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New Model #1225 » uv5r.py

Temporary test driver for reading BaoFeng UV-8 - #2 - Jim Unroe, 09/25/2014 10:25 AM

 
# Copyright 2012 Dan Smith <dsmith@danplanet.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 struct
import time
import os

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

if os.getenv("CHIRP_DEBUG"):
CHIRP_DEBUG = True
else:
CHIRP_DEBUG = False

MEM_FORMAT = """
#seekto 0x0008;
struct {
lbcd rxfreq[4];
lbcd txfreq[4];
ul16 rxtone;
ul16 txtone;
u8 unused1:3,
isuhf:1,
scode:4;
u8 unknown1:7,
txtoneicon:1;
u8 mailicon:3,
unknown2:3,
lowpower:2;
u8 unknown3:1,
wide:1,
unknown4:2,
bcl:1,
scan:1,
pttid:2;
} memory[128];

#seekto 0x0B08;
struct {
u8 code[5];
u8 unused[11];
} pttid[15];

#seekto 0x0C88;
struct {
u8 code222[3];
u8 unused222[2];
u8 code333[3];
u8 unused333[2];
u8 alarmcode[3];
u8 unused119[2];
u8 unknown1;
u8 code555[3];
u8 unused555[2];
u8 code666[3];
u8 unused666[2];
u8 code777[3];
u8 unused777[2];
u8 unknown2;
u8 code60606[5];
u8 code70707[5];
u8 code[5];
u8 unused1:6,
aniid:2;
u8 unknown[2];
u8 dtmfon;
u8 dtmfoff;
} ani;

#seekto 0x0E28;
struct {
u8 squelch;
u8 step;
u8 unknown1;
u8 save;
u8 vox;
u8 unknown2;
u8 abr;
u8 tdr;
u8 beep;
u8 timeout;
u8 unknown3[4];
u8 voice;
u8 unknown4;
u8 dtmfst;
u8 unknown5;
u8 unknown12:6,
screv:2;
u8 pttid;
u8 pttlt;
u8 mdfa;
u8 mdfb;
u8 bcl;
u8 autolk; // NOTE: The UV-6 calls this byte voxenable, but the UV-5R calls
// it autolk. Since this is a minor difference, it will be referred
// to by the wrong name for the UV-6.
u8 sftd;
u8 unknown6[3];
u8 wtled;
u8 rxled;
u8 txled;
u8 almod;
u8 band;
u8 tdrab;
u8 ste;
u8 rpste;
u8 rptrl;
u8 ponmsg;
u8 roger;
u8 rogerrx;
u8 tdrch;
u8 displayab:1,
unknown1:2,
fmradio:1,
alarm:1,
unknown2:1,
reset:1,
menu:1;
u8 unknown1:6,
singleptt:1,
vfomrlock:1;
u8 workmode;
u8 keylock;
} settings;

#seekto 0x0E7E;
struct {
u8 unused1:1,
mrcha:7;
u8 unused2:1,
mrchb:7;
} wmchannel;

#seekto 0x0F10;
struct {
u8 freq[8];
u8 unknown1;
u8 offset[4];
u8 unknown2;
ul16 rxtone;
ul16 txtone;
u8 unused1:7,
band:1;
u8 unknown3;
u8 unused2:2,
sftd:2,
scode:4;
u8 unknown4;
u8 unused3:1
step:3,
unused4:4;
u8 txpower:1,
widenarr:1,
unknown5:4,
txpower3:2;
} vfoa;

#seekto 0x0F30;
struct {
u8 freq[8];
u8 unknown1;
u8 offset[4];
u8 unknown2;
ul16 rxtone;
ul16 txtone;
u8 unused1:7,
band:1;
u8 unknown3;
u8 unused2:2,
sftd:2,
scode:4;
u8 unknown4;
u8 unused3:1
step:3,
unused4:4;
u8 txpower:1,
widenarr:1,
unknown5:4,
txpower3:2;
} vfob;

#seekto 0x0F56;
u16 fm_presets;

#seekto 0x1008;
struct {
char name[7];
u8 unknown2[9];
} names[128];

#seekto 0x1818;
struct {
char line1[7];
char line2[7];
} sixpoweron_msg;

#seekto 0x%04X;
struct {
char line1[7];
char line2[7];
} poweron_msg;

#seekto 0x1838;
struct {
char line1[7];
char line2[7];
} firmware_msg;

struct limit {
u8 enable;
bbcd lower[2];
bbcd upper[2];
};

#seekto 0x1908;
struct {
struct limit vhf;
struct limit uhf;
} limits_new;

#seekto 0x1910;
struct {
u8 unknown1[2];
struct limit vhf;
u8 unknown2;
u8 unknown3[8];
u8 unknown4[2];
struct limit uhf;
} limits_old;

"""

# 0x1EC0 - 0x2000

vhf_220_radio = "\x02"

BASETYPE_UV5R = ["BFS", "BFB", "N5R-2"]
BASETYPE_F11 = ["USA"]
BASETYPE_UV82 = ["US2S", "B82S", "BF82"]
BASETYPE_BJ55 = ["BJ55"] # needed for for the Baojie UV-55 in bjuv55.py
BASETYPE_UV6 = ["BF1"]
BASETYPE_KT980HP = ["BFP3V3 B"]
BASETYPE_F8HP = ["BFP3V3 F", "N5R-3"]
BASETYPE_LIST = BASETYPE_UV5R + BASETYPE_F11 + BASETYPE_UV82 + \
BASETYPE_BJ55 + BASETYPE_UV6 + BASETYPE_KT980HP + \
BASETYPE_F8HP

