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execExpr.c
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1/*-------------------------------------------------------------------------
2 *
3 * execExpr.c
4 * Expression evaluation infrastructure.
5 *
6 * During executor startup, we compile each expression tree (which has
7 * previously been processed by the parser and planner) into an ExprState,
8 * using ExecInitExpr() et al. This converts the tree into a flat array
9 * of ExprEvalSteps, which may be thought of as instructions in a program.
10 * At runtime, we'll execute steps, starting with the first, until we reach
11 * an EEOP_DONE_{RETURN|NO_RETURN} opcode.
12 *
13 * This file contains the "compilation" logic. It is independent of the
14 * specific execution technology we use (switch statement, computed goto,
15 * JIT compilation, etc).
16 *
17 * See src/backend/executor/README for some background, specifically the
18 * "Expression Trees and ExprState nodes", "Expression Initialization",
19 * and "Expression Evaluation" sections.
20 *
21 *
22 * Portions Copyright (c) 1996-2025, PostgreSQL Global Development Group
23 * Portions Copyright (c) 1994, Regents of the University of California
24 *
25 *
26 * IDENTIFICATION
27 * src/backend/executor/execExpr.c
28 *
29 *-------------------------------------------------------------------------
30 */
31#include "postgres.h"
32
33#include "access/nbtree.h"
34#include "catalog/objectaccess.h"
35#include "catalog/pg_proc.h"
36#include "catalog/pg_type.h"
37#include "executor/execExpr.h"
38#include "executor/nodeSubplan.h"
39#include "funcapi.h"
40#include "jit/jit.h"
41#include "miscadmin.h"
42#include "nodes/makefuncs.h"
43#include "nodes/nodeFuncs.h"
44#include "nodes/subscripting.h"
45#include "optimizer/optimizer.h"
46#include "pgstat.h"
47#include "utils/acl.h"
48#include "utils/array.h"
49#include "utils/builtins.h"
50#include "utils/jsonfuncs.h"
51#include "utils/jsonpath.h"
52#include "utils/lsyscache.h"
53#include "utils/typcache.h"
54
55
56typedef struct ExprSetupInfo
57{
58 /*
59 * Highest attribute numbers fetched from inner/outer/scan/old/new tuple
60 * slots:
61 */
62 AttrNumber last_inner;
63 AttrNumber last_outer;
64 AttrNumber last_scan;
65 AttrNumber last_old;
66 AttrNumber last_new;
67 /* MULTIEXPR SubPlan nodes appearing in the expression: */
68 List *multiexpr_subplans;
69} ExprSetupInfo;
70
71static void ExecReadyExpr(ExprState *state);
72static void ExecInitExprRec(Expr *node, ExprState *state,
73 Datum *resv, bool *resnull);
74static void ExecInitFunc(ExprEvalStep *scratch, Expr *node, List *args,
75 Oid funcid, Oid inputcollid,
76 ExprState *state);
77static void ExecInitSubPlanExpr(SubPlan *subplan,
78 ExprState *state,
79 Datum *resv, bool *resnull);
80static void ExecCreateExprSetupSteps(ExprState *state, Node *node);
81static void ExecPushExprSetupSteps(ExprState *state, ExprSetupInfo *info);
82static bool expr_setup_walker(Node *node, ExprSetupInfo *info);
83static bool ExecComputeSlotInfo(ExprState *state, ExprEvalStep *op);
84static void ExecInitWholeRowVar(ExprEvalStep *scratch, Var *variable,
85 ExprState *state);
86static void ExecInitSubscriptingRef(ExprEvalStep *scratch,
87 SubscriptingRef *sbsref,
88 ExprState *state,
89 Datum *resv, bool *resnull);
90static bool isAssignmentIndirectionExpr(Expr *expr);
91static void ExecInitCoerceToDomain(ExprEvalStep *scratch, CoerceToDomain *ctest,
92 ExprState *state,
93 Datum *resv, bool *resnull);
94static void ExecBuildAggTransCall(ExprState *state, AggState *aggstate,
95 ExprEvalStep *scratch,
96 FunctionCallInfo fcinfo, AggStatePerTrans pertrans,
97 int transno, int setno, int setoff, bool ishash,
98 bool nullcheck);
99static void ExecInitJsonExpr(JsonExpr *jsexpr, ExprState *state,
100 Datum *resv, bool *resnull,
101 ExprEvalStep *scratch);
102static void ExecInitJsonCoercion(ExprState *state, JsonReturning *returning,
103 ErrorSaveContext *escontext, bool omit_quotes,
104 bool exists_coerce,
105 Datum *resv, bool *resnull);
106
107
108/*
109 * ExecInitExpr: prepare an expression tree for execution
110 *
111 * This function builds and returns an ExprState implementing the given
112 * Expr node tree. The return ExprState can then be handed to ExecEvalExpr
113 * for execution. Because the Expr tree itself is read-only as far as
114 * ExecInitExpr and ExecEvalExpr are concerned, several different executions
115 * of the same plan tree can occur concurrently. (But note that an ExprState
116 * does mutate at runtime, so it can't be re-used concurrently.)
117 *
118 * This must be called in a memory context that will last as long as repeated
119 * executions of the expression are needed. Typically the context will be
120 * the same as the per-query context of the associated ExprContext.
121 *
122 * Any Aggref, WindowFunc, or SubPlan nodes found in the tree are added to
123 * the lists of such nodes held by the parent PlanState.
124 *
125 * Note: there is no ExecEndExpr function; we assume that any resource
126 * cleanup needed will be handled by just releasing the memory context
127 * in which the state tree is built. Functions that require additional
128 * cleanup work can register a shutdown callback in the ExprContext.
129 *
130 * 'node' is the root of the expression tree to compile.
131 * 'parent' is the PlanState node that owns the expression.
132 *
133 * 'parent' may be NULL if we are preparing an expression that is not
134 * associated with a plan tree. (If so, it can't have aggs or subplans.)
135 * Such cases should usually come through ExecPrepareExpr, not directly here.
136 *
137 * Also, if 'node' is NULL, we just return NULL. This is convenient for some
138 * callers that may or may not have an expression that needs to be compiled.
139 * Note that a NULL ExprState pointer *cannot* be handed to ExecEvalExpr,
140 * although ExecQual and ExecCheck will accept one (and treat it as "true").
141 */
142ExprState *
143ExecInitExpr(Expr *node, PlanState *parent)
144{
145 ExprState *state;
146 ExprEvalStep scratch = {0};
147
148 /* Special case: NULL expression produces a NULL ExprState pointer */
149 if (node == NULL)
150 return NULL;
151
152 /* Initialize ExprState with empty step list */
153 state = makeNode(ExprState);
154 state->expr = node;
155 state->parent = parent;
156 state->ext_params = NULL;
157
158 /* Insert setup steps as needed */
159 ExecCreateExprSetupSteps(state, (Node *) node);
160
161 /* Compile the expression proper */
162 ExecInitExprRec(node, state, &state->resvalue, &state->resnull);
163
164 /* Finally, append a DONE step */
165 scratch.opcode = EEOP_DONE_RETURN;
166 ExprEvalPushStep(state, &scratch);
167
168 ExecReadyExpr(state);
169
170 return state;
171}
172
173/*
174 * ExecInitExprWithParams: prepare a standalone expression tree for execution
175 *
176 * This is the same as ExecInitExpr, except that there is no parent PlanState,
177 * and instead we may have a ParamListInfo describing PARAM_EXTERN Params.
178 */
179ExprState *
180ExecInitExprWithParams(Expr *node, ParamListInfo ext_params)
181{
182 ExprState *state;
183 ExprEvalStep scratch = {0};
184
185 /* Special case: NULL expression produces a NULL ExprState pointer */
186 if (node == NULL)
187 return NULL;
188
189 /* Initialize ExprState with empty step list */
190 state = makeNode(ExprState);
191 state->expr = node;
192 state->parent = NULL;
193 state->ext_params = ext_params;
194
195 /* Insert setup steps as needed */
196 ExecCreateExprSetupSteps(state, (Node *) node);
197
198 /* Compile the expression proper */
199 ExecInitExprRec(node, state, &state->resvalue, &state->resnull);
200
201 /* Finally, append a DONE step */
202 scratch.opcode = EEOP_DONE_RETURN;
203 ExprEvalPushStep(state, &scratch);
204
205 ExecReadyExpr(state);
206
207 return state;
208}
209
210/*
211 * ExecInitQual: prepare a qual for execution by ExecQual
212 *
213 * Prepares for the evaluation of a conjunctive boolean expression (qual list
214 * with implicit AND semantics) that returns true if none of the
215 * subexpressions are false.
216 *
217 * We must return true if the list is empty. Since that's a very common case,
218 * we optimize it a bit further by translating to a NULL ExprState pointer
219 * rather than setting up an ExprState that computes constant TRUE. (Some
220 * especially hot-spot callers of ExecQual detect this and avoid calling
221 * ExecQual at all.)
222 *
223 * If any of the subexpressions yield NULL, then the result of the conjunction
224 * is false. This makes ExecQual primarily useful for evaluating WHERE
225 * clauses, since SQL specifies that tuples with null WHERE results do not
226 * get selected.
227 */
228ExprState *
229ExecInitQual(List *qual, PlanState *parent)
230{
231 ExprState *state;
232 ExprEvalStep scratch = {0};
233 List *adjust_jumps = NIL;
234
235 /* short-circuit (here and in ExecQual) for empty restriction list */
236 if (qual == NIL)
237 return NULL;
238
239 Assert(IsA(qual, List));
240
241 state = makeNode(ExprState);
242 state->expr = (Expr *) qual;
243 state->parent = parent;
244 state->ext_params = NULL;
245
246 /* mark expression as to be used with ExecQual() */
247 state->flags = EEO_FLAG_IS_QUAL;
248
249 /* Insert setup steps as needed */
250 ExecCreateExprSetupSteps(state, (Node *) qual);
251
252 /*
253 * ExecQual() needs to return false for an expression returning NULL. That
254 * allows us to short-circuit the evaluation the first time a NULL is
255 * encountered. As qual evaluation is a hot-path this warrants using a
256 * special opcode for qual evaluation that's simpler than BOOL_AND (which
257 * has more complex NULL handling).
258 */
259 scratch.opcode = EEOP_QUAL;
260
261 /*
262 * We can use ExprState's resvalue/resnull as target for each qual expr.
263 */
264 scratch.resvalue = &state->resvalue;
265 scratch.resnull = &state->resnull;
266
267 foreach_ptr(Expr, node, qual)
268 {
269 /* first evaluate expression */
270 ExecInitExprRec(node, state, &state->resvalue, &state->resnull);
271
272 /* then emit EEOP_QUAL to detect if it's false (or null) */
273 scratch.d.qualexpr.jumpdone = -1;
274 ExprEvalPushStep(state, &scratch);
275 adjust_jumps = lappend_int(adjust_jumps,
276 state->steps_len - 1);
277 }
278
279 /* adjust jump targets */
280 foreach_int(jump, adjust_jumps)
281 {
282 ExprEvalStep *as = &state->steps[jump];
283
284 Assert(as->opcode == EEOP_QUAL);
285 Assert(as->d.qualexpr.jumpdone == -1);
286 as->d.qualexpr.jumpdone = state->steps_len;
287 }
288
289 /*
290 * At the end, we don't need to do anything more. The last qual expr must
291 * have yielded TRUE, and since its result is stored in the desired output
292 * location, we're done.
293 */
294 scratch.opcode = EEOP_DONE_RETURN;
295 ExprEvalPushStep(state, &scratch);
296
297 ExecReadyExpr(state);
298
299 return state;
300}
301
302/*
303 * ExecInitCheck: prepare a check constraint for execution by ExecCheck
304 *
305 * This is much like ExecInitQual/ExecQual, except that a null result from
306 * the conjunction is treated as TRUE. This behavior is appropriate for
307 * evaluating CHECK constraints, since SQL specifies that NULL constraint
308 * conditions are not failures.
309 *
310 * Note that like ExecInitQual, this expects input in implicit-AND format.
311 * Users of ExecCheck that have expressions in normal explicit-AND format
312 * can just apply ExecInitExpr to produce suitable input for ExecCheck.
313 */
314ExprState *
315ExecInitCheck(List *qual, PlanState *parent)
316{
317 /* short-circuit (here and in ExecCheck) for empty restriction list */
318 if (qual == NIL)
319 return NULL;
320
321 Assert(IsA(qual, List));
322
323 /*
324 * Just convert the implicit-AND list to an explicit AND (if there's more
325 * than one entry), and compile normally. Unlike ExecQual, we can't
326 * short-circuit on NULL results, so the regular AND behavior is needed.
327 */
328 return ExecInitExpr(make_ands_explicit(qual), parent);
329}
330
331/*
332 * Call ExecInitExpr() on a list of expressions, return a list of ExprStates.
333 */
334List *
335ExecInitExprList(List *nodes, PlanState *parent)
336{
337 List *result = NIL;
338 ListCell *lc;
339
340 foreach(lc, nodes)
341 {
342 Expr *e = lfirst(lc);
343
344 result = lappend(result, ExecInitExpr(e, parent));
345 }
346
347 return result;
348}
349
350/*
351 * ExecBuildProjectionInfo
352 *
353 * Build a ProjectionInfo node for evaluating the given tlist in the given
354 * econtext, and storing the result into the tuple slot. (Caller must have
355 * ensured that tuple slot has a descriptor matching the tlist!)
356 *
357 * inputDesc can be NULL, but if it is not, we check to see whether simple
358 * Vars in the tlist match the descriptor. It is important to provide
359 * inputDesc for relation-scan plan nodes, as a cross check that the relation
360 * hasn't been changed since the plan was made. At higher levels of a plan,
361 * there is no need to recheck.
362 *
363 * This is implemented by internally building an ExprState that performs the
364 * whole projection in one go.
365 *
366 * Caution: before PG v10, the targetList was a list of ExprStates; now it
367 * should be the planner-created targetlist, since we do the compilation here.
368 */
369ProjectionInfo *
370ExecBuildProjectionInfo(List *targetList,
371 ExprContext *econtext,
372 TupleTableSlot *slot,
373 PlanState *parent,
374 TupleDesc inputDesc)
375{
376 ProjectionInfo *projInfo = makeNode(ProjectionInfo);
377 ExprState *state;
378 ExprEvalStep scratch = {0};
379 ListCell *lc;
380
381 projInfo->pi_exprContext = econtext;
382 /* We embed ExprState into ProjectionInfo instead of doing extra palloc */
383 projInfo->pi_state.type = T_ExprState;
384 state = &projInfo->pi_state;
385 state->expr = (Expr *) targetList;
386 state->parent = parent;
387 state->ext_params = NULL;
388
389 state->resultslot = slot;
390
391 /* Insert setup steps as needed */
392 ExecCreateExprSetupSteps(state, (Node *) targetList);
393
394 /* Now compile each tlist column */
395 foreach(lc, targetList)
396 {
397 TargetEntry *tle = lfirst_node(TargetEntry, lc);
398 Var *variable = NULL;
399 AttrNumber attnum = 0;
400 bool isSafeVar = false;
401
402 /*
403 * If tlist expression is a safe non-system Var, use the fast-path
404 * ASSIGN_*_VAR opcodes. "Safe" means that we don't need to apply
405 * CheckVarSlotCompatibility() during plan startup. If a source slot
406 * was provided, we make the equivalent tests here; if a slot was not
407 * provided, we assume that no check is needed because we're dealing
408 * with a non-relation-scan-level expression.
409 */
410 if (tle->expr != NULL &&
411 IsA(tle->expr, Var) &&
412 ((Var *) tle->expr)->varattno > 0)
413 {
414 /* Non-system Var, but how safe is it? */
415 variable = (Var *) tle->expr;
416 attnum = variable->varattno;
417
418 if (inputDesc == NULL)
419 isSafeVar = true; /* can't check, just assume OK */
420 else if (attnum <= inputDesc->natts)
421 {
422 Form_pg_attribute attr = TupleDescAttr(inputDesc, attnum - 1);
423
424 /*
425 * If user attribute is dropped or has a type mismatch, don't
426 * use ASSIGN_*_VAR. Instead let the normal expression
427 * machinery handle it (which'll possibly error out).
428 */
429 if (!attr->attisdropped && variable->vartype == attr->atttypid)
430 {
431 isSafeVar = true;
432 }
433 }
434 }
435
436 if (isSafeVar)
437 {
438 /* Fast-path: just generate an EEOP_ASSIGN_*_VAR step */
439 switch (variable->varno)
440 {
441 case INNER_VAR:
442 /* get the tuple from the inner node */
443 scratch.opcode = EEOP_ASSIGN_INNER_VAR;
444 break;
445
446 case OUTER_VAR:
447 /* get the tuple from the outer node */
448 scratch.opcode = EEOP_ASSIGN_OUTER_VAR;
449 break;
450
451 /* INDEX_VAR is handled by default case */
452
453 default:
454
455 /*
456 * Get the tuple from the relation being scanned, or the
457 * old/new tuple slot, if old/new values were requested.
458 */
459 switch (variable->varreturningtype)
460 {
461 case VAR_RETURNING_DEFAULT:
462 scratch.opcode = EEOP_ASSIGN_SCAN_VAR;
463 break;
464 case VAR_RETURNING_OLD:
465 scratch.opcode = EEOP_ASSIGN_OLD_VAR;
466 state->flags |= EEO_FLAG_HAS_OLD;
467 break;
468 case VAR_RETURNING_NEW:
469 scratch.opcode = EEOP_ASSIGN_NEW_VAR;
470 state->flags |= EEO_FLAG_HAS_NEW;
471 break;
472 }
473 break;
474 }
475
476 scratch.d.assign_var.attnum = attnum - 1;
477 scratch.d.assign_var.resultnum = tle->resno - 1;
478 ExprEvalPushStep(state, &scratch);
479 }
480 else
481 {
482 /*
483 * Otherwise, compile the column expression normally.
484 *
485 * We can't tell the expression to evaluate directly into the
486 * result slot, as the result slot (and the exprstate for that
487 * matter) can change between executions. We instead evaluate
488 * into the ExprState's resvalue/resnull and then move.
489 */
490 ExecInitExprRec(tle->expr, state,
491 &state->resvalue, &state->resnull);
492
493 /*
494 * Column might be referenced multiple times in upper nodes, so
495 * force value to R/O - but only if it could be an expanded datum.
496 */
497 if (get_typlen(exprType((Node *) tle->expr)) == -1)
498 scratch.opcode = EEOP_ASSIGN_TMP_MAKE_RO;
499 else
500 scratch.opcode = EEOP_ASSIGN_TMP;
501 scratch.d.assign_tmp.resultnum = tle->resno - 1;
502 ExprEvalPushStep(state, &scratch);
503 }
504 }
505
506 scratch.opcode = EEOP_DONE_NO_RETURN;
507 ExprEvalPushStep(state, &scratch);
508
509 ExecReadyExpr(state);
510
511 return projInfo;
512}
513
514/*
515 * ExecBuildUpdateProjection
516 *
517 * Build a ProjectionInfo node for constructing a new tuple during UPDATE.
518 * The projection will be executed in the given econtext and the result will
519 * be stored into the given tuple slot. (Caller must have ensured that tuple
520 * slot has a descriptor matching the target rel!)
521 *
522 * When evalTargetList is false, targetList contains the UPDATE ... SET
523 * expressions that have already been computed by a subplan node; the values
524 * from this tlist are assumed to be available in the "outer" tuple slot.
525 * When evalTargetList is true, targetList contains the UPDATE ... SET
526 * expressions that must be computed (which could contain references to
527 * the outer, inner, or scan tuple slots).
528 *
529 * In either case, targetColnos contains a list of the target column numbers
530 * corresponding to the non-resjunk entries of targetList. The tlist values
531 * are assigned into these columns of the result tuple slot. Target columns
532 * not listed in targetColnos are filled from the UPDATE's old tuple, which
533 * is assumed to be available in the "scan" tuple slot.
534 *
535 * targetList can also contain resjunk columns. These must be evaluated
536 * if evalTargetList is true, but their values are discarded.
537 *
538 * relDesc must describe the relation we intend to update.
539 *
540 * This is basically a specialized variant of ExecBuildProjectionInfo.
541 * However, it also performs sanity checks equivalent to ExecCheckPlanOutput.
542 * Since we never make a normal tlist equivalent to the whole
543 * tuple-to-be-assigned, there is no convenient way to apply
544 * ExecCheckPlanOutput, so we must do our safety checks here.
545 */
546ProjectionInfo *
547ExecBuildUpdateProjection(List *targetList,
548 bool evalTargetList,
549 List *targetColnos,
550 TupleDesc relDesc,
551 ExprContext *econtext,
552 TupleTableSlot *slot,
553 PlanState *parent)
554{
555 ProjectionInfo *projInfo = makeNode(ProjectionInfo);
556 ExprState *state;
557 int nAssignableCols;
558 bool sawJunk;
559 Bitmapset *assignedCols;
560 ExprSetupInfo deform = {0, 0, 0, 0, 0, NIL};
561 ExprEvalStep scratch = {0};
562 int outerattnum;
563 ListCell *lc,
564 *lc2;
565
566 projInfo->pi_exprContext = econtext;
567 /* We embed ExprState into ProjectionInfo instead of doing extra palloc */
568 projInfo->pi_state.type = T_ExprState;
569 state = &projInfo->pi_state;
570 if (evalTargetList)
571 state->expr = (Expr *) targetList;
572 else
573 state->expr = NULL; /* not used */
574 state->parent = parent;
575 state->ext_params = NULL;
576
577 state->resultslot = slot;
578
579 /*
580 * Examine the targetList to see how many non-junk columns there are, and
581 * to verify that the non-junk columns come before the junk ones.
582 */
583 nAssignableCols = 0;
584 sawJunk = false;
585 foreach(lc, targetList)
586 {
587 TargetEntry *tle = lfirst_node(TargetEntry, lc);
588
589 if (tle->resjunk)
590 sawJunk = true;
591 else
592 {
593 if (sawJunk)
594 elog(ERROR, "subplan target list is out of order");
595 nAssignableCols++;
596 }
597 }
598
599 /* We should have one targetColnos entry per non-junk column */
600 if (nAssignableCols != list_length(targetColnos))
601 elog(ERROR, "targetColnos does not match subplan target list");
602
603 /*
604 * Build a bitmapset of the columns in targetColnos. (We could just use
605 * list_member_int() tests, but that risks O(N^2) behavior with many
606 * columns.)
607 */
608 assignedCols = NULL;
609 foreach(lc, targetColnos)
610 {
611 AttrNumber targetattnum = lfirst_int(lc);
612
613 assignedCols = bms_add_member(assignedCols, targetattnum);
614 }
615
616 /*
617 * We need to insert EEOP_*_FETCHSOME steps to ensure the input tuples are
618 * sufficiently deconstructed. The scan tuple must be deconstructed at
619 * least as far as the last old column we need.
620 */
621 for (int attnum = relDesc->natts; attnum > 0; attnum--)
622 {
623 CompactAttribute *attr = TupleDescCompactAttr(relDesc, attnum - 1);
624
625 if (attr->attisdropped)
626 continue;
627 if (bms_is_member(attnum, assignedCols))
628 continue;
629 deform.last_scan = attnum;
630 break;
631 }
632
633 /*
634 * If we're actually evaluating the tlist, incorporate its input
635 * requirements too; otherwise, we'll just need to fetch the appropriate
636 * number of columns of the "outer" tuple.
637 */
638 if (evalTargetList)
639 expr_setup_walker((Node *) targetList, &deform);
640 else
641 deform.last_outer = nAssignableCols;
642
643 ExecPushExprSetupSteps(state, &deform);
644
645 /*
646 * Now generate code to evaluate the tlist's assignable expressions or
647 * fetch them from the outer tuple, incidentally validating that they'll
648 * be of the right data type. The checks above ensure that the forboth()
649 * will iterate over exactly the non-junk columns. Note that we don't
650 * bother evaluating any remaining resjunk columns.
651 */
652 outerattnum = 0;
653 forboth(lc, targetList, lc2, targetColnos)
654 {
655 TargetEntry *tle = lfirst_node(TargetEntry, lc);
656 AttrNumber targetattnum = lfirst_int(lc2);
657 Form_pg_attribute attr;
658
659 Assert(!tle->resjunk);
660
661 /*
662 * Apply sanity checks comparable to ExecCheckPlanOutput().
663 */
664 if (targetattnum <= 0 || targetattnum > relDesc->natts)
665 ereport(ERROR,
666 (errcode(ERRCODE_DATATYPE_MISMATCH),
667 errmsg("table row type and query-specified row type do not match"),
668 errdetail("Query has too many columns.")));
669 attr = TupleDescAttr(relDesc, targetattnum - 1);
670
671 if (attr->attisdropped)
672 ereport(ERROR,
673 (errcode(ERRCODE_DATATYPE_MISMATCH),
674 errmsg("table row type and query-specified row type do not match"),
675 errdetail("Query provides a value for a dropped column at ordinal position %d.",
676 targetattnum)));
677 if (exprType((Node *) tle->expr) != attr->atttypid)
678 ereport(ERROR,
679 (errcode(ERRCODE_DATATYPE_MISMATCH),
680 errmsg("table row type and query-specified row type do not match"),
681 errdetail("Table has type %s at ordinal position %d, but query expects %s.",
682 format_type_be(attr->atttypid),
683 targetattnum,
684 format_type_be(exprType((Node *) tle->expr)))));
685
686 /* OK, generate code to perform the assignment. */
687 if (evalTargetList)
688 {
689 /*
690 * We must evaluate the TLE's expression and assign it. We do not
691 * bother jumping through hoops for "safe" Vars like
692 * ExecBuildProjectionInfo does; this is a relatively less-used
693 * path and it doesn't seem worth expending code for that.
694 */
695 ExecInitExprRec(tle->expr, state,
696 &state->resvalue, &state->resnull);
697 /* Needn't worry about read-only-ness here, either. */
698 scratch.opcode = EEOP_ASSIGN_TMP;
699 scratch.d.assign_tmp.resultnum = targetattnum - 1;
700 ExprEvalPushStep(state, &scratch);
701 }
702 else
703 {
704 /* Just assign from the outer tuple. */
705 scratch.opcode = EEOP_ASSIGN_OUTER_VAR;
706 scratch.d.assign_var.attnum = outerattnum;
707 scratch.d.assign_var.resultnum = targetattnum - 1;
708 ExprEvalPushStep(state, &scratch);
709 }
710 outerattnum++;
711 }
712
713 /*
714 * Now generate code to copy over any old columns that were not assigned
715 * to, and to ensure that dropped columns are set to NULL.
716 */
717 for (int attnum = 1; attnum <= relDesc->natts; attnum++)
718 {
719 CompactAttribute *attr = TupleDescCompactAttr(relDesc, attnum - 1);
720
721 if (attr->attisdropped)
722 {
723 /* Put a null into the ExprState's resvalue/resnull ... */
724 scratch.opcode = EEOP_CONST;
725 scratch.resvalue = &state->resvalue;
726 scratch.resnull = &state->resnull;
727 scratch.d.constval.value = (Datum) 0;
728 scratch.d.constval.isnull = true;
729 ExprEvalPushStep(state, &scratch);
730 /* ... then assign it to the result slot */
731 scratch.opcode = EEOP_ASSIGN_TMP;
732 scratch.d.assign_tmp.resultnum = attnum - 1;
733 ExprEvalPushStep(state, &scratch);
734 }
735 else if (!bms_is_member(attnum, assignedCols))
736 {
737 /* Certainly the right type, so needn't check */
738 scratch.opcode = EEOP_ASSIGN_SCAN_VAR;
739 scratch.d.assign_var.attnum = attnum - 1;
740 scratch.d.assign_var.resultnum = attnum - 1;
741 ExprEvalPushStep(state, &scratch);
742 }
743 }
744
745 scratch.opcode = EEOP_DONE_NO_RETURN;
746 ExprEvalPushStep(state, &scratch);
747
748 ExecReadyExpr(state);
749
750 return projInfo;
751}
752
753/*
754 * ExecPrepareExpr --- initialize for expression execution outside a normal
755 * Plan tree context.
756 *
757 * This differs from ExecInitExpr in that we don't assume the caller is
758 * already running in the EState's per-query context. Also, we run the
759 * passed expression tree through expression_planner() to prepare it for
760 * execution. (In ordinary Plan trees the regular planning process will have
761 * made the appropriate transformations on expressions, but for standalone
762 * expressions this won't have happened.)
763 */
764ExprState *
765ExecPrepareExpr(Expr *node, EState *estate)
766{
767 ExprState *result;
768 MemoryContext oldcontext;
769
770 oldcontext = MemoryContextSwitchTo(estate->es_query_cxt);
771
772 node = expression_planner(node);
773
774 result = ExecInitExpr(node, NULL);
775
776 MemoryContextSwitchTo(oldcontext);
777
778 return result;
779}
780
781/*
782 * ExecPrepareQual --- initialize for qual execution outside a normal
783 * Plan tree context.
784 *
785 * This differs from ExecInitQual in that we don't assume the caller is
786 * already running in the EState's per-query context. Also, we run the
787 * passed expression tree through expression_planner() to prepare it for
788 * execution. (In ordinary Plan trees the regular planning process will have
789 * made the appropriate transformations on expressions, but for standalone
790 * expressions this won't have happened.)
791 */
792ExprState *
793ExecPrepareQual(List *qual, EState *estate)
794{
795 ExprState *result;
796 MemoryContext oldcontext;
797
798 oldcontext = MemoryContextSwitchTo(estate->es_query_cxt);
799
800 qual = (List *) expression_planner((Expr *) qual);
801
802 result = ExecInitQual(qual, NULL);
803
804 MemoryContextSwitchTo(oldcontext);
805
806 return result;
807}
808
809/*
810 * ExecPrepareCheck -- initialize check constraint for execution outside a
811 * normal Plan tree context.
812 *
813 * See ExecPrepareExpr() and ExecInitCheck() for details.
