1PTRACE(2)                  Linux Programmer's Manual                 PTRACE(2)
2
3
4

NAME

6       ptrace - process trace
7

SYNOPSIS

9       #include <sys/ptrace.h>
10
11       long ptrace(enum __ptrace_request request, pid_t pid,
12                   void *addr, void *data);
13

DESCRIPTION

15       The  ptrace()  system  call  provides a means by which one process (the
16       "tracer") may observe and control the execution of another process (the
17       "tracee"),  and  examine  and change the tracee's memory and registers.
18       It is primarily used to implement breakpoint debugging and system  call
19       tracing.
20
21       A tracee first needs to be attached to the tracer.  Attachment and sub‐
22       sequent commands are per thread:  in  a  multithreaded  process,  every
23       thread  can  be  individually  attached  to  a  (potentially different)
24       tracer, or  left  not  attached  and  thus  not  debugged.   Therefore,
25       "tracee" always means "(one) thread", never "a (possibly multithreaded)
26       process".  Ptrace commands are always sent to a specific tracee using a
27       call of the form
28
29           ptrace(PTRACE_foo, pid, ...)
30
31       where pid is the thread ID of the corresponding Linux thread.
32
33       (Note that in this page, a "multithreaded process" means a thread group
34       consisting of threads created using the clone(2) CLONE_THREAD flag.)
35
36       A process can initiate a  trace  by  calling  fork(2)  and  having  the
37       resulting  child  do  a  PTRACE_TRACEME,  followed  (typically)  by  an
38       execve(2).  Alternatively, one process  may  commence  tracing  another
39       process using PTRACE_ATTACH or PTRACE_SEIZE.
40
41       While  being  traced, the tracee will stop each time a signal is deliv‐
42       ered, even if the signal is being ignored.  (An exception  is  SIGKILL,
43       which  has  its usual effect.)  The tracer will be notified at its next
44       call to waitpid(2) (or one of the related "wait"  system  calls);  that
45       call  will  return a status value containing information that indicates
46       the cause of the stop in the tracee.  While the tracee is stopped,  the
47       tracer  can  use  various  ptrace  requests  to  inspect and modify the
48       tracee.  The tracer then causes  the  tracee  to  continue,  optionally
49       ignoring  the  delivered  signal (or even delivering a different signal
50       instead).
51
52       If the PTRACE_O_TRACEEXEC option is not in effect, all successful calls
53       to  execve(2)  by the traced process will cause it to be sent a SIGTRAP
54       signal, giving the parent a chance to gain control before the new  pro‐
55       gram begins execution.
56
57       When  the  tracer  is finished tracing, it can cause the tracee to con‐
58       tinue executing in a normal, untraced mode via PTRACE_DETACH.
59
60       The value of request determines the action to be performed:
61
62       PTRACE_TRACEME
63              Indicate that this process is to be traced  by  its  parent.   A
64              process probably shouldn't make this request if its parent isn't
65              expecting to trace it.  (pid, addr, and data are ignored.)
66
67              The PTRACE_TRACEME request is  used  only  by  the  tracee;  the
68              remaining  requests are used only by the tracer.  In the follow‐
69              ing requests, pid specifies the thread ID of the  tracee  to  be
70              acted  on.  For requests other than PTRACE_ATTACH, PTRACE_SEIZE,
71              PTRACE_INTERRUPT, and PTRACE_KILL, the tracee must be stopped.
72
73       PTRACE_PEEKTEXT, PTRACE_PEEKDATA
74              Read a word at the address addr in the tracee's memory,  return‐
75              ing the word as the result of the ptrace() call.  Linux does not
76              have separate  text  and  data  address  spaces,  so  these  two
77              requests  are  currently  equivalent.  (data is ignored; but see
78              NOTES.)
79
80       PTRACE_PEEKUSER
81              Read a word at offset addr in  the  tracee's  USER  area,  which
82              holds the registers and other information about the process (see
83              <sys/user.h>).  The word  is  returned  as  the  result  of  the
84              ptrace()  call.   Typically,  the  offset  must be word-aligned,
85              though this might vary by architecture.  See  NOTES.   (data  is
86              ignored; but see NOTES.)
87
88       PTRACE_POKETEXT, PTRACE_POKEDATA
89              Copy  the  word data to the address addr in the tracee's memory.
90              As for PTRACE_PEEKTEXT and PTRACE_PEEKDATA, these  two  requests
91              are currently equivalent.
92
93       PTRACE_POKEUSER
94              Copy the word data to offset addr in the tracee's USER area.  As
95              for PTRACE_PEEKUSER, the offset must typically be  word-aligned.
96              In order to maintain the integrity of the kernel, some modifica‐
97              tions to the USER area are disallowed.
98
99       PTRACE_GETREGS, PTRACE_GETFPREGS
100              Copy the tracee's general-purpose or  floating-point  registers,
101              respectively,   to   the   address  data  in  the  tracer.   See
102              <sys/user.h> for information on the format of this data.   (addr
103              is  ignored.)   Note that SPARC systems have the meaning of data
104              and addr reversed; that is, data is ignored  and  the  registers
105              are copied to the address addr.  PTRACE_GETREGS and PTRACE_GETF‐
106              PREGS are not present on all architectures.
107
108       PTRACE_GETREGSET (since Linux 2.6.34)
109              Read the tracee's registers.  addr specifies,  in  an  architec‐
110              ture-dependent way, the type of registers to be read.  NT_PRSTA‐
111              TUS (with numerical value 1) usually results in reading of  gen‐
112              eral-purpose  registers.  If the CPU has, for example, floating-
113              point and/or vector registers, they can be retrieved by  setting
114              addr  to  the  corresponding  NT_foo constant.  data points to a
115              struct iovec, which describes the destination buffer's  location
116              and  length.  On return, the kernel modifies iov.len to indicate
117              the actual number of bytes returned.
118
119       PTRACE_SETREGS, PTRACE_SETFPREGS
120              Modify the tracee's general-purpose or floating-point registers,
121              respectively,  from  the  address  data  in  the tracer.  As for
122              PTRACE_POKEUSER, some general-purpose register modifications may
123              be disallowed.  (addr is ignored.)  Note that SPARC systems have
124              the meaning of data and addr reversed; that is, data is  ignored
125              and   the   registers   are   copied   from  the  address  addr.
126              PTRACE_SETREGS and  PTRACE_SETFPREGS  are  not  present  on  all
127              architectures.
128
129       PTRACE_SETREGSET (since Linux 2.6.34)
130              Modify  the tracee's registers.  The meaning of addr and data is
131              analogous to PTRACE_GETREGSET.
132
133       PTRACE_GETSIGINFO (since Linux 2.3.99-pre6)
134              Retrieve information about the  signal  that  caused  the  stop.
135              Copy a siginfo_t structure (see sigaction(2)) from the tracee to
136              the address data in the tracer.  (addr is ignored.)
137
138       PTRACE_SETSIGINFO (since Linux 2.3.99-pre6)
139              Set signal information: copy  a  siginfo_t  structure  from  the
140              address data in the tracer to the tracee.  This will affect only
141              signals that would normally be delivered to the tracee and  were
142              caught  by the tracer.  It may be difficult to tell these normal
143              signals from synthetic signals  generated  by  ptrace()  itself.
144              (addr is ignored.)
145
146       PTRACE_PEEKSIGINFO (since Linux 3.10)
147              Retrieve  siginfo_t  structures  without removing signals from a
148              queue.  addr points to a ptrace_peeksiginfo_args structure  that
149              specifies  the  ordinal  position  from which copying of signals
150              should start, and the number  of  signals  to  copy.   siginfo_t
151              structures  are  copied into the buffer pointed to by data.  The
152              return value contains the number of copied signals  (zero  indi‐
153              cates  that  there  is  no signal corresponding to the specified
154              ordinal position).  Within the returned siginfo structures,  the
155              si_code field includes information (__SI_CHLD, __SI_FAULT, etc.)
156              that are not otherwise exposed to user space.
157
158           struct ptrace_peeksiginfo_args {
159               u64 off;    /* Ordinal position in queue at which
160                              to start copying signals */
161               u32 flags;  /* PTRACE_PEEKSIGINFO_SHARED or 0 */
162               s32 nr;     /* Number of signals to copy */
163           };
164
165              Currently, there is only  one  flag,  PTRACE_PEEKSIGINFO_SHARED,
166              for dumping signals from the process-wide signal queue.  If this
167              flag is not set, signals are read from the per-thread  queue  of
168              the specified thread.
169
170       PTRACE_GETSIGMASK (since Linux 3.11)
171              Place a copy of the mask of blocked signals (see sigprocmask(2))
172              in the buffer pointed to by data, which should be a pointer to a
173              buffer of type sigset_t.  The addr argument contains the size of
174              the buffer pointed to by data (i.e., sizeof(sigset_t)).
175
176       PTRACE_SETSIGMASK (since Linux 3.11)
177              Change the mask of blocked signals (see sigprocmask(2))  to  the
178              value  specified  in the buffer pointed to by data, which should
179              be a pointer to a buffer of type sigset_t.   The  addr  argument
180              contains  the  size  of  the  buffer  pointed  to by data (i.e.,
181              sizeof(sigset_t)).
182
183       PTRACE_SETOPTIONS (since Linux 2.4.6; see BUGS for caveats)
184              Set ptrace options from  data.   (addr  is  ignored.)   data  is
185              interpreted as a bit mask of options, which are specified by the
186              following flags:
187
188              PTRACE_O_EXITKILL (since Linux 3.8)
189                     Send a SIGKILL signal to the tracee if the tracer  exits.
