Provided by: libhamlib-utils_4.3.1-1build2_amd64 
NAME
rigctld - TCP radio control daemon
SYNOPSIS
rigctld [-hlLouV] [-m id] [-r device] [-p device] [-d device] [-P type] [-D type] [-s baud] [-c id]
[-T IPADDR] [-t number] [-C parm=val] [-X seconds] [-v[-Z]]
DESCRIPTION
The rigctld program is a radio control daemon that handles client requests via TCP sockets. This allows
multiple user programs to share one radio (this needs more development). Multiple radios can be
controlled on different TCP ports by use of multiple rigctld processes. Note that multiple
processes/ports are also necessary if some clients use extended responses and/or vfo mode. So up to 4
processes/ports may be needed for each combination of extended response/vfo mode. The syntax of the
commands are the same as rigctl(1). It is hoped that rigctld will be especially useful for client
authors using languages such as Perl, Python, PHP, and others.
rigctld communicates to a client through a TCP socket using text commands shared with rigctl. The
protocol is simple, commands are sent to rigctld on one line and rigctld responds to get commands with
the requested values, one per line, when successful, otherwise, it responds with one line “RPRT x”, where
‘x’ is a negative number indicating the error code. Commands that do not return values respond with the
line “RPRT x”, where ‘x’ is ‘0’ when successful, otherwise is a regative number indicating the error
code. Each line is terminated with a newline ‘\n’ character. This protocol is primarily for use by the
NET rigctl (radio model 2) backend.
A separate Extended Response Protocol extends the above behavior by echoing the received command string
as a header, any returned values as a key: value pair, and the “RPRT x” string as the end of response
marker which includes the Hamlib success or failure value. See the PROTOCOL section for details.
Consider using this protocol for clients that will interact with rigctld directly through a TCP socket.
Keep in mind that Hamlib is BETA level software. While a lot of backend libraries lack complete rotator
support, the basic functions are usually well supported.
Please report bugs and provide feedback at the e-mail address given in the BUGS section below. Patches
and code enhancements sent to the same address are welcome.
OPTIONS
This program follows the usual GNU command line syntax. Short options that take an argument may have the
value follow immediately or be separated by a space. Long options starting with two dashes (‘-’) require
an ‘=’ between the option and any argument.
Here is a summary of the supported options:
-m, --model=id
Select radio model number.
See model list (use “rigctl -l”).
Note: rigctl (or third party software using the C API) will use radio model 2 for NET rigctl (this
model number is not used for rigctld even though it shows in the model list).
-r, --rig-file=device
Use device as the file name of the port connected to the radio.
Often a serial port, but could be a USB to serial adapter. Typically /dev/ttyS0, /dev/ttyS1,
/dev/ttyUSB0, etc. on Linux, COM1, COM2, etc. on MS Windows. The BSD flavors and Mac OS/X have
their own designations. See your system's documentation.
The special string “uh-rig” may be given to enable micro-ham device support.
-p, --ptt-file=device
Use device as the file name of the Push-To-Talk device using a device file as described above.
-d, --dcd-file=device
Use device as the file name of the Data Carrier Detect device using a device file as described
above.
-P, --ptt-type=type
Use type of Push-To-Talk device.
Supported types are ‘RIG’ (CAT command), ‘DTR’, ‘RTS’, ‘PARALLEL’, ‘NONE’, overriding PTT type
defined in the rig's backend.
Some side effects of this command are that when type is set to DTR, read PTT state comes from the
Hamlib frontend, not read from the radio. When set to NONE, PTT state cannot be read or set even
if rig backend supports reading/setting PTT status from the rig.
-D, --dcd-type=type
Use type of Data Carrier Detect device.
Supported types are ‘RIG’ (CAT command), ‘DSR’, ‘CTS’, ‘CD’, ‘PARALLEL’, ‘NONE’.
-s, --serial-speed=baud
Set serial speed to baud rate.
Uses maximum serial speed from radio backend capabilities (set by -m above) as the default.
