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1 712 jeremybenn
/* Deal with interfaces.
2
   Copyright (C) 2000, 2001, 2002, 2004, 2005, 2006, 2007, 2008, 2009,
3
   2010, 2011, 2012
4
   Free Software Foundation, Inc.
5
   Contributed by Andy Vaught
6
 
7
This file is part of GCC.
8
 
9
GCC is free software; you can redistribute it and/or modify it under
10
the terms of the GNU General Public License as published by the Free
11
Software Foundation; either version 3, or (at your option) any later
12
version.
13
 
14
GCC is distributed in the hope that it will be useful, but WITHOUT ANY
15
WARRANTY; without even the implied warranty of MERCHANTABILITY or
16
FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
17
for more details.
18
 
19
You should have received a copy of the GNU General Public License
20
along with GCC; see the file COPYING3.  If not see
21
<http://www.gnu.org/licenses/>.  */
22
 
23
 
24
/* Deal with interfaces.  An explicit interface is represented as a
25
   singly linked list of formal argument structures attached to the
26
   relevant symbols.  For an implicit interface, the arguments don't
27
   point to symbols.  Explicit interfaces point to namespaces that
28
   contain the symbols within that interface.
29
 
30
   Implicit interfaces are linked together in a singly linked list
31
   along the next_if member of symbol nodes.  Since a particular
32
   symbol can only have a single explicit interface, the symbol cannot
33
   be part of multiple lists and a single next-member suffices.
34
 
35
   This is not the case for general classes, though.  An operator
36
   definition is independent of just about all other uses and has it's
37
   own head pointer.
38
 
39
   Nameless interfaces:
40
     Nameless interfaces create symbols with explicit interfaces within
41
     the current namespace.  They are otherwise unlinked.
42
 
43
   Generic interfaces:
44
     The generic name points to a linked list of symbols.  Each symbol
45
     has an explicit interface.  Each explicit interface has its own
46
     namespace containing the arguments.  Module procedures are symbols in
47
     which the interface is added later when the module procedure is parsed.
48
 
49
   User operators:
50
     User-defined operators are stored in a their own set of symtrees
51
     separate from regular symbols.  The symtrees point to gfc_user_op
52
     structures which in turn head up a list of relevant interfaces.
53
 
54
   Extended intrinsics and assignment:
55
     The head of these interface lists are stored in the containing namespace.
56
 
57
   Implicit interfaces:
58
     An implicit interface is represented as a singly linked list of
59
     formal argument list structures that don't point to any symbol
60
     nodes -- they just contain types.
61
 
62
 
63
   When a subprogram is defined, the program unit's name points to an
64
   interface as usual, but the link to the namespace is NULL and the
65
   formal argument list points to symbols within the same namespace as
66
   the program unit name.  */
67
 
68
#include "config.h"
69
#include "system.h"
70
#include "gfortran.h"
71
#include "match.h"
72
#include "arith.h"
73
 
74
/* The current_interface structure holds information about the
75
   interface currently being parsed.  This structure is saved and
76
   restored during recursive interfaces.  */
77
 
78
gfc_interface_info current_interface;
79
 
80
 
81
/* Free a singly linked list of gfc_interface structures.  */
82
 
83
void
84
gfc_free_interface (gfc_interface *intr)
85
{
86
  gfc_interface *next;
87
 
88
  for (; intr; intr = next)
89
    {
90
      next = intr->next;
91
      free (intr);
92
    }
93
}
94
 
95
 
96
/* Change the operators unary plus and minus into binary plus and
97
   minus respectively, leaving the rest unchanged.  */
98
 
99
static gfc_intrinsic_op
100
fold_unary_intrinsic (gfc_intrinsic_op op)
101
{
102
  switch (op)
103
    {
104
    case INTRINSIC_UPLUS:
105
      op = INTRINSIC_PLUS;
106
      break;
107
    case INTRINSIC_UMINUS:
108
      op = INTRINSIC_MINUS;
109
      break;
110
    default:
111
      break;
112
    }
113
 
114
  return op;
115
}
116
 
117
 
118
/* Match a generic specification.  Depending on which type of
119
   interface is found, the 'name' or 'op' pointers may be set.
120
   This subroutine doesn't return MATCH_NO.  */
121
 
122
match
123
gfc_match_generic_spec (interface_type *type,
124
                        char *name,
125
                        gfc_intrinsic_op *op)
126
{
127
  char buffer[GFC_MAX_SYMBOL_LEN + 1];
128
  match m;
129
  gfc_intrinsic_op i;
130
 
131
  if (gfc_match (" assignment ( = )") == MATCH_YES)
132
    {
133
      *type = INTERFACE_INTRINSIC_OP;
134
      *op = INTRINSIC_ASSIGN;
135
      return MATCH_YES;
136
    }
137
 
138
  if (gfc_match (" operator ( %o )", &i) == MATCH_YES)
139
    {                           /* Operator i/f */
140
      *type = INTERFACE_INTRINSIC_OP;
141
      *op = fold_unary_intrinsic (i);
142
      return MATCH_YES;
143
    }
144
 
145
  *op = INTRINSIC_NONE;
146
  if (gfc_match (" operator ( ") == MATCH_YES)
147
    {
148
      m = gfc_match_defined_op_name (buffer, 1);
149
      if (m == MATCH_NO)
150
        goto syntax;
151
      if (m != MATCH_YES)
152
        return MATCH_ERROR;
153
 
154
      m = gfc_match_char (')');
155
      if (m == MATCH_NO)
156
        goto syntax;
157
      if (m != MATCH_YES)
158
        return MATCH_ERROR;
159
 
160
      strcpy (name, buffer);
161
      *type = INTERFACE_USER_OP;
162
      return MATCH_YES;
163
    }
164
 
165
  if (gfc_match_name (buffer) == MATCH_YES)
166
    {
167
      strcpy (name, buffer);
168
      *type = INTERFACE_GENERIC;
169
      return MATCH_YES;
170
    }
171
 
172
  *type = INTERFACE_NAMELESS;
173
  return MATCH_YES;
174
 
175
syntax:
176
  gfc_error ("Syntax error in generic specification at %C");
177
  return MATCH_ERROR;
178
}
179
 
180
 
181
/* Match one of the five F95 forms of an interface statement.  The
182
   matcher for the abstract interface follows.  */
183
 
184
match
185
gfc_match_interface (void)
186
{
187
  char name[GFC_MAX_SYMBOL_LEN + 1];
188
  interface_type type;
189
  gfc_symbol *sym;
190
  gfc_intrinsic_op op;
191
  match m;
192
 
193
  m = gfc_match_space ();
194
 
195
  if (gfc_match_generic_spec (&type, name, &op) == MATCH_ERROR)
196
    return MATCH_ERROR;
197
 
198
  /* If we're not looking at the end of the statement now, or if this
199
     is not a nameless interface but we did not see a space, punt.  */
200
  if (gfc_match_eos () != MATCH_YES
201
      || (type != INTERFACE_NAMELESS && m != MATCH_YES))
202
    {
203
      gfc_error ("Syntax error: Trailing garbage in INTERFACE statement "
204
                 "at %C");
205
      return MATCH_ERROR;
206
    }
207
 
208
  current_interface.type = type;
209
 
210
  switch (type)
211
    {
212
    case INTERFACE_GENERIC:
213
      if (gfc_get_symbol (name, NULL, &sym))
214
        return MATCH_ERROR;
215
 
216
      if (!sym->attr.generic
217
          && gfc_add_generic (&sym->attr, sym->name, NULL) == FAILURE)
218
        return MATCH_ERROR;
219
 
220
      if (sym->attr.dummy)
221
        {
222
          gfc_error ("Dummy procedure '%s' at %C cannot have a "
223
                     "generic interface", sym->name);
224
          return MATCH_ERROR;
225
        }
226
 
227
      current_interface.sym = gfc_new_block = sym;
228
      break;
229
 
230
    case INTERFACE_USER_OP:
231
      current_interface.uop = gfc_get_uop (name);
232
      break;
233
 
234
    case INTERFACE_INTRINSIC_OP:
235
      current_interface.op = op;
236
      break;
237
 
238
    case INTERFACE_NAMELESS:
239
    case INTERFACE_ABSTRACT:
240
      break;
241
    }
242
 
243
  return MATCH_YES;
244
}
245
 
246
 
247
 
248
/* Match a F2003 abstract interface.  */
249
 
250
match
251
gfc_match_abstract_interface (void)
252
{
253
  match m;
254
 
255
  if (gfc_notify_std (GFC_STD_F2003, "Fortran 2003: ABSTRACT INTERFACE at %C")
256
                      == FAILURE)
257
    return MATCH_ERROR;
258
 
259
  m = gfc_match_eos ();
260
 
261
  if (m != MATCH_YES)
262
    {
263
      gfc_error ("Syntax error in ABSTRACT INTERFACE statement at %C");
264
      return MATCH_ERROR;
265
    }
266
 
267
  current_interface.type = INTERFACE_ABSTRACT;
268
 
269
  return m;
270
}
271
 
272
 
273
/* Match the different sort of generic-specs that can be present after
274
   the END INTERFACE itself.  */
275
 
276
match
277
gfc_match_end_interface (void)
278
{
279
  char name[GFC_MAX_SYMBOL_LEN + 1];
280
  interface_type type;
281
  gfc_intrinsic_op op;
282
  match m;
283
 
284
  m = gfc_match_space ();
285
 
286
  if (gfc_match_generic_spec (&type, name, &op) == MATCH_ERROR)
287
    return MATCH_ERROR;
288
 
289
  /* If we're not looking at the end of the statement now, or if this
290
     is not a nameless interface but we did not see a space, punt.  */
291
  if (gfc_match_eos () != MATCH_YES
292
      || (type != INTERFACE_NAMELESS && m != MATCH_YES))
293
    {
294
      gfc_error ("Syntax error: Trailing garbage in END INTERFACE "
295
                 "statement at %C");
296
      return MATCH_ERROR;
297
    }
298
 
299
  m = MATCH_YES;
300
 
301
  switch (current_interface.type)
302
    {
303
    case INTERFACE_NAMELESS:
304
    case INTERFACE_ABSTRACT:
305
      if (type != INTERFACE_NAMELESS)
306
        {
307
          gfc_error ("Expected a nameless interface at %C");
308
          m = MATCH_ERROR;
309
        }
310
 
311
      break;
312
 
313
    case INTERFACE_INTRINSIC_OP:
314
      if (type != current_interface.type || op != current_interface.op)
315
        {
316
 
317
          if (current_interface.op == INTRINSIC_ASSIGN)
318
            {
319
              m = MATCH_ERROR;
320
              gfc_error ("Expected 'END INTERFACE ASSIGNMENT (=)' at %C");
321
            }
322
          else
323
            {
324
              const char *s1, *s2;
325
              s1 = gfc_op2string (current_interface.op);
326
              s2 = gfc_op2string (op);
327
 
328
              /* The following if-statements are used to enforce C1202
329
                 from F2003.  */
330
              if ((strcmp(s1, "==") == 0 && strcmp(s2, ".eq.") == 0)
331
                  || (strcmp(s1, ".eq.") == 0 && strcmp(s2, "==") == 0))
332
                break;
333
              if ((strcmp(s1, "/=") == 0 && strcmp(s2, ".ne.") == 0)
334
                  || (strcmp(s1, ".ne.") == 0 && strcmp(s2, "/=") == 0))
335
                break;
336
              if ((strcmp(s1, "<=") == 0 && strcmp(s2, ".le.") == 0)
337
                  || (strcmp(s1, ".le.") == 0 && strcmp(s2, "<=") == 0))
338
                break;
339
              if ((strcmp(s1, "<") == 0 && strcmp(s2, ".lt.") == 0)
340
                  || (strcmp(s1, ".lt.") == 0 && strcmp(s2, "<") == 0))
341
                break;
342
              if ((strcmp(s1, ">=") == 0 && strcmp(s2, ".ge.") == 0)
343
                  || (strcmp(s1, ".ge.") == 0 && strcmp(s2, ">=") == 0))
344
                break;
345
              if ((strcmp(s1, ">") == 0 && strcmp(s2, ".gt.") == 0)
346
                  || (strcmp(s1, ".gt.") == 0 && strcmp(s2, ">") == 0))
347
                break;
348
 
349
              m = MATCH_ERROR;
350
              gfc_error ("Expecting 'END INTERFACE OPERATOR (%s)' at %C, "
351
                         "but got %s", s1, s2);
352
            }
353
 
354
        }
355
 
356
      break;
357
 
358
    case INTERFACE_USER_OP:
359
      /* Comparing the symbol node names is OK because only use-associated
360
         symbols can be renamed.  */
361
      if (type != current_interface.type
362
          || strcmp (current_interface.uop->name, name) != 0)
363
        {
364
          gfc_error ("Expecting 'END INTERFACE OPERATOR (.%s.)' at %C",
365
                     current_interface.uop->name);
366
          m = MATCH_ERROR;
367
        }
368
 
369
      break;
370
 
371
    case INTERFACE_GENERIC:
372
      if (type != current_interface.type
373
          || strcmp (current_interface.sym->name, name) != 0)
374
        {
375
          gfc_error ("Expecting 'END INTERFACE %s' at %C",
376
                     current_interface.sym->name);
377
          m = MATCH_ERROR;
378
        }
379
 
380
      break;
381
    }
382
 
383
  return m;
384
}
385
 
386
 
387
/* Compare two derived types using the criteria in 4.4.2 of the standard,
388
   recursing through gfc_compare_types for the components.  */
389
 
390
int
391
gfc_compare_derived_types (gfc_symbol *derived1, gfc_symbol *derived2)
392
{
393
  gfc_component *dt1, *dt2;
394
 
395
  if (derived1 == derived2)
396
    return 1;
397
 
398
  /* Special case for comparing derived types across namespaces.  If the
399
     true names and module names are the same and the module name is
400
     nonnull, then they are equal.  */
401
  if (derived1 != NULL && derived2 != NULL
402
      && strcmp (derived1->name, derived2->name) == 0
403
      && derived1->module != NULL && derived2->module != NULL
404
      && strcmp (derived1->module, derived2->module) == 0)
405
    return 1;
406
 
407
  /* Compare type via the rules of the standard.  Both types must have
408
     the SEQUENCE or BIND(C) attribute to be equal.  */
409
 
410
  if (strcmp (derived1->name, derived2->name))
411
    return 0;
412
 
413
  if (derived1->component_access == ACCESS_PRIVATE
414
      || derived2->component_access == ACCESS_PRIVATE)
415
    return 0;
416
 
417
  if (!(derived1->attr.sequence && derived2->attr.sequence)
418
      && !(derived1->attr.is_bind_c && derived2->attr.is_bind_c))
419
    return 0;
420
 
421
  dt1 = derived1->components;
422
  dt2 = derived2->components;
423
 
424
  /* Since subtypes of SEQUENCE types must be SEQUENCE types as well, a
425
     simple test can speed things up.  Otherwise, lots of things have to
426
     match.  */
427
  for (;;)
428
    {
429
      if (strcmp (dt1->name, dt2->name) != 0)
430
        return 0;
431
 
432
      if (dt1->attr.access != dt2->attr.access)
433
        return 0;
434
 
435
      if (dt1->attr.pointer != dt2->attr.pointer)
436
        return 0;
437
 
438
      if (dt1->attr.dimension != dt2->attr.dimension)
439
        return 0;
440
 
441
     if (dt1->attr.allocatable != dt2->attr.allocatable)
442
        return 0;
443
 
444
      if (dt1->attr.dimension && gfc_compare_array_spec (dt1->as, dt2->as) == 0)
445
        return 0;
446
 
447
      /* Make sure that link lists do not put this function into an
448
         endless recursive loop!  */
449
      if (!(dt1->ts.type == BT_DERIVED && derived1 == dt1->ts.u.derived)
450
            && !(dt1->ts.type == BT_DERIVED && derived1 == dt1->ts.u.derived)
451
            && gfc_compare_types (&dt1->ts, &dt2->ts) == 0)
452
        return 0;
453
 
454
      else if ((dt1->ts.type == BT_DERIVED && derived1 == dt1->ts.u.derived)
455
                && !(dt1->ts.type == BT_DERIVED && derived1 == dt1->ts.u.derived))
456
        return 0;
457
 
458
      else if (!(dt1->ts.type == BT_DERIVED && derived1 == dt1->ts.u.derived)
459
                && (dt1->ts.type == BT_DERIVED && derived1 == dt1->ts.u.derived))
460
        return 0;
461
 
462
      dt1 = dt1->next;
463
      dt2 = dt2->next;
464
 
465
      if (dt1 == NULL && dt2 == NULL)
466
        break;
467
      if (dt1 == NULL || dt2 == NULL)
468
        return 0;
469
    }
470
 
471
  return 1;
472
}
473
 
474
 
475
/* Compare two typespecs, recursively if necessary.  */
476
 
477
int
478
gfc_compare_types (gfc_typespec *ts1, gfc_typespec *ts2)
479
{
480
  /* See if one of the typespecs is a BT_VOID, which is what is being used
481
     to allow the funcs like c_f_pointer to accept any pointer type.
482
     TODO: Possibly should narrow this to just the one typespec coming in
483
     that is for the formal arg, but oh well.  */
484
  if (ts1->type == BT_VOID || ts2->type == BT_VOID)
485
    return 1;
486
 
487
  if (ts1->type != ts2->type
488
      && ((ts1->type != BT_DERIVED && ts1->type != BT_CLASS)
489
          || (ts2->type != BT_DERIVED && ts2->type != BT_CLASS)))
490
    return 0;
491
  if (ts1->type != BT_DERIVED && ts1->type != BT_CLASS)
492
    return (ts1->kind == ts2->kind);
493
 
494
  /* Compare derived types.  */
495
  if (gfc_type_compatible (ts1, ts2))
496
    return 1;
497
 
498
  return gfc_compare_derived_types (ts1->u.derived ,ts2->u.derived);
499
}
500
 
501
 
502
/* Given two symbols that are formal arguments, compare their ranks
503
   and types.  Returns nonzero if they have the same rank and type,
504
   zero otherwise.  */
505
 
506
static int
507
compare_type_rank (gfc_symbol *s1, gfc_symbol *s2)
508
{
509
  int r1, r2;
510
 
511
  r1 = (s1->as != NULL) ? s1->as->rank : 0;
512
  r2 = (s2->as != NULL) ? s2->as->rank : 0;
513
 
514
  if (r1 != r2)
515
    return 0;                    /* Ranks differ.  */
516
 
517
  return gfc_compare_types (&s1->ts, &s2->ts);
518
}
519
 
520
 
521
/* Given two symbols that are formal arguments, compare their types
522
   and rank and their formal interfaces if they are both dummy
523
   procedures.  Returns nonzero if the same, zero if different.  */
524
 
525
static int
526
compare_type_rank_if (gfc_symbol *s1, gfc_symbol *s2)
527
{
528
  if (s1 == NULL || s2 == NULL)
529
    return s1 == s2 ? 1 : 0;
530
 
