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[/] [or1k/] [trunk/] [gdb-5.3/] [gdb/] [infttrace.c] - Blame information for rev 1773

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1 1181 sfurman
/* Low level Unix child interface to ttrace, for GDB when running under HP-UX.
2
   Copyright 1988, 1989, 1990, 1991, 1992, 1993, 1994, 1995, 1996, 1998,
3
   1999, 2000, 2001
4
   Free Software Foundation, Inc.
5
 
6
   This file is part of GDB.
7
 
8
   This program is free software; you can redistribute it and/or modify
9
   it under the terms of the GNU General Public License as published by
10
   the Free Software Foundation; either version 2 of the License, or
11
   (at your option) any later version.
12
 
13
   This program is distributed in the hope that it will be useful,
14
   but WITHOUT ANY WARRANTY; without even the implied warranty of
15
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
16
   GNU General Public License for more details.
17
 
18
   You should have received a copy of the GNU General Public License
19
   along with this program; if not, write to the Free Software
20
   Foundation, Inc., 59 Temple Place - Suite 330,
21
   Boston, MA 02111-1307, USA.  */
22
 
23
#include "defs.h"
24
#include "frame.h"
25
#include "inferior.h"
26
#include "target.h"
27
#include "gdb_string.h"
28
#include "gdb_wait.h"
29
#include "command.h"
30
 
31
/* We need pstat functionality so that we can get the exec file
32
   for a process we attach to.
33
 
34
   According to HP, we should use the 64bit interfaces, so we
35
   define _PSTAT64 to achieve this.  */
36
#define _PSTAT64
37
#include <sys/pstat.h>
38
 
39
/* Some hackery to work around a use of the #define name NO_FLAGS
40
 * in both gdb and HPUX (bfd.h and /usr/include/machine/vmparam.h).
41
 */
42
#ifdef  NO_FLAGS
43
#define INFTTRACE_TEMP_HACK NO_FLAGS
44
#undef  NO_FLAGS
45
#endif
46
 
47
#ifdef USG
48
#include <sys/types.h>
49
#endif
50
 
51
#include <sys/param.h>
52
#include <sys/dir.h>
53
#include <signal.h>
54
#include <sys/ioctl.h>
55
 
56
#include <sys/ttrace.h>
57
#include <sys/mman.h>
58
 
59
#ifndef NO_PTRACE_H
60
#ifdef PTRACE_IN_WRONG_PLACE
61
#include <ptrace.h>
62
#else
63
#include <sys/ptrace.h>
64
#endif
65
#endif /* NO_PTRACE_H */
66
 
67
/* Second half of the hackery above.  Non-ANSI C, so
68
 * we can't use "#error", alas.
69
 */
70
#ifdef NO_FLAGS
71
#if (NO_FLAGS != INFTTRACE_TEMP_HACK )
72
  /* #error "Hackery to remove warning didn't work right" */
73
#else
74
  /* Ok, new def'n of NO_FLAGS is same as old one; no action needed. */
75
#endif
76
#else
77
  /* #error "Didn't get expected re-definition of NO_FLAGS" */
78
#define NO_FLAGS INFTTRACE_TEMP_HACK
79
#endif
80
 
81
#if !defined (PT_SETTRC)
82
#define PT_SETTRC       0        /* Make process traceable by parent */
83
#endif
84
#if !defined (PT_READ_I)
85
#define PT_READ_I       1       /* Read word from text space */
86
#endif
87
#if !defined (PT_READ_D)
88
#define PT_READ_D       2       /* Read word from data space */
89
#endif
90
#if !defined (PT_READ_U)
91
#define PT_READ_U       3       /* Read word from kernel user struct */
92
#endif
93
#if !defined (PT_WRITE_I)
94
#define PT_WRITE_I      4       /* Write word to text space */
95
#endif
96
#if !defined (PT_WRITE_D)
97
#define PT_WRITE_D      5       /* Write word to data space */
98
#endif
99
#if !defined (PT_WRITE_U)
100
#define PT_WRITE_U      6       /* Write word to kernel user struct */
101
#endif
102
#if !defined (PT_CONTINUE)
103
#define PT_CONTINUE     7       /* Continue after signal */
104
#endif
105
#if !defined (PT_STEP)
106
#define PT_STEP         9       /* Set flag for single stepping */
107
#endif
108
#if !defined (PT_KILL)
109
#define PT_KILL         8       /* Send child a SIGKILL signal */
110
#endif
111
 
112
#ifndef PT_ATTACH
113
#define PT_ATTACH PTRACE_ATTACH
114
#endif
115
#ifndef PT_DETACH
116
#define PT_DETACH PTRACE_DETACH
117
#endif
118
 
119
#include "gdbcore.h"
120
#ifndef NO_SYS_FILE
121
#include <sys/file.h>
122
#endif
123
 
124
/* This semaphore is used to coordinate the child and parent processes
125
   after a fork(), and before an exec() by the child.  See parent_attach_all
126
   for details.
127
 */
128
typedef struct
129
  {
130
    int parent_channel[2];      /* Parent "talks" to [1], child "listens" to [0] */
131
    int child_channel[2];       /* Child "talks" to [1], parent "listens" to [0] */
132
  }
133
startup_semaphore_t;
134
 
135
#define SEM_TALK (1)
136
#define SEM_LISTEN (0)
137
 
138
static startup_semaphore_t startup_semaphore;
139
 
140
/* See can_touch_threads_of_process for details. */
141
static int vforking_child_pid = 0;
142
static int vfork_in_flight = 0;
143
 
144
/* To support PREPARE_TO_PROCEED (hppa_prepare_to_proceed).
145
 */
146
static pid_t old_gdb_pid = 0;
147
static pid_t reported_pid = 0;
148
static int reported_bpt = 0;
149
 
150
/* 1 if ok as results of a ttrace or ttrace_wait call, 0 otherwise.
151
 */
152
#define TT_OK( _status, _errno ) \
153
    (((_status) == 1) && ((_errno) == 0))
154
 
155
#define TTRACE_ARG_TYPE uint64_t
156
 
157
/* When supplied as the "addr" operand, ttrace interprets this
158
   to mean, "from the current address".
159
 */
160
#define TT_USE_CURRENT_PC ((TTRACE_ARG_TYPE) TT_NOPC)
161
 
162
/* When supplied as the "addr", "data" or "addr2" operand for most
163
   requests, ttrace interprets this to mean, "pay no heed to this
164
   argument".
165
 */
166
#define TT_NIL ((TTRACE_ARG_TYPE) TT_NULLARG)
167
 
168
/* This is capable of holding the value of a 32-bit register.  The
169
   value is always left-aligned in the buffer; i.e., [0] contains
170
   the most-significant byte of the register's value, and [sizeof(reg)]
171
   contains the least-significant value.
172
 
173
   ??rehrauer: Yes, this assumes that an int is 32-bits on HP-UX, and
174
   that registers are 32-bits on HP-UX.  The latter assumption changes
175
   with PA2.0.
176
 */
177
typedef int register_value_t;
178
 
179
/********************************************************************
180
 
181
                 How this works:
182
 
183
   1.  Thread numbers
184
 
185
   The rest of GDB sees threads as being things with different
186
   "pid" (process id) values.  See "thread.c" for details.  The
187
   separate threads will be seen and reacted to if infttrace passes
188
   back different pid values (for _events_).  See wait_for_inferior
189
   in inftarg.c.
190
 
191
   So infttrace is going to use thread ids externally, pretending
192
   they are process ids, and keep track internally so that it can
193
   use the real process id (and thread id) when calling ttrace.
194
 
195
   The data structure that supports this is a linked list of the
196
   current threads.  Since at some date infttrace will have to
197
   deal with multiple processes, each list element records its
198
   corresponding pid, rather than having a single global.
199
 
200
   Note that the list is only approximately current; that's ok, as
201
   it's up to date when we need it (we hope!).  Also, it can contain
202
   dead threads, as there's no harm if it does.
203
 
204
   The approach taken here is to bury the translation from external
205
   to internal inside "call_ttrace" and a few other places.
206
 
207
   There are some wrinkles:
208
 
209
   o  When GDB forks itself to create the debug target process,
210
      there's only a pid of 0 around in the child, so the
211
      TT_PROC_SETTRC operation uses a more direct call to ttrace;
212
      Similiarly, the initial setting of the event mask happens
213
      early as  well, and so is also special-cased, and an attach
214
      uses a real pid;
215
 
216
   o  We define an unthreaded application as having a "pseudo"
217
      thread;
218
 
219
   o  To keep from confusing the rest of GDB, we don't switch
220
      the PID for the pseudo thread to a TID.  A table will help:
221
 
222
      Rest of GDB sees these PIDs:     pid   tid1  tid2  tid3 ...
223
 
224
      Our thread list stores:          pid   pid   pid   pid  ...
225
                                       tid0  tid1  tid2  tid3
226
 
227
      Ttrace sees these TIDS:          tid0  tid1  tid2  tid3 ...
228
 
229
      Both pid and tid0 will map to tid0, as there are infttrace.c-internal
230
      calls to ttrace using tid0.
231
 
232
   2. Step and Continue
233
 
234
   Since we're implementing the "stop the world" model, sub-model
235
   "other threads run during step", we have some stuff to do:
236
 
237
   o  User steps require continuing all threads other than the
238
      one the user is stepping;
239
 
240
   o  Internal debugger steps (such as over a breakpoint or watchpoint,
241
      but not out of a library load thunk) require stepping only
242
      the selected thread; this means that we have to report the
243
      step finish on that thread, which can lead to complications;
244
 
245
   o  When a thread is created, it is created running, rather
246
      than stopped--so we have to stop it.
247
 
248
   The OS doesn't guarantee the stopped thread list will be stable,
249
   no does it guarantee where on the stopped thread list a thread
250
   that is single-stepped will wind up: it's possible that it will
251
   be off the list for a while, it's possible the step will complete
252
   and it will be re-posted to the end...
253
 
254
   This means we have to scan the stopped thread list, build up
255
   a work-list, and then run down the work list; we can't do the
256
   step/continue during the scan.
257
 
258
   3. Buffering events
259
 
260
   Then there's the issue of waiting for an event.  We do this by
261
   noticing how many events are reported at the end of each wait.
262
   From then on, we "fake" all resumes and steps, returning instantly,
263
   and don't do another wait.  Once all pending events are reported,
264
   we can really resume again.
265
 
266
   To keep this hidden, all the routines which know about tids and
267
   pids or real events and simulated ones are static (file-local).
268
 
269
   This code can make lots of calls to ttrace, in particular it
270
   can spin down the list of thread states more than once.  If this
271
   becomes a performance hit, the spin could be done once and the
272
   various "tsp" blocks saved, keeping all later spins in this
273
   process.
274
 
275
   The O/S doesn't promise to keep the list straight, and so we must
276
   re-scan a lot.  By observation, it looks like a single-step/wait
277
   puts the stepped thread at the end of the list but doesn't change
278
   it otherwise.
279
 
280
****************************************************************
281
*/
282
 
283
/* Uncomment these to turn on various debugging output */
284
/* #define THREAD_DEBUG */
285
/* #define WAIT_BUFFER_DEBUG */
286
/* #define PARANOIA */
287
 
288
 
289
#define INFTTRACE_ALL_THREADS (-1)
290
#define INFTTRACE_STEP        (1)
291
#define INFTTRACE_CONTINUE    (0)
292
 
293
/* FIX: this is used in inftarg.c/child_wait, in a hack.
294
 */
295
extern int not_same_real_pid;
296
 
297
/* This is used to count buffered events.
298
 */
299
static unsigned int more_events_left = 0;
300
 
301
/* Process state.
302
 */
303
typedef enum process_state_enum
304
  {
305
    STOPPED,
306
    FAKE_STEPPING,
307
    FAKE_CONTINUE,              /* For later use */
308
    RUNNING,
309
    FORKING,
310
    VFORKING
311
  }
312
process_state_t;
313
 
314
static process_state_t process_state = STOPPED;
315
 
316
/* User-specified stepping modality.
317
 */
318
typedef enum stepping_mode_enum
319
  {
320
    DO_DEFAULT,                 /* ...which is a continue! */
321
    DO_STEP,
322
    DO_CONTINUE
323
  }
324
stepping_mode_t;
325
 
326
/* Action to take on an attach, depends on
327
 * what kind (user command, fork, vfork).
328
 *
329
 * At the moment, this is either:
330
 *
331
 * o  continue with a SIGTRAP signal, or
332
 *
333
 * o  leave stopped.
334
 */
335
typedef enum attach_continue_enum
336
  {
337
    DO_ATTACH_CONTINUE,
338
    DONT_ATTACH_CONTINUE
339
  }
340
attach_continue_t;
341
 
342
/* This flag is true if we are doing a step-over-bpt
343
 * with buffered events.  We will have to be sure to
344
 * report the right thread, as otherwise the spaghetti
345
 * code in "infrun.c/wait_for_inferior" will get
346
 * confused.
347
 */
348
static int doing_fake_step = 0;
349
static lwpid_t fake_step_tid = 0;
350
 
351
 
352
/****************************************************
353
 * Thread information structure routines and types. *
354
 ****************************************************
355
 */
356
typedef
357
struct thread_info_struct
358
  {
359
    int am_pseudo;              /* This is a pseudo-thread for the process. */
360
    int pid;                    /* Process ID */
361
    lwpid_t tid;                /* Thread  ID */
362
    int handled;                /* 1 if a buffered event was handled. */
363
    int seen;                   /* 1 if this thread was seen on a traverse. */
364
    int terminated;             /* 1 if thread has terminated. */
365
    int have_signal;            /* 1 if signal to be sent */
366
    enum target_signal signal_value;    /* Signal to send */
367
    int have_start;             /* 1 if alternate starting address */
368
    stepping_mode_t stepping_mode;      /* Whether to step or continue */
369
    CORE_ADDR start;            /* Where to start */
370
    int have_state;             /* 1 if the event state has been set */
371
    ttstate_t last_stop_state;  /* The most recently-waited event for this thread. */
372
    struct thread_info_struct
373
     *next;                     /* All threads are linked via this field. */
374
    struct thread_info_struct
375
     *next_pseudo;              /* All pseudo-threads are linked via this field. */
376
  }
377
thread_info;
378
 
379
typedef
380
struct thread_info_header_struct
381
  {
382
    int count;
383
    thread_info *head;
384
    thread_info *head_pseudo;
385
 
386
  }
387
thread_info_header;
388
 
389
static thread_info_header thread_head =
390
{0, NULL, NULL};
391
static thread_info_header deleted_threads =
392
{0, NULL, NULL};
393
 
394
static ptid_t saved_real_ptid;
395
 
396
 
397
/*************************************************
398
 *          Debugging support functions          *
399
 *************************************************
400
 */
401
CORE_ADDR
402
get_raw_pc (lwpid_t ttid)
403
{
404
  unsigned long pc_val;
405
  int offset;
406
  int res;
407
 
408
  offset = register_addr (PC_REGNUM, U_REGS_OFFSET);
409
  res = read_from_register_save_state (
410
                                        ttid,
411
                                        (TTRACE_ARG_TYPE) offset,
412
                                        (char *) &pc_val,
413
                                        sizeof (pc_val));
414
  if (res <= 0)
415
    {
416
      return (CORE_ADDR) pc_val;
417
    }
418
  else
419
    {
420
      return (CORE_ADDR) 0;
421
    }
422
}
423
 
424
static char *
425
get_printable_name_of_stepping_mode (stepping_mode_t mode)
426
{
427
  switch (mode)
428
    {
429
    case DO_DEFAULT:
430
      return "DO_DEFAULT";
431
    case DO_STEP:
432
      return "DO_STEP";
433
    case DO_CONTINUE:
434
      return "DO_CONTINUE";
435
    default:
436
      return "?unknown mode?";
437
    }
438
}
439
 
440
/* This function returns a pointer to a string describing the
441
 * ttrace event being reported.
442
 */
443
char *
444
get_printable_name_of_ttrace_event (ttevents_t event)
445
{
446
  /* This enumeration is "gappy", so don't use a table. */
447
  switch (event)
448
    {
449
 
450
    case TTEVT_NONE:
451
      return "TTEVT_NONE";
452
    case TTEVT_SIGNAL:
453
      return "TTEVT_SIGNAL";
454
    case TTEVT_FORK:
455
      return "TTEVT_FORK";
456
    case TTEVT_EXEC:
457
      return "TTEVT_EXEC";
458
    case TTEVT_EXIT:
459
      return "TTEVT_EXIT";
460
    case TTEVT_VFORK:
461
      return "TTEVT_VFORK";
462
    case TTEVT_SYSCALL_RETURN:
463
      return "TTEVT_SYSCALL_RETURN";
464
    case TTEVT_LWP_CREATE:
465
      return "TTEVT_LWP_CREATE";
466
    case TTEVT_LWP_TERMINATE:
467
      return "TTEVT_LWP_TERMINATE";
468
    case TTEVT_LWP_EXIT:
469
      return "TTEVT_LWP_EXIT";
470
    case TTEVT_LWP_ABORT_SYSCALL:
471
      return "TTEVT_LWP_ABORT_SYSCALL";
472
    case TTEVT_SYSCALL_ENTRY:
473
      return "TTEVT_SYSCALL_ENTRY";
474
    case TTEVT_SYSCALL_RESTART:
475
      return "TTEVT_SYSCALL_RESTART";
476
    default:
477
      return "?new event?";
478
    }
479
}
480
 
481
 
482
/* This function translates the ttrace request enumeration into
483
 * a character string that is its printable (aka "human readable")
484
 * name.
485
 */
486
char *
487
get_printable_name_of_ttrace_request (ttreq_t request)
488
{
489
  if (!IS_TTRACE_REQ (request))
490
    return "?bad req?";
491
 
492
  /* This enumeration is "gappy", so don't use a table. */
493
  switch (request)
494
    {
495
    case TT_PROC_SETTRC:
496
      return "TT_PROC_SETTRC";
497
    case TT_PROC_ATTACH:
498
      return "TT_PROC_ATTACH";
499
    case TT_PROC_DETACH:
500
      return "TT_PROC_DETACH";
501
    case TT_PROC_RDTEXT:
502
      return "TT_PROC_RDTEXT";
503
    case TT_PROC_WRTEXT:
504
      return "TT_PROC_WRTEXT";
505
    case TT_PROC_RDDATA:
506
      return "TT_PROC_RDDATA";
507
    case TT_PROC_WRDATA:
508
      return "TT_PROC_WRDATA";
509
    case TT_PROC_STOP:
510
      return "TT_PROC_STOP";
511
    case TT_PROC_CONTINUE:
512
      return "TT_PROC_CONTINUE";
513
    case TT_PROC_GET_PATHNAME:
514
      return "TT_PROC_GET_PATHNAME";
515
    case TT_PROC_GET_EVENT_MASK:
516
      return "TT_PROC_GET_EVENT_MASK";
517
    case TT_PROC_SET_EVENT_MASK:
518
      return "TT_PROC_SET_EVENT_MASK";
519
    case TT_PROC_GET_FIRST_LWP_STATE:
520
      return "TT_PROC_GET_FIRST_LWP_STATE";
521
    case TT_PROC_GET_NEXT_LWP_STATE:
522
      return "TT_PROC_GET_NEXT_LWP_STATE";
523
    case TT_PROC_EXIT:
524
      return "TT_PROC_EXIT";
525
    case TT_PROC_GET_MPROTECT:
526
      return "TT_PROC_GET_MPROTECT";
527
    case TT_PROC_SET_MPROTECT:
528
      return "TT_PROC_SET_MPROTECT";
529
    case TT_PROC_SET_SCBM:
530
      return "TT_PROC_SET_SCBM";
531
    case TT_LWP_STOP:
532
      return "TT_LWP_STOP";
533
    case TT_LWP_CONTINUE:
534
      return "TT_LWP_CONTINUE";
535
    case TT_LWP_SINGLE:
536
      return "TT_LWP_SINGLE";
537
    case TT_LWP_RUREGS:
538
      return "TT_LWP_RUREGS";
539
    case TT_LWP_WUREGS:
540
      return "TT_LWP_WUREGS";
541
    case TT_LWP_GET_EVENT_MASK:
542
      return "TT_LWP_GET_EVENT_MASK";
543
    case TT_LWP_SET_EVENT_MASK:
544
      return "TT_LWP_SET_EVENT_MASK";
545
    case TT_LWP_GET_STATE:
546
      return "TT_LWP_GET_STATE";
547
    default:
548
      return "?new req?";
549
    }
550
}
551
 
552
 
553
/* This function translates the process state enumeration into
554
 * a character string that is its printable (aka "human readable")
555
 * name.
556
 */
557
static char *
558
get_printable_name_of_process_state (process_state_t process_state)
559
{
560
  switch (process_state)
561
    {
562
    case STOPPED:
563
      return "STOPPED";
564
    case FAKE_STEPPING:
565
      return "FAKE_STEPPING";
566
    case RUNNING:
567
      return "RUNNING";
568
    case FORKING:
569
      return "FORKING";
570
    case VFORKING:
571
      return "VFORKING";
572
    default:
573
      return "?some unknown state?";
574
    }
575
}
576
 
577
/* Set a ttrace thread state to a safe, initial state.
578
 */
579
static void
580
clear_ttstate_t (ttstate_t *tts)
581
{
582
  tts->tts_pid = 0;
583
  tts->tts_lwpid = 0;
584
  tts->tts_user_tid = 0;
585
  tts->tts_event = TTEVT_NONE;
586
}
587
 
588
/* Copy ttrace thread state TTS_FROM into TTS_TO.
589
 */
590
static void
591
copy_ttstate_t (ttstate_t *tts_to, ttstate_t *tts_from)
592
{
593
  memcpy ((char *) tts_to, (char *) tts_from, sizeof (*tts_to));
594
}
595
 
596
/* Are there any live threads we know about?
597
 */
598
static int
599
any_thread_records (void)
600
{
601
  return (thread_head.count > 0);
602
}
603
 
604
/* Create, fill in and link in a thread descriptor.
605
 */
606
static thread_info *
607
create_thread_info (int pid, lwpid_t tid)
608
{
609
  thread_info *new_p;
610
  thread_info *p;
611
  int thread_count_of_pid;
612
 
613
  new_p = xmalloc (sizeof (thread_info));
614
  new_p->pid = pid;
615
  new_p->tid = tid;
616
  new_p->have_signal = 0;
617
  new_p->have_start = 0;
618
  new_p->have_state = 0;
619
  clear_ttstate_t (&new_p->last_stop_state);
620
  new_p->am_pseudo = 0;
621
  new_p->handled = 0;
622
  new_p->seen = 0;
623
  new_p->terminated = 0;
624
  new_p->next = NULL;
625
  new_p->next_pseudo = NULL;
626
  new_p->stepping_mode = DO_DEFAULT;
627
 
628
  if (0 == thread_head.count)
629
    {
630
#ifdef THREAD_DEBUG
631
      if (debug_on)
632
        printf ("First thread, pid %d tid %d!\n", pid, tid);
633
#endif
634
      saved_real_ptid = inferior_ptid;
635
    }
636
  else
637
    {
638
#ifdef THREAD_DEBUG
639
      if (debug_on)
640
        printf ("Subsequent thread, pid %d tid %d\n", pid, tid);
641
#endif
642
    }
643
 
644
  /* Another day, another thread...
645
   */
646
  thread_head.count++;
647
 
648
  /* The new thread always goes at the head of the list.
649
   */
650
  new_p->next = thread_head.head;
651
  thread_head.head = new_p;
652
 
653
  /* Is this the "pseudo" thread of a process?  It is if there's
654
   * no other thread for this process on the list.  (Note that this
655
   * accomodates multiple processes, such as we see even for simple
656
   * cases like forking "non-threaded" programs.)
657
   */
658
  p = thread_head.head;
659
  thread_count_of_pid = 0;
660
  while (p)
661
    {
662
      if (p->pid == new_p->pid)
663
        thread_count_of_pid++;
664
      p = p->next;
665
    }
666
 
667
  /* Did we see any other threads for this pid?  (Recall that we just
668
   * added this thread to the list...)
669
   */
670
  if (thread_count_of_pid == 1)
671
    {
672
      new_p->am_pseudo = 1;
673
      new_p->next_pseudo = thread_head.head_pseudo;
674
      thread_head.head_pseudo = new_p;
675
    }
676
 
677
  return new_p;
678
}
679
 
680
/* Get rid of our thread info.
681
 */
682
static void
683
clear_thread_info (void)
684
{
685
  thread_info *p;
686
  thread_info *q;
687
 
688
#ifdef THREAD_DEBUG
689
  if (debug_on)
690
    printf ("Clearing all thread info\n");
691
#endif
692
 
693
  p = thread_head.head;
694
  while (p)
695
    {
696
      q = p;
697
      p = p->next;
698
      xfree (q);
699
    }
700
 
701
  thread_head.head = NULL;
702
  thread_head.head_pseudo = NULL;
703
  thread_head.count = 0;
704
 
705
  p = deleted_threads.head;
706
  while (p)
707
    {
708
      q = p;
709
      p = p->next;
710
      xfree (q);
711
    }
712
 
713
  deleted_threads.head = NULL;
714
  deleted_threads.head_pseudo = NULL;
715
  deleted_threads.count = 0;
716
 
