OpenCores
URL https://opencores.org/ocsvn/or1k/or1k/trunk

Subversion Repositories or1k

[/] [or1k/] [trunk/] [insight/] [gdb/] [lin-thread.c] - Blame information for rev 1765

Details | Compare with Previous | View Log

Line No. Rev Author Line
1 578 markom
/* Multi-threaded debugging support for the thread_db interface,
2
   used on operating systems such as Solaris and Linux.
3
   Copyright 1999, 2000, 2001 Free Software Foundation, Inc.
4
 
5
   This file is part of GDB.
6
 
7
   This program is free software; you can redistribute it and/or modify
8
   it under the terms of the GNU General Public License as published by
9
   the Free Software Foundation; either version 2 of the License, or
10
   (at your option) any later version.
11
 
12
   This program is distributed in the hope that it will be useful,
13
   but WITHOUT ANY WARRANTY; without even the implied warranty of
14
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
15
   GNU General Public License for more details.
16
 
17
   You should have received a copy of the GNU General Public License
18
   along with this program; if not, write to the Free Software
19
   Foundation, Inc., 59 Temple Place - Suite 330,
20
   Boston, MA 02111-1307, USA.  */
21
 
22
/* This module implements a thread_stratum target that sits on top of
23
   a normal process_stratum target (such as procfs or ptrace).  The
24
   process_stratum target must install this thread_stratum target when
25
   it detects the presence of the thread_db shared library.
26
 
27
   This module will then use the thread_db API to add thread-awareness
28
   to the functionality provided by the process_stratum target (or in
29
   some cases, to add user-level thread awareness on top of the
30
   kernel-level thread awareness that is already provided by the
31
   process_stratum target).
32
 
33
   Solaris threads (for instance) are a multi-level thread implementation;
34
   the kernel provides a Light Weight Process (LWP) which the procfs
35
   process_stratum module is aware of.  This module must then mediate
36
   the relationship between kernel LWP threads and user (eg. posix)
37
   threads.
38
 
39
   Linux threads are likely to be different -- but the thread_db
40
   library API should make the difference largely transparent to GDB.
41
 
42
   */
43
 
44
/* The thread_db API provides a number of functions that give the caller
45
   access to the inner workings of the child process's thread library.
46
   We will be using the following (others may be added):
47
 
48
   td_thr_validate              Confirm valid "live" thread
49
   td_thr_get_info              Get info about a thread
50
   td_thr_getgregs              Get thread's general registers
51
   td_thr_getfpregs             Get thread's floating point registers
52
   td_thr_setgregs              Set thread's general registers
53
   td_thr_setfpregs             Set thread's floating point registers
54
   td_ta_map_id2thr             Get thread handle from thread id
55
   td_ta_map_lwp2thr            Get thread handle from LWP id
56
   td_ta_thr_iter               Iterate over all threads (with callback)
57
 
58
   In return, the debugger has to provide certain services to the
59
   thread_db library.  Some of these aren't actually required to do
60
   anything in practice.  For instance, the thread_db expects to be
61
   able to stop the child process and start it again: but in our
62
   context, the child process will always be stopped already when we
63
   invoke the thread_db library, so the functions that we provide for
64
   the library to stop and start the child process are no-ops.
65
 
66
   Here is the list of functions which we export to the thread_db
67
   library, divided into no-op functions vs. functions that actually
68
   have to do something:
69
 
70
   No-op functions:
71
 
72
   ps_pstop                     Stop the child process
73
   ps_pcontinue                 Continue the child process
74
   ps_lstop                     Stop a specific LWP (kernel thread)
75
   ps_lcontinue                 Continue an LWP
76
   ps_lgetxregsize              Get size of LWP's xregs (sparc)
77
   ps_lgetxregs                 Get LWP's xregs (sparc)
78
   ps_lsetxregs                 Set LWP's xregs (sparc)
79
 
80
   Functions that have to do useful work:
81
 
82
   ps_pglobal_lookup            Get the address of a global symbol
83
   ps_pdread                    Read memory, data segment
84
   ps_ptread                    Read memory, text segment
85
   ps_pdwrite                   Write memory, data segment
86
   ps_ptwrite                   Write memory, text segment
87
   ps_lgetregs                  Get LWP's general registers
88
   ps_lgetfpregs                Get LWP's floating point registers
89
   ps_lsetregs                  Set LWP's general registers
90
   ps_lsetfpregs                Set LWP's floating point registers
91
   ps_lgetLDT                   Get LWP's Local Descriptor Table (x86)
92
 
93
   Thus, if we ask the thread_db library to give us the general registers
94
   for user thread X, thread_db may figure out that user thread X is
95
   actually mapped onto kernel thread Y.  Thread_db does not know how
96
   to obtain the registers for kernel thread Y, but GDB does, so thread_db
97
   turns the request right back to us via the ps_lgetregs callback.  */
98
 
99
#include "defs.h"
100
#include "gdbthread.h"
101
#include "target.h"
102
#include "inferior.h"
103
#include "gdbcmd.h"
104
#include "regcache.h"
105
 
106
#include "gdb_wait.h"
107
 
108
#include <time.h>
109
 
110
#if defined(USE_PROC_FS) || defined(HAVE_GREGSET_T)
111
#include <sys/procfs.h>
112
#endif
113
 
114
#include "gdb_proc_service.h"
115
 
116
#if defined HAVE_STDINT_H       /* Pre-5.2 systems don't have this header */
117
#if defined (HAVE_THREAD_DB_H)
118
#include <thread_db.h>          /* defines outgoing API (td_thr_* calls) */
119
#else
120
#include "gdb_thread_db.h"
121
#endif
122
 
123
#include <dlfcn.h>              /* dynamic library interface */
124
 
125
/* Prototypes for supply_gregset etc. */
126
#include "gregset.h"
127
 
128
/* Macros for superimposing PID and TID into inferior_ptid.  */
129
#define GET_PID(ptid)           ptid_get_pid (ptid)
130
#define GET_LWP(ptid)           ptid_get_lwp (ptid)
131
#define GET_THREAD(ptid)        ptid_get_tid (ptid)
132
 
133
#define is_lwp(ptid)            (GET_LWP (ptid) != 0)
134
#define is_thread(ptid)         (GET_THREAD (ptid) != 0)
135
 
136
#define BUILD_LWP(lwp, pid)     ptid_build (pid, lwp, 0)
137
#define BUILD_THREAD(tid, pid)  ptid_build (pid, 0, tid)
138
 
139
/* From linux-thread.c.  FIXME: These should go in a separate header
140
   file, but I'm told that the life expectancy of lin-thread.c and
141
   linux-thread.c isn't very long... */
142
 
143
extern int linux_child_wait (int, int *, int *);
144
extern void check_all_signal_numbers (void);
145
extern void linuxthreads_discard_global_state (void);
146
extern void attach_thread (int);
147
 
148
/*
149
 * target_beneath is a pointer to the target_ops underlying this one.
150
 */
151
 
152
static struct target_ops *target_beneath;
153
 
154
 
155
/*
156
 * target vector defined in this module:
157
 */
158
 
159
static struct target_ops thread_db_ops;
160
 
161
/*
162
 * Typedefs required to resolve differences between the thread_db
163
 * and proc_service API defined on different versions of Solaris:
164
 */
165
 
166
#if defined(PROC_SERVICE_IS_OLD)
167
typedef const struct ps_prochandle *gdb_ps_prochandle_t;
168
typedef char *gdb_ps_read_buf_t;
169
typedef char *gdb_ps_write_buf_t;
170
typedef int gdb_ps_size_t;
171
#else
172
typedef struct ps_prochandle *gdb_ps_prochandle_t;
173
typedef void *gdb_ps_read_buf_t;
174
typedef const void *gdb_ps_write_buf_t;
175
typedef size_t gdb_ps_size_t;
176
#endif
177
 
178
/*
179
 * proc_service callback functions, called by thread_db.
180
 */
181
 
182
ps_err_e
183
ps_pstop (gdb_ps_prochandle_t ph)               /* Process stop */
184
{
185
  return PS_OK;
186
}
187
 
188
ps_err_e
189
ps_pcontinue (gdb_ps_prochandle_t ph)           /* Process continue */
190
{
191
  return PS_OK;
192
}
193
 
194
ps_err_e
195
ps_lstop (gdb_ps_prochandle_t ph,               /* LWP stop */
196
          lwpid_t lwpid)
197
{
198
  return PS_OK;
199
}
200
 
201
ps_err_e
202
ps_lcontinue (gdb_ps_prochandle_t ph,           /* LWP continue */
203
              lwpid_t lwpid)
204
{
205
  return PS_OK;
206
}
207
 
208
ps_err_e
209
ps_lgetxregsize (gdb_ps_prochandle_t ph,        /* Get XREG size */
210
                 lwpid_t lwpid,
211
                 int *xregsize)
212
{
213
  return PS_OK;
214
}
215
 
216
ps_err_e
217
ps_lgetxregs (gdb_ps_prochandle_t ph,           /* Get XREGS */
218
              lwpid_t lwpid,
219
              caddr_t xregset)
220
{
221
  return PS_OK;
222
}
223
 
224
ps_err_e
225
ps_lsetxregs (gdb_ps_prochandle_t ph,           /* Set XREGS */
226
              lwpid_t lwpid,
227
              caddr_t xregset)
228
{
229
  return PS_OK;
230
}
231
 
232
void
233
ps_plog (const char *fmt, ...)
234
{
235
  va_list args;
236
 
237
  va_start (args, fmt);
238
  vfprintf_filtered (gdb_stderr, fmt, args);
239
}
240
 
241
/* Look up a symbol in GDB's global symbol table.
242
   Return the symbol's address.
243
   FIXME: it would be more correct to look up the symbol in the context
244
   of the LD_OBJECT_NAME provided.  However we're probably fairly safe
245
   as long as there aren't name conflicts with other libraries.  */
246
 
247
ps_err_e
248
ps_pglobal_lookup (gdb_ps_prochandle_t ph,
249
                   const char *ld_object_name,  /* the library name */
250
                   const char *ld_symbol_name,  /* the symbol name */
251
                   paddr_t    *ld_symbol_addr)  /* return the symbol addr */
252
{
253
  struct minimal_symbol *ms;
254
 
255
  ms = lookup_minimal_symbol (ld_symbol_name, NULL, NULL);
256
 
257
  if (!ms)
258
    return PS_NOSYM;
259
 
260
  *ld_symbol_addr = SYMBOL_VALUE_ADDRESS (ms);
261
 
262
  return PS_OK;
263
}
264
 
265
/* Worker function for all memory reads and writes: */
266
static ps_err_e rw_common (const struct ps_prochandle *ph,
267
                           paddr_t addr,
268
                           char *buf,
269
                           int size,
270
                           int write_p);
271
 
272
/* target_xfer_memory direction consts */
273
enum {PS_READ = 0, PS_WRITE = 1};
274
 
275
ps_err_e
276
ps_pdread (gdb_ps_prochandle_t ph,      /* read from data segment */
277
           paddr_t             addr,
278
           gdb_ps_read_buf_t   buf,
279
           gdb_ps_size_t       size)
280
{
281
  return rw_common (ph, addr, buf, size, PS_READ);
282
}
283
 
284
ps_err_e
285
ps_pdwrite (gdb_ps_prochandle_t ph,     /* write to data segment */
286
            paddr_t             addr,
287
            gdb_ps_write_buf_t  buf,
288
            gdb_ps_size_t       size)
289
{
290
  return rw_common (ph, addr, (char *) buf, size, PS_WRITE);
291
}
292
 
293
ps_err_e
294
ps_ptread (gdb_ps_prochandle_t ph,      /* read from text segment */
295
           paddr_t             addr,
296
           gdb_ps_read_buf_t   buf,
297
           gdb_ps_size_t       size)
298
{
299
  return rw_common (ph, addr, buf, size, PS_READ);
300
}
301
 
302
ps_err_e
303
ps_ptwrite (gdb_ps_prochandle_t ph,     /* write to text segment */
304
            paddr_t             addr,
305
            gdb_ps_write_buf_t  buf,
306
            gdb_ps_size_t       size)
307
{
308
  return rw_common (ph, addr, (char *) buf, size, PS_WRITE);
309
}
310
 
311
static char *thr_err_string   (td_err_e);
312
static char *thr_state_string (td_thr_state_e);
313
 
314
struct ps_prochandle main_prochandle;
315
td_thragent_t *      main_threadagent;
316
 
317
/*
318
 * Common proc_service routine for reading and writing memory.
319
 */
320
 
321
/* FIXME: once we've munged the inferior_ptid, why can't we
322
   simply call target_read/write_memory and return?  */
323
 
324
static ps_err_e
325
rw_common (const struct ps_prochandle *ph,
326
           paddr_t addr,
327
           char   *buf,
328
           int     size,
329
           int     write_p)
330
{
331
  struct cleanup *old_chain = save_inferior_ptid ();
332
  int to_do = size;
333
  int done  = 0;
334
 
335
  inferior_ptid = pid_to_ptid (main_prochandle.pid);
336
 
337
  while (to_do > 0)
338
    {
339
      done = current_target.to_xfer_memory (addr, buf, size, write_p,
340
                                            &current_target);
341
      if (done <= 0)
342
        {
343
          if (write_p == PS_READ)
344
            print_sys_errmsg ("rw_common (): read", errno);
345
          else
346
            print_sys_errmsg ("rw_common (): write", errno);
347
 
348
          return PS_ERR;
349
        }
350
      to_do -= done;
351
      buf   += done;
352
    }
353
  do_cleanups (old_chain);
354
  return PS_OK;
355
}
356
 
357
/* Cleanup functions used by the register callbacks
358
   (which have to manipulate the global inferior_ptid).  */
359
 
360
ps_err_e
361
ps_lgetregs (gdb_ps_prochandle_t ph,            /* Get LWP general regs */
362
             lwpid_t     lwpid,
363
             prgregset_t gregset)
364
{
365
  struct cleanup *old_chain = save_inferior_ptid ();
366
 
367
  inferior_ptid = BUILD_LWP (lwpid, main_prochandle.pid);
368
  current_target.to_fetch_registers (-1);
369
 
370
  fill_gregset ((gdb_gregset_t *) gregset, -1);
371
  do_cleanups (old_chain);
372
 
373
  return PS_OK;
374
}
375
 
376
ps_err_e
377
ps_lsetregs (gdb_ps_prochandle_t ph,            /* Set LWP general regs */
378
             lwpid_t           lwpid,
379
             const prgregset_t gregset)
380
{
381
  struct cleanup *old_chain = save_inferior_ptid ();
382
 
383
  inferior_ptid = BUILD_LWP (lwpid, main_prochandle.pid);
384
  supply_gregset ((gdb_gregset_t *) gregset);
385
  current_target.to_store_registers (-1);
386
  do_cleanups (old_chain);
387
  return PS_OK;
388
}
389
 
390
ps_err_e
391
ps_lgetfpregs (gdb_ps_prochandle_t ph,          /* Get LWP float regs */
392
               lwpid_t       lwpid,
393
               gdb_prfpregset_t *fpregset)
394
{
395
  struct cleanup *old_chain = save_inferior_ptid ();
396
 
397
  inferior_ptid = BUILD_LWP (lwpid, main_prochandle.pid);
398
  current_target.to_fetch_registers (-1);
399
  fill_fpregset (fpregset, -1);
400
  do_cleanups (old_chain);
401
  return PS_OK;
402
}
403
 
404
ps_err_e
405
ps_lsetfpregs (gdb_ps_prochandle_t ph,          /* Set LWP float regs */
406
               lwpid_t             lwpid,
407
               const gdb_prfpregset_t *fpregset)
408
{
409
  struct cleanup *old_chain = save_inferior_ptid ();
410
 
411
  inferior_ptid = BUILD_LWP (lwpid, main_prochandle.pid);
412
  supply_fpregset (fpregset);
413
  current_target.to_store_registers (-1);
414
  do_cleanups (old_chain);
415
  return PS_OK;
416
}
417
 
418
/*
419
 * ps_getpid
420
 *
421
 * return the main pid for the child process
422
 * (special for Linux -- not used on Solaris)
423
 */
424
 
425
pid_t
426
ps_getpid (gdb_ps_prochandle_t ph)
427
{
428
  return ph->pid;
429
}
430
 
431
#ifdef TM_I386SOL2_H
432
 
433
/* Reads the local descriptor table of a LWP.  */
434
 
435
ps_err_e
436
ps_lgetLDT (gdb_ps_prochandle_t ph, lwpid_t lwpid,
437
            struct ssd *pldt)
438
{
439
  /* NOTE: only used on Solaris, therefore OK to refer to procfs.c */
440
  extern struct ssd *procfs_find_LDT_entry (int);
441
  struct ssd *ret;
442
 
443
  ret = procfs_find_LDT_entry (BUILD_LWP (lwpid,
444
                                          PIDGET (main_prochandle.pid)));
445
  if (ret)
446
    {
447
      memcpy (pldt, ret, sizeof (struct ssd));
448
      return PS_OK;
449
    }
450
  else  /* LDT not found. */
451
    return PS_ERR;
452
}
453
#endif /* TM_I386SOL2_H */
454
 
455
/*
456
 * Pointers to thread_db functions:
457
 *
458
 * These are a dynamic library mechanism.
459
 * The dlfcn.h interface will be used to initialize these
460
 * so that they point to the appropriate functions in the
461
 * thread_db dynamic library.  This is done dynamically
462
 * so that GDB can still run on systems that lack thread_db.
463
 */
464
 
465
static td_err_e (*p_td_init)              (void);
466
 
467
static td_err_e (*p_td_ta_new)            (const struct ps_prochandle *ph_p,
468
                                           td_thragent_t **ta_pp);
469
 
470
static td_err_e (*p_td_ta_delete)         (td_thragent_t *ta_p);
471
 
472
static td_err_e (*p_td_ta_get_nthreads)   (const td_thragent_t *ta_p,
473
                                           int *nthread_p);
474
 
475
 
476
static td_err_e (*p_td_ta_thr_iter)       (const td_thragent_t *ta_p,
477
                                           td_thr_iter_f *cb,
478
                                           void *cbdata_p,
479
                                           td_thr_state_e state,
480
                                           int ti_pri,
481
                                           sigset_t *ti_sigmask_p,
482
                                           unsigned ti_user_flags);
483
 
484
static td_err_e (*p_td_ta_event_addr)     (const td_thragent_t *ta_p,
485
                                           u_long event,
486
                                           td_notify_t *notify_p);
487
 
488
static td_err_e (*p_td_ta_event_getmsg)   (const td_thragent_t *ta_p,
489
                                           td_event_msg_t *msg);
490
 
491
static td_err_e (*p_td_ta_set_event)      (const td_thragent_t *ta_p,
492
                                           td_thr_events_t *events);
493
 
494
static td_err_e (*p_td_thr_validate)      (const td_thrhandle_t *th_p);
495
 
496
static td_err_e (*p_td_thr_event_enable)  (const td_thrhandle_t *th_p,
497
                                           int on_off);
498
 
499
static td_err_e (*p_td_thr_get_info)      (const td_thrhandle_t *th_p,
500
                                           td_thrinfo_t *ti_p);
501
 
502
static td_err_e (*p_td_thr_getgregs)      (const td_thrhandle_t *th_p,
503
                                           prgregset_t regset);
504
 
505
static td_err_e (*p_td_thr_setgregs)      (const td_thrhandle_t *th_p,
506
                                           const prgregset_t regset);
507
 
508
static td_err_e (*p_td_thr_getfpregs)     (const td_thrhandle_t *th_p,
509
                                           gdb_prfpregset_t *fpregset);
510
 
511
static td_err_e (*p_td_thr_setfpregs)     (const td_thrhandle_t *th_p,
512
                                           const gdb_prfpregset_t *fpregset);
513
 
514
static td_err_e (*p_td_ta_map_id2thr)     (const td_thragent_t *ta_p,
515
                                           thread_t tid,
516
                                           td_thrhandle_t *th_p);
517
 
518
static td_err_e (*p_td_ta_map_lwp2thr)    (const td_thragent_t *ta_p,
519
                                           lwpid_t lwpid,
520
                                           td_thrhandle_t *th_p);
521
 
