bevy/examples/animation/animated_ui.rs

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Allow animation clips to animate arbitrary properties. (#15282) Currently, Bevy restricts animation clips to animating `Transform::translation`, `Transform::rotation`, `Transform::scale`, or `MorphWeights`, which correspond to the properties that glTF can animate. This is insufficient for many use cases such as animating UI, as the UI layout systems expect to have exclusive control over UI elements' `Transform`s and therefore the `Style` properties must be animated instead. This commit fixes this, allowing for `AnimationClip`s to animate arbitrary properties. The `Keyframes` structure has been turned into a low-level trait that can be implemented to achieve arbitrary animation behavior. Along with `Keyframes`, this patch adds a higher-level trait, `AnimatableProperty`, that simplifies the task of animating single interpolable properties. Built-in `Keyframes` implementations exist for translation, rotation, scale, and morph weights. For the most part, you can migrate by simply changing your code from `Keyframes::Translation(...)` to `TranslationKeyframes(...)`, and likewise for rotation, scale, and morph weights. An example `AnimatableProperty` implementation for the font size of a text section follows: #[derive(Reflect)] struct FontSizeProperty; impl AnimatableProperty for FontSizeProperty { type Component = Text; type Property = f32; fn get_mut(component: &mut Self::Component) -> Option<&mut Self::Property> { Some(&mut component.sections.get_mut(0)?.style.font_size) } } In order to keep this patch relatively small, this patch doesn't include an implementation of `AnimatableProperty` on top of the reflection system. That can be a follow-up. This patch builds on top of the new `EntityMutExcept<>` type in order to widen the `AnimationTarget` query to include write access to all components. Because `EntityMutExcept<>` has some performance overhead over an explicit query, we continue to explicitly query `Transform` in order to avoid regressing the performance of skeletal animation, such as the `many_foxes` benchmark. I've measured the performance of that benchmark and have found no significant regressions. A new example, `animated_ui`, has been added. This example shows how to use Bevy's built-in animation infrastructure to animate font size and color, which wasn't possible before this patch. ## Showcase https://github.com/user-attachments/assets/1fa73492-a9ce-405a-a8f2-4aacd7f6dc97 ## Migration Guide * Animation keyframes are now an extensible trait, not an enum. Replace `Keyframes::Translation(...)`, `Keyframes::Scale(...)`, `Keyframes::Rotation(...)`, and `Keyframes::Weights(...)` with `Box::new(TranslationKeyframes(...))`, `Box::new(ScaleKeyframes(...))`, `Box::new(RotationKeyframes(...))`, and `Box::new(MorphWeightsKeyframes(...))` respectively.
2024-09-23 17:14:12 +00:00
//! Shows how to use animation clips to animate UI properties.
use bevy::{
animation::{AnimationTarget, AnimationTargetId},
prelude::*,
};
// A type that represents the font size of the first text section.
//
// We implement `AnimatableProperty` on this.
#[derive(Reflect)]
struct FontSizeProperty;
// A type that represents the color of the first text section.
//
// We implement `AnimatableProperty` on this.
#[derive(Reflect)]
struct TextColorProperty;
// 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,
}
// The entry point.
fn main() {
App::new()
.add_plugins(DefaultPlugins)
// Note that we don't need any systems other than the setup system,
// because Bevy automatically updates animations every frame.
.add_systems(Startup, setup)
.run();
}
impl AnimatableProperty for FontSizeProperty {
type Component = Text;
type Property = f32;
fn get_mut(component: &mut Self::Component) -> Option<&mut Self::Property> {
Some(&mut component.sections.get_mut(0)?.style.font_size)
}
}
impl AnimatableProperty for TextColorProperty {
type Component = Text;
type Property = Srgba;
fn get_mut(component: &mut Self::Component) -> Option<&mut Self::Property> {
match component.sections.get_mut(0)?.style.color {
Color::Srgba(ref mut color) => Some(color),
_ => None,
}
}
}
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("Text");
let animation_target_id = AnimationTargetId::from_name(&animation_target_name);
// Allocate an animation clip.
let mut animation_clip = AnimationClip::default();
// Create a curve that animates font size.
//
Curve-based animation (#15434) # Objective This PR extends and reworks the material from #15282 by allowing arbitrary curves to be used by the animation system to animate arbitrary properties. The goals of this work are to: - Allow far greater flexibility in how animations are allowed to be defined in order to be used with `bevy_animation`. - Delegate responsibility over keyframe interpolation to `bevy_math` and the `Curve` libraries and reduce reliance on keyframes in animation definitions generally. - Move away from allowing the glTF spec to completely define animations on a mechanical level. ## Solution ### Overview At a high level, curves have been incorporated into the animation system using the `AnimationCurve` trait (closely related to what was `Keyframes`). From the top down: 1. In `animate_targets`, animations are driven by `VariableCurve`, which is now a thin wrapper around a `Box<dyn AnimationCurve>`. 2. `AnimationCurve` is something built out of a `Curve`, and it tells the animation system how to use the curve's output to actually mutate component properties. The trait looks like this: ```rust /// A low-level trait that provides control over how curves are actually applied to entities /// by the animation system. /// /// Typically, this will not need to be implemented manually, since it is automatically /// implemented by [`AnimatableCurve`] and other curves used by the animation system /// (e.g. those that animate parts of transforms or morph weights). However, this can be /// implemented manually when `AnimatableCurve` is not sufficiently expressive. /// /// In many respects, this behaves like a type-erased form of [`Curve`], where the output /// type of the curve is remembered only in the components that are mutated in the /// implementation of [`apply`]. /// /// [`apply`]: AnimationCurve::apply pub trait AnimationCurve: Reflect + Debug + Send + Sync { /// Returns a boxed clone of this value. fn clone_value(&self) -> Box<dyn AnimationCurve>; /// The range of times for which this animation is defined. fn domain(&self) -> Interval; /// Write the value of sampling this curve at time `t` into `transform` or `entity`, /// as appropriate, interpolating between the existing value and the sampled value /// using the given `weight`. fn