717
  /* No threads, so can't have pending events.
718
   */
719
  more_events_left = 0;
720
}
721
 
722
/* Given a tid, find the thread block for it.
723
 */
724
static thread_info *
725
find_thread_info (lwpid_t tid)
726
{
727
  thread_info *p;
728
 
729
  for (p = thread_head.head; p; p = p->next)
730
    {
731
      if (p->tid == tid)
732
        {
733
          return p;
734
        }
735
    }
736
 
737
  for (p = deleted_threads.head; p; p = p->next)
738
    {
739
      if (p->tid == tid)
740
        {
741
          return p;
742
        }
743
    }
744
 
745
  return NULL;
746
}
747
 
748
/* For any but the pseudo thread, this maps to the
749
 * thread ID.  For the pseudo thread, if you pass either
750
 * the thread id or the PID, you get the pseudo thread ID.
751
 *
752
 * We have to be prepared for core gdb to ask about
753
 * deleted threads.  We do the map, but we don't like it.
754
 */
755
static lwpid_t
756
map_from_gdb_tid (lwpid_t gdb_tid)
757
{
758
  thread_info *p;
759
 
760
  /* First assume gdb_tid really is a tid, and try to find a
761
   * matching entry on the threads list.
762
   */
763
  for (p = thread_head.head; p; p = p->next)
764
    {
765
      if (p->tid == gdb_tid)
766
        return gdb_tid;
767
    }
768
 
769
  /* It doesn't appear to be a tid; perhaps it's really a pid?
770
   * Try to find a "pseudo" thread entry on the threads list.
771
   */
772
  for (p = thread_head.head_pseudo; p != NULL; p = p->next_pseudo)
773
    {
774
      if (p->pid == gdb_tid)
775
        return p->tid;
776
    }
777
 
778
  /* Perhaps it's the tid of a deleted thread we may still
779
   * have some knowledge of?
780
   */
781
  for (p = deleted_threads.head; p; p = p->next)
782
    {
783
      if (p->tid == gdb_tid)
784
        return gdb_tid;
785
    }
786
 
787
  /* Or perhaps it's the pid of a deleted process we may still
788
   * have knowledge of?
789
   */
790
  for (p = deleted_threads.head_pseudo; p != NULL; p = p->next_pseudo)
791
    {
792
      if (p->pid == gdb_tid)
793
        return p->tid;
794
    }
795
 
796
  return 0;                      /* Error? */
797
}
798
 
799
/* Map the other way: from a real tid to the
800
 * "pid" known by core gdb.  This tid may be
801
 * for a thread that just got deleted, so we
802
 * also need to consider deleted threads.
803
 */
804
static lwpid_t
805
map_to_gdb_tid (lwpid_t real_tid)
806
{
807
  thread_info *p;
808
 
809
  for (p = thread_head.head; p; p = p->next)
810
    {
811
      if (p->tid == real_tid)
812
        {
813
          if (p->am_pseudo)
814
            return p->pid;
815
          else
816
            return real_tid;
817
        }
818
    }
819
 
820
  for (p = deleted_threads.head; p; p = p->next)
821
    {
822
      if (p->tid == real_tid)
823
        if (p->am_pseudo)
824
          return p->pid;        /* Error? */
825
        else
826
          return real_tid;
827
    }
828
 
829
  return 0;                      /* Error?  Never heard of this thread! */
830
}
831
 
832
/* Do any threads have saved signals?
833
 */
834
static int
835
saved_signals_exist (void)
836
{
837
  thread_info *p;
838
 
839
  for (p = thread_head.head; p; p = p->next)
840
    {
841
      if (p->have_signal)
842
        {
843
          return 1;
844
        }
845
    }
846
 
847
  return 0;
848
}
849
 
850
/* Is this the tid for the zero-th thread?
851
 */
852
static int
853
is_pseudo_thread (lwpid_t tid)
854
{
855
  thread_info *p = find_thread_info (tid);
856
  if (NULL == p || p->terminated)
857
    return 0;
858
  else
859
    return p->am_pseudo;
860
}
861
 
862
/* Is this thread terminated?
863
 */
864
static int
865
is_terminated (lwpid_t tid)
866
{
867
  thread_info *p = find_thread_info (tid);
868
 
869
  if (NULL != p)
870
    return p->terminated;
871
 
872
  return 0;
873
}
874
 
875
/* Is this pid a real PID or a TID?
876
 */
877
static int
878
is_process_id (int pid)
879
{
880
  lwpid_t tid;
881
  thread_info *tinfo;
882
  pid_t this_pid;
883
  int this_pid_count;
884
 
885
  /* What does PID really represent?
886
   */
887
  tid = map_from_gdb_tid (pid);
888
  if (tid <= 0)
889
    return 0;                    /* Actually, is probably an error... */
890
 
891
  tinfo = find_thread_info (tid);
892
 
893
  /* Does it appear to be a true thread?
894
   */
895
  if (!tinfo->am_pseudo)
896
    return 0;
897
 
898
  /* Else, it looks like it may be a process.  See if there's any other
899
   * threads with the same process ID, though.  If there are, then TID
900
   * just happens to be the first thread of several for this process.
901
   */
902
  this_pid = tinfo->pid;
903
  this_pid_count = 0;
904
  for (tinfo = thread_head.head; tinfo; tinfo = tinfo->next)
905
    {
906
      if (tinfo->pid == this_pid)
907
        this_pid_count++;
908
    }
909
 
910
  return (this_pid_count == 1);
911
}
912
 
913
 
914
/* Add a thread to our info.  Prevent duplicate entries.
915
 */
916
static thread_info *
917
add_tthread (int pid, lwpid_t tid)
918
{
919
  thread_info *p;
920
 
921
  p = find_thread_info (tid);
922
  if (NULL == p)
923
    p = create_thread_info (pid, tid);
924
 
925
  return p;
926
}
927
 
928
/* Notice that a thread was deleted.
929
 */
930
static void
931
del_tthread (lwpid_t tid)
932
{
933
  thread_info *p;
934
  thread_info *chase;
935
 
936
  if (thread_head.count <= 0)
937
    {
938
      error ("Internal error in thread database.");
939
      return;
940
    }
941
 
942
  chase = NULL;
943
  for (p = thread_head.head; p; p = p->next)
944
    {
945
      if (p->tid == tid)
946
        {
947
 
948
#ifdef THREAD_DEBUG
949
          if (debug_on)
950
            printf ("Delete here: %d \n", tid);
951
#endif
952
 
953
          if (p->am_pseudo)
954
            {
955
              /*
956
               * Deleting a main thread is ok if we're doing
957
               * a parent-follow on a child; this is odd but
958
               * not wrong.  It apparently _doesn't_ happen
959
               * on the child-follow, as we don't just delete
960
               * the pseudo while keeping the rest of the
961
               * threads around--instead, we clear out the whole
962
               * thread list at once.
963
               */
964
              thread_info *q;
965
              thread_info *q_chase;
966
 
967
              q_chase = NULL;
968
              for (q = thread_head.head_pseudo; q; q = q->next)
969
                {
970
                  if (q == p)
971
                    {
972
                      /* Remove from pseudo list.
973
                       */
974
                      if (q_chase == NULL)
975
                        thread_head.head_pseudo = p->next_pseudo;
976
                      else
977
                        q_chase->next = p->next_pseudo;
978
                    }
979
                  else
980
                    q_chase = q;
981
                }
982
            }
983
 
984
          /* Remove from live list.
985
           */
986
          thread_head.count--;
987
 
988
          if (NULL == chase)
989
            thread_head.head = p->next;
990
          else
991
            chase->next = p->next;
992
 
993
          /* Add to deleted thread list.
994
           */
995
          p->next = deleted_threads.head;
996
          deleted_threads.head = p;
997
          deleted_threads.count++;
998
          if (p->am_pseudo)
999
            {
1000
              p->next_pseudo = deleted_threads.head_pseudo;
1001
              deleted_threads.head_pseudo = p;
1002
            }
1003
          p->terminated = 1;
1004
 
1005
          return;
1006
        }
1007
 
1008
      else
1009
        chase = p;
1010
    }
1011
}
1012
 
1013
/* Get the pid for this tid. (Has to be a real TID!).
1014
 */
1015
static int
1016
get_pid_for (lwpid_t tid)
1017
{
1018
  thread_info *p;
1019
 
1020
  for (p = thread_head.head; p; p = p->next)
1021
    {
1022
      if (p->tid == tid)
1023
        {
1024
          return p->pid;
1025
        }
1026
    }
1027
 
1028
  for (p = deleted_threads.head; p; p = p->next)
1029
    {
1030
      if (p->tid == tid)
1031
        {
1032
          return p->pid;
1033
        }
1034
    }
1035
 
1036
  return 0;
1037
}
1038
 
1039
/* Note that this thread's current event has been handled.
1040
 */
1041
static void
1042
set_handled (int pid, lwpid_t tid)
1043
{
1044
  thread_info *p;
1045
 
1046
  p = find_thread_info (tid);
1047
  if (NULL == p)
1048
    p = add_tthread (pid, tid);
1049
 
1050
  p->handled = 1;
1051
}
1052
 
1053
/* Was this thread's current event handled?
1054
 */
1055
static int
1056
was_handled (lwpid_t tid)
1057
{
1058
  thread_info *p;
1059
 
1060
  p = find_thread_info (tid);
1061
  if (NULL != p)
1062
    return p->handled;
1063
 
1064
  return 0;                      /* New threads have not been handled */
1065
}
1066
 
1067
/* Set this thread to unhandled.
1068
 */
1069
static void
1070
clear_handled (lwpid_t tid)
1071
{
1072
  thread_info *p;
1073
 
1074
#ifdef WAIT_BUFFER_DEBUG
1075
  if (debug_on)
1076
    printf ("clear_handled %d\n", (int) tid);
1077
#endif
1078
 
1079
  p = find_thread_info (tid);
1080
  if (p == NULL)
1081
    error ("Internal error: No thread state to clear?");
1082
 
1083
  p->handled = 0;
1084
}
1085
 
1086
/* Set all threads to unhandled.
1087
 */
1088
static void
1089
clear_all_handled (void)
1090
{
1091
  thread_info *p;
1092
 
1093
#ifdef WAIT_BUFFER_DEBUG
1094
  if (debug_on)
1095
    printf ("clear_all_handled\n");
1096
#endif
1097
 
1098
  for (p = thread_head.head; p; p = p->next)
1099
    {
1100
      p->handled = 0;
1101
    }
1102
 
1103
  for (p = deleted_threads.head; p; p = p->next)
1104
    {
1105
      p->handled = 0;
1106
    }
1107
}
1108
 
1109
/* Set this thread to default stepping mode.
1110
 */
1111
static void
1112
clear_stepping_mode (lwpid_t tid)
1113
{
1114
  thread_info *p;
1115
 
1116
#ifdef WAIT_BUFFER_DEBUG
1117
  if (debug_on)
1118
    printf ("clear_stepping_mode %d\n", (int) tid);
1119
#endif
1120
 
1121
  p = find_thread_info (tid);
1122
  if (p == NULL)
1123
    error ("Internal error: No thread state to clear?");
1124
 
1125
  p->stepping_mode = DO_DEFAULT;
1126
}
1127
 
1128
/* Set all threads to do default continue on resume.
1129
 */
1130
static void
1131
clear_all_stepping_mode (void)
1132
{
1133
  thread_info *p;
1134
 
1135
#ifdef WAIT_BUFFER_DEBUG
1136
  if (debug_on)
1137
    printf ("clear_all_stepping_mode\n");
1138
#endif
1139
 
1140
  for (p = thread_head.head; p; p = p->next)
1141
    {
1142
      p->stepping_mode = DO_DEFAULT;
1143
    }
1144
 
1145
  for (p = deleted_threads.head; p; p = p->next)
1146
    {
1147
      p->stepping_mode = DO_DEFAULT;
1148
    }
1149
}
1150
 
1151
/* Set all threads to unseen on this pass.
1152
 */
1153
static void
1154
set_all_unseen (void)
1155
{
1156
  thread_info *p;
1157
 
1158
  for (p = thread_head.head; p; p = p->next)
1159
    {
1160
      p->seen = 0;
1161
    }
1162
}
1163
 
1164
#if (defined( THREAD_DEBUG ) || defined( PARANOIA ))
1165
/* debugging routine.
1166
 */
1167
static void
1168
print_tthread (thread_info *p)
1169
{
1170
  printf (" Thread pid %d, tid %d", p->pid, p->tid);
1171
  if (p->have_state)
1172
    printf (", event is %s",
1173
         get_printable_name_of_ttrace_event (p->last_stop_state.tts_event));
1174
 
1175
  if (p->am_pseudo)
1176
    printf (", pseudo thread");
1177
 
1178
  if (p->have_signal)
1179
    printf (", have signal 0x%x", p->signal_value);
1180
 
1181
  if (p->have_start)
1182
    printf (", have start at 0x%x", p->start);
1183
 
1184
  printf (", step is %s", get_printable_name_of_stepping_mode (p->stepping_mode));
1185
 
1186
  if (p->handled)
1187
    printf (", handled");
1188
  else
1189
    printf (", not handled");
1190
 
1191
  if (p->seen)
1192
    printf (", seen");
1193
  else
1194
    printf (", not seen");
1195
 
1196
  printf ("\n");
1197
}
1198
 
1199
static void
1200
print_tthreads (void)
1201
{
1202
  thread_info *p;
1203
 
1204
  if (thread_head.count == 0)
1205
    printf ("Thread list is empty\n");
1206
  else
1207
    {
1208
      printf ("Thread list has ");
1209
      if (thread_head.count == 1)
1210
        printf ("1 entry:\n");
1211
      else
1212
        printf ("%d entries:\n", thread_head.count);
1213
      for (p = thread_head.head; p; p = p->next)
1214
        {
1215
          print_tthread (p);
1216
        }
1217
    }
1218
 
1219
  if (deleted_threads.count == 0)
1220
    printf ("Deleted thread list is empty\n");
1221
  else
1222
    {
1223
      printf ("Deleted thread list has ");
1224
      if (deleted_threads.count == 1)
1225
        printf ("1 entry:\n");
1226
      else
1227
        printf ("%d entries:\n", deleted_threads.count);
1228
 
1229
      for (p = deleted_threads.head; p; p = p->next)
1230
        {
1231
          print_tthread (p);
1232
        }
1233
    }
1234
}
1235
#endif
1236
 
1237
/* Update the thread list based on the "seen" bits.
1238
 */
1239
static void
1240
update_thread_list (void)
1241
{
1242
  thread_info *p;
1243
  thread_info *chase;
1244
 
1245
  chase = NULL;
1246
  for (p = thread_head.head; p; p = p->next)
1247
    {
1248
      /* Is this an "unseen" thread which really happens to be a process?
1249
         If so, is it inferior_ptid and is a vfork in flight?  If yes to
1250
         all, then DON'T REMOVE IT!  We're in the midst of moving a vfork
1251
         operation, which is a multiple step thing, to the point where we
1252
         can touch the parent again.  We've most likely stopped to examine
1253
         the child at a late stage in the vfork, and if we're not following
1254
         the child, we'd best not treat the parent as a dead "thread"...
1255
       */
1256
      if ((!p->seen) && p->am_pseudo && vfork_in_flight
1257
          && (p->pid != vforking_child_pid))
1258
        p->seen = 1;
1259
 
1260
      if (!p->seen)
1261
        {
1262
          /* Remove this one
1263
           */
1264
 
1265
#ifdef THREAD_DEBUG
1266
          if (debug_on)
1267
            printf ("Delete unseen thread: %d \n", p->tid);
1268
#endif
1269
          del_tthread (p->tid);
1270
        }
1271
    }
1272
}
1273
 
1274
 
1275
 
1276
/************************************************
1277
 *            O/S call wrappers                 *
1278
 ************************************************
1279
 */
1280
 
1281
/* This function simply calls ttrace with the given arguments.
1282
 * It exists so that all calls to ttrace are isolated.  All
1283
 * parameters should be as specified by "man 2 ttrace".
1284
 *
1285
 * No other "raw" calls to ttrace should exist in this module.
1286
 */
1287
static int
1288
call_real_ttrace (ttreq_t request, pid_t pid, lwpid_t tid, TTRACE_ARG_TYPE addr,
1289
                  TTRACE_ARG_TYPE data, TTRACE_ARG_TYPE addr2)
1290
{
1291
  int tt_status;
1292
 
1293
  errno = 0;
1294
  tt_status = ttrace (request, pid, tid, addr, data, addr2);
1295
 
1296
#ifdef THREAD_DEBUG
1297
  if (errno)
1298
    {
1299
      /* Don't bother for a known benign error: if you ask for the
1300
       * first thread state, but there is only one thread and it's
1301
       * not stopped, ttrace complains.
1302
       *
1303
       * We have this inside the #ifdef because our caller will do
1304
       * this check for real.
1305
       */
1306
      if (request != TT_PROC_GET_FIRST_LWP_STATE
1307
          || errno != EPROTO)
1308
        {
1309
          if (debug_on)
1310
            printf ("TT fail for %s, with pid %d, tid %d, status %d \n",
1311
                    get_printable_name_of_ttrace_request (request),
1312
                    pid, tid, tt_status);
1313
        }
1314
    }
1315
#endif
1316
 
1317
#if 0
1318
  /* ??rehrauer: It would probably be most robust to catch and report
1319
   * failed requests here.  However, some clients of this interface
1320
   * seem to expect to catch & deal with them, so we'd best not.
1321
   */
1322
  if (errno)
1323
    {
1324
      strcpy (reason_for_failure, "ttrace (");
1325
      strcat (reason_for_failure, get_printable_name_of_ttrace_request (request));
1326
      strcat (reason_for_failure, ")");
1327
      printf ("ttrace error, errno = %d\n", errno);
1328
      perror_with_name (reason_for_failure);
1329
    }
1330
#endif
1331
 
1332
  return tt_status;
1333
}
1334
 
1335
 
1336
/* This function simply calls ttrace_wait with the given arguments.
1337
 * It exists so that all calls to ttrace_wait are isolated.
1338
 *
1339
 * No "raw" calls to ttrace_wait should exist elsewhere.
1340
 */
1341
static int
1342
call_real_ttrace_wait (int pid, lwpid_t tid, ttwopt_t option, ttstate_t *tsp,
1343
                       size_t tsp_size)
1344
{
1345
  int ttw_status;
1346
  thread_info *tinfo = NULL;
1347
 
1348
  errno = 0;
1349
  ttw_status = ttrace_wait (pid, tid, option, tsp, tsp_size);
1350
 
1351
  if (errno)
1352
    {
1353
#ifdef THREAD_DEBUG
1354
      if (debug_on)
1355
        printf ("TW fail with pid %d, tid %d \n", pid, tid);
1356
#endif
1357
 
1358
      perror_with_name ("ttrace wait");
1359
    }
1360
 
1361
  return ttw_status;
1362
}
1363
 
1364
 
1365
/* A process may have one or more kernel threads, of which all or
1366
   none may be stopped.  This function returns the ID of the first
1367
   kernel thread in a stopped state, or 0 if none are stopped.
1368
 
1369
   This function can be used with get_process_next_stopped_thread_id
1370
   to iterate over the IDs of all stopped threads of this process.
1371
 */
1372
static lwpid_t
1373
get_process_first_stopped_thread_id (int pid, ttstate_t *thread_state)
1374
{
1375
  int tt_status;
1376
 
1377
  tt_status = call_real_ttrace (TT_PROC_GET_FIRST_LWP_STATE,
1378
                                (pid_t) pid,
1379
                                (lwpid_t) TT_NIL,
1380
                                (TTRACE_ARG_TYPE) thread_state,
1381
                                (TTRACE_ARG_TYPE) sizeof (*thread_state),
1382
                                TT_NIL);
1383
 
1384
  if (errno)
1385
    {
1386
      if (errno == EPROTO)
1387
        {
1388
          /* This is an error we can handle: there isn't any stopped
1389
           * thread.  This happens when we're re-starting the application
1390
           * and it has only one thread.  GET_NEXT handles the case of
1391
           * no more stopped threads well; GET_FIRST doesn't.  (A ttrace
1392
           * "feature".)
1393
           */
1394
          tt_status = 1;
1395
          errno = 0;
1396
          return 0;
1397
        }
1398
      else
1399
        perror_with_name ("ttrace");
1400
    }
1401
 
1402
  if (tt_status < 0)
1403
    /* Failed somehow.
1404
     */
1405
    return 0;
1406
 
1407
  return thread_state->tts_lwpid;
1408
}
1409
 
1410
 
1411
/* This function returns the ID of the "next" kernel thread in a
1412
   stopped state, or 0 if there are none.  "Next" refers to the
1413
   thread following that of the last successful call to this
1414
   function or to get_process_first_stopped_thread_id, using
1415
   the value of thread_state returned by that call.
1416
 
1417
   This function can be used with get_process_first_stopped_thread_id
1418
   to iterate over the IDs of all stopped threads of this process.
1419
 */
1420
static lwpid_t
1421
get_process_next_stopped_thread_id (int pid, ttstate_t *thread_state)
1422
{
1423
  int tt_status;
1424
 
1425
  tt_status = call_real_ttrace (
1426
                                 TT_PROC_GET_NEXT_LWP_STATE,
1427
                                 (pid_t) pid,
1428
                                 (lwpid_t) TT_NIL,
1429
                                 (TTRACE_ARG_TYPE) thread_state,
1430
                                 (TTRACE_ARG_TYPE) sizeof (*thread_state),
1431
                                 TT_NIL);
1432
  if (errno)
1433
    perror_with_name ("ttrace");
1434
 
1435
  if (tt_status < 0)
1436
    /* Failed
1437
     */
1438
    return 0;
1439
 
1440
  else if (tt_status == 0)
1441
    {
1442
      /* End of list, no next state.  Don't return the
1443
       * tts_lwpid, as it's a meaningless "240".
1444
       *
1445
       * This is an HPUX "feature".
1446
       */
1447
      return 0;
1448
    }
1449
 
1450
  return thread_state->tts_lwpid;
1451
}
1452
 
1453
/* ??rehrauer: Eventually this function perhaps should be calling
1454
   pid_to_thread_id.  However, that function currently does nothing
1455
   for HP-UX.  Even then, I'm not clear whether that function
1456
   will return a "kernel" thread ID, or a "user" thread ID.  If
1457
   the former, we can just call it here.  If the latter, we must
1458
   map from the "user" tid to a "kernel" tid.
1459
 
1460
   NOTE: currently not called.
1461
 */
1462
static lwpid_t
1463
get_active_tid_of_pid (int pid)
1464
{
1465
  ttstate_t thread_state;
1466
 
1467
  return get_process_first_stopped_thread_id (pid, &thread_state);
1468
}
1469
 
1470
/* This function returns 1 if tt_request is a ttrace request that
1471
 * operates upon all threads of a (i.e., the entire) process.
1472
 */
1473
int
1474
is_process_ttrace_request (ttreq_t tt_request)
1475
{
1476
  return IS_TTRACE_PROCREQ (tt_request);
1477
}
1478
 
1479
 
1480
/* This function translates a thread ttrace request into
1481
 * the equivalent process request for a one-thread process.
1482
 */
1483
static ttreq_t
1484
make_process_version (ttreq_t request)
1485
{
1486
  if (!IS_TTRACE_REQ (request))
1487
    {
1488
      error ("Internal error, bad ttrace request made\n");
1489
      return -1;
1490
    }
1491
 
1492
  switch (request)
1493
    {
1494
    case TT_LWP_STOP:
1495
      return TT_PROC_STOP;
1496
 
1497
    case TT_LWP_CONTINUE:
1498
      return TT_PROC_CONTINUE;
1499
 
1500
    case TT_LWP_GET_EVENT_MASK:
1501
      return TT_PROC_GET_EVENT_MASK;
1502
 
1503
    case TT_LWP_SET_EVENT_MASK:
1504
      return TT_PROC_SET_EVENT_MASK;
1505
 
1506
    case TT_LWP_SINGLE:
1507
    case TT_LWP_RUREGS:
1508
    case TT_LWP_WUREGS:
1509
    case TT_LWP_GET_STATE:
1510
      return -1;                /* No equivalent */
1511
 
1512
    default:
1513
      return request;
1514
    }
1515
}
1516
 
1517
 
1518
/* This function translates the "pid" used by the rest of
1519
 * gdb to a real pid and a tid.  It then calls "call_real_ttrace"
1520
 * with the given arguments.
1521
 *
1522
 * In general, other parts of this module should call this
1523
 * function when they are dealing with external users, who only
1524
 * have tids to pass (but they call it "pid" for historical
1525
 * reasons).
1526
 */
1527
static int
1528
call_ttrace (ttreq_t request, int gdb_tid, TTRACE_ARG_TYPE addr,
1529
             TTRACE_ARG_TYPE data, TTRACE_ARG_TYPE addr2)
1530
{
1531
  lwpid_t real_tid;
1532
  int real_pid;
1533
  ttreq_t new_request;
1534
  int tt_status;
1535
  char reason_for_failure[100]; /* Arbitrary size, should be big enough. */
1536
 
