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

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1 712 jeremybenn
/* Dependency analysis
2
   Copyright (C) 2000, 2001, 2002, 2005, 2006, 2007, 2008, 2009, 2010
3
   Free Software Foundation, Inc.
4
   Contributed by Paul Brook <paul@nowt.org>
5
 
6
This file is part of GCC.
7
 
8
GCC is free software; you can redistribute it and/or modify it under
9
the terms of the GNU General Public License as published by the Free
10
Software Foundation; either version 3, or (at your option) any later
11
version.
12
 
13
GCC is distributed in the hope that it will be useful, but WITHOUT ANY
14
WARRANTY; without even the implied warranty of MERCHANTABILITY or
15
FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
16
for more details.
17
 
18
You should have received a copy of the GNU General Public License
19
along with GCC; see the file COPYING3.  If not see
20
<http://www.gnu.org/licenses/>.  */
21
 
22
/* dependency.c -- Expression dependency analysis code.  */
23
/* There's probably quite a bit of duplication in this file.  We currently
24
   have different dependency checking functions for different types
25
   if dependencies.  Ideally these would probably be merged.  */
26
 
27
#include "config.h"
28
#include "system.h"
29
#include "gfortran.h"
30
#include "dependency.h"
31
#include "constructor.h"
32
#include "arith.h"
33
 
34
/* static declarations */
35
/* Enums  */
36
enum range {LHS, RHS, MID};
37
 
38
/* Dependency types.  These must be in reverse order of priority.  */
39
typedef enum
40
{
41
  GFC_DEP_ERROR,
42
  GFC_DEP_EQUAL,        /* Identical Ranges.  */
43
  GFC_DEP_FORWARD,      /* e.g., a(1:3) = a(2:4).  */
44
  GFC_DEP_BACKWARD,     /* e.g. a(2:4) = a(1:3).  */
45
  GFC_DEP_OVERLAP,      /* May overlap in some other way.  */
46
  GFC_DEP_NODEP         /* Distinct ranges.  */
47
}
48
gfc_dependency;
49
 
50
/* Macros */
51
#define IS_ARRAY_EXPLICIT(as) ((as->type == AS_EXPLICIT ? 1 : 0))
52
 
53
/* Forward declarations */
54
 
55
static gfc_dependency check_section_vs_section (gfc_array_ref *,
56
                                                gfc_array_ref *, int);
57
 
58
/* Returns 1 if the expr is an integer constant value 1, 0 if it is not or
59
   def if the value could not be determined.  */
60
 
61
int
62
gfc_expr_is_one (gfc_expr *expr, int def)
63
{
64
  gcc_assert (expr != NULL);
65
 
66
  if (expr->expr_type != EXPR_CONSTANT)
67
    return def;
68
 
69
  if (expr->ts.type != BT_INTEGER)
70
    return def;
71
 
72
  return mpz_cmp_si (expr->value.integer, 1) == 0;
73
}
74
 
75
/* Check if two array references are known to be identical.  Calls
76
   gfc_dep_compare_expr if necessary for comparing array indices.  */
77
 
78
static bool
79
identical_array_ref (gfc_array_ref *a1, gfc_array_ref *a2)
80
{
81
  int i;
82
 
83
  if (a1->type == AR_FULL && a2->type == AR_FULL)
84
    return true;
85
 
86
  if (a1->type == AR_SECTION && a2->type == AR_SECTION)
87
    {
88
      gcc_assert (a1->dimen == a2->dimen);
89
 
90
      for ( i = 0; i < a1->dimen; i++)
91
        {
92
          /* TODO: Currently, we punt on an integer array as an index.  */
93
          if (a1->dimen_type[i] != DIMEN_RANGE
94
              || a2->dimen_type[i] != DIMEN_RANGE)
95
            return false;
96
 
97
          if (check_section_vs_section (a1, a2, i) != GFC_DEP_EQUAL)
98
            return false;
99
        }
100
      return true;
101
    }
102
 
103
  if (a1->type == AR_ELEMENT && a2->type == AR_ELEMENT)
104
    {
105
      gcc_assert (a1->dimen == a2->dimen);
106
      for (i = 0; i < a1->dimen; i++)
107
        {
108
          if (gfc_dep_compare_expr (a1->start[i], a2->start[i]) != 0)
109
            return false;
110
        }
111
      return true;
112
    }
113
  return false;
114
}
115
 
116
 
117
 
118
/* Return true for identical variables, checking for references if
119
   necessary.  Calls identical_array_ref for checking array sections.  */
120
 
121
static bool
122
are_identical_variables (gfc_expr *e1, gfc_expr *e2)
123
{
124
  gfc_ref *r1, *r2;
125
 
126
  if (e1->symtree->n.sym->attr.dummy && e2->symtree->n.sym->attr.dummy)
127
    {
128
      /* Dummy arguments: Only check for equal names.  */
129
      if (e1->symtree->n.sym->name != e2->symtree->n.sym->name)
130
        return false;
131
    }
132
  else
133
    {
134
      /* Check for equal symbols.  */
135
      if (e1->symtree->n.sym != e2->symtree->n.sym)
136
        return false;
137
    }
138
 
139
  /* Volatile variables should never compare equal to themselves.  */
140
 
141
  if (e1->symtree->n.sym->attr.volatile_)
142
    return false;
143
 
144
  r1 = e1->ref;
145
  r2 = e2->ref;
146
 
147
  while (r1 != NULL || r2 != NULL)
148
    {
149
 
150
      /* Assume the variables are not equal if one has a reference and the
151
         other doesn't.
152
         TODO: Handle full references like comparing a(:) to a.
153
      */
154
 
155
      if (r1 == NULL || r2 == NULL)
156
        return false;
157
 
158
      if (r1->type != r2->type)
159
        return false;
160
 
161
      switch (r1->type)
162
        {
163
 
164
        case REF_ARRAY:
165
          if (!identical_array_ref (&r1->u.ar,  &r2->u.ar))
166
            return false;
167
 
168
          break;
169
 
170
        case REF_COMPONENT:
171
          if (r1->u.c.component != r2->u.c.component)
172
            return false;
173
          break;
174
 
175
        case REF_SUBSTRING:
176
          if (gfc_dep_compare_expr (r1->u.ss.start, r2->u.ss.start) != 0)
177
            return false;
178
 
179
          /* If both are NULL, the end length compares equal, because we
180
             are looking at the same variable. This can only happen for
181
             assumed- or deferred-length character arguments.  */
182
 
183
          if (r1->u.ss.end == NULL && r2->u.ss.end == NULL)
184
            break;
185
 
186
          if (gfc_dep_compare_expr (r1->u.ss.end, r2->u.ss.end) != 0)
187
            return false;
188
 
189
          break;
190
 
191
        default:
192
          gfc_internal_error ("are_identical_variables: Bad type");
193
        }
194
      r1 = r1->next;
195
      r2 = r2->next;
196
    }
197
  return true;
198
}
199
 
200
/* Compare two functions for equality.  Returns 0 if e1==e2, -2 otherwise.  If
201
   impure_ok is false, only return 0 for pure functions.  */
202
 
203
int
204
gfc_dep_compare_functions (gfc_expr *e1, gfc_expr *e2, bool impure_ok)
205
{
206
 
207
  gfc_actual_arglist *args1;
208
  gfc_actual_arglist *args2;
209
 
210
  if (e1->expr_type != EXPR_FUNCTION || e2->expr_type != EXPR_FUNCTION)
211
    return -2;
212
 
213
  if ((e1->value.function.esym && e2->value.function.esym
214
       && e1->value.function.esym == e2->value.function.esym
215
       && (e1->value.function.esym->result->attr.pure || impure_ok))
216
       || (e1->value.function.isym && e2->value.function.isym
217
           && e1->value.function.isym == e2->value.function.isym
218
           && (e1->value.function.isym->pure || impure_ok)))
219
    {
220
      args1 = e1->value.function.actual;
221
      args2 = e2->value.function.actual;
222
 
223
      /* Compare the argument lists for equality.  */
224
      while (args1 && args2)
225
        {
226
          /*  Bitwise xor, since C has no non-bitwise xor operator.  */
227
          if ((args1->expr == NULL) ^ (args2->expr == NULL))
228
            return -2;
229
 
230
          if (args1->expr != NULL && args2->expr != NULL
231
              && gfc_dep_compare_expr (args1->expr, args2->expr) != 0)
232
            return -2;
233
 
234
          args1 = args1->next;
235
          args2 = args2->next;
236
        }
237
      return (args1 || args2) ? -2 : 0;
238
    }
239
      else
240
        return -2;
241
}
242
 
243
/* Compare two expressions.  Return values:
244
   * +1 if e1 > e2
245
   * 0 if e1 == e2
246
   * -1 if e1 < e2
247
   * -2 if the relationship could not be determined
248
   * -3 if e1 /= e2, but we cannot tell which one is larger.
249
   REAL and COMPLEX constants are only compared for equality
250
   or inequality; if they are unequal, -2 is returned in all cases.  */
251
 
252
int
253
gfc_dep_compare_expr (gfc_expr *e1, gfc_expr *e2)
254
{
255
  gfc_actual_arglist *args1;
256
  gfc_actual_arglist *args2;
257
  int i;
258
  gfc_expr *n1, *n2;
259
 
