Fixed buffer overflows in sunrise_sunset_face

Merge branch 'main' of github.com:joeycastillo/Sensor-Watch
sensor watch pro test procedure
2025-05-15 11:59:21 -03:00 · 2025-05-06 23:57:45 -04:00 · 2025-05-06 23:56:19 -04:00 · 2025-04-03 08:58:30 -04:00 · 2025-04-01 09:55:41 -04:00 · 2025-04-01 09:55:41 -04:00
7 changed files with 476 additions and 9 deletions
--- a/README.md
+++ b/README.md
@ -74,6 +74,17 @@ python3 -m http.server -d build-sim
 Finally, visit [watch.html](http://localhost:8000/watch.html) to see your work.
 Hardware Schematics and PCBs
 ----------------------------
 | Name | Color | Schematic | Gerbers |
 | ---- | ----- | --------- | ------- |
 | Sensorwatch Lite | RED   | [PCB/Main Boards/OSO-SWAT-B1](PCB/Main%20Boards/OSO-SWAT-B1) | [OSO-SWAT-B1-03](PCB/Main%20Boards/OSO-SWAT-B1/OSO-SWAT-B1-03.zip) |
 | Sensorwatch      | GREEN | [OSO-SWAT-A1-05](PCB/Main%20Boards/OSO-SWAT-A1/OSO-SWAT-A1-05.sch) (Eagle format) | ? |
 | Sensorwatch Pro  | TBD   | TBD  | TBD |
 License
 -------
 Different components of the project are licensed differently, see [LICENSE.md](https://github.com/joeycastillo/Sensor-Watch/blob/main/LICENSE.md).
--- a/apps/sensor-watch-pro-test/app.c
+++ b/apps/sensor-watch-pro-test/app.c
@ -0,0 +1,420 @@
 #include <stdio.h>
 #include <string.h>
 #include "watch.h"
 #include "spiflash.h"
 bool has_ticked = false;
 extern struct io_descriptor *uart_io;
 // array of lcd pins from pins.h
 const uint8_t lcd_pins[] = {
    SLCD26, // SEG23
    SLCD25, // SEG22
    SLCD24, // SEG21
    SLCD23, // SEG20
    SLCD22, // SEG19
    SLCD21, // SEG18
    SLCD20, // SEG17
    SLCD19, // SEG16
    SLCD18, // SEG15
    SLCD17, // SEG14
    SLCD16, // SEG13
    SLCD15, // SEG12
    SLCD14, // SEG11
    SLCD13, // SEG10
    SLCD12, // SEG9
    SLCD11, // SEG8
    SLCD10, // SEG7
    SLCD9,  // SEG6
    SLCD8,  // SEG5
    SLCD7,  // SEG4
    SLCD6,  // SEG3
    SLCD5,  // SEG2
    SLCD4,  // SEG1
    SLCD3,  // SEG0
    SLCD2,  // COM2
    SLCD1,  // COM1
    SLCD0,  // COM0
 };
 void cb_tick(void);
 void cb_tick(void) {
    has_ticked = true;
    watch_rtc_disable_periodic_callback(8);
 }
 void pass_if(bool passed);
 void pass_if(bool passed) {
    if (passed) {
        watch_set_led_green();
        delay_ms(100);
        watch_set_led_off();
    } else {
        watch_set_led_red();
        delay_ms(100);
        watch_set_led_off();
    }
 }
 void app_init(void) {
 }
 void app_wake_from_backup(void) {
 }
 static void enable_irda_uart() {
    gpio_set_pin_direction(IR_ENABLE, GPIO_DIRECTION_OUT);
    gpio_set_pin_level(IR_ENABLE, false);
    SERCOM_USART_CTRLA_Type ctrla;
    SERCOM_USART_CTRLB_Type ctrlb;
    ctrla.reg = SERCOM_USART_CTRLA_DORD | SERCOM_USART_CTRLA_MODE(1);
    ctrlb.reg = SERCOM_USART_CTRLB_CHSIZE(0) | SERCOM_USART_CTRLB_ENC;
    MCLK->APBCMASK.reg |= MCLK_APBCMASK_SERCOM0;
    GCLK->PCHCTRL[SERCOM0_GCLK_ID_CORE].reg = GCLK_PCHCTRL_GEN(0) | GCLK_PCHCTRL_CHEN;
    while (0 == (GCLK->PCHCTRL[SERCOM0_GCLK_ID_CORE].reg & GCLK_PCHCTRL_CHEN));
 	usart_sync_init(&USART_0, SERCOM0, (void *)NULL);
