mirror of
https://github.com/bevyengine/bevy
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48fb4aa6d5
# Objective This PR update breakout to use the new 0.15 Required Component feature instead of the Bundle. Add more information in the comment about where to find more info about Required Components. ## Solution Replace `#[derive(Bundle)]` with a new Wall component and `#[require()]` Macro to include the other components. ## Testing Tested with `cargo test` as well tested the game manually with `cargo run --example breakout` It looks to me that it works like it used to before the changes. Tested on Arch Linux, Wayland --------- Co-authored-by: Arnav Mummineni <45217840+RCoder01@users.noreply.github.com> Co-authored-by: Joona Aalto <jondolf.dev@gmail.com>
438 lines
14 KiB
Rust
438 lines
14 KiB
Rust
//! A simplified implementation of the classic game "Breakout".
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//!
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//! Demonstrates Bevy's stepping capabilities if compiled with the `bevy_debug_stepping` feature.
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use bevy::{
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math::bounding::{Aabb2d, BoundingCircle, BoundingVolume, IntersectsVolume},
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prelude::*,
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};
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mod stepping;
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// These constants are defined in `Transform` units.
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// Using the default 2D camera they correspond 1:1 with screen pixels.
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const PADDLE_SIZE: Vec2 = Vec2::new(120.0, 20.0);
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const GAP_BETWEEN_PADDLE_AND_FLOOR: f32 = 60.0;
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const PADDLE_SPEED: f32 = 500.0;
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// How close can the paddle get to the wall
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const PADDLE_PADDING: f32 = 10.0;
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// We set the z-value of the ball to 1 so it renders on top in the case of overlapping sprites.
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const BALL_STARTING_POSITION: Vec3 = Vec3::new(0.0, -50.0, 1.0);
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const BALL_DIAMETER: f32 = 30.;
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const BALL_SPEED: f32 = 400.0;
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const INITIAL_BALL_DIRECTION: Vec2 = Vec2::new(0.5, -0.5);
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const WALL_THICKNESS: f32 = 10.0;
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// x coordinates
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const LEFT_WALL: f32 = -450.;
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const RIGHT_WALL: f32 = 450.;
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// y coordinates
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const BOTTOM_WALL: f32 = -300.;
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const TOP_WALL: f32 = 300.;
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const BRICK_SIZE: Vec2 = Vec2::new(100., 30.);
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// These values are exact
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const GAP_BETWEEN_PADDLE_AND_BRICKS: f32 = 270.0;
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const GAP_BETWEEN_BRICKS: f32 = 5.0;
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// These values are lower bounds, as the number of bricks is computed
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const GAP_BETWEEN_BRICKS_AND_CEILING: f32 = 20.0;
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const GAP_BETWEEN_BRICKS_AND_SIDES: f32 = 20.0;
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const SCOREBOARD_FONT_SIZE: f32 = 33.0;
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const SCOREBOARD_TEXT_PADDING: Val = Val::Px(5.0);
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const BACKGROUND_COLOR: Color = Color::srgb(0.9, 0.9, 0.9);
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const PADDLE_COLOR: Color = Color::srgb(0.3, 0.3, 0.7);
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const BALL_COLOR: Color = Color::srgb(1.0, 0.5, 0.5);
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const BRICK_COLOR: Color = Color::srgb(0.5, 0.5, 1.0);
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const WALL_COLOR: Color = Color::srgb(0.8, 0.8, 0.8);
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const TEXT_COLOR: Color = Color::srgb(0.5, 0.5, 1.0);
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const SCORE_COLOR: Color = Color::srgb(1.0, 0.5, 0.5);
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fn main() {
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App::new()
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.add_plugins(DefaultPlugins)
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.add_plugins(
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stepping::SteppingPlugin::default()
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.add_schedule(Update)
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.add_schedule(FixedUpdate)
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.at(Val::Percent(35.0), Val::Percent(50.0)),
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)
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.insert_resource(Score(0))
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.insert_resource(ClearColor(BACKGROUND_COLOR))
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.add_event::<CollisionEvent>()
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.add_systems(Startup, setup)
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// Add our gameplay simulation systems to the fixed timestep schedule
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// which runs at 64 Hz by default
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.add_systems(
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FixedUpdate,
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(
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apply_velocity,
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move_paddle,
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check_for_collisions,
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play_collision_sound,
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)
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// `chain`ing systems together runs them in order
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.chain(),
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)
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.add_systems(Update, update_scoreboard)
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.run();
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}
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#[derive(Component)]
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struct Paddle;
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#[derive(Component)]
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struct Ball;
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#[derive(Component, Deref, DerefMut)]
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struct Velocity(Vec2);
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#[derive(Event, Default)]
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struct CollisionEvent;
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#[derive(Component)]
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struct Brick;
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#[derive(Resource, Deref)]
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struct CollisionSound(Handle<AudioSource>);
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// Default must be implemented to define this as a required component for the Wall component below
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#[derive(Component, Default)]
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struct Collider;
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// This is a collection of the components that define a "Wall" in our game
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#[derive(Component)]
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#[require(Sprite, Transform, Collider)]
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struct Wall;
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/// Which side of the arena is this wall located on?
