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funcapi.c
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1 /*-------------------------------------------------------------------------
2  *
3  * funcapi.c
4  * Utility and convenience functions for fmgr functions that return
5  * sets and/or composite types, or deal with VARIADIC inputs.
6  *
7  * Copyright (c) 2002-2024, PostgreSQL Global Development Group
8  *
9  * IDENTIFICATION
10  * src/backend/utils/fmgr/funcapi.c
11  *
12  *-------------------------------------------------------------------------
13  */
14 #include "postgres.h"
15 
16 #include "access/htup_details.h"
17 #include "access/relation.h"
18 #include "catalog/namespace.h"
19 #include "catalog/pg_proc.h"
20 #include "catalog/pg_type.h"
21 #include "funcapi.h"
22 #include "miscadmin.h"
23 #include "nodes/nodeFuncs.h"
24 #include "utils/array.h"
25 #include "utils/builtins.h"
26 #include "utils/lsyscache.h"
27 #include "utils/memutils.h"
28 #include "utils/regproc.h"
29 #include "utils/rel.h"
30 #include "utils/syscache.h"
31 #include "utils/tuplestore.h"
32 #include "utils/typcache.h"
33 
34 
35 typedef struct polymorphic_actuals
36 {
37  Oid anyelement_type; /* anyelement mapping, if known */
38  Oid anyarray_type; /* anyarray mapping, if known */
39  Oid anyrange_type; /* anyrange mapping, if known */
40  Oid anymultirange_type; /* anymultirange mapping, if known */
42 
43 static void shutdown_MultiFuncCall(Datum arg);
45  Node *call_expr,
46  ReturnSetInfo *rsinfo,
47  Oid *resultTypeId,
48  TupleDesc *resultTupleDesc);
53 static bool resolve_polymorphic_tupdesc(TupleDesc tupdesc,
54  oidvector *declared_args,
55  Node *call_expr);
56 static TypeFuncClass get_type_func_class(Oid typid, Oid *base_typeid);
57 
58 
59 /*
60  * InitMaterializedSRF
61  *
62  * Helper function to build the state of a set-returning function used
63  * in the context of a single call with materialize mode. This code
64  * includes sanity checks on ReturnSetInfo, creates the Tuplestore and
65  * the TupleDesc used with the function and stores them into the
66  * function's ReturnSetInfo.
67  *
68  * "flags" can be set to MAT_SRF_USE_EXPECTED_DESC, to use the tuple
69  * descriptor coming from expectedDesc, which is the tuple descriptor
70  * expected by the caller. MAT_SRF_BLESS can be set to complete the
71  * information associated to the tuple descriptor, which is necessary
72  * in some cases where the tuple descriptor comes from a transient
73  * RECORD datatype.
74  */
75 void
77 {
78  bool random_access;
79  ReturnSetInfo *rsinfo = (ReturnSetInfo *) fcinfo->resultinfo;
80  Tuplestorestate *tupstore;
81  MemoryContext old_context,
82  per_query_ctx;
83  TupleDesc stored_tupdesc;
84 
85  /* check to see if caller supports returning a tuplestore */
86  if (rsinfo == NULL || !IsA(rsinfo, ReturnSetInfo))
87  ereport(ERROR,
88  (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
89  errmsg("set-valued function called in context that cannot accept a set")));
90  if (!(rsinfo->allowedModes & SFRM_Materialize) ||
91  ((flags & MAT_SRF_USE_EXPECTED_DESC) != 0 && rsinfo->expectedDesc == NULL))
92  ereport(ERROR,
93  (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
94  errmsg("materialize mode required, but it is not allowed in this context")));
95 
96  /*
97  * Store the tuplestore and the tuple descriptor in ReturnSetInfo. This
98  * must be done in the per-query memory context.
99  */
100  per_query_ctx = rsinfo->econtext->ecxt_per_query_memory;
101  old_context = MemoryContextSwitchTo(per_query_ctx);
102 
103  /* build a tuple descriptor for our result type */
104  if ((flags & MAT_SRF_USE_EXPECTED_DESC) != 0)
105  stored_tupdesc = CreateTupleDescCopy(rsinfo->expectedDesc);
106  else
107  {
108  if (get_call_result_type(fcinfo, NULL, &stored_tupdesc) != TYPEFUNC_COMPOSITE)
109  elog(ERROR, "return type must be a row type");
110  }
111 
112  /* If requested, bless the tuple descriptor */
113  if ((flags & MAT_SRF_BLESS) != 0)
114  BlessTupleDesc(stored_tupdesc);
115 
116  random_access = (rsinfo->allowedModes & SFRM_Materialize_Random) != 0;
117 
118  tupstore = tuplestore_begin_heap(random_access, false, work_mem);
119  rsinfo->returnMode = SFRM_Materialize;
120  rsinfo->setResult = tupstore;
121  rsinfo->setDesc = stored_tupdesc;
122  MemoryContextSwitchTo(old_context);
123 }
124 
125 
126 /*
127  * init_MultiFuncCall
128  * Create an empty FuncCallContext data structure
129  * and do some other basic Multi-function call setup
130  * and error checking
131  */
134 {
135  FuncCallContext *retval;
136 
137  /*
138  * Bail if we're called in the wrong context
139  */
140  if (fcinfo->resultinfo == NULL || !IsA(fcinfo->resultinfo, ReturnSetInfo))
141  ereport(ERROR,
142  (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
143  errmsg("set-valued function called in context that cannot accept a set")));
144 
145  if (fcinfo->flinfo->fn_extra == NULL)
146  {
147  /*
148  * First call
149  */
150  ReturnSetInfo *rsi = (ReturnSetInfo *) fcinfo->resultinfo;
151  MemoryContext multi_call_ctx;
152 
153  /*
154  * Create a suitably long-lived context to hold cross-call data
155  */
156  multi_call_ctx = AllocSetContextCreate(fcinfo->flinfo->fn_mcxt,
157  "SRF multi-call context",
159 
160  /*
161  * Allocate suitably long-lived space and zero it
162  */
163  retval = (FuncCallContext *)
164  MemoryContextAllocZero(multi_call_ctx,
165  sizeof(FuncCallContext));
166 
167  /*
168  * initialize the elements
169  */
170  retval->call_cntr = 0;
171  retval->max_calls = 0;
172  retval->user_fctx = NULL;
173  retval->attinmeta = NULL;
174  retval->tuple_desc = NULL;
175  retval->multi_call_memory_ctx = multi_call_ctx;
176 
177  /*
178  * save the pointer for cross-call use
179  */
180  fcinfo->flinfo->fn_extra = retval;
181 
182  /*
183  * Ensure we will get shut down cleanly if the exprcontext is not run
184  * to completion.
185  */
188  PointerGetDatum(fcinfo->flinfo));
189  }
190  else
191  {
192  /* second and subsequent calls */
193  elog(ERROR, "init_MultiFuncCall cannot be called more than once");
194 
195  /* never reached, but keep compiler happy */
196  retval = NULL;
197  }
198 
199  return retval;
200 }
201 
202 /*
203  * per_MultiFuncCall
204  *
205  * Do Multi-function per-call setup
206  */
209 {
210  FuncCallContext *retval = (FuncCallContext *) fcinfo->flinfo->fn_extra;
211 
212  return retval;
213 }
214 
215 /*
216  * end_MultiFuncCall
217  * Clean up after init_MultiFuncCall
218  */
219 void
221 {
222  ReturnSetInfo *rsi = (ReturnSetInfo *) fcinfo->resultinfo;
223 
224  /* Deregister the shutdown callback */
227  PointerGetDatum(fcinfo->flinfo));
228 
229  /* But use it to do the real work */
230  shutdown_MultiFuncCall(PointerGetDatum(fcinfo->flinfo));
231 }
232 
233 /*
234  * shutdown_MultiFuncCall
235  * Shutdown function to clean up after init_MultiFuncCall
236  */
237 static void
239 {
240  FmgrInfo *flinfo = (FmgrInfo *) DatumGetPointer(arg);
241  FuncCallContext *funcctx = (FuncCallContext *) flinfo->fn_extra;
242 
243  /* unbind from flinfo */
244  flinfo->fn_extra = NULL;
245 
246  /*
247  * Delete context that holds all multi-call data, including the
248  * FuncCallContext itself
249  */
251 }
252 
253 
254 /*
255  * get_call_result_type
256  * Given a function's call info record, determine the kind of datatype
257  * it is supposed to return. If resultTypeId isn't NULL, *resultTypeId
258  * receives the actual datatype OID (this is mainly useful for scalar
259  * result types). If resultTupleDesc isn't NULL, *resultTupleDesc
260  * receives a pointer to a TupleDesc when the result is of a composite
261  * type, or NULL when it's a scalar result.
262  *
263  * One hard case that this handles is resolution of actual rowtypes for
264  * functions returning RECORD (from either the function's OUT parameter
265  * list, or a ReturnSetInfo context node). TYPEFUNC_RECORD is returned
266  * only when we couldn't resolve the actual rowtype for lack of information.
267  *
268  * The other hard case that this handles is resolution of polymorphism.
269  * We will never return polymorphic pseudotypes (ANYELEMENT etc), either
270  * as a scalar result type or as a component of a rowtype.
271  *
272  * This function is relatively expensive --- in a function returning set,
273  * try to call it only the first time through.
274  */
277  Oid *resultTypeId,
278  TupleDesc *resultTupleDesc)
279 {
280  return internal_get_result_type(fcinfo->flinfo->fn_oid,
281  fcinfo->flinfo->fn_expr,
282  (ReturnSetInfo *) fcinfo->resultinfo,
283  resultTypeId,
284  resultTupleDesc);
285 }
286 
287 /*
288  * get_expr_result_type
289  * As above, but work from a calling expression node tree
290  *
291  * Beware of using this on the funcexpr of a RTE that has a coldeflist.
292  * The correct conclusion in such cases is always that the function returns
293  * RECORD with the columns defined by the coldeflist fields (funccolnames etc).
294  * If it does not, it's the executor's responsibility to catch the discrepancy
295  * at runtime; but code processing the query in advance of that point might
296  * come to inconsistent conclusions if it checks the actual expression.