522
/*
523
 * API and target vector initialization function: thread_db_initialize.
524
 *
525
 * NOTE: this function is deliberately NOT named with the GDB convention
526
 * of module initializer function names that begin with "_initialize".
527
 * This module is NOT intended to be auto-initialized at GDB startup.
528
 * Rather, it will only be initialized when a multi-threaded child
529
 * process is detected.
530
 *
531
 */
532
 
533
/*
534
 * Initializer for thread_db library interface.
535
 * This function does the dynamic library stuff (dlopen, dlsym),
536
 * and then calls the thread_db library's one-time initializer
537
 * function (td_init).  If everything succeeds, this function
538
 * returns true; otherwise it returns false, and this module
539
 * cannot be used.
540
 */
541
 
542
static int
543
init_thread_db_library (void)
544
{
545
  void *dlhandle;
546
  td_err_e ret;
547
 
548
  /* Open a handle to the "thread_db" dynamic library.  */
549
  if ((dlhandle = dlopen ("libthread_db.so.1", RTLD_NOW)) == NULL)
550
    return 0;                    /* fail */
551
 
552
  /* Initialize pointers to the dynamic library functions we will use.
553
   * Note that we are not calling the functions here -- we are only
554
   * establishing pointers to them.
555
   */
556
 
557
  /* td_init: initialize thread_db library. */
558
  if ((p_td_init = dlsym (dlhandle, "td_init")) == NULL)
559
    return 0;                    /* fail */
560
  /* td_ta_new: register a target process with thread_db.  */
561
  if ((p_td_ta_new = dlsym (dlhandle, "td_ta_new")) == NULL)
562
    return 0;                    /* fail */
563
  /* td_ta_delete: un-register a target process with thread_db.  */
564
  if ((p_td_ta_delete = dlsym (dlhandle, "td_ta_delete")) == NULL)
565
    return 0;                    /* fail */
566
 
567
  /* td_ta_map_id2thr: get thread handle from thread id.  */
568
  if ((p_td_ta_map_id2thr = dlsym (dlhandle, "td_ta_map_id2thr")) == NULL)
569
    return 0;                    /* fail */
570
  /* td_ta_map_lwp2thr: get thread handle from lwp id.  */
571
  if ((p_td_ta_map_lwp2thr = dlsym (dlhandle, "td_ta_map_lwp2thr")) == NULL)
572
    return 0;                    /* fail */
573
  /* td_ta_get_nthreads: get number of threads in target process.  */
574
  if ((p_td_ta_get_nthreads = dlsym (dlhandle, "td_ta_get_nthreads")) == NULL)
575
    return 0;                    /* fail */
576
  /* td_ta_thr_iter: iterate over all thread handles.  */
577
  if ((p_td_ta_thr_iter = dlsym (dlhandle, "td_ta_thr_iter")) == NULL)
578
    return 0;                    /* fail */
579
 
580
  /* td_thr_validate: make sure a thread handle is real and alive.  */
581
  if ((p_td_thr_validate = dlsym (dlhandle, "td_thr_validate")) == NULL)
582
    return 0;                    /* fail */
583
  /* td_thr_get_info: get a bunch of info about a thread.  */
584
  if ((p_td_thr_get_info = dlsym (dlhandle, "td_thr_get_info")) == NULL)
585
    return 0;                    /* fail */
586
  /* td_thr_getgregs: get general registers for thread.  */
587
  if ((p_td_thr_getgregs = dlsym (dlhandle, "td_thr_getgregs")) == NULL)
588
    return 0;                    /* fail */
589
  /* td_thr_setgregs: set general registers for thread.  */
590
  if ((p_td_thr_setgregs = dlsym (dlhandle, "td_thr_setgregs")) == NULL)
591
    return 0;                    /* fail */
592
  /* td_thr_getfpregs: get floating point registers for thread.  */
593
  if ((p_td_thr_getfpregs = dlsym (dlhandle, "td_thr_getfpregs")) == NULL)
594
    return 0;                    /* fail */
595
  /* td_thr_setfpregs: set floating point registers for thread.  */
596
  if ((p_td_thr_setfpregs = dlsym (dlhandle, "td_thr_setfpregs")) == NULL)
597
    return 0;                    /* fail */
598
 
599
  ret = p_td_init ();
600
  if (ret != TD_OK)
601
    {
602
      warning ("init_thread_db: td_init: %s", thr_err_string (ret));
603
      return 0;
604
    }
605
 
606
  /* Optional functions:
607
     We can still debug even if the following functions are not found.  */
608
 
609
  /* td_ta_event_addr: get the breakpoint address for specified event.  */
610
  p_td_ta_event_addr = dlsym (dlhandle, "td_ta_event_addr");
611
 
612
  /* td_ta_event_getmsg: get the next event message for the process.  */
613
  p_td_ta_event_getmsg = dlsym (dlhandle, "td_ta_event_getmsg");
614
 
615
  /* td_ta_set_event: request notification of an event.  */
616
  p_td_ta_set_event = dlsym (dlhandle, "td_ta_set_event");
617
 
618
  /* td_thr_event_enable: enable event reporting in a thread.  */
619
  p_td_thr_event_enable = dlsym (dlhandle, "td_thr_event_enable");
620
 
621
  return 1;                     /* success */
622
}
623
 
624
/*
625
 * Local utility functions:
626
 */
627
 
628
/*
629
 
630
   LOCAL FUNCTION
631
 
632
   thr_err_string - Convert a thread_db error code to a string
633
 
634
   SYNOPSIS
635
 
636
   char * thr_err_string (errcode)
637
 
638
   DESCRIPTION
639
 
640
   Return a string description of the thread_db errcode.  If errcode
641
   is unknown, then return an <unknown> message.
642
 
643
 */
644
 
645
static char *
646
thr_err_string (td_err_e errcode)
647
{
648
  static char buf[50];
649
 
650
  switch (errcode) {
651
  case TD_OK:           return "generic 'call succeeded'";
652
  case TD_ERR:          return "generic error";
653
  case TD_NOTHR:        return "no thread to satisfy query";
654
  case TD_NOSV:         return "no sync handle to satisfy query";
655
  case TD_NOLWP:        return "no lwp to satisfy query";
656
  case TD_BADPH:        return "invalid process handle";
657
  case TD_BADTH:        return "invalid thread handle";
658
  case TD_BADSH:        return "invalid synchronization handle";
659
  case TD_BADTA:        return "invalid thread agent";
660
  case TD_BADKEY:       return "invalid key";
661
  case TD_NOMSG:        return "no event message for getmsg";
662
  case TD_NOFPREGS:     return "FPU register set not available";
663
  case TD_NOLIBTHREAD:  return "application not linked with libthread";
664
  case TD_NOEVENT:      return "requested event is not supported";
665
  case TD_NOCAPAB:      return "capability not available";
666
  case TD_DBERR:        return "debugger service failed";
667
  case TD_NOAPLIC:      return "operation not applicable to";
668
  case TD_NOTSD:        return "no thread-specific data for this thread";
669
  case TD_MALLOC:       return "malloc failed";
670
  case TD_PARTIALREG:   return "only part of register set was written/read";
671
  case TD_NOXREGS:      return "X register set not available for this thread";
672
  default:
673
    sprintf (buf, "unknown thread_db error '%d'", errcode);
674
    return buf;
675
  }
676
}
677
 
678
/*
679
 
680
   LOCAL FUNCTION
681
 
682
   thr_state_string - Convert a thread_db state code to a string
683
 
684
   SYNOPSIS
685
 
686
   char *thr_state_string (statecode)
687
 
688
   DESCRIPTION
689
 
690
   Return the thread_db state string associated with statecode.
691
   If statecode is unknown, then return an <unknown> message.
692
 
693
 */
694
 
695
static char *
696
thr_state_string (td_thr_state_e statecode)
697
{
698
  static char buf[50];
699
 
700
  switch (statecode) {
701
  case TD_THR_STOPPED:          return "stopped by debugger";
702
  case TD_THR_RUN:              return "runnable";
703
  case TD_THR_ACTIVE:           return "active";
704
  case TD_THR_ZOMBIE:           return "zombie";
705
  case TD_THR_SLEEP:            return "sleeping";
706
  case TD_THR_STOPPED_ASLEEP:   return "stopped by debugger AND blocked";
707
  default:
708
    sprintf (buf, "unknown thread_db state %d", statecode);
709
    return buf;
710
  }
711
}
712
 
713
/*
714
 * Local thread/event list.
715
 * This data structure will be used to hold a list of threads and
716
 * pending/deliverable events.
717
 */
718
 
719
typedef struct THREADINFO {
720
  thread_t       tid;           /* thread ID */
721
  pid_t          lid;           /* process/lwp ID */
722
  td_thr_state_e state;         /* thread state (a la thread_db) */
723
  td_thr_type_e  type;          /* thread type (a la thread_db) */
724
  int            pending;       /* true if holding a pending event */
725
  int            status;        /* wait status of any interesting event */
726
} threadinfo;
727
 
728
threadinfo * threadlist;
729
int threadlist_max = 0;          /* current size of table */
730
int threadlist_top = 0;          /* number of threads now in table */
731
#define THREADLIST_ALLOC 100    /* chunk size by which to expand table */
732
 
733
static threadinfo *
734
insert_thread (int tid, int lid, td_thr_state_e state, td_thr_type_e type)
735
{
736
  if (threadlist_top >= threadlist_max)
737
    {
738
      threadlist_max += THREADLIST_ALLOC;
739
      threadlist      = xrealloc (threadlist,
740
                                  threadlist_max * sizeof (threadinfo));
741
      if (threadlist == NULL)
742
        return NULL;
743
    }
744
  threadlist[threadlist_top].tid     = tid;
745
  threadlist[threadlist_top].lid     = lid;
746
  threadlist[threadlist_top].state   = state;
747
  threadlist[threadlist_top].type    = type;
748
  threadlist[threadlist_top].pending = 0;
749
  threadlist[threadlist_top].status  = 0;
750
 
751
  return &threadlist[threadlist_top++];
752
}
753
 
754
static void
755
empty_threadlist (void)
756
{
757
  threadlist_top = 0;
758
}
759
 