    SERCOM0->USART.CTRLA.reg &= ~SERCOM_USART_CTRLA_ENABLE;
    gpio_set_pin_direction(IRSENSE, GPIO_DIRECTION_IN);
    gpio_set_pin_function(IRSENSE, PINMUX_PA04D_SERCOM0_PAD0);
    ctrla.reg |= SERCOM_USART_CTRLA_RXPO(0);
    ctrlb.reg |= SERCOM_USART_CTRLB_RXEN;
    SERCOM0->USART.CTRLA.reg = ctrla.reg;
    SERCOM0->USART.CTRLB.reg = ctrlb.reg;
    if (hri_usbdevice_get_CTRLA_ENABLE_bit(USB)) {
        uint64_t br = 65536 - ((65536 * 16.0f * 600) / 8000000);
        SERCOM0->USART.BAUD.reg = (uint16_t)br;
    } else {
        uint64_t br = 65536 - ((65536 * 16.0f * 600) / 4000000);
        SERCOM0->USART.BAUD.reg = (uint16_t)br;
    }
    SERCOM0->USART.CTRLA.reg |= SERCOM_USART_CTRLA_ENABLE;
 	usart_sync_enable(&USART_0);
    usart_sync_get_io_descriptor(&USART_0, &uart_io);
 }
 void app_setup(void) {
    // Set up tick for RTC test
    watch_rtc_register_periodic_callback(cb_tick, 8);
    // Set up UART for communication with tester
    enable_irda_uart();
    // Set up LED pins
    watch_enable_leds();
    watch_enable_buzzer();
    // Set up buttons with pull-down resistors
    gpio_set_pin_direction(BTN_ALARM, GPIO_DIRECTION_IN);
    gpio_set_pin_pull_mode(BTN_ALARM, GPIO_PULL_DOWN);
    gpio_set_pin_direction(BTN_LIGHT, GPIO_DIRECTION_IN);
    gpio_set_pin_pull_mode(BTN_LIGHT, GPIO_PULL_DOWN);
    gpio_set_pin_direction(BTN_MODE, GPIO_DIRECTION_IN);
    gpio_set_pin_pull_mode(BTN_MODE, GPIO_PULL_DOWN);
    // Set up ADC for thermistor and light sensor tests
    watch_enable_adc();
    watch_enable_analog_input(TEMPSENSE);
    // Pin A0 is the thermistor enable pin
    gpio_set_pin_direction(TS_ENABLE, GPIO_DIRECTION_OUT);
 }
 void app_prepare_for_standby(void) {
 }
 void app_wake_from_standby(void) {
 }
 static bool test_i2c(void) {
    watch_enable_i2c();
    uint16_t device_id = watch_i2c_read8(0x48, 0x0F);
    printf("%d\n", device_id);
    return device_id == 0x75;
 }
 static bool test_spi(void) {
 	gpio_set_pin_level(A3, true);
 	gpio_set_pin_direction(A3, GPIO_DIRECTION_OUT);
    watch_enable_spi();
    delay_ms(10);
    watch_set_pin_level(A3, false);
    delay_ms(10);
    uint8_t read_status_response[3] = {0};
    bool ok = spi_flash_read_command(0x9F, read_status_response, 3);
    watch_set_pin_level(A3, true);
    printf("%d %d %d\n", read_status_response[0], read_status_response[1], read_status_response[2]);
    return (read_status_response[0] == 0xC8 && read_status_response[1] == 0x40 && read_status_response[2] == 0x13);
 }
 bool app_loop(void) {
    uint8_t buf[5] = {0};
    watch_storage_read(10, 0, buf, 4);
    printf("%s\n", (const char *)buf);
    if (strcmp((const char *)buf, "BEEP") == 0) {
        watch_set_led_yellow();
        watch_buzzer_play_note(BUZZER_NOTE_C5, 150);
        watch_buzzer_play_note(BUZZER_NOTE_REST, 25);
        watch_buzzer_play_note(BUZZER_NOTE_E5, 150);
        watch_buzzer_play_note(BUZZER_NOTE_REST, 25);
        watch_buzzer_play_note(BUZZER_NOTE_G5, 150);
        watch_buzzer_play_note(BUZZER_NOTE_REST, 25);
        watch_buzzer_play_note(BUZZER_NOTE_C6, 150);
        watch_storage_erase(10);