1537
#ifdef THREAD_DEBUG
1538
  int is_interesting = 0;
1539
 
1540
  if (TT_LWP_RUREGS == request)
1541
    {
1542
      is_interesting = 1;       /* Adjust code here as desired */
1543
    }
1544
 
1545
  if (is_interesting && 0 && debug_on)
1546
    {
1547
      if (!is_process_ttrace_request (request))
1548
        {
1549
          printf ("TT: Thread request, tid is %d", gdb_tid);
1550
          printf ("== SINGLE at %x", addr);
1551
        }
1552
      else
1553
        {
1554
          printf ("TT: Process request, tid is %d\n", gdb_tid);
1555
          printf ("==! SINGLE at %x", addr);
1556
        }
1557
    }
1558
#endif
1559
 
1560
  /* The initial SETTRC and SET_EVENT_MASK calls (and all others
1561
   * which happen before any threads get set up) should go
1562
   * directly to "call_real_ttrace", so they don't happen here.
1563
   *
1564
   * But hardware watchpoints do a SET_EVENT_MASK, so we can't
1565
   * rule them out....
1566
   */
1567
#ifdef THREAD_DEBUG
1568
  if (request == TT_PROC_SETTRC && debug_on)
1569
    printf ("Unexpected call for TT_PROC_SETTRC\n");
1570
#endif
1571
 
1572
  /* Sometimes we get called with a bogus tid (e.g., if a
1573
   * thread has terminated, we return 0; inftarg later asks
1574
   * whether the thread has exited/forked/vforked).
1575
   */
1576
  if (gdb_tid == 0)
1577
    {
1578
      errno = ESRCH;            /* ttrace's response would probably be "No such process". */
1579
      return -1;
1580
    }
1581
 
1582
  /* All other cases should be able to expect that there are
1583
   * thread records.
1584
   */
1585
  if (!any_thread_records ())
1586
    {
1587
#ifdef THREAD_DEBUG
1588
      if (debug_on)
1589
        warning ("No thread records for ttrace call");
1590
#endif
1591
      errno = ESRCH;            /* ttrace's response would be "No such process". */
1592
      return -1;
1593
    }
1594
 
1595
  /* OK, now the task is to translate the incoming tid into
1596
   * a pid/tid pair.
1597
   */
1598
  real_tid = map_from_gdb_tid (gdb_tid);
1599
  real_pid = get_pid_for (real_tid);
1600
 
1601
  /* Now check the result.  "Real_pid" is NULL if our list
1602
   * didn't find it.  We have some tricks we can play to fix
1603
   * this, however.
1604
   */
1605
  if (0 == real_pid)
1606
    {
1607
      ttstate_t thread_state;
1608
 
1609
#ifdef THREAD_DEBUG
1610
      if (debug_on)
1611
        printf ("No saved pid for tid %d\n", gdb_tid);
1612
#endif
1613
 
1614
      if (is_process_ttrace_request (request))
1615
        {
1616
 
1617
          /* Ok, we couldn't get a tid.  Try to translate to
1618
           * the equivalent process operation.  We expect this
1619
           * NOT to happen, so this is a desparation-type
1620
           * move.  It can happen if there is an internal
1621
           * error and so no "wait()" call is ever done.
1622
           */
1623
          new_request = make_process_version (request);
1624
          if (new_request == -1)
1625
            {
1626
 
1627
#ifdef THREAD_DEBUG
1628
              if (debug_on)
1629
                printf ("...and couldn't make process version of thread operation\n");
1630
#endif
1631
 
1632
              /* Use hacky saved pid, which won't always be correct
1633
               * in the multi-process future.  Use tid as thread,
1634
               * probably dooming this to failure.  FIX!
1635
               */
1636
              if (! ptid_equal (saved_real_ptid, null_ptid))
1637
                {
1638
#ifdef THREAD_DEBUG
1639
                  if (debug_on)
1640
                    printf ("...using saved pid %d\n",
1641
                            PIDGET (saved_real_ptid));
1642
#endif
1643
 
1644
                  real_pid = PIDGET (saved_real_ptid);
1645
                  real_tid = gdb_tid;
1646
                }
1647
 
1648
              else
1649
                error ("Unable to perform thread operation");
1650
            }
1651
 
1652
          else
1653
            {
1654
              /* Sucessfully translated this to a process request,
1655
               * which needs no thread value.
1656
               */
1657
              real_pid = gdb_tid;
1658
              real_tid = 0;
1659
              request = new_request;
1660
 
1661
#ifdef THREAD_DEBUG
1662
              if (debug_on)
1663
                {
1664
                  printf ("Translated thread request to process request\n");
1665
                  if (ptid_equal (saved_real_ptid, null_ptid))
1666
                    printf ("...but there's no saved pid\n");
1667
 
1668
                  else
1669
                    {
1670
                      if (gdb_tid != PIDGET (saved_real_ptid))
1671
                        printf ("...but have the wrong pid (%d rather than %d)\n",
1672
                                gdb_tid, PIDGET (saved_real_ptid));
1673
                    }
1674
                }
1675
#endif
1676
            }                   /* Translated to a process request */
1677
        }                       /* Is a process request */
1678
 
1679
      else
1680
        {
1681
          /* We have to have a thread.  Ooops.
1682
           */
1683
          error ("Thread request with no threads (%s)",
1684
                 get_printable_name_of_ttrace_request (request));
1685
        }
1686
    }
1687
 
1688
  /* Ttrace doesn't like to see tid values on process requests,
1689
   * even if we have the right one.
1690
   */
1691
  if (is_process_ttrace_request (request))
1692
    {
1693
      real_tid = 0;
1694
    }
1695
 
1696
#ifdef THREAD_DEBUG
1697
  if (is_interesting && 0 && debug_on)
1698
    {
1699
      printf ("    now tid %d, pid %d\n", real_tid, real_pid);
1700
      printf ("    request is %s\n", get_printable_name_of_ttrace_request (request));
1701
    }
1702
#endif
1703
 
1704
  /* Finally, the (almost) real call.
1705
   */
1706
  tt_status = call_real_ttrace (request, real_pid, real_tid, addr, data, addr2);
1707
 
1708
#ifdef THREAD_DEBUG
1709
  if (is_interesting && debug_on)
1710
    {
1711
      if (!TT_OK (tt_status, errno)
1712
          && !(tt_status == 0 & errno == 0))
1713
        printf (" got error (errno==%d, status==%d)\n", errno, tt_status);
1714
    }
1715
#endif
1716
 
1717
  return tt_status;
1718
}
1719
 
1720
 
1721
/* Stop all the threads of a process.
1722
 
1723
 * NOTE: use of TT_PROC_STOP can cause a thread with a real event
1724
 *       to get a TTEVT_NONE event, discarding the old event.  Be
1725
 *       very careful, and only call TT_PROC_STOP when you mean it!
1726
 */
1727
static void
1728
stop_all_threads_of_process (pid_t real_pid)
1729
{
1730
  int ttw_status;
1731
 
1732
  ttw_status = call_real_ttrace (TT_PROC_STOP,
1733
                                 (pid_t) real_pid,
1734
                                 (lwpid_t) TT_NIL,
1735
                                 (TTRACE_ARG_TYPE) TT_NIL,
1736
                                 (TTRACE_ARG_TYPE) TT_NIL,
1737
                                 TT_NIL);
1738
  if (errno)
1739
    perror_with_name ("ttrace stop of other threads");
1740
}
1741
 
1742
 
1743
/* Under some circumstances, it's unsafe to attempt to stop, or even
1744
   query the state of, a process' threads.
1745
 
1746
   In ttrace-based HP-UX, an example is a vforking child process.  The
1747
   vforking parent and child are somewhat fragile, w/r/t what we can do
1748
   what we can do to them with ttrace, until after the child exits or
1749
   execs, or until the parent's vfork event is delivered.  Until that
1750
   time, we must not try to stop the process' threads, or inquire how
1751
   many there are, or even alter its data segments, or it typically dies
1752
   with a SIGILL.  Sigh.
1753
 
1754
   This function returns 1 if this stopped process, and the event that
1755
   we're told was responsible for its current stopped state, cannot safely
1756
   have its threads examined.
1757
 */
1758
#define CHILD_VFORKED(evt,pid) \
1759
  (((evt) == TTEVT_VFORK) && ((pid) != PIDGET (inferior_ptid)))
1760
#define CHILD_URPED(evt,pid) \
1761
  ((((evt) == TTEVT_EXEC) || ((evt) == TTEVT_EXIT)) && ((pid) != vforking_child_pid))
1762
#define PARENT_VFORKED(evt,pid) \
1763
  (((evt) == TTEVT_VFORK) && ((pid) == PIDGET (inferior_ptid)))
1764
 
1765
static int
1766
can_touch_threads_of_process (int pid, ttevents_t stopping_event)
1767
{
1768
  if (CHILD_VFORKED (stopping_event, pid))
1769
    {
1770
      vforking_child_pid = pid;
1771
      vfork_in_flight = 1;
1772
    }
1773
 
1774
  else if (vfork_in_flight &&
1775
           (PARENT_VFORKED (stopping_event, pid) ||
1776
            CHILD_URPED (stopping_event, pid)))
1777
    {
1778
      vfork_in_flight = 0;
1779
      vforking_child_pid = 0;
1780
    }
1781
 
1782
  return !vfork_in_flight;
1783
}
1784
 
1785
 
1786
/* If we can find an as-yet-unhandled thread state of a
1787
 * stopped thread of this process return 1 and set "tsp".
1788
 * Return 0 if we can't.
1789
 *
1790
 * If this function is used when the threads of PIS haven't
1791
 * been stopped, undefined behaviour is guaranteed!
1792
 */
1793
static int
1794
select_stopped_thread_of_process (int pid, ttstate_t *tsp)
1795
{
1796
  lwpid_t candidate_tid, tid;
1797
  ttstate_t candidate_tstate, tstate;
1798
 
1799
  /* If we're not allowed to touch the process now, then just
1800
   * return the current value of *TSP.
1801
   *
1802
   * This supports "vfork".  It's ok, really, to double the
1803
   * current event (the child EXEC, we hope!).
1804
   */
1805
  if (!can_touch_threads_of_process (pid, tsp->tts_event))
1806
    return 1;
1807
 
1808
  /* Decide which of (possibly more than one) events to
1809
   * return as the first one.  We scan them all so that
1810
   * we always return the result of a fake-step first.
1811
   */
1812
  candidate_tid = 0;
1813
  for (tid = get_process_first_stopped_thread_id (pid, &tstate);
1814
       tid != 0;
1815
       tid = get_process_next_stopped_thread_id (pid, &tstate))
1816
    {
1817
      /* TTEVT_NONE events are uninteresting to our clients.  They're
1818
       * an artifact of our "stop the world" model--the thread is
1819
       * stopped because we stopped it.
1820
       */
1821
      if (tstate.tts_event == TTEVT_NONE)
1822
        {
1823
          set_handled (pid, tstate.tts_lwpid);
1824
        }
1825
 
1826
      /* Did we just single-step a single thread, without letting any
1827
       * of the others run?  Is this an event for that thread?
1828
       *
1829
       * If so, we believe our client would prefer to see this event
1830
       * over any others.  (Typically the client wants to just push
1831
       * one thread a little farther forward, and then go around
1832
       * checking for what all threads are doing.)
1833
       */
1834
      else if (doing_fake_step && (tstate.tts_lwpid == fake_step_tid))
1835
        {
1836
#ifdef WAIT_BUFFER_DEBUG
1837
          /* It's possible here to see either a SIGTRAP (due to
1838
           * successful completion of a step) or a SYSCALL_ENTRY
1839
           * (due to a step completion with active hardware
1840
           * watchpoints).
1841
           */
1842
          if (debug_on)
1843
            printf ("Ending fake step with tid %d, state %s\n",
1844
                    tstate.tts_lwpid,
1845
                    get_printable_name_of_ttrace_event (tstate.tts_event));
1846
#endif
1847
 
1848
          /* Remember this one, and throw away any previous
1849
           * candidate.
1850
           */
1851
          candidate_tid = tstate.tts_lwpid;
1852
          candidate_tstate = tstate;
1853
        }
1854
 
1855
#ifdef FORGET_DELETED_BPTS
1856
 
1857
      /* We can't just do this, as if we do, and then wind
1858
       * up the loop with no unhandled events, we need to
1859
       * handle that case--the appropriate reaction is to
1860
       * just continue, but there's no easy way to do that.
1861
       *
1862
       * Better to put this in the ttrace_wait call--if, when
1863
       * we fake a wait, we update our events based on the
1864
       * breakpoint_here_pc call and find there are no more events,
1865
       * then we better continue and so on.
1866
       *
1867
       * Or we could put it in the next/continue fake.
1868
       * But it has to go in the buffering code, not in the
1869
       * real go/wait code.
1870
       */
1871
      else if ((TTEVT_SIGNAL == tstate.tts_event)
1872
               && (5 == tstate.tts_u.tts_signal.tts_signo)
1873
               && (0 != get_raw_pc (tstate.tts_lwpid))
1874
               && !breakpoint_here_p (get_raw_pc (tstate.tts_lwpid)))
1875
        {
1876
          /*
1877
           * If the user deleted a breakpoint while this
1878
           * breakpoint-hit event was buffered, we can forget
1879
           * it now.
1880
           */
1881
#ifdef WAIT_BUFFER_DEBUG
1882
          if (debug_on)
1883
            printf ("Forgetting deleted bp hit for thread %d\n",
1884
                    tstate.tts_lwpid);
1885
#endif
1886
 
1887
          set_handled (pid, tstate.tts_lwpid);
1888
        }
1889
#endif
1890
 
1891
      /* Else, is this the first "unhandled" event?  If so,
1892
       * we believe our client wants to see it (if we don't
1893
       * see a fake-step later on in the scan).
1894
       */
1895
      else if (!was_handled (tstate.tts_lwpid) && candidate_tid == 0)
1896
        {
1897
          candidate_tid = tstate.tts_lwpid;
1898
          candidate_tstate = tstate;
1899
        }
1900
 
1901
      /* This is either an event that has already been "handled",
1902
       * and thus we believe is uninteresting to our client, or we
1903
       * already have a candidate event.  Ignore it...
1904
       */
1905
    }
1906
 
1907
  /* What do we report?
1908
   */
1909
  if (doing_fake_step)
1910
    {
1911
      if (candidate_tid == fake_step_tid)
1912
        {
1913
          /* Fake step.
1914
           */
1915
          tstate = candidate_tstate;
1916
        }
1917
      else
1918
        {
1919
          warning ("Internal error: fake-step failed to complete.");
1920
          return 0;
1921
        }
1922
    }
1923
  else if (candidate_tid != 0)
1924
    {
1925
      /* Found a candidate unhandled event.
1926
       */
1927
      tstate = candidate_tstate;
1928
    }
1929
  else if (tid != 0)
1930
    {
1931
      warning ("Internal error in call of ttrace_wait.");
1932
      return 0;
1933
    }
1934
  else
1935
    {
1936
      warning ("Internal error: no unhandled thread event to select");
1937
      return 0;
1938
    }
1939
 
1940
  copy_ttstate_t (tsp, &tstate);
1941
  return 1;
1942
}                               /* End of select_stopped_thread_of_process */
1943
 
1944
#ifdef PARANOIA
1945
/* Check our internal thread data against the real thing.
1946
 */
1947
static void
1948
check_thread_consistency (pid_t real_pid)
1949
{
1950
  int tid;                      /* really lwpid_t */
1951
  ttstate_t tstate;
1952
  thread_info *p;
1953
 
1954
  /* Spin down the O/S list of threads, checking that they
1955
   * match what we've got.
1956
   */
1957
  for (tid = get_process_first_stopped_thread_id (real_pid, &tstate);
1958
       tid != 0;
1959
       tid = get_process_next_stopped_thread_id (real_pid, &tstate))
1960
    {
1961
 
1962
      p = find_thread_info (tid);
1963
 
1964
      if (NULL == p)
1965
        {
1966
          warning ("No internal thread data for thread %d.", tid);
1967
          continue;
1968
        }
1969
 
1970
      if (!p->seen)
1971
        {
1972
          warning ("Inconsistent internal thread data for thread %d.", tid);
1973
        }
1974
 
1975
      if (p->terminated)
1976
        {
1977
          warning ("Thread %d is not terminated, internal error.", tid);
1978
          continue;
1979
        }
1980
 
1981
 
1982
#define TT_COMPARE( fld ) \
1983
            tstate.fld != p->last_stop_state.fld
1984
 
1985
      if (p->have_state)
1986
        {
1987
          if (TT_COMPARE (tts_pid)
1988
              || TT_COMPARE (tts_lwpid)
1989
              || TT_COMPARE (tts_user_tid)
1990
              || TT_COMPARE (tts_event)
1991
              || TT_COMPARE (tts_flags)
1992
              || TT_COMPARE (tts_scno)
1993
              || TT_COMPARE (tts_scnargs))
1994
            {
1995
              warning ("Internal thread data for thread %d is wrong.", tid);
1996
              continue;
1997
            }
1998
        }
1999
    }
2000
}
2001
#endif /* PARANOIA */
2002
 
2003
 
2004
/* This function wraps calls to "call_real_ttrace_wait" so
2005
 * that a actual wait is only done when all pending events
2006
 * have been reported.
2007
 *
2008
 * Note that typically it is called with a pid of "0", i.e.
2009
 * the "don't care" value.
2010
 *
2011
 * Return value is the status of the pseudo wait.
2012
 */
2013
static int
2014
call_ttrace_wait (int pid, ttwopt_t option, ttstate_t *tsp, size_t tsp_size)
2015
{
2016
  /* This holds the actual, for-real, true process ID.
2017
   */
2018
  static int real_pid;
2019
 
2020
  /* As an argument to ttrace_wait, zero pid
2021
   * means "Any process", and zero tid means
2022
   * "Any thread of the specified process".
2023
   */
2024
  int wait_pid = 0;
2025
  lwpid_t wait_tid = 0;
2026
  lwpid_t real_tid;
2027
 
2028
  int ttw_status = 0;            /* To be returned */
2029
 
2030
  thread_info *tinfo = NULL;
2031
 
2032
  if (pid != 0)
2033
    {
2034
      /* Unexpected case.
2035
       */
2036
#ifdef THREAD_DEBUG
2037
      if (debug_on)
2038
        printf ("TW: Pid to wait on is %d\n", pid);
2039
#endif
2040
 
2041
      if (!any_thread_records ())
2042
        error ("No thread records for ttrace call w. specific pid");
2043
 
2044
      /* OK, now the task is to translate the incoming tid into
2045
       * a pid/tid pair.
2046
       */
2047
      real_tid = map_from_gdb_tid (pid);
2048
      real_pid = get_pid_for (real_tid);
2049
#ifdef THREAD_DEBUG
2050
      if (debug_on)
2051
        printf ("==TW: real pid %d, real tid %d\n", real_pid, real_tid);
2052
#endif
2053
    }
2054
 
2055
 
2056
  /* Sanity checks and set-up.
2057
   *                             Process State
2058
   *
2059
   *                        Stopped   Running    Fake-step  (v)Fork
2060
   *                      \________________________________________
2061
   *                      |
2062
   *  No buffered events  |  error     wait       wait      wait
2063
   *                      |
2064
   *  Buffered events     |  debuffer  error      wait      debuffer (?)
2065
   *
2066
   */
2067
  if (more_events_left == 0)
2068
    {
2069
 
2070
      if (process_state == RUNNING)
2071
        {
2072
          /* OK--normal call of ttrace_wait with no buffered events.
2073
           */
2074
          ;
2075
        }
2076
      else if (process_state == FAKE_STEPPING)
2077
        {
2078
          /* Ok--call of ttrace_wait to support
2079
           * fake stepping with no buffered events.
2080
           *
2081
           * But we better be fake-stepping!
2082
           */
2083
          if (!doing_fake_step)
2084
            {
2085
              warning ("Inconsistent thread state.");
2086
            }
2087
        }
2088
      else if ((process_state == FORKING)
2089
               || (process_state == VFORKING))
2090
        {
2091
          /* Ok--there are two processes, so waiting
2092
           * for the second while the first is stopped
2093
           * is ok.  Handled bits stay as they were.
2094
           */
2095
          ;
2096
        }
2097
      else if (process_state == STOPPED)
2098
        {
2099
          warning ("Process not running at wait call.");
2100
        }
2101
      else
2102
        /* No known state.
2103
         */
2104
        warning ("Inconsistent process state.");
2105
    }
2106
 
2107
  else
2108
    {
2109
      /* More events left
2110
       */
2111
      if (process_state == STOPPED)
2112
        {
2113
          /* OK--buffered events being unbuffered.
2114
           */
2115
          ;
2116
        }
2117
      else if (process_state == RUNNING)
2118
        {
2119
          /* An error--shouldn't have buffered events
2120
           * when running.
2121
           */
2122
          warning ("Trying to continue with buffered events:");
2123
        }
2124
      else if (process_state == FAKE_STEPPING)
2125
        {
2126
          /*
2127
           * Better be fake-stepping!
2128
           */
2129
          if (!doing_fake_step)
2130
            {
2131
              warning ("Losing buffered thread events!\n");
2132
            }
2133
        }
2134
      else if ((process_state == FORKING)
2135
               || (process_state == VFORKING))
2136
        {
2137
          /* Ok--there are two processes, so waiting
2138
           * for the second while the first is stopped
2139
           * is ok.  Handled bits stay as they were.
2140
           */
2141
          ;
2142
        }
2143
      else
2144
        warning ("Process in unknown state with buffered events.");
2145
    }
2146
 
2147
  /* Sometimes we have to wait for a particular thread
2148
   * (if we're stepping over a bpt).  In that case, we
2149
   * _know_ it's going to complete the single-step we
2150
   * asked for (because we're only doing the step under
2151
   * certain very well-understood circumstances), so it
2152
   * can't block.
2153
   */
2154
  if (doing_fake_step)
2155
    {
2156
      wait_tid = fake_step_tid;
2157
      wait_pid = get_pid_for (fake_step_tid);
2158
 
2159
#ifdef WAIT_BUFFER_DEBUG
2160
      if (debug_on)
2161
        printf ("Doing a wait after a fake-step for %d, pid %d\n",
2162
                wait_tid, wait_pid);
2163
#endif
2164
    }
2165
 
2166
  if (more_events_left == 0      /* No buffered events, need real ones. */
2167
      || process_state != STOPPED)
2168
    {
2169
      /* If there are no buffered events, and so we need
2170
       * real ones, or if we are FORKING, VFORKING,
2171
       * FAKE_STEPPING or RUNNING, and thus have to do
2172
       * a real wait, then do a real wait.
2173
       */
2174
 
2175
#ifdef WAIT_BUFFER_DEBUG
2176
      /* Normal case... */
2177
      if (debug_on)
2178
        printf ("TW: do it for real; pid %d, tid %d\n", wait_pid, wait_tid);
2179
#endif
2180
 
2181
      /* The actual wait call.
2182
       */
2183
      ttw_status = call_real_ttrace_wait (wait_pid, wait_tid, option, tsp, tsp_size);
2184
 
2185
      /* Note that the routines we'll call will be using "call_real_ttrace",
2186
       * not "call_ttrace", and thus need the real pid rather than the pseudo-tid
2187
       * the rest of the world uses (which is actually the tid).
2188
       */
2189
      real_pid = tsp->tts_pid;
2190
 
2191
      /* For most events: Stop the world!
2192
 
2193
       * It's sometimes not safe to stop all threads of a process.
2194
       * Sometimes it's not even safe to ask for the thread state
2195
       * of a process!
2196
       */
2197
      if (can_touch_threads_of_process (real_pid, tsp->tts_event))
2198
        {
2199
          /* If we're really only stepping a single thread, then don't
2200
           * try to stop all the others -- we only do this single-stepping
2201
           * business when all others were already stopped...and the stop
2202
           * would mess up other threads' events.
2203
           *
2204
           * Similiarly, if there are other threads with events,
2205
           * don't do the stop.
2206
           */
2207
          if (!doing_fake_step)
2208
            {
2209
              if (more_events_left > 0)
2210
                warning ("Internal error in stopping process");
2211
 
2212
              stop_all_threads_of_process (real_pid);
2213
 
2214
              /* At this point, we could scan and update_thread_list(),
2215
               * and only use the local list for the rest of the
2216
               * module! We'd get rid of the scans in the various
2217
               * continue routines (adding one in attach).  It'd
2218
               * be great--UPGRADE ME!
2219
               */
2220
            }
2221
        }
2222
 
2223
#ifdef PARANOIA
2224
      else if (debug_on)
2225
        {
2226
          if (more_events_left > 0)
2227
            printf ("== Can't stop process; more events!\n");
2228
          else
2229
            printf ("== Can't stop process!\n");
2230
        }
2231
#endif
2232
 
2233
      process_state = STOPPED;
2234
 
2235
#ifdef WAIT_BUFFER_DEBUG
2236
      if (debug_on)
2237
        printf ("Process set to STOPPED\n");
2238
#endif
2239
    }
2240
 
2241
  else
2242
    {
2243
      /* Fake a call to ttrace_wait.  The process must be
2244
       * STOPPED, as we aren't going to do any wait.
2245
       */
2246
#ifdef WAIT_BUFFER_DEBUG
2247
      if (debug_on)
2248
        printf ("TW: fake it\n");
2249
#endif
2250
 
