Re: [chirp_devel] [PATCH] [TH-UV88] New Model: TYT TH-UV88

Attached: - factory image to test against - patch file in case the "hg email tip" version does not apply

Jim KC9HI

On Mon, Nov 16, 2020 at 4:08 PM Jim Unroe via chirp_devel < chirp_devel@intrepid.danplanet.com> wrote:

# HG changeset patch # User Jim Unroe # Date 1605557938 18000 # Mon Nov 16 15:18:58 2020 -0500 # Node ID 3fd7ed9a0de01f7897286c9ac274237a45cc7831 # Parent d5e496f563fdfc9ea89dea5f119357235b82db6f [TH-UV88] New Model: TYT TH-UV88

This patch adds support for the TYT TH-UV88

Initial radio protocol decode, channels and memory layout by James Berry , Summer 2020

Related to #7817

diff -r d5e496f563fd -r 3fd7ed9a0de0 chirp/drivers/th_uv88.py --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/chirp/drivers/th_uv88.py Mon Nov 16 15:18:58 2020 -0500 @@ -0,0 +1,917 @@ +# Version 1.0 for TYT-UV88 +# Initial radio protocol decode, channels and memory layout +# by James Berry , Summer 2020 +# Additional configuration and help, Jim Unroe +# +# 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/ https://cgafehc.r.bh.d.sendibt3.com/tr/cl/QpgoPSH5r0NV4hvIlBzrvEcq4oc9bR7ML-hY3nUq1zcKpuB6PoNuxRO5sk1uyvjY6xNti_2BBKjXrXX0srodnvuyJCJoyWI2-Yvxp23eOYPzyGJ9YGcERkgxudTdeOKMmfxyCn3t2CYacNXoU-fUTH2l-Z72EkLeHxcFk6bRAjewSghXhQJGJrU87xwkmenKqH8swQaX2VY .

+import time +import struct +import logging +import re +import math +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 = """ +struct chns {

• ul32 rxfreq;
• ul32 txfreq;
• ul16 scramble:4
• rxtone:12; //decode:12
• ul16 decodeDSCI:1
• encodeDSCI:1
• unk1:1
• unk2:1
• txtone:12; //encode:12
• u8 power:2
• wide:2
• b_lock:2
• unk3:2;
• u8 unk4:3
• signal:2
• displayName:1
• unk5:2;
• u8 unk6:2
• pttid:2
• step:4; // not required
• u8 name[6];

+};

+struct vfo {

• ul32 rxfreq;
• ul32 txfreq; // displayed as an offset
• ul16 scramble:4
• rxtone:12; //decode:12
• ul16 decodeDSCI:1
• encodeDSCI:1
• unk1:1
• unk2:1
• txtone:12; //encode:12
• u8 power:2
• wide:2
• b_lock:2
• unk3:2;
• u8 unk4:3
• signal:2
• displayName:1
• unk5:2;
• u8 unk6:2
• pttid:2
• step:4;
• u8 name[6];

+};

+struct chname {

• u8 extra_name[10];

+};

+#seekto 0x0000; +struct chns chan_mem[199];

+#seekto 0x1960; +struct chname chan_name[199];

+#seekto 0x1180; +struct {

• u8 bitmap[26]; // one bit for each channel marked in use

+} chan_avail;

+#seekto 0x11A0; +struct {

• u8 bitmap[26]; // one bit for each channel skipped

+} chan_skip;

+#seekto 0x1140; +struct {

• u8 autoKeylock:1, // 0x1140 [18] *OFF, On
• unk_bit6_5:2, //
• vfomrmode:1, // *VFO, MR
• unk_bit3_0:4; //
• u8 unk_1141; // 0x1141
• u8 unk_1142; // 0x1142
• u8 unk_bit7_3:5, //
• ab:1, // * A, B
• unk_bit1_0:2; //

+} workmodesettings;

