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1 104 markom
/* GDB-specific functions for operating on agent expressions
2
   Copyright 1998, 2000 Free Software Foundation, Inc.
3
 
4
   This file is part of GDB.
5
 
6
   This program is free software; you can redistribute it and/or modify
7
   it under the terms of the GNU General Public License as published by
8
   the Free Software Foundation; either version 2 of the License, or
9
   (at your option) any later version.
10
 
11
   This program is distributed in the hope that it will be useful,
12
   but WITHOUT ANY WARRANTY; without even the implied warranty of
13
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
14
   GNU General Public License for more details.
15
 
16
   You should have received a copy of the GNU General Public License
17
   along with this program; if not, write to the Free Software
18
   Foundation, Inc., 59 Temple Place - Suite 330,
19
   Boston, MA 02111-1307, USA.  */
20
 
21
#include "defs.h"
22
#include "symtab.h"
23
#include "symfile.h"
24
#include "gdbtypes.h"
25
#include "value.h"
26
#include "expression.h"
27
#include "command.h"
28
#include "gdbcmd.h"
29
#include "frame.h"
30
#include "target.h"
31
#include "ax.h"
32
#include "ax-gdb.h"
33
 
34
/* To make sense of this file, you should read doc/agentexpr.texi.
35
   Then look at the types and enums in ax-gdb.h.  For the code itself,
36
   look at gen_expr, towards the bottom; that's the main function that
37
   looks at the GDB expressions and calls everything else to generate
38
   code.
39
 
40
   I'm beginning to wonder whether it wouldn't be nicer to internally
41
   generate trees, with types, and then spit out the bytecode in
42
   linear form afterwards; we could generate fewer `swap', `ext', and
43
   `zero_ext' bytecodes that way; it would make good constant folding
44
   easier, too.  But at the moment, I think we should be willing to
45
   pay for the simplicity of this code with less-than-optimal bytecode
46
   strings.
47
 
48
   Remember, "GBD" stands for "Great Britain, Dammit!"  So be careful.  */
49
 
50
 
51
 
52
/* Prototypes for local functions. */
53
 
54
/* There's a standard order to the arguments of these functions:
55
   union exp_element ** --- pointer into expression
56
   struct agent_expr * --- agent expression buffer to generate code into
57
   struct axs_value * --- describes value left on top of stack  */
58
 
59
static struct value *const_var_ref PARAMS ((struct symbol * var));
60
static struct value *const_expr PARAMS ((union exp_element ** pc));
61
static struct value *maybe_const_expr PARAMS ((union exp_element ** pc));
62
 
63
static void gen_traced_pop PARAMS ((struct agent_expr *, struct axs_value *));
64
 
65
static void gen_sign_extend PARAMS ((struct agent_expr *, struct type *));
66
static void gen_extend PARAMS ((struct agent_expr *, struct type *));
67
static void gen_fetch PARAMS ((struct agent_expr *, struct type *));
68
static void gen_left_shift PARAMS ((struct agent_expr *, int));
69
 
70
 
71
static void gen_frame_args_address PARAMS ((struct agent_expr *));
72
static void gen_frame_locals_address PARAMS ((struct agent_expr *));
73
static void gen_offset PARAMS ((struct agent_expr * ax, int offset));
74
static void gen_sym_offset PARAMS ((struct agent_expr *, struct symbol *));
75
static void gen_var_ref PARAMS ((struct agent_expr * ax,
76
                                 struct axs_value * value,
77
                                 struct symbol * var));
78
 
79
 
80
static void gen_int_literal PARAMS ((struct agent_expr * ax,
81
                                     struct axs_value * value,
82
                                     LONGEST k, struct type * type));
83
 
84
 
85
static void require_rvalue PARAMS ((struct agent_expr * ax,
86
                                    struct axs_value * value));
87
static void gen_usual_unary PARAMS ((struct agent_expr * ax,
88
                                     struct axs_value * value));
89
static int type_wider_than PARAMS ((struct type * type1,
90
                                    struct type * type2));
91
static struct type *max_type PARAMS ((struct type * type1,
92
                                      struct type * type2));
93
static void gen_conversion PARAMS ((struct agent_expr * ax,
94
                                    struct type * from,
95
                                    struct type * to));
96
static int is_nontrivial_conversion PARAMS ((struct type * from,
97
                                             struct type * to));
98
static void gen_usual_arithmetic PARAMS ((struct agent_expr * ax,
99
                                          struct axs_value * value1,
100
                                          struct axs_value * value2));
101
static void gen_integral_promotions PARAMS ((struct agent_expr * ax,
102
                                             struct axs_value * value));
103
static void gen_cast PARAMS ((struct agent_expr * ax,
104
                              struct axs_value * value,
105
                              struct type * type));
106
static void gen_scale PARAMS ((struct agent_expr * ax,
107
                               enum agent_op op,
108
                               struct type * type));
109
static void gen_add PARAMS ((struct agent_expr * ax,
110
                             struct axs_value * value,
111
                             struct axs_value * value1,
112
                             struct axs_value * value2,
113
                             char *name));
114
static void gen_sub PARAMS ((struct agent_expr * ax,
115
                             struct axs_value * value,
116
                             struct axs_value * value1,
117
                             struct axs_value * value2));
118
static void gen_binop PARAMS ((struct agent_expr * ax,
119
                               struct axs_value * value,
120
                               struct axs_value * value1,
121
                               struct axs_value * value2,
122
                               enum agent_op op,
123
                               enum agent_op op_unsigned,
124
                               int may_carry,
125
                               char *name));
126
static void gen_logical_not PARAMS ((struct agent_expr * ax,
127
                                     struct axs_value * value));
128
static void gen_complement PARAMS ((struct agent_expr * ax,
129
                                    struct axs_value * value));
130
static void gen_deref PARAMS ((struct agent_expr *, struct axs_value *));
131
static void gen_address_of PARAMS ((struct agent_expr *, struct axs_value *));
132
static int find_field PARAMS ((struct type * type, char *name));
133
static void gen_bitfield_ref PARAMS ((struct agent_expr * ax,
134
                                      struct axs_value * value,
135
                                      struct type * type,
136
                                      int start, int end));
137
static void gen_struct_ref PARAMS ((struct agent_expr * ax,
138
                                    struct axs_value * value,
139
                                    char *field,
140
                                    char *operator_name,
141
                                    char *operand_name));
142
static void gen_repeat PARAMS ((union exp_element ** pc,
143
                                struct agent_expr * ax,
144
                                struct axs_value * value));
145
static void gen_sizeof PARAMS ((union exp_element ** pc,
146
                                struct agent_expr * ax,
147
                                struct axs_value * value));
148
static void gen_expr PARAMS ((union exp_element ** pc,
149
                              struct agent_expr * ax,
150
                              struct axs_value * value));
151
 
152
static void print_axs_value (struct ui_file *f, struct axs_value * value);
153
static void agent_command PARAMS ((char *exp, int from_tty));
154
 
155
 
156
/* Detecting constant expressions.  */
157
 
158
/* If the variable reference at *PC is a constant, return its value.
159
   Otherwise, return zero.
160
 
161
   Hey, Wally!  How can a variable reference be a constant?
162
 
163
   Well, Beav, this function really handles the OP_VAR_VALUE operator,
164
   not specifically variable references.  GDB uses OP_VAR_VALUE to
165
   refer to any kind of symbolic reference: function names, enum
166
   elements, and goto labels are all handled through the OP_VAR_VALUE
167
   operator, even though they're constants.  It makes sense given the
168
   situation.
169
 
170
   Gee, Wally, don'cha wonder sometimes if data representations that
171
   subvert commonly accepted definitions of terms in favor of heavily
172
   context-specific interpretations are really just a tool of the
173
   programming hegemony to preserve their power and exclude the
174
   proletariat?  */
175
 
176
static struct value *
177
const_var_ref (var)
178
     struct symbol *var;
179
{
180
  struct type *type = SYMBOL_TYPE (var);
181
 
182
  switch (SYMBOL_CLASS (var))
183
    {
184
    case LOC_CONST:
185
      return value_from_longest (type, (LONGEST) SYMBOL_VALUE (var));
186
 
187
    case LOC_LABEL:
188
      return value_from_longest (type, (LONGEST) SYMBOL_VALUE_ADDRESS (var));
189
 
190
    default:
191
      return 0;
192
    }
193
}
194
 
195
 
196
/* If the expression starting at *PC has a constant value, return it.
197
   Otherwise, return zero.  If we return a value, then *PC will be
198
   advanced to the end of it.  If we return zero, *PC could be
199
   anywhere.  */
200
static struct value *
201
const_expr (pc)
202
     union exp_element **pc;
203
{
204
  enum exp_opcode op = (*pc)->opcode;
205
  struct value *v1;
206
 
207
  switch (op)
208
    {
209
    case OP_LONG:
210
      {
211
        struct type *type = (*pc)[1].type;
212
        LONGEST k = (*pc)[2].longconst;
213
        (*pc) += 4;
214
        return value_from_longest (type, k);
215
      }
216
 
217
    case OP_VAR_VALUE:
218
      {
219
        struct value *v = const_var_ref ((*pc)[2].symbol);
220
        (*pc) += 4;
221
        return v;
222
      }
223
 
224
      /* We could add more operators in here.  */
225
 
226
    case UNOP_NEG:
227
      (*pc)++;
228
      v1 = const_expr (pc);
229
      if (v1)
230
        return value_neg (v1);
231
      else
232
        return 0;
233
 
