cases where we need to recheck the quals;
537 * for example, when the bitmap is lossy about the specific rows on a page
538 * that meet the index condition.
539 * ----------------
540 */
541typedef struct BitmapHeapScan
542{
544 List *bitmapqualorig; /* index quals, in standard expr form */
546
547/* ----------------
548 * tid scan node
549 *
550 * tidquals is an implicitly OR'ed list of qual expressions of the form
551 * "CTID = pseudoconstant", or "CTID = ANY(pseudoconstant_array)",
552 * or a CurrentOfExpr for the relation.
553 * ----------------
554 */
555typedef struct TidScan
556{
558 List *tidquals; /* qual(s) involving CTID = something */
560
561/* ----------------
562 * tid range scan node
563 *
564 * tidrangequals is an implicitly AND'ed list of qual expressions of the form
565 * "CTID relop pseudoconstant", where relop is one of >,>=,<,<=.
566 * ----------------
567 */
568typedef struct TidRangeScan
569{
571 List *tidrangequals; /* qual(s) involving CTID op something */
573
574/* ----------------
575 * subquery scan node
576 *
577 * SubqueryScan is for scanning the output of a sub-query in the range table.
578 * We often need an extra plan node above the sub-query's plan to perform
579 * expression evaluations (which we can't push into the sub-query without
580 * risking changing its semantics). Although we are not scanning a physical
581 * relation, we make this a descendant of Scan anyway for code-sharing
582 * purposes.
583 *
584 * SubqueryScanStatus caches the trivial_subqueryscan property of the node.
585 * SUBQUERY_SCAN_UNKNOWN means not yet determined. This is only used during
586 * planning.
587 *
588 * Note: we store the sub-plan in the type-specific subplan field, not in
589 * the generic lefttree field as you might expect. This is because we do
590 * not want plan-tree-traversal routines to recurse into the subplan without
591 * knowing that they are changing Query contexts.
592 * ----------------
593 */
595{
600
601typedef struct SubqueryScan
602{
607
608/* ----------------
609 * FunctionScan node
610 * ----------------
611 */
612typedef struct FunctionScan
613{
615 List *functions; /* list of RangeTblFunction nodes */
616 bool funcordinality; /* WITH ORDINALITY */
618
619/* ----------------
620 * ValuesScan node
621 * ----------------
622 */
623typedef struct ValuesScan
624{
626 List *values_lists; /* list of expression lists */
628
629/* ----------------
630 * TableFunc scan node
631 * ----------------
632 */
633typedef struct TableFuncScan
634{
636 TableFunc *tablefunc; /* table function node */
638
639/* ----------------
640 * CteScan node
641 * ----------------
642 */
643typedef struct CteScan
644{
646 int ctePlanId; /* ID of init SubPlan for CTE */
647 int cteParam; /* ID of Param representing CTE output */
649
650/* ----------------
651 * NamedTuplestoreScan node
652 * ----------------
653 */
655{
657 char *enrname; /* Name given to Ephemeral Named Relation */
659
660/* ----------------
661 * WorkTableScan node
662 * ----------------
663 */
664typedef struct WorkTableScan
665{
667 int wtParam; /* ID of Param representing work table */
669
670/* ----------------
671 * ForeignScan node
672 *
673 * fdw_exprs and fdw_private are both under the control of the foreign-data
674 * wrapper, but fdw_exprs is presumed to contain expression trees and will
675 * be post-processed accordingly by the planner; fdw_private won't be.
676 * Note that everything in both lists must be copiable by copyObject().
677 * One way to store an arbitrary blob of bytes is to represent it as a bytea
678 * Const. Usually, though, you'll be better off choosing a representation
679 * that can be dumped usefully by nodeToString().
680 *
681 * fdw_scan_tlist is a targetlist describing the contents of the scan tuple
682 * returned by the FDW; it can be NIL if the scan tuple matches the declared
683 * rowtype of the foreign table, which is the normal case for a simple foreign
684 * table scan. (If the plan node represents a foreign join, fdw_scan_tlist
685 * is required since there is no rowtype available from the system catalogs.)
686 * When fdw_scan_tlist is provided, Vars in the node's tlist and quals must
687 * have varno INDEX_VAR, and their varattnos correspond to resnos in the
688 * fdw_scan_tlist (which are also column numbers in the actual scan tuple).
689 * fdw_scan_tlist is never actually executed; it just holds expression trees
690 * describing what is in the scan tuple's columns.
691 *
692 * fdw_recheck_quals should contain any quals which the core system passed to
693 * the FDW but which were not added to scan.plan.qual; that is, it should
694 * contain the quals being checked remotely. This is needed for correct
695 * behavior during EvalPlanQual rechecks.
696 *
697 * When the plan node represents a foreign join, scan.scanrelid is zero and
698 * fs_relids must be consulted to identify the join relation. (fs_relids
699 * is valid for simple scans as well, but will always match scan.scanrelid.)
700 * fs_relids includes outer joins; fs_base_relids does not.
701 *
702 * If the FDW's PlanDirectModify() callback decides to repurpose a ForeignScan
703 * node to perform the UPDATE or DELETE operation directly in the remote
704 * server, it sets 'operation' and 'resultRelation' to identify the operation
705 * type and target relation. Note that these fields are only set if the
706 * modification is performed *fully* remotely; otherwise, the modification is
707 * driven by a local ModifyTable node and 'operation' is left to CMD_SELECT.
708 * ----------------
709 */
710typedef struct ForeignScan
711{
713 CmdType operation; /* SELECT/INSERT/UPDATE/DELETE */
714 Index resultRelation; /* direct modification target's RT index */
715 Oid checkAsUser; /* user to perform the scan as; 0 means to
716 * check as current user */
717 Oid fs_server; /* OID of foreign server */
718 List *fdw_exprs; /* expressions that FDW may evaluate */
719 List *fdw_private; /* private data for FDW */
720 List *fdw_scan_tlist; /* optional tlist describing scan tuple */
721 List *fdw_recheck_quals; /* original quals not in scan.plan.qual */
722 Bitmapset *fs_relids; /* base+OJ RTIs generated by this scan */
723 Bitmapset *fs_base_relids; /* base RTIs generated by this scan */
724 bool fsSystemCol; /* true if any "system column" is needed */
726
727/* ----------------
728 * CustomScan node
729 *
730 * The comments for ForeignScan's fdw_exprs, fdw_private, fdw_scan_tlist,
731 * and fs_relids fields apply equally to CustomScan's custom_exprs,
732 * custom_private, custom_scan_tlist, and custom_relids fields. The
733 * convention of setting scan.scanrelid to zero for joins applies as well.
734 *
735 * Note that since Plan trees can be copied, custom scan providers *must*
736 * fit all plan data they need into those fields; embedding CustomScan in
737 * a larger struct will not work.
