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New Model #8803 » kguv8h.py

Latest dev-driver, removed vhf1 band and fixed some limits and other minor tweaks - Pavel Milanes, 05/04/2021 11:39 AM

 
# Copyright 2019 Pavel Milanes CO7WT <pavelmc@gmail.com>
#
# Based on the work of Krystian Struzik <toner_82@tlen.pl>
# who figured out the crypt used and made possible the
# Wuoxun KG-UV8D Plus driver, in which this work is based.
#
# This program is free software: you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <http://www.gnu.org/licenses/>.

"""Wouxun KG-UV8H radio management module"""

import time
import os
import logging
from chirp import util, chirp_common, bitwise, memmap, errors, directory
from chirp.settings import RadioSetting, RadioSettingGroup, \
RadioSettingValueBoolean, RadioSettingValueList, \
RadioSettingValueInteger, RadioSettingValueString, \
RadioSettings

LOG = logging.getLogger(__name__)

CMD_ID = 128 # \x80
CMD_END = 129 # \x81
CMD_RD = 130 # \82
CMD_WR = 131 # \83

MEM_VALID = 158

AB_LIST = ["A", "B"]
STEPS = [2.5, 5.0, 6.25, 10.0, 12.5, 25.0, 50.0, 100.0]
STEP_LIST = [str(x) for x in STEPS]
ROGER_LIST = ["Off", "Begin", "End", "Both"]
TIMEOUT_LIST = ["Off"] + [str(x) + "s" for x in range(15, 901, 15)]
VOX_LIST = ["Off"] + ["%s" % x for x in range(1, 10)]
BANDWIDTH_LIST = ["Narrow", "Wide"]
VOICE_LIST = ["Off", "On"]
LANGUAGE_LIST = ["Chinese", "English"]
SCANMODE_LIST = ["TO", "CO", "SE"]
PF1KEY_LIST = ["Call", "VFTX"]
PF3KEY_LIST = ["Disable", "Scan", "Lamp", "Tele Alarm", "SOS-CH", "Radio"]
WORKMODE_LIST = ["VFO", "Channel No.", "Ch. No.+Freq.", "Ch. No.+Name"]
BACKLIGHT_LIST = ["Always On"] + [str(x) + "s" for x in range(1, 21)] + \
["Always Off"]
OFFSET_LIST = ["+", "-"]
PONMSG_LIST = ["Bitmap", "Battery Volts"]
SPMUTE_LIST = ["QT", "QT+DTMF", "QT*DTMF"]
DTMFST_LIST = ["DT-ST", "ANI-ST", "DT-ANI", "Off"]
DTMF_TIMES = ["%s" % x for x in range(50, 501, 10)]
RPTSET_LIST = ["", "X-DIRRPT", "X-TWRPT"] # TODO < what is index 0?
ALERTS = [1750, 2100, 1000, 1450]
ALERTS_LIST = [str(x) for x in ALERTS]
PTTID_LIST = ["Begin", "End", "Both"]
LIST_10 = ["Off"] + ["%s" % x for x in range(1, 11)]
SCANGRP_LIST = ["All"] + ["%s" % x for x in range(1, 11)]
SCQT_LIST = ["Decoder", "Encoder", "All"]
SMUTESET_LIST = ["Off", "Tx", "Rx", "Tx/Rx"]
POWER_LIST = ["Lo", "Hi"]
HOLD_TIMES = ["Off"] + ["%s" % x for x in range(100, 5001, 100)]
RPTMODE_LIST = ["Radio", "Repeater"]

# memory slot 0 is not used, start at 1 (so need 1000 slots, not 999)
# structure elements whose name starts with x are currently unidentified

_MEM_FORMAT = """
#seekto 0x0044;
struct {
u32 rx_start;
u32 rx_stop;
u32 tx_start;
u32 tx_stop;
} uhf_limits;

#seekto 0x0054;
struct {
u32 rx_start;
u32 rx_stop;
u32 tx_start;
u32 tx_stop;
} vhf_limits;

#seekto 0x0400;
struct {
u8 oem1[8];
u8 unknown[2];
u8 unknown2[10];
u8 unknown3[10];
u8 unknown4[8];
u8 model[10];
u8 version[6];
u8 date[8];
u8 unknown5[1];
u8 oem2[8];
} oem_info;

#seekto 0x0480;
struct {
u16 lower;
u16 upper;
} scan_groups[10];

#seekto 0x0500;
struct {
u8 call_code[6];
} call_groups[20];

#seekto 0x0580;
struct {
char call_name[6];
} call_group_name[20];