2251
      if (process_state != STOPPED)
2252
        {
2253
          warning ("Process not stopped at wait call, in state '%s'.\n",
2254
                   get_printable_name_of_process_state (process_state));
2255
        }
2256
 
2257
      if (doing_fake_step)
2258
        error ("Internal error in stepping over breakpoint");
2259
 
2260
      ttw_status = 0;            /* Faking it is always successful! */
2261
    }                           /* End of fake or not? if */
2262
 
2263
  /* Pick an event to pass to our caller.  Be paranoid.
2264
   */
2265
  if (!select_stopped_thread_of_process (real_pid, tsp))
2266
    warning ("Can't find event, using previous event.");
2267
 
2268
  else if (tsp->tts_event == TTEVT_NONE)
2269
    warning ("Internal error: no thread has a real event.");
2270
 
2271
  else if (doing_fake_step)
2272
    {
2273
      if (fake_step_tid != tsp->tts_lwpid)
2274
        warning ("Internal error in stepping over breakpoint.");
2275
 
2276
      /* This wait clears the (current) fake-step if there was one.
2277
       */
2278
      doing_fake_step = 0;
2279
      fake_step_tid = 0;
2280
    }
2281
 
2282
  /* We now have a correct tsp and ttw_status for the thread
2283
   * which we want to report.  So it's "handled"!  This call
2284
   * will add it to our list if it's not there already.
2285
   */
2286
  set_handled (real_pid, tsp->tts_lwpid);
2287
 
2288
  /* Save a copy of the ttrace state of this thread, in our local
2289
     thread descriptor.
2290
 
2291
     This caches the state.  The implementation of queries like
2292
     target_has_execd can then use this cached state, rather than
2293
     be forced to make an explicit ttrace call to get it.
2294
 
2295
     (Guard against the condition that this is the first time we've
2296
     waited on, i.e., seen this thread, and so haven't yet entered
2297
     it into our list of threads.)
2298
   */
2299
  tinfo = find_thread_info (tsp->tts_lwpid);
2300
  if (tinfo != NULL)
2301
    {
2302
      copy_ttstate_t (&tinfo->last_stop_state, tsp);
2303
      tinfo->have_state = 1;
2304
    }
2305
 
2306
  return ttw_status;
2307
}                               /* call_ttrace_wait */
2308
 
2309
#if defined(CHILD_REPORTED_EXEC_EVENTS_PER_EXEC_CALL)
2310
int
2311
child_reported_exec_events_per_exec_call (void)
2312
{
2313
  return 1;                     /* ttrace reports the event once per call. */
2314
}
2315
#endif
2316
 
2317
 
2318
 
2319
/* Our implementation of hardware watchpoints involves making memory
2320
   pages write-protected.  We must remember a page's original permissions,
2321
   and we must also know when it is appropriate to restore a page's
2322
   permissions to its original state.
2323
 
2324
   We use a "dictionary" of hardware-watched pages to do this.  Each
2325
   hardware-watched page is recorded in the dictionary.  Each page's
2326
   dictionary entry contains the original permissions and a reference
2327
   count.  Pages are hashed into the dictionary by their start address.
2328
 
2329
   When hardware watchpoint is set on page X for the first time, page X
2330
   is added to the dictionary with a reference count of 1.  If other
2331
   hardware watchpoints are subsequently set on page X, its reference
2332
   count is incremented.  When hardware watchpoints are removed from
2333
   page X, its reference count is decremented.  If a page's reference
2334
   count drops to 0, it's permissions are restored and the page's entry
2335
   is thrown out of the dictionary.
2336
 */
2337
typedef struct memory_page
2338
{
2339
  CORE_ADDR page_start;
2340
  int reference_count;
2341
  int original_permissions;
2342
  struct memory_page *next;
2343
  struct memory_page *previous;
2344
}
2345
memory_page_t;
2346
 
2347
#define MEMORY_PAGE_DICTIONARY_BUCKET_COUNT  128
2348
 
2349
static struct
2350
  {
2351
    LONGEST page_count;
2352
    int page_size;
2353
    int page_protections_allowed;
2354
    /* These are just the heads of chains of actual page descriptors. */
2355
    memory_page_t buckets[MEMORY_PAGE_DICTIONARY_BUCKET_COUNT];
2356
  }
2357
memory_page_dictionary;
2358
 
2359
 
2360
static void
2361
require_memory_page_dictionary (void)
2362
{
2363
  int i;
2364
 
2365
  /* Is the memory page dictionary ready for use?  If so, we're done. */
2366
  if (memory_page_dictionary.page_count >= (LONGEST) 0)
2367
    return;
2368
 
2369
  /* Else, initialize it. */
2370
  memory_page_dictionary.page_count = (LONGEST) 0;
2371
 
2372
  for (i = 0; i < MEMORY_PAGE_DICTIONARY_BUCKET_COUNT; i++)
2373
    {
2374
      memory_page_dictionary.buckets[i].page_start = (CORE_ADDR) 0;
2375
      memory_page_dictionary.buckets[i].reference_count = 0;
2376
      memory_page_dictionary.buckets[i].next = NULL;
2377
      memory_page_dictionary.buckets[i].previous = NULL;
2378
    }
2379
}
2380
 
2381
 
2382
static void
2383
retire_memory_page_dictionary (void)
2384
{
2385
  memory_page_dictionary.page_count = (LONGEST) - 1;
2386
}
2387
 
2388
 
2389
/* Write-protect the memory page that starts at this address.
2390
 
2391
   Returns the original permissions of the page.
2392
 */
2393
static int
2394
write_protect_page (int pid, CORE_ADDR page_start)
2395
{
2396
  int tt_status;
2397
  int original_permissions;
2398
  int new_permissions;
2399
 
2400
  tt_status = call_ttrace (TT_PROC_GET_MPROTECT,
2401
                           pid,
2402
                           (TTRACE_ARG_TYPE) page_start,
2403
                           TT_NIL,
2404
                           (TTRACE_ARG_TYPE) & original_permissions);
2405
  if (errno || (tt_status < 0))
2406
    {
2407
      return 0;                  /* What else can we do? */
2408
    }
2409
 
2410
  /* We'll also write-protect the page now, if that's allowed. */
2411
  if (memory_page_dictionary.page_protections_allowed)
2412
    {
2413
      new_permissions = original_permissions & ~PROT_WRITE;
2414
      tt_status = call_ttrace (TT_PROC_SET_MPROTECT,
2415
                               pid,
2416
                               (TTRACE_ARG_TYPE) page_start,
2417
                         (TTRACE_ARG_TYPE) memory_page_dictionary.page_size,
2418
                               (TTRACE_ARG_TYPE) new_permissions);
2419
      if (errno || (tt_status < 0))
2420
        {
2421
          return 0;              /* What else can we do? */
2422
        }
2423
    }
2424
 
2425
  return original_permissions;
2426
}
2427
 
2428
 
2429
/* Unwrite-protect the memory page that starts at this address, restoring
2430
   (what we must assume are) its original permissions.
2431
 */
2432
static void
2433
unwrite_protect_page (int pid, CORE_ADDR page_start, int original_permissions)
2434
{
2435
  int tt_status;
2436
 
2437
  tt_status = call_ttrace (TT_PROC_SET_MPROTECT,
2438
                           pid,
2439
                           (TTRACE_ARG_TYPE) page_start,
2440
                         (TTRACE_ARG_TYPE) memory_page_dictionary.page_size,
2441
                           (TTRACE_ARG_TYPE) original_permissions);
2442
  if (errno || (tt_status < 0))
2443
    {
2444
      return;                   /* What else can we do? */
2445
    }
2446
}
2447
 
2448
 
2449
/* Memory page-protections are used to implement "hardware" watchpoints
2450
   on HP-UX.
2451
 
2452
   For every memory page that is currently being watched (i.e., that
2453
   presently should be write-protected), write-protect it.
2454
 */
2455
void
2456
hppa_enable_page_protection_events (int pid)
2457
{
2458
  int bucket;
2459
 
2460
  memory_page_dictionary.page_protections_allowed = 1;
2461
 
2462
  for (bucket = 0; bucket < MEMORY_PAGE_DICTIONARY_BUCKET_COUNT; bucket++)
2463
    {
2464
      memory_page_t *page;
2465
 
2466
      page = memory_page_dictionary.buckets[bucket].next;
2467
      while (page != NULL)
2468
        {
2469
          page->original_permissions = write_protect_page (pid, page->page_start);
2470
          page = page->next;
2471
        }
2472
    }
2473
}
2474
 
2475
 
2476
/* Memory page-protections are used to implement "hardware" watchpoints
2477
   on HP-UX.
2478
 
2479
   For every memory page that is currently being watched (i.e., that
2480
   presently is or should be write-protected), un-write-protect it.
2481
 */
2482
void
2483
hppa_disable_page_protection_events (int pid)
2484
{
2485
  int bucket;
2486
 
2487
  for (bucket = 0; bucket < MEMORY_PAGE_DICTIONARY_BUCKET_COUNT; bucket++)
2488
    {
2489
      memory_page_t *page;
2490
 
2491
      page = memory_page_dictionary.buckets[bucket].next;
2492
      while (page != NULL)
2493
        {
2494
          unwrite_protect_page (pid, page->page_start, page->original_permissions);
2495
          page = page->next;
2496
        }
2497
    }
2498
 
2499
  memory_page_dictionary.page_protections_allowed = 0;
2500
}
2501
 
2502
/* Count the number of outstanding events.  At this
2503
 * point, we have selected one thread and its event
2504
 * as the one to be "reported" upwards to core gdb.
2505
 * That thread is already marked as "handled".
2506
 *
2507
 * Note: we could just scan our own thread list.  FIXME!
2508
 */
2509
static int
2510
count_unhandled_events (int real_pid, lwpid_t real_tid)
2511
{
2512
  ttstate_t tstate;
2513
  lwpid_t ttid;
2514
  int events_left;
2515
 
2516
  /* Ok, find out how many threads have real events to report.
2517
   */
2518
  events_left = 0;
2519
  ttid = get_process_first_stopped_thread_id (real_pid, &tstate);
2520
 
2521
#ifdef THREAD_DEBUG
2522
  if (debug_on)
2523
    {
2524
      if (ttid == 0)
2525
        printf ("Process %d has no threads\n", real_pid);
2526
      else
2527
        printf ("Process %d has these threads:\n", real_pid);
2528
    }
2529
#endif
2530
 
2531
  while (ttid > 0)
2532
    {
2533
      if (tstate.tts_event != TTEVT_NONE
2534
          && !was_handled (ttid))
2535
        {
2536
          /* TTEVT_NONE implies we just stopped it ourselves
2537
           * because we're the stop-the-world guys, so it's
2538
           * not an event from our point of view.
2539
           *
2540
           * If "was_handled" is true, this is an event we
2541
           * already handled, so don't count it.
2542
           *
2543
           * Note that we don't count the thread with the
2544
           * currently-reported event, as it's already marked
2545
           * as handled.
2546
           */
2547
          events_left++;
2548
        }
2549
 
2550
#if defined( THREAD_DEBUG ) || defined( WAIT_BUFFER_DEBUG )
2551
      if (debug_on)
2552
        {
2553
          if (ttid == real_tid)
2554
            printf ("*");       /* Thread we're reporting */
2555
          else
2556
            printf (" ");
2557
 
2558
          if (tstate.tts_event != TTEVT_NONE)
2559
            printf ("+");       /* Thread with a real event */
2560
          else
2561
            printf (" ");
2562
 
2563
          if (was_handled (ttid))
2564
            printf ("h");       /* Thread has been handled */
2565
          else
2566
            printf (" ");
2567
 
2568
          printf (" %d, with event %s", ttid,
2569
                  get_printable_name_of_ttrace_event (tstate.tts_event));
2570
 
2571
          if (tstate.tts_event == TTEVT_SIGNAL
2572
              && 5 == tstate.tts_u.tts_signal.tts_signo)
2573
            {
2574
              CORE_ADDR pc_val;
2575
 
2576
              pc_val = get_raw_pc (ttid);
2577
 
2578
              if (pc_val > 0)
2579
                printf (" breakpoint at 0x%x\n", pc_val);
2580
              else
2581
                printf (" bpt, can't fetch pc.\n");
2582
            }
2583
          else
2584
            printf ("\n");
2585
        }
2586
#endif
2587
 
2588
      ttid = get_process_next_stopped_thread_id (real_pid, &tstate);
2589
    }
2590
 
2591
#if defined( THREAD_DEBUG ) || defined( WAIT_BUFFER_DEBUG )
2592
  if (debug_on)
2593
    if (events_left > 0)
2594
      printf ("There are thus %d pending events\n", events_left);
2595
#endif
2596
 
2597
  return events_left;
2598
}
2599
 
2600
/* This function is provided as a sop to clients that are calling
2601
 * ptrace_wait to wait for a process to stop.  (see the
2602
 * implementation of child_wait.)  Return value is the pid for
2603
 * the event that ended the wait.
2604
 *
2605
 * Note: used by core gdb and so uses the pseudo-pid (really tid).
2606
 */
2607
int
2608
ptrace_wait (ptid_t ptid, int *status)
2609
{
2610
  ttstate_t tsp;
2611
  int ttwait_return;
2612
  int real_pid;
2613
  ttstate_t state;
2614
  lwpid_t real_tid;
2615
  int return_pid;
2616
 
2617
  /* The ptrace implementation of this also ignores pid.
2618
   */
2619
  *status = 0;
2620
 
2621
  ttwait_return = call_ttrace_wait (0, TTRACE_WAITOK, &tsp, sizeof (tsp));
2622
  if (ttwait_return < 0)
2623
    {
2624
      /* ??rehrauer: It appears that if our inferior exits and we
2625
         haven't asked for exit events, that we're not getting any
2626
         indication save a negative return from ttrace_wait and an
2627
         errno set to ESRCH?
2628
       */
2629
      if (errno == ESRCH)
2630
        {
2631
          *status = 0;           /* WIFEXITED */
2632
          return PIDGET (inferior_ptid);
2633
        }
2634
 
2635
      warning ("Call of ttrace_wait returned with errno %d.",
2636
               errno);
2637
      *status = ttwait_return;
2638
      return PIDGET (inferior_ptid);
2639
    }
2640
 
2641
  real_pid = tsp.tts_pid;
2642
  real_tid = tsp.tts_lwpid;
2643
 
2644
  /* One complication is that the "tts_event" structure has
2645
   * a set of flags, and more than one can be set.  So we
2646
   * either have to force an order (as we do here), or handle
2647
   * more than one flag at a time.
2648
   */
2649
  if (tsp.tts_event & TTEVT_LWP_CREATE)
2650
    {
2651
 
2652
      /* Unlike what you might expect, this event is reported in
2653
       * the _creating_ thread, and the _created_ thread (whose tid
2654
       * we have) is still running.  So we have to stop it.  This
2655
       * has already been done in "call_ttrace_wait", but should we
2656
       * ever abandon the "stop-the-world" model, here's the command
2657
       * to use:
2658
       *
2659
       *    call_ttrace( TT_LWP_STOP, real_tid, TT_NIL, TT_NIL, TT_NIL );
2660
       *
2661
       * Note that this would depend on being called _after_ "add_tthread"
2662
       * below for the tid-to-pid translation to be done in "call_ttrace".
2663
       */
2664
 
2665
#ifdef THREAD_DEBUG
2666
      if (debug_on)
2667
        printf ("New thread: pid %d, tid %d, creator tid %d\n",
2668
                real_pid, tsp.tts_u.tts_thread.tts_target_lwpid,
2669
                real_tid);
2670
#endif
2671
 
2672
      /* Now we have to return the tid of the created thread, not
2673
       * the creating thread, or "wait_for_inferior" won't know we
2674
       * have a new "process" (thread).  Plus we should record it
2675
       * right, too.
2676
       */
2677
      real_tid = tsp.tts_u.tts_thread.tts_target_lwpid;
2678
 
2679
      add_tthread (real_pid, real_tid);
2680
    }
2681
 
2682
  else if ((tsp.tts_event & TTEVT_LWP_TERMINATE)
2683
           || (tsp.tts_event & TTEVT_LWP_EXIT))
2684
    {
2685
 
2686
#ifdef THREAD_DEBUG
2687
      if (debug_on)
2688
        printf ("Thread dies: %d\n", real_tid);
2689
#endif
2690
 
2691
      del_tthread (real_tid);
2692
    }
2693
 
2694
  else if (tsp.tts_event & TTEVT_EXEC)
2695
    {
2696
 
2697
#ifdef THREAD_DEBUG
2698
      if (debug_on)
2699
        printf ("Pid %d has zero'th thread %d; inferior pid is %d\n",
2700
                real_pid, real_tid, PIDGET (inferior_ptid));
2701
#endif
2702
 
2703
      add_tthread (real_pid, real_tid);
2704
    }
2705
 
2706
#ifdef THREAD_DEBUG
2707
  else if (debug_on)
2708
    {
2709
      printf ("Process-level event %s, using tid %d\n",
2710
              get_printable_name_of_ttrace_event (tsp.tts_event),
2711
              real_tid);
2712
 
2713
      /* OK to do this, as "add_tthread" won't add
2714
       * duplicate entries.  Also OK not to do it,
2715
       * as this event isn't one which can change the
2716
       * thread state.
2717
       */
2718
      add_tthread (real_pid, real_tid);
2719
    }
2720
#endif
2721
 
2722
 
2723
  /* How many events are left to report later?
2724
   * In a non-stop-the-world model, this isn't needed.
2725
   *
2726
   * Note that it's not always safe to query the thread state of a process,
2727
   * which is what count_unhandled_events does.  (If unsafe, we're left with
2728
   * no other resort than to assume that no more events remain...)
2729
   */
2730
  if (can_touch_threads_of_process (real_pid, tsp.tts_event))
2731
    more_events_left = count_unhandled_events (real_pid, real_tid);
2732
 
2733
  else
2734
    {
2735
      if (more_events_left > 0)
2736
        warning ("Vfork or fork causing loss of %d buffered events.",
2737
                 more_events_left);
2738
 
2739
      more_events_left = 0;
2740
    }
2741
 
2742
  /* Attempt to translate the ttrace_wait-returned status into the
2743
     ptrace equivalent.
2744
 
2745
     ??rehrauer: This is somewhat fragile.  We really ought to rewrite
2746
     clients that expect to pick apart a ptrace wait status, to use
2747
     something a little more abstract.
2748
   */
2749
  if ((tsp.tts_event & TTEVT_EXEC)
2750
      || (tsp.tts_event & TTEVT_FORK)
2751
      || (tsp.tts_event & TTEVT_VFORK))
2752
    {
2753
      /* Forks come in pairs (parent and child), so core gdb
2754
       * will do two waits.  Be ready to notice this.
2755
       */
2756
      if (tsp.tts_event & TTEVT_FORK)
2757
        {
2758
          process_state = FORKING;
2759
 
2760
#ifdef WAIT_BUFFER_DEBUG
2761
          if (debug_on)
2762
            printf ("Process set to FORKING\n");
2763
#endif
2764
        }
2765
      else if (tsp.tts_event & TTEVT_VFORK)
2766
        {
2767
          process_state = VFORKING;
2768
 
2769
#ifdef WAIT_BUFFER_DEBUG
2770
          if (debug_on)
2771
            printf ("Process set to VFORKING\n");
2772
#endif
2773
        }
2774
 
2775
      /* Make an exec or fork look like a breakpoint.  Definitely a hack,
2776
         but I don't think non HP-UX-specific clients really carefully
2777
         inspect the first events they get after inferior startup, so
2778
         it probably almost doesn't matter what we claim this is.
2779
       */
2780
 
2781
#ifdef THREAD_DEBUG
2782
      if (debug_on)
2783
        printf ("..a process 'event'\n");
2784
#endif
2785
 
2786
      /* Also make fork and exec events look like bpts, so they can be caught.
2787
       */
2788
      *status = 0177 | (_SIGTRAP << 8);
2789
    }
2790
 
2791
  /* Special-cases: We ask for syscall entry and exit events to implement
2792
     "fast" (aka "hardware") watchpoints.
2793
 
2794
     When we get a syscall entry, we want to disable page-protections,
2795
     and resume the inferior; this isn't an event we wish for
2796
     wait_for_inferior to see.  Note that we must resume ONLY the
2797
     thread that reported the syscall entry; we don't want to allow
2798
     other threads to run with the page protections off, as they might
2799
     then be able to write to watch memory without it being caught.
2800
 
2801
     When we get a syscall exit, we want to reenable page-protections,
2802
     but we don't want to resume the inferior; this is an event we wish
2803
     wait_for_inferior to see.  Make it look like the signal we normally
2804
     get for a single-step completion.  This should cause wait_for_inferior
2805
     to evaluate whether any watchpoint triggered.
2806
 
2807
     Or rather, that's what we'd LIKE to do for syscall exit; we can't,
2808
     due to some HP-UX "features".  Some syscalls have problems with
2809
     write-protections on some pages, and some syscalls seem to have
2810
     pending writes to those pages at the time we're getting the return
2811
     event.  So, we'll single-step the inferior to get out of the syscall,
2812
     and then reenable protections.
2813
 
2814
     Note that we're intentionally allowing the syscall exit case to
2815
     fall through into the succeeding cases, as sometimes we single-
2816
     step out of one syscall only to immediately enter another...
2817
   */
2818
  else if ((tsp.tts_event & TTEVT_SYSCALL_ENTRY)
2819
           || (tsp.tts_event & TTEVT_SYSCALL_RETURN))
2820
    {
2821
      /* Make a syscall event look like a breakpoint.  Same comments
2822
         as for exec & fork events.
2823
       */
2824
#ifdef THREAD_DEBUG
2825
      if (debug_on)
2826
        printf ("..a syscall 'event'\n");
2827
#endif
2828
 
2829
      /* Also make syscall events look like bpts, so they can be caught.
2830
       */
2831
      *status = 0177 | (_SIGTRAP << 8);
2832
    }
2833
 
2834
  else if ((tsp.tts_event & TTEVT_LWP_CREATE)
2835
           || (tsp.tts_event & TTEVT_LWP_TERMINATE)
2836
           || (tsp.tts_event & TTEVT_LWP_EXIT))
2837
    {
2838
      /* Make a thread event look like a breakpoint.  Same comments
2839
       * as for exec & fork events.
2840
       */
2841
#ifdef THREAD_DEBUG
2842
      if (debug_on)
2843
        printf ("..a thread 'event'\n");
2844
#endif
2845
 
2846
      /* Also make thread events look like bpts, so they can be caught.
2847
       */
2848
      *status = 0177 | (_SIGTRAP << 8);
2849
    }
2850
 
2851
  else if ((tsp.tts_event & TTEVT_EXIT))
2852
    {                           /* WIFEXITED */
2853
 
2854
#ifdef THREAD_DEBUG
2855
      if (debug_on)
2856
        printf ("..an exit\n");
2857
#endif
2858
 
2859
      /* Prevent rest of gdb from thinking this is
2860
       * a new thread if for some reason it's never
2861
       * seen the main thread before.
2862
       */
2863
      inferior_ptid = pid_to_ptid (map_to_gdb_tid (real_tid));  /* HACK, FIX */
2864
 
2865
      *status = 0 | (tsp.tts_u.tts_exit.tts_exitcode);
2866
    }
2867
 
2868
  else if (tsp.tts_event & TTEVT_SIGNAL)
2869
    {                           /* WIFSTOPPED */
2870
#ifdef THREAD_DEBUG
2871
      if (debug_on)
2872
        printf ("..a signal, %d\n", tsp.tts_u.tts_signal.tts_signo);
2873
#endif
2874
 
2875
      *status = 0177 | (tsp.tts_u.tts_signal.tts_signo << 8);
2876
    }
2877
 
2878
  else
2879
    {                           /* !WIFSTOPPED */
2880
 
2881
      /* This means the process or thread terminated.  But we should've
2882
         caught an explicit exit/termination above.  So warn (this is
2883
         really an internal error) and claim the process or thread
2884
         terminated with a SIGTRAP.
2885
       */
2886
 
2887
      warning ("process_wait: unknown process state");
2888
 
2889
#ifdef THREAD_DEBUG
2890
      if (debug_on)
2891
        printf ("Process-level event %s, using tid %d\n",
2892
                get_printable_name_of_ttrace_event (tsp.tts_event),
2893
                real_tid);
2894
#endif
2895
 
2896
      *status = _SIGTRAP;
2897
    }
2898
 
2899
  target_post_wait (pid_to_ptid (tsp.tts_pid), *status);
2900
 
2901
 
2902
#ifdef THREAD_DEBUG
2903
  if (debug_on)
2904
    printf ("Done waiting, pid is %d, tid %d\n", real_pid, real_tid);
2905
#endif
2906
 
2907
  /* All code external to this module uses the tid, but calls
2908
   * it "pid".  There's some tweaking so that the outside sees
2909
   * the first thread as having the same number as the starting
2910
   * pid.
2911
   */
2912
  return_pid = map_to_gdb_tid (real_tid);
2913
 
2914
  /* Remember this for later use in "hppa_prepare_to_proceed".
2915
   */
2916
  old_gdb_pid = PIDGET (inferior_ptid);
2917
  reported_pid = return_pid;
2918
  reported_bpt = ((tsp.tts_event & TTEVT_SIGNAL) && (5 == tsp.tts_u.tts_signal.tts_signo));
2919
 