190                     This  option  is  useful  for ptrace jailers that want to
191                     ensure that tracees can never escape  the  tracer's  con‐
192                     trol.
193
194              PTRACE_O_TRACECLONE (since Linux 2.5.46)
195                     Stop  the  tracee  at the next clone(2) and automatically
196                     start tracing the newly cloned process, which will  start
197                     with  a SIGSTOP, or PTRACE_EVENT_STOP if PTRACE_SEIZE was
198                     used.  A waitpid(2) by the tracer will  return  a  status
199                     value such that
200
201                       status>>8 == (SIGTRAP | (PTRACE_EVENT_CLONE<<8))
202
203                     The  PID  of  the  new  process  can  be  retrieved  with
204                     PTRACE_GETEVENTMSG.
205
206                     This option may not catch clone(2) calls  in  all  cases.
207                     If  the  tracee calls clone(2) with the CLONE_VFORK flag,
208                     PTRACE_EVENT_VFORK   will   be   delivered   instead   if
209                     PTRACE_O_TRACEVFORK is set; otherwise if the tracee calls
210                     clone(2)  with  the   exit   signal   set   to   SIGCHLD,
211                     PTRACE_EVENT_FORK will be delivered if PTRACE_O_TRACEFORK
212                     is set.
213
214              PTRACE_O_TRACEEXEC (since Linux 2.5.46)
215                     Stop the tracee at the next execve(2).  A  waitpid(2)  by
216                     the tracer will return a status value such that
217
218                       status>>8 == (SIGTRAP | (PTRACE_EVENT_EXEC<<8))
219
220                     If  the  execing thread is not a thread group leader, the
221                     thread ID is reset to thread  group  leader's  ID  before
222                     this  stop.  Since Linux 3.0, the former thread ID can be
223                     retrieved with PTRACE_GETEVENTMSG.
224
225              PTRACE_O_TRACEEXIT (since Linux 2.5.60)
226                     Stop the tracee at exit.  A waitpid(2) by the tracer will
227                     return a status value such that
228
229                       status>>8 == (SIGTRAP | (PTRACE_EVENT_EXIT<<8))
230
231                     The   tracee's   exit   status   can  be  retrieved  with
232                     PTRACE_GETEVENTMSG.
233
234                     The tracee is stopped early  during  process  exit,  when
235                     registers are still available, allowing the tracer to see
236                     where the exit occurred, whereas the normal exit  notifi‐
237                     cation  is  done  after  the process is finished exiting.
238                     Even though context is available, the tracer cannot  pre‐
239                     vent the exit from happening at this point.
240
241              PTRACE_O_TRACEFORK (since Linux 2.5.46)
242                     Stop  the  tracee  at  the next fork(2) and automatically
243                     start tracing the newly forked process, which will  start
244                     with  a SIGSTOP, or PTRACE_EVENT_STOP if PTRACE_SEIZE was
245                     used.  A waitpid(2) by the tracer will  return  a  status
246                     value such that
247
248                       status>>8 == (SIGTRAP | (PTRACE_EVENT_FORK<<8))
249
250                     The  PID  of  the  new  process  can  be  retrieved  with
251                     PTRACE_GETEVENTMSG.
252
253              PTRACE_O_TRACESYSGOOD (since Linux 2.4.6)
254                     When delivering system call traps, set bit 7 in the  sig‐
255                     nal  number  (i.e., deliver SIGTRAP|0x80).  This makes it
256                     easy for the tracer  to  distinguish  normal  traps  from
257                     those  caused  by  a system call.  (PTRACE_O_TRACESYSGOOD
258                     may not work on all architectures.)
259
260              PTRACE_O_TRACEVFORK (since Linux 2.5.46)
261                     Stop the tracee at the next  vfork(2)  and  automatically
262                     start tracing the newly vforked process, which will start
263                     with a SIGSTOP, or PTRACE_EVENT_STOP if PTRACE_SEIZE  was
264                     used.   A  waitpid(2)  by the tracer will return a status
265                     value such that
266
267                       status>>8 == (SIGTRAP | (PTRACE_EVENT_VFORK<<8))
268
269                     The  PID  of  the  new  process  can  be  retrieved  with
270                     PTRACE_GETEVENTMSG.
271
272              PTRACE_O_TRACEVFORKDONE (since Linux 2.5.60)
273                     Stop  the  tracee at the completion of the next vfork(2).
274                     A waitpid(2) by the tracer will  return  a  status  value
275                     such that
276
277                       status>>8 == (SIGTRAP | (PTRACE_EVENT_VFORK_DONE<<8))
278
279                     The  PID  of  the new process can (since Linux 2.6.18) be
280                     retrieved with PTRACE_GETEVENTMSG.
281
282              PTRACE_O_TRACESECCOMP (since Linux 3.5)
283                     Stop the tracee when a seccomp(2) SECCOMP_RET_TRACE  rule
284                     is  triggered.   A waitpid(2) by the tracer will return a
285                     status value such that
286
287                       status>>8 == (SIGTRAP | (PTRACE_EVENT_SECCOMP<<8))
288
289                     While this triggers a PTRACE_EVENT stop, it is similar to
290                     a  syscall-enter-stop.   For  details,  see  the  note on
291                     PTRACE_EVENT_SECCOMP below.  The  seccomp  event  message
292                     data  (from  the  SECCOMP_RET_DATA portion of the seccomp
293                     filter rule) can be retrieved with PTRACE_GETEVENTMSG.
294
295              PTRACE_O_SUSPEND_SECCOMP (since Linux 4.3)
296                     Suspend the tracee's seccomp protections.   This  applies
297                     regardless  of  mode, and can be used when the tracee has
298                     not yet installed seccomp filters.  That is, a valid  use
299                     case  is to suspend a tracee's seccomp protections before
300                     they are installed by the tracee, let the tracee  install
301                     the  filters,  and  then clear this flag when the filters
302                     should be resumed.  Setting this option requires that the
303                     tracer  have  the  CAP_SYS_ADMIN capability, not have any
304                     seccomp protections installed, and not have PTRACE_O_SUS‐
305                     PEND_SECCOMP set on itself.
306
307       PTRACE_GETEVENTMSG (since Linux 2.5.46)
308              Retrieve  a message (as an unsigned long) about the ptrace event
309              that just happened, placing  it  at  the  address  data  in  the
310              tracer.   For  PTRACE_EVENT_EXIT, this is the tracee's exit sta‐
311              tus.       For      PTRACE_EVENT_FORK,       PTRACE_EVENT_VFORK,
312              PTRACE_EVENT_VFORK_DONE, and PTRACE_EVENT_CLONE, this is the PID
313              of the new process.  For PTRACE_EVENT_SECCOMP, this is the  sec‐
314              comp(2)  filter's SECCOMP_RET_DATA associated with the triggered
315              rule.  (addr is ignored.)
316
317       PTRACE_CONT
318              Restart the stopped tracee process.  If data is nonzero,  it  is
319              interpreted  as  the  number  of a signal to be delivered to the
320              tracee; otherwise, no signal is delivered.  Thus,  for  example,
321              the  tracer  can  control whether a signal sent to the tracee is
322              delivered or not.  (addr is ignored.)
323
324       PTRACE_SYSCALL, PTRACE_SINGLESTEP
325              Restart the stopped tracee as for PTRACE_CONT, but  arrange  for
326              the  tracee  to  be  stopped at the next entry to or exit from a
327              system call, or after execution of a single instruction, respec‐
328              tively.   (The  tracee  will  also,  as  usual,  be stopped upon
329              receipt of a signal.)  From the tracer's perspective, the tracee
330              will  appear  to have been stopped by receipt of a SIGTRAP.  So,
331              for PTRACE_SYSCALL, for example, the  idea  is  to  inspect  the
332              arguments  to the system call at the first stop, then do another
333              PTRACE_SYSCALL and inspect the return value of the  system  call
334              at  the  second  stop.   The  data  argument  is  treated as for
335              PTRACE_CONT.  (addr is ignored.)
336
337       PTRACE_SYSEMU, PTRACE_SYSEMU_SINGLESTEP (since Linux 2.6.14)
338              For PTRACE_SYSEMU, continue and stop on entry to the next system
339              call,  which  will  not  be  executed.  See the documentation on
340              syscall-stops below.  For PTRACE_SYSEMU_SINGLESTEP, do the  same
341              but  also singlestep if not a system call.  This call is used by
342              programs like User Mode Linux  that  want  to  emulate  all  the
343              tracee's  system  calls.   The  data  argument is treated as for
344              PTRACE_CONT.  The addr argument is ignored.  These requests  are
345              currently supported only on x86.
346
347       PTRACE_LISTEN (since Linux 3.4)
348              Restart  the stopped tracee, but prevent it from executing.  The
349              resulting state of the tracee is similar to a process which  has
350              been  stopped  by a SIGSTOP (or other stopping signal).  See the
351              "group-stop" subsection for additional information.  PTRACE_LIS‐
352              TEN works only on tracees attached by PTRACE_SEIZE.
353
354       PTRACE_KILL
355              Send  the  tracee a SIGKILL to terminate it.  (addr and data are
356              ignored.)
357
358              This operation is deprecated; do not use it!   Instead,  send  a
359              SIGKILL  directly  using kill(2) or tgkill(2).  The problem with
360              PTRACE_KILL is that it requires the  tracee  to  be  in  signal-
361              delivery-stop,  otherwise  it  may  not work (i.e., may complete
362              successfully but won't kill the tracee).  By contrast, sending a
363              SIGKILL directly has no such limitation.
364
365       PTRACE_INTERRUPT (since Linux 3.4)
366              Stop  a  tracee.  If the tracee is running or sleeping in kernel
367              space and PTRACE_SYSCALL is in effect, the system call is inter‐
368              rupted and syscall-exit-stop is reported.  (The interrupted sys‐
369              tem call is restarted when the tracee  is  restarted.)   If  the
