# Copyright 2022 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 . import struct import logging from chirp import chirp_common, directory, memmap from chirp import bitwise, errors, util from chirp import bandplan_na from chirp.settings import RadioSetting, RadioSettingGroup, \ RadioSettingValueInteger, RadioSettingValueList, \ RadioSettingValueBoolean, RadioSettings LOG = logging.getLogger(__name__) MEM_FORMAT = """ struct memory { u32 rxfreq; // 00-03 u16 decQT; // 04-05 u32 txfreq; // 06-09 u16 encQT; // 0a-0b u8 lowpower:1, // Power Level // 0c unknown1:1, isnarrow:1, // Bandwidth bcl:2, // Busy Channel Lockout scan:1, // Scan Add encode:1, // Encode unknown2:1; u8 unknown3[3]; // 0d-0f }; #seekto 0x0170; struct memory channels[99]; #seekto 0x0162; struct { u8 unknown_1:1, // 0x0162 voice:2, // Voice Prompt beep:1, // Beep Switch unknown_2:1, vox:1, // VOX autolock:1, // Auto Lock vibrate:1; // Vibrate Switch u8 squelch:4, // 0x0163 SQ Level unknown_3:1, volume:3; // Volume Level u8 voxl:4, // 0x0164 VOX Level voxd:4; // VOX Delay u8 unknown_5:1, // 0x0165 save:3, // Power Save calltone:4; // Call Tone u8 unknown_6:4, // 0x0166 roger:2, // Roger Tone backlight:2; // Backlight Set u16 tot; // 0x0167-0x0168 Time-out Timer u8 unknown_7[3]; // 0x0169-0x016B u8 skeyul; // 0x016C Side Key Up Long u8 skeyus; // 0x016D Side Key Up Short u8 skeydl; // 0x016E Side Key Down Long u8 skeyds; // 0x016F Side Key Down Short } settings; """ CMD_ACK = b"\x06" RB15_DTCS = tuple(sorted(chirp_common.DTCS_CODES + (645,))) LIST_BACKLIGHT = ["Off", "On", "Auto"] LIST_BCL = ["None", "Carrier", "QT/DQT Match"] LIST_ROGER = ["Off", "Start", "End", "Start and End"] LIST_SAVE = ["Off", "1:1", "1:2", "1:3", "1:4", "1:5"] _STEP_LIST = [2.5, 5., 6.25, 10., 12.5, 20., 25., 50.] LIST_VOICE = ["Off", "Chinese", "English"] LIST_VOXD = ["0.0", "0.5", "1.0", "1.5", "2.0", "2.5", "3.0", "3.5", "4.0", "4.5", "5.0S"] SKEY_CHOICES = ["None", "Scan", "Monitor", "VOX On/Off", "Local Alarm", "Remote Alarm", "Backlight On/Off", "Call Tone"] SKEY_VALUES = [0x00, 0x01, 0x03, 0x04, 0x09, 0x0A, 0x13, 0x14] TOT_CHOICES = ["Off", "15", "30", "45", "60", "75", "90", "105", "120", "135", "150", "165", "180", "195", "210", "225", "240", "255", "270", "285", "300", "315", "330", "345", "360", "375", "390", "405", "420", "435", "450", "465", "480", "495", "510", "525", "540", "555", "570", "585", "600" ] TOT_VALUES = [0x00, 0x0F, 0x1E, 0x2D, 0x3C, 0x4B, 0x5A, 0x69, 0x78, 0x87, 0x96, 0xA5, 0xB4, 0xC3, 0xD2, 0xE1, 0xF0, 0xFF, 0x10E, 0x11D, 0x12C, 0x13B, 0x14A, 0x159, 0x168, 0x177, 0x186, 0x195, 0x1A4, 0x1B3, 0x1C2, 0x1D1, 0x1E0, 0x1EF, 0x1FE, 0x20D, 0x21C, 0x22B, 0x23A, 0x249, 0x258 ] def _checksum(data): cs = 0 for byte in data: cs += byte return cs % 256 def tone2short(t): """Convert a string tone or DCS to an encoded u16 """ tone = str(t) if tone == "----": u16tone = 0x0000 elif tone[0] == 'D': # This is a DCS code c = tone[1: -1] code = int(c, 8) if tone[-1] == 'I': code |= 0x4000 u16tone = code | 0x8000 else: # This is an analog CTCSS u16tone = int(tone[0:-2]+tone[-1]) & 0xffff # strip the '.' return u16tone def short2tone(tone): """ Map a binary CTCSS/DCS to a string name for the tone """ if tone == 0 or tone == 0xffff: ret = "----" else: code = tone & 0x3fff if tone & 0x4000: # This is a DCS ret = "D%0.3oN" % code elif tone & 0x8000: # This is an inverse code ret = "D%0.3oI" % code else: # Just plain old analog CTCSS ret = "%4.1f" % (code / 10.0) return ret def _rb15_enter_programming_mode(radio): serial = radio.pipe # lengthen the timeout here as these radios are resetting due to timeout radio.pipe.timeout = 0.75 exito = False for i in range(0, 5): serial.write(radio.magic) ack = serial.read(1) try: if ack == CMD_ACK: exito = True break except: LOG.debug("Attempt #%s, failed, trying again" % i) pass # return timeout to default value radio.pipe.timeout = 0.25 # check if we had EXITO if exito is False: msg = "The radio did not accept program mode after five tries.