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# Copyright 2018 Jim Lieb <lieb@sea-troll.net>
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#
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# Driver for Wouxon KG-UV9D Plus
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#
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# Borrowed from other chirp drivers, especially the KG-UV8D Plus
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# by Krystian Struzik <toner_82@tlen.pl>
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#
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# This program is free software: you can redistribute it and/or modify
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# it under the terms of the GNU General Public License as published by
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# the Free Software Foundation, either version 3 of the License, or
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# (at your option) any later version.
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#
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# This program is distributed in the hope that it will be useful,
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# but WITHOUT ANY WARRANTY; without even the implied warranty of
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# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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# GNU General Public License for more details.
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#
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# You should have received a copy of the GNU General Public License
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# along with this program. If not, see <http://www.gnu.org/licenses/>.
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"""Wouxun KG-UV9D Plus radio management module"""
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import time
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import os
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import logging
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import struct
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import string
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from chirp import util, chirp_common, bitwise, memmap, errors, directory
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from chirp.settings import RadioSetting, RadioSettingValue, \
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RadioSettingGroup, \
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RadioSettingValueBoolean, RadioSettingValueList, \
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RadioSettingValueInteger, RadioSettingValueString, \
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RadioSettings, RadioSettingValueMap, InvalidValueError
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LOG = logging.getLogger(__name__)
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CMD_IDENT = 0x80
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CMD_HANGUP = 0x81
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CMD_RCONF = 0x82
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CMD_WCONF = 0x83
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CMD_RCHAN = 0x84
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CMD_WCHAN = 0x85
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cmd_name = {
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CMD_IDENT: "ident",
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CMD_HANGUP: "hangup",
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CMD_RCONF: "read config",
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CMD_WCONF: "write config",
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CMD_RCHAN: "read channel memory", # Unused
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CMD_WCHAN: "write channel memory" # Unused because it is a hack.
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}
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# This is used to write the configuration of the radio base on info
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# gleaned from the downloaded app. There are empty spaces and we honor
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# them because we don't know what they are (yet) although we read the
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# whole of memory.
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#
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# Channel memory is separate. There are 1000 (1-999) channels.
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# These are read/written to the radio in 4 channel (96 byte)
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# records starting at address 0xa00 and ending at
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# 0x4800 (presuming the end of channel 1000 is 0x4860-1
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config_map = ( # map address, write size, write count
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(0x40, 16, 1), # Passwords
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(0x740, 40, 1), # FM chan 1-20
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(0x780, 16, 1), # vfo-b-150
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(0x790, 16, 1), # vfo-b-450
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(0x800, 16, 1), # vfo-a-150
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(0x810, 16, 1), # vfo-a-450
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(0x820, 16, 1), # vfo-a-300
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(0x830, 16, 1), # vfo-a-700
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(0x840, 16, 1), # vfo-a-200
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(0x860, 16, 1), # area-a-conf
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(0x870, 16, 1), # area-b-conf
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(0x880, 16, 1), # radio conf 0
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(0x890, 16, 1), # radio conf 1
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(0x8a0, 16, 1), # radio conf 2
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(0x8b0, 16, 1), # radio conf 3
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(0x8c0, 16, 1), # PTT-ANI
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(0x8d0, 16, 1), # SCC
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(0x8e0, 16, 1), # power save
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(0x8f0, 16, 1), # Display banner
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(0x940, 64, 2), # Scan groups and names
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(0xa00, 64, 249), # Memory Channels 1-996
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(0x4840, 48, 1), # Memory Channels 997-999
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(0x4900, 32, 249), # Memory Names 1-996
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(0x6820, 24, 1), # Memory Names 997-999
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(0x7400, 64, 5), # CALL-ID 1-20, names 1-20
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)
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MEM_VALID = 0xfc
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MEM_INVALID = 0xff
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# Radio memory map. This matches the reads/writes above.
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# structure elements whose name starts with x are currently unidentified
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_MEM_FORMAT02 = """
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#seekto 0x40;
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struct {
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char reset[6];
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char x46[2];
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char mode_sw[6];
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char x4e;
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} passwords;
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#seekto 0x740;
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struct {
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u16 fm_freq;
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} fm_chans[20];
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// each band has its own configuration, essentially its default params
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struct vfo {
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u32 freq;
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u32 offset;
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u16 encqt;
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u16 decqt;
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u8 bit7_4:3,
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qt:3,
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bit1_0:2;
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u8 bit7:1,
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scan:1,
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bit5:1,
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pwr:2,
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mod:1,
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fm_dev:2;
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u8 pad2:6,
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shift:2;
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u8 zeros;
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};
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#seekto 0x780;
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struct {
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struct vfo band_150;
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struct vfo band_450;
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} vfo_b;
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#seekto 0x800;
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struct {
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struct vfo band_150;
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struct vfo band_450;
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struct vfo band_300;
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struct vfo band_700;
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struct vfo band_200;
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} vfo_a;
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// There are two independent radios, aka areas (as described
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// in the manual as the upper and lower portions of the display...
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struct area_conf {
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u8 w_mode;
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u8 x861;
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u8 w_chan;
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u8 scan_grp;
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u8 bcl;
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u8 sql;
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u8 cset;
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u8 step;
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u8 scan_mode;
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u8 x869;
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u8 scan_range;
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u8 x86b;
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u8 x86c;
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u8 x86d;
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u8 x86e;
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u8 x86f;
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};
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#seekto 0x860;
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struct area_conf a_conf;
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#seekto 0x870;
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struct area_conf b_conf;
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#seekto 0x880;
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struct {
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u8 menu_avail;
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u8 reset_avail;
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u8 x882;
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u8 x883;
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u8 lang;
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u8 x885;
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u8 beep;
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u8 auto_am;
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u8 qt_sw;
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u8 lock;
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u8 x88a;
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u8 pf1;
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u8 pf2;
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u8 pf3;
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u8 s_mute;
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u8 type_set;
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u8 tot;
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u8 toa;
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u8 ptt_id;
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u8 x893;
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u8 id_dly;
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u8 x895;
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u8 voice_sw;
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u8 s_tone;
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u8 abr_lvl;
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u8 ring_time;
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u8 roger;
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u8 x89b;
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u8 abr;
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u8 save_m;
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u8 lock_m;
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u8 auto_lk;
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u8 rpt_ptt;
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u8 rpt_spk;
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u8 rpt_rct;
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u8 prich_sw;
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u16 pri_ch;
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u8 x8a6;
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u8 x8a7;
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u8 dtmf_st;
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u8 dtmf_tx;
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u8 x8aa;
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u8 sc_qt;
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u8 apo_tmr;
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u8 vox_grd;
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u8 vox_dly;
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u8 rpt_kpt;
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struct {
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u16 scan_st;
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u16 scan_end;
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} a;
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struct {
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u16 scan_st;
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u16 scan_end;
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} b;
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u8 x8b8;
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u8 x8b9;
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u8 x8ba;
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u8 ponmsg;
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u8 blcdsw;
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u8 bledsw;
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u8 x8be;
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u8 x8bf;
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} settings;
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#seekto 0x8c0;
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struct {
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u8 code[6];
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char x8c6[10];
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} my_callid;
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#seekto 0x8d0;
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struct {
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u8 scc[6];
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char x8d6[10];
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} stun;
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#seekto 0x8e0;
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struct {
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u16 wake;
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u16 sleep;
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} save[4];
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#seekto 0x8f0;
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struct {
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char banner[16];
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} display;
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#seekto 0x940;
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struct {
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struct {
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i16 scan_st;
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i16 scan_end;
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} addrs[10];
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u8 x0968[8];
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struct {
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char name[8];
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} names[10];
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} scn_grps;
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// this array of structs is marshalled via the R/WCHAN commands
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#seekto 0xa00;
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struct {
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u32 rxfreq;
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u32 txfreq;
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u16 encQT;
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u16 decQT;
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u8 bit7_5:3, // all ones
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qt:3,
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bit1_0:2;
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u8 bit7:1,
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scan:1,
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bit5:1,
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pwr:2,
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mod:1,
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fm_dev:2;
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u8 state;
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u8 c3;
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} chan_blk[999];
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// nobody really sees this. It is marshalled with chan_blk
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// in 4 entry chunks
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#seekto 0x4900;
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// Tracks with the index of chan_blk[]
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struct {
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char name[8];
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} chan_name[999];
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#seekto 0x7400;
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struct {
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u8 cid[6];
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u8 pad[2];
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}call_ids[20];
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// This array tracks with the index of call_ids[]
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struct {
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char name[6];
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char pad[2];
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} cid_names[20];
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"""
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# Support for the Wouxun KG-UV9D Plus radio
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# Serial coms are at 19200 baud
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# The data is passed in variable length records
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# Record structure:
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# Offset Usage
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# 0 start of record (\x7d)
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# 1 Command (6 commands, see above)
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# 2 direction (\xff PC-> Radio, \x00 Radio -> PC)
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# 3 length of payload (excluding header/checksum) (n)
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# 4 payload (n bytes)
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# 4+n+1 checksum - byte sum (% 256) of bytes 1 -> 4+n
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#
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# Memory Read Records:
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# the payload is 3 bytes, first 2 are offset (big endian),
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# 3rd is number of bytes to read
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# Memory Write Records:
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# the maximum payload size (from the Wouxun software)
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# seems to be 66 bytes (2 bytes location + 64 bytes data).
