/node-rpi-ws281x-native

native bindings to drive WS2811 (or WS2812) LED-Controllers on a Raspberry Pi

Primary LanguageJavaScriptMIT LicenseMIT

control ws281x-LEDs with node.js

if you happen to know C++ and node/iojs/V8, I would really appreciate any help and feedback on this module. There is certainly lots of room for improvement.

This module provides native bindings to the rpi_ws281x library by Jeremy Garff to provide a very basic set of functions to write data to a strip of ws2811/ws2812 LEDs. this will only run on the Raspberry Pi.

setup

this module is available via npm:

npm install rpi-ws281x-native

if you prefer installing from source:

npm install -g node-gyp
git clone --recursive https://github.com/beyondscreen/node-rpi-ws281x-native.git
cd rpi-ws281x-native
npm install
node-gyp rebuild

basic usage

this module mainly exports four functions to send data to the LED-String.

exports = {
    /**
     * configures PWM and DMA for sending data to the LEDs.
     *
     * @param {Number} numLeds  number of LEDs to be controlled
     * @param {?Object} options  (acutally only tested with default-values)
     *                           intialization-options for the library
     *                           (PWM frequency, DMA channel, GPIO, Brightness)
     */
    init: function(numLeds, options) {},

    /**
     * register a mapping to manipulate array-indices within the
     * data-array before rendering.
     *
     * @param {Array.<Number>} map  the mapping, indexed by destination.
     */
    setIndexMapping: function(map) {},

    /**
     * set the overall-brightness for the entire strip.
     * This is a fixed scaling applied by the driver when
     * data is sent to the strip
     *
     * @param {Number} brightness the brightness, value from 0 to 255.
     */
    setBrightness: function(brightness) {},

    /**
     * send data to the LED-strip.
     *
     * @param {Uint32Array} data  the pixel-data, 24bit per pixel in
     *                            RGB-format (0xff0000 is red).
     */
    render: function(data) {},

    /**
     * clears all LEDs, resets the PWM and DMA-parts and deallocates
     * all internal structures.
     */
    reset: function() {}
};

Index-Mapping

As the wiring of the LEDs not neccessarily corresponds to the pixel-ordering in the data-array, this module supports index-remapping. So, if you are building a grid of LEDs you can just use an alternating, top-to-bottom or mirrored wiring and use the remapping in order to use a unified structure in the incoming data-arrays.

Events

In addition to that, the exported object is an EventEmitter that will emit the following Events:

  • beforeRender: emitted just before the data is prepared and sent to the LED-driver. The handler will receive the pixel-data array (an Uint32Array) as single argument. As this event is handled synchronously, you can use this to manipulate the data before it is sent to the LED-Strip.
  • render: emitted after the data has been sent to the LED-Strip. The single argument passed to the handler is the final pixel-data array, after index-remapping and gamma-correction.

testing basic functionality

connect the WS2812-strip to the raspberry-pi as described here and run the command sudo node examples/rainbow.js <numLeds>. You should now see some rainbow-colors animation on the LED-strip.

needs to run as root

As the native part of this module needs to directly interface with the physical memory of the raspberry-pi (which is required in order to configure the PWM and DMA-modules), it always has to run with root-privileges (there are probably ways around this requirement, but that doesn't change the fact that the node-process running the LEDs needs access to the raw physical memory – a thing you should never allow to any user other than root).

If you are using this module as part of a program that should not be run with elevated privileges, it would be a good idea to have the LED-driver running in a seperate process. In such a case you could use the openpixel-control protocol to send the pixel-data to the driver-process. A stream-based node-implementation and some more information can be found here.

Hardware

There is a guide over at adafruit.com on how to get the hardware up and running. I followed these instructions by the word and had a working LED-strip.

Essentially, you need the Raspberry Pi, a logic-level converter to shift the output-voltage of the GPIO from 3.3V up to 5V (the guide mentions the 74AHCT125, mine is an 74HCT125N which works just as well) and of course a LED-Strip or other types of WS2812-LEDs.

To connect all that together, I'd recommend buying a small breadboard and some jumper-wires. Also, consider buying a 5V power-supply that can deliver up to 60mA per LED (so you'll need up to 6A (30W) to fully power 100 LEDs). For smaller applications, a decent USB-charger should do.

Buying stuff

A short checklist of what you will need:

  • Raspberry-PI and SD-Card
  • 5V power-supply (Meanwell for instance builds really good ones)
  • LED-Strip with WS2811/WS2812 Controllers (there are several other controller-variations that are not supported)
  • a breadboard and some jumper-wires (m/m as well as at least two f/m to connect the GPIO-Pins)
  • a 3.3V to 5V logic-level converter (74AHCT125 or 74HCT125N, others will probably also work)
  • more wire to connect the LED-strips

You can buy everything at adafruit.com, sparkfun, on ebay or your favourite electronics retailer (germany: check conrad electronic, watterott or reichelt where i bought most of my stuff).

Known Issues

There is a conflict where the internal soundcard uses the same GPIO / DMA / PWM functions that are needed to run the LED-drivers. As far as I know you can not use both at the same time.

One workaround is to use an external (USB) soundcard and make it the default device:

Edit /etc/modprobe.d/alsa-base.conf and comment out the line

options snd-usb-audio index=-2

If anyone finds a better solution please get in touch!