297  */
300  Oid *resultTypeId,
301  TupleDesc *resultTupleDesc)
302 {
303  TypeFuncClass result;
304 
305  if (expr && IsA(expr, FuncExpr))
306  result = internal_get_result_type(((FuncExpr *) expr)->funcid,
307  expr,
308  NULL,
309  resultTypeId,
310  resultTupleDesc);
311  else if (expr && IsA(expr, OpExpr))
312  result = internal_get_result_type(get_opcode(((OpExpr *) expr)->opno),
313  expr,
314  NULL,
315  resultTypeId,
316  resultTupleDesc);
317  else if (expr && IsA(expr, RowExpr) &&
318  ((RowExpr *) expr)->row_typeid == RECORDOID)
319  {
320  /* We can resolve the record type by generating the tupdesc directly */
321  RowExpr *rexpr = (RowExpr *) expr;
322  TupleDesc tupdesc;
323  AttrNumber i = 1;
324  ListCell *lcc,
325  *lcn;
326 
327  tupdesc = CreateTemplateTupleDesc(list_length(rexpr->args));
328  Assert(list_length(rexpr->args) == list_length(rexpr->colnames));
329  forboth(lcc, rexpr->args, lcn, rexpr->colnames)
330  {
331  Node *col = (Node *) lfirst(lcc);
332  char *colname = strVal(lfirst(lcn));
333 
334  TupleDescInitEntry(tupdesc, i,
335  colname,
336  exprType(col),
337  exprTypmod(col),
338  0);
340  exprCollation(col));
341  i++;
342  }
343  if (resultTypeId)
344  *resultTypeId = rexpr->row_typeid;
345  if (resultTupleDesc)
346  *resultTupleDesc = BlessTupleDesc(tupdesc);
347  return TYPEFUNC_COMPOSITE;
348  }
349  else if (expr && IsA(expr, Const) &&
350  ((Const *) expr)->consttype == RECORDOID &&
351  !((Const *) expr)->constisnull)
352  {
353  /*
354  * When EXPLAIN'ing some queries with SEARCH/CYCLE clauses, we may
355  * need to resolve field names of a RECORD-type Const. The datum
356  * should contain a typmod that will tell us that.
357  */
358  HeapTupleHeader rec;
359  Oid tupType;
360  int32 tupTypmod;
361 
362  rec = DatumGetHeapTupleHeader(((Const *) expr)->constvalue);
363  tupType = HeapTupleHeaderGetTypeId(rec);
364  tupTypmod = HeapTupleHeaderGetTypMod(rec);
365  if (resultTypeId)
366  *resultTypeId = tupType;
367  if (tupType != RECORDOID || tupTypmod >= 0)
368  {
369  /* Should be able to look it up */
370  if (resultTupleDesc)
371  *resultTupleDesc = lookup_rowtype_tupdesc_copy(tupType,
372  tupTypmod);
373  return TYPEFUNC_COMPOSITE;
374  }
375  else
376  {
377  /* This shouldn't really happen ... */
378  if (resultTupleDesc)
379  *resultTupleDesc = NULL;
380  return TYPEFUNC_RECORD;
381  }
382  }
383  else
384  {
385  /* handle as a generic expression; no chance to resolve RECORD */
386  Oid typid = exprType(expr);
387  Oid base_typid;
388 
389  if (resultTypeId)
390  *resultTypeId = typid;
391  if (resultTupleDesc)
392  *resultTupleDesc = NULL;
393  result = get_type_func_class(typid, &base_typid);
394  if ((result == TYPEFUNC_COMPOSITE ||
395  result == TYPEFUNC_COMPOSITE_DOMAIN) &&
396  resultTupleDesc)
397  *resultTupleDesc = lookup_rowtype_tupdesc_copy(base_typid, -1);
398  }
399 
400  return result;
401 }
402 
403 /*
404  * get_func_result_type
405  * As above, but work from a function's OID only
406  *
407  * This will not be able to resolve pure-RECORD results nor polymorphism.
408  */
411  Oid *resultTypeId,
412  TupleDesc *resultTupleDesc)
413 {
414  return internal_get_result_type(functionId,
415  NULL,
416  NULL,
417  resultTypeId,
418  resultTupleDesc);
419 }
420 
421 /*
422  * internal_get_result_type -- workhorse code implementing all the above
423  *
424  * funcid must always be supplied. call_expr and rsinfo can be NULL if not
425  * available. We will return TYPEFUNC_RECORD, and store NULL into
426  * *resultTupleDesc, if we cannot deduce the complete result rowtype from
427  * the available information.
428  */
429 static TypeFuncClass
431  Node *call_expr,
432  ReturnSetInfo *rsinfo,
433  Oid *resultTypeId,
434  TupleDesc *resultTupleDesc)
435 {
436  TypeFuncClass result;
437  HeapTuple tp;
438  Form_pg_proc procform;
439  Oid rettype;
440  Oid base_rettype;
441  TupleDesc tupdesc;
442 
443  /* First fetch the function's pg_proc row to inspect its rettype */
444  tp = SearchSysCache1(PROCOID, ObjectIdGetDatum(funcid));
445  if (!HeapTupleIsValid(tp))
446  elog(ERROR, "cache lookup failed for function %u", funcid);
447  procform = (Form_pg_proc) GETSTRUCT(tp);
448 
449  rettype = procform->prorettype;
450 
451  /* Check for OUT parameters defining a RECORD result */
452  tupdesc = build_function_result_tupdesc_t(tp);
453  if (tupdesc)
454  {
455  /*
456  * It has OUT parameters, so it's basically like a regular composite
457  * type, except we have to be able to resolve any polymorphic OUT
458  * parameters.
459  */
460  if (resultTypeId)
461  *resultTypeId = rettype;
462 
463  if (resolve_polymorphic_tupdesc(tupdesc,
464  &procform->proargtypes,
465  call_expr))
466  {
467  if (tupdesc->tdtypeid == RECORDOID &&
468  tupdesc->tdtypmod < 0)
469  assign_record_type_typmod(tupdesc);
470  if (resultTupleDesc)
471  *resultTupleDesc = tupdesc;
472  result = TYPEFUNC_COMPOSITE;
473  }
474  else
475  {
476  if (resultTupleDesc)
477  *resultTupleDesc = NULL;
478  result = TYPEFUNC_RECORD;
479  }
480 
481  ReleaseSysCache(tp);
482 
483  return result;
484  }
485 
486  /*
487  * If scalar polymorphic result, try to resolve it.
488  */
489  if (IsPolymorphicType(rettype))
490  {
491  Oid newrettype = exprType(call_expr);
492 
493  if (newrettype == InvalidOid) /* this probably should not happen */
494  ereport(ERROR,
495  (errcode(ERRCODE_DATATYPE_MISMATCH),
496  errmsg("could not determine actual result type for function \"%s\" declared to return type %s",
497  NameStr(procform->proname),
498  format_type_be(rettype))));
499  rettype = newrettype;
500  }
501 
502  if (resultTypeId)
503  *resultTypeId = rettype;
504  if (resultTupleDesc)
505  *resultTupleDesc = NULL; /* default result */
506 
507  /* Classify the result type */
508  result = get_type_func_class(rettype, &base_rettype);
509  switch (result)
510  {
511  case TYPEFUNC_COMPOSITE:
513  if (resultTupleDesc)
514  *resultTupleDesc = lookup_rowtype_tupdesc_copy(base_rettype, -1);
515  /* Named composite types can't have any polymorphic columns */
516  break;
517  case TYPEFUNC_SCALAR:
518  break;
519  case TYPEFUNC_RECORD:
520  /* We must get the tupledesc from call context */
521  if (rsinfo && IsA(rsinfo, ReturnSetInfo) &&
522  rsinfo->expectedDesc != NULL)
523  {
524  result = TYPEFUNC_COMPOSITE;
525  if (resultTupleDesc)
526  *resultTupleDesc = rsinfo->expectedDesc;
527  /* Assume no polymorphic columns here, either */
528  }
529  break;
530  default:
531  break;
532  }
533 
534  ReleaseSysCache(tp);
535 
536  return result;
537 }
538 
539 /*
540  * get_expr_result_tupdesc
541  * Get a tupdesc describing the result of a composite-valued expression
542  *
543  * If expression is not composite or rowtype can't be determined, returns NULL
544  * if noError is true, else throws error.
545  *
546  * This is a simpler version of get_expr_result_type() for use when the caller
547  * is only interested in determinate rowtype results. As with that function,
548  * beware of using this on the funcexpr of a RTE that has a coldeflist.
549  */
550 TupleDesc
551 get_expr_result_tupdesc(Node *expr, bool noError)
552 {
553  TupleDesc tupleDesc;
554  TypeFuncClass functypclass;
555 
556  functypclass = get_expr_result_type(expr, NULL, &tupleDesc);
557 
558  if (functypclass == TYPEFUNC_COMPOSITE ||
559  functypclass == TYPEFUNC_COMPOSITE_DOMAIN)
560  return tupleDesc;
561 
562  if (!noError)
563  {
564  Oid exprTypeId = exprType(expr);
565 
566  if (exprTypeId != RECORDOID)
567  ereport(ERROR,
568  (errcode(ERRCODE_WRONG_OBJECT_TYPE),
569  errmsg("type %s is not composite",
570  format_type_be(exprTypeId))));
571  else
572  ereport(ERROR,
573  (errcode(ERRCODE_WRONG_OBJECT_TYPE),
574  errmsg("record type has not been registered")));
575  }
576 
577  return NULL;
578 }
579 
580 /*
581  * Resolve actual type of ANYELEMENT from other polymorphic inputs
582  *
583  * Note: the error cases here and in the sibling functions below are not
584  * really user-facing; they could only occur if the function signature is
585  * incorrect or the parser failed to enforce consistency of the actual
586  * argument types. Hence, we don't sweat too much over the error messages.
