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app.c
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app.c
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#include <stdint.h>
#include "tl_common.h"
#include "drivers.h"
#include "stack/ble/ble.h"
#include "vendor/common/blt_common.h"
#include "cmd_parser.h"
#include "flash_eep.h"
#include "battery.h"
#include "ble.h"
#include "lcd.h"
#include "app.h"
#include "i2c.h"
#include "sensor.h"
#if (DEV_SERVICES & SERVICE_PRESSURE)
#include "hx71x.h"
#endif
#if (DEV_SERVICES & SERVICE_HARD_CLOCK)
#include "rtc.h"
#endif
#include "trigger.h"
#if (DEV_SERVICES & SERVICE_RDS)
#include "rds_count.h"
#endif
#if (DEV_SERVICES & SERVICE_HISTORY)
#include "logger.h"
#endif
#if USE_MIHOME_BEACON
#include "mi_beacon.h"
#endif
#if USE_BTHOME_BEACON
#include "bthome_beacon.h"
#endif
#include "ext_ota.h"
void app_enter_ota_mode(void);
RAM measured_data_t measured_data;
RAM work_flg_t wrk;
//RAM volatile uint8_t tx_measures; // measurement transfer counter, flag
//RAM volatile uint8_t start_measure; // start measurements
//RAM uint8_t flg_measured; // flags = 0xff -> measurements completed
//RAM uint32_t tim_measure; // measurement timer
RAM uint32_t adv_interval; // adv interval in 0.625 ms // = cfg.advertising_interval * 100
RAM uint32_t connection_timeout; // connection timeout in 10 ms, Tdefault = connection_latency_ms * 4 = 2000 * 4 = 8000 ms
RAM uint32_t measurement_step_time; // = adv_interval * measure_interval
RAM uint32_t utc_time_sec; // clock in sec (= 0 1970-01-01 00:00:00)
RAM uint32_t utc_time_sec_tick; // clock counter in 1/16 us
#if (DEV_SERVICES & SERVICE_TIME_ADJUST)
RAM uint32_t utc_time_tick_step = CLOCK_16M_SYS_TIMER_CLK_1S; // adjust time clock (in 1/16 us for 1 sec)
#else
#define utc_time_tick_step CLOCK_16M_SYS_TIMER_CLK_1S
#endif
#if (DEV_SERVICES & SERVICE_KEY) || (DEV_SERVICES & SERVICE_RDS)
RAM ext_key_t ext_key; // extension keys
#endif
#if (DEV_SERVICES & SERVICE_PINCODE)
RAM uint32_t pincode;
#endif
#if (DEV_SERVICES & SERVICE_BINDKEY)
RAM uint8_t bindkey[16];
#endif
#if (DEV_SERVICES & SERVICE_SCREEN)
RAM scomfort_t cmf;
const scomfort_t def_cmf = {
.t = {2100,2600}, // x0.01 C
.h = {3000,6000} // x0.01 %
};
#endif
// Settings
const cfg_t def_cfg = {
.flg.temp_F_or_C = false,
.flg.comfort_smiley = true,
.flg.lp_measures = true,
.flg.advertising_type = ADV_TYPE_DEFAULT,
.rf_tx_power = RF_POWER_P0p04dBm, // RF_POWER_P3p01dBm,
.connect_latency = DEF_CONNECT_LATENCY, // (49+1)*1.25*16 = 1000 ms
#if DEVICE_TYPE == DEVICE_MJWSD05MMC
.advertising_interval = 80, // multiply by 62.5 ms = 5 sec
.flg.comfort_smiley = true,
.measure_interval = 4, // * advertising_interval = 20 sec
.hw_ver = HW_VER_MJWSD05MMC,
#if (DEV_SERVICES & SERVICE_HISTORY)
.averaging_measurements = 90, // * measure_interval = 20 * 90 = 1800 sec = 30 minutes
#endif
#elif DEVICE_TYPE == DEVICE_LYWSD03MMC
.flg2.adv_flags = true,
.advertising_interval = 40, // multiply by 62.5 ms = 2.5 sec
.flg.comfort_smiley = true,
.measure_interval = 4, // * advertising_interval = 10 sec
.min_step_time_update_lcd = 49, //x0.05 sec, 2.45 sec
.hw_ver = HW_VER_LYWSD03MMC_B14,
#if (DEV_SERVICES & SERVICE_HISTORY)
.averaging_measurements = 180, // * measure_interval = 10 * 180 = 1800 sec = 30 minutes
#endif
#elif DEVICE_TYPE == DEVICE_MHO_C401
.flg2.adv_flags = true,
.advertising_interval = 40, // multiply by 62.5 ms = 2.5 sec
.flg.comfort_smiley = true,
.measure_interval = 8, // * advertising_interval = 20 sec
.min_step_time_update_lcd = 99, //x0.05 sec, 4.95 sec
.hw_ver = HW_VER_MHO_C401,
#if (DEV_SERVICES & SERVICE_HISTORY)
.averaging_measurements = 90, // * measure_interval = 20 * 90 = 1800 sec = 30 minutes
#endif
#elif DEVICE_TYPE == DEVICE_MHO_C401N
.flg2.adv_flags = true,
.advertising_interval = 40, // multiply by 62.5 ms = 2.5 sec
.flg.comfort_smiley = true,
.measure_interval = 8, // * advertising_interval = 20 sec
.min_step_time_update_lcd = 99, //x0.05 sec, 4.95 sec
.hw_ver = HW_VER_MHO_C401_2022,
#if (DEV_SERVICES & SERVICE_HISTORY)
.averaging_measurements = 90, // * measure_interval = 20 * 90 = 1800 sec = 30 minutes
