1signal(7)              Miscellaneous Information Manual              signal(7)
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NAME

6       signal - overview of signals
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DESCRIPTION

9       Linux  supports both POSIX reliable signals (hereinafter "standard sig‐
10       nals") and POSIX real-time signals.
11
12   Signal dispositions
13       Each signal has a current disposition, which determines how the process
14       behaves when it is delivered the signal.
15
16       The  entries  in the "Action" column of the table below specify the de‐
17       fault disposition for each signal, as follows:
18
19       Term   Default action is to terminate the process.
20
21       Ign    Default action is to ignore the signal.
22
23       Core   Default action is to terminate the process and  dump  core  (see
24              core(5)).
25
26       Stop   Default action is to stop the process.
27
28       Cont   Default  action  is  to  continue the process if it is currently
29              stopped.
30
31       A process can change the disposition of a signal using sigaction(2)  or
32       signal(2).   (The  latter  is  less portable when establishing a signal
33       handler; see signal(2) for  details.)   Using  these  system  calls,  a
34       process  can  elect one of the following behaviors to occur on delivery
35       of the signal: perform the default action; ignore the signal; or  catch
36       the signal with a signal handler, a programmer-defined function that is
37       automatically invoked when the signal is delivered.
38
39       By default, a signal handler is invoked on the  normal  process  stack.
40       It  is  possible  to  arrange that the signal handler uses an alternate
41       stack; see sigaltstack(2) for a discussion of how to do this  and  when
42       it might be useful.
43
44       The  signal  disposition is a per-process attribute: in a multithreaded
45       application, the disposition of a particular signal is the same for all
46       threads.
47
48       A child created via fork(2) inherits a copy of its parent's signal dis‐
49       positions.  During an execve(2), the dispositions  of  handled  signals
50       are  reset to the default; the dispositions of ignored signals are left
51       unchanged.
52
53   Sending a signal
54       The following system calls and library functions allow  the  caller  to
55       send a signal:
56
57       raise(3)
58              Sends a signal to the calling thread.
59
60       kill(2)
61              Sends a signal to a specified process, to all members of a spec‐
62              ified process group, or to all processes on the system.
63
64       pidfd_send_signal(2)
65              Sends a signal to a process identified by a PID file descriptor.
66
67       killpg(3)
68              Sends a signal to all of the  members  of  a  specified  process
69              group.
70
71       pthread_kill(3)
72              Sends  a  signal to a specified POSIX thread in the same process
73              as the caller.
74
75       tgkill(2)
76              Sends a signal to a specified thread within a specific  process.
77              (This is the system call used to implement pthread_kill(3).)
78
79       sigqueue(3)
80              Sends  a  real-time signal with accompanying data to a specified
81              process.
82
83   Waiting for a signal to be caught
84       The following system calls suspend execution of the calling thread  un‐
85       til a signal is caught (or an unhandled signal terminates the process):
86
87       pause(2)
88              Suspends execution until any signal is caught.
89
90       sigsuspend(2)
91              Temporarily changes the signal mask (see below) and suspends ex‐
92              ecution until one of the unmasked signals is caught.
93
94   Synchronously accepting a signal
95       Rather than asynchronously catching a signal via a signal  handler,  it
96       is  possible to synchronously accept the signal, that is, to block exe‐
97       cution until the signal is delivered, at which point the kernel returns
98       information about the signal to the caller.  There are two general ways
99       to do this:
100
101sigwaitinfo(2), sigtimedwait(2), and  sigwait(3)  suspend  execution
102          until  one  of the signals in a specified set is delivered.  Each of
103          these calls returns information about the delivered signal.
104
105signalfd(2) returns a file descriptor that can be used to  read  in‐
106          formation  about  signals  that  are  delivered to the caller.  Each
107          read(2) from this file descriptor blocks until one of the signals in
108          the  set  specified  in  the  signalfd(2)  call  is delivered to the
109          caller.  The buffer returned by read(2)  contains  a  structure  de‐
110          scribing the signal.
111
112   Signal mask and pending signals
113       A  signal may be blocked, which means that it will not be delivered un‐
114       til it is later unblocked.  Between the time when it is  generated  and
115       when it is delivered a signal is said to be pending.
