Current Path : /usr/src/contrib/ntp/ntpd/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //usr/src/contrib/ntp/ntpd/refclock_atom.c |
/* * refclock_atom - clock driver for 1-pps signals */ #ifdef HAVE_CONFIG_H #include <config.h> #endif #include <stdio.h> #include <ctype.h> #include "ntpd.h" #include "ntp_io.h" #include "ntp_unixtime.h" #include "ntp_refclock.h" #include "ntp_stdlib.h" #if defined(REFCLOCK) && defined(CLOCK_ATOM) #ifdef HAVE_PPSAPI # include "ppsapi_timepps.h" #endif /* HAVE_PPSAPI */ /* * This driver furnishes an interface for pulse-per-second (PPS) signals * produced by a cesium clock, timing receiver or related equipment. It * can be used to remove accumulated jitter and retime a secondary * server when synchronized to a primary server over a congested, wide- * area network and before redistributing the time to local clients. * * Before this driver becomes active, the local clock must be set to * within +-500 ms by another means, such as a radio clock or NTP * itself. There are two ways to connect the PPS signal, normally at TTL * levels, to the computer. One is to shift to EIA levels and connect to * pin 8 (DCD) of a serial port. This requires a level converter and * may require a one-shot flipflop to lengthen the pulse. The other is * to connect the PPS signal directly to pin 10 (ACK) of a PC paralell * port. These methods are architecture dependent. * * Both methods require a modified device driver and kernel interface * compatible with the Pulse-per-Second API for Unix-like Operating * Systems, Version 1.0, RFC-2783 (PPSAPI). Implementations are * available for FreeBSD, Linux, SunOS, Solaris and Alpha. However, at * present only the Alpha implementation provides the full generality of * the API with multiple PPS drivers and multiple handles per driver. If * the PPSAPI is normally implemented in the /usr/include/sys/timepps.h * header file and kernel support specific to each operating system. * However, this driver can operate without this interface if means are * proviced to call the pps_sample() routine from another driver. Please * note; if the PPSAPI interface is present, it must be used. * * In many configurations a single port is used for the radio timecode * and PPS signal. In order to provide for this configuration and others * involving dedicated multiple serial/parallel ports, the driver first * attempts to open the device /dev/pps%d, where %d is the unit number. * If this fails, the driver attempts to open the device specified by * the pps configuration command. If a port is to be shared, the pps * command must be placed before the radio device(s) and the radio * device(s) must be placed before the PPS driver(s) in the * configuration file. * * This driver normally uses the PLL/FLL clock discipline implemented in * the ntpd code. Ordinarily, this is the most accurate means, as the * median filter in the driver interface is much larger than in the * kernel. However, if the systemic clock frequency error is large (tens * to hundreds of PPM), it's better to used the kernel support, if * available. * * Fudge Factors * * If flag2 is dim (default), the on-time epoch is the assert edge of * the PPS signal; if lit, the on-time epoch is the clear edge. If flag2 * is lit, the assert edge is used; if flag3 is dim (default), the * kernel PPS support is disabled; if lit it is enabled. The time1 * parameter can be used to compensate for miscellaneous device driver * and OS delays. */ /* * Interface definitions */ #ifdef HAVE_PPSAPI #define