260
  n1 = NULL;
261
  n2 = NULL;
262
 
263
  /* Remove any integer conversion functions to larger types.  */
264
  if (e1->expr_type == EXPR_FUNCTION && e1->value.function.isym
265
      && e1->value.function.isym->id == GFC_ISYM_CONVERSION
266
      && e1->ts.type == BT_INTEGER)
267
    {
268
      args1 = e1->value.function.actual;
269
      if (args1->expr->ts.type == BT_INTEGER
270
          && e1->ts.kind > args1->expr->ts.kind)
271
        n1 = args1->expr;
272
    }
273
 
274
  if (e2->expr_type == EXPR_FUNCTION && e2->value.function.isym
275
      && e2->value.function.isym->id == GFC_ISYM_CONVERSION
276
      && e2->ts.type == BT_INTEGER)
277
    {
278
      args2 = e2->value.function.actual;
279
      if (args2->expr->ts.type == BT_INTEGER
280
          && e2->ts.kind > args2->expr->ts.kind)
281
        n2 = args2->expr;
282
    }
283
 
284
  if (n1 != NULL)
285
    {
286
      if (n2 != NULL)
287
        return gfc_dep_compare_expr (n1, n2);
288
      else
289
        return gfc_dep_compare_expr (n1, e2);
290
    }
291
  else
292
    {
293
      if (n2 != NULL)
294
        return gfc_dep_compare_expr (e1, n2);
295
    }
296
 
297
  if (e1->expr_type == EXPR_OP
298
      && (e1->value.op.op == INTRINSIC_UPLUS
299
          || e1->value.op.op == INTRINSIC_PARENTHESES))
300
    return gfc_dep_compare_expr (e1->value.op.op1, e2);
301
  if (e2->expr_type == EXPR_OP
302
      && (e2->value.op.op == INTRINSIC_UPLUS
303
          || e2->value.op.op == INTRINSIC_PARENTHESES))
304
    return gfc_dep_compare_expr (e1, e2->value.op.op1);
305
 
306
  if (e1->expr_type == EXPR_OP && e1->value.op.op == INTRINSIC_PLUS)
307
    {
308
      /* Compare X+C vs. X, for INTEGER only.  */
309
      if (e1->value.op.op2->expr_type == EXPR_CONSTANT
310
          && e1->value.op.op2->ts.type == BT_INTEGER
311
          && gfc_dep_compare_expr (e1->value.op.op1, e2) == 0)
312
        return mpz_sgn (e1->value.op.op2->value.integer);
313
 
314
      /* Compare P+Q vs. R+S.  */
315
      if (e2->expr_type == EXPR_OP && e2->value.op.op == INTRINSIC_PLUS)
316
        {
317
          int l, r;
318
 
319
          l = gfc_dep_compare_expr (e1->value.op.op1, e2->value.op.op1);
320
          r = gfc_dep_compare_expr (e1->value.op.op2, e2->value.op.op2);
321
          if (l == 0 && r == 0)
322
            return 0;
323
          if (l == 0 && r > -2)
324
            return r;
325
          if (l > -2 && r == 0)
326
            return l;
327
          if (l == 1 && r == 1)
328
            return 1;
329
          if (l == -1 && r == -1)
330
            return -1;
331
 
332
          l = gfc_dep_compare_expr (e1->value.op.op1, e2->value.op.op2);
333
          r = gfc_dep_compare_expr (e1->value.op.op2, e2->value.op.op1);
334
          if (l == 0 && r == 0)
335
            return 0;
336
          if (l == 0 && r > -2)
337
            return r;
338
          if (l > -2 && r == 0)
339
            return l;
340
          if (l == 1 && r == 1)
341
            return 1;
342
          if (l == -1 && r == -1)
343
            return -1;
344
        }
345
    }
346
 
347
  /* Compare X vs. X+C, for INTEGER only.  */
348
  if (e2->expr_type == EXPR_OP && e2->value.op.op == INTRINSIC_PLUS)
349
    {
350
      if (e2->value.op.op2->expr_type == EXPR_CONSTANT
351
          && e2->value.op.op2->ts.type == BT_INTEGER
352
          && gfc_dep_compare_expr (e1, e2->value.op.op1) == 0)
353
        return -mpz_sgn (e2->value.op.op2->value.integer);
354
    }
355
 
356
  /* Compare X-C vs. X, for INTEGER only.  */
357
  if (e1->expr_type == EXPR_OP && e1->value.op.op == INTRINSIC_MINUS)
358
    {
359
      if (e1->value.op.op2->expr_type == EXPR_CONSTANT
360
          && e1->value.op.op2->ts.type == BT_INTEGER
361
          && gfc_dep_compare_expr (e1->value.op.op1, e2) == 0)
362
        return -mpz_sgn (e1->value.op.op2->value.integer);
363
 
364
      /* Compare P-Q vs. R-S.  */
365
      if (e2->expr_type == EXPR_OP && e2->value.op.op == INTRINSIC_MINUS)
366
        {
367
          int l, r;
368
 
369
          l = gfc_dep_compare_expr (e1->value.op.op1, e2->value.op.op1);
370
          r = gfc_dep_compare_expr (e1->value.op.op2, e2->value.op.op2);
371
          if (l == 0 && r == 0)
372
            return 0;
373
          if (l > -2 && r == 0)
374
            return l;
375
          if (l == 0 && r > -2)
376
            return -r;
377
          if (l == 1 && r == -1)
378
            return 1;
379
          if (l == -1 && r == 1)
380
            return -1;
381
        }
382
    }
383
 
384
  /* Compare A // B vs. C // D.  */
385
 
386
  if (e1->expr_type == EXPR_OP && e1->value.op.op == INTRINSIC_CONCAT
387
      && e2->expr_type == EXPR_OP && e2->value.op.op == INTRINSIC_CONCAT)
388
    {
389
      int l, r;
390
 
391
      l = gfc_dep_compare_expr (e1->value.op.op1, e2->value.op.op1);
392
      r = gfc_dep_compare_expr (e1->value.op.op2, e2->value.op.op2);
393
 
394
      if (l <= -2)
395
        return l;
396
 
397
      if (l == 0)
398
        {
399
          /* Watch out for 'A ' // x vs. 'A' // x.  */
400
          gfc_expr *e1_left = e1->value.op.op1;
401
          gfc_expr *e2_left = e2->value.op.op1;
402
 
403
          if (e1_left->expr_type == EXPR_CONSTANT
404
              && e2_left->expr_type == EXPR_CONSTANT
405
              && e1_left->value.character.length
406
                 != e2_left->value.character.length)
407
            return -2;
408
          else
409
            return r;
410
        }
411
      else
412
        {
413
          if (l != 0)
414
            return l;
415
          else
416
            return r;
417
        }
418
    }
419
 
420
  /* Compare X vs. X-C, for INTEGER only.  */
421
  if (e2->expr_type == EXPR_OP && e2->value.op.op == INTRINSIC_MINUS)
422
    {
423
      if (e2->value.op.op2->expr_type == EXPR_CONSTANT
424
          && e2->value.op.op2->ts.type == BT_INTEGER
425
          && gfc_dep_compare_expr (e1, e2->value.op.op1) == 0)
426
        return mpz_sgn (e2->value.op.op2->value.integer);
427
    }
428
 
429
  if (e1->expr_type != e2->expr_type)
430
    return -3;
431
 
432
  switch (e1->expr_type)
433
    {
434
    case EXPR_CONSTANT:
435
      /* Compare strings for equality.  */
436
      if (e1->ts.type == BT_CHARACTER && e2->ts.type == BT_CHARACTER)
437
        return gfc_compare_string (e1, e2);
438
 
439
      /* Compare REAL and COMPLEX constants.  Because of the
440
         traps and pitfalls associated with comparing
441
         a + 1.0 with a + 0.5, check for equality only.  */
442
      if (e2->expr_type == EXPR_CONSTANT)
443
        {
444
          if (e1->ts.type == BT_REAL && e2->ts.type == BT_REAL)
445
            {
446
              if (mpfr_cmp (e1->value.real, e2->value.real) == 0)
447
                return 0;
448
              else
449
                return -2;
450
            }
451
          else if (e1->ts.type == BT_COMPLEX && e2->ts.type == BT_COMPLEX)
452
            {
453
              if (mpc_cmp (e1->value.complex, e2->value.complex) == 0)
454
                return 0;
455
              else
456
                return -2;
457
            }
458
        }
459
 
460
      if (e1->ts.type != BT_INTEGER || e2->ts.type != BT_INTEGER)
461
        return -2;
462
 
463
      /* For INTEGER, all cases where e2 is not constant should have
464
         been filtered out above.  */
465
      gcc_assert (e2->expr_type == EXPR_CONSTANT);
466
 
467
      i = mpz_cmp (e1->value.integer, e2->value.integer);
468
      if (i == 0)
469
        return 0;
470
      else if (i < 0)
471
        return -1;
472
      return 1;
473
 
474
    case EXPR_VARIABLE:
475
      if (are_identical_variables (e1, e2))
476
        return 0;
477
      else
478
        return -3;
479
 
480
    case EXPR_OP:
481
      /* Intrinsic operators are the same if their operands are the same.  */
482
      if (e1->value.op.op != e2->value.op.op)
483
        return -2;
484
      if (e1->value.op.op2 == 0)
485
        {
486
          i = gfc_dep_compare_expr (e1->value.op.op1, e2->value.op.op1);
487
          return i == 0 ? 0 : -2;
488
        }
489
      if (gfc_dep_compare_expr (e1->value.op.op1, e2->value.op.op1) == 0
490
          && gfc_dep_compare_expr (e1->value.op.op2, e2->value.op.op2) == 0)
491
        return 0;
492
      else if (e1->value.op.op == INTRINSIC_TIMES
493
               && gfc_dep_compare_expr (e1->value.op.op1, e2->value.op.op2) == 0
494
               && gfc_dep_compare_expr (e1->value.op.op2, e2->value.op.op1) == 0)
495
        /* Commutativity of multiplication; addition is handled above.  */
496
        return 0;
497
 
