Is it valid to have multiple signal handlers for same signal? - c

I have two shared libraries linked to my test application. Both of the libraries have signal handlers for SIGINT.
Is it valid to have multiple signal handlers for same signal? Which order the handlers will execute when I generate a SIGINT signal?


As said by others, only one signal handler can be set, which is the last one. You would then have to manage calling two functions yourself. The sigaction function can return the previously installed signal handler which you can call yourself.
Something like this (untested code):
/* other signal handlers */
static void (*lib1_sighandler)(int) = NULL;
static void (*lib2_sighandler)(int) = NULL;
static void aggregate_handler(int signum)
{
/* your own cleanup */
if (lib1_sighandler)
lib1_sighandler(signum);
if (lib2_sighandler)
lib2_sighandler(signum);
}
... (later in main)
struct sigaction sa;
struct sigaction old;
lib1_init(...);
/* retrieve lib1's sig handler */
sigaction(SIGINT, NULL, &old);
lib1_sighandler = old.sa_handler;
lib2_init(...);
/* retrieve lib2's sig handler */
sigaction(SIGINT, NULL, &old);
lib2_sighandler = old.sa_handler;
/* set our own sig handler */
memset(&sa, 0, sizeof(sa));
sa.sa_handler = aggregate_handler;
sigemptyset(&sa.sa_mask);
sigaction(SIGINT, &sa, NULL);


Only one signal handler can be installed per signal. Only the latest installed handler will be active.


we can handle multiple signal with single signal handler but
but its is not possible to have multiple signal handler for same signal.
void sig_handler(int signo)
{
if (signo == SIGINT)
printf("received SIGINT 1\n");
}
void sig(int signo)
{
if (signo == SIGINT)
printf("received SIGINT 2\n");
}
int main(void)
{
if(signal(SIGINT, sig_handler) == SIG_ERR)
printf("\ncan't catch SIGINT\n");
if (signal(SIGINT, sig) == SIG_ERR)
printf("\ncan't catch SIGINT\n");
// A long long wait so that we can easily issue a signal to this process
while(1)
sleep(1);
return 0;
}
if u try to run this code u will find that the last assigned signal handler is set for that signal.
i think it is not possible to have a multiple signal handler for same signal.


As you could see in the man page for sigaction, the new signal handler replaces the old one and the old one is returned.
If you have two unused signals (say SIGUSR1 and SIGUSR2), assign those signals the two signal handlers for SIGINT. Then you may write your own Signal Handler for SIGINT and from that, you may raise the needed unused signal as per you want.


Shabaz hit the nail on the head. However, if you're looking for something all your libraries could use (provided you have access to the source code), you could do something along the following lines:
linked_list* sigint_handlers = NULL;
void sighand_init(sighand_config_t* config) {
struct sigaction action;
memset(&signalaction, 0, sizeof(signalaction));
action.sa_handler = &sighand_main;
// Order is important, in case we get a signal during start-up
sigint_handlers = linked_list_new();
sigaction(SIGINT, &action);
}
void sighand_main(int signum) {
if (signum == SIGINT) {
linked_list_node* node = linked_list_head(sigint_handlers);
while ((node = node->next) != NULL) {
node->object(signum);
}
if (sighand_config.exitonint) {
app_exit(0);
}
}
}
void sighand_add_int_handler(void (*handler)(int)) {
if (handler == NULL) return;
linked_list_add(sigint_handlers, handler);
}
void sighand_destroy() {
...
linked_list_destroy(signint_handlers);
...
}
Or, you could use this yourself, and after loading each library, get the handler and later call add_handler. Something along the lines of:
loadlibrary(lib1.so);
sigaction1 = signalget(SIGINT);
loadlibrary(lib2.so);
sigaction2 = signalget(SIGINT);
sighand_init(...);
sighand_add_int_handler(sigaction1.sa_handler);
sighand_add_int_handler(sigaction2.sa_handler);
Just some thoughts,
Anthony

