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Current File : //compat/linux/proc/68247/cwd/usr/src/lib/libkse/thread/thr_sig.c |
/* * Copyright (c) 1995-1998 John Birrell <jb@cimlogic.com.au> * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the author nor the names of any co-contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY JOHN BIRRELL AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD: release/9.1.0/lib/libkse/thread/thr_sig.c 177626 2008-03-26 07:32:08Z brueffer $ */ #include "namespace.h" #include <sys/param.h> #include <sys/types.h> #include <sys/signalvar.h> #include <signal.h> #include <errno.h> #include <fcntl.h> #include <unistd.h> #include <string.h> #include <pthread.h> #include "un-namespace.h" #include "thr_private.h" /* Prototypes: */ static inline void build_siginfo(siginfo_t *info, int signo); #ifndef SYSTEM_SCOPE_ONLY static struct pthread *thr_sig_find(struct kse *curkse, int sig, siginfo_t *info); #endif static inline void thr_sigframe_restore(struct pthread *thread, struct pthread_sigframe *psf); static inline void thr_sigframe_save(struct pthread *thread, struct pthread_sigframe *psf); #define SA_KILL 0x01 /* terminates process by default */ #define SA_STOP 0x02 #define SA_CONT 0x04 static int sigproptbl[NSIG] = { SA_KILL, /* SIGHUP */ SA_KILL, /* SIGINT */ SA_KILL, /* SIGQUIT */ SA_KILL, /* SIGILL */ SA_KILL, /* SIGTRAP */ SA_KILL, /* SIGABRT */ SA_KILL, /* SIGEMT */ SA_KILL, /* SIGFPE */ SA_KILL, /* SIGKILL */ SA_KILL, /* SIGBUS */ SA_KILL, /* SIGSEGV */ SA_KILL, /* SIGSYS */ SA_KILL, /* SIGPIPE */ SA_KILL, /* SIGALRM */ SA_KILL, /* SIGTERM */ 0, /* SIGURG */ SA_STOP, /* SIGSTOP */ SA_STOP, /* SIGTSTP */ SA_CONT, /* SIGCONT */ 0, /* SIGCHLD */ SA_STOP, /* SIGTTIN */ SA_STOP, /* SIGTTOU */ 0, /* SIGIO */ SA_KILL, /* SIGXCPU */ SA_KILL, /* SIGXFSZ */ SA_KILL, /* SIGVTALRM */ SA_KILL, /* SIGPROF */ 0, /* SIGWINCH */ 0, /* SIGINFO */ SA_KILL, /* SIGUSR1 */ SA_KILL /* SIGUSR2 */ }; /* #define DEBUG_SIGNAL */ #ifdef DEBUG_SIGNAL #define DBG_MSG stdout_debug #else #define DBG_MSG(x...) #endif /* * Signal setup and delivery. * * 1) Delivering signals to threads in the same KSE. * These signals are sent by upcall events and are set in the * km_sigscaught field of the KSE mailbox. Since these signals * are received while operating on the KSE stack, they can be * delivered either by using signalcontext() to add a stack frame * to the target thread's stack, or by adding them in the thread's * pending set and having the thread run them down after it * 2) Delivering signals to threads in other KSEs/KSEGs. * 3) Delivering signals to threads in critical regions. * 4) Delivering signals to threads after they change their signal masks. * * Methods of delivering signals. * * 1) Add a signal frame to the thread's saved context. * 2) Add the signal to the thread structure, mark the thread as * having signals to handle, and let the thread run them down * after it resumes from the KSE scheduler. * * Problem with 1). You can't do this to a running thread or a * thread in a critical region. * * Problem with 2). You can't do this to a thread that doesn't * yield in some way (explicitly enters the scheduler). A thread * blocked in the kernel or a CPU hungry thread will not see the * signal without entering the scheduler. * * The solution is to use both 1) and 2) to deliver signals: * * o Thread in critical region - use 2). When the thread * leaves the critical region it will check to see if it * has pending signals and run them down. * * o Thread enters scheduler explicitly - use 2). The thread * can check for pending signals after it returns from the * the scheduler. * * o Thread is running and not current thread - use 2). When the * thread hits a condition specified by one of the other bullets, * the signal will be delivered. * * o Thread is running and is current thread (e.g., the thread * has just changed its signal mask and now sees that it has * pending signals) - just run down the pending signals. * * o Thread is swapped out due to quantum expiration - use 1) * * o Thread is blocked in kernel - kse_thr_wakeup() and then * use 