738 * ----------------
739 */
740struct CustomScanMethods;
741
742typedef struct CustomScan
743{
745 uint32 flags; /* mask of CUSTOMPATH_* flags, see
746 * nodes/extensible.h */
747 List *custom_plans; /* list of Plan nodes, if any */
748 List *custom_exprs; /* expressions that custom code may evaluate */
749 List *custom_private; /* private data for custom code */
750 List *custom_scan_tlist; /* optional tlist describing scan tuple */
751 Bitmapset *custom_relids; /* RTIs generated by this scan */
752
753 /*
754 * NOTE: The method field of CustomScan is required to be a pointer to a
755 * static table of callback functions. So we don't copy the table itself,
756 * just reference the original one.
757 */
760
761/*
762 * ==========
763 * Join nodes
764 * ==========
765 */
766
767/* ----------------
768 * Join node
769 *
770 * jointype: rule for joining tuples from left and right subtrees
771 * inner_unique each outer tuple can match to no more than one inner tuple
772 * joinqual: qual conditions that came from JOIN/ON or JOIN/USING
773 * (plan.qual contains conditions that came from WHERE)
774 *
775 * When jointype is INNER, joinqual and plan.qual are semantically
776 * interchangeable. For OUTER jointypes, the two are *not* interchangeable;
777 * only joinqual is used to determine whether a match has been found for
778 * the purpose of deciding whether to generate null-extended tuples.
779 * (But plan.qual is still applied before actually returning a tuple.)
780 * For an outer join, only joinquals are allowed to be used as the merge
781 * or hash condition of a merge or hash join.
782 *
783 * inner_unique is set if the joinquals are such that no more than one inner
784 * tuple could match any given outer tuple. This allows the executor to
785 * skip searching for additional matches. (This must be provable from just
786 * the joinquals, ignoring plan.qual, due to where the executor tests it.)
787 * ----------------
788 */
789typedef struct Join
790{
791 pg_node_attr(abstract)
792
793 Plan plan;
796 List *joinqual; /* JOIN quals (in addition to plan.qual) */
798
799/* ----------------
800 * nest loop join node
801 *
802 * The nestParams list identifies any executor Params that must be passed
803 * into execution of the inner subplan carrying values from the current row
804 * of the outer subplan. Currently we restrict these values to be simple
805 * Vars, but perhaps someday that'd be worth relaxing. (Note: during plan
806 * creation, the paramval can actually be a PlaceHolderVar expression; but it
807 * must be a Var with varno OUTER_VAR by the time it gets to the executor.)
808 * ----------------
809 */
810typedef struct NestLoop
811{
813 List *nestParams; /* list of NestLoopParam nodes */
815
816typedef struct NestLoopParam
817{
818 pg_node_attr(no_equal, no_query_jumble)
819
821 int paramno; /* number of the PARAM_EXEC Param to set */
822 Var *paramval; /* outer-relation Var to assign to Param */
824
825/* ----------------
826 * merge join node
827 *
828 * The expected ordering of each mergeable column is described by a btree
829 * opfamily OID, a collation OID, a direction (BTLessStrategyNumber or
830 * BTGreaterStrategyNumber) and a nulls-first flag. Note that the two sides
831 * of each mergeclause may be of different datatypes, but they are ordered the
832 * same way according to the common opfamily and collation. The operator in
833 * each mergeclause must be an equality operator of the indicated opfamily.
834 * ----------------
835 */
836typedef struct MergeJoin
837{
839
840 /* Can we skip mark/restore calls? */
842
843 /* mergeclauses as expression trees */
845
846 /* these are arrays, but have the same length as the mergeclauses list: */
847
848 /* per-clause OIDs of btree opfamilies */
849 Oid *mergeFamilies pg_node_attr(array_size(mergeclauses));
850
851 /* per-clause OIDs of collations */
852 Oid *mergeCollations pg_node_attr(array_size(mergeclauses));
853
854 /* per-clause ordering (ASC or DESC) */
855 bool *mergeReversals pg_node_attr(array_size(mergeclauses));
856
857 /* per-clause nulls ordering */
858 bool *mergeNullsFirst pg_node_attr(array_size(mergeclauses));
860
861/* ----------------
862 * hash join node
863 * ----------------
864 */
865typedef struct HashJoin
866{
871
872 /*
873 * List of expressions to be hashed for tuples from the outer plan, to
874 * perform lookups in the hashtable over the inner plan.
875 */
878
879/* ----------------
880 * materialization node
881 * ----------------
882 */
883typedef struct Material
884{
887
888/* ----------------
889 * memoize node
890 * ----------------
891 */
892typedef struct Memoize
893{
895
896 /* size of the two arrays below */
898
899 /* hash operators for each key */
900 Oid *hashOperators pg_node_attr(array_size(numKeys));
901
902 /* collations for each key */
903 Oid *collations pg_node_attr(array_size(numKeys));
904
905 /* cache keys in the form of exprs containing parameters */
907
908 /*
909 * true if the cache entry should be marked as complete after we store the
910 * first tuple in it.
911 */
913
914 /*
915 * true when cache key should be compared bit by bit, false when using
916 * hash equality ops
917 */
919
920 /*
921 * The maximum number of entries that the planner expects will fit in the
922 * cache, or 0 if unknown
923 */
925
926 /* paramids from param_exprs */
929
930/* ----------------
931 * sort node
932 * ----------------
933 */
934typedef struct Sort
935{
937
938 /* number of sort-key columns */
940
941 /* their indexes in the target list */
942 AttrNumber *sortColIdx pg_node_attr(array_size(numCols));
943
944 /* OIDs of operators to sort them by */
945 Oid *sortOperators pg_node_attr(array_size(numCols));
946
947 /* OIDs of collations */
948 Oid *collations pg_node_attr(array_size(numCols));
949
950 /* NULLS FIRST/LAST directions */
951 bool *nullsFirst pg_node_attr(array_size(numCols));
953
954/* ----------------
955 * incremental sort node
956 * ----------------
957 */
958typedef struct IncrementalSort
959{
961 int nPresortedCols; /* number of presorted columns */
963
964/* ---------------
965 * group node -
966 * Used for queries with GROUP BY (but no aggregates) specified.
967 * The input must be presorted according to the grouping columns.
968 * ---------------
969 */
970typedef struct Group
971{
973
974 /* number of grouping columns */
976
977 /* their indexes in the target list */
978 AttrNumber *grpColIdx pg_node_attr(array_size(numCols));
979
980 /* equality operators to compare with */
981 Oid *grpOperators pg_node_attr(array_size(numCols));
982 Oid *grpCollations pg_node_attr(array_size(numCols));
984
985/* ---------------
986 * aggregate node
987 *
988 * An Agg node implements plain or grouped aggregation. For grouped
989 * aggregation, we can work with presorted input or unsorted input;
990 * the latter strategy uses an internal hashtable.
991 *
992 * Notice the lack of any direct info about the aggregate functions to be
993 * computed. They are found by scanning the node's tlist and quals during
994 * executor startup. (It is possible that there are no aggregate functions;
995 * this could happen if they get optimized away by constant-folding, or if
996 * we are using the Agg node to implement hash-based grouping.)