-c, --civaddr=id
Use id as the CI-V address to communicate with the rig.
Only useful for Icom and some Ten-Tec rigs.
Note: The id is in decimal notation, unless prefixed by 0x, in which case it is hexadecimal.
-T, --listen-addr=IPADDR
Use IPADDR as the listening IP address.
The default is ANY (0.0.0.0).
rigctld can be run and connected to like this:
rigctld
rigctl -m 2
rigctl -m 2 -r 127.0.0.1
rigctl -m 2 -r localhost
rigctl -m 2 -r 192.168.1.1 (local IP address)
rigctl -m 2 -r ::1 (on Linux rigctld doesn't listen on IPV6 by default)
rigctld -T 127.0.0.1
rigctl -m 2
rigctl -m 2 -r 127.0.0.1
Exceptions:
rigctl -m 2 -r localhost (only works if localhost is IPV4 address)
rigctld -T localhost (will set up on IPV4 or IPV6 based on localhost)
rigctl -m 2
rigctl -m 2 -r localhost
rigctl -m 2 ip6-localhost
Exceptions:
rigctl -m 2 -r 127.0.0.1 (only works if localhost is IPV4 address)
rigctl -m 2 -r ::1 (only works localhost is IPV6 address)
On Linux only where ip6-localhost is fe00::0:
rigctld -T ip6-localhost
rigctl -m 2 -r ip6-localhost
-t, --port=number
Use number as the TCP listening port.
The default is 4532.
Note: As rotctld's default port is 4533, it is advisable to use even numbered ports for rigctld,
e.g. 4532, 4534, 4536, etc.
-L, --show-conf
List all config parameters for the radio defined with -m above.
-C, --set-conf=parm=val[,parm=val]
Set radio configuration parameter(s), e.g. stop_bits=2.
Use the -L option above for a list of configuration parameters for a given model number.
-u, --dump-caps
Dump capabilities for the radio defined with -m above and exit.
-l, --list
List all model numbers defined in Hamlib and exit.
The list is sorted by model number.
Note: In Linux the list can be scrolled back using Shift-PageUp/Shift-PageDown, or using the
scrollbars of a virtual terminal in X or the cmd window in Windows. The output can be piped to
more(1) or less(1), e.g. “rigctl -l | more”.
-o, --vfo
Enable vfo mode.
An extra VFO argument will be required in front of each appropriate command (except set_vfo).
Otherwise, ‘currVFO’ is used when this option is not set and an extra VFO argument is not used.
See chk_vfo below.
-v, --verbose
Set verbose mode, cumulative (see DIAGNOSTICS below).
-W, --twiddle_timeout=seconds
Enables timeout when VFO twiddling is detected. Some functions will be ignored.
Should only be needed when controlling software should be "paused" so you can move the VFO.
Continuous movement extends the timeout.
-x, --uplink=option
1=Sub, 2=Main
For GPredict use to ignore get_freq for Sub or Main uplink VFO.
Should allow downlink VFO movement without confusing GPredict or the uplink
-Z, --debug-time-stamps
Enable time stamps for the debug messages.
Use only in combination with the -v option as it generates no output on its own.
-h, --help
Show a summary of these options and exit.
-V, --version
Show version of rigctl and exit.
Note: Some options may not be implemented by a given backend and will return an error. This is most
likely to occur with the --set-conf and --show-conf options.
Please note that the backend for the radio to be controlled, or the radio itself may not support some
commands. In that case, the operation will fail with a Hamlib error code.
COMMANDS
Commands can be sent over the TCP socket either as a single char, or as a long command name plus the
value(s) space separated on one ‘\n’ terminated line. See PROTOCOL.
Since most of the Hamlib operations have a set and a get method, an upper case letter will be used for
set methods whereas the corresponding lower case letter refers to the get method. Each operation also
has a long name; prepend a backslash, ‘\’, to send a long command name.
