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New Model #2107 ยป tdxone_tdq8a_beta1.py

first test driver with TDXone TD-Q8A support - Jim Unroe, 12/27/2016 03:22 PM

 
# Copyright 2016:
# * Jim Unroe KC9HI, <rock.unroe@gmail.com>
#
# 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 2 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/>.

import time
import struct
import logging
import re

from chirp import chirp_common, directory, memmap
from chirp import bitwise, errors, util
from chirp.settings import RadioSettingGroup, RadioSetting, \
RadioSettingValueBoolean, RadioSettingValueList, \
RadioSettingValueString, RadioSettingValueInteger, \
RadioSettingValueFloat, RadioSettings, \
InvalidValueError
from textwrap import dedent

LOG = logging.getLogger(__name__)

MEM_FORMAT = """
#seekto 0x0010;
struct {
lbcd rxfreq[4];
lbcd txfreq[4];
ul16 rxtone;
ul16 txtone;
u8 unknown1:2,
dtmf:1, // DTMF
unknown2:1,
bcl:1, // Busy Channel Lockout
unknown3:3;
u8 unknown4:1,
scan:1, // Scan Add
highpower:1, // TX Power Level
wide:1, // BandWidth
unknown5:4;
u8 unknown6[2];
} memory[128];

#seekto 0x0E17;
struct {
u8 displayab:1, // Selected Display
unknown1:6,
unknown2:1;
} settings1;

#seekto 0x0E22;
struct {
u8 squelcha; // menu 02a Squelch Level 0xe22
u8 unknown1;
u8 tdrab; // TDR A/B 0xe24
u8 roger; // menu 20 Roger Beep 0xe25
u8 timeout; // menu 16 TOT 0xe26
u8 vox; // menu 05 VOX 0xe27
u8 unknown2;
u8 mdfb; // menu 27b Memory Display Format B 0xe37
u8 dw; // menu 37 DW 0xe2a
u8 tdr; // menu 29 Dual Watch 0xe2b
u8 voice; // menu 03 Voice Prompts 0xe2c
u8 beep; // menu 01 Key Beep 0xe2d
u8 ani; // menu 30 ANI 0xe2e
u8 unknown3[4];
u8 pttdly; // menu 31 PTT-ID Delay 0xe33
u8 unknown4;
u8 dtmfst; // menu 33 DTMF Side Tone 0xe35
u8 toa; // menu 15 TOT Pre-Alert 0xe36
u8 mdfa; // menu 27a Memory Display Format A 0xe37
u8 screv; // menu 09 Scan Resume Method 0xe38
u8 pttid; // menu 32 PTT-ID Enable 0xe39
u8 ponmsg; // menu 36 Power-on Message 0xe3a
u8 pf1; // menu 28 Programmable Function Key 0xe3b
u8 unknown5;
u8 wtled; // menu 17 Standby LED Color 0xe3d
u8 rxled; // menu 18 RX LED Color 0xe3e
u8 txled; // menu 19 TX LED Color 0xe3f
u8 unknown6;
u8 autolk; // menu 06 Auto Key Lock 0xe41
u8 squelchb; // menu 02b Squelch Level 0xe42
u8 control; // Control Code 0xe43
u8 unknown7;
u8 ach; // Selected A channel Number 0xe45
u8 unknown8[4];
u8 password[6]; // Control Password 0xe4a-0xe4f
u8 unknown9[7];
u8 code[3]; // PTT ID Code 0xe57-0xe59
u8 vfomr; // Frequency/Channel Modevel 0xe5a
u8 keylk; // Key Lock 0xe5b
u8 unknown10[2];
u8 prioritych; // Priority Channel 0xe5e
u8 bch; // Selected B channel Number 0xe5f
} settings;

struct vfo {
u8 unknown0[8];
u8 freq[8];
u8 offset[6];
ul16 rxtone;
ul16 txtone;
u8 unused0:7,
band:1;
u8 unknown3;
u8 unknown4:2,
sftd:2,
scode:4;
u8 unknown5;
u8 unknown6:1,
step:3,
unknown7:4;
u8 txpower:1,
widenarr:1,
unknown8:6;
};

#seekto 0x0F10;
struct {
struct vfo a;
struct vfo b;
} vfo;

#seekto 0x1010;
struct {
u8 name[6];
u8 unknown[10];
} names[128];

"""