370              tracee  was  already  stopped  by a signal and PTRACE_LISTEN was
371              sent to it, the tracee stops with PTRACE_EVENT_STOP  and  WSTOP‐
372              SIG(status)  returns  the stop signal.  If any other ptrace-stop
373              is generated at the same time (for example, if a signal is  sent
374              to  the tracee), this ptrace-stop happens.  If none of the above
375              applies (for example, if the tracee is running in  user  space),
376              it  stops  with  PTRACE_EVENT_STOP with WSTOPSIG(status) == SIG‐
377              TRAP.   PTRACE_INTERRUPT  only  works  on  tracees  attached  by
378              PTRACE_SEIZE.
379
380       PTRACE_ATTACH
381              Attach  to  the  process specified in pid, making it a tracee of
382              the calling process.  The tracee is sent a SIGSTOP, but will not
383              necessarily  have  stopped  by  the completion of this call; use
384              waitpid(2) to wait for the tracee to stop.  See  the  "Attaching
385              and detaching" subsection for additional information.  (addr and
386              data are ignored.)
387
388              Permission to perform a PTRACE_ATTACH is governed  by  a  ptrace
389              access mode PTRACE_MODE_ATTACH_REALCREDS check; see below.
390
391       PTRACE_SEIZE (since Linux 3.4)
392              Attach  to  the  process specified in pid, making it a tracee of
393              the calling process.  Unlike  PTRACE_ATTACH,  PTRACE_SEIZE  does
394              not   stop   the   process.    Group-stops   are   reported   as
395              PTRACE_EVENT_STOP and WSTOPSIG(status) returns the stop  signal.
396              Automatically  attached children stop with PTRACE_EVENT_STOP and
397              WSTOPSIG(status) returns SIGTRAP instead of having SIGSTOP  sig‐
398              nal delivered to them.  execve(2) does not deliver an extra SIG‐
399              TRAP.  Only a PTRACE_SEIZEd process can accept  PTRACE_INTERRUPT
400              and   PTRACE_LISTEN   commands.    The  "seized"  behavior  just
401              described  is  inherited  by  children  that  are  automatically
402              attached   using  PTRACE_O_TRACEFORK,  PTRACE_O_TRACEVFORK,  and
403              PTRACE_O_TRACECLONE.  addr must be zero.  data  contains  a  bit
404              mask of ptrace options to activate immediately.
405
406              Permission  to  perform  a  PTRACE_SEIZE is governed by a ptrace
407              access mode PTRACE_MODE_ATTACH_REALCREDS check; see below.
408
409       PTRACE_SECCOMP_GET_FILTER (since Linux 4.4)
410              This operation allows the tracer to dump  the  tracee's  classic
411              BPF filters.
412
413              addr  is  an  integer  specifying  the index of the filter to be
414              dumped.  The most recently installed filter has the index 0.  If
415              addr is greater than the number of installed filters, the opera‐
416              tion fails with the error ENOENT.
417
418              data is either a pointer to a struct sock_filter array  that  is
419              large enough to store the BPF program, or NULL if the program is
420              not to be stored.
421
422              Upon success, the return value is the number of instructions  in
423              the  BPF  program.  If data was NULL, then this return value can
424              be used to correctly size the struct sock_filter array passed in
425              a subsequent call.
426
427              This  operation  fails with the error EACCESS if the caller does
428              not have the CAP_SYS_ADMIN capability or if  the  caller  is  in
429              strict  or  filter  seccomp  mode.  If the filter referred to by
430              addr is not a classic BPF filter, the operation fails  with  the
431              error EMEDIUMTYPE.
432
433              This  operation  is  available if the kernel was configured with
434              both the CONFIG_SECCOMP_FILTER and the CONFIG_CHECKPOINT_RESTORE
435              options.
436
437       PTRACE_DETACH
438              Restart  the stopped tracee as for PTRACE_CONT, but first detach
439              from it.  Under Linux, a tracee can  be  detached  in  this  way
440              regardless  of which method was used to initiate tracing.  (addr
441              is ignored.)
442
443       PTRACE_GET_THREAD_AREA (since Linux 2.6.0)
444              This operation performs a similar  task  to  get_thread_area(2).
445              It  reads the TLS entry in the GDT whose index is given in addr,
446              placing a copy of the entry into the struct user_desc pointed to
447              by data.  (By contrast with get_thread_area(2), the entry_number
448              of the struct user_desc is ignored.)
449
450       PTRACE_SET_THREAD_AREA (since Linux 2.6.0)
451              This operation performs a similar  task  to  set_thread_area(2).
452              It  sets  the TLS entry in the GDT whose index is given in addr,
453              assigning it the data supplied in the struct  user_desc  pointed
454              to   by   data.    (By  contrast  with  set_thread_area(2),  the
455              entry_number of the struct user_desc is ignored; in other words,
456              this  ptrace  operation  can't  be  used  to allocate a free TLS
457              entry.)
458
459   Death under ptrace
460       When a (possibly multithreaded) process receives a killing signal  (one
461       whose disposition is set to SIG_DFL and whose default action is to kill
462       the process), all threads exit.  Tracees report their  death  to  their
463       tracer(s).  Notification of this event is delivered via waitpid(2).
464
465       Note  that the killing signal will first cause signal-delivery-stop (on
466       one tracee only), and only after it is injected by the tracer (or after
467       it  was dispatched to a thread which isn't traced), will death from the
468       signal happen on all tracees within a multithreaded process.  (The term
469       "signal-delivery-stop" is explained below.)
470
471       SIGKILL does not generate signal-delivery-stop and therefore the tracer
472       can't suppress it.  SIGKILL kills even within  system  calls  (syscall-
473       exit-stop  is not generated prior to death by SIGKILL).  The net effect
474       is that SIGKILL always kills the process (all  its  threads),  even  if
475       some threads of the process are ptraced.
476
477       When  the  tracee  calls  _exit(2), it reports its death to its tracer.
478       Other threads are not affected.
479
480       When any thread executes exit_group(2),  every  tracee  in  its  thread
481       group reports its death to its tracer.
482
483       If  the  PTRACE_O_TRACEEXIT option is on, PTRACE_EVENT_EXIT will happen
484       before actual death.  This applies to exits via exit(2), exit_group(2),
485       and signal deaths (except SIGKILL, depending on the kernel version; see
486       BUGS below), and when threads are torn down on execve(2)  in  a  multi‐
487       threaded process.
488
489       The  tracer cannot assume that the ptrace-stopped tracee exists.  There
490       are many scenarios when the tracee  may  die  while  stopped  (such  as
491       SIGKILL).   Therefore,  the  tracer must be prepared to handle an ESRCH
492       error on any  ptrace  operation.   Unfortunately,  the  same  error  is
493       returned  if  the tracee exists but is not ptrace-stopped (for commands
494       which require a stopped tracee), or if it is not traced by the  process
495       which  issued  the  ptrace call.  The tracer needs to keep track of the
496       stopped/running state of the tracee, and  interpret  ESRCH  as  "tracee
497       died  unexpectedly"  only if it knows that the tracee has been observed
498       to enter ptrace-stop.  Note that  there  is  no  guarantee  that  wait‐
499       pid(WNOHANG) will reliably report the tracee's death status if a ptrace
500       operation returned ESRCH.  waitpid(WNOHANG) may return 0  instead.   In
501       other words, the tracee may be "not yet fully dead", but already refus‐
502       ing ptrace requests.
503
504       The tracer can't assume that the tracee always ends its life by report‐
505       ing  WIFEXITED(status)  or  WIFSIGNALED(status);  there are cases where
506       this does not occur.  For example, if a thread other than thread  group
507       leader  does  an  execve(2),  it disappears; its PID will never be seen
508       again, and any subsequent ptrace  stops  will  be  reported  under  the
509       thread group leader's PID.
510
511   Stopped states
512       A tracee can be in two states: running or stopped.  For the purposes of
513       ptrace, a tracee which is blocked in a system call  (such  as  read(2),
514       pause(2),  etc.)  is nevertheless considered to be running, even if the
515       tracee is blocked for a long time.   The  state  of  the  tracee  after
516       PTRACE_LISTEN  is somewhat of a gray area: it is not in any ptrace-stop
517       (ptrace commands won't work on it, and it will deliver waitpid(2) noti‐
518       fications),  but  it also may be considered "stopped" because it is not
519       executing instructions (is not scheduled), and if it was in  group-stop
520       before  PTRACE_LISTEN,  it will not respond to signals until SIGCONT is
521       received.
522
523       There are many kinds of states when  the  tracee  is  stopped,  and  in
524       ptrace  discussions  they are often conflated.  Therefore, it is impor‐
525       tant to use precise terms.
526
527       In this manual page, any stopped state in which the tracee is ready  to
528       accept  ptrace commands from the tracer is called ptrace-stop.  Ptrace-
529       stops can be further subdivided into signal-delivery-stop,  group-stop,
530       syscall-stop,  PTRACE_EVENT stops, and so on.  These stopped states are
531       described in detail below.
532
533       When the running tracee enters  ptrace-stop,  it  notifies  its  tracer
534       using  waitpid(2)  (or  one of the other "wait" system calls).  Most of
535       this manual page assumes that the tracer waits with:
536
537           pid = waitpid(pid_or_minus_1, &status, __WALL);
538
539       Ptrace-stopped tracees are reported as returns with pid greater than  0
540       and WIFSTOPPED(status) true.
541
542       The  __WALL  flag  does not include the WSTOPPED and WEXITED flags, but
543       implies their functionality.
544
545       Setting the WCONTINUED flag when calling waitpid(2) is not recommended:
546       the  "continued"  state is per-process and consuming it can confuse the