+#seekto 0x1160; +struct {

• u8 introScreen1[12]; // 0x1160 *Intro Screen Line 1(truncated to 12 alpha
• // text characters)
• u8 offFreqVoltage : 3, // 0x116C unknown referred to in code but not on
• // screen
• unk_bit4 : 1, //
• sqlLevel : 4; // [05] *OFF, 1-9
• u8 beep : 1 // 0x116D [09] *OFF, On
• callKind : 2, // code says 1750,2100,1000,1450 as options
• // not on screen
• introScreen: 2, // [20] *OFF, Voltage, Char String
• unkstr2: 2, //
• txChSelect : 1; // [02] *Last CH, Main CH
• u8 autoPowOff : 3, // 0x116E not on screen? OFF, 30Min, 1HR, 2HR
• unk : 1, //
• tot : 4; // [11] *OFF, 30 Second, 60 Second, 90 Second,
• // ... , 270 Second
• u8 unk_bit7:1, // 0x116F
• roger:1, // [14] *OFF, On
• dailDef:1, // Unknown - 'Volume, Frequency'
• language:1, // ?Chinese, English
• unk_bit3:1, //
• endToneElim:1, // *OFF, Frequency
• unkCheckBox1:1, //
• unkCheckBox2:1; //
• u8 scanResumeTime : 2, // 0x1170 2S, 5S, 10S, 15S (not on screen)
• disMode : 2, // [33] *Frequency, Channel, Name
• scanType: 2, // [17] *To, Co, Se
• ledMode: 2; // [07] *Off, On, Auto
• u8 unky; // 0x1171
• u8 str6; // 0x1172 Has flags to do with logging - factory
• // enabled (bits 16,64,128)
• u8 unk; // 0x1173
• u8 swAudio : 1, // 0x1174 [19] *OFF, On
• radioMoni : 1, // [34]*OFF, On
• keylock : 1, // *OFF, Auto
• dualWait : 1, // [06] *OFF, On
• unk_bit3 : 1, //
• light : 3; // [08] *1, 2, 3, 4, 5, 6, 7
• u8 voxSw : 1, // 0x1175 [13] *OFF, On
• voxDelay: 4, // *0.5S, 1.0S, 1.5S, 2.0S, 2.5S, 3.0S, 3.5S,
• // 4.0S, 4.5S, 5.0S
• voxLevel : 3; // [03] *1, 2, 3, 4, 5, 6, 7
• u8 str9 : 4, // 0x1176
• saveMode : 2, // [16] *OFF, 1:1, 1:2, 1:4
• keyMode : 2; // [32] *ALL, PTT, KEY, Key & Side Key
• u8 unk2; // 0x1177
• u8 unk3; // 0x1178
• u8 unk4; // 0x1179
• u8 name2[6]; // 0x117A unused

+} basicsettings;

+#seekto 0x1940; +struct {

• u8 name1[16]; // Intro Screen Line 1 (16 alpha text characters)
• u8 name2[16]; // Intro Screen Line 2 (16 alpha text characters)

+} openradioname;

+"""

+MEM_SIZE = 0x22A0 +BLOCK_SIZE = 0x20 +STIMEOUT = 2 +BAUDRATE = 57600

+# Channel power: 3 levels +POWER_LEVELS = [chirp_common.PowerLevel("High", watts=5.00),

• chirp_common.PowerLevel("Mid", watts=2.50),
• chirp_common.PowerLevel("Low", watts=0.50)]

+SCRAMBLE_LIST = ["OFF", "1", "2", "3", "4", "5", "6", "7", "8"] +B_LOCK_LIST = ["OFF", "Sub", "Carrier"] +OPTSIG_LIST = ["OFF", "DTMF", "2TONE", "5TONE"] +PTTID_LIST = ["Off", "BOT", "EOT", "Both"] +STEPS = [2.5, 5.0, 6.25, 10.0, 12.5, 25.0, 50.0, 100.0] +LIST_STEPS = [str(x) for x in STEPS]

+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 Exception:
• _exit_program_mode(radio)
• msg = "Generic error reading data from radio; check your cable."
• raise errors.RadioError(msg)
• if len(data) != amount:
• _exit_program_mode(radio)
• msg = "Error reading 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 Exception:
• raise errors.RadioError("Error sending data to radio")

+def _make_read_frame(addr, length):

• frame = "\xFE\xFE\xEE\xEF\xEB"
• """Pack the info in the header format"""
• frame += struct.pack(">ih", addr, length)
• frame += "\xFD"
• # Return the data
• return frame

+def _make_write_frame(addr, length, data=""):

• frame = "\xFE\xFE\xEE\xEF\xE4"
• """Pack the info in the header format"""
• output = struct.pack(">ih", addr, length)
• # Add the data if set
• if len(data) != 0:
• output += data
• frame += output
• frame += _calculate_checksum(output)
• frame += "\xFD"
• # Return the data
• return frame

+def _calculate_checksum(data):