##### MAGICS #########################################################

# TDXone TD-Q8A magic string
MSTRING_TDQ8A = "\x02PYNCRAM"

#STIMEOUT = 2

LIST_DTMF = ["QT", "QT+DTMF"]
LIST_VOICE = ["Off", "Chinese", "English"]
LIST_OFF1TO9 = ["Off"] + list("123456789")
LIST_OFF1TO10 = LIST_OFF1TO9 + ["10"]
LIST_RESUME = ["Time Operated(TO)", "Carrier Operated(CO)", "Search(SE)"]
LIST_COLOR = ["Off", "Blue", "Orange", "Purple"]
LIST_MODE = ["Channel", "Frequency", "Name"]
LIST_PF1 = ["Off", "Scan", "Lamp", "FM Radio", "Alarm"]
LIST_OFF1TO30 = ["OFF"] + ["%s" % x for x in range(1, 31)]
LIST_DTMFST = ["Off", "DTMF Sidetone", "ANI Sidetone", "DTMF+ANI Sidetone"]
LIST_PONMSG = ["Full", "Welcome", "Battery Voltage"]
LIST_TIMEOUT = ["Off"] + ["%s sec" % x for x in range(15, 615, 15)]
LIST_PTTID = ["BOT", "EOT", "Both"]
LIST_ROGER = ["Off"] + LIST_PTTID
LIST_PRIORITY = ["Off"] + ["%s" % x for x in range(1, 129)]
LIST_WORKMODE = ["Frequency", "Channel"]
LIST_AB = ["A", "B"]

LIST_ALMOD = ["Site", "Tone", "Code"]
LIST_BANDWIDTH = ["Wide", "Narrow"]
LIST_DELAYPROCTIME = ["%s ms" % x for x in range(100, 4100, 100)]
LIST_DTMFSPEED = ["%s ms" % x for x in range(50, 2010, 10)]
LIST_OFFAB = ["Off"] + LIST_AB
LIST_RESETTIME = ["%s ms" % x for x in range(100, 16100, 100)]
LIST_SCODE = ["%s" % x for x in range(1, 16)]
LIST_RPSTE = ["Off"] + ["%s" % x for x in range(1, 11)]
LIST_SAVE = ["Off", "1:1", "1:2", "1:3", "1:4"]
LIST_SHIFTD = ["Off", "+", "-"]
LIST_STEDELAY = ["Off"] + ["%s ms" % x for x in range(100, 1100, 100)]
#LIST_STEP = [str(x) for x in STEPS]
LIST_TXPOWER = ["High", "Low"]
LIST_DTMF_SPECIAL_DIGITS = [ "*", "#", "A", "B", "C", "D"]
LIST_DTMF_SPECIAL_VALUES = [ 0x0B, 0x0C, 0x0D, 0x0E, 0x0F, 0x00]

CHARSET = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ?+-*"
STEPS = [2.5, 5.0, 6.25, 10.0, 12.5, 25.0]
POWER_LEVELS = [chirp_common.PowerLevel("High", watts=5),
chirp_common.PowerLevel("Low", watts=1)]
VALID_BANDS = [(136000000, 174000000),
(400000000, 520000000)]


#def _clean_buffer(radio):
# radio.pipe.timeout = 0.005
# junk = radio.pipe.read(256)
# radio.pipe.timeout = STIMEOUT
# if junk:
# LOG.debug("Got %i bytes of junk before starting" % len(junk))


def _rawrecv(radio, amount):
"""Raw read from the radio device"""
data = ""
try:
data = radio.pipe.read(amount)
except:
msg = "Generic error reading data from radio; check your cable."
raise errors.RadioError(msg)

if len(data) != amount:
msg = "Error reading data from radio: not the amount of data we want."
raise errors.RadioError(msg)

return data


def _rawsend(radio, data):
"""Raw send to the radio device"""
try:
radio.pipe.write(data)
except:
raise errors.RadioError("Error sending data to radio")


def _make_frame(cmd, addr, length, data=""):
"""Pack the info in the headder format"""
frame = struct.pack(">BHB", ord(cmd), addr, length)
# add the data if set
if len(data) != 0:
frame += data
# return the data
return frame


def _recv(radio, addr, length):
"""Get data from the radio """
# read 4 bytes of header
hdr = _rawrecv(radio, 4)