116
117       Each  thread  in  a process has an independent signal mask, which indi‐
118       cates the set of signals that the  thread  is  currently  blocking.   A
119       thread  can  manipulate its signal mask using pthread_sigmask(3).  In a
120       traditional single-threaded application, sigprocmask(2) can be used  to
121       manipulate the signal mask.
122
123       A  child  created  via  fork(2)  inherits a copy of its parent's signal
124       mask; the signal mask is preserved across execve(2).
125
126       A signal may be process-directed  or  thread-directed.   A  process-di‐
127       rected  signal  is  one  that is targeted at (and thus pending for) the
128       process as a whole.  A signal may be process-directed  because  it  was
129       generated by the kernel for reasons other than a hardware exception, or
130       because it was sent using kill(2) or  sigqueue(3).   A  thread-directed
131       signal  is  one that is targeted at a specific thread.  A signal may be
132       thread-directed because it was generated as a consequence of  executing
133       a  specific  machine-language instruction that triggered a hardware ex‐
134       ception (e.g., SIGSEGV for an invalid memory access, or  SIGFPE  for  a
135       math  error), or because it was targeted at a specific thread using in‐
136       terfaces such as tgkill(2) or pthread_kill(3).
137
138       A process-directed signal may be delivered to any one  of  the  threads
139       that  does  not currently have the signal blocked.  If more than one of
140       the threads has the signal unblocked, then the kernel chooses an  arbi‐
141       trary thread to which to deliver the signal.
142
143       A  thread  can  obtain the set of signals that it currently has pending
144       using sigpending(2).  This set will consist of the union of the set  of
145       pending process-directed signals and the set of signals pending for the
146       calling thread.
147
148       A child created via fork(2) initially has an empty pending signal  set;
149       the pending signal set is preserved across an execve(2).
150
151   Execution of signal handlers
152       Whenever  there is a transition from kernel-mode to user-mode execution
153       (e.g., on return from a system call or scheduling of a thread onto  the
154       CPU), the kernel checks whether there is a pending unblocked signal for
155       which the process has established a signal handler.  If there is such a
156       pending signal, the following steps occur:
157
158       (1)  The  kernel performs the necessary preparatory steps for execution
159            of the signal handler:
160
161            (1.1)  The signal is removed from the set of pending signals.
162
163            (1.2)  If the signal handler was installed by  a  call  to  sigac‐
164                   tion(2)  that  specified the SA_ONSTACK flag and the thread
165                   has  defined  an  alternate  signal  stack  (using  sigalt‐
166                   stack(2)), then that stack is installed.
167
168            (1.3)  Various  pieces  of signal-related context are saved into a
169                   special frame that is created on the stack.  The saved  in‐
170                   formation includes:
171
172                   •  the  program  counter register (i.e., the address of the
173                      next instruction in the main program that should be exe‐
174                      cuted when the signal handler returns);
175
176                   •  architecture-specific register state required for resum‐
177                      ing the interrupted program;
178
179                   •  the thread's current signal mask;
180
181                   •  the thread's alternate signal stack settings.
182
183                   (If the signal handler was installed using the sigaction(2)
184                   SA_SIGINFO  flag,  then the above information is accessible
185                   via the ucontext_t object that is pointed to by  the  third
186                   argument of the signal handler.)
187
188            (1.4)  Any  signals specified in act->sa_mask when registering the
189                   handler with sigprocmask(2) are added to the thread's  sig‐
190                   nal  mask.  The signal being delivered is also added to the
191                   signal mask, unless SA_NODEFER was specified when register‐
192                   ing  the handler.  These signals are thus blocked while the
193                   handler executes.
194
195       (2)  The kernel constructs a frame for the signal handler on the stack.
196            The kernel sets the program counter for the thread to point to the
197            first instruction of the signal handler function,  and  configures
198            the  return address for that function to point to a piece of user-
199            space code known as the signal  trampoline  (described  in  sigre‐
200            turn(2)).
201
202       (3)  The kernel passes control back to user-space, where execution com‐
203            mences at the start of the signal handler function.
204
205       (4)  When the signal handler returns,  control  passes  to  the  signal
206            trampoline code.
207
208       (5)  The  signal trampoline calls sigreturn(2), a system call that uses
209            the information in the stack frame created in step  1  to  restore
210            the thread to its state before the signal handler was called.  The
211            thread's signal mask and alternate signal stack settings  are  re‐
212            stored  as part of this procedure.  Upon completion of the call to
213            sigreturn(2), the kernel transfers control back to user space, and
214            the  thread recommences execution at the point where it was inter‐
215            rupted by the signal handler.