531
  if (s1 == s2)
532
    return 1;
533
 
534
  if (s1->attr.flavor != FL_PROCEDURE && s2->attr.flavor != FL_PROCEDURE)
535
    return compare_type_rank (s1, s2);
536
 
537
  if (s1->attr.flavor != FL_PROCEDURE || s2->attr.flavor != FL_PROCEDURE)
538
    return 0;
539
 
540
  /* At this point, both symbols are procedures.  It can happen that
541
     external procedures are compared, where one is identified by usage
542
     to be a function or subroutine but the other is not.  Check TKR
543
     nonetheless for these cases.  */
544
  if (s1->attr.function == 0 && s1->attr.subroutine == 0)
545
    return s1->attr.external == 1 ? compare_type_rank (s1, s2) : 0;
546
 
547
  if (s2->attr.function == 0 && s2->attr.subroutine == 0)
548
    return s2->attr.external == 1 ? compare_type_rank (s1, s2) : 0;
549
 
550
  /* Now the type of procedure has been identified.  */
551
  if (s1->attr.function != s2->attr.function
552
      || s1->attr.subroutine != s2->attr.subroutine)
553
    return 0;
554
 
555
  if (s1->attr.function && compare_type_rank (s1, s2) == 0)
556
    return 0;
557
 
558
  /* Originally, gfortran recursed here to check the interfaces of passed
559
     procedures.  This is explicitly not required by the standard.  */
560
  return 1;
561
}
562
 
563
 
564
/* Given a formal argument list and a keyword name, search the list
565
   for that keyword.  Returns the correct symbol node if found, NULL
566
   if not found.  */
567
 
568
static gfc_symbol *
569
find_keyword_arg (const char *name, gfc_formal_arglist *f)
570
{
571
  for (; f; f = f->next)
572
    if (strcmp (f->sym->name, name) == 0)
573
      return f->sym;
574
 
575
  return NULL;
576
}
577
 
578
 
579
/******** Interface checking subroutines **********/
580
 
581
 
582
/* Given an operator interface and the operator, make sure that all
583
   interfaces for that operator are legal.  */
584
 
585
bool
586
gfc_check_operator_interface (gfc_symbol *sym, gfc_intrinsic_op op,
587
                              locus opwhere)
588
{
589
  gfc_formal_arglist *formal;
590
  sym_intent i1, i2;
591
  bt t1, t2;
592
  int args, r1, r2, k1, k2;
593
 
594
  gcc_assert (sym);
595
 
596
  args = 0;
597
  t1 = t2 = BT_UNKNOWN;
598
  i1 = i2 = INTENT_UNKNOWN;
599
  r1 = r2 = -1;
600
  k1 = k2 = -1;
601
 
602
  for (formal = sym->formal; formal; formal = formal->next)
603
    {
604
      gfc_symbol *fsym = formal->sym;
605
      if (fsym == NULL)
606
        {
607
          gfc_error ("Alternate return cannot appear in operator "
608
                     "interface at %L", &sym->declared_at);
609
          return false;
610
        }
611
      if (args == 0)
612
        {
613
          t1 = fsym->ts.type;
614
          i1 = fsym->attr.intent;
615
          r1 = (fsym->as != NULL) ? fsym->as->rank : 0;
616
          k1 = fsym->ts.kind;
617
        }
618
      if (args == 1)
619
        {
620
          t2 = fsym->ts.type;
621
          i2 = fsym->attr.intent;
622
          r2 = (fsym->as != NULL) ? fsym->as->rank : 0;
623
          k2 = fsym->ts.kind;
624
        }
625
      args++;
626
    }
627
 
628
  /* Only +, - and .not. can be unary operators.
629
     .not. cannot be a binary operator.  */
630
  if (args == 0 || args > 2 || (args == 1 && op != INTRINSIC_PLUS
631
                                && op != INTRINSIC_MINUS
632
                                && op != INTRINSIC_NOT)
633
      || (args == 2 && op == INTRINSIC_NOT))
634
    {
635
      gfc_error ("Operator interface at %L has the wrong number of arguments",
636
                 &sym->declared_at);
637
      return false;
638
    }
639
 
640
  /* Check that intrinsics are mapped to functions, except
641
     INTRINSIC_ASSIGN which should map to a subroutine.  */
642
  if (op == INTRINSIC_ASSIGN)
643
    {
644
      if (!sym->attr.subroutine)
645
        {
646
          gfc_error ("Assignment operator interface at %L must be "
647
                     "a SUBROUTINE", &sym->declared_at);
648
          return false;
649
        }
650
      if (args != 2)
651
        {
652
          gfc_error ("Assignment operator interface at %L must have "
653
                     "two arguments", &sym->declared_at);
654
          return false;
655
        }
656
 
657
      /* Allowed are (per F2003, 12.3.2.1.2 Defined assignments):
658
         - First argument an array with different rank than second,
659
         - First argument is a scalar and second an array,
660
         - Types and kinds do not conform, or
661
         - First argument is of derived type.  */
662
      if (sym->formal->sym->ts.type != BT_DERIVED
663
          && sym->formal->sym->ts.type != BT_CLASS
664
          && (r2 == 0 || r1 == r2)
665
          && (sym->formal->sym->ts.type == sym->formal->next->sym->ts.type
666
              || (gfc_numeric_ts (&sym->formal->sym->ts)
667
                  && gfc_numeric_ts (&sym->formal->next->sym->ts))))
668
        {
669
          gfc_error ("Assignment operator interface at %L must not redefine "
670
                     "an INTRINSIC type assignment", &sym->declared_at);
671
          return false;
672
        }
673
    }
674
  else
675
    {
676
      if (!sym->attr.function)
677
        {
678
          gfc_error ("Intrinsic operator interface at %L must be a FUNCTION",
679
                     &sym->declared_at);
680
          return false;
681
        }
682
    }
683
 
684
  /* Check intents on operator interfaces.  */
685
  if (op == INTRINSIC_ASSIGN)
686
    {
687
      if (i1 != INTENT_OUT && i1 != INTENT_INOUT)
688
        {
689
          gfc_error ("First argument of defined assignment at %L must be "
690
                     "INTENT(OUT) or INTENT(INOUT)", &sym->declared_at);
691
          return false;
692
        }
693
 
694
      if (i2 != INTENT_IN)
695
        {
696
          gfc_error ("Second argument of defined assignment at %L must be "
697
                     "INTENT(IN)", &sym->declared_at);
698
          return false;
699
        }
700
    }
701
  else
702
    {
703
      if (i1 != INTENT_IN)
704
        {
705
          gfc_error ("First argument of operator interface at %L must be "
706
                     "INTENT(IN)", &sym->declared_at);
707
          return false;
708
        }
709
 
710
      if (args == 2 && i2 != INTENT_IN)
711
        {
712
          gfc_error ("Second argument of operator interface at %L must be "
713
                     "INTENT(IN)", &sym->declared_at);
714
          return false;
715
        }
716
    }
717
 
718
  /* From now on, all we have to do is check that the operator definition
719
     doesn't conflict with an intrinsic operator. The rules for this
720
     game are defined in 7.1.2 and 7.1.3 of both F95 and F2003 standards,
721
     as well as 12.3.2.1.1 of Fortran 2003:
722
 
723
     "If the operator is an intrinsic-operator (R310), the number of
724
     function arguments shall be consistent with the intrinsic uses of
725
     that operator, and the types, kind type parameters, or ranks of the
726
     dummy arguments shall differ from those required for the intrinsic
727
     operation (7.1.2)."  */
728
 
729
#define IS_NUMERIC_TYPE(t) \
730
  ((t) == BT_INTEGER || (t) == BT_REAL || (t) == BT_COMPLEX)
731
 
732
  /* Unary ops are easy, do them first.  */
733
  if (op == INTRINSIC_NOT)
734
    {
735
      if (t1 == BT_LOGICAL)
736
        goto bad_repl;
737
      else
738
        return true;
739
    }
740
 
741
  if (args == 1 && (op == INTRINSIC_PLUS || op == INTRINSIC_MINUS))
742
    {
743
      if (IS_NUMERIC_TYPE (t1))
744
        goto bad_repl;
745
      else
746
        return true;
747
    }
748
 
749
  /* Character intrinsic operators have same character kind, thus
750
     operator definitions with operands of different character kinds
751
     are always safe.  */
752
  if (t1 == BT_CHARACTER && t2 == BT_CHARACTER && k1 != k2)
753
    return true;
754
 
755
  /* Intrinsic operators always perform on arguments of same rank,
756
     so different ranks is also always safe.  (rank == 0) is an exception
757
     to that, because all intrinsic operators are elemental.  */
758
  if (r1 != r2 && r1 != 0 && r2 != 0)
759
    return true;
760
 
761
  switch (op)
762
  {
763
    case INTRINSIC_EQ:
764
    case INTRINSIC_EQ_OS:
765
    case INTRINSIC_NE:
766
    case INTRINSIC_NE_OS:
767
      if (t1 == BT_CHARACTER && t2 == BT_CHARACTER)
768
        goto bad_repl;
769
      /* Fall through.  */
770
 
771
    case INTRINSIC_PLUS:
772
    case INTRINSIC_MINUS:
773
    case INTRINSIC_TIMES:
774
    case INTRINSIC_DIVIDE:
775
    case INTRINSIC_POWER:
776
      if (IS_NUMERIC_TYPE (t1) && IS_NUMERIC_TYPE (t2))
777
        goto bad_repl;
778
      break;
779
 
780
    case INTRINSIC_GT:
781
    case INTRINSIC_GT_OS:
782
    case INTRINSIC_GE:
783
    case INTRINSIC_GE_OS:
784
    case INTRINSIC_LT:
785
    case INTRINSIC_LT_OS:
786
    case INTRINSIC_LE:
787
    case INTRINSIC_LE_OS:
788
      if (t1 == BT_CHARACTER && t2 == BT_CHARACTER)
789
        goto bad_repl;
790
      if ((t1 == BT_INTEGER || t1 == BT_REAL)
791
          && (t2 == BT_INTEGER || t2 == BT_REAL))
792
        goto bad_repl;
793
      break;
794
 
795
    case INTRINSIC_CONCAT:
796
      if (t1 == BT_CHARACTER && t2 == BT_CHARACTER)
797
        goto bad_repl;
798
      break;
799
 
800
    case INTRINSIC_AND:
801
    case INTRINSIC_OR:
802
    case INTRINSIC_EQV:
803
    case INTRINSIC_NEQV:
804
      if (t1 == BT_LOGICAL && t2 == BT_LOGICAL)
805
        goto bad_repl;
806
      break;
807
 
808
    default:
809
      break;
810
  }
811
 
812
  return true;
813
 
814
#undef IS_NUMERIC_TYPE
815
 
816
bad_repl:
817
  gfc_error ("Operator interface at %L conflicts with intrinsic interface",
818
             &opwhere);
819
  return false;
820
}
821
 
822
 
823
/* Given a pair of formal argument lists, we see if the two lists can
824
   be distinguished by counting the number of nonoptional arguments of
825
   a given type/rank in f1 and seeing if there are less then that
826
   number of those arguments in f2 (including optional arguments).
827
   Since this test is asymmetric, it has to be called twice to make it
828
   symmetric.  Returns nonzero if the argument lists are incompatible
829
   by this test.  This subroutine implements rule 1 of section
830
   14.1.2.3 in the Fortran 95 standard.  */
831
 
832
static int
833
count_types_test (gfc_formal_arglist *f1, gfc_formal_arglist *f2)
834
{
835
  int rc, ac1, ac2, i, j, k, n1;
836
  gfc_formal_arglist *f;
837
 
838
  typedef struct
839
  {
840
    int flag;
841
    gfc_symbol *sym;
842
  }
843
  arginfo;
844
 
845
  arginfo *arg;
846
 
847
  n1 = 0;
848
 
849
  for (f = f1; f; f = f->next)
850
    n1++;
851
 
852
  /* Build an array of integers that gives the same integer to
853
     arguments of the same type/rank.  */
854
  arg = XCNEWVEC (arginfo, n1);
855
 
856
  f = f1;
857
  for (i = 0; i < n1; i++, f = f->next)
858
    {
859
      arg[i].flag = -1;
860
      arg[i].sym = f->sym;
861
    }
862
 
863
  k = 0;
864
 
865
  for (i = 0; i < n1; i++)
866
    {
867
      if (arg[i].flag != -1)
868
        continue;
869
 
870
      if (arg[i].sym && arg[i].sym->attr.optional)
871
        continue;               /* Skip optional arguments.  */
872
 
873
      arg[i].flag = k;
874
 
875
      /* Find other nonoptional arguments of the same type/rank.  */
876
      for (j = i + 1; j < n1; j++)
877
        if ((arg[j].sym == NULL || !arg[j].sym->attr.optional)
878
            && (compare_type_rank_if (arg[i].sym, arg[j].sym)
879
                || compare_type_rank_if (arg[j].sym, arg[i].sym)))
880
          arg[j].flag = k;
881
 
882
      k++;
883
    }
884
 
885
  /* Now loop over each distinct type found in f1.  */
886
  k = 0;
887
  rc = 0;
888
 
889
  for (i = 0; i < n1; i++)
890
    {
891
      if (arg[i].flag != k)
892
        continue;
893
 
894
      ac1 = 1;
895
      for (j = i + 1; j < n1; j++)
896
        if (arg[j].flag == k)
897
          ac1++;
898
 
899
      /* Count the number of arguments in f2 with that type, including
900
         those that are optional.  */
901
      ac2 = 0;
902
 
903
      for (f = f2; f; f = f->next)
904
        if (compare_type_rank_if (arg[i].sym, f->sym)
905
            || compare_type_rank_if (f->sym, arg[i].sym))
906
          ac2++;
907
 
908
      if (ac1 > ac2)
909
        {
910
          rc = 1;
911
          break;
912
        }
913
 
914
      k++;
915
    }
916
 
917
  free (arg);
918
 
919
  return rc;
920
}
921
 
922
 
923
/* Perform the correspondence test in rule 2 of section 14.1.2.3.
924
   Returns zero if no argument is found that satisfies rule 2, nonzero
925
   otherwise.
926
 
927
   This test is also not symmetric in f1 and f2 and must be called
928
   twice.  This test finds problems caused by sorting the actual
929
   argument list with keywords.  For example:
930
 
931
   INTERFACE FOO
932
       SUBROUTINE F1(A, B)
933
           INTEGER :: A ; REAL :: B
934
       END SUBROUTINE F1
935
 
936
       SUBROUTINE F2(B, A)
937
           INTEGER :: A ; REAL :: B
938
       END SUBROUTINE F1
939
   END INTERFACE FOO
940
 
941
   At this point, 'CALL FOO(A=1, B=1.0)' is ambiguous.  */
942
 
943
static int
944
generic_correspondence (gfc_formal_arglist *f1, gfc_formal_arglist *f2)
945
{
946
  gfc_formal_arglist *f2_save, *g;
947
  gfc_symbol *sym;
948
 
949
  f2_save = f2;
950
 
951
  while (f1)
952
    {
953
      if (f1->sym->attr.optional)
954
        goto next;
955
 
956
      if (f2 != NULL && (compare_type_rank (f1->sym, f2->sym)
957
                         || compare_type_rank (f2->sym, f1->sym)))
958
        goto next;
959
 
960
      /* Now search for a disambiguating keyword argument starting at
961
         the current non-match.  */
962
      for (g = f1; g; g = g->next)
963
        {
964
          if (g->sym->attr.optional)
965
            continue;
966
 
967
          sym = find_keyword_arg (g->sym->name, f2_save);
968
          if (sym == NULL || !compare_type_rank (g->sym, sym))
969
            return 1;
970
        }
971
 
972
    next:
973
      f1 = f1->next;
974
      if (f2 != NULL)
975
        f2 = f2->next;
976
    }
977
 
978
  return 0;
979
}
980
 
981
 
982
/* Check if the characteristics of two dummy arguments match,
983
   cf. F08:12.3.2.  */
984
 
985
static gfc_try
986
check_dummy_characteristics (gfc_symbol *s1, gfc_symbol *s2,
987
                             bool type_must_agree, char *errmsg, int err_len)
988
{
989
  /* Check type and rank.  */
990
  if (type_must_agree && !compare_type_rank (s2, s1))
991
    {
992
      if (errmsg != NULL)
993
        snprintf (errmsg, err_len, "Type/rank mismatch in argument '%s'",
994
                  s1->name);
995
      return FAILURE;
996
    }
997
 
998
  /* Check INTENT.  */
999
  if (s1->attr.intent != s2->attr.intent)
1000
    {
1001
      snprintf (errmsg, err_len, "INTENT mismatch in argument '%s'",
1002
                s1->name);
1003
      return FAILURE;
1004
    }
1005
 
1006
  /* Check OPTIONAL attribute.  */
1007
  if (s1->attr.optional != s2->attr.optional)
1008
    {
1009
      snprintf (errmsg, err_len, "OPTIONAL mismatch in argument '%s'",
1010
                s1->name);
1011
      return FAILURE;
1012
    }
1013
 
1014
  /* Check ALLOCATABLE attribute.  */
1015
  if (s1->attr.allocatable != s2->attr.allocatable)
1016
    {
1017
      snprintf (errmsg, err_len, "ALLOCATABLE mismatch in argument '%s'",
1018
                s1->name);
1019
      return FAILURE;
1020
    }
1021
 
1022
  /* Check POINTER attribute.  */
1023
  if (s1->attr.pointer != s2->attr.pointer)
1024
    {
1025
      snprintf (errmsg, err_len, "POINTER mismatch in argument '%s'",
1026
                s1->name);
1027
      return FAILURE;
1028
    }
1029
 
1030
  /* Check TARGET attribute.  */
1031
  if (s1->attr.target != s2->attr.target)
1032
    {
1033
      snprintf (errmsg, err_len, "TARGET mismatch in argument '%s'",
1034
                s1->name);
1035
      return FAILURE;
1036
    }
1037
 
1038
  /* FIXME: Do more comprehensive testing of attributes, like e.g.
1039
            ASYNCHRONOUS, CONTIGUOUS, VALUE, VOLATILE, etc.  */
1040
 
1041
  /* Check string length.  */
1042
  if (s1->ts.type == BT_CHARACTER
1043
      && s1->ts.u.cl && s1->ts.u.cl->length
1044
      && s2->ts.u.cl && s2->ts.u.cl->length)
1045
    {
1046
      int compval = gfc_dep_compare_expr (s1->ts.u.cl->length,
1047
                                          s2->ts.u.cl->length);
1048
      switch (compval)
1049
      {
1050
        case -1:
1051
        case  1:
1052
        case -3:
1053
          snprintf (errmsg, err_len, "Character length mismatch "
1054
                    "in argument '%s'", s1->name);
1055
          return FAILURE;
1056
 
1057
        case -2:
1058
          /* FIXME: Implement a warning for this case.
1059
          gfc_warning ("Possible character length mismatch in argument '%s'",
1060
                       s1->name);*/
1061
          break;
1062
 
