Fix typos and thinkos reported by Sun Ming (and one reported by John).
[deliverable/binutils-gdb.git] / gdb / procfs.c
CommitLineData
35f5886e 1/* Machine independent support for SVR4 /proc (process file system) for GDB.
ec8ceca3 2 Copyright 1991, 1992 Free Software Foundation, Inc.
35f5886e
FF
3 Written by Fred Fish at Cygnus Support.
4
5This file is part of GDB.
6
7This program is free software; you can redistribute it and/or modify
8it under the terms of the GNU General Public License as published by
9the Free Software Foundation; either version 2 of the License, or
10(at your option) any later version.
11
12This program is distributed in the hope that it will be useful,
13but WITHOUT ANY WARRANTY; without even the implied warranty of
14MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15GNU General Public License for more details.
16
17You should have received a copy of the GNU General Public License
18along with this program; if not, write to the Free Software
19Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */
20
21
22/* N O T E S
23
24For information on the details of using /proc consult section proc(4)
25in the UNIX System V Release 4 System Administrator's Reference Manual.
26
27The general register and floating point register sets are manipulated by
28separate ioctl's. This file makes the assumption that if FP0_REGNUM is
29defined, then support for the floating point register set is desired,
30regardless of whether or not the actual target has floating point hardware.
31
32 */
33
34
5129100c 35#include "defs.h"
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36
37#ifdef USE_PROC_FS /* Entire file goes away if not using /proc */
38
407a8389 39#include <time.h>
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40#include <sys/procfs.h>
41#include <fcntl.h>
42#include <errno.h>
51b57ded 43#include <string.h>
35f5886e 44
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45#include "inferior.h"
46#include "target.h"
51b57ded 47#include "command.h"
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48
49#define MAX_SYSCALLS 256 /* Maximum number of syscalls for table */
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50
51#ifndef PROC_NAME_FMT
6c316cfd 52#define PROC_NAME_FMT "/proc/%05d"
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53#endif
54
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55#if 1 /* FIXME: Gross and ugly hack to resolve coredep.c global */
56CORE_ADDR kernel_u_addr;
57#endif
58
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59#ifdef BROKEN_SIGINFO_H /* Workaround broken SGS <sys/siginfo.h> */
60#undef si_pid
61#define si_pid _data._proc.pid
62#undef si_uid
63#define si_uid _data._proc._pdata._kill.uid
64#endif /* BROKEN_SIGINFO_H */
65
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66/* All access to the inferior, either one started by gdb or one that has
67 been attached to, is controlled by an instance of a procinfo structure,
68 defined below. Since gdb currently only handles one inferior at a time,
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69 the procinfo structure for the inferior is statically allocated and
70 only one exists at any given time. There is a separate procinfo
71 structure for use by the "info proc" command, so that we can print
72 useful information about any random process without interfering with
73 the inferior's procinfo information. */
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74
75struct procinfo {
76 int valid; /* Nonzero if pid, fd, & pathname are valid */
77 int pid; /* Process ID of inferior */
78 int fd; /* File descriptor for /proc entry */
79 char *pathname; /* Pathname to /proc entry */
80 int was_stopped; /* Nonzero if was stopped prior to attach */
d65eee73 81 int nopass_next_sigstop; /* Don't pass a sigstop on next resume */
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82 prrun_t prrun; /* Control state when it is run */
83 prstatus_t prstatus; /* Current process status info */
84 gregset_t gregset; /* General register set */
85 fpregset_t fpregset; /* Floating point register set */
86 fltset_t fltset; /* Current traced hardware fault set */
87 sigset_t trace; /* Current traced signal set */
88 sysset_t exitset; /* Current traced system call exit set */
89 sysset_t entryset; /* Current traced system call entry set */
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90 fltset_t saved_fltset; /* Saved traced hardware fault set */
91 sigset_t saved_trace; /* Saved traced signal set */
92 sigset_t saved_sighold; /* Saved held signal set */
93 sysset_t saved_exitset; /* Saved traced system call exit set */
94 sysset_t saved_entryset; /* Saved traced system call entry set */
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95};
96
97static struct procinfo pi; /* Inferior's process information */
35f5886e 98
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99/* Much of the information used in the /proc interface, particularly for
100 printing status information, is kept as tables of structures of the
101 following form. These tables can be used to map numeric values to
102 their symbolic names and to a string that describes their specific use. */
103
104struct trans {
105 int value; /* The numeric value */
106 char *name; /* The equivalent symbolic value */
107 char *desc; /* Short description of value */
108};
109
110/* Translate bits in the pr_flags member of the prstatus structure, into the
111 names and desc information. */
112
113static struct trans pr_flag_table[] =
114{
115#if defined (PR_STOPPED)
116 PR_STOPPED, "PR_STOPPED", "Process is stopped",
117#endif
118#if defined (PR_ISTOP)
119 PR_ISTOP, "PR_ISTOP", "Stopped on an event of interest",
120#endif
121#if defined (PR_DSTOP)
122 PR_DSTOP, "PR_DSTOP", "A stop directive is in effect",
123#endif
124#if defined (PR_ASLEEP)
125 PR_ASLEEP, "PR_ASLEEP", "Sleeping in an interruptible system call",
126#endif
127#if defined (PR_FORK)
128 PR_FORK, "PR_FORK", "Inherit-on-fork is in effect",
129#endif
130#if defined (PR_RLC)
131 PR_RLC, "PR_RLC", "Run-on-last-close is in effect",
132#endif
133#if defined (PR_PTRACE)
134 PR_PTRACE, "PR_PTRACE", "Process is being controlled by ptrace",
135#endif
136#if defined (PR_PCINVAL)
137 PR_PCINVAL, "PR_PCINVAL", "PC refers to an invalid virtual address",
138#endif
139#if defined (PR_ISSYS)
140 PR_ISSYS, "PR_ISSYS", "Is a system process",
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141#endif
142#if defined (PR_STEP)
143 PR_STEP, "PR_STEP", "Process has single step pending",
144#endif
145#if defined (PR_KLC)
146 PR_KLC, "PR_KLC", "Kill-on-last-close is in effect",
147#endif
148#if defined (PR_ASYNC)
149 PR_ASYNC, "PR_ASYNC", "Asynchronous stop is in effect",
150#endif
151#if defined (PR_PCOMPAT)
152 PR_PCOMPAT, "PR_PCOMPAT", "Ptrace compatibility mode in effect",
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153#endif
154 0, NULL, NULL
155};
156
157/* Translate values in the pr_why field of the prstatus struct. */
158
159static struct trans pr_why_table[] =
160{
161#if defined (PR_REQUESTED)
162 PR_REQUESTED, "PR_REQUESTED", "Directed to stop via PIOCSTOP/PIOCWSTOP",
163#endif
164#if defined (PR_SIGNALLED)
165 PR_SIGNALLED, "PR_SIGNALLED", "Receipt of a traced signal",
166#endif
167#if defined (PR_FAULTED)
168 PR_FAULTED, "PR_FAULTED", "Incurred a traced hardware fault",
169#endif
170#if defined (PR_SYSENTRY)
171 PR_SYSENTRY, "PR_SYSENTRY", "Entry to a traced system call",
172#endif
173#if defined (PR_SYSEXIT)
174 PR_SYSEXIT, "PR_SYSEXIT", "Exit from a traced system call",
175#endif
176#if defined (PR_JOBCONTROL)
177 PR_JOBCONTROL, "PR_JOBCONTROL", "Default job control stop signal action",
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178#endif
179#if defined (PR_SUSPENDED)
180 PR_SUSPENDED, "PR_SUSPENDED", "Process suspended",
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181#endif
182 0, NULL, NULL
183};
184
185/* Hardware fault translation table. */
186
187static struct trans faults_table[] =
188{
189#if defined (FLTILL)
190 FLTILL, "FLTILL", "Illegal instruction",
191#endif
192#if defined (FLTPRIV)
193 FLTPRIV, "FLTPRIV", "Privileged instruction",
194#endif
195#if defined (FLTBPT)
196 FLTBPT, "FLTBPT", "Breakpoint trap",
197#endif
198#if defined (FLTTRACE)
199 FLTTRACE, "FLTTRACE", "Trace trap",
200#endif
201#if defined (FLTACCESS)
202 FLTACCESS, "FLTACCESS", "Memory access fault",
203#endif
204#if defined (FLTBOUNDS)
205 FLTBOUNDS, "FLTBOUNDS", "Memory bounds violation",
206#endif
207#if defined (FLTIOVF)
208 FLTIOVF, "FLTIOVF", "Integer overflow",
209#endif
210#if defined (FLTIZDIV)
211 FLTIZDIV, "FLTIZDIV", "Integer zero divide",
212#endif
213#if defined (FLTFPE)
214 FLTFPE, "FLTFPE", "Floating-point exception",
215#endif
216#if defined (FLTSTACK)
217 FLTSTACK, "FLTSTACK", "Unrecoverable stack fault",
218#endif
219#if defined (FLTPAGE)
220 FLTPAGE, "FLTPAGE", "Recoverable page fault",
221#endif
222 0, NULL, NULL
223};
224
225/* Translation table for signal generation information. See UNIX System
226 V Release 4 Programmer's Reference Manual, siginfo(5). */
227
228static struct sigcode {
229 int signo;
230 int code;
231 char *codename;
232 char *desc;
233} siginfo_table[] = {
234#if defined (SIGILL) && defined (ILL_ILLOPC)
235 SIGILL, ILL_ILLOPC, "ILL_ILLOPC", "Illegal opcode",
236#endif
237#if defined (SIGILL) && defined (ILL_ILLOPN)
238 SIGILL, ILL_ILLOPN, "ILL_ILLOPN", "Illegal operand",
239#endif
240#if defined (SIGILL) && defined (ILL_ILLADR)
241 SIGILL, ILL_ILLADR, "ILL_ILLADR", "Illegal addressing mode",
242#endif
243#if defined (SIGILL) && defined (ILL_ILLTRP)
244 SIGILL, ILL_ILLTRP, "ILL_ILLTRP", "Illegal trap",
245#endif
246#if defined (SIGILL) && defined (ILL_PRVOPC)
247 SIGILL, ILL_PRVOPC, "ILL_PRVOPC", "Privileged opcode",
248#endif
249#if defined (SIGILL) && defined (ILL_PRVREG)
250 SIGILL, ILL_PRVREG, "ILL_PRVREG", "Privileged register",
251#endif
252#if defined (SIGILL) && defined (ILL_COPROC)
253 SIGILL, ILL_COPROC, "ILL_COPROC", "Coprocessor error",
254#endif
255#if defined (SIGILL) && defined (ILL_BADSTK)
256 SIGILL, ILL_BADSTK, "ILL_BADSTK", "Internal stack error",
257#endif
258#if defined (SIGFPE) && defined (FPE_INTDIV)
259 SIGFPE, FPE_INTDIV, "FPE_INTDIV", "Integer divide by zero",
260#endif
261#if defined (SIGFPE) && defined (FPE_INTOVF)
262 SIGFPE, FPE_INTOVF, "FPE_INTOVF", "Integer overflow",
263#endif
264#if defined (SIGFPE) && defined (FPE_FLTDIV)
265 SIGFPE, FPE_FLTDIV, "FPE_FLTDIV", "Floating point divide by zero",
266#endif
267#if defined (SIGFPE) && defined (FPE_FLTOVF)
268 SIGFPE, FPE_FLTOVF, "FPE_FLTOVF", "Floating point overflow",
269#endif
270#if defined (SIGFPE) && defined (FPE_FLTUND)
271 SIGFPE, FPE_FLTUND, "FPE_FLTUND", "Floating point underflow",
272#endif
273#if defined (SIGFPE) && defined (FPE_FLTRES)
274 SIGFPE, FPE_FLTRES, "FPE_FLTRES", "Floating point inexact result",
275#endif
276#if defined (SIGFPE) && defined (FPE_FLTINV)
277 SIGFPE, FPE_FLTINV, "FPE_FLTINV", "Invalid floating point operation",
278#endif
279#if defined (SIGFPE) && defined (FPE_FLTSUB)
280 SIGFPE, FPE_FLTSUB, "FPE_FLTSUB", "Subscript out of range",
281#endif
282#if defined (SIGSEGV) && defined (SEGV_MAPERR)
283 SIGSEGV, SEGV_MAPERR, "SEGV_MAPERR", "Address not mapped to object",
284#endif
285#if defined (SIGSEGV) && defined (SEGV_ACCERR)
286 SIGSEGV, SEGV_ACCERR, "SEGV_ACCERR", "Invalid permissions for object",
287#endif
288#if defined (SIGBUS) && defined (BUS_ADRALN)
289 SIGBUS, BUS_ADRALN, "BUS_ADRALN", "Invalid address alignment",
290#endif
291#if defined (SIGBUS) && defined (BUS_ADRERR)
292 SIGBUS, BUS_ADRERR, "BUS_ADRERR", "Non-existent physical address",
293#endif
294#if defined (SIGBUS) && defined (BUS_OBJERR)
295 SIGBUS, BUS_OBJERR, "BUS_OBJERR", "Object specific hardware error",
296#endif
297#if defined (SIGTRAP) && defined (TRAP_BRKPT)
298 SIGTRAP, TRAP_BRKPT, "TRAP_BRKPT", "Process breakpoint",
299#endif
300#if defined (SIGTRAP) && defined (TRAP_TRACE)
301 SIGTRAP, TRAP_TRACE, "TRAP_TRACE", "Process trace trap",
302#endif
303#if defined (SIGCLD) && defined (CLD_EXITED)
304 SIGCLD, CLD_EXITED, "CLD_EXITED", "Child has exited",
305#endif
306#if defined (SIGCLD) && defined (CLD_KILLED)
307 SIGCLD, CLD_KILLED, "CLD_KILLED", "Child was killed",
308#endif
309#if defined (SIGCLD) && defined (CLD_DUMPED)
310 SIGCLD, CLD_DUMPED, "CLD_DUMPED", "Child has terminated abnormally",
311#endif
312#if defined (SIGCLD) && defined (CLD_TRAPPED)
313 SIGCLD, CLD_TRAPPED, "CLD_TRAPPED", "Traced child has trapped",
314#endif
315#if defined (SIGCLD) && defined (CLD_STOPPED)
316 SIGCLD, CLD_STOPPED, "CLD_STOPPED", "Child has stopped",
317#endif
318#if defined (SIGCLD) && defined (CLD_CONTINUED)
319 SIGCLD, CLD_CONTINUED, "CLD_CONTINUED", "Stopped child had continued",
320#endif
321#if defined (SIGPOLL) && defined (POLL_IN)
322 SIGPOLL, POLL_IN, "POLL_IN", "Input input available",
323#endif
324#if defined (SIGPOLL) && defined (POLL_OUT)
325 SIGPOLL, POLL_OUT, "POLL_OUT", "Output buffers available",
326#endif
327#if defined (SIGPOLL) && defined (POLL_MSG)
328 SIGPOLL, POLL_MSG, "POLL_MSG", "Input message available",
329#endif
330#if defined (SIGPOLL) && defined (POLL_ERR)
331 SIGPOLL, POLL_ERR, "POLL_ERR", "I/O error",
332#endif
333#if defined (SIGPOLL) && defined (POLL_PRI)
334 SIGPOLL, POLL_PRI, "POLL_PRI", "High priority input available",
335#endif
336#if defined (SIGPOLL) && defined (POLL_HUP)
337 SIGPOLL, POLL_HUP, "POLL_HUP", "Device disconnected",
338#endif
339 0, 0, NULL, NULL
340};
341
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342static char *syscall_table[MAX_SYSCALLS];
343
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344/* Prototypes for local functions */
345
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346static void
347set_proc_siginfo PARAMS ((struct procinfo *, int));
348
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349static void
350init_syscall_table PARAMS ((void));
351
352static char *
353syscallname PARAMS ((int));
354
355static char *
356signalname PARAMS ((int));
357
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358static char *
359errnoname PARAMS ((int));
360
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361static int
362proc_address_to_fd PARAMS ((CORE_ADDR, int));
363
364static int
ec8ceca3 365open_proc_file PARAMS ((int, struct procinfo *, int));
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366
367static void
368close_proc_file PARAMS ((struct procinfo *));
369
370static void
371unconditionally_kill_inferior PARAMS ((void));
372
373static void
374proc_init_failed PARAMS ((char *));
375
376static void
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377info_proc PARAMS ((char *, int));
378
379static void
380info_proc_flags PARAMS ((struct procinfo *, int));
381
382static void
383info_proc_stop PARAMS ((struct procinfo *, int));
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384
385static void
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386info_proc_siginfo PARAMS ((struct procinfo *, int));
387
388static void
389info_proc_syscalls PARAMS ((struct procinfo *, int));
390
391static void
392info_proc_mappings PARAMS ((struct procinfo *, int));
393
394static void
395info_proc_signals PARAMS ((struct procinfo *, int));
396
397static void
398info_proc_faults PARAMS ((struct procinfo *, int));
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399
400static char *
401mappingflags PARAMS ((long));
402
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403static char *
404lookupname PARAMS ((struct trans *, unsigned int, char *));
405
406static char *
407lookupdesc PARAMS ((struct trans *, unsigned int));
408
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409/* External function prototypes that can't be easily included in any
410 header file because the args are typedefs in system include files. */
411
412extern void
413supply_gregset PARAMS ((gregset_t *));
414
415extern void
416fill_gregset PARAMS ((gregset_t *, int));
417
418extern void
419supply_fpregset PARAMS ((fpregset_t *));
420
421extern void
422fill_fpregset PARAMS ((fpregset_t *, int));
35f5886e 423
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424/*
425
426LOCAL FUNCTION
427
428 lookupdesc -- translate a value to a summary desc string
429
430SYNOPSIS
431
432 static char *lookupdesc (struct trans *transp, unsigned int val);
433
434DESCRIPTION
435
436 Given a pointer to a translation table and a value to be translated,
437 lookup the desc string and return it.
438 */
439
440static char *
441lookupdesc (transp, val)
442 struct trans *transp;
443 unsigned int val;
444{
445 char *desc;
446
447 for (desc = NULL; transp -> name != NULL; transp++)
448 {
449 if (transp -> value == val)
450 {
451 desc = transp -> desc;
452 break;
453 }
454 }
455
456 /* Didn't find a translation for the specified value, set a default one. */
457
458 if (desc == NULL)
459 {
460 desc = "Unknown";
461 }
462 return (desc);
463}
464
465/*
466
467LOCAL FUNCTION
468
469 lookupname -- translate a value to symbolic name
470
471SYNOPSIS
472
473 static char *lookupname (struct trans *transp, unsigned int val,
474 char *prefix);
475
476DESCRIPTION
477
478 Given a pointer to a translation table, a value to be translated,
479 and a default prefix to return if the value can't be translated,
480 match the value with one of the translation table entries and
481 return a pointer to the symbolic name.
482
483 If no match is found it just returns the value as a printable string,
484 with the given prefix. The previous such value, if any, is freed
485 at this time.
486 */
487
488static char *
489lookupname (transp, val, prefix)
490 struct trans *transp;
491 unsigned int val;
492 char *prefix;
493{
494 static char *locbuf;
495 char *name;
496
497 for (name = NULL; transp -> name != NULL; transp++)
498 {
499 if (transp -> value == val)
500 {
501 name = transp -> name;
502 break;
503 }
504 }
505
506 /* Didn't find a translation for the specified value, build a default
507 one using the specified prefix and return it. The lifetime of
508 the value is only until the next one is needed. */
509
510 if (name == NULL)
511 {
512 if (locbuf != NULL)
513 {
514 free (locbuf);
515 }
516 locbuf = xmalloc (strlen (prefix) + 16);
4ed3a9ea 517 sprintf (locbuf, "%s %u", prefix, val);
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518 name = locbuf;
519 }
520 return (name);
521}
522
523static char *
524sigcodename (sip)
525 siginfo_t *sip;
526{
527 struct sigcode *scp;
528 char *name = NULL;
529 static char locbuf[32];
530
531 for (scp = siginfo_table; scp -> codename != NULL; scp++)
532 {
533 if ((scp -> signo == sip -> si_signo) &&
534 (scp -> code == sip -> si_code))
535 {
536 name = scp -> codename;
537 break;
538 }
539 }
540 if (name == NULL)
541 {
4ed3a9ea 542 sprintf (locbuf, "sigcode %u", sip -> si_signo);
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543 name = locbuf;
544 }
545 return (name);
546}
547
548static char *sigcodedesc (sip)
549 siginfo_t *sip;
550{
551 struct sigcode *scp;
552 char *desc = NULL;
553
554 for (scp = siginfo_table; scp -> codename != NULL; scp++)
555 {
556 if ((scp -> signo == sip -> si_signo) &&
557 (scp -> code == sip -> si_code))
558 {
559 desc = scp -> desc;
560 break;
561 }
562 }
563 if (desc == NULL)
564 {
565 desc = "Unrecognized signal or trap use";
566 }
567 return (desc);
568}
569
570/*
571
572LOCAL FUNCTION
573
574 syscallname - translate a system call number into a system call name
575
576SYNOPSIS
577
578 char *syscallname (int syscallnum)
579
580DESCRIPTION
581
582 Given a system call number, translate it into the printable name
583 of a system call, or into "syscall <num>" if it is an unknown
584 number.
585 */
586
587static char *
588syscallname (syscallnum)
589 int syscallnum;
590{
591 static char locbuf[32];
592 char *rtnval;
593
594 if (syscallnum >= 0 && syscallnum < MAX_SYSCALLS)
595 {
596 rtnval = syscall_table[syscallnum];
597 }
598 else
599 {
4ed3a9ea 600 sprintf (locbuf, "syscall %u", syscallnum);
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601 rtnval = locbuf;
602 }
603 return (rtnval);
604}
605
606/*
607
608LOCAL FUNCTION
609
610 init_syscall_table - initialize syscall translation table
611
612SYNOPSIS
613
614 void init_syscall_table (void)
615
616DESCRIPTION
617
618 Dynamically initialize the translation table to convert system
619 call numbers into printable system call names. Done once per
620 gdb run, on initialization.
621
622NOTES
623
624 This is awfully ugly, but preprocessor tricks to make it prettier
625 tend to be nonportable.