Example (Perl): “print $socket "\\dump_caps\n";” to see what the radio's backend can do (Note: In Perl
and many other languages a ‘\’ will need to be escaped with a preceding ‘\’ so that even though two
backslash characters appear in the code, only one will be passed to rigctld. This is a possible bug,
beware!).
Note: The backend for the radio to be controlled, or the radio itself may not support some commands. In
that case, the operation will fail with a Hamlib error message.
Here is a summary of the supported commands (In the case of set commands the quoted italicized string is
replaced by the value in the description. In the case of get commands the quoted italicized string is
the key name of the value returned.):
F, set_freq 'Frequency'
Set 'Frequency', in Hz.
Frequency may be a floating point or integer value.
f, get_freq
Get 'Frequency', in Hz.
Returns an integer value and the VFO hamlib thinks is active. Note that some rigs (e.g. all
Icoms) cannot track current VFO so hamlib can get out of sync with the rig if the user presses rig
buttons like the VFO. rigctld clients should ensure they set the intended VFO or use vfo mode.
M, set_mode 'Mode' 'Passband'
Set 'Mode' and 'Passband'.
Mode is a token: ‘USB’, ‘LSB’, ‘CW’, ‘CWR’, ‘RTTY’, ‘RTTYR’, ‘AM’, ‘FM’, ‘WFM’, ‘AMS’, ‘PKTLSB’,
‘PKTUSB’, ‘PKTFM’, ‘ECSSUSB’, ‘ECSSLSB’, ‘FA’, ‘SAM’, ‘SAL’, ‘SAH’, ‘DSB’.
Passband is in Hz as an integer, or ‘0’ for the radio backend default.
Note: Passing a ‘?’ (query) as the first argument instead of a Mode token will return a space
separated list of radio backend supported Modes. Use this to determine the supported Modes of a
given radio backend.
m, get_mode
Get 'Mode' and 'Passband'.
Returns Mode as a token and Passband in Hz as in set_mode above.
V, set_vfo 'VFO'
Set 'VFO'.
VFO is a token: ‘VFOA’, ‘VFOB’, ‘VFOC’, ‘currVFO’, ‘VFO’, ‘MEM’, ‘Main’, ‘Sub’, ‘TX’, ‘RX’.
In VFO mode (see --vfo option above) only a single VFO parameter is required:
$ rigctl -m 229 -r /dev/rig -o
Rig command: V
VFO: VFOB
Rig command:
v, get_vfo
Get current 'VFO'.
Returns VFO as a token as in set_vfo above.
J, set_rit 'RIT'
Set 'RIT'.
RIT is in Hz and can be + or -. A value of ‘0’ resets RIT (Receiver Incremental Tuning) to match
the VFO frequency.
Note: RIT needs to be explicitly activated or deactivated with the set_func command. This allows
setting the RIT offset independently of its activation and allows RIT to remain active while
setting the offset to ‘0’.
j, get_rit
Get 'RIT' in Hz.
Returned value is an integer.
Z, set_xit 'XIT'
Set 'XIT'.
XIT is in Hz and can be + or -. A value of ‘0’ resets XIT (Transmitter Incremental Tuning) to
match the VFO frequency.
Note: XIT needs to be explicitly activated or deactivated with the set_func command. This allows
setting the XIT offset independently of its activation and allows XIT to remain active while
setting the offset to ‘0’.
z, get_xit
Get 'XIT' in Hz.
Returned value is an integer.
T, set_ptt 'PTT'
Set 'PTT'.
PTT is a value: ‘0’ (RX), ‘1’ (TX), ‘2’ (TX mic), or ‘3’ (TX data).
t, get_ptt
Get 'PTT' status.
Returns PTT as a value in set_ptt above.
S, set_split_vfo 'Split' 'TX VFO'
Set 'Split' mode.
Split is either ‘0’ = Normal or ‘1’ = Split.
Set 'TX VFO'.