# read data
data = _rawrecv(radio, length)

# DEBUG
LOG.info("Response:")
LOG.debug(util.hexprint(hdr + data))

c, a, l = struct.unpack(">BHB", hdr)
if a != addr or l != length or c != ord("W"):
LOG.error("Invalid answer for block 0x%04x:" % addr)
LOG.debug("CMD: %s ADDR: %04x SIZE: %02x" % (c, a, l))
raise errors.RadioError("Unknown response from the radio")

return data


def _do_ident(radio, magic):
"""Put the radio in PROGRAM mode"""
# set the serial discipline
radio.pipe.baudrate = 9600
####radio.pipe.timeout = STIMEOUT

## flush input buffer
#_clean_buffer(radio)

# send request to enter program mode
_rawsend(radio, magic)

ack = _rawrecv(radio, 1)
if ack != "\x06":
if ack:
LOG.debug(repr(ack))
raise errors.RadioError("Radio did not respond")

_rawsend(radio, "\x02")

# Ok, get the response
ident = _rawrecv(radio, radio._magic_response_length)

# check if response is OK
if not ident.startswith("P3107"):
# bad response
msg = "Unexpected response, got this:"
msg += util.hexprint(ident)
LOG.debug(msg)
raise errors.RadioError("Unexpected response from radio.")

# DEBUG
LOG.info("Valid response, got this:")
LOG.debug(util.hexprint(ident))

_rawsend(radio, "\x06")
ack = _rawrecv(radio, 1)
if ack != "\x06":
if ack:
LOG.debug(repr(ack))
raise errors.RadioError("Radio refused clone")

return ident


def _ident_radio(radio):
for magic in radio._magic:
error = None
try:
data = _do_ident(radio, magic)
return data
except errors.RadioError, e:
print e
error = e
time.sleep(2)
if error:
raise error
raise errors.RadioError("Radio did not respond")


def _download(radio):
"""Get the memory map"""
# put radio in program mode
ident = _ident_radio(radio)

# UI progress
status = chirp_common.Status()
status.cur = 0
status.max = radio._mem_size / radio._recv_block_size
status.msg = "Cloning from radio..."
radio.status_fn(status)

data = ""
for addr in range(0, radio._mem_size, radio._recv_block_size):
frame = _make_frame("R", addr, radio._recv_block_size)
# DEBUG
LOG.info("Request sent:")
LOG.debug(util.hexprint(frame))

# sending the read request
_rawsend(radio, frame)

# now we read
d = _recv(radio, addr, radio._recv_block_size)

time.sleep(0.05)

_rawsend(radio, "\x06")

ack = _rawrecv(radio, 1)
if ack != "\x06":
raise errors.RadioError(
"Radio refused to send block 0x%04x" % addr)

####time.sleep(0.05)

# aggregate the data
data += d

# UI Update
status.cur = addr / radio._recv_block_size
status.msg = "Cloning from radio..."
radio.status_fn(status)

data += radio.MODEL.ljust(8)

return data


def _upload(radio):
"""Upload procedure"""
# put radio in program mode
_ident_radio(radio)



addr = 0x0f80
frame = _make_frame("R", addr, radio._recv_block_size)
# DEBUG
LOG.info("Request sent:")
LOG.debug(util.hexprint(frame))

# sending the read request
_rawsend(radio, frame)

# now we read
d = _recv(radio, addr, radio._recv_block_size)

time.sleep(0.05)

_rawsend(radio, "\x06")

ack = _rawrecv(radio, 1)
if ack != "\x06":
raise errors.RadioError(
"Radio refused to send block 0x%04x" % addr)



_ranges = radio._ranges

# UI progress
status = chirp_common.Status()
status.cur = 0
status.max = radio._mem_size / radio._send_block_size
status.msg = "Cloning to radio..."
radio.status_fn(status)

# the fun start here
for start, end in _ranges:
for addr in range(start, end, radio._send_block_size):
# sending the data
data = radio.get_mmap()[addr:addr + radio._send_block_size]

frame = _make_frame("W", addr, radio._send_block_size, data)

_rawsend(radio, frame)
#time.sleep(0.05)

# receiving the response
ack = _rawrecv(radio, 1)
if ack != "\x06":
msg = "Bad ack writing block 0x%04x" % addr
raise errors.RadioError(msg)

# UI Update
status.cur = addr / radio._send_block_size
status.msg = "Cloning to radio..."
radio.status_fn(status)


def model_match(cls, data):
"""Match the opened/downloaded image to the correct version"""

if len(data) == 0x2008:
rid = data[0x2000:0x2008]
print rid
return rid.startswith(cls.MODEL)
else:
return False


def _split(rf, f1, f2):
"""Returns False if the two freqs are in the same band (no split)
or True otherwise"""