1) */ /* * Rules for selecting threads for signals received: * * 1) If the signal is a sychronous signal, it is delivered to * the generating (current thread). If the thread has the * signal masked, it is added to the threads pending signal * set until the thread unmasks it. * * 2) A thread in sigwait() where the signal is in the thread's * waitset. * * 3) A thread in sigsuspend() where the signal is not in the * thread's suspended signal mask. * * 4) Any thread (first found/easiest to deliver) that has the * signal unmasked. */ #ifndef SYSTEM_SCOPE_ONLY static void * sig_daemon(void *arg __unused) { int i; kse_critical_t crit; struct timespec ts; sigset_t set; struct kse *curkse; struct pthread *curthread = _get_curthread(); DBG_MSG("signal daemon started(%p)\n", curthread); curthread->name = strdup("signal thread"); crit = _kse_critical_enter(); curkse = _get_curkse(); /* * Daemon thread is a bound thread and we must be created with * all signals masked */ #if 0 SIGFILLSET(set); __sys_sigprocmask(SIG_SETMASK, &set, NULL); #endif __sys_sigpending(&set); ts.tv_sec = 0; ts.tv_nsec = 0; while (1) { KSE_LOCK_ACQUIRE(curkse, &_thread_signal_lock); _thr_proc_sigpending = set; KSE_LOCK_RELEASE(curkse, &_thread_signal_lock); for (i = 1; i <= _SIG_MAXSIG; i++) { if (SIGISMEMBER(set, i) != 0) _thr_sig_dispatch(curkse, i, NULL /* no siginfo */); } ts.tv_sec = 30; ts.tv_nsec = 0; curkse->k_kcb->kcb_kmbx.km_flags = KMF_NOUPCALL | KMF_NOCOMPLETED | KMF_WAITSIGEVENT; kse_release(&ts); curkse->k_kcb->kcb_kmbx.km_flags = 0; set = curkse->k_kcb->kcb_kmbx.km_sigscaught; } return (0); } /* Utility function to create signal daemon thread */ int _thr_start_sig_daemon(void) { pthread_attr_t attr; sigset_t sigset, oldset; SIGFILLSET(sigset); _pthread_sigmask(SIG_SETMASK, &sigset, &oldset); _pthread_attr_init(&attr); _pthread_attr_setscope(&attr, PTHREAD_SCOPE_SYSTEM); attr->flags |= THR_SIGNAL_THREAD; /* sigmask will be inherited */ if (_pthread_create(&_thr_sig_daemon, &attr, sig_daemon, NULL)) PANIC("can not create signal daemon thread!\n"); _pthread_attr_destroy(&attr); _pthread_sigmask(SIG_SETMASK, &oldset, NULL); return (0); } /* * This signal handler only delivers asynchronous signals. * This must be called with upcalls disabled and without * holding any locks. */ void _thr_sig_dispatch(struct kse *curkse, int sig, siginfo_t *info) { struct kse_mailbox *kmbx; struct pthread *thread; DBG_MSG(">>> _thr_sig_dispatch(%d)\n", sig); /* Check if the signal requires a dump of thread information: */ if (_thr_dump_enabled() && (sig == SIGINFO)) { /* Dump thread information to file: */ _thread_dump_info(); } while ((thread = thr_sig_find(curkse, sig, info)) != NULL) { /* * Setup the target thread to receive the signal: */ DBG_MSG("Got signal %d, selecting thread %p\n", sig, thread); KSE_SCHED_LOCK(curkse, thread->kseg); if ((thread->state == PS_DEAD) || (thread->state == PS_DEADLOCK) || THR_IS_EXITING(thread) || THR_IS_SUSPENDED(thread)) { KSE_SCHED_UNLOCK(curkse, thread->kseg); _thr_ref_delete(NULL, thread); } else if (SIGISMEMBER(thread->sigmask, sig)) { KSE_SCHED_UNLOCK(curkse, thread->kseg); _thr_ref_delete(NULL, thread); } else { kmbx = _thr_sig_add(thread, sig, info); KSE_SCHED_UNLOCK(curkse, thread->kseg); _thr_ref_delete(NULL, thread); if (kmbx != NULL) kse_wakeup(kmbx); break; } } DBG_MSG("<<< _thr_sig_dispatch\n"); } #endif /* ! SYSTEM_SCOPE_ONLY */ static __inline int sigprop(int sig) { if (sig > 0 && sig < NSIG) return (sigproptbl[_SIG_IDX(sig)]); return (0); } typedef void (*ohandler)(int sig, int code, struct sigcontext *scp, char *addr, __sighandler_t *catcher); void _thr_sig_handler(int sig, siginfo_t *info, void *ucp_arg) { struct pthread_sigframe psf; __siginfohandler_t *sigfunc; struct pthread *curthread; struct kse *curkse; ucontext_t *ucp; struct sigaction act; int sa_flags, err_save; err_save = errno; ucp = (ucontext_t *)ucp_arg; DBG_MSG(">>> _thr_sig_handler(%d)\n", sig); curthread = _get_curthread(); if (curthread == NULL) PANIC("No current thread.\n"); if (!(curthread->attr.flags & PTHREAD_SCOPE_SYSTEM)) PANIC("Thread is not system scope.