OpenCores
URL https://opencores.org/ocsvn/openrisc/openrisc/trunk

Subversion Repositories openrisc

[/] [openrisc/] [trunk/] [gnu-stable/] [gcc-4.5.1/] [gcc/] [genrecog.c] - Blame information for rev 843

Go to most recent revision | Details | Compare with Previous | View Log

Line No. Rev Author Line
1 280 jeremybenn
/* Generate code from machine description to recognize rtl as insns.
2
   Copyright (C) 1987, 1988, 1992, 1993, 1994, 1995, 1997, 1998,
3
   1999, 2000, 2001, 2002, 2003, 2004, 2005, 2007, 2008, 2009
4
   Free Software Foundation, Inc.
5
 
6
   This file is part of GCC.
7
 
8
   GCC is free software; you can redistribute it and/or modify it
9
   under the terms of the GNU General Public License as published by
10
   the Free Software Foundation; either version 3, or (at your option)
11
   any later version.
12
 
13
   GCC is distributed in the hope that it will be useful, but WITHOUT
14
   ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
15
   or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public
16
   License 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
 
23
/* This program is used to produce insn-recog.c, which contains a
24
   function called `recog' plus its subroutines.  These functions
25
   contain a decision tree that recognizes whether an rtx, the
26
   argument given to recog, is a valid instruction.
27
 
28
   recog returns -1 if the rtx is not valid.  If the rtx is valid,
29
   recog returns a nonnegative number which is the insn code number
30
   for the pattern that matched.  This is the same as the order in the
31
   machine description of the entry that matched.  This number can be
32
   used as an index into various insn_* tables, such as insn_template,
33
   insn_outfun, and insn_n_operands (found in insn-output.c).
34
 
35
   The third argument to recog is an optional pointer to an int.  If
36
   present, recog will accept a pattern if it matches except for
37
   missing CLOBBER expressions at the end.  In that case, the value
38
   pointed to by the optional pointer will be set to the number of
39
   CLOBBERs that need to be added (it should be initialized to zero by
40
   the caller).  If it is set nonzero, the caller should allocate a
41
   PARALLEL of the appropriate size, copy the initial entries, and
42
   call add_clobbers (found in insn-emit.c) to fill in the CLOBBERs.
43
 
44
   This program also generates the function `split_insns', which
45
   returns 0 if the rtl could not be split, or it returns the split
46
   rtl as an INSN list.
47
 
48
   This program also generates the function `peephole2_insns', which
49
   returns 0 if the rtl could not be matched.  If there was a match,
50
   the new rtl is returned in an INSN list, and LAST_INSN will point
51
   to the last recognized insn in the old sequence.  */
52
 
53
#include "bconfig.h"
54
#include "system.h"
55
#include "coretypes.h"
56
#include "tm.h"
57
#include "rtl.h"
58
#include "errors.h"
59
#include "gensupport.h"
60
 
61
#define OUTPUT_LABEL(INDENT_STRING, LABEL_NUMBER) \
62
  printf("%sL%d: ATTRIBUTE_UNUSED_LABEL\n", (INDENT_STRING), (LABEL_NUMBER))
63
 
64
/* A listhead of decision trees.  The alternatives to a node are kept
65
   in a doubly-linked list so we can easily add nodes to the proper
66
   place when merging.  */
67
 
68
struct decision_head
69
{
70
  struct decision *first;
71
  struct decision *last;
72
};
73
 
74
/* These types are roughly in the order in which we'd like to test them.  */
75
enum decision_type
76
{
77
  DT_num_insns,
78
  DT_mode, DT_code, DT_veclen,
79
  DT_elt_zero_int, DT_elt_one_int, DT_elt_zero_wide, DT_elt_zero_wide_safe,
80
  DT_const_int,
81
  DT_veclen_ge, DT_dup, DT_pred, DT_c_test,
82
  DT_accept_op, DT_accept_insn
83
};
84
 
85
/* A single test.  The two accept types aren't tests per-se, but
86
   their equality (or lack thereof) does affect tree merging so
87
   it is convenient to keep them here.  */
88
 
89
struct decision_test
90
{
91
  /* A linked list through the tests attached to a node.  */
92
  struct decision_test *next;
93
 
94
  enum decision_type type;
95
 
96
  union
97
  {
98
    int num_insns;              /* Number if insn in a define_peephole2.  */
99
    enum machine_mode mode;     /* Machine mode of node.  */
100
    RTX_CODE code;              /* Code to test.  */
101
 
102
    struct
103
    {
104
      const char *name;         /* Predicate to call.  */
105
      const struct pred_data *data;
106
                                /* Optimization hints for this predicate.  */
107
      enum machine_mode mode;   /* Machine mode for node.  */
108
    } pred;
109
 
110
    const char *c_test;         /* Additional test to perform.  */
111
    int veclen;                 /* Length of vector.  */
112
    int dup;                    /* Number of operand to compare against.  */
113
    HOST_WIDE_INT intval;       /* Value for XINT for XWINT.  */
114
    int opno;                   /* Operand number matched.  */
115
 
116
    struct {
117
      int code_number;          /* Insn number matched.  */
118
      int lineno;               /* Line number of the insn.  */
119
      int num_clobbers_to_add;  /* Number of CLOBBERs to be added.  */
120
    } insn;
121
  } u;
122
};
123
 
124
/* Data structure for decision tree for recognizing legitimate insns.  */
125
 
126
struct decision
127
{
128
  struct decision_head success; /* Nodes to test on success.  */
129
  struct decision *next;        /* Node to test on failure.  */
130
  struct decision *prev;        /* Node whose failure tests us.  */
131
  struct decision *afterward;   /* Node to test on success,
132
                                   but failure of successor nodes.  */
133
 
134
  const char *position;         /* String denoting position in pattern.  */
135
 
136
  struct decision_test *tests;  /* The tests for this node.  */
137
 
138
  int number;                   /* Node number, used for labels */
139
  int subroutine_number;        /* Number of subroutine this node starts */
140
  int need_label;               /* Label needs to be output.  */
141
};
142
 
143
#define SUBROUTINE_THRESHOLD    100
144
 
145
static int next_subroutine_number;
146
 
147
/* We can write three types of subroutines: One for insn recognition,
148
   one to split insns, and one for peephole-type optimizations.  This
149
   defines which type is being written.  */
150
 
151
enum routine_type {
152
  RECOG, SPLIT, PEEPHOLE2
153
};
154
 
155
#define IS_SPLIT(X) ((X) != RECOG)
156
 
157
/* Next available node number for tree nodes.  */
158
 
159
static int next_number;
160
 
161
/* Next number to use as an insn_code.  */
162
 
163
static int next_insn_code;
164
 
165
/* Record the highest depth we ever have so we know how many variables to
166
   allocate in each subroutine we make.  */
167
 
168
static int max_depth;
169
 
170
/* The line number of the start of the pattern currently being processed.  */
171
static int pattern_lineno;
172
 
173
/* Count of errors.  */
174
static int error_count;
175
 
176
/* Predicate handling.
177
 
178
   We construct from the machine description a table mapping each
179
   predicate to a list of the rtl codes it can possibly match.  The
180
   function 'maybe_both_true' uses it to deduce that there are no
181
   expressions that can be matches by certain pairs of tree nodes.
182
   Also, if a predicate can match only one code, we can hardwire that
183
   code into the node testing the predicate.
184
 
185
   Some predicates are flagged as special.  validate_pattern will not
186
   warn about modeless match_operand expressions if they have a
187
   special predicate.  Predicates that allow only constants are also
188
   treated as special, for this purpose.
189
 
190
   validate_pattern will warn about predicates that allow non-lvalues
191
   when they appear in destination operands.
192
 
193
   Calculating the set of rtx codes that can possibly be accepted by a
194
   predicate expression EXP requires a three-state logic: any given
195
   subexpression may definitively accept a code C (Y), definitively
196
   reject a code C (N), or may have an indeterminate effect (I).  N
197
   and I is N; Y or I is Y; Y and I, N or I are both I.  Here are full
198
   truth tables.
199
 
200
     a b  a&b  a|b
201
     Y Y   Y    Y
202
     N Y   N    Y
203
     N N   N    N
204
     I Y   I    Y
205
     I N   N    I
206
     I I   I    I
207
 
208
   We represent Y with 1, N with 0, I with 2.  If any code is left in
209
   an I state by the complete expression, we must assume that that
210
   code can be accepted.  */
211
 
212
#define N 0
213
#define Y 1
214
#define I 2
215
 
216
#define TRISTATE_AND(a,b)                       \
217
  ((a) == I ? ((b) == N ? N : I) :              \
218
   (b) == I ? ((a) == N ? N : I) :              \
219
   (a) && (b))
220
 
221
#define TRISTATE_OR(a,b)                        \
222
  ((a) == I ? ((b) == Y ? Y : I) :              \
223
   (b) == I ? ((a) == Y ? Y : I) :              \
224
   (a) || (b))
225
 
226
#define TRISTATE_NOT(a)                         \
227
  ((a) == I ? I : !(a))
228
 
229
/* 0 means no warning about that code yet, 1 means warned.  */
230
static char did_you_mean_codes[NUM_RTX_CODE];
231
 
232
/* Recursively calculate the set of rtx codes accepted by the
233
   predicate expression EXP, writing the result to CODES.  */
234
static void
235
compute_predicate_codes (rtx exp, char codes[NUM_RTX_CODE])
236
{
237
  char op0_codes[NUM_RTX_CODE];
238
  char op1_codes[NUM_RTX_CODE];
239
  char op2_codes[NUM_RTX_CODE];
240
  int i;
241
 
242
  switch (GET_CODE (exp))
243
    {
244
    case AND:
245
      compute_predicate_codes (XEXP (exp, 0), op0_codes);
246
      compute_predicate_codes (XEXP (exp, 1), op1_codes);
247
      for (i = 0; i < NUM_RTX_CODE; i++)
248
        codes[i] = TRISTATE_AND (op0_codes[i], op1_codes[i]);
249
      break;
250
 
251
    case IOR:
252
      compute_predicate_codes (XEXP (exp, 0), op0_codes);
253
      compute_predicate_codes (XEXP (exp, 1), op1_codes);
254
      for (i = 0; i < NUM_RTX_CODE; i++)
255
        codes[i] = TRISTATE_OR (op0_codes[i], op1_codes[i]);
256
      break;
257
    case NOT:
258
      compute_predicate_codes (XEXP (exp, 0), op0_codes);
259
      for (i = 0; i < NUM_RTX_CODE; i++)
260
        codes[i] = TRISTATE_NOT (op0_codes[i]);
261
      break;
262
 
263
    case IF_THEN_ELSE:
264
      /* a ? b : c  accepts the same codes as (a & b) | (!a & c).  */
265
      compute_predicate_codes (XEXP (exp, 0), op0_codes);
266
      compute_predicate_codes (XEXP (exp, 1), op1_codes);
267
      compute_predicate_codes (XEXP (exp, 2), op2_codes);
268
      for (i = 0; i < NUM_RTX_CODE; i++)
269
        codes[i] = TRISTATE_OR (TRISTATE_AND (op0_codes[i], op1_codes[i]),
270
                                TRISTATE_AND (TRISTATE_NOT (op0_codes[i]),
271
                                              op2_codes[i]));
272
      break;
273
 
274
    case MATCH_CODE:
275
      /* MATCH_CODE allows a specified list of codes.  However, if it
276
         does not apply to the top level of the expression, it does not
277
         constrain the set of codes for the top level.  */
278
      if (XSTR (exp, 1)[0] != '\0')
279
        {
280
          memset (codes, Y, NUM_RTX_CODE);
281
          break;
282
        }
283
 
284
      memset (codes, N, NUM_RTX_CODE);
285
      {
286
        const char *next_code = XSTR (exp, 0);
287
        const char *code;
288
 
289
        if (*next_code == '\0')
290
          {
291
            message_with_line (pattern_lineno, "empty match_code expression");
292
            error_count++;
293
            break;
294
          }
295
 
296
        while ((code = scan_comma_elt (&next_code)) != 0)
297
          {
298
            size_t n = next_code - code;
299
            int found_it = 0;
300
 
301
            for (i = 0; i < NUM_RTX_CODE; i++)
302
              if (!strncmp (code, GET_RTX_NAME (i), n)
303
                  && GET_RTX_NAME (i)[n] == '\0')
304
                {
305
                  codes[i] = Y;
306
                  found_it = 1;
307
                  break;
308
                }
309
            if (!found_it)
310
              {
311
                message_with_line (pattern_lineno, "match_code \"%.*s\" matches nothing",
312
                                   (int) n, code);
313
                error_count ++;
314
                for (i = 0; i < NUM_RTX_CODE; i++)
315
                  if (!strncasecmp (code, GET_RTX_NAME (i), n)
316
                      && GET_RTX_NAME (i)[n] == '\0'
317
                      && !did_you_mean_codes[i])
318
                    {
319
                      did_you_mean_codes[i] = 1;
320
                      message_with_line (pattern_lineno, "(did you mean \"%s\"?)", GET_RTX_NAME (i));
321
                    }
322
              }
323
 