Related

Received SIGTERM from own process

My daemon (linux only) has the following signal handler:
static void signal_handler(int id, siginfo_t *si, void *context) {
if (id == SIGTERM) {
/* prevent suicide - see below */
if (si->si_pid == getpid()) {
printf("Warning: received SIGTERM from own process\n");
return;
}
/* rest of code omitted */
}
/* rest of code omitted */
}
... which is installed like this in main():
struct sigaction sa;
memset(&sa, 0, sizeof(sa));
sa.sa_sigaction = &signal_handler;
sa.sa_flags = SA_SIGINFO;
sigaction(SIGINT, &sa, NULL);
sigaction(SIGTERM, &sa, NULL);
sigaction(SIGHUP, &sa, NULL);
The reason for the suicide check in the signal handler is that from time to time (once in 4 weeks) my daemon terminated because it received a SIGTERM from itself.
I am unable to find the cause. The only single kill() call used in the program is this one:
int kill_wrapper(pid_t pid, int sig) {
if (pid <= 0 || pid == getpid())
return -1;
return kill(pid, sig);
}
The code has no single raise() or abort() calls.
I wonder which possible (maybe external) reasons might exist that can cause this program to receive SIGTERM from itself under Linux ?

See this discussion. The bottom line is that si_pid is meaningful in very few cases.

sigwait() and signal handler

If I setup and signal handler for SIGABRT and meanwhile I have a thread that waits on sigwait() for SIGABRT to come (I have a blocked SIGABRT in other threads by pthread_sigmask).
So which one will be processed first ? Signal handler or sigwait() ?
[I am facing some issues that sigwait() is get blocked for ever. I am debugging it currently]
main()
{
sigset_t signal_set;
sigemptyset(&signal_set);
sigaddset(&signal_set, SIGABRT);
sigprocmask(SIG_BLOCK, &signal_set, NULL);
// Dont deliver SIGABORT while running this thread and it's kids.
pthread_sigmask(SIG_BLOCK, &signal_set, NULL);
pthread_create(&tAbortWaitThread, NULL, WaitForAbortThread, NULL);
..
Create all other threads
...
}
static void* WaitForAbortThread(void* v)
{
sigset_t signal_set;
int stat;
int sig;
sigfillset( &signal_set);
pthread_sigmask( SIG_BLOCK, &signal_set, NULL ); // Dont want any signals
sigemptyset(&signal_set);
sigaddset(&signal_set, SIGABRT); // Add only SIGABRT
// This thread while executing , will handle the SIGABORT signal via signal handler.
pthread_sigmask(SIG_UNBLOCK, &signal_set, NULL);
stat= sigwait( &signal_set, &sig ); // lets wait for signal handled in CatchAbort().
while (stat == -1)
{
stat= sigwait( &signal_set, &sig );
}
TellAllThreadsWeAreGoingDown();
sleep(10);
return null;
}
// Abort signal handler executed via sigaction().
static void CatchAbort(int i, siginfo_t* info, void* v)
{
sleep(20); // Dont return , hold on till the other threads are down.
}
Here at sigwait(), i will come to know that SIGABRT is received. I will tell other threads about it. Then will hold abort signal handler so that process is not terminated.
I wanted to know the interaction of sigwait() and the signal handler.

From sigwait() documentation :
The sigwait() function suspends execution of the calling thread until
one of the signals specified in the signal set becomes pending.
A pending signal means a blocked signal waiting to be delivered to one of the thread/process. Therefore, you need not to unblock the signal like you did with your pthread_sigmask(SIG_UNBLOCK, &signal_set, NULL) call.
This should work :
static void* WaitForAbortThread(void* v){
sigset_t signal_set;
sigemptyset(&signal_set);
sigaddset(&signal_set, SIGABRT);
sigwait( &signal_set, &sig );
TellAllThreadsWeAreGoingDown();
sleep(10);
return null;
}

I got some information from this <link>
It says :
To allow a thread to wait for asynchronously generated signals, the threads library provides the sigwait subroutine. The sigwait subroutine blocks the calling thread until one of the awaited signals is sent to the process or to the thread. There must not be a signal handler installed on the awaited signal using the sigwait subroutine.
I will remove the sigaction() handler and try only sigwait().

From the code snippet you've posted, it seems you got the use of sigwait() wrong. AFAIU, you need WaitForAbortThread like below:
sigemptyset( &signal_set); // change it from sigfillset()
for (;;) {
stat = sigwait(&signal_set, &sig);
if (sig == SIGABRT) {
printf("here's sigbart.. do whatever you want.\n");
pthread_kill(tid, signal); // thread id and signal
}
}
I don't think pthread_sigmask() is really needed. Since you only want to handle SIGABRT, first init signal_set as empty then simply add SIGABRT, then jump into the infinite loop, sigwait will wait for the particular signal that you're looking for, you check the signal if it's SIGABRT, if yes - do whatever you want. NOTE the uses of pthread_kill(), use it to sent any signal to other threads specified via tid and the signal you want to sent, make sure you know the tid of other threads you want to sent signal. Hope this will help!