DEVICE "/dev/pps%d" /* device name and unit */ #endif /* HAVE_PPSAPI */ #define PRECISION (-20) /* precision assumed (about 1 us) */ #define REFID "PPS\0" /* reference ID */ #define DESCRIPTION "PPS Clock Discipline" /* WRU */ #define NANOSECOND 1000000000 /* one second (ns) */ #define RANGEGATE 500000 /* range gate (ns) */ static struct peer *pps_peer; /* atom driver for PPS sources */ #ifdef HAVE_PPSAPI /* * PPS unit control structure */ struct ppsunit { struct timespec ts; /* last timestamp */ int fddev; /* pps device descriptor */ pps_params_t pps_params; /* pps parameters */ pps_info_t pps_info; /* last pps data */ pps_handle_t handle; /* pps handlebars */ }; #endif /* HAVE_PPSAPI */ /* * Function prototypes */ static int atom_start P((int, struct peer *)); static void atom_poll P((int, struct peer *)); static void atom_shutdown P((int, struct peer *)); #ifdef HAVE_PPSAPI static void atom_control P((int, struct refclockstat *, struct refclockstat *, struct peer *)); static void atom_timer P((int, struct peer *)); static int atom_ppsapi P((struct peer *, int)); #endif /* HAVE_PPSAPI */ /* * Transfer vector */ #ifdef HAVE_PPSAPI struct refclock refclock_atom = { atom_start, /* start up driver */ atom_shutdown, /* shut down driver */ atom_poll, /* transmit poll message */ atom_control, /* fudge control */ noentry, /* initialize driver (not used) */ noentry, /* buginfo (not used) */ atom_timer, /* called once per second */ }; #else /* HAVE_PPSAPI */ struct refclock refclock_atom = { atom_start, /* start up driver */ atom_shutdown, /* shut down driver */ atom_poll, /* transmit poll message */ noentry, /* fudge control (not used) */ noentry, /* initialize driver (not used) */ noentry, /* buginfo (not used) */ NOFLAGS /* not used */ }; #endif /* HAVE_PPPSAPI */ /* * atom_start - initialize data for processing */ static int atom_start( int unit, /* unit number (not used) */ struct peer *peer /* peer structure pointer */ ) { struct refclockproc *pp; #ifdef HAVE_PPSAPI register struct ppsunit *up; char device[80]; int mode; #endif /* HAVE_PPSAPI */ /* * Allocate and initialize unit structure */ pps_peer = peer; pp = peer->procptr; peer->precision = PRECISION; pp->clockdesc = DESCRIPTION; pp->stratum = STRATUM_UNSPEC; memcpy((char *)&pp->refid, REFID, 4); #ifdef HAVE_PPSAPI up = emalloc(sizeof(struct ppsunit)); memset(up, 0, sizeof(struct ppsunit)); pp->unitptr = (caddr_t)up; /* * Open PPS device. This can be any serial or parallel port and * not necessarily the port used for the associated radio. */ sprintf(device, DEVICE, unit); up->fddev = open(device, O_RDWR, 0777); if (up->fddev <= 0) { msyslog(LOG_ERR, "refclock_atom: %s: %m", device); return (0); } /* * Light off the PPSAPI interface. */ if (time_pps_create(up->fddev, &up->handle) < 0) { msyslog(LOG_ERR, "refclock_atom: time_pps_create failed: %m"); return (0); } /* * If the mode is nonzero, use that for the time_pps_setparams() * mode; otherwise, PPS_CAPTUREASSERT. Enable kernel PPS if * flag3 is lit. */ mode = peer->ttl; if (mode == 0) mode = PPS_CAPTUREASSERT; return (atom_ppsapi(peer, mode)); #else /* HAVE_PPSAPI */ return (1); #endif /* HAVE_PPSAPI */ } /* * atom_shutdown - shut down the clock */ static void atom_shutdown( int unit, /* unit number (not used) */ struct peer *peer /* peer structure pointer */ ) { struct refclockproc *pp; register struct ppsunit *up; pp = peer->procptr; up = (struct ppsunit *)pp->unitptr; #ifdef HAVE_PPSAPI if (up->fddev > 0) close(up->fddev); if (up->handle != 0) time_pps_destroy(up->handle); #endif /* HAVE_PPSAPI */ if (pps_peer == peer) pps_peer = NULL; free(up); } #ifdef HAVE_PPSAPI /* * atom_control - fudge control */ static void atom_control( int unit, /* unit (not used */ struct refclockstat *in, /* input parameters (not uded) */ struct refclockstat *out, /* output parameters (not used) */ struct peer *peer /* peer structure pointer */ ) { struct refclockproc *pp; int mode; pp = peer->procptr; if (peer->ttl != 0) /* all legal modes must be nonzero */ return; if (pp->sloppyclockflag & CLK_FLAG2) mode = PPS_CAPTURECLEAR; else mode = PPS_CAPTUREASSERT; atom_ppsapi(peer, mode); } /* * Initialize PPSAPI */ int atom_ppsapi( struct peer *peer, /* peer structure pointer */ int mode /* mode */ ) { struct refclockproc *pp; register struct ppsunit *up; int capability; pp = peer->procptr; up = (struct ppsunit *)pp->unitptr; if (up->handle == 0) return (0); if (time_pps_getcap(up->handle, &capability) < 0) { msyslog(LOG_ERR, "refclock_atom: time_pps_getcap failed: %m"); return (0); } memset(&up->pps_params, 0, sizeof(pps_params_t)); up->pps_params.api_version = PPS_API_VERS_1; up->pps_params.mode = mode | PPS_TSFMT_TSPEC; if (time_pps_setparams(up->handle, &up->pps_params) < 0) { msyslog(LOG_ERR, "refclock_atom: time_pps_setparams failed: %m"); return (0); } if (pp->sloppyclockflag & CLK_FLAG3) { if (time_pps_kcbind(up->handle, PPS_KC_HARDPPS, up->pps_params.mode & ~PPS_TSFMT_TSPEC, PPS_TSFMT_TSPEC) < 0) { msyslog(LOG_ERR, "refclock_atom: time_pps_kcbind failed: %m"); return (0); } pps_enable = 1; } #if DEBUG if (debug) { time_pps_getparams(up->handle, &up->pps_params); printf( "refclock_ppsapi: fd %d capability 0x%x version %d mode 0x%x\n", up->fddev, capability, up->pps_params.api_version, up->pps_params.mode); } #endif return (1); } /* * atom_timer - called once per second * * This routine is called once per second when the PPSAPI interface is * present. It snatches the PPS timestamp from the kernel and saves the * sign-extended fraction in a circular buffer for processing at the * next poll event. */ static void atom_timer( int unit, /* unit number (not used) */ struct peer *peer /* peer structure pointer */ ) { register struct ppsunit *up; struct refclockproc *pp; pps_info_t pps_info; struct timespec timeout, ts; long sec, nsec; double dtemp; char tbuf[80]; /* monitor buffer */ /* * Convert the timespec nanoseconds field to signed double and * save in the median filter. for billboards. No harm is done if * previous data are overwritten. If the discipline comes bum or * the data grow stale, just forget it. A range gate rejects new * samples if less than a jiggle time from the next second. */ pp = peer->procptr; up = (struct ppsunit *)pp->unitptr; if (up->handle == 0) return; timeout.tv_sec = 0; timeout.tv_nsec = 0; memcpy(&pps_info, &up->pps_info, sizeof(pps_info_t)); if (time_pps_fetch(up->handle, PPS_TSFMT_TSPEC, &up->pps_info, &timeout) < 0) { refclock_report(peer, CEVNT_FAULT); return; } if (up->pps_params.mode & PPS_CAPTUREASSERT) { ts = up->pps_info.assert_timestamp; } else if (up->pps_params.mode & PPS_CAPTURECLEAR) { ts = up->pps_info.clear_timestamp; } else { refclock_report(peer, CEVNT_FAULT); return; } /* * There can be zero, one or two PPS seconds between polls. If * zero, either the poll clock is slightly faster than the PPS * clock or the PPS clock has died. If the PPS clock advanced * once between polls, we make sure the fraction time difference * since the last sample is within the range gate of 5 ms (500 * PPM). If the PPS clock