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[/] [openrisc/] [trunk/] [gnu-src/] [gcc-4.5.1/] [gcc/] [fortran/] [module.c] - Blame information for rev 290

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

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