• num = 0
• for x in range(0, len(data)):
• num = (num + ord(data[x])) % 256
• if num == 0:
• return chr(0)
• return chr(256 - num)

+def _recv(radio, addr, length):

• """Get data from the radio """
• data = _rawrecv(radio, length)
• # DEBUG
• LOG.info("Response:")
• LOG.debug(util.hexprint(data))
• return data

+def _do_ident(radio):

• """Put the radio in PROGRAM mode & identify it"""
• radio.pipe.baudrate = BAUDRATE
• radio.pipe.parity = "N"
• radio.pipe.timeout = STIMEOUT
• # Flush input buffer
• _clean_buffer(radio)
• # Ident radio
• magic = "\xFE\xFE\xEE\xEF\xE0\x55\x56\x38\x38\xFD"
• _rawsend(radio, magic)
• ack = _rawrecv(radio, 36)
• if not ack.startswith("\xFE\xFE\xEF\xEE\xE1\x55\x56\x38\x38"
• ) or not ack.endswith("\xFD"):
• _exit_program_mode(radio)
• if ack:
• LOG.debug(repr(ack))
• raise errors.RadioError("Radio did not respond as expected (A)")
• return True

+def _exit_program_mode(radio):

• # This may be the last part of a read
• magic = "\xFE\xFE\xEE\xEF\xE5\x55\x56\x38\x38\xFD"
• _rawsend(radio, magic)
• ack = _rawrecv(radio, 7)
• if ack != "\xFE\xFE\xEF\xEE\xE6\x00\xFD":
• _exit_program_mode(radio)
• if ack:
• LOG.debug(repr(ack))
• raise errors.RadioError("Radio did not respond as expected (B)")

+def _download(radio):

• """Get the memory map"""
• # Put radio in program mode and identify it
• _do_ident(radio)
• # Enter read mode
• magic = "\xFE\xFE\xEE\xEF\xE2\x55\x56\x38\x38\xFD"
• _rawsend(radio, magic)
• ack = _rawrecv(radio, 7)
• if ack != "\xFE\xFE\xEF\xEE\xE6\x00\xFD":
• _exit_program_mode(radio)
• if ack:
• LOG.debug(repr(ack))
• raise errors.RadioError("Radio did not respond to enter read mode")
• # UI progress
• status = chirp_common.Status()
• status.cur = 0
• status.max = MEM_SIZE / BLOCK_SIZE
• status.msg = "Cloning from radio..."
• radio.status_fn(status)
• data = ""
• for addr in range(0, MEM_SIZE, BLOCK_SIZE):
• frame = _make_read_frame(addr, BLOCK_SIZE)
• # DEBUG
• LOG.debug("Frame=" + util.hexprint(frame))
• # Sending the read request
• _rawsend(radio, frame)
• # Now we read data
• d = _recv(radio, addr, BLOCK_SIZE + 13)
• LOG.debug("Response Data= " + util.hexprint(d))
• if not d.startswith("\xFE\xFE\xEF\xEE\xE4"):
• LOG.warning("Incorrect start")
• if not d.endswith("\xFD"):
• LOG.warning("Incorrect end")
• # could validate the block data
• # Aggregate the data
• data += d[11:-2]
• # UI Update
• status.cur = addr / BLOCK_SIZE
• status.msg = "Cloning from radio..."
• radio.status_fn(status)
• _exit_program_mode(radio)
• return data

+def _upload(radio):

• """Upload procedure"""
• # Put radio in program mode and identify it
• _do_ident(radio)
• magic = "\xFE\xFE\xEE\xEF\xE3\x55\x56\x38\x38\xFD"
• _rawsend(radio, magic)
• ack = _rawrecv(radio, 7)
• if ack != "\xFE\xFE\xEF\xEE\xE6\x00\xFD":
• _exit_program_mode(radio)
• if ack:
• LOG.debug(repr(ack))
• raise errors.RadioError("Radio did not respond to enter write mode")
• # UI progress
• status = chirp_common.Status()
• status.cur = 0
• status.max = MEM_SIZE / BLOCK_SIZE
• status.msg = "Cloning to radio..."
• radio.status_fn(status)
• # The fun starts here
• for addr in range(0, MEM_SIZE, BLOCK_SIZE):
• # Official programmer skips writing these memory locations
• if addr >= 0x1680 and addr < 0x1940:
• continue
• # Sending the data
• data = radio.get_mmap()[addr:addr + BLOCK_SIZE]
• frame = _make_write_frame(addr, BLOCK_SIZE, data)
• LOG.warning("Frame:%s:" % util.hexprint(frame))
• _rawsend(radio, frame)
• ack = _rawrecv(radio, 7)
• LOG.debug("Response Data= " + util.hexprint(ack))
• if not ack.startswith("\xFE\xFE\xEF\xEE\xE6\x00\xFD"):
• LOG.warning("Unexpected response")
• _exit_program_mode(radio)
• msg = "Bad ack writing block 0x%04x" % addr
• raise errors.RadioError(msg)
• # UI Update
• status.cur = addr / BLOCK_SIZE
• status.msg = "Cloning to radio..."
• radio.status_fn(status)
• _exit_program_mode(radio)

