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[/] [openrisc/] [trunk/] [gnu-dev/] [or1k-gcc/] [gcc/] [fortran/] [module.c] - Blame information for rev 801

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1 712 jeremybenn
/* Handle modules, which amounts to loading and saving symbols and
2
   their attendant structures.
3
   Copyright (C) 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008,
4
   2009, 2010, 2011, 2012
5
   Free Software Foundation, Inc.
6
   Contributed by Andy Vaught
7
 
8
This file is part of GCC.
9
 
10
GCC is free software; you can redistribute it and/or modify it under
11
the terms of the GNU General Public License as published by the Free
12
Software Foundation; either version 3, or (at your option) any later
13
version.
14
 
15
GCC is distributed in the hope that it will be useful, but WITHOUT ANY
16
WARRANTY; without even the implied warranty of MERCHANTABILITY or
17
FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
18
for more details.
19
 
20
You should have received a copy of the GNU General Public License
21
along with GCC; see the file COPYING3.  If not see
22
<http://www.gnu.org/licenses/>.  */
23
 
24
/* The syntax of gfortran modules resembles that of lisp lists, i.e. a
25
   sequence of atoms, which can be left or right parenthesis, names,
26
   integers or strings.  Parenthesis are always matched which allows
27
   us to skip over sections at high speed without having to know
28
   anything about the internal structure of the lists.  A "name" is
29
   usually a fortran 95 identifier, but can also start with '@' in
30
   order to reference a hidden symbol.
31
 
32
   The first line of a module is an informational message about what
33
   created the module, the file it came from and when it was created.
34
   The second line is a warning for people not to edit the module.
35
   The rest of the module looks like:
36
 
37
   ( ( <Interface info for UPLUS> )
38
     ( <Interface info for UMINUS> )
39
     ...
40
   )
41
   ( ( <name of operator interface> <module of op interface> <i/f1> ... )
42
     ...
43
   )
44
   ( ( <name of generic interface> <module of generic interface> <i/f1> ... )
45
     ...
46
   )
47
   ( ( <common name> <symbol> <saved flag>)
48
     ...
49
   )
50
 
51
   ( equivalence list )
52
 
53
   ( <Symbol Number (in no particular order)>
54
     <True name of symbol>
55
     <Module name of symbol>
56
     ( <symbol information> )
57
     ...
58
   )
59
   ( <Symtree name>
60
     <Ambiguous flag>
61
     <Symbol number>
62
     ...
63
   )
64
 
65
   In general, symbols refer to other symbols by their symbol number,
66
   which are zero based.  Symbols are written to the module in no
67
   particular order.  */
68
 
69
#include "config.h"
70
#include "system.h"
71
#include "gfortran.h"
72
#include "arith.h"
73
#include "match.h"
74
#include "parse.h" /* FIXME */
75
#include "md5.h"
76
#include "constructor.h"
77
#include "cpp.h"
78
#include "tree.h"
79
 
80
#define MODULE_EXTENSION ".mod"
81
 
82
/* Don't put any single quote (') in MOD_VERSION,
83
   if yout want it to be recognized.  */
84
#define MOD_VERSION "9"
85
 
86
 
87
/* Structure that describes a position within a module file.  */
88
 
89
typedef struct
90
{
91
  int column, line;
92
  fpos_t pos;
93
}
94
module_locus;
95
 
96
/* Structure for list of symbols of intrinsic modules.  */
97
typedef struct
98
{
99
  int id;
100
  const char *name;
101
  int value;
102
  int standard;
103
}
104
intmod_sym;
105
 
106
 
107
typedef enum
108
{
109
  P_UNKNOWN = 0, P_OTHER, P_NAMESPACE, P_COMPONENT, P_SYMBOL
110
}
111
pointer_t;
112
 
113
/* The fixup structure lists pointers to pointers that have to
114
   be updated when a pointer value becomes known.  */
115
 
116
typedef struct fixup_t
117
{
118
  void **pointer;
119
  struct fixup_t *next;
120
}
121
fixup_t;
122
 
123
 
124
/* Structure for holding extra info needed for pointers being read.  */
125
 
126
enum gfc_rsym_state
127
{
128
  UNUSED,
129
  NEEDED,
130
  USED
131
};
132
 
133
enum gfc_wsym_state
134
{
135
  UNREFERENCED = 0,
136
  NEEDS_WRITE,
137
  WRITTEN
138
};
139
 
140
typedef struct pointer_info
141
{
142
  BBT_HEADER (pointer_info);
143
  int integer;
144
  pointer_t type;
145
 
146
  /* The first component of each member of the union is the pointer
147
     being stored.  */
148
 
149
  fixup_t *fixup;
150
 
151
  union
152
  {
153
    void *pointer;      /* Member for doing pointer searches.  */
154
 
155
    struct
156
    {
157
      gfc_symbol *sym;
158
      char *true_name, *module, *binding_label;
159
      fixup_t *stfixup;
160
      gfc_symtree *symtree;
161
      enum gfc_rsym_state state;
162
      int ns, referenced, renamed;
163
      module_locus where;
164
    }
165
    rsym;
166
 
167
    struct
168
    {
169
      gfc_symbol *sym;
170
      enum gfc_wsym_state state;
171
    }
172
    wsym;
173
  }
174
  u;
175
 
176
}
177
pointer_info;
178
 
179
#define gfc_get_pointer_info() XCNEW (pointer_info)
180
 
181
 
182
/* Local variables */
183
 
184
/* The FILE for the module we're reading or writing.  */
185
static FILE *module_fp;
186
 
187
/* MD5 context structure.  */
188
static struct md5_ctx ctx;
189
 
190
/* The name of the module we're reading (USE'ing) or writing.  */
191
static const char *module_name;
192
static gfc_use_list *module_list;
193
 
194
static int module_line, module_column, only_flag;
195
static int prev_module_line, prev_module_column, prev_character;
196
 
197
static enum
198
{ IO_INPUT, IO_OUTPUT }
199
iomode;
200
 
201
static gfc_use_rename *gfc_rename_list;
202
static pointer_info *pi_root;
203
static int symbol_number;       /* Counter for assigning symbol numbers */
204
 
205
/* Tells mio_expr_ref to make symbols for unused equivalence members.  */
206
static bool in_load_equiv;
207
 
208
 
209
 
210
/*****************************************************************/
211
 
212
/* Pointer/integer conversion.  Pointers between structures are stored
213
   as integers in the module file.  The next couple of subroutines
214
   handle this translation for reading and writing.  */
215
 
216
/* Recursively free the tree of pointer structures.  */
217
 
218
static void
219
free_pi_tree (pointer_info *p)
220
{
221
  if (p == NULL)
222
    return;
223
 
224
  if (p->fixup != NULL)
225
    gfc_internal_error ("free_pi_tree(): Unresolved fixup");
226
 
227
  free_pi_tree (p->left);
228
  free_pi_tree (p->right);
229
 
230
  if (iomode == IO_INPUT)
231
    {
232
      XDELETEVEC (p->u.rsym.true_name);
233
      XDELETEVEC (p->u.rsym.module);
234
      XDELETEVEC (p->u.rsym.binding_label);
235
    }
236
 
237
  free (p);
238
}
239
 
240
 
241
/* Compare pointers when searching by pointer.  Used when writing a
242
   module.  */
243
 
244
static int
245
compare_pointers (void *_sn1, void *_sn2)
246
{
247
  pointer_info *sn1, *sn2;
248
 
249
  sn1 = (pointer_info *) _sn1;
250
  sn2 = (pointer_info *) _sn2;
251
 
252
  if (sn1->u.pointer < sn2->u.pointer)
253
    return -1;
254
  if (sn1->u.pointer > sn2->u.pointer)
255
    return 1;
256
 
257
  return 0;
258
}
259
 
260
 
261
/* Compare integers when searching by integer.  Used when reading a
262
   module.  */
263
 
264
static int
265
compare_integers (void *_sn1, void *_sn2)
266
{
267
  pointer_info *sn1, *sn2;
268
 
269
  sn1 = (pointer_info *) _sn1;
270
  sn2 = (pointer_info *) _sn2;
271
 
272
  if (sn1->integer < sn2->integer)
273
    return -1;
274
  if (sn1->integer > sn2->integer)
275
    return 1;
276
 
277
  return 0;
278
}
279
 
280
 
281
/* Initialize the pointer_info tree.  */
282
 
283
static void
284
init_pi_tree (void)
285
{
286
  compare_fn compare;
287
  pointer_info *p;
288
 
289
  pi_root = NULL;
290
  compare = (iomode == IO_INPUT) ? compare_integers : compare_pointers;
291
 
292
  /* Pointer 0 is the NULL pointer.  */
293
  p = gfc_get_pointer_info ();
294
  p->u.pointer = NULL;
295
  p->integer = 0;
296
  p->type = P_OTHER;
297
 
298
  gfc_insert_bbt (&pi_root, p, compare);
299
 
300
  /* Pointer 1 is the current namespace.  */
301
  p = gfc_get_pointer_info ();
302
  p->u.pointer = gfc_current_ns;
303
  p->integer = 1;
304
  p->type = P_NAMESPACE;
305
 
306
  gfc_insert_bbt (&pi_root, p, compare);
307
 
308
  symbol_number = 2;
309
}
310
 
311
 
312
/* During module writing, call here with a pointer to something,
313
   returning the pointer_info node.  */
314
 
315
static pointer_info *
316
find_pointer (void *gp)
317
{
318
  pointer_info *p;
319
 
320
  p = pi_root;
321
  while (p != NULL)
322
    {
323
      if (p->u.pointer == gp)
324
        break;
325
      p = (gp < p->u.pointer) ? p->left : p->right;
326
    }
327
 
328
  return p;
329
}
330
 
331
 
332
/* Given a pointer while writing, returns the pointer_info tree node,
333
   creating it if it doesn't exist.  */
334
 
335
static pointer_info *
336
get_pointer (void *gp)
337
{
338
  pointer_info *p;
339
 
340
  p = find_pointer (gp);
341
  if (p != NULL)
342
    return p;
343
 
344
  /* Pointer doesn't have an integer.  Give it one.  */
345
  p = gfc_get_pointer_info ();
346
 
347
  p->u.pointer = gp;
348
  p->integer = symbol_number++;
349
 
350
  gfc_insert_bbt (&pi_root, p, compare_pointers);
351
 
352
  return p;
353
}
354
 
355
 
356
/* Given an integer during reading, find it in the pointer_info tree,
357
   creating the node if not found.  */
358
 
359
static pointer_info *
360
get_integer (int integer)
361
{
362
  pointer_info *p, t;
363
  int c;
364
 
365
  t.integer = integer;
366
 
367
  p = pi_root;
368
  while (p != NULL)
369
    {
370
      c = compare_integers (&t, p);
371
      if (c == 0)
372
        break;
373
 
374
      p = (c < 0) ? p->left : p->right;
375
    }
376
 
377
  if (p != NULL)
378
    return p;
379
 
380
  p = gfc_get_pointer_info ();
381
  p->integer = integer;
382
  p->u.pointer = NULL;
383
 
384
  gfc_insert_bbt (&pi_root, p, compare_integers);
385
 
386
  return p;
387
}
388
 
389
 
390
/* Recursive function to find a pointer within a tree by brute force.  */
391
 
392
static pointer_info *
393
fp2 (pointer_info *p, const void *target)
394
{
395
  pointer_info *q;
396
 
397
  if (p == NULL)
398
    return NULL;
399
 
400
  if (p->u.pointer == target)
401
    return p;
402
 
403
  q = fp2 (p->left, target);
404
  if (q != NULL)
405
    return q;
406
 
407
  return fp2 (p->right, target);
408
}
409
 
410
 
411
/* During reading, find a pointer_info node from the pointer value.
412
   This amounts to a brute-force search.  */
413
 
414
static pointer_info *
415
find_pointer2 (void *p)
416
{
417
  return fp2 (pi_root, p);
418
}
419
 
420
 
421
/* Resolve any fixups using a known pointer.  */
422
 
423
static void
424
resolve_fixups (fixup_t *f, void *gp)
425
{
426
  fixup_t *next;
427
 
428
  for (; f; f = next)
429
    {
430
      next = f->next;
431
      *(f->pointer) = gp;
432
      free (f);
433
    }
434
}
435
 
436
 
437
/* Convert a string such that it starts with a lower-case character. Used
438
   to convert the symtree name of a derived-type to the symbol name or to
439
   the name of the associated generic function.  */
440
 
441
static const char *
442
dt_lower_string (const char *name)
443
{
444
  if (name[0] != (char) TOLOWER ((unsigned char) name[0]))
445
    return gfc_get_string ("%c%s", (char) TOLOWER ((unsigned char) name[0]),
446
                           &name[1]);
447
  return gfc_get_string (name);
448
}
449
 
450
 
451
/* Convert a string such that it starts with an upper-case character. Used to
452
   return the symtree-name for a derived type; the symbol name itself and the
453
   symtree/symbol name of the associated generic function start with a lower-
454
   case character.  */
455
 
456
static const char *
457
dt_upper_string (const char *name)
458
{
459
  if (name[0] != (char) TOUPPER ((unsigned char) name[0]))
460
    return gfc_get_string ("%c%s", (char) TOUPPER ((unsigned char) name[0]),
461
                           &name[1]);
462
  return gfc_get_string (name);
463
}
464
 
465
/* Call here during module reading when we know what pointer to
466
   associate with an integer.  Any fixups that exist are resolved at
467
   this time.  */
468
 
469
static void
470
associate_integer_pointer (pointer_info *p, void *gp)
471
{
472
  if (p->u.pointer != NULL)
473
    gfc_internal_error ("associate_integer_pointer(): Already associated");
474
 
475
  p->u.pointer = gp;
476
 
477
  resolve_fixups (p->fixup, gp);
478
 
479
  p->fixup = NULL;
480
}
481
 
482
 
483
/* During module reading, given an integer and a pointer to a pointer,
484
   either store the pointer from an already-known value or create a
485
   fixup structure in order to store things later.  Returns zero if
486
   the reference has been actually stored, or nonzero if the reference
487
   must be fixed later (i.e., associate_integer_pointer must be called
488
   sometime later.  Returns the pointer_info structure.  */
489
 
490
static pointer_info *
491
add_fixup (int integer, void *gp)
492
{
493
  pointer_info *p;
494
  fixup_t *f;
495
  char **cp;
496
 
497
  p = get_integer (integer);
498
 
499
  if (p->integer == 0 || p->u.pointer != NULL)
500
    {
501
      cp = (char **) gp;
502
      *cp = (char *) p->u.pointer;
503
    }
504
  else
505
    {
506
      f = XCNEW (fixup_t);
507
 
508
      f->next = p->fixup;
509
      p->fixup = f;
510
 
511
      f->pointer = (void **) gp;
512
    }
513
 
514
  return p;
515
}
516
 
517
 
518
/*****************************************************************/
519
 
520
/* Parser related subroutines */
521
 
522
/* Free the rename list left behind by a USE statement.  */
523
 
524
static void
525
free_rename (gfc_use_rename *list)
526
{
527
  gfc_use_rename *next;
528
 
529
  for (; list; list = next)
530
    {
531
      next = list->next;
532
      free (list);
533
    }
534
}
535
 
536
 
537
/* Match a USE statement.  */
538
 
539
match
540
gfc_match_use (void)
541
{
542
  char name[GFC_MAX_SYMBOL_LEN + 1], module_nature[GFC_MAX_SYMBOL_LEN + 1];
543
  gfc_use_rename *tail = NULL, *new_use;
544
  interface_type type, type2;
545
  gfc_intrinsic_op op;
546
  match m;
547
  gfc_use_list *use_list;
548
 
549
  use_list = gfc_get_use_list ();
550
 
551
  if (gfc_match (" , ") == MATCH_YES)
552
    {
553
      if ((m = gfc_match (" %n ::", module_nature)) == MATCH_YES)
554
        {
555
          if (gfc_notify_std (GFC_STD_F2003, "Fortran 2003: module "
556
                              "nature in USE statement at %C") == FAILURE)
557
            goto cleanup;
558
 
559
          if (strcmp (module_nature, "intrinsic") == 0)
560
            use_list->intrinsic = true;
561
          else
562
            {
563
              if (strcmp (module_nature, "non_intrinsic") == 0)
564
                use_list->non_intrinsic = true;
565
              else
566
                {
567
                  gfc_error ("Module nature in USE statement at %C shall "
568
                             "be either INTRINSIC or NON_INTRINSIC");
569
                  goto cleanup;
570
                }
571
            }
572
        }
573
      else
574
        {
575
          /* Help output a better error message than "Unclassifiable
576
             statement".  */
577
          gfc_match (" %n", module_nature);
578
          if (strcmp (module_nature, "intrinsic") == 0
579
              || strcmp (module_nature, "non_intrinsic") == 0)
580
            gfc_error ("\"::\" was expected after module nature at %C "
581
                       "but was not found");
582
          free (use_list);
583
          return m;
584
        }
585
    }
586
  else
587
    {
588
      m = gfc_match (" ::");
589
      if (m == MATCH_YES &&
590
          gfc_notify_std (GFC_STD_F2003, "Fortran 2003: "
591
                          "\"USE :: module\" at %C") == FAILURE)
592
        goto cleanup;
593
 
594
      if (m != MATCH_YES)
595
        {
596
          m = gfc_match ("% ");
597
          if (m != MATCH_YES)
598
            {
599
              free (use_list);
600
              return m;
601
            }
602
        }
603
    }
604
 
605
  use_list->where = gfc_current_locus;
606
 
607
  m = gfc_match_name (name);
608
  if (m != MATCH_YES)
609
    {
610
      free (use_list);
611
      return m;
612
    }
613
 
614
  use_list->module_name = gfc_get_string (name);
615
 
616
  if (gfc_match_eos () == MATCH_YES)
617
    goto done;
618
 
619
  if (gfc_match_char (',') != MATCH_YES)
620
    goto syntax;
621
 
622
  if (gfc_match (" only :") == MATCH_YES)
623
    use_list->only_flag = true;
624
 
625
  if (gfc_match_eos () == MATCH_YES)
626
    goto done;
627
 
628
  for (;;)
629
    {
630
      /* Get a new rename struct and add it to the rename list.  */
631
      new_use = gfc_get_use_rename ();
632
      new_use->where = gfc_current_locus;
633
      new_use->found = 0;
634
 
635
      if (use_list->rename == NULL)
636
        use_list->rename = new_use;
637
      else
638
        tail->next = new_use;
639
      tail = new_use;
640
 
641
      /* See what kind of interface we're dealing with.  Assume it is
642
         not an operator.  */
643
      new_use->op = INTRINSIC_NONE;
644
      if (gfc_match_generic_spec (&type, name, &op) == MATCH_ERROR)
645
        goto cleanup;
646
 
647
      switch (type)
648
        {
649
        case INTERFACE_NAMELESS:
650
          gfc_error ("Missing generic specification in USE statement at %C");
651
          goto cleanup;
652
 
653
        case INTERFACE_USER_OP:
654
        case INTERFACE_GENERIC:
655
          m = gfc_match (" =>");
656
 
657
          if (type == INTERFACE_USER_OP && m == MATCH_YES
658
              && (gfc_notify_std (GFC_STD_F2003, "Fortran 2003: Renaming "
659
                                  "operators in USE statements at %C")
660
                 == FAILURE))
661
            goto cleanup;
662
 
663
          if (type == INTERFACE_USER_OP)
664
            new_use->op = INTRINSIC_USER;
665
 
666
          if (use_list->only_flag)
667
            {
668
              if (m != MATCH_YES)
669
                strcpy (new_use->use_name, name);
670
              else
671
                {
672
                  strcpy (new_use->local_name, name);
673
                  m = gfc_match_generic_spec (&type2, new_use->use_name, &op);
674
                  if (type != type2)
675
                    goto syntax;
676
                  if (m == MATCH_NO)
677
                    goto syntax;
678
                  if (m == MATCH_ERROR)
679
                    goto cleanup;
680
                }
681
            }
682
          else
683
            {
684
              if (m != MATCH_YES)
685
                goto syntax;
686
              strcpy (new_use->local_name, name);
687
 
688
              m = gfc_match_generic_spec (&type2, new_use->use_name, &op);
689
              if (type != type2)
690
                goto syntax;
691
              if (m == MATCH_NO)
692
                goto syntax;
693
              if (m == MATCH_ERROR)
694
                goto cleanup;
695
            }
696
 
697
          if (strcmp (new_use->use_name, use_list->module_name) == 0
698
              || strcmp (new_use->local_name, use_list->module_name) == 0)
699
            {
700
              gfc_error ("The name '%s' at %C has already been used as "
701
                         "an external module name.", use_list->module_name);
702
              goto cleanup;
703
            }
704
          break;
705
 
706
        case INTERFACE_INTRINSIC_OP:
707
          new_use->op = op;
708
          break;
709
 
710
        default:
711
          gcc_unreachable ();
712
        }
713
 
714
      if (gfc_match_eos () == MATCH_YES)
715
        break;
716
      if (gfc_match_char (',') != MATCH_YES)
717
        goto syntax;
718
    }
719
 
720
done:
721
  if (module_list)
722
    {
723
      gfc_use_list *last = module_list;
724
      while (last->next)
725
        last = last->next;
726
      last->next = use_list;
727
    }
728
  else
729
    module_list = use_list;
730
 
731
  return MATCH_YES;
732
 
733
syntax:
734
  gfc_syntax_error (ST_USE);
735
 
736
cleanup:
737
  free_rename (use_list->rename);
738
  free (use_list);
739
  return MATCH_ERROR;
740
}
741
 
742
 
743
/* Given a name and a number, inst, return the inst name
744
   under which to load this symbol. Returns NULL if this
745
   symbol shouldn't be loaded. If inst is zero, returns
746
   the number of instances of this name. If interface is
747
   true, a user-defined operator is sought, otherwise only
748
   non-operators are sought.  */
749
 
750
static const char *
751
find_use_name_n (const char *name, int *inst, bool interface)
752
{
753
  gfc_use_rename *u;
754
  const char *low_name = NULL;
755
  int i;
756
 
757
  /* For derived types.  */
758
  if (name[0] != (char) TOLOWER ((unsigned char) name[0]))
759
    low_name = dt_lower_string (name);
760
 
761
  i = 0;
762
  for (u = gfc_rename_list; u; u = u->next)
763
    {
764
      if ((!low_name && strcmp (u->use_name, name) != 0)
765
          || (low_name && strcmp (u->use_name, low_name) != 0)
766
          || (u->op == INTRINSIC_USER && !interface)
767
          || (u->op != INTRINSIC_USER &&  interface))
768
        continue;
769
      if (++i == *inst)
770
        break;
771
    }
772
 
773
  if (!*inst)
774
    {
775
      *inst = i;
776
      return NULL;
777
    }
778
 
779
  if (u == NULL)
780
    return only_flag ? NULL : name;
781
 
782
  u->found = 1;
783
 
784
  if (low_name)
785
    {
786
      if (u->local_name[0] == '\0')
787
        return name;
788
      return dt_upper_string (u->local_name);
789
    }
790
 
791
  return (u->local_name[0] != '\0') ? u->local_name : name;
792
}
793
 
794
 
795
/* Given a name, return the name under which to load this symbol.
796
   Returns NULL if this symbol shouldn't be loaded.  */
797
 
798
static const char *
799
find_use_name (const char *name, bool interface)
800
{
801
  int i = 1;
802
  return find_use_name_n (name, &i, interface);
803
}
804
 
805
 
806
/* Given a real name, return the number of use names associated with it.  */
807
 
808
static int
809
number_use_names (const char *name, bool interface)
810
{
811
  int i = 0;
812
  find_use_name_n (name, &i, interface);
813
  return i;
814
}
815
 
816
 
817
/* Try to find the operator in the current list.  */
818
 
819
static gfc_use_rename *
820
find_use_operator (gfc_intrinsic_op op)
821
{
822
  gfc_use_rename *u;
823
 
824
  for (u = gfc_rename_list; u; u = u->next)
825
    if (u->op == op)
826
      return u;
827
 
828
  return NULL;
829
}
830
 
831
 
832
/*****************************************************************/
833
 
834
/* The next couple of subroutines maintain a tree used to avoid a
835
   brute-force search for a combination of true name and module name.
836
   While symtree names, the name that a particular symbol is known by
837
   can changed with USE statements, we still have to keep track of the
838
   true names to generate the correct reference, and also avoid
839
   loading the same real symbol twice in a program unit.
840
 
841
   When we start reading, the true name tree is built and maintained
842
   as symbols are read.  The tree is searched as we load new symbols
843
   to see if it already exists someplace in the namespace.  */
844
 
845
typedef struct true_name
846
{
847
  BBT_HEADER (true_name);
848
  const char *name;
849
  gfc_symbol *sym;
850
}
851
true_name;
852
 
853
static true_name *true_name_root;
854
 
855
 
856
/* Compare two true_name structures.  */
857
 
858
static int
859
compare_true_names (void *_t1, void *_t2)
860
{
861
  true_name *t1, *t2;
862
  int c;
863
 
864
  t1 = (true_name *) _t1;
865
  t2 = (true_name *) _t2;
866
 
867
  c = ((t1->sym->module > t2->sym->module)
868
       - (t1->sym->module < t2->sym->module));
869
  if (c != 0)
870
    return c;
871
 
872
  return strcmp (t1->name, t2->name);
873
}
874
 
875
 
876
/* Given a true name, search the true name tree to see if it exists
877
   within the main namespace.  */
878
 
879
static gfc_symbol *
880
find_true_name (const char *name, const char *module)
881
{
882
  true_name t, *p;
883
  gfc_symbol sym;
884
  int c;
885
 
886
  t.name = gfc_get_string (name);
887
  if (module != NULL)
888
    sym.module = gfc_get_string (module);
889
  else
890
    sym.module = NULL;
891
  t.sym = &sym;
892
 
893
  p = true_name_root;
894
  while (p != NULL)
895
    {
896
      c = compare_true_names ((void *) (&t), (void *) p);
897
      if (c == 0)
898
        return p->sym;
899
 
900
      p = (c < 0) ? p->left : p->right;
901
    }
902
 
903
  return NULL;
904
}
905
 
906
 
907
/* Given a gfc_symbol pointer that is not in the true name tree, add it.  */
908
 
909
static void
910
add_true_name (gfc_symbol *sym)
911
{
912
  true_name *t;
913
 
914
  t = XCNEW (true_name);
915
  t->sym = sym;
916
  if (sym->attr.flavor == FL_DERIVED)
917
    t->name = dt_upper_string (sym->name);
918
  else
919
    t->name = sym->name;
920
 