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def _pkt_encode(op, payload):
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"""Assemble a packet for the radio and encode it for transmission.
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Yes indeed, the checksum we store is only 4 bits. Why?
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I suspect it's a bug in the radio firmware guys didn't want to fix,
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i.e. a typo 0xff -> 0xf..."""
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data = bytearray()
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data.append(0x7d) # tag that marks the beginning of the packet
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data.append(op)
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data.append(0xff) # 0xff is from app to radio
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# calc checksum from op to end
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cksum = op + 0xff
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if (payload):
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data.append(len(payload))
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cksum += len(payload)
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for byte in payload:
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cksum += byte
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data.append(byte)
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else:
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data.append(0x00)
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# Yea, this is a 4 bit cksum (also known as a bug)
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data.append(cksum & 0xf)
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# now obfuscate by an xor starting with first payload byte ^ 0x52
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# including the trailing cksum.
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xorbits = 0x52
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for i, byte in enumerate(data[4:]):
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xord = xorbits ^ byte
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data[i + 4] = xord
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xorbits = xord
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return(data)
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def _pkt_decode(data):
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"""Take a packet hot off the wire and decode it into clear text
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and return the fields. We say <<cleartext>> here because all it
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turns out to be is annoying obfuscation.
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This is the inverse of pkt_decode"""
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# we don't care about data[0].
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# It is always 0x7d and not included in checksum
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op = data[1]
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direction = data[2]
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bytecount = data[3]
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# First un-obfuscate the payload and cksum
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payload = bytearray()
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xorbits = 0x52
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for i, byte in enumerate(data[4:]):
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payload.append(xorbits ^ byte)
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xorbits = byte
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# Calculate the checksum starting with the 3 bytes of the header
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cksum = op + direction + bytecount
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for byte in payload[:-1]:
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cksum += byte
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# yes, a 4 bit cksum to match the encode
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cksum_match = (cksum & 0xf) == payload[-1]
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if (not cksum_match):
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LOG.debug(
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"Checksum missmatch: %x != %x; " % (cksum, payload[-1]))
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return (cksum_match, op, payload[:-1])
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# UI callbacks to process input for mapping UI fields to memory cells
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def freq2int(val, min, max):
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"""Convert a frequency as a string to a u32. Units is Hz
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"""
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_freq = chirp_common.parse_freq(str(val))
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if _freq > max or _freq < min:
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raise InvalidValueError("Frequency %s is not with in %s-%s" %
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(chirp_common.format_freq(_freq),
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chirp_common.format_freq(min),
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chirp_common.format_freq(max)))
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return _freq
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def int2freq(freq):
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"""
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Convert a u32 frequency to a string for UI data entry/display
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This is stored in the radio as units of 10Hz which we compensate to Hz.
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A value of -1 indicates <no freqency>, i.e. unused channel.
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"""
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if (int(freq) > 0):
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f = chirp_common.format_freq(freq)
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return f
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else:
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return ""
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def freq2short(val, min, max):
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"""Convert a frequency as a string to a u16 which is units of 10KHz
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"""
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_freq = chirp_common.parse_freq(str(val))
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if _freq > max or _freq < min:
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raise InvalidValueError("Frequency %s is not with in %s-%s" %
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(chirp_common.format_freq(_freq),
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chirp_common.format_freq(min),
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chirp_common.format_freq(max)))
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return _freq/100000 & 0xFFFF
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def short2freq(freq):
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"""
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Convert a short frequency to a string for UI data entry/display
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This is stored in the radio as units of 10KHz which we
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compensate to Hz.
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A value of -1 indicates <no frequency>, i.e. unused channel.
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"""
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if (int(freq) > 0):
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f = chirp_common.format_freq(freq * 100000)
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return f
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else:
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return ""
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def tone2short(t):
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"""Convert a string tone or DCS to an encoded u16
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"""
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tone = str(t)
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if tone == "----":
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u16tone = 0x0000
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elif tone[0] == 'D': # This is a DCS code
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c = tone[1: -1]
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code = int(c, 8)
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if tone[-1] == 'I':
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code |= 0x4000
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u16tone = code | 0x8000
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else: # This is an analog CTCSS
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u16tone = int(tone[0:-2]+tone[-1]) & 0xffff # strip the '.'
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return u16tone
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def short2tone(tone):
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""" Map a binary CTCSS/DCS to a string name for the tone
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"""
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if tone == 0 or tone == 0xffff:
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ret = "----"
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else:
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code = tone & 0x3fff
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if tone & 0x8000: # This is a DCS
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if tone & 0x4000: # This is an inverse code
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ret = "D%0.3oI" % code
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else:
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ret = "D%0.3oN" % code
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else: # Just plain old analog CTCSS
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ret = "%4.1f" % (code / 10.0)
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return ret
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def callid2str(cid):
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"""Caller ID per MDC-1200 spec? Must be 3-6 digits (100 - 999999).
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One digit (binary) per byte, terminated with '0xc'
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"""
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bin2ascii = " 1234567890"
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cidstr = ""
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for i in range(0, 6):
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b = cid[i].get_value()
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if b == 0xc: # the cid EOL
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break
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if b == 0 or b > 0xa:
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raise InvalidValueError(
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"Caller ID code has illegal byte 0x%x" % b)
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cidstr += bin2ascii[b]
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return cidstr
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def str2callid(val):
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""" Convert caller id strings from callid2str.
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"""
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ascii2bin = "0123456789"
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s = str(val).strip()
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if len(s) < 3 or len(s) > 6:
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raise InvalidValueError(
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"Caller ID must be at least 3 and no more than 6 digits")
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if s[0] == '0':
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raise InvalidValueError(
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"First digit of a Caller ID cannot be a zero '0'")
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blk = bytearray()
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for c in s:
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if c not in ascii2bin:
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raise InvalidValueError(
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"Caller ID must be all digits 0x%x" % c)
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b = (0xa, 0x1, 0x2, 0x3, 0x4, 0x5, 0x6, 0x7, 0x8, 0x9)[int(c)]
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blk.append(b)
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if len(blk) < 6:
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blk.append(0xc) # EOL a short ID
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if len(blk) < 6:
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for i in range(0, (6 - len(blk))):
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blk.append(0xf0)
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return blk
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|
|
def digits2str(digits, padding=' ', width=6):
|
|
"""Convert a password or SCC digit string to a string
|
|
Passwords are expanded to and must be 6 chars. Fill them with '0'
|
|
"""
|
|
|
|
bin2ascii = "0123456789"
|
|
digitsstr = ""
|
|
for i in range(0, 6):
|
|
b = digits[i].get_value()
|
|
if b == 0xc: # the digits EOL
|
|
break
|
|
if b >= 0xa:
|
|
raise InvalidValueError(
|
|
"Value has illegal byte 0x%x" % ord(b))
|
|
digitsstr += bin2ascii[b]
|
|
digitsstr = digitsstr.ljust(width, padding)
|
|
return digitsstr
|
|
|
|
|
|
def str2digits(val):
|
|
""" Callback for edited strings from digits2str.
|
|
"""
|
|
ascii2bin = " 0123456789"
|
|
s = str(val).strip()
|
|
if len(s) < 3 or len(s) > 6:
|
|
raise InvalidValueError(
|
|
"Value must be at least 3 and no more than 6 digits")
|
|
blk = bytearray()
|
|
for c in s:
|
|
if c not in ascii2bin:
|
|
raise InvalidValueError("Value must be all digits 0x%x" % c)
|
|
blk.append(int(c))
|
|
for i in range(len(blk), 6):
|
|
blk.append(0xc) # EOL a short ID
|
|
return blk
|
|
|
|
|
|
def name2str(name):
|
|
""" Convert a callid or scan group name to a string
|
|
Deal with fixed field padding (\0 or \0xff)
|
|
"""
|
|
|
|
namestr = ""
|
|
for i in range(0, len(name)):
|
|
b = ord(name[i].get_value())
|
|
if b != 0 and b != 0xff:
|
|
namestr += chr(b)
|
|
return namestr
|
|
|
|
|
|
def str2name(val, size=6, fillchar='\0', emptyfill='\0'):
|
|
""" Convert a string to a name. A name is a 6 element bytearray
|
|
with ascii chars.