324
          }
325
      }
326
      break;
327
 
328
    case MATCH_OPERAND:
329
      /* MATCH_OPERAND disallows the set of codes that the named predicate
330
         disallows, and is indeterminate for the codes that it does allow.  */
331
      {
332
        struct pred_data *p = lookup_predicate (XSTR (exp, 1));
333
        if (!p)
334
          {
335
            message_with_line (pattern_lineno,
336
                               "reference to unknown predicate '%s'",
337
                               XSTR (exp, 1));
338
            error_count++;
339
            break;
340
          }
341
        for (i = 0; i < NUM_RTX_CODE; i++)
342
          codes[i] = p->codes[i] ? I : N;
343
      }
344
      break;
345
 
346
 
347
    case MATCH_TEST:
348
      /* (match_test WHATEVER) is completely indeterminate.  */
349
      memset (codes, I, NUM_RTX_CODE);
350
      break;
351
 
352
    default:
353
      message_with_line (pattern_lineno,
354
         "'%s' cannot be used in a define_predicate expression",
355
         GET_RTX_NAME (GET_CODE (exp)));
356
      error_count++;
357
      memset (codes, I, NUM_RTX_CODE);
358
      break;
359
    }
360
}
361
 
362
#undef TRISTATE_OR
363
#undef TRISTATE_AND
364
#undef TRISTATE_NOT
365
 
366
/* Process a define_predicate expression: compute the set of predicates
367
   that can be matched, and record this as a known predicate.  */
368
static void
369
process_define_predicate (rtx desc)
370
{
371
  struct pred_data *pred = XCNEW (struct pred_data);
372
  char codes[NUM_RTX_CODE];
373
  int i;
374
 
375
  pred->name = XSTR (desc, 0);
376
  if (GET_CODE (desc) == DEFINE_SPECIAL_PREDICATE)
377
    pred->special = 1;
378
 
379
  compute_predicate_codes (XEXP (desc, 1), codes);
380
 
381
  for (i = 0; i < NUM_RTX_CODE; i++)
382
    if (codes[i] != N)
383
      add_predicate_code (pred, (enum rtx_code) i);
384
 
385
  add_predicate (pred);
386
}
387
#undef I
388
#undef N
389
#undef Y
390
 
391
 
392
static struct decision *new_decision
393
  (const char *, struct decision_head *);
394
static struct decision_test *new_decision_test
395
  (enum decision_type, struct decision_test ***);
396
static rtx find_operand
397
  (rtx, int, rtx);
398
static rtx find_matching_operand
399
  (rtx, int);
400
static void validate_pattern
401
  (rtx, rtx, rtx, int);
402
static struct decision *add_to_sequence
403
  (rtx, struct decision_head *, const char *, enum routine_type, int);
404
 
405
static int maybe_both_true_2
406
  (struct decision_test *, struct decision_test *);
407
static int maybe_both_true_1
408
  (struct decision_test *, struct decision_test *);
409
static int maybe_both_true
410
  (struct decision *, struct decision *, int);
411
 
412
static int nodes_identical_1
413
  (struct decision_test *, struct decision_test *);
414
static int nodes_identical
415
  (struct decision *, struct decision *);
416
static void merge_accept_insn
417
  (struct decision *, struct decision *);
418
static void merge_trees
419
  (struct decision_head *, struct decision_head *);
420
 
421
static void factor_tests
422
  (struct decision_head *);
423
static void simplify_tests
424
  (struct decision_head *);
425
static int break_out_subroutines
426
  (struct decision_head *, int);
427
static void find_afterward
428
  (struct decision_head *, struct decision *);
429
 
430
static void change_state
431
  (const char *, const char *, const char *);
432
static void print_code
433
  (enum rtx_code);
434
static void write_afterward
435
  (struct decision *, struct decision *, const char *);
436
static struct decision *write_switch
437
  (struct decision *, int);
438
static void write_cond
439
  (struct decision_test *, int, enum routine_type);
440
static void write_action
441
  (struct decision *, struct decision_test *, int, int,
442
   struct decision *, enum routine_type);
443
static int is_unconditional
444
  (struct decision_test *, enum routine_type);
445
static int write_node
446
  (struct decision *, int, enum routine_type);
447
static void write_tree_1
448
  (struct decision_head *, int, enum routine_type);
449
static void write_tree
450
  (struct decision_head *, const char *, enum routine_type, int);
451
static void write_subroutine
452
  (struct decision_head *, enum routine_type);
453
static void write_subroutines
454
  (struct decision_head *, enum routine_type);
455
static void write_header
456
  (void);
457
 
458
static struct decision_head make_insn_sequence
459
  (rtx, enum routine_type);
460
static void process_tree
461
  (struct decision_head *, enum routine_type);
462
 
463
static void debug_decision_0
464
  (struct decision *, int, int);
465
static void debug_decision_1
466
  (struct decision *, int);
467
static void debug_decision_2
468
  (struct decision_test *);
469
extern void debug_decision
470
  (struct decision *);
471
extern void debug_decision_list
472
  (struct decision *);
473
 
474
/* Create a new node in sequence after LAST.  */
475
 
476
static struct decision *
477
new_decision (const char *position, struct decision_head *last)
478
{
479
  struct decision *new_decision = XCNEW (struct decision);
480
 
481
  new_decision->success = *last;
482
  new_decision->position = xstrdup (position);
483
  new_decision->number = next_number++;
484
 
485
  last->first = last->last = new_decision;
486
  return new_decision;
487
}
488
 
489
/* Create a new test and link it in at PLACE.  */
490
 
491
static struct decision_test *
492
new_decision_test (enum decision_type type, struct decision_test ***pplace)
493
{
494
  struct decision_test **place = *pplace;
495
  struct decision_test *test;
496
 
497
  test = XNEW (struct decision_test);
498
  test->next = *place;
499
  test->type = type;
500
  *place = test;
501
 
502
  place = &test->next;
503
  *pplace = place;
504
 
505
  return test;
506
}
507
 
508
/* Search for and return operand N, stop when reaching node STOP.  */
509
 
510
static rtx
511
find_operand (rtx pattern, int n, rtx stop)
512
{
513
  const char *fmt;
514
  RTX_CODE code;
515
  int i, j, len;
516
  rtx r;
517
 
518
  if (pattern == stop)
519
    return stop;
520
 
521
  code = GET_CODE (pattern);
522
  if ((code == MATCH_SCRATCH
523
       || code == MATCH_OPERAND
524
       || code == MATCH_OPERATOR
525
       || code == MATCH_PARALLEL)
526
      && XINT (pattern, 0) == n)
527
    return pattern;
528
 
529
  fmt = GET_RTX_FORMAT (code);
530
  len = GET_RTX_LENGTH (code);
531
  for (i = 0; i < len; i++)
532
    {
533
      switch (fmt[i])
534
        {
535
        case 'e': case 'u':
536
          if ((r = find_operand (XEXP (pattern, i), n, stop)) != NULL_RTX)
537
            return r;
538
          break;
539
 
540
        case 'V':
541
          if (! XVEC (pattern, i))
542
            break;
543
          /* Fall through.  */
544
 
545
        case 'E':
546
          for (j = 0; j < XVECLEN (pattern, i); j++)
547
            if ((r = find_operand (XVECEXP (pattern, i, j), n, stop))
548
                != NULL_RTX)
549
              return r;
550
          break;
551
 
552
        case 'i': case 'w': case '0': case 's':
553
          break;
554
 
555
        default:
556
          gcc_unreachable ();
557
        }
558
    }
559
 
560
  return NULL;
561
}
562
 
563
/* Search for and return operand M, such that it has a matching
564
   constraint for operand N.  */
565
 
566
static rtx
567
find_matching_operand (rtx pattern, int n)
568
{
569
  const char *fmt;
570
  RTX_CODE code;
571
  int i, j, len;
572
  rtx r;
573
 
574
  code = GET_CODE (pattern);
575
  if (code == MATCH_OPERAND
576
      && (XSTR (pattern, 2)[0] == '0' + n
577
          || (XSTR (pattern, 2)[0] == '%'
578
              && XSTR (pattern, 2)[1] == '0' + n)))
579
    return pattern;
580
 
581
  fmt = GET_RTX_FORMAT (code);
582
  len = GET_RTX_LENGTH (code);
583
  for (i = 0; i < len; i++)
584
    {
585
      switch (fmt[i])
586
        {
587
        case 'e': case 'u':
588
          if ((r = find_matching_operand (XEXP (pattern, i), n)))
589
            return r;
590
          break;
591
 
592
        case 'V':
593
          if (! XVEC (pattern, i))
594
            break;
595
          /* Fall through.  */
596
 
597
        case 'E':
598
          for (j = 0; j < XVECLEN (pattern, i); j++)
599
            if ((r = find_matching_operand (XVECEXP (pattern, i, j), n)))
600
              return r;
601
          break;
602
 
603
        case 'i': case 'w': case '0': case 's':
604
          break;
605
 
606
        default:
607
          gcc_unreachable ();
608
        }
609
    }
610
 
611
  return NULL;
612
}
613
 
614
 
615
/* Check for various errors in patterns.  SET is nonnull for a destination,
616
   and is the complete set pattern.  SET_CODE is '=' for normal sets, and
617
   '+' within a context that requires in-out constraints.  */
618
 
619
static void
620
validate_pattern (rtx pattern, rtx insn, rtx set, int set_code)
621
{
622
  const char *fmt;
623
  RTX_CODE code;
624
  size_t i, len;
625
  int j;
626
 
627
  code = GET_CODE (pattern);
628
  switch (code)
629
    {
630
    case MATCH_SCRATCH:
631
      return;
632
    case MATCH_DUP:
633
    case MATCH_OP_DUP:
634
    case MATCH_PAR_DUP:
635
      if (find_operand (insn, XINT (pattern, 0), pattern) == pattern)
636
        {
637
          message_with_line (pattern_lineno,
638
                             "operand %i duplicated before defined",
639
                             XINT (pattern, 0));
640
          error_count++;
641
        }
642
      break;
643
    case MATCH_OPERAND:
644
    case MATCH_OPERATOR:
645
      {
646
        const char *pred_name = XSTR (pattern, 1);
647
        const struct pred_data *pred;
648
        const char *c_test;
649
 
650
        if (GET_CODE (insn) == DEFINE_INSN)
651
          c_test = XSTR (insn, 2);
652
        else
653
          c_test = XSTR (insn, 1);
654
 
655
        if (pred_name[0] != 0)
656
          {
657
            pred = lookup_predicate (pred_name);
658
            if (!pred)
659
              message_with_line (pattern_lineno,
660
                                 "warning: unknown predicate '%s'",
661
                                 pred_name);
662
          }
663
        else
664
          pred = 0;
665
 
666
        if (code == MATCH_OPERAND)
667
          {
668
            const char constraints0 = XSTR (pattern, 2)[0];
669
 
670
            /* In DEFINE_EXPAND, DEFINE_SPLIT, and DEFINE_PEEPHOLE2, we
671
               don't use the MATCH_OPERAND constraint, only the predicate.
672
               This is confusing to folks doing new ports, so help them
673
               not make the mistake.  */
674
            if (GET_CODE (insn) == DEFINE_EXPAND
675
                || GET_CODE (insn) == DEFINE_SPLIT
676
                || GET_CODE (insn) == DEFINE_PEEPHOLE2)
677
              {
678
                if (constraints0)
679
                  message_with_line (pattern_lineno,
680
                                     "warning: constraints not supported in %s",
681
                                     rtx_name[GET_CODE (insn)]);
682
              }
683
 
684
            /* A MATCH_OPERAND that is a SET should have an output reload.  */
685
            else if (set && constraints0)
686
              {
687
                if (set_code == '+')
688
                  {
689
                    if (constraints0 == '+')
690
                      ;
691
                    /* If we've only got an output reload for this operand,
692
                       we'd better have a matching input operand.  */
693
                    else if (constraints0 == '='
694
                             && find_matching_operand (insn, XINT (pattern, 0)))
695
                      ;
696
                    else
697
                      {
698
                        message_with_line (pattern_lineno,
699
                                           "operand %d missing in-out reload",
700
                                           XINT (pattern, 0));
701
                        error_count++;
702
                      }
703
                  }
704
                else if (constraints0 != '=' && constraints0 != '+')
705
                  {
706
                    message_with_line (pattern_lineno,
707
                                       "operand %d missing output reload",
708
                                       XINT (pattern, 0));
709
                    error_count++;
710
                  }
711
              }
712
          }
713
 
714
        /* Allowing non-lvalues in destinations -- particularly CONST_INT --
715
           while not likely to occur at runtime, results in less efficient
716
           code from insn-recog.c.  */
717
        if (set && pred && pred->allows_non_lvalue)
718
          message_with_line (pattern_lineno,
719
                             "warning: destination operand %d "
720
                             "allows non-lvalue",
721
                             XINT (pattern, 0));
722
 
723
        /* A modeless MATCH_OPERAND can be handy when we can check for
724
           multiple modes in the c_test.  In most other cases, it is a
725
           mistake.  Only DEFINE_INSN is eligible, since SPLIT and
726
           PEEP2 can FAIL within the output pattern.  Exclude special
727
           predicates, which check the mode themselves.  Also exclude
728
           predicates that allow only constants.  Exclude the SET_DEST
729
           of a call instruction, as that is a common idiom.  */
730
 