\n" msg += "Check you interface cable and power cycle your radio." raise errors.RadioError(msg) def _rb15_exit_programming_mode(radio): serial = radio.pipe try: serial.write(b"21" + b"\x05\xEE" + b"V") except: raise errors.RadioError("Radio refused to exit programming mode") def _rb15_read_block(radio, block_addr, block_size): serial = radio.pipe cmd = struct.pack(">BH", ord(b'R'), block_addr) ccs = bytes([_checksum(cmd)]) expectedresponse = b"R" + cmd[1:] cmd = cmd + ccs LOG.debug("Reading block %04x..." % (block_addr)) try: serial.write(cmd) response = serial.read(3 + block_size + 1) cs = bytes([_checksum(response[:-1])]) if response[:3] != expectedresponse: raise Exception("Error reading block %04x." % (block_addr)) chunk = response[3:] if chunk[-1:] != cs: raise Exception("Block failed checksum!") block_data = chunk[:-1] except: raise errors.RadioError("Failed to read block at %04x" % block_addr) return block_data def _rb15_write_block(radio, block_addr, block_size): serial = radio.pipe cmd = struct.pack(">BH", ord(b'W'), block_addr) data = radio.get_mmap()[block_addr:block_addr + block_size] cs = bytes([_checksum(cmd + data)]) data += cs LOG.debug("Writing Data:") LOG.debug(util.hexprint(cmd + data)) try: serial.write(cmd + data) if serial.read(1) != CMD_ACK: raise Exception("No ACK") except: raise errors.RadioError("Failed to send block " "to radio at %04x" % block_addr) def do_download(radio): LOG.debug("download") _rb15_enter_programming_mode(radio) data = b"" status = chirp_common.Status() status.msg = "Cloning from radio" status.cur = 0 status.max = radio._memsize for addr in range(0x0000, radio._memsize, radio.BLOCK_SIZE): status.cur = addr + radio.BLOCK_SIZE radio.status_fn(status) block = _rb15_read_block(radio, addr, radio.BLOCK_SIZE) data += block LOG.debug("Address: %04x" % addr) LOG.debug(util.hexprint(block)) _rb15_exit_programming_mode(radio) return memmap.MemoryMapBytes(data) def do_upload(radio): status = chirp_common.Status() status.msg = "Uploading to radio" _rb15_enter_programming_mode(radio) status.cur = 0 status.max = radio._memsize for start_addr, end_addr in radio._ranges: for addr in range(start_addr, end_addr, radio.BLOCK_SIZE): status.cur = addr + radio.BLOCK_SIZE radio.status_fn(status) _rb15_write_block(radio, addr, radio.BLOCK_SIZE) _rb15_exit_programming_mode(radio) def _split(rf, f1, f2): """Returns False if the two freqs are in the same band (no split) or True otherwise""" # determine if the two freqs are in the same band for low, high in rf.valid_bands: if f1 >= low and f1 <= high and \ f2 >= low and f2 <= high: # if the two freqs are on the same Band this is not a split return False # if you get here is because the freq pairs are split return True class RB15RadioBase(chirp_common.CloneModeRadio): """RETEVIS RB15 BASE""" VENDOR = "Retevis" BAUD_RATE = 9600 NEEDS_COMPAT_SERIAL = False BLOCK_SIZE = 0x10 magic = b"21" + b"\x05\x10" + b"x" VALID_BANDS = [(400000000, 520000000)] _ranges = [ (0x0150, 0x07A0), ] _memsize = 0x07A0 _frs = _pmr = False def get_features(self): rf = chirp_common.RadioFeatures() rf.has_settings = True rf.has_bank = False rf.has_ctone = True rf.has_cross = True rf.has_rx_dtcs = True rf.has_tuning_step = False rf.can_odd_split = True rf.has_name = False rf.valid_skips = ["", "S"] rf.valid_tmodes = ["", "Tone", "TSQL", "DTCS", "Cross"] rf.valid_cross_modes = ["Tone->Tone", "Tone->DTCS", "DTCS->Tone", "->Tone", "->DTCS", "DTCS->", "DTCS->DTCS"] rf.valid_power_levels = self.POWER_LEVELS rf.valid_duplexes = ["", "-", "+", "split", "off"] rf.valid_modes = ["FM", "NFM"] # 25 kHz, 12.5 kHz. rf.valid_dtcs_codes = RB15_DTCS rf.memory_bounds = (1, self._upper) rf.valid_tuning_steps = _STEP_LIST rf.valid_bands = self.VALID_BANDS return rf def process_mmap(self): self._memobj = bitwise.parse(MEM_FORMAT, self._mmap) def sync_in(self): """Download from radio""" try: data = do_download(self) except errors.RadioError: # Pass through any real errors we raise raise except: # If anything unexpected happens, make sure we raise # a RadioError and log the problem LOG.exception('Unexpected error during download') raise errors.RadioError('Unexpected error communicating ' 'with the radio') self._mmap = data self.process_mmap() def sync_out(self): """Upload to radio""" try: do_upload(self) except: # If anything unexpected happens, make sure we raise # a RadioError and log the problem LOG.exception('Unexpected error during upload') raise errors.RadioError('Unexpected error communicating ' 'with the radio') def get_raw_memory(self, number): return repr(self._memobj.memory[number - 1]) def _get_tone(self, _mem, mem): """Decode both the encode and decode CTSS/DCS codes from the memory channel and stuff them into the UI memory channel row. """ txtone = short2tone(_mem.encQT) rxtone = short2tone(_mem.decQT) pt = "N" pr = "N" if txtone == "----": txmode = "" elif txtone[0] == "D": mem.dtcs = int(txtone[1:4]) if txtone[4] == "I": pt = "R" txmode = "DTCS" else: mem.rtone = float(txtone) txmode = "Tone" if rxtone == "----": rxmode = "" elif rxtone[0] == "D": mem.rx_dtcs = int(rxtone[1:4]) if rxtone[4] == "I": pr = "R" rxmode = "DTCS" else: mem.ctone = float(rxtone) rxmode = "Tone" if txmode == "Tone" and len(rxmode) == 0: 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 (len(rxmode) + len(txmode)) > 0: mem.tmode = "Cross" mem.cross_mode = "%s->%s" % (txmode, rxmode) mem.dtcs_polarity = pt + pr LOG.debug("_get_tone: Got TX %s (%i) RX %s (%i)" % (txmode, _mem.encQT, rxmode, _mem.decQT)) def _set_tone(self, mem, _mem): """Update the memory channel block CTCC/DCS tones from the UI fields """ def _set_dcs(code, pol): val = int("%i" % code, 8) | 0x4000 if pol == "R": val = int("%i" % code, 8) | 0x8000 return val rx_mode = tx_mode = None rxtone = txtone = 0x0000 if mem.tmode == "Tone": tx_mode = "Tone" txtone = int(mem.rtone * 10) elif mem.tmode == "TSQL": rx_mode = tx_mode = "Tone" rxtone = txtone = int(mem.ctone * 10) elif mem.tmode == "DTCS": tx_mode = rx_mode = "DTCS" txtone = _set_dcs(mem.dtcs, mem.dtcs_polarity[0]) rxtone = _set_dcs(mem.dtcs, mem.dtcs_polarity[1]) elif mem.tmode == "Cross": tx_mode, rx_mode = mem.cross_mode.split("->") if tx_mode == "DTCS": txtone = _set_dcs(mem.dtcs, mem.dtcs_polarity[0]) elif tx_mode == "Tone": txtone = int(mem.rtone * 10) if rx_mode == "DTCS": rxtone = _set_dcs(mem.rx_dtcs, mem.dtcs_polarity[1]) elif rx_mode == "Tone": rxtone = int(mem.ctone * 10) _mem.decQT = rxtone _mem.encQT = txtone LOG.debug("Set TX %s (%i) RX %s (%i)" % (tx_mode, _mem.encQT, rx_mode, _mem.decQT)) def get_memory(self, number): mem = chirp_common.Memory() _mem = self._memobj.channels[number - 1] mem.number = number mem.freq = int(_mem.rxfreq) * 10 # We'll consider any blank (i.e. 0 MHz frequency) to be empty if mem.freq == 0: mem.empty = True return mem if _mem.rxfreq.get_raw() == "\xFF\xFF\xFF\xFF": mem.freq = 0 mem.empty = True return mem if _mem.get_raw() == ("\xFF" * 