AB_LIST = ["A", "B"]
ALMOD_LIST = ["Site", "Tone", "Code", "_unknown_"]
BANDWIDTH_LIST = ["Wide", "Narrow"]
COLOR_LIST = ["Off", "Blue", "Orange", "Purple"]
DTMFSPEED_LIST = ["%s ms" % x for x in range(50, 2010, 10)]
DTMFST_LIST = ["OFF", "DT-ST", "ANI-ST", "DT+ANI"]
MODE_LIST = ["Channel", "Name", "Frequency"]
PONMSG_LIST = ["Full", "Message"]
PTTID_LIST = ["Off", "BOT", "EOT", "Both"]
PTTIDCODE_LIST = ["%s" % x for x in range(1, 16)]
RESUME_LIST = ["TO", "CO", "SE"]
ROGERRX_LIST = ["Off"] + AB_LIST
RPSTE_LIST = ["OFF"] + ["%s" % x for x in range(1, 11)]
SAVE_LIST = ["Off", "1:1", "1:2", "1:3", "1:4"]
SCODE_LIST = ["%s" % x for x in range(1, 16)]
SHIFTD_LIST = ["Off", "+", "-"]
STEDELAY_LIST = ["OFF"] + ["%s ms" % x for x in range(100, 1100, 100)]
STEPS = [2.5, 5.0, 6.25, 10.0, 12.5, 25.0]
STEP_LIST = [str(x) for x in STEPS]
STEPS = [2.5, 5.0, 6.25, 10.0, 12.5, 20.0, 25.0, 50.0]
STEP291_LIST = [str(x) for x in STEPS]
TDRAB_LIST = ["Off"] + AB_LIST
TDRCH_LIST = ["CH%s" % x for x in range(1, 129)]
TIMEOUT_LIST = ["%s sec" % x for x in range(15, 615, 15)]
TXPOWER_LIST = ["High", "Low"]
TXPOWER3_LIST = ["High", "Mid", "Low"]
VOICE_LIST = ["Off", "English", "Chinese"]
VOX_LIST = ["OFF"] + ["%s" % x for x in range(1, 11)]
WORKMODE_LIST = ["Frequency", "Channel"]

SETTING_LISTS = {
"almod" : ALMOD_LIST,
"aniid" : PTTID_LIST,
"displayab" : AB_LIST,
"dtmfst" : DTMFST_LIST,
"dtmfspeed" : DTMFSPEED_LIST,
"mdfa" : MODE_LIST,
"mdfb" : MODE_LIST,
"ponmsg" : PONMSG_LIST,
"pttid" : PTTID_LIST,
"rogerrx" : ROGERRX_LIST,
"rpste" : RPSTE_LIST,
"rxled" : COLOR_LIST,
"save" : SAVE_LIST,
"scode" : PTTIDCODE_LIST,
"screv" : RESUME_LIST,
"sftd" : SHIFTD_LIST,
"stedelay" : STEDELAY_LIST,
"step" : STEP_LIST,
"step291" : STEP291_LIST,
"tdrab" : TDRAB_LIST,
"tdrch" : TDRCH_LIST,
"timeout" : TIMEOUT_LIST,
"txled" : COLOR_LIST,
"txpower" : TXPOWER_LIST,
"txpower3" : TXPOWER3_LIST,
"voice" : VOICE_LIST,
"vox" : VOX_LIST,
"widenarr" : BANDWIDTH_LIST,
"workmode" : WORKMODE_LIST,
"wtled" : COLOR_LIST
}

def _do_status(radio, block):
status = chirp_common.Status()
status.msg = "Cloning"
status.cur = block
status.max = radio.get_memsize()
radio.status_fn(status)

def validate_orig(ident):
try:
ver = int(ident[4:7])
if ver >= 291:
raise errors.RadioError("Radio version %i not supported" % ver)
except ValueError:
raise errors.RadioError("Radio reported invalid version string")

def validate_291(ident):
if ident[4:7] != "\x30\x04\x50":
raise errors.RadioError("Radio version not supported")

UV5R_MODEL_ORIG = "\x50\xBB\xFF\x01\x25\x98\x4D"
UV5R_MODEL_291 = "\x50\xBB\xFF\x20\x12\x07\x25"
UV5R_MODEL_F11 = "\x50\xBB\xFF\x13\xA1\x11\xDD"
UV5R_MODEL_UV82 = "\x50\xBB\xFF\x20\x13\x01\x05"
UV5R_MODEL_UV6 = "\x50\xBB\xFF\x20\x12\x08\x23"
UV5R_MODEL_UV6_ORIG = "\x50\xBB\xFF\x12\x03\x98\x4D"
UV5R_MODEL_UV8 = "\x50\xBB\xFF\x20\x12\x11\x19"

def _upper_band_from_data(data):
return data[0x03:0x04]

def _upper_band_from_image(radio):
return _upper_band_from_data(radio.get_mmap())

def _firmware_version_from_data(data, version_start, version_stop):
version_tag = data[version_start:version_stop]
return version_tag

def _firmware_version_from_image(radio):
version = _firmware_version_from_data(radio.get_mmap(),
radio._fw_ver_file_start,
radio._fw_ver_file_stop)
if CHIRP_DEBUG:
print "_firmware_version_from_image: " + util.hexprint(version)
return version

def _special_block_from_data(data, special_block_start, special_block_stop):
special_block_tag = data[special_block_start:special_block_stop]
return special_block_tag

def _special_block_from_image(radio):
special_block = _special_block_from_data(radio.get_mmap(), 0x0CFA, 0x0D01)
if CHIRP_DEBUG:
print "_special_block_from_image: " + util.hexprint(special_block)
return special_block

def _do_ident(radio, magic):
serial = radio.pipe
serial.setTimeout(1)

print "Sending Magic: %s" % util.hexprint(magic)
for byte in magic:
serial.write(byte)
time.sleep(0.01)
ack = serial.read(1)

if ack != "\x06":
if ack:
print repr(ack)
raise errors.RadioError("Radio did not respond")

serial.write("\x02")
ident = serial.read(8)

