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[/] [or1k/] [trunk/] [gdb-5.3/] [gdb/] [mi/] [mi-main.c] - Blame information for rev 1765

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1 1181 sfurman
/* MI Command Set.
2
   Copyright 2000, 2001, 2002 Free Software Foundation, Inc.
3
   Contributed by Cygnus Solutions (a Red Hat company).
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 2 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, write to the Free Software
19
   Foundation, Inc., 59 Temple Place - Suite 330,
20
   Boston, MA 02111-1307, USA.  */
21
 
22
/* Work in progress */
23
 
24
#include "defs.h"
25
#include "target.h"
26
#include "inferior.h"
27
#include "gdb_string.h"
28
#include "top.h"
29
#include "gdbthread.h"
30
#include "mi-cmds.h"
31
#include "mi-parse.h"
32
#include "mi-getopt.h"
33
#include "mi-console.h"
34
#include "ui-out.h"
35
#include "mi-out.h"
36
#include "event-loop.h"
37
#include "event-top.h"
38
#include "gdbcore.h"            /* for write_memory() */
39
#include "value.h"              /* for write_register_bytes() */
40
#include "regcache.h"
41
#include "gdb.h"
42
#include <ctype.h>
43
#include <sys/time.h>
44
 
45
enum
46
  {
47
    FROM_TTY = 0
48
  };
49
 
50
/* Enumerations of the actions that may result from calling
51
   captured_mi_execute_command */
52
 
53
enum captured_mi_execute_command_actions
54
  {
55
    EXECUTE_COMMAND_DISPLAY_PROMPT,
56
    EXECUTE_COMMAND_SUPRESS_PROMPT,
57
    EXECUTE_COMMAND_DISPLAY_ERROR
58
  };
59
 
60
/* This structure is used to pass information from captured_mi_execute_command
61
   to mi_execute_command. */
62
struct captured_mi_execute_command_args
63
{
64
  /* This return result of the MI command (output) */
65
  enum mi_cmd_result rc;
66
 
67
  /* What action to perform when the call is finished (output) */
68
  enum captured_mi_execute_command_actions action;
69
 
70
  /* The command context to be executed (input) */
71
  struct mi_parse *command;
72
};
73
 
74
int mi_debug_p;
75
struct ui_file *raw_stdout;
76
 
77
/* The token of the last asynchronous command */
78
static char *last_async_command;
79
static char *previous_async_command;
80
static char *mi_error_message;
81
static char *old_regs;
82
 
83
extern void _initialize_mi_main (void);
84
static char *mi_input (char *);
85
static void mi_execute_command (char *cmd, int from_tty);
86
static enum mi_cmd_result mi_cmd_execute (struct mi_parse *parse);
87
 
88
static void mi_execute_cli_command (const char *cli, char *args);
89
static enum mi_cmd_result mi_execute_async_cli_command (char *mi, char *args, int from_tty);
90
static void mi_execute_command_wrapper (char *cmd);
91
 
92
void mi_exec_async_cli_cmd_continuation (struct continuation_arg *arg);
93
 
94
static int register_changed_p (int regnum);
95
static int get_register (int regnum, int format);
96
static void mi_load_progress (const char *section_name,
97
                              unsigned long sent_so_far,
98
                              unsigned long total_section,
99
                              unsigned long total_sent,
100
                              unsigned long grand_total);
101
 
102
/* FIXME: these should go in some .h file, but infcmd.c doesn't have a
103
   corresponding .h file. These wrappers will be obsolete anyway, once
104
   we pull the plug on the sanitization. */
105
extern void interrupt_target_command_wrapper (char *, int);
106
extern void return_command_wrapper (char *, int);
107
 
108
/* Command implementations. FIXME: Is this libgdb? No.  This is the MI
109
   layer that calls libgdb.  Any operation used in the below should be
110
   formalized. */
111
 
112
enum mi_cmd_result
113
mi_cmd_gdb_exit (char *command, char **argv, int argc)
114
{
115
  /* We have to print everything right here because we never return */
116
  if (last_async_command)
117
    fputs_unfiltered (last_async_command, raw_stdout);
118
  fputs_unfiltered ("^exit\n", raw_stdout);
119
  mi_out_put (uiout, raw_stdout);
120
  /* FIXME: The function called is not yet a formal libgdb function */
121
  quit_force (NULL, FROM_TTY);
122
  return MI_CMD_DONE;
123
}
124
 
125
enum mi_cmd_result
126
mi_cmd_exec_run (char *args, int from_tty)
127
{
128
  /* FIXME: Should call a libgdb function, not a cli wrapper */
129
  return mi_execute_async_cli_command ("run", args, from_tty);
130
}
131
 
132
enum mi_cmd_result
133
mi_cmd_exec_next (char *args, int from_tty)
134
{
135
  /* FIXME: Should call a libgdb function, not a cli wrapper */
136
  return mi_execute_async_cli_command ("next", args, from_tty);
137
}
138
 
139
enum mi_cmd_result
140
mi_cmd_exec_next_instruction (char *args, int from_tty)
141
{
142
  /* FIXME: Should call a libgdb function, not a cli wrapper */
143
  return mi_execute_async_cli_command ("nexti", args, from_tty);
144
}
145
 
146
enum mi_cmd_result
147
mi_cmd_exec_step (char *args, int from_tty)
148
{
149
  /* FIXME: Should call a libgdb function, not a cli wrapper */
150
  return mi_execute_async_cli_command ("step", args, from_tty);
151
}
152
 
153
enum mi_cmd_result
154
mi_cmd_exec_step_instruction (char *args, int from_tty)
155
{
156
  /* FIXME: Should call a libgdb function, not a cli wrapper */
157
  return mi_execute_async_cli_command ("stepi", args, from_tty);
158
}
159
 
160
enum mi_cmd_result
161
mi_cmd_exec_finish (char *args, int from_tty)
162
{
163
  /* FIXME: Should call a libgdb function, not a cli wrapper */
164
  return mi_execute_async_cli_command ("finish", args, from_tty);
165
}
166
 
167
enum mi_cmd_result
168
mi_cmd_exec_until (char *args, int from_tty)
169
{
170
  /* FIXME: Should call a libgdb function, not a cli wrapper */
171
  return mi_execute_async_cli_command ("until", args, from_tty);
172
}
173
 
174
enum mi_cmd_result
175
mi_cmd_exec_return (char *args, int from_tty)
176
{
177
  /* This command doesn't really execute the target, it just pops the
178
     specified number of frames. */
179
  if (*args)
180
    /* Call return_command with from_tty argument equal to 0 so as to
181
       avoid being queried. */
182
    return_command_wrapper (args, 0);
183
  else
184
    /* Call return_command with from_tty argument equal to 0 so as to
185
       avoid being queried. */
186
    return_command_wrapper (NULL, 0);
187
 
188
  /* Because we have called return_command with from_tty = 0, we need
189
     to print the frame here. */
190
  show_and_print_stack_frame (selected_frame,
191
                              frame_relative_level (selected_frame),
192
                              LOC_AND_ADDRESS);
193
 
194
  return MI_CMD_DONE;
195
}
196
 
197
enum mi_cmd_result
198
mi_cmd_exec_continue (char *args, int from_tty)
199
{
200
  /* FIXME: Should call a libgdb function, not a cli wrapper */
201
  return mi_execute_async_cli_command ("continue", args, from_tty);
202
}
203
 