2920
  if (real_tid == 0 || return_pid == 0)
2921
    {
2922
      warning ("Internal error: process-wait failed.");
2923
    }
2924
 
2925
  return return_pid;
2926
}
2927
 
2928
 
2929
/* This function causes the caller's process to be traced by its
2930
   parent.  This is intended to be called after GDB forks itself,
2931
   and before the child execs the target.  Despite the name, it
2932
   is called by the child.
2933
 
2934
   Note that HP-UX ttrace is rather funky in how this is done.
2935
   If the parent wants to get the initial exec event of a child,
2936
   it must set the ttrace event mask of the child to include execs.
2937
   (The child cannot do this itself.)  This must be done after the
2938
   child is forked, but before it execs.
2939
 
2940
   To coordinate the parent and child, we implement a semaphore using
2941
   pipes.  After SETTRC'ing itself, the child tells the parent that
2942
   it is now traceable by the parent, and waits for the parent's
2943
   acknowledgement.  The parent can then set the child's event mask,
2944
   and notify the child that it can now exec.
2945
 
2946
   (The acknowledgement by parent happens as a result of a call to
2947
   child_acknowledge_created_inferior.)
2948
 */
2949
int
2950
parent_attach_all (void)
2951
{
2952
  int tt_status;
2953
 
2954
  /* We need a memory home for a constant, to pass it to ttrace.
2955
     The value of the constant is arbitrary, so long as both
2956
     parent and child use the same value.  Might as well use the
2957
     "magic" constant provided by ttrace...
2958
   */
2959
  uint64_t tc_magic_child = TT_VERSION;
2960
  uint64_t tc_magic_parent = 0;
2961
 
2962
  tt_status = call_real_ttrace (
2963
                                 TT_PROC_SETTRC,
2964
                                 (int) TT_NIL,
2965
                                 (lwpid_t) TT_NIL,
2966
                                 TT_NIL,
2967
                                 (TTRACE_ARG_TYPE) TT_VERSION,
2968
                                 TT_NIL);
2969
 
2970
  if (tt_status < 0)
2971
    return tt_status;
2972
 
2973
  /* Notify the parent that we're potentially ready to exec(). */
2974
  write (startup_semaphore.child_channel[SEM_TALK],
2975
         &tc_magic_child,
2976
         sizeof (tc_magic_child));
2977
 
2978
  /* Wait for acknowledgement from the parent. */
2979
  read (startup_semaphore.parent_channel[SEM_LISTEN],
2980
        &tc_magic_parent,
2981
        sizeof (tc_magic_parent));
2982
 
2983
  if (tc_magic_child != tc_magic_parent)
2984
    warning ("mismatched semaphore magic");
2985
 
2986
  /* Discard our copy of the semaphore. */
2987
  (void) close (startup_semaphore.parent_channel[SEM_LISTEN]);
2988
  (void) close (startup_semaphore.parent_channel[SEM_TALK]);
2989
  (void) close (startup_semaphore.child_channel[SEM_LISTEN]);
2990
  (void) close (startup_semaphore.child_channel[SEM_TALK]);
2991
 
2992
  return tt_status;
2993
}
2994
 
2995
/* Despite being file-local, this routine is dealing with
2996
 * actual process IDs, not thread ids.  That's because it's
2997
 * called before the first "wait" call, and there's no map
2998
 * yet from tids to pids.
2999
 *
3000
 * When it is called, a forked child is running, but waiting on
3001
 * the semaphore.  If you stop the child and re-start it,
3002
 * things get confused, so don't do that!  An attached child is
3003
 * stopped.
3004
 *
3005
 * Since this is called after either attach or run, we
3006
 * have to be the common part of both.
3007
 */
3008
static void
3009
require_notification_of_events (int real_pid)
3010
{
3011
  int tt_status;
3012
  ttevent_t notifiable_events;
3013
 
3014
  lwpid_t tid;
3015
  ttstate_t thread_state;
3016
 
3017
#ifdef THREAD_DEBUG
3018
  if (debug_on)
3019
    printf ("Require notif, pid is %d\n", real_pid);
3020
#endif
3021
 
3022
  /* Temporary HACK: tell inftarg.c/child_wait to not
3023
   * loop until pids are the same.
3024
   */
3025
  not_same_real_pid = 0;
3026
 
3027
  sigemptyset (&notifiable_events.tte_signals);
3028
  notifiable_events.tte_opts = TTEO_NONE;
3029
 
3030
  /* This ensures that forked children inherit their parent's
3031
   * event mask, which we're setting here.
3032
   *
3033
   * NOTE: if you debug gdb with itself, then the ultimate
3034
   *       debuggee gets flags set by the outermost gdb, as
3035
   *       a child of a child will still inherit.
3036
   */
3037
  notifiable_events.tte_opts |= TTEO_PROC_INHERIT;
3038
 
3039
  notifiable_events.tte_events = TTEVT_DEFAULT;
3040
  notifiable_events.tte_events |= TTEVT_SIGNAL;
3041
  notifiable_events.tte_events |= TTEVT_EXEC;
3042
  notifiable_events.tte_events |= TTEVT_EXIT;
3043
  notifiable_events.tte_events |= TTEVT_FORK;
3044
  notifiable_events.tte_events |= TTEVT_VFORK;
3045
  notifiable_events.tte_events |= TTEVT_LWP_CREATE;
3046
  notifiable_events.tte_events |= TTEVT_LWP_EXIT;
3047
  notifiable_events.tte_events |= TTEVT_LWP_TERMINATE;
3048
 
3049
  tt_status = call_real_ttrace (
3050
                                 TT_PROC_SET_EVENT_MASK,
3051
                                 real_pid,
3052
                                 (lwpid_t) TT_NIL,
3053
                                 (TTRACE_ARG_TYPE) & notifiable_events,
3054
                               (TTRACE_ARG_TYPE) sizeof (notifiable_events),
3055
                                 TT_NIL);
3056
}
3057
 
3058
static void
3059
require_notification_of_exec_events (int real_pid)
3060
{
3061
  int tt_status;
3062
  ttevent_t notifiable_events;
3063
 
3064
  lwpid_t tid;
3065
  ttstate_t thread_state;
3066
 
3067
#ifdef THREAD_DEBUG
3068
  if (debug_on)
3069
    printf ("Require notif, pid is %d\n", real_pid);
3070
#endif
3071
 
3072
  /* Temporary HACK: tell inftarg.c/child_wait to not
3073
   * loop until pids are the same.
3074
   */
3075
  not_same_real_pid = 0;
3076
 
3077
  sigemptyset (&notifiable_events.tte_signals);
3078
  notifiable_events.tte_opts = TTEO_NOSTRCCHLD;
3079
 
3080
  /* This ensures that forked children don't inherit their parent's
3081
   * event mask, which we're setting here.
3082
   */
3083
  notifiable_events.tte_opts &= ~TTEO_PROC_INHERIT;
3084
 
3085
  notifiable_events.tte_events = TTEVT_DEFAULT;
3086
  notifiable_events.tte_events |= TTEVT_EXEC;
3087
  notifiable_events.tte_events |= TTEVT_EXIT;
3088
 
3089
  tt_status = call_real_ttrace (
3090
                                 TT_PROC_SET_EVENT_MASK,
3091
                                 real_pid,
3092
                                 (lwpid_t) TT_NIL,
3093
                                 (TTRACE_ARG_TYPE) & notifiable_events,
3094
                               (TTRACE_ARG_TYPE) sizeof (notifiable_events),
3095
                                 TT_NIL);
3096
}
3097
 
3098
 
3099
/* This function is called by the parent process, with pid being the
3100
 * ID of the child process, after the debugger has forked.
3101
 */
3102
void
3103
child_acknowledge_created_inferior (int pid)
3104
{
3105
  /* We need a memory home for a constant, to pass it to ttrace.
3106
     The value of the constant is arbitrary, so long as both
3107
     parent and child use the same value.  Might as well use the
3108
     "magic" constant provided by ttrace...
3109
   */
3110
  uint64_t tc_magic_parent = TT_VERSION;
3111
  uint64_t tc_magic_child = 0;
3112
 
3113
  /* Wait for the child to tell us that it has forked. */
3114
  read (startup_semaphore.child_channel[SEM_LISTEN],
3115
        &tc_magic_child,
3116
        sizeof (tc_magic_child));
3117
 
3118
  /* Clear thread info now.  We'd like to do this in
3119
   * "require...", but that messes up attach.
3120
   */
3121
  clear_thread_info ();
3122
 
3123
  /* Tell the "rest of gdb" that the initial thread exists.
3124
   * This isn't really a hack.  Other thread-based versions
3125
   * of gdb (e.g. gnu-nat.c) seem to do the same thing.
3126
   *
3127
   * Q: Why don't we also add this thread to the local
3128
   *    list via "add_tthread"?
3129
   *
3130
   * A: Because we don't know the tid, and can't stop the
3131
   *    the process safely to ask what it is.  Anyway, we'll
3132
   *    add it when it gets the EXEC event.
3133
   */
3134
  add_thread (pid_to_ptid (pid));               /* in thread.c */
3135
 
3136
  /* We can now set the child's ttrace event mask.
3137
   */
3138
  require_notification_of_exec_events (pid);
3139
 
3140
  /* Tell ourselves that the process is running.
3141
   */
3142
  process_state = RUNNING;
3143
 
3144
  /* Notify the child that it can exec. */
3145
  write (startup_semaphore.parent_channel[SEM_TALK],
3146
         &tc_magic_parent,
3147
         sizeof (tc_magic_parent));
3148
 
3149
  /* Discard our copy of the semaphore. */
3150
  (void) close (startup_semaphore.parent_channel[SEM_LISTEN]);
3151
  (void) close (startup_semaphore.parent_channel[SEM_TALK]);
3152
  (void) close (startup_semaphore.child_channel[SEM_LISTEN]);
3153
  (void) close (startup_semaphore.child_channel[SEM_TALK]);
3154
}
3155
 
3156
 
3157
/*
3158
 * arrange for notification of all events by
3159
 * calling require_notification_of_events.
3160
 */
3161
void
3162
child_post_startup_inferior (ptid_t ptid)
3163
{
3164
  require_notification_of_events (PIDGET (ptid));
3165
}
3166
 
3167
/* From here on, we should expect tids rather than pids.
3168
 */
3169
static void
3170
hppa_enable_catch_fork (int tid)
3171
{
3172
  int tt_status;
3173
  ttevent_t ttrace_events;
3174
 
3175
  /* Get the set of events that are currently enabled.
3176
   */
3177
  tt_status = call_ttrace (TT_PROC_GET_EVENT_MASK,
3178
                           tid,
3179
                           (TTRACE_ARG_TYPE) & ttrace_events,
3180
                           (TTRACE_ARG_TYPE) sizeof (ttrace_events),
3181
                           TT_NIL);
3182
  if (errno)
3183
    perror_with_name ("ttrace");
3184
 
3185
  /* Add forks to that set. */
3186
  ttrace_events.tte_events |= TTEVT_FORK;
3187
 
3188
#ifdef THREAD_DEBUG
3189
  if (debug_on)
3190
    printf ("enable fork, tid is %d\n", tid);
3191
#endif
3192
 
3193
  tt_status = call_ttrace (TT_PROC_SET_EVENT_MASK,
3194
                           tid,
3195
                           (TTRACE_ARG_TYPE) & ttrace_events,
3196
                           (TTRACE_ARG_TYPE) sizeof (ttrace_events),
3197
                           TT_NIL);
3198
  if (errno)
3199
    perror_with_name ("ttrace");
3200
}
3201
 
3202
 
3203
static void
3204
hppa_disable_catch_fork (int tid)
3205
{
3206
  int tt_status;
3207
  ttevent_t ttrace_events;
3208
 
3209
  /* Get the set of events that are currently enabled.
3210
   */
3211
  tt_status = call_ttrace (TT_PROC_GET_EVENT_MASK,
3212
                           tid,
3213
                           (TTRACE_ARG_TYPE) & ttrace_events,
3214
                           (TTRACE_ARG_TYPE) sizeof (ttrace_events),
3215
                           TT_NIL);
3216
 
3217
  if (errno)
3218
    perror_with_name ("ttrace");
3219
 
3220
  /* Remove forks from that set. */
3221
  ttrace_events.tte_events &= ~TTEVT_FORK;
3222
 
3223
#ifdef THREAD_DEBUG
3224
  if (debug_on)
3225
    printf ("disable fork, tid is %d\n", tid);
3226
#endif
3227
 
3228
  tt_status = call_ttrace (TT_PROC_SET_EVENT_MASK,
3229
                           tid,
3230
                           (TTRACE_ARG_TYPE) & ttrace_events,
3231
                           (TTRACE_ARG_TYPE) sizeof (ttrace_events),
3232
                           TT_NIL);
3233
 
3234
  if (errno)
3235
    perror_with_name ("ttrace");
3236
}
3237
 
3238
 
3239
#if defined(CHILD_INSERT_FORK_CATCHPOINT)
3240
int
3241
child_insert_fork_catchpoint (int tid)
3242
{
3243
  /* Enable reporting of fork events from the kernel. */
3244
  /* ??rehrauer: For the moment, we're always enabling these events,
3245
     and just ignoring them if there's no catchpoint to catch them.
3246
   */
3247
  return 0;
3248
}
3249
#endif
3250
 
3251
 
3252
#if defined(CHILD_REMOVE_FORK_CATCHPOINT)
3253
int
3254
child_remove_fork_catchpoint (int tid)
3255
{
3256
  /* Disable reporting of fork events from the kernel. */
3257
  /* ??rehrauer: For the moment, we're always enabling these events,
3258
     and just ignoring them if there's no catchpoint to catch them.
3259
   */
3260
  return 0;
3261
}
3262
#endif
3263
 
3264
 
3265
static void
3266
hppa_enable_catch_vfork (int tid)
3267
{
3268
  int tt_status;
3269
  ttevent_t ttrace_events;
3270
 
3271
  /* Get the set of events that are currently enabled.
3272
   */
3273
  tt_status = call_ttrace (TT_PROC_GET_EVENT_MASK,
3274
                           tid,
3275
                           (TTRACE_ARG_TYPE) & ttrace_events,
3276
                           (TTRACE_ARG_TYPE) sizeof (ttrace_events),
3277
                           TT_NIL);
3278
 
3279
  if (errno)
3280
    perror_with_name ("ttrace");
3281
 
3282
  /* Add vforks to that set. */
3283
  ttrace_events.tte_events |= TTEVT_VFORK;
3284
 
3285
#ifdef THREAD_DEBUG
3286
  if (debug_on)
3287
    printf ("enable vfork, tid is %d\n", tid);
3288
#endif
3289
 
3290
  tt_status = call_ttrace (TT_PROC_SET_EVENT_MASK,
3291
                           tid,
3292
                           (TTRACE_ARG_TYPE) & ttrace_events,
3293
                           (TTRACE_ARG_TYPE) sizeof (ttrace_events),
3294
                           TT_NIL);
3295
 
3296
  if (errno)
3297
    perror_with_name ("ttrace");
3298
}
3299
 
3300
 
3301
static void
3302
hppa_disable_catch_vfork (int tid)
3303
{
3304
  int tt_status;
3305
  ttevent_t ttrace_events;
3306
 
3307
  /* Get the set of events that are currently enabled. */
3308
  tt_status = call_ttrace (TT_PROC_GET_EVENT_MASK,
3309
                           tid,
3310
                           (TTRACE_ARG_TYPE) & ttrace_events,
3311
                           (TTRACE_ARG_TYPE) sizeof (ttrace_events),
3312
                           TT_NIL);
3313
 
3314
  if (errno)
3315
    perror_with_name ("ttrace");
3316
 
3317
  /* Remove vforks from that set. */
3318
  ttrace_events.tte_events &= ~TTEVT_VFORK;
3319
 
3320
#ifdef THREAD_DEBUG
3321
  if (debug_on)
3322
    printf ("disable vfork, tid is %d\n", tid);
3323
#endif
3324
  tt_status = call_ttrace (TT_PROC_SET_EVENT_MASK,
3325
                           tid,
3326
                           (TTRACE_ARG_TYPE) & ttrace_events,
3327
                           (TTRACE_ARG_TYPE) sizeof (ttrace_events),
3328
                           TT_NIL);
3329
 
3330
  if (errno)
3331
    perror_with_name ("ttrace");
3332
}
3333
 
3334
 
3335
#if defined(CHILD_INSERT_VFORK_CATCHPOINT)
3336
int
3337
child_insert_vfork_catchpoint (int tid)
3338
{
3339
  /* Enable reporting of vfork events from the kernel. */
3340
  /* ??rehrauer: For the moment, we're always enabling these events,
3341
     and just ignoring them if there's no catchpoint to catch them.
3342
   */
3343
  return 0;
3344
}
3345
#endif
3346
 
3347
 
3348
#if defined(CHILD_REMOVE_VFORK_CATCHPOINT)
3349
int
3350
child_remove_vfork_catchpoint (int tid)
3351
{
3352
  /* Disable reporting of vfork events from the kernel. */
3353
  /* ??rehrauer: For the moment, we're always enabling these events,
3354
     and just ignoring them if there's no catchpoint to catch them.
3355
   */
3356
  return 0;
3357
}
3358
#endif
3359
 
3360
#if defined(CHILD_HAS_FORKED)
3361
 
3362
/* Q: Do we need to map the returned process ID to a thread ID?
3363
 
3364
 * A: I don't think so--here we want a _real_ pid.  Any later
3365
 *    operations will call "require_notification_of_events" and
3366
 *    start the mapping.
3367
 */
3368
int
3369
child_has_forked (int tid, int *childpid)
3370
{
3371
  int tt_status;
3372
  ttstate_t ttrace_state;
3373
  thread_info *tinfo;
3374
 
3375
  /* Do we have cached thread state that we can consult?  If so, use it. */
3376
  tinfo = find_thread_info (map_from_gdb_tid (tid));
3377
  if (tinfo != NULL)
3378
    {
3379
      copy_ttstate_t (&ttrace_state, &tinfo->last_stop_state);
3380
    }
3381
 
3382
  /* Nope, must read the thread's current state */
3383
  else
3384
    {
3385
      tt_status = call_ttrace (TT_LWP_GET_STATE,
3386
                               tid,
3387
                               (TTRACE_ARG_TYPE) & ttrace_state,
3388
                               (TTRACE_ARG_TYPE) sizeof (ttrace_state),
3389
                               TT_NIL);
3390
 
3391
      if (errno)
3392
        perror_with_name ("ttrace");
3393
 
3394
      if (tt_status < 0)
3395
        return 0;
3396
    }
3397
 
3398
  if (ttrace_state.tts_event & TTEVT_FORK)
3399
    {
3400
      *childpid = ttrace_state.tts_u.tts_fork.tts_fpid;
3401
      return 1;
3402
    }
3403
 
3404
  return 0;
3405
}
3406
#endif
3407
 
3408
 
3409
#if defined(CHILD_HAS_VFORKED)
3410
 
3411
/* See child_has_forked for pid discussion.
3412
 */
3413
int
3414
child_has_vforked (int tid, int *childpid)
3415
{
3416
  int tt_status;
3417
  ttstate_t ttrace_state;
3418
  thread_info *tinfo;
3419
 
3420
  /* Do we have cached thread state that we can consult?  If so, use it. */
3421
  tinfo = find_thread_info (map_from_gdb_tid (tid));
3422
  if (tinfo != NULL)
3423
    copy_ttstate_t (&ttrace_state, &tinfo->last_stop_state);
3424
 
3425
  /* Nope, must read the thread's current state */
3426
  else
3427
    {
3428
      tt_status = call_ttrace (TT_LWP_GET_STATE,
3429
                               tid,
3430
                               (TTRACE_ARG_TYPE) & ttrace_state,
3431
                               (TTRACE_ARG_TYPE) sizeof (ttrace_state),
3432
                               TT_NIL);
3433
 
3434
      if (errno)
3435
        perror_with_name ("ttrace");
3436
 
3437
      if (tt_status < 0)
3438
        return 0;
3439
    }
3440
 
3441
  if (ttrace_state.tts_event & TTEVT_VFORK)
3442
    {
3443
      *childpid = ttrace_state.tts_u.tts_fork.tts_fpid;
3444
      return 1;
3445
    }
3446
 
3447
  return 0;
3448
}
3449
#endif
3450
 
3451
 
3452
#if defined(CHILD_CAN_FOLLOW_VFORK_PRIOR_TO_EXEC)
3453
int
3454
child_can_follow_vfork_prior_to_exec (void)
3455
{
3456
  /* ttrace does allow this.
3457
 
3458
     ??rehrauer: However, I had major-league problems trying to
3459
     convince wait_for_inferior to handle that case.  Perhaps when
3460
     it is rewritten to grok multiple processes in an explicit way...
3461
   */
3462
  return 0;
3463
}
3464
#endif
3465
 
3466
 
3467
#if defined(CHILD_INSERT_EXEC_CATCHPOINT)
3468
int
3469
child_insert_exec_catchpoint (int tid)
3470
{
3471
  /* Enable reporting of exec events from the kernel. */
3472
  /* ??rehrauer: For the moment, we're always enabling these events,
3473
     and just ignoring them if there's no catchpoint to catch them.
3474
   */
3475
  return 0;
3476
}
3477
#endif
3478
 
3479
 
3480
#if defined(CHILD_REMOVE_EXEC_CATCHPOINT)
3481
int
3482
child_remove_exec_catchpoint (int tid)
3483
{
3484
  /* Disable reporting of execevents from the kernel. */
3485
  /* ??rehrauer: For the moment, we're always enabling these events,
3486
     and just ignoring them if there's no catchpoint to catch them.
3487
   */
3488
  return 0;
3489
}
3490
#endif
3491
 
3492
 
3493
#if defined(CHILD_HAS_EXECD)
3494
int
3495
child_has_execd (int tid, char **execd_pathname)
3496
{
3497
  int tt_status;
3498
  ttstate_t ttrace_state;
3499
  thread_info *tinfo;
3500
 
3501
  /* Do we have cached thread state that we can consult?  If so, use it. */
3502
  tinfo = find_thread_info (map_from_gdb_tid (tid));
3503
  if (tinfo != NULL)
3504
    copy_ttstate_t (&ttrace_state, &tinfo->last_stop_state);
3505
 
3506
  /* Nope, must read the thread's current state */
3507
  else
3508
    {
3509
      tt_status = call_ttrace (TT_LWP_GET_STATE,
3510
                               tid,
3511
                               (TTRACE_ARG_TYPE) & ttrace_state,
3512
                               (TTRACE_ARG_TYPE) sizeof (ttrace_state),
3513
                               TT_NIL);
3514
 
3515
      if (errno)
3516
        perror_with_name ("ttrace");
3517
 
3518
      if (tt_status < 0)
3519
        return 0;
3520
    }
3521
 
3522
  if (ttrace_state.tts_event & TTEVT_EXEC)
3523
    {
3524
      /* See child_pid_to_exec_file in this file: this is a macro.
3525
       */
3526
      char *exec_file = target_pid_to_exec_file (tid);
3527
 
3528
      *execd_pathname = savestring (exec_file, strlen (exec_file));
3529
      return 1;
3530
    }
3531
 
3532
  return 0;
3533
}
3534
#endif
3535
 
3536
 
3537
#if defined(CHILD_HAS_SYSCALL_EVENT)
3538
int
3539
child_has_syscall_event (int pid, enum target_waitkind *kind, int *syscall_id)
3540
{
3541
  int tt_status;
3542
  ttstate_t ttrace_state;
3543
  thread_info *tinfo;
3544
 
3545
  /* Do we have cached thread state that we can consult?  If so, use it. */
3546
  tinfo = find_thread_info (map_from_gdb_tid (pid));
3547
  if (tinfo != NULL)
3548
    copy_ttstate_t (&ttrace_state, &tinfo->last_stop_state);
3549
 
3550
  /* Nope, must read the thread's current state */
3551
  else
3552
    {
3553
      tt_status = call_ttrace (TT_LWP_GET_STATE,
3554
                               pid,
3555
                               (TTRACE_ARG_TYPE) & ttrace_state,
3556
                               (TTRACE_ARG_TYPE) sizeof (ttrace_state),
3557
                               TT_NIL);
3558
 
3559
      if (errno)
3560
        perror_with_name ("ttrace");
3561
 
3562
      if (tt_status < 0)
3563
        return 0;
3564
    }
3565
 
3566
  *kind = TARGET_WAITKIND_SPURIOUS;     /* Until proven otherwise... */
3567
  *syscall_id = -1;
3568
 
3569
  if (ttrace_state.tts_event & TTEVT_SYSCALL_ENTRY)
3570
    *kind = TARGET_WAITKIND_SYSCALL_ENTRY;
3571
  else if (ttrace_state.tts_event & TTEVT_SYSCALL_RETURN)
3572
    *kind = TARGET_WAITKIND_SYSCALL_RETURN;
3573
  else
3574
    return 0;
3575
 
3576
  *syscall_id = ttrace_state.tts_scno;
3577
  return 1;
3578
}
3579
#endif
3580
 
