/* Asynchronous timers. Copyright (C) 2000-2013 Free Software Foundation, Inc. This file is part of GNU Emacs. GNU Emacs is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. GNU Emacs is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GNU Emacs. If not, see . */ #include #include #include "lisp.h" #include "syssignal.h" #include "systime.h" #include "blockinput.h" #include "atimer.h" #include /* Free-list of atimer structures. */ static struct atimer *free_atimers; /* List of currently not running timers due to a call to lock_atimer. */ static struct atimer *stopped_atimers; /* List of active atimers, sorted by expiration time. The timer that will become ripe next is always at the front of this list. */ static struct atimer *atimers; /* The alarm timer and whether it was properly initialized, if POSIX timers are available. */ #ifdef HAVE_ITIMERSPEC static timer_t alarm_timer; static bool alarm_timer_ok; #endif /* Block/unblock SIGALRM. */ static void sigmask_atimers (int how) { sigset_t blocked; sigemptyset (&blocked); sigaddset (&blocked, SIGALRM); pthread_sigmask (how, &blocked, 0); } static void block_atimers (void) { sigmask_atimers (SIG_BLOCK); } static void unblock_atimers (void) { sigmask_atimers (SIG_UNBLOCK); } /* Function prototypes. */ static void set_alarm (void); static void schedule_atimer (struct atimer *); static struct atimer *append_atimer_lists (struct atimer *, struct atimer *); /* Start a new atimer of type TYPE. TIME specifies when the timer is ripe. FN is the function to call when the timer fires. CLIENT_DATA is stored in the client_data member of the atimer structure returned and so made available to FN when it is called. If TYPE is ATIMER_ABSOLUTE, TIME is the absolute time at which the timer fires. If TYPE is ATIMER_RELATIVE, the timer is ripe TIME s/us in the future. In both cases, the timer is automatically freed after it has fired. If TYPE is ATIMER_CONTINUOUS, the timer fires every TIME s/us. Value is a pointer to the atimer started. It can be used in calls to cancel_atimer; don't free it yourself. */ struct atimer * start_atimer (enum atimer_type type, EMACS_TIME timestamp, atimer_callback fn, void *client_data) { struct atimer *t; /* Round TIME up to the next full second if we don't have itimers. */ #ifndef HAVE_SETITIMER if (EMACS_NSECS (timestamp) != 0 && EMACS_SECS (timestamp) < TYPE_MAXIMUM (time_t)) timestamp = make_emacs_time (EMACS_SECS (timestamp) + 1, 0); #endif /* not HAVE_SETITIMER */ /* Get an atimer structure from the free-list, or allocate a new one. */ if (free_atimers) { t = free_atimers; free_atimers = t->next; } else t = xmalloc (sizeof *t); /* Fill the atimer structure. */ memset (t, 0, sizeof *t); t->type = type; t->fn = fn; t->client_data = client_data; block_atimers (); /* Compute the timer's expiration time. */ switch (type) { case ATIMER_ABSOLUTE: t->expiration = timestamp; break; case ATIMER_RELATIVE: t->expiration = add_emacs_time (current_emacs_time (), timestamp); break; case ATIMER_CONTINUOUS: t->expiration = add_emacs_time (current_emacs_time (), timestamp); t->interval = timestamp; break; } /* Insert the timer in the list of active atimers. */ schedule_atimer (t); unblock_atimers (); /* Arrange for a SIGALRM at the time the next atimer is ripe. */ set_alarm (); return t; } /* Cancel and free atimer TIMER. */ void cancel_atimer (struct atimer *timer) { int i; block_atimers (); for (i = 0; i < 2; ++i) { struct atimer *t, *prev; struct atimer **list = i ? &stopped_atimers : &atimers; /* See if TIMER is active or stopped. */ for (t = *list, prev = NULL; t && t != timer; prev = t, t = t->next) ; /* If it is, take it off its list, and put in on the free-list. We don't bother to arrange for setting a different alarm time, since a too early one doesn't hurt. */ if (t) { if (prev) prev->next = t->next; else *list = t->next; t->next = free_atimers; free_atimers = t; break; } } unblock_atimers (); } /* Append two lists of atimers LIST_1 and LIST_2 and return the result list. */ static struct atimer * append_atimer_lists (struct atimer *list_1, struct atimer *list_2) { if (list_1 == NULL) return list_2; else if (list_2 == NULL) return list_1; else { struct atimer *p; for (p = list_1; p->next; p = p->next) ; p->next = list_2; return list_1; } } /* Stop all timers except timer T. T null means stop all timers. */ void stop_other_atimers (struct atimer *t) { block_atimers (); if (t) { struct atimer *p, *prev; /* See if T is active. */ for (p = atimers, prev = NULL; p && p != t; prev = p, p = p->next) ; if (p == t) { if (prev) prev->next = t->next; else atimers = t->next; t->next = NULL; } else /* T is not active. Let's handle this like T == 0. */ t = NULL; } stopped_atimers = append_atimer_lists (atimers, stopped_atimers); atimers = t; unblock_atimers (); } /* Run all timers again, if some have been stopped with a call to stop_other_atimers. */ void run_all_atimers (void) { if (stopped_atimers) { struct atimer *t = atimers; struct atimer *next; block_atimers (); atimers = stopped_atimers; stopped_atimers = NULL; while (t) { next = t->next; schedule_atimer (t); t = next; } unblock_atimers (); } } /* Arrange for a SIGALRM to arrive when the next timer is ripe. */ static void set_alarm (void) { if (atimers) { #ifdef HAVE_SETITIMER struct itimerval it; #endif EMACS_TIME now, interval; #ifdef HAVE_ITIMERSPEC if (alarm_timer_ok) { struct itimerspec ispec; ispec.it_value = atimers->expiration; ispec.it_interval.tv_sec = ispec.it_interval.tv_nsec = 0; if (timer_settime (alarm_timer, 0, &ispec, 0) == 0) return; } #endif /* Determine interval till the next timer is ripe. Don't set the interval to 0; this disables the timer. */ now = current_emacs_time (); interval = (EMACS_TIME_LE (atimers->expiration, now) ? make_emacs_time (0, 1000 * 1000) : sub_emacs_time (atimers->expiration, now)); #ifdef HAVE_SETITIMER memset (&it, 0, sizeof it); it.it_value = make_timeval (interval); setitimer (ITIMER_REAL, &it, 0); #else /* not HAVE_SETITIMER */ alarm (max (EMACS_SECS (interval), 1)); #endif /* not HAVE_SETITIMER */ } } /* Insert timer T into the list of active atimers `atimers', keeping the list sorted by expiration time. T must not be in this list already. */ static void schedule_atimer (struct atimer *t) { struct atimer *a = atimers, *prev = NULL; /* Look for the first atimer that is ripe after T. */ while (a && EMACS_TIME_LT (a->expiration, t->expiration)) prev = a, a = a->next; /* Insert T in front of the atimer found, if any. */ if (prev) prev->next = t; else atimers = t; t->next = a; } static void run_timers (void) { EMACS_TIME now = current_emacs_time (); while (atimers && EMACS_TIME_LE (atimers->expiration, now)) { struct atimer *t = atimers; atimers = atimers->next; t->fn (t); if (t->type == ATIMER_CONTINUOUS) { t->expiration = add_emacs_time (now, t->interval); schedule_atimer (t); } else { t->next = free_atimers; free_atimers = t; } } set_alarm (); } /* Signal handler for SIGALRM. SIGNO is the signal number, i.e. SIGALRM. */ static void handle_alarm_signal (int sig) { pending_signals = 1; } /* Do pending timers. */ void do_pending_atimers (void) { if (atimers) { block_atimers (); run_timers (); unblock_atimers (); } } /* Turn alarms on/off. This seems to be temporarily necessary on some systems like HPUX (see process.c). */ void turn_on_atimers (bool on) { if (on) set_alarm (); else alarm (0); } void init_atimer (void) { struct sigaction action; #ifdef HAVE_ITIMERSPEC struct sigevent sigev; sigev.sigev_notify = SIGEV_SIGNAL; sigev.sigev_signo = SIGALRM; sigev.sigev_value.sival_ptr = &alarm_timer; alarm_timer_ok = timer_create (CLOCK_REALTIME, &sigev, &alarm_timer) == 0; #endif free_atimers = stopped_atimers = atimers = NULL; /* pending_signals is initialized in init_keyboard.*/ emacs_sigaction_init (&action, handle_alarm_signal); sigaction (SIGALRM, &action, 0); }