|
|
"""
|
|
val = str(val).rstrip(' \t\r\n\0\0xff')
|
|
if len(val) == 0:
|
|
name = "".ljust(size, emptyfill)
|
|
else:
|
|
name = val.ljust(size, fillchar)
|
|
return name
|
|
|
|
|
|
def pw2str(pw):
|
|
"""Convert a password string (6 digits) to a string
|
|
Passwords must be 6 digits. If it is shorter, pad right with '0'
|
|
"""
|
|
pwstr = ""
|
|
ascii2bin = "0123456789"
|
|
for i in range(0, len(pw)):
|
|
b = pw[i].get_value()
|
|
if b not in ascii2bin:
|
|
raise InvalidValueError("Value must be digits 0-9")
|
|
pwstr += b
|
|
pwstr = pwstr.ljust(6, '0')
|
|
return pwstr
|
|
|
|
|
|
def str2pw(val):
|
|
"""Store a password from UI to memory obj
|
|
If we clear the password (make it go away), change the
|
|
empty string to '000000' since the radio must have *something*
|
|
Also, fill a < 6 digit pw with 0's
|
|
"""
|
|
ascii2bin = "0123456789"
|
|
val = str(val).rstrip(' \t\r\n\0\0xff')
|
|
if len(val) == 0: # a null password
|
|
val = "000000"
|
|
for i in range(0, len(val)):
|
|
b = val[i]
|
|
if b not in ascii2bin:
|
|
raise InvalidValueError("Value must be digits 0-9")
|
|
if len(val) == 0:
|
|
pw = "".ljust(6, '\0')
|
|
else:
|
|
pw = val.ljust(6, '0')
|
|
return pw
|
|
|
|
|
|
# Helpers to replace python2 things like confused str/byte
|
|
|
|
def _hex_print(data, addrfmt=None):
|
|
"""Return a hexdump-like encoding of @data
|
|
We expect data to be a bytearray, not a string.
|
|
Expanded from borrowed code to use the first 2 bytes as the address
|
|
per comm packet format.
|
|
"""
|
|
if addrfmt is None:
|
|
addrfmt = '%(addr)03i'
|
|
addr = 0
|
|
else: # assume first 2 bytes are address
|
|
a = struct.unpack(">H", data[0:2])
|
|
addr = a[0]
|
|
data = data[2:]
|
|
|
|
block_size = 16
|
|
|
|
lines = (len(data) / block_size)
|
|
if (len(data) % block_size > 0):
|
|
lines += 1
|
|
|
|
out = ""
|
|
left = len(data)
|
|
for block in range(0, lines):
|
|
addr += block * block_size
|
|
try:
|
|
out += addrfmt % locals()
|
|
except (OverflowError, ValueError, TypeError, KeyError):
|
|
out += "%03i" % addr
|
|
out += ': '
|
|
|
|
if left < block_size:
|
|
limit = left
|
|
else:
|
|
limit = block_size
|
|
|
|
for j in range(0, block_size):
|
|
if (j < limit):
|
|
out += "%02x " % data[(block * block_size) + j]
|
|
else:
|
|
out += " "
|
|
|
|
out += " "
|
|
|
|
for j in range(0, block_size):
|
|
|
|
if (j < limit):
|
|
_byte = data[(block * block_size) + j]
|
|
if _byte >= 0x20 and _byte < 0x7F:
|
|
out += "%s" % chr(_byte)
|
|
else:
|
|
out += "."
|
|
else:
|
|
out += " "
|
|
out += "\n"
|
|
if (left > block_size):
|
|
left -= block_size
|
|
|
|
return out
|
|
|
|
|
|
# Useful UI lists
|
|
STEPS = [2.5, 5.0, 6.25, 10.0, 12.5, 25.0, 50.0, 100.0]
|
|
S_TONES = [str(x) for x in [1000, 1450, 1750, 2100]]
|
|
STEP_LIST = [str(x)+"kHz" for x in STEPS]
|
|
ROGER_LIST = ["Off", "Begin", "End", "Both"]
|
|
TIMEOUT_LIST = [str(x) + "s" for x in range(15, 601, 15)]
|
|
TOA_LIST = ["Off"] + ["%ds" % t for t in range(1, 11)]
|
|
BANDWIDTH_LIST = ["Wide", "Narrow"]
|
|
LANGUAGE_LIST = ["English", "Chinese"]
|
|
PF1KEY_LIST = ["OFF", "call id", "r-alarm", "SOS", "SF-TX"]
|
|
PF2KEY_LIST = ["OFF", "Scan", "Second", "lamp", "SDF-DIR", "K-lamp"]
|
|
PF3KEY_LIST = ["OFF", "Call ID", "R-ALARM", "SOS", "SF-TX"]
|
|
WORKMODE_LIST = ["VFO freq", "Channel No.", "Ch. No.+Freq.",
|
|
"Ch. No.+Name"]
|
|
BACKLIGHT_LIST = ["Off"] + ["%sS" % t for t in range(1, 31)] + \
|
|
["Always On"]
|
|
SAVE_MODES = ["Off", "1", "2", "3", "4"]
|
|
LOCK_MODES = ["key-lk", "key+pg", "key+ptt", "all"]
|
|
APO_TIMES = ["Off"] + ["%dm" % t for t in range(15, 151, 15)]
|
|
OFFSET_LIST = ["none", "+", "-"]
|
|
PONMSG_LIST = ["Battery Volts", "Bitmap"]
|
|
SPMUTE_LIST = ["QT", "QT*T", "QT&T"]
|
|
DTMFST_LIST = ["Off", "DT-ST", "ANI-ST", "DT-ANI"]
|
|
DTMF_TIMES = ["%d" % x for x in range(80, 501, 20)]
|
|
PTTID_LIST = ["Off", "Begin", "End", "Both"]
|
|
ID_DLY_LIST = ["%dms" % t for t in range(100, 3001, 100)]
|
|
VOX_GRDS = ["Off"] + ["%dlevel" % l for l in range(1, 11)]
|
|
VOX_DLYS = ["Off"] + ["%ds" % t for t in range(1, 5)]
|
|
RPT_KPTS = ["Off"] + ["%dms" % t for t in range(100, 5001, 100)]
|
|
ABR_LVL_MAP = [("1",1), ("2",2), ("3",3), ("4",4), ("5",5)]
|
|
LIST_1_5 = ["%s" % x for x in range(1, 6)]
|
|
LIST_0_9 = ["%s" % x for x in range(0, 10)]
|
|
LIST_1_20 = ["%s" % x for x in range(1, 21)]
|
|
LIST_OFF_10 = ["Off"] + ["%s" % x for x in range(1, 11)]
|
|
SCANGRP_LIST = ["All"] + ["%s" % x for x in range(1, 11)]
|
|
SCANMODE_LIST = ["TO", "CO", "SE"]
|
|
SCANRANGE_LIST = ["Current band", "freq range", "ALL"]
|
|
SCQT_LIST = ["Decoder", "Encoder", "Both"]
|
|
S_MUTE_LIST = ["off", "rx mute", "tx mute", "r/t mute"]
|
|
POWER_LIST = ["Low", "Med", "High"]
|
|
RPTMODE_LIST = ["Radio", "One direction Repeater",
|
|
"Two direction repeater"]
|
|
TONE_LIST = ["----"] + ["%s" % str(t) for t in chirp_common.TONES] + \
|
|
["D%0.3dN" % dts for dts in chirp_common.DTCS_CODES] + \
|
|
["D%0.3dI" % dts for dts in chirp_common.DTCS_CODES]
|
|
|
|
|
|
@directory.register
|
|
class KGUV9DPlusRadio(chirp_common.CloneModeRadio,
|
|
chirp_common.ExperimentalRadio):
|
|
|
|
"""Wouxun KG-UV9D Plus"""
|
|
VENDOR = "Wouxun"
|
|
MODEL = "KG-UV9D Plus"
|
|
_model = "KG-UV9D"
|
|
_rev = "00" # default rev for the radio I know about...
|
|
_file_ident = "kg-uv9d"
|
|
BAUD_RATE = 19200
|
|
POWER_LEVELS = [chirp_common.PowerLevel("L", watts=1),
|
|
chirp_common.PowerLevel("M", watts=2),
|
|
chirp_common.PowerLevel("H", watts=5)]
|
|
_mmap = ""
|
|
|
|
def _read_record(self):
|
|
""" Read and validate the header of a radio reply.
|
|
A record is a formatted byte stream as follows:
|
|
0x7D All records start with this
|
|
opcode This is in the set of legal commands.
|
|
The radio reply matches the request
|
|
dir This is the direction, 0xFF to the radio,
|
|
0x00 from the radio.