731
        if (GET_MODE (pattern) == VOIDmode
732
            && code == MATCH_OPERAND
733
            && GET_CODE (insn) == DEFINE_INSN
734
            && pred
735
            && !pred->special
736
            && pred->allows_non_const
737
            && strstr (c_test, "operands") == NULL
738
            && ! (set
739
                  && GET_CODE (set) == SET
740
                  && GET_CODE (SET_SRC (set)) == CALL))
741
          message_with_line (pattern_lineno,
742
                             "warning: operand %d missing mode?",
743
                             XINT (pattern, 0));
744
        return;
745
      }
746
 
747
    case SET:
748
      {
749
        enum machine_mode dmode, smode;
750
        rtx dest, src;
751
 
752
        dest = SET_DEST (pattern);
753
        src = SET_SRC (pattern);
754
 
755
        /* STRICT_LOW_PART is a wrapper.  Its argument is the real
756
           destination, and it's mode should match the source.  */
757
        if (GET_CODE (dest) == STRICT_LOW_PART)
758
          dest = XEXP (dest, 0);
759
 
760
        /* Find the referent for a DUP.  */
761
 
762
        if (GET_CODE (dest) == MATCH_DUP
763
            || GET_CODE (dest) == MATCH_OP_DUP
764
            || GET_CODE (dest) == MATCH_PAR_DUP)
765
          dest = find_operand (insn, XINT (dest, 0), NULL);
766
 
767
        if (GET_CODE (src) == MATCH_DUP
768
            || GET_CODE (src) == MATCH_OP_DUP
769
            || GET_CODE (src) == MATCH_PAR_DUP)
770
          src = find_operand (insn, XINT (src, 0), NULL);
771
 
772
        dmode = GET_MODE (dest);
773
        smode = GET_MODE (src);
774
 
775
        /* The mode of an ADDRESS_OPERAND is the mode of the memory
776
           reference, not the mode of the address.  */
777
        if (GET_CODE (src) == MATCH_OPERAND
778
            && ! strcmp (XSTR (src, 1), "address_operand"))
779
          ;
780
 
781
        /* The operands of a SET must have the same mode unless one
782
           is VOIDmode.  */
783
        else if (dmode != VOIDmode && smode != VOIDmode && dmode != smode)
784
          {
785
            message_with_line (pattern_lineno,
786
                               "mode mismatch in set: %smode vs %smode",
787
                               GET_MODE_NAME (dmode), GET_MODE_NAME (smode));
788
            error_count++;
789
          }
790
 
791
        /* If only one of the operands is VOIDmode, and PC or CC0 is
792
           not involved, it's probably a mistake.  */
793
        else if (dmode != smode
794
                 && GET_CODE (dest) != PC
795
                 && GET_CODE (dest) != CC0
796
                 && GET_CODE (src) != PC
797
                 && GET_CODE (src) != CC0
798
                 && !CONST_INT_P (src)
799
                 && GET_CODE (src) != CALL)
800
          {
801
            const char *which;
802
            which = (dmode == VOIDmode ? "destination" : "source");
803
            message_with_line (pattern_lineno,
804
                               "warning: %s missing a mode?", which);
805
          }
806
 
807
        if (dest != SET_DEST (pattern))
808
          validate_pattern (dest, insn, pattern, '=');
809
        validate_pattern (SET_DEST (pattern), insn, pattern, '=');
810
        validate_pattern (SET_SRC (pattern), insn, NULL_RTX, 0);
811
        return;
812
      }
813
 
814
    case CLOBBER:
815
      validate_pattern (SET_DEST (pattern), insn, pattern, '=');
816
      return;
817
 
818
    case ZERO_EXTRACT:
819
      validate_pattern (XEXP (pattern, 0), insn, set, set ? '+' : 0);
820
      validate_pattern (XEXP (pattern, 1), insn, NULL_RTX, 0);
821
      validate_pattern (XEXP (pattern, 2), insn, NULL_RTX, 0);
822
      return;
823
 
824
    case STRICT_LOW_PART:
825
      validate_pattern (XEXP (pattern, 0), insn, set, set ? '+' : 0);
826
      return;
827
 
828
    case LABEL_REF:
829
      if (GET_MODE (XEXP (pattern, 0)) != VOIDmode)
830
        {
831
          message_with_line (pattern_lineno,
832
                             "operand to label_ref %smode not VOIDmode",
833
                             GET_MODE_NAME (GET_MODE (XEXP (pattern, 0))));
834
          error_count++;
835
        }
836
      break;
837
 
838
    default:
839
      break;
840
    }
841
 
842
  fmt = GET_RTX_FORMAT (code);
843
  len = GET_RTX_LENGTH (code);
844
  for (i = 0; i < len; i++)
845
    {
846
      switch (fmt[i])
847
        {
848
        case 'e': case 'u':
849
          validate_pattern (XEXP (pattern, i), insn, NULL_RTX, 0);
850
          break;
851
 
852
        case 'E':
853
          for (j = 0; j < XVECLEN (pattern, i); j++)
854
            validate_pattern (XVECEXP (pattern, i, j), insn, NULL_RTX, 0);
855
          break;
856
 
857
        case 'i': case 'w': case '0': case 's':
858
          break;
859
 
860
        default:
861
          gcc_unreachable ();
862
        }
863
    }
864
}
865
 
866
/* Create a chain of nodes to verify that an rtl expression matches
867
   PATTERN.
868
 
869
   LAST is a pointer to the listhead in the previous node in the chain (or
870
   in the calling function, for the first node).
871
 
872
   POSITION is the string representing the current position in the insn.
873
 
874
   INSN_TYPE is the type of insn for which we are emitting code.
875
 
876
   A pointer to the final node in the chain is returned.  */
877
 
878
static struct decision *
879
add_to_sequence (rtx pattern, struct decision_head *last, const char *position,
880
                 enum routine_type insn_type, int top)
881
{
882
  RTX_CODE code;
883
  struct decision *this_decision, *sub;
884
  struct decision_test *test;
885
  struct decision_test **place;
886
  char *subpos;
887
  size_t i;
888
  const char *fmt;
889
  int depth = strlen (position);
890
  int len;
891
  enum machine_mode mode;
892
 
893
  if (depth > max_depth)
894
    max_depth = depth;
895
 
896
  subpos = XNEWVAR (char, depth + 2);
897
  strcpy (subpos, position);
898
  subpos[depth + 1] = 0;
899
 
900
  sub = this_decision = new_decision (position, last);
901
  place = &this_decision->tests;
902
 
903
 restart:
904
  mode = GET_MODE (pattern);
905
  code = GET_CODE (pattern);
906
 
907
  switch (code)
908
    {
909
    case PARALLEL:
910
      /* Toplevel peephole pattern.  */
911
      if (insn_type == PEEPHOLE2 && top)
912
        {
913
          int num_insns;
914
 
915
          /* Check we have sufficient insns.  This avoids complications
916
             because we then know peep2_next_insn never fails.  */
917
          num_insns = XVECLEN (pattern, 0);
918
          if (num_insns > 1)
919
            {
920
              test = new_decision_test (DT_num_insns, &place);
921
              test->u.num_insns = num_insns;
922
              last = &sub->success;
923
            }
924
          else
925
            {
926
              /* We don't need the node we just created -- unlink it.  */
927
              last->first = last->last = NULL;
928
            }
929
 
930
          for (i = 0; i < (size_t) XVECLEN (pattern, 0); i++)
931
            {
932
              /* Which insn we're looking at is represented by A-Z. We don't
933
                 ever use 'A', however; it is always implied.  */
934
 
935
              subpos[depth] = (i > 0 ? 'A' + i : 0);
936
              sub = add_to_sequence (XVECEXP (pattern, 0, i),
937
                                     last, subpos, insn_type, 0);
938
              last = &sub->success;
939
            }
940
          goto ret;
941
        }
942
 
943
      /* Else nothing special.  */
944
      break;
945
 
946
    case MATCH_PARALLEL:
947
      /* The explicit patterns within a match_parallel enforce a minimum
948
         length on the vector.  The match_parallel predicate may allow
949
         for more elements.  We do need to check for this minimum here
950
         or the code generated to match the internals may reference data
951
         beyond the end of the vector.  */
952
      test = new_decision_test (DT_veclen_ge, &place);
953
      test->u.veclen = XVECLEN (pattern, 2);
954
      /* Fall through.  */
955
 
956
    case MATCH_OPERAND:
957
    case MATCH_SCRATCH:
958
    case MATCH_OPERATOR:
959
      {
960
        RTX_CODE was_code = code;
961
        const char *pred_name;
962
        bool allows_const_int = true;
963
 
964
        if (code == MATCH_SCRATCH)
965
          {
966
            pred_name = "scratch_operand";
967
            code = UNKNOWN;
968
          }
969
        else
970
          {
971
            pred_name = XSTR (pattern, 1);
972
            if (code == MATCH_PARALLEL)
973
              code = PARALLEL;
974
            else
975
              code = UNKNOWN;
976
          }
977
 
978
        if (pred_name[0] != 0)
979
          {
980
            const struct pred_data *pred;
981
 
982
            test = new_decision_test (DT_pred, &place);
983
            test->u.pred.name = pred_name;
984
            test->u.pred.mode = mode;
985
 
986
            /* See if we know about this predicate.
987
               If we do, remember it for use below.
988
 
989
               We can optimize the generated code a little if either
990
               (a) the predicate only accepts one code, or (b) the
991
               predicate does not allow CONST_INT, in which case it
992
               can match only if the modes match.  */
993
            pred = lookup_predicate (pred_name);
994
            if (pred)
995
              {
996
                test->u.pred.data = pred;
997
                allows_const_int = pred->codes[CONST_INT];
998
                if (was_code == MATCH_PARALLEL
999
                    && pred->singleton != PARALLEL)
1000
                  message_with_line (pattern_lineno,
1001
                        "predicate '%s' used in match_parallel "
1002
                        "does not allow only PARALLEL", pred->name);
1003
                else
1004
                  code = pred->singleton;
1005
              }
1006
            else
1007
              message_with_line (pattern_lineno,
1008
                        "warning: unknown predicate '%s' in '%s' expression",
1009
                        pred_name, GET_RTX_NAME (was_code));
1010
          }
1011
 
1012
        /* Can't enforce a mode if we allow const_int.  */
1013
        if (allows_const_int)
1014
          mode = VOIDmode;
1015
 
1016
        /* Accept the operand, i.e. record it in `operands'.  */
1017
        test = new_decision_test (DT_accept_op, &place);
1018
        test->u.opno = XINT (pattern, 0);
1019
 
1020
        if (was_code == MATCH_OPERATOR || was_code == MATCH_PARALLEL)
1021
          {
1022
            char base = (was_code == MATCH_OPERATOR ? '0' : 'a');
1023
            for (i = 0; i < (size_t) XVECLEN (pattern, 2); i++)
1024
              {
1025
                subpos[depth] = i + base;
1026
                sub = add_to_sequence (XVECEXP (pattern, 2, i),
1027
                                       &sub->success, subpos, insn_type, 0);
1028
              }
1029
          }
1030
        goto fini;
1031
      }
1032
 
1033
    case MATCH_OP_DUP:
1034
      code = UNKNOWN;
1035
 
1036
      test = new_decision_test (DT_dup, &place);
1037
      test->u.dup = XINT (pattern, 0);
1038
 
1039
      test = new_decision_test (DT_accept_op, &place);
1040
      test->u.opno = XINT (pattern, 0);
1041
 
1042
      for (i = 0; i < (size_t) XVECLEN (pattern, 1); i++)
1043
        {
1044
          subpos[depth] = i + '0';
1045
          sub = add_to_sequence (XVECEXP (pattern, 1, i),
1046
                                 &sub->success, subpos, insn_type, 0);
1047
        }
1048
      goto fini;
1049
 
1050
    case MATCH_DUP:
1051
    case MATCH_PAR_DUP:
1052
      code = UNKNOWN;
1053
 
1054
      test = new_decision_test (DT_dup, &place);
1055
      test->u.dup = XINT (pattern, 0);
1056
      goto fini;
1057
 
1058
    case ADDRESS:
1059
      pattern = XEXP (pattern, 0);
1060
      goto restart;
1061
 
1062
    default:
1063
      break;
1064
    }
1065
 
1066
  fmt = GET_RTX_FORMAT (code);
1067
  len = GET_RTX_LENGTH (code);
1068
 
1069
  /* Do tests against the current node first.  */
1070
  for (i = 0; i < (size_t) len; i++)
1071
    {
1072
      if (fmt[i] == 'i')
1073
        {
1074
          gcc_assert (i < 2);
1075
 
1076
          if (!i)
1077
            {
1078
              test = new_decision_test (DT_elt_zero_int, &place);
1079
              test->u.intval = XINT (pattern, i);
1080
            }
1081
          else
1082
            {
1083
              test = new_decision_test (DT_elt_one_int, &place);
1084
              test->u.intval = XINT (pattern, i);
1085
            }
1086
        }
1087
      else if (fmt[i] == 'w')
1088
        {
1089
          /* If this value actually fits in an int, we can use a switch
1090
             statement here, so indicate that.  */
1091
          enum decision_type type
1092
            = ((int) XWINT (pattern, i) == XWINT (pattern, i))
1093
              ? DT_elt_zero_wide_safe : DT_elt_zero_wide;
1094
 
1095
          gcc_assert (!i);
1096
 
1097
          test = new_decision_test (type, &place);
1098
          test->u.intval = XWINT (pattern, i);
1099
        }
1100
      else if (fmt[i] == 'E')
1101
        {
1102
          gcc_assert (!i);
1103
 
