Struct AnimatableCurve 

pub struct AnimatableCurve<P, C> {
    pub property: P,
    pub curve: C,
}

This type allows the conversion of a curve valued in the property type of an AnimatableProperty into an AnimationCurve which animates that property.

Fields

property: P

The property selector, which defines what component to access and how to access a property on that component.

curve: C

The inner curve whose values are used to animate the property.

Implementations

impl<P, C> AnimatableCurve<P, C>

where P: AnimatableProperty, C: AnimationCompatibleCurve<<P as AnimatableProperty>::Property>,

pub fn new(property: P, curve: C) -> AnimatableCurve<P, C>

Create an AnimatableCurve (and thus an AnimationCurve) from a curve valued in an animatable property.

Examples found in repository

examples/animation/animated_ui.rs (lines 50-60)

    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.
        animation_clip.add_curve_to_target(
            animation_target_id,
            AnimatableCurve::new(
                animated_field!(TextFont::font_size),
                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]),
                )
                .expect(
                    "should be able to build translation curve because we pass in valid samples",
                ),
            ),
        );

        // Create a curve that animates font color. Note that this should have
        // the same time duration as the previous curve.
        //
        // This time we use a "custom property", which in this case animates TextColor under the assumption
        // that it is in the "srgba" format.
        animation_clip.add_curve_to_target(
            animation_target_id,
            AnimatableCurve::new(
                TextColorProperty,
                AnimatableKeyframeCurve::new([0.0, 1.0, 2.0, 3.0].into_iter().zip([
                    Srgba::RED,
                    Srgba::GREEN,
                    Srgba::BLUE,
                    Srgba::RED,
                ]))
                .expect(
                    "should be able to build translation curve because we pass in valid samples",
                ),
            ),
        );

        // 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,
        }
    }

examples/animation/eased_motion.rs (line 132)

    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 = EasingCurve::new(
            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 = EasingCurve::new(
            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,
            AnimatableCurve::new(animated_field!(Transform::translation), translation_curve),
        );
        animation_clip.add_curve_to_target(
            animation_target_id,
            AnimatableCurve::new(animated_field!(Transform::rotation), 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,
        }
    }

examples/animation/animated_transform.rs (lines 56-68)

fn setup(
    mut commands: Commands,
    mut meshes: ResMut<Assets<Mesh>>,
    mut materials: ResMut<Assets<StandardMaterial>>,
    mut animations: ResMut<Assets<AnimationClip>>,
    mut graphs: ResMut<Assets<AnimationGraph>>,
) {
    // Camera
    commands.spawn((
        Camera3d::default(),
        Transform::from_xyz(-2.0, 2.5, 5.0).looking_at(Vec3::ZERO, Vec3::Y),
    ));

    // Light
    commands.spawn((
        PointLight {
            intensity: 500_000.0,
            ..default()
        },
        Transform::from_xyz(0.0, 2.5, 0.0),
    ));

    // Let's use the `Name` component to target entities. We can use anything we
    // like, but names are convenient.
    let planet = Name::new("planet");
    let orbit_controller = Name::new("orbit_controller");
    let satellite = Name::new("satellite");

    // Creating the animation
    let mut animation = AnimationClip::default();
    // A curve can modify a single part of a transform: here, the translation.
    let planet_animation_target_id = AnimationTargetId::from_name(&planet);
    animation.add_curve_to_target(
        planet_animation_target_id,
        AnimatableCurve::new(
            animated_field!(Transform::translation),
            UnevenSampleAutoCurve::new([0.0, 1.0, 2.0, 3.0, 4.0].into_iter().zip([
                Vec3::new(1.0, 0.0, 1.0),
                Vec3::new(-1.0, 0.0, 1.0),
                Vec3::new(-1.0, 0.0, -1.0),
                Vec3::new(1.0, 0.0, -1.0),
                // in case seamless looping is wanted, the last keyframe should
                // be the same as the first one
                Vec3::new(1.0, 0.0, 1.0),
            ]))
            .expect("should be able to build translation curve because we pass in valid samples"),
        ),
    );
    // Or it can modify the rotation of the transform.
    // To find the entity to modify, the hierarchy will be traversed looking for
    // an entity with the right name at each level.
    let orbit_controller_animation_target_id =
        AnimationTargetId::from_names([planet.clone(), orbit_controller.clone()].iter());
    animation.add_curve_to_target(
        orbit_controller_animation_target_id,
        AnimatableCurve::new(
            animated_field!(Transform::rotation),
            UnevenSampleAutoCurve::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,
            ]))
            .expect("Failed to build rotation curve"),
        ),
    );
    // If a curve in an animation is shorter than the other, it will not repeat
    // until all other curves are finished. In that case, another animation should
    // be created for each part that would have a different duration / period.
    let satellite_animation_target_id = AnimationTargetId::from_names(
        [planet.clone(), orbit_controller.clone(), satellite.clone()].iter(),
    );
    animation.add_curve_to_target(
        satellite_animation_target_id,
        AnimatableCurve::new(
            animated_field!(Transform::scale),
            UnevenSampleAutoCurve::new(
                [0.0, 0.5, 1.0, 1.5, 2.0, 2.5, 3.0, 3.5, 4.0]
                    .into_iter()
                    .zip([
                        Vec3::splat(0.8),
                        Vec3::splat(1.2),
                        Vec3::splat(0.8),
                        Vec3::splat(1.2),
                        Vec3::splat(0.8),
                        Vec3::splat(1.2),
                        Vec3::splat(0.8),
                        Vec3::splat(1.2),
                        Vec3::splat(0.8),
                    ]),
            )
            .expect("Failed to build scale curve"),
        ),
    );
    // There can be more than one curve targeting the same entity path.
    animation.add_curve_to_target(
        AnimationTargetId::from_names(
            [planet.clone(), orbit_controller.clone(), satellite.clone()].iter(),
        ),
        AnimatableCurve::new(
            animated_field!(Transform::rotation),
            UnevenSampleAutoCurve::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,
            ]))
            .expect("should be able to build translation curve because we pass in valid samples"),
        ),
    );