587  */
588 static void
590 {
591  if (OidIsValid(actuals->anyarray_type))
592  {
593  /* Use the element type corresponding to actual type */
594  Oid array_base_type = getBaseType(actuals->anyarray_type);
595  Oid array_typelem = get_element_type(array_base_type);
596 
597  if (!OidIsValid(array_typelem))
598  ereport(ERROR,
599  (errcode(ERRCODE_DATATYPE_MISMATCH),
600  errmsg("argument declared %s is not an array but type %s",
601  "anyarray",
602  format_type_be(array_base_type))));
603  actuals->anyelement_type = array_typelem;
604  }
605  else if (OidIsValid(actuals->anyrange_type))
606  {
607  /* Use the element type corresponding to actual type */
608  Oid range_base_type = getBaseType(actuals->anyrange_type);
609  Oid range_typelem = get_range_subtype(range_base_type);
610 
611  if (!OidIsValid(range_typelem))
612  ereport(ERROR,
613  (errcode(ERRCODE_DATATYPE_MISMATCH),
614  errmsg("argument declared %s is not a range type but type %s",
615  "anyrange",
616  format_type_be(range_base_type))));
617  actuals->anyelement_type = range_typelem;
618  }
619  else if (OidIsValid(actuals->anymultirange_type))
620  {
621  /* Use the element type based on the multirange type */
622  Oid multirange_base_type;
623  Oid multirange_typelem;
624  Oid range_base_type;
625  Oid range_typelem;
626 
627  multirange_base_type = getBaseType(actuals->anymultirange_type);
628  multirange_typelem = get_multirange_range(multirange_base_type);
629  if (!OidIsValid(multirange_typelem))
630  ereport(ERROR,
631  (errcode(ERRCODE_DATATYPE_MISMATCH),
632  errmsg("argument declared %s is not a multirange type but type %s",
633  "anymultirange",
634  format_type_be(multirange_base_type))));
635 
636  range_base_type = getBaseType(multirange_typelem);
637  range_typelem = get_range_subtype(range_base_type);
638 
639  if (!OidIsValid(range_typelem))
640  ereport(ERROR,
641  (errcode(ERRCODE_DATATYPE_MISMATCH),
642  errmsg("argument declared %s does not contain a range type but type %s",
643  "anymultirange",
644  format_type_be(range_base_type))));
645  actuals->anyelement_type = range_typelem;
646  }
647  else
648  elog(ERROR, "could not determine polymorphic type");
649 }
650 
651 /*
652  * Resolve actual type of ANYARRAY from other polymorphic inputs
653  */
654 static void
656 {
657  /* If we don't know ANYELEMENT, resolve that first */
658  if (!OidIsValid(actuals->anyelement_type))
660 
661  if (OidIsValid(actuals->anyelement_type))
662  {
663  /* Use the array type corresponding to actual type */
664  Oid array_typeid = get_array_type(actuals->anyelement_type);
665 
666  if (!OidIsValid(array_typeid))
667  ereport(ERROR,
668  (errcode(ERRCODE_UNDEFINED_OBJECT),
669  errmsg("could not find array type for data type %s",
670  format_type_be(actuals->anyelement_type))));
671  actuals->anyarray_type = array_typeid;
672  }
673  else
674  elog(ERROR, "could not determine polymorphic type");
675 }
676 
677 /*
678  * Resolve actual type of ANYRANGE from other polymorphic inputs
679  */
680 static void
682 {
683  /*
684  * We can't deduce a range type from other polymorphic array or base
685  * types, because there may be multiple range types with the same subtype,
686  * but we can deduce it from a polymorphic multirange type.
687  */
688  if (OidIsValid(actuals->anymultirange_type))
689  {
690  /* Use the element type based on the multirange type */
691  Oid multirange_base_type = getBaseType(actuals->anymultirange_type);
692  Oid multirange_typelem = get_multirange_range(multirange_base_type);
693 
694  if (!OidIsValid(multirange_typelem))
695  ereport(ERROR,
696  (errcode(ERRCODE_DATATYPE_MISMATCH),
697  errmsg("argument declared %s is not a multirange type but type %s",
698  "anymultirange",
699  format_type_be(multirange_base_type))));
700  actuals->anyrange_type = multirange_typelem;
701  }
702  else
703  elog(ERROR, "could not determine polymorphic type");
704 }
705 
706 /*
707  * Resolve actual type of ANYMULTIRANGE from other polymorphic inputs
708  */
709 static void
711 {
712  /*
713  * We can't deduce a multirange type from polymorphic array or base types,
714  * because there may be multiple range types with the same subtype, but we
715  * can deduce it from a polymorphic range type.
716  */
717  if (OidIsValid(actuals->anyrange_type))
718  {
719  Oid range_base_type = getBaseType(actuals->anyrange_type);
720  Oid multirange_typeid = get_range_multirange(range_base_type);
721 
722  if (!OidIsValid(multirange_typeid))
723  ereport(ERROR,
724  (errcode(ERRCODE_UNDEFINED_OBJECT),
725  errmsg("could not find multirange type for data type %s",
726  format_type_be(actuals->anyrange_type))));
727  actuals->anymultirange_type = multirange_typeid;
728  }
729  else
730  elog(ERROR, "could not determine polymorphic type");
731 }
732 
733 /*
734  * Given the result tuple descriptor for a function with OUT parameters,
735  * replace any polymorphic column types (ANYELEMENT etc) in the tupdesc
736  * with concrete data types deduced from the input arguments.
737  * declared_args is an oidvector of the function's declared input arg types
738  * (showing which are polymorphic), and call_expr is the call expression.
739  *
740  * Returns true if able to deduce all types, false if necessary information
741  * is not provided (call_expr is NULL or arg types aren't identifiable).
742  */
743 static bool
745  Node *call_expr)
746 {
747  int natts = tupdesc->natts;
748  int nargs = declared_args->dim1;
749  bool have_polymorphic_result = false;
750  bool have_anyelement_result = false;
751  bool have_anyarray_result = false;
752  bool have_anyrange_result = false;
753  bool have_anymultirange_result = false;
754  bool have_anycompatible_result = false;
755  bool have_anycompatible_array_result = false;
756  bool have_anycompatible_range_result = false;
757  bool have_anycompatible_multirange_result = false;
758  polymorphic_actuals poly_actuals;
759  polymorphic_actuals anyc_actuals;
760  Oid anycollation = InvalidOid;
761  Oid anycompatcollation = InvalidOid;
762  int i;
763 
764  /* See if there are any polymorphic outputs; quick out if not */
765  for (i = 0; i < natts; i++)
766  {
767  switch (TupleDescAttr(tupdesc, i)->atttypid)
768  {
769  case ANYELEMENTOID:
770  case ANYNONARRAYOID:
771  case ANYENUMOID:
772  have_polymorphic_result = true;
773  have_anyelement_result = true;
774  break;
775  case ANYARRAYOID:
776  have_polymorphic_result = true;
777  have_anyarray_result = true;
778  break;
779  case ANYRANGEOID:
780  have_polymorphic_result = true;
781  have_anyrange_result = true;
782  break;
783  case ANYMULTIRANGEOID:
784  have_polymorphic_result = true;
785  have_anymultirange_result = true;
786  break;
787  case ANYCOMPATIBLEOID:
788  case ANYCOMPATIBLENONARRAYOID:
789  have_polymorphic_result = true;
790  have_anycompatible_result = true;
791  break;
792  case ANYCOMPATIBLEARRAYOID:
793  have_polymorphic_result = true;
794  have_anycompatible_array_result = true;
795  break;
796  case ANYCOMPATIBLERANGEOID:
797  have_polymorphic_result = true;
798  have_anycompatible_range_result = true;
799  break;
800  case ANYCOMPATIBLEMULTIRANGEOID:
801  have_polymorphic_result = true;
802  have_anycompatible_multirange_result = true;
803  break;
804  default:
805  break;
806  }
807  }
808  if (!have_polymorphic_result)
809  return true;
810 
811  /*
812  * Otherwise, extract actual datatype(s) from input arguments. (We assume
813  * the parser already validated consistency of the arguments. Also, for
814  * the ANYCOMPATIBLE pseudotype family, we expect that all matching
815  * arguments were coerced to the selected common supertype, so that it
816  * doesn't matter which one's exposed type we look at.)
817  */
818  if (!call_expr)
819  return false; /* no hope */
820 
821  memset(&poly_actuals, 0, sizeof(poly_actuals));
822  memset(&anyc_actuals, 0, sizeof(anyc_actuals));
823 
824  for (i = 0; i < nargs; i++)
825  {
826  switch (declared_args->values[i])
827  {
828  case ANYELEMENTOID:
829  case ANYNONARRAYOID:
830  case ANYENUMOID:
831  if (!OidIsValid(poly_actuals.anyelement_type))
832  {
833  poly_actuals.anyelement_type =
834  get_call_expr_argtype(call_expr, i);
835  if (!OidIsValid(poly_actuals.anyelement_type))
836  return false;
837  }
838  break;
839  case ANYARRAYOID:
840  if (!OidIsValid(poly_actuals.anyarray_type))
841  {
842  poly_actuals.anyarray_type =
843  get_call_expr_argtype(call_expr, i);
844  if (!OidIsValid(poly_actuals.anyarray_type))
845  return false;
846  }
847  break;
848  case ANYRANGEOID:
849  if (!OidIsValid(poly_actuals.anyrange_type))
850  {
851  poly_actuals.anyrange_type =
852  get_call_expr_argtype(call_expr, i);
853  if (!OidIsValid(poly_actuals.anyrange_type))
854  return false;
855  }
856  break;
857  case ANYMULTIRANGEOID:
858  if (!OidIsValid(poly_actuals.anymultirange_type))
859  {
860  poly_actuals.anymultirange_type =
861  get_call_expr_argtype(call_expr, i);
862  if (!OidIsValid(poly_actuals.anymultirange_type))
863  return false;
864  }
865  break;
866  case ANYCOMPATIBLEOID:
867  case ANYCOMPATIBLENONARRAYOID:
868  if (!OidIsValid(anyc_actuals.anyelement_type))
869  {
870  anyc_actuals.anyelement_type =
871  get_call_expr_argtype(call_expr, i);
872  if (!OidIsValid(anyc_actuals.anyelement_type))
873  return false;
874  }
875  break;
876  case ANYCOMPATIBLEARRAYOID:
877  if (!OidIsValid(anyc_actuals.anyarray_type))
878  {
879  anyc_actuals.anyarray_type =
880  get_call_expr_argtype(call_expr, i);
881  if (!OidIsValid(anyc_actuals.anyarray_type))
882  return false;
883  }
884  break;
885  case ANYCOMPATIBLERANGEOID:
886  if (!OidIsValid(anyc_actuals.anyrange_type))
887  {
888  anyc_actuals.anyrange_type =
889  get_call_expr_argtype(call_expr, i);
890  if (!OidIsValid(anyc_actuals.anyrange_type))
891  return false;
892  }
893  break;
894  case ANYCOMPATIBLEMULTIRANGEOID:
895  if (!OidIsValid(anyc_actuals.anymultirange_type))
896  {
897  anyc_actuals.anymultirange_type =
898  get_call_expr_argtype(call_expr, i);
899  if (!OidIsValid(anyc_actuals.anymultirange_type))
900  return false;
901  }
902  break;
903  default:
904  break;
905  }
906  }
907 
908  /* If needed, deduce one polymorphic type from others */
909  if (have_anyelement_result && !OidIsValid(poly_actuals.anyelement_type))
910  resolve_anyelement_from_others(&poly_actuals);
911 
912  if (have_anyarray_result && !OidIsValid(poly_actuals.anyarray_type))
913  resolve_anyarray_from_others(&poly_actuals);
914 
915  if (have_anyrange_result && !OidIsValid(poly_actuals.anyrange_type))
916  resolve_anyrange_from_others(&poly_actuals);
917 
918  if (have_anymultirange_result && !OidIsValid(poly_actuals.anymultirange_type))
919  resolve_anymultirange_from_others(&poly_actuals);
920 
921  if (have_anycompatible_result && !OidIsValid(anyc_actuals.anyelement_type))
922  resolve_anyelement_from_others(&anyc_actuals);
923 
924  if (have_anycompatible_array_result && !OidIsValid(anyc_actuals.anyarray_type))
925  resolve_anyarray_from_others(&anyc_actuals);
926 
927  if (have_anycompatible_range_result && !OidIsValid(anyc_actuals.anyrange_type))
928  resolve_anyrange_from_others(&anyc_actuals);
929 
930  if (have_anycompatible_multirange_result && !OidIsValid(anyc_actuals.anymultirange_type))
931  resolve_anymultirange_from_others(&anyc_actuals);
932 
933  /*
934  * Identify the collation to use for polymorphic OUT parameters. (It'll
935  * necessarily be the same for both anyelement and anyarray, likewise for
936  * anycompatible and anycompatiblearray.) Note that range types are not
937  * collatable, so any possible internal collation of a range type is not
938  * considered here.