print "Ident:\n%s" % util.hexprint(ident)

serial.write("\x06")
ack = serial.read(1)
if ack != "\x06":
ack = serial.read(1)
if ack != "\x06":
raise errors.RadioError("Radio refused clone")

return ident

def _read_block(radio, start, size):
msg = struct.pack(">BHB", ord("S"), start, size)
radio.pipe.write(msg)

answer = radio.pipe.read(4)
if len(answer) != 4:
raise errors.RadioError("Radio refused to send block 0x%04x" % start)

cmd, addr, length = struct.unpack(">BHB", answer)
if cmd != ord("X") or addr != start or length != size:
print "Invalid answer for block 0x%04x:" % start
print "CMD: %s ADDR: %04x SIZE: %02x" % (cmd, addr, length)
raise errors.RadioError("Unknown response from radio")

chunk = radio.pipe.read(0x40)
if not chunk:
raise errors.RadioError("Radio did not send block 0x%04x" % start)
elif len(chunk) != size:
print "Chunk length was 0x%04i" % len(chunk)
raise errors.RadioError("Radio sent incomplete block 0x%04x" % start)

radio.pipe.write("\x06")

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

return chunk

def _get_radio_firmware_version(radio):
if radio.MODEL == "BJ-UV55":
block = _read_block(radio, 0x1FF0, 0x40)
version = block[0:6]
else:
block1 = _read_block(radio, 0x1EC0, 0x40)
block2 = _read_block(radio, 0x1F00, 0x40)
block = block1 + block2
version = block[48:62]
return version

def _get_radio_special_block(radio):
block = _read_block(radio, 0xCF0, 0x40)
special_block = block[2:9]
return special_block

def _ident_radio(radio):
for magic in radio._idents:
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 _do_download(radio):
data = _ident_radio(radio)

radio_version = _get_radio_firmware_version(radio)
print "Radio Version is %s" % repr(radio_version)

if not any(type in radio_version for type in radio._basetype):
raise errors.RadioError("Incorrect 'Model' selected.")

# Main block
if CHIRP_DEBUG:
print "downloading main block..."
for i in range(0, 0x1800, 0x40):
data += _read_block(radio, i, 0x40)
_do_status(radio, i)
if CHIRP_DEBUG:
print "done."
print "downloading aux block..."
# Auxiliary block starts at 0x1ECO (?)
for i in range(0x1EC0, 0x2000, 0x40):
data += _read_block(radio, i, 0x40)
if CHIRP_DEBUG:
print "done."
return memmap.MemoryMap(data)

def _send_block(radio, addr, data):
msg = struct.pack(">BHB", ord("X"), addr, len(data))
radio.pipe.write(msg + data)

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

def _do_upload(radio):
ident = _ident_radio(radio)
radio_upper_band = ident[3:4]
image_upper_band = _upper_band_from_image(radio)

if image_upper_band == vhf_220_radio or radio_upper_band == vhf_220_radio:
if image_upper_band != radio_upper_band:
raise errors.RadioError("Image not supported by radio")

image_version = _firmware_version_from_image(radio)
radio_version = _get_radio_firmware_version(radio)
print "Image Version is %s" % repr(image_version)
print "Radio Version is %s" % repr(radio_version)

if not any(type in radio_version for type in BASETYPE_LIST):
raise errors.RadioError("Unsupported firmware version: `%s'" %
radio_version)

image_special_block = _special_block_from_image(radio)
radio_special_block = _get_radio_special_block(radio)
print "Image Special Block is " + util.hexprint(image_special_block)
print "Radio Special Block is " + util.hexprint(radio_special_block)

if image_special_block != radio_special_block:
raise errors.RadioError("Image not supported by radio: `%s'" %
radio_special_block)

# Main block
for i in range(0x08, 0x1808, 0x10):
_send_block(radio, i - 0x08, radio.get_mmap()[i:i + 0x10])
_do_status(radio, i)

if len(radio.get_mmap().get_packed()) == 0x1808:
print "Old image, not writing aux block"
return # Old image, no aux block

if image_version != radio_version:
msg = ("Upload finished, but the 'Other Settings' "
"could not be sent because the firmware "
"version of the image (%s) does not match "
"that of the radio (%s).")
raise errors.RadioError(msg % (image_version, radio_version))

# Auxiliary block at radio address 0x1EC0, our offset 0x1808
for i in range(0x1EC0, 0x2000, 0x10):
addr = 0x1808 + (i - 0x1EC0)
_send_block(radio, i, radio.get_mmap()[addr:addr + 0x10])

UV5R_POWER_LEVELS = [chirp_common.PowerLevel("High", watts=4.00),
chirp_common.PowerLevel("Low", watts=1.00)]

UV5R_POWER_LEVELS3 = [chirp_common.PowerLevel("High", watts=8.00),
chirp_common.PowerLevel("Med", watts=4.00),
chirp_common.PowerLevel("Low", watts=1.00)]

UV5R_DTCS = sorted(chirp_common.DTCS_CODES + [645])

UV5R_CHARSET = chirp_common.CHARSET_UPPER_NUMERIC + \
"!@#$%^&*()+-=[]:\";'<>?,./"

# Uncomment this to actually register this radio in CHIRP
@directory.register
class BaofengUV5R(chirp_common.CloneModeRadio,
chirp_common.ExperimentalRadio):
"""Baofeng UV-5R"""
VENDOR = "Baofeng"
MODEL = "UV-5R"
BAUD_RATE = 9600

_memsize = 0x1808
_basetype = BASETYPE_UV5R
_idents = [UV5R_MODEL_291,
UV5R_MODEL_ORIG
]
_vhf_range = (136000000, 174000000)
_220_range = (220000000, 260000000)
_uhf_range = (400000000, 520000000)
_mem_params = ( 0x1828 # poweron_msg offset
)
# offset of fw version in image file
_fw_ver_file_start = 0x1838
_fw_ver_file_stop = 0x1846