TX VFO is a token: ‘VFOA’, ‘VFOB’, ‘VFOC’, ‘currVFO’, ‘VFO’, ‘MEM’, ‘Main’, ‘Sub’, ‘TX’, ‘RX’.
s, get_split_vfo
Get 'Split' mode.
Split is either ‘0’ = Normal or ‘1’ = Split.
Get 'TX VFO'.
TX VFO is a token as in set_split_vfo above.
I, set_split_freq 'Tx Frequency'
Set 'TX Frequency', in Hz.
Frequency may be a floating point or integer value.
i, get_split_freq
Get 'TX Frequency', in Hz.
Returns an integer value.
X, set_split_mode 'TX Mode' 'TX Passband'
Set 'TX Mode' and 'TX Passband'.
TX Mode is a token: ‘USB’, ‘LSB’, ‘CW’, ‘CWR’, ‘RTTY’, ‘RTTYR’, ‘AM’, ‘FM’, ‘WFM’, ‘AMS’,
‘PKTLSB’, ‘PKTUSB’, ‘PKTFM’, ‘ECSSUSB’, ‘ECSSLSB’, ‘FA’, ‘SAM’, ‘SAL’, ‘SAH’, ‘DSB’.
TX Passband is in Hz as an integer, or ‘0’ for the radio backend default.
Note: Passing a ‘?’ (query) as the first argument instead of a TX Mode token will return a space
separated list of radio backend supported TX Modes. Use this to determine the supported TX Modes
of a given radio backend.
x, get_split_mode
Get 'TX Mode' and 'TX Passband'.
Returns TX Mode as a token and TX Passband in Hz as in set_split_mode above.
Y, set_ant 'Antenna'
Set 'Antenna' number (‘0’, ‘1’, ‘2’, ...).
Option depends on rig..for Icom it probably sets the Tx & Rx antennas as in the IC-7851. See your
manual for rig specific option values. Most rigs don't care about the option.
For the IC-7851 (and perhaps others) it means this:
1 = TX/RX = ANT1
2 = TX/RX = ANT2
3 = TX/RX = ANT3
4 = TX/RX = ANT1/ANT4
5 = TX/RX = ANT2/ANT4
6 = TX/RX = ANT3/ANT4
y, get_ant
Get 'Antenna' number (‘0’, ‘1’, ‘2’, ...).
b, send_morse 'Morse'
Send 'Morse' symbols.
0x8b, get_dcd
Get 'DCD' (squelch) status: ‘0’ (Closed) or ‘1’ (Open).
R, set_rptr_shift 'Rptr Shift'
Set 'Rptr Shift'.
Rptr Shift is one of: ‘+’, ‘-’, or something else for ‘None’.
r, get_rptr_shift
Get 'Rptr Shift'.
Returns ‘+’, ‘-’, or ‘None’.
O, set_rptr_offs 'Rptr Offset'
Set 'Rptr Offset', in Hz.
o, get_rptr_offs
Get 'Rptr Offset', in Hz.
C, set_ctcss_tone 'CTCSS Tone'
Set 'CTCSS Tone', in tenths of Hz.
c, get_ctcss_tone
Get 'CTCSS Tone', in tenths of Hz.
D, set_dcs_code 'DCS Code'
Set 'DCS Code'.
d, get_dcs_code
Get 'DCS Code'.
0x90, set_ctcss_sql 'CTCSS Sql'
Set 'CTCSS Sql' tone, in tenths of Hz.
0x91, get_ctcss_sql
Get 'CTCSS Sql' tone, in tenths of Hz.
0x92, set_dcs_sql 'DCS Sql'
Set 'DCS Sql' code.
0x93, get_dcs_sql
Get 'DCS Sql'
code.
N, set_ts 'Tuning Step'
Set 'Tuning Step', in Hz.
n, get_ts
Get 'Tuning Step', in Hz.
U, set_func 'Func' 'Func Status'
Set 'Func' and 'Func Status'.