204
/* Interrupt the execution of the target. Note how we must play around
205
   with the token varialbes, in order to display the current token in
206
   the result of the interrupt command, and the previous execution
207
   token when the target finally stops. See comments in
208
   mi_cmd_execute. */
209
enum mi_cmd_result
210
mi_cmd_exec_interrupt (char *args, int from_tty)
211
{
212
  if (!target_executing)
213
    {
214
      xasprintf (&mi_error_message,
215
                 "mi_cmd_exec_interrupt: Inferior not executing.");
216
      return MI_CMD_ERROR;
217
    }
218
  interrupt_target_command_wrapper (args, from_tty);
219
  if (last_async_command)
220
    fputs_unfiltered (last_async_command, raw_stdout);
221
  fputs_unfiltered ("^done", raw_stdout);
222
  xfree (last_async_command);
223
  if (previous_async_command)
224
    last_async_command = xstrdup (previous_async_command);
225
  xfree (previous_async_command);
226
  previous_async_command = NULL;
227
  mi_out_put (uiout, raw_stdout);
228
  mi_out_rewind (uiout);
229
  fputs_unfiltered ("\n", raw_stdout);
230
  return MI_CMD_QUIET;
231
}
232
 
233
enum mi_cmd_result
234
mi_cmd_thread_select (char *command, char **argv, int argc)
235
{
236
  enum gdb_rc rc;
237
 
238
  if (argc != 1)
239
    {
240
      xasprintf (&mi_error_message,
241
                 "mi_cmd_thread_select: USAGE: threadnum.");
242
      return MI_CMD_ERROR;
243
    }
244
  else
245
    rc = gdb_thread_select (uiout, argv[0]);
246
 
247
  if (rc == GDB_RC_FAIL)
248
    return MI_CMD_CAUGHT_ERROR;
249
  else
250
    return MI_CMD_DONE;
251
}
252
 
253
enum mi_cmd_result
254
mi_cmd_thread_list_ids (char *command, char **argv, int argc)
255
{
256
  enum gdb_rc rc = MI_CMD_DONE;
257
 
258
  if (argc != 0)
259
    {
260
      xasprintf (&mi_error_message,
261
                 "mi_cmd_thread_list_ids: No arguments required.");
262
      return MI_CMD_ERROR;
263
    }
264
  else
265
    rc = gdb_list_thread_ids (uiout);
266
 
267
  if (rc == GDB_RC_FAIL)
268
    return MI_CMD_CAUGHT_ERROR;
269
  else
270
    return MI_CMD_DONE;
271
}
272
 
273
enum mi_cmd_result
274
mi_cmd_data_list_register_names (char *command, char **argv, int argc)
275
{
276
  int regnum, numregs;
277
  int i;
278
 
279
  /* Note that the test for a valid register must include checking the
280
     REGISTER_NAME because NUM_REGS may be allocated for the union of
281
     the register sets within a family of related processors.  In this
282
     case, some entries of REGISTER_NAME will change depending upon
283
     the particular processor being debugged.  */
284
 
285
  numregs = NUM_REGS + NUM_PSEUDO_REGS;
286
 
287
  ui_out_list_begin (uiout, "register-names");
288
 
289
  if (argc == 0)         /* No args, just do all the regs */
290
    {
291
      for (regnum = 0;
292
           regnum < numregs;
293
           regnum++)
294
        {
295
          if (REGISTER_NAME (regnum) == NULL
296
              || *(REGISTER_NAME (regnum)) == '\0')
297
            ui_out_field_string (uiout, NULL, "");
298
          else
299
            ui_out_field_string (uiout, NULL, REGISTER_NAME (regnum));
300
        }
301
    }
302
 
303
  /* Else, list of register #s, just do listed regs */
304
  for (i = 0; i < argc; i++)
305
    {
306
      regnum = atoi (argv[i]);
307
      if (regnum < 0 || regnum >= numregs)
308
        {
309
          xasprintf (&mi_error_message, "bad register number");
310
          return MI_CMD_ERROR;
311
        }
312
      if (REGISTER_NAME (regnum) == NULL
313
          || *(REGISTER_NAME (regnum)) == '\0')
314
        ui_out_field_string (uiout, NULL, "");
315
      else
316
        ui_out_field_string (uiout, NULL, REGISTER_NAME (regnum));
317
    }
318
  ui_out_list_end (uiout);
319
  return MI_CMD_DONE;
320
}
321
 
322
enum mi_cmd_result
323
mi_cmd_data_list_changed_registers (char *command, char **argv, int argc)
324
{
325
  int regnum, numregs, changed;
326
  int i;
327
 
328
  /* Note that the test for a valid register must include checking the
329
     REGISTER_NAME because NUM_REGS may be allocated for the union of
330
     the register sets within a family of related processors.  In this
331
     case, some entries of REGISTER_NAME will change depending upon
332
     the particular processor being debugged.  */
333
 
334
  numregs = NUM_REGS;
335
 
336
  ui_out_list_begin (uiout, "changed-registers");
337
 
338
  if (argc == 0)         /* No args, just do all the regs */
339
    {
340
      for (regnum = 0;
341
           regnum < numregs;
342
           regnum++)
343
        {
344
          if (REGISTER_NAME (regnum) == NULL
345
              || *(REGISTER_NAME (regnum)) == '\0')
346
            continue;
347
          changed = register_changed_p (regnum);
348
          if (changed < 0)
349
            {
350
              xasprintf (&mi_error_message,
351
                         "mi_cmd_data_list_changed_registers: Unable to read register contents.");
352
              return MI_CMD_ERROR;
353
            }
354
          else if (changed)
355
            ui_out_field_int (uiout, NULL, regnum);
356
        }
357
    }
358
 
359
  /* Else, list of register #s, just do listed regs */
360
  for (i = 0; i < argc; i++)
361
    {
362
      regnum = atoi (argv[i]);
363
 
364
      if (regnum >= 0
365
          && regnum < numregs
366
          && REGISTER_NAME (regnum) != NULL
367
          && *REGISTER_NAME (regnum) != '\000')
368
        {
369
          changed = register_changed_p (regnum);
370
          if (changed < 0)
371
            {
372
              xasprintf (&mi_error_message,
373
                         "mi_cmd_data_list_register_change: Unable to read register contents.");
374
              return MI_CMD_ERROR;
375
            }
376
          else if (changed)
377
            ui_out_field_int (uiout, NULL, regnum);
378
        }
379
      else
380
        {
381
          xasprintf (&mi_error_message, "bad register number");
382
          return MI_CMD_ERROR;
383
        }
384
    }
385
  ui_out_list_end (uiout);
386
  return MI_CMD_DONE;
387
}
388
 
389
static int
390
register_changed_p (int regnum)
391
{
392
  char *raw_buffer = alloca (MAX_REGISTER_RAW_SIZE);
393
 
394
  if (! frame_register_read (selected_frame, regnum, raw_buffer))
395
    return -1;
396
 
397
  if (memcmp (&old_regs[REGISTER_BYTE (regnum)], raw_buffer,
398
              REGISTER_RAW_SIZE (regnum)) == 0)
399
    return 0;
400
 
401
  /* Found a changed register. Return 1. */
402
 
403
  memcpy (&old_regs[REGISTER_BYTE (regnum)], raw_buffer,
404
          REGISTER_RAW_SIZE (regnum));
405
 