760
static threadinfo *
761
next_pending_event (void)
762
{
763
  int i;
764
 
765
  for (i = 0; i < threadlist_top; i++)
766
    if (threadlist[i].pending)
767
      return &threadlist[i];
768
 
769
  return NULL;
770
}
771
 
772
static void
773
threadlist_iter (int (*func) (), void *data, td_thr_state_e state,
774
                 td_thr_type_e type)
775
{
776
  int i;
777
 
778
  for (i = 0; i < threadlist_top; i++)
779
    if ((state == TD_THR_ANY_STATE || state == threadlist[i].state) &&
780
        (type  == TD_THR_ANY_TYPE  || type  == threadlist[i].type))
781
      if ((*func) (&threadlist[i], data) != 0)
782
        break;
783
 
784
  return;
785
}
786
 
787
/*
788
 * Global state
789
 *
790
 * Here we keep state information all collected in one place.
791
 */
792
 
793
/* This flag is set when we activate, so that we don't do it twice.
794
   Defined in linux-thread.c and used for inter-target syncronization.  */
795
extern int using_thread_db;
796
 
797
/* The process id for which we've stopped.
798
 * This is only set when we actually stop all threads.
799
 * Otherwise it's zero.
800
 */
801
static int event_pid;
802
 
803
/*
804
 * The process id for a new thread to which we've just attached.
805
 * This process needs special handling at resume time.
806
 */
807
static int attach_pid;
808
 
809
 
810
/*
811
 * thread_db event handling:
812
 *
813
 * The mechanism for event notification via the thread_db API.
814
 * These events are implemented as breakpoints.  The thread_db
815
 * library gives us an address where we can set a breakpoint.
816
 * When the breakpoint is hit, it represents an event of interest
817
 * such as:
818
 *   Thread creation
819
 *   Thread death
820
 *   Thread reap
821
 */
822
 
823
/* Location of the thread creation event breakpoint.  The code at this
824
   location in the child process will be called by the pthread library
825
   whenever a new thread is created.  By setting a special breakpoint
826
   at this location, GDB can detect when a new thread is created.  We
827
   obtain this location via the td_ta_event_addr call.  */
828
 
829
static CORE_ADDR thread_creation_bkpt_address;
830
 
831
/* Location of the thread death event breakpoint.  The code at this
832
   location in the child process will be called by the pthread library
833
   whenever a thread is destroyed.  By setting a special breakpoint at
834
   this location, GDB can detect when a new thread is created.  We
835
   obtain this location via the td_ta_event_addr call.  */
836
 
837
static CORE_ADDR thread_death_bkpt_address;
838
 
839
/* This function handles the global parts of enabling thread events.
840
   The thread-specific enabling is handled per-thread elsewhere.  */
841
 
842
static void
843
enable_thread_event_reporting (td_thragent_t *ta)
844
{
845
  td_thr_events_t events;
846
  td_notify_t     notify;
847
  CORE_ADDR       addr;
848
 
849
  if (p_td_ta_set_event     == NULL ||
850
      p_td_ta_event_addr    == NULL ||
851
      p_td_ta_event_getmsg  == NULL ||
852
      p_td_thr_event_enable == NULL)
853
    return;     /* can't do thread event reporting without these funcs */
854
 
855
  /* set process wide mask saying which events we are interested in */
856
  td_event_emptyset (&events);
857
  td_event_addset (&events, TD_CREATE);
858
  td_event_addset (&events, TD_DEATH);
859
 
860
  if (p_td_ta_set_event (ta, &events) != TD_OK)
861
    {
862
      warning ("unable to set global thread event mask");
863
      return;
864
    }
865
 
866
  /* Delete previous thread event breakpoints, if any.  */
867
  remove_thread_event_breakpoints ();
868
 
869
  /* create breakpoints -- thread creation and death */
870
  /* thread creation */
871
  /* get breakpoint location */
872
  if (p_td_ta_event_addr (ta, TD_CREATE, &notify) != TD_OK)
873
    {
874
      warning ("unable to get location for thread creation breakpoint");
875
      return;
876
    }
877
 
878
  /* Set up the breakpoint. */
879
  create_thread_event_breakpoint ((CORE_ADDR) notify.u.bptaddr);
880
 
881
  /* Save it's location. */
882
  thread_creation_bkpt_address = (CORE_ADDR) notify.u.bptaddr;
883
 
884
  /* thread death */
885
  /* get breakpoint location */
886
  if (p_td_ta_event_addr (ta, TD_DEATH, &notify) != TD_OK)
887
    {
888
      warning ("unable to get location for thread death breakpoint");
889
      return;
890
    }
891
  /* Set up the breakpoint. */
892
  create_thread_event_breakpoint ((CORE_ADDR) notify.u.bptaddr);
893
 
894
  /* Save it's location. */
895
  thread_death_bkpt_address = (CORE_ADDR) notify.u.bptaddr;
896
}
897
 
898
/* This function handles the global parts of disabling thread events.
899
   The thread-specific enabling is handled per-thread elsewhere.  */
900
 
901
static void
902
disable_thread_event_reporting (td_thragent_t *ta)
903
{
904
  td_thr_events_t events;
905
 
906
  /* set process wide mask saying we aren't interested in any events */
907
  td_event_emptyset (&events);
908
  p_td_ta_set_event (main_threadagent, &events);
909
 
910
  /* Delete thread event breakpoints, if any.  */
911
  remove_thread_event_breakpoints ();
912
  thread_creation_bkpt_address = 0;
913
  thread_death_bkpt_address = 0;
914
}
915
 
916
/* check_for_thread_event
917
 
918
   if it's a thread event we recognize (currently
919
   we only recognize creation and destruction
920
   events), return 1; else return 0.  */
921
 
922
 
923
static int
924
check_for_thread_event (struct target_waitstatus *tws, int event_pid)
925
{
926
  /* FIXME: to be more efficient, we should keep a static
927
     list of threads, and update it only here (with td_ta_thr_iter). */
928
  return 0;
929
}
930
 
931
static void
932
thread_db_push_target (void)
933
{
934
  /* Called ONLY from thread_db_new_objfile after td_ta_new call succeeds. */
935
 
936
  /* Push this target vector */
937
  push_target (&thread_db_ops);
938
  /* Find the underlying process-layer target for calling later.  */
939
  target_beneath = find_target_beneath (&thread_db_ops);
940
  using_thread_db = 1;
941
  /* Turn on thread_db event-reporting API.  */
942
  enable_thread_event_reporting (main_threadagent);
943
}
944
 
945
static void
946
thread_db_unpush_target (void)
947
{
948
  /* Must be called whenever we remove ourself from the target stack! */
949
 
950
  using_thread_db = 0;
951
  target_beneath = NULL;
952
 
953
  /* delete local list of threads */
954
  empty_threadlist ();
955
  /* Turn off the thread_db API.  */
956
  p_td_ta_delete (main_threadagent);
957
  /* Unpush this target vector */
958
  unpush_target (&thread_db_ops);
959
  /* Reset linuxthreads module.  */
960
  linuxthreads_discard_global_state ();
961
}
962
 
963
/*
964
 * New objfile hook function:
965
 * Called for each new objfile (image, shared lib) in the target process.
966
 *
967
 * The purpose of this function is to detect that the target process
968
 * is linked with the (appropriate) thread library.  So every time a
969
 * new target shared library is detected, we will call td_ta_new.
970
 * If it succeeds, we know we have a multi-threaded target process
971
 * that we can debug using the thread_db API.
972
 */
973
 
974
/*
975
 * new_objfile function:
976
 *
977
 * connected to target_new_objfile_hook, this function gets called
978
 * every time a new binary image is loaded.
979
 *
980
 * At each call, we attempt to open the thread_db connection to the
981
 * child process.  If it succeeds, we know we have a libthread process
982
 * and we can debug it with this target vector.  Therefore we push
983
 * ourself onto the target stack.
984
 */
985
 
986
static void (*target_new_objfile_chain)   (struct objfile *objfile);
987
static int stop_or_attach_thread_callback (const td_thrhandle_t *th,
988
                                           void *data);
989
static int wait_thread_callback           (const td_thrhandle_t *th,
990
                                           void *data);
991
 
992
static void
993
thread_db_new_objfile (struct objfile *objfile)
994
{
995
  td_err_e   ret;
996
 
997
  if (using_thread_db)                  /* libthread already detected, and */
998
    goto quit;                          /* thread target vector activated. */
999
 
1000
  if (objfile == NULL)
1001
    goto quit;  /* un-interesting object file */
1002
 
1003
  /* Initialize our "main prochandle" with the main inferior pid.  */
1004
  main_prochandle.pid = PIDGET (inferior_ptid);
1005
 
1006
  /* Now attempt to open a thread_db connection to the
1007
     thread library running in the child process.  */
1008
  ret = p_td_ta_new (&main_prochandle, &main_threadagent);
1009
  switch (ret) {
1010
  default:
1011
    warning ("Unexpected error initializing thread_db: %s",
1012
             thr_err_string (ret));
1013
    break;
1014
  case TD_NOLIBTHREAD:  /* expected: no libthread in child process (yet) */
1015
    break;
1016
  case TD_OK:           /* libthread detected in child: we go live now! */
1017
    thread_db_push_target ();
1018
    event_pid = PIDGET (inferior_ptid); /* for resume */
1019
 
1020
    /* Now stop everyone else, and attach any new threads you find.  */
1021
    p_td_ta_thr_iter (main_threadagent,
1022
                      stop_or_attach_thread_callback,
1023
                      (void *) 0,
1024
                      TD_THR_ANY_STATE,
1025
                      TD_THR_LOWEST_PRIORITY,
1026
                      TD_SIGNO_MASK,
1027
                      TD_THR_ANY_USER_FLAGS);
1028
 
1029
    /* Now go call wait on all the threads you've stopped:
1030
       This allows us to absorb the SIGKILL event, and to make sure
1031
       that the thread knows that it is stopped (Linux peculiarity).  */
1032
    p_td_ta_thr_iter (main_threadagent,
1033
                      wait_thread_callback,
1034
                      (void *) 0,
1035
                      TD_THR_ANY_STATE,
1036
                      TD_THR_LOWEST_PRIORITY,
1037
                      TD_SIGNO_MASK,
1038
                      TD_THR_ANY_USER_FLAGS);
1039
 
