uv-k5-firmware-custom/settings.c
2024-01-15 22:30:12 +01:00

762 lines
23 KiB
C

/* Copyright 2023 Dual Tachyon
* https://github.com/DualTachyon
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <string.h>
#include "app/dtmf.h"
#ifdef ENABLE_FMRADIO
#include "app/fm.h"
#endif
#include "driver/bk1080.h"
#include "driver/bk4819.h"
#include "driver/eeprom.h"
#include "misc.h"
#include "settings.h"
#include "ui/menu.h"
static const uint32_t gDefaultFrequencyTable[] =
{
14500000, //
14550000, //
43300000, //
43320000, //
43350000 //
};
EEPROM_Config_t gEeprom = { 0 };
void SETTINGS_InitEEPROM(void)
{
uint8_t Data[16] = {0};
// 0E70..0E77
EEPROM_ReadBuffer(0x0E70, Data, 8);
gEeprom.CHAN_1_CALL = IS_MR_CHANNEL(Data[0]) ? Data[0] : MR_CHANNEL_FIRST;
gEeprom.SQUELCH_LEVEL = (Data[1] < 10) ? Data[1] : 1;
gEeprom.TX_TIMEOUT_TIMER = (Data[2] < 11) ? Data[2] : 1;
#ifdef ENABLE_NOAA
gEeprom.NOAA_AUTO_SCAN = (Data[3] < 2) ? Data[3] : false;
#endif
gEeprom.KEY_LOCK = (Data[4] < 2) ? Data[4] : false;
#ifdef ENABLE_VOX
gEeprom.VOX_SWITCH = (Data[5] < 2) ? Data[5] : false;
gEeprom.VOX_LEVEL = (Data[6] < 10) ? Data[6] : 1;
#endif
gEeprom.MIC_SENSITIVITY = (Data[7] < 5) ? Data[7] : 4;
// 0E78..0E7F
EEPROM_ReadBuffer(0x0E78, Data, 8);
gEeprom.BACKLIGHT_MAX = (Data[0] & 0xF) <= 10 ? (Data[0] & 0xF) : 10;
gEeprom.BACKLIGHT_MIN = (Data[0] >> 4) < gEeprom.BACKLIGHT_MAX ? (Data[0] >> 4) : 0;
#ifdef ENABLE_BLMIN_TMP_OFF
gEeprom.BACKLIGHT_MIN_STAT = BLMIN_STAT_ON;
#endif
gEeprom.CHANNEL_DISPLAY_MODE = (Data[1] < 4) ? Data[1] : MDF_FREQUENCY; // 4 instead of 3 - extra display mode
gEeprom.CROSS_BAND_RX_TX = (Data[2] < 3) ? Data[2] : CROSS_BAND_OFF;
gEeprom.BATTERY_SAVE = (Data[3] < 5) ? Data[3] : 4;
gEeprom.DUAL_WATCH = (Data[4] < 3) ? Data[4] : DUAL_WATCH_CHAN_A;
gEeprom.BACKLIGHT_TIME = (Data[5] < ARRAY_SIZE(gSubMenu_BACKLIGHT)) ? Data[5] : 3;
gEeprom.TAIL_TONE_ELIMINATION = (Data[6] < 2) ? Data[6] : false;
gEeprom.VFO_OPEN = (Data[7] < 2) ? Data[7] : true;
// 0E80..0E87
EEPROM_ReadBuffer(0x0E80, Data, 8);
gEeprom.ScreenChannel[0] = IS_VALID_CHANNEL(Data[0]) ? Data[0] : (FREQ_CHANNEL_FIRST + BAND6_400MHz);
gEeprom.ScreenChannel[1] = IS_VALID_CHANNEL(Data[3]) ? Data[3] : (FREQ_CHANNEL_FIRST + BAND6_400MHz);
gEeprom.MrChannel[0] = IS_MR_CHANNEL(Data[1]) ? Data[1] : MR_CHANNEL_FIRST;
gEeprom.MrChannel[1] = IS_MR_CHANNEL(Data[4]) ? Data[4] : MR_CHANNEL_FIRST;
gEeprom.FreqChannel[0] = IS_FREQ_CHANNEL(Data[2]) ? Data[2] : (FREQ_CHANNEL_FIRST + BAND6_400MHz);
gEeprom.FreqChannel[1] = IS_FREQ_CHANNEL(Data[5]) ? Data[5] : (FREQ_CHANNEL_FIRST + BAND6_400MHz);
#ifdef ENABLE_NOAA
gEeprom.NoaaChannel[0] = IS_NOAA_CHANNEL(Data[6]) ? Data[6] : NOAA_CHANNEL_FIRST;
gEeprom.NoaaChannel[1] = IS_NOAA_CHANNEL(Data[7]) ? Data[7] : NOAA_CHANNEL_FIRST;
#endif
#ifdef ENABLE_FMRADIO
{ // 0E88..0E8F
struct
{
uint16_t selFreq;
uint8_t selChn;
uint8_t isMrMode:1;
uint8_t band:2;
//uint8_t space:2;
} __attribute__((packed)) fmCfg;
EEPROM_ReadBuffer(0x0E88, &fmCfg, 4);
gEeprom.FM_Band = fmCfg.band;
//gEeprom.FM_Space = fmCfg.space;
gEeprom.FM_SelectedFrequency =
(fmCfg.selFreq >= BK1080_GetFreqLoLimit(gEeprom.FM_Band) && fmCfg.selFreq <= BK1080_GetFreqHiLimit(gEeprom.FM_Band)) ?
