bevy/examples/2d/cpu_draw.rs

//! Example of how to draw to a texture from the CPU.
//!
//! You can set the values of individual pixels to whatever you want.
//! Bevy provides user-friendly APIs that work with [`Color`](bevy::color::Color)
//! values and automatically perform any necessary conversions and encoding
//! into the texture's native pixel format.

use bevy::color::{color_difference::EuclideanDistance, palettes::css};
use bevy::prelude::*;
use bevy::render::{
    render_asset::RenderAssetUsages,
    render_resource::{Extent3d, TextureDimension, TextureFormat},
};
use rand::Rng;

const IMAGE_WIDTH: u32 = 256;
const IMAGE_HEIGHT: u32 = 256;

fn main() {
    App::new()
        .add_plugins(DefaultPlugins)
        // In this example, we will use a fixed timestep to draw a pattern on the screen
        // one pixel at a time, so the pattern will gradually emerge over time, and
        // the speed at which it appears is not tied to the framerate.
        // Let's make the fixed update very fast, so it doesn't take too long. :)
        .insert_resource(Time::<Fixed>::from_hz(1024.0))
        .add_systems(Startup, setup)
        .add_systems(FixedUpdate, draw)
        .run();
}

/// Store the image handle that we will draw to, here.
#[derive(Resource)]
struct MyProcGenImage(Handle<Image>);

fn setup(mut commands: Commands, mut images: ResMut<Assets<Image>>) {
    // spawn a camera
    commands.spawn(Camera2d);

    // create an image that we are going to draw into
    let mut image = Image::new_fill(
        // 2D image of size 256x256
        Extent3d {
            width: IMAGE_WIDTH,
            height: IMAGE_HEIGHT,
            depth_or_array_layers: 1,
        },
        TextureDimension::D2,
        // Initialize it with a beige color
        &(css::BEIGE.to_u8_array()),
        // Use the same encoding as the color we set
        TextureFormat::Rgba8UnormSrgb,
        RenderAssetUsages::MAIN_WORLD | RenderAssetUsages::RENDER_WORLD,
    );

    // to make it extra fancy, we can set the Alpha of each pixel
    // so that it fades out in a circular fashion
    for y in 0..IMAGE_HEIGHT {
        for x in 0..IMAGE_WIDTH {
            let center = Vec2::new(IMAGE_WIDTH as f32 / 2.0, IMAGE_HEIGHT as f32 / 2.0);
            let max_radius = IMAGE_HEIGHT.min(IMAGE_WIDTH) as f32 / 2.0;
            let r = Vec2::new(x as f32, y as f32).distance(center);
            let a = 1.0 - (r / max_radius).clamp(0.0, 1.0);

            // here we will set the A value by accessing the raw data bytes
            // (it is the 4th byte of each pixel, as per our `TextureFormat`)

            // find our pixel by its coordinates
            let pixel_bytes = image.pixel_bytes_mut(UVec3::new(x, y, 0)).unwrap();
            // convert our f32 to u8
            pixel_bytes[3] = (a * u8::MAX as f32) as u8;
        }
    }

    // add it to Bevy's assets, so it can be used for rendering
    // this will give us a handle we can use
    // (to display it in a sprite, or as part of UI, etc.)
    let handle = images.add(image);

    // create a sprite entity using our image
    commands.spawn(SpriteBundle {
        texture: handle.clone(),
        ..Default::default()
    });

    commands.insert_resource(MyProcGenImage(handle));
}

/// Every fixed update tick, draw one more pixel to make a spiral pattern
fn draw(
    my_handle: Res<MyProcGenImage>,
    mut images: ResMut<Assets<Image>>,
    // used to keep track of where we are
    mut i: Local<u32>,
    mut draw_color: Local<Color>,
) {
    let mut rng = rand::thread_rng();

    if *i == 0 {
        // Generate a random color on first run.
        *draw_color = Color::linear_rgb(rng.gen(), rng.gen(), rng.gen());
    }

    // Get the image from Bevy's asset storage.
    let image = images.get_mut(&my_handle.0).expect("Image not found");

    // Compute the position of the pixel to draw.