1040
    break;
1041
  }
1042
quit:
1043
  if (target_new_objfile_chain)
1044
    target_new_objfile_chain (objfile);
1045
}
1046
 
1047
 
1048
/*
1049
 
1050
   LOCAL FUNCTION
1051
 
1052
   thread_db_alive     - test thread for "aliveness"
1053
 
1054
   SYNOPSIS
1055
 
1056
   static bool thread_db_alive (int pid);
1057
 
1058
   DESCRIPTION
1059
 
1060
   returns true if thread still active in inferior.
1061
 
1062
 */
1063
 
1064
static int
1065
thread_db_alive (ptid_t ptid)
1066
{
1067
  if (is_thread (ptid))         /* user-space (non-kernel) thread */
1068
    {
1069
      td_thrhandle_t th;
1070
      td_err_e ret;
1071
      int pid = GET_THREAD (ptid);
1072
 
1073
      if ((ret = p_td_ta_map_id2thr (main_threadagent, pid, &th)) != TD_OK)
1074
        return 0;                /* thread not found */
1075
      if ((ret = p_td_thr_validate (&th)) != TD_OK)
1076
        return 0;                /* thread not valid */
1077
      return 1;                 /* known thread: return true */
1078
    }
1079
  else if (target_beneath->to_thread_alive)
1080
    return target_beneath->to_thread_alive (ptid);
1081
  else
1082
    return 0;            /* default to "not alive" (shouldn't happen anyway) */
1083
}
1084
 
1085
/*
1086
 * get_lwp_from_thread_handle
1087
 */
1088
 
1089
static int      /* lwpid_t or pid_t */
1090
get_lwp_from_thread_handle (td_thrhandle_t *th)
1091
{
1092
  td_thrinfo_t ti;
1093
  td_err_e     ret;
1094
 
1095
  if ((ret = p_td_thr_get_info (th, &ti)) != TD_OK)
1096
    error ("get_lwp_from_thread_handle: thr_get_info failed: %s",
1097
           thr_err_string (ret));
1098
 
1099
  return ti.ti_lid;
1100
}
1101
 
1102
/*
1103
 * get_lwp_from_thread_id
1104
 */
1105
 
1106
static int      /* lwpid_t or pid_t */
1107
get_lwp_from_thread_id (int tid /* thread_t? */)
1108
{
1109
  td_thrhandle_t th;
1110
  td_err_e       ret;
1111
 
1112
  if ((ret = p_td_ta_map_id2thr (main_threadagent, tid, &th)) != TD_OK)
1113
    error ("get_lwp_from_thread_id: map_id2thr failed: %s",
1114
           thr_err_string (ret));
1115
 
1116
  return get_lwp_from_thread_handle (&th);
1117
}
1118
 
1119
/*
1120
 * pid_to_str has to handle user-space threads.
1121
 * If not a user-space thread, then pass the request on to the
1122
 * underlying stratum if it can handle it: else call normal_pid_to_str.
1123
 */
1124
 
1125
static char *
1126
thread_db_pid_to_str (ptid_t ptid)
1127
{
1128
  static char buf[100];
1129
  td_thrhandle_t th;
1130
  td_thrinfo_t ti;
1131
  td_err_e ret;
1132
 
1133
  if (is_thread (ptid))
1134
    {
1135
      if ((ret = p_td_ta_map_id2thr (main_threadagent,
1136
                                     GET_THREAD (ptid),
1137
                                     &th)) != TD_OK)
1138
        error ("thread_db: map_id2thr failed: %s", thr_err_string (ret));
1139
 
1140
      if ((ret = p_td_thr_get_info (&th, &ti)) != TD_OK)
1141
        error ("thread_db: thr_get_info failed: %s", thr_err_string (ret));
1142
 
1143
      if (ti.ti_state == TD_THR_ACTIVE &&
1144
          ti.ti_lid != 0)
1145
        sprintf (buf, "Thread %ld (LWP %d)", ti.ti_tid, ti.ti_lid);
1146
      else
1147
        sprintf (buf, "Thread %ld (%s)", ti.ti_tid,
1148
                 thr_state_string (ti.ti_state));
1149
    }
1150
  else if (GET_LWP (ptid))
1151
    sprintf (buf, "LWP %ld", GET_LWP (ptid));
1152
  else return normal_pid_to_str (ptid);
1153
 
1154
  return buf;
1155
}
1156
 
1157
/*
1158
 * thread_db target vector functions:
1159
 */
1160
 
1161
static void
1162
thread_db_files_info (struct target_ops *tgt_vector)
1163
{
1164
  /* This function will be unnecessary in real life.  */
1165
  printf_filtered ("thread_db stratum:\n");
1166
  target_beneath->to_files_info (tgt_vector);
1167
}
1168
 
1169
/*
1170
 * xfer_memory has to munge the inferior_ptid before passing the call
1171
 * down to the target layer.
1172
 */
1173
 
1174
static int
1175
thread_db_xfer_memory (CORE_ADDR memaddr, char *myaddr, int len, int dowrite,
1176
                       struct mem_attrib *attrib,
1177
                       struct target_ops *target)
1178
{
1179
  struct cleanup *old_chain;
1180
  int ret;
1181
 
1182
  old_chain = save_inferior_ptid ();
1183
 
1184
  if (is_thread (inferior_ptid) ||
1185
      !target_thread_alive (inferior_ptid))
1186
    {
1187
      /* FIXME: use the LID/LWP, so that underlying process layer
1188
         can read memory from specific threads?  */
1189
      inferior_ptid = pid_to_ptid (main_prochandle.pid);
1190
    }
1191
 
1192
  ret = target_beneath->to_xfer_memory (memaddr, myaddr, len,
1193
                                        dowrite, attrib, target);
1194
  do_cleanups (old_chain);
1195
  return ret;
1196
}
1197
 
1198
/*
1199
 * fetch_registers has to determine if inferior_ptid is a user-space thread.
1200
 * If so, we use the thread_db API to get the registers.
1201
 * And if not, we call the underlying process stratum.
1202
 */
1203
 
1204
static void
1205
thread_db_fetch_registers (int regno)
1206
{
1207
  td_thrhandle_t thandle;
1208
  gdb_prfpregset_t fpregset;
1209
  prgregset_t gregset;
1210
  thread_t thread;
1211
  td_err_e ret;
1212
 
1213
  if (!is_thread (inferior_ptid))       /* kernel thread */
1214
    {                   /* pass the request on to the target underneath.  */
1215
      target_beneath->to_fetch_registers (regno);
1216
      return;
1217
    }
1218
 
1219
  /* convert inferior_ptid into a td_thrhandle_t */
1220
 
1221
  if ((thread = GET_THREAD (inferior_ptid)) == 0)
1222
    error ("fetch_registers:  thread == 0");
1223
 
1224
  if ((ret = p_td_ta_map_id2thr (main_threadagent, thread, &thandle)) != TD_OK)
1225
    error ("fetch_registers: td_ta_map_id2thr: %s", thr_err_string (ret));
1226
 
1227
  /* Get the integer regs:
1228
     For the sparc, TD_PARTIALREG means that only i0->i7, l0->l7,
1229
     pc and sp are saved (by a thread context switch).  */
1230
  if ((ret = p_td_thr_getgregs (&thandle, gregset)) != TD_OK &&
1231
      ret != TD_PARTIALREG)
1232
    error ("fetch_registers: td_thr_getgregs %s", thr_err_string (ret));
1233
 
1234
  /* And, now the fp regs */
1235
  if ((ret = p_td_thr_getfpregs (&thandle, &fpregset)) != TD_OK &&
1236
      ret != TD_NOFPREGS)
1237
    error ("fetch_registers: td_thr_getfpregs %s", thr_err_string (ret));
1238
 
1239
/* Note that we must call supply_{g fp}regset *after* calling the td routines
1240
   because the td routines call ps_lget* which affect the values stored in the
1241
   registers array.  */
1242
 
1243
  supply_gregset ((gdb_gregset_t *) gregset);
1244
  supply_fpregset (&fpregset);
1245
 
1246
}
1247
 
1248
/*
1249
 * store_registers has to determine if inferior_ptid is a user-space thread.
1250
 * If so, we use the thread_db API to get the registers.
1251
 * And if not, we call the underlying process stratum.
1252
 */
1253
 
1254
static void
1255
thread_db_store_registers (int regno)
1256
{
1257
  td_thrhandle_t thandle;
1258
  gdb_prfpregset_t fpregset;
1259
  prgregset_t  gregset;
1260
  thread_t thread;
1261
  td_err_e ret;
1262
 
1263
  if (!is_thread (inferior_ptid))       /* Kernel thread: */
1264
    {           /* pass the request on to the underlying target vector.  */
1265
      target_beneath->to_store_registers (regno);
1266
      return;
1267
    }
1268
 
1269
  /* convert inferior_ptid into a td_thrhandle_t */
1270
 
1271
  if ((thread = GET_THREAD (inferior_ptid)) == 0)
1272
    error ("store_registers: thread == 0");
1273
 
1274
  if ((ret = p_td_ta_map_id2thr (main_threadagent, thread, &thandle)) != TD_OK)
1275
    error ("store_registers: td_ta_map_id2thr %s", thr_err_string (ret));
1276
 
1277
  if (regno != -1)
1278
    {                           /* Not writing all the regs */
1279
      /* save new register value */
1280
      /* MVS: I don't understand this... */
1281
      char old_value[REGISTER_SIZE];
1282
 
1283
      memcpy (old_value, &registers[REGISTER_BYTE (regno)], REGISTER_SIZE);
1284
 
1285
      if ((ret = p_td_thr_getgregs (&thandle, gregset)) != TD_OK)
1286
        error ("store_registers: td_thr_getgregs %s", thr_err_string (ret));
1287
      if ((ret = p_td_thr_getfpregs (&thandle, &fpregset)) != TD_OK)
1288
        error ("store_registers: td_thr_getfpregs %s", thr_err_string (ret));
1289
 
