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NAME | DESCRIPTION | CONFORMING TO | NOTES | BUGS | SEE ALSO | COLOPHON |
SIGNAL(7) Linux Programmer's Manual SIGNAL(7)
signal - overview of signals
Linux supports both POSIX reliable signals (hereinafter "standard
signals") and POSIX real-time signals.
Signal dispositions
Each signal has a current disposition, which determines how the
process behaves when it is delivered the signal.
The entries in the "Action" column of the table below specify the
default disposition for each signal, as follows:
Term Default action is to terminate the process.
Ign Default action is to ignore the signal.
Core Default action is to terminate the process and dump core (see
core(5)).
Stop Default action is to stop the process.
Cont Default action is to continue the process if it is currently
stopped.
A process can change the disposition of a signal using sigaction(2)
or signal(2). (The latter is less portable when establishing a
signal handler; see signal(2) for details.) Using these system
calls, a process can elect one of the following behaviors to occur on
delivery of the signal: perform the default action; ignore the
signal; or catch the signal with a signal handler, a programmer-
defined function that is automatically invoked when the signal is
delivered.
By default, a signal handler is invoked on the normal process stack.
It is possible to arrange that the signal handler uses an alternate
stack; see sigaltstack(2) for a discussion of how to do this and when
it might be useful.
The signal disposition is a per-process attribute: in a multithreaded
application, the disposition of a particular signal is the same for
all threads.
A child created via fork(2) inherits a copy of its parent's signal
dispositions. During an execve(2), the dispositions of handled
signals are reset to the default; the dispositions of ignored signals
are left unchanged.
Sending a signal
The following system calls and library functions allow the caller to
send a signal:
raise(3) Sends a signal to the calling thread.
kill(2) Sends a signal to a specified process, to all members
of a specified process group, or to all processes on
the system.
killpg(3) Sends a signal to all of the members of a specified
process group.
pthread_kill(3) Sends a signal to a specified POSIX thread in the
same process as the caller.
tgkill(2) Sends a signal to a specified thread within a
specific process. (This is the system call used to
implement pthread_kill(3).)
sigqueue(3) Sends a real-time signal with accompanying data to a
specified process.
Waiting for a signal to be caught
The following system calls suspend execution of the calling thread
until a signal is caught (or an unhandled signal terminates the
process):
pause(2) Suspends execution until any signal is caught.
sigsuspend(2) Temporarily changes the signal mask (see below) and
suspends execution until one of the unmasked signals
is caught.
Synchronously accepting a signal
Rather than asynchronously catching a signal via a signal handler, it
is possible to synchronously accept the signal, that is, to block
execution until the signal is delivered, at which point the kernel
returns information about the signal to the caller. There are two
general ways to do this:
* sigwaitinfo(2), sigtimedwait(2), and sigwait(3) suspend execution
until one of the signals in a specified set is delivered. Each of
these calls returns information about the delivered signal.
* signalfd(2) returns a file descriptor that can be used to read
information about signals that are delivered to the caller. Each
read(2) from this file descriptor blocks until one of the signals
in the set specified in the signalfd(2) call is delivered to the
caller. The buffer returned by read(2) contains a structure
describing the signal.
Signal mask and pending signals
A signal may be blocked, which means that it will not be delivered
until it is later unblocked. Between the time when it is generated
and when it is delivered a signal is said to be pending.
Each thread in a process has an independent signal mask, which
indicates the set of signals that the thread is currently blocking.
A thread can manipulate its signal mask using pthread_sigmask(3). In
a traditional single-threaded application, sigprocmask(2) can be used
to manipulate the signal mask.
A child created via fork(2) inherits a copy of its parent's signal
mask; the signal mask is preserved across execve(2).
A signal may be process-directed or thread-directed. A process-
directed signal is one that is targeted at (and thus pending for) the
process as a whole. A signal may be process-directed because it was
generated by the kernel for reasons other than a hardware exception,
or because it was sent using kill(2) or sigqueue(3). A thread-
directed signal is one that is targeted at a specific thread. A
signal may be thread-directed because it was generated as a
consequence of executing a specific machine-language instruction that
triggered a hardware exception (e.g., SIGSEGV for an invalid memory
access, or SIGFPE for a math error), or because it was targeted at a
specific thread using interfaces such as tgkill(2) or
pthread_kill(3).