626 */
627
628static void
629init_syscall_table ()
630{
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631#if defined (SYS_exit)
632 syscall_table[SYS_exit] = "exit";
633#endif
634#if defined (SYS_fork)
635 syscall_table[SYS_fork] = "fork";
636#endif
637#if defined (SYS_read)
638 syscall_table[SYS_read] = "read";
639#endif
640#if defined (SYS_write)
641 syscall_table[SYS_write] = "write";
642#endif
643#if defined (SYS_open)
644 syscall_table[SYS_open] = "open";
645#endif
646#if defined (SYS_close)
647 syscall_table[SYS_close] = "close";
648#endif
649#if defined (SYS_wait)
650 syscall_table[SYS_wait] = "wait";
651#endif
652#if defined (SYS_creat)
653 syscall_table[SYS_creat] = "creat";
654#endif
655#if defined (SYS_link)
656 syscall_table[SYS_link] = "link";
657#endif
658#if defined (SYS_unlink)
659 syscall_table[SYS_unlink] = "unlink";
660#endif
661#if defined (SYS_exec)
662 syscall_table[SYS_exec] = "exec";
663#endif
664#if defined (SYS_execv)
665 syscall_table[SYS_execv] = "execv";
666#endif
667#if defined (SYS_execve)
668 syscall_table[SYS_execve] = "execve";
669#endif
670#if defined (SYS_chdir)
671 syscall_table[SYS_chdir] = "chdir";
672#endif
673#if defined (SYS_time)
674 syscall_table[SYS_time] = "time";
675#endif
676#if defined (SYS_mknod)
677 syscall_table[SYS_mknod] = "mknod";
678#endif
679#if defined (SYS_chmod)
680 syscall_table[SYS_chmod] = "chmod";
681#endif
682#if defined (SYS_chown)
683 syscall_table[SYS_chown] = "chown";
684#endif
685#if defined (SYS_brk)
686 syscall_table[SYS_brk] = "brk";
687#endif
688#if defined (SYS_stat)
689 syscall_table[SYS_stat] = "stat";
690#endif
691#if defined (SYS_lseek)
692 syscall_table[SYS_lseek] = "lseek";
693#endif
694#if defined (SYS_getpid)
695 syscall_table[SYS_getpid] = "getpid";
696#endif
697#if defined (SYS_mount)
698 syscall_table[SYS_mount] = "mount";
699#endif
700#if defined (SYS_umount)
701 syscall_table[SYS_umount] = "umount";
702#endif
703#if defined (SYS_setuid)
704 syscall_table[SYS_setuid] = "setuid";
705#endif
706#if defined (SYS_getuid)
707 syscall_table[SYS_getuid] = "getuid";
708#endif
709#if defined (SYS_stime)
710 syscall_table[SYS_stime] = "stime";
711#endif
712#if defined (SYS_ptrace)
713 syscall_table[SYS_ptrace] = "ptrace";
714#endif
715#if defined (SYS_alarm)
716 syscall_table[SYS_alarm] = "alarm";
717#endif
718#if defined (SYS_fstat)
719 syscall_table[SYS_fstat] = "fstat";
720#endif
721#if defined (SYS_pause)
722 syscall_table[SYS_pause] = "pause";
723#endif
724#if defined (SYS_utime)
725 syscall_table[SYS_utime] = "utime";
726#endif
727#if defined (SYS_stty)
728 syscall_table[SYS_stty] = "stty";
729#endif
730#if defined (SYS_gtty)
731 syscall_table[SYS_gtty] = "gtty";
732#endif
733#if defined (SYS_access)
734 syscall_table[SYS_access] = "access";
735#endif
736#if defined (SYS_nice)
737 syscall_table[SYS_nice] = "nice";
738#endif
739#if defined (SYS_statfs)
740 syscall_table[SYS_statfs] = "statfs";
741#endif
742#if defined (SYS_sync)
743 syscall_table[SYS_sync] = "sync";
744#endif
745#if defined (SYS_kill)
746 syscall_table[SYS_kill] = "kill";
747#endif
748#if defined (SYS_fstatfs)
749 syscall_table[SYS_fstatfs] = "fstatfs";
750#endif
751#if defined (SYS_pgrpsys)
752 syscall_table[SYS_pgrpsys] = "pgrpsys";
753#endif
754#if defined (SYS_xenix)
755 syscall_table[SYS_xenix] = "xenix";
756#endif
757#if defined (SYS_dup)
758 syscall_table[SYS_dup] = "dup";
759#endif
760#if defined (SYS_pipe)
761 syscall_table[SYS_pipe] = "pipe";
762#endif
763#if defined (SYS_times)
764 syscall_table[SYS_times] = "times";
765#endif
766#if defined (SYS_profil)
767 syscall_table[SYS_profil] = "profil";
768#endif
769#if defined (SYS_plock)
770 syscall_table[SYS_plock] = "plock";
771#endif
772#if defined (SYS_setgid)
773 syscall_table[SYS_setgid] = "setgid";
774#endif
775#if defined (SYS_getgid)
776 syscall_table[SYS_getgid] = "getgid";
777#endif
778#if defined (SYS_signal)
779 syscall_table[SYS_signal] = "signal";
780#endif
781#if defined (SYS_msgsys)
782 syscall_table[SYS_msgsys] = "msgsys";
783#endif
784#if defined (SYS_sys3b)
785 syscall_table[SYS_sys3b] = "sys3b";
786#endif
787#if defined (SYS_acct)
788 syscall_table[SYS_acct] = "acct";
789#endif
790#if defined (SYS_shmsys)
791 syscall_table[SYS_shmsys] = "shmsys";
792#endif
793#if defined (SYS_semsys)
794 syscall_table[SYS_semsys] = "semsys";
795#endif
796#if defined (SYS_ioctl)
797 syscall_table[SYS_ioctl] = "ioctl";
798#endif
799#if defined (SYS_uadmin)
800 syscall_table[SYS_uadmin] = "uadmin";
801#endif
802#if defined (SYS_utssys)
803 syscall_table[SYS_utssys] = "utssys";
804#endif
805#if defined (SYS_fsync)
806 syscall_table[SYS_fsync] = "fsync";
807#endif
808#if defined (SYS_umask)
809 syscall_table[SYS_umask] = "umask";
810#endif
811#if defined (SYS_chroot)
812 syscall_table[SYS_chroot] = "chroot";
813#endif
814#if defined (SYS_fcntl)
815 syscall_table[SYS_fcntl] = "fcntl";
816#endif
817#if defined (SYS_ulimit)
818 syscall_table[SYS_ulimit] = "ulimit";
819#endif
820#if defined (SYS_rfsys)
821 syscall_table[SYS_rfsys] = "rfsys";
822#endif
823#if defined (SYS_rmdir)
824 syscall_table[SYS_rmdir] = "rmdir";
825#endif
826#if defined (SYS_mkdir)
827 syscall_table[SYS_mkdir] = "mkdir";
828#endif
829#if defined (SYS_getdents)
830 syscall_table[SYS_getdents] = "getdents";
831#endif
832#if defined (SYS_sysfs)
833 syscall_table[SYS_sysfs] = "sysfs";
834#endif
835#if defined (SYS_getmsg)
836 syscall_table[SYS_getmsg] = "getmsg";
837#endif
838#if defined (SYS_putmsg)
839 syscall_table[SYS_putmsg] = "putmsg";
840#endif
841#if defined (SYS_poll)
842 syscall_table[SYS_poll] = "poll";
843#endif
844#if defined (SYS_lstat)
845 syscall_table[SYS_lstat] = "lstat";
846#endif
847#if defined (SYS_symlink)
848 syscall_table[SYS_symlink] = "symlink";
849#endif
850#if defined (SYS_readlink)
851 syscall_table[SYS_readlink] = "readlink";
852#endif
853#if defined (SYS_setgroups)
854 syscall_table[SYS_setgroups] = "setgroups";
855#endif
856#if defined (SYS_getgroups)
857 syscall_table[SYS_getgroups] = "getgroups";
858#endif
859#if defined (SYS_fchmod)
860 syscall_table[SYS_fchmod] = "fchmod";
861#endif
862#if defined (SYS_fchown)
863 syscall_table[SYS_fchown] = "fchown";
864#endif
865#if defined (SYS_sigprocmask)
866 syscall_table[SYS_sigprocmask] = "sigprocmask";
867#endif
868#if defined (SYS_sigsuspend)
869 syscall_table[SYS_sigsuspend] = "sigsuspend";
870#endif
871#if defined (SYS_sigaltstack)
872 syscall_table[SYS_sigaltstack] = "sigaltstack";
873#endif
874#if defined (SYS_sigaction)
875 syscall_table[SYS_sigaction] = "sigaction";
876#endif
877#if defined (SYS_sigpending)
878 syscall_table[SYS_sigpending] = "sigpending";
879#endif
880#if defined (SYS_context)
881 syscall_table[SYS_context] = "context";
882#endif
883#if defined (SYS_evsys)
884 syscall_table[SYS_evsys] = "evsys";
885#endif
886#if defined (SYS_evtrapret)
887 syscall_table[SYS_evtrapret] = "evtrapret";
888#endif
889#if defined (SYS_statvfs)
890 syscall_table[SYS_statvfs] = "statvfs";
891#endif
892#if defined (SYS_fstatvfs)
893 syscall_table[SYS_fstatvfs] = "fstatvfs";
894#endif
895#if defined (SYS_nfssys)
896 syscall_table[SYS_nfssys] = "nfssys";
897#endif
898#if defined (SYS_waitsys)
899 syscall_table[SYS_waitsys] = "waitsys";
900#endif
901#if defined (SYS_sigsendsys)
902 syscall_table[SYS_sigsendsys] = "sigsendsys";
903#endif
904#if defined (SYS_hrtsys)
905 syscall_table[SYS_hrtsys] = "hrtsys";
906#endif
907#if defined (SYS_acancel)
908 syscall_table[SYS_acancel] = "acancel";
909#endif
910#if defined (SYS_async)
911 syscall_table[SYS_async] = "async";
912#endif
913#if defined (SYS_priocntlsys)
914 syscall_table[SYS_priocntlsys] = "priocntlsys";
915#endif
916#if defined (SYS_pathconf)
917 syscall_table[SYS_pathconf] = "pathconf";
918#endif
919#if defined (SYS_mincore)
920 syscall_table[SYS_mincore] = "mincore";
921#endif
922#if defined (SYS_mmap)
923 syscall_table[SYS_mmap] = "mmap";
924#endif
925#if defined (SYS_mprotect)
926 syscall_table[SYS_mprotect] = "mprotect";
927#endif
928#if defined (SYS_munmap)
929 syscall_table[SYS_munmap] = "munmap";
930#endif
931#if defined (SYS_fpathconf)
932 syscall_table[SYS_fpathconf] = "fpathconf";
933#endif
934#if defined (SYS_vfork)
935 syscall_table[SYS_vfork] = "vfork";
936#endif
937#if defined (SYS_fchdir)
938 syscall_table[SYS_fchdir] = "fchdir";
939#endif
940#if defined (SYS_readv)
941 syscall_table[SYS_readv] = "readv";
942#endif
943#if defined (SYS_writev)
944 syscall_table[SYS_writev] = "writev";
945#endif
946#if defined (SYS_xstat)
947 syscall_table[SYS_xstat] = "xstat";
948#endif
949#if defined (SYS_lxstat)
950 syscall_table[SYS_lxstat] = "lxstat";
951#endif
952#if defined (SYS_fxstat)
953 syscall_table[SYS_fxstat] = "fxstat";
954#endif
955#if defined (SYS_xmknod)
956 syscall_table[SYS_xmknod] = "xmknod";
957#endif
958#if defined (SYS_clocal)
959 syscall_table[SYS_clocal] = "clocal";
960#endif
961#if defined (SYS_setrlimit)
962 syscall_table[SYS_setrlimit] = "setrlimit";
963#endif
964#if defined (SYS_getrlimit)
965 syscall_table[SYS_getrlimit] = "getrlimit";
966#endif
967#if defined (SYS_lchown)
968 syscall_table[SYS_lchown] = "lchown";
969#endif
970#if defined (SYS_memcntl)
971 syscall_table[SYS_memcntl] = "memcntl";
972#endif
973#if defined (SYS_getpmsg)
974 syscall_table[SYS_getpmsg] = "getpmsg";
975#endif
976#if defined (SYS_putpmsg)
977 syscall_table[SYS_putpmsg] = "putpmsg";
978#endif
979#if defined (SYS_rename)
980 syscall_table[SYS_rename] = "rename";
981#endif
982#if defined (SYS_uname)
983 syscall_table[SYS_uname] = "uname";
984#endif
985#if defined (SYS_setegid)
986 syscall_table[SYS_setegid] = "setegid";
987#endif
988#if defined (SYS_sysconfig)
989 syscall_table[SYS_sysconfig] = "sysconfig";
990#endif
991#if defined (SYS_adjtime)
992 syscall_table[SYS_adjtime] = "adjtime";
993#endif
994#if defined (SYS_systeminfo)
995 syscall_table[SYS_systeminfo] = "systeminfo";
996#endif
997#if defined (SYS_seteuid)
998 syscall_table[SYS_seteuid] = "seteuid";
999#endif
1000}
35f5886e
FF
1001
1002/*
1003
1004GLOBAL FUNCTION
1005
1006 ptrace -- override library version to force errors for /proc version
1007
1008SYNOPSIS
1009
e676a15f 1010 int ptrace (int request, int pid, PTRACE_ARG3_TYPE arg3, int arg4)
35f5886e
FF
1011
1012DESCRIPTION
1013
1014 When gdb is configured to use /proc, it should not be calling
1015 or otherwise attempting to use ptrace. In order to catch errors
1016 where use of /proc is configured, but some routine is still calling
1017 ptrace, we provide a local version of a function with that name
1018 that does nothing but issue an error message.
1019*/
1020
1021int
1ab3bf1b
JG
1022ptrace (request, pid, arg3, arg4)
1023 int request;
1024 int pid;
e676a15f 1025 PTRACE_ARG3_TYPE arg3;
1ab3bf1b 1026 int arg4;
35f5886e
FF
1027{
1028 error ("internal error - there is a call to ptrace() somewhere");
1029 /*NOTREACHED*/
1030}
1031
1032/*
1033
1034GLOBAL FUNCTION
1035
1036 kill_inferior_fast -- kill inferior while gdb is exiting
1037
1038SYNOPSIS
1039
1040 void kill_inferior_fast (void)
1041
1042DESCRIPTION
1043
1044 This is used when GDB is exiting. It gives less chance of error.
1045
1046NOTES
1047
1048 Don't attempt to kill attached inferiors since we may be called
1049 when gdb is in the process of aborting, and killing the attached
1050 inferior may be very anti-social. This is particularly true if we
1051 were attached just so we could use the /proc facilities to get
1052 detailed information about it's status.
1053
1054*/
1055
1056void
1ab3bf1b 1057kill_inferior_fast ()
35f5886e
FF
1058{
1059 if (inferior_pid != 0 && !attach_flag)
1060 {
1061 unconditionally_kill_inferior ();
1062 }
1063}
1064
1065/*
1066
1067GLOBAL FUNCTION
1068
1069 kill_inferior - kill any currently inferior
1070
1071SYNOPSIS
1072
1073 void kill_inferior (void)
1074
1075DESCRIPTION
1076
1077 Kill any current inferior.
1078
1079NOTES
1080
1081 Kills even attached inferiors. Presumably the user has already
1082 been prompted that the inferior is an attached one rather than
1083 one started by gdb. (FIXME?)
1084
1085*/
1086
1087void
1ab3bf1b 1088kill_inferior ()
35f5886e
FF
1089{
1090 if (inferior_pid != 0)
1091 {
1092 unconditionally_kill_inferior ();
1093 target_mourn_inferior ();
1094 }
1095}
1096
1097/*
1098
1099LOCAL FUNCTION
1100
1101 unconditionally_kill_inferior - terminate the inferior
1102
1103SYNOPSIS
1104
1105 static void unconditionally_kill_inferior (void)
1106
1107DESCRIPTION
1108
1109 Kill the current inferior. Should not be called until it
1110 is at least tested that there is an inferior.
1111
1112NOTE
1113
1114 A possibly useful enhancement would be to first try sending
1115 the inferior a terminate signal, politely asking it to commit
1116 suicide, before we murder it.
1117
1118*/
1119
1120static void
1ab3bf1b 1121unconditionally_kill_inferior ()
35f5886e
FF
1122{
1123 int signo;
1124
1125 signo = SIGKILL;
4ed3a9ea 1126 ioctl (pi.fd, PIOCKILL, &signo);
a39ad5ce 1127 close_proc_file (&pi);
35f5886e
FF
1128 wait ((int *) 0);
1129}
1130
1131/*
1132
1133GLOBAL FUNCTION
1134
1135 child_xfer_memory -- copy data to or from inferior memory space
1136
1137SYNOPSIS
1138
1139 int child_xfer_memory (CORE_ADDR memaddr, char *myaddr, int len,
1140 int dowrite, struct target_ops target)
1141
1142DESCRIPTION
1143
1144 Copy LEN bytes to/from inferior's memory starting at MEMADDR
1145 from/to debugger memory starting at MYADDR. Copy from inferior
1146 if DOWRITE is zero or to inferior if DOWRITE is nonzero.