921
  gfc_insert_bbt (&true_name_root, t, compare_true_names);
922
}
923
 
924
 
925
/* Recursive function to build the initial true name tree by
926
   recursively traversing the current namespace.  */
927
 
928
static void
929
build_tnt (gfc_symtree *st)
930
{
931
  const char *name;
932
  if (st == NULL)
933
    return;
934
 
935
  build_tnt (st->left);
936
  build_tnt (st->right);
937
 
938
  if (st->n.sym->attr.flavor == FL_DERIVED)
939
    name = dt_upper_string (st->n.sym->name);
940
  else
941
    name = st->n.sym->name;
942
 
943
  if (find_true_name (name, st->n.sym->module) != NULL)
944
    return;
945
 
946
  add_true_name (st->n.sym);
947
}
948
 
949
 
950
/* Initialize the true name tree with the current namespace.  */
951
 
952
static void
953
init_true_name_tree (void)
954
{
955
  true_name_root = NULL;
956
  build_tnt (gfc_current_ns->sym_root);
957
}
958
 
959
 
960
/* Recursively free a true name tree node.  */
961
 
962
static void
963
free_true_name (true_name *t)
964
{
965
  if (t == NULL)
966
    return;
967
  free_true_name (t->left);
968
  free_true_name (t->right);
969
 
970
  free (t);
971
}
972
 
973
 
974
/*****************************************************************/
975
 
976
/* Module reading and writing.  */
977
 
978
typedef enum
979
{
980
  ATOM_NAME, ATOM_LPAREN, ATOM_RPAREN, ATOM_INTEGER, ATOM_STRING
981
}
982
atom_type;
983
 
984
static atom_type last_atom;
985
 
986
 
987
/* The name buffer must be at least as long as a symbol name.  Right
988
   now it's not clear how we're going to store numeric constants--
989
   probably as a hexadecimal string, since this will allow the exact
990
   number to be preserved (this can't be done by a decimal
991
   representation).  Worry about that later.  TODO!  */
992
 
993
#define MAX_ATOM_SIZE 100
994
 
995
static int atom_int;
996
static char *atom_string, atom_name[MAX_ATOM_SIZE];
997
 
998
 
999
/* Report problems with a module.  Error reporting is not very
1000
   elaborate, since this sorts of errors shouldn't really happen.
1001
   This subroutine never returns.  */
1002
 
1003
static void bad_module (const char *) ATTRIBUTE_NORETURN;
1004
 
1005
static void
1006
bad_module (const char *msgid)
1007
{
1008
  fclose (module_fp);
1009
 
1010
  switch (iomode)
1011
    {
1012
    case IO_INPUT:
1013
      gfc_fatal_error ("Reading module %s at line %d column %d: %s",
1014
                       module_name, module_line, module_column, msgid);
1015
      break;
1016
    case IO_OUTPUT:
1017
      gfc_fatal_error ("Writing module %s at line %d column %d: %s",
1018
                       module_name, module_line, module_column, msgid);
1019
      break;
1020
    default:
1021
      gfc_fatal_error ("Module %s at line %d column %d: %s",
1022
                       module_name, module_line, module_column, msgid);
1023
      break;
1024
    }
1025
}
1026
 
1027
 
1028
/* Set the module's input pointer.  */
1029
 
1030
static void
1031
set_module_locus (module_locus *m)
1032
{
1033
  module_column = m->column;
1034
  module_line = m->line;
1035
  fsetpos (module_fp, &m->pos);
1036
}
1037
 
1038
 
1039
/* Get the module's input pointer so that we can restore it later.  */
1040
 
1041
static void
1042
get_module_locus (module_locus *m)
1043
{
1044
  m->column = module_column;
1045
  m->line = module_line;
1046
  fgetpos (module_fp, &m->pos);
1047
}
1048
 
1049
 
1050
/* Get the next character in the module, updating our reckoning of
1051
   where we are.  */
1052
 
1053
static int
1054
module_char (void)
1055
{
1056
  int c;
1057
 
1058
  c = getc (module_fp);
1059
 
1060
  if (c == EOF)
1061
    bad_module ("Unexpected EOF");
1062
 
1063
  prev_module_line = module_line;
1064
  prev_module_column = module_column;
1065
  prev_character = c;
1066
 
1067
  if (c == '\n')
1068
    {
1069
      module_line++;
1070
      module_column = 0;
1071
    }
1072
 
1073
  module_column++;
1074
  return c;
1075
}
1076
 
1077
/* Unget a character while remembering the line and column.  Works for
1078
   a single character only.  */
1079
 
1080
static void
1081
module_unget_char (void)
1082
{
1083
  module_line = prev_module_line;
1084
  module_column = prev_module_column;
1085
  ungetc (prev_character, module_fp);
1086
}
1087
 
1088
/* Parse a string constant.  The delimiter is guaranteed to be a
1089
   single quote.  */
1090
 
1091
static void
1092
parse_string (void)
1093
{
1094
  int c;
1095
  size_t cursz = 30;
1096
  size_t len = 0;
1097
 
1098
  atom_string = XNEWVEC (char, cursz);
1099
 
1100
  for ( ; ; )
1101
    {
1102
      c = module_char ();
1103
 
1104
      if (c == '\'')
1105
        {
1106
          int c2 = module_char ();
1107
          if (c2 != '\'')
1108
            {
1109
              module_unget_char ();
1110
              break;
1111
            }
1112
        }
1113
 
1114
      if (len >= cursz)
1115
        {
1116
          cursz *= 2;
1117
          atom_string = XRESIZEVEC (char, atom_string, cursz);
1118
        }
1119
      atom_string[len] = c;
1120
      len++;
1121
    }
1122
 
1123
  atom_string = XRESIZEVEC (char, atom_string, len + 1);
1124
  atom_string[len] = '\0';      /* C-style string for debug purposes.  */
1125
}
1126
 
1127
 
1128
/* Parse a small integer.  */
1129
 
1130
static void
1131
parse_integer (int c)
1132
{
1133
  atom_int = c - '0';
1134
 
1135
  for (;;)
1136
    {
1137
      c = module_char ();
1138
      if (!ISDIGIT (c))
1139
        {
1140
          module_unget_char ();
1141
          break;
1142
        }
1143
 
1144
      atom_int = 10 * atom_int + c - '0';
1145
      if (atom_int > 99999999)
1146
        bad_module ("Integer overflow");
1147
    }
1148
 
1149
}
1150
 
1151
 
1152
/* Parse a name.  */
1153
 
1154
static void
1155
parse_name (int c)
1156
{
1157
  char *p;
1158
  int len;
1159
 
1160
  p = atom_name;
1161
 
1162
  *p++ = c;
1163
  len = 1;
1164
 
1165
  for (;;)
1166
    {
1167
      c = module_char ();
1168
      if (!ISALNUM (c) && c != '_' && c != '-')
1169
        {
1170
          module_unget_char ();
1171
          break;
1172
        }
1173
 
1174
      *p++ = c;
1175
      if (++len > GFC_MAX_SYMBOL_LEN)
1176
        bad_module ("Name too long");
1177
    }
1178
 
1179
  *p = '\0';
1180
 
1181
}
1182
 
1183
 
1184
/* Read the next atom in the module's input stream.  */
1185
 
1186
static atom_type
1187
parse_atom (void)
1188
{
1189
  int c;
1190
 
1191
  do
1192
    {
1193
      c = module_char ();
1194
    }
1195
  while (c == ' ' || c == '\r' || c == '\n');
1196
 
1197
  switch (c)
1198
    {
1199
    case '(':
1200
      return ATOM_LPAREN;
1201
 
1202
    case ')':
1203
      return ATOM_RPAREN;
1204
 
1205
    case '\'':
1206
      parse_string ();
1207
      return ATOM_STRING;
1208
 
1209
    case '0':
1210
    case '1':
1211
    case '2':
1212
    case '3':
1213
    case '4':
1214
    case '5':
1215
    case '6':
1216
    case '7':
1217
    case '8':
1218
    case '9':
1219
      parse_integer (c);
1220
      return ATOM_INTEGER;
1221
 
1222
    case 'a':
1223
    case 'b':
1224
    case 'c':
1225
    case 'd':
1226
    case 'e':
1227
    case 'f':
1228
    case 'g':
1229
    case 'h':
1230
    case 'i':
1231
    case 'j':
1232
    case 'k':
1233
    case 'l':
1234
    case 'm':
1235
    case 'n':
1236
    case 'o':
1237
    case 'p':
1238
    case 'q':
1239
    case 'r':
1240
    case 's':
1241
    case 't':
1242
    case 'u':
1243
    case 'v':
1244
    case 'w':
1245
    case 'x':
1246
    case 'y':
1247
    case 'z':
1248
    case 'A':
1249
    case 'B':
1250
    case 'C':
1251
    case 'D':
1252
    case 'E':
1253
    case 'F':
1254
    case 'G':
1255
    case 'H':
1256
    case 'I':
1257
    case 'J':
1258
    case 'K':
1259
    case 'L':
1260
    case 'M':
1261
    case 'N':
1262
    case 'O':
1263
    case 'P':
1264
    case 'Q':
1265
    case 'R':
1266
    case 'S':
1267
    case 'T':
1268
    case 'U':
1269
    case 'V':
1270
    case 'W':
1271
    case 'X':
1272
    case 'Y':
1273
    case 'Z':
1274
      parse_name (c);
1275
      return ATOM_NAME;
1276
 
1277
    default:
1278
      bad_module ("Bad name");
1279
    }
1280
 
1281
  /* Not reached.  */
1282
}
1283
 
1284
 
1285
/* Peek at the next atom on the input.  */
1286
 
1287
static atom_type
1288
peek_atom (void)
1289
{
1290
  int c;
1291
 
1292
  do
1293
    {
1294
      c = module_char ();
1295
    }
1296
  while (c == ' ' || c == '\r' || c == '\n');
1297
 
1298
  switch (c)
1299
    {
1300
    case '(':
1301
      module_unget_char ();
1302
      return ATOM_LPAREN;
1303
 
1304
    case ')':
1305
      module_unget_char ();
1306
      return ATOM_RPAREN;
1307
 
1308
    case '\'':
1309
      module_unget_char ();
1310
      return ATOM_STRING;
1311
 
1312
    case '0':
1313
    case '1':
1314
    case '2':
1315
    case '3':
1316
    case '4':
1317
    case '5':
1318
    case '6':
1319
    case '7':
1320
    case '8':
1321
    case '9':
1322
      module_unget_char ();
1323
      return ATOM_INTEGER;
1324
 
1325
    case 'a':
1326
    case 'b':
1327
    case 'c':
1328
    case 'd':
1329
    case 'e':
1330
    case 'f':
1331
    case 'g':
1332
    case 'h':
1333
    case 'i':
1334
    case 'j':
1335
    case 'k':
1336
    case 'l':
1337
    case 'm':
1338
    case 'n':
1339
    case 'o':
1340
    case 'p':
1341
    case 'q':
1342
    case 'r':
1343
    case 's':
1344
    case 't':
1345
    case 'u':
1346
    case 'v':
1347
    case 'w':
1348
    case 'x':
1349
    case 'y':
1350
    case 'z':
1351
    case 'A':
1352
    case 'B':
1353
    case 'C':
1354
    case 'D':
1355
    case 'E':
1356
    case 'F':
1357
    case 'G':
1358
    case 'H':
1359
    case 'I':
1360
    case 'J':
1361
    case 'K':
1362
    case 'L':
1363
    case 'M':
1364
    case 'N':
1365
    case 'O':
1366
    case 'P':
1367
    case 'Q':
1368
    case 'R':
1369
    case 'S':
1370
    case 'T':
1371
    case 'U':
1372
    case 'V':
1373
    case 'W':
1374
    case 'X':
1375
    case 'Y':
1376
    case 'Z':
1377
      module_unget_char ();
1378
      return ATOM_NAME;
1379
 
1380
    default:
1381
      bad_module ("Bad name");
1382
    }
1383
}
1384
 
1385
 
1386
/* Read the next atom from the input, requiring that it be a
1387
   particular kind.  */
1388
 
1389
static void
1390
require_atom (atom_type type)
1391
{
1392
  atom_type t;
1393
  const char *p;
1394
  int column, line;
1395
 
1396
  column = module_column;
1397
  line = module_line;
1398
 
1399
  t = parse_atom ();
1400
  if (t != type)
1401
    {
1402
      switch (type)
1403
        {
1404
        case ATOM_NAME:
1405
          p = _("Expected name");
1406
          break;
1407
        case ATOM_LPAREN:
1408
          p = _("Expected left parenthesis");
1409
          break;
1410
        case ATOM_RPAREN:
1411
          p = _("Expected right parenthesis");
1412
          break;
1413
        case ATOM_INTEGER:
1414
          p = _("Expected integer");
1415
          break;
1416
        case ATOM_STRING:
1417
          p = _("Expected string");
1418
          break;
1419
        default:
1420
          gfc_internal_error ("require_atom(): bad atom type required");
1421
        }
1422
 
1423
      module_column = column;
1424
      module_line = line;
1425
      bad_module (p);
1426
    }
1427
}
1428
 
1429
 
1430
/* Given a pointer to an mstring array, require that the current input
1431
   be one of the strings in the array.  We return the enum value.  */
1432
 
1433
static int
1434
find_enum (const mstring *m)
1435
{
1436
  int i;
1437
 
1438
  i = gfc_string2code (m, atom_name);
1439
  if (i >= 0)
1440
    return i;
1441
 
1442
  bad_module ("find_enum(): Enum not found");
1443
 
1444
  /* Not reached.  */
1445
}
1446
 
1447
 
1448
/* Read a string. The caller is responsible for freeing.  */
1449
 
1450
static char*
1451
read_string (void)
1452
{
1453
  char* p;
1454
  require_atom (ATOM_STRING);
1455
  p = atom_string;
1456
  atom_string = NULL;
1457
  return p;
1458
}
1459
 
1460
 
1461
/**************** Module output subroutines ***************************/
1462
 
1463
/* Output a character to a module file.  */
1464
 
1465
static void
1466
write_char (char out)
1467
{
1468
  if (putc (out, module_fp) == EOF)
1469
    gfc_fatal_error ("Error writing modules file: %s", xstrerror (errno));
1470
 
1471
  /* Add this to our MD5.  */
1472
  md5_process_bytes (&out, sizeof (out), &ctx);
1473
 
1474
  if (out != '\n')
1475
    module_column++;
1476
  else
1477
    {
1478
      module_column = 1;
1479
      module_line++;
1480
    }
1481
}
1482
 
1483
 
1484
/* Write an atom to a module.  The line wrapping isn't perfect, but it
1485
   should work most of the time.  This isn't that big of a deal, since
1486
   the file really isn't meant to be read by people anyway.  */
1487
 
1488
static void
1489
write_atom (atom_type atom, const void *v)
1490
{
1491
  char buffer[20];
1492
  int i, len;
1493
  const char *p;
1494
 
1495
  switch (atom)
1496
    {
1497
    case ATOM_STRING:
1498
    case ATOM_NAME:
1499
      p = (const char *) v;
1500
      break;
1501
 
1502
    case ATOM_LPAREN:
1503
      p = "(";
1504
      break;
1505
 
1506
    case ATOM_RPAREN:
1507
      p = ")";
1508
      break;
1509
 
1510
    case ATOM_INTEGER:
1511
      i = *((const int *) v);
1512
      if (i < 0)
1513
        gfc_internal_error ("write_atom(): Writing negative integer");
1514
 
1515
      sprintf (buffer, "%d", i);
1516
      p = buffer;
1517
      break;
1518
 
1519
    default:
1520
      gfc_internal_error ("write_atom(): Trying to write dab atom");
1521
 
1522
    }
1523
 
1524
  if(p == NULL || *p == '\0')
1525
     len = 0;
1526
  else
1527
  len = strlen (p);
1528
 
1529
  if (atom != ATOM_RPAREN)
1530
    {
1531
      if (module_column + len > 72)
1532
        write_char ('\n');
1533
      else
1534
        {
1535
 
1536
          if (last_atom != ATOM_LPAREN && module_column != 1)
1537
            write_char (' ');
1538
        }
1539
    }
1540
 
1541
  if (atom == ATOM_STRING)
1542
    write_char ('\'');
1543
 
1544
  while (p != NULL && *p)
1545
    {
1546
      if (atom == ATOM_STRING && *p == '\'')
1547
        write_char ('\'');
1548
      write_char (*p++);
1549
    }
1550
 
1551
  if (atom == ATOM_STRING)
1552
    write_char ('\'');
1553
 
1554
  last_atom = atom;
1555
}
1556
 
1557
 
1558
 
1559
/***************** Mid-level I/O subroutines *****************/
1560
 
1561
/* These subroutines let their caller read or write atoms without
1562
   caring about which of the two is actually happening.  This lets a
1563
   subroutine concentrate on the actual format of the data being
1564
   written.  */
1565
 
1566
static void mio_expr (gfc_expr **);
1567
pointer_info *mio_symbol_ref (gfc_symbol **);
1568
pointer_info *mio_interface_rest (gfc_interface **);
1569
static void mio_symtree_ref (gfc_symtree **);
1570
 
1571
/* Read or write an enumerated value.  On writing, we return the input
1572
   value for the convenience of callers.  We avoid using an integer
1573
   pointer because enums are sometimes inside bitfields.  */
1574
 
1575
static int
1576
mio_name (int t, const mstring *m)
1577
{
1578
  if (iomode == IO_OUTPUT)
1579
    write_atom (ATOM_NAME, gfc_code2string (m, t));
1580
  else
1581
    {
1582
      require_atom (ATOM_NAME);
1583
      t = find_enum (m);
1584
    }
1585
 
1586
  return t;
1587
}
1588
 
1589
/* Specialization of mio_name.  */
1590
 
1591
#define DECL_MIO_NAME(TYPE) \
1592
 static inline TYPE \
1593
 MIO_NAME(TYPE) (TYPE t, const mstring *m) \
1594
 { \
1595
   return (TYPE) mio_name ((int) t, m); \
1596
 }
1597
#define MIO_NAME(TYPE) mio_name_##TYPE
1598
 
1599
static void
1600
mio_lparen (void)
1601
{
1602
  if (iomode == IO_OUTPUT)
1603
    write_atom (ATOM_LPAREN, NULL);
1604
  else
1605
    require_atom (ATOM_LPAREN);
1606
}
1607
 
1608
 
1609
static void
1610
mio_rparen (void)
1611
{
1612
  if (iomode == IO_OUTPUT)
1613
    write_atom (ATOM_RPAREN, NULL);
1614
  else
1615
    require_atom (ATOM_RPAREN);
1616
}
1617
 
1618
 
1619
static void
1620
mio_integer (int *ip)
1621
{
1622
  if (iomode == IO_OUTPUT)
1623
    write_atom (ATOM_INTEGER, ip);
1624
  else
1625
    {
1626
      require_atom (ATOM_INTEGER);
1627
      *ip = atom_int;
1628
    }
1629
}
1630
 
1631
 
1632
/* Read or write a gfc_intrinsic_op value.  */
1633
 
1634
static void
1635
mio_intrinsic_op (gfc_intrinsic_op* op)
1636
{
1637
  /* FIXME: Would be nicer to do this via the operators symbolic name.  */
1638
  if (iomode == IO_OUTPUT)
1639
    {
1640
      int converted = (int) *op;
1641
      write_atom (ATOM_INTEGER, &converted);
1642
    }
1643
  else
1644
    {
1645
      require_atom (ATOM_INTEGER);
1646
      *op = (gfc_intrinsic_op) atom_int;
1647
    }
1648
}
1649
 
1650
 
1651
/* Read or write a character pointer that points to a string on the heap.  */
1652
 
1653
static const char *
1654
mio_allocated_string (const char *s)
1655
{
1656
  if (iomode == IO_OUTPUT)
1657
    {
1658
      write_atom (ATOM_STRING, s);
1659
      return s;
1660
    }
1661
  else
1662
    {
1663
      require_atom (ATOM_STRING);
1664
      return atom_string;
1665
    }
1666
}
1667
 
1668
 
1669
/* Functions for quoting and unquoting strings.  */
1670
 
1671
static char *
1672
quote_string (const gfc_char_t *s, const size_t slength)
1673
{
1674
  const gfc_char_t *p;
1675
  char *res, *q;
1676
  size_t len = 0, i;
1677
 
1678
  /* Calculate the length we'll need: a backslash takes two ("\\"),
1679
     non-printable characters take 10 ("\Uxxxxxxxx") and others take 1.  */
1680
  for (p = s, i = 0; i < slength; p++, i++)
1681
    {
1682
      if (*p == '\\')
1683
        len += 2;
1684
      else if (!gfc_wide_is_printable (*p))
1685
        len += 10;
1686
      else
1687
        len++;
1688
    }
1689
 
1690
  q = res = XCNEWVEC (char, len + 1);
1691
  for (p = s, i = 0; i < slength; p++, i++)
1692
    {
1693
      if (*p == '\\')
1694
        *q++ = '\\', *q++ = '\\';
1695
      else if (!gfc_wide_is_printable (*p))
1696
        {
1697
          sprintf (q, "\\U%08" HOST_WIDE_INT_PRINT "x",
1698
                   (unsigned HOST_WIDE_INT) *p);
1699
          q += 10;
1700
        }
1701
      else
1702
        *q++ = (unsigned char) *p;
1703
    }
1704
 
1705
  res[len] = '\0';
1706
  return res;
1707
}
1708
 
1709
static gfc_char_t *
1710
unquote_string (const char *s)
1711
{
1712
  size_t len, i;
1713
  const char *p;
1714
  gfc_char_t *res;
1715
 
1716
  for (p = s, len = 0; *p; p++, len++)
1717
    {
1718
      if (*p != '\\')
1719
        continue;
1720
 
1721
      if (p[1] == '\\')
1722
        p++;
1723
      else if (p[1] == 'U')
1724
        p += 9; /* That is a "\U????????". */
1725
      else
1726
        gfc_internal_error ("unquote_string(): got bad string");
1727
    }
1728
 
1729
  res = gfc_get_wide_string (len + 1);
1730
  for (i = 0, p = s; i < len; i++, p++)
1731
    {
1732
      gcc_assert (*p);
1733
 
1734
      if (*p != '\\')
1735
        res[i] = (unsigned char) *p;
1736
      else if (p[1] == '\\')
1737
        {
1738
          res[i] = (unsigned char) '\\';
1739
          p++;
1740
        }
1741
      else
1742
        {
1743
          /* We read the 8-digits hexadecimal constant that follows.  */
1744
          int j;
1745
          unsigned n;
1746
          gfc_char_t c = 0;
1747
 
1748
          gcc_assert (p[1] == 'U');
1749
          for (j = 0; j < 8; j++)
1750
            {
1751
              c = c << 4;
1752
              gcc_assert (sscanf (&p[j+2], "%01x", &n) == 1);
1753
              c += n;
1754
            }
1755
 
1756
          res[i] = c;
1757
          p += 9;
1758
        }
1759
    }
1760
 
1761
  res[len] = '\0';
1762
  return res;
1763
}
1764
 
1765
 
1766
/* Read or write a character pointer that points to a wide string on the
1767
   heap, performing quoting/unquoting of nonprintable characters using the
1768
   form \U???????? (where each ? is a hexadecimal digit).
1769
   Length is the length of the string, only known and used in output mode.  */
1770
 
1771
static const gfc_char_t *
1772
mio_allocated_wide_string (const gfc_char_t *s, const size_t length)
1773
{
1774
  if (iomode == IO_OUTPUT)
1775
    {
1776
      char *quoted = quote_string (s, length);
1777
      write_atom (ATOM_STRING, quoted);
1778
      free (quoted);
1779
      return s;
1780
    }
1781
  else
1782
    {
1783
      gfc_char_t *unquoted;
1784
 
1785
      require_atom (ATOM_STRING);
1786
      unquoted = unquote_string (atom_string);
1787
      free (atom_string);
1788
      return unquoted;
1789
    }
1790
}
1791
 
1792
 
1793
/* Read or write a string that is in static memory.  */
1794
 
1795
static void
1796
mio_pool_string (const char **stringp)
1797
{
1798
  /* TODO: one could write the string only once, and refer to it via a
1799
     fixup pointer.  */
1800
 
1801
  /* As a special case we have to deal with a NULL string.  This
1802
     happens for the 'module' member of 'gfc_symbol's that are not in a
1803
     module.  We read / write these as the empty string.  */
1804
  if (iomode == IO_OUTPUT)
1805
    {
1806
      const char *p = *stringp == NULL ? "" : *stringp;
1807
      write_atom (ATOM_STRING, p);
1808
    }
1809
  else
1810
    {
1811
      require_atom (ATOM_STRING);
1812
      *stringp = atom_string[0] == '\0' ? NULL : gfc_get_string (atom_string);
1813
      free (atom_string);
1814
    }
1815
}
1816
 
1817
 
1818
/* Read or write a string that is inside of some already-allocated
1819
   structure.  */
1820
 
1821
static void
1822
mio_internal_string (char *string)
1823
{
1824
  if (iomode == IO_OUTPUT)
1825
    write_atom (ATOM_STRING, string);
1826
  else
1827
    {
1828
      require_atom (ATOM_STRING);
1829
      strcpy (string, atom_string);
1830
      free (atom_string);
1831
    }
1832
}
1833
 
1834
 
1835
typedef enum
1836
{ AB_ALLOCATABLE, AB_DIMENSION, AB_EXTERNAL, AB_INTRINSIC, AB_OPTIONAL,
1837
  AB_POINTER, AB_TARGET, AB_DUMMY, AB_RESULT, AB_DATA,
1838
  AB_IN_NAMELIST, AB_IN_COMMON, AB_FUNCTION, AB_SUBROUTINE, AB_SEQUENCE,
1839
  AB_ELEMENTAL, AB_PURE, AB_RECURSIVE, AB_GENERIC, AB_ALWAYS_EXPLICIT,
1840
  AB_CRAY_POINTER, AB_CRAY_POINTEE, AB_THREADPRIVATE,
1841
  AB_ALLOC_COMP, AB_POINTER_COMP, AB_PROC_POINTER_COMP, AB_PRIVATE_COMP,
1842
  AB_VALUE, AB_VOLATILE, AB_PROTECTED, AB_LOCK_COMP,
1843
  AB_IS_BIND_C, AB_IS_C_INTEROP, AB_IS_ISO_C, AB_ABSTRACT, AB_ZERO_COMP,
1844
  AB_IS_CLASS, AB_PROCEDURE, AB_PROC_POINTER, AB_ASYNCHRONOUS, AB_CODIMENSION,
1845
  AB_COARRAY_COMP, AB_VTYPE, AB_VTAB, AB_CONTIGUOUS, AB_CLASS_POINTER,
1846
  AB_IMPLICIT_PURE
1847
}
1848
ab_attribute;
1849
 
