Go binding for rpi-rgb-led-matrix an excellent C++ library to control RGB LED displays with Raspberry Pi GPIO.
This library includes the basic bindings to control de LED Matrix directly and also a convenient ToolKit with more high level functions. Also some examples are included to test the library and the configuration.
The Canvas struct implements the image.Image interface from the Go standard library. This makes the interaction with the matrix simple as work with a normal image in Go, allowing the usage of any Go library build around the image.Image interface.
To learn about the configuration and the wiring go to the original library, is highly detailed and well explained.
The recommended way to add go-rpi-rgb-led-matrix package into your project is:
go get -v github.com/zaggash/go-rpi-rgb-led-matrixThen you will get an expected error like this:
# github.com/zaggash/go-rpi-rgb-led-matrix
../../../go/pkg/mod/github.com/zaggash/[email protected]/matrix.go:6:10: fatal error: led-matrix-c.h: No such file or directory
6 | #include <led-matrix-c.h>
| ^~~~~~~~~~~~~~~~
compilation terminated.
This happens because you need to compile the rgbmatrix C bindings. Using the path provided to the go mod package:
cd $GOPATH/go/pkg/mod/github.com/zaggash/[email protected]/
chmod u+w ./
mkdir ./lib && cd lib
git clone https://github.com/hzeller/rpi-rgb-led-matrix.git
cd rpi-rgb-led-matrix
make -jThis will compile the latest version of the library. The latest version tested with the binding is always the one as the submodule in this repo. Try with that commit if you encounter any issues. This have to be compiled for the destination architecture that will run the Go binary.
After this is done go back to your project and execute the go get command again. This should now work:
$ go get -v github.com/zaggash/go-rpi-rgb-led-matrix
go: finding github.com/zaggash/go-rpi-rgb-led-matrix latest
github.com/zaggash/go-rpi-rgb-led-matrixSetting all the pixels to white:
// create a new Matrix instance with the DefaultConfig and if needed the Runtimeconfig
m, _ := rgbmatrix.NewRGBLedMatrix(&rgbmatrix.DefaultConfig, nil)
// create the Canvas, implements the image.Image interface
c := rgbmatrix.NewCanvas(m)
defer c.Close() // don't forgot close the Matrix, if not your leds will remain on
// using the standard draw.Draw function we copy a white image onto the Canvas
draw.Draw(c, c.Bounds(), &image.Uniform{color.White}, image.Point{}, draw.Src)
// don't forget call Render to display the new led status
c.Render()Playing a GIF into your matrix during 30 seconds:
// create a new Matrix instance with the DefaultConfig and if needed the Runtimeconfig
m, _ := rgbmatrix.NewRGBLedMatrix(&rgbmatrix.DefaultConfig, nil)
// create a ToolKit instance
tk := rgbmatrix.NewToolKit(m)
defer tk.Close() // don't forgot close the Matrix, if not your leds will remain on
// open the gif file for reading
file, _ := os.Open("mario.gif")
// play of the gif using the io.Reader
close, _ := tk.PlayGIF(f)
fatal(err)
// we wait 30 seconds and then we stop the playing gif sending a True to the returned chan
time.Sleep(time.Second * 30)
close <- trueThe image of the header was recorded using this few lines, the running Mario gif, and three 32x64 pannels.
Check the folder examples folder for more examples
As part of the library an small Matrix emulator is provided. The emulator renderize a virtual RGB matrix on a window in your desktop, without needing a real RGB matrix connected to your computer.
To execute the emulator set the MATRIX_EMULATOR environment variable to 1, then when NewRGBLedMatrix is used, a emulator.Emulator is returned instead of a interface the real board.
MIT, see LICENSE