1147
1148 Returns the length copied, which is either the LEN argument or
1149 zero. This xfer function does not do partial moves, since child_ops
1150 doesn't allow memory operations to cross below us in the target stack
1151 anyway.
1152
1153NOTES
1154
1155 The /proc interface makes this an almost trivial task.
1156 */
1157
1158
1159int
1ab3bf1b
JG
1160child_xfer_memory (memaddr, myaddr, len, dowrite, target)
1161 CORE_ADDR memaddr;
1162 char *myaddr;
1163 int len;
1164 int dowrite;
1165 struct target_ops *target; /* ignored */
35f5886e
FF
1166{
1167 int nbytes = 0;
1168
1169 if (lseek (pi.fd, (off_t) memaddr, 0) == (off_t) memaddr)
1170 {
1171 if (dowrite)
1172 {
1173 nbytes = write (pi.fd, myaddr, len);
1174 }
1175 else
1176 {
1177 nbytes = read (pi.fd, myaddr, len);
1178 }
1179 if (nbytes < 0)
1180 {
1181 nbytes = 0;
1182 }
1183 }
1184 return (nbytes);
1185}
1186
1187/*
1188
1189GLOBAL FUNCTION
1190
1191 store_inferior_registers -- copy register values back to inferior
1192
1193SYNOPSIS
1194
1195 void store_inferior_registers (int regno)
1196
1197DESCRIPTION
1198
1199 Store our current register values back into the inferior. If
1200 REGNO is -1 then store all the register, otherwise store just
1201 the value specified by REGNO.
1202
1203NOTES
1204
1205 If we are storing only a single register, we first have to get all
1206 the current values from the process, overwrite the desired register
1207 in the gregset with the one we want from gdb's registers, and then
1208 send the whole set back to the process. For writing all the
1209 registers, all we have to do is generate the gregset and send it to
1210 the process.
1211
1212 Also note that the process has to be stopped on an event of interest
1213 for this to work, which basically means that it has to have been
1214 run under the control of one of the other /proc ioctl calls and not
1215 ptrace. Since we don't use ptrace anyway, we don't worry about this
1216 fine point, but it is worth noting for future reference.
1217
1218 Gdb is confused about what this function is supposed to return.
1219 Some versions return a value, others return nothing. Some are
1220 declared to return a value and actually return nothing. Gdb ignores
1221 anything returned. (FIXME)
1222
1223 */
1224
1225void
1ab3bf1b
JG
1226store_inferior_registers (regno)
1227 int regno;
35f5886e
FF
1228{
1229 if (regno != -1)
1230 {
4ed3a9ea 1231 ioctl (pi.fd, PIOCGREG, &pi.gregset);
35f5886e
FF
1232 }
1233 fill_gregset (&pi.gregset, regno);
4ed3a9ea 1234 ioctl (pi.fd, PIOCSREG, &pi.gregset);
35f5886e
FF
1235
1236#if defined (FP0_REGNUM)
1237
1238 /* Now repeat everything using the floating point register set, if the
1239 target has floating point hardware. Since we ignore the returned value,
1240 we'll never know whether it worked or not anyway. */
1241
1242 if (regno != -1)
1243 {
4ed3a9ea 1244 ioctl (pi.fd, PIOCGFPREG, &pi.fpregset);
35f5886e
FF
1245 }
1246 fill_fpregset (&pi.fpregset, regno);
4ed3a9ea 1247 ioctl (pi.fd, PIOCSFPREG, &pi.fpregset);
35f5886e
FF
1248
1249#endif /* FP0_REGNUM */
1250
1251}
1252
1253/*
1254
1255GLOBAL FUNCTION
1256
1257 inferior_proc_init - initialize access to a /proc entry
1258
1259SYNOPSIS
1260
1261 void inferior_proc_init (int pid)
1262
1263DESCRIPTION
1264
1265 When gdb starts an inferior, this function is called in the parent
1266 process immediately after the fork. It waits for the child to stop
1267 on the return from the exec system call (the child itself takes care
1268 of ensuring that this is set up), then sets up the set of signals
1269 and faults that are to be traced.
1270
1271NOTES
1272
1273 If proc_init_failed ever gets called, control returns to the command
1274 processing loop via the standard error handling code.
cc221e76 1275
35f5886e
FF
1276 */
1277
1278void
1ab3bf1b
JG
1279inferior_proc_init (pid)
1280 int pid;
35f5886e 1281{
ec8ceca3 1282 if (!open_proc_file (pid, &pi, O_RDWR))
35f5886e
FF
1283 {
1284 proc_init_failed ("can't open process file");
1285 }
1286 else
1287 {
4ed3a9ea 1288 memset ((char *) &pi.prrun, 0, sizeof (pi.prrun));
35f5886e 1289 prfillset (&pi.prrun.pr_trace);
cc221e76 1290 proc_signal_handling_change ();
35f5886e
FF
1291 prfillset (&pi.prrun.pr_fault);
1292 prdelset (&pi.prrun.pr_fault, FLTPAGE);
1293 if (ioctl (pi.fd, PIOCWSTOP, &pi.prstatus) < 0)
1294 {
1295 proc_init_failed ("PIOCWSTOP failed");
1296 }
35f5886e
FF
1297 else if (ioctl (pi.fd, PIOCSFAULT, &pi.prrun.pr_fault) < 0)
1298 {
1299 proc_init_failed ("PIOCSFAULT failed");
1300 }
1301 }
1302}
1303
1304/*
1305
cc221e76
FF
1306GLOBAL FUNCTION
1307
1308 proc_signal_handling_change
1309
1310SYNOPSIS
1311
1312 void proc_signal_handling_change (void);
1313
1314DESCRIPTION
1315
1316 When the user changes the state of gdb's signal handling via the
1317 "handle" command, this function gets called to see if any change
1318 in the /proc interface is required. It is also called internally
1319 by other /proc interface functions to initialize the state of
1320 the traced signal set.
1321
1322 One thing it does is that signals for which the state is "nostop",
1323 "noprint", and "pass", have their trace bits reset in the pr_trace
1324 field, so that they are no longer traced. This allows them to be
1325 delivered directly to the inferior without the debugger ever being
1326 involved.
1327 */
1328
1329void
1330proc_signal_handling_change ()
1331{
1332 int signo;
1333
1334 if (pi.valid)
1335 {
1336 for (signo = 0; signo < NSIG; signo++)
1337 {
1338 if (signal_stop_state (signo) == 0 &&
1339 signal_print_state (signo) == 0 &&
1340 signal_pass_state (signo) == 1)
1341 {
1342 prdelset (&pi.prrun.pr_trace, signo);
1343 }
1344 else
1345 {
1346 praddset (&pi.prrun.pr_trace, signo);
1347 }
1348 }
1349 if (ioctl (pi.fd, PIOCSTRACE, &pi.prrun.pr_trace))
1350 {
1351 print_sys_errmsg ("PIOCSTRACE failed", errno);
1352 }
1353 }
1354}
1355
1356/*
1357
35f5886e
FF
1358GLOBAL FUNCTION
1359
1360 proc_set_exec_trap -- arrange for exec'd child to halt at startup
1361
1362SYNOPSIS
1363
1364 void proc_set_exec_trap (void)
1365
1366DESCRIPTION
1367
1368 This function is called in the child process when starting up
1369 an inferior, prior to doing the exec of the actual inferior.
1370 It sets the child process's exitset to make exit from the exec
1371 system call an event of interest to stop on, and then simply
1372 returns. The child does the exec, the system call returns, and
1373 the child stops at the first instruction, ready for the gdb
1374 parent process to take control of it.
1375
1376NOTE
1377
1378 We need to use all local variables since the child may be sharing
1379 it's data space with the parent, if vfork was used rather than
1380 fork.
cc221e76
FF
1381
1382 Also note that we want to turn off the inherit-on-fork flag in
1383 the child process so that any grand-children start with all
1384 tracing flags cleared.
35f5886e
FF
1385 */
1386
1387void
1ab3bf1b 1388proc_set_exec_trap ()
35f5886e
FF
1389{
1390 sysset_t exitset;
1391 auto char procname[32];
1392 int fd;
1393
4ed3a9ea 1394 sprintf (procname, PROC_NAME_FMT, getpid ());
35f5886e
FF
1395 if ((fd = open (procname, O_RDWR)) < 0)
1396 {
1397 perror (procname);
1398 fflush (stderr);
1399 _exit (127);
1400 }
1401 premptyset (&exitset);
407a8389 1402
cc221e76
FF
1403 /* GW: Rationale...
1404 Not all systems with /proc have all the exec* syscalls with the same
1405 names. On the SGI, for example, there is no SYS_exec, but there
1406 *is* a SYS_execv. So, we try to account for that. */
1407
407a8389 1408#ifdef SYS_exec
35f5886e 1409 praddset (&exitset, SYS_exec);
407a8389
SG
1410#endif
1411#ifdef SYS_execve
35f5886e 1412 praddset (&exitset, SYS_execve);
407a8389
SG
1413#endif
1414#ifdef SYS_execv
1415 praddset(&exitset, SYS_execv);
1416#endif
1417
35f5886e
FF
1418 if (ioctl (fd, PIOCSEXIT, &exitset) < 0)
1419 {
1420 perror (procname);
1421 fflush (stderr);
1422 _exit (127);
1423 }
cc221e76
FF
1424
1425 /* Turn off inherit-on-fork flag so that all grand-children of gdb
1426 start with tracing flags cleared. */
1427
5c1c5e67 1428#if defined (PIOCRESET) /* New method */
cc221e76
FF
1429 {
1430 long pr_flags;
1431 pr_flags = PR_FORK;
4ed3a9ea 1432 ioctl (fd, PIOCRESET, &pr_flags);
cc221e76 1433 }
5c1c5e67
FF
1434#else
1435#if defined (PIOCRFORK) /* Original method */
4ed3a9ea 1436 ioctl (fd, PIOCRFORK, NULL);
cc221e76 1437#endif
ec8ceca3
JG
1438#endif
1439
1440 /* Turn on run-on-last-close flag so that this process will not hang
1441 if GDB goes away for some reason. */
1442
1443#if defined (PIOCSET) /* New method */
1444 {
1445 long pr_flags;
1446 pr_flags = PR_RLC;
1447 (void) ioctl (fd, PIOCSET, &pr_flags);
1448 }
1449#else
1450#if defined (PIOCSRLC) /* Original method */
1451 (void) ioctl (fd, PIOCSRLC, 0);
1452#endif
cc221e76 1453#endif
35f5886e
FF
1454}
1455
f8b76e70
FF
1456/*
1457
a39ad5ce
FF
1458GLOBAL FUNCTION
1459
1460 proc_iterate_over_mappings -- call function for every mapped space
1461
1462SYNOPSIS
1463
1464 int proc_iterate_over_mappings (int (*func)())
1465
1466DESCRIPTION
1467
1468 Given a pointer to a function, call that function for every
1469 mapped address space, passing it an open file descriptor for
1470 the file corresponding to that mapped address space (if any)
1471 and the base address of the mapped space. Quit when we hit
1472 the end of the mappings or the function returns nonzero.
1473 */
1474
1475int
1ab3bf1b
JG
1476proc_iterate_over_mappings (func)
1477 int (*func) PARAMS ((int, CORE_ADDR));
a39ad5ce
FF
1478{
1479 int nmap;
1480 int fd;
1481 int funcstat = 0;
1482 struct prmap *prmaps;
1483 struct prmap *prmap;
a39ad5ce
FF
1484
1485 if (pi.valid && (ioctl (pi.fd, PIOCNMAP, &nmap) == 0))
1486 {
1ab3bf1b 1487 prmaps = (struct prmap *) alloca ((nmap + 1) * sizeof (*prmaps));
a39ad5ce
FF
1488 if (ioctl (pi.fd, PIOCMAP, prmaps) == 0)
1489 {
1490 for (prmap = prmaps; prmap -> pr_size && funcstat == 0; ++prmap)
1491 {
1ab3bf1b
JG
1492 fd = proc_address_to_fd ((CORE_ADDR) prmap -> pr_vaddr, 0);
1493 funcstat = (*func) (fd, (CORE_ADDR) prmap -> pr_vaddr);
a39ad5ce
FF
1494 close (fd);
1495 }
1496 }
1497 }
1498 return (funcstat);
1499}
1500
1501/*
1502
f8b76e70
FF
1503GLOBAL FUNCTION
1504
1505 proc_base_address -- find base address for segment containing address
1506
1507SYNOPSIS
1508
1509 CORE_ADDR proc_base_address (CORE_ADDR addr)
1510
1511DESCRIPTION
1512
1513 Given an address of a location in the inferior, find and return
1514 the base address of the mapped segment containing that address.
1515
1516 This is used for example, by the shared library support code,
1517 where we have the pc value for some location in the shared library
1518 where we are stopped, and need to know the base address of the
1519 segment containing that address.
1520*/
1521
1522
1ab3bf1b
JG
1523#if 0 /* Currently unused */
1524
f8b76e70 1525CORE_ADDR
1ab3bf1b 1526proc_base_address (addr)
cc221e76 1527 CORE_ADDR addr;
f8b76e70
FF
1528{
1529 int nmap;
1530 struct prmap *prmaps;
1531 struct prmap *prmap;
1532 CORE_ADDR baseaddr = 0;
1533
a39ad5ce 1534 if (pi.valid && (ioctl (pi.fd, PIOCNMAP, &nmap) == 0))
f8b76e70 1535 {
1ab3bf1b 1536 prmaps = (struct prmap *) alloca ((nmap + 1) * sizeof (*prmaps));
f8b76e70
FF
1537 if (ioctl (pi.fd, PIOCMAP, prmaps) == 0)
1538 {
1539 for (prmap = prmaps; prmap -> pr_size; ++prmap)
1540 {
1541 if ((prmap -> pr_vaddr <= (caddr_t) addr) &&
1542 (prmap -> pr_vaddr + prmap -> pr_size > (caddr_t) addr))
1543 {
1544 baseaddr = (CORE_ADDR) prmap -> pr_vaddr;
1545 break;
1546 }
1547 }
1548 }
1549 }
1550 return (baseaddr);
1551}
1552
1ab3bf1b
JG
1553#endif /* 0 */
1554
f8b76e70
FF
1555/*
1556
cc221e76 1557LOCAL FUNCTION
f8b76e70
FF
1558
1559 proc_address_to_fd -- return open fd for file mapped to address
1560
1561SYNOPSIS
1562
a39ad5ce 1563 int proc_address_to_fd (CORE_ADDR addr, complain)
f8b76e70
FF
1564
1565DESCRIPTION
1566
1567 Given an address in the current inferior's address space, use the
1568 /proc interface to find an open file descriptor for the file that
1569 this address was mapped in from. Return -1 if there is no current
1570 inferior. Print a warning message if there is an inferior but
1571 the address corresponds to no file (IE a bogus address).
1572
1573*/
1574
1ab3bf1b
JG
1575static int
1576proc_address_to_fd (addr, complain)
1577 CORE_ADDR addr;
1578 int complain;
f8b76e70
FF
1579{
1580 int fd = -1;
1581
1582 if (pi.valid)
1583 {
1584 if ((fd = ioctl (pi.fd, PIOCOPENM, (caddr_t *) &addr)) < 0)
1585 {
a39ad5ce
FF
1586 if (complain)
1587 {
1588 print_sys_errmsg (pi.pathname, errno);
1589 warning ("can't find mapped file for address 0x%x", addr);
1590 }
f8b76e70
FF
1591 }
1592 }
1593 return (fd);
1594}
1595
35f5886e
FF
1596
1597#ifdef ATTACH_DETACH
1598
1599/*
1600
1601GLOBAL FUNCTION
1602
1603 attach -- attach to an already existing process
1604
1605SYNOPSIS
1606
1607 int attach (int pid)
1608
1609DESCRIPTION
1610
1611 Attach to an already existing process with the specified process
1612 id. If the process is not already stopped, query whether to
1613 stop it or not.
1614
1615NOTES
1616
1617 The option of stopping at attach time is specific to the /proc
1618 versions of gdb. Versions using ptrace force the attachee
ec8ceca3
JG
1619 to stop. (I have changed this version to do so, too. All you
1620 have to do is "continue" to make it go on. -- gnu@cygnus.com)
35f5886e
FF
1621
1622*/
1623
1624int
1ab3bf1b
JG
1625attach (pid)
1626 int pid;
35f5886e 1627{
ec8ceca3
JG
1628 int result;
1629
1630 if (!open_proc_file (pid, &pi, O_RDWR))
35f5886e
FF
1631 {
1632 perror_with_name (pi.pathname);
1633 /* NOTREACHED */
1634 }
1635
1636 /* Get current status of process and if it is not already stopped,
1637 then stop it. Remember whether or not it was stopped when we first
1638 examined it. */
1639
1640 if (ioctl (pi.fd, PIOCSTATUS, &pi.prstatus) < 0)
1641 {
1642 print_sys_errmsg (pi.pathname, errno);
a39ad5ce 1643 close_proc_file (&pi);
35f5886e
FF
1644 error ("PIOCSTATUS failed");
1645 }
1646 if (pi.prstatus.pr_flags & (PR_STOPPED | PR_ISTOP))
1647 {
1648 pi.was_stopped = 1;
1649 }
1650 else
1651 {
1652 pi.was_stopped = 0;
ec8ceca3 1653 if (1 || query ("Process is currently running, stop it? "))
35f5886e 1654 {
ec8ceca3
JG
1655 /* Make it run again when we close it. */
1656#if defined (PIOCSET) /* New method */
1657 {
1658 long pr_flags;
1659 pr_flags = PR_RLC;
1660 result = ioctl (pi.fd, PIOCSET, &pr_flags);
1661 }
1662#else
1663#if defined (PIOCSRLC) /* Original method */
1664 result = ioctl (pi.fd, PIOCSRLC, 0);
1665#endif
1666#endif
1667 if (result < 0)
1668 {
1669 print_sys_errmsg (pi.pathname, errno);
1670 close_proc_file (&pi);
1671 error ("PIOCSRLC or PIOCSET failed");
1672 }
35f5886e
FF
1673 if (ioctl (pi.fd, PIOCSTOP, &pi.prstatus) < 0)
1674 {
1675 print_sys_errmsg (pi.pathname, errno);
a39ad5ce 1676 close_proc_file (&pi);
35f5886e
FF
1677 error ("PIOCSTOP failed");
1678 }
d65eee73
FF
1679 pi.nopass_next_sigstop = 1;
1680 }
1681 else
1682 {
1683 printf ("Ok, gdb will wait for process %u to stop.\n", pid);
35f5886e
FF
1684 }
1685 }
ec8ceca3 1686
35f5886e
FF
1687 /* Remember some things about the inferior that we will, or might, change
1688 so that we can restore them when we detach. */
1689
4ed3a9ea
FF
1690 ioctl (pi.fd, PIOCGTRACE, &pi.saved_trace);
1691 ioctl (pi.fd, PIOCGHOLD, &pi.saved_sighold);
1692 ioctl (pi.fd, PIOCGFAULT, &pi.saved_fltset);
1693 ioctl (pi.fd, PIOCGENTRY, &pi.saved_entryset);
1694 ioctl (pi.fd, PIOCGEXIT, &pi.saved_exitset);
35f5886e
FF
1695
1696 /* Set up trace and fault sets, as gdb expects them. */
1697
4ed3a9ea 1698 memset (&pi.prrun, 0, sizeof (pi.prrun));
35f5886e 1699 prfillset (&pi.prrun.pr_trace);
cc221e76 1700 proc_signal_handling_change ();
35f5886e
FF
1701 prfillset (&pi.prrun.pr_fault);
1702 prdelset (&pi.prrun.pr_fault, FLTPAGE);
1703 if (ioctl (pi.fd, PIOCSFAULT, &pi.prrun.pr_fault))
1704 {
f66f459f 1705 print_sys_errmsg ("PIOCSFAULT failed", errno);
35f5886e
FF
1706 }
1707 if (ioctl (pi.fd, PIOCSTRACE, &pi.prrun.pr_trace))
1708 {
f66f459f 1709 print_sys_errmsg ("PIOCSTRACE failed", errno);
35f5886e
FF
1710 }
1711 attach_flag = 1;
1712 return (pid);
1713}
1714
1715/*
1716
1717GLOBAL FUNCTION
1718
1719 detach -- detach from an attached-to process
1720
1721SYNOPSIS
1722
1723 void detach (int signal)
1724
1725DESCRIPTION
1726
1727 Detach from the current attachee.
1728
1729 If signal is non-zero, the attachee is started running again and sent
1730 the specified signal.
1731
1732 If signal is zero and the attachee was not already stopped when we
1733 attached to it, then we make it runnable again when we detach.
1734
1735 Otherwise, we query whether or not to make the attachee runnable
1736 again, since we may simply want to leave it in the state it was in
1737 when we attached.
1738
1739 We report any problems, but do not consider them errors, since we
1740 MUST detach even if some things don't seem to go right. This may not
1741 be the ideal situation. (FIXME).
1742 */
1743
1744void
1ab3bf1b
JG
1745detach (signal)
1746 int signal;
35f5886e 1747{
ec8ceca3
JG
1748 int result;
1749
35f5886e
FF
1750 if (signal)
1751 {
6b801388 1752 set_proc_siginfo (&pi, signal);
35f5886e 1753 }
cc221e76 1754 if (ioctl (pi.fd, PIOCSEXIT, &pi.saved_exitset) < 0)
35f5886e
FF
1755 {
1756 print_sys_errmsg (pi.pathname, errno);
1757 printf ("PIOCSEXIT failed.\n");
1758 }
cc221e76 1759 if (ioctl (pi.fd, PIOCSENTRY, &pi.saved_entryset) < 0)
35f5886e
FF
1760 {
1761 print_sys_errmsg (pi.pathname, errno);
1762 printf ("PIOCSENTRY failed.\n");
1763 }
cc221e76 1764 if (ioctl (pi.fd, PIOCSTRACE, &pi.saved_trace) < 0)
35f5886e
FF
1765 {
1766 print_sys_errmsg (pi.pathname, errno);
1767 printf ("PIOCSTRACE failed.\n");
1768 }
cc221e76
FF
1769 if (ioctl (pi.fd, PIOCSHOLD, &pi.saved_sighold) < 0)
1770 {
1771 print_sys_errmsg (pi.pathname, errno);
1772 printf ("PIOSCHOLD failed.\n");
1773 }
1774 if (ioctl (pi.fd, PIOCSFAULT, &pi.saved_fltset) < 0)
35f5886e
FF
1775 {
1776 print_sys_errmsg (pi.pathname, errno);
1777 printf ("PIOCSFAULT failed.\n");
1778 }
1779 if (ioctl (pi.fd, PIOCSTATUS, &pi.prstatus) < 0)
1780 {
1781 print_sys_errmsg (pi.pathname, errno);
1782 printf ("PIOCSTATUS failed.\n");
1783 }
1784 else
1785 {
1786 if (signal || (pi.prstatus.pr_flags & (PR_STOPPED | PR_ISTOP)))
1787 {
1788 if (signal || !pi.was_stopped ||
1789 query ("Was stopped when attached, make it runnable again? "))
1790 {
ec8ceca3
JG
1791 /* Clear any fault that might have stopped it. */
1792 if (ioctl (pi.fd, PIOCCFAULT, 0))
1793 {
1794 print_sys_errmsg (pi.pathname, errno);
1795 printf ("PIOCCFAULT failed.\n");
1796 }
1797
1798 /* Make it run again when we close it. */
1799#if defined (PIOCSET) /* New method */
1800 {
1801 long pr_flags;
1802 pr_flags = PR_RLC;
1803 result = ioctl (pi.fd, PIOCSET, &pr_flags);
1804 }
1805#else
1806#if defined (PIOCSRLC) /* Original method */
1807 result = ioctl (pi.fd, PIOCSRLC, 0);
1808#endif
1809#endif
1810 if (result)
35f5886e
FF
1811 {
1812 print_sys_errmsg (pi.pathname, errno);
ec8ceca3 1813 printf ("PIOCSRLC or PIOCSET failed.\n");
35f5886e
FF
1814 }
1815 }
1816 }
1817 }
a39ad5ce 1818 close_proc_file (&pi);
35f5886e
FF
1819 attach_flag = 0;
1820}
1821
fb182850
FF
1822#endif /* ATTACH_DETACH */
1823
35f5886e
FF
1824/*
1825
1826GLOBAL FUNCTION
1827
1828 proc_wait -- emulate wait() as much as possible
1829
1830SYNOPSIS
1831
1832 int proc_wait (int *statloc)
1833
1834DESCRIPTION
1835
1836 Try to emulate wait() as much as possible. Not sure why we can't
1837 just use wait(), but it seems to have problems when applied to a
1838 process being controlled with the /proc interface.
1839
1840NOTES
1841
1842 We have a race problem here with no obvious solution. We need to let
1843 the inferior run until it stops on an event of interest, which means
1844 that we need to use the PIOCWSTOP ioctl. However, we cannot use this
1845 ioctl if the process is already stopped on something that is not an
1846 event of interest, or the call will hang indefinitely. Thus we first
1847 use PIOCSTATUS to see if the process is not stopped. If not, then we
1848 use PIOCWSTOP. But during the window between the two, if the process
1849 stops for any reason that is not an event of interest (such as a job
1850 control signal) then gdb will hang. One possible workaround is to set
1851 an alarm to wake up every minute of so and check to see if the process
1852 is still running, and if so, then reissue the PIOCWSTOP. But this is
1853 a real kludge, so has not been implemented. FIXME: investigate
1854 alternatives.
1855
1856 FIXME: Investigate why wait() seems to have problems with programs
1857 being control by /proc routines.