fmCfg.selFreq : BK1080_GetFreqLoLimit(gEeprom.FM_Band);
gEeprom.FM_SelectedChannel = fmCfg.selChn;
gEeprom.FM_IsMrMode = fmCfg.isMrMode;
}
// 0E40..0E67
EEPROM_ReadBuffer(0x0E40, gFM_Channels, sizeof(gFM_Channels));
FM_ConfigureChannelState();
#endif
// 0E90..0E97
EEPROM_ReadBuffer(0x0E90, Data, 8);
gEeprom.BEEP_CONTROL = Data[0] & 1;
gEeprom.KEY_M_LONG_PRESS_ACTION = ((Data[0] >> 1) < ACTION_OPT_LEN) ? (Data[0] >> 1) : ACTION_OPT_NONE;
gEeprom.KEY_1_SHORT_PRESS_ACTION = (Data[1] < ACTION_OPT_LEN) ? Data[1] : ACTION_OPT_MONITOR;
gEeprom.KEY_1_LONG_PRESS_ACTION = (Data[2] < ACTION_OPT_LEN) ? Data[2] : ACTION_OPT_NONE;
gEeprom.KEY_2_SHORT_PRESS_ACTION = (Data[3] < ACTION_OPT_LEN) ? Data[3] : ACTION_OPT_SCAN;
gEeprom.KEY_2_LONG_PRESS_ACTION = (Data[4] < ACTION_OPT_LEN) ? Data[4] : ACTION_OPT_NONE;
gEeprom.SCAN_RESUME_MODE = (Data[5] < 3) ? Data[5] : SCAN_RESUME_CO;
gEeprom.AUTO_KEYPAD_LOCK = (Data[6] < 2) ? Data[6] : false;
gEeprom.POWER_ON_DISPLAY_MODE = (Data[7] < 4) ? Data[7] : POWER_ON_DISPLAY_MODE_VOLTAGE;
// 0E98..0E9F
EEPROM_ReadBuffer(0x0E98, Data, 8);
memcpy(&gEeprom.POWER_ON_PASSWORD, Data, 4);
// 0EA0..0EA7
EEPROM_ReadBuffer(0x0EA0, Data, 8);
#ifdef ENABLE_VOICE
gEeprom.VOICE_PROMPT = (Data[0] < 3) ? Data[0] : VOICE_PROMPT_ENGLISH;
#endif
#ifdef ENABLE_RSSI_BAR
if((Data[1] < 200 && Data[1] > 90) && (Data[2] < Data[1]-9 && Data[1] < 160 && Data[2] > 50)) {
gEeprom.S0_LEVEL = Data[1];
gEeprom.S9_LEVEL = Data[2];
}
else {
gEeprom.S0_LEVEL = 130;
gEeprom.S9_LEVEL = 76;
}
#endif
// 0EA8..0EAF
EEPROM_ReadBuffer(0x0EA8, Data, 8);
#ifdef ENABLE_ALARM
gEeprom.ALARM_MODE = (Data[0] < 2) ? Data[0] : true;
#endif
gEeprom.ROGER = (Data[1] < 3) ? Data[1] : ROGER_MODE_OFF;
gEeprom.REPEATER_TAIL_TONE_ELIMINATION = (Data[2] < 11) ? Data[2] : 0;
gEeprom.TX_VFO = (Data[3] < 2) ? Data[3] : 0;
gEeprom.BATTERY_TYPE = (Data[4] < BATTERY_TYPE_UNKNOWN) ? Data[4] : BATTERY_TYPE_1600_MAH;
// 0ED0..0ED7
EEPROM_ReadBuffer(0x0ED0, Data, 8);
gEeprom.DTMF_SIDE_TONE = (Data[0] < 2) ? Data[0] : true;
#ifdef ENABLE_DTMF_CALLING
gEeprom.DTMF_SEPARATE_CODE = DTMF_ValidateCodes((char *)(Data + 1), 1) ? Data[1] : '*';
gEeprom.DTMF_GROUP_CALL_CODE = DTMF_ValidateCodes((char *)(Data + 2), 1) ? Data[2] : '#';
gEeprom.DTMF_DECODE_RESPONSE = (Data[3] < 4) ? Data[3] : 0;
gEeprom.DTMF_auto_reset_time = (Data[4] < 61) ? Data[4] : (Data[4] >= 5) ? Data[4] : 10;
#endif
gEeprom.DTMF_PRELOAD_TIME = (Data[5] < 101) ? Data[5] * 10 : 300;
gEeprom.DTMF_FIRST_CODE_PERSIST_TIME = (Data[6] < 101) ? Data[6] * 10 : 100;
gEeprom.DTMF_HASH_CODE_PERSIST_TIME = (Data[7] < 101) ? Data[7] * 10 : 100;