216
217       Note that if the signal handler  does  not  return  (e.g.,  control  is
218       transferred out of the handler using siglongjmp(3), or the handler exe‐
219       cutes a new program with execve(2)), then the final step  is  not  per‐
220       formed.   In  particular,  in such scenarios it is the programmer's re‐
221       sponsibility to restore the state of the signal  mask  (using  sigproc‐
222       mask(2)),  if it is desired to unblock the signals that were blocked on
223       entry to the signal handler.  (Note that siglongjmp(3) may or  may  not
224       restore the signal mask, depending on the savesigs value that was spec‐
225       ified in the corresponding call to sigsetjmp(3).)
226
227       From the kernel's point of view, execution of the signal  handler  code
228       is  exactly  the  same  as  the execution of any other user-space code.
229       That is to say, the kernel does not record any special  state  informa‐
230       tion  indicating that the thread is currently executing inside a signal
231       handler.  All necessary state information is maintained  in  user-space
232       registers  and  the user-space stack.  The depth to which nested signal
233       handlers may be invoked is thus limited only by  the  user-space  stack
234       (and sensible software design!).
235
236   Standard signals
237       Linux supports the standard signals listed below.  The second column of
238       the table indicates which  standard  (if  any)  specified  the  signal:
239       "P1990"  indicates  that  the  signal  is  described  in  the  original
240       POSIX.1-1990 standard; "P2001" indicates that the signal was  added  in
241       SUSv2 and POSIX.1-2001.
242
243       Signal      Standard   Action   Comment
244       ────────────────────────────────────────────────────────────────────────
245       SIGABRT      P1990      Core    Abort signal from abort(3)
246       SIGALRM      P1990      Term    Timer signal from alarm(2)
247       SIGBUS       P2001      Core    Bus error (bad memory access)
248       SIGCHLD      P1990      Ign     Child stopped or terminated
249       SIGCLD         -        Ign     A synonym for SIGCHLD
250       SIGCONT      P1990      Cont    Continue if stopped
251       SIGEMT         -        Term    Emulator trap
252       SIGFPE       P1990      Core    Floating-point exception
253       SIGHUP       P1990      Term    Hangup detected on controlling terminal
254                                       or death of controlling process
255       SIGILL       P1990      Core    Illegal Instruction
256       SIGINFO        -                A synonym for SIGPWR
257       SIGINT       P1990      Term    Interrupt from keyboard
258       SIGIO          -        Term    I/O now possible (4.2BSD)
259       SIGIOT         -        Core    IOT trap. A synonym for SIGABRT
260       SIGKILL      P1990      Term    Kill signal
261       SIGLOST        -        Term    File lock lost (unused)
262       SIGPIPE      P1990      Term    Broken pipe: write to pipe with no
263                                       readers; see pipe(7)
264
265       SIGPOLL      P2001      Term    Pollable event (Sys V);
266                                       synonym for SIGIO
267       SIGPROF      P2001      Term    Profiling timer expired
268       SIGPWR         -        Term    Power failure (System V)
269       SIGQUIT      P1990      Core    Quit from keyboard
270       SIGSEGV      P1990      Core    Invalid memory reference
271       SIGSTKFLT      -        Term    Stack fault on coprocessor (unused)
272       SIGSTOP      P1990      Stop    Stop process
273       SIGTSTP      P1990      Stop    Stop typed at terminal
274       SIGSYS       P2001      Core    Bad system call (SVr4);
275                                       see also seccomp(2)
276       SIGTERM      P1990      Term    Termination signal
277       SIGTRAP      P2001      Core    Trace/breakpoint trap
278       SIGTTIN      P1990      Stop    Terminal input for background process
279       SIGTTOU      P1990      Stop    Terminal output for background process
280       SIGUNUSED      -        Core    Synonymous with SIGSYS
281       SIGURG       P2001      Ign     Urgent condition on socket (4.2BSD)
282       SIGUSR1      P1990      Term    User-defined signal 1
283       SIGUSR2      P1990      Term    User-defined signal 2
284       SIGVTALRM    P2001      Term    Virtual alarm clock (4.2BSD)
285       SIGXCPU      P2001      Core    CPU time limit exceeded (4.2BSD);
286                                       see setrlimit(2)
287       SIGXFSZ      P2001      Core    File size limit exceeded (4.2BSD);
288                                       see setrlimit(2)