#endif
#elif DEVICE_TYPE == DEVICE_CGG1
#if DEVICE_CGG1_ver == 2022
.flg2.adv_flags = true,
.advertising_interval = 40, // multiply by 62.5 ms = 2.5 sec
.flg.comfort_smiley = true,
.measure_interval = 4, // * advertising_interval = 10 sec
.min_step_time_update_lcd = 49, //x0.05 sec, 2.45 sec
.hw_ver = HW_VER_CGG1_2022,
#if (DEV_SERVICES & SERVICE_HISTORY)
.averaging_measurements = 180, // * measure_interval = 10 * 180 = 1800 sec = 30 minutes
#endif
#else
.flg2.adv_flags = true,
.advertising_interval = 40, // multiply by 62.5 ms = 2.5 sec
.flg.comfort_smiley = true,
.measure_interval = 8, // * advertising_interval = 20 sec
.min_step_time_update_lcd = 99, //x0.05 sec, 4.95 sec
.hw_ver = HW_VER_CGG1,
#if (DEV_SERVICES & SERVICE_HISTORY)
.averaging_measurements = 90, // * measure_interval = 20 * 90 = 1800 sec = 30 minutes
#endif
#endif
#elif DEVICE_TYPE == DEVICE_CGDK2
.flg2.adv_flags = true,
.advertising_interval = 40, // multiply by 62.5 ms = 2.5 sec
.flg.comfort_smiley = false,
.measure_interval = 4, // * advertising_interval = 10 sec
.min_step_time_update_lcd = 49, //x0.05 sec, 2.45 sec
.hw_ver = HW_VER_CGDK2,
#if (DEV_SERVICES & SERVICE_HISTORY)
.averaging_measurements = 180, // * measure_interval = 10 * 180 = 1800 sec = 30 minutes
#endif
#elif DEVICE_TYPE == DEVICE_MHO_C122
.flg2.adv_flags = true,
.advertising_interval = 40, // multiply by 62.5 ms = 2.5 sec
.flg.comfort_smiley = true,
.measure_interval = 4, // * advertising_interval = 10 sec
.min_step_time_update_lcd = 49, //x0.05 sec, 2.45 sec
.hw_ver = HW_VER_MHO_C122,
#if (DEV_SERVICES & SERVICE_HISTORY)
.averaging_measurements = 180, // * measure_interval = 10 * 180 = 1800 sec = 30 minutes
#endif
#elif (DEVICE_TYPE == DEVICE_TNK01)
.flg2.adv_flags = true,
.advertising_interval = 24, // multiply by 62.5 ms = 1.5 sec
.measure_interval = 2, // * advertising_interval = 3 sec
.hw_ver = DEVICE_TYPE,
#if (DEV_SERVICES & SERVICE_HISTORY)
.averaging_measurements = 200, // * measure_interval = 3 * 200 = 600 sec = 10 minutes
#endif
#elif (DEVICE_TYPE == DEVICE_TB03F)
.flg2.adv_flags = true,
.advertising_interval = 34, // multiply by 62.5 ms = 2.125 sec
.measure_interval = 4, // * advertising_interval = 8500 sec
.hw_ver = DEVICE_TYPE,
#if (DEV_SERVICES & SERVICE_HISTORY)
.averaging_measurements = 212, // * measure_interval = 8.5 * 212 = 1802 sec = 30 minutes
#endif
#elif (DEVICE_TYPE == DEVICE_TS0201) || (DEVICE_TYPE == DEVICE_TH03Z) || (DEVICE_TYPE == DEVICE_ZTH01) || (DEVICE_TYPE == DEVICE_ZTH02)
.flg2.adv_flags = true,
.advertising_interval = 40, // multiply by 62.5 ms = 2.5 sec
.flg.comfort_smiley = true,
.measure_interval = 4, // * advertising_interval = 10 sec
.hw_ver = DEVICE_TYPE,
#if (DEV_SERVICES & SERVICE_HISTORY)
.averaging_measurements = 180, // * measure_interval = 10 * 180 = 1800 sec = 30 minutes
#endif
#endif
};
RAM cfg_t cfg;
#if (DEV_SERVICES & SERVICE_SCREEN)
static const external_data_t def_ext = {
#if DEVICE_TYPE != DEVICE_MJWSD05MMC
.big_number = 0,
.small_number = 0,
.vtime_sec = 60, // 1 minutes
.flg.smiley = 7, // 7 = "(ooo)"
.flg.percent_on = true,
.flg.battery = false,
.flg.temp_symbol = 5 // 5 = "°C", ... app.h
#else
.number = 1234500,
.vtime_sec = 30, // 30 sec
.flg.smiley = 7, // 7 = "(ooo)"
.flg.battery = false,
.flg.temp_symbol = LCD_SYM_N // 0 = " ", ... app.h
#endif
};
RAM external_data_t ext;
#endif
#if DEVICE_TYPE == DEVICE_LYWSD03MMC
/* 0 - LYWSD03MMC B1.4
3 - LYWSD03MMC B1.9
4 - LYWSD03MMC B1.6
5 - LYWSD03MMC B1.7
10 - LYWSD03MMC B1.5 */
static const uint8_t id2hwver[8] = {
'4','0','5','9','6','7','0','0'
};
#endif // DEVICE_TYPE == DEVICE_LYWSD03MMC
void set_hw_version(void) {
#if DEVICE_TYPE == DEVICE_LYWSD03MMC
/* The version is determined by the addresses of the display and sensor on I2C
HW | LCD I2C addr | SHTxxx I2C addr | Note
-- | -- | -- | --
B1.4 | 0x3C | 0x70 (SHTC3) |
B1.5 | UART! | 0x70 (SHTC3) |
B1.6 | UART! | 0x44 (SHT4x) |
B1.7 | 0x3C | 0x44 (SHT4x) | Test original string HW
B1.9 | 0x3E | 0x44 (SHT4x) |
B2.0 | 0x3C | 0x44 (SHT4x) | Test original string HW
Version 1.7 or 2.0 is determined at first run by reading the HW line written in Flash.