1063
        case 0:
1064
          break;
1065
 
1066
        default:
1067
          gfc_internal_error ("check_dummy_characteristics: Unexpected result "
1068
                              "%i of gfc_dep_compare_expr", compval);
1069
          break;
1070
      }
1071
    }
1072
 
1073
  /* Check array shape.  */
1074
  if (s1->as && s2->as)
1075
    {
1076
      int i, compval;
1077
      gfc_expr *shape1, *shape2;
1078
 
1079
      if (s1->as->type != s2->as->type)
1080
        {
1081
          snprintf (errmsg, err_len, "Shape mismatch in argument '%s'",
1082
                    s1->name);
1083
          return FAILURE;
1084
        }
1085
 
1086
      if (s1->as->type == AS_EXPLICIT)
1087
        for (i = 0; i < s1->as->rank + s1->as->corank; i++)
1088
          {
1089
            shape1 = gfc_subtract (gfc_copy_expr (s1->as->upper[i]),
1090
                                  gfc_copy_expr (s1->as->lower[i]));
1091
            shape2 = gfc_subtract (gfc_copy_expr (s2->as->upper[i]),
1092
                                  gfc_copy_expr (s2->as->lower[i]));
1093
            compval = gfc_dep_compare_expr (shape1, shape2);
1094
            gfc_free_expr (shape1);
1095
            gfc_free_expr (shape2);
1096
            switch (compval)
1097
            {
1098
              case -1:
1099
              case  1:
1100
              case -3:
1101
                snprintf (errmsg, err_len, "Shape mismatch in dimension %i of "
1102
                          "argument '%s'", i + 1, s1->name);
1103
                return FAILURE;
1104
 
1105
              case -2:
1106
                /* FIXME: Implement a warning for this case.
1107
                gfc_warning ("Possible shape mismatch in argument '%s'",
1108
                            s1->name);*/
1109
                break;
1110
 
1111
              case 0:
1112
                break;
1113
 
1114
              default:
1115
                gfc_internal_error ("check_dummy_characteristics: Unexpected "
1116
                                    "result %i of gfc_dep_compare_expr",
1117
                                    compval);
1118
                break;
1119
            }
1120
          }
1121
    }
1122
 
1123
  return SUCCESS;
1124
}
1125
 
1126
 
1127
/* 'Compare' two formal interfaces associated with a pair of symbols.
1128
   We return nonzero if there exists an actual argument list that
1129
   would be ambiguous between the two interfaces, zero otherwise.
1130
   'strict_flag' specifies whether all the characteristics are
1131
   required to match, which is not the case for ambiguity checks.*/
1132
 
1133
int
1134
gfc_compare_interfaces (gfc_symbol *s1, gfc_symbol *s2, const char *name2,
1135
                        int generic_flag, int strict_flag,
1136
                        char *errmsg, int err_len)
1137
{
1138
  gfc_formal_arglist *f1, *f2;
1139
 
1140
  gcc_assert (name2 != NULL);
1141
 
1142
  if (s1->attr.function && (s2->attr.subroutine
1143
      || (!s2->attr.function && s2->ts.type == BT_UNKNOWN
1144
          && gfc_get_default_type (name2, s2->ns)->type == BT_UNKNOWN)))
1145
    {
1146
      if (errmsg != NULL)
1147
        snprintf (errmsg, err_len, "'%s' is not a function", name2);
1148
      return 0;
1149
    }
1150
 
1151
  if (s1->attr.subroutine && s2->attr.function)
1152
    {
1153
      if (errmsg != NULL)
1154
        snprintf (errmsg, err_len, "'%s' is not a subroutine", name2);
1155
      return 0;
1156
    }
1157
 
1158
  /* Do strict checks on all characteristics
1159
     (for dummy procedures and procedure pointer assignments).  */
1160
  if (!generic_flag && strict_flag)
1161
    {
1162
      if (s1->attr.function && s2->attr.function)
1163
        {
1164
          /* If both are functions, check result type.  */
1165
          if (s1->ts.type == BT_UNKNOWN)
1166
            return 1;
1167
          if (!compare_type_rank (s1,s2))
1168
            {
1169
              if (errmsg != NULL)
1170
                snprintf (errmsg, err_len, "Type/rank mismatch in return value "
1171
                          "of '%s'", name2);
1172
              return 0;
1173
            }
1174
 
1175
          /* FIXME: Check array bounds and string length of result.  */
1176
        }
1177
 
1178
      if (s1->attr.pure && !s2->attr.pure)
1179
        {
1180
          snprintf (errmsg, err_len, "Mismatch in PURE attribute");
1181
          return 0;
1182
        }
1183
      if (s1->attr.elemental && !s2->attr.elemental)
1184
        {
1185
          snprintf (errmsg, err_len, "Mismatch in ELEMENTAL attribute");
1186
          return 0;
1187
        }
1188
    }
1189
 
1190
  if (s1->attr.if_source == IFSRC_UNKNOWN
1191
      || s2->attr.if_source == IFSRC_UNKNOWN)
1192
    return 1;
1193
 
1194
  f1 = s1->formal;
1195
  f2 = s2->formal;
1196
 
1197
  if (f1 == NULL && f2 == NULL)
1198
    return 1;                   /* Special case: No arguments.  */
1199
 
1200
  if (generic_flag)
1201
    {
1202
      if (count_types_test (f1, f2) || count_types_test (f2, f1))
1203
        return 0;
1204
      if (generic_correspondence (f1, f2) || generic_correspondence (f2, f1))
1205
        return 0;
1206
    }
1207
  else
1208
    /* Perform the abbreviated correspondence test for operators (the
1209
       arguments cannot be optional and are always ordered correctly).
1210
       This is also done when comparing interfaces for dummy procedures and in
1211
       procedure pointer assignments.  */
1212
 
1213
    for (;;)
1214
      {
1215
        /* Check existence.  */
1216
        if (f1 == NULL && f2 == NULL)
1217
          break;
1218
        if (f1 == NULL || f2 == NULL)
1219
          {
1220
            if (errmsg != NULL)
1221
              snprintf (errmsg, err_len, "'%s' has the wrong number of "
1222
                        "arguments", name2);
1223
            return 0;
1224
          }
1225
 
1226
        if (strict_flag)
1227
          {
1228
            /* Check all characteristics.  */
1229
            if (check_dummy_characteristics (f1->sym, f2->sym,
1230
                                             true, errmsg, err_len) == FAILURE)
1231
              return 0;
1232
          }
1233
        else if (!compare_type_rank (f2->sym, f1->sym))
1234
          {
1235
            /* Only check type and rank.  */
1236
            if (errmsg != NULL)
1237
              snprintf (errmsg, err_len, "Type/rank mismatch in argument '%s'",
1238
                        f1->sym->name);
1239
            return 0;
1240
          }
1241
 
1242
        f1 = f1->next;
1243
        f2 = f2->next;
1244
      }
1245
 
1246
  return 1;
1247
}
1248
 
1249
 
1250
/* Given a pointer to an interface pointer, remove duplicate
1251
   interfaces and make sure that all symbols are either functions
1252
   or subroutines, and all of the same kind.  Returns nonzero if
1253
   something goes wrong.  */
1254
 
1255
static int
1256
check_interface0 (gfc_interface *p, const char *interface_name)
1257
{
1258
  gfc_interface *psave, *q, *qlast;
1259
 
1260
  psave = p;
1261
  for (; p; p = p->next)
1262
    {
1263
      /* Make sure all symbols in the interface have been defined as
1264
         functions or subroutines.  */
1265
      if (((!p->sym->attr.function && !p->sym->attr.subroutine)
1266
           || !p->sym->attr.if_source)
1267
          && p->sym->attr.flavor != FL_DERIVED)
1268
        {
1269
          if (p->sym->attr.external)
1270
            gfc_error ("Procedure '%s' in %s at %L has no explicit interface",
1271
                       p->sym->name, interface_name, &p->sym->declared_at);
1272
          else
1273
            gfc_error ("Procedure '%s' in %s at %L is neither function nor "
1274
                       "subroutine", p->sym->name, interface_name,
1275
                      &p->sym->declared_at);
1276
          return 1;
1277
        }
1278
 
1279
      /* Verify that procedures are either all SUBROUTINEs or all FUNCTIONs.  */
1280
      if ((psave->sym->attr.function && !p->sym->attr.function
1281
           && p->sym->attr.flavor != FL_DERIVED)
1282
          || (psave->sym->attr.subroutine && !p->sym->attr.subroutine))
1283
        {
1284
          if (p->sym->attr.flavor != FL_DERIVED)
1285
            gfc_error ("In %s at %L procedures must be either all SUBROUTINEs"
1286
                       " or all FUNCTIONs", interface_name,
1287
                       &p->sym->declared_at);
1288
          else
1289
            gfc_error ("In %s at %L procedures must be all FUNCTIONs as the "
1290
                       "generic name is also the name of a derived type",
1291
                       interface_name, &p->sym->declared_at);
1292
          return 1;
1293
        }
1294
 
1295
      /* F2003, C1207. F2008, C1207.  */
1296
      if (p->sym->attr.proc == PROC_INTERNAL
1297
          && gfc_notify_std (GFC_STD_F2008, "Fortran 2008: Internal procedure "
1298
                             "'%s' in %s at %L", p->sym->name, interface_name,
1299
                             &p->sym->declared_at) == FAILURE)
1300
        return 1;
1301
    }
1302
  p = psave;
1303
 
1304
  /* Remove duplicate interfaces in this interface list.  */
1305
  for (; p; p = p->next)
1306
    {
1307
      qlast = p;
1308
 
1309
      for (q = p->next; q;)
1310
        {
1311
          if (p->sym != q->sym)
1312
            {
1313
              qlast = q;
1314
              q = q->next;
1315
            }
1316
          else
1317
            {
1318
              /* Duplicate interface.  */
1319
              qlast->next = q->next;
1320
              free (q);
1321
              q = qlast->next;
1322
            }
1323
        }
1324
    }
1325
 
1326
  return 0;
1327
}
1328
 
1329
 
1330
/* Check lists of interfaces to make sure that no two interfaces are
1331
   ambiguous.  Duplicate interfaces (from the same symbol) are OK here.  */
1332
 
1333
static int
1334
check_interface1 (gfc_interface *p, gfc_interface *q0,
1335
                  int generic_flag, const char *interface_name,
1336
                  bool referenced)
1337
{
1338
  gfc_interface *q;
1339
  for (; p; p = p->next)
1340
    for (q = q0; q; q = q->next)
1341
      {
1342
        if (p->sym == q->sym)
1343
          continue;             /* Duplicates OK here.  */
1344
 
1345
        if (p->sym->name == q->sym->name && p->sym->module == q->sym->module)
1346
          continue;
1347
 
1348
        if (p->sym->attr.flavor != FL_DERIVED
1349
            && q->sym->attr.flavor != FL_DERIVED
1350
            && gfc_compare_interfaces (p->sym, q->sym, q->sym->name,
1351
                                       generic_flag, 0, NULL, 0))
1352
          {
1353
            if (referenced)
1354
              gfc_error ("Ambiguous interfaces '%s' and '%s' in %s at %L",
1355
                         p->sym->name, q->sym->name, interface_name,
1356
                         &p->where);
1357
            else if (!p->sym->attr.use_assoc && q->sym->attr.use_assoc)
1358
              gfc_warning ("Ambiguous interfaces '%s' and '%s' in %s at %L",
1359
                           p->sym->name, q->sym->name, interface_name,
1360
                           &p->where);
1361
            else
1362
              gfc_warning ("Although not referenced, '%s' has ambiguous "
1363
                           "interfaces at %L", interface_name, &p->where);
1364
            return 1;
1365
          }
1366
      }
1367
  return 0;
1368
}
1369
 
1370
 
1371
/* Check the generic and operator interfaces of symbols to make sure
1372
   that none of the interfaces conflict.  The check has to be done
1373
   after all of the symbols are actually loaded.  */
1374
 
1375
static void
1376
check_sym_interfaces (gfc_symbol *sym)
1377
{
1378
  char interface_name[100];
1379
  gfc_interface *p;
1380
 
1381
  if (sym->ns != gfc_current_ns)
1382
    return;
1383
 
1384
  if (sym->generic != NULL)
1385
    {
1386
      sprintf (interface_name, "generic interface '%s'", sym->name);
1387
      if (check_interface0 (sym->generic, interface_name))
1388
        return;
1389
 
1390
      for (p = sym->generic; p; p = p->next)
1391
        {
1392
          if (p->sym->attr.mod_proc
1393
              && (p->sym->attr.if_source != IFSRC_DECL
1394
                  || p->sym->attr.procedure))
1395
            {
1396
              gfc_error ("'%s' at %L is not a module procedure",
1397
                         p->sym->name, &p->where);
1398
              return;
1399
            }
1400
        }
1401
 
1402
      /* Originally, this test was applied to host interfaces too;
1403
         this is incorrect since host associated symbols, from any
1404
         source, cannot be ambiguous with local symbols.  */
1405
      check_interface1 (sym->generic, sym->generic, 1, interface_name,
1406
                        sym->attr.referenced || !sym->attr.use_assoc);
1407
    }
1408
}
1409
 
1410
 
1411
static void
1412
check_uop_interfaces (gfc_user_op *uop)
1413
{
1414
  char interface_name[100];
1415
  gfc_user_op *uop2;
1416
  gfc_namespace *ns;
1417
 
1418
  sprintf (interface_name, "operator interface '%s'", uop->name);
1419
  if (check_interface0 (uop->op, interface_name))
1420
    return;
1421
 
1422
  for (ns = gfc_current_ns; ns; ns = ns->parent)
1423
    {
1424
      uop2 = gfc_find_uop (uop->name, ns);
1425
      if (uop2 == NULL)
1426
        continue;
1427
 
1428
      check_interface1 (uop->op, uop2->op, 0,
1429
                        interface_name, true);
1430
    }
1431
}
1432
 
1433
/* Given an intrinsic op, return an equivalent op if one exists,
1434
   or INTRINSIC_NONE otherwise.  */
1435
 
1436
gfc_intrinsic_op
1437
gfc_equivalent_op (gfc_intrinsic_op op)
1438
{
1439
  switch(op)
1440
    {
1441
    case INTRINSIC_EQ:
1442
      return INTRINSIC_EQ_OS;
1443
 
1444
    case INTRINSIC_EQ_OS:
1445
      return INTRINSIC_EQ;
1446
 
1447
    case INTRINSIC_NE:
1448
      return INTRINSIC_NE_OS;
1449
 
1450
    case INTRINSIC_NE_OS:
1451
      return INTRINSIC_NE;
1452
 
1453
    case INTRINSIC_GT:
1454
      return INTRINSIC_GT_OS;
1455
 
1456
    case INTRINSIC_GT_OS:
1457
      return INTRINSIC_GT;
1458
 
1459
    case INTRINSIC_GE:
1460
      return INTRINSIC_GE_OS;
1461
 
1462
    case INTRINSIC_GE_OS:
1463
      return INTRINSIC_GE;
1464
 
1465
    case INTRINSIC_LT:
1466
      return INTRINSIC_LT_OS;
1467
 
1468
    case INTRINSIC_LT_OS:
1469
      return INTRINSIC_LT;
1470
 
1471
    case INTRINSIC_LE:
1472
      return INTRINSIC_LE_OS;
1473
 
1474
    case INTRINSIC_LE_OS:
1475
      return INTRINSIC_LE;
1476
 
1477
    default:
1478
      return INTRINSIC_NONE;
1479
    }
1480
}
1481
 
1482
/* For the namespace, check generic, user operator and intrinsic
1483
   operator interfaces for consistency and to remove duplicate
1484
   interfaces.  We traverse the whole namespace, counting on the fact
1485
   that most symbols will not have generic or operator interfaces.  */
1486
 
1487
void
1488
gfc_check_interfaces (gfc_namespace *ns)
1489
{
1490
  gfc_namespace *old_ns, *ns2;
1491
  char interface_name[100];
1492
  int i;
1493
 
1494
  old_ns = gfc_current_ns;
1495
  gfc_current_ns = ns;
1496
 
1497
  gfc_traverse_ns (ns, check_sym_interfaces);
1498
 
1499
  gfc_traverse_user_op (ns, check_uop_interfaces);
1500
 
1501
  for (i = GFC_INTRINSIC_BEGIN; i != GFC_INTRINSIC_END; i++)
1502
    {
1503
      if (i == INTRINSIC_USER)
1504
        continue;
1505
 
1506
      if (i == INTRINSIC_ASSIGN)
1507
        strcpy (interface_name, "intrinsic assignment operator");
1508
      else
1509
        sprintf (interface_name, "intrinsic '%s' operator",
1510
                 gfc_op2string ((gfc_intrinsic_op) i));
1511
 
1512
      if (check_interface0 (ns->op[i], interface_name))
1513
        continue;
1514
 
1515
      if (ns->op[i])
1516
        gfc_check_operator_interface (ns->op[i]->sym, (gfc_intrinsic_op) i,
1517
                                      ns->op[i]->where);
1518
 
1519
      for (ns2 = ns; ns2; ns2 = ns2->parent)
1520
        {
1521
          gfc_intrinsic_op other_op;
1522
 
1523
          if (check_interface1 (ns->op[i], ns2->op[i], 0,
1524
                                interface_name, true))
1525
            goto done;
1526
 
1527
          /* i should be gfc_intrinsic_op, but has to be int with this cast
1528
             here for stupid C++ compatibility rules.  */
1529
          other_op = gfc_equivalent_op ((gfc_intrinsic_op) i);
1530
          if (other_op != INTRINSIC_NONE
1531
            &&  check_interface1 (ns->op[i], ns2->op[other_op],
1532
                                  0, interface_name, true))
1533
            goto done;
1534
        }
1535
    }
1536
 
1537
done:
1538
  gfc_current_ns = old_ns;
1539
}
1540
 
1541
 
1542
static int
1543
symbol_rank (gfc_symbol *sym)
1544
{
1545
  if (sym->ts.type == BT_CLASS && CLASS_DATA (sym)->as)
1546
    return CLASS_DATA (sym)->as->rank;
1547
 
1548
  return (sym->as == NULL) ? 0 : sym->as->rank;
1549
}
1550
 
1551
 
1552
/* Given a symbol of a formal argument list and an expression, if the
1553
   formal argument is allocatable, check that the actual argument is
1554
   allocatable. Returns nonzero if compatible, zero if not compatible.  */
1555
 
1556
static int
1557
compare_allocatable (gfc_symbol *formal, gfc_expr *actual)
1558
{
1559
  symbol_attribute attr;
1560
 
1561
  if (formal->attr.allocatable
1562
      || (formal->ts.type == BT_CLASS && CLASS_DATA (formal)->attr.allocatable))
1563
    {
1564
      attr = gfc_expr_attr (actual);
1565
      if (!attr.allocatable)
1566
        return 0;
1567
    }
1568
 
