#framebuffer #windowing #softbuffer

softbuffer-rgb

A wrapper around softbuffer that makes it easier to modify a raw pixel buffer

2 releases

0.1.1 Jul 26, 2024
0.1.0 Jul 26, 2024

#66 in Rendering

MIT license

415KB
50 lines

softbuffer-rgb

softbuffer-rgb is a wrapper around softbuffer that makes it easier to modify a raw pixel buffer.

Instead of doing this:

buffer.buffer_mut()[y * width + x] = u32::from_le_bytes([0, 200, 70, 10]);

...you can now do this:

buffer.pixels[y][x] = [0, 200, 70, 10];

Problem

softbuffer stores pixel data in a u32 buffer where each u32 is an "0RGB" color. The first byte is always zero, the second byte is red, the third byte is green, and the fourth byte is blue.

It's intuitive to store colors as arrays, like this:

let color = [0, 200, 70, 10];

But in softbuffer, colors need to be u32s:

let color = u32::from_le_bytes([0, 200, 70, 10]);

Additionally, softbuffer buffers are one-dimensional. Typically, you'll want to program in a 2D (x, y) coordinate space, meaning that you'll have to convert 2D (x, y) coordinates to 1D indices. It's a cheap operation but if you have to do it for many pixels, per frame, the performance cost can add up!

Solution

softbuffer-rgb uses a tiny bit of unsafe code to rearrange the raw buffer data into a 3D array: (width, height, 0RGB). Modifying this pixels array will modify the the underlying u32 buffer array, and vice versa.

As a result:

  • softbuffer-rgb can be easier to use than softbuffer.
  • softbuffer-rgb can be slightly faster because you don't need to convert to u32s and you don't need to convert (x, y) coordinates to indices.

Caveat

softbuffer-rgb relies on generic constants to define the size of pixels, meaning that the buffer size must be known at compile-time.

Example

use softbuffer::{Context, Surface};
use std::num::NonZeroU32;
use winit::application::ApplicationHandler;
use winit::dpi::LogicalSize;
use winit::event::{StartCause, WindowEvent};
use winit::event_loop::{ActiveEventLoop, EventLoop};
use winit::window::{Window, WindowAttributes, WindowId};

use softbuffer_rgb::RgbBuffer;

const X: usize = 400;
const Y: usize = 300;

fn main() {
   let mut app = App::default();
   let event_loop = EventLoop::new().unwrap();
   event_loop.run_app(&mut app).unwrap();
}

#[derive(Default)]
struct App {
   window: Option<Window>,
}

impl ApplicationHandler for App {
   fn resumed(&mut self, _: &ActiveEventLoop) {}

   fn new_events(&mut self, event_loop: &ActiveEventLoop, cause: StartCause) {
       if let StartCause::Init = cause {
           let window_attributes =
               WindowAttributes::default().with_inner_size(LogicalSize::new(X as u32, Y as u32));
           // Create the window.
           self.window = Some(event_loop.create_window(window_attributes).unwrap());
           // Get the window.
           let window = self.window.as_ref().unwrap();
           let context = Context::new(window).unwrap();
           let mut surface = Surface::new(&context, &window).unwrap();
           surface
               .resize(
                   NonZeroU32::new(X as u32).unwrap(),
                   NonZeroU32::new(Y as u32).unwrap(),
               )
               .unwrap();
           let mut rgb_buffer =
               RgbBuffer::<X, Y, _, _>::from_softbuffer(surface.buffer_mut().unwrap()).unwrap();
           let x = 12;
           let y = 23;
           rgb_buffer.pixels[y][x] = [0, 200, 100, 70];
           event_loop.exit();
       }
   }

   fn window_event(&mut self, _: &ActiveEventLoop, _: WindowId, _: WindowEvent) {}
}

Dependencies

~0.3–9MB
~79K SLoC