// 0ED8..0EDF
EEPROM_ReadBuffer(0x0ED8, Data, 8);
gEeprom.DTMF_CODE_PERSIST_TIME = (Data[0] < 101) ? Data[0] * 10 : 100;
gEeprom.DTMF_CODE_INTERVAL_TIME = (Data[1] < 101) ? Data[1] * 10 : 100;
#ifdef ENABLE_DTMF_CALLING
gEeprom.PERMIT_REMOTE_KILL = (Data[2] < 2) ? Data[2] : true;
// 0EE0..0EE7
EEPROM_ReadBuffer(0x0EE0, Data, sizeof(gEeprom.ANI_DTMF_ID));
if (DTMF_ValidateCodes((char *)Data, sizeof(gEeprom.ANI_DTMF_ID))) {
memcpy(gEeprom.ANI_DTMF_ID, Data, sizeof(gEeprom.ANI_DTMF_ID));
} else {
strcpy(gEeprom.ANI_DTMF_ID, "123");
}
// 0EE8..0EEF
EEPROM_ReadBuffer(0x0EE8, Data, sizeof(gEeprom.KILL_CODE));
if (DTMF_ValidateCodes((char *)Data, sizeof(gEeprom.KILL_CODE))) {
memcpy(gEeprom.KILL_CODE, Data, sizeof(gEeprom.KILL_CODE));
} else {
strcpy(gEeprom.KILL_CODE, "ABCD9");
}
// 0EF0..0EF7
EEPROM_ReadBuffer(0x0EF0, Data, sizeof(gEeprom.REVIVE_CODE));
if (DTMF_ValidateCodes((char *)Data, sizeof(gEeprom.REVIVE_CODE))) {
memcpy(gEeprom.REVIVE_CODE, Data, sizeof(gEeprom.REVIVE_CODE));
} else {
strcpy(gEeprom.REVIVE_CODE, "9DCBA");
}
#endif
// 0EF8..0F07
EEPROM_ReadBuffer(0x0EF8, Data, sizeof(gEeprom.DTMF_UP_CODE));
if (DTMF_ValidateCodes((char *)Data, sizeof(gEeprom.DTMF_UP_CODE))) {
memcpy(gEeprom.DTMF_UP_CODE, Data, sizeof(gEeprom.DTMF_UP_CODE));
} else {
strcpy(gEeprom.DTMF_UP_CODE, "12345");
}
// 0F08..0F17
EEPROM_ReadBuffer(0x0F08, Data, sizeof(gEeprom.DTMF_DOWN_CODE));
if (DTMF_ValidateCodes((char *)Data, sizeof(gEeprom.DTMF_DOWN_CODE))) {
memcpy(gEeprom.DTMF_DOWN_CODE, Data, sizeof(gEeprom.DTMF_DOWN_CODE));
} else {
strcpy(gEeprom.DTMF_DOWN_CODE, "54321");
}
// 0F18..0F1F
EEPROM_ReadBuffer(0x0F18, Data, 8);
gEeprom.SCAN_LIST_DEFAULT = (Data[0] < 3) ? Data[0] : 0; // we now have 'all' channel scan option
for (unsigned int i = 0; i < 2; i++)
{
const unsigned int j = 1 + (i * 3);
gEeprom.SCAN_LIST_ENABLED[i] = (Data[j + 0] < 2) ? Data[j] : false;
gEeprom.SCANLIST_PRIORITY_CH1[i] = Data[j + 1];
gEeprom.SCANLIST_PRIORITY_CH2[i] = Data[j + 2];
}
// 0F40..0F47
EEPROM_ReadBuffer(0x0F40, Data, 8);
gSetting_F_LOCK = (Data[0] < F_LOCK_LEN) ? Data[0] : F_LOCK_DEF;
gSetting_350TX = (Data[1] < 2) ? Data[1] : false; // was true
#ifdef ENABLE_DTMF_CALLING
gSetting_KILLED = (Data[2] < 2) ? Data[2] : false;
#endif
gSetting_200TX = (Data[3] < 2) ? Data[3] : false;
gSetting_500TX = (Data[4] < 2) ? Data[4] : false;
gSetting_350EN = (Data[5] < 2) ? Data[5] : true;
gSetting_ScrambleEnable = (Data[6] < 2) ? Data[6] : true;
//gSetting_TX_EN = (Data[7] & (1u << 0)) ? true : false;
gSetting_live_DTMF_decoder = !!(Data[7] & (1u << 1));