apply<'a>( &self, t: f32, transform: Option<Mut<'a, Transform>>, entity: EntityMutExcept<'a, (Transform, AnimationPlayer, Handle<AnimationGraph>)>, weight: f32, ) -> Result<(), AnimationEvaluationError>; } ``` 3. The conversion process from a `Curve` to an `AnimationCurve` involves using wrappers which communicate the intent to animate a particular property. For example, here is `TranslationCurve`, which wraps a `Curve<Vec3>` and uses it to animate `Transform::translation`: ```rust /// This type allows a curve valued in `Vec3` to become an [`AnimationCurve`] that animates /// the translation component of a transform. pub struct TranslationCurve<C>(pub C); ``` ### Animatable Properties The `AnimatableProperty` trait survives in the transition, and it can be used to allow curves to animate arbitrary component properties. The updated documentation for `AnimatableProperty` explains this process: <details> <summary>Expand AnimatableProperty example</summary An `AnimatableProperty` is a value on a component that Bevy can animate. You can implement this trait on a unit struct in order to support animating custom components other than transforms and morph weights. Use that type in conjunction with `AnimatableCurve` (and perhaps `AnimatableKeyframeCurve` to define the animation itself). For example, in order to animate font size of a text section from 24 pt. to 80 pt., you might use: ```rust #[derive(Reflect)] struct FontSizeProperty; impl AnimatableProperty for FontSizeProperty { type Component = Text; type Property = f32; fn get_mut(component: &mut Self::Component) -> Option<&mut Self::Property> { Some(&mut component.sections.get_mut(0)?.style.font_size) } } ``` You can then create an `AnimationClip` to animate this property like so: ```rust let mut animation_clip = AnimationClip::default(); animation_clip.add_curve_to_target( animation_target_id, AnimatableKeyframeCurve::new( [ (0.0, 24.0), (1.0, 80.0), ] ) .map(AnimatableCurve::<FontSizeProperty, _>::from_curve) .expect("Failed to create font size curve") ); ``` Here, the use of `AnimatableKeyframeCurve` creates a curve out of the given keyframe time-value pairs, using the `Animatable` implementation of `f32` to interpolate between them. The invocation of `AnimatableCurve::from_curve` with `FontSizeProperty` indicates that the `f32` output from that curve is to be used to animate the font size of a `Text` component (as configured above). </details> ### glTF Loading glTF animations are now loaded into `Curve` types of various kinds, depending on what is being animated and what interpolation mode is being used. Those types get wrapped into and converted into `Box<dyn AnimationCurve>` and shoved inside of a `VariableCurve` just like everybody else. ### Morph Weights There is an `IterableCurve` abstraction which allows sampling these from a contiguous buffer without allocating. Its only reason for existing is that Rust disallows you from naming function types, otherwise we would just use `Curve` with an iterator output type. (The iterator involves `Map`, and the name of the function type would have to be able to be named, but it is not.) A `WeightsCurve` adaptor turns an `IterableCurve` into an `AnimationCurve`, so it behaves like everything else in that regard. ## Testing Tested by running existing animation examples. Interpolation logic has had additional tests added within the `Curve` API to replace the tests in `bevy_animation`. Some kinds of out-of-bounds errors have become impossible. Performance testing on `many_foxes` (`animate_targets`) suggests that performance is very similar to the existing implementation. Here are a couple trace histograms across different runs (yellow is this branch, red is main). <img width="669" alt="Screenshot 2024-09-27 at 9 41 50 AM" src="https://github.com/user-attachments/assets/5ba4e9ac-3aea-452e-aaf8-1492acc2d7fc"> <img width="673" alt="Screenshot 2024-09-27 at 9 45 18 AM" src="https://github.com/user-attachments/assets/8982538b-04cf-46b5-97b2-164c6bc8162e"> --- ## Migration Guide Most user code that does not directly deal with `AnimationClip` and `VariableCurve` will not need to be changed. On the other hand, `VariableCurve` has been completely overhauled. If you were previously defining animation curves in code using keyframes, you will need to migrate that code to use curve constructors instead. For example, a rotation animation defined using keyframes and added to an animation clip like this: ```rust animation_clip.add_curve_to_target( animation_target_id, VariableCurve { keyframe_timestamps: vec![0.0, 1.0, 2.0, 3.0, 4.0], keyframes: Keyframes::Rotation(vec![ Quat::IDENTITY, Quat::from_axis_angle(Vec3::Y, PI / 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 3.), Quat::IDENTITY, ]), interpolation: Interpolation::Linear, }, ); ``` would now be added like this: ```rust animation_clip.add_curve_to_target( animation_target_id, AnimatableKeyframeCurve::new([0.0, 1.0, 2.0, 3.0, 4.0].into_iter().zip([ Quat::IDENTITY, Quat::from_axis_angle(Vec3::Y, PI / 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 3.), Quat::IDENTITY, ])) .map(RotationCurve) .expect("Failed to build rotation curve"), ); ``` Note that the interface of `AnimationClip::add_curve_to_target` has also changed (as this example shows, if subtly), and now takes its curve input as an `impl AnimationCurve`. If you need to add a `VariableCurve` directly, a new method `add_variable_curve_to_target` accommodates that (and serves as a one-to-one migration in this regard). ### For reviewers The diff is pretty big, and the structure of some of the changes might not be super-obvious: - `keyframes.rs` became `animation_curves.rs`, and `AnimationCurve` is based heavily on `Keyframes`, with the adaptors also largely following suite. - The Curve API adaptor structs were moved from `bevy_math::curve::mod` into their own module `adaptors`. There are no functional changes to how these adaptors work; this is just to make room for the specialized reflection implementations since `mod.rs` was getting kind of cramped. - The new module `gltf_curves` holds the additional curve constructions that are needed by the glTF loader. Note that the loader uses a mix of these and off-the-shelf `bevy_math` curve stuff. - `animatable.rs` no longer holds logic related to keyframe interpolation, which is now delegated to the existing abstractions in `bevy_math::curve::cores`. --------- Co-authored-by: Gino Valente <49806985+MrGVSV@users.noreply.github.com> Co-authored-by: aecsocket <43144841+aecsocket@users.noreply.github.com>
2024-09-30 19:56:55 +00:00
// The curve itself is a `Curve<f32>`, and `f32` is `FontSizeProperty::Property`,
// which is required by `AnimatableCurve::from_curve`.
