/* source: xiosigchld.c */ /* Copyright Gerhard Rieger 2001-2008 */ /* Published under the GNU General Public License V.2, see file COPYING */ /* this is the source of the extended child signal handler */ #include "xiosysincludes.h" #include "xioopen.h" #include "xiosigchld.h" /*****************************************************************************/ /* we maintain a table of all known child processes */ /* for now, we use a very primitive data structure - just an unsorted, size limited array */ #define XIO_MAXCHILDPIDS 16 struct _xiosigchld_child { pid_t pid; void (*sigaction)(int, siginfo_t *, void *); void *context; } ; static struct _xiosigchld_child * _xiosigchld_find(pid_t pid); static struct _xiosigchld_child xio_childpids[XIO_MAXCHILDPIDS]; #if 1 /*!!!*/ /*!! with socat, at most 4 managed children exist */ pid_t diedunknown1; /* child died before it is registered */ pid_t diedunknown2; pid_t diedunknown3; pid_t diedunknown4; #endif /* register for a xio filedescriptor a callback (handler). when a SIGCHLD occurs, the signal handler will ??? */ int xiosetsigchild(xiofile_t *xfd, int (*callback)(struct single *)) { if (xfd->tag != XIO_TAG_DUAL) { xfd->stream.child.sigchild = callback; } else { xfd->dual.stream[0]->child.sigchild = callback; xfd->dual.stream[1]->child.sigchild = callback; } return 0; } /* exec'd child has died, perform appropriate changes to descriptor */ static int sigchld_stream(struct single *file) { /*!! call back to application */ file->child.pid = 0; if (file->child.sigchild) { return (*file->child.sigchild)(file); } return 0; } /* return 0 if socket is not responsible for deadchild */ static int xio_checkchild(xiofile_t *socket, int socknum, pid_t deadchild) { int retval; if (socket != NULL) { if (socket->tag != XIO_TAG_DUAL) { if (socket->stream.child.pid == deadchild) { Info2("exec'd process %d on socket %d terminated", socket->stream.child.pid, socknum); sigchld_stream(&socket->stream); return 1; } } else { if (retval = xio_checkchild((xiofile_t *)socket->dual.stream[0], socknum, deadchild)) return retval; else return xio_checkchild((xiofile_t *)socket->dual.stream[1], socknum, deadchild); } } return 0; } /* this is the "physical" signal handler for SIGCHLD */ /* the current socat/xio implementation knows two kinds of children: exec/system addresses perform a fork: their children are registered and their death's influence the parents' flow; listen-socket with fork children: these children are "anonymous" and their death does not affect the parent process (now; maybe we have a child process counter later) */ void childdied(int signum #if HAVE_SIGACTION , siginfo_t *siginfo, void *context #endif /* HAVE_SIGACTION */ ) { pid_t pid; int _errno; int status = 0; bool wassig = false; int i; struct _xiosigchld_child *entry; _errno = errno; /* save current value; e.g., select() on Cygwin seems to set it to EINTR _before_ handling the signal, and then passes the value left by the signal handler to the caller of select(), accept() etc. */ /* is not thread/signal save, but confused messages in rare cases are better than no messages at all */ Info1("childdied(signum=%d)", signum); do { pid = Waitpid(-1, &status, WNOHANG); if (pid == 0) { Msg(wassig?E_INFO:E_WARN, "waitpid(-1, {}, WNOHANG): no child has exited"); Info("childdied() finished"); errno = _errno; return; } else if (pid < 0 && errno == ECHILD) { Msg1(wassig?E_INFO:E_WARN, "waitpid(-1, {}, WNOHANG): %s", strerror(errno)); Info("childdied() finished"); errno = _errno; return; } wassig = true; if (pid < 0) { Warn2("waitpid(-1, {%d}, WNOHANG): %s", status, strerror(errno)); Info("childdied() finished"); errno = _errno; return; } #if 0 /*! indent */ /* check if it was a registered child process */ i = 0; while (i < XIO_MAXSOCK) { if (xio_checkchild(sock[i], i, pid)) break; ++i; } if (i == XIO_MAXSOCK) { Info2("childdied(%d): cannot identify child %d", signum, pid); if (diedunknown1 == 0) { diedunknown1 = pid; Debug("saving pid in diedunknown1"); } else if (diedunknown2 == 0) { diedunknown2 = pid; Debug("saving pid in diedunknown2"); } else if (diedunknown3 == 0) { diedunknown3 = pid; Debug("saving pid in diedunknown3"); } else { diedunknown4 = pid; Debug("saving pid in diedunknown4"); } } #else entry = _xiosigchld_find(pid); if (entry == NULL) { Info("dead child "F_pid" died unknown"); } else { (*entry->sigaction)(signum, siginfo, entry->context); xiosigchld_unregister(pid); } #endif if (WIFEXITED(status)) { if (WEXITSTATUS(status) == 0) { Info2("waitpid(): child %d exited with status %d", pid, WEXITSTATUS(status)); } else { Warn2("waitpid(): child %d exited with status %d", pid, WEXITSTATUS(status)); } } else if (WIFSIGNALED(status)) { Info2("waitpid(): child %d exited on signal %d", pid, WTERMSIG(status)); } else if (WIFSTOPPED(status)) { Info2("waitpid(): child %d stopped on signal %d", pid, WSTOPSIG(status)); } else { Warn1("waitpid(): cannot determine status of child %d", pid); } #if !HAVE_SIGACTION /* we might need to re-register our handler */ if (Signal(SIGCHLD, childdied) == SIG_ERR) { Warn2("signal(SIGCHLD, %p): %s", childdied, strerror(errno)); } #endif /* !HAVE_SIGACTION */ } while (1); Info("childdied() finished"); errno = _errno; } /* search for given pid in child process table. returns matching entry on success, or NULL if not found. Can be used with pid==0 to look for an empty entry. */ static struct _xiosigchld_child * _xiosigchld_find(pid_t pid) { int i; /* is it already registered? */ for (i = 0; i < XIO_MAXCHILDPIDS; ++i) { if (pid == xio_childpids[i].pid) { return &xio_childpids[i]; } } return NULL; } /* add a child process to the table returns 0 on success (registered or reregistered child) returns -1 on table overflow */ int xiosigchld_register(pid_t pid, void (*sigaction)(int, siginfo_t *, void *), void *context) { struct _xiosigchld_child *entry; /* is it already registered? */ if (entry = _xiosigchld_find(pid)) { /* was already registered, override */ entry->sigaction = sigaction; entry->context = context; return 0; } /* try to register it */ if (entry = _xiosigchld_find(0)) { entry->pid = pid; entry->sigaction = sigaction; entry->context = context; return 0; } Warn("xiosigchld_register(): table overflow"); return -1; } /* remove a child process to the table returns 0 on success returns 1 if pid was not found in table */ int xiosigchld_unregister(pid_t pid) { struct _xiosigchld_child *entry; /* is it already registered? */ if (entry = _xiosigchld_find(pid)) { /* found, remove it from table */ entry->pid = 0; return 0; } return 1; } /* clear the child process table */ /* especially interesting after fork() in child process returns 0 */ int xiosigchld_clearall(void) { int i; for (i = 0; i < XIO_MAXCHILDPIDS; ++i) { xio_childpids[i].pid = 0; } return 0; } void xiosigaction_subaddr_ok(int signum, siginfo_t *siginfo, void *ucontext) { pid_t subpid = siginfo->si_pid; struct _xiosigchld_child *entry; xiosingle_t *xfd; entry = _xiosigchld_find(subpid); if (entry == NULL) { Warn1("SIGUSR1 from unregistered process "F_pid, subpid); return; } xfd = entry->context; xfd->subaddrstat = 1; } void xiosigaction_child(int signum, siginfo_t *siginfo, void *ucontext) { pid_t subpid = siginfo->si_pid; xiosingle_t *xfd = ucontext; /* the sub process that is connected to this xio address has terminated */ Notice2("sub process "F_pid" died, setting in xfd %p", subpid, xfd); xfd->subaddrstat = -1; xfd->subaddrexit = siginfo->si_status; if (xfd->child.sigchild) { (*xfd->child.sigchild)(xfd); } } int xiosetchilddied(void) { #if HAVE_SIGACTION struct sigaction act; memset(&act, 0, sizeof(struct sigaction)); act.sa_flags = SA_NOCLDSTOP|SA_RESTART|SA_SIGINFO #ifdef SA_NOMASK |SA_NOMASK #endif ; act.sa_sigaction = childdied; if (Sigaction(SIGCHLD, &act, NULL) < 0) { /*! man does not say that errno is defined */ Warn2("sigaction(SIGCHLD, %p, NULL): %s", childdied, strerror(errno)); } #else /* HAVE_SIGACTION */ if (Signal(SIGCHLD, childdied) == SIG_ERR) { Warn2("signal(SIGCHLD, %p): %s", childdied, strerror(errno)); } #endif /* !HAVE_SIGACTION */ return 0; }