gSetting_battery_text = (((Data[7] >> 2) & 3u) <= 2) ? (Data[7] >> 2) & 3 : 2;
#ifdef ENABLE_AUDIO_BAR
gSetting_mic_bar = !!(Data[7] & (1u << 4));
#endif
#ifdef ENABLE_AM_FIX
gSetting_AM_fix = !!(Data[7] & (1u << 5));
#endif
gSetting_backlight_on_tx_rx = (Data[7] >> 6) & 3u;
if (!gEeprom.VFO_OPEN)
{
gEeprom.ScreenChannel[0] = gEeprom.MrChannel[0];
gEeprom.ScreenChannel[1] = gEeprom.MrChannel[1];
}
// 0D60..0E27
EEPROM_ReadBuffer(0x0D60, gMR_ChannelAttributes, sizeof(gMR_ChannelAttributes));
for(uint16_t i = 0; i < sizeof(gMR_ChannelAttributes); i++) {
ChannelAttributes_t *att = &gMR_ChannelAttributes[i];
if(att->__val == 0xff){
att->__val = 0;
att->band = 0xf;
}
}
// 0F30..0F3F
EEPROM_ReadBuffer(0x0F30, gCustomAesKey, sizeof(gCustomAesKey));
bHasCustomAesKey = false;
for (unsigned int i = 0; i < ARRAY_SIZE(gCustomAesKey); i++)
{
if (gCustomAesKey[i] != 0xFFFFFFFFu)
{
bHasCustomAesKey = true;
return;
}
}
}
void SETTINGS_LoadCalibration(void)
{
// uint8_t Mic;
EEPROM_ReadBuffer(0x1EC0, gEEPROM_RSSI_CALIB[3], 8);
memcpy(gEEPROM_RSSI_CALIB[4], gEEPROM_RSSI_CALIB[3], 8);
memcpy(gEEPROM_RSSI_CALIB[5], gEEPROM_RSSI_CALIB[3], 8);
memcpy(gEEPROM_RSSI_CALIB[6], gEEPROM_RSSI_CALIB[3], 8);
EEPROM_ReadBuffer(0x1EC8, gEEPROM_RSSI_CALIB[0], 8);
memcpy(gEEPROM_RSSI_CALIB[1], gEEPROM_RSSI_CALIB[0], 8);
memcpy(gEEPROM_RSSI_CALIB[2], gEEPROM_RSSI_CALIB[0], 8);
EEPROM_ReadBuffer(0x1F40, gBatteryCalibration, 12);
if (gBatteryCalibration[0] >= 5000)
{
gBatteryCalibration[0] = 1900;
gBatteryCalibration[1] = 2000;
}
gBatteryCalibration[5] = 2300;
#ifdef ENABLE_VOX
EEPROM_ReadBuffer(0x1F50 + (gEeprom.VOX_LEVEL * 2), &gEeprom.VOX1_THRESHOLD, 2);
EEPROM_ReadBuffer(0x1F68 + (gEeprom.VOX_LEVEL * 2), &gEeprom.VOX0_THRESHOLD, 2);
#endif
//EEPROM_ReadBuffer(0x1F80 + gEeprom.MIC_SENSITIVITY, &Mic, 1);
//gEeprom.MIC_SENSITIVITY_TUNING = (Mic < 32) ? Mic : 15;
gEeprom.MIC_SENSITIVITY_TUNING = gMicGain_dB2[gEeprom.MIC_SENSITIVITY];
{
struct
{
int16_t BK4819_XtalFreqLow;
uint16_t EEPROM_1F8A;
uint16_t EEPROM_1F8C;
uint8_t VOLUME_GAIN;
uint8_t DAC_GAIN;
} __attribute__((packed)) Misc;
// radio 1 .. 04 00 46 00 50 00 2C 0E
// radio 2 .. 05 00 46 00 50 00 2C 0E
EEPROM_ReadBuffer(0x1F88, &Misc, 8);
gEeprom.BK4819_XTAL_FREQ_LOW = (Misc.BK4819_XtalFreqLow >= -1000 && Misc.BK4819_XtalFreqLow <= 1000) ? Misc.BK4819_XtalFreqLow : 0;
gEEPROM_1F8A = Misc.EEPROM_1F8A & 0x01FF;
gEEPROM_1F8C = Misc.EEPROM_1F8C & 0x01FF;
gEeprom.VOLUME_GAIN = (Misc.VOLUME_GAIN < 64) ? Misc.VOLUME_GAIN : 58;
gEeprom.DAC_GAIN = (Misc.DAC_GAIN < 16) ? Misc.DAC_GAIN : 8;
BK4819_WriteRegister(BK4819_REG_3B, 22656 + gEeprom.BK4819_XTAL_FREQ_LOW);
// BK4819_WriteRegister(BK4819_REG_3C, gEeprom.BK4819_XTAL_FREQ_HIGH);
}
}
uint32_t SETTINGS_FetchChannelFrequency(const int channel)
{
struct
{
uint32_t frequency;
uint32_t offset;
} __attribute__((packed)) info;
EEPROM_ReadBuffer(channel * 16, &info, sizeof(info));
return info.frequency;
}
void SETTINGS_FetchChannelName(char *s, const int channel)
{
if (s == NULL)
return;
s[0] = 0;
if (channel < 0)
return;
if (!RADIO_CheckValidChannel(channel, false, 0))
return;
EEPROM_ReadBuffer(0x0F50 + (channel * 16), s, 10);
int i;
for (i = 0; i < 10; i++)
if (s[i] < 32 || s[i] > 127)
break; // invalid char
s[i--] = 0; // null term
while (i >= 0 && s[i] == 32) // trim trailing spaces
s[i--] = 0; // null term
}
void SETTINGS_FactoryReset(bool bIsAll)
{
uint16_t i;
uint8_t Template[8];
memset(Template, 0xFF, sizeof(Template));
for (i = 0x0C80; i < 0x1E00; i += 8)
{
if (
!(i >= 0x0EE0 && i < 0x0F18) && // ANI ID + DTMF codes
!(i >= 0x0F30 && i < 0x0F50) && // AES KEY + F LOCK + Scramble Enable
!(i >= 0x1C00 && i < 0x1E00) && // DTMF contacts
!(i >= 0x0EB0 && i < 0x0ED0) && // Welcome strings
!(i >= 0x0EA0 && i < 0x0EA8) && // Voice Prompt
(bIsAll ||
(
!(i >= 0x0D60 && i < 0x0E28) && // MR Channel Attributes
!(i >= 0x0F18 && i < 0x0F30) && // Scan List
!(i >= 0x0F50 && i < 0x1C00) && // MR Channel Names
!(i >= 0x0E40 && i < 0x0E70) && // FM Channels
!(i >= 0x0E88 && i < 0x0E90) // FM settings
))
)
{
EEPROM_WriteBuffer(i, Template);
}
}
if (bIsAll)
{
RADIO_InitInfo(gRxVfo, FREQ_CHANNEL_FIRST + BAND6_400MHz, 43350000);
// set the first few memory channels
for (i = 0; i < ARRAY_SIZE(gDefaultFrequencyTable); i++)
{
const uint32_t Frequency = gDefaultFrequencyTable[i];
gRxVfo->freq_config_RX.Frequency = Frequency;
gRxVfo->freq_config_TX.Frequency = Frequency;
gRxVfo->Band = FREQUENCY_GetBand(Frequency);
SETTINGS_SaveChannel(MR_CHANNEL_FIRST + i, 0, gRxVfo, 2);
}
}
}
#ifdef ENABLE_FMRADIO
void SETTINGS_SaveFM(void)
{
union {
struct {
uint16_t selFreq;
uint8_t selChn;
uint8_t isMrMode:1;
uint8_t band:2;
//uint8_t space:2;
};
uint8_t __raw[8];
} __attribute__((packed)) fmCfg;
memset(fmCfg.__raw, 0xFF, sizeof(fmCfg.__raw));
fmCfg.selChn = gEeprom.FM_SelectedChannel;
fmCfg.selFreq = gEeprom.FM_SelectedFrequency;
fmCfg.isMrMode = gEeprom.FM_IsMrMode;
fmCfg.band = gEeprom.FM_Band;
//fmCfg.space = gEeprom.FM_Space;
EEPROM_WriteBuffer(0x0E88, fmCfg.__raw);
for (unsigned i = 0; i < 5; i++)
EEPROM_WriteBuffer(0x0E40 + (i * 8), &gFM_Channels[i * 4]);
}
#endif