547       real parent of the tracee.
548
549       Use of the WNOHANG flag may cause waitpid(2)  to  return  0  ("no  wait
550       results  available  yet")  even  if  the tracer knows there should be a
551       notification.  Example:
552
553           errno = 0;
554           ptrace(PTRACE_CONT, pid, 0L, 0L);
555           if (errno == ESRCH) {
556               /* tracee is dead */
557               r = waitpid(tracee, &status, __WALL | WNOHANG);
558               /* r can still be 0 here! */
559           }
560
561       The  following  kinds  of  ptrace-stops  exist:  signal-delivery-stops,
562       group-stops,  PTRACE_EVENT stops, syscall-stops.  They all are reported
563       by waitpid(2) with WIFSTOPPED(status) true.  They may be differentiated
564       by  examining  the  value  status>>8, and if there is ambiguity in that
565       value, by  querying  PTRACE_GETSIGINFO.   (Note:  the  WSTOPSIG(status)
566       macro can't be used to perform this examination, because it returns the
567       value (status>>8) & 0xff.)
568
569   Signal-delivery-stop
570       When a (possibly multithreaded)  process  receives  any  signal  except
571       SIGKILL,  the kernel selects an arbitrary thread which handles the sig‐
572       nal.  (If the signal is generated with tgkill(2), the target thread can
573       be  explicitly  selected  by  the  caller.)   If the selected thread is
574       traced, it enters signal-delivery-stop.  At this point, the  signal  is
575       not  yet delivered to the process, and can be suppressed by the tracer.
576       If the tracer doesn't suppress the signal, it passes the signal to  the
577       tracee  in the next ptrace restart request.  This second step of signal
578       delivery is called signal injection in this manual page.  Note that  if
579       the  signal  is  blocked, signal-delivery-stop doesn't happen until the
580       signal is unblocked, with the usual exception  that  SIGSTOP  can't  be
581       blocked.
582
583       Signal-delivery-stop  is observed by the tracer as waitpid(2) returning
584       with WIFSTOPPED(status) true, with the signal returned by WSTOPSIG(sta‐
585       tus).   If  the  signal  is  SIGTRAP,  this  may be a different kind of
586       ptrace-stop; see the "Syscall-stops" and "execve"  sections  below  for
587       details.   If WSTOPSIG(status) returns a stopping signal, this may be a
588       group-stop; see below.
589
590   Signal injection and suppression
591       After signal-delivery-stop is observed by the tracer, the tracer should
592       restart the tracee with the call
593
594           ptrace(PTRACE_restart, pid, 0, sig)
595
596       where  PTRACE_restart is one of the restarting ptrace requests.  If sig
597       is 0, then a signal is not delivered.  Otherwise,  the  signal  sig  is
598       delivered.   This  operation  is called signal injection in this manual
599       page, to distinguish it from signal-delivery-stop.
600
601       The sig value may be different from  the  WSTOPSIG(status)  value:  the
602       tracer can cause a different signal to be injected.
603
604       Note  that a suppressed signal still causes system calls to return pre‐
605       maturely.  In this case, system calls will  be  restarted:  the  tracer
606       will  observe  the  tracee to reexecute the interrupted system call (or
607       restart_syscall(2) system call for a few system calls which use a  dif‐
608       ferent  mechanism  for  restarting)  if the tracer uses PTRACE_SYSCALL.
609       Even system calls (such as poll(2)) which  are  not  restartable  after
610       signal  are  restarted after signal is suppressed; however, kernel bugs
611       exist which cause some system calls to fail with EINTR even  though  no
612       observable signal is injected to the tracee.
613
614       Restarting  ptrace  commands  issued in ptrace-stops other than signal-
615       delivery-stop are not guaranteed to inject a signal,  even  if  sig  is
616       nonzero.   No  error  is reported; a nonzero sig may simply be ignored.
617       Ptrace users should not try to "create a  new  signal"  this  way:  use
618       tgkill(2) instead.
619
620       The  fact that signal injection requests may be ignored when restarting
621       the tracee after ptrace stops that are not signal-delivery-stops  is  a
622       cause  of  confusion  among ptrace users.  One typical scenario is that
623       the tracer observes group-stop, mistakes it  for  signal-delivery-stop,
624       restarts the tracee with
625
626           ptrace(PTRACE_restart, pid, 0, stopsig)
627
628       with  the  intention of injecting stopsig, but stopsig gets ignored and
629       the tracee continues to run.
630
631       The SIGCONT signal has a side effect of waking up (all  threads  of)  a
632       group-stopped  process.   This side effect happens before signal-deliv‐
633       ery-stop.  The tracer can't suppress this side effect (it can only sup‐
634       press signal injection, which only causes the SIGCONT handler to not be
635       executed in the tracee, if such a handler is installed).  In fact, wak‐
636       ing up from group-stop may be followed by signal-delivery-stop for sig‐
637       nal(s) other than SIGCONT, if they were pending when SIGCONT was deliv‐
638       ered.   In other words, SIGCONT may be not the first signal observed by
639       the tracee after it was sent.
640
641       Stopping signals cause (all threads of) a process to enter  group-stop.
642       This  side  effect happens after signal injection, and therefore can be
643       suppressed by the tracer.
644
645       In Linux 2.4 and earlier, the SIGSTOP signal can't be injected.
646
647       PTRACE_GETSIGINFO can be used to retrieve a siginfo_t  structure  which
648       corresponds  to the delivered signal.  PTRACE_SETSIGINFO may be used to
649       modify it.  If PTRACE_SETSIGINFO has been used to alter siginfo_t,  the
650       si_signo  field  and  the  sig parameter in the restarting command must
651       match, otherwise the result is undefined.
652
653   Group-stop
654       When a (possibly multithreaded) process receives a stopping signal, all
655       threads  stop.   If  some  threads are traced, they enter a group-stop.
656       Note that the stopping signal will first cause signal-delivery-stop (on
657       one tracee only), and only after it is injected by the tracer (or after
658       it was dispatched to a thread which isn't traced), will  group-stop  be
659       initiated  on  all tracees within the multithreaded process.  As usual,
660       every tracee reports its group-stop  separately  to  the  corresponding
661       tracer.
662
663       Group-stop  is observed by the tracer as waitpid(2) returning with WIF‐
664       STOPPED(status) true, with the stopping  signal  available  via  WSTOP‐
665       SIG(status).   The  same  result  is  returned by some other classes of
666       ptrace-stops, therefore the recommended practice is to perform the call
667
668           ptrace(PTRACE_GETSIGINFO, pid, 0, &siginfo)
669
670       The call can be avoided if the signal is not SIGSTOP, SIGTSTP, SIGTTIN,
671       or  SIGTTOU;  only  these  four  signals  are stopping signals.  If the
672       tracer sees something else, it can't be a group-stop.   Otherwise,  the
673       tracer  needs  to  call  PTRACE_GETSIGINFO.  If PTRACE_GETSIGINFO fails
674       with EINVAL, then it is definitely a group-stop.  (Other failure  codes
675       are possible, such as ESRCH ("no such process") if a SIGKILL killed the
676       tracee.)
677
678       If tracee was attached using PTRACE_SEIZE, group-stop is  indicated  by
679       PTRACE_EVENT_STOP: status>>16 == PTRACE_EVENT_STOP.  This allows detec‐
680       tion of group-stops without requiring an extra PTRACE_GETSIGINFO call.
681
682       As of Linux 2.6.38, after the tracer sees the  tracee  ptrace-stop  and
683       until  it  restarts  or kills it, the tracee will not run, and will not
684       send notifications (except SIGKILL death) to the tracer,  even  if  the
685       tracer enters into another waitpid(2) call.
686
687       The  kernel behavior described in the previous paragraph causes a prob‐
688       lem with transparent handling  of  stopping  signals.   If  the  tracer
689       restarts  the  tracee  after  group-stop, the stopping signal is effec‐
690       tively ignored—the tracee doesn't remain  stopped,  it  runs.   If  the
691       tracer  doesn't  restart the tracee before entering into the next wait‐
692       pid(2), future SIGCONT signals will not be reported to the tracer; this
693       would cause the SIGCONT signals to have no effect on the tracee.
694
695       Since Linux 3.4, there is a method to overcome this problem: instead of
696       PTRACE_CONT, a PTRACE_LISTEN command can be used to restart a tracee in
697       a way where it does not execute, but waits for a new event which it can
698       report via waitpid(2) (such as when it is restarted by a SIGCONT).
699
700   PTRACE_EVENT stops
701       If the tracer sets PTRACE_O_TRACE_*  options,  the  tracee  will  enter
702       ptrace-stops called PTRACE_EVENT stops.
703
704       PTRACE_EVENT  stops  are observed by the tracer as waitpid(2) returning
705       with WIFSTOPPED(status),  and  WSTOPSIG(status)  returns  SIGTRAP.   An
706       additional  bit is set in the higher byte of the status word: the value
707       status>>8 will be
708
709           (SIGTRAP | PTRACE_EVENT_foo << 8).
710
711       The following events exist:
712
713       PTRACE_EVENT_VFORK
714              Stop  before  return  from  vfork(2)  or   clone(2)   with   the
715              CLONE_VFORK flag.  When the tracee is continued after this stop,
716              it will wait for child to exit/exec before continuing its execu‐
717              tion (in other words, the usual behavior on vfork(2)).
718
719       PTRACE_EVENT_FORK
720              Stop before return from fork(2) or clone(2) with the exit signal
721              set to SIGCHLD.
722
723       PTRACE_EVENT_CLONE
724              Stop before return from clone(2).
725
726       PTRACE_EVENT_VFORK_DONE
727              Stop  before  return  from  vfork(2)  or   clone(2)   with   the
728              CLONE_VFORK  flag,  but after the child unblocked this tracee by
729              exiting or execing.
730
731       For all four stops described above,  the  stop  occurs  in  the  parent
732       (i.e.,    the    tracee),    not   in   the   newly   created   thread.
733       PTRACE_GETEVENTMSG can be used to retrieve the new thread's ID.
734
735       PTRACE_EVENT_EXEC
736              Stop  before  return   from   execve(2).    Since   Linux   3.0,