advanced twice since the last poll, * the poll bracketed more than one second and the first second * was lost to a slip. Since the interval since the last sample * found is now two seconds, just widen the range gate. If the * PPS clock advanced three or more times, either the signal has * failed for a number of seconds or we have runts, in which * case just ignore them. * * If flag4 is lit, record each second offset to clockstats. * That's so we can make awesome Allan deviation plots. */ sec = ts.tv_sec - up->ts.tv_sec; nsec = ts.tv_nsec - up->ts.tv_nsec; up->ts = ts; if (nsec < 0) { sec --; nsec += NANOSECOND; } else if (nsec >= NANOSECOND) { sec++; nsec -= NANOSECOND; } if (sec * NANOSECOND + nsec > NANOSECOND + RANGEGATE) return; else if (sec * NANOSECOND + nsec < NANOSECOND - RANGEGATE) return; pp->lastrec.l_ui = ts.tv_sec + JAN_1970; dtemp = ts.tv_nsec * FRAC / 1e9; if (dtemp >= FRAC) pp->lastrec.l_ui++; pp->lastrec.l_uf = (u_int32)dtemp; if (ts.tv_nsec > NANOSECOND / 2) ts.tv_nsec -= NANOSECOND; dtemp = -(double)ts.tv_nsec / NANOSECOND; SAMPLE(dtemp + pp->fudgetime1); if (pp->sloppyclockflag & CLK_FLAG4){ sprintf(tbuf, "%.9f", dtemp); record_clock_stats(&peer->srcadr, tbuf); } #ifdef DEBUG if (debug > 1) printf("atom_timer: %lu %f %f\n", current_time, dtemp, pp->fudgetime1); #endif return; } #endif /* HAVE_PPSAPI */ /* * pps_sample - receive PPS data from some other clock driver * * This routine is called once per second when the external clock driver * processes PPS information. It processes the PPS timestamp and saves * the sign-extended fraction in a circular buffer for processing at the * next poll event. This works only for a single PPS device. * * The routine should be used by another configured driver ONLY when * this driver is configured as well and the PPSAPI is NOT in use. */ int pps_sample( l_fp *offset /* PPS offset */ ) { register struct peer *peer; struct refclockproc *pp; l_fp lftmp; double doffset; peer = pps_peer; if (peer == NULL) return (1); pp = peer->procptr; /* * Convert the timeval to l_fp and save for billboards. Sign- * extend the fraction and stash in the buffer. No harm is done * if previous data are overwritten. If the discipline comes bum * or the data grow stale, just forget it. */ pp->lastrec = *offset; L_CLR(&lftmp); L_ADDF(&lftmp, pp->lastrec.l_f); LFPTOD(&lftmp, doffset); SAMPLE(-doffset + pp->fudgetime1); return (0); } /* * atom_poll - called by the transmit procedure */ static void atom_poll( int unit, /* unit number (not used) */ struct peer *peer /* peer structure pointer */ ) { struct refclockproc *pp; pp = peer->procptr; pp->polls++; /* * Valid time is returned only if the prefer peer has survived * the intersection algorithm and within 0.4 s of local time * and not too long ago. This ensures the PPS time is within * 0.5 s of the local time and the seconds numbering is * unambiguous. Note that the leap bits, stratum and refid are * set from the prefer peer, unless overriden by a fudge * command. */ if (pp->codeproc == pp->coderecv) { refclock_report(peer, CEVNT_TIMEOUT); return; } else if (sys_prefer == NULL) { pp->codeproc = pp->coderecv; return; } else if (fabs(sys_prefer->offset) >= 0.4) { pp->codeproc = pp->coderecv; return; } pp->leap = sys_prefer->leap; if (pp->stratum >= STRATUM_UNSPEC) peer->stratum = sys_prefer->stratum; else peer->stratum = pp->stratum; pp->lastref = pp->lastrec; refclock_receive(peer); } #else int refclock_atom_bs; int pps_sample( l_fp *offset /* PPS offset */ ) { return (1); } #endif /* REFCLOCK */