# HG changeset patch # User Rick DeWitt # Date 1605564872 28800 # Mon Nov 16 14:14:32 2020 -0800 # Node ID 25ea0536d1f6676a7c622ced7c74581fdc5621d7 # Parent 322a135bdf2bf42ad8b6f4026a488adad003e4c0 [th_uv8000] Issue # 8339, Priority channel: OFF now enabled Allowed priority channel number to be 0 diff -r 322a135bdf2b -r 25ea0536d1f6 chirp/drivers/th_uv8000.py --- a/chirp/drivers/th_uv8000.py Mon Nov 16 14:08:27 2020 -0800 +++ b/chirp/drivers/th_uv8000.py Mon Nov 16 14:14:32 2020 -0800 @@ -1,1491 +1,1480 @@ -# Copyright 2019: Rick DeWitt (RJD), -# Version 1.0 for TYT-UV8000D/E -# Thanks to Damon Schaefer (K9CQB) and the Loudoun County, VA ARES -# club for the donated radio. -# And thanks to Ian Harris (VA3IHX) for decoding the memory map. -# -# 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 . - -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; - u8 rxtone[2]; - u8 txtone[2]; - u8 wide:1 // 0x0c - vox_on:1 - chunk01:1 - bcl:1 // inv bool - epilogue:1 - power:1 - chunk02:1 - chunk03:1; - u8 ani:1 // 0x0d inv - chunk08:1 - ptt:2 - chpad04:4; - u8 chunk05; // 0x0e - u16 id_code; // 0x0f, 10 - u8 chunk06; - u8 name[7]; - ul32 chpad06; // Need 56 byte pad - ul16 chpad07; - u8 chpad08; -}; - -struct fm_chn { - ul16 rxfreq; -}; - -struct frqx { - ul32 rxfreq; - ul24 ofst; - u8 fqunk01:4 // 0x07 - funk10:2 - duplx:2; - u8 rxtone[2]; // 0x08, 9 - u8 txtone[2]; // 0x0a, b - u8 wide:1 // 0x0c - vox_on:1 - funk11:1 - bcl:1 // inv bool - epilogue:1 - power:1 - fqunk02:2; - u8 ani:1 // 0x0d inv bool - fqunk03:1 - ptt:2 - fqunk12:1 - fqunk04:3; - u8 fqunk07; // 0x0e - u16 id_code; // 0x0f, 0x10 - u8 name[7]; // dummy - u8 fqunk09[8]; // empty bytes after 1st entry -}; - -struct bitmap { - u8 map[16]; -}; - -#seekto 0x0010; -struct chns chan_mem[128]; - -#seekto 0x1010; -struct frqx frq[2]; - -#seekto 0x1050; -struct fm_chn fm_stations[25]; - -#seekto 0x1080; -struct { - u8 fmunk01[14]; - ul16 fmcur; -} fmfrqs; - -#seekto 0x1190; -struct bitmap chnmap; - -#seekto 0x11a0; -struct bitmap skpchns; - -#seekto 0x011b0; -struct { - u8 fmset[4]; -} fmmap; - -#seekto 0x011b4; -struct { - u8 setunk01[4]; - u8 setunk02[3]; - u8 chs_name:1 // 0x11bb - txsel:1 - dbw:1 - setunk05:1 - ponfmchs:2 - ponchs:2; - u8 voltx:2 // 0x11bc - setunk04:1 - keylok:1 - setunk07:1 - batsav:3; - u8 setunk09:1 // 0x11bd - rxinhib:1 - rgrbeep:1 // inv bool - lampon:2 - voice:2 - beepon:1; - u8 setunk11:1 // 0x11be - manualset:1 - xbandon:1 // inv - xbandenable:1 - openmsg:2 - ledclr:2; - u8 tot:4 // 0x11bf - sql:4; - u8 setunk27:1 // 0x11c0 - voxdelay:2 - setunk28:1 - voxgain:4; - u8 fmstep:4 // 0x11c1 - freqstep:4; - u8 scanspeed:4 // 0x11c2 - scanmode:4; - u8 scantmo; // 0x11c3 - u8 prichan; // 0x11c4 - u8 setunk12:4 // 0x11c5 - supersave:4; - u8 setunk13; - u8 fmsclo; // 0x11c7 ??? placeholder - u8 radioname[7]; // hex char codes, not true ASCII - u8 fmschi; // ??? placeholder - u8 setunk14[3]; // 0x11d0 - u8 setunk17[2]; // 0x011d3, 4 - u8 setunk18:4 - dtmfspd:4; - u8 dtmfdig1dly:4 // 0x11d6 - dtmfdig1time:4; - u8 stuntype:1 - setunk19:1 - dtmfspms:2 - grpcode:4; - u8 setunk20:1 // 0x11d8 - txdecode:1 - codeabcd:1 - idedit:1 - pttidon:2 - setunk40:1, - dtmfside:1; - u8 setunk50:4, - autoresettmo:4; - u8 codespctim:4, // 0x11da - decodetmo:4; - u8 pttecnt:4 // 0x11db - pttbcnt:4; - lbcd dtmfdecode[3]; - u8 setunk22; - u8 stuncnt; // 0x11e0 - u8 stuncode[5]; - u8 setunk60; - u8 setunk61; - u8 pttbot[8]; // 0x11e8-f - u8 ptteot[8]; // 0x11f0-7 - u8 setunk62; // 0x11f8 - u8 setunk63; - u8 setunk64; // 0x11fa - u8 setunk65; - u8 setunk66; - u8 manfrqyn; // 0x11fd - u8 setunk27:3 - frqr3:1 - setunk28:1 - frqr2:1 - setunk29:1 - frqr1:1; - u8 setunk25; - ul32 frqr1lo; // 0x1200 - ul32 frqr1hi; - ul32 frqr2lo; - ul32 frqr2hi; - ul32 frqr3lo; // 0x1210 - ul32 frqr3hi; - u8 setunk26[8]; -} setstuf; - -#seekto 0x1260; -struct { - u8 modnum[7]; -} modcode; - -#seekto 0x1300; -struct { - char mod_num[9]; -} mod_id; -""" - -MEM_SIZE = 0x1300 -BLOCK_SIZE = 0x10 # can read 0x20, but must write 0x10 -STIMEOUT = 2 -BAUDRATE = 4800 -# Channel power: 2 levels -POWER_LEVELS = [chirp_common.PowerLevel("Low", watts=5.00), - chirp_common.PowerLevel("High", watts=10.00)] - -LIST_RECVMODE = ["QT/DQT", "QT/DQT + Signaling"] -LIST_COLOR = ["Off", "Orange", "Blue", "Purple"] -LIST_LEDSW = ["Auto", "On"] -LIST_TIMEOUT = ["Off"] + ["%s" % x for x in range(30, 390, 30)] -LIST_VFOMODE = ["Frequency Mode", "Channel Mode"] -# Tones are numeric, Defined in \chirp\chirp_common.py -TONES_CTCSS = sorted(chirp_common.TONES) -# Converted to strings -LIST_CTCSS = ["Off"] + [str(x) for x in TONES_CTCSS] -# Now append the DxxxN and DxxxI DTCS codes from chirp_common -for x in chirp_common.DTCS_CODES: - LIST_CTCSS.append("D{:03d}N".format(x)) -for x in chirp_common.DTCS_CODES: - LIST_CTCSS.append("D{:03d}R".format(x)) -LIST_BW = ["Narrow", "Wide"] -LIST_SHIFT = ["off", "+", "-"] -STEPS = [0.5, 2.5, 5.0, 6.25, 10.0, 12.5, 25.0, 37.5, 50.0, 100.0] -LIST_STEPS = [str(x) for x in STEPS] -LIST_VOXDLY = ["0.5", "1.0", "2.0", "3.0"] # LISTS must be strings -LIST_PTT = ["Both", "EoT", "BoT", "Off"] - -SETTING_LISTS = {"tot": LIST_TIMEOUT, "wtled": LIST_COLOR, - "rxled": LIST_COLOR, "txled": LIST_COLOR, - "ledsw": LIST_LEDSW, "frq_chn_mode": LIST_VFOMODE, - "rx_tone": LIST_CTCSS, "tx_tone": LIST_CTCSS, - "rx_mode": LIST_RECVMODE, "fm_bw": LIST_BW, - "shift": LIST_SHIFT, "step": LIST_STEPS, - "vox_dly": LIST_VOXDLY, "ptt": LIST_PTT} - - -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_frame(cmd, addr, length, data=""): - """Pack the info in the headder format""" - frame = struct.pack(">shB", 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 """ - - 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) - - magic = "PROGRAMa" - _rawsend(radio, magic) - ack = _rawrecv(radio, 1) - # LOG.warning("PROGa Ack:" + util.hexprint(ack)) - if ack != "\x06": - _exit_program_mode(radio) - if ack: - LOG.debug(repr(ack)) - raise errors.RadioError("Radio did not respond") - magic = "PROGRAMb" - _rawsend(radio, magic) - ack = _rawrecv(radio, 1) - if ack != "\x06": - _exit_program_mode(radio) - if ack: - LOG.debug(repr(ack)) - raise errors.RadioError("Radio did not respond to B") - magic = chr(0x02) - _rawsend(radio, magic) - ack = _rawrecv(radio, 1) # s/b: 0x50 - magic = _rawrecv(radio, 7) # s/b TC88... - magic = "MTC88CUMHS3E7BN-" - _rawsend(radio, magic) - ack = _rawrecv(radio, 1) # s/b 0x80 - magic = chr(0x06) - _rawsend(radio, magic) - ack = _rawrecv(radio, 1) - - return True - - -def _exit_program_mode(radio): - endframe = "E" - _rawsend(radio, endframe) - - -def _download(radio): - """Get the memory map""" - - # Put radio in program mode and identify it - _do_ident(radio) - - # 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_frame("R", addr, BLOCK_SIZE) - # DEBUG - LOG.info("Request sent:") - LOG.debug("Frame=" + util.hexprint(frame)) - - # Sending the read request - _rawsend(radio, frame) - dx = _rawrecv(radio, 4) - - # Now we read data - d = _recv(radio, addr, BLOCK_SIZE) - # LOG.warning("Data= " + util.hexprint(d)) - - # Aggregate the data - data += d - - # 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) - - # 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): - # Sending the data - data = radio.get_mmap()[addr:addr + BLOCK_SIZE] - - frame = _make_frame("W", addr, BLOCK_SIZE, data) - # LOG.warning("Frame:%s:" % util.hexprint(frame)) - _rawsend(radio, frame) - - # Receiving the response - ack = _rawrecv(radio, 1) - if ack != "\x06": - _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 set_tone(_mem, txrx, ctdt, tval, pol): - """Set rxtone[] or txtone[] word values as decimal bytes""" - # txrx: Boolean T= set Rx tones, F= set Tx tones - # ctdt: Boolean T = CTCSS, F= DTCS - # tval = integer tone freq (*10) or DTCS code - # pol = string for DTCS polarity "R" or "N" - xv = int(str(tval), 16) - if txrx: # True = set rxtones - _mem.rxtone[0] = xv & 0xFF # Low byte - _mem.rxtone[1] = (xv >> 8) # Hi byte - if not ctdt: # dtcs, - if pol == "R": - _mem.rxtone[1] = _mem.rxtone[1] | 0xC0 - else: - _mem.rxtone[1] = _mem.rxtone[1] | 0x80 - else: # txtones - _mem.txtone[0] = xv & 0xFF # Low byte - _mem.txtone[1] = (xv >> 8) - if not ctdt: # dtcs - if pol == "R": - _mem.txtone[1] = _mem.txtone[1] | 0xC0 - else: - _mem.txtone[1] = _mem.txtone[1] | 0x80 - - return 0 - - -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 THUV8000Radio(chirp_common.CloneModeRadio): - """TYT UV8000D Radio""" - VENDOR = "TYT" - MODEL = "TH-UV8000" - MODES = ["NFM", "FM"] - TONES = chirp_common.TONES - DTCS_CODES = sorted(chirp_common.DTCS_CODES + [645]) - NAME_LENGTH = 7 - DTMF_CHARS = list("0123456789ABCD*#") - # NOTE: SE Model supports 220-260 MHz - # The following bands are the the range the radio is capable of, - # not the legal FCC amateur bands - VALID_BANDS = [(87500000, 107900000), (136000000, 174000000), - (220000000, 260000000), (400000000, 520000000)] - - # Valid chars on the LCD - VALID_CHARS = chirp_common.CHARSET_ALPHANUMERIC + \ - "`!