Display matrices or controllers are different for all versions, except B1.7 = B2.0. */
#if (DEV_SERVICES & SERVICE_SCREEN)
#if USE_DEVICE_INFO_CHR_UUID
#else
uint8_t my_HardStr[4];
#endif
uint8_t hwver = 0;
if (lcd_i2c_addr == (B14_I2C_ADDR << 1)) {
// if (cfg.hw_cfg.shtc3) { // sensor SHTC3 ?
if (sensor_cfg.sensor_type == TH_SENSOR_SHTC3) {
hwver = HW_VER_LYWSD03MMC_B14; // HW:B1.4
} else { // sensor SHT4x or ?
hwver = HW_VER_LYWSD03MMC_B17; // HW:B1.7 or B2.0
if(flash_read_cfg(&my_HardStr, EEP_ID_HWV, sizeof(my_HardStr)) == sizeof(my_HardStr)
&& my_HardStr[0] == 'B'
&& my_HardStr[2] == '.') {
if (my_HardStr[1] == '1')
my_HardStr[3] = '7';
else if(my_HardStr[1] == '2') {
my_HardStr[3] = '0';
}
flash_write_cfg(&my_HardStr, EEP_ID_HWV, sizeof(my_HardStr));
return;
}
}
} else {
if (lcd_i2c_addr == (B19_I2C_ADDR << 1))
hwver = HW_VER_LYWSD03MMC_B19; // HW:B1.9
else { // UART
// if(cfg.hw_cfg.shtc3)
if (sensor_cfg.sensor_type == TH_SENSOR_SHTC3)
hwver = HW_VER_LYWSD03MMC_B15; // HW:B1.5
else
hwver = HW_VER_LYWSD03MMC_B16; // HW:B1.6
}
}
my_HardStr[0] = 'B';
my_HardStr[1] = '1';
my_HardStr[2] = '.';
my_HardStr[3] = id2hwver[hwver & 7];
cfg.hw_ver = hwver;
flash_write_cfg(&my_HardStr, EEP_ID_HWV, sizeof(my_HardStr));
#else
cfg.hw_ver = DEVICE_TYPE;
#endif
return;
#elif DEVICE_TYPE == DEVICE_MHO_C401
cfg.hw_ver = HW_VER_MHO_C401;
#elif DEVICE_TYPE == DEVICE_CGG1
#if DEVICE_CGG1_ver == 2022
cfg.hw_ver = HW_VER_CGG1_2022;
#else
cfg.hw_ver = HW_VER_CGG1;
#endif
#elif DEVICE_TYPE == DEVICE_CGDK2
cfg.hw_ver = HW_VER_CGDK2;
#elif DEVICE_TYPE == DEVICE_MHO_C401N
cfg.hw_ver = HW_VER_MHO_C401_2022;
#elif DEVICE_TYPE == DEVICE_MJWSD05MMC
cfg.hw_ver = HW_VER_MJWSD05MMC;
#elif DEVICE_TYPE == DEVICE_MHO_C122
cfg.hw_ver = HW_VER_MHO_C122;
#elif DEVICE_TYPE > HW_VER_EXTENDED
cfg.hw_ver = DEVICE_TYPE;
#else
cfg.hw_ver = HW_VER_EXTENDED;
#endif
}
// go deep-sleep
void go_sleep(uint32_t tik) {
cpu_sleep_wakeup(DEEPSLEEP_MODE, PM_WAKEUP_TIMER,
clock_time() + tik);
while(1);
}
__attribute__((optimize("-Os")))
void test_config(void) {
if (cfg.flg2.longrange)
cfg.flg2.bt5phy = 1;
if (cfg.rf_tx_power & BIT(7)) {
if (cfg.rf_tx_power < RF_POWER_N25p18dBm)
cfg.rf_tx_power = RF_POWER_N25p18dBm;
else if (cfg.rf_tx_power > RF_POWER_P3p01dBm)
cfg.rf_tx_power = RF_POWER_P3p01dBm;
} else {
if (cfg.rf_tx_power < RF_POWER_P3p23dBm)
cfg.rf_tx_power = RF_POWER_P3p23dBm;
else if (cfg.rf_tx_power > RF_POWER_P10p46dBm)
cfg.rf_tx_power = RF_POWER_P10p46dBm;
}
if (cfg.flg.tx_measures)
wrk.tx_measures = 0xff; // always notify
if (cfg.advertising_interval == 0) // 0 ?
cfg.advertising_interval = 1; // 1*62.5 = 62.5 ms
else if (cfg.advertising_interval > 160) // max 160 : 160*62.5 = 10000 ms
cfg.advertising_interval = 160; // 160*62.5 = 10000 ms
adv_interval = cfg.advertising_interval * 100; // Tadv_interval = adv_interval * 62.5 ms , adv_interval in 0.625 ms
// measurement_step_time = adv_interval * 62.5 * measure_interval, max 250 sec
if (cfg.measure_interval < 2)
cfg.measure_interval = 2; // T = cfg.measure_interval * advertising_interval_ms (ms), Tmin = 1 * 1*62.5 = 62.5 ms / 1 * 160 * 62.5 = 10000 ms
measurement_step_time = adv_interval * (uint32_t)cfg.measure_interval;
// test overflow 250 sec
uint32_t tmp = 400000 - adv_interval; // 250000000us/6250=400000
if(measurement_step_time > tmp) {
cfg.measure_interval = tmp / adv_interval;
measurement_step_time = adv_interval * (uint32_t)cfg.measure_interval;
}
measurement_step_time *= (625 * sys_tick_per_us);
measurement_step_time -= 256; // us
if(cfg.connect_latency > DEF_CONNECT_LATENCY
#if USE_AVERAGE_BATTERY
&& measured_data.average_battery_mv < LOW_VBAT_MV)
#else
&& measured_data.battery_mv < LOW_VBAT_MV)
#endif
cfg.connect_latency = DEF_CONNECT_LATENCY;
/* interval = 16;
* connection_interval_ms = (interval * 125) / 100;
* connection_latency_ms = (cfg.connect_latency + 1) * connection_interval_ms = (16*125/100)*(99+1) = 2000;
* connection_timeout_ms = connection_latency_ms * 4 = 2000 * 4 = 8000;
*/
connection_timeout = ((cfg.connect_latency + 1) * (4 * DEF_CON_INERVAL * 125)) / 1000; // = 800, default = 8 sec
if (connection_timeout > 32 * 100)
connection_timeout = 32 * 100; //x10 ms, max 32 sec?