@classmethod
def get_prompts(cls):
rp = chirp_common.RadioPrompts()
rp.experimental = ('Due to the fact that the manufacturer continues to '
'release new versions of the firmware with obscure and '
'hard-to-track changes, this driver may not work with '
'your device. Thus far and to the best knowledge of the '
'author, no UV-5R radios have been harmed by using CHIRP. '
'However, proceed at your own risk!')
rp.pre_download = _(dedent("""\
1. Turn radio off.
2. Connect cable to mic/spkr connector.
3. Make sure connector is firmly connected.
4. Turn radio on.
5. Ensure that the radio is tuned to channel with no activity.
6. Click OK to download image from device."""))
rp.pre_upload = _(dedent("""\
1. Turn radio off.
2. Connect cable to mic/spkr connector.
3. Make sure connector is firmly connected.
4. Turn radio on.
5. Ensure that the radio is tuned to channel with no activity.
6. Click OK to upload image to device."""))
return rp

def get_features(self):
rf = chirp_common.RadioFeatures()
rf.has_settings = True
rf.has_bank = False
rf.has_cross = True
rf.has_rx_dtcs = True
rf.has_tuning_step = False
rf.can_odd_split = True
rf.valid_name_length = 7
rf.valid_characters = UV5R_CHARSET
rf.valid_skips = ["", "S"]
rf.valid_tmodes = ["", "Tone", "TSQL", "DTCS", "Cross"]
rf.valid_cross_modes = ["Tone->Tone", "Tone->DTCS", "DTCS->Tone",
"->Tone", "->DTCS", "DTCS->", "DTCS->DTCS"]
rf.valid_power_levels = UV5R_POWER_LEVELS
rf.valid_duplexes = ["", "-", "+", "split", "off"]
rf.valid_modes = ["FM", "NFM"]

normal_bands = [self._vhf_range, self._uhf_range]
rax_bands = [self._vhf_range, self._220_range]

if self._mmap is None:
rf.valid_bands = [normal_bands[0], rax_bands[1], normal_bands[1]]
elif not self._is_orig() and self._my_upper_band() == vhf_220_radio:
rf.valid_bands = rax_bands
else:
rf.valid_bands = normal_bands
rf.memory_bounds = (0, 127)
return rf

@classmethod
def match_model(cls, filedata, filename):
match_size = False
match_model = False
if len(filedata) in [0x1808, 0x1948]:
match_size = True
fwdata = _firmware_version_from_data(filedata,
cls._fw_ver_file_start,
cls._fw_ver_file_stop)
if any(type in fwdata for type in cls._basetype):
match_model = True
if match_size and match_model:
return True
else:
return False

def process_mmap(self):
self._memobj = bitwise.parse(MEM_FORMAT % self._mem_params, self._mmap)

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

def sync_out(self):
try:
_do_upload(self)
except errors.RadioError:
raise
except Exception, e:
raise errors.RadioError("Failed to communicate with radio: %s" % e)

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

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]

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

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):
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 str(char) == "\xFF":
char = " " # The UV-5R software may have 0xFF mid-name
mem.name += str(char)
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
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 = UV5R_DTCS[index]
else:
print "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
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 = UV5R_DTCS[index]
else:
print "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 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"

if self.MODEL == "KT-980HP" or self.MODEL == "BF-F8HP":
levels = UV5R_POWER_LEVELS3
else:
levels = UV5R_POWER_LEVELS
try:
mem.power = levels[_mem.lowpower]
except IndexError:
print "Radio reported invalid power level %s (in %s)" % (
_mem.power, levels)
mem.power = levels[0]

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

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

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

rs = RadioSetting("pttid", "PTT ID",
RadioSettingValueList(PTTID_LIST,
PTTID_LIST[_mem.pttid]))
mem.extra.append(rs)

rs = RadioSetting("scode", "PTT ID Code",
RadioSettingValueList(PTTIDCODE_LIST,
PTTIDCODE_LIST[_mem.scode]))
mem.extra.append(rs)

return mem

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

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

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

if mem.empty:
_mem.set_raw("\xff" * 16)
return

_mem.set_raw("\x00" * 16)

_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

_namelength = self.get_features().valid_name_length
for i in range(_namelength):
try:
_nam.name[i] = mem.name[i]
except IndexError:
_nam.name[i] = "\xFF"

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 = UV5R_DTCS.index(mem.dtcs) + 1
_mem.rxtone = UV5R_DTCS.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 = UV5R_DTCS.index(mem.dtcs) + 1
else:
_mem.txtone = 0
if rxmode == "Tone":
_mem.rxtone = int(mem.ctone * 10)
elif rxmode == "DTCS":
_mem.rxtone = UV5R_DTCS.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"

if mem.power:
if self.MODEL == "KT-980HP" or self.MODEL == "BF-F8HP":
levels = [str(l) for l in UV5R_POWER_LEVELS3]
_mem.lowpower = levels.index(str(mem.power))
else:
_mem.lowpower = UV5R_POWER_LEVELS.index(mem.power)
else:
_mem.lowpower = 0