939  */
940  if (OidIsValid(poly_actuals.anyelement_type))
941  anycollation = get_typcollation(poly_actuals.anyelement_type);
942  else if (OidIsValid(poly_actuals.anyarray_type))
943  anycollation = get_typcollation(poly_actuals.anyarray_type);
944 
945  if (OidIsValid(anyc_actuals.anyelement_type))
946  anycompatcollation = get_typcollation(anyc_actuals.anyelement_type);
947  else if (OidIsValid(anyc_actuals.anyarray_type))
948  anycompatcollation = get_typcollation(anyc_actuals.anyarray_type);
949 
950  if (OidIsValid(anycollation) || OidIsValid(anycompatcollation))
951  {
952  /*
953  * The types are collatable, so consider whether to use a nondefault
954  * collation. We do so if we can identify the input collation used
955  * for the function.
956  */
957  Oid inputcollation = exprInputCollation(call_expr);
958 
959  if (OidIsValid(inputcollation))
960  {
961  if (OidIsValid(anycollation))
962  anycollation = inputcollation;
963  if (OidIsValid(anycompatcollation))
964  anycompatcollation = inputcollation;
965  }
966  }
967 
968  /* And finally replace the tuple column types as needed */
969  for (i = 0; i < natts; i++)
970  {
971  Form_pg_attribute att = TupleDescAttr(tupdesc, i);
972 
973  switch (att->atttypid)
974  {
975  case ANYELEMENTOID:
976  case ANYNONARRAYOID:
977  case ANYENUMOID:
978  TupleDescInitEntry(tupdesc, i + 1,
979  NameStr(att->attname),
980  poly_actuals.anyelement_type,
981  -1,
982  0);
983  TupleDescInitEntryCollation(tupdesc, i + 1, anycollation);
984  break;
985  case ANYARRAYOID:
986  TupleDescInitEntry(tupdesc, i + 1,
987  NameStr(att->attname),
988  poly_actuals.anyarray_type,
989  -1,
990  0);
991  TupleDescInitEntryCollation(tupdesc, i + 1, anycollation);
992  break;
993  case ANYRANGEOID:
994  TupleDescInitEntry(tupdesc, i + 1,
995  NameStr(att->attname),
996  poly_actuals.anyrange_type,
997  -1,
998  0);
999  /* no collation should be attached to a range type */
1000  break;
1001  case ANYMULTIRANGEOID:
1002  TupleDescInitEntry(tupdesc, i + 1,
1003  NameStr(att->attname),
1004  poly_actuals.anymultirange_type,
1005  -1,
1006  0);
1007  /* no collation should be attached to a multirange type */
1008  break;
1009  case ANYCOMPATIBLEOID:
1010  case ANYCOMPATIBLENONARRAYOID:
1011  TupleDescInitEntry(tupdesc, i + 1,
1012  NameStr(att->attname),
1013  anyc_actuals.anyelement_type,
1014  -1,
1015  0);
1016  TupleDescInitEntryCollation(tupdesc, i + 1, anycompatcollation);
1017  break;
1018  case ANYCOMPATIBLEARRAYOID:
1019  TupleDescInitEntry(tupdesc, i + 1,
1020  NameStr(att->attname),
1021  anyc_actuals.anyarray_type,
1022  -1,
1023  0);
1024  TupleDescInitEntryCollation(tupdesc, i + 1, anycompatcollation);
1025  break;
1026  case ANYCOMPATIBLERANGEOID:
1027  TupleDescInitEntry(tupdesc, i + 1,
1028  NameStr(att->attname),
1029  anyc_actuals.anyrange_type,
1030  -1,
1031  0);
1032  /* no collation should be attached to a range type */
1033  break;
1034  case ANYCOMPATIBLEMULTIRANGEOID:
1035  TupleDescInitEntry(tupdesc, i + 1,
1036  NameStr(att->attname),
1037  anyc_actuals.anymultirange_type,
1038  -1,
1039  0);
1040  /* no collation should be attached to a multirange type */
1041  break;
1042  default:
1043  break;
1044  }
1045  }
1046 
1047  return true;
1048 }
1049 
1050 /*
1051  * Given the declared argument types and modes for a function, replace any
1052  * polymorphic types (ANYELEMENT etc) in argtypes[] with concrete data types
1053  * deduced from the input arguments found in call_expr.
1054  *
1055  * Returns true if able to deduce all types, false if necessary information
1056  * is not provided (call_expr is NULL or arg types aren't identifiable).
1057  *
1058  * This is the same logic as resolve_polymorphic_tupdesc, but with a different
1059  * argument representation, and slightly different output responsibilities.
1060  *
1061  * argmodes may be NULL, in which case all arguments are assumed to be IN mode.
1062  */
1063 bool
1064 resolve_polymorphic_argtypes(int numargs, Oid *argtypes, char *argmodes,
1065  Node *call_expr)
1066 {
1067  bool have_polymorphic_result = false;
1068  bool have_anyelement_result = false;
1069  bool have_anyarray_result = false;
1070  bool have_anyrange_result = false;
1071  bool have_anymultirange_result = false;
1072  bool have_anycompatible_result = false;
1073  bool have_anycompatible_array_result = false;
1074  bool have_anycompatible_range_result = false;
1075  bool have_anycompatible_multirange_result = false;
1076  polymorphic_actuals poly_actuals;
1077  polymorphic_actuals anyc_actuals;
1078  int inargno;
1079  int i;
1080 
1081  /*
1082  * First pass: resolve polymorphic inputs, check for outputs. As in
1083  * resolve_polymorphic_tupdesc, we rely on the parser to have enforced
1084  * type consistency and coerced ANYCOMPATIBLE args to a common supertype.
1085  */
1086  memset(&poly_actuals, 0, sizeof(poly_actuals));
1087  memset(&anyc_actuals, 0, sizeof(anyc_actuals));
1088  inargno = 0;
1089  for (i = 0; i < numargs; i++)
1090  {
1091  char argmode = argmodes ? argmodes[i] : PROARGMODE_IN;
1092 
1093  switch (argtypes[i])
1094  {
1095  case ANYELEMENTOID:
1096  case ANYNONARRAYOID:
1097  case ANYENUMOID:
1098  if (argmode == PROARGMODE_OUT || argmode == PROARGMODE_TABLE)
1099  {
1100  have_polymorphic_result = true;
1101  have_anyelement_result = true;
1102  }
1103  else
1104  {
1105  if (!OidIsValid(poly_actuals.anyelement_type))
1106  {
1107  poly_actuals.anyelement_type =
1108  get_call_expr_argtype(call_expr, inargno);
1109  if (!OidIsValid(poly_actuals.anyelement_type))
1110  return false;
1111  }
1112  argtypes[i] = poly_actuals.anyelement_type;
1113  }
1114  break;
1115  case ANYARRAYOID:
1116  if (argmode == PROARGMODE_OUT || argmode == PROARGMODE_TABLE)
1117  {
1118  have_polymorphic_result = true;
1119  have_anyarray_result = true;
1120  }
1121  else
1122  {
1123  if (!OidIsValid(poly_actuals.anyarray_type))
1124  {
1125  poly_actuals.anyarray_type =
1126  get_call_expr_argtype(call_expr, inargno);
1127  if (!OidIsValid(poly_actuals.anyarray_type))
1128  return false;
1129  }
1130  argtypes[i] = poly_actuals.anyarray_type;
1131  }
1132  break;
1133  case ANYRANGEOID:
1134  if (argmode == PROARGMODE_OUT || argmode == PROARGMODE_TABLE)
1135  {
1136  have_polymorphic_result = true;
1137  have_anyrange_result = true;
1138  }
1139  else
1140  {
1141  if (!OidIsValid(poly_actuals.anyrange_type))
1142  {
1143  poly_actuals.anyrange_type =
1144  get_call_expr_argtype(call_expr, inargno);
1145  if (!OidIsValid(poly_actuals.anyrange_type))
1146  return false;
1147  }
1148  argtypes[i] = poly_actuals.anyrange_type;
1149  }
1150  break;
1151  case ANYMULTIRANGEOID:
1152  if (argmode == PROARGMODE_OUT || argmode == PROARGMODE_TABLE)
1153  {
1154  have_polymorphic_result = true;
1155  have_anymultirange_result = true;
1156  }
1157  else
1158  {
1159  if (!OidIsValid(poly_actuals.anymultirange_type))
1160  {
1161  poly_actuals.anymultirange_type =
1162  get_call_expr_argtype(call_expr, inargno);
1163  if (!OidIsValid(poly_actuals.anymultirange_type))
1164  return false;
1165  }
1166  argtypes[i] = poly_actuals.anymultirange_type;
1167  }
1168  break;
1169  case ANYCOMPATIBLEOID:
1170  case ANYCOMPATIBLENONARRAYOID:
1171  if (argmode == PROARGMODE_OUT || argmode == PROARGMODE_TABLE)
1172  {
1173  have_polymorphic_result = true;
1174  have_anycompatible_result = true;
1175  }
1176  else
1177  {
1178  if (!OidIsValid(anyc_actuals.anyelement_type))
1179  {
1180  anyc_actuals.anyelement_type =
1181  get_call_expr_argtype(call_expr, inargno);
1182  if (!OidIsValid(anyc_actuals.anyelement_type))
1183  return false;
1184  }
1185  argtypes[i] = anyc_actuals.anyelement_type;
1186  }
1187  break;
1188  case ANYCOMPATIBLEARRAYOID:
1189  if (argmode == PROARGMODE_OUT || argmode == PROARGMODE_TABLE)
1190  {
1191  have_polymorphic_result = true;
1192  have_anycompatible_array_result = true;
1193  }
1194  else
1195  {
1196  if (!OidIsValid(anyc_actuals.anyarray_type))
1197  {
1198  anyc_actuals.anyarray_type =
1199  get_call_expr_argtype(call_expr, inargno);
1200  if (!OidIsValid(anyc_actuals.anyarray_type))
1201  return false;
1202  }
1203  argtypes[i] = anyc_actuals.anyarray_type;
1204  }
1205  break;
1206  case ANYCOMPATIBLERANGEOID:
1207  if (argmode == PROARGMODE_OUT || argmode == PROARGMODE_TABLE)
1208  {
1209  have_polymorphic_result = true;
1210  have_anycompatible_range_result = true;
1211  }
1212  else
1213  {