498
      return -2;
499
 
500
    case EXPR_FUNCTION:
501
      return gfc_dep_compare_functions (e1, e2, false);
502
      break;
503
 
504
    default:
505
      return -2;
506
    }
507
}
508
 
509
 
510
/* Returns 1 if the two ranges are the same and 0 if they are not (or if the
511
   results are indeterminate). 'n' is the dimension to compare.  */
512
 
513
static int
514
is_same_range (gfc_array_ref *ar1, gfc_array_ref *ar2, int n)
515
{
516
  gfc_expr *e1;
517
  gfc_expr *e2;
518
  int i;
519
 
520
  /* TODO: More sophisticated range comparison.  */
521
  gcc_assert (ar1 && ar2);
522
 
523
  gcc_assert (ar1->dimen_type[n] == ar2->dimen_type[n]);
524
 
525
  e1 = ar1->stride[n];
526
  e2 = ar2->stride[n];
527
  /* Check for mismatching strides.  A NULL stride means a stride of 1.  */
528
  if (e1 && !e2)
529
    {
530
      i = gfc_expr_is_one (e1, -1);
531
      if (i == -1 || i == 0)
532
        return 0;
533
    }
534
  else if (e2 && !e1)
535
    {
536
      i = gfc_expr_is_one (e2, -1);
537
      if (i == -1 || i == 0)
538
        return 0;
539
    }
540
  else if (e1 && e2)
541
    {
542
      i = gfc_dep_compare_expr (e1, e2);
543
      if (i != 0)
544
        return 0;
545
    }
546
  /* The strides match.  */
547
 
548
  /* Check the range start.  */
549
  e1 = ar1->start[n];
550
  e2 = ar2->start[n];
551
  if (e1 || e2)
552
    {
553
      /* Use the bound of the array if no bound is specified.  */
554
      if (ar1->as && !e1)
555
        e1 = ar1->as->lower[n];
556
 
557
      if (ar2->as && !e2)
558
        e2 = ar2->as->lower[n];
559
 
560
      /* Check we have values for both.  */
561
      if (!(e1 && e2))
562
        return 0;
563
 
564
      i = gfc_dep_compare_expr (e1, e2);
565
      if (i != 0)
566
        return 0;
567
    }
568
 
569
  /* Check the range end.  */
570
  e1 = ar1->end[n];
571
  e2 = ar2->end[n];
572
  if (e1 || e2)
573
    {
574
      /* Use the bound of the array if no bound is specified.  */
575
      if (ar1->as && !e1)
576
        e1 = ar1->as->upper[n];
577
 
578
      if (ar2->as && !e2)
579
        e2 = ar2->as->upper[n];
580
 
581
      /* Check we have values for both.  */
582
      if (!(e1 && e2))
583
        return 0;
584
 
585
      i = gfc_dep_compare_expr (e1, e2);
586
      if (i != 0)
587
        return 0;
588
    }
589
 
590
  return 1;
591
}
592
 
593
 
594
/* Some array-returning intrinsics can be implemented by reusing the
595
   data from one of the array arguments.  For example, TRANSPOSE does
596
   not necessarily need to allocate new data: it can be implemented
597
   by copying the original array's descriptor and simply swapping the
598
   two dimension specifications.
599
 
600
   If EXPR is a call to such an intrinsic, return the argument
601
   whose data can be reused, otherwise return NULL.  */
602
 
603
gfc_expr *
604
gfc_get_noncopying_intrinsic_argument (gfc_expr *expr)
605
{
606
  if (expr->expr_type != EXPR_FUNCTION || !expr->value.function.isym)
607
    return NULL;
608
 
609
  switch (expr->value.function.isym->id)
610
    {
611
    case GFC_ISYM_TRANSPOSE:
612
      return expr->value.function.actual->expr;
613
 
614
    default:
615
      return NULL;
616
    }
617
}
618
 
619
 
620
/* Return true if the result of reference REF can only be constructed
621
   using a temporary array.  */
622
 
623
bool
624
gfc_ref_needs_temporary_p (gfc_ref *ref)
625
{
626
  int n;
627
  bool subarray_p;
628
 
629
  subarray_p = false;
630
  for (; ref; ref = ref->next)
631
    switch (ref->type)
632
      {
633
      case REF_ARRAY:
634
        /* Vector dimensions are generally not monotonic and must be
635
           handled using a temporary.  */
636
        if (ref->u.ar.type == AR_SECTION)
637
          for (n = 0; n < ref->u.ar.dimen; n++)
638
            if (ref->u.ar.dimen_type[n] == DIMEN_VECTOR)
639
              return true;
640
 
641
        subarray_p = true;
642
        break;
643
 
644
      case REF_SUBSTRING:
645
        /* Within an array reference, character substrings generally
646
           need a temporary.  Character array strides are expressed as
647
           multiples of the element size (consistent with other array
648
           types), not in characters.  */
649
        return subarray_p;
650
 
651
      case REF_COMPONENT:
652
        break;
653
      }
654
 
655
  return false;
656
}
657
 
658
 
659
static int
660
gfc_is_data_pointer (gfc_expr *e)
661
{
662
  gfc_ref *ref;
663
 
664
  if (e->expr_type != EXPR_VARIABLE && e->expr_type != EXPR_FUNCTION)
665
    return 0;
666
 
667
  /* No subreference if it is a function  */
668
  gcc_assert (e->expr_type == EXPR_VARIABLE || !e->ref);
669
 
670
  if (e->symtree->n.sym->attr.pointer)
671
    return 1;
672
 
673
  for (ref = e->ref; ref; ref = ref->next)
674
    if (ref->type == REF_COMPONENT && ref->u.c.component->attr.pointer)
675
      return 1;
676
 
677
  return 0;
678
}
679
 
680
 
681
/* Return true if array variable VAR could be passed to the same function
682
   as argument EXPR without interfering with EXPR.  INTENT is the intent
683
   of VAR.
684
 
685
   This is considerably less conservative than other dependencies
686
   because many function arguments will already be copied into a
687
   temporary.  */
688
 
689
static int
690
gfc_check_argument_var_dependency (gfc_expr *var, sym_intent intent,
691
                                   gfc_expr *expr, gfc_dep_check elemental)
692
{
693
  gfc_expr *arg;
694
 
695
  gcc_assert (var->expr_type == EXPR_VARIABLE);
696
  gcc_assert (var->rank > 0);
697
 
698
  switch (expr->expr_type)
699
    {
700
    case EXPR_VARIABLE:
701
      /* In case of elemental subroutines, there is no dependency
702
         between two same-range array references.  */
703
      if (gfc_ref_needs_temporary_p (expr->ref)
704
          || gfc_check_dependency (var, expr, elemental == NOT_ELEMENTAL))
705
        {
706
          if (elemental == ELEM_DONT_CHECK_VARIABLE)
707
            {
708
              /* Too many false positive with pointers.  */
709
              if (!gfc_is_data_pointer (var) && !gfc_is_data_pointer (expr))
710
                {
711
                  /* Elemental procedures forbid unspecified intents,
712
                     and we don't check dependencies for INTENT_IN args.  */
713
                  gcc_assert (intent == INTENT_OUT || intent == INTENT_INOUT);
714
 
715
                  /* We are told not to check dependencies.
716
                     We do it, however, and issue a warning in case we find one.
717
                     If a dependency is found in the case
718
                     elemental == ELEM_CHECK_VARIABLE, we will generate
719
                     a temporary, so we don't need to bother the user.  */
720
                  gfc_warning ("INTENT(%s) actual argument at %L might "
721
                               "interfere with actual argument at %L.",
722
                               intent == INTENT_OUT ? "OUT" : "INOUT",
723
                               &var->where, &expr->where);
724
                }
725
              return 0;
726
            }
727
          else
728
            return 1;
729
        }
730
      return 0;
731
 
732
    case EXPR_ARRAY:
733
      return gfc_check_dependency (var, expr, 1);
734
 
735
    case EXPR_FUNCTION:
736
      if (intent != INTENT_IN)
737
        {
738
          arg = gfc_get_noncopying_intrinsic_argument (expr);
739
          if (arg != NULL)
740
            return gfc_check_argument_var_dependency (var, intent, arg,
741
                                                      NOT_ELEMENTAL);
742
        }
743
 
744
      if (elemental != NOT_ELEMENTAL)
745
        {
746
          if ((expr->value.function.esym
747
               && expr->value.function.esym->attr.elemental)
748
              || (expr->value.function.isym
749
                  && expr->value.function.isym->elemental))
750
            return gfc_check_fncall_dependency (var, intent, NULL,
751
                                                expr->value.function.actual,
752
                                                ELEM_CHECK_VARIABLE);
753
 
754
          if (gfc_inline_intrinsic_function_p (expr))
755
            {
756
              /* The TRANSPOSE case should have been caught in the
757
                 noncopying intrinsic case above.  */
758
              gcc_assert (expr->value.function.isym->id != GFC_ISYM_TRANSPOSE);
759
 
760
              return gfc_check_fncall_dependency (var, intent, NULL,
761
                                                  expr->value.function.actual,
762
                                                  ELEM_CHECK_VARIABLE);
763
            }
764
        }
765
      return 0;
766
 