I know this question is about a year old, but I often use a pattern, which solves exactly this issue using pthreads and signals. It is a little length but takes care of any issues I am aware of.
I recently used in combination with a library wrapped with SWIG and called from within Python. An annoying issue was that my IRQ thread waiting for SIGINT using sigwait never received the SIGINT signal. The same library worked perfectly when called from Matlab, which didn't capture the SIGINT signal.
The solution was to install a signal handler
#define _NTHREADS 8
#include <signal.h>
#include <pthread.h>
#include <unistd.h>
#include <sched.h>
#include <linux/unistd.h>
#include <sys/signal.h>
#include <sys/syscall.h>
#include <setjmp.h>
#include <stdio.h>
#include <stdlib.h>
#include <errno.h>
#include <string.h> // strerror
#define CallErr(fun, arg) { if ((fun arg)<0) \
FailErr(#fun) }
#define CallErrExit(fun, arg, ret) { if ((fun arg)<0) \
FailErrExit(#fun,ret) }
#define FailErrExit(msg,ret) { \
(void)fprintf(stderr, "FAILED: %s(errno=%d strerror=%s)\n", \
msg, errno, strerror(errno)); \
(void)fflush(stderr); \
return ret; }
#define FailErr(msg) { \
(void)fprintf(stderr, "FAILED: %s(errno=%d strerror=%s)\n", \
msg, errno, strerror(errno)); \
(void)fflush(stderr);}
typedef struct thread_arg {
int cpu_id;
int thread_id;
} thread_arg_t;
static jmp_buf jmp_env;
static struct sigaction act;
static struct sigaction oact;
size_t exitnow = 0;
pthread_mutex_t exit_mutex;
pthread_attr_t attr;
pthread_t pids[_NTHREADS];
pid_t tids[_NTHREADS+1];
static volatile int status[_NTHREADS]; // 0: suspended, 1: interrupted, 2: success
sigset_t mask;
static pid_t gettid( void );
static void *thread_function(void *arg);
static void signalHandler(int);
int main() {
cpu_set_t cpuset;
int nproc;
int i;
thread_arg_t thread_args[_NTHREADS];
int id;
CPU_ZERO( &cpuset );
CallErr(sched_getaffinity,
(gettid(), sizeof( cpu_set_t ), &cpuset));
nproc = CPU_COUNT(&cpuset);
for (i=0 ; i < _NTHREADS ; i++) {
thread_args[i].cpu_id = i % nproc;
thread_args[i].thread_id = i;
status[i] = 0;
}
pthread_attr_init(&attr);
pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_JOINABLE);
pthread_mutex_init(&exit_mutex, NULL);
// We pray for no locks on buffers and setbuf will work, if not we
// need to use filelock() on on FILE* access, tricky
setbuf(stdout, NULL);
setbuf(stderr, NULL);
act.sa_flags = SA_NOCLDSTOP | SA_NOCLDWAIT;
act.sa_handler = signalHandler;
sigemptyset(&act.sa_mask);
sigemptyset(&mask);
sigaddset(&mask, SIGINT);
if (setjmp(jmp_env)) {
if (gettid()==tids[0]) {
// Main Thread
printf("main thread: waiting for clients to terminate\n");
for (i = 0; i < _NTHREADS; i++) {
CallErr(pthread_join, (pids[i], NULL));
if (status[i] == 1)
printf("thread %d: terminated\n",i+1);
}
// On linux this can be done immediate after creation
CallErr(pthread_attr_destroy, (&attr));
CallErr(pthread_mutex_destroy, (&exit_mutex));
return 0;
}
else {
// Should never happen
printf("worker thread received signal");
}
return -1;
}
// Install handler
CallErr(sigaction, (SIGINT, &act, &oact));
// Block SIGINT
CallErr(pthread_sigmask, (SIG_BLOCK, &mask, NULL));
tids[0] = gettid();
srand ( time(NULL) );
for (i = 0; i < _NTHREADS; i++) {
// Inherits main threads signal handler, they are blocking
CallErr(pthread_create,
(&pids[i], &attr, thread_function,
(void *)&thread_args[i]));
}
if (pthread_sigmask(SIG_UNBLOCK, &mask, NULL)) {
fprintf(stderr, "main thread: can't block SIGINT");
}
printf("Infinite loop started - CTRL-C to exit\n");
for (i = 0; i < _NTHREADS; i++) {
CallErr(pthread_join, (pids[i], NULL));
//printf("%d\n",status[i]);
if (status[i] == 2)
printf("thread %d: finished succesfully\n",i+1);
}
// Clean up and exit
CallErr(pthread_attr_destroy, (&attr));
CallErr(pthread_mutex_destroy, (&exit_mutex));
return 0;
}
static void signalHandler(int sig) {
int i;
pthread_t id;
id = pthread_self();
for (i = 0; i < _NTHREADS; i++)
if (pids[i] == id) {
// Exits if worker thread
printf("Worker thread caught signal");
break;
}
if (sig==2) {
sigaction(SIGINT, &oact, &act);
}
pthread_mutex_lock(&exit_mutex);
if (!exitnow)
exitnow = 1;
pthread_mutex_unlock(&exit_mutex);
longjmp(jmp_env, 1);
}
void *thread_function(void *arg) {
cpu_set_t set;
thread_arg_t* threadarg;
int thread_id;
threadarg = (thread_arg_t*) arg;
thread_id = threadarg->thread_id+1;
tids[thread_id] = gettid();
CPU_ZERO( &set );
CPU_SET( threadarg->cpu_id, &set );
CallErrExit(sched_setaffinity, (gettid(), sizeof(cpu_set_t), &set ),
NULL);
int k = 8;
// While loop waiting for exit condition
while (k>0) {
sleep(rand() % 3);
pthread_mutex_lock(&exit_mutex);
if (exitnow) {
status[threadarg->thread_id] = 1;
pthread_mutex_unlock(&exit_mutex);
pthread_exit(NULL);
}
pthread_mutex_unlock(&exit_mutex);
k--;
}
status[threadarg->thread_id] = 2;
pthread_exit(NULL);
}
static pid_t gettid( void ) {
pid_t pid;
CallErr(pid = syscall, (__NR_gettid));
return pid;
}