Allow animation clips to animate arbitrary properties. (#15282) Currently, Bevy restricts animation clips to animating `Transform::translation`, `Transform::rotation`, `Transform::scale`, or `MorphWeights`, which correspond to the properties that glTF can animate. This is insufficient for many use cases such as animating UI, as the UI layout systems expect to have exclusive control over UI elements' `Transform`s and therefore the `Style` properties must be animated instead. This commit fixes this, allowing for `AnimationClip`s to animate arbitrary properties. The `Keyframes` structure has been turned into a low-level trait that can be implemented to achieve arbitrary animation behavior. Along with `Keyframes`, this patch adds a higher-level trait, `AnimatableProperty`, that simplifies the task of animating single interpolable properties. Built-in `Keyframes` implementations exist for translation, rotation, scale, and morph weights. For the most part, you can migrate by simply changing your code from `Keyframes::Translation(...)` to `TranslationKeyframes(...)`, and likewise for rotation, scale, and morph weights. An example `AnimatableProperty` implementation for the font size of a text section follows: #[derive(Reflect)] struct FontSizeProperty; impl AnimatableProperty for FontSizeProperty { type Component = Text; type Property = f32; fn get_mut(component: &mut Self::Component) -> Option<&mut Self::Property> { Some(&mut component.sections.get_mut(0)?.style.font_size) } } In order to keep this patch relatively small, this patch doesn't include an implementation of `AnimatableProperty` on top of the reflection system. That can be a follow-up. This patch builds on top of the new `EntityMutExcept<>` type in order to widen the `AnimationTarget` query to include write access to all components. Because `EntityMutExcept<>` has some performance overhead over an explicit query, we continue to explicitly query `Transform` in order to avoid regressing the performance of skeletal animation, such as the `many_foxes` benchmark. I've measured the performance of that benchmark and have found no significant regressions. A new example, `animated_ui`, has been added. This example shows how to use Bevy's built-in animation infrastructure to animate font size and color, which wasn't possible before this patch. ## Showcase https://github.com/user-attachments/assets/1fa73492-a9ce-405a-a8f2-4aacd7f6dc97 ## Migration Guide * Animation keyframes are now an extensible trait, not an enum. Replace `Keyframes::Translation(...)`, `Keyframes::Scale(...)`, `Keyframes::Rotation(...)`, and `Keyframes::Weights(...)` with `Box::new(TranslationKeyframes(...))`, `Box::new(ScaleKeyframes(...))`, `Box::new(RotationKeyframes(...))`, and `Box::new(MorphWeightsKeyframes(...))` respectively.
2024-09-23 17:14:12 +00:00
animation_clip.add_curve_to_target(
animation_target_id,
Curve-based animation (#15434) # Objective This PR extends and reworks the material from #15282 by allowing arbitrary curves to be used by the animation system to animate arbitrary properties. The goals of this work are to: - Allow far greater flexibility in how animations are allowed to be defined in order to be used with `bevy_animation`. - Delegate responsibility over keyframe interpolation to `bevy_math` and the `Curve` libraries and reduce reliance on keyframes in animation definitions generally. - Move away from allowing the glTF spec to completely define animations on a mechanical level. ## Solution ### Overview At a high level, curves have been incorporated into the animation system using the `AnimationCurve` trait (closely related to what was `Keyframes`). From the top down: 1. In `animate_targets`, animations are driven by `VariableCurve`, which is now a thin wrapper around a `Box<dyn AnimationCurve>`. 2. `AnimationCurve` is something built out of a `Curve`, and it tells the animation system how to use the curve's output to actually mutate component properties. The trait looks like this: ```rust /// A low-level trait that provides control over how curves are actually applied to entities /// by the animation system. /// /// Typically, this will not need to be implemented manually, since it is automatically /// implemented by [`AnimatableCurve`] and other curves used by the animation system /// (e.g. those that animate parts of transforms or morph weights). However, this can be /// implemented manually when `AnimatableCurve` is not sufficiently expressive. /// /// In many respects, this behaves like a type-erased form of [`Curve`], where the output /// type of the curve is remembered only in the components that are mutated in the /// implementation of [`apply`]. /// /// [`apply`]: AnimationCurve::apply pub trait AnimationCurve: Reflect + Debug + Send + Sync { /// Returns a boxed clone of this value. fn clone_value(&self) -> Box<dyn AnimationCurve>; /// The range of times for which this animation is defined. fn domain(&self) -> Interval; /// Write the value of sampling this curve at time `t` into `transform` or `entity`, /// as appropriate, interpolating between the existing value and the sampled value /// using the given `weight`. fn apply<'a>( &self, t: f32, transform: Option<Mut<'a, Transform>>, entity: EntityMutExcept<'a, (Transform, AnimationPlayer, Handle<AnimationGraph>)>, weight: f32, ) -> Result<(), AnimationEvaluationError>; } ``` 3. The conversion process from a `Curve` to an `AnimationCurve` involves using wrappers which communicate the intent to animate a particular property. For example, here is `TranslationCurve`, which wraps a `Curve<Vec3>` and uses it to animate `Transform::translation`: ```rust /// This type allows a curve valued in `Vec3` to become an [`AnimationCurve`] that animates /// the translation component of a transform. pub struct TranslationCurve<C>(pub C); ``` ### Animatable Properties The `AnimatableProperty` trait survives in the transition, and it can be used to allow curves to animate arbitrary component properties. The updated documentation for `AnimatableProperty` explains this process: <details> <summary>Expand AnimatableProperty example</summary An `AnimatableProperty` is a value on a component that Bevy can animate. You can implement this trait on a unit struct in order to support animating custom components other than transforms and morph weights. Use that type in conjunction with `AnimatableCurve` (and perhaps `AnimatableKeyframeCurve` to define the animation itself). For example, in order to animate font size of a text section from 24 pt. to 80 pt., you might use: ```rust #[derive(Reflect)] struct FontSizeProperty; impl AnimatableProperty for FontSizeProperty { type Component = Text; type Property = f32; fn get_mut(component: &mut Self::Component) -> Option<&mut Self::Property> { Some(&mut component.sections.get_mut(0)?.style.font_size) } } ``` You can then create an `AnimationClip` to animate this property like so: ```rust let mut animation_clip = AnimationClip::default(); animation_clip.add_curve_to_target( animation_target_id, AnimatableKeyframeCurve::new( [ (0.0, 24.0), (1.0, 80.0), ] ) .map(AnimatableCurve::<FontSizeProperty, _>::from_curve) .expect("Failed to create font size curve") ); ``` Here, the use of `AnimatableKeyframeCurve` creates a curve out of the given keyframe time-value pairs, using the `Animatable` implementation of `f32` to interpolate between them. The invocation of `AnimatableCurve::from_curve` with `FontSizeProperty` indicates that the `f32` output from that curve is to be used to animate the font size of a `Text` component (as configured above). </details> ### glTF Loading glTF animations are now loaded into `Curve` types of various kinds, depending on what is being animated and what interpolation mode is being used. Those types get wrapped into and converted into `Box<dyn AnimationCurve>` and shoved inside of a `VariableCurve` just like everybody else. ### Morph Weights There is an `IterableCurve` abstraction which allows sampling these from a contiguous buffer without allocating. Its only reason for existing is that Rust disallows you from naming function types, otherwise we would just use `Curve` with an iterator output type. (The iterator involves `Map`, and the name of the function type would have to be able to be named, but it is not.) A `WeightsCurve` adaptor turns an `IterableCurve` into an `AnimationCurve`, so it behaves like everything else in that regard. ## Testing Tested by running existing animation examples. Interpolation logic has had additional tests added within the `Curve` API to replace the tests in `bevy_animation`. Some kinds of out-of-bounds errors have become impossible. Performance testing on `many_foxes` (`animate_targets`) suggests that performance is very similar to the existing implementation. Here are a couple trace histograms across different runs (yellow is this branch, red is main). <img width="669" alt="Screenshot 2024-09-27 at 9 41 50 AM" src="https://github.com/user-attachments/assets/5ba4e9ac-3aea-452e-aaf8-1492acc2d7fc"> <img width="673" alt="Screenshot 2024-09-27 at 9 45 18 AM" src="https://github.com/user-attachments/assets/8982538b-04cf-46b5-97b2-164c6bc8162e"> --- ## Migration Guide Most user code that does not directly deal with `AnimationClip` and `VariableCurve` will not need to be changed. On the other hand, `VariableCurve` has been completely overhauled. If you were previously defining animation curves in code using keyframes, you will need to migrate that code to use curve constructors instead. For example, a rotation animation defined using keyframes and added to an animation clip like this: ```rust animation_clip.add_curve_to_target( animation_target_id, VariableCurve { keyframe_timestamps: vec![0.0, 1.0, 2.0, 3.0, 4.0], keyframes: Keyframes::Rotation(vec![ Quat::IDENTITY, Quat::from_axis_angle(Vec3::Y, PI / 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 3.), Quat::IDENTITY, ]), interpolation: Interpolation::Linear, }, ); ``` would now be added like this: ```rust animation_clip.add_curve_to_target( animation_target_id, AnimatableKeyframeCurve::new([0.0, 1.0, 2.0, 3.0, 4.0].into_iter().zip([ Quat::IDENTITY, Quat::from_axis_angle(Vec3::Y, PI / 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 3.), Quat::IDENTITY, ])) .map(RotationCurve) .expect("Failed to build rotation curve"), ); ``` Note that the interface of `AnimationClip::add_curve_to_target` has also changed (as this example shows, if subtly), and now takes its curve input as an `impl AnimationCurve`. If you need to add a `VariableCurve` directly, a new method `add_variable_curve_to_target` accommodates that (and serves as a one-to-one migration in this regard). ### For reviewers The diff is pretty big, and the structure of some of the changes might not be super-obvious: - `keyframes.rs` became `animation_curves.rs`, and `AnimationCurve` is based heavily on `Keyframes`, with the adaptors also largely following suite. - The Curve API adaptor structs were moved from `bevy_math::curve::mod` into their own module `adaptors`. There are no functional changes to how these adaptors work; this is just to make room for the specialized reflection implementations since `mod.rs` was getting kind of cramped. - The new module `gltf_curves` holds the additional curve constructions that are needed by the glTF loader. Note that the loader uses a mix of these and off-the-shelf `bevy_math` curve stuff. - `animatable.rs` no longer holds logic related to keyframe interpolation, which is now delegated to the existing abstractions in `bevy_math::curve::cores`. --------- Co-authored-by: Gino Valente <49806985+MrGVSV@users.noreply.github.com> Co-authored-by: aecsocket <43144841+aecsocket@users.noreply.github.com>
2024-09-30 19:56:55 +00:00
AnimatableKeyframeCurve::new(
[0.0, 0.5, 1.0, 1.5, 2.0, 2.5, 3.0]
.into_iter()
.zip([24.0, 80.0, 24.0, 80.0, 24.0, 80.0, 24.0]),
)
.map(AnimatableCurve::<FontSizeProperty, _>::from_curve)
.expect("should be able to build translation curve because we pass in valid samples"),
Allow animation clips to animate arbitrary properties. (#15282) Currently, Bevy restricts animation clips to animating `Transform::translation`, `Transform::rotation`, `Transform::scale`, or `MorphWeights`, which correspond to the properties that glTF can animate. This is insufficient for many use cases such as animating UI, as the UI layout systems expect to have exclusive control over UI elements' `Transform`s and therefore the `Style` properties must be animated instead. This commit fixes this, allowing for `AnimationClip`s to animate arbitrary properties. The `Keyframes` structure has been turned into a low-level trait that can be implemented to achieve arbitrary animation behavior. Along with `Keyframes`, this patch adds a higher-level trait, `AnimatableProperty`, that simplifies the task of animating single interpolable properties. Built-in `Keyframes` implementations exist for translation, rotation, scale, and morph weights. For the most part, you can migrate by simply changing your code from `Keyframes::Translation(...)` to `TranslationKeyframes(...)`, and likewise for rotation, scale, and morph weights. An example `AnimatableProperty` implementation for the font size of a text section follows: #[derive(Reflect)] struct FontSizeProperty; impl AnimatableProperty for FontSizeProperty { type Component = Text; type Property = f32; fn get_mut(component: &mut Self::Component) -> Option<&mut Self::Property> { Some(&mut component.sections.get_mut(0)?.style.font_size) } } In order to keep this patch relatively small, this patch doesn't include an implementation of `AnimatableProperty` on top of the reflection system. That can be a follow-up. This patch builds on top of the new `EntityMutExcept<>` type in order to widen the `AnimationTarget` query to include write access to all components. Because `EntityMutExcept<>` has some performance overhead over an explicit query, we continue to explicitly query `Transform` in order to avoid regressing the performance of skeletal animation, such as the `many_foxes` benchmark. I've measured the performance of that benchmark and have found no significant regressions. A new example, `animated_ui`, has been added. This example shows how to use Bevy's built-in animation infrastructure to animate font size and color, which wasn't possible before this patch. ## Showcase https://github.com/user-attachments/assets/1fa73492-a9ce-405a-a8f2-4aacd7f6dc97 ## Migration Guide * Animation keyframes are now an extensible trait, not an enum. Replace `Keyframes::Translation(...)`, `Keyframes::Scale(...)`, `Keyframes::Rotation(...)`, and `Keyframes::Weights(...)` with `Box::new(TranslationKeyframes(...))`, `Box::new(ScaleKeyframes(...))`, `Box::new(RotationKeyframes(...))`, and `Box::new(MorphWeightsKeyframes(...))` respectively.