\"#$%&'()*+,-./:;<=>?@[]^_" - - # Special Channels Declaration - # WARNING Indecis are hard wired in get/set_memory code !!! - # Channels print in + increasing index order (most negative first) - SPECIAL_MEMORIES = { - "UpVFO": -2, - "LoVFO": -1 - } - FIRST_FREQ_INDEX = -1 - LAST_FREQ_INDEX = -2 - - SPECIAL_MEMORIES_REV = dict(zip(SPECIAL_MEMORIES.values(), - SPECIAL_MEMORIES.keys())) - - @classmethod - def get_prompts(cls): - rp = chirp_common.RadioPrompts() - rp.info = \ - ('Click on the "Special Channels" toggle-button of the memory ' - 'editor to see/set the upper and lower frequency-mode values.\n') - - rp.pre_download = _(dedent("""\ - Follow these instructions to download the radio memory: - - 1 - Turn off your radio - 2 - Connect your interface cable - 3 - Turn on your radio, volume @ 50% - 4 - Radio > Download from radio - """)) - rp.pre_upload = _(dedent("""\ - Follow these instructions to upload the radio memory: - - 1 - Turn off your radio - 2 - Connect your interface cable - 3 - Turn on your radio, volume @ 50% - 4 - Radio > Upload to radio - """)) - return rp - - def get_features(self): - rf = chirp_common.RadioFeatures() - # .has. attributes are boolean, .valid. are lists - rf.has_settings = True - rf.has_bank = False - rf.has_comment = False - rf.has_nostep_tuning = True # Radio accepts any entered freq - rf.has_tuning_step = False # Not as chan feature - 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 = self.DTCS_CODES - rf.valid_bands = self.VALID_BANDS - rf.memory_bounds = (1, 128) - rf.valid_skips = ["", "S"] - rf.valid_special_chans = sorted(self.SPECIAL_MEMORIES.keys()) - 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 get_memory(self, number): - if isinstance(number, str): - return self._get_special(number) - elif number < 0: - # I can't stop delete operation from loosing extd_number but - # I know how to get it back - return self._get_special(self.SPECIAL_MEMORIES_REV[number]) - else: - return self._get_normal(number) - - 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) - if memory.number < 0: - return self._set_special(memory) - else: - return self._set_normal(memory) - - def _get_normal(self, number): - # radio first channel is 1, mem map is base 0 - _mem = self._memobj.chan_mem[number - 1] - mem = chirp_common.Memory() - mem.number = number - - return self._get_memory(mem, _mem) - - def _get_memory(self, mem, _mem): - """Convert raw channel memory data into UI columns""" - mem.extra = RadioSettingGroup("extra", "Extra") - - if _mem.get_raw()[0] == "\xff": - mem.empty = True - return mem - - mem.empty = False - # This function process both 'normal' and Freq up/down' entries - mem.freq = int(_mem.rxfreq) * 10 - mem.power = POWER_LEVELS[_mem.power] - mem.mode = self.MODES[_mem.wide] - dtcs_pol = ["N", "N"] - - if _mem.rxtone[0] == 0xFF: - rxmode = "" - elif _mem.rxtone[1] < 0x26: - # CTCSS - rxmode = "Tone" - tonehi = int(str(_mem.rxtone[1])[2:]) - tonelo = int(str(_mem.rxtone[0])[2:]) - mem.ctone = int(tonehi * 100 + tonelo) / 10.0 - else: - # Digital - rxmode = "DTCS" - tonehi = int(str(_mem.rxtone[1] & 0x3f)) - tonelo = int(str(_mem.rxtone[0])[2:]) - mem.rx_dtcs = int(tonehi * 100 + tonelo) - if (_mem.rxtone[1] & 0x40) != 0: - dtcs_pol[1] = "R" - - if _mem.txtone[0] == 0xFF: - txmode = "" - elif _mem.txtone[1] < 0x26: - # CTCSS - txmode = "Tone" - tonehi = int(str(_mem.txtone[1])[2:]) - tonelo = int(str(_mem.txtone[0])[2:]) - mem.rtone = int(tonehi * 100 + tonelo) / 10.0 - else: - # Digital - txmode = "DTCS" - tonehi = int(str(_mem.txtone[1] & 0x3f)) - tonelo = int(str(_mem.txtone[0])[2:]) - mem.dtcs = int(tonehi * 100 + tonelo) - if (_mem.txtone[1] & 0x40) != 0: - dtcs_pol[0] = "R" - - 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) - - mem.dtcs_polarity = "".join(dtcs_pol) - - # Now test the mem.number to process special vs normal - if mem.number >= 0: # Normal - mem.name = "" - for i in range(self.NAME_LENGTH): # 0 - 6 - mem.name += chr(_mem.name[i] + 32) - mem.name = mem.name.rstrip() # remove trailing spaces - - 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 - - if _do_map(mem.number, 2, self._memobj.skpchns.map) > 0: - mem.skip = "S" - else: - mem.skip = "" - - else: # specials VFO - mem.name = "----" - mem.duplex = LIST_SHIFT[_mem.duplx] - mem.offset = int(_mem.ofst) * 10 - mem.skip = "" - # End if specials - - # Channel Extra settings: Only Boolean & List methods, no call-backs - rx = RadioSettingValueBoolean(bool(not _mem.bcl)) # Inverted bool - # NOTE: first param of RadioSetting is the object attribute name - rset = RadioSetting("bcl", "Busy Channel Lockout", rx) - mem.extra.append(rset) - - rx = RadioSettingValueBoolean(bool(not _mem.vox_on)) - rset = RadioSetting("vox_on", "Vox", rx) - mem.extra.append(rset) - - rx = RadioSettingValueBoolean(bool(not _mem.ani)) - rset = RadioSetting("ani", "Auto Number ID (ANI)", rx) - mem.extra.append(rset) - - # ID code can't be done in extra - no Integer method or call-back - - rx = RadioSettingValueList(LIST_PTT, LIST_PTT[_mem.ptt]) - rset = RadioSetting("ptt", "Xmit PTT ID", rx) - mem.extra.append(rset) - - rx = RadioSettingValueBoolean(bool(_mem.epilogue)) - rset = RadioSetting("epilogue", "Epilogue/Tail", rx) - mem.extra.append(rset) - - return mem - - def _get_special(self, number): - mem = chirp_common.Memory() - mem.number = self.SPECIAL_MEMORIES[number] - mem.extd_number = number - # Unused attributes are ignored in Set_memory - if (mem.number == -1) or (mem.number == -2): - # Print Upper[1] first, and Lower[0] next - rx = 0 - if mem.number == -2: - rx = 1 - _mem = self._memobj.frq[rx] - # immutable = ["number", "extd_number", "name"] - mem = self._get_memory(mem, _mem) - else: - raise Exception("Sorry, you can't edit that special" - " memory channel %i." % mem.number) - - # mem.immutable = immutable - - return mem - - def _set_memory(self, mem, _mem): - """Convert UI column data (mem) into MEM_FORMAT memory (_mem).""" - # At this point mem points to either normal or Freq chans - # These first attributes are common to all types - if mem.empty: - if mem.number > 0: - _mem.rxfreq = 0xffffffff - # Set 'empty' and 'skip' bits - _do_map(mem.number, 1, self._memobj.chnmap.map) - _do_map(mem.number, 1, self._memobj.skpchns.map) - elif mem.number == -2: # upper VFO Freq - _mem.rxfreq = 14652000 # VHF National Calling freq - elif mem.number == -1: # lower VFO - _mem.rxfreq = 44600000 # UHF National Calling freq - return - - _mem.rxfreq = mem.freq / 10 - - if str(mem.power) == "Low": - _mem.power = 0 - else: - _mem.power = 1 - - _mem.wide = self.MODES.index(mem.mode) - - 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) - - sx = mem.dtcs_polarity[1] - if rxmode == "": - _mem.rxtone[0] = 0xFF - _mem.rxtone[1] = 0xFF - elif rxmode == "Tone": - val = int(mem.ctone * 10) - i = set_tone(_mem, True, True, val, sx) - elif rxmode == "DTCSSQL": - i = set_tone(_mem, True, False, mem.dtcs, sx) - elif rxmode == "DTCS": - i = set_tone(_mem, True, False, mem.rx_dtcs, sx) - - sx = mem.dtcs_polarity[0] - if txmode == "": - _mem.txtone[0] = 0xFF - _mem.txtone[1] = 0xFF - elif txmode == "Tone": - val = int(mem.rtone * 10) - i = set_tone(_mem, False, True, val, sx) - elif txmode == "TSQL": - val = int(mem.ctone * 10) - i = set_tone(_mem, False, True, val, sx) - elif txmode == "DTCS": - i = set_tone(_mem, False, False, mem.dtcs, sx) - - if mem.number > 0: # Normal chans - for i in range(self.NAME_LENGTH): - pq = ord(mem.name.ljust(self.NAME_LENGTH)[i]) - 32 - if pq < 0: - pq = 0 - _mem.name[i] = pq - - 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.freq / 10 - - # Set the channel map bit FALSE = Enabled - _do_map(mem.number, 0, self._memobj.chnmap.map) - # Skip - if mem.skip == "S": - _do_map(mem.number, 1, self._memobj.skpchns.map) - else: - _do_map(mem.number, 0, self._memobj.skpchns.map) - - else: # Freq (VFO) chans - _mem.duplx = 0 - _mem.ofst = 0 - if mem.duplex == "+": - _mem.duplx = 1 - _mem.ofst = mem.offset / 10 - elif mem.duplex == "-": - _mem.duplx = 2 - _mem.ofst = mem.offset / 10 - for i in range(self.NAME_LENGTH): - _mem.name[i] = 0xff - - # All mem.extra << Once the channel is defined - for setting in mem.extra: - # Overide list strings with signed value - if setting.get_name() == "ptt": - sx = str(setting.value) - for i in range(0, 4): - if sx == LIST_PTT[i]: - val = i - setattr(_mem, "ptt", val) - elif setting.get_name() == "epilogue": # not inverted bool - setattr(_mem, setting.get_name(), setting.value) - else: # inverted booleans - setattr(_mem, setting.get_name(), not setting.value) - - def _set_special(self, mem): - - cur_mem = self._get_special(self.SPECIAL_MEMORIES_REV[mem.number]) - - if mem.number == -2: # upper frq[1] - _mem = self._memobj.frq[1] - elif mem.number == -1: # lower frq[0] - _mem = self._memobj.frq[0] - else: - raise Exception("Sorry, you can't edit that special memory.") - - self._set_memory(mem, _mem) # Now update the _mem - - def _set_normal(self, mem): - _mem = self._memobj.chan_mem[mem.number - 1] - - self._set_memory(mem, _mem) - - def get_settings(self): - """Translate the MEM_FORMAT structs into setstuf in the UI""" - # Define mem struct write-back shortcuts - _sets = self._memobj.setstuf - _fmx = self._memobj.fmfrqs - - basic = RadioSettingGroup("basic", "Basic Settings") - adv = RadioSettingGroup("adv", "Other Settings") - fmb = RadioSettingGroup("fmb", "FM Broadcast") - scn = RadioSettingGroup("scn", "Scan Settings") - dtmf = RadioSettingGroup("dtmf", "DTMF Settings") - frng = RadioSettingGroup("frng", "Frequency Ranges") - group = RadioSettings(basic, adv, scn, fmb, dtmf, frng) - - def my_val_list(setting, obj, atrb): - """Callback:from ValueList with non-sequential, actual values.""" - # This call back also used in get_settings - value = int(str(setting.value)) # Get the integer value - setattr(obj, atrb, value) - return - - def my_adjraw(setting, obj, atrb, fix): - """Callback from Integer add or subtract fix from value.""" - vx = int(str(setting.value)) - value = vx + int(fix) - if value < 0: - value = 0 - setattr(obj, atrb, value) - return - - def my_strnam(setting, obj, atrb, mln): - """Callback from String to build u8 array with -32 offset.""" - # mln is max string length - ary = [] - knt = mln - for j in range(mln - 1, -1, -1): # Strip trailing spaces or nulls - pq = str(setting.value)[j] - if pq == "" or pq == " ": - knt = knt - 1 - else: - break - for j in range(mln): # 0 to mln-1 - pq = str(setting.value).ljust(mln)[j] - if j < knt: - ary.append(ord(pq) - 32) - else: - ary.append(0) - setattr(obj, atrb, ary) - return - - def unpack_str(cary, cknt, mxw): - """Convert u8 nibble array to a string: NOT a callback.""" - # cknt is char count, 2/word; mxw is max WORDS - stx = "" - mty = True - for i in range(mxw): # unpack entire array - nib = (cary[i] & 0xf0) >> 4 # LE, Hi nib first - if nib != 0xf: - mty = False - stx += format(nib, '0X') - nib = cary[i] & 0xf - if nib != 0xf: - mty = False - stx += format(nib, '0X') - stx = stx[:cknt] - if mty: # all ff, empty string - sty = "" - else: - # Convert E to #, F to * - sty = "" - for i in range(cknt): - if stx[i] == "E": - sty += "#" - elif stx[i] == "F": - sty += "*" - else: - sty += stx[i] - - return sty - - def pack_chars(setting, obj, atrstr, atrcnt, mxl): - """Callback to build 0-9,A-D,*# nibble array from string""" - # cknt is generated char count, 2 chars per word - # String will be f padded to mxl - # Chars are stored as hex values - # store cknt-1 in atrcnt, 0xf if empty - cknt = 0 - ary = [] - stx = str(setting.value).upper() - stx = stx.strip() # trim spaces - # Remove illegal characters first - sty = "" - for j in range(0, len(stx)): - if stx[j] in self.DTMF_CHARS: - sty += stx[j] - for j in range(mxl): - if j < len(sty): - if sty[j] == "#": - chrv = 0xE - elif sty[j] == "*": - chrv = 0xF - else: - chrv = int(sty[j], 16) - cknt += 1 # char count - else: # pad to mxl, cknt does not increment - chrv = 0xF - if (j % 2) == 0: # odd count (0-based), high nibble - hi_nib = chrv - else: # even count, lower nibble - lo_nib = chrv - nibs = lo_nib | (hi_nib << 4) - ary.append(nibs) # append word - setattr(obj, atrstr, ary) - if setting.get_name() != "setstuf.stuncode": # cknt is actual - if cknt > 0: - cknt = cknt - 1 - else: - cknt = 0xf - setattr(obj, atrcnt, cknt) - return - - def myset_freq(setting, obj, atrb, mult): - """ Callback to set frequency by applying multiplier""" - value = int(float(str(setting.value)) * mult) - setattr(obj, atrb, value) - return - - def my_invbool(setting, obj, atrb): - """Callback to invert the boolean """ - bval = not setting.value - setattr(obj, atrb, bval) - return - - def my_batsav(setting, obj, atrb): - """Callback to set batsav attribute """ - stx = str(setting.value) # Off, 1:1... - if stx == "Off": - value = 0x1 # bit value 4 clear, ratio 1 = 1:2 - elif stx == "1:1": - value = 0x4 # On, ratio 0 = 1:1 - elif stx == "1:2": - value = 0x5 # On, ratio 1 = 1:2 - elif stx == "1:3": - value = 0x6 # On, ratio 2 = 1:3 - else: - value = 0x7 # On, ratio 3 = 1:4 - # LOG.warning("Batsav stx:%s:, value= %x" % (stx, value)) - setattr(obj, atrb, value) - return - - def my_manfrq(setting, obj, atrb): - """Callback to set 2-byte manfrqyn yes/no """ - # LOG.warning("Manfrq value = %d" % setting.value) - if (str(setting.value)) == "No": - value = 0xff - else: - value = 0xaa - setattr(obj, atrb, value) - return - - def myset_mask(setting, obj, atrb, nx): - if bool(setting.value): # Enabled = 0 - vx = 0 - else: - vx = 1 - _do_map(nx + 1, vx, self._memobj.fmmap.fmset) - return - - def myset_fmfrq(setting, obj, atrb, nx): - """ Callback to set xx.x FM freq in memory as xx.x * 40""" - # in-valid even KHz freqs are allowed; to satisfy run_tests - vx = float(str(setting.value)) - vx = int(vx * 40) - setattr(obj[nx], atrb, vx) - return - - rx = RadioSettingValueInteger(1, 9, _sets.voxgain + 1) - rset = RadioSetting("setstuf.voxgain", "Vox Level", rx) - rset.set_apply_callback(my_adjraw, _sets, "voxgain", -1) - basic.append(rset) - - rx = RadioSettingValueList(LIST_VOXDLY, LIST_VOXDLY[_sets.voxdelay]) - rset = RadioSetting("setstuf.voxdelay", "Vox Delay (secs)", rx) - basic.append(rset) - - rx = RadioSettingValueInteger(0, 9, _sets.sql) - rset = RadioSetting("setstuf.sql", "Squelch", rx) - basic.append(rset) - - rx = RadioSettingValueList(LIST_STEPS, LIST_STEPS[_sets.freqstep]) - rset = RadioSetting("setstuf.freqstep", "VFO Tune Step (KHz))", rx) - basic.append(rset) - - rx = RadioSettingValueBoolean(bool(_sets.dbw)) # true logic - rset = RadioSetting("setstuf.dbw", "Dual Band Watch (D.WAIT)", rx) - basic.append(rset) - - options = ["Off", "On", "Auto"] - rx = RadioSettingValueList(options, options[_sets.lampon]) - rset = RadioSetting("setstuf.lampon", "Backlight (LED)", rx) - basic.append(rset) - - options = ["Orange", "Purple", "Blue"] - rx = RadioSettingValueList(options, options[_sets.ledclr]) - rset = RadioSetting("setstuf.ledclr", "Backlight Color (LIGHT)", rx) - basic.append(rset) - - rx = RadioSettingValueBoolean(bool(_sets.beepon)) - rset = RadioSetting("setstuf.beepon", "Keypad Beep", rx) - basic.append(rset) - - rx = RadioSettingValueBoolean(bool(_sets.xbandenable)) - rset = RadioSetting("setstuf.xbandenable", "Cross Band Allowed", rx) - basic.append(rset) - - rx = RadioSettingValueBoolean(bool(not _sets.xbandon)) - rset = RadioSetting("setstuf.xbandon", "Cross Band On", rx) - rset.set_apply_callback(my_invbool, _sets, "xbandon") - basic.append(rset) - - rx = RadioSettingValueList(LIST_TIMEOUT, LIST_TIMEOUT[_sets.tot]) - rset = RadioSetting("setstuf.tot", "TX Timeout (Secs)", rx) - basic.append(rset) - - rx = RadioSettingValueBoolean(bool(not _sets.rgrbeep)) # Invert - rset = RadioSetting("setstuf.rgrbeep", "Beep at Eot (Roger)", rx) - rset.set_apply_callback(my_invbool, _sets, "rgrbeep") - basic.append(rset) - - rx = RadioSettingValueBoolean(bool(not _sets.keylok)) - rset = RadioSetting("setstuf.keylok", "Keypad AutoLock", rx) - rset.set_apply_callback(my_invbool, _sets, "keylok") - basic.append(rset) - - options = ["None", "Message", "DC Volts"] - rx = RadioSettingValueList(options, options[_sets.openmsg]) - rset = RadioSetting("setstuf.openmsg", "Power-On Display", rx) - basic.append(rset) - - options = ["Channel Name", "Frequency"] - rx = RadioSettingValueList(options, options[_sets.chs_name]) - rset = RadioSetting("setstuf.chs_name", "Display Name/Frq", rx) - basic.append(rset) - - sx = "" - for i in range(7): - if _sets.radioname[i] != 0: - sx += chr(_sets.radioname[i] + 32) - rx = RadioSettingValueString(0, 7, sx) - rset = RadioSetting("setstuf.radioname", "Power-On Message", rx) - rset.set_apply_callback(my_strnam, _sets, "radioname", 7) - basic.append(rset) - - # Advanced (Strange) Settings - options = ["Busy: Last Tx Band", "Edit: Current Band"] - rx = RadioSettingValueList(options, options[_sets.txsel]) - rset = RadioSetting("setstuf.txsel", "Transmit Priority", rx) - rset.set_doc("'Busy' transmits on last band used, not current one.") - adv.append(rset) - - options = ["Off", "English", "Unk", "Chinese"] - val = _sets.voice - rx = RadioSettingValueList(options, options[val]) - rset = RadioSetting("setstuf.voice", "Voice", rx) - adv.append(rset) - - options = ["Off", "1:1", "1:2", "1:3", "1:4"] - val = (_sets.batsav & 0x3) + 1 # ratio - if (_sets.batsav & 0x4) == 0: # Off - val = 0 - rx = RadioSettingValueList(options, options[val]) - rset = RadioSetting("setstuf.batsav", "Battery Saver", rx) - rset.set_apply_callback(my_batsav, _sets, "batsav") - adv.append(rset) - - # Find out what & where SuperSave is - options = ["Off", "1", "2", "3", "4", "5", "6", "7", "8", "9"] - rx = RadioSettingValueList(options, options[_sets.supersave]) - rset = RadioSetting("setstuf.supersave", "Super Save (Secs)", rx) - rset.set_doc("Unknown radio attribute??") - adv.append(rset) - - sx = unpack_str(_sets.pttbot, _sets.pttbcnt + 1, 8) - rx = RadioSettingValueString(0, 16, sx) - rset = RadioSetting("setstuf.pttbot", "PTT BoT Code", rx) - rset.set_apply_callback(pack_chars, _sets, "pttbot", "pttbcnt", 16) - adv.append(rset) - - sx = unpack_str(_sets.ptteot, _sets.pttecnt + 1, 8) - rx = RadioSettingValueString(0, 16, sx) - rset = RadioSetting("setstuf.ptteot", "PTT EoT Code", rx) - rset.set_apply_callback(pack_chars, _sets, "ptteot", "pttecnt", 16) - adv.append(rset) - - options = ["None", "Low", "High", "Both"] - rx = RadioSettingValueList(options, options[_sets.voltx]) - rset = RadioSetting("setstuf.voltx", "Transmit Inhibit Voltage", rx) - rset.set_doc("Block Transmit if battery volts are too high or low,") - adv.append(rset) - - val = 0 # No = 0xff - if _sets.manfrqyn == 0xaa: - val = 1 - options = ["No", "Yes"] - rx = RadioSettingValueList(options, options[val]) - rset = RadioSetting("setstuf.manfrqyn", "Manual Frequency", rx) - rset.set_apply_callback(my_manfrq, _sets, "manfrqyn") - adv.append(rset) - - rx = RadioSettingValueBoolean(bool(_sets.manualset)) - rset = RadioSetting("setstuf.manualset", "Manual Setting", rx) - adv.append(rset) - - # Scan Settings - options = ["CO: During Rx", "TO: Timed", "SE: Halt"] - rx = RadioSettingValueList(options, options[_sets.scanmode]) - rset = RadioSetting("setstuf.scanmode", - "Scan Mode (Scan Pauses When)", rx) - scn.append(rset) - - options = ["100", "150", "200", "250", - "300", "350", "400", "450"] - rx = RadioSettingValueList(options, options[_sets.scanspeed]) - rset = RadioSetting("setstuf.scanspeed", "Scan Speed (ms)", rx) - scn.append(rset) - - val = _sets.scantmo + 3 - rx = RadioSettingValueInteger(3, 30, val) - rset = RadioSetting("setstuf.scantmo", - "TO Mode Timeout (secs)", rx) - rset.set_apply_callback(my_adjraw, _sets, "scantmo", -3) - scn.append(rset) - - val = _sets.prichan - if val <= 0: - val = 1 - rx = RadioSettingValueInteger(1, 128, val) - rset = RadioSetting("setstuf.prichan", "Priority Channel", rx) - scn.append(rset) - - # FM Broadcast Settings - val = _fmx.fmcur - val = val / 40.0 - if val < 87.5 or val > 107.9: - val = 88.0 - rx = RadioSettingValueFloat(87.5, 107.9, val, 0.1, 1) - rset = RadioSetting("fmfrqs.fmcur", "Manual FM Freq (MHz)", rx) - rset.set_apply_callback(myset_freq, _fmx, "fmcur", 40) - fmb.append(rset) - - options = ["5", "50", "100", "200(USA)"] # 5 is not used - rx = RadioSettingValueList(options, options[_sets.fmstep]) - rset = RadioSetting("setstuf.fmstep", "FM Freq Step (KHz)", rx) - fmb.append(rset) - - # FM Scan Range fmsclo and fmschi are unknown memory locations, - # Not supported at this time - - rx = RadioSettingValueBoolean(bool(_sets.rxinhib)) - rset = RadioSetting("setstuf.rxinhib", - "Rcvr Will Interupt FM (DW)", rx) - fmb.append(rset) - - _fmfrq = self._memobj.fm_stations - _fmap = self._memobj.fmmap - for j in range(0, 25): - val = _fmfrq[j].rxfreq - if val == 0xFFFF: - val = 88.0 - fmset = False - else: - val = (float(int(val)) / 40) - # get fmmap bit value: 0 = enabled - ndx = int(math.floor((j) / 8)) - bv = j % 8 - msk = 1 << bv - vx = _fmap.fmset[ndx] - fmset = not bool(vx & msk) - rx = RadioSettingValueBoolean(fmset) - rset = RadioSetting("fmmap.fmset/%d" % j, - "FM Preset %02d" % (j + 1), rx) - rset.set_apply_callback(myset_mask, _fmap, "fmset", j) - fmb.append(rset) - - rx = RadioSettingValueFloat(87.5, 107.9, val, 0.1, 1) - rset = RadioSetting("fm_stations/%d.rxfreq" % j, - " Preset %02d Freq" % (j + 1), rx) - # This callback uses the array index - rset.set_apply_callback(myset_fmfrq, _fmfrq, "rxfreq", j) - fmb.append(rset) - - # DTMF Settings - options = [str(x) for x in range(4, 16)] - rx = RadioSettingValueList(options, options[_sets.dtmfspd]) - rset = RadioSetting("setstuf.dtmfspd", - "Tx Speed (digits/sec)", rx) - dtmf.append(rset) - - options = [str(x) for x in range(0, 1100, 100)] - rx = RadioSettingValueList(options, options[_sets.dtmfdig1time]) - rset = RadioSetting("setstuf.dtmfdig1time", - "Tx 1st Digit Time (ms)", rx) - dtmf.append(rset) - - options = [str(x) for x in range(100, 1100, 100)] - rx = RadioSettingValueList(options, options[_sets.dtmfdig1dly]) - rset = RadioSetting("setstuf.dtmfdig1dly", - "Tx 1st Digit Delay (ms)", rx) - dtmf.append(rset) - - options = ["0", "100", "500", "1000"] - rx = RadioSettingValueList(options, options[_sets.dtmfspms]) - rset = RadioSetting("setstuf.dtmfspms", - "Tx Star & Pound Time (ms)", rx) - dtmf.append(rset) - - options = ["None"] + [str(x) for x in range(600, 2100, 100)] - rx = RadioSettingValueList(options, options[_sets.codespctim]) - rset = RadioSetting("setstuf.codespctim", - "Tx Code Space Time (ms)", rx) - dtmf.append(rset) - - rx = RadioSettingValueBoolean(bool(_sets.codeabcd)) - rset = RadioSetting("setstuf.codeabcd", "Tx Codes A,B,C,D", rx) - dtmf.append(rset) - - rx = RadioSettingValueBoolean(bool(_sets.dtmfside)) - rset = RadioSetting("setstuf.dtmfside", "DTMF Side Tone", rx) - dtmf.append(rset) - - options = ["Off", "A", "B", "C", "D"] - rx = RadioSettingValueList(options, options[_sets.grpcode]) - rset = RadioSetting("setstuf.grpcode", "Rx Group Code", rx) - dtmf.append(rset) - - options = ["Off"] + [str(x) for x in range(1, 16)] - rx = RadioSettingValueList(options, options[_sets.autoresettmo]) - rset = RadioSetting("setstuf.autoresettmo", - "Rx Auto Reset Timeout (secs)", rx) - dtmf.append(rset) - - rx = RadioSettingValueBoolean(bool(_sets.txdecode)) - rset = RadioSetting("setstuf.txdecode", "Tx Decode", rx) - dtmf.append(rset) - - rx = RadioSettingValueBoolean(bool(_sets.idedit)) - rset = RadioSetting("setstuf.idedit", "Allow ANI Code Edit", rx) - dtmf.append(rset) - - options = [str(x) for x in range(500, 1600, 100)] - rx = RadioSettingValueList(options, options[_sets.decodetmo]) - rset = RadioSetting("setstuf.decodetmo", - "Rx Decode Timeout (ms)", rx) - dtmf.append(rset) - - options = ["Tx & Rx Inhibit", "Tx Inhibit"] - rx = RadioSettingValueList(options, options[_sets.stuntype]) - rset = RadioSetting("setstuf.stuntype", "Stun Type", rx) - dtmf.append(rset) - - sx = unpack_str(_sets.stuncode, _sets.stuncnt, 5) - rx = RadioSettingValueString(0, 10, sx) - rset = RadioSetting("setstuf.stuncode", "Stun Code", rx) - rset.set_apply_callback(pack_chars, _sets, - "stuncode", "stuncnt", 10) - dtmf.append(rset) - - # Frequency ranges - rx = RadioSettingValueBoolean(bool(_sets.frqr1)) - rset = RadioSetting("setstuf.frqr1", "Freq Range 1 (UHF)", rx) - rset.set_doc("Enable the UHF frequency bank.") - frng.append(rset) - - rx = RadioSettingValueBoolean(bool(_sets.frqr2)) - rset = RadioSetting("setstuf.frqr2", "Freq Range 2 (VHF)", rx) - rset.set_doc("Enable the VHF frequency bank.") - frng.append(rset) - - mod_se = True # UV8000SE has 3rd freq bank - if mod_se: - rx = RadioSettingValueBoolean(bool(_sets.frqr3)) - rset = RadioSetting("setstuf.frqr3", "Freq Range 3 (220Mhz)", rx) - rset.set_doc("Enable the 220MHz frequency bank.") - frng.append(rset) - - frqm = 100000 - val = _sets.frqr1lo / frqm - rx = RadioSettingValueFloat(400.0, 520.0, val, 0.005, 3) - rset = RadioSetting("setstuf.frqr1lo", - "UHF Range Low Limit (MHz)", rx) - rset.set_apply_callback(myset_freq, _sets, "frqr1lo", frqm) - rset.set_doc("Low limit of the UHF frequency bank.") - frng.append(rset) - - val = _sets.frqr1hi / frqm - rx = RadioSettingValueFloat(400.0, 520.0, val, 0.005, 3) - rset = RadioSetting("setstuf.frqr1hi", - "UHF Range High Limit (MHz)", rx) - rset.set_apply_callback(myset_freq, _sets, "frqr1hi", frqm) - rset.set_doc("High limit of the UHF frequency bank.") - frng.append(rset) - - val = _sets.frqr2lo / frqm - rx = RadioSettingValueFloat(136.0, 174.0, val, 0.005, 3) - rset = RadioSetting("setstuf.frqr2lo", - "VHF Range Low Limit (MHz)", rx) - rset.set_apply_callback(myset_freq, _sets, "frqr2lo", frqm) - rset.set_doc("Low limit of the VHF frequency bank.") - frng.append(rset) - - val = _sets.frqr2hi / frqm - rx = RadioSettingValueFloat(136.0, 174.0, val, 0.005, 3) - rset = RadioSetting("setstuf.frqr2hi", - "VHF Range High Limit (MHz)", rx) - rset.set_apply_callback(myset_freq, _sets, "frqr2hi", frqm) - rset.set_doc("High limit of the VHF frequency bank.") - frng.append(rset) - - if mod_se: - val = _sets.frqr3lo / frqm - if val < 220.0: - val = 220.0 - rx = RadioSettingValueFloat(220.0, 260.0, val, 0.005, 3) - rset = RadioSetting("setstuf.frqr3lo", - "1.25m Range Low Limit (MHz)", rx) - rset.set_apply_callback(myset_freq, _sets, "frqr3lo", frqm) - frng.append(rset) - - val = _sets.frqr3hi / frqm - if val < 220.0: - val = 260.0 - rx = RadioSettingValueFloat(220.0, 260.0, val, 0.005, 3) - rset = RadioSetting("setstuf.frqr3hi", - "1.25m Range High Limit (MHz)", rx) - rset.set_apply_callback(myset_freq, _sets, "frqr3hi", 