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bevy/crates/bevy_ecs/examples/change_detection.rs
Paweł Grabarz 07ed1d053e Implement and require #[derive(Component)] on all component structs (#2254) 
This implements the most minimal variant of #1843 - a derive for marker trait. This is a prerequisite to more complicated features like statically defined storage type or opt-out component reflection.

In order to make component struct's purpose explicit and avoid misuse, it must be annotated with `#[derive(Component)]` (manual impl is discouraged for compatibility). Right now this is just a marker trait, but in the future it might be expanded. Making this change early allows us to make further changes later without breaking backward compatibility for derive macro users.

This already prevents a lot of issues, like using bundles in `insert` calls. Primitive types are no longer valid components as well. This can be easily worked around by adding newtype wrappers and deriving `Component` for them.

One funny example of prevented bad code (from our own tests) is when an newtype struct or enum variant is used. Previously, it was possible to write `insert(Newtype)` instead of `insert(Newtype(value))`. That code compiled, because function pointers (in this case newtype struct constructor) implement `Send + Sync + 'static`, so we allowed them to be used as components. This is no longer the case and such invalid code will trigger a compile error.


Co-authored-by: = <=>
Co-authored-by: TheRawMeatball <therawmeatball@gmail.com>
Co-authored-by: Carter Anderson <mcanders1@gmail.com>
2021-10-03 19:23:44 +00:00

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use bevy_ecs::prelude::*;
use rand::Rng;
use std::ops::Deref;
// In this example we will simulate a population of entities. In every tick we will:
// 1. spawn a new entity with a certain possibility
// 2. age all entities
// 3. despawn entities with age > 2
//
// To demonstrate change detection, there are some console outputs based on changes in
// the EntityCounter resource and updated Age components
fn main() {
// Create a new empty World to hold our Entities, Components and Resources
let mut world = World::new();
// Add the counter resource to remember how many entities where spawned
world.insert_resource(EntityCounter { value: 0 });
// Create a new Schedule, which defines an execution strategy for Systems
let mut schedule = Schedule::default();
// Create a Stage to add to our Schedule. Each Stage in a schedule runs all of its systems
// before moving on to the next Stage
let mut update = SystemStage::parallel();
// Add systems to the Stage to execute our app logic
// We can label our systems to force a specific run-order between some of them
update.add_system(spawn_entities.label(SimulationSystem::Spawn));
update.add_system(print_counter_when_changed.after(SimulationSystem::Spawn));
update.add_system(age_all_entities.label(SimulationSystem::Age));
update.add_system(remove_old_entities.after(SimulationSystem::Age));
update.add_system(print_changed_entities.after(SimulationSystem::Age));
// Add the Stage with our systems to the Schedule
schedule.add_stage("update", update);
// Simulate 10 frames in our world
for iteration in 1..=10 {
println!("Simulating frame {}/10", iteration);
schedule.run(&mut world);
}
}
// This struct will be used as a Resource keeping track of the total amount of spawned entities
#[derive(Debug)]
struct EntityCounter {
pub value: i32,
}
// This struct represents a Component and holds the age in frames of the entity it gets assigned to
#[derive(Component, Default, Debug)]
struct Age {
frames: i32,
}
// System labels to enforce a run order of our systems
#[derive(SystemLabel, Debug, Clone, PartialEq, Eq, Hash)]
enum SimulationSystem {
Spawn,
Age,
}
// This system randomly spawns a new entity in 60% of all frames
// The entity will start with an age of 0 frames
// If an entity gets spawned, we increase the counter in the EntityCounter resource
fn spawn_entities(mut commands: Commands, mut entity_counter: ResMut<EntityCounter>) {
if rand::thread_rng().gen_bool(0.6) {
let entity_id = commands.spawn().insert(Age::default()).id();
println!(" spawning {:?}", entity_id);
entity_counter.value += 1;
}
}
// This system prints out changes in our entity collection
// For every entity that just got the Age component added we will print that it's the
// entities first birthday. These entities where spawned in the previous frame.
// For every entity with a changed Age component we will print the new value.
// In this example the Age component is changed in every frame, so we don't actually
// need the `Changed` here, but it is still used for the purpose of demonstration.
fn print_changed_entities(
entity_with_added_component: Query<Entity, Added<Age>>,
entity_with_mutated_component: Query<(Entity, &Age), Changed<Age>>,
) {
for entity in entity_with_added_component.iter() {
println!(" {:?} has it's first birthday!", entity);
}
for (entity, value) in entity_with_mutated_component.iter() {
println!(" {:?} is now {:?} frames old", entity, value);
}
}
// This system iterates over all entities and increases their age in every frame
fn age_all_entities(mut entities: Query<&mut Age>) {
for mut age in entities.iter_mut() {
age.frames += 1;
}
}
// This system iterates over all entities in every frame and despawns entities older than 2 frames
fn remove_old_entities(mut commands: Commands, entities: Query<(Entity, &Age)>) {
for (entity, age) in entities.iter() {
if age.frames > 2 {
println!(" despawning {:?} due to age > 2", entity);
commands.entity(entity).despawn();
}
}
}
// This system will print the new counter value everytime it was changed since
// the last execution of the system.
fn print_counter_when_changed(entity_counter: Res<EntityCounter>) {
if entity_counter.is_changed() {
println!(
" total number of entities spawned: {}",
entity_counter.deref().value
);
}
}
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