#include #include #include #include #include #include #include #include #include #include #include static uint8_t dmx_universe[129]; static struct animation led_animation; enum color_mode { MODE_RED, MODE_GREEN, MODE_BLUE, MODE_RGB, MODE_WHITE_DISCRETE, MODE_ANIMATION, MODE_GREEN_BLUE_ANGLE, MODE_WHITE_ANGLE, MODE_DMX_SHUTDOWN, }; static void setup_pins(void) { uint32_t tmp; RCC->AHBENR |= RCC_AHBENR_GPIOAEN | RCC_AHBENR_GPIOBEN; tmp = GPIOA->MODER; /* Reset all used port pins */ tmp &= MODER_DELETE(0) & MODER_DELETE(1) & MODER_DELETE(2) & MODER_DELETE(3) & MODER_DELETE(4) & MODER_DELETE(5) & MODER_DELETE(6) & MODER_DELETE(7) & MODER_DELETE(8) & MODER_DELETE(9) & MODER_DELETE(10); /* Analog ports for POTIs */ tmp |= ANALOG(0) | ANALOG(1) | ANALOG(4); /* Setup USART1 RX/TX (AF1) */ tmp |= ALTFUNC(2) | ALTFUNC(3); SETAF(GPIOA, 2, 1); SETAF(GPIOA, 3, 1); /* LED enables for Potentiometers */ tmp |= OUTPUT(5) | OUTPUT(6) | OUTPUT(7); GPIOA->ODR &= ~((1 << 5) | (1 << 6) | (1 << 7)); /* Setup I2C pins (AF4) */ tmp |= ALTFUNC(9) | ALTFUNC(10); SETAF(GPIOA, 9, 4); SETAF(GPIOA, 10, 4); /* Set I2C Pins to open drain. Others are push pull */ GPIOA->OTYPER = OTYP_OPENDRAIN(9) | OTYP_OPENDRAIN(10); /* Write changes to GPIOA mode register */ GPIOA->MODER = tmp; /* PB1 Input with pullup */ GPIOB->MODER &= MODER_DELETE(1); GPIOB->PUPDR = PULLUP(1); } static uint32_t map_index_to_range(int32_t index, uint32_t len) { int32_t mapped; if (index < 0) { mapped = len - (-index) % len; } else { mapped = index % len; } return (uint32_t)mapped; } static void dmx_universe_set_rgbw(uint32_t led_idx, const struct rgbw_color *col) { dmx_universe[led_idx * 4 + 0] = col->red; dmx_universe[led_idx * 4 + 1] = col->green; dmx_universe[led_idx * 4 + 2] = col->blue; dmx_universe[led_idx * 4 + 3] = col->white; } static void set_angle(uint32_t led_count, uint32_t pos, uint32_t width, const struct rgbw_color *col, const struct rgbw_color *rest) { int32_t lower_end; int32_t upper_end; int32_t idx; int32_t mapped_idx; if (width > led_count) return; upper_end = pos + width / 2u; lower_end = pos - width / 2u; /* Set leds to color */ for (idx = lower_end; idx <= upper_end; idx++) { mapped_idx = map_index_to_range(idx, led_count); dmx_universe_set_rgbw(mapped_idx, col); } /* Set the rest ring to rest color */ for (idx = upper_end + 1; idx < (upper_end + 1 + (int32_t)(led_count - width)); idx++) { mapped_idx = map_index_to_range(idx, led_count); dmx_universe_set_rgbw(mapped_idx, rest); } } static void process_mode(enum color_mode mode, const struct poti_values *poti_vals) { uint32_t odr; static bool last_blink_state = false; bool blink_state; int i; struct rgbw_color col1 = {0, 0, 0, 0}; struct rgbw_color col2 = {0, 0, 0, 0}; odr = GPIOA->ODR; odr &= ~((1<<5) | (1<<6) | (1<<7)); switch (mode) { case MODE_RED: case MODE_GREEN: case MODE_BLUE: for (i = 0; i < 32; i++) { dmx_universe[i * 4 + 0] = mode == MODE_RED ? poti_vals->pot_vals_filtered[0] : 0; dmx_universe[i * 4 + 1] = mode == MODE_GREEN ? poti_vals->pot_vals_filtered[0] : 0; dmx_universe[i * 4 + 2] = mode == MODE_BLUE ? poti_vals->pot_vals_filtered[0] : 0; dmx_universe[i * 4 + 3] = 0x0; } dmx_universe[128] = 0; odr |= (1<<5); break; case MODE_RGB: odr |= (1<<5) | (1<<6) | (1<<7); for (i = 0; i < 32; i++) { dmx_universe[i * 4 + 0] = poti_vals->pot_vals_filtered[0]; dmx_universe[i * 4 + 1] = poti_vals->pot_vals_filtered[1]; dmx_universe[i * 4 + 2] = poti_vals->pot_vals_filtered[2]; dmx_universe[i * 4 + 3] = 0x0; } dmx_universe[128] = 0; break; case MODE_WHITE_DISCRETE: odr |= (1<<5) | (1<<6); for (i = 0; i < 32; i++) { dmx_universe[i * 4 + 0] = 0; dmx_universe[i * 4 + 1] = 0; dmx_universe[i * 4 + 2] = 0; dmx_universe[i * 4 + 3] = gamma_corr(poti_vals->pot_vals_filtered[1]); } dmx_universe[128] = gamma_corr(poti_vals->pot_vals_filtered[0]); break; case MODE_ANIMATION: animation_process(&led_animation, dmx_universe); break; case