814 */
815ExprState *
816ExecPrepareCheck(List *qual, EState *estate)
817{
818 ExprState *result;
819 MemoryContext oldcontext;
820
821 oldcontext = MemoryContextSwitchTo(estate->es_query_cxt);
822
823 qual = (List *) expression_planner((Expr *) qual);
824
825 result = ExecInitCheck(qual, NULL);
826
827 MemoryContextSwitchTo(oldcontext);
828
829 return result;
830}
831
832/*
833 * Call ExecPrepareExpr() on each member of a list of Exprs, and return
834 * a list of ExprStates.
835 *
836 * See ExecPrepareExpr() for details.
837 */
838List *
839ExecPrepareExprList(List *nodes, EState *estate)
840{
841 List *result = NIL;
842 MemoryContext oldcontext;
843 ListCell *lc;
844
845 /* Ensure that the list cell nodes are in the right context too */
846 oldcontext = MemoryContextSwitchTo(estate->es_query_cxt);
847
848 foreach(lc, nodes)
849 {
850 Expr *e = (Expr *) lfirst(lc);
851
852 result = lappend(result, ExecPrepareExpr(e, estate));
853 }
854
855 MemoryContextSwitchTo(oldcontext);
856
857 return result;
858}
859
860/*
861 * ExecCheck - evaluate a check constraint
862 *
863 * For check constraints, a null result is taken as TRUE, ie the constraint
864 * passes.
865 *
866 * The check constraint may have been prepared with ExecInitCheck
867 * (possibly via ExecPrepareCheck) if the caller had it in implicit-AND
868 * format, but a regular boolean expression prepared with ExecInitExpr or
869 * ExecPrepareExpr works too.
870 */
871bool
872ExecCheck(ExprState *state, ExprContext *econtext)
873{
874 Datum ret;
875 bool isnull;
876
877 /* short-circuit (here and in ExecInitCheck) for empty restriction list */
878 if (state == NULL)
879 return true;
880
881 /* verify that expression was not compiled using ExecInitQual */
882 Assert(!(state->flags & EEO_FLAG_IS_QUAL));
883
884 ret = ExecEvalExprSwitchContext(state, econtext, &isnull);
885
886 if (isnull)
887 return true;
888
889 return DatumGetBool(ret);
890}
891
892/*
893 * Prepare a compiled expression for execution. This has to be called for
894 * every ExprState before it can be executed.
895 *
896 * NB: While this currently only calls ExecReadyInterpretedExpr(),
897 * this will likely get extended to further expression evaluation methods.
898 * Therefore this should be used instead of directly calling
899 * ExecReadyInterpretedExpr().
900 */
901static void
902ExecReadyExpr(ExprState *state)
903{
904 if (jit_compile_expr(state))
905 return;
906
907 ExecReadyInterpretedExpr(state);
908}
909
910/*
911 * Append the steps necessary for the evaluation of node to ExprState->steps,
912 * possibly recursing into sub-expressions of node.
913 *
914 * node - expression to evaluate
915 * state - ExprState to whose ->steps to append the necessary operations
916 * resv / resnull - where to store the result of the node into
917 */
918static void
919ExecInitExprRec(Expr *node, ExprState *state,
920 Datum *resv, bool *resnull)
921{
922 ExprEvalStep scratch = {0};
923
924 /* Guard against stack overflow due to overly complex expressions */
925 check_stack_depth();
926
927 /* Step's output location is always what the caller gave us */
928 Assert(resv != NULL && resnull != NULL);
929 scratch.resvalue = resv;
930 scratch.resnull = resnull;
931
932 /* cases should be ordered as they are in enum NodeTag */
933 switch (nodeTag(node))
934 {
935 case T_Var:
936 {
937 Var *variable = (Var *) node;
938
939 if (variable->varattno == InvalidAttrNumber)
940 {
941 /* whole-row Var */
942 ExecInitWholeRowVar(&scratch, variable, state);
943 }
944 else if (variable->varattno <= 0)
945 {
946 /* system column */
947 scratch.d.var.attnum = variable->varattno;
948 scratch.d.var.vartype = variable->vartype;
949 scratch.d.var.varreturningtype = variable->varreturningtype;
950 switch (variable->varno)
951 {
952 case INNER_VAR:
953 scratch.opcode = EEOP_INNER_SYSVAR;
954 break;
955 case OUTER_VAR:
956 scratch.opcode = EEOP_OUTER_SYSVAR;
957 break;
958
959 /* INDEX_VAR is handled by default case */
960
961 default:
962 switch (variable->varreturningtype)
963 {
964 case VAR_RETURNING_DEFAULT:
965 scratch.opcode = EEOP_SCAN_SYSVAR;
966 break;
967 case VAR_RETURNING_OLD:
968 scratch.opcode = EEOP_OLD_SYSVAR;
969 state->flags |= EEO_FLAG_HAS_OLD;
970 break;
971 case VAR_RETURNING_NEW:
972 scratch.opcode = EEOP_NEW_SYSVAR;
973 state->flags |= EEO_FLAG_HAS_NEW;
974 break;
975 }
976 break;
977 }
978 }
979 else
980 {
981 /* regular user column */
982 scratch.d.var.attnum = variable->varattno - 1;
983 scratch.d.var.vartype = variable->vartype;
984 scratch.d.var.varreturningtype = variable->varreturningtype;
985 switch (variable->varno)
986 {
987 case INNER_VAR:
988 scratch.opcode = EEOP_INNER_VAR;
989 break;
990 case OUTER_VAR:
991 scratch.opcode = EEOP_OUTER_VAR;
992 break;
993
994 /* INDEX_VAR is handled by default case */
995
996 default:
997 switch (variable->varreturningtype)
998 {
999 case VAR_RETURNING_DEFAULT:
1000 scratch.opcode = EEOP_SCAN_VAR;
1001 break;
1002 case VAR_RETURNING_OLD:
1003 scratch.opcode = EEOP_OLD_VAR;
1004 state->flags |= EEO_FLAG_HAS_OLD;
1005 break;
1006 case VAR_RETURNING_NEW:
1007 scratch.opcode = EEOP_NEW_VAR;
1008 state->flags |= EEO_FLAG_HAS_NEW;
1009 break;
1010 }
1011 break;
1012 }
1013 }
1014
1015 ExprEvalPushStep(state, &scratch);
1016 break;
1017 }
1018
1019 case T_Const:
1020 {
1021 Const *con = (Const *) node;
1022
1023 scratch.opcode = EEOP_CONST;
1024 scratch.d.constval.value = con->constvalue;
1025 scratch.d.constval.isnull = con->constisnull;
1026
1027 ExprEvalPushStep(state, &scratch);
1028 break;
1029 }
1030
1031 case T_Param:
1032 {
1033 Param *param = (Param *) node;
1034 ParamListInfo params;
1035
1036 switch (param->paramkind)
1037 {
1038 case PARAM_EXEC:
1039 scratch.opcode = EEOP_PARAM_EXEC;
1040 scratch.d.param.paramid = param->paramid;
1041 scratch.d.param.paramtype = param->paramtype;
1042 ExprEvalPushStep(state, &scratch);
1043 break;
1044 case PARAM_EXTERN:
1045
1046 /*
1047 * If we have a relevant ParamCompileHook, use it;
1048 * otherwise compile a standard EEOP_PARAM_EXTERN
1049 * step. ext_params, if supplied, takes precedence
1050 * over info from the parent node's EState (if any).
1051 */
1052 if (state->ext_params)
1053 params = state->ext_params;
1054 else if (state->parent &&
1055 state->parent->state)
1056 params = state->parent->state->es_param_list_info;
1057 else
1058 params = NULL;
1059 if (params && params->paramCompile)
1060 {
1061 params->paramCompile(params, param, state,
1062 resv, resnull);
1063 }
1064 else
1065 {
1066 scratch.opcode = EEOP_PARAM_EXTERN;
1067 scratch.d.param.paramid = param->paramid;
1068 scratch.d.param.paramtype = param->paramtype;
1069 ExprEvalPushStep(state, &scratch);
1070 }
1071 break;
1072 default:
1073 elog(ERROR, "unrecognized paramkind: %d",
1074 (int) param->paramkind);
1075 break;
1076 }
1077 break;
1078 }
1079
1080 case T_Aggref:
1081 {
1082 Aggref *aggref = (Aggref *) node;
1083
1084 scratch.opcode = EEOP_AGGREF;
1085 scratch.d.aggref.aggno = aggref->aggno;
1086
1087 if (state->parent && IsA(state->parent, AggState))
1088 {
1089 AggState *aggstate = (AggState *) state->parent;
1090
1091 aggstate->aggs = lappend(aggstate->aggs, aggref);
1092 }
1093 else
1094 {
1095 /* planner messed up */
1096 elog(ERROR, "Aggref found in non-Agg plan node");
1097 }
1098
1099 ExprEvalPushStep(state, &scratch);
1100 break;
1101 }
1102
1103 case T_GroupingFunc:
1104 {
1105 GroupingFunc *grp_node = (GroupingFunc *) node;
1106 Agg *agg;
1107
1108 if (!state->parent || !IsA(state->parent, AggState) ||
1109 !IsA(state->parent->plan, Agg))
1110 elog(ERROR, "GroupingFunc found in non-Agg plan node");
1111
1112 scratch.opcode = EEOP_GROUPING_FUNC;
1113
1114 agg = (Agg *) (state->parent->plan);
1115
1116 if (agg->groupingSets)
1117 scratch.d.grouping_func.clauses = grp_node->cols;
1118 else
1119 scratch.d.grouping_func.clauses = NIL;
1120
1121 ExprEvalPushStep(state, &scratch);
1122 break;
1123 }
1124
1125 case T_WindowFunc:
1126 {
1127 WindowFunc *wfunc = (WindowFunc *) node;
1128 WindowFuncExprState *wfstate = makeNode(WindowFuncExprState);
1129
1130 wfstate->wfunc = wfunc;
1131
1132 if (state->parent && IsA(state->parent, WindowAggState))
1133 {
1134 WindowAggState *winstate = (WindowAggState *) state->parent;
1135 int nfuncs;
1136
1137 winstate->funcs = lappend(winstate->funcs, wfstate);
1138 nfuncs = ++winstate->numfuncs;
1139 if (wfunc->winagg)
1140 winstate->numaggs++;
1141
1142 /* for now initialize agg using old style expressions */
1143 wfstate->args = ExecInitExprList(wfunc->args,
1144 state->parent);
1145 wfstate->aggfilter = ExecInitExpr(wfunc->aggfilter,
1146 state->parent);
1147
1148 /*
1149 * Complain if the windowfunc's arguments contain any
1150 * windowfuncs; nested window functions are semantically
1151 * nonsensical. (This should have been caught earlier,
1152 * but we defend against it here anyway.)
1153 */
1154 if (nfuncs != winstate->numfuncs)
1155 ereport(ERROR,
1156 (errcode(ERRCODE_WINDOWING_ERROR),
1157 errmsg("window function calls cannot be nested")));
1158 }
1159 else
1160 {
1161 /* planner messed up */
1162 elog(ERROR, "WindowFunc found in non-WindowAgg plan node");
1163 }
1164
1165 scratch.opcode = EEOP_WINDOW_FUNC;
1166 scratch.d.window_func.wfstate = wfstate;
1167 ExprEvalPushStep(state, &scratch);
1168 break;
1169 }
1170
1171 case T_MergeSupportFunc:
1172 {
1173 /* must be in a MERGE, else something messed up */
1174 if (!state->parent ||
1175 !IsA(state->parent, ModifyTableState) ||
1176 ((ModifyTableState *) state->parent)->operation != CMD_MERGE)
1177 elog(ERROR, "MergeSupportFunc found in non-merge plan node");
1178
1179 scratch.opcode = EEOP_MERGE_SUPPORT_FUNC;
1180 ExprEvalPushStep(state, &scratch);
1181 break;
1182 }
1183
1184 case T_SubscriptingRef:
1185 {
1186 SubscriptingRef *sbsref = (SubscriptingRef *) node;
1187
1188 ExecInitSubscriptingRef(&scratch, sbsref, state, resv, resnull);
1189 break;
1190 }
1191
1192 case T_FuncExpr:
1193 {
1194 FuncExpr *func = (FuncExpr *) node;
1195
1196 ExecInitFunc(&scratch, node,
1197 func->args, func->funcid, func->inputcollid,
1198 state);
1199 ExprEvalPushStep(state, &scratch);
1200 break;
1201 }
1202
1203 case T_OpExpr:
1204 {
1205 OpExpr *op = (OpExpr *) node;
1206
1207 ExecInitFunc(&scratch, node,
1208 op->args, op->opfuncid, op->inputcollid,
1209 state);
1210 ExprEvalPushStep(state, &scratch);
1211 break;
1212 }
1213
1214 case T_DistinctExpr:
1215 {
1216 DistinctExpr *op = (DistinctExpr *) node;
1217
1218 ExecInitFunc(&scratch, node,
1219 op->args, op->opfuncid, op->inputcollid,
1220 state);
1221
1222 /*
1223 * Change opcode of call instruction to EEOP_DISTINCT.
1224 *
1225 * XXX: historically we've not called the function usage
1226 * pgstat infrastructure - that seems inconsistent given that
1227 * we do so for normal function *and* operator evaluation. If
1228 * we decided to do that here, we'd probably want separate
1229 * opcodes for FUSAGE or not.
1230 */
1231 scratch.opcode = EEOP_DISTINCT;
1232 ExprEvalPushStep(state, &scratch);
1233 break;
1234 }
1235
1236 case T_NullIfExpr:
1237 {
1238 NullIfExpr *op = (NullIfExpr *) node;
1239
1240 ExecInitFunc(&scratch, node,
1241 op->args, op->opfuncid, op->inputcollid,
1242 state);
1243
1244 /*
1245 * If first argument is of varlena type, we'll need to ensure
1246 * that the value passed to the comparison function is a
1247 * read-only pointer.
1248 */
1249 scratch.d.func.make_ro =
1250 (get_typlen(exprType((Node *) linitial(op->args))) == -1);
1251
1252 /*
1253 * Change opcode of call instruction to EEOP_NULLIF.
1254 *
1255 * XXX: historically we've not called the function usage
1256 * pgstat infrastructure - that seems inconsistent given that
1257 * we do so for normal function *and* operator evaluation. If
1258 * we decided to do that here, we'd probably want separate
1259 * opcodes for FUSAGE or not.
1260 */
1261 scratch.opcode = EEOP_NULLIF;
1262 ExprEvalPushStep(state, &scratch);
1263 break;
1264 }
1265
1266 case T_ScalarArrayOpExpr:
1267 {
1268 ScalarArrayOpExpr *opexpr = (ScalarArrayOpExpr *) node;
1269 Expr *scalararg;
1270 Expr *arrayarg;
1271 FmgrInfo *finfo;
1272 FunctionCallInfo fcinfo;
1273 AclResult aclresult;
1274 Oid cmpfuncid;
1275
1276 /*
1277 * Select the correct comparison function. When we do hashed
1278 * NOT IN clauses, the opfuncid will be the inequality
1279 * comparison function and negfuncid will be set to equality.
1280 * We need to use the equality function for hash probes.
1281 */
1282 if (OidIsValid(opexpr->negfuncid))
1283 {
1284 Assert(OidIsValid(opexpr->hashfuncid));
1285 cmpfuncid = opexpr->negfuncid;
1286 }
1287 else
1288 cmpfuncid = opexpr->opfuncid;
1289
1290 Assert(list_length(opexpr->args) == 2);
1291 scalararg = (Expr *) linitial(opexpr->args);
1292 arrayarg = (Expr *) lsecond(opexpr->args);
1293
1294 /* Check permission to call function */
1295 aclresult = object_aclcheck(ProcedureRelationId, cmpfuncid,
1296 GetUserId(),
1297 ACL_EXECUTE);
1298 if (aclresult != ACLCHECK_OK)
1299 aclcheck_error(aclresult, OBJECT_FUNCTION,
1300 get_func_name(cmpfuncid));
1301 InvokeFunctionExecuteHook(cmpfuncid);
1302
1303 if (OidIsValid(opexpr->hashfuncid))
1304 {
1305 aclresult = object_aclcheck(ProcedureRelationId, opexpr->hashfuncid,
1306 GetUserId(),
1307 ACL_EXECUTE);
1308 if (aclresult != ACLCHECK_OK)
1309 aclcheck_error(aclresult, OBJECT_FUNCTION,
1310 get_func_name(opexpr->hashfuncid));
1311 InvokeFunctionExecuteHook(opexpr->hashfuncid);
1312 }
1313
1314 /* Set up the primary fmgr lookup information */
1315 finfo = palloc0(sizeof(FmgrInfo));
1316 fcinfo = palloc0(SizeForFunctionCallInfo(2));
1317 fmgr_info(cmpfuncid, finfo);
1318 fmgr_info_set_expr((Node *) node, finfo);
1319 InitFunctionCallInfoData(*fcinfo, finfo, 2,
1320 opexpr->inputcollid, NULL, NULL);
1321
1322 /*
1323 * If hashfuncid is set, we create a EEOP_HASHED_SCALARARRAYOP
1324 * step instead of a EEOP_SCALARARRAYOP. This provides much
1325 * faster lookup performance than the normal linear search
1326 * when the number of items in the array is anything but very
1327 * small.
1328 */
1329 if (OidIsValid(opexpr->hashfuncid))
1330 {
1331 /* Evaluate scalar directly into left function argument */
1332 ExecInitExprRec(scalararg, state,
1333 &fcinfo->args[0].value, &fcinfo->args[0].isnull);
1334
1335 /*
1336 * Evaluate array argument into our return value. There's
1337 * no danger in that, because the return value is
1338 * guaranteed to be overwritten by
1339 * EEOP_HASHED_SCALARARRAYOP, and will not be passed to
1340 * any other expression.
1341 */
1342 ExecInitExprRec(arrayarg, state, resv, resnull);
1343
1344 /* And perform the operation */
1345 scratch.opcode = EEOP_HASHED_SCALARARRAYOP;
1346 scratch.d.hashedscalararrayop.inclause = opexpr->useOr;
1347 scratch.d.hashedscalararrayop.finfo = finfo;
1348 scratch.d.hashedscalararrayop.fcinfo_data = fcinfo;
1349 scratch.d.hashedscalararrayop.saop = opexpr;
1350
1351
1352 ExprEvalPushStep(state, &scratch);
1353 }
1354 else
1355 {
1356 /* Evaluate scalar directly into left function argument */
1357 ExecInitExprRec(scalararg, state,
1358 &fcinfo->args[0].value,
1359 &fcinfo->args[0].isnull);
1360
1361 /*
1362 * Evaluate array argument into our return value. There's
1363 * no danger in that, because the return value is
1364 * guaranteed to be overwritten by EEOP_SCALARARRAYOP, and
1365 * will not be passed to any other expression.
1366 */
1367 ExecInitExprRec(arrayarg, state, resv, resnull);
1368
1369 /* And perform the operation */
1370 scratch.opcode = EEOP_SCALARARRAYOP;
1371 scratch.d.scalararrayop.element_type = InvalidOid;
1372 scratch.d.scalararrayop.useOr = opexpr->useOr;
1373 scratch.d.scalararrayop.finfo = finfo;
1374 scratch.d.scalararrayop.fcinfo_data = fcinfo;
1375 scratch.d.scalararrayop.fn_addr = finfo->fn_addr;
1376 ExprEvalPushStep(state, &scratch);
1377 }
1378 break;
1379 }
1380
1381 case T_BoolExpr:
1382 {
1383 BoolExpr *boolexpr = (BoolExpr *) node;
1384 int nargs = list_length(boolexpr->args);
1385 List *adjust_jumps = NIL;
1386 int off;
1387 ListCell *lc;
1388
1389 /* allocate scratch memory used by all steps of AND/OR */
1390 if (boolexpr->boolop != NOT_EXPR)
1391 scratch.d.boolexpr.anynull = (bool *) palloc(sizeof(bool));
1392
1393 /*
1394 * For each argument evaluate the argument itself, then
1395 * perform the bool operation's appropriate handling.
1396 *
1397 * We can evaluate each argument into our result area, since
1398 * the short-circuiting logic means we only need to remember
1399 * previous NULL values.
1400 *
1401 * AND/OR is split into separate STEP_FIRST (one) / STEP (zero
1402 * or more) / STEP_LAST (one) steps, as each of those has to
1403 * perform different work. The FIRST/LAST split is valid
1404 * because AND/OR have at least two arguments.
1405 */
1406 off = 0;
1407 foreach(lc, boolexpr->args)
1408 {
1409 Expr *arg = (Expr *) lfirst(lc);
1410
1411 /* Evaluate argument into our output variable */
1412 ExecInitExprRec(arg, state, resv, resnull);
1413
1414 /* Perform the appropriate step type */
1415 switch (boolexpr->boolop)
1416 {
1417 case AND_EXPR:
1418 Assert(nargs >= 2);
1419
1420 if (off == 0)
1421 scratch.opcode = EEOP_BOOL_AND_STEP_FIRST;
1422 else if (off + 1 == nargs)
1423 scratch.opcode = EEOP_BOOL_AND_STEP_LAST;
1424 else
1425 scratch.opcode = EEOP_BOOL_AND_STEP;
1426 break;
1427 case OR_EXPR:
1428 Assert(nargs >= 2);
1429
1430 if (off == 0)
1431 scratch.opcode = EEOP_BOOL_OR_STEP_FIRST;
1432 else if (off + 1 == nargs)
1433 scratch.opcode = EEOP_BOOL_OR_STEP_LAST;
1434 else
1435 scratch.opcode = EEOP_BOOL_OR_STEP;
1436 break;
1437 case NOT_EXPR:
1438 Assert(nargs == 1);
1439
1440 scratch.opcode = EEOP_BOOL_NOT_STEP;
1441 break;
1442 default:
1443 elog(ERROR, "unrecognized boolop: %d",
1444 (int) boolexpr->boolop);
1445 break;
1446 }
1447
1448 scratch.d.boolexpr.jumpdone = -1;
1449 ExprEvalPushStep(state, &scratch);
1450 adjust_jumps = lappend_int(adjust_jumps,
1451 state->steps_len - 1);
1452 off++;
1453 }
1454
1455 /* adjust jump targets */
1456 foreach(lc, adjust_jumps)
1457 {
1458 ExprEvalStep *as = &state->steps[lfirst_int(lc)];
1459
1460 Assert(as->d.boolexpr.jumpdone == -1);
1461 as->d.boolexpr.jumpdone = state->steps_len;
1462 }
1463
1464 break;
1465 }
1466
1467 case T_SubPlan:
1468 {
1469 SubPlan *subplan = (SubPlan *) node;
1470
1471 /*
1472 * Real execution of a MULTIEXPR SubPlan has already been
1473 * done. What we have to do here is return a dummy NULL record
1474 * value in case this targetlist element is assigned
1475 * someplace.
1476 */
1477 if (subplan->subLinkType == MULTIEXPR_SUBLINK)
1478 {
1479 scratch.opcode = EEOP_CONST;
1480 scratch.d.constval.value = (Datum) 0;
1481 scratch.d.constval.isnull = true;
1482 ExprEvalPushStep(state, &scratch);
1483 break;
1484 }
1485
1486 ExecInitSubPlanExpr(subplan, state, resv, resnull);
1487 break;
1488 }
1489
1490 case T_FieldSelect:
1491 {
1492 FieldSelect *fselect = (FieldSelect *) node;
1493
1494 /* evaluate row/record argument into result area */
1495 ExecInitExprRec(fselect->arg, state, resv, resnull);
1496
1497 /* and extract field */
1498 scratch.opcode = EEOP_FIELDSELECT;
1499 scratch.d.fieldselect.fieldnum = fselect->fieldnum;
1500 scratch.d.fieldselect.resulttype = fselect->resulttype;
1501 scratch.d.fieldselect.rowcache.cacheptr = NULL;
1502
1503 ExprEvalPushStep(state, &scratch);
1504 break;
1505 }
1506
1507 case T_FieldStore:
1508 {
1509 FieldStore *fstore = (FieldStore *) node;
1510 TupleDesc tupDesc;
1511 ExprEvalRowtypeCache *rowcachep;
1512 Datum *values;
1513 bool *nulls;
1514 int ncolumns;
1515 ListCell *l1,
1516 *l2;
1517
1518 /* find out the number of columns in the composite type */
1519 tupDesc = lookup_rowtype_tupdesc(fstore->resulttype, -1);
1520 ncolumns = tupDesc->natts;
1521 ReleaseTupleDesc(tupDesc);
1522
1523 /* create workspace for column values */
1524 values = (Datum *) palloc(sizeof(Datum) * ncolumns);
1525 nulls = (bool *) palloc(sizeof(bool) * ncolumns);
1526
1527 /* create shared composite-type-lookup cache struct */
1528 rowcachep = palloc(sizeof(ExprEvalRowtypeCache));
1529 rowcachep->cacheptr = NULL;
1530
1531 /* emit code to evaluate the composite input value */
1532 ExecInitExprRec(fstore->arg, state, resv, resnull);
1533
1534 /* next, deform the input tuple into our workspace */
1535 scratch.opcode = EEOP_FIELDSTORE_DEFORM;
1536 scratch.d.fieldstore.fstore = fstore;
1537 scratch.d.fieldstore.rowcache = rowcachep;
1538 scratch.d.fieldstore.values = values;
1539 scratch.d.fieldstore.nulls = nulls;
1540 scratch.d.fieldstore.ncolumns = ncolumns;
1541 ExprEvalPushStep(state, &scratch);
1542
1543 /* evaluate new field values, store in workspace columns */
1544 forboth(l1, fstore->newvals, l2, fstore->fieldnums)
1545 {
1546 Expr *e = (Expr *) lfirst(l1);
1547 AttrNumber fieldnum = lfirst_int(l2);
1548 Datum *save_innermost_caseval;
1549 bool *save_innermost_casenull;
1550
1551 if (fieldnum <= 0 || fieldnum > ncolumns)
1552 elog(ERROR, "field number %d is out of range in FieldStore",
1553 fieldnum);
1554
1555 /*
1556 * Use the CaseTestExpr mechanism to pass down the old
1557 * value of the field being replaced; this is needed in
1558 * case the newval is itself a FieldStore or
1559 * SubscriptingRef that has to obtain and modify the old
1560 * value. It's safe to reuse the CASE mechanism because
1561 * there cannot be a CASE between here and where the value
1562 * would be needed, and a field assignment can't be within
1563 * a CASE either. (So saving and restoring
1564 * innermost_caseval is just paranoia, but let's do it
1565 * anyway.)
1566 *
1567 * Another non-obvious point is that it's safe to use the
1568 * field's values[]/nulls[] entries as both the caseval
1569 * source and the result address for this subexpression.
1570 * That's okay only because (1) both FieldStore and
1571 * SubscriptingRef evaluate their arg or refexpr inputs
1572 * first, and (2) any such CaseTestExpr is directly the
1573 * arg or refexpr input. So any read of the caseval will
1574 * occur before there's a chance to overwrite it. Also,
1575 * if multiple entries in the newvals/fieldnums lists
1576 * target the same field, they'll effectively be applied
1577 * left-to-right which is what we want.
1578 */
1579 save_innermost_caseval = state->innermost_caseval;
1580 save_innermost_casenull = state->innermost_casenull;
1581 state->innermost_caseval = &values[fieldnum - 1];
1582 state->innermost_casenull = &nulls[fieldnum - 1];
1583
1584 ExecInitExprRec(e, state,
1585 &values[fieldnum - 1],
1586 &nulls[fieldnum - 1]);
1587
1588 state->innermost_caseval = save_innermost_caseval;
1589 state->innermost_casenull = save_innermost_casenull;
1590 }
1591
1592 /* finally, form result tuple */
1593 scratch.opcode = EEOP_FIELDSTORE_FORM;
1594 scratch.d.fieldstore.fstore = fstore;
1595 scratch.d.fieldstore.rowcache = rowcachep;
1596 scratch.d.fieldstore.values = values;
1597 scratch.d.fieldstore.nulls = nulls;
1598 scratch.d.fieldstore.ncolumns = ncolumns;
1599 ExprEvalPushStep(state, &scratch);
1600 break;
1601 }
1602
1603 case T_RelabelType:
1604 {
1605 /* relabel doesn't need to do anything at runtime */
1606 RelabelType *relabel = (RelabelType *) node;
1607
1608 ExecInitExprRec(relabel->arg, state, resv, resnull);
1609 break;
1610 }
1611
1612 case T_CoerceViaIO:
1613 {
1614 CoerceViaIO *iocoerce = (CoerceViaIO *) node;
1615 Oid iofunc;
1616 bool typisvarlena;
1617 Oid typioparam;
1618 FunctionCallInfo fcinfo_in;
1619
1620 /* evaluate argument into step's result area */
1621 ExecInitExprRec(iocoerce->arg, state, resv, resnull);
1622
1623 /*
1624 * Prepare both output and input function calls, to be
1625 * evaluated inside a single evaluation step for speed - this
1626 * can be a very common operation.
1627 *
1628 * We don't check permissions here as a type's input/output
1629 * function are assumed to be executable by everyone.
1630 */
1631 if (state->escontext == NULL)
1632 scratch.opcode = EEOP_IOCOERCE;
1633 else
1634 scratch.opcode = EEOP_IOCOERCE_SAFE;
1635
1636 /* lookup the source type's output function */
1637 scratch.d.iocoerce.finfo_out = palloc0(sizeof(FmgrInfo));
1638 scratch.d.iocoerce.fcinfo_data_out = palloc0(SizeForFunctionCallInfo(1));
1639
1640 getTypeOutputInfo(exprType((Node *) iocoerce->arg),
1641 &iofunc, &typisvarlena);
1642 fmgr_info(iofunc, scratch.d.iocoerce.finfo_out);
1643 fmgr_info_set_expr((Node *) node, scratch.d.iocoerce.finfo_out);
1644 InitFunctionCallInfoData(*scratch.d.iocoerce.fcinfo_data_out,
1645 scratch.d.iocoerce.finfo_out,
1646 1, InvalidOid, NULL, NULL);
1647
1648 /* lookup the result type's input function */
1649 scratch.d.iocoerce.finfo_in = palloc0(sizeof(FmgrInfo));
1650 scratch.d.iocoerce.fcinfo_data_in = palloc0(SizeForFunctionCallInfo(3));
1651
1652 getTypeInputInfo(iocoerce->resulttype,
1653 &iofunc, &typioparam);
1654 fmgr_info(iofunc, scratch.d.iocoerce.finfo_in);
1655 fmgr_info_set_expr((Node *) node, scratch.d.iocoerce.finfo_in);
1656 InitFunctionCallInfoData(*scratch.d.iocoerce.fcinfo_data_in,
1657 scratch.d.iocoerce.finfo_in,
1658 3, InvalidOid, NULL, NULL);
1659
1660 /*
1661 * We can preload the second and third arguments for the input
1662 * function, since they're constants.