234
    default:
235
      return 0;
236
    }
237
}
238
 
239
 
240
/* Like const_expr, but guarantee also that *PC is undisturbed if the
241
   expression is not constant.  */
242
static struct value *
243
maybe_const_expr (pc)
244
     union exp_element **pc;
245
{
246
  union exp_element *tentative_pc = *pc;
247
  struct value *v = const_expr (&tentative_pc);
248
 
249
  /* If we got a value, then update the real PC.  */
250
  if (v)
251
    *pc = tentative_pc;
252
 
253
  return v;
254
}
255
 
256
 
257
/* Generating bytecode from GDB expressions: general assumptions */
258
 
259
/* Here are a few general assumptions made throughout the code; if you
260
   want to make a change that contradicts one of these, then you'd
261
   better scan things pretty thoroughly.
262
 
263
   - We assume that all values occupy one stack element.  For example,
264
   sometimes we'll swap to get at the left argument to a binary
265
   operator.  If we decide that void values should occupy no stack
266
   elements, or that synthetic arrays (whose size is determined at
267
   run time, created by the `@' operator) should occupy two stack
268
   elements (address and length), then this will cause trouble.
269
 
270
   - We assume the stack elements are infinitely wide, and that we
271
   don't have to worry what happens if the user requests an
272
   operation that is wider than the actual interpreter's stack.
273
   That is, it's up to the interpreter to handle directly all the
274
   integer widths the user has access to.  (Woe betide the language
275
   with bignums!)
276
 
277
   - We don't support side effects.  Thus, we don't have to worry about
278
   GCC's generalized lvalues, function calls, etc.
279
 
280
   - We don't support floating point.  Many places where we switch on
281
   some type don't bother to include cases for floating point; there
282
   may be even more subtle ways this assumption exists.  For
283
   example, the arguments to % must be integers.
284
 
285
   - We assume all subexpressions have a static, unchanging type.  If
286
   we tried to support convenience variables, this would be a
287
   problem.
288
 
289
   - All values on the stack should always be fully zero- or
290
   sign-extended.
291
 
292
   (I wasn't sure whether to choose this or its opposite --- that
293
   only addresses are assumed extended --- but it turns out that
294
   neither convention completely eliminates spurious extend
295
   operations (if everything is always extended, then you have to
296
   extend after add, because it could overflow; if nothing is
297
   extended, then you end up producing extends whenever you change
298
   sizes), and this is simpler.)  */
299
 
300
 
301
/* Generating bytecode from GDB expressions: the `trace' kludge  */
302
 
303
/* The compiler in this file is a general-purpose mechanism for
304
   translating GDB expressions into bytecode.  One ought to be able to
305
   find a million and one uses for it.
306
 
307
   However, at the moment it is HOPELESSLY BRAIN-DAMAGED for the sake
308
   of expediency.  Let he who is without sin cast the first stone.
309
 
310
   For the data tracing facility, we need to insert `trace' bytecodes
311
   before each data fetch; this records all the memory that the
312
   expression touches in the course of evaluation, so that memory will
313
   be available when the user later tries to evaluate the expression
314
   in GDB.
315
 
316
   This should be done (I think) in a post-processing pass, that walks
317
   an arbitrary agent expression and inserts `trace' operations at the
318
   appropriate points.  But it's much faster to just hack them
319
   directly into the code.  And since we're in a crunch, that's what
320
   I've done.
321
 
322
   Setting the flag trace_kludge to non-zero enables the code that
323
   emits the trace bytecodes at the appropriate points.  */
324
static int trace_kludge;
325
 
326
/* Trace the lvalue on the stack, if it needs it.  In either case, pop
327
   the value.  Useful on the left side of a comma, and at the end of
328
   an expression being used for tracing.  */
329
static void
330
gen_traced_pop (ax, value)
331
     struct agent_expr *ax;
332
     struct axs_value *value;
333
{
334
  if (trace_kludge)
335
    switch (value->kind)
336
      {
337
      case axs_rvalue:
338
        /* We don't trace rvalues, just the lvalues necessary to
339
           produce them.  So just dispose of this value.  */
340
        ax_simple (ax, aop_pop);
341
        break;
342
 
343
      case axs_lvalue_memory:
344
        {
345
          int length = TYPE_LENGTH (value->type);
346
 
347
          /* There's no point in trying to use a trace_quick bytecode
348
             here, since "trace_quick SIZE pop" is three bytes, whereas
349
             "const8 SIZE trace" is also three bytes, does the same
350
             thing, and the simplest code which generates that will also
351
             work correctly for objects with large sizes.  */
352
          ax_const_l (ax, length);
353
          ax_simple (ax, aop_trace);
354
        }
355
        break;
356
 
357
      case axs_lvalue_register:
358
        /* We need to mention the register somewhere in the bytecode,
359
           so ax_reqs will pick it up and add it to the mask of
360
           registers used.  */
361
        ax_reg (ax, value->u.reg);
362
        ax_simple (ax, aop_pop);
363
        break;
364
      }
365
  else
366
    /* If we're not tracing, just pop the value.  */
367
    ax_simple (ax, aop_pop);
368
}
369
 
370
 
371
 
372
/* Generating bytecode from GDB expressions: helper functions */
373
 
374
/* Assume that the lower bits of the top of the stack is a value of
375
   type TYPE, and the upper bits are zero.  Sign-extend if necessary.  */
376
static void
377
gen_sign_extend (ax, type)
378
     struct agent_expr *ax;
379
     struct type *type;
380
{
381
  /* Do we need to sign-extend this?  */
382
  if (!TYPE_UNSIGNED (type))
383
    ax_ext (ax, type->length * TARGET_CHAR_BIT);
384
}
385
 
386
 
387
/* Assume the lower bits of the top of the stack hold a value of type
388
   TYPE, and the upper bits are garbage.  Sign-extend or truncate as
389
   needed.  */
390
static void
391
gen_extend (ax, type)
392
     struct agent_expr *ax;
393
     struct type *type;
394
{
395
  int bits = type->length * TARGET_CHAR_BIT;
396
  /* I just had to.  */
397
  ((TYPE_UNSIGNED (type) ? ax_zero_ext : ax_ext) (ax, bits));
398
}
399
 
400
 
401
/* Assume that the top of the stack contains a value of type "pointer
402
   to TYPE"; generate code to fetch its value.  Note that TYPE is the
403
   target type, not the pointer type.  */
404
static void
405
gen_fetch (ax, type)
406
     struct agent_expr *ax;
407
     struct type *type;
408
{
409
  if (trace_kludge)
410
    {
411
      /* Record the area of memory we're about to fetch.  */
412
      ax_trace_quick (ax, TYPE_LENGTH (type));
413
    }
414
 
415
  switch (type->code)
416
    {
417
    case TYPE_CODE_PTR:
418
    case TYPE_CODE_ENUM:
419
    case TYPE_CODE_INT:
420
    case TYPE_CODE_CHAR:
421
      /* It's a scalar value, so we know how to dereference it.  How
422
         many bytes long is it?  */
423
      switch (type->length)
424
        {
425
        case 8 / TARGET_CHAR_BIT:
426
          ax_simple (ax, aop_ref8);
427
          break;
428
        case 16 / TARGET_CHAR_BIT:
429
          ax_simple (ax, aop_ref16);
430
          break;
431
        case 32 / TARGET_CHAR_BIT:
432
          ax_simple (ax, aop_ref32);
433
          break;
434
        case 64 / TARGET_CHAR_BIT:
435
          ax_simple (ax, aop_ref64);
436
          break;
437
 
438
          /* Either our caller shouldn't have asked us to dereference
439
             that pointer (other code's fault), or we're not
440
             implementing something we should be (this code's fault).
441
             In any case, it's a bug the user shouldn't see.  */
442
        default:
443
          internal_error ("ax-gdb.c (gen_fetch): strange size");
444
        }
445
 
446
      gen_sign_extend (ax, type);
447
      break;
448
 
449
    default:
450
      /* Either our caller shouldn't have asked us to dereference that
451
         pointer (other code's fault), or we're not implementing
452
         something we should be (this code's fault).  In any case,
453
         it's a bug the user shouldn't see.  */
454
      internal_error ("ax-gdb.c (gen_fetch): bad type code");
455
    }
456
}
457
 
458
 
459
/* Generate code to left shift the top of the stack by DISTANCE bits, or
460
   right shift it by -DISTANCE bits if DISTANCE < 0.  This generates
461
   unsigned (logical) right shifts.  */
462
static void
463
gen_left_shift (ax, distance)
464
     struct agent_expr *ax;
465
     int distance;
466
{
467
  if (distance > 0)
468
    {
469
      ax_const_l (ax, distance);
470
      ax_simple (ax, aop_lsh);
471
    }
472
  else if (distance < 0)
473
    {
474
      ax_const_l (ax, -distance);
475
      ax_simple (ax, aop_rsh_unsigned);
476
    }
477
}
478
 
479
 
480
 
481
/* Generating bytecode from GDB expressions: symbol references */
482
 
483
/* Generate code to push the base address of the argument portion of
484
   the top stack frame.  */
485
static void
486
gen_frame_args_address (ax)
487
     struct agent_expr *ax;
488
{
489
  long frame_reg, frame_offset;
490
 
491
  TARGET_VIRTUAL_FRAME_POINTER (ax->scope, &frame_reg, &frame_offset);
492
  ax_reg (ax, frame_reg);
493
  gen_offset (ax, frame_offset);
494
}
495
 