997 * ---------------
998 */
999typedef struct Agg
1000{
1002
1003 /* basic strategy, see nodes.h */
1005
1006 /* agg-splitting mode, see nodes.h */
1008
1009 /* number of grouping columns */
1011
1012 /* their indexes in the target list */
1013 AttrNumber *grpColIdx pg_node_attr(array_size(numCols));
1014
1015 /* equality operators to compare with */
1016 Oid *grpOperators pg_node_attr(array_size(numCols));
1017 Oid *grpCollations pg_node_attr(array_size(numCols));
1018
1019 /* estimated number of groups in input */
1021
1022 /* for pass-by-ref transition data */
1024
1025 /* IDs of Params used in Aggref inputs */
1027
1028 /* Note: planner provides numGroups & aggParams only in HASHED/MIXED case */
1029
1030 /* grouping sets to use */
1032
1033 /* chained Agg/Sort nodes */
1036
1037/* ----------------
1038 * window aggregate node
1039 * ----------------
1040 */
1041typedef struct WindowAgg
1042{
1044
1045 /* ID referenced by window functions */
1047
1048 /* number of columns in partition clause */
1050
1051 /* their indexes in the target list */
1052 AttrNumber *partColIdx pg_node_attr(array_size(partNumCols));
1053
1054 /* equality operators for partition columns */
1055 Oid *partOperators pg_node_attr(array_size(partNumCols));
1056
1057 /* collations for partition columns */
1058 Oid *partCollations pg_node_attr(array_size(partNumCols));
1059
1060 /* number of columns in ordering clause */
1062
1063 /* their indexes in the target list */
1064 AttrNumber *ordColIdx pg_node_attr(array_size(ordNumCols));
1065
1066 /* equality operators for ordering columns */
1067 Oid *ordOperators pg_node_attr(array_size(ordNumCols));
1068
1069 /* collations for ordering columns */
1070 Oid *ordCollations pg_node_attr(array_size(ordNumCols));
1071
1072 /* frame_clause options, see WindowDef */
1074
1075 /* expression for starting bound, if any */
1077
1078 /* expression for ending bound, if any */
1080
1081 /* qual to help short-circuit execution */
1083
1084 /* runCondition for display in EXPLAIN */
1086
1087 /* these fields are used with RANGE offset PRECEDING/FOLLOWING: */
1088
1089 /* in_range function for startOffset */
1091
1092 /* in_range function for endOffset */
1094
1095 /* collation for in_range tests */
1097
1098 /* use ASC sort order for in_range tests? */
1100
1101 /* nulls sort first for in_range tests? */
1103
1104 /*
1105 * false for all apart from the WindowAgg that's closest to the root of
1106 * the plan
1107 */
1110
1111/* ----------------
1112 * unique node
1113 * ----------------
1114 */
1115typedef struct Unique
1116{
1118
1119 /* number of columns to check for uniqueness */
1121
1122 /* their indexes in the target list */
1123 AttrNumber *uniqColIdx pg_node_attr(array_size(numCols));
1124
1125 /* equality operators to compare with */
1126 Oid *uniqOperators pg_node_attr(array_size(numCols));
1127
1128 /* collations for equality comparisons */
1129 Oid *uniqCollations pg_node_attr(array_size(numCols));
1131
1132/* ------------
1133 * gather node
1134 *
1135 * Note: rescan_param is the ID of a PARAM_EXEC parameter slot. That slot
1136 * will never actually contain a value, but the Gather node must flag it as
1137 * having changed whenever it is rescanned. The child parallel-aware scan
1138 * nodes are marked as depending on that parameter, so that the rescan
1139 * machinery is aware that their output is likely to change across rescans.
1140 * In some cases we don't need a rescan Param, so rescan_param is set to -1.
1141 * ------------
1142 */
1143typedef struct Gather
1144{
1146 int num_workers; /* planned number of worker processes */
1147 int rescan_param; /* ID of Param that signals a rescan, or -1 */
1148 bool single_copy; /* don't execute plan more than once */
1149 bool invisible; /* suppress EXPLAIN display (for testing)? */
1150 Bitmapset *initParam; /* param id's of initplans which are referred
1151 * at gather or one of it's child node */
1153
1154/* ------------
1155 * gather merge node
1156 * ------------
1157 */
1158typedef struct GatherMerge
1159{
1161
1162 /* planned number of worker processes */
1164
1165 /* ID of Param that signals a rescan, or -1 */
1167
1168 /* remaining fields are just like the sort-key info in struct Sort */
1169
1170 /* number of sort-key columns */
1172
1173 /* their indexes in the target list */
1174 AttrNumber *sortColIdx pg_node_attr(array_size(numCols));
1175
1176 /* OIDs of operators to sort them by */
1177 Oid *sortOperators pg_node_attr(array_size(numCols));
1178
1179 /* OIDs of collations */
1180 Oid *collations pg_node_attr(array_size(numCols));
1181
1182 /* NULLS FIRST/LAST directions */
1183 bool *nullsFirst pg_node_attr(array_size(numCols));
1184
1185 /*
1186 * param id's of initplans which are referred at gather merge or one of
1187 * it's child node
1188 */
1191
1192/* ----------------
1193 * hash build node
1194 *
1195 * If the executor is supposed to try to apply skew join optimization, then
1196 * skewTable/skewColumn/skewInherit identify the outer relation's join key
1197 * column, from which the relevant MCV statistics can be fetched.
1198 * ----------------
1199 */
1200typedef struct Hash
1201{
1203
1204 /*
1205 * List of expressions to be hashed for tuples from Hash's outer plan,
1206 * needed to put them into the hashtable.
1207 */
1208 List *hashkeys; /* hash keys for the hashjoin condition */
1209 Oid skewTable; /* outer join key's table OID, or InvalidOid */
1210 AttrNumber skewColumn; /* outer join key's column #, or zero */
1211 bool skewInherit; /* is outer join rel an inheritance tree? */
1212 /* all other info is in the parent HashJoin node */
1213 Cardinality rows_total; /* estimate total rows if parallel_aware */
1215
1216/* ----------------
1217 * setop node
1218 * ----------------
1219 */
1220typedef struct SetOp
1221{
1223
1224 /* what to do, see nodes.h */
1226
1227 /* how to do it, see nodes.h */
1229
1230 /* number of columns to compare */
1232
1233 /* their indexes in the target list */
1234 AttrNumber *cmpColIdx pg_node_attr(array_size(numCols));
1235
1236 /* comparison operators (either equality operators or sort operators) */
1237 Oid *cmpOperators pg_node_attr(array_size(numCols));
1238 Oid *cmpCollations pg_node_attr(array_size(numCols));
1239
1240 /* nulls-first flags if sorting, otherwise not interesting */
1241 bool *cmpNullsFirst pg_node_attr(array_size(numCols));
1242
1243 /* estimated number of groups in left input */
1246
1247/* ----------------
1248 * lock-rows node
1249 *
1250 * rowMarks identifies the rels to be locked by this node; it should be
1251 * a subset of the rowMarks listed in the top-level PlannedStmt.