\n"); if (curthread->flags & THR_FLAGS_EXITING) { errno = err_save; return; } curkse = _get_curkse(); /* * If thread is in critical region or if thread is on * the way of state transition, then latch signal into buffer. */ if (_kse_in_critical() || THR_IN_CRITICAL(curthread) || curthread->state != PS_RUNNING) { DBG_MSG(">>> _thr_sig_handler(%d) in critical\n", sig); curthread->siginfo[sig-1] = *info; curthread->check_pending = 1; curkse->k_sigseqno++; SIGADDSET(curthread->sigpend, sig); /* * If the kse is on the way to idle itself, but * we have signal ready, we should prevent it * to sleep, kernel will latch the wakeup request, * so kse_release will return from kernel immediately. */ if (KSE_IS_IDLE(curkse)) kse_wakeup(&curkse->k_kcb->kcb_kmbx); errno = err_save; return; } /* Check if the signal requires a dump of thread information: */ if (_thr_dump_enabled() && (sig == SIGINFO)) { /* Dump thread information to file: */ _thread_dump_info(); } /* Check the threads previous state: */ curthread->critical_count++; if (curthread->sigbackout != NULL) curthread->sigbackout((void *)curthread); curthread->critical_count--; thr_sigframe_save(curthread, &psf); THR_ASSERT(!(curthread->sigbackout), "sigbackout was not cleared."); _kse_critical_enter(); /* Get a fresh copy of signal mask */ __sys_sigprocmask(SIG_BLOCK, NULL, &curthread->sigmask); KSE_LOCK_ACQUIRE(curkse, &_thread_signal_lock); sigfunc = _thread_sigact[sig - 1].sa_sigaction; sa_flags = _thread_sigact[sig - 1].sa_flags; if (sa_flags & SA_RESETHAND) { act.sa_handler = SIG_DFL; act.sa_flags = SA_RESTART; SIGEMPTYSET(act.sa_mask); __sys_sigaction(sig, &act, NULL); __sys_sigaction(sig, NULL, &_thread_sigact[sig - 1]); } KSE_LOCK_RELEASE(curkse, &_thread_signal_lock); _kse_critical_leave(&curthread->tcb->tcb_tmbx); /* Now invoke real handler */ if (((__sighandler_t *)sigfunc != SIG_DFL) && ((__sighandler_t *)sigfunc != SIG_IGN) && (sigfunc != (__siginfohandler_t *)_thr_sig_handler)) { if ((sa_flags & SA_SIGINFO) != 0 || info == NULL) (*(sigfunc))(sig, info, ucp); else { ((ohandler)(*sigfunc))( sig, info->si_code, (struct sigcontext *)ucp, info->si_addr, (__sighandler_t *)sigfunc); } } else { if ((__sighandler_t *)sigfunc == SIG_DFL) { if (sigprop(sig) & SA_KILL) { if (_kse_isthreaded()) kse_thr_interrupt(NULL, KSE_INTR_SIGEXIT, sig); else kill(getpid(), sig); } #ifdef NOTYET else if (sigprop(sig) & SA_STOP) kse_thr_interrupt(NULL, KSE_INTR_JOBSTOP, sig); #endif } } _kse_critical_enter(); curthread->sigmask = ucp->uc_sigmask; SIG_CANTMASK(curthread->sigmask); _kse_critical_leave(&curthread->tcb->tcb_tmbx); thr_sigframe_restore(curthread, &psf); DBG_MSG("<<< _thr_sig_handler(%d)\n", sig); errno = err_save; } struct sighandle_info { __siginfohandler_t *sigfunc; int sa_flags; int sig; siginfo_t *info; ucontext_t *ucp; }; static void handle_signal(struct pthread *curthread, struct sighandle_info *shi); static void handle_signal_altstack(struct pthread *curthread, struct sighandle_info *shi); /* Must be called with signal lock and schedule lock held in order */ static void thr_sig_invoke_handler(struct pthread *curthread, int sig, siginfo_t *info, ucontext_t *ucp) { __siginfohandler_t *sigfunc; sigset_t sigmask; int sa_flags; int onstack; struct sigaction act; struct kse *curkse; struct sighandle_info shi; /* * Invoke the signal handler without going through the scheduler: */ DBG_MSG("Got signal %d, calling handler for current thread %p\n", sig, curthread); if (!_kse_in_critical()) PANIC("thr_sig_invoke_handler without in critical\n"); curkse = curthread->kse; /* * Check that a custom handler is installed and if * the signal is not blocked: */ sigfunc = _thread_sigact[sig - 1].sa_sigaction; sa_flags = _thread_sigact[sig - 1].sa_flags; sigmask = curthread->sigmask; SIGSETOR(curthread->sigmask, _thread_sigact[sig - 1].sa_mask); if (!