496
 
497
/* Generate code to push the base address of the locals portion of the
498
   top stack frame.  */
499
static void
500
gen_frame_locals_address (ax)
501
     struct agent_expr *ax;
502
{
503
  long frame_reg, frame_offset;
504
 
505
  TARGET_VIRTUAL_FRAME_POINTER (ax->scope, &frame_reg, &frame_offset);
506
  ax_reg (ax, frame_reg);
507
  gen_offset (ax, frame_offset);
508
}
509
 
510
 
511
/* Generate code to add OFFSET to the top of the stack.  Try to
512
   generate short and readable code.  We use this for getting to
513
   variables on the stack, and structure members.  If we were
514
   programming in ML, it would be clearer why these are the same
515
   thing.  */
516
static void
517
gen_offset (ax, offset)
518
     struct agent_expr *ax;
519
     int offset;
520
{
521
  /* It would suffice to simply push the offset and add it, but this
522
     makes it easier to read positive and negative offsets in the
523
     bytecode.  */
524
  if (offset > 0)
525
    {
526
      ax_const_l (ax, offset);
527
      ax_simple (ax, aop_add);
528
    }
529
  else if (offset < 0)
530
    {
531
      ax_const_l (ax, -offset);
532
      ax_simple (ax, aop_sub);
533
    }
534
}
535
 
536
 
537
/* In many cases, a symbol's value is the offset from some other
538
   address (stack frame, base register, etc.)  Generate code to add
539
   VAR's value to the top of the stack.  */
540
static void
541
gen_sym_offset (ax, var)
542
     struct agent_expr *ax;
543
     struct symbol *var;
544
{
545
  gen_offset (ax, SYMBOL_VALUE (var));
546
}
547
 
548
 
549
/* Generate code for a variable reference to AX.  The variable is the
550
   symbol VAR.  Set VALUE to describe the result.  */
551
 
552
static void
553
gen_var_ref (ax, value, var)
554
     struct agent_expr *ax;
555
     struct axs_value *value;
556
     struct symbol *var;
557
{
558
  /* Dereference any typedefs. */
559
  value->type = check_typedef (SYMBOL_TYPE (var));
560
 
561
  /* I'm imitating the code in read_var_value.  */
562
  switch (SYMBOL_CLASS (var))
563
    {
564
    case LOC_CONST:             /* A constant, like an enum value.  */
565
      ax_const_l (ax, (LONGEST) SYMBOL_VALUE (var));
566
      value->kind = axs_rvalue;
567
      break;
568
 
569
    case LOC_LABEL:             /* A goto label, being used as a value.  */
570
      ax_const_l (ax, (LONGEST) SYMBOL_VALUE_ADDRESS (var));
571
      value->kind = axs_rvalue;
572
      break;
573
 
574
    case LOC_CONST_BYTES:
575
      internal_error ("ax-gdb.c (gen_var_ref): LOC_CONST_BYTES symbols are not supported");
576
 
577
      /* Variable at a fixed location in memory.  Easy.  */
578
    case LOC_STATIC:
579
      /* Push the address of the variable.  */
580
      ax_const_l (ax, SYMBOL_VALUE_ADDRESS (var));
581
      value->kind = axs_lvalue_memory;
582
      break;
583
 
584
    case LOC_ARG:               /* var lives in argument area of frame */
585
      gen_frame_args_address (ax);
586
      gen_sym_offset (ax, var);
587
      value->kind = axs_lvalue_memory;
588
      break;
589
 
590
    case LOC_REF_ARG:           /* As above, but the frame slot really
591
                                   holds the address of the variable.  */
592
      gen_frame_args_address (ax);
593
      gen_sym_offset (ax, var);
594
      /* Don't assume any particular pointer size.  */
595
      gen_fetch (ax, lookup_pointer_type (builtin_type_void));
596
      value->kind = axs_lvalue_memory;
597
      break;
598
 
599
    case LOC_LOCAL:             /* var lives in locals area of frame */
600
    case LOC_LOCAL_ARG:
601
      gen_frame_locals_address (ax);
602
      gen_sym_offset (ax, var);
603
      value->kind = axs_lvalue_memory;
604
      break;
605
 
606
    case LOC_BASEREG:           /* relative to some base register */
607
    case LOC_BASEREG_ARG:
608
      ax_reg (ax, SYMBOL_BASEREG (var));
609
      gen_sym_offset (ax, var);
610
      value->kind = axs_lvalue_memory;
611
      break;
612
 
613
    case LOC_TYPEDEF:
614
      error ("Cannot compute value of typedef `%s'.",
615
             SYMBOL_SOURCE_NAME (var));
616
      break;
617
 
618
    case LOC_BLOCK:
619
      ax_const_l (ax, BLOCK_START (SYMBOL_BLOCK_VALUE (var)));
620
      value->kind = axs_rvalue;
621
      break;
622
 
623
    case LOC_REGISTER:
624
    case LOC_REGPARM:
625
      /* Don't generate any code at all; in the process of treating
626
         this as an lvalue or rvalue, the caller will generate the
627
         right code.  */
628
      value->kind = axs_lvalue_register;
629
      value->u.reg = SYMBOL_VALUE (var);
630
      break;
631
 
632
      /* A lot like LOC_REF_ARG, but the pointer lives directly in a
633
         register, not on the stack.  Simpler than LOC_REGISTER and
634
         LOC_REGPARM, because it's just like any other case where the
635
         thing has a real address.  */
636
    case LOC_REGPARM_ADDR:
637
      ax_reg (ax, SYMBOL_VALUE (var));
638
      value->kind = axs_lvalue_memory;
639
      break;
640
 
641
    case LOC_UNRESOLVED:
642
      {
643
        struct minimal_symbol *msym
644
        = lookup_minimal_symbol (SYMBOL_NAME (var), NULL, NULL);
645
        if (!msym)
646
          error ("Couldn't resolve symbol `%s'.", SYMBOL_SOURCE_NAME (var));
647
 
648
        /* Push the address of the variable.  */
649
        ax_const_l (ax, SYMBOL_VALUE_ADDRESS (msym));
650
        value->kind = axs_lvalue_memory;
651
      }
652
      break;
653
 
654
    case LOC_OPTIMIZED_OUT:
655
      error ("The variable `%s' has been optimized out.",
656
             SYMBOL_SOURCE_NAME (var));
657
      break;
658
 
659
    default:
660
      error ("Cannot find value of botched symbol `%s'.",
661
             SYMBOL_SOURCE_NAME (var));
662
      break;
663
    }
664
}
665
 
666
 
667
 
668
/* Generating bytecode from GDB expressions: literals */
669
 
670
static void
671
gen_int_literal (ax, value, k, type)
672
     struct agent_expr *ax;
673
     struct axs_value *value;
674
     LONGEST k;
675
     struct type *type;
676
{
677
  ax_const_l (ax, k);
678
  value->kind = axs_rvalue;
679
  value->type = type;
680
}
681
 
682
 
683
 
684
/* Generating bytecode from GDB expressions: unary conversions, casts */
685
 
686
/* Take what's on the top of the stack (as described by VALUE), and
687
   try to make an rvalue out of it.  Signal an error if we can't do
688
   that.  */
689
static void
690
require_rvalue (ax, value)
691
     struct agent_expr *ax;
692
     struct axs_value *value;
693
{
694
  switch (value->kind)
695
    {
696
    case axs_rvalue:
697
      /* It's already an rvalue.  */
698
      break;
699
 
700
    case axs_lvalue_memory:
701
      /* The top of stack is the address of the object.  Dereference.  */
702
      gen_fetch (ax, value->type);
703
      break;
704
 
705
    case axs_lvalue_register:
706
      /* There's nothing on the stack, but value->u.reg is the
707
         register number containing the value.
708
 
709
         When we add floating-point support, this is going to have to
710
         change.  What about SPARC register pairs, for example?  */
711
      ax_reg (ax, value->u.reg);
712
      gen_extend (ax, value->type);
713
      break;
714
    }
715
 
716
  value->kind = axs_rvalue;
717
}
718
 
719
 
720
/* Assume the top of the stack is described by VALUE, and perform the
721
   usual unary conversions.  This is motivated by ANSI 6.2.2, but of
722
   course GDB expressions are not ANSI; they're the mishmash union of
723
   a bunch of languages.  Rah.
724
 
725
   NOTE!  This function promises to produce an rvalue only when the
726
   incoming value is of an appropriate type.  In other words, the
727
   consumer of the value this function produces may assume the value
728
   is an rvalue only after checking its type.
729
 
730
   The immediate issue is that if the user tries to use a structure or
731
   union as an operand of, say, the `+' operator, we don't want to try
732
   to convert that structure to an rvalue; require_rvalue will bomb on
733
   structs and unions.  Rather, we want to simply pass the struct
734
   lvalue through unchanged, and let `+' raise an error.  */
735
 
736
static void
737
gen_usual_unary (ax, value)
738
     struct agent_expr *ax;
739
     struct axs_value *value;
740
{
741
  /* We don't have to generate any code for the usual integral
742
     conversions, since values are always represented as full-width on
743
     the stack.  Should we tweak the type?  */
744
 
745
  /* Some types require special handling.  */
746
  switch (value->type->code)
747
    {
748
      /* Functions get converted to a pointer to the function.  */
749
    case TYPE_CODE_FUNC:
750
      value->type = lookup_pointer_type (value->type);
751
      value->kind = axs_rvalue; /* Should always be true, but just in case.  */
752
      break;
753
 