void SETTINGS_SaveVfoIndices(void)
{
uint8_t State[8];
#ifndef ENABLE_NOAA
EEPROM_ReadBuffer(0x0E80, State, sizeof(State));
#endif
State[0] = gEeprom.ScreenChannel[0];
State[1] = gEeprom.MrChannel[0];
State[2] = gEeprom.FreqChannel[0];
State[3] = gEeprom.ScreenChannel[1];
State[4] = gEeprom.MrChannel[1];
State[5] = gEeprom.FreqChannel[1];
#ifdef ENABLE_NOAA
State[6] = gEeprom.NoaaChannel[0];
State[7] = gEeprom.NoaaChannel[1];
#endif
EEPROM_WriteBuffer(0x0E80, State);
}
void SETTINGS_SaveSettings(void)
{
uint8_t State[8];
uint32_t Password[2];
State[0] = gEeprom.CHAN_1_CALL;
State[1] = gEeprom.SQUELCH_LEVEL;
State[2] = gEeprom.TX_TIMEOUT_TIMER;
#ifdef ENABLE_NOAA
State[3] = gEeprom.NOAA_AUTO_SCAN;
#else
State[3] = false;
#endif
State[4] = gEeprom.KEY_LOCK;
#ifdef ENABLE_VOX
State[5] = gEeprom.VOX_SWITCH;
State[6] = gEeprom.VOX_LEVEL;
#else
State[5] = false;
State[6] = 0;
#endif
State[7] = gEeprom.MIC_SENSITIVITY;
EEPROM_WriteBuffer(0x0E70, State);
State[0] = (gEeprom.BACKLIGHT_MIN << 4) + gEeprom.BACKLIGHT_MAX;
State[1] = gEeprom.CHANNEL_DISPLAY_MODE;
State[2] = gEeprom.CROSS_BAND_RX_TX;
State[3] = gEeprom.BATTERY_SAVE;
State[4] = gEeprom.DUAL_WATCH;
State[5] = gEeprom.BACKLIGHT_TIME;
State[6] = gEeprom.TAIL_TONE_ELIMINATION;
State[7] = gEeprom.VFO_OPEN;
EEPROM_WriteBuffer(0x0E78, State);
State[0] = gEeprom.BEEP_CONTROL;
State[0] |= gEeprom.KEY_M_LONG_PRESS_ACTION << 1;
State[1] = gEeprom.KEY_1_SHORT_PRESS_ACTION;
State[2] = gEeprom.KEY_1_LONG_PRESS_ACTION;
State[3] = gEeprom.KEY_2_SHORT_PRESS_ACTION;
State[4] = gEeprom.KEY_2_LONG_PRESS_ACTION;
State[5] = gEeprom.SCAN_RESUME_MODE;
State[6] = gEeprom.AUTO_KEYPAD_LOCK;
State[7] = gEeprom.POWER_ON_DISPLAY_MODE;
EEPROM_WriteBuffer(0x0E90, State);
memset(Password, 0xFF, sizeof(Password));
#ifdef ENABLE_PWRON_PASSWORD
Password[0] = gEeprom.POWER_ON_PASSWORD;
#endif
EEPROM_WriteBuffer(0x0E98, Password);
memset(State, 0xFF, sizeof(State));
#ifdef ENABLE_VOICE
State[0] = gEeprom.VOICE_PROMPT;
#endif
#ifdef ENABLE_RSSI_BAR
State[1] = gEeprom.S0_LEVEL;
State[2] = gEeprom.S9_LEVEL;
#endif
EEPROM_WriteBuffer(0x0EA0, State);
#if defined(ENABLE_ALARM) || defined(ENABLE_TX1750)
State[0] = gEeprom.ALARM_MODE;
#else
State[0] = false;
#endif
State[1] = gEeprom.ROGER;
State[2] = gEeprom.REPEATER_TAIL_TONE_ELIMINATION;
State[3] = gEeprom.TX_VFO;
State[4] = gEeprom.BATTERY_TYPE;
EEPROM_WriteBuffer(0x0EA8, State);
State[0] = gEeprom.DTMF_SIDE_TONE;
#ifdef ENABLE_DTMF_CALLING
State[1] = gEeprom.DTMF_SEPARATE_CODE;
State[2] = gEeprom.DTMF_GROUP_CALL_CODE;
State[3] = gEeprom.DTMF_DECODE_RESPONSE;