+def _do_map(chn, sclr, mary):

• """Set or Clear the chn (1-128) bit in mary[] word array map"""
• # chn is 1-based channel, sclr:1 = set, 0= = clear, 2= return state
• # mary[] is u8 array, but the map is by nibbles
• ndx = int(math.floor((chn - 1) / 8))
• bv = (chn - 1) % 8
• msk = 1 << bv
• mapbit = sclr
• if sclr == 1: # Set the bit
• mary[ndx] = mary[ndx] | msk
• elif sclr == 0: # clear
• mary[ndx] = mary[ndx] & (~ msk) # ~ is complement
• else: # return current bit state
• mapbit = 0
• if (mary[ndx] & msk) > 0:
• mapbit = 1
• return mapbit

+@directory.register +class THUV88Radio(chirp_common.CloneModeRadio):

• """TYT UV88 Radio"""
• VENDOR = "TYT"
• MODEL = "TH-UV88"
• MODES = ['WFM', 'FM', 'NFM']
• TONES = chirp_common.TONES
• DTCS_CODES = chirp_common.DTCS_CODES
• NAME_LENGTH = 10
• DTMF_CHARS = list("0123456789ABCD*#")
• # 136-174, 400-480
• VALID_BANDS = [(136000000, 174000000), (400000000, 480000000)]
• # Valid chars on the LCD
• VALID_CHARS = chirp_common.CHARSET_ALPHANUMERIC + \
• "`!"#$%&'()*+,-./:;<=>?@[]^_"
• @classmethod
• def get_prompts(cls):
• rp = chirp_common.RadioPrompts()
• rp.info = \
• ('TYT UV-88\n')
• rp.pre_download = _(dedent("""\
• This is an early stage beta driver
• """))
• rp.pre_upload = _(dedent("""\
• This is an early stage beta driver - upload at your own risk
• """))
• return rp
• def get_features(self):
• rf = chirp_common.RadioFeatures()
• rf.has_settings = True
• rf.has_bank = False
• rf.has_comment = False
• rf.has_tuning_step = False # Not as chan feature
• rf.valid_tuning_steps = STEPS
• rf.can_odd_split = False
• rf.has_name = True
• rf.has_offset = True
• rf.has_mode = True
• rf.has_dtcs = True
• rf.has_rx_dtcs = True
• rf.has_dtcs_polarity = True
• rf.has_ctone = True
• rf.has_cross = True
• rf.has_sub_devices = False
• rf.valid_name_length = self.NAME_LENGTH
• rf.valid_modes = self.MODES
• rf.valid_characters = self.VALID_CHARS
• rf.valid_duplexes = ["-", "+", "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_skips = []
• rf.valid_power_levels = POWER_LEVELS
• rf.valid_dtcs_codes = chirp_common.ALL_DTCS_CODES # this is just to
• # get it working, not sure this is right
• rf.valid_bands = self.VALID_BANDS
• rf.memory_bounds = (1, 199)
• rf.valid_skips = ["", "S"]
• return rf
• def sync_in(self):
• """Download from radio"""
• try:
• data = _download(self)
• except errors.RadioError:
• # Pass through any real errors we raise
• raise
• except Exception:
• # 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 Exception:
• # 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 process_mmap(self):
• """Process the mem map into the mem object"""
• self._memobj = bitwise.parse(MEM_FORMAT, self._mmap)
• def get_raw_memory(self, number):
• return repr(self._memobj.memory[number - 1])
• def set_memory(self, memory):
• """A value in a UI column for chan 'number' has been modified."""
• # update all raw channel memory values (_mem) from UI (mem)
• _mem = self._memobj.chan_mem[memory.number - 1]
• _name = self._memobj.chan_name[memory.number - 1]
• if memory.empty:
• _do_map(memory.number, 0, self._memobj.chan_avail.bitmap)
• return
• _do_map(memory.number, 1, self._memobj.chan_avail.bitmap)
• if memory.skip == "":
• _do_map(memory.number, 1, self._memobj.chan_skip.bitmap)
• else:
• _do_map(memory.number, 0, self._memobj.chan_skip.bitmap)
• return self._set_memory(memory, _mem, _name)
• def get_memory(self, number):
• # radio first channel is 1, mem map is base 0
• _mem = self._memobj.chan_mem[number - 1]
• _name = self._memobj.chan_name[number - 1]
• mem = chirp_common.Memory()
• mem.number = number
• # Determine if channel is empty
• if _do_map(number, 2, self._memobj.chan_avail.bitmap) == 0:
• mem.empty = True
• return mem
• if _do_map(mem.number, 2, self._memobj.chan_skip.bitmap) > 0:
• mem.skip = ""
• else:
• mem.skip = "S"
• return self._get_memory(mem, _mem, _name)
• def _get_memory(self, mem, _mem, _name):
• """Convert raw channel memory data into UI columns"""
• mem.extra = RadioSettingGroup("extra", "Extra")
• mem.empty = False
• # This function process both 'normal' and Freq up/down' entries
• mem.freq = int(_mem.rxfreq) * 10
• if _mem.txfreq == 0xFFFFFFFF:
• # TX freq not set
• mem.duplex = "off"
• mem.offset = 0
• elif int(_mem.rxfreq) == int(_mem.txfreq):
• mem.duplex = ""
• mem.offset = 0
• else:
• mem.duplex = int(_mem.rxfreq) > int(_mem.txfreq) \
• and "-" or "+"
• mem.offset = abs(int(_mem.rxfreq) - int(_mem.txfreq)) * 10
• mem.name = ""
• for i in range(6): # 0 - 6
• mem.name += chr(_mem.name[i])
• for i in range(10):
• mem.name += chr(_name.extra_name[i])
• mem.name = mem.name.rstrip() # remove trailing spaces
• # ########## TONE ##########
• if _mem.txtone > 2600:
• # All off
• txmode = ""
• elif _mem.txtone > 511:
• txmode = "Tone"
• mem.rtone = int(_mem.txtone) / 10.0
• else:
• # DTSC
• txmode = "DTCS"
• mem.dtcs = int(format(int(_mem.txtone), 'o'))
• if _mem.rxtone > 2600:
• rxmode = ""
• elif _mem.rxtone > 511:
• rxmode = "Tone"
• mem.ctone = int(_mem.rxtone) / 10.0
• else:
• rxmode = "DTCS"
• mem.rx_dtcs = int(format(int(_mem.rxtone), 'o'))
• mem.dtcs_polarity = ("N", "R")[_mem.encodeDSCI] + (
• "N", "R")[_mem.decodeDSCI]
• mem.tmode = ""
• 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)
• # ########## TONE ##########
• mem.mode = self.MODES[_mem.wide]
• mem.power = POWER_LEVELS[int(_mem.power)]
• b_lock = RadioSetting("b_lock", "B_Lock",
• RadioSettingValueList(B_LOCK_LIST,
• B_LOCK_LIST[_mem.b_lock]))
• mem.extra.append(b_lock)
• b_lock = RadioSetting("step", "Step",
• RadioSettingValueList(LIST_STEPS,
• LIST_STEPS[_mem.step]))
• mem.extra.append(b_lock)
• scramble_value = _mem.scramble
• if scramble_value >= 8: # Looks like OFF is 0x0f ** CONFIRM
• scramble_value = 0
• scramble = RadioSetting("scramble", "Scramble",
• RadioSettingValueList(SCRAMBLE_LIST,
• SCRAMBLE_LIST[
• scramble_value]))
• mem.extra.append(scramble)
• optsig = RadioSetting("signal", "Optional signaling",
• RadioSettingValueList(
• OPTSIG_LIST,
• OPTSIG_LIST[_mem.signal]))
• mem.extra.append(optsig)
• rs = RadioSetting("pttid", "PTT ID",
• RadioSettingValueList(PTTID_LIST,
• PTTID_LIST[_mem.pttid]))
• mem.extra.append(rs)
• return mem
• def _set_memory(self, mem, _mem, _name):
• # """Convert UI column data (mem) into MEM_FORMAT memory (_mem)."""
• _mem.rxfreq = mem.freq / 10
• if mem.duplex == "off":
• _mem.txfreq = 0xFFFFFFFF
• elif mem.duplex == "+":
• _mem.txfreq = (mem.freq + mem.offset) / 10
• elif mem.duplex == "-":
• _mem.txfreq = (mem.freq - mem.offset) / 10
• else:
• _mem.txfreq = _mem.rxfreq
