# Copyright 2016 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 time import os import struct import logging from chirp import chirp_common, directory, memmap from chirp import bitwise, errors, util from chirp.settings import RadioSetting, RadioSettingGroup, \ RadioSettingValueInteger, RadioSettingValueList, \ RadioSettingValueBoolean, RadioSettings, \ RadioSettingValueString LOG = logging.getLogger(__name__) MEM_FORMAT = """ #seekto 0x0010; struct { lbcd rxfreq[4]; lbcd txfreq[4]; ul16 rx_tone; ul16 tx_tone; u8 unknown1; u8 unknown3:2, highpower:1, // Power Level wide:1, // Bandwidth unknown4:4; u8 unknown5[2]; } memory[16]; #seekto 0x012F; struct { u8 voice; // Voice Annunciation u8 tot; // Time-out Timer u8 unknown1[3]; u8 squelch; // Squelch Level u8 save; // Battery Saver u8 beep; // Beep u8 unknown2[2]; u8 vox; // VOX u8 voxgain; // VOX Gain u8 voxdelay; // VOX Delay u8 unknown3[2]; u8 pf2key; // PF2 Key } settings; #seekto 0x017E; u8 skipflags[2]; // SCAN_ADD #seekto 0x0300; struct { char line1[32]; char line2[32]; } embedded_msg; """ CMD_ACK = "\x06" RT22_POWER_LEVELS = [chirp_common.PowerLevel("Low", watts=2.00), chirp_common.PowerLevel("High", watts=5.00)] RT22_DTCS = sorted(chirp_common.DTCS_CODES + [645]) PF2KEY_LIST = ["Scan", "Local Alarm", "Remote Alarm"] TIMEOUTTIMER_LIST = [""] + ["%s seconds" % x for x in range(15, 615, 15)] VOICE_LIST = ["Off", "Chinese", "English"] VOX_LIST = ["OFF"] + ["%s" % x for x in range(1, 17)] VOXDELAY_LIST = ["0.5", "1.0", "1.5", "2.0", "2.5", "3.0"] SETTING_LISTS = { "pf2key": PF2KEY_LIST, "tot": TIMEOUTTIMER_LIST, "voice": VOICE_LIST, "vox": VOX_LIST, "voxdelay": VOXDELAY_LIST, } VALID_CHARS = chirp_common.CHARSET_ALPHANUMERIC + \ "`{|}!\"#$%&'()*+,-./:;<=>?@[]^_" def _ident_from_data(data): return data[0x1B8:0x1C0] def _ident_from_image(radio): return _ident_from_data(radio.get_mmap()) def _rt22_enter_programming_mode(radio): serial = radio.pipe magic = "PROGRGS" exito = False for i in range(0, 5): for j in range(0, len(magic)): time.sleep(0.005) serial.write(magic[j]) ack = serial.read(1) try: if ack == CMD_ACK: exito = True break except: LOG.debug("Attempt #%s, failed, trying again" % i) pass # 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) try: serial.write("\x02") ident = serial.read(8) except: _rt22_exit_programming_mode(radio) raise errors.RadioError("Error communicating with radio") # check if ident is OK itis = False for fp in radio._fileid: if fp in ident: # got it! itis = True break if itis is False: LOG.debug("Incorrect model ID, got this:\n\n" + util.hexprint(ident)) raise errors.RadioError("Radio identification failed.") try: serial.write(CMD_ACK) ack = serial.read(1) except: _rt22_exit_programming_mode(radio) raise errors.RadioError("Error communicating with radio") if ack != CMD_ACK: _rt22_exit_programming_mode(radio) raise errors.RadioError("Radio refused to enter programming mode") try: serial.write("\x07") ack = serial.read(1) except: _rt22_exit_programming_mode(radio) raise errors.RadioError("Error communicating with radio") if ack != "\x4E": _rt22_exit_programming_mode(radio) raise errors.RadioError("Radio refused to enter programming mode") return ident def _rt22_exit_programming_mode(radio): serial = radio.pipe try: serial.write("E") except: raise errors.RadioError("Radio refused to exit programming mode") def _rt22_read_block(radio, block_addr, block_size): serial = radio.pipe cmd = struct.pack(">cHb", 'R', block_addr, block_size) expectedresponse = "W" + cmd[1:] LOG.debug("Reading block %04x..." % (block_addr)) try: for j in range(0, len(cmd)): time.sleep(0.005) serial.write(cmd[j]) response = serial.read(4 + block_size) if response[:4] != expectedresponse: _rt22_exit_programming_mode(radio) raise Exception("Error reading block %04x." % (block_addr)) block_data = response[4:] serial.write(CMD_ACK) ack = serial.read(1) except: _rt22_exit_programming_mode(radio) raise errors.RadioError("Failed to read block at %04x" % block_addr) if ack != CMD_ACK: _rt22_exit_programming_mode(radio) raise Exception("No ACK reading block %04x." % (block_addr)) return block_data def _rt22_write_block(radio, block_addr, block_size, _requires_patch, _patch_id): serial = radio.pipe cmd = struct.pack(">cHb", 'W', block_addr, block_size) # For some radios (RT-622 & RT22FRS) memory at 0x1b8 reads as 0, but # radio ID should be written instead if block_addr == 0x1b8 and _requires_patch: if _patch_id == "P3207!\xF8\xFF": data = _patch_id + "\x00" * 8 else: data = _patch_id + "\xFF" * 8 LOG.debug("Writing Patched Data:") LOG.debug(util.hexprint(cmd + data)) else: data = radio.get_mmap()[block_addr:block_addr + block_size] LOG.debug("Writing Data:") LOG.debug(util.hexprint(cmd + data)) try: for j in range(0, len(cmd)): time.sleep(0.005) serial.write(cmd[j]) for j in range(0, len(data)): time.sleep(0.005) serial.write(data[j]) if serial.read(1) != CMD_ACK: raise Exception("No ACK") except: _rt22_exit_programming_mode(radio) raise errors.RadioError("Failed to send block " "to radio at %04x" % block_addr) def do_download(radio): LOG.debug("download") _rt22_enter_programming_mode(radio) data = "" status = chirp_common.Status() status.msg = "Cloning from radio" status.cur = 0 status.max = radio._memsize for addr in range(0, radio._memsize, radio._block_size): status.cur = addr + radio._block_size radio.status_fn(status) block = _rt22_read_block(radio, addr, radio._block_size) data += block LOG.debug("Address: %04x" % addr) LOG.debug(util.hexprint(block)) data += radio.MODEL.ljust(8) _rt22_exit_programming_mode(radio) return memmap.MemoryMap(data) def do_upload(radio): status = chirp_common.Status() status.msg = "Uploading to radio" radio_ident = _rt22_enter_programming_mode(radio) LOG.info("Radio Ident is %s" % repr(radio_ident)) image_ident = _ident_from_image(radio) LOG.info("Image Ident is %s" % repr(image_ident)) if image_ident == "\x00\x00\x00\x00\x00\x00\xFF\xFF": patch_block = True else: patch_block = False LOG.debug("Writing Data:") LOG.debug(patch_block) status.cur = 0 status.max = radio._memsize for start_addr, end_addr, block_size in radio._ranges: for addr in range(start_addr, end_addr, block_size): status.cur = addr + block_size radio.status_fn(status) _rt22_write_block(radio, addr, block_size, patch_block, radio_ident) _rt22_exit_programming_mode(radio) def model_match(cls, data): """Match the opened/downloaded image to the correct version""" if len(data) == 0x0408: rid = data[0x0400:0x0408] return rid.startswith(cls.MODEL) else: return False @directory.register class RT22Radio(chirp_common.CloneModeRadio): """Retevis RT22""" VENDOR = "Retevis" MODEL = "RT22" BAUD_RATE = 9600 _ranges = [ (0x0000, 0x0180, 0x10), (0x01B8, 0x01F8, 0x10), (0x01F8, 0x0200, 0x08), (0x0200, 0x0340, 0x10), ] _memsize = 0x0400 _block_size = 0x40 _fileid = ["P32073", "P3" + "\x00\x00\x00" + "3", "P3207!"] 