289       SIGWINCH       -        Ign     Window resize signal (4.3BSD, Sun)
290
291       The signals SIGKILL and SIGSTOP cannot be caught, blocked, or ignored.
292
293       Up  to  and including Linux 2.2, the default behavior for SIGSYS, SIGX‐
294       CPU, SIGXFSZ, and (on architectures other than SPARC and  MIPS)  SIGBUS
295       was  to  terminate  the  process (without a core dump).  (On some other
296       UNIX systems the default action for SIGXCPU and SIGXFSZ is to terminate
297       the   process  without  a  core  dump.)   Linux  2.4  conforms  to  the
298       POSIX.1-2001 requirements for these signals,  terminating  the  process
299       with a core dump.
300
301       SIGEMT  is  not  specified in POSIX.1-2001, but nevertheless appears on
302       most other UNIX systems, where its default action is typically to  ter‐
303       minate the process with a core dump.
304
305       SIGPWR (which is not specified in POSIX.1-2001) is typically ignored by
306       default on those other UNIX systems where it appears.
307
308       SIGIO (which is not specified in POSIX.1-2001) is ignored by default on
309       several other UNIX systems.
310
311   Queueing and delivery semantics for standard signals
312       If  multiple  standard  signals are pending for a process, the order in
313       which the signals are delivered is unspecified.
314
315       Standard signals do not queue.  If multiple  instances  of  a  standard
316       signal  are  generated  while that signal is blocked, then only one in‐
317       stance of the signal is marked as pending (and the signal will  be  de‐
318       livered  just once when it is unblocked).  In the case where a standard
319       signal is already pending, the siginfo_t structure  (see  sigaction(2))
320       associated with that signal is not overwritten on arrival of subsequent
321       instances of the same signal.  Thus, the process will receive  the  in‐
322       formation associated with the first instance of the signal.
323
324   Signal numbering for standard signals
325       The  numeric  value  for  each  signal is given in the table below.  As
326       shown in the table, many signals have different numeric values on  dif‐
327       ferent  architectures.  The first numeric value in each table row shows
328       the signal number on x86, ARM, and most other architectures; the second
329       value  is  for  Alpha and SPARC; the third is for MIPS; and the last is
330       for PARISC.  A dash (-) denotes that a signal is absent on  the  corre‐
331       sponding architecture.
332
333       Signal        x86/ARM     Alpha/   MIPS   PARISC   Notes
334                   most others   SPARC
335       ─────────────────────────────────────────────────────────────────
336       SIGHUP           1           1       1       1
337       SIGINT           2           2       2       2
338       SIGQUIT          3           3       3       3
339       SIGILL           4           4       4       4
340       SIGTRAP          5           5       5       5
341       SIGABRT          6           6       6       6
342       SIGIOT           6           6       6       6
343       SIGBUS           7          10      10      10
344       SIGEMT           -           7       7      -
345       SIGFPE           8           8       8       8
346       SIGKILL          9           9       9       9
347       SIGUSR1         10          30      16      16
348       SIGSEGV         11          11      11      11
349       SIGUSR2         12          31      17      17
350       SIGPIPE         13          13      13      13
351       SIGALRM         14          14      14      14
352       SIGTERM         15          15      15      15
353       SIGSTKFLT       16          -       -        7
354       SIGCHLD         17          20      18      18
355       SIGCLD           -          -       18      -
356       SIGCONT         18          19      25      26
357       SIGSTOP         19          17      23      24
358       SIGTSTP         20          18      24      25
359       SIGTTIN         21          21      26      27
360       SIGTTOU         22          22      27      28
361       SIGURG          23          16      21      29
362       SIGXCPU         24          24      30      12
363       SIGXFSZ         25          25      31      30
364       SIGVTALRM       26          26      28      20
365       SIGPROF         27          27      29      21
366       SIGWINCH        28          28      20      23
367       SIGIO           29          23      22      22
368       SIGPOLL                                            Same as SIGIO
369       SIGPWR          30         29/-     19      19
370       SIGINFO          -         29/-     -       -
371       SIGLOST          -         -/29     -       -
372       SIGSYS          31          12      12      31
373       SIGUNUSED       31          -       -       31
374
375       Note the following:
376
377       •  Where  defined,  SIGUNUSED  is  synonymous with SIGSYS.  Since glibc
378          2.26, SIGUNUSED is no longer defined on any architecture.