        delay_ms(10);
        watch_storage_write(10, 0, (const char *)"9PIN", 4);
        watch_storage_sync();
        watch_storage_read(10, 0, buf, 4);
        delay_ms(10);
        if(strcmp((const char *)buf, (const char *)"9PIN") == 0) {
            watch_set_led_off();
            while(1);
        }
    }
    if (strcmp((const char *)buf, "9PIN") == 0) {
        bool i2c_passed = test_i2c();
        bool spi_passed = test_spi();
        if (i2c_passed && spi_passed) {
            watch_storage_erase(10);
            delay_ms(10);
            watch_storage_write(10, 0, (const char *)"PASS", 4);
            watch_storage_sync();
            watch_storage_read(10, 0, buf, 4);
            delay_ms(10);
            if(strcmp((const char *)buf, (const char *)"PASS") == 0) {
                gpio_set_pin_direction(A0, GPIO_DIRECTION_OUT);
                gpio_set_pin_level(A0, true);
            }
        } else if (i2c_passed) {
            // SPI failed, RED indicator
            watch_set_led_color_rgb(128, 0, 0);
        } else if (spi_passed) {
            // I2C failed, BLUE indicator
            watch_set_led_color_rgb(0, 0, 128);
        } else {
            // both failed, PURPLE indicator
            watch_set_led_color_rgb(64, 0, 128);
        }
        while(1);
    }
    if(strcmp((const char *)buf, (const char *)"PASS") == 0) {
        watch_set_led_green();
        while(1);
    }
    char char_received = watch_uart_getc();
    if (char_received) {
        switch (char_received) {
            // - [X] RTC
            case 'R':
                pass_if(has_ticked);
                break;
            // - [X] LCD pin continuity
            case 'O':
                // Set all LCD pins high
                for (int i = 0; i < 27; i++) {
                    gpio_set_pin_function(lcd_pins[i], GPIO_PIN_FUNCTION_OFF);
                    gpio_set_pin_direction(lcd_pins[i], GPIO_DIRECTION_OUT);
                    gpio_set_pin_level(lcd_pins[i], true);
                }
                // It is the tester's responsibility to check that the pins are high
                break;
            case 'P':
                // Set all LCD pins low
                for (int i = 0; i < 27; i++) {
                    gpio_set_pin_function(lcd_pins[i], GPIO_PIN_FUNCTION_OFF);
                    gpio_set_pin_direction(lcd_pins[i], GPIO_DIRECTION_OUT);
                    gpio_set_pin_level(lcd_pins[i], false);
                }
                // It is the tester's responsibility to check that the pins are low
                break;
            // - [X] LCD pin bridging
            case 'Q':
                {
                    bool passed = true;
                    // Pull all LCD pins up
                    for (int i = 0; i < 27; i++) {
                        gpio_set_pin_function(lcd_pins[i], GPIO_PIN_FUNCTION_OFF);
                        gpio_set_pin_direction(lcd_pins[i], GPIO_DIRECTION_IN);
                        gpio_set_pin_pull_mode(lcd_pins[i], GPIO_PULL_UP);
                    }
                    // SEG23 is adjacent to the green LED.