1569
  return 1;
1570
}
1571
 
1572
 
1573
/* Given a symbol of a formal argument list and an expression, if the
1574
   formal argument is a pointer, see if the actual argument is a
1575
   pointer. Returns nonzero if compatible, zero if not compatible.  */
1576
 
1577
static int
1578
compare_pointer (gfc_symbol *formal, gfc_expr *actual)
1579
{
1580
  symbol_attribute attr;
1581
 
1582
  if (formal->attr.pointer)
1583
    {
1584
      attr = gfc_expr_attr (actual);
1585
 
1586
      /* Fortran 2008 allows non-pointer actual arguments.  */
1587
      if (!attr.pointer && attr.target && formal->attr.intent == INTENT_IN)
1588
        return 2;
1589
 
1590
      if (!attr.pointer)
1591
        return 0;
1592
    }
1593
 
1594
  return 1;
1595
}
1596
 
1597
 
1598
/* Emit clear error messages for rank mismatch.  */
1599
 
1600
static void
1601
argument_rank_mismatch (const char *name, locus *where,
1602
                        int rank1, int rank2)
1603
{
1604
  if (rank1 == 0)
1605
    {
1606
      gfc_error ("Rank mismatch in argument '%s' at %L "
1607
                 "(scalar and rank-%d)", name, where, rank2);
1608
    }
1609
  else if (rank2 == 0)
1610
    {
1611
      gfc_error ("Rank mismatch in argument '%s' at %L "
1612
                 "(rank-%d and scalar)", name, where, rank1);
1613
    }
1614
  else
1615
    {
1616
      gfc_error ("Rank mismatch in argument '%s' at %L "
1617
                 "(rank-%d and rank-%d)", name, where, rank1, rank2);
1618
    }
1619
}
1620
 
1621
 
1622
/* Given a symbol of a formal argument list and an expression, see if
1623
   the two are compatible as arguments.  Returns nonzero if
1624
   compatible, zero if not compatible.  */
1625
 
1626
static int
1627
compare_parameter (gfc_symbol *formal, gfc_expr *actual,
1628
                   int ranks_must_agree, int is_elemental, locus *where)
1629
{
1630
  gfc_ref *ref;
1631
  bool rank_check, is_pointer;
1632
 
1633
  /* If the formal arg has type BT_VOID, it's to one of the iso_c_binding
1634
     procs c_f_pointer or c_f_procpointer, and we need to accept most
1635
     pointers the user could give us.  This should allow that.  */
1636
  if (formal->ts.type == BT_VOID)
1637
    return 1;
1638
 
1639
  if (formal->ts.type == BT_DERIVED
1640
      && formal->ts.u.derived && formal->ts.u.derived->ts.is_iso_c
1641
      && actual->ts.type == BT_DERIVED
1642
      && actual->ts.u.derived && actual->ts.u.derived->ts.is_iso_c)
1643
    return 1;
1644
 
1645
  if (formal->ts.type == BT_CLASS && actual->ts.type == BT_DERIVED)
1646
    /* Make sure the vtab symbol is present when
1647
       the module variables are generated.  */
1648
    gfc_find_derived_vtab (actual->ts.u.derived);
1649
 
1650
  if (actual->ts.type == BT_PROCEDURE)
1651
    {
1652
      char err[200];
1653
      gfc_symbol *act_sym = actual->symtree->n.sym;
1654
 
1655
      if (formal->attr.flavor != FL_PROCEDURE)
1656
        {
1657
          if (where)
1658
            gfc_error ("Invalid procedure argument at %L", &actual->where);
1659
          return 0;
1660
        }
1661
 
1662
      if (!gfc_compare_interfaces (formal, act_sym, act_sym->name, 0, 1, err,
1663
                                   sizeof(err)))
1664
        {
1665
          if (where)
1666
            gfc_error ("Interface mismatch in dummy procedure '%s' at %L: %s",
1667
                       formal->name, &actual->where, err);
1668
          return 0;
1669
        }
1670
 
1671
      if (formal->attr.function && !act_sym->attr.function)
1672
        {
1673
          gfc_add_function (&act_sym->attr, act_sym->name,
1674
          &act_sym->declared_at);
1675
          if (act_sym->ts.type == BT_UNKNOWN
1676
              && gfc_set_default_type (act_sym, 1, act_sym->ns) == FAILURE)
1677
            return 0;
1678
        }
1679
      else if (formal->attr.subroutine && !act_sym->attr.subroutine)
1680
        gfc_add_subroutine (&act_sym->attr, act_sym->name,
1681
                            &act_sym->declared_at);
1682
 
1683
      return 1;
1684
    }
1685
 
1686
  /* F2008, C1241.  */
1687
  if (formal->attr.pointer && formal->attr.contiguous
1688
      && !gfc_is_simply_contiguous (actual, true))
1689
    {
1690
      if (where)
1691
        gfc_error ("Actual argument to contiguous pointer dummy '%s' at %L "
1692
                   "must be simply contigous", formal->name, &actual->where);
1693
      return 0;
1694
    }
1695
 
1696
  if ((actual->expr_type != EXPR_NULL || actual->ts.type != BT_UNKNOWN)
1697
      && actual->ts.type != BT_HOLLERITH
1698
      && !gfc_compare_types (&formal->ts, &actual->ts)
1699
      && !(formal->ts.type == BT_DERIVED && actual->ts.type == BT_CLASS
1700
           && gfc_compare_derived_types (formal->ts.u.derived,
1701
                                         CLASS_DATA (actual)->ts.u.derived)))
1702
    {
1703
      if (where)
1704
        gfc_error ("Type mismatch in argument '%s' at %L; passed %s to %s",
1705
                   formal->name, &actual->where, gfc_typename (&actual->ts),
1706
                   gfc_typename (&formal->ts));
1707
      return 0;
1708
    }
1709
 
1710
  /* F2008, 12.5.2.5.  */
1711
  if (formal->ts.type == BT_CLASS
1712
      && (CLASS_DATA (formal)->attr.class_pointer
1713
          || CLASS_DATA (formal)->attr.allocatable))
1714
    {
1715
      if (actual->ts.type != BT_CLASS)
1716
        {
1717
          if (where)
1718
            gfc_error ("Actual argument to '%s' at %L must be polymorphic",
1719
                        formal->name, &actual->where);
1720
          return 0;
1721
        }
1722
      if (!gfc_compare_derived_types (CLASS_DATA (actual)->ts.u.derived,
1723
                                      CLASS_DATA (formal)->ts.u.derived))
1724
        {
1725
          if (where)
1726
            gfc_error ("Actual argument to '%s' at %L must have the same "
1727
                       "declared type", formal->name, &actual->where);
1728
          return 0;
1729
        }
1730
    }
1731
 
1732
  if (formal->attr.codimension && !gfc_is_coarray (actual))
1733
    {
1734
      if (where)
1735
        gfc_error ("Actual argument to '%s' at %L must be a coarray",
1736
                       formal->name, &actual->where);
1737
      return 0;
1738
    }
1739
 
1740
  if (formal->attr.codimension && formal->attr.allocatable)
1741
    {
1742
      gfc_ref *last = NULL;
1743
 
1744
      for (ref = actual->ref; ref; ref = ref->next)
1745
        if (ref->type == REF_COMPONENT)
1746
          last = ref;
1747
 
1748
      /* F2008, 12.5.2.6.  */
1749
      if ((last && last->u.c.component->as->corank != formal->as->corank)
1750
          || (!last
1751
              && actual->symtree->n.sym->as->corank != formal->as->corank))
1752
        {
1753
          if (where)
1754
            gfc_error ("Corank mismatch in argument '%s' at %L (%d and %d)",
1755
                   formal->name, &actual->where, formal->as->corank,
1756
                   last ? last->u.c.component->as->corank
1757
                        : actual->symtree->n.sym->as->corank);
1758
          return 0;
1759
        }
1760
    }
1761
 
1762
  if (formal->attr.codimension)
1763
    {
1764
      /* F2008, 12.5.2.8.  */
1765
      if (formal->attr.dimension
1766
          && (formal->attr.contiguous || formal->as->type != AS_ASSUMED_SHAPE)
1767
          && gfc_expr_attr (actual).dimension
1768
          && !gfc_is_simply_contiguous (actual, true))
1769
        {
1770
          if (where)
1771
            gfc_error ("Actual argument to '%s' at %L must be simply "
1772
                       "contiguous", formal->name, &actual->where);
1773
          return 0;
1774
        }
1775
 
1776
      /* F2008, C1303 and C1304.  */
1777
      if (formal->attr.intent != INTENT_INOUT
1778
          && (((formal->ts.type == BT_DERIVED || formal->ts.type == BT_CLASS)
1779
               && formal->ts.u.derived->from_intmod == INTMOD_ISO_FORTRAN_ENV
1780
               && formal->ts.u.derived->intmod_sym_id == ISOFORTRAN_LOCK_TYPE)
1781
              || formal->attr.lock_comp))
1782
 
1783
        {
1784
          if (where)
1785
            gfc_error ("Actual argument to non-INTENT(INOUT) dummy '%s' at %L, "
1786
                       "which is LOCK_TYPE or has a LOCK_TYPE component",
1787
                       formal->name, &actual->where);
1788
          return 0;
1789
        }
1790
    }
1791
 
1792
  /* F2008, C1239/C1240.  */
1793
  if (actual->expr_type == EXPR_VARIABLE
1794
      && (actual->symtree->n.sym->attr.asynchronous
1795
         || actual->symtree->n.sym->attr.volatile_)
1796
      &&  (formal->attr.asynchronous || formal->attr.volatile_)
1797
      && actual->rank && !gfc_is_simply_contiguous (actual, true)
1798
      && ((formal->as->type != AS_ASSUMED_SHAPE && !formal->attr.pointer)
1799
          || formal->attr.contiguous))
1800
    {
1801
      if (where)
1802
        gfc_error ("Dummy argument '%s' has to be a pointer or assumed-shape "
1803
                   "array without CONTIGUOUS attribute - as actual argument at"
1804
                   " %L is not simply contiguous and both are ASYNCHRONOUS "
1805
                   "or VOLATILE", formal->name, &actual->where);
1806
      return 0;
1807
    }
1808
 
1809
  if (formal->attr.allocatable && !formal->attr.codimension
1810
      && gfc_expr_attr (actual).codimension)
1811
    {
1812
      if (formal->attr.intent == INTENT_OUT)
1813
        {
1814
          if (where)
1815
            gfc_error ("Passing coarray at %L to allocatable, noncoarray, "
1816
                       "INTENT(OUT) dummy argument '%s'", &actual->where,
1817
                       formal->name);
1818
            return 0;
1819
        }
1820
      else if (gfc_option.warn_surprising && where
1821
               && formal->attr.intent != INTENT_IN)
1822
        gfc_warning ("Passing coarray at %L to allocatable, noncoarray dummy "
1823
                     "argument '%s', which is invalid if the allocation status"
1824
                     " is modified",  &actual->where, formal->name);
1825
    }
1826
 
1827
  if (symbol_rank (formal) == actual->rank)
1828
    return 1;
1829
 
1830
  if (actual->ts.type == BT_CLASS && CLASS_DATA (actual)->as
1831
        && CLASS_DATA (actual)->as->rank == symbol_rank (formal))
1832
    return 1;
1833
 
1834
  rank_check = where != NULL && !is_elemental && formal->as
1835
               && (formal->as->type == AS_ASSUMED_SHAPE
1836
                   || formal->as->type == AS_DEFERRED)
1837
               && actual->expr_type != EXPR_NULL;
1838
 
1839
  /* Scalar & coindexed, see: F2008, Section 12.5.2.4.  */
1840
  if (rank_check || ranks_must_agree
1841
      || (formal->attr.pointer && actual->expr_type != EXPR_NULL)
1842
      || (actual->rank != 0 && !(is_elemental || formal->attr.dimension))
1843
      || (actual->rank == 0
1844
          && ((formal->ts.type == BT_CLASS
1845
               && CLASS_DATA (formal)->as->type == AS_ASSUMED_SHAPE)
1846
              || (formal->ts.type != BT_CLASS
1847
                   && formal->as->type == AS_ASSUMED_SHAPE))
1848
          && actual->expr_type != EXPR_NULL)
1849
      || (actual->rank == 0 && formal->attr.dimension
1850
          && gfc_is_coindexed (actual)))
1851
    {
1852
      if (where)
1853
        argument_rank_mismatch (formal->name, &actual->where,
1854
                                symbol_rank (formal), actual->rank);
1855
      return 0;
1856
    }
1857
  else if (actual->rank != 0 && (is_elemental || formal->attr.dimension))
1858
    return 1;
1859
 
1860
  /* At this point, we are considering a scalar passed to an array.   This
1861
     is valid (cf. F95 12.4.1.1, F2003 12.4.1.2, and F2008 12.5.2.4),
1862
     - if the actual argument is (a substring of) an element of a
1863
       non-assumed-shape/non-pointer/non-polymorphic array; or
1864
     - (F2003) if the actual argument is of type character of default/c_char
1865
       kind.  */
1866
 
1867
  is_pointer = actual->expr_type == EXPR_VARIABLE
1868
               ? actual->symtree->n.sym->attr.pointer : false;
1869
 
1870
  for (ref = actual->ref; ref; ref = ref->next)
1871
    {
1872
      if (ref->type == REF_COMPONENT)
1873
        is_pointer = ref->u.c.component->attr.pointer;
1874
      else if (ref->type == REF_ARRAY && ref->u.ar.type == AR_ELEMENT
1875
               && ref->u.ar.dimen > 0
1876
               && (!ref->next
1877
                   || (ref->next->type == REF_SUBSTRING && !ref->next->next)))
1878
        break;
1879
    }
1880
 
1881
  if (actual->ts.type == BT_CLASS && actual->expr_type != EXPR_NULL)
1882
    {
1883
      if (where)
1884
        gfc_error ("Polymorphic scalar passed to array dummy argument '%s' "
1885
                   "at %L", formal->name, &actual->where);
1886
      return 0;
1887
    }
1888
 
1889
  if (actual->expr_type != EXPR_NULL && ref && actual->ts.type != BT_CHARACTER
1890
      && (is_pointer || ref->u.ar.as->type == AS_ASSUMED_SHAPE))
1891
    {
1892
      if (where)
1893
        gfc_error ("Element of assumed-shaped or pointer "
1894
                   "array passed to array dummy argument '%s' at %L",
1895
                   formal->name, &actual->where);
1896
      return 0;
1897
    }
1898
 
1899
  if (actual->ts.type == BT_CHARACTER && actual->expr_type != EXPR_NULL
1900
      && (!ref || is_pointer || ref->u.ar.as->type == AS_ASSUMED_SHAPE))
1901
    {
1902
      if (formal->ts.kind != 1 && (gfc_option.allow_std & GFC_STD_GNU) == 0)
1903
        {
1904
          if (where)
1905
            gfc_error ("Extension: Scalar non-default-kind, non-C_CHAR-kind "
1906
                       "CHARACTER actual argument with array dummy argument "
1907
                       "'%s' at %L", formal->name, &actual->where);
1908
          return 0;
1909
        }
1910
 
1911
      if (where && (gfc_option.allow_std & GFC_STD_F2003) == 0)
1912
        {
1913
          gfc_error ("Fortran 2003: Scalar CHARACTER actual argument with "
1914
                     "array dummy argument '%s' at %L",
1915
                     formal->name, &actual->where);
1916
          return 0;
1917
        }
1918
      else if ((gfc_option.allow_std & GFC_STD_F2003) == 0)
1919
        return 0;
1920
      else
1921
        return 1;
1922
    }
1923
 
1924
  if (ref == NULL && actual->expr_type != EXPR_NULL)
1925
    {
1926
      if (where)
1927
        argument_rank_mismatch (formal->name, &actual->where,
1928
                                symbol_rank (formal), actual->rank);
1929
      return 0;
1930
    }
1931
 
1932
  return 1;
1933
}
1934
 
1935
 
1936
/* Returns the storage size of a symbol (formal argument) or
1937
   zero if it cannot be determined.  */
1938
 
1939
static unsigned long
1940
get_sym_storage_size (gfc_symbol *sym)
1941
{
1942
  int i;
1943
  unsigned long strlen, elements;
1944
 
1945
  if (sym->ts.type == BT_CHARACTER)
1946
    {
1947
      if (sym->ts.u.cl && sym->ts.u.cl->length
1948
          && sym->ts.u.cl->length->expr_type == EXPR_CONSTANT)
1949
        strlen = mpz_get_ui (sym->ts.u.cl->length->value.integer);
1950
      else
1951
        return 0;
1952
    }
1953
  else
1954
    strlen = 1;
1955
 
1956
  if (symbol_rank (sym) == 0)
1957
    return strlen;
1958
 
1959
  elements = 1;
1960
  if (sym->as->type != AS_EXPLICIT)
1961
    return 0;
1962
  for (i = 0; i < sym->as->rank; i++)
1963
    {
1964
      if (!sym->as || sym->as->upper[i]->expr_type != EXPR_CONSTANT
1965
          || sym->as->lower[i]->expr_type != EXPR_CONSTANT)
1966
        return 0;
1967
 
1968
      elements *= mpz_get_si (sym->as->upper[i]->value.integer)
1969
                  - mpz_get_si (sym->as->lower[i]->value.integer) + 1L;
1970
    }
1971
 
1972
  return strlen*elements;
1973
}
1974
 
1975
 
1976
/* Returns the storage size of an expression (actual argument) or
1977
   zero if it cannot be determined. For an array element, it returns
1978
   the remaining size as the element sequence consists of all storage
1979
   units of the actual argument up to the end of the array.  */
1980
 
1981
static unsigned long
1982
get_expr_storage_size (gfc_expr *e)
1983
{
1984
  int i;
1985
  long int strlen, elements;
1986
  long int substrlen = 0;
1987
  bool is_str_storage = false;
1988
  gfc_ref *ref;
1989
 
1990
  if (e == NULL)
1991
    return 0;
1992
 
1993
  if (e->ts.type == BT_CHARACTER)
1994
    {
1995
      if (e->ts.u.cl && e->ts.u.cl->length
1996
          && e->ts.u.cl->length->expr_type == EXPR_CONSTANT)
1997
        strlen = mpz_get_si (e->ts.u.cl->length->value.integer);
1998
      else if (e->expr_type == EXPR_CONSTANT
1999
               && (e->ts.u.cl == NULL || e->ts.u.cl->length == NULL))
2000
        strlen = e->value.character.length;
2001
      else
2002
        return 0;
2003
    }
2004
  else
2005
    strlen = 1; /* Length per element.  */
2006
 
2007
  if (e->rank == 0 && !e->ref)
2008
    return strlen;
2009
 
2010
  elements = 1;
2011
  if (!e->ref)
2012
    {
2013
      if (!e->shape)
2014
        return 0;
2015
      for (i = 0; i < e->rank; i++)
2016
        elements *= mpz_get_si (e->shape[i]);
2017
      return elements*strlen;
2018
    }
2019
 