    let center = Vec2::new(IMAGE_WIDTH as f32 / 2.0, IMAGE_HEIGHT as f32 / 2.0);
    let max_radius = IMAGE_HEIGHT.min(IMAGE_WIDTH) as f32 / 2.0;
    let rot_speed = 0.0123;
    let period = 0.12345;

    let r = ops::sin(*i as f32 * period) * max_radius;
    let xy = Vec2::from_angle(*i as f32 * rot_speed) * r + center;
    let (x, y) = (xy.x as u32, xy.y as u32);

    // Get the old color of that pixel.
    let old_color = image.get_color_at(x, y).unwrap();

    // If the old color is our current color, change our drawing color.
    let tolerance = 1.0 / 255.0;
    if old_color.distance(&draw_color) <= tolerance {
        *draw_color = Color::linear_rgb(rng.gen(), rng.gen(), rng.gen());
    }

    // Set the new color, but keep old alpha value from image.
    image
        .set_color_at(x, y, draw_color.with_alpha(old_color.alpha()))
        .unwrap();

    *i += 1;
}
Add `Image` methods for easy access to a pixel's color (#10392) # Objective If you want to draw / generate images from the CPU, such as: - to create procedurally-generated assets - for games whose artstyle is best implemented by poking pixels directly from the CPU, instead of using shaders It is currently very unergonomic to do in Bevy, because you have to deal with the raw bytes inside `image.data`, take care of the pixel format, etc. ## Solution This PR adds some helper methods to `Image` for pixel manipulation. These methods allow you to use Bevy's user-friendly `Color` struct to read and write the colors of pixels, at arbitrary coordinates (specified as `UVec3` to support any texture dimension). They handle encoding/decoding to the `Image`s `TextureFormat`, incl. any sRGB conversion. While we are at it, also add methods to help with direct access to the raw bytes. It is now easy to compute the offset where the bytes of a specific pixel coordinate are found, or to just get a Rust slice to access them. Caveat: `Color` roundtrips are obviously going to be lossy for non-float `TextureFormat`s. Using `set_color_at` followed by `get_color_at` will return a different value, due to the data conversions involved (such as `f32` -> `u8` -> `f32` for the common `Rgba8UnormSrgb` texture format). Be careful when comparing colors (such as checking for a color you wrote before)! Also adding a new example: `cpu_draw` (under `2d`), to showcase these new APIs. --- ## Changelog ### Added - `Image` APIs for easy access to the colors of specific pixels. --------- Co-authored-by: Pascal Hertleif <killercup@gmail.com> Co-authored-by: François <mockersf@gmail.com> Co-authored-by: ltdk <usr@ltdk.xyz> 2024-10-07 14:38:41 +00:00			`//! Example of how to draw to a texture from the CPU.`
			`//!`
			`//! You can set the values of individual pixels to whatever you want.`
			//! Bevy provides user-friendly APIs that work with [`Color`](bevy::color::Color)
			`//! values and automatically perform any necessary conversions and encoding`
			`//! into the texture's native pixel format.`

			`use bevy::color::{color_difference::EuclideanDistance, palettes::css};`
			`use bevy::prelude::*;`
			`use bevy::render::{`
			`render_asset::RenderAssetUsages,`
			`render_resource::{Extent3d, TextureDimension, TextureFormat},`
			`};`
			`use rand::Rng;`

			`const IMAGE_WIDTH: u32 = 256;`
			`const IMAGE_HEIGHT: u32 = 256;`

			`fn main() {`
			`App::new()`
			`.add_plugins(DefaultPlugins)`
			`// In this example, we will use a fixed timestep to draw a pattern on the screen`
			`// one pixel at a time, so the pattern will gradually emerge over time, and`
			`// the speed at which it appears is not tied to the framerate.`
			`// Let's make the fixed update very fast, so it doesn't take too long. :)`
			`.insert_resource(Time::<Fixed>::from_hz(1024.0))`
			`.add_systems(Startup, setup)`
			`.add_systems(FixedUpdate, draw)`
			`.run();`
			`}`

			`/// Store the image handle that we will draw to, here.`
			`#[derive(Resource)]`
			`struct MyProcGenImage(Handle<Image>);`