MODE_DMX_SHUTDOWN: blink_state = systick_get_blink_state(); if (blink_state != last_blink_state) { port_expander_set_leds(blink_state ? (1<<0) : (1<<4)); } last_blink_state = blink_state; break; case MODE_GREEN_BLUE_ANGLE: dmx_universe[128] = 0u; odr |= (1<<5) | (1<<6) | (1<<7); col1.blue = poti_vals->pot_vals_filtered[0]; col2.green = poti_vals->pot_vals_filtered[0]; set_angle(32u, (int32_t)poti_vals->pot_vals_filtered[1] * 32u / 255u, (int32_t)poti_vals->pot_vals_filtered[2] * 32u / 255u, &col1, &col2); break; case MODE_WHITE_ANGLE: dmx_universe[128] = 0u; odr |= (1<<5) | (1<<6) | (1<<7); col1.white = poti_vals->pot_vals_filtered[0]; col1.red = poti_vals->pot_vals_filtered[0]; col1.green = poti_vals->pot_vals_filtered[0]; col1.blue = poti_vals->pot_vals_filtered[0]; set_angle(32u, (int32_t)poti_vals->pot_vals_filtered[1] * 32u / 255u, (int32_t)poti_vals->pot_vals_filtered[2] * 32u / 255u, &col1, &col2); break; default: break; } GPIOA->ODR = odr; } static bool filtered_poti_vals_equal(const struct poti_values *p1, const struct poti_values *p2) { uint32_t i; bool ret = true; for (i = 0; i < POTI_COUNT; i++) { if (p1->pot_vals_filtered[i] != p2->pot_vals_filtered[i]) { ret = false; break; } } return ret; } /** * @brief Check if a color mode requires continous updates * * @param mode Color mode input * @return true Color mode requires continous updates * @return false Color mode does not reuqire continuous update */ static bool mode_is_continuous(enum color_mode mode) { bool ret = false; switch (mode) { case MODE_ANIMATION: case MODE_DMX_SHUTDOWN: ret = true; break; default: ret = false; break; } return ret; } int main(void) { unsigned int i; uint8_t port; uint8_t button_pressed; enum color_mode mode = MODE_DMX_SHUTDOWN; enum color_mode old_mode = MODE_BLUE; struct poti_values poti_vals = {0}; struct poti_values old_poti_vals = {0}; bool buttons_released_since_dual_press = true; setup_pins(); dmx_init(dmx_universe, sizeof(dmx_universe), GPIOA, 2u, 2000u, 10u, 5u); poti_init_adc(); port_expander_init(); port_expander_set_leds(1 << 4); /* Setup Systick for 1ms ticks */ SysTick_Config(48000000UL/1000); for (i = 0; i < sizeof(dmx_universe); i++) { dmx_universe[i] = 0x00; } while (1) { systick_wait_ms(20); poti_get_values(&poti_vals); port = port_expander_get_buttons(); /* Isolate lowest set bit. This prevents edge cases where multipe switches are pressed */ button_pressed = 0u; for (i = 0; i < 8; i++) { if (port & (1 << i)) { button_pressed = i + 1u; break; } } if (button_pressed) { if (!buttons_released_since_dual_press) button_pressed = 0u; } else { /* Buttons are released. Remember this */ buttons_released_since_dual_press = true; } switch (button_pressed) { case 1: mode = MODE_RED; break; case 2: mode = MODE_GREEN; break; case 3: mode = MODE_BLUE; break; case 4: mode = MODE_RGB; break; case 5: mode = MODE_WHITE_DISCRETE; break; case 6: mode = MODE_WHITE_ANGLE; break; case 7: mode = MODE_GREEN_BLUE_ANGLE; break; case 8: animation_reset(&led_animation); mode = MODE_ANIMATION; break; default: break; } /* Check for special case: 1 + 5 pressed simultaneously*/ if ((port & ((1<<0 | (1<<4)))) == ((1<<4) | (1<<0))) { /* Prevent nomal logic from triggering on this */ button_pressed = 0; /* set mode to DMX off and disable DMX */ mode = MODE_DMX_SHUTDOWN; buttons_released_since_dual_press = false; dmx_stream_stop(); } else if (mode != old_mode && old_mode == MODE_DMX_SHUTDOWN && buttons_released_since_dual_press) { /* Wakeup DMX */ dmx_stream_start(); } if (button_pressed) port_expander_set_leds((1 << (button_pressed - 1))); if (mode != old_mode || !filtered_poti_vals_equal(&poti_vals, &old_poti_vals) || mode_is_continuous(mode)) { /* The values changed. Update the DMX frame */ process_mode(mode, &poti_vals); } /* Move to old values. Used to detect changes */ old_mode = mode; old_poti_vals = poti_vals; } }