1252 * epqParam is a Param that all scan nodes below this one must depend on.
1253 * It is used to force re-evaluation of the plan during EvalPlanQual.
1254 * ----------------
1255 */
1256typedef struct LockRows
1257{
1259 List *rowMarks; /* a list of PlanRowMark's */
1260 int epqParam; /* ID of Param for EvalPlanQual re-eval */
1262
1263/* ----------------
1264 * limit node
1265 *
1266 * Note: as of Postgres 8.2, the offset and count expressions are expected
1267 * to yield int8, rather than int4 as before.
1268 * ----------------
1269 */
1270typedef struct Limit
1271{
1273
1274 /* OFFSET parameter, or NULL if none */
1276
1277 /* COUNT parameter, or NULL if none */
1279
1280 /* limit type */
1282
1283 /* number of columns to check for similarity */
1285
1286 /* their indexes in the target list */
1287 AttrNumber *uniqColIdx pg_node_attr(array_size(uniqNumCols));
1288
1289 /* equality operators to compare with */
1290 Oid *uniqOperators pg_node_attr(array_size(uniqNumCols));
1291
1292 /* collations for equality comparisons */
1293 Oid *uniqCollations pg_node_attr(array_size(uniqNumCols));
1295
1296
1297/*
1298 * RowMarkType -
1299 * enums for types of row-marking operations
1300 *
1301 * The first four of these values represent different lock strengths that
1302 * we can take on tuples according to SELECT FOR [KEY] UPDATE/SHARE requests.
1303 * We support these on regular tables, as well as on foreign tables whose FDWs
1304 * report support for late locking. For other foreign tables, any locking
1305 * that might be done for such requests must happen during the initial row
1306 * fetch; their FDWs provide no mechanism for going back to lock a row later.
1307 * This means that the semantics will be a bit different than for a local
1308 * table; in particular we are likely to lock more rows than would be locked
1309 * locally, since remote rows will be locked even if they then fail
1310 * locally-checked restriction or join quals. However, the prospect of
1311 * doing a separate remote query to lock each selected row is usually pretty
1312 * unappealing, so early locking remains a credible design choice for FDWs.
1313 *
1314 * When doing UPDATE/DELETE/MERGE/SELECT FOR UPDATE/SHARE, we have to uniquely
1315 * identify all the source rows, not only those from the target relations, so
1316 * that we can perform EvalPlanQual rechecking at need. For plain tables we
1317 * can just fetch the TID, much as for a target relation; this case is
1318 * represented by ROW_MARK_REFERENCE. Otherwise (for example for VALUES or
1319 * FUNCTION scans) we have to copy the whole row value. ROW_MARK_COPY is
1320 * pretty inefficient, since most of the time we'll never need the data; but
1321 * fortunately the overhead is usually not performance-critical in practice.
1322 * By default we use ROW_MARK_COPY for foreign tables, but if the FDW has
1323 * a concept of rowid it can request to use ROW_MARK_REFERENCE instead.
1324 * (Again, this probably doesn't make sense if a physical remote fetch is
1325 * needed, but for FDWs that map to local storage it might be credible.)
1326 */
1327typedef enum RowMarkType
1328{
1329 ROW_MARK_EXCLUSIVE, /* obtain exclusive tuple lock */
1330 ROW_MARK_NOKEYEXCLUSIVE, /* obtain no-key exclusive tuple lock */
1331 ROW_MARK_SHARE, /* obtain shared tuple lock */
1332 ROW_MARK_KEYSHARE, /* obtain keyshare tuple lock */
1333 ROW_MARK_REFERENCE, /* just fetch the TID, don't lock it */
1334 ROW_MARK_COPY, /* physically copy the row value */
1336
1337#define RowMarkRequiresRowShareLock(marktype) ((marktype) <= ROW_MARK_KEYSHARE)
1338
1339/*
1340 * PlanRowMark -
1341 * plan-time representation of FOR [KEY] UPDATE/SHARE clauses
1342 *
1343 * When doing UPDATE/DELETE/MERGE/SELECT FOR UPDATE/SHARE, we create a separate
1344 * PlanRowMark node for each non-target relation in the query. Relations that
1345 * are not specified as FOR UPDATE/SHARE are marked ROW_MARK_REFERENCE (if
1346 * regular tables or supported foreign tables) or ROW_MARK_COPY (if not).
1347 *
1348 * Initially all PlanRowMarks have rti == prti and isParent == false.
1349 * When the planner discovers that a relation is the root of an inheritance
1350 * tree, it sets isParent true, and adds an additional PlanRowMark to the
1351 * list for each child relation (including the target rel itself in its role
1352 * as a child, if it is not a partitioned table). Any non-leaf partitioned
1353 * child relations will also have entries with isParent = true. The child
1354 * entries have rti == child rel's RT index and prti == top parent's RT index,
1355 * and can therefore be recognized as children by the fact that prti != rti.
1356 * The parent's allMarkTypes field gets the OR of (1<<markType) across all
1357 * its children (this definition allows children to use different markTypes).
1358 *
1359 * The planner also adds resjunk output columns to the plan that carry
1360 * information sufficient to identify the locked or fetched rows. When
1361 * markType != ROW_MARK_COPY, these columns are named
1362 * tableoid%u OID of table
1363 * ctid%u TID of row
1364 * The tableoid column is only present for an inheritance hierarchy.
1365 * When markType == ROW_MARK_COPY, there is instead a single column named
1366 * wholerow%u whole-row value of relation
1367 * (An inheritance hierarchy could have all three resjunk output columns,
1368 * if some children use a different markType than others.)
1369 * In all three cases, %u represents the rowmark ID number (rowmarkId).
1370 * This number is unique within a plan tree, except that child relation
1371 * entries copy their parent's rowmarkId. (Assigning unique numbers
1372 * means we needn't renumber rowmarkIds when flattening subqueries, which
1373 * would require finding and renaming the resjunk columns as well.)
1374 * Note this means that all tables in an inheritance hierarchy share the
1375 * same resjunk column names.
1376 */
1377typedef struct PlanRowMark
1378{
1379 pg_node_attr(no_equal, no_query_jumble)
1380
1381 NodeTag type;
1382 Index rti; /* range table index of markable relation */
1383 Index prti; /* range table index of parent relation */
1384 Index rowmarkId; /* unique identifier for resjunk columns */
1385 RowMarkType markType; /* see enum above */
1386 int allMarkTypes; /* OR of (1<<markType) for all children */
1387 LockClauseStrength strength; /* LockingClause's strength, or LCS_NONE */
1388 LockWaitPolicy waitPolicy; /* NOWAIT and SKIP LOCKED options */
1389 bool isParent; /* true if this is a "dummy" parent entry */
1391
1392
1393/*
1394 * Node types to represent partition pruning information.
1395 */
1396
1397/*
1398 * PartitionPruneInfo - Details required to allow the executor to prune
1399 * partitions.