3581
 
3582
 
3583
#if defined(CHILD_THREAD_ALIVE)
3584
 
3585
/* Check to see if the given thread is alive.
3586
 
3587
 * We'll trust the thread list, as the more correct
3588
 * approach of stopping the process and spinning down
3589
 * the OS's thread list is _very_ expensive.
3590
 *
3591
 * May need a FIXME for that reason.
3592
 */
3593
int
3594
child_thread_alive (ptid_t ptid)
3595
{
3596
  lwpid_t gdb_tid = PIDGET (ptid);
3597
  lwpid_t tid;
3598
 
3599
  /* This spins down the lists twice.
3600
   * Possible peformance improvement here!
3601
   */
3602
  tid = map_from_gdb_tid (gdb_tid);
3603
  return !is_terminated (tid);
3604
}
3605
 
3606
#endif
3607
 
3608
 
3609
 
3610
/* This function attempts to read the specified number of bytes from the
3611
   save_state_t that is our view into the hardware registers, starting at
3612
   ss_offset, and ending at ss_offset + sizeof_buf - 1
3613
 
3614
   If this function succeeds, it deposits the fetched bytes into buf,
3615
   and returns 0.
3616
 
3617
   If it fails, it returns a negative result.  The contents of buf are
3618
   undefined it this function fails.
3619
 */
3620
int
3621
read_from_register_save_state (int tid, TTRACE_ARG_TYPE ss_offset, char *buf,
3622
                               int sizeof_buf)
3623
{
3624
  int tt_status;
3625
  register_value_t register_value = 0;
3626
 
3627
  tt_status = call_ttrace (TT_LWP_RUREGS,
3628
                           tid,
3629
                           ss_offset,
3630
                           (TTRACE_ARG_TYPE) sizeof_buf,
3631
                           (TTRACE_ARG_TYPE) buf);
3632
 
3633
  if (tt_status == 1)
3634
    /* Map ttrace's version of success to our version.
3635
     * Sometime ttrace returns 0, but that's ok here.
3636
     */
3637
    return 0;
3638
 
3639
  return tt_status;
3640
}
3641
 
3642
 
3643
/* This function attempts to write the specified number of bytes to the
3644
   save_state_t that is our view into the hardware registers, starting at
3645
   ss_offset, and ending at ss_offset + sizeof_buf - 1
3646
 
3647
   If this function succeeds, it deposits the bytes in buf, and returns 0.
3648
 
3649
   If it fails, it returns a negative result.  The contents of the save_state_t
3650
   are undefined it this function fails.
3651
 */
3652
int
3653
write_to_register_save_state (int tid, TTRACE_ARG_TYPE ss_offset, char *buf,
3654
                              int sizeof_buf)
3655
{
3656
  int tt_status;
3657
  register_value_t register_value = 0;
3658
 
3659
  tt_status = call_ttrace (TT_LWP_WUREGS,
3660
                           tid,
3661
                           ss_offset,
3662
                           (TTRACE_ARG_TYPE) sizeof_buf,
3663
                           (TTRACE_ARG_TYPE) buf);
3664
  return tt_status;
3665
}
3666
 
3667
 
3668
/* This function is a sop to the largeish number of direct calls
3669
   to call_ptrace that exist in other files.  Rather than create
3670
   functions whose name abstracts away from ptrace, and change all
3671
   the present callers of call_ptrace, we'll do the expedient (and
3672
   perhaps only practical) thing.
3673
 
3674
   Note HP-UX explicitly disallows a mix of ptrace & ttrace on a traced
3675
   process.  Thus, we must translate all ptrace requests into their
3676
   process-specific, ttrace equivalents.
3677
 */
3678
int
3679
call_ptrace (int pt_request, int gdb_tid, PTRACE_ARG3_TYPE addr, int data)
3680
{
3681
  ttreq_t tt_request;
3682
  TTRACE_ARG_TYPE tt_addr = (TTRACE_ARG_TYPE) addr;
3683
  TTRACE_ARG_TYPE tt_data = (TTRACE_ARG_TYPE) data;
3684
  TTRACE_ARG_TYPE tt_addr2 = TT_NIL;
3685
  int tt_status;
3686
  register_value_t register_value;
3687
  int read_buf;
3688
 
3689
  /* Perform the necessary argument translation.  Note that some
3690
     cases are funky enough in the ttrace realm that we handle them
3691
     very specially.
3692
   */
3693
  switch (pt_request)
3694
    {
3695
      /* The following cases cannot conveniently be handled conveniently
3696
         by merely adjusting the ptrace arguments and feeding into the
3697
         generic call to ttrace at the bottom of this function.
3698
 
3699
         Note that because all branches of this switch end in "return",
3700
         there's no need for any "break" statements.
3701
       */
3702
    case PT_SETTRC:
3703
      return parent_attach_all ();
3704
 
3705
    case PT_RUREGS:
3706
      tt_status = read_from_register_save_state (gdb_tid,
3707
                                                 tt_addr,
3708
                                                 &register_value,
3709
                                                 sizeof (register_value));
3710
      if (tt_status < 0)
3711
        return tt_status;
3712
      return register_value;
3713
 
3714
    case PT_WUREGS:
3715
      register_value = (int) tt_data;
3716
      tt_status = write_to_register_save_state (gdb_tid,
3717
                                                tt_addr,
3718
                                                &register_value,
3719
                                                sizeof (register_value));
3720
      return tt_status;
3721
      break;
3722
 
3723
    case PT_READ_I:
3724
      tt_status = call_ttrace (TT_PROC_RDTEXT,  /* Implicit 4-byte xfer becomes block-xfer. */
3725
                               gdb_tid,
3726
                               tt_addr,
3727
                               (TTRACE_ARG_TYPE) 4,
3728
                               (TTRACE_ARG_TYPE) & read_buf);
3729
      if (tt_status < 0)
3730
        return tt_status;
3731
      return read_buf;
3732
 
3733
    case PT_READ_D:
3734
      tt_status = call_ttrace (TT_PROC_RDDATA,  /* Implicit 4-byte xfer becomes block-xfer. */
3735
                               gdb_tid,
3736
                               tt_addr,
3737
                               (TTRACE_ARG_TYPE) 4,
3738
                               (TTRACE_ARG_TYPE) & read_buf);
3739
      if (tt_status < 0)
3740
        return tt_status;
3741
      return read_buf;
3742
 
3743
    case PT_ATTACH:
3744
      tt_status = call_real_ttrace (TT_PROC_ATTACH,
3745
                                    map_from_gdb_tid (gdb_tid),
3746
                                    (lwpid_t) TT_NIL,
3747
                                    tt_addr,
3748
                                    (TTRACE_ARG_TYPE) TT_VERSION,
3749
                                    tt_addr2);
3750
      if (tt_status < 0)
3751
        return tt_status;
3752
      return tt_status;
3753
 
3754
      /* The following cases are handled by merely adjusting the ptrace
3755
         arguments and feeding into the generic call to ttrace.
3756
       */
3757
    case PT_DETACH:
3758
      tt_request = TT_PROC_DETACH;
3759
      break;
3760
 
3761
    case PT_WRITE_I:
3762
      tt_request = TT_PROC_WRTEXT;      /* Translates 4-byte xfer to block-xfer. */
3763
      tt_data = 4;              /* This many bytes. */
3764
      tt_addr2 = (TTRACE_ARG_TYPE) & data;      /* Address of xfer source. */
3765
      break;
3766
 
3767
    case PT_WRITE_D:
3768
      tt_request = TT_PROC_WRDATA;      /* Translates 4-byte xfer to block-xfer. */
3769
      tt_data = 4;              /* This many bytes. */
3770
      tt_addr2 = (TTRACE_ARG_TYPE) & data;      /* Address of xfer source. */
3771
      break;
3772
 
3773
    case PT_RDTEXT:
3774
      tt_request = TT_PROC_RDTEXT;
3775
      break;
3776
 
3777
    case PT_RDDATA:
3778
      tt_request = TT_PROC_RDDATA;
3779
      break;
3780
 
3781
    case PT_WRTEXT:
3782
      tt_request = TT_PROC_WRTEXT;
3783
      break;
3784
 
3785
    case PT_WRDATA:
3786
      tt_request = TT_PROC_WRDATA;
3787
      break;
3788
 
3789
    case PT_CONTINUE:
3790
      tt_request = TT_PROC_CONTINUE;
3791
      break;
3792
 
3793
    case PT_STEP:
3794
      tt_request = TT_LWP_SINGLE;       /* Should not be making this request? */
3795
      break;
3796
 
3797
    case PT_KILL:
3798
      tt_request = TT_PROC_EXIT;
3799
      break;
3800
 
3801
    case PT_GET_PROCESS_PATHNAME:
3802
      tt_request = TT_PROC_GET_PATHNAME;
3803
      break;
3804
 
3805
    default:
3806
      tt_request = pt_request;  /* Let ttrace be the one to complain. */
3807
      break;
3808
    }
3809
 
3810
  return call_ttrace (tt_request,
3811
                      gdb_tid,
3812
                      tt_addr,
3813
                      tt_data,
3814
                      tt_addr2);
3815
}
3816
 
3817
/* Kill that pesky process!
3818
 */
3819
void
3820
kill_inferior (void)
3821
{
3822
  int tid;
3823
  int wait_status;
3824
  thread_info *t;
3825
  thread_info **paranoia;
3826
  int para_count, i;
3827
 
3828
  if (PIDGET (inferior_ptid) == 0)
3829
    return;
3830
 
3831
  /* Walk the list of "threads", some of which are "pseudo threads",
3832
     aka "processes".  For each that is NOT inferior_ptid, stop it,
3833
     and detach it.
3834
 
3835
     You see, we may not have just a single process to kill.  If we're
3836
     restarting or quitting or detaching just after the inferior has
3837
     forked, then we've actually two processes to clean up.
3838
 
3839
     But we can't just call target_mourn_inferior() for each, since that
3840
     zaps the target vector.
3841
   */
3842
 
3843
  paranoia = (thread_info **) xmalloc (thread_head.count *
3844
                                       sizeof (thread_info *));
3845
  para_count = 0;
3846
 
3847
  t = thread_head.head;
3848
  while (t)
3849
    {
3850
 
3851
      paranoia[para_count] = t;
3852
      for (i = 0; i < para_count; i++)
3853
        {
3854
          if (t->next == paranoia[i])
3855
            {
3856
              warning ("Bad data in gdb's thread data; repairing.");
3857
              t->next = 0;
3858
            }
3859
        }
3860
      para_count++;
3861
 
3862
      if (t->am_pseudo && (t->pid != PIDGET (inferior_ptid)))
3863
        {
3864
          call_ttrace (TT_PROC_EXIT,
3865
                       t->pid,
3866
                       TT_NIL,
3867
                       TT_NIL,
3868
                       TT_NIL);
3869
        }
3870
      t = t->next;
3871
    }
3872
 
3873
  xfree (paranoia);
3874
 
3875
  call_ttrace (TT_PROC_EXIT,
3876
               PIDGET (inferior_ptid),
3877
               TT_NIL,
3878
               TT_NIL,
3879
               TT_NIL);
3880
  target_mourn_inferior ();
3881
  clear_thread_info ();
3882
}
3883
 
3884
 
3885
#ifndef CHILD_RESUME
3886
 
3887
/* Sanity check a thread about to be continued.
3888
 */
3889
static void
3890
thread_dropping_event_check (thread_info *p)
3891
{
3892
  if (!p->handled)
3893
    {
3894
      /*
3895
       * This seems to happen when we "next" over a
3896
       * "fork()" while following the parent.  If it's
3897
       * the FORK event, that's ok.  If it's a SIGNAL
3898
       * in the unfollowed child, that's ok to--but
3899
       * how can we know that's what's going on?
3900
       *
3901
       * FIXME!
3902
       */
3903
      if (p->have_state)
3904
        {
3905
          if (p->last_stop_state.tts_event == TTEVT_FORK)
3906
            {
3907
              /* Ok */
3908
              ;
3909
            }
3910
          else if (p->last_stop_state.tts_event == TTEVT_SIGNAL)
3911
            {
3912
              /* Ok, close eyes and let it happen.
3913
               */
3914
              ;
3915
            }
3916
          else
3917
            {
3918
              /* This shouldn't happen--we're dropping a
3919
               * real event.
3920
               */
3921
              warning ("About to continue process %d, thread %d with unhandled event %s.",
3922
                       p->pid, p->tid,
3923
                       get_printable_name_of_ttrace_event (
3924
                                             p->last_stop_state.tts_event));
3925
 
3926
#ifdef PARANOIA
3927
              if (debug_on)
3928
                print_tthread (p);
3929
#endif
3930
            }
3931
        }
3932
      else
3933
        {
3934
          /* No saved state, have to assume it failed.
3935
           */
3936
          warning ("About to continue process %d, thread %d with unhandled event.",
3937
                   p->pid, p->tid);
3938
#ifdef PARANOIA
3939
          if (debug_on)
3940
            print_tthread (p);
3941
#endif
3942
        }
3943
    }
3944
 
3945
}                               /* thread_dropping_event_check */
3946
 
3947
/* Use a loop over the threads to continue all the threads but
3948
 * the one specified, which is to be stepped.
3949
 */
3950
static void
3951
threads_continue_all_but_one (lwpid_t gdb_tid, int signal)
3952
{
3953
  thread_info *p;
3954
  int thread_signal;
3955
  lwpid_t real_tid;
3956
  lwpid_t scan_tid;
3957
  ttstate_t state;
3958
  int real_pid;
3959
 
3960
#ifdef THREAD_DEBUG
3961
  if (debug_on)
3962
    printf ("Using loop over threads to step/resume with signals\n");
3963
#endif
3964
 
3965
  /* First update the thread list.
3966
   */
3967
  set_all_unseen ();
3968
  real_tid = map_from_gdb_tid (gdb_tid);
3969
  real_pid = get_pid_for (real_tid);
3970
 
3971
  scan_tid = get_process_first_stopped_thread_id (real_pid, &state);
3972
  while (0 != scan_tid)
3973
    {
3974
 
3975
#ifdef THREAD_DEBUG
3976
      /* FIX: later should check state is stopped;
3977
       * state.tts_flags & TTS_STATEMASK == TTS_WASSUSPENDED
3978
       */
3979
      if (debug_on)
3980
        if (state.tts_flags & TTS_STATEMASK != TTS_WASSUSPENDED)
3981
          printf ("About to continue non-stopped thread %d\n", scan_tid);
3982
#endif
3983
 
3984
      p = find_thread_info (scan_tid);
3985
      if (NULL == p)
3986
        {
3987
          add_tthread (real_pid, scan_tid);
3988
          p = find_thread_info (scan_tid);
3989
 
3990
          /* This is either a newly-created thread or the
3991
           * result of a fork; in either case there's no
3992
           * actual event to worry about.
3993
           */
3994
          p->handled = 1;
3995
 
3996
          if (state.tts_event != TTEVT_NONE)
3997
            {
3998
              /* Oops, do need to worry!
3999
               */
4000
              warning ("Unexpected thread with \"%s\" event.",
4001
                       get_printable_name_of_ttrace_event (state.tts_event));
4002
            }
4003
        }
4004
      else if (scan_tid != p->tid)
4005
        error ("Bad data in thread database.");
4006
 
4007
#ifdef THREAD_DEBUG
4008
      if (debug_on)
4009
        if (p->terminated)
4010
          printf ("Why are we continuing a dead thread?\n");
4011
#endif
4012
 
4013
      p->seen = 1;
4014
 
4015
      scan_tid = get_process_next_stopped_thread_id (real_pid, &state);
4016
    }
4017
 
4018
  /* Remove unseen threads.
4019
   */
4020
  update_thread_list ();
4021
 
4022
  /* Now run down the thread list and continue or step.
4023
   */
4024
  for (p = thread_head.head; p; p = p->next)
4025
    {
4026
 
4027
      /* Sanity check.
4028
       */
4029
      thread_dropping_event_check (p);
4030
 
4031
      /* Pass the correct signals along.
4032
       */
4033
      if (p->have_signal)
4034
        {
4035
          thread_signal = p->signal_value;
4036
          p->have_signal = 0;
4037
        }
4038
      else
4039
        thread_signal = 0;
4040
 
4041
      if (p->tid != real_tid)
4042
        {
4043
          /*
4044
           * Not the thread of interest, so continue it
4045
           * as the user expects.
4046
           */
4047
          if (p->stepping_mode == DO_STEP)
4048
            {
4049
              /* Just step this thread.
4050
               */
4051
              call_ttrace (
4052
                            TT_LWP_SINGLE,
4053
                            p->tid,
4054
                            TT_USE_CURRENT_PC,
4055
                            (TTRACE_ARG_TYPE) target_signal_to_host (signal),
4056
                            TT_NIL);
4057
            }
4058
          else
4059
            {
4060
              /* Regular continue (default case).
4061
               */
4062
              call_ttrace (
4063
                            TT_LWP_CONTINUE,
4064
                            p->tid,
4065
                            TT_USE_CURRENT_PC,
4066
                    (TTRACE_ARG_TYPE) target_signal_to_host (thread_signal),
4067
                            TT_NIL);
4068
            }
4069
        }
4070
      else
4071
        {
4072
          /* Step the thread of interest.
4073
           */
4074
          call_ttrace (
4075
                        TT_LWP_SINGLE,
4076
                        real_tid,
4077
                        TT_USE_CURRENT_PC,
4078
                        (TTRACE_ARG_TYPE) target_signal_to_host (signal),
4079
                        TT_NIL);
4080
        }
4081
    }                           /* Loop over threads */
4082
}                               /* End threads_continue_all_but_one */
4083
 
4084
/* Use a loop over the threads to continue all the threads.
4085
 * This is done when a signal must be sent to any of the threads.
4086
 */
4087
static void
4088
threads_continue_all_with_signals (lwpid_t gdb_tid, int signal)
4089
{
4090
  thread_info *p;
4091
  int thread_signal;
4092
  lwpid_t real_tid;
4093
  lwpid_t scan_tid;
4094
  ttstate_t state;
4095
  int real_pid;
4096
 
4097
#ifdef THREAD_DEBUG
4098
  if (debug_on)
4099
    printf ("Using loop over threads to resume with signals\n");
4100
#endif
4101
 
4102
  /* Scan and update thread list.
4103
   */
4104
  set_all_unseen ();
4105
  real_tid = map_from_gdb_tid (gdb_tid);
4106
  real_pid = get_pid_for (real_tid);
4107
 
4108
  scan_tid = get_process_first_stopped_thread_id (real_pid, &state);
4109
  while (0 != scan_tid)
4110
    {
4111
 
4112
#ifdef THREAD_DEBUG
4113
      if (debug_on)
4114
        if (state.tts_flags & TTS_STATEMASK != TTS_WASSUSPENDED)
4115
          warning ("About to continue non-stopped thread %d\n", scan_tid);
4116
#endif
4117
 
4118
      p = find_thread_info (scan_tid);
4119
      if (NULL == p)
4120
        {
4121
          add_tthread (real_pid, scan_tid);
4122
          p = find_thread_info (scan_tid);
4123
 
4124
          /* This is either a newly-created thread or the
4125
           * result of a fork; in either case there's no
4126
           * actual event to worry about.
4127
           */
4128
          p->handled = 1;
4129
 
4130
          if (state.tts_event != TTEVT_NONE)
4131
            {
4132
              /* Oops, do need to worry!
4133
               */
4134
              warning ("Unexpected thread with \"%s\" event.",
4135
                       get_printable_name_of_ttrace_event (state.tts_event));
4136
            }
4137
        }
4138
 
4139
#ifdef THREAD_DEBUG
4140
      if (debug_on)
4141
        if (p->terminated)
4142
          printf ("Why are we continuing a dead thread? (1)\n");
4143
#endif
4144
 
4145
      p->seen = 1;
4146
 
4147
      scan_tid = get_process_next_stopped_thread_id (real_pid, &state);
4148
    }
4149
 
4150
  /* Remove unseen threads from our list.
4151
   */
4152
  update_thread_list ();
4153
 
4154
  /* Continue the threads.
4155
   */
4156
  for (p = thread_head.head; p; p = p->next)
4157
    {
4158
 
4159
      /* Sanity check.
4160
       */
4161
      thread_dropping_event_check (p);
4162
 
4163
      /* Pass the correct signals along.
4164
       */
4165
      if (p->tid == real_tid)
4166
        {
4167
          thread_signal = signal;
4168
          p->have_signal = 0;
4169
        }
4170
      else if (p->have_signal)
4171
        {
4172
          thread_signal = p->signal_value;
4173
          p->have_signal = 0;
4174
        }
4175
      else
4176
        thread_signal = 0;
4177
 
4178
      if (p->stepping_mode == DO_STEP)
4179
        {
4180
          call_ttrace (
4181
                        TT_LWP_SINGLE,
4182
                        p->tid,
4183
                        TT_USE_CURRENT_PC,
4184
                        (TTRACE_ARG_TYPE) target_signal_to_host (signal),
4185
                        TT_NIL);
4186
        }
4187
      else
4188
        {
4189
          /* Continue this thread (default case).
4190
           */
4191
          call_ttrace (
4192
                        TT_LWP_CONTINUE,
4193
                        p->tid,
4194
                        TT_USE_CURRENT_PC,
4195
                    (TTRACE_ARG_TYPE) target_signal_to_host (thread_signal),
4196
                        TT_NIL);
4197
        }
4198
    }
4199
}                               /* End threads_continue_all_with_signals */
4200
 
4201
/* Step one thread only.
4202
 */
4203
static void
4204
thread_fake_step (lwpid_t tid, enum target_signal signal)
4205
{
4206
  thread_info *p;
4207
 
4208
#ifdef THREAD_DEBUG
4209
  if (debug_on)
4210
    {
4211
      printf ("Doing a fake-step over a bpt, etc. for %d\n", tid);
4212
 
4213
      if (is_terminated (tid))
4214
        printf ("Why are we continuing a dead thread? (4)\n");
4215
    }
4216
#endif
4217
 
4218
  if (doing_fake_step)
4219
    warning ("Step while step already in progress.");
4220
 
4221
  /* See if there's a saved signal value for this
4222
   * thread to be passed on, but no current signal.
4223
   */
4224
  p = find_thread_info (tid);
4225
  if (p != NULL)
4226
    {
4227
      if (p->have_signal && signal == TARGET_SIGNAL_0)
4228
        {
4229
          /* Pass on a saved signal.
4230
           */
4231
          signal = p->signal_value;
4232
        }
4233
 
4234
      p->have_signal = 0;
4235
    }
4236
 
4237
  if (!p->handled)
4238
    warning ("Internal error: continuing unhandled thread.");
4239
 
4240
  call_ttrace (TT_LWP_SINGLE,
4241
               tid,
4242
               TT_USE_CURRENT_PC,
4243
               (TTRACE_ARG_TYPE) target_signal_to_host (signal),
4244
               TT_NIL);
4245
 
4246
  /* Do bookkeeping so "call_ttrace_wait" knows it has to wait
4247
   * for this thread only, and clear any saved signal info.
4248
   */
4249
  doing_fake_step = 1;
4250
  fake_step_tid = tid;
4251
 
4252
}                               /* End thread_fake_step */
4253
 
4254
/* Continue one thread when a signal must be sent to it.
4255
 */
4256
static void
4257
threads_continue_one_with_signal (lwpid_t gdb_tid, int signal)
4258
{
4259
  thread_info *p;
4260
  lwpid_t real_tid;
4261
  int real_pid;
4262
 
4263
#ifdef THREAD_DEBUG
4264
  if (debug_on)
4265
    printf ("Continuing one thread with a signal\n");
4266
#endif
4267
 
4268
  real_tid = map_from_gdb_tid (gdb_tid);
4269
  real_pid = get_pid_for (real_tid);
4270
 
4271
  p = find_thread_info (real_tid);
4272
  if (NULL == p)
4273
    {
4274
      add_tthread (real_pid, real_tid);
4275
    }
4276
 
4277
#ifdef THREAD_DEBUG
4278
  if (debug_on)
4279
    if (p->terminated)
4280
      printf ("Why are we continuing a dead thread? (2)\n");
4281
#endif
4282
 
4283
  if (!p->handled)
4284
    warning ("Internal error: continuing unhandled thread.");
4285
 
4286
  p->have_signal = 0;
4287
 
4288
  call_ttrace (TT_LWP_CONTINUE,
4289
               gdb_tid,
4290
               TT_USE_CURRENT_PC,
4291
               (TTRACE_ARG_TYPE) target_signal_to_host (signal),
4292
               TT_NIL);
4293
}
4294
#endif
4295
 