379
380       •  Signal 29 is SIGINFO/SIGPWR (synonyms for the same value)  on  Alpha
381          but SIGLOST on SPARC.
382
383   Real-time signals
384       Starting with Linux 2.2, Linux supports real-time signals as originally
385       defined in the POSIX.1b  real-time  extensions  (and  now  included  in
386       POSIX.1-2001).   The range of supported real-time signals is defined by
387       the macros SIGRTMIN and SIGRTMAX.  POSIX.1-2001 requires that an imple‐
388       mentation support at least _POSIX_RTSIG_MAX (8) real-time signals.
389
390       The  Linux  kernel  supports a range of 33 different real-time signals,
391       numbered 32 to 64.  However, the glibc POSIX threads implementation in‐
392       ternally uses two (for NPTL) or three (for LinuxThreads) real-time sig‐
393       nals (see pthreads(7)), and adjusts the value of SIGRTMIN suitably  (to
394       34 or 35).  Because the range of available real-time signals varies ac‐
395       cording to the glibc threading implementation (and this  variation  can
396       occur at run time according to the available kernel and glibc), and in‐
397       deed the range of real-time signals varies across  UNIX  systems,  pro‐
398       grams should never refer to real-time signals using hard-coded numbers,
399       but instead should always refer to real-time signals using the notation
400       SIGRTMIN+n, and include suitable (run-time) checks that SIGRTMIN+n does
401       not exceed SIGRTMAX.
402
403       Unlike standard signals, real-time signals have no predefined meanings:
404       the entire set of real-time signals can be used for application-defined
405       purposes.
406
407       The default action for an unhandled real-time signal  is  to  terminate
408       the receiving process.
409
410       Real-time signals are distinguished by the following:
411
412       •  Multiple instances of real-time signals can be queued.  By contrast,
413          if multiple instances of a standard signal are delivered while  that
414          signal is currently blocked, then only one instance is queued.
415
416       •  If  the signal is sent using sigqueue(3), an accompanying value (ei‐
417          ther an integer or a pointer) can be sent with the signal.   If  the
418          receiving  process  establishes  a handler for this signal using the
419          SA_SIGINFO flag to sigaction(2), then it can obtain  this  data  via
420          the  si_value  field of the siginfo_t structure passed as the second
421          argument to the handler.  Furthermore, the si_pid and si_uid  fields
422          of  this structure can be used to obtain the PID and real user ID of
423          the process sending the signal.
424
425       •  Real-time signals are delivered in  a  guaranteed  order.   Multiple
426          real-time  signals  of the same type are delivered in the order they
427          were sent.  If different real-time signals are sent  to  a  process,
428          they are delivered starting with the lowest-numbered signal.  (I.e.,
429          low-numbered signals have highest priority.)  By contrast, if multi‐
430          ple  standard  signals are pending for a process, the order in which
431          they are delivered is unspecified.
432
433       If both standard and real-time signals are pending for a process, POSIX
434       leaves it unspecified which is delivered first.  Linux, like many other
435       implementations, gives priority to standard signals in this case.
436
437       According  to  POSIX,  an  implementation  should   permit   at   least
438       _POSIX_SIGQUEUE_MAX  (32)  real-time signals to be queued to a process.
439       However, Linux does things differently.   Up  to  and  including  Linux
440       2.6.7,  Linux imposes a system-wide limit on the number of queued real-
441       time signals for all processes.  This limit can  be  viewed  and  (with
442       privilege)  changed via the /proc/sys/kernel/rtsig-max file.  A related
443       file, /proc/sys/kernel/rtsig-nr, can be used to find out how many real-
444       time  signals are currently queued.  In Linux 2.6.8, these /proc inter‐
445       faces were replaced by  the  RLIMIT_SIGPENDING  resource  limit,  which
446       specifies  a  per-user  limit  for queued signals; see setrlimit(2) for
447       further details.