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enum WallLocation {
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Left,
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Right,
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Bottom,
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Top,
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}
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impl WallLocation {
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/// Location of the *center* of the wall, used in `transform.translation()`
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fn position(&self) -> Vec2 {
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match self {
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WallLocation::Left => Vec2::new(LEFT_WALL, 0.),
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WallLocation::Right => Vec2::new(RIGHT_WALL, 0.),
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WallLocation::Bottom => Vec2::new(0., BOTTOM_WALL),
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WallLocation::Top => Vec2::new(0., TOP_WALL),
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}
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}
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/// (x, y) dimensions of the wall, used in `transform.scale()`
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fn size(&self) -> Vec2 {
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let arena_height = TOP_WALL - BOTTOM_WALL;
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let arena_width = RIGHT_WALL - LEFT_WALL;
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// Make sure we haven't messed up our constants
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assert!(arena_height > 0.0);
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assert!(arena_width > 0.0);
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match self {
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WallLocation::Left | WallLocation::Right => {
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Vec2::new(WALL_THICKNESS, arena_height + WALL_THICKNESS)
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}
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WallLocation::Bottom | WallLocation::Top => {
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Vec2::new(arena_width + WALL_THICKNESS, WALL_THICKNESS)
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}
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}
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}
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}
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impl Wall {
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// This "builder method" allows us to reuse logic across our wall entities,
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// making our code easier to read and less prone to bugs when we change the logic
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// Notice the use of Sprite and Transform alongside Wall, overwriting the default values defined for the required components
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fn new(location: WallLocation) -> (Wall, Sprite, Transform) {
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(
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Wall,
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Sprite::from_color(WALL_COLOR, Vec2::ONE),
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Transform {
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// We need to convert our Vec2 into a Vec3, by giving it a z-coordinate
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// This is used to determine the order of our sprites
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translation: location.position().extend(0.0),
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// The z-scale of 2D objects must always be 1.0,
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// or their ordering will be affected in surprising ways.
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// See https://github.com/bevyengine/bevy/issues/4149
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scale: location.size().extend(1.0),
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..default()
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},
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)
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}
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}
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// This resource tracks the game's score
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#[derive(Resource, Deref, DerefMut)]
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struct Score(usize);
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#[derive(Component)]
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struct ScoreboardUi;
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// Add the game's entities to our world
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fn setup(
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mut commands: Commands,
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mut meshes: ResMut<Assets<Mesh>>,
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mut materials: ResMut<Assets<ColorMaterial>>,
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asset_server: Res<AssetServer>,
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) {
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// Camera
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commands.spawn(Camera2d);
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// Sound
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let ball_collision_sound = asset_server.load("sounds/breakout_collision.ogg");
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commands.insert_resource(CollisionSound(ball_collision_sound));
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// Paddle
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let paddle_y = BOTTOM_WALL + GAP_BETWEEN_PADDLE_AND_FLOOR;
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commands.spawn((
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Sprite::from_color(PADDLE_COLOR, Vec2::ONE),
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Transform {
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translation: Vec3::new(0.0, paddle_y, 0.0),
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scale: PADDLE_SIZE.extend(1.0),
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..default()
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},
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Paddle,
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Collider,
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));
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// Ball
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commands.spawn((
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Mesh2d(meshes.add(Circle::default())),
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MeshMaterial2d(materials.add(BALL_COLOR)),
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Transform::from_translation(BALL_STARTING_POSITION)
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.with_scale(Vec2::splat(BALL_DIAMETER).extend(1.)),
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Ball,
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Velocity(INITIAL_BALL_DIRECTION.normalize() * BALL_SPEED),
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));
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// Scoreboard
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commands
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.spawn((
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Text::new("Score: "),
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TextFont {
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font_size: SCOREBOARD_FONT_SIZE,
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..default()