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 = RT22_POWER_LEVELS rf.valid_duplexes = ["", "-", "+", "split", "off"] rf.valid_modes = ["NFM", "FM"] # 12.5 KHz, 25 kHz. rf.memory_bounds = (1, 16) rf.valid_tuning_steps = [2.5, 5., 6.25, 10., 12.5, 25.] rf.valid_bands = [(400000000, 520000000)] 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): def _get_dcs(val): code = int("%03o" % (val & 0x07FF)) pol = (val & 0x8000) and "R" or "N" return code, pol if _mem.tx_tone != 0xFFFF and _mem.tx_tone > 0x2800: tcode, tpol = _get_dcs(_mem.tx_tone) mem.dtcs = tcode txmode = "DTCS" elif _mem.tx_tone != 0xFFFF: mem.rtone = _mem.tx_tone / 10.0 txmode = "Tone" else: txmode = "" if _mem.rx_tone != 0xFFFF and _mem.rx_tone > 0x2800: rcode, rpol = _get_dcs(_mem.rx_tone) mem.rx_dtcs = rcode rxmode = "DTCS" elif _mem.rx_tone != 0xFFFF: mem.ctone = _mem.rx_tone / 10.0 rxmode = "Tone" else: rxmode = "" 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) if mem.tmode == "DTCS": mem.dtcs_polarity = "%s%s" % (tpol, rpol) LOG.debug("Got TX %s (%i) RX %s (%i)" % (txmode, _mem.tx_tone, rxmode, _mem.rx_tone)) def get_memory(self, number): bitpos = (1 << ((number - 1) % 8)) bytepos = ((number - 1) / 8) LOG.debug("bitpos %s" % bitpos) LOG.debug("bytepos %s" % bytepos) _mem = self._memobj.memory[number - 1] _skp = self._memobj.skipflags[bytepos] mem = chirp_common.Memory() mem.number = number mem.freq = int(_mem.rxfreq) * 10 # We'll consider any blank (i.e. 0MHz 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 int(_mem.rxfreq) == int(_mem.txfreq): mem.duplex = "" mem.offset = 0 else: mem.duplex = int(_mem.rxfreq) > int(_mem.txfreq) and "-" or "+" mem.offset = abs(int(_mem.rxfreq) - int(_mem.txfreq)) * 10 mem.mode = _mem.wide and "FM" or "NFM" self._get_tone(_mem, mem) mem.power = RT22_POWER_LEVELS[_mem.highpower] mem.skip = "" if (_skp & bitpos) else "S" LOG.debug("mem.skip %s" % mem.skip) return mem def _set_tone(self, mem, _mem): def _set_dcs(code, pol): val = int("%i" % code, 8) + 0x2800 if pol == "R": val += 0x8000 return val rx_mode = tx_mode = None rx_tone = tx_tone = 0xFFFF if mem.tmode == "Tone": tx_mode = "Tone" rx_mode = None tx_tone = int(mem.rtone * 10) elif mem.tmode == "TSQL": rx_mode = tx_mode = "Tone" rx_tone = tx_tone = int(mem.ctone * 10) elif mem.tmode == "DTCS": tx_mode = rx_mode = "DTCS" tx_tone = _set_dcs(mem.dtcs, mem.dtcs_polarity[0]) rx_tone = _set_dcs(mem.dtcs, mem.dtcs_polarity[1]) elif mem.tmode == "Cross": tx_mode, rx_mode = mem.cross_mode.split("->") if tx_mode == "DTCS": tx_tone = _set_dcs(mem.dtcs, mem.dtcs_polarity[0]) elif tx_mode == "Tone": tx_tone = int(mem.rtone * 10) if rx_mode == "DTCS": rx_tone = _set_dcs(mem.rx_dtcs, mem.dtcs_polarity[1]) elif rx_mode == "Tone": rx_tone = int(mem.ctone * 10) _mem.rx_tone = rx_tone _mem.tx_tone = tx_tone LOG.debug("Set TX %s (%i) RX %s (%i)" % (tx_mode, _mem.tx_tone, rx_mode, _mem.rx_tone)) def set_memory(self, mem): bitpos = (1 << ((mem.number - 1) % 8)) bytepos = ((mem.number - 1) / 8) LOG.debug("bitpos %s" % bitpos) LOG.debug("bytepos %s" % bytepos) _mem = self._memobj.memory[mem.number - 1] _skp = self._memobj.skipflags[bytepos] if mem.empty: _mem.set_raw("\xFF" * (_mem.size() / 8)) 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.wide = mem.mode == "FM" self._set_tone(mem, _mem) _mem.highpower = mem.power == RT22_POWER_LEVELS[1] if mem.skip != "S": _skp |= bitpos else: _skp &= ~bitpos LOG.debug("_skp %s" % _skp) def get_settings(self): _settings = self._memobj.settings _message = self._memobj.embedded_msg basic = RadioSettingGroup("basic", "Basic Settings") top = RadioSettings(basic) rs = RadioSetting("squelch", "Squelch Level", RadioSettingValueInteger(0, 9, _settings.squelch)) basic.append(rs) rs = RadioSetting("tot", "Time-out timer", RadioSettingValueList( TIMEOUTTIMER_LIST, TIMEOUTTIMER_LIST[_settings.tot])) basic.append(rs) rs = RadioSetting("voice", "Voice Prompts", RadioSettingValueList( VOICE_LIST, VOICE_LIST[_settings.voice])) basic.append(rs) rs = RadioSetting("pf2key", "PF2 Key", RadioSettingValueList( PF2KEY_LIST, PF2KEY_LIST[_settings.pf2key])) basic.append(rs) rs = RadioSetting("vox", "Vox", RadioSettingValueBoolean(_settings.vox)) basic.append(rs) rs = RadioSetting("voxgain", "VOX Level", RadioSettingValueList( VOX_LIST, VOX_LIST[_settings.voxgain])) basic.append(rs) rs = RadioSetting("voxdelay", "VOX Delay Time", RadioSettingValueList( VOXDELAY_LIST, VOXDELAY_LIST[_settings.voxdelay])) basic.append(rs) rs = RadioSetting("save", "Battery Save", RadioSettingValueBoolean(_settings.save)) basic.append(rs) rs = RadioSetting("beep", "Beep", RadioSettingValueBoolean(_settings.beep)) basic.append(rs) def _filter(name): filtered = "" for char in str(name): if char in VALID_CHARS: filtered += char else: filtered += " " return filtered rs = RadioSetting("embedded_msg.line1", "Embedded Message 1", RadioSettingValueString(0, 32, _filter( _message.line1))) basic.append(rs) rs = RadioSetting("embedded_msg.line2", "Embedded Message 2", RadioSettingValueString(0, 32, _filter( _message.line2))) basic.append(rs) 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() LOG.debug("Setting %s = %s" % (setting, element.value)) setattr(obj, setting, element.value) except Exception, e: LOG.debug(element.get_name()) raise @classmethod def match_model(cls, filedata, filename): match_size = False match_model = False # testing the file data size if len(filedata) in [0x0408, ]: match_size = True # testing the model fingerprint match_model = model_match(cls, filedata) if match_size and match_model: return True else: return False @directory.register class KDC1(RT22Radio): """WLN KD-C1""" VENDOR = "WLN" MODEL = "KD-C1" @directory.register class ZTX6(RT22Radio): """Zastone ZT-X6""" VENDOR = "Zastone" MODEL = "ZT-X6" @directory.register class LT316(RT22Radio): """Luiton LT-316""" VENDOR = "LUITON" MODEL = "LT-316" @directory.register class TDM8(RT22Radio): VENDOR = "TID" MODEL = "TD-M8" @directory.register class RT622(RT22Radio): VENDOR = "Retevis" MODEL = "RT622"