1104
          test = new_decision_test (DT_veclen, &place);
1105
          test->u.veclen = XVECLEN (pattern, i);
1106
        }
1107
    }
1108
 
1109
  /* Now test our sub-patterns.  */
1110
  for (i = 0; i < (size_t) len; i++)
1111
    {
1112
      switch (fmt[i])
1113
        {
1114
        case 'e': case 'u':
1115
          subpos[depth] = '0' + i;
1116
          sub = add_to_sequence (XEXP (pattern, i), &sub->success,
1117
                                 subpos, insn_type, 0);
1118
          break;
1119
 
1120
        case 'E':
1121
          {
1122
            int j;
1123
            for (j = 0; j < XVECLEN (pattern, i); j++)
1124
              {
1125
                subpos[depth] = 'a' + j;
1126
                sub = add_to_sequence (XVECEXP (pattern, i, j),
1127
                                       &sub->success, subpos, insn_type, 0);
1128
              }
1129
            break;
1130
          }
1131
 
1132
        case 'i': case 'w':
1133
          /* Handled above.  */
1134
          break;
1135
        case '0':
1136
          break;
1137
 
1138
        default:
1139
          gcc_unreachable ();
1140
        }
1141
    }
1142
 
1143
 fini:
1144
  /* Insert nodes testing mode and code, if they're still relevant,
1145
     before any of the nodes we may have added above.  */
1146
  if (code != UNKNOWN)
1147
    {
1148
      place = &this_decision->tests;
1149
      test = new_decision_test (DT_code, &place);
1150
      test->u.code = code;
1151
    }
1152
 
1153
  if (mode != VOIDmode)
1154
    {
1155
      place = &this_decision->tests;
1156
      test = new_decision_test (DT_mode, &place);
1157
      test->u.mode = mode;
1158
    }
1159
 
1160
  /* If we didn't insert any tests or accept nodes, hork.  */
1161
  gcc_assert (this_decision->tests);
1162
 
1163
 ret:
1164
  free (subpos);
1165
  return sub;
1166
}
1167
 
1168
/* A subroutine of maybe_both_true; examines only one test.
1169
   Returns > 0 for "definitely both true" and < 0 for "maybe both true".  */
1170
 
1171
static int
1172
maybe_both_true_2 (struct decision_test *d1, struct decision_test *d2)
1173
{
1174
  if (d1->type == d2->type)
1175
    {
1176
      switch (d1->type)
1177
        {
1178
        case DT_num_insns:
1179
          if (d1->u.num_insns == d2->u.num_insns)
1180
            return 1;
1181
          else
1182
            return -1;
1183
 
1184
        case DT_mode:
1185
          return d1->u.mode == d2->u.mode;
1186
 
1187
        case DT_code:
1188
          return d1->u.code == d2->u.code;
1189
 
1190
        case DT_veclen:
1191
          return d1->u.veclen == d2->u.veclen;
1192
 
1193
        case DT_elt_zero_int:
1194
        case DT_elt_one_int:
1195
        case DT_elt_zero_wide:
1196
        case DT_elt_zero_wide_safe:
1197
          return d1->u.intval == d2->u.intval;
1198
 
1199
        default:
1200
          break;
1201
        }
1202
    }
1203
 
1204
  /* If either has a predicate that we know something about, set
1205
     things up so that D1 is the one that always has a known
1206
     predicate.  Then see if they have any codes in common.  */
1207
 
1208
  if (d1->type == DT_pred || d2->type == DT_pred)
1209
    {
1210
      if (d2->type == DT_pred)
1211
        {
1212
          struct decision_test *tmp;
1213
          tmp = d1, d1 = d2, d2 = tmp;
1214
        }
1215
 
1216
      /* If D2 tests a mode, see if it matches D1.  */
1217
      if (d1->u.pred.mode != VOIDmode)
1218
        {
1219
          if (d2->type == DT_mode)
1220
            {
1221
              if (d1->u.pred.mode != d2->u.mode
1222
                  /* The mode of an address_operand predicate is the
1223
                     mode of the memory, not the operand.  It can only
1224
                     be used for testing the predicate, so we must
1225
                     ignore it here.  */
1226
                  && strcmp (d1->u.pred.name, "address_operand") != 0)
1227
                return 0;
1228
            }
1229
          /* Don't check two predicate modes here, because if both predicates
1230
             accept CONST_INT, then both can still be true even if the modes
1231
             are different.  If they don't accept CONST_INT, there will be a
1232
             separate DT_mode that will make maybe_both_true_1 return 0.  */
1233
        }
1234
 
1235
      if (d1->u.pred.data)
1236
        {
1237
          /* If D2 tests a code, see if it is in the list of valid
1238
             codes for D1's predicate.  */
1239
          if (d2->type == DT_code)
1240
            {
1241
              if (!d1->u.pred.data->codes[d2->u.code])
1242
                return 0;
1243
            }
1244
 
1245
          /* Otherwise see if the predicates have any codes in common.  */
1246
          else if (d2->type == DT_pred && d2->u.pred.data)
1247
            {
1248
              bool common = false;
1249
              int c;
1250
 
1251
              for (c = 0; c < NUM_RTX_CODE; c++)
1252
                if (d1->u.pred.data->codes[c] && d2->u.pred.data->codes[c])
1253
                  {
1254
                    common = true;
1255
                    break;
1256
                  }
1257
 
1258
              if (!common)
1259
                return 0;
1260
            }
1261
        }
1262
    }
1263
 
1264
  /* Tests vs veclen may be known when strict equality is involved.  */
1265
  if (d1->type == DT_veclen && d2->type == DT_veclen_ge)
1266
    return d1->u.veclen >= d2->u.veclen;
1267
  if (d1->type == DT_veclen_ge && d2->type == DT_veclen)
1268
    return d2->u.veclen >= d1->u.veclen;
1269
 
1270
  return -1;
1271
}
1272
 
1273
/* A subroutine of maybe_both_true; examines all the tests for a given node.
1274
   Returns > 0 for "definitely both true" and < 0 for "maybe both true".  */
1275
 
1276
static int
1277
maybe_both_true_1 (struct decision_test *d1, struct decision_test *d2)
1278
{
1279
  struct decision_test *t1, *t2;
1280
 
1281
  /* A match_operand with no predicate can match anything.  Recognize
1282
     this by the existence of a lone DT_accept_op test.  */
1283
  if (d1->type == DT_accept_op || d2->type == DT_accept_op)
1284
    return 1;
1285
 
1286
  /* Eliminate pairs of tests while they can exactly match.  */
1287
  while (d1 && d2 && d1->type == d2->type)
1288
    {
1289
      if (maybe_both_true_2 (d1, d2) == 0)
1290
        return 0;
1291
      d1 = d1->next, d2 = d2->next;
1292
    }
1293
 
1294
  /* After that, consider all pairs.  */
1295
  for (t1 = d1; t1 ; t1 = t1->next)
1296
    for (t2 = d2; t2 ; t2 = t2->next)
1297
      if (maybe_both_true_2 (t1, t2) == 0)
1298
        return 0;
1299
 
1300
  return -1;
1301
}
1302
 
1303
/* Return 0 if we can prove that there is no RTL that can match both
1304
   D1 and D2.  Otherwise, return 1 (it may be that there is an RTL that
1305
   can match both or just that we couldn't prove there wasn't such an RTL).
1306
 
1307
   TOPLEVEL is nonzero if we are to only look at the top level and not
1308
   recursively descend.  */
1309
 
1310
static int
1311
maybe_both_true (struct decision *d1, struct decision *d2,
1312
                 int toplevel)
1313
{
1314
  struct decision *p1, *p2;
1315
  int cmp;
1316
 
1317
  /* Don't compare strings on the different positions in insn.  Doing so
1318
     is incorrect and results in false matches from constructs like
1319
 
1320
        [(set (subreg:HI (match_operand:SI "register_operand" "r") 0)
1321
              (subreg:HI (match_operand:SI "register_operand" "r") 0))]
1322
     vs
1323
        [(set (match_operand:HI "register_operand" "r")
1324
              (match_operand:HI "register_operand" "r"))]
1325
 
1326
     If we are presented with such, we are recursing through the remainder
1327
     of a node's success nodes (from the loop at the end of this function).
1328
     Skip forward until we come to a position that matches.
1329
 
1330
     Due to the way position strings are constructed, we know that iterating
1331
     forward from the lexically lower position (e.g. "00") will run into
1332
     the lexically higher position (e.g. "1") and not the other way around.
1333
     This saves a bit of effort.  */
1334
 
1335
  cmp = strcmp (d1->position, d2->position);
1336
  if (cmp != 0)
1337
    {
1338
      gcc_assert (!toplevel);
1339
 
1340
      /* If the d2->position was lexically lower, swap.  */
1341
      if (cmp > 0)
1342
        p1 = d1, d1 = d2, d2 = p1;
1343
 
1344
      if (d1->success.first == 0)
1345
        return 1;
1346
      for (p1 = d1->success.first; p1; p1 = p1->next)
1347
        if (maybe_both_true (p1, d2, 0))
1348
          return 1;
1349
 
1350
      return 0;
1351
    }
1352
 
1353
  /* Test the current level.  */
1354
  cmp = maybe_both_true_1 (d1->tests, d2->tests);
1355
  if (cmp >= 0)
1356
    return cmp;
1357
 
1358
  /* We can't prove that D1 and D2 cannot both be true.  If we are only
1359
     to check the top level, return 1.  Otherwise, see if we can prove
1360
     that all choices in both successors are mutually exclusive.  If
1361
     either does not have any successors, we can't prove they can't both
1362
     be true.  */
1363
 
1364
  if (toplevel || d1->success.first == 0 || d2->success.first == 0)
1365
    return 1;
1366
 
1367
  for (p1 = d1->success.first; p1; p1 = p1->next)
1368
    for (p2 = d2->success.first; p2; p2 = p2->next)
1369
      if (maybe_both_true (p1, p2, 0))
1370
        return 1;
1371
 
1372
  return 0;
1373
}
1374
 
1375
/* A subroutine of nodes_identical.  Examine two tests for equivalence.  */
1376
 
1377
static int
1378
nodes_identical_1 (struct decision_test *d1, struct decision_test *d2)
1379
{
1380
  switch (d1->type)
1381
    {
1382
    case DT_num_insns:
1383
      return d1->u.num_insns == d2->u.num_insns;
1384
 
1385
    case DT_mode:
1386
      return d1->u.mode == d2->u.mode;
1387
 
1388
    case DT_code:
1389
      return d1->u.code == d2->u.code;
1390
 
1391
    case DT_pred:
1392
      return (d1->u.pred.mode == d2->u.pred.mode
1393
              && strcmp (d1->u.pred.name, d2->u.pred.name) == 0);
1394
 
1395
    case DT_c_test:
1396
      return strcmp (d1->u.c_test, d2->u.c_test) == 0;
1397
 
1398
    case DT_veclen:
1399
    case DT_veclen_ge:
1400
      return d1->u.veclen == d2->u.veclen;
1401
 
1402
    case DT_dup:
1403
      return d1->u.dup == d2->u.dup;
1404
 
1405
    case DT_elt_zero_int:
1406
    case DT_elt_one_int:
1407
    case DT_elt_zero_wide:
1408
    case DT_elt_zero_wide_safe:
1409
      return d1->u.intval == d2->u.intval;
1410
 
1411
    case DT_accept_op:
1412
      return d1->u.opno == d2->u.opno;
1413
 
1414
    case DT_accept_insn:
1415
      /* Differences will be handled in merge_accept_insn.  */
1416
      return 1;
1417
 
1418
    default:
1419
      gcc_unreachable ();
1420
    }
1421
}
1422
 
1423
/* True iff the two nodes are identical (on one level only).  Due
1424
   to the way these lists are constructed, we shouldn't have to
1425
   consider different orderings on the tests.  */
1426
 
1427
static int
1428
nodes_identical (struct decision *d1, struct decision *d2)
1429
{
1430
  struct decision_test *t1, *t2;
1431
 
1432
  for (t1 = d1->tests, t2 = d2->tests; t1 && t2; t1 = t1->next, t2 = t2->next)
1433
    {
1434
      if (t1->type != t2->type)
1435
        return 0;
1436
      if (! nodes_identical_1 (t1, t2))
1437
        return 0;
1438
    }
1439
 
1440
  /* For success, they should now both be null.  */
1441
  if (t1 != t2)
1442
    return 0;
1443
 
1444
  /* Check that their subnodes are at the same position, as any one set
1445
     of sibling decisions must be at the same position.  Allowing this
1446
     requires complications to find_afterward and when change_state is
1447
     invoked.  */
1448
  if (d1->success.first
1449
      && d2->success.first
1450
      && strcmp (d1->success.first->position, d2->success.first->position))
1451
    return 0;
1452
 
1453
  return 1;
1454
}
1455
 
1456
/* A subroutine of merge_trees; given two nodes that have been declared
1457
   identical, cope with two insn accept states.  If they differ in the
1458
   number of clobbers, then the conflict was created by make_insn_sequence
1459
   and we can drop the with-clobbers version on the floor.  If both
1460
   nodes have no additional clobbers, we have found an ambiguity in the
1461
   source machine description.  */
1462
 