|
|
cnt Count of bytes in payload
|
|
(not including the trailing checksum byte)
|
|
<cnt bytes>
|
|
<checksum byte>
|
|
"""
|
|
|
|
# first get the header and validate it
|
|
data = bytearray(self.pipe.read(4))
|
|
if (len(data) < 4):
|
|
raise errors.RadioError('Radio did not respond')
|
|
if (data[0] != 0x7D):
|
|
raise errors.RadioError(
|
|
'Radio reply garbled (%02x)' % data[0])
|
|
if (data[1] not in cmd_name):
|
|
raise errors.RadioError(
|
|
"Unrecognized opcode (%02x)" % data[1])
|
|
if (data[2] != 0x00):
|
|
raise errors.RadioError(
|
|
"Direction incorrect. Got (%02x)" % data[2])
|
|
payload_len = data[3]
|
|
# don't forget to read the checksum byte
|
|
data.extend(self.pipe.read(payload_len + 1))
|
|
if (len(data) != (payload_len + 5)): # we got a short read
|
|
raise errors.RadioError(
|
|
"Radio reply wrong size. Wanted %d, got %d" %
|
|
((payload_len + 1), (len(data) - 4)))
|
|
return _pkt_decode(data)
|
|
|
|
def _write_record(self, cmd, payload=None):
|
|
""" Write a request packet to the radio.
|
|
"""
|
|
|
|
packet = _pkt_encode(cmd, payload)
|
|
self.pipe.write(packet)
|
|
|
|
@classmethod
|
|
def match_model(cls, filedata, filename):
|
|
"""Look for bits in the file image and see if it looks
|
|
like ours...
|
|
TODO: there is a bunch of rubbish between 0x50 and 0x160
|
|
that is still a known unknown
|
|
"""
|
|
return cls._file_ident in filedata[0x51:0x59].lower()
|
|
|
|
def _identify(self):
|
|
""" Identify the radio
|
|
The ident block identifies the radio and its capabilities.
|
|
This block is always 78 bytes. The rev == '01' is the base
|
|
radio and '02' seems to be the '-Plus' version.
|
|
I don't really trust the content after the model and revision.
|
|
One would assume this is pretty much constant data but I have
|
|
seen differences between my radio and the dump named
|
|
KG-UV9D-Plus-OutOfBox-Read.txt from bug #3509. The first
|
|
five bands match the OEM windows
|
|
app except the 350-400 band. The OOB trace has the 700MHz
|
|
band different. This is speculation at this point.
|
|
|
|
TODO: This could be smarter and reject a radio not actually
|
|
a UV9D...
|
|
"""
|
|
|
|
for _i in range(0, 10): # retry 10 times if we get junk
|
|
self._write_record(CMD_IDENT)
|
|
chksum_match, op, _resp = self._read_record()
|
|
if len(_resp) == 0:
|
|
raise Exception("Radio not responding")
|
|
if len(_resp) != 74:
|
|
LOG.error(
|
|
"Expected and IDENT reply of 78 bytes. Got (%d)" %
|
|
len(_resp))
|
|
continue
|
|
if not chksum_match:
|
|
LOG.error("Checksum error: retrying ident...")
|
|
time.sleep(0.100)
|
|
continue
|
|
if op != CMD_IDENT:
|
|
LOG.error("Expected IDENT reply. Got (%02x)" % op)
|
|
continue
|
|
LOG.debug("Got:\n%s" % _hex_print(_resp))
|
|
(mod, rev) = struct.unpack(">7s2s", _resp[0:9])
|
|
LOG.debug("Model %s, rev %s" % (mod, rev))
|
|
if mod == self._model:
|
|
self._rev = rev
|
|
return
|
|
else:
|
|
raise Exception("Unable to identify radio")
|
|
raise Exception("All retries to identify failed")
|
|
|
|
def process_mmap(self):
|
|
if self._rev == "02" or self._rev == "00":
|
|
self._memobj = bitwise.parse(_MEM_FORMAT02, self._mmap)
|
|
else: # this is where you elif the other variants and non-Plus radios
|
|
raise errors.RadioError(
|
|
"Unrecognized model variation (%s). No memory map for it" %
|
|
self._rev)
|
|
|
|
def sync_in(self):
|
|
""" Public sync_in
|
|
Download contents of the radio. Throw errors back
|
|
to the core if the radio does not respond.
|
|
"""
|
|
try:
|
|
self._identify()
|
|
self._mmap = self._do_download()
|
|
self._write_record(CMD_HANGUP)
|
|
except errors.RadioError:
|
|
raise
|
|
except Exception, e:
|
|
LOG.exception('Unknown error during download process')
|
|
raise errors.RadioError(
|
|
"Failed to communicate with radio: %s" % e)
|
|
self.process_mmap()
|
|
|
|
def sync_out(self):
|
|
""" Public sync_out
|
|
Upload the modified memory image into the radio.
|
|
"""
|
|
|
|
try:
|
|
self._identify()
|
|
self._do_upload()
|
|
self._write_record(CMD_HANGUP)
|
|
except errors.RadioError:
|
|
raise
|
|
except Exception, e:
|
|
raise errors.RadioError(
|
|
"Failed to communicate with radio: %s" % e)
|
|
return
|
|
|
|
def _do_download(self):
|
|
""" Read the whole of radio memory in 64 byte chunks.
|
|
We load the config space followed by loading memory channels.
|
|
The radio seems to be a "clone" type and the memory channels
|
|
are actually within the config space. There are separate
|
|
commands (CMD_RCHAN, CMD_WCHAN) for reading channel memory but
|
|
these seem to be a hack that can only do 4 channels at a time.
|
|
Since the radio only supports 999, (can only support 3 chars
|
|
in the display UI?) although the vendors app reads 1000
|
|
channels, it hacks back to config writes (CMD_WCONF) for the
|
|
last 3 channels and names. We keep it simple and just read
|
|
the whole thing even though the vendor app doesn't. Channels
|
|
are separate in their app simply because the radio protocol
|
|
has read/write commands to access it. What they do is simply
|
|
marshal the frequency+mode bits in 4 channel chunks followed
|
|
by a separate chunk of for names. In config space, they are two
|
|
separate arrays 1..999. Given that this space is not a
|
|
multiple of 4, there is hackery on upload to do the writes to
|
|
config space. See upload for this.
|
|
"""
|
|
|
|
mem = bytearray(0x8000) # The radio's memory map is 32k
|
|
for addr in range(0, 0x8000, 64):
|
|
req = bytearray(struct.pack(">HB", addr, 64))
|
|
self._write_record(CMD_RCONF, req)
|
|
chksum_match, op, resp = self._read_record()
|
|
if not chksum_match:
|
|
LOG.debug(_hex_print(resp))
|
|
raise Exception(
|
|
"Checksum error while reading configuration (0x%x)" %
|
|
addr)
|
|
pa = struct.unpack(">H", resp[0:2])
|
|
pkt_addr = pa[0]
|
|
payload = resp[2:]
|
|
if op != CMD_RCONF or addr != pkt_addr:
|
|
raise Exception(
|
|
"Expected CMD_RCONF (%x) reply. Got (%02x: %x)" %
|
|
(addr, op, pkt_addr))
|
|
LOG.debug("Config read (0x%x):\n%s" %
|
|
(addr, _hex_print(resp, '0x%(addr)04x')))
|
|
for i in range(0, len(payload) - 1):
|
|
mem[addr + i] = payload[i]
|
|
if self.status_fn:
|
|
status = chirp_common.Status()
|
|
status.cur = addr
|
|
status.max = 0x8000
|
|
status.msg = "Cloning from radio"
|
|
self.status_fn(status)
|
|
strmem = "".join([chr(x) for x in mem])
|
|
return memmap.MemoryMap(strmem)
|
|
|
|
def _do_upload(self):
|
|
"""Walk through the config map and write updated records to
|
|
the radio. The config map contains only the regions we know
|
|
about. We don't use the channel memory commands to avoid the
|
|
hackery of using config write commands to fill in the last
|
|
3 channel memory and names slots. As we discover other useful
|
|
goodies in the map, we can add more slots...
|
|
"""
|
|
for ar, size, count in config_map:
|
|
for addr in range(ar, ar + (size*count), size):
|
|
req = bytearray(struct.pack(">H", addr))
|
|
req.extend(self.get_mmap()[addr:addr + size])
|
|
self._write_record(CMD_WCONF, req)
|
|
LOG.debug("Config write (0x%x):\n%s" %
|
|
(addr, _hex_print(req)))
|
|
chksum_match, op, ack = self._read_record()
|
|
LOG.debug("Config write ack [%x]\n%s" %
|
|
(addr, _hex_print(ack)))
|
|
a = struct.unpack(">H", ack) # big endian short...
