/* * A prototype driver. Doesn't run, doesn't even compile. * * For new driver authors: replace "_PROTO_" and "_proto_" with the name of * your new driver. That will give you a skeleton with all the required * functions defined. * * Once that is done, you will likely have to define a large number of * flags and masks. From there, you will be able to start extracting * useful quantities. There are roughed-in decoders for the navigation * solution, satellite status and gps-utc offset. These are the 3 key * messages that gpsd needs. Some protocols transmit error estimates * separately from the navigation solution; if developing a driver for * such a protocol you will need to add a decoder function for that * message. Be extra careful when using sizeof() to extract part * of packets (ie. don't do it). This idiom creates portability problems * between 32 and 64 bit systems. * * For anyone hacking this driver skeleton: "_PROTO_" and "_proto_" are now * reserved tokens. We suggest that they only ever be used as prefixes, * but if they are used infix, they must be used in a way that allows a * driver author to find-and-replace to create a unique namespace for * driver functions. * * If using vi, ":%s/_PROTO_/MYDRIVER/g" and ":%s/_proto_/mydriver/g" * should produce a source file that comes very close to being useful. * You will also need to add hooks for your new driver to: * Makefile.am * drivers.c * gpsd.h-tail * libgpsd_core.c * packet.c * packet_states.h * * This file is Copyright (c) 2010 by the GPSD project * BSD terms apply: see the file COPYING in the distribution root for details. */ #include #include #include #if defined(_PROTO__ENABLE) && defined(BINARY_ENABLE) #include "bits.h" static gps_mask_t _proto__parse_input(struct gps_device_t *); static gps_mask_t _proto__dispatch(struct gps_device_t *, unsigned char *, size_t ); static gps_mask_t _proto__msg_navsol(struct gps_device_t *, unsigned char *, size_t ); static gps_mask_t _proto__msg_utctime(struct gps_device_t *, unsigned char *, size_t ); static gps_mask_t _proto__msg_svinfo(struct gps_device_t *, unsigned char *, size_t ); static gps_mask_t _proto__msg_raw(struct gps_device_t *, unsigned char *, size_t ); /* * These methods may be called elsewhere in gpsd */ static ssize_t _proto__control_send(struct gps_device_t *, char *, size_t); static bool _proto__probe_detect(struct gps_device_t *); static void _proto__event_hook(struct gps_device_t *, event_t); static bool _proto__set_speed(struct gps_device_t *, speed_t, char, int); static void _proto__set_mode(struct gps_device_t *, int); /* * Decode the navigation solution message */ static gps_mask_t _proto__msg_navsol(struct gps_device_t *session, unsigned char *buf, size_t data_len) { gps_mask_t mask; int flags; double Px, Py, Pz, Vx, Vy, Vz; if (data_len != _PROTO__NAVSOL_MSG_LEN) return 0; gpsd_report(LOG_IO, "_proto_ NAVSOL - navigation data\n"); /* if this protocol has a way to test message validity, use it */ flags = GET_FLAGS(); if ((flags & _PROTO__SOLUTION_VALID) == 0) return 0; mask = ONLINE_IS; /* extract ECEF navigation solution here */ /* or extract the local tangential plane (ENU) solution */ [Px, Py, Pz, Vx, Vy, Vz] = GET_ECEF_FIX(); ecef_to_wgs84fix(&session->newdata, &session->gpsdata.separation, Px, Py, Pz, Vx, Vy, Vz); mask |= LATLON_IS | ALTITUDE_IS | SPEED_IS | TRACK_IS | CLIMB_IS ; session->newdata.epx = GET_LONGITUDE_ERROR(); session->newdata.epy = GET_LATITUDE_ERROR(); session->newdata.eps = GET_SPEED_ERROR(); session->gpsdata.satellites_used = GET_SATELLITES_USED(); /* * Do *not* clear DOPs in a navigation solution message; * instead, opportunistically pick up whatever it gives * us and replace whatever values we computed from the * visibility matrix for he last skyview. The reason to trust * the chip returns over what we compute is that some * chips have internal deweighting albums to throw out sats * that increase DOP. */ session->gpsdata.dop.hdop = GET_HDOP(); session->gpsdata.dop.vdop = GET_VDOP(); /* other DOP if available */ mask |= DOP_IS; session->newdata.mode = GET_FIX_MODE(); session->gpsdata.status = GET_FIX_STATUS(); /* * Mix in CLEAR_IS to clue the daemon in about when to clear fix * information. Mix in REPORT_IS when the sentence is reliably * the last in a reporting cycle. */ mask |= MODE_IS | STATUS_IS | REPORT_IS; /* * At