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[/] [openrisc/] [trunk/] [gnu-src/] [gdb-7.2/] [gdb/] [macroexp.c] - Blame information for rev 631

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1 330 jeremybenn
/* C preprocessor macro expansion for GDB.
2
   Copyright (C) 2002, 2007, 2008, 2009, 2010 Free Software Foundation, Inc.
3
   Contributed by Red Hat, Inc.
4
 
5
   This file is part of GDB.
6
 
7
   This program is free software; you can redistribute it and/or modify
8
   it under the terms of the GNU General Public License as published by
9
   the Free Software Foundation; either version 3 of the License, or
10
   (at your option) any later version.
11
 
12
   This program is distributed in the hope that it will be useful,
13
   but WITHOUT ANY WARRANTY; without even the implied warranty of
14
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
15
   GNU General Public License for more details.
16
 
17
   You should have received a copy of the GNU General Public License
18
   along with this program.  If not, see <http://www.gnu.org/licenses/>.  */
19
 
20
#include "defs.h"
21
#include "gdb_obstack.h"
22
#include "bcache.h"
23
#include "macrotab.h"
24
#include "macroexp.h"
25
#include "gdb_assert.h"
26
#include "c-lang.h"
27
 
28
 
29
 
30
/* A resizeable, substringable string type.  */
31
 
32
 
33
/* A string type that we can resize, quickly append to, and use to
34
   refer to substrings of other strings.  */
35
struct macro_buffer
36
{
37
  /* An array of characters.  The first LEN bytes are the real text,
38
     but there are SIZE bytes allocated to the array.  If SIZE is
39
     zero, then this doesn't point to a malloc'ed block.  If SHARED is
40
     non-zero, then this buffer is actually a pointer into some larger
41
     string, and we shouldn't append characters to it, etc.  Because
42
     of sharing, we can't assume in general that the text is
43
     null-terminated.  */
44
  char *text;
45
 
46
  /* The number of characters in the string.  */
47
  int len;
48
 
49
  /* The number of characters allocated to the string.  If SHARED is
50
     non-zero, this is meaningless; in this case, we set it to zero so
51
     that any "do we have room to append something?" tests will fail,
52
     so we don't always have to check SHARED before using this field.  */
53
  int size;
54
 
55
  /* Zero if TEXT can be safely realloc'ed (i.e., it's its own malloc
56
     block).  Non-zero if TEXT is actually pointing into the middle of
57
     some other block, and we shouldn't reallocate it.  */
58
  int shared;
59
 
60
  /* For detecting token splicing.
61
 
62
     This is the index in TEXT of the first character of the token
63
     that abuts the end of TEXT.  If TEXT contains no tokens, then we
64
     set this equal to LEN.  If TEXT ends in whitespace, then there is
65
     no token abutting the end of TEXT (it's just whitespace), and
66
     again, we set this equal to LEN.  We set this to -1 if we don't
67
     know the nature of TEXT.  */
68
  int last_token;
69
 
70
  /* If this buffer is holding the result from get_token, then this
71
     is non-zero if it is an identifier token, zero otherwise.  */
72
  int is_identifier;
73
};
74
 
75
 
76
/* Set the macro buffer *B to the empty string, guessing that its
77
   final contents will fit in N bytes.  (It'll get resized if it
78
   doesn't, so the guess doesn't have to be right.)  Allocate the
79
   initial storage with xmalloc.  */
80
static void
81
init_buffer (struct macro_buffer *b, int n)
82
{
83
  b->size = n;
84
  if (n > 0)
85
    b->text = (char *) xmalloc (n);
86
  else
87
    b->text = NULL;
88
  b->len = 0;
89
  b->shared = 0;
90
  b->last_token = -1;
91
}
92
 
93
 
94
/* Set the macro buffer *BUF to refer to the LEN bytes at ADDR, as a
95
   shared substring.  */
96
static void
97
init_shared_buffer (struct macro_buffer *buf, char *addr, int len)
98
{
99
  buf->text = addr;
100
  buf->len = len;
101
  buf->shared = 1;
102
  buf->size = 0;
103
  buf->last_token = -1;
104
}
105
 
106
 
107
/* Free the text of the buffer B.  Raise an error if B is shared.  */
108
static void
109
free_buffer (struct macro_buffer *b)
110
{
111
  gdb_assert (! b->shared);
112
  if (b->size)
113
    xfree (b->text);
114
}
115
 
116
 
117
/* A cleanup function for macro buffers.  */
118
static void
119
cleanup_macro_buffer (void *untyped_buf)
120
{
121
  free_buffer ((struct macro_buffer *) untyped_buf);
122
}
123
 
124
 
125
/* Resize the buffer B to be at least N bytes long.  Raise an error if
126
   B shouldn't be resized.  */
127
static void
128
resize_buffer (struct macro_buffer *b, int n)
129
{
130
  /* We shouldn't be trying to resize shared strings.  */
131
  gdb_assert (! b->shared);
132
 
133
  if (b->size == 0)
134
    b->size = n;
135
  else
136
    while (b->size <= n)
137
      b->size *= 2;
138
 
139
  b->text = xrealloc (b->text, b->size);
140
}
141
 
142
 
143
/* Append the character C to the buffer B.  */
144
static void
145
appendc (struct macro_buffer *b, int c)
146
{
147
  int new_len = b->len + 1;
148
 
149
  if (new_len > b->size)
150
    resize_buffer (b, new_len);
151
 
152
  b->text[b->len] = c;
153
  b->len = new_len;
154
}
155
 
156
 
157
/* Append the LEN bytes at ADDR to the buffer B.  */
158
static void
159
appendmem (struct macro_buffer *b, char *addr, int len)
160
{
161
  int new_len = b->len + len;
162
 
163
  if (new_len > b->size)
164
    resize_buffer (b, new_len);
165
 
166
  memcpy (b->text + b->len, addr, len);
167
  b->len = new_len;
168
}
169
 
170
 
171
 
172
/* Recognizing preprocessor tokens.  */
173
 
174
 
175
int
176
macro_is_whitespace (int c)
177
{
178
  return (c == ' '
179
          || c == '\t'
180
          || c == '\n'
181
          || c == '\v'
182
          || c == '\f');
183
}
184
 
185
 
186
int
187
macro_is_digit (int c)
188
{
189
  return ('0' <= c && c <= '9');
190
}
191
 