Func is a token: ‘FAGC’, ‘NB’, ‘COMP’, ‘VOX’, ‘TONE’, ‘TSQL’, ‘SBKIN’, ‘FBKIN’, ‘ANF’, ‘NR’,
‘AIP’, ‘APF’, ‘MON’, ‘MN’, ‘RF’, ‘ARO’, ‘LOCK’, ‘MUTE’, ‘VSC’, ‘REV’, ‘SQL’, ‘ABM’, ‘BC’, ‘MBC’,
‘RIT’, ‘AFC’, ‘SATMODE’, ‘SCOPE’, ‘RESUME’, ‘TBURST’, ‘TUNER’, ‘XIT’.
Func Status is a non null value for “activate” or “de-activate” otherwise, much as TRUE/FALSE
definitions in the C language (true is non-zero and false is zero, ‘0’).
Note: Passing a ‘?’ (query) as the first argument instead of a Func token will return a space
separated list of radio backend supported set function tokens. Use this to determine the
supported functions of a given radio backend.
u, get_func 'Func'
Get 'Func Status'.
Returns Func Status as a non null value for the Func token given as in set_func above.
Note: Passing a ‘?’ (query) as the first argument instead of a Func token will return a space
separated list of radio backend supported get function tokens. Use this to determine the
supported functions of a given radio backend.
L, set_level 'Level' 'Level Value'
Set 'Level' and 'Level Value'.
Level is a token: ‘PREAMP’, ‘ATT’, ‘VOX’, ‘AF’, ‘RF’, ‘SQL’, ‘IF’, ‘APF’, ‘NR’, ‘PBT_IN’,
‘PBT_OUT’, ‘CWPITCH’, ‘RFPOWER’, ‘RFPOWER_METER’, ‘RFPOWER_METER_WATTS’, ‘MICGAIN’, ‘KEYSPD’,
‘NOTCHF’, ‘COMP’, ‘AGC’, ‘BKINDL’, ‘BAL’, ‘METER’, ‘VOXGAIN’, ‘ANTIVOX’, ‘SLOPE_LOW’,
‘SLOPE_HIGH’, ‘RAWSTR’, ‘SWR’, ‘ALC’, ‘STRENGTH’.
The Level Value can be a float or an integer value. For the AGC token the value is one of ‘0’ =
OFF, ‘1’ = SUPERFAST, ‘2’ = FAST, ‘3’ = SLOW, ‘4’ = USER, ‘5’ = MEDIUM, ‘6’ = AUTO.
Note: Passing a ‘?’ (query) as the first argument instead of a Level token will return a space
separated list of radio backend supported set level tokens. Use this to determine the supported
levels of a given radio backend.
l, get_level 'Level'
Get 'Level Value'.
Returns Level Value as a float or integer for the Level token given as in set_level above.
Note: Passing a ‘?’ (query) as the first argument instead of a Level token will return a space
separated list of radio backend supported get level tokens. Use this to determine the supported
levels of a given radio backend.
P, set_parm 'Parm' 'Parm Value'
Set 'Parm' and 'Parm Value'.
Parm is a token: ‘ANN’, ‘APO’, ‘BACKLIGHT’, ‘BEEP’, ‘TIME’, ‘BAT’, ‘KEYLIGHT’.
Note: Passing a ‘?’ (query) as the first argument instead of a Parm token will return a space
separated list of radio backend supported set parameter tokens. Use this to determine the
supported parameters of a given radio backend.
p, get_parm 'Parm'
Get 'Parm Value'.
Returns Parm Value as a float or integer for the Parm token given as in set_parm above.
Note: Passing a ‘?’ (query) as the first argument instead of a Parm token will return a space
separated list of radio backend supported get parameter tokens. Use this to determine the
supported parameters of a given radio backend.
B, set_bank 'Bank'
Set 'Bank'.
Sets the current memory bank number.
E, set_mem 'Memory#'
Set 'Memory#' channel number.
e, get_mem
Get 'Memory#' channel number.
G, vfo_op 'Mem/VFO Op'
Perform a 'Mem/VFO Op'.