754
      /* Arrays get converted to a pointer to their first element, and
755
         are no longer an lvalue.  */
756
    case TYPE_CODE_ARRAY:
757
      {
758
        struct type *elements = TYPE_TARGET_TYPE (value->type);
759
        value->type = lookup_pointer_type (elements);
760
        value->kind = axs_rvalue;
761
        /* We don't need to generate any code; the address of the array
762
           is also the address of its first element.  */
763
      }
764
      break;
765
 
766
      /* Don't try to convert structures and unions to rvalues.  Let the
767
         consumer signal an error.  */
768
    case TYPE_CODE_STRUCT:
769
    case TYPE_CODE_UNION:
770
      return;
771
 
772
      /* If the value is an enum, call it an integer.  */
773
    case TYPE_CODE_ENUM:
774
      value->type = builtin_type_int;
775
      break;
776
    }
777
 
778
  /* If the value is an lvalue, dereference it.  */
779
  require_rvalue (ax, value);
780
}
781
 
782
 
783
/* Return non-zero iff the type TYPE1 is considered "wider" than the
784
   type TYPE2, according to the rules described in gen_usual_arithmetic.  */
785
static int
786
type_wider_than (type1, type2)
787
     struct type *type1, *type2;
788
{
789
  return (TYPE_LENGTH (type1) > TYPE_LENGTH (type2)
790
          || (TYPE_LENGTH (type1) == TYPE_LENGTH (type2)
791
              && TYPE_UNSIGNED (type1)
792
              && !TYPE_UNSIGNED (type2)));
793
}
794
 
795
 
796
/* Return the "wider" of the two types TYPE1 and TYPE2.  */
797
static struct type *
798
max_type (type1, type2)
799
     struct type *type1, *type2;
800
{
801
  return type_wider_than (type1, type2) ? type1 : type2;
802
}
803
 
804
 
805
/* Generate code to convert a scalar value of type FROM to type TO.  */
806
static void
807
gen_conversion (ax, from, to)
808
     struct agent_expr *ax;
809
     struct type *from, *to;
810
{
811
  /* Perhaps there is a more graceful way to state these rules.  */
812
 
813
  /* If we're converting to a narrower type, then we need to clear out
814
     the upper bits.  */
815
  if (TYPE_LENGTH (to) < TYPE_LENGTH (from))
816
    gen_extend (ax, from);
817
 
818
  /* If the two values have equal width, but different signednesses,
819
     then we need to extend.  */
820
  else if (TYPE_LENGTH (to) == TYPE_LENGTH (from))
821
    {
822
      if (TYPE_UNSIGNED (from) != TYPE_UNSIGNED (to))
823
        gen_extend (ax, to);
824
    }
825
 
826
  /* If we're converting to a wider type, and becoming unsigned, then
827
     we need to zero out any possible sign bits.  */
828
  else if (TYPE_LENGTH (to) > TYPE_LENGTH (from))
829
    {
830
      if (TYPE_UNSIGNED (to))
831
        gen_extend (ax, to);
832
    }
833
}
834
 
835
 
836
/* Return non-zero iff the type FROM will require any bytecodes to be
837
   emitted to be converted to the type TO.  */
838
static int
839
is_nontrivial_conversion (from, to)
840
     struct type *from, *to;
841
{
842
  struct agent_expr *ax = new_agent_expr (0);
843
  int nontrivial;
844
 
845
  /* Actually generate the code, and see if anything came out.  At the
846
     moment, it would be trivial to replicate the code in
847
     gen_conversion here, but in the future, when we're supporting
848
     floating point and the like, it may not be.  Doing things this
849
     way allows this function to be independent of the logic in
850
     gen_conversion.  */
851
  gen_conversion (ax, from, to);
852
  nontrivial = ax->len > 0;
853
  free_agent_expr (ax);
854
  return nontrivial;
855
}
856
 
857
 
858
/* Generate code to perform the "usual arithmetic conversions" (ANSI C
859
   6.2.1.5) for the two operands of an arithmetic operator.  This
860
   effectively finds a "least upper bound" type for the two arguments,
861
   and promotes each argument to that type.  *VALUE1 and *VALUE2
862
   describe the values as they are passed in, and as they are left.  */
863
static void
864
gen_usual_arithmetic (ax, value1, value2)
865
     struct agent_expr *ax;
866
     struct axs_value *value1, *value2;
867
{
868
  /* Do the usual binary conversions.  */
869
  if (TYPE_CODE (value1->type) == TYPE_CODE_INT
870
      && TYPE_CODE (value2->type) == TYPE_CODE_INT)
871
    {
872
      /* The ANSI integral promotions seem to work this way: Order the
873
         integer types by size, and then by signedness: an n-bit
874
         unsigned type is considered "wider" than an n-bit signed
875
         type.  Promote to the "wider" of the two types, and always
876
         promote at least to int.  */
877
      struct type *target = max_type (builtin_type_int,
878
                                      max_type (value1->type, value2->type));
879
 
880
      /* Deal with value2, on the top of the stack.  */
881
      gen_conversion (ax, value2->type, target);
882
 
883
      /* Deal with value1, not on the top of the stack.  Don't
884
         generate the `swap' instructions if we're not actually going
885
         to do anything.  */
886
      if (is_nontrivial_conversion (value1->type, target))
887
        {
888
          ax_simple (ax, aop_swap);
889
          gen_conversion (ax, value1->type, target);
890
          ax_simple (ax, aop_swap);
891
        }
892
 
893
      value1->type = value2->type = target;
894
    }
895
}
896
 
897
 
898
/* Generate code to perform the integral promotions (ANSI 6.2.1.1) on
899
   the value on the top of the stack, as described by VALUE.  Assume
900
   the value has integral type.  */
901
static void
902
gen_integral_promotions (ax, value)
903
     struct agent_expr *ax;
904
     struct axs_value *value;
905
{
906
  if (!type_wider_than (value->type, builtin_type_int))
907
    {
908
      gen_conversion (ax, value->type, builtin_type_int);
909
      value->type = builtin_type_int;
910
    }
911
  else if (!type_wider_than (value->type, builtin_type_unsigned_int))
912
    {
913
      gen_conversion (ax, value->type, builtin_type_unsigned_int);
914
      value->type = builtin_type_unsigned_int;
915
    }
916
}
917
 
918
 
919
/* Generate code for a cast to TYPE.  */
920
static void
921
gen_cast (ax, value, type)
922
     struct agent_expr *ax;
923
     struct axs_value *value;
924
     struct type *type;
925
{
926
  /* GCC does allow casts to yield lvalues, so this should be fixed
927
     before merging these changes into the trunk.  */
928
  require_rvalue (ax, value);
929
  /* Dereference typedefs. */
930
  type = check_typedef (type);
931
 
932
  switch (type->code)
933
    {
934
    case TYPE_CODE_PTR:
935
      /* It's implementation-defined, and I'll bet this is what GCC
936
         does.  */
937
      break;
938
 
939
    case TYPE_CODE_ARRAY:
940
    case TYPE_CODE_STRUCT:
941
    case TYPE_CODE_UNION:
942
    case TYPE_CODE_FUNC:
943
      error ("Illegal type cast: intended type must be scalar.");
944
 
945
    case TYPE_CODE_ENUM:
946
      /* We don't have to worry about the size of the value, because
947
         all our integral values are fully sign-extended, and when
948
         casting pointers we can do anything we like.  Is there any
949
         way for us to actually know what GCC actually does with a
950
         cast like this?  */
951
      value->type = type;
952
      break;
953
 
954
    case TYPE_CODE_INT:
955
      gen_conversion (ax, value->type, type);
956
      break;
957
 
958
    case TYPE_CODE_VOID:
959
      /* We could pop the value, and rely on everyone else to check
960
         the type and notice that this value doesn't occupy a stack
961
         slot.  But for now, leave the value on the stack, and
962
         preserve the "value == stack element" assumption.  */
963
      break;
964
 
965
    default:
966
      error ("Casts to requested type are not yet implemented.");
967
    }
968
 
969
  value->type = type;
970
}
971
 
972
 
973
 
974
/* Generating bytecode from GDB expressions: arithmetic */
975
 
976
/* Scale the integer on the top of the stack by the size of the target
977
   of the pointer type TYPE.  */
978
static void
979
gen_scale (ax, op, type)
980
     struct agent_expr *ax;
981
     enum agent_op op;
982
     struct type *type;
983
{
984
  struct type *element = TYPE_TARGET_TYPE (type);
985
 
986
  if (element->length != 1)
987
    {
988
      ax_const_l (ax, element->length);
989
      ax_simple (ax, op);
990
    }
991
}
992
 
993
 
994
/* Generate code for an addition; non-trivial because we deal with
995
   pointer arithmetic.  We set VALUE to describe the result value; we
996
   assume VALUE1 and VALUE2 describe the two operands, and that
997
   they've undergone the usual binary conversions.  Used by both
998
   BINOP_ADD and BINOP_SUBSCRIPT.  NAME is used in error messages.  */
999
static void
1000
gen_add (ax, value, value1, value2, name)
1001
     struct agent_expr *ax;
1002
     struct axs_value *value, *value1, *value2;
1003
     char *name;
1004
{
1005
  /* Is it INT+PTR?  */
1006
  if (value1->type->code == TYPE_CODE_INT
1007
      && value2->type->code == TYPE_CODE_PTR)
1008
    {
1009
      /* Swap the values and proceed normally.  */
1010
      ax_simple (ax, aop_swap);
1011
      gen_scale (ax, aop_mul, value2->type);
1012
      ax_simple (ax, aop_add);
1013
      gen_extend (ax, value2->type);    /* Catch overflow.  */
1014
      value->type = value2->type;
1015
    }
1016
 
