/* * ntp_timer.c - event timer support routines */ #ifdef HAVE_CONFIG_H # include #endif #include "ntp_machine.h" #include "ntpd.h" #include "ntp_stdlib.h" #include "ntp_calendar.h" #include "ntp_leapsec.h" #if defined(HAVE_IO_COMPLETION_PORT) # include "ntp_iocompletionport.h" # include "ntp_timer.h" #endif #include #include #ifdef HAVE_SYS_SIGNAL_H # include #endif #ifdef HAVE_UNISTD_H # include #endif #ifdef KERNEL_PLL #include "ntp_syscall.h" #endif /* KERNEL_PLL */ #ifdef AUTOKEY #include #endif /* AUTOKEY */ /* TC_ERR represents the timer_create() error return value. */ #ifdef SYS_VXWORKS #define TC_ERR ERROR #else #define TC_ERR (-1) #endif static void check_leapsec(u_int32, const time_t*, int/*BOOL*/); /* * These routines provide support for the event timer. The timer is * implemented by an interrupt routine which sets a flag once every * second, and a timer routine which is called when the mainline code * gets around to seeing the flag. The timer routine dispatches the * clock adjustment code if its time has come, then searches the timer * queue for expiries which are dispatched to the transmit procedure. * Finally, we call the hourly procedure to do cleanup and print a * message. */ volatile int interface_interval; /* init_io() sets def. 300s */ /* * Initializing flag. All async routines watch this and only do their * thing when it is clear. */ int initializing; /* * Alarm flag. The mainline code imports this. */ volatile int alarm_flag; /* * The counters and timeouts */ static u_long interface_timer; /* interface update timer */ static u_long adjust_timer; /* second timer */ static u_long stats_timer; /* stats timer */ static u_long leapf_timer; /* Report leapfile problems once/day */ static u_long huffpuff_timer; /* huff-n'-puff timer */ static u_long worker_idle_timer;/* next check for idle intres */ u_long leapsec; /* seconds to next leap (proximity class) */ int leapdif; /* TAI difference step at next leap second*/ u_long orphwait; /* orphan wait time */ #ifdef AUTOKEY static u_long revoke_timer; /* keys revoke timer */ static u_long keys_timer; /* session key timer */ u_long sys_revoke = KEY_REVOKE; /* keys revoke timeout (log2 s) */ u_long sys_automax = NTP_AUTOMAX; /* key list timeout (log2 s) */ #endif /* AUTOKEY */ /* * Statistics counter for the interested. */ volatile u_long alarm_overflow; u_long current_time; /* seconds since startup */ /* * Stats. Number of overflows and number of calls to transmit(). */ u_long timer_timereset; u_long timer_overflows; u_long timer_xmtcalls; #if defined(VMS) static int vmstimer[2]; /* time for next timer AST */ static int vmsinc[2]; /* timer increment */ #endif /* VMS */ #ifdef SYS_WINNT HANDLE WaitableTimerHandle; #else static RETSIGTYPE alarming (int); #endif /* SYS_WINNT */ #if !defined(VMS) # if !defined SYS_WINNT || defined(SYS_CYGWIN32) # ifdef HAVE_TIMER_CREATE static timer_t timer_id; typedef struct itimerspec intervaltimer; # define itv_frac tv_nsec # else typedef struct itimerval intervaltimer; # define itv_frac tv_usec # endif intervaltimer itimer; # endif #endif #if !defined(SYS_WINNT) && !defined(VMS) void set_timer_or_die(const intervaltimer *); #endif #if !defined(SYS_WINNT) && !defined(VMS) void set_timer_or_die( const intervaltimer * ptimer ) { const char * setfunc; int rc; # ifdef HAVE_TIMER_CREATE setfunc = "timer_settime"; rc = timer_settime(timer_id, 0, &itimer, NULL); # else setfunc = "setitimer"; rc = setitimer(ITIMER_REAL, &itimer, NULL); # endif if (-1 == rc) { msyslog(LOG_ERR, "interval timer %s