This is the gpsd to-do list. If you're viewing it with Emacs, try doing Ctl-C Ctl-t and browsing through the outline headers. Ctl-C Ctl-a will unfold them again. For contribution guidelines and internals documentation, please see the "Hacking Guide" on the project website. The list of bugs exposed by gpsd in other software has moved to the "Upstream Bugs" page on the project website. ** Documentation ** We now have two different calibration procedures in the Time Service HOWTO. One was written by Gary and is based on peerstats; the other by Sanjeev Gupta and is based on loopstats. Can these be merged? How do we know which is appropriate to use when? What could we build in the way of tools and visualization aids to make the calibration process less annoying? ** Things to do when we can break compatibility ** In gps_data_t make device subtype longer. 128 chars long sounds good. In gps_data_t, save PPS precision; this will require creating a pps struct. In gps_fix_t, maybe change time away from float to timespec? Add MMSI sequence number fields to AIS type 7. ** Bugs in gpsd and its clients: *** Tracker bugs See the GPSD bug tracker on the project website, but don't be surprised if it's empty or very sparse. Our rate of new defects per month is quite low. *** RFC2783 bugs **** detangle TIOCMIWAIT and RFC2783 Currently, the code for RFC2783 seems to depend (logically) on TIOCMIWAIT support. However, RFC2783 (and really, no standard) defines TIOCMIWAIT, and NetBSD (and probably FreeBSD) do not implement it. So, there really should be two separate implementations, one that works with TIOCMIWAIT (and thus only on Linux and OpenBSD) and one that assumes only RFC2783 (and thus works on Linux, FreeBSD and NetBSD, as well as any future system that complies with RFC2783 and uses the serial port for time_pps_init). *** Client bugs *** Dispatcher/network issues **** Reading AISHub data via UDP confuses xgps with short writes To reproduce, "gpsd -D 5 -N -n udp://192.168.1.3:12346" (only works inside thyrsus.com) and run xgps. Probably some kind of packet aggregation issue as it doesn't happen with test logs. *** Driver issues **** RTCM3 analysis is incomplete We can presently decode RTCM3 messages of type 1001-1014, 1029, and 1033. This is not the complete set. We need more test data with different types in them, and a copy of the RTCM3 standard at latest revision (all we have is revision 3). The support for unpacking RTCM3 sentences in the client library is limited to 1001, 1002, 1007, 1008, 1009, 1010, 1014, and 1033. There are some design issues with the baby JSON parser that are going to make extending this set difficult. **** Reporting code for specialized Type 6 and 8 AIS messages is incomplete. This one is mine and Kurt Schwehr's. Support is currently nearly complete; the only missing cases are a handful of IMO 236 and IMO 289 message 6 and 8 subtypes - specifically, 6/23, 8/21, 8/22, 8/24, and 8/26. ** New features ** *** Time tracking Our goal is to be independent of the system clock. **** Maybe apply wraparound compensation **** See *** Optionally use tag blocks in NMEA output Ed W. writes: >Feature request: I would like to see an option to get the NMEA data >out of gpsd, but augmented with a timestamp on each sentence and >details of which input fed in the data. TAG blocks appear to solve >that problem perfectly. So the feature request is simply an option >that inserts a TAG block for each emitted sentence from GPSd with a >timestamp and some handle which references the input method for the >sentence. > >I think all this is effectively emitted with the JSON output (?), so >really this is just adding it to the NMEA sentence output options via >the TAG structure However, Iván Sánchez Ortega notes: >There is one *big* problem with using TAG blocks to timestamp the sentences. >The standards (as far as I/we know) say that the timestamp is **either** the >number of seconds **or** milliseconds since the UNIX epoch, but we do **not** >know if the initial state should be secs, msecs, or nothing. We do not know >how clients reading that TAGblocked NMEA stream should ask GPSD to switch the >timestamp units (or enable/disable them). > >There are a few sentences introduced in NMEA 4.00 that supposedly allow that - >the client sends a sentence to the server, and then the server starts >TAGblocking sentences. But, alas, there are no examples anywhere. > >>From my personal experience, the way to know if a TAGblocked timestamp is in >seconds or milliseconds is ask the people in charge of setting up the >device/service. Perhaps some devices output only secs/msecs, and some other >accept the NMEA 4.00 TAGblock configuration sentences. > >I, for one, would like to see the secs/msecs problem solved before GPSD >embarks on the enterprise of writing TAGblocks. If someone is working on this, please see: http://www.nmea.org/Assets/0183_errata_tag_block_final.pdf **** Speed, mode and rate-changes in client-mode gpsctl. Baud rate and mode changes work in direct mode but are not reliable in client mode. **** Optional dump of GPS configuration using gpsctl. Some settings, like antenna in use, dead-reckoning mode, would be helpful to see. **** Integrate 1PPS into profiling *** We caw now *really* measure latency