bevy/examples/animation/eased_motion.rs

//! Demonstrates the application of easing curves to animate a transition.

use std::f32::consts::FRAC_PI_2;

use bevy::{
    animation::{AnimationTarget, AnimationTargetId},
    color::palettes::css::{ORANGE, SILVER},
    math::vec3,
    prelude::*,
};

fn main() {
    App::new()
        .add_plugins(DefaultPlugins)
        .add_systems(Startup, setup)
        .run();
}

fn setup(
    mut commands: Commands,
    mut meshes: ResMut<Assets<Mesh>>,
    mut materials: ResMut<Assets<StandardMaterial>>,
    mut animation_graphs: ResMut<Assets<AnimationGraph>>,
    mut animation_clips: ResMut<Assets<AnimationClip>>,
) {
    // Create the animation:
    let AnimationInfo {
        target_name: animation_target_name,
        target_id: animation_target_id,
        graph: animation_graph,
        node_index: animation_node_index,
    } = AnimationInfo::create(&mut animation_graphs, &mut animation_clips);

    // Build an animation player that automatically plays the animation.
    let mut animation_player = AnimationPlayer::default();
    animation_player.play(animation_node_index).repeat();

    // A cube together with the components needed to animate it
    let cube_entity = commands
        .spawn((
            Mesh3d(meshes.add(Cuboid::from_length(2.0))),
            MeshMaterial3d(materials.add(Color::from(ORANGE))),
            Transform::from_translation(vec3(-6., 2., 0.)),
            animation_target_name,
            animation_player,
            animation_graph,
        ))
        .id();

    commands.entity(cube_entity).insert(AnimationTarget {
        id: animation_target_id,
        player: cube_entity,
    });

    // Some light to see something
    commands.spawn((
        PointLight {
            shadows_enabled: true,
            intensity: 10_000_000.,
            range: 100.0,
            ..default()
        },
        Transform::from_xyz(8., 16., 8.),
    ));

    // Ground plane
    commands.spawn((
        Mesh3d(meshes.add(Plane3d::default().mesh().size(50., 50.))),
        MeshMaterial3d(materials.add(Color::from(SILVER))),
    ));

    // The camera
    commands.spawn((
        Camera3d::default(),
        Transform::from_xyz(0., 6., 12.).looking_at(Vec3::new(0., 1.5, 0.), Vec3::Y),
    ));
}

// Holds information about the animation we programmatically create.
struct AnimationInfo {
    // The name of the animation target (in this case, the text).
    target_name: Name,
    // The ID of the animation target, derived from the name.
    target_id: AnimationTargetId,
    // The animation graph asset.
    graph: Handle<AnimationGraph>,
    // The index of the node within that graph.
    node_index: AnimationNodeIndex,
}

impl AnimationInfo {
    // Programmatically creates the UI animation.
    fn create(
        animation_graphs: &mut Assets<AnimationGraph>,
        animation_clips: &mut Assets<AnimationClip>,
    ) -> AnimationInfo {
        // Create an ID that identifies the text node we're going to animate.
        let animation_target_name = Name::new("Cube");
        let animation_target_id = AnimationTargetId::from_name(&animation_target_name);

        // Allocate an animation clip.
        let mut animation_clip = AnimationClip::default();

        // Each leg of the translation motion should take 3 seconds.
        let animation_domain = interval(0.0, 3.0).unwrap();

        // The easing curve is parametrized over [0, 1], so we reparametrize it and
        // then ping-pong, which makes it spend another 3 seconds on the return journey.
        let translation_curve = easing_curve(
            vec3(-6., 2., 0.),
            vec3(6., 2., 0.),
            EaseFunction::CubicInOut,
        )
        .reparametrize_linear(animation_domain)
        .expect("this curve has bounded domain, so this should never fail")
        .ping_pong()
        .expect("this curve has bounded domain, so this should never fail");

        // Something similar for rotation. The repetition here is an illusion caused
        // by the symmetry of the cube; it rotates on the forward journey and never
        // rotates back.
        let rotation_curve = easing_curve(
            Quat::IDENTITY,
            Quat::from_rotation_y(FRAC_PI_2),
            EaseFunction::ElasticInOut,
        )
        .reparametrize_linear(interval(0.0, 4.0).unwrap())
        .expect("this curve has bounded domain, so this should never fail");

        animation_clip
            .add_curve_to_target(animation_target_id, TranslationCurve(translation_curve));
        animation_clip.add_curve_to_target(animation_target_id, RotationCurve(rotation_curve));

        // Save our animation clip as an asset.
        let animation_clip_handle = animation_clips.add(animation_clip);