I run serveral tests and the conbinations and results are:
For all test cases, I register a signal handler by calling sigaction in the main thread.
main thread block target signal, thread A unblock target signal by calling pthread_sigmask, thread A sleep, send target signal.
result: signal handler is executed in thread A.
main thread block target signal, thread A unblock target signal by calling pthread_sigmask, thread A calls sigwait, send target signal.
result: sigwait is executed.
main thread does not block target signal, thread A does not block target signal, thread A calls sigwait, send target signal.
result: main thread is chosen and the registered signal handler is executed in the main thread.
As you can see, conbination 1 and 2 are easy to understand and conclude.
It is:
If a signal is blocked by a thread, then the process-wide signal handler registered by sigaction just can't catch or even know it.
If a signal is not blocked, and it's sent before calling sigwait, the process-wide signal handler wins. And that's why APUE the books require us to block the target signal before calling sigwait. Here I use sleep in thread A to simulate a long "window time".
If a signal is not blocked, and it's sent when sigwait has already been waiting, sigwait wins.
But you should notice that for test case 1 and 2, main thread is designed to block the target signal.
At last for test case 3, when main thread is not blocked the target signal, and sigwait in thread A is also waiting, the signal handler is executed in the main thread.
I believe the behaviour of test case 3 is what APUE talks about:
From APUE ยง12.8:
If a signal is being caught (the process has established a signal
handler by using sigaction, for example) and a thread is waiting for
the same signal in a call to sigwait, it is left up to the
implementation to decide which way to deliver the signal. The
implementation could either allow sigwait to return or invoke the
signal handler, but not both.
Above all, if you want to accomplish one thread <-> one signal model, you should:
block all signals in the main thread with pthread_sigmask (subsequent thread created in main thread inheris the signal mask)
create threads and call sigwait(target_signal) with target signal.
test code
#define _POSIX_C_SOURCE 200809L
#include <signal.h>
#include <stdio.h>
#include <pthread.h>
#include <stdlib.h>
#include <unistd.h>
#include <fcntl.h>
FILE* file;
void* threadA(void* argv){
fprintf(file, "%ld\n", pthread_self());
sigset_t m;
sigemptyset(&m);
sigaddset(&m, SIGUSR1);
int signo;
int err;
// sigset_t q;
// sigemptyset(&q);
// pthread_sigmask(SIG_SETMASK, &q, NULL);
// sleep(50);
fprintf(file, "1\n");
err = sigwait(&m, &signo);
if (err != 0){
fprintf(file, "sigwait error\n");
exit(1);
}
switch (signo)
{
case SIGUSR1:
fprintf(file, "SIGUSR1 received\n");
break;
default:
fprintf(file, "?\n");
break;
}
fprintf(file, "2\n");
}
void hello(int signo){
fprintf(file, "%ld\n", pthread_self());
fprintf(file, "hello\n");
}
int main(){
file = fopen("daemon", "wb");
setbuf(file, NULL);
struct sigaction sa;
sigemptyset(&sa.sa_mask);
sa.sa_handler = hello;
sigaction(SIGUSR1, &sa, NULL);
sigset_t n;
sigemptyset(&n);
sigaddset(&n, SIGUSR1);
// pthread_sigmask(SIG_BLOCK, &n, NULL);
pthread_t pid;
int err;
err = pthread_create(&pid, NULL, threadA, NULL);
if(err != 0){
fprintf(file, "create thread error\n");
exit(1);
}
pause();
fprintf(file, "after pause\n");
fclose(file);
return 0;
}
run with ./a.out & (run in the background), and use kill -SIGUSR1 pid to test. Do not use raise. raise, sleep, pause are thread-wide.