failed, %m", setfunc); exit(1); } } #endif /* !SYS_WINNT && !VMS */ /* * reinit_timer - reinitialize interval timer after a clock step. */ void reinit_timer(void) { #if !defined(SYS_WINNT) && !defined(VMS) ZERO(itimer); # ifdef HAVE_TIMER_CREATE timer_gettime(timer_id, &itimer); # else getitimer(ITIMER_REAL, &itimer); # endif if (itimer.it_value.tv_sec < 0 || itimer.it_value.tv_sec > (1 << EVENT_TIMEOUT)) itimer.it_value.tv_sec = (1 << EVENT_TIMEOUT); if (itimer.it_value.itv_frac < 0) itimer.it_value.itv_frac = 0; if (0 == itimer.it_value.tv_sec && 0 == itimer.it_value.itv_frac) itimer.it_value.tv_sec = (1 << EVENT_TIMEOUT); itimer.it_interval.tv_sec = (1 << EVENT_TIMEOUT); itimer.it_interval.itv_frac = 0; set_timer_or_die(&itimer); # endif /* VMS */ } /* * init_timer - initialize the timer data structures */ void init_timer(void) { /* * Initialize... */ alarm_flag = FALSE; alarm_overflow = 0; adjust_timer = 1; stats_timer = SECSPERHR; leapf_timer = SECSPERDAY; huffpuff_timer = 0; interface_timer = 0; current_time = 0; timer_overflows = 0; timer_xmtcalls = 0; timer_timereset = 0; #ifndef SYS_WINNT /* * Set up the alarm interrupt. The first comes 2**EVENT_TIMEOUT * seconds from now and they continue on every 2**EVENT_TIMEOUT * seconds. */ # ifndef VMS # ifdef HAVE_TIMER_CREATE if (TC_ERR == timer_create(CLOCK_REALTIME, NULL, &timer_id)) { msyslog(LOG_ERR, "timer_create failed, %m"); exit(1); } # endif signal_no_reset(SIGALRM, alarming); itimer.it_interval.tv_sec = itimer.it_value.tv_sec = (1 << EVENT_TIMEOUT); itimer.it_interval.itv_frac = itimer.it_value.itv_frac = 0; set_timer_or_die(&itimer); # else /* VMS follows */ vmsinc[0] = 10000000; /* 1 sec */ vmsinc[1] = 0; lib$emul(&(1<p_link; if (FLAG_REFCLOCK & p->flags) refclock_timer(p); } #endif /* REFCLOCK */ } /* * Now dispatch any peers whose event timer has expired. Be * careful here, since the peer structure might go away as the * result of the call. */ for (p = peer_list; p != NULL; p = next_peer) { next_peer = p->p_link; /* * Restrain the non-burst packet rate not more * than one packet every 16 seconds. This is * usually tripped using iburst and minpoll of * 128 s or less. */ if (p->throttle > 0) p->throttle--; if (p->nextdate <= current_time) { #ifdef REFCLOCK if (FLAG_REFCLOCK & p->flags) refclock_transmit(p); else #endif /* REFCLOCK */ transmit(p); } } /* * Orphan mode is active when enabled and when no servers less * than the orphan stratum are available. A server with no other * synchronization source is an orphan. It shows offset zero and * reference ID the loopback address. */ if (sys_orphan < STRATUM_UNSPEC && sys_peer == NULL && current_time > orphwait) { if (sys_leap == LEAP_NOTINSYNC) { set_sys_leap(LEAP_NOWARNING); #ifdef AUTOKEY if (crypto_flags) crypto_update(); #endif /* AUTOKEY */ } sys_stratum = (u_char)sys_orphan; if (sys_stratum > 1) sys_refid = htonl(LOOPBACKADR); else memcpy(&sys_refid, "LOOP", 4); sys_offset = 0; sys_rootdelay = 0; sys_rootdisp = 0; } get_systime(&now); time(&tnow); /* * Leapseconds. Get time and defer to worker if either something * is imminent or every 8th second. */ if (leapsec > LSPROX_NOWARN || 0 == (current_time & 7)) check_leapsec(now.l_ui, &tnow, (sys_leap == LEAP_NOTINSYNC)); if (sys_leap != LEAP_NOTINSYNC) { if (leapsec >= LSPROX_ANNOUNCE && leapdif) { if (leapdif > 0) set_sys_leap(LEAP_ADDSECOND); else set_sys_leap(LEAP_DELSECOND); } else { set_sys_leap(LEAP_NOWARNING); } } /* * Update huff-n'-puff filter. */ if (huffpuff_timer <= current_time) { huffpuff_timer += HUFFPUFF; huffpuff(); } #ifdef AUTOKEY /* * Garbage collect expired keys. */ if (keys_timer <= current_time) { keys_timer += 1 << sys_automax; auth_agekeys(); } /* * Generate new private value. This causes all associations * to regenerate cookies. */ if (revoke_timer && revoke_timer <= current_time) { revoke_timer += 1 << sys_revoke; RAND_bytes((u_char *)&sys_private, 4); } #endif /* AUTOKEY */ /* * Interface update timer */ if (interface_interval && interface_timer <= current_time) { timer_interfacetimeout(current_time + interface_interval); DPRINTF(2, ("timer: interface update\n")); interface_update(NULL, NULL); } if (worker_idle_timer && worker_idle_timer <= current_time) worker_idle_timer_fired(); /* * Finally, write hourly stats and do the hourly * and daily leapfile checks. */ if (stats_timer <= current_time) { stats_timer += SECSPERHR; write_stats(); if (leapf_timer <= current_time) { leapf_timer += SECSPERDAY; check_leap_file(TRUE, now.l_ui, &tnow); } else { check_leap_file(FALSE, now.l_ui, &tnow); } } } #ifndef SYS_WINNT /* * alarming - tell the world we've been alarmed */ static RETSIGTYPE alarming( int sig ) { # ifdef DEBUG const char *msg = "alarming: initializing TRUE\n"; # endif if (!initializing) { if (alarm_flag) { alarm_overflow++; # ifdef DEBUG msg = "alarming: overflow\n"; # endif } else { # ifndef VMS alarm_flag++; # else /* VMS AST routine, increment is no good */ alarm_flag = 1; # endif # ifdef DEBUG msg = "alarming: normal\n"; # endif } } # ifdef VMS lib$addx(&vmsinc, &vmstimer, &vmstimer); sys$setimr(0, &vmstimer, alarming, alarming, 0); # endif # ifdef DEBUG if (debug >= 4) (void)(-1 == write(1, msg, strlen(msg))); # endif } #endif /* SYS_WINNT */ void timer_interfacetimeout(u_long timeout) { interface_timer = timeout; } /* * timer_clr_stats - clear timer module stat counters */ void timer_clr_stats(void) { timer_overflows = 0; timer_xmtcalls = 0; timer_timereset = current_time; } static void check_leap_sec_in_progress( const leap_result_t *lsdata ) { int prv_leap_sec_in_progress = leap_sec_in_progress; leap_sec_in_progress = lsdata->tai_diff && (lsdata->ddist < 3); /* if changed we may have to update the leap status sent to clients */ if (leap_sec_in_progress != prv_leap_sec_in_progress) set_sys_leap(sys_leap); } static void check_leapsec( u_int32 now , const time_t * tpiv , int/*BOOL*/ reset) { static const char leapmsg_p_step[] = "Positive leap second, stepped backward."; static const char leapmsg_p_slew[] = "Positive leap second, no step correction. " "System clock will be inaccurate for a long time."; static const char leapmsg_n_step[] = "Negative leap second, stepped forward."; static const char leapmsg_n_slew[] = "Negative leap second, no step correction. " "System clock will be inaccurate for a long time."; leap_result_t lsdata; u_int32 lsprox; #ifdef AUTOKEY int/*BOOL*/ update_autokey = FALSE; #endif #ifndef SYS_WINNT /* WinNT port has its own leap second handling */ # ifdef KERNEL_PLL leapsec_electric(pll_control && kern_enable); # else leapsec_electric(0); # endif #endif #ifdef LEAP_SMEAR leap_smear.enabled = leap_smear_intv != 0; #endif if (reset) { lsprox = LSPROX_NOWARN; leapsec_reset_frame(); memset(&lsdata, 0, sizeof(lsdata)); } else { int fired; fired = leapsec_query(&lsdata, now, tpiv); DPRINTF(3, ("*** leapsec_query: fired %i, now %u (0x%08X), tai_diff %i, ddist %u\n", fired, now, now, lsdata.tai_diff, lsdata.ddist)); #ifdef LEAP_SMEAR leap_smear.in_progress = 0; leap_smear.doffset = 0.0; if (leap_smear.enabled) { if (lsdata.tai_diff) { if (leap_smear.interval == 0) { leap_smear.interval = leap_smear_intv; leap_smear.intv_end = lsdata.ttime.Q_s; leap_smear.intv_start = leap_smear.intv_end - leap_smear.interval; DPRINTF(1, ("*** leapsec_query: setting leap_smear interval %li, begin %.0f, end %.0f\n", leap_smear.interval, leap_smear.intv_start, leap_smear.intv_end)); } } else { if (leap_smear.interval) DPRINTF(1, ("*** leapsec_query: clearing leap_smear interval\n")); leap_smear.interval = 0; } if (leap_smear.interval) { double dtemp = now; if (dtemp >= leap_smear.intv_start && dtemp <= leap_smear.intv_end) { double leap_smear_time = dtemp - leap_smear.intv_start; /* * For now we just do a linear interpolation over the smear interval */ #if 0 // linear interpolation leap_smear.doffset = -(leap_smear_time * lsdata.tai_diff / leap_smear.interval); #else // Google approach: lie(t) = (1.0 - cos(pi * t / w)) / 2.0 leap_smear.doffset = -((double) lsdata.tai_diff - cos( M_PI * leap_smear_time / leap_smear.interval)) / 2.0; #endif /* * TODO see if we're inside an inserted leap second, so we need to compute * leap_smear.doffset = 1.0 - leap_smear.doffset */ leap_smear.in_progress = 1; #if 0 && defined( DEBUG ) msyslog(LOG_NOTICE, "*** leapsec_query: [%.0f:%.0f] (%li), now %u (%.0f), smear offset %.6f ms\n", leap_smear.intv_start, leap_smear.intv_end, leap_smear.interval, now, leap_smear_time, leap_smear.doffset); #else DPRINTF(1, ("*** leapsec_query: [%.0f:%.0f] (%li), now %u (%.0f), smear offset %.6f ms\n", leap_smear.intv_start, leap_smear.intv_end, leap_smear.interval, now, leap_smear_time, leap_smear.doffset)); #endif } } } else leap_smear.interval = 0; /* * Update the current leap smear offset, eventually 0.0 if outside smear interval. */ DTOLFP(leap_smear.doffset, &leap_smear.offset); #endif /* LEAP_SMEAR */ if (fired) { /* Full hit. Eventually step the clock, but always * announce the leap event has happened. */ const char *leapmsg = NULL; double lswarp = lsdata.warped; if (lswarp < 0.0) { if (clock_max_back > 0.0 && clock_max_back < -lswarp) { step_systime(lswarp); leapmsg = leapmsg_p_step; } else { leapmsg = leapmsg_p_slew; } } else if (lswarp > 0.0) { if (clock_max_fwd > 0.0 && clock_max_fwd < lswarp) { step_systime(lswarp); leapmsg = leapmsg_n_step; } else { leapmsg = leapmsg_n_slew; } } if (leapmsg) msyslog(LOG_NOTICE, "%s", leapmsg); report_event(EVNT_LEAP, NULL, NULL); #ifdef AUTOKEY update_autokey = TRUE; #endif lsprox = LSPROX_NOWARN; leapsec = LSPROX_NOWARN; sys_tai = lsdata.tai_offs; } else { #ifdef AUTOKEY update_autokey = (sys_tai != (u_int)lsdata.tai_offs); #endif lsprox = lsdata.proximity; sys_tai = lsdata.tai_offs; } } /* We guard against panic alarming during the red alert phase. * Strange and evil things might happen if we go from stone cold * to piping hot in one step. If things are already that wobbly, * we let the normal clock correction take over, even if a jump * is involved. * Also make sure the alarming events are edge-triggered, that is, * ceated only when the threshold is crossed. */ if ( (leapsec > 0 || lsprox < LSPROX_ALERT) && leapsec < lsprox ) { if ( leapsec < LSPROX_SCHEDULE && lsprox >= LSPROX_SCHEDULE) { if (lsdata.dynamic) report_event(PEVNT_ARMED, sys_peer, NULL); else report_event(EVNT_ARMED, NULL, NULL); } leapsec = lsprox; } if (leapsec > lsprox) { if ( leapsec >= LSPROX_SCHEDULE && lsprox < LSPROX_SCHEDULE) { report_event(EVNT_DISARMED, NULL, NULL); } leapsec = lsprox; } if (leapsec >= LSPROX_SCHEDULE) leapdif = lsdata.tai_diff; else leapdif = 0; check_leap_sec_in_progress(&lsdata); #ifdef AUTOKEY if (update_autokey) crypto_update_taichange(); #endif }