|
|
ack = a[0]
|
|
if not chksum_match or op != CMD_WCONF or addr != ack:
|
|
msg = ""
|
|
if not chksum_match:
|
|
msg += "Checksum err, "
|
|
if op != CMD_WCONF:
|
|
msg += "cmd mismatch %x != %x, " % \
|
|
(op, CMD_WCONF)
|
|
if addr != ack:
|
|
msg += "ack error %x != %x, " % (addr, ack)
|
|
raise Exception("Radio did not ack block: %s error" % msg)
|
|
if self.status_fn:
|
|
status = chirp_common.Status()
|
|
status.cur = addr
|
|
status.max = 0x8000
|
|
status.msg = "Update radio"
|
|
self.status_fn(status)
|
|
|
|
def get_features(self):
|
|
""" Public get_features
|
|
Return the features of this radio once we have identified
|
|
it and gotten its bits
|
|
"""
|
|
rf = chirp_common.RadioFeatures()
|
|
rf.has_settings = True
|
|
rf.has_ctone = True
|
|
rf.has_rx_dtcs = True
|
|
rf.has_cross = True
|
|
rf.has_tuning_step = False
|
|
rf.has_bank = False
|
|
rf.can_odd_split = True
|
|
rf.valid_skips = ["", "S"]
|
|
rf.valid_tmodes = ["", "Tone", "TSQL", "DTCS", "Cross"]
|
|
rf.valid_cross_modes = [
|
|
"Tone->Tone",
|
|
"Tone->DTCS",
|
|
"DTCS->Tone",
|
|
"DTCS->",
|
|
"->Tone",
|
|
"->DTCS",
|
|
"DTCS->DTCS",
|
|
]
|
|
rf.valid_modes = ["FM", "NFM", "AM"]
|
|
rf.valid_power_levels = self.POWER_LEVELS
|
|
rf.valid_name_length = 8
|
|
rf.valid_duplexes = ["", "-", "+", "split", "off"]
|
|
rf.valid_bands = [(108000000, 136000000), # Aircraft AM
|
|
(136000000, 180000000), # supports 2m
|
|
(230000000, 250000000),
|
|
(350000000, 400000000),
|
|
(400000000, 520000000), # supports 70cm
|
|
(700000000, 985000000)]
|
|
rf.valid_characters = chirp_common.CHARSET_ASCII
|
|
rf.valid_tuning_steps = STEPS
|
|
rf.memory_bounds = (1, 999) # 999 memories
|
|
return rf
|
|
|
|
@classmethod
|
|
def get_prompts(cls):
|
|
rp = chirp_common.RadioPrompts()
|
|
rp.experimental = ("This radio driver is currently under development. "
|
|
"There are no known issues with it, but you should "
|
|
"proceed with caution.")
|
|
return rp
|
|
|
|
def get_raw_memory(self, number):
|
|
return repr(self._memobj.chan_blk[number])
|
|
|
|
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 get_memory(self, number):
|
|
""" Public get_memory
|
|
Return the channel memory referenced by number to the UI.
|
|
"""
|
|
_mem = self._memobj.chan_blk[number - 1]
|
|
_nam = self._memobj.chan_name[number - 1]
|
|
|
|
mem = chirp_common.Memory()
|
|
mem.number = number
|
|
_valid = _mem.state
|
|
if _valid != MEM_VALID and _valid != 0 and _valid != 2:
|
|
# In Issue #6995 we can find _valid values of 0 and 2 in the IMG
|
|
# so these values should be treated like MEM_VALID.
|
|
mem.empty = True
|
|
return mem
|
|
else:
|
|
mem.empty = False
|
|
|
|
mem.freq = int(_mem.rxfreq) * 10
|
|
|
|
if _mem.txfreq == 0xFFFFFFFF:
|
|
# TX freq not set
|
|
mem.duplex = "off"
|
|
mem.offset = 0
|
|
elif int(_mem.rxfreq) == int(_mem.txfreq):
|
|
mem.duplex = ""
|
|
mem.offset = 0
|
|
elif abs(int(_mem.rxfreq) * 10 - int(_mem.txfreq) * 10) > 70000000:
|
|
mem.duplex = "split"
|
|
mem.offset = int(_mem.txfreq) * 10
|
|
else:
|
|
mem.duplex = int(_mem.rxfreq) > int(_mem.txfreq) and "-" or "+"
|
|
mem.offset = abs(int(_mem.rxfreq) - int(_mem.txfreq)) * 10
|
|
|
|
mem.name = name2str(_nam.name)
|
|
|
|
self._get_tone(_mem, mem)
|
|
|
|
mem.skip = "" if bool(_mem.scan) else "S"
|
|
|
|
mem.power = self.POWER_LEVELS[_mem.pwr]
|
|
if _mem.mod == 1:
|
|
mem.mode = "AM"
|
|
elif _mem.fm_dev == 0:
|
|
mem.mode = "FM"
|
|
else:
|
|
mem.mode = "NFM"
|
|
# qt has no home in the UI
|
|
return mem
|
|
|
|
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) | 0x8000
|
|
if pol == "R":
|
|
val |= 0x4000
|
|
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 set_memory(self, mem):
|
|
""" Public set_memory
|
|
Inverse of get_memory. Update the radio memory image
|
|
from the mem object
|
|
"""
|
|
number = mem.number
|
|
|
|
_mem = self._memobj.chan_blk[number - 1]
|
|
_nam = self._memobj.chan_name[number - 1]
|
|
|
|
if mem.empty:
|
|
_mem.set_raw("\xFF" * (_mem.size() / 8))
|
|
_nam.name = str2name("", 8, '\0', '\0')
|
|
_mem.state = MEM_INVALID
|
|
return
|
|
|
|
_mem.rxfreq = int(mem.freq / 10)
|
|
if mem.duplex == "off":
|
|
_mem.txfreq = 0xFFFFFFFF
|
|
elif mem.duplex == "split":
|
|
_mem.txfreq = int(mem.offset / 10)
|
|
elif mem.duplex == "+":
|
|
_mem.txfreq = int(mem.freq / 10) + int(mem.offset / 10)
|
|
elif mem.duplex == "-":
|
|
_mem.txfreq = int(mem.freq / 10) - int(mem.offset / 10)
|
|
else:
|
|
_mem.txfreq = int(mem.freq / 10)
|
|
_mem.scan = int(mem.skip != "S")
|
|
if mem.mode == "FM":
|
|
_mem.mod = 0 # make sure forced AM is off
|
|
_mem.fm_dev = 0
|
|
elif mem.mode == "NFM":
|
|
_mem.mod = 0
|
|
_mem.fm_dev = 1
|
|
elif mem.mode == "AM":
|
|
_mem.mod = 1 # AM on
|
|
_mem.fm_dev = 1 # set NFM bandwidth
|
|
else:
|
|
_mem.mod = 0
|
|
_mem.fm_dev = 0 # Catchall default is FM
|
|
# set the tone
|
|
self._set_tone(mem, _mem)
|
|
# set the power
|
|
if mem.power:
|
|
_mem.pwr = self.POWER_LEVELS.index(mem.power)
|
|
else:
|
|
_mem.pwr = True
|
|
|
|
# Set fields we can't access via the UI table to safe defaults
|
|
_mem.qt = 0 # mute mode to QT
|
|
|
|
_nam.name = str2name(mem.name, 8, '\0', '\0')
|
|
_mem.state = MEM_VALID
|
|
|
|
# Build the UI configuration tabs
|
|
# the channel memory tab is built by the core.
|
|
# We have no control over it
|
|
|
|
def _core_tab(self):
|
|
""" Build Core Configuration tab
|
|
Radio settings common to all modes and areas go here.