State[4] = gEeprom.DTMF_auto_reset_time;
#endif
State[5] = gEeprom.DTMF_PRELOAD_TIME / 10U;
State[6] = gEeprom.DTMF_FIRST_CODE_PERSIST_TIME / 10U;
State[7] = gEeprom.DTMF_HASH_CODE_PERSIST_TIME / 10U;
EEPROM_WriteBuffer(0x0ED0, State);
memset(State, 0xFF, sizeof(State));
State[0] = gEeprom.DTMF_CODE_PERSIST_TIME / 10U;
State[1] = gEeprom.DTMF_CODE_INTERVAL_TIME / 10U;
#ifdef ENABLE_DTMF_CALLING
State[2] = gEeprom.PERMIT_REMOTE_KILL;
#endif
EEPROM_WriteBuffer(0x0ED8, State);
State[0] = gEeprom.SCAN_LIST_DEFAULT;
State[1] = gEeprom.SCAN_LIST_ENABLED[0];
State[2] = gEeprom.SCANLIST_PRIORITY_CH1[0];
State[3] = gEeprom.SCANLIST_PRIORITY_CH2[0];
State[4] = gEeprom.SCAN_LIST_ENABLED[1];
State[5] = gEeprom.SCANLIST_PRIORITY_CH1[1];
State[6] = gEeprom.SCANLIST_PRIORITY_CH2[1];
State[7] = 0xFF;
EEPROM_WriteBuffer(0x0F18, State);
memset(State, 0xFF, sizeof(State));
State[0] = gSetting_F_LOCK;
State[1] = gSetting_350TX;
#ifdef ENABLE_DTMF_CALLING
State[2] = gSetting_KILLED;
#endif
State[3] = gSetting_200TX;
State[4] = gSetting_500TX;
State[5] = gSetting_350EN;
State[6] = gSetting_ScrambleEnable;
//if (!gSetting_TX_EN) State[7] &= ~(1u << 0);
if (!gSetting_live_DTMF_decoder) State[7] &= ~(1u << 1);
State[7] = (State[7] & ~(3u << 2)) | ((gSetting_battery_text & 3u) << 2);
#ifdef ENABLE_AUDIO_BAR
if (!gSetting_mic_bar) State[7] &= ~(1u << 4);
#endif
#ifdef ENABLE_AM_FIX
if (!gSetting_AM_fix) State[7] &= ~(1u << 5);
#endif
State[7] = (State[7] & ~(3u << 6)) | ((gSetting_backlight_on_tx_rx & 3u) << 6);
EEPROM_WriteBuffer(0x0F40, State);
}
void SETTINGS_SaveChannel(uint8_t Channel, uint8_t VFO, const VFO_Info_t *pVFO, uint8_t Mode)
{
#ifdef ENABLE_NOAA
if (IS_NOAA_CHANNEL(Channel))
return;
#endif
uint16_t OffsetVFO = Channel * 16;
if (IS_FREQ_CHANNEL(Channel)) { // it's a VFO, not a channel
OffsetVFO = (VFO == 0) ? 0x0C80 : 0x0C90;
OffsetVFO += (Channel - FREQ_CHANNEL_FIRST) * 32;
}
if (Mode >= 2 || IS_FREQ_CHANNEL(Channel)) { // copy VFO to a channel
union {
uint8_t _8[8];
uint32_t _32[2];
} State;
State._32[0] = pVFO->freq_config_RX.Frequency;
State._32[1] = pVFO->TX_OFFSET_FREQUENCY;
EEPROM_WriteBuffer(OffsetVFO + 0, State._32);
State._8[0] = pVFO->freq_config_RX.Code;
State._8[1] = pVFO->freq_config_TX.Code;
State._8[2] = (pVFO->freq_config_TX.CodeType << 4) | pVFO->freq_config_RX.CodeType;
State._8[3] = (pVFO->Modulation << 4) | pVFO->TX_OFFSET_FREQUENCY_DIRECTION;
State._8[4] = 0
| (pVFO->BUSY_CHANNEL_LOCK << 4)
| (pVFO->OUTPUT_POWER << 2)
| (pVFO->CHANNEL_BANDWIDTH << 1)
| (pVFO->FrequencyReverse << 0);