1463
static void
1464
merge_accept_insn (struct decision *oldd, struct decision *addd)
1465
{
1466
  struct decision_test *old, *add;
1467
 
1468
  for (old = oldd->tests; old; old = old->next)
1469
    if (old->type == DT_accept_insn)
1470
      break;
1471
  if (old == NULL)
1472
    return;
1473
 
1474
  for (add = addd->tests; add; add = add->next)
1475
    if (add->type == DT_accept_insn)
1476
      break;
1477
  if (add == NULL)
1478
    return;
1479
 
1480
  /* If one node is for a normal insn and the second is for the base
1481
     insn with clobbers stripped off, the second node should be ignored.  */
1482
 
1483
  if (old->u.insn.num_clobbers_to_add == 0
1484
      && add->u.insn.num_clobbers_to_add > 0)
1485
    {
1486
      /* Nothing to do here.  */
1487
    }
1488
  else if (old->u.insn.num_clobbers_to_add > 0
1489
           && add->u.insn.num_clobbers_to_add == 0)
1490
    {
1491
      /* In this case, replace OLD with ADD.  */
1492
      old->u.insn = add->u.insn;
1493
    }
1494
  else
1495
    {
1496
      message_with_line (add->u.insn.lineno, "`%s' matches `%s'",
1497
                         get_insn_name (add->u.insn.code_number),
1498
                         get_insn_name (old->u.insn.code_number));
1499
      message_with_line (old->u.insn.lineno, "previous definition of `%s'",
1500
                         get_insn_name (old->u.insn.code_number));
1501
      error_count++;
1502
    }
1503
}
1504
 
1505
/* Merge two decision trees OLDH and ADDH, modifying OLDH destructively.  */
1506
 
1507
static void
1508
merge_trees (struct decision_head *oldh, struct decision_head *addh)
1509
{
1510
  struct decision *next, *add;
1511
 
1512
  if (addh->first == 0)
1513
    return;
1514
  if (oldh->first == 0)
1515
    {
1516
      *oldh = *addh;
1517
      return;
1518
    }
1519
 
1520
  /* Trying to merge bits at different positions isn't possible.  */
1521
  gcc_assert (!strcmp (oldh->first->position, addh->first->position));
1522
 
1523
  for (add = addh->first; add ; add = next)
1524
    {
1525
      struct decision *old, *insert_before = NULL;
1526
 
1527
      next = add->next;
1528
 
1529
      /* The semantics of pattern matching state that the tests are
1530
         done in the order given in the MD file so that if an insn
1531
         matches two patterns, the first one will be used.  However,
1532
         in practice, most, if not all, patterns are unambiguous so
1533
         that their order is independent.  In that case, we can merge
1534
         identical tests and group all similar modes and codes together.
1535
 
1536
         Scan starting from the end of OLDH until we reach a point
1537
         where we reach the head of the list or where we pass a
1538
         pattern that could also be true if NEW is true.  If we find
1539
         an identical pattern, we can merge them.  Also, record the
1540
         last node that tests the same code and mode and the last one
1541
         that tests just the same mode.
1542
 
1543
         If we have no match, place NEW after the closest match we found.  */
1544
 
1545
      for (old = oldh->last; old; old = old->prev)
1546
        {
1547
          if (nodes_identical (old, add))
1548
            {
1549
              merge_accept_insn (old, add);
1550
              merge_trees (&old->success, &add->success);
1551
              goto merged_nodes;
1552
            }
1553
 
1554
          if (maybe_both_true (old, add, 0))
1555
            break;
1556
 
1557
          /* Insert the nodes in DT test type order, which is roughly
1558
             how expensive/important the test is.  Given that the tests
1559
             are also ordered within the list, examining the first is
1560
             sufficient.  */
1561
          if ((int) add->tests->type < (int) old->tests->type)
1562
            insert_before = old;
1563
        }
1564
 
1565
      if (insert_before == NULL)
1566
        {
1567
          add->next = NULL;
1568
          add->prev = oldh->last;
1569
          oldh->last->next = add;
1570
          oldh->last = add;
1571
        }
1572
      else
1573
        {
1574
          if ((add->prev = insert_before->prev) != NULL)
1575
            add->prev->next = add;
1576
          else
1577
            oldh->first = add;
1578
          add->next = insert_before;
1579
          insert_before->prev = add;
1580
        }
1581
 
1582
    merged_nodes:;
1583
    }
1584
}
1585
 
1586
/* Walk the tree looking for sub-nodes that perform common tests.
1587
   Factor out the common test into a new node.  This enables us
1588
   (depending on the test type) to emit switch statements later.  */
1589
 
1590
static void
1591
factor_tests (struct decision_head *head)
1592
{
1593
  struct decision *first, *next;
1594
 
1595
  for (first = head->first; first && first->next; first = next)
1596
    {
1597
      enum decision_type type;
1598
      struct decision *new_dec, *old_last;
1599
 
1600
      type = first->tests->type;
1601
      next = first->next;
1602
 
1603
      /* Want at least two compatible sequential nodes.  */
1604
      if (next->tests->type != type)
1605
        continue;
1606
 
1607
      /* Don't want all node types, just those we can turn into
1608
         switch statements.  */
1609
      if (type != DT_mode
1610
          && type != DT_code
1611
          && type != DT_veclen
1612
          && type != DT_elt_zero_int
1613
          && type != DT_elt_one_int
1614
          && type != DT_elt_zero_wide_safe)
1615
        continue;
1616
 
1617
      /* If we'd been performing more than one test, create a new node
1618
         below our first test.  */
1619
      if (first->tests->next != NULL)
1620
        {
1621
          new_dec = new_decision (first->position, &first->success);
1622
          new_dec->tests = first->tests->next;
1623
          first->tests->next = NULL;
1624
        }
1625
 
1626
      /* Crop the node tree off after our first test.  */
1627
      first->next = NULL;
1628
      old_last = head->last;
1629
      head->last = first;
1630
 
1631
      /* For each compatible test, adjust to perform only one test in
1632
         the top level node, then merge the node back into the tree.  */
1633
      do
1634
        {
1635
          struct decision_head h;
1636
 
1637
          if (next->tests->next != NULL)
1638
            {
1639
              new_dec = new_decision (next->position, &next->success);
1640
              new_dec->tests = next->tests->next;
1641
              next->tests->next = NULL;
1642
            }
1643
          new_dec = next;
1644
          next = next->next;
1645
          new_dec->next = NULL;
1646
          h.first = h.last = new_dec;
1647
 
1648
          merge_trees (head, &h);
1649
        }
1650
      while (next && next->tests->type == type);
1651
 
1652
      /* After we run out of compatible tests, graft the remaining nodes
1653
         back onto the tree.  */
1654
      if (next)
1655
        {
1656
          next->prev = head->last;
1657
          head->last->next = next;
1658
          head->last = old_last;
1659
        }
1660
    }
1661
 
1662
  /* Recurse.  */
1663
  for (first = head->first; first; first = first->next)
1664
    factor_tests (&first->success);
1665
}
1666
 
1667
/* After factoring, try to simplify the tests on any one node.
1668
   Tests that are useful for switch statements are recognizable
1669
   by having only a single test on a node -- we'll be manipulating
1670
   nodes with multiple tests:
1671
 
1672
   If we have mode tests or code tests that are redundant with
1673
   predicates, remove them.  */
1674
 
1675
static void
1676
simplify_tests (struct decision_head *head)
1677
{
1678
  struct decision *tree;
1679
 
1680
  for (tree = head->first; tree; tree = tree->next)
1681
    {
1682
      struct decision_test *a, *b;
1683
 
1684
      a = tree->tests;
1685
      b = a->next;
1686
      if (b == NULL)
1687
        continue;
1688
 
1689
      /* Find a predicate node.  */
1690
      while (b && b->type != DT_pred)
1691
        b = b->next;
1692
      if (b)
1693
        {
1694
          /* Due to how these tests are constructed, we don't even need
1695
             to check that the mode and code are compatible -- they were
1696
             generated from the predicate in the first place.  */
1697
          while (a->type == DT_mode || a->type == DT_code)
1698
            a = a->next;
1699
          tree->tests = a;
1700
        }
1701
    }
1702
 
1703
  /* Recurse.  */
1704
  for (tree = head->first; tree; tree = tree->next)
1705
    simplify_tests (&tree->success);
1706
}
1707
 
1708
/* Count the number of subnodes of HEAD.  If the number is high enough,
1709
   make the first node in HEAD start a separate subroutine in the C code
1710
   that is generated.  */
1711
 
1712
static int
1713
break_out_subroutines (struct decision_head *head, int initial)
1714
{
1715
  int size = 0;
1716
  struct decision *sub;
1717
 
1718
  for (sub = head->first; sub; sub = sub->next)
1719
    size += 1 + break_out_subroutines (&sub->success, 0);
1720
 
1721
  if (size > SUBROUTINE_THRESHOLD && ! initial)
1722
    {
1723
      head->first->subroutine_number = ++next_subroutine_number;
1724
      size = 1;
1725
    }
1726
  return size;
1727
}
1728
 
1729
/* For each node p, find the next alternative that might be true
1730
   when p is true.  */
1731
 
1732
static void
1733
find_afterward (struct decision_head *head, struct decision *real_afterward)
1734
{
1735
  struct decision *p, *q, *afterward;
1736
 
1737
  /* We can't propagate alternatives across subroutine boundaries.
1738
     This is not incorrect, merely a minor optimization loss.  */
1739
 
1740
  p = head->first;
1741
  afterward = (p->subroutine_number > 0 ? NULL : real_afterward);
1742
 
1743
  for ( ; p ; p = p->next)
1744
    {
1745
      /* Find the next node that might be true if this one fails.  */
1746
      for (q = p->next; q ; q = q->next)
1747
        if (maybe_both_true (p, q, 1))
1748
          break;
1749
 
1750
      /* If we reached the end of the list without finding one,
1751
         use the incoming afterward position.  */
1752
      if (!q)
1753
        q = afterward;
1754
      p->afterward = q;
1755
      if (q)
1756
        q->need_label = 1;
1757
    }
1758
 
1759
  /* Recurse.  */
1760
  for (p = head->first; p ; p = p->next)
1761
    if (p->success.first)
1762
      find_afterward (&p->success, p->afterward);
1763
 
1764
  /* When we are generating a subroutine, record the real afterward
1765
     position in the first node where write_tree can find it, and we
1766
     can do the right thing at the subroutine call site.  */
1767
  p = head->first;
1768
  if (p->subroutine_number > 0)
1769
    p->afterward = real_afterward;
1770
}
1771
 
1772
/* Assuming that the state of argument is denoted by OLDPOS, take whatever
1773
   actions are necessary to move to NEWPOS.  If we fail to move to the
1774
   new state, branch to node AFTERWARD if nonzero, otherwise return.
1775
 
1776
   Failure to move to the new state can only occur if we are trying to
1777
   match multiple insns and we try to step past the end of the stream.  */
1778
 
1779
static void
1780
change_state (const char *oldpos, const char *newpos, const char *indent)
1781
{
1782
  int odepth = strlen (oldpos);
1783
  int ndepth = strlen (newpos);
1784
  int depth;
1785
  int old_has_insn, new_has_insn;
1786
 
1787
  /* Pop up as many levels as necessary.  */
1788
  for (depth = odepth; strncmp (oldpos, newpos, depth) != 0; --depth)
1789
    continue;
1790
 
1791
  /* Hunt for the last [A-Z] in both strings.  */
1792
  for (old_has_insn = odepth - 1; old_has_insn >= 0; --old_has_insn)
1793
    if (ISUPPER (oldpos[old_has_insn]))
1794
      break;
1795
  for (new_has_insn = ndepth - 1; new_has_insn >= 0; --new_has_insn)
1796
    if (ISUPPER (newpos[new_has_insn]))
1797
      break;
1798
 
1799
  /* Go down to desired level.  */
1800
  while (depth < ndepth)
1801
    {
1802
      /* It's a different insn from the first one.  */
1803
      if (ISUPPER (newpos[depth]))
1804
        {
1805
          printf ("%stem = peep2_next_insn (%d);\n",
1806
                  indent, newpos[depth] - 'A');
1807
          printf ("%sx%d = PATTERN (tem);\n", indent, depth + 1);
1808
        }
1809
      else if (ISLOWER (newpos[depth]))
1810
        printf ("%sx%d = XVECEXP (x%d, 0, %d);\n",
1811
                indent, depth + 1, depth, newpos[depth] - 'a');
1812
      else
1813
        printf ("%sx%d = XEXP (x%d, %c);\n",
1814
                indent, depth + 1, depth, newpos[depth]);
1815
      ++depth;
1816
    }
1817
}
1818
 
1819
/* Print the enumerator constant for CODE -- the upcase version of
1820
   the name.  */
1821
 
1822
static void
1823
print_code (enum rtx_code code)
1824
{
1825
  const char *p;
1826
  for (p = GET_RTX_NAME (code); *p; p++)
1827
    putchar (TOUPPER (*p));
1828
}
1829
 
1830
/* Emit code to cross an afterward link -- change state and branch.  */
1831
 
1832
static void
1833
write_afterward (struct decision *start, struct decision *afterward,
1834
                 const char *indent)
1835
{
1836
  if (!afterward || start->subroutine_number > 0)
1837
    printf("%sgoto ret0;\n", indent);
1838
  else
1839
    {
1840
      change_state (start->position, afterward->position, indent);
1841
      printf ("%sgoto L%d;\n", indent, afterward->number);
1842
    }
1843
}
1844
 