• out_name = mem.name.ljust(16)
• for i in range(6): # 0 - 6
• _mem.name[i] = ord(out_name[i])
• for i in range(10):
• _name.extra_name[i] = ord(out_name[i+6])
• if mem.name != "":
• _mem.displayName = 1 # Name only displayed if this is set on
• else:
• _mem.displayName = 0
• rxmode = ""
• txmode = ""
• if mem.tmode == "Tone":
• txmode = "Tone"
• elif mem.tmode == "TSQL":
• rxmode = "Tone"
• txmode = "TSQL"
• elif mem.tmode == "DTCS":
• rxmode = "DTCSSQL"
• txmode = "DTCS"
• elif mem.tmode == "Cross":
• txmode, rxmode = mem.cross_mode.split("->", 1)
• if mem.dtcs_polarity[1] == "N":
• _mem.decodeDSCI = 0
• else:
• _mem.decodeDSCI = 1
• if rxmode == "":
• _mem.rxtone = 0xFFF
• elif rxmode == "Tone":
• _mem.rxtone = int(float(mem.ctone) * 10)
• elif rxmode == "DTCSSQL":
• _mem.rxtone = int(str(mem.dtcs), 8)
• elif rxmode == "DTCS":
• _mem.rxtone = int(str(mem.rx_dtcs), 8)
• if mem.dtcs_polarity[0] == "N":
• _mem.encodeDSCI = 0
• else:
• _mem.encodeDSCI = 1
• if txmode == "":
• _mem.txtone = 0xFFF
• elif txmode == "Tone":
• _mem.txtone = int(float(mem.rtone) * 10)
• elif txmode == "TSQL":
• _mem.txtone = int(float(mem.ctone) * 10)
• elif txmode == "DTCS":
• _mem.txtone = int(str(mem.dtcs), 8)
• _mem.wide = self.MODES.index(mem.mode)
• _mem.power = 0 if mem.power is None else POWER_LEVELS.index(mem.power)
• for element in mem.extra:
• setattr(_mem, element.get_name(), element.value)
• return
• def get_settings(self):
• """Translate the MEM_FORMAT structs into setstuf in the UI"""
• _settings = self._memobj.basicsettings
• _workmode = self._memobj.workmodesettings
• basic = RadioSettingGroup("basic", "Basic Settings")
• group = RadioSettings(basic)
• # Menu 02 - TX Channel Select
• options = ["Last Channel", "Main Channel"]
• rx = RadioSettingValueList(options, options[_settings.txChSelect])
• rset = RadioSetting("basicsettings.txChSelect",
• "Priority Transmit", rx)
• basic.append(rset)
• # Menu 03 - VOX Level
• rx = RadioSettingValueInteger(1, 7, _settings.voxLevel - 1)
• rset = RadioSetting("basicsettings.voxLevel", "Vox Level", rx)
• basic.append(rset)
• # Menu 05 - Squelch Level
• options = ["OFF"] + ["%s" % x for x in range(1, 10)]
• rx = RadioSettingValueList(options, options[_settings.sqlLevel])
• rset = RadioSetting("basicsettings.sqlLevel", "Squelch Level", rx)
• basic.append(rset)
• # Menu 06 - Dual Wait
• rx = RadioSettingValueBoolean(_settings.dualWait)
• rset = RadioSetting("basicsettings.dualWait", "Dual Wait/Standby", rx)
• basic.append(rset)
• # Menu 07 - LED Mode
• options = ["Off", "On", "Auto"]
• rx = RadioSettingValueList(options, options[_settings.ledMode])
• rset = RadioSetting("basicsettings.ledMode", "LED Display Mode", rx)
• basic.append(rset)
• # Menu 08 - Light
• options = ["%s" % x for x in range(1, 8)]
• rx = RadioSettingValueList(options, options[_settings.light])
• rset = RadioSetting("basicsettings.light",
• "Background Light Color", rx)
• basic.append(rset)
• # Menu 09 - Beep
• rx = RadioSettingValueBoolean(_settings.beep)
• rset = RadioSetting("basicsettings.beep", "Keypad Beep", rx)
• basic.append(rset)
• # Menu 11 - TOT
• options = ["Off"] + ["%s seconds" % x for x in range(30, 300, 30)]
• rx = RadioSettingValueList(options, options[_settings.tot])
• rset = RadioSetting("basicsettings.tot",
