|Skip Navigation Links|
|Exit Print View|
|man pages section 2: System Calls Oracle Solaris 11 Express 11/10|
- detailed signal management
#include <signal.h> int sigaction(int sig, const struct sigaction *restrict act, struct sigaction *restrict oact);
The sigaction() function allows the calling process to examine or specify the action to be taken on delivery of a specific signal. See signal.h(3HEAD) for an explanation of general signal concepts.
The sig argument specifies the signal and can be assigned any of the signals specified in signal.h(3HEAD) except SIGKILL and SIGSTOP.
If the argument act is not NULL, it points to a structure specifying the new action to be taken when delivering sig. If the argument oact is not NULL, it points to a structure where the action previously associated with sig is to be stored on return from sigaction().
The sigaction structure includes the following members:
void (*sa_handler)( ); void (*sa_sigaction)(int, siginfo_t *, void *); sigset_t sa_mask; int sa_flags;
The storage occupied by sa_handler and sa_sigaction may overlap, and a standard-conforming application (see standards(5)) must not use both simultaneously.
The sa_handler member identifies the action to be associated with the specified signal, if the SA_SIGINFO flag (see below) is cleared in the sa_flags field of the sigaction structure. It may take any of the values specified in signal.h(3HEAD) or that of a user specified signal handler. If the SA_SIGINFO flag is set in the sa_flags field, the sa_sigaction field specifies a signal-catching function.
The sa_mask member specifies a set of signals to be blocked while the signal handler is active. On entry to the signal handler, that set of signals is added to the set of signals already being blocked when the signal is delivered. In addition, the signal that caused the handler to be executed will also be blocked, unless the SA_NODEFER flag has been specified. SIGSTOP and SIGKILL cannot be blocked (the system silently enforces this restriction).
The sa_flags member specifies a set of flags used to modify the delivery of the signal. It is formed by a logical OR of any of the following values:
If set and the signal is caught, and if the thread that is chosen to processes a delivered signal has an alternate signal stack declared with sigaltstack(2), then it will process the signal on that stack. Otherwise, the signal is delivered on the thread's normal stack.
If set and the signal is caught, the disposition of the signal is reset to SIG_DFL and the signal will not be blocked on entry to the signal handler (SIGILL, SIGTRAP, and SIGPWR cannot be automatically reset when delivered; the system silently enforces this restriction).
If set and the signal is caught, the signal will not be automatically blocked by the kernel while it is being caught.
If set and the signal is caught, functions that are interrupted by the execution of this signal's handler are transparently restarted by the system, namely fcntl(2), ioctl(2), wait(3C), waitid(2), and the following functions on slow devices like terminals: getmsg() and getpmsg() (see getmsg(2)); putmsg() and putpmsg() (see putmsg(2)); pread(), read(), and readv() (see read(2)); pwrite(), write(), and writev() (see write(2)); recv(), recvfrom(), and recvmsg() (see recv(3SOCKET)); and send(), sendto(), and sendmsg() (see send(3SOCKET)). Otherwise, the function returns an EINTR error.
If cleared and the signal is caught, sig is passed as the only argument to the signal-catching function. If set and the signal is caught, two additional arguments are passed to the signal-catching function. If the second argument is not equal to NULL, it points to a siginfo_t structure containing the reason why the signal was generated (see siginfo.h(3HEAD)); the third argument points to a ucontext_t structure containing the receiving process's context when the signal was delivered (see ucontext.h(3HEAD)).
If set and sig equals SIGCHLD, the system will not create zombie processes when children of the calling process exit. If the calling process subsequently issues a wait(3C), it blocks until all of the calling process's child processes terminate, and then returns -1 with errno set to ECHILD.
If set and sig equals SIGCHLD, SIGCHLD will not be sent to the calling process when its child processes stop or continue.
Upon successful completion, 0 is returned. Otherwise, -1 is returned, errno is set to indicate the error, and no new signal handler is installed.
The sigaction() function will fail if:
The value of the sig argument is not a valid signal number or is equal to SIGKILL or SIGSTOP. In addition, if in a multithreaded process, it is equal to SIGWAITING, SIGCANCEL, or SIGLWP.
See attributes(5) for descriptions of the following attributes:
kill(1), Intro(2), exit(2), fcntl(2), getmsg(2), ioctl(2), kill(2), pause(2), putmsg(2), read(2), sigaltstack(2), sigprocmask(2), sigsend(2), sigsuspend(2), waitid(2), write(2), recv(3SOCKET), send(3SOCKET), siginfo.h(3HEAD), signal(3C), signal.h(3HEAD), sigsetops(3C), ucontext.h(3HEAD), wait(3C), attributes(5), standards(5)
The handler routine can be declared:
void handler (int sig, siginfo_t *sip, ucontext_t *ucp);
The sig argument is the signal number. The sip argument is a pointer (to space on the stack) to a siginfo_t structure, which provides additional detail about the delivery of the signal. The ucp argument is a pointer (again to space on the stack) to a ucontext_t structure (defined in <sys/ucontext.h>) which contains the context from before the signal. It is not recommended that ucp be used by the handler to restore the context from before the signal delivery.