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

def _is_orig(self):
version_tag = _firmware_version_from_image(self)
if CHIRP_DEBUG:
print "@_is_orig, version_tag:", util.hexprint(version_tag)
try:
if 'BFB' in version_tag:
idx = version_tag.index("BFB") + 3
version = int(version_tag[idx:idx + 3])
return version < 291
return False
except:
pass
raise errors.RadioError("Unable to parse version string %s" %
version_tag)

def _my_version(self):
version_tag = _firmware_version_from_image(self)
if 'BFS' in version_tag:
idx = version_tag.index("BFS") + 3
return int(version_tag[idx:idx + 3])
elif 'BF82' in version_tag:
idx = version_tag.index("BF82") + 2
return int(version_tag[idx:idx + 4])
elif 'B82S' in version_tag:
idx = version_tag.index("B82S") + 4
return int(version_tag[idx:idx + 2]) + 8200
elif 'US2S' in version_tag:
idx = version_tag.index("US2S") + 4
return int(version_tag[idx:idx + 2]) + 8200
elif 'USA' in version_tag:
idx = version_tag.index("USA") + 3
return int(version_tag[idx:idx + 3]) + 11000
elif 'BJ55' in version_tag:
idx = version_tag.index("BJ55") + 2
return int(version_tag[idx:idx + 4])
elif 'BF1' in version_tag:
idx = version_tag.index("BF1") + 2
return int(version_tag[idx:idx + 4])
elif 'BFP' in version_tag:
idx = version_tag.index("BFP") + 5
return int(version_tag[idx:idx + 1]) + 98000
elif 'N5R-2' in version_tag:
idx = version_tag.index("N5R-2") + 4
return int(version_tag[idx:idx + 2]) + 300
elif 'N5R-3' in version_tag:
idx = version_tag.index("N5R-3") + 4
return int(version_tag[idx:idx + 2]) + 98000
elif 'BFB' in version_tag:
idx = version_tag.index("BFB") + 3
return int(version_tag[idx:idx + 3])

raise Exception("Unrecognized firmware version string")

def _my_upper_band(self):
band_tag = _upper_band_from_image(self)
return band_tag

def _get_settings(self):
_ani = self._memobj.ani
_settings = self._memobj.settings
_vfoa = self._memobj.vfoa
_vfob = self._memobj.vfob
_wmchannel = self._memobj.wmchannel
basic = RadioSettingGroup("basic", "Basic Settings")
advanced = RadioSettingGroup("advanced", "Advanced Settings")
group = RadioSettingGroup("top", "All Settings", basic, advanced)

rs = RadioSetting("squelch", "Carrier Squelch Level",
RadioSettingValueInteger(0, 9, _settings.squelch))
basic.append(rs)

rs = RadioSetting("save", "Battery Saver",
RadioSettingValueList(SAVE_LIST,
SAVE_LIST[_settings.save]))
basic.append(rs)

rs = RadioSetting("vox", "VOX Sensitivity",
RadioSettingValueList(VOX_LIST,
VOX_LIST[_settings.vox]))
advanced.append(rs)

if self.MODEL == "UV-6":
# NOTE: The UV-6 calls this byte voxenable, but the UV-5R calls it
# autolk. Since this is a minor difference, it will be referred to
# by the wrong name for the UV-6.
rs = RadioSetting("autolk", "Vox",
RadioSettingValueBoolean(_settings.autolk))
advanced.append(rs)

if self.MODEL != "UV-6":
rs = RadioSetting("abr", "Backlight Timeout",
RadioSettingValueInteger(0, 24, _settings.abr))
basic.append(rs)

rs = RadioSetting("tdr", "Dual Watch",
RadioSettingValueBoolean(_settings.tdr))
advanced.append(rs)

if self.MODEL == "UV-6":
rs = RadioSetting("tdrch", "Dual Watch Channel",
RadioSettingValueList(TDRCH_LIST,
TDRCH_LIST[
_settings.tdrch]))
advanced.append(rs)

rs = RadioSetting("tdrab", "Dual Watch TX Priority",
RadioSettingValueBoolean(_settings.tdrab))
advanced.append(rs)
else:
rs = RadioSetting("tdrab", "Dual Watch TX Priority",
RadioSettingValueList(TDRAB_LIST,
TDRAB_LIST[
_settings.tdrab]))
advanced.append(rs)

if self.MODEL == "UV-6":
rs = RadioSetting("alarm", "Alarm Sound",
RadioSettingValueBoolean(_settings.alarm))
advanced.append(rs)

rs = RadioSetting("almod", "Alarm Mode",
RadioSettingValueList(ALMOD_LIST,
ALMOD_LIST[_settings.almod]))
advanced.append(rs)

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

rs = RadioSetting("timeout", "Timeout Timer",
RadioSettingValueList(TIMEOUT_LIST,
TIMEOUT_LIST[
_settings.timeout]))
basic.append(rs)

if self._is_orig() and self._my_version() < 251:
rs = RadioSetting("voice", "Voice",
RadioSettingValueBoolean(_settings.voice))
advanced.append(rs)
else:
rs = RadioSetting("voice", "Voice",
RadioSettingValueList(VOICE_LIST,
VOICE_LIST[
_settings.voice]))
advanced.append(rs)

rs = RadioSetting("screv", "Scan Resume",
RadioSettingValueList(RESUME_LIST,
RESUME_LIST[_settings.screv]))
advanced.append(rs)

if self.MODEL != "UV-6":
rs = RadioSetting("mdfa", "Display Mode (A)",
RadioSettingValueList(MODE_LIST,
MODE_LIST[_settings.mdfa]))
basic.append(rs)

rs = RadioSetting("mdfb", "Display Mode (B)",
RadioSettingValueList(MODE_LIST,
MODE_LIST[_settings.mdfb]))
basic.append(rs)

rs = RadioSetting("bcl", "Busy Channel Lockout",
RadioSettingValueBoolean(_settings.bcl))
advanced.append(rs)

if self.MODEL != "UV-6":
rs = RadioSetting("autolk", "Automatic Key Lock",
RadioSettingValueBoolean(_settings.autolk))
advanced.append(rs)

rs = RadioSetting("fmradio", "Broadcast FM Radio",
RadioSettingValueBoolean(_settings.fmradio))
advanced.append(rs)

if self.MODEL != "UV-6":
rs = RadioSetting("wtled", "Standby LED Color",
RadioSettingValueList(COLOR_LIST,
COLOR_LIST[
_settings.wtled]))
basic.append(rs)