737              PTRACE_GETEVENTMSG returns the former thread ID.
738
739       PTRACE_EVENT_EXIT
740              Stop  before  exit  (including death from exit_group(2)), signal
741              death, or exit caused by execve(2) in a  multithreaded  process.
742              PTRACE_GETEVENTMSG  returns  the  exit status.  Registers can be
743              examined (unlike when "real" exit happens).  The tracee is still
744              alive; it needs to be PTRACE_CONTed or PTRACE_DETACHed to finish
745              exiting.
746
747       PTRACE_EVENT_STOP
748              Stop induced by PTRACE_INTERRUPT command, or group-stop, or ini‐
749              tial  ptrace-stop when a new child is attached (only if attached
750              using PTRACE_SEIZE).
751
752       PTRACE_EVENT_SECCOMP
753              Stop triggered by a seccomp(2) rule on tracee syscall entry when
754              PTRACE_O_TRACESECCOMP  has  been set by the tracer.  The seccomp
755              event message data (from the  SECCOMP_RET_DATA  portion  of  the
756              seccomp  filter  rule) can be retrieved with PTRACE_GETEVENTMSG.
757              The semantics of this stop are described in detail in a separate
758              section below.
759
760       PTRACE_GETSIGINFO  on  PTRACE_EVENT  stops returns SIGTRAP in si_signo,
761       with si_code set to (event<<8) | SIGTRAP.
762
763   Syscall-stops
764       If the tracee was restarted by  PTRACE_SYSCALL  or  PTRACE_SYSEMU,  the
765       tracee enters syscall-enter-stop just prior to entering any system call
766       (which will not be executed if the  restart  was  using  PTRACE_SYSEMU,
767       regardless  of  any  change  made to registers at this point or how the
768       tracee is restarted after this stop).  No matter  which  method  caused
769       the   syscall-entry-stop,  if  the  tracer  restarts  the  tracee  with
770       PTRACE_SYSCALL, the tracee enters  syscall-exit-stop  when  the  system
771       call  is finished, or if it is interrupted by a signal.  (That is, sig‐
772       nal-delivery-stop never happens between syscall-enter-stop and syscall-
773       exit-stop; it happens after syscall-exit-stop.).  If the tracee is con‐
774       tinued using any other method (including  PTRACE_SYSEMU),  no  syscall-
775       exit-stop  occurs.   Note that all mentions PTRACE_SYSEMU apply equally
776       to PTRACE_SYSEMU_SINGLESTEP.
777
778       However, even if the tracee was continued using PTRACE_SYSCALL , it  is
779       not  guaranteed  that the next stop will be a syscall-exit-stop.  Other
780       possibilities are that the tracee  may  stop  in  a  PTRACE_EVENT  stop
781       (including   seccomp   stops),   exit   (if   it  entered  _exit(2)  or
782       exit_group(2)), be killed by SIGKILL, or  die  silently  (if  it  is  a
783       thread group leader, the execve(2) happened in another thread, and that
784       thread is not traced by the same tracer; this  situation  is  discussed
785       later).
786
787       Syscall-enter-stop  and syscall-exit-stop are observed by the tracer as
788       waitpid(2) returning with WIFSTOPPED(status) true, and WSTOPSIG(status)
789       giving  SIGTRAP.   If  the  PTRACE_O_TRACESYSGOOD option was set by the
790       tracer, then WSTOPSIG(status) will give the value (SIGTRAP | 0x80).
791
792       Syscall-stops can be distinguished from signal-delivery-stop with  SIG‐
793       TRAP by querying PTRACE_GETSIGINFO for the following cases:
794
795       si_code <= 0
796              SIGTRAP  was  delivered  as a result of a user-space action, for
797              example, a system call (tgkill(2), kill(2), sigqueue(3),  etc.),
798              expiration  of a POSIX timer, change of state on a POSIX message
799              queue, or completion of an asynchronous I/O request.
800
801       si_code == SI_KERNEL (0x80)
802              SIGTRAP was sent by the kernel.
803
804       si_code == SIGTRAP or si_code == (SIGTRAP|0x80)
805              This is a syscall-stop.
806
807       However, syscall-stops happen very often (twice per system  call),  and
808       performing  PTRACE_GETSIGINFO  for  every  syscall-stop may be somewhat
809       expensive.
810
811       Some architectures allow the cases to  be  distinguished  by  examining
812       registers.   For example, on x86, rax == -ENOSYS in syscall-enter-stop.
813       Since SIGTRAP (like any other signal)  always  happens  after  syscall-
814       exit-stop,  and  at  this  point rax almost never contains -ENOSYS, the
815       SIGTRAP looks like "syscall-stop which is not  syscall-enter-stop";  in
816       other  words,  it  looks  like  a  "stray syscall-exit-stop" and can be
817       detected this way.  But such detection is fragile and is best avoided.
818
819       Using the PTRACE_O_TRACESYSGOOD option is  the  recommended  method  to
820       distinguish syscall-stops from other kinds of ptrace-stops, since it is
821       reliable and does not incur a performance penalty.
822
823       Syscall-enter-stop and  syscall-exit-stop  are  indistinguishable  from
824       each  other  by  the  tracer.   The  tracer  needs to keep track of the
825       sequence of ptrace-stops in order to  not  misinterpret  syscall-enter-
826       stop  as syscall-exit-stop or vice versa.  In general, a syscall-enter-
827       stop is always followed by syscall-exit-stop, PTRACE_EVENT stop, or the
828       tracee's  death;  no  other  kinds of ptrace-stop can occur in between.
829       However, note that seccomp stops (see below)  can  cause  syscall-exit-
830       stops,  without  preceding  syscall-entry-stops.  If seccomp is in use,
831       care needs to be taken not to misinterpret such stops as syscall-entry-
832       stops.
833
834       If after syscall-enter-stop, the tracer uses a restarting command other
835       than PTRACE_SYSCALL, syscall-exit-stop is not generated.
836
837       PTRACE_GETSIGINFO on syscall-stops returns SIGTRAP  in  si_signo,  with
838       si_code set to SIGTRAP or (SIGTRAP|0x80).
839
840   PTRACE_EVENT_SECCOMP stops (Linux 3.5 to 4.7)
841       The  behavior  of PTRACE_EVENT_SECCOMP stops and their interaction with
842       other kinds of ptrace stops has changed between kernel versions.   This
843       documents  the behavior from their introduction until Linux 4.7 (inclu‐
844       sive).  The behavior in later kernel versions is documented in the next
845       section.
846
847       A PTRACE_EVENT_SECCOMP stop occurs whenever a SECCOMP_RET_TRACE rule is
848       triggered.  This is independent of which methods was  used  to  restart
849       the  system  call.   Notably, seccomp still runs even if the tracee was
850       restarted using PTRACE_SYSEMU and this system call  is  unconditionally
851       skipped.
852
853       Restarts  from  this stop will behave as if the stop had occurred right
854       before the system call in question.  In particular, both PTRACE_SYSCALL
855       and  PTRACE_SYSEMU will normally cause a subsequent syscall-entry-stop.
856       However, if after the PTRACE_EVENT_SECCOMP the system  call  number  is
857       negative,  both  the syscall-entry-stop and the system call itself will
858       be skipped.  This means that if the  system  call  number  is  negative
859       after   a  PTRACE_EVENT_SECCOMP  and  the  tracee  is  restarted  using
860       PTRACE_SYSCALL, the next observed stop  will  be  a  syscall-exit-stop,
861       rather than the syscall-entry-stop that might have been expected.
862
863   PTRACE_EVENT_SECCOMP stops (since Linux 4.8)
864       Starting with Linux 4.8, the PTRACE_EVENT_SECCOMP stop was reordered to
865       occur between syscall-entry-stop and syscall-exit-stop.  Note that sec‐
866       comp  no  longer runs (and no PTRACE_EVENT_SECCOMP will be reported) if
867       the system call is skipped due to PTRACE_SYSEMU.
868
869       Functionally, a PTRACE_EVENT_SECCOMP stop  functions  comparably  to  a
870       syscall-entry-stop (i.e., continuations using PTRACE_SYSCALL will cause
871       syscall-exit-stops, the system call number may be changed and any other
872       modified  registers  are  visible  to the to-be-executed system call as
873       well).  Note that there may be, but need  not  have  been  a  preceding
874       syscall-entry-stop.
875
876       After  a  PTRACE_EVENT_SECCOMP stop, seccomp will be rerun, with a SEC‐
877       COMP_RET_TRACE rule now functioning the same  as  a  SECCOMP_RET_ALLOW.
878       Specifically,  this means that if registers are not modified during the
879       PTRACE_EVENT_SECCOMP stop, the system call will then be allowed.
880
881   PTRACE_SINGLESTEP stops
882       [Details of these kinds of stops are yet to be documented.]
883
884   Informational and restarting ptrace commands
885       Most  ptrace  commands   (all   except   PTRACE_ATTACH,   PTRACE_SEIZE,
886       PTRACE_TRACEME,  PTRACE_INTERRUPT,  and PTRACE_KILL) require the tracee
887       to be in a ptrace-stop, otherwise they fail with ESRCH.
888
889       When the tracee is in ptrace-stop, the tracer can read and  write  data
890       to  the  tracee using informational commands.  These commands leave the
891       tracee in ptrace-stopped state:
892
893           ptrace(PTRACE_PEEKTEXT/PEEKDATA/PEEKUSER, pid, addr, 0);
894           ptrace(PTRACE_POKETEXT/POKEDATA/POKEUSER, pid, addr, long_val);
895           ptrace(PTRACE_GETREGS/GETFPREGS, pid, 0, &struct);
896           ptrace(PTRACE_SETREGS/SETFPREGS, pid, 0, &struct);
897           ptrace(PTRACE_GETREGSET, pid, NT_foo, &iov);
898           ptrace(PTRACE_SETREGSET, pid, NT_foo, &iov);
899           ptrace(PTRACE_GETSIGINFO, pid, 0, &siginfo);
900           ptrace(PTRACE_SETSIGINFO, pid, 0, &siginfo);
901           ptrace(PTRACE_GETEVENTMSG, pid, 0, &long_var);
902           ptrace(PTRACE_SETOPTIONS, pid, 0, PTRACE_O_flags);
903
904       Note that some errors are not reported.  For  example,  setting  signal
905       information  (siginfo) may have no effect in some ptrace-stops, yet the
906       call  may  succeed   (return   0   and   not   set   errno);   querying
907       PTRACE_GETEVENTMSG  may succeed and return some random value if current
908       ptrace-stop is not documented as returning a meaningful event message.
909
910       The call
911
912           ptrace(PTRACE_SETOPTIONS, pid, 0, PTRACE_O_flags);
913
914       affects one tracee.  The tracee's current flags  are  replaced.   Flags
915       are  inherited  by  new  tracees created and "auto-attached" via active
916       PTRACE_O_TRACEFORK,   PTRACE_O_TRACEVFORK,    or    PTRACE_O_TRACECLONE
917       options.
918