# determine if the two freqs are in the same band
for low, high in rf.valid_bands:
if f1 >= low and f1 <= high and \
f2 >= low and f2 <= high:
# if the two freqs are on the same Band this is not a split
return False

# if you get here is because the freq pairs are split
return True


@directory.register
class TDXoneTDQ8A(chirp_common.CloneModeRadio,
chirp_common.ExperimentalRadio):
"""TDXone TD-Q8A Radio"""
VENDOR = "TDXone"
MODEL = "TD-Q8A"

####_fileid = [TDQ8A_fp1, ]

_magic = [MSTRING_TDQ8A, MSTRING_TDQ8A,]
_magic_response_length = 8
_fw_ver_start = 0x1EF0
_recv_block_size = 0x40
_mem_size = 0x2000

#_ranges = [(0x0000, 0x2000)]
# same as radio
#_ranges = [(0x0010, 0x0810),
# (0x0F10, 0x0F30),
# (0x1010, 0x1810),
# (0x0E20, 0x0E60),
# (0x1F10, 0x1F30)]
# in increasing order
_ranges = [(0x0010, 0x0810),
(0x0E20, 0x0E60),
(0x0F10, 0x0F30),
(0x1010, 0x1810),
(0x1F10, 0x1F30)]
_send_block_size = 0x10

#DTCS_CODES = sorted(chirp_common.DTCS_CODES + [645])
#DTCS_CODES = sorted(chirp_common.ALL_DTCS_CODES)
#POWER_LEVELS = [chirp_common.PowerLevel("Low", watts=1.00),
# chirp_common.PowerLevel("High", watts=5.00)]
#VALID_BANDS = [(136000000, 174000000),
# (400000000, 520000000)]


@classmethod
def get_prompts(cls):
rp = chirp_common.RadioPrompts()
rp.experimental = \
('The TDXone TD-Q8A driver is a beta version.\n'
'\n'
'Please save an unedited copy of your first successful\n'
'download to a CHIRP Radio Images(*.img) file.'
)
rp.pre_download = _(dedent("""\
Follow these instructions to download your info:

1 - Turn off your radio
2 - Connect your interface cable
3 - Turn on your radio
4 - Do the download of your radio data
"""))
rp.pre_upload = _(dedent("""\
Follow this instructions to upload your info:

1 - Turn off your radio
2 - Connect your interface cable
3 - Turn on your radio
4 - Do the upload of your radio data
"""))
return rp


def get_features(self):
"""Get the radio's features"""

rf = chirp_common.RadioFeatures()
rf.has_settings = True
rf.has_bank = False
rf.has_tuning_step = False
rf.can_odd_split = True
rf.has_name = True
rf.has_offset = True
rf.has_mode = True
rf.has_dtcs = False #True
rf.has_rx_dtcs = False #True
rf.has_dtcs_polarity = False #True
rf.has_ctone = True
rf.has_cross = True
rf.valid_modes = ["FM", "NFM"]
#rf.valid_characters = self.VALID_CHARS
rf.valid_characters = CHARSET
rf.valid_name_length = 6
rf.valid_duplexes = ["", "-", "+", "split", "off"]
#rf.valid_tmodes = ['', 'Tone', 'TSQL', 'DTCS', 'Cross']
#rf.valid_cross_modes = [
# "Tone->Tone",
# "DTCS->",
# "->DTCS",
# "Tone->DTCS",
# "DTCS->Tone",
# "->Tone",
# "DTCS->DTCS"]
rf.valid_tmodes = ['', 'Tone', 'TSQL', 'Cross']
rf.valid_cross_modes = [
"Tone->Tone",
"->Tone"]
rf.valid_skips = ["", "S"]
#rf.valid_dtcs_codes = self.DTCS_CODES
rf.memory_bounds = (1, 128)
rf.valid_power_levels = POWER_LEVELS
rf.valid_bands = VALID_BANDS

return rf


def process_mmap(self):
"""Process the mem map into the mem object"""
self._memobj = bitwise.parse(MEM_FORMAT, self._mmap)