192
 
193
int
194
macro_is_identifier_nondigit (int c)
195
{
196
  return (c == '_'
197
          || ('a' <= c && c <= 'z')
198
          || ('A' <= c && c <= 'Z'));
199
}
200
 
201
 
202
static void
203
set_token (struct macro_buffer *tok, char *start, char *end)
204
{
205
  init_shared_buffer (tok, start, end - start);
206
  tok->last_token = 0;
207
 
208
  /* Presumed; get_identifier may overwrite this. */
209
  tok->is_identifier = 0;
210
}
211
 
212
 
213
static int
214
get_comment (struct macro_buffer *tok, char *p, char *end)
215
{
216
  if (p + 2 > end)
217
    return 0;
218
  else if (p[0] == '/'
219
           && p[1] == '*')
220
    {
221
      char *tok_start = p;
222
 
223
      p += 2;
224
 
225
      for (; p < end; p++)
226
        if (p + 2 <= end
227
            && p[0] == '*'
228
            && p[1] == '/')
229
          {
230
            p += 2;
231
            set_token (tok, tok_start, p);
232
            return 1;
233
          }
234
 
235
      error (_("Unterminated comment in macro expansion."));
236
    }
237
  else if (p[0] == '/'
238
           && p[1] == '/')
239
    {
240
      char *tok_start = p;
241
 
242
      p += 2;
243
      for (; p < end; p++)
244
        if (*p == '\n')
245
          break;
246
 
247
      set_token (tok, tok_start, p);
248
      return 1;
249
    }
250
  else
251
    return 0;
252
}
253
 
254
 
255
static int
256
get_identifier (struct macro_buffer *tok, char *p, char *end)
257
{
258
  if (p < end
259
      && macro_is_identifier_nondigit (*p))
260
    {
261
      char *tok_start = p;
262
 
263
      while (p < end
264
             && (macro_is_identifier_nondigit (*p)
265
                 || macro_is_digit (*p)))
266
        p++;
267
 
268
      set_token (tok, tok_start, p);
269
      tok->is_identifier = 1;
270
      return 1;
271
    }
272
  else
273
    return 0;
274
}
275
 
276
 
277
static int
278
get_pp_number (struct macro_buffer *tok, char *p, char *end)
279
{
280
  if (p < end
281
      && (macro_is_digit (*p)
282
          || (*p == '.'
283
              && p + 2 <= end
284
              && macro_is_digit (p[1]))))
285
    {
286
      char *tok_start = p;
287
 
288
      while (p < end)
289
        {
290
          if (p + 2 <= end
291
              && strchr ("eEpP", *p)
292
              && (p[1] == '+' || p[1] == '-'))
293
            p += 2;
294
          else if (macro_is_digit (*p)
295
                   || macro_is_identifier_nondigit (*p)
296
                   || *p == '.')
297
            p++;
298
          else
299
            break;
300
        }
301
 
302
      set_token (tok, tok_start, p);
303
      return 1;
304
    }
305
  else
306
    return 0;
307
}
308
 
309
 
310
 
311
/* If the text starting at P going up to (but not including) END
312
   starts with a character constant, set *TOK to point to that
313
   character constant, and return 1.  Otherwise, return zero.
314
   Signal an error if it contains a malformed or incomplete character
315
   constant.  */
316
static int
317
get_character_constant (struct macro_buffer *tok, char *p, char *end)
318
{
319
  /* ISO/IEC 9899:1999 (E)  Section 6.4.4.4  paragraph 1
320
     But of course, what really matters is that we handle it the same
321
     way GDB's C/C++ lexer does.  So we call parse_escape in utils.c
322
     to handle escape sequences.  */
323
  if ((p + 1 <= end && *p == '\'')
324
      || (p + 2 <= end
325
          && (p[0] == 'L' || p[0] == 'u' || p[0] == 'U')
326
          && p[1] == '\''))
327
    {
328
      char *tok_start = p;
329
      char *body_start;
330
      int char_count = 0;
331
 
332
      if (*p == '\'')
333
        p++;
334
      else if (*p == 'L' || *p == 'u' || *p == 'U')
335
        p += 2;
336
      else
337
        gdb_assert (0);
338
 
339
      body_start = p;
340
      for (;;)
341
        {
342
          if (p >= end)
343
            error (_("Unmatched single quote."));
344
          else if (*p == '\'')
345
            {
346
              if (!char_count)
347
                error (_("A character constant must contain at least one "
348
                       "character."));
349
              p++;
350
              break;
351
            }
352
          else if (*p == '\\')
353
            {
354
              p++;
355
              char_count += c_parse_escape (&p, NULL);
356
            }
357
          else
358
            {
359
              p++;
360
              char_count++;
361
            }
362
        }
363
 
364
      set_token (tok, tok_start, p);
365
      return 1;
366
    }
367
  else
368
    return 0;
369
}
370
 
371
 
372
/* If the text starting at P going up to (but not including) END
373
   starts with a string literal, set *TOK to point to that string
374
   literal, and return 1.  Otherwise, return zero.  Signal an error if
375
   it contains a malformed or incomplete string literal.  */
376
static int
377
get_string_literal (struct macro_buffer *tok, char *p, char *end)
378
{
379
  if ((p + 1 <= end
380
       && *p == '"')
381
      || (p + 2 <= end
382
          && (p[0] == 'L' || p[0] == 'u' || p[0] == 'U')
383
          && p[1] == '"'))
384
    {
385
      char *tok_start = p;
386
 
387
      if (*p == '"')
388
        p++;
389
      else if (*p == 'L' || *p == 'u' || *p == 'U')
390
        p += 2;
391
      else
392
        gdb_assert (0);
393
 
394
      for (;;)
395
        {
396
          if (p >= end)
397
            error (_("Unterminated string in expression."));
398
          else if (*p == '"')
399
            {
400
              p++;
401
              break;
402
            }
403
          else if (*p == '\n')
404
            error (_("Newline characters may not appear in string "
405
                   "constants."));
406
          else if (*p == '\\')
407
            {
408
              p++;
409
              c_parse_escape (&p, NULL);
410
            }
411
          else
412
            p++;
413
        }
414
 
415
      set_token (tok, tok_start, p);
416
      return 1;
417
    }
418
  else
419
    return 0;
420
}
421
 
422
 
423
static int
424
get_punctuator (struct macro_buffer *tok, char *p, char *end)
425
{
426
  /* Here, speed is much less important than correctness and clarity.  */
427
 