• "Transmission Time-out Timer", rx)
• basic.append(rset)
• # Menu 13 - VOX Switch
• rx = RadioSettingValueBoolean(_settings.voxSw)
• rset = RadioSetting("basicsettings.voxSw", "Vox Switch", rx)
• basic.append(rset)
• # Menu 14 - Roger
• rx = RadioSettingValueBoolean(_settings.roger)
• rset = RadioSetting("basicsettings.roger", "Roger Beep", rx)
• basic.append(rset)
• # Menu 16 - Save Mode
• options = ["Off", "1:1", "1:2", "1:4"]
• rx = RadioSettingValueList(options, options[_settings.saveMode])
• rset = RadioSetting("basicsettings.saveMode", "Battery Save Mode", rx)
• basic.append(rset)
• # Menu 33 - Display Mode
• options = ['Frequency', 'Channel', 'Name']
• rx = RadioSettingValueList(options, options[_settings.disMode])
• rset = RadioSetting("basicsettings.disMode", "LED Display Mode", rx)
• basic.append(rset)
• advanced = RadioSettingGroup("advanced", "Advanced Settings")
• group.append(advanced)
• # software only
• options = ['0.5S', '1.0S', '1.5S', '2.0S', '2.5S', '3.0S', '3.5S',
• '4.0S', '4.5S', '5.0S']
• rx = RadioSettingValueList(options, options[_settings.voxDelay])
• rset = RadioSetting("basicsettings.voxDelay", "VOX Delay", rx)
• advanced.append(rset)
• # software only
• name = ""
• for i in range(16): # 0 - 16
• name += chr(self._memobj.openradioname.name1[i])
• name = name.rstrip() # remove trailing spaces
• rx = RadioSettingValueString(0, 16, name)
• rset = RadioSetting("openradioname.name1", "Intro Line 1", rx)
• advanced.append(rset)
• # software only
• name = ""
• for i in range(16): # 0 - 16
• name += chr(self._memobj.openradioname.name2[i])
• name = name.rstrip() # remove trailing spaces
• rx = RadioSettingValueString(0, 16, name)
• rset = RadioSetting("openradioname.name2", "Intro Line 2", rx)
• advanced.append(rset)
• workmode = RadioSettingGroup("workmode", "Work Mode Settings")
• group.append(workmode)
• # Toggle with [#] key
• options = ["Frequency", "Channel"]
• rx = RadioSettingValueList(options, options[_workmode.vfomrmode])
• rset = RadioSetting("workmodesettings.vfomrmode", "VFO/MR Mode", rx)
• workmode.append(rset)
• # Toggle with [A/B] key
• options = ["A", "B"]
• rx = RadioSettingValueList(options, options[_workmode.ab])
• rset = RadioSetting("workmodesettings.ab", "A/B Select", rx)
• workmode.append(rset)
• return group # END get_settings()
• def set_settings(self, settings):
• return
• _settings = self._memobj.settings
• _mem = self._memobj
• for element in settings:
• if not isinstance(element, RadioSetting):
• 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 setting == "voxLevel":
• setattr(obj, setting, int(element.value) + 1)
• 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

diff -r d5e496f563fd -r 3fd7ed9a0de0 tools/cpep8.manifest --- a/tools/cpep8.manifest Fri Nov 13 08:07:04 2020 -0500 +++ b/tools/cpep8.manifest Mon Nov 16 15:18:58 2020 -0500 @@ -77,6 +77,7 @@ ./chirp/drivers/th_uv3r.py ./chirp/drivers/th_uv3r25.py ./chirp/drivers/th_uv8000.py +./chirp/drivers/th_uv88.py ./chirp/drivers/th_uvf8d.py ./chirp/drivers/thd72.py ./chirp/drivers/thuv1f.py _______________________________________________ chirp_devel mailing list chirp_devel@intrepid.danplanet.com http://intrepid.danplanet.com/mailman/listinfo/chirp_devel Developer docs: http://chirp.danplanet.com/projects/chirp/wiki/Developers