def sync_in(self):
"""Download from radio"""
try:
data = _download(self)
except errors.RadioError:
# Pass through any real errors we raise
raise
except:
# If anything unexpected happens, make sure we raise
# a RadioError and log the problem
LOG.exception('Unexpected error during download')
raise errors.RadioError('Unexpected error communicating '
'with the radio')
self._mmap = memmap.MemoryMap(data)
self.process_mmap()


def sync_out(self):
"""Upload to radio"""
try:
_upload(self)
except:
# If anything unexpected happens, make sure we raise
# a RadioError and log the problem
LOG.exception('Unexpected error during upload')
raise errors.RadioError('Unexpected error communicating '
'with the radio')


def _is_txinh(self, _mem):
raw_tx = ""
for i in range(0, 4):
raw_tx += _mem.txfreq[i].get_raw()
return raw_tx == "\xFF\xFF\xFF\xFF"


def _get_mem(self, number):
return self._memobj.memory[number - 1]

def _get_nam(self, number):
return self._memobj.names[number - 1]

def get_memory(self, number):
_mem = self._get_mem(number)
_nam = self._get_nam(number)

mem = chirp_common.Memory()
mem.number = number

if _mem.get_raw()[0] == "\xff":
mem.empty = True
return mem

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

if self._is_txinh(_mem):
# TX freq not set
mem.duplex = "off"
mem.offset = 0
else:
# TX freq set
offset = (int(_mem.txfreq) * 10) - mem.freq
if offset != 0:
if _split(self.get_features(), mem.freq, int(_mem.txfreq) * 10):
mem.duplex = "split"
mem.offset = int(_mem.txfreq) * 10
elif offset < 0:
mem.offset = abs(offset)
mem.duplex = "-"
elif offset > 0:
mem.offset = offset
mem.duplex = "+"
else:
mem.offset = 0

if _nam.name:
for char in _nam.name:
try:
mem.name += CHARSET[char]
except IndexError:
break
mem.name = mem.name.rstrip()

#dtcs_pol = ["N", "N"]

if _mem.txtone in [0, 0xFFFF]:
txmode = ""
elif _mem.txtone >= 0x0258:
txmode = "Tone"
mem.rtone = int(_mem.txtone) / 10.0
else:
LOG.warn("Bug: txtone is %04x" % _mem.txtone)

#elif _mem.txtone <= 0x0258:
# txmode = "DTCS"
# if _mem.txtone > 0x69:
# index = _mem.txtone - 0x6A
# dtcs_pol[0] = "R"
# else:
# index = _mem.txtone - 1
# mem.dtcs = self.DTCS_CODES[index]
#else:
# LOG.warn("Bug: txtone is %04x" % _mem.txtone)

if _mem.rxtone in [0, 0xFFFF]:
rxmode = ""
elif _mem.rxtone >= 0x0258:
rxmode = "Tone"
mem.ctone = int(_mem.rxtone) / 10.0
else:
LOG.warn("Bug: rxtone is %04x" % _mem.rxtone)

#elif _mem.rxtone <= 0x0258:
# rxmode = "DTCS"
# if _mem.rxtone >= 0x6A:
# index = _mem.rxtone - 0x6A
# dtcs_pol[1] = "R"
# else:
# index = _mem.rxtone - 1
# mem.rx_dtcs = self.DTCS_CODES[index]
#else:
# LOG.warn("Bug: rxtone is %04x" % _mem.rxtone)

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

#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)

#mem.dtcs_polarity = "".join(dtcs_pol)

if not _mem.scan:
mem.skip = "S"

mem.power = POWER_LEVELS[1 - _mem.highpower]

mem.mode = _mem.wide and "FM" or "NFM"

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

rs = RadioSetting("dtmf", "DTMF",
RadioSettingValueList(LIST_DTMF,
LIST_DTMF[_mem.dtmf]))
mem.extra.append(rs)

rs = RadioSetting("bcl", "BCL",
RadioSettingValueBoolean(_mem.bcl))
mem.extra.append(rs)

return mem


def _set_mem(self, number):
return self._memobj.memory[number - 1]

def _set_nam(self, number):
return self._memobj.names[number - 1]

def set_memory(self, mem):
_mem = self._get_mem(mem.number)
_nam = self._get_nam(mem.number)

if mem.empty:
_mem.set_raw("\xff" * 12 + "\xbf" +"\xff" * 3)
_nam.set_raw("\xff" * 16)
return

#_mem.set_raw("\x00" * 16)
_mem.set_raw("\xff" * 12 + "\x9f" +"\xff" * 3)