(sa_flags & (SA_NODEFER | SA_RESETHAND))) SIGADDSET(curthread->sigmask, sig); if ((sig != SIGILL) && (sa_flags & SA_RESETHAND)) { act.sa_handler = SIG_DFL; act.sa_flags = SA_RESTART; SIGEMPTYSET(act.sa_mask); __sys_sigaction(sig, &act, NULL); __sys_sigaction(sig, NULL, &_thread_sigact[sig - 1]); } KSE_LOCK_RELEASE(curkse, &_thread_signal_lock); KSE_SCHED_UNLOCK(curkse, curkse->k_kseg); /* * We are processing buffered signals, synchronize working * signal mask into kernel. */ if (curthread->attr.flags & PTHREAD_SCOPE_SYSTEM) __sys_sigprocmask(SIG_SETMASK, &curthread->sigmask, NULL); onstack = _thr_sigonstack(&sigfunc); ucp->uc_stack = curthread->sigstk; ucp->uc_stack.ss_flags = (curthread->sigstk.ss_flags & SS_DISABLE) ? SS_DISABLE : ((onstack) ? SS_ONSTACK : 0); if (curthread->oldsigmask) { ucp->uc_sigmask = *(curthread->oldsigmask); curthread->oldsigmask = NULL; } else ucp->uc_sigmask = sigmask; shi.sigfunc = sigfunc; shi.sig = sig; shi.sa_flags = sa_flags; shi.info = info; shi.ucp = ucp; if ((curthread->sigstk.ss_flags & SS_DISABLE) == 0) { /* Deliver signal on alternative stack */ if (sa_flags & SA_ONSTACK && !onstack) handle_signal_altstack(curthread, &shi); else handle_signal(curthread, &shi); } else { handle_signal(curthread, &shi); } _kse_critical_enter(); /* Don't trust after critical leave/enter */ curkse = curthread->kse; /* * Restore the thread's signal mask. */ curthread->sigmask = ucp->uc_sigmask; SIG_CANTMASK(curthread->sigmask); if (curthread->attr.flags & PTHREAD_SCOPE_SYSTEM) __sys_sigprocmask(SIG_SETMASK, &ucp->uc_sigmask, NULL); KSE_SCHED_LOCK(curkse, curkse->k_kseg); KSE_LOCK_ACQUIRE(curkse, &_thread_signal_lock); DBG_MSG("Got signal %d, handler returned %p\n", sig, curthread); } static void handle_signal(struct pthread *curthread, struct sighandle_info *shi) { _kse_critical_leave(&curthread->tcb->tcb_tmbx); /* Check if the signal requires a dump of thread information: */ if (_thr_dump_enabled() && (shi->sig == SIGINFO)) { /* Dump thread information to file: */ _thread_dump_info(); } if (((__sighandler_t *)shi->sigfunc != SIG_DFL) && ((__sighandler_t *)shi->sigfunc != SIG_IGN)) { if ((shi->sa_flags & SA_SIGINFO) != 0 || shi->info == NULL) (*(shi->sigfunc))(shi->sig, shi->info, shi->ucp); else { ((ohandler)(*shi->sigfunc))( shi->sig, shi->info->si_code, (struct sigcontext *)shi->ucp, shi->info->si_addr, (__sighandler_t *)shi->sigfunc); } } else { if ((__sighandler_t *)shi->sigfunc == SIG_DFL) { if (sigprop(shi->sig) & SA_KILL) { if (_kse_isthreaded()) kse_thr_interrupt(NULL, KSE_INTR_SIGEXIT, shi->sig); else kill(getpid(), shi->sig); } #ifdef NOTYET else if (sigprop(shi->sig) & SA_STOP) kse_thr_interrupt(NULL, KSE_INTR_JOBSTOP, shi->sig); #endif } } } static void handle_signal_wrapper(struct pthread *curthread, ucontext_t *ret_uc, struct sighandle_info *shi) { shi->ucp->uc_stack.ss_flags = SS_ONSTACK; handle_signal(curthread, shi); if (curthread->attr.flags & PTHREAD_SCOPE_SYSTEM) setcontext(ret_uc); else { /* Work around for ia64, THR_SETCONTEXT does not work */ _kse_critical_enter(); curthread->tcb->tcb_tmbx.tm_context = *ret_uc; _thread_switch(curthread->kse->k_kcb, curthread->tcb, 1); /* THR_SETCONTEXT */ } } /* * Jump to stack set by sigaltstack before invoking signal handler */ static void handle_signal_altstack(struct pthread *curthread, struct sighandle_info *shi) { volatile int once; ucontext_t uc1, *uc2; THR_ASSERT(_kse_in_critical(), "Not in critical"); once = 0; THR_GETCONTEXT(&uc1); if (once == 0) { once = 1; /* XXX * We are still in critical region, it is safe to operate thread * context */ uc2 = &curthread->tcb->tcb_tmbx.tm_context; uc2->uc_stack = curthread->sigstk; makecontext(uc2, (void (*)(void))handle_signal_wrapper, 3, curthread, &uc1, shi); if (curthread->attr.flags & PTHREAD_SCOPE_SYSTEM) setcontext(uc2); else { _thread_switch(curthread->kse->k_kcb, curthread->tcb, 1); /* THR_SETCONTEXT(uc2); */ } } } int _thr_getprocsig(int sig, siginfo_t *siginfo) { kse_critical_t crit; struct kse *curkse; int ret; DBG_MSG(">>> _thr_getprocsig\n"); crit = _kse_critical_enter(); curkse = _get_curkse(); KSE_LOCK_ACQUIRE(curkse, &_thread_signal_lock); ret = _thr_getprocsig_unlocked(sig, siginfo); KSE_LOCK_RELEASE(curkse, &_thread_signal_lock); _kse_critical_leave(crit); DBG_MSG("<<< _thr_getprocsig\n"); return (ret); } int _thr_getprocsig_unlocked(int sig, siginfo_t *siginfo) { sigset_t sigset; struct timespec ts; /* try to retrieve signal from