else if (connection_timeout < 100)
connection_timeout = 100; //x10 ms, 1 sec
if (!cfg.connect_latency) {
my_periConnParameters.intervalMin = (cfg.advertising_interval * 625 / 30) - 1; // Tmin = 20*1.25 = 25 ms, Tmax = 3333*1.25 = 4166.25 ms
my_periConnParameters.intervalMax = my_periConnParameters.intervalMin + 5;
my_periConnParameters.latency = 0;
} else {
my_periConnParameters.intervalMin = DEF_CON_INERVAL; // 16*1.25 = 20 ms
my_periConnParameters.intervalMax = DEF_CON_INERVAL; // 16*1.25 = 20 ms
my_periConnParameters.latency = cfg.connect_latency;
}
my_periConnParameters.timeout = connection_timeout;
#if (DEV_SERVICES & SERVICE_SCREEN)
#if DEVICE_TYPE != DEVICE_MJWSD05MMC
#if USE_EPD
if (cfg.min_step_time_update_lcd < USE_EPD) // min 0.5 sec: (10*50ms)
cfg.min_step_time_update_lcd = USE_EPD;
#endif
if (cfg.min_step_time_update_lcd < 10) // min 0.5 sec: (10*50ms)
cfg.min_step_time_update_lcd = 10;
lcd_flg.min_step_time_update_lcd = cfg.min_step_time_update_lcd * (50 * CLOCK_16M_SYS_TIMER_CLK_1MS);
#endif
#endif // (DEV_SERVICES & SERVICE_SCREEN)
set_hw_version();
my_RxTx_Data[0] = CMD_ID_CFG;
my_RxTx_Data[1] = VERSION;
memcpy(&my_RxTx_Data[2], &cfg, sizeof(cfg));
}
void low_vbat(void) {
#if (DEV_SERVICES & RDS)
rds1_input_off();
#endif
#if (DEV_SERVICES & SERVICE_SCREEN)
#if DEVICE_TYPE == DEVICE_MJWSD05MMC
show_low_bat();
#else
#if (USE_EPD)
while(task_lcd()) pm_wait_ms(10);
#endif
show_temp_symbol(0);
#if (DEVICE_TYPE != DEVICE_CGDK2)
show_smiley(0);
#endif
show_big_number_x10(measured_data.battery_mv * 10);
#if (DEVICE_TYPE == DEVICE_CGG1) || (DEVICE_TYPE == DEVICE_CGDK2)
show_small_number_x10(-1023, 1); // "Lo"
#else
show_small_number(-123, 1); // "Lo"
#endif
show_battery_symbol(1);
update_lcd();
#if (USE_EPD)
while(task_lcd()) pm_wait_ms(10);
#endif // USE_EPD
#endif // DEVICE_TYPE == DEVICE_MJWSD05MMC
#endif // (DEV_SERVICES & SERVICE_SCREEN)
go_sleep(120 * CLOCK_16M_SYS_TIMER_CLK_1S); // go deep-sleep 2 minutes
}
#if (DEV_SERVICES & SERVICE_THS) || (DEV_SERVICES & SERVICE_IUS)
#if SENSOR_SLEEP_MEASURE
_attribute_ram_code_
void WakeupLowPowerCb(int par) {
(void) par;
if (sensor_cfg.time_measure) {
#else
_attribute_ram_code_
void read_sensors(void) {
#endif
#if (DEV_SERVICES & SERVICE_RDS)
rds_input_on();
#endif
#if (defined(CHL_ADC1) || defined(CHL_ADC1))
if (1) {
#else
if (read_sensor_cb()) {
#endif
#ifdef CHL_ADC1 // DIY version only!
measured_data.temp = get_adc_mv(CHL_ADC1);
#endif
#ifdef CHL_ADC2 // DIY version only!