1290
      /* restore new register value */
1291
      memcpy (&registers[REGISTER_BYTE (regno)], old_value, REGISTER_SIZE);
1292
 
1293
    }
1294
 
1295
  fill_gregset  ((gdb_gregset_t *) gregset, regno);
1296
  fill_fpregset (&fpregset, regno);
1297
 
1298
  if ((ret = p_td_thr_setgregs (&thandle, gregset)) != TD_OK)
1299
    error ("store_registers: td_thr_setgregs %s", thr_err_string (ret));
1300
  if ((ret = p_td_thr_setfpregs (&thandle, &fpregset)) != TD_OK &&
1301
      ret != TD_NOFPREGS)
1302
    error ("store_registers: td_thr_setfpregs %s", thr_err_string (ret));
1303
}
1304
 
1305
static void
1306
handle_new_thread (int tid,     /* user thread id */
1307
                   int lid,     /* kernel thread id */
1308
                   int verbose)
1309
{
1310
  ptid_t gdb_ptid = BUILD_THREAD (tid, main_prochandle.pid);
1311
  int wait_pid, wait_status;
1312
 
1313
  if (verbose)
1314
    printf_filtered ("[New %s]\n", target_pid_to_str (gdb_ptid));
1315
  add_thread (gdb_ptid);
1316
 
1317
  if (lid != main_prochandle.pid)
1318
    {
1319
      attach_thread (lid);
1320
      /* According to the Eric Paire model, we now have to send
1321
         the restart signal to the new thread -- however, empirically,
1322
         I do not find that to be necessary.  */
1323
      attach_pid = lid;
1324
    }
1325
}
1326
 
1327
static void
1328
test_for_new_thread (int tid, int lid, int verbose)
1329
{
1330
  if (!in_thread_list (BUILD_THREAD (tid, main_prochandle.pid)))
1331
    handle_new_thread (tid, lid, verbose);
1332
}
1333
 
1334
/*
1335
 * Callback function that gets called once per USER thread
1336
 * (i.e., not kernel) thread by td_ta_thr_iter.
1337
 */
1338
 
1339
static int
1340
find_new_threads_callback (const td_thrhandle_t *th, void *ignored)
1341
{
1342
  td_thrinfo_t ti;
1343
  td_err_e     ret;
1344
 
1345
  if ((ret = p_td_thr_get_info (th, &ti)) != TD_OK)
1346
    {
1347
      warning ("find_new_threads_callback: %s", thr_err_string (ret));
1348
      return -1;                /* bail out, get_info failed. */
1349
    }
1350
 
1351
  /* FIXME:
1352
     As things now stand, this should never detect a new thread.
1353
     But if it does, we could be in trouble because we aren't calling
1354
     wait_thread_callback for it.  */
1355
  test_for_new_thread (ti.ti_tid, ti.ti_lid, 0);
1356
  return 0;
1357
}
1358
 
1359
/*
1360
 * find_new_threads uses the thread_db iterator function to discover
1361
 * user-space threads.  Then if the underlying process stratum has a
1362
 * find_new_threads method, we call that too.
1363
 */
1364
 
1365
static void
1366
thread_db_find_new_threads (void)
1367
{
1368
  if (PIDGET (inferior_ptid) == -1)     /* FIXME: still necessary? */
1369
    {
1370
      printf_filtered ("No process.\n");
1371
      return;
1372
    }
1373
  p_td_ta_thr_iter (main_threadagent,
1374
                    find_new_threads_callback,
1375
                    (void *) 0,
1376
                    TD_THR_ANY_STATE,
1377
                    TD_THR_LOWEST_PRIORITY,
1378
                    TD_SIGNO_MASK,
1379
                    TD_THR_ANY_USER_FLAGS);
1380
  if (target_beneath->to_find_new_threads)
1381
    target_beneath->to_find_new_threads ();
1382
}
1383
 
1384
/*
1385
 * Resume all threads, or resume a single thread.
1386
 * If step is true, then single-step the appropriate thread
1387
 * (or single-step inferior_ptid, but continue everyone else).
1388
 * If signo is true, then send that signal to at least one thread.
1389
 */
1390
 
1391
/*
1392
 * This function is called once for each thread before resuming.
1393
 * It sends continue (no step, and no signal) to each thread except
1394
 *   the main thread, and
1395
 *   the event thread (the one that stopped at a breakpoint etc.)
1396
 *
1397
 * The event thread is handled separately so that it can be sent
1398
 * the stepping and signal args with which target_resume was called.
1399
 *
1400
 * The main thread is resumed last, so that the thread_db proc_service
1401
 * callbacks will still work during the iterator function.
1402
 */
1403
 
1404
static int
1405
resume_thread_callback (const td_thrhandle_t *th, void *data)
1406
{
1407
  td_thrinfo_t ti;
1408
  td_err_e     ret;
1409
 
1410
  if ((ret = p_td_thr_get_info (th, &ti)) != TD_OK)
1411
    {
1412
      warning ("resume_thread_callback: %s", thr_err_string (ret));
1413
      return -1;                /* bail out, get_info failed. */
1414
    }
1415
  /* FIXME:
1416
     As things now stand, this should never detect a new thread.
1417
     But if it does, we could be in trouble because we aren't calling
1418
     wait_thread_callback for it.  */
1419
  test_for_new_thread (ti.ti_tid, ti.ti_lid, 1);
1420
 
1421
  if (ti.ti_lid != main_prochandle.pid &&
1422
      ti.ti_lid != event_pid)
1423
    {
1424
      /* Unconditionally continue the thread with no signal.
1425
         Only the event thread will get a signal of any kind.  */
1426
 
1427
      target_beneath->to_resume (pid_to_ptid (ti.ti_lid), 0, 0);
1428
    }
1429
  return 0;
1430
}
1431
 
1432
static int
1433
new_resume_thread_callback (threadinfo *thread, void *data)
1434
{
1435
  if (thread->lid != event_pid &&
1436
      thread->lid != main_prochandle.pid)
1437
    {
1438
      /* Unconditionally continue the thread with no signal (for now).  */
1439
 
1440
      target_beneath->to_resume (pid_to_ptid (thread->lid), 0, 0);
1441
    }
1442
  return 0;
1443
}
1444
 
1445
static int last_resume_pid;
1446
static int last_resume_step;
1447
static int last_resume_signo;
1448
 
1449
static void
1450
thread_db_resume (ptid_t ptid, int step, enum target_signal signo)
1451
{
1452
  last_resume_pid   = PIDGET (ptid);
1453
  last_resume_step  = step;
1454
  last_resume_signo = signo;
1455
 
1456
  /* resuming a specific pid? */
1457
  if (PIDGET (ptid) != -1)
1458
    {
1459
      if (is_thread (ptid))
1460
        ptid = pid_to_ptid (get_lwp_from_thread_id (GET_THREAD (ptid)));
1461
      else if (GET_LWP (ptid))
1462
        ptid = pid_to_ptid (GET_LWP (ptid));
1463
    }
1464
 
1465
  /* Apparently the interpretation of 'pid' is dependent on 'step':
1466
     If step is true, then a specific pid means 'step only this pid'.
1467
     But if step is not true, then pid means 'continue ALL pids, but
1468
     give the signal only to this one'.  */
1469
  if (PIDGET (ptid) != -1 && step)
1470
    {
1471
      /* FIXME: is this gonna work in all circumstances? */
1472
      target_beneath->to_resume (ptid, step, signo);
1473
    }
1474
  else
1475
    {
1476
      /* 1) Continue all threads except the event thread and the main thread.
1477
         2) resume the event thread with step and signo.
1478
         3) If event thread != main thread, continue the main thread.
1479
 
1480
         Note: order of 2 and 3 may need to be reversed.  */
1481
 
1482
      threadlist_iter (new_resume_thread_callback,
1483
                        (void *) 0,
1484
                        TD_THR_ANY_STATE,
1485
                        TD_THR_ANY_TYPE);
1486
      /* now resume event thread, and if necessary also main thread. */
1487
      if (event_pid)
1488
        {
1489
          target_beneath->to_resume (pid_to_ptid (event_pid), step, signo);
1490
        }
1491
      if (event_pid != main_prochandle.pid)
1492
        {
1493
          target_beneath->to_resume (pid_to_ptid (main_prochandle.pid), 0, 0);
1494
        }
1495
    }
1496
}
1497
 
1498
/* All new threads will be attached.
1499
   All previously known threads will be stopped using kill (SIGKILL).  */
1500
 
1501
static int
1502
stop_or_attach_thread_callback (const td_thrhandle_t *th, void *data)
1503
{
1504
  td_thrinfo_t ti;
1505
  td_err_e     ret;
1506
  ptid_t      gdb_ptid;
1507
  int on_off = 1;
1508
 
1509
  if ((ret = p_td_thr_get_info (th, &ti)) != TD_OK)
1510
    {
1511
      warning ("stop_or_attach_thread_callback: %s", thr_err_string (ret));
1512
      return -1;                /* bail out, get_info failed. */
1513
    }
1514
 
1515
  /* First add it to our internal list.
1516
     We build this list anew at every wait event.  */
1517
  insert_thread (ti.ti_tid, ti.ti_lid, ti.ti_state, ti.ti_type);
1518
  /* Now: if we've already seen it, stop it, else add it and attach it.  */
1519
  gdb_ptid = BUILD_THREAD (ti.ti_tid, main_prochandle.pid);
1520
  if (!in_thread_list (gdb_ptid))       /* new thread */
1521
    {
1522
      handle_new_thread (ti.ti_tid, ti.ti_lid, 1);
1523
      /* Enable thread events */
1524
      if (p_td_thr_event_enable)
1525
        if ((ret = p_td_thr_event_enable (th, on_off)) != TD_OK)
1526
          warning ("stop_or_attach_thread: %s", thr_err_string (ret));
1527
    }
1528
  else if (ti.ti_lid != event_pid &&
1529
           ti.ti_lid != main_prochandle.pid)
1530
    {
1531
      ret = (td_err_e) kill (ti.ti_lid, SIGSTOP);
1532
    }
1533
 
1534
  return 0;
1535
}
1536
 
1537
/*
1538
 * Wait for signal N from pid PID.
1539
 * If wait returns any other signals, put them back before returning.
1540
 */
1541
 