1000) - frng.append(rset) - - return group # END get_settings() - - def set_settings(self, settings): - _settings = self._memobj.setstuf - _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 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 +# Copyright 2020: Rick DeWitt (RJD), +# Version 1.1 for TYT-UV8000D/E +# V1.1 fixes issue #8339 Priority scan channel: OFF +# Thanks to Damon Schaefer (K9CQB) and the Loudoun County, VA ARES +# club for the donated radio. +# And thanks to Ian Harris (VA3IHX) for decoding the memory map. +# +# 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 . + +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; + u8 rxtone[2]; + u8 txtone[2]; + u8 wide:1 // 0x0c + vox_on:1 + chunk01:1 + bcl:1 // inv bool + epilogue:1 + power:1 + chunk02:1 + chunk03:1; + u8 ani:1 // 0x0d inv + chunk08:1 + ptt:2 + chpad04:4; + u8 chunk05; // 0x0e + u16 id_code; // 0x0f, 10 + u8 chunk06; + u8 name[7]; + ul32 chpad06; // Need 56 byte pad + ul16 chpad07; + u8 chpad08; +}; + +struct fm_chn { + ul16 rxfreq; +}; + +struct frqx { + ul32 rxfreq; + ul24 ofst; + u8 fqunk01:4 // 0x07 + funk10:2 + duplx:2; + u8 rxtone[2]; // 0x08, 9 + u8 txtone[2]; // 0x0a, b + u8 wide:1 // 0x0c + vox_on:1 + funk11:1 + bcl:1 // inv bool + epilogue:1 + power:1 + fqunk02:2; + u8 ani:1 // 0x0d inv bool + fqunk03:1 + ptt:2 + fqunk12:1 + fqunk04:3; + u8 fqunk07; // 0x0e + u16 id_code; // 0x0f, 0x10 + u8 name[7]; // dummy + u8 fqunk09[8]; // empty bytes after 1st entry +}; + +struct bitmap { + u8 map[16]; +}; + +#seekto 0x0010; +struct chns chan_mem[128]; + +#seekto 0x1010; +struct frqx frq[2]; + +#seekto 0x1050; +struct fm_chn fm_stations[25]; + +#seekto 0x1080; +struct { + u8 fmunk01[14]; + ul16 fmcur; +} fmfrqs; + +#seekto 0x1190; +struct bitmap chnmap; + +#seekto 0x11a0; +struct bitmap skpchns; + +#seekto 0x011b0; +struct { + u8 fmset[4]; +} fmmap; + +#seekto 0x011b4; +struct { + u8 setunk01[4]; + u8 setunk02[3]; + u8 chs_name:1 // 0x11bb + txsel:1 + dbw:1 + setunk05:1 + ponfmchs:2 + ponchs:2; + u8 voltx:2 // 0x11bc + setunk04:1 + keylok:1 + setunk07:1 + batsav:3; + u8 setunk09:1 // 0x11bd + rxinhib:1 + rgrbeep:1 // inv bool + lampon:2 + voice:2 + beepon:1; + u8 setunk11:1 // 0x11be + manualset:1 + xbandon:1 // inv + xbandenable:1 + openmsg:2 + ledclr:2; + u8 tot:4 // 0x11bf + sql:4; + u8 setunk27:1 // 0x11c0 + voxdelay:2 + setunk28:1 + voxgain:4; + u8 fmstep:4 // 0x11c1 + freqstep:4; + u8 scanspeed:4 // 0x11c2 + scanmode:4; + u8 scantmo; // 0x11c3 + u8 prichan; // 0x11c4 + u8 setunk12:4 // 0x11c5 + supersave:4; + u8 setunk13; + u8 fmsclo; // 0x11c7 ??? placeholder + u8 radioname[7]; // hex char codes, not true ASCII + u8 fmschi; // ??? placeholder + u8 setunk14[3]; // 0x11d0 + u8 setunk17[2]; // 0x011d3, 4 + u8 setunk18:4 + dtmfspd:4; + u8 dtmfdig1dly:4 // 0x11d6 + dtmfdig1time:4; + u8 stuntype:1 + setunk19:1 + dtmfspms:2 + grpcode:4; + u8 setunk20:1 // 0x11d8 + txdecode:1 + codeabcd:1 + idedit:1 + pttidon:2 + setunk40:1, + dtmfside:1; + u8 setunk50:4, + autoresettmo:4; + u8 codespctim:4, // 0x11da + decodetmo:4; + u8 pttecnt:4 // 0x11db + pttbcnt:4; + lbcd dtmfdecode[3]; + u8 setunk22; + u8 stuncnt; // 0x11e0 + u8 stuncode[5]; + u8 setunk60; + u8 setunk61; + u8 pttbot[8]; // 0x11e8-f + u8 ptteot[8]; // 0x11f0-7 + u8 setunk62; // 0x11f8 + u8 setunk63; + u8 setunk64; // 0x11fa + u8 setunk65; + u8 setunk66; + u8 manfrqyn; // 0x11fd + u8 setunk27:3 + frqr3:1 + setunk28:1 + frqr2:1 + setunk29:1 + frqr1:1; + u8 setunk25; + ul32 frqr1lo; // 0x1200 + ul32 frqr1hi; + ul32 frqr2lo; + ul32 frqr2hi; + ul32 frqr3lo; // 0x1210 + ul32 frqr3hi; + u8 setunk26[8]; +} setstuf; + +#seekto 0x1260; +struct { + u8 modnum[7]; +} modcode; + +#seekto 0x1300; +struct { + char mod_num[9]; +} mod_id; +""" + +MEM_SIZE = 0x1300 +BLOCK_SIZE = 0x10 # can read 0x20, but must write 0x10 +STIMEOUT = 2 +BAUDRATE = 4800 +# Channel power: 2 levels +POWER_LEVELS = [chirp_common.PowerLevel("Low", watts=5.00), + chirp_common.PowerLevel("High", watts=10.00)] + +LIST_RECVMODE = ["QT/DQT", "QT/DQT + Signaling"] +LIST_COLOR = ["Off", "Orange", "Blue", "Purple"] +LIST_LEDSW = ["Auto", "On"] +LIST_TIMEOUT = ["Off"] + ["%s" % x for x in range(30, 390, 30)] +LIST_VFOMODE = ["Frequency Mode", "Channel Mode"] +# Tones are numeric, Defined in \chirp\chirp_common.py +TONES_CTCSS = sorted(chirp_common.TONES) +# Converted to strings +LIST_CTCSS = ["Off"] + [str(x) for x in TONES_CTCSS] +# Now append the DxxxN and DxxxI DTCS codes from chirp_common +for x in chirp_common.DTCS_CODES: + LIST_CTCSS.append("D{:03d}N".format(x)) +for x in chirp_common.DTCS_CODES: + LIST_CTCSS.append("D{:03d}R".format(x)) +LIST_BW = ["Narrow", "Wide"] +LIST_SHIFT = ["off", "+", "-"] +STEPS = [0.5, 2.5, 5.0, 6.25, 10.0, 12.5, 25.0, 37.5, 50.0, 100.0] +LIST_STEPS = [str(x) for x in STEPS] +LIST_VOXDLY = ["0.5", "1.0", "2.0", "3.0"] # LISTS must be strings +LIST_PTT = ["Both", "EoT", "BoT", "Off"] + +SETTING_LISTS = {"tot": LIST_TIMEOUT, "wtled": LIST_COLOR, + "rxled": LIST_COLOR, "txled": LIST_COLOR, + "ledsw": LIST_LEDSW, "frq_chn_mode": LIST_VFOMODE, + "rx_tone": LIST_CTCSS, "tx_tone": LIST_CTCSS, + "rx_mode": LIST_RECVMODE, "fm_bw": LIST_BW, + "shift": LIST_SHIFT, "step": LIST_STEPS, + "vox_dly": LIST_VOXDLY, "ptt": LIST_PTT} + + +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_frame(cmd, addr, length, data=""): + """Pack the info in the headder format""" + frame = struct.pack(">shB", 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 """ + + 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) + + magic = "PROGRAMa" + _rawsend(radio, magic) + ack = _rawrecv(radio, 1) + # LOG.warning("PROGa Ack:" + util.hexprint(ack)) + if ack != "\x06": + _exit_program_mode(radio) + if ack: + LOG.debug(repr(ack)) + raise errors.RadioError("Radio did not respond") + magic = "PROGRAMb" + _rawsend(radio, magic) + ack = _rawrecv(radio, 1) + if ack != "\x06": + _exit_program_mode(radio) + if ack: + LOG.debug(repr(ack)) + raise errors.RadioError("Radio did not respond to B") + magic = chr(0x02) + _rawsend(radio, magic) + ack = _rawrecv(radio, 1) # s/b: 0x50 + magic = _rawrecv(radio, 7) # s/b TC88... + magic = "MTC88CUMHS3E7BN-" + _rawsend(radio, magic) + ack = _rawrecv(radio, 1) # s/b 0x80 + magic = chr(0x06) + _rawsend(radio, magic) + ack = _rawrecv(radio, 1) + + return True + + +def _exit_program_mode(radio): + endframe = "E" + _rawsend(radio, endframe) + + +def _download(radio): + """Get the memory map""" + + # Put radio in program mode and identify it + _do_ident(radio) + + # 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_frame("R", addr, BLOCK_SIZE) + # DEBUG + LOG.info("Request sent:") + LOG.debug("Frame=" + util.hexprint(frame)) + + # Sending the read request + _rawsend(radio, frame) + dx = _rawrecv(radio, 4) + + # Now we read data + d = _recv(radio, addr, BLOCK_SIZE) + # LOG.warning("Data= " + util.hexprint(d)) + + # Aggregate the data + data += d + + # 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) + + # 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): + # Sending the data + data = radio.get_mmap()[addr:addr + BLOCK_SIZE] + + frame = _make_frame("W", addr, BLOCK_SIZE, data) + # LOG.warning("Frame:%s:" % util.hexprint(frame)) + _rawsend(radio, frame) + + # Receiving the response + ack = _rawrecv(radio, 1) + if ack != "\x06": + _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 set_tone(_mem, txrx, ctdt, tval, pol): + """Set rxtone[] or txtone[] word values as decimal bytes""" + # txrx: Boolean T= set Rx tones, F= set Tx tones + # ctdt: Boolean T = CTCSS, F= DTCS + # tval = integer tone freq (*10) or DTCS code + # pol = string for DTCS polarity "R" or "N" + xv = int(str(tval), 16) + if txrx: # True = set rxtones + _mem.rxtone[0] = xv & 0xFF # Low byte + _mem.rxtone[1] = (xv >> 8) # Hi byte + if not ctdt: # dtcs, + if pol == "R": + _mem.rxtone[1] = _mem.rxtone[1] | 0xC0 + else: + _mem.rxtone[1] = _mem.rxtone[1] | 0x80 + else: # txtones + _mem.txtone[0] = xv & 0xFF # Low byte + _mem.txtone[1] = (xv >> 8) + if not ctdt: # dtcs + if pol == "R": + _mem.txtone[1] = _mem.txtone[1] | 0xC0 + else: + _mem.txtone[1] = _mem.txtone[1] | 0x80 + + + +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 THUV8000Radio(chirp_common.CloneModeRadio): + """TYT UV8000D Radio""" + VENDOR = "TYT" + MODEL = "TH-UV8000" + MODES = ["NFM", "FM"] + TONES = chirp_common.TONES + DTCS_CODES = sorted(chirp_common.DTCS_CODES + [645]) + NAME_LENGTH = 7 + DTMF_CHARS = list("0123456789ABCD*#") + # NOTE: SE Model supports 220-260 MHz + # The following bands are the the range the radio is capable of, + # not the legal FCC amateur bands + VALID_BANDS = [(87500000, 107900000), (136000000, 174000000), + (220000000, 260000000), (400000000, 520000000)] + + # Valid chars on the LCD + VALID_CHARS = chirp_common.CHARSET_ALPHANUMERIC + \ + "`!\"#$%&'()*+,-./:;<=>?