the end of each packet-cracking function, report at LOG_DATA level * the fields it potentially set and the transfer mask. Doing this * makes it relatively easy to track down data-management problems. */ gpsd_report(LOG_DATA, "NAVSOL: time=%.2f, lat=%.2f lon=%.2f alt=%.2f mode=%d status=%d mask=%s\n", session->newdata.time, session->newdata.latitude, session->newdata.longitude, session->newdata.altitude, session->newdata.mode, session->gpsdata.status, gpsd_maskdump(mask)); return mask; } /** * GPS Leap Seconds */ static gps_mask_t _proto__msg_utctime(struct gps_device_t *session, unsigned char *buf, size_t data_len) { double t; if (data_len != UTCTIME_MSG_LEN) return 0; gpsd_report(LOG_IO, "_proto_ UTCTIME - navigation data\n"); /* if this protocol has a way to test message validity, use it */ flags = GET_FLAGS(); if ((flags & _PROTO__TIME_VALID) == 0) return 0; tow = GET_MS_TIMEOFWEEK(); gps_week = GET_WEEKNUMBER(); session->context->leap_seconds = GET_GPS_LEAPSECONDS(); session->newdata.time = gpsd_gpstime_resolve(session, gps_week, tow / 1000.0); return TIME_IS | ONLINE_IS; } /** * GPS Satellite Info */ static gps_mask_t _proto__msg_svinfo(struct gps_device_t *session, unsigned char *buf, size_t data_len) { unsigned char i, st, nchan, nsv; unsigned int tow; if (data_len != SVINFO_MSG_LEN ) return 0; gpsd_report(LOG_IO, "_proto_ SVINFO - navigation data\n"); /* if this protocol has a way to test message validity, use it */ flags = GET_FLAGS(); if ((flags & _PROTO__SVINFO_VALID) == 0) return 0; /* * some protocols have a variable length message listing only visible * satellites, even if there are less than the number of channels. others * have a fixed length message and send empty records for idle channels * that are not tracking or searching. whatever the case, nchan should * be set to the number of satellites which might be visible. */ nchan = GET_NUMBER_OF_CHANNELS(); if ((nchan < 1) || (nchan > MAXCHANNELS)) { gpsd_report(LOG_INF, "too many channels reported\n"); return 0; } gpsd_zero_satellites(&session->gpsdata); nsv = 0; /* number of actually used satellites */ for (i = st = 0; i < nchan; i++) { /* get info for one channel/satellite */ int off = GET_CHANNEL_STATUS(i); session->gpsdata.PRN[i] = PRN_THIS_CHANNEL_IS_TRACKING(i); session->gpsdata.ss[i] = (float)SIGNAL_STRENGTH_FOR_CHANNEL(i); session->gpsdata.elevation[i] = SV_ELEVATION_FOR_CHANNEL(i); session->gpsdata.azimuth[i] = SV_AZIMUTH_FOR_CHANNEL(i); if (CHANNEL_USED_IN_SOLUTION(i)) session->gpsdata.used[nsv++] = session->gpsdata.PRN[i]; if(session->gpsdata.PRN[i]) st++; } /* if the satellite-info setence gives you UTC time, use it */ session->gpsdata.skyview_time = NaN; session->gpsdata.satellites_used = nsv; session->gpsdata.satellites_visible = st; gpsd_report(LOG_DATA, "SVINFO: visible=%d used=%d mask={SATELLITE|USED}\n", session->gpsdata.satellites_visible, session->gpsdata.satellites_used); return SATELLITE_IS | USED_IS; } /** * Raw measurements */ static gps_mask_t _proto__msg_raw(struct gps_device_t *session, unsigned char *buf, size_t data_len) { unsigned char i, st, nchan, nsv; unsigned int tow; if (data_len != RAW_MSG_LEN ) return 0; gpsd_report(LOG_IO, "_proto_ RAW - raw measurements\n"); /* if this protocol has a way to test message validity, use it */ flags = GET_FLAGS(); if ((flags & _PROTO__SVINFO_VALID) == 0) return 0; /* * not all chipsets emit the same information. some of these observables * can be easily converted into others. these are suggestions for the * quantities you may wish to try extract. chipset documentation may say * something like "this message contains information required to generate * a RINEX file." assign NAN for unavailable data. */ nchan = GET_NUMBER_OF_CHANNELS(); if ((nchan < 1) || (nchan > MAXCHANNELS)) { gpsd_report(LOG_INF, "too many channels reported\n"); return 0; } for (i = 0; i < n; i++){ session->gpsdata.PRN[i] = GET_PRN(); session->gpsdata.ss[i] = GET_SIGNAL() session->gpsdata.raw.satstat[i] = GET_FLAGS(); session->gpsdata.raw.pseudorange[i] = GET_PSEUDORANGE(); session->gpsdata.raw.doppler[i] = GET_DOPPLER(); session->gpsdata.raw.carrierphase[i] = GET_CARRIER_PHASE(); session->gpsdata.raw.mtime[i] = GET_MEASUREMENT_TIME(); session->gpsdata.raw.codephase[i] = GET_CODE_PHASE(); session->gpsdata.raw.deltarange[i] = GET_DELTA_RANGE(); } return