448
449       The addition of real-time signals required the widening of  the  signal
450       set  structure  (sigset_t)  from  32 to 64 bits.  Consequently, various
451       system calls were superseded by new system  calls  that  supported  the
452       larger signal sets.  The old and new system calls are as follows:
453
454       Linux 2.0 and earlier   Linux 2.2 and later
455       sigaction(2)            rt_sigaction(2)
456       sigpending(2)           rt_sigpending(2)
457       sigprocmask(2)          rt_sigprocmask(2)
458       sigreturn(2)            rt_sigreturn(2)
459       sigsuspend(2)           rt_sigsuspend(2)
460       sigtimedwait(2)         rt_sigtimedwait(2)
461
462   Interruption of system calls and library functions by signal handlers
463       If  a signal handler is invoked while a system call or library function
464       call is blocked, then either:
465
466       •  the call is automatically restarted after  the  signal  handler  re‐
467          turns; or
468
469       •  the call fails with the error EINTR.
470
471       Which  of  these  two  behaviors  occurs  depends  on the interface and
472       whether or not the signal handler was established using the  SA_RESTART
473       flag  (see sigaction(2)).  The details vary across UNIX systems; below,
474       the details for Linux.
475
476       If a blocked call to one of the following interfaces is interrupted  by
477       a  signal  handler,  then the call is automatically restarted after the
478       signal handler returns if the SA_RESTART flag was used;  otherwise  the
479       call fails with the error EINTR:
480
481read(2), readv(2), write(2), writev(2), and ioctl(2) calls on "slow"
482          devices.  A "slow" device is one where the I/O call may block for an
483          indefinite  time,  for  example, a terminal, pipe, or socket.  If an
484          I/O call on a slow device has already transferred some data  by  the
485          time  it  is interrupted by a signal handler, then the call will re‐
486          turn a success status (normally, the number of  bytes  transferred).
487          Note that a (local) disk is not a slow device according to this def‐
488          inition; I/O operations on disk devices are not interrupted by  sig‐
489          nals.
490
491open(2), if it can block (e.g., when opening a FIFO; see fifo(7)).
492
493wait(2), wait3(2), wait4(2), waitid(2), and waitpid(2).
494
495       •  Socket  interfaces:  accept(2),  connect(2),  recv(2),  recvfrom(2),
496          recvmmsg(2), recvmsg(2), send(2), sendto(2), and sendmsg(2),  unless
497          a timeout has been set on the socket (see below).
498
499       •  File  locking interfaces: flock(2) and the F_SETLKW and F_OFD_SETLKW
500          operations of fcntl(2)
501
502       •  POSIX message queue interfaces:  mq_receive(3),  mq_timedreceive(3),
503          mq_send(3), and mq_timedsend(3).
504
505futex(2)  FUTEX_WAIT  (since Linux 2.6.22; beforehand, always failed
506          with EINTR).
507
508getrandom(2).
509
510       •  pthread_mutex_lock(3), pthread_cond_wait(3), and related APIs.
511
512futex(2) FUTEX_WAIT_BITSET.
513
514       •  POSIX semaphore interfaces: sem_wait(3) and sem_timedwait(3)  (since
515          Linux 2.6.22; beforehand, always failed with EINTR).
516
517read(2) from an inotify(7) file descriptor (since Linux 3.8; before‐
518          hand, always failed with EINTR).
519
520       The following interfaces are never restarted after being interrupted by
521       a signal handler, regardless of the use of SA_RESTART; they always fail
522       with the error EINTR when interrupted by a signal handler:
523
524       •  "Input" socket interfaces, when a timeout (SO_RCVTIMEO) has been set
525          on  the socket using setsockopt(2): accept(2), recv(2), recvfrom(2),
526          recvmmsg(2) (also with a non-NULL timeout argument), and recvmsg(2).
527
528       •  "Output" socket interfaces, when a timeout  (SO_RCVTIMEO)  has  been
529          set   on   the  socket  using  setsockopt(2):  connect(2),  send(2),
530          sendto(2), and sendmsg(2).
531
532       •  Interfaces used to wait for signals: pause(2),  sigsuspend(2),  sig‐
533          timedwait(2), and sigwaitinfo(2).
534
535       •  File     descriptor    multiplexing    interfaces:    epoll_wait(2),
536          epoll_pwait(2), poll(2), ppoll(2), select(2), and pselect(2).
537
538       •  System V IPC interfaces: msgrcv(2), msgsnd(2),  semop(2),  and  sem‐
539          timedop(2).
540
541       •  Sleep interfaces: clock_nanosleep(2), nanosleep(2), and usleep(3).
542
543io_getevents(2).