Mem/VFO Operation is a token: ‘CPY’, ‘XCHG’, ‘FROM_VFO’, ‘TO_VFO’, ‘MCL’, ‘UP’, ‘DOWN’, ‘BAND_UP’,
‘BAND_DOWN’, ‘LEFT’, ‘RIGHT’, ‘TUNE’, ‘TOGGLE’.
Note: Passing a ‘?’ (query) as the first argument instead of a Mem/VFO Op token will return a
space separated list of radio backend supported Set Mem/VFO Op tokens. Use this to determine the
supported Mem/VFO Ops of a given radio backend.
g, scan 'Scan Fct' 'Scan Channel'
Perform a 'Scan Fct' on a 'Scan Channel'.
Scan Function is a token: ‘STOP’, ‘MEM’, ‘SLCT’, ‘PRIO’, ‘PROG’, ‘DELTA’, ‘VFO’, ‘PLT’.
Scan Channel is an integer (maybe?).
Note: Passing a ‘?’ (query) as the first argument instead of a Scan Fct token will return a space
separated list of radio backend supported Scan Function tokens. Use this to determine the
supported Scan Functions of a given radio backend.
H, set_channel 'Channel'
Set memory 'Channel' data.
Not implemented yet.
h, get_channel 'readonly'
Get channel memory.
If readonly!=0 then only channel data is returned and rig remains on the current channel. If
readonly=0 then rig will be set to the channel requested. data.
A, set_trn 'Transceive'
Set 'Transceive' mode.
Transcieve is a token: ‘OFF’, ‘RIG’, ‘POLL’.
Transceive is a mechanism for radios to report events without a specific call for information.
Note: Passing a ‘?’ (query) as the first argument instead of a Transceive token will return a
space separated list of radio backend supported Transceive mode tokens. Use this to determine the
supported Transceive modes of a given radio backend.
a, get_trn
Get 'Transceive' mode.
Transceive mode (reporting event) as in set_trn above.
*, reset 'Reset'
Perform rig 'Reset'.
Reset is a value: ‘0’ = None, ‘1’ = Software reset, ‘2’ = VFO reset, ‘4’ = Memory Clear reset, ‘8’
= Master reset.
Since these values are defined as a bitmask in include/hamlib/rig.h, it should be possible to AND
these values together to do multiple resets at once, if the backend supports it or supports a
reset action via rig control at all.
0x87, set_powerstat 'Power Status'
Set 'Power Status'.
Power Status is a value: ‘0’ = Power Off, ‘1’ = Power On, ‘2’ = Power Standby.
0x88, get_powerstat
Get 'Power Status' as in set_powerstat above.
0x89, send_dtmf 'Digits'
Set DTMF 'Digits'.
0x8a, recv_dtmf
Get DTMF 'Digits'.
_, get_info
Get misc information about the rig.
0xf5, get_rig_info
Get misc information about the rig vfos and other info.
0xf3, get_vfo_info 'VFO'
Get misc information about a specific vfo.
dump_state
Return certain state information about the radio backend.
1, dump_caps
Not a real rig remote command, it just dumps capabilities, i.e. what the backend knows about this
model, and what it can do.
TODO: Ensure this is in a consistent format so it can be read into a hash, dictionary, etc. Bug
reports requested.
Note: This command will produce many lines of output so be very careful if using a fixed length
array! For example, running this command against the Dummy backend results in over 5kB of text
output.
VFO parameter not used in 'VFO mode'.
2, power2mW 'Power [0.0..1.0]' 'Frequency' 'Mode'
Returns 'Power mW'.
Converts a Power value in a range of 0.0...1.0 to the real transmit power in milli-Watts
(integer).
'Frequency' and 'Mode' also need to be provided as output power may vary according to these
values.
VFO parameter is not used in VFO mode.
4, mW2power 'Power mW' 'Frequency' 'Mode'
Returns 'Power [0.0..1.0]'.