2020
  for (ref = e->ref; ref; ref = ref->next)
2021
    {
2022
      if (ref->type == REF_SUBSTRING && ref->u.ss.start
2023
          && ref->u.ss.start->expr_type == EXPR_CONSTANT)
2024
        {
2025
          if (is_str_storage)
2026
            {
2027
              /* The string length is the substring length.
2028
                 Set now to full string length.  */
2029
              if (!ref->u.ss.length || !ref->u.ss.length->length
2030
                  || ref->u.ss.length->length->expr_type != EXPR_CONSTANT)
2031
                return 0;
2032
 
2033
              strlen = mpz_get_ui (ref->u.ss.length->length->value.integer);
2034
            }
2035
          substrlen = strlen - mpz_get_ui (ref->u.ss.start->value.integer) + 1;
2036
          continue;
2037
        }
2038
 
2039
      if (ref->type == REF_ARRAY && ref->u.ar.type == AR_SECTION
2040
          && ref->u.ar.start && ref->u.ar.end && ref->u.ar.stride
2041
          && ref->u.ar.as->upper)
2042
        for (i = 0; i < ref->u.ar.dimen; i++)
2043
          {
2044
            long int start, end, stride;
2045
            stride = 1;
2046
 
2047
            if (ref->u.ar.stride[i])
2048
              {
2049
                if (ref->u.ar.stride[i]->expr_type == EXPR_CONSTANT)
2050
                  stride = mpz_get_si (ref->u.ar.stride[i]->value.integer);
2051
                else
2052
                  return 0;
2053
              }
2054
 
2055
            if (ref->u.ar.start[i])
2056
              {
2057
                if (ref->u.ar.start[i]->expr_type == EXPR_CONSTANT)
2058
                  start = mpz_get_si (ref->u.ar.start[i]->value.integer);
2059
                else
2060
                  return 0;
2061
              }
2062
            else if (ref->u.ar.as->lower[i]
2063
                     && ref->u.ar.as->lower[i]->expr_type == EXPR_CONSTANT)
2064
              start = mpz_get_si (ref->u.ar.as->lower[i]->value.integer);
2065
            else
2066
              return 0;
2067
 
2068
            if (ref->u.ar.end[i])
2069
              {
2070
                if (ref->u.ar.end[i]->expr_type == EXPR_CONSTANT)
2071
                  end = mpz_get_si (ref->u.ar.end[i]->value.integer);
2072
                else
2073
                  return 0;
2074
              }
2075
            else if (ref->u.ar.as->upper[i]
2076
                     && ref->u.ar.as->upper[i]->expr_type == EXPR_CONSTANT)
2077
              end = mpz_get_si (ref->u.ar.as->upper[i]->value.integer);
2078
            else
2079
              return 0;
2080
 
2081
            elements *= (end - start)/stride + 1L;
2082
          }
2083
      else if (ref->type == REF_ARRAY && ref->u.ar.type == AR_FULL
2084
               && ref->u.ar.as->lower && ref->u.ar.as->upper)
2085
        for (i = 0; i < ref->u.ar.as->rank; i++)
2086
          {
2087
            if (ref->u.ar.as->lower[i] && ref->u.ar.as->upper[i]
2088
                && ref->u.ar.as->lower[i]->expr_type == EXPR_CONSTANT
2089
                && ref->u.ar.as->upper[i]->expr_type == EXPR_CONSTANT)
2090
              elements *= mpz_get_si (ref->u.ar.as->upper[i]->value.integer)
2091
                          - mpz_get_si (ref->u.ar.as->lower[i]->value.integer)
2092
                          + 1L;
2093
            else
2094
              return 0;
2095
          }
2096
      else if (ref->type == REF_ARRAY && ref->u.ar.type == AR_ELEMENT
2097
               && e->expr_type == EXPR_VARIABLE)
2098
        {
2099
          if (ref->u.ar.as->type == AS_ASSUMED_SHAPE
2100
              || e->symtree->n.sym->attr.pointer)
2101
            {
2102
              elements = 1;
2103
              continue;
2104
            }
2105
 
2106
          /* Determine the number of remaining elements in the element
2107
             sequence for array element designators.  */
2108
          is_str_storage = true;
2109
          for (i = ref->u.ar.dimen - 1; i >= 0; i--)
2110
            {
2111
              if (ref->u.ar.start[i] == NULL
2112
                  || ref->u.ar.start[i]->expr_type != EXPR_CONSTANT
2113
                  || ref->u.ar.as->upper[i] == NULL
2114
                  || ref->u.ar.as->lower[i] == NULL
2115
                  || ref->u.ar.as->upper[i]->expr_type != EXPR_CONSTANT
2116
                  || ref->u.ar.as->lower[i]->expr_type != EXPR_CONSTANT)
2117
                return 0;
2118
 
2119
              elements
2120
                   = elements
2121
                     * (mpz_get_si (ref->u.ar.as->upper[i]->value.integer)
2122
                        - mpz_get_si (ref->u.ar.as->lower[i]->value.integer)
2123
                        + 1L)
2124
                     - (mpz_get_si (ref->u.ar.start[i]->value.integer)
2125
                        - mpz_get_si (ref->u.ar.as->lower[i]->value.integer));
2126
            }
2127
        }
2128
    }
2129
 
2130
  if (substrlen)
2131
    return (is_str_storage) ? substrlen + (elements-1)*strlen
2132
                            : elements*strlen;
2133
  else
2134
    return elements*strlen;
2135
}
2136
 
2137
 
2138
/* Given an expression, check whether it is an array section
2139
   which has a vector subscript. If it has, one is returned,
2140
   otherwise zero.  */
2141
 
2142
int
2143
gfc_has_vector_subscript (gfc_expr *e)
2144
{
2145
  int i;
2146
  gfc_ref *ref;
2147
 
2148
  if (e == NULL || e->rank == 0 || e->expr_type != EXPR_VARIABLE)
2149
    return 0;
2150
 
2151
  for (ref = e->ref; ref; ref = ref->next)
2152
    if (ref->type == REF_ARRAY && ref->u.ar.type == AR_SECTION)
2153
      for (i = 0; i < ref->u.ar.dimen; i++)
2154
        if (ref->u.ar.dimen_type[i] == DIMEN_VECTOR)
2155
          return 1;
2156
 
2157
  return 0;
2158
}
2159
 
2160
 
2161
/* Given formal and actual argument lists, see if they are compatible.
2162
   If they are compatible, the actual argument list is sorted to
2163
   correspond with the formal list, and elements for missing optional
2164
   arguments are inserted. If WHERE pointer is nonnull, then we issue
2165
   errors when things don't match instead of just returning the status
2166
   code.  */
2167
 
2168
static int
2169
compare_actual_formal (gfc_actual_arglist **ap, gfc_formal_arglist *formal,
2170
                       int ranks_must_agree, int is_elemental, locus *where)
2171
{
2172
  gfc_actual_arglist **new_arg, *a, *actual, temp;
2173
  gfc_formal_arglist *f;
2174
  int i, n, na;
2175
  unsigned long actual_size, formal_size;
2176
  bool full_array = false;
2177
 
2178
  actual = *ap;
2179
 
2180
  if (actual == NULL && formal == NULL)
2181
    return 1;
2182
 
2183
  n = 0;
2184
  for (f = formal; f; f = f->next)
2185
    n++;
2186
 
2187
  new_arg = XALLOCAVEC (gfc_actual_arglist *, n);
2188
 
2189
  for (i = 0; i < n; i++)
2190
    new_arg[i] = NULL;
2191
 
2192
  na = 0;
2193
  f = formal;
2194
  i = 0;
2195
 
2196
  for (a = actual; a; a = a->next, f = f->next)
2197
    {
2198
      /* Look for keywords but ignore g77 extensions like %VAL.  */
2199
      if (a->name != NULL && a->name[0] != '%')
2200
        {
2201
          i = 0;
2202
          for (f = formal; f; f = f->next, i++)
2203
            {
2204
              if (f->sym == NULL)
2205
                continue;
2206
              if (strcmp (f->sym->name, a->name) == 0)
2207
                break;
2208
            }
2209
 
2210
          if (f == NULL)
2211
            {
2212
              if (where)
2213
                gfc_error ("Keyword argument '%s' at %L is not in "
2214
                           "the procedure", a->name, &a->expr->where);
2215
              return 0;
2216
            }
2217
 
2218
          if (new_arg[i] != NULL)
2219
            {
2220
              if (where)
2221
                gfc_error ("Keyword argument '%s' at %L is already associated "
2222
                           "with another actual argument", a->name,
2223
                           &a->expr->where);
2224
              return 0;
2225
            }
2226
        }
2227
 
2228
      if (f == NULL)
2229
        {
2230
          if (where)
2231
            gfc_error ("More actual than formal arguments in procedure "
2232
                       "call at %L", where);
2233
 
2234
          return 0;
2235
        }
2236
 
2237
      if (f->sym == NULL && a->expr == NULL)
2238
        goto match;
2239
 
2240
      if (f->sym == NULL)
2241
        {
2242
          if (where)
2243
            gfc_error ("Missing alternate return spec in subroutine call "
2244
                       "at %L", where);
2245
          return 0;
2246
        }
2247
 
2248
      if (a->expr == NULL)
2249
        {
2250
          if (where)
2251
            gfc_error ("Unexpected alternate return spec in subroutine "
2252
                       "call at %L", where);
2253
          return 0;
2254
        }
2255
 
2256
      if (a->expr->expr_type == EXPR_NULL && !f->sym->attr.pointer
2257
          && (f->sym->attr.allocatable || !f->sym->attr.optional
2258
              || (gfc_option.allow_std & GFC_STD_F2008) == 0))
2259
        {
2260
          if (where && (f->sym->attr.allocatable || !f->sym->attr.optional))
2261
            gfc_error ("Unexpected NULL() intrinsic at %L to dummy '%s'",
2262
                       where, f->sym->name);
2263
          else if (where)
2264
            gfc_error ("Fortran 2008: Null pointer at %L to non-pointer "
2265
                       "dummy '%s'", where, f->sym->name);
2266
 
2267
          return 0;
2268
        }
2269
 
2270
      if (!compare_parameter (f->sym, a->expr, ranks_must_agree,
2271
                              is_elemental, where))
2272
        return 0;
2273
 
2274
      /* Special case for character arguments.  For allocatable, pointer
2275
         and assumed-shape dummies, the string length needs to match
2276
         exactly.  */
2277
      if (a->expr->ts.type == BT_CHARACTER
2278
           && a->expr->ts.u.cl && a->expr->ts.u.cl->length
2279
           && a->expr->ts.u.cl->length->expr_type == EXPR_CONSTANT
2280
           && f->sym->ts.u.cl && f->sym->ts.u.cl && f->sym->ts.u.cl->length
2281
           && f->sym->ts.u.cl->length->expr_type == EXPR_CONSTANT
2282
           && (f->sym->attr.pointer || f->sym->attr.allocatable
2283
               || (f->sym->as && f->sym->as->type == AS_ASSUMED_SHAPE))
2284
           && (mpz_cmp (a->expr->ts.u.cl->length->value.integer,
2285
                        f->sym->ts.u.cl->length->value.integer) != 0))
2286
         {
2287
           if (where && (f->sym->attr.pointer || f->sym->attr.allocatable))
2288
             gfc_warning ("Character length mismatch (%ld/%ld) between actual "
2289
                          "argument and pointer or allocatable dummy argument "
2290
                          "'%s' at %L",
2291
                          mpz_get_si (a->expr->ts.u.cl->length->value.integer),
2292
                          mpz_get_si (f->sym->ts.u.cl->length->value.integer),
2293
                          f->sym->name, &a->expr->where);
2294
           else if (where)
2295
             gfc_warning ("Character length mismatch (%ld/%ld) between actual "
2296
                          "argument and assumed-shape dummy argument '%s' "
2297
                          "at %L",
2298
                          mpz_get_si (a->expr->ts.u.cl->length->value.integer),
2299
                          mpz_get_si (f->sym->ts.u.cl->length->value.integer),
2300
                          f->sym->name, &a->expr->where);
2301
           return 0;
2302
         }
2303
 
2304
      if ((f->sym->attr.pointer || f->sym->attr.allocatable)
2305
            && f->sym->ts.deferred != a->expr->ts.deferred
2306
            && a->expr->ts.type == BT_CHARACTER)
2307
        {
2308
          if (where)
2309
            gfc_error ("Actual argument at %L to allocatable or "
2310
                       "pointer dummy argument '%s' must have a deferred "
2311
                       "length type parameter if and only if the dummy has one",
2312
                       &a->expr->where, f->sym->name);
2313
          return 0;
2314
        }
2315
 
2316
      if (f->sym->ts.type == BT_CLASS)
2317
        goto skip_size_check;
2318
 
2319
      actual_size = get_expr_storage_size (a->expr);
2320
      formal_size = get_sym_storage_size (f->sym);
2321
      if (actual_size != 0 && actual_size < formal_size
2322
          && a->expr->ts.type != BT_PROCEDURE
2323
          && f->sym->attr.flavor != FL_PROCEDURE)
2324
        {
2325
          if (a->expr->ts.type == BT_CHARACTER && !f->sym->as && where)
2326
            gfc_warning ("Character length of actual argument shorter "
2327
                         "than of dummy argument '%s' (%lu/%lu) at %L",
2328
                         f->sym->name, actual_size, formal_size,
2329
                         &a->expr->where);
2330
          else if (where)
2331
            gfc_warning ("Actual argument contains too few "
2332
                         "elements for dummy argument '%s' (%lu/%lu) at %L",
2333
                         f->sym->name, actual_size, formal_size,
2334
                         &a->expr->where);
2335
          return  0;
2336
        }
2337
 
2338
     skip_size_check:
2339
 
2340
      /* Satisfy 12.4.1.3 by ensuring that a procedure pointer actual argument
2341
         is provided for a procedure pointer formal argument.  */
2342
      if (f->sym->attr.proc_pointer
2343
          && !((a->expr->expr_type == EXPR_VARIABLE
2344
                && a->expr->symtree->n.sym->attr.proc_pointer)
2345
               || (a->expr->expr_type == EXPR_FUNCTION
2346
                   && a->expr->symtree->n.sym->result->attr.proc_pointer)
2347
               || gfc_is_proc_ptr_comp (a->expr, NULL)))
2348
        {
2349
          if (where)
2350
            gfc_error ("Expected a procedure pointer for argument '%s' at %L",
2351
                       f->sym->name, &a->expr->where);
2352
          return 0;
2353
        }
2354
 
2355
      /* Satisfy 12.4.1.2 by ensuring that a procedure actual argument is
2356
         provided for a procedure formal argument.  */
2357
      if (a->expr->ts.type != BT_PROCEDURE && !gfc_is_proc_ptr_comp (a->expr, NULL)
2358
          && a->expr->expr_type == EXPR_VARIABLE
2359
          && f->sym->attr.flavor == FL_PROCEDURE)
2360
        {
2361
          if (where)
2362
            gfc_error ("Expected a procedure for argument '%s' at %L",
2363
                       f->sym->name, &a->expr->where);
2364
          return 0;
2365
        }
2366
 
2367
      if (f->sym->as && f->sym->as->type == AS_ASSUMED_SHAPE
2368
          && a->expr->expr_type == EXPR_VARIABLE
2369
          && a->expr->symtree->n.sym->as
2370
          && a->expr->symtree->n.sym->as->type == AS_ASSUMED_SIZE
2371
          && (a->expr->ref == NULL
2372
              || (a->expr->ref->type == REF_ARRAY
2373
                  && a->expr->ref->u.ar.type == AR_FULL)))
2374
        {
2375
          if (where)
2376
            gfc_error ("Actual argument for '%s' cannot be an assumed-size"
2377
                       " array at %L", f->sym->name, where);
2378
          return 0;
2379
        }
2380
 
2381
      if (a->expr->expr_type != EXPR_NULL
2382
          && compare_pointer (f->sym, a->expr) == 0)
2383
        {
2384
          if (where)
2385
            gfc_error ("Actual argument for '%s' must be a pointer at %L",
2386
                       f->sym->name, &a->expr->where);
2387
          return 0;
2388
        }
2389
 
2390
      if (a->expr->expr_type != EXPR_NULL
2391
          && (gfc_option.allow_std & GFC_STD_F2008) == 0
2392
          && compare_pointer (f->sym, a->expr) == 2)
2393
        {
2394
          if (where)
2395
            gfc_error ("Fortran 2008: Non-pointer actual argument at %L to "
2396
                       "pointer dummy '%s'", &a->expr->where,f->sym->name);
2397
          return 0;
2398
        }
2399
 
2400
 
2401
      /* Fortran 2008, C1242.  */
2402
      if (f->sym->attr.pointer && gfc_is_coindexed (a->expr))
2403
        {
2404
          if (where)
2405
            gfc_error ("Coindexed actual argument at %L to pointer "
2406
                       "dummy '%s'",
2407
                       &a->expr->where, f->sym->name);
2408
          return 0;
2409
        }
2410
 
2411
      /* Fortran 2008, 12.5.2.5 (no constraint).  */
2412
      if (a->expr->expr_type == EXPR_VARIABLE
2413
          && f->sym->attr.intent != INTENT_IN
2414
          && f->sym->attr.allocatable
2415
          && gfc_is_coindexed (a->expr))
2416
        {
2417
          if (where)
2418
            gfc_error ("Coindexed actual argument at %L to allocatable "
2419
                       "dummy '%s' requires INTENT(IN)",
2420
                       &a->expr->where, f->sym->name);
2421
          return 0;
2422
        }
2423
 
2424
      /* Fortran 2008, C1237.  */
2425
      if (a->expr->expr_type == EXPR_VARIABLE
2426
          && (f->sym->attr.asynchronous || f->sym->attr.volatile_)
2427
          && gfc_is_coindexed (a->expr)
2428
          && (a->expr->symtree->n.sym->attr.volatile_
2429
              || a->expr->symtree->n.sym->attr.asynchronous))
2430
        {
2431
          if (where)
2432
            gfc_error ("Coindexed ASYNCHRONOUS or VOLATILE actual argument at "
2433
                       "%L requires that dummy '%s' has neither "
2434
                       "ASYNCHRONOUS nor VOLATILE", &a->expr->where,
2435
                       f->sym->name);
2436
          return 0;
2437
        }
2438
 
2439
      /* Fortran 2008, 12.5.2.4 (no constraint).  */
2440
      if (a->expr->expr_type == EXPR_VARIABLE
2441
          && f->sym->attr.intent != INTENT_IN && !f->sym->attr.value
2442
          && gfc_is_coindexed (a->expr)
2443
          && gfc_has_ultimate_allocatable (a->expr))
2444
        {
2445
          if (where)
2446
            gfc_error ("Coindexed actual argument at %L with allocatable "
2447
                       "ultimate component to dummy '%s' requires either VALUE "
2448
                       "or INTENT(IN)", &a->expr->where, f->sym->name);
2449
          return 0;
2450
        }
2451
 