1214  if (!OidIsValid(anyc_actuals.anyrange_type))
1215  {
1216  anyc_actuals.anyrange_type =
1217  get_call_expr_argtype(call_expr, inargno);
1218  if (!OidIsValid(anyc_actuals.anyrange_type))
1219  return false;
1220  }
1221  argtypes[i] = anyc_actuals.anyrange_type;
1222  }
1223  break;
1224  case ANYCOMPATIBLEMULTIRANGEOID:
1225  if (argmode == PROARGMODE_OUT || argmode == PROARGMODE_TABLE)
1226  {
1227  have_polymorphic_result = true;
1228  have_anycompatible_multirange_result = true;
1229  }
1230  else
1231  {
1232  if (!OidIsValid(anyc_actuals.anymultirange_type))
1233  {
1234  anyc_actuals.anymultirange_type =
1235  get_call_expr_argtype(call_expr, inargno);
1236  if (!OidIsValid(anyc_actuals.anymultirange_type))
1237  return false;
1238  }
1239  argtypes[i] = anyc_actuals.anymultirange_type;
1240  }
1241  break;
1242  default:
1243  break;
1244  }
1245  if (argmode != PROARGMODE_OUT && argmode != PROARGMODE_TABLE)
1246  inargno++;
1247  }
1248 
1249  /* Done? */
1250  if (!have_polymorphic_result)
1251  return true;
1252 
1253  /* If needed, deduce one polymorphic type from others */
1254  if (have_anyelement_result && !OidIsValid(poly_actuals.anyelement_type))
1255  resolve_anyelement_from_others(&poly_actuals);
1256 
1257  if (have_anyarray_result && !OidIsValid(poly_actuals.anyarray_type))
1258  resolve_anyarray_from_others(&poly_actuals);
1259 
1260  if (have_anyrange_result && !OidIsValid(poly_actuals.anyrange_type))
1261  resolve_anyrange_from_others(&poly_actuals);
1262 
1263  if (have_anymultirange_result && !OidIsValid(poly_actuals.anymultirange_type))
1264  resolve_anymultirange_from_others(&poly_actuals);
1265 
1266  if (have_anycompatible_result && !OidIsValid(anyc_actuals.anyelement_type))
1267  resolve_anyelement_from_others(&anyc_actuals);
1268 
1269  if (have_anycompatible_array_result && !OidIsValid(anyc_actuals.anyarray_type))
1270  resolve_anyarray_from_others(&anyc_actuals);
1271 
1272  if (have_anycompatible_range_result && !OidIsValid(anyc_actuals.anyrange_type))
1273  resolve_anyrange_from_others(&anyc_actuals);
1274 
1275  if (have_anycompatible_multirange_result && !OidIsValid(anyc_actuals.anymultirange_type))
1276  resolve_anymultirange_from_others(&anyc_actuals);
1277 
1278  /* And finally replace the output column types as needed */
1279  for (i = 0; i < numargs; i++)
1280  {
1281  switch (argtypes[i])
1282  {
1283  case ANYELEMENTOID:
1284  case ANYNONARRAYOID:
1285  case ANYENUMOID:
1286  argtypes[i] = poly_actuals.anyelement_type;
1287  break;
1288  case ANYARRAYOID:
1289  argtypes[i] = poly_actuals.anyarray_type;
1290  break;
1291  case ANYRANGEOID:
1292  argtypes[i] = poly_actuals.anyrange_type;
1293  break;
1294  case ANYMULTIRANGEOID:
1295  argtypes[i] = poly_actuals.anymultirange_type;
1296  break;
1297  case ANYCOMPATIBLEOID:
1298  case ANYCOMPATIBLENONARRAYOID:
1299  argtypes[i] = anyc_actuals.anyelement_type;
1300  break;
1301  case ANYCOMPATIBLEARRAYOID:
1302  argtypes[i] = anyc_actuals.anyarray_type;
1303  break;
1304  case ANYCOMPATIBLERANGEOID:
1305  argtypes[i] = anyc_actuals.anyrange_type;
1306  break;
1307  case ANYCOMPATIBLEMULTIRANGEOID:
1308  argtypes[i] = anyc_actuals.anymultirange_type;
1309  break;
1310  default:
1311  break;
1312  }
1313  }
1314 
1315  return true;
1316 }
1317 
1318 /*
1319  * get_type_func_class
1320  * Given the type OID, obtain its TYPEFUNC classification.
1321  * Also, if it's a domain, return the base type OID.
1322  *
1323  * This is intended to centralize a bunch of formerly ad-hoc code for
1324  * classifying types. The categories used here are useful for deciding
1325  * how to handle functions returning the datatype.
1326  */
1327 static TypeFuncClass
1328 get_type_func_class(Oid typid, Oid *base_typeid)
1329 {
1330  *base_typeid = typid;
1331 
1332  switch (get_typtype(typid))
1333  {
1334  case TYPTYPE_COMPOSITE:
1335  return TYPEFUNC_COMPOSITE;
1336  case TYPTYPE_BASE:
1337  case TYPTYPE_ENUM:
1338  case TYPTYPE_RANGE:
1339  case TYPTYPE_MULTIRANGE:
1340  return TYPEFUNC_SCALAR;
1341  case TYPTYPE_DOMAIN:
1342  *base_typeid = typid = getBaseType(typid);
1343  if (get_typtype(typid) == TYPTYPE_COMPOSITE)
1345  else /* domain base type can't be a pseudotype */
1346  return TYPEFUNC_SCALAR;
1347  case TYPTYPE_PSEUDO:
1348  if (typid == RECORDOID)
1349  return TYPEFUNC_RECORD;
1350 
1351  /*
1352  * We treat VOID and CSTRING as legitimate scalar datatypes,
1353  * mostly for the convenience of the JDBC driver (which wants to
1354  * be able to do "SELECT * FROM foo()" for all legitimately
1355  * user-callable functions).
1356  */
1357  if (typid == VOIDOID || typid == CSTRINGOID)
1358  return TYPEFUNC_SCALAR;
1359  return TYPEFUNC_OTHER;
1360  }
1361  /* shouldn't get here, probably */
1362  return TYPEFUNC_OTHER;
1363 }
1364 
1365 
1366 /*
1367  * get_func_arg_info
1368  *
1369  * Fetch info about the argument types, names, and IN/OUT modes from the
1370  * pg_proc tuple. Return value is the total number of arguments.
1371  * Other results are palloc'd. *p_argtypes is always filled in, but
1372  * *p_argnames and *p_argmodes will be set NULL in the default cases
1373  * (no names, and all IN arguments, respectively).
1374  *
1375  * Note that this function simply fetches what is in the pg_proc tuple;
1376  * it doesn't do any interpretation of polymorphic types.
1377  */
1378 int
1380  Oid **p_argtypes, char ***p_argnames, char **p_argmodes)
1381 {
1382  Form_pg_proc procStruct = (Form_pg_proc) GETSTRUCT(procTup);
1383  Datum proallargtypes;
1384  Datum proargmodes;
1385  Datum proargnames;
1386  bool isNull;
1387  ArrayType *arr;
1388  int numargs;
1389  Datum *elems;
1390  int nelems;
1391  int i;
1392 
1393  /* First discover the total number of parameters and get their types */
1394  proallargtypes = SysCacheGetAttr(PROCOID, procTup,
1395  Anum_pg_proc_proallargtypes,
1396  &isNull);
1397  if (!isNull)
1398  {
1399  /*
1400  * We expect the arrays to be 1-D arrays of the right types; verify
1401  * that. For the OID and char arrays, we don't need to use
1402  * deconstruct_array() since the array data is just going to look like
1403  * a C array of values.
1404  */
1405  arr = DatumGetArrayTypeP(proallargtypes); /* ensure not toasted */
1406  numargs = ARR_DIMS(arr)[0];
1407  if (ARR_NDIM(arr) != 1 ||
1408  numargs < 0 ||
1409  ARR_HASNULL(arr) ||
1410  ARR_ELEMTYPE(arr) != OIDOID)
1411  elog(ERROR, "proallargtypes is not a 1-D Oid array or it contains nulls");
1412  Assert(numargs >= procStruct->pronargs);
1413  *p_argtypes = (Oid *) palloc(numargs * sizeof(Oid));
1414  memcpy(*p_argtypes, ARR_DATA_PTR(arr),
1415  numargs * sizeof(Oid));
1416  }
1417  else
1418  {
1419  /* If no proallargtypes, use proargtypes */
1420  numargs = procStruct->proargtypes.dim1;
1421  Assert(numargs == procStruct->pronargs);
1422  *p_argtypes = (Oid *) palloc(numargs * sizeof(Oid));
1423  memcpy(*p_argtypes, procStruct->proargtypes.values,
1424  numargs * sizeof(Oid));
1425  }
1426 
1427  /* Get argument names, if available */
1428  proargnames = SysCacheGetAttr(PROCOID, procTup,
1429  Anum_pg_proc_proargnames,
1430  &isNull);
1431  if (isNull)
1432  *p_argnames = NULL;
1433  else
1434  {
1435  deconstruct_array_builtin(DatumGetArrayTypeP(proargnames), TEXTOID,
1436  &elems, NULL, &nelems);
1437  if (nelems != numargs) /* should not happen */
1438  elog(ERROR, "proargnames must have the same number of elements as the function has arguments");
1439  *p_argnames = (char **) palloc(sizeof(char *) * numargs);
1440  for (i = 0; i < numargs; i++)
1441  (*p_argnames)[i] = TextDatumGetCString(elems[i]);
1442  }
1443 
1444  /* Get argument modes, if available */
1445  proargmodes = SysCacheGetAttr(PROCOID, procTup,
1446  Anum_pg_proc_proargmodes,
1447  &isNull);
1448  if (isNull)
1449  *p_argmodes = NULL;
1450  else
1451  {
1452  arr = DatumGetArrayTypeP(proargmodes); /* ensure not toasted */
1453  if (ARR_NDIM(arr) != 1 ||
1454  ARR_DIMS(arr)[0] != numargs ||
1455  ARR_HASNULL(arr) ||
1456  ARR_ELEMTYPE(arr) != CHAROID)
1457  elog(ERROR, "proargmodes is not a 1-D char array of length %d or it contains nulls",
1458  numargs);
1459  *p_argmodes = (char *) palloc(numargs * sizeof(char));
1460  memcpy(*p_argmodes, ARR_DATA_PTR(arr),
1461  numargs * sizeof(char));
1462  }
1463 
1464  return numargs;
1465 }
1466 
1467 /*
1468  * get_func_trftypes
1469  *
1470  * Returns the number of transformed types used by the function.