1850
static const mstring attr_bits[] =
1851
{
1852
    minit ("ALLOCATABLE", AB_ALLOCATABLE),
1853
    minit ("ASYNCHRONOUS", AB_ASYNCHRONOUS),
1854
    minit ("DIMENSION", AB_DIMENSION),
1855
    minit ("CODIMENSION", AB_CODIMENSION),
1856
    minit ("CONTIGUOUS", AB_CONTIGUOUS),
1857
    minit ("EXTERNAL", AB_EXTERNAL),
1858
    minit ("INTRINSIC", AB_INTRINSIC),
1859
    minit ("OPTIONAL", AB_OPTIONAL),
1860
    minit ("POINTER", AB_POINTER),
1861
    minit ("VOLATILE", AB_VOLATILE),
1862
    minit ("TARGET", AB_TARGET),
1863
    minit ("THREADPRIVATE", AB_THREADPRIVATE),
1864
    minit ("DUMMY", AB_DUMMY),
1865
    minit ("RESULT", AB_RESULT),
1866
    minit ("DATA", AB_DATA),
1867
    minit ("IN_NAMELIST", AB_IN_NAMELIST),
1868
    minit ("IN_COMMON", AB_IN_COMMON),
1869
    minit ("FUNCTION", AB_FUNCTION),
1870
    minit ("SUBROUTINE", AB_SUBROUTINE),
1871
    minit ("SEQUENCE", AB_SEQUENCE),
1872
    minit ("ELEMENTAL", AB_ELEMENTAL),
1873
    minit ("PURE", AB_PURE),
1874
    minit ("RECURSIVE", AB_RECURSIVE),
1875
    minit ("GENERIC", AB_GENERIC),
1876
    minit ("ALWAYS_EXPLICIT", AB_ALWAYS_EXPLICIT),
1877
    minit ("CRAY_POINTER", AB_CRAY_POINTER),
1878
    minit ("CRAY_POINTEE", AB_CRAY_POINTEE),
1879
    minit ("IS_BIND_C", AB_IS_BIND_C),
1880
    minit ("IS_C_INTEROP", AB_IS_C_INTEROP),
1881
    minit ("IS_ISO_C", AB_IS_ISO_C),
1882
    minit ("VALUE", AB_VALUE),
1883
    minit ("ALLOC_COMP", AB_ALLOC_COMP),
1884
    minit ("COARRAY_COMP", AB_COARRAY_COMP),
1885
    minit ("LOCK_COMP", AB_LOCK_COMP),
1886
    minit ("POINTER_COMP", AB_POINTER_COMP),
1887
    minit ("PROC_POINTER_COMP", AB_PROC_POINTER_COMP),
1888
    minit ("PRIVATE_COMP", AB_PRIVATE_COMP),
1889
    minit ("ZERO_COMP", AB_ZERO_COMP),
1890
    minit ("PROTECTED", AB_PROTECTED),
1891
    minit ("ABSTRACT", AB_ABSTRACT),
1892
    minit ("IS_CLASS", AB_IS_CLASS),
1893
    minit ("PROCEDURE", AB_PROCEDURE),
1894
    minit ("PROC_POINTER", AB_PROC_POINTER),
1895
    minit ("VTYPE", AB_VTYPE),
1896
    minit ("VTAB", AB_VTAB),
1897
    minit ("CLASS_POINTER", AB_CLASS_POINTER),
1898
    minit ("IMPLICIT_PURE", AB_IMPLICIT_PURE),
1899
    minit (NULL, -1)
1900
};
1901
 
1902
/* For binding attributes.  */
1903
static const mstring binding_passing[] =
1904
{
1905
    minit ("PASS", 0),
1906
    minit ("NOPASS", 1),
1907
    minit (NULL, -1)
1908
};
1909
static const mstring binding_overriding[] =
1910
{
1911
    minit ("OVERRIDABLE", 0),
1912
    minit ("NON_OVERRIDABLE", 1),
1913
    minit ("DEFERRED", 2),
1914
    minit (NULL, -1)
1915
};
1916
static const mstring binding_generic[] =
1917
{
1918
    minit ("SPECIFIC", 0),
1919
    minit ("GENERIC", 1),
1920
    minit (NULL, -1)
1921
};
1922
static const mstring binding_ppc[] =
1923
{
1924
    minit ("NO_PPC", 0),
1925
    minit ("PPC", 1),
1926
    minit (NULL, -1)
1927
};
1928
 
1929
/* Specialization of mio_name.  */
1930
DECL_MIO_NAME (ab_attribute)
1931
DECL_MIO_NAME (ar_type)
1932
DECL_MIO_NAME (array_type)
1933
DECL_MIO_NAME (bt)
1934
DECL_MIO_NAME (expr_t)
1935
DECL_MIO_NAME (gfc_access)
1936
DECL_MIO_NAME (gfc_intrinsic_op)
1937
DECL_MIO_NAME (ifsrc)
1938
DECL_MIO_NAME (save_state)
1939
DECL_MIO_NAME (procedure_type)
1940
DECL_MIO_NAME (ref_type)
1941
DECL_MIO_NAME (sym_flavor)
1942
DECL_MIO_NAME (sym_intent)
1943
#undef DECL_MIO_NAME
1944
 
1945
/* Symbol attributes are stored in list with the first three elements
1946
   being the enumerated fields, while the remaining elements (if any)
1947
   indicate the individual attribute bits.  The access field is not
1948
   saved-- it controls what symbols are exported when a module is
1949
   written.  */
1950
 
1951
static void
1952
mio_symbol_attribute (symbol_attribute *attr)
1953
{
1954
  atom_type t;
1955
  unsigned ext_attr,extension_level;
1956
 
1957
  mio_lparen ();
1958
 
1959
  attr->flavor = MIO_NAME (sym_flavor) (attr->flavor, flavors);
1960
  attr->intent = MIO_NAME (sym_intent) (attr->intent, intents);
1961
  attr->proc = MIO_NAME (procedure_type) (attr->proc, procedures);
1962
  attr->if_source = MIO_NAME (ifsrc) (attr->if_source, ifsrc_types);
1963
  attr->save = MIO_NAME (save_state) (attr->save, save_status);
1964
 
1965
  ext_attr = attr->ext_attr;
1966
  mio_integer ((int *) &ext_attr);
1967
  attr->ext_attr = ext_attr;
1968
 
1969
  extension_level = attr->extension;
1970
  mio_integer ((int *) &extension_level);
1971
  attr->extension = extension_level;
1972
 
1973
  if (iomode == IO_OUTPUT)
1974
    {
1975
      if (attr->allocatable)
1976
        MIO_NAME (ab_attribute) (AB_ALLOCATABLE, attr_bits);
1977
      if (attr->asynchronous)
1978
        MIO_NAME (ab_attribute) (AB_ASYNCHRONOUS, attr_bits);
1979
      if (attr->dimension)
1980
        MIO_NAME (ab_attribute) (AB_DIMENSION, attr_bits);
1981
      if (attr->codimension)
1982
        MIO_NAME (ab_attribute) (AB_CODIMENSION, attr_bits);
1983
      if (attr->contiguous)
1984
        MIO_NAME (ab_attribute) (AB_CONTIGUOUS, attr_bits);
1985
      if (attr->external)
1986
        MIO_NAME (ab_attribute) (AB_EXTERNAL, attr_bits);
1987
      if (attr->intrinsic)
1988
        MIO_NAME (ab_attribute) (AB_INTRINSIC, attr_bits);
1989
      if (attr->optional)
1990
        MIO_NAME (ab_attribute) (AB_OPTIONAL, attr_bits);
1991
      if (attr->pointer)
1992
        MIO_NAME (ab_attribute) (AB_POINTER, attr_bits);
1993
      if (attr->class_pointer)
1994
        MIO_NAME (ab_attribute) (AB_CLASS_POINTER, attr_bits);
1995
      if (attr->is_protected)
1996
        MIO_NAME (ab_attribute) (AB_PROTECTED, attr_bits);
1997
      if (attr->value)
1998
        MIO_NAME (ab_attribute) (AB_VALUE, attr_bits);
1999
      if (attr->volatile_)
2000
        MIO_NAME (ab_attribute) (AB_VOLATILE, attr_bits);
2001
      if (attr->target)
2002
        MIO_NAME (ab_attribute) (AB_TARGET, attr_bits);
2003
      if (attr->threadprivate)
2004
        MIO_NAME (ab_attribute) (AB_THREADPRIVATE, attr_bits);
2005
      if (attr->dummy)
2006
        MIO_NAME (ab_attribute) (AB_DUMMY, attr_bits);
2007
      if (attr->result)
2008
        MIO_NAME (ab_attribute) (AB_RESULT, attr_bits);
2009
      /* We deliberately don't preserve the "entry" flag.  */
2010
 
2011
      if (attr->data)
2012
        MIO_NAME (ab_attribute) (AB_DATA, attr_bits);
2013
      if (attr->in_namelist)
2014
        MIO_NAME (ab_attribute) (AB_IN_NAMELIST, attr_bits);
2015
      if (attr->in_common)
2016
        MIO_NAME (ab_attribute) (AB_IN_COMMON, attr_bits);
2017
 
2018
      if (attr->function)
2019
        MIO_NAME (ab_attribute) (AB_FUNCTION, attr_bits);
2020
      if (attr->subroutine)
2021
        MIO_NAME (ab_attribute) (AB_SUBROUTINE, attr_bits);
2022
      if (attr->generic)
2023
        MIO_NAME (ab_attribute) (AB_GENERIC, attr_bits);
2024
      if (attr->abstract)
2025
        MIO_NAME (ab_attribute) (AB_ABSTRACT, attr_bits);
2026
 
2027
      if (attr->sequence)
2028
        MIO_NAME (ab_attribute) (AB_SEQUENCE, attr_bits);
2029
      if (attr->elemental)
2030
        MIO_NAME (ab_attribute) (AB_ELEMENTAL, attr_bits);
2031
      if (attr->pure)
2032
        MIO_NAME (ab_attribute) (AB_PURE, attr_bits);
2033
      if (attr->implicit_pure)
2034
        MIO_NAME (ab_attribute) (AB_IMPLICIT_PURE, attr_bits);
2035
      if (attr->recursive)
2036
        MIO_NAME (ab_attribute) (AB_RECURSIVE, attr_bits);
2037
      if (attr->always_explicit)
2038
        MIO_NAME (ab_attribute) (AB_ALWAYS_EXPLICIT, attr_bits);
2039
      if (attr->cray_pointer)
2040
        MIO_NAME (ab_attribute) (AB_CRAY_POINTER, attr_bits);
2041
      if (attr->cray_pointee)
2042
        MIO_NAME (ab_attribute) (AB_CRAY_POINTEE, attr_bits);
2043
      if (attr->is_bind_c)
2044
        MIO_NAME(ab_attribute) (AB_IS_BIND_C, attr_bits);
2045
      if (attr->is_c_interop)
2046
        MIO_NAME(ab_attribute) (AB_IS_C_INTEROP, attr_bits);
2047
      if (attr->is_iso_c)
2048
        MIO_NAME(ab_attribute) (AB_IS_ISO_C, attr_bits);
2049
      if (attr->alloc_comp)
2050
        MIO_NAME (ab_attribute) (AB_ALLOC_COMP, attr_bits);
2051
      if (attr->pointer_comp)
2052
        MIO_NAME (ab_attribute) (AB_POINTER_COMP, attr_bits);
2053
      if (attr->proc_pointer_comp)
2054
        MIO_NAME (ab_attribute) (AB_PROC_POINTER_COMP, attr_bits);
2055
      if (attr->private_comp)
2056
        MIO_NAME (ab_attribute) (AB_PRIVATE_COMP, attr_bits);
2057
      if (attr->coarray_comp)
2058
        MIO_NAME (ab_attribute) (AB_COARRAY_COMP, attr_bits);
2059
      if (attr->lock_comp)
2060
        MIO_NAME (ab_attribute) (AB_LOCK_COMP, attr_bits);
2061
      if (attr->zero_comp)
2062
        MIO_NAME (ab_attribute) (AB_ZERO_COMP, attr_bits);
2063
      if (attr->is_class)
2064
        MIO_NAME (ab_attribute) (AB_IS_CLASS, attr_bits);
2065
      if (attr->procedure)
2066
        MIO_NAME (ab_attribute) (AB_PROCEDURE, attr_bits);
2067
      if (attr->proc_pointer)
2068
        MIO_NAME (ab_attribute) (AB_PROC_POINTER, attr_bits);
2069
      if (attr->vtype)
2070
        MIO_NAME (ab_attribute) (AB_VTYPE, attr_bits);
2071
      if (attr->vtab)
2072
        MIO_NAME (ab_attribute) (AB_VTAB, attr_bits);
2073
 
2074
      mio_rparen ();
2075
 
2076
    }
2077
  else
2078
    {
2079
      for (;;)
2080
        {
2081
          t = parse_atom ();
2082
          if (t == ATOM_RPAREN)
2083
            break;
2084
          if (t != ATOM_NAME)
2085
            bad_module ("Expected attribute bit name");
2086
 
2087
          switch ((ab_attribute) find_enum (attr_bits))
2088
            {
2089
            case AB_ALLOCATABLE:
2090
              attr->allocatable = 1;
2091
              break;
2092
            case AB_ASYNCHRONOUS:
2093
              attr->asynchronous = 1;
2094
              break;
2095
            case AB_DIMENSION:
2096
              attr->dimension = 1;
2097
              break;
2098
            case AB_CODIMENSION:
2099
              attr->codimension = 1;
2100
              break;
2101
            case AB_CONTIGUOUS:
2102
              attr->contiguous = 1;
2103
              break;
2104
            case AB_EXTERNAL:
2105
              attr->external = 1;
2106
              break;
2107
            case AB_INTRINSIC:
2108
              attr->intrinsic = 1;
2109
              break;
2110
            case AB_OPTIONAL:
2111
              attr->optional = 1;
2112
              break;
2113
            case AB_POINTER:
2114
              attr->pointer = 1;
2115
              break;
2116
            case AB_CLASS_POINTER:
2117
              attr->class_pointer = 1;
2118
              break;
2119
            case AB_PROTECTED:
2120
              attr->is_protected = 1;
2121
              break;
2122
            case AB_VALUE:
2123
              attr->value = 1;
2124
              break;
2125
            case AB_VOLATILE:
2126
              attr->volatile_ = 1;
2127
              break;
2128
            case AB_TARGET:
2129
              attr->target = 1;
2130
              break;
2131
            case AB_THREADPRIVATE:
2132
              attr->threadprivate = 1;
2133
              break;
2134
            case AB_DUMMY:
2135
              attr->dummy = 1;
2136
              break;
2137
            case AB_RESULT:
2138
              attr->result = 1;
2139
              break;
2140
            case AB_DATA:
2141
              attr->data = 1;
2142
              break;
2143
            case AB_IN_NAMELIST:
2144
              attr->in_namelist = 1;
2145
              break;
2146
            case AB_IN_COMMON:
2147
              attr->in_common = 1;
2148
              break;
2149
            case AB_FUNCTION:
2150
              attr->function = 1;
2151
              break;
2152
            case AB_SUBROUTINE:
2153
              attr->subroutine = 1;
2154
              break;
2155
            case AB_GENERIC:
2156
              attr->generic = 1;
2157
              break;
2158
            case AB_ABSTRACT:
2159
              attr->abstract = 1;
2160
              break;
2161
            case AB_SEQUENCE:
2162
              attr->sequence = 1;
2163
              break;
2164
            case AB_ELEMENTAL:
2165
              attr->elemental = 1;
2166
              break;
2167
            case AB_PURE:
2168
              attr->pure = 1;
2169
              break;
2170
            case AB_IMPLICIT_PURE:
2171
              attr->implicit_pure = 1;
2172
              break;
2173
            case AB_RECURSIVE:
2174
              attr->recursive = 1;
2175
              break;
2176
            case AB_ALWAYS_EXPLICIT:
2177
              attr->always_explicit = 1;
2178
              break;
2179
            case AB_CRAY_POINTER:
2180
              attr->cray_pointer = 1;
2181
              break;
2182
            case AB_CRAY_POINTEE:
2183
              attr->cray_pointee = 1;
2184
              break;
2185
            case AB_IS_BIND_C:
2186
              attr->is_bind_c = 1;
2187
              break;
2188
            case AB_IS_C_INTEROP:
2189
              attr->is_c_interop = 1;
2190
              break;
2191
            case AB_IS_ISO_C:
2192
              attr->is_iso_c = 1;
2193
              break;
2194
            case AB_ALLOC_COMP:
2195
              attr->alloc_comp = 1;
2196
              break;
2197
            case AB_COARRAY_COMP:
2198
              attr->coarray_comp = 1;
2199
              break;
2200
            case AB_LOCK_COMP:
2201
              attr->lock_comp = 1;
2202
              break;
2203
            case AB_POINTER_COMP:
2204
              attr->pointer_comp = 1;
2205
              break;
2206
            case AB_PROC_POINTER_COMP:
2207
              attr->proc_pointer_comp = 1;
2208
              break;
2209
            case AB_PRIVATE_COMP:
2210
              attr->private_comp = 1;
2211
              break;
2212
            case AB_ZERO_COMP:
2213
              attr->zero_comp = 1;
2214
              break;
2215
            case AB_IS_CLASS:
2216
              attr->is_class = 1;
2217
              break;
2218
            case AB_PROCEDURE:
2219
              attr->procedure = 1;
2220
              break;
2221
            case AB_PROC_POINTER:
2222
              attr->proc_pointer = 1;
2223
              break;
2224
            case AB_VTYPE:
2225
              attr->vtype = 1;
2226
              break;
2227
            case AB_VTAB:
2228
              attr->vtab = 1;
2229
              break;
2230
            }
2231
        }
2232
    }
2233
}
2234
 
2235
 
2236
static const mstring bt_types[] = {
2237
    minit ("INTEGER", BT_INTEGER),
2238
    minit ("REAL", BT_REAL),
2239
    minit ("COMPLEX", BT_COMPLEX),
2240
    minit ("LOGICAL", BT_LOGICAL),
2241
    minit ("CHARACTER", BT_CHARACTER),
2242
    minit ("DERIVED", BT_DERIVED),
2243
    minit ("CLASS", BT_CLASS),
2244
    minit ("PROCEDURE", BT_PROCEDURE),
2245
    minit ("UNKNOWN", BT_UNKNOWN),
2246
    minit ("VOID", BT_VOID),
2247
    minit (NULL, -1)
2248
};
2249
 
2250
 
2251
static void
2252
mio_charlen (gfc_charlen **clp)
2253
{
2254
  gfc_charlen *cl;
2255
 
2256
  mio_lparen ();
2257
 
2258
  if (iomode == IO_OUTPUT)
2259
    {
2260
      cl = *clp;
2261
      if (cl != NULL)
2262
        mio_expr (&cl->length);
2263
    }
2264
  else
2265
    {
2266
      if (peek_atom () != ATOM_RPAREN)
2267
        {
2268
          cl = gfc_new_charlen (gfc_current_ns, NULL);
2269
          mio_expr (&cl->length);
2270
          *clp = cl;
2271
        }
2272
    }
2273
 
2274
  mio_rparen ();
2275
}
2276
 
2277
 
2278
/* See if a name is a generated name.  */
2279
 
2280
static int
2281
check_unique_name (const char *name)
2282
{
2283
  return *name == '@';
2284
}
2285
 
2286
 
2287
static void
2288
mio_typespec (gfc_typespec *ts)
2289
{
2290
  mio_lparen ();
2291
 
2292
  ts->type = MIO_NAME (bt) (ts->type, bt_types);
2293
 
2294
  if (ts->type != BT_DERIVED && ts->type != BT_CLASS)
2295
    mio_integer (&ts->kind);
2296
  else
2297
    mio_symbol_ref (&ts->u.derived);
2298
 
2299
  mio_symbol_ref (&ts->interface);
2300
 
2301
  /* Add info for C interop and is_iso_c.  */
2302
  mio_integer (&ts->is_c_interop);
2303
  mio_integer (&ts->is_iso_c);
2304
 
2305
  /* If the typespec is for an identifier either from iso_c_binding, or
2306
     a constant that was initialized to an identifier from it, use the
2307
     f90_type.  Otherwise, use the ts->type, since it shouldn't matter.  */
2308
  if (ts->is_iso_c)
2309
    ts->f90_type = MIO_NAME (bt) (ts->f90_type, bt_types);
2310
  else
2311
    ts->f90_type = MIO_NAME (bt) (ts->type, bt_types);
2312
 
2313
  if (ts->type != BT_CHARACTER)
2314
    {
2315
      /* ts->u.cl is only valid for BT_CHARACTER.  */
2316
      mio_lparen ();
2317
      mio_rparen ();
2318
    }
2319
  else
2320
    mio_charlen (&ts->u.cl);
2321
 
2322
  /* So as not to disturb the existing API, use an ATOM_NAME to
2323
     transmit deferred characteristic for characters (F2003).  */
2324
  if (iomode == IO_OUTPUT)
2325
    {
2326
      if (ts->type == BT_CHARACTER && ts->deferred)
2327
        write_atom (ATOM_NAME, "DEFERRED_CL");
2328
    }
2329
  else if (peek_atom () != ATOM_RPAREN)
2330
    {
2331
      if (parse_atom () != ATOM_NAME)
2332
        bad_module ("Expected string");
2333
      ts->deferred = 1;
2334
    }
2335
 
2336
  mio_rparen ();
2337
}
2338
 
2339
 
2340
static const mstring array_spec_types[] = {
2341
    minit ("EXPLICIT", AS_EXPLICIT),
2342
    minit ("ASSUMED_SHAPE", AS_ASSUMED_SHAPE),
2343
    minit ("DEFERRED", AS_DEFERRED),
2344
    minit ("ASSUMED_SIZE", AS_ASSUMED_SIZE),
2345
    minit (NULL, -1)
2346
};
2347
 
2348
 
2349
static void
2350
mio_array_spec (gfc_array_spec **asp)
2351
{
2352
  gfc_array_spec *as;
2353
  int i;
2354
 
2355
  mio_lparen ();
2356
 
2357
  if (iomode == IO_OUTPUT)
2358
    {
2359
      if (*asp == NULL)
2360
        goto done;
2361
      as = *asp;
2362
    }
2363
  else
2364
    {
2365
      if (peek_atom () == ATOM_RPAREN)
2366
        {
2367
          *asp = NULL;
2368
          goto done;
2369
        }
2370
 
2371
      *asp = as = gfc_get_array_spec ();
2372
    }
2373
 
2374
  mio_integer (&as->rank);
2375
  mio_integer (&as->corank);
2376
  as->type = MIO_NAME (array_type) (as->type, array_spec_types);
2377
 
2378
  if (iomode == IO_INPUT && as->corank)
2379
    as->cotype = (as->type == AS_DEFERRED) ? AS_DEFERRED : AS_EXPLICIT;
2380
 
2381
  for (i = 0; i < as->rank + as->corank; i++)
2382
    {
2383
      mio_expr (&as->lower[i]);
2384
      mio_expr (&as->upper[i]);
2385
    }
2386
 
2387
done:
2388
  mio_rparen ();
2389
}
2390
 
2391
 
2392
/* Given a pointer to an array reference structure (which lives in a
2393
   gfc_ref structure), find the corresponding array specification
2394
   structure.  Storing the pointer in the ref structure doesn't quite
2395
   work when loading from a module. Generating code for an array
2396
   reference also needs more information than just the array spec.  */
2397
 
2398
static const mstring array_ref_types[] = {
2399
    minit ("FULL", AR_FULL),
2400
    minit ("ELEMENT", AR_ELEMENT),
2401
    minit ("SECTION", AR_SECTION),
2402
    minit (NULL, -1)
2403
};
2404
 
2405
 
2406
static void
2407
mio_array_ref (gfc_array_ref *ar)
2408
{
2409
  int i;
2410
 
2411
  mio_lparen ();
2412
  ar->type = MIO_NAME (ar_type) (ar->type, array_ref_types);
2413
  mio_integer (&ar->dimen);
2414
 
2415
  switch (ar->type)
2416
    {
2417
    case AR_FULL:
2418
      break;
2419
 
2420
    case AR_ELEMENT:
2421
      for (i = 0; i < ar->dimen; i++)
2422
        mio_expr (&ar->start[i]);
2423
 
2424
      break;
2425
 
2426
    case AR_SECTION:
2427
      for (i = 0; i < ar->dimen; i++)
2428
        {
2429
          mio_expr (&ar->start[i]);
2430
          mio_expr (&ar->end[i]);
2431
          mio_expr (&ar->stride[i]);
2432
        }
2433
 
2434
      break;
2435
 
2436
    case AR_UNKNOWN:
2437
      gfc_internal_error ("mio_array_ref(): Unknown array ref");
2438
    }
2439
 
2440
  /* Unfortunately, ar->dimen_type is an anonymous enumerated type so
2441
     we can't call mio_integer directly.  Instead loop over each element
2442
     and cast it to/from an integer.  */
2443
  if (iomode == IO_OUTPUT)
2444
    {
2445
      for (i = 0; i < ar->dimen; i++)
2446
        {
2447
          int tmp = (int)ar->dimen_type[i];
2448
          write_atom (ATOM_INTEGER, &tmp);
2449
        }
2450
    }
2451
  else
2452
    {
2453
      for (i = 0; i < ar->dimen; i++)
2454
        {
2455
          require_atom (ATOM_INTEGER);
2456
          ar->dimen_type[i] = (enum gfc_array_ref_dimen_type) atom_int;
2457
        }
2458
    }
2459
 
2460
  if (iomode == IO_INPUT)
2461
    {
2462
      ar->where = gfc_current_locus;
2463
 
2464
      for (i = 0; i < ar->dimen; i++)
2465
        ar->c_where[i] = gfc_current_locus;
2466
    }
2467
 
2468
  mio_rparen ();
2469
}
2470
 
2471
 
2472
/* Saves or restores a pointer.  The pointer is converted back and
2473
   forth from an integer.  We return the pointer_info pointer so that
2474
   the caller can take additional action based on the pointer type.  */
2475
 
2476
static pointer_info *
2477
mio_pointer_ref (void *gp)
2478
{
2479
  pointer_info *p;
2480
 