A process-directed signal may be delivered to any one of the threads
that does not currently have the signal blocked. If more than one of
the threads has the signal unblocked, then the kernel chooses an
arbitrary thread to which to deliver the signal.
A thread can obtain the set of signals that it currently has pending
using sigpending(2). This set will consist of the union of the set
of pending process-directed signals and the set of signals pending
for the calling thread.
A child created via fork(2) initially has an empty pending signal
set; the pending signal set is preserved across an execve(2).
Standard signals
Linux supports the standard signals listed below. The second column
of the table indicates which standard (if any) specified the signal:
"P1990" indicates that the signal is described in the original
POSIX.1-1990 standard; "P2001" indicates that the signal was added in
SUSv2 and POSIX.1-2001.
Signal Standard Action Comment
────────────────────────────────────────────────────────────────────────
SIGABRT P1990 Core Abort signal from abort(3)
SIGALRM P1990 Term Timer signal from alarm(2)
SIGBUS P2001 Core Bus error (bad memory access)
SIGCHLD P1990 Ign Child stopped or terminated
SIGCLD - Ign A synonym for SIGCHLD
SIGCONT P1990 Cont Continue if stopped
SIGEMT - Term Emulator trap
SIGFPE P1990 Core Floating-point exception
SIGHUP P1990 Term Hangup detected on controlling terminal
or death of controlling process
SIGILL P1990 Core Illegal Instruction
SIGINFO - A synonym for SIGPWR
SIGINT P1990 Term Interrupt from keyboard
SIGIO - Term I/O now possible (4.2BSD)
SIGIOT - Core IOT trap. A synonym for SIGABRT
SIGKILL P1990 Term Kill signal
SIGLOST - Term File lock lost (unused)
SIGPIPE P1990 Term Broken pipe: write to pipe with no
readers; see pipe(7)
SIGPOLL P2001 Term Pollable event (Sys V);
synonym for SIGIO
SIGPROF P2001 Term Profiling timer expired
SIGPWR - Term Power failure (System V)
SIGQUIT P1990 Core Quit from keyboard
SIGSEGV P1990 Core Invalid memory reference
SIGSTKFLT - Term Stack fault on coprocessor (unused)
SIGSTOP P1990 Stop Stop process
SIGTSTP P1990 Stop Stop typed at terminal
SIGSYS P2001 Core Bad system call (SVr4);
see also seccomp(2)
SIGTERM P1990 Term Termination signal
SIGTRAP P2001 Core Trace/breakpoint trap
SIGTTIN P1990 Stop Terminal input for background process
SIGTTOU P1990 Stop Terminal output for background process
SIGUNUSED - Core Synonymous with SIGSYS
SIGURG P2001 Ign Urgent condition on socket (4.2BSD)
SIGUSR1 P1990 Term User-defined signal 1
SIGUSR2 P1990 Term User-defined signal 2
SIGVTALRM P2001 Term Virtual alarm clock (4.2BSD)
SIGXCPU P2001 Core CPU time limit exceeded (4.2BSD);
see setrlimit(2)
SIGXFSZ P2001 Core File size limit exceeded (4.2BSD);
see setrlimit(2)
SIGWINCH - Ign Window resize signal (4.3BSD, Sun)
The signals SIGKILL and SIGSTOP cannot be caught, blocked, or
ignored.
Up to and including Linux 2.2, the default behavior for SIGSYS,
SIGXCPU, SIGXFSZ, and (on architectures other than SPARC and MIPS)
SIGBUS was to terminate the process (without a core dump). (On some
other UNIX systems the default action for SIGXCPU and SIGXFSZ is to
terminate the process without a core dump.) Linux 2.4 conforms to
the POSIX.1-2001 requirements for these signals, terminating the
process with a core dump.
SIGEMT is not specified in POSIX.1-2001, but nevertheless appears on
most other UNIX systems, where its default action is typically to
terminate the process with a core dump.
SIGPWR (which is not specified in POSIX.1-2001) is typically ignored
by default on those other UNIX systems where it appears.
SIGIO (which is not specified in POSIX.1-2001) is ignored by default
on several other UNIX systems.
Queueing and delivery semantics for standard signals
If multiple standard signals are pending for a process, the order in
which the signals are delivered is unspecified.