1471  * If there are any, a palloc'd array of the type OIDs is returned
1472  * into *p_trftypes.
1473  */
1474 int
1476  Oid **p_trftypes)
1477 {
1478  Datum protrftypes;
1479  ArrayType *arr;
1480  int nelems;
1481  bool isNull;
1482 
1483  protrftypes = SysCacheGetAttr(PROCOID, procTup,
1484  Anum_pg_proc_protrftypes,
1485  &isNull);
1486  if (!isNull)
1487  {
1488  /*
1489  * We expect the arrays to be 1-D arrays of the right types; verify
1490  * that. For the OID and char arrays, we don't need to use
1491  * deconstruct_array() since the array data is just going to look like
1492  * a C array of values.
1493  */
1494  arr = DatumGetArrayTypeP(protrftypes); /* ensure not toasted */
1495  nelems = ARR_DIMS(arr)[0];
1496  if (ARR_NDIM(arr) != 1 ||
1497  nelems < 0 ||
1498  ARR_HASNULL(arr) ||
1499  ARR_ELEMTYPE(arr) != OIDOID)
1500  elog(ERROR, "protrftypes is not a 1-D Oid array or it contains nulls");
1501  *p_trftypes = (Oid *) palloc(nelems * sizeof(Oid));
1502  memcpy(*p_trftypes, ARR_DATA_PTR(arr),
1503  nelems * sizeof(Oid));
1504 
1505  return nelems;
1506  }
1507  else
1508  return 0;
1509 }
1510 
1511 /*
1512  * get_func_input_arg_names
1513  *
1514  * Extract the names of input arguments only, given a function's
1515  * proargnames and proargmodes entries in Datum form.
1516  *
1517  * Returns the number of input arguments, which is the length of the
1518  * palloc'd array returned to *arg_names. Entries for unnamed args
1519  * are set to NULL. You don't get anything if proargnames is NULL.
1520  */
1521 int
1522 get_func_input_arg_names(Datum proargnames, Datum proargmodes,
1523  char ***arg_names)
1524 {
1525  ArrayType *arr;
1526  int numargs;
1527  Datum *argnames;
1528  char *argmodes;
1529  char **inargnames;
1530  int numinargs;
1531  int i;
1532 
1533  /* Do nothing if null proargnames */
1534  if (proargnames == PointerGetDatum(NULL))
1535  {
1536  *arg_names = NULL;
1537  return 0;
1538  }
1539 
1540  /*
1541  * We expect the arrays to be 1-D arrays of the right types; verify that.
1542  * For proargmodes, we don't need to use deconstruct_array() since the
1543  * array data is just going to look like a C array of values.
1544  */
1545  arr = DatumGetArrayTypeP(proargnames); /* ensure not toasted */
1546  if (ARR_NDIM(arr) != 1 ||
1547  ARR_HASNULL(arr) ||
1548  ARR_ELEMTYPE(arr) != TEXTOID)
1549  elog(ERROR, "proargnames is not a 1-D text array or it contains nulls");
1550  deconstruct_array_builtin(arr, TEXTOID, &argnames, NULL, &numargs);
1551  if (proargmodes != PointerGetDatum(NULL))
1552  {
1553  arr = DatumGetArrayTypeP(proargmodes); /* ensure not toasted */
1554  if (ARR_NDIM(arr) != 1 ||
1555  ARR_DIMS(arr)[0] != numargs ||
1556  ARR_HASNULL(arr) ||
1557  ARR_ELEMTYPE(arr) != CHAROID)
1558  elog(ERROR, "proargmodes is not a 1-D char array of length %d or it contains nulls",
1559  numargs);
1560  argmodes = (char *) ARR_DATA_PTR(arr);
1561  }
1562  else
1563  argmodes = NULL;
1564 
1565  /* zero elements probably shouldn't happen, but handle it gracefully */
1566  if (numargs <= 0)
1567  {
1568  *arg_names = NULL;
1569  return 0;
1570  }
1571 
1572  /* extract input-argument names */
1573  inargnames = (char **) palloc(numargs * sizeof(char *));
1574  numinargs = 0;
1575  for (i = 0; i < numargs; i++)
1576  {
1577  if (argmodes == NULL ||
1578  argmodes[i] == PROARGMODE_IN ||
1579  argmodes[i] == PROARGMODE_INOUT ||
1580  argmodes[i] == PROARGMODE_VARIADIC)
1581  {
1582  char *pname = TextDatumGetCString(argnames[i]);
1583 
1584  if (pname[0] != '\0')
1585  inargnames[numinargs] = pname;
1586  else
1587  inargnames[numinargs] = NULL;
1588  numinargs++;
1589  }
1590  }
1591 
1592  *arg_names = inargnames;
1593  return numinargs;
1594 }
1595 
1596 
1597 /*
1598  * get_func_result_name
1599  *
1600  * If the function has exactly one output parameter, and that parameter
1601  * is named, return the name (as a palloc'd string). Else return NULL.
1602  *
1603  * This is used to determine the default output column name for functions
1604  * returning scalar types.
1605  */
1606 char *
1608 {
1609  char *result;
1610  HeapTuple procTuple;
1611  Datum proargmodes;
1612  Datum proargnames;
1613  ArrayType *arr;
1614  int numargs;
1615  char *argmodes;
1616  Datum *argnames;
1617  int numoutargs;
1618  int nargnames;
1619  int i;
1620 
1621  /* First fetch the function's pg_proc row */
1622  procTuple = SearchSysCache1(PROCOID, ObjectIdGetDatum(functionId));
1623  if (!HeapTupleIsValid(procTuple))
1624  elog(ERROR, "cache lookup failed for function %u", functionId);
1625 
1626  /* If there are no named OUT parameters, return NULL */
1627  if (heap_attisnull(procTuple, Anum_pg_proc_proargmodes, NULL) ||
1628  heap_attisnull(procTuple, Anum_pg_proc_proargnames, NULL))
1629  result = NULL;
1630  else
1631  {
1632  /* Get the data out of the tuple */
1633  proargmodes = SysCacheGetAttrNotNull(PROCOID, procTuple,
1634  Anum_pg_proc_proargmodes);
1635  proargnames = SysCacheGetAttrNotNull(PROCOID, procTuple,
1636  Anum_pg_proc_proargnames);
1637 
1638  /*
1639  * We expect the arrays to be 1-D arrays of the right types; verify
1640  * that. For the char array, we don't need to use deconstruct_array()
1641  * since the array data is just going to look like a C array of
1642  * values.
1643  */
1644  arr = DatumGetArrayTypeP(proargmodes); /* ensure not toasted */
1645  numargs = ARR_DIMS(arr)[0];
1646  if (ARR_NDIM(arr) != 1 ||
1647  numargs < 0 ||
1648  ARR_HASNULL(arr) ||
1649  ARR_ELEMTYPE(arr) != CHAROID)
1650  elog(ERROR, "proargmodes is not a 1-D char array or it contains nulls");
1651  argmodes = (char *) ARR_DATA_PTR(arr);
1652  arr = DatumGetArrayTypeP(proargnames); /* ensure not toasted */
1653  if (ARR_NDIM(arr) != 1 ||
1654  ARR_DIMS(arr)[0] != numargs ||
1655  ARR_HASNULL(arr) ||
1656  ARR_ELEMTYPE(arr) != TEXTOID)
1657  elog(ERROR, "proargnames is not a 1-D text array of length %d or it contains nulls",
1658  numargs);
1659  deconstruct_array_builtin(arr, TEXTOID, &argnames, NULL, &nargnames);
1660  Assert(nargnames == numargs);
1661 
1662  /* scan for output argument(s) */
1663  result = NULL;
1664  numoutargs = 0;
1665  for (i = 0; i < numargs; i++)
1666  {
1667  if (argmodes[i] == PROARGMODE_IN ||
1668  argmodes[i] == PROARGMODE_VARIADIC)
1669  continue;
1670  Assert(argmodes[i] == PROARGMODE_OUT ||
1671  argmodes[i] == PROARGMODE_INOUT ||
1672  argmodes[i] == PROARGMODE_TABLE);
1673  if (++numoutargs > 1)
1674  {
1675  /* multiple out args, so forget it */
1676  result = NULL;
1677  break;
1678  }
1679  result = TextDatumGetCString(argnames[i]);
1680  if (result == NULL || result[0] == '\0')
1681  {
1682  /* Parameter is not named, so forget it */
1683  result = NULL;
1684  break;
1685  }
1686  }
1687  }
1688 
1689  ReleaseSysCache(procTuple);
1690 
1691  return result;
1692 }
1693 
1694 
1695 /*
1696  * build_function_result_tupdesc_t
1697  *
1698  * Given a pg_proc row for a function, return a tuple descriptor for the
1699  * result rowtype, or NULL if the function does not have OUT parameters.
1700  *
1701  * Note that this does not handle resolution of polymorphic types;
1702  * that is deliberate.
1703  */
1704 TupleDesc
1706 {
1707  Form_pg_proc procform = (Form_pg_proc) GETSTRUCT(procTuple);
1708  Datum proallargtypes;
1709  Datum proargmodes;
1710  Datum proargnames;
1711  bool isnull;
1712 
1713  /* Return NULL if the function isn't declared to return RECORD */
1714  if (procform->prorettype != RECORDOID)
1715  return NULL;
1716 
1717  /* If there are no OUT parameters, return NULL */
1718  if (heap_attisnull(procTuple, Anum_pg_proc_proallargtypes, NULL) ||
1719  heap_attisnull(procTuple, Anum_pg_proc_proargmodes, NULL))
1720  return NULL;
1721 
1722  /* Get the data out of the tuple */
1723  proallargtypes = SysCacheGetAttrNotNull(PROCOID, procTuple,
1724  Anum_pg_proc_proallargtypes);
1725  proargmodes = SysCacheGetAttrNotNull(PROCOID, procTuple,
1726  Anum_pg_proc_proargmodes);
1727  proargnames = SysCacheGetAttr(PROCOID, procTuple,
1728  Anum_pg_proc_proargnames,
1729  &isnull);
1730  if (isnull)
1731  proargnames = PointerGetDatum(NULL); /* just to be sure */
1732 
1733  return build_function_result_tupdesc_d(procform->prokind,
1734  proallargtypes,
1735  proargmodes,
1736  proargnames);
1737 }
1738 
1739 /*
1740  * build_function_result_tupdesc_d
1741  *
1742  * Build a RECORD function's tupledesc from the pg_proc proallargtypes,
1743  * proargmodes, and proargnames arrays. This is split out for the
1744  * convenience of ProcedureCreate, which needs to be able to compute the
1745  * tupledesc before actually creating the function.