_mem.rxfreq = mem.freq / 10

if mem.duplex == "off":
for i in range(0, 4):
_mem.txfreq[i].set_raw("\xFF")
elif mem.duplex == "split":
_mem.txfreq = mem.offset / 10
elif mem.duplex == "+":
_mem.txfreq = (mem.freq + mem.offset) / 10
elif mem.duplex == "-":
_mem.txfreq = (mem.freq - mem.offset) / 10
else:
_mem.txfreq = mem.freq / 10

if _nam.name:
for i in range(0, 6):
try:
_nam.name[i] = CHARSET.index(mem.name[i])
except IndexError:
_nam.name[i] = 0xFF

rxmode = txmode = ""
if mem.tmode == "Tone":
_mem.txtone = int(mem.rtone * 10)
_mem.rxtone = 0
elif mem.tmode == "TSQL":
_mem.txtone = int(mem.ctone * 10)
_mem.rxtone = int(mem.ctone * 10)
#elif mem.tmode == "DTCS":
# rxmode = txmode = "DTCS"
# _mem.txtone = self.DTCS_CODES.index(mem.dtcs) + 1
# _mem.rxtone = self.DTCS_CODES.index(mem.dtcs) + 1
elif mem.tmode == "Cross":
txmode, rxmode = mem.cross_mode.split("->", 1)
if txmode == "Tone":
_mem.txtone = int(mem.rtone * 10)
#elif txmode == "DTCS":
# _mem.txtone = self.DTCS_CODES.index(mem.dtcs) + 1
else:
_mem.txtone = 0
if rxmode == "Tone":
_mem.rxtone = int(mem.ctone * 10)
#elif rxmode == "DTCS":
# _mem.rxtone = self.DTCS_CODES.index(mem.rx_dtcs) + 1
else:
_mem.rxtone = 0
else:
_mem.rxtone = 0
_mem.txtone = 0

#if txmode == "DTCS" and mem.dtcs_polarity[0] == "R":
# _mem.txtone += 0x69
#if rxmode == "DTCS" and mem.dtcs_polarity[1] == "R":
# _mem.rxtone += 0x69

_mem.scan = mem.skip != "S"
_mem.wide = mem.mode == "FM"

_mem.highpower = mem.power == POWER_LEVELS[0]

for setting in mem.extra:
setattr(_mem, setting.get_name(), setting.value)


def get_settings(self):
# """Translate the bit in the mem_struct into settings in the UI"""
_mem = self._memobj
basic = RadioSettingGroup("basic", "Basic Settings")
advanced = RadioSettingGroup("advanced", "Advanced Settings")
#other = RadioSettingGroup("other", "Other Settings")
#work = RadioSettingGroup("work", "Work Mode Settings")
#fm_preset = RadioSettingGroup("fm_preset", "FM Preset")
#dtmfe = RadioSettingGroup("dtmfe", "DTMF Encode Settings")
#dtmfd = RadioSettingGroup("dtmfd", "DTMF Decode Settings")
#service = RadioSettingGroup("service", "Service Settings")
#top = RadioSettings(basic, advanced, other, work, fm_preset, dtmfe,
# dtmfd, service)
top = RadioSettings(basic, advanced, )

# Basic settings
rs = RadioSetting("settings.beep", "Beep",
RadioSettingValueBoolean(_mem.settings.beep))
basic.append(rs)

if _mem.settings.squelcha > 0x09:
val = 0x00
else:
val = _mem.settings.squelcha
rs = RadioSetting("squelcha", "Squelch Level A",
RadioSettingValueInteger(0, 9, _mem.settings.squelcha))
basic.append(rs)


if _mem.settings.squelchb > 0x09:
val = 0x00
else:
val = _mem.settings.squelchb
rs = RadioSetting("squelchb", "Squelch Level B",
RadioSettingValueInteger(0, 9, _mem.settings.squelchb))
basic.append(rs)


if _mem.settings.voice > 0x02:
val = 0x01
else:
val = _mem.settings.voice
rs = RadioSetting("settings.voice", "Voice Prompt",
RadioSettingValueList(
LIST_VOICE, LIST_VOICE[val]))
basic.append(rs)

if _mem.settings.vox > 0x0A:
val = 0x00
else:
val = _mem.settings.vox
rs = RadioSetting("settings.vox", "VOX",
RadioSettingValueList(
LIST_OFF1TO10, LIST_OFF1TO10[val]))
basic.append(rs)