1858
1859 */
1860
1861int
1ab3bf1b
JG
1862proc_wait (statloc)
1863 int *statloc;
35f5886e
FF
1864{
1865 short what;
1866 short why;
1867 int statval = 0;
1868 int checkerr = 0;
1869 int rtnval = -1;
1870
1871 if (ioctl (pi.fd, PIOCSTATUS, &pi.prstatus) < 0)
1872 {
1873 checkerr++;
1874 }
1875 else if (!(pi.prstatus.pr_flags & (PR_STOPPED | PR_ISTOP)))
1876 {
1877 if (ioctl (pi.fd, PIOCWSTOP, &pi.prstatus) < 0)
1878 {
1879 checkerr++;
1880 }
1881 }
1882 if (checkerr)
1883 {
1884 if (errno == ENOENT)
1885 {
1886 rtnval = wait (&statval);
1887 if (rtnval != inferior_pid)
1888 {
1889 error ("PIOCWSTOP, wait failed, returned %d", rtnval);
1890 /* NOTREACHED */
1891 }
1892 }
1893 else
1894 {
1895 print_sys_errmsg (pi.pathname, errno);
1896 error ("PIOCSTATUS or PIOCWSTOP failed.");
1897 /* NOTREACHED */
1898 }
1899 }
1900 else if (pi.prstatus.pr_flags & (PR_STOPPED | PR_ISTOP))
1901 {
1902 rtnval = pi.prstatus.pr_pid;
1903 why = pi.prstatus.pr_why;
1904 what = pi.prstatus.pr_what;
1905 if (why == PR_SIGNALLED)
1906 {
1907 statval = (what << 8) | 0177;
1908 }
407a8389
SG
1909 else if ((why == PR_SYSEXIT)
1910 &&
1911 (
1912#ifdef SYS_exec
1913 what == SYS_exec
1914#else
1915 0 == 0
1916#endif
1917#ifdef SYS_execve
1918 || what == SYS_execve
1919#endif
1920#ifdef SYS_execv
1921 || what == SYS_execv
1922#endif
1923 ))
35f5886e
FF
1924 {
1925 statval = (SIGTRAP << 8) | 0177;
1926 }
1927 else if (why == PR_REQUESTED)
1928 {
1929 statval = (SIGSTOP << 8) | 0177;
1930 }
1931 else if (why == PR_JOBCONTROL)
1932 {
1933 statval = (what << 8) | 0177;
1934 }
1935 else if (why == PR_FAULTED)
1936 {
1937 switch (what)
1938 {
1939 case FLTPRIV:
1940 case FLTILL:
1941 statval = (SIGILL << 8) | 0177;
1942 break;
1943 case FLTBPT:
1944 case FLTTRACE:
1945 statval = (SIGTRAP << 8) | 0177;
1946 break;
1947 case FLTSTACK:
1948 case FLTACCESS:
1949 case FLTBOUNDS:
1950 statval = (SIGSEGV << 8) | 0177;
1951 break;
1952 case FLTIOVF:
1953 case FLTIZDIV:
1954 case FLTFPE:
1955 statval = (SIGFPE << 8) | 0177;
1956 break;
1957 case FLTPAGE: /* Recoverable page fault */
1958 default:
1959 rtnval = -1;
1960 error ("PIOCWSTOP, unknown why %d, what %d", why, what);
1961 /* NOTREACHED */
1962 }
1963 }
1964 else
1965 {
1966 rtnval = -1;
1967 error ("PIOCWSTOP, unknown why %d, what %d", why, what);
1968 /* NOTREACHED */
1969 }
1970 }
1971 else
1972 {
1973 error ("PIOCWSTOP, stopped for unknown/unhandled reason, flags %#x",
1974 pi.prstatus.pr_flags);
1975 /* NOTREACHED */
1976 }
1977 if (statloc)
1978 {
1979 *statloc = statval;
1980 }
1981 return (rtnval);
1982}
1983
1984/*
1985
6b801388
FF
1986LOCAL FUNCTION
1987
1988 set_proc_siginfo - set a process's current signal info
1989
1990SYNOPSIS
1991
1992 void set_proc_siginfo (struct procinfo *pip, int signo);
1993
1994DESCRIPTION
1995
1996 Given a pointer to a process info struct in PIP and a signal number
1997 in SIGNO, set the process's current signal and its associated signal
1998 information. The signal will be delivered to the process immediately
1999 after execution is resumed, even if it is being held. In addition,
2000 this particular delivery will not cause another PR_SIGNALLED stop
2001 even if the signal is being traced.
2002
2003 If we are not delivering the same signal that the prstatus siginfo
2004 struct contains information about, then synthesize a siginfo struct
2005 to match the signal we are doing to deliver, make it of the type
2006 "generated by a user process", and send this synthesized copy. When
2007 used to set the inferior's signal state, this will be required if we
2008 are not currently stopped because of a traced signal, or if we decide
2009 to continue with a different signal.
2010
2011 Note that when continuing the inferior from a stop due to receipt
2012 of a traced signal, we either have set PRCSIG to clear the existing
2013 signal, or we have to call this function to do a PIOCSSIG with either
2014 the existing siginfo struct from pr_info, or one we have synthesized
2015 appropriately for the signal we want to deliver. Otherwise if the
2016 signal is still being traced, the inferior will immediately stop
2017 again.
2018
2019 See siginfo(5) for more details.
2020*/
2021
2022static void
2023set_proc_siginfo (pip, signo)
cc221e76
FF
2024 struct procinfo *pip;
2025 int signo;
6b801388
FF
2026{
2027 struct siginfo newsiginfo;
2028 struct siginfo *sip;
2029
2030 if (pip -> valid)
2031 {
2032 if (signo == pip -> prstatus.pr_info.si_signo)
2033 {
2034 sip = &pip -> prstatus.pr_info;
2035 }
2036 else
2037 {
4ed3a9ea 2038 memset ((char *) &newsiginfo, 0, sizeof (newsiginfo));
6b801388
FF
2039 sip = &newsiginfo;
2040 sip -> si_signo = signo;
2041 sip -> si_code = 0;
2042 sip -> si_errno = 0;
2043 sip -> si_pid = getpid ();
2044 sip -> si_uid = getuid ();
2045 }
2046 if (ioctl (pip -> fd, PIOCSSIG, sip) < 0)
2047 {
2048 print_sys_errmsg (pip -> pathname, errno);
2049 warning ("PIOCSSIG failed");
2050 }
2051 }
2052}
2053
2054/*
2055
35f5886e
FF
2056GLOBAL FUNCTION
2057
2058 child_resume -- resume execution of the inferior process
2059
2060SYNOPSIS
2061
cc221e76 2062 void child_resume (int step, int signo)
35f5886e
FF
2063
2064DESCRIPTION
2065
2066 Resume execution of the inferior process. If STEP is nozero, then
2067 just single step it. If SIGNAL is nonzero, restart it with that
2068 signal activated.
2069
2070NOTE
2071
2072 It may not be absolutely necessary to specify the PC value for
2073 restarting, but to be safe we use the value that gdb considers
2074 to be current. One case where this might be necessary is if the
2075 user explicitly changes the PC value that gdb considers to be
2076 current. FIXME: Investigate if this is necessary or not.
d65eee73
FF
2077
2078 When attaching to a child process, if we forced it to stop with
2079 a PIOCSTOP, then we will have set the nopass_next_sigstop flag.
2080 Upon resuming the first time after such a stop, we explicitly
2081 inhibit sending it another SIGSTOP, which would be the normal
2082 result of default signal handling. One potential drawback to
2083 this is that we will also ignore any attempt to by the user
2084 to explicitly continue after the attach with a SIGSTOP. Ultimately
2085 this problem should be dealt with by making the routines that
2086 deal with the inferior a little smarter, and possibly even allow
2087 an inferior to continue running at the same time as gdb. (FIXME?)
35f5886e
FF
2088 */
2089
2090void
cc221e76 2091child_resume (step, signo)
1ab3bf1b 2092 int step;
cc221e76 2093 int signo;
35f5886e
FF
2094{
2095 errno = 0;
99fd9e3e
SG
2096 pi.prrun.pr_flags = PRSTRACE | PRSFAULT | PRCFAULT;
2097
c3192172 2098#ifdef PRSVADDR_BROKEN
99fd9e3e
SG
2099/* Can't do this under Solaris running on a Sparc, as there seems to be no
2100 place to put nPC. In fact, if you use this, nPC seems to be set to some
2101 random garbage. We have to rely on the fact that PC and nPC have been
2102 written previously via PIOCSREG during a register flush. */
2103
35f5886e 2104 pi.prrun.pr_vaddr = (caddr_t) *(int *) &registers[REGISTER_BYTE (PC_REGNUM)];
99fd9e3e
SG
2105 pi.prrun.pr_flags != PRSVADDR;
2106#endif
2107
d65eee73 2108 if (signo && !(signo == SIGSTOP && pi.nopass_next_sigstop))
35f5886e 2109 {
cc221e76 2110 set_proc_siginfo (&pi, signo);
35f5886e
FF
2111 }
2112 else
2113 {
2114 pi.prrun.pr_flags |= PRCSIG;
2115 }
d65eee73 2116 pi.nopass_next_sigstop = 0;
35f5886e
FF
2117 if (step)
2118 {
2119 pi.prrun.pr_flags |= PRSTEP;
2120 }
2121 if (ioctl (pi.fd, PIOCRUN, &pi.prrun) != 0)
2122 {
2123 perror_with_name (pi.pathname);
2124 /* NOTREACHED */
2125 }
2126}
2127
2128/*
2129
2130GLOBAL FUNCTION
2131
2132 fetch_inferior_registers -- fetch current registers from inferior
2133
2134SYNOPSIS
2135
1ab3bf1b 2136 void fetch_inferior_registers (int regno)
35f5886e
FF
2137
2138DESCRIPTION
2139
2140 Read the current values of the inferior's registers, both the
2141 general register set and floating point registers (if supported)
2142 and update gdb's idea of their current values.
2143
2144*/
2145
2146void
1ab3bf1b
JG
2147fetch_inferior_registers (regno)
2148 int regno;
35f5886e
FF
2149{
2150 if (ioctl (pi.fd, PIOCGREG, &pi.gregset) != -1)
2151 {
2152 supply_gregset (&pi.gregset);
2153 }
2154#if defined (FP0_REGNUM)
2155 if (ioctl (pi.fd, PIOCGFPREG, &pi.fpregset) != -1)
2156 {
2157 supply_fpregset (&pi.fpregset);
2158 }
2159#endif
2160}
2161
fb182850
FF
2162/*
2163
2164GLOBAL FUNCTION
2165
2166 fetch_core_registers -- fetch current registers from core file data
2167
2168SYNOPSIS
2169
2170 void fetch_core_registers (char *core_reg_sect, unsigned core_reg_size,
1ab3bf1b 2171 int which, unsigned in reg_addr)
fb182850
FF
2172
2173DESCRIPTION
2174
2175 Read the values of either the general register set (WHICH equals 0)
2176 or the floating point register set (WHICH equals 2) from the core
2177 file data (pointed to by CORE_REG_SECT), and update gdb's idea of
2178 their current values. The CORE_REG_SIZE parameter is ignored.
2179
2180NOTES
2181
2182 Use the indicated sizes to validate the gregset and fpregset
2183 structures.
2184*/
2185
2186void
1ab3bf1b 2187fetch_core_registers (core_reg_sect, core_reg_size, which, reg_addr)
cc221e76
FF
2188 char *core_reg_sect;
2189 unsigned core_reg_size;
2190 int which;
2191 unsigned int reg_addr; /* Unused in this version */
fb182850
FF
2192{
2193
2194 if (which == 0)
2195 {
2196 if (core_reg_size != sizeof (pi.gregset))
2197 {
2198 warning ("wrong size gregset struct in core file");
2199 }
2200 else
2201 {
4ed3a9ea 2202 memcpy ((char *) &pi.gregset, core_reg_sect, sizeof (pi.gregset));
fb182850
FF
2203 supply_gregset (&pi.gregset);
2204 }
2205 }
2206 else if (which == 2)
2207 {
2208 if (core_reg_size != sizeof (pi.fpregset))
2209 {
2210 warning ("wrong size fpregset struct in core file");
2211 }
2212 else
2213 {
4ed3a9ea 2214 memcpy ((char *) &pi.fpregset, core_reg_sect, sizeof (pi.fpregset));
fb182850
FF
2215#if defined (FP0_REGNUM)
2216 supply_fpregset (&pi.fpregset);
2217#endif
2218 }
2219 }
2220}
35f5886e
FF
2221
2222/*
2223
2224LOCAL FUNCTION
2225
2226 proc_init_failed - called whenever /proc access initialization fails
2227
2228SYNOPSIS
2229
2230 static void proc_init_failed (char *why)
2231
2232DESCRIPTION
2233
2234 This function is called whenever initialization of access to a /proc
2235 entry fails. It prints a suitable error message, does some cleanup,
2236 and then invokes the standard error processing routine which dumps
2237 us back into the command loop.