2481
  if (iomode == IO_OUTPUT)
2482
    {
2483
      p = get_pointer (*((char **) gp));
2484
      write_atom (ATOM_INTEGER, &p->integer);
2485
    }
2486
  else
2487
    {
2488
      require_atom (ATOM_INTEGER);
2489
      p = add_fixup (atom_int, gp);
2490
    }
2491
 
2492
  return p;
2493
}
2494
 
2495
 
2496
/* Save and load references to components that occur within
2497
   expressions.  We have to describe these references by a number and
2498
   by name.  The number is necessary for forward references during
2499
   reading, and the name is necessary if the symbol already exists in
2500
   the namespace and is not loaded again.  */
2501
 
2502
static void
2503
mio_component_ref (gfc_component **cp, gfc_symbol *sym)
2504
{
2505
  char name[GFC_MAX_SYMBOL_LEN + 1];
2506
  gfc_component *q;
2507
  pointer_info *p;
2508
 
2509
  p = mio_pointer_ref (cp);
2510
  if (p->type == P_UNKNOWN)
2511
    p->type = P_COMPONENT;
2512
 
2513
  if (iomode == IO_OUTPUT)
2514
    mio_pool_string (&(*cp)->name);
2515
  else
2516
    {
2517
      mio_internal_string (name);
2518
 
2519
      if (sym && sym->attr.is_class)
2520
        sym = sym->components->ts.u.derived;
2521
 
2522
      /* It can happen that a component reference can be read before the
2523
         associated derived type symbol has been loaded. Return now and
2524
         wait for a later iteration of load_needed.  */
2525
      if (sym == NULL)
2526
        return;
2527
 
2528
      if (sym->components != NULL && p->u.pointer == NULL)
2529
        {
2530
          /* Symbol already loaded, so search by name.  */
2531
          q = gfc_find_component (sym, name, true, true);
2532
 
2533
          if (q)
2534
            associate_integer_pointer (p, q);
2535
        }
2536
 
2537
      /* Make sure this symbol will eventually be loaded.  */
2538
      p = find_pointer2 (sym);
2539
      if (p->u.rsym.state == UNUSED)
2540
        p->u.rsym.state = NEEDED;
2541
    }
2542
}
2543
 
2544
 
2545
static void mio_namespace_ref (gfc_namespace **nsp);
2546
static void mio_formal_arglist (gfc_formal_arglist **formal);
2547
static void mio_typebound_proc (gfc_typebound_proc** proc);
2548
 
2549
static void
2550
mio_component (gfc_component *c, int vtype)
2551
{
2552
  pointer_info *p;
2553
  int n;
2554
  gfc_formal_arglist *formal;
2555
 
2556
  mio_lparen ();
2557
 
2558
  if (iomode == IO_OUTPUT)
2559
    {
2560
      p = get_pointer (c);
2561
      mio_integer (&p->integer);
2562
    }
2563
  else
2564
    {
2565
      mio_integer (&n);
2566
      p = get_integer (n);
2567
      associate_integer_pointer (p, c);
2568
    }
2569
 
2570
  if (p->type == P_UNKNOWN)
2571
    p->type = P_COMPONENT;
2572
 
2573
  mio_pool_string (&c->name);
2574
  mio_typespec (&c->ts);
2575
  mio_array_spec (&c->as);
2576
 
2577
  mio_symbol_attribute (&c->attr);
2578
  if (c->ts.type == BT_CLASS)
2579
    c->attr.class_ok = 1;
2580
  c->attr.access = MIO_NAME (gfc_access) (c->attr.access, access_types);
2581
 
2582
  if (!vtype)
2583
    mio_expr (&c->initializer);
2584
 
2585
  if (c->attr.proc_pointer)
2586
    {
2587
      if (iomode == IO_OUTPUT)
2588
        {
2589
          formal = c->formal;
2590
          while (formal && !formal->sym)
2591
            formal = formal->next;
2592
 
2593
          if (formal)
2594
            mio_namespace_ref (&formal->sym->ns);
2595
          else
2596
            mio_namespace_ref (&c->formal_ns);
2597
        }
2598
      else
2599
        {
2600
          mio_namespace_ref (&c->formal_ns);
2601
          /* TODO: if (c->formal_ns)
2602
            {
2603
              c->formal_ns->proc_name = c;
2604
              c->refs++;
2605
            }*/
2606
        }
2607
 
2608
      mio_formal_arglist (&c->formal);
2609
 
2610
      mio_typebound_proc (&c->tb);
2611
    }
2612
 
2613
  mio_rparen ();
2614
}
2615
 
2616
 
2617
static void
2618
mio_component_list (gfc_component **cp, int vtype)
2619
{
2620
  gfc_component *c, *tail;
2621
 
2622
  mio_lparen ();
2623
 
2624
  if (iomode == IO_OUTPUT)
2625
    {
2626
      for (c = *cp; c; c = c->next)
2627
        mio_component (c, vtype);
2628
    }
2629
  else
2630
    {
2631
      *cp = NULL;
2632
      tail = NULL;
2633
 
2634
      for (;;)
2635
        {
2636
          if (peek_atom () == ATOM_RPAREN)
2637
            break;
2638
 
2639
          c = gfc_get_component ();
2640
          mio_component (c, vtype);
2641
 
2642
          if (tail == NULL)
2643
            *cp = c;
2644
          else
2645
            tail->next = c;
2646
 
2647
          tail = c;
2648
        }
2649
    }
2650
 
2651
  mio_rparen ();
2652
}
2653
 
2654
 
2655
static void
2656
mio_actual_arg (gfc_actual_arglist *a)
2657
{
2658
  mio_lparen ();
2659
  mio_pool_string (&a->name);
2660
  mio_expr (&a->expr);
2661
  mio_rparen ();
2662
}
2663
 
2664
 
2665
static void
2666
mio_actual_arglist (gfc_actual_arglist **ap)
2667
{
2668
  gfc_actual_arglist *a, *tail;
2669
 
2670
  mio_lparen ();
2671
 
2672
  if (iomode == IO_OUTPUT)
2673
    {
2674
      for (a = *ap; a; a = a->next)
2675
        mio_actual_arg (a);
2676
 
2677
    }
2678
  else
2679
    {
2680
      tail = NULL;
2681
 
2682
      for (;;)
2683
        {
2684
          if (peek_atom () != ATOM_LPAREN)
2685
            break;
2686
 
2687
          a = gfc_get_actual_arglist ();
2688
 
2689
          if (tail == NULL)
2690
            *ap = a;
2691
          else
2692
            tail->next = a;
2693
 
2694
          tail = a;
2695
          mio_actual_arg (a);
2696
        }
2697
    }
2698
 
2699
  mio_rparen ();
2700
}
2701
 
2702
 
2703
/* Read and write formal argument lists.  */
2704
 
2705
static void
2706
mio_formal_arglist (gfc_formal_arglist **formal)
2707
{
2708
  gfc_formal_arglist *f, *tail;
2709
 
2710
  mio_lparen ();
2711
 
2712
  if (iomode == IO_OUTPUT)
2713
    {
2714
      for (f = *formal; f; f = f->next)
2715
        mio_symbol_ref (&f->sym);
2716
    }
2717
  else
2718
    {
2719
      *formal = tail = NULL;
2720
 
2721
      while (peek_atom () != ATOM_RPAREN)
2722
        {
2723
          f = gfc_get_formal_arglist ();
2724
          mio_symbol_ref (&f->sym);
2725
 
2726
          if (*formal == NULL)
2727
            *formal = f;
2728
          else
2729
            tail->next = f;
2730
 
2731
          tail = f;
2732
        }
2733
    }
2734
 
2735
  mio_rparen ();
2736
}
2737
 
2738
 
2739
/* Save or restore a reference to a symbol node.  */
2740
 
2741
pointer_info *
2742
mio_symbol_ref (gfc_symbol **symp)
2743
{
2744
  pointer_info *p;
2745
 
2746
  p = mio_pointer_ref (symp);
2747
  if (p->type == P_UNKNOWN)
2748
    p->type = P_SYMBOL;
2749
 
2750
  if (iomode == IO_OUTPUT)
2751
    {
2752
      if (p->u.wsym.state == UNREFERENCED)
2753
        p->u.wsym.state = NEEDS_WRITE;
2754
    }
2755
  else
2756
    {
2757
      if (p->u.rsym.state == UNUSED)
2758
        p->u.rsym.state = NEEDED;
2759
    }
2760
  return p;
2761
}
2762
 
2763
 
2764
/* Save or restore a reference to a symtree node.  */
2765
 
2766
static void
2767
mio_symtree_ref (gfc_symtree **stp)
2768
{
2769
  pointer_info *p;
2770
  fixup_t *f;
2771
 
2772
  if (iomode == IO_OUTPUT)
2773
    mio_symbol_ref (&(*stp)->n.sym);
2774
  else
2775
    {
2776
      require_atom (ATOM_INTEGER);
2777
      p = get_integer (atom_int);
2778
 
2779
      /* An unused equivalence member; make a symbol and a symtree
2780
         for it.  */
2781
      if (in_load_equiv && p->u.rsym.symtree == NULL)
2782
        {
2783
          /* Since this is not used, it must have a unique name.  */
2784
          p->u.rsym.symtree = gfc_get_unique_symtree (gfc_current_ns);
2785
 
2786
          /* Make the symbol.  */
2787
          if (p->u.rsym.sym == NULL)
2788
            {
2789
              p->u.rsym.sym = gfc_new_symbol (p->u.rsym.true_name,
2790
                                              gfc_current_ns);
2791
              p->u.rsym.sym->module = gfc_get_string (p->u.rsym.module);
2792
            }
2793
 
2794
          p->u.rsym.symtree->n.sym = p->u.rsym.sym;
2795
          p->u.rsym.symtree->n.sym->refs++;
2796
          p->u.rsym.referenced = 1;
2797
 
2798
          /* If the symbol is PRIVATE and in COMMON, load_commons will
2799
             generate a fixup symbol, which must be associated.  */
2800
          if (p->fixup)
2801
            resolve_fixups (p->fixup, p->u.rsym.sym);
2802
          p->fixup = NULL;
2803
        }
2804
 
2805
      if (p->type == P_UNKNOWN)
2806
        p->type = P_SYMBOL;
2807
 
2808
      if (p->u.rsym.state == UNUSED)
2809
        p->u.rsym.state = NEEDED;
2810
 
2811
      if (p->u.rsym.symtree != NULL)
2812
        {
2813
          *stp = p->u.rsym.symtree;
2814
        }
2815
      else
2816
        {
2817
          f = XCNEW (fixup_t);
2818
 
2819
          f->next = p->u.rsym.stfixup;
2820
          p->u.rsym.stfixup = f;
2821
 
2822
          f->pointer = (void **) stp;
2823
        }
2824
    }
2825
}
2826
 
2827
 
2828
static void
2829
mio_iterator (gfc_iterator **ip)
2830
{
2831
  gfc_iterator *iter;
2832
 
2833
  mio_lparen ();
2834
 
2835
  if (iomode == IO_OUTPUT)
2836
    {
2837
      if (*ip == NULL)
2838
        goto done;
2839
    }
2840
  else
2841
    {
2842
      if (peek_atom () == ATOM_RPAREN)
2843
        {
2844
          *ip = NULL;
2845
          goto done;
2846
        }
2847
 
2848
      *ip = gfc_get_iterator ();
2849
    }
2850
 
2851
  iter = *ip;
2852
 
2853
  mio_expr (&iter->var);
2854
  mio_expr (&iter->start);
2855
  mio_expr (&iter->end);
2856
  mio_expr (&iter->step);
2857
 
2858
done:
2859
  mio_rparen ();
2860
}
2861
 
2862
 
2863
static void
2864
mio_constructor (gfc_constructor_base *cp)
2865
{
2866
  gfc_constructor *c;
2867
 
2868
  mio_lparen ();
2869
 
2870
  if (iomode == IO_OUTPUT)
2871
    {
2872
      for (c = gfc_constructor_first (*cp); c; c = gfc_constructor_next (c))
2873
        {
2874
          mio_lparen ();
2875
          mio_expr (&c->expr);
2876
          mio_iterator (&c->iterator);
2877
          mio_rparen ();
2878
        }
2879
    }
2880
  else
2881
    {
2882
      while (peek_atom () != ATOM_RPAREN)
2883
        {
2884
          c = gfc_constructor_append_expr (cp, NULL, NULL);
2885
 
2886
          mio_lparen ();
2887
          mio_expr (&c->expr);
2888
          mio_iterator (&c->iterator);
2889
          mio_rparen ();
2890
        }
2891
    }
2892
 
2893
  mio_rparen ();
2894
}
2895
 
2896
 
2897
static const mstring ref_types[] = {
2898
    minit ("ARRAY", REF_ARRAY),
2899
    minit ("COMPONENT", REF_COMPONENT),
2900
    minit ("SUBSTRING", REF_SUBSTRING),
2901
    minit (NULL, -1)
2902
};
2903
 
2904
 
2905
static void
2906
mio_ref (gfc_ref **rp)
2907
{
2908
  gfc_ref *r;
2909
 
2910
  mio_lparen ();
2911
 
2912
  r = *rp;
2913
  r->type = MIO_NAME (ref_type) (r->type, ref_types);
2914
 
2915
  switch (r->type)
2916
    {
2917
    case REF_ARRAY:
2918
      mio_array_ref (&r->u.ar);
2919
      break;
2920
 
2921
    case REF_COMPONENT:
2922
      mio_symbol_ref (&r->u.c.sym);
2923
      mio_component_ref (&r->u.c.component, r->u.c.sym);
2924
      break;
2925
 
2926
    case REF_SUBSTRING:
2927
      mio_expr (&r->u.ss.start);
2928
      mio_expr (&r->u.ss.end);
2929
      mio_charlen (&r->u.ss.length);
2930
      break;
2931
    }
2932
 
2933
  mio_rparen ();
2934
}
2935
 
2936
 
2937
static void
2938
mio_ref_list (gfc_ref **rp)
2939
{
2940
  gfc_ref *ref, *head, *tail;
2941
 
2942
  mio_lparen ();
2943
 
2944
  if (iomode == IO_OUTPUT)
2945
    {
2946
      for (ref = *rp; ref; ref = ref->next)
2947
        mio_ref (&ref);
2948
    }
2949
  else
2950
    {
2951
      head = tail = NULL;
2952
 
2953
      while (peek_atom () != ATOM_RPAREN)
2954
        {
2955
          if (head == NULL)
2956
            head = tail = gfc_get_ref ();
2957
          else
2958
            {
2959
              tail->next = gfc_get_ref ();
2960
              tail = tail->next;
2961
            }
2962
 
2963
          mio_ref (&tail);
2964
        }
2965
 
2966
      *rp = head;
2967
    }
2968
 
2969
  mio_rparen ();
2970
}
2971
 
2972
 
2973
/* Read and write an integer value.  */
2974
 
2975
static void
2976
mio_gmp_integer (mpz_t *integer)
2977
{
2978
  char *p;
2979
 
2980
  if (iomode == IO_INPUT)
2981
    {
2982
      if (parse_atom () != ATOM_STRING)
2983
        bad_module ("Expected integer string");
2984
 
2985
      mpz_init (*integer);
2986
      if (mpz_set_str (*integer, atom_string, 10))
2987
        bad_module ("Error converting integer");
2988
 
2989
      free (atom_string);
2990
    }
2991
  else
2992
    {
2993
      p = mpz_get_str (NULL, 10, *integer);
2994
      write_atom (ATOM_STRING, p);
2995
      free (p);
2996
    }
2997
}
2998
 
2999
 
3000
static void
3001
mio_gmp_real (mpfr_t *real)
3002
{
3003
  mp_exp_t exponent;
3004
  char *p;
3005
 
3006
  if (iomode == IO_INPUT)
3007
    {
3008
      if (parse_atom () != ATOM_STRING)
3009
        bad_module ("Expected real string");
3010
 
3011
      mpfr_init (*real);
3012
      mpfr_set_str (*real, atom_string, 16, GFC_RND_MODE);
3013
      free (atom_string);
3014
    }
3015
  else
3016
    {
3017
      p = mpfr_get_str (NULL, &exponent, 16, 0, *real, GFC_RND_MODE);
3018
 
3019
      if (mpfr_nan_p (*real) || mpfr_inf_p (*real))
3020
        {
3021
          write_atom (ATOM_STRING, p);
3022
          free (p);
3023
          return;
3024
        }
3025
 
3026
      atom_string = XCNEWVEC (char, strlen (p) + 20);
3027
 
3028
      sprintf (atom_string, "0.%s@%ld", p, exponent);
3029
 
3030
      /* Fix negative numbers.  */
3031
      if (atom_string[2] == '-')
3032
        {
3033
          atom_string[0] = '-';
3034
          atom_string[1] = '0';
3035
          atom_string[2] = '.';
3036
        }
3037
 
3038
      write_atom (ATOM_STRING, atom_string);
3039
 
3040
      free (atom_string);
3041
      free (p);
3042
    }
3043
}
3044
 
3045
 
3046
/* Save and restore the shape of an array constructor.  */
3047
 
3048
static void
3049
mio_shape (mpz_t **pshape, int rank)
3050
{
3051
  mpz_t *shape;
3052
  atom_type t;
3053
  int n;
3054
 
3055
  /* A NULL shape is represented by ().  */
3056
  mio_lparen ();
3057
 
3058
  if (iomode == IO_OUTPUT)
3059
    {
3060
      shape = *pshape;
3061
      if (!shape)
3062
        {
3063
          mio_rparen ();
3064
          return;
3065
        }
3066
    }
3067
  else
3068
    {
3069
      t = peek_atom ();
3070
      if (t == ATOM_RPAREN)
3071
        {
3072
          *pshape = NULL;
3073
          mio_rparen ();
3074
          return;
3075
        }
3076
 
3077
      shape = gfc_get_shape (rank);
3078
      *pshape = shape;
3079
    }
3080
 
3081
  for (n = 0; n < rank; n++)
3082
    mio_gmp_integer (&shape[n]);
3083
 
3084
  mio_rparen ();
3085
}
3086
 
3087
 
3088
static const mstring expr_types[] = {
3089
    minit ("OP", EXPR_OP),
3090
    minit ("FUNCTION", EXPR_FUNCTION),
3091
    minit ("CONSTANT", EXPR_CONSTANT),
3092
    minit ("VARIABLE", EXPR_VARIABLE),
3093
    minit ("SUBSTRING", EXPR_SUBSTRING),
3094
    minit ("STRUCTURE", EXPR_STRUCTURE),
3095
    minit ("ARRAY", EXPR_ARRAY),
3096
    minit ("NULL", EXPR_NULL),
3097
    minit ("COMPCALL", EXPR_COMPCALL),
3098
    minit (NULL, -1)
3099
};
3100
 
3101
/* INTRINSIC_ASSIGN is missing because it is used as an index for
3102
   generic operators, not in expressions.  INTRINSIC_USER is also
3103
   replaced by the correct function name by the time we see it.  */
3104
 
3105
static const mstring intrinsics[] =
3106
{
3107
    minit ("UPLUS", INTRINSIC_UPLUS),
3108
    minit ("UMINUS", INTRINSIC_UMINUS),
3109
    minit ("PLUS", INTRINSIC_PLUS),
3110
    minit ("MINUS", INTRINSIC_MINUS),
3111
    minit ("TIMES", INTRINSIC_TIMES),
3112
    minit ("DIVIDE", INTRINSIC_DIVIDE),
3113
    minit ("POWER", INTRINSIC_POWER),
3114
    minit ("CONCAT", INTRINSIC_CONCAT),
3115
    minit ("AND", INTRINSIC_AND),
3116
    minit ("OR", INTRINSIC_OR),
3117
    minit ("EQV", INTRINSIC_EQV),
3118
    minit ("NEQV", INTRINSIC_NEQV),
3119
    minit ("EQ_SIGN", INTRINSIC_EQ),
3120
    minit ("EQ", INTRINSIC_EQ_OS),
3121
    minit ("NE_SIGN", INTRINSIC_NE),
3122
    minit ("NE", INTRINSIC_NE_OS),
3123
    minit ("GT_SIGN", INTRINSIC_GT),
3124
    minit ("GT", INTRINSIC_GT_OS),
3125
    minit ("GE_SIGN", INTRINSIC_GE),
3126
    minit ("GE", INTRINSIC_GE_OS),
3127
    minit ("LT_SIGN", INTRINSIC_LT),
3128
    minit ("LT", INTRINSIC_LT_OS),
3129
    minit ("LE_SIGN", INTRINSIC_LE),
3130
    minit ("LE", INTRINSIC_LE_OS),
3131
    minit ("NOT", INTRINSIC_NOT),
3132
    minit ("PARENTHESES", INTRINSIC_PARENTHESES),
3133
    minit (NULL, -1)
3134
};
3135
 
3136
 
3137
/* Remedy a couple of situations where the gfc_expr's can be defective.  */
3138
 
3139
static void
3140
fix_mio_expr (gfc_expr *e)
3141
{
3142
  gfc_symtree *ns_st = NULL;
3143
  const char *fname;
3144
 
3145
  if (iomode != IO_OUTPUT)
3146
    return;
3147
 
3148
  if (e->symtree)
3149
    {
3150
      /* If this is a symtree for a symbol that came from a contained module
3151
         namespace, it has a unique name and we should look in the current
3152
         namespace to see if the required, non-contained symbol is available
3153
         yet. If so, the latter should be written.  */
3154
      if (e->symtree->n.sym && check_unique_name (e->symtree->name))
3155
        {
3156
          const char *name = e->symtree->n.sym->name;
3157
          if (e->symtree->n.sym->attr.flavor == FL_DERIVED)
3158
            name = dt_upper_string (name);
3159
          ns_st = gfc_find_symtree (gfc_current_ns->sym_root, name);
3160
        }
3161
 
3162
      /* On the other hand, if the existing symbol is the module name or the
3163
         new symbol is a dummy argument, do not do the promotion.  */
3164
      if (ns_st && ns_st->n.sym
3165
          && ns_st->n.sym->attr.flavor != FL_MODULE
3166
          && !e->symtree->n.sym->attr.dummy)
3167
        e->symtree = ns_st;
3168
    }
3169
  else if (e->expr_type == EXPR_FUNCTION && e->value.function.name)
3170
    {
3171
      gfc_symbol *sym;
3172
 
3173
      /* In some circumstances, a function used in an initialization
3174
         expression, in one use associated module, can fail to be
3175
         coupled to its symtree when used in a specification
3176
         expression in another module.  */
3177
      fname = e->value.function.esym ? e->value.function.esym->name
3178
                                     : e->value.function.isym->name;
3179
      e->symtree = gfc_find_symtree (gfc_current_ns->sym_root, fname);
3180
 
3181
      if (e->symtree)
3182
        return;
3183
 
3184
      /* This is probably a reference to a private procedure from another
3185
         module.  To prevent a segfault, make a generic with no specific
3186
         instances.  If this module is used, without the required
3187
         specific coming from somewhere, the appropriate error message
3188
         is issued.  */
3189
      gfc_get_symbol (fname, gfc_current_ns, &sym);
3190
      sym->attr.flavor = FL_PROCEDURE;
3191
      sym->attr.generic = 1;
3192
      e->symtree = gfc_find_symtree (gfc_current_ns->sym_root, fname);
3193
      gfc_commit_symbol (sym);
3194
    }
3195
}
3196
 
3197
 
3198
/* Read and write expressions.  The form "()" is allowed to indicate a
3199
   NULL expression.  */
3200
 
3201
static void
3202
mio_expr (gfc_expr **ep)
3203
{
3204
  gfc_expr *e;
3205
  atom_type t;
3206
  int flag;
3207
 
3208
  mio_lparen ();
3209
 
3210
  if (iomode == IO_OUTPUT)
3211
    {
3212
      if (*ep == NULL)
3213
        {
3214
          mio_rparen ();
3215
          return;
3216
        }
3217
 
3218
      e = *ep;
3219
      MIO_NAME (expr_t) (e->expr_type, expr_types);
3220
    }
3221
  else
3222
    {
3223
      t = parse_atom ();
3224
      if (t == ATOM_RPAREN)
3225
        {
3226
          *ep = NULL;
3227
          return;
3228
        }
3229
 
3230
      if (t != ATOM_NAME)
3231
        bad_module ("Expected expression type");
3232
 
3233
      e = *ep = gfc_get_expr ();
3234
      e->where = gfc_current_locus;
3235
      e->expr_type = (expr_t) find_enum (expr_types);
3236
    }
3237
 
3238
  mio_typespec (&e->ts);
3239
  mio_integer (&e->rank);
3240
 
3241
  fix_mio_expr (e);
3242
 
3243
  switch (e->expr_type)
3244
    {
3245
    case EXPR_OP:
3246
      e->value.op.op
3247
        = MIO_NAME (gfc_intrinsic_op) (e->value.op.op, intrinsics);
3248
 
3249
      switch (e->value.op.op)
3250
        {
3251
        case INTRINSIC_UPLUS:
3252
        case INTRINSIC_UMINUS:
3253
        case INTRINSIC_NOT:
3254
        case INTRINSIC_PARENTHESES:
3255
          mio_expr (&e->value.op.op1);
3256
          break;
3257
 
3258
        case INTRINSIC_PLUS:
3259
        case INTRINSIC_MINUS:
3260
        case INTRINSIC_TIMES:
3261
        case INTRINSIC_DIVIDE:
3262
        case INTRINSIC_POWER:
3263
        case INTRINSIC_CONCAT:
3264
        case INTRINSIC_AND:
3265
        case INTRINSIC_OR:
3266
        case INTRINSIC_EQV:
3267
        case INTRINSIC_NEQV:
3268
        case INTRINSIC_EQ:
3269
        case INTRINSIC_EQ_OS:
3270
        case INTRINSIC_NE:
3271
        case INTRINSIC_NE_OS:
3272
        case INTRINSIC_GT:
3273
        case INTRINSIC_GT_OS:
3274
        case INTRINSIC_GE:
3275
        case INTRINSIC_GE_OS:
3276
        case INTRINSIC_LT:
3277
        case INTRINSIC_LT_OS:
3278
        case INTRINSIC_LE:
3279
        case INTRINSIC_LE_OS:
3280
          mio_expr (&e->value.op.op1);
3281
          mio_expr (&e->value.op.op2);
3282
          break;
3283
 
3284
        default:
3285
          bad_module ("Bad operator");
3286
        }
3287
 
3288
      break;
3289
 
3290
    case EXPR_FUNCTION:
3291
      mio_symtree_ref (&e->symtree);
3292
      mio_actual_arglist (&e->value.function.actual);
3293
 