1845
/* Emit a HOST_WIDE_INT as an integer constant expression.  We need to take
1846
   special care to avoid "decimal constant is so large that it is unsigned"
1847
   warnings in the resulting code.  */
1848
 
1849
static void
1850
print_host_wide_int (HOST_WIDE_INT val)
1851
{
1852
  HOST_WIDE_INT min = (unsigned HOST_WIDE_INT)1 << (HOST_BITS_PER_WIDE_INT-1);
1853
  if (val == min)
1854
    printf ("(" HOST_WIDE_INT_PRINT_DEC_C "-1)", val + 1);
1855
  else
1856
    printf (HOST_WIDE_INT_PRINT_DEC_C, val);
1857
}
1858
 
1859
/* Emit a switch statement, if possible, for an initial sequence of
1860
   nodes at START.  Return the first node yet untested.  */
1861
 
1862
static struct decision *
1863
write_switch (struct decision *start, int depth)
1864
{
1865
  struct decision *p = start;
1866
  enum decision_type type = p->tests->type;
1867
  struct decision *needs_label = NULL;
1868
 
1869
  /* If we have two or more nodes in sequence that test the same one
1870
     thing, we may be able to use a switch statement.  */
1871
 
1872
  if (!p->next
1873
      || p->tests->next
1874
      || p->next->tests->type != type
1875
      || p->next->tests->next
1876
      || nodes_identical_1 (p->tests, p->next->tests))
1877
    return p;
1878
 
1879
  /* DT_code is special in that we can do interesting things with
1880
     known predicates at the same time.  */
1881
  if (type == DT_code)
1882
    {
1883
      char codemap[NUM_RTX_CODE];
1884
      struct decision *ret;
1885
      RTX_CODE code;
1886
 
1887
      memset (codemap, 0, sizeof(codemap));
1888
 
1889
      printf ("  switch (GET_CODE (x%d))\n    {\n", depth);
1890
      code = p->tests->u.code;
1891
      do
1892
        {
1893
          if (p != start && p->need_label && needs_label == NULL)
1894
            needs_label = p;
1895
 
1896
          printf ("    case ");
1897
          print_code (code);
1898
          printf (":\n      goto L%d;\n", p->success.first->number);
1899
          p->success.first->need_label = 1;
1900
 
1901
          codemap[code] = 1;
1902
          p = p->next;
1903
        }
1904
      while (p
1905
             && ! p->tests->next
1906
             && p->tests->type == DT_code
1907
             && ! codemap[code = p->tests->u.code]);
1908
 
1909
      /* If P is testing a predicate that we know about and we haven't
1910
         seen any of the codes that are valid for the predicate, we can
1911
         write a series of "case" statement, one for each possible code.
1912
         Since we are already in a switch, these redundant tests are very
1913
         cheap and will reduce the number of predicates called.  */
1914
 
1915
      /* Note that while we write out cases for these predicates here,
1916
         we don't actually write the test here, as it gets kinda messy.
1917
         It is trivial to leave this to later by telling our caller that
1918
         we only processed the CODE tests.  */
1919
      if (needs_label != NULL)
1920
        ret = needs_label;
1921
      else
1922
        ret = p;
1923
 
1924
      while (p && p->tests->type == DT_pred && p->tests->u.pred.data)
1925
        {
1926
          const struct pred_data *data = p->tests->u.pred.data;
1927
          int c;
1928
 
1929
          for (c = 0; c < NUM_RTX_CODE; c++)
1930
            if (codemap[c] && data->codes[c])
1931
              goto pred_done;
1932
 
1933
          for (c = 0; c < NUM_RTX_CODE; c++)
1934
            if (data->codes[c])
1935
              {
1936
                fputs ("    case ", stdout);
1937
                print_code ((enum rtx_code) c);
1938
                fputs (":\n", stdout);
1939
                codemap[c] = 1;
1940
              }
1941
 
1942
          printf ("      goto L%d;\n", p->number);
1943
          p->need_label = 1;
1944
          p = p->next;
1945
        }
1946
 
1947
    pred_done:
1948
      /* Make the default case skip the predicates we managed to match.  */
1949
 
1950
      printf ("    default:\n");
1951
      if (p != ret)
1952
        {
1953
          if (p)
1954
            {
1955
              printf ("      goto L%d;\n", p->number);
1956
              p->need_label = 1;
1957
            }
1958
          else
1959
            write_afterward (start, start->afterward, "      ");
1960
        }
1961
      else
1962
        printf ("     break;\n");
1963
      printf ("   }\n");
1964
 
1965
      return ret;
1966
    }
1967
  else if (type == DT_mode
1968
           || type == DT_veclen
1969
           || type == DT_elt_zero_int
1970
           || type == DT_elt_one_int
1971
           || type == DT_elt_zero_wide_safe)
1972
    {
1973
      const char *indent = "";
1974
 
1975
      /* We cast switch parameter to integer, so we must ensure that the value
1976
         fits.  */
1977
      if (type == DT_elt_zero_wide_safe)
1978
        {
1979
          indent = "  ";
1980
          printf("  if ((int) XWINT (x%d, 0) == XWINT (x%d, 0))\n", depth, depth);
1981
        }
1982
      printf ("%s  switch (", indent);
1983
      switch (type)
1984
        {
1985
        case DT_mode:
1986
          printf ("GET_MODE (x%d)", depth);
1987
          break;
1988
        case DT_veclen:
1989
          printf ("XVECLEN (x%d, 0)", depth);
1990
          break;
1991
        case DT_elt_zero_int:
1992
          printf ("XINT (x%d, 0)", depth);
1993
          break;
1994
        case DT_elt_one_int:
1995
          printf ("XINT (x%d, 1)", depth);
1996
          break;
1997
        case DT_elt_zero_wide_safe:
1998
          /* Convert result of XWINT to int for portability since some C
1999
             compilers won't do it and some will.  */
2000
          printf ("(int) XWINT (x%d, 0)", depth);
2001
          break;
2002
        default:
2003
          gcc_unreachable ();
2004
        }
2005
      printf (")\n%s    {\n", indent);
2006
 
2007
      do
2008
        {
2009
          /* Merge trees will not unify identical nodes if their
2010
             sub-nodes are at different levels.  Thus we must check
2011
             for duplicate cases.  */
2012
          struct decision *q;
2013
          for (q = start; q != p; q = q->next)
2014
            if (nodes_identical_1 (p->tests, q->tests))
2015
              goto case_done;
2016
 
2017
          if (p != start && p->need_label && needs_label == NULL)
2018
            needs_label = p;
2019
 
2020
          printf ("%s    case ", indent);
2021
          switch (type)
2022
            {
2023
            case DT_mode:
2024
              printf ("%smode", GET_MODE_NAME (p->tests->u.mode));
2025
              break;
2026
            case DT_veclen:
2027
              printf ("%d", p->tests->u.veclen);
2028
              break;
2029
            case DT_elt_zero_int:
2030
            case DT_elt_one_int:
2031
            case DT_elt_zero_wide:
2032
            case DT_elt_zero_wide_safe:
2033
              print_host_wide_int (p->tests->u.intval);
2034
              break;
2035
            default:
2036
              gcc_unreachable ();
2037
            }
2038
          printf (":\n%s      goto L%d;\n", indent, p->success.first->number);
2039
          p->success.first->need_label = 1;
2040
 
2041
          p = p->next;
2042
        }
2043
      while (p && p->tests->type == type && !p->tests->next);
2044
 
2045
    case_done:
2046
      printf ("%s    default:\n%s      break;\n%s    }\n",
2047
              indent, indent, indent);
2048
 
2049
      return needs_label != NULL ? needs_label : p;
2050
    }
2051
  else
2052
    {
2053
      /* None of the other tests are amenable.  */
2054
      return p;
2055
    }
2056
}
2057
 
2058
/* Emit code for one test.  */
2059
 
2060
static void
2061
write_cond (struct decision_test *p, int depth,
2062
            enum routine_type subroutine_type)
2063
{
2064
  switch (p->type)
2065
    {
2066
    case DT_num_insns:
2067
      printf ("peep2_current_count >= %d", p->u.num_insns);
2068
      break;
2069
 
2070
    case DT_mode:
2071
      printf ("GET_MODE (x%d) == %smode", depth, GET_MODE_NAME (p->u.mode));
2072
      break;
2073
 
2074
    case DT_code:
2075
      printf ("GET_CODE (x%d) == ", depth);
2076
      print_code (p->u.code);
2077
      break;
2078
 
2079
    case DT_veclen:
2080
      printf ("XVECLEN (x%d, 0) == %d", depth, p->u.veclen);
2081
      break;
2082
 
2083
    case DT_elt_zero_int:
2084
      printf ("XINT (x%d, 0) == %d", depth, (int) p->u.intval);
2085
      break;
2086
 
2087
    case DT_elt_one_int:
2088
      printf ("XINT (x%d, 1) == %d", depth, (int) p->u.intval);
2089
      break;
2090
 
2091
    case DT_elt_zero_wide:
2092
    case DT_elt_zero_wide_safe:
2093
      printf ("XWINT (x%d, 0) == ", depth);
2094
      print_host_wide_int (p->u.intval);
2095
      break;
2096
 
2097
    case DT_const_int:
2098
      printf ("x%d == const_int_rtx[MAX_SAVED_CONST_INT + (%d)]",
2099
              depth, (int) p->u.intval);
2100
      break;
2101
 
2102
    case DT_veclen_ge:
2103
      printf ("XVECLEN (x%d, 0) >= %d", depth, p->u.veclen);
2104
      break;
2105
 
2106
    case DT_dup:
2107
      printf ("rtx_equal_p (x%d, operands[%d])", depth, p->u.dup);
2108
      break;
2109
 
2110
    case DT_pred:
2111
      printf ("%s (x%d, %smode)", p->u.pred.name, depth,
2112
              GET_MODE_NAME (p->u.pred.mode));
2113
      break;
2114
 
2115
    case DT_c_test:
2116
      print_c_condition (p->u.c_test);
2117
      break;
2118
 
2119
    case DT_accept_insn:
2120
      gcc_assert (subroutine_type == RECOG);
2121
      gcc_assert (p->u.insn.num_clobbers_to_add);
2122
      printf ("pnum_clobbers != NULL");
2123
      break;
2124
 
2125
    default:
2126
      gcc_unreachable ();
2127
    }
2128
}
2129
 
2130
/* Emit code for one action.  The previous tests have succeeded;
2131
   TEST is the last of the chain.  In the normal case we simply
2132
   perform a state change.  For the `accept' tests we must do more work.  */
2133
 
2134
static void
2135
write_action (struct decision *p, struct decision_test *test,
2136
              int depth, int uncond, struct decision *success,
2137
              enum routine_type subroutine_type)
2138
{
2139
  const char *indent;
2140
  int want_close = 0;
2141
 
2142
  if (uncond)
2143
    indent = "  ";
2144
  else if (test->type == DT_accept_op || test->type == DT_accept_insn)
2145
    {
2146
      fputs ("    {\n", stdout);
2147
      indent = "      ";
2148
      want_close = 1;
2149
    }
2150
  else
2151
    indent = "    ";
2152
 
2153
  if (test->type == DT_accept_op)
2154
    {
2155
      printf("%soperands[%d] = x%d;\n", indent, test->u.opno, depth);
2156
 
2157
      /* Only allow DT_accept_insn to follow.  */
2158
      if (test->next)
2159
        {
2160
          test = test->next;
2161
          gcc_assert (test->type == DT_accept_insn);
2162
        }
2163
    }
2164
 
2165
  /* Sanity check that we're now at the end of the list of tests.  */
2166
  gcc_assert (!test->next);
2167
 
2168
  if (test->type == DT_accept_insn)
2169
    {
2170
      switch (subroutine_type)
2171
        {
2172
        case RECOG:
2173
          if (test->u.insn.num_clobbers_to_add != 0)
2174
            printf ("%s*pnum_clobbers = %d;\n",
2175
                    indent, test->u.insn.num_clobbers_to_add);
2176
          printf ("%sreturn %d;  /* %s */\n", indent,
2177
                  test->u.insn.code_number,
2178
                  get_insn_name (test->u.insn.code_number));
2179
          break;
2180
 
2181
        case SPLIT:
2182
          printf ("%sreturn gen_split_%d (insn, operands);\n",
2183
                  indent, test->u.insn.code_number);
2184
          break;
2185
 
2186
        case PEEPHOLE2:
2187
          {
2188
            int match_len = 0, i;
2189
 
2190
            for (i = strlen (p->position) - 1; i >= 0; --i)
2191
              if (ISUPPER (p->position[i]))
2192
                {
2193
                  match_len = p->position[i] - 'A';
2194
                  break;
2195
                }
2196
            printf ("%s*_pmatch_len = %d;\n", indent, match_len);
2197
            printf ("%stem = gen_peephole2_%d (insn, operands);\n",
2198
                    indent, test->u.insn.code_number);
2199
            printf ("%sif (tem != 0)\n%s  return tem;\n", indent, indent);
2200
          }
2201
          break;
2202
 
2203
        default:
2204
          gcc_unreachable ();
2205
        }
2206
    }
2207
  else
2208
    {
2209
      printf("%sgoto L%d;\n", indent, success->number);
2210
      success->need_label = 1;
2211
    }
2212
 
2213
  if (want_close)
2214
    fputs ("    }\n", stdout);
2215
}
2216
 
2217
/* Return 1 if the test is always true and has no fallthru path.  Return -1
2218
   if the test does have a fallthru path, but requires that the condition be
2219
   terminated.  Otherwise return 0 for a normal test.  */
2220
/* ??? is_unconditional is a stupid name for a tri-state function.  */
2221
 
2222
static int
2223
is_unconditional (struct decision_test *t, enum routine_type subroutine_type)
2224
{
2225
  if (t->type == DT_accept_op)
2226
    return 1;
2227
 
2228
  if (t->type == DT_accept_insn)
2229
    {
2230
      switch (subroutine_type)
2231
        {
2232
        case RECOG:
2233
          return (t->u.insn.num_clobbers_to_add == 0);
2234
        case SPLIT:
2235
          return 1;
2236
        case PEEPHOLE2:
2237
          return -1;
2238
        default:
2239
          gcc_unreachable ();
2240
        }
2241
    }
2242
 
2243
  return 0;
2244
}
2245
 
2246
/* Emit code for one node -- the conditional and the accompanying action.
2247
   Return true if there is no fallthru path.  */
2248
 
2249
static int
2250
write_node (struct decision *p, int depth,
2251
            enum routine_type subroutine_type)
2252
{
2253
  struct decision_test *test, *last_test;
2254
  int uncond;
2255
 
2256
  /* Scan the tests and simplify comparisons against small
2257
     constants.  */
2258
  for (test = p->tests; test; test = test->next)
2259
    {
2260
      if (test->type == DT_code
2261
          && test->u.code == CONST_INT
2262
          && test->next
2263
          && test->next->type == DT_elt_zero_wide_safe
2264
          && -MAX_SAVED_CONST_INT <= test->next->u.intval
2265
          && test->next->u.intval <= MAX_SAVED_CONST_INT)
2266
        {
2267
          test->type = DT_const_int;
2268
          test->u.intval = test->next->u.intval;
2269
          test->next = test->next->next;
2270
        }
2271
    }
2272
 
2273
  last_test = test = p->tests;
2274
  uncond = is_unconditional (test, subroutine_type);
2275
  if (uncond == 0)
2276
    {
2277
      printf ("  if (");
2278
      write_cond (test, depth, subroutine_type);
2279
 
2280
      while ((test = test->next) != NULL)
2281
        {
2282
          last_test = test;
2283
          if (is_unconditional (test, subroutine_type))
2284
            break;
2285
 
2286
          printf ("\n      && ");
2287
          write_cond (test, depth, subroutine_type);
2288
        }
2289
 
2290
      printf (")\n");
2291
    }
2292
 
2293
  write_action (p, last_test, depth, uncond, p->success.first, subroutine_type);
2294
 
2295
  return uncond > 0;
2296
}
2297
 
2298
/* Emit code for all of the sibling nodes of HEAD.  */
2299
 
2300
static void
2301
write_tree_1 (struct decision_head *head, int depth,
2302
              enum routine_type subroutine_type)
2303
{
2304
  struct decision *p, *next;
2305
  int uncond = 0;
2306
 
2307
  for (p = head->first; p ; p = next)
2308
    {
2309
      /* The label for the first element was printed in write_tree.  */
2310
      if (p != head->first && p->need_label)
2311
        OUTPUT_LABEL (" ", p->number);
2312
 
2313
      /* Attempt to write a switch statement for a whole sequence.  */
2314
      next = write_switch (p, depth);
2315
      if (p != next)
2316
        uncond = 0;
2317
      else
2318
        {
2319
          /* Failed -- fall back and write one node.  */
2320
          uncond = write_node (p, depth, subroutine_type);
2321
          next = p->next;
2322
        }
2323
    }
2324
 
2325
  /* Finished with this chain.  Close a fallthru path by branching
2326
     to the afterward node.  */
2327
  if (! uncond)
2328
    write_afterward (head->last, head->last->afterward, "  ");
2329
}
2330
 
2331
/* Write out the decision tree starting at HEAD.  PREVPOS is the
2332
   position at the node that branched to this node.  */
2333
 
2334
static void
2335
write_tree (struct decision_head *head, const char *prevpos,
2336
            enum routine_type type, int initial)
2337
{
2338
  struct decision *p = head->first;
2339
 
2340
  putchar ('\n');
2341
  if (p->need_label)
2342
    OUTPUT_LABEL (" ", p->number);
2343
 
2344
  if (! initial && p->subroutine_number > 0)
2345
    {
2346
      static const char * const name_prefix[] = {
2347
          "recog", "split", "peephole2"
2348
      };
2349
 
2350
      static const char * const call_suffix[] = {
2351
          ", pnum_clobbers", "", ", _pmatch_len"
2352
      };
2353
 
2354
      /* This node has been broken out into a separate subroutine.
2355
         Call it, test the result, and branch accordingly.  */
2356
 
2357
      if (p->afterward)
2358
        {
2359
          printf ("  tem = %s_%d (x0, insn%s);\n",
2360
                  name_prefix[type], p->subroutine_number, call_suffix[type]);
2361
          if (IS_SPLIT (type))
2362
            printf ("  if (tem != 0)\n    return tem;\n");
2363
          else
2364
            printf ("  if (tem >= 0)\n    return tem;\n");
2365
 
2366
          change_state (p->position, p->afterward->position, "  ");
2367
          printf ("  goto L%d;\n", p->afterward->number);
2368
        }
2369
      else
2370
        {
2371
          printf ("  return %s_%d (x0, insn%s);\n",
2372
                  name_prefix[type], p->subroutine_number, call_suffix[type]);
2373
        }
2374
    }
2375
  else
2376
    {
2377
      int depth = strlen (p->position);
2378
 
2379
      change_state (prevpos, p->position, "  ");
2380
      write_tree_1 (head, depth, type);
2381
 
2382
      for (p = head->first; p; p = p->next)
2383
        if (p->success.first)
2384
          write_tree (&p->success, p->position, type, 0);
2385
    }
2386
}
2387
 
2388
/* Write out a subroutine of type TYPE to do comparisons starting at
2389
   node TREE.  */
2390
 
2391
static void
2392
write_subroutine (struct decision_head *head, enum routine_type type)
2393
{
2394
  int subfunction = head->first ? head->first->subroutine_number : 0;
2395
  const char *s_or_e;
2396
  char extension[32];
2397
  int i;
2398
 
2399
  s_or_e = subfunction ? "static " : "";
2400
 
2401
  if (subfunction)
2402
    sprintf (extension, "_%d", subfunction);
2403
  else if (type == RECOG)
2404
    extension[0] = '\0';
2405
  else
2406
    strcpy (extension, "_insns");
2407
 
2408
  switch (type)
2409
    {
2410
    case RECOG:
2411
      printf ("%sint\n\
2412
recog%s (rtx x0 ATTRIBUTE_UNUSED,\n\trtx insn ATTRIBUTE_UNUSED,\n\tint *pnum_clobbers ATTRIBUTE_UNUSED)\n", s_or_e, extension);
2413
      break;
2414
    case SPLIT:
2415
      printf ("%srtx\n\
2416
split%s (rtx x0 ATTRIBUTE_UNUSED, rtx insn ATTRIBUTE_UNUSED)\n",
2417
              s_or_e, extension);
2418
      break;
2419
    case PEEPHOLE2:
2420
      printf ("%srtx\n\
2421
peephole2%s (rtx x0 ATTRIBUTE_UNUSED,\n\trtx insn ATTRIBUTE_UNUSED,\n\tint *_pmatch_len ATTRIBUTE_UNUSED)\n",
2422
              s_or_e, extension);
2423
      break;
2424
    }
2425
 
2426
  printf ("{\n  rtx * const operands ATTRIBUTE_UNUSED = &recog_data.operand[0];\n");
2427
  for (i = 1; i <= max_depth; i++)
2428
    printf ("  rtx x%d ATTRIBUTE_UNUSED;\n", i);
2429
 
2430
  printf ("  %s tem ATTRIBUTE_UNUSED;\n", IS_SPLIT (type) ? "rtx" : "int");
2431
 
2432
  if (!subfunction)
2433
    printf ("  recog_data.insn = NULL_RTX;\n");
2434
 
2435
  if (head->first)
2436
    write_tree (head, "", type, 1);
2437
  else
2438
    printf ("  goto ret0;\n");
2439
 
2440
  printf (" ret0:\n  return %d;\n}\n\n", IS_SPLIT (type) ? 0 : -1);
2441
}
2442
 
2443
/* In break_out_subroutines, we discovered the boundaries for the
2444
   subroutines, but did not write them out.  Do so now.  */
2445
 
2446
static void
2447
write_subroutines (struct decision_head *head, enum routine_type type)
2448
{
2449
  struct decision *p;
2450
 
2451
  for (p = head->first; p ; p = p->next)
2452
    if (p->success.first)
2453
      write_subroutines (&p->success, type);
2454
 
2455
  if (head->first->subroutine_number > 0)
2456
    write_subroutine (head, type);
2457
}
2458
 
2459
/* Begin the output file.  */
2460
 
2461
static void
2462
write_header (void)
2463
{
2464
  puts ("\
2465
/* Generated automatically by the program `genrecog' from the target\n\
2466
   machine description file.  */\n\
2467
\n\
2468
#include \"config.h\"\n\
2469
#include \"system.h\"\n\
2470
#include \"coretypes.h\"\n\
2471
#include \"tm.h\"\n\
2472
#include \"rtl.h\"\n\
2473
#include \"tm_p.h\"\n\
2474
#include \"function.h\"\n\
2475
#include \"insn-config.h\"\n\
2476
#include \"recog.h\"\n\
2477
#include \"real.h\"\n\
2478
#include \"output.h\"\n\
2479
#include \"flags.h\"\n\
2480
#include \"hard-reg-set.h\"\n\
2481
#include \"resource.h\"\n\
2482
#include \"toplev.h\"\n\
2483
#include \"reload.h\"\n\
2484
#include \"regs.h\"\n\
2485
#include \"tm-constrs.h\"\n\
2486
\n");
2487
 
2488
  puts ("\n\
2489
/* `recog' contains a decision tree that recognizes whether the rtx\n\
2490
   X0 is a valid instruction.\n\
2491
\n\
2492
   recog returns -1 if the rtx is not valid.  If the rtx is valid, recog\n\
2493
   returns a nonnegative number which is the insn code number for the\n\
2494
   pattern that matched.  This is the same as the order in the machine\n\
2495
   description of the entry that matched.  This number can be used as an\n\
2496
   index into `insn_data' and other tables.\n");
2497
  puts ("\
2498
   The third argument to recog is an optional pointer to an int.  If\n\
2499
   present, recog will accept a pattern if it matches except for missing\n\
2500
   CLOBBER expressions at the end.  In that case, the value pointed to by\n\
2501
   the optional pointer will be set to the number of CLOBBERs that need\n\
2502
   to be added (it should be initialized to zero by the caller).  If it");
2503
  puts ("\
2504
   is set nonzero, the caller should allocate a PARALLEL of the\n\
2505
   appropriate size, copy the initial entries, and call add_clobbers\n\
2506
   (found in insn-emit.c) to fill in the CLOBBERs.\n\
2507
");
2508
 
2509
  puts ("\n\
2510
   The function split_insns returns 0 if the rtl could not\n\
2511
   be split or the split rtl as an INSN list if it can be.\n\
2512
\n\
2513
   The function peephole2_insns returns 0 if the rtl could not\n\
2514
   be matched. If there was a match, the new rtl is returned in an INSN list,\n\
2515
   and LAST_INSN will point to the last recognized insn in the old sequence.\n\
2516
*/\n\n");
2517
}
2518
 
2519
 
2520
/* Construct and return a sequence of decisions
2521
   that will recognize INSN.
2522
 
2523
   TYPE says what type of routine we are recognizing (RECOG or SPLIT).  */
2524
 
2525
static struct decision_head
2526
make_insn_sequence (rtx insn, enum routine_type type)
2527
{
2528
  rtx x;
2529
  const char *c_test = XSTR (insn, type == RECOG ? 2 : 1);
2530
  int truth = maybe_eval_c_test (c_test);
2531
  struct decision *last;
2532
  struct decision_test *test, **place;
2533
  struct decision_head head;
2534
  char c_test_pos[2];
2535
 
2536
  /* We should never see an insn whose C test is false at compile time.  */
2537
  gcc_assert (truth);
2538
 
2539
  c_test_pos[0] = '\0';
2540
  if (type == PEEPHOLE2)
2541
    {
2542
      int i, j;
2543
 
2544
      /* peephole2 gets special treatment:
2545
         - X always gets an outer parallel even if it's only one entry
2546
         - we remove all traces of outer-level match_scratch and match_dup
2547
           expressions here.  */
2548
      x = rtx_alloc (PARALLEL);
2549
      PUT_MODE (x, VOIDmode);
2550
      XVEC (x, 0) = rtvec_alloc (XVECLEN (insn, 0));
2551
      for (i = j = 0; i < XVECLEN (insn, 0); i++)
2552
        {
2553
          rtx tmp = XVECEXP (insn, 0, i);
2554
          if (GET_CODE (tmp) != MATCH_SCRATCH && GET_CODE (tmp) != MATCH_DUP)
2555
            {
2556
              XVECEXP (x, 0, j) = tmp;
2557
              j++;
2558
            }
2559
        }
2560
      XVECLEN (x, 0) = j;
2561
 
