pimoroni-pico/examples/plasma2040/plasma2040_rotary.cpp

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#include <stdio.h>
#include <math.h>
#include <cstdint>
#include "pico/stdlib.h"
#include "plasma2040.hpp"
#include "common/pimoroni_common.hpp"
#include "breakout_encoder.hpp"
#include "rgbled.hpp"
#include "button.hpp"
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/*
Press "B" to enable cycling.
Press "A" to change the encoder mode.
Press "Boot" to reset the effects back to default.
*/
using namespace pimoroni;
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using namespace plasma;
// Set how many LEDs you have
const uint N_LEDS = 30;
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// The speed that the LEDs will start cycling at
const int16_t DEFAULT_SPEED = 20;
// The hue (in degrees) that the LEDs will start at
const int16_t DEFAULT_HUE = 0;
// The angle (in degrees) from the hue, that the LEDs will end at
const int16_t DEFAULT_ANGLE = 120;
// The brightness (between 0 and 31) to set the LEDs to
const int16_t DEFAULT_BRIGHTNESS = 16;
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// How many times the LEDs will be updated per second
const uint UPDATES = 60;
// Pick *one* LED type by uncommenting the relevant line below:
// APA102-style LEDs with Data/Clock lines. AKA DotStar
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//APA102 led_strip(N_LEDS, pio0, 0, plasma2040::DAT, plasma2040::CLK);
// WS28X-style LEDs with a single signal line. AKA NeoPixel
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WS2812 led_strip(N_LEDS, pio0, 0, plasma2040::DAT);
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Button user_sw(plasma2040::USER_SW, Polarity::ACTIVE_LOW, 0);
Button button_a(plasma2040::BUTTON_A, Polarity::ACTIVE_LOW, 0);
Button button_b(plasma2040::BUTTON_B, Polarity::ACTIVE_LOW, 0);
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RGBLED led(plasma2040::LED_R, plasma2040::LED_G, plasma2040::LED_B);
I2C i2c(BOARD::PICO_EXPLORER);
BreakoutEncoder enc(&i2c);
enum ENCODER_MODE {
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COLOUR,
ANGLE,
BRIGHTNESS,
SPEED
};
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float wrap(float v, float min, float max) {
if(v <= min)
v += (max - min);
if(v > max)
v -= (max - min);
return v;
}
void colour_cycle(float hue, float t, float angle) {
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t /= 200.0f;
for(auto i = 0u; i < led_strip.num_leds; ++i) {
float percent_along = (float)i / led_strip.num_leds;
float offset = sinf((percent_along + 0.5f + t) * M_PI) * angle;
float h = wrap((hue + offset) / 360.0f, 0.0f, 1.0f);
led_strip.set_hsv(i, h, 1.0f, 1.0f);
}
}
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void speed_gauge(uint v, uint vmax = 100) {
uint light_pixels = led_strip.num_leds * v / vmax;
for(auto i = 0u; i < led_strip.num_leds; ++i) {
if(i < light_pixels) {
led_strip.set_rgb(i, 0, 255, 0);
}
else {
led_strip.set_rgb(i, 255, 0, 0);
}
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}
}
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void brightness_gauge(uint v, uint vmax = 100) {
uint light_pixels = led_strip.num_leds * v / vmax;
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for(auto i = 0u; i < led_strip.num_leds; ++i) {
if(i < light_pixels) {
led_strip.set_rgb(i, 64, 64, 64);
}
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else {
led_strip.set_rgb(i, 0, 0, 0);
}
}
}
int main() {
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stdio_init_all();
led_strip.start(UPDATES);
bool encoder_detected = enc.init();
enc.clear_interrupt_flag();
//Initialise the default values
int16_t speed = DEFAULT_SPEED;
int16_t hue = DEFAULT_HUE;
int16_t angle = DEFAULT_ANGLE;
int16_t brightness = DEFAULT_BRIGHTNESS;
bool cycle = true;
ENCODER_MODE mode = ENCODER_MODE::COLOUR;
uint32_t start_time = millis();
while(true) {
uint32_t t = millis() - start_time;
if(encoder_detected) {
if(enc.get_interrupt_flag()) {
int16_t count = enc.read();
enc.clear_interrupt_flag();
enc.clear();
cycle = false;
switch(mode) {
case ENCODER_MODE::COLOUR:
hue += count;
hue = std::min((int16_t)359, std::max((int16_t)0, hue));
colour_cycle((float)hue, 0, (float)angle);
break;
case ENCODER_MODE::ANGLE:
angle += count;
angle = std::min((int16_t)359, std::max((int16_t)0, angle));
colour_cycle((float)hue, 0, (float)angle);
break;
case ENCODER_MODE::BRIGHTNESS:
brightness += count;
brightness = std::min((int16_t)31, std::max((int16_t)0, brightness));
led_strip.set_brightness((uint8_t)brightness);
brightness_gauge(brightness, 31);
break;
case ENCODER_MODE::SPEED:
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speed += count;
speed = std::min((int16_t)100, std::max((int16_t)0, speed));
speed_gauge(speed, 100);
break;
}
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}
}
bool sw_pressed = user_sw.read();
bool a_pressed = button_a.read();
bool b_pressed = button_b.read();
if(sw_pressed) {
speed = DEFAULT_SPEED;
hue = DEFAULT_HUE;
angle = DEFAULT_ANGLE;
brightness = DEFAULT_BRIGHTNESS;
}
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if(b_pressed) {
if(!cycle)
start_time = millis();
cycle = true;
}
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switch(mode) {
case ENCODER_MODE::COLOUR:
led.set_rgb(255, 0, 0);
if(a_pressed) mode = ENCODER_MODE::ANGLE;
break;
case ENCODER_MODE::ANGLE:
led.set_rgb(255, 255, 0);
if(a_pressed) mode = ENCODER_MODE::BRIGHTNESS;
break;
case ENCODER_MODE::BRIGHTNESS:
led.set_rgb(0, 255, 0);
if(a_pressed) mode = ENCODER_MODE::SPEED;
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break;
case ENCODER_MODE::SPEED:
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led.set_rgb(0, 0, 255);
if(a_pressed) mode = ENCODER_MODE::COLOUR;
break;
}
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if(cycle)
colour_cycle(hue, (float)(t * speed) / 100.0f, (float)angle);
auto mid_led = led_strip.get(led_strip.num_leds / 2);
enc.set_led(mid_led.r, mid_led.g, mid_led.b);
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// Sleep time controls the rate at which the LED buffer is updated
// but *not* the actual framerate at which the buffer is sent to the LEDs
sleep_ms(1000 / UPDATES);
}
}