767
    case EXPR_OP:
768
      /* In case of non-elemental procedures, there is no need to catch
769
         dependencies, as we will make a temporary anyway.  */
770
      if (elemental)
771
        {
772
          /* If the actual arg EXPR is an expression, we need to catch
773
             a dependency between variables in EXPR and VAR,
774
             an intent((IN)OUT) variable.  */
775
          if (expr->value.op.op1
776
              && gfc_check_argument_var_dependency (var, intent,
777
                                                    expr->value.op.op1,
778
                                                    ELEM_CHECK_VARIABLE))
779
            return 1;
780
          else if (expr->value.op.op2
781
                   && gfc_check_argument_var_dependency (var, intent,
782
                                                         expr->value.op.op2,
783
                                                         ELEM_CHECK_VARIABLE))
784
            return 1;
785
        }
786
      return 0;
787
 
788
    default:
789
      return 0;
790
    }
791
}
792
 
793
 
794
/* Like gfc_check_argument_var_dependency, but extended to any
795
   array expression OTHER, not just variables.  */
796
 
797
static int
798
gfc_check_argument_dependency (gfc_expr *other, sym_intent intent,
799
                               gfc_expr *expr, gfc_dep_check elemental)
800
{
801
  switch (other->expr_type)
802
    {
803
    case EXPR_VARIABLE:
804
      return gfc_check_argument_var_dependency (other, intent, expr, elemental);
805
 
806
    case EXPR_FUNCTION:
807
      other = gfc_get_noncopying_intrinsic_argument (other);
808
      if (other != NULL)
809
        return gfc_check_argument_dependency (other, INTENT_IN, expr,
810
                                              NOT_ELEMENTAL);
811
 
812
      return 0;
813
 
814
    default:
815
      return 0;
816
    }
817
}
818
 
819
 
820
/* Like gfc_check_argument_dependency, but check all the arguments in ACTUAL.
821
   FNSYM is the function being called, or NULL if not known.  */
822
 
823
int
824
gfc_check_fncall_dependency (gfc_expr *other, sym_intent intent,
825
                             gfc_symbol *fnsym, gfc_actual_arglist *actual,
826
                             gfc_dep_check elemental)
827
{
828
  gfc_formal_arglist *formal;
829
  gfc_expr *expr;
830
 
831
  formal = fnsym ? fnsym->formal : NULL;
832
  for (; actual; actual = actual->next, formal = formal ? formal->next : NULL)
833
    {
834
      expr = actual->expr;
835
 
836
      /* Skip args which are not present.  */
837
      if (!expr)
838
        continue;
839
 
840
      /* Skip other itself.  */
841
      if (expr == other)
842
        continue;
843
 
844
      /* Skip intent(in) arguments if OTHER itself is intent(in).  */
845
      if (formal && intent == INTENT_IN
846
          && formal->sym->attr.intent == INTENT_IN)
847
        continue;
848
 
849
      if (gfc_check_argument_dependency (other, intent, expr, elemental))
850
        return 1;
851
    }
852
 
853
  return 0;
854
}
855
 
856
 
857
/* Return 1 if e1 and e2 are equivalenced arrays, either
858
   directly or indirectly; i.e., equivalence (a,b) for a and b
859
   or equivalence (a,c),(b,c).  This function uses the equiv_
860
   lists, generated in trans-common(add_equivalences), that are
861
   guaranteed to pick up indirect equivalences.  We explicitly
862
   check for overlap using the offset and length of the equivalence.
863
   This function is symmetric.
864
   TODO: This function only checks whether the full top-level
865
   symbols overlap.  An improved implementation could inspect
866
   e1->ref and e2->ref to determine whether the actually accessed
867
   portions of these variables/arrays potentially overlap.  */
868
 
869
int
870
gfc_are_equivalenced_arrays (gfc_expr *e1, gfc_expr *e2)
871
{
872
  gfc_equiv_list *l;
873
  gfc_equiv_info *s, *fl1, *fl2;
874
 
875
  gcc_assert (e1->expr_type == EXPR_VARIABLE
876
              && e2->expr_type == EXPR_VARIABLE);
877
 
878
  if (!e1->symtree->n.sym->attr.in_equivalence
879
      || !e2->symtree->n.sym->attr.in_equivalence|| !e1->rank || !e2->rank)
880
    return 0;
881
 
882
  if (e1->symtree->n.sym->ns
883
        && e1->symtree->n.sym->ns != gfc_current_ns)
884
    l = e1->symtree->n.sym->ns->equiv_lists;
885
  else
886
    l = gfc_current_ns->equiv_lists;
887
 
888
  /* Go through the equiv_lists and return 1 if the variables
889
     e1 and e2 are members of the same group and satisfy the
890
     requirement on their relative offsets.  */
891
  for (; l; l = l->next)
892
    {
893
      fl1 = NULL;
894
      fl2 = NULL;
895
      for (s = l->equiv; s; s = s->next)
896
        {
897
          if (s->sym == e1->symtree->n.sym)
898
            {
899
              fl1 = s;
900
              if (fl2)
901
                break;
902
            }
903
          if (s->sym == e2->symtree->n.sym)
904
            {
905
              fl2 = s;
906
              if (fl1)
907
                break;
908
            }
909
        }
910
 
911
      if (s)
912
        {
913
          /* Can these lengths be zero?  */
914
          if (fl1->length <= 0 || fl2->length <= 0)
915
            return 1;
916
          /* These can't overlap if [f11,fl1+length] is before
917
             [fl2,fl2+length], or [fl2,fl2+length] is before
918
             [fl1,fl1+length], otherwise they do overlap.  */
919
          if (fl1->offset + fl1->length > fl2->offset
920
              && fl2->offset + fl2->length > fl1->offset)
921
            return 1;
922
        }
923
    }
924
  return 0;
925
}
926
 
927
 
928
/* Return true if there is no possibility of aliasing because of a type
929
   mismatch between all the possible pointer references and the
930
   potential target.  Note that this function is asymmetric in the
931
   arguments and so must be called twice with the arguments exchanged.  */
932
 
933
static bool
934
check_data_pointer_types (gfc_expr *expr1, gfc_expr *expr2)
935
{
936
  gfc_component *cm1;
937
  gfc_symbol *sym1;
938
  gfc_symbol *sym2;
939
  gfc_ref *ref1;
940
  bool seen_component_ref;
941
 
942
  if (expr1->expr_type != EXPR_VARIABLE
943
        || expr1->expr_type != EXPR_VARIABLE)
944
    return false;
945
 
946
  sym1 = expr1->symtree->n.sym;
947
  sym2 = expr2->symtree->n.sym;
948
 
949
  /* Keep it simple for now.  */
950
  if (sym1->ts.type == BT_DERIVED && sym2->ts.type == BT_DERIVED)
951
    return false;
952
 
953
  if (sym1->attr.pointer)
954
    {
955
      if (gfc_compare_types (&sym1->ts, &sym2->ts))
956
        return false;
957
    }
958
 
959
  /* This is a conservative check on the components of the derived type
960
     if no component references have been seen.  Since we will not dig
961
     into the components of derived type components, we play it safe by
962
     returning false.  First we check the reference chain and then, if
963
     no component references have been seen, the components.  */
964
  seen_component_ref = false;
965
  if (sym1->ts.type == BT_DERIVED)
966
    {
967
      for (ref1 = expr1->ref; ref1; ref1 = ref1->next)
968
        {
969
          if (ref1->type != REF_COMPONENT)
970
            continue;
971
 
972
          if (ref1->u.c.component->ts.type == BT_DERIVED)
973
            return false;
974
 
975
          if ((sym2->attr.pointer || ref1->u.c.component->attr.pointer)
976
                && gfc_compare_types (&ref1->u.c.component->ts, &sym2->ts))
977
            return false;
978
 
979
          seen_component_ref = true;
980
        }
981
    }
982
 
983
  if (sym1->ts.type == BT_DERIVED && !seen_component_ref)
984
    {
985
      for (cm1 = sym1->ts.u.derived->components; cm1; cm1 = cm1->next)
986
        {
987
          if (cm1->ts.type == BT_DERIVED)
988
            return false;
989
 
990
          if ((sym2->attr.pointer || cm1->attr.pointer)
991
                && gfc_compare_types (&cm1->ts, &sym2->ts))
992
            return false;
993
        }
994
    }
995
 
996
  return true;
997
}
998
 
999
 
1000
/* Return true if the statement body redefines the condition.  Returns
1001
   true if expr2 depends on expr1.  expr1 should be a single term
1002
   suitable for the lhs of an assignment.  The IDENTICAL flag indicates
1003
   whether array references to the same symbol with identical range
1004
   references count as a dependency or not.  Used for forall and where
1005
   statements.  Also used with functions returning arrays without a
1006
   temporary.  */
1007
 
1008
int
1009
gfc_check_dependency (gfc_expr *expr1, gfc_expr *expr2, bool identical)
1010
{
1011
  gfc_actual_arglist *actual;
1012
  gfc_constructor *c;
1013
  int n;
1014
 
1015
  gcc_assert (expr1->expr_type == EXPR_VARIABLE);
1016
 
1017
  switch (expr2->expr_type)
1018
    {
1019
    case EXPR_OP:
1020
      n = gfc_check_dependency (expr1, expr2->value.op.op1, identical);
1021
      if (n)
1022
        return n;
1023
      if (expr2->value.op.op2)
1024
        return gfc_check_dependency (expr1, expr2->value.op.op2, identical);
1025
      return 0;
1026
 
