/* * systime -- routines to fiddle a UNIX clock. * * ATTENTION: Get approval from Dave Mills on all changes to this file! * */ #include #include #include "ntp.h" #include "ntpd.h" #include "ntp_syslog.h" #include "ntp_stdlib.h" #include "ntp_random.h" #include "iosignal.h" #include "timevalops.h" #include "timespecops.h" #include "ntp_calendar.h" #include "lib_strbuf.h" #ifdef HAVE_SYS_PARAM_H # include #endif #ifdef HAVE_UTMP_H # include #endif /* HAVE_UTMP_H */ #ifdef HAVE_UTMPX_H # include #endif /* HAVE_UTMPX_H */ int allow_panic = FALSE; /* allow panic correction (-g) */ int enable_panic_check = TRUE; /* Can we check allow_panic's state? */ u_long sys_lamport; /* Lamport violation */ u_long sys_tsrounding; /* timestamp rounding errors */ #ifndef USE_COMPILETIME_PIVOT # define USE_COMPILETIME_PIVOT 1 #endif /* * These routines (get_systime, step_systime, adj_systime) implement an * interface between the system independent NTP clock and the Unix * system clock in various architectures and operating systems. Time is * a precious quantity in these routines and every effort is made to * minimize errors by unbiased rounding and amortizing adjustment * residues. * * In order to improve the apparent resolution, provide unbiased * rounding and most importantly ensure that the readings cannot be * predicted, the low-order unused portion of the time below the minimum * time to read the clock is filled with an unbiased random fuzz. * * The sys_tick variable specifies the system clock tick interval in * seconds, for stepping clocks, defined as those which return times * less than MINSTEP greater than the previous reading. For systems that * use a high-resolution counter such that each clock reading is always * at least MINSTEP greater than the prior, sys_tick is the time to read * the system clock. * * The sys_fuzz variable measures the minimum time to read the system * clock, regardless of its precision. When reading the system clock * using get_systime() after sys_tick and sys_fuzz have been determined, * ntpd ensures each unprocessed clock reading is no less than sys_fuzz * later than the prior unprocessed reading, and then fuzzes the bits * below sys_fuzz in the timestamp returned, ensuring each of its * resulting readings is strictly later than the previous. * * When slewing the system clock using adj_systime() (with the kernel * loop discipline unavailable or disabled), adjtime() offsets are * quantized to sys_tick, if sys_tick is greater than sys_fuzz, which * is to say if the OS presents a stepping clock. Otherwise, offsets * are quantized to the microsecond resolution of adjtime()'s timeval * input. The remaining correction sys_residual is carried into the * next adjtime() and meanwhile is also factored into get_systime() * readings. */ double sys_tick = 0; /* tick size or time to read (s) */ double sys_fuzz = 0; /* min. time to read the clock (s) */ long sys_fuzz_nsec = 0; /* min. time to read the clock (ns) */ double measured_tick; /* non-overridable sys_tick (s) */ double sys_residual = 0; /* adjustment residue (s) */ int trunc_os_clock; /* sys_tick > measured_tick */ time_stepped_callback step_callback; #ifndef SIM /* perlinger@ntp.org: As 'get_sysime()' does it's own check for clock * backstepping, this could probably become a local variable in * 'get_systime()' and the cruft associated with communicating via a * static value