4296
#ifndef CHILD_RESUME
4297
 
4298
/* Resume execution of the inferior process.
4299
 
4300
 * This routine is in charge of setting the "handled" bits.
4301
 *
4302
 *   If STEP is zero,      continue it.
4303
 *   If STEP is nonzero,   single-step it.
4304
 *
4305
 *   If SIGNAL is nonzero, give it that signal.
4306
 *
4307
 *   If TID is -1,         apply to all threads.
4308
 *   If TID is not -1,     apply to specified thread.
4309
 *
4310
 *           STEP
4311
 *      \      !0                        0
4312
 *  TID  \________________________________________________
4313
 *       |
4314
 *   -1  |   Step current            Continue all threads
4315
 *       |   thread and              (but which gets any
4316
 *       |   continue others         signal?--We look at
4317
 *       |                           "inferior_ptid")
4318
 *       |
4319
 *    N  |   Step _this_ thread      Continue _this_ thread
4320
 *       |   and leave others        and leave others
4321
 *       |   stopped; internally     stopped; used only for
4322
 *       |   used by gdb, never      hardware watchpoints
4323
 *       |   a user command.         and attach, never a
4324
 *       |                           user command.
4325
 */
4326
void
4327
child_resume (ptid_t ptid, int step, enum target_signal signal)
4328
{
4329
  int resume_all_threads;
4330
  lwpid_t tid;
4331
  process_state_t new_process_state;
4332
  lwpid_t gdb_tid = PIDGET (ptid);
4333
 
4334
  resume_all_threads =
4335
    (gdb_tid == INFTTRACE_ALL_THREADS) ||
4336
    (vfork_in_flight);
4337
 
4338
  if (resume_all_threads)
4339
    {
4340
      /* Resume all threads, but first pick a tid value
4341
       * so we can get the pid when in call_ttrace doing
4342
       * the map.
4343
       */
4344
      if (vfork_in_flight)
4345
        tid = vforking_child_pid;
4346
      else
4347
        tid = map_from_gdb_tid (PIDGET (inferior_ptid));
4348
    }
4349
  else
4350
    tid = map_from_gdb_tid (gdb_tid);
4351
 
4352
#ifdef THREAD_DEBUG
4353
  if (debug_on)
4354
    {
4355
      if (more_events_left)
4356
        printf ("More events; ");
4357
 
4358
      if (signal != 0)
4359
        printf ("Sending signal %d; ", signal);
4360
 
4361
      if (resume_all_threads)
4362
        {
4363
          if (step == 0)
4364
            printf ("Continue process %d\n", tid);
4365
          else
4366
            printf ("Step/continue thread %d\n", tid);
4367
        }
4368
      else
4369
        {
4370
          if (step == 0)
4371
            printf ("Continue thread %d\n", tid);
4372
          else
4373
            printf ("Step just thread %d\n", tid);
4374
        }
4375
 
4376
      if (vfork_in_flight)
4377
        printf ("Vfork in flight\n");
4378
    }
4379
#endif
4380
 
4381
  if (process_state == RUNNING)
4382
    warning ("Internal error in resume logic; doing resume or step anyway.");
4383
 
4384
  if (!step                     /* Asked to continue...       */
4385
      && resume_all_threads     /* whole process..            */
4386
      && signal != 0             /* with a signal...           */
4387
      && more_events_left > 0)
4388
    {                           /* but we can't yet--save it! */
4389
 
4390
      /* Continue with signal means we have to set the pending
4391
       * signal value for this thread.
4392
       */
4393
      thread_info *k;
4394
 
4395
#ifdef THREAD_DEBUG
4396
      if (debug_on)
4397
        printf ("Saving signal %d for thread %d\n", signal, tid);
4398
#endif
4399
 
4400
      k = find_thread_info (tid);
4401
      if (k != NULL)
4402
        {
4403
          k->have_signal = 1;
4404
          k->signal_value = signal;
4405
 
4406
#ifdef THREAD_DEBUG
4407
          if (debug_on)
4408
            if (k->terminated)
4409
              printf ("Why are we continuing a dead thread? (3)\n");
4410
#endif
4411
 
4412
        }
4413
 
4414
#ifdef THREAD_DEBUG
4415
      else if (debug_on)
4416
        {
4417
          printf ("No thread info for tid %d\n", tid);
4418
        }
4419
#endif
4420
    }
4421
 
4422
  /* Are we faking this "continue" or "step"?
4423
 
4424
   * We used to do steps by continuing all the threads for
4425
   * which the events had been handled already.  While
4426
   * conceptually nicer (hides it all in a lower level), this
4427
   * can lead to starvation and a hang (e.g. all but one thread
4428
   * are unhandled at a breakpoint just before a "join" operation,
4429
   * and one thread is in the join, and the user wants to step that
4430
   * thread).
4431
   */
4432
  if (resume_all_threads        /* Whole process, therefore user command */
4433
      && more_events_left > 0)
4434
    {                           /* But we can't do this yet--fake it! */
4435
      thread_info *p;
4436
 
4437
      if (!step)
4438
        {
4439
          /* No need to do any notes on a per-thread
4440
           * basis--we're done!
4441
           */
4442
#ifdef WAIT_BUFFER_DEBUG
4443
          if (debug_on)
4444
            printf ("Faking a process resume.\n");
4445
#endif
4446
 
4447
          return;
4448
        }
4449
      else
4450
        {
4451
 
4452
#ifdef WAIT_BUFFER_DEBUG
4453
          if (debug_on)
4454
            printf ("Faking a process step.\n");
4455
#endif
4456
 
4457
        }
4458
 
4459
      p = find_thread_info (tid);
4460
      if (p == NULL)
4461
        {
4462
          warning ("No thread information for tid %d, 'next' command ignored.\n", tid);
4463
          return;
4464
        }
4465
      else
4466
        {
4467
 
4468
#ifdef THREAD_DEBUG
4469
          if (debug_on)
4470
            if (p->terminated)
4471
              printf ("Why are we continuing a dead thread? (3.5)\n");
4472
#endif
4473
 
4474
          if (p->stepping_mode != DO_DEFAULT)
4475
            {
4476
              warning ("Step or continue command applied to thread which is already stepping or continuing; command ignored.");
4477
 
4478
              return;
4479
            }
4480
 
4481
          if (step)
4482
            p->stepping_mode = DO_STEP;
4483
          else
4484
            p->stepping_mode = DO_CONTINUE;
4485
 
4486
          return;
4487
        }                       /* Have thread info */
4488
    }                           /* Must fake step or go */
4489
 
4490
  /* Execept for fake-steps, from here on we know we are
4491
   * going to wind up with a running process which will
4492
   * need a real wait.
4493
   */
4494
  new_process_state = RUNNING;
4495
 
4496
  /* An address of TT_USE_CURRENT_PC tells ttrace to continue from where
4497
   * it was.  (If GDB wanted it to start some other way, we have already
4498
   * written a new PC value to the child.)
4499
   *
4500
   * If this system does not support PT_STEP, a higher level function will
4501
   * have called single_step() to transmute the step request into a
4502
   * continue request (by setting breakpoints on all possible successor
4503
   * instructions), so we don't have to worry about that here.
4504
   */
4505
  if (step)
4506
    {
4507
      if (resume_all_threads)
4508
        {
4509
          /*
4510
           * Regular user step: other threads get a "continue".
4511
           */
4512
          threads_continue_all_but_one (tid, signal);
4513
          clear_all_handled ();
4514
          clear_all_stepping_mode ();
4515
        }
4516
 
4517
      else
4518
        {
4519
          /* "Fake step": gdb is stepping one thread over a
4520
           * breakpoint, watchpoint, or out of a library load
4521
           * event, etc.  The rest just stay where they are.
4522
           *
4523
           * Also used when there are pending events: we really
4524
           * step the current thread, but leave the rest stopped.
4525
           * Users can't request this, but "wait_for_inferior"
4526
           * does--a lot!
4527
           */
4528
          thread_fake_step (tid, signal);
4529
 
4530
          /* Clear the "handled" state of this thread, because
4531
           * we'll soon get a new event for it.  Other events
4532
           * stay as they were.
4533
           */
4534
          clear_handled (tid);
4535
          clear_stepping_mode (tid);
4536
          new_process_state = FAKE_STEPPING;
4537
        }
4538
    }
4539
 
4540
  else
4541
    {
4542
      /* TT_LWP_CONTINUE can pass signals to threads, TT_PROC_CONTINUE can't.
4543
         Therefore, we really can't use TT_PROC_CONTINUE here.
4544
 
4545
         Consider a process which stopped due to signal which gdb decides
4546
         to handle and not pass on to the inferior.  In that case we must
4547
         clear the pending signal by restarting the inferior using
4548
         TT_LWP_CONTINUE and pass zero as the signal number.  Else the
4549
         pending signal will be passed to the inferior.  interrupt.exp
4550
         in the testsuite does this precise thing and fails due to the
4551
         unwanted signal delivery to the inferior.  */
4552
      if (resume_all_threads)
4553
        {
4554
#ifdef THREAD_DEBUG
4555
          if (debug_on)
4556
            printf ("Doing a continue by loop of all threads\n");
4557
#endif
4558
 
4559
          threads_continue_all_with_signals (tid, signal);
4560
 
4561
          clear_all_handled ();
4562
          clear_all_stepping_mode ();
4563
        }
4564
      else
4565
        {
4566
#ifdef THREAD_DEBUG
4567
          printf ("Doing a continue w/signal of just thread %d\n", tid);
4568
#endif
4569
 
4570
          threads_continue_one_with_signal (tid, signal);
4571
 
4572
          /* Clear the "handled" state of this thread, because we
4573
             will soon get a new event for it.  Other events can
4574
             stay as they were.  */
4575
          clear_handled (tid);
4576
          clear_stepping_mode (tid);
4577
        }
4578
    }
4579
 
4580
  process_state = new_process_state;
4581
 
4582
#ifdef WAIT_BUFFER_DEBUG
4583
  if (debug_on)
4584
    printf ("Process set to %s\n",
4585
            get_printable_name_of_process_state (process_state));
4586
#endif
4587
 
4588
}
4589
#endif /* CHILD_RESUME */
4590
 
4591
 
4592
#ifdef ATTACH_DETACH
4593
/*
4594
 * Like it says.
4595
 *
4596
 * One worry is that we may not be attaching to "inferior_ptid"
4597
 * and thus may not want to clear out our data.  FIXME?
4598
 *
4599
 */
4600
static void
4601
update_thread_state_after_attach (int pid, attach_continue_t kind_of_go)
4602
{
4603
  int tt_status;
4604
  ttstate_t thread_state;
4605
  lwpid_t a_thread;
4606
  lwpid_t tid;
4607
 
4608
  /* The process better be stopped.
4609
   */
4610
  if (process_state != STOPPED
4611
      && process_state != VFORKING)
4612
    warning ("Internal error attaching.");
4613
 
4614
  /* Clear out old tthread info and start over.  This has the
4615
   * side effect of ensuring that the TRAP is reported as being
4616
   * in the right thread (re-mapped from tid to pid).
4617
   *
4618
   * It's because we need to add the tthread _now_ that we
4619
   * need to call "clear_thread_info" _now_, and that's why
4620
   * "require_notification_of_events" doesn't clear the thread
4621
   * info (it's called later than this routine).
4622
   */
4623
  clear_thread_info ();
4624
  a_thread = 0;
4625
 
4626
  for (tid = get_process_first_stopped_thread_id (pid, &thread_state);
4627
       tid != 0;
4628
       tid = get_process_next_stopped_thread_id (pid, &thread_state))
4629
    {
4630
      thread_info *p;
4631
 
4632
      if (a_thread == 0)
4633
        {
4634
          a_thread = tid;
4635
#ifdef THREAD_DEBUG
4636
          if (debug_on)
4637
            printf ("Attaching to process %d, thread %d\n",
4638
                    pid, a_thread);
4639
#endif
4640
        }
4641
 
4642
      /* Tell ourselves and the "rest of gdb" that this thread
4643
       * exists.
4644
       *
4645
       * This isn't really a hack.  Other thread-based versions
4646
       * of gdb (e.g. gnu-nat.c) seem to do the same thing.
4647
       *
4648
       * We don't need to do mapping here, as we know this
4649
       * is the first thread and thus gets the real pid
4650
       * (and is "inferior_ptid").
4651
       *
4652
       * NOTE: it probably isn't the originating thread,
4653
       *       but that doesn't matter (we hope!).
4654
       */
4655
      add_tthread (pid, tid);
4656
      p = find_thread_info (tid);
4657
      if (NULL == p)            /* ?We just added it! */
4658
        error ("Internal error adding a thread on attach.");
4659
 
4660
      copy_ttstate_t (&p->last_stop_state, &thread_state);
4661
      p->have_state = 1;
4662
 
4663
      if (DO_ATTACH_CONTINUE == kind_of_go)
4664
        {
4665
          /*
4666
           * If we are going to CONTINUE afterwards,
4667
           * raising a SIGTRAP, don't bother trying to
4668
           * handle this event.  But check first!
4669
           */
4670
          switch (p->last_stop_state.tts_event)
4671
            {
4672
 
4673
            case TTEVT_NONE:
4674
              /* Ok to set this handled.
4675
               */
4676
              break;
4677
 
4678
            default:
4679
              warning ("Internal error; skipping event %s on process %d, thread %d.",
4680
                       get_printable_name_of_ttrace_event (
4681
                                              p->last_stop_state.tts_event),
4682
                       p->pid, p->tid);
4683
            }
4684
 
4685
          set_handled (pid, tid);
4686
 
4687
        }
4688
      else
4689
        {
4690
          /* There will be no "continue" opertion, so the
4691
           * process remains stopped.  Don't set any events
4692
           * handled except the "gimmies".
4693
           */
4694
          switch (p->last_stop_state.tts_event)
4695
            {
4696
 
4697
            case TTEVT_NONE:
4698
              /* Ok to ignore this.
4699
               */
4700
              set_handled (pid, tid);
4701
              break;
4702
 
4703
            case TTEVT_EXEC:
4704
            case TTEVT_FORK:
4705
              /* Expected "other" FORK or EXEC event from a
4706
               * fork or vfork.
4707
               */
4708
              break;
4709
 
4710
            default:
4711
              printf ("Internal error: failed to handle event %s on process %d, thread %d.",
4712
                      get_printable_name_of_ttrace_event (
4713
                                              p->last_stop_state.tts_event),
4714
                      p->pid, p->tid);
4715
            }
4716
        }
4717
 
4718
      add_thread (pid_to_ptid (pid));           /* in thread.c */
4719
    }
4720
 
4721
#ifdef PARANOIA
4722
  if (debug_on)
4723
    print_tthreads ();
4724
#endif
4725
 
4726
  /* One mustn't call ttrace_wait() after attaching via ttrace,
4727
     'cause the process is stopped already.
4728
 
4729
     However, the upper layers of gdb's execution control will
4730
     want to wait after attaching (but not after forks, in
4731
     which case they will be doing a "target_resume", anticipating
4732
     a later TTEVT_EXEC or TTEVT_FORK event).
4733
 
4734
     To make this attach() implementation more compatible with
4735
     others, we'll make the attached-to process raise a SIGTRAP.
4736
 
4737
     Issue: this continues only one thread.  That could be
4738
     dangerous if the thread is blocked--the process won't run
4739
     and no trap will be raised.  FIX! (check state.tts_flags?
4740
     need one that's either TTS_WASRUNNING--but we've stopped
4741
     it and made it TTS_WASSUSPENDED.  Hum...FIXME!)
4742
   */
4743
  if (DO_ATTACH_CONTINUE == kind_of_go)
4744
    {
4745
      tt_status = call_real_ttrace (
4746
                                     TT_LWP_CONTINUE,
4747
                                     pid,
4748
                                     a_thread,
4749
                                     TT_USE_CURRENT_PC,
4750
               (TTRACE_ARG_TYPE) target_signal_to_host (TARGET_SIGNAL_TRAP),
4751
                                     TT_NIL);
4752
      if (errno)
4753
        perror_with_name ("ttrace");
4754
 
4755
      clear_handled (a_thread); /* So TRAP will be reported. */
4756
 
4757
      /* Now running.
4758
       */
4759
      process_state = RUNNING;
4760
    }
4761
 
4762
  attach_flag = 1;
4763
}
4764
#endif /* ATTACH_DETACH */
4765
 
4766
 
4767
#ifdef ATTACH_DETACH
4768
/* Start debugging the process whose number is PID.
4769
 * (A _real_ pid).
4770
 */
4771
int
4772
attach (int pid)
4773
{
4774
  int tt_status;
4775
 
4776
  tt_status = call_real_ttrace (
4777
                                 TT_PROC_ATTACH,
4778
                                 pid,
4779
                                 (lwpid_t) TT_NIL,
4780
                                 TT_NIL,
4781
                                 (TTRACE_ARG_TYPE) TT_VERSION,
4782
                                 TT_NIL);
4783
  if (errno)
4784
    perror_with_name ("ttrace attach");
4785
 
4786
  /* If successful, the process is now stopped.
4787
   */
4788
  process_state = STOPPED;
4789
 
4790
  /* Our caller ("attach_command" in "infcmd.c")
4791
   * expects to do a "wait_for_inferior" after
4792
   * the attach, so make sure the inferior is
4793
   * running when we're done.
4794
   */
4795
  update_thread_state_after_attach (pid, DO_ATTACH_CONTINUE);
4796
 
4797
  return pid;
4798
}
4799
 
4800
 
4801
#if defined(CHILD_POST_ATTACH)
4802
void
4803
child_post_attach (int pid)
4804
{
4805
#ifdef THREAD_DEBUG
4806
  if (debug_on)
4807
    printf ("child-post-attach call\n");
4808
#endif
4809
 
4810
  require_notification_of_events (pid);
4811
}
4812
#endif
4813
 
4814
 
4815
/* Stop debugging the process whose number is PID
4816
   and continue it with signal number SIGNAL.
4817
   SIGNAL = 0 means just continue it.
4818
 */
4819
void
4820
detach (int signal)
4821
{
4822
  errno = 0;
4823
  call_ttrace (TT_PROC_DETACH,
4824
               PIDGET (inferior_ptid),
4825
               TT_NIL,
4826
               (TTRACE_ARG_TYPE) signal,
4827
               TT_NIL);
4828
  attach_flag = 0;
4829
 
4830
  clear_thread_info ();
4831
 
4832
  /* Process-state? */
4833
}
4834
#endif /* ATTACH_DETACH */
4835
 
4836
 
4837
/* Default the type of the ttrace transfer to int.  */
4838
#ifndef TTRACE_XFER_TYPE
4839
#define TTRACE_XFER_TYPE int
4840
#endif
4841
 
4842
void
4843
_initialize_kernel_u_addr (void)
4844
{
4845
}
4846
 
4847
#if !defined (CHILD_XFER_MEMORY)
4848
/* NOTE! I tried using TTRACE_READDATA, etc., to read and write memory
4849
   in the NEW_SUN_TTRACE case.
4850
   It ought to be straightforward.  But it appears that writing did
4851
   not write the data that I specified.  I cannot understand where
4852
   it got the data that it actually did write.  */
4853
 
4854
/* Copy LEN bytes to or from inferior's memory starting at MEMADDR
4855
   to debugger memory starting at MYADDR.   Copy to inferior if
4856
   WRITE is nonzero.  TARGET is ignored.
4857
 
4858
   Returns the length copied, which is either the LEN argument or zero.
4859
   This xfer function does not do partial moves, since child_ops
4860
   doesn't allow memory operations to cross below us in the target stack
4861
   anyway.  */
4862
 
4863
int
4864
child_xfer_memory (CORE_ADDR memaddr, char *myaddr, int len, int write,
4865
                   struct mem_attrib *attrib,
4866
                   struct target_ops *target)
4867
{
4868
  register int i;
4869
  /* Round starting address down to longword boundary.  */
4870
  register CORE_ADDR addr = memaddr & -(CORE_ADDR) sizeof (TTRACE_XFER_TYPE);
4871
  /* Round ending address up; get number of longwords that makes.  */
4872
  register int count
4873
  = (((memaddr + len) - addr) + sizeof (TTRACE_XFER_TYPE) - 1)
4874
  / sizeof (TTRACE_XFER_TYPE);
4875
  /* Allocate buffer of that many longwords.  */
4876
  /* FIXME (alloca): This code, cloned from infptrace.c, is unsafe
4877
     because it uses alloca to allocate a buffer of arbitrary size.
4878
     For very large xfers, this could crash GDB's stack.  */
4879
  register TTRACE_XFER_TYPE *buffer
4880
    = (TTRACE_XFER_TYPE *) alloca (count * sizeof (TTRACE_XFER_TYPE));
4881
 
4882
  if (write)
4883
    {
4884
      /* Fill start and end extra bytes of buffer with existing memory data.  */
4885
 
4886
      if (addr != memaddr || len < (int) sizeof (TTRACE_XFER_TYPE))
4887
        {
4888
          /* Need part of initial word -- fetch it.  */
4889
          buffer[0] = call_ttrace (TT_LWP_RDTEXT,
4890
                                   PIDGET (inferior_ptid),
4891
                                   (TTRACE_ARG_TYPE) addr,
4892
                                   TT_NIL,
4893
                                   TT_NIL);
4894
        }
4895
 
4896
      if (count > 1)            /* FIXME, avoid if even boundary */
4897
        {
4898
          buffer[count - 1] = call_ttrace (TT_LWP_RDTEXT,
4899
                                           PIDGET (inferior_ptid),
4900
                                           ((TTRACE_ARG_TYPE)
4901
                          (addr + (count - 1) * sizeof (TTRACE_XFER_TYPE))),
4902
                                           TT_NIL,
4903
                                           TT_NIL);
4904
        }
4905
 
4906
      /* Copy data to be written over corresponding part of buffer */
4907
 
4908
      memcpy ((char *) buffer + (memaddr & (sizeof (TTRACE_XFER_TYPE) - 1)),
4909
              myaddr,
4910
              len);
4911
 
4912
      /* Write the entire buffer.  */
4913
 
4914
      for (i = 0; i < count; i++, addr += sizeof (TTRACE_XFER_TYPE))
4915
        {
4916
          errno = 0;
4917
          call_ttrace (TT_LWP_WRDATA,
4918
                       PIDGET (inferior_ptid),
4919
                       (TTRACE_ARG_TYPE) addr,
4920
                       (TTRACE_ARG_TYPE) buffer[i],
4921
                       TT_NIL);
4922
          if (errno)
4923
            {
4924
              /* Using the appropriate one (I or D) is necessary for
4925
                 Gould NP1, at least.  */
4926
              errno = 0;
4927
              call_ttrace (TT_LWP_WRTEXT,
4928
                           PIDGET (inferior_ptid),
4929
                           (TTRACE_ARG_TYPE) addr,
4930
                           (TTRACE_ARG_TYPE) buffer[i],
4931
                           TT_NIL);
4932
            }
4933
          if (errno)
4934
            return 0;
4935
        }
4936
    }
4937
  else
4938
    {
4939
      /* Read all the longwords */
4940
      for (i = 0; i < count; i++, addr += sizeof (TTRACE_XFER_TYPE))
4941
        {
4942
          errno = 0;
4943
          buffer[i] = call_ttrace (TT_LWP_RDTEXT,
4944
                                   PIDGET (inferior_ptid),
4945
                                   (TTRACE_ARG_TYPE) addr,
4946
                                   TT_NIL,
4947
                                   TT_NIL);
4948
          if (errno)
4949
            return 0;
4950
          QUIT;
4951
        }
4952
 
4953
      /* Copy appropriate bytes out of the buffer.  */
4954
      memcpy (myaddr,
4955
              (char *) buffer + (memaddr & (sizeof (TTRACE_XFER_TYPE) - 1)),
4956
              len);
4957
    }
4958
  return len;
4959
}
4960
 
4961
 
4962
static void
4963
udot_info (void)
4964
{
4965
  int udot_off;                 /* Offset into user struct */
4966
  int udot_val;                 /* Value from user struct at udot_off */
4967
  char mess[128];               /* For messages */
4968
 
4969
  if (!target_has_execution)
4970
    {
4971
      error ("The program is not being run.");
4972
    }
4973
 
4974
#if !defined (KERNEL_U_SIZE)
4975
 
4976
  /* Adding support for this command is easy.  Typically you just add a
4977
     routine, called "kernel_u_size" that returns the size of the user
4978
     struct, to the appropriate *-nat.c file and then add to the native
4979
     config file "#define KERNEL_U_SIZE kernel_u_size()" */
4980
  error ("Don't know how large ``struct user'' is in this version of gdb.");
4981
 
4982
#else
4983
 
4984
  for (udot_off = 0; udot_off < KERNEL_U_SIZE; udot_off += sizeof (udot_val))
4985
    {
4986
      if ((udot_off % 24) == 0)
4987
        {
4988
          if (udot_off > 0)
4989
            {
4990
              printf_filtered ("\n");
4991
            }
4992
          printf_filtered ("%04x:", udot_off);
4993
        }
4994
      udot_val = call_ttrace (TT_LWP_RUREGS,
4995
                              PIDGET (inferior_ptid),
4996
                              (TTRACE_ARG_TYPE) udot_off,
4997
                              TT_NIL,
4998
                              TT_NIL);
4999
      if (errno != 0)
5000
        {
5001
          sprintf (mess, "\nreading user struct at offset 0x%x", udot_off);
5002
          perror_with_name (mess);
5003
        }
5004
      /* Avoid using nonportable (?) "*" in print specs */
5005
      printf_filtered (sizeof (int) == 4 ? " 0x%08x" : " 0x%16x", udot_val);
5006
    }
5007
  printf_filtered ("\n");
5008
 