measured_data.humi = get_adc_mv(CHL_ADC2);
#endif
#if (DEV_SERVICES & SERVICE_THS)
measured_data.temp_x01 = (measured_data.temp + 5)/ 10;
measured_data.humi_x01 = (measured_data.humi + 5)/ 10;
measured_data.humi_x1 = (measured_data.humi + 50)/ 100;
#endif
#if (DEV_SERVICES & SERVICE_TH_TRG)
set_trigger_out();
#endif
#if (DEV_SERVICES & SERVICE_HISTORY)
if (cfg.averaging_measurements)
write_memo();
#endif
#if (DEV_SERVICES & SERVICE_BINDKEY) && USE_MIHOME_BEACON
if ((cfg.flg.advertising_type == ADV_TYPE_MI) && cfg.flg2.adv_crypto)
mi_beacon_summ();
#endif
}
#if (DEV_SERVICES & SERVICE_RDS)
if (trg.rds.type1 == RDS_NONE) {
trg.flg.rds1_input = get_rds1_input();
rds1_input_off();
}
#ifdef GPIO_RDS2
if (trg.rds.type2 == RDS_NONE) {
trg.flg.rds2_input = get_rds2_input();
rds2_input_off();
}
#endif
#endif
wrk.msc.all_flgs = 0xff;
#if (DEVICE_TYPE == DEVICE_MJWSD05MMC)
SET_LCD_UPDATE();
#endif
#if SENSOR_SLEEP_MEASURE
sensor_cfg.time_measure = 0;
}
bls_pm_setAppWakeupLowPower(0, 0); // clear callback
#endif
}
#endif
_attribute_ram_code_
static void suspend_exit_cb(u8 e, u8 *p, int n) {
(void) e; (void) p; (void) n;
rf_set_power_level_index(cfg.rf_tx_power);
}
#if (DEV_SERVICES & SERVICE_KEY) || (DEV_SERVICES & SERVICE_RDS) // || (USE_SENSOR_HX71X)
_attribute_ram_code_
static void suspend_enter_cb(u8 e, u8 *p, int n) {
(void) e; (void) p; (void) n;
#if (DEV_SERVICES & SERVICE_RDS)
if(trg.rds.type1 != RDS_NONE)
cpu_set_gpio_wakeup(GPIO_RDS1, BM_IS_SET(reg_gpio_in(GPIO_RDS1), GPIO_RDS1 & 0xff)? Level_Low : Level_High, 1); // pad wakeup deepsleep enable
// else
// cpu_set_gpio_wakeup(GPIO_RDS1, Level_Low, 0); // pad wakeup deepsleep disable
#ifdef GPIO_RDS2
if(trg.rds.type2 != RDS_NONE)
cpu_set_gpio_wakeup(GPIO_RDS2, BM_IS_SET(reg_gpio_in(GPIO_RDS2), GPIO_RDS2 & 0xff)? Level_Low : Level_High, 1); // pad wakeup deepsleep enable
// else
// cpu_set_gpio_wakeup(GPIO_RDS2, Level_Low, 0); // pad wakeup deepsleep disable
#endif
#endif
#if (DEV_SERVICES & SERVICE_KEY)
cpu_set_gpio_wakeup(GPIO_KEY2, BM_IS_SET(reg_gpio_in(GPIO_KEY2), GPIO_KEY2 & 0xff)? Level_Low : Level_High, 1); // pad wakeup deepsleep enable
#endif // (DEV_SERVICES & SERVICE_KEY)
bls_pm_setWakeupSource(PM_WAKEUP_PAD | PM_WAKEUP_TIMER); // gpio pad wakeup suspend/deepsleep
}
#endif // (DEV_SERVICES & SERVICE_KEY) || (DEV_SERVICES & SERVICE_RDS)
#if USE_AVERAGE_BATTERY
//--- check battery
#define BAT_AVERAGE_SHL 4 // 16*16 = 256 ( 256*10/60 = 42.7 min)
#define BAT_AVERAGE_COUNT (1 << BAT_AVERAGE_SHL) // 8
RAM struct {
uint32_t buf2[BAT_AVERAGE_COUNT];
uint16_t buf1[BAT_AVERAGE_COUNT];
uint8_t index1;
uint8_t index2;
} bat_average;
#endif
_attribute_ram_code_
__attribute__((optimize("-Os")))
void check_battery(void) {
measured_data.battery_mv = get_battery_mv();
if (measured_data.battery_mv < END_VBAT_MV) // It is not recommended to write Flash below 2V
low_vbat();
#if USE_AVERAGE_BATTERY
uint32_t i;
uint32_t summ = 0;
bat_average.index1++;
bat_average.index1 &= BAT_AVERAGE_COUNT - 1;
if(bat_average.index1 == 0) {
bat_average.index2++;
bat_average.index2 &= BAT_AVERAGE_COUNT - 1;
}
bat_average.buf1[bat_average.index1] = measured_data.battery_mv;
for(i = 0; i < BAT_AVERAGE_COUNT; i++)
summ += bat_average.buf1[i];
bat_average.buf2[bat_average.index2] = summ;
summ = 0;
for(i = 0; i < BAT_AVERAGE_COUNT; i++)
summ += bat_average.buf2[i];
measured_data.average_battery_mv = summ >> (2*BAT_AVERAGE_SHL);
measured_data.battery_level = get_battery_level(measured_data.average_battery_mv);
#endif
}
__attribute__((optimize("-Os")))
static void start_tst_battery(void) {
uint16_t avr_mv = get_battery_mv();
measured_data.battery_mv = avr_mv;
if (avr_mv < MIN_VBAT_MV) { // 2.2V
#if USE_SENSOR_SHTC3
send_i2c_word(0x70 << 1, 0x98b0); // SHTC3 go SLEEP: Sleep command of the sensor
#endif // USE_SENSOR_SHTC3
#if (DEVICE_TYPE == DEVICE_LYWSD03MMC) || (DEVICE_TYPE == DEVICE_CGDK2) || (DEVICE_TYPE == DEVICE_MJWSD05MMC) || (DEVICE_TYPE == DEVICE_MHO_C122)
// Set sleep power < 1 uA
send_i2c_byte(0x3E << 1, 0xEA); // BU9792AFUV reset
#endif
go_sleep(120 * CLOCK_16M_SYS_TIMER_CLK_1S); // go deep-sleep 2 minutes
}
#if USE_AVERAGE_BATTERY
int i;
measured_data.average_battery_mv = avr_mv;
for(i = 0; i < BAT_AVERAGE_COUNT; i++)
bat_average.buf1[i] = avr_mv;