1663 */
1664 fcinfo_in = scratch.d.iocoerce.fcinfo_data_in;
1665 fcinfo_in->args[1].value = ObjectIdGetDatum(typioparam);
1666 fcinfo_in->args[1].isnull = false;
1667 fcinfo_in->args[2].value = Int32GetDatum(-1);
1668 fcinfo_in->args[2].isnull = false;
1669
1670 fcinfo_in->context = (Node *) state->escontext;
1671
1672 ExprEvalPushStep(state, &scratch);
1673 break;
1674 }
1675
1676 case T_ArrayCoerceExpr:
1677 {
1678 ArrayCoerceExpr *acoerce = (ArrayCoerceExpr *) node;
1679 Oid resultelemtype;
1680 ExprState *elemstate;
1681
1682 /* evaluate argument into step's result area */
1683 ExecInitExprRec(acoerce->arg, state, resv, resnull);
1684
1685 resultelemtype = get_element_type(acoerce->resulttype);
1686 if (!OidIsValid(resultelemtype))
1687 ereport(ERROR,
1688 (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
1689 errmsg("target type is not an array")));
1690
1691 /*
1692 * Construct a sub-expression for the per-element expression;
1693 * but don't ready it until after we check it for triviality.
1694 * We assume it hasn't any Var references, but does have a
1695 * CaseTestExpr representing the source array element values.
1696 */
1697 elemstate = makeNode(ExprState);
1698 elemstate->expr = acoerce->elemexpr;
1699 elemstate->parent = state->parent;
1700 elemstate->ext_params = state->ext_params;
1701
1702 elemstate->innermost_caseval = (Datum *) palloc(sizeof(Datum));
1703 elemstate->innermost_casenull = (bool *) palloc(sizeof(bool));
1704
1705 ExecInitExprRec(acoerce->elemexpr, elemstate,
1706 &elemstate->resvalue, &elemstate->resnull);
1707
1708 if (elemstate->steps_len == 1 &&
1709 elemstate->steps[0].opcode == EEOP_CASE_TESTVAL)
1710 {
1711 /* Trivial, so we need no per-element work at runtime */
1712 elemstate = NULL;
1713 }
1714 else
1715 {
1716 /* Not trivial, so append a DONE step */
1717 scratch.opcode = EEOP_DONE_RETURN;
1718 ExprEvalPushStep(elemstate, &scratch);
1719 /* and ready the subexpression */
1720 ExecReadyExpr(elemstate);
1721 }
1722
1723 scratch.opcode = EEOP_ARRAYCOERCE;
1724 scratch.d.arraycoerce.elemexprstate = elemstate;
1725 scratch.d.arraycoerce.resultelemtype = resultelemtype;
1726
1727 if (elemstate)
1728 {
1729 /* Set up workspace for array_map */
1730 scratch.d.arraycoerce.amstate =
1731 (ArrayMapState *) palloc0(sizeof(ArrayMapState));
1732 }
1733 else
1734 {
1735 /* Don't need workspace if there's no subexpression */
1736 scratch.d.arraycoerce.amstate = NULL;
1737 }
1738
1739 ExprEvalPushStep(state, &scratch);
1740 break;
1741 }
1742
1743 case T_ConvertRowtypeExpr:
1744 {
1745 ConvertRowtypeExpr *convert = (ConvertRowtypeExpr *) node;
1746 ExprEvalRowtypeCache *rowcachep;
1747
1748 /* cache structs must be out-of-line for space reasons */
1749 rowcachep = palloc(2 * sizeof(ExprEvalRowtypeCache));
1750 rowcachep[0].cacheptr = NULL;
1751 rowcachep[1].cacheptr = NULL;
1752
1753 /* evaluate argument into step's result area */
1754 ExecInitExprRec(convert->arg, state, resv, resnull);
1755
1756 /* and push conversion step */
1757 scratch.opcode = EEOP_CONVERT_ROWTYPE;
1758 scratch.d.convert_rowtype.inputtype =
1759 exprType((Node *) convert->arg);
1760 scratch.d.convert_rowtype.outputtype = convert->resulttype;
1761 scratch.d.convert_rowtype.incache = &rowcachep[0];
1762 scratch.d.convert_rowtype.outcache = &rowcachep[1];
1763 scratch.d.convert_rowtype.map = NULL;
1764
1765 ExprEvalPushStep(state, &scratch);
1766 break;
1767 }
1768
1769 /* note that CaseWhen expressions are handled within this block */
1770 case T_CaseExpr:
1771 {
1772 CaseExpr *caseExpr = (CaseExpr *) node;
1773 List *adjust_jumps = NIL;
1774 Datum *caseval = NULL;
1775 bool *casenull = NULL;
1776 ListCell *lc;
1777
1778 /*
1779 * If there's a test expression, we have to evaluate it and
1780 * save the value where the CaseTestExpr placeholders can find
1781 * it.
1782 */
1783 if (caseExpr->arg != NULL)
1784 {
1785 /* Evaluate testexpr into caseval/casenull workspace */
1786 caseval = palloc(sizeof(Datum));
1787 casenull = palloc(sizeof(bool));
1788
1789 ExecInitExprRec(caseExpr->arg, state,
1790 caseval, casenull);
1791
1792 /*
1793 * Since value might be read multiple times, force to R/O
1794 * - but only if it could be an expanded datum.
1795 */
1796 if (get_typlen(exprType((Node *) caseExpr->arg)) == -1)
1797 {
1798 /* change caseval in-place */
1799 scratch.opcode = EEOP_MAKE_READONLY;
1800 scratch.resvalue = caseval;
1801 scratch.resnull = casenull;
1802 scratch.d.make_readonly.value = caseval;
1803 scratch.d.make_readonly.isnull = casenull;
1804 ExprEvalPushStep(state, &scratch);
1805 /* restore normal settings of scratch fields */
1806 scratch.resvalue = resv;
1807 scratch.resnull = resnull;
1808 }
1809 }
1810
1811 /*
1812 * Prepare to evaluate each of the WHEN clauses in turn; as
1813 * soon as one is true we return the value of the
1814 * corresponding THEN clause. If none are true then we return
1815 * the value of the ELSE clause, or NULL if there is none.
1816 */
1817 foreach(lc, caseExpr->args)
1818 {
1819 CaseWhen *when = (CaseWhen *) lfirst(lc);
1820 Datum *save_innermost_caseval;
1821 bool *save_innermost_casenull;
1822 int whenstep;
1823
1824 /*
1825 * Make testexpr result available to CaseTestExpr nodes
1826 * within the condition. We must save and restore prior
1827 * setting of innermost_caseval fields, in case this node
1828 * is itself within a larger CASE.
1829 *
1830 * If there's no test expression, we don't actually need
1831 * to save and restore these fields; but it's less code to
1832 * just do so unconditionally.
1833 */
1834 save_innermost_caseval = state->innermost_caseval;
1835 save_innermost_casenull = state->innermost_casenull;
1836 state->innermost_caseval = caseval;
1837 state->innermost_casenull = casenull;
1838
1839 /* evaluate condition into CASE's result variables */
1840 ExecInitExprRec(when->expr, state, resv, resnull);
1841
1842 state->innermost_caseval = save_innermost_caseval;
1843 state->innermost_casenull = save_innermost_casenull;
1844
1845 /* If WHEN result isn't true, jump to next CASE arm */
1846 scratch.opcode = EEOP_JUMP_IF_NOT_TRUE;
1847 scratch.d.jump.jumpdone = -1; /* computed later */
1848 ExprEvalPushStep(state, &scratch);
1849 whenstep = state->steps_len - 1;
1850
1851 /*
1852 * If WHEN result is true, evaluate THEN result, storing
1853 * it into the CASE's result variables.
1854 */
1855 ExecInitExprRec(when->result, state, resv, resnull);
1856
1857 /* Emit JUMP step to jump to end of CASE's code */
1858 scratch.opcode = EEOP_JUMP;
1859 scratch.d.jump.jumpdone = -1; /* computed later */
1860 ExprEvalPushStep(state, &scratch);
1861
1862 /*
1863 * Don't know address for that jump yet, compute once the
1864 * whole CASE expression is built.
1865 */
1866 adjust_jumps = lappend_int(adjust_jumps,
1867 state->steps_len - 1);
1868
1869 /*
1870 * But we can set WHEN test's jump target now, to make it
1871 * jump to the next WHEN subexpression or the ELSE.
1872 */
1873 state->steps[whenstep].d.jump.jumpdone = state->steps_len;
1874 }
1875
1876 /* transformCaseExpr always adds a default */
1877 Assert(caseExpr->defresult);
1878
1879 /* evaluate ELSE expr into CASE's result variables */
1880 ExecInitExprRec(caseExpr->defresult, state,
1881 resv, resnull);
1882
1883 /* adjust jump targets */
1884 foreach(lc, adjust_jumps)
1885 {
1886 ExprEvalStep *as = &state->steps[lfirst_int(lc)];
1887
1888 Assert(as->opcode == EEOP_JUMP);
1889 Assert(as->d.jump.jumpdone == -1);
1890 as->d.jump.jumpdone = state->steps_len;
1891 }
1892
1893 break;
1894 }
1895
1896 case T_CaseTestExpr:
1897 {
1898 /*
1899 * Read from location identified by innermost_caseval. Note
1900 * that innermost_caseval could be NULL, if this node isn't
1901 * actually within a CaseExpr, ArrayCoerceExpr, etc structure.
1902 * That can happen because some parts of the system abuse
1903 * CaseTestExpr to cause a read of a value externally supplied
1904 * in econtext->caseValue_datum. We'll take care of that by
1905 * generating a specialized operation.
1906 */
1907 if (state->innermost_caseval == NULL)
1908 scratch.opcode = EEOP_CASE_TESTVAL_EXT;
1909 else
1910 {
1911 scratch.opcode = EEOP_CASE_TESTVAL;
1912 scratch.d.casetest.value = state->innermost_caseval;
1913 scratch.d.casetest.isnull = state->innermost_casenull;
1914 }
1915 ExprEvalPushStep(state, &scratch);
1916 break;
1917 }
1918
1919 case T_ArrayExpr:
1920 {
1921 ArrayExpr *arrayexpr = (ArrayExpr *) node;
1922 int nelems = list_length(arrayexpr->elements);
1923 ListCell *lc;
1924 int elemoff;
1925
1926 /*
1927 * Evaluate by computing each element, and then forming the
1928 * array. Elements are computed into scratch arrays
1929 * associated with the ARRAYEXPR step.
1930 */
1931 scratch.opcode = EEOP_ARRAYEXPR;
1932 scratch.d.arrayexpr.elemvalues =
1933 (Datum *) palloc(sizeof(Datum) * nelems);
1934 scratch.d.arrayexpr.elemnulls =
1935 (bool *) palloc(sizeof(bool) * nelems);
1936 scratch.d.arrayexpr.nelems = nelems;
1937
1938 /* fill remaining fields of step */
1939 scratch.d.arrayexpr.multidims = arrayexpr->multidims;
1940 scratch.d.arrayexpr.elemtype = arrayexpr->element_typeid;
1941
1942 /* do one-time catalog lookup for type info */
1943 get_typlenbyvalalign(arrayexpr->element_typeid,
1944 &scratch.d.arrayexpr.elemlength,
1945 &scratch.d.arrayexpr.elembyval,
1946 &scratch.d.arrayexpr.elemalign);
1947
1948 /* prepare to evaluate all arguments */
1949 elemoff = 0;
1950 foreach(lc, arrayexpr->elements)
1951 {
1952 Expr *e = (Expr *) lfirst(lc);
1953
1954 ExecInitExprRec(e, state,
1955 &scratch.d.arrayexpr.elemvalues[elemoff],
1956 &scratch.d.arrayexpr.elemnulls[elemoff]);
1957 elemoff++;
1958 }
1959
1960 /* and then collect all into an array */
1961 ExprEvalPushStep(state, &scratch);
1962 break;
1963 }
1964
1965 case T_RowExpr:
1966 {
1967 RowExpr *rowexpr = (RowExpr *) node;
1968 int nelems = list_length(rowexpr->args);
1969 TupleDesc tupdesc;
1970 int i;
1971 ListCell *l;
1972
1973 /* Build tupdesc to describe result tuples */
1974 if (rowexpr->row_typeid == RECORDOID)
1975 {
1976 /* generic record, use types of given expressions */
1977 tupdesc = ExecTypeFromExprList(rowexpr->args);
1978 /* ... but adopt RowExpr's column aliases */
1979 ExecTypeSetColNames(tupdesc, rowexpr->colnames);
1980 /* Bless the tupdesc so it can be looked up later */
1981 BlessTupleDesc(tupdesc);
1982 }
1983 else
1984 {
1985 /* it's been cast to a named type, use that */
1986 tupdesc = lookup_rowtype_tupdesc_copy(rowexpr->row_typeid, -1);
1987 }
1988
1989 /*
1990 * In the named-type case, the tupdesc could have more columns
1991 * than are in the args list, since the type might have had
1992 * columns added since the ROW() was parsed. We want those
1993 * extra columns to go to nulls, so we make sure that the
1994 * workspace arrays are large enough and then initialize any
1995 * extra columns to read as NULLs.
1996 */
1997 Assert(nelems <= tupdesc->natts);
1998 nelems = Max(nelems, tupdesc->natts);
1999
2000 /*
2001 * Evaluate by first building datums for each field, and then
2002 * a final step forming the composite datum.
2003 */
2004 scratch.opcode = EEOP_ROW;
2005 scratch.d.row.tupdesc = tupdesc;
2006
2007 /* space for the individual field datums */
2008 scratch.d.row.elemvalues =
2009 (Datum *) palloc(sizeof(Datum) * nelems);
2010 scratch.d.row.elemnulls =
2011 (bool *) palloc(sizeof(bool) * nelems);
2012 /* as explained above, make sure any extra columns are null */
2013 memset(scratch.d.row.elemnulls, true, sizeof(bool) * nelems);
2014
2015 /* Set up evaluation, skipping any deleted columns */
2016 i = 0;
2017 foreach(l, rowexpr->args)
2018 {
2019 Form_pg_attribute att = TupleDescAttr(tupdesc, i);
2020 Expr *e = (Expr *) lfirst(l);
2021
2022 if (!att->attisdropped)
2023 {
2024 /*
2025 * Guard against ALTER COLUMN TYPE on rowtype since
2026 * the RowExpr was created. XXX should we check
2027 * typmod too? Not sure we can be sure it'll be the
2028 * same.
2029 */
2030 if (exprType((Node *) e) != att->atttypid)
2031 ereport(ERROR,
2032 (errcode(ERRCODE_DATATYPE_MISMATCH),
2033 errmsg("ROW() column has type %s instead of type %s",
2034 format_type_be(exprType((Node *) e)),
2035 format_type_be(att->atttypid))));
2036 }
2037 else
2038 {
2039 /*
2040 * Ignore original expression and insert a NULL. We
2041 * don't really care what type of NULL it is, so
2042 * always make an int4 NULL.
2043 */
2044 e = (Expr *) makeNullConst(INT4OID, -1, InvalidOid);
2045 }
2046
2047 /* Evaluate column expr into appropriate workspace slot */
2048 ExecInitExprRec(e, state,
2049 &scratch.d.row.elemvalues[i],
2050 &scratch.d.row.elemnulls[i]);
2051 i++;
2052 }
2053
2054 /* And finally build the row value */
2055 ExprEvalPushStep(state, &scratch);
2056 break;
2057 }
2058
2059 case T_RowCompareExpr:
2060 {
2061 RowCompareExpr *rcexpr = (RowCompareExpr *) node;
2062 int nopers = list_length(rcexpr->opnos);
2063 List *adjust_jumps = NIL;
2064 ListCell *l_left_expr,
2065 *l_right_expr,
2066 *l_opno,
2067 *l_opfamily,
2068 *l_inputcollid;
2069 ListCell *lc;
2070
2071 /*
2072 * Iterate over each field, prepare comparisons. To handle
2073 * NULL results, prepare jumps to after the expression. If a
2074 * comparison yields a != 0 result, jump to the final step.
2075 */
2076 Assert(list_length(rcexpr->largs) == nopers);
2077 Assert(list_length(rcexpr->rargs) == nopers);
2078 Assert(list_length(rcexpr->opfamilies) == nopers);
2079 Assert(list_length(rcexpr->inputcollids) == nopers);
2080
2081 forfive(l_left_expr, rcexpr->largs,
2082 l_right_expr, rcexpr->rargs,
2083 l_opno, rcexpr->opnos,
2084 l_opfamily, rcexpr->opfamilies,
2085 l_inputcollid, rcexpr->inputcollids)
2086 {
2087 Expr *left_expr = (Expr *) lfirst(l_left_expr);
2088 Expr *right_expr = (Expr *) lfirst(l_right_expr);
2089 Oid opno = lfirst_oid(l_opno);
2090 Oid opfamily = lfirst_oid(l_opfamily);
2091 Oid inputcollid = lfirst_oid(l_inputcollid);
2092 int strategy;
2093 Oid lefttype;
2094 Oid righttype;
2095 Oid proc;
2096 FmgrInfo *finfo;
2097 FunctionCallInfo fcinfo;
2098
2099 get_op_opfamily_properties(opno, opfamily, false,
2100 &strategy,
2101 &lefttype,
2102 &righttype);
2103 proc = get_opfamily_proc(opfamily,
2104 lefttype,
2105 righttype,
2106 BTORDER_PROC);
2107 if (!OidIsValid(proc))
2108 elog(ERROR, "missing support function %d(%u,%u) in opfamily %u",
2109 BTORDER_PROC, lefttype, righttype, opfamily);
2110
2111 /* Set up the primary fmgr lookup information */
2112 finfo = palloc0(sizeof(FmgrInfo));
2113 fcinfo = palloc0(SizeForFunctionCallInfo(2));
2114 fmgr_info(proc, finfo);
2115 fmgr_info_set_expr((Node *) node, finfo);
2116 InitFunctionCallInfoData(*fcinfo, finfo, 2,
2117 inputcollid, NULL, NULL);
2118
2119 /*
2120 * If we enforced permissions checks on index support
2121 * functions, we'd need to make a check here. But the
2122 * index support machinery doesn't do that, and thus
2123 * neither does this code.
2124 */
2125
2126 /* evaluate left and right args directly into fcinfo */
2127 ExecInitExprRec(left_expr, state,
2128 &fcinfo->args[0].value, &fcinfo->args[0].isnull);
2129 ExecInitExprRec(right_expr, state,
2130 &fcinfo->args[1].value, &fcinfo->args[1].isnull);
2131
2132 scratch.opcode = EEOP_ROWCOMPARE_STEP;
2133 scratch.d.rowcompare_step.finfo = finfo;
2134 scratch.d.rowcompare_step.fcinfo_data = fcinfo;
2135 scratch.d.rowcompare_step.fn_addr = finfo->fn_addr;
2136 /* jump targets filled below */
2137 scratch.d.rowcompare_step.jumpnull = -1;
2138 scratch.d.rowcompare_step.jumpdone = -1;
2139
2140 ExprEvalPushStep(state, &scratch);
2141 adjust_jumps = lappend_int(adjust_jumps,
2142 state->steps_len - 1);
2143 }
2144
2145 /*
2146 * We could have a zero-column rowtype, in which case the rows
2147 * necessarily compare equal.
2148 */
2149 if (nopers == 0)
2150 {
2151 scratch.opcode = EEOP_CONST;
2152 scratch.d.constval.value = Int32GetDatum(0);
2153 scratch.d.constval.isnull = false;
2154 ExprEvalPushStep(state, &scratch);
2155 }
2156
2157 /* Finally, examine the last comparison result */
2158 scratch.opcode = EEOP_ROWCOMPARE_FINAL;
2159 scratch.d.rowcompare_final.cmptype = rcexpr->cmptype;
2160 ExprEvalPushStep(state, &scratch);
2161
2162 /* adjust jump targets */
2163 foreach(lc, adjust_jumps)
2164 {
2165 ExprEvalStep *as = &state->steps[lfirst_int(lc)];
2166
2167 Assert(as->opcode == EEOP_ROWCOMPARE_STEP);
2168 Assert(as->d.rowcompare_step.jumpdone == -1);
2169 Assert(as->d.rowcompare_step.jumpnull == -1);
2170
2171 /* jump to comparison evaluation */
2172 as->d.rowcompare_step.jumpdone = state->steps_len - 1;
2173 /* jump to the following expression */
2174 as->d.rowcompare_step.jumpnull = state->steps_len;
2175 }
2176
2177 break;
2178 }
2179
2180 case T_CoalesceExpr:
2181 {
2182 CoalesceExpr *coalesce = (CoalesceExpr *) node;
2183 List *adjust_jumps = NIL;
2184 ListCell *lc;
2185
2186 /* We assume there's at least one arg */
2187 Assert(coalesce->args != NIL);
2188
2189 /*
2190 * Prepare evaluation of all coalesced arguments, after each
2191 * one push a step that short-circuits if not null.
2192 */
2193 foreach(lc, coalesce->args)
2194 {
2195 Expr *e = (Expr *) lfirst(lc);
2196
2197 /* evaluate argument, directly into result datum */
2198 ExecInitExprRec(e, state, resv, resnull);
2199
2200 /* if it's not null, skip to end of COALESCE expr */
2201 scratch.opcode = EEOP_JUMP_IF_NOT_NULL;
2202 scratch.d.jump.jumpdone = -1; /* adjust later */
2203 ExprEvalPushStep(state, &scratch);
2204
2205 adjust_jumps = lappend_int(adjust_jumps,
2206 state->steps_len - 1);
2207 }
2208
2209 /*
2210 * No need to add a constant NULL return - we only can get to
2211 * the end of the expression if a NULL already is being
2212 * returned.
2213 */
2214
2215 /* adjust jump targets */
2216 foreach(lc, adjust_jumps)
2217 {
2218 ExprEvalStep *as = &state->steps[lfirst_int(lc)];
2219
2220 Assert(as->opcode == EEOP_JUMP_IF_NOT_NULL);
2221 Assert(as->d.jump.jumpdone == -1);
2222 as->d.jump.jumpdone = state->steps_len;
2223 }
2224
2225 break;
2226 }
2227
2228 case T_MinMaxExpr:
2229 {
2230 MinMaxExpr *minmaxexpr = (MinMaxExpr *) node;
2231 int nelems = list_length(minmaxexpr->args);
2232 TypeCacheEntry *typentry;
2233 FmgrInfo *finfo;
2234 FunctionCallInfo fcinfo;
2235 ListCell *lc;
2236 int off;
2237
2238 /* Look up the btree comparison function for the datatype */
2239 typentry = lookup_type_cache(minmaxexpr->minmaxtype,
2240 TYPECACHE_CMP_PROC);
2241 if (!OidIsValid(typentry->cmp_proc))
2242 ereport(ERROR,
2243 (errcode(ERRCODE_UNDEFINED_FUNCTION),
2244 errmsg("could not identify a comparison function for type %s",
2245 format_type_be(minmaxexpr->minmaxtype))));
2246
2247 /*
2248 * If we enforced permissions checks on index support
2249 * functions, we'd need to make a check here. But the index
2250 * support machinery doesn't do that, and thus neither does
2251 * this code.
2252 */
2253
2254 /* Perform function lookup */
2255 finfo = palloc0(sizeof(FmgrInfo));
2256 fcinfo = palloc0(SizeForFunctionCallInfo(2));
2257 fmgr_info(typentry->cmp_proc, finfo);
2258 fmgr_info_set_expr((Node *) node, finfo);
2259 InitFunctionCallInfoData(*fcinfo, finfo, 2,
2260 minmaxexpr->inputcollid, NULL, NULL);
2261
2262 scratch.opcode = EEOP_MINMAX;
2263 /* allocate space to store arguments */
2264 scratch.d.minmax.values =
2265 (Datum *) palloc(sizeof(Datum) * nelems);
2266 scratch.d.minmax.nulls =
2267 (bool *) palloc(sizeof(bool) * nelems);
2268 scratch.d.minmax.nelems = nelems;
2269
2270 scratch.d.minmax.op = minmaxexpr->op;
2271 scratch.d.minmax.finfo = finfo;
2272 scratch.d.minmax.fcinfo_data = fcinfo;
2273
2274 /* evaluate expressions into minmax->values/nulls */
2275 off = 0;
2276 foreach(lc, minmaxexpr->args)
2277 {
2278 Expr *e = (Expr *) lfirst(lc);
2279
2280 ExecInitExprRec(e, state,
2281 &scratch.d.minmax.values[off],
2282 &scratch.d.minmax.nulls[off]);
2283 off++;
2284 }
2285
2286 /* and push the final comparison */
2287 ExprEvalPushStep(state, &scratch);
2288 break;
2289 }
2290
2291 case T_SQLValueFunction:
2292 {
2293 SQLValueFunction *svf = (SQLValueFunction *) node;
2294
2295 scratch.opcode = EEOP_SQLVALUEFUNCTION;
2296 scratch.d.sqlvaluefunction.svf = svf;
2297
2298 ExprEvalPushStep(state, &scratch);
2299 break;
2300 }
2301
2302 case T_XmlExpr:
2303 {
2304 XmlExpr *xexpr = (XmlExpr *) node;
2305 int nnamed = list_length(xexpr->named_args);
2306 int nargs = list_length(xexpr->args);
2307 int off;
2308 ListCell *arg;
2309
2310 scratch.opcode = EEOP_XMLEXPR;
2311 scratch.d.xmlexpr.xexpr = xexpr;
2312
2313 /* allocate space for storing all the arguments */
2314 if (nnamed)
2315 {
2316 scratch.d.xmlexpr.named_argvalue =
2317 (Datum *) palloc(sizeof(Datum) * nnamed);
2318 scratch.d.xmlexpr.named_argnull =
2319 (bool *) palloc(sizeof(bool) * nnamed);
2320 }
2321 else
2322 {
2323 scratch.d.xmlexpr.named_argvalue = NULL;
2324 scratch.d.xmlexpr.named_argnull = NULL;
2325 }
2326
2327 if (nargs)
2328 {
2329 scratch.d.xmlexpr.argvalue =
2330 (Datum *) palloc(sizeof(Datum) * nargs);
2331 scratch.d.xmlexpr.argnull =
2332 (bool *) palloc(sizeof(bool) * nargs);
2333 }
2334 else
2335 {
2336 scratch.d.xmlexpr.argvalue = NULL;
2337 scratch.d.xmlexpr.argnull = NULL;
2338 }
2339
2340 /* prepare argument execution */
2341 off = 0;
2342 foreach(arg, xexpr->named_args)
2343 {
2344 Expr *e = (Expr *) lfirst(arg);
2345
2346 ExecInitExprRec(e, state,
2347 &scratch.d.xmlexpr.named_argvalue[off],
2348 &scratch.d.xmlexpr.named_argnull[off]);
2349 off++;
2350 }
2351
2352 off = 0;
2353 foreach(arg, xexpr->args)
2354 {
2355 Expr *e = (Expr *) lfirst(arg);
2356
2357 ExecInitExprRec(e, state,
2358 &scratch.d.xmlexpr.argvalue[off],
2359 &scratch.d.xmlexpr.argnull[off]);
2360 off++;
2361 }
2362
2363 /* and evaluate the actual XML expression */
2364 ExprEvalPushStep(state, &scratch);
2365 break;
2366 }
2367
2368 case T_JsonValueExpr:
2369 {
2370 JsonValueExpr *jve = (JsonValueExpr *) node;
2371
2372 Assert(jve->raw_expr != NULL);
2373 ExecInitExprRec(jve->raw_expr, state, resv, resnull);
2374 Assert(jve->formatted_expr != NULL);
2375 ExecInitExprRec(jve->formatted_expr, state, resv, resnull);
2376 break;
2377 }
2378
2379 case T_JsonConstructorExpr:
2380 {
2381 JsonConstructorExpr *ctor = (JsonConstructorExpr *) node;
2382 List *args = ctor->args;
2383 ListCell *lc;
2384 int nargs = list_length(args);
2385 int argno = 0;
2386
2387 if (ctor->func)
2388 {
2389 ExecInitExprRec(ctor->func, state, resv, resnull);
2390 }
2391 else if ((ctor->type == JSCTOR_JSON_PARSE && !ctor->unique) ||
2392 ctor->type == JSCTOR_JSON_SERIALIZE)
2393 {
2394 /* Use the value of the first argument as result */
2395 ExecInitExprRec(linitial(args), state, resv, resnull);
2396 }
2397 else
2398 {
2399 JsonConstructorExprState *jcstate;
2400
2401 jcstate = palloc0(sizeof(JsonConstructorExprState));
2402
2403 scratch.opcode = EEOP_JSON_CONSTRUCTOR;
2404 scratch.d.json_constructor.jcstate = jcstate;
2405
2406 jcstate->constructor = ctor;
2407 jcstate->arg_values = (Datum *) palloc(sizeof(Datum) * nargs);
2408 jcstate->arg_nulls = (bool *) palloc(sizeof(bool) * nargs);
2409 jcstate->arg_types = (Oid *) palloc(sizeof(Oid) * nargs);
2410 jcstate->nargs = nargs;
2411
2412 foreach(lc, args)
2413 {
2414 Expr *arg = (Expr *) lfirst(lc);
2415
2416 jcstate->arg_types[argno] = exprType((Node *) arg);
2417
2418 if (IsA(arg, Const))
2419 {
2420 /* Don't evaluate const arguments every round */
2421 Const *con = (Const *) arg;
2422
2423 jcstate->arg_values[argno] = con->constvalue;
2424 jcstate->arg_nulls[argno] = con->constisnull;
2425 }
2426 else
2427 {
2428 ExecInitExprRec(arg, state,
2429 &jcstate->arg_values[argno],
2430 &jcstate->arg_nulls[argno]);
2431 }
2432 argno++;
2433 }
2434
2435 /* prepare type cache for datum_to_json[b]() */
2436 if (ctor->type == JSCTOR_JSON_SCALAR)
2437 {
2438 bool is_jsonb =
2439 ctor->returning->format->format_type == JS_FORMAT_JSONB;
2440
2441 jcstate->arg_type_cache =
2442 palloc(sizeof(*jcstate->arg_type_cache) * nargs);
2443
2444 for (int i = 0; i < nargs; i++)
2445 {
2446 JsonTypeCategory category;
2447 Oid outfuncid;
2448 Oid typid = jcstate->arg_types[i];
2449
2450 json_categorize_type(typid, is_jsonb,
2451 &category, &outfuncid);
2452
2453 jcstate->arg_type_cache[i].outfuncid = outfuncid;
2454 jcstate->arg_type_cache[i].category = (int) category;
2455 }
2456 }
2457
2458 ExprEvalPushStep(state, &scratch);
2459 }
2460
2461 if (ctor->coercion)
2462 {
2463 Datum *innermost_caseval = state->innermost_caseval;
2464 bool *innermost_isnull = state->innermost_casenull;
2465
2466 state->innermost_caseval = resv;
2467 state->innermost_casenull = resnull;
2468
2469 ExecInitExprRec(ctor->coercion, state, resv, resnull);
2470
2471 state->innermost_caseval = innermost_caseval;
2472 state->innermost_casenull = innermost_isnull;
2473 }
2474 }
2475 break;
2476
2477 case T_JsonIsPredicate:
2478 {
2479 JsonIsPredicate *pred = (JsonIsPredicate *) node;
2480
2481 ExecInitExprRec((Expr *) pred->expr, state, resv, resnull);
2482
2483 scratch.opcode = EEOP_IS_JSON;
2484 scratch.d.is_json.pred = pred;
2485
2486 ExprEvalPushStep(state, &scratch);
2487 break;
2488 }
2489
2490 case T_JsonExpr:
2491 {
2492 JsonExpr *jsexpr = castNode(JsonExpr, node);
2493
2494 /*
2495 * No need to initialize a full JsonExprState For
2496 * JSON_TABLE(), because the upstream caller tfuncFetchRows()
2497 * is only interested in the value of formatted_expr.
2498 */
2499 if (jsexpr->op == JSON_TABLE_OP)
2500 ExecInitExprRec((Expr *) jsexpr->formatted_expr, state,
2501 resv, resnull);
2502 else
2503 ExecInitJsonExpr(jsexpr, state, resv, resnull, &scratch);
2504 break;
2505 }
2506
2507 case T_NullTest:
2508 {
2509 NullTest *ntest = (NullTest *) node;
2510
2511 if (ntest->nulltesttype == IS_NULL)
2512 {
2513 if (ntest->argisrow)
2514 scratch.opcode = EEOP_NULLTEST_ROWISNULL;
2515 else
2516 scratch.opcode = EEOP_NULLTEST_ISNULL;
2517 }
2518 else if (ntest->nulltesttype == IS_NOT_NULL)
2519 {
2520 if (ntest->argisrow)
2521 scratch.opcode = EEOP_NULLTEST_ROWISNOTNULL;
2522 else
2523 scratch.opcode = EEOP_NULLTEST_ISNOTNULL;
2524 }
2525 else
2526 {
2527 elog(ERROR, "unrecognized nulltesttype: %d",
2528 (int) ntest->nulltesttype);
2529 }
2530 /* initialize cache in case it's a row test */
2531 scratch.d.nulltest_row.rowcache.cacheptr = NULL;
2532
2533 /* first evaluate argument into result variable */
2534 ExecInitExprRec(ntest->arg, state,
2535 resv, resnull);
2536
2537 /* then push the test of that argument */
2538 ExprEvalPushStep(state, &scratch);
2539 break;
2540 }
2541
2542 case T_BooleanTest:
2543 {
2544 BooleanTest *btest = (BooleanTest *) node;
2545
2546 /*
2547 * Evaluate argument, directly into result datum. That's ok,
2548 * because resv/resnull is definitely not used anywhere else,
2549 * and will get overwritten by the below EEOP_BOOLTEST_IS_*
2550 * step.
2551 */
2552 ExecInitExprRec(btest->arg, state, resv, resnull);
2553
2554 switch (btest->booltesttype)
2555 {
2556 case IS_TRUE:
2557 scratch.opcode = EEOP_BOOLTEST_IS_TRUE;
2558 break;
2559 case IS_NOT_TRUE:
2560 scratch.opcode = EEOP_BOOLTEST_IS_NOT_TRUE;
2561 break;
2562 case IS_FALSE:
2563 scratch.opcode = EEOP_BOOLTEST_IS_FALSE;
2564 break;
2565 case IS_NOT_FALSE:
2566 scratch.opcode = EEOP_BOOLTEST_IS_NOT_FALSE;
2567 break;
2568 case IS_UNKNOWN:
2569 /* Same as scalar IS NULL test */
2570 scratch.opcode = EEOP_NULLTEST_ISNULL;
2571 break;
2572 case IS_NOT_UNKNOWN:
2573 /* Same as scalar IS NOT NULL test */
2574 scratch.opcode = EEOP_NULLTEST_ISNOTNULL;
2575 break;
2576 default:
2577 elog(ERROR, "unrecognized booltesttype: %d",
2578 (int) btest->booltesttype);
2579 }
2580
2581 ExprEvalPushStep(state, &scratch);
2582 break;
2583 }
2584
2585 case T_CoerceToDomain:
2586 {
2587 CoerceToDomain *ctest = (CoerceToDomain *) node;
2588
2589 ExecInitCoerceToDomain(&scratch, ctest, state,
2590 resv, resnull);
2591 break;
2592 }
2593
2594 case T_CoerceToDomainValue:
2595 {
2596 /*
2597 * Read from location identified by innermost_domainval. Note
2598 * that innermost_domainval could be NULL, if we're compiling
2599 * a standalone domain check rather than one embedded in a
2600 * larger expression. In that case we must read from
2601 * econtext->domainValue_datum. We'll take care of that by
2602 * generating a specialized operation.
2603 */
2604 if (state->innermost_domainval == NULL)
2605 scratch.opcode = EEOP_DOMAIN_TESTVAL_EXT;
2606 else
2607 {
2608 scratch.opcode = EEOP_DOMAIN_TESTVAL;
2609 /* we share instruction union variant with case testval */
2610 scratch.d.casetest.value = state->innermost_domainval;
2611 scratch.d.casetest.isnull = state->innermost_domainnull;
2612 }
2613 ExprEvalPushStep(state, &scratch);
2614 break;
2615 }
2616
2617 case T_CurrentOfExpr:
2618 {
2619 scratch.opcode = EEOP_CURRENTOFEXPR;
2620 ExprEvalPushStep(state, &scratch);
2621 break;
2622 }
2623
2624 case T_NextValueExpr:
2625 {
2626 NextValueExpr *nve = (NextValueExpr *) node;
2627
2628 scratch.opcode = EEOP_NEXTVALUEEXPR;
2629 scratch.d.nextvalueexpr.seqid = nve->seqid;
2630 scratch.d.nextvalueexpr.seqtypid = nve->typeId;
2631
2632 ExprEvalPushStep(state, &scratch);
2633 break;
2634 }
2635
2636 case T_ReturningExpr:
2637 {
2638 ReturningExpr *rexpr = (ReturningExpr *) node;
2639 int retstep;
2640
2641 /* Skip expression evaluation if OLD/NEW row doesn't exist */
2642 scratch.opcode = EEOP_RETURNINGEXPR;
2643 scratch.d.returningexpr.nullflag = rexpr->retold ?
2644 EEO_FLAG_OLD_IS_NULL : EEO_FLAG_NEW_IS_NULL;
2645 scratch.d.returningexpr.jumpdone = -1; /* set below */
2646 ExprEvalPushStep(state, &scratch);
2647 retstep = state->steps_len - 1;
2648
2649 /* Steps to evaluate expression to return */
2650 ExecInitExprRec(rexpr->retexpr, state, resv, resnull);
2651
2652 /* Jump target used if OLD/NEW row doesn't exist */
2653 state->steps[retstep].d.returningexpr.jumpdone = state->steps_len;
2654
2655 /* Update ExprState flags */
2656 if (rexpr->retold)
2657 state->flags |= EEO_FLAG_HAS_OLD;
2658 else
2659 state->flags |= EEO_FLAG_HAS_NEW;
2660
2661 break;
2662 }
2663
2664 default:
2665 elog(ERROR, "unrecognized node type: %d",
2666 (int) nodeTag(node));
2667 break;
2668 }
2669}
2670
2671/*
2672 * Add another expression evaluation step to ExprState->steps.
2673 *
2674 * Note that this potentially re-allocates es->steps, therefore no pointer
2675 * into that array may be used while the expression is still being built.
2676 */
2677void
2678ExprEvalPushStep(ExprState *es, const ExprEvalStep *s)
2679{
2680 if (es->steps_alloc == 0)
2681 {
2682 es->steps_alloc = 16;
2683 es->steps = palloc(sizeof(ExprEvalStep) * es->steps_alloc);
2684 }
2685 else if (es->steps_alloc == es->steps_len)
2686 {
2687 es->steps_alloc *= 2;
2688 es->steps = repalloc(es->steps,
2689 sizeof(ExprEvalStep) * es->steps_alloc);
2690 }
2691
2692 memcpy(&es->steps[es->steps_len++], s, sizeof(ExprEvalStep));
2693}
2694
2695/*
2696 * Perform setup necessary for the evaluation of a function-like expression,
2697 * appending argument evaluation steps to the steps list in *state, and
2698 * setting up *scratch so it is ready to be pushed.
2699 *
2700 * *scratch is not pushed here, so that callers may override the opcode,
2701 * which is useful for function-like cases like DISTINCT.
2702 */
2703static void
2704ExecInitFunc(ExprEvalStep *scratch, Expr *node, List *args, Oid funcid,
2705 Oid inputcollid, ExprState *state)
2706{
2707 int nargs = list_length(args);
2708 AclResult aclresult;
2709 FmgrInfo *flinfo;
2710 FunctionCallInfo fcinfo;
2711 int argno;
2712 ListCell *lc;
2713
2714 /* Check permission to call function */
2715 aclresult = object_aclcheck(ProcedureRelationId, funcid, GetUserId(), ACL_EXECUTE);
2716 if (aclresult != ACLCHECK_OK)
2717 aclcheck_error(aclresult, OBJECT_FUNCTION, get_func_name(funcid));
2718 InvokeFunctionExecuteHook(funcid);
2719
2720 /*
2721 * Safety check on nargs. Under normal circumstances this should never
2722 * fail, as parser should check sooner. But possibly it might fail if
2723 * server has been compiled with FUNC_MAX_ARGS smaller than some functions
2724 * declared in pg_proc?
2725 */
2726 if (nargs > FUNC_MAX_ARGS)
2727 ereport(ERROR,
2728 (errcode(ERRCODE_TOO_MANY_ARGUMENTS),
2729 errmsg_plural("cannot pass more than %d argument to a function",
2730 "cannot pass more than %d arguments to a function",
2731 FUNC_MAX_ARGS,
2732 FUNC_MAX_ARGS)));
2733
2734 /* Allocate function lookup data and parameter workspace for this call */
2735 scratch->d.func.finfo = palloc0(sizeof(FmgrInfo));
2736 scratch->d.func.fcinfo_data = palloc0(SizeForFunctionCallInfo(nargs));
2737 flinfo = scratch->d.func.finfo;
2738 fcinfo = scratch->d.func.fcinfo_data;
2739
2740 /* Set up the primary fmgr lookup information */
2741 fmgr_info(funcid, flinfo);
2742 fmgr_info_set_expr((Node *) node, flinfo);
2743
2744 /* Initialize function call parameter structure too */
2745 InitFunctionCallInfoData(*fcinfo, flinfo,
2746 nargs, inputcollid, NULL, NULL);
2747
2748 /* Keep extra copies of this info to save an indirection at runtime */
2749 scratch->d.func.fn_addr = flinfo->fn_addr;
2750 scratch->d.func.nargs = nargs;
2751
2752 /* We only support non-set functions here */
2753 if (flinfo->fn_retset)
2754 ereport(ERROR,
2755 (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
2756 errmsg("set-valued function called in context that cannot accept a set"),
2757 state->parent ?
2758 executor_errposition(state->parent->state,
2759 exprLocation((Node *) node)) : 0));
2760
2761 /* Build code to evaluate arguments directly into the fcinfo struct */
2762 argno = 0;
2763 foreach(lc, args)
2764 {
2765 Expr *arg = (Expr *) lfirst(lc);
2766
2767 if (IsA(arg, Const))
2768 {
2769 /*
2770 * Don't evaluate const arguments every round; especially
2771 * interesting for constants in comparisons.
2772 */
2773 Const *con = (Const *) arg;
2774
2775 fcinfo->args[argno].value = con->constvalue;
2776 fcinfo->args[argno].isnull = con->constisnull;
2777 }
2778 else
2779 {
2780 ExecInitExprRec(arg, state,
2781 &fcinfo->args[argno].value,
2782 &fcinfo->args[argno].isnull);
2783 }
2784 argno++;
2785 }
2786
2787 /* Insert appropriate opcode depending on strictness and stats level */
2788 if (pgstat_track_functions <= flinfo->fn_stats)
2789 {
2790 if (flinfo->fn_strict && nargs > 0)
2791 {
2792 /* Choose nargs optimized implementation if available. */
2793 if (nargs == 1)
2794 scratch->opcode = EEOP_FUNCEXPR_STRICT_1;
2795 else if (nargs == 2)
2796 scratch->opcode = EEOP_FUNCEXPR_STRICT_2;
2797 else
2798 scratch->opcode = EEOP_FUNCEXPR_STRICT;
2799 }
2800 else
2801 scratch->opcode = EEOP_FUNCEXPR;
2802 }
2803 else
2804 {
2805 if (flinfo->fn_strict && nargs > 0)
2806 scratch->opcode = EEOP_FUNCEXPR_STRICT_FUSAGE;
2807 else
2808 scratch->opcode = EEOP_FUNCEXPR_FUSAGE;
2809 }
2810}
2811
2812/*
2813 * Append the steps necessary for the evaluation of a SubPlan node to
2814 * ExprState->steps.
2815 *
2816 * subplan - SubPlan expression to evaluate
2817 * state - ExprState to whose ->steps to append the necessary operations
2818 * resv / resnull - where to store the result of the node into
2819 */
2820static void
2821ExecInitSubPlanExpr(SubPlan *subplan,
2822 ExprState *state,
2823 Datum *resv, bool *resnull)
2824{
2825 ExprEvalStep scratch = {0};
2826 SubPlanState *sstate;
2827 ListCell *pvar;
2828 ListCell *l;
2829
2830 if (!state->parent)
2831 elog(ERROR, "SubPlan found with no parent plan");
2832
2833 /*
2834 * Generate steps to evaluate input arguments for the subplan.
2835 *
2836 * We evaluate the argument expressions into ExprState's resvalue/resnull,
2837 * and then use PARAM_SET to update the parameter. We do that, instead of
2838 * evaluating directly into the param, to avoid depending on the pointer
2839 * value remaining stable / being included in the generated expression. No
2840 * danger of conflicts with other uses of resvalue/resnull as storing and
2841 * using the value always is in subsequent steps.
2842 *
2843 * Any calculation we have to do can be done in the parent econtext, since
2844 * the Param values don't need to have per-query lifetime.
2845 */
2846 Assert(list_length(subplan->parParam) == list_length(subplan->args));
2847 forboth(l, subplan->parParam, pvar, subplan->args)
2848 {
2849 int paramid = lfirst_int(l);
2850 Expr *arg = (Expr *) lfirst(pvar);
2851
2852 ExecInitExprRec(arg, state,
2853 &state->resvalue, &state->resnull);
2854
2855 scratch.opcode = EEOP_PARAM_SET;
2856 scratch.d.param.paramid = paramid;
2857 /* paramtype's not actually used, but we might as well fill it */
2858 scratch.d.param.paramtype = exprType((Node *) arg);
2859 ExprEvalPushStep(state, &scratch);
2860 }
2861
2862 sstate = ExecInitSubPlan(subplan, state->parent);
2863
2864 /* add SubPlanState nodes to state->parent->subPlan */
2865 state->parent->subPlan = lappend(state->parent->subPlan,
2866 sstate);
2867
2868 scratch.opcode = EEOP_SUBPLAN;
2869 scratch.resvalue = resv;
2870 scratch.resnull = resnull;
2871 scratch.d.subplan.sstate = sstate;
2872
2873 ExprEvalPushStep(state, &scratch);
2874}
2875
2876/*
2877 * Add expression steps performing setup that's needed before any of the
2878 * main execution of the expression.
2879 */
2880static void
2881ExecCreateExprSetupSteps(ExprState *state, Node *node)
2882{
2883 ExprSetupInfo info = {0, 0, 0, 0, 0, NIL};
2884
2885 /* Prescan to find out what we need. */
2886 expr_setup_walker(node, &info);
2887
2888 /* And generate those steps. */
2889 ExecPushExprSetupSteps(state, &info);
2890}
2891
2892/*
2893 * Add steps performing expression setup as indicated by "info".
2894 * This is useful when building an ExprState covering more than one expression.
2895 */
2896static void
2897ExecPushExprSetupSteps(ExprState *state, ExprSetupInfo *info)
2898{
2899 ExprEvalStep scratch = {0};
2900 ListCell *lc;
2901
2902 scratch.resvalue = NULL;
2903 scratch.resnull = NULL;
2904
2905 /*
2906 * Add steps deforming the ExprState's inner/outer/scan/old/new slots as
2907 * much as required by any Vars appearing in the expression.
2908 */
2909 if (info->last_inner > 0)
2910 {
2911 scratch.opcode = EEOP_INNER_FETCHSOME;
2912 scratch.d.fetch.last_var = info->last_inner;
2913 scratch.d.fetch.fixed = false;
2914 scratch.d.fetch.kind = NULL;
2915 scratch.d.fetch.known_desc = NULL;
2916 if (ExecComputeSlotInfo(state, &scratch))
2917 ExprEvalPushStep(state, &scratch);
2918 }
2919 if (info->last_outer > 0)
2920 {
2921 scratch.opcode = EEOP_OUTER_FETCHSOME;
2922 scratch.d.fetch.last_var = info->last_outer;
2923 scratch.d.fetch.fixed = false;
2924 scratch.d.fetch.kind = NULL;
2925 scratch.d.fetch.known_desc = NULL;
2926 if (ExecComputeSlotInfo(state, &scratch))
2927 ExprEvalPushStep(state, &scratch);
2928 }
2929 if (info->last_scan > 0)
2930 {
2931 scratch.opcode = EEOP_SCAN_FETCHSOME;
2932 scratch.d.fetch.last_var = info->last_scan;
2933 scratch.d.fetch.fixed = false;
2934 scratch.d.fetch.kind = NULL;
2935 scratch.d.fetch.known_desc = NULL;
2936 if (ExecComputeSlotInfo(state, &scratch))
2937 ExprEvalPushStep(state, &scratch);
2938 }
2939 if (info->last_old > 0)
2940 {
2941 scratch.opcode = EEOP_OLD_FETCHSOME;
2942 scratch.d.fetch.last_var = info->last_old;
2943 scratch.d.fetch.fixed = false;
2944 scratch.d.fetch.kind = NULL;
2945 scratch.d.fetch.known_desc = NULL;
2946 if (ExecComputeSlotInfo(state, &scratch))
2947 ExprEvalPushStep(state, &scratch);
2948 }
2949 if (info->last_new > 0)
2950 {
2951 scratch.opcode = EEOP_NEW_FETCHSOME;
2952 scratch.d.fetch.last_var = info->last_new;
2953 scratch.d.fetch.fixed = false;
2954 scratch.d.fetch.kind = NULL;
2955 scratch.d.fetch.known_desc = NULL;
2956 if (ExecComputeSlotInfo(state, &scratch))
2957 ExprEvalPushStep(state, &scratch);
2958 }
2959
2960 /*
2961 * Add steps to execute any MULTIEXPR SubPlans appearing in the
2962 * expression. We need to evaluate these before any of the Params
2963 * referencing their outputs are used, but after we've prepared for any
2964 * Var references they may contain. (There cannot be cross-references
2965 * between MULTIEXPR SubPlans, so we needn't worry about their order.)
2966 */
2967 foreach(lc, info->multiexpr_subplans)
2968 {
2969 SubPlan *subplan = (SubPlan *) lfirst(lc);
2970
2971 Assert(subplan->subLinkType == MULTIEXPR_SUBLINK);
2972
2973 /* The result can be ignored, but we better put it somewhere */
2974 ExecInitSubPlanExpr(subplan, state,
2975 &state->resvalue, &state->resnull);
2976 }
2977}
2978
2979/*
2980 * expr_setup_walker: expression walker for ExecCreateExprSetupSteps
2981 */
2982static bool
2983expr_setup_walker(Node *node, ExprSetupInfo *info)
2984{
2985 if (node == NULL)
2986 return false;
2987 if (IsA(node, Var))
2988 {
2989 Var *variable = (Var *) node;
2990 AttrNumber attnum = variable->varattno;
2991
2992 switch (variable->varno)
2993 {
2994 case INNER_VAR:
2995 info->last_inner = Max(info->last_inner, attnum);
2996 break;
2997
2998 case OUTER_VAR:
2999 info->last_outer = Max(info->last_outer, attnum);
3000 break;
3001
3002 /* INDEX_VAR is handled by default case */
3003
3004 default:
3005 switch (variable->varreturningtype)
3006 {
3007 case VAR_RETURNING_DEFAULT:
3008 info->last_scan = Max(info->last_scan, attnum);
3009 break;
3010 case VAR_RETURNING_OLD:
3011 info->last_old = Max(info->last_old, attnum);
3012 break;
3013 case VAR_RETURNING_NEW:
3014 info->last_new = Max(info->last_new, attnum);
3015 break;
3016 }
3017 break;
3018 }
3019 return false;
3020 }
3021
3022 /* Collect all MULTIEXPR SubPlans, too */
3023 if (IsA(node, SubPlan))
3024 {
3025 SubPlan *subplan = (SubPlan *) node;
3026
3027 if (subplan->subLinkType == MULTIEXPR_SUBLINK)
3028 info->multiexpr_subplans = lappend(info->multiexpr_subplans,
3029 subplan);
3030 }
3031
3032 /*
3033 * Don't examine the arguments or filters of Aggrefs or WindowFuncs,
3034 * because those do not represent expressions to be evaluated within the
3035 * calling expression's econtext. GroupingFunc arguments are never
3036 * evaluated at all.
3037 */
3038 if (IsA(node, Aggref))
3039 return false;
3040 if (IsA(node, WindowFunc))
3041 return false;
3042 if (IsA(node, GroupingFunc))
3043 return false;
3044 return expression_tree_walker(node, expr_setup_walker, info);
3045}
3046
3047/*
3048 * Compute additional information for EEOP_*_FETCHSOME ops.
3049 *
3050 * The goal is to determine whether a slot is 'fixed', that is, every
3051 * evaluation of the expression will have the same type of slot, with an
3052 * equivalent descriptor.
3053 *
3054 * EEOP_OLD_FETCHSOME and EEOP_NEW_FETCHSOME are used to process RETURNING, if
3055 * OLD/NEW columns are referred to explicitly. In both cases, the tuple
3056 * descriptor comes from the parent scan node, so we treat them the same as
3057 * EEOP_SCAN_FETCHSOME.
3058 *
3059 * Returns true if the deforming step is required, false otherwise.
3060 */
3061static bool
3062ExecComputeSlotInfo(ExprState *state, ExprEvalStep *op)
3063{
3064 PlanState *parent = state->parent;
3065 TupleDesc desc = NULL;
3066 const TupleTableSlotOps *tts_ops = NULL;
3067 bool isfixed = false;
3068 ExprEvalOp opcode = op->opcode;
3069
3070 Assert(opcode == EEOP_INNER_FETCHSOME ||
3071 opcode == EEOP_OUTER_FETCHSOME ||
3072 opcode == EEOP_SCAN_FETCHSOME ||
3073 opcode == EEOP_OLD_FETCHSOME ||
3074 opcode == EEOP_NEW_FETCHSOME);
3075
3076 if (op->d.fetch.known_desc != NULL)
3077 {
3078 desc = op->d.fetch.known_desc;
3079 tts_ops = op->d.fetch.kind;
3080 isfixed = op->d.fetch.kind != NULL;
3081 }
3082 else if (!parent)
3083 {
3084 isfixed = false;
3085 }
3086 else if (opcode == EEOP_INNER_FETCHSOME)
3087 {
3088 PlanState *is = innerPlanState(parent);
3089
3090 if (parent->inneropsset && !parent->inneropsfixed)
3091 {
3092 isfixed = false;
3093 }
3094 else if (parent->inneropsset && parent->innerops)
3095 {
3096 isfixed = true;
3097 tts_ops = parent->innerops;
3098 desc = ExecGetResultType(is);
3099 }
3100 else if (is)
3101 {
3102 tts_ops = ExecGetResultSlotOps(is, &isfixed);
3103 desc = ExecGetResultType(is);
3104 }
3105 }
3106 else if (opcode == EEOP_OUTER_FETCHSOME)
3107 {
3108 PlanState *os = outerPlanState(parent);
3109
3110 if (parent->outeropsset && !parent->outeropsfixed)
3111 {
3112 isfixed = false;
3113 }
3114 else if (parent->outeropsset && parent->outerops)
3115 {
3116 isfixed = true;
3117 tts_ops = parent->outerops;
3118 desc = ExecGetResultType(os);
3119 }
3120 else if (os)
3121 {
3122 tts_ops = ExecGetResultSlotOps(os, &isfixed);
3123 desc = ExecGetResultType(os);
3124 }
3125 }
3126 else if (opcode == EEOP_SCAN_FETCHSOME ||
3127 opcode == EEOP_OLD_FETCHSOME ||
3128 opcode == EEOP_NEW_FETCHSOME)
3129 {
3130 desc = parent->scandesc;
3131
3132 if (parent->scanops)
3133 tts_ops = parent->scanops;
3134
3135 if (parent->scanopsset)
3136 isfixed = parent->scanopsfixed;
3137 }
3138
3139 if (isfixed && desc != NULL && tts_ops != NULL)
3140 {
3141 op->d.fetch.fixed = true;
3142 op->d.fetch.kind = tts_ops;
3143 op->d.fetch.known_desc = desc;
3144 }
3145 else
3146 {
3147 op->d.fetch.fixed = false;
3148 op->d.fetch.kind = NULL;
3149 op->d.fetch.known_desc = NULL;
3150 }
3151
3152 /* if the slot is known to always virtual we never need to deform */
3153 if (op->d.fetch.fixed && op->d.fetch.kind == &TTSOpsVirtual)
3154 return false;
3155
3156 return true;
3157}
3158
3159/*
3160 * Prepare step for the evaluation of a whole-row variable.
3161 * The caller still has to push the step.
3162 */
3163static void
3164ExecInitWholeRowVar(ExprEvalStep *scratch, Var *variable, ExprState *state)
3165{
3166 PlanState *parent = state->parent;
3167
3168 /* fill in all but the target */
3169 scratch->opcode = EEOP_WHOLEROW;
3170 scratch->d.wholerow.var = variable;
3171 scratch->d.wholerow.first = true;
3172 scratch->d.wholerow.slow = false;
3173 scratch->d.wholerow.tupdesc = NULL; /* filled at runtime */
3174 scratch->d.wholerow.junkFilter = NULL;
3175
3176 /* update ExprState flags if Var refers to OLD/NEW */
3177 if (variable->varreturningtype == VAR_RETURNING_OLD)
3178 state->flags |= EEO_FLAG_HAS_OLD;
3179 else if (variable->varreturningtype == VAR_RETURNING_NEW)
3180 state->flags |= EEO_FLAG_HAS_NEW;
3181
3182 /*
3183 * If the input tuple came from a subquery, it might contain "resjunk"
3184 * columns (such as GROUP BY or ORDER BY columns), which we don't want to
3185 * keep in the whole-row result. We can get rid of such columns by
3186 * passing the tuple through a JunkFilter --- but to make one, we have to
3187 * lay our hands on the subquery's targetlist. Fortunately, there are not
3188 * very many cases where this can happen, and we can identify all of them
3189 * by examining our parent PlanState. We assume this is not an issue in
3190 * standalone expressions that don't have parent plans. (Whole-row Vars
3191 * can occur in such expressions, but they will always be referencing
3192 * table rows.)
3193 */
3194 if (parent)
3195 {
3196 PlanState *subplan = NULL;
3197
3198 switch (nodeTag(parent))
3199 {
3200 case T_SubqueryScanState:
3201 subplan = ((SubqueryScanState *) parent)->subplan;
3202 break;
3203 case T_CteScanState:
3204 subplan = ((CteScanState *) parent)->cteplanstate;
3205 break;
3206 default:
3207 break;
3208 }
3209
3210 if (subplan)
3211 {
3212 bool junk_filter_needed = false;
3213 ListCell *tlist;
3214
3215 /* Detect whether subplan tlist actually has any junk columns */
3216 foreach(tlist, subplan->plan->targetlist)
3217 {
3218 TargetEntry *tle = (TargetEntry *) lfirst(tlist);
3219
3220 if (tle->resjunk)
3221 {
3222 junk_filter_needed = true;
3223 break;
3224 }
3225 }
3226
3227 /* If so, build the junkfilter now */
3228 if (junk_filter_needed)
3229 {
3230 scratch->d.wholerow.junkFilter =
3231 ExecInitJunkFilter(subplan->plan->targetlist,
3232 ExecInitExtraTupleSlot(parent->state, NULL,
3233 &TTSOpsVirtual));
3234 }
3235 }
3236 }
3237}
3238
3239/*
3240 * Prepare evaluation of a SubscriptingRef expression.