5009
#endif
5010
}
5011
#endif /* !defined (CHILD_XFER_MEMORY).  */
5012
 
5013
 
5014
/* TTrace version of "target_pid_to_exec_file"
5015
 */
5016
char *
5017
child_pid_to_exec_file (int tid)
5018
{
5019
  int tt_status;
5020
  static char exec_file_buffer[1024];
5021
  pid_t pid;
5022
  static struct pst_status buf;
5023
 
5024
  /* On various versions of hpux11, this may fail due to a supposed
5025
     kernel bug.  We have alternate methods to get this information
5026
     (ie pstat).  */
5027
  tt_status = call_ttrace (TT_PROC_GET_PATHNAME,
5028
                           tid,
5029
                           (uint64_t) exec_file_buffer,
5030
                           sizeof (exec_file_buffer) - 1,
5031
                           0);
5032
  if (tt_status >= 0)
5033
    return exec_file_buffer;
5034
 
5035
  /* Try to get process information via pstat and extract the filename
5036
     from the pst_cmd field within the pst_status structure.  */
5037
  if (pstat_getproc (&buf, sizeof (struct pst_status), 0, tid) != -1)
5038
    {
5039
      char *p = buf.pst_cmd;
5040
 
5041
      while (*p && *p != ' ')
5042
        p++;
5043
      *p = 0;
5044
 
5045
      return (buf.pst_cmd);
5046
    }
5047
 
5048
  return (NULL);
5049
}
5050
 
5051
void
5052
pre_fork_inferior (void)
5053
{
5054
  int status;
5055
 
5056
  status = pipe (startup_semaphore.parent_channel);
5057
  if (status < 0)
5058
    {
5059
      warning ("error getting parent pipe for startup semaphore");
5060
      return;
5061
    }
5062
 
5063
  status = pipe (startup_semaphore.child_channel);
5064
  if (status < 0)
5065
    {
5066
      warning ("error getting child pipe for startup semaphore");
5067
      return;
5068
    }
5069
}
5070
 
5071
/* Called via #define REQUIRE_ATTACH from inftarg.c,
5072
 * ultimately from "follow_inferior_fork" in infrun.c,
5073
 * itself called from "resume".
5074
 *
5075
 * This seems to be intended to attach after a fork or
5076
 * vfork, while "attach" is used to attach to a pid
5077
 * given by the user.  The check for an existing attach
5078
 * seems odd--it always fails in our test system.
5079
 */
5080
int
5081
hppa_require_attach (int pid)
5082
{
5083
  int tt_status;
5084
  CORE_ADDR pc;
5085
  CORE_ADDR pc_addr;
5086
  unsigned int regs_offset;
5087
  process_state_t old_process_state = process_state;
5088
 
5089
  /* Are we already attached?  There appears to be no explicit
5090
   * way to answer this via ttrace, so we try something which
5091
   * should be innocuous if we are attached.  If that fails,
5092
   * then we assume we're not attached, and so attempt to make
5093
   * it so.
5094
   */
5095
  errno = 0;
5096
  tt_status = call_real_ttrace (TT_PROC_STOP,
5097
                                pid,
5098
                                (lwpid_t) TT_NIL,
5099
                                (TTRACE_ARG_TYPE) TT_NIL,
5100
                                (TTRACE_ARG_TYPE) TT_NIL,
5101
                                TT_NIL);
5102
 
5103
  if (errno)
5104
    {
5105
      /* No change to process-state!
5106
       */
5107
      errno = 0;
5108
      pid = attach (pid);
5109
    }
5110
  else
5111
    {
5112
      /* If successful, the process is now stopped.  But if
5113
       * we're VFORKING, the parent is still running, so don't
5114
       * change the process state.
5115
       */
5116
      if (process_state != VFORKING)
5117
        process_state = STOPPED;
5118
 
5119
      /* If we were already attached, you'd think that we
5120
       * would need to start going again--but you'd be wrong,
5121
       * as the fork-following code is actually in the middle
5122
       * of the "resume" routine in in "infrun.c" and so
5123
       * will (almost) immediately do a resume.
5124
       *
5125
       * On the other hand, if we are VFORKING, which means
5126
       * that the child and the parent share a process for a
5127
       * while, we know that "resume" won't be resuming
5128
       * until the child EXEC event is seen.  But we still
5129
       * don't want to continue, as the event is already
5130
       * there waiting.
5131
       */
5132
      update_thread_state_after_attach (pid, DONT_ATTACH_CONTINUE);
5133
    }                           /* STOP succeeded */
5134
 
5135
  return pid;
5136
}
5137
 
5138
int
5139
hppa_require_detach (int pid, int signal)
5140
{
5141
  int tt_status;
5142
 
5143
  /* If signal is non-zero, we must pass the signal on to the active
5144
     thread prior to detaching.  We do this by continuing the threads
5145
     with the signal.
5146
   */
5147
  if (signal != 0)
5148
    {
5149
      errno = 0;
5150
      threads_continue_all_with_signals (pid, signal);
5151
    }
5152
 
5153
  errno = 0;
5154
  tt_status = call_ttrace (TT_PROC_DETACH,
5155
                           pid,
5156
                           TT_NIL,
5157
                           TT_NIL,
5158
                           TT_NIL);
5159
 
5160
  errno = 0;                     /* Ignore any errors. */
5161
 
5162
  /* process_state? */
5163
 
5164
  return pid;
5165
}
5166
 
5167
/* Given the starting address of a memory page, hash it to a bucket in
5168
   the memory page dictionary.
5169
 */
5170
static int
5171
get_dictionary_bucket_of_page (CORE_ADDR page_start)
5172
{
5173
  int hash;
5174
 
5175
  hash = (page_start / memory_page_dictionary.page_size);
5176
  hash = hash % MEMORY_PAGE_DICTIONARY_BUCKET_COUNT;
5177
 
5178
  return hash;
5179
}
5180
 
5181
 
5182
/* Given a memory page's starting address, get (i.e., find an existing
5183
   or create a new) dictionary entry for the page.  The page will be
5184
   write-protected when this function returns, but may have a reference
5185
   count of 0 (if the page was newly-added to the dictionary).
5186
 */
5187
static memory_page_t *
5188
get_dictionary_entry_of_page (int pid, CORE_ADDR page_start)
5189
{
5190
  int bucket;
5191
  memory_page_t *page = NULL;
5192
  memory_page_t *previous_page = NULL;
5193
 
5194
  /* We're going to be using the dictionary now, than-kew. */
5195
  require_memory_page_dictionary ();
5196
 
5197
  /* Try to find an existing dictionary entry for this page.  Hash
5198
     on the page's starting address.
5199
   */
5200
  bucket = get_dictionary_bucket_of_page (page_start);
5201
  page = &memory_page_dictionary.buckets[bucket];
5202
  while (page != NULL)
5203
    {
5204
      if (page->page_start == page_start)
5205
        break;
5206
      previous_page = page;
5207
      page = page->next;
5208
    }
5209
 
5210
  /* Did we find a dictionary entry for this page?  If not, then
5211
     add it to the dictionary now.
5212
   */
5213
  if (page == NULL)
5214
    {
5215
      /* Create a new entry. */
5216
      page = (memory_page_t *) xmalloc (sizeof (memory_page_t));
5217
      page->page_start = page_start;
5218
      page->reference_count = 0;
5219
      page->next = NULL;
5220
      page->previous = NULL;
5221
 
5222
      /* We'll write-protect the page now, if that's allowed. */
5223
      page->original_permissions = write_protect_page (pid, page_start);
5224
 
5225
      /* Add the new entry to the dictionary. */
5226
      page->previous = previous_page;
5227
      previous_page->next = page;
5228
 
5229
      memory_page_dictionary.page_count++;
5230
    }
5231
 
5232
  return page;
5233
}
5234
 
5235
 
5236
static void
5237
remove_dictionary_entry_of_page (int pid, memory_page_t *page)
5238
{
5239
  /* Restore the page's original permissions. */
5240
  unwrite_protect_page (pid, page->page_start, page->original_permissions);
5241
 
5242
  /* Kick the page out of the dictionary. */
5243
  if (page->previous != NULL)
5244
    page->previous->next = page->next;
5245
  if (page->next != NULL)
5246
    page->next->previous = page->previous;
5247
 
5248
  /* Just in case someone retains a handle to this after it's freed. */
5249
  page->page_start = (CORE_ADDR) 0;
5250
 
5251
  memory_page_dictionary.page_count--;
5252
 
5253
  xfree (page);
5254
}
5255
 
5256
 
5257
static void
5258
hppa_enable_syscall_events (int pid)
5259
{
5260
  int tt_status;
5261
  ttevent_t ttrace_events;
5262
 
5263
  /* Get the set of events that are currently enabled. */
5264
  tt_status = call_ttrace (TT_PROC_GET_EVENT_MASK,
5265
                           pid,
5266
                           (TTRACE_ARG_TYPE) & ttrace_events,
5267
                           (TTRACE_ARG_TYPE) sizeof (ttrace_events),
5268
                           TT_NIL);
5269
  if (errno)
5270
    perror_with_name ("ttrace");
5271
 
5272
  /* Add syscall events to that set. */
5273
  ttrace_events.tte_events |= TTEVT_SYSCALL_ENTRY;
5274
  ttrace_events.tte_events |= TTEVT_SYSCALL_RETURN;
5275
 
5276
  tt_status = call_ttrace (TT_PROC_SET_EVENT_MASK,
5277
                           pid,
5278
                           (TTRACE_ARG_TYPE) & ttrace_events,
5279
                           (TTRACE_ARG_TYPE) sizeof (ttrace_events),
5280
                           TT_NIL);
5281
  if (errno)
5282
    perror_with_name ("ttrace");
5283
}
5284
 
5285
 
5286
static void
5287
hppa_disable_syscall_events (int pid)
5288
{
5289
  int tt_status;
5290
  ttevent_t ttrace_events;
5291
 
5292
  /* Get the set of events that are currently enabled. */
5293
  tt_status = call_ttrace (TT_PROC_GET_EVENT_MASK,
5294
                           pid,
5295
                           (TTRACE_ARG_TYPE) & ttrace_events,
5296
                           (TTRACE_ARG_TYPE) sizeof (ttrace_events),
5297
                           TT_NIL);
5298
  if (errno)
5299
    perror_with_name ("ttrace");
5300
 
5301
  /* Remove syscall events from that set. */
5302
  ttrace_events.tte_events &= ~TTEVT_SYSCALL_ENTRY;
5303
  ttrace_events.tte_events &= ~TTEVT_SYSCALL_RETURN;
5304
 
5305
  tt_status = call_ttrace (TT_PROC_SET_EVENT_MASK,
5306
                           pid,
5307
                           (TTRACE_ARG_TYPE) & ttrace_events,
5308
                           (TTRACE_ARG_TYPE) sizeof (ttrace_events),
5309
                           TT_NIL);
5310
  if (errno)
5311
    perror_with_name ("ttrace");
5312
}
5313
 
5314
 
5315
/* The address range beginning with START and ending with START+LEN-1
5316
   (inclusive) is to be watched via page-protection by a new watchpoint.
5317
   Set protection for all pages that overlap that range.
5318
 
5319
   Note that our caller sets TYPE to:
5320
 
5321
   1 for a bp_read_watchpoint,
5322
   2 for a bp_access_watchpoint
5323
 
5324
   (Yes, this is intentionally (though lord only knows why) different
5325
   from the TYPE that is passed to hppa_remove_hw_watchpoint.)
5326
 */
5327
int
5328
hppa_insert_hw_watchpoint (int pid, CORE_ADDR start, LONGEST len, int type)
5329
{
5330
  CORE_ADDR page_start;
5331
  int dictionary_was_empty;
5332
  int page_size;
5333
  int page_id;
5334
  LONGEST range_size_in_pages;
5335
 
5336
  if (type != 0)
5337
    error ("read or access hardware watchpoints not supported on HP-UX");
5338
 
5339
  /* Examine all pages in the address range. */
5340
  require_memory_page_dictionary ();
5341
 
5342
  dictionary_was_empty = (memory_page_dictionary.page_count == (LONGEST) 0);
5343
 
5344
  page_size = memory_page_dictionary.page_size;
5345
  page_start = (start / page_size) * page_size;
5346
  range_size_in_pages = ((LONGEST) len + (LONGEST) page_size - 1) / (LONGEST) page_size;
5347
 
5348
  for (page_id = 0; page_id < range_size_in_pages; page_id++, page_start += page_size)
5349
    {
5350
      memory_page_t *page;
5351
 
5352
      /* This gets the page entered into the dictionary if it was
5353
         not already entered.
5354
       */
5355
      page = get_dictionary_entry_of_page (pid, page_start);
5356
      page->reference_count++;
5357
    }
5358
 
5359
  /* Our implementation depends on seeing calls to kernel code, for the
5360
     following reason.  Here we ask to be notified of syscalls.
5361
 
5362
     When a protected page is accessed by user code, HP-UX raises a SIGBUS.
5363
     Fine.
5364
 
5365
     But when kernel code accesses the page, it doesn't give a SIGBUS.
5366
     Rather, the system call that touched the page fails, with errno=EFAULT.
5367
     Not good for us.
5368
 
5369
     We could accomodate this "feature" by asking to be notified of syscall
5370
     entries & exits; upon getting an entry event, disabling page-protections;
5371
     upon getting an exit event, reenabling page-protections and then checking
5372
     if any watchpoints triggered.
5373
 
5374
     However, this turns out to be a real performance loser.  syscalls are
5375
     usually a frequent occurrence.  Having to unprotect-reprotect all watched
5376
     pages, and also to then read all watched memory locations and compare for
5377
     triggers, can be quite expensive.
5378
 
5379
     Instead, we'll only ask to be notified of syscall exits.  When we get
5380
     one, we'll check whether errno is set.  If not, or if it's not EFAULT,
5381
     we can just continue the inferior.
5382
 
5383
     If errno is set upon syscall exit to EFAULT, we must perform some fairly
5384
     hackish stuff to determine whether the failure really was due to a
5385
     page-protect trap on a watched location.
5386
   */
5387
  if (dictionary_was_empty)
5388
    hppa_enable_syscall_events (pid);
5389
 
5390
  return 1;
5391
}
5392
 
5393
 
5394
/* The address range beginning with START and ending with START+LEN-1
5395
   (inclusive) was being watched via page-protection by a watchpoint
5396
   which has been removed.  Remove protection for all pages that
5397
   overlap that range, which are not also being watched by other
5398
   watchpoints.
5399
 */
5400
int
5401
hppa_remove_hw_watchpoint (int pid, CORE_ADDR start, LONGEST len,
5402
                           enum bptype type)
5403
{
5404
  CORE_ADDR page_start;
5405
  int dictionary_is_empty;
5406
  int page_size;
5407
  int page_id;
5408
  LONGEST range_size_in_pages;
5409
 
5410
  if (type != 0)
5411
    error ("read or access hardware watchpoints not supported on HP-UX");
5412
 
5413
  /* Examine all pages in the address range. */
5414
  require_memory_page_dictionary ();
5415
 
5416
  page_size = memory_page_dictionary.page_size;
5417
  page_start = (start / page_size) * page_size;
5418
  range_size_in_pages = ((LONGEST) len + (LONGEST) page_size - 1) / (LONGEST) page_size;
5419
 
5420
  for (page_id = 0; page_id < range_size_in_pages; page_id++, page_start += page_size)
5421
    {
5422
      memory_page_t *page;
5423
 
5424
      page = get_dictionary_entry_of_page (pid, page_start);
5425
      page->reference_count--;
5426
 
5427
      /* Was this the last reference of this page?  If so, then we
5428
         must scrub the entry from the dictionary, and also restore
5429
         the page's original permissions.
5430
       */
5431
      if (page->reference_count == 0)
5432
        remove_dictionary_entry_of_page (pid, page);
5433
    }
5434
 
5435
  dictionary_is_empty = (memory_page_dictionary.page_count == (LONGEST) 0);
5436
 
5437
  /* If write protections are currently disallowed, then that implies that
5438
     wait_for_inferior believes that the inferior is within a system call.
5439
     Since we want to see both syscall entry and return, it's clearly not
5440
     good to disable syscall events in this state!
5441
 
5442
     ??rehrauer: Yeah, it'd be better if we had a specific flag that said,
5443
     "inferior is between syscall events now".  Oh well.
5444
   */
5445
  if (dictionary_is_empty && memory_page_dictionary.page_protections_allowed)
5446
    hppa_disable_syscall_events (pid);
5447
 
5448
  return 1;
5449
}
5450
 
5451
 
5452
/* Could we implement a watchpoint of this type via our available
5453
   hardware support?
5454
 
5455
   This query does not consider whether a particular address range
5456
   could be so watched, but just whether support is generally available
5457
   for such things.  See hppa_range_profitable_for_hw_watchpoint for a
5458
   query that answers whether a particular range should be watched via
5459
   hardware support.
5460
 */
5461
int
5462
hppa_can_use_hw_watchpoint (enum bptype type, int cnt, enum bptype ot)
5463
{
5464
  return (type == bp_hardware_watchpoint);
5465
}
5466
 
5467
 
5468
/* Assuming we could set a hardware watchpoint on this address, do
5469
   we think it would be profitable ("a good idea") to do so?  If not,
5470
   we can always set a regular (aka single-step & test) watchpoint
5471
   on the address...
5472
 */
5473
int
5474
hppa_range_profitable_for_hw_watchpoint (int pid, CORE_ADDR start, LONGEST len)
5475
{
5476
  int range_is_stack_based;
5477
  int range_is_accessible;
5478
  CORE_ADDR page_start;
5479
  int page_size;
5480
  int page;
5481
  LONGEST range_size_in_pages;
5482
 
5483
  /* ??rehrauer: For now, say that all addresses are potentially
5484
     profitable.  Possibly later we'll want to test the address
5485
     for "stackness"?
5486
   */
5487
  range_is_stack_based = 0;
5488
 
5489
  /* If any page in the range is inaccessible, then we cannot
5490
     really use hardware watchpointing, even though our client
5491
     thinks we can.  In that case, it's actually an error to
5492
     attempt to use hw watchpoints, so we'll tell our client
5493
     that the range is "unprofitable", and hope that they listen...
5494
   */
5495
  range_is_accessible = 1;      /* Until proven otherwise. */
5496
 
5497
  /* Examine all pages in the address range. */
5498
  errno = 0;
5499
  page_size = sysconf (_SC_PAGE_SIZE);
5500
 
5501
  /* If we can't determine page size, we're hosed.  Tell our
5502
     client it's unprofitable to use hw watchpoints for this
5503
     range.
5504
   */
5505
  if (errno || (page_size <= 0))
5506
    {
5507
      errno = 0;
5508
      return 0;
5509
    }
5510
 
5511
  page_start = (start / page_size) * page_size;
5512
  range_size_in_pages = len / (LONGEST) page_size;
5513
 
5514
  for (page = 0; page < range_size_in_pages; page++, page_start += page_size)
5515
    {
5516
      int tt_status;
5517
      int page_permissions;
5518
 
5519
      /* Is this page accessible? */
5520
      errno = 0;
5521
      tt_status = call_ttrace (TT_PROC_GET_MPROTECT,
5522
                               pid,
5523
                               (TTRACE_ARG_TYPE) page_start,
5524
                               TT_NIL,
5525
                               (TTRACE_ARG_TYPE) & page_permissions);
5526
      if (errno || (tt_status < 0))
5527
        {
5528
          errno = 0;
5529
          range_is_accessible = 0;
5530
          break;
5531
        }
5532
 
5533
      /* Yes, go for another... */
5534
    }
5535
 
5536
  return (!range_is_stack_based && range_is_accessible);
5537
}
5538
 
5539
 
5540
char *
5541
hppa_pid_or_tid_to_str (ptid_t ptid)
5542
{
5543
  static char buf[100];         /* Static because address returned. */
5544
  pid_t id = PIDGET (ptid);
5545
 
5546
  /* Does this appear to be a process?  If so, print it that way. */
5547
  if (is_process_id (id))
5548
    return child_pid_to_str (ptid);
5549
 
5550
  /* Else, print both the GDB thread number and the system thread id. */
5551
  sprintf (buf, "thread %d (", pid_to_thread_id (ptid));
5552
  strcat (buf, hppa_tid_to_str (ptid));
5553
  strcat (buf, ")\0");
5554
 
5555
  return buf;
5556
}
5557
 
5558
 
5559
/* If the current pid is not the pid this module reported
5560
 * from "ptrace_wait" with the most recent event, then the
5561
 * user has switched threads.
5562
 *
5563
 * If the last reported event was a breakpoint, then return
5564
 * the old thread id, else return 0.
5565
 */
5566
pid_t
5567
hppa_switched_threads (pid_t gdb_pid)
5568
{
5569
  if (gdb_pid == old_gdb_pid)
5570
    {
5571
      /*
5572
       * Core gdb is working with the same pid that it
5573
       * was before we reported the last event.  This
5574
       * is ok: e.g. we reported hitting a thread-specific
5575
       * breakpoint, but we were reporting the wrong
5576
       * thread, so the core just ignored the event.
5577
       *
5578
       * No thread switch has happened.
5579
       */
5580
      return (pid_t) 0;
5581
    }
5582
  else if (gdb_pid == reported_pid)
5583
    {
5584
      /*
5585
       * Core gdb is working with the pid we reported, so
5586
       * any continue or step will be able to figure out
5587
       * that it needs to step over any hit breakpoints
5588
       * without our (i.e. PREPARE_TO_PROCEED's) help.
5589
       */
5590
      return (pid_t) 0;
5591
    }
5592
  else if (!reported_bpt)
5593
    {
5594
      /*
5595
       * The core switched, but we didn't just report a
5596
       * breakpoint, so there's no just-hit breakpoint
5597
       * instruction at "reported_pid"'s PC, and thus there
5598
       * is no need to step over it.
5599
       */
5600
      return (pid_t) 0;
5601
    }
5602
  else
5603
    {
5604
      /* There's been a real switch, and we reported
5605
       * a hit breakpoint.  Let "hppa_prepare_to_proceed"
5606
       * know, so it can see whether the breakpoint is
5607
       * still active.
5608
       */
5609
      return reported_pid;
5610
    }
5611
 
5612
  /* Keep compiler happy with an obvious return at the end.
5613
   */
5614
  return (pid_t) 0;
5615
}
5616
 
5617
void
5618
hppa_ensure_vforking_parent_remains_stopped (int pid)
5619
{
5620
  /* Nothing to do when using ttrace.  Only the ptrace-based implementation
5621
     must do real work.
5622
   */
5623
}
5624
 
5625
 
5626
int
5627
hppa_resume_execd_vforking_child_to_get_parent_vfork (void)
5628
{
5629
  return 0;                      /* No, the parent vfork is available now. */
5630
}
5631
 
5632
 
5633
/* Write a register as a 64bit value.  This may be necessary if the
5634
   native OS is too braindamaged to allow some (or all) registers to
5635
   be written in 32bit hunks such as hpux11 and the PC queue registers.
5636
 
5637
   This is horribly gross and disgusting.  */
5638
 
5639
int
5640
ttrace_write_reg_64 (int gdb_tid, CORE_ADDR dest_addr, CORE_ADDR src_addr)
5641
{
5642
  pid_t         pid;
5643
  lwpid_t       tid;
5644
  int           tt_status;
5645
 
5646
  tid = map_from_gdb_tid (gdb_tid);
5647
  pid = get_pid_for (tid);
5648
 
5649
  errno = 0;
5650
  tt_status = ttrace (TT_LWP_WUREGS,
5651
                      pid,
5652
                      tid,
5653
                      (TTRACE_ARG_TYPE) dest_addr,
5654
                      8,
5655
                      (TTRACE_ARG_TYPE) src_addr );
5656
 
5657
#ifdef THREAD_DEBUG
5658
  if (errno)
5659
    {
5660
      /* Don't bother for a known benign error: if you ask for the
5661
         first thread state, but there is only one thread and it's
5662
         not stopped, ttrace complains.
5663
 
5664
         We have this inside the #ifdef because our caller will do
5665
         this check for real.  */
5666
      if( request != TT_PROC_GET_FIRST_LWP_STATE
5667
          ||  errno   != EPROTO )
5668
        {
5669
          if( debug_on )
5670
            printf( "TT fail for %s, with pid %d, tid %d, status %d \n",
5671
                    get_printable_name_of_ttrace_request (TT_LWP_WUREGS),
5672
                    pid, tid, tt_status );
5673
        }
5674
    }
5675
#endif
5676
 
5677
  return tt_status;
5678
}
5679
 
5680
void
5681
_initialize_infttrace (void)
5682
{
5683
  /* Initialize the ttrace-based hardware watchpoint implementation. */
5684
  memory_page_dictionary.page_count = (LONGEST) - 1;
5685
  memory_page_dictionary.page_protections_allowed = 1;
5686
 
5687
  errno = 0;
5688
  memory_page_dictionary.page_size = sysconf (_SC_PAGE_SIZE);
5689
 
5690
  /* We do a lot of casts from pointers to TTRACE_ARG_TYPE; make sure
5691
     this is okay.  */
5692
  if (sizeof (TTRACE_ARG_TYPE) < sizeof (void *))
5693
    internal_error (__FILE__, __LINE__, "failed internal consistency check");
5694
 
5695
  if (errno || (memory_page_dictionary.page_size <= 0))
5696
    perror_with_name ("sysconf");
5697
}

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