Converts the real transmit power in milli-Watts (integer) to a Power value in a range of 0.0 ...
1.0.
'Frequency' and 'Mode' also need to be provided as output power may vary according to these
values.
VFO parameter is not used in VFO mode.
chk_vfo
Returns “CHKVFO 1\n” (single line only) if rigctld was invoked with the -o/--vfo option and
“CHKVFO 0\n” if not.
When in VFO mode the client will need to pass 'VFO' as the first parameter to set or get commands.
VFO is one of the strings defined in set_vfo above.
set_vfo_opt 'Status'
Set 'Status'
Set vfo option Status 1=on or 0=off This is the same as using the -o switch for rigctl and
ritctld. This can be dyamically changed while running.
PROTOCOL
There are two protocols in use by rigctld, the Default Protocol and the Extended Response Protocol.
The Default Protocol is intended primarily for the communication between Hamlib library functions and
rigctld (“NET rigctl”, available using radio model ‘2’).
The Extended Response Protocol is intended to be used with scripts or other programs interacting directly
with rigctld as consistent feedback is provided.
Default Protocol
The Default Protocol is intentionally simple. Commands are entered on a single line with any needed
values. In practice, reliable results are obtained by terminating each command string with a newline
character, ‘\n’.
Example set frequency and mode commands (Perl code (typed text shown in bold)):
print $socket "F 14250000\n";
print $socket "\\set_mode LSB 2400\n"; # escape leading '\'
A one line response will be sent as a reply to set commands, “RPRT x\n” where x is the Hamlib error code
with ‘0’ indicating success of the command.
Responses from rigctld get commands are text values and match the same tokens used in the set commands.
Each value is returned on its own line. On error the string “RPRT x\n” is returned where x is the Hamlib
error code.
Example get frequency (Perl code):
print $socket "f\n";
"14250000\n"
Most get functions return one to three values. A notable exception is the dump_caps command which returns
many lines of key:value pairs.
This protocol is primarily used by the “NET rigctl” (rigctl model 2) backend which allows applications
already written for Hamlib's C API to take advantage of rigctld without the need of rewriting application
code. An application's user can select rotator model 2 (“NET rigctl”) and then set rig_pathname to
“localhost:4532” or other network host:port (set by the -T/-t options, respectively, above).
Extended Response Protocol
The Extended Response protocol adds several rules to the strings returned by rigctld and adds a rule for
the command syntax.
1. The command received by rigctld is echoed with its long command name followed by the value(s) (if any)
received from the client terminated by the specified response separator as the first record of the
response.
2. The last record of each block is the string “RPRT x\n” where x is the numeric return value of the
Hamlib backend function that was called by the command.
3. Any records consisting of data values returned by the radio backend are prepended by a string
immediately followed by a colon then a space and then the value terminated by the response separator.
e.g. “Frequency: 14250000\n” when the command was prepended by ‘+’.
4. All commands received will be acknowledged by rigctld
with records from rules 1 and 2. Records from rule 3 are only returned when data values must be
returned to the client.
An example response to a set_mode command sent from the shell prompt (note the prepended ‘+’):
$ echo "+M USB 2400" | nc -w 1 localhost 4532
set_mode: USB 2400
RPRT 0
In this case the long command name and values are returned on the first line and the second line contains
the end of block marker and the numeric radio backend return value indicating success.
An example response to a get_mode query:
$ echo "+\get_mode" | nc -w 1 localhost 4532
get_mode:
Mode: USB
Passband: 2400
RPRT 0
Note: The ‘\’ is still required for the long command name even with the ERP character.
In this case, as no value is passed to rigctld, the first line consists only of the long command name.
The final line shows that the command was processed successfully by the radio backend.
Invoking the Extended Response Protocol requires prepending a command with a punctuation character. As
shown in the examples above, prepending a ‘+’ character to the command results in the responses being
separated by a newline character (‘\n’). Any other punctuation character recognized by the C ispunct()
function except ‘\’, ‘?’, or ‘_’ will cause that character to become the response separator and the
entire response will be on one line.