1027
    case EXPR_VARIABLE:
1028
      /* The interesting cases are when the symbols don't match.  */
1029
      if (expr1->symtree->n.sym != expr2->symtree->n.sym)
1030
        {
1031
          gfc_typespec *ts1 = &expr1->symtree->n.sym->ts;
1032
          gfc_typespec *ts2 = &expr2->symtree->n.sym->ts;
1033
 
1034
          /* Return 1 if expr1 and expr2 are equivalenced arrays.  */
1035
          if (gfc_are_equivalenced_arrays (expr1, expr2))
1036
            return 1;
1037
 
1038
          /* Symbols can only alias if they have the same type.  */
1039
          if (ts1->type != BT_UNKNOWN && ts2->type != BT_UNKNOWN
1040
              && ts1->type != BT_DERIVED && ts2->type != BT_DERIVED)
1041
            {
1042
              if (ts1->type != ts2->type || ts1->kind != ts2->kind)
1043
                return 0;
1044
            }
1045
 
1046
          /* If either variable is a pointer, assume the worst.  */
1047
          /* TODO: -fassume-no-pointer-aliasing */
1048
          if (gfc_is_data_pointer (expr1) || gfc_is_data_pointer (expr2))
1049
            {
1050
              if (check_data_pointer_types (expr1, expr2)
1051
                    && check_data_pointer_types (expr2, expr1))
1052
                return 0;
1053
 
1054
              return 1;
1055
            }
1056
          else
1057
            {
1058
              gfc_symbol *sym1 = expr1->symtree->n.sym;
1059
              gfc_symbol *sym2 = expr2->symtree->n.sym;
1060
              if (sym1->attr.target && sym2->attr.target
1061
                  && ((sym1->attr.dummy && !sym1->attr.contiguous
1062
                       && (!sym1->attr.dimension
1063
                           || sym2->as->type == AS_ASSUMED_SHAPE))
1064
                      || (sym2->attr.dummy && !sym2->attr.contiguous
1065
                          && (!sym2->attr.dimension
1066
                              || sym2->as->type == AS_ASSUMED_SHAPE))))
1067
                return 1;
1068
            }
1069
 
1070
          /* Otherwise distinct symbols have no dependencies.  */
1071
          return 0;
1072
        }
1073
 
1074
      if (identical)
1075
        return 1;
1076
 
1077
      /* Identical and disjoint ranges return 0,
1078
         overlapping ranges return 1.  */
1079
      if (expr1->ref && expr2->ref)
1080
        return gfc_dep_resolver (expr1->ref, expr2->ref, NULL);
1081
 
1082
      return 1;
1083
 
1084
    case EXPR_FUNCTION:
1085
      if (gfc_get_noncopying_intrinsic_argument (expr2) != NULL)
1086
        identical = 1;
1087
 
1088
      /* Remember possible differences between elemental and
1089
         transformational functions.  All functions inside a FORALL
1090
         will be pure.  */
1091
      for (actual = expr2->value.function.actual;
1092
           actual; actual = actual->next)
1093
        {
1094
          if (!actual->expr)
1095
            continue;
1096
          n = gfc_check_dependency (expr1, actual->expr, identical);
1097
          if (n)
1098
            return n;
1099
        }
1100
      return 0;
1101
 
1102
    case EXPR_CONSTANT:
1103
    case EXPR_NULL:
1104
      return 0;
1105
 
1106
    case EXPR_ARRAY:
1107
      /* Loop through the array constructor's elements.  */
1108
      for (c = gfc_constructor_first (expr2->value.constructor);
1109
           c; c = gfc_constructor_next (c))
1110
        {
1111
          /* If this is an iterator, assume the worst.  */
1112
          if (c->iterator)
1113
            return 1;
1114
          /* Avoid recursion in the common case.  */
1115
          if (c->expr->expr_type == EXPR_CONSTANT)
1116
            continue;
1117
          if (gfc_check_dependency (expr1, c->expr, 1))
1118
            return 1;
1119
        }
1120
      return 0;
1121
 
1122
    default:
1123
      return 1;
1124
    }
1125
}
1126
 
1127
 
1128
/* Determines overlapping for two array sections.  */
1129
 
1130
static gfc_dependency
1131
check_section_vs_section (gfc_array_ref *l_ar, gfc_array_ref *r_ar, int n)
1132
{
1133
  gfc_expr *l_start;
1134
  gfc_expr *l_end;
1135
  gfc_expr *l_stride;
1136
  gfc_expr *l_lower;
1137
  gfc_expr *l_upper;
1138
  int l_dir;
1139
 
1140
  gfc_expr *r_start;
1141
  gfc_expr *r_end;
1142
  gfc_expr *r_stride;
1143
  gfc_expr *r_lower;
1144
  gfc_expr *r_upper;
1145
  gfc_expr *one_expr;
1146
  int r_dir;
1147
  int stride_comparison;
1148
  int start_comparison;
1149
 
1150
  /* If they are the same range, return without more ado.  */
1151
  if (is_same_range (l_ar, r_ar, n))
1152
    return GFC_DEP_EQUAL;
1153
 
1154
  l_start = l_ar->start[n];
1155
  l_end = l_ar->end[n];
1156
  l_stride = l_ar->stride[n];
1157
 
1158
  r_start = r_ar->start[n];
1159
  r_end = r_ar->end[n];
1160
  r_stride = r_ar->stride[n];
1161
 
1162
  /* If l_start is NULL take it from array specifier.  */
1163
  if (NULL == l_start && IS_ARRAY_EXPLICIT (l_ar->as))
1164
    l_start = l_ar->as->lower[n];
1165
  /* If l_end is NULL take it from array specifier.  */
1166
  if (NULL == l_end && IS_ARRAY_EXPLICIT (l_ar->as))
1167
    l_end = l_ar->as->upper[n];
1168
 
1169
  /* If r_start is NULL take it from array specifier.  */
1170
  if (NULL == r_start && IS_ARRAY_EXPLICIT (r_ar->as))
1171
    r_start = r_ar->as->lower[n];
1172
  /* If r_end is NULL take it from array specifier.  */
1173
  if (NULL == r_end && IS_ARRAY_EXPLICIT (r_ar->as))
1174
    r_end = r_ar->as->upper[n];
1175
 
1176
  /* Determine whether the l_stride is positive or negative.  */
1177
  if (!l_stride)
1178
    l_dir = 1;
1179
  else if (l_stride->expr_type == EXPR_CONSTANT
1180
           && l_stride->ts.type == BT_INTEGER)
1181
    l_dir = mpz_sgn (l_stride->value.integer);
1182
  else if (l_start && l_end)
1183
    l_dir = gfc_dep_compare_expr (l_end, l_start);
1184
  else
1185
    l_dir = -2;
1186
 
1187
  /* Determine whether the r_stride is positive or negative.  */
1188
  if (!r_stride)
1189
    r_dir = 1;
1190
  else if (r_stride->expr_type == EXPR_CONSTANT
1191
           && r_stride->ts.type == BT_INTEGER)
1192
    r_dir = mpz_sgn (r_stride->value.integer);
1193
  else if (r_start && r_end)
1194
    r_dir = gfc_dep_compare_expr (r_end, r_start);
1195
  else
1196
    r_dir = -2;
1197
 
1198
  /* The strides should never be zero.  */
1199
  if (l_dir == 0 || r_dir == 0)
1200
    return GFC_DEP_OVERLAP;
1201
 
1202
  /* Determine the relationship between the strides.  Set stride_comparison to
1203
     -2 if the dependency cannot be determined
1204
     -1 if l_stride < r_stride
1205
 
1206
      1 if l_stride > r_stride
1207
     as determined by gfc_dep_compare_expr.  */
1208
 
1209
  one_expr = gfc_get_int_expr (gfc_index_integer_kind, NULL, 1);
1210
 
1211
  stride_comparison = gfc_dep_compare_expr (l_stride ? l_stride : one_expr,
1212
                                            r_stride ? r_stride : one_expr);
1213
 
1214
  if (l_start && r_start)
1215
    start_comparison = gfc_dep_compare_expr (l_start, r_start);
1216
  else
1217
    start_comparison = -2;
1218
 
1219
  free (one_expr);
1220
 
1221
  /* Determine LHS upper and lower bounds.  */
1222
  if (l_dir == 1)
1223
    {
1224
      l_lower = l_start;
1225
      l_upper = l_end;
1226
    }
1227
  else if (l_dir == -1)
1228
    {
1229
      l_lower = l_end;
1230
      l_upper = l_start;
1231
    }
1232
  else
1233
    {
1234
      l_lower = NULL;
1235
      l_upper = NULL;
1236
    }
1237
 
1238
  /* Determine RHS upper and lower bounds.  */
1239
  if (r_dir == 1)
1240
    {
1241
      r_lower = r_start;
1242
      r_upper = r_end;
1243
    }
1244
  else if (r_dir == -1)
1245
    {
1246
      r_lower = r_end;
1247
      r_upper = r_start;
1248
    }
1249
  else
1250
    {
1251
      r_lower = NULL;
1252
      r_upper = NULL;
1253
    }
1254
 
1255
  /* Check whether the ranges are disjoint.  */
1256
  if (l_upper && r_lower && gfc_dep_compare_expr (l_upper, r_lower) == -1)
1257
    return GFC_DEP_NODEP;
1258
  if (r_upper && l_lower && gfc_dep_compare_expr (r_upper, l_lower) == -1)
1259
    return GFC_DEP_NODEP;
1260
 