kernel */ SIGEMPTYSET(sigset); SIGADDSET(sigset, sig); ts.tv_sec = 0; ts.tv_nsec = 0; SIGDELSET(_thr_proc_sigpending, sig); if (__sys_sigtimedwait(&sigset, siginfo, &ts) > 0) return (sig); return (0); } #ifndef SYSTEM_SCOPE_ONLY /* * Find a thread that can handle the signal. This must be called * with upcalls disabled. */ struct pthread * thr_sig_find(struct kse *curkse, int sig, siginfo_t *info __unused) { struct kse_mailbox *kmbx = NULL; struct pthread *pthread; struct pthread *suspended_thread, *signaled_thread; __siginfohandler_t *sigfunc; siginfo_t si; DBG_MSG("Looking for thread to handle signal %d\n", sig); /* * Enter a loop to look for threads that have the signal * unmasked. POSIX specifies that a thread in a sigwait * will get the signal over any other threads. Second * preference will be threads in a sigsuspend. Third * preference will be the current thread. If none of the * above, then the signal is delivered to the first thread * that is found. Note that if a custom handler is not * installed, the signal only affects threads in sigwait. */ suspended_thread = NULL; signaled_thread = NULL; KSE_LOCK_ACQUIRE(curkse, &_thread_list_lock); TAILQ_FOREACH(pthread, &_thread_list, tle) { if (pthread == _thr_sig_daemon) continue; /* Signal delivering to bound thread is done by kernel */ if (pthread->attr.flags & PTHREAD_SCOPE_SYSTEM) continue; /* Take the scheduling lock. */ KSE_SCHED_LOCK(curkse, pthread->kseg); if ((pthread->state == PS_DEAD) || (pthread->state == PS_DEADLOCK) || THR_IS_EXITING(pthread) || THR_IS_SUSPENDED(pthread)) { ; /* Skip this thread. */ } else if (pthread->state == PS_SIGWAIT && SIGISMEMBER(*(pthread->data.sigwait->waitset), sig)) { /* * retrieve signal from kernel, if it is job control * signal, and sigaction is SIG_DFL, then we will * be stopped in kernel, we hold lock here, but that * does not matter, because that's job control, and * whole process should be stopped. */ if (_thr_getprocsig(sig, &si)) { DBG_MSG("Waking thread %p in sigwait" " with signal %d\n", pthread, sig); /* where to put siginfo ? */ *(pthread->data.sigwait->siginfo) = si; kmbx = _thr_setrunnable_unlocked(pthread); } KSE_SCHED_UNLOCK(curkse, pthread->kseg); /* * POSIX doesn't doesn't specify which thread * will get the signal if there are multiple * waiters, so we give it to the first thread * we find. * * Do not attempt to deliver this signal * to other threads and do not add the signal * to the process pending set. */ KSE_LOCK_RELEASE(curkse, &_thread_list_lock); if (kmbx != NULL) kse_wakeup(kmbx); if (suspended_thread != NULL) _thr_ref_delete(NULL, suspended_thread); if (signaled_thread != NULL) _thr_ref_delete(NULL, signaled_thread); return (NULL); } else if (!SIGISMEMBER(pthread->sigmask, sig)) { /* * If debugger is running, we don't quick exit, * and give it a chance to check the signal. */ if (_libkse_debug == 0) { sigfunc = _thread_sigact[sig - 1].sa_sigaction; if ((__sighandler_t *)sigfunc == SIG_DFL) { if (sigprop(sig) & SA_KILL) { kse_thr_interrupt(NULL, KSE_INTR_SIGEXIT, sig); /* Never reach */ } } } if (pthread->state == PS_SIGSUSPEND) { if (suspended_thread == NULL) { suspended_thread = pthread; suspended_thread->refcount++; } } else if (signaled_thread == NULL) { signaled_thread = pthread; signaled_thread->refcount++; } } KSE_SCHED_UNLOCK(curkse, pthread->kseg); } KSE_LOCK_RELEASE(curkse, &_thread_list_lock); if (suspended_thread != NULL) { pthread = suspended_thread; if (signaled_thread) _thr_ref_delete(NULL, signaled_thread); } else if (signaled_thread) { pthread = signaled_thread; } else { pthread = NULL; } return (pthread); } #endif /* ! SYSTEM_SCOPE_ONLY */ static inline void build_siginfo(siginfo_t *info, int signo) { bzero(info, sizeof(*info)); info->si_signo = signo; info->si_pid = _thr_pid; } /* * This is called by a thread when it has pending signals to deliver. * It should only be called from the context of the thread. */ void _thr_sig_rundown(struct pthread *curthread, ucontext_t *ucp) { struct pthread_sigframe psf; siginfo_t siginfo; int i, err_save; kse_critical_t crit; struct kse *curkse; sigset_t sigmask; err_save = errno; DBG_MSG(">>> thr_sig_rundown (%p)\n", curthread); /* Check the threads previous state: */ curthread->critical_count++; if (curthread->sigbackout != NULL) curthread->sigbackout((void *)curthread); curthread->critical_count--; THR_ASSERT(!