#seekto 0x0800;
struct {
u8 ponmsg;
char dispstr[15];
u8 x0810;
u8 x0811;
u8 x0812;
u8 x0813;
u8 x0814;
u8 voice;
u8 timeout;
u8 toalarm;
u8 channel_menu;
u8 power_save;
u8 autolock;
u8 keylock;
u8 beep;
u8 stopwatch;
u8 vox;
u8 scan_rev;
u8 backlight;
u8 roger_beep;
u8 x0822[6];
u8 x0823[6];
u16 pri_ch;
u8 ani_sw;
u8 ptt_delay;
u8 ani_code[6];
u8 dtmf_st;
u8 bcl_a;
u8 bcl_b;
u8 ptt_id;
u8 prich_sw;
u8 rpt_set;
u8 rpt_spk;
u8 rpt_ptt;
u8 alert;
u8 pf1_func;
u8 pf3_func;
u8 x0843;
u8 workmode_a;
u8 workmode_b;
u8 dtmf_tx_time;
u8 dtmf_interval;
u8 main_ab;
u16 work_cha;
u16 work_chb;
u8 x084d;
u8 x084e;
u8 x084f;
u8 x0850;
u8 x0851;
u8 x0852;
u8 x0853;
u8 x0854;
u8 rpt_mode;
u8 language;
u8 x0857;
u8 x0858;
u8 x0859;
u8 x085a;
u8 x085b;
u8 x085c;
u8 x085d;
u8 x085e;
u8 single_display;
u8 ring_time;
u8 scg_a;
u8 scg_b;
u8 x0863;
u8 rpt_tone;
u8 rpt_hold;
u8 scan_det;
u8 sc_qt;
u8 x0868;
u8 smuteset;
u8 callcode;
} settings;

#seekto 0x0880;
struct {
u32 rxfreq;
u32 txoffset;
u16 rxtone;
u16 txtone;
u8 scrambler:4,
unknown1:2,
power:1,
unknown2:1;
u8 unknown3:1,
shift_dir:2
unknown4:1,
compander:1,
mute_mode:2,
iswide:1;
u8 step;
u8 squelch;
} vfoa;

#seekto 0x08c0;
struct {
u32 rxfreq;
u32 txoffset;
u16 rxtone;
u16 txtone;
u8 scrambler:4,
unknown1:2,
power:1,
unknown2:1;
u8 unknown3:1,
shift_dir:2
unknown4:1,
compander:1,
mute_mode:2,
iswide:1;
u8 step;
u8 squelch;
} vfob;

#seekto 0x0900;
struct {
u32 rxfreq;
u32 txfreq;
u16 rxtone;
u16 txtone;
u8 scrambler:4,
unknown1:2,
power:1,
unknown2:1;
u8 unknown3:2,
scan_add:1,
unknown4:1,
compander:1,
mute_mode:2,
iswide:1;
u16 padding;
} memory[1000];

#seekto 0x4780;
struct {
u8 name[8];
u8 unknown[4];
} names[1000];

#seekto 0x7670;
u8 valid[1000];
"""

# Support for the Wouxun KG-UV8H radio
# Serial coms are at 19200 baud
# The data is passed in variable length records
# Record structure:
# Offset Usage
# 0 start of record (\x7c)
# 1 Command (\x80 Identify \x81 End/Reboot \x82 Read \x83 Write)
# 2 direction (\xff PC-> Radio, \x00 Radio -> PC)
# 3 length of payload (excluding header/checksum) (n)
# 4 payload (n bytes)
# 4+n+1 checksum - byte sum (% 256) of bytes 1 -> 4+n
#
# Memory Read Records:
# the payload is 3 bytes, first 2 are offset (big endian),
# 3rd is number of bytes to read
# Memory Write Records:
# the maximum payload size (from the Wouxun software) seems to be 66 bytes
# (2 bytes location + 64 bytes data).

class KGUV8TRadio(chirp_common.Alias):
VENDOR = "Wuoxun"
MODEL = "KG-UV8H"

@directory.register
class KGUV8HRadio(chirp_common.CloneModeRadio,
chirp_common.ExperimentalRadio):

"""Wouxun KG-UV8H"""
VENDOR = "Wouxun"
MODEL = "KG-UV8H"
_model = "KG-UV8D-B"
_file_ident = "UV8H"
BAUD_RATE = 19200
POWER_LEVELS = [chirp_common.PowerLevel("L", watts=1),
chirp_common.PowerLevel("H", watts=5)]
_mmap = ""
ALIASES = [KGUV8TRadio,]

def _checksum(self, data):
cs = 0
for byte in data:
cs += ord(byte)
return chr(cs % 256)

def _write_record(self, cmd, payload = None):
# build the packet
_header = '\x7c' + chr(cmd) + '\xff'

_length = 0
if payload:
_length = len(payload)