could be removed after the v4.2.8 release. */ static int lamport_violated; /* clock was stepped back */ #endif /* !SIM */ #ifdef DEBUG static int systime_init_done; # define DONE_SYSTIME_INIT() systime_init_done = TRUE #else # define DONE_SYSTIME_INIT() do {} while (FALSE) #endif #ifdef HAVE_SIGNALED_IO int using_sigio; #endif #ifdef SYS_WINNT CRITICAL_SECTION get_systime_cs; #endif void set_sys_fuzz( double fuzz_val ) { sys_fuzz = fuzz_val; INSIST(sys_fuzz >= 0); INSIST(sys_fuzz <= 1.0); /* [Bug 3450] ensure nsec fuzz >= sys_fuzz to reduce chance of * short-falling fuzz advance */ sys_fuzz_nsec = (long)ceil(sys_fuzz * 1e9); } void init_systime(void) { INIT_GET_SYSTIME_CRITSEC(); INIT_WIN_PRECISE_TIME(); DONE_SYSTIME_INIT(); } #ifndef SIM /* ntpsim.c has get_systime() and friends for sim */ static inline void get_ostime( struct timespec * tsp ) { int rc; long ticks; #if defined(HAVE_CLOCK_GETTIME) rc = clock_gettime(CLOCK_REALTIME, tsp); #elif defined(HAVE_GETCLOCK) rc = getclock(TIMEOFDAY, tsp); #else struct timeval tv; rc = GETTIMEOFDAY(&tv, NULL); tsp->tv_sec = tv.tv_sec; tsp->tv_nsec = tv.tv_usec * 1000; #endif if (rc < 0) { msyslog(LOG_ERR, "read system clock failed: %m (%d)", errno); exit(1); } if (trunc_os_clock) { ticks = (long)((tsp->tv_nsec * 1e-9) / sys_tick); tsp->tv_nsec = (long)(ticks * 1e9 * sys_tick); } } /* * get_systime - return system time in NTP timestamp format. */ void get_systime( l_fp *now /* system time */ ) { static struct timespec ts_last; /* last sampled os time */ static struct timespec ts_prev; /* prior os time */ static l_fp lfp_prev; /* prior result */ struct timespec ts; /* seconds and nanoseconds */ struct timespec ts_min; /* earliest permissible */ struct timespec ts_lam; /* lamport fictional increment */ double dfuzz; l_fp result; l_fp lfpfuzz; l_fp lfpdelta; get_ostime(&ts); DEBUG_REQUIRE(systime_init_done); ENTER_GET_SYSTIME_CRITSEC(); /* First check if here was a Lamport violation, that is, two * successive calls to 'get_ostime()' resulted in negative * time difference. Use a few milliseconds of permissible * tolerance -- being too sharp can hurt here. (This is intented * for the Win32 target, where the HPC interpolation might * introduce small steps backward. It should not be an issue on * systems where get_ostime() results in a true syscall.) */ if (cmp_tspec(add_tspec_ns(ts, 50000000), ts_last) < 0) { lamport_violated = 1; sys_lamport++; } ts_last = ts; /* * After default_get_precision() has set a nonzero sys_fuzz, * ensure every reading of the OS clock advances by at least * sys_fuzz over the prior reading, thereby assuring each * fuzzed result is strictly later than the prior. Limit the * necessary fiction to 1 second. */ if (!USING_SIGIO()) { ts_min = add_tspec_ns(ts_prev, sys_fuzz_nsec); if (cmp_tspec(ts, ts_min) < 0) { ts_lam = sub_tspec(ts_min, ts); if (ts_lam.tv_sec > 0 && !lamport_violated) { msyslog(LOG_ERR, "get_systime Lamport advance exceeds one second (%.9f)", ts_lam.tv_sec + 1e-9 * ts_lam.tv_nsec); exit(1); } if (!lamport_violated) ts = ts_min; } ts_prev = ts; } /* convert from timespec to l_fp fixed-point */ result = tspec_stamp_to_lfp(ts); /* * Add in the fuzz. 