rs = RadioSetting("rxled", "RX LED Color",
RadioSettingValueList(COLOR_LIST,
COLOR_LIST[
_settings.rxled]))
basic.append(rs)

rs = RadioSetting("txled", "TX LED Color",
RadioSettingValueList(COLOR_LIST,
COLOR_LIST[
_settings.txled]))
basic.append(rs)

if self.MODEL == "UV-82":
rs = RadioSetting("roger", "Roger Beep (TX)",
RadioSettingValueBoolean(_settings.roger))
basic.append(rs)
rs = RadioSetting("rogerrx", "Roger Beep (RX)",
RadioSettingValueList(ROGERRX_LIST,
ROGERRX_LIST[
_settings.rogerrx]))
basic.append(rs)
else:
rs = RadioSetting("roger", "Roger Beep",
RadioSettingValueBoolean(_settings.roger))
basic.append(rs)

rs = RadioSetting("ste", "Squelch Tail Eliminate (HT to HT)",
RadioSettingValueBoolean(_settings.ste))
advanced.append(rs)

rs = RadioSetting("rpste", "Squelch Tail Eliminate (repeater)",
RadioSettingValueList(RPSTE_LIST,
RPSTE_LIST[_settings.rpste]))
advanced.append(rs)

rs = RadioSetting("rptrl", "STE Repeater Delay",
RadioSettingValueList(STEDELAY_LIST,
STEDELAY_LIST[_settings.rptrl]))
advanced.append(rs)

if self.MODEL != "UV-6":
rs = RadioSetting("reset", "RESET Menu",
RadioSettingValueBoolean(_settings.reset))
advanced.append(rs)

rs = RadioSetting("menu", "All Menus",
RadioSettingValueBoolean(_settings.menu))
advanced.append(rs)

if self.MODEL == "F-11":
# this is an F-11 only feature
rs = RadioSetting("vfomrlock", "VFO/MR Button",
RadioSettingValueBoolean(_settings.vfomrlock))
advanced.append(rs)

if self.MODEL == "UV-82":
# this is a UV-82C only feature
rs = RadioSetting("vfomrlock", "VFO/MR Switching (UV-82C only)",
RadioSettingValueBoolean(_settings.vfomrlock))
advanced.append(rs)

if self.MODEL == "UV-82":
# this is an UV-82C only feature
rs = RadioSetting("singleptt", "Single PTT (UV-82C only)",
RadioSettingValueBoolean(_settings.singleptt))
advanced.append(rs)

if len(self._mmap.get_packed()) == 0x1808:
# Old image, without aux block
return group

other = RadioSettingGroup("other", "Other Settings")
group.append(other)

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

_msg = self._memobj.firmware_msg
val = RadioSettingValueString(0, 7, _filter(_msg.line1))
val.set_mutable(False)
rs = RadioSetting("firmware_msg.line1", "Firmware Message 1", val)
other.append(rs)

val = RadioSettingValueString(0, 7, _filter(_msg.line2))
val.set_mutable(False)
rs = RadioSetting("firmware_msg.line2", "Firmware Message 2", val)
other.append(rs)

if self.MODEL != "UV-6":
_msg = self._memobj.sixpoweron_msg
rs = RadioSetting("sixpoweron_msg.line1", "6+Power-On Message 1",
RadioSettingValueString(0, 7, _filter(
_msg.line1)))
other.append(rs)
rs = RadioSetting("sixpoweron_msg.line2", "6+Power-On Message 2",
RadioSettingValueString(0, 7, _filter(
_msg.line2)))
other.append(rs)

_msg = self._memobj.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)

rs = RadioSetting("ponmsg", "Power-On Message",
RadioSettingValueList(PONMSG_LIST,
PONMSG_LIST[
_settings.ponmsg]))
other.append(rs)

if self._is_orig():
limit = "limits_old"
else:
limit = "limits_new"

vhf_limit = getattr(self._memobj, limit).vhf
rs = RadioSetting("%s.vhf.lower" % limit, "VHF Lower Limit (MHz)",
RadioSettingValueInteger(1, 1000,
vhf_limit.lower))
other.append(rs)

rs = RadioSetting("%s.vhf.upper" % limit, "VHF Upper Limit (MHz)",
RadioSettingValueInteger(1, 1000,
vhf_limit.upper))
other.append(rs)

rs = RadioSetting("%s.vhf.enable" % limit, "VHF TX Enabled",
RadioSettingValueBoolean(vhf_limit.enable))
other.append(rs)

uhf_limit = getattr(self._memobj, limit).uhf
rs = RadioSetting("%s.uhf.lower" % limit, "UHF Lower Limit (MHz)",
RadioSettingValueInteger(1, 1000,
uhf_limit.lower))
other.append(rs)
rs = RadioSetting("%s.uhf.upper" % limit, "UHF Upper Limit (MHz)",
RadioSettingValueInteger(1, 1000,
uhf_limit.upper))
other.append(rs)
rs = RadioSetting("%s.uhf.enable" % limit, "UHF TX Enabled",
RadioSettingValueBoolean(uhf_limit.enable))
other.append(rs)

if self.MODEL != "UV-6":
workmode = RadioSettingGroup("workmode", "Work Mode Settings")
group.append(workmode)

rs = RadioSetting("displayab", "Display",
RadioSettingValueList(AB_LIST,
AB_LIST[
_settings.displayab]))
workmode.append(rs)

rs = RadioSetting("workmode", "VFO/MR Mode",
RadioSettingValueList(WORKMODE_LIST,
WORKMODE_LIST[
_settings.workmode]))
workmode.append(rs)

rs = RadioSetting("keylock", "Keypad Lock",
RadioSettingValueBoolean(_settings.keylock))
workmode.append(rs)

rs = RadioSetting("wmchannel.mrcha", "MR A Channel",
RadioSettingValueInteger(0, 127,
_wmchannel.mrcha))
workmode.append(rs)