1400 *
1401 * Here we store mapping details to allow translation of a partitioned table's
1402 * index as returned by the partition pruning code into subplan indexes for
1403 * plan types which support arbitrary numbers of subplans, such as Append.
1404 * We also store various details to tell the executor when it should be
1405 * performing partition pruning.
1406 *
1407 * Each PartitionedRelPruneInfo describes the partitioning rules for a single
1408 * partitioned table (a/k/a level of partitioning). Since a partitioning
1409 * hierarchy could contain multiple levels, we represent it by a List of
1410 * PartitionedRelPruneInfos, where the first entry represents the topmost
1411 * partitioned table and additional entries represent non-leaf child
1412 * partitions, ordered such that parents appear before their children.
1413 * Then, since an Append-type node could have multiple partitioning
1414 * hierarchies among its children, we have an unordered List of those Lists.
1415 *
1416 * prune_infos List of Lists containing PartitionedRelPruneInfo nodes,
1417 * one sublist per run-time-prunable partition hierarchy
1418 * appearing in the parent plan node's subplans.
1419 * other_subplans Indexes of any subplans that are not accounted for
1420 * by any of the PartitionedRelPruneInfo nodes in
1421 * "prune_infos". These subplans must not be pruned.
1422 */
1424{
1425 pg_node_attr(no_equal, no_query_jumble)
1426
1427 NodeTag type;
1431
1432/*
1433 * PartitionedRelPruneInfo - Details required to allow the executor to prune
1434 * partitions for a single partitioned table.
1435 *
1436 * subplan_map[] and subpart_map[] are indexed by partition index of the
1437 * partitioned table referenced by 'rtindex', the partition index being the
1438 * order that the partitions are defined in the table's PartitionDesc. For a
1439 * leaf partition p, subplan_map[p] contains the zero-based index of the
1440 * partition's subplan in the parent plan's subplan list; it is -1 if the
1441 * partition is non-leaf or has been pruned. For a non-leaf partition p,
1442 * subpart_map[p] contains the zero-based index of that sub-partition's
1443 * PartitionedRelPruneInfo in the hierarchy's PartitionedRelPruneInfo list;
1444 * it is -1 if the partition is a leaf or has been pruned. Note that subplan
1445 * indexes, as stored in 'subplan_map', are global across the parent plan
1446 * node, but partition indexes are valid only within a particular hierarchy.
1447 * relid_map[p] contains the partition's OID, or 0 if the partition was pruned.
1448 */
1450{
1451 pg_node_attr(no_equal, no_query_jumble)
1452
1453 NodeTag type;
1454
1455 /* RT index of partition rel for this level */
1457
1458 /* Indexes of all partitions which subplans or subparts are present for */
1460
1461 /* Length of the following arrays: */
1463
1464 /* subplan index by partition index, or -1 */
1465 int *subplan_map pg_node_attr(array_size(nparts));
1466
1467 /* subpart index by partition index, or -1 */
1468 int *subpart_map pg_node_attr(array_size(nparts));
1469
1470 /* relation OID by partition index, or 0 */
1471 Oid *relid_map pg_node_attr(array_size(nparts));
1472
1473 /*
1474 * initial_pruning_steps shows how to prune during executor startup (i.e.,
1475 * without use of any PARAM_EXEC Params); it is NIL if no startup pruning
1476 * is required. exec_pruning_steps shows how to prune with PARAM_EXEC
1477 * Params; it is NIL if no per-scan pruning is required.
1478 */
1479 List *initial_pruning_steps; /* List of PartitionPruneStep */
1480 List *exec_pruning_steps; /* List of PartitionPruneStep */
1481
1482 /* All PARAM_EXEC Param IDs in exec_pruning_steps */
1485
1486/*
1487 * Abstract Node type for partition pruning steps (there are no concrete
1488 * Nodes of this type).
1489 *
1490 * step_id is the global identifier of the step within its pruning context.
1491 */
1493{
1494 pg_node_attr(abstract, no_equal, no_query_jumble)
1495
1496 NodeTag type;
1499
1500/*
1501 * PartitionPruneStepOp - Information to prune using a set of mutually ANDed
1502 * OpExpr clauses
1503 *
1504 * This contains information extracted from up to partnatts OpExpr clauses,
1505 * where partnatts is the number of partition key columns. 'opstrategy' is the
1506 * strategy of the operator in the clause matched to the last partition key.
1507 * 'exprs' contains expressions which comprise the lookup key to be passed to
1508 * the partition bound search function. 'cmpfns' contains the OIDs of
1509 * comparison functions used to compare aforementioned expressions with
1510 * partition bounds. Both 'exprs' and 'cmpfns' contain the same number of
1511 * items, up to partnatts items.
1512 *
1513 * Once we find the offset of a partition bound using the lookup key, we
1514 * determine which partitions to include in the result based on the value of
1515 * 'opstrategy'. For example, if it were equality, we'd return just the
1516 * partition that would contain that key or a set of partitions if the key
1517 * didn't consist of all partitioning columns. For non-equality strategies,
1518 * we'd need to include other partitions as appropriate.
1519 *
1520 * 'nullkeys' is the set containing the offset of the partition keys (0 to
1521 * partnatts - 1) that were matched to an IS NULL clause. This is only
1522 * considered for hash partitioning as we need to pass which keys are null
1523 * to the hash partition bound search function. It is never possible to
1524 * have an expression be present in 'exprs' for a given partition key and
1525 * the corresponding bit set in 'nullkeys'.
1526 */
1528{
1530
1536
1537/*
1538 * PartitionPruneStepCombine - Information to prune using a BoolExpr clause
1539 *
1540 * For BoolExpr clauses, we combine the set of partitions determined for each
1541 * of the argument clauses.
1542 */
1544{
1548
1550{
1552
1556
1557
1558/*
1559 * Plan invalidation info
1560 *
1561 * We track the objects on which a PlannedStmt depends in two ways:
1562 * relations are recorded as a simple list of OIDs, and everything else
1563 * is represented as a list of PlanInvalItems. A PlanInvalItem is designed
1564 * to be used with the syscache invalidation mechanism, so it identifies a
1565 * system catalog entry by cache ID and hash value.
1566 */
1567typedef struct PlanInvalItem
1568{
1569 pg_node_attr(no_equal, no_query_jumble)
1570
1571 NodeTag type;
1572 int cacheId; /* a syscache ID, see utils/syscache.h */
1573 uint32 hashValue; /* hash value of object's cache lookup key */
1575
1576/*
1577 * MonotonicFunction
1578 *
1579 * Allows the planner to track monotonic properties of functions. A function
1580 * is monotonically increasing if a subsequent call cannot yield a lower value
1581 * than the previous call. A monotonically decreasing function cannot yield a
1582 * higher value on subsequent calls, and a function which is both must return
1583 * the same value on each call.