2452
     if (f->sym->ts.type == BT_CLASS
2453
           && CLASS_DATA (f->sym)->attr.allocatable
2454
           && gfc_is_class_array_ref (a->expr, &full_array)
2455
           && !full_array)
2456
        {
2457
          if (where)
2458
            gfc_error ("Actual CLASS array argument for '%s' must be a full "
2459
                       "array at %L", f->sym->name, &a->expr->where);
2460
          return 0;
2461
        }
2462
 
2463
 
2464
      if (a->expr->expr_type != EXPR_NULL
2465
          && compare_allocatable (f->sym, a->expr) == 0)
2466
        {
2467
          if (where)
2468
            gfc_error ("Actual argument for '%s' must be ALLOCATABLE at %L",
2469
                       f->sym->name, &a->expr->where);
2470
          return 0;
2471
        }
2472
 
2473
      /* Check intent = OUT/INOUT for definable actual argument.  */
2474
      if ((f->sym->attr.intent == INTENT_OUT
2475
          || f->sym->attr.intent == INTENT_INOUT))
2476
        {
2477
          const char* context = (where
2478
                                 ? _("actual argument to INTENT = OUT/INOUT")
2479
                                 : NULL);
2480
 
2481
          if (f->sym->attr.pointer
2482
              && gfc_check_vardef_context (a->expr, true, false, context)
2483
                   == FAILURE)
2484
            return 0;
2485
          if (gfc_check_vardef_context (a->expr, false, false, context)
2486
                == FAILURE)
2487
            return 0;
2488
        }
2489
 
2490
      if ((f->sym->attr.intent == INTENT_OUT
2491
           || f->sym->attr.intent == INTENT_INOUT
2492
           || f->sym->attr.volatile_
2493
           || f->sym->attr.asynchronous)
2494
          && gfc_has_vector_subscript (a->expr))
2495
        {
2496
          if (where)
2497
            gfc_error ("Array-section actual argument with vector "
2498
                       "subscripts at %L is incompatible with INTENT(OUT), "
2499
                       "INTENT(INOUT), VOLATILE or ASYNCHRONOUS attribute "
2500
                       "of the dummy argument '%s'",
2501
                       &a->expr->where, f->sym->name);
2502
          return 0;
2503
        }
2504
 
2505
      /* C1232 (R1221) For an actual argument which is an array section or
2506
         an assumed-shape array, the dummy argument shall be an assumed-
2507
         shape array, if the dummy argument has the VOLATILE attribute.  */
2508
 
2509
      if (f->sym->attr.volatile_
2510
          && a->expr->symtree->n.sym->as
2511
          && a->expr->symtree->n.sym->as->type == AS_ASSUMED_SHAPE
2512
          && !(f->sym->as && f->sym->as->type == AS_ASSUMED_SHAPE))
2513
        {
2514
          if (where)
2515
            gfc_error ("Assumed-shape actual argument at %L is "
2516
                       "incompatible with the non-assumed-shape "
2517
                       "dummy argument '%s' due to VOLATILE attribute",
2518
                       &a->expr->where,f->sym->name);
2519
          return 0;
2520
        }
2521
 
2522
      if (f->sym->attr.volatile_
2523
          && a->expr->ref && a->expr->ref->u.ar.type == AR_SECTION
2524
          && !(f->sym->as && f->sym->as->type == AS_ASSUMED_SHAPE))
2525
        {
2526
          if (where)
2527
            gfc_error ("Array-section actual argument at %L is "
2528
                       "incompatible with the non-assumed-shape "
2529
                       "dummy argument '%s' due to VOLATILE attribute",
2530
                       &a->expr->where,f->sym->name);
2531
          return 0;
2532
        }
2533
 
2534
      /* C1233 (R1221) For an actual argument which is a pointer array, the
2535
         dummy argument shall be an assumed-shape or pointer array, if the
2536
         dummy argument has the VOLATILE attribute.  */
2537
 
2538
      if (f->sym->attr.volatile_
2539
          && a->expr->symtree->n.sym->attr.pointer
2540
          && a->expr->symtree->n.sym->as
2541
          && !(f->sym->as
2542
               && (f->sym->as->type == AS_ASSUMED_SHAPE
2543
                   || f->sym->attr.pointer)))
2544
        {
2545
          if (where)
2546
            gfc_error ("Pointer-array actual argument at %L requires "
2547
                       "an assumed-shape or pointer-array dummy "
2548
                       "argument '%s' due to VOLATILE attribute",
2549
                       &a->expr->where,f->sym->name);
2550
          return 0;
2551
        }
2552
 
2553
    match:
2554
      if (a == actual)
2555
        na = i;
2556
 
2557
      new_arg[i++] = a;
2558
    }
2559
 
2560
  /* Make sure missing actual arguments are optional.  */
2561
  i = 0;
2562
  for (f = formal; f; f = f->next, i++)
2563
    {
2564
      if (new_arg[i] != NULL)
2565
        continue;
2566
      if (f->sym == NULL)
2567
        {
2568
          if (where)
2569
            gfc_error ("Missing alternate return spec in subroutine call "
2570
                       "at %L", where);
2571
          return 0;
2572
        }
2573
      if (!f->sym->attr.optional)
2574
        {
2575
          if (where)
2576
            gfc_error ("Missing actual argument for argument '%s' at %L",
2577
                       f->sym->name, where);
2578
          return 0;
2579
        }
2580
    }
2581
 
2582
  /* The argument lists are compatible.  We now relink a new actual
2583
     argument list with null arguments in the right places.  The head
2584
     of the list remains the head.  */
2585
  for (i = 0; i < n; i++)
2586
    if (new_arg[i] == NULL)
2587
      new_arg[i] = gfc_get_actual_arglist ();
2588
 
2589
  if (na != 0)
2590
    {
2591
      temp = *new_arg[0];
2592
      *new_arg[0] = *actual;
2593
      *actual = temp;
2594
 
2595
      a = new_arg[0];
2596
      new_arg[0] = new_arg[na];
2597
      new_arg[na] = a;
2598
    }
2599
 
2600
  for (i = 0; i < n - 1; i++)
2601
    new_arg[i]->next = new_arg[i + 1];
2602
 
2603
  new_arg[i]->next = NULL;
2604
 
2605
  if (*ap == NULL && n > 0)
2606
    *ap = new_arg[0];
2607
 
2608
  /* Note the types of omitted optional arguments.  */
2609
  for (a = *ap, f = formal; a; a = a->next, f = f->next)
2610
    if (a->expr == NULL && a->label == NULL)
2611
      a->missing_arg_type = f->sym->ts.type;
2612
 
2613
  return 1;
2614
}
2615
 
2616
 
2617
typedef struct
2618
{
2619
  gfc_formal_arglist *f;
2620
  gfc_actual_arglist *a;
2621
}
2622
argpair;
2623
 
2624
/* qsort comparison function for argument pairs, with the following
2625
   order:
2626
    - p->a->expr == NULL
2627
    - p->a->expr->expr_type != EXPR_VARIABLE
2628
    - growing p->a->expr->symbol.  */
2629
 
2630
static int
2631
pair_cmp (const void *p1, const void *p2)
2632
{
2633
  const gfc_actual_arglist *a1, *a2;
2634
 
2635
  /* *p1 and *p2 are elements of the to-be-sorted array.  */
2636
  a1 = ((const argpair *) p1)->a;
2637
  a2 = ((const argpair *) p2)->a;
2638
  if (!a1->expr)
2639
    {
2640
      if (!a2->expr)
2641
        return 0;
2642
      return -1;
2643
    }
2644
  if (!a2->expr)
2645
    return 1;
2646
  if (a1->expr->expr_type != EXPR_VARIABLE)
2647
    {
2648
      if (a2->expr->expr_type != EXPR_VARIABLE)
2649
        return 0;
2650
      return -1;
2651
    }
2652
  if (a2->expr->expr_type != EXPR_VARIABLE)
2653
    return 1;
2654
  return a1->expr->symtree->n.sym < a2->expr->symtree->n.sym;
2655
}
2656
 
2657
 
2658
/* Given two expressions from some actual arguments, test whether they
2659
   refer to the same expression. The analysis is conservative.
2660
   Returning FAILURE will produce no warning.  */
2661
 
2662
static gfc_try
2663
compare_actual_expr (gfc_expr *e1, gfc_expr *e2)
2664
{
2665
  const gfc_ref *r1, *r2;
2666
 
2667
  if (!e1 || !e2
2668
      || e1->expr_type != EXPR_VARIABLE
2669
      || e2->expr_type != EXPR_VARIABLE
2670
      || e1->symtree->n.sym != e2->symtree->n.sym)
2671
    return FAILURE;
2672
 
2673
  /* TODO: improve comparison, see expr.c:show_ref().  */
2674
  for (r1 = e1->ref, r2 = e2->ref; r1 && r2; r1 = r1->next, r2 = r2->next)
2675
    {
2676
      if (r1->type != r2->type)
2677
        return FAILURE;
2678
      switch (r1->type)
2679
        {
2680
        case REF_ARRAY:
2681
          if (r1->u.ar.type != r2->u.ar.type)
2682
            return FAILURE;
2683
          /* TODO: At the moment, consider only full arrays;
2684
             we could do better.  */
2685
          if (r1->u.ar.type != AR_FULL || r2->u.ar.type != AR_FULL)
2686
            return FAILURE;
2687
          break;
2688
 
2689
        case REF_COMPONENT:
2690
          if (r1->u.c.component != r2->u.c.component)
2691
            return FAILURE;
2692
          break;
2693
 
2694
        case REF_SUBSTRING:
2695
          return FAILURE;
2696
 
2697
        default:
2698
          gfc_internal_error ("compare_actual_expr(): Bad component code");
2699
        }
2700
    }
2701
  if (!r1 && !r2)
2702
    return SUCCESS;
2703
  return FAILURE;
2704
}
2705
 
2706
 
2707
/* Given formal and actual argument lists that correspond to one
2708
   another, check that identical actual arguments aren't not
2709
   associated with some incompatible INTENTs.  */
2710
 
2711
static gfc_try
2712
check_some_aliasing (gfc_formal_arglist *f, gfc_actual_arglist *a)
2713
{
2714
  sym_intent f1_intent, f2_intent;
2715
  gfc_formal_arglist *f1;
2716
  gfc_actual_arglist *a1;
2717
  size_t n, i, j;
2718
  argpair *p;
2719
  gfc_try t = SUCCESS;
2720
 
2721
  n = 0;
2722
  for (f1 = f, a1 = a;; f1 = f1->next, a1 = a1->next)
2723
    {
2724
      if (f1 == NULL && a1 == NULL)
2725
        break;
2726
      if (f1 == NULL || a1 == NULL)
2727
        gfc_internal_error ("check_some_aliasing(): List mismatch");
2728
      n++;
2729
    }
2730
  if (n == 0)
2731
    return t;
2732
  p = XALLOCAVEC (argpair, n);
2733
 
2734
  for (i = 0, f1 = f, a1 = a; i < n; i++, f1 = f1->next, a1 = a1->next)
2735
    {
2736
      p[i].f = f1;
2737
      p[i].a = a1;
2738
    }
2739
 
2740
  qsort (p, n, sizeof (argpair), pair_cmp);
2741
 
2742
  for (i = 0; i < n; i++)
2743
    {
2744
      if (!p[i].a->expr
2745
          || p[i].a->expr->expr_type != EXPR_VARIABLE
2746
          || p[i].a->expr->ts.type == BT_PROCEDURE)
2747
        continue;
2748
      f1_intent = p[i].f->sym->attr.intent;
2749
      for (j = i + 1; j < n; j++)
2750
        {
2751
          /* Expected order after the sort.  */
2752
          if (!p[j].a->expr || p[j].a->expr->expr_type != EXPR_VARIABLE)
2753
            gfc_internal_error ("check_some_aliasing(): corrupted data");
2754
 
2755
          /* Are the expression the same?  */
2756
          if (compare_actual_expr (p[i].a->expr, p[j].a->expr) == FAILURE)
2757
            break;
2758
          f2_intent = p[j].f->sym->attr.intent;
2759
          if ((f1_intent == INTENT_IN && f2_intent == INTENT_OUT)
2760
              || (f1_intent == INTENT_OUT && f2_intent == INTENT_IN))
2761
            {
2762
              gfc_warning ("Same actual argument associated with INTENT(%s) "
2763
                           "argument '%s' and INTENT(%s) argument '%s' at %L",
2764
                           gfc_intent_string (f1_intent), p[i].f->sym->name,
2765
                           gfc_intent_string (f2_intent), p[j].f->sym->name,
2766
                           &p[i].a->expr->where);
2767
              t = FAILURE;
2768
            }
2769
        }
2770
    }
2771
 
2772
  return t;
2773
}
2774
 
2775
 
2776
/* Given a symbol of a formal argument list and an expression,
2777
   return nonzero if their intents are compatible, zero otherwise.  */
2778
 
2779
static int
2780
compare_parameter_intent (gfc_symbol *formal, gfc_expr *actual)
2781
{
2782
  if (actual->symtree->n.sym->attr.pointer && !formal->attr.pointer)
2783
    return 1;
2784
 
2785
  if (actual->symtree->n.sym->attr.intent != INTENT_IN)
2786
    return 1;
2787
 
2788
  if (formal->attr.intent == INTENT_INOUT || formal->attr.intent == INTENT_OUT)
2789
    return 0;
2790
 
2791
  return 1;
2792
}
2793
 
2794
 
2795
/* Given formal and actual argument lists that correspond to one
2796
   another, check that they are compatible in the sense that intents
2797
   are not mismatched.  */
2798
 
2799
static gfc_try
2800
check_intents (gfc_formal_arglist *f, gfc_actual_arglist *a)
2801
{
2802
  sym_intent f_intent;
2803
 
2804
  for (;; f = f->next, a = a->next)
2805
    {
2806
      if (f == NULL && a == NULL)
2807
        break;
2808
      if (f == NULL || a == NULL)
2809
        gfc_internal_error ("check_intents(): List mismatch");
2810
 
2811
      if (a->expr == NULL || a->expr->expr_type != EXPR_VARIABLE)
2812
        continue;
2813
 
2814
      f_intent = f->sym->attr.intent;
2815
 
2816
      if (!compare_parameter_intent(f->sym, a->expr))
2817
        {
2818
          gfc_error ("Procedure argument at %L is INTENT(IN) while interface "
2819
                     "specifies INTENT(%s)", &a->expr->where,
2820
                     gfc_intent_string (f_intent));
2821
          return FAILURE;
2822
        }
2823
 
2824
      if (gfc_pure (NULL) && gfc_impure_variable (a->expr->symtree->n.sym))
2825
        {
2826
          if (f_intent == INTENT_INOUT || f_intent == INTENT_OUT)
2827
            {
2828
              gfc_error ("Procedure argument at %L is local to a PURE "
2829
                         "procedure and is passed to an INTENT(%s) argument",
2830
                         &a->expr->where, gfc_intent_string (f_intent));
2831
              return FAILURE;
2832
            }
2833
 
2834
          if (f->sym->attr.pointer)
2835
            {
2836
              gfc_error ("Procedure argument at %L is local to a PURE "
2837
                         "procedure and has the POINTER attribute",
2838
                         &a->expr->where);
2839
              return FAILURE;
2840
            }
2841
        }
2842
 
2843
       /* Fortran 2008, C1283.  */
2844
       if (gfc_pure (NULL) && gfc_is_coindexed (a->expr))
2845
        {
2846
          if (f_intent == INTENT_INOUT || f_intent == INTENT_OUT)
2847
            {
2848
              gfc_error ("Coindexed actual argument at %L in PURE procedure "
2849
                         "is passed to an INTENT(%s) argument",
2850
                         &a->expr->where, gfc_intent_string (f_intent));
2851
              return FAILURE;
2852
            }
2853
 
2854
          if (f->sym->attr.pointer)
2855
            {
2856
              gfc_error ("Coindexed actual argument at %L in PURE procedure "
2857
                         "is passed to a POINTER dummy argument",
2858
                         &a->expr->where);
2859
              return FAILURE;
2860
            }
2861
        }
2862
 
2863
       /* F2008, Section 12.5.2.4.  */
2864
       if (a->expr->ts.type == BT_CLASS && f->sym->ts.type == BT_CLASS
2865
           && gfc_is_coindexed (a->expr))
2866
         {
2867
           gfc_error ("Coindexed polymorphic actual argument at %L is passed "
2868
                      "polymorphic dummy argument '%s'",
2869
                         &a->expr->where, f->sym->name);
2870
           return FAILURE;
2871
         }
2872
    }
2873
 
2874
  return SUCCESS;
2875
}
2876
 
2877
 
2878
/* Check how a procedure is used against its interface.  If all goes
2879
   well, the actual argument list will also end up being properly
2880
   sorted.  */
2881
 
2882
void
2883
gfc_procedure_use (gfc_symbol *sym, gfc_actual_arglist **ap, locus *where)
2884
{
2885
 
2886
  /* Warn about calls with an implicit interface.  Special case
2887
     for calling a ISO_C_BINDING becase c_loc and c_funloc
2888
     are pseudo-unknown.  Additionally, warn about procedures not
2889
     explicitly declared at all if requested.  */
2890
  if (sym->attr.if_source == IFSRC_UNKNOWN && ! sym->attr.is_iso_c)
2891
    {
2892
      if (gfc_option.warn_implicit_interface)
2893
        gfc_warning ("Procedure '%s' called with an implicit interface at %L",
2894
                     sym->name, where);
2895
      else if (gfc_option.warn_implicit_procedure
2896
               && sym->attr.proc == PROC_UNKNOWN)
2897
        gfc_warning ("Procedure '%s' called at %L is not explicitly declared",
2898
                     sym->name, where);
2899
    }
2900
 
2901
  if (sym->attr.if_source == IFSRC_UNKNOWN)
2902
    {
2903
      gfc_actual_arglist *a;
2904
 
2905
      if (sym->attr.pointer)
2906
        {
2907
          gfc_error("The pointer object '%s' at %L must have an explicit "
2908
                    "function interface or be declared as array",
2909
                    sym->name, where);
2910
          return;
2911
        }
2912
 
2913
      if (sym->attr.allocatable && !sym->attr.external)
2914
        {
2915
          gfc_error("The allocatable object '%s' at %L must have an explicit "
2916
                    "function interface or be declared as array",
2917
                    sym->name, where);
2918
          return;
2919
        }
2920
 
2921
      if (sym->attr.allocatable)
2922
        {
2923
          gfc_error("Allocatable function '%s' at %L must have an explicit "
2924
                    "function interface", sym->name, where);
2925
          return;
2926
        }
2927
 
2928
      for (a = *ap; a; a = a->next)
2929
        {
2930
          /* Skip g77 keyword extensions like %VAL, %REF, %LOC.  */
2931
          if (a->name != NULL && a->name[0] != '%')
2932
            {
2933
              gfc_error("Keyword argument requires explicit interface "
2934
                        "for procedure '%s' at %L", sym->name, &a->expr->where);
2935
              break;
2936
            }
2937
 