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},
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TextColor(TEXT_COLOR),
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ScoreboardUi,
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Node {
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position_type: PositionType::Absolute,
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top: SCOREBOARD_TEXT_PADDING,
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left: SCOREBOARD_TEXT_PADDING,
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..default()
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},
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))
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.with_child((
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TextSpan::default(),
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TextFont {
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font_size: SCOREBOARD_FONT_SIZE,
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..default()
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},
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TextColor(SCORE_COLOR),
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));
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// Walls
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commands.spawn(Wall::new(WallLocation::Left));
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commands.spawn(Wall::new(WallLocation::Right));
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commands.spawn(Wall::new(WallLocation::Bottom));
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commands.spawn(Wall::new(WallLocation::Top));
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// Bricks
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let total_width_of_bricks = (RIGHT_WALL - LEFT_WALL) - 2. * GAP_BETWEEN_BRICKS_AND_SIDES;
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let bottom_edge_of_bricks = paddle_y + GAP_BETWEEN_PADDLE_AND_BRICKS;
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let total_height_of_bricks = TOP_WALL - bottom_edge_of_bricks - GAP_BETWEEN_BRICKS_AND_CEILING;
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assert!(total_width_of_bricks > 0.0);
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assert!(total_height_of_bricks > 0.0);
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// Given the space available, compute how many rows and columns of bricks we can fit
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let n_columns = (total_width_of_bricks / (BRICK_SIZE.x + GAP_BETWEEN_BRICKS)).floor() as usize;
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let n_rows = (total_height_of_bricks / (BRICK_SIZE.y + GAP_BETWEEN_BRICKS)).floor() as usize;
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let n_vertical_gaps = n_columns - 1;
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// Because we need to round the number of columns,
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// the space on the top and sides of the bricks only captures a lower bound, not an exact value
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let center_of_bricks = (LEFT_WALL + RIGHT_WALL) / 2.0;
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let left_edge_of_bricks = center_of_bricks
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// Space taken up by the bricks
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- (n_columns as f32 / 2.0 * BRICK_SIZE.x)
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// Space taken up by the gaps
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- n_vertical_gaps as f32 / 2.0 * GAP_BETWEEN_BRICKS;
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// In Bevy, the `translation` of an entity describes the center point,
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// not its bottom-left corner
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let offset_x = left_edge_of_bricks + BRICK_SIZE.x / 2.;
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let offset_y = bottom_edge_of_bricks + BRICK_SIZE.y / 2.;
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for row in 0..n_rows {
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for column in 0..n_columns {
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let brick_position = Vec2::new(
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offset_x + column as f32 * (BRICK_SIZE.x + GAP_BETWEEN_BRICKS),
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offset_y + row as f32 * (BRICK_SIZE.y + GAP_BETWEEN_BRICKS),
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);
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// brick
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commands.spawn((
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Sprite {
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color: BRICK_COLOR,
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..default()
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},
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Transform {
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translation: brick_position.extend(0.0),
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scale: Vec3::new(BRICK_SIZE.x, BRICK_SIZE.y, 1.0),
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..default()
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},
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Brick,
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Collider,
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));
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}
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}
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}
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fn move_paddle(
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keyboard_input: Res<ButtonInput<KeyCode>>,
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mut paddle_transform: Single<&mut Transform, With<Paddle>>,
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time: Res<Time>,
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) {
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let mut direction = 0.0;
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if keyboard_input.pressed(KeyCode::ArrowLeft) {
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direction -= 1.0;
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}
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if keyboard_input.pressed(KeyCode::ArrowRight) {
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direction += 1.0;
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}
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// Calculate the new horizontal paddle position based on player input
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let new_paddle_position =
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paddle_transform.translation.x + direction * PADDLE_SPEED * time.delta_secs();
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// Update the paddle position,
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// making sure it doesn't cause the paddle to leave the arena
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let left_bound = LEFT_WALL + WALL_THICKNESS / 2.0 + PADDLE_SIZE.x / 2.0 + PADDLE_PADDING;
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let right_bound = RIGHT_WALL - WALL_THICKNESS / 2.0 - PADDLE_SIZE.x / 2.0 - PADDLE_PADDING;
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paddle_transform.translation.x = new_paddle_position.clamp(left_bound, right_bound);
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}
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fn apply_velocity(mut query: Query<(&mut Transform, &Velocity)>, time: Res<Time>) {
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for (mut transform, velocity) in &mut query {
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transform.translation.x += velocity.x * time.delta_secs();