RAW_IS; } /** * Parse the data from the device */ /*@ +charint @*/ gps_mask_t _proto__dispatch(struct gps_device_t *session, unsigned char *buf, size_t len) { size_t i; int type, used, visible, retmask = 0; if (len == 0) return 0; /* * Set this if the driver reliably signals end of cycle. * The core library zeroes it just before it calls each driver's * packet analyzer. */ session->cycle_end_reliable = true; if (msgid == MY_START_OF_CYCLE) retmask |= CLEAR_IS; else if (msgid == MY_END_OF_CYCLE) retmask |= REPORT_IS; type = GET_MESSAGE_TYPE(); /* we may need to dump the raw packet */ gpsd_report(LOG_RAW, "raw _proto_ packet type 0x%02x length %d: %s\n", type, len, gpsd_hexdump_wrapper(buf, len, LOG_RAW)); /* * The tag field is only 8 bytes; be careful you do not overflow. * Using an abbreviation (eg. "italk" -> "itk") may be useful. */ (void)snprintf(session->gpsdata.tag, sizeof(session->gpsdata.tag), "_PROTO_%02x", type); switch (type) { /* Deliver message to specific decoder based on message type */ default: /* This gets noisy in a hurry. Change once your driver works */ gpsd_report(LOG_WARN, "unknown packet id %d length %d: %s\n", type, len, gpsd_hexdump_wrapper(buf, len, LOG_WARN)); return 0; } } /*@ -charint @*/ /********************************************************** * * Externally called routines below here * **********************************************************/ static bool _proto__probe_detect(struct gps_device_t *session) { /* * This method is used to elicit a positively identifying * response from a candidate device. Some drivers may use * this to test for the presence of a certain kernel module. */ int test, satisfied; /* Your testing code here */ test=satisfied=0; if (test==satisfied) return true; return false; } #ifdef ALLOW_CONTROLSEND /** * Write data to the device, doing any required padding or checksumming */ /*@ +charint -usedef -compdef @*/ static ssize_t _proto__control_send(struct gps_device_t *session, char *msg, size_t msglen) { bool ok; /* CONSTRUCT THE MESSAGE */ /* * This copy to a public assembly buffer * enables gpsmon to snoop the control message * after it has been sent. */ session->msgbuflen = msglen; (void)memcpy(session->msgbuf, msg, msglen); /* we may need to dump the message */ return gpsd_write(session, session->msgbuf, session->msgbuflen); gpsd_report(LOG_IO, "writing _proto_ control type %02x:%s\n", msg[0], gpsd_hexdump_wrapper(session->msgbuf, session->msgbuflen, LOG_IO)); return gpsd_write(session, session->msgbuf, session->msgbuflen); } /*@ -charint +usedef +compdef @*/ #endif /* ALLOW_CONTROLSEND */ #ifdef ALLOW_RECONFIGURE static void _proto__event_hook(struct gps_device_t *session, event_t event) { if (session->context->readonly) return; if (event == event_wakeup) { /* * Code to make the device ready to communicate. Only needed if the * device is in some kind of sleeping state, and only shipped to * RS232C (so that gpsd won't send strings to unidentified USB devices) * that might not be GPSes at all. */ } if (event == event_identified) { /* * Fires when the first full packet is recognized from a * previously unidentified device. The session packet counter * is zeroed. If your device has a default cycle time other * than 1 second, set session->device->gpsdata.cycle here. If * possible, get the software version and store it in * session->subtype. */ } if (event == event_configure) { /* * Change sentence mix and set reporting modes as needed. * Called immediately after event_identified fires, then just * after every packet received thereafter, but you probably * only want to take actions on the first few packets after * the session packet counter has been zeroed, * * Remember that session->packet.counter is available when you * write this hook; you can use this fact to interleave configuration * sends with the first few packet reads, which is useful for * devices with small receive buffers. */ } else if (event == event_driver_switch) { /* * Fires when the driver on a device is changed *after* it * has been identified. */ } else if (event == event_deactivate) { /* * Fires when the device is deactivated. Usr this to revert * whatever was done at event_identify and event_configure * time. */ } else if (event == event_reactivate) { /* * Fires when a device is reactivated after having been closed. * Use this hook for re-establishing