rs = RadioSetting("settings.autolk", "Automatic Key Lock",
RadioSettingValueBoolean(_mem.settings.autolk))
basic.append(rs)

if _mem.settings.screv > 0x02:
val = 0x01
else:
val = _mem.settings.screv
rs = RadioSetting("settings.screv", "Scan Resume",
RadioSettingValueList(
LIST_RESUME, LIST_RESUME[val]))
basic.append(rs)

if _mem.settings.toa > 0x0A:
val = 0x00
else:
val = _mem.settings.toa
rs = RadioSetting("settings.toa", "Time-out Pre-Alert",
RadioSettingValueList(
LIST_OFF1TO10, LIST_OFF1TO10[val]))
basic.append(rs)

if _mem.settings.timeout > 0x28:
val = 0x03
else:
val = _mem.settings.timeout
rs = RadioSetting("settings.timeout", "Timeout Timer",
RadioSettingValueList(
LIST_TIMEOUT, LIST_TIMEOUT[val]))
basic.append(rs)

rs = RadioSetting("settings.wtled", "Standby LED Color",
RadioSettingValueList(
LIST_COLOR, LIST_COLOR[_mem.settings.wtled]))
basic.append(rs)

rs = RadioSetting("settings.rxled", "RX LED Color",
RadioSettingValueList(
LIST_COLOR, LIST_COLOR[_mem.settings.rxled]))
basic.append(rs)

rs = RadioSetting("settings.txled", "TX LED Color",
RadioSettingValueList(
LIST_COLOR, LIST_COLOR[_mem.settings.txled]))
basic.append(rs)

rs = RadioSetting("settings.roger", "Roger Beep",
RadioSettingValueList(LIST_ROGER, LIST_ROGER[
_mem.settings.roger]))
basic.append(rs)

rs = RadioSetting("settings.mdfa", "Display Mode (A)",
RadioSettingValueList(LIST_MODE, LIST_MODE[
_mem.settings.mdfa]))
basic.append(rs)

rs = RadioSetting("settings.mdfb", "Display Mode (B)",
RadioSettingValueList(LIST_MODE, LIST_MODE[
_mem.settings.mdfb]))
basic.append(rs)

rs = RadioSetting("settings.pf1", "PF1 Key Assignment",
RadioSettingValueList(LIST_PF1, LIST_PF1[
_mem.settings.pf1]))
basic.append(rs)

rs = RadioSetting("settings.tdr", "Dual Watch(TDR)",
RadioSettingValueBoolean(_mem.settings.tdr))
basic.append(rs)

rs = RadioSetting("settings.ani", "ANI",
RadioSettingValueBoolean(_mem.settings.ani))
basic.append(rs)

if _mem.settings.pttdly > 0x0A:
val = 0x00
else:
val = _mem.settings.pttdly
rs = RadioSetting("settings.pttdly", "PTT ID Delay",
RadioSettingValueList(
LIST_OFF1TO30, LIST_OFF1TO30[val]))
basic.append(rs)

rs = RadioSetting("settings.pttid", "When to send PTT ID",
RadioSettingValueList(LIST_PTTID,
LIST_PTTID[_mem.settings.pttid]))
basic.append(rs)

rs = RadioSetting("settings.dtmfst", "DTMF Sidetone",
RadioSettingValueList(LIST_DTMFST, LIST_DTMFST[
_mem.settings.dtmfst]))
basic.append(rs)

rs = RadioSetting("settings.ponmsg", "Power-On Message",
RadioSettingValueList(LIST_PONMSG, LIST_PONMSG[
_mem.settings.ponmsg]))
basic.append(rs)

rs = RadioSetting("settings.dw", "DW",
RadioSettingValueBoolean(_mem.settings.dw))
basic.append(rs)

# Advanced settings
rs = RadioSetting("settings.prioritych", "Priority Channel",
RadioSettingValueList(LIST_PRIORITY, LIST_PRIORITY[
_mem.settings.prioritych]))
advanced.append(rs)

rs = RadioSetting("settings.vfomr", "Work Mode",
RadioSettingValueList(LIST_WORKMODE, LIST_WORKMODE[
_mem.settings.vfomr]))
advanced.append(rs)

dtmfchars = "0123456789"
_codeobj = _mem.settings.code
_code = "".join([dtmfchars[x] for x in _codeobj if int(x) < 0x1F])
val = RadioSettingValueString(0, 3, _code, False)
val.set_charset(dtmfchars)
rs = RadioSetting("settings.code", "PTT-ID Code", val)

def apply_code(setting, obj):
code = []
for j in range(0, 3):
try:
code.append(dtmfchars.index(str(setting.value)[j]))
except IndexError:
code.append(0xFF)
obj.code = code
rs.set_apply_callback(apply_code, _mem.settings)
advanced.append(rs)