How is it possible multiple signals can get into handler even when signal is disabled?

So I have the following code segment as part of my program. Handler is the handler for the SIGALRM.
static void handler(void)
{
//DISABLE SIGALRM
sigset_t oldset;
disable_sigalrm(&oldset);
if(queue_length(&queue) == 0)
{
ucontext_t context;
getcontext(&context);
swapcontext(&context,&uctxt_main);
}
else
{
//...
//enable sigalarm
}
}
The program disable_sigalrm looks as follows:
void disable_sigalrm(sigset_t* oldset)
{
sigset_t sset;
//Empty sset
if(sigemptyset(&sset) == -1)
{
printf("Error in emptying the signal set.\n");
}
//Add SIGALRM to sset
if(sigaddset(&sset,SIGALRM) == -1)
{
printf("Error in adding SIGALRM to the specified signal set.\n");
}
//Block any occurence of SIGALRM
if(sigprocmask(SIG_BLOCK,&sset,oldset) == -1)
{
printf("Error in adding the specified signal; set to the signal mask.\n ");
}
}
Now when I run in the debugger even after the queue length reaches zero it keeps coming back to handler.
Since the SIGALRM is disabled, the only explanation that makes sense is if there are multiple signals waiting to reach the handler. Is it possible that multiple signals can wait to run to the handler? If so how would you disable them running the handler?

Is there a way to sigaction() to a signal handler with multiple parameters?

I am using sigaction() to perform an action every time SIGINT is received. All tutorials I have seen use this prototype as a signal handler
void sig_handler(int sig);
Is there a way somehow to make this to take more parameters so it suits my needs? So for example
void sig_handler(char* surname, int age);
This is my code:
void sig_handler(int sig) {
printf("SIGINT(%d) received\n", sig);
}
int main( ){
struct sigaction act;
act.sa_handler=sig_handler;
sigaction(SIGINT, &act, NULL);
while(1){};
return 0 ;
}

Not directly, but you could set a global variable that tells your sig_handler() what to do.
int ACTION = 0;
void sig_handler(int sig) {
if (sig == SIGINT) {
switch (ACTION) {
case 0: other_function(char* surname, int age);
break;
// more cases
default:
;
}
} else if ( .... // more signals
}
}
int main( ){
struct sigaction act;
act.sa_handler=sig_handler;
sigaction(SIGINT, &act, NULL);
while(1){};
return 0 ;
}

You can't do this with signals. How would these parameters be supplied and delivered? A signal is just a predefined numeric code that causes the process to execute the handler asynchronously, by interrupting the main flow.
You can, however, use a Unix socket, a pipe, or a fifo file for this.

How to send and trap a signal sent to a PID, using C

Suppose, i know the process of my parent id and would like to
kill(my_parent_id, SIGTERM)
As a parent process, how can i catch this signal?

Register to catch the signal:
void termination_handler(int sig)
{
/* do something */
}
struct sigaction handler;
handler.sa_handler = termination_handler;
sigemptyset (&handler.sa_mask);
handler.sa_flags = SA_RESTART;
sigaction(SIGTERM, &handler, NULL);
Here is a good example page.
You could use the old style, but it is not suggested:
void termination_handler()
{
/* do something */
}
signal(SIGTERM, termination_handler);

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