1746  *
1747  * For functions (but not for procedures), returns NULL if there are not at
1748  * least two OUT or INOUT arguments.
1749  */
1750 TupleDesc
1752  Datum proallargtypes,
1753  Datum proargmodes,
1754  Datum proargnames)
1755 {
1756  TupleDesc desc;
1757  ArrayType *arr;
1758  int numargs;
1759  Oid *argtypes;
1760  char *argmodes;
1761  Datum *argnames = NULL;
1762  Oid *outargtypes;
1763  char **outargnames;
1764  int numoutargs;
1765  int nargnames;
1766  int i;
1767 
1768  /* Can't have output args if columns are null */
1769  if (proallargtypes == PointerGetDatum(NULL) ||
1770  proargmodes == PointerGetDatum(NULL))
1771  return NULL;
1772 
1773  /*
1774  * We expect the arrays to be 1-D arrays of the right types; verify that.
1775  * For the OID and char arrays, we don't need to use deconstruct_array()
1776  * since the array data is just going to look like a C array of values.
1777  */
1778  arr = DatumGetArrayTypeP(proallargtypes); /* ensure not toasted */
1779  numargs = ARR_DIMS(arr)[0];
1780  if (ARR_NDIM(arr) != 1 ||
1781  numargs < 0 ||
1782  ARR_HASNULL(arr) ||
1783  ARR_ELEMTYPE(arr) != OIDOID)
1784  elog(ERROR, "proallargtypes is not a 1-D Oid array or it contains nulls");
1785  argtypes = (Oid *) ARR_DATA_PTR(arr);
1786  arr = DatumGetArrayTypeP(proargmodes); /* ensure not toasted */
1787  if (ARR_NDIM(arr) != 1 ||
1788  ARR_DIMS(arr)[0] != numargs ||
1789  ARR_HASNULL(arr) ||
1790  ARR_ELEMTYPE(arr) != CHAROID)
1791  elog(ERROR, "proargmodes is not a 1-D char array of length %d or it contains nulls",
1792  numargs);
1793  argmodes = (char *) ARR_DATA_PTR(arr);
1794  if (proargnames != PointerGetDatum(NULL))
1795  {
1796  arr = DatumGetArrayTypeP(proargnames); /* ensure not toasted */
1797  if (ARR_NDIM(arr) != 1 ||
1798  ARR_DIMS(arr)[0] != numargs ||
1799  ARR_HASNULL(arr) ||
1800  ARR_ELEMTYPE(arr) != TEXTOID)
1801  elog(ERROR, "proargnames is not a 1-D text array of length %d or it contains nulls",
1802  numargs);
1803  deconstruct_array_builtin(arr, TEXTOID, &argnames, NULL, &nargnames);
1804  Assert(nargnames == numargs);
1805  }
1806 
1807  /* zero elements probably shouldn't happen, but handle it gracefully */
1808  if (numargs <= 0)
1809  return NULL;
1810 
1811  /* extract output-argument types and names */
1812  outargtypes = (Oid *) palloc(numargs * sizeof(Oid));
1813  outargnames = (char **) palloc(numargs * sizeof(char *));
1814  numoutargs = 0;
1815  for (i = 0; i < numargs; i++)
1816  {
1817  char *pname;
1818 
1819  if (argmodes[i] == PROARGMODE_IN ||
1820  argmodes[i] == PROARGMODE_VARIADIC)
1821  continue;
1822  Assert(argmodes[i] == PROARGMODE_OUT ||
1823  argmodes[i] == PROARGMODE_INOUT ||
1824  argmodes[i] == PROARGMODE_TABLE);
1825  outargtypes[numoutargs] = argtypes[i];
1826  if (argnames)
1827  pname = TextDatumGetCString(argnames[i]);
1828  else
1829  pname = NULL;
1830  if (pname == NULL || pname[0] == '\0')
1831  {
1832  /* Parameter is not named, so gin up a column name */
1833  pname = psprintf("column%d", numoutargs + 1);
1834  }
1835  outargnames[numoutargs] = pname;
1836  numoutargs++;
1837  }
1838 
1839  /*
1840  * If there is no output argument, or only one, the function does not
1841  * return tuples.
1842  */
1843  if (numoutargs < 2 && prokind != PROKIND_PROCEDURE)
1844  return NULL;
1845 
1846  desc = CreateTemplateTupleDesc(numoutargs);
1847  for (i = 0; i < numoutargs; i++)
1848  {
1849  TupleDescInitEntry(desc, i + 1,
1850  outargnames[i],
1851  outargtypes[i],
1852  -1,
1853  0);
1854  }
1855 
1856  return desc;
1857 }
1858 
1859 
1860 /*
1861  * RelationNameGetTupleDesc
1862  *
1863  * Given a (possibly qualified) relation name, build a TupleDesc.
1864  *
1865  * Note: while this works as advertised, it's seldom the best way to
1866  * build a tupdesc for a function's result type. It's kept around
1867  * only for backwards compatibility with existing user-written code.
1868  */
1869 TupleDesc
1871 {
1872  RangeVar *relvar;
1873  Relation rel;
1874  TupleDesc tupdesc;
1875  List *relname_list;
1876 
1877  /* Open relation and copy the tuple description */
1878  relname_list = stringToQualifiedNameList(relname, NULL);
1879  relvar = makeRangeVarFromNameList(relname_list);
1880  rel = relation_openrv(relvar, AccessShareLock);
1881  tupdesc = CreateTupleDescCopy(RelationGetDescr(rel));
1883 
1884  return tupdesc;
1885 }
1886 
1887 /*
1888  * TypeGetTupleDesc
1889  *
1890  * Given a type Oid, build a TupleDesc. (In most cases you should be
1891  * using get_call_result_type or one of its siblings instead of this
1892  * routine, so that you can handle OUT parameters, RECORD result type,
1893  * and polymorphic results.)
1894  *
1895  * If the type is composite, *and* a colaliases List is provided, *and*
1896  * the List is of natts length, use the aliases instead of the relation
1897  * attnames. (NB: this usage is deprecated since it may result in
1898  * creation of unnecessary transient record types.)
1899  *
1900  * If the type is a base type, a single item alias List is required.
1901  */
1902 TupleDesc
1903 TypeGetTupleDesc(Oid typeoid, List *colaliases)
1904 {
1905  Oid base_typeoid;
1906  TypeFuncClass functypclass = get_type_func_class(typeoid, &base_typeoid);
1907  TupleDesc tupdesc = NULL;
1908 
1909  /*
1910  * Build a suitable tupledesc representing the output rows. We
1911  * intentionally do not support TYPEFUNC_COMPOSITE_DOMAIN here, as it's
1912  * unlikely that legacy callers of this obsolete function would be
1913  * prepared to apply domain constraints.
1914  */
1915  if (functypclass == TYPEFUNC_COMPOSITE)
1916  {
1917  /* Composite data type, e.g. a table's row type */
1918  tupdesc = lookup_rowtype_tupdesc_copy(base_typeoid, -1);
1919 
1920  if (colaliases != NIL)
1921  {
1922  int natts = tupdesc->natts;
1923  int varattno;
1924 
1925  /* does the list length match the number of attributes? */
1926  if (list_length(colaliases) != natts)
1927  ereport(ERROR,
1928  (errcode(ERRCODE_DATATYPE_MISMATCH),
1929  errmsg("number of aliases does not match number of columns")));
1930 
1931  /* OK, use the aliases instead */
1932  for (varattno = 0; varattno < natts; varattno++)
1933  {
1934  char *label = strVal(list_nth(colaliases, varattno));
1935  Form_pg_attribute attr = TupleDescAttr(tupdesc, varattno);
1936 
1937  if (label != NULL)
1938  namestrcpy(&(attr->attname), label);
1939  }
1940 
1941  /* The tuple type is now an anonymous record type */
1942  tupdesc->tdtypeid = RECORDOID;
1943  tupdesc->tdtypmod = -1;
1944  }
1945  }
1946  else if (functypclass == TYPEFUNC_SCALAR)
1947  {
1948  /* Base data type, i.e. scalar */
1949  char *attname;
1950 
1951  /* the alias list is required for base types */
1952  if (colaliases == NIL)
1953  ereport(ERROR,
1954  (errcode(ERRCODE_DATATYPE_MISMATCH),
1955  errmsg("no column alias was provided")));
1956 
1957  /* the alias list length must be 1 */
1958  if (list_length(colaliases) != 1)
1959  ereport(ERROR,
1960  (errcode(ERRCODE_DATATYPE_MISMATCH),
1961  errmsg("number of aliases does not match number of columns")));
1962 
1963  /* OK, get the column alias */
1964  attname = strVal(linitial(colaliases));
1965 
1966  tupdesc = CreateTemplateTupleDesc(1);
1967  TupleDescInitEntry(tupdesc,
1968  (AttrNumber) 1,
1969  attname,
1970  typeoid,
1971  -1,
1972  0);
1973  }
1974  else if (functypclass == TYPEFUNC_RECORD)
1975  {
1976  /* XXX can't support this because typmod wasn't passed in ... */
1977  ereport(ERROR,
1978  (errcode(ERRCODE_DATATYPE_MISMATCH),
1979  errmsg("could not determine row description for function returning record")));
1980  }
1981  else
1982  {
1983  /* crummy error message, but parser should have caught this */
1984  elog(ERROR, "function in FROM has unsupported return type");
1985  }
1986 
1987  return tupdesc;
1988 }
1989 
1990 /*
1991  * extract_variadic_args
1992  *
1993  * Extract a set of argument values, types and NULL markers for a given
1994  * input function which makes use of a VARIADIC input whose argument list
1995  * depends on the caller context. When doing a VARIADIC call, the caller
1996  * has provided one argument made of an array of values, so deconstruct the
1997  * array data before using it for the next processing. If no VARIADIC call
1998  * is used, just fill in the status data based on all the arguments given
1999  * by the caller.
2000  *
2001  * This function returns the number of arguments generated, or -1 in the
2002  * case of "VARIADIC NULL".