'ntp_random()' returns [0..2**31-1] so we * must scale up the result by 2.0 to cover the full fractional * range. */ dfuzz = ntp_random() * 2. / FRAC * sys_fuzz; DTOLFP(dfuzz, &lfpfuzz); L_ADD(&result, &lfpfuzz); /* * Ensure result is strictly greater than prior result (ignoring * sys_residual's effect for now) once sys_fuzz has been * determined. * * [Bug 3450] Rounding errors and time slew can lead to a * violation of the expected postcondition. This is bound to * happen from time to time (depending on state of the random * generator, the current slew and the closeness of system time * stamps drawn) and does not warrant a syslog entry. Instead it * makes much more sense to ensure the postcondition and hop * along silently. */ if (!USING_SIGIO()) { if ( !L_ISZERO(&lfp_prev) && !lamport_violated && (sys_fuzz > 0.0) ) { lfpdelta = result; L_SUB(&lfpdelta, &lfp_prev); L_SUBUF(&lfpdelta, 1); if (lfpdelta.l_i < 0) { L_NEG(&lfpdelta); DPRINTF(1, ("get_systime: postcond failed by %s secs, fixed\n", lfptoa(&lfpdelta, 9))); result = lfp_prev; L_ADDUF(&result, 1); sys_tsrounding++; } } lfp_prev = result; if (lamport_violated) lamport_violated = FALSE; } LEAVE_GET_SYSTIME_CRITSEC(); *now = result; } /* * adj_systime - adjust system time by the argument. */ #if !defined SYS_WINNT int /* 0 okay, 1 error */ adj_systime( double now /* adjustment (s) */ ) { struct timeval adjtv; /* new adjustment */ struct timeval oadjtv; /* residual adjustment */ double quant; /* quantize to multiples of */ double dtemp; long ticks; int isneg = 0; /* * The Windows port adj_systime() depends on being called each * second even when there's no additional correction, to allow * emulation of adjtime() behavior on top of an API that simply * sets the current rate. This POSIX implementation needs to * ignore invocations with zero correction, otherwise ongoing * EVNT_NSET adjtime() can be aborted by a tiny adjtime() * triggered by sys_residual. */ if (0. == now) { if (enable_panic_check && allow_panic) { msyslog(LOG_ERR, "adj_systime: allow_panic is TRUE!"); INSIST(!allow_panic); } return TRUE; } /* * Most Unix adjtime() implementations adjust the system clock * in microsecond quanta, but some adjust in 10-ms quanta. We * carefully round the adjustment to the nearest quantum, then * adjust in quanta and keep the residue for later. */ dtemp = now + sys_residual; if (dtemp < 0) { isneg = 1; dtemp = -dtemp; } adjtv.tv_sec = (long)dtemp; dtemp -= adjtv.tv_sec; if (sys_tick > sys_fuzz) quant = sys_tick; else quant = 1e-6; ticks = (long)(dtemp / quant + .5); adjtv.tv_usec = (long)(ticks * quant * 1.e6 + .5); /* The rounding in the conversions could us push over the * limits: make sure the result is properly normalised! * note: sign comes later, all numbers non-negative here. */ if (adjtv.tv_usec >= 1000000) { adjtv.tv_sec += 1; adjtv.tv_usec -= 1000000; dtemp -= 1.; } /* set the new residual with leftover from correction */ sys_residual = dtemp - adjtv.tv_usec * 1.e-6; /* * Convert to signed seconds and microseconds for the Unix * adjtime() system call. Note we purposely lose the adjtime() * leftover. */ if (isneg) { adjtv.tv_sec = -adjtv.tv_sec; adjtv.tv_usec = -adjtv.tv_usec; sys_residual = -sys_residual; } if (adjtv.tv_sec != 0 || adjtv.tv_usec != 0) { if (adjtime(&adjtv, &oadjtv) < 0) { msyslog(LOG_ERR, "adj_systime: %m"); if (enable_panic_check && allow_panic) { msyslog(LOG_ERR, "adj_systime: allow_panic is TRUE!"); } return FALSE; } } if (enable_panic_check && allow_panic) { msyslog(LOG_ERR, "adj_systime: allow_panic is TRUE!"); } return TRUE; } #endif /* * helper to keep utmp/wtmp up to date */ static void update_uwtmp( struct timeval timetv, struct timeval tvlast ) { struct timeval tvdiff; /* * FreeBSD, for example, has: * struct utmp { * char ut_line[UT_LINESIZE]; * char ut_name[UT_NAMESIZE]; * char ut_host[UT_HOSTSIZE]; * long ut_time; * }; * and appends line="|", name="date", host="", time for the OLD * and appends line="{", name="date", host="", time for the NEW // } * to _PATH_WTMP . * * Some OSes have utmp, some have utmpx. */ /* * Write old and new time entries in utmp and wtmp if step * adjustment is greater than one second. * * This might become even Uglier... */ tvdiff = abs_tval(sub_tval(timetv, tvlast)); if (tvdiff.tv_sec > 0) { #ifdef HAVE_UTMP_H struct utmp ut; #endif #ifdef HAVE_UTMPX_H struct utmpx utx; #endif #ifdef HAVE_UTMP_H ZERO(ut); #endif #ifdef HAVE_UTMPX_H ZERO(utx); #endif /* UTMP */ #ifdef UPDATE_UTMP # ifdef HAVE_PUTUTLINE # ifndef _PATH_UTMP # define _PATH_UTMP UTMP_FILE # endif utmpname(_PATH_UTMP); ut.ut_type = OLD_TIME; strlcpy(ut.ut_line, OTIME_MSG, sizeof(ut.ut_line)); ut.ut_time = tvlast.tv_sec; setutent(); pututline(&ut); ut.ut_type = NEW_TIME; strlcpy(ut.ut_line, NTIME_MSG, sizeof(ut.ut_line)); ut.ut_time = timetv.tv_sec; setutent(); pututline(&ut); endutent(); # else /* not HAVE_PUTUTLINE */ # endif /* not HAVE_PUTUTLINE */ #endif /* UPDATE_UTMP */ /* UTMPX */ #ifdef UPDATE_UTMPX # ifdef HAVE_PUTUTXLINE utx.ut_type = OLD_TIME; strlcpy(utx.ut_line, OTIME_MSG, sizeof(utx.ut_line)); utx.ut_tv = tvlast; setutxent(); pututxline(&utx); utx.ut_type = NEW_TIME; strlcpy(utx.ut_line, NTIME_MSG, sizeof(utx.ut_line)); utx.ut_tv = timetv; setutxent(); pututxline(&utx); endutxent(); # else /* not HAVE_PUTUTXLINE */ # endif /* not HAVE_PUTUTXLINE */ #endif /* UPDATE_UTMPX */ /* WTMP */ #ifdef UPDATE_WTMP # ifdef HAVE_PUTUTLINE # ifndef _PATH_WTMP # define _PATH_WTMP WTMP_FILE # endif utmpname(_PATH_WTMP); ut.ut_type = OLD_TIME; strlcpy(ut.ut_line, OTIME_MSG, sizeof(ut.ut_line)); ut.ut_time = tvlast.tv_sec; setutent(); pututline(&ut); ut.ut_type = NEW_TIME; strlcpy(ut.ut_line, NTIME_MSG, sizeof(ut.ut_line)); ut.ut_time = timetv.tv_sec; setutent(); pututline(&ut); endutent(); # else /* not HAVE_PUTUTLINE */ # endif /* not HAVE_PUTUTLINE */ #endif /* UPDATE_WTMP */ /* WTMPX */ #ifdef UPDATE_WTMPX # ifdef HAVE_PUTUTXLINE utx.ut_type = OLD_TIME; utx.ut_tv = tvlast; strlcpy(utx.ut_line, OTIME_MSG, sizeof(utx.ut_line)); # ifdef HAVE_UPDWTMPX updwtmpx(WTMPX_FILE, &utx); # else /* not HAVE_UPDWTMPX */ # endif /* not HAVE_UPDWTMPX */ # else /* not HAVE_PUTUTXLINE */ # endif /* not HAVE_PUTUTXLINE */ # ifdef HAVE_PUTUTXLINE utx.ut_type = NEW_TIME; utx.ut_tv = timetv; strlcpy(utx.ut_line, NTIME_MSG, sizeof(utx.ut_line)); # ifdef HAVE_UPDWTMPX updwtmpx(WTMPX_FILE, &utx); # else /* not HAVE_UPDWTMPX */ # endif /* not HAVE_UPDWTMPX */ # else /* not HAVE_PUTUTXLINE */ # endif /* not HAVE_PUTUTXLINE */ #endif /* UPDATE_WTMPX */ } } /* * step_systime - step the system clock. */ int step_systime( double step ) { time_t pivot; /* for ntp era unfolding */ struct timeval timetv, tvlast; struct timespec timets; l_fp fp_ofs, fp_sys; /* offset and target system time in FP */ /* * Get pivot time for NTP era unfolding. Since we don't step * very often, we can afford to do the whole calculation from * scratch. And we're not in the time-critical path yet. */ #if SIZEOF_TIME_T > 4 pivot = basedate_get_eracenter(); #else /* This