|
|
"""
|
|
s = self._memobj.settings
|
|
|
|
cf = RadioSettingGroup("cfg_grp", "Configuration")
|
|
|
|
cf.append(RadioSetting("auto_am",
|
|
"Auto detect AM(53)",
|
|
RadioSettingValueBoolean(s.auto_am)))
|
|
cf.append(RadioSetting("qt_sw",
|
|
"Scan tone detect(59)",
|
|
RadioSettingValueBoolean(s.qt_sw)))
|
|
cf.append(
|
|
RadioSetting("s_mute",
|
|
"SubFreq Mute(60)",
|
|
RadioSettingValueList(S_MUTE_LIST,
|
|
S_MUTE_LIST[s.s_mute])))
|
|
cf.append(
|
|
RadioSetting("tot",
|
|
"Transmit timeout Timer(10)",
|
|
RadioSettingValueList(TIMEOUT_LIST,
|
|
TIMEOUT_LIST[s.tot])))
|
|
cf.append(
|
|
RadioSetting("toa",
|
|
"Transmit Timeout Alarm(11)",
|
|
RadioSettingValueList(TOA_LIST,
|
|
TOA_LIST[s.toa])))
|
|
cf.append(
|
|
RadioSetting("ptt_id",
|
|
"PTT Caller ID mode(23)",
|
|
RadioSettingValueList(PTTID_LIST,
|
|
PTTID_LIST[s.ptt_id])))
|
|
cf.append(
|
|
RadioSetting("id_dly",
|
|
"Caller ID Delay time(25)",
|
|
RadioSettingValueList(ID_DLY_LIST,
|
|
ID_DLY_LIST[s.id_dly])))
|
|
cf.append(RadioSetting("voice_sw",
|
|
"Voice Guide(12)",
|
|
RadioSettingValueBoolean(s.voice_sw)))
|
|
cf.append(RadioSetting("beep",
|
|
"Keypad Beep(13)",
|
|
RadioSettingValueBoolean(s.beep)))
|
|
cf.append(
|
|
RadioSetting("s_tone",
|
|
"Side Tone(36)",
|
|
RadioSettingValueList(S_TONES,
|
|
S_TONES[s.s_tone])))
|
|
cf.append(
|
|
RadioSetting("ring_time",
|
|
"Ring Time(26)",
|
|
RadioSettingValueList(
|
|
LIST_OFF_10,
|
|
LIST_OFF_10[s.ring_time])))
|
|
cf.append(
|
|
RadioSetting("roger",
|
|
"Roger Beep(9)",
|
|
RadioSettingValueList(ROGER_LIST,
|
|
ROGER_LIST[s.roger])))
|
|
cf.append(RadioSetting("blcdsw",
|
|
"Backlight(41)",
|
|
RadioSettingValueBoolean(s.blcdsw)))
|
|
cf.append(
|
|
RadioSetting("abr",
|
|
"Auto Backlight Time(1)",
|
|
RadioSettingValueList(BACKLIGHT_LIST,
|
|
BACKLIGHT_LIST[s.abr])))
|
|
cf.append(
|
|
RadioSetting("abr_lvl",
|
|
"Backlight Brightness(27)",
|
|
RadioSettingValueMap(ABR_LVL_MAP,
|
|
s.abr_lvl)))
|
|
cf.append(RadioSetting("lock",
|
|
"Keypad Lock",
|
|
RadioSettingValueBoolean(s.lock)))
|
|
cf.append(
|
|
RadioSetting("lock_m",
|
|
"Keypad Lock Mode(35)",
|
|
RadioSettingValueList(LOCK_MODES,
|
|
LOCK_MODES[s.lock_m])))
|
|
cf.append(RadioSetting("auto_lk",
|
|
"Keypad Autolock(34)",
|
|
RadioSettingValueBoolean(s.auto_lk)))
|
|
cf.append(RadioSetting("prich_sw",
|
|
"Priority Channel Scan(33)",
|
|
RadioSettingValueBoolean(s.prich_sw)))
|
|
cf.append(RadioSetting("pri_ch",
|
|
"Priority Channel(32)",
|
|
RadioSettingValueInteger(1, 999,
|
|
s.pri_ch)))
|
|
cf.append(
|
|
RadioSetting("dtmf_st",
|
|
"DTMF Sidetone(22)",
|
|
RadioSettingValueList(DTMFST_LIST,
|
|
DTMFST_LIST[s.dtmf_st])))
|
|
cf.append(RadioSetting("sc_qt",
|
|
"Scan QT Save Mode(38)",
|
|
RadioSettingValueList(
|
|
SCQT_LIST,
|
|
SCQT_LIST[s.sc_qt])))
|
|
cf.append(
|
|
RadioSetting("apo_tmr",
|
|
"Automatic Power-off(39)",
|
|
RadioSettingValueList(APO_TIMES,
|
|
APO_TIMES[s.apo_tmr])))
|
|
cf.append( # VOX "guard" is really VOX trigger audio level
|
|
RadioSetting("vox_grd",
|
|
"VOX level(7)",
|
|
RadioSettingValueList(VOX_GRDS,
|
|
VOX_GRDS[s.vox_grd])))
|
|
cf.append(
|
|
RadioSetting("vox_dly",
|
|
"VOX Delay(37)",
|
|
RadioSettingValueList(VOX_DLYS,
|
|
VOX_DLYS[s.vox_dly])))
|
|
cf.append(
|
|
RadioSetting("lang",
|
|
"Menu Language(14)",
|
|
RadioSettingValueList(LANGUAGE_LIST,
|
|
LANGUAGE_LIST[s.lang])))
|
|
cf.append(RadioSetting("ponmsg",
|
|
"Poweron message(40)",
|
|
RadioSettingValueList(
|
|
PONMSG_LIST, PONMSG_LIST[s.ponmsg])))
|
|
cf.append(RadioSetting("bledsw",
|
|
"Receive LED(42)",
|
|
RadioSettingValueBoolean(s.bledsw)))
|
|
return cf
|
|
|
|
def _repeater_tab(self):
|
|
"""Repeater mode functions
|
|
"""
|
|
s = self._memobj.settings
|
|
cf = RadioSettingGroup("repeater", "Repeater Functions")
|
|
|
|
cf.append(
|
|
RadioSetting("type_set",
|
|
"Radio Mode(43)",
|
|
RadioSettingValueList(
|
|
RPTMODE_LIST,
|
|
RPTMODE_LIST[s.type_set])))
|
|
cf.append(RadioSetting("rpt_ptt",
|
|
"Repeater PTT(45)",
|
|
RadioSettingValueBoolean(s.rpt_ptt)))
|
|
cf.append(RadioSetting("rpt_spk",
|
|
"Repeater Mode Speaker(44)",
|
|
RadioSettingValueBoolean(s.rpt_spk)))
|
|
cf.append(
|
|
RadioSetting("rpt_kpt",
|
|
"Repeater Hold Time(46)",
|
|
RadioSettingValueList(RPT_KPTS,
|
|
RPT_KPTS[s.rpt_kpt])))
|
|
cf.append(RadioSetting("rpt_rct",
|
|
"Repeater Receipt Tone(47)",
|
|
RadioSettingValueBoolean(s.rpt_rct)))
|
|
return cf
|
|
|
|
def _admin_tab(self):
|
|
"""Admin functions not present in radio menu...
|
|
These are admin functions not radio operation configuration
|
|
"""
|
|
|
|
def apply_cid(setting, obj):
|
|
c = str2callid(setting.value)
|
|
obj.code = c
|
|
|
|
def apply_scc(setting, obj):
|
|
c = str2digits(setting.value)
|
|
obj.scc = c
|
|
|
|
def apply_mode_sw(setting, obj):
|
|
pw = str2pw(setting.value)
|
|
obj.mode_sw = pw
|
|
setting.value = pw2str(obj.mode_sw)
|
|
|
|
def apply_reset(setting, obj):
|
|
pw = str2pw(setting.value)
|
|
obj.reset = pw
|
|
setting.value = pw2str(obj.reset)
|
|
|
|
def apply_wake(setting, obj):
|
|
obj.wake = int(setting.value)/10
|
|
|
|
def apply_sleep(setting, obj):
|
|
obj.sleep = int(setting.value)/10
|
|
|
|
pw = self._memobj.passwords # admin passwords
|
|
s = self._memobj.settings
|
|
|
|
cf = RadioSettingGroup("admin", "Admin Functions")
|
|
|
|
cf.append(RadioSetting("menu_avail",
|
|
"Menu available in channel mode",
|
|
RadioSettingValueBoolean(s.menu_avail)))
|
|
mode_sw = RadioSettingValueString(0, 6,
|
|
pw2str(pw.mode_sw), False)
|
|
rs = RadioSetting("passwords.mode_sw",
|
|
"Mode Switch Password", mode_sw)
|
|
rs.set_apply_callback(apply_mode_sw, pw)
|
|
cf.append(rs)
|
|
|
|
cf.append(RadioSetting("reset_avail",
|
|
"Radio Reset Available",
|
|
RadioSettingValueBoolean(s.reset_avail)))
|
|
reset = RadioSettingValueString(0, 6, pw2str(pw.reset), False)
|
|
rs = RadioSetting("passwords.reset",
|
|
"Radio Reset Password", reset)
|
|
rs.set_apply_callback(apply_reset, pw)
|
|
cf.append(rs)
|
|
|
|
cf.append(
|
|
RadioSetting("dtmf_tx",
|
|
"DTMF Tx Duration",
|
|
RadioSettingValueList(DTMF_TIMES,
|
|
DTMF_TIMES[s.dtmf_tx])))
|
|
cid = self._memobj.my_callid
|
|
my_callid = RadioSettingValueString(3, 6,
|
|