1542
static void
1543
wait_for_stop (int pid)
1544
{
1545
  int i;
1546
  int retpid;
1547
  int status;
1548
 
1549
  /* Array of wait/signal status */
1550
  /* FIXME: wrong data structure, we need a queue.
1551
     Realtime signals may be delivered more than once.
1552
     And at that, we really can't handle them (see below).  */
1553
#if defined (NSIG)
1554
  static int   wstatus [NSIG];
1555
#elif defined (_NSIG)
1556
  static int   wstatus [_NSIG];
1557
#else
1558
#error No definition for number of signals!
1559
#endif
1560
 
1561
  /* clear wait/status list */
1562
  memset (&wstatus, 0, sizeof (wstatus));
1563
 
1564
  /* Now look for SIGSTOP event on all threads except event thread.  */
1565
  do {
1566
    errno = 0;
1567
    if (pid == main_prochandle.pid)
1568
      retpid = waitpid (pid, &status, 0);
1569
    else
1570
      retpid = waitpid (pid, &status, __WCLONE);
1571
 
1572
    if (retpid > 0)
1573
      if (WSTOPSIG (status) == SIGSTOP)
1574
        {
1575
          /* Got the SIGSTOP event we're looking for.
1576
             Throw it away, and throw any other events back!  */
1577
          for (i = 0; i < sizeof(wstatus) / sizeof (wstatus[0]); i++)
1578
            if (wstatus[i])
1579
              if (i != SIGSTOP)
1580
                {
1581
                  kill (retpid, i);
1582
                }
1583
          break;        /* all done */
1584
        }
1585
      else
1586
        {
1587
          int signo;
1588
          /* Oops, got an event other than SIGSTOP.
1589
             Save it, and throw it back after we find the SIGSTOP event.  */
1590
 
1591
          /* FIXME (how?)  This method is going to fail for realtime
1592
             signals, which cannot be put back simply by using kill.  */
1593
 
1594
          if (WIFEXITED (status))
1595
            error ("Ack!  Thread Exited event.  What do I do now???");
1596
          else if (WIFSTOPPED (status))
1597
            signo = WSTOPSIG (status);
1598
          else
1599
            signo = WTERMSIG (status);
1600
 
1601
          /* If a thread other than the event thread has hit a GDB
1602
             breakpoint (as opposed to some random trap signal), then
1603
             just arrange for it to hit it again later.  Back up the
1604
             PC if necessary.  Don't forward the SIGTRAP signal to
1605
             the thread.  We will handle the current event, eventually
1606
             we will resume all the threads, and this one will get
1607
             it's breakpoint trap again.
1608
 
1609
             If we do not do this, then we run the risk that the user
1610
             will delete or disable the breakpoint, but the thread will
1611
             have already tripped on it.  */
1612
 
1613
          if (retpid != event_pid &&
1614
              signo == SIGTRAP &&
1615
              breakpoint_inserted_here_p (read_pc_pid (pid_to_ptid (retpid)) -
1616
                                          DECR_PC_AFTER_BREAK))
1617
            {
1618
              /* Set the pc to before the trap and DO NOT re-send the signal */
1619
              if (DECR_PC_AFTER_BREAK)
1620
                write_pc_pid (read_pc_pid (pid_to_ptid (retpid))
1621
                                - DECR_PC_AFTER_BREAK,
1622
                              pid_to_ptid (retpid));
1623
            }
1624
 
1625
          /* Since SIGINT gets forwarded to the entire process group
1626
             (in the case where ^C is typed at the tty / console),
1627
             just ignore all SIGINTs from other than the event thread.  */
1628
          else if (retpid != event_pid && signo == SIGINT)
1629
            { /* do nothing.  Signal will disappear into oblivion!  */
1630
              ;
1631
            }
1632
 
1633
          else /* This is some random signal other than a breakpoint. */
1634
            {
1635
              wstatus [signo] = 1;
1636
            }
1637
          child_resume (pid_to_ptid (retpid), 0, TARGET_SIGNAL_0);
1638
          continue;
1639
        }
1640
 
1641
  } while (errno == 0 || errno == EINTR);
1642
}
1643
 
1644
/*
1645
 * wait_thread_callback
1646
 *
1647
 * Calls waitpid for each thread, repeatedly if necessary, until
1648
 * SIGSTOP is returned.  Afterward, if any other signals were returned
1649
 * by waitpid, return them to the thread's pending queue by calling kill.
1650
 */
1651
 
1652
static int
1653
wait_thread_callback (const td_thrhandle_t *th, void *data)
1654
{
1655
  td_thrinfo_t ti;
1656
  td_err_e     ret;
1657
 
1658
  if ((ret = p_td_thr_get_info (th, &ti)) != TD_OK)
1659
    {
1660
      warning ("wait_thread_callback: %s", thr_err_string (ret));
1661
      return -1;                /* bail out, get_info failed. */
1662
    }
1663
 
1664
  /* This callback to act on all threads except the event thread: */
1665
  if (ti.ti_lid == event_pid ||         /* no need to wait (no sigstop) */
1666
      ti.ti_lid == main_prochandle.pid) /* no need to wait (already waited) */
1667
    return 0;    /* don't wait on the event thread.  */
1668
 
1669
  wait_for_stop (ti.ti_lid);
1670
  return 0;      /* finished: next thread. */
1671
}
1672
 
1673
static int
1674
new_wait_thread_callback (threadinfo *thread, void *data)
1675
{
1676
  /* don't wait on the event thread -- it's already stopped and waited.
1677
     Ditto the main thread.  */
1678
  if (thread->lid != event_pid &&
1679
      thread->lid != main_prochandle.pid)
1680
    {
1681
      wait_for_stop (thread->lid);
1682
    }
1683
  return 0;
1684
}
1685
 
1686
/*
1687
 * Wait for any thread to stop, by calling the underlying wait method.
1688
 * The PID returned by the underlying target may be a kernel thread,
1689
 * in which case we will want to convert it to the corresponding
1690
 * user-space thread.
1691
 */
1692
 
1693
static ptid_t
1694
thread_db_wait (ptid_t ptid, struct target_waitstatus *ourstatus)
1695
{
1696
  td_thrhandle_t thandle;
1697
  td_thrinfo_t ti;
1698
  td_err_e ret;
1699
  lwpid_t lwp;
1700
  int retpid;
1701
  ptid_t retptid;
1702
  int status;
1703
  int save_errno;
1704
 
1705
  /* OK, we're about to wait for an event from the running inferior.
1706
     Make sure we're ignoring the right signals.  */
1707
 
1708
  check_all_signal_numbers ();  /* see if magic signals changed. */
1709
 
1710
  event_pid = 0;
1711
  attach_pid = 0;
1712
 
1713
  /* FIXME: should I do the wait right here inline?  */
1714
#if 0
1715
  if (PIDGET (ptid) == -1)
1716
    lwp = -1;
1717
  else
1718
    lwp = get_lwp_from_thread_id (GET_THREAD (ptid));
1719
#endif
1720
 
1721
 
1722
  save_errno = linux_child_wait (-1, &retpid, &status);
1723
  store_waitstatus (ourstatus, status);
1724
 
1725
  /* Thread ID is irrelevant if the target process exited.
1726
     FIXME: do I have any killing to do?
1727
     Can I get this event mistakenly from a thread?  */
1728
  if (ourstatus->kind == TARGET_WAITKIND_EXITED)
1729
    return pid_to_ptid (retpid);
1730
 
1731
  /* OK, we got an event of interest.
1732
     Go stop all threads and look for new ones.
1733
     FIXME: maybe don't do this for the restart signal?  Optimization...  */
1734
  event_pid = retpid;
1735
 
1736
  /* If the last call to resume was for a specific thread, then we don't
1737
     need to stop everyone else: they should already be stopped.  */
1738
  if (last_resume_step == 0 || last_resume_pid == -1)
1739
    {
1740
      /* Main thread must be stopped before calling the iterator.  */
1741
      if (retpid != main_prochandle.pid)
1742
        {
1743
          kill (main_prochandle.pid, SIGSTOP);
1744
          wait_for_stop (main_prochandle.pid);
1745
        }
1746
 
1747
      empty_threadlist ();
1748
      /* Now stop everyone else, and attach any new threads you find.  */
1749
      p_td_ta_thr_iter (main_threadagent,
1750
                        stop_or_attach_thread_callback,
1751
                        (void *) 0,
1752
                        TD_THR_ANY_STATE,
1753
                        TD_THR_LOWEST_PRIORITY,
1754
                        TD_SIGNO_MASK,
1755
                        TD_THR_ANY_USER_FLAGS);
1756
 
1757
      /* Now go call wait on all the threads we've stopped:
1758
         This allows us to absorb the SIGKILL event, and to make sure
1759
         that the thread knows that it is stopped (Linux peculiarity).  */
1760
 
1761
      threadlist_iter (new_wait_thread_callback,
1762
                       (void *) 0,
1763
                       TD_THR_ANY_STATE,
1764
                       TD_THR_ANY_TYPE);
1765
    }
1766
 
1767
  /* Convert the kernel thread id to the corresponding thread id.  */
1768
 
1769
  /* If the process layer does not furnish an lwp,
1770
     then perhaps the returned pid IS the lwp... */
1771
#if 0 /* Always true (if it'd compile...) */
1772
  if ((lwp = GET_LWP (pid_to_ptid (retpid))) == 0)
1773
#endif
1774
    lwp = retpid;
1775
 
1776
  if ((ret = p_td_ta_map_lwp2thr (main_threadagent, lwp, &thandle)) != TD_OK)
1777
    return pid_to_ptid (retpid); /* LWP is not mapped onto a user-space thread. */
1778
 
1779
  if ((ret = p_td_thr_validate (&thandle)) != TD_OK)
1780
    return pid_to_ptid (retpid);        /* LWP is not mapped onto a valid thread. */
1781
 
1782
  if ((ret = p_td_thr_get_info (&thandle, &ti)) != TD_OK)
1783
    {
1784
      warning ("thread_db: thr_get_info failed ('%s')", thr_err_string (ret));
1785
      return pid_to_ptid (retpid);
1786
    }
1787
 