State._8[5] = ((pVFO->DTMF_PTT_ID_TX_MODE & 7u) << 1)
#ifdef ENABLE_DTMF_CALLING
| ((pVFO->DTMF_DECODING_ENABLE & 1u) << 0)
#endif
;
State._8[6] = pVFO->STEP_SETTING;
State._8[7] = pVFO->SCRAMBLING_TYPE;
EEPROM_WriteBuffer(OffsetVFO + 8, State._8);
SETTINGS_UpdateChannel(Channel, pVFO, true);
if (IS_MR_CHANNEL(Channel)) {
#ifndef ENABLE_KEEP_MEM_NAME
// clear/reset the channel name
SETTINGS_SaveChannelName(Channel, "");
#else
if (Mode >= 3) {
SETTINGS_SaveChannelName(Channel, pVFO->Name);
}
#endif
}
}
}
void SETTINGS_SaveBatteryCalibration(const uint16_t * batteryCalibration)
{
uint16_t buf[4];
EEPROM_WriteBuffer(0x1F40, batteryCalibration);
EEPROM_ReadBuffer( 0x1F48, buf, sizeof(buf));
buf[0] = batteryCalibration[4];
buf[1] = batteryCalibration[5];
EEPROM_WriteBuffer(0x1F48, buf);
}
void SETTINGS_SaveChannelName(uint8_t channel, const char * name)
{
uint16_t offset = channel * 16;
uint8_t buf[16] = {0};
memcpy(buf, name, MIN(strlen(name), 10u));
EEPROM_WriteBuffer(0x0F50 + offset, buf);
EEPROM_WriteBuffer(0x0F58 + offset, buf + 8);
}
void SETTINGS_UpdateChannel(uint8_t channel, const VFO_Info_t *pVFO, bool keep)
{
#ifdef ENABLE_NOAA
if (!IS_NOAA_CHANNEL(channel))
#endif
{
uint8_t state[8];
ChannelAttributes_t att = {
.band = 0xf,
.compander = 0,
.scanlist1 = 0,
.scanlist2 = 0,
}; // default attributes
uint16_t offset = 0x0D60 + (channel & ~7u);
EEPROM_ReadBuffer(offset, state, sizeof(state));
if (keep) {
att.band = pVFO->Band;
att.scanlist1 = pVFO->SCANLIST1_PARTICIPATION;
att.scanlist2 = pVFO->SCANLIST2_PARTICIPATION;
att.compander = pVFO->Compander;
if (state[channel & 7u] == att.__val)
return; // no change in the attributes
}
state[channel & 7u] = att.__val;
EEPROM_WriteBuffer(offset, state);
gMR_ChannelAttributes[channel] = att;
if (IS_MR_CHANNEL(channel)) { // it's a memory channel
if (!keep) {
// clear/reset the channel name
SETTINGS_SaveChannelName(channel, "");
}
}
}
}
void SETTINGS_WriteBuildOptions(void)
{
uint8_t buf[8] = {0};
buf[0] = 0
#ifdef ENABLE_FMRADIO
| (1 << 0)
#endif
#ifdef ENABLE_NOAA
| (1 << 1)
#endif
#ifdef ENABLE_VOICE
| (1 << 2)
#endif
#ifdef ENABLE_VOX
| (1 << 3)
#endif
#ifdef ENABLE_ALARM
| (1 << 4)
#endif
#ifdef ENABLE_TX1750
| (1 << 5)
#endif
#ifdef ENABLE_PWRON_PASSWORD
| (1 << 6)
#endif
#ifdef ENABLE_DTMF_CALLING
| (1 << 7)
#endif
;
buf[1] = 0
#ifdef ENABLE_FLASHLIGHT
| (1 << 0)
#endif
#ifdef ENABLE_WIDE_RX
| (1 << 1)
#endif
#ifdef ENABLE_BYP_RAW_DEMODULATORS
| (1 << 2)
#endif
#ifdef ENABLE_BLMIN_TMP_OFF
| (1 << 3)
#endif
#ifdef ENABLE_AM_FIX
| (1 << 4)
#endif
;
EEPROM_WriteBuffer(0x1FF0, buf);
}