1017
  /* Is it PTR+INT?  */
1018
  else if (value1->type->code == TYPE_CODE_PTR
1019
           && value2->type->code == TYPE_CODE_INT)
1020
    {
1021
      gen_scale (ax, aop_mul, value1->type);
1022
      ax_simple (ax, aop_add);
1023
      gen_extend (ax, value1->type);    /* Catch overflow.  */
1024
      value->type = value1->type;
1025
    }
1026
 
1027
  /* Must be number + number; the usual binary conversions will have
1028
     brought them both to the same width.  */
1029
  else if (value1->type->code == TYPE_CODE_INT
1030
           && value2->type->code == TYPE_CODE_INT)
1031
    {
1032
      ax_simple (ax, aop_add);
1033
      gen_extend (ax, value1->type);    /* Catch overflow.  */
1034
      value->type = value1->type;
1035
    }
1036
 
1037
  else
1038
    error ("Illegal combination of types in %s.", name);
1039
 
1040
  value->kind = axs_rvalue;
1041
}
1042
 
1043
 
1044
/* Generate code for an addition; non-trivial because we have to deal
1045
   with pointer arithmetic.  We set VALUE to describe the result
1046
   value; we assume VALUE1 and VALUE2 describe the two operands, and
1047
   that they've undergone the usual binary conversions.  */
1048
static void
1049
gen_sub (ax, value, value1, value2)
1050
     struct agent_expr *ax;
1051
     struct axs_value *value, *value1, *value2;
1052
{
1053
  if (value1->type->code == TYPE_CODE_PTR)
1054
    {
1055
      /* Is it PTR - INT?  */
1056
      if (value2->type->code == TYPE_CODE_INT)
1057
        {
1058
          gen_scale (ax, aop_mul, value1->type);
1059
          ax_simple (ax, aop_sub);
1060
          gen_extend (ax, value1->type);        /* Catch overflow.  */
1061
          value->type = value1->type;
1062
        }
1063
 
1064
      /* Is it PTR - PTR?  Strictly speaking, the types ought to
1065
         match, but this is what the normal GDB expression evaluator
1066
         tests for.  */
1067
      else if (value2->type->code == TYPE_CODE_PTR
1068
               && (TYPE_LENGTH (TYPE_TARGET_TYPE (value1->type))
1069
                   == TYPE_LENGTH (TYPE_TARGET_TYPE (value2->type))))
1070
        {
1071
          ax_simple (ax, aop_sub);
1072
          gen_scale (ax, aop_div_unsigned, value1->type);
1073
          value->type = builtin_type_long;      /* FIXME --- should be ptrdiff_t */
1074
        }
1075
      else
1076
        error ("\
1077
First argument of `-' is a pointer, but second argument is neither\n\
1078
an integer nor a pointer of the same type.");
1079
    }
1080
 
1081
  /* Must be number + number.  */
1082
  else if (value1->type->code == TYPE_CODE_INT
1083
           && value2->type->code == TYPE_CODE_INT)
1084
    {
1085
      ax_simple (ax, aop_sub);
1086
      gen_extend (ax, value1->type);    /* Catch overflow.  */
1087
      value->type = value1->type;
1088
    }
1089
 
1090
  else
1091
    error ("Illegal combination of types in subtraction.");
1092
 
1093
  value->kind = axs_rvalue;
1094
}
1095
 
1096
/* Generate code for a binary operator that doesn't do pointer magic.
1097
   We set VALUE to describe the result value; we assume VALUE1 and
1098
   VALUE2 describe the two operands, and that they've undergone the
1099
   usual binary conversions.  MAY_CARRY should be non-zero iff the
1100
   result needs to be extended.  NAME is the English name of the
1101
   operator, used in error messages */
1102
static void
1103
gen_binop (ax, value, value1, value2, op, op_unsigned, may_carry, name)
1104
     struct agent_expr *ax;
1105
     struct axs_value *value, *value1, *value2;
1106
     enum agent_op op, op_unsigned;
1107
     int may_carry;
1108
     char *name;
1109
{
1110
  /* We only handle INT op INT.  */
1111
  if ((value1->type->code != TYPE_CODE_INT)
1112
      || (value2->type->code != TYPE_CODE_INT))
1113
    error ("Illegal combination of types in %s.", name);
1114
 
1115
  ax_simple (ax,
1116
             TYPE_UNSIGNED (value1->type) ? op_unsigned : op);
1117
  if (may_carry)
1118
    gen_extend (ax, value1->type);      /* catch overflow */
1119
  value->type = value1->type;
1120
  value->kind = axs_rvalue;
1121
}
1122
 
1123
 
1124
static void
1125
gen_logical_not (ax, value)
1126
     struct agent_expr *ax;
1127
     struct axs_value *value;
1128
{
1129
  if (TYPE_CODE (value->type) != TYPE_CODE_INT
1130
      && TYPE_CODE (value->type) != TYPE_CODE_PTR)
1131
    error ("Illegal type of operand to `!'.");
1132
 
1133
  gen_usual_unary (ax, value);
1134
  ax_simple (ax, aop_log_not);
1135
  value->type = builtin_type_int;
1136
}
1137
 
1138
 
1139
static void
1140
gen_complement (ax, value)
1141
     struct agent_expr *ax;
1142
     struct axs_value *value;
1143
{
1144
  if (TYPE_CODE (value->type) != TYPE_CODE_INT)
1145
    error ("Illegal type of operand to `~'.");
1146
 
1147
  gen_usual_unary (ax, value);
1148
  gen_integral_promotions (ax, value);
1149
  ax_simple (ax, aop_bit_not);
1150
  gen_extend (ax, value->type);
1151
}
1152
 
1153
 
1154
 
1155
/* Generating bytecode from GDB expressions: * & . -> @ sizeof */
1156
 
1157
/* Dereference the value on the top of the stack.  */
1158
static void
1159
gen_deref (ax, value)
1160
     struct agent_expr *ax;
1161
     struct axs_value *value;
1162
{
1163
  /* The caller should check the type, because several operators use
1164
     this, and we don't know what error message to generate.  */
1165
  if (value->type->code != TYPE_CODE_PTR)
1166
    internal_error ("ax-gdb.c (gen_deref): expected a pointer");
1167
 
1168
  /* We've got an rvalue now, which is a pointer.  We want to yield an
1169
     lvalue, whose address is exactly that pointer.  So we don't
1170
     actually emit any code; we just change the type from "Pointer to
1171
     T" to "T", and mark the value as an lvalue in memory.  Leave it
1172
     to the consumer to actually dereference it.  */
1173
  value->type = check_typedef (TYPE_TARGET_TYPE (value->type));
1174
  value->kind = ((value->type->code == TYPE_CODE_FUNC)
1175
                 ? axs_rvalue : axs_lvalue_memory);
1176
}
1177
 
1178
 
1179
/* Produce the address of the lvalue on the top of the stack.  */
1180
static void
1181
gen_address_of (ax, value)
1182
     struct agent_expr *ax;
1183
     struct axs_value *value;
1184
{
1185
  /* Special case for taking the address of a function.  The ANSI
1186
     standard describes this as a special case, too, so this
1187
     arrangement is not without motivation.  */
1188
  if (value->type->code == TYPE_CODE_FUNC)
1189
    /* The value's already an rvalue on the stack, so we just need to
1190
       change the type.  */
1191
    value->type = lookup_pointer_type (value->type);
1192
  else
1193
    switch (value->kind)
1194
      {
1195
      case axs_rvalue:
1196
        error ("Operand of `&' is an rvalue, which has no address.");
1197
 
1198
      case axs_lvalue_register:
1199
        error ("Operand of `&' is in a register, and has no address.");
1200
 
1201
      case axs_lvalue_memory:
1202
        value->kind = axs_rvalue;
1203
        value->type = lookup_pointer_type (value->type);
1204
        break;
1205
      }
1206
}
1207
 
1208
 
1209
/* A lot of this stuff will have to change to support C++.  But we're
1210
   not going to deal with that at the moment.  */
1211
 
1212
/* Find the field in the structure type TYPE named NAME, and return
1213
   its index in TYPE's field array.  */
1214
static int
1215
find_field (type, name)
1216
     struct type *type;
1217
     char *name;
1218
{
1219
  int i;
1220
 
1221
  CHECK_TYPEDEF (type);
1222
 
1223
  /* Make sure this isn't C++.  */
1224
  if (TYPE_N_BASECLASSES (type) != 0)
1225
    internal_error ("ax-gdb.c (find_field): derived classes supported");
1226
 
1227
  for (i = 0; i < TYPE_NFIELDS (type); i++)
1228
    {
1229
      char *this_name = TYPE_FIELD_NAME (type, i);
1230
 
1231
      if (this_name && STREQ (name, this_name))
1232
        return i;
1233
 
1234
      if (this_name[0] == '\0')
1235
        internal_error ("ax-gdb.c (find_field): anonymous unions not supported");
1236
    }
1237
 
1238
  error ("Couldn't find member named `%s' in struct/union `%s'",
1239
         name, type->tag_name);
1240
 