428
  /* ISO/IEC 9899:1999 (E)  Section 6.4.6  Paragraph 1.
429
     Note that this table is ordered in a special way.  A punctuator
430
     which is a prefix of another punctuator must appear after its
431
     "extension".  Otherwise, the wrong token will be returned.  */
432
  static const char * const punctuators[] = {
433
    "[", "]", "(", ")", "{", "}", "?", ";", ",", "~",
434
    "...", ".",
435
    "->", "--", "-=", "-",
436
    "++", "+=", "+",
437
    "*=", "*",
438
    "!=", "!",
439
    "&&", "&=", "&",
440
    "/=", "/",
441
    "%>", "%:%:", "%:", "%=", "%",
442
    "^=", "^",
443
    "##", "#",
444
    ":>", ":",
445
    "||", "|=", "|",
446
    "<<=", "<<", "<=", "<:", "<%", "<",
447
    ">>=", ">>", ">=", ">",
448
    "==", "=",
449
 
450
  };
451
 
452
  int i;
453
 
454
  if (p + 1 <= end)
455
    {
456
      for (i = 0; punctuators[i]; i++)
457
        {
458
          const char *punctuator = punctuators[i];
459
 
460
          if (p[0] == punctuator[0])
461
            {
462
              int len = strlen (punctuator);
463
 
464
              if (p + len <= end
465
                  && ! memcmp (p, punctuator, len))
466
                {
467
                  set_token (tok, p, p + len);
468
                  return 1;
469
                }
470
            }
471
        }
472
    }
473
 
474
  return 0;
475
}
476
 
477
 
478
/* Peel the next preprocessor token off of SRC, and put it in TOK.
479
   Mutate TOK to refer to the first token in SRC, and mutate SRC to
480
   refer to the text after that token.  SRC must be a shared buffer;
481
   the resulting TOK will be shared, pointing into the same string SRC
482
   does.  Initialize TOK's last_token field.  Return non-zero if we
483
   succeed, or 0 if we didn't find any more tokens in SRC.  */
484
static int
485
get_token (struct macro_buffer *tok,
486
           struct macro_buffer *src)
487
{
488
  char *p = src->text;
489
  char *end = p + src->len;
490
 
491
  gdb_assert (src->shared);
492
 
493
  /* From the ISO C standard, ISO/IEC 9899:1999 (E), section 6.4:
494
 
495
     preprocessing-token:
496
         header-name
497
         identifier
498
         pp-number
499
         character-constant
500
         string-literal
501
         punctuator
502
         each non-white-space character that cannot be one of the above
503
 
504
     We don't have to deal with header-name tokens, since those can
505
     only occur after a #include, which we will never see.  */
506
 
507
  while (p < end)
508
    if (macro_is_whitespace (*p))
509
      p++;
510
    else if (get_comment (tok, p, end))
511
      p += tok->len;
512
    else if (get_pp_number (tok, p, end)
513
             || get_character_constant (tok, p, end)
514
             || get_string_literal (tok, p, end)
515
             /* Note: the grammar in the standard seems to be
516
                ambiguous: L'x' can be either a wide character
517
                constant, or an identifier followed by a normal
518
                character constant.  By trying `get_identifier' after
519
                we try get_character_constant and get_string_literal,
520
                we give the wide character syntax precedence.  Now,
521
                since GDB doesn't handle wide character constants
522
                anyway, is this the right thing to do?  */
523
             || get_identifier (tok, p, end)
524
             || get_punctuator (tok, p, end))
525
      {
526
        /* How many characters did we consume, including whitespace?  */
527
        int consumed = p - src->text + tok->len;
528
 
529
        src->text += consumed;
530
        src->len -= consumed;
531
        return 1;
532
      }
533
    else
534
      {
535
        /* We have found a "non-whitespace character that cannot be
536
           one of the above."  Make a token out of it.  */
537
        int consumed;
538
 
539
        set_token (tok, p, p + 1);
540
        consumed = p - src->text + tok->len;
541
        src->text += consumed;
542
        src->len -= consumed;
543
        return 1;
544
      }
545
 
546
  return 0;
547
}
548
 
549
 
550
 
551
/* Appending token strings, with and without splicing  */
552
 
553
 
554
/* Append the macro buffer SRC to the end of DEST, and ensure that
555
   doing so doesn't splice the token at the end of SRC with the token
556
   at the beginning of DEST.  SRC and DEST must have their last_token
557
   fields set.  Upon return, DEST's last_token field is set correctly.
558
 
559
   For example:
560
 
561
   If DEST is "(" and SRC is "y", then we can return with
562
   DEST set to "(y" --- we've simply appended the two buffers.
563
 
564
   However, if DEST is "x" and SRC is "y", then we must not return
565
   with DEST set to "xy" --- that would splice the two tokens "x" and
566
   "y" together to make a single token "xy".  However, it would be
567
   fine to return with DEST set to "x y".  Similarly, "<" and "<" must
568
   yield "< <", not "<<", etc.  */
569
static void
570
append_tokens_without_splicing (struct macro_buffer *dest,
571
                                struct macro_buffer *src)
572
{
573
  int original_dest_len = dest->len;
574
  struct macro_buffer dest_tail, new_token;
575
 
576
  gdb_assert (src->last_token != -1);
577
  gdb_assert (dest->last_token != -1);
578
 
579
  /* First, just try appending the two, and call get_token to see if
580
     we got a splice.  */
581
  appendmem (dest, src->text, src->len);
582
 
583
  /* If DEST originally had no token abutting its end, then we can't
584
     have spliced anything, so we're done.  */
585
  if (dest->last_token == original_dest_len)
586
    {
587
      dest->last_token = original_dest_len + src->last_token;
588
      return;
589
    }
590
 
591
  /* Set DEST_TAIL to point to the last token in DEST, followed by
592
     all the stuff we just appended.  */
593
  init_shared_buffer (&dest_tail,
594
                      dest->text + dest->last_token,
595
                      dest->len - dest->last_token);
596
 
597
  /* Re-parse DEST's last token.  We know that DEST used to contain
598
     at least one token, so if it doesn't contain any after the
599
     append, then we must have spliced "/" and "*" or "/" and "/" to
600
     make a comment start.  (Just for the record, I got this right
601
     the first time.  This is not a bug fix.)  */
602
  if (get_token (&new_token, &dest_tail)
603
      && (new_token.text + new_token.len
604
          == dest->text + original_dest_len))
605
    {
606
      /* No splice, so we're done.  */
607
      dest->last_token = original_dest_len + src->last_token;
608
      return;
609
    }
610
 