# update the length field
_header += chr(_length)

if payload:
# calculate checksum then add it with the payload to the packet and encrypt
crc = self._checksum(_header[1:] + payload)
payload += crc
_header += self.encrypt(payload)
else:
# calculate and add encrypted checksum to the packet
crc = self._checksum(_header[1:])
_header += self.strxor(crc, '\x57')

try:
self.pipe.write(_header)
except Exception, e:
raise errors.RadioError("Failed to communicate with radio: %s" % e)

def _read_record(self):
# read 4 chars for the header
_header = self.pipe.read(4)
if len(_header) != 4:
raise errors.RadioError('Radio did not respond')
_length = ord(_header[3])
_packet = self.pipe.read(_length)
_rcs_xor = _packet[-1]
_packet = self.decrypt(_packet)
_cs = ord(self._checksum(_header[1:] + _packet))
# read the checksum and decrypt it
_rcs = ord(self.strxor(self.pipe.read(1), _rcs_xor))
return (_rcs != _cs, _packet)

def decrypt(self, data):
result = ''
for i in range(len(data)-1, 0, -1):
result += self.strxor(data[i], data[i - 1])
result += self.strxor(data[0], '\x57')
return result[::-1]

def encrypt(self, data):
result = self.strxor('\x57', data[0])
for i in range(1, len(data), 1):
result += self.strxor(result[i - 1], data[i])
return result

def strxor (self, xora, xorb):
return chr(ord(xora) ^ ord(xorb))

# Identify the radio
#
# A Gotcha: the first identify packet returns a bad checksum, subsequent
# attempts return the correct checksum... (well it does on my radio!)
#
# The ID record returned by the radio also includes the current frequency range
# as 4 bytes big-endian in 10Hz increments
#
# Offset
# 0:10 Model, zero padded (Looks for 'KG-UV8D-B')

@classmethod
def match_model(cls, filedata, filename):
id = cls._file_ident
return cls._file_ident in filedata[0x426:0x430]

def _identify(self):
"""Do the identification dance"""
for _i in range(0, 10):
self._write_record(CMD_ID)
_chksum_err, _resp = self._read_record()
LOG.debug("Got:\n%s" % util.hexprint(_resp))
if _chksum_err:
LOG.error("Checksum error: retrying ident...")
time.sleep(0.100)
continue
LOG.debug("Model %s" % util.hexprint(_resp[0:9]))
if _resp[0:9] == self._model:
return
if len(_resp) == 0:
raise Exception("Radio not responding")
else:
raise Exception("Unable to identify radio")

def _finish(self):
self._write_record(CMD_END)

def process_mmap(self):
self._memobj = bitwise.parse(_MEM_FORMAT, self._mmap)

def sync_in(self):
try:
self._mmap = self._download()
except errors.RadioError:
raise
except Exception, e:
raise errors.RadioError("Failed to communicate with radio: %s" % e)
self.process_mmap()

def sync_out(self):
self._upload()

# TODO: Load all memory.
# It would be smarter to only load the active areas and none of
# the padding/unused areas. Padding still need to be investigated.
def _download(self):
"""Talk to a wouxun KG-UV8H and do a download"""
try:
self._identify()
return self._do_download(0, 32768, 64)
except errors.RadioError:
raise
except Exception, e:
LOG.exception('Unknown error during download process')
raise errors.RadioError("Failed to communicate with radio: %s" % e)

def _do_download(self, start, end, blocksize):
# allocate & fill memory
image = ""
for i in range(start, end, blocksize):
req = chr(i / 256) + chr(i % 256) + chr(blocksize)
self._write_record(CMD_RD, req)
cs_error, resp = self._read_record()
if cs_error:
LOG.debug(util.hexprint(resp))
raise Exception("Checksum error on read")
# LOG.debug("Got:\n%s" % util.hexprint(resp))
image += resp[2:]
if self.status_fn:
status = chirp_common.Status()
status.cur = i
status.max = end
status.msg = "Cloning from radio"
self.status_fn(status)
self._finish()
return memmap.MemoryMap(''.join(image))

def _upload(self):
"""Talk to a wouxun KG-UV8H and do a upload"""
try:
self._identify()
self._do_upload(0, 32768, 64)
except errors.RadioError:
raise
except Exception, e:
raise errors.RadioError("Failed to communicate with radio: %s" % e)
return

def _do_upload(self, start, end, blocksize):
ptr = start
for i in range(start, end, blocksize):
req = chr(i / 256) + chr(i % 256)
chunk = self.get_mmap()[ptr:ptr + blocksize]
self._write_record(CMD_WR, req + chunk)
LOG.debug(util.hexprint(req + chunk))
cserr, ack = self._read_record()
LOG.debug(util.hexprint(ack))
j = ord(ack[0]) * 256 + ord(ack[1])
if cserr or j != ptr:
raise Exception("Radio did not ack block %i" % ptr)
ptr += blocksize
if self.status_fn:
status = chirp_common.Status()
status.cur = i
status.max = end
status.msg = "Cloning to radio"
self.status_fn(status)
self._finish()

def get_features(self):
rf = chirp_common.RadioFeatures()
rf.has_settings = True
rf.has_ctone = True
rf.has_rx_dtcs = True
rf.has_cross = True
rf.has_tuning_step = False
rf.has_bank = False
rf.can_odd_split = True
rf.valid_skips = ["", "S"]
rf.valid_tmodes = ["", "Tone", "TSQL", "DTCS", "Cross"]
rf.valid_cross_modes = [
"Tone->Tone",
"Tone->DTCS",
"DTCS->Tone",
"DTCS->",
"->Tone",
"->DTCS",
"DTCS->DTCS",
]
rf.valid_modes = ["FM", "NFM"]
rf.valid_power_levels = self.POWER_LEVELS
rf.valid_name_length = 8
rf.valid_duplexes = ["", "-", "+", "split", "off"]
rf.valid_bands = [(137000000, 175000000), # supports 2m
(400000000, 480000000)] # supports 70cm
rf.valid_characters = chirp_common.CHARSET_ASCII
rf.memory_bounds = (1, 999) # 999 memories
rf.valid_tuning_steps = STEPS
return rf

@classmethod
def get_prompts(cls):
rp = chirp_common.RadioPrompts()
rp.experimental = \
('This driver is experimental.\n'
'\n'
'Please keep a copy of your memories with the original software '
'if you treasure them, this driver is new and may contain'
' bugs.\n'
'\n'
)
return rp

def get_raw_memory(self, number):
return repr(self._memobj.memory[number])

def _get_tone(self, _mem, mem):
def _get_dcs(val):
code = int("%03o" % (val & 0x07FF))
pol = (val & 0x8000) and "R" or "N"
return code, pol

tpol = False
if _mem.txtone != 0xFFFF and (_mem.txtone & 0x2800) == 0x2800:
tcode, tpol = _get_dcs(_mem.txtone)
mem.dtcs = tcode
txmode = "DTCS"
elif _mem.txtone != 0xFFFF and _mem.txtone != 0x0:
mem.rtone = (_mem.txtone & 0x7fff) / 10.0
txmode = "Tone"
else:
txmode = ""

rpol = False
if _mem.rxtone != 0xFFFF and (_mem.rxtone & 0x2800) == 0x2800:
rcode, rpol = _get_dcs(_mem.rxtone)
mem.rx_dtcs = rcode
rxmode = "DTCS"
elif _mem.rxtone != 0xFFFF and _mem.rxtone != 0x0:
mem.ctone = (_mem.rxtone & 0x7fff) / 10.0
rxmode = "Tone"
else:
rxmode = ""

if txmode == "Tone" and not rxmode:
mem.tmode = "Tone"
elif txmode == rxmode and txmode == "Tone" and mem.rtone == mem.ctone:
mem.tmode = "TSQL"
elif txmode == rxmode and txmode == "DTCS" and mem.dtcs == mem.rx_dtcs:
mem.tmode = "DTCS"
elif rxmode or txmode:
mem.tmode = "Cross"
mem.cross_mode = "%s->%s" % (txmode, rxmode)

# always set it even if no dtcs is used
mem.dtcs_polarity = "%s%s" % (tpol or "N", rpol or "N")

LOG.debug("Got TX %s (%i) RX %s (%i)" %
(txmode, _mem.txtone, rxmode, _mem.rxtone))

def get_memory(self, number):
_mem = self._memobj.memory[number]
_nam = self._memobj.names[number]

mem = chirp_common.Memory()
mem.number = number
_valid = self._memobj.valid[mem.number]
LOG.debug("%d %s", number, _valid == MEM_VALID)
if _valid != MEM_VALID:
mem.empty = True
return mem
else:
mem.empty = False

mem.freq = int(_mem.rxfreq) * 10

if _mem.txfreq == 0xFFFFFFFF:
# TX freq not set
mem.duplex = "off"
mem.offset = 0
elif int(_mem.rxfreq) == int(_mem.txfreq):
mem.duplex = ""
mem.offset = 0
elif abs(int(_mem.rxfreq) * 10 - int(_mem.txfreq) * 10) > 70000000:
mem.duplex = "split"
mem.offset = int(_mem.txfreq) * 10
else:
mem.duplex = int(_mem.rxfreq) > int(_mem.txfreq) and "-" or "+"
mem.offset = abs(int(_mem.rxfreq) - int(_mem.txfreq)) * 10

for char in _nam.name:
if char != 0:
mem.name += chr(char)
mem.name = mem.name.rstrip()

self._get_tone(_mem, mem)

mem.skip = "" if bool(_mem.scan_add) else "S"

mem.power = self.POWER_LEVELS[_mem.power]
mem.mode = _mem.iswide and "FM" or "NFM"
return mem

def _set_tone(self, mem, _mem):
def _set_dcs(code, pol):
val = int("%i" % code, 8) + 0x2800
if pol == "R":
val += 0x8000
return val

rx_mode = tx_mode = None
rxtone = txtone = 0x0000

if mem.tmode == "Tone":
tx_mode = "Tone"
rx_mode = None
txtone = int(mem.rtone * 10) + 0x8000
elif mem.tmode == "TSQL":
rx_mode = tx_mode = "Tone"
rxtone = txtone = int(mem.ctone * 10) + 0x8000
elif mem.tmode == "DTCS":
tx_mode = rx_mode = "DTCS"
txtone = _set_dcs(mem.dtcs, mem.dtcs_polarity[0])
rxtone = _set_dcs(mem.dtcs, mem.dtcs_polarity[1])
elif mem.tmode == "Cross":
tx_mode, rx_mode = mem.cross_mode.split("->")
if tx_mode == "DTCS":
txtone = _set_dcs(mem.dtcs, mem.dtcs_polarity[0])
elif tx_mode == "Tone":
txtone = int(mem.rtone * 10) + 0x8000
if rx_mode == "DTCS":
rxtone = _set_dcs(mem.rx_dtcs, mem.dtcs_polarity[1])
elif rx_mode == "Tone":
rxtone = int(mem.ctone * 10) + 0x8000

_mem.rxtone = rxtone
_mem.txtone = txtone

LOG.debug("Set TX %s (%i) RX %s (%i)" %
(tx_mode, _mem.txtone, rx_mode, _mem.rxtone))

def set_memory(self, mem):
number = mem.number

_mem = self._memobj.memory[number]
_nam = self._memobj.names[number]

if mem.empty:
_mem.set_raw("\x00" * (_mem.size() / 8))
self._memobj.valid[number] = 0
self._memobj.names[number].set_raw("\x00" * (_nam.size() / 8))
return

_mem.rxfreq = int(mem.freq / 10)
if mem.duplex == "off":
_mem.txfreq = 0xFFFFFFFF
elif mem.duplex == "split":
_mem.txfreq = int(mem.offset / 10)
elif mem.duplex == "off":
for i in range(0, 4):
_mem.txfreq[i].set_raw("\xFF")
elif mem.duplex == "+":
_mem.txfreq = int(mem.freq / 10) + int(mem.offset / 10)
elif mem.duplex == "-":
_mem.txfreq = int(mem.freq / 10) - int(mem.offset / 10)
else:
_mem.txfreq = int(mem.freq / 10)
_mem.scan_add = int(mem.skip != "S")
_mem.iswide = int(mem.mode == "FM")
# set the tone
self._set_tone(mem, _mem)
# set the scrambler and compander to off by default
_mem.scrambler = 0
_mem.compander = 0
# set the power
if mem.power:
_mem.power = self.POWER_LEVELS.index(mem.power)
else:
_mem.power = True
# set to mute mode to QT (not QT+DTMF or QT*DTMF) by default
_mem.mute_mode = 0

for i in range(0, len(_nam.name)):
if i < len(mem.name) and mem.name[i]:
_nam.name[i] = ord(mem.name[i])
else:
_nam.name[i] = 0x0
self._memobj.valid[mem.number] = MEM_VALID

def _get_settings(self):
_settings = self._memobj.settings
_vfoa = self._memobj.vfoa
_vfob = self._memobj.vfob
cfg_grp = RadioSettingGroup("cfg_grp", "Configuration")
vfoa_grp = RadioSettingGroup("vfoa_grp", "VFO A Settings")
vfob_grp = RadioSettingGroup("vfob_grp", "VFO B Settings")
key_grp = RadioSettingGroup("key_grp", "Key Settings")
lmt_grp = RadioSettingGroup("lmt_grp", "Frequency Limits")
uhf_lmt_grp = RadioSettingGroup("uhf_lmt_grp", "UHF")
vhf_lmt_grp = RadioSettingGroup("vhf_lmt_grp", "VHF")
oem_grp = RadioSettingGroup("oem_grp", "OEM Info")

lmt_grp.append(vhf_lmt_grp);
lmt_grp.append(uhf_lmt_grp);
group = RadioSettings(cfg_grp, vfoa_grp, vfob_grp,
key_grp, lmt_grp, oem_grp)

