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https://github.com/bevyengine/bevy
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# Objective Continue improving the user experience of our UI Node API in the direction specified by [Bevy's Next Generation Scene / UI System](https://github.com/bevyengine/bevy/discussions/14437) ## Solution As specified in the document above, merge `Style` fields into `Node`, and move "computed Node fields" into `ComputedNode` (I chose this name over something like `ComputedNodeLayout` because it currently contains more than just layout info. If we want to break this up / rename these concepts, lets do that in a separate PR). `Style` has been removed. This accomplishes a number of goals: ## Ergonomics wins Specifying both `Node` and `Style` is now no longer required for non-default styles Before: ```rust commands.spawn(( Node::default(), Style { width: Val::Px(100.), ..default() }, )); ``` After: ```rust commands.spawn(Node { width: Val::Px(100.), ..default() }); ``` ## Conceptual clarity `Style` was never a comprehensive "style sheet". It only defined "core" style properties that all `Nodes` shared. Any "styled property" that couldn't fit that mold had to be in a separate component. A "real" style system would style properties _across_ components (`Node`, `Button`, etc). We have plans to build a true style system (see the doc linked above). By moving the `Style` fields to `Node`, we fully embrace `Node` as the driving concept and remove the "style system" confusion. ## Next Steps * Consider identifying and splitting out "style properties that aren't core to Node". This should not happen for Bevy 0.15. --- ## Migration Guide Move any fields set on `Style` into `Node` and replace all `Style` component usage with `Node`. Before: ```rust commands.spawn(( Node::default(), Style { width: Val::Px(100.), ..default() }, )); ``` After: ```rust commands.spawn(Node { width: Val::Px(100.), ..default() }); ``` For any usage of the "computed node properties" that used to live on `Node`, use `ComputedNode` instead: Before: ```rust fn system(nodes: Query<&Node>) { for node in &nodes { let computed_size = node.size(); } } ``` After: ```rust fn system(computed_nodes: Query<&ComputedNode>) { for computed_node in &computed_nodes { let computed_size = computed_node.size(); } } ```
215 lines
6.7 KiB
Rust
215 lines
6.7 KiB
Rust
//! Demonstrates how to observe life-cycle triggers as well as define custom ones.
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use bevy::{
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prelude::*,
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utils::{HashMap, HashSet},
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};
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use rand::{Rng, SeedableRng};
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use rand_chacha::ChaCha8Rng;
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fn main() {
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App::new()
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.add_plugins(DefaultPlugins)
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.init_resource::<SpatialIndex>()
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.add_systems(Startup, setup)
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.add_systems(Update, (draw_shapes, handle_click))
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// Observers are systems that run when an event is "triggered". This observer runs whenever
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// `ExplodeMines` is triggered.
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.add_observer(
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|trigger: Trigger<ExplodeMines>,
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mines: Query<&Mine>,
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index: Res<SpatialIndex>,
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mut commands: Commands| {
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// You can access the trigger data via the `Observer`
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let event = trigger.event();
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// Access resources
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for e in index.get_nearby(event.pos) {
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// Run queries
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let mine = mines.get(e).unwrap();
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if mine.pos.distance(event.pos) < mine.size + event.radius {
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// And queue commands, including triggering additional events
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// Here we trigger the `Explode` event for entity `e`
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commands.trigger_targets(Explode, e);
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}
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}
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},
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)
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// This observer runs whenever the `Mine` component is added to an entity, and places it in a simple spatial index.
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.add_observer(on_add_mine)
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// This observer runs whenever the `Mine` component is removed from an entity (including despawning it)
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// and removes it from the spatial index.
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.add_observer(on_remove_mine)
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.run();
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}
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#[derive(Component)]
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struct Mine {
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pos: Vec2,
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size: f32,
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}
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impl Mine {
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fn random(rand: &mut ChaCha8Rng) -> Self {
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Mine {
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pos: Vec2::new(
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(rand.gen::<f32>() - 0.5) * 1200.0,
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(rand.gen::<f32>() - 0.5) * 600.0,
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),
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size: 4.0 + rand.gen::<f32>() * 16.0,
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}
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}
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}
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#[derive(Event)]
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struct ExplodeMines {
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pos: Vec2,
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radius: f32,
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}
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#[derive(Event)]
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struct Explode;
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fn setup(mut commands: Commands) {
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commands.spawn(Camera2d);
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commands.spawn((
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Text::new(
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"Click on a \"Mine\" to trigger it.\n\
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When it explodes it will trigger all overlapping mines.",
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),
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Node {
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position_type: PositionType::Absolute,
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top: Val::Px(12.),
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left: Val::Px(12.),
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..default()
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},
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));
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let mut rng = ChaCha8Rng::seed_from_u64(19878367467713);
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commands
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.spawn(Mine::random(&mut rng))
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// Observers can watch for events targeting a specific entity.