2238 */
2239
2240static void
1ab3bf1b
JG
2241proc_init_failed (why)
2242 char *why;
35f5886e
FF
2243{
2244 print_sys_errmsg (pi.pathname, errno);
4ed3a9ea 2245 kill (pi.pid, SIGKILL);
a39ad5ce 2246 close_proc_file (&pi);
35f5886e
FF
2247 error (why);
2248 /* NOTREACHED */
2249}
2250
2251/*
2252
2253LOCAL FUNCTION
2254
2255 close_proc_file - close any currently open /proc entry
2256
2257SYNOPSIS
2258
a39ad5ce 2259 static void close_proc_file (struct procinfo *pip)
35f5886e
FF
2260
2261DESCRIPTION
2262
2263 Close any currently open /proc entry and mark the process information
2264 entry as invalid. In order to ensure that we don't try to reuse any
2265 stale information, the pid, fd, and pathnames are explicitly
2266 invalidated, which may be overkill.
2267
2268 */
2269
2270static void
1ab3bf1b
JG
2271close_proc_file (pip)
2272 struct procinfo *pip;
35f5886e 2273{
a39ad5ce
FF
2274 pip -> pid = 0;
2275 if (pip -> valid)
35f5886e 2276 {
4ed3a9ea 2277 close (pip -> fd);
35f5886e 2278 }
a39ad5ce
FF
2279 pip -> fd = -1;
2280 if (pip -> pathname)
35f5886e 2281 {
a39ad5ce
FF
2282 free (pip -> pathname);
2283 pip -> pathname = NULL;
35f5886e 2284 }
a39ad5ce 2285 pip -> valid = 0;
35f5886e
FF
2286}
2287
2288/*
2289
2290LOCAL FUNCTION
2291
2292 open_proc_file - open a /proc entry for a given process id
2293
2294SYNOPSIS
2295
ec8ceca3 2296 static int open_proc_file (int pid, struct procinfo *pip, int mode)
35f5886e
FF
2297
2298DESCRIPTION
2299
ec8ceca3
JG
2300 Given a process id and a mode, close the existing open /proc
2301 entry (if any) and open one for the new process id, in the
2302 specified mode. Once it is open, then mark the local process
2303 information structure as valid, which guarantees that the pid,
2304 fd, and pathname fields match an open /proc entry. Returns
2305 zero if the open fails, nonzero otherwise.
35f5886e
FF
2306
2307 Note that the pathname is left intact, even when the open fails,
2308 so that callers can use it to construct meaningful error messages
2309 rather than just "file open failed".
2310 */
2311
2312static int
ec8ceca3 2313open_proc_file (pid, pip, mode)
1ab3bf1b
JG
2314 int pid;
2315 struct procinfo *pip;
ec8ceca3 2316 int mode;
35f5886e 2317{
ec8ceca3 2318 pip -> valid = 0; /* FIXME, what is this? ?! */
a39ad5ce
FF
2319 if (pip -> valid)
2320 {
4ed3a9ea 2321 close (pip -> fd);
a39ad5ce
FF
2322 }
2323 if (pip -> pathname == NULL)
2324 {
2325 pip -> pathname = xmalloc (32);
2326 }
2327 sprintf (pip -> pathname, PROC_NAME_FMT, pid);
ec8ceca3 2328 if ((pip -> fd = open (pip -> pathname, mode)) >= 0)
a39ad5ce
FF
2329 {
2330 pip -> valid = 1;
2331 pip -> pid = pid;
2332 }
2333 return (pip -> valid);
2334}
2335
f66f459f 2336static char *
1ab3bf1b
JG
2337mappingflags (flags)
2338 long flags;
a39ad5ce 2339{
5c1c5e67 2340 static char asciiflags[8];
a39ad5ce 2341
5c1c5e67
FF
2342 strcpy (asciiflags, "-------");
2343#if defined (MA_PHYS)
2344 if (flags & MA_PHYS) asciiflags[0] = 'd';
2345#endif
2346 if (flags & MA_STACK) asciiflags[1] = 's';
2347 if (flags & MA_BREAK) asciiflags[2] = 'b';
2348 if (flags & MA_SHARED) asciiflags[3] = 's';
2349 if (flags & MA_READ) asciiflags[4] = 'r';
2350 if (flags & MA_WRITE) asciiflags[5] = 'w';
2351 if (flags & MA_EXEC) asciiflags[6] = 'x';
a39ad5ce
FF
2352 return (asciiflags);
2353}
2354
2355static void
cc221e76
FF
2356info_proc_flags (pip, summary)
2357 struct procinfo *pip;
2358 int summary;
2359{
2360 struct trans *transp;
2361
2362 printf_filtered ("%-32s", "Process status flags:");
2363 if (!summary)
2364 {
2365 printf_filtered ("\n\n");
2366 }
2367 for (transp = pr_flag_table; transp -> name != NULL; transp++)
2368 {
2369 if (pip -> prstatus.pr_flags & transp -> value)
2370 {
2371 if (summary)
2372 {
2373 printf_filtered ("%s ", transp -> name);
2374 }
2375 else
2376 {
2377 printf_filtered ("\t%-16s %s.\n", transp -> name, transp -> desc);
2378 }
2379 }
2380 }
2381 printf_filtered ("\n");
2382}
2383
2384static void
2385info_proc_stop (pip, summary)
2386 struct procinfo *pip;
2387 int summary;
2388{
2389 struct trans *transp;
2390 int why;
2391 int what;
2392
2393 why = pip -> prstatus.pr_why;
2394 what = pip -> prstatus.pr_what;
2395
2396 if (pip -> prstatus.pr_flags & PR_STOPPED)
2397 {
2398 printf_filtered ("%-32s", "Reason for stopping:");
2399 if (!summary)
2400 {
2401 printf_filtered ("\n\n");
2402 }
2403 for (transp = pr_why_table; transp -> name != NULL; transp++)
2404 {
2405 if (why == transp -> value)
2406 {
2407 if (summary)
2408 {
2409 printf_filtered ("%s ", transp -> name);
2410 }
2411 else
2412 {
2413 printf_filtered ("\t%-16s %s.\n",
2414 transp -> name, transp -> desc);
2415 }
2416 break;
2417 }
2418 }
2419
2420 /* Use the pr_why field to determine what the pr_what field means, and
2421 print more information. */
2422
2423 switch (why)
2424 {
2425 case PR_REQUESTED:
2426 /* pr_what is unused for this case */
2427 break;
2428 case PR_JOBCONTROL:
2429 case PR_SIGNALLED:
2430 if (summary)
2431 {
2432 printf_filtered ("%s ", signalname (what));
2433 }
2434 else
2435 {
2436 printf_filtered ("\t%-16s %s.\n", signalname (what),
4ace50a5 2437 safe_strsignal (what));
cc221e76
FF
2438 }
2439 break;
2440 case PR_SYSENTRY:
2441 if (summary)
2442 {
2443 printf_filtered ("%s ", syscallname (what));
2444 }
2445 else
2446 {
2447 printf_filtered ("\t%-16s %s.\n", syscallname (what),
2448 "Entered this system call");
2449 }
2450 break;
2451 case PR_SYSEXIT:
2452 if (summary)
2453 {
2454 printf_filtered ("%s ", syscallname (what));
2455 }
2456 else
2457 {
2458 printf_filtered ("\t%-16s %s.\n", syscallname (what),
2459 "Returned from this system call");
2460 }
2461 break;
2462 case PR_FAULTED:
2463 if (summary)
2464 {
2465 printf_filtered ("%s ",
2466 lookupname (faults_table, what, "fault"));
2467 }
2468 else
2469 {
2470 printf_filtered ("\t%-16s %s.\n",
2471 lookupname (faults_table, what, "fault"),
2472 lookupdesc (faults_table, what));
2473 }
2474 break;
2475 }
2476 printf_filtered ("\n");
2477 }
2478}
2479
2480static void
2481info_proc_siginfo (pip, summary)
2482 struct procinfo *pip;
2483 int summary;
2484{
2485 struct siginfo *sip;
2486
2487 if ((pip -> prstatus.pr_flags & PR_STOPPED) &&
2488 (pip -> prstatus.pr_why == PR_SIGNALLED ||
2489 pip -> prstatus.pr_why == PR_FAULTED))
2490 {
2491 printf_filtered ("%-32s", "Additional signal/fault info:");
2492 sip = &pip -> prstatus.pr_info;
2493 if (summary)
2494 {
2495 printf_filtered ("%s ", signalname (sip -> si_signo));
2496 if (sip -> si_errno > 0)
2497 {
4ace50a5 2498 printf_filtered ("%s ", errnoname (sip -> si_errno));
cc221e76
FF
2499 }
2500 if (sip -> si_code <= 0)
2501 {
2502 printf_filtered ("sent by pid %d, uid %d ", sip -> si_pid,
2503 sip -> si_uid);
2504 }
2505 else
2506 {
2507 printf_filtered ("%s ", sigcodename (sip));
2508 if ((sip -> si_signo == SIGILL) ||
2509 (sip -> si_signo == SIGFPE) ||
2510 (sip -> si_signo == SIGSEGV) ||
2511 (sip -> si_signo == SIGBUS))
2512 {
2513 printf_filtered ("addr=%#x ", sip -> si_addr);
2514 }
2515 else if ((sip -> si_signo == SIGCHLD))
2516 {
2517 printf_filtered ("child pid %u, status %u ",
2518 sip -> si_pid,
2519 sip -> si_status);
2520 }
2521 else if ((sip -> si_signo == SIGPOLL))
2522 {
2523 printf_filtered ("band %u ", sip -> si_band);
2524 }
2525 }
2526 }
2527 else
2528 {
2529 printf_filtered ("\n\n");
2530 printf_filtered ("\t%-16s %s.\n", signalname (sip -> si_signo),
4ace50a5 2531 safe_strsignal (sip -> si_signo));
cc221e76
FF
2532 if (sip -> si_errno > 0)
2533 {
2534 printf_filtered ("\t%-16s %s.\n",
4ace50a5
FF
2535 errnoname (sip -> si_errno),
2536 safe_strerror (sip -> si_errno));
cc221e76
FF
2537 }
2538 if (sip -> si_code <= 0)
2539 {
2540 printf_filtered ("\t%-16u %s\n", sip -> si_pid,
2541 "PID of process sending signal");
2542 printf_filtered ("\t%-16u %s\n", sip -> si_uid,
2543 "UID of process sending signal");
2544 }
2545 else
2546 {
2547 printf_filtered ("\t%-16s %s.\n", sigcodename (sip),
2548 sigcodedesc (sip));
2549 if ((sip -> si_signo == SIGILL) ||
2550 (sip -> si_signo == SIGFPE))
2551 {
2552 printf_filtered ("\t%-16#x %s.\n", sip -> si_addr,
2553 "Address of faulting instruction");
2554 }
2555 else if ((sip -> si_signo == SIGSEGV) ||
2556 (sip -> si_signo == SIGBUS))
2557 {
2558 printf_filtered ("\t%-16#x %s.\n", sip -> si_addr,
2559 "Address of faulting memory reference");
2560 }
2561 else if ((sip -> si_signo == SIGCHLD))
2562 {
2563 printf_filtered ("\t%-16u %s.\n", sip -> si_pid,
2564 "Child process ID");
2565 printf_filtered ("\t%-16u %s.\n", sip -> si_status,
2566 "Child process exit value or signal");
2567 }
2568 else if ((sip -> si_signo == SIGPOLL))
2569 {
2570 printf_filtered ("\t%-16u %s.\n", sip -> si_band,
2571 "Band event for POLL_{IN,OUT,MSG}");
2572 }
2573 }
2574 }
2575 printf_filtered ("\n");
2576 }
2577}
2578
2579static void
2580info_proc_syscalls (pip, summary)
2581 struct procinfo *pip;
2582 int summary;
2583{
2584 int syscallnum;
2585
2586 if (!summary)
2587 {
2588
2589#if 0 /* FIXME: Needs to use gdb-wide configured info about system calls. */
2590 if (pip -> prstatus.pr_flags & PR_ASLEEP)
2591 {
2592 int syscallnum = pip -> prstatus.pr_reg[R_D0];
2593 if (summary)
2594 {
2595 printf_filtered ("%-32s", "Sleeping in system call:");
2596 printf_filtered ("%s", syscallname (syscallnum));
2597 }
2598 else
2599 {
2600 printf_filtered ("Sleeping in system call '%s'.\n",
2601 syscallname (syscallnum));
2602 }
2603 }
2604#endif
2605
2606 if (ioctl (pip -> fd, PIOCGENTRY, &pip -> entryset) < 0)
2607 {
2608 print_sys_errmsg (pip -> pathname, errno);
2609 error ("PIOCGENTRY failed");
2610 }
2611
2612 if (ioctl (pip -> fd, PIOCGEXIT, &pip -> exitset) < 0)
2613 {
2614 print_sys_errmsg (pip -> pathname, errno);
2615 error ("PIOCGEXIT failed");
2616 }
2617
2618 printf_filtered ("System call tracing information:\n\n");
2619
2620 printf_filtered ("\t%-12s %-8s %-8s\n",
2621 "System call",
2622 "Entry",
2623 "Exit");
2624 for (syscallnum = 0; syscallnum < MAX_SYSCALLS; syscallnum++)
2625 {