avr_mv <<= BAT_AVERAGE_SHL;
for(i = 0; i < BAT_AVERAGE_COUNT; i++)
bat_average.buf2[i] = avr_mv;
#endif
}
#if (DEV_SERVICES & SERVICE_BINDKEY)
void bindkey_init(void) {
if (flash_read_cfg(bindkey, EEP_ID_KEY, sizeof(bindkey))
!= sizeof(bindkey)) {
generateRandomNum(sizeof(bindkey), bindkey);
flash_write_cfg(bindkey, EEP_ID_KEY, sizeof(bindkey));
}
#if USE_MIHOME_BEACON
mi_beacon_init();
#endif // USE_MIHOME_BEACON
#if USE_BTHOME_BEACON
bthome_beacon_init();
#endif
}
#endif // #if (DEV_SERVICES & SERVICE_BINDKEY)
#if (DEV_SERVICES & SERVICE_KEY) || (DEV_SERVICES & SERVICE_RDS)
void set_default_cfg(void) {
memcpy(&cfg, &def_cfg, sizeof(cfg));
test_config();
flash_write_cfg(&cfg, EEP_ID_CFG, sizeof(cfg));
SHOW_REBOOT_SCREEN();
go_sleep(2*CLOCK_16M_SYS_TIMER_CLK_1S); // go deep-sleep 2 sec
}
#endif // (DEV_SERVICES & SERVICE_KEY) || (DEV_SERVICES & SERVICE_RDS)
//=========================================================
//-------------------- user_init_normal -------------------
void user_init_normal(void) {//this will get executed one time after power up
bool next_start = false;
unsigned int old_ver;
adc_power_on_sar_adc(0); // - 0.4 mA
lpc_power_down();
blc_ll_initBasicMCU(); //must
start_tst_battery();
flash_unlock();
random_generator_init(); //must
#if !ZIGBEE_TUYA_OTA // USE_EXT_OTA
big_to_low_ota(); // Correct FW OTA address? Reformat Big OTA to Low OTA
#endif
#if defined(MI_HW_VER_FADDR) && (MI_HW_VER_FADDR)
uint32_t hw_ver = get_mi_hw_version();
#endif // (DEVICE_TYPE == DEVICE_LYWSD03MMC) || (DEVICE_TYPE == DEVICE_MJWSD05MMC)
// Read config
if(flash_read_cfg(&old_ver, EEP_ID_VER, sizeof(old_ver)) != sizeof(old_ver))
old_ver = 0;
next_start = flash_supported_eep_ver(EEP_SUP_VER, VERSION);
if (next_start) {
if (flash_read_cfg(&cfg, EEP_ID_CFG, sizeof(cfg)) != sizeof(cfg))
memcpy(&cfg, &def_cfg, sizeof(cfg));
#if (DEV_SERVICES & SERVICE_SCREEN)
if (flash_read_cfg(&cmf, EEP_ID_CMF, sizeof(cmf)) != sizeof(cmf))
memcpy(&cmf, &def_cmf, sizeof(cmf));
#endif
#if (DEV_SERVICES & SERVICE_TIME_ADJUST)
if (flash_read_cfg(&utc_time_tick_step, EEP_ID_TIM,
sizeof(utc_time_tick_step)) != sizeof(utc_time_tick_step))
utc_time_tick_step = CLOCK_16M_SYS_TIMER_CLK_1S;
#endif
#if (DEV_SERVICES & SERVICE_PINCODE)
if (flash_read_cfg(&pincode, EEP_ID_PCD, sizeof(pincode))
!= sizeof(pincode))
pincode = 0;
#endif
#if (DEV_SERVICES & SERVICE_TH_TRG)
if (flash_read_cfg(&trg, EEP_ID_TRG, FEEP_SAVE_SIZE_TRG)
!= FEEP_SAVE_SIZE_TRG)
memcpy(&trg, &def_trg, FEEP_SAVE_SIZE_TRG);
#endif
#if (DEV_SERVICES & SERVICE_THS) || (DEV_SERVICES & SERVICE_IUS)
if (flash_read_cfg(&sensor_cfg.coef, EEP_ID_CFS, sizeof(sensor_cfg.coef))
!= sizeof(sensor_cfg.coef))
memset(&sensor_cfg.coef, 0, sizeof(sensor_cfg.coef));
#endif
#if (DEV_SERVICES & SERVICE_PRESSURE) && USE_SENSOR_HX71X
if (flash_read_cfg(&hx71x.cfg, EEP_ID_HXC, sizeof(hx71x.cfg))
!= sizeof(hx71x.cfg))
memcpy(&hx71x.cfg, &def_hx71x_cfg, sizeof(hx71x.cfg));
#endif
// if version < 4.2 -> clear cfg.flg2.longrange
if (old_ver <= 0x41) {
cfg.flg2.longrange = 0;
flash_write_cfg(&cfg, EEP_ID_CFG, sizeof(cfg));
}
} else {
#if (DEV_SERVICES & SERVICE_PINCODE)
pincode = 0;
#endif
memcpy(&cfg, &def_cfg, sizeof(cfg));
#if (DEV_SERVICES & SERVICE_SCREEN)
memcpy(&cmf, &def_cmf, sizeof(cmf));
#endif
#if (DEV_SERVICES & SERVICE_TH_TRG)
memcpy(&trg, &def_trg, FEEP_SAVE_SIZE_TRG);
#endif
#if (DEV_SERVICES & SERVICE_PRESSURE) && USE_SENSOR_HX71X
memcpy(&hx71x.cfg, &def_hx71x_cfg, sizeof(hx71x.cfg));
#endif
#if defined(MI_HW_VER_FADDR) && (MI_HW_VER_FADDR)
if (hw_ver)
flash_write_cfg(&hw_ver, EEP_ID_HWV, sizeof(hw_ver));
#endif
}
#if (DEV_SERVICES & SERVICE_RDS)
rds_init();
#endif
init_i2c();
reg_i2c_speed = (uint8_t)(CLOCK_SYS_CLOCK_HZ/(4*100000)); // 100 kHz
test_config();
#if (POWERUP_SCREEN) || (DEV_SERVICES & SERVICE_HARD_CLOCK) || (DEV_SERVICES & SERVICE_LE_LR)
if(analog_read(DEEP_ANA_REG0) != 0x55) {
#if (DEV_SERVICES & SERVICE_LE_LR)
cfg.flg2.longrange = 0;
flash_write_cfg(&cfg, EEP_ID_CFG, sizeof(cfg));
#endif // #if (DEV_SERVICES & SERVICE_LE_LR)
analog_write(DEEP_ANA_REG0, 0x55);
#if (DEV_SERVICES & SERVICE_HARD_CLOCK)
#if POWERUP_SCREEN
init_lcd();
SHOW_REBOOT_SCREEN();
#endif // POWERUP_SCREEN
// RTC wakes up after powering on > 1 second.