rs = RadioSetting("wmchannel.mrchb", "MR B Channel",
RadioSettingValueInteger(0, 127,
_wmchannel.mrchb))
workmode.append(rs)

def convert_bytes_to_freq(bytes):
real_freq = 0
for byte in bytes:
real_freq = (real_freq * 10) + byte
return chirp_common.format_freq(real_freq * 10)

def my_validate(value):
value = chirp_common.parse_freq(value)
if 17400000 <= value and value < 40000000:
msg = ("Can't be between 174.00000-400.00000")
raise InvalidValueError(msg)
return chirp_common.format_freq(value)

def apply_freq(setting, obj):
value = chirp_common.parse_freq(str(setting.value)) / 10
obj.band = value >= 40000000
for i in range(7, -1, -1):
obj.freq[i] = value % 10
value /= 10

val1a = RadioSettingValueString(0, 10,
convert_bytes_to_freq(_vfoa.freq))
val1a.set_validate_callback(my_validate)
rs = RadioSetting("vfoa.freq", "VFO A Frequency", val1a)
rs.set_apply_callback(apply_freq, _vfoa)
workmode.append(rs)

val1b = RadioSettingValueString(0, 10,
convert_bytes_to_freq(_vfob.freq))
val1b.set_validate_callback(my_validate)
rs = RadioSetting("vfob.freq", "VFO B Frequency", val1b)
rs.set_apply_callback(apply_freq, _vfob)
workmode.append(rs)

rs = RadioSetting("vfoa.sftd", "VFO A Shift",
RadioSettingValueList(SHIFTD_LIST,
SHIFTD_LIST[_vfoa.sftd]))
workmode.append(rs)

rs = RadioSetting("vfob.sftd", "VFO B Shift",
RadioSettingValueList(SHIFTD_LIST,
SHIFTD_LIST[_vfob.sftd]))
workmode.append(rs)

def convert_bytes_to_offset(bytes):
real_offset = 0
for byte in bytes:
real_offset = (real_offset * 10) + byte
return chirp_common.format_freq(real_offset * 10000)

def apply_offset(setting, obj):
value = chirp_common.parse_freq(str(setting.value)) / 10000
for i in range(3, -1, -1):
obj.offset[i] = value % 10
value /= 10

val1a = RadioSettingValueString(0, 10,
convert_bytes_to_offset(
_vfoa.offset))
rs = RadioSetting("vfoa.offset", "VFO A Offset (0.00-69.95)", val1a)
rs.set_apply_callback(apply_offset, _vfoa)
workmode.append(rs)

val1b = RadioSettingValueString(0, 10,
convert_bytes_to_offset(
_vfob.offset))
rs = RadioSetting("vfob.offset", "VFO B Offset (0.00-69.95)", val1b)
rs.set_apply_callback(apply_offset, _vfob)
workmode.append(rs)

if self.MODEL == "KT-980HP" or self.MODEL == "BF-F8HP":
rs = RadioSetting("vfoa.txpower3", "VFO A Power",
RadioSettingValueList(TXPOWER3_LIST,
TXPOWER3_LIST[
_vfoa.txpower3]))
workmode.append(rs)

rs = RadioSetting("vfob.txpower3", "VFO B Power",
RadioSettingValueList(TXPOWER3_LIST,
TXPOWER3_LIST[
_vfob.txpower3]))
workmode.append(rs)
else:
rs = RadioSetting("vfoa.txpower", "VFO A Power",
RadioSettingValueList(TXPOWER_LIST,
TXPOWER_LIST[
_vfoa.txpower]))
workmode.append(rs)

rs = RadioSetting("vfob.txpower", "VFO B Power",
RadioSettingValueList(TXPOWER_LIST,
TXPOWER_LIST[
_vfob.txpower]))
workmode.append(rs)


rs = RadioSetting("vfoa.widenarr", "VFO A Bandwidth",
RadioSettingValueList(BANDWIDTH_LIST,
BANDWIDTH_LIST[
_vfoa.widenarr]))
workmode.append(rs)

rs = RadioSetting("vfob.widenarr", "VFO B Bandwidth",
RadioSettingValueList(BANDWIDTH_LIST,
BANDWIDTH_LIST[
_vfob.widenarr]))
workmode.append(rs)

rs = RadioSetting("vfoa.scode", "VFO A PTT-ID",
RadioSettingValueList(PTTIDCODE_LIST,
PTTIDCODE_LIST[
_vfoa.scode]))
workmode.append(rs)

rs = RadioSetting("vfob.scode", "VFO B PTT-ID",
RadioSettingValueList(PTTIDCODE_LIST,
PTTIDCODE_LIST[
_vfob.scode]))
workmode.append(rs)

if not self._is_orig():
rs = RadioSetting("vfoa.step", "VFO A Tuning Step",
RadioSettingValueList(STEP291_LIST,
STEP291_LIST[
_vfoa.step]))
workmode.append(rs)
rs = RadioSetting("vfob.step", "VFO B Tuning Step",
RadioSettingValueList(STEP291_LIST,
STEP291_LIST[
_vfob.step]))
workmode.append(rs)
else:
rs = RadioSetting("vfoa.step", "VFO A Tuning Step",
RadioSettingValueList(STEP_LIST,
STEP_LIST[_vfoa.step]))
workmode.append(rs)
rs = RadioSetting("vfob.step", "VFO B Tuning Step",
RadioSettingValueList(STEP_LIST,
STEP_LIST[_vfob.step]))
workmode.append(rs)

fm_preset = RadioSettingGroup("fm_preset", "FM Radio Preset")
group.append(fm_preset)

if self._memobj.fm_presets <= 116.1 * 10 - 650:
preset = self._memobj.fm_presets / 10.0 + 65
else:
preset = 76.0
rs = RadioSetting("fm_presets", "FM Preset(MHz)",
RadioSettingValueFloat(65, 116.1, preset, 0.1, 1))
fm_preset.append(rs)