Standard signals do not queue. If multiple instances of a standard
signal are generated while that signal is blocked, then only one
instance of the signal is marked as pending (and the signal will be
delivered just once when it is unblocked). In the case where a
standard signal is already pending, the siginfo_t structure (see
sigaction(2)) associated with that signal is not overwritten on
arrival of subsequent instances of the same signal. Thus, the
process will receive the information associated with the first
instance of the signal.
Signal numbering for standard signals
The numeric value for each signal is given in the table below. As
shown in the table, many signals have different numeric values on
different architectures. The first numeric value in each table row
shows the signal number on x86, ARM, and most other architectures;
the second value is for Alpha and SPARC; the third is for MIPS; and
the last is for PARISC. A dash (-) denotes that a signal is absent
on the corresponding architecture.
Signal x86/ARM Alpha/ MIPS PARISC Notes
most others SPARC
─────────────────────────────────────────────────────────────────
SIGHUP 1 1 1 1
SIGINT 2 2 2 2
SIGQUIT 3 3 3 3
SIGILL 4 4 4 4
SIGTRAP 5 5 5 5
SIGABRT 6 6 6 6
SIGIOT 6 6 6 6
SIGBUS 7 10 10 10
SIGEMT - 7 7 -
SIGFPE 8 8 8 8
SIGKILL 9 9 9 9
SIGUSR1 10 30 16 16
SIGSEGV 11 11 11 11
SIGUSR2 12 31 17 17
SIGPIPE 13 13 13 13
SIGALRM 14 14 14 14
SIGTERM 15 15 15 15
SIGSTKFLT 16 - - 7
SIGCHLD 17 20 18 18
SIGCLD - - 18 -
SIGCONT 18 19 25 26
SIGSTOP 19 17 23 24
SIGTSTP 20 18 24 25
SIGTTIN 21 21 26 27
SIGTTOU 22 22 27 28
SIGURG 23 16 21 29
SIGXCPU 24 24 30 12
SIGXFSZ 25 25 31 30
SIGVTALRM 26 26 28 20
SIGPROF 27 27 29 21
SIGWINCH 28 28 20 23
SIGIO 29 23 22 22
SIGPOLL Same as SIGIO
SIGPWR 30 29/- 19 19
SIGINFO - 29/- - -
SIGLOST - -/29 - -
SIGSYS 31 12 12 31
SIGUNUSED 31 - - 31
Note the following:
* Where defined, SIGUNUSED is synonymous with SIGSYS. Since glibc
2.26, SIGUNUSED is no longer defined on any architecture.
* Signal 29 is SIGINFO/SIGPWR (synonyms for the same value) on Alpha
but SIGLOST on SPARC.
Real-time signals
Starting with version 2.2, Linux supports real-time signals as
originally defined in the POSIX.1b real-time extensions (and now
included in POSIX.1-2001). The range of supported real-time signals
is defined by the macros SIGRTMIN and SIGRTMAX. POSIX.1-2001
requires that an implementation support at least _POSIX_RTSIG_MAX (8)
real-time signals.
The Linux kernel supports a range of 33 different real-time signals,
numbered 32 to 64. However, the glibc POSIX threads implementation
internally uses two (for NPTL) or three (for LinuxThreads) real-time
signals (see pthreads(7)), and adjusts the value of SIGRTMIN suitably
(to 34 or 35). Because the range of available real-time signals
varies according to the glibc threading implementation (and this
variation can occur at run time according to the available kernel and
glibc), and indeed the range of real-time signals varies across UNIX
systems, programs should never refer to real-time signals using hard-
coded numbers, but instead should always refer to real-time signals
using the notation SIGRTMIN+n, and include suitable (run-time) checks
that SIGRTMIN+n does not exceed SIGRTMAX.
Unlike standard signals, real-time signals have no predefined
meanings: the entire set of real-time signals can be used for
application-defined purposes.
The default action for an unhandled real-time signal is to terminate
the receiving process.
Real-time signals are distinguished by the following:
1. Multiple instances of real-time signals can be queued. By
contrast, if multiple instances of a standard signal are
delivered while that signal is currently blocked, then only one
instance is queued.
2. If the signal is sent using sigqueue(3), an accompanying value
(either an integer or a pointer) can be sent with the signal. If
the receiving process establishes a handler for this signal using
the SA_SIGINFO flag to sigaction(2), then it can obtain this data
via the si_value field of the siginfo_t structure passed as the
second argument to the handler. Furthermore, the si_pid and
si_uid fields of this structure can be used to obtain the PID and
real user ID of the process sending the signal.