3294
      if (iomode == IO_OUTPUT)
3295
        {
3296
          e->value.function.name
3297
            = mio_allocated_string (e->value.function.name);
3298
          flag = e->value.function.esym != NULL;
3299
          mio_integer (&flag);
3300
          if (flag)
3301
            mio_symbol_ref (&e->value.function.esym);
3302
          else
3303
            write_atom (ATOM_STRING, e->value.function.isym->name);
3304
        }
3305
      else
3306
        {
3307
          require_atom (ATOM_STRING);
3308
          e->value.function.name = gfc_get_string (atom_string);
3309
          free (atom_string);
3310
 
3311
          mio_integer (&flag);
3312
          if (flag)
3313
            mio_symbol_ref (&e->value.function.esym);
3314
          else
3315
            {
3316
              require_atom (ATOM_STRING);
3317
              e->value.function.isym = gfc_find_function (atom_string);
3318
              free (atom_string);
3319
            }
3320
        }
3321
 
3322
      break;
3323
 
3324
    case EXPR_VARIABLE:
3325
      mio_symtree_ref (&e->symtree);
3326
      mio_ref_list (&e->ref);
3327
      break;
3328
 
3329
    case EXPR_SUBSTRING:
3330
      e->value.character.string
3331
        = CONST_CAST (gfc_char_t *,
3332
                      mio_allocated_wide_string (e->value.character.string,
3333
                                                 e->value.character.length));
3334
      mio_ref_list (&e->ref);
3335
      break;
3336
 
3337
    case EXPR_STRUCTURE:
3338
    case EXPR_ARRAY:
3339
      mio_constructor (&e->value.constructor);
3340
      mio_shape (&e->shape, e->rank);
3341
      break;
3342
 
3343
    case EXPR_CONSTANT:
3344
      switch (e->ts.type)
3345
        {
3346
        case BT_INTEGER:
3347
          mio_gmp_integer (&e->value.integer);
3348
          break;
3349
 
3350
        case BT_REAL:
3351
          gfc_set_model_kind (e->ts.kind);
3352
          mio_gmp_real (&e->value.real);
3353
          break;
3354
 
3355
        case BT_COMPLEX:
3356
          gfc_set_model_kind (e->ts.kind);
3357
          mio_gmp_real (&mpc_realref (e->value.complex));
3358
          mio_gmp_real (&mpc_imagref (e->value.complex));
3359
          break;
3360
 
3361
        case BT_LOGICAL:
3362
          mio_integer (&e->value.logical);
3363
          break;
3364
 
3365
        case BT_CHARACTER:
3366
          mio_integer (&e->value.character.length);
3367
          e->value.character.string
3368
            = CONST_CAST (gfc_char_t *,
3369
                          mio_allocated_wide_string (e->value.character.string,
3370
                                                     e->value.character.length));
3371
          break;
3372
 
3373
        default:
3374
          bad_module ("Bad type in constant expression");
3375
        }
3376
 
3377
      break;
3378
 
3379
    case EXPR_NULL:
3380
      break;
3381
 
3382
    case EXPR_COMPCALL:
3383
    case EXPR_PPC:
3384
      gcc_unreachable ();
3385
      break;
3386
    }
3387
 
3388
  mio_rparen ();
3389
}
3390
 
3391
 
3392
/* Read and write namelists.  */
3393
 
3394
static void
3395
mio_namelist (gfc_symbol *sym)
3396
{
3397
  gfc_namelist *n, *m;
3398
  const char *check_name;
3399
 
3400
  mio_lparen ();
3401
 
3402
  if (iomode == IO_OUTPUT)
3403
    {
3404
      for (n = sym->namelist; n; n = n->next)
3405
        mio_symbol_ref (&n->sym);
3406
    }
3407
  else
3408
    {
3409
      /* This departure from the standard is flagged as an error.
3410
         It does, in fact, work correctly. TODO: Allow it
3411
         conditionally?  */
3412
      if (sym->attr.flavor == FL_NAMELIST)
3413
        {
3414
          check_name = find_use_name (sym->name, false);
3415
          if (check_name && strcmp (check_name, sym->name) != 0)
3416
            gfc_error ("Namelist %s cannot be renamed by USE "
3417
                       "association to %s", sym->name, check_name);
3418
        }
3419
 
3420
      m = NULL;
3421
      while (peek_atom () != ATOM_RPAREN)
3422
        {
3423
          n = gfc_get_namelist ();
3424
          mio_symbol_ref (&n->sym);
3425
 
3426
          if (sym->namelist == NULL)
3427
            sym->namelist = n;
3428
          else
3429
            m->next = n;
3430
 
3431
          m = n;
3432
        }
3433
      sym->namelist_tail = m;
3434
    }
3435
 
3436
  mio_rparen ();
3437
}
3438
 
3439
 
3440
/* Save/restore lists of gfc_interface structures.  When loading an
3441
   interface, we are really appending to the existing list of
3442
   interfaces.  Checking for duplicate and ambiguous interfaces has to
3443
   be done later when all symbols have been loaded.  */
3444
 
3445
pointer_info *
3446
mio_interface_rest (gfc_interface **ip)
3447
{
3448
  gfc_interface *tail, *p;
3449
  pointer_info *pi = NULL;
3450
 
3451
  if (iomode == IO_OUTPUT)
3452
    {
3453
      if (ip != NULL)
3454
        for (p = *ip; p; p = p->next)
3455
          mio_symbol_ref (&p->sym);
3456
    }
3457
  else
3458
    {
3459
      if (*ip == NULL)
3460
        tail = NULL;
3461
      else
3462
        {
3463
          tail = *ip;
3464
          while (tail->next)
3465
            tail = tail->next;
3466
        }
3467
 
3468
      for (;;)
3469
        {
3470
          if (peek_atom () == ATOM_RPAREN)
3471
            break;
3472
 
3473
          p = gfc_get_interface ();
3474
          p->where = gfc_current_locus;
3475
          pi = mio_symbol_ref (&p->sym);
3476
 
3477
          if (tail == NULL)
3478
            *ip = p;
3479
          else
3480
            tail->next = p;
3481
 
3482
          tail = p;
3483
        }
3484
    }
3485
 
3486
  mio_rparen ();
3487
  return pi;
3488
}
3489
 
3490
 
3491
/* Save/restore a nameless operator interface.  */
3492
 
3493
static void
3494
mio_interface (gfc_interface **ip)
3495
{
3496
  mio_lparen ();
3497
  mio_interface_rest (ip);
3498
}
3499
 
3500
 
3501
/* Save/restore a named operator interface.  */
3502
 
3503
static void
3504
mio_symbol_interface (const char **name, const char **module,
3505
                      gfc_interface **ip)
3506
{
3507
  mio_lparen ();
3508
  mio_pool_string (name);
3509
  mio_pool_string (module);
3510
  mio_interface_rest (ip);
3511
}
3512
 
3513
 
3514
static void
3515
mio_namespace_ref (gfc_namespace **nsp)
3516
{
3517
  gfc_namespace *ns;
3518
  pointer_info *p;
3519
 
3520
  p = mio_pointer_ref (nsp);
3521
 
3522
  if (p->type == P_UNKNOWN)
3523
    p->type = P_NAMESPACE;
3524
 
3525
  if (iomode == IO_INPUT && p->integer != 0)
3526
    {
3527
      ns = (gfc_namespace *) p->u.pointer;
3528
      if (ns == NULL)
3529
        {
3530
          ns = gfc_get_namespace (NULL, 0);
3531
          associate_integer_pointer (p, ns);
3532
        }
3533
      else
3534
        ns->refs++;
3535
    }
3536
}
3537
 
3538
 
3539
/* Save/restore the f2k_derived namespace of a derived-type symbol.  */
3540
 
3541
static gfc_namespace* current_f2k_derived;
3542
 
3543
static void
3544
mio_typebound_proc (gfc_typebound_proc** proc)
3545
{
3546
  int flag;
3547
  int overriding_flag;
3548
 
3549
  if (iomode == IO_INPUT)
3550
    {
3551
      *proc = gfc_get_typebound_proc (NULL);
3552
      (*proc)->where = gfc_current_locus;
3553
    }
3554
  gcc_assert (*proc);
3555
 
3556
  mio_lparen ();
3557
 
3558
  (*proc)->access = MIO_NAME (gfc_access) ((*proc)->access, access_types);
3559
 
3560
  /* IO the NON_OVERRIDABLE/DEFERRED combination.  */
3561
  gcc_assert (!((*proc)->deferred && (*proc)->non_overridable));
3562
  overriding_flag = ((*proc)->deferred << 1) | (*proc)->non_overridable;
3563
  overriding_flag = mio_name (overriding_flag, binding_overriding);
3564
  (*proc)->deferred = ((overriding_flag & 2) != 0);
3565
  (*proc)->non_overridable = ((overriding_flag & 1) != 0);
3566
  gcc_assert (!((*proc)->deferred && (*proc)->non_overridable));
3567
 
3568
  (*proc)->nopass = mio_name ((*proc)->nopass, binding_passing);
3569
  (*proc)->is_generic = mio_name ((*proc)->is_generic, binding_generic);
3570
  (*proc)->ppc = mio_name((*proc)->ppc, binding_ppc);
3571
 
3572
  mio_pool_string (&((*proc)->pass_arg));
3573
 
3574
  flag = (int) (*proc)->pass_arg_num;
3575
  mio_integer (&flag);
3576
  (*proc)->pass_arg_num = (unsigned) flag;
3577
 
3578
  if ((*proc)->is_generic)
3579
    {
3580
      gfc_tbp_generic* g;
3581
      int iop;
3582
 
3583
      mio_lparen ();
3584
 
3585
      if (iomode == IO_OUTPUT)
3586
        for (g = (*proc)->u.generic; g; g = g->next)
3587
          {
3588
            iop = (int) g->is_operator;
3589
            mio_integer (&iop);
3590
            mio_allocated_string (g->specific_st->name);
3591
          }
3592
      else
3593
        {
3594
          (*proc)->u.generic = NULL;
3595
          while (peek_atom () != ATOM_RPAREN)
3596
            {
3597
              gfc_symtree** sym_root;
3598
 
3599
              g = gfc_get_tbp_generic ();
3600
              g->specific = NULL;
3601
 
3602
              mio_integer (&iop);
3603
              g->is_operator = (bool) iop;
3604
 
3605
              require_atom (ATOM_STRING);
3606
              sym_root = &current_f2k_derived->tb_sym_root;
3607
              g->specific_st = gfc_get_tbp_symtree (sym_root, atom_string);
3608
              free (atom_string);
3609
 
3610
              g->next = (*proc)->u.generic;
3611
              (*proc)->u.generic = g;
3612
            }
3613
        }
3614
 
3615
      mio_rparen ();
3616
    }
3617
  else if (!(*proc)->ppc)
3618
    mio_symtree_ref (&(*proc)->u.specific);
3619
 
3620
  mio_rparen ();
3621
}
3622
 
3623
/* Walker-callback function for this purpose.  */
3624
static void
3625
mio_typebound_symtree (gfc_symtree* st)
3626
{
3627
  if (iomode == IO_OUTPUT && !st->n.tb)
3628
    return;
3629
 
3630
  if (iomode == IO_OUTPUT)
3631
    {
3632
      mio_lparen ();
3633
      mio_allocated_string (st->name);
3634
    }
3635
  /* For IO_INPUT, the above is done in mio_f2k_derived.  */
3636
 
3637
  mio_typebound_proc (&st->n.tb);
3638
  mio_rparen ();
3639
}
3640
 
3641
/* IO a full symtree (in all depth).  */
3642
static void
3643
mio_full_typebound_tree (gfc_symtree** root)
3644
{
3645
  mio_lparen ();
3646
 
3647
  if (iomode == IO_OUTPUT)
3648
    gfc_traverse_symtree (*root, &mio_typebound_symtree);
3649
  else
3650
    {
3651
      while (peek_atom () == ATOM_LPAREN)
3652
        {
3653
          gfc_symtree* st;
3654
 
3655
          mio_lparen ();
3656
 
3657
          require_atom (ATOM_STRING);
3658
          st = gfc_get_tbp_symtree (root, atom_string);
3659
          free (atom_string);
3660
 
3661
          mio_typebound_symtree (st);
3662
        }
3663
    }
3664
 
3665
  mio_rparen ();
3666
}
3667
 
3668
static void
3669
mio_finalizer (gfc_finalizer **f)
3670
{
3671
  if (iomode == IO_OUTPUT)
3672
    {
3673
      gcc_assert (*f);
3674
      gcc_assert ((*f)->proc_tree); /* Should already be resolved.  */
3675
      mio_symtree_ref (&(*f)->proc_tree);
3676
    }
3677
  else
3678
    {
3679
      *f = gfc_get_finalizer ();
3680
      (*f)->where = gfc_current_locus; /* Value should not matter.  */
3681
      (*f)->next = NULL;
3682
 
3683
      mio_symtree_ref (&(*f)->proc_tree);
3684
      (*f)->proc_sym = NULL;
3685
    }
3686
}
3687
 
3688
static void
3689
mio_f2k_derived (gfc_namespace *f2k)
3690
{
3691
  current_f2k_derived = f2k;
3692
 
3693
  /* Handle the list of finalizer procedures.  */
3694
  mio_lparen ();
3695
  if (iomode == IO_OUTPUT)
3696
    {
3697
      gfc_finalizer *f;
3698
      for (f = f2k->finalizers; f; f = f->next)
3699
        mio_finalizer (&f);
3700
    }
3701
  else
3702
    {
3703
      f2k->finalizers = NULL;
3704
      while (peek_atom () != ATOM_RPAREN)
3705
        {
3706
          gfc_finalizer *cur = NULL;
3707
          mio_finalizer (&cur);
3708
          cur->next = f2k->finalizers;
3709
          f2k->finalizers = cur;
3710
        }
3711
    }
3712
  mio_rparen ();
3713
 
3714
  /* Handle type-bound procedures.  */
3715
  mio_full_typebound_tree (&f2k->tb_sym_root);
3716
 
3717
  /* Type-bound user operators.  */
3718
  mio_full_typebound_tree (&f2k->tb_uop_root);
3719
 
3720
  /* Type-bound intrinsic operators.  */
3721
  mio_lparen ();
3722
  if (iomode == IO_OUTPUT)
3723
    {
3724
      int op;
3725
      for (op = GFC_INTRINSIC_BEGIN; op != GFC_INTRINSIC_END; ++op)
3726
        {
3727
          gfc_intrinsic_op realop;
3728
 
3729
          if (op == INTRINSIC_USER || !f2k->tb_op[op])
3730
            continue;
3731
 
3732
          mio_lparen ();
3733
          realop = (gfc_intrinsic_op) op;
3734
          mio_intrinsic_op (&realop);
3735
          mio_typebound_proc (&f2k->tb_op[op]);
3736
          mio_rparen ();
3737
        }
3738
    }
3739
  else
3740
    while (peek_atom () != ATOM_RPAREN)
3741
      {
3742
        gfc_intrinsic_op op = GFC_INTRINSIC_BEGIN; /* Silence GCC.  */
3743
 
3744
        mio_lparen ();
3745
        mio_intrinsic_op (&op);
3746
        mio_typebound_proc (&f2k->tb_op[op]);
3747
        mio_rparen ();
3748
      }
3749
  mio_rparen ();
3750
}
3751
 
3752
static void
3753
mio_full_f2k_derived (gfc_symbol *sym)
3754
{
3755
  mio_lparen ();
3756
 
3757
  if (iomode == IO_OUTPUT)
3758
    {
3759
      if (sym->f2k_derived)
3760
        mio_f2k_derived (sym->f2k_derived);
3761
    }
3762
  else
3763
    {
3764
      if (peek_atom () != ATOM_RPAREN)
3765
        {
3766
          sym->f2k_derived = gfc_get_namespace (NULL, 0);
3767
          mio_f2k_derived (sym->f2k_derived);
3768
        }
3769
      else
3770
        gcc_assert (!sym->f2k_derived);
3771
    }
3772
 
3773
  mio_rparen ();
3774
}
3775
 
3776
 
3777
/* Unlike most other routines, the address of the symbol node is already
3778
   fixed on input and the name/module has already been filled in.  */
3779
 
3780
static void
3781
mio_symbol (gfc_symbol *sym)
3782
{
3783
  int intmod = INTMOD_NONE;
3784
 
3785
  mio_lparen ();
3786
 
3787
  mio_symbol_attribute (&sym->attr);
3788
  mio_typespec (&sym->ts);
3789
  if (sym->ts.type == BT_CLASS)
3790
    sym->attr.class_ok = 1;
3791
 
3792
  if (iomode == IO_OUTPUT)
3793
    mio_namespace_ref (&sym->formal_ns);
3794
  else
3795
    {
3796
      mio_namespace_ref (&sym->formal_ns);
3797
      if (sym->formal_ns)
3798
        {
3799
          sym->formal_ns->proc_name = sym;
3800
          sym->refs++;
3801
        }
3802
    }
3803
 
3804
  /* Save/restore common block links.  */
3805
  mio_symbol_ref (&sym->common_next);
3806
 
3807
  mio_formal_arglist (&sym->formal);
3808
 
3809
  if (sym->attr.flavor == FL_PARAMETER)
3810
    mio_expr (&sym->value);
3811
 
3812
  mio_array_spec (&sym->as);
3813
 
3814
  mio_symbol_ref (&sym->result);
3815
 
3816
  if (sym->attr.cray_pointee)
3817
    mio_symbol_ref (&sym->cp_pointer);
3818
 
3819
  /* Note that components are always saved, even if they are supposed
3820
     to be private.  Component access is checked during searching.  */
3821
 
3822
  mio_component_list (&sym->components, sym->attr.vtype);
3823
 
3824
  if (sym->components != NULL)
3825
    sym->component_access
3826
      = MIO_NAME (gfc_access) (sym->component_access, access_types);
3827
 
3828
  /* Load/save the f2k_derived namespace of a derived-type symbol.  */
3829
  mio_full_f2k_derived (sym);
3830
 
3831
  mio_namelist (sym);
3832
 
3833
  /* Add the fields that say whether this is from an intrinsic module,
3834
     and if so, what symbol it is within the module.  */
3835
/*   mio_integer (&(sym->from_intmod)); */
3836
  if (iomode == IO_OUTPUT)
3837
    {
3838
      intmod = sym->from_intmod;
3839
      mio_integer (&intmod);
3840
    }
3841
  else
3842
    {
3843
      mio_integer (&intmod);
3844
      sym->from_intmod = (intmod_id) intmod;
3845
    }
3846
 
3847
  mio_integer (&(sym->intmod_sym_id));
3848
 
3849
  if (sym->attr.flavor == FL_DERIVED)
3850
    mio_integer (&(sym->hash_value));
3851
 
3852
  mio_rparen ();
3853
}
3854
 
3855
 
3856
/************************* Top level subroutines *************************/
3857
 
3858
/* Given a root symtree node and a symbol, try to find a symtree that
3859
   references the symbol that is not a unique name.  */
3860
 
3861
static gfc_symtree *
3862
find_symtree_for_symbol (gfc_symtree *st, gfc_symbol *sym)
3863
{
3864
  gfc_symtree *s = NULL;
3865
 
3866
  if (st == NULL)
3867
    return s;
3868
 
3869
  s = find_symtree_for_symbol (st->right, sym);
3870
  if (s != NULL)
3871
    return s;
3872
  s = find_symtree_for_symbol (st->left, sym);
3873
  if (s != NULL)
3874
    return s;
3875
 
3876
  if (st->n.sym == sym && !check_unique_name (st->name))
3877
    return st;
3878
 
3879
  return s;
3880
}
3881
 
3882
 
3883
/* A recursive function to look for a specific symbol by name and by
3884
   module.  Whilst several symtrees might point to one symbol, its
3885
   is sufficient for the purposes here than one exist.  Note that
3886
   generic interfaces are distinguished as are symbols that have been
3887
   renamed in another module.  */
3888
static gfc_symtree *
3889
find_symbol (gfc_symtree *st, const char *name,
3890
             const char *module, int generic)
3891
{
3892
  int c;
3893
  gfc_symtree *retval, *s;
3894
 
3895
  if (st == NULL || st->n.sym == NULL)
3896
    return NULL;
3897
 
3898
  c = strcmp (name, st->n.sym->name);
3899
  if (c == 0 && st->n.sym->module
3900
             && strcmp (module, st->n.sym->module) == 0
3901
             && !check_unique_name (st->name))
3902
    {
3903
      s = gfc_find_symtree (gfc_current_ns->sym_root, name);
3904
 
3905
      /* Detect symbols that are renamed by use association in another
3906
         module by the absence of a symtree and null attr.use_rename,
3907
         since the latter is not transmitted in the module file.  */
3908
      if (((!generic && !st->n.sym->attr.generic)
3909
                || (generic && st->n.sym->attr.generic))
3910
            && !(s == NULL && !st->n.sym->attr.use_rename))
3911
        return st;
3912
    }
3913
 
3914
  retval = find_symbol (st->left, name, module, generic);
3915
 
3916
  if (retval == NULL)
3917
    retval = find_symbol (st->right, name, module, generic);
3918
 
3919
  return retval;
3920
}
3921
 
3922
 
3923
/* Skip a list between balanced left and right parens.  */
3924
 
3925
static void
3926
skip_list (void)
3927
{
3928
  int level;
3929
 
3930
  level = 0;
3931
  do
3932
    {
3933
      switch (parse_atom ())
3934
        {
3935
        case ATOM_LPAREN:
3936
          level++;
3937
          break;
3938
 
3939
        case ATOM_RPAREN:
3940
          level--;
3941
          break;
3942
 
3943
        case ATOM_STRING:
3944
          free (atom_string);
3945
          break;
3946
 
3947
        case ATOM_NAME:
3948
        case ATOM_INTEGER:
3949
          break;
3950
        }
3951
    }
3952
  while (level > 0);
3953
}
3954
 
3955
 
3956
/* Load operator interfaces from the module.  Interfaces are unusual
3957
   in that they attach themselves to existing symbols.  */
3958
 
3959
static void
3960
load_operator_interfaces (void)
3961
{
3962
  const char *p;
3963
  char name[GFC_MAX_SYMBOL_LEN + 1], module[GFC_MAX_SYMBOL_LEN + 1];
3964
  gfc_user_op *uop;
3965
  pointer_info *pi = NULL;
3966
  int n, i;
3967
 
3968
  mio_lparen ();
3969
 
3970
  while (peek_atom () != ATOM_RPAREN)
3971
    {
3972
      mio_lparen ();
3973
 
3974
      mio_internal_string (name);
3975
      mio_internal_string (module);
3976
 
3977
      n = number_use_names (name, true);
3978
      n = n ? n : 1;
3979
 
3980
      for (i = 1; i <= n; i++)
3981
        {
3982
          /* Decide if we need to load this one or not.  */
3983
          p = find_use_name_n (name, &i, true);
3984
 
3985
          if (p == NULL)
3986
            {
3987
              while (parse_atom () != ATOM_RPAREN);
3988
              continue;
3989
            }
3990
 
3991
          if (i == 1)
3992
            {
3993
              uop = gfc_get_uop (p);
3994
              pi = mio_interface_rest (&uop->op);
3995
            }
3996
          else
3997
            {
3998
              if (gfc_find_uop (p, NULL))
3999
                continue;
4000
              uop = gfc_get_uop (p);
4001
              uop->op = gfc_get_interface ();
4002
              uop->op->where = gfc_current_locus;
4003
              add_fixup (pi->integer, &uop->op->sym);
4004
            }
4005
        }
4006
    }
4007
 
4008
  mio_rparen ();
4009
}
4010
 
4011
 
4012
/* Load interfaces from the module.  Interfaces are unusual in that
4013
   they attach themselves to existing symbols.  */
4014
 
4015
static void
4016
load_generic_interfaces (void)
4017
{
4018
  const char *p;
4019
  char name[GFC_MAX_SYMBOL_LEN + 1], module[GFC_MAX_SYMBOL_LEN + 1];
4020
  gfc_symbol *sym;
4021
  gfc_interface *generic = NULL, *gen = NULL;
4022
  int n, i, renamed;
4023
  bool ambiguous_set = false;
4024
 
4025
  mio_lparen ();
4026
 
4027
  while (peek_atom () != ATOM_RPAREN)
4028
    {
4029
      mio_lparen ();
4030
 
4031
      mio_internal_string (name);
4032
      mio_internal_string (module);
4033
 
4034
      n = number_use_names (name, false);
4035
      renamed = n ? 1 : 0;
4036
      n = n ? n : 1;
4037
 
4038
      for (i = 1; i <= n; i++)
4039
        {
4040
          gfc_symtree *st;
4041
          /* Decide if we need to load this one or not.  */
4042
          p = find_use_name_n (name, &i, false);
4043
 
4044
          st = find_symbol (gfc_current_ns->sym_root,
4045
                            name, module_name, 1);
4046
 
4047
          if (!p || gfc_find_symbol (p, NULL, 0, &sym))
4048
            {
4049
              /* Skip the specific names for these cases.  */
4050
              while (i == 1 && parse_atom () != ATOM_RPAREN);
4051
 
4052
              continue;
4053
            }
4054
 
4055
          /* If the symbol exists already and is being USEd without being
4056
             in an ONLY clause, do not load a new symtree(11.3.2).  */
4057
          if (!only_flag && st)
4058
            sym = st->n.sym;
4059
 
4060
          if (!sym)
4061
            {
4062
              if (st)
4063
                {
4064
                  sym = st->n.sym;
4065
                  if (strcmp (st->name, p) != 0)
4066
                    {
4067
                      st = gfc_new_symtree (&gfc_current_ns->sym_root, p);
4068
                      st->n.sym = sym;
4069
                      sym->refs++;
4070
                    }
4071
                }
4072
 
4073
              /* Since we haven't found a valid generic interface, we had
4074
                 better make one.  */
4075
              if (!sym)
4076
                {
4077
                  gfc_get_symbol (p, NULL, &sym);
4078
                  sym->name = gfc_get_string (name);
4079
                  sym->module = module_name;
4080
                  sym->attr.flavor = FL_PROCEDURE;
4081
                  sym->attr.generic = 1;
4082
                  sym->attr.use_assoc = 1;
4083
                }
4084
            }
4085
          else
4086
            {
4087
              /* Unless sym is a generic interface, this reference
4088
                 is ambiguous.  */
4089
              if (st == NULL)
4090
                st = gfc_find_symtree (gfc_current_ns->sym_root, p);
4091
 