1261
  /* Handle cases like x:y:1 vs. x:z:-1 as GFC_DEP_EQUAL.  */
1262
  if (l_start && r_start && gfc_dep_compare_expr (l_start, r_start) == 0)
1263
    {
1264
      if (l_dir == 1 && r_dir == -1)
1265
        return GFC_DEP_EQUAL;
1266
      if (l_dir == -1 && r_dir == 1)
1267
        return GFC_DEP_EQUAL;
1268
    }
1269
 
1270
  /* Handle cases like x:y:1 vs. z:y:-1 as GFC_DEP_EQUAL.  */
1271
  if (l_end && r_end && gfc_dep_compare_expr (l_end, r_end) == 0)
1272
    {
1273
      if (l_dir == 1 && r_dir == -1)
1274
        return GFC_DEP_EQUAL;
1275
      if (l_dir == -1 && r_dir == 1)
1276
        return GFC_DEP_EQUAL;
1277
    }
1278
 
1279
  /* Handle cases like x:y:2 vs. x+1:z:4 as GFC_DEP_NODEP.
1280
     There is no dependency if the remainder of
1281
     (l_start - r_start) / gcd(l_stride, r_stride) is
1282
     nonzero.
1283
     TODO:
1284
       - Handle cases where x is an expression.
1285
       - Cases like a(1:4:2) = a(2:3) are still not handled.
1286
  */
1287
 
1288
#define IS_CONSTANT_INTEGER(a) ((a) && ((a)->expr_type == EXPR_CONSTANT) \
1289
                              && (a)->ts.type == BT_INTEGER)
1290
 
1291
  if (IS_CONSTANT_INTEGER(l_start) && IS_CONSTANT_INTEGER(r_start)
1292
      && IS_CONSTANT_INTEGER(l_stride) && IS_CONSTANT_INTEGER(r_stride))
1293
    {
1294
      mpz_t gcd, tmp;
1295
      int result;
1296
 
1297
      mpz_init (gcd);
1298
      mpz_init (tmp);
1299
 
1300
      mpz_gcd (gcd, l_stride->value.integer, r_stride->value.integer);
1301
      mpz_sub (tmp, l_start->value.integer, r_start->value.integer);
1302
 
1303
      mpz_fdiv_r (tmp, tmp, gcd);
1304
      result = mpz_cmp_si (tmp, 0L);
1305
 
1306
      mpz_clear (gcd);
1307
      mpz_clear (tmp);
1308
 
1309
      if (result != 0)
1310
        return GFC_DEP_NODEP;
1311
    }
1312
 
1313
#undef IS_CONSTANT_INTEGER
1314
 
1315
  /* Check for forward dependencies x:y vs. x+1:z and x:y:z vs. x:y:z+1. */
1316
 
1317
  if (l_dir == 1 && r_dir == 1 &&
1318
      (start_comparison == 0 || start_comparison == -1)
1319
      && (stride_comparison == 0 || stride_comparison == -1))
1320
          return GFC_DEP_FORWARD;
1321
 
1322
  /* Check for forward dependencies x:y:-1 vs. x-1:z:-1 and
1323
     x:y:-1 vs. x:y:-2.  */
1324
  if (l_dir == -1 && r_dir == -1 &&
1325
      (start_comparison == 0 || start_comparison == 1)
1326
      && (stride_comparison == 0 || stride_comparison == 1))
1327
    return GFC_DEP_FORWARD;
1328
 
1329
  if (stride_comparison == 0 || stride_comparison == -1)
1330
    {
1331
      if (l_start && IS_ARRAY_EXPLICIT (l_ar->as))
1332
        {
1333
 
1334
          /* Check for a(low:y:s) vs. a(z:x:s) or
1335
             a(low:y:s) vs. a(z:x:s+1) where a has a lower bound
1336
             of low, which is always at least a forward dependence.  */
1337
 
1338
          if (r_dir == 1
1339
              && gfc_dep_compare_expr (l_start, l_ar->as->lower[n]) == 0)
1340
            return GFC_DEP_FORWARD;
1341
        }
1342
    }
1343
 
1344
  if (stride_comparison == 0 || stride_comparison == 1)
1345
    {
1346
      if (l_start && IS_ARRAY_EXPLICIT (l_ar->as))
1347
        {
1348
 
1349
          /* Check for a(high:y:-s) vs. a(z:x:-s) or
1350
             a(high:y:-s vs. a(z:x:-s-1) where a has a higher bound
1351
             of high, which is always at least a forward dependence.  */
1352
 
1353
          if (r_dir == -1
1354
              && gfc_dep_compare_expr (l_start, l_ar->as->upper[n]) == 0)
1355
            return GFC_DEP_FORWARD;
1356
        }
1357
    }
1358
 
1359
 
1360
  if (stride_comparison == 0)
1361
    {
1362
      /* From here, check for backwards dependencies.  */
1363
      /* x+1:y vs. x:z.  */
1364
      if (l_dir == 1 && r_dir == 1  && start_comparison == 1)
1365
        return GFC_DEP_BACKWARD;
1366
 
1367
      /* x-1:y:-1 vs. x:z:-1.  */
1368
      if (l_dir == -1 && r_dir == -1 && start_comparison == -1)
1369
        return GFC_DEP_BACKWARD;
1370
    }
1371
 
1372
  return GFC_DEP_OVERLAP;
1373
}
1374
 
1375
 
1376
/* Determines overlapping for a single element and a section.  */
1377
 
1378
static gfc_dependency
1379
gfc_check_element_vs_section( gfc_ref *lref, gfc_ref *rref, int n)
1380
{
1381
  gfc_array_ref *ref;
1382
  gfc_expr *elem;
1383
  gfc_expr *start;
1384
  gfc_expr *end;
1385
  gfc_expr *stride;
1386
  int s;
1387
 
1388
  elem = lref->u.ar.start[n];
1389
  if (!elem)
1390
    return GFC_DEP_OVERLAP;
1391
 
1392
  ref = &rref->u.ar;
1393
  start = ref->start[n] ;
1394
  end = ref->end[n] ;
1395
  stride = ref->stride[n];
1396
 
1397
  if (!start && IS_ARRAY_EXPLICIT (ref->as))
1398
    start = ref->as->lower[n];
1399
  if (!end && IS_ARRAY_EXPLICIT (ref->as))
1400
    end = ref->as->upper[n];
1401
 
1402
  /* Determine whether the stride is positive or negative.  */
1403
  if (!stride)
1404
    s = 1;
1405
  else if (stride->expr_type == EXPR_CONSTANT
1406
           && stride->ts.type == BT_INTEGER)
1407
    s = mpz_sgn (stride->value.integer);
1408
  else
1409
    s = -2;
1410
 
1411
  /* Stride should never be zero.  */
1412
  if (s == 0)
1413
    return GFC_DEP_OVERLAP;
1414
 
1415
  /* Positive strides.  */
1416
  if (s == 1)
1417
    {
1418
      /* Check for elem < lower.  */
1419
      if (start && gfc_dep_compare_expr (elem, start) == -1)
1420
        return GFC_DEP_NODEP;
1421
      /* Check for elem > upper.  */
1422
      if (end && gfc_dep_compare_expr (elem, end) == 1)
1423
        return GFC_DEP_NODEP;
1424
 
1425
      if (start && end)
1426
        {
1427
          s = gfc_dep_compare_expr (start, end);
1428
          /* Check for an empty range.  */
1429
          if (s == 1)
1430
            return GFC_DEP_NODEP;
1431
          if (s == 0 && gfc_dep_compare_expr (elem, start) == 0)
1432
            return GFC_DEP_EQUAL;
1433
        }
1434
    }
1435
  /* Negative strides.  */
1436
  else if (s == -1)
1437
    {
1438
      /* Check for elem > upper.  */
1439
      if (end && gfc_dep_compare_expr (elem, start) == 1)
1440
        return GFC_DEP_NODEP;
1441
      /* Check for elem < lower.  */
1442
      if (start && gfc_dep_compare_expr (elem, end) == -1)
1443
        return GFC_DEP_NODEP;
1444
 
1445
      if (start && end)
1446
        {
1447
          s = gfc_dep_compare_expr (start, end);
1448
          /* Check for an empty range.  */
1449
          if (s == -1)
1450
            return GFC_DEP_NODEP;
1451
          if (s == 0 && gfc_dep_compare_expr (elem, start) == 0)
1452
            return GFC_DEP_EQUAL;
1453
        }
1454
    }
1455
  /* Unknown strides.  */
1456
  else
1457
    {
1458
      if (!start || !end)
1459
        return GFC_DEP_OVERLAP;
1460
      s = gfc_dep_compare_expr (start, end);
1461
      if (s <= -2)
1462
        return GFC_DEP_OVERLAP;
1463
      /* Assume positive stride.  */
1464
      if (s == -1)
1465
        {
1466
          /* Check for elem < lower.  */
1467
          if (gfc_dep_compare_expr (elem, start) == -1)
1468
            return GFC_DEP_NODEP;
1469
          /* Check for elem > upper.  */
1470
          if (gfc_dep_compare_expr (elem, end) == 1)
1471
            return GFC_DEP_NODEP;
1472
        }
1473
      /* Assume negative stride.  */
1474
      else if (s == 1)
1475
        {
1476
          /* Check for elem > upper.  */
1477
          if (gfc_dep_compare_expr (elem, start) == 1)
1478
            return GFC_DEP_NODEP;
1479
          /* Check for elem < lower.  */
1480
          if (gfc_dep_compare_expr (elem, end) == -1)
1481
            return GFC_DEP_NODEP;
1482
        }
1483
      /* Equal bounds.  */
1484
      else if (s == 0)
1485
        {
1486
          s = gfc_dep_compare_expr (elem, start);
1487
          if (s == 0)
1488
            return GFC_DEP_EQUAL;
1489
          if (s == 1 || s == -1)
1490
            return GFC_DEP_NODEP;
1491
        }
1492
    }
1493
 