406
  return 1;
407
}
408
 
409
/* Return a list of register number and value pairs. The valid
410
   arguments expected are: a letter indicating the format in which to
411
   display the registers contents. This can be one of: x (hexadecimal), d
412
   (decimal), N (natural), t (binary), o (octal), r (raw).  After the
413
   format argumetn there can be a sequence of numbers, indicating which
414
   registers to fetch the content of. If the format is the only argument,
415
   a list of all the registers with their values is returned. */
416
enum mi_cmd_result
417
mi_cmd_data_list_register_values (char *command, char **argv, int argc)
418
{
419
  int regnum, numregs, format, result;
420
  int i;
421
 
422
  /* Note that the test for a valid register must include checking the
423
     REGISTER_NAME because NUM_REGS may be allocated for the union of
424
     the register sets within a family of related processors.  In this
425
     case, some entries of REGISTER_NAME will change depending upon
426
     the particular processor being debugged.  */
427
 
428
  numregs = NUM_REGS;
429
 
430
  if (argc == 0)
431
    {
432
      xasprintf (&mi_error_message,
433
                 "mi_cmd_data_list_register_values: Usage: -data-list-register-values <format> [<regnum1>...<regnumN>]");
434
      return MI_CMD_ERROR;
435
    }
436
 
437
  format = (int) argv[0][0];
438
 
439
  if (!target_has_registers)
440
    {
441
      xasprintf (&mi_error_message,
442
                 "mi_cmd_data_list_register_values: No registers.");
443
      return MI_CMD_ERROR;
444
    }
445
 
446
  ui_out_list_begin (uiout, "register-values");
447
 
448
  if (argc == 1)                /* No args, beside the format: do all the regs */
449
    {
450
      for (regnum = 0;
451
           regnum < numregs;
452
           regnum++)
453
        {
454
          if (REGISTER_NAME (regnum) == NULL
455
              || *(REGISTER_NAME (regnum)) == '\0')
456
            continue;
457
          ui_out_tuple_begin (uiout, NULL);
458
          ui_out_field_int (uiout, "number", regnum);
459
          result = get_register (regnum, format);
460
          if (result == -1)
461
            return MI_CMD_ERROR;
462
          ui_out_tuple_end (uiout);
463
        }
464
    }
465
 
466
  /* Else, list of register #s, just do listed regs */
467
  for (i = 1; i < argc; i++)
468
    {
469
      regnum = atoi (argv[i]);
470
 
471
      if (regnum >= 0
472
          && regnum < numregs
473
          && REGISTER_NAME (regnum) != NULL
474
          && *REGISTER_NAME (regnum) != '\000')
475
        {
476
          ui_out_tuple_begin (uiout, NULL);
477
          ui_out_field_int (uiout, "number", regnum);
478
          result = get_register (regnum, format);
479
          if (result == -1)
480
            return MI_CMD_ERROR;
481
          ui_out_tuple_end (uiout);
482
        }
483
      else
484
        {
485
          xasprintf (&mi_error_message, "bad register number");
486
          return MI_CMD_ERROR;
487
        }
488
    }
489
  ui_out_list_end (uiout);
490
  return MI_CMD_DONE;
491
}
492
 
493
/* Output one register's contents in the desired format. */
494
static int
495
get_register (int regnum, int format)
496
{
497
  char *raw_buffer = alloca (MAX_REGISTER_RAW_SIZE);
498
  char *virtual_buffer = alloca (MAX_REGISTER_VIRTUAL_SIZE);
499
  int optim;
500
  static struct ui_stream *stb = NULL;
501
 
502
  stb = ui_out_stream_new (uiout);
503
 
504
  if (format == 'N')
505
    format = 0;
506
 
507
  get_saved_register (raw_buffer, &optim, (CORE_ADDR *) NULL, selected_frame,
508
                      regnum, (enum lval_type *) NULL);
509
  if (optim)
510
    {
511
      xasprintf (&mi_error_message, "Optimized out");
512
      return -1;
513
    }
514
 
515
  /* Convert raw data to virtual format if necessary.  */
516
 
517
  if (REGISTER_CONVERTIBLE (regnum))
518
    {
519
      REGISTER_CONVERT_TO_VIRTUAL (regnum, REGISTER_VIRTUAL_TYPE (regnum),
520
                                   raw_buffer, virtual_buffer);
521
    }
522
  else
523
    memcpy (virtual_buffer, raw_buffer, REGISTER_VIRTUAL_SIZE (regnum));
524
 
525
  if (format == 'r')
526
    {
527
      int j;
528
      char *ptr, buf[1024];
529
 
530
      strcpy (buf, "0x");
531
      ptr = buf + 2;
532
      for (j = 0; j < REGISTER_RAW_SIZE (regnum); j++)
533
        {
534
          register int idx = TARGET_BYTE_ORDER == BFD_ENDIAN_BIG ? j
535
          : REGISTER_RAW_SIZE (regnum) - 1 - j;
536
          sprintf (ptr, "%02x", (unsigned char) raw_buffer[idx]);
537
          ptr += 2;
538
        }
539
      ui_out_field_string (uiout, "value", buf);
540
      /*fputs_filtered (buf, gdb_stdout); */
541
    }
542
  else
543
    {
544
      val_print (REGISTER_VIRTUAL_TYPE (regnum), virtual_buffer, 0, 0,
545
                 stb->stream, format, 1, 0, Val_pretty_default);
546
      ui_out_field_stream (uiout, "value", stb);
547
      ui_out_stream_delete (stb);
548
    }
549
  return 1;
550
}
551
 
552
/* Write given values into registers. The registers and values are
553
   given as pairs. The corresponding MI command is
554
   -data-write-register-values <format> [<regnum1> <value1>...<regnumN> <valueN>]*/
555
enum mi_cmd_result
556
mi_cmd_data_write_register_values (char *command, char **argv, int argc)
557
{
558
  int regnum;
559
  int i;
560
  int numregs;
561
  LONGEST value;
562
  char format;
563
 
564
  /* Note that the test for a valid register must include checking the
565
     REGISTER_NAME because NUM_REGS may be allocated for the union of
566
     the register sets within a family of related processors.  In this
567
     case, some entries of REGISTER_NAME will change depending upon
568
     the particular processor being debugged.  */
569
 
570
  numregs = NUM_REGS;
571
 
572
  if (argc == 0)
573
    {
574
      xasprintf (&mi_error_message,
575
                 "mi_cmd_data_write_register_values: Usage: -data-write-register-values <format> [<regnum1> <value1>...<regnumN> <valueN>]");
576
      return MI_CMD_ERROR;
577
    }
578
 
579
  format = (int) argv[0][0];
580
 
581
  if (!target_has_registers)
582
    {
583
      xasprintf (&mi_error_message,
584
                 "mi_cmd_data_write_register_values: No registers.");
585
      return MI_CMD_ERROR;
586
    }
587
 
588
  if (!(argc - 1))
589
    {
590
      xasprintf (&mi_error_message,
591
                 "mi_cmd_data_write_register_values: No regs and values specified.");
592
      return MI_CMD_ERROR;
593
    }
594
 
595
  if ((argc - 1) % 2)
596
    {
597
      xasprintf (&mi_error_message,
598
                 "mi_cmd_data_write_register_values: Regs and vals are not in pairs.");
599
      return MI_CMD_ERROR;
600
    }
601
 
602
  for (i = 1; i < argc; i = i + 2)
603
    {
604
      regnum = atoi (argv[i]);
605
 
606
      if (regnum >= 0
607
          && regnum < numregs
608
          && REGISTER_NAME (regnum) != NULL
609
          && *REGISTER_NAME (regnum) != '\000')
610
        {
611
          void *buffer;
612
          struct cleanup *old_chain;
613
 