3. Real-time signals are delivered in a guaranteed order. Multiple
real-time signals of the same type are delivered in the order
they were sent. If different real-time signals are sent to a
process, they are delivered starting with the lowest-numbered
signal. (I.e., low-numbered signals have highest priority.) By
contrast, if multiple standard signals are pending for a process,
the order in which they are delivered is unspecified.
If both standard and real-time signals are pending for a process,
POSIX leaves it unspecified which is delivered first. Linux, like
many other implementations, gives priority to standard signals in
this case.
According to POSIX, an implementation should permit at least
_POSIX_SIGQUEUE_MAX (32) real-time signals to be queued to a process.
However, Linux does things differently. In kernels up to and
including 2.6.7, Linux imposes a system-wide limit on the number of
queued real-time signals for all processes. This limit can be viewed
and (with privilege) changed via the /proc/sys/kernel/rtsig-max file.
A related file, /proc/sys/kernel/rtsig-nr, can be used to find out
how many real-time signals are currently queued. In Linux 2.6.8,
these /proc interfaces were replaced by the RLIMIT_SIGPENDING
resource limit, which specifies a per-user limit for queued signals;
see setrlimit(2) for further details.
The addition of real-time signals required the widening of the signal
set structure (sigset_t) from 32 to 64 bits. Consequently, various
system calls were superseded by new system calls that supported the
larger signal sets. The old and new system calls are as follows:
Linux 2.0 and earlier Linux 2.2 and later
sigaction(2) rt_sigaction(2)
sigpending(2) rt_sigpending(2)
sigprocmask(2) rt_sigprocmask(2)
sigreturn(2) rt_sigreturn(2)
sigsuspend(2) rt_sigsuspend(2)
sigtimedwait(2) rt_sigtimedwait(2)
Interruption of system calls and library functions by signal handlers
If a signal handler is invoked while a system call or library
function call is blocked, then either:
* the call is automatically restarted after the signal handler
returns; or
* the call fails with the error EINTR.
Which of these two behaviors occurs depends on the interface and
whether or not the signal handler was established using the
SA_RESTART flag (see sigaction(2)). The details vary across UNIX
systems; below, the details for Linux.
If a blocked call to one of the following interfaces is interrupted
by a signal handler, then the call is automatically restarted after
the signal handler returns if the SA_RESTART flag was used; otherwise
the call fails with the error EINTR:
* read(2), readv(2), write(2), writev(2), and ioctl(2) calls on
"slow" devices. A "slow" device is one where the I/O call may
block for an indefinite time, for example, a terminal, pipe, or
socket. If an I/O call on a slow device has already transferred
some data by the time it is interrupted by a signal handler, then
the call will return a success status (normally, the number of
bytes transferred). Note that a (local) disk is not a slow device
according to this definition; I/O operations on disk devices are
not interrupted by signals.
* open(2), if it can block (e.g., when opening a FIFO; see fifo(7)).
* wait(2), wait3(2), wait4(2), waitid(2), and waitpid(2).
* Socket interfaces: accept(2), connect(2), recv(2), recvfrom(2),
recvmmsg(2), recvmsg(2), send(2), sendto(2), and sendmsg(2), unless
a timeout has been set on the socket (see below).
* File locking interfaces: flock(2) and the F_SETLKW and F_OFD_SETLKW
operations of fcntl(2)
* POSIX message queue interfaces: mq_receive(3), mq_timedreceive(3),
mq_send(3), and mq_timedsend(3).
* futex(2) FUTEX_WAIT (since Linux 2.6.22; beforehand, always failed
with EINTR).
* getrandom(2).
* pthread_mutex_lock(3), pthread_cond_wait(3), and related APIs.
* futex(2) FUTEX_WAIT_BITSET.
* POSIX semaphore interfaces: sem_wait(3) and sem_timedwait(3) (since
Linux 2.6.22; beforehand, always failed with EINTR).
* read(2) from an inotify(7) file descriptor (since Linux 3.8;
beforehand, always failed with EINTR).
The following interfaces are never restarted after being interrupted
by a signal handler, regardless of the use of SA_RESTART; they always
fail with the error EINTR when interrupted by a signal handler:
* "Input" socket interfaces, when a timeout (SO_RCVTIMEO) has been
set on the socket using setsockopt(2): accept(2), recv(2),
recvfrom(2), recvmmsg(2) (also with a non-NULL timeout argument),
and recvmsg(2).