2938
          /* F2008, C1303 and C1304.  */
2939
          if (a->expr
2940
              && (a->expr->ts.type == BT_DERIVED || a->expr->ts.type == BT_CLASS)
2941
              && ((a->expr->ts.u.derived->from_intmod == INTMOD_ISO_FORTRAN_ENV
2942
                   && a->expr->ts.u.derived->intmod_sym_id == ISOFORTRAN_LOCK_TYPE)
2943
                  || gfc_expr_attr (a->expr).lock_comp))
2944
            {
2945
              gfc_error("Actual argument of LOCK_TYPE or with LOCK_TYPE "
2946
                        "component at %L requires an explicit interface for "
2947
                        "procedure '%s'", &a->expr->where, sym->name);
2948
              break;
2949
            }
2950
 
2951
          if (a->expr && a->expr->expr_type == EXPR_NULL
2952
              && a->expr->ts.type == BT_UNKNOWN)
2953
            {
2954
              gfc_error ("MOLD argument to NULL required at %L", &a->expr->where);
2955
              return;
2956
            }
2957
        }
2958
 
2959
      return;
2960
    }
2961
 
2962
  if (!compare_actual_formal (ap, sym->formal, 0, sym->attr.elemental, where))
2963
    return;
2964
 
2965
  check_intents (sym->formal, *ap);
2966
  if (gfc_option.warn_aliasing)
2967
    check_some_aliasing (sym->formal, *ap);
2968
}
2969
 
2970
 
2971
/* Check how a procedure pointer component is used against its interface.
2972
   If all goes well, the actual argument list will also end up being properly
2973
   sorted. Completely analogous to gfc_procedure_use.  */
2974
 
2975
void
2976
gfc_ppc_use (gfc_component *comp, gfc_actual_arglist **ap, locus *where)
2977
{
2978
 
2979
  /* Warn about calls with an implicit interface.  Special case
2980
     for calling a ISO_C_BINDING becase c_loc and c_funloc
2981
     are pseudo-unknown.  */
2982
  if (gfc_option.warn_implicit_interface
2983
      && comp->attr.if_source == IFSRC_UNKNOWN
2984
      && !comp->attr.is_iso_c)
2985
    gfc_warning ("Procedure pointer component '%s' called with an implicit "
2986
                 "interface at %L", comp->name, where);
2987
 
2988
  if (comp->attr.if_source == IFSRC_UNKNOWN)
2989
    {
2990
      gfc_actual_arglist *a;
2991
      for (a = *ap; a; a = a->next)
2992
        {
2993
          /* Skip g77 keyword extensions like %VAL, %REF, %LOC.  */
2994
          if (a->name != NULL && a->name[0] != '%')
2995
            {
2996
              gfc_error("Keyword argument requires explicit interface "
2997
                        "for procedure pointer component '%s' at %L",
2998
                        comp->name, &a->expr->where);
2999
              break;
3000
            }
3001
        }
3002
 
3003
      return;
3004
    }
3005
 
3006
  if (!compare_actual_formal (ap, comp->formal, 0, comp->attr.elemental, where))
3007
    return;
3008
 
3009
  check_intents (comp->formal, *ap);
3010
  if (gfc_option.warn_aliasing)
3011
    check_some_aliasing (comp->formal, *ap);
3012
}
3013
 
3014
 
3015
/* Try if an actual argument list matches the formal list of a symbol,
3016
   respecting the symbol's attributes like ELEMENTAL.  This is used for
3017
   GENERIC resolution.  */
3018
 
3019
bool
3020
gfc_arglist_matches_symbol (gfc_actual_arglist** args, gfc_symbol* sym)
3021
{
3022
  bool r;
3023
 
3024
  gcc_assert (sym->attr.flavor == FL_PROCEDURE);
3025
 
3026
  r = !sym->attr.elemental;
3027
  if (compare_actual_formal (args, sym->formal, r, !r, NULL))
3028
    {
3029
      check_intents (sym->formal, *args);
3030
      if (gfc_option.warn_aliasing)
3031
        check_some_aliasing (sym->formal, *args);
3032
      return true;
3033
    }
3034
 
3035
  return false;
3036
}
3037
 
3038
 
3039
/* Given an interface pointer and an actual argument list, search for
3040
   a formal argument list that matches the actual.  If found, returns
3041
   a pointer to the symbol of the correct interface.  Returns NULL if
3042
   not found.  */
3043
 
3044
gfc_symbol *
3045
gfc_search_interface (gfc_interface *intr, int sub_flag,
3046
                      gfc_actual_arglist **ap)
3047
{
3048
  gfc_symbol *elem_sym = NULL;
3049
  gfc_symbol *null_sym = NULL;
3050
  locus null_expr_loc;
3051
  gfc_actual_arglist *a;
3052
  bool has_null_arg = false;
3053
 
3054
  for (a = *ap; a; a = a->next)
3055
    if (a->expr && a->expr->expr_type == EXPR_NULL
3056
        && a->expr->ts.type == BT_UNKNOWN)
3057
      {
3058
        has_null_arg = true;
3059
        null_expr_loc = a->expr->where;
3060
        break;
3061
      }
3062
 
3063
  for (; intr; intr = intr->next)
3064
    {
3065
      if (intr->sym->attr.flavor == FL_DERIVED)
3066
        continue;
3067
      if (sub_flag && intr->sym->attr.function)
3068
        continue;
3069
      if (!sub_flag && intr->sym->attr.subroutine)
3070
        continue;
3071
 
3072
      if (gfc_arglist_matches_symbol (ap, intr->sym))
3073
        {
3074
          if (has_null_arg && null_sym)
3075
            {
3076
              gfc_error ("MOLD= required in NULL() argument at %L: Ambiguity "
3077
                         "between specific functions %s and %s",
3078
                         &null_expr_loc, null_sym->name, intr->sym->name);
3079
              return NULL;
3080
            }
3081
          else if (has_null_arg)
3082
            {
3083
              null_sym = intr->sym;
3084
              continue;
3085
            }
3086
 
3087
          /* Satisfy 12.4.4.1 such that an elemental match has lower
3088
             weight than a non-elemental match.  */
3089
          if (intr->sym->attr.elemental)
3090
            {
3091
              elem_sym = intr->sym;
3092
              continue;
3093
            }
3094
          return intr->sym;
3095
        }
3096
    }
3097
 
3098
  if (null_sym)
3099
    return null_sym;
3100
 
3101
  return elem_sym ? elem_sym : NULL;
3102
}
3103
 
3104
 
3105
/* Do a brute force recursive search for a symbol.  */
3106
 
3107
static gfc_symtree *
3108
find_symtree0 (gfc_symtree *root, gfc_symbol *sym)
3109
{
3110
  gfc_symtree * st;
3111
 
3112
  if (root->n.sym == sym)
3113
    return root;
3114
 
3115
  st = NULL;
3116
  if (root->left)
3117
    st = find_symtree0 (root->left, sym);
3118
  if (root->right && ! st)
3119
    st = find_symtree0 (root->right, sym);
3120
  return st;
3121
}
3122
 
3123
 
3124
/* Find a symtree for a symbol.  */
3125
 
3126
gfc_symtree *
3127
gfc_find_sym_in_symtree (gfc_symbol *sym)
3128
{
3129
  gfc_symtree *st;
3130
  gfc_namespace *ns;
3131
 
3132
  /* First try to find it by name.  */
3133
  gfc_find_sym_tree (sym->name, gfc_current_ns, 1, &st);
3134
  if (st && st->n.sym == sym)
3135
    return st;
3136
 
3137
  /* If it's been renamed, resort to a brute-force search.  */
3138
  /* TODO: avoid having to do this search.  If the symbol doesn't exist
3139
     in the symtree for the current namespace, it should probably be added.  */
3140
  for (ns = gfc_current_ns; ns; ns = ns->parent)
3141
    {
3142
      st = find_symtree0 (ns->sym_root, sym);
3143
      if (st)
3144
        return st;
3145
    }
3146
  gfc_internal_error ("Unable to find symbol %s", sym->name);
3147
  /* Not reached.  */
3148
}
3149
 
3150
 
3151
/* See if the arglist to an operator-call contains a derived-type argument
3152
   with a matching type-bound operator.  If so, return the matching specific
3153
   procedure defined as operator-target as well as the base-object to use
3154
   (which is the found derived-type argument with operator).  The generic
3155
   name, if any, is transmitted to the final expression via 'gname'.  */
3156
 
3157
static gfc_typebound_proc*
3158
matching_typebound_op (gfc_expr** tb_base,
3159
                       gfc_actual_arglist* args,
3160
                       gfc_intrinsic_op op, const char* uop,
3161
                       const char ** gname)
3162
{
3163
  gfc_actual_arglist* base;
3164
 
3165
  for (base = args; base; base = base->next)
3166
    if (base->expr->ts.type == BT_DERIVED || base->expr->ts.type == BT_CLASS)
3167
      {
3168
        gfc_typebound_proc* tb;
3169
        gfc_symbol* derived;
3170
        gfc_try result;
3171
 
3172
        while (base->expr->expr_type == EXPR_OP
3173
               && base->expr->value.op.op == INTRINSIC_PARENTHESES)
3174
          base->expr = base->expr->value.op.op1;
3175
 
3176
        if (base->expr->ts.type == BT_CLASS)
3177
          {
3178
            if (CLASS_DATA (base->expr) == NULL)
3179
              continue;
3180
            derived = CLASS_DATA (base->expr)->ts.u.derived;
3181
          }
3182
        else
3183
          derived = base->expr->ts.u.derived;
3184
 
3185
        if (op == INTRINSIC_USER)
3186
          {
3187
            gfc_symtree* tb_uop;
3188
 
3189
            gcc_assert (uop);
3190
            tb_uop = gfc_find_typebound_user_op (derived, &result, uop,
3191
                                                 false, NULL);
3192
 
3193
            if (tb_uop)
3194
              tb = tb_uop->n.tb;
3195
            else
3196
              tb = NULL;
3197
          }
3198
        else
3199
          tb = gfc_find_typebound_intrinsic_op (derived, &result, op,
3200
                                                false, NULL);
3201
 
3202
        /* This means we hit a PRIVATE operator which is use-associated and
3203
           should thus not be seen.  */
3204
        if (result == FAILURE)
3205
          tb = NULL;
3206
 
3207
        /* Look through the super-type hierarchy for a matching specific
3208
           binding.  */
3209
        for (; tb; tb = tb->overridden)
3210
          {
3211
            gfc_tbp_generic* g;
3212
 
3213
            gcc_assert (tb->is_generic);
3214
            for (g = tb->u.generic; g; g = g->next)
3215
              {
3216
                gfc_symbol* target;
3217
                gfc_actual_arglist* argcopy;
3218
                bool matches;
3219
 
3220
                gcc_assert (g->specific);
3221
                if (g->specific->error)
3222
                  continue;
3223
 
3224
                target = g->specific->u.specific->n.sym;
3225
 
3226
                /* Check if this arglist matches the formal.  */
3227
                argcopy = gfc_copy_actual_arglist (args);
3228
                matches = gfc_arglist_matches_symbol (&argcopy, target);
3229
                gfc_free_actual_arglist (argcopy);
3230
 
3231
                /* Return if we found a match.  */
3232
                if (matches)
3233
                  {
3234
                    *tb_base = base->expr;
3235
                    *gname = g->specific_st->name;
3236
                    return g->specific;
3237
                  }
3238
              }
3239
          }
3240
      }
3241
 
3242
  return NULL;
3243
}
3244
 
3245
 
3246
/* For the 'actual arglist' of an operator call and a specific typebound
3247
   procedure that has been found the target of a type-bound operator, build the
3248
   appropriate EXPR_COMPCALL and resolve it.  We take this indirection over
3249
   type-bound procedures rather than resolving type-bound operators 'directly'
3250
   so that we can reuse the existing logic.  */
3251
 
3252
static void
3253
build_compcall_for_operator (gfc_expr* e, gfc_actual_arglist* actual,
3254
                             gfc_expr* base, gfc_typebound_proc* target,
3255
                             const char *gname)
3256
{
3257
  e->expr_type = EXPR_COMPCALL;
3258
  e->value.compcall.tbp = target;
3259
  e->value.compcall.name = gname ? gname : "$op";
3260
  e->value.compcall.actual = actual;
3261
  e->value.compcall.base_object = base;
3262
  e->value.compcall.ignore_pass = 1;
3263
  e->value.compcall.assign = 0;
3264
  if (e->ts.type == BT_UNKNOWN
3265
        && target->function)
3266
    {
3267
      if (target->is_generic)
3268
        e->ts = target->u.generic->specific->u.specific->n.sym->ts;
3269
      else
3270
        e->ts = target->u.specific->n.sym->ts;
3271
    }
3272
}
3273
 
3274
 
3275
/* This subroutine is called when an expression is being resolved.
3276
   The expression node in question is either a user defined operator
3277
   or an intrinsic operator with arguments that aren't compatible
3278
   with the operator.  This subroutine builds an actual argument list
3279
   corresponding to the operands, then searches for a compatible
3280
   interface.  If one is found, the expression node is replaced with
3281
   the appropriate function call. We use the 'match' enum to specify
3282
   whether a replacement has been made or not, or if an error occurred.  */
3283
 
3284
match
3285
gfc_extend_expr (gfc_expr *e)
3286
{
3287
  gfc_actual_arglist *actual;
3288
  gfc_symbol *sym;
3289
  gfc_namespace *ns;
3290
  gfc_user_op *uop;
3291
  gfc_intrinsic_op i;
3292
  const char *gname;
3293
 
3294
  sym = NULL;
3295
 
3296
  actual = gfc_get_actual_arglist ();
3297
  actual->expr = e->value.op.op1;
3298
 
3299
  gname = NULL;
3300
 
3301
  if (e->value.op.op2 != NULL)
3302
    {
3303
      actual->next = gfc_get_actual_arglist ();
3304
      actual->next->expr = e->value.op.op2;
3305
    }
3306
 
3307
  i = fold_unary_intrinsic (e->value.op.op);
3308
 
3309
  if (i == INTRINSIC_USER)
3310
    {
3311
      for (ns = gfc_current_ns; ns; ns = ns->parent)
3312
        {
3313
          uop = gfc_find_uop (e->value.op.uop->name, ns);
3314
          if (uop == NULL)
3315
            continue;
3316
 
3317
          sym = gfc_search_interface (uop->op, 0, &actual);
3318
          if (sym != NULL)
3319
            break;
3320
        }
3321
    }
3322
  else
3323
    {
3324
      for (ns = gfc_current_ns; ns; ns = ns->parent)
3325
        {
3326
          /* Due to the distinction between '==' and '.eq.' and friends, one has
3327
             to check if either is defined.  */
3328
          switch (i)
3329
            {
3330
#define CHECK_OS_COMPARISON(comp) \
3331
  case INTRINSIC_##comp: \
3332
  case INTRINSIC_##comp##_OS: \
3333
    sym = gfc_search_interface (ns->op[INTRINSIC_##comp], 0, &actual); \
3334
    if (!sym) \
3335
      sym = gfc_search_interface (ns->op[INTRINSIC_##comp##_OS], 0, &actual); \
3336
    break;
3337
              CHECK_OS_COMPARISON(EQ)
3338
              CHECK_OS_COMPARISON(NE)
3339
              CHECK_OS_COMPARISON(GT)
3340
              CHECK_OS_COMPARISON(GE)
3341
              CHECK_OS_COMPARISON(LT)
3342
              CHECK_OS_COMPARISON(LE)
3343
#undef CHECK_OS_COMPARISON
3344
 
3345
              default:
3346
                sym = gfc_search_interface (ns->op[i], 0, &actual);
3347
            }
3348
 
3349
          if (sym != NULL)
3350
            break;
3351
        }
3352
    }
3353
 
3354
  /* TODO: Do an ambiguity-check and error if multiple matching interfaces are
3355
     found rather than just taking the first one and not checking further.  */
3356
 
3357
  if (sym == NULL)
3358
    {
3359
      gfc_typebound_proc* tbo;
3360
      gfc_expr* tb_base;
3361
 
3362
      /* See if we find a matching type-bound operator.  */
3363
      if (i == INTRINSIC_USER)
3364
        tbo = matching_typebound_op (&tb_base, actual,
3365
                                     i, e->value.op.uop->name, &gname);
3366
      else
3367
        switch (i)
3368
          {
3369
#define CHECK_OS_COMPARISON(comp) \
3370
  case INTRINSIC_##comp: \
3371
  case INTRINSIC_##comp##_OS: \
3372
    tbo = matching_typebound_op (&tb_base, actual, \
3373
                                 INTRINSIC_##comp, NULL, &gname); \
3374
    if (!tbo) \
3375
      tbo = matching_typebound_op (&tb_base, actual, \
3376
                                   INTRINSIC_##comp##_OS, NULL, &gname); \
3377
    break;
3378
            CHECK_OS_COMPARISON(EQ)
3379
            CHECK_OS_COMPARISON(NE)
3380
            CHECK_OS_COMPARISON(GT)
3381
            CHECK_OS_COMPARISON(GE)
3382
            CHECK_OS_COMPARISON(LT)
3383
            CHECK_OS_COMPARISON(LE)
3384
#undef CHECK_OS_COMPARISON
3385
 
3386
            default:
3387
              tbo = matching_typebound_op (&tb_base, actual, i, NULL, &gname);
3388
              break;
3389
          }
3390
 
3391
      /* If there is a matching typebound-operator, replace the expression with
3392
         a call to it and succeed.  */
3393
      if (tbo)
3394
        {
3395
          gfc_try result;
3396
 
3397
          gcc_assert (tb_base);
3398
          build_compcall_for_operator (e, actual, tb_base, tbo, gname);
3399
 
3400
          result = gfc_resolve_expr (e);
3401
          if (result == FAILURE)
3402
            return MATCH_ERROR;
3403
 
3404
          return MATCH_YES;
3405
        }
3406
 
3407
      /* Don't use gfc_free_actual_arglist().  */
3408
      free (actual->next);
3409
      free (actual);
3410
 
3411
      return MATCH_NO;
3412
    }
3413
 
3414
  /* Change the expression node to a function call.  */
3415
  e->expr_type = EXPR_FUNCTION;
3416
  e->symtree = gfc_find_sym_in_symtree (sym);
3417
  e->value.function.actual = actual;
3418
  e->value.function.esym = NULL;
3419
  e->value.function.isym = NULL;
3420
  e->value.function.name = NULL;
3421
  e->user_operator = 1;
3422
 
3423
  if (gfc_resolve_expr (e) == FAILURE)
3424
    return MATCH_ERROR;
3425
 
3426
  return MATCH_YES;
3427
}
3428
 
3429
 
3430
/* Tries to replace an assignment code node with a subroutine call to
3431
   the subroutine associated with the assignment operator.  Return
3432
   SUCCESS if the node was replaced.  On FAILURE, no error is
3433
   generated.  */
3434
 