1584 */
1586{
1592
1593#endif /* PLANNODES_H */
int16 AttrNumber
Definition: attnum.h:21
uint64_t uint64
Definition: c.h:489
uint32_t uint32
Definition: c.h:488
unsigned int Index
Definition: c.h:571
LockWaitPolicy
Definition: lockoptions.h:37
LockClauseStrength
Definition: lockoptions.h:22
SetOpCmd
Definition: nodes.h:397
SetOpStrategy
Definition: nodes.h:405
double Cost
Definition: nodes.h:251
OnConflictAction
Definition: nodes.h:417
double Cardinality
Definition: nodes.h:252
CmdType
Definition: nodes.h:263
AggStrategy
Definition: nodes.h:353
NodeTag
Definition: nodes.h:27
AggSplit
Definition: nodes.h:375
LimitOption
Definition: nodes.h:430
int ParseLoc
Definition: nodes.h:240
JoinType
Definition: nodes.h:288
#define plan(x)
Definition: pg_regress.c:161
struct ForeignScan ForeignScan
struct TableFuncScan TableFuncScan
struct IndexScan IndexScan
struct MergeJoin MergeJoin
struct Memoize Memoize
struct Plan Plan
struct SampleScan SampleScan
struct WindowAgg WindowAgg
struct WorkTableScan WorkTableScan
struct ProjectSet ProjectSet
struct Sort Sort
struct PartitionedRelPruneInfo PartitionedRelPruneInfo
struct BitmapIndexScan BitmapIndexScan
struct TidScan TidScan
struct LockRows LockRows
struct TidRangeScan TidRangeScan
struct PartitionPruneStepOp PartitionPruneStepOp
SubqueryScanStatus
Definition: plannodes.h:595
@ SUBQUERY_SCAN_NONTRIVIAL
Definition: plannodes.h:598
@ SUBQUERY_SCAN_UNKNOWN
Definition: plannodes.h:596
@ SUBQUERY_SCAN_TRIVIAL
Definition: plannodes.h:597
struct PlanInvalItem PlanInvalItem
struct SubqueryScan SubqueryScan
PartitionPruneCombineOp
Definition: plannodes.h:1544
@ PARTPRUNE_COMBINE_INTERSECT
Definition: plannodes.h:1546
@ PARTPRUNE_COMBINE_UNION
Definition: plannodes.h:1545
struct IncrementalSort IncrementalSort
struct CteScan CteScan
struct NestLoop NestLoop
struct PlanRowMark PlanRowMark
struct Limit Limit
struct Unique Unique
struct Join Join
struct BitmapOr BitmapOr
struct SeqScan SeqScan
struct HashJoin HashJoin
struct Group Group
struct Scan Scan
struct PartitionPruneInfo PartitionPruneInfo
struct Append Append
struct Material Material
struct BitmapHeapScan BitmapHeapScan
struct NamedTuplestoreScan NamedTuplestoreScan
struct SetOp SetOp
struct NestLoopParam NestLoopParam
struct BitmapAnd BitmapAnd
struct GatherMerge GatherMerge
struct ModifyTable ModifyTable
struct PartitionPruneStep PartitionPruneStep
struct Hash Hash
RowMarkType
Definition: plannodes.h:1328
@ ROW_MARK_COPY
Definition: plannodes.h:1334
@ ROW_MARK_REFERENCE
Definition: plannodes.h:1333
@ ROW_MARK_SHARE
Definition: plannodes.h:1331
@ ROW_MARK_EXCLUSIVE
Definition: plannodes.h:1329
@ ROW_MARK_NOKEYEXCLUSIVE
Definition: plannodes.h:1330
@ ROW_MARK_KEYSHARE
Definition: plannodes.h:1332
MonotonicFunction
Definition: plannodes.h:1586
@ MONOTONICFUNC_NONE
Definition: plannodes.h:1587
@ MONOTONICFUNC_DECREASING
Definition: plannodes.h:1589
@ MONOTONICFUNC_INCREASING
Definition: plannodes.h:1588
@ MONOTONICFUNC_BOTH
Definition: plannodes.h:1590
struct RecursiveUnion RecursiveUnion
struct IndexOnlyScan IndexOnlyScan
struct FunctionScan FunctionScan
struct Result Result
struct MergeAppend MergeAppend
struct PartitionPruneStepCombine PartitionPruneStepCombine
struct CustomScan CustomScan
struct Agg Agg
struct ValuesScan ValuesScan
struct Gather Gather
struct PlannedStmt PlannedStmt
unsigned int Oid
Definition: postgres_ext.h:32
ScanDirection
Definition: sdir.h:25
uint16 StrategyNumber
Definition: stratnum.h:22
AggSplit aggsplit
Definition: plannodes.h:1007
List * chain
Definition: plannodes.h:1034
Oid *grpCollations pg_node_attr(array_size(numCols))
long numGroups
Definition: plannodes.h:1020
List * groupingSets
Definition: plannodes.h:1031
Bitmapset * aggParams
Definition: plannodes.h:1026
Plan plan
Definition: plannodes.h:1001
int numCols
Definition: plannodes.h:1010
Oid *grpOperators pg_node_attr(array_size(numCols))
uint64 transitionSpace
Definition: plannodes.h:1023
AttrNumber *grpColIdx pg_node_attr(array_size(numCols))
AggStrategy aggstrategy
Definition: plannodes.h:1004
int first_partial_plan
Definition: plannodes.h:279
struct PartitionPruneInfo * part_prune_info
Definition: plannodes.h:282
int nasyncplans
Definition: plannodes.h:273
Bitmapset * apprelids
Definition: plannodes.h:271
Plan plan
Definition: plannodes.h:270
List * appendplans
Definition: plannodes.h:272
Plan plan
Definition: plannodes.h:361
List * bitmapplans
Definition: plannodes.h:362
List * bitmapqualorig
Definition: plannodes.h:544
List * indexqualorig
Definition: plannodes.h:529
List * indexqual
Definition: plannodes.h:528
List * bitmapplans
Definition: plannodes.h:377
bool isshared
Definition: plannodes.h:376
Plan plan
Definition: plannodes.h:375
int ctePlanId
Definition: plannodes.h:646
int cteParam
Definition: plannodes.h:647
Scan scan
Definition: plannodes.h:645
uint32 flags
Definition: plannodes.h:745
List * custom_scan_tlist
Definition: plannodes.h:750
Scan scan
Definition: plannodes.h:744
List * custom_private
Definition: plannodes.h:749
Bitmapset * custom_relids
Definition: plannodes.h:751
List * custom_exprs
Definition: plannodes.h:748
const struct CustomScanMethods * methods
Definition: plannodes.h:758
List * custom_plans
Definition: plannodes.h:747
Oid checkAsUser
Definition: plannodes.h:715
CmdType operation
Definition: plannodes.h:713
Oid fs_server
Definition: plannodes.h:717
List * fdw_exprs
Definition: plannodes.h:718
bool fsSystemCol
Definition: plannodes.h:724
Bitmapset * fs_relids
Definition: plannodes.h:722
List * fdw_private
Definition: plannodes.h:719
Bitmapset * fs_base_relids
Definition: plannodes.h:723
Index resultRelation
Definition: plannodes.h:714
List * fdw_recheck_quals
Definition: plannodes.h:721
List * fdw_scan_tlist
Definition: plannodes.h:720
List * functions