611
  /* Okay, a simple append caused a splice.  Let's chop dest back to
612
     its original length and try again, but separate the texts with a
613
     space.  */
614
  dest->len = original_dest_len;
615
  appendc (dest, ' ');
616
  appendmem (dest, src->text, src->len);
617
 
618
  init_shared_buffer (&dest_tail,
619
                      dest->text + dest->last_token,
620
                      dest->len - dest->last_token);
621
 
622
  /* Try to re-parse DEST's last token, as above.  */
623
  if (get_token (&new_token, &dest_tail)
624
      && (new_token.text + new_token.len
625
          == dest->text + original_dest_len))
626
    {
627
      /* No splice, so we're done.  */
628
      dest->last_token = original_dest_len + 1 + src->last_token;
629
      return;
630
    }
631
 
632
  /* As far as I know, there's no case where inserting a space isn't
633
     enough to prevent a splice.  */
634
  internal_error (__FILE__, __LINE__,
635
                  _("unable to avoid splicing tokens during macro expansion"));
636
}
637
 
638
/* Stringify an argument, and insert it into DEST.  ARG is the text to
639
   stringify; it is LEN bytes long.  */
640
 
641
static void
642
stringify (struct macro_buffer *dest, char *arg, int len)
643
{
644
  /* Trim initial whitespace from ARG.  */
645
  while (len > 0 && macro_is_whitespace (*arg))
646
    {
647
      ++arg;
648
      --len;
649
    }
650
 
651
  /* Trim trailing whitespace from ARG.  */
652
  while (len > 0 && macro_is_whitespace (arg[len - 1]))
653
    --len;
654
 
655
  /* Insert the string.  */
656
  appendc (dest, '"');
657
  while (len > 0)
658
    {
659
      /* We could try to handle strange cases here, like control
660
         characters, but there doesn't seem to be much point.  */
661
      if (macro_is_whitespace (*arg))
662
        {
663
          /* Replace a sequence of whitespace with a single space.  */
664
          appendc (dest, ' ');
665
          while (len > 1 && macro_is_whitespace (arg[1]))
666
            {
667
              ++arg;
668
              --len;
669
            }
670
        }
671
      else if (*arg == '\\' || *arg == '"')
672
        {
673
          appendc (dest, '\\');
674
          appendc (dest, *arg);
675
        }
676
      else
677
        appendc (dest, *arg);
678
      ++arg;
679
      --len;
680
    }
681
  appendc (dest, '"');
682
  dest->last_token = dest->len;
683
}
684
 
685
 
686
/* Expanding macros!  */
687
 
688
 
689
/* A singly-linked list of the names of the macros we are currently
690
   expanding --- for detecting expansion loops.  */
691
struct macro_name_list {
692
  const char *name;
693
  struct macro_name_list *next;
694
};
695
 
696
 
697
/* Return non-zero if we are currently expanding the macro named NAME,
698
   according to LIST; otherwise, return zero.
699
 
700
   You know, it would be possible to get rid of all the NO_LOOP
701
   arguments to these functions by simply generating a new lookup
702
   function and baton which refuses to find the definition for a
703
   particular macro, and otherwise delegates the decision to another
704
   function/baton pair.  But that makes the linked list of excluded
705
   macros chained through untyped baton pointers, which will make it
706
   harder to debug.  :( */
707
static int
708
currently_rescanning (struct macro_name_list *list, const char *name)
709
{
710
  for (; list; list = list->next)
711
    if (strcmp (name, list->name) == 0)
712
      return 1;
713
 
714
  return 0;
715
}
716
 
717
 
718
/* Gather the arguments to a macro expansion.
719
 
720
   NAME is the name of the macro being invoked.  (It's only used for
721
   printing error messages.)
722
 
723
   Assume that SRC is the text of the macro invocation immediately
724
   following the macro name.  For example, if we're processing the
725
   text foo(bar, baz), then NAME would be foo and SRC will be (bar,
726
   baz).
727
 
728
   If SRC doesn't start with an open paren ( token at all, return
729
   zero, leave SRC unchanged, and don't set *ARGC_P to anything.
730
 
731
   If SRC doesn't contain a properly terminated argument list, then
732
   raise an error.
733
 
734
   For a variadic macro, NARGS holds the number of formal arguments to
735
   the macro.  For a GNU-style variadic macro, this should be the
736
   number of named arguments.  For a non-variadic macro, NARGS should
737
   be -1.
738
 
739
   Otherwise, return a pointer to the first element of an array of
740
   macro buffers referring to the argument texts, and set *ARGC_P to
741
   the number of arguments we found --- the number of elements in the
742
   array.  The macro buffers share their text with SRC, and their
743
   last_token fields are initialized.  The array is allocated with
744
   xmalloc, and the caller is responsible for freeing it.
745
 
746
   NOTE WELL: if SRC starts with a open paren ( token followed
747
   immediately by a close paren ) token (e.g., the invocation looks
748
   like "foo()"), we treat that as one argument, which happens to be
749
   the empty list of tokens.  The caller should keep in mind that such
750
   a sequence of tokens is a valid way to invoke one-parameter
751
   function-like macros, but also a valid way to invoke zero-parameter
752
   function-like macros.  Eeew.
753
 
754
   Consume the tokens from SRC; after this call, SRC contains the text
755
   following the invocation.  */
756
 
757
static struct macro_buffer *
758
gather_arguments (const char *name, struct macro_buffer *src,
759
                  int nargs, int *argc_p)
760
{
761
  struct macro_buffer tok;
762
  int args_len, args_size;
763
  struct macro_buffer *args = NULL;
764
  struct cleanup *back_to = make_cleanup (free_current_contents, &args);
765
 
766
  /* Does SRC start with an opening paren token?  Read from a copy of
767
     SRC, so SRC itself is unaffected if we don't find an opening
768
     paren.  */
769
  {
770
    struct macro_buffer temp;
771
 
772
    init_shared_buffer (&temp, src->text, src->len);
773
 
774
    if (! get_token (&tok, &temp)
775
        || tok.len != 1
776
        || tok.text[0] != '(')
777
      {
778
        discard_cleanups (back_to);
779
        return 0;
780
      }
781
  }
782
 
