/**
* Dim the screen if necessary. Called by the Controller. Will dim in
* several steps (one dim level at each call)
*/
void Controller::do_dimming() {
if(m_never_dim) return;
// only dim if not in brightness changing mode
if(!m_dim_off) {
// Check for no key presses then dim screen
uint32_t release_time = cap_last_press_any();
uint32_t press_time = cap_last_release_any();
uint32_t current_time = realtime_get_unixtime();
uint8_t current_brightness = display_get_brightness();
if(((current_time - press_time) > 10) && ((current_time - release_time) > 10)) {
if(current_brightness > 1) display_set_brightness(current_brightness-1);
} else {
const char *sbright = flashstorage_keyval_get("BRIGHTNESS");
unsigned int user_brightness=15;
if(sbright != 0) {
sscanf(sbright, "%u", &user_brightness);
}
if(current_brightness < user_brightness) {
display_set_brightness(current_brightness+1);
}
}
}
}
irom static app_action_t application_function_display_brightness(application_parameters_t ap)
{
int8_t id;
int8_t value;
static const char *usage = "display-brightness: usage: display_id <brightess>=0,1,2,3,4\n";
id = (uint8_t)atoi((*ap.args)[1]);
if(ap.nargs > 2)
{
value = (uint8_t)atoi((*ap.args)[2]);
if(!display_set_brightness(id, value))
{
snprintf(ap.dst, ap.size, "%s", usage);
return(app_action_error);
}
}
if(!display_get_brightness(id, &value))
{
snprintf(ap.dst, ap.size, "%s", usage);
return(app_action_error);
}
snprintf(ap.dst, ap.size, "display %u brightness: %u\n", id, value);
return(app_action_normal);
}
void Controller::event_varnum_brightness(const char *event,const char *value) {
int b = m_gui->get_item_state_uint8("BRIGHTNESS");
m_dim_off=true;
int br;
if(b<= 5) br = (b*2) +1;
if(b> 5) br = b+6;
display_set_brightness(br);
}
void Controller::event_leftbrightness(const char *event,const char *value) {
const char *sbright = flashstorage_keyval_get("BRIGHTNESS");
if(sbright != 0) {
unsigned int c;
sscanf(sbright, "%u", &c);
display_set_brightness(c);
}
m_dim_off=false;
}
void Controller::event_brightnessscn(const char *event,const char *value) {
const char *sbright = flashstorage_keyval_get("BRIGHTNESS");
unsigned int c=15;
if(sbright != 0) {
sscanf(sbright, "%u", &c);
display_set_brightness(c);
}
uint8 b;
if(c <= 11) b = (c-1)/2;
if(c > 11) b = c-6;
m_gui->receive_update("BRIGHTNESS",&b);
m_gui->redraw();
}
void Controller::event_save_brightness(const char *event,const char *value) {
uint8 b = m_gui->get_item_state_uint8("BRIGHTNESS");
int br;
if(b<= 5) br = (b*2) +1;
if(b> 5) br = b+6;
display_set_brightness(br);
char sbright[50];
sprintf(sbright,"%u",br);
flashstorage_keyval_set("BRIGHTNESS",sbright);
m_dim_off=false;
m_gui->jump_to_screen(0);
}
void Controller::initialise_calibration() {
m_dim_off=true;
display_set_brightness(15);
m_calibration_base = system_geiger->get_microsieverts_nocal();
char text_sieverts[50];
float_to_char(m_calibration_base*system_geiger->get_calibration(),text_sieverts,5);
text_sieverts[5] = ' ';
text_sieverts[6] = '\x80';
text_sieverts[7] = 'S';
text_sieverts[8] = 'v';
text_sieverts[9] = 0;
m_gui->receive_update("FIXEDSV",text_sieverts);
uint8_t c1=system_geiger->get_calibration();
uint8_t c2=((uint32_t)(system_geiger->get_calibration()*10))%10;
uint8_t c3=((uint32_t)(system_geiger->get_calibration()*100))%10;
uint8_t c4=((uint32_t)(system_geiger->get_calibration()*1000))%10;
m_gui->receive_update("CAL1",&c1);
m_gui->receive_update("CAL2",&c2);
m_gui->receive_update("CAL3",&c3);
m_gui->receive_update("CAL4",&c4);
}
/*-------------------------------------------------------------------------------------------------------------------------------------------