        // Create an animation graph with that clip.
        let (animation_graph, animation_node_index) =
            AnimationGraph::from_clip(animation_clip_handle);
        let animation_graph_handle = animation_graphs.add(animation_graph);

        AnimationInfo {
            target_name: animation_target_name,
            target_id: animation_target_id,
            graph: animation_graph_handle,
            node_index: animation_node_index,
        }
    }
}
Simplified easing curves (#15711) # Objective Simplify the API surrounding easing curves. Broaden the base of types that support easing. ## Solution There is now a single library function, `easing_curve`, which constructs a unit-parametrized easing curve between two values based on an `EaseFunction`: ```rust /// Given a `start` and `end` value, create a curve parametrized over [the unit interval] /// that connects them, using the given [ease function] to determine the form of the /// curve in between. /// /// [the unit interval]: Interval::UNIT /// [ease function]: EaseFunction pub fn easing_curve<T: Ease>(start: T, end: T, ease_fn: EaseFunction) -> EasingCurve<T> { //... } ``` As this shows, the type of the output curve is generic only in `T`. In particular, as long as `T` is `Reflect` (and `FromReflect` etc. — i.e., a standard "well-behaved" reflectable type), `EasingCurve<T>` is also `Reflect`, and there is no special field handling nonsense. Therefore, `EasingCurve` is the kind of thing that would be able to be easily changed in an editor. This is made possible by storing the actual `EaseFunction` on `EasingCurve<T>` instead of indirecting through some kind of function type (which generally leads to issues with reflection). The types that can be eased are those that implement a trait `Ease`: ```rust /// A type whose values can be eased between. /// /// This requires the construction of an interpolation curve that actually extends /// beyond the curve segment that connects two values, because an easing curve may /// extrapolate before the starting value and after the ending value. This is /// especially common in easing functions that mimic elastic or springlike behavior. pub trait Ease: Sized { /// Given `start` and `end` values, produce a curve with [unlimited domain] /// that: /// - takes a value equivalent to `start` at `t = 0` /// - takes a value equivalent to `end` at `t = 1` /// - has constant speed everywhere, including outside of `[0, 1]` /// /// [unlimited domain]: Interval::EVERYWHERE fn interpolating_curve_unbounded(start: &Self, end: &Self) -> impl Curve<Self>; } ``` (I know, I know, yet another interpolation trait. See 'Future direction'.) The other existing easing functions from the previous version of this module have also become new members of `EaseFunction`: `Linear`, `Steps`, and `Elastic` (which maybe needs a different name). The latter two are parametrized. ## Testing Tested using the `easing_functions` example. I also axed the `cubic_curve` example which was of questionable value and replaced it with `eased_motion`, which uses this API in the context of animation: https://github.com/user-attachments/assets/3c802992-6b9b-4b56-aeb1-a47501c29ce2 --- ## Future direction Morally speaking, `Ease` is incredibly similar to `StableInterpolate`. Probably, we should just merge `StableInterpolate` into `Ease`, and then make `SmoothNudge` an automatic extension trait of `Ease`. The reason I didn't do that is that `StableInterpolate` is not implemented for `VectorSpace` because of concerns about the `Color` types, and I wanted to avoid controversy. I think that may be a good idea though. As Alice mentioned before, we should also probably get rid of the `interpolation` dependency. The parametrized `Elastic` variant probably also needs some additional work (e.g. renaming, in/out/in-out variants, etc.) if we want to keep it. 2024-10-08 19:45:13 +00:00			`//! Demonstrates the application of easing curves to animate a transition.`

			`use std::f32::consts::FRAC_PI_2;`

			`use bevy::{`
			`animation::{AnimationTarget, AnimationTargetId},`
			`color::palettes::css::{ORANGE, SILVER},`
			`math::vec3,`
			`prelude::*,`
			`};`

			`fn main() {`
			`App::new()`
			`.add_plugins(DefaultPlugins)`
			`.add_systems(Startup, setup)`
			`.run();`
			`}`

			`fn setup(`
			`mut commands: Commands,`
			`mut meshes: ResMut<Assets<Mesh>>,`
			`mut materials: ResMut<Assets<StandardMaterial>>,`
			`mut animation_graphs: ResMut<Assets<AnimationGraph>>,`
			`mut animation_clips: ResMut<Assets<AnimationClip>>,`
			`) {`
			`// Create the animation:`
			`let AnimationInfo {`
			`target_name: animation_target_name,`
			`target_id: animation_target_id,`
			`graph: animation_graph,`
			`node_index: animation_node_index,`
			`} = AnimationInfo::create(&mut animation_graphs, &mut animation_clips);`