1494
  return GFC_DEP_OVERLAP;
1495
}
1496
 
1497
 
1498
/* Traverse expr, checking all EXPR_VARIABLE symbols for their
1499
   forall_index attribute.  Return true if any variable may be
1500
   being used as a FORALL index.  Its safe to pessimistically
1501
   return true, and assume a dependency.  */
1502
 
1503
static bool
1504
contains_forall_index_p (gfc_expr *expr)
1505
{
1506
  gfc_actual_arglist *arg;
1507
  gfc_constructor *c;
1508
  gfc_ref *ref;
1509
  int i;
1510
 
1511
  if (!expr)
1512
    return false;
1513
 
1514
  switch (expr->expr_type)
1515
    {
1516
    case EXPR_VARIABLE:
1517
      if (expr->symtree->n.sym->forall_index)
1518
        return true;
1519
      break;
1520
 
1521
    case EXPR_OP:
1522
      if (contains_forall_index_p (expr->value.op.op1)
1523
          || contains_forall_index_p (expr->value.op.op2))
1524
        return true;
1525
      break;
1526
 
1527
    case EXPR_FUNCTION:
1528
      for (arg = expr->value.function.actual; arg; arg = arg->next)
1529
        if (contains_forall_index_p (arg->expr))
1530
          return true;
1531
      break;
1532
 
1533
    case EXPR_CONSTANT:
1534
    case EXPR_NULL:
1535
    case EXPR_SUBSTRING:
1536
      break;
1537
 
1538
    case EXPR_STRUCTURE:
1539
    case EXPR_ARRAY:
1540
      for (c = gfc_constructor_first (expr->value.constructor);
1541
           c; gfc_constructor_next (c))
1542
        if (contains_forall_index_p (c->expr))
1543
          return true;
1544
      break;
1545
 
1546
    default:
1547
      gcc_unreachable ();
1548
    }
1549
 
1550
  for (ref = expr->ref; ref; ref = ref->next)
1551
    switch (ref->type)
1552
      {
1553
      case REF_ARRAY:
1554
        for (i = 0; i < ref->u.ar.dimen; i++)
1555
          if (contains_forall_index_p (ref->u.ar.start[i])
1556
              || contains_forall_index_p (ref->u.ar.end[i])
1557
              || contains_forall_index_p (ref->u.ar.stride[i]))
1558
            return true;
1559
        break;
1560
 
1561
      case REF_COMPONENT:
1562
        break;
1563
 
1564
      case REF_SUBSTRING:
1565
        if (contains_forall_index_p (ref->u.ss.start)
1566
            || contains_forall_index_p (ref->u.ss.end))
1567
          return true;
1568
        break;
1569
 
1570
      default:
1571
        gcc_unreachable ();
1572
      }
1573
 
1574
  return false;
1575
}
1576
 
1577
/* Determines overlapping for two single element array references.  */
1578
 
1579
static gfc_dependency
1580
gfc_check_element_vs_element (gfc_ref *lref, gfc_ref *rref, int n)
1581
{
1582
  gfc_array_ref l_ar;
1583
  gfc_array_ref r_ar;
1584
  gfc_expr *l_start;
1585
  gfc_expr *r_start;
1586
  int i;
1587
 
1588
  l_ar = lref->u.ar;
1589
  r_ar = rref->u.ar;
1590
  l_start = l_ar.start[n] ;
1591
  r_start = r_ar.start[n] ;
1592
  i = gfc_dep_compare_expr (r_start, l_start);
1593
  if (i == 0)
1594
    return GFC_DEP_EQUAL;
1595
 
1596
  /* Treat two scalar variables as potentially equal.  This allows
1597
     us to prove that a(i,:) and a(j,:) have no dependency.  See
1598
     Gerald Roth, "Evaluation of Array Syntax Dependence Analysis",
1599
     Proceedings of the International Conference on Parallel and
1600
     Distributed Processing Techniques and Applications (PDPTA2001),
1601
     Las Vegas, Nevada, June 2001.  */
1602
  /* However, we need to be careful when either scalar expression
1603
     contains a FORALL index, as these can potentially change value
1604
     during the scalarization/traversal of this array reference.  */
1605
  if (contains_forall_index_p (r_start) || contains_forall_index_p (l_start))
1606
    return GFC_DEP_OVERLAP;
1607
 
1608
  if (i > -2)
1609
    return GFC_DEP_NODEP;
1610
  return GFC_DEP_EQUAL;
1611
}
1612
 
1613
 
1614
/* Determine if an array ref, usually an array section specifies the
1615
   entire array.  In addition, if the second, pointer argument is
1616
   provided, the function will return true if the reference is
1617
   contiguous; eg. (:, 1) gives true but (1,:) gives false.  */
1618
 
1619
bool
1620
gfc_full_array_ref_p (gfc_ref *ref, bool *contiguous)
1621
{
1622
  int i;
1623
  int n;
1624
  bool lbound_OK = true;
1625
  bool ubound_OK = true;
1626
 
1627
  if (contiguous)
1628
    *contiguous = false;
1629
 
1630
  if (ref->type != REF_ARRAY)
1631
    return false;
1632
 
1633
  if (ref->u.ar.type == AR_FULL)
1634
    {
1635
      if (contiguous)
1636
        *contiguous = true;
1637
      return true;
1638
    }
1639
 
1640
  if (ref->u.ar.type != AR_SECTION)
1641
    return false;
1642
  if (ref->next)
1643
    return false;
1644
 
1645
  for (i = 0; i < ref->u.ar.dimen; i++)
1646
    {
1647
      /* If we have a single element in the reference, for the reference
1648
         to be full, we need to ascertain that the array has a single
1649
         element in this dimension and that we actually reference the
1650
         correct element.  */
1651
      if (ref->u.ar.dimen_type[i] == DIMEN_ELEMENT)
1652
        {
1653
          /* This is unconditionally a contiguous reference if all the
1654
             remaining dimensions are elements.  */
1655
          if (contiguous)
1656
            {
1657
              *contiguous = true;
1658
              for (n = i + 1; n < ref->u.ar.dimen; n++)
1659
                if (ref->u.ar.dimen_type[n] != DIMEN_ELEMENT)
1660
                  *contiguous = false;
1661
            }
1662
 
1663
          if (!ref->u.ar.as
1664
              || !ref->u.ar.as->lower[i]
1665
              || !ref->u.ar.as->upper[i]
1666
              || gfc_dep_compare_expr (ref->u.ar.as->lower[i],
1667
                                       ref->u.ar.as->upper[i])
1668
              || !ref->u.ar.start[i]
1669
              || gfc_dep_compare_expr (ref->u.ar.start[i],
1670
                                       ref->u.ar.as->lower[i]))
1671
            return false;
1672
          else
1673
            continue;
1674
        }
1675
 
1676
      /* Check the lower bound.  */
1677
      if (ref->u.ar.start[i]
1678
          && (!ref->u.ar.as
1679
              || !ref->u.ar.as->lower[i]
1680
              || gfc_dep_compare_expr (ref->u.ar.start[i],
1681
                                       ref->u.ar.as->lower[i])))
1682
        lbound_OK = false;
1683
      /* Check the upper bound.  */
1684
      if (ref->u.ar.end[i]
1685
          && (!ref->u.ar.as
1686
              || !ref->u.ar.as->upper[i]
1687
              || gfc_dep_compare_expr (ref->u.ar.end[i],
1688
                                       ref->u.ar.as->upper[i])))
1689
        ubound_OK = false;
1690
      /* Check the stride.  */
1691
      if (ref->u.ar.stride[i]
1692
            && !gfc_expr_is_one (ref->u.ar.stride[i], 0))
1693
        return false;
1694
 
1695
      /* This is unconditionally a contiguous reference as long as all
1696
         the subsequent dimensions are elements.  */
1697
      if (contiguous)
1698
        {
1699
          *contiguous = true;
1700
          for (n = i + 1; n < ref->u.ar.dimen; n++)
1701
            if (ref->u.ar.dimen_type[n] != DIMEN_ELEMENT)
1702
              *contiguous = false;
1703
        }
1704
 
1705
      if (!lbound_OK || !ubound_OK)
1706
        return false;
1707
    }
1708
  return true;
1709
}
1710
 
1711
 
1712
/* Determine if a full array is the same as an array section with one
1713
   variable limit.  For this to be so, the strides must both be unity
1714
   and one of either start == lower or end == upper must be true.  */
1715
 
1716
static bool
1717
ref_same_as_full_array (gfc_ref *full_ref, gfc_ref *ref)
1718
{
1719
  int i;
1720
  bool upper_or_lower;
1721
 
1722
  if (full_ref->type != REF_ARRAY)
1723
    return false;
1724
  if (full_ref->u.ar.type != AR_FULL)
1725
    return false;
1726
  if (ref->type != REF_ARRAY)
1727
    return false;
1728
  if (ref->u.ar.type != AR_SECTION)
1729
    return false;
1730
 