783
  /* Consume SRC's opening paren.  */
784
  get_token (&tok, src);
785
 
786
  args_len = 0;
787
  args_size = 6;
788
  args = (struct macro_buffer *) xmalloc (sizeof (*args) * args_size);
789
 
790
  for (;;)
791
    {
792
      struct macro_buffer *arg;
793
      int depth;
794
 
795
      /* Make sure we have room for the next argument.  */
796
      if (args_len >= args_size)
797
        {
798
          args_size *= 2;
799
          args = xrealloc (args, sizeof (*args) * args_size);
800
        }
801
 
802
      /* Initialize the next argument.  */
803
      arg = &args[args_len++];
804
      set_token (arg, src->text, src->text);
805
 
806
      /* Gather the argument's tokens.  */
807
      depth = 0;
808
      for (;;)
809
        {
810
          if (! get_token (&tok, src))
811
            error (_("Malformed argument list for macro `%s'."), name);
812
 
813
          /* Is tok an opening paren?  */
814
          if (tok.len == 1 && tok.text[0] == '(')
815
            depth++;
816
 
817
          /* Is tok is a closing paren?  */
818
          else if (tok.len == 1 && tok.text[0] == ')')
819
            {
820
              /* If it's a closing paren at the top level, then that's
821
                 the end of the argument list.  */
822
              if (depth == 0)
823
                {
824
                  /* In the varargs case, the last argument may be
825
                     missing.  Add an empty argument in this case.  */
826
                  if (nargs != -1 && args_len == nargs - 1)
827
                    {
828
                      /* Make sure we have room for the argument.  */
829
                      if (args_len >= args_size)
830
                        {
831
                          args_size++;
832
                          args = xrealloc (args, sizeof (*args) * args_size);
833
                        }
834
                      arg = &args[args_len++];
835
                      set_token (arg, src->text, src->text);
836
                    }
837
 
838
                  discard_cleanups (back_to);
839
                  *argc_p = args_len;
840
                  return args;
841
                }
842
 
843
              depth--;
844
            }
845
 
846
          /* If tok is a comma at top level, then that's the end of
847
             the current argument.  However, if we are handling a
848
             variadic macro and we are computing the last argument, we
849
             want to include the comma and remaining tokens.  */
850
          else if (tok.len == 1 && tok.text[0] == ',' && depth == 0
851
                   && (nargs == -1 || args_len < nargs))
852
            break;
853
 
854
          /* Extend the current argument to enclose this token.  If
855
             this is the current argument's first token, leave out any
856
             leading whitespace, just for aesthetics.  */
857
          if (arg->len == 0)
858
            {
859
              arg->text = tok.text;
860
              arg->len = tok.len;
861
              arg->last_token = 0;
862
            }
863
          else
864
            {
865
              arg->len = (tok.text + tok.len) - arg->text;
866
              arg->last_token = tok.text - arg->text;
867
            }
868
        }
869
    }
870
}
871
 
872
 
873
/* The `expand' and `substitute_args' functions both invoke `scan'
874
   recursively, so we need a forward declaration somewhere.  */
875
static void scan (struct macro_buffer *dest,
876
                  struct macro_buffer *src,
877
                  struct macro_name_list *no_loop,
878
                  macro_lookup_ftype *lookup_func,
879
                  void *lookup_baton);
880
 
881
 
882
/* A helper function for substitute_args.
883
 
884
   ARGV is a vector of all the arguments; ARGC is the number of
885
   arguments.  IS_VARARGS is true if the macro being substituted is a
886
   varargs macro; in this case VA_ARG_NAME is the name of the
887
   "variable" argument.  VA_ARG_NAME is ignored if IS_VARARGS is
888
   false.
889
 
890
   If the token TOK is the name of a parameter, return the parameter's
891
   index.  If TOK is not an argument, return -1.  */
892
 
893
static int
894
find_parameter (const struct macro_buffer *tok,
895
                int is_varargs, const struct macro_buffer *va_arg_name,
896
                int argc, const char * const *argv)
897
{
898
  int i;
899
 
900
  if (! tok->is_identifier)
901
    return -1;
902
 
903
  for (i = 0; i < argc; ++i)
904
    if (tok->len == strlen (argv[i]) && ! memcmp (tok->text, argv[i], tok->len))
905
      return i;
906
 
907
  if (is_varargs && tok->len == va_arg_name->len
908
      && ! memcmp (tok->text, va_arg_name->text, tok->len))
909
    return argc - 1;
910
 
911
  return -1;
912
}
913
 
914
/* Given the macro definition DEF, being invoked with the actual
915
   arguments given by ARGC and ARGV, substitute the arguments into the
916
   replacement list, and store the result in DEST.
917
 
918
   IS_VARARGS should be true if DEF is a varargs macro.  In this case,
919
   VA_ARG_NAME should be the name of the "variable" argument -- either
920
   __VA_ARGS__ for c99-style varargs, or the final argument name, for
921
   GNU-style varargs.  If IS_VARARGS is false, this parameter is
922
   ignored.
923
 
924
   If it is necessary to expand macro invocations in one of the
925
   arguments, use LOOKUP_FUNC and LOOKUP_BATON to find the macro
926
   definitions, and don't expand invocations of the macros listed in
927
   NO_LOOP.  */
928
 
929
static void
930
substitute_args (struct macro_buffer *dest,
931
                 struct macro_definition *def,
932
                 int is_varargs, const struct macro_buffer *va_arg_name,
933
                 int argc, struct macro_buffer *argv,
934
                 struct macro_name_list *no_loop,
935
                 macro_lookup_ftype *lookup_func,
936
                 void *lookup_baton)
937
{
938
  /* A macro buffer for the macro's replacement list.  */
939
  struct macro_buffer replacement_list;
940
  /* The token we are currently considering.  */
941
  struct macro_buffer tok;
942
  /* The replacement list's pointer from just before TOK was lexed.  */
943
  char *original_rl_start;
944
  /* We have a single lookahead token to handle token splicing.  */
945
  struct macro_buffer lookahead;
946
  /* The lookahead token might not be valid.  */
947
  int lookahead_valid;
948
  /* The replacement list's pointer from just before LOOKAHEAD was
949
     lexed.  */
950
  char *lookahead_rl_start;
951
 
952
  init_shared_buffer (&replacement_list, (char *) def->replacement,
953
                      strlen (def->replacement));
954
 