			`// Build an animation player that automatically plays the animation.`
			`let mut animation_player = AnimationPlayer::default();`
			`animation_player.play(animation_node_index).repeat();`

			`// A cube together with the components needed to animate it`
			`let cube_entity = commands`
			`.spawn((`
			`Mesh3d(meshes.add(Cuboid::from_length(2.0))),`
			`MeshMaterial3d(materials.add(Color::from(ORANGE))),`
			`Transform::from_translation(vec3(-6., 2., 0.)),`
			`animation_target_name,`
			`animation_player,`
			`animation_graph,`
			`))`
			`.id();`

			`commands.entity(cube_entity).insert(AnimationTarget {`
			`id: animation_target_id,`
			`player: cube_entity,`
			`});`

			`// Some light to see something`
			`commands.spawn((`
			`PointLight {`
			`shadows_enabled: true,`
			`intensity: 10_000_000.,`
			`range: 100.0,`
			`..default()`
			`},`
			`Transform::from_xyz(8., 16., 8.),`
			`));`

			`// Ground plane`
			`commands.spawn((`
			`Mesh3d(meshes.add(Plane3d::default().mesh().size(50., 50.))),`
			`MeshMaterial3d(materials.add(Color::from(SILVER))),`
			`));`

			`// The camera`
			`commands.spawn((`
			`Camera3d::default(),`
			`Transform::from_xyz(0., 6., 12.).looking_at(Vec3::new(0., 1.5, 0.), Vec3::Y),`
			`));`
			`}`

			`// Holds information about the animation we programmatically create.`
			`struct AnimationInfo {`
			`// The name of the animation target (in this case, the text).`
			`target_name: Name,`
			`// The ID of the animation target, derived from the name.`
			`target_id: AnimationTargetId,`
			`// The animation graph asset.`
			`graph: Handle<AnimationGraph>,`
			`// The index of the node within that graph.`
			`node_index: AnimationNodeIndex,`
			`}`

			`impl AnimationInfo {`
			`// Programmatically creates the UI animation.`
			`fn create(`
			`animation_graphs: &mut Assets<AnimationGraph>,`
			`animation_clips: &mut Assets<AnimationClip>,`
			`) -> AnimationInfo {`
			`// Create an ID that identifies the text node we're going to animate.`
			`let animation_target_name = Name::new("Cube");`
			`let animation_target_id = AnimationTargetId::from_name(&animation_target_name);`

			`// Allocate an animation clip.`
			`let mut animation_clip = AnimationClip::default();`

			`// Each leg of the translation motion should take 3 seconds.`
			`let animation_domain = interval(0.0, 3.0).unwrap();`

			`// The easing curve is parametrized over [0, 1], so we reparametrize it and`
			`// then ping-pong, which makes it spend another 3 seconds on the return journey.`
			`let translation_curve = easing_curve(`
			`vec3(-6., 2., 0.),`
			`vec3(6., 2., 0.),`
			`EaseFunction::CubicInOut,`
			`)`
			`.reparametrize_linear(animation_domain)`
			`.expect("this curve has bounded domain, so this should never fail")`
			`.ping_pong()`
			`.expect("this curve has bounded domain, so this should never fail");`

			`// Something similar for rotation. The repetition here is an illusion caused`
			`// by the symmetry of the cube; it rotates on the forward journey and never`
			`// rotates back.`
			`let rotation_curve = easing_curve(`
			`Quat::IDENTITY,`
			`Quat::from_rotation_y(FRAC_PI_2),`
			`EaseFunction::ElasticInOut,`
			`)`
			`.reparametrize_linear(interval(0.0, 4.0).unwrap())`
			`.expect("this curve has bounded domain, so this should never fail");`

			`animation_clip`
			`.add_curve_to_target(animation_target_id, TranslationCurve(translation_curve));`
			`animation_clip.add_curve_to_target(animation_target_id, RotationCurve(rotation_curve));`

			`// Save our animation clip as an asset.`
			`let animation_clip_handle = animation_clips.add(animation_clip);`

			`// Create an animation graph with that clip.`
			`let (animation_graph, animation_node_index) =`
			`AnimationGraph::from_clip(animation_clip_handle);`
			`let animation_graph_handle = animation_graphs.add(animation_graph);`

			`AnimationInfo {`
			`target_name: animation_target_name,`
			`target_id: animation_target_id,`
			`graph: animation_graph_handle,`
			`node_index: animation_node_index,`
			`}`
			`}`
			`}`