* main function
*-------------------------------------------------------------------------------------------------------------------------------------------
*/
int
main ()
{
static uint_fast8_t last_ldr_value = 0xFF;
struct tm tm;
LISTENER_DATA lis;
ESP8266_INFO * esp8266_infop;
uint_fast8_t esp8266_is_up = 0;
uint_fast8_t code;
#if SAVE_RAM == 0
IRMP_DATA irmp_data;
uint32_t stop_time;
uint_fast8_t cmd;
#endif
uint_fast8_t status_led_cnt = 0;
uint_fast8_t display_flag = DISPLAY_FLAG_UPDATE_ALL;
uint_fast8_t show_temperature = 0;
uint_fast8_t time_changed = 0;
uint_fast8_t power_is_on = 1;
uint_fast8_t night_power_is_on = 1;
uint_fast8_t ldr_value;
uint_fast8_t ap_mode = 0;
SystemInit ();
SystemCoreClockUpdate(); // needed for Nucleo board
#if defined (STM32F103) // disable JTAG to get back PB3, PB4, PA13, PA14, PA15
RCC_APB2PeriphClockCmd(RCC_APB2Periph_AFIO, ENABLE); // turn on clock for the alternate function register
GPIO_PinRemapConfig(GPIO_Remap_SWJ_JTAGDisable, ENABLE); // disable the JTAG, enable the SWJ interface
#endif
log_init (); // initilize logger on uart
#if SAVE_RAM == 0
irmp_init (); // initialize IRMP
#endif
timer2_init (); // initialize timer2 for IRMP, DCF77, EEPROM etc.
delay_init (DELAY_RESOLUTION_1_US); // initialize delay functions with granularity of 1 us
board_led_init (); // initialize GPIO for green LED on disco or nucleo board
button_init (); // initialize GPIO for user button on disco or nucleo board
rtc_init (); // initialize I2C RTC
eeprom_init (); // initialize I2C EEPROM
if (button_pressed ()) // set ESP8266 into flash mode
{
board_led_on ();
esp8266_flash ();
}
log_msg ("\r\nWelcome to WordClock Logger!");
log_msg ("----------------------------");
log_str ("Version: ");
log_msg (VERSION);
if (rtc_is_up)
{
log_msg ("rtc is online");
}
else
{
log_msg ("rtc is offline");
}
if (eeprom_is_up)
{
log_msg ("eeprom is online");
read_version_from_eeprom ();
log_printf ("current eeprom version: 0x%08x\r\n", eeprom_version);
if ((eeprom_version & 0xFF0000FF) == 0x00000000)
{ // Upper and Lower Byte must be 0x00
if (eeprom_version >= EEPROM_VERSION_1_5_0)
{
#if SAVE_RAM == 0
log_msg ("reading ir codes from eeprom");
remote_ir_read_codes_from_eeprom ();
#endif
log_msg ("reading display configuration from eeprom");
display_read_config_from_eeprom ();
log_msg ("reading timeserver data from eeprom");
timeserver_read_data_from_eeprom ();
}
if (eeprom_version >= EEPROM_VERSION_1_7_0)
{
log_msg ("reading night timers from eeprom");
night_read_data_from_eeprom ();
}
}
}
else
{
log_msg ("eeprom is offline");
}
ldr_init (); // initialize LDR (ADC)
display_init (); // initialize display
dcf77_init (); // initialize DCF77
night_init (); // initialize night time routines
short_isr = 1;
temp_init (); // initialize DS18xx
short_isr = 0;
display_reset_led_states ();
display_mode = display_get_display_mode ();
animation_mode = display_get_animation_mode ();
auto_brightness = display_get_automatic_brightness_control ();
if (eeprom_is_up)
{
if (eeprom_version != EEPROM_VERSION)
{
log_printf ("updating EEPROM to version 0x%08x\r\n", EEPROM_VERSION);
eeprom_version = EEPROM_VERSION;
write_version_to_eeprom ();
#if SAVE_RAM == 0
remote_ir_write_codes_to_eeprom ();
#endif
display_write_config_to_eeprom ();
timeserver_write_data_to_eeprom ();
night_write_data_to_eeprom ();
eeprom_version = EEPROM_VERSION;
}
}
ds3231_flag = 1;
#if SAVE_RAM == 0
stop_time = uptime + 3; // wait 3 seconds for IR signal...
display_set_status_led (1, 1, 1); // show white status LED
while (uptime < stop_time)
{
if (irmp_get_data (&irmp_data)) // got IR signal?
{
display_set_status_led (1, 0, 0); // yes, show red status LED
delay_sec (1); // and wait 1 second
(void) irmp_get_data (&irmp_data); // flush input of IRMP now
display_set_status_led (0, 0, 0); // and switch status LED off
log_msg ("calling IR learn function");
if (remote_ir_learn ()) // learn IR commands
{
remote_ir_write_codes_to_eeprom (); // if successful, save them in EEPROM
}
break; // and break the loop
}
}
#endif
display_set_status_led (0, 0, 0); // switch off status LED
esp8266_init ();
esp8266_infop = esp8266_get_info ();
while (1)
{
if (! ap_mode && esp8266_is_up && button_pressed ()) // if user pressed user button, set ESP8266 to AP mode
{
ap_mode = 1;
log_msg ("user button pressed: configuring esp8266 as access point");
esp8266_is_online = 0;
esp8266_infop->is_online = 0;
esp8266_infop->ipaddress[0] = '\0';
esp8266_accesspoint ("wordclock", "1234567890");
}
if (status_led_cnt)
{
status_led_cnt--;
if (! status_led_cnt)
{
display_set_status_led (0, 0, 0);
}
}
if ((code = listener (&lis)) != 0)
{
display_set_status_led (1, 0, 0); // got net command, light red status LED
status_led_cnt = STATUS_LED_FLASH_TIME;
switch (code)
{
case LISTENER_SET_COLOR_CODE: // set color
{
display_set_colors (&(lis.rgb));
log_printf ("command: set colors to %d %d %d\r\n", lis.rgb.red, lis.rgb.green, lis.rgb.blue);
break;
}
case LISTENER_POWER_CODE: // power on/off
{
if (power_is_on != lis.power)
{
power_is_on = lis.power;
display_flag = DISPLAY_FLAG_UPDATE_ALL;
log_msg ("command: set power");
}
break;
}
case LISTENER_DISPLAY_MODE_CODE: // set display mode
{
if (display_mode != lis.mode)
{
display_mode = display_set_display_mode (lis.mode);
display_flag = DISPLAY_FLAG_UPDATE_ALL;
log_printf ("command: set display mode to %d\r\n", display_mode);
}
break;
}
case LISTENER_ANIMATION_MODE_CODE: // set animation mode
{
if (animation_mode != lis.mode)
{
animation_mode = display_set_animation_mode (lis.mode);
animation_flag = 0;
display_flag = DISPLAY_FLAG_UPDATE_ALL;
log_printf ("command: set animation mode to %d\r\n", animation_flag);
}
break;
}
case LISTENER_DISPLAY_TEMPERATURE_CODE: // set animation mode
{
show_temperature = 1;
log_msg ("command: show temperature");
break;
}
case LISTENER_SET_BRIGHTNESS_CODE: // set brightness
{
if (auto_brightness)
{
auto_brightness = 0;
last_ldr_value = 0xFF;
display_set_automatic_brightness_control (auto_brightness);
}
display_set_brightness (lis.brightness);
display_flag = DISPLAY_FLAG_UPDATE_NO_ANIMATION;
log_printf ("command: set brightness to %d, disable autmomatic brightness control per LDR\r\n", lis.brightness);
break;
}
case LISTENER_SET_AUTOMATIC_BRIHGHTNESS_CODE: // automatic brightness control on/off
{
if (lis.automatic_brightness_control)
{
auto_brightness = 1;
log_msg ("command: enable automatic brightness control");
}
else
{
auto_brightness = 0;
log_msg ("command: disable automatic brightness control");
}
last_ldr_value = 0xFF;
display_set_automatic_brightness_control (auto_brightness);
break;
}
case LISTENER_TEST_DISPLAY_CODE: // test display
{
log_msg ("command: start display test");
display_test ();
break;
}
case LISTENER_SET_DATE_TIME_CODE: // set date/time
{
if (rtc_is_up)
{
rtc_set_date_time (&(lis.tm));
}
if (hour != (uint_fast8_t) lis.tm.tm_hour || minute != (uint_fast8_t) lis.tm.tm_min)
{
display_flag = DISPLAY_FLAG_UPDATE_ALL;
}
wday = lis.tm.tm_wday;
hour = lis.tm.tm_hour;
minute = lis.tm.tm_min;
second = lis.tm.tm_sec;
log_printf ("command: set time to %s %4d-%02d-%02d %02d:%02d:%02d\r\n",
wdays_en[lis.tm.tm_wday], lis.tm.tm_year + 1900, lis.tm.tm_mon + 1, lis.tm.tm_mday,
lis.tm.tm_hour, lis.tm.tm_min, lis.tm.tm_sec);
break;
}
case LISTENER_GET_NET_TIME_CODE: // get net time
{
net_time_flag = 1;
log_msg ("command: start net time request");
break;
}
case LISTENER_IR_LEARN_CODE: // IR learn
{
#if SAVE_RAM == 0
log_msg ("command: learn IR codes");
if (remote_ir_learn ())
{
remote_ir_write_codes_to_eeprom ();
}
#endif
break;
}
case LISTENER_SAVE_DISPLAY_CONFIGURATION: // save display configuration
{
display_write_config_to_eeprom ();
log_msg ("command: save display settings");
break;
}
}
}
if (auto_brightness && ldr_poll_brightness (&ldr_value))
{
if (ldr_value + 1 < last_ldr_value || ldr_value > last_ldr_value + 1) // difference greater than 2
{
log_printf ("ldr: old brightnes: %d new brightness: %d\r\n", last_ldr_value, ldr_value);
last_ldr_value = ldr_value;
display_set_brightness (ldr_value);
display_flag = DISPLAY_FLAG_UPDATE_NO_ANIMATION;
}
}
if (!esp8266_is_up) // esp8266 up yet?
{
if (esp8266_infop->is_up)
{
esp8266_is_up = 1;
log_msg ("esp8266 now up");
}
}
else
{ // esp8266 is up...
if (! esp8266_is_online) // but not online yet...
{
if (esp8266_infop->is_online) // now online?
{
char buf[32];
esp8266_is_online = 1;
log_msg ("esp8266 now online");
sprintf (buf, " IP %s", esp8266_infop->ipaddress);
display_banner (buf);
display_flag = DISPLAY_FLAG_UPDATE_ALL;
net_time_flag = 1;
}
}
}
if (dcf77_time(&tm))
{
display_set_status_led (1, 1, 0); // got DCF77 time, light yellow = green + red LED
status_led_cnt = 50;
if (rtc_is_up)
{
rtc_set_date_time (&tm);
}
if (hour != (uint_fast8_t) tm.tm_hour || minute != (uint_fast8_t) tm.tm_min)
{
display_flag = DISPLAY_FLAG_UPDATE_ALL;
}
wday = tm.tm_wday;
hour = tm.tm_hour;
minute = tm.tm_min;
second = tm.tm_sec;
log_printf ("dcf77: %s %4d-%02d-%02d %02d:%02d:%02d\r\n",
wdays_en[tm.tm_wday], tm.tm_year + 1900, tm.tm_mon + 1, tm.tm_mday, tm.tm_hour, tm.tm_min, tm.tm_sec);
}
if (ds3231_flag)
{
if (rtc_is_up && rtc_get_date_time (&tm))
{
if (hour != (uint_fast8_t) tm.tm_hour || minute != (uint_fast8_t) tm.tm_min)
{
display_flag = DISPLAY_FLAG_UPDATE_ALL;
}
wday = tm.tm_wday;
hour = tm.tm_hour;
minute = tm.tm_min;
second = tm.tm_sec;
log_printf ("read rtc: %s %4d-%02d-%02d %02d:%02d:%02d\r\n",
wdays_en[tm.tm_wday], tm.tm_year + 1900, tm.tm_mon + 1, tm.tm_mday, tm.tm_hour, tm.tm_min, tm.tm_sec);
}
ds3231_flag = 0;
}
if (auto_brightness && ldr_conversion_flag)
{
ldr_start_conversion ();
ldr_conversion_flag = 0;
}
if (net_time_flag)
{
if (esp8266_infop->is_online)
{
display_set_status_led (0, 0, 1); // light blue status LED
status_led_cnt = STATUS_LED_FLASH_TIME;
timeserver_start_timeserver_request (); // start a timeserver request, answer follows...
}
net_time_flag = 0;
net_time_countdown = 3800; // next net time after 3800 sec
}
if (show_time_flag) // set every full minute
{
#if WCLOCK24H == 1
display_flag = DISPLAY_FLAG_UPDATE_ALL;
#else
if (minute % 5)
{
display_flag = DISPLAY_FLAG_UPDATE_MINUTES; // only update minute LEDs
}
else
{
display_flag = DISPLAY_FLAG_UPDATE_ALL;
}
#endif
show_time_flag = 0;
}
if (power_is_on == night_power_is_on && night_check_night_times (power_is_on, wday, hour * 60 + minute))
{
power_is_on = ! power_is_on;
night_power_is_on = ! night_power_is_on;
display_flag = DISPLAY_FLAG_UPDATE_ALL;
log_printf ("Found Timer: %s at %02d:%02d\r\n", power_is_on ? "on" : "off", hour, minute);
}
if (show_temperature)
{
uint_fast8_t temperature_index;
show_temperature = 0;
if (ds18xx_is_up)
{
short_isr = 1;
temperature_index = temp_read_temp_index ();
short_isr = 0;
log_printf ("got temperature from DS18xxx: %d%s\r\n", temperature_index / 2, (temperature_index % 2) ? ".5" : "");
}
else if (rtc_is_up)
{
temperature_index = rtc_get_temperature_index ();
log_printf ("got temperature from RTC: %d%s\r\n", temperature_index / 2, (temperature_index % 2) ? ".5" : "");
}
else
{
temperature_index = 0xFF;
log_msg ("no temperature available");
}
if (temperature_index != 0xFF)
{
display_temperature (power_is_on, temperature_index);
#if WCLOCK24H == 1 // WC24H shows temperature with animation, WC12H rolls itself
uint32_t stop_time;
stop_time = uptime + 5;
while (uptime < stop_time)
{
if (animation_flag)
{
animation_flag = 0;
display_animation ();
}
}
#endif
display_flag = DISPLAY_FLAG_UPDATE_ALL; // force update
}
}
if (display_flag) // refresh display (time/mode changed)
{
log_msg ("update display");
#if WCLOCK24H == 1
if (display_mode == MODES_COUNT - 1) // temperature
{
uint_fast8_t temperature_index;
if (ds18xx_is_up)
{
short_isr = 1;
temperature_index = temp_read_temp_index ();
short_isr = 0;
log_printf ("got temperature from DS18xxx: %d%s\r\n", temperature_index / 2, (temperature_index % 2) ? ".5" : "");
}
else if (rtc_is_up)
{
temperature_index = rtc_get_temperature_index ();
log_printf ("got temperature from RTC: %d%s\r\n", temperature_index / 2, (temperature_index % 2) ? ".5" : "");
}
else
{
temperature_index = 0x00;
log_msg ("no temperature available");
}
display_clock (power_is_on, 0, temperature_index - 20, display_flag); // show new time
}
else
{
display_clock (power_is_on, hour, minute, display_flag); // show new time
}
#else
display_clock (power_is_on, hour, minute, display_flag); // show new time
#endif
display_flag = DISPLAY_FLAG_NONE;
}
if (animation_flag)
{
animation_flag = 0;
display_animation ();
}
if (dcf77_flag)
{
dcf77_flag = 0;
dcf77_tick ();
}
#if SAVE_RAM == 0
cmd = remote_ir_get_cmd (); // get IR command
if (cmd != REMOTE_IR_CMD_INVALID) // got IR command, light green LED
{
display_set_status_led (1, 0, 0);
status_led_cnt = STATUS_LED_FLASH_TIME;
}
if (cmd != REMOTE_IR_CMD_INVALID) // if command valid, log command code
{
switch (cmd)
{
case REMOTE_IR_CMD_POWER: log_msg ("IRMP: POWER key"); break;
case REMOTE_IR_CMD_OK: log_msg ("IRMP: OK key"); break;
case REMOTE_IR_CMD_DECREMENT_DISPLAY_MODE: log_msg ("IRMP: decrement display mode"); break;
case REMOTE_IR_CMD_INCREMENT_DISPLAY_MODE: log_msg ("IRMP: increment display mode"); break;
case REMOTE_IR_CMD_DECREMENT_ANIMATION_MODE: log_msg ("IRMP: decrement animation mode"); break;
case REMOTE_IR_CMD_INCREMENT_ANIMATION_MODE: log_msg ("IRMP: increment animation mode"); break;
case REMOTE_IR_CMD_DECREMENT_HOUR: log_msg ("IRMP: decrement hour"); break;
case REMOTE_IR_CMD_INCREMENT_HOUR: log_msg ("IRMP: increment hour"); break;
case REMOTE_IR_CMD_DECREMENT_MINUTE: log_msg ("IRMP: decrement minute"); break;
case REMOTE_IR_CMD_INCREMENT_MINUTE: log_msg ("IRMP: increment minute"); break;
case REMOTE_IR_CMD_DECREMENT_BRIGHTNESS_RED: log_msg ("IRMP: decrement red brightness"); break;
case REMOTE_IR_CMD_INCREMENT_BRIGHTNESS_RED: log_msg ("IRMP: increment red brightness"); break;
case REMOTE_IR_CMD_DECREMENT_BRIGHTNESS_GREEN: log_msg ("IRMP: decrement green brightness"); break;
case REMOTE_IR_CMD_INCREMENT_BRIGHTNESS_GREEN: log_msg ("IRMP: increment green brightness"); break;
case REMOTE_IR_CMD_DECREMENT_BRIGHTNESS_BLUE: log_msg ("IRMP: decrement blue brightness"); break;
case REMOTE_IR_CMD_INCREMENT_BRIGHTNESS_BLUE: log_msg ("IRMP: increment blue brightness"); break;
case REMOTE_IR_CMD_DECREMENT_BRIGHTNESS: log_msg ("IRMP: decrement brightness"); break;
case REMOTE_IR_CMD_INCREMENT_BRIGHTNESS: log_msg ("IRMP: increment brightness"); break;
case REMOTE_IR_CMD_GET_TEMPERATURE: log_msg ("IRMP: get temperature"); break;
}
}
switch (cmd)
{
case REMOTE_IR_CMD_POWER:
{
power_is_on = ! power_is_on;
display_flag = DISPLAY_FLAG_UPDATE_ALL;
break;
}
case REMOTE_IR_CMD_OK:
{
display_write_config_to_eeprom ();
break;
}
case REMOTE_IR_CMD_DECREMENT_DISPLAY_MODE: // decrement display mode
{
display_mode = display_decrement_display_mode ();
display_flag = DISPLAY_FLAG_UPDATE_ALL;
break;
}
case REMOTE_IR_CMD_INCREMENT_DISPLAY_MODE: // increment display mode
{
display_mode = display_increment_display_mode ();
display_flag = DISPLAY_FLAG_UPDATE_ALL;
break;
}
case REMOTE_IR_CMD_DECREMENT_ANIMATION_MODE: // decrement display mode
{
animation_mode = display_decrement_animation_mode ();
display_flag = DISPLAY_FLAG_UPDATE_ALL;
break;
}
case REMOTE_IR_CMD_INCREMENT_ANIMATION_MODE: // increment display mode
{
animation_mode = display_increment_animation_mode ();
display_flag = DISPLAY_FLAG_UPDATE_ALL;
break;
}
case REMOTE_IR_CMD_DECREMENT_HOUR: // decrement hour
{
if (hour > 0)
{
hour--;
}
else
{
hour = 23;
}
second = 0;
display_flag = DISPLAY_FLAG_UPDATE_ALL;
time_changed = 1;
break;
}
case REMOTE_IR_CMD_INCREMENT_HOUR: // increment hour
{
if (hour < 23)
{
hour++;
}
else
{
hour = 0;
}
second = 0;
display_flag = DISPLAY_FLAG_UPDATE_ALL;
time_changed = 1;
break;
}
case REMOTE_IR_CMD_DECREMENT_MINUTE: // decrement minute
{
if (minute > 0)
{
minute--;
}
else
{
minute = 59;
}
second = 0;
display_flag = DISPLAY_FLAG_UPDATE_ALL;
time_changed = 1;
break;
}
case REMOTE_IR_CMD_INCREMENT_MINUTE: // increment minute
{
if (minute < 59)
{
minute++;
}
else
{
minute = 0;
}
second = 0;
display_flag = DISPLAY_FLAG_UPDATE_ALL;
time_changed = 1;
break;
}
case REMOTE_IR_CMD_DECREMENT_BRIGHTNESS_RED: // decrement red brightness
{
display_decrement_color_red ();
display_flag = DISPLAY_FLAG_UPDATE_NO_ANIMATION;
break;
}
case REMOTE_IR_CMD_INCREMENT_BRIGHTNESS_RED: // increment red brightness
{
display_increment_color_red ();
display_flag = DISPLAY_FLAG_UPDATE_NO_ANIMATION;
break;
}
case REMOTE_IR_CMD_DECREMENT_BRIGHTNESS_GREEN: // decrement green brightness
{
display_decrement_color_green ();
display_flag = DISPLAY_FLAG_UPDATE_NO_ANIMATION;
break;
}
case REMOTE_IR_CMD_INCREMENT_BRIGHTNESS_GREEN: // increment green brightness
{
display_increment_color_green ();
display_flag = DISPLAY_FLAG_UPDATE_NO_ANIMATION;
break;
}
case REMOTE_IR_CMD_DECREMENT_BRIGHTNESS_BLUE: // decrement blue brightness
{
display_decrement_color_blue ();
display_flag = DISPLAY_FLAG_UPDATE_NO_ANIMATION;
break;
}
case REMOTE_IR_CMD_INCREMENT_BRIGHTNESS_BLUE: // increment blue brightness
{
display_increment_color_blue ();
display_flag = DISPLAY_FLAG_UPDATE_NO_ANIMATION;
break;
}
case REMOTE_IR_CMD_AUTO_BRIGHTNESS_CONTROL: // toggle auto brightness
{
auto_brightness = ! auto_brightness;
last_ldr_value = 0xFF;
display_set_automatic_brightness_control (auto_brightness);
display_flag = DISPLAY_FLAG_UPDATE_NO_ANIMATION;
break;
}
case REMOTE_IR_CMD_DECREMENT_BRIGHTNESS: // decrement brightness
{
if (auto_brightness)
{
auto_brightness = 0;
last_ldr_value = 0xFF;
display_set_automatic_brightness_control (auto_brightness);
display_flag = DISPLAY_FLAG_UPDATE_NO_ANIMATION;
}
display_decrement_brightness ();
display_flag = DISPLAY_FLAG_UPDATE_NO_ANIMATION;
break;
}
case REMOTE_IR_CMD_INCREMENT_BRIGHTNESS: // increment brightness
{
if (auto_brightness)
{
auto_brightness = 0;
last_ldr_value = 0xFF;
display_set_automatic_brightness_control (auto_brightness);
display_flag = DISPLAY_FLAG_UPDATE_NO_ANIMATION;
}
display_increment_brightness ();
display_flag = DISPLAY_FLAG_UPDATE_NO_ANIMATION;
break;
}
case REMOTE_IR_CMD_GET_TEMPERATURE: // get temperature
{
show_temperature = 1;
break;
}
default:
{
break;
}
}
#endif // SAVE_RAM == 0
if (time_changed)
{
if (rtc_is_up)
{
tm.tm_hour = hour;
tm.tm_min = minute;
tm.tm_sec = second;
rtc_set_date_time (&tm);
}
time_changed = 0;
}
}
return 0;
}
int main(void) {
Geiger g;
power_initialise();
if(power_battery_level() < 1) {
power_standby();
}
flashstorage_initialise();
buzzer_initialise();
realtime_initialise();
g.initialise();
uint8_t *private_key = ((uint8_t *) &_binary___binary_data_private_key_data_start);
if(private_key[0] != 0) delay_us(1000);
delay_us(10000); // can be removed?
#ifndef DISABLE_ACCEL
accel_init();
#endif
Controller c(g);
switch_initialise();
// if we woke up on an alarm, we're going to be sending the system back.
#ifndef NEVERSLEEP
if(power_get_wakeup_source() == WAKEUP_RTC) {
c.m_sleeping = true;
} else {
buzzer_nonblocking_buzz(0.05);
display_initialise();
const char *devicetag = flashstorage_keyval_get("DEVICETAG");
char revtext[10];
sprintf(revtext,"VERSION: %s ",OS100VERSION);
display_splashscreen(devicetag,revtext);
delay_us(3000000);
display_clear(0);
}
#endif
#ifdef NEVERSLEEP
buzzer_nonblocking_buzz(0.05);
display_initialise();
#endif
GUI m_gui(c);
bool full = flashstorage_log_isfull();
if((full == true) && (c.m_sleeping == false)) {
m_gui.show_dialog("Flash Log","is full",0,0,0);
}
c.set_gui(m_gui);
UserInput u(m_gui);
u.initialise();
serial_initialise();
int8_t utcoffsetmins_n = 0;
const char *utcoffsetmins = flashstorage_keyval_get("UTCOFFSETMINS");
if(utcoffsetmins != 0) {
unsigned int c;
sscanf(utcoffsetmins, "%u", &c);
utcoffsetmins_n = c;
realtime_setutcoffset_mins(utcoffsetmins_n);
}
// Need to refactor out stored settings
if(c.m_sleeping == false) {
const char *sbright = flashstorage_keyval_get("BRIGHTNESS");
if(sbright != 0) {
unsigned int c;
sscanf(sbright, "%u", &c);
display_set_brightness(c);
}
const char *sbeep = flashstorage_keyval_get("GEIGERBEEP");
if(sbeep != 0) {
if(strcmp(sbeep,"true") == 0) { g.set_beep(true); tick_item("Geiger Beep",true); }
else g.set_beep(false);
}
const char *scpmcps = flashstorage_keyval_get("CPMCPSAUTO");
if(scpmcps != 0) {
if(strcmp(scpmcps,"true") == 0) { c.m_cpm_cps_switch = true; tick_item("CPM/CPS Auto",true); }
}
const char *language = flashstorage_keyval_get("LANGUAGE");
if(language != 0) {
if(strcmp(language,"English" ) == 0) { m_gui.set_language(LANGUAGE_ENGLISH); tick_item("English" ,true); } else
if(strcmp(language,"Japanese") == 0) { m_gui.set_language(LANGUAGE_JAPANESE); tick_item("Japanese" ,true); }
} else {
m_gui.set_language(LANGUAGE_ENGLISH);
tick_item("English",true);
}
const char *svrem = flashstorage_keyval_get("SVREM");
if(strcmp(svrem,"REM") == 0) { tick_item("Roentgen",true); }
else { tick_item("Sievert",true);}
}
m_gui.jump_to_screen(1);
m_gui.push_stack(0,1);
for(;;) {
if(power_battery_level() < 1) {
power_standby();
}
//display_draw_text(0,110,"preupdate",0);
c.update();
//display_draw_text(0,110,"prerender",0);
m_gui.render();
//display_draw_text(0,110,"preserial",0);
serial_eventloop();
//display_draw_text(0,110,"preserial",0);
// It might be a good idea to move the following code to Controller.
// Hack to check that captouch is ok, and reset it if not.
bool c = cap_check();
if(c == false) {
display_draw_text(0,90,"CAPFAIL",0);
cap_init();
}
// Screen lock code
uint32_t release1_time = cap_last_press(KEY_BACK);
uint32_t press1_time = cap_last_release(KEY_BACK);
uint32_t release2_time = cap_last_press(KEY_SELECT);
uint32_t press2_time = cap_last_release(KEY_SELECT);
uint32_t current_time = realtime_get_unixtime();
if((release1_time != 0) &&
(release2_time != 0) &&
((current_time-press1_time) > 3) &&
((current_time-press2_time) > 3) &&
cap_ispressed(KEY_BACK ) &&
cap_ispressed(KEY_SELECT)) {
system_gui->toggle_screen_lock();
cap_clear_press();
}
power_wfi();
}
// should never get here
for(int n=0;n<60;n++) {
delay_us(100000);
buzzer_blocking_buzz(1000);
}
return 0;
}