2024-09-23 17:14:12 +00:00
);
// Create a curve that animates font color. Note that this should have
// the same time duration as the previous curve.
Curve-based animation (#15434) # Objective This PR extends and reworks the material from #15282 by allowing arbitrary curves to be used by the animation system to animate arbitrary properties. The goals of this work are to: - Allow far greater flexibility in how animations are allowed to be defined in order to be used with `bevy_animation`. - Delegate responsibility over keyframe interpolation to `bevy_math` and the `Curve` libraries and reduce reliance on keyframes in animation definitions generally. - Move away from allowing the glTF spec to completely define animations on a mechanical level. ## Solution ### Overview At a high level, curves have been incorporated into the animation system using the `AnimationCurve` trait (closely related to what was `Keyframes`). From the top down: 1. In `animate_targets`, animations are driven by `VariableCurve`, which is now a thin wrapper around a `Box<dyn AnimationCurve>`. 2. `AnimationCurve` is something built out of a `Curve`, and it tells the animation system how to use the curve's output to actually mutate component properties. The trait looks like this: ```rust /// A low-level trait that provides control over how curves are actually applied to entities /// by the animation system. /// /// Typically, this will not need to be implemented manually, since it is automatically /// implemented by [`AnimatableCurve`] and other curves used by the animation system /// (e.g. those that animate parts of transforms or morph weights). However, this can be /// implemented manually when `AnimatableCurve` is not sufficiently expressive. /// /// In many respects, this behaves like a type-erased form of [`Curve`], where the output /// type of the curve is remembered only in the components that are mutated in the /// implementation of [`apply`]. /// /// [`apply`]: AnimationCurve::apply pub trait AnimationCurve: Reflect + Debug + Send + Sync { /// Returns a boxed clone of this value. fn clone_value(&self) -> Box<dyn AnimationCurve>; /// The range of times for which this animation is defined. fn domain(&self) -> Interval; /// Write the value of sampling this curve at time `t` into `transform` or `entity`, /// as appropriate, interpolating between the existing value and the sampled value /// using the given `weight`. fn apply<'a>( &self, t: f32, transform: Option<Mut<'a, Transform>>, entity: EntityMutExcept<'a, (Transform, AnimationPlayer, Handle<AnimationGraph>)>, weight: f32, ) -> Result<(), AnimationEvaluationError>; } ``` 3. The conversion process from a `Curve` to an `AnimationCurve` involves using wrappers which communicate the intent to animate a particular property. For example, here is `TranslationCurve`, which wraps a `Curve<Vec3>` and uses it to animate `Transform::translation`: ```rust /// This type allows a curve valued in `Vec3` to become an [`AnimationCurve`] that animates /// the translation component of a transform. pub struct TranslationCurve<C>(pub C); ``` ### Animatable Properties The `AnimatableProperty` trait survives in the transition, and it can be used to allow curves to animate arbitrary component properties. The updated documentation for `AnimatableProperty` explains this process: <details> <summary>Expand AnimatableProperty example</summary An `AnimatableProperty` is a value on a component that Bevy can animate. You can implement this trait on a unit struct in order to support animating custom components other than transforms and morph weights. Use that type in conjunction with `AnimatableCurve` (and perhaps `AnimatableKeyframeCurve` to define the animation itself). For example, in order to animate font size of a text section from 24 pt. to 80 pt., you might use: ```rust #[derive(Reflect)] struct FontSizeProperty; impl AnimatableProperty for FontSizeProperty { type Component = Text; type Property = f32; fn get_mut(component: &mut Self::Component) -> Option<&mut Self::Property> { Some(&mut component.sections.get_mut(0)?.style.font_size) } } ``` You can then create an `AnimationClip` to animate this property like so: ```rust let mut animation_clip = AnimationClip::default(); animation_clip.add_curve_to_target( animation_target_id, AnimatableKeyframeCurve::new( [ (0.0, 24.0), (1.0, 80.0), ] ) .map(AnimatableCurve::<FontSizeProperty, _>::from_curve) .expect("Failed to create font size curve") ); ``` Here, the use of `AnimatableKeyframeCurve` creates a curve out of the given keyframe time-value pairs, using the `Animatable` implementation of `f32` to interpolate between them. The invocation of `AnimatableCurve::from_curve` with `FontSizeProperty` indicates that the `f32` output from that curve is to be used to animate the font size of a `Text` component (as configured above). </details> ### glTF Loading glTF animations are now loaded into `Curve` types of various kinds, depending on what is being animated and what interpolation mode is being used. Those types get wrapped into and converted into `Box<dyn AnimationCurve>` and shoved inside of a `VariableCurve` just like everybody else. ### Morph Weights There is an `IterableCurve` abstraction which allows sampling these from a contiguous buffer without allocating. Its only reason for existing is that Rust disallows you from naming function types, otherwise we would just use `Curve` with an iterator output type. (The iterator involves `Map`, and the name of the function type would have to be able to be named, but it is not.) A `WeightsCurve` adaptor turns an `IterableCurve` into an `AnimationCurve`, so it behaves like everything else in that regard. ## Testing Tested by running existing animation examples. Interpolation logic has had additional tests added within the `Curve` API to replace the tests in `bevy_animation`. Some kinds of out-of-bounds errors have become impossible. Performance testing on `many_foxes` (`animate_targets`) suggests that performance is very similar to the existing implementation. Here are a couple trace histograms across different runs (yellow is this branch, red is main). <img width="669" alt="Screenshot 2024-09-27 at 9 41 50 AM" src="https://github.com/user-attachments/assets/5ba4e9ac-3aea-452e-aaf8-1492acc2d7fc"> <img width="673" alt="Screenshot 2024-09-27 at 9 45 18 AM" src="https://github.com/user-attachments/assets/8982538b-04cf-46b5-97b2-164c6bc8162e"> --- ## Migration Guide Most user code that does not directly deal with `AnimationClip` and `VariableCurve` will not need to be changed. On the other hand, `VariableCurve` has been completely overhauled. If you were previously defining animation curves in code using keyframes, you will need to migrate that code to use curve constructors instead. For example, a rotation animation defined using keyframes and added to an animation clip like this: ```rust animation_clip.add_curve_to_target( animation_target_id, VariableCurve { keyframe_timestamps: vec![0.0, 1.0, 2.0, 3.0, 4.0], keyframes: Keyframes::Rotation(vec![ Quat::IDENTITY, Quat::from_axis_angle(Vec3::Y, PI / 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 3.), Quat::IDENTITY, ]), interpolation: Interpolation::Linear, }, ); ``` would now be added like this: ```rust animation_clip.add_curve_to_target( animation_target_id, AnimatableKeyframeCurve::new([0.0, 1.0, 2.0, 3.0, 4.0].into_iter().zip([ Quat::IDENTITY, Quat::from_axis_angle(Vec3::Y, PI / 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 3.), Quat::IDENTITY, ])) .map(RotationCurve) .expect("Failed to build rotation curve"), ); ``` Note that the interface of `AnimationClip::add_curve_to_target` has also changed (as this example shows, if subtly), and now takes its curve input as an `impl AnimationCurve`. If you need to add a `VariableCurve` directly, a new method `add_variable_curve_to_target` accommodates that (and serves as a one-to-one migration in this regard). ### For reviewers The diff is pretty big, and the structure of some of the changes might not be super-obvious: - `keyframes.rs` became `animation_curves.rs`, and `AnimationCurve` is based heavily on `Keyframes`, with the adaptors also largely following suite. - The Curve API adaptor structs were moved from `bevy_math::curve::mod` into their own module `adaptors`. There are no functional changes to how these adaptors work; this is just to make room for the specialized reflection implementations since `mod.rs` was getting kind of cramped. - The new module `gltf_curves` holds the additional curve constructions that are needed by the glTF loader. Note that the loader uses a mix of these and off-the-shelf `bevy_math` curve stuff. - `animatable.rs` no longer holds logic related to keyframe interpolation, which is now delegated to the existing abstractions in `bevy_math::curve::cores`. --------- Co-authored-by: Gino Valente <49806985+MrGVSV@users.noreply.github.com> Co-authored-by: aecsocket <43144841+aecsocket@users.noreply.github.com>
2024-09-30 19:56:55 +00:00
//
// Similar to the above, the curve itself is a `Curve<Srgba>`, and `Srgba` is
// `TextColorProperty::Property`, which is required by the `from_curve` method.
