Add Raspberry Pi Pico WS2812 LED example

2024-12-24 05:01:31 +11:00 · 2022-01-09 15:27:29 +01:00 · 2022-01-09 15:27:29 +01:00 · 2b49bc6b60
parent 0e3136da11
commit 2b49bc6b60
2 changed files with 226 additions and 0 deletions
--- a/boards/rp-pico/Cargo.toml
+++ b/boards/rp-pico/Cargo.toml
@ -29,6 +29,8 @@ nb = "1.0"
 i2c-pio = { git = "https://github.com/ithinuel/i2c-pio-rs", rev = "df06e4ac94a5b2c985d6a9426dc4cc9be0d535c0" }
 heapless = "0.7.9"
 embedded-sdmmc = { git = "https://github.com/rust-embedded-community/embedded-sdmmc-rs.git" }
 smart-leds = "0.3.0"
 ws2812-pio = { git = "https://github.com/ithinuel/ws2812-pio-rs", rev = "4f0d81e594ea9934f9c4c38ed9824ad0cce4ebb5" }
 defmt = "0.2.0"
 defmt-rtt = "0.2.0"
--- a/boards/rp-pico/examples/pico_ws2812_led.rs
+++ b/boards/rp-pico/examples/pico_ws2812_led.rs
@ -0,0 +1,224 @@
 //! # Pico WS2812 RGB LED Example
 //!
 //! Drives 3 WS2812 LEDs connected directly to the Raspberry Pi Pico.
 //! This assumes you drive the Raspberry Pi Pico via USB power, so that VBUS
 //! delivers the 5V and at least enough amperes to drive the LEDs.
 //!
 //! For a more large scale and longer strips you should use an extra power
 //! supply for the LED strip (or know what you are doing ;-) ).
 //!
 //! The example also comes with an utility function to calculate the colors
 //! from HSV color space. It also limits the brightness a bit to save a
 //! few amperes.
 //!
 //! The example assumes you connected the data input to pin 6 of the
 //! Raspberry Pi Pico, which is GPIO4 of the rp2040. Here is a circuit
 //! diagram that shows the assumed setup:
 //!
 //! ```text
 //!  _______________      /----------------------\
 //! |+5V  /---\  +5V|----/         _|USB|_       |
 //! |DO <-|LED|<- DI|-\           |1  R 40|-VBUS-/
 //! |GND  \---/  GND|--+---\      |2  P 39|
 //!  """""""""""""""   |    \-GND-|3    38|
 //!                    |          |4  P 37|
 //!                    |          |5  I 36|
 //!                    \------GP4-|6  C   |
 //!                               |7  O   |
 //!                               |       |
 //!                               .........
 //!                               |20   21|
 //!                                """""""
 //! Symbols:
 //!     - (+) crossing lines, not connected
 //!     - (o) connected lines
 //! ```
 //!
 //! See the `Cargo.toml` file for Copyright and licence details.
 #![no_std]
 #![no_main]
 // The macro for our start-up function
 use cortex_m_rt::entry;
 // Ensure we halt the program on panic (if we don't mention this crate it won't
 // be linked)
 use panic_halt as _;
 // Pull in any important traits
 use rp_pico::hal::prelude::*;
 // Embed the `Hz` function/trait:
 use embedded_time::rate::*;
 // A shorter alias for the Peripheral Access Crate, which provides low-level
 // register access
 use rp_pico::hal::pac;
 // Import the Timer for Ws2812:
 use rp_pico::hal::timer::Timer;
 // A shorter alias for the Hardware Abstraction Layer, which provides
 // higher-level drivers.