614
          /* Get the value as a number */
615
          value = parse_and_eval_address (argv[i + 1]);
616
          /* Get the value into an array */
617
          buffer = xmalloc (REGISTER_SIZE);
618
          old_chain = make_cleanup (xfree, buffer);
619
          store_signed_integer (buffer, REGISTER_SIZE, value);
620
          /* Write it down */
621
          write_register_bytes (REGISTER_BYTE (regnum), buffer, REGISTER_RAW_SIZE (regnum));
622
          /* Free the buffer.  */
623
          do_cleanups (old_chain);
624
        }
625
      else
626
        {
627
          xasprintf (&mi_error_message, "bad register number");
628
          return MI_CMD_ERROR;
629
        }
630
    }
631
  return MI_CMD_DONE;
632
}
633
 
634
#if 0
635
/*This is commented out because we decided it was not useful. I leave
636
   it, just in case. ezannoni:1999-12-08 */
637
 
638
/* Assign a value to a variable. The expression argument must be in
639
   the form A=2 or "A = 2" (I.e. if there are spaces it needs to be
640
   quoted. */
641
enum mi_cmd_result
642
mi_cmd_data_assign (char *command, char **argv, int argc)
643
{
644
  struct expression *expr;
645
  struct cleanup *old_chain;
646
 
647
  if (argc != 1)
648
    {
649
      xasprintf (&mi_error_message,
650
                 "mi_cmd_data_assign: Usage: -data-assign expression");
651
      return MI_CMD_ERROR;
652
    }
653
 
654
  /* NOTE what follows is a clone of set_command(). FIXME: ezannoni
655
     01-12-1999: Need to decide what to do with this for libgdb purposes. */
656
 
657
  expr = parse_expression (argv[0]);
658
  old_chain = make_cleanup (free_current_contents, &expr);
659
  evaluate_expression (expr);
660
  do_cleanups (old_chain);
661
  return MI_CMD_DONE;
662
}
663
#endif
664
 
665
/* Evaluate the value of the argument. The argument is an
666
   expression. If the expression contains spaces it needs to be
667
   included in double quotes. */
668
enum mi_cmd_result
669
mi_cmd_data_evaluate_expression (char *command, char **argv, int argc)
670
{
671
  struct expression *expr;
672
  struct cleanup *old_chain = NULL;
673
  struct value *val;
674
  struct ui_stream *stb = NULL;
675
 
676
  stb = ui_out_stream_new (uiout);
677
 
678
  if (argc != 1)
679
    {
680
      xasprintf (&mi_error_message,
681
                 "mi_cmd_data_evaluate_expression: Usage: -data-evaluate-expression expression");
682
      return MI_CMD_ERROR;
683
    }
684
 
685
  expr = parse_expression (argv[0]);
686
 
687
  old_chain = make_cleanup (free_current_contents, &expr);
688
 
689
  val = evaluate_expression (expr);
690
 
691
  /* Print the result of the expression evaluation. */
692
  val_print (VALUE_TYPE (val), VALUE_CONTENTS (val),
693
             VALUE_EMBEDDED_OFFSET (val), VALUE_ADDRESS (val),
694
             stb->stream, 0, 0, 0, 0);
695
 
696
  ui_out_field_stream (uiout, "value", stb);
697
  ui_out_stream_delete (stb);
698
 
699
  do_cleanups (old_chain);
700
 
701
  return MI_CMD_DONE;
702
}
703
 
704
enum mi_cmd_result
705
mi_cmd_target_download (char *args, int from_tty)
706
{
707
  char *run;
708
  struct cleanup *old_cleanups = NULL;
709
 
710
  xasprintf (&run, "load %s", args);
711
  old_cleanups = make_cleanup (xfree, run);
712
  execute_command (run, from_tty);
713
 
714
  do_cleanups (old_cleanups);
715
  return MI_CMD_DONE;
716
}
717
 
718
/* Connect to the remote target. */
719
enum mi_cmd_result
720
mi_cmd_target_select (char *args, int from_tty)
721
{
722
  char *run;
723
  struct cleanup *old_cleanups = NULL;
724
 
725
  xasprintf (&run, "target %s", args);
726
  old_cleanups = make_cleanup (xfree, run);
727
 
728
  /* target-select is always synchronous.  once the call has returned
729
     we know that we are connected. */
730
  /* NOTE: At present all targets that are connected are also
731
     (implicitly) talking to a halted target.  In the future this may
732
     change. */
733
  execute_command (run, from_tty);
734
 
735
  do_cleanups (old_cleanups);
736
 
737
  /* Issue the completion message here. */
738
  if (last_async_command)
739
    fputs_unfiltered (last_async_command, raw_stdout);
740
  fputs_unfiltered ("^connected", raw_stdout);
741
  mi_out_put (uiout, raw_stdout);
742
  mi_out_rewind (uiout);
743
  fputs_unfiltered ("\n", raw_stdout);
744
  do_exec_cleanups (ALL_CLEANUPS);
745
  return MI_CMD_QUIET;
746
}
747
 
748
/* DATA-MEMORY-READ:
749
 
750
   ADDR: start address of data to be dumped.
751
   WORD-FORMAT: a char indicating format for the ``word''. See
752
   the ``x'' command.
753
   WORD-SIZE: size of each ``word''; 1,2,4, or 8 bytes
754
   NR_ROW: Number of rows.
755
   NR_COL: The number of colums (words per row).
756
   ASCHAR: (OPTIONAL) Append an ascii character dump to each row.  Use
757
   ASCHAR for unprintable characters.
758
 
759
   Reads SIZE*NR_ROW*NR_COL bytes starting at ADDR from memory and
760
   displayes them.  Returns:
761
 
762
   {addr="...",rowN={wordN="..." ,... [,ascii="..."]}, ...}
763
 
764
   Returns:
765
   The number of bytes read is SIZE*ROW*COL. */
766
 
767
enum mi_cmd_result
768
mi_cmd_data_read_memory (char *command, char **argv, int argc)
769
{
770
  struct cleanup *cleanups = make_cleanup (null_cleanup, NULL);
771
  CORE_ADDR addr;
772
  long total_bytes;
773
  long nr_cols;
774
  long nr_rows;
775
  char word_format;
776
  struct type *word_type;
777
  long word_size;
778
  char word_asize;
779
  char aschar;
780
  char *mbuf;
781
  int nr_bytes;
782
  long offset = 0;
783
  int optind = 0;
784
  char *optarg;
785
  enum opt
786
    {
787
      OFFSET_OPT
788
    };
789
  static struct mi_opt opts[] =
790
  {
791
    {"o", OFFSET_OPT, 1},
792
 
793
  };
794
 
795
  while (1)
796
    {
797
      int opt = mi_getopt ("mi_cmd_data_read_memory", argc, argv, opts,
798
                           &optind, &optarg);
799
      if (opt < 0)
800
        break;
801
      switch ((enum opt) opt)
802
        {
803
        case OFFSET_OPT:
804
          offset = atol (optarg);
805
          break;
806
        }
807
    }
808
  argv += optind;
809
  argc -= optind;
810
 
811
  if (argc < 5 || argc > 6)
812
    {
813
      xasprintf (&mi_error_message,
814
                 "mi_cmd_data_read_memory: Usage: ADDR WORD-FORMAT WORD-SIZE NR-ROWS NR-COLS [ASCHAR].");
815
      return MI_CMD_ERROR;
816
    }
817
 
