Blinkt is a Rust library that provides an interface for the Pimoroni Blinkt!, and any similar APA102 or SK9822 LED strips or boards, on a Raspberry Pi. The library supports bitbanging mode on any GPIO pins, and hardware SPI mode on GPIO 10 (physical pin 19) for data, and GPIO 11 (physical pin 23) for clock.
For bitbanging mode, Blinkt gains access to the BCM283x GPIO peripheral either through /dev/gpiomem
or /dev/mem
. Hardware SPI mode is controlled through /dev/spidev0.0
.
Both the original APA102 and the SK9822 clone are supported. The RGB LED/driver ICs are referred to as pixels throughout the code and documentation.
Backwards compatibility for minor revisions isn't guaranteed until the library reaches v1.0.0.
Blinkt is under development on the master branch of the repository on GitHub. If you're looking for the README.md
or the examples
directory for the latest release or any of the earlier releases, visit crates.io, download an archived release from the GitHub releases page, or clone and checkout the relevant release tag.
Online documentation is available for the latest release, older releases, and the version currently in development.
- Latest release: docs.golemparts.com/blinkt
- Older releases: docs.rs/blinkt
- In development: docs.golemparts.com/blinkt-dev
Add a dependency for blinkt
to your Cargo.toml
using cargo add blinkt
, or by adding the following line to your dependencies section.
[dependencies]
blinkt = "0.7.1"
Call Blinkt::new()
to create a new Blinkt with the default settings. Alternative configuration options are available through Blinkt::with_settings()
and Blinkt::with_spi()
.
use blinkt::Blinkt;
let mut blinkt = Blinkt::new()?;
The example below demonstrates swapping all pixels on a Blinkt! board between red, green and blue.
use std::error::Error;
use std::time::Duration;
use std::{mem, thread};
use blinkt::Blinkt;
fn main() -> Result<(), Box<dyn Error>> {
let mut blinkt = Blinkt::new()?;
let (red, green, blue) = (&mut 255, &mut 0, &mut 0);
loop {
blinkt.set_all_pixels(*red, *green, *blue);
blinkt.show()?;
thread::sleep(Duration::from_millis(250));
mem::swap(red, green);
mem::swap(red, blue);
}
}
To control an LED strip consisting of 144 pixels, connected to the Raspberry Pi's hardware SPI pins (data on GPIO 10 (physical pin 19), and clock on GPIO 11 (physical pin 23)), at 16 MHz clock speed, replace the Blinkt::new()
line in the above example with the following. You may have to tweak the maximum clock speed based on the number of pixels and the wire quality.
let mut blinkt = Blinkt::with_spi(16_000_000, 144)?;
Additional examples can be found in the examples
directory.
If you're not working directly on a Raspberry Pi, you'll have to cross-compile your code for the appropriate ARM architecture. Check out this guide for more information, or try the cross project for "zero setup" cross compilation.
While additional steps may be necessary to cross-compile binaries on your platform, checking your code with cargo check
only requires the installation of an appropriate target. Most Raspberry Pi models need the armv7-unknown-linux-gnueabihf
target. For some models, like the Raspberry Pi Zero, a different target triple is required.
Install the relevant target using rustup
.
rustup target install armv7-unknown-linux-gnueabihf
In the root directory of your project, create a .cargo
subdirectory, and then save the following snippet to .cargo/config
.
[build]
target = "armv7-unknown-linux-gnueabihf"
The rust-analyzer extension for Visual Studio Code needs to be made aware of the target platform by setting the rust-analyzer.cargo.target
configuration option. In the root directory of your project, create a .vscode
subdirectory, and then save the following snippet to .vscode/settings.json
.
{
"rust-analyzer.cargo.target": "armv7-unknown-linux-gnueabihf"
}
Copyright (c) 2016-2022 Rene van der Meer. Released under the MIT license.