/* the thread display clock */ void *pro_thread_clock(void *fb_inf) { while (clock_flag == 0) { usleep(1); } display_clock(*(fb_info *)fb_inf); return NULL; }
/*! do stuff every 1/4 second called from clock_10ms(), do not call directly */ static void clock_250ms(void) { if (heaters_all_zero()) { if (psu_timeout > (30 * 4)) { power_off(); } else { ATOMIC_START psu_timeout++; ATOMIC_END } } temp_heater_tick(); ifclock(clock_flag_1s) { #ifdef DISPLAY display_clock(); #endif temp_residency_tick(); if (DEBUG_POSITION && (debug_flags & DEBUG_POSITION)) { // current position update_current_position(); sersendf_P(PSTR("Pos: %lq,%lq,%lq,%lq,%lu\n"), current_position.axis[X], current_position.axis[Y], current_position.axis[Z], current_position.axis[E], current_position.F); // target position sersendf_P(PSTR("Dst: %lq,%lq,%lq,%lq,%lu\n"), movebuffer[mb_tail].endpoint.axis[X], movebuffer[mb_tail].endpoint.axis[Y], movebuffer[mb_tail].endpoint.axis[Z], movebuffer[mb_tail].endpoint.axis[E], movebuffer[mb_tail].endpoint.F); // Queue print_queue(); // newline serial_writechar('\n'); } // temperature /* if (temp_get_target()) temp_print();*/ } #ifdef TEMP_INTERCOM start_send(); #endif }
/* * This is the code for the simple DMA2D Demo * * Basically it lets you put display digits on the * screen manually or with the DMA2D peripheral. It * has various 'bling' levels, and it tracks performance * by measuring how long it takes to go from one frame * to the next. */ int main(void) { int i; uint32_t t1, t0; char buf[35]; char *scr_opt; int f_ndx = 0; float avg_frame; int can_switch; int opt, ds; /* Enable the clock to the DMA2D device */ rcc_periph_clock_enable(RCC_DMA2D); fprintf(stderr, "DMA2D Demo program : Digits Gone Wild\n"); printf("Generate background\n"); generate_background(); printf("Generate digits\n"); generate_digits(); gfx_init(lcd_draw_pixel, 800, 480, GFX_FONT_LARGE); opt = 0; /* screen clearing mode */ can_switch = 0; /* auto switching every 10 seconds */ t0 = mtime(); ds = 0; while (1) { switch (opt) { default: case 0: /* very slow way to clear the screen */ scr_opt = "manual clear"; gfx_fillScreen(0xffff); break; case 1: /* faster, using a tight loop */ scr_opt = "dedicated loop"; lcd_clear(0xff7f7f); break; case 2: /* fastest? Using DMA2D to fill screen */ scr_opt = "DMA 2D Fill"; dma2d_fill(0xff7fff7f); break; case 3: /* still fast, using DMA2D to pre-populate BG */ scr_opt = "DMA 2D Background"; dma2d_bgfill(); break; case 4: /* Now render all of the digits with DMA2D */ scr_opt = "DMA 2D Digits"; ds = 0; dma2d_bgfill(); break; case 5: /* still fast, using DMA2D to render drop shadows */ scr_opt = "DMA 2D Shadowed Digits"; ds = 1; dma2d_bgfill(); break; } /* This little state machine implements an automatic switch * every 10 seconds unless you've disabled it with the 'd' * command. */ if (((t0 / 1000) % 10 == 0) && (can_switch > 0)) { opt = (opt + 1) % MAX_OPTS; can_switch = 0; } else if (((t0 / 1000) % 10 != 0) && (can_switch == 0)) { can_switch = 1; } /* * The first four options (0, 1, 2, 3) all render the digits * in software every time, options 4 and 5 use the DMA2 * device to render the digits */ if (opt < 4) { display_clock(25, 20, mtime()); } else { dma2d_clock(25, 20, mtime(), ds); } for (i = 0; i < 10; i++) { if (opt < 4) { draw_digit(25 + i * (DISP_WIDTH + 8), 350, i, GFX_COLOR_GREEN, GFX_COLOR_BLACK); } else { if (ds) { dma2d_digit(35 + i * (DISP_WIDTH + 8), 360, i, SHADOW, SHADOW); } dma2d_digit(25 + i * (DISP_WIDTH + 8), 350, i, 0xff40c040, 0xff000000); } } /* In both cases we write the notes using the graphics library */ gfx_setTextColor(0, 0); gfx_setTextSize(3); gfx_setCursor(25, 30 + DISP_HEIGHT + gfx_getTextHeight() + 2); gfx_puts((unsigned char *)"Hello world for DMA2D!"); lcd_flip(te_lock); t1 = mtime(); /* this computes a running average of the last 10 frames */ frame_times[f_ndx] = t1 - t0; f_ndx = (f_ndx + 1) % N_FRAMES; for (i = 0, avg_frame = 0; i < N_FRAMES; i++) { avg_frame += frame_times[i]; } avg_frame = avg_frame / (float) N_FRAMES; snprintf(buf, 35, "FPS: %6.2f", 1000.0 / avg_frame); gfx_setCursor(25, 30 + DISP_HEIGHT + 2 * (gfx_getTextHeight() + 2)); gfx_puts((unsigned char *)buf); gfx_puts((unsigned char *)" "); gfx_setCursor(25, 30 + DISP_HEIGHT + 3 * (gfx_getTextHeight() + 2)); gfx_puts((unsigned char *)scr_opt); /* * The demo runs continuously but it watches for characters * typed at the console. There are a few options you can select. */ i = console_getc(0); switch (i) { case 's': opt = (opt + 1) % MAX_OPTS; printf("Switched to : %s\n", demo_options[opt]); break; case 'd': can_switch = -1; printf("Auto switching disabled\n"); break; case 'e': can_switch = 0; printf("Auto switching enabled\n"); break; case 't': te_lock = (te_lock == 0); printf("We are %s for the TE bit to be set\n", (te_lock) ? "WAITING" : "NOT WAITING"); break; default: printf("Options:\n"); printf("\ts - switch demo mode\n"); printf("\td - disable auto-switching of demo mode\n"); printf("\te - enable auto-switching of demo mode\n"); printf("\tt - enable/disable Tearing effect lock wait\n"); case 0: break; } t0 = t1; } }
/*------------------------------------------------------------------------------------------------------------------------------------------- * 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; }
/// @param[in] str: User supplied command line /// /// @return 1 The return code indicates a command matched. /// @return 0 if no rules matched MEMSPACE int user_tests(int argc, char *argv[]) { char *ptr; time_t t; double freq; extern int connections; int ind; if(argc < 2) return(0); ind = 1; ptr = argv[ind++]; if (MATCHARGS(ptr,"help", (ind+0),argc )) { user_help(); return(1); } #ifdef POSIX_TESTS if(posix_tests(argc,argv)) return(1); #endif #ifdef FATFS_TESTS if(fatfs_tests(argc,argv)) return(1); #endif #ifdef ADF4351 if (MATCHARGS(ptr,"adf4351", (ind + 1) ,argc)) { adf4351_cmd(argc,argv); return(1); } #endif if (MATCHARGS(ptr,"setdate", (ind + 1) ,argc)) { setdate_r(argv[ind++]); return(1); } if (MATCHARGS(ptr,"display_clock", (ind + 0) ,argc)) { display_clock(); return(1); } if (MATCHARGS(ptr,"time", (ind + 0) ,argc)) { t = time(0); printf("TIME:%s\n", ctime(&t)); return(1); } if (MATCHARGS(ptr,"connection", (ind + 0) ,argc)) { printf("connections:%d\n", connections); return(1); } if (MATCHARGS(ptr,"mem", (ind + 0) ,argc)) { PrintRam(); return(1); } if (MATCHARGS(ptr,"timetest", (ind + 1) ,argc)) { timetests(argv[ind++],0); return(1); } #ifdef DISPLAY if (MATCHARGS(ptr,"calibrate", (ind + 1) ,argc)) { int ret = atoi(argv[ind++]); tft_setRotation(ret); tft_touch_calibrate(master); MatWrite("/tft_calX",tft_calX); MatWrite("/tft_calY",tft_calY); setup_windows(ret & 3,0); return(1); } if (MATCHARGS(ptr,"calibrate_test", (ind + 1) ,argc)) { int ret = atoi(argv[ind++]); tft_setRotation(ret); tft_touch_calibrate(master); MatWrite("/tft_calX",tft_calX); MatWrite("/tft_calY",tft_calY); tft_map_test(master, 10); setup_windows(ret & 3,0); return(1); } if (MATCHARGS(ptr,"rotate", (ind + 1) ,argc)) { // FIXME rotate calibration data ??? int ret = atoi(argv[ind++]); tft_setRotation(ret); setup_windows(ret & 3,0); return(1); } #ifdef VFONTS if (MATCHARGS(ptr,"draw", (ind + 1) ,argc)) { char *ptr = argv[ind++]; int c = *ptr++; int n = *ptr++; if( n == '1') drawSVG(winmsg, 8, 24, c, 0.08, ILI9341_WHITE, 1); else drawSVG(winmsg, 8, 24, c, 0.08, ILI9341_WHITE, 0); return(1); } #endif if (MATCHARGS(ptr,"pixel", (ind + 0) ,argc)) { int c; int x,y; tft_drawPixel(winmsg, 8, 24, ILI9341_WHITE); for(y=24;y<26;++y) { for(x=8;x<10;++x) { c = tft_readPixel(winmsg, x, y); printf("pixel(%d,%d): %04x\n", x,y,c); } } return(1); } #endif //DISPLAY return(0); }