955
  gdb_assert (dest->len == 0);
956
  dest->last_token = 0;
957
 
958
  original_rl_start = replacement_list.text;
959
  if (! get_token (&tok, &replacement_list))
960
    return;
961
  lookahead_rl_start = replacement_list.text;
962
  lookahead_valid = get_token (&lookahead, &replacement_list);
963
 
964
  for (;;)
965
    {
966
      /* Just for aesthetics.  If we skipped some whitespace, copy
967
         that to DEST.  */
968
      if (tok.text > original_rl_start)
969
        {
970
          appendmem (dest, original_rl_start, tok.text - original_rl_start);
971
          dest->last_token = dest->len;
972
        }
973
 
974
      /* Is this token the stringification operator?  */
975
      if (tok.len == 1
976
          && tok.text[0] == '#')
977
        {
978
          int arg;
979
 
980
          if (!lookahead_valid)
981
            error (_("Stringification operator requires an argument."));
982
 
983
          arg = find_parameter (&lookahead, is_varargs, va_arg_name,
984
                                def->argc, def->argv);
985
          if (arg == -1)
986
            error (_("Argument to stringification operator must name "
987
                     "a macro parameter."));
988
 
989
          stringify (dest, argv[arg].text, argv[arg].len);
990
 
991
          /* Read one token and let the loop iteration code handle the
992
             rest.  */
993
          lookahead_rl_start = replacement_list.text;
994
          lookahead_valid = get_token (&lookahead, &replacement_list);
995
        }
996
      /* Is this token the splicing operator?  */
997
      else if (tok.len == 2
998
               && tok.text[0] == '#'
999
               && tok.text[1] == '#')
1000
        error (_("Stray splicing operator"));
1001
      /* Is the next token the splicing operator?  */
1002
      else if (lookahead_valid
1003
               && lookahead.len == 2
1004
               && lookahead.text[0] == '#'
1005
               && lookahead.text[1] == '#')
1006
        {
1007
          int finished = 0;
1008
          int prev_was_comma = 0;
1009
 
1010
          /* Note that GCC warns if the result of splicing is not a
1011
             token.  In the debugger there doesn't seem to be much
1012
             benefit from doing this.  */
1013
 
1014
          /* Insert the first token.  */
1015
          if (tok.len == 1 && tok.text[0] == ',')
1016
            prev_was_comma = 1;
1017
          else
1018
            {
1019
              int arg = find_parameter (&tok, is_varargs, va_arg_name,
1020
                                        def->argc, def->argv);
1021
 
1022
              if (arg != -1)
1023
                appendmem (dest, argv[arg].text, argv[arg].len);
1024
              else
1025
                appendmem (dest, tok.text, tok.len);
1026
            }
1027
 
1028
          /* Apply a possible sequence of ## operators.  */
1029
          for (;;)
1030
            {
1031
              if (! get_token (&tok, &replacement_list))
1032
                error (_("Splicing operator at end of macro"));
1033
 
1034
              /* Handle a comma before a ##.  If we are handling
1035
                 varargs, and the token on the right hand side is the
1036
                 varargs marker, and the final argument is empty or
1037
                 missing, then drop the comma.  This is a GNU
1038
                 extension.  There is one ambiguous case here,
1039
                 involving pedantic behavior with an empty argument,
1040
                 but we settle that in favor of GNU-style (GCC uses an
1041
                 option).  If we aren't dealing with varargs, we
1042
                 simply insert the comma.  */
1043
              if (prev_was_comma)
1044
                {
1045
                  if (! (is_varargs
1046
                         && tok.len == va_arg_name->len
1047
                         && !memcmp (tok.text, va_arg_name->text, tok.len)
1048
                         && argv[argc - 1].len == 0))
1049
                    appendmem (dest, ",", 1);
1050
                  prev_was_comma = 0;
1051
                }
1052
 
1053
              /* Insert the token.  If it is a parameter, insert the
1054
                 argument.  If it is a comma, treat it specially.  */
1055
              if (tok.len == 1 && tok.text[0] == ',')
1056
                prev_was_comma = 1;
1057
              else
1058
                {
1059
                  int arg = find_parameter (&tok, is_varargs, va_arg_name,
1060
                                            def->argc, def->argv);
1061
 
1062
                  if (arg != -1)
1063
                    appendmem (dest, argv[arg].text, argv[arg].len);
1064
                  else
1065
                    appendmem (dest, tok.text, tok.len);
1066
                }
1067
 
1068
              /* Now read another token.  If it is another splice, we
1069
                 loop.  */
1070
              original_rl_start = replacement_list.text;
1071
              if (! get_token (&tok, &replacement_list))
1072
                {
1073
                  finished = 1;
1074
                  break;
1075
                }
1076
 
1077
              if (! (tok.len == 2
1078
                     && tok.text[0] == '#'
1079
                     && tok.text[1] == '#'))
1080
                break;
1081
            }
1082
 
1083
          if (prev_was_comma)
1084
            {
1085
              /* We saw a comma.  Insert it now.  */
1086
              appendmem (dest, ",", 1);
1087
            }
1088
 
1089
          dest->last_token = dest->len;
1090
          if (finished)
1091
            lookahead_valid = 0;
1092
          else
1093
            {
1094
              /* Set up for the loop iterator.  */
1095
              lookahead = tok;
1096
              lookahead_rl_start = original_rl_start;
1097
              lookahead_valid = 1;
1098
            }
1099
        }
1100
      else
1101
        {
1102
          /* Is this token an identifier?  */
1103
          int substituted = 0;
1104
          int arg = find_parameter (&tok, is_varargs, va_arg_name,
1105
                                    def->argc, def->argv);
1106
 
1107
          if (arg != -1)
1108
            {
1109
              struct macro_buffer arg_src;
1110
 
1111
              /* Expand any macro invocations in the argument text,
1112
                 and append the result to dest.  Remember that scan
1113
                 mutates its source, so we need to scan a new buffer
1114
                 referring to the argument's text, not the argument
1115
                 itself.  */
1116
              init_shared_buffer (&arg_src, argv[arg].text, argv[arg].len);
1117
              scan (dest, &arg_src, no_loop, lookup_func, lookup_baton);
1118
              substituted = 1;
1119
            }
1120
 
1121
          /* If it wasn't a parameter, then just copy it across.  */
1122
          if (! substituted)
1123
            append_tokens_without_splicing (dest, &tok);
1124
        }
1125
 