Definition: plannodes.h:615
bool funcordinality
Definition: plannodes.h:616
int rescan_param
Definition: plannodes.h:1166
Oid *collations pg_node_attr(array_size(numCols))
Oid *sortOperators pg_node_attr(array_size(numCols))
bool *nullsFirst pg_node_attr(array_size(numCols))
Bitmapset * initParam
Definition: plannodes.h:1189
AttrNumber *sortColIdx pg_node_attr(array_size(numCols))
int num_workers
Definition: plannodes.h:1163
int num_workers
Definition: plannodes.h:1146
bool invisible
Definition: plannodes.h:1149
Bitmapset * initParam
Definition: plannodes.h:1150
bool single_copy
Definition: plannodes.h:1148
Plan plan
Definition: plannodes.h:1145
int rescan_param
Definition: plannodes.h:1147
AttrNumber *grpColIdx pg_node_attr(array_size(numCols))
int numCols
Definition: plannodes.h:975
Plan plan
Definition: plannodes.h:972
Oid *grpCollations pg_node_attr(array_size(numCols))
Oid *grpOperators pg_node_attr(array_size(numCols))
List * hashcollations
Definition: plannodes.h:870
List * hashclauses
Definition: plannodes.h:868
List * hashoperators
Definition: plannodes.h:869
Join join
Definition: plannodes.h:867
List * hashkeys
Definition: plannodes.h:876
AttrNumber skewColumn
Definition: plannodes.h:1210
List * hashkeys
Definition: plannodes.h:1208
Oid skewTable
Definition: plannodes.h:1209
bool skewInherit
Definition: plannodes.h:1211
Cardinality rows_total
Definition: plannodes.h:1213
Plan plan
Definition: plannodes.h:1202
List * indexqual
Definition: plannodes.h:499
List * recheckqual
Definition: plannodes.h:500
List * indextlist
Definition: plannodes.h:502
ScanDirection indexorderdir
Definition: plannodes.h:503
List * indexorderby
Definition: plannodes.h:501
List * indexorderby
Definition: plannodes.h:458
List * indexorderbyops
Definition: plannodes.h:460
ScanDirection indexorderdir
Definition: plannodes.h:461
Scan scan
Definition: plannodes.h:454
List * indexqualorig
Definition: plannodes.h:457
Oid indexid
Definition: plannodes.h:455
List * indexqual
Definition: plannodes.h:456
List * indexorderbyorig
Definition: plannodes.h:459
pg_node_attr(abstract) Plan plan
List * joinqual
Definition: plannodes.h:796
JoinType jointype
Definition: plannodes.h:794
bool inner_unique
Definition: plannodes.h:795
LimitOption limitOption
Definition: plannodes.h:1281
Oid *uniqOperators pg_node_attr(array_size(uniqNumCols))
Plan plan
Definition: plannodes.h:1272
Node * limitCount
Definition: plannodes.h:1278
AttrNumber *uniqColIdx pg_node_attr(array_size(uniqNumCols))
int uniqNumCols
Definition: plannodes.h:1284
Oid *uniqCollations pg_node_attr(array_size(uniqNumCols))
Node * limitOffset
Definition: plannodes.h:1275
Definition: pg_list.h:54
int epqParam
Definition: plannodes.h:1260
List * rowMarks
Definition: plannodes.h:1259
Plan plan
Definition: plannodes.h:1258
Plan plan
Definition: plannodes.h:885
Plan plan
Definition: plannodes.h:894
bool singlerow
Definition: plannodes.h:912
Bitmapset * keyparamids
Definition: plannodes.h:927
Oid *hashOperators pg_node_attr(array_size(numKeys))
bool binary_mode
Definition: plannodes.h:918
int numKeys
Definition: plannodes.h:897
List * param_exprs
Definition: plannodes.h:906
uint32 est_entries
Definition: plannodes.h:924
Oid *collations pg_node_attr(array_size(numKeys))
struct PartitionPruneInfo * part_prune_info
Definition: plannodes.h:317
bool *nullsFirst pg_node_attr(array_size(numCols))
AttrNumber *sortColIdx pg_node_attr(array_size(numCols))
Oid *sortOperators pg_node_attr(array_size(numCols))
Bitmapset * apprelids
Definition: plannodes.h:295
Oid *collations pg_node_attr(array_size(numCols))
List * mergeplans
Definition: plannodes.h:297
List * mergeclauses
Definition: plannodes.h:844
Join join
Definition: plannodes.h:838
Oid *mergeFamilies pg_node_attr(array_size(mergeclauses))
bool skip_mark_restore
Definition: plannodes.h:841
bool *mergeReversals pg_node_attr(array_size(mergeclauses))
bool *mergeNullsFirst pg_node_attr(array_size(mergeclauses))
Oid *mergeCollations pg_node_attr(array_size(mergeclauses))
List * updateColnosLists
Definition: plannodes.h:239
Index nominalRelation
Definition: plannodes.h:235
List * arbiterIndexes
Definition: plannodes.h:249
List * onConflictCols
Definition: plannodes.h:251
List * mergeJoinConditions
Definition: plannodes.h:257
char * returningOldAlias
Definition: plannodes.h:241
char * returningNewAlias
Definition: plannodes.h:242
CmdType operation
Definition: plannodes.h:233
int epqParam
Definition: plannodes.h:247
List * resultRelations
Definition: plannodes.h:238
Bitmapset * fdwDirectModifyPlans
Definition: plannodes.h:245
List * onConflictSet
Definition: plannodes.h:250
List * exclRelTlist
Definition: plannodes.h:254
List * mergeActionLists
Definition: plannodes.h:255
bool canSetTag
Definition: plannodes.h:234
List * fdwPrivLists
Definition: plannodes.h:244
bool partColsUpdated
Definition: plannodes.h:237
List * returningLists
Definition: plannodes.h:243
List * withCheckOptionLists
Definition: plannodes.h:240
Index rootRelation
Definition: plannodes.h:236
Node * onConflictWhere
Definition: plannodes.h:252
List * rowMarks
Definition: plannodes.h:246
OnConflictAction onConflictAction
Definition: plannodes.h:248
Index exclRelRTI
Definition: plannodes.h:253
Var * paramval
Definition: plannodes.h:822
pg_node_attr(no_equal, no_query_jumble) NodeTag type
List * nestParams
Definition: plannodes.h:813
Join join
Definition: plannodes.h:812
Definition: nodes.h:129
Bitmapset * other_subplans
Definition: plannodes.h:1429
pg_node_attr(no_equal, no_query_jumble) NodeTag type
PartitionPruneCombineOp combineOp
Definition: plannodes.h:1553
PartitionPruneStep step
Definition: plannodes.h:1551
PartitionPruneStep step
Definition: plannodes.h:1529
StrategyNumber opstrategy
Definition: plannodes.h:1531