3241 */
3242static void
3243ExecInitSubscriptingRef(ExprEvalStep *scratch, SubscriptingRef *sbsref,
3244 ExprState *state, Datum *resv, bool *resnull)
3245{
3246 bool isAssignment = (sbsref->refassgnexpr != NULL);
3247 int nupper = list_length(sbsref->refupperindexpr);
3248 int nlower = list_length(sbsref->reflowerindexpr);
3249 const SubscriptRoutines *sbsroutines;
3250 SubscriptingRefState *sbsrefstate;
3251 SubscriptExecSteps methods;
3252 char *ptr;
3253 List *adjust_jumps = NIL;
3254 ListCell *lc;
3255 int i;
3256
3257 /* Look up the subscripting support methods */
3258 sbsroutines = getSubscriptingRoutines(sbsref->refcontainertype, NULL);
3259 if (!sbsroutines)
3260 ereport(ERROR,
3261 (errcode(ERRCODE_DATATYPE_MISMATCH),
3262 errmsg("cannot subscript type %s because it does not support subscripting",
3263 format_type_be(sbsref->refcontainertype)),
3264 state->parent ?
3265 executor_errposition(state->parent->state,
3266 exprLocation((Node *) sbsref)) : 0));
3267
3268 /* Allocate sbsrefstate, with enough space for per-subscript arrays too */
3269 sbsrefstate = palloc0(MAXALIGN(sizeof(SubscriptingRefState)) +
3270 (nupper + nlower) * (sizeof(Datum) +
3271 2 * sizeof(bool)));
3272
3273 /* Fill constant fields of SubscriptingRefState */
3274 sbsrefstate->isassignment = isAssignment;
3275 sbsrefstate->numupper = nupper;
3276 sbsrefstate->numlower = nlower;
3277 /* Set up per-subscript arrays */
3278 ptr = ((char *) sbsrefstate) + MAXALIGN(sizeof(SubscriptingRefState));
3279 sbsrefstate->upperindex = (Datum *) ptr;
3280 ptr += nupper * sizeof(Datum);
3281 sbsrefstate->lowerindex = (Datum *) ptr;
3282 ptr += nlower * sizeof(Datum);
3283 sbsrefstate->upperprovided = (bool *) ptr;
3284 ptr += nupper * sizeof(bool);
3285 sbsrefstate->lowerprovided = (bool *) ptr;
3286 ptr += nlower * sizeof(bool);
3287 sbsrefstate->upperindexnull = (bool *) ptr;
3288 ptr += nupper * sizeof(bool);
3289 sbsrefstate->lowerindexnull = (bool *) ptr;
3290 /* ptr += nlower * sizeof(bool); */
3291
3292 /*
3293 * Let the container-type-specific code have a chance. It must fill the
3294 * "methods" struct with function pointers for us to possibly use in
3295 * execution steps below; and it can optionally set up some data pointed
3296 * to by the workspace field.
3297 */
3298 memset(&methods, 0, sizeof(methods));
3299 sbsroutines->exec_setup(sbsref, sbsrefstate, &methods);
3300
3301 /*
3302 * Evaluate array input. It's safe to do so into resv/resnull, because we
3303 * won't use that as target for any of the other subexpressions, and it'll
3304 * be overwritten by the final EEOP_SBSREF_FETCH/ASSIGN step, which is
3305 * pushed last.
3306 */
3307 ExecInitExprRec(sbsref->refexpr, state, resv, resnull);
3308
3309 /*
3310 * If refexpr yields NULL, and the operation should be strict, then result
3311 * is NULL. We can implement this with just JUMP_IF_NULL, since we
3312 * evaluated the array into the desired target location.
3313 */
3314 if (!isAssignment && sbsroutines->fetch_strict)
3315 {
3316 scratch->opcode = EEOP_JUMP_IF_NULL;
3317 scratch->d.jump.jumpdone = -1; /* adjust later */
3318 ExprEvalPushStep(state, scratch);
3319 adjust_jumps = lappend_int(adjust_jumps,
3320 state->steps_len - 1);
3321 }
3322
3323 /* Evaluate upper subscripts */
3324 i = 0;
3325 foreach(lc, sbsref->refupperindexpr)
3326 {
3327 Expr *e = (Expr *) lfirst(lc);
3328
3329 /* When slicing, individual subscript bounds can be omitted */
3330 if (!e)
3331 {
3332 sbsrefstate->upperprovided[i] = false;
3333 sbsrefstate->upperindexnull[i] = true;
3334 }
3335 else
3336 {
3337 sbsrefstate->upperprovided[i] = true;
3338 /* Each subscript is evaluated into appropriate array entry */
3339 ExecInitExprRec(e, state,
3340 &sbsrefstate->upperindex[i],
3341 &sbsrefstate->upperindexnull[i]);
3342 }
3343 i++;
3344 }
3345
3346 /* Evaluate lower subscripts similarly */
3347 i = 0;
3348 foreach(lc, sbsref->reflowerindexpr)
3349 {
3350 Expr *e = (Expr *) lfirst(lc);
3351
3352 /* When slicing, individual subscript bounds can be omitted */
3353 if (!e)
3354 {
3355 sbsrefstate->lowerprovided[i] = false;
3356 sbsrefstate->lowerindexnull[i] = true;
3357 }
3358 else
3359 {
3360 sbsrefstate->lowerprovided[i] = true;
3361 /* Each subscript is evaluated into appropriate array entry */
3362 ExecInitExprRec(e, state,
3363 &sbsrefstate->lowerindex[i],
3364 &sbsrefstate->lowerindexnull[i]);
3365 }
3366 i++;
3367 }
3368
3369 /* SBSREF_SUBSCRIPTS checks and converts all the subscripts at once */
3370 if (methods.sbs_check_subscripts)
3371 {
3372 scratch->opcode = EEOP_SBSREF_SUBSCRIPTS;
3373 scratch->d.sbsref_subscript.subscriptfunc = methods.sbs_check_subscripts;
3374 scratch->d.sbsref_subscript.state = sbsrefstate;
3375 scratch->d.sbsref_subscript.jumpdone = -1; /* adjust later */
3376 ExprEvalPushStep(state, scratch);
3377 adjust_jumps = lappend_int(adjust_jumps,
3378 state->steps_len - 1);
3379 }
3380
3381 if (isAssignment)
3382 {
3383 Datum *save_innermost_caseval;
3384 bool *save_innermost_casenull;
3385
3386 /* Check for unimplemented methods */
3387 if (!methods.sbs_assign)
3388 ereport(ERROR,
3389 (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
3390 errmsg("type %s does not support subscripted assignment",
3391 format_type_be(sbsref->refcontainertype))));
3392
3393 /*
3394 * We might have a nested-assignment situation, in which the
3395 * refassgnexpr is itself a FieldStore or SubscriptingRef that needs
3396 * to obtain and modify the previous value of the array element or
3397 * slice being replaced. If so, we have to extract that value from
3398 * the array and pass it down via the CaseTestExpr mechanism. It's
3399 * safe to reuse the CASE mechanism because there cannot be a CASE
3400 * between here and where the value would be needed, and an array
3401 * assignment can't be within a CASE either. (So saving and restoring
3402 * innermost_caseval is just paranoia, but let's do it anyway.)
3403 *
3404 * Since fetching the old element might be a nontrivial expense, do it
3405 * only if the argument actually needs it.
3406 */
3407 if (isAssignmentIndirectionExpr(sbsref->refassgnexpr))
3408 {
3409 if (!methods.sbs_fetch_old)
3410 ereport(ERROR,
3411 (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
3412 errmsg("type %s does not support subscripted assignment",
3413 format_type_be(sbsref->refcontainertype))));
3414 scratch->opcode = EEOP_SBSREF_OLD;
3415 scratch->d.sbsref.subscriptfunc = methods.sbs_fetch_old;
3416 scratch->d.sbsref.state = sbsrefstate;
3417 ExprEvalPushStep(state, scratch);
3418 }
3419
3420 /* SBSREF_OLD puts extracted value into prevvalue/prevnull */
3421 save_innermost_caseval = state->innermost_caseval;
3422 save_innermost_casenull = state->innermost_casenull;
3423 state->innermost_caseval = &sbsrefstate->prevvalue;
3424 state->innermost_casenull = &sbsrefstate->prevnull;
3425
3426 /* evaluate replacement value into replacevalue/replacenull */
3427 ExecInitExprRec(sbsref->refassgnexpr, state,
3428 &sbsrefstate->replacevalue, &sbsrefstate->replacenull);
3429
3430 state->innermost_caseval = save_innermost_caseval;
3431 state->innermost_casenull = save_innermost_casenull;
3432
3433 /* and perform the assignment */
3434 scratch->opcode = EEOP_SBSREF_ASSIGN;
3435 scratch->d.sbsref.subscriptfunc = methods.sbs_assign;
3436 scratch->d.sbsref.state = sbsrefstate;
3437 ExprEvalPushStep(state, scratch);
3438 }
3439 else
3440 {
3441 /* array fetch is much simpler */
3442 scratch->opcode = EEOP_SBSREF_FETCH;
3443 scratch->d.sbsref.subscriptfunc = methods.sbs_fetch;
3444 scratch->d.sbsref.state = sbsrefstate;
3445 ExprEvalPushStep(state, scratch);
3446 }
3447
3448 /* adjust jump targets */
3449 foreach(lc, adjust_jumps)
3450 {
3451 ExprEvalStep *as = &state->steps[lfirst_int(lc)];
3452
3453 if (as->opcode == EEOP_SBSREF_SUBSCRIPTS)
3454 {
3455 Assert(as->d.sbsref_subscript.jumpdone == -1);
3456 as->d.sbsref_subscript.jumpdone = state->steps_len;
3457 }
3458 else
3459 {
3460 Assert(as->opcode == EEOP_JUMP_IF_NULL);
3461 Assert(as->d.jump.jumpdone == -1);
3462 as->d.jump.jumpdone = state->steps_len;
3463 }
3464 }
3465}
3466
3467/*
3468 * Helper for preparing SubscriptingRef expressions for evaluation: is expr
3469 * a nested FieldStore or SubscriptingRef that needs the old element value
3470 * passed down?
3471 *
3472 * (We could use this in FieldStore too, but in that case passing the old
3473 * value is so cheap there's no need.)
3474 *
3475 * Note: it might seem that this needs to recurse, but in most cases it does
3476 * not; the CaseTestExpr, if any, will be directly the arg or refexpr of the
3477 * top-level node. Nested-assignment situations give rise to expression
3478 * trees in which each level of assignment has its own CaseTestExpr, and the
3479 * recursive structure appears within the newvals or refassgnexpr field.
3480 * There is an exception, though: if the array is an array-of-domain, we will
3481 * have a CoerceToDomain or RelabelType as the refassgnexpr, and we need to
3482 * be able to look through that.
3483 */
3484static bool
3485isAssignmentIndirectionExpr(Expr *expr)
3486{
3487 if (expr == NULL)
3488 return false; /* just paranoia */
3489 if (IsA(expr, FieldStore))
3490 {
3491 FieldStore *fstore = (FieldStore *) expr;
3492
3493 if (fstore->arg && IsA(fstore->arg, CaseTestExpr))
3494 return true;
3495 }
3496 else if (IsA(expr, SubscriptingRef))
3497 {
3498 SubscriptingRef *sbsRef = (SubscriptingRef *) expr;
3499
3500 if (sbsRef->refexpr && IsA(sbsRef->refexpr, CaseTestExpr))
3501 return true;
3502 }
3503 else if (IsA(expr, CoerceToDomain))
3504 {
3505 CoerceToDomain *cd = (CoerceToDomain *) expr;
3506
3507 return isAssignmentIndirectionExpr(cd->arg);
3508 }
3509 else if (IsA(expr, RelabelType))
3510 {
3511 RelabelType *r = (RelabelType *) expr;
3512
3513 return isAssignmentIndirectionExpr(r->arg);
3514 }
3515 return false;
3516}
3517
3518/*
3519 * Prepare evaluation of a CoerceToDomain expression.
3520 */
3521static void
3522ExecInitCoerceToDomain(ExprEvalStep *scratch, CoerceToDomain *ctest,
3523 ExprState *state, Datum *resv, bool *resnull)
3524{
3525 DomainConstraintRef *constraint_ref;
3526 Datum *domainval = NULL;
3527 bool *domainnull = NULL;
3528 ListCell *l;
3529
3530 scratch->d.domaincheck.resulttype = ctest->resulttype;
3531 /* we'll allocate workspace only if needed */
3532 scratch->d.domaincheck.checkvalue = NULL;
3533 scratch->d.domaincheck.checknull = NULL;
3534 scratch->d.domaincheck.escontext = state->escontext;
3535
3536 /*
3537 * Evaluate argument - it's fine to directly store it into resv/resnull,
3538 * if there's constraint failures there'll be errors, otherwise it's what
3539 * needs to be returned.
3540 */
3541 ExecInitExprRec(ctest->arg, state, resv, resnull);
3542
3543 /*
3544 * Note: if the argument is of varlena type, it could be a R/W expanded
3545 * object. We want to return the R/W pointer as the final result, but we
3546 * have to pass a R/O pointer as the value to be tested by any functions
3547 * in check expressions. We don't bother to emit a MAKE_READONLY step
3548 * unless there's actually at least one check expression, though. Until
3549 * we've tested that, domainval/domainnull are NULL.
3550 */
3551
3552 /*
3553 * Collect the constraints associated with the domain.
3554 *
3555 * Note: before PG v10 we'd recheck the set of constraints during each
3556 * evaluation of the expression. Now we bake them into the ExprState
3557 * during executor initialization. That means we don't need typcache.c to
3558 * provide compiled exprs.
3559 */
3560 constraint_ref = (DomainConstraintRef *)
3561 palloc(sizeof(DomainConstraintRef));
3562 InitDomainConstraintRef(ctest->resulttype,
3563 constraint_ref,
3564 CurrentMemoryContext,
3565 false);
3566
3567 /*
3568 * Compile code to check each domain constraint. NOTNULL constraints can
3569 * just be applied on the resv/resnull value, but for CHECK constraints we
3570 * need more pushups.
3571 */
3572 foreach(l, constraint_ref->constraints)
3573 {
3574 DomainConstraintState *con = (DomainConstraintState *) lfirst(l);
3575 Datum *save_innermost_domainval;
3576 bool *save_innermost_domainnull;
3577
3578 scratch->d.domaincheck.constraintname = con->name;
3579
3580 switch (con->constrainttype)
3581 {
3582 case DOM_CONSTRAINT_NOTNULL:
3583 scratch->opcode = EEOP_DOMAIN_NOTNULL;
3584 ExprEvalPushStep(state, scratch);
3585 break;
3586 case DOM_CONSTRAINT_CHECK:
3587 /* Allocate workspace for CHECK output if we didn't yet */
3588 if (scratch->d.domaincheck.checkvalue == NULL)
3589 {
3590 scratch->d.domaincheck.checkvalue =
3591 (Datum *) palloc(sizeof(Datum));
3592 scratch->d.domaincheck.checknull =
3593 (bool *) palloc(sizeof(bool));
3594 }
3595
3596 /*
3597 * If first time through, determine where CoerceToDomainValue
3598 * nodes should read from.
3599 */
3600 if (domainval == NULL)
3601 {
3602 /*
3603 * Since value might be read multiple times, force to R/O
3604 * - but only if it could be an expanded datum.
3605 */
3606 if (get_typlen(ctest->resulttype) == -1)
3607 {
3608 ExprEvalStep scratch2 = {0};
3609
3610 /* Yes, so make output workspace for MAKE_READONLY */
3611 domainval = (Datum *) palloc(sizeof(Datum));
3612 domainnull = (bool *) palloc(sizeof(bool));
3613
3614 /* Emit MAKE_READONLY */
3615 scratch2.opcode = EEOP_MAKE_READONLY;
3616 scratch2.resvalue = domainval;
3617 scratch2.resnull = domainnull;
3618 scratch2.d.make_readonly.value = resv;
3619 scratch2.d.make_readonly.isnull = resnull;
3620 ExprEvalPushStep(state, &scratch2);
3621 }
3622 else
3623 {
3624 /* No, so it's fine to read from resv/resnull */
3625 domainval = resv;
3626 domainnull = resnull;
3627 }
3628 }
3629
3630 /*
3631 * Set up value to be returned by CoerceToDomainValue nodes.
3632 * We must save and restore innermost_domainval/null fields,
3633 * in case this node is itself within a check expression for
3634 * another domain.
3635 */
3636 save_innermost_domainval = state->innermost_domainval;
3637 save_innermost_domainnull = state->innermost_domainnull;
3638 state->innermost_domainval = domainval;
3639 state->innermost_domainnull = domainnull;
3640
3641 /* evaluate check expression value */
3642 ExecInitExprRec(con->check_expr, state,
3643 scratch->d.domaincheck.checkvalue,
3644 scratch->d.domaincheck.checknull);
3645
3646 state->innermost_domainval = save_innermost_domainval;
3647 state->innermost_domainnull = save_innermost_domainnull;
3648
3649 /* now test result */
3650 scratch->opcode = EEOP_DOMAIN_CHECK;
3651 ExprEvalPushStep(state, scratch);
3652
3653 break;
3654 default:
3655 elog(ERROR, "unrecognized constraint type: %d",
3656 (int) con->constrainttype);
3657 break;
3658 }
3659 }
3660}
3661
3662/*
3663 * Build transition/combine function invocations for all aggregate transition
3664 * / combination function invocations in a grouping sets phase. This has to
3665 * invoke all sort based transitions in a phase (if doSort is true), all hash
3666 * based transitions (if doHash is true), or both (both true).
3667 *
3668 * The resulting expression will, for each set of transition values, first
3669 * check for filters, evaluate aggregate input, check that that input is not
3670 * NULL for a strict transition function, and then finally invoke the
3671 * transition for each of the concurrently computed grouping sets.
3672 *
3673 * If nullcheck is true, the generated code will check for a NULL pointer to
3674 * the array of AggStatePerGroup, and skip evaluation if so.
3675 */
3676ExprState *
3677ExecBuildAggTrans(AggState *aggstate, AggStatePerPhase phase,
3678 bool doSort, bool doHash, bool nullcheck)
3679{
3680 ExprState *state = makeNode(ExprState);
3681 PlanState *parent = &aggstate->ss.ps;
3682 ExprEvalStep scratch = {0};
3683 bool isCombine = DO_AGGSPLIT_COMBINE(aggstate->aggsplit);
3684 ExprSetupInfo deform = {0, 0, 0, 0, 0, NIL};
3685
3686 state->expr = (Expr *) aggstate;
3687 state->parent = parent;
3688
3689 scratch.resvalue = &state->resvalue;
3690 scratch.resnull = &state->resnull;
3691
3692 /*
3693 * First figure out which slots, and how many columns from each, we're
3694 * going to need.
3695 */
3696 for (int transno = 0; transno < aggstate->numtrans; transno++)
3697 {
3698 AggStatePerTrans pertrans = &aggstate->pertrans[transno];
3699
3700 expr_setup_walker((Node *) pertrans->aggref->aggdirectargs,
3701 &deform);
3702 expr_setup_walker((Node *) pertrans->aggref->args,
3703 &deform);
3704 expr_setup_walker((Node *) pertrans->aggref->aggorder,
3705 &deform);
3706 expr_setup_walker((Node *) pertrans->aggref->aggdistinct,
3707 &deform);
3708 expr_setup_walker((Node *) pertrans->aggref->aggfilter,
3709 &deform);
3710 }
3711 ExecPushExprSetupSteps(state, &deform);
3712
3713 /*
3714 * Emit instructions for each transition value / grouping set combination.
3715 */
3716 for (int transno = 0; transno < aggstate->numtrans; transno++)
3717 {
3718 AggStatePerTrans pertrans = &aggstate->pertrans[transno];
3719 FunctionCallInfo trans_fcinfo = pertrans->transfn_fcinfo;
3720 List *adjust_bailout = NIL;
3721 NullableDatum *strictargs = NULL;
3722 bool *strictnulls = NULL;
3723 int argno;
3724 ListCell *bail;
3725
3726 /*
3727 * If filter present, emit. Do so before evaluating the input, to
3728 * avoid potentially unneeded computations, or even worse, unintended
3729 * side-effects. When combining, all the necessary filtering has
3730 * already been done.
3731 */
3732 if (pertrans->aggref->aggfilter && !isCombine)
3733 {
3734 /* evaluate filter expression */
3735 ExecInitExprRec(pertrans->aggref->aggfilter, state,
3736 &state->resvalue, &state->resnull);
3737 /* and jump out if false */
3738 scratch.opcode = EEOP_JUMP_IF_NOT_TRUE;
3739 scratch.d.jump.jumpdone = -1; /* adjust later */
3740 ExprEvalPushStep(state, &scratch);
3741 adjust_bailout = lappend_int(adjust_bailout,
3742 state->steps_len - 1);
3743 }
3744
3745 /*
3746 * Evaluate arguments to aggregate/combine function.
3747 */
3748 argno = 0;
3749 if (isCombine)
3750 {
3751 /*
3752 * Combining two aggregate transition values. Instead of directly
3753 * coming from a tuple the input is a, potentially deserialized,
3754 * transition value.
3755 */
3756 TargetEntry *source_tle;
3757
3758 Assert(pertrans->numSortCols == 0);
3759 Assert(list_length(pertrans->aggref->args) == 1);
3760
3761 strictargs = trans_fcinfo->args + 1;
3762 source_tle = (TargetEntry *) linitial(pertrans->aggref->args);
3763
3764 /*
3765 * deserialfn_oid will be set if we must deserialize the input
3766 * state before calling the combine function.
3767 */
3768 if (!OidIsValid(pertrans->deserialfn_oid))
3769 {
3770 /*
3771 * Start from 1, since the 0th arg will be the transition
3772 * value
3773 */
3774 ExecInitExprRec(source_tle->expr, state,
3775 &trans_fcinfo->args[argno + 1].value,
3776 &trans_fcinfo->args[argno + 1].isnull);
3777 }
3778 else
3779 {
3780 FunctionCallInfo ds_fcinfo = pertrans->deserialfn_fcinfo;
3781
3782 /* evaluate argument */
3783 ExecInitExprRec(source_tle->expr, state,
3784 &ds_fcinfo->args[0].value,
3785 &ds_fcinfo->args[0].isnull);
3786
3787 /* Dummy second argument for type-safety reasons */
3788 ds_fcinfo->args[1].value = PointerGetDatum(NULL);
3789 ds_fcinfo->args[1].isnull = false;
3790
3791 /*
3792 * Don't call a strict deserialization function with NULL
3793 * input
3794 */
3795 if (pertrans->deserialfn.fn_strict)
3796 scratch.opcode = EEOP_AGG_STRICT_DESERIALIZE;
3797 else
3798 scratch.opcode = EEOP_AGG_DESERIALIZE;
3799
3800 scratch.d.agg_deserialize.fcinfo_data = ds_fcinfo;
3801 scratch.d.agg_deserialize.jumpnull = -1; /* adjust later */
3802 scratch.resvalue = &trans_fcinfo->args[argno + 1].value;
3803 scratch.resnull = &trans_fcinfo->args[argno + 1].isnull;
3804
3805 ExprEvalPushStep(state, &scratch);
3806 /* don't add an adjustment unless the function is strict */
3807 if (pertrans->deserialfn.fn_strict)
3808 adjust_bailout = lappend_int(adjust_bailout,
3809 state->steps_len - 1);
3810
3811 /* restore normal settings of scratch fields */
3812 scratch.resvalue = &state->resvalue;
3813 scratch.resnull = &state->resnull;
3814 }
3815 argno++;
3816
3817 Assert(pertrans->numInputs == argno);
3818 }
3819 else if (!pertrans->aggsortrequired)
3820 {
3821 ListCell *arg;
3822
3823 /*
3824 * Normal transition function without ORDER BY / DISTINCT or with
3825 * ORDER BY / DISTINCT but the planner has given us pre-sorted
3826 * input.
3827 */
3828 strictargs = trans_fcinfo->args + 1;
3829
3830 foreach(arg, pertrans->aggref->args)
3831 {
3832 TargetEntry *source_tle = (TargetEntry *) lfirst(arg);
3833
3834 /*
3835 * Don't initialize args for any ORDER BY clause that might
3836 * exist in a presorted aggregate.
3837 */
3838 if (argno == pertrans->numTransInputs)
3839 break;
3840
3841 /*
3842 * Start from 1, since the 0th arg will be the transition
3843 * value
3844 */
3845 ExecInitExprRec(source_tle->expr, state,
3846 &trans_fcinfo->args[argno + 1].value,
3847 &trans_fcinfo->args[argno + 1].isnull);
3848 argno++;
3849 }
3850 Assert(pertrans->numTransInputs == argno);
3851 }
3852 else if (pertrans->numInputs == 1)
3853 {
3854 /*
3855 * Non-presorted DISTINCT and/or ORDER BY case, with a single
3856 * column sorted on.
3857 */
3858 TargetEntry *source_tle =
3859 (TargetEntry *) linitial(pertrans->aggref->args);
3860
3861 Assert(list_length(pertrans->aggref->args) == 1);
3862
3863 ExecInitExprRec(source_tle->expr, state,
3864 &state->resvalue,
3865 &state->resnull);
3866 strictnulls = &state->resnull;
3867 argno++;
3868
3869 Assert(pertrans->numInputs == argno);
3870 }
3871 else
3872 {
3873 /*
3874 * Non-presorted DISTINCT and/or ORDER BY case, with multiple
3875 * columns sorted on.
3876 */
3877 Datum *values = pertrans->sortslot->tts_values;
3878 bool *nulls = pertrans->sortslot->tts_isnull;
3879 ListCell *arg;
3880
3881 strictnulls = nulls;
3882
3883 foreach(arg, pertrans->aggref->args)
3884 {
3885 TargetEntry *source_tle = (TargetEntry *) lfirst(arg);
3886
3887 ExecInitExprRec(source_tle->expr, state,
3888 &values[argno], &nulls[argno]);
3889 argno++;
3890 }
3891 Assert(pertrans->numInputs == argno);
3892 }
3893
3894 /*
3895 * For a strict transfn, nothing happens when there's a NULL input; we
3896 * just keep the prior transValue. This is true for both plain and
3897 * sorted/distinct aggregates.
3898 */
3899 if (trans_fcinfo->flinfo->fn_strict && pertrans->numTransInputs > 0)
3900 {
3901 if (strictnulls)
3902 scratch.opcode = EEOP_AGG_STRICT_INPUT_CHECK_NULLS;
3903 else if (strictargs && pertrans->numTransInputs == 1)
3904 scratch.opcode = EEOP_AGG_STRICT_INPUT_CHECK_ARGS_1;
3905 else
3906 scratch.opcode = EEOP_AGG_STRICT_INPUT_CHECK_ARGS;
3907 scratch.d.agg_strict_input_check.nulls = strictnulls;
3908 scratch.d.agg_strict_input_check.args = strictargs;
3909 scratch.d.agg_strict_input_check.jumpnull = -1; /* adjust later */
3910 scratch.d.agg_strict_input_check.nargs = pertrans->numTransInputs;
3911 ExprEvalPushStep(state, &scratch);
3912 adjust_bailout = lappend_int(adjust_bailout,
3913 state->steps_len - 1);
3914 }
3915
3916 /* Handle DISTINCT aggregates which have pre-sorted input */
3917 if (pertrans->numDistinctCols > 0 && !pertrans->aggsortrequired)
3918 {
3919 if (pertrans->numDistinctCols > 1)
3920 scratch.opcode = EEOP_AGG_PRESORTED_DISTINCT_MULTI;
3921 else
3922 scratch.opcode = EEOP_AGG_PRESORTED_DISTINCT_SINGLE;
3923
3924 scratch.d.agg_presorted_distinctcheck.pertrans = pertrans;
3925 scratch.d.agg_presorted_distinctcheck.jumpdistinct = -1; /* adjust later */
3926 ExprEvalPushStep(state, &scratch);
3927 adjust_bailout = lappend_int(adjust_bailout,
3928 state->steps_len - 1);
3929 }
3930
3931 /*
3932 * Call transition function (once for each concurrently evaluated
3933 * grouping set). Do so for both sort and hash based computations, as
3934 * applicable.