    // Create the animation graph
    let (graph, animation_index) = AnimationGraph::from_clip(animations.add(animation));

    // Create the animation player, and set it to repeat
    let mut player = AnimationPlayer::default();
    player.play(animation_index).repeat();

    // Create the scene that will be animated
    // First entity is the planet
    let planet_entity = commands
        .spawn((
            Mesh3d(meshes.add(Sphere::default())),
            MeshMaterial3d(materials.add(Color::srgb(0.8, 0.7, 0.6))),
            // Add the animation graph and player
            planet,
            AnimationGraphHandle(graphs.add(graph)),
            player,
        ))
        .id();
    commands.entity(planet_entity).insert((
        AnimationTarget {
            id: planet_animation_target_id,
            player: planet_entity,
        },
        children![(
            Transform::default(),
            Visibility::default(),
            orbit_controller,
            AnimationTarget {
                id: orbit_controller_animation_target_id,
                player: planet_entity,
            },
            children![(
                Mesh3d(meshes.add(Cuboid::new(0.5, 0.5, 0.5))),
                MeshMaterial3d(materials.add(Color::srgb(0.3, 0.9, 0.3))),
                Transform::from_xyz(1.5, 0.0, 0.0),
                AnimationTarget {
                    id: satellite_animation_target_id,
                    player: planet_entity,
                },
                satellite,
            )],
        )],
    ));
}

Trait Implementations

impl<P, C> AnimationCurve for AnimatableCurve<P, C>

where P: Send + Sync + 'static + AnimatableProperty + Clone, C: AnimationCompatibleCurve<<P as AnimatableProperty>::Property> + Clone,

fn clone_value(&self) -> Box<dyn AnimationCurve>

Returns a boxed clone of this value.

fn domain(&self) -> Interval

The range of times for which this animation is defined.

fn evaluator_id(&self) -> EvaluatorId<'_>

Returns the type ID of the AnimationCurveEvaluator.

fn create_evaluator(&self) -> Box<dyn AnimationCurveEvaluator>

Returns a newly-instantiated AnimationCurveEvaluator for use with this curve.

fn apply( &self, curve_evaluator: &mut (dyn AnimationCurveEvaluator + 'static), t: f32, weight: f32, graph_node: NodeIndex, ) -> Result<(), AnimationEvaluationError>

Samples the curve at the given time t, and pushes the sampled value onto the evaluation stack of the curve_evaluator.

impl<P, C> Clone for AnimatableCurve<P, C>

where C: Clone, P: Clone,

fn clone(&self) -> AnimatableCurve<P, C>

Returns a duplicate of the value.

fn clone_from(&mut self, source: &Self)

Performs copy-assignment from source.

impl<P, C> Debug for AnimatableCurve<P, C>

where C: Debug,

fn fmt(&self, f: &mut Formatter<'_>) -> Result<(), Error>

Formats the value using the given formatter.

impl<P, C> FromArg for AnimatableCurve<P, C>

where AnimatableCurve<P, C>: Any + Send + Sync, P: TypePath + PartialReflect + MaybeTyped + RegisterForReflection, C: TypePath + PartialReflect + MaybeTyped + RegisterForReflection,

type This<'from_arg> = AnimatableCurve<P, C>

The type to convert into.

fn from_arg( arg: Arg<'_>, ) -> Result<<AnimatableCurve<P, C> as FromArg>::This<'_>, ArgError>

Creates an item from an argument.

impl<P, C> FromReflect for AnimatableCurve<P, C>

where AnimatableCurve<P, C>: Any + Send + Sync, P: TypePath + FromReflect + MaybeTyped + RegisterForReflection, C: TypePath + FromReflect + MaybeTyped + RegisterForReflection,

fn from_reflect( reflect: &(dyn PartialReflect + 'static), ) -> Option<AnimatableCurve<P, C>>

Constructs a concrete instance of Self from a reflected value.

fn take_from_reflect( reflect: Box<dyn PartialReflect>, ) -> Result<Self, Box<dyn PartialReflect>>

Attempts to downcast the given value to Self using, constructing the value using from_reflect if that fails.

impl<P, C> GetOwnership for AnimatableCurve<P, C>

where AnimatableCurve<P, C>: Any + Send + Sync, P: TypePath + PartialReflect + MaybeTyped + RegisterForReflection, C: TypePath + PartialReflect + MaybeTyped + RegisterForReflection,

fn ownership() -> Ownership

Returns the ownership of Self.

impl<P, C> GetTypeRegistration for AnimatableCurve<P, C>

where AnimatableCurve<P, C>: Any + Send + Sync, P: TypePath + PartialReflect + MaybeTyped + RegisterForReflection, C: TypePath + PartialReflect + MaybeTyped + RegisterForReflection,

fn get_type_registration() -> TypeRegistration

Returns the default TypeRegistration for this type.

fn register_type_dependencies(registry: &mut TypeRegistry)

Registers other types needed by this type.

impl<P, C> IntoReturn for AnimatableCurve<P, C>

where AnimatableCurve<P, C>: Any + Send + Sync, P: TypePath + PartialReflect + MaybeTyped + RegisterForReflection, C: TypePath + PartialReflect + MaybeTyped + RegisterForReflection,

fn into_return<'into_return>(self) -> Return<'into_return>

where AnimatableCurve<P, C>: 'into