Bitmapset * nullkeys
Definition: plannodes.h:1534
pg_node_attr(abstract, no_equal, no_query_jumble) NodeTag type
Oid *relid_map pg_node_attr(array_size(nparts))
pg_node_attr(no_equal, no_query_jumble) NodeTag type
Bitmapset * present_parts
Definition: plannodes.h:1459
Bitmapset * execparamids
Definition: plannodes.h:1483
int *subplan_map pg_node_attr(array_size(nparts))
int *subpart_map pg_node_attr(array_size(nparts))
uint32 hashValue
Definition: plannodes.h:1573
pg_node_attr(no_equal, no_query_jumble) NodeTag type
LockClauseStrength strength
Definition: plannodes.h:1387
Index prti
Definition: plannodes.h:1383
RowMarkType markType
Definition: plannodes.h:1385
LockWaitPolicy waitPolicy
Definition: plannodes.h:1388
bool isParent
Definition: plannodes.h:1389
Index rowmarkId
Definition: plannodes.h:1384
int allMarkTypes
Definition: plannodes.h:1386
pg_node_attr(no_equal, no_query_jumble) NodeTag type
Bitmapset * extParam
Definition: plannodes.h:171
struct Plan * lefttree
Definition: plannodes.h:155
bool async_capable
Definition: plannodes.h:147
Cost total_cost
Definition: plannodes.h:130
struct Plan * righttree
Definition: plannodes.h:156
bool parallel_aware
Definition: plannodes.h:141
Cost startup_cost
Definition: plannodes.h:129
List * qual
Definition: plannodes.h:154
int plan_width
Definition: plannodes.h:136
Bitmapset * allParam
Definition: plannodes.h:172
bool parallel_safe
Definition: plannodes.h:142
Cardinality plan_rows
Definition: plannodes.h:135
int plan_node_id
Definition: plannodes.h:152
int disabled_nodes
Definition: plannodes.h:128
List * targetlist
Definition: plannodes.h:153
pg_node_attr(abstract, no_equal, no_query_jumble) NodeTag type
List * initPlan
Definition: plannodes.h:157
struct Plan * planTree
Definition: plannodes.h:70
bool hasModifyingCTE
Definition: plannodes.h:58
List * appendRelations
Definition: plannodes.h:80
List * permInfos
Definition: plannodes.h:74
bool canSetTag
Definition: plannodes.h:60
List * rowMarks
Definition: plannodes.h:87
int jitFlags
Definition: plannodes.h:68
Bitmapset * rewindPlanIDs
Definition: plannodes.h:85
ParseLoc stmt_len
Definition: plannodes.h:99
bool hasReturning
Definition: plannodes.h:56
ParseLoc stmt_location
Definition: plannodes.h:98
List * invalItems
Definition: plannodes.h:91
bool transientPlan
Definition: plannodes.h:62
List * resultRelations
Definition: plannodes.h:78
List * subplans
Definition: plannodes.h:82
List * relationOids
Definition: plannodes.h:89
bool dependsOnRole
Definition: plannodes.h:64
CmdType commandType
Definition: plannodes.h:52
pg_node_attr(no_equal, no_query_jumble) NodeTag type
Node * utilityStmt
Definition: plannodes.h:95
List * rtable
Definition: plannodes.h:72
List * paramExecTypes
Definition: plannodes.h:93
bool parallelModeNeeded
Definition: plannodes.h:66
uint64 queryId
Definition: plannodes.h:54
Plan plan
Definition: plannodes.h:211
AttrNumber *dupColIdx pg_node_attr(array_size(numCols))
Oid *dupOperators pg_node_attr(array_size(numCols))
Oid *dupCollations pg_node_attr(array_size(numCols))
Node * resconstantqual
Definition: plannodes.h:200
Plan plan
Definition: plannodes.h:199
struct TableSampleClause * tablesample
Definition: plannodes.h:412
Scan scan
Definition: plannodes.h:410
Index scanrelid
Definition: plannodes.h:392
pg_node_attr(abstract) Plan plan
Scan scan
Definition: plannodes.h:401
SetOpStrategy strategy
Definition: plannodes.h:1228
Oid *cmpOperators pg_node_attr(array_size(numCols))
AttrNumber *cmpColIdx pg_node_attr(array_size(numCols))
SetOpCmd cmd
Definition: plannodes.h:1225
Oid *cmpCollations pg_node_attr(array_size(numCols))
int numCols
Definition: plannodes.h:1231
Plan plan
Definition: plannodes.h:1222
bool *cmpNullsFirst pg_node_attr(array_size(numCols))
long numGroups
Definition: plannodes.h:1244
Oid *collations pg_node_attr(array_size(numCols))
bool *nullsFirst pg_node_attr(array_size(numCols))
Oid *sortOperators pg_node_attr(array_size(numCols))
int numCols
Definition: plannodes.h:939
AttrNumber *sortColIdx pg_node_attr(array_size(numCols))
Plan plan
Definition: plannodes.h:936
SubqueryScanStatus scanstatus
Definition: plannodes.h:605
Plan * subplan
Definition: plannodes.h:604
TableFunc * tablefunc
Definition: plannodes.h:636
List * tidrangequals
Definition: plannodes.h:571
Scan scan
Definition: plannodes.h:557
List * tidquals
Definition: plannodes.h:558
AttrNumber *uniqColIdx pg_node_attr(array_size(numCols))
Oid *uniqOperators pg_node_attr(array_size(numCols))
Oid *uniqCollations pg_node_attr(array_size(numCols))
Plan plan
Definition: plannodes.h:1117
int numCols
Definition: plannodes.h:1120
Scan scan
Definition: plannodes.h:625
List * values_lists
Definition: plannodes.h:626
Definition: primnodes.h:261
AttrNumber *ordColIdx pg_node_attr(array_size(ordNumCols))
int partNumCols
Definition: plannodes.h:1049
Oid endInRangeFunc
Definition: plannodes.h:1093
Node * endOffset
Definition: plannodes.h:1079
Oid *partCollations pg_node_attr(array_size(partNumCols))
bool topWindow
Definition: plannodes.h:1108
Plan plan
Definition: plannodes.h:1043
Oid *ordOperators pg_node_attr(array_size(ordNumCols))
List * runConditionOrig
Definition: plannodes.h:1085
Oid inRangeColl
Definition: plannodes.h:1096
Node * startOffset
Definition: plannodes.h:1076
List * runCondition
Definition: plannodes.h:1082
Oid startInRangeFunc
Definition: plannodes.h:1090
bool inRangeAsc
Definition: plannodes.h:1099
Index winref
Definition: plannodes.h:1046
AttrNumber *partColIdx pg_node_attr(array_size(partNumCols))
bool inRangeNullsFirst
Definition: plannodes.h:1102
Oid *partOperators pg_node_attr(array_size(partNumCols))
int ordNumCols
Definition: plannodes.h:1061
Oid *ordCollations pg_node_attr(array_size(ordNumCols))
int frameOptions
Definition: plannodes.h:1073
const char * type