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async_compute.rs
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async_compute.rs
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//! This example shows how to use the ECS and the [`AsyncComputeTaskPool`]
//! to spawn, poll, and complete tasks across systems and system ticks.
use bevy::{
prelude::*,
tasks::{AsyncComputeTaskPool, Task},
};
use futures_lite::future;
use rand::Rng;
use std::time::{Duration, Instant};
fn main() {
App::new()
.add_plugins(DefaultPlugins)
.add_startup_system(setup_env)
.add_startup_system(add_assets)
.add_startup_system(spawn_tasks)
.add_system(handle_tasks)
.run();
}
// Number of cubes to spawn across the x, y, and z axis
const NUM_CUBES: u32 = 6;
#[derive(Resource, Deref)]
struct BoxMeshHandle(Handle<Mesh>);
#[derive(Resource, Deref)]
struct BoxMaterialHandle(Handle<StandardMaterial>);
/// Startup system which runs only once and generates our Box Mesh
/// and Box Material assets, adds them to their respective Asset
/// Resources, and stores their handles as resources so we can access
/// them later when we're ready to render our Boxes
fn add_assets(
mut commands: Commands,
mut meshes: ResMut<Assets<Mesh>>,
mut materials: ResMut<Assets<StandardMaterial>>,
) {
let box_mesh_handle = meshes.add(Mesh::from(shape::Cube { size: 0.25 }));
commands.insert_resource(BoxMeshHandle(box_mesh_handle));
let box_material_handle = materials.add(Color::rgb(1.0, 0.2, 0.3).into());
commands.insert_resource(BoxMaterialHandle(box_material_handle));
}
#[derive(Component)]
struct ComputeTransform(Task<Transform>);
/// This system generates tasks simulating computationally intensive
/// work that potentially spans multiple frames/ticks. A separate
/// system, `handle_tasks`, will poll the spawned tasks on subsequent
/// frames/ticks, and use the results to spawn cubes
fn spawn_tasks(mut commands: Commands) {
let thread_pool = AsyncComputeTaskPool::get();
for x in 0..NUM_CUBES {
for y in 0..NUM_CUBES {
for z in 0..NUM_CUBES {
// Spawn new task on the AsyncComputeTaskPool
let task = thread_pool.spawn(async move {
let mut rng = rand::thread_rng();
let start_time = Instant::now();
let duration = Duration::from_secs_f32(rng.gen_range(0.05..0.2));
while start_time.elapsed() < duration {
// Spinning for 'duration', simulating doing hard
// compute work generating translation coords!
}
// Such hard work, all done!
Transform::from_xyz(x as f32, y as f32, z as f32)
});
// Spawn new entity and add our new task as a component
commands.spawn(ComputeTransform(task));
}
}
}
}
/// This system queries for entities that have our Task<Transform> component. It polls the
/// tasks to see if they're complete. If the task is complete it takes the result, adds a
/// new [`PbrBundle`] of components to the entity using the result from the task's work, and
/// removes the task component from the entity.
fn handle_tasks(
mut commands: Commands,
mut transform_tasks: Query<(Entity, &mut ComputeTransform)>,
box_mesh_handle: Res<BoxMeshHandle>,
box_material_handle: Res<BoxMaterialHandle>,
) {
for (entity, mut task) in &mut transform_tasks {
if let Some(transform) = future::block_on(future::poll_once(&mut task.0)) {
// Add our new PbrBundle of components to our tagged entity
commands.entity(entity).insert(PbrBundle {
mesh: box_mesh_handle.clone(),
material: box_material_handle.clone(),
transform,
..default()
});
// Task is complete, so remove task component from entity
commands.entity(entity).remove::<ComputeTransform>();
}
}
}
/// This system is only used to setup light and camera for the environment
fn setup_env(mut commands: Commands) {
// Used to center camera on spawned cubes
let offset = if NUM_CUBES % 2 == 0 {
(NUM_CUBES / 2) as f32 - 0.5
} else {
(NUM_CUBES / 2) as f32
};
// lights
commands.spawn(PointLightBundle {
transform: Transform::from_xyz(4.0, 12.0, 15.0),
..default()
});
// camera
commands.spawn(Camera3dBundle {
transform: Transform::from_xyz(offset, offset, 15.0)
.looking_at(Vec3::new(offset, offset, 0.0), Vec3::Y),
..default()
});
}