919       Another  group  of  commands makes the ptrace-stopped tracee run.  They
920       have the form:
921
922           ptrace(cmd, pid, 0, sig);
923
924       where cmd is PTRACE_CONT, PTRACE_LISTEN, PTRACE_DETACH, PTRACE_SYSCALL,
925       PTRACE_SINGLESTEP,  PTRACE_SYSEMU, or PTRACE_SYSEMU_SINGLESTEP.  If the
926       tracee is in signal-delivery-stop, sig is the signal to be injected (if
927       it  is  nonzero).   Otherwise,  sig may be ignored.  (When restarting a
928       tracee from a ptrace-stop other than signal-delivery-stop,  recommended
929       practice is to always pass 0 in sig.)
930
931   Attaching and detaching
932       A thread can be attached to the tracer using the call
933
934           ptrace(PTRACE_ATTACH, pid, 0, 0);
935
936       or
937
938           ptrace(PTRACE_SEIZE, pid, 0, PTRACE_O_flags);
939
940       PTRACE_ATTACH  sends  SIGSTOP to this thread.  If the tracer wants this
941       SIGSTOP to have no effect, it needs to suppress it.  Note that if other
942       signals  are concurrently sent to this thread during attach, the tracer
943       may see the tracee  enter  signal-delivery-stop  with  other  signal(s)
944       first!   The  usual practice is to reinject these signals until SIGSTOP
945       is seen, then suppress SIGSTOP injection.  The design bug here is  that
946       a  ptrace  attach and a concurrently delivered SIGSTOP may race and the
947       concurrent SIGSTOP may be lost.
948
949       Since attaching sends SIGSTOP and the  tracer  usually  suppresses  it,
950       this may cause a stray EINTR return from the currently executing system
951       call in the tracee, as described in the "Signal injection and  suppres‐
952       sion" section.
953
954       Since  Linux  3.4,  PTRACE_SEIZE  can be used instead of PTRACE_ATTACH.
955       PTRACE_SEIZE does not stop the attached process.  If you need  to  stop
956       it  after attach (or at any other time) without sending it any signals,
957       use PTRACE_INTERRUPT command.
958
959       The request
960
961           ptrace(PTRACE_TRACEME, 0, 0, 0);
962
963       turns the calling thread into a tracee.  The thread  continues  to  run
964       (doesn't  enter  ptrace-stop).   A  common  practice  is  to follow the
965       PTRACE_TRACEME with
966
967           raise(SIGSTOP);
968
969       and allow the parent (which is our tracer now) to observe  our  signal-
970       delivery-stop.
971
972       If  the PTRACE_O_TRACEFORK, PTRACE_O_TRACEVFORK, or PTRACE_O_TRACECLONE
973       options are in effect, then children created by, respectively, vfork(2)
974       or  clone(2)  with  the  CLONE_VFORK flag, fork(2) or clone(2) with the
975       exit signal set to SIGCHLD, and other kinds of clone(2), are  automati‐
976       cally  attached  to the same tracer which traced their parent.  SIGSTOP
977       is delivered to the children, causing them  to  enter  signal-delivery-
978       stop after they exit the system call which created them.
979
980       Detaching of the tracee is performed by:
981
982           ptrace(PTRACE_DETACH, pid, 0, sig);
983
984       PTRACE_DETACH  is  a  restarting  operation;  therefore it requires the
985       tracee to be in ptrace-stop.  If the tracee is in signal-delivery-stop,
986       a signal can be injected.  Otherwise, the sig parameter may be silently
987       ignored.
988
989       If the tracee is running when the tracer wants to detach it, the  usual
990       solution  is  to send SIGSTOP (using tgkill(2), to make sure it goes to
991       the correct thread), wait for the tracee to  stop  in  signal-delivery-
992       stop for SIGSTOP and then detach it (suppressing SIGSTOP injection).  A
993       design bug is that this can race  with  concurrent  SIGSTOPs.   Another
994       complication  is that the tracee may enter other ptrace-stops and needs
995       to be restarted and waited for  again,  until  SIGSTOP  is  seen.   Yet
996       another  complication  is  to  be  sure  that the tracee is not already
997       ptrace-stopped, because no signal delivery happens while it is—not even
998       SIGSTOP.
999
1000       If  the  tracer  dies,  all  tracees  are  automatically  detached  and
1001       restarted, unless they were in group-stop.  Handling  of  restart  from
1002       group-stop  is  currently  buggy,  but  the "as planned" behavior is to
1003       leave tracee stopped  and  waiting  for  SIGCONT.   If  the  tracee  is
1004       restarted from signal-delivery-stop, the pending signal is injected.
1005
1006   execve(2) under ptrace
1007       When  one thread in a multithreaded process calls execve(2), the kernel
1008       destroys all other threads in the process, and resets the thread ID  of
1009       the  execing  thread  to the thread group ID (process ID).  (Or, to put
1010       things another way, when a multithreaded process does an execve(2),  at
1011       completion  of the call, it appears as though the execve(2) occurred in
1012       the thread group leader, regardless of which thread did the execve(2).)
1013       This resetting of the thread ID looks very confusing to tracers:
1014
1015       *  All   other   threads   stop   in  PTRACE_EVENT_EXIT  stop,  if  the
1016          PTRACE_O_TRACEEXIT option was turned on.   Then  all  other  threads
1017          except  the  thread  group leader report death as if they exited via
1018          _exit(2) with exit code 0.
1019
1020       *  The execing tracee  changes  its  thread  ID  while  it  is  in  the
1021          execve(2).   (Remember,  under ptrace, the "pid" returned from wait‐
1022          pid(2), or fed into ptrace calls, is the tracee's thread ID.)   That
1023          is,  the  tracee's  thread ID is reset to be the same as its process
1024          ID, which is the same as the thread group leader's thread ID.
1025
1026       *  Then a PTRACE_EVENT_EXEC stop  happens,  if  the  PTRACE_O_TRACEEXEC
1027          option was turned on.
1028
1029       *  If  the  thread group leader has reported its PTRACE_EVENT_EXIT stop
1030          by this time, it appears to the tracer that the dead  thread  leader
1031          "reappears  from  nowhere".  (Note: the thread group leader does not
1032          report death via WIFEXITED(status) until there is at least one other
1033          live  thread.   This eliminates the possibility that the tracer will
1034          see it dying and then reappearing.)  If the thread group leader  was
1035          still  alive, for the tracer this may look as if thread group leader
1036          returns from a different  system  call  than  it  entered,  or  even
1037          "returned  from  a  system call even though it was not in any system
1038          call".  If the thread group leader was not traced (or was traced  by
1039          a  different  tracer), then during execve(2) it will appear as if it
1040          has become a tracee of the tracer of the execing tracee.
1041
1042       All of the above effects are the artifacts of the thread ID  change  in
1043       the tracee.
1044
1045       The  PTRACE_O_TRACEEXEC option is the recommended tool for dealing with
1046       this situation.  First, it enables PTRACE_EVENT_EXEC stop, which occurs
1047       before   execve(2)   returns.    In  this  stop,  the  tracer  can  use
1048       PTRACE_GETEVENTMSG to retrieve the tracee's former  thread  ID.   (This
1049       feature  was  introduced in Linux 3.0.)  Second, the PTRACE_O_TRACEEXEC
1050       option disables legacy SIGTRAP generation on execve(2).
1051
1052       When the tracer receives PTRACE_EVENT_EXEC  stop  notification,  it  is
1053       guaranteed  that  except  this  tracee  and the thread group leader, no
1054       other threads from the process are alive.
1055
1056       On receiving the PTRACE_EVENT_EXEC stop notification, the tracer should
1057       clean  up  all  its  internal data structures describing the threads of
1058       this process, and retain only one data  structure—one  which  describes
1059       the single still running tracee, with
1060
1061           thread ID == thread group ID == process ID.
1062
1063       Example: two threads call execve(2) at the same time:
1064
1065       *** we get syscall-enter-stop in thread 1: **
1066       PID1 execve("/bin/foo", "foo" <unfinished ...>
1067       *** we issue PTRACE_SYSCALL for thread 1 **
1068       *** we get syscall-enter-stop in thread 2: **
1069       PID2 execve("/bin/bar", "bar" <unfinished ...>
1070       *** we issue PTRACE_SYSCALL for thread 2 **
1071       *** we get PTRACE_EVENT_EXEC for PID0, we issue PTRACE_SYSCALL **
1072       *** we get syscall-exit-stop for PID0: **
1073       PID0 <... execve resumed> )             = 0
1074
1075       If  the  PTRACE_O_TRACEEXEC  option  is  not  in effect for the execing
1076       tracee,  and  if   the   tracee   was   PTRACE_ATTACHed   rather   that
1077       PTRACE_SEIZEd, the kernel delivers an extra SIGTRAP to the tracee after
1078       execve(2) returns.  This is an ordinary signal (similar  to  one  which
1079       can  be  generated  by  kill -TRAP), not a special kind of ptrace-stop.
1080       Employing PTRACE_GETSIGINFO for this signal returns si_code  set  to  0
1081       (SI_USER).   This signal may be blocked by signal mask, and thus may be
1082       delivered (much) later.
1083
1084       Usually, the tracer (for example, strace(1)) would  not  want  to  show
1085       this  extra  post-execve SIGTRAP signal to the user, and would suppress
1086       its delivery to the tracee (if SIGTRAP is  set  to  SIG_DFL,  it  is  a
1087       killing signal).  However, determining which SIGTRAP to suppress is not
1088       easy.  Setting the PTRACE_O_TRACEEXEC option or using PTRACE_SEIZE  and
1089       thus suppressing this extra SIGTRAP is the recommended approach.
1090
1091   Real parent
1092       The  ptrace  API (ab)uses the standard UNIX parent/child signaling over
1093       waitpid(2).  This used to cause the real parent of the process to  stop
1094       receiving  several  kinds  of  waitpid(2)  notifications when the child
1095       process is traced by some other process.
1096
1097       Many of these bugs have been fixed, but  as  of  Linux  2.6.38  several
1098       still exist; see BUGS below.
1099
1100       As of Linux 2.6.38, the following is believed to work correctly:
1101
1102       *  exit/death by signal is reported first to the tracer, then, when the
1103          tracer consumes the waitpid(2) result, to the real  parent  (to  the
1104          real  parent  only  when the whole multithreaded process exits).  If
1105          the tracer and the real parent are the same process, the  report  is
1106          sent only once.
1107

RETURN VALUE

1109       On  success,  the  PTRACE_PEEK* requests return the requested data (but
1110       see NOTES), the PTRACE_SECCOMP_GET_FILTER request returns the number of
1111       instructions in the BPF program, and other requests return zero.
1112
1113       On  error,  all  requests  return  -1,  and errno is set appropriately.
1114       Since the value returned by a successful PTRACE_PEEK*  request  may  be
1115       -1,  the  caller  must  clear  errno before the call, and then check it
1116       afterward to determine whether or not an error occurred.
1117

ERRORS

1119       EBUSY  (i386 only) There was an error  with  allocating  or  freeing  a
1120              debug register.
1121
1122       EFAULT There was an attempt to read from or write to an invalid area in
1123              the tracer's or the tracee's memory, probably because  the  area
1124              wasn't  mapped  or accessible.  Unfortunately, under Linux, dif‐
1125              ferent variations of this fault will return EIO or  EFAULT  more
1126              or less arbitrarily.
1127
1128       EINVAL An attempt was made to set an invalid option.
1129
1130       EIO    request is invalid, or an attempt was made to read from or write
1131              to an invalid area in the tracer's or the  tracee's  memory,  or
1132              there  was  a word-alignment violation, or an invalid signal was
1133              specified during a restart request.
1134
1135       EPERM  The specified process cannot be traced.  This could  be  because
1136              the  tracer has insufficient privileges (the required capability
1137              is CAP_SYS_PTRACE); unprivileged  processes  cannot  trace  pro‐
1138              cesses  that  they  cannot send signals to or those running set-
1139              user-ID/set-group-ID programs, for  obvious  reasons.   Alterna‐
1140              tively,  the process may already be being traced, or (on kernels
1141              before 2.6.26) be init(1) (PID 1).
1142
1143       ESRCH  The specified process does not exist, or is not currently  being
1144              traced  by  the  caller,  or  is  not stopped (for requests that
1145              require a stopped tracee).
1146