1241
  return 0;
1242
}
1243
 
1244
 
1245
/* Generate code to push the value of a bitfield of a structure whose
1246
   address is on the top of the stack.  START and END give the
1247
   starting and one-past-ending *bit* numbers of the field within the
1248
   structure.  */
1249
static void
1250
gen_bitfield_ref (ax, value, type, start, end)
1251
     struct agent_expr *ax;
1252
     struct axs_value *value;
1253
     struct type *type;
1254
     int start, end;
1255
{
1256
  /* Note that ops[i] fetches 8 << i bits.  */
1257
  static enum agent_op ops[]
1258
  =
1259
  {aop_ref8, aop_ref16, aop_ref32, aop_ref64};
1260
  static int num_ops = (sizeof (ops) / sizeof (ops[0]));
1261
 
1262
  /* We don't want to touch any byte that the bitfield doesn't
1263
     actually occupy; we shouldn't make any accesses we're not
1264
     explicitly permitted to.  We rely here on the fact that the
1265
     bytecode `ref' operators work on unaligned addresses.
1266
 
1267
     It takes some fancy footwork to get the stack to work the way
1268
     we'd like.  Say we're retrieving a bitfield that requires three
1269
     fetches.  Initially, the stack just contains the address:
1270
     addr
1271
     For the first fetch, we duplicate the address
1272
     addr addr
1273
     then add the byte offset, do the fetch, and shift and mask as
1274
     needed, yielding a fragment of the value, properly aligned for
1275
     the final bitwise or:
1276
     addr frag1
1277
     then we swap, and repeat the process:
1278
     frag1 addr                    --- address on top
1279
     frag1 addr addr               --- duplicate it
1280
     frag1 addr frag2              --- get second fragment
1281
     frag1 frag2 addr              --- swap again
1282
     frag1 frag2 frag3             --- get third fragment
1283
     Notice that, since the third fragment is the last one, we don't
1284
     bother duplicating the address this time.  Now we have all the
1285
     fragments on the stack, and we can simply `or' them together,
1286
     yielding the final value of the bitfield.  */
1287
 
1288
  /* The first and one-after-last bits in the field, but rounded down
1289
     and up to byte boundaries.  */
1290
  int bound_start = (start / TARGET_CHAR_BIT) * TARGET_CHAR_BIT;
1291
  int bound_end = (((end + TARGET_CHAR_BIT - 1)
1292
                    / TARGET_CHAR_BIT)
1293
                   * TARGET_CHAR_BIT);
1294
 
1295
  /* current bit offset within the structure */
1296
  int offset;
1297
 
1298
  /* The index in ops of the opcode we're considering.  */
1299
  int op;
1300
 
1301
  /* The number of fragments we generated in the process.  Probably
1302
     equal to the number of `one' bits in bytesize, but who cares?  */
1303
  int fragment_count;
1304
 
1305
  /* Dereference any typedefs. */
1306
  type = check_typedef (type);
1307
 
1308
  /* Can we fetch the number of bits requested at all?  */
1309
  if ((end - start) > ((1 << num_ops) * 8))
1310
    internal_error ("ax-gdb.c (gen_bitfield_ref): bitfield too wide");
1311
 
1312
  /* Note that we know here that we only need to try each opcode once.
1313
     That may not be true on machines with weird byte sizes.  */
1314
  offset = bound_start;
1315
  fragment_count = 0;
1316
  for (op = num_ops - 1; op >= 0; op--)
1317
    {
1318
      /* number of bits that ops[op] would fetch */
1319
      int op_size = 8 << op;
1320
 
1321
      /* The stack at this point, from bottom to top, contains zero or
1322
         more fragments, then the address.  */
1323
 
1324
      /* Does this fetch fit within the bitfield?  */
1325
      if (offset + op_size <= bound_end)
1326
        {
1327
          /* Is this the last fragment?  */
1328
          int last_frag = (offset + op_size == bound_end);
1329
 
1330
          if (!last_frag)
1331
            ax_simple (ax, aop_dup);    /* keep a copy of the address */
1332
 
1333
          /* Add the offset.  */
1334
          gen_offset (ax, offset / TARGET_CHAR_BIT);
1335
 
1336
          if (trace_kludge)
1337
            {
1338
              /* Record the area of memory we're about to fetch.  */
1339
              ax_trace_quick (ax, op_size / TARGET_CHAR_BIT);
1340
            }
1341
 
1342
          /* Perform the fetch.  */
1343
          ax_simple (ax, ops[op]);
1344
 
1345
          /* Shift the bits we have to their proper position.
1346
             gen_left_shift will generate right shifts when the operand
1347
             is negative.
1348
 
1349
             A big-endian field diagram to ponder:
1350
             byte 0  byte 1  byte 2  byte 3  byte 4  byte 5  byte 6  byte 7
1351
             +------++------++------++------++------++------++------++------+
1352
             xxxxAAAAAAAAAAAAAAAAAAAAAAAAAAAABBBBBBBBBBBBBBBBCCCCCxxxxxxxxxxx
1353
             ^               ^               ^    ^
1354
             bit number      16              32              48   53
1355
             These are bit numbers as supplied by GDB.  Note that the
1356
             bit numbers run from right to left once you've fetched the
1357
             value!
1358
 
1359
             A little-endian field diagram to ponder:
1360
             byte 7  byte 6  byte 5  byte 4  byte 3  byte 2  byte 1  byte 0
1361
             +------++------++------++------++------++------++------++------+
1362
             xxxxxxxxxxxAAAAABBBBBBBBBBBBBBBBCCCCCCCCCCCCCCCCCCCCCCCCCCCCxxxx
1363
             ^               ^               ^           ^   ^
1364
             bit number     48              32              16          4   0
1365
 
1366
             In both cases, the most significant end is on the left
1367
             (i.e. normal numeric writing order), which means that you
1368
             don't go crazy thinking about `left' and `right' shifts.
1369
 
1370
             We don't have to worry about masking yet:
1371
             - If they contain garbage off the least significant end, then we
1372
             must be looking at the low end of the field, and the right
1373
             shift will wipe them out.
1374
             - If they contain garbage off the most significant end, then we
1375
             must be looking at the most significant end of the word, and
1376
             the sign/zero extension will wipe them out.
1377
             - If we're in the interior of the word, then there is no garbage
1378
             on either end, because the ref operators zero-extend.  */
1379
          if (TARGET_BYTE_ORDER == BIG_ENDIAN)
1380
            gen_left_shift (ax, end - (offset + op_size));
1381
          else
1382
            gen_left_shift (ax, offset - start);
1383
 
1384
          if (!last_frag)
1385
            /* Bring the copy of the address up to the top.  */
1386
            ax_simple (ax, aop_swap);
1387
 
1388
          offset += op_size;
1389
          fragment_count++;
1390
        }
1391
    }
1392
 
1393
  /* Generate enough bitwise `or' operations to combine all the
1394
     fragments we left on the stack.  */
1395
  while (fragment_count-- > 1)
1396
    ax_simple (ax, aop_bit_or);
1397
 
1398
  /* Sign- or zero-extend the value as appropriate.  */
1399
  ((TYPE_UNSIGNED (type) ? ax_zero_ext : ax_ext) (ax, end - start));
1400
 
1401
  /* This is *not* an lvalue.  Ugh.  */
1402
  value->kind = axs_rvalue;
1403
  value->type = type;
1404
}
1405
 
1406
 
1407
/* Generate code to reference the member named FIELD of a structure or
1408
   union.  The top of the stack, as described by VALUE, should have
1409
   type (pointer to a)* struct/union.  OPERATOR_NAME is the name of
1410
   the operator being compiled, and OPERAND_NAME is the kind of thing
1411
   it operates on; we use them in error messages.  */
1412
static void
1413
gen_struct_ref (ax, value, field, operator_name, operand_name)
1414
     struct agent_expr *ax;
1415
     struct axs_value *value;
1416
     char *field;
1417
     char *operator_name;
1418
     char *operand_name;
1419
{
1420
  struct type *type;
1421
  int i;
1422
 
1423
  /* Follow pointers until we reach a non-pointer.  These aren't the C
1424
     semantics, but they're what the normal GDB evaluator does, so we
1425
     should at least be consistent.  */
1426
  while (value->type->code == TYPE_CODE_PTR)
1427
    {
1428
      gen_usual_unary (ax, value);
1429
      gen_deref (ax, value);
1430
    }
1431
  type = value->type;
1432
 
1433
  /* This must yield a structure or a union.  */
1434
  if (TYPE_CODE (type) != TYPE_CODE_STRUCT
1435
      && TYPE_CODE (type) != TYPE_CODE_UNION)
1436
    error ("The left operand of `%s' is not a %s.",
1437
           operator_name, operand_name);
1438
 
1439
  /* And it must be in memory; we don't deal with structure rvalues,
1440
     or structures living in registers.  */
1441
  if (value->kind != axs_lvalue_memory)
1442
    error ("Structure does not live in memory.");
1443
 
1444
  i = find_field (type, field);
1445
 
1446
  /* Is this a bitfield?  */
1447
  if (TYPE_FIELD_PACKED (type, i))
1448
    gen_bitfield_ref (ax, value, TYPE_FIELD_TYPE (type, i),
1449
                      TYPE_FIELD_BITPOS (type, i),
1450
                      (TYPE_FIELD_BITPOS (type, i)
1451
                       + TYPE_FIELD_BITSIZE (type, i)));
1452
  else
1453
    {
1454
      gen_offset (ax, TYPE_FIELD_BITPOS (type, i) / TARGET_CHAR_BIT);
1455
      value->kind = axs_lvalue_memory;
1456
      value->type = TYPE_FIELD_TYPE (type, i);
1457
    }
1458
}
1459
 
1460
 
1461
/* Generate code for GDB's magical `repeat' operator.
1462
   LVALUE @ INT creates an array INT elements long, and whose elements
1463
   have the same type as LVALUE, located in memory so that LVALUE is
1464
   its first element.  For example, argv[0]@argc gives you the array
1465
   of command-line arguments.
1466
 
1467
   Unfortunately, because we have to know the types before we actually
1468
   have a value for the expression, we can't implement this perfectly
1469
   without changing the type system, having values that occupy two
1470
   stack slots, doing weird things with sizeof, etc.  So we require
1471
   the right operand to be a constant expression.  */
1472
static void
1473
gen_repeat (pc, ax, value)
1474
     union exp_element **pc;
1475
     struct agent_expr *ax;
1476
     struct axs_value *value;
1477
{
1478
  struct axs_value value1;
1479
  /* We don't want to turn this into an rvalue, so no conversions
1480
     here.  */
1481
  gen_expr (pc, ax, &value1);
1482
  if (value1.kind != axs_lvalue_memory)
1483
    error ("Left operand of `@' must be an object in memory.");
1484
 
1485
  /* Evaluate the length; it had better be a constant.  */
1486
  {
1487
    struct value *v = const_expr (pc);
1488
    int length;
1489
 
1490
    if (!v)
1491
      error ("Right operand of `@' must be a constant, in agent expressions.");
1492
    if (v->type->code != TYPE_CODE_INT)
1493
      error ("Right operand of `@' must be an integer.");
1494
    length = value_as_long (v);
1495
    if (length <= 0)
1496
      error ("Right operand of `@' must be positive.");
1497
 
1498
    /* The top of the stack is already the address of the object, so
1499
       all we need to do is frob the type of the lvalue.  */
1500
    {
1501
      /* FIXME-type-allocation: need a way to free this type when we are
1502
         done with it.  */
1503
      struct type *range
1504
      = create_range_type (0, builtin_type_int, 0, length - 1);
1505
      struct type *array = create_array_type (0, value1.type, range);
1506
 
1507
      value->kind = axs_lvalue_memory;
1508
      value->type = array;
1509
    }
1510
  }
1511
}
1512
 
1513
 
1514
/* Emit code for the `sizeof' operator.
1515
   *PC should point at the start of the operand expression; we advance it
1516
   to the first instruction after the operand.  */
1517
static void
1518
gen_sizeof (pc, ax, value)
1519
     union exp_element **pc;
1520
     struct agent_expr *ax;
1521
     struct axs_value *value;
1522
{
1523
  /* We don't care about the value of the operand expression; we only
1524
     care about its type.  However, in the current arrangement, the
1525
     only way to find an expression's type is to generate code for it.
1526
     So we generate code for the operand, and then throw it away,
1527
     replacing it with code that simply pushes its size.  */
1528
  int start = ax->len;
1529
  gen_expr (pc, ax, value);
1530
 
1531
  /* Throw away the code we just generated.  */
1532
  ax->len = start;
1533
 
1534
  ax_const_l (ax, TYPE_LENGTH (value->type));
1535
  value->kind = axs_rvalue;
1536
  value->type = builtin_type_int;
1537
}
1538
 
1539
 
1540
/* Generating bytecode from GDB expressions: general recursive thingy  */
1541
 
1542
/* A gen_expr function written by a Gen-X'er guy.
1543
   Append code for the subexpression of EXPR starting at *POS_P to AX.  */
1544
static void
1545
gen_expr (pc, ax, value)
1546
     union exp_element **pc;
1547
     struct agent_expr *ax;
1548
     struct axs_value *value;
1549
{
1550
  /* Used to hold the descriptions of operand expressions.  */
1551
  struct axs_value value1, value2;
1552
  enum exp_opcode op = (*pc)[0].opcode;
1553
 
1554
  /* If we're looking at a constant expression, just push its value.  */
1555
  {
1556
    struct value *v = maybe_const_expr (pc);
1557
 
1558
    if (v)
1559
      {
1560
        ax_const_l (ax, value_as_long (v));
1561
        value->kind = axs_rvalue;
1562
        value->type = check_typedef (VALUE_TYPE (v));
1563
        return;
1564
      }
1565
  }
1566
 
1567
  /* Otherwise, go ahead and generate code for it.  */
1568
  switch (op)
1569
    {
1570
      /* Binary arithmetic operators.  */
1571
    case BINOP_ADD:
1572
    case BINOP_SUB:
1573
    case BINOP_MUL:
1574
    case BINOP_DIV:
1575
    case BINOP_REM:
1576
    case BINOP_SUBSCRIPT:
1577
    case BINOP_BITWISE_AND:
1578
    case BINOP_BITWISE_IOR:
1579
    case BINOP_BITWISE_XOR:
1580
      (*pc)++;
1581
      gen_expr (pc, ax, &value1);
1582
      gen_usual_unary (ax, &value1);
1583
      gen_expr (pc, ax, &value2);
1584
      gen_usual_unary (ax, &value2);
1585
      gen_usual_arithmetic (ax, &value1, &value2);
1586
      switch (op)
1587
        {
1588
        case BINOP_ADD:
1589
          gen_add (ax, value, &value1, &value2, "addition");
1590
          break;
1591
        case BINOP_SUB:
1592
          gen_sub (ax, value, &value1, &value2);
1593
          break;
1594
        case BINOP_MUL:
1595
          gen_binop (ax, value, &value1, &value2,
1596
                     aop_mul, aop_mul, 1, "multiplication");
1597
          break;
1598
        case BINOP_DIV:
1599
          gen_binop (ax, value, &value1, &value2,
1600
                     aop_div_signed, aop_div_unsigned, 1, "division");
1601
          break;
1602
        case BINOP_REM:
1603
          gen_binop (ax, value, &value1, &value2,
1604
                     aop_rem_signed, aop_rem_unsigned, 1, "remainder");
1605
          break;
1606
        case BINOP_SUBSCRIPT:
1607
          gen_add (ax, value, &value1, &value2, "array subscripting");
1608
          if (TYPE_CODE (value->type) != TYPE_CODE_PTR)
1609
            error ("Illegal combination of types in array subscripting.");
1610
          gen_deref (ax, value);
1611
          break;
1612
        case BINOP_BITWISE_AND:
1613
          gen_binop (ax, value, &value1, &value2,
1614
                     aop_bit_and, aop_bit_and, 0, "bitwise and");
1615
          break;
1616
 
1617
        case BINOP_BITWISE_IOR:
1618
          gen_binop (ax, value, &value1, &value2,
1619
                     aop_bit_or, aop_bit_or, 0, "bitwise or");
1620
          break;
1621
 
1622
        case BINOP_BITWISE_XOR:
1623
          gen_binop (ax, value, &value1, &value2,
1624
                     aop_bit_xor, aop_bit_xor, 0, "bitwise exclusive-or");
1625
          break;
1626
 
1627
        default:
1628
          /* We should only list operators in the outer case statement
1629
             that we actually handle in the inner case statement.  */
1630
          internal_error ("ax-gdb.c (gen_expr): op case sets don't match");
1631
        }
1632
      break;
1633
 
1634
      /* Note that we need to be a little subtle about generating code
1635
         for comma.  In C, we can do some optimizations here because
1636
         we know the left operand is only being evaluated for effect.
1637
         However, if the tracing kludge is in effect, then we always
1638
         need to evaluate the left hand side fully, so that all the
1639
         variables it mentions get traced.  */
1640
    case BINOP_COMMA:
1641
      (*pc)++;
1642
      gen_expr (pc, ax, &value1);
1643
      /* Don't just dispose of the left operand.  We might be tracing,
1644
         in which case we want to emit code to trace it if it's an
1645
         lvalue.  */
1646
      gen_traced_pop (ax, &value1);
1647
      gen_expr (pc, ax, value);
1648
      /* It's the consumer's responsibility to trace the right operand.  */
1649
      break;
1650
 
1651
    case OP_LONG:               /* some integer constant */
1652
      {
1653
        struct type *type = (*pc)[1].type;
1654
        LONGEST k = (*pc)[2].longconst;
1655
        (*pc) += 4;
1656
        gen_int_literal (ax, value, k, type);
1657
      }
1658
      break;
1659
 
1660
    case OP_VAR_VALUE:
1661
      gen_var_ref (ax, value, (*pc)[2].symbol);
1662
      (*pc) += 4;
1663
      break;
1664
 
1665
    case OP_REGISTER:
1666
      {
1667
        int reg = (int) (*pc)[1].longconst;
1668
        (*pc) += 3;
1669
        value->kind = axs_lvalue_register;
1670
        value->u.reg = reg;
1671
        value->type = REGISTER_VIRTUAL_TYPE (reg);
1672
      }
1673
      break;
1674
 
1675
    case OP_INTERNALVAR:
1676
      error ("GDB agent expressions cannot use convenience variables.");
1677
 
1678
      /* Weirdo operator: see comments for gen_repeat for details.  */
1679
    case BINOP_REPEAT:
1680
      /* Note that gen_repeat handles its own argument evaluation.  */
1681
      (*pc)++;
1682
      gen_repeat (pc, ax, value);
1683
      break;
1684
 
1685
    case UNOP_CAST:
1686
      {
1687
        struct type *type = (*pc)[1].type;
1688
        (*pc) += 3;
1689
        gen_expr (pc, ax, value);
1690
        gen_cast (ax, value, type);
1691
      }
1692
      break;
1693
 
1694
    case UNOP_MEMVAL:
1695
      {
1696
        struct type *type = check_typedef ((*pc)[1].type);
1697
        (*pc) += 3;
1698
        gen_expr (pc, ax, value);
1699
        /* I'm not sure I understand UNOP_MEMVAL entirely.  I think
1700
           it's just a hack for dealing with minsyms; you take some
1701
           integer constant, pretend it's the address of an lvalue of
1702
           the given type, and dereference it.  */
1703
        if (value->kind != axs_rvalue)
1704
          /* This would be weird.  */
1705
          internal_error ("ax-gdb.c (gen_expr): OP_MEMVAL operand isn't an rvalue???");
1706
        value->type = type;
1707
        value->kind = axs_lvalue_memory;
1708
      }
1709
      break;
1710
 
1711
    case UNOP_NEG:
1712
      (*pc)++;
1713
      /* -FOO is equivalent to 0 - FOO.  */
1714
      gen_int_literal (ax, &value1, (LONGEST) 0, builtin_type_int);
1715
      gen_usual_unary (ax, &value1);    /* shouldn't do much */
1716
      gen_expr (pc, ax, &value2);
1717
      gen_usual_unary (ax, &value2);
1718
      gen_usual_arithmetic (ax, &value1, &value2);
1719
      gen_sub (ax, value, &value1, &value2);
1720
      break;
1721
 
1722
    case UNOP_LOGICAL_NOT:
1723
      (*pc)++;
1724
      gen_expr (pc, ax, value);
1725
      gen_logical_not (ax, value);
1726
      break;
1727
 
1728
    case UNOP_COMPLEMENT:
1729
      (*pc)++;
1730
      gen_expr (pc, ax, value);
1731
      gen_complement (ax, value);
1732
      break;
1733
 
1734
    case UNOP_IND:
1735
      (*pc)++;
1736
      gen_expr (pc, ax, value);
1737
      gen_usual_unary (ax, value);
1738
      if (TYPE_CODE (value->type) != TYPE_CODE_PTR)
1739
        error ("Argument of unary `*' is not a pointer.");
1740
      gen_deref (ax, value);
1741
      break;
1742
 
1743
    case UNOP_ADDR:
1744
      (*pc)++;
1745
      gen_expr (pc, ax, value);
1746
      gen_address_of (ax, value);
1747
      break;
1748
 
1749
    case UNOP_SIZEOF:
1750
      (*pc)++;
1751
      /* Notice that gen_sizeof handles its own operand, unlike most
1752
         of the other unary operator functions.  This is because we
1753
         have to throw away the code we generate.  */
1754
      gen_sizeof (pc, ax, value);
1755
      break;
1756
 
1757
    case STRUCTOP_STRUCT:
1758
    case STRUCTOP_PTR:
1759
      {
1760
        int length = (*pc)[1].longconst;
1761
        char *name = &(*pc)[2].string;
1762
 
1763
        (*pc) += 4 + BYTES_TO_EXP_ELEM (length + 1);
1764
        gen_expr (pc, ax, value);
1765
        if (op == STRUCTOP_STRUCT)
1766
          gen_struct_ref (ax, value, name, ".", "structure or union");
1767
        else if (op == STRUCTOP_PTR)
1768
          gen_struct_ref (ax, value, name, "->",
1769
                          "pointer to a structure or union");
1770
        else
1771
          /* If this `if' chain doesn't handle it, then the case list
1772
             shouldn't mention it, and we shouldn't be here.  */
1773
          internal_error ("ax-gdb.c (gen_expr): unhandled struct case");
1774
      }
1775
      break;
1776
 
1777
    case OP_TYPE:
1778
      error ("Attempt to use a type name as an expression.");
1779
 
1780
    default:
1781
      error ("Unsupported operator in expression.");
1782
    }
1783
}
1784
 
1785
 
1786
 
1787
/* Generating bytecode from GDB expressions: driver */
1788
 
1789
/* Given a GDB expression EXPR, produce a string of agent bytecode
1790
   which computes its value.  Return the agent expression, and set
1791
   *VALUE to describe its type, and whether it's an lvalue or rvalue.  */
1792
struct agent_expr *
1793
expr_to_agent (expr, value)
1794
     struct expression *expr;
1795
     struct axs_value *value;
1796
{
1797
  struct cleanup *old_chain = 0;
1798
  struct agent_expr *ax = new_agent_expr (0);
1799
  union exp_element *pc;
1800
 
1801
  old_chain = make_cleanup ((make_cleanup_func) free_agent_expr, ax);
1802
 
1803
  pc = expr->elts;
1804
  trace_kludge = 0;
1805
  gen_expr (&pc, ax, value);
1806
 
1807
  /* We have successfully built the agent expr, so cancel the cleanup
1808
     request.  If we add more cleanups that we always want done, this
1809
     will have to get more complicated.  */
1810
  discard_cleanups (old_chain);
1811
  return ax;
1812
}
1813
 
1814
 
1815
#if 0                           /* not used */
1816
/* Given a GDB expression EXPR denoting an lvalue in memory, produce a
1817
   string of agent bytecode which will leave its address and size on
1818
   the top of stack.  Return the agent expression.
1819
 
1820
   Not sure this function is useful at all.  */
1821
struct agent_expr *
1822
expr_to_address_and_size (expr)
1823
     struct expression *expr;
1824
{
1825
  struct axs_value value;
1826
  struct agent_expr *ax = expr_to_agent (expr, &value);
1827
 
1828
  /* Complain if the result is not a memory lvalue.  */
1829
  if (value.kind != axs_lvalue_memory)
1830
    {
1831
      free_agent_expr (ax);
1832
      error ("Expression does not denote an object in memory.");
1833
    }
1834
 
1835
  /* Push the object's size on the stack.  */
1836
  ax_const_l (ax, TYPE_LENGTH (value.type));
1837
 
1838
  return ax;
1839
}
1840
#endif
1841
 
1842
/* Given a GDB expression EXPR, return bytecode to trace its value.
1843
   The result will use the `trace' and `trace_quick' bytecodes to
1844
   record the value of all memory touched by the expression.  The
1845
   caller can then use the ax_reqs function to discover which
1846
   registers it relies upon.  */
1847
struct agent_expr *
1848
gen_trace_for_expr (scope, expr)
1849
     CORE_ADDR scope;
1850
     struct expression *expr;
1851
{
1852
  struct cleanup *old_chain = 0;
1853
  struct agent_expr *ax = new_agent_expr (scope);
1854
  union exp_element *pc;
1855
  struct axs_value value;
1856
 
1857
  old_chain = make_cleanup ((make_cleanup_func) free_agent_expr, ax);
1858
 
1859
  pc = expr->elts;
1860
  trace_kludge = 1;
1861
  gen_expr (&pc, ax, &value);
1862
 
1863
  /* Make sure we record the final object, and get rid of it.  */
1864
  gen_traced_pop (ax, &value);
1865
 
1866
  /* Oh, and terminate.  */
1867
  ax_simple (ax, aop_end);
1868
 
1869
  /* We have successfully built the agent expr, so cancel the cleanup
1870
     request.  If we add more cleanups that we always want done, this
1871
     will have to get more complicated.  */
1872
  discard_cleanups (old_chain);
1873
  return ax;
1874
}
1875
 
1876
 
1877
 
1878
/* The "agent" command, for testing: compile and disassemble an expression.  */
1879
 
1880
static void
1881
print_axs_value (f, value)
1882
     struct ui_file *f;
1883
     struct axs_value *value;
1884
{
1885
  switch (value->kind)
1886
    {
1887
    case axs_rvalue:
1888
      fputs_filtered ("rvalue", f);
1889
      break;
1890
 
1891
    case axs_lvalue_memory:
1892
      fputs_filtered ("memory lvalue", f);
1893
      break;
1894
 
1895
    case axs_lvalue_register:
1896
      fprintf_filtered (f, "register %d lvalue", value->u.reg);
1897
      break;
1898
    }
1899
 
1900
  fputs_filtered (" : ", f);
1901
  type_print (value->type, "", f, -1);
1902
}
1903
 
1904
 
1905
static void
1906
agent_command (exp, from_tty)
1907
     char *exp;
1908
     int from_tty;
1909
{
1910
  struct cleanup *old_chain = 0;
1911
  struct expression *expr;
1912
  struct agent_expr *agent;
1913
  struct frame_info *fi = get_current_frame (); /* need current scope */
1914
 
1915
  /* We don't deal with overlay debugging at the moment.  We need to
1916
     think more carefully about this.  If you copy this code into
1917
     another command, change the error message; the user shouldn't
1918
     have to know anything about agent expressions.  */
1919
  if (overlay_debugging)
1920
    error ("GDB can't do agent expression translation with overlays.");
1921
 
1922
  if (exp == 0)
1923
    error_no_arg ("expression to translate");
1924
 
1925
  expr = parse_expression (exp);
1926
  old_chain = make_cleanup ((make_cleanup_func) free_current_contents, &expr);
1927
  agent = gen_trace_for_expr (fi->pc, expr);
1928
  make_cleanup ((make_cleanup_func) free_agent_expr, agent);
1929
  ax_print (gdb_stdout, agent);
1930
 
1931
  /* It would be nice to call ax_reqs here to gather some general info
1932
     about the expression, and then print out the result.  */
1933
 
1934
  do_cleanups (old_chain);
1935
  dont_repeat ();
1936
}
1937
 
1938
 
1939
/* Initialization code.  */
1940
 
1941
void _initialize_ax_gdb PARAMS ((void));
1942
void
1943
_initialize_ax_gdb ()
1944
{
1945
  add_cmd ("agent", class_maintenance, agent_command,
1946
           "Translate an expression into remote agent bytecode.",
1947
           &maintenancelist);
1948
}

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