3935 */
3936 if (doSort)
3937 {
3938 int processGroupingSets = Max(phase->numsets, 1);
3939 int setoff = 0;
3940
3941 for (int setno = 0; setno < processGroupingSets; setno++)
3942 {
3943 ExecBuildAggTransCall(state, aggstate, &scratch, trans_fcinfo,
3944 pertrans, transno, setno, setoff, false,
3945 nullcheck);
3946 setoff++;
3947 }
3948 }
3949
3950 if (doHash)
3951 {
3952 int numHashes = aggstate->num_hashes;
3953 int setoff;
3954
3955 /* in MIXED mode, there'll be preceding transition values */
3956 if (aggstate->aggstrategy != AGG_HASHED)
3957 setoff = aggstate->maxsets;
3958 else
3959 setoff = 0;
3960
3961 for (int setno = 0; setno < numHashes; setno++)
3962 {
3963 ExecBuildAggTransCall(state, aggstate, &scratch, trans_fcinfo,
3964 pertrans, transno, setno, setoff, true,
3965 nullcheck);
3966 setoff++;
3967 }
3968 }
3969
3970 /* adjust early bail out jump target(s) */
3971 foreach(bail, adjust_bailout)
3972 {
3973 ExprEvalStep *as = &state->steps[lfirst_int(bail)];
3974
3975 if (as->opcode == EEOP_JUMP_IF_NOT_TRUE)
3976 {
3977 Assert(as->d.jump.jumpdone == -1);
3978 as->d.jump.jumpdone = state->steps_len;
3979 }
3980 else if (as->opcode == EEOP_AGG_STRICT_INPUT_CHECK_ARGS ||
3981 as->opcode == EEOP_AGG_STRICT_INPUT_CHECK_ARGS_1 ||
3982 as->opcode == EEOP_AGG_STRICT_INPUT_CHECK_NULLS)
3983 {
3984 Assert(as->d.agg_strict_input_check.jumpnull == -1);
3985 as->d.agg_strict_input_check.jumpnull = state->steps_len;
3986 }
3987 else if (as->opcode == EEOP_AGG_STRICT_DESERIALIZE)
3988 {
3989 Assert(as->d.agg_deserialize.jumpnull == -1);
3990 as->d.agg_deserialize.jumpnull = state->steps_len;
3991 }
3992 else if (as->opcode == EEOP_AGG_PRESORTED_DISTINCT_SINGLE ||
3993 as->opcode == EEOP_AGG_PRESORTED_DISTINCT_MULTI)
3994 {
3995 Assert(as->d.agg_presorted_distinctcheck.jumpdistinct == -1);
3996 as->d.agg_presorted_distinctcheck.jumpdistinct = state->steps_len;
3997 }
3998 else
3999 Assert(false);
4000 }
4001 }
4002
4003 scratch.resvalue = NULL;
4004 scratch.resnull = NULL;
4005 scratch.opcode = EEOP_DONE_NO_RETURN;
4006 ExprEvalPushStep(state, &scratch);
4007
4008 ExecReadyExpr(state);
4009
4010 return state;
4011}
4012
4013/*
4014 * Build transition/combine function invocation for a single transition
4015 * value. This is separated from ExecBuildAggTrans() because there are
4016 * multiple callsites (hash and sort in some grouping set cases).
4017 */
4018static void
4019ExecBuildAggTransCall(ExprState *state, AggState *aggstate,
4020 ExprEvalStep *scratch,
4021 FunctionCallInfo fcinfo, AggStatePerTrans pertrans,
4022 int transno, int setno, int setoff, bool ishash,
4023 bool nullcheck)
4024{
4025 ExprContext *aggcontext;
4026 int adjust_jumpnull = -1;
4027
4028 if (ishash)
4029 aggcontext = aggstate->hashcontext;
4030 else
4031 aggcontext = aggstate->aggcontexts[setno];
4032
4033 /* add check for NULL pointer? */
4034 if (nullcheck)
4035 {
4036 scratch->opcode = EEOP_AGG_PLAIN_PERGROUP_NULLCHECK;
4037 scratch->d.agg_plain_pergroup_nullcheck.setoff = setoff;
4038 /* adjust later */
4039 scratch->d.agg_plain_pergroup_nullcheck.jumpnull = -1;
4040 ExprEvalPushStep(state, scratch);
4041 adjust_jumpnull = state->steps_len - 1;
4042 }
4043
4044 /*
4045 * Determine appropriate transition implementation.
4046 *
4047 * For non-ordered aggregates and ORDER BY / DISTINCT aggregates with
4048 * presorted input:
4049 *
4050 * If the initial value for the transition state doesn't exist in the
4051 * pg_aggregate table then we will let the first non-NULL value returned
4052 * from the outer procNode become the initial value. (This is useful for
4053 * aggregates like max() and min().) The noTransValue flag signals that we
4054 * need to do so. If true, generate a
4055 * EEOP_AGG_INIT_STRICT_PLAIN_TRANS{,_BYVAL} step. This step also needs to
4056 * do the work described next:
4057 *
4058 * If the function is strict, but does have an initial value, choose
4059 * EEOP_AGG_STRICT_PLAIN_TRANS{,_BYVAL}, which skips the transition
4060 * function if the transition value has become NULL (because a previous
4061 * transition function returned NULL). This step also needs to do the work
4062 * described next:
4063 *
4064 * Otherwise we call EEOP_AGG_PLAIN_TRANS{,_BYVAL}, which does not have to
4065 * perform either of the above checks.
4066 *
4067 * Having steps with overlapping responsibilities is not nice, but
4068 * aggregations are very performance sensitive, making this worthwhile.
4069 *
4070 * For ordered aggregates:
4071 *
4072 * Only need to choose between the faster path for a single ordered
4073 * column, and the one between multiple columns. Checking strictness etc
4074 * is done when finalizing the aggregate. See
4075 * process_ordered_aggregate_{single, multi} and
4076 * advance_transition_function.
4077 */
4078 if (!pertrans->aggsortrequired)
4079 {
4080 if (pertrans->transtypeByVal)
4081 {
4082 if (fcinfo->flinfo->fn_strict &&
4083 pertrans->initValueIsNull)
4084 scratch->opcode = EEOP_AGG_PLAIN_TRANS_INIT_STRICT_BYVAL;
4085 else if (fcinfo->flinfo->fn_strict)
4086 scratch->opcode = EEOP_AGG_PLAIN_TRANS_STRICT_BYVAL;
4087 else
4088 scratch->opcode = EEOP_AGG_PLAIN_TRANS_BYVAL;
4089 }
4090 else
4091 {
4092 if (fcinfo->flinfo->fn_strict &&
4093 pertrans->initValueIsNull)
4094 scratch->opcode = EEOP_AGG_PLAIN_TRANS_INIT_STRICT_BYREF;
4095 else if (fcinfo->flinfo->fn_strict)
4096 scratch->opcode = EEOP_AGG_PLAIN_TRANS_STRICT_BYREF;
4097 else
4098 scratch->opcode = EEOP_AGG_PLAIN_TRANS_BYREF;
4099 }
4100 }
4101 else if (pertrans->numInputs == 1)
4102 scratch->opcode = EEOP_AGG_ORDERED_TRANS_DATUM;
4103 else
4104 scratch->opcode = EEOP_AGG_ORDERED_TRANS_TUPLE;
4105
4106 scratch->d.agg_trans.pertrans = pertrans;
4107 scratch->d.agg_trans.setno = setno;
4108 scratch->d.agg_trans.setoff = setoff;
4109 scratch->d.agg_trans.transno = transno;
4110 scratch->d.agg_trans.aggcontext = aggcontext;
4111 ExprEvalPushStep(state, scratch);
4112
4113 /* fix up jumpnull */
4114 if (adjust_jumpnull != -1)
4115 {
4116 ExprEvalStep *as = &state->steps[adjust_jumpnull];
4117
4118 Assert(as->opcode == EEOP_AGG_PLAIN_PERGROUP_NULLCHECK);
4119 Assert(as->d.agg_plain_pergroup_nullcheck.jumpnull == -1);
4120 as->d.agg_plain_pergroup_nullcheck.jumpnull = state->steps_len;
4121 }
4122}
4123
4124/*
4125 * Build an ExprState that calls the given hash function(s) on the attnums
4126 * given by 'keyColIdx' . When numCols > 1, the hash values returned by each
4127 * hash function are combined to produce a single hash value.
4128 *
4129 * desc: tuple descriptor for the to-be-hashed columns
4130 * ops: TupleTableSlotOps to use for the give TupleDesc
4131 * hashfunctions: FmgrInfos for each hash function to call, one per numCols.
4132 * These are used directly in the returned ExprState so must remain allocated.
4133 * collations: collation to use when calling the hash function.
4134 * numCols: array length of hashfunctions, collations and keyColIdx.
4135 * parent: PlanState node that the resulting ExprState will be evaluated at
4136 * init_value: Normally 0, but can be set to other values to seed the hash
4137 * with. Non-zero is marginally slower, so best to only use if it's provably
4138 * worthwhile.
4139 */
4140ExprState *
4141ExecBuildHash32FromAttrs(TupleDesc desc, const TupleTableSlotOps *ops,
4142 FmgrInfo *hashfunctions, Oid *collations,
4143 int numCols, AttrNumber *keyColIdx,
4144 PlanState *parent, uint32 init_value)
4145{
4146 ExprState *state = makeNode(ExprState);
4147 ExprEvalStep scratch = {0};
4148 NullableDatum *iresult = NULL;
4149 intptr_t opcode;
4150 AttrNumber last_attnum = 0;
4151
4152 Assert(numCols >= 0);
4153
4154 state->parent = parent;
4155
4156 /*
4157 * Make a place to store intermediate hash values between subsequent
4158 * hashing of individual columns. We only need this if there is more than
4159 * one column to hash or an initial value plus one column.
4160 */
4161 if ((int64) numCols + (init_value != 0) > 1)
4162 iresult = palloc(sizeof(NullableDatum));
4163
4164 /* find the highest attnum so we deform the tuple to that point */
4165 for (int i = 0; i < numCols; i++)
4166 last_attnum = Max(last_attnum, keyColIdx[i]);
4167
4168 scratch.opcode = EEOP_INNER_FETCHSOME;
4169 scratch.d.fetch.last_var = last_attnum;
4170 scratch.d.fetch.fixed = false;
4171 scratch.d.fetch.kind = ops;
4172 scratch.d.fetch.known_desc = desc;
4173 if (ExecComputeSlotInfo(state, &scratch))
4174 ExprEvalPushStep(state, &scratch);
4175
4176 if (init_value == 0)
4177 {
4178 /*
4179 * No initial value, so we can assign the result of the hash function
4180 * for the first attribute without having to concern ourselves with
4181 * combining the result with any initial value.
4182 */
4183 opcode = EEOP_HASHDATUM_FIRST;
4184 }
4185 else
4186 {
4187 /*
4188 * Set up operation to set the initial value. Normally we store this
4189 * in the intermediate hash value location, but if there are no
4190 * columns to hash, store it in the ExprState's result field.
4191 */
4192 scratch.opcode = EEOP_HASHDATUM_SET_INITVAL;
4193 scratch.d.hashdatum_initvalue.init_value = UInt32GetDatum(init_value);
4194 scratch.resvalue = numCols > 0 ? &iresult->value : &state->resvalue;
4195 scratch.resnull = numCols > 0 ? &iresult->isnull : &state->resnull;
4196
4197 ExprEvalPushStep(state, &scratch);
4198
4199 /*
4200 * When using an initial value use the NEXT32 ops as the FIRST ops
4201 * would overwrite the stored initial value.
4202 */
4203 opcode = EEOP_HASHDATUM_NEXT32;
4204 }
4205
4206 for (int i = 0; i < numCols; i++)
4207 {
4208 FmgrInfo *finfo;
4209 FunctionCallInfo fcinfo;
4210 Oid inputcollid = collations[i];
4211 AttrNumber attnum = keyColIdx[i] - 1;
4212
4213 finfo = &hashfunctions[i];
4214 fcinfo = palloc0(SizeForFunctionCallInfo(1));
4215
4216 /* Initialize function call parameter structure too */
4217 InitFunctionCallInfoData(*fcinfo, finfo, 1, inputcollid, NULL, NULL);
4218
4219 /*
4220 * Fetch inner Var for this attnum and store it in the 1st arg of the
4221 * hash func.
4222 */
4223 scratch.opcode = EEOP_INNER_VAR;
4224 scratch.resvalue = &fcinfo->args[0].value;
4225 scratch.resnull = &fcinfo->args[0].isnull;
4226 scratch.d.var.attnum = attnum;
4227 scratch.d.var.vartype = TupleDescAttr(desc, attnum)->atttypid;
4228 scratch.d.var.varreturningtype = VAR_RETURNING_DEFAULT;
4229
4230 ExprEvalPushStep(state, &scratch);
4231
4232 /* Call the hash function */
4233 scratch.opcode = opcode;
4234
4235 if (i == numCols - 1)
4236 {
4237 /*
4238 * The result for hashing the final column is stored in the
4239 * ExprState.
4240 */
4241 scratch.resvalue = &state->resvalue;
4242 scratch.resnull = &state->resnull;
4243 }
4244 else
4245 {
4246 Assert(iresult != NULL);
4247
4248 /* intermediate values are stored in an intermediate result */
4249 scratch.resvalue = &iresult->value;
4250 scratch.resnull = &iresult->isnull;
4251 }
4252
4253 /*
4254 * NEXT32 opcodes need to look at the intermediate result. We might
4255 * as well just set this for all ops. FIRSTs won't look at it.
4256 */
4257 scratch.d.hashdatum.iresult = iresult;
4258
4259 scratch.d.hashdatum.finfo = finfo;
4260 scratch.d.hashdatum.fcinfo_data = fcinfo;
4261 scratch.d.hashdatum.fn_addr = finfo->fn_addr;
4262 scratch.d.hashdatum.jumpdone = -1;
4263
4264 ExprEvalPushStep(state, &scratch);
4265
4266 /* subsequent attnums must be combined with the previous */
4267 opcode = EEOP_HASHDATUM_NEXT32;
4268 }
4269
4270 scratch.resvalue = NULL;
4271 scratch.resnull = NULL;
4272 scratch.opcode = EEOP_DONE_RETURN;
4273 ExprEvalPushStep(state, &scratch);
4274
4275 ExecReadyExpr(state);
4276
4277 return state;
4278}
4279
4280/*
4281 * Build an ExprState that calls the given hash function(s) on the given
4282 * 'hash_exprs'. When multiple expressions are present, the hash values
4283 * returned by each hash function are combined to produce a single hash value.
4284 *
4285 * desc: tuple descriptor for the to-be-hashed expressions
4286 * ops: TupleTableSlotOps for the TupleDesc
4287 * hashfunc_oids: Oid for each hash function to call, one for each 'hash_expr'
4288 * collations: collation to use when calling the hash function.
4289 * hash_expr: list of expressions to hash the value of
4290 * opstrict: array corresponding to the 'hashfunc_oids' to store op_strict()
4291 * parent: PlanState node that the 'hash_exprs' will be evaluated at
4292 * init_value: Normally 0, but can be set to other values to seed the hash
4293 * with some other value. Using non-zero is slightly less efficient but can
4294 * be useful.
4295 * keep_nulls: if true, evaluation of the returned ExprState will abort early
4296 * returning NULL if the given hash function is strict and the Datum to hash
4297 * is null. When set to false, any NULL input Datums are skipped.
4298 */
4299ExprState *
4300ExecBuildHash32Expr(TupleDesc desc, const TupleTableSlotOps *ops,
4301 const Oid *hashfunc_oids, const List *collations,
4302 const List *hash_exprs, const bool *opstrict,
4303 PlanState *parent, uint32 init_value, bool keep_nulls)
4304{
4305 ExprState *state = makeNode(ExprState);
4306 ExprEvalStep scratch = {0};
4307 NullableDatum *iresult = NULL;
4308 List *adjust_jumps = NIL;
4309 ListCell *lc;
4310 ListCell *lc2;
4311 intptr_t strict_opcode;
4312 intptr_t opcode;
4313 int num_exprs = list_length(hash_exprs);
4314
4315 Assert(num_exprs == list_length(collations));
4316
4317 state->parent = parent;
4318
4319 /* Insert setup steps as needed. */
4320 ExecCreateExprSetupSteps(state, (Node *) hash_exprs);
4321
4322 /*
4323 * Make a place to store intermediate hash values between subsequent
4324 * hashing of individual expressions. We only need this if there is more
4325 * than one expression to hash or an initial value plus one expression.
4326 */
4327 if ((int64) num_exprs + (init_value != 0) > 1)
4328 iresult = palloc(sizeof(NullableDatum));
4329
4330 if (init_value == 0)
4331 {
4332 /*
4333 * No initial value, so we can assign the result of the hash function
4334 * for the first hash_expr without having to concern ourselves with
4335 * combining the result with any initial value.
4336 */
4337 strict_opcode = EEOP_HASHDATUM_FIRST_STRICT;
4338 opcode = EEOP_HASHDATUM_FIRST;
4339 }
4340 else
4341 {
4342 /*
4343 * Set up operation to set the initial value. Normally we store this
4344 * in the intermediate hash value location, but if there are no exprs
4345 * to hash, store it in the ExprState's result field.
4346 */
4347 scratch.opcode = EEOP_HASHDATUM_SET_INITVAL;
4348 scratch.d.hashdatum_initvalue.init_value = UInt32GetDatum(init_value);
4349 scratch.resvalue = num_exprs > 0 ? &iresult->value : &state->resvalue;
4350 scratch.resnull = num_exprs > 0 ? &iresult->isnull : &state->resnull;
4351
4352 ExprEvalPushStep(state, &scratch);
4353
4354 /*
4355 * When using an initial value use the NEXT32/NEXT32_STRICT ops as the
4356 * FIRST/FIRST_STRICT ops would overwrite the stored initial value.
4357 */
4358 strict_opcode = EEOP_HASHDATUM_NEXT32_STRICT;
4359 opcode = EEOP_HASHDATUM_NEXT32;
4360 }
4361
4362 forboth(lc, hash_exprs, lc2, collations)
4363 {
4364 Expr *expr = (Expr *) lfirst(lc);
4365 FmgrInfo *finfo;
4366 FunctionCallInfo fcinfo;
4367 int i = foreach_current_index(lc);
4368 Oid funcid;
4369 Oid inputcollid = lfirst_oid(lc2);
4370
4371 funcid = hashfunc_oids[i];
4372
4373 /* Allocate hash function lookup data. */
4374 finfo = palloc0(sizeof(FmgrInfo));
4375 fcinfo = palloc0(SizeForFunctionCallInfo(1));
4376
4377 fmgr_info(funcid, finfo);
4378
4379 /*
4380 * Build the steps to evaluate the hash function's argument have it so
4381 * the value of that is stored in the 0th argument of the hash func.
4382 */
4383 ExecInitExprRec(expr,
4384 state,
4385 &fcinfo->args[0].value,
4386 &fcinfo->args[0].isnull);
4387
4388 if (i == num_exprs - 1)
4389 {
4390 /* the result for hashing the final expr is stored in the state */
4391 scratch.resvalue = &state->resvalue;
4392 scratch.resnull = &state->resnull;
4393 }
4394 else
4395 {
4396 Assert(iresult != NULL);
4397
4398 /* intermediate values are stored in an intermediate result */
4399 scratch.resvalue = &iresult->value;
4400 scratch.resnull = &iresult->isnull;
4401 }
4402
4403 /*
4404 * NEXT32 opcodes need to look at the intermediate result. We might
4405 * as well just set this for all ops. FIRSTs won't look at it.
4406 */
4407 scratch.d.hashdatum.iresult = iresult;
4408
4409 /* Initialize function call parameter structure too */
4410 InitFunctionCallInfoData(*fcinfo, finfo, 1, inputcollid, NULL, NULL);
4411
4412 scratch.d.hashdatum.finfo = finfo;
4413 scratch.d.hashdatum.fcinfo_data = fcinfo;
4414 scratch.d.hashdatum.fn_addr = finfo->fn_addr;
4415
4416 scratch.opcode = opstrict[i] && !keep_nulls ? strict_opcode : opcode;
4417 scratch.d.hashdatum.jumpdone = -1;
4418
4419 ExprEvalPushStep(state, &scratch);
4420 adjust_jumps = lappend_int(adjust_jumps, state->steps_len - 1);
4421
4422 /*
4423 * For subsequent keys we must combine the hash value with the
4424 * previous hashes.
4425 */
4426 strict_opcode = EEOP_HASHDATUM_NEXT32_STRICT;
4427 opcode = EEOP_HASHDATUM_NEXT32;
4428 }
4429
4430 /* adjust jump targets */
4431 foreach(lc, adjust_jumps)
4432 {
4433 ExprEvalStep *as = &state->steps[lfirst_int(lc)];
4434
4435 Assert(as->opcode == EEOP_HASHDATUM_FIRST ||
4436 as->opcode == EEOP_HASHDATUM_FIRST_STRICT ||
4437 as->opcode == EEOP_HASHDATUM_NEXT32 ||
4438 as->opcode == EEOP_HASHDATUM_NEXT32_STRICT);
4439 Assert(as->d.hashdatum.jumpdone == -1);
4440 as->d.hashdatum.jumpdone = state->steps_len;
4441 }
4442
4443 scratch.resvalue = NULL;
4444 scratch.resnull = NULL;
4445 scratch.opcode = EEOP_DONE_RETURN;
4446 ExprEvalPushStep(state, &scratch);
4447
4448 ExecReadyExpr(state);
4449
4450 return state;
4451}
4452
4453/*
4454 * Build equality expression that can be evaluated using ExecQual(), returning
4455 * true if the expression context's inner/outer tuple are NOT DISTINCT. I.e
4456 * two nulls match, a null and a not-null don't match.
4457 *
4458 * desc: tuple descriptor of the to-be-compared tuples
4459 * numCols: the number of attributes to be examined
4460 * keyColIdx: array of attribute column numbers
4461 * eqFunctions: array of function oids of the equality functions to use
4462 * parent: parent executor node
4463 */
4464ExprState *
4465ExecBuildGroupingEqual(TupleDesc ldesc, TupleDesc rdesc,
4466 const TupleTableSlotOps *lops, const TupleTableSlotOps *rops,
4467 int numCols,
4468 const AttrNumber *keyColIdx,
4469 const Oid *eqfunctions,
4470 const Oid *collations,
4471 PlanState *parent)
4472{
4473 ExprState *state = makeNode(ExprState);
4474 ExprEvalStep scratch = {0};
4475 int maxatt = -1;
4476 List *adjust_jumps = NIL;
4477 ListCell *lc;
4478
4479 /*
4480 * When no columns are actually compared, the result's always true. See
4481 * special case in ExecQual().
4482 */
4483 if (numCols == 0)
4484 return NULL;
4485
4486 state->expr = NULL;
4487 state->flags = EEO_FLAG_IS_QUAL;
4488 state->parent = parent;
4489
4490 scratch.resvalue = &state->resvalue;
4491 scratch.resnull = &state->resnull;
4492
4493 /* compute max needed attribute */
4494 for (int natt = 0; natt < numCols; natt++)
4495 {
4496 int attno = keyColIdx[natt];
4497
4498 if (attno > maxatt)
4499 maxatt = attno;
4500 }
4501 Assert(maxatt >= 0);
4502
4503 /* push deform steps */
4504 scratch.opcode = EEOP_INNER_FETCHSOME;
4505 scratch.d.fetch.last_var = maxatt;
4506 scratch.d.fetch.fixed = false;
4507 scratch.d.fetch.known_desc = ldesc;
4508 scratch.d.fetch.kind = lops;
4509 if (ExecComputeSlotInfo(state, &scratch))
4510 ExprEvalPushStep(state, &scratch);
4511
4512 scratch.opcode = EEOP_OUTER_FETCHSOME;
4513 scratch.d.fetch.last_var = maxatt;
4514 scratch.d.fetch.fixed = false;
4515 scratch.d.fetch.known_desc = rdesc;
4516 scratch.d.fetch.kind = rops;
4517 if (ExecComputeSlotInfo(state, &scratch))
4518 ExprEvalPushStep(state, &scratch);
4519
4520 /*
4521 * Start comparing at the last field (least significant sort key). That's
4522 * the most likely to be different if we are dealing with sorted input.
4523 */
4524 for (int natt = numCols; --natt >= 0;)
4525 {
4526 int attno = keyColIdx[natt];
4527 Form_pg_attribute latt = TupleDescAttr(ldesc, attno - 1);
4528 Form_pg_attribute ratt = TupleDescAttr(rdesc, attno - 1);
4529 Oid foid = eqfunctions[natt];
4530 Oid collid = collations[natt];
4531 FmgrInfo *finfo;
4532 FunctionCallInfo fcinfo;
4533 AclResult aclresult;
4534
4535 /* Check permission to call function */
4536 aclresult = object_aclcheck(ProcedureRelationId, foid, GetUserId(), ACL_EXECUTE);
4537 if (aclresult != ACLCHECK_OK)
4538 aclcheck_error(aclresult, OBJECT_FUNCTION, get_func_name(foid));
4539
4540 InvokeFunctionExecuteHook(foid);
4541
4542 /* Set up the primary fmgr lookup information */
4543 finfo = palloc0(sizeof(FmgrInfo));
4544 fcinfo = palloc0(SizeForFunctionCallInfo(2));
4545 fmgr_info(foid, finfo);
4546 fmgr_info_set_expr(NULL, finfo);
4547 InitFunctionCallInfoData(*fcinfo, finfo, 2,
4548 collid, NULL, NULL);
4549
4550 /* left arg */
4551 scratch.opcode = EEOP_INNER_VAR;
4552 scratch.d.var.attnum = attno - 1;
4553 scratch.d.var.vartype = latt->atttypid;
4554 scratch.d.var.varreturningtype = VAR_RETURNING_DEFAULT;
4555 scratch.resvalue = &fcinfo->args[0].value;
4556 scratch.resnull = &fcinfo->args[0].isnull;
4557 ExprEvalPushStep(state, &scratch);
4558
4559 /* right arg */
4560 scratch.opcode = EEOP_OUTER_VAR;
4561 scratch.d.var.attnum = attno - 1;
4562 scratch.d.var.vartype = ratt->atttypid;
4563 scratch.d.var.varreturningtype = VAR_RETURNING_DEFAULT;
4564 scratch.resvalue = &fcinfo->args[1].value;
4565 scratch.resnull = &fcinfo->args[1].isnull;
4566 ExprEvalPushStep(state, &scratch);
4567
4568 /* evaluate distinctness */
4569 scratch.opcode = EEOP_NOT_DISTINCT;
4570 scratch.d.func.finfo = finfo;
4571 scratch.d.func.fcinfo_data = fcinfo;
4572 scratch.d.func.fn_addr = finfo->fn_addr;
4573 scratch.d.func.nargs = 2;
4574 scratch.resvalue = &state->resvalue;
4575 scratch.resnull = &state->resnull;
4576 ExprEvalPushStep(state, &scratch);
4577
4578 /* then emit EEOP_QUAL to detect if result is false (or null) */
4579 scratch.opcode = EEOP_QUAL;
4580 scratch.d.qualexpr.jumpdone = -1;
4581 scratch.resvalue = &state->resvalue;
4582 scratch.resnull = &state->resnull;
4583 ExprEvalPushStep(state, &scratch);
4584 adjust_jumps = lappend_int(adjust_jumps,
4585 state->steps_len - 1);
4586 }
4587
4588 /* adjust jump targets */
4589 foreach(lc, adjust_jumps)
4590 {
4591 ExprEvalStep *as = &state->steps[lfirst_int(lc)];
4592
4593 Assert(as->opcode == EEOP_QUAL);
4594 Assert(as->d.qualexpr.jumpdone == -1);
4595 as->d.qualexpr.jumpdone = state->steps_len;
4596 }
4597
4598 scratch.resvalue = NULL;
4599 scratch.resnull = NULL;
4600 scratch.opcode = EEOP_DONE_RETURN;
4601 ExprEvalPushStep(state, &scratch);
4602
4603 ExecReadyExpr(state);
4604
4605 return state;
4606}
4607
4608/*
4609 * Build equality expression that can be evaluated using ExecQual(), returning
4610 * true if the expression context's inner/outer tuples are equal. Datums in
4611 * the inner/outer slots are assumed to be in the same order and quantity as
4612 * the 'eqfunctions' parameter. NULLs are treated as equal.
4613 *
4614 * desc: tuple descriptor of the to-be-compared tuples
4615 * lops: the slot ops for the inner tuple slots
4616 * rops: the slot ops for the outer tuple slots
4617 * eqFunctions: array of function oids of the equality functions to use
4618 * this must be the same length as the 'param_exprs' list.
4619 * collations: collation Oids to use for equality comparison. Must be the
4620 * same length as the 'param_exprs' list.