Allow animation clips to animate arbitrary properties. (#15282) Currently, Bevy restricts animation clips to animating `Transform::translation`, `Transform::rotation`, `Transform::scale`, or `MorphWeights`, which correspond to the properties that glTF can animate. This is insufficient for many use cases such as animating UI, as the UI layout systems expect to have exclusive control over UI elements' `Transform`s and therefore the `Style` properties must be animated instead. This commit fixes this, allowing for `AnimationClip`s to animate arbitrary properties. The `Keyframes` structure has been turned into a low-level trait that can be implemented to achieve arbitrary animation behavior. Along with `Keyframes`, this patch adds a higher-level trait, `AnimatableProperty`, that simplifies the task of animating single interpolable properties. Built-in `Keyframes` implementations exist for translation, rotation, scale, and morph weights. For the most part, you can migrate by simply changing your code from `Keyframes::Translation(...)` to `TranslationKeyframes(...)`, and likewise for rotation, scale, and morph weights. An example `AnimatableProperty` implementation for the font size of a text section follows: #[derive(Reflect)] struct FontSizeProperty; impl AnimatableProperty for FontSizeProperty { type Component = Text; type Property = f32; fn get_mut(component: &mut Self::Component) -> Option<&mut Self::Property> { Some(&mut component.sections.get_mut(0)?.style.font_size) } } In order to keep this patch relatively small, this patch doesn't include an implementation of `AnimatableProperty` on top of the reflection system. That can be a follow-up. This patch builds on top of the new `EntityMutExcept<>` type in order to widen the `AnimationTarget` query to include write access to all components. Because `EntityMutExcept<>` has some performance overhead over an explicit query, we continue to explicitly query `Transform` in order to avoid regressing the performance of skeletal animation, such as the `many_foxes` benchmark. I've measured the performance of that benchmark and have found no significant regressions. A new example, `animated_ui`, has been added. This example shows how to use Bevy's built-in animation infrastructure to animate font size and color, which wasn't possible before this patch. ## Showcase https://github.com/user-attachments/assets/1fa73492-a9ce-405a-a8f2-4aacd7f6dc97 ## Migration Guide * Animation keyframes are now an extensible trait, not an enum. Replace `Keyframes::Translation(...)`, `Keyframes::Scale(...)`, `Keyframes::Rotation(...)`, and `Keyframes::Weights(...)` with `Box::new(TranslationKeyframes(...))`, `Box::new(ScaleKeyframes(...))`, `Box::new(RotationKeyframes(...))`, and `Box::new(MorphWeightsKeyframes(...))` respectively.
2024-09-23 17:14:12 +00:00
animation_clip.add_curve_to_target(
animation_target_id,
Curve-based animation (#15434) # Objective This PR extends and reworks the material from #15282 by allowing arbitrary curves to be used by the animation system to animate arbitrary properties. The goals of this work are to: - Allow far greater flexibility in how animations are allowed to be defined in order to be used with `bevy_animation`. - Delegate responsibility over keyframe interpolation to `bevy_math` and the `Curve` libraries and reduce reliance on keyframes in animation definitions generally. - Move away from allowing the glTF spec to completely define animations on a mechanical level. ## Solution ### Overview At a high level, curves have been incorporated into the animation system using the `AnimationCurve` trait (closely related to what was `Keyframes`). From the top down: 1. In `animate_targets`, animations are driven by `VariableCurve`, which is now a thin wrapper around a `Box<dyn AnimationCurve>`. 2. `AnimationCurve` is something built out of a `Curve`, and it tells the animation system how to use the curve's output to actually mutate component properties. The trait looks like this: ```rust /// A low-level trait that provides control over how curves are actually applied to entities /// by the animation system. /// /// Typically, this will not need to be implemented manually, since it is automatically /// implemented by [`AnimatableCurve`] and other curves used by the animation system /// (e.g. those that animate parts of transforms or morph weights). However, this can be /// implemented manually when `AnimatableCurve` is not sufficiently expressive. /// /// In many respects, this behaves like a type-erased form of [`Curve`], where the output /// type of the curve is remembered only in the components that are mutated in the /// implementation of [`apply`]. /// /// [`apply`]: AnimationCurve::apply pub trait AnimationCurve: Reflect + Debug + Send + Sync { /// Returns a boxed clone of this value. fn clone_value(&self) -> Box<dyn AnimationCurve>; /// The range of times for which this animation is defined. fn domain(&self) -> Interval; /// Write the value of sampling this curve at time `t` into `transform` or `entity`, /// as appropriate, interpolating between the existing value and the sampled value /// using the given `weight`. fn apply<'a>( &self, t: f32, transform: Option<Mut<'a, Transform>>, entity: EntityMutExcept<'a, (Transform, AnimationPlayer, Handle<AnimationGraph>)>, weight: f32, ) -> Result<(), AnimationEvaluationError>; } ``` 3. The conversion process from a `Curve` to an `AnimationCurve` involves using wrappers which communicate the intent to animate a particular property. For example, here is `TranslationCurve`, which wraps a `Curve<Vec3>` and uses it to animate `Transform::translation`: ```rust /// This type allows a curve valued in `Vec3` to become an [`AnimationCurve`] that animates /// the translation component of a transform. pub struct TranslationCurve<C>(pub C); ``` ### Animatable Properties The `AnimatableProperty` trait survives in the transition, and it can be used to allow curves to animate arbitrary component properties. The updated documentation for `AnimatableProperty` explains this process: <details> <summary>Expand AnimatableProperty example</summary An `AnimatableProperty` is a value on a component that Bevy can animate. You can implement this trait on a unit struct in order to support animating custom components other than transforms and morph weights. Use that type in conjunction