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// This will create a new observer that runs whenever the Explode event
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// is triggered for this spawned entity.
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.observe(explode_mine);
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// We want to spawn a bunch of mines. We could just call the code above for each of them.
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// That would create a new observer instance for every Mine entity. Having duplicate observers
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// generally isn't worth worrying about as the overhead is low. But if you want to be maximally efficient,
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// you can reuse observers across entities.
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//
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// First, observers are actually just entities with the Observer component! The `observe()` functions
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// you've seen so far in this example are just shorthand for manually spawning an observer.
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let mut observer = Observer::new(explode_mine);
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// As we spawn entities, we can make this observer watch each of them:
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for _ in 0..1000 {
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let entity = commands.spawn(Mine::random(&mut rng)).id();
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observer.watch_entity(entity);
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}
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// By spawning the Observer component, it becomes active!
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commands.spawn(observer);
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}
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fn on_add_mine(
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trigger: Trigger<OnAdd, Mine>,
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query: Query<&Mine>,
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mut index: ResMut<SpatialIndex>,
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) {
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let mine = query.get(trigger.entity()).unwrap();
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let tile = (
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(mine.pos.x / CELL_SIZE).floor() as i32,
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(mine.pos.y / CELL_SIZE).floor() as i32,
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);
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index.map.entry(tile).or_default().insert(trigger.entity());
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}
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// Remove despawned mines from our index
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fn on_remove_mine(
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trigger: Trigger<OnRemove, Mine>,
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query: Query<&Mine>,
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mut index: ResMut<SpatialIndex>,
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) {
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let mine = query.get(trigger.entity()).unwrap();
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let tile = (
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(mine.pos.x / CELL_SIZE).floor() as i32,
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(mine.pos.y / CELL_SIZE).floor() as i32,
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);
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index.map.entry(tile).and_modify(|set| {
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set.remove(&trigger.entity());
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});
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}
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fn explode_mine(trigger: Trigger<Explode>, query: Query<&Mine>, mut commands: Commands) {
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// If a triggered event is targeting a specific entity you can access it with `.entity()`
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let id = trigger.entity();
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let Some(mut entity) = commands.get_entity(id) else {
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return;
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};
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info!("Boom! {:?} exploded.", id.index());
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entity.despawn();
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let mine = query.get(id).unwrap();
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// Trigger another explosion cascade.
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commands.trigger(ExplodeMines {
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pos: mine.pos,
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radius: mine.size,
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});
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}
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// Draw a circle for each mine using `Gizmos`
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fn draw_shapes(mut gizmos: Gizmos, mines: Query<&Mine>) {
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for mine in &mines {
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gizmos.circle_2d(
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mine.pos,
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mine.size,
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Color::hsl((mine.size - 4.0) / 16.0 * 360.0, 1.0, 0.8),
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);
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}
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}
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// Trigger `ExplodeMines` at the position of a given click
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fn handle_click(
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mouse_button_input: Res<ButtonInput<MouseButton>>,
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camera: Single<(&Camera, &GlobalTransform)>,
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windows: Single<&Window>,
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mut commands: Commands,
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) {
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let (camera, camera_transform) = *camera;
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if let Some(pos) = windows
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.cursor_position()
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.and_then(|cursor| camera.viewport_to_world(camera_transform, cursor).ok())
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.map(|ray| ray.origin.truncate())
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{
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if mouse_button_input.just_pressed(MouseButton::Left) {
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commands.trigger(ExplodeMines { pos, radius: 1.0 });
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}
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}
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}
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#[derive(Resource, Default)]
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struct SpatialIndex {
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map: HashMap<(i32, i32), HashSet<Entity>>,
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}
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/// Cell size has to be bigger than any `TriggerMine::radius`
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const CELL_SIZE: f32 = 64.0;
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impl SpatialIndex {
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// Lookup all entities within adjacent cells of our spatial index
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fn get_nearby(&self, pos: Vec2) -> Vec<Entity> {
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let tile = (
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(pos.x / CELL_SIZE).floor() as i32,
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(pos.y / CELL_SIZE).floor() as i32,
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);
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let mut nearby = Vec::new();
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for x in -1..2 {
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for y in -1..2 {
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if let Some(mines) = self.map.get(&(tile.0 + x, tile.1 + y)) {
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nearby.extend(mines.iter());
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}
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}
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}
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nearby
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}
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}
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