4621 * parent: parent executor node
4622 */
4623ExprState *
4624ExecBuildParamSetEqual(TupleDesc desc,
4625 const TupleTableSlotOps *lops,
4626 const TupleTableSlotOps *rops,
4627 const Oid *eqfunctions,
4628 const Oid *collations,
4629 const List *param_exprs,
4630 PlanState *parent)
4631{
4632 ExprState *state = makeNode(ExprState);
4633 ExprEvalStep scratch = {0};
4634 int maxatt = list_length(param_exprs);
4635 List *adjust_jumps = NIL;
4636 ListCell *lc;
4637
4638 state->expr = NULL;
4639 state->flags = EEO_FLAG_IS_QUAL;
4640 state->parent = parent;
4641
4642 scratch.resvalue = &state->resvalue;
4643 scratch.resnull = &state->resnull;
4644
4645 /* push deform steps */
4646 scratch.opcode = EEOP_INNER_FETCHSOME;
4647 scratch.d.fetch.last_var = maxatt;
4648 scratch.d.fetch.fixed = false;
4649 scratch.d.fetch.known_desc = desc;
4650 scratch.d.fetch.kind = lops;
4651 if (ExecComputeSlotInfo(state, &scratch))
4652 ExprEvalPushStep(state, &scratch);
4653
4654 scratch.opcode = EEOP_OUTER_FETCHSOME;
4655 scratch.d.fetch.last_var = maxatt;
4656 scratch.d.fetch.fixed = false;
4657 scratch.d.fetch.known_desc = desc;
4658 scratch.d.fetch.kind = rops;
4659 if (ExecComputeSlotInfo(state, &scratch))
4660 ExprEvalPushStep(state, &scratch);
4661
4662 for (int attno = 0; attno < maxatt; attno++)
4663 {
4664 Form_pg_attribute att = TupleDescAttr(desc, attno);
4665 Oid foid = eqfunctions[attno];
4666 Oid collid = collations[attno];
4667 FmgrInfo *finfo;
4668 FunctionCallInfo fcinfo;
4669 AclResult aclresult;
4670
4671 /* Check permission to call function */
4672 aclresult = object_aclcheck(ProcedureRelationId, foid, GetUserId(), ACL_EXECUTE);
4673 if (aclresult != ACLCHECK_OK)
4674 aclcheck_error(aclresult, OBJECT_FUNCTION, get_func_name(foid));
4675
4676 InvokeFunctionExecuteHook(foid);
4677
4678 /* Set up the primary fmgr lookup information */
4679 finfo = palloc0(sizeof(FmgrInfo));
4680 fcinfo = palloc0(SizeForFunctionCallInfo(2));
4681 fmgr_info(foid, finfo);
4682 fmgr_info_set_expr(NULL, finfo);
4683 InitFunctionCallInfoData(*fcinfo, finfo, 2,
4684 collid, NULL, NULL);
4685
4686 /* left arg */
4687 scratch.opcode = EEOP_INNER_VAR;
4688 scratch.d.var.attnum = attno;
4689 scratch.d.var.vartype = att->atttypid;
4690 scratch.d.var.varreturningtype = VAR_RETURNING_DEFAULT;
4691 scratch.resvalue = &fcinfo->args[0].value;
4692 scratch.resnull = &fcinfo->args[0].isnull;
4693 ExprEvalPushStep(state, &scratch);
4694
4695 /* right arg */
4696 scratch.opcode = EEOP_OUTER_VAR;
4697 scratch.d.var.attnum = attno;
4698 scratch.d.var.vartype = att->atttypid;
4699 scratch.d.var.varreturningtype = VAR_RETURNING_DEFAULT;
4700 scratch.resvalue = &fcinfo->args[1].value;
4701 scratch.resnull = &fcinfo->args[1].isnull;
4702 ExprEvalPushStep(state, &scratch);
4703
4704 /* evaluate distinctness */
4705 scratch.opcode = EEOP_NOT_DISTINCT;
4706 scratch.d.func.finfo = finfo;
4707 scratch.d.func.fcinfo_data = fcinfo;
4708 scratch.d.func.fn_addr = finfo->fn_addr;
4709 scratch.d.func.nargs = 2;
4710 scratch.resvalue = &state->resvalue;
4711 scratch.resnull = &state->resnull;
4712 ExprEvalPushStep(state, &scratch);
4713
4714 /* then emit EEOP_QUAL to detect if result is false (or null) */
4715 scratch.opcode = EEOP_QUAL;
4716 scratch.d.qualexpr.jumpdone = -1;
4717 scratch.resvalue = &state->resvalue;
4718 scratch.resnull = &state->resnull;
4719 ExprEvalPushStep(state, &scratch);
4720 adjust_jumps = lappend_int(adjust_jumps,
4721 state->steps_len - 1);
4722 }
4723
4724 /* adjust jump targets */
4725 foreach(lc, adjust_jumps)
4726 {
4727 ExprEvalStep *as = &state->steps[lfirst_int(lc)];
4728
4729 Assert(as->opcode == EEOP_QUAL);
4730 Assert(as->d.qualexpr.jumpdone == -1);
4731 as->d.qualexpr.jumpdone = state->steps_len;
4732 }
4733
4734 scratch.resvalue = NULL;
4735 scratch.resnull = NULL;
4736 scratch.opcode = EEOP_DONE_RETURN;
4737 ExprEvalPushStep(state, &scratch);
4738
4739 ExecReadyExpr(state);
4740
4741 return state;
4742}
4743
4744/*
4745 * Push steps to evaluate a JsonExpr and its various subsidiary expressions.
4746 */
4747static void
4748ExecInitJsonExpr(JsonExpr *jsexpr, ExprState *state,
4749 Datum *resv, bool *resnull,
4750 ExprEvalStep *scratch)
4751{
4752 JsonExprState *jsestate = palloc0(sizeof(JsonExprState));
4753 ListCell *argexprlc;
4754 ListCell *argnamelc;
4755 List *jumps_return_null = NIL;
4756 List *jumps_to_end = NIL;
4757 ListCell *lc;
4758 ErrorSaveContext *escontext;
4759 bool returning_domain =
4760 get_typtype(jsexpr->returning->typid) == TYPTYPE_DOMAIN;
4761
4762 Assert(jsexpr->on_error != NULL);
4763
4764 jsestate->jsexpr = jsexpr;
4765
4766 /*
4767 * Evaluate formatted_expr storing the result into
4768 * jsestate->formatted_expr.
4769 */
4770 ExecInitExprRec((Expr *) jsexpr->formatted_expr, state,
4771 &jsestate->formatted_expr.value,
4772 &jsestate->formatted_expr.isnull);
4773
4774 /* JUMP to return NULL if formatted_expr evaluates to NULL */
4775 jumps_return_null = lappend_int(jumps_return_null, state->steps_len);
4776 scratch->opcode = EEOP_JUMP_IF_NULL;
4777 scratch->resnull = &jsestate->formatted_expr.isnull;
4778 scratch->d.jump.jumpdone = -1; /* set below */
4779 ExprEvalPushStep(state, scratch);
4780
4781 /*
4782 * Evaluate pathspec expression storing the result into
4783 * jsestate->pathspec.
4784 */
4785 ExecInitExprRec((Expr *) jsexpr->path_spec, state,
4786 &jsestate->pathspec.value,
4787 &jsestate->pathspec.isnull);
4788
4789 /* JUMP to return NULL if path_spec evaluates to NULL */
4790 jumps_return_null = lappend_int(jumps_return_null, state->steps_len);
4791 scratch->opcode = EEOP_JUMP_IF_NULL;
4792 scratch->resnull = &jsestate->pathspec.isnull;
4793 scratch->d.jump.jumpdone = -1; /* set below */
4794 ExprEvalPushStep(state, scratch);
4795
4796 /* Steps to compute PASSING args. */
4797 jsestate->args = NIL;
4798 forboth(argexprlc, jsexpr->passing_values,
4799 argnamelc, jsexpr->passing_names)
4800 {
4801 Expr *argexpr = (Expr *) lfirst(argexprlc);
4802 String *argname = lfirst_node(String, argnamelc);
4803 JsonPathVariable *var = palloc(sizeof(*var));
4804
4805 var->name = argname->sval;
4806 var->namelen = strlen(var->name);
4807 var->typid = exprType((Node *) argexpr);
4808 var->typmod = exprTypmod((Node *) argexpr);
4809
4810 ExecInitExprRec((Expr *) argexpr, state, &var->value, &var->isnull);
4811
4812 jsestate->args = lappend(jsestate->args, var);
4813 }
4814
4815 /* Step for jsonpath evaluation; see ExecEvalJsonExprPath(). */
4816 scratch->opcode = EEOP_JSONEXPR_PATH;
4817 scratch->resvalue = resv;
4818 scratch->resnull = resnull;
4819 scratch->d.jsonexpr.jsestate = jsestate;
4820 ExprEvalPushStep(state, scratch);
4821
4822 /*
4823 * Step to return NULL after jumping to skip the EEOP_JSONEXPR_PATH step
4824 * when either formatted_expr or pathspec is NULL. Adjust jump target
4825 * addresses of JUMPs that we added above.
4826 */
4827 foreach(lc, jumps_return_null)
4828 {
4829 ExprEvalStep *as = &state->steps[lfirst_int(lc)];
4830
4831 as->d.jump.jumpdone = state->steps_len;
4832 }
4833 scratch->opcode = EEOP_CONST;
4834 scratch->resvalue = resv;
4835 scratch->resnull = resnull;
4836 scratch->d.constval.value = (Datum) 0;
4837 scratch->d.constval.isnull = true;
4838 ExprEvalPushStep(state, scratch);
4839
4840 escontext = jsexpr->on_error->btype != JSON_BEHAVIOR_ERROR ?
4841 &jsestate->escontext : NULL;
4842
4843 /*
4844 * To handle coercion errors softly, use the following ErrorSaveContext to
4845 * pass to ExecInitExprRec() when initializing the coercion expressions
4846 * and in the EEOP_JSONEXPR_COERCION step.
4847 */
4848 jsestate->escontext.type = T_ErrorSaveContext;
4849
4850 /*
4851 * Steps to coerce the result value computed by EEOP_JSONEXPR_PATH or the
4852 * NULL returned on NULL input as described above.
4853 */
4854 jsestate->jump_eval_coercion = -1;
4855 if (jsexpr->use_json_coercion)
4856 {
4857 jsestate->jump_eval_coercion = state->steps_len;
4858
4859 ExecInitJsonCoercion(state, jsexpr->returning, escontext,
4860 jsexpr->omit_quotes,
4861 jsexpr->op == JSON_EXISTS_OP,
4862 resv, resnull);
4863 }
4864 else if (jsexpr->use_io_coercion)
4865 {
4866 /*
4867 * Here we only need to initialize the FunctionCallInfo for the target
4868 * type's input function, which is called by ExecEvalJsonExprPath()
4869 * itself, so no additional step is necessary.
4870 */
4871 Oid typinput;
4872 Oid typioparam;
4873 FmgrInfo *finfo;
4874 FunctionCallInfo fcinfo;
4875
4876 getTypeInputInfo(jsexpr->returning->typid, &typinput, &typioparam);
4877 finfo = palloc0(sizeof(FmgrInfo));
4878 fcinfo = palloc0(SizeForFunctionCallInfo(3));
4879 fmgr_info(typinput, finfo);
4880 fmgr_info_set_expr((Node *) jsexpr->returning, finfo);
4881 InitFunctionCallInfoData(*fcinfo, finfo, 3, InvalidOid, NULL, NULL);
4882
4883 /*
4884 * We can preload the second and third arguments for the input
4885 * function, since they're constants.
4886 */
4887 fcinfo->args[1].value = ObjectIdGetDatum(typioparam);
4888 fcinfo->args[1].isnull = false;
4889 fcinfo->args[2].value = Int32GetDatum(jsexpr->returning->typmod);
4890 fcinfo->args[2].isnull = false;
4891 fcinfo->context = (Node *) escontext;
4892
4893 jsestate->input_fcinfo = fcinfo;
4894 }
4895
4896 /*
4897 * Add a special step, if needed, to check if the coercion evaluation ran
4898 * into an error but was not thrown because the ON ERROR behavior is not
4899 * ERROR. It will set jsestate->error if an error did occur.
4900 */
4901 if (jsestate->jump_eval_coercion >= 0 && escontext != NULL)
4902 {
4903 scratch->opcode = EEOP_JSONEXPR_COERCION_FINISH;
4904 scratch->d.jsonexpr.jsestate = jsestate;
4905 ExprEvalPushStep(state, scratch);
4906 }
4907
4908 jsestate->jump_empty = jsestate->jump_error = -1;
4909
4910 /*
4911 * Step to check jsestate->error and return the ON ERROR expression if
4912 * there is one. This handles both the errors that occur during jsonpath
4913 * evaluation in EEOP_JSONEXPR_PATH and subsequent coercion evaluation.
4914 *
4915 * Speed up common cases by avoiding extra steps for a NULL-valued ON
4916 * ERROR expression unless RETURNING a domain type, where constraints must
4917 * be checked. ExecEvalJsonExprPath() already returns NULL on error,
4918 * making additional steps unnecessary in typical scenarios. Note that the
4919 * default ON ERROR behavior for JSON_VALUE() and JSON_QUERY() is to
4920 * return NULL.
4921 */
4922 if (jsexpr->on_error->btype != JSON_BEHAVIOR_ERROR &&
4923 (!(IsA(jsexpr->on_error->expr, Const) &&
4924 ((Const *) jsexpr->on_error->expr)->constisnull) ||
4925 returning_domain))
4926 {
4927 ErrorSaveContext *saved_escontext;
4928
4929 jsestate->jump_error = state->steps_len;
4930
4931 /* JUMP to end if false, that is, skip the ON ERROR expression. */
4932 jumps_to_end = lappend_int(jumps_to_end, state->steps_len);
4933 scratch->opcode = EEOP_JUMP_IF_NOT_TRUE;
4934 scratch->resvalue = &jsestate->error.value;
4935 scratch->resnull = &jsestate->error.isnull;
4936 scratch->d.jump.jumpdone = -1; /* set below */
4937 ExprEvalPushStep(state, scratch);
4938
4939 /*
4940 * Steps to evaluate the ON ERROR expression; handle errors softly to
4941 * rethrow them in COERCION_FINISH step that will be added later.
4942 */
4943 saved_escontext = state->escontext;
4944 state->escontext = escontext;
4945 ExecInitExprRec((Expr *) jsexpr->on_error->expr,
4946 state, resv, resnull);
4947 state->escontext = saved_escontext;
4948
4949 /* Step to coerce the ON ERROR expression if needed */
4950 if (jsexpr->on_error->coerce)
4951 ExecInitJsonCoercion(state, jsexpr->returning, escontext,
4952 jsexpr->omit_quotes, false,
4953 resv, resnull);
4954
4955 /*
4956 * Add a COERCION_FINISH step to check for errors that may occur when
4957 * coercing and rethrow them.
4958 */
4959 if (jsexpr->on_error->coerce ||
4960 IsA(jsexpr->on_error->expr, CoerceViaIO) ||
4961 IsA(jsexpr->on_error->expr, CoerceToDomain))
4962 {
4963 scratch->opcode = EEOP_JSONEXPR_COERCION_FINISH;
4964 scratch->resvalue = resv;
4965 scratch->resnull = resnull;
4966 scratch->d.jsonexpr.jsestate = jsestate;
4967 ExprEvalPushStep(state, scratch);
4968 }
4969
4970 /* JUMP to end to skip the ON EMPTY steps added below. */
4971 jumps_to_end = lappend_int(jumps_to_end, state->steps_len);
4972 scratch->opcode = EEOP_JUMP;
4973 scratch->d.jump.jumpdone = -1;
4974 ExprEvalPushStep(state, scratch);
4975 }
4976
4977 /*
4978 * Step to check jsestate->empty and return the ON EMPTY expression if
4979 * there is one.
4980 *
4981 * See the comment above for details on the optimization for NULL-valued
4982 * expressions.
4983 */
4984 if (jsexpr->on_empty != NULL &&
4985 jsexpr->on_empty->btype != JSON_BEHAVIOR_ERROR &&
4986 (!(IsA(jsexpr->on_empty->expr, Const) &&
4987 ((Const *) jsexpr->on_empty->expr)->constisnull) ||
4988 returning_domain))
4989 {
4990 ErrorSaveContext *saved_escontext;
4991
4992 jsestate->jump_empty = state->steps_len;
4993
4994 /* JUMP to end if false, that is, skip the ON EMPTY expression. */
4995 jumps_to_end = lappend_int(jumps_to_end, state->steps_len);
4996 scratch->opcode = EEOP_JUMP_IF_NOT_TRUE;
4997 scratch->resvalue = &jsestate->empty.value;
4998 scratch->resnull = &jsestate->empty.isnull;
4999 scratch->d.jump.jumpdone = -1; /* set below */
5000 ExprEvalPushStep(state, scratch);
5001
5002 /*
5003 * Steps to evaluate the ON EMPTY expression; handle errors softly to
5004 * rethrow them in COERCION_FINISH step that will be added later.
5005 */
5006 saved_escontext = state->escontext;
5007 state->escontext = escontext;
5008 ExecInitExprRec((Expr *) jsexpr->on_empty->expr,
5009 state, resv, resnull);
5010 state->escontext = saved_escontext;
5011
5012 /* Step to coerce the ON EMPTY expression if needed */
5013 if (jsexpr->on_empty->coerce)
5014 ExecInitJsonCoercion(state, jsexpr->returning, escontext,
5015 jsexpr->omit_quotes, false,
5016 resv, resnull);
5017
5018 /*
5019 * Add a COERCION_FINISH step to check for errors that may occur when
5020 * coercing and rethrow them.
5021 */
5022 if (jsexpr->on_empty->coerce ||
5023 IsA(jsexpr->on_empty->expr, CoerceViaIO) ||
5024 IsA(jsexpr->on_empty->expr, CoerceToDomain))
5025 {
5026
5027 scratch->opcode = EEOP_JSONEXPR_COERCION_FINISH;
5028 scratch->resvalue = resv;
5029 scratch->resnull = resnull;
5030 scratch->d.jsonexpr.jsestate = jsestate;
5031 ExprEvalPushStep(state, scratch);
5032 }
5033 }
5034
5035 foreach(lc, jumps_to_end)
5036 {
5037 ExprEvalStep *as = &state->steps[lfirst_int(lc)];
5038
5039 as->d.jump.jumpdone = state->steps_len;
5040 }
5041
5042 jsestate->jump_end = state->steps_len;
5043}
5044
5045/*
5046 * Initialize a EEOP_JSONEXPR_COERCION step to coerce the value given in resv
5047 * to the given RETURNING type.
5048 */
5049static void
5050ExecInitJsonCoercion(ExprState *state, JsonReturning *returning,
5051 ErrorSaveContext *escontext, bool omit_quotes,
5052 bool exists_coerce,
5053 Datum *resv, bool *resnull)
5054{
5055 ExprEvalStep scratch = {0};
5056
5057 /* For json_populate_type() */
5058 scratch.opcode = EEOP_JSONEXPR_COERCION;
5059 scratch.resvalue = resv;
5060 scratch.resnull = resnull;
5061 scratch.d.jsonexpr_coercion.targettype = returning->typid;
5062 scratch.d.jsonexpr_coercion.targettypmod = returning->typmod;
5063 scratch.d.jsonexpr_coercion.json_coercion_cache = NULL;
5064 scratch.d.jsonexpr_coercion.escontext = escontext;
5065 scratch.d.jsonexpr_coercion.omit_quotes = omit_quotes;
5066 scratch.d.jsonexpr_coercion.exists_coerce = exists_coerce;
5067 scratch.d.jsonexpr_coercion.exists_cast_to_int = exists_coerce &&
5068 getBaseType(returning->typid) == INT4OID;
5069 scratch.d.jsonexpr_coercion.exists_check_domain = exists_coerce &&
5070 DomainHasConstraints(returning->typid);
5071 ExprEvalPushStep(state, &scratch);
5072}
AclResult
AclResult
Definition: acl.h:182
ACLCHECK_OK
@ ACLCHECK_OK
Definition: acl.h:183
aclcheck_error
void aclcheck_error(AclResult aclerr, ObjectType objtype, const char *objectname)
Definition: aclchk.c:2639
object_aclcheck
AclResult object_aclcheck(Oid classid, Oid objectid, Oid roleid, AclMode mode)
Definition: aclchk.c:3821
AttrNumber
int16 AttrNumber
Definition: attnum.h:21
InvalidAttrNumber
#define InvalidAttrNumber
Definition: attnum.h:23
bms_is_member
bool bms_is_member(int x, const Bitmapset *a)
Definition: bitmapset.c:510
bms_add_member
Bitmapset * bms_add_member(Bitmapset *a, int x)
Definition: bitmapset.c:815
values
static Datum values[MAXATTR]
Definition: bootstrap.c:151
MAXALIGN
#define MAXALIGN(LEN)
Definition: c.h:782
Max
#define Max(x, y)
Definition: c.h:969
int64
int64_t int64
Definition: c.h:499
uint32
uint32_t uint32
Definition: c.h:502
OidIsValid
#define OidIsValid(objectId)
Definition: c.h:746
collid
Oid collid
Definition: collationcmds.c:700
errmsg_plural
int errmsg_plural(const char *fmt_singular, const char *fmt_plural, unsigned long n,...)
Definition: elog.c:1181
errdetail
int errdetail(const char *fmt,...)
Definition: elog.c:1204
errcode
int errcode(int sqlerrcode)
Definition: elog.c:854
errmsg
int errmsg(const char *fmt,...)
Definition: elog.c:1071
ERROR
#define ERROR
Definition: elog.h:39
elog
#define elog(elevel,...)
Definition: elog.h:225
ereport
#define ereport(elevel,...)
Definition: elog.h:149
ExecReadyInterpretedExpr
void ExecReadyInterpretedExpr(ExprState *state)
Definition: execExprInterp.c:242
ExecInitCoerceToDomain
static void ExecInitCoerceToDomain(ExprEvalStep *scratch, CoerceToDomain *ctest, ExprState *state, Datum *resv, bool *resnull)
Definition: execExpr.c:3522
ExecInitSubPlanExpr
static void ExecInitSubPlanExpr(SubPlan *subplan, ExprState *state, Datum *resv, bool *resnull)
Definition: execExpr.c:2821
ExecBuildHash32FromAttrs
ExprState * ExecBuildHash32FromAttrs(TupleDesc desc, const TupleTableSlotOps *ops, FmgrInfo *hashfunctions, Oid *collations, int numCols, AttrNumber *keyColIdx, PlanState *parent, uint32 init_value)
Definition: execExpr.c:4141
ExecInitExpr
ExprState * ExecInitExpr(Expr *node, PlanState *parent)
Definition: execExpr.c:143
ExecPrepareExpr
ExprState * ExecPrepareExpr(Expr *node, EState *estate)
Definition: execExpr.c:765
ExecCheck
bool ExecCheck(ExprState *state, ExprContext *econtext)
Definition: execExpr.c:872
ExecInitCheck
ExprState * ExecInitCheck(List *qual, PlanState *parent)
Definition: execExpr.c:315
ExecPushExprSetupSteps
static void ExecPushExprSetupSteps(ExprState *state, ExprSetupInfo *info)
Definition: execExpr.c:2897
ExecInitExprRec
static void ExecInitExprRec(Expr *node, ExprState *state, Datum *resv, bool *resnull)
Definition: execExpr.c:919
ExecBuildAggTransCall
static void ExecBuildAggTransCall(ExprState *state, AggState *aggstate, ExprEvalStep *scratch, FunctionCallInfo fcinfo, AggStatePerTrans pertrans, int transno, int setno, int setoff, bool ishash, bool nullcheck)
Definition: execExpr.c:4019
ExecInitWholeRowVar
static void ExecInitWholeRowVar(ExprEvalStep *scratch, Var *variable, ExprState *state)
Definition: execExpr.c:3164
ExprEvalPushStep
void ExprEvalPushStep(ExprState *es, const ExprEvalStep *s)
Definition: execExpr.c:2678
ExecBuildProjectionInfo
ProjectionInfo * ExecBuildProjectionInfo(List *targetList, ExprContext *econtext, TupleTableSlot *slot, PlanState *parent, TupleDesc inputDesc)
Definition: execExpr.c:370
ExprSetupInfo
struct ExprSetupInfo ExprSetupInfo
isAssignmentIndirectionExpr
static bool isAssignmentIndirectionExpr(Expr *expr)
Definition: execExpr.c:3485
ExecInitSubscriptingRef
static void ExecInitSubscriptingRef(ExprEvalStep *scratch, SubscriptingRef *sbsref, ExprState *state, Datum *resv, bool *resnull)
Definition: execExpr.c:3243
ExecPrepareQual
ExprState * ExecPrepareQual(List *qual, EState *estate)
Definition: execExpr.c:793
ExecInitQual
ExprState * ExecInitQual(List *qual, PlanState *parent)
Definition: execExpr.c:229
expr_setup_walker
static bool expr_setup_walker(Node *node, ExprSetupInfo *info)
Definition: execExpr.c:2983
ExecInitJsonCoercion
static void ExecInitJsonCoercion(ExprState *state, JsonReturning *returning, ErrorSaveContext *escontext, bool omit_quotes, bool exists_coerce, Datum *resv, bool *resnull)
Definition: execExpr.c:5050
ExecInitExprList
List * ExecInitExprList(List *nodes, PlanState *parent)
Definition: execExpr.c:335
ExecInitExprWithParams
ExprState * ExecInitExprWithParams(Expr *node, ParamListInfo ext_params)
Definition: execExpr.c:180
ExecBuildUpdateProjection
ProjectionInfo * ExecBuildUpdateProjection(List *targetList, bool evalTargetList, List *targetColnos, TupleDesc relDesc, ExprContext *econtext, TupleTableSlot *slot, PlanState *parent)
Definition: execExpr.c:547
ExecBuildGroupingEqual
ExprState * ExecBuildGroupingEqual(TupleDesc ldesc, TupleDesc rdesc, const TupleTableSlotOps *lops, const TupleTableSlotOps *rops, int numCols, const AttrNumber *keyColIdx, const Oid *eqfunctions, const Oid *collations, PlanState *parent)
Definition: execExpr.c:4465
ExecComputeSlotInfo
static bool ExecComputeSlotInfo(ExprState *state, ExprEvalStep *op)
Definition: execExpr.c:3062
ExecBuildAggTrans
ExprState * ExecBuildAggTrans(AggState *aggstate, AggStatePerPhase phase, bool doSort, bool doHash, bool nullcheck)
Definition: execExpr.c:3677
ExecInitFunc
static void ExecInitFunc(ExprEvalStep *scratch, Expr *node, List *args, Oid funcid, Oid inputcollid, ExprState *state)
Definition: execExpr.c:2704
ExecCreateExprSetupSteps
static void ExecCreateExprSetupSteps(ExprState *state, Node *node)
Definition: execExpr.c:2881
ExecPrepareExprList
List * ExecPrepareExprList(List *nodes, EState *estate)
Definition: execExpr.c:839
ExecReadyExpr
static void ExecReadyExpr(ExprState *state)
Definition: execExpr.c:902
ExecInitJsonExpr
static void ExecInitJsonExpr(JsonExpr *jsexpr, ExprState *state, Datum *resv, bool *resnull, ExprEvalStep *scratch)
Definition: execExpr.c:4748
ExecBuildParamSetEqual
ExprState * ExecBuildParamSetEqual(TupleDesc desc, const TupleTableSlotOps *lops, const TupleTableSlotOps *rops, const Oid *eqfunctions, const Oid *collations, const List *param_exprs, PlanState *parent)
Definition: execExpr.c:4624
ExecBuildHash32Expr
ExprState * ExecBuildHash32Expr(TupleDesc desc, const TupleTableSlotOps *ops, const Oid *hashfunc_oids, const List *collations, const List *hash_exprs, const bool *opstrict, PlanState *parent, uint32 init_value, bool keep_nulls)
Definition: execExpr.c:4300
ExecPrepareCheck
ExprState * ExecPrepareCheck(List *qual, EState *estate)
Definition: execExpr.c:816
ExprEvalOp
ExprEvalOp
Definition: execExpr.h:67
EEOP_OLD_VAR
@ EEOP_OLD_VAR
Definition: execExpr.h:85
EEOP_ASSIGN_TMP
@ EEOP_ASSIGN_TMP
Definition: execExpr.h:110
EEOP_SUBPLAN
@ EEOP_SUBPLAN
Definition: execExpr.h:275