with `AnimatableCurve` (and perhaps `AnimatableKeyframeCurve` to define the animation itself). For example, in order to animate font size of a text section from 24 pt. to 80 pt., you might use: ```rust #[derive(Reflect)] struct FontSizeProperty; impl AnimatableProperty for FontSizeProperty { type Component = Text; type Property = f32; fn get_mut(component: &mut Self::Component) -> Option<&mut Self::Property> { Some(&mut component.sections.get_mut(0)?.style.font_size) } } ``` You can then create an `AnimationClip` to animate this property like so: ```rust let mut animation_clip = AnimationClip::default(); animation_clip.add_curve_to_target( animation_target_id, AnimatableKeyframeCurve::new( [ (0.0, 24.0), (1.0, 80.0), ] ) .map(AnimatableCurve::<FontSizeProperty, _>::from_curve) .expect("Failed to create font size curve") ); ``` Here, the use of `AnimatableKeyframeCurve` creates a curve out of the given keyframe time-value pairs, using the `Animatable` implementation of `f32` to interpolate between them. The invocation of `AnimatableCurve::from_curve` with `FontSizeProperty` indicates that the `f32` output from that curve is to be used to animate the font size of a `Text` component (as configured above). </details> ### glTF Loading glTF animations are now loaded into `Curve` types of various kinds, depending on what is being animated and what interpolation mode is being used. Those types get wrapped into and converted into `Box<dyn AnimationCurve>` and shoved inside of a `VariableCurve` just like everybody else. ### Morph Weights There is an `IterableCurve` abstraction which allows sampling these from a contiguous buffer without allocating. Its only reason for existing is that Rust disallows you from naming function types, otherwise we would just use `Curve` with an iterator output type. (The iterator involves `Map`, and the name of the function type would have to be able to be named, but it is not.) A `WeightsCurve` adaptor turns an `IterableCurve` into an `AnimationCurve`, so it behaves like everything else in that regard. ## Testing Tested by running existing animation examples. Interpolation logic has had additional tests added within the `Curve` API to replace the tests in `bevy_animation`. Some kinds of out-of-bounds errors have become impossible. Performance testing on `many_foxes` (`animate_targets`) suggests that performance is very similar to the existing implementation. Here are a couple trace histograms across different runs (yellow is this branch, red is main). <img width="669" alt="Screenshot 2024-09-27 at 9 41 50 AM" src="https://github.com/user-attachments/assets/5ba4e9ac-3aea-452e-aaf8-1492acc2d7fc"> <img width="673" alt="Screenshot 2024-09-27 at 9 45 18 AM" src="https://github.com/user-attachments/assets/8982538b-04cf-46b5-97b2-164c6bc8162e"> --- ## Migration Guide Most user code that does not directly deal with `AnimationClip` and `VariableCurve` will not need to be changed. On the other hand, `VariableCurve` has been completely overhauled. If you were previously defining animation curves in code using keyframes, you will need to migrate that code to use curve constructors instead. For example, a rotation animation defined using keyframes and added to an animation clip like this: ```rust animation_clip.add_curve_to_target( animation_target_id, VariableCurve { keyframe_timestamps: vec![0.0, 1.0, 2.0, 3.0, 4.0], keyframes: Keyframes::Rotation(vec![ Quat::IDENTITY, Quat::from_axis_angle(Vec3::Y, PI / 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 3.), Quat::IDENTITY, ]), interpolation: Interpolation::Linear, }, ); ``` would now be added like this: ```rust animation_clip.add_curve_to_target( animation_target_id, AnimatableKeyframeCurve::new([0.0, 1.0, 2.0, 3.0, 4.0].into_iter().zip([ Quat::IDENTITY, Quat::from_axis_angle(Vec3::Y, PI / 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 2.), Quat::from_axis_angle(Vec3::Y, PI / 2. * 3.), Quat::IDENTITY, ])) .map(RotationCurve) .expect("Failed to build rotation curve"), ); ``` Note that the interface of `AnimationClip::add_curve_to_target` has also changed (as this example shows, if subtly), and now takes its curve input as an `impl AnimationCurve`. If you need to add a `VariableCurve` directly, a new method `add_variable_curve_to_target` accommodates that (and serves as a one-to-one migration in this regard). ### For reviewers The diff is pretty big, and the structure of some of the changes might not be super-obvious: - `keyframes.rs` became `animation_curves.rs`, and `AnimationCurve` is based heavily on `Keyframes`, with the adaptors also largely following suite. - The Curve API adaptor structs were moved from `bevy_math::curve::mod` into their own module `adaptors`. There are no functional changes to how these adaptors work; this is just to make room for the specialized reflection implementations since `mod.rs` was getting kind of cramped. - The new module `gltf_curves` holds the additional curve constructions that are needed by the glTF loader. Note that the loader uses a mix of these and off-the-shelf `bevy_math` curve stuff. - `animatable.rs` no longer holds logic related to keyframe interpolation, which is now delegated to the existing abstractions in `bevy_math::curve::cores`. --------- Co-authored-by: Gino Valente <49806985+MrGVSV@users.noreply.github.com> Co-authored-by: aecsocket <43144841+aecsocket@users.noreply.github.com>
2024-09-30 19:56:55 +00:00
AnimatableKeyframeCurve::new([0.0, 1.0, 2.0, 3.0].into_iter().zip([
Srgba::RED,
Srgba::GREEN,
Srgba::BLUE,
Srgba::RED,
]))
.map(AnimatableCurve::<TextColorProperty, _>::from_curve)
.expect("should be able to build translation curve because we pass in valid samples"),