4092
              sym = st->n.sym;
4093
 
4094
              if (st && !sym->attr.generic
4095
                     && !st->ambiguous
4096
                     && sym->module
4097
                     && strcmp(module, sym->module))
4098
                {
4099
                  ambiguous_set = true;
4100
                  st->ambiguous = 1;
4101
                }
4102
            }
4103
 
4104
          sym->attr.use_only = only_flag;
4105
          sym->attr.use_rename = renamed;
4106
 
4107
          if (i == 1)
4108
            {
4109
              mio_interface_rest (&sym->generic);
4110
              generic = sym->generic;
4111
            }
4112
          else if (!sym->generic)
4113
            {
4114
              sym->generic = generic;
4115
              sym->attr.generic_copy = 1;
4116
            }
4117
 
4118
          /* If a procedure that is not generic has generic interfaces
4119
             that include itself, it is generic! We need to take care
4120
             to retain symbols ambiguous that were already so.  */
4121
          if (sym->attr.use_assoc
4122
                && !sym->attr.generic
4123
                && sym->attr.flavor == FL_PROCEDURE)
4124
            {
4125
              for (gen = generic; gen; gen = gen->next)
4126
                {
4127
                  if (gen->sym == sym)
4128
                    {
4129
                      sym->attr.generic = 1;
4130
                      if (ambiguous_set)
4131
                        st->ambiguous = 0;
4132
                      break;
4133
                    }
4134
                }
4135
            }
4136
 
4137
        }
4138
    }
4139
 
4140
  mio_rparen ();
4141
}
4142
 
4143
 
4144
/* Load common blocks.  */
4145
 
4146
static void
4147
load_commons (void)
4148
{
4149
  char name[GFC_MAX_SYMBOL_LEN + 1];
4150
  gfc_common_head *p;
4151
 
4152
  mio_lparen ();
4153
 
4154
  while (peek_atom () != ATOM_RPAREN)
4155
    {
4156
      int flags;
4157
      char* label;
4158
      mio_lparen ();
4159
      mio_internal_string (name);
4160
 
4161
      p = gfc_get_common (name, 1);
4162
 
4163
      mio_symbol_ref (&p->head);
4164
      mio_integer (&flags);
4165
      if (flags & 1)
4166
        p->saved = 1;
4167
      if (flags & 2)
4168
        p->threadprivate = 1;
4169
      p->use_assoc = 1;
4170
 
4171
      /* Get whether this was a bind(c) common or not.  */
4172
      mio_integer (&p->is_bind_c);
4173
      /* Get the binding label.  */
4174
      label = read_string ();
4175
      if (strlen (label))
4176
        p->binding_label = IDENTIFIER_POINTER (get_identifier (label));
4177
      XDELETEVEC (label);
4178
 
4179
      mio_rparen ();
4180
    }
4181
 
4182
  mio_rparen ();
4183
}
4184
 
4185
 
4186
/* Load equivalences.  The flag in_load_equiv informs mio_expr_ref of this
4187
   so that unused variables are not loaded and so that the expression can
4188
   be safely freed.  */
4189
 
4190
static void
4191
load_equiv (void)
4192
{
4193
  gfc_equiv *head, *tail, *end, *eq;
4194
  bool unused;
4195
 
4196
  mio_lparen ();
4197
  in_load_equiv = true;
4198
 
4199
  end = gfc_current_ns->equiv;
4200
  while (end != NULL && end->next != NULL)
4201
    end = end->next;
4202
 
4203
  while (peek_atom () != ATOM_RPAREN) {
4204
    mio_lparen ();
4205
    head = tail = NULL;
4206
 
4207
    while(peek_atom () != ATOM_RPAREN)
4208
      {
4209
        if (head == NULL)
4210
          head = tail = gfc_get_equiv ();
4211
        else
4212
          {
4213
            tail->eq = gfc_get_equiv ();
4214
            tail = tail->eq;
4215
          }
4216
 
4217
        mio_pool_string (&tail->module);
4218
        mio_expr (&tail->expr);
4219
      }
4220
 
4221
    /* Unused equivalence members have a unique name.  In addition, it
4222
       must be checked that the symbols are from the same module.  */
4223
    unused = true;
4224
    for (eq = head; eq; eq = eq->eq)
4225
      {
4226
        if (eq->expr->symtree->n.sym->module
4227
              && head->expr->symtree->n.sym->module
4228
              && strcmp (head->expr->symtree->n.sym->module,
4229
                         eq->expr->symtree->n.sym->module) == 0
4230
              && !check_unique_name (eq->expr->symtree->name))
4231
          {
4232
            unused = false;
4233
            break;
4234
          }
4235
      }
4236
 
4237
    if (unused)
4238
      {
4239
        for (eq = head; eq; eq = head)
4240
          {
4241
            head = eq->eq;
4242
            gfc_free_expr (eq->expr);
4243
            free (eq);
4244
          }
4245
      }
4246
 
4247
    if (end == NULL)
4248
      gfc_current_ns->equiv = head;
4249
    else
4250
      end->next = head;
4251
 
4252
    if (head != NULL)
4253
      end = head;
4254
 
4255
    mio_rparen ();
4256
  }
4257
 
4258
  mio_rparen ();
4259
  in_load_equiv = false;
4260
}
4261
 
4262
 
4263
/* This function loads the sym_root of f2k_derived with the extensions to
4264
   the derived type.  */
4265
static void
4266
load_derived_extensions (void)
4267
{
4268
  int symbol, j;
4269
  gfc_symbol *derived;
4270
  gfc_symbol *dt;
4271
  gfc_symtree *st;
4272
  pointer_info *info;
4273
  char name[GFC_MAX_SYMBOL_LEN + 1];
4274
  char module[GFC_MAX_SYMBOL_LEN + 1];
4275
  const char *p;
4276
 
4277
  mio_lparen ();
4278
  while (peek_atom () != ATOM_RPAREN)
4279
    {
4280
      mio_lparen ();
4281
      mio_integer (&symbol);
4282
      info = get_integer (symbol);
4283
      derived = info->u.rsym.sym;
4284
 
4285
      /* This one is not being loaded.  */
4286
      if (!info || !derived)
4287
        {
4288
          while (peek_atom () != ATOM_RPAREN)
4289
            skip_list ();
4290
          continue;
4291
        }
4292
 
4293
      gcc_assert (derived->attr.flavor == FL_DERIVED);
4294
      if (derived->f2k_derived == NULL)
4295
        derived->f2k_derived = gfc_get_namespace (NULL, 0);
4296
 
4297
      while (peek_atom () != ATOM_RPAREN)
4298
        {
4299
          mio_lparen ();
4300
          mio_internal_string (name);
4301
          mio_internal_string (module);
4302
 
4303
          /* Only use one use name to find the symbol.  */
4304
          j = 1;
4305
          p = find_use_name_n (name, &j, false);
4306
          if (p)
4307
            {
4308
              st = gfc_find_symtree (gfc_current_ns->sym_root, p);
4309
              dt = st->n.sym;
4310
              st = gfc_find_symtree (derived->f2k_derived->sym_root, name);
4311
              if (st == NULL)
4312
                {
4313
                  /* Only use the real name in f2k_derived to ensure a single
4314
                    symtree.  */
4315
                  st = gfc_new_symtree (&derived->f2k_derived->sym_root, name);
4316
                  st->n.sym = dt;
4317
                  st->n.sym->refs++;
4318
                }
4319
            }
4320
          mio_rparen ();
4321
        }
4322
      mio_rparen ();
4323
    }
4324
  mio_rparen ();
4325
}
4326
 
4327
 
4328
/* Recursive function to traverse the pointer_info tree and load a
4329
   needed symbol.  We return nonzero if we load a symbol and stop the
4330
   traversal, because the act of loading can alter the tree.  */
4331
 
4332
static int
4333
load_needed (pointer_info *p)
4334
{
4335
  gfc_namespace *ns;
4336
  pointer_info *q;
4337
  gfc_symbol *sym;
4338
  int rv;
4339
 
4340
  rv = 0;
4341
  if (p == NULL)
4342
    return rv;
4343
 
4344
  rv |= load_needed (p->left);
4345
  rv |= load_needed (p->right);
4346
 
4347
  if (p->type != P_SYMBOL || p->u.rsym.state != NEEDED)
4348
    return rv;
4349
 
4350
  p->u.rsym.state = USED;
4351
 
4352
  set_module_locus (&p->u.rsym.where);
4353
 
4354
  sym = p->u.rsym.sym;
4355
  if (sym == NULL)
4356
    {
4357
      q = get_integer (p->u.rsym.ns);
4358
 
4359
      ns = (gfc_namespace *) q->u.pointer;
4360
      if (ns == NULL)
4361
        {
4362
          /* Create an interface namespace if necessary.  These are
4363
             the namespaces that hold the formal parameters of module
4364
             procedures.  */
4365
 
4366
          ns = gfc_get_namespace (NULL, 0);
4367
          associate_integer_pointer (q, ns);
4368
        }
4369
 
4370
      /* Use the module sym as 'proc_name' so that gfc_get_symbol_decl
4371
         doesn't go pear-shaped if the symbol is used.  */
4372
      if (!ns->proc_name)
4373
        gfc_find_symbol (p->u.rsym.module, gfc_current_ns,
4374
                                 1, &ns->proc_name);
4375
 
4376
      sym = gfc_new_symbol (p->u.rsym.true_name, ns);
4377
      sym->name = dt_lower_string (p->u.rsym.true_name);
4378
      sym->module = gfc_get_string (p->u.rsym.module);
4379
      if (p->u.rsym.binding_label)
4380
        sym->binding_label = IDENTIFIER_POINTER (get_identifier
4381
                                                 (p->u.rsym.binding_label));
4382
 
4383
      associate_integer_pointer (p, sym);
4384
    }
4385
 
4386
  mio_symbol (sym);
4387
  sym->attr.use_assoc = 1;
4388
 
4389
  /* Mark as only or rename for later diagnosis for explicitly imported
4390
     but not used warnings; don't mark internal symbols such as __vtab,
4391
     __def_init etc.  */
4392
  if (only_flag && sym->name[0] != '_' && sym->name[1] != '_')
4393
    sym->attr.use_only = 1;
4394
  if (p->u.rsym.renamed)
4395
    sym->attr.use_rename = 1;
4396
 
4397
  return 1;
4398
}
4399
 
4400
 
4401
/* Recursive function for cleaning up things after a module has been read.  */
4402
 
4403
static void
4404
read_cleanup (pointer_info *p)
4405
{
4406
  gfc_symtree *st;
4407
  pointer_info *q;
4408
 
4409
  if (p == NULL)
4410
    return;
4411
 
4412
  read_cleanup (p->left);
4413
  read_cleanup (p->right);
4414
 
4415
  if (p->type == P_SYMBOL && p->u.rsym.state == USED && !p->u.rsym.referenced)
4416
    {
4417
      gfc_namespace *ns;
4418
      /* Add hidden symbols to the symtree.  */
4419
      q = get_integer (p->u.rsym.ns);
4420
      ns = (gfc_namespace *) q->u.pointer;
4421
 
4422
      if (!p->u.rsym.sym->attr.vtype
4423
            && !p->u.rsym.sym->attr.vtab)
4424
        st = gfc_get_unique_symtree (ns);
4425
      else
4426
        {
4427
          /* There is no reason to use 'unique_symtrees' for vtabs or
4428
             vtypes - their name is fine for a symtree and reduces the
4429
             namespace pollution.  */
4430
          st = gfc_find_symtree (ns->sym_root, p->u.rsym.sym->name);
4431
          if (!st)
4432
            st = gfc_new_symtree (&ns->sym_root, p->u.rsym.sym->name);
4433
        }
4434
 
4435
      st->n.sym = p->u.rsym.sym;
4436
      st->n.sym->refs++;
4437
 
4438
      /* Fixup any symtree references.  */
4439
      p->u.rsym.symtree = st;
4440
      resolve_fixups (p->u.rsym.stfixup, st);
4441
      p->u.rsym.stfixup = NULL;
4442
    }
4443
 
4444
  /* Free unused symbols.  */
4445
  if (p->type == P_SYMBOL && p->u.rsym.state == UNUSED)
4446
    gfc_free_symbol (p->u.rsym.sym);
4447
}
4448
 
4449
 
4450
/* It is not quite enough to check for ambiguity in the symbols by
4451
   the loaded symbol and the new symbol not being identical.  */
4452
static bool
4453
check_for_ambiguous (gfc_symbol *st_sym, pointer_info *info)
4454
{
4455
  gfc_symbol *rsym;
4456
  module_locus locus;
4457
  symbol_attribute attr;
4458
 
4459
  if (st_sym->ns->proc_name && st_sym->name == st_sym->ns->proc_name->name)
4460
    {
4461
      gfc_error ("'%s' of module '%s', imported at %C, is also the name of the "
4462
                 "current program unit", st_sym->name, module_name);
4463
      return true;
4464
    }
4465
 
4466
  rsym = info->u.rsym.sym;
4467
  if (st_sym == rsym)
4468
    return false;
4469
 
4470
  if (st_sym->attr.vtab || st_sym->attr.vtype)
4471
    return false;
4472
 
4473
  /* If the existing symbol is generic from a different module and
4474
     the new symbol is generic there can be no ambiguity.  */
4475
  if (st_sym->attr.generic
4476
        && st_sym->module
4477
        && st_sym->module != module_name)
4478
    {
4479
      /* The new symbol's attributes have not yet been read.  Since
4480
         we need attr.generic, read it directly.  */
4481
      get_module_locus (&locus);
4482
      set_module_locus (&info->u.rsym.where);
4483
      mio_lparen ();
4484
      attr.generic = 0;
4485
      mio_symbol_attribute (&attr);
4486
      set_module_locus (&locus);
4487
      if (attr.generic)
4488
        return false;
4489
    }
4490
 
4491
  return true;
4492
}
4493
 
4494
 
4495
/* Read a module file.  */
4496
 
4497
static void
4498
read_module (void)
4499
{
4500
  module_locus operator_interfaces, user_operators, extensions;
4501
  const char *p;
4502
  char name[GFC_MAX_SYMBOL_LEN + 1];
4503
  int i;
4504
  int ambiguous, j, nuse, symbol;
4505
  pointer_info *info, *q;
4506
  gfc_use_rename *u = NULL;
4507
  gfc_symtree *st;
4508
  gfc_symbol *sym;
4509
 
4510
  get_module_locus (&operator_interfaces);      /* Skip these for now.  */
4511
  skip_list ();
4512
 
4513
  get_module_locus (&user_operators);
4514
  skip_list ();
4515
  skip_list ();
4516
 
4517
  /* Skip commons, equivalences and derived type extensions for now.  */
4518
  skip_list ();
4519
  skip_list ();
4520
 
4521
  get_module_locus (&extensions);
4522
  skip_list ();
4523
 
4524
  mio_lparen ();
4525
 
4526
  /* Create the fixup nodes for all the symbols.  */
4527
 
4528
  while (peek_atom () != ATOM_RPAREN)
4529
    {
4530
      char* bind_label;
4531
      require_atom (ATOM_INTEGER);
4532
      info = get_integer (atom_int);
4533
 
4534
      info->type = P_SYMBOL;
4535
      info->u.rsym.state = UNUSED;
4536
 
4537
      info->u.rsym.true_name = read_string ();
4538
      info->u.rsym.module = read_string ();
4539
      bind_label = read_string ();
4540
      if (strlen (bind_label))
4541
        info->u.rsym.binding_label = bind_label;
4542
      else
4543
        XDELETEVEC (bind_label);
4544
 
4545
      require_atom (ATOM_INTEGER);
4546
      info->u.rsym.ns = atom_int;
4547
 
4548
      get_module_locus (&info->u.rsym.where);
4549
      skip_list ();
4550
 
4551
      /* See if the symbol has already been loaded by a previous module.
4552
         If so, we reference the existing symbol and prevent it from
4553
         being loaded again.  This should not happen if the symbol being
4554
         read is an index for an assumed shape dummy array (ns != 1).  */
4555
 
4556
      sym = find_true_name (info->u.rsym.true_name, info->u.rsym.module);
4557
 
4558
      if (sym == NULL
4559
          || (sym->attr.flavor == FL_VARIABLE && info->u.rsym.ns !=1))
4560
        continue;
4561
 
4562
      info->u.rsym.state = USED;
4563
      info->u.rsym.sym = sym;
4564
 
4565
      /* Some symbols do not have a namespace (eg. formal arguments),
4566
         so the automatic "unique symtree" mechanism must be suppressed
4567
         by marking them as referenced.  */
4568
      q = get_integer (info->u.rsym.ns);
4569
      if (q->u.pointer == NULL)
4570
        {
4571
          info->u.rsym.referenced = 1;
4572
          continue;
4573
        }
4574
 
4575
      /* If possible recycle the symtree that references the symbol.
4576
         If a symtree is not found and the module does not import one,
4577
         a unique-name symtree is found by read_cleanup.  */
4578
      st = find_symtree_for_symbol (gfc_current_ns->sym_root, sym);
4579
      if (st != NULL)
4580
        {
4581
          info->u.rsym.symtree = st;
4582
          info->u.rsym.referenced = 1;
4583
        }
4584
    }
4585
 
4586
  mio_rparen ();
4587
 
4588
  /* Parse the symtree lists.  This lets us mark which symbols need to
4589
     be loaded.  Renaming is also done at this point by replacing the
4590
     symtree name.  */
4591
 
4592
  mio_lparen ();
4593
 
4594
  while (peek_atom () != ATOM_RPAREN)
4595
    {
4596
      mio_internal_string (name);
4597
      mio_integer (&ambiguous);
4598
      mio_integer (&symbol);
4599
 
4600
      info = get_integer (symbol);
4601
 
4602
      /* See how many use names there are.  If none, go through the start
4603
         of the loop at least once.  */
4604
      nuse = number_use_names (name, false);
4605
      info->u.rsym.renamed = nuse ? 1 : 0;
4606
 
4607
      if (nuse == 0)
4608
        nuse = 1;
4609
 
4610
      for (j = 1; j <= nuse; j++)
4611
        {
4612
          /* Get the jth local name for this symbol.  */
4613
          p = find_use_name_n (name, &j, false);
4614
 
4615
          if (p == NULL && strcmp (name, module_name) == 0)
4616
            p = name;
4617
 
4618
          /* Exception: Always import vtabs & vtypes.  */
4619
          if (p == NULL && name[0] == '_'
4620
              && (strncmp (name, "__vtab_", 5) == 0
4621
                  || strncmp (name, "__vtype_", 6) == 0))
4622
            p = name;
4623
 
4624
          /* Skip symtree nodes not in an ONLY clause, unless there
4625
             is an existing symtree loaded from another USE statement.  */
4626
          if (p == NULL)
4627
            {
4628
              st = gfc_find_symtree (gfc_current_ns->sym_root, name);
4629
              if (st != NULL)
4630
                info->u.rsym.symtree = st;
4631
              continue;
4632
            }
4633
 
4634
          /* If a symbol of the same name and module exists already,
4635
             this symbol, which is not in an ONLY clause, must not be
4636
             added to the namespace(11.3.2).  Note that find_symbol
4637
             only returns the first occurrence that it finds.  */
4638
          if (!only_flag && !info->u.rsym.renamed
4639
                && strcmp (name, module_name) != 0
4640
                && find_symbol (gfc_current_ns->sym_root, name,
4641
                                module_name, 0))
4642
            continue;
4643
 
4644
          st = gfc_find_symtree (gfc_current_ns->sym_root, p);
4645
 
4646
          if (st != NULL)
4647
            {
4648
              /* Check for ambiguous symbols.  */
4649
              if (check_for_ambiguous (st->n.sym, info))
4650
                st->ambiguous = 1;
4651
              info->u.rsym.symtree = st;
4652
            }
4653
          else
4654
            {
4655
              st = gfc_find_symtree (gfc_current_ns->sym_root, name);
4656
 
4657
              /* Create a symtree node in the current namespace for this
4658
                 symbol.  */
4659
              st = check_unique_name (p)
4660
                   ? gfc_get_unique_symtree (gfc_current_ns)
4661
                   : gfc_new_symtree (&gfc_current_ns->sym_root, p);
4662
              st->ambiguous = ambiguous;
4663
 
4664
              sym = info->u.rsym.sym;
4665
 
4666
              /* Create a symbol node if it doesn't already exist.  */
4667
              if (sym == NULL)
4668
                {
4669
                  info->u.rsym.sym = gfc_new_symbol (info->u.rsym.true_name,
4670
                                                     gfc_current_ns);
4671
                  info->u.rsym.sym->name = dt_lower_string (info->u.rsym.true_name);
4672
                  sym = info->u.rsym.sym;
4673
                  sym->module = gfc_get_string (info->u.rsym.module);
4674
 
4675
                  if (info->u.rsym.binding_label)
4676
                    sym->binding_label =
4677
                      IDENTIFIER_POINTER (get_identifier
4678
                                          (info->u.rsym.binding_label));
4679
                }
4680
 
4681
              st->n.sym = sym;
4682
              st->n.sym->refs++;
4683
 
4684
              if (strcmp (name, p) != 0)
4685
                sym->attr.use_rename = 1;
4686
 
4687
              if (name[0] != '_'
4688
                  || (strncmp (name, "__vtab_", 5) != 0
4689
                      && strncmp (name, "__vtype_", 6) != 0))
4690
                sym->attr.use_only = only_flag;
4691
 
4692
              /* Store the symtree pointing to this symbol.  */
4693
              info->u.rsym.symtree = st;
4694
 
4695
              if (info->u.rsym.state == UNUSED)
4696
                info->u.rsym.state = NEEDED;
4697
              info->u.rsym.referenced = 1;
4698
            }
4699
        }
4700
    }
4701
 
4702
  mio_rparen ();
4703
 
4704
  /* Load intrinsic operator interfaces.  */
4705
  set_module_locus (&operator_interfaces);
4706
  mio_lparen ();
4707
 
4708
  for (i = GFC_INTRINSIC_BEGIN; i != GFC_INTRINSIC_END; i++)
4709
    {
4710
      if (i == INTRINSIC_USER)
4711
        continue;
4712
 
4713
      if (only_flag)
4714
        {
4715
          u = find_use_operator ((gfc_intrinsic_op) i);
4716
 
4717
          if (u == NULL)
4718
            {
4719
              skip_list ();
4720
              continue;
4721
            }
4722
 
4723
          u->found = 1;
4724
        }
4725
 
4726
      mio_interface (&gfc_current_ns->op[i]);
4727
      if (u && !gfc_current_ns->op[i])
4728
        u->found = 0;
4729
    }
4730
 
4731
  mio_rparen ();
4732
 
4733
  /* Load generic and user operator interfaces.  These must follow the
4734
     loading of symtree because otherwise symbols can be marked as
4735
     ambiguous.  */
4736
 
4737
  set_module_locus (&user_operators);
4738
 
4739
  load_operator_interfaces ();
4740
  load_generic_interfaces ();
4741
 
4742
  load_commons ();
4743
  load_equiv ();
4744
 
4745
  /* At this point, we read those symbols that are needed but haven't
4746
     been loaded yet.  If one symbol requires another, the other gets
4747
     marked as NEEDED if its previous state was UNUSED.  */
4748
 
4749
  while (load_needed (pi_root));
4750
 
4751
  /* Make sure all elements of the rename-list were found in the module.  */
4752
 
4753
  for (u = gfc_rename_list; u; u = u->next)
4754
    {
4755
      if (u->found)
4756
        continue;
4757
 
4758
      if (u->op == INTRINSIC_NONE)
4759
        {
4760
          gfc_error ("Symbol '%s' referenced at %L not found in module '%s'",
4761
                     u->use_name, &u->where, module_name);
4762
          continue;
4763
        }
4764
 
4765
      if (u->op == INTRINSIC_USER)
4766
        {
4767
          gfc_error ("User operator '%s' referenced at %L not found "
4768
                     "in module '%s'", u->use_name, &u->where, module_name);
4769
          continue;
4770
        }
4771
 
4772
      gfc_error ("Intrinsic operator '%s' referenced at %L not found "
4773
                 "in module '%s'", gfc_op2string (u->op), &u->where,
4774
                 module_name);
4775
    }
4776
 
4777
  /* Now we should be in a position to fill f2k_derived with derived type
4778
     extensions, since everything has been loaded.  */
4779
  set_module_locus (&extensions);
4780
  load_derived_extensions ();
4781
 
4782
  /* Clean up symbol nodes that were never loaded, create references
4783
     to hidden symbols.  */
4784
 
4785
  read_cleanup (pi_root);
4786
}
4787
 
4788
 
4789
/* Given an access type that is specific to an entity and the default
4790
   access, return nonzero if the entity is publicly accessible.  If the
4791
   element is declared as PUBLIC, then it is public; if declared
4792
   PRIVATE, then private, and otherwise it is public unless the default
4793
   access in this context has been declared PRIVATE.  */
4794
 
4795
static bool
4796
check_access (gfc_access specific_access, gfc_access default_access)
4797
{
4798
  if (specific_access == ACCESS_PUBLIC)
4799
    return TRUE;
4800
  if (specific_access == ACCESS_PRIVATE)
4801
    return FALSE;
4802
 
4803
  if (gfc_option.flag_module_private)
4804
    return default_access == ACCESS_PUBLIC;
4805
  else
4806
    return default_access != ACCESS_PRIVATE;
4807
}
4808
 
4809
 
4810
bool
4811
gfc_check_symbol_access (gfc_symbol *sym)
4812
{
4813
  if (sym->attr.vtab || sym->attr.vtype)
4814
    return true;
4815
  else
4816
    return check_access (sym->attr.access, sym->ns->default_access);
4817
}
4818
 
4819
 
4820
/* A structure to remember which commons we've already written.  */
4821
 
4822
struct written_common
4823
{
4824
  BBT_HEADER(written_common);
4825
  const char *name, *label;
4826
};
4827
 
4828
static struct written_common *written_commons = NULL;
4829
 
4830
/* Comparison function used for balancing the binary tree.  */
4831
 
4832
static int
4833
compare_written_commons (void *a1, void *b1)
4834
{
4835
  const char *aname = ((struct written_common *) a1)->name;
4836
  const char *alabel = ((struct written_common *) a1)->label;
4837
  const char *bname = ((struct written_common *) b1)->name;
4838
  const char *blabel = ((struct written_common *) b1)->label;
4839
  int c = strcmp (aname, bname);
4840
 
4841
  return (c != 0 ? c : strcmp (alabel, blabel));
4842
}
4843
 
4844
/* Free a list of written commons.  */
4845
 
4846
static void
4847
free_written_common (struct written_common *w)
4848
{
4849
  if (!w)
4850
    return;
4851
 