 use rp_pico::hal;
 // PIOExt for the split() method that is needed to bring
 // PIO0 into useable form for Ws2812:
 use rp_pico::hal::pio::PIOExt;
 // Import useful traits to handle the ws2812 LEDs:
 use smart_leds::{brightness, SmartLedsWrite, RGB8};
 // Import the actual crate to handle the Ws2812 protocol:
 use ws2812_pio::Ws2812;
 // Currently 3 consecutive LEDs are driven by this example
 // to keep the power draw compatible with USB:
 const STRIP_LEN: usize = 3;
 #[entry]
 fn main() -> ! {
    // Grab our singleton objects
    let mut pac = pac::Peripherals::take().unwrap();
    let core = pac::CorePeripherals::take().unwrap();
    // Set up the watchdog driver - needed by the clock setup code
    let mut watchdog = hal::Watchdog::new(pac.WATCHDOG);
    // Configure the clocks
    //
    // The default is to generate a 125 MHz system clock
    let clocks = hal::clocks::init_clocks_and_plls(
        rp_pico::XOSC_CRYSTAL_FREQ,
        pac.XOSC,
        pac.CLOCKS,
        pac.PLL_SYS,
        pac.PLL_USB,
        &mut pac.RESETS,
        &mut watchdog,
    )
    .ok()
    .unwrap();
    // The single-cycle I/O block controls our GPIO pins
    let sio = hal::Sio::new(pac.SIO);
    // Set the pins up according to their function on this particular board
    let pins = rp_pico::Pins::new(
        pac.IO_BANK0,
        pac.PADS_BANK0,
        sio.gpio_bank0,
        &mut pac.RESETS,
    );
    // Setup a delay for the LED blink signals:
    let mut frame_delay =
        cortex_m::delay::Delay::new(core.SYST, clocks.system_clock.freq().integer());
    // Import the `sin` function for a smooth hue animation from the
    // Pico rp2040 ROM:
    let sin = unsafe {
        core::mem::transmute::<_, fn(f32) -> f32>(rp_pico::hal::rom_data::float_funcs::fsin())
    };
    // Create a count down timer for the Ws2812 instance:
    let timer = Timer::new(pac.TIMER, &mut pac.RESETS);
    // Split the PIO state machine 0 into individual objects, so that
    // Ws2812 can use it:
    let (mut pio, sm0, _, _, _) = pac.PIO0.split(&mut pac.RESETS);
    // Instanciate a Ws2812 LED strip:
    let mut ws = Ws2812::new(
        // Use pin 6 on the Raspberry Pi Pico (which is GPIO4 of the rp2040 chip)
        // for the LED data output:
        pins.gpio4.into_mode(),
        &mut pio,
        sm0,
        clocks.peripheral_clock.freq(),
        timer.count_down(),
    );
    let mut leds: [RGB8; STRIP_LEN] = [(0, 0, 0).into(); STRIP_LEN];
    let mut t = 0.0;
    // Bring down the overall brightness of the strip to save
    // a few amperes (every LED draws ~60mA, RGB means 3 LEDs per
    // ws2812 LED, for 3 LEDs that would be: 3 * 3 * 60mA, which is
    // already 540mA!
    let strip_brightness = 64u8; // Limit brightness to 64/256
    // Slow down timer by this factor (0.1 will result in 10 seconds):
    let animation_speed = 0.1;
    loop {
        for (i, led) in leds.iter_mut().enumerate() {
            // An offset to give 3 consecutive LEDs a different color:
            let hue_offs = match i % 3 {
                1 => 0.25,
                2 => 0.5,
                _ => 0.0,
            };
            let sin_11 = sin((t + hue_offs) * 2.0 * core::f32::consts::PI);
            // Bring -1..1 sine range to 0..1 range:
            let sin_01 = (sin_11 + 1.0) * 0.5;
            let hue = 360.0 * sin_01;
            let sat = 1.0;
            let val = 1.0;
            let rgb = hsv2rgb_u8(hue, sat, val);
            *led = rgb.into();
        }
        // Here the magic happens and the `leds` buffer is written to the
        // ws2812 LEDs:
        ws.write(brightness(leds.iter().copied(), strip_brightness))
            .unwrap();
        // Wait a bit until calculating the next frame:
        frame_delay.delay_ms(16); // ~60 FPS
        // Increase the time counter variable and make sure it
        // stays inbetween 0.0 to 1.0 range:
        t += (16.0 / 1000.0) * animation_speed;
        while t > 1.0 {
            t -= 1.0;
        }
    }
 }
 pub fn hsv2rgb(hue: f32, sat: f32, val: f32) -> (f32, f32, f32) {
    let c = val * sat;
    let v = (hue / 60.0) % 2.0 - 1.0;
    let v = if v < 0.0 { -v } else { v };
    let x = c * (1.0 - v);
    let m = val - c;
    let (r_, g_, b_) = if (0.0..60.0).contains(&hue) {
        (c, x, 0.0)
    } else if (60.0..120.0).contains(&hue) {
        (x, c, 0.0)
    } else if (120.0..180.0).contains(&hue) {
        (0.0, c, x)
    } else if (180.0..240.0).contains(&hue) {
        (0.0, x, c)
    } else if (240.0..300.0).contains(&hue) {
        (x, 0.0, c)
    } else {
        // if hue >= 300.0 && hue < 360.0 {
        (c, 0.0, x)
    };
    (r_ + m, g_ + m, b_ + m)
 }
 pub fn hsv2rgb_u8(h: f32, s: f32, v: f32) -> (u8, u8, u8) {
    let r = hsv2rgb(h, s, v);
    (
        (r.0 * 255.0) as u8,
        (r.1 * 255.0) as u8,
        (r.2 * 255.0) as u8,
    )
 }