#
# Configuration Settings
#
rs = RadioSetting("channel_menu", "Menu available in channel mode",
RadioSettingValueBoolean(_settings.channel_menu))
cfg_grp.append(rs)
rs = RadioSetting("ponmsg", "Poweron message",
RadioSettingValueList(
PONMSG_LIST, PONMSG_LIST[_settings.ponmsg]))
cfg_grp.append(rs)
rs = RadioSetting("voice", "Voice Guide",
RadioSettingValueBoolean(_settings.voice))
cfg_grp.append(rs)
rs = RadioSetting("language", "Language",
RadioSettingValueList(LANGUAGE_LIST,
LANGUAGE_LIST[_settings.
language]))
cfg_grp.append(rs)
rs = RadioSetting("timeout", "Timeout Timer",
RadioSettingValueList(
TIMEOUT_LIST, TIMEOUT_LIST[_settings.timeout]))
cfg_grp.append(rs)
rs = RadioSetting("toalarm", "Timeout Alarm",
RadioSettingValueInteger(0, 10, _settings.toalarm))
cfg_grp.append(rs)
rs = RadioSetting("roger_beep", "Roger Beep",
RadioSettingValueList(ROGER_LIST,
ROGER_LIST[_settings.roger_beep]))
cfg_grp.append(rs)
rs = RadioSetting("power_save", "Power save",
RadioSettingValueBoolean(_settings.power_save))
cfg_grp.append(rs)
rs = RadioSetting("autolock", "Autolock",
RadioSettingValueBoolean(_settings.autolock))
cfg_grp.append(rs)
rs = RadioSetting("keylock", "Keypad Lock",
RadioSettingValueBoolean(_settings.keylock))
cfg_grp.append(rs)
rs = RadioSetting("beep", "Keypad Beep",
RadioSettingValueBoolean(_settings.beep))
cfg_grp.append(rs)
rs = RadioSetting("stopwatch", "Stopwatch",
RadioSettingValueBoolean(_settings.stopwatch))
cfg_grp.append(rs)
rs = RadioSetting("backlight", "Backlight",
RadioSettingValueList(BACKLIGHT_LIST,
BACKLIGHT_LIST[_settings.
backlight]))
cfg_grp.append(rs)
rs = RadioSetting("dtmf_st", "DTMF Sidetone",
RadioSettingValueList(DTMFST_LIST,
DTMFST_LIST[_settings.
dtmf_st]))
cfg_grp.append(rs)
rs = RadioSetting("ani_sw", "ANI-ID Switch",
RadioSettingValueBoolean(_settings.ani_sw))
cfg_grp.append(rs)
rs = RadioSetting("ptt_id", "PTT-ID Delay",
RadioSettingValueList(PTTID_LIST,
PTTID_LIST[_settings.ptt_id]))
cfg_grp.append(rs)
rs = RadioSetting("ring_time", "Ring Time",
RadioSettingValueList(LIST_10,
LIST_10[_settings.ring_time]))
cfg_grp.append(rs)
rs = RadioSetting("scan_rev", "Scan Mode",
RadioSettingValueList(SCANMODE_LIST,
SCANMODE_LIST[_settings.
scan_rev]))
cfg_grp.append(rs)
rs = RadioSetting("vox", "VOX",
RadioSettingValueList(LIST_10,
LIST_10[_settings.vox]))
cfg_grp.append(rs)
rs = RadioSetting("prich_sw", "Priority Channel Switch",
RadioSettingValueBoolean(_settings.prich_sw))
cfg_grp.append(rs)
rs = RadioSetting("pri_ch", "Priority Channel",
RadioSettingValueInteger(1, 999, _settings.pri_ch))
cfg_grp.append(rs)
rs = RadioSetting("rpt_mode", "Radio Mode",
RadioSettingValueList(RPTMODE_LIST,
RPTMODE_LIST[_settings.
rpt_mode]))
cfg_grp.append(rs)
rs = RadioSetting("rpt_set", "Repeater Setting",
RadioSettingValueList(RPTSET_LIST,
RPTSET_LIST[_settings.
rpt_set]))
cfg_grp.append(rs)
rs = RadioSetting("rpt_spk", "Repeater Mode Speaker",
RadioSettingValueBoolean(_settings.rpt_spk))
cfg_grp.append(rs)
rs = RadioSetting("rpt_ptt", "Repeater PTT",
RadioSettingValueBoolean(_settings.rpt_ptt))
cfg_grp.append(rs)
rs = RadioSetting("dtmf_tx_time", "DTMF Tx Duration",
RadioSettingValueList(DTMF_TIMES,
DTMF_TIMES[_settings.
dtmf_tx_time]))
cfg_grp.append(rs)
rs = RadioSetting("dtmf_interval", "DTMF Interval",
RadioSettingValueList(DTMF_TIMES,
DTMF_TIMES[_settings.
dtmf_interval]))
cfg_grp.append(rs)
rs = RadioSetting("alert", "Alert Tone",
RadioSettingValueList(ALERTS_LIST,
ALERTS_LIST[_settings.alert]))
cfg_grp.append(rs)
rs = RadioSetting("rpt_tone", "Repeater Tone",
RadioSettingValueBoolean(_settings.rpt_tone))
cfg_grp.append(rs)
rs = RadioSetting("rpt_hold", "Repeater Hold Time",
RadioSettingValueList(HOLD_TIMES,
HOLD_TIMES[_settings.
rpt_hold]))
cfg_grp.append(rs)
rs = RadioSetting("scan_det", "Scan DET",
RadioSettingValueBoolean(_settings.scan_det))
cfg_grp.append(rs)
rs = RadioSetting("sc_qt", "SC-QT",
RadioSettingValueList(SCQT_LIST,
SCQT_LIST[_settings.sc_qt]))
cfg_grp.append(rs)
rs = RadioSetting("smuteset", "SubFreq Mute",
RadioSettingValueList(SMUTESET_LIST,
SMUTESET_LIST[_settings.
smuteset]))
cfg_grp.append(rs)

#
# VFO A Settings
#
rs = RadioSetting("workmode_a", "VFO A Workmode",
RadioSettingValueList(WORKMODE_LIST, WORKMODE_LIST[_settings.workmode_a]))
vfoa_grp.append(rs)
rs = RadioSetting("work_cha", "VFO A Channel",
RadioSettingValueInteger(1, 999, _settings.work_cha))
vfoa_grp.append(rs)
rs = RadioSetting("vfoa.rxfreq", "VFO A Rx Frequency",
RadioSettingValueInteger(
134000000, 520000000, _vfoa.rxfreq * 10, 5000))
vfoa_grp.append(rs)
rs = RadioSetting("vfoa.txoffset", "VFO A Tx Offset",
RadioSettingValueInteger(
0, 520000000, _vfoa.txoffset * 10, 5000))
vfoa_grp.append(rs)
# u16 rxtone;
# u16 txtone;
rs = RadioSetting("vfoa.power", "VFO A Power",
RadioSettingValueList(
POWER_LIST, POWER_LIST[_vfoa.power]))
vfoa_grp.append(rs)
# shift_dir:2
rs = RadioSetting("vfoa.iswide", "VFO A NBFM",
RadioSettingValueList(
BANDWIDTH_LIST, BANDWIDTH_LIST[_vfoa.iswide]))
vfoa_grp.append(rs)
rs = RadioSetting("vfoa.mute_mode", "VFO A Mute",
RadioSettingValueList(
SPMUTE_LIST, SPMUTE_LIST[_vfoa.mute_mode]))
vfoa_grp.append(rs)
rs = RadioSetting("vfoa.step", "VFO A Step (kHz)",
RadioSettingValueList(
STEP_LIST, STEP_LIST[_vfoa.step]))
vfoa_grp.append(rs)
rs = RadioSetting("vfoa.squelch", "VFO A Squelch",
RadioSettingValueList(
LIST_10, LIST_10[_vfoa.squelch]))
vfoa_grp.append(rs)
rs = RadioSetting("bcl_a", "Busy Channel Lock-out A",
RadioSettingValueBoolean(_settings.bcl_a))
vfoa_grp.append(rs)

#
# VFO B Settings
#
rs = RadioSetting("workmode_b", "VFO B Workmode",
RadioSettingValueList(WORKMODE_LIST, WORKMODE_LIST[_settings.workmode_b]))
vfob_grp.append(rs)
rs = RadioSetting("work_chb", "VFO B Channel",
RadioSettingValueInteger(1, 999, _settings.work_chb))
vfob_grp.append(rs)
rs = RadioSetting("vfob.rxfreq", "VFO B Rx Frequency",
RadioSettingValueInteger(
134000000, 520000000, _vfob.rxfreq * 10, 5000))
vfob_grp.append(rs)
rs = RadioSetting("vfob.txoffset", "VFO B Tx Offset",
RadioSettingValueInteger(
0, 520000000, _vfob.txoffset * 10, 5000))
vfob_grp.append(rs)
# u16 rxtone;
# u16 txtone;
rs = RadioSetting("vfob.power", "VFO B Power",
RadioSettingValueList(
POWER_LIST, POWER_LIST[_vfob.power]))
vfob_grp.append(rs)
# shift_dir:2
rs = RadioSetting("vfob.iswide", "VFO B NBFM",
RadioSettingValueList(
BANDWIDTH_LIST, BANDWIDTH_LIST[_vfob.iswide]))
vfob_grp.append(rs)
rs = RadioSetting("vfob.mute_mode", "VFO B Mute",
RadioSettingValueList(
SPMUTE_LIST, SPMUTE_LIST[_vfob.mute_mode]))
vfob_grp.append(rs)
rs = RadioSetting("vfob.step", "VFO B Step (kHz)",
RadioSettingValueList(
STEP_LIST, STEP_LIST[_vfob.step]))
vfob_grp.append(rs)
rs = RadioSetting("vfob.squelch", "VFO B Squelch",
RadioSettingValueList(
LIST_10, LIST_10[_vfob.squelch]))
vfob_grp.append(rs)
rs = RadioSetting("bcl_b", "Busy Channel Lock-out B",
RadioSettingValueBoolean(_settings.bcl_b))
vfob_grp.append(rs)

#
# Key Settings
#
_msg = str(_settings.dispstr).split("\0")[0]
val = RadioSettingValueString(0, 15, _msg)
val.set_mutable(True)
rs = RadioSetting("dispstr", "Display Message", val)
key_grp.append(rs)

dtmfchars = "0123456789"
_codeobj = _settings.ani_code
_code = "".join([dtmfchars[x] for x in _codeobj if int(x) < 0x0A])
val = RadioSettingValueString(3, 6, _code, False)
val.set_charset(dtmfchars)
rs = RadioSetting("ani_code", "ANI Code", val)
def apply_ani_id(setting, obj):
value = []
for j in range(0, 6):
try:
value.append(dtmfchars.index(str(setting.value)[j]))
except IndexError:
value.append(0xFF)
obj.ani_code = value
rs.set_apply_callback(apply_ani_id, _settings)
key_grp.append(rs)

rs = RadioSetting("pf1_func", "PF1 Key function",
RadioSettingValueList(
PF1KEY_LIST,
PF1KEY_LIST[_settings.pf1_func]))
key_grp.append(rs)
rs = RadioSetting("pf3_func", "PF3 Key function",
RadioSettingValueList(
PF3KEY_LIST,
PF3KEY_LIST[_settings.pf3_func]))
key_grp.append(rs)

#
# Limits settings
#
rs = RadioSetting("vhf_limits.rx_start", "VHF RX Lower Limit",
RadioSettingValueInteger(
134000000, 174997500,
self._memobj.vhf_limits.rx_start * 10, 5000))
vhf_lmt_grp.append(rs)
rs = RadioSetting("vhf_limits.rx_stop", "VHF RX Upper Limit",
RadioSettingValueInteger(
134000000, 174997500,
self._memobj.vhf_limits.rx_stop * 10, 5000))
vhf_lmt_grp.append(rs)
rs = RadioSetting("vhf_limits.tx_start", "VHF TX Lower Limit",
RadioSettingValueInteger(
134000000, 174997500,
self._memobj.vhf_limits.tx_start * 10, 5000))
vhf_lmt_grp.append(rs)
rs = RadioSetting("vhf_limits.tx_stop", "VHF TX Upper Limit",
RadioSettingValueInteger(
134000000, 174997500,
self._memobj.vhf_limits.tx_stop * 10, 5000))
vhf_lmt_grp.append(rs)

rs = RadioSetting("uhf_limits.rx_start", "UHF RX Lower Limit",
RadioSettingValueInteger(
400000000, 520000000,
self._memobj.uhf_limits.rx_start * 10, 5000))
uhf_lmt_grp.append(rs)
rs = RadioSetting("uhf_limits.rx_stop", "UHF RX Upper Limit",
RadioSettingValueInteger(
400000000, 520000000,
self._memobj.uhf_limits.rx_stop * 10, 5000))
uhf_lmt_grp.append(rs)
rs = RadioSetting("uhf_limits.tx_start", "UHF TX Lower Limit",
RadioSettingValueInteger(
400000000, 520000000,
self._memobj.uhf_limits.tx_start * 10, 5000))
uhf_lmt_grp.append(rs)
rs = RadioSetting("uhf_limits.tx_stop", "UHF TX Upper Limit",
RadioSettingValueInteger(
400000000, 520000000,
self._memobj.uhf_limits.tx_stop * 10, 5000))
uhf_lmt_grp.append(rs)

#
# OEM info
#
def _decode(lst):
_str = ''.join([chr(c) for c in lst
if chr(c) in chirp_common.CHARSET_ASCII])
return _str

def do_nothing(setting, obj):
return

_str = _decode(self._memobj.oem_info.model)
val = RadioSettingValueString(0, 15, _str)
val.set_mutable(False)
rs = RadioSetting("oem_info.model", "Model", val)
rs.set_apply_callback(do_nothing, _settings)
oem_grp.append(rs)
_str = _decode(self._memobj.oem_info.oem1)
val = RadioSettingValueString(0, 15, _str)
val.set_mutable(False)
rs = RadioSetting("oem_info.oem1", "OEM String 1", val)
rs.set_apply_callback(do_nothing, _settings)
oem_grp.append(rs)
_str = _decode(self._memobj.oem_info.oem2)
val = RadioSettingValueString(0, 15, _str)
val.set_mutable(False)
rs = RadioSetting("oem_info.oem2", "OEM String 2", val)
rs.set_apply_callback(do_nothing, _settings)
oem_grp.append(rs)
_str = _decode(self._memobj.oem_info.version)
val = RadioSettingValueString(0, 15, _str)
val.set_mutable(False)
rs = RadioSetting("oem_info.version", "Software Version", val)
rs.set_apply_callback(do_nothing, _settings)
oem_grp.append(rs)
_str = _decode(self._memobj.oem_info.date)
val = RadioSettingValueString(0, 15, _str)
val.set_mutable(False)
rs = RadioSetting("oem_info.date", "OEM Date", val)
rs.set_apply_callback(do_nothing, _settings)
oem_grp.append(rs)

return group

def get_settings(self):
try:
return self._get_settings()
except:
import traceback
LOG.error("Failed to parse settings: %s", traceback.format_exc())
return None

def set_settings(self, settings):
for element in settings:
if not isinstance(element, RadioSetting):
self.set_settings(element)
continue
else:
try:
if "." in element.get_name():
bits = element.get_name().split(".")
obj = self._memobj
for bit in bits[:-1]:
obj = getattr(obj, bit)
setting = bits[-1]
else:
obj = self._memobj.settings
setting = element.get_name()

if element.has_apply_callback():
LOG.debug("Using apply callback")
element.run_apply_callback()
else:
LOG.debug("Setting %s = %s" % (setting, element.value))
if self._is_freq(element):
setattr(obj, setting, int(element.value)/10)
else:
setattr(obj, setting, element.value)
except Exception, e:
LOG.debug(element.get_name())
raise

def _is_freq(self, element):
return "rxfreq" in element.get_name() or "txoffset" in element.get_name() or "rx_start" in element.get_name() or "rx_stop" in element.get_name() or "tx_start" in element.get_name() or "tx_stop" in element.get_name()
(19-19/37)
Copyright 2023 CHIRP Software LLC