2562
      c_test_pos[0] = 'A' + j - 1;
2563
      c_test_pos[1] = '\0';
2564
    }
2565
  else if (XVECLEN (insn, type == RECOG) == 1)
2566
    x = XVECEXP (insn, type == RECOG, 0);
2567
  else
2568
    {
2569
      x = rtx_alloc (PARALLEL);
2570
      XVEC (x, 0) = XVEC (insn, type == RECOG);
2571
      PUT_MODE (x, VOIDmode);
2572
    }
2573
 
2574
  validate_pattern (x, insn, NULL_RTX, 0);
2575
 
2576
  memset(&head, 0, sizeof(head));
2577
  last = add_to_sequence (x, &head, "", type, 1);
2578
 
2579
  /* Find the end of the test chain on the last node.  */
2580
  for (test = last->tests; test->next; test = test->next)
2581
    continue;
2582
  place = &test->next;
2583
 
2584
  /* Skip the C test if it's known to be true at compile time.  */
2585
  if (truth == -1)
2586
    {
2587
      /* Need a new node if we have another test to add.  */
2588
      if (test->type == DT_accept_op)
2589
        {
2590
          last = new_decision (c_test_pos, &last->success);
2591
          place = &last->tests;
2592
        }
2593
      test = new_decision_test (DT_c_test, &place);
2594
      test->u.c_test = c_test;
2595
    }
2596
 
2597
  test = new_decision_test (DT_accept_insn, &place);
2598
  test->u.insn.code_number = next_insn_code;
2599
  test->u.insn.lineno = pattern_lineno;
2600
  test->u.insn.num_clobbers_to_add = 0;
2601
 
2602
  switch (type)
2603
    {
2604
    case RECOG:
2605
      /* If this is a DEFINE_INSN and X is a PARALLEL, see if it ends
2606
         with a group of CLOBBERs of (hard) registers or MATCH_SCRATCHes.
2607
         If so, set up to recognize the pattern without these CLOBBERs.  */
2608
 
2609
      if (GET_CODE (x) == PARALLEL)
2610
        {
2611
          int i;
2612
 
2613
          /* Find the last non-clobber in the parallel.  */
2614
          for (i = XVECLEN (x, 0); i > 0; i--)
2615
            {
2616
              rtx y = XVECEXP (x, 0, i - 1);
2617
              if (GET_CODE (y) != CLOBBER
2618
                  || (!REG_P (XEXP (y, 0))
2619
                      && GET_CODE (XEXP (y, 0)) != MATCH_SCRATCH))
2620
                break;
2621
            }
2622
 
2623
          if (i != XVECLEN (x, 0))
2624
            {
2625
              rtx new_rtx;
2626
              struct decision_head clobber_head;
2627
 
2628
              /* Build a similar insn without the clobbers.  */
2629
              if (i == 1)
2630
                new_rtx = XVECEXP (x, 0, 0);
2631
              else
2632
                {
2633
                  int j;
2634
 
2635
                  new_rtx = rtx_alloc (PARALLEL);
2636
                  XVEC (new_rtx, 0) = rtvec_alloc (i);
2637
                  for (j = i - 1; j >= 0; j--)
2638
                    XVECEXP (new_rtx, 0, j) = XVECEXP (x, 0, j);
2639
                }
2640
 
2641
              /* Recognize it.  */
2642
              memset (&clobber_head, 0, sizeof(clobber_head));
2643
              last = add_to_sequence (new_rtx, &clobber_head, "", type, 1);
2644
 
2645
              /* Find the end of the test chain on the last node.  */
2646
              for (test = last->tests; test->next; test = test->next)
2647
                continue;
2648
 
2649
              /* We definitely have a new test to add -- create a new
2650
                 node if needed.  */
2651
              place = &test->next;
2652
              if (test->type == DT_accept_op)
2653
                {
2654
                  last = new_decision ("", &last->success);
2655
                  place = &last->tests;
2656
                }
2657
 
2658
              /* Skip the C test if it's known to be true at compile
2659
                 time.  */
2660
              if (truth == -1)
2661
                {
2662
                  test = new_decision_test (DT_c_test, &place);
2663
                  test->u.c_test = c_test;
2664
                }
2665
 
2666
              test = new_decision_test (DT_accept_insn, &place);
2667
              test->u.insn.code_number = next_insn_code;
2668
              test->u.insn.lineno = pattern_lineno;
2669
              test->u.insn.num_clobbers_to_add = XVECLEN (x, 0) - i;
2670
 
2671
              merge_trees (&head, &clobber_head);
2672
            }
2673
        }
2674
      break;
2675
 
2676
    case SPLIT:
2677
      /* Define the subroutine we will call below and emit in genemit.  */
2678
      printf ("extern rtx gen_split_%d (rtx, rtx *);\n", next_insn_code);
2679
      break;
2680
 
2681
    case PEEPHOLE2:
2682
      /* Define the subroutine we will call below and emit in genemit.  */
2683
      printf ("extern rtx gen_peephole2_%d (rtx, rtx *);\n",
2684
              next_insn_code);
2685
      break;
2686
    }
2687
 
2688
  return head;
2689
}
2690
 
2691
static void
2692
process_tree (struct decision_head *head, enum routine_type subroutine_type)
2693
{
2694
  if (head->first == NULL)
2695
    {
2696
      /* We can elide peephole2_insns, but not recog or split_insns.  */
2697
      if (subroutine_type == PEEPHOLE2)
2698
        return;
2699
    }
2700
  else
2701
    {
2702
      factor_tests (head);
2703
 
2704
      next_subroutine_number = 0;
2705
      break_out_subroutines (head, 1);
2706
      find_afterward (head, NULL);
2707
 
2708
      /* We run this after find_afterward, because find_afterward needs
2709
         the redundant DT_mode tests on predicates to determine whether
2710
         two tests can both be true or not.  */
2711
      simplify_tests(head);
2712
 
2713
      write_subroutines (head, subroutine_type);
2714
    }
2715
 
2716
  write_subroutine (head, subroutine_type);
2717
}
2718
 
2719
extern int main (int, char **);
2720
 
2721
int
2722
main (int argc, char **argv)
2723
{
2724
  rtx desc;
2725
  struct decision_head recog_tree, split_tree, peephole2_tree, h;
2726
 
2727
  progname = "genrecog";
2728
 
2729
  memset (&recog_tree, 0, sizeof recog_tree);
2730
  memset (&split_tree, 0, sizeof split_tree);
2731
  memset (&peephole2_tree, 0, sizeof peephole2_tree);
2732
 
2733
  if (init_md_reader_args (argc, argv) != SUCCESS_EXIT_CODE)
2734
    return (FATAL_EXIT_CODE);
2735
 
2736
  next_insn_code = 0;
2737
 
2738
  write_header ();
2739
 
2740
  /* Read the machine description.  */
2741
 
2742
  while (1)
2743
    {
2744
      desc = read_md_rtx (&pattern_lineno, &next_insn_code);
2745
      if (desc == NULL)
2746
        break;
2747
 
2748
      switch (GET_CODE (desc))
2749
        {
2750
        case DEFINE_PREDICATE:
2751
        case DEFINE_SPECIAL_PREDICATE:
2752
          process_define_predicate (desc);
2753
          break;
2754
 
2755
        case DEFINE_INSN:
2756
          h = make_insn_sequence (desc, RECOG);
2757
          merge_trees (&recog_tree, &h);
2758
          break;
2759
 
2760
        case DEFINE_SPLIT:
2761
          h = make_insn_sequence (desc, SPLIT);
2762
          merge_trees (&split_tree, &h);
2763
          break;
2764
 
2765
        case DEFINE_PEEPHOLE2:
2766
          h = make_insn_sequence (desc, PEEPHOLE2);
2767
          merge_trees (&peephole2_tree, &h);
2768
 
2769
        default:
2770
          /* do nothing */;
2771
        }
2772
    }
2773
 
2774
  if (error_count || have_error)
2775
    return FATAL_EXIT_CODE;
2776
 
2777
  puts ("\n\n");
2778
 
2779
  process_tree (&recog_tree, RECOG);
2780
  process_tree (&split_tree, SPLIT);
2781
  process_tree (&peephole2_tree, PEEPHOLE2);
2782
 
2783
  fflush (stdout);
2784
  return (ferror (stdout) != 0 ? FATAL_EXIT_CODE : SUCCESS_EXIT_CODE);
2785
}
2786
 
2787
static void
2788
debug_decision_2 (struct decision_test *test)
2789
{
2790
  switch (test->type)
2791
    {
2792
    case DT_num_insns:
2793
      fprintf (stderr, "num_insns=%d", test->u.num_insns);
2794
      break;
2795
    case DT_mode:
2796
      fprintf (stderr, "mode=%s", GET_MODE_NAME (test->u.mode));
2797
      break;
2798
    case DT_code:
2799
      fprintf (stderr, "code=%s", GET_RTX_NAME (test->u.code));
2800
      break;
2801
    case DT_veclen:
2802
      fprintf (stderr, "veclen=%d", test->u.veclen);
2803
      break;
2804
    case DT_elt_zero_int:
2805
      fprintf (stderr, "elt0_i=%d", (int) test->u.intval);
2806
      break;
2807
    case DT_elt_one_int:
2808
      fprintf (stderr, "elt1_i=%d", (int) test->u.intval);
2809
      break;
2810
    case DT_elt_zero_wide:
2811
      fprintf (stderr, "elt0_w=" HOST_WIDE_INT_PRINT_DEC, test->u.intval);
2812
      break;
2813
    case DT_elt_zero_wide_safe:
2814
      fprintf (stderr, "elt0_ws=" HOST_WIDE_INT_PRINT_DEC, test->u.intval);
2815
      break;
2816
    case DT_veclen_ge:
2817
      fprintf (stderr, "veclen>=%d", test->u.veclen);
2818
      break;
2819
    case DT_dup:
2820
      fprintf (stderr, "dup=%d", test->u.dup);
2821
      break;
2822
    case DT_pred:
2823
      fprintf (stderr, "pred=(%s,%s)",
2824
               test->u.pred.name, GET_MODE_NAME(test->u.pred.mode));
2825
      break;
2826
    case DT_c_test:
2827
      {
2828
        char sub[16+4];
2829
        strncpy (sub, test->u.c_test, sizeof(sub));
2830
        memcpy (sub+16, "...", 4);
2831
        fprintf (stderr, "c_test=\"%s\"", sub);
2832
      }
2833
      break;
2834
    case DT_accept_op:
2835
      fprintf (stderr, "A_op=%d", test->u.opno);
2836
      break;
2837
    case DT_accept_insn:
2838
      fprintf (stderr, "A_insn=(%d,%d)",
2839
               test->u.insn.code_number, test->u.insn.num_clobbers_to_add);
2840
      break;
2841
 
2842
    default:
2843
      gcc_unreachable ();
2844
    }
2845
}
2846
 
2847
static void
2848
debug_decision_1 (struct decision *d, int indent)
2849
{
2850
  int i;
2851
  struct decision_test *test;
2852
 
2853
  if (d == NULL)
2854
    {
2855
      for (i = 0; i < indent; ++i)
2856
        putc (' ', stderr);
2857
      fputs ("(nil)\n", stderr);
2858
      return;
2859
    }
2860
 
2861
  for (i = 0; i < indent; ++i)
2862
    putc (' ', stderr);
2863
 
2864
  putc ('{', stderr);
2865
  test = d->tests;
2866
  if (test)
2867
    {
2868
      debug_decision_2 (test);
2869
      while ((test = test->next) != NULL)
2870
        {
2871
          fputs (" + ", stderr);
2872
          debug_decision_2 (test);
2873
        }
2874
    }
2875
  fprintf (stderr, "} %d n %d a %d\n", d->number,
2876
           (d->next ? d->next->number : -1),
2877
           (d->afterward ? d->afterward->number : -1));
2878
}
2879
 
2880
static void
2881
debug_decision_0 (struct decision *d, int indent, int maxdepth)
2882
{
2883
  struct decision *n;
2884
  int i;
2885
 
2886
  if (maxdepth < 0)
2887
    return;
2888
  if (d == NULL)
2889
    {
2890
      for (i = 0; i < indent; ++i)
2891
        putc (' ', stderr);
2892
      fputs ("(nil)\n", stderr);
2893
      return;
2894
    }
2895
 
2896
  debug_decision_1 (d, indent);
2897
  for (n = d->success.first; n ; n = n->next)
2898
    debug_decision_0 (n, indent + 2, maxdepth - 1);
2899
}
2900
 
2901
void
2902
debug_decision (struct decision *d)
2903
{
2904
  debug_decision_0 (d, 0, 1000000);
2905
}
2906
 
2907
void
2908
debug_decision_list (struct decision *d)
2909
{
2910
  while (d)
2911
    {
2912
      debug_decision_0 (d, 0, 0);
2913
      d = d->next;
2914
    }
2915
}

powered by: WebSVN 2.1.0

© copyright 1999-2024 OpenCores.org, equivalent to Oliscience, all rights reserved. OpenCores®, registered trademark.