2626 QUIT;
2627 if (syscall_table[syscallnum] != NULL)
2628 {
2629 printf_filtered ("\t%-12s ", syscall_table[syscallnum]);
2630 printf_filtered ("%-8s ",
2631 prismember (&pip -> entryset, syscallnum)
2632 ? "on" : "off");
2633 printf_filtered ("%-8s ",
2634 prismember (&pip -> exitset, syscallnum)
2635 ? "on" : "off");
2636 printf_filtered ("\n");
2637 }
2638 }
2639 printf_filtered ("\n");
2640 }
2641}
2642
2643static char *
2644signalname (signo)
2645 int signo;
2646{
4ace50a5
FF
2647 char *name;
2648 static char locbuf[32];
2649
2650 name = strsigno (signo);
2651 if (name == NULL)
2652 {
2653 sprintf (locbuf, "Signal %d", signo);
2654 }
2655 else
2656 {
2657 sprintf (locbuf, "%s (%d)", name, signo);
2658 }
2659 return (locbuf);
2660}
2661
2662static char *
2663errnoname (errnum)
2664 int errnum;
2665{
2666 char *name;
cc221e76
FF
2667 static char locbuf[32];
2668
4ace50a5
FF
2669 name = strerrno (errnum);
2670 if (name == NULL)
cc221e76 2671 {
4ace50a5 2672 sprintf (locbuf, "Errno %d", errnum);
cc221e76
FF
2673 }
2674 else
2675 {
4ace50a5 2676 sprintf (locbuf, "%s (%d)", name, errnum);
cc221e76
FF
2677 }
2678 return (locbuf);
2679}
2680
2681static void
2682info_proc_signals (pip, summary)
2683 struct procinfo *pip;
2684 int summary;
2685{
2686 int signo;
2687
2688 if (!summary)
2689 {
2690 if (ioctl (pip -> fd, PIOCGTRACE, &pip -> trace) < 0)
2691 {
2692 print_sys_errmsg (pip -> pathname, errno);
2693 error ("PIOCGTRACE failed");
2694 }
2695
2696 printf_filtered ("Disposition of signals:\n\n");
2697 printf_filtered ("\t%-15s %-8s %-8s %-8s %s\n\n",
2698 "Signal", "Trace", "Hold", "Pending", "Description");
2699 for (signo = 0; signo < NSIG; signo++)
2700 {
2701 QUIT;
2702 printf_filtered ("\t%-15s ", signalname (signo));
2703 printf_filtered ("%-8s ",
2704 prismember (&pip -> trace, signo)
2705 ? "on" : "off");
2706 printf_filtered ("%-8s ",
2707 prismember (&pip -> prstatus.pr_sighold, signo)
2708 ? "on" : "off");
2709 printf_filtered ("%-8s ",
2710 prismember (&pip -> prstatus.pr_sigpend, signo)
2711 ? "yes" : "no");
4ace50a5 2712 printf_filtered (" %s\n", safe_strsignal (signo));
cc221e76
FF
2713 }
2714 printf_filtered ("\n");
2715 }
2716}
2717
2718static void
2719info_proc_faults (pip, summary)
2720 struct procinfo *pip;
2721 int summary;
2722{
2723 struct trans *transp;
2724
2725 if (!summary)
2726 {
2727 if (ioctl (pip -> fd, PIOCGFAULT, &pip -> fltset) < 0)
2728 {
2729 print_sys_errmsg (pip -> pathname, errno);
2730 error ("PIOCGFAULT failed");
2731 }
2732
2733 printf_filtered ("Current traced hardware fault set:\n\n");
2734 printf_filtered ("\t%-12s %-8s\n", "Fault", "Trace");
2735
2736 for (transp = faults_table; transp -> name != NULL; transp++)
2737 {
2738 QUIT;
2739 printf_filtered ("\t%-12s ", transp -> name);
2740 printf_filtered ("%-8s", prismember (&pip -> fltset, transp -> value)
2741 ? "on" : "off");
2742 printf_filtered ("\n");
2743 }
2744 printf_filtered ("\n");
2745 }
2746}
2747
2748static void
2749info_proc_mappings (pip, summary)
1ab3bf1b 2750 struct procinfo *pip;
cc221e76 2751 int summary;
a39ad5ce
FF
2752{
2753 int nmap;
2754 struct prmap *prmaps;
2755 struct prmap *prmap;
2756
cc221e76 2757 if (!summary)
a39ad5ce 2758 {
cc221e76 2759 printf_filtered ("Mapped address spaces:\n\n");
5c1c5e67 2760 printf_filtered ("\t%10s %10s %10s %10s %7s\n",
cc221e76
FF
2761 "Start Addr",
2762 " End Addr",
2763 " Size",
2764 " Offset",
2765 "Flags");
2766 if (ioctl (pip -> fd, PIOCNMAP, &nmap) == 0)
a39ad5ce 2767 {
cc221e76
FF
2768 prmaps = (struct prmap *) alloca ((nmap + 1) * sizeof (*prmaps));
2769 if (ioctl (pip -> fd, PIOCMAP, prmaps) == 0)
a39ad5ce 2770 {
cc221e76
FF
2771 for (prmap = prmaps; prmap -> pr_size; ++prmap)
2772 {
5c1c5e67 2773 printf_filtered ("\t%#10x %#10x %#10x %#10x %7s\n",
cc221e76
FF
2774 prmap -> pr_vaddr,
2775 prmap -> pr_vaddr + prmap -> pr_size - 1,
2776 prmap -> pr_size,
2777 prmap -> pr_off,
2778 mappingflags (prmap -> pr_mflags));
2779 }
a39ad5ce
FF
2780 }
2781 }
cc221e76 2782 printf_filtered ("\n");
a39ad5ce 2783 }
a39ad5ce
FF
2784}
2785
2786/*
2787
2788LOCAL FUNCTION
2789
cc221e76 2790 info_proc -- implement the "info proc" command
a39ad5ce
FF
2791
2792SYNOPSIS
2793
cc221e76 2794 void info_proc (char *args, int from_tty)
a39ad5ce
FF
2795
2796DESCRIPTION
2797
2798 Implement gdb's "info proc" command by using the /proc interface
2799 to print status information about any currently running process.
2800
2801 Examples of the use of "info proc" are:
2802
cc221e76
FF
2803 info proc (prints summary info for current inferior)
2804 info proc 123 (prints summary info for process with pid 123)
2805 info proc mappings (prints address mappings)
2806 info proc times (prints process/children times)
2807 info proc id (prints pid, ppid, gid, sid, etc)
2808 info proc status (prints general process state info)
2809 info proc signals (prints info about signal handling)
2810 info proc all (prints all info)
a39ad5ce
FF
2811
2812 */
2813
2814static void
cc221e76 2815info_proc (args, from_tty)
1ab3bf1b
JG
2816 char *args;
2817 int from_tty;
a39ad5ce 2818{
a39ad5ce
FF
2819 int pid;
2820 struct procinfo pii;
2821 struct procinfo *pip;
2822 struct cleanup *old_chain;
cc221e76
FF
2823 char **argv;
2824 int argsize;
2825 int summary = 1;
2826 int flags = 0;
2827 int syscalls = 0;
2828 int signals = 0;
2829 int faults = 0;
2830 int mappings = 0;
2831 int times = 0;
2832 int id = 0;
2833 int status = 0;
2834 int all = 0;
a39ad5ce
FF
2835
2836 old_chain = make_cleanup (null_cleanup, 0);
2837
2838 /* Default to using the current inferior if no pid specified */
2839
2840 pip = &pi;
2841
a39ad5ce 2842 if (args != NULL)
35f5886e 2843 {
cc221e76 2844 if ((argv = buildargv (args)) == NULL)
a39ad5ce 2845 {
cc221e76
FF
2846 nomem (0);
2847 }
2848 make_cleanup (freeargv, (char *) argv);
2849
2850 while (*argv != NULL)
2851 {
2852 argsize = strlen (*argv);
2853 if (argsize >= 1 && strncmp (*argv, "all", argsize) == 0)
2854 {
2855 summary = 0;
2856 all = 1;
2857 }
2858 else if (argsize >= 2 && strncmp (*argv, "faults", argsize) == 0)
2859 {
2860 summary = 0;
2861 faults = 1;
2862 }
2863 else if (argsize >= 2 && strncmp (*argv, "flags", argsize) == 0)
2864 {
2865 summary = 0;
2866 flags = 1;
2867 }
2868 else if (argsize >= 1 && strncmp (*argv, "id", argsize) == 0)
2869 {
2870 summary = 0;
2871 id = 1;
2872 }
2873 else if (argsize >= 1 && strncmp (*argv, "mappings", argsize) == 0)
2874 {
2875 summary = 0;
2876 mappings = 1;
2877 }
2878 else if (argsize >= 2 && strncmp (*argv, "signals", argsize) == 0)
2879 {
2880 summary = 0;
2881 signals = 1;
2882 }
2883 else if (argsize >= 2 && strncmp (*argv, "status", argsize) == 0)
2884 {
2885 summary = 0;
2886 status = 1;
2887 }
2888 else if (argsize >= 2 && strncmp (*argv, "syscalls", argsize) == 0)
2889 {
2890 summary = 0;
2891 syscalls = 1;
2892 }
2893 else if (argsize >= 1 && strncmp (*argv, "times", argsize) == 0)
a39ad5ce 2894 {
cc221e76
FF
2895 summary = 0;
2896 times = 1;
a39ad5ce 2897 }
cc221e76 2898 else if ((pii.pid = atoi (*argv)) > 0)
a39ad5ce
FF
2899 {
2900 pid = pii.pid;
2901 pip = &pii;
4ed3a9ea 2902 memset (&pii, 0, sizeof (pii));
ec8ceca3 2903 if (!open_proc_file (pid, pip, O_RDONLY))
a39ad5ce
FF
2904 {
2905 perror_with_name (pip -> pathname);
2906 /* NOTREACHED */
2907 }
2908 make_cleanup (close_proc_file, pip);
2909 }
cc221e76
FF
2910 else if (**argv != '\000')
2911 {
2912 error ("Unrecognized or ambiguous keyword `%s'.", *argv);
2913 }
2914 argv++;
a39ad5ce 2915 }
35f5886e 2916 }
a39ad5ce
FF
2917
2918 /* If we don't have a valid open process at this point, then we have no
2919 inferior or didn't specify a specific pid. */
2920
2921 if (!pip -> valid)
35f5886e 2922 {
a39ad5ce 2923 error ("No process. Run an inferior or specify an explicit pid.");
35f5886e 2924 }
a39ad5ce 2925 if (ioctl (pip -> fd, PIOCSTATUS, &(pip -> prstatus)) < 0)
35f5886e 2926 {
a39ad5ce
FF
2927 print_sys_errmsg (pip -> pathname, errno);
2928 error ("PIOCSTATUS failed");
35f5886e 2929 }
a39ad5ce 2930
cc221e76
FF
2931 /* Print verbose information of the requested type(s), or just a summary
2932 of the information for all types. */
2933
2934 printf_filtered ("\nInformation for %s:\n\n", pip -> pathname);
2935 if (summary || all || flags)
2936 {
2937 info_proc_flags (pip, summary);
2938 }
2939 if (summary || all)
2940 {
2941 info_proc_stop (pip, summary);
2942 }
2943 if (summary || all || signals || faults)
2944 {
2945 info_proc_siginfo (pip, summary);
2946 }
2947 if (summary || all || syscalls)
2948 {
2949 info_proc_syscalls (pip, summary);
2950 }
2951 if (summary || all || mappings)
2952 {
2953 info_proc_mappings (pip, summary);
2954 }
2955 if (summary || all || signals)
2956 {
2957 info_proc_signals (pip, summary);
2958 }
2959 if (summary || all || faults)
2960 {
2961 info_proc_faults (pip, summary);
2962 }
2963 printf_filtered ("\n");
a39ad5ce
FF
2964
2965 /* All done, deal with closing any temporary process info structure,
2966 freeing temporary memory , etc. */
2967
2968 do_cleanups (old_chain);
2969}
2970
2971/*
2972
2973GLOBAL FUNCTION
2974
2975 _initialize_proc_fs -- initialize the process file system stuff
2976
2977SYNOPSIS
2978
2979 void _initialize_proc_fs (void)
2980
2981DESCRIPTION
2982
2983 Do required initializations during gdb startup for using the
2984 /proc file system interface.
2985
2986*/
2987
2988static char *proc_desc =
cc221e76
FF
2989"Show process status information using /proc entry.\n\
2990Specify process id or use current inferior by default.\n\
2991Specify keywords for detailed information; default is summary.\n\
2992Keywords are: `all', `faults', `flags', `id', `mappings', `signals',\n\
2993`status', `syscalls', and `times'.\n\
2994Unambiguous abbreviations may be used.";
a39ad5ce
FF
2995
2996void
2997_initialize_proc_fs ()
2998{
cc221e76
FF
2999 add_info ("proc", info_proc, proc_desc);
3000 init_syscall_table ();
35f5886e
FF
3001}
3002
3003#endif /* USE_PROC_FS */
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