EEOP_CONVERT_ROWTYPE
@ EEOP_CONVERT_ROWTYPE
Definition: execExpr.h:262
EEOP_FUNCEXPR_STRICT_FUSAGE
@ EEOP_FUNCEXPR_STRICT_FUSAGE
Definition: execExpr.h:127
EEOP_ARRAYEXPR
@ EEOP_ARRAYEXPR
Definition: execExpr.h:196
EEOP_JSONEXPR_PATH
@ EEOP_JSONEXPR_PATH
Definition: execExpr.h:268
EEOP_NOT_DISTINCT
@ EEOP_NOT_DISTINCT
Definition: execExpr.h:190
EEOP_DOMAIN_TESTVAL
@ EEOP_DOMAIN_TESTVAL
Definition: execExpr.h:245
EEOP_PARAM_EXTERN
@ EEOP_PARAM_EXTERN
Definition: execExpr.h:174
EEOP_HASHDATUM_NEXT32_STRICT
@ EEOP_HASHDATUM_NEXT32_STRICT
Definition: execExpr.h:259
EEOP_IOCOERCE_SAFE
@ EEOP_IOCOERCE_SAFE
Definition: execExpr.h:188
EEOP_BOOL_AND_STEP
@ EEOP_BOOL_AND_STEP
Definition: execExpr.h:136
EEOP_DONE_RETURN
@ EEOP_DONE_RETURN
Definition: execExpr.h:69
EEOP_WHOLEROW
@ EEOP_WHOLEROW
Definition: execExpr.h:96
EEOP_JSONEXPR_COERCION_FINISH
@ EEOP_JSONEXPR_COERCION_FINISH
Definition: execExpr.h:270
EEOP_HASHDATUM_FIRST_STRICT
@ EEOP_HASHDATUM_FIRST_STRICT
Definition: execExpr.h:257
EEOP_AGGREF
@ EEOP_AGGREF
Definition: execExpr.h:271
EEOP_FUNCEXPR_STRICT_1
@ EEOP_FUNCEXPR_STRICT_1
Definition: execExpr.h:124
EEOP_INNER_VAR
@ EEOP_INNER_VAR
Definition: execExpr.h:82
EEOP_AGG_PLAIN_PERGROUP_NULLCHECK
@ EEOP_AGG_PLAIN_PERGROUP_NULLCHECK
Definition: execExpr.h:283
EEOP_HASHDATUM_NEXT32
@ EEOP_HASHDATUM_NEXT32
Definition: execExpr.h:258
EEOP_ROWCOMPARE_FINAL
@ EEOP_ROWCOMPARE_FINAL
Definition: execExpr.h:207
EEOP_AGG_STRICT_DESERIALIZE
@ EEOP_AGG_STRICT_DESERIALIZE
Definition: execExpr.h:278
EEOP_IOCOERCE
@ EEOP_IOCOERCE
Definition: execExpr.h:187
EEOP_RETURNINGEXPR
@ EEOP_RETURNINGEXPR
Definition: execExpr.h:195
EEOP_GROUPING_FUNC
@ EEOP_GROUPING_FUNC
Definition: execExpr.h:272
EEOP_DOMAIN_CHECK
@ EEOP_DOMAIN_CHECK
Definition: execExpr.h:252
EEOP_BOOLTEST_IS_NOT_FALSE
@ EEOP_BOOLTEST_IS_NOT_FALSE
Definition: execExpr.h:170
EEOP_PARAM_SET
@ EEOP_PARAM_SET
Definition: execExpr.h:177
EEOP_NEXTVALUEEXPR
@ EEOP_NEXTVALUEEXPR
Definition: execExpr.h:194
EEOP_NEW_SYSVAR
@ EEOP_NEW_SYSVAR
Definition: execExpr.h:93
EEOP_AGG_PLAIN_TRANS_BYREF
@ EEOP_AGG_PLAIN_TRANS_BYREF
Definition: execExpr.h:289
EEOP_QUAL
@ EEOP_QUAL
Definition: execExpr.h:148
EEOP_AGG_PRESORTED_DISTINCT_MULTI
@ EEOP_AGG_PRESORTED_DISTINCT_MULTI
Definition: execExpr.h:291
EEOP_AGG_PLAIN_TRANS_BYVAL
@ EEOP_AGG_PLAIN_TRANS_BYVAL
Definition: execExpr.h:286
EEOP_SCAN_VAR
@ EEOP_SCAN_VAR
Definition: execExpr.h:84
EEOP_CASE_TESTVAL_EXT
@ EEOP_CASE_TESTVAL_EXT
Definition: execExpr.h:181
EEOP_BOOL_NOT_STEP
@ EEOP_BOOL_NOT_STEP
Definition: execExpr.h:145
EEOP_ASSIGN_SCAN_VAR
@ EEOP_ASSIGN_SCAN_VAR
Definition: execExpr.h:105
EEOP_NEW_VAR
@ EEOP_NEW_VAR
Definition: execExpr.h:86
EEOP_SCAN_SYSVAR
@ EEOP_SCAN_SYSVAR
Definition: execExpr.h:91
EEOP_SCALARARRAYOP
@ EEOP_SCALARARRAYOP
Definition: execExpr.h:263
EEOP_DOMAIN_NOTNULL
@ EEOP_DOMAIN_NOTNULL
Definition: execExpr.h:249
EEOP_WINDOW_FUNC
@ EEOP_WINDOW_FUNC
Definition: execExpr.h:273
EEOP_INNER_FETCHSOME
@ EEOP_INNER_FETCHSOME
Definition: execExpr.h:75
EEOP_NULLTEST_ROWISNOTNULL
@ EEOP_NULLTEST_ROWISNOTNULL
Definition: execExpr.h:164
EEOP_ASSIGN_OUTER_VAR
@ EEOP_ASSIGN_OUTER_VAR
Definition: execExpr.h:104
EEOP_ROW
@ EEOP_ROW
Definition: execExpr.h:198
EEOP_MAKE_READONLY
@ EEOP_MAKE_READONLY
Definition: execExpr.h:184
EEOP_FIELDSTORE_FORM
@ EEOP_FIELDSTORE_FORM
Definition: execExpr.h:226
EEOP_ASSIGN_OLD_VAR
@ EEOP_ASSIGN_OLD_VAR
Definition: execExpr.h:106
EEOP_SBSREF_SUBSCRIPTS
@ EEOP_SBSREF_SUBSCRIPTS
Definition: execExpr.h:229
EEOP_FUNCEXPR_STRICT_2
@ EEOP_FUNCEXPR_STRICT_2
Definition: execExpr.h:125
EEOP_SBSREF_FETCH
@ EEOP_SBSREF_FETCH
Definition: execExpr.h:242
EEOP_FUNCEXPR_STRICT
@ EEOP_FUNCEXPR_STRICT
Definition: execExpr.h:123
EEOP_NULLIF
@ EEOP_NULLIF
Definition: execExpr.h:191
EEOP_CURRENTOFEXPR
@ EEOP_CURRENTOFEXPR
Definition: execExpr.h:193
EEOP_INNER_SYSVAR
@ EEOP_INNER_SYSVAR
Definition: execExpr.h:89
EEOP_ASSIGN_TMP_MAKE_RO
@ EEOP_ASSIGN_TMP_MAKE_RO
Definition: execExpr.h:112
EEOP_CONST
@ EEOP_CONST
Definition: execExpr.h:115
EEOP_BOOL_OR_STEP_LAST
@ EEOP_BOOL_OR_STEP_LAST
Definition: execExpr.h:142
EEOP_JSONEXPR_COERCION
@ EEOP_JSONEXPR_COERCION
Definition: execExpr.h:269
EEOP_BOOL_OR_STEP_FIRST
@ EEOP_BOOL_OR_STEP_FIRST
Definition: execExpr.h:140
EEOP_XMLEXPR
@ EEOP_XMLEXPR
Definition: execExpr.h:265
EEOP_AGG_STRICT_INPUT_CHECK_NULLS
@ EEOP_AGG_STRICT_INPUT_CHECK_NULLS
Definition: execExpr.h:282
EEOP_SBSREF_ASSIGN
@ EEOP_SBSREF_ASSIGN
Definition: execExpr.h:239
EEOP_OUTER_SYSVAR
@ EEOP_OUTER_SYSVAR
Definition: execExpr.h:90
EEOP_ASSIGN_INNER_VAR
@ EEOP_ASSIGN_INNER_VAR
Definition: execExpr.h:103
EEOP_BOOL_OR_STEP
@ EEOP_BOOL_OR_STEP
Definition: execExpr.h:141
EEOP_AGG_STRICT_INPUT_CHECK_ARGS_1
@ EEOP_AGG_STRICT_INPUT_CHECK_ARGS_1
Definition: execExpr.h:281
EEOP_OUTER_FETCHSOME
@ EEOP_OUTER_FETCHSOME
Definition: execExpr.h:76
EEOP_AGG_STRICT_INPUT_CHECK_ARGS
@ EEOP_AGG_STRICT_INPUT_CHECK_ARGS
Definition: execExpr.h:280
EEOP_NULLTEST_ROWISNULL
@ EEOP_NULLTEST_ROWISNULL
Definition: execExpr.h:163
EEOP_BOOLTEST_IS_TRUE
@ EEOP_BOOLTEST_IS_TRUE
Definition: execExpr.h:167
EEOP_FUNCEXPR
@ EEOP_FUNCEXPR
Definition: execExpr.h:122
EEOP_NULLTEST_ISNOTNULL
@ EEOP_NULLTEST_ISNOTNULL
Definition: execExpr.h:160
EEOP_ROWCOMPARE_STEP
@ EEOP_ROWCOMPARE_STEP
Definition: execExpr.h:204
EEOP_MERGE_SUPPORT_FUNC
@ EEOP_MERGE_SUPPORT_FUNC
Definition: execExpr.h:274
EEOP_AGG_DESERIALIZE
@ EEOP_AGG_DESERIALIZE
Definition: execExpr.h:279
EEOP_HASHDATUM_FIRST
@ EEOP_HASHDATUM_FIRST
Definition: execExpr.h:256
EEOP_DISTINCT
@ EEOP_DISTINCT
Definition: execExpr.h:189
EEOP_JUMP_IF_NOT_TRUE
@ EEOP_JUMP_IF_NOT_TRUE
Definition: execExpr.h:156
EEOP_FUNCEXPR_FUSAGE
@ EEOP_FUNCEXPR_FUSAGE
Definition: execExpr.h:126
EEOP_AGG_PRESORTED_DISTINCT_SINGLE
@ EEOP_AGG_PRESORTED_DISTINCT_SINGLE
Definition: execExpr.h:290
EEOP_BOOL_AND_STEP_FIRST
@ EEOP_BOOL_AND_STEP_FIRST
Definition: execExpr.h:135
EEOP_JUMP
@ EEOP_JUMP
Definition: execExpr.h:151
EEOP_DONE_NO_RETURN
@ EEOP_DONE_NO_RETURN
Definition: execExpr.h:72
EEOP_DOMAIN_TESTVAL_EXT
@ EEOP_DOMAIN_TESTVAL_EXT
Definition: execExpr.h:246
EEOP_OLD_SYSVAR
@ EEOP_OLD_SYSVAR
Definition: execExpr.h:92
EEOP_BOOL_AND_STEP_LAST
@ EEOP_BOOL_AND_STEP_LAST
Definition: execExpr.h:137
EEOP_NEW_FETCHSOME
@ EEOP_NEW_FETCHSOME
Definition: execExpr.h:79
EEOP_AGG_ORDERED_TRANS_DATUM
@ EEOP_AGG_ORDERED_TRANS_DATUM
Definition: execExpr.h:292
EEOP_OLD_FETCHSOME
@ EEOP_OLD_FETCHSOME
Definition: execExpr.h:78
EEOP_ASSIGN_NEW_VAR
@ EEOP_ASSIGN_NEW_VAR
Definition: execExpr.h:107
EEOP_SBSREF_OLD
@ EEOP_SBSREF_OLD
Definition: execExpr.h:236
EEOP_SQLVALUEFUNCTION
@ EEOP_SQLVALUEFUNCTION
Definition: execExpr.h:192
EEOP_HASHDATUM_SET_INITVAL
@ EEOP_HASHDATUM_SET_INITVAL
Definition: execExpr.h:255
EEOP_JUMP_IF_NOT_NULL
@ EEOP_JUMP_IF_NOT_NULL
Definition: execExpr.h:155
EEOP_AGG_PLAIN_TRANS_STRICT_BYREF
@ EEOP_AGG_PLAIN_TRANS_STRICT_BYREF
Definition: execExpr.h:288
EEOP_FIELDSTORE_DEFORM
@ EEOP_FIELDSTORE_DEFORM
Definition: execExpr.h:219
EEOP_BOOLTEST_IS_FALSE
@ EEOP_BOOLTEST_IS_FALSE
Definition: execExpr.h:169
EEOP_BOOLTEST_IS_NOT_TRUE
@ EEOP_BOOLTEST_IS_NOT_TRUE
Definition: execExpr.h:168
EEOP_AGG_PLAIN_TRANS_INIT_STRICT_BYVAL
@ EEOP_AGG_PLAIN_TRANS_INIT_STRICT_BYVAL
Definition: execExpr.h:284
EEOP_PARAM_EXEC
@ EEOP_PARAM_EXEC
Definition: execExpr.h:173
EEOP_JSON_CONSTRUCTOR
@ EEOP_JSON_CONSTRUCTOR
Definition: execExpr.h:266
EEOP_AGG_PLAIN_TRANS_STRICT_BYVAL
@ EEOP_AGG_PLAIN_TRANS_STRICT_BYVAL
Definition: execExpr.h:285
EEOP_NULLTEST_ISNULL
@ EEOP_NULLTEST_ISNULL
Definition: execExpr.h:159
EEOP_MINMAX
@ EEOP_MINMAX
Definition: execExpr.h:210
EEOP_JUMP_IF_NULL
@ EEOP_JUMP_IF_NULL
Definition: execExpr.h:154
EEOP_ARRAYCOERCE
@ EEOP_ARRAYCOERCE
Definition: execExpr.h:197
EEOP_FIELDSELECT
@ EEOP_FIELDSELECT
Definition: execExpr.h:213
EEOP_CASE_TESTVAL
@ EEOP_CASE_TESTVAL
Definition: execExpr.h:180
EEOP_AGG_PLAIN_TRANS_INIT_STRICT_BYREF
@ EEOP_AGG_PLAIN_TRANS_INIT_STRICT_BYREF
Definition: execExpr.h:287
EEOP_HASHED_SCALARARRAYOP
@ EEOP_HASHED_SCALARARRAYOP
Definition: execExpr.h:264
EEOP_OUTER_VAR
@ EEOP_OUTER_VAR
Definition: execExpr.h:83
EEOP_AGG_ORDERED_TRANS_TUPLE
@ EEOP_AGG_ORDERED_TRANS_TUPLE
Definition: execExpr.h:293
EEOP_SCAN_FETCHSOME
@ EEOP_SCAN_FETCHSOME
Definition: execExpr.h:77
EEOP_IS_JSON
@ EEOP_IS_JSON
Definition: execExpr.h:267
ExecInitJunkFilter
JunkFilter * ExecInitJunkFilter(List *targetList, TupleTableSlot *slot)
Definition: execJunk.c:60
BlessTupleDesc
TupleDesc BlessTupleDesc(TupleDesc tupdesc)
Definition: execTuples.c:2260
TTSOpsVirtual
const TupleTableSlotOps TTSOpsVirtual
Definition: execTuples.c:84
ExecTypeSetColNames
void ExecTypeSetColNames(TupleDesc typeInfo, List *namesList)
Definition: execTuples.c:2219
ExecInitExtraTupleSlot
TupleTableSlot * ExecInitExtraTupleSlot(EState *estate, TupleDesc tupledesc, const TupleTableSlotOps *tts_ops)
Definition: execTuples.c:2020
ExecTypeFromExprList
TupleDesc ExecTypeFromExprList(List *exprList)
Definition: execTuples.c:2186
ExecGetResultType
TupleDesc ExecGetResultType(PlanState *planstate)
Definition: execUtils.c:495
executor_errposition
int executor_errposition(EState *estate, int location)
Definition: execUtils.c:936
ExecGetResultSlotOps
const TupleTableSlotOps * ExecGetResultSlotOps(PlanState *planstate, bool *isfixed)
Definition: execUtils.c:504
EEO_FLAG_HAS_OLD
#define EEO_FLAG_HAS_OLD
Definition: execnodes.h:78
outerPlanState
#define outerPlanState(node)
Definition: execnodes.h:1252
EEO_FLAG_NEW_IS_NULL
#define EEO_FLAG_NEW_IS_NULL
Definition: execnodes.h:84
innerPlanState
#define innerPlanState(node)
Definition: execnodes.h:1251
EEO_FLAG_OLD_IS_NULL
#define EEO_FLAG_OLD_IS_NULL
Definition: execnodes.h:82
DOM_CONSTRAINT_CHECK
@ DOM_CONSTRAINT_CHECK
Definition: execnodes.h:1041
DOM_CONSTRAINT_NOTNULL
@ DOM_CONSTRAINT_NOTNULL
Definition: execnodes.h:1040
EEO_FLAG_IS_QUAL
#define EEO_FLAG_IS_QUAL
Definition: execnodes.h:76
EEO_FLAG_HAS_NEW
#define EEO_FLAG_HAS_NEW
Definition: execnodes.h:80
ExecEvalExprSwitchContext
static Datum ExecEvalExprSwitchContext(ExprState *state, ExprContext *econtext, bool *isNull)
Definition: executor.h:430
fmgr_info
void fmgr_info(Oid functionId, FmgrInfo *finfo)
Definition: fmgr.c:127
SizeForFunctionCallInfo
#define SizeForFunctionCallInfo(nargs)
Definition: fmgr.h:102
InitFunctionCallInfoData
#define InitFunctionCallInfoData(Fcinfo, Flinfo, Nargs, Collation, Context, Resultinfo)
Definition: fmgr.h:150
fmgr_info_set_expr
#define fmgr_info_set_expr(expr, finfo)
Definition: fmgr.h:135
format_type_be
char * format_type_be(Oid type_oid)
Definition: format_type.c:343
Assert
Assert(PointerIsAligned(start, uint64))
i
int i
Definition: isn.c:77
if
if(TABLE==NULL||TABLE_index==NULL)
Definition: isn.c:81
jit_compile_expr
bool jit_compile_expr(struct ExprState *state)
Definition: jit.c:151
json_categorize_type
void json_categorize_type(Oid typoid, bool is_jsonb, JsonTypeCategory *tcategory, Oid *outfuncoid)
Definition: jsonfuncs.c:5999
JsonTypeCategory
JsonTypeCategory
Definition: jsonfuncs.h:69
lappend
List * lappend(List *list, void *datum)
Definition: list.c:339
lappend_int
List * lappend_int(List *list, int datum)
Definition: list.c:357
get_op_opfamily_properties
void get_op_opfamily_properties(Oid opno, Oid opfamily, bool ordering_op, int *strategy, Oid *lefttype, Oid *righttype)
Definition: lsyscache.c:137
get_element_type
Oid get_element_type(Oid typid)
Definition: lsyscache.c:2899
getTypeOutputInfo
void getTypeOutputInfo(Oid type, Oid *typOutput, bool *typIsVarlena)
Definition: lsyscache.c:3047
get_typlenbyvalalign
void get_typlenbyvalalign(Oid typid, int16 *typlen, bool *typbyval, char *typalign)
Definition: lsyscache.c:2411
get_opfamily_proc
Oid get_opfamily_proc(Oid opfamily, Oid lefttype, Oid righttype, int16 procnum)
Definition: lsyscache.c:888
getTypeInputInfo
void getTypeInputInfo(Oid type, Oid *typInput, Oid *typIOParam)
Definition: lsyscache.c:3014
getSubscriptingRoutines
const struct SubscriptRoutines * getSubscriptingRoutines(Oid typid, Oid *typelemp)
Definition: lsyscache.c:3270
get_func_name
char * get_func_name(Oid funcid)
Definition: lsyscache.c:1748
get_typlen
int16 get_typlen(Oid typid)
Definition: lsyscache.c:2337
get_typtype
char get_typtype(Oid typid)
Definition: lsyscache.c:2769
getBaseType
Oid getBaseType(Oid typid)
Definition: lsyscache.c:2661
make_ands_explicit
Expr * make_ands_explicit(List *andclauses)
Definition: makefuncs.c:799
makeNullConst
Const * makeNullConst(Oid consttype, int32 consttypmod, Oid constcollid)
Definition: makefuncs.c:388
repalloc
void * repalloc(void *pointer, Size size)
Definition: mcxt.c:1548
palloc0
void * palloc0(Size size)
Definition: mcxt.c:1351
palloc
void * palloc(Size size)
Definition: mcxt.c:1321
CurrentMemoryContext
MemoryContext CurrentMemoryContext
Definition: mcxt.c:143
GetUserId
Oid GetUserId(void)
Definition: miscinit.c:520
generate_unaccent_rules.args
args
Definition: generate_unaccent_rules.py:288
BTORDER_PROC
#define BTORDER_PROC
Definition: nbtree.h:717
exprType
Oid exprType(const Node *expr)
Definition: nodeFuncs.c:42
exprTypmod
int32 exprTypmod(const Node *expr)
Definition: nodeFuncs.c:301
exprLocation
int exprLocation(const Node *expr)
Definition: nodeFuncs.c:1388
expression_tree_walker
#define expression_tree_walker(n, w, c)
Definition: nodeFuncs.h:153
ExecInitSubPlan
SubPlanState * ExecInitSubPlan(SubPlan *subplan, PlanState *parent)
Definition: nodeSubplan.c:826
IsA
#define IsA(nodeptr, _type_)
Definition: nodes.h:164
nodeTag
#define nodeTag(nodeptr)
Definition: nodes.h:139
DO_AGGSPLIT_COMBINE
#define DO_AGGSPLIT_COMBINE(as)
Definition: nodes.h:391
CMD_MERGE
@ CMD_MERGE
Definition: nodes.h:275
AGG_HASHED
@ AGG_HASHED
Definition: nodes.h:362
makeNode
#define makeNode(_type_)
Definition: nodes.h:161
castNode
#define castNode(_type_, nodeptr)
Definition: nodes.h:182
InvokeFunctionExecuteHook
#define InvokeFunctionExecuteHook(objectId)
Definition: objectaccess.h:213
MemoryContextSwitchTo
static MemoryContext MemoryContextSwitchTo(MemoryContext context)
Definition: palloc.h:124
OBJECT_FUNCTION
@ OBJECT_FUNCTION
Definition: parsenodes.h:2336
ACL_EXECUTE
#define ACL_EXECUTE
Definition: parsenodes.h:83
attnum
int16 attnum
Definition: pg_attribute.h:74
Form_pg_attribute
FormData_pg_attribute * Form_pg_attribute
Definition: pg_attribute.h:202
arg
void * arg
Definition: pg_backup_utils.c:29
FUNC_MAX_ARGS
#define FUNC_MAX_ARGS
Definition: pg_config_manual.h:43
lfirst
#define lfirst(lc)
Definition: pg_list.h:172
lfirst_node
#define lfirst_node(type, lc)
Definition: pg_list.h:176
list_length
static int list_length(const List *l)
Definition: pg_list.h:152
NIL
#define NIL
Definition: pg_list.h:68
forboth
#define forboth(cell1, list1, cell2, list2)
Definition: pg_list.h:518
foreach_current_index
#define foreach_current_index(var_or_cell)
Definition: pg_list.h:403
lfirst_int
#define lfirst_int(lc)
Definition: pg_list.h:173
foreach_ptr
#define foreach_ptr(type, var, lst)
Definition: pg_list.h:469
linitial
#define linitial(l)
Definition: pg_list.h:178
lsecond
#define lsecond(l)
Definition: pg_list.h:183
forfive
#define forfive(cell1, list1, cell2, list2, cell3, list3, cell4, list4, cell5, list5)
Definition: pg_list.h:588
lfirst_oid
#define lfirst_oid(lc)
Definition: pg_list.h:174
foreach_int
#define foreach_int(var, lst)
Definition: pg_list.h:470
pg_proc.h
bail
#define bail(...)
Definition: pg_regress.c:167
pg_type.h
expression_planner
Expr * expression_planner(Expr *expr)
Definition: planner.c:6691
DatumGetBool
static bool DatumGetBool(Datum X)
Definition: postgres.h:95
PointerGetDatum
static Datum PointerGetDatum(const void *X)
Definition: postgres.h:327
Datum
uintptr_t Datum
Definition: postgres.h:69
ObjectIdGetDatum
static Datum ObjectIdGetDatum(Oid X)
Definition: postgres.h:257
Int32GetDatum
static Datum Int32GetDatum(int32 X)
Definition: postgres.h:217
UInt32GetDatum
static Datum UInt32GetDatum(uint32 X)
Definition: postgres.h:237
InvalidOid
#define InvalidOid
Definition: postgres_ext.h:35
Oid
unsigned int Oid
Definition: postgres_ext.h:30
e
e
Definition: preproc-init.c:82
IS_NOT_TRUE
@ IS_NOT_TRUE
Definition: primnodes.h:1981
IS_NOT_FALSE
@ IS_NOT_FALSE
Definition: primnodes.h:1981
IS_NOT_UNKNOWN
@ IS_NOT_UNKNOWN
Definition: primnodes.h:1981
IS_TRUE
@ IS_TRUE
Definition: primnodes.h:1981
IS_UNKNOWN
@ IS_UNKNOWN
Definition: primnodes.h:1981
IS_FALSE
@ IS_FALSE
Definition: primnodes.h:1981
MULTIEXPR_SUBLINK
@ MULTIEXPR_SUBLINK
Definition: primnodes.h:1019
JS_FORMAT_JSONB
@ JS_FORMAT_JSONB
Definition: primnodes.h:1645
AND_EXPR
@ AND_EXPR
Definition: primnodes.h:948
OR_EXPR
@ OR_EXPR
Definition: primnodes.h:948
NOT_EXPR
@ NOT_EXPR
Definition: primnodes.h:948
PARAM_EXTERN
@ PARAM_EXTERN
Definition: primnodes.h:384
PARAM_EXEC
@ PARAM_EXEC
Definition: primnodes.h:385
VAR_RETURNING_OLD
@ VAR_RETURNING_OLD
Definition: primnodes.h:257
VAR_RETURNING_NEW
@ VAR_RETURNING_NEW
Definition: primnodes.h:258
VAR_RETURNING_DEFAULT
@ VAR_RETURNING_DEFAULT
Definition: primnodes.h:256
JSON_BEHAVIOR_ERROR
@ JSON_BEHAVIOR_ERROR
Definition: primnodes.h:1771
JSON_TABLE_OP
@ JSON_TABLE_OP
Definition: primnodes.h:1810
JSON_EXISTS_OP
@ JSON_EXISTS_OP
Definition: primnodes.h:1807
IS_NULL
@ IS_NULL
Definition: primnodes.h:1957
IS_NOT_NULL
@ IS_NOT_NULL
Definition: primnodes.h:1957
OUTER_VAR
#define OUTER_VAR
Definition: primnodes.h:243
JSCTOR_JSON_SERIALIZE
@ JSCTOR_JSON_SERIALIZE
Definition: primnodes.h:1701
JSCTOR_JSON_PARSE
@ JSCTOR_JSON_PARSE
Definition: primnodes.h:1699
JSCTOR_JSON_SCALAR
@ JSCTOR_JSON_SCALAR
Definition: primnodes.h:1700
INNER_VAR
#define INNER_VAR
Definition: primnodes.h:242
check_stack_depth
void check_stack_depth(void)
Definition: stack_depth.c:95
AggStatePerTransData::sortslot
TupleTableSlot * sortslot
Definition: nodeAgg.h:141
AggStatePerTransData::aggref
Aggref * aggref
Definition: nodeAgg.h:44
AggStatePerTransData::deserialfn
FmgrInfo deserialfn
Definition: nodeAgg.h:92
AggStatePerTransData::deserialfn_fcinfo
FunctionCallInfo deserialfn_fcinfo
Definition: nodeAgg.h:175
AggStatePerTransData::transfn_fcinfo
FunctionCallInfo transfn_fcinfo
Definition: nodeAgg.h:170
AggState::ss
ScanState ss
Definition: execnodes.h:2524
AggState::aggs
List * aggs
Definition: execnodes.h:2525
AggState::pertrans
AggStatePerTrans pertrans
Definition: execnodes.h:2534
AggState::aggstrategy
AggStrategy aggstrategy
Definition: execnodes.h:2528
AggState::numtrans
int numtrans
Definition: execnodes.h:2527
AggState::hashcontext
ExprContext * hashcontext
Definition: execnodes.h:2535
AggState::aggsplit
AggSplit aggsplit
Definition: execnodes.h:2529
AggState::num_hashes
int num_hashes
Definition: execnodes.h:2565
AggState::maxsets
int maxsets
Definition: execnodes.h:2554
AggState::aggcontexts
ExprContext ** aggcontexts
Definition: execnodes.h:2536
Agg::groupingSets
List * groupingSets
Definition: plannodes.h:1163
Aggref::aggdistinct
List * aggdistinct
Definition: primnodes.h:491
Aggref::aggdirectargs
List * aggdirectargs
Definition: primnodes.h:482
Aggref::args
List * args
Definition: primnodes.h:485
Aggref::aggfilter
Expr * aggfilter
Definition: primnodes.h:494
Aggref::aggorder
List * aggorder
Definition: primnodes.h:488
BoolExpr::boolop
BoolExprType boolop
Definition: primnodes.h:956
BoolExpr::args
List * args
Definition: primnodes.h:957
BooleanTest::booltesttype
BoolTestType booltesttype
Definition: primnodes.h:1988
BooleanTest::arg
Expr * arg
Definition: primnodes.h:1987
CaseExpr::arg
Expr * arg
Definition: primnodes.h:1330
CaseExpr::defresult
Expr * defresult
Definition: primnodes.h:1332
CaseExpr::args
List * args
Definition: primnodes.h:1331
CoalesceExpr::args
List * args
Definition: primnodes.h:1497
CoerceViaIO::arg
Expr * arg
Definition: primnodes.h:1224
CoerceViaIO::resulttype
Oid resulttype
Definition: primnodes.h:1225
CompactAttribute::attisdropped
bool attisdropped
Definition: tupdesc.h:77
DomainConstraintState::constrainttype
DomainConstraintType constrainttype
Definition: execnodes.h:1047
EState::es_query_cxt
MemoryContext es_query_cxt
Definition: execnodes.h:706
ErrorSaveContext::type
NodeTag type
Definition: miscnodes.h:46
ExprEvalStep::xexpr
XmlExpr * xexpr
Definition: execExpr.h:653
ExprEvalStep::pred
JsonIsPredicate * pred
Definition: execExpr.h:750
ExprEvalStep::nullflag
uint8 nullflag
Definition: execExpr.h:373
ExprEvalStep::anynull
bool * anynull
Definition: execExpr.h:399
ExprEvalStep::elemexprstate
ExprState * elemexprstate
Definition: execExpr.h:493
ExprEvalStep::op
MinMaxOp op
Definition: execExpr.h:534
ExprEvalStep::elemalign
char elemalign
Definition: execExpr.h:486
ExprEvalStep::grouping_func
struct ExprEvalStep::@55::@94 grouping_func
ExprEvalStep::jump
struct ExprEvalStep::@55::@66 jump
ExprEvalStep::clauses
List * clauses
Definition: execExpr.h:677
ExprEvalStep::wfstate
WindowFuncExprState * wfstate
Definition: execExpr.h:684
ExprEvalStep::json_coercion_cache
void * json_coercion_cache
Definition: execExpr.h:769
ExprEvalStep::subscriptfunc
ExecEvalBoolSubroutine subscriptfunc
Definition: execExpr.h:568
ExprEvalStep::exists_coerce
bool exists_coerce
Definition: execExpr.h:766
ExprEvalStep::tupdesc
TupleDesc tupdesc
Definition: execExpr.h:350
ExprEvalStep::seqtypid
Oid seqtypid
Definition: execExpr.h:474
ExprEvalStep::last_var
int last_var
Definition: execExpr.h:325
ExprEvalStep::junkFilter
JunkFilter * junkFilter
Definition: execExpr.h:351
ExprEvalStep::fieldselect
struct ExprEvalStep::@55::@81 fieldselect
ExprEvalStep::finfo_out
FmgrInfo * finfo_out
Definition: execExpr.h:457
ExprEvalStep::fieldnum
AttrNumber fieldnum
Definition: execExpr.h:543
ExprEvalStep::hashedscalararrayop
struct ExprEvalStep::@55::@90 hashedscalararrayop
ExprEvalStep::json_constructor
struct ExprEvalStep::@55::@92 json_constructor
ExprEvalStep::values
Datum * values
Definition: execExpr.h:530
ExprEvalStep::elemnulls
bool * elemnulls
Definition: execExpr.h:481
ExprEvalStep::assign_tmp
struct ExprEvalStep::@55::@60 assign_tmp
ExprEvalStep::make_readonly
struct ExprEvalStep::@55::@71 make_readonly
ExprEvalStep::checknull
bool * checknull
Definition: execExpr.h:589
ExprEvalStep::ncolumns
int ncolumns
Definition: execExpr.h:562
ExprEvalStep::named_argnull
bool * named_argnull
Definition: execExpr.h:656
ExprEvalStep::var
struct ExprEvalStep::@55::@57 var
ExprEvalStep::outputtype
Oid outputtype
Definition: execExpr.h:617
ExprEvalStep::fieldstore
struct ExprEvalStep::@55::@82 fieldstore
ExprEvalStep::domaincheck
struct ExprEvalStep::@55::@85 domaincheck
ExprEvalStep::is_json
struct ExprEvalStep::@55::@102 is_json
ExprEvalStep::inclause
bool inclause
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