1731
  for (i = 0; i < ref->u.ar.dimen; i++)
1732
    {
1733
      /* If we have a single element in the reference, we need to check
1734
         that the array has a single element and that we actually reference
1735
         the correct element.  */
1736
      if (ref->u.ar.dimen_type[i] == DIMEN_ELEMENT)
1737
        {
1738
          if (!full_ref->u.ar.as
1739
              || !full_ref->u.ar.as->lower[i]
1740
              || !full_ref->u.ar.as->upper[i]
1741
              || gfc_dep_compare_expr (full_ref->u.ar.as->lower[i],
1742
                                       full_ref->u.ar.as->upper[i])
1743
              || !ref->u.ar.start[i]
1744
              || gfc_dep_compare_expr (ref->u.ar.start[i],
1745
                                       full_ref->u.ar.as->lower[i]))
1746
            return false;
1747
        }
1748
 
1749
      /* Check the strides.  */
1750
      if (full_ref->u.ar.stride[i] && !gfc_expr_is_one (full_ref->u.ar.stride[i], 0))
1751
        return false;
1752
      if (ref->u.ar.stride[i] && !gfc_expr_is_one (ref->u.ar.stride[i], 0))
1753
        return false;
1754
 
1755
      upper_or_lower = false;
1756
      /* Check the lower bound.  */
1757
      if (ref->u.ar.start[i]
1758
          && (ref->u.ar.as
1759
                && full_ref->u.ar.as->lower[i]
1760
                && gfc_dep_compare_expr (ref->u.ar.start[i],
1761
                                         full_ref->u.ar.as->lower[i]) == 0))
1762
        upper_or_lower =  true;
1763
      /* Check the upper bound.  */
1764
      if (ref->u.ar.end[i]
1765
          && (ref->u.ar.as
1766
                && full_ref->u.ar.as->upper[i]
1767
                && gfc_dep_compare_expr (ref->u.ar.end[i],
1768
                                         full_ref->u.ar.as->upper[i]) == 0))
1769
        upper_or_lower =  true;
1770
      if (!upper_or_lower)
1771
        return false;
1772
    }
1773
  return true;
1774
}
1775
 
1776
 
1777
/* Finds if two array references are overlapping or not.
1778
   Return value
1779
        2 : array references are overlapping but reversal of one or
1780
            more dimensions will clear the dependency.
1781
        1 : array references are overlapping.
1782
 
1783
 
1784
int
1785
gfc_dep_resolver (gfc_ref *lref, gfc_ref *rref, gfc_reverse *reverse)
1786
{
1787
  int n;
1788
  gfc_dependency fin_dep;
1789
  gfc_dependency this_dep;
1790
 
1791
  this_dep = GFC_DEP_ERROR;
1792
  fin_dep = GFC_DEP_ERROR;
1793
  /* Dependencies due to pointers should already have been identified.
1794
     We only need to check for overlapping array references.  */
1795
 
1796
  while (lref && rref)
1797
    {
1798
      /* We're resolving from the same base symbol, so both refs should be
1799
         the same type.  We traverse the reference chain until we find ranges
1800
         that are not equal.  */
1801
      gcc_assert (lref->type == rref->type);
1802
      switch (lref->type)
1803
        {
1804
        case REF_COMPONENT:
1805
          /* The two ranges can't overlap if they are from different
1806
             components.  */
1807
          if (lref->u.c.component != rref->u.c.component)
1808
            return 0;
1809
          break;
1810
 
1811
        case REF_SUBSTRING:
1812
          /* Substring overlaps are handled by the string assignment code
1813
             if there is not an underlying dependency.  */
1814
          return (fin_dep == GFC_DEP_OVERLAP) ? 1 : 0;
1815
 
1816
        case REF_ARRAY:
1817
 
1818
          if (ref_same_as_full_array (lref, rref))
1819
            return 0;
1820
 
1821
          if (ref_same_as_full_array (rref, lref))
1822
            return 0;
1823
 
1824
          if (lref->u.ar.dimen != rref->u.ar.dimen)
1825
            {
1826
              if (lref->u.ar.type == AR_FULL)
1827
                fin_dep = gfc_full_array_ref_p (rref, NULL) ? GFC_DEP_EQUAL
1828
                                                            : GFC_DEP_OVERLAP;
1829
              else if (rref->u.ar.type == AR_FULL)
1830
                fin_dep = gfc_full_array_ref_p (lref, NULL) ? GFC_DEP_EQUAL
1831
                                                            : GFC_DEP_OVERLAP;
1832
              else
1833
                return 1;
1834
              break;
1835
            }
1836
 
1837
          for (n=0; n < lref->u.ar.dimen; n++)
1838
            {
1839
              /* Assume dependency when either of array reference is vector
1840
                 subscript.  */
1841
              if (lref->u.ar.dimen_type[n] == DIMEN_VECTOR
1842
                  || rref->u.ar.dimen_type[n] == DIMEN_VECTOR)
1843
                return 1;
1844
 
1845
              if (lref->u.ar.dimen_type[n] == DIMEN_RANGE
1846
                  && rref->u.ar.dimen_type[n] == DIMEN_RANGE)
1847
                this_dep = check_section_vs_section (&lref->u.ar, &rref->u.ar, n);
1848
              else if (lref->u.ar.dimen_type[n] == DIMEN_ELEMENT
1849
                       && rref->u.ar.dimen_type[n] == DIMEN_RANGE)
1850
                this_dep = gfc_check_element_vs_section (lref, rref, n);
1851
              else if (rref->u.ar.dimen_type[n] == DIMEN_ELEMENT
1852
                       && lref->u.ar.dimen_type[n] == DIMEN_RANGE)
1853
                this_dep = gfc_check_element_vs_section (rref, lref, n);
1854
              else
1855
                {
1856
                  gcc_assert (rref->u.ar.dimen_type[n] == DIMEN_ELEMENT
1857
                              && lref->u.ar.dimen_type[n] == DIMEN_ELEMENT);
1858
                  this_dep = gfc_check_element_vs_element (rref, lref, n);
1859
                }
1860
 
1861
              /* If any dimension doesn't overlap, we have no dependency.  */
1862
              if (this_dep == GFC_DEP_NODEP)
1863
                return 0;
1864
 
1865
              /* Now deal with the loop reversal logic:  This only works on
1866
                 ranges and is activated by setting
1867
                                reverse[n] == GFC_ENABLE_REVERSE
1868
                 The ability to reverse or not is set by previous conditions
1869
                 in this dimension.  If reversal is not activated, the
1870
                 value GFC_DEP_BACKWARD is reset to GFC_DEP_OVERLAP.  */
1871
              if (rref->u.ar.dimen_type[n] == DIMEN_RANGE
1872
                    && lref->u.ar.dimen_type[n] == DIMEN_RANGE)
1873
                {
1874
                  /* Set reverse if backward dependence and not inhibited.  */
1875
                  if (reverse && reverse[n] == GFC_ENABLE_REVERSE)
1876
                    reverse[n] = (this_dep == GFC_DEP_BACKWARD) ?
1877
                                 GFC_REVERSE_SET : reverse[n];
1878
 
1879
                  /* Set forward if forward dependence and not inhibited.  */
1880
                  if (reverse && reverse[n] == GFC_ENABLE_REVERSE)
1881
                    reverse[n] = (this_dep == GFC_DEP_FORWARD) ?
1882
                                 GFC_FORWARD_SET : reverse[n];
1883
 
1884
                  /* Flag up overlap if dependence not compatible with
1885
                     the overall state of the expression.  */
1886
                  if (reverse && reverse[n] == GFC_REVERSE_SET
1887
                        && this_dep == GFC_DEP_FORWARD)
1888
                    {
1889
                      reverse[n] = GFC_INHIBIT_REVERSE;
1890
                      this_dep = GFC_DEP_OVERLAP;
1891
                    }
1892
                  else if (reverse && reverse[n] == GFC_FORWARD_SET
1893
                        && this_dep == GFC_DEP_BACKWARD)
1894
                    {
1895
                      reverse[n] = GFC_INHIBIT_REVERSE;
1896
                      this_dep = GFC_DEP_OVERLAP;
1897
                    }
1898
 
1899
                  /* If no intention of reversing or reversing is explicitly
1900
                     inhibited, convert backward dependence to overlap.  */
1901
                  if ((reverse == NULL && this_dep == GFC_DEP_BACKWARD)
1902
                      || (reverse != NULL && reverse[n] == GFC_INHIBIT_REVERSE))
1903
                    this_dep = GFC_DEP_OVERLAP;
1904
                }
1905
 
1906
              /* Overlap codes are in order of priority.  We only need to
1907
                 know the worst one.*/
1908
              if (this_dep > fin_dep)
1909
                fin_dep = this_dep;
1910
            }
1911
 
1912
          /* If this is an equal element, we have to keep going until we find
1913
             the "real" array reference.  */
1914
          if (lref->u.ar.type == AR_ELEMENT
1915
                && rref->u.ar.type == AR_ELEMENT
1916
                && fin_dep == GFC_DEP_EQUAL)
1917
            break;
1918
 
1919
          /* Exactly matching and forward overlapping ranges don't cause a
1920
             dependency.  */
1921
          if (fin_dep < GFC_DEP_BACKWARD)
1922
            return 0;
1923
 
1924
          /* Keep checking.  We only have a dependency if
1925
             subsequent references also overlap.  */
1926
          break;
1927
 
1928
        default:
1929
          gcc_unreachable ();
1930
        }
1931
      lref = lref->next;
1932
      rref = rref->next;
1933
    }
1934
 
1935
  /* If we haven't seen any array refs then something went wrong.  */
1936
  gcc_assert (fin_dep != GFC_DEP_ERROR);
1937
 
1938
  /* Assume the worst if we nest to different depths.  */
1939
  if (lref || rref)
1940
    return 1;
1941
 
1942
  return fin_dep == GFC_DEP_OVERLAP;
1943
}

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