16): LOG.debug("Initializing empty memory") _mem.set_raw("\x00" * 16) # Freq and offset mem.freq = int(_mem.rxfreq) * 10 # tx freq can be blank if _mem.get_raw()[4] == "\xFF": # TX freq not set mem.offset = 0 mem.duplex = "off" else: # TX freq set offset = (int(_mem.txfreq) * 10) - mem.freq if offset != 0: if _split(self.get_features(), mem.freq, int( _mem.txfreq) * 10): mem.duplex = "split" mem.offset = int(_mem.txfreq) * 10 elif offset < 0: mem.offset = abs(offset) mem.duplex = "-" elif offset > 0: mem.offset = offset mem.duplex = "+" else: mem.offset = 0 mem.mode = _mem.isnarrow and "NFM" or "FM" self._get_tone(_mem, mem) mem.power = self.POWER_LEVELS[_mem.lowpower] if not _mem.scan: mem.skip = "S" mem.extra = RadioSettingGroup("Extra", "extra") if _mem.bcl > 0x02: val = 0 else: val = _mem.bcl rs = RadioSetting("bcl", "BCL", RadioSettingValueList( LIST_BCL, LIST_BCL[val])) mem.extra.append(rs) rs = RadioSetting("encode", "Encode", RadioSettingValueBoolean(_mem.encode)) mem.extra.append(rs) return mem def set_memory(self, mem): LOG.debug("Setting %i(%s)" % (mem.number, mem.extd_number)) _mem = self._memobj.channels[mem.number - 1] # if empty memory if mem.empty: _mem.set_raw("\xFF" * 8 + "\x00" * 5 + "\xFF" * 3) return _mem.rxfreq = mem.freq / 10 if mem.duplex == "off": for i in range(0, 4): _mem.txfreq[i].set_raw("\xFF") elif mem.duplex == "split": _mem.txfreq = mem.offset / 10 elif mem.duplex == "+": _mem.txfreq = (mem.freq + mem.offset) / 10 elif mem.duplex == "-": _mem.txfreq = (mem.freq - mem.offset) / 10 else: _mem.txfreq = mem.freq / 10 _mem.scan = mem.skip != "S" _mem.isnarrow = mem.mode == "NFM" self._set_tone(mem, _mem) _mem.lowpower = mem.power == self.POWER_LEVELS[1] for setting in mem.extra: setattr(_mem, setting.get_name(), setting.value) def get_settings(self): _settings = self._memobj.settings basic = RadioSettingGroup("basic", "Basic Settings") sidekey = RadioSettingGroup("sidekey", "Side Key Settings") voxset = RadioSettingGroup("vox", "VOX Settings") top = RadioSettings(basic, sidekey, voxset) voice = RadioSetting("voice", "Language", RadioSettingValueList( LIST_VOICE, LIST_VOICE[_settings.voice])) basic.append(voice) beep = RadioSetting("beep", "Key Beep", RadioSettingValueBoolean(_settings.beep)) basic.append(beep) volume = RadioSetting("volume", "Volume Level", RadioSettingValueInteger( 0, 7, _settings.volume)) basic.append(volume) save = RadioSetting("save", "Battery Save", RadioSettingValueList( LIST_SAVE, LIST_SAVE[_settings.save])) basic.append(save) backlight = RadioSetting("backlight", "Backlight", RadioSettingValueList( LIST_BACKLIGHT, LIST_BACKLIGHT[_settings.backlight])) basic.append(backlight) vibrate = RadioSetting("vibrate", "Vibrate", RadioSettingValueBoolean(_settings.vibrate)) basic.append(vibrate) autolock = RadioSetting("autolock", "Auto Lock", RadioSettingValueBoolean(_settings.autolock)) basic.append(autolock) calltone = RadioSetting("calltone", "Call Tone", RadioSettingValueInteger( 1, 10, _settings.calltone)) basic.append(calltone) roger = RadioSetting("roger", "Roger Tone", RadioSettingValueList( LIST_ROGER, LIST_ROGER[_settings.roger])) basic.append(roger) squelch = RadioSetting("squelch", "Squelch Level", RadioSettingValueInteger( 0, 10, _settings.squelch)) basic.append(squelch) def apply_tot_listvalue(setting, obj): LOG.debug("Setting value: " + str( setting.value) + " from list") val = str(setting.value) index = TOT_CHOICES.index(val) val = TOT_VALUES[index] obj.set_value(val) if _settings.tot in TOT_VALUES: idx = TOT_VALUES.index(_settings.tot) else: idx = TOT_VALUES.index(0x78) rs = RadioSettingValueList(TOT_CHOICES, TOT_CHOICES[idx]) rset = RadioSetting("tot", "Time-out Timer", rs) rset.set_apply_callback(apply_tot_listvalue, _settings.tot) basic.append(rset) # Side Key Settings def apply_skey_listvalue(setting, obj): LOG.debug("Setting value: " + str( setting.value) + " from list") val = str(setting.value) index = SKEY_CHOICES.index(val) val = SKEY_VALUES[index] obj.set_value(val) # Side Key (Upper) - Short Press if _settings.skeyus in SKEY_VALUES: idx = SKEY_VALUES.index(_settings.skeyus) else: idx = SKEY_VALUES.index(0x01) rs = RadioSettingValueList(SKEY_CHOICES, SKEY_CHOICES[idx]) rset = RadioSetting("skeyus", "Side Key(upper) - Short Press", rs) rset.set_apply_callback(apply_skey_listvalue, _settings.skeyus) sidekey.append(rset) # Side Key (Upper) - Long Press if _settings.skeyul in SKEY_VALUES: idx = SKEY_VALUES.index(_settings.skeyul) else: idx = SKEY_VALUES.index(0x04) rs = RadioSettingValueList(SKEY_CHOICES, SKEY_CHOICES[idx]) rset = RadioSetting("skeyul", "Side Key(upper) - Long Press", rs) rset.set_apply_callback(apply_skey_listvalue, _settings.skeyul) sidekey.append(rset) # Side Key (Lower) - Short Press if _settings.skeyds in SKEY_VALUES: idx = SKEY_VALUES.index(_settings.skeyds) else: idx = SKEY_VALUES.index(0x03) rs = RadioSettingValueList(SKEY_CHOICES, SKEY_CHOICES[idx]) rset = RadioSetting("skeyds", "Side Key(lower) - Short Press", rs) rset.set_apply_callback(apply_skey_listvalue, _settings.skeyds) sidekey.append(rset) # Side Key (Lower) - Long Press if _settings.skeyul in SKEY_VALUES: idx = SKEY_VALUES.index(_settings.skeydl) else: idx = SKEY_VALUES.index(0x14) rs = RadioSettingValueList(SKEY_CHOICES, SKEY_CHOICES[idx]) rset = RadioSetting("skeydl", "Side Key(lower) - Long Press", rs) rset.set_apply_callback(apply_skey_listvalue, _settings.skeydl) sidekey.append(rset) # VOX Settings vox = RadioSetting("vox", "VOX", RadioSettingValueBoolean(_settings.vox)) voxset.append(vox) voxl = RadioSetting("voxl", "VOX Level", RadioSettingValueInteger( 0, 10, _settings.voxl)) voxset.append(voxl) voxd = RadioSetting("voxd", "VOX Delay (seconde)", RadioSettingValueList( LIST_VOXD, LIST_VOXD[_settings.voxd])) voxset.append(voxd) return top def set_settings(self, settings): for element in settings: if not isinstance(element, RadioSetting): self.set_settings(element) continue else: try: if "." in element.get_name(): bits = element.get_name().split(".") obj = self._memobj for bit in bits[:-1]: obj = getattr(obj, bit) setting = bits[-1] else: obj = self._memobj.settings setting = element.get_name() if element.has_apply_callback(): LOG.debug("Using apply callback") element.run_apply_callback() elif element.value.get_mutable(): LOG.debug("Setting %s = %s" % (setting, element.value)) setattr(obj, setting, element.value) except Exception: LOG.debug(element.get_name()) raise @classmethod def match_model(cls, filedata, filename): # This radio has always been post-metadata, so never do # old-school detection return False @directory.register class RB15Radio(RB15RadioBase): """RETEVIS RB15""" VENDOR = "Retevis" MODEL = "RB15" POWER_LEVELS = [chirp_common.PowerLevel("High", watts=2.00), chirp_common.PowerLevel("Low", watts=0.50)] _ranges = [ (0x0150, 0x07A0), ] _memsize = 0x07A0 _upper = 99 _frs = False # sold as FRS radio but supports full band TX/RX @directory.register class RB615RadioBase(RB15RadioBase): """RETEVIS RB615""" VENDOR = "Retevis" MODEL = "RB615" POWER_LEVELS = [chirp_common.PowerLevel("High", watts=2.00), chirp_common.PowerLevel("Low", watts=0.50)] _ranges = [ (0x0150, 0x07A0), ] _memsize = 0x07A0 _upper = 99 _pmr = False # sold as PMR radio but supports full band TX/RX