* "Output" socket interfaces, when a timeout (SO_RCVTIMEO) has been
set on the socket using setsockopt(2): connect(2), send(2),
sendto(2), and sendmsg(2).
* Interfaces used to wait for signals: pause(2), sigsuspend(2),
sigtimedwait(2), and sigwaitinfo(2).
* File descriptor multiplexing interfaces: epoll_wait(2),
epoll_pwait(2), poll(2), ppoll(2), select(2), and pselect(2).
* System V IPC interfaces: msgrcv(2), msgsnd(2), semop(2), and
semtimedop(2).
* Sleep interfaces: clock_nanosleep(2), nanosleep(2), and usleep(3).
* io_getevents(2).
The sleep(3) function is also never restarted if interrupted by a
handler, but gives a success return: the number of seconds remaining
to sleep.
Interruption of system calls and library functions by stop signals
On Linux, even in the absence of signal handlers, certain blocking
interfaces can fail with the error EINTR after the process is stopped
by one of the stop signals and then resumed via SIGCONT. This
behavior is not sanctioned by POSIX.1, and doesn't occur on other
systems.
The Linux interfaces that display this behavior are:
* "Input" socket interfaces, when a timeout (SO_RCVTIMEO) has been
set on the socket using setsockopt(2): accept(2), recv(2),
recvfrom(2), recvmmsg(2) (also with a non-NULL timeout argument),
and recvmsg(2).
* "Output" socket interfaces, when a timeout (SO_RCVTIMEO) has been
set on the socket using setsockopt(2): connect(2), send(2),
sendto(2), and sendmsg(2), if a send timeout (SO_SNDTIMEO) has been
set.
* epoll_wait(2), epoll_pwait(2).
* semop(2), semtimedop(2).
* sigtimedwait(2), sigwaitinfo(2).
* Linux 3.7 and earlier: read(2) from an inotify(7) file descriptor
* Linux 2.6.21 and earlier: futex(2) FUTEX_WAIT, sem_timedwait(3),
sem_wait(3).
* Linux 2.6.8 and earlier: msgrcv(2), msgsnd(2).
* Linux 2.4 and earlier: nanosleep(2).
POSIX.1, except as noted.
For a discussion of async-signal-safe functions, see
signal-safety(7).
The /proc/[pid]/task/[tid]/status file contains various fields that
show the signals that a thread is blocking (SigBlk), catching
(SigCgt), or ignoring (SigIgn). (The set of signals that are caught
or ignored will be the same across all threads in a process.) Other
fields show the set of pending signals that are directed to the
thread (SigPnd) as well as the set of pending signals that are
directed to the process as a whole (ShdPnd). The corresponding
fields in /proc/[pid]/status show the information for the main
thread. See proc(5) for further details.
There are six signals that can be delivered as a consequence of a
hardware exception: SIGBUS, SIGEMT, SIGFPE, SIGILL, SIGSEGV, and
SIGTRAP. Which of these signals is delivered, for any given hardware
exception, is not documented and does not always make sense.
For example, an invalid memory access that causes delivery of SIGSEGV
on one CPU architecture may cause delivery of SIGBUS on another
architecture, or vice versa.
For another example, using the x86 int instruction with a forbidden
argument (any number other than 3 or 128) causes delivery of SIGSEGV,
even though SIGILL would make more sense, because of how the CPU
reports the forbidden operation to the kernel.
kill(1), clone(2), getrlimit(2), kill(2), pidfd_send_signal(2),
restart_syscall(2), rt_sigqueueinfo(2), setitimer(2), setrlimit(2),
sgetmask(2), sigaction(2), sigaltstack(2), signal(2), signalfd(2),
sigpending(2), sigprocmask(2), sigreturn(2), sigsuspend(2),
sigwaitinfo(2), abort(3), bsd_signal(3), killpg(3), longjmp(3),
pthread_sigqueue(3), raise(3), sigqueue(3), sigset(3), sigsetops(3),
sigvec(3), sigwait(3), strsignal(3), sysv_signal(3), core(5),
proc(5), nptl(7), pthreads(7), sigevent(7)
This page is part of release 5.08 of the Linux man-pages project. A
description of the project, information about reporting bugs, and the
latest version of this page, can be found at
https://www.kernel.org/doc/man-pages/.
Linux 2020-08-13 SIGNAL(7)
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