                    // setting the LED green drives GREEN low.
                    watch_set_led_green();
                    if (!gpio_get_pin_level(SLCD26)) {
                        // If SEG23 is low, then it must be bridged to the green pin
                        pass_if(false);
                    }
                    // SEG13 is adjacent to the blue LED.
                    // setting the LED blue drives BLUE low.
                    watch_set_led_color_rgb(0, 0, 255);
                    if (!gpio_get_pin_level(SLCD16)) {
                        // If SEG13 is low, then it must be bridged to the blue pin
                        pass_if(false);
                    }
                    // SEG12 is adjacent to the red LED.
                    // setting the LED red drives RED low.
                    watch_set_led_red();
                    if (!gpio_get_pin_level(SLCD15)) {
                        // If SEG12 is low, then it must be bridged to the red pin
                        pass_if(false);
                    }
                    watch_set_led_off();
                    // After this, all LCD pins are adjacent. Test if each pin is bridged to the previous one.
                    for (int i = 1; i < 27; i++) {
                        gpio_set_pin_direction(lcd_pins[i - 1], GPIO_DIRECTION_OUT);
                        gpio_set_pin_level(lcd_pins[i - 1], false);
                        if (!gpio_get_pin_level(lcd_pins[i])) {
                            passed = false;
                            break;
                        }
                        gpio_set_pin_direction(lcd_pins[i - 1], GPIO_DIRECTION_IN);
                        gpio_set_pin_pull_mode(lcd_pins[i - 1], GPIO_PULL_UP);
                    }
                    // Special cases:
                    // SLCD0 neighbors VCC
                    gpio_set_pin_direction(SLCD0, GPIO_DIRECTION_IN);
                    gpio_set_pin_pull_mode(SLCD0, GPIO_PULL_DOWN);
                    if (gpio_get_pin_level(SLCD0)) {
                        passed = false;
                    }
                    // SLCD18 neighbors VCC
                    gpio_set_pin_direction(SLCD18, GPIO_DIRECTION_IN);
                    gpio_set_pin_pull_mode(SLCD18, GPIO_PULL_DOWN);
                    if (gpio_get_pin_level(SLCD18)) {
                        passed = false;
                    }
                    // SLCD26 neighbors USB_N
                    gpio_set_pin_direction(GPIO(GPIO_PORTA, 24), GPIO_DIRECTION_OUT);
                    gpio_set_pin_level(GPIO(GPIO_PORTA, 24), true);
                    gpio_set_pin_direction(SLCD26, GPIO_DIRECTION_IN);
                    gpio_set_pin_pull_mode(SLCD26, GPIO_PULL_DOWN);
                    // if SLCD26 is high, then it is bridged to USB_N
                    if (gpio_get_pin_level(SLCD26)) {
                        passed = false;
                    }
                    // SLCD11 neighbors VLCD
                    watch_enable_display();
                    delay_ms(50);
                    gpio_set_pin_function(SLCD11, GPIO_PIN_FUNCTION_OFF);
                    gpio_set_pin_direction(SLCD11, GPIO_DIRECTION_IN);
                    gpio_set_pin_pull_mode(SLCD11, GPIO_PULL_DOWN);
                    if (gpio_get_pin_level(SLCD11)) {
                        passed = false;
                    }
                    for (int i = 0; i < 27; i++) {
                        gpio_set_pin_function(lcd_pins[i], GPIO_PIN_FUNCTION_OFF);
                        gpio_set_pin_direction(lcd_pins[i], GPIO_DIRECTION_IN);
                        gpio_set_pin_pull_mode(lcd_pins[i], GPIO_PULL_OFF);
                    }
                    pass_if(passed);
                }
                break;
            // - [X] Thermistor high
            case 'U':
                // Set TS_ENABLE high and read the value of TEMPSENSE via the ADC.