go_sleep(1500*CLOCK_16M_SYS_TIMER_CLK_1MS); // go deep-sleep 1.5 sec
#endif // SHOW_REBOOT_SCREEN || (DEV_SERVICES & SERVICE_HARD_CLOCK)
}
#endif // POWERUP_SCREEN || (DEV_SERVICES & SERVICE_HARD_CLOCK) || (DEV_SERVICES & SERVICE_LE_LR)
#if (DEV_SERVICES & SERVICE_SCREEN)
memcpy(&ext, &def_ext, sizeof(ext));
#endif
init_ble();
bls_app_registerEventCallback(BLT_EV_FLAG_SUSPEND_EXIT, &suspend_exit_cb);
#if (DEV_SERVICES & SERVICE_KEY) || (DEV_SERVICES & SERVICE_RDS) || (USE_SENSOR_HX71X)
bls_app_registerEventCallback(BLT_EV_FLAG_SUSPEND_ENTER, &suspend_enter_cb);
#endif
// start_tst_battery(); // step 2
#if (DEV_SERVICES & SERVICE_THS) || (DEV_SERVICES & SERVICE_IUS)
init_sensor();
#endif
#if USE_SENSOR_HX71X && (DEV_SERVICES & SERVICE_PRESSURE)
hx711_gpio_wakeup();
hx71x_get_data(HX71XMODE_A128);
#endif
#if (DEV_SERVICES & SERVICE_HISTORY)
memo_init();
#endif
#if (DEV_SERVICES & SERVICE_HARD_CLOCK)
init_rtc();
#endif
init_lcd();
set_hw_version();
#if defined(GPIO_ADC1) || defined(GPIO_ADC2)
sensor_go_sleep();
#endif
#if (DEV_SERVICES & SERVICE_BINDKEY)
bindkey_init();
#endif
check_battery();
#if USE_SENSOR_HX71X && (DEV_SERVICES & SERVICE_PRESSURE)
hx71x_task();
#endif
lcd();
#if (!USE_EPD)
// update_lcd();
#endif
if (!next_start) { // first start?
flash_write_cfg(&cfg, EEP_ID_CFG, sizeof(cfg));
}
test_config();
#if defined(MI_HW_VER_FADDR) && (MI_HW_VER_FADDR)
set_SerialStr();
#endif
wrk.start_measure = 1;
bls_pm_setManualLatency(0);
}
//=========================================================
//------------------ user_init_deepRetn -------------------
_attribute_ram_code_
void user_init_deepRetn(void) {//after sleep this will get executed
blc_ll_initBasicMCU();
rf_set_power_level_index(cfg.rf_tx_power);
blc_ll_recoverDeepRetention();
bls_ota_registerStartCmdCb(app_enter_ota_mode);
}
//=========================================================
//----------------------- main_loop() ---------------------
_attribute_ram_code_
void main_loop(void) {
blt_sdk_main_loop();
while (clock_time() - utc_time_sec_tick > utc_time_tick_step) {
utc_time_sec_tick += utc_time_tick_step;
utc_time_sec++; // + 1 sec
#if (DEV_SERVICES & SERVICE_HARD_CLOCK)
if(++rtc.seconds >= 60) {
rtc.seconds = 0;
if(++rtc.minutes >= 60) {
rtc.minutes = 0;
rtc_sync_utime = utc_time_sec;
}
SET_LCD_UPDATE();
}
#endif
}
#if SENSOR_SLEEP_MEASURE
if(sensor_cfg.time_measure && clock_time() - sensor_cfg.time_measure > sensor_cfg.measure_timeout)
WakeupLowPowerCb(0);
#endif
if (wrk.ota_is_working) {
#if (DEV_SERVICES & SERVICE_OTA_EXT)
if(wrk.ota_is_working == OTA_EXTENDED) {
bls_pm_setManualLatency(3);
clear_ota_area();
} else
#endif
{
if ((wrk.ble_connected & BIT(CONNECTED_FLG_PAR_UPDATE))==0)
bls_pm_setManualLatency(0);
}
bls_pm_setSuspendMask (SUSPEND_ADV | SUSPEND_CONN);
} else {
#if (DEV_SERVICES & SERVICE_RDS)
#ifndef GPIO_RDS2
if(trg.rds.type1 != RDS_NONE) // rds: switch or counter
#endif
rds_task();
#endif
#if USE_SENSOR_HX71X && (DEV_SERVICES & SERVICE_PRESSURE)
hx71x_task();
#endif
uint32_t new = clock_time();
#if (DEV_SERVICES & SERVICE_KEY)
if(!get_key2_pressed()) {
if(!ext_key.key2pressed) {
// key2 on
ext_key.key2pressed = 1;
ext_key.key_pressed_tik1 = new;
ext_key.key_pressed_tik2 = new;
set_adv_con_time(0); // set connection adv.
SET_LCD_UPDATE();
#if (DEV_SERVICES & SERVICE_RDS) || (DEV_SERVICES & SERVICE_TH_TRG)
trg.flg.key_pressed = 1;
#endif
#if (DEV_SERVICES & SERVICE_LED)
gpio_setup_up_down_resistor(GPIO_LED, PM_PIN_PULLUP_10K);
#endif
}
else {
if(new - ext_key.key_pressed_tik1 > 1750*CLOCK_16M_SYS_TIMER_CLK_1MS) {
ext_key.key_pressed_tik1 = new;
#if (DEVICE_TYPE == DEVICE_MJWSD05MMC)
if(++cfg.flg2.screen_type > SCR_TYPE_EXT)
cfg.flg2.screen_type = SCR_TYPE_TIME;
#elif (DEV_SERVICES & SERVICE_SCREEN)
cfg.flg.temp_F_or_C ^= 1;
#endif
if(ext_key.rest_adv_int_tad) {
set_adv_con_time(1); // restore default adv.