Separator character summary:
‘+’ Each record of the response is appended with a newline (‘\n’).
‘;’, ‘|’, or, ‘,’
Each record of the response is appended by the given character resulting in entire response on one
line.
These are common record separators for text representations of spreadsheet data, etc.
‘?’ Reserved for help in rigctl.
‘_’ Reserved for get_info short command
‘#’ Reserved for comments when reading a command file script.
Note: Other punctuation characters have not been tested! Use at your own risk.
For example, invoking a get_mode query with a leading ‘;’ returns:
get_mode:;Mode: USB;Passband: 2400;RPRT 0
Or, using the pipe character ‘|’ returns:
get_mode:|Mode: USB|Passband: 2400|RPRT 0
And a set_mode command prepended with a ‘|’ returns:
set_mode: USB 2400|RPRT 0
Such a format will allow reading a response as a single event using a preferred response separator.
Other punctuation characters have not been tested!
The following commands have been tested with the Extended Response protocol and the included testctld.pl
Perl script:
set_freq, get_freq, set_split_freq, get_split_freq, set_mode, get_mode, set_split_mode,
get_split_mode, set_vfo, get_vfo, set_split_vfo, get_split_vfo, set_rit, get_rit, set_xit,
get_xit, set_ptt, get_ptt, power2mW, mW2power, dump_caps.
DIAGNOSTICS
The -v, --verbose option allows different levels of diagnostics to be output to stderr and correspond to
-v for BUG, -vv for ERR, -vvv for WARN, -vvvv for VERBOSE, or -vvvvv for TRACE.
A given verbose level is useful for providing needed debugging information to the email address below.
For example, TRACE output shows all of the values sent to and received from the radio which is very
useful for radio backend library development and may be requested by the developers.
EXAMPLES
Start rigctld for a Yaesu FT-920 using a USB-to-serial adapter and backgrounding:
$ rigctld -m 1014 -r /dev/ttyUSB1 &
Start rigctld for a Yaesu FT-920 using a USB-to-serial adapter while setting baud rate and stop bits, and
backgrounding:
$ rigctld -m 1014 -r /dev/ttyUSB1 -s 4800 -C stop_bits=2 &
Start rigctld for an Elecraft K3 using COM2 on MS Windows:
$ rigctld -m 2029 -r COM2
Connect to the already running rigctld and set the frequency to 14.266 MHz with a 1 second read timeout
using the default protocol from the shell prompt:
$ echo "\set_freq 14266000" | nc -w 1 localhost 4532P
Connect to a running rigctld with rigctl on the local host:
$ rigctl -m2
SECURITY
No authentication whatsoever; DO NOT leave this TCP port open wide to the Internet. Please ask if
stronger security is needed or consider using a Secure Shell (ssh(1)) tunnel.
As rigctld does not need any greater permissions than rigctl, it is advisable to not start rigctld as
“root” or another system user account in order to limit any vulnerability.
BUGS
The daemon is not detaching and backgrounding itself.
No method to exit the daemon so the kill(1) command must be used to terminate it.
Multiple clients using the daemon may experience contention with the connected radio.
Report bugs to:
Hamlib Developer mailing list
COPYING
This file is part of Hamlib, a project to develop a library that simplifies radio, rotator, and amplifier
control functions for developers of software primarily of interest to radio amateurs and those interested
in radio communications.
Copyright © 2000-2010 Stephane Fillod
Copyright © 2000-2018 the Hamlib Group (various contributors)
Copyright © 2011-2020 Nate Bargmann
This is free software; see the file COPYING for copying conditions. There is NO warranty; not even for
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
SEE ALSO
kill(1), rigctl(1), ssh(1), hamlib(7)
COLOPHON
Links to the Hamlib Wiki, Git repository, release archives, and daily snapshot archives are available via
hamlib.org.
Hamlib 2020-09-09 RIGCTLD(1)