/* * refclock_as2201 - clock driver for the Austron 2201A GPS * Timing Receiver */ #ifdef HAVE_CONFIG_H #include #endif #if defined(REFCLOCK) && defined(CLOCK_AS2201) #include "ntpd.h" #include "ntp_io.h" #include "ntp_refclock.h" #include "ntp_unixtime.h" #include "ntp_stdlib.h" #include #include /* * This driver supports the Austron 2200A/2201A GPS Receiver with * Buffered RS-232-C Interface Module. Note that the original 2200/2201 * receivers will not work reliably with this driver, since the older * design cannot accept input commands at any reasonable data rate. * * The program sends a "*toc\r" to the radio and expects a response of * the form "yy:ddd:hh:mm:ss.mmm\r" where yy = year of century, ddd = * day of year, hh:mm:ss = second of day and mmm = millisecond of * second. Then, it sends statistics commands to the radio and expects * a multi-line reply showing the corresponding statistics or other * selected data. Statistics commands are sent in order as determined by * a vector of commands; these might have to be changed with different * radio options. If flag4 of the fudge configuration command is set to * 1, the statistics data are written to the clockstats file for later * processing. * * In order for this code to work, the radio must be placed in non- * interactive mode using the "off" command and with a single * response using the "term cr" command. The setting of the "echo" * and "df" commands does not matter. The radio should select UTC * timescale using the "ts utc" command. * * There are two modes of operation for this driver. The first with * default configuration is used with stock kernels and serial-line * drivers and works with almost any machine. In this mode the driver * assumes the radio captures a timestamp upon receipt of the "*" that * begins the driver query. Accuracies in this mode are in the order of * a millisecond or two and the receiver can be connected to only one * host. * * The second mode of operation can be used for SunOS kernels that have * been modified with the ppsclock streams module included in this * distribution. The mode is enabled if flag3 of the fudge configuration * command has been set to 1. In this mode a precise timestamp is * available using a gadget box and 1-pps signal from the receiver. This * improves the accuracy to the order of a few tens of microseconds. In * addition, the serial output and 1-pps signal can be bussed to more * than one hosts, but only one of them should be connected to the * radio input data line. */ /* * GPS Definitions */ #define SMAX 200 /* statistics buffer length */ #define DEVICE "/dev/gps%d" /* device name and unit */ #define SPEED232 B9600 /* uart speed (9600 baud) */ #define PRECISION (-20) /* precision assumed (about 1 us) */ #define REFID "GPS\0" /* reference ID */ #define DESCRIPTION "Austron 2201A GPS Receiver" /* WRU */ #define LENTOC 19 /* yy:ddd:hh:mm:ss.mmm timecode lngth */ /* * AS2201 unit control structure. */ struct as2201unit { char *lastptr; /* statistics buffer pointer */ char stats[SMAX]; /* statistics buffer */ int linect; /* count of lines remaining */ int index; /* current statistics command */ }; /* * Radio commands to extract statitistics * * A command consists of an ASCII string terminated by a (\r). The * command list consist of a sequence of commands terminated by a null * string ("\0"). One command from the list is sent immediately * following each received timecode (*toc\r command) and the ASCII * strings received from the radio are saved along with the timecode in * the clockstats file. Subsequent commands are sent at each timecode, * with the last one in the list followed by the first one. The data * received from the radio consist of ASCII strings, each terminated by * a (\r) character. The number of strings for each command is * specified as the first line of output as an ASCII-encode number. Note * that the ETF command requires the Input Buffer Module and the LORAN * commands require the LORAN Assist Module. However, if these modules * are not installed, the radio and this driver will continue to operate * successfuly, but no data will be captured for these commands. */ static char stat_command[][30] = { "ITF\r", /* internal time/frequency */ "ETF\r", /* external time/frequency */ "LORAN ENSEMBLE\r", /* GPS/LORAN ensemble statistics */ "LORAN TDATA\r", /* LORAN signal data */ "ID;OPT;VER\r", /* model; options; software version */ "ITF\r", /* internal time/frequency */ "ETF\r", /* external time/frequency */ "LORAN ENSEMBLE\r", /* GPS/LORAN ensemble statistics */ "TRSTAT\r", /* satellite tracking status */ "POS;PPS;PPSOFF\r", /* position, pps source, offsets */ "ITF\r", /* internal time/frequency */ "ETF\r", /* external time/frequency */ "LORAN ENSEMBLE\r", /* GPS/LORAN ensemble statistics */ "LORAN TDATA\r", /* LORAN signal data */ "UTC\r", /* UTC leap info */ "ITF\r", /* internal time/frequency */ "ETF\r", /* external time/frequency */ "LORAN ENSEMBLE\r", /* GPS/LORAN ensemble statistics */ "TRSTAT\r", /* satellite tracking status */ "OSC;ET;TEMP\r", /* osc type; tune volts; oven temp */ "\0" /* end of table */ }; /* * Function prototypes */ static int as2201_start (int, struct peer *); static void as2201_shutdown (int, struct peer *); static void as2201_receive (struct recvbuf *); static void as2201_poll (int, struct peer *); /* * Transfer vector */ struct refclock refclock_as2201 = { as2201_start, /* start up driver */ as2201_shutdown, /* shut down driver */ as2201_poll, /* transmit poll message */ noentry, /* not used (old as2201_control) */ noentry, /* initialize driver (not used) */ noentry, /* not used (old as2201_buginfo) */ NOFLAGS /* not used */ }; /* * as2201_start - open the devices and initialize data for processing */ static int as2201_start( int unit, struct peer *peer ) { register struct as2201unit *up; struct refclockproc *pp; int fd; char gpsdev[20]; /* * Open serial port. Use CLK line discipline, if available. */ snprintf(gpsdev, sizeof(gpsdev), DEVICE, unit); fd = refclock_open(&peer->srcadr, gpsdev, SPEED232, LDISC_CLK); if (fd <= 0) return (0); /* * Allocate and initialize unit structure */ up = emalloc_zero(sizeof(*up)); pp = peer->procptr; pp->io.clock_recv = as2201_receive; pp->io.srcclock = peer; pp->io.datalen = 0; pp->io.fd = fd; if (!io_addclock(&pp->io)) { close(fd); pp->io.fd = -1; free(up); return (0); } pp->unitptr = up; /* * Initialize miscellaneous variables */ peer->precision = PRECISION; pp->clockdesc = DESCRIPTION; memcpy((char *)&pp->refid, REFID, 4); up->lastptr = up->stats; up->index = 0; return (1); } /* * as2201_shutdown - shut down the clock */ static void as2201_shutdown( int unit, struct peer *peer ) { register struct as2201unit *up; struct refclockproc *pp; pp = peer->procptr; up = pp->unitptr; if (-1 != pp->io.fd) io_closeclock(&pp->io); if (NULL != up) free(up); } /* * as2201__receive - receive data from the serial interface */ static void as2201_receive( struct recvbuf *rbufp ) { register struct as2201unit *up; struct refclockproc *pp; struct peer *peer; l_fp trtmp; size_t octets; /* * Initialize pointers and read the timecode and timestamp. */ peer = rbufp->recv_peer; pp = peer->procptr; up = pp->unitptr; pp->lencode = refclock_gtlin(rbufp, pp->a_lastcode, BMAX, &trtmp); #ifdef DEBUG if (debug) printf("gps: timecode %d %d %s\n", up->linect, pp->lencode, pp->a_lastcode); #endif if (pp->lencode == 0) return; /* * If linect is greater than zero, we must be in the middle of a * statistics operation, so simply tack the received data at the * end of the statistics string. If not, we could either have * just received the timecode itself or a decimal number * indicating the number of following lines of the statistics * reply. In the former case, write the accumulated statistics * data to the clockstats file and continue onward to process * the timecode; in the later case, save the number of lines and * quietly return. */ if (pp->sloppyclockflag & CLK_FLAG2) pp->lastrec = trtmp; if (up->linect > 0) { up->linect--; if ((int)(up->lastptr - up->stats + pp->lencode) > SMAX - 2) return; *up->lastptr++ = ' '; memcpy(up->lastptr, pp->a_lastcode, 1 + pp->lencode); up->lastptr += pp->lencode; return; } else { if (pp->lencode == 1) { up->linect = atoi(pp->a_lastcode); return; } else { record_clock_stats(&peer->srcadr, up->stats); #ifdef DEBUG if (debug) printf("gps: stat %s\n", up->stats); #endif } } up->lastptr = up->stats; *up->lastptr = '\0'; /* * We get down to business, check the timecode format and decode * its contents. If the timecode has invalid length or is not in * proper format, we declare bad format and exit. */ if (pp->lencode < LENTOC) { refclock_report(peer, CEVNT_BADREPLY); return; } /* * Timecode format: "yy:ddd:hh:mm:ss.mmm" */ if (sscanf(pp->a_lastcode, "%2d:%3d:%2d:%2d:%2d.%3ld", &pp->year, &pp->day, &pp->hour, &pp->minute, &pp->second, &pp->nsec) != 6) { refclock_report(peer, CEVNT_BADREPLY); return; } pp->nsec *= 1000000; /* * Test for synchronization (this is a temporary crock). */ if (pp->a_lastcode[2] != ':') pp->leap = LEAP_NOTINSYNC; else pp->leap = LEAP_NOWARNING; /* * Process the new sample in the median filter and determine the * timecode timestamp. */ if (!refclock_process(pp)) { refclock_report(peer, CEVNT_BADTIME); return; } /* * If CLK_FLAG4 is set, initialize the statistics buffer and * send the next command. If not, simply write the timecode to * the clockstats file. */ if ((int)(up->lastptr - up->stats + pp->lencode) > SMAX - 2) return; memcpy(up->lastptr, pp->a_lastcode, pp->lencode); up->lastptr += pp->lencode; if (pp->sloppyclockflag & CLK_FLAG4) { octets = strlen(stat_command[up->index]); if ((int)(up->lastptr - up->stats + 1 + octets) > SMAX - 2) return; *up->lastptr++ = ' '; memcpy(up->lastptr, stat_command[up->index], octets); up->lastptr += octets - 1; *up->lastptr = '\0'; refclock_write(peer, stat_command[up->index], strlen(stat_command[up->index]), "command"); up->index++; if (*stat_command[up->index] == '\0') up->index = 0; } } /* * as2201_poll - called by the transmit procedure * * We go to great pains to avoid changing state here, since there may be * more than one eavesdropper receiving the same timecode. */ static void as2201_poll( int unit, struct peer *peer ) { struct refclockproc *pp; /* * Send a "\r*toc\r" to get things going. We go to great pains * to avoid changing state, since there may be more than one * eavesdropper watching the radio. */ pp = peer->procptr; if (write(pp->io.fd, "\r*toc\r", 6) != 6) { refclock_report(peer, CEVNT_FAULT); } else { pp->polls++; if (!(pp->sloppyclockflag & CLK_FLAG2)) get_systime(&pp->lastrec); } if (pp->coderecv == pp->codeproc) { refclock_report(peer, CEVNT_TIMEOUT); return; } refclock_receive(peer); } #else NONEMPTY_TRANSLATION_UNIT #endif /* REFCLOCK */