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transform.translation.y += velocity.y * time.delta_secs();
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}
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}
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fn update_scoreboard(
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score: Res<Score>,
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score_root: Single<Entity, (With<ScoreboardUi>, With<Text>)>,
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mut writer: TextUiWriter,
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) {
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*writer.text(*score_root, 1) = score.to_string();
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}
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fn check_for_collisions(
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mut commands: Commands,
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mut score: ResMut<Score>,
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ball_query: Single<(&mut Velocity, &Transform), With<Ball>>,
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collider_query: Query<(Entity, &Transform, Option<&Brick>), With<Collider>>,
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mut collision_events: EventWriter<CollisionEvent>,
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) {
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let (mut ball_velocity, ball_transform) = ball_query.into_inner();
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for (collider_entity, collider_transform, maybe_brick) in &collider_query {
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let collision = ball_collision(
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BoundingCircle::new(ball_transform.translation.truncate(), BALL_DIAMETER / 2.),
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Aabb2d::new(
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collider_transform.translation.truncate(),
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collider_transform.scale.truncate() / 2.,
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),
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);
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if let Some(collision) = collision {
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// Sends a collision event so that other systems can react to the collision
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collision_events.send_default();
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// Bricks should be despawned and increment the scoreboard on collision
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if maybe_brick.is_some() {
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commands.entity(collider_entity).despawn();
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**score += 1;
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}
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// Reflect the ball's velocity when it collides
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let mut reflect_x = false;
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let mut reflect_y = false;
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// Reflect only if the velocity is in the opposite direction of the collision
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// This prevents the ball from getting stuck inside the bar
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match collision {
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Collision::Left => reflect_x = ball_velocity.x > 0.0,
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Collision::Right => reflect_x = ball_velocity.x < 0.0,
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Collision::Top => reflect_y = ball_velocity.y < 0.0,
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Collision::Bottom => reflect_y = ball_velocity.y > 0.0,
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}
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// Reflect velocity on the x-axis if we hit something on the x-axis
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if reflect_x {
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ball_velocity.x = -ball_velocity.x;
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}
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// Reflect velocity on the y-axis if we hit something on the y-axis
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if reflect_y {
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ball_velocity.y = -ball_velocity.y;
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}
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}
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}
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}
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fn play_collision_sound(
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mut commands: Commands,
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mut collision_events: EventReader<CollisionEvent>,
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sound: Res<CollisionSound>,
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) {
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// Play a sound once per frame if a collision occurred.
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if !collision_events.is_empty() {
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// This prevents events staying active on the next frame.
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collision_events.clear();
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commands.spawn((AudioPlayer(sound.clone()), PlaybackSettings::DESPAWN));
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}
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}
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#[derive(Debug, PartialEq, Eq, Copy, Clone)]
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enum Collision {
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Left,
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Right,
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Top,
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Bottom,
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}
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// Returns `Some` if `ball` collides with `bounding_box`.
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// The returned `Collision` is the side of `bounding_box` that `ball` hit.
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fn ball_collision(ball: BoundingCircle, bounding_box: Aabb2d) -> Option<Collision> {
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if !ball.intersects(&bounding_box) {
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return None;
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}
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let closest = bounding_box.closest_point(ball.center());
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let offset = ball.center() - closest;
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let side = if offset.x.abs() > offset.y.abs() {
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if offset.x < 0. {
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Collision::Left
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} else {
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Collision::Right
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}
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} else if offset.y > 0. {
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Collision::Top
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} else {
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Collision::Bottom
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};
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Some(side)
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}
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