_codeobj = _mem.settings.password
_code = "".join([dtmfchars[x] for x in _codeobj if int(x) < 0x1F])
val = RadioSettingValueString(0, 6, _code, False)
val.set_charset(dtmfchars)
rs = RadioSetting("settings.password", "Control Password", val)

def apply_code(setting, obj):
code = []
for j in range(0, 6):
try:
code.append(dtmfchars.index(str(setting.value)[j]))
except IndexError:
code.append(0xFF)
obj.password = code
rs.set_apply_callback(apply_code, _mem.settings)
advanced.append(rs)

if _mem.settings.tdrab > 0x01:
val = 0x00
else:
val = _mem.settings.tdrab
rs = RadioSetting("settings.tdrab", "Dual Watch TX Priority",
RadioSettingValueList(
LIST_AB, LIST_AB[val]))
advanced.append(rs)

rs = RadioSetting("settings.keylk", "Key Lock",
RadioSettingValueBoolean(_mem.settings.keylk))
advanced.append(rs)

rs = RadioSetting("settings.control", "Control Code",
RadioSettingValueBoolean(_mem.settings.control))
advanced.append(rs)

return top



"""
# Other settings
def _filter(name):
filtered = ""
for char in str(name):
if char in chirp_common.CHARSET_ASCII:
filtered += char
else:
filtered += " "
return filtered

_msg = _mem.sixpoweron_msg
val = RadioSettingValueString(0, 7, _filter(_msg.line1))
val.set_mutable(False)
rs = RadioSetting("sixpoweron_msg.line1", "6+Power-On Message 1", val)
other.append(rs)
val = RadioSettingValueString(0, 7, _filter(_msg.line2))
val.set_mutable(False)
rs = RadioSetting("sixpoweron_msg.line2", "6+Power-On Message 2", val)
other.append(rs)

_msg = _mem.poweron_msg
rs = RadioSetting("poweron_msg.line1", "Power-On Message 1",
RadioSettingValueString(
0, 7, _filter(_msg.line1)))
other.append(rs)
rs = RadioSetting("poweron_msg.line2", "Power-On Message 2",
RadioSettingValueString(
0, 7, _filter(_msg.line2)))
other.append(rs)

# DTMF encode settings

if _mem.ani.dtmfon > 0xC3:
val = 0x03
else:
val = _mem.ani.dtmfon
rs = RadioSetting("ani.dtmfon", "DTMF Speed (on)",
RadioSettingValueList(LIST_DTMFSPEED,
LIST_DTMFSPEED[val]))
dtmfe.append(rs)

if _mem.ani.dtmfoff > 0xC3:
val = 0x03
else:
val = _mem.ani.dtmfoff
rs = RadioSetting("ani.dtmfoff", "DTMF Speed (off)",
RadioSettingValueList(LIST_DTMFSPEED,
LIST_DTMFSPEED[val]))
dtmfe.append(rs)

"""


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

if element.has_apply_callback():
LOG.debug("Using apply callback")
element.run_apply_callback()
elif element.value.get_mutable():
LOG.debug("Setting %s = %s" % (setting, element.value))
setattr(obj, setting, element.value)
except Exception, e:
LOG.debug(element.get_name())
raise

def _set_fm_preset(self, settings):
for element in settings:
try:
val = element.value
if self._memobj.fm_presets <= 108.0 * 10 - 650:
value = int(val.get_value() * 10 - 650)
else:
value = int(val.get_value() * 10)
LOG.debug("Setting fm_presets = %s" % (value))
self._memobj.fm_presets = value
except Exception, e:
LOG.debug(element.get_name())
raise


@classmethod
def match_model(cls, filedata, filename):
match_size = False
match_model = False

# testing the file data size
if len(filedata) == 0x2008:
match_size = True

# testing the model fingerprint
match_model = model_match(cls, filedata)

#if match_size and match_model:
if match_size and match_model:
return True
else:
return False
    (1-1/1)