from GPS top of second when it has 1PPS. Add this capability to gpsprof and revise the "Where's the Latency?" white paper. *** Low-power autoconfiguration in the uBlox driver *** Anthony Stirk writes on Wed May 21 06:09:00 2014: The low power modes are really good on the ublox modules (especially the MAX7's) however a word of warning. We use the 1 sec cyclic mode on our balloon trackers but if the module looses satellites or is jammed out (cheap Chinese cameras do it) the ublox modules seem to hang and become unresponsive. To mitigate against this you need to put the module back in max performance mode as soon as the satellites drops below 4. I'm not sure for most applications the low power mode needs to be used at all on the newer ublox modules. The values for the MAX-7Q are 22mA (6Q 50mA) under acquire, tracking (i.e locked and in max performance) current at is 17mA (39mA 6Q) and power saving reduces this to 5mA or less (15mA on the 6Q). We've observed the issue on the 6 and 7 series. A possibility: drop the chip to low-power mode when it can see > 4 sats, revert to normal otherwise. *** Make subframe reports available in the C API. gpsd now reports subframes when they're available, but the C client library doesn't yet parse them. A sample program to dump the SUBFRAME data would also be useful. Gary Miller has this in his queue. *** Write advanced features for TNT Revolution device The baud-rate switcher in the TNT driver needs to be tested. gpsmon could support a number of TNT configuration commands, including unit changes. See http://gpsd.googlecode.com/truenorth-reference.pdf for possibilities. Jon Schlueter has one of these on a flock machine, so testing shouldn't be difficult. *** Enable flocktest on the Debian server farm Debian server farm boxes have a screwy chrooted environment setup. flocktest needs to be modified to deal with it. *** Finish gpssim It's blocked on skyview computation. *** Complete and test the speed/parity/stopbit methods in the drivers These are used for the '?DEVICE' command. All work for 8N1. **** superstar2: not implemented (driver is unfinished) **** italk: not implemented (but could be) **** tsip: speed tested, parity and stop-bit switching not tested **** sirf: speed tested, parity and stop-bit switching not tested **** evermore: speed tested, rejects parity/stopbit setting **** ubx: fully implemented, parity and stop-bit switching not tested **** zodiac: fully implemented, not tested **** navcom.c: speed tested, rejects parity/stopbit setting SiRF, UBX, TSIP, and even Zodiac can support non-8N1 modes; these need to be tested. *** Per-driver restore of changed config settings on exit. This is a solved problem for generic NMEA, EverMore, TripMate, EarthMate, TNT, Zodiac, and RTCM104 drivers (if only because they don't configure any device settings). The SiRF driver now restores NMEA when necessary. It also restores some (but not all) of the things it tweaks in binary mode -- at the moment, just the Navigation Parameters from message 0x13. With more work, we should be able to do a full revert. The TSIP driver changes its per-cycle sentence inventory and thus needs some state-restore logic. This can be done; the same packet 0x35 we use to configure it can be sent in a no-argument mode to query the current sentence mix for later restore. The FV18 changes its per-cycle sentence inventory to include GSAs. It is possible to query that inventory, though we don't have code to do it yet. Garmin devices are a mess. We reconfigure those heavily, and we don't know if there's any way to capture their configuration state before we do it. The iTrax02 driver sets SYNCMODE to start navigation messages without checking to see if it's already on, and stops navigation methods on wrapup. It also forces the set of sentences issued. There doesn't seem to be any way to query these settings. ** Future features (?) *** Industry-standard format dumping of raw satellite data It would be useful to be able to report raw GPS data (pseudoranges, clock, doppler carrier) from any GPS device that can report pseudoranges etc. This belongs in the daemon because the device drivers are already doing the packet-cracking needed to get the data off the chips. Several commodity chipsets (ANTARIS, iTrax3, SiRF and Trimble) readily output enough data to make this a chore, rather than a hard problem. Probably the best way to do this would be to add support for unscaled output of pseudoranges in SKY and add clock and doppler carrier phase. This JSON could then be interpreted by a client program and dumped in various standard formats. Currently the RT-IGS format is looking like the favorite for implementation; it's a fairly lightweight protocol, flexible enough to handle all the quantities required, and it is actually in use in production reference networks. RT-IGS is also a packet-oriented format, rather than a file-oriented format like RINEX. *** Support for more survey / professional / up-scale receivers. Devices such as the Javad JNSCore, Hemisphere Crescent, Septentrio AsteRx and PolaRx, NovAtel Superstar2 and OEMV, Thales (Magellan Professional) AC12 and DG14 would all be welcome. Of course, these are not $50 USB mice... Local variables: mode: outline paragraph-separate: "[ ]*$" end: