Project

General

Profile

Download (81.7 KB)

New Model #7223 » kguv980p b1.0.py

Mel Terechenok, 10/06/2022 11:20 PM

 
# melvin.terechenok@gmail.com
# modify for KG-UV980P

# 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-UV980P radio management module"""

from pickle import FALSE, TRUE
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, \
RadioSettingValueFloat, RadioSettingValueMap, RadioSettings


LOG = logging.getLogger(__name__)

CMD_ID = 128 # \x80
CMD_END = 129 # \x81
CMD_RD = 130 # \x82
CMD_X1 = 131 # \x83
CMD_WR = 132 # \x84
CMD_X2 = 133 # \x85

MEM_VALID = 0x00

CHARSET_NUMERIC = "0123456789"
CHARSET = "0123456789" + \
":;<=>?@" + \
"ABCDEFGHIJKLMNOPQRSTUVWXYZ" + \
"[\]^_`" + \
"abcdefghijklmnopqrstuvwxyz" + \
"{|}~\x4E" + \
" !\"#$%&'()*+,-./"

MUTE_MODE_MAP = [('QT', 0b01),
('QT*DTMF', 0b10),
('QT+DTMF', 0b11)]
STEPS = [2.5, 5.0, 6.25, 10.0, 12.5, 20.0, 25.0, 30.0, 50.0, 100.0]
STEP_LIST = [str(x) for x in STEPS]
SQL_LIST = [int(i) for i in range(0, 10)]
M_POWER_MAP = [('1 = 20W', 1),
('2 = 10W', 2)]
ROGER_LIST = ["Off", "BOT", "EOT", "Both"]
VOICE_LIST = ["Off", "Chinese", "English"]
SC_REV_MAP = [('Timeout (TO)', 1),
('Carrier (CO)', 2),
('Stop (SE)', 3)]
TOT_MAP = [('%d' % i, int('%02d' % i, 16)) for i in range(1, 61)]
TOA_MAP = [('Off', 0)] + \
[('%d' % i, int('%02d' % i, 16)) for i in range(1, 11)]
RING_MAP = [('Off', 0)] + \
[('%d' % i, int('%02d' % i, 16)) for i in range(1, 11)]
DTMF_ST_LIST = ["Off", "DT-ST", "ANI-ST", "DT+ANI"]
PTT_ID_LIST = ["BOT", "EOT", "Both"]
PTT_ID_MAP = [('BOT', 1),
('EOT', 2),
('Both', 3)]
BACKLIGHT_LIST = ["Off", "Red", "Orange", "Green"]
SPEAKER_MAP = [('SPK_1', 1),
('SPK_2', 2),
('SPK_1+2', 3)]
RPT_MODE_LIST = ["Radio", "X-DIRPT", "X-TWRPT", "RPT-RX", "T-W RPT"]
APO_TIME_LIST = ["Off", "30", "60", "90", "120", "150"]
ALERT_MAP = [('1750', 1),
('2100', 2),
('1000', 3),
('1450', 4)]
FAN_MODE_LIST = ["TX", "Hi-Temp/TX", "Always"]
SCAN_GROUP_LIST = ["All"] + ["%s" % x for x in range(1, 11)]
WORKMODE_MAP = [('VFO', 1),
('Ch. No.', 2),
('Ch. No.+Freq.', 3),
('Ch. No.+Name', 4)]
VFOBAND_MAP = [("150M",0),
("450M",1),
("20M",2),
("50M",3),
("350M",4),
("850M",5)]
AB_LIST = ["A", "B"]
POWER_MAP = [('Low', 0),
('Med', 1),
('Med2', 2),
('High', 3)]
BANDWIDTH_MAP = [('Narrow', 1),
('Wide', 0)]
SCRAMBLER_LIST = ["Off", "1", "2", "3", "4", "5", "6", "7", "8"]
ANS_LIST = ["Off", "Normal", "Strong"]
DTMF_TIMES = [str(x) for x in range(80, 501, 20)]
DTMF_INTERVALS = [str(x) for x in range(60, 501, 20)]
ROGER_TIMES = [str(x) for x in range(20, 1001, 20)]
PTT_ID_DELAY_MAP = [(str(x), x/100) for x in range(100, 1001, 100)]
ROGER_INTERVALS = ROGER_TIMES
TONE_MAP = [('Off', 0x0000)] + \
[('%.1f' % tone, int(tone * 10)) for tone in chirp_common.TONES] + \
[('DN%d' % tone, int(0x8000 + tone))
for tone in chirp_common.DTCS_CODES] + \
[('DI%d' % tone, int(0xC000 + tone))
for tone in chirp_common.DTCS_CODES]
DUPLEX_LIST = ["Off", "Plus", "Minus"]
SC_QT_MAP = [("Decoder - Rx QT/DT MEM", 1), ("Encoder- Tx QT/DT MEM", 2),
("All- RxTx QT/DT MEM", 3)]
HOLD_TIMES = ["Off"] + ["%s" % x for x in range(100, 5001, 100)]
PF1_SETTINGS = ["Off", "Stun", "Kill", "Monitor", "Inspection"]
# 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 0x004c;
struct {
u24 mode_psw;
} mode;

#seekto 0x0060;
struct {
u16 limit_144M_ChA_rx_start;
u16 limit_144M_ChA_rx_stop;
u16 limit_70cm_rx_start;
u16 limit_70cm_rx_stop;
u16 limit_10m_rx_start;
u16 limit_10m_rx_stop;
u16 limit_6m_rx_start;
u16 limit_6m_rx_stop;
u16 limit_350M_rx_start;
u16 limit_350M_rx_stop;
u16 limit_850M_rx_start;
u16 limit_850M_rx_stop;
u16 limit_144M_ChA_tx_start;
u16 limit_144M_ChA_tx_stop;
u16 limit_70cm_tx_start;
u16 limit_70cm_tx_stop;
u16 limit_10m_tx_start;
u16 limit_10m_tx_stop;
u16 limit_6m_tx_start;
u16 limit_6m_tx_stop;
u16 limit_144M_ChB_rx_start;
u16 limit_144M_ChB_rx_stop;
} bandlimits;


#seekto 0x0740;
struct {
u16 FM_radio1;
u16 FM_radio2;
u16 FM_radio3;
u16 FM_radio4;
u16 FM_radio5;
u16 FM_radio6;
u16 FM_radio7;
u16 FM_radio8;
u16 FM_radio9;
u16 FM_radio10;
u16 FM_radio11;
u16 FM_radio12;
u16 FM_radio13;
u16 FM_radio14;
u16 FM_radio15;
u16 FM_radio16;
u16 FM_radio17;
u16 FM_radio18;
u16 FM_radio19;
u16 FM_radio20;
u16 FM_radio21;
u16 FM_radio22;
u8 x76c_pad[196];
u32 vfofreq1; // 0x0830
u32 vfoofst1;
u16 txtone1;
u16 rxtone1;
u8 xunk83C_1:3,
mute1:2,
xunk83C_2:3;
u8 xunk83d_1:1,
xunk83d_2:1,
xunk83d_3:1,
power1:2,
am_mode1:1,
xunk83d_7:1,
narrow1:1;
u8 xunk83e:6,
shft_dir1:2;
u8 xunk83F:3,
compander1:1,
scrambler1:4;
u32 vfofreq2;
u32 vfoofst2;
u16 txtone2;
u16 rxtone2;
u8 xunk84C_1:3,
mute2:2,
xunk84C_2:3;
u8 xunk84d_1:1,
xunk84d_2:1,
xunk84d_3:1,
power2:2,
am_mode2:1,
xunk84d_7:1,
narrow2:1;
u8 xunk84e:6,
shft_dir2:2;
u8 xunk84F:3,
compander2:1,
scrambler2:4;
u32 vfofreq3;
u32 vfoofst3;
u16 txtone3;
u16 rxtone3;
u8 xunk85C_1:3,
mute3:2,
xunk85C_2:3;
u8 xunk85d_1:1,
xunk85d_2:1,
xunk85d_3:1,
power3:2,
am_mode3:1,
xunk85d_7:1,
narrow3:1;
u8 xunk85e:6,
shft_dir3:2;
u8 xunk85F:3,
compander3:1,
scrambler3:4;
u32 vfofreq4;
u32 vfoofst4;
u16 txtone4;
u16 rxtone4;
u8 xunk86C_1:3,
mute4:2,
xunk86C_2:3;
u8 xunk86d_1:1,
xunk86d_2:1,
xunk86d_3:1,
power4:2,
am_mode4:1,
xunk86d_7:1,
narrow4:1;
u8 xunk86e:6,
shft_dir4:2;
u8 xunk86F:3,
compander4:1,
scrambler4:4;
u32 vfofreq5;
u32 vfoofst5;
u16 txtone5;
u16 rxtone5;
u8 xunk87C_1:3,
mute5:2,
xunk87C_2:3;
u8 xunk87d_1:1,
xunk87d_2:1,
xunk87d_3:1,
power5:2,
am_mode5:1,
xunk87d_7:1,
narrow5:1;
u8 xunk87e:6,
shft_dir5:2;
u8 xunk87F:3,
compander5:1,
scrambler5:4;
u32 vfofreq6;
u32 vfoofst6;
u16 txtone6;
u16 rxtone6;
u8 xunk88C_1:3,
mute6:2,
xunk88C_2:3;
u8 xunk88d_1:1,
xunk88d_2:1,
xunk88d_3:1,
power6:2,
am_mode6:1,
xunk88d_7:1,
narrow6:1;
u8 xunk88e:6,
shft_dir6:2;
u8 xunk8F:3,
compander6:1,
scrambler6:4;
u32 vfofreq7;
u32 vfoofst7;
u16 txtone7;
u16 rxtone7;
u8 xunk89C_1:3,
mute7:2,
xunk89C_2:3;
u8 xunk89d_1:1,
xunk89d_2:1,
xunk89d_3:1,
power7:2,
am_mode7:1,
xunk89d_7:1,
narrow7:1;
u8 xunk89e:6,
shft_dir7:2;
u8 xunk89F:3,
compander7:1,
scrambler7:4;
u8 x8a0;
u16 vfochan_a;
u8 x8a3;
u16 vfochan_b;
u16 pri_ch;
u8 x8a8;
u8 x8a9;
u8 scan_a_act;
u8 scan_b_act;
u8 m_pwr;
u8 hold_time_rpt;
u8 spk_cont;
u8 ptt_id_dly;
u8 x8b0;
u8 voice;
u8 tot;
u8 toa;
u8 roger;
u8 sc_rev;
u8 dtmfsf;
u8 ptt_id;
u8 ring;
u8 ani_sw;
u8 rc_sw;
u8 alert;
u8 bcl_a;
u8 prich_sw;
u8 x8bE;
u8 ptt_id_dly;
u8 menu;
u8 x8c1;
u8 beep;
u8 x8c3;
u8 x8c4;
u8 tx_led;
u8 wt_led;
u8 rx_led;
u8 x8c8;
u8 vfomode_a;
u8 vfomode_b;
u8 vfosquelch_a;
u8 vfosquelch_b;
u8 vfostep_a;
u8 vfostep_b;
u8 x8cF;
u8 rpt_spk;
u8 rpt_ptt;
u8 autolock;
u8 apo_time;
u8 low_v;
u8 fan;
u8 rpt_set_model;
u8 pf1_set;
u8 auto_am;
u8 dtmf_time;
u8 dtmf_int;
u8 bcl_b;
u8 rpt_tone;
u8 sc_qt;
u8 vfoband_a;
u8 x8dF;
u8 x8e0;
u8 x8e1;
u8 x8e2;
u8 x8e3;
u8 x8e4;
u8 x8e5;
u8 x8e6;
u8 x8e7;
u8 x8e8;
u8 x8e9;
u8 x8eA;
u8 x8eB;
u8 x8eC;
u8 x8eD;
u8 x8eE;
u8 x8eF;
u8 x8f0;
u8 x8f1;
u8 x8f2;
u8 x8f3;
u8 x8f4;
u8 x8f5;
u8 x8f6;
u8 x8f7;
u8 x8f8;
u8 x8f9;
u8 x8fA;
u8 x8fB;
u8 x8fC;
u8 x8fD;
u8 x8fE;
u8 x8fF;
u8 x900;
u8 x901;
u8 x902;
u8 scan_det;
u8 x904;
u8 thr_vol_tx;
u16 thr_vol_lvl;
u8 x908;
u8 x909;
u8 x90A;
u8 x90B;
u8 x90C;
u8 x90D;
u8 x90E;
u8 x90F;
u8 x910;
u8 x911;
u8 x912;
u8 x913;
u8 x914;
u8 x915;
u8 x916;
u8 x917;
u8 x918;
u8 x919;
u8 x91A;
u8 x91B;
u8 x91C;
u8 x91D;
u8 x91E;
u8 x91F;
u8 x920;
u8 x921;
u8 x922;
u8 x923;
u8 x924;
u8 x925;
u8 x926;
u8 x927;
u8 x928;
u8 x929;
u8 x92A;
u8 x92B;
u8 x92C;
u8 x92D;
u8 x92E;
u8 x92F;
u8 x930;
u8 x931;
u8 x932;
u8 x933;
u8 x934;
u8 x935;
u8 x936;
u8 x937;
u8 x938;
u8 x939;
u8 x93A;
u8 x93B;
u8 x93C;
u8 x93D;
u8 x93E;
u8 x93F;
u16 scanlower1;
u16 scanupper1;
u16 scanlower2;
u16 scanupper2;
u16 scanlower3;
u16 scanupper3;
u16 scanlower4;
u16 scanupper4;
u16 scanlower5;
u16 scanupper5;
u16 scanlower6;
u16 scanupper6;
u16 scanlower7;
u16 scanupper7;
u16 scanlower8;
u16 scanupper8;
u16 scanlower9;
u16 scanupper9;
u16 scanlower10;
u16 scanupper10;
char scanname0[6];
u8 x96E;
u8 x96F;
char scanname1[6];
u8 x976;
u8 x977;
char scanname2[6];
u8 x97E;
u8 x97F;
char scanname3[6];
u8 x986;
u8 x987;
char scanname4[6];
u8 x98E;
u8 x98F;
char scanname5[6];
u8 x996;
u8 x997;
char scanname6[6];
u8 x99E;
u8 x99F;
char scanname7[6];
u8 x9a6;
u8 x9a7;
char scanname8[6];
u8 x9aE;
u8 x9aF;
char scanname9[6];
u8 x9b6;
u8 x9b7;
char scanname10[6];
u8 x9bE;
u8 x9bF;
} settings;


#seekto 0x09f0;
struct {
u32 rxfreq;
u32 txfreq;
u16 txtone;
u16 rxtone;
u8 unknown1:3,
mute_mode:2,
unknown2:3;
u8 named:1,
scan_add:1,
extra_power_bit:1,
power:2,
am_mode:1,
unknownbit2:1,
isnarrow:1;
u8 unknown3:6,
Unknown4_shft_dir:2;
u8 unknown5:3,
compander:1
scrambler:4;
} memory[1000];

#seekto 0x48f8;
struct {
u8 name[8];
} names[1000];

#seekto 0x6fff;
u8 valid[1000];
"""
def _freq_decode(in_freq, bytes=4):
out_freq = 0
for i in range(bytes*2):
out_freq += (in_freq & 0xF) * (10 ** i)
in_freq = in_freq >> 4
if bytes == 4:
return out_freq * 10
elif bytes == 2:
return out_freq * 100000


def _freq_encode(in_freq, bytes=4):
if bytes == 4:
return int('%08d' % (in_freq / 10), 16)
elif bytes == 2:
return int('%04d' % (in_freq / 100000), 16)

def _str_decode(in_str):
out_str = ''
stopchar = FALSE
for c in in_str:
if c !=0x00 and stopchar==FALSE:
if chr(c) in chirp_common.CHARSET_ASCII:
out_str+= chr(c)
else:
out_str+=''
stopchar = TRUE
return out_str


def _str_encode(in_str):
out_str = ''
for c in in_str:
try:
out_str += chr(ord(c))
except ValueError:
pass
while len(out_str) < 8:
out_str += chr(0x00)
return out_str

def _chnum_decode(in_ch):
return int(('%04x' % in_ch)[0:3])


def _chnum_encode(in_ch):
return int('%03d0' % in_ch, 16)

# Support for the Wouxun KG-UV980P 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 - only lower 4 bits of 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 = "Wouxun"
MODEL = "KG-UV980P"


@directory.register
class KG980GRadio(chirp_common.CloneModeRadio,
chirp_common.ExperimentalRadio):

"""Wouxun KG-UV980P"""
VENDOR = "Wouxun"
MODEL = "KG-UV980P"
_model = "KG-UV950R2"
_file_ident = "980P"
BAUD_RATE = 19200

POWER_LEVELS = [chirp_common.PowerLevel("L", watts=1.0),
chirp_common.PowerLevel("M", watts=20.0),
chirp_common.PowerLevel("H", watts=50.0)]
_mmap = ""
ALIASES = [KGUV8TRadio, ]

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

# def _write_record_id(self):
# _header = '\xda\x80\xff\x00\x58'
# LOG.error("Sent:\n%s" % util.hexprint(_header))
# self.pipe.write(_header)

def _write_record(self, cmd, payload=None):
# build the packet
_header = '\xda' + 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)
# Checksum is only the lower 4 bits
crc = chr(ord(crc) & 0xf)
payload += crc
_header += self.encrypt(payload)
else:
# calculate and add encrypted checksum to the packet
crc = self._checksum(_header[1:])
# Checksum is only the lower 4 bits
crc = chr(ord(crc) & 0xf)
_header += self.strxor(crc, '\x57')

try:
LOG.debug("Sent:\n%s" % util.hexprint(_header))
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)
#LOG.debug("header = " % util.hexprint(_header))
if len(_header) != 4:
raise errors.RadioError('Radio did not respond- header length')
_length = ord(_header[3])
_packet = self.pipe.read(_length)
_rcs_xor = _packet[-1]
_packet = self.decrypt(_packet)
_cs = ord(self._checksum(_header[1:] + _packet))
#It appears the checksum is only 4bits
_cs = _cs & 0xf
# LOG.debug("csum = " % _cs)
#read the checksum and decrypt it
_rcs = ord(self.strxor(self.pipe.read(1), _rcs_xor))
_rcs = _rcs & 0xf
# LOG.debug("Rcsum = " % _rcs)
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, 3):
LOG.debug("ID try #"+str(_i))
self._write_record(CMD_ID)
_chksum_err, _resp = self._read_record()
if len(_resp) == 0:
raise Exception("Radio not responding")
else:
LOG.debug("Got:\n%s" % util.hexprint(_resp))
LOG.debug("Model received is %s" % _resp[0:10])
LOG.debug("Model expected is %s" % self._model)
if _chksum_err:
LOG.error("Checksum error: retrying ident...")
time.sleep(0.100)
continue
else:
LOG.debug("checksum passed")
if _resp[0:8] == self._model[0:8]:
LOG.debug("Passed identify")
break
else:
LOG.debug("FAILED to identify")

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-UV980P 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
LOG.debug("Start Download")
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()
LOG.debug("Got:\n%s" % util.hexprint(resp))

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-UV980P and do a upload"""
try:
self._identify()
LOG.debug("Done with Upload Identify")
self._do_upload(1856, 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):
LOG.debug("Start of _do_upload")
ptr = start
LOG.debug("ptr = " + str(ptr))
for i in range(start, end, blocksize):
LOG.debug("Start of loop in _do_upload index = "+str(i))
LOG.debug("Start %i End %i Size %i" % (start, end, blocksize))
req = chr(i/ 256) + chr(i % 256)
LOG.debug("REQ")
chunk = self.get_mmap()[ptr:ptr + blocksize]
LOG.debug("CHUNK")
self._write_record(CMD_X1, req + chunk)
# LOG.debug("Upload-- SENT : " % util.hexprint(_sent))
cserr, ack = self._read_record()
LOG.debug("Upload-- CSUM ERROR : " + str(cserr))
LOG.debug("Upload-- RCVD :\n%s " % 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", "AM", "NAM"]
rf.valid_power_levels = self.POWER_LEVELS
rf.valid_name_length = 8
rf.valid_duplexes = ["", "-", "+", "split", "off"]
# MRT - Open up channel memory freq range to support RxFreq limit expansion
rf.valid_bands = [(26000000, 299999999), # supports VHF
(300000000, 999999999)] # supports UHF

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 and may contain bugs. \n'
'USE AT YOUR OWN RISK \n'
'\nAll CPS available settings are implemented EXCEPT \n'
'---- MODE-PSW \n'
'---- Remote Settings\n'
'\n'
'Mute, Compander and Scrambler are defaulted to '
'QT, OFF , OFF for all channel memories\n\n'
'Development continuing to implement other settings \n'
'found on radio menu\n'
)
return rp

def get_raw_memory(self, number):
return repr(self._memobj.memory[number])
# MRT - corrected the Polarity decoding to match 980P implementation
# use 0x4000 bit mask for R
# MRT - 0x4000 appears to be the bit mask for Inverted DCS tones
# MRT - n DCS Tone will be 0x8xxx values - i DCS Tones will
# be 0xCxxx values.
# MRT - Chirp Uses N for n DCS Tones and R for i DCS Tones
# MRT - 980P encodes DCS tone # in decimal - NOT OCTAL

def _get_tone(self, _mem, mem):
def _get_dcs(val):
code = int("%03d" % (val & 0x07FF))
pol = (val & 0x4000) and "R" or "N"
return code, pol
# MRT - Modified the function below to bitwise AND with 0x4000
# to check for 980P DCS Tone decoding
# MRT 0x8000 appears to be the bit mask for DCS tones
tpol = False
# MRT Beta 1.1 - Fix the txtone compare to 0x8000 - was rxtone.
if _mem.txtone != 0xFFFF and (_mem.txtone & 0x8000) == 0x8000:
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 = ""
# MRT - Modified the function below to bitwise AND with 0x4000
# to check for 980P DCS Tone decoding
rpol = False
if _mem.rxtone != 0xFFFF and (_mem.rxtone & 0x8000) == 0x8000:
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("Mem %d valid is %s", number, _valid == MEM_VALID)
LOG.debug("Rx Freq %s", _mem.rxfreq)
if (_valid != MEM_VALID) & (_mem.rxfreq == 0xFFFFFFFF):
mem.empty = True
return mem
elif (_valid != MEM_VALID) & ((_mem.rxfreq != 0xFFFFFFFF)
or (_mem.rxfreq != 0x00000000)):
LOG.debug("Changed chan %d %s", number, "to valid")
_valid = MEM_VALID
mem.empty = False
else:
_valid = MEM_VALID
mem.empty = False
mem.freq = int(_mem.rxfreq) * 10
_rxfreq = _freq_decode(_mem.rxfreq)
_txfreq = _freq_decode(_mem.txfreq)
mem.freq = _rxfreq
LOG.debug("Tx Freq is "+ str(_mem.txfreq))
if _mem.txfreq == 0xFFFFFFFF:
# TX freq not set
mem.duplex = "off"
mem.offset = 0
elif int(_rxfreq) == int(_txfreq):
mem.duplex = ""
mem.offset = 0
elif abs(_rxfreq - _txfreq) > 70000000:
mem.duplex = "split"
mem.offset = _txfreq
else:
mem.duplex = _rxfreq > _txfreq and "-" or "+"
mem.offset = abs(_rxfreq - _txfreq)

if _mem.named:
mem.name = _str_decode(self._memobj.names[number].name)
else:
mem.name = ''


self._get_tone(_mem, mem)

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

LOG.debug("Mem Power " + str(_mem.power))
pwr_index= _mem.power
if _mem.power == 3:
pwr_index = 2
LOG.debug("Force Mem Power to" + str(pwr_index))
if _mem.power:
mem.power = self.POWER_LEVELS[pwr_index]
else:
mem.power = self.POWER_LEVELS[0]
# mem.am_mode = _mem.power & 0x2

# LOG.debug("Mem Power Index " + str(_mem.power))
# mem.power = self.POWER_LEVELS[_mem.power]

if _mem.am_mode:
if _mem.isnarrow:
mem.mode = "NAM"
else:
mem.mode = "AM"
else:
mem.mode = _mem.isnarrow and "NFM" or "FM"

mem.extra = RadioSettingGroup("Extra", "extra")

_scram = _mem.scrambler
if _mem.scrambler > 8:
_scram = 0
# rs = RadioSetting("scrambler", "Scrambler",
# RadioSettingValueList(SCRAMBLER_LIST,
# SCRAMBLER_LIST[_scram]))
# mem.extra.append(rs)

# rs = RadioSetting("compander", "Compander",
# RadioSettingValueBoolean(_mem.compander))
# mem.extra.append(rs)

# rs = RadioSetting("mute_mode", "Mute",
# RadioSettingValueMap(MUTE_MODE_MAP, _mem.mute_mode))
# mem.extra.append(rs)

return mem

def _set_tone(self, mem, _mem):
def _set_dcs(code, pol):
# MRT Change to 0x8000 to
# set the bit for DCS- code is a decimal version of the code # - NOT OCTAL
val = int("%i" % code, 10) | 0x8000
if pol == "R":
# MRT Change to 0x4000 to set the bit for
# i/R polarity
val += 0x4000
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)
elif mem.tmode == "TSQL":
rx_mode = tx_mode = "Tone"
rxtone = txtone = int(mem.ctone * 10)
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)
if rx_mode == "DTCS":
rxtone = _set_dcs(mem.rx_dtcs, mem.dtcs_polarity[1])
elif rx_mode == "Tone":
rxtone = int(mem.ctone * 10)

_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):
# _mem = Stored Memory value
# mem = New value from user entry
number = mem.number
_mem = self._memobj.memory[number]
_nam = self._memobj.names[number]

if len(mem.name) > 0:
LOG.debug("new name = %s", (mem.name))
_mem.named = True
name_encoded = _str_encode(mem.name)
LOG.debug("name endcoded = %s", (name_encoded))
LOG.debug("number = %s", (number))
for i in range(0, 8):
_nam.name[i] = ord(name_encoded[i])
else:
_mem.named = False

# 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 = _freq_encode(mem.freq)
if mem.duplex == "off":
_mem.txfreq = 0xFFFFFFFF
elif mem.duplex == "split":
_mem.txfreq = _freq_encode(mem.offset)
elif mem.duplex == "+":
_mem.txfreq = _freq_encode(mem.freq + mem.offset)
elif mem.duplex == "-":
_mem.txfreq = _freq_encode(mem.freq - mem.offset)
else:
_mem.txfreq = _freq_encode(mem.freq)

_mem.scan_add = int(mem.skip != "S")

if mem.mode == "AM":
_mem.am_mode = True
_mem.isnarrow = False
elif mem.mode == "NAM":
_mem.am_mode = True
_mem.isnarrow = True
else:
_mem.am_mode = False
if mem.mode =="NFM":
_mem.isnarrow = True
else:
_mem.isnarrow = False

# set the tone
self._set_tone(mem, _mem)
# MRT set the scrambler and compander to off by default
# MRT This changes them in the channel memory
_mem.scrambler = 0
_mem.compander = 0
# set the power
# if mem.power:
# _mem.power = self.POWER_LEVELS.index(mem.power)
# else:
# _mem.power = True
LOG.debug("Set mem.power = %s" % mem.power)
# pwr_index= mem.power
# LOG.debug("pwr index = " + str(pwr_index))
index = self.POWER_LEVELS.index(mem.power)
LOG.debug("index = %i", (index))
if index == 2:
_mem.power = 0b11 #self.POWER_LEVELS.index(mem.power)
else:
_mem.power = self.POWER_LEVELS.index(mem.power)
# Not sure what this bit does yet but it causes the radio to display
# MED power when the CPS shows Low Power. Forcing it to 0 to keep them
# consistent
_mem.extra_power_bit = 0
# Set other unknowns to 0 to match default CPS values
_mem.unknown1 = 0
_mem.unknown2 = 0
_mem.unknownbit2 = 0
_mem.unknown3 = 0
_mem.Unknown4_shft_dir = 0
_mem.unknown5 = 0
# if mem.power:
# _mem.power = self.POWER_LEVELS.index[mem.power]
# else:
# _mem.power = True

# MRT set to mute mode to QT (not QT+DTMF or QT*DTMF) by default
# MRT This changes them in the channel memory
_mem.mute_mode = 0

def _get_settings(self):
_settings = self._memobj.settings
_limits = self._memobj.bandlimits
# _vfoa = self._memobj.vfoa
# _vfob = self._memobj.vfob
# _scan = self._memobj.scan_groups
# _call = self._memobj.call_groups
# _callname = self._memobj.call_names
# _fmpreset = self._memobj.fm_preset

cfg_grp = RadioSettingGroup("cfg_grp", "Config Settings")
cfg1_grp = RadioSettingGroup("cfg1_grp", "Config Settings 1")
cfg2_grp = RadioSettingGroup("cfg2_grp", "Config Settings 2")
vfoa_grp = RadioSettingGroup("vfoa_grp", "VFO A Settings")
vfo150_grp = RadioSettingGroup("vfo150_grp", "150M Settings")
vfo450_grp = RadioSettingGroup("vfo450_grp", "450M Settings")
vfo20_grp = RadioSettingGroup("vfo20_grp", "20M Settings")
vfo50_grp = RadioSettingGroup("vfo50_grp", "50M Settings")
vfo350_grp = RadioSettingGroup("vfo350_grp", "350M Settings")
vfo850_grp = RadioSettingGroup("vfo850_grp", "850M Settings")
vfoabands_grp = RadioSettingGroup("vfoabands_grp", "VFO A Band Settings")
vfob_grp = RadioSettingGroup("vfob_grp", "VFO B Settings")
key_grp = RadioSettingGroup("key_grp", "Key Settings")
fmradio_grp = RadioSettingGroup("fmradio_grp", "FM Broadcast Memory")
lmt_grp = RadioSettingGroup("lmt_grp", "Frequency Limits")
lmwrn_grp = RadioSettingGroup("lmwrn_grp", "READ ONLY")
rxlim_grp = RadioSettingGroup("rxlim_grp", "Rx Limits")
txlim_grp = RadioSettingGroup("txlim_grp", "Tx Limits")
uhf_lmt_grp = RadioSettingGroup("uhf_lmt_grp", "UHF")
vhf_lmt_grp = RadioSettingGroup("vhf_lmt_grp", "VHF")
oem_grp = RadioSettingGroup("oem_grp", "OEM Info")
scan_grp = RadioSettingGroup("scan_grp", "Scan Group")
scanname_grp = RadioSettingGroup("scanname_grp", "Scan Names")
call_grp = RadioSettingGroup("call_grp", "Call Settings")
extra_grp = RadioSettingGroup("extra_grp",
"Extra Settings"
"\nNOT Changed by RESET or CPS")
vfo_grp = RadioSettingGroup("vfo_grp",
"VFO Settings")
memxtras_grp = RadioSettingGroup("memxtras_grp", "Memory Extras")
# extra_grp.append(oem_grp)
cfg_grp.append(cfg1_grp)
cfg_grp.append(cfg2_grp)
lmt_grp.append(lmwrn_grp)
lmt_grp.append(rxlim_grp)
lmt_grp.append(txlim_grp)
extra_grp.append(lmt_grp)
vfo_grp.append(vfoa_grp)
vfo_grp.append(vfob_grp)
# vfoa_grp.append(vfoabands_grp)
vfoa_grp.append(vfo150_grp)
vfoa_grp.append(vfo450_grp)
vfoa_grp.append(vfo20_grp)
vfoa_grp.append(vfo50_grp)
vfoa_grp.append(vfo350_grp)
vfoa_grp.append(vfo850_grp)
scan_grp.append(scanname_grp)
# group = RadioSettings(cfg_grp, vfoa_grp, vfob_grp,
# fmradio_grp, key_grp, scan_grp,
# call_grp, extra_grp)
group = RadioSettings(cfg_grp, vfo_grp, fmradio_grp,
scan_grp, memxtras_grp, extra_grp)

# Memory extras
# rs = RadioSetting("_mem.mute_mode", "Mute Mode"+str(number),
# RadioSettingValueBoolean(_mem.mute_mode))
# memxtras_grp.append(rs)

# Configuration Settings

rs = RadioSetting("roger", "Roger Beep",
RadioSettingValueList(ROGER_LIST,
ROGER_LIST[_settings.
roger]))
cfg1_grp.append(rs)

rs = RadioSetting("beep", "Keypad Beep",
RadioSettingValueBoolean(_settings.beep))
cfg1_grp.append(rs)

rs = RadioSetting("voice", "Voice Guide",
RadioSettingValueBoolean(_settings.voice))
cfg1_grp.append(rs)

rs = RadioSetting("bcl_a", "Busy Channel Lock-out A",
RadioSettingValueBoolean(_settings.bcl_a))
cfg1_grp.append(rs)

rs = RadioSetting("bcl_b", "Busy Channel Lock-out B",
RadioSettingValueBoolean(_settings.bcl_b))
cfg1_grp.append(rs)

rs = RadioSetting("sc_rev", "Scan Mode",
RadioSettingValueMap(SC_REV_MAP, _settings.sc_rev))
cfg1_grp.append(rs)
rs = RadioSetting("tot", "Timeout Timer (TOT)",
RadioSettingValueMap(
TOT_MAP, _settings.tot))
cfg1_grp.append(rs)

rs = RadioSetting("toa", "Timeout Alarm (TOA)",
RadioSettingValueMap(
TOA_MAP, _settings.toa))
cfg1_grp.append(rs)

rs = RadioSetting("ani_sw", "Caller ID Tx - ANI-SW",
RadioSettingValueBoolean(_settings.ani_sw))
cfg1_grp.append(rs)

rs = RadioSetting("ring", "Ring Time (Sec)",
RadioSettingValueMap(RING_MAP, _settings.ring))
cfg1_grp.append(rs)


rs = RadioSetting("dtmfsf", "DTMF Sidetone",
RadioSettingValueList(
DTMF_ST_LIST,
DTMF_ST_LIST[_settings.dtmfsf]))
cfg1_grp.append(rs)


rs = RadioSetting("ptt_id", "Caller ID Tx Mode (PTT_ID)",
RadioSettingValueMap(PTT_ID_MAP, _settings.ptt_id))
cfg1_grp.append(rs)


rs = RadioSetting("wt_led", "Standby / WT LED",
RadioSettingValueList(
BACKLIGHT_LIST,
BACKLIGHT_LIST[_settings.wt_led]))
cfg1_grp.append(rs)

rs = RadioSetting("tx_led", "TX LED",
RadioSettingValueList(
BACKLIGHT_LIST,
BACKLIGHT_LIST[_settings.tx_led]))
cfg1_grp.append(rs)

rs = RadioSetting("rx_led", "Rx LED",
RadioSettingValueList(
BACKLIGHT_LIST,
BACKLIGHT_LIST[_settings.rx_led]))
cfg1_grp.append(rs)

rs = RadioSetting("prich_sw", "Priority Channel Scan",
RadioSettingValueBoolean(_settings.prich_sw))
cfg1_grp.append(rs)

rs = RadioSetting("spk_cont", "Speaker Control",
RadioSettingValueMap(
SPEAKER_MAP,
_settings.spk_cont))
cfg1_grp.append(rs)

rs = RadioSetting("autolock", "Autolock",
RadioSettingValueBoolean(_settings.autolock))
cfg1_grp.append(rs)

rs = RadioSetting("low_v", "Low Voltage Shutoff",
RadioSettingValueBoolean(_settings.low_v))
cfg1_grp.append(rs)

rs = RadioSetting("fan", "Fan Mode",
RadioSettingValueList(
FAN_MODE_LIST,
FAN_MODE_LIST[_settings.fan]))
cfg1_grp.append(rs)

rs = RadioSetting("apo_time", "Auto Power-Off (Min)",
RadioSettingValueList(
APO_TIME_LIST,
APO_TIME_LIST[_settings.apo_time]))
cfg1_grp.append(rs)

rs = RadioSetting("alert", "Alert Pulse (Hz)",
RadioSettingValueMap(ALERT_MAP, _settings.alert))
cfg1_grp.append(rs)
rs = RadioSetting("m_pwr", "Medium Power Level (W)",
RadioSettingValueMap(M_POWER_MAP,
_settings.m_pwr))
cfg1_grp.append(rs)

rs = RadioSetting("rpt_set_model", "Model (RPT-SET)",
RadioSettingValueList(
RPT_MODE_LIST,
RPT_MODE_LIST[_settings.rpt_set_model]))
cfg2_grp.append(rs)

rs = RadioSetting("rpt_spk", "Repeater Speaker Switch (RPT-SPK)",
RadioSettingValueBoolean(_settings.rpt_spk))
cfg2_grp.append(rs)

rs = RadioSetting("rpt_ptt", "Repeater PTT (RPT-PTT)",
RadioSettingValueBoolean(_settings.rpt_ptt))
cfg2_grp.append(rs)

rs = RadioSetting("dtmf_time", "DTMF Tx Duration (ms)",
RadioSettingValueList(
DTMF_TIMES,
DTMF_TIMES[_settings.dtmf_time]))
cfg2_grp.append(rs)
rs = RadioSetting("dtmf_int", "DTMF Interval (ms)",
RadioSettingValueList(
DTMF_INTERVALS,
DTMF_INTERVALS[_settings.dtmf_int]))
cfg2_grp.append(rs)

rs = RadioSetting("sc_qt", "CTCSS/DCS Scan",
RadioSettingValueMap(
SC_QT_MAP,_settings.sc_qt))
cfg2_grp.append(rs)

rs = RadioSetting("pri_ch", "Priority Channel",
RadioSettingValueInteger(
1, 999, _chnum_decode(_settings.pri_ch)))
cfg2_grp.append(rs)

rs = RadioSetting("ptt_id_dly", "Caller ID Tx Delay PTT-ID-DLY (ms)",
RadioSettingValueMap(PTT_ID_DELAY_MAP,
_settings.ptt_id_dly))
cfg2_grp.append(rs)

rs = RadioSetting("rc_sw", "Remote Control RC-SW",
RadioSettingValueBoolean(_settings.rc_sw))
cfg2_grp.append(rs)

rs = RadioSetting("scan_det", "Scan DET",
RadioSettingValueBoolean(_settings.scan_det))
cfg2_grp.append(rs)

rs = RadioSetting("menu", "Menu Available",
RadioSettingValueBoolean(_settings.menu))
cfg2_grp.append(rs)

rs = RadioSetting("thr_vol_tx", "Threshold Voltage Tx",
RadioSettingValueBoolean(_settings.thr_vol_tx))
cfg2_grp.append(rs)

rs = RadioSetting("hold_time_rpt", "Hold Time of Repeat (ms)",
RadioSettingValueList(
HOLD_TIMES,
HOLD_TIMES[_settings.hold_time_rpt]))
cfg2_grp.append(rs)

rs = RadioSetting("auto_am", "Auto AM",
RadioSettingValueBoolean(_settings.auto_am))
cfg2_grp.append(rs)

rs = RadioSetting("rpt_tone", "Repeat Tone",
RadioSettingValueBoolean(_settings.rpt_tone))
cfg2_grp.append(rs)

rs = RadioSetting("pf1_set", "PF1 setting",
RadioSettingValueList(
PF1_SETTINGS,
PF1_SETTINGS[_settings.pf1_set]))
cfg2_grp.append(rs)

rs = RadioSetting("settings.thr_vol_lvl", "Threshold Voltage Level",
RadioSettingValueFloat(
9.5, 10.5, _settings.thr_vol_lvl / 100.0 , 0.1, 1))
cfg2_grp.append(rs)


# Freq Limits settings
# Conver Integer back to correct limit HEX value: limit = hex(int(str(limit*10),16))
# # LOG.debug("limit =" % limit)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_144M_ChA_rx_start, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_144M_ChA_rx_start", "144M ChA Rx Lower Limit (MHz)",
val)
rxlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_144M_ChA_rx_stop, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_144M_ChA_rx_stop", "144M ChA Rx Upper Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
rxlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_144M_ChB_rx_start, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_144M_ChB_rx_start", "144M ChB Rx Lower Limit (MHz)",
val)
rxlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_144M_ChB_rx_stop, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_144M_ChB_rx_stop", "144M ChB Rx Upper Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
rxlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_70cm_rx_start, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_70cm_rx_start", "450M Rx Lower Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
rxlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_70cm_rx_stop, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_70cm_rx_stop", "450M Rx Upper Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
rxlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_10m_rx_start, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_10m_rx_start", "20M Rx Lower Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
rxlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_10m_rx_stop, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_10m_rx_stop", "20M Rx Upper Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
rxlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_6m_rx_start, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_6m_rx_start", "50M Rx Lower Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
rxlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_6m_rx_stop, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_6m_rx_stop", "50M Rx Upper Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
rxlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_350M_rx_start, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_350M_rx_start", "350M Rx Lower Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
rxlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_350M_rx_stop, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_350M_rx_stop", "350M Rx Upper Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
rxlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_850M_rx_start, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_850M_rx_start", "850M Rx Lower Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
rxlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_850M_rx_stop, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_850M_rx_stop", "850M Rx Upper Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
rxlim_grp.append(rs)


_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_144M_ChA_tx_start, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_144M_ChA_tx_start", "144M ChA Tx Lower Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
txlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_144M_ChA_tx_stop, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_144M_ChA_tx_stop", "144M ChA Tx Upper Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
txlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_70cm_tx_start, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_70cm_tx_start", "450M Tx Lower Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
txlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_70cm_tx_stop, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_70cm_tx_stop", "450M tx Upper Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
txlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_10m_tx_start, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_10m_tx_start", "20M tx Lower Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
txlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_10m_tx_stop, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_10m_tx_stop", "20M tx Upper Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
txlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_6m_tx_start, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_6m_tx_start", "50M tx Lower Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
txlim_grp.append(rs)

_temp =str(hex(int("%i" % self._memobj.bandlimits.limit_6m_tx_stop, 10)))
_temp = int(int(_temp[2:])/10.0)
val= RadioSettingValueInteger(0,999, _temp)
rs = RadioSetting("bandlimits.limit_6m_tx_stop", "50M tx Upper Limit (MHz)",
RadioSettingValueInteger(0,999,
val))
txlim_grp.append(rs)

# VFO Settings
rs = RadioSetting("vfomode_a", "VFO A Working Mode",
RadioSettingValueMap(WORKMODE_MAP,
_settings.vfomode_a))
vfoa_grp.append(rs)

rs = RadioSetting("vfoband_a", "VFO A Current Band",
RadioSettingValueMap(VFOBAND_MAP,
_settings.vfoband_a))
vfoa_grp.append(rs)

rs = RadioSetting("vfochan_a", "VFO A Channel",
RadioSettingValueInteger(1, 999,
_chnum_decode(_settings.vfochan_a)))
vfoa_grp.append(rs)

rs = RadioSetting("vfosquelch_a", "VFO A Squelch",
RadioSettingValueInteger(0, 9,
_settings.vfosquelch_a))
vfoa_grp.append(rs)
rs = RadioSetting("vfostep_a", "VFO A Step",
RadioSettingValueList(
STEP_LIST,
STEP_LIST[_settings.vfostep_a]))
vfoa_grp.append(rs)
######################

rs = RadioSetting("vfofreq1", "VFO 150M Freq",
RadioSettingValueFloat(
0, 999.999999, (_freq_decode
(_settings.vfofreq1)/1000000.0) ,0.000001, 6))
vfo150_grp.append(rs)

rs = RadioSetting("vfoofst1", "VFO 150M Offset",
RadioSettingValueFloat(
0, 999.999999, (_freq_decode
(_settings.vfoofst1)/1000000.0),0.000001, 6))
vfo150_grp.append(rs)

rs = RadioSetting("rxtone1", "VFO 150M Rx tone",
RadioSettingValueMap(
TONE_MAP, _settings.rxtone1))
vfo150_grp.append(rs)

rs = RadioSetting("txtone1", "VFO 150M Tx tone",
RadioSettingValueMap(
TONE_MAP, _settings.txtone1))
vfo150_grp.append(rs)

rs = RadioSetting("power1", "VFO 150M Power",
RadioSettingValueMap(
POWER_MAP, _settings.power1))
vfo150_grp.append(rs)

rs = RadioSetting("narrow1", "VFO 150M Bandwidth",
RadioSettingValueMap(
BANDWIDTH_MAP, _settings.narrow1))
vfo150_grp.append(rs)

rs = RadioSetting("mute1", "VFO 150M Mute Mode",
RadioSettingValueMap(
MUTE_MODE_MAP, _settings.mute1))
vfo150_grp.append(rs)

rs = RadioSetting("shft_dir1", "VFO 150M Shift Direction",
RadioSettingValueList(
DUPLEX_LIST,
DUPLEX_LIST[_settings.shft_dir1]))
vfo150_grp.append(rs)

rs = RadioSetting("compander1", "VFO 150M Compander",
RadioSettingValueBoolean(
_settings.compander1))
vfo150_grp.append(rs)

rs = RadioSetting("scrambler1", "VFO 150M Scrambler",
RadioSettingValueList(
SCRAMBLER_LIST,
SCRAMBLER_LIST[_settings.scrambler1]))
vfo150_grp.append(rs)
rs = RadioSetting("am_mode1", "VFO 150M AM Mode",
RadioSettingValueBoolean(
_settings.am_mode1))
vfo150_grp.append(rs)
############################

rs = RadioSetting("vfofreq2", "VFO 450M Freq",
RadioSettingValueFloat(
0, 999.999999, (_freq_decode
(_settings.vfofreq2)/1000000.0) ,0.000001, 6))
vfo450_grp.append(rs)

rs = RadioSetting("vfoofst2", "VFO 450M Offset",
RadioSettingValueFloat(
0, 999.999999, (_freq_decode
(_settings.vfoofst2)/1000000.0),0.000001, 6))
vfo450_grp.append(rs)

rs = RadioSetting("rxtone2", "VFO 450M Rx tone",
RadioSettingValueMap(
TONE_MAP, _settings.rxtone2))
vfo450_grp.append(rs)

rs = RadioSetting("txtone2", "VFO 450M Tx tone",
RadioSettingValueMap(
TONE_MAP, _settings.txtone2))
vfo450_grp.append(rs)
rs = RadioSetting("power2", "VFO 450M Power",
RadioSettingValueMap(
POWER_MAP, _settings.power2))
vfo450_grp.append(rs)