818
  /* Extract all the arguments. */
819
 
820
  /* Start address of the memory dump. */
821
  addr = parse_and_eval_address (argv[0]) + offset;
822
  /* The format character to use when displaying a memory word. See
823
     the ``x'' command. */
824
  word_format = argv[1][0];
825
  /* The size of the memory word. */
826
  word_size = atol (argv[2]);
827
  switch (word_size)
828
    {
829
    case 1:
830
      word_type = builtin_type_int8;
831
      word_asize = 'b';
832
      break;
833
    case 2:
834
      word_type = builtin_type_int16;
835
      word_asize = 'h';
836
      break;
837
    case 4:
838
      word_type = builtin_type_int32;
839
      word_asize = 'w';
840
      break;
841
    case 8:
842
      word_type = builtin_type_int64;
843
      word_asize = 'g';
844
      break;
845
    default:
846
      word_type = builtin_type_int8;
847
      word_asize = 'b';
848
    }
849
  /* The number of rows */
850
  nr_rows = atol (argv[3]);
851
  if (nr_rows <= 0)
852
    {
853
      xasprintf (&mi_error_message,
854
                 "mi_cmd_data_read_memory: invalid number of rows.");
855
      return MI_CMD_ERROR;
856
    }
857
  /* number of bytes per row. */
858
  nr_cols = atol (argv[4]);
859
  if (nr_cols <= 0)
860
    {
861
      xasprintf (&mi_error_message,
862
                 "mi_cmd_data_read_memory: invalid number of columns.");
863
    }
864
  /* The un-printable character when printing ascii. */
865
  if (argc == 6)
866
    aschar = *argv[5];
867
  else
868
    aschar = 0;
869
 
870
  /* create a buffer and read it in. */
871
  total_bytes = word_size * nr_rows * nr_cols;
872
  mbuf = xcalloc (total_bytes, 1);
873
  make_cleanup (xfree, mbuf);
874
  if (mbuf == NULL)
875
    {
876
      xasprintf (&mi_error_message,
877
                 "mi_cmd_data_read_memory: out of memory.");
878
      return MI_CMD_ERROR;
879
    }
880
  nr_bytes = 0;
881
  while (nr_bytes < total_bytes)
882
    {
883
      int error;
884
      long num = target_read_memory_partial (addr + nr_bytes, mbuf + nr_bytes,
885
                                             total_bytes - nr_bytes,
886
                                             &error);
887
      if (num <= 0)
888
        break;
889
      nr_bytes += num;
890
    }
891
 
892
  /* output the header information. */
893
  ui_out_field_core_addr (uiout, "addr", addr);
894
  ui_out_field_int (uiout, "nr-bytes", nr_bytes);
895
  ui_out_field_int (uiout, "total-bytes", total_bytes);
896
  ui_out_field_core_addr (uiout, "next-row", addr + word_size * nr_cols);
897
  ui_out_field_core_addr (uiout, "prev-row", addr - word_size * nr_cols);
898
  ui_out_field_core_addr (uiout, "next-page", addr + total_bytes);
899
  ui_out_field_core_addr (uiout, "prev-page", addr - total_bytes);
900
 
901
  /* Build the result as a two dimentional table. */
902
  {
903
    struct ui_stream *stream = ui_out_stream_new (uiout);
904
    int row;
905
    int row_byte;
906
    ui_out_list_begin (uiout, "memory");
907
    for (row = 0, row_byte = 0;
908
         row < nr_rows;
909
         row++, row_byte += nr_cols * word_size)
910
      {
911
        int col;
912
        int col_byte;
913
        ui_out_tuple_begin (uiout, NULL);
914
        ui_out_field_core_addr (uiout, "addr", addr + row_byte);
915
        /* ui_out_field_core_addr_symbolic (uiout, "saddr", addr + row_byte); */
916
        ui_out_list_begin (uiout, "data");
917
        for (col = 0, col_byte = row_byte;
918
             col < nr_cols;
919
             col++, col_byte += word_size)
920
          {
921
            if (col_byte + word_size > nr_bytes)
922
              {
923
                ui_out_field_string (uiout, NULL, "N/A");
924
              }
925
            else
926
              {
927
                ui_file_rewind (stream->stream);
928
                print_scalar_formatted (mbuf + col_byte, word_type, word_format,
929
                                        word_asize, stream->stream);
930
                ui_out_field_stream (uiout, NULL, stream);
931
              }
932
          }
933
        ui_out_list_end (uiout);
934
        if (aschar)
935
          {
936
            int byte;
937
            ui_file_rewind (stream->stream);
938
            for (byte = row_byte; byte < row_byte + word_size * nr_cols; byte++)
939
              {
940
                if (byte >= nr_bytes)
941
                  {
942
                    fputc_unfiltered ('X', stream->stream);
943
                  }
944
                else if (mbuf[byte] < 32 || mbuf[byte] > 126)
945
                  {
946
                    fputc_unfiltered (aschar, stream->stream);
947
                  }
948
                else
949
                  fputc_unfiltered (mbuf[byte], stream->stream);
950
              }
951
            ui_out_field_stream (uiout, "ascii", stream);
952
          }
953
        ui_out_tuple_end (uiout);
954
      }
955
    ui_out_stream_delete (stream);
956
    ui_out_list_end (uiout);
957
  }
958
  do_cleanups (cleanups);
959
  return MI_CMD_DONE;
960
}
961
 
962
/* DATA-MEMORY-WRITE:
963
 
964
   COLUMN_OFFSET: optional argument. Must be preceeded by '-o'. The
965
   offset from the beginning of the memory grid row where the cell to
966
   be written is.
967
   ADDR: start address of the row in the memory grid where the memory
968
   cell is, if OFFSET_COLUMN is specified. Otherwise, the address of
969
   the location to write to.
970
   FORMAT: a char indicating format for the ``word''. See
971
   the ``x'' command.
972
   WORD_SIZE: size of each ``word''; 1,2,4, or 8 bytes
973
   VALUE: value to be written into the memory address.
974
 
975
   Writes VALUE into ADDR + (COLUMN_OFFSET * WORD_SIZE).
976
 
977
   Prints nothing. */
978
enum mi_cmd_result
979
mi_cmd_data_write_memory (char *command, char **argv, int argc)
980
{
981
  CORE_ADDR addr;
982
  char word_format;
983
  long word_size;
984
  /* FIXME: ezannoni 2000-02-17 LONGEST could possibly not be big
985
     enough when using a compiler other than GCC. */
986
  LONGEST value;
987
  void *buffer;
988
  struct cleanup *old_chain;
989
  long offset = 0;
990
  int optind = 0;
991
  char *optarg;
992
  enum opt
993
    {
994
      OFFSET_OPT
995
    };
996
  static struct mi_opt opts[] =
997
  {
998
    {"o", OFFSET_OPT, 1},
999
 
1000
  };
1001
 
1002
  while (1)
1003
    {
1004
      int opt = mi_getopt ("mi_cmd_data_write_memory", argc, argv, opts,
1005
                           &optind, &optarg);
1006
      if (opt < 0)
1007
        break;
1008
      switch ((enum opt) opt)
1009
        {
1010
        case OFFSET_OPT:
1011
          offset = atol (optarg);
1012
          break;
1013
        }
1014
    }
1015
  argv += optind;
1016
  argc -= optind;
1017
 
1018
  if (argc != 4)
1019
    {
1020
      xasprintf (&mi_error_message,
1021
                 "mi_cmd_data_write_memory: Usage: [-o COLUMN_OFFSET] ADDR FORMAT WORD-SIZE VALUE.");
1022
      return MI_CMD_ERROR;
1023
    }
1024
 
1025
  /* Extract all the arguments. */
1026
  /* Start address of the memory dump. */
1027
  addr = parse_and_eval_address (argv[0]);
1028
  /* The format character to use when displaying a memory word. See
1029
     the ``x'' command. */
1030
  word_format = argv[1][0];
1031
  /* The size of the memory word. */
1032
  word_size = atol (argv[2]);
1033
 
1034
  /* Calculate the real address of the write destination. */
1035
  addr += (offset * word_size);
1036
 
1037
  /* Get the value as a number */
1038
  value = parse_and_eval_address (argv[3]);
1039
  /* Get the value into an array */
1040
  buffer = xmalloc (word_size);
1041
  old_chain = make_cleanup (xfree, buffer);
1042
  store_signed_integer (buffer, word_size, value);
1043
  /* Write it down to memory */
1044
  write_memory (addr, buffer, word_size);
1045
  /* Free the buffer.  */
1046
  do_cleanups (old_chain);
1047
 
1048
  return MI_CMD_DONE;
1049
}
1050
 
1051
/* Execute a command within a safe environment.
1052
   Return <0 for error; >=0 for ok.
1053
 
1054
   args->action will tell mi_execute_command what action
1055
   to perfrom after the given command has executed (display/supress
1056
   prompt, display error). */
1057
 
1058
static int
1059
captured_mi_execute_command (struct ui_out *uiout, void *data)
1060
{
1061
  struct captured_mi_execute_command_args *args =
1062
    (struct captured_mi_execute_command_args *) data;
1063
  struct mi_parse *context = args->command;
1064
 
1065
  switch (context->op)
1066
    {
1067
 
1068
    case MI_COMMAND:
1069
      /* A MI command was read from the input stream */
1070
      if (mi_debug_p)
1071
        /* FIXME: gdb_???? */
1072
        fprintf_unfiltered (raw_stdout, " token=`%s' command=`%s' args=`%s'\n",
1073
                            context->token, context->command, context->args);
1074
      /* FIXME: cagney/1999-09-25: Rather than this convoluted
1075
         condition expression, each function should return an
1076
         indication of what action is required and then switch on
1077
         that. */
1078
      args->action = EXECUTE_COMMAND_DISPLAY_PROMPT;
1079
      args->rc = mi_cmd_execute (context);
1080
 
1081
      if (!target_can_async_p () || !target_executing)
1082
        {
1083
          /* print the result if there were no errors */
1084
          if (args->rc == MI_CMD_DONE)
1085
            {
1086
              fputs_unfiltered (context->token, raw_stdout);
1087
              fputs_unfiltered ("^done", raw_stdout);
1088
              mi_out_put (uiout, raw_stdout);
1089
              mi_out_rewind (uiout);
1090
              fputs_unfiltered ("\n", raw_stdout);
1091
            }
1092
          else if (args->rc == MI_CMD_ERROR)
1093
            {
1094
              if (mi_error_message)
1095
                {
1096
                  fputs_unfiltered (context->token, raw_stdout);
1097
                  fputs_unfiltered ("^error,msg=\"", raw_stdout);
1098
                  fputstr_unfiltered (mi_error_message, '"', raw_stdout);
1099
                  xfree (mi_error_message);
1100
                  fputs_unfiltered ("\"\n", raw_stdout);
1101
                }
1102
              mi_out_rewind (uiout);
1103
            }
1104
          else if (args->rc == MI_CMD_CAUGHT_ERROR)
1105
            {
1106
              mi_out_rewind (uiout);
1107
              args->action = EXECUTE_COMMAND_DISPLAY_ERROR;
1108
              return 1;
1109
            }
1110
          else
1111
            mi_out_rewind (uiout);
1112
        }
1113
      else if (sync_execution)
1114
        {
1115
          /* Don't print the prompt. We are executing the target in
1116
             synchronous mode. */
1117
          args->action = EXECUTE_COMMAND_SUPRESS_PROMPT;
1118
          return 1;
1119
        }
1120
      break;
1121
 
1122
    case CLI_COMMAND:
1123
      /* A CLI command was read from the input stream */
1124
      /* This will be removed as soon as we have a complete set of
1125
         mi commands */
1126
      /* echo the command on the console. */
1127
      fprintf_unfiltered (gdb_stdlog, "%s\n", context->command);
1128
      /* FIXME: If the command string has something that looks like
1129
         a format spec (e.g. %s) we will get a core dump */
1130
      mi_execute_cli_command ("%s", context->command);
1131
      /* print the result */
1132
      /* FIXME: Check for errors here. */
1133
      fputs_unfiltered (context->token, raw_stdout);
1134
      fputs_unfiltered ("^done", raw_stdout);
1135
      mi_out_put (uiout, raw_stdout);
1136
      mi_out_rewind (uiout);
1137
      fputs_unfiltered ("\n", raw_stdout);
1138
      args->action = EXECUTE_COMMAND_DISPLAY_PROMPT;
1139
      args->rc = MI_CMD_DONE;
1140
      break;
1141
 
1142
    }
1143
 
1144
  return 1;
1145
}
1146
 
1147
 
1148
void
1149
mi_execute_command (char *cmd, int from_tty)
1150
{
1151
  struct mi_parse *command;
1152
  struct captured_mi_execute_command_args args;
1153
  struct ui_out *saved_uiout = uiout;
1154
  int result, rc;
1155
 
1156
  /* This is to handle EOF (^D). We just quit gdb. */
1157
  /* FIXME: we should call some API function here. */
1158
  if (cmd == 0)
1159
    quit_force (NULL, from_tty);
1160
 
1161
  command = mi_parse (cmd);
1162
 
1163
  if (command != NULL)
1164
    {
1165
      /* FIXME: cagney/1999-11-04: Can this use of catch_exceptions either
1166
         be pushed even further down or even eliminated? */
1167
      args.command = command;
1168
      result = catch_exceptions (uiout, captured_mi_execute_command, &args, "",
1169
                                 RETURN_MASK_ALL);
1170
 
1171
      if (args.action == EXECUTE_COMMAND_SUPRESS_PROMPT)
1172
        {
1173
          /* The command is executing synchronously.  Bail out early
1174
             suppressing the finished prompt. */
1175
          mi_parse_free (command);
1176
          return;
1177
        }
1178
      if (args.action == EXECUTE_COMMAND_DISPLAY_ERROR || result < 0)
1179
        {
1180
          char *msg = error_last_message ();
1181
          struct cleanup *cleanup = make_cleanup (xfree, msg);
1182
          /* The command execution failed and error() was called
1183
             somewhere */
1184
          fputs_unfiltered (command->token, raw_stdout);
1185
          fputs_unfiltered ("^error,msg=\"", raw_stdout);
1186
          fputstr_unfiltered (msg, '"', raw_stdout);
1187
          fputs_unfiltered ("\"\n", raw_stdout);
1188
        }
1189
      mi_parse_free (command);
1190
    }
1191
 
1192
  fputs_unfiltered ("(gdb) \n", raw_stdout);
1193
  gdb_flush (raw_stdout);
1194
  /* print any buffered hook code */
1195
  /* ..... */
1196
}
1197
 