callid2str(cid.code), False)
|
|
rs = RadioSetting("my_callid.code",
|
|
"PTT Caller ID code(24)", my_callid)
|
|
rs.set_apply_callback(apply_cid, cid)
|
|
cf.append(rs)
|
|
|
|
stun = self._memobj.stun
|
|
st = RadioSettingValueString(0, 6, digits2str(stun.scc), False)
|
|
rs = RadioSetting("stun.scc", "Security code", st)
|
|
rs.set_apply_callback(apply_scc, stun)
|
|
cf.append(rs)
|
|
|
|
cf.append(
|
|
RadioSetting("settings.save_m",
|
|
"Save Mode (2)",
|
|
RadioSettingValueList(SAVE_MODES,
|
|
SAVE_MODES[s.save_m])))
|
|
for i in range(0, 4):
|
|
sm = self._memobj.save[i]
|
|
wake = RadioSettingValueInteger(0, 18000, sm.wake * 10, 1)
|
|
wf = RadioSetting("save[%i].wake" % i,
|
|
"Save Mode %d Wake Time" % (i+1), wake)
|
|
wf.set_apply_callback(apply_wake, sm)
|
|
cf.append(wf)
|
|
|
|
slp = RadioSettingValueInteger(0, 18000, sm.sleep * 10, 1)
|
|
wf = RadioSetting("save[%i].sleep" % i,
|
|
"Save Mode %d Sleep Time" % (i+1), slp)
|
|
wf.set_apply_callback(apply_sleep, sm)
|
|
cf.append(wf)
|
|
|
|
_msg = str(self._memobj.display.banner).split("\0")[0]
|
|
val = RadioSettingValueString(0, 16, _msg)
|
|
val.set_mutable(True)
|
|
cf.append(RadioSetting("display.banner",
|
|
"Display Message", val))
|
|
return cf
|
|
|
|
def _fm_tab(self):
|
|
"""FM Broadcast channels
|
|
"""
|
|
def apply_fm(setting, obj):
|
|
f = freq2short(setting.value, 76000000, 108000000)
|
|
obj.fm_freq = f
|
|
|
|
fm = RadioSettingGroup("fm_chans", "FM Broadcast")
|
|
for ch in range(0, 20):
|
|
chan = self._memobj.fm_chans[ch]
|
|
freq = RadioSettingValueString(0, 20,
|
|
short2freq(chan.fm_freq))
|
|
rs = RadioSetting("fm_%d" % (ch + 1),
|
|
"FM Channel %d" % (ch + 1), freq)
|
|
rs.set_apply_callback(apply_fm, chan)
|
|
fm.append(rs)
|
|
return fm
|
|
|
|
def _scan_grp(self):
|
|
"""Scan groups
|
|
"""
|
|
def apply_name(setting, obj):
|
|
name = str2name(setting.value, 8, '\0', '\0')
|
|
obj.name = name
|
|
|
|
def apply_start(setting, obj):
|
|
"""Do a callback to deal with RadioSettingInteger limitation
|
|
on memory address resolution
|
|
"""
|
|
obj.scan_st = int(setting.value)
|
|
|
|
def apply_end(setting, obj):
|
|
"""Do a callback to deal with RadioSettingInteger limitation
|
|
on memory address resolution
|
|
"""
|
|
obj.scan_end = int(setting.value)
|
|
|
|
sgrp = self._memobj.scn_grps
|
|
scan = RadioSettingGroup("scn_grps", "Channel Scanner Groups")
|
|
for i in range(0, 10):
|
|
s_grp = sgrp.addrs[i]
|
|
s_name = sgrp.names[i]
|
|
rs_name = RadioSettingValueString(0, 8,
|
|
name2str(s_name.name))
|
|
rs = RadioSetting("scn_grps.names[%i].name" % i,
|
|
"Group %i Name" % (i + 1), rs_name)
|
|
rs.set_apply_callback(apply_name, s_name)
|
|
scan.append(rs)
|
|
rs_st = RadioSettingValueInteger(1, 999, s_grp.scan_st)
|
|
rs = RadioSetting("scn_grps.addrs[%i].scan_st" % i,
|
|
"Starting Channel", rs_st)
|
|
rs.set_apply_callback(apply_start, s_grp)
|
|
scan.append(rs)
|
|
rs_end = RadioSettingValueInteger(1, 999, s_grp.scan_end)
|
|
rs = RadioSetting("scn_grps.addrs[%i].scan_end" % i,
|
|
"Last Channel", rs_end)
|
|
rs.set_apply_callback(apply_end, s_grp)
|
|
scan.append(rs)
|
|
return scan
|
|
|
|
def _callid_grp(self):
|
|
"""Caller IDs to be recognized by radio
|
|
This really should be a table in the UI
|
|
"""
|
|
def apply_callid(setting, obj):
|
|
c = str2callid(setting.value)
|
|
obj.cid = c
|
|
|
|
def apply_name(setting, obj):
|
|
name = str2name(setting.value, 6, '\0', '\xff')
|
|
obj.name = name
|
|
|
|
cid = RadioSettingGroup("callids", "Caller IDs")
|
|
for i in range(0, 20):
|
|
callid = self._memobj.call_ids[i]
|
|
name = self._memobj.cid_names[i]
|
|
c_name = RadioSettingValueString(0, 6, name2str(name.name))
|
|
rs = RadioSetting("cid_names[%i].name" % i,
|
|
"Caller ID %i Name" % (i + 1), c_name)
|
|
rs.set_apply_callback(apply_name, name)
|
|
cid.append(rs)
|
|
c_id = RadioSettingValueString(0, 6,
|
|
callid2str(callid.cid),
|
|
False)
|
|
rs = RadioSetting("call_ids[%i].cid" % i,
|
|
"Caller ID Code", c_id)
|
|
rs.set_apply_callback(apply_callid, callid)
|
|
cid.append(rs)
|
|
return cid
|
|
|
|
def _band_tab(self, area, band):
|
|
""" Build a band tab inside a VFO/Area
|
|
"""
|
|
def apply_freq(setting, lo, hi, obj):
|
|
f = freq2int(setting.value, lo, hi)
|
|
obj.freq = f/10
|
|
|
|
def apply_offset(setting, obj):
|
|
f = freq2int(setting.value, 0, 5000000)
|
|
obj.offset = f/10
|
|
|
|
def apply_enc(setting, obj):
|
|
t = tone2short(setting.value)
|
|
obj.encqt = t
|
|
|
|
def apply_dec(setting, obj):
|
|
t = tone2short(setting.value)
|
|
obj.decqt = t
|
|
|
|
if area == "a":
|
|
if band == 150:
|
|
c = self._memobj.vfo_a.band_150
|
|
lo = 108000000
|
|
hi = 180000000
|
|
elif band == 200:
|
|
c = self._memobj.vfo_a.band_200
|
|
lo = 230000000
|
|
hi = 250000000
|
|
elif band == 300:
|
|
c = self._memobj.vfo_a.band_300
|
|
lo = 350000000
|
|
hi = 400000000
|
|
elif band == 450:
|
|
c = self._memobj.vfo_a.band_450
|
|
lo = 400000000
|
|
hi = 512000000
|
|
else: # 700
|
|
c = self._memobj.vfo_a.band_700
|
|
lo = 700000000
|
|
hi = 985000000
|
|
else: # area 'b'
|
|
if band == 150:
|
|
c = self._memobj.vfo_b.band_150
|
|
lo = 136000000
|
|
hi = 180000000
|
|
else: # 450
|
|
c = self._memobj.vfo_b.band_450
|
|
lo = 400000000
|
|
hi = 512000000
|
|
|
|
prefix = "vfo_%s.band_%d" % (area, band)
|
|
bf = RadioSettingGroup(prefix, "%dMHz Band" % band)
|
|
freq = RadioSettingValueString(0, 15, int2freq(c.freq * 10))
|
|
rs = RadioSetting(prefix + ".freq", "Rx Frequency", freq)
|
|
rs.set_apply_callback(apply_freq, lo, hi, c)
|
|
bf.append(rs)
|
|
|
|
off = RadioSettingValueString(0, 15, int2freq(c.offset * 10))
|
|
rs = RadioSetting(prefix + ".offset", "Tx Offset(28)", off)
|
|
rs.set_apply_callback(apply_offset, c)
|
|
bf.append(rs)
|
|
|
|
rs = RadioSetting(prefix + ".encqt",
|
|
"Encode QT(17,19)",
|
|
RadioSettingValueList(TONE_LIST,
|
|
short2tone(c.encqt)))
|
|
rs.set_apply_callback(apply_enc, c)
|
|
bf.append(rs)
|
|
|
|
rs = RadioSetting(prefix + ".decqt",
|
|
"Decode QT(16,18)",
|
|
RadioSettingValueList(TONE_LIST,
|
|
short2tone(c.decqt)))
|
|
rs.set_apply_callback(apply_dec, c)
|
|
bf.append(rs)
|
|
|
|
bf.append(RadioSetting(prefix + ".qt",
|
|
"Mute Mode(21)",
|
|
RadioSettingValueList(SPMUTE_LIST,