			`fn setup(mut commands: Commands, mut images: ResMut<Assets<Image>>) {`
			`// spawn a camera`
			`commands.spawn(Camera2d);`

			`// create an image that we are going to draw into`
			`let mut image = Image::new_fill(`
			`// 2D image of size 256x256`
			`Extent3d {`
			`width: IMAGE_WIDTH,`
			`height: IMAGE_HEIGHT,`
			`depth_or_array_layers: 1,`
			`},`
			`TextureDimension::D2,`
			`// Initialize it with a beige color`
			`&(css::BEIGE.to_u8_array()),`
			`// Use the same encoding as the color we set`
			`TextureFormat::Rgba8UnormSrgb,`
			`RenderAssetUsages::MAIN_WORLD \| RenderAssetUsages::RENDER_WORLD,`
			`);`

			`// to make it extra fancy, we can set the Alpha of each pixel`
			`// so that it fades out in a circular fashion`
			`for y in 0..IMAGE_HEIGHT {`
			`for x in 0..IMAGE_WIDTH {`
			`let center = Vec2::new(IMAGE_WIDTH as f32 / 2.0, IMAGE_HEIGHT as f32 / 2.0);`
			`let max_radius = IMAGE_HEIGHT.min(IMAGE_WIDTH) as f32 / 2.0;`
			`let r = Vec2::new(x as f32, y as f32).distance(center);`
			`let a = 1.0 - (r / max_radius).clamp(0.0, 1.0);`

			`// here we will set the A value by accessing the raw data bytes`
			// (it is the 4th byte of each pixel, as per our `TextureFormat`)

			`// find our pixel by its coordinates`
			`let pixel_bytes = image.pixel_bytes_mut(UVec3::new(x, y, 0)).unwrap();`
			`// convert our f32 to u8`
			`pixel_bytes[3] = (a * u8::MAX as f32) as u8;`
			`}`
			`}`

			`// add it to Bevy's assets, so it can be used for rendering`
			`// this will give us a handle we can use`
			`// (to display it in a sprite, or as part of UI, etc.)`
			`let handle = images.add(image);`

			`// create a sprite entity using our image`
			`commands.spawn(SpriteBundle {`
			`texture: handle.clone(),`
			`..Default::default()`
			`});`

			`commands.insert_resource(MyProcGenImage(handle));`
			`}`

			`/// Every fixed update tick, draw one more pixel to make a spiral pattern`
			`fn draw(`
			`my_handle: Res<MyProcGenImage>,`
			`mut images: ResMut<Assets<Image>>,`
			`// used to keep track of where we are`
			`mut i: Local<u32>,`
			`mut draw_color: Local<Color>,`
			`) {`
			`let mut rng = rand::thread_rng();`

			`if *i == 0 {`
			`// Generate a random color on first run.`
			`*draw_color = Color::linear_rgb(rng.gen(), rng.gen(), rng.gen());`
			`}`

			`// Get the image from Bevy's asset storage.`
			`let image = images.get_mut(&my_handle.0).expect("Image not found");`

			`// Compute the position of the pixel to draw.`

			`let center = Vec2::new(IMAGE_WIDTH as f32 / 2.0, IMAGE_HEIGHT as f32 / 2.0);`
			`let max_radius = IMAGE_HEIGHT.min(IMAGE_WIDTH) as f32 / 2.0;`
			`let rot_speed = 0.0123;`
			`let period = 0.12345;`

			`let r = ops::sin(i as f32 period) * max_radius;`
			`let xy = Vec2::from_angle(i as f32 rot_speed) * r + center;`
			`let (x, y) = (xy.x as u32, xy.y as u32);`

			`// Get the old color of that pixel.`
			`let old_color = image.get_color_at(x, y).unwrap();`

			`// If the old color is our current color, change our drawing color.`
			`let tolerance = 1.0 / 255.0;`
			`if old_color.distance(&draw_color) <= tolerance {`
			`*draw_color = Color::linear_rgb(rng.gen(), rng.gen(), rng.gen());`
			`}`

			`// Set the new color, but keep old alpha value from image.`
			`image`
			`.set_color_at(x, y, draw_color.with_alpha(old_color.alpha()))`
			`.unwrap();`

			`*i += 1;`
			`}`