ext_key.rest_adv_int_tad = 0;
}
SET_LCD_UPDATE();
#if (DEV_SERVICES & SERVICE_LED)
gpio_setup_up_down_resistor(GPIO_LED, PM_PIN_PULLDOWN_100K);
#endif
}
#ifdef GPIO_KEY1
if(new - ext_key.key_pressed_tik2 > 5*CLOCK_16M_SYS_TIMER_CLK_1S) {
if((reg_gpio_in(GPIO_KEY1) & (GPIO_KEY1 & 0xff))==0)
#else
if(new - ext_key.key_pressed_tik2 > 7*CLOCK_16M_SYS_TIMER_CLK_1S) {
#endif
set_default_cfg();
#if (DEV_SERVICES & SERVICE_RDS) || (DEV_SERVICES & SERVICE_TH_TRG)
trg.flg.key_pressed = 0;
#endif
#if (DEV_SERVICES & SERVICE_LED)
gpio_setup_up_down_resistor(GPIO_LED, PM_PIN_PULLUP_10K);
#endif
}
}
}
else {
// key2 off
ext_key.key2pressed = 0;
ext_key.key_pressed_tik1 = new;
ext_key.key_pressed_tik2 = new;
#if (DEV_SERVICES & SERVICE_LED)
gpio_setup_up_down_resistor(GPIO_LED, PM_PIN_PULLDOWN_100K);
#endif
}
#endif // (DEV_SERVICES & SERVICE_KEY)
#if (DEV_SERVICES & SERVICE_KEY) || (DEV_SERVICES & SERVICE_RDS)
if(ext_key.rest_adv_int_tad < -80) {
set_adv_con_time(1); // restore default adv.
SET_LCD_UPDATE();
}
#endif
#if SENSOR_SLEEP_MEASURE
if (wrk.start_measure
&& sensor_cfg.time_measure == 0
// && bls_pm_getSystemWakeupTick() - new > sensor_cfg.measure_timeout + 5*CLOCK_16M_SYS_TIMER_CLK_1MS // есть время на замер ?
) {
wrk.start_measure = 0;
bls_pm_setSuspendMask(SUSPEND_DISABLE);
#if defined(GPIO_ADC1) || defined(GPIO_ADC2)
check_battery();
WakeupLowPowerCb(0);
#else
check_battery();
start_measure_sensor_deep_sleep();
#if (DEV_SERVICES & SERVICE_PRESSURE)
measured_data.pressure = hx71x_get_volume();
#endif
if(cfg.flg.lp_measures == 0
#if USE_SENSOR_SHTC3
|| sensor_cfg.sensor_type == TH_SENSOR_SHTC3
#endif
) {
if(clock_time() - sensor_cfg.time_measure > sensor_cfg.measure_timeout - 3)
WakeupLowPowerCb(0);
else {
bls_pm_registerAppWakeupLowPowerCb(WakeupLowPowerCb);
bls_pm_setAppWakeupLowPower(sensor_cfg.time_measure + sensor_cfg.measure_timeout, 1);
}
}
#endif
} else
#else // ! SENSOR_SLEEP_MEASURE
if (wrk.start_measure) {
wrk.start_measure = 0;
check_battery();
read_sensors();
#if (DEV_SERVICES & SERVICE_PRESSURE)
measured_data.pressure = hx71x_get_volume();
#endif
} else
#endif
{
if (wrk.ble_connected && blc_ll_getTxFifoNumber() < 9) {
// if ble_connected & TxFifo ready
if (wrk.msc.b.send_measure) {
wrk.msc.b.send_measure = 0;
if (RxTxValueInCCC && wrk.tx_measures) {
if (wrk.tx_measures != 0xff)
wrk.tx_measures--;
ble_send_measures();
}
if (batteryValueInCCC)
ble_send_battery();
#if (DEV_SERVICES & SERVICE_THS)
if (tempValueInCCC)
ble_send_temp();
if (temp2ValueInCCC)
ble_send_temp2();
if (humiValueInCCC)
ble_send_humi();
#endif
#if (DEV_SERVICES & SERVICE_IUS)
if (anaValueInCCC)
ble_send_ana();
#endif
#if (DEV_SERVICES & SERVICE_HISTORY)
} else if (rd_memo.cnt) {
send_memo_blk();
#endif
#if (DEV_SERVICES & SERVICE_MI_KEYS)
} else if (mi_key_stage) {
mi_key_stage = get_mi_keys(mi_key_stage);
#endif
#if (DEV_SERVICES & SERVICE_SCREEN)
} else if (RxTxValueInCCC) {
if (lcd_flg.b.send_notify) {
// LCD for send notify
lcd_flg.b.send_notify = 0;
ble_send_lcd();
}
#endif
}
}
#if (DEV_SERVICES & SERVICE_HARD_CLOCK)
else if(rtc_sync_utime) {
rtc_sync_utime = 0;
utc_time_sec = rtc_get_utime();
}
#endif // (DEV_SERVICES & SERVICE_HARD_CLOCK)
#if (DEV_SERVICES & SERVICE_THS) || (DEV_SERVICES & SERVICE_IUS)
#if SENSOR_SLEEP_MEASURE
if(sensor_cfg.time_measure == 0)
#endif
{
if(wrk.ble_connected) {
if (new - wrk.tim_measure >= measurement_step_time) {
wrk.tim_measure = new;
adv_buf.meas_count = 0;
wrk.start_measure = 1;
}
}
}
#endif
#if (DEV_SERVICES & SERVICE_SCREEN)
if(!cfg.flg2.screen_off) {
#if (USE_EPD)
if ((!stage_lcd) && (new - lcd_flg.tim_last_chow >= lcd_flg.min_step_time_update_lcd)) {
lcd_flg.tim_last_chow = new;
lcd_flg.show_stage++;
if(lcd_flg.update_next_measure) {
lcd_flg.update = wrk.msc.b.update_lcd;
wrk.msc.b.update_lcd = 0;
} else