makes sure the resulting time stamp is on or after * 1969-12-31/23:59:59 UTC and gives us additional two years, * from the change of NTP era in 2036 to the UNIX rollover in * 2038. (Minus one second, but that won't hurt.) We *really* * need a longer 'time_t' after that! Or a different baseline, * but that would cause other serious trouble, too. */ pivot = 0x7FFFFFFF; #endif /* get the complete jump distance as l_fp */ DTOLFP(sys_residual, &fp_sys); DTOLFP(step, &fp_ofs); L_ADD(&fp_ofs, &fp_sys); /* ---> time-critical path starts ---> */ /* get the current time as l_fp (without fuzz) and as struct timeval */ get_ostime(&timets); fp_sys = tspec_stamp_to_lfp(timets); tvlast.tv_sec = timets.tv_sec; tvlast.tv_usec = (timets.tv_nsec + 500) / 1000; /* get the target time as l_fp */ L_ADD(&fp_sys, &fp_ofs); /* unfold the new system time */ timetv = lfp_stamp_to_tval(fp_sys, &pivot); /* now set new system time */ if (ntp_set_tod(&timetv, NULL) != 0) { msyslog(LOG_ERR, "step-systime: %m"); if (enable_panic_check && allow_panic) { msyslog(LOG_ERR, "step_systime: allow_panic is TRUE!"); } return FALSE; } /* <--- time-critical path ended with 'ntp_set_tod()' <--- */ sys_residual = 0; lamport_violated = (step < 0); if (step_callback) (*step_callback)(); #ifdef NEED_HPUX_ADJTIME /* * CHECKME: is this correct when called by ntpdate????? */ _clear_adjtime(); #endif update_uwtmp(timetv, tvlast); if (enable_panic_check && allow_panic) { msyslog(LOG_ERR, "step_systime: allow_panic is TRUE!"); INSIST(!allow_panic); } return TRUE; } static const char * tv_fmt_libbuf( const struct timeval * ptv ) { char * retv; vint64 secs; ntpcal_split dds; struct calendar jd; secs = time_to_vint64(&ptv->tv_sec); dds = ntpcal_daysplit(&secs); ntpcal_daysplit_to_date(&jd, &dds, DAY_UNIX_STARTS); LIB_GETBUF(retv); snprintf(retv, LIB_BUFLENGTH, "%04hu-%02hu-%02hu/%02hu:%02hu:%02hu.%06u", jd.year, (u_short)jd.month, (u_short)jd.monthday, (u_short)jd.hour, (u_short)jd.minute, (u_short)jd.second, (u_int)ptv->tv_usec); return retv; } int /*BOOL*/ clamp_systime(void) { #if SIZEOF_TIME_T > 4 struct timeval timetv, tvlast; struct timespec timets; uint32_t tdiff; timetv.tv_sec = basedate_get_erabase(); /* ---> time-critical path starts ---> */ /* get the current time as l_fp (without fuzz) and as struct timeval */ get_ostime(&timets); tvlast.tv_sec = timets.tv_sec; tvlast.tv_usec = (timets.tv_nsec + 500) / 1000; if (tvlast.tv_usec >= 1000000) { tvlast.tv_usec -= 1000000; tvlast.tv_sec += 1; } timetv.tv_usec = tvlast.tv_usec; tdiff = (uint32_t)(tvlast.tv_sec & UINT32_MAX) - (uint32_t)(timetv.tv_sec & UINT32_MAX); timetv.tv_sec += tdiff; if (timetv.tv_sec != tvlast.tv_sec) { /* now set new system time */ if (ntp_set_tod(&timetv, NULL) != 0) { msyslog(LOG_ERR, "clamp-systime: %m"); return FALSE; } } else { msyslog(LOG_INFO, "clamp-systime: clock (%s) in allowed range", tv_fmt_libbuf(&timetv)); return FALSE; } /* <--- time-critical path ended with 'ntp_set_tod()' <--- */ sys_residual = 0; lamport_violated = (timetv.tv_sec < tvlast.tv_sec); if (step_callback) (*step_callback)(); # ifdef NEED_HPUX_ADJTIME /* * CHECKME: is this correct when called by ntpdate????? */ _clear_adjtime(); # endif update_uwtmp(timetv, tvlast); msyslog(LOG_WARNING, "clamp-systime: clock stepped from %s to %s!", tv_fmt_libbuf(&tvlast), tv_fmt_libbuf(&timetv)); return TRUE; #else return 0; #endif } #endif /* !SIM */