18.4. signal — Set handlers for asynchronous events
This module provides mechanisms to use signal handlers in Python. Some general
rules for working with signals and their handlers:
- A handler for a particular signal, once set, remains installed until it is
explicitly reset (Python emulates the BSD style interface regardless of the
underlying implementation), with the exception of the handler for
SIGCHLD, which follows the underlying implementation.
- There is no way to “block” signals temporarily from critical sections (since
this is not supported by all Unix flavors).
- Although Python signal handlers are called asynchronously as far as the Python
user is concerned, they can only occur between the “atomic” instructions of the
Python interpreter. This means that signals arriving during long calculations
implemented purely in C (such as regular expression matches on large bodies of
text) may be delayed for an arbitrary amount of time.
- When a signal arrives during an I/O operation, it is possible that the I/O
operation raises an exception after the signal handler returns. This is
dependent on the underlying Unix system’s semantics regarding interrupted system
calls.
- Because the C signal handler always returns, it makes little sense to catch
synchronous errors like SIGFPE or SIGSEGV.
- Python installs a small number of signal handlers by default: SIGPIPE
is ignored (so write errors on pipes and sockets can be reported as ordinary
Python exceptions) and SIGINT is translated into a
KeyboardInterrupt exception. All of these can be overridden.
- Some care must be taken if both signals and threads are used in the same
program. The fundamental thing to remember in using signals and threads
simultaneously is: always perform signal() operations in the main thread
of execution. Any thread can perform an alarm(), getsignal(),
pause(), setitimer() or getitimer(); only the main thread
can set a new signal handler, and the main thread will be the only one to
receive signals (this is enforced by the Python signal module, even
if the underlying thread implementation supports sending signals to
individual threads). This means that signals can’t be used as a means of
inter-thread communication. Use locks instead.
The variables defined in the signal module are:
-
signal.SIG_DFL
- This is one of two standard signal handling options; it will simply perform
the default function for the signal. For example, on most systems the
default action for SIGQUIT is to dump core and exit, while the
default action for SIGCHLD is to simply ignore it.
-
signal.SIG_IGN
- This is another standard signal handler, which will simply ignore the given
signal.
-
SIG*
- All the signal numbers are defined symbolically. For example, the hangup signal
is defined as signal.SIGHUP; the variable names are identical to the
names used in C programs, as found in <signal.h>. The Unix man page for
‘signal()‘ lists the existing signals (on some systems this is
signal(2), on others the list is in signal(7)). Note that
not all systems define the same set of signal names; only those names defined by
the system are defined by this module.
-
signal.NSIG
- One more than the number of the highest signal number.
-
signal.ITIMER_REAL
- Decrements interval timer in real time, and delivers SIGALRM upon expiration.
-
signal.ITIMER_VIRTUAL
- Decrements interval timer only when the process is executing, and delivers
SIGVTALRM upon expiration.
-
signal.ITIMER_PROF
- Decrements interval timer both when the process executes and when the
system is executing on behalf of the process. Coupled with ITIMER_VIRTUAL,
this timer is usually used to profile the time spent by the application
in user and kernel space. SIGPROF is delivered upon expiration.
The signal module defines one exception:
-
exception signal.ItimerError
- Raised to signal an error from the underlying setitimer() or
getitimer() implementation. Expect this error if an invalid
interval timer or a negative time is passed to setitimer().
This error is a subtype of IOError.
The signal module defines the following functions:
-
signal.alarm(time)
- If time is non-zero, this function requests that a SIGALRM signal be
sent to the process in time seconds. Any previously scheduled alarm is
canceled (only one alarm can be scheduled at any time). The returned value is
then the number of seconds before any previously set alarm was to have been
delivered. If time is zero, no alarm is scheduled, and any scheduled alarm is
canceled. If the return value is zero, no alarm is currently scheduled. (See
the Unix man page alarm(2).) Availability: Unix.
-
signal.getsignal(signalnum)
- Return the current signal handler for the signal signalnum. The returned value
may be a callable Python object, or one of the special values
signal.SIG_IGN, signal.SIG_DFL or None. Here,
signal.SIG_IGN means that the signal was previously ignored,
signal.SIG_DFL means that the default way of handling the signal was
previously in use, and None means that the previous signal handler was not
installed from Python.
-
signal.pause()
- Cause the process to sleep until a signal is received; the appropriate handler
will then be called. Returns nothing. Not on Windows. (See the Unix man page
signal(2).)
-
signal.setitimer(which, seconds[, interval])
Sets given interval timer (one of signal.ITIMER_REAL,
signal.ITIMER_VIRTUAL or signal.ITIMER_PROF) specified
by which to fire after seconds (float is accepted, different from
alarm()) and after that every interval seconds. The interval
timer specified by which can be cleared by setting seconds to zero.
When an interval timer fires, a signal is sent to the process.
The signal sent is dependent on the timer being used;
signal.ITIMER_REAL will deliver SIGALRM,
signal.ITIMER_VIRTUAL sends SIGVTALRM,
and signal.ITIMER_PROF will deliver SIGPROF.
The old values are returned as a tuple: (delay, interval).
Attempting to pass an invalid interval timer will cause a
ItimerError.
New in version 2.6.
-
signal.getitimer(which)
Returns current value of a given interval timer specified by which.
New in version 2.6.
-
signal.set_wakeup_fd(fd)
Set the wakeup fd to fd. When a signal is received, a '\0' byte is
written to the fd. This can be used by a library to wakeup a poll or select
call, allowing the signal to be fully processed.
The old wakeup fd is returned. fd must be non-blocking. It is up to the
library to remove any bytes before calling poll or select again.
When threads are enabled, this function can only be called from the main thread;
attempting to call it from other threads will cause a ValueError
exception to be raised.
-
signal.siginterrupt(signalnum, flag)
Change system call restart behaviour: if flag is False, system calls
will be restarted when interrupted by signal signalnum, otherwise system calls will
be interrupted. Returns nothing. Availability: Unix (see the man page
siginterrupt(3) for further information).
Note that installing a signal handler with signal() will reset the restart
behaviour to interruptible by implicitly calling siginterrupt() with a true flag
value for the given signal.
New in version 2.6.
-
signal.signal(signalnum, handler)
Set the handler for signal signalnum to the function handler. handler can
be a callable Python object taking two arguments (see below), or one of the
special values signal.SIG_IGN or signal.SIG_DFL. The previous
signal handler will be returned (see the description of getsignal()
above). (See the Unix man page signal(2).)
When threads are enabled, this function can only be called from the main thread;
attempting to call it from other threads will cause a ValueError
exception to be raised.
The handler is called with two arguments: the signal number and the current
stack frame (None or a frame object; for a description of frame objects, see
the reference manual section on the standard type hierarchy or see the attribute
descriptions in the inspect module).
18.4.1. Example
Here is a minimal example program. It uses the alarm() function to limit
the time spent waiting to open a file; this is useful if the file is for a
serial device that may not be turned on, which would normally cause the
os.open() to hang indefinitely. The solution is to set a 5-second alarm
before opening the file; if the operation takes too long, the alarm signal will
be sent, and the handler raises an exception.
import signal, os
def handler(signum, frame):
print 'Signal handler called with signal', signum
raise IOError, "Couldn't open device!"
# Set the signal handler and a 5-second alarm
signal.signal(signal.SIGALRM, handler)
signal.alarm(5)
# This open() may hang indefinitely
fd = os.open('/dev/ttyS0', os.O_RDWR)
signal.alarm(0) # Disable the alarm