1126
      if (! lookahead_valid)
1127
        break;
1128
 
1129
      tok = lookahead;
1130
      original_rl_start = lookahead_rl_start;
1131
 
1132
      lookahead_rl_start = replacement_list.text;
1133
      lookahead_valid = get_token (&lookahead, &replacement_list);
1134
    }
1135
}
1136
 
1137
 
1138
/* Expand a call to a macro named ID, whose definition is DEF.  Append
1139
   its expansion to DEST.  SRC is the input text following the ID
1140
   token.  We are currently rescanning the expansions of the macros
1141
   named in NO_LOOP; don't re-expand them.  Use LOOKUP_FUNC and
1142
   LOOKUP_BATON to find definitions for any nested macro references.
1143
 
1144
   Return 1 if we decided to expand it, zero otherwise.  (If it's a
1145
   function-like macro name that isn't followed by an argument list,
1146
   we don't expand it.)  If we return zero, leave SRC unchanged.  */
1147
static int
1148
expand (const char *id,
1149
        struct macro_definition *def,
1150
        struct macro_buffer *dest,
1151
        struct macro_buffer *src,
1152
        struct macro_name_list *no_loop,
1153
        macro_lookup_ftype *lookup_func,
1154
        void *lookup_baton)
1155
{
1156
  struct macro_name_list new_no_loop;
1157
 
1158
  /* Create a new node to be added to the front of the no-expand list.
1159
     This list is appropriate for re-scanning replacement lists, but
1160
     it is *not* appropriate for scanning macro arguments; invocations
1161
     of the macro whose arguments we are gathering *do* get expanded
1162
     there.  */
1163
  new_no_loop.name = id;
1164
  new_no_loop.next = no_loop;
1165
 
1166
  /* What kind of macro are we expanding?  */
1167
  if (def->kind == macro_object_like)
1168
    {
1169
      struct macro_buffer replacement_list;
1170
 
1171
      init_shared_buffer (&replacement_list, (char *) def->replacement,
1172
                          strlen (def->replacement));
1173
 
1174
      scan (dest, &replacement_list, &new_no_loop, lookup_func, lookup_baton);
1175
      return 1;
1176
    }
1177
  else if (def->kind == macro_function_like)
1178
    {
1179
      struct cleanup *back_to = make_cleanup (null_cleanup, 0);
1180
      int argc = 0;
1181
      struct macro_buffer *argv = NULL;
1182
      struct macro_buffer substituted;
1183
      struct macro_buffer substituted_src;
1184
      struct macro_buffer va_arg_name;
1185
      int is_varargs = 0;
1186
 
1187
      if (def->argc >= 1)
1188
        {
1189
          if (strcmp (def->argv[def->argc - 1], "...") == 0)
1190
            {
1191
              /* In C99-style varargs, substitution is done using
1192
                 __VA_ARGS__.  */
1193
              init_shared_buffer (&va_arg_name, "__VA_ARGS__",
1194
                                  strlen ("__VA_ARGS__"));
1195
              is_varargs = 1;
1196
            }
1197
          else
1198
            {
1199
              int len = strlen (def->argv[def->argc - 1]);
1200
 
1201
              if (len > 3
1202
                  && strcmp (def->argv[def->argc - 1] + len - 3, "...") == 0)
1203
                {
1204
                  /* In GNU-style varargs, the name of the
1205
                     substitution parameter is the name of the formal
1206
                     argument without the "...".  */
1207
                  init_shared_buffer (&va_arg_name,
1208
                                      (char *) def->argv[def->argc - 1],
1209
                                      len - 3);
1210
                  is_varargs = 1;
1211
                }
1212
            }
1213
        }
1214
 
1215
      make_cleanup (free_current_contents, &argv);
1216
      argv = gather_arguments (id, src, is_varargs ? def->argc : -1,
1217
                               &argc);
1218
 
1219
      /* If we couldn't find any argument list, then we don't expand
1220
         this macro.  */
1221
      if (! argv)
1222
        {
1223
          do_cleanups (back_to);
1224
          return 0;
1225
        }
1226
 
1227
      /* Check that we're passing an acceptable number of arguments for
1228
         this macro.  */
1229
      if (argc != def->argc)
1230
        {
1231
          if (is_varargs && argc >= def->argc - 1)
1232
            {
1233
              /* Ok.  */
1234
            }
1235
          /* Remember that a sequence of tokens like "foo()" is a
1236
             valid invocation of a macro expecting either zero or one
1237
             arguments.  */
1238
          else if (! (argc == 1
1239
                      && argv[0].len == 0
1240
                      && def->argc == 0))
1241
            error (_("Wrong number of arguments to macro `%s' "
1242
                   "(expected %d, got %d)."),
1243
                   id, def->argc, argc);
1244
        }
1245
 
1246
      /* Note that we don't expand macro invocations in the arguments
1247
         yet --- we let subst_args take care of that.  Parameters that
1248
         appear as operands of the stringifying operator "#" or the
1249
         splicing operator "##" don't get macro references expanded,
1250
         so we can't really tell whether it's appropriate to macro-
1251
         expand an argument until we see how it's being used.  */
1252
      init_buffer (&substituted, 0);
1253
      make_cleanup (cleanup_macro_buffer, &substituted);
1254
      substitute_args (&substituted, def, is_varargs, &va_arg_name,
1255
                       argc, argv, no_loop, lookup_func, lookup_baton);
1256
 
1257
      /* Now `substituted' is the macro's replacement list, with all
1258
         argument values substituted into it properly.  Re-scan it for
1259
         macro references, but don't expand invocations of this macro.
1260
 
1261
         We create a new buffer, `substituted_src', which points into
1262
         `substituted', and scan that.  We can't scan `substituted'
1263
         itself, since the tokenization process moves the buffer's
1264
         text pointer around, and we still need to be able to find
1265
         `substituted's original text buffer after scanning it so we
1266
         can free it.  */
1267
      init_shared_buffer (&substituted_src, substituted.text, substituted.len);
1268
      scan (dest, &substituted_src, &new_no_loop, lookup_func, lookup_baton);
1269
 
1270
      do_cleanups (back_to);
1271
 
1272
      return 1;
1273
    }
1274
  else
1275
    internal_error (__FILE__, __LINE__, _("bad macro definition kind"));
1276
}
1277
 