Allow animation clips to animate arbitrary properties. (#15282) Currently, Bevy restricts animation clips to animating `Transform::translation`, `Transform::rotation`, `Transform::scale`, or `MorphWeights`, which correspond to the properties that glTF can animate. This is insufficient for many use cases such as animating UI, as the UI layout systems expect to have exclusive control over UI elements' `Transform`s and therefore the `Style` properties must be animated instead. This commit fixes this, allowing for `AnimationClip`s to animate arbitrary properties. The `Keyframes` structure has been turned into a low-level trait that can be implemented to achieve arbitrary animation behavior. Along with `Keyframes`, this patch adds a higher-level trait, `AnimatableProperty`, that simplifies the task of animating single interpolable properties. Built-in `Keyframes` implementations exist for translation, rotation, scale, and morph weights. For the most part, you can migrate by simply changing your code from `Keyframes::Translation(...)` to `TranslationKeyframes(...)`, and likewise for rotation, scale, and morph weights. An example `AnimatableProperty` implementation for the font size of a text section follows: #[derive(Reflect)] struct FontSizeProperty; impl AnimatableProperty for FontSizeProperty { type Component = Text; type Property = f32; fn get_mut(component: &mut Self::Component) -> Option<&mut Self::Property> { Some(&mut component.sections.get_mut(0)?.style.font_size) } } In order to keep this patch relatively small, this patch doesn't include an implementation of `AnimatableProperty` on top of the reflection system. That can be a follow-up. This patch builds on top of the new `EntityMutExcept<>` type in order to widen the `AnimationTarget` query to include write access to all components. Because `EntityMutExcept<>` has some performance overhead over an explicit query, we continue to explicitly query `Transform` in order to avoid regressing the performance of skeletal animation, such as the `many_foxes` benchmark. I've measured the performance of that benchmark and have found no significant regressions. A new example, `animated_ui`, has been added. This example shows how to use Bevy's built-in animation infrastructure to animate font size and color, which wasn't possible before this patch. ## Showcase https://github.com/user-attachments/assets/1fa73492-a9ce-405a-a8f2-4aacd7f6dc97 ## Migration Guide * Animation keyframes are now an extensible trait, not an enum. Replace `Keyframes::Translation(...)`, `Keyframes::Scale(...)`, `Keyframes::Rotation(...)`, and `Keyframes::Weights(...)` with `Box::new(TranslationKeyframes(...))`, `Box::new(ScaleKeyframes(...))`, `Box::new(RotationKeyframes(...))`, and `Box::new(MorphWeightsKeyframes(...))` respectively.
2024-09-23 17:14:12 +00:00
);
// 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,
}
}
}
// Creates all the entities in the scene.
fn setup(
mut commands: Commands,
asset_server: Res<AssetServer>,
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 UI animation.
let mut animation_player = AnimationPlayer::default();
animation_player.play(animation_node_index).repeat();
// Add a camera.
commands.spawn(Camera2d);
Allow animation clips to animate arbitrary properties. (#15282) Currently, Bevy restricts animation clips to animating `Transform::translation`, `Transform::rotation`, `Transform::scale`, or `MorphWeights`, which correspond to the properties that glTF can animate. This is insufficient for many use cases such as animating UI, as the UI layout systems expect to have exclusive control over UI elements' `Transform`s and therefore the `Style` properties must be animated instead. This commit fixes this, allowing for `AnimationClip`s to animate arbitrary properties. The `Keyframes` structure has been turned into a low-level trait that can be implemented to achieve arbitrary animation behavior. Along with `Keyframes`, this patch adds a higher-level trait, `AnimatableProperty`, that simplifies the task of animating single interpolable properties. Built-in `Keyframes` implementations exist for translation, rotation, scale, and morph weights. For the most part, you can migrate by simply changing your code from `Keyframes::Translation(...)` to `TranslationKeyframes(...)`, and likewise for rotation, scale, and morph weights. An example `AnimatableProperty` implementation for the font size of a text section follows: #[derive(Reflect)] struct FontSizeProperty; impl AnimatableProperty for FontSizeProperty { type Component = Text; type Property = f32; fn get_mut(component: &mut Self::Component) -> Option<&mut Self::Property> { Some(&mut component.sections.get_mut(0)?.style.font_size) } } In order to keep this patch relatively small, this patch doesn't include an implementation of `AnimatableProperty` on top of the reflection system. That can be a follow-up. This patch builds on top of the new `EntityMutExcept<>` type in order to widen the `AnimationTarget` query to include write access to all components. Because `EntityMutExcept<>` has some performance overhead over an explicit query, we continue to explicitly query `Transform` in order to avoid regressing the performance of skeletal animation, such as the `many_foxes` benchmark. I've measured the performance of that benchmark and have found no significant regressions. A new example, `animated_ui`, has been added. This example shows how to use Bevy's built-in animation infrastructure to animate font size and color, which wasn't possible before this patch. ## Showcase https://github.com/user-attachments/assets/1fa73492-a9ce-405a-a8f2-4aacd7f6dc97 ## Migration Guide * Animation keyframes are now an extensible trait, not an enum. Replace `Keyframes::Translation(...)`, `Keyframes::Scale(...)`, `Keyframes::Rotation(...)`, and `Keyframes::Weights(...)` with `Box::new(TranslationKeyframes(...))`, `Box::new(ScaleKeyframes(...))`, `Box::new(RotationKeyframes(...))`, and `Box::new(MorphWeightsKeyframes(...))` respectively.
2024-09-23 17:14:12 +00:00
// Build the UI. We have a parent node that covers the whole screen and
// contains the `AnimationPlayer`, as well as a child node that contains the
// text to be animated.
commands
.spawn(NodeBundle {
// Cover the whole screen, and center contents.
style: Style {
position_type: PositionType::Absolute,
top: Val::Px(0.0),
left: Val::Px(0.0),
right: Val::Px(0.0),
bottom: Val::Px(0.0),
justify_content: JustifyContent::Center,
align_items: AlignItems::Center,
..default()
},
..default()
})
.insert(animation_player)
.insert(animation_graph)
.with_children(|builder| {
// Build the text node.
let player = builder.parent_entity();
builder
.spawn(
TextBundle::from_section(
"Bevy",
TextStyle {
font: asset_server.load("fonts/FiraSans-Bold.ttf"),
font_size: 24.0,
color: Color::Srgba(Srgba::RED),
},
)
.with_text_justify(JustifyText::Center),
)
// Mark as an animation target.
.insert(AnimationTarget {
id: animation_target_id,
player,
})
.insert(animation_target_name);
});
}