CONFORMING TO

1148       SVr4, 4.3BSD.
1149

NOTES

1151       Although arguments to ptrace() are interpreted according to the  proto‐
1152       type  given,  glibc  currently declares ptrace() as a variadic function
1153       with only the request argument fixed.  It is recommended to always sup‐
1154       ply  four arguments, even if the requested operation does not use them,
1155       setting unused/ignored arguments to 0L or (void *) 0.
1156
1157       In Linux kernels before 2.6.26, init(1), the process with  PID  1,  may
1158       not be traced.
1159
1160       A  tracees  parent continues to be the tracer even if that tracer calls
1161       execve(2).
1162
1163       The layout of the contents of memory and the USER area are quite  oper‐
1164       ating-system-  and architecture-specific.  The offset supplied, and the
1165       data returned, might not entirely match with the definition  of  struct
1166       user.
1167
1168       The  size  of  a  "word"  is determined by the operating-system variant
1169       (e.g., for 32-bit Linux it is 32 bits).
1170
1171       This page documents the way the ptrace() call works currently in Linux.
1172       Its  behavior  differs  significantly on other flavors of UNIX.  In any
1173       case, use of ptrace() is highly specific to the  operating  system  and
1174       architecture.
1175
1176   Ptrace access mode checking
1177       Various  parts  of  the kernel-user-space API (not just ptrace() opera‐
1178       tions), require so-called "ptrace access mode"  checks,  whose  outcome
1179       determines  whether  an  operation  is  permitted  (or, in a few cases,
1180       causes a "read" operation to return sanitized data).  These checks  are
1181       performed  in cases where one process can inspect sensitive information
1182       about, or in some cases modify the  state  of,  another  process.   The
1183       checks are based on factors such as the credentials and capabilities of
1184       the two processes, whether or not the "target" process is dumpable, and
1185       the  results  of  checks performed by any enabled Linux Security Module
1186       (LSM)—for example, SELinux, Yama, or Smack—and  by  the  commoncap  LSM
1187       (which is always invoked).
1188
1189       Prior  to Linux 2.6.27, all access checks were of a single type.  Since
1190       Linux 2.6.27, two access mode levels are distinguished:
1191
1192       PTRACE_MODE_READ
1193              For "read" operations or other operations that are less  danger‐
1194              ous,    such    as:    get_robust_list(2);    kcmp(2);   reading
1195              /proc/[pid]/auxv, /proc/[pid]/environ, or  /proc/[pid]/stat;  or
1196              readlink(2) of a /proc/[pid]/ns/* file.
1197
1198       PTRACE_MODE_ATTACH
1199              For  "write"  operations, or other operations that are more dan‐
1200              gerous, such as: ptrace  attaching  (PTRACE_ATTACH)  to  another
1201              process  or  calling  process_vm_writev(2).  (PTRACE_MODE_ATTACH
1202              was effectively the default before Linux 2.6.27.)
1203
1204       Since Linux 4.5, the above access mode checks are combined (ORed)  with
1205       one of the following modifiers:
1206
1207       PTRACE_MODE_FSCREDS
1208              Use  the caller's filesystem UID and GID (see credentials(7)) or
1209              effective capabilities for LSM checks.
1210
1211       PTRACE_MODE_REALCREDS
1212              Use the caller's real UID and GID or permitted capabilities  for
1213              LSM checks.  This was effectively the default before Linux 4.5.
1214
1215       Because  combining  one  of  the  credential  modifiers with one of the
1216       aforementioned access modes is typical, some macros are defined in  the
1217       kernel sources for the combinations:
1218
1219       PTRACE_MODE_READ_FSCREDS
1220              Defined as PTRACE_MODE_READ | PTRACE_MODE_FSCREDS.
1221
1222       PTRACE_MODE_READ_REALCREDS
1223              Defined as PTRACE_MODE_READ | PTRACE_MODE_REALCREDS.
1224
1225       PTRACE_MODE_ATTACH_FSCREDS
1226              Defined as PTRACE_MODE_ATTACH | PTRACE_MODE_FSCREDS.
1227
1228       PTRACE_MODE_ATTACH_REALCREDS
1229              Defined as PTRACE_MODE_ATTACH | PTRACE_MODE_REALCREDS.
1230
1231       One further modifier can be ORed with the access mode:
1232
1233       PTRACE_MODE_NOAUDIT (since Linux 3.3)
1234              Don't  audit  this access mode check.  This modifier is employed
1235              for ptrace access mode  checks  (such  as  checks  when  reading
1236              /proc/[pid]/stat) that merely cause the output to be filtered or
1237              sanitized, rather than causing an error to be  returned  to  the
1238              caller.   In  these  cases, accessing the file is not a security
1239              violation and there is no reason to generate  a  security  audit
1240              record.   This  modifier  suppresses  the  generation of such an
1241              audit record for the particular access check.
1242
1243       Note that all of the PTRACE_MODE_* constants described in this  subsec‐
1244       tion  are kernel-internal, and not visible to user space.  The constant
1245       names are mentioned here in order to label the various kinds of  ptrace
1246       access  mode  checks  that  are  performed for various system calls and
1247       accesses to various pseudofiles (e.g., under /proc).  These  names  are
1248       used  in  other manual pages to provide a simple shorthand for labeling
1249       the different kernel checks.
1250
1251       The algorithm employed  for  ptrace  access  mode  checking  determines
1252       whether  the  calling  process  is allowed to perform the corresponding
1253       action on the target process.  (In  the  case  of  opening  /proc/[pid]
1254       files,  the  "calling  process"  is  the  one opening the file, and the
1255       process with the corresponding PID is the "target process".)  The algo‐
1256       rithm is as follows:
1257
1258       1. If  the  calling thread and the target thread are in the same thread
1259          group, access is always allowed.
1260
1261       2. If the access mode  specifies  PTRACE_MODE_FSCREDS,  then,  for  the
1262          check  in the next step, employ the caller's filesystem UID and GID.
1263          (As noted in credentials(7),  the  filesystem  UID  and  GID  almost
1264          always have the same values as the corresponding effective IDs.)
1265
1266          Otherwise,  the  access mode specifies PTRACE_MODE_REALCREDS, so use
1267          the caller's real UID and GID for  the  checks  in  the  next  step.
1268          (Most  APIs  that  check  the caller's UID and GID use the effective
1269          IDs.  For historical reasons, the PTRACE_MODE_REALCREDS  check  uses
1270          the real IDs instead.)
1271
1272       3. Deny access if neither of the following is true:
1273
1274          · The  real,  effective,  and saved-set user IDs of the target match
1275            the caller's user ID, and the real, effective, and saved-set group
1276            IDs of the target match the caller's group ID.
1277
1278          · The caller has the CAP_SYS_PTRACE capability in the user namespace
1279            of the target.
1280
1281       4. Deny access if the target process "dumpable" attribute has  a  value
1282          other  than 1 (SUID_DUMP_USER; see the discussion of PR_SET_DUMPABLE
1283          in prctl(2)), and the caller does not have the CAP_SYS_PTRACE  capa‐
1284          bility in the user namespace of the target process.
1285
1286       5. The  kernel  LSM security_ptrace_access_check() interface is invoked
1287          to see if ptrace access is permitted.  The  results  depend  on  the
1288          LSM(s).   The  implementation of this interface in the commoncap LSM
1289          performs the following steps:
1290
1291          a) If the access mode includes  PTRACE_MODE_FSCREDS,  then  use  the
1292             caller's  effective capability set in the following check; other‐
1293             wise (the access mode specifies  PTRACE_MODE_REALCREDS,  so)  use
1294             the caller's permitted capability set.
1295
1296          b) Deny access if neither of the following is true:
1297
1298             · The  caller  and the target process are in the same user names‐
1299               pace, and the caller's capabilities are a  proper  superset  of
1300               the target process's permitted capabilities.
1301
1302             · The  caller  has  the  CAP_SYS_PTRACE  capability in the target
1303               process's user namespace.
1304
1305             Note  that  the  commoncap  LSM  does  not  distinguish   between
1306             PTRACE_MODE_READ and PTRACE_MODE_ATTACH.
1307
1308       6. If  access  has  not been denied by any of the preceding steps, then
1309          access is allowed.
1310
1311   /proc/sys/kernel/yama/ptrace_scope
1312       On systems with the Yama Linux Security Module (LSM)  installed  (i.e.,
1313       the    kernel    was   configured   with   CONFIG_SECURITY_YAMA),   the
1314       /proc/sys/kernel/yama/ptrace_scope file (available since Linux 3.4) can
1315       be  used  to restrict the ability to trace a process with ptrace() (and
1316       thus also the ability to use tools such as strace(1) and gdb(1)).   The
1317       goal  of  such  restrictions  is to prevent attack escalation whereby a
1318       compromised process can  ptrace-attach  to  other  sensitive  processes
1319       (e.g.,  a  GPG  agent  or an SSH session) owned by the user in order to
1320       gain additional credentials that may exist in memory  and  thus  expand
1321       the scope of the attack.
1322
1323       More precisely, the Yama LSM limits two types of operations:
1324
1325       *  Any  operation that performs a ptrace access mode PTRACE_MODE_ATTACH
1326          check—for example, ptrace() PTRACE_ATTACH.  (See the "Ptrace  access
1327          mode checking" discussion above.)
1328
1329       *  ptrace() PTRACE_TRACEME.
1330
1331       A  process  that  has  the  CAP_SYS_PTRACE  capability  can  update the
1332       /proc/sys/kernel/yama/ptrace_scope file with one of the following  val‐
1333       ues:
1334
1335       0 ("classic ptrace permissions")
1336              No   additional   restrictions   on   operations   that  perform
1337              PTRACE_MODE_ATTACH checks (beyond those imposed by the commoncap
1338              and other LSMs).
1339
1340              The use of PTRACE_TRACEME is unchanged.
1341
1342       1 ("restricted ptrace") [default value]
1343              When  performing an operation that requires a PTRACE_MODE_ATTACH
1344              check, the calling process must either have  the  CAP_SYS_PTRACE
1345              capability  in  the  user  namespace of the target process or it
1346              must have a predefined relationship with the target process.  By
1347              default,  the predefined relationship is that the target process
1348              must be a descendant of the caller.
1349
1350              A target process can employ the prctl(2)  PR_SET_PTRACER  opera‐
1351              tion  to  declare  an  additional PID that is allowed to perform
1352              PTRACE_MODE_ATTACH operations on the  target.   See  the  kernel
1353              source  file Documentation/admin-guide/LSM/Yama.rst (or Documen‐
1354              tation/security/Yama.txt before Linux 4.13) for further details.
1355
1356              The use of PTRACE_TRACEME is unchanged.
1357
1358       2 ("admin-only attach")
1359              Only processes with the CAP_SYS_PTRACE capability  in  the  user
1360              namespace  of  the target process may perform PTRACE_MODE_ATTACH
1361              operations or trace children that employ PTRACE_TRACEME.
1362
1363       3 ("no attach")
1364              No process may perform PTRACE_MODE_ATTACH  operations  or  trace
1365              children that employ PTRACE_TRACEME.
1366
1367              Once  this  value  has  been  written  to the file, it cannot be
1368              changed.
1369
1370       With respect to values 1 and 2, note that creating a new user namespace
1371       effectively  removes the protection offered by Yama.  This is because a
1372       process in the parent user namespace whose effective  UID  matches  the
1373       UID of the creator of a child namespace has all capabilities (including
1374       CAP_SYS_PTRACE) when performing operations within the child user names‐
1375       pace  (and  further-removed  descendants  of  that  namespace).  Conse‐
1376       quently, when a process tries to use user namespaces to sandbox itself,
1377       it inadvertently weakens the protections offered by the Yama LSM.
1378
1379   C library/kernel differences
1380       At  the  system  call  level, the PTRACE_PEEKTEXT, PTRACE_PEEKDATA, and
1381       PTRACE_PEEKUSER requests have a different API: they store the result at
1382       the  address  specified  by the data parameter, and the return value is
1383       the error flag.  The glibc wrapper function provides the API  given  in
1384       DESCRIPTION  above,  with  the  result  being returned via the function
1385       return value.
1386

BUGS

1388       On hosts with 2.6 kernel headers, PTRACE_SETOPTIONS is declared with  a
1389       different  value than the one for 2.4.  This leads to applications com‐
1390       piled with 2.6 kernel headers failing when run on  2.4  kernels.   This
1391       can  be  worked around by redefining PTRACE_SETOPTIONS to PTRACE_OLDSE‐
1392       TOPTIONS, if that is defined.
1393
1394       Group-stop notifications are sent to the tracer, but not to  real  par‐
1395       ent.  Last confirmed on 2.6.38.6.
1396
1397       If  a  thread  group  leader is traced and exits by calling _exit(2), a
1398       PTRACE_EVENT_EXIT stop will happen for it (if requested), but the  sub‐
1399       sequent  WIFEXITED  notification  will not be delivered until all other
1400       threads exit.  As explained  above,  if  one  of  other  threads  calls
1401       execve(2), the death of the thread group leader will never be reported.
1402       If the execed thread is not traced by  this  tracer,  the  tracer  will
1403       never  know  that  execve(2)  happened.   One possible workaround is to
1404       PTRACE_DETACH the thread group leader instead of restarting it in  this
1405       case.  Last confirmed on 2.6.38.6.
1406
1407       A SIGKILL signal may still cause a PTRACE_EVENT_EXIT stop before actual
1408       signal death.  This may be changed in the future; SIGKILL is  meant  to
1409       always  immediately  kill  tasks  even under ptrace.  Last confirmed on
1410       Linux 3.13.
1411
1412       Some system calls return with EINTR if a signal was sent to  a  tracee,
1413       but delivery was suppressed by the tracer.  (This is very typical oper‐
1414       ation: it is usually done by debuggers on every attach, in order to not
1415       introduce  a  bogus  SIGSTOP).  As of Linux 3.2.9, the following system
1416       calls are affected (this list is likely incomplete): epoll_wait(2), and
1417       read(2)  from an inotify(7) file descriptor.  The usual symptom of this
1418       bug is that when you attach to a quiescent process with the command
1419
1420           strace -p <process-ID>
1421
1422       then, instead of the usual and expected one-line output such as
1423
1424           restart_syscall(<... resuming interrupted call ...>_
1425
1426       or
1427
1428           select(6, [5], NULL, [5], NULL_
1429
1430       ('_' denotes the cursor position), you observe more than one line.  For
1431       example:
1432
1433               clock_gettime(CLOCK_MONOTONIC, {15370, 690928118}) = 0
1434               epoll_wait(4,_
1435
1436       What   is  not  visible  here  is  that  the  process  was  blocked  in
1437       epoll_wait(2) before strace(1) has attached to  it.   Attaching  caused
1438       epoll_wait(2)  to  return  to user space with the error EINTR.  In this
1439       particular case, the program reacted to EINTR by checking  the  current
1440       time,  and  then executing epoll_wait(2) again.  (Programs which do not
1441       expect such "stray" EINTR errors may behave in an unintended  way  upon
1442       an strace(1) attach.)
1443

SEE ALSO

1445       gdb(1),  ltrace(1), strace(1), clone(2), execve(2), fork(2), gettid(2),
1446       prctl(2), seccomp(2), sigaction(2),  tgkill(2),  vfork(2),  waitpid(2),
1447       exec(3), capabilities(7), signal(7)
1448

COLOPHON

1450       This  page  is  part of release 4.16 of the Linux man-pages project.  A
1451       description of the project, information about reporting bugs,  and  the
1452       latest     version     of     this    page,    can    be    found    at
1453       https://www.kernel.org/doc/man-pages/.
1454
1455
1456
1457Linux                             2018-04-30                         PTRACE(2)
Impressum