544
545       The  sleep(3) function is also never restarted if interrupted by a han‐
546       dler, but gives a success return: the number of  seconds  remaining  to
547       sleep.
548
549       In  certain  circumstances, the seccomp(2) user-space notification fea‐
550       ture can lead to restarting of system calls that would otherwise  never
551       be restarted by SA_RESTART; for details, see seccomp_unotify(2).
552
553   Interruption of system calls and library functions by stop signals
554       On  Linux, even in the absence of signal handlers, certain blocking in‐
555       terfaces can fail with the error EINTR after the process is stopped  by
556       one of the stop signals and then resumed via SIGCONT.  This behavior is
557       not sanctioned by POSIX.1, and doesn't occur on other systems.
558
559       The Linux interfaces that display this behavior are:
560
561       •  "Input" socket interfaces, when a timeout (SO_RCVTIMEO) has been set
562          on  the socket using setsockopt(2): accept(2), recv(2), recvfrom(2),
563          recvmmsg(2) (also with a non-NULL timeout argument), and recvmsg(2).
564
565       •  "Output" socket interfaces, when a timeout  (SO_RCVTIMEO)  has  been
566          set   on   the  socket  using  setsockopt(2):  connect(2),  send(2),
567          sendto(2), and sendmsg(2), if a send timeout (SO_SNDTIMEO) has  been
568          set.
569
570epoll_wait(2), epoll_pwait(2).
571
572semop(2), semtimedop(2).
573
574sigtimedwait(2), sigwaitinfo(2).
575
576       •  Linux 3.7 and earlier: read(2) from an inotify(7) file descriptor
577
578       •  Linux  2.6.21  and  earlier:  futex(2) FUTEX_WAIT, sem_timedwait(3),
579          sem_wait(3).
580
581       •  Linux 2.6.8 and earlier: msgrcv(2), msgsnd(2).
582
583       •  Linux 2.4 and earlier: nanosleep(2).
584

STANDARDS

586       POSIX.1, except as noted.
587

NOTES

589       For a discussion of async-signal-safe functions, see signal-safety(7).
590
591       The /proc/pid/task/tid/status file contains various  fields  that  show
592       the  signals  that a thread is blocking (SigBlk), catching (SigCgt), or
593       ignoring (SigIgn).  (The set of signals that are caught or ignored will
594       be  the  same  across all threads in a process.)  Other fields show the
595       set of pending signals that are directed to the thread (SigPnd) as well
596       as  the  set  of  pending signals that are directed to the process as a
597       whole (ShdPnd).  The corresponding fields in /proc/pid/status show  the
598       information for the main thread.  See proc(5) for further details.
599

BUGS

601       There are six signals that can be delivered as a consequence of a hard‐
602       ware exception: SIGBUS, SIGEMT, SIGFPE, SIGILL, SIGSEGV,  and  SIGTRAP.
603       Which  of these signals is delivered, for any given hardware exception,
604       is not documented and does not always make sense.
605
606       For example, an invalid memory access that causes delivery  of  SIGSEGV
607       on  one CPU architecture may cause delivery of SIGBUS on another archi‐
608       tecture, or vice versa.
609
610       For another example, using the x86 int instruction with a forbidden ar‐
611       gument  (any  number  other  than 3 or 128) causes delivery of SIGSEGV,
612       even though SIGILL would make more sense, because of how  the  CPU  re‐
613       ports the forbidden operation to the kernel.
614

SEE ALSO

616       kill(1),   clone(2),   getrlimit(2),   kill(2),   pidfd_send_signal(2),
617       restart_syscall(2),  rt_sigqueueinfo(2),  setitimer(2),   setrlimit(2),
618       sgetmask(2), sigaction(2), sigaltstack(2), signal(2), signalfd(2), sig‐
619       pending(2),  sigprocmask(2),  sigreturn(2),   sigsuspend(2),   sigwait‐
620       info(2),     abort(3),     bsd_signal(3),     killpg(3),    longjmp(3),
621       pthread_sigqueue(3), raise(3),  sigqueue(3),  sigset(3),  sigsetops(3),
622       sigvec(3),  sigwait(3),  strsignal(3),  swapcontext(3), sysv_signal(3),
623       core(5), proc(5), nptl(7), pthreads(7), sigevent(7)
624
625
626
627Linux man-pages 6.05              2023-04-03                         signal(7)
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