rs = RadioSetting("narrow2", "VFO 450M Bandwidth",
RadioSettingValueMap(
BANDWIDTH_MAP, _settings.narrow2))
vfo450_grp.append(rs)

rs = RadioSetting("mute2", "VFO 450M Mute Mode",
RadioSettingValueMap(
MUTE_MODE_MAP, _settings.mute2))
vfo450_grp.append(rs)

rs = RadioSetting("shft_dir2", "VFO 450M Shift Direction",
RadioSettingValueList(
DUPLEX_LIST,
DUPLEX_LIST[_settings.shft_dir2]))
vfo450_grp.append(rs)

rs = RadioSetting("compander2", "VFO 450M Compander",
RadioSettingValueBoolean(
_settings.compander2))
vfo450_grp.append(rs)

rs = RadioSetting("scrambler2", "VFO 450M Scrambler",
RadioSettingValueList(
SCRAMBLER_LIST,
SCRAMBLER_LIST[_settings.scrambler2]))
vfo450_grp.append(rs)

rs = RadioSetting("am_mode2", "VFO 450M AM Mode",
RadioSettingValueBoolean(
_settings.am_mode2))
vfo450_grp.append(rs)
############################
rs = RadioSetting("vfofreq3", "VFO 20M Freq",
RadioSettingValueFloat(
0, 999.999999, (_freq_decode
(_settings.vfofreq3)/1000000.0) ,0.000001, 6))
vfo20_grp.append(rs)

rs = RadioSetting("vfoofst3", "VFO 20M Offset",
RadioSettingValueFloat(
0, 999.999999, (_freq_decode
(_settings.vfoofst3)/1000000.0),0.000001, 6))
vfo20_grp.append(rs)

rs = RadioSetting("rxtone3", "VFO 20M Rx tone",
RadioSettingValueMap(
TONE_MAP, _settings.rxtone3))
vfo20_grp.append(rs)

rs = RadioSetting("txtone3", "VFO 20M Tx tone",
RadioSettingValueMap(
TONE_MAP, _settings.txtone3))
vfo20_grp.append(rs)
rs = RadioSetting("power3", "VFO 20M Power",
RadioSettingValueMap(
POWER_MAP, _settings.power3))
vfo20_grp.append(rs)

rs = RadioSetting("narrow3", "VFO 20M Bandwidth",
RadioSettingValueMap(
BANDWIDTH_MAP, _settings.narrow3))
vfo20_grp.append(rs)

rs = RadioSetting("mute3", "VFO 20M Mute Mode",
RadioSettingValueMap(
MUTE_MODE_MAP, _settings.mute3))
vfo20_grp.append(rs)

rs = RadioSetting("shft_dir3", "VFO 20M Shift Direction",
RadioSettingValueList(
DUPLEX_LIST,
DUPLEX_LIST[_settings.shft_dir3]))
vfo20_grp.append(rs)

rs = RadioSetting("compander3", "VFO 20M Compander",
RadioSettingValueBoolean(
_settings.compander3))
vfo20_grp.append(rs)

rs = RadioSetting("scrambler3", "VFO 20M Scrambler",
RadioSettingValueList(
SCRAMBLER_LIST,
SCRAMBLER_LIST[_settings.scrambler3]))
vfo20_grp.append(rs)

rs = RadioSetting("am_mode3", "VFO 20M AM Mode",
RadioSettingValueBoolean(
_settings.am_mode3))
vfo20_grp.append(rs)
############################
rs = RadioSetting("vfofreq4", "VFO 50M Freq",
RadioSettingValueFloat(
0, 999.999999, (_freq_decode
(_settings.vfofreq4)/1000000.0) ,0.000001, 6))
vfo50_grp.append(rs)

rs = RadioSetting("vfoofst4", "VFO 50M Offset",
RadioSettingValueFloat(
0, 999.999999, (_freq_decode
(_settings.vfoofst4)/1000000.0),0.000001, 6))
vfo50_grp.append(rs)

rs = RadioSetting("rxtone4", "VFO 50M Rx tone",
RadioSettingValueMap(
TONE_MAP, _settings.rxtone4))
vfo50_grp.append(rs)

rs = RadioSetting("txtone4", "VFO 50M Tx tone",
RadioSettingValueMap(
TONE_MAP, _settings.txtone4))
vfo50_grp.append(rs)
rs = RadioSetting("power4", "VFO 50M Power",
RadioSettingValueMap(
POWER_MAP, _settings.power4))
vfo50_grp.append(rs)

rs = RadioSetting("narrow4", "VFO 50M Bandwidth",
RadioSettingValueMap(
BANDWIDTH_MAP, _settings.narrow4))
vfo50_grp.append(rs)

rs = RadioSetting("mute4", "VFO 50M Mute Mode",
RadioSettingValueMap(
MUTE_MODE_MAP, _settings.mute4))
vfo50_grp.append(rs)

rs = RadioSetting("shft_dir4", "VFO 50M Shift Direction",
RadioSettingValueList(
DUPLEX_LIST,
DUPLEX_LIST[_settings.shft_dir4]))
vfo50_grp.append(rs)

rs = RadioSetting("compander4", "VFO 50M Compander",
RadioSettingValueBoolean(
_settings.compander4))
vfo50_grp.append(rs)

rs = RadioSetting("scrambler4", "VFO 50M Scrambler",
RadioSettingValueList(
SCRAMBLER_LIST,
SCRAMBLER_LIST[_settings.scrambler4]))
vfo50_grp.append(rs)

rs = RadioSetting("am_mode4", "VFO 50M AM Mode",
RadioSettingValueBoolean(
_settings.am_mode4))
vfo50_grp.append(rs)
############################
rs = RadioSetting("vfofreq5", "VFO 350M Freq",
RadioSettingValueFloat(
0, 999.999999, (_freq_decode
(_settings.vfofreq5)/1000000.0) ,0.000001, 6))
vfo350_grp.append(rs)

rs = RadioSetting("vfoofst5", "VFO 350M Offset",
RadioSettingValueFloat(
0, 999.999999, (_freq_decode
(_settings.vfoofst5)/1000000.0),0.000001, 6))
vfo350_grp.append(rs)

rs = RadioSetting("rxtone5", "VFO 350M Rx tone",
RadioSettingValueMap(
TONE_MAP, _settings.rxtone5))
vfo350_grp.append(rs)

rs = RadioSetting("txtone5", "VFO 350M Tx tone",
RadioSettingValueMap(
TONE_MAP, _settings.txtone5))
vfo350_grp.append(rs)
rs = RadioSetting("power5", "VFO 350M Power",
RadioSettingValueMap(
POWER_MAP, _settings.power5))
vfo350_grp.append(rs)

rs = RadioSetting("narrow5", "VFO 350M Bandwidth",
RadioSettingValueMap(
BANDWIDTH_MAP, _settings.narrow5))
vfo350_grp.append(rs)

rs = RadioSetting("mute5", "VFO 350M Mute Mode",
RadioSettingValueMap(
MUTE_MODE_MAP, _settings.mute5))
vfo350_grp.append(rs)

rs = RadioSetting("shft_dir5", "VFO 350M Shift Direction",
RadioSettingValueList(
DUPLEX_LIST,
DUPLEX_LIST[_settings.shft_dir5]))
vfo350_grp.append(rs)

rs = RadioSetting("compander5", "VFO 350M Compander",
RadioSettingValueBoolean(
_settings.compander5))
vfo350_grp.append(rs)

rs = RadioSetting("scrambler5", "VFO 350M Scrambler",
RadioSettingValueList(
SCRAMBLER_LIST,
SCRAMBLER_LIST[_settings.scrambler5]))
vfo350_grp.append(rs)

rs = RadioSetting("am_mode5", "VFO 350M AM Mode",
RadioSettingValueBoolean(
_settings.am_mode5))
vfo350_grp.append(rs)

# ############################
rs = RadioSetting("vfofreq6", "VFO 850M Freq",
RadioSettingValueFloat(
0, 999.999999, (_freq_decode
(_settings.vfofreq6)/1000000.0) ,0.000001, 6))
vfo850_grp.append(rs)

rs = RadioSetting("vfoofst6", "VFO 850M Offset",
RadioSettingValueFloat(
0, 999.999999, (_freq_decode
(_settings.vfoofst6)/1000000.0),0.000001, 6))
vfo850_grp.append(rs)

rs = RadioSetting("rxtone6", "VFO 850M Rx tone",
RadioSettingValueMap(
TONE_MAP, _settings.rxtone6))
vfo850_grp.append(rs)

rs = RadioSetting("txtone6", "VFO 850M Tx tone",
RadioSettingValueMap(
TONE_MAP, _settings.txtone6))
vfo850_grp.append(rs)
rs = RadioSetting("power6", "VFO 850M Power",
RadioSettingValueMap(
POWER_MAP, _settings.power6))
vfo850_grp.append(rs)

rs = RadioSetting("narrow6", "VFO 850M Bandwidth",
RadioSettingValueMap(
BANDWIDTH_MAP, _settings.narrow6))
vfo850_grp.append(rs)

rs = RadioSetting("mute6", "VFO 850M Mute Mode",
RadioSettingValueMap(
MUTE_MODE_MAP, _settings.mute6))
vfo850_grp.append(rs)

rs = RadioSetting("shft_dir6", "VFO 850M Shift Direction",
RadioSettingValueList(
DUPLEX_LIST,
DUPLEX_LIST[_settings.shft_dir6]))
vfo850_grp.append(rs)

rs = RadioSetting("compander6", "VFO 850M Compander",
RadioSettingValueBoolean(
_settings.compander6))
vfo850_grp.append(rs)

rs = RadioSetting("scrambler6", "VFO 850M Scrambler",
RadioSettingValueList(
SCRAMBLER_LIST,
SCRAMBLER_LIST[_settings.scrambler6]))
vfo850_grp.append(rs)

rs = RadioSetting("am_mode6", "VFO 850M AM Mode",
RadioSettingValueBoolean(
_settings.am_mode6))
vfo850_grp.append(rs)

############################

rs = RadioSetting("vfomode_b", "VFO B Working Mode",
RadioSettingValueMap(WORKMODE_MAP,
_settings.vfomode_b))
vfob_grp.append(rs)

rs = RadioSetting("vfochan_b", "VFO B Work Channel",
RadioSettingValueInteger(1, 999,
_chnum_decode(_settings.vfochan_b)))
vfob_grp.append(rs)

rs = RadioSetting("vfofreq7", "VFO B Freq",
RadioSettingValueFloat(
0, 999.999999, (_freq_decode
(_settings.vfofreq7)/1000000.0) ,0.000001, 6))
vfob_grp.append(rs)

rs = RadioSetting("vfoofst7", "VFO B Offset",
RadioSettingValueFloat(
0, 999.999999, (_freq_decode
(_settings.vfoofst7)/1000000.0),0.000001, 6))
vfob_grp.append(rs)

rs = RadioSetting("rxtone7", "VFOB Rx tone",
RadioSettingValueMap(
TONE_MAP, _settings.rxtone7))
vfob_grp.append(rs)

rs = RadioSetting("txtone7", "VFOB Tx tone",
RadioSettingValueMap(
TONE_MAP, _settings.txtone7))
vfob_grp.append(rs)
rs = RadioSetting("power7", "VFOB Power",
RadioSettingValueMap(
POWER_MAP, _settings.power7))
vfob_grp.append(rs)
rs = RadioSetting("narrow7", "VFOB Bandwidth",
RadioSettingValueMap(
BANDWIDTH_MAP, _settings.narrow7))
vfob_grp.append(rs)
rs = RadioSetting("mute7", "VFOB Mute Mode",
RadioSettingValueMap(
MUTE_MODE_MAP, _settings.mute7))
vfob_grp.append(rs)
rs = RadioSetting("shft_dir7", "VFOB Shift Direction",
RadioSettingValueList(
DUPLEX_LIST,
DUPLEX_LIST[_settings.shft_dir7]))
vfob_grp.append(rs)
rs = RadioSetting("compander7", "VFOB Compander",
RadioSettingValueBoolean(
_settings.compander7))
vfob_grp.append(rs)

rs = RadioSetting("scrambler7", "VFOB Scrambler",
RadioSettingValueList(
SCRAMBLER_LIST,
SCRAMBLER_LIST[_settings.scrambler7]))
vfob_grp.append(rs)

rs = RadioSetting("vfosquelch_b", "VFO B Squelch",
RadioSettingValueInteger(0, 9,
_settings.vfosquelch_b))
vfob_grp.append(rs)
rs = RadioSetting("vfostep_b", "VFO B Step",
RadioSettingValueList(
STEP_LIST,
STEP_LIST[_settings.vfostep_b]))
vfob_grp.append(rs)
# rs = RadioSetting("am_mode7", "VFOB AM Mode",
# RadioSettingValueBoolean(
# _settings.am_mode7))
# vfob_grp.append(rs)

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

rs = RadioSetting("scan_a_act", "Scan A Active Group",
RadioSettingValueList(
SCAN_GROUP_LIST,
SCAN_GROUP_LIST[_settings.scan_a_act]))
scan_grp.append(rs)
rs = RadioSetting("scan_b_act", "Scan B Active Group",
RadioSettingValueList(
SCAN_GROUP_LIST,
SCAN_GROUP_LIST[_settings.scan_b_act]))
scan_grp.append(rs)

for i in range(1,11):
x=str(i)
_str = _decode(eval("_settings.scanname"+x))
val = RadioSettingValueString(0, 6, _str)
val.set_mutable(True)
rs = RadioSetting("scanname"+x, "Scan Name "+x, val)
scanname_grp.append(rs)

scngrp = str(i)
rs = RadioSetting("scanlower"+scngrp, "Scan Lower "+scngrp,
RadioSettingValueInteger(1, 999,
eval("_settings.scanlower"+scngrp)))
scan_grp.append(rs)
rs = RadioSetting("scanupper"+scngrp, "Scan Uower "+scngrp,
RadioSettingValueInteger(1, 999,
eval("_settings.scanupper"+scngrp)))
scan_grp.append(rs)





# FM RADIO PRESETS

# memory stores raw integer value like 7600
# radio will divide 7600 by 100 and interpret correctly at 76.0Mhz
#
# FM Radio Presets Settings
#
for i in range(1, 21):
chan = str(i)
rs = RadioSetting("FM_radio" + chan, "FM Preset " + chan,
RadioSettingValueFloat(76.0, 108.0,
eval("_settings.FM_radio" +
chan)/100.0,
0.1, 1))
fmradio_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))
# MRT rescale freq values to match radio
# expected values
value = _freq_encode(element[0].get_value()*1000000.0)
setattr(obj, setting, value)

elif self._is_fmradio_or_voltage(element):
# MRT rescale FM Radio values to match radio
# expected values
setattr(obj, setting,
int(element.values()[0]._current * 100.0))

elif self._is_limit(element):
setattr(obj, setting,
int(str(element.values()[0]._current * 10), 16))
# Special VFO A Settings
#
elif self._is_chan(element):
value = _chnum_encode(element[0].get_value())
setattr(obj, setting, value)
continue
#
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 \
"vfofreq" in element.get_name() or\
"vfoofst" in element.get_name()
# "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()

def _is_limit(self, element):
return "limit" in element.get_name()

def _is_fmradio_or_voltage(self, element):
return "FM_radio" in element.get_name() or\
"thr_vol_lvl" in element.get_name()

def _is_chan(self, element):
return "vfochan" in element.get_name() or\
"pri_ch" in element.get_name()
# def _is_vfofreq(self, element):
# return "vfofreq" in element.get_name() or\
# "vfoofst" in element.get_name()
(1-1/8)
Copyright 2023 CHIRP Software LLC