2003  */
2004 int
2005 extract_variadic_args(FunctionCallInfo fcinfo, int variadic_start,
2006  bool convert_unknown, Datum **args, Oid **types,
2007  bool **nulls)
2008 {
2009  bool variadic = get_fn_expr_variadic(fcinfo->flinfo);
2010  Datum *args_res;
2011  bool *nulls_res;
2012  Oid *types_res;
2013  int nargs,
2014  i;
2015 
2016  *args = NULL;
2017  *types = NULL;
2018  *nulls = NULL;
2019 
2020  if (variadic)
2021  {
2023  Oid element_type;
2024  bool typbyval;
2025  char typalign;
2026  int16 typlen;
2027 
2028  Assert(PG_NARGS() == variadic_start + 1);
2029 
2030  if (PG_ARGISNULL(variadic_start))
2031  return -1;
2032 
2033  array_in = PG_GETARG_ARRAYTYPE_P(variadic_start);
2034  element_type = ARR_ELEMTYPE(array_in);
2035 
2036  get_typlenbyvalalign(element_type,
2037  &typlen, &typbyval, &typalign);
2038  deconstruct_array(array_in, element_type, typlen, typbyval,
2039  typalign, &args_res, &nulls_res,
2040  &nargs);
2041 
2042  /* All the elements of the array have the same type */
2043  types_res = (Oid *) palloc0(nargs * sizeof(Oid));
2044  for (i = 0; i < nargs; i++)
2045  types_res[i] = element_type;
2046  }
2047  else
2048  {
2049  nargs = PG_NARGS() - variadic_start;
2050  Assert(nargs > 0);
2051  nulls_res = (bool *) palloc0(nargs * sizeof(bool));
2052  args_res = (Datum *) palloc0(nargs * sizeof(Datum));
2053  types_res = (Oid *) palloc0(nargs * sizeof(Oid));
2054 
2055  for (i = 0; i < nargs; i++)
2056  {
2057  nulls_res[i] = PG_ARGISNULL(i + variadic_start);
2058  types_res[i] = get_fn_expr_argtype(fcinfo->flinfo,
2059  i + variadic_start);
2060 
2061  /*
2062  * Turn a constant (more or less literal) value that's of unknown
2063  * type into text if required. Unknowns come in as a cstring
2064  * pointer. Note: for functions declared as taking type "any", the
2065  * parser will not do any type conversion on unknown-type literals
2066  * (that is, undecorated strings or NULLs).
2067  */
2068  if (convert_unknown &&
2069  types_res[i] == UNKNOWNOID &&
2070  get_fn_expr_arg_stable(fcinfo->flinfo, i + variadic_start))
2071  {
2072  types_res[i] = TEXTOID;
2073 
2074  if (PG_ARGISNULL(i + variadic_start))
2075  args_res[i] = (Datum) 0;
2076  else
2077  args_res[i] =
2078  CStringGetTextDatum(PG_GETARG_POINTER(i + variadic_start));
2079  }
2080  else
2081  {
2082  /* no conversion needed, just take the datum as given */
2083  args_res[i] = PG_GETARG_DATUM(i + variadic_start);
2084  }
2085 
2086  if (!OidIsValid(types_res[i]) ||
2087  (convert_unknown && types_res[i] == UNKNOWNOID))
2088  ereport(ERROR,
2089  (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
2090  errmsg("could not determine data type for argument %d",
2091  i + 1)));
2092  }
2093  }
2094 
2095  /* Fill in results */
2096  *args = args_res;
2097  *nulls = nulls_res;
2098  *types = types_res;
2099 
2100  return nargs;
2101 }
#define ARR_NDIM(a)
Definition: array.h:290
#define PG_GETARG_ARRAYTYPE_P(n)
Definition: array.h:263
#define ARR_DATA_PTR(a)
Definition: array.h:322
#define DatumGetArrayTypeP(X)
Definition: array.h:261
#define ARR_ELEMTYPE(a)
Definition: array.h:292
#define ARR_DIMS(a)
Definition: array.h:294
#define ARR_HASNULL(a)
Definition: array.h:291
void deconstruct_array(ArrayType *array, Oid elmtype, int elmlen, bool elmbyval, char elmalign, Datum **elemsp, bool **nullsp, int *nelemsp)
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void deconstruct_array_builtin(ArrayType *array, Oid elmtype, Datum **elemsp, bool **nullsp, int *nelemsp)
Definition: arrayfuncs.c:3697
Datum array_in(PG_FUNCTION_ARGS)
Definition: arrayfuncs.c:179
int16 AttrNumber
Definition: attnum.h:21
#define CStringGetTextDatum(s)
Definition: builtins.h:97
#define TextDatumGetCString(d)
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#define NameStr(name)
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signed short int16
Definition: c.h:481
signed int int32
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uint32 bits32
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#define OidIsValid(objectId)
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struct typedefs * types
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int errmsg(const char *fmt,...)
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#define ERROR
Definition: elog.h:39
#define elog(elevel,...)
Definition: elog.h:225
#define ereport(elevel,...)
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TupleDesc BlessTupleDesc(TupleDesc tupdesc)
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void UnregisterExprContextCallback(ExprContext *econtext, ExprContextCallbackFunction function, Datum arg)
Definition: execUtils.c:925
void RegisterExprContextCallback(ExprContext *econtext, ExprContextCallbackFunction function, Datum arg)
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@ SFRM_Materialize_Random
Definition: execnodes.h:321
@ SFRM_Materialize
Definition: execnodes.h:320
bool get_fn_expr_arg_stable(FmgrInfo *flinfo, int argnum)
Definition: fmgr.c:1975
bool get_fn_expr_variadic(FmgrInfo *flinfo)
Definition: fmgr.c:2044
Oid get_call_expr_argtype(Node *expr, int argnum)
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Oid get_fn_expr_argtype(FmgrInfo *flinfo, int argnum)
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#define DatumGetHeapTupleHeader(X)
Definition: fmgr.h:295
#define PG_GETARG_POINTER(n)
Definition: fmgr.h:276
#define PG_ARGISNULL(n)
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#define PG_GETARG_DATUM(n)
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#define PG_NARGS()
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#define PG_FUNCTION_ARGS
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Definition: format_type.c:343
static TypeFuncClass get_type_func_class(Oid typid, Oid *base_typeid)
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struct polymorphic_actuals polymorphic_actuals
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static TypeFuncClass internal_get_result_type(Oid funcid, Node *call_expr, ReturnSetInfo *rsinfo, Oid *resultTypeId, TupleDesc *resultTupleDesc)
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int get_func_trftypes(HeapTuple procTup, Oid **p_trftypes)
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TupleDesc build_function_result_tupdesc_t(HeapTuple procTuple)
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TupleDesc build_function_result_tupdesc_d(char prokind, Datum proallargtypes, Datum proargmodes, Datum proargnames)
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bool resolve_polymorphic_argtypes(int numargs, Oid *argtypes, char *argmodes, Node *call_expr)
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char * get_func_result_name(Oid functionId)
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Definition: funcapi.c:220
static void resolve_anyelement_from_others(polymorphic_actuals *actuals)
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int get_func_input_arg_names(Datum proargnames, Datum proargmodes, char ***arg_names)
Definition: funcapi.c:1522
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static bool resolve_polymorphic_tupdesc(TupleDesc tupdesc, oidvector *declared_args, Node *call_expr)
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TupleDesc RelationNameGetTupleDesc(const char *relname)
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TypeFuncClass get_call_result_type(FunctionCallInfo fcinfo, Oid *resultTypeId, TupleDesc *resultTupleDesc)
Definition: funcapi.c:276
int extract_variadic_args(FunctionCallInfo fcinfo, int variadic_start, bool convert_unknown, Datum **args, Oid **types, bool **nulls)
Definition: funcapi.c:2005
FuncCallContext * init_MultiFuncCall(PG_FUNCTION_ARGS)
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static void resolve_anyrange_from_others(polymorphic_actuals *actuals)
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static void shutdown_MultiFuncCall(Datum arg)
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TupleDesc get_expr_result_tupdesc(Node *expr, bool noError)
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TupleDesc TypeGetTupleDesc(Oid typeoid, List *colaliases)
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TypeFuncClass get_func_result_type(Oid functionId, Oid *resultTypeId, TupleDesc *resultTupleDesc)
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static void resolve_anyarray_from_others(polymorphic_actuals *actuals)
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TypeFuncClass get_expr_result_type(Node *expr, Oid *resultTypeId, TupleDesc *resultTupleDesc)
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FuncCallContext * per_MultiFuncCall(PG_FUNCTION_ARGS)
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TypeFuncClass
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@ TYPEFUNC_SCALAR
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@ TYPEFUNC_COMPOSITE
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@ TYPEFUNC_RECORD
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@ TYPEFUNC_COMPOSITE_DOMAIN
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@ TYPEFUNC_OTHER
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#define MAT_SRF_BLESS
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#define MAT_SRF_USE_EXPECTED_DESC
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#define HeapTupleIsValid(tuple)
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Oid get_range_subtype(Oid rangeOid)
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FormData_pg_attribute * Form_pg_attribute
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void * arg
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#define lfirst(lc)
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static int list_length(const List *l)
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#define NIL
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#define forboth(cell1, list1, cell2, list2)
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#define linitial(l)
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static void * list_nth(const List *list, int n)
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uintptr_t Datum
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static Datum ObjectIdGetDatum(Oid X)
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static Pointer DatumGetPointer(Datum X)
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#define InvalidOid
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unsigned int Oid
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List * stringToQualifiedNameList(const char *string, Node *escontext)
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Relation relation_openrv(const RangeVar *relation, LOCKMODE lockmode)
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void * fn_extra
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uint64 call_cntr
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AttInMetadata * attinmeta
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MemoryContext multi_call_memory_ctx
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TupleDesc tuple_desc
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Definition: pg_list.h:54
Definition: nodes.h:129
SetFunctionReturnMode returnMode
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ExprContext * econtext
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Tuplestorestate * setResult
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List * args
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int32 tdtypmod
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Oid tdtypeid
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Oid values[FLEXIBLE_ARRAY_MEMBER]
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HeapTuple SearchSysCache1(int cacheId, Datum key1)
Definition: syscache.c:221
Datum SysCacheGetAttr(int cacheId, HeapTuple tup, AttrNumber attributeNumber, bool *isNull)
Definition: syscache.c:600
Datum SysCacheGetAttrNotNull(int cacheId, HeapTuple tup, AttrNumber attributeNumber)
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TupleDesc CreateTupleDescCopy(TupleDesc tupdesc)
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void TupleDescInitEntryCollation(TupleDesc desc, AttrNumber attributeNumber, Oid collationid)
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void TupleDescInitEntry(TupleDesc desc, AttrNumber attributeNumber, const char *attributeName, Oid oidtypeid, int32 typmod, int attdim)
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#define TupleDescAttr(tupdesc, i)
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#define strVal(v)
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