3435
gfc_try
3436
gfc_extend_assign (gfc_code *c, gfc_namespace *ns)
3437
{
3438
  gfc_actual_arglist *actual;
3439
  gfc_expr *lhs, *rhs;
3440
  gfc_symbol *sym;
3441
  const char *gname;
3442
 
3443
  gname = NULL;
3444
 
3445
  lhs = c->expr1;
3446
  rhs = c->expr2;
3447
 
3448
  /* Don't allow an intrinsic assignment to be replaced.  */
3449
  if (lhs->ts.type != BT_DERIVED && lhs->ts.type != BT_CLASS
3450
      && (rhs->rank == 0 || rhs->rank == lhs->rank)
3451
      && (lhs->ts.type == rhs->ts.type
3452
          || (gfc_numeric_ts (&lhs->ts) && gfc_numeric_ts (&rhs->ts))))
3453
    return FAILURE;
3454
 
3455
  actual = gfc_get_actual_arglist ();
3456
  actual->expr = lhs;
3457
 
3458
  actual->next = gfc_get_actual_arglist ();
3459
  actual->next->expr = rhs;
3460
 
3461
  sym = NULL;
3462
 
3463
  for (; ns; ns = ns->parent)
3464
    {
3465
      sym = gfc_search_interface (ns->op[INTRINSIC_ASSIGN], 1, &actual);
3466
      if (sym != NULL)
3467
        break;
3468
    }
3469
 
3470
  /* TODO: Ambiguity-check, see above for gfc_extend_expr.  */
3471
 
3472
  if (sym == NULL)
3473
    {
3474
      gfc_typebound_proc* tbo;
3475
      gfc_expr* tb_base;
3476
 
3477
      /* See if we find a matching type-bound assignment.  */
3478
      tbo = matching_typebound_op (&tb_base, actual,
3479
                                   INTRINSIC_ASSIGN, NULL, &gname);
3480
 
3481
      /* If there is one, replace the expression with a call to it and
3482
         succeed.  */
3483
      if (tbo)
3484
        {
3485
          gcc_assert (tb_base);
3486
          c->expr1 = gfc_get_expr ();
3487
          build_compcall_for_operator (c->expr1, actual, tb_base, tbo, gname);
3488
          c->expr1->value.compcall.assign = 1;
3489
          c->expr1->where = c->loc;
3490
          c->expr2 = NULL;
3491
          c->op = EXEC_COMPCALL;
3492
 
3493
          /* c is resolved from the caller, so no need to do it here.  */
3494
 
3495
          return SUCCESS;
3496
        }
3497
 
3498
      free (actual->next);
3499
      free (actual);
3500
      return FAILURE;
3501
    }
3502
 
3503
  /* Replace the assignment with the call.  */
3504
  c->op = EXEC_ASSIGN_CALL;
3505
  c->symtree = gfc_find_sym_in_symtree (sym);
3506
  c->expr1 = NULL;
3507
  c->expr2 = NULL;
3508
  c->ext.actual = actual;
3509
 
3510
  return SUCCESS;
3511
}
3512
 
3513
 
3514
/* Make sure that the interface just parsed is not already present in
3515
   the given interface list.  Ambiguity isn't checked yet since module
3516
   procedures can be present without interfaces.  */
3517
 
3518
static gfc_try
3519
check_new_interface (gfc_interface *base, gfc_symbol *new_sym)
3520
{
3521
  gfc_interface *ip;
3522
 
3523
  for (ip = base; ip; ip = ip->next)
3524
    {
3525
      if (ip->sym == new_sym)
3526
        {
3527
          gfc_error ("Entity '%s' at %C is already present in the interface",
3528
                     new_sym->name);
3529
          return FAILURE;
3530
        }
3531
    }
3532
 
3533
  return SUCCESS;
3534
}
3535
 
3536
 
3537
/* Add a symbol to the current interface.  */
3538
 
3539
gfc_try
3540
gfc_add_interface (gfc_symbol *new_sym)
3541
{
3542
  gfc_interface **head, *intr;
3543
  gfc_namespace *ns;
3544
  gfc_symbol *sym;
3545
 
3546
  switch (current_interface.type)
3547
    {
3548
    case INTERFACE_NAMELESS:
3549
    case INTERFACE_ABSTRACT:
3550
      return SUCCESS;
3551
 
3552
    case INTERFACE_INTRINSIC_OP:
3553
      for (ns = current_interface.ns; ns; ns = ns->parent)
3554
        switch (current_interface.op)
3555
          {
3556
            case INTRINSIC_EQ:
3557
            case INTRINSIC_EQ_OS:
3558
              if (check_new_interface (ns->op[INTRINSIC_EQ], new_sym) == FAILURE ||
3559
                  check_new_interface (ns->op[INTRINSIC_EQ_OS], new_sym) == FAILURE)
3560
                return FAILURE;
3561
              break;
3562
 
3563
            case INTRINSIC_NE:
3564
            case INTRINSIC_NE_OS:
3565
              if (check_new_interface (ns->op[INTRINSIC_NE], new_sym) == FAILURE ||
3566
                  check_new_interface (ns->op[INTRINSIC_NE_OS], new_sym) == FAILURE)
3567
                return FAILURE;
3568
              break;
3569
 
3570
            case INTRINSIC_GT:
3571
            case INTRINSIC_GT_OS:
3572
              if (check_new_interface (ns->op[INTRINSIC_GT], new_sym) == FAILURE ||
3573
                  check_new_interface (ns->op[INTRINSIC_GT_OS], new_sym) == FAILURE)
3574
                return FAILURE;
3575
              break;
3576
 
3577
            case INTRINSIC_GE:
3578
            case INTRINSIC_GE_OS:
3579
              if (check_new_interface (ns->op[INTRINSIC_GE], new_sym) == FAILURE ||
3580
                  check_new_interface (ns->op[INTRINSIC_GE_OS], new_sym) == FAILURE)
3581
                return FAILURE;
3582
              break;
3583
 
3584
            case INTRINSIC_LT:
3585
            case INTRINSIC_LT_OS:
3586
              if (check_new_interface (ns->op[INTRINSIC_LT], new_sym) == FAILURE ||
3587
                  check_new_interface (ns->op[INTRINSIC_LT_OS], new_sym) == FAILURE)
3588
                return FAILURE;
3589
              break;
3590
 
3591
            case INTRINSIC_LE:
3592
            case INTRINSIC_LE_OS:
3593
              if (check_new_interface (ns->op[INTRINSIC_LE], new_sym) == FAILURE ||
3594
                  check_new_interface (ns->op[INTRINSIC_LE_OS], new_sym) == FAILURE)
3595
                return FAILURE;
3596
              break;
3597
 
3598
            default:
3599
              if (check_new_interface (ns->op[current_interface.op], new_sym) == FAILURE)
3600
                return FAILURE;
3601
          }
3602
 
3603
      head = &current_interface.ns->op[current_interface.op];
3604
      break;
3605
 
3606
    case INTERFACE_GENERIC:
3607
      for (ns = current_interface.ns; ns; ns = ns->parent)
3608
        {
3609
          gfc_find_symbol (current_interface.sym->name, ns, 0, &sym);
3610
          if (sym == NULL)
3611
            continue;
3612
 
3613
          if (check_new_interface (sym->generic, new_sym) == FAILURE)
3614
            return FAILURE;
3615
        }
3616
 
3617
      head = &current_interface.sym->generic;
3618
      break;
3619
 
3620
    case INTERFACE_USER_OP:
3621
      if (check_new_interface (current_interface.uop->op, new_sym)
3622
          == FAILURE)
3623
        return FAILURE;
3624
 
3625
      head = &current_interface.uop->op;
3626
      break;
3627
 
3628
    default:
3629
      gfc_internal_error ("gfc_add_interface(): Bad interface type");
3630
    }
3631
 
3632
  intr = gfc_get_interface ();
3633
  intr->sym = new_sym;
3634
  intr->where = gfc_current_locus;
3635
 
3636
  intr->next = *head;
3637
  *head = intr;
3638
 
3639
  return SUCCESS;
3640
}
3641
 
3642
 
3643
gfc_interface *
3644
gfc_current_interface_head (void)
3645
{
3646
  switch (current_interface.type)
3647
    {
3648
      case INTERFACE_INTRINSIC_OP:
3649
        return current_interface.ns->op[current_interface.op];
3650
        break;
3651
 
3652
      case INTERFACE_GENERIC:
3653
        return current_interface.sym->generic;
3654
        break;
3655
 
3656
      case INTERFACE_USER_OP:
3657
        return current_interface.uop->op;
3658
        break;
3659
 
3660
      default:
3661
        gcc_unreachable ();
3662
    }
3663
}
3664
 
3665
 
3666
void
3667
gfc_set_current_interface_head (gfc_interface *i)
3668
{
3669
  switch (current_interface.type)
3670
    {
3671
      case INTERFACE_INTRINSIC_OP:
3672
        current_interface.ns->op[current_interface.op] = i;
3673
        break;
3674
 
3675
      case INTERFACE_GENERIC:
3676
        current_interface.sym->generic = i;
3677
        break;
3678
 
3679
      case INTERFACE_USER_OP:
3680
        current_interface.uop->op = i;
3681
        break;
3682
 
3683
      default:
3684
        gcc_unreachable ();
3685
    }
3686
}
3687
 
3688
 
3689
/* Gets rid of a formal argument list.  We do not free symbols.
3690
   Symbols are freed when a namespace is freed.  */
3691
 
3692
void
3693
gfc_free_formal_arglist (gfc_formal_arglist *p)
3694
{
3695
  gfc_formal_arglist *q;
3696
 
3697
  for (; p; p = q)
3698
    {
3699
      q = p->next;
3700
      free (p);
3701
    }
3702
}
3703
 
3704
 
3705
/* Check that it is ok for the type-bound procedure 'proc' to override the
3706
   procedure 'old', cf. F08:4.5.7.3.  */
3707
 
3708
gfc_try
3709
gfc_check_typebound_override (gfc_symtree* proc, gfc_symtree* old)
3710
{
3711
  locus where;
3712
  const gfc_symbol *proc_target, *old_target;
3713
  unsigned proc_pass_arg, old_pass_arg, argpos;
3714
  gfc_formal_arglist *proc_formal, *old_formal;
3715
  bool check_type;
3716
  char err[200];
3717
 
3718
  /* This procedure should only be called for non-GENERIC proc.  */
3719
  gcc_assert (!proc->n.tb->is_generic);
3720
 
3721
  /* If the overwritten procedure is GENERIC, this is an error.  */
3722
  if (old->n.tb->is_generic)
3723
    {
3724
      gfc_error ("Can't overwrite GENERIC '%s' at %L",
3725
                 old->name, &proc->n.tb->where);
3726
      return FAILURE;
3727
    }
3728
 
3729
  where = proc->n.tb->where;
3730
  proc_target = proc->n.tb->u.specific->n.sym;
3731
  old_target = old->n.tb->u.specific->n.sym;
3732
 
3733
  /* Check that overridden binding is not NON_OVERRIDABLE.  */
3734
  if (old->n.tb->non_overridable)
3735
    {
3736
      gfc_error ("'%s' at %L overrides a procedure binding declared"
3737
                 " NON_OVERRIDABLE", proc->name, &where);
3738
      return FAILURE;
3739
    }
3740
 
3741
  /* It's an error to override a non-DEFERRED procedure with a DEFERRED one.  */
3742
  if (!old->n.tb->deferred && proc->n.tb->deferred)
3743
    {
3744
      gfc_error ("'%s' at %L must not be DEFERRED as it overrides a"
3745
                 " non-DEFERRED binding", proc->name, &where);
3746
      return FAILURE;
3747
    }
3748
 
3749
  /* If the overridden binding is PURE, the overriding must be, too.  */
3750
  if (old_target->attr.pure && !proc_target->attr.pure)
3751
    {
3752
      gfc_error ("'%s' at %L overrides a PURE procedure and must also be PURE",
3753
                 proc->name, &where);
3754
      return FAILURE;
3755
    }
3756
 
3757
  /* If the overridden binding is ELEMENTAL, the overriding must be, too.  If it
3758
     is not, the overriding must not be either.  */
3759
  if (old_target->attr.elemental && !proc_target->attr.elemental)
3760
    {
3761
      gfc_error ("'%s' at %L overrides an ELEMENTAL procedure and must also be"
3762
                 " ELEMENTAL", proc->name, &where);
3763
      return FAILURE;
3764
    }
3765
  if (!old_target->attr.elemental && proc_target->attr.elemental)
3766
    {
3767
      gfc_error ("'%s' at %L overrides a non-ELEMENTAL procedure and must not"
3768
                 " be ELEMENTAL, either", proc->name, &where);
3769
      return FAILURE;
3770
    }
3771
 
3772
  /* If the overridden binding is a SUBROUTINE, the overriding must also be a
3773
     SUBROUTINE.  */
3774
  if (old_target->attr.subroutine && !proc_target->attr.subroutine)
3775
    {
3776
      gfc_error ("'%s' at %L overrides a SUBROUTINE and must also be a"
3777
                 " SUBROUTINE", proc->name, &where);
3778
      return FAILURE;
3779
    }
3780
 
3781
  /* If the overridden binding is a FUNCTION, the overriding must also be a
3782
     FUNCTION and have the same characteristics.  */
3783
  if (old_target->attr.function)
3784
    {
3785
      if (!proc_target->attr.function)
3786
        {
3787
          gfc_error ("'%s' at %L overrides a FUNCTION and must also be a"
3788
                     " FUNCTION", proc->name, &where);
3789
          return FAILURE;
3790
        }
3791
 
3792
      /* FIXME:  Do more comprehensive checking (including, for instance, the
3793
         array-shape).  */
3794
      gcc_assert (proc_target->result && old_target->result);
3795
      if (!compare_type_rank (proc_target->result, old_target->result))
3796
        {
3797
          gfc_error ("'%s' at %L and the overridden FUNCTION should have"
3798
                     " matching result types and ranks", proc->name, &where);
3799
          return FAILURE;
3800
        }
3801
 
3802
      /* Check string length.  */
3803
      if (proc_target->result->ts.type == BT_CHARACTER
3804
          && proc_target->result->ts.u.cl && old_target->result->ts.u.cl)
3805
        {
3806
          int compval = gfc_dep_compare_expr (proc_target->result->ts.u.cl->length,
3807
                                              old_target->result->ts.u.cl->length);
3808
          switch (compval)
3809
          {
3810
            case -1:
3811
            case  1:
3812
            case -3:
3813
              gfc_error ("Character length mismatch between '%s' at '%L' and "
3814
                         "overridden FUNCTION", proc->name, &where);
3815
              return FAILURE;
3816
 
3817
            case -2:
3818
              gfc_warning ("Possible character length mismatch between '%s' at"
3819
                           " '%L' and overridden FUNCTION", proc->name, &where);
3820
              break;
3821
 
3822
            case 0:
3823
              break;
3824
 
3825
            default:
3826
              gfc_internal_error ("gfc_check_typebound_override: Unexpected "
3827
                                  "result %i of gfc_dep_compare_expr", compval);
3828
              break;
3829
          }
3830
        }
3831
    }
3832
 
3833
  /* If the overridden binding is PUBLIC, the overriding one must not be
3834
     PRIVATE.  */
3835
  if (old->n.tb->access == ACCESS_PUBLIC
3836
      && proc->n.tb->access == ACCESS_PRIVATE)
3837
    {
3838
      gfc_error ("'%s' at %L overrides a PUBLIC procedure and must not be"
3839
                 " PRIVATE", proc->name, &where);
3840
      return FAILURE;
3841
    }
3842
 
3843
  /* Compare the formal argument lists of both procedures.  This is also abused
3844
     to find the position of the passed-object dummy arguments of both
3845
     bindings as at least the overridden one might not yet be resolved and we
3846
     need those positions in the check below.  */
3847
  proc_pass_arg = old_pass_arg = 0;
3848
  if (!proc->n.tb->nopass && !proc->n.tb->pass_arg)
3849
    proc_pass_arg = 1;
3850
  if (!old->n.tb->nopass && !old->n.tb->pass_arg)
3851
    old_pass_arg = 1;
3852
  argpos = 1;
3853
  for (proc_formal = proc_target->formal, old_formal = old_target->formal;
3854
       proc_formal && old_formal;
3855
       proc_formal = proc_formal->next, old_formal = old_formal->next)
3856
    {
3857
      if (proc->n.tb->pass_arg
3858
          && !strcmp (proc->n.tb->pass_arg, proc_formal->sym->name))
3859
        proc_pass_arg = argpos;
3860
      if (old->n.tb->pass_arg
3861
          && !strcmp (old->n.tb->pass_arg, old_formal->sym->name))
3862
        old_pass_arg = argpos;
3863
 
3864
      /* Check that the names correspond.  */
3865
      if (strcmp (proc_formal->sym->name, old_formal->sym->name))
3866
        {
3867
          gfc_error ("Dummy argument '%s' of '%s' at %L should be named '%s' as"
3868
                     " to match the corresponding argument of the overridden"
3869
                     " procedure", proc_formal->sym->name, proc->name, &where,
3870
                     old_formal->sym->name);
3871
          return FAILURE;
3872
        }
3873
 
3874
      check_type = proc_pass_arg != argpos && old_pass_arg != argpos;
3875
      if (check_dummy_characteristics (proc_formal->sym, old_formal->sym,
3876
                                       check_type, err, sizeof(err)) == FAILURE)
3877
        {
3878
          gfc_error ("Argument mismatch for the overriding procedure "
3879
                     "'%s' at %L: %s", proc->name, &where, err);
3880
          return FAILURE;
3881
        }
3882
 
3883
      ++argpos;
3884
    }
3885
  if (proc_formal || old_formal)
3886
    {
3887
      gfc_error ("'%s' at %L must have the same number of formal arguments as"
3888
                 " the overridden procedure", proc->name, &where);
3889
      return FAILURE;
3890
    }
3891
 
3892
  /* If the overridden binding is NOPASS, the overriding one must also be
3893
     NOPASS.  */
3894
  if (old->n.tb->nopass && !proc->n.tb->nopass)
3895
    {
3896
      gfc_error ("'%s' at %L overrides a NOPASS binding and must also be"
3897
                 " NOPASS", proc->name, &where);
3898
      return FAILURE;
3899
    }
3900
 
3901
  /* If the overridden binding is PASS(x), the overriding one must also be
3902
     PASS and the passed-object dummy arguments must correspond.  */
3903
  if (!old->n.tb->nopass)
3904
    {
3905
      if (proc->n.tb->nopass)
3906
        {
3907
          gfc_error ("'%s' at %L overrides a binding with PASS and must also be"
3908
                     " PASS", proc->name, &where);
3909
          return FAILURE;
3910
        }
3911
 
3912
      if (proc_pass_arg != old_pass_arg)
3913
        {
3914
          gfc_error ("Passed-object dummy argument of '%s' at %L must be at"
3915
                     " the same position as the passed-object dummy argument of"
3916
                     " the overridden procedure", proc->name, &where);
3917
          return FAILURE;
3918
        }
3919
    }
3920
 
3921
  return SUCCESS;
3922
}

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