                // Pass if the value is near VCC.
                gpio_set_pin_level(TS_ENABLE, true);
                pass_if(watch_get_analog_pin_level(TEMPSENSE) > 65000);
                break;
            // - [X] Thermistor low
            case 'T':
            {
                // Set TS_ENABLE low and read the value of TEMPSENSE via the ADC.
                // Pass if the value is within the realm of reasonable temperatures.
                // 15000 is a few minutes in the freezer, 45000 is holding it a few feet above a stovetop
                gpio_set_pin_level(TS_ENABLE, false);
                uint16_t value = watch_get_analog_pin_level(TEMPSENSE);
                pass_if(value < 45000 && value > 15000);
            }
                break;
            // - [X] VLCD low
            case 'V':
                watch_enable_display();
                SLCD->CTRLA.bit.ENABLE = 0;
                while(SLCD->SYNCBUSY.bit.ENABLE);
                SLCD->CTRLC.bit.CTST = 0x0;
                SLCD->CTRLA.bit.ENABLE = 1;
                while(SLCD->SYNCBUSY.bit.ENABLE);
                break;
            // - [X] VLCD high
            case 'W':
                watch_enable_display();
                SLCD->CTRLA.bit.ENABLE = 0;
                while(SLCD->SYNCBUSY.bit.ENABLE);
                SLCD->CTRLC.bit.CTST = 0xD;
                SLCD->CTRLA.bit.ENABLE = 1;
                while(SLCD->SYNCBUSY.bit.ENABLE);
                break;
            /// TODO: LED
            case 'r':
                watch_set_led_color_rgb(255, 0, 0);
                delay_ms(100);
                watch_set_led_color_rgb(0, 0, 0);
                // It is the tester's responsibility to check the LED color.
                break;
            case 'g':
                watch_set_led_color_rgb(0, 255, 0);
                delay_ms(100);
                watch_set_led_color_rgb(0, 0, 0);
                // It is the tester's responsibility to check the LED color.
                break;
            case 'b':
                watch_set_led_color_rgb(0, 0, 255);
                delay_ms(100);
                watch_set_led_color_rgb(0, 0, 0);
                // It is the tester's responsibility to check the LED color.
                break;
            // - [X] Buttons
            case 'B':
                // Pass if all three buttons are low
                pass_if(!gpio_get_pin_level(BTN_ALARM) && !gpio_get_pin_level(BTN_LIGHT) && !gpio_get_pin_level(BTN_MODE));
                break;
            case 'L':
                // pass if BTN_LIGHT is high and the other two are low
                pass_if(gpio_get_pin_level(BTN_LIGHT) && !gpio_get_pin_level(BTN_ALARM) && !gpio_get_pin_level(BTN_MODE));
                break;
            case 'A':
                // pass if BTN_ALARM is high and the other two are low
                pass_if(gpio_get_pin_level(BTN_ALARM) && !gpio_get_pin_level(BTN_LIGHT) && !gpio_get_pin_level(BTN_MODE));
                break;
            case 'M':
                // pass if BTN_MODE is high and the other two are low
                pass_if(gpio_get_pin_level(BTN_MODE) && !gpio_get_pin_level(BTN_ALARM) && !gpio_get_pin_level(BTN_LIGHT));
                break;
            // - [X] File system
            case 'F':
                watch_storage_erase(10);
                delay_ms(10);
                watch_storage_write(10, 0, (const char *)"BEEP", 4);
                watch_storage_sync();
                watch_storage_read(10, 0, buf, 4);
                delay_ms(10);
                // No need to do anything here; comparison with 'beep' happens at next loop invocation.
                break;
        }
    }
    return false;
 }
--- a/apps/sensor-watch-pro-test/make/Makefile
+++ b/apps/sensor-watch-pro-test/make/Makefile
@ -0,0 +1,10 @@
 TOP = ../../..
 include $(TOP)/make.mk
 INCLUDES += \
  -I../
 SRCS += \
  ../app.c
 include $(TOP)/rules.mk
--- a/boards/OSO-SWAT-C1-00/pins.h
+++ b/boards/OSO-SWAT-C1-00/pins.h
@ -12,6 +12,14 @@
 #define BTN_MODE GPIO(GPIO_PORTA, 31)
 #define WATCH_BTN_MODE_EIC_CHANNEL 11
 // Temperature Sensor
 #define TS_ENABLE GPIO(GPIO_PORTB, 23)
 #define TEMPSENSE GPIO(GPIO_PORTA, 3)
 // Light Sensor
 #define IR_ENABLE GPIO(GPIO_PORTB, 22)
 #define IRSENSE GPIO(GPIO_PORTA, 4)
 // Buzzer
 #define BUZZER GPIO(GPIO_PORTA, 27)
 #define WATCH_BUZZER_TCC_PINMUX PINMUX_PA27F_TCC0_WO5
--- a/make.mk
+++ b/make.mk
@ -223,7 +223,7 @@ ifndef COLOR
 $(error Set the COLOR variable to RED, BLUE, or GREEN depending on what board you have.)
 endif
-COLOR_VALID := $(filter $(COLOR),RED BLUE GREEN)
+COLOR_VALID := $(filter $(COLOR),RED BLUE GREEN PRO)
 ifeq ($(COLOR_VALID),)
 $(error COLOR must be RED, BLUE, or GREEN)
--- a/movement/watch_faces/complication/sunrise_sunset_face.c
+++ b/movement/watch_faces/complication/sunrise_sunset_face.c
@ -45,7 +45,7 @@ static void _sunrise_sunset_set_expiration(sunrise_sunset_state_t *state, watch_
 }
 static void _sunrise_sunset_face_update(movement_settings_t *settings, sunrise_sunset_state_t *state) {
-    char buf[14];
+    char buf[11];
    double rise, set, minutes, seconds;
    bool show_next_match = false;
    movement_location_t movement_location;
@ -87,7 +87,7 @@ static void _sunrise_sunset_face_update(movement_settings_t *settings, sunrise_s
            watch_clear_colon();
            watch_clear_indicator(WATCH_INDICATOR_PM);
            watch_clear_indicator(WATCH_INDICATOR_24H);
-            sprintf(buf, "%s%2d none ", (result == 1) ? "SE" : "rI", scratch_time.unit.day);
+            snprintf(buf, sizeof(buf), "%s%2d none ", (result == 1) ? "SE" : "rI", scratch_time.unit.day);
            watch_display_string(buf, 0);
            return;
        }
@ -120,7 +120,7 @@ static void _sunrise_sunset_face_update(movement_settings_t *settings, sunrise_s
                } else if (settings->bit.clock_24h_leading_zero && scratch_time.unit.hour < 10) {
                    set_leading_zero = true;
                }
-                sprintf(buf, "rI%2d%2d%02d%s", scratch_time.unit.day, scratch_time.unit.hour, scratch_time.unit.minute,longLatPresets[state->longLatToUse].name);
+                snprintf(buf, sizeof(buf), "rI%2d%2d%02d%s", scratch_time.unit.day, scratch_time.unit.hour, scratch_time.unit.minute,longLatPresets[state->longLatToUse].name);
                watch_display_string(buf, 0);
                if (set_leading_zero)
                    watch_display_string("0", 4);
@ -152,7 +152,7 @@ static void _sunrise_sunset_face_update(movement_settings_t *settings, sunrise_s
                } else if (settings->bit.clock_24h_leading_zero && scratch_time.unit.hour < 10) {
                    set_leading_zero = true;
                }
-                sprintf(buf, "SE%2d%2d%02d%s", scratch_time.unit.day, scratch_time.unit.hour, scratch_time.unit.minute, longLatPresets[state->longLatToUse].name);
+                snprintf(buf, sizeof(buf), "SE%2d%2d%02d%s", scratch_time.unit.day, scratch_time.unit.hour, scratch_time.unit.minute, longLatPresets[state->longLatToUse].name);
                watch_display_string(buf, 0);
                if (set_leading_zero)
                    watch_display_string("0", 4);
@ -212,16 +212,16 @@ static void _sunrise_sunset_face_update_location_register(sunrise_sunset_state_t
 }
 static void _sunrise_sunset_face_update_settings_display(movement_event_t event, sunrise_sunset_state_t *state) {
-    char buf[12];
+    char buf[11];
    switch (state->page) {
        case 0:
            return;
        case 1:
-            sprintf(buf, "LA  %c %04d", state->working_latitude.sign ? '-' : '+', abs(_sunrise_sunset_face_latlon_from_struct(state->working_latitude)));
+            snprintf(buf, sizeof(buf), "LA  %c %04d", state->working_latitude.sign ? '-' : '+', abs(_sunrise_sunset_face_latlon_from_struct(state->working_latitude)));
            break;
        case 2:
-            sprintf(buf, "LO  %c%05d", state->working_longitude.sign ? '-' : '+', abs(_sunrise_sunset_face_latlon_from_struct(state->working_longitude)));
+            snprintf(buf, sizeof(buf), "LO  %c%05d", state->working_longitude.sign ? '-' : '+', abs(_sunrise_sunset_face_latlon_from_struct(state->working_longitude)));
            break;
    }
    if (event.subsecond % 2) {
--- a/watch-library/hardware/watch/watch_adc.c
+++ b/watch-library/hardware/watch/watch_adc.c
@ -97,6 +97,16 @@ void watch_enable_analog_input(const uint8_t pin) {
        case A4:
            gpio_set_pin_function(pin, PINMUX_PB00B_ADC_AIN8);
            break;
 #ifdef TEMPSENSE
        case TEMPSENSE:
            gpio_set_pin_function(pin, PINMUX_PA03B_ADC_AIN1);
            break;
 #endif
 #ifdef IRSENSE
        case IRSENSE:
            gpio_set_pin_function(pin, PINMUX_PA04B_ADC_AIN4);
            break;
 #endif
        default:
            return;
    }
@ -114,7 +124,15 @@ uint16_t watch_get_analog_pin_level(const uint8_t pin) {
            return _watch_get_analog_value(ADC_INPUTCTRL_MUXPOS_AIN11_Val);
        case A4:
            return _watch_get_analog_value(ADC_INPUTCTRL_MUXPOS_AIN8_Val);
-        default:
+#ifdef TEMPSENSE
        case TEMPSENSE:
            return _watch_get_analog_value(ADC_INPUTCTRL_MUXPOS_AIN1_Val);
 #endif
 #ifdef IRSENSE
        case IRSENSE:
            return _watch_get_analog_value(ADC_INPUTCTRL_MUXPOS_AIN4_Val);
 #endif
            default:
            return 0;
    }
 }
Author	SHA1	Message	Date
hueso	8abf6f4f5b	Fixed buffer overflows in sunrise_sunset_face Some checks failed Build / build (push) Has been cancelled Details Build / build-simulator (push) Has been cancelled Details GitHub Pages / gh-pages (push) Has been cancelled Details	2025-05-15 11:59:21 -03:00
Joey Castillo	8c39d42824	Merge branch 'main' of github.com:joeycastillo/Sensor-Watch	2025-05-06 23:57:45 -04:00
Joey Castillo	56f2c93783	sensor watch pro test procedure	2025-05-06 23:56:19 -04:00
Wesley Ellis	14e64caac9	Merge pull request #512 from tahnok/schematic-readme Add schematic info to README	2025-04-03 08:58:30 -04:00
Wesley Ellis	cc6a0c363e	Add links to schematics and gerbers for different models	2025-04-01 09:55:41 -04:00
Wesley Ellis	845caa30fb	Add link to schematics and gerbers to README	2025-04-01 09:55:41 -04:00