1278
 
1279
/* If the single token in SRC_FIRST followed by the tokens in SRC_REST
1280
   constitute a macro invokation not forbidden in NO_LOOP, append its
1281
   expansion to DEST and return non-zero.  Otherwise, return zero, and
1282
   leave DEST unchanged.
1283
 
1284
   SRC_FIRST and SRC_REST must be shared buffers; DEST must not be one.
1285
   SRC_FIRST must be a string built by get_token.  */
1286
static int
1287
maybe_expand (struct macro_buffer *dest,
1288
              struct macro_buffer *src_first,
1289
              struct macro_buffer *src_rest,
1290
              struct macro_name_list *no_loop,
1291
              macro_lookup_ftype *lookup_func,
1292
              void *lookup_baton)
1293
{
1294
  gdb_assert (src_first->shared);
1295
  gdb_assert (src_rest->shared);
1296
  gdb_assert (! dest->shared);
1297
 
1298
  /* Is this token an identifier?  */
1299
  if (src_first->is_identifier)
1300
    {
1301
      /* Make a null-terminated copy of it, since that's what our
1302
         lookup function expects.  */
1303
      char *id = xmalloc (src_first->len + 1);
1304
      struct cleanup *back_to = make_cleanup (xfree, id);
1305
 
1306
      memcpy (id, src_first->text, src_first->len);
1307
      id[src_first->len] = 0;
1308
 
1309
      /* If we're currently re-scanning the result of expanding
1310
         this macro, don't expand it again.  */
1311
      if (! currently_rescanning (no_loop, id))
1312
        {
1313
          /* Does this identifier have a macro definition in scope?  */
1314
          struct macro_definition *def = lookup_func (id, lookup_baton);
1315
 
1316
          if (def && expand (id, def, dest, src_rest, no_loop,
1317
                             lookup_func, lookup_baton))
1318
            {
1319
              do_cleanups (back_to);
1320
              return 1;
1321
            }
1322
        }
1323
 
1324
      do_cleanups (back_to);
1325
    }
1326
 
1327
  return 0;
1328
}
1329
 
1330
 
1331
/* Expand macro references in SRC, appending the results to DEST.
1332
   Assume we are re-scanning the result of expanding the macros named
1333
   in NO_LOOP, and don't try to re-expand references to them.
1334
 
1335
   SRC must be a shared buffer; DEST must not be one.  */
1336
static void
1337
scan (struct macro_buffer *dest,
1338
      struct macro_buffer *src,
1339
      struct macro_name_list *no_loop,
1340
      macro_lookup_ftype *lookup_func,
1341
      void *lookup_baton)
1342
{
1343
  gdb_assert (src->shared);
1344
  gdb_assert (! dest->shared);
1345
 
1346
  for (;;)
1347
    {
1348
      struct macro_buffer tok;
1349
      char *original_src_start = src->text;
1350
 
1351
      /* Find the next token in SRC.  */
1352
      if (! get_token (&tok, src))
1353
        break;
1354
 
1355
      /* Just for aesthetics.  If we skipped some whitespace, copy
1356
         that to DEST.  */
1357
      if (tok.text > original_src_start)
1358
        {
1359
          appendmem (dest, original_src_start, tok.text - original_src_start);
1360
          dest->last_token = dest->len;
1361
        }
1362
 
1363
      if (! maybe_expand (dest, &tok, src, no_loop, lookup_func, lookup_baton))
1364
        /* We didn't end up expanding tok as a macro reference, so
1365
           simply append it to dest.  */
1366
        append_tokens_without_splicing (dest, &tok);
1367
    }
1368
 
1369
  /* Just for aesthetics.  If there was any trailing whitespace in
1370
     src, copy it to dest.  */
1371
  if (src->len)
1372
    {
1373
      appendmem (dest, src->text, src->len);
1374
      dest->last_token = dest->len;
1375
    }
1376
}
1377
 
1378
 
1379
char *
1380
macro_expand (const char *source,
1381
              macro_lookup_ftype *lookup_func,
1382
              void *lookup_func_baton)
1383
{
1384
  struct macro_buffer src, dest;
1385
  struct cleanup *back_to;
1386
 
1387
  init_shared_buffer (&src, (char *) source, strlen (source));
1388
 
1389
  init_buffer (&dest, 0);
1390
  dest.last_token = 0;
1391
  back_to = make_cleanup (cleanup_macro_buffer, &dest);
1392
 
1393
  scan (&dest, &src, 0, lookup_func, lookup_func_baton);
1394
 
1395
  appendc (&dest, '\0');
1396
 
1397
  discard_cleanups (back_to);
1398
  return dest.text;
1399
}
1400
 
1401
 
1402
char *
1403
macro_expand_once (const char *source,
1404
                   macro_lookup_ftype *lookup_func,
1405
                   void *lookup_func_baton)
1406
{
1407
  error (_("Expand-once not implemented yet."));
1408
}
1409
 
1410
 
1411
char *
1412
macro_expand_next (char **lexptr,
1413
                   macro_lookup_ftype *lookup_func,
1414
                   void *lookup_baton)
1415
{
1416
  struct macro_buffer src, dest, tok;
1417
  struct cleanup *back_to;
1418
 
1419
  /* Set up SRC to refer to the input text, pointed to by *lexptr.  */
1420
  init_shared_buffer (&src, *lexptr, strlen (*lexptr));
1421
 
1422
  /* Set up DEST to receive the expansion, if there is one.  */
1423
  init_buffer (&dest, 0);
1424
  dest.last_token = 0;
1425
  back_to = make_cleanup (cleanup_macro_buffer, &dest);
1426
 
1427
  /* Get the text's first preprocessing token.  */
1428
  if (! get_token (&tok, &src))
1429
    {
1430
      do_cleanups (back_to);
1431
      return 0;
1432
    }
1433
 
1434
  /* If it's a macro invocation, expand it.  */
1435
  if (maybe_expand (&dest, &tok, &src, 0, lookup_func, lookup_baton))
1436
    {
1437
      /* It was a macro invocation!  Package up the expansion as a
1438
         null-terminated string and return it.  Set *lexptr to the
1439
         start of the next token in the input.  */
1440
      appendc (&dest, '\0');
1441
      discard_cleanups (back_to);
1442
      *lexptr = src.text;
1443
      return dest.text;
1444
    }
1445
  else
1446
    {
1447
      /* It wasn't a macro invocation.  */
1448
      do_cleanups (back_to);
1449
      return 0;
1450
    }
1451
}

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