device settings that * it doesn't hold through closes. */ } } /* * This is the entry point to the driver. When the packet sniffer recognizes * a packet for this driver, it calls this method which passes the packet to * the binary processor or the nmea processor, depending on the session type. */ static gps_mask_t _proto__parse_input(struct gps_device_t *session) { gps_mask_t st; if (session->packet.type == _PROTO__PACKET) { st = _proto__dispatch(session, session->packet.outbuffer, session->packet.outbuflen); session->gpsdata.driver_mode = MODE_BINARY; return st; #ifdef NMEA_ENABLE } else if (session->packet.type == NMEA_PACKET) { st = nmea_parse((char *)session->packet.outbuffer, session); session->gpsdata.driver_mode = MODE_NMEA; return st; #endif /* NMEA_ENABLE */ } else return 0; } static bool _proto__set_speed(struct gps_device_t *session, speed_t speed, char parity, int stopbits) { /* * Set port operating mode, speed, parity, stopbits etc. here. * Note: parity is passed as 'N'/'E'/'O', but you should program * defensively and allow 0/1/2 as well. */ } /* * Switch between NMEA and binary mode, if supported */ static void _proto__set_mode(struct gps_device_t *session, int mode) { if (mode == MODE_NMEA) { // _proto__to_nmea(session->gpsdata.gps_fd,session->gpsdata.baudrate); /* send the mode switch control string */ session->gpsdata.driver_mode = MODE_NMEA; /* * Anticipatory switching works only when the packet getter is the * generic one and it recognizes packets of the type this driver * is expecting. This should be the normal case. */ (void)gpsd_switch_driver(session, "Generic NMEA"); } else { session->back_to_nmea = false; session->gpsdata.driver_mode = MODE_BINARY; } } #endif /* ALLOW_RECONFIGURE */ #ifdef NTPSHM_ENABLE static double _proto_ntp_offset(struct gps_device_t *session) { /* * If NTP notification is enabled, the GPS will occasionally NTP * its notion of the time. This will lag behind actual time by * some amount which has to be determined by observation vs. (say * WWVB radio broadcasts) and, furthermore, may differ by baud * rate. This method is for computing the NTP fudge factor. If * it's absent, an offset of 0.0 will be assumed, effectively * falling back on what's in ntp.conf. When it returns NAN, * nothing will be sent to NTP. */ return MAGIC_CONSTANT; } #endif /* NTPSHM_ENABLE */ static void _proto__wrapup(struct gps_device_t *session) { } /* The methods in this code take parameters and have */ /* return values that conform to the requirements AT */ /* THE TIME THE CODE WAS WRITTEN. */ /* */ /* These values may well have changed by the time */ /* you read this and methods could have been added */ /* or deleted. Unused methods can be set to NULL. */ /* */ /* The latest version can be found by inspecting */ /* the contents of struct gps_type_t in gpsd.h. */ /* */ /* This always contains the correct definitions that */ /* any driver must use to compile. */ /* This is everything we export */ /* *INDENT-OFF* */ const struct gps_type_t _proto__binary = { /* Full name of type */ .type_name = "_proto_ binary", /* Associated lexer packet type */ .packet_type = _PROTO__PACKET, /* Driver tyoe flags */ .flags = DRIVER_NOFLAGS, /* Response string that identifies device (not active) */ .trigger = NULL, /* Number of satellite channels supported by the device */ .channels = 12, /* Startup-time device detector */ .probe_detect = _proto__probe_detect, /* Packet getter (using default routine) */ .get_packet = generic_get, /* Parse message packets */ .parse_packet = _proto__parse_input, /* RTCM handler (using default routine) */ .rtcm_writer = pass_rtcm, /* fire on various lifetime events */ .event_hook = _proto__event_hook, #ifdef ALLOW_RECONFIGURE /* Speed (baudrate) switch */ .speed_switcher = _proto__set_speed, /* Switch to NMEA mode */ .mode_switcher = _proto__set_mode, /* Message delivery rate switcher (not active) */ .rate_switcher = NULL, /* Minimum cycle time of the device */ .min_cycle = 1, #endif /* ALLOW_RECONFIGURE */ #ifdef ALLOW_CONTROLSEND /* Control string sender - should provide checksum and headers/trailer */ .control_send = _proto__control_send, #endif /* ALLOW_CONTROLSEND */ #ifdef NTPSHM_ENABLE .ntp_offset = _proto_ntp_offset, #endif /* NTPSHM_ENABLE */ /* *INDENT-ON* */ }; #endif /* defined(_PROTO__ENABLE) && defined(BINARY_ENABLE) */