dtmf = RadioSettingGroup("dtmf", "DTMF Settings")
group.append(dtmf)
dtmfchars = "0123456789 *#ABCD"

for i in range(0, 15):
_codeobj = self._memobj.pttid[i].code
_code = "".join([dtmfchars[x] for x in _codeobj if int(x) < 0x1F])
val = RadioSettingValueString(0, 5, _code, False)
val.set_charset(dtmfchars)
rs = RadioSetting("pttid/%i.code" % i,
"PTT ID Code %i" % (i + 1), val)
def apply_code(setting, obj):
code = []
for j in range(0, 5):
try:
code.append(dtmfchars.index(str(setting.value)[j]))
except IndexError:
code.append(0xFF)
obj.code = code
rs.set_apply_callback(apply_code, self._memobj.pttid[i])
dtmf.append(rs)

_codeobj = self._memobj.ani.code
_code = "".join([dtmfchars[x] for x in _codeobj if int(x) < 0x1F])
val = RadioSettingValueString(0, 5, _code, False)
val.set_charset(dtmfchars)
rs = RadioSetting("ani.code", "ANI Code", val)
def apply_code(setting, obj):
code = []
for j in range(0, 5):
try:
code.append(dtmfchars.index(str(setting.value)[j]))
except IndexError:
code.append(0xFF)
obj.code = code
rs.set_apply_callback(apply_code, _ani)
dtmf.append(rs)

rs = RadioSetting("ani.aniid", "ANI ID",
RadioSettingValueList(PTTID_LIST,
PTTID_LIST[_ani.aniid]))
dtmf.append(rs)

_codeobj = self._memobj.ani.alarmcode
_code = "".join([dtmfchars[x] for x in _codeobj if int(x) < 0x1F])
val = RadioSettingValueString(0, 3, _code, False)
val.set_charset(dtmfchars)
rs = RadioSetting("ani.alarmcode", "Alarm Code", val)
def apply_code(setting, obj):
alarmcode = []
for j in range(0, 3):
try:
alarmcode.append(dtmfchars.index(str(setting.value)[j]))
except IndexError:
alarmcode.append(0xFF)
obj.alarmcode = alarmcode
rs.set_apply_callback(apply_code, _ani)
dtmf.append(rs)

rs = RadioSetting("dtmfst", "DTMF Sidetone",
RadioSettingValueList(DTMFST_LIST,
DTMFST_LIST[_settings.dtmfst]))
dtmf.append(rs)

if _ani.dtmfon > 0xC3:
val = 0x00
else:
val = _ani.dtmfon
rs = RadioSetting("ani.dtmfon", "DTMF Speed (on)",
RadioSettingValueList(DTMFSPEED_LIST,
DTMFSPEED_LIST[val]))
dtmf.append(rs)

if _ani.dtmfoff > 0xC3:
val = 0x00
else:
val = _ani.dtmfoff
rs = RadioSetting("ani.dtmfoff", "DTMF Speed (off)",
RadioSettingValueList(DTMFSPEED_LIST,
DTMFSPEED_LIST[val]))
dtmf.append(rs)

return group

def get_settings(self):
try:
return self._get_settings()
except:
import traceback
print "Failed to parse settings:"
traceback.print_exc()
return None

def set_settings(self, settings):
_settings = self._memobj.settings
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():
print "Using apply callback"
element.run_apply_callback()
else:
print "Setting %s = %s" % (setting, element.value)
setattr(obj, setting, element.value)
except Exception, e:
print element.get_name()
raise

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

@directory.register
class BaofengF11Radio(BaofengUV5R):
VENDOR = "Baofeng"
MODEL = "F-11"
_basetype = BASETYPE_F11
_idents = [UV5R_MODEL_F11]

def _is_orig(self):
# Override this for F11 to always return False
return False

@directory.register
class BaofengUV82Radio(BaofengUV5R):
MODEL = "UV-82"
_basetype = BASETYPE_UV82
_idents = [UV5R_MODEL_UV82]
_vhf_range = (130000000, 176000000)
_uhf_range = (400000000, 521000000)

def _is_orig(self):
# Override this for UV82 to always return False
return False

@directory.register
class BaofengUV6Radio(BaofengUV5R):
"""Baofeng UV-6/UV-7"""
VENDOR = "Baofeng"
MODEL = "UV-6"
_basetype = BASETYPE_UV6
_idents = [UV5R_MODEL_UV6,
UV5R_MODEL_UV6_ORIG,
UV5R_MODEL_UV8
]

def get_features(self):
rf = BaofengUV5R.get_features(self)
rf.memory_bounds = (1, 128)
return rf

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

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

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

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

def _is_orig(self):
# Override this for UV6 to always return False
return False

@directory.register
class IntekKT980Radio(BaofengUV5R):
VENDOR = "Intek"
MODEL = "KT-980HP"
_basetype = BASETYPE_KT980HP
_idents = [UV5R_MODEL_291]
_vhf_range = (130000000, 180000000)
_uhf_range = (400000000, 521000000)

def get_features(self):
rf = BaofengUV5R.get_features(self)
rf.valid_power_levels = UV5R_POWER_LEVELS3
return rf

def _is_orig(self):
# Override this for KT980HP to always return False
return False

@directory.register
class BaofengBFF8HPRadio(BaofengUV5R):
VENDOR = "Baofeng"
MODEL = "BF-F8HP"
_basetype = BASETYPE_F8HP
_idents = [UV5R_MODEL_291]
_vhf_range = (130000000, 180000000)
_uhf_range = (400000000, 521000000)

def get_features(self):
rf = BaofengUV5R.get_features(self)
rf.valid_power_levels = UV5R_POWER_LEVELS3
return rf

def _is_orig(self):
# Override this for BFF8HP to always return False
return False
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