|
|
SPMUTE_LIST[c.qt])))
|
|
bf.append(RadioSetting(prefix + ".scan",
|
|
"Scan this(48)",
|
|
RadioSettingValueBoolean(c.scan)))
|
|
bf.append(RadioSetting(prefix + ".pwr",
|
|
"Power(5)",
|
|
RadioSettingValueList(
|
|
POWER_LIST, POWER_LIST[c.pwr])))
|
|
bf.append(RadioSetting(prefix + ".mod",
|
|
"AM Modulation(54)",
|
|
RadioSettingValueBoolean(c.mod)))
|
|
bf.append(RadioSetting(prefix + ".fm_dev",
|
|
"FM Deviation(4)",
|
|
RadioSettingValueList(
|
|
BANDWIDTH_LIST,
|
|
BANDWIDTH_LIST[c.fm_dev])))
|
|
bf.append(
|
|
RadioSetting(prefix + ".shift",
|
|
"Frequency Shift(6)",
|
|
RadioSettingValueList(OFFSET_LIST,
|
|
OFFSET_LIST[c.shift])))
|
|
return bf
|
|
|
|
def _area_tab(self, area):
|
|
"""Build a VFO tab
|
|
"""
|
|
def apply_scan_st(setting, scan_lo, scan_hi, obj):
|
|
f = freq2short(setting.value, scan_lo, scan_hi)
|
|
obj.scan_st = f
|
|
|
|
def apply_scan_end(setting, scan_lo, scan_hi, obj):
|
|
f = freq2short(setting.value, scan_lo, scan_hi)
|
|
obj.scan_end = f
|
|
|
|
if area == "a":
|
|
desc = "Area A Settings"
|
|
c = self._memobj.a_conf
|
|
scan_lo = 108000000
|
|
scan_hi = 985000000
|
|
scan_rng = self._memobj.settings.a
|
|
band_list = (150, 200, 300, 450, 700)
|
|
else:
|
|
desc = "Area B Settings"
|
|
c = self._memobj.b_conf
|
|
scan_lo = 136000000
|
|
scan_hi = 512000000
|
|
scan_rng = self._memobj.settings.b
|
|
band_list = (150, 450)
|
|
|
|
prefix = "%s_conf" % area
|
|
af = RadioSettingGroup(prefix, desc)
|
|
af.append(
|
|
RadioSetting(prefix + ".w_mode",
|
|
"Workmode",
|
|
RadioSettingValueList(
|
|
WORKMODE_LIST,
|
|
WORKMODE_LIST[c.w_mode])))
|
|
af.append(RadioSetting(prefix + ".w_chan",
|
|
"Channel",
|
|
RadioSettingValueInteger(1, 999,
|
|
c.w_chan)))
|
|
af.append(
|
|
RadioSetting(prefix + ".scan_grp",
|
|
"Scan Group(49)",
|
|
RadioSettingValueList(
|
|
SCANGRP_LIST,
|
|
SCANGRP_LIST[c.scan_grp])))
|
|
af.append(RadioSetting(prefix + ".bcl",
|
|
"Busy Channel Lock-out(15)",
|
|
RadioSettingValueBoolean(c.bcl)))
|
|
af.append(
|
|
RadioSetting(prefix + ".sql",
|
|
"Squelch Level(8)",
|
|
RadioSettingValueList(LIST_0_9,
|
|
LIST_0_9[c.sql])))
|
|
af.append(
|
|
RadioSetting(prefix + ".cset",
|
|
"Call ID Group(52)",
|
|
RadioSettingValueList(LIST_1_20,
|
|
LIST_1_20[c.cset])))
|
|
af.append(
|
|
RadioSetting(prefix + ".step",
|
|
"Frequency Step(3)",
|
|
RadioSettingValueList(
|
|
STEP_LIST, STEP_LIST[c.step])))
|
|
af.append(
|
|
RadioSetting(prefix + ".scan_mode",
|
|
"Scan Mode(20)",
|
|
RadioSettingValueList(
|
|
SCANMODE_LIST,
|
|
SCANMODE_LIST[c.scan_mode])))
|
|
af.append(
|
|
RadioSetting(prefix + ".scan_range",
|
|
"Scan Range(50)",
|
|
RadioSettingValueList(
|
|
SCANRANGE_LIST,
|
|
SCANRANGE_LIST[c.scan_range])))
|
|
st = RadioSettingValueString(0, 15,
|
|
short2freq(scan_rng.scan_st))
|
|
rs = RadioSetting("settings.%s.scan_st" % area,
|
|
"Frequency Scan Start", st)
|
|
rs.set_apply_callback(apply_scan_st, scan_lo, scan_hi, scan_rng)
|
|
af.append(rs)
|
|
|
|
end = RadioSettingValueString(0, 15,
|
|
short2freq(scan_rng.scan_end))
|
|
rs = RadioSetting("settings.%s.scan_end" % area,
|
|
"Frequency Scan End", end)
|
|
rs.set_apply_callback(apply_scan_end, scan_lo, scan_hi,
|
|
scan_rng)
|
|
af.append(rs)
|
|
# Each area has its own set of bands
|
|
for band in (band_list):
|
|
af.append(self._band_tab(area, band))
|
|
return af
|
|
|
|
def _key_tab(self):
|
|
"""Build radio key/button menu
|
|
"""
|
|
s = self._memobj.settings
|
|
kf = RadioSettingGroup("key_grp", "Key Settings")
|
|
|
|
kf.append(RadioSetting("settings.pf1",
|
|
"PF1 Key function(55)",
|
|
RadioSettingValueList(
|
|
PF1KEY_LIST,
|
|
PF1KEY_LIST[s.pf1])))
|
|
kf.append(RadioSetting("settings.pf2",
|
|
"PF2 Key function(56)",
|
|
RadioSettingValueList(
|
|
PF2KEY_LIST,
|
|
PF2KEY_LIST[s.pf2])))
|
|
kf.append(RadioSetting("settings.pf3",
|
|
"PF3 Key function(57)",
|
|
RadioSettingValueList(
|
|
PF3KEY_LIST,
|
|
PF3KEY_LIST[s.pf3])))
|
|
return kf
|
|
|
|
def _get_settings(self):
|
|
"""Build the radio configuration settings menus
|
|
"""
|
|
|
|
core_grp = self._core_tab()
|
|
fm_grp = self._fm_tab()
|
|
area_a_grp = self._area_tab("a")
|
|
area_b_grp = self._area_tab("b")
|
|
key_grp = self._key_tab()
|
|
scan_grp = self._scan_grp()
|
|
callid_grp = self._callid_grp()
|
|
admin_grp = self._admin_tab()
|
|
rpt_grp = self._repeater_tab()
|
|
|
|
core_grp.append(key_grp)
|
|
core_grp.append(admin_grp)
|
|
core_grp.append(rpt_grp)
|
|
group = RadioSettings(core_grp,
|
|
area_a_grp,
|
|
area_b_grp,
|
|
fm_grp,
|
|
scan_grp,
|
|
callid_grp
|
|
)
|
|
return group
|
|
|
|
def get_settings(self):
|
|
""" Public build out linkage between radio settings and UI
|
|
"""
|
|
try:
|
|
return self._get_settings()
|
|
except Exception:
|
|
import traceback
|
|
LOG.error("Failed to parse settings: %s",
|
|
traceback.format_exc())
|
|
return None
|
|
|
|
def _is_freq(self, element):
|
|
"""This is a hack to smoke out whether we need to do
|
|
frequency translations for otherwise innocent u16s and u32s
|
|
"""
|
|
return "rxfreq" in element.get_name() or \
|
|
"txfreq" in element.get_name() or \
|
|
"scan_st" in element.get_name() or \
|
|
"scan_end" in element.get_name() or \
|
|
"offset" in element.get_name() or \
|
|
"fm_stop" in element.get_name()
|
|
|
|
def set_settings(self, settings):
|
|
""" Public update radio settings via UI callback
|
|
A lot of this should be in common code....
|
|
"""
|
|
|
|
for element in settings:
|
|
if not isinstance(element, RadioSetting):
|
|
LOG.debug("set_settings: not instance %s" %
|
|
element.get_name())
|
|
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]:
|
|
# decode an array index
|
|
if "[" in bit and "]" in bit:
|
|
bit, index = bit.split("[", 1)
|
|
index, junk = index.split("]", 1)
|
|
index = int(index)
|
|
obj = getattr(obj, bit)[index]
|
|
else:
|
|
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()
|
|
else:
|
|
LOG.debug("Setting %s = %s" %
|
|
(setting, element.value))
|
|
if self._is_freq(element):
|
|
setattr(obj, setting, int(element.value)/10)
|
|
else:
|
|
setattr(obj, setting, element.value)
|
|
except Exception, e:
|
|
LOG.debug("set_settings: Exception with %s" %
|
|
element.get_name())
|
|
raise
|