1198
static enum mi_cmd_result
1199
mi_cmd_execute (struct mi_parse *parse)
1200
{
1201
  if (parse->cmd->argv_func != NULL
1202
      || parse->cmd->args_func != NULL)
1203
    {
1204
      /* FIXME: We need to save the token because the command executed
1205
         may be asynchronous and need to print the token again.
1206
         In the future we can pass the token down to the func
1207
         and get rid of the last_async_command */
1208
      /* The problem here is to keep the token around when we launch
1209
         the target, and we want to interrupt it later on.  The
1210
         interrupt command will have its own token, but when the
1211
         target stops, we must display the token corresponding to the
1212
         last execution command given. So we have another string where
1213
         we copy the token (previous_async_command), if this was
1214
         indeed the token of an execution command, and when we stop we
1215
         print that one. This is possible because the interrupt
1216
         command, when over, will copy that token back into the
1217
         default token string (last_async_command). */
1218
 
1219
      if (target_executing)
1220
        {
1221
          if (!previous_async_command)
1222
            previous_async_command = xstrdup (last_async_command);
1223
          if (strcmp (parse->command, "exec-interrupt"))
1224
            {
1225
              fputs_unfiltered (parse->token, raw_stdout);
1226
              fputs_unfiltered ("^error,msg=\"", raw_stdout);
1227
              fputs_unfiltered ("Cannot execute command ", raw_stdout);
1228
              fputstr_unfiltered (parse->command, '"', raw_stdout);
1229
              fputs_unfiltered (" while target running", raw_stdout);
1230
              fputs_unfiltered ("\"\n", raw_stdout);
1231
              return MI_CMD_ERROR;
1232
            }
1233
        }
1234
      last_async_command = xstrdup (parse->token);
1235
      make_exec_cleanup (free_current_contents, &last_async_command);
1236
      /* FIXME: DELETE THIS! */
1237
      if (parse->cmd->args_func != NULL)
1238
        return parse->cmd->args_func (parse->args, 0 /*from_tty */ );
1239
      return parse->cmd->argv_func (parse->command, parse->argv, parse->argc);
1240
    }
1241
  else if (parse->cmd->cli != 0)
1242
    {
1243
      /* FIXME: DELETE THIS. */
1244
      /* The operation is still implemented by a cli command */
1245
      /* Must be a synchronous one */
1246
      mi_execute_cli_command (parse->cmd->cli, parse->args);
1247
      return MI_CMD_DONE;
1248
    }
1249
  else
1250
    {
1251
      /* FIXME: DELETE THIS. */
1252
      fputs_unfiltered (parse->token, raw_stdout);
1253
      fputs_unfiltered ("^error,msg=\"", raw_stdout);
1254
      fputs_unfiltered ("Undefined mi command: ", raw_stdout);
1255
      fputstr_unfiltered (parse->command, '"', raw_stdout);
1256
      fputs_unfiltered (" (missing implementation)", raw_stdout);
1257
      fputs_unfiltered ("\"\n", raw_stdout);
1258
      return MI_CMD_ERROR;
1259
    }
1260
}
1261
 
1262
static void
1263
mi_execute_command_wrapper (char *cmd)
1264
{
1265
  mi_execute_command (cmd, stdin == instream);
1266
}
1267
 
1268
/* FIXME: This is just a hack so we can get some extra commands going.
1269
   We don't want to channel things through the CLI, but call libgdb directly */
1270
/* Use only for synchronous commands */
1271
 
1272
void
1273
mi_execute_cli_command (const char *cli, char *args)
1274
{
1275
  if (cli != 0)
1276
    {
1277
      struct cleanup *old_cleanups;
1278
      char *run;
1279
      xasprintf (&run, cli, args);
1280
      if (mi_debug_p)
1281
        /* FIXME: gdb_???? */
1282
        fprintf_unfiltered (gdb_stdout, "cli=%s run=%s\n",
1283
                            cli, run);
1284
      old_cleanups = make_cleanup (xfree, run);
1285
      execute_command ( /*ui */ run, 0 /*from_tty */ );
1286
      do_cleanups (old_cleanups);
1287
      return;
1288
    }
1289
}
1290
 
1291
enum mi_cmd_result
1292
mi_execute_async_cli_command (char *mi, char *args, int from_tty)
1293
{
1294
  struct cleanup *old_cleanups;
1295
  char *run;
1296
  char *async_args;
1297
 
1298
  if (target_can_async_p ())
1299
    {
1300
      async_args = (char *) xmalloc (strlen (args) + 2);
1301
      make_exec_cleanup (free, async_args);
1302
      strcpy (async_args, args);
1303
      strcat (async_args, "&");
1304
      xasprintf (&run, "%s %s", mi, async_args);
1305
      make_exec_cleanup (free, run);
1306
      add_continuation (mi_exec_async_cli_cmd_continuation, NULL);
1307
      old_cleanups = NULL;
1308
    }
1309
  else
1310
    {
1311
      xasprintf (&run, "%s %s", mi, args);
1312
      old_cleanups = make_cleanup (xfree, run);
1313
    }
1314
 
1315
  if (!target_can_async_p ())
1316
    {
1317
      /* NOTE: For synchronous targets asynchronous behavour is faked by
1318
         printing out the GDB prompt before we even try to execute the
1319
         command. */
1320
      if (last_async_command)
1321
        fputs_unfiltered (last_async_command, raw_stdout);
1322
      fputs_unfiltered ("^running\n", raw_stdout);
1323
      fputs_unfiltered ("(gdb) \n", raw_stdout);
1324
      gdb_flush (raw_stdout);
1325
    }
1326
  else
1327
    {
1328
      /* FIXME: cagney/1999-11-29: Printing this message before
1329
         calling execute_command is wrong.  It should only be printed
1330
         once gdb has confirmed that it really has managed to send a
1331
         run command to the target. */
1332
      if (last_async_command)
1333
        fputs_unfiltered (last_async_command, raw_stdout);
1334
      fputs_unfiltered ("^running\n", raw_stdout);
1335
    }
1336
 
1337
  execute_command ( /*ui */ run, 0 /*from_tty */ );
1338
 
1339
  if (!target_can_async_p ())
1340
    {
1341
      /* Do this before doing any printing.  It would appear that some
1342
         print code leaves garbage around in the buffer. */
1343
      do_cleanups (old_cleanups);
1344
      /* If the target was doing the operation synchronously we fake
1345
         the stopped message. */
1346
      if (last_async_command)
1347
        fputs_unfiltered (last_async_command, raw_stdout);
1348
      fputs_unfiltered ("*stopped", raw_stdout);
1349
      mi_out_put (uiout, raw_stdout);
1350
      mi_out_rewind (uiout);
1351
      fputs_unfiltered ("\n", raw_stdout);
1352
      return MI_CMD_QUIET;
1353
    }
1354
  return MI_CMD_DONE;
1355
}
1356
 
1357
void
1358
mi_exec_async_cli_cmd_continuation (struct continuation_arg *arg)
1359
{
1360
  if (last_async_command)
1361
    fputs_unfiltered (last_async_command, raw_stdout);
1362
  fputs_unfiltered ("*stopped", raw_stdout);
1363
  mi_out_put (uiout, raw_stdout);
1364
  fputs_unfiltered ("\n", raw_stdout);
1365
  fputs_unfiltered ("(gdb) \n", raw_stdout);
1366
  gdb_flush (raw_stdout);
1367
  do_exec_cleanups (ALL_CLEANUPS);
1368
}
1369
 
1370
static char *
1371
mi_input (char *buf)
1372
{
1373
  return gdb_readline (NULL);
1374
}
1375
 