4852
  if (w->left)
4853
    free_written_common (w->left);
4854
  if (w->right)
4855
    free_written_common (w->right);
4856
 
4857
  free (w);
4858
}
4859
 
4860
/* Write a common block to the module -- recursive helper function.  */
4861
 
4862
static void
4863
write_common_0 (gfc_symtree *st, bool this_module)
4864
{
4865
  gfc_common_head *p;
4866
  const char * name;
4867
  int flags;
4868
  const char *label;
4869
  struct written_common *w;
4870
  bool write_me = true;
4871
 
4872
  if (st == NULL)
4873
    return;
4874
 
4875
  write_common_0 (st->left, this_module);
4876
 
4877
  /* We will write out the binding label, or "" if no label given.  */
4878
  name = st->n.common->name;
4879
  p = st->n.common;
4880
  label = (p->is_bind_c && p->binding_label) ? p->binding_label : "";
4881
 
4882
  /* Check if we've already output this common.  */
4883
  w = written_commons;
4884
  while (w)
4885
    {
4886
      int c = strcmp (name, w->name);
4887
      c = (c != 0 ? c : strcmp (label, w->label));
4888
      if (c == 0)
4889
        write_me = false;
4890
 
4891
      w = (c < 0) ? w->left : w->right;
4892
    }
4893
 
4894
  if (this_module && p->use_assoc)
4895
    write_me = false;
4896
 
4897
  if (write_me)
4898
    {
4899
      /* Write the common to the module.  */
4900
      mio_lparen ();
4901
      mio_pool_string (&name);
4902
 
4903
      mio_symbol_ref (&p->head);
4904
      flags = p->saved ? 1 : 0;
4905
      if (p->threadprivate)
4906
        flags |= 2;
4907
      mio_integer (&flags);
4908
 
4909
      /* Write out whether the common block is bind(c) or not.  */
4910
      mio_integer (&(p->is_bind_c));
4911
 
4912
      mio_pool_string (&label);
4913
      mio_rparen ();
4914
 
4915
      /* Record that we have written this common.  */
4916
      w = XCNEW (struct written_common);
4917
      w->name = p->name;
4918
      w->label = label;
4919
      gfc_insert_bbt (&written_commons, w, compare_written_commons);
4920
    }
4921
 
4922
  write_common_0 (st->right, this_module);
4923
}
4924
 
4925
 
4926
/* Write a common, by initializing the list of written commons, calling
4927
   the recursive function write_common_0() and cleaning up afterwards.  */
4928
 
4929
static void
4930
write_common (gfc_symtree *st)
4931
{
4932
  written_commons = NULL;
4933
  write_common_0 (st, true);
4934
  write_common_0 (st, false);
4935
  free_written_common (written_commons);
4936
  written_commons = NULL;
4937
}
4938
 
4939
 
4940
/* Write the blank common block to the module.  */
4941
 
4942
static void
4943
write_blank_common (void)
4944
{
4945
  const char * name = BLANK_COMMON_NAME;
4946
  int saved;
4947
  /* TODO: Blank commons are not bind(c).  The F2003 standard probably says
4948
     this, but it hasn't been checked.  Just making it so for now.  */
4949
  int is_bind_c = 0;
4950
 
4951
  if (gfc_current_ns->blank_common.head == NULL)
4952
    return;
4953
 
4954
  mio_lparen ();
4955
 
4956
  mio_pool_string (&name);
4957
 
4958
  mio_symbol_ref (&gfc_current_ns->blank_common.head);
4959
  saved = gfc_current_ns->blank_common.saved;
4960
  mio_integer (&saved);
4961
 
4962
  /* Write out whether the common block is bind(c) or not.  */
4963
  mio_integer (&is_bind_c);
4964
 
4965
  /* Write out an empty binding label.  */
4966
  write_atom (ATOM_STRING, "");
4967
 
4968
  mio_rparen ();
4969
}
4970
 
4971
 
4972
/* Write equivalences to the module.  */
4973
 
4974
static void
4975
write_equiv (void)
4976
{
4977
  gfc_equiv *eq, *e;
4978
  int num;
4979
 
4980
  num = 0;
4981
  for (eq = gfc_current_ns->equiv; eq; eq = eq->next)
4982
    {
4983
      mio_lparen ();
4984
 
4985
      for (e = eq; e; e = e->eq)
4986
        {
4987
          if (e->module == NULL)
4988
            e->module = gfc_get_string ("%s.eq.%d", module_name, num);
4989
          mio_allocated_string (e->module);
4990
          mio_expr (&e->expr);
4991
        }
4992
 
4993
      num++;
4994
      mio_rparen ();
4995
    }
4996
}
4997
 
4998
 
4999
/* Write derived type extensions to the module.  */
5000
 
5001
static void
5002
write_dt_extensions (gfc_symtree *st)
5003
{
5004
  if (!gfc_check_symbol_access (st->n.sym))
5005
    return;
5006
  if (!(st->n.sym->ns && st->n.sym->ns->proc_name
5007
        && st->n.sym->ns->proc_name->attr.flavor == FL_MODULE))
5008
    return;
5009
 
5010
  mio_lparen ();
5011
  mio_pool_string (&st->name);
5012
  if (st->n.sym->module != NULL)
5013
    mio_pool_string (&st->n.sym->module);
5014
  else
5015
    {
5016
      char name[GFC_MAX_SYMBOL_LEN + 1];
5017
      if (iomode == IO_OUTPUT)
5018
        strcpy (name, module_name);
5019
      mio_internal_string (name);
5020
      if (iomode == IO_INPUT)
5021
        module_name = gfc_get_string (name);
5022
    }
5023
  mio_rparen ();
5024
}
5025
 
5026
static void
5027
write_derived_extensions (gfc_symtree *st)
5028
{
5029
  if (!((st->n.sym->attr.flavor == FL_DERIVED)
5030
          && (st->n.sym->f2k_derived != NULL)
5031
          && (st->n.sym->f2k_derived->sym_root != NULL)))
5032
    return;
5033
 
5034
  mio_lparen ();
5035
  mio_symbol_ref (&(st->n.sym));
5036
  gfc_traverse_symtree (st->n.sym->f2k_derived->sym_root,
5037
                        write_dt_extensions);
5038
  mio_rparen ();
5039
}
5040
 
5041
 
5042
/* Write a symbol to the module.  */
5043
 
5044
static void
5045
write_symbol (int n, gfc_symbol *sym)
5046
{
5047
  const char *label;
5048
 
5049
  if (sym->attr.flavor == FL_UNKNOWN || sym->attr.flavor == FL_LABEL)
5050
    gfc_internal_error ("write_symbol(): bad module symbol '%s'", sym->name);
5051
 
5052
  mio_integer (&n);
5053
 
5054
  if (sym->attr.flavor == FL_DERIVED)
5055
    {
5056
      const char *name;
5057
      name = dt_upper_string (sym->name);
5058
      mio_pool_string (&name);
5059
    }
5060
  else
5061
    mio_pool_string (&sym->name);
5062
 
5063
  mio_pool_string (&sym->module);
5064
  if ((sym->attr.is_bind_c || sym->attr.is_iso_c) && sym->binding_label)
5065
    {
5066
      label = sym->binding_label;
5067
      mio_pool_string (&label);
5068
    }
5069
  else
5070
    write_atom (ATOM_STRING, "");
5071
 
5072
  mio_pointer_ref (&sym->ns);
5073
 
5074
  mio_symbol (sym);
5075
  write_char ('\n');
5076
}
5077
 
5078
 
5079
/* Recursive traversal function to write the initial set of symbols to
5080
   the module.  We check to see if the symbol should be written
5081
   according to the access specification.  */
5082
 
5083
static void
5084
write_symbol0 (gfc_symtree *st)
5085
{
5086
  gfc_symbol *sym;
5087
  pointer_info *p;
5088
  bool dont_write = false;
5089
 
5090
  if (st == NULL)
5091
    return;
5092
 
5093
  write_symbol0 (st->left);
5094
 
5095
  sym = st->n.sym;
5096
  if (sym->module == NULL)
5097
    sym->module = module_name;
5098
 
5099
  if (sym->attr.flavor == FL_PROCEDURE && sym->attr.generic
5100
      && !sym->attr.subroutine && !sym->attr.function)
5101
    dont_write = true;
5102
 
5103
  if (!gfc_check_symbol_access (sym))
5104
    dont_write = true;
5105
 
5106
  if (!dont_write)
5107
    {
5108
      p = get_pointer (sym);
5109
      if (p->type == P_UNKNOWN)
5110
        p->type = P_SYMBOL;
5111
 
5112
      if (p->u.wsym.state != WRITTEN)
5113
        {
5114
          write_symbol (p->integer, sym);
5115
          p->u.wsym.state = WRITTEN;
5116
        }
5117
    }
5118
 
5119
  write_symbol0 (st->right);
5120
}
5121
 
5122
 
5123
/* Recursive traversal function to write the secondary set of symbols
5124
   to the module file.  These are symbols that were not public yet are
5125
   needed by the public symbols or another dependent symbol.  The act
5126
   of writing a symbol can modify the pointer_info tree, so we cease
5127
   traversal if we find a symbol to write.  We return nonzero if a
5128
   symbol was written and pass that information upwards.  */
5129
 
5130
static int
5131
write_symbol1 (pointer_info *p)
5132
{
5133
  int result;
5134
 
5135
  if (!p)
5136
    return 0;
5137
 
5138
  result = write_symbol1 (p->left);
5139
 
5140
  if (!(p->type != P_SYMBOL || p->u.wsym.state != NEEDS_WRITE))
5141
    {
5142
      p->u.wsym.state = WRITTEN;
5143
      write_symbol (p->integer, p->u.wsym.sym);
5144
      result = 1;
5145
    }
5146
 
5147
  result |= write_symbol1 (p->right);
5148
  return result;
5149
}
5150
 
5151
 
5152
/* Write operator interfaces associated with a symbol.  */
5153
 
5154
static void
5155
write_operator (gfc_user_op *uop)
5156
{
5157
  static char nullstring[] = "";
5158
  const char *p = nullstring;
5159
 
5160
  if (uop->op == NULL || !check_access (uop->access, uop->ns->default_access))
5161
    return;
5162
 
5163
  mio_symbol_interface (&uop->name, &p, &uop->op);
5164
}
5165
 
5166
 
5167
/* Write generic interfaces from the namespace sym_root.  */
5168
 
5169
static void
5170
write_generic (gfc_symtree *st)
5171
{
5172
  gfc_symbol *sym;
5173
 
5174
  if (st == NULL)
5175
    return;
5176
 
5177
  write_generic (st->left);
5178
  write_generic (st->right);
5179
 
5180
  sym = st->n.sym;
5181
  if (!sym || check_unique_name (st->name))
5182
    return;
5183
 
5184
  if (sym->generic == NULL || !gfc_check_symbol_access (sym))
5185
    return;
5186
 
5187
  if (sym->module == NULL)
5188
    sym->module = module_name;
5189
 
5190
  mio_symbol_interface (&st->name, &sym->module, &sym->generic);
5191
}
5192
 
5193
 
5194
static void
5195
write_symtree (gfc_symtree *st)
5196
{
5197
  gfc_symbol *sym;
5198
  pointer_info *p;
5199
 
5200
  sym = st->n.sym;
5201
 
5202
  /* A symbol in an interface body must not be visible in the
5203
     module file.  */
5204
  if (sym->ns != gfc_current_ns
5205
        && sym->ns->proc_name
5206
        && sym->ns->proc_name->attr.if_source == IFSRC_IFBODY)
5207
    return;
5208
 
5209
  if (!gfc_check_symbol_access (sym)
5210
      || (sym->attr.flavor == FL_PROCEDURE && sym->attr.generic
5211
          && !sym->attr.subroutine && !sym->attr.function))
5212
    return;
5213
 
5214
  if (check_unique_name (st->name))
5215
    return;
5216
 
5217
  p = find_pointer (sym);
5218
  if (p == NULL)
5219
    gfc_internal_error ("write_symtree(): Symbol not written");
5220
 
5221
  mio_pool_string (&st->name);
5222
  mio_integer (&st->ambiguous);
5223
  mio_integer (&p->integer);
5224
}
5225
 
5226
 
5227
static void
5228
write_module (void)
5229
{
5230
  int i;
5231
 
5232
  /* Write the operator interfaces.  */
5233
  mio_lparen ();
5234
 
5235
  for (i = GFC_INTRINSIC_BEGIN; i != GFC_INTRINSIC_END; i++)
5236
    {
5237
      if (i == INTRINSIC_USER)
5238
        continue;
5239
 
5240
      mio_interface (check_access (gfc_current_ns->operator_access[i],
5241
                                   gfc_current_ns->default_access)
5242
                     ? &gfc_current_ns->op[i] : NULL);
5243
    }
5244
 
5245
  mio_rparen ();
5246
  write_char ('\n');
5247
  write_char ('\n');
5248
 
5249
  mio_lparen ();
5250
  gfc_traverse_user_op (gfc_current_ns, write_operator);
5251
  mio_rparen ();
5252
  write_char ('\n');
5253
  write_char ('\n');
5254
 
5255
  mio_lparen ();
5256
  write_generic (gfc_current_ns->sym_root);
5257
  mio_rparen ();
5258
  write_char ('\n');
5259
  write_char ('\n');
5260
 
5261
  mio_lparen ();
5262
  write_blank_common ();
5263
  write_common (gfc_current_ns->common_root);
5264
  mio_rparen ();
5265
  write_char ('\n');
5266
  write_char ('\n');
5267
 
5268
  mio_lparen ();
5269
  write_equiv ();
5270
  mio_rparen ();
5271
  write_char ('\n');
5272
  write_char ('\n');
5273
 
5274
  mio_lparen ();
5275
  gfc_traverse_symtree (gfc_current_ns->sym_root,
5276
                        write_derived_extensions);
5277
  mio_rparen ();
5278
  write_char ('\n');
5279
  write_char ('\n');
5280
 
5281
  /* Write symbol information.  First we traverse all symbols in the
5282
     primary namespace, writing those that need to be written.
5283
     Sometimes writing one symbol will cause another to need to be
5284
     written.  A list of these symbols ends up on the write stack, and
5285
     we end by popping the bottom of the stack and writing the symbol
5286
     until the stack is empty.  */
5287
 
5288
  mio_lparen ();
5289
 
5290
  write_symbol0 (gfc_current_ns->sym_root);
5291
  while (write_symbol1 (pi_root))
5292
    /* Nothing.  */;
5293
 
5294
  mio_rparen ();
5295
 
5296
  write_char ('\n');
5297
  write_char ('\n');
5298
 
5299
  mio_lparen ();
5300
  gfc_traverse_symtree (gfc_current_ns->sym_root, write_symtree);
5301
  mio_rparen ();
5302
}
5303
 
5304
 
5305
/* Read a MD5 sum from the header of a module file.  If the file cannot
5306
   be opened, or we have any other error, we return -1.  */
5307
 
5308
static int
5309
read_md5_from_module_file (const char * filename, unsigned char md5[16])
5310
{
5311
  FILE *file;
5312
  char buf[1024];
5313
  int n;
5314
 
5315
  /* Open the file.  */
5316
  if ((file = fopen (filename, "r")) == NULL)
5317
    return -1;
5318
 
5319
  /* Read the first line.  */
5320
  if (fgets (buf, sizeof (buf) - 1, file) == NULL)
5321
    {
5322
      fclose (file);
5323
      return -1;
5324
    }
5325
 
5326
  /* The file also needs to be overwritten if the version number changed.  */
5327
  n = strlen ("GFORTRAN module version '" MOD_VERSION "' created");
5328
  if (strncmp (buf, "GFORTRAN module version '" MOD_VERSION "' created", n) != 0)
5329
    {
5330
      fclose (file);
5331
      return -1;
5332
    }
5333
 
5334
  /* Read a second line.  */
5335
  if (fgets (buf, sizeof (buf) - 1, file) == NULL)
5336
    {
5337
      fclose (file);
5338
      return -1;
5339
    }
5340
 
5341
  /* Close the file.  */
5342
  fclose (file);
5343
 
5344
  /* If the header is not what we expect, or is too short, bail out.  */
5345
  if (strncmp (buf, "MD5:", 4) != 0 || strlen (buf) < 4 + 16)
5346
    return -1;
5347
 
5348
  /* Now, we have a real MD5, read it into the array.  */
5349
  for (n = 0; n < 16; n++)
5350
    {
5351
      unsigned int x;
5352
 
5353
      if (sscanf (&(buf[4+2*n]), "%02x", &x) != 1)
5354
       return -1;
5355
 
5356
      md5[n] = x;
5357
    }
5358
 
5359
  return 0;
5360
}
5361
 
5362
 
5363
/* Given module, dump it to disk.  If there was an error while
5364
   processing the module, dump_flag will be set to zero and we delete
5365
   the module file, even if it was already there.  */
5366
 
5367
void
5368
gfc_dump_module (const char *name, int dump_flag)
5369
{
5370
  int n;
5371
  char *filename, *filename_tmp;
5372
  fpos_t md5_pos;
5373
  unsigned char md5_new[16], md5_old[16];
5374
 
5375
  n = strlen (name) + strlen (MODULE_EXTENSION) + 1;
5376
  if (gfc_option.module_dir != NULL)
5377
    {
5378
      n += strlen (gfc_option.module_dir);
5379
      filename = (char *) alloca (n);
5380
      strcpy (filename, gfc_option.module_dir);
5381
      strcat (filename, name);
5382
    }
5383
  else
5384
    {
5385
      filename = (char *) alloca (n);
5386
      strcpy (filename, name);
5387
    }
5388
  strcat (filename, MODULE_EXTENSION);
5389
 
5390
  /* Name of the temporary file used to write the module.  */
5391
  filename_tmp = (char *) alloca (n + 1);
5392
  strcpy (filename_tmp, filename);
5393
  strcat (filename_tmp, "0");
5394
 
5395
  /* There was an error while processing the module.  We delete the
5396
     module file, even if it was already there.  */
5397
  if (!dump_flag)
5398
    {
5399
      unlink (filename);
5400
      return;
5401
    }
5402
 
5403
  if (gfc_cpp_makedep ())
5404
    gfc_cpp_add_target (filename);
5405
 
5406
  /* Write the module to the temporary file.  */
5407
  module_fp = fopen (filename_tmp, "w");
5408
  if (module_fp == NULL)
5409
    gfc_fatal_error ("Can't open module file '%s' for writing at %C: %s",
5410
                     filename_tmp, xstrerror (errno));
5411
 
5412
  /* Write the header, including space reserved for the MD5 sum.  */
5413
  fprintf (module_fp, "GFORTRAN module version '%s' created from %s\n"
5414
           "MD5:", MOD_VERSION, gfc_source_file);
5415
  fgetpos (module_fp, &md5_pos);
5416
  fputs ("00000000000000000000000000000000 -- "
5417
        "If you edit this, you'll get what you deserve.\n\n", module_fp);
5418
 
5419
  /* Initialize the MD5 context that will be used for output.  */
5420
  md5_init_ctx (&ctx);
5421
 
5422
  /* Write the module itself.  */
5423
  iomode = IO_OUTPUT;
5424
  module_name = gfc_get_string (name);
5425
 
5426
  init_pi_tree ();
5427
 
5428
  write_module ();
5429
 
5430
  free_pi_tree (pi_root);
5431
  pi_root = NULL;
5432
 
5433
  write_char ('\n');
5434
 
5435
  /* Write the MD5 sum to the header of the module file.  */
5436
  md5_finish_ctx (&ctx, md5_new);
5437
  fsetpos (module_fp, &md5_pos);
5438
  for (n = 0; n < 16; n++)
5439
    fprintf (module_fp, "%02x", md5_new[n]);
5440
 
5441
  if (fclose (module_fp))
5442
    gfc_fatal_error ("Error writing module file '%s' for writing: %s",
5443
                     filename_tmp, xstrerror (errno));
5444
 
5445
  /* Read the MD5 from the header of the old module file and compare.  */
5446
  if (read_md5_from_module_file (filename, md5_old) != 0
5447
      || memcmp (md5_old, md5_new, sizeof (md5_old)) != 0)
5448
    {
5449
      /* Module file have changed, replace the old one.  */
5450
      if (unlink (filename) && errno != ENOENT)
5451
        gfc_fatal_error ("Can't delete module file '%s': %s", filename,
5452
                         xstrerror (errno));
5453
      if (rename (filename_tmp, filename))
5454
        gfc_fatal_error ("Can't rename module file '%s' to '%s': %s",
5455
                         filename_tmp, filename, xstrerror (errno));
5456
    }
5457
  else
5458
    {
5459
      if (unlink (filename_tmp))
5460
        gfc_fatal_error ("Can't delete temporary module file '%s': %s",
5461
                         filename_tmp, xstrerror (errno));
5462
    }
5463
}
5464
 
5465
 
5466
static void
5467
create_intrinsic_function (const char *name, gfc_isym_id id,
5468
                           const char *modname, intmod_id module)
5469
{
5470
  gfc_intrinsic_sym *isym;
5471
  gfc_symtree *tmp_symtree;
5472
  gfc_symbol *sym;
5473
 
5474
  tmp_symtree = gfc_find_symtree (gfc_current_ns->sym_root, name);
5475
  if (tmp_symtree)
5476
    {
5477
      if (strcmp (modname, tmp_symtree->n.sym->module) == 0)
5478
        return;
5479
      gfc_error ("Symbol '%s' already declared", name);
5480
    }
5481
 
5482
  gfc_get_sym_tree (name, gfc_current_ns, &tmp_symtree, false);
5483
  sym = tmp_symtree->n.sym;
5484
 
5485
  isym = gfc_intrinsic_function_by_id (id);
5486
  gcc_assert (isym);
5487
 
5488
  sym->attr.flavor = FL_PROCEDURE;
5489
  sym->attr.intrinsic = 1;
5490
 
5491
  sym->module = gfc_get_string (modname);
5492
  sym->attr.use_assoc = 1;
5493
  sym->from_intmod = module;
5494
  sym->intmod_sym_id = id;
5495
}
5496
 
5497
 
5498
/* Import the intrinsic ISO_C_BINDING module, generating symbols in
5499
   the current namespace for all named constants, pointer types, and
5500
   procedures in the module unless the only clause was used or a rename
5501
   list was provided.  */
5502
 
5503
static void
5504
import_iso_c_binding_module (void)
5505
{
5506
  gfc_symbol *mod_sym = NULL;
5507
  gfc_symtree *mod_symtree = NULL;
5508
  const char *iso_c_module_name = "__iso_c_binding";
5509
  gfc_use_rename *u;
5510
  int i;
5511
 
5512
  /* Look only in the current namespace.  */
5513
  mod_symtree = gfc_find_symtree (gfc_current_ns->sym_root, iso_c_module_name);
5514
 
5515
  if (mod_symtree == NULL)
5516
    {
5517
      /* symtree doesn't already exist in current namespace.  */
5518
      gfc_get_sym_tree (iso_c_module_name, gfc_current_ns, &mod_symtree,
5519
                        false);
5520
 
5521
      if (mod_symtree != NULL)
5522
        mod_sym = mod_symtree->n.sym;
5523
      else
5524
        gfc_internal_error ("import_iso_c_binding_module(): Unable to "
5525
                            "create symbol for %s", iso_c_module_name);
5526
 
5527
      mod_sym->attr.flavor = FL_MODULE;
5528
      mod_sym->attr.intrinsic = 1;
5529
      mod_sym->module = gfc_get_string (iso_c_module_name);
5530
      mod_sym->from_intmod = INTMOD_ISO_C_BINDING;
5531
    }
5532
 
5533
  /* Generate the symbols for the named constants representing
5534
     the kinds for intrinsic data types.  */
5535
  for (i = 0; i < ISOCBINDING_NUMBER; i++)
5536
    {
5537
      bool found = false;
5538
      for (u = gfc_rename_list; u; u = u->next)
5539
        if (strcmp (c_interop_kinds_table[i].name, u->use_name) == 0)
5540
          {
5541
            bool not_in_std;
5542
            const char *name;
5543
            u->found = 1;
5544
            found = true;
5545
 
5546
            switch (i)
5547
              {
5548
#define NAMED_FUNCTION(a,b,c,d) \
5549
                case a: \
5550
                  not_in_std = (gfc_option.allow_std & d) == 0; \
5551
                  name = b; \
5552
                  break;
5553
#include "iso-c-binding.def"
5554
#undef NAMED_FUNCTION
5555
#define NAMED_INTCST(a,b,c,d) \
5556
                case a: \
5557
                  not_in_std = (gfc_option.allow_std & d) == 0; \
5558
                  name = b; \
5559
                  break;
5560
#include "iso-c-binding.def"
5561
#undef NAMED_INTCST
5562
#define NAMED_REALCST(a,b,c,d) \
5563
                case a: \
5564
                  not_in_std = (gfc_option.allow_std & d) == 0; \
5565
                  name = b; \
5566
                  break;
5567
#include "iso-c-binding.def"
5568
#undef NAMED_REALCST
5569
#define NAMED_CMPXCST(a,b,c,d) \
5570
                case a: \
5571
                  not_in_std = (gfc_option.allow_std & d) == 0; \
5572
                  name = b; \
5573
                  break;
5574
#include "iso-c-binding.def"
5575
#undef NAMED_CMPXCST
5576
                default:
5577
                  not_in_std = false;
5578
                  name = "";
5579
              }
5580
 
5581
            if (not_in_std)
5582
              {
5583
                gfc_error ("The symbol '%s', referenced at %L, is not "
5584
                           "in the selected standard", name, &u->where);
5585
                continue;
5586
              }
5587
 
5588
            switch (i)
5589
              {
5590
#define NAMED_FUNCTION(a,b,c,d) \
5591
                case a: \
5592
                  create_intrinsic_function (u->local_name[0] ? u->local_name \
5593
                                                              : u->use_name, \
5594
                                             (gfc_isym_id) c, \
5595
                                             iso_c_module_name, \
5596
                                             INTMOD_ISO_C_BINDING); \
5597
                  break;
5598
#include "iso-c-binding.def"
5599
#undef NAMED_FUNCTION
5600
 
5601
                default:
5602
                  generate_isocbinding_symbol (iso_c_module_name,
5603
                                               (iso_c_binding_symbol) i,
5604
                                               u->local_name[0] ? u->local_name
5605
                                                                : u->use_name);
5606
              }
5607
          }
5608
 