1788
  retptid = BUILD_THREAD (ti.ti_tid, main_prochandle.pid);
1789
  /* If this is a new user thread, notify GDB about it.  */
1790
  if (!in_thread_list (retptid))
1791
    {
1792
      printf_filtered ("[New %s]\n", target_pid_to_str (retptid));
1793
      add_thread (retptid);
1794
    }
1795
 
1796
#if 0
1797
  /* Now detect if this is a thread creation/deletion event: */
1798
  check_for_thread_event (ourstatus, retpid);
1799
#endif
1800
  return retptid;
1801
}
1802
 
1803
/*
1804
 * kill has to call the underlying kill.
1805
 * FIXME: I'm not sure if it's necessary to check inferior_ptid any more,
1806
 * but we might need to fix inferior_ptid up if it's a user thread.
1807
 */
1808
 
1809
static int
1810
kill_thread_callback (const td_thrhandle_t *th, void *data)
1811
{
1812
  td_thrinfo_t ti;
1813
  td_err_e     ret;
1814
 
1815
  /* Fixme:
1816
     For Linux, threads may need to be waited.  */
1817
  if ((ret = p_td_thr_get_info (th, &ti)) != TD_OK)
1818
    {
1819
      warning ("kill_thread_callback: %s", thr_err_string (ret));
1820
      return -1;                /* bail out, get_info failed. */
1821
    }
1822
 
1823
  if (ti.ti_lid != main_prochandle.pid)
1824
    {
1825
      kill (ti.ti_lid, SIGKILL);
1826
    }
1827
  return 0;
1828
}
1829
 
1830
 
1831
static void thread_db_kill (void)
1832
{
1833
  int rpid;
1834
  int status;
1835
 
1836
  /* Fixme:
1837
     For Linux, threads may need to be waited.  */
1838
  if (! ptid_equal (inferior_ptid, null_ptid))
1839
    {
1840
      /* Go kill the children first.  Save the main thread for last. */
1841
      p_td_ta_thr_iter (main_threadagent,
1842
                        kill_thread_callback,
1843
                        (void *) 0,
1844
                        TD_THR_ANY_STATE,
1845
                        TD_THR_LOWEST_PRIORITY,
1846
                        TD_SIGNO_MASK,
1847
                        TD_THR_ANY_USER_FLAGS);
1848
 
1849
      /* Turn off thread_db event-reporting API *before* killing the
1850
         main thread, since this operation requires child memory access.
1851
         Can't move this into thread_db_unpush target because then
1852
         detach would not work.  */
1853
      disable_thread_event_reporting (main_threadagent);
1854
 
1855
      inferior_ptid = pid_to_ptid (main_prochandle.pid);
1856
 
1857
      /*
1858
       * Since both procfs_kill and ptrace_kill call target_mourn,
1859
       * it should be sufficient for me to call one of them.
1860
       * That will result in my mourn being called, which will both
1861
       * unpush me and call the underlying mourn.
1862
       */
1863
      target_beneath->to_kill ();
1864
    }
1865
 
1866
  /* Wait for all threads. */
1867
  /* FIXME: need a universal wait_for_signal func? */
1868
  do
1869
    {
1870
      rpid = waitpid (-1, &status, __WCLONE | WNOHANG);
1871
    }
1872
  while (rpid > 0 || errno == EINTR);
1873
 
1874
  do
1875
    {
1876
      rpid = waitpid (-1, &status, WNOHANG);
1877
    }
1878
  while (rpid > 0 || errno == EINTR);
1879
}
1880
 
1881
/*
1882
 * Mourn has to remove us from the target stack,
1883
 * and then call the underlying mourn.
1884
 */
1885
 
1886
static void thread_db_mourn_inferior (void)
1887
{
1888
  thread_db_unpush_target ();
1889
  target_mourn_inferior ();     /* call the underlying mourn */
1890
}
1891
 
1892
/*
1893
 * Detach has to remove us from the target stack,
1894
 * and then call the underlying detach.
1895
 *
1896
 * But first, it has to detach all the cloned threads!
1897
 */
1898
 
1899
static int
1900
detach_thread_callback (const td_thrhandle_t *th, void *data)
1901
{
1902
  /* Called once per thread.  */
1903
  td_thrinfo_t ti;
1904
  td_err_e     ret;
1905
 
1906
  if ((ret = p_td_thr_get_info (th, &ti)) != TD_OK)
1907
    {
1908
      warning ("detach_thread_callback: %s", thr_err_string (ret));
1909
      return -1;                /* bail out, get_info failed. */
1910
    }
1911
 
1912
  if (!in_thread_list (BUILD_THREAD (ti.ti_tid, main_prochandle.pid)))
1913
    return 0;    /* apparently we don't know this one.  */
1914
 
1915
  /* Save main thread for last, or the iterator will fail! */
1916
  if (ti.ti_lid != main_prochandle.pid)
1917
    {
1918
      struct cleanup *old_chain;
1919
      int off = 0;
1920
 
1921
      /* Time to detach this thread.
1922
         First disable thread_db event reporting for the thread.  */
1923
      if (p_td_thr_event_enable &&
1924
          (ret = p_td_thr_event_enable (th, off)) != TD_OK)
1925
        {
1926
          warning ("detach_thread_callback: %s\n", thr_err_string (ret));
1927
          return 0;
1928
        }
1929
 
1930
      /* Now cancel any pending SIGTRAPS.  FIXME!  */
1931
 
1932
      /* Call underlying detach method.  FIXME just detach it.  */
1933
      old_chain = save_inferior_ptid ();
1934
      inferior_ptid = pid_to_ptid (ti.ti_lid);
1935
      detach (TARGET_SIGNAL_0);
1936
      do_cleanups (old_chain);
1937
    }
1938
  return 0;
1939
}
1940
 
1941
static void
1942
thread_db_detach (char *args, int from_tty)
1943
{
1944
  td_err_e ret;
1945
 
1946
  if ((ret = p_td_ta_thr_iter (main_threadagent,
1947
                               detach_thread_callback,
1948
                               (void *) 0,
1949
                               TD_THR_ANY_STATE,
1950
                               TD_THR_LOWEST_PRIORITY,
1951
                               TD_SIGNO_MASK,
1952
                               TD_THR_ANY_USER_FLAGS))
1953
      != TD_OK)
1954
    warning ("detach (thr_iter): %s", thr_err_string (ret));
1955
 
1956
  /* Turn off thread_db event-reporting API
1957
     (before detaching the main thread) */
1958
  disable_thread_event_reporting (main_threadagent);
1959
 
1960
  thread_db_unpush_target ();
1961
 
1962
  /* above call nullifies target_beneath, so don't use that! */
1963
  inferior_ptid = pid_to_ptid (PIDGET (inferior_ptid));
1964
  target_detach (args, from_tty);
1965
}
1966
 
1967
 
1968
/*
1969
 * We never want to actually create the inferior!
1970
 *
1971
 * If this is ever called, it means we were on the target stack
1972
 * when the user said "run".  But we don't want to be on the new
1973
 * inferior's target stack until the thread_db / libthread
1974
 * connection is ready to be made.
1975
 *
1976
 * So, what shall we do?
1977
 * Unpush ourselves from the stack, and then invoke
1978
 * find_default_create_inferior, which will invoke the
1979
 * appropriate process_stratum target to do the create.
1980
 */
1981
 
1982
static void
1983
thread_db_create_inferior (char *exec_file, char *allargs, char **env)
1984
{
1985
  thread_db_unpush_target ();
1986
  find_default_create_inferior (exec_file, allargs, env);
1987
}
1988
 
1989
/*
1990
 * Thread_db target vector initializer.
1991
 */
1992
 
1993
void
1994
init_thread_db_ops (void)
1995
{
1996
  thread_db_ops.to_shortname        = "multi-thread";
1997
  thread_db_ops.to_longname         = "multi-threaded child process.";
1998
  thread_db_ops.to_doc              = "Threads and pthreads support.";
1999
  thread_db_ops.to_files_info       = thread_db_files_info;
2000
  thread_db_ops.to_create_inferior  = thread_db_create_inferior;
2001
  thread_db_ops.to_detach           = thread_db_detach;
2002
  thread_db_ops.to_wait             = thread_db_wait;
2003
  thread_db_ops.to_resume           = thread_db_resume;
2004
  thread_db_ops.to_mourn_inferior   = thread_db_mourn_inferior;
2005
  thread_db_ops.to_kill             = thread_db_kill;
2006
  thread_db_ops.to_xfer_memory      = thread_db_xfer_memory;
2007
  thread_db_ops.to_fetch_registers  = thread_db_fetch_registers;
2008
  thread_db_ops.to_store_registers  = thread_db_store_registers;
2009
  thread_db_ops.to_thread_alive     = thread_db_alive;
2010
  thread_db_ops.to_find_new_threads = thread_db_find_new_threads;
2011
  thread_db_ops.to_pid_to_str       = thread_db_pid_to_str;
2012
  thread_db_ops.to_stratum          = thread_stratum;
2013
  thread_db_ops.to_has_thread_control = tc_schedlock;
2014
  thread_db_ops.to_magic            = OPS_MAGIC;
2015
}
2016
#endif  /* HAVE_STDINT_H */
2017
 
2018
/*
2019
 * Module constructor / initializer function.
2020
 * If connection to thread_db dynamic library is successful,
2021
 * then initialize this module's target vectors and the
2022
 * new_objfile hook.
2023
 */
2024
 
2025
 
2026
void
2027
_initialize_thread_db (void)
2028
{
2029
#ifdef HAVE_STDINT_H    /* stub out entire module, leave initializer empty */
2030
  if (init_thread_db_library ())
2031
    {
2032
      init_thread_db_ops ();
2033
      add_target (&thread_db_ops);
2034
      /*
2035
       * Hook up to the new_objfile event.
2036
       * If someone is already there, arrange for him to be called
2037
       * after we are.
2038
       */
2039
      target_new_objfile_chain = target_new_objfile_hook;
2040
      target_new_objfile_hook  = thread_db_new_objfile;
2041
    }
2042
#endif  /* HAVE_STDINT_H */
2043
}
2044
 

powered by: WebSVN 2.1.0

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