1376
static void
1377
mi_load_progress (const char *section_name,
1378
                  unsigned long sent_so_far,
1379
                  unsigned long total_section,
1380
                  unsigned long total_sent,
1381
                  unsigned long grand_total)
1382
{
1383
  struct timeval time_now, delta, update_threshold;
1384
  static struct timeval last_update;
1385
  static char *previous_sect_name = NULL;
1386
  int new_section;
1387
 
1388
  if (!interpreter_p || strncmp (interpreter_p, "mi", 2) != 0)
1389
    return;
1390
 
1391
  update_threshold.tv_sec = 0;
1392
  update_threshold.tv_usec = 500000;
1393
  gettimeofday (&time_now, NULL);
1394
 
1395
  delta.tv_usec = time_now.tv_usec - last_update.tv_usec;
1396
  delta.tv_sec = time_now.tv_sec - last_update.tv_sec;
1397
 
1398
  if (delta.tv_usec < 0)
1399
    {
1400
      delta.tv_sec -= 1;
1401
      delta.tv_usec += 1000000;
1402
    }
1403
 
1404
  new_section = (previous_sect_name ?
1405
                 strcmp (previous_sect_name, section_name) : 1);
1406
  if (new_section)
1407
    {
1408
      xfree (previous_sect_name);
1409
      previous_sect_name = xstrdup (section_name);
1410
 
1411
      if (last_async_command)
1412
        fputs_unfiltered (last_async_command, raw_stdout);
1413
      fputs_unfiltered ("+download", raw_stdout);
1414
      ui_out_tuple_begin (uiout, NULL);
1415
      ui_out_field_string (uiout, "section", section_name);
1416
      ui_out_field_int (uiout, "section-size", total_section);
1417
      ui_out_field_int (uiout, "total-size", grand_total);
1418
      ui_out_tuple_end (uiout);
1419
      mi_out_put (uiout, raw_stdout);
1420
      fputs_unfiltered ("\n", raw_stdout);
1421
      gdb_flush (raw_stdout);
1422
    }
1423
 
1424
  if (delta.tv_sec >= update_threshold.tv_sec &&
1425
      delta.tv_usec >= update_threshold.tv_usec)
1426
    {
1427
      last_update.tv_sec = time_now.tv_sec;
1428
      last_update.tv_usec = time_now.tv_usec;
1429
      if (last_async_command)
1430
        fputs_unfiltered (last_async_command, raw_stdout);
1431
      fputs_unfiltered ("+download", raw_stdout);
1432
      ui_out_tuple_begin (uiout, NULL);
1433
      ui_out_field_string (uiout, "section", section_name);
1434
      ui_out_field_int (uiout, "section-sent", sent_so_far);
1435
      ui_out_field_int (uiout, "section-size", total_section);
1436
      ui_out_field_int (uiout, "total-sent", total_sent);
1437
      ui_out_field_int (uiout, "total-size", grand_total);
1438
      ui_out_tuple_end (uiout);
1439
      mi_out_put (uiout, raw_stdout);
1440
      fputs_unfiltered ("\n", raw_stdout);
1441
      gdb_flush (raw_stdout);
1442
    }
1443
}
1444
 
1445
static void
1446
mi_command_loop (int mi_version)
1447
{
1448
  /* HACK: Force stdout/stderr to point at the console.  This avoids
1449
     any potential side effects caused by legacy code that is still
1450
     using the TUI / fputs_unfiltered_hook */
1451
  raw_stdout = stdio_fileopen (stdout);
1452
  /* Route normal output through the MIx */
1453
  gdb_stdout = mi_console_file_new (raw_stdout, "~");
1454
  /* Route error and log output through the MI */
1455
  gdb_stderr = mi_console_file_new (raw_stdout, "&");
1456
  gdb_stdlog = gdb_stderr;
1457
  /* Route target output through the MI. */
1458
  gdb_stdtarg = mi_console_file_new (raw_stdout, "@");
1459
 
1460
  /* HACK: Poke the ui_out table directly.  Should we be creating a
1461
     mi_out object wired up to the above gdb_stdout / gdb_stderr? */
1462
  uiout = mi_out_new (mi_version);
1463
 
1464
  /* HACK: Override any other interpreter hooks.  We need to create a
1465
     real event table and pass in that. */
1466
  init_ui_hook = 0;
1467
  /* command_loop_hook = 0; */
1468
  print_frame_info_listing_hook = 0;
1469
  query_hook = 0;
1470
  warning_hook = 0;
1471
  create_breakpoint_hook = 0;
1472
  delete_breakpoint_hook = 0;
1473
  modify_breakpoint_hook = 0;
1474
  interactive_hook = 0;
1475
  registers_changed_hook = 0;
1476
  readline_begin_hook = 0;
1477
  readline_hook = 0;
1478
  readline_end_hook = 0;
1479
  register_changed_hook = 0;
1480
  memory_changed_hook = 0;
1481
  context_hook = 0;
1482
  target_wait_hook = 0;
1483
  call_command_hook = 0;
1484
  error_hook = 0;
1485
  error_begin_hook = 0;
1486
  show_load_progress = mi_load_progress;
1487
 
1488
  /* Turn off 8 bit strings in quoted output.  Any character with the
1489
     high bit set is printed using C's octal format. */
1490
  sevenbit_strings = 1;
1491
 
1492
  /* Tell the world that we're alive */
1493
  fputs_unfiltered ("(gdb) \n", raw_stdout);
1494
  gdb_flush (raw_stdout);
1495
 
1496
  if (!event_loop_p)
1497
    simplified_command_loop (mi_input, mi_execute_command);
1498
  else
1499
    start_event_loop ();
1500
}
1501
 
1502
static void
1503
mi0_command_loop (void)
1504
{
1505
  mi_command_loop (0);
1506
}
1507
 
1508
static void
1509
mi1_command_loop (void)
1510
{
1511
  mi_command_loop (1);
1512
}
1513
 
1514
static void
1515
setup_architecture_data (void)
1516
{
1517
  /* don't trust REGISTER_BYTES to be zero. */
1518
  old_regs = xmalloc (REGISTER_BYTES + 1);
1519
  memset (old_regs, 0, REGISTER_BYTES + 1);
1520
}
1521
 
1522
static void
1523
mi_init_ui (char *arg0)
1524
{
1525
  /* Eventually this will contain code that takes control of the
1526
     console. */
1527
}
1528
 
1529
void
1530
_initialize_mi_main (void)
1531
{
1532
  if (interpreter_p == NULL)
1533
    return;
1534
 
1535
  /* If we're _the_ interpreter, take control. */
1536
  if (strcmp (interpreter_p, "mi0") == 0)
1537
    command_loop_hook = mi0_command_loop;
1538
  else if (strcmp (interpreter_p, "mi") == 0
1539
           || strcmp (interpreter_p, "mi1") == 0)
1540
    command_loop_hook = mi1_command_loop;
1541
  else
1542
    return;
1543
 
1544
  init_ui_hook = mi_init_ui;
1545
  setup_architecture_data ();
1546
  register_gdbarch_swap (&old_regs, sizeof (old_regs), NULL);
1547
  register_gdbarch_swap (NULL, 0, setup_architecture_data);
1548
  if (event_loop_p)
1549
    {
1550
      /* These overwrite some of the initialization done in
1551
         _intialize_event_loop. */
1552
      call_readline = gdb_readline2;
1553
      input_handler = mi_execute_command_wrapper;
1554
      add_file_handler (input_fd, stdin_event_handler, 0);
1555
      async_command_editing_p = 0;
1556
    }
1557
  /* FIXME: Should we notify main that we are here as a possible
1558
     interpreter? */
1559
}

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