5609
      if (!found && !only_flag)
5610
        {
5611
          /* Skip, if the symbol is not in the enabled standard.  */
5612
          switch (i)
5613
            {
5614
#define NAMED_FUNCTION(a,b,c,d) \
5615
              case a: \
5616
                if ((gfc_option.allow_std & d) == 0) \
5617
                  continue; \
5618
                break;
5619
#include "iso-c-binding.def"
5620
#undef NAMED_FUNCTION
5621
 
5622
#define NAMED_INTCST(a,b,c,d) \
5623
              case a: \
5624
                if ((gfc_option.allow_std & d) == 0) \
5625
                  continue; \
5626
                break;
5627
#include "iso-c-binding.def"
5628
#undef NAMED_INTCST
5629
#define NAMED_REALCST(a,b,c,d) \
5630
              case a: \
5631
                if ((gfc_option.allow_std & d) == 0) \
5632
                  continue; \
5633
                break;
5634
#include "iso-c-binding.def"
5635
#undef NAMED_REALCST
5636
#define NAMED_CMPXCST(a,b,c,d) \
5637
              case a: \
5638
                if ((gfc_option.allow_std & d) == 0) \
5639
                  continue; \
5640
                break;
5641
#include "iso-c-binding.def"
5642
#undef NAMED_CMPXCST
5643
              default:
5644
                ; /* Not GFC_STD_* versioned. */
5645
            }
5646
 
5647
          switch (i)
5648
            {
5649
#define NAMED_FUNCTION(a,b,c,d) \
5650
              case a: \
5651
                create_intrinsic_function (b, (gfc_isym_id) c, \
5652
                                           iso_c_module_name, \
5653
                                           INTMOD_ISO_C_BINDING); \
5654
                  break;
5655
#include "iso-c-binding.def"
5656
#undef NAMED_FUNCTION
5657
 
5658
              default:
5659
                generate_isocbinding_symbol (iso_c_module_name,
5660
                                             (iso_c_binding_symbol) i, NULL);
5661
            }
5662
        }
5663
   }
5664
 
5665
   for (u = gfc_rename_list; u; u = u->next)
5666
     {
5667
      if (u->found)
5668
        continue;
5669
 
5670
      gfc_error ("Symbol '%s' referenced at %L not found in intrinsic "
5671
                 "module ISO_C_BINDING", u->use_name, &u->where);
5672
     }
5673
}
5674
 
5675
 
5676
/* Add an integer named constant from a given module.  */
5677
 
5678
static void
5679
create_int_parameter (const char *name, int value, const char *modname,
5680
                      intmod_id module, int id)
5681
{
5682
  gfc_symtree *tmp_symtree;
5683
  gfc_symbol *sym;
5684
 
5685
  tmp_symtree = gfc_find_symtree (gfc_current_ns->sym_root, name);
5686
  if (tmp_symtree != NULL)
5687
    {
5688
      if (strcmp (modname, tmp_symtree->n.sym->module) == 0)
5689
        return;
5690
      else
5691
        gfc_error ("Symbol '%s' already declared", name);
5692
    }
5693
 
5694
  gfc_get_sym_tree (name, gfc_current_ns, &tmp_symtree, false);
5695
  sym = tmp_symtree->n.sym;
5696
 
5697
  sym->module = gfc_get_string (modname);
5698
  sym->attr.flavor = FL_PARAMETER;
5699
  sym->ts.type = BT_INTEGER;
5700
  sym->ts.kind = gfc_default_integer_kind;
5701
  sym->value = gfc_get_int_expr (gfc_default_integer_kind, NULL, value);
5702
  sym->attr.use_assoc = 1;
5703
  sym->from_intmod = module;
5704
  sym->intmod_sym_id = id;
5705
}
5706
 
5707
 
5708
/* Value is already contained by the array constructor, but not
5709
   yet the shape.  */
5710
 
5711
static void
5712
create_int_parameter_array (const char *name, int size, gfc_expr *value,
5713
                            const char *modname, intmod_id module, int id)
5714
{
5715
  gfc_symtree *tmp_symtree;
5716
  gfc_symbol *sym;
5717
 
5718
  tmp_symtree = gfc_find_symtree (gfc_current_ns->sym_root, name);
5719
  if (tmp_symtree != NULL)
5720
    {
5721
      if (strcmp (modname, tmp_symtree->n.sym->module) == 0)
5722
        return;
5723
      else
5724
        gfc_error ("Symbol '%s' already declared", name);
5725
    }
5726
 
5727
  gfc_get_sym_tree (name, gfc_current_ns, &tmp_symtree, false);
5728
  sym = tmp_symtree->n.sym;
5729
 
5730
  sym->module = gfc_get_string (modname);
5731
  sym->attr.flavor = FL_PARAMETER;
5732
  sym->ts.type = BT_INTEGER;
5733
  sym->ts.kind = gfc_default_integer_kind;
5734
  sym->attr.use_assoc = 1;
5735
  sym->from_intmod = module;
5736
  sym->intmod_sym_id = id;
5737
  sym->attr.dimension = 1;
5738
  sym->as = gfc_get_array_spec ();
5739
  sym->as->rank = 1;
5740
  sym->as->type = AS_EXPLICIT;
5741
  sym->as->lower[0] = gfc_get_int_expr (gfc_default_integer_kind, NULL, 1);
5742
  sym->as->upper[0] = gfc_get_int_expr (gfc_default_integer_kind, NULL, size);
5743
 
5744
  sym->value = value;
5745
  sym->value->shape = gfc_get_shape (1);
5746
  mpz_init_set_ui (sym->value->shape[0], size);
5747
}
5748
 
5749
 
5750
/* Add an derived type for a given module.  */
5751
 
5752
static void
5753
create_derived_type (const char *name, const char *modname,
5754
                      intmod_id module, int id)
5755
{
5756
  gfc_symtree *tmp_symtree;
5757
  gfc_symbol *sym, *dt_sym;
5758
  gfc_interface *intr, *head;
5759
 
5760
  tmp_symtree = gfc_find_symtree (gfc_current_ns->sym_root, name);
5761
  if (tmp_symtree != NULL)
5762
    {
5763
      if (strcmp (modname, tmp_symtree->n.sym->module) == 0)
5764
        return;
5765
      else
5766
        gfc_error ("Symbol '%s' already declared", name);
5767
    }
5768
 
5769
  gfc_get_sym_tree (name, gfc_current_ns, &tmp_symtree, false);
5770
  sym = tmp_symtree->n.sym;
5771
  sym->module = gfc_get_string (modname);
5772
  sym->from_intmod = module;
5773
  sym->intmod_sym_id = id;
5774
  sym->attr.flavor = FL_PROCEDURE;
5775
  sym->attr.function = 1;
5776
  sym->attr.generic = 1;
5777
 
5778
  gfc_get_sym_tree (dt_upper_string (sym->name),
5779
                    gfc_current_ns, &tmp_symtree, false);
5780
  dt_sym = tmp_symtree->n.sym;
5781
  dt_sym->name = gfc_get_string (sym->name);
5782
  dt_sym->attr.flavor = FL_DERIVED;
5783
  dt_sym->attr.private_comp = 1;
5784
  dt_sym->attr.zero_comp = 1;
5785
  dt_sym->attr.use_assoc = 1;
5786
  dt_sym->module = gfc_get_string (modname);
5787
  dt_sym->from_intmod = module;
5788
  dt_sym->intmod_sym_id = id;
5789
 
5790
  head = sym->generic;
5791
  intr = gfc_get_interface ();
5792
  intr->sym = dt_sym;
5793
  intr->where = gfc_current_locus;
5794
  intr->next = head;
5795
  sym->generic = intr;
5796
  sym->attr.if_source = IFSRC_DECL;
5797
}
5798
 
5799
 
5800
/* USE the ISO_FORTRAN_ENV intrinsic module.  */
5801
 
5802
static void
5803
use_iso_fortran_env_module (void)
5804
{
5805
  static char mod[] = "iso_fortran_env";
5806
  gfc_use_rename *u;
5807
  gfc_symbol *mod_sym;
5808
  gfc_symtree *mod_symtree;
5809
  gfc_expr *expr;
5810
  int i, j;
5811
 
5812
  intmod_sym symbol[] = {
5813
#define NAMED_INTCST(a,b,c,d) { a, b, 0, d },
5814
#include "iso-fortran-env.def"
5815
#undef NAMED_INTCST
5816
#define NAMED_KINDARRAY(a,b,c,d) { a, b, 0, d },
5817
#include "iso-fortran-env.def"
5818
#undef NAMED_KINDARRAY
5819
#define NAMED_DERIVED_TYPE(a,b,c,d) { a, b, 0, d },
5820
#include "iso-fortran-env.def"
5821
#undef NAMED_DERIVED_TYPE
5822
#define NAMED_FUNCTION(a,b,c,d) { a, b, c, d },
5823
#include "iso-fortran-env.def"
5824
#undef NAMED_FUNCTION
5825
    { ISOFORTRANENV_INVALID, NULL, -1234, 0 } };
5826
 
5827
  i = 0;
5828
#define NAMED_INTCST(a,b,c,d) symbol[i++].value = c;
5829
#include "iso-fortran-env.def"
5830
#undef NAMED_INTCST
5831
 
5832
  /* Generate the symbol for the module itself.  */
5833
  mod_symtree = gfc_find_symtree (gfc_current_ns->sym_root, mod);
5834
  if (mod_symtree == NULL)
5835
    {
5836
      gfc_get_sym_tree (mod, gfc_current_ns, &mod_symtree, false);
5837
      gcc_assert (mod_symtree);
5838
      mod_sym = mod_symtree->n.sym;
5839
 
5840
      mod_sym->attr.flavor = FL_MODULE;
5841
      mod_sym->attr.intrinsic = 1;
5842
      mod_sym->module = gfc_get_string (mod);
5843
      mod_sym->from_intmod = INTMOD_ISO_FORTRAN_ENV;
5844
    }
5845
  else
5846
    if (!mod_symtree->n.sym->attr.intrinsic)
5847
      gfc_error ("Use of intrinsic module '%s' at %C conflicts with "
5848
                 "non-intrinsic module name used previously", mod);
5849
 
5850
  /* Generate the symbols for the module integer named constants.  */
5851
 
5852
  for (i = 0; symbol[i].name; i++)
5853
    {
5854
      bool found = false;
5855
      for (u = gfc_rename_list; u; u = u->next)
5856
        {
5857
          if (strcmp (symbol[i].name, u->use_name) == 0)
5858
            {
5859
              found = true;
5860
              u->found = 1;
5861
 
5862
              if (gfc_notify_std (symbol[i].standard, "The symbol '%s', "
5863
                                  "referenced at %L, is not in the selected "
5864
                                  "standard", symbol[i].name,
5865
                                  &u->where) == FAILURE)
5866
                continue;
5867
 
5868
              if ((gfc_option.flag_default_integer || gfc_option.flag_default_real)
5869
                  && symbol[i].id == ISOFORTRANENV_NUMERIC_STORAGE_SIZE)
5870
                gfc_warning_now ("Use of the NUMERIC_STORAGE_SIZE named "
5871
                                 "constant from intrinsic module "
5872
                                 "ISO_FORTRAN_ENV at %L is incompatible with "
5873
                                 "option %s", &u->where,
5874
                                 gfc_option.flag_default_integer
5875
                                   ? "-fdefault-integer-8"
5876
                                   : "-fdefault-real-8");
5877
              switch (symbol[i].id)
5878
                {
5879
#define NAMED_INTCST(a,b,c,d) \
5880
                case a:
5881
#include "iso-fortran-env.def"
5882
#undef NAMED_INTCST
5883
                  create_int_parameter (u->local_name[0] ? u->local_name
5884
                                                         : u->use_name,
5885
                                        symbol[i].value, mod,
5886
                                        INTMOD_ISO_FORTRAN_ENV, symbol[i].id);
5887
                  break;
5888
 
5889
#define NAMED_KINDARRAY(a,b,KINDS,d) \
5890
                case a:\
5891
                  expr = gfc_get_array_expr (BT_INTEGER, \
5892
                                             gfc_default_integer_kind,\
5893
                                             NULL); \
5894
                  for (j = 0; KINDS[j].kind != 0; j++) \
5895
                    gfc_constructor_append_expr (&expr->value.constructor, \
5896
                        gfc_get_int_expr (gfc_default_integer_kind, NULL, \
5897
                                          KINDS[j].kind), NULL); \
5898
                  create_int_parameter_array (u->local_name[0] ? u->local_name \
5899
                                                         : u->use_name, \
5900
                                              j, expr, mod, \
5901
                                              INTMOD_ISO_FORTRAN_ENV, \
5902
                                              symbol[i].id); \
5903
                  break;
5904
#include "iso-fortran-env.def"
5905
#undef NAMED_KINDARRAY
5906
 
5907
#define NAMED_DERIVED_TYPE(a,b,TYPE,STD) \
5908
                case a:
5909
#include "iso-fortran-env.def"
5910
                  create_derived_type (u->local_name[0] ? u->local_name
5911
                                                        : u->use_name,
5912
                                       mod, INTMOD_ISO_FORTRAN_ENV,
5913
                                       symbol[i].id);
5914
                  break;
5915
#undef NAMED_DERIVED_TYPE
5916
 
5917
#define NAMED_FUNCTION(a,b,c,d) \
5918
                case a:
5919
#include "iso-fortran-env.def"
5920
#undef NAMED_FUNCTION
5921
                  create_intrinsic_function (u->local_name[0] ? u->local_name
5922
                                                              : u->use_name,
5923
                                             (gfc_isym_id) symbol[i].value, mod,
5924
                                             INTMOD_ISO_FORTRAN_ENV);
5925
                  break;
5926
 
5927
                default:
5928
                  gcc_unreachable ();
5929
                }
5930
            }
5931
        }
5932
 
5933
      if (!found && !only_flag)
5934
        {
5935
          if ((gfc_option.allow_std & symbol[i].standard) == 0)
5936
            continue;
5937
 
5938
          if ((gfc_option.flag_default_integer || gfc_option.flag_default_real)
5939
              && symbol[i].id == ISOFORTRANENV_NUMERIC_STORAGE_SIZE)
5940
            gfc_warning_now ("Use of the NUMERIC_STORAGE_SIZE named constant "
5941
                             "from intrinsic module ISO_FORTRAN_ENV at %C is "
5942
                             "incompatible with option %s",
5943
                             gfc_option.flag_default_integer
5944
                                ? "-fdefault-integer-8" : "-fdefault-real-8");
5945
 
5946
          switch (symbol[i].id)
5947
            {
5948
#define NAMED_INTCST(a,b,c,d) \
5949
            case a:
5950
#include "iso-fortran-env.def"
5951
#undef NAMED_INTCST
5952
              create_int_parameter (symbol[i].name, symbol[i].value, mod,
5953
                                    INTMOD_ISO_FORTRAN_ENV, symbol[i].id);
5954
              break;
5955
 
5956
#define NAMED_KINDARRAY(a,b,KINDS,d) \
5957
            case a:\
5958
              expr = gfc_get_array_expr (BT_INTEGER, gfc_default_integer_kind, \
5959
                                         NULL); \
5960
              for (j = 0; KINDS[j].kind != 0; j++) \
5961
                gfc_constructor_append_expr (&expr->value.constructor, \
5962
                      gfc_get_int_expr (gfc_default_integer_kind, NULL, \
5963
                                        KINDS[j].kind), NULL); \
5964
            create_int_parameter_array (symbol[i].name, j, expr, mod, \
5965
                                        INTMOD_ISO_FORTRAN_ENV, symbol[i].id);\
5966
            break;
5967
#include "iso-fortran-env.def"
5968
#undef NAMED_KINDARRAY
5969
 
5970
#define NAMED_DERIVED_TYPE(a,b,TYPE,STD) \
5971
          case a:
5972
#include "iso-fortran-env.def"
5973
            create_derived_type (symbol[i].name, mod, INTMOD_ISO_FORTRAN_ENV,
5974
                                 symbol[i].id);
5975
            break;
5976
#undef NAMED_DERIVED_TYPE
5977
 
5978
#define NAMED_FUNCTION(a,b,c,d) \
5979
                case a:
5980
#include "iso-fortran-env.def"
5981
#undef NAMED_FUNCTION
5982
                  create_intrinsic_function (symbol[i].name,
5983
                                             (gfc_isym_id) symbol[i].value, mod,
5984
                                             INTMOD_ISO_FORTRAN_ENV);
5985
                  break;
5986
 
5987
          default:
5988
            gcc_unreachable ();
5989
          }
5990
        }
5991
    }
5992
 
5993
  for (u = gfc_rename_list; u; u = u->next)
5994
    {
5995
      if (u->found)
5996
        continue;
5997
 
5998
      gfc_error ("Symbol '%s' referenced at %L not found in intrinsic "
5999
                     "module ISO_FORTRAN_ENV", u->use_name, &u->where);
6000
    }
6001
}
6002
 
6003
 
6004
/* Process a USE directive.  */
6005
 
6006
static void
6007
gfc_use_module (gfc_use_list *module)
6008
{
6009
  char *filename;
6010
  gfc_state_data *p;
6011
  int c, line, start;
6012
  gfc_symtree *mod_symtree;
6013
  gfc_use_list *use_stmt;
6014
  locus old_locus = gfc_current_locus;
6015
 
6016
  gfc_current_locus = module->where;
6017
  module_name = module->module_name;
6018
  gfc_rename_list = module->rename;
6019
  only_flag = module->only_flag;
6020
 
6021
  filename = XALLOCAVEC (char, strlen (module_name) + strlen (MODULE_EXTENSION)
6022
                               + 1);
6023
  strcpy (filename, module_name);
6024
  strcat (filename, MODULE_EXTENSION);
6025
 
6026
  /* First, try to find an non-intrinsic module, unless the USE statement
6027
     specified that the module is intrinsic.  */
6028
  module_fp = NULL;
6029
  if (!module->intrinsic)
6030
    module_fp = gfc_open_included_file (filename, true, true);
6031
 
6032
  /* Then, see if it's an intrinsic one, unless the USE statement
6033
     specified that the module is non-intrinsic.  */
6034
  if (module_fp == NULL && !module->non_intrinsic)
6035
    {
6036
      if (strcmp (module_name, "iso_fortran_env") == 0
6037
          && gfc_notify_std (GFC_STD_F2003, "Fortran 2003: ISO_FORTRAN_ENV "
6038
                             "intrinsic module at %C") != FAILURE)
6039
       {
6040
         use_iso_fortran_env_module ();
6041
         gfc_current_locus = old_locus;
6042
         module->intrinsic = true;
6043
         return;
6044
       }
6045
 
6046
      if (strcmp (module_name, "iso_c_binding") == 0
6047
          && gfc_notify_std (GFC_STD_F2003, "Fortran 2003: "
6048
                             "ISO_C_BINDING module at %C") != FAILURE)
6049
        {
6050
          import_iso_c_binding_module();
6051
          gfc_current_locus = old_locus;
6052
          module->intrinsic = true;
6053
          return;
6054
        }
6055
 
6056
      module_fp = gfc_open_intrinsic_module (filename);
6057
 
6058
      if (module_fp == NULL && module->intrinsic)
6059
        gfc_fatal_error ("Can't find an intrinsic module named '%s' at %C",
6060
                         module_name);
6061
    }
6062
 
6063
  if (module_fp == NULL)
6064
    gfc_fatal_error ("Can't open module file '%s' for reading at %C: %s",
6065
                     filename, xstrerror (errno));
6066
 
6067
  /* Check that we haven't already USEd an intrinsic module with the
6068
     same name.  */
6069
 
6070
  mod_symtree = gfc_find_symtree (gfc_current_ns->sym_root, module_name);
6071
  if (mod_symtree && mod_symtree->n.sym->attr.intrinsic)
6072
    gfc_error ("Use of non-intrinsic module '%s' at %C conflicts with "
6073
               "intrinsic module name used previously", module_name);
6074
 
6075
  iomode = IO_INPUT;
6076
  module_line = 1;
6077
  module_column = 1;
6078
  start = 0;
6079
 
6080
  /* Skip the first two lines of the module, after checking that this is
6081
     a gfortran module file.  */
6082
  line = 0;
6083
  while (line < 2)
6084
    {
6085
      c = module_char ();
6086
      if (c == EOF)
6087
        bad_module ("Unexpected end of module");
6088
      if (start++ < 3)
6089
        parse_name (c);
6090
      if ((start == 1 && strcmp (atom_name, "GFORTRAN") != 0)
6091
          || (start == 2 && strcmp (atom_name, " module") != 0))
6092
        gfc_fatal_error ("File '%s' opened at %C is not a GFORTRAN module "
6093
                         "file", filename);
6094
      if (start == 3)
6095
        {
6096
          if (strcmp (atom_name, " version") != 0
6097
              || module_char () != ' '
6098
              || parse_atom () != ATOM_STRING)
6099
            gfc_fatal_error ("Parse error when checking module version"
6100
                             " for file '%s' opened at %C", filename);
6101
 
6102
          if (strcmp (atom_string, MOD_VERSION))
6103
            {
6104
              gfc_fatal_error ("Wrong module version '%s' (expected '%s') "
6105
                               "for file '%s' opened at %C", atom_string,
6106
                               MOD_VERSION, filename);
6107
            }
6108
 
6109
          free (atom_string);
6110
        }
6111
 
6112
      if (c == '\n')
6113
        line++;
6114
    }
6115
 
6116
  /* Make sure we're not reading the same module that we may be building.  */
6117
  for (p = gfc_state_stack; p; p = p->previous)
6118
    if (p->state == COMP_MODULE && strcmp (p->sym->name, module_name) == 0)
6119
      gfc_fatal_error ("Can't USE the same module we're building!");
6120
 
6121
  init_pi_tree ();
6122
  init_true_name_tree ();
6123
 
6124
  read_module ();
6125
 
6126
  free_true_name (true_name_root);
6127
  true_name_root = NULL;
6128
 
6129
  free_pi_tree (pi_root);
6130
  pi_root = NULL;
6131
 
6132
  fclose (module_fp);
6133
 
6134
  use_stmt = gfc_get_use_list ();
6135
  *use_stmt = *module;
6136
  use_stmt->next = gfc_current_ns->use_stmts;
6137
  gfc_current_ns->use_stmts = use_stmt;
6138
 
6139
  gfc_current_locus = old_locus;
6140
}
6141
 
6142
 
6143
/* Remove duplicated intrinsic operators from the rename list. */
6144
 
6145
static void
6146
rename_list_remove_duplicate (gfc_use_rename *list)
6147
{
6148
  gfc_use_rename *seek, *last;
6149
 
6150
  for (; list; list = list->next)
6151
    if (list->op != INTRINSIC_USER && list->op != INTRINSIC_NONE)
6152
      {
6153
        last = list;
6154
        for (seek = list->next; seek; seek = last->next)
6155
          {
6156
            if (list->op == seek->op)
6157
              {
6158
                last->next = seek->next;
6159
                free (seek);
6160
              }
6161
            else
6162
              last = seek;
6163
          }
6164
      }
6165
}
6166
 
6167
 
6168
/* Process all USE directives.  */
6169
 
6170
void
6171
gfc_use_modules (void)
6172
{
6173
  gfc_use_list *next, *seek, *last;
6174
 
6175
  for (next = module_list; next; next = next->next)
6176
    {
6177
      bool non_intrinsic = next->non_intrinsic;
6178
      bool intrinsic = next->intrinsic;
6179
      bool neither = !non_intrinsic && !intrinsic;
6180
 
6181
      for (seek = next->next; seek; seek = seek->next)
6182
        {
6183
          if (next->module_name != seek->module_name)
6184
            continue;
6185
 
6186
          if (seek->non_intrinsic)
6187
            non_intrinsic = true;
6188
          else if (seek->intrinsic)
6189
            intrinsic = true;
6190
          else
6191
            neither = true;
6192
        }
6193
 
6194
      if (intrinsic && neither && !non_intrinsic)
6195
        {
6196
          char *filename;
6197
          FILE *fp;
6198
 
6199
          filename = XALLOCAVEC (char,
6200
                                 strlen (next->module_name)
6201
                                 + strlen (MODULE_EXTENSION) + 1);
6202
          strcpy (filename, next->module_name);
6203
          strcat (filename, MODULE_EXTENSION);
6204
          fp = gfc_open_included_file (filename, true, true);
6205
          if (fp != NULL)
6206
            {
6207
              non_intrinsic = true;
6208
              fclose (fp);
6209
            }
6210
        }
6211
 
6212
      last = next;
6213
      for (seek = next->next; seek; seek = last->next)
6214
        {
6215
          if (next->module_name != seek->module_name)
6216
            {
6217
              last = seek;
6218
              continue;
6219
            }
6220
 
6221
          if ((!next->intrinsic && !seek->intrinsic)
6222
              || (next->intrinsic && seek->intrinsic)
6223
              || !non_intrinsic)
6224
            {
6225
              if (!seek->only_flag)
6226
                next->only_flag = false;
6227
              if (seek->rename)
6228
                {
6229
                  gfc_use_rename *r = seek->rename;
6230
                  while (r->next)
6231
                    r = r->next;
6232
                  r->next = next->rename;
6233
                  next->rename = seek->rename;
6234
                }
6235
              last->next = seek->next;
6236
              free (seek);
6237
            }
6238
          else
6239
            last = seek;
6240
        }
6241
    }
6242
 
6243
  for (; module_list; module_list = next)
6244
    {
6245
      next = module_list->next;
6246
      rename_list_remove_duplicate (module_list->rename);
6247
      gfc_use_module (module_list);
6248
      if (module_list->intrinsic)
6249
        free_rename (module_list->rename);
6250
      free (module_list);
6251
    }
6252
  gfc_rename_list = NULL;
6253
}
6254
 
6255
 
6256
void
6257
gfc_free_use_stmts (gfc_use_list *use_stmts)
6258
{
6259
  gfc_use_list *next;
6260
  for (; use_stmts; use_stmts = next)
6261
    {
6262
      gfc_use_rename *next_rename;
6263
 
6264
      for (; use_stmts->rename; use_stmts->rename = next_rename)
6265
        {
6266
          next_rename = use_stmts->rename->next;
6267
          free (use_stmts->rename);
6268
        }
6269
      next = use_stmts->next;
6270
      free (use_stmts);
6271
    }
6272
}
6273
 
6274
 
6275
void
6276
gfc_module_init_2 (void)
6277
{
6278
  last_atom = ATOM_LPAREN;
6279
  gfc_rename_list = NULL;
6280
  module_list = NULL;
6281
}
6282
 
6283
 
6284
void
6285
gfc_module_done_2 (void)
6286
{
6287
  free_rename (gfc_rename_list);
6288
  gfc_rename_list = NULL;
6289
}

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