@[]^_" + + # Special Channels Declaration + # WARNING Indecis are hard wired in get/set_memory code !!! + # Channels print in + increasing index order (most negative first) + SPECIAL_MEMORIES = { + "UpVFO": -2, + "LoVFO": -1 + } + FIRST_FREQ_INDEX = -1 + LAST_FREQ_INDEX = -2 + + SPECIAL_MEMORIES_REV = dict(zip(SPECIAL_MEMORIES.values(), + SPECIAL_MEMORIES.keys())) + + @classmethod + def get_prompts(cls): + rp = chirp_common.RadioPrompts() + rp.info = \ + ('Click on the "Special Channels" toggle-button of the memory ' + 'editor to see/set the upper and lower frequency-mode values.\n') + + rp.pre_download = _(dedent("""\ + Follow these instructions to download the radio memory: + + 1 - Turn off your radio + 2 - Connect your interface cable + 3 - Turn on your radio, volume @ 50% + 4 - Radio > Download from radio + """)) + rp.pre_upload = _(dedent("""\ + Follow these instructions to upload the radio memory: + + 1 - Turn off your radio + 2 - Connect your interface cable + 3 - Turn on your radio, volume @ 50% + 4 - Radio > Upload to radio + """)) + return rp + + def get_features(self): + rf = chirp_common.RadioFeatures() + # .has. attributes are boolean, .valid. are lists + rf.has_settings = True + rf.has_bank = False + rf.has_comment = False + rf.has_nostep_tuning = True # Radio accepts any entered freq + rf.has_tuning_step = False # Not as chan feature + 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_power_levels = POWER_LEVELS + rf.valid_dtcs_codes = self.DTCS_CODES + rf.valid_bands = self.VALID_BANDS + rf.memory_bounds = (1, 128) + rf.valid_skips = ["", "S"] + rf.valid_special_chans = sorted(self.SPECIAL_MEMORIES.keys()) + 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 get_memory(self, number): + if isinstance(number, str): + return self._get_special(number) + elif number < 0: + # I can't stop delete operation from loosing extd_number but + # I know how to get it back + return self._get_special(self.SPECIAL_MEMORIES_REV[number]) + else: + return self._get_normal(number) + + 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) + if memory.number < 0: + return self._set_special(memory) + else: + return self._set_normal(memory) + + def _get_normal(self, number): + # radio first channel is 1, mem map is base 0 + _mem = self._memobj.chan_mem[number - 1] + mem = chirp_common.Memory() + mem.number = number + + return self._get_memory(mem, _mem) + + def _get_memory(self, mem, _mem): + """Convert raw channel memory data into UI columns""" + mem.extra = RadioSettingGroup("extra", "Extra") + + if _mem.get_raw()[0] == "\xff": + mem.empty = True + return mem + + mem.empty = False + # This function process both 'normal' and Freq up/down' entries + mem.freq = int(_mem.rxfreq) * 10 + mem.power = POWER_LEVELS[_mem.power] + mem.mode = self.MODES[_mem.wide] + dtcs_pol = ["N", "N"] + + if _mem.rxtone[0] == 0xFF: + rxmode = "" + elif _mem.rxtone[1] < 0x26: + # CTCSS + rxmode = "Tone" + tonehi = int(str(_mem.rxtone[1])[2:]) + tonelo = int(str(_mem.rxtone[0])[2:]) + mem.ctone = int(tonehi * 100 + tonelo) / 10.0 + else: + # Digital + rxmode = "DTCS" + tonehi = int(str(_mem.rxtone[1] & 0x3f)) + tonelo = int(str(_mem.rxtone[0])[2:]) + mem.rx_dtcs = int(tonehi * 100 + tonelo) + if (_mem.rxtone[1] & 0x40) != 0: + dtcs_pol[1] = "R" + + if _mem.txtone[0] == 0xFF: + txmode = "" + elif _mem.txtone[1] < 0x26: + # CTCSS + txmode = "Tone" + tonehi = int(str(_mem.txtone[1])[2:]) + tonelo = int(str(_mem.txtone[0])[2:]) + mem.rtone = int(tonehi * 100 + tonelo) / 10.0 + else: + # Digital + txmode = "DTCS" + tonehi = int(str(_mem.txtone[1] & 0x3f)) + tonelo = int(str(_mem.txtone[0])[2:]) + mem.dtcs = int(tonehi * 100 + tonelo) + if (_mem.txtone[1] & 0x40) != 0: + dtcs_pol[0] = "R" + + 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) + + mem.dtcs_polarity = "".join(dtcs_pol) + + # Now test the mem.number to process special vs normal + if mem.number >= 0: # Normal + mem.name = "" + for i in range(self.NAME_LENGTH): # 0 - 6 + mem.name += chr(_mem.name[i] + 32) + mem.name = mem.name.rstrip() # remove trailing spaces + + 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 + + if _do_map(mem.number, 2, self._memobj.skpchns.map) > 0: + mem.skip = "S" + else: + mem.skip = "" + + else: # specials VFO + mem.name = "----" + mem.duplex = LIST_SHIFT[_mem.duplx] + mem.offset = int(_mem.ofst) * 10 + mem.skip = "" + # End if specials + + # Channel Extra settings: Only Boolean & List methods, no call-backs + rx = RadioSettingValueBoolean(bool(not _mem.bcl)) # Inverted bool + # NOTE: first param of RadioSetting is the object attribute name + rset = RadioSetting("bcl", "Busy Channel Lockout", rx) + mem.extra.append(rset) + + rx = RadioSettingValueBoolean(bool(not _mem.vox_on)) + rset = RadioSetting("vox_on", "Vox", rx) + mem.extra.append(rset) + + rx = RadioSettingValueBoolean(bool(not _mem.ani)) + rset = RadioSetting("ani", "Auto Number ID (ANI)", rx) + mem.extra.append(rset) + + # ID code can't be done in extra - no Integer method or call-back + + rx = RadioSettingValueList(LIST_PTT, LIST_PTT[_mem.ptt]) + rset = RadioSetting("ptt", "Xmit PTT ID", rx) + mem.extra.append(rset) + + rx = RadioSettingValueBoolean(bool(_mem.epilogue)) + rset = RadioSetting("epilogue", "Epilogue/Tail", rx) + mem.extra.append(rset) + + return mem + + def _get_special(self, number): + mem = chirp_common.Memory() + mem.number = self.SPECIAL_MEMORIES[number] + mem.extd_number = number + # Unused attributes are ignored in Set_memory + if (mem.number == -1) or (mem.number == -2): + # Print Upper[1] first, and Lower[0] next + rx = 0 + if mem.number == -2: + rx = 1 + _mem = self._memobj.frq[rx] + # immutable = ["number", "extd_number", "name"] + mem = self._get_memory(mem, _mem) + else: + raise Exception("Sorry, you can't edit that special" + " memory channel %i." % mem.number) + + # mem.immutable = immutable + + return mem + + def _set_memory(self, mem, _mem): + """Convert UI column data (mem) into MEM_FORMAT memory (_mem).""" + # At this point mem points to either normal or Freq chans + # These first attributes are common to all types + if mem.empty: + if mem.number > 0: + _mem.rxfreq = 0xffffffff + # Set 'empty' and 'skip' bits + _do_map(mem.number, 1, self._memobj.chnmap.map) + _do_map(mem.number, 1, self._memobj.skpchns.map) + elif mem.number == -2: # upper VFO Freq + _mem.rxfreq = 14652000 # VHF National Calling freq + elif mem.number == -1: # lower VFO + _mem.rxfreq = 44600000 # UHF National Calling freq + return + + _mem.rxfreq = mem.freq / 10 + + if str(mem.power) == "Low": + _mem.power = 0 + else: + _mem.power = 1 + + _mem.wide = self.MODES.index(mem.mode) + + 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) + + sx = mem.dtcs_polarity[1] + if rxmode == "": + _mem.rxtone[0] = 0xFF + _mem.rxtone[1] = 0xFF + elif rxmode == "Tone": + val = int(mem.ctone * 10) + i = set_tone(_mem, True, True, val, sx) + elif rxmode == "DTCSSQL": + i = set_tone(_mem, True, False, mem.dtcs, sx) + elif rxmode == "DTCS": + i = set_tone(_mem, True, False, mem.rx_dtcs, sx) + + sx = mem.dtcs_polarity[0] + if txmode == "": + _mem.txtone[0] = 0xFF + _mem.txtone[1] = 0xFF + elif txmode == "Tone": + val = int(mem.rtone * 10) + i = set_tone(_mem, False, True, val, sx) + elif txmode == "TSQL": + val = int(mem.ctone * 10) + i = set_tone(_mem, False, True, val, sx) + elif txmode == "DTCS": + i = set_tone(_mem, False, False, mem.dtcs, sx) + + if mem.number > 0: # Normal chans + for i in range(self.NAME_LENGTH): + pq = ord(mem.name.ljust(self.NAME_LENGTH)[i]) - 32 + if pq < 0: + pq = 0 + _mem.name[i] = pq + + 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.freq / 10 + + # Set the channel map bit FALSE = Enabled + _do_map(mem.number, 0, self._memobj.chnmap.map) + # Skip + if mem.skip == "S": + _do_map(mem.number, 1, self._memobj.skpchns.map) + else: + _do_map(mem.number, 0, self._memobj.skpchns.map) + + else: # Freq (VFO) chans + _mem.duplx = 0 + _mem.ofst = 0 + if mem.duplex == "+": + _mem.duplx = 1 + _mem.ofst = mem.offset / 10 + elif mem.duplex == "-": + _mem.duplx = 2 + _mem.ofst = mem.offset / 10 + for i in range(self.NAME_LENGTH): + _mem.name[i] = 0xff + + # All mem.extra << Once the channel is defined + for setting in mem.extra: + # Overide list strings with signed value + if setting.get_name() == "ptt": + sx = str(setting.value) + for i in range(0, 4): + if sx == LIST_PTT[i]: + val = i + setattr(_mem, "ptt", val) + elif setting.get_name() == "epilogue": # not inverted bool + setattr(_mem, setting.get_name(), setting.value) + else: # inverted booleans + setattr(_mem, setting.get_name(), not setting.value) + + def _set_special(self, mem): + + cur_mem = self._get_special(self.SPECIAL_MEMORIES_REV[mem.number]) + + if mem.number == -2: # upper frq[1] + _mem = self._memobj.frq[1] + elif mem.number == -1: # lower frq[0] + _mem = self._memobj.frq[0] + else: + raise Exception("Sorry, you can't edit that special memory.") + + self._set_memory(mem, _mem) # Now update the _mem + + def _set_normal(self, mem): + _mem = self._memobj.chan_mem[mem.number - 1] + + self._set_memory(mem, _mem) + + def get_settings(self): + """Translate the MEM_FORMAT structs into setstuf in the UI""" + # Define mem struct write-back shortcuts + _sets = self._memobj.setstuf + _fmx = self._memobj.fmfrqs + + basic = RadioSettingGroup("basic", "Basic Settings") + adv = RadioSettingGroup("adv", "Other Settings") + fmb = RadioSettingGroup("fmb", "FM Broadcast") + scn = RadioSettingGroup("scn", "Scan Settings") + dtmf = RadioSettingGroup("dtmf", "DTMF Settings") + frng = RadioSettingGroup("frng", "Frequency Ranges") + group = RadioSettings(basic, adv, scn, fmb, dtmf, frng) + + def my_val_list(setting, obj, atrb): + """Callback:from ValueList with non-sequential, actual values.""" + # This call back also used in get_settings + value = int(str(setting.value)) # Get the integer value + setattr(obj, atrb, value) + + def my_adjraw(setting, obj, atrb, fix): + """Callback from Integer add or subtract fix from value.""" + vx = int(str(setting.value)) + value = vx + int(fix) + if value < 0: + value = 0 + setattr(obj, atrb, value) + + def my_strnam(setting, obj, atrb, mln): + """Callback from String to build u8 array with -32 offset.""" + # mln is max string length + ary = [] + knt = mln + for j in range(mln - 1, -1, -1): # Strip trailing spaces or nulls + pq = str(setting.value)[j] + if pq == "" or pq == " ": + knt = knt - 1 + else: + break + for j in range(mln): # 0 to mln-1 + pq = str(setting.value).ljust(mln)[j] + if j < knt: + ary.append(ord(pq) - 32) + else: + ary.append(0) + setattr(obj, atrb, ary) + + def unpack_str(cary, cknt, mxw): + """Convert u8 nibble array to a string: NOT a callback.""" + # cknt is char count, 2/word; mxw is max WORDS + stx = "" + mty = True + for i in range(mxw): # unpack entire array + nib = (cary[i] & 0xf0) >> 4 # LE, Hi nib first + if nib != 0xf: + mty = False + stx += format(nib, '0X') + nib = cary[i] & 0xf + if nib != 0xf: + mty = False + stx += format(nib, '0X') + stx = stx[:cknt] + if mty: # all ff, empty string + sty = "" + else: + # Convert E to #, F to * + sty = "" + for i in range(cknt): + if stx[i] == "E": + sty += "#" + elif stx[i] == "F": + sty += "*" + else: + sty += stx[i] + + return sty + + def pack_chars(setting, obj, atrstr, atrcnt, mxl): + """Callback to build 0-9,A-D,*# nibble array from string""" + # cknt is generated char count, 2 chars per word + # String will be f padded to mxl + # Chars are stored as hex values + # store cknt-1 in atrcnt, 0xf if empty + cknt = 0 + ary = [] + stx = str(setting.value).upper() + stx = stx.strip() # trim spaces + # Remove illegal characters first + sty = "" + for j in range(0, len(stx)): + if stx[j] in self.DTMF_CHARS: + sty += stx[j] + for j in range(mxl): + if j < len(sty): + if sty[j] == "#": + chrv = 0xE + elif sty[j] == "*": + chrv = 0xF + else: + chrv = int(sty[j], 16) + cknt += 1 # char count + else: # pad to mxl, cknt does not increment + chrv = 0xF + if (j % 2) == 0: # odd count (0-based), high nibble + hi_nib = chrv + else: # even count, lower nibble + lo_nib = chrv + nibs = lo_nib | (hi_nib << 4) + ary.append(nibs) # append word + setattr(obj, atrstr, ary) + if setting.get_name() != "setstuf.stuncode": # cknt is actual + if cknt > 0: + cknt = cknt - 1 + else: + cknt = 0xf + setattr(obj, atrcnt, cknt) + + def myset_freq(setting, obj, atrb, mult): + """ Callback to set frequency by applying multiplier""" + value = int(float(str(setting.value)) * mult) + setattr(obj, atrb, value) + + def my_invbool(setting, obj, atrb): + """Callback to invert the boolean """ + bval = not setting.value + setattr(obj, atrb, bval) + + def my_batsav(setting, obj, atrb): + """Callback to set batsav attribute """ + stx = str(setting.value) # Off, 1:1... + if stx == "Off": + value = 0x1 # bit value 4 clear, ratio 1 = 1:2 + elif stx == "1:1": + value = 0x4 # On, ratio 0 = 1:1 + elif stx == "1:2": + value = 0x5 # On, ratio 1 = 1:2 + elif stx == "1:3": + value = 0x6 # On, ratio 2 = 1:3 + else: + value = 0x7 # On, ratio 3 = 1:4 + # LOG.warning("Batsav stx:%s:, value= %x" % (stx, value)) + setattr(obj, atrb, value) + + def my_manfrq(setting, obj, atrb): + """Callback to set 2-byte manfrqyn yes/no """ + # LOG.warning("Manfrq value = %d" % setting.value) + if (str(setting.value)) == "No": + value = 0xff + else: + value = 0xaa + setattr(obj, atrb, value) + + def myset_mask(setting, obj, atrb, nx): + if bool(setting.value): # Enabled = 0 + vx = 0 + else: + vx = 1 + _do_map(nx + 1, vx, self._memobj.fmmap.fmset) + + def myset_fmfrq(setting, obj, atrb, nx): + """ Callback to set xx.x FM freq in memory as xx.x * 40""" + # in-valid even KHz freqs are allowed; to satisfy run_tests + vx = float(str(setting.value)) + vx = int(vx * 40) + setattr(obj[nx], atrb, vx) + + rx = RadioSettingValueInteger(1, 9, _sets.voxgain + 1) + rset = RadioSetting("setstuf.voxgain", "Vox Level", rx) + rset.set_apply_callback(my_adjraw, _sets, "voxgain", -1) + basic.append(rset) + + rx = RadioSettingValueList(LIST_VOXDLY, LIST_VOXDLY[_sets.voxdelay]) + rset = RadioSetting("setstuf.voxdelay", "Vox Delay (secs)", rx) + basic.append(rset) + + rx = RadioSettingValueInteger(0, 9, _sets.sql) + rset = RadioSetting("setstuf.sql", "Squelch", rx) + basic.append(rset) + + rx = RadioSettingValueList(LIST_STEPS, LIST_STEPS[_sets.freqstep]) + rset = RadioSetting("setstuf.freqstep", "VFO Tune Step (KHz))", rx) + basic.append(rset) + + rx = RadioSettingValueBoolean(bool(_sets.dbw)) # true logic + rset = RadioSetting("setstuf.dbw", "Dual Band Watch (D.WAIT)", rx) + basic.append(rset) + + options = ["Off", "On", "Auto"] + rx = RadioSettingValueList(options, options[_sets.lampon]) + rset = RadioSetting("setstuf.lampon", "Backlight (LED)", rx) + basic.append(rset) + + options = ["Orange", "Purple", "Blue"] + rx = RadioSettingValueList(options, options[_sets.ledclr]) + rset = RadioSetting("setstuf.ledclr", "Backlight Color (LIGHT)", rx) + basic.append(rset) + + rx = RadioSettingValueBoolean(bool(_sets.beepon)) + rset = RadioSetting("setstuf.beepon", "Keypad Beep", rx) + basic.append(rset) + + rx = RadioSettingValueBoolean(bool(_sets.xbandenable)) + rset = RadioSetting("setstuf.xbandenable", "Cross Band Allowed", rx) + basic.append(rset) + + rx = RadioSettingValueBoolean(bool(not _sets.xbandon)) + rset = RadioSetting("setstuf.xbandon", "Cross Band On", rx) + rset.set_apply_callback(my_invbool, _sets, "xbandon") + basic.append(rset) + + rx = RadioSettingValueList(LIST_TIMEOUT, LIST_TIMEOUT[_sets.tot]) + rset = RadioSetting("setstuf.tot", "TX Timeout (Secs)", rx) + basic.append(rset) + + rx = RadioSettingValueBoolean(bool(not _sets.rgrbeep)) # Invert + rset = RadioSetting("setstuf.rgrbeep", "Beep at Eot (Roger)", rx) + rset.set_apply_callback(my_invbool, _sets, "rgrbeep") + basic.append(rset) + + rx = RadioSettingValueBoolean(bool(not _sets.keylok)) + rset = RadioSetting("setstuf.keylok", "Keypad AutoLock", rx) + rset.set_apply_callback(my_invbool, _sets, "keylok") + basic.append(rset) + + options = ["None", "Message", "DC Volts"] + rx = RadioSettingValueList(options, options[_sets.openmsg]) + rset = RadioSetting("setstuf.openmsg", "Power-On Display", rx) + basic.append(rset) + + options = ["Channel Name", "Frequency"] + rx = RadioSettingValueList(options, options[_sets.chs_name]) + rset = RadioSetting("setstuf.chs_name", "Display Name/Frq", rx) + basic.append(rset) + + sx = "" + for i in range(7): + if _sets.radioname[i] != 0: + sx += chr(_sets.radioname[i] + 32) + rx = RadioSettingValueString(0, 7, sx) + rset = RadioSetting("setstuf.radioname", "Power-On Message", rx) + rset.set_apply_callback(my_strnam, _sets, "radioname", 7) + basic.append(rset) + + # Advanced (Strange) Settings + options = ["Busy: Last Tx Band", "Edit: Current Band"] + rx = RadioSettingValueList(options, options[_sets.txsel]) + rset = RadioSetting("setstuf.txsel", "Transmit Priority", rx) + rset.set_doc("'Busy' transmits on last band used, not current one.") + adv.append(rset) + + options = ["Off", "English", "Unk", "Chinese"] + val = _sets.voice + rx = RadioSettingValueList(options, options[val]) + rset = RadioSetting("setstuf.voice", "Voice", rx) + adv.append(rset) + + options = ["Off", "1:1", "1:2", "1:3", "1:4"] + val = (_sets.batsav & 0x3) + 1 # ratio + if (_sets.batsav & 0x4) == 0: # Off + val = 0 + rx = RadioSettingValueList(options, options[val]) + rset = RadioSetting("setstuf.batsav", "Battery Saver", rx) + rset.set_apply_callback(my_batsav, _sets, "batsav") + adv.append(rset) + + # Find out what & where SuperSave is + options = ["Off", "1", "2", "3", "4", "5", "6", "7", "8", "9"] + rx = RadioSettingValueList(options, options[_sets.supersave]) + rset = RadioSetting("setstuf.supersave", "Super Save (Secs)", rx) + rset.set_doc("Unknown radio attribute??") + adv.append(rset) + + sx = unpack_str(_sets.pttbot, _sets.pttbcnt + 1, 8) + rx = RadioSettingValueString(0, 16, sx) + rset = RadioSetting("setstuf.pttbot", "PTT BoT Code", rx) + rset.set_apply_callback(pack_chars, _sets, "pttbot", "pttbcnt", 16) + adv.append(rset) + + sx = unpack_str(_sets.ptteot, _sets.pttecnt + 1, 8) + rx = RadioSettingValueString(0, 16, sx) + rset = RadioSetting("setstuf.ptteot", "PTT EoT Code", rx) + rset.set_apply_callback(pack_chars, _sets, "ptteot", "pttecnt", 16) + adv.append(rset) + + options = ["None", "Low", "High", "Both"] + rx = RadioSettingValueList(options, options[_sets.voltx]) + rset = RadioSetting("setstuf.voltx", "Transmit Inhibit Voltage", rx) + rset.set_doc("Block Transmit if battery volts are too high or low,") + adv.append(rset) + + val = 0 # No = 0xff + if _sets.manfrqyn == 0xaa: + val = 1 + options = ["No", "Yes"] + rx = RadioSettingValueList(options, options[val]) + rset = RadioSetting("setstuf.manfrqyn", "Manual Frequency", rx) + rset.set_apply_callback(my_manfrq, _sets, "manfrqyn") + adv.append(rset) + + rx = RadioSettingValueBoolean(bool(_sets.manualset)) + rset = RadioSetting("setstuf.manualset", "Manual Setting", rx) + adv.append(rset) + + # Scan Settings + options = ["CO: During Rx", "TO: Timed", "SE: Halt"] + rx = RadioSettingValueList(options, options[_sets.scanmode]) + rset = RadioSetting("setstuf.scanmode", + "Scan Mode (Scan Pauses When)", rx) + scn.append(rset) + + options = ["100", "150", "200", "250", + "300", "350", "400", "450"] + rx = RadioSettingValueList(options, options[_sets.scanspeed]) + rset = RadioSetting("setstuf.scanspeed", "Scan Speed (ms)", rx) + scn.append(rset) + + val = _sets.scantmo + 3 + rx = RadioSettingValueInteger(3, 30, val) + rset = RadioSetting("setstuf.scantmo", + "TO Mode Timeout (secs)", rx) + rset.set_apply_callback(my_adjraw, _sets, "scantmo", -3) + scn.append(rset) + + val = _sets.prichan + if val <= 0: + val = 0 + rx = RadioSettingValueInteger(0, 128, val) + rset = RadioSetting("setstuf.prichan", "Priority Channel (0=OFF)", rx) + scn.append(rset) + + # FM Broadcast Settings + val = _fmx.fmcur + val = val / 40.0 + if val < 87.5 or val > 107.9: + val = 88.0 + rx = RadioSettingValueFloat(87.5, 107.9, val, 0.1, 1) + rset = RadioSetting("fmfrqs.fmcur", "Manual FM Freq (MHz)", rx) + rset.set_apply_callback(myset_freq, _fmx, "fmcur", 40) + fmb.append(rset) + + options = ["5", "50", "100", "200(USA)"] # 5 is not used + rx = RadioSettingValueList(options, options[_sets.fmstep]) + rset = RadioSetting("setstuf.fmstep", "FM Freq Step (KHz)", rx) + fmb.append(rset) + + # FM Scan Range fmsclo and fmschi are unknown memory locations, + # Not supported at this time + + rx = RadioSettingValueBoolean(bool(_sets.rxinhib)) + rset = RadioSetting("setstuf.rxinhib", + "Rcvr Will Interupt FM (DW)", rx) + fmb.append(rset) + + _fmfrq = self._memobj.fm_stations + _fmap = self._memobj.fmmap + for j in range(0, 25): + val = _fmfrq[j].rxfreq + if val == 0xFFFF: + val = 88.0 + fmset = False + else: + val = (float(int(val)) / 40) + # get fmmap bit value: 0 = enabled + ndx = int(math.floor((j) / 8)) + bv = j % 8 + msk = 1 << bv + vx = _fmap.fmset[ndx] + fmset = not bool(vx & msk) + rx = RadioSettingValueBoolean(fmset) + rset = RadioSetting("fmmap.fmset/%d" % j, + "FM Preset %02d" % (j + 1), rx) + rset.set_apply_callback(myset_mask, _fmap, "fmset", j) + fmb.append(rset) + + rx = RadioSettingValueFloat(87.5, 107.9, val, 0.1, 1) + rset = RadioSetting("fm_stations/%d.rxfreq" % j, + " Preset %02d Freq" % (j + 1), rx) + # This callback uses the array index + rset.set_apply_callback(myset_fmfrq, _fmfrq, "rxfreq", j) + fmb.append(rset) + + # DTMF Settings + options = [str(x) for x in range(4, 16)] + rx = RadioSettingValueList(options, options[_sets.dtmfspd]) + rset = RadioSetting("setstuf.dtmfspd", + "Tx Speed (digits/sec)", rx) + dtmf.append(rset) + + options = [str(x) for x in range(0, 1100, 100)] + rx = RadioSettingValueList(options, options[_sets.dtmfdig1time]) + rset = RadioSetting("setstuf.dtmfdig1time", + "Tx 1st Digit Time (ms)", rx) + dtmf.append(rset) + + options = [str(x) for x in range(100, 1100, 100)] + rx = RadioSettingValueList(options, options[_sets.dtmfdig1dly]) + rset = RadioSetting("setstuf.dtmfdig1dly", + "Tx 1st Digit Delay (ms)", rx) + dtmf.append(rset) + + options = ["0", "100", "500", "1000"] + rx = RadioSettingValueList(options, options[_sets.dtmfspms]) + rset = RadioSetting("setstuf.dtmfspms", + "Tx Star & Pound Time (ms)", rx) + dtmf.append(rset) + + options = ["None"] + [str(x) for x in range(600, 2100, 100)] + rx = RadioSettingValueList(options, options[_sets.codespctim]) + rset = RadioSetting("setstuf.codespctim", + "Tx Code Space Time (ms)", rx) + dtmf.append(rset) + + rx = RadioSettingValueBoolean(bool(_sets.codeabcd)) + rset = RadioSetting("setstuf.codeabcd", "Tx Codes A,B,C,D", rx) + dtmf.append(rset) + + rx = RadioSettingValueBoolean(bool(_sets.dtmfside)) + rset = RadioSetting("setstuf.dtmfside", "DTMF Side Tone", rx) + dtmf.append(rset) + + options = ["Off", "A", "B", "C", "D"] + rx = RadioSettingValueList(options, options[_sets.grpcode]) + rset = RadioSetting("setstuf.grpcode", "Rx Group Code", rx) + dtmf.append(rset) + + options = ["Off"] + [str(x) for x in range(1, 16)] + rx = RadioSettingValueList(options, options[_sets.autoresettmo]) + rset = RadioSetting("setstuf.autoresettmo", + "Rx Auto Reset Timeout (secs)", rx) + dtmf.append(rset) + + rx = RadioSettingValueBoolean(bool(_sets.txdecode)) + rset = RadioSetting("setstuf.txdecode", "Tx Decode", rx) + dtmf.append(rset) + + rx = RadioSettingValueBoolean(bool(_sets.idedit)) + rset = RadioSetting("setstuf.idedit", "Allow ANI Code Edit", rx) + dtmf.append(rset) + + options = [str(x) for x in range(500, 1600, 100)] + rx = RadioSettingValueList(options, options[_sets.decodetmo]) + rset = RadioSetting("setstuf.decodetmo", + "Rx Decode Timeout (ms)", rx) + dtmf.append(rset) + + options = ["Tx & Rx Inhibit", "Tx Inhibit"] + rx = RadioSettingValueList(options, options[_sets.stuntype]) + rset = RadioSetting("setstuf.stuntype", "Stun Type", rx) + dtmf.append(rset) + + sx = unpack_str(_sets.stuncode, _sets.stuncnt, 5) + rx = RadioSettingValueString(0, 10, sx) + rset = RadioSetting("setstuf.stuncode", "Stun Code", rx) + rset.set_apply_callback(pack_chars, _sets, + "stuncode", "stuncnt", 10) + dtmf.append(rset) + + # Frequency ranges + rx = RadioSettingValueBoolean(bool(_sets.frqr1)) + rset = RadioSetting("setstuf.frqr1", "Freq Range 1 (UHF)", rx) + rset.set_doc("Enable the UHF frequency bank.") + frng.append(rset) + + rx = RadioSettingValueBoolean(bool(_sets.frqr2)) + rset = RadioSetting("setstuf.frqr2", "Freq Range 2 (VHF)", rx) + rset.set_doc("Enable the VHF frequency bank.") + frng.append(rset) + + mod_se = True # UV8000SE has 3rd freq bank + if mod_se: + rx = RadioSettingValueBoolean(bool(_sets.frqr3)) + rset = RadioSetting("setstuf.frqr3", "Freq Range 3 (220Mhz)", rx) + rset.set_doc("Enable the 220MHz frequency bank.") + frng.append(rset) + + frqm = 100000 + val = _sets.frqr1lo / frqm + rx = RadioSettingValueFloat(400.0, 520.0, val, 0.005, 3) + rset = RadioSetting("setstuf.frqr1lo", + "UHF Range Low Limit (MHz)", rx) + rset.set_apply_callback(myset_freq, _sets, "frqr1lo", frqm) + rset.set_doc("Low limit of the UHF frequency bank.") + frng.append(rset) + + val = _sets.frqr1hi / frqm + rx = RadioSettingValueFloat(400.0, 520.0, val, 0.005, 3) + rset = RadioSetting("setstuf.frqr1hi", + "UHF Range High Limit (MHz)", rx) + rset.set_apply_callback(myset_freq, _sets, "frqr1hi", frqm) + rset.set_doc("High limit of the UHF frequency bank.") + frng.append(rset) + + val = _sets.frqr2lo / frqm + rx = RadioSettingValueFloat(136.0, 174.0, val, 0.005, 3) + rset = RadioSetting("setstuf.frqr2lo", + "VHF Range Low Limit (MHz)", rx) + rset.set_apply_callback(myset_freq, _sets, "frqr2lo", frqm) + rset.set_doc("Low limit of the VHF frequency bank.") + frng.append(rset) + + val = _sets.frqr2hi / frqm + rx = RadioSettingValueFloat(136.0, 174.0, val, 0.005, 3) + rset = RadioSetting("setstuf.frqr2hi", + "VHF Range High Limit (MHz)", rx) + rset.set_apply_callback(myset_freq, _sets, "frqr2hi", frqm) + rset.set_doc("High limit of the VHF frequency bank.") + frng.append(rset) + + if mod_se: + val = _sets.frqr3lo / frqm + if val < 220.0: + val = 220.0 + rx = RadioSettingValueFloat(220.0, 260.0, val, 0.005, 3) + rset = RadioSetting("setstuf.frqr3lo", + "1.25m Range Low Limit (MHz)", rx) + rset.set_apply_callback(myset_freq, _sets, "frqr3lo", frqm) + frng.append(rset) + + val = _sets.frqr3hi / frqm + if val < 220.0: + val = 260.0 + rx = RadioSettingValueFloat(220.0, 260.0, val, 0.005, 3) + rset = RadioSetting("setstuf.frqr3hi", + "1.25m Range High Limit (MHz)", rx) + rset.set_apply_callback(myset_freq, _sets, "frqr3hi", 1000) + frng.append(rset) + + return group # END get_settings() + + def set_settings(self, settings): + _settings = self._memobj.setstuf + _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 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