(curthread->sigbackout), "sigbackout was not cleared."); THR_ASSERT((curthread->state == PS_RUNNING), "state is not PS_RUNNING"); thr_sigframe_save(curthread, &psf); /* * Lower the priority before calling the handler in case * it never returns (longjmps back): */ crit = _kse_critical_enter(); curkse = curthread->kse; KSE_SCHED_LOCK(curkse, curkse->k_kseg); KSE_LOCK_ACQUIRE(curkse, &_thread_signal_lock); curthread->active_priority &= ~THR_SIGNAL_PRIORITY; SIGFILLSET(sigmask); while (1) { /* * For bound thread, we mask all signals and get a fresh * copy of signal mask from kernel */ if (curthread->attr.flags & PTHREAD_SCOPE_SYSTEM) { __sys_sigprocmask(SIG_SETMASK, &sigmask, &curthread->sigmask); } for (i = 1; i <= _SIG_MAXSIG; i++) { if (SIGISMEMBER(curthread->sigmask, i)) continue; if (SIGISMEMBER(curthread->sigpend, i)) { SIGDELSET(curthread->sigpend, i); siginfo = curthread->siginfo[i-1]; break; } if (!(curthread->attr.flags & PTHREAD_SCOPE_SYSTEM) && SIGISMEMBER(_thr_proc_sigpending, i)) { if (_thr_getprocsig_unlocked(i, &siginfo)) break; } } if (i <= _SIG_MAXSIG) thr_sig_invoke_handler(curthread, i, &siginfo, ucp); else { if (curthread->attr.flags & PTHREAD_SCOPE_SYSTEM) { __sys_sigprocmask(SIG_SETMASK, &curthread->sigmask, NULL); } break; } } /* Don't trust after signal handling */ curkse = curthread->kse; KSE_LOCK_RELEASE(curkse, &_thread_signal_lock); KSE_SCHED_UNLOCK(curkse, curkse->k_kseg); _kse_critical_leave(&curthread->tcb->tcb_tmbx); /* repost masked signal to kernel, it hardly happens in real world */ if ((curthread->attr.flags & PTHREAD_SCOPE_SYSTEM) && !SIGISEMPTY(curthread->sigpend)) { /* dirty read */ __sys_sigprocmask(SIG_SETMASK, &sigmask, &curthread->sigmask); for (i = 1; i <= _SIG_MAXSIG; ++i) { if (SIGISMEMBER(curthread->sigpend, i)) { SIGDELSET(curthread->sigpend, i); if (!_kse_isthreaded()) kill(getpid(), i); else kse_thr_interrupt( &curthread->tcb->tcb_tmbx, KSE_INTR_SENDSIG, i); } } __sys_sigprocmask(SIG_SETMASK, &curthread->sigmask, NULL); } DBG_MSG("<<< thr_sig_rundown (%p)\n", curthread); thr_sigframe_restore(curthread, &psf); errno = err_save; } /* * This checks pending signals for the current thread. It should be * called whenever a thread changes its signal mask. Note that this * is called from a thread (using its stack). * * XXX - We might want to just check to see if there are pending * signals for the thread here, but enter the UTS scheduler * to actually install the signal handler(s). */ void _thr_sig_check_pending(struct pthread *curthread) { ucontext_t uc; volatile int once; int errsave; /* * If the thread is in critical region, delay processing signals. * If the thread state is not PS_RUNNING, it might be switching * into UTS and but a THR_LOCK_RELEASE saw check_pending, and it * goes here, in the case we delay processing signals, lets UTS * process complicated things, normally UTS will call _thr_sig_add * to resume the thread, so we needn't repeat doing it here. */ if (THR_IN_CRITICAL(curthread) || curthread->state != PS_RUNNING) return; errsave = errno; once = 0; THR_GETCONTEXT(&uc); if (once == 0) { once = 1; curthread->check_pending = 0; _thr_sig_rundown(curthread, &uc); } errno = errsave; } /* * Perform thread specific actions in response to a signal. * This function is only called if there is a handler installed * for the signal, and if the target thread has the signal * unmasked. * * This must be called with the thread's scheduling lock held. */ struct kse_mailbox * _thr_sig_add(struct pthread *pthread, int sig, siginfo_t *info) { siginfo_t siginfo; struct kse *curkse; struct kse_mailbox *kmbx = NULL; struct pthread *curthread = _get_curthread(); int restart; int suppress_handler = 0; int fromproc = 0; __sighandler_t *sigfunc; DBG_MSG(">>> _thr_sig_add %p (%d)\n", pthread, sig); curkse = _get_curkse(); restart = _thread_sigact[sig - 1].sa_flags & SA_RESTART; sigfunc = _thread_sigact[sig - 1].sa_handler; fromproc = (curthread == _thr_sig_daemon); if (pthread->state == PS_DEAD || pthread->state == PS_DEADLOCK || pthread->state == PS_STATE_MAX) return (NULL); /* return false */ if ((pthread->attr.flags & PTHREAD_SCOPE_SYSTEM) && (curthread != pthread)) { PANIC("Please use _thr_send_sig for bound thread"); return (NULL); } if (pthread->state != PS_SIGWAIT && SIGISMEMBER(pthread->sigmask, sig)) { /* signal is masked, just add signal to thread. */ if (!fromproc) { SIGADDSET(pthread->sigpend, sig); if (info == NULL) build_siginfo(&pthread->siginfo[sig-1], sig); else if (info != &pthread->siginfo[sig-1]) memcpy(&pthread->siginfo[sig-1], info, sizeof(*info)); } else { if (!_thr_getprocsig(sig, &pthread->siginfo[sig-1])) return (NULL); SIGADDSET(pthread->sigpend, sig); } } else { /* if process signal not exists, just return */ if (fromproc) { if (!_thr_getprocsig(sig, &siginfo)) return (NULL); info = &siginfo; } if (pthread->state != PS_SIGWAIT && sigfunc == SIG_DFL && (sigprop(sig) & SA_KILL)) { kse_thr_interrupt(NULL, KSE_INTR_SIGEXIT, sig); /* Never reach */ } /* * Process according to thread state: */ switch (pthread->state) { case PS_DEAD: case PS_DEADLOCK: case PS_STATE_MAX: return (NULL); /* XXX return false */ case PS_LOCKWAIT: case PS_SUSPENDED: /* * You can't call a signal handler for threads in these * states. */ suppress_handler = 1; break; case PS_RUNNING: if ((pthread->flags & THR_FLAGS_IN_RUNQ)) { THR_RUNQ_REMOVE(pthread); pthread->active_priority |= THR_SIGNAL_PRIORITY; THR_RUNQ_INSERT_TAIL(pthread); } else { /* Possible not in RUNQ and has curframe ? */ pthread->active_priority |= THR_SIGNAL_PRIORITY; } break; /* * States which cannot be interrupted but still require the * signal handler to run: */ case PS_COND_WAIT: case PS_MUTEX_WAIT: break; case PS_SLEEP_WAIT: /* * Unmasked signals always cause sleep to terminate * early regardless of SA_RESTART: */ pthread->interrupted = 1; break; case PS_JOIN: break; case PS_SIGSUSPEND: pthread->interrupted = 1; break; case PS_SIGWAIT: if (info == NULL) build_siginfo(&pthread->siginfo[sig-1], sig); else if (info != &pthread->siginfo[sig-1]) memcpy(&pthread->siginfo[sig-1], info, sizeof(*info)); /* * The signal handler is not called for threads in * SIGWAIT. */ suppress_handler = 1; /* Wake up the thread if the signal is not blocked. */ if (SIGISMEMBER(*(pthread->data.sigwait->waitset), sig)) { /* Return the signal number: */ *(pthread->data.sigwait->siginfo) = pthread->siginfo[sig-1]; /* Make the thread runnable: */ kmbx = _thr_setrunnable_unlocked(pthread); } else { /* Increment the pending signal count. */ SIGADDSET(pthread->sigpend, sig); if (!SIGISMEMBER(pthread->sigmask, sig)) { if (sigfunc == SIG_DFL && sigprop(sig) & SA_KILL) { kse_thr_interrupt(NULL, KSE_INTR_SIGEXIT, sig); /* Never reach */ } pthread->check_pending = 1; pthread->interrupted = 1; kmbx = _thr_setrunnable_unlocked(pthread); } } return (kmbx); } SIGADDSET(pthread->sigpend, sig); if (info == NULL) build_siginfo(&pthread->siginfo[sig-1], sig); else if (info != &pthread->siginfo[sig-1]) memcpy(&pthread->siginfo[sig-1], info, sizeof(*info)); pthread->check_pending = 1; if (!(pthread->attr.flags & PTHREAD_SCOPE_SYSTEM) && (pthread->blocked != 0) && !THR_IN_CRITICAL(pthread)) kse_thr_interrupt(&pthread->tcb->tcb_tmbx, restart ? KSE_INTR_RESTART : KSE_INTR_INTERRUPT, 0); if (suppress_handler == 0) { /* * Setup a signal frame and save the current threads * state: */ if (pthread->state != PS_RUNNING) { if (pthread->flags & THR_FLAGS_IN_RUNQ) THR_RUNQ_REMOVE(pthread); pthread->active_priority |= THR_SIGNAL_PRIORITY; kmbx = _thr_setrunnable_unlocked(pthread); } } } return (kmbx); } /* * Send a signal to a specific thread (ala pthread_kill): */ void _thr_sig_send(struct pthread *pthread, int sig) { struct pthread *curthread = _get_curthread(); struct kse_mailbox *kmbx; if (pthread->attr.flags & PTHREAD_SCOPE_SYSTEM) { kse_thr_interrupt(&pthread->tcb->tcb_tmbx, KSE_INTR_SENDSIG, sig); return; } /* Lock the scheduling queue of the target thread. */ THR_SCHED_LOCK(curthread, pthread); if (_thread_sigact[sig - 1].sa_handler != SIG_IGN) { kmbx = _thr_sig_add(pthread, sig, NULL); /* Add a preemption point. */ if (kmbx == NULL && (curthread->kseg == pthread->kseg) && (pthread->active_priority > curthread->active_priority)) curthread->critical_yield = 1; THR_SCHED_UNLOCK(curthread, pthread); if (kmbx != NULL) kse_wakeup(kmbx); /* XXX * If thread sent signal to itself, check signals now. * It is not really needed, _kse_critical_leave should * have already checked signals. */ if (pthread == curthread && curthread->check_pending) _thr_sig_check_pending(curthread); } else { THR_SCHED_UNLOCK(curthread, pthread); } } static inline void thr_sigframe_restore(struct pthread *curthread, struct pthread_sigframe *psf) { kse_critical_t crit; struct kse *curkse; THR_THREAD_LOCK(curthread, curthread); curthread->cancelflags = psf->psf_cancelflags; crit = _kse_critical_enter(); curkse = curthread->kse; KSE_SCHED_LOCK(curkse, curthread->kseg); curthread->flags = psf->psf_flags; curthread->interrupted = psf->psf_interrupted; curthread->timeout = psf->psf_timeout; curthread->data = psf->psf_wait_data; curthread->wakeup_time = psf->psf_wakeup_time; curthread->continuation = psf->psf_continuation; KSE_SCHED_UNLOCK(curkse, curthread->kseg); _kse_critical_leave(crit); THR_THREAD_UNLOCK(curthread, curthread); } static inline void thr_sigframe_save(struct pthread *curthread, struct pthread_sigframe *psf) { kse_critical_t crit; struct kse *curkse; THR_THREAD_LOCK(curthread, curthread); psf->psf_cancelflags = curthread->cancelflags; crit = _kse_critical_enter(); curkse = curthread->kse; KSE_SCHED_LOCK(curkse, curthread->kseg); /* This has to initialize all members of the sigframe. */ psf->psf_flags = (curthread->flags & (THR_FLAGS_PRIVATE | THR_FLAGS_EXITING)); psf->psf_interrupted = curthread->interrupted; psf->psf_timeout = curthread->timeout; psf->psf_wait_data = curthread->data; psf->psf_wakeup_time = curthread->wakeup_time; psf->psf_continuation = curthread->continuation; KSE_SCHED_UNLOCK(curkse, curthread->kseg); _kse_critical_leave(crit); THR_THREAD_UNLOCK(curthread, curthread); } void _thr_signal_init(void) { struct sigaction act; __siginfohandler_t *sigfunc; int i; sigset_t sigset; SIGFILLSET(sigset); __sys_sigprocmask(SIG_SETMASK, &sigset, &_thr_initial->sigmask); /* Enter a loop to get the existing signal status: */ for (i = 1; i <= _SIG_MAXSIG; i++) { /* Get the signal handler details: */ if (__sys_sigaction(i, NULL, &_thread_sigact[i - 1]) != 0) { /* * Abort this process if signal * initialisation fails: */ PANIC("Cannot read signal handler info"); } /* Intall wrapper if handler was set */ sigfunc = _thread_sigact[i - 1].sa_sigaction; if (((__sighandler_t *)sigfunc) != SIG_DFL && ((__sighandler_t *)sigfunc) != SIG_IGN) { act = _thread_sigact[i - 1]; act.sa_flags |= SA_SIGINFO; act.sa_sigaction = (__siginfohandler_t *)_thr_sig_handler; __sys_sigaction(i, &act, NULL); } } if (_thr_dump_enabled()) { /* * Install the signal handler for SIGINFO. It isn't * really needed, but it is nice to have for debugging * purposes. */ _thread_sigact[SIGINFO - 1].sa_flags = SA_SIGINFO | SA_RESTART; SIGEMPTYSET(act.sa_mask); act.sa_flags = SA_SIGINFO | SA_RESTART; act.sa_sigaction = (__siginfohandler_t *)&_thr_sig_handler; if (__sys_sigaction(SIGINFO, &act, NULL) != 0) { __sys_sigprocmask(SIG_SETMASK, &_thr_initial->sigmask, NULL); /* * Abort this process if signal initialisation fails: */ PANIC("Cannot initialize signal handler"); } } __sys_sigprocmask(SIG_SETMASK, &_thr_initial->sigmask, NULL); __sys_sigaltstack(NULL, &_thr_initial->sigstk); } void _thr_signal_deinit(void) { int i; struct pthread *curthread = _get_curthread(); /* Clear process pending signals. */ sigemptyset(&_thr_proc_sigpending); /* Enter a loop to get the existing signal status: */ for (i = 1; i <= _SIG_MAXSIG; i++) { /* Check for signals which cannot be trapped: */ if (i == SIGKILL || i == SIGSTOP) { } /* Set the signal handler details: */ else if (__sys_sigaction(i, &_thread_sigact[i - 1], NULL) != 0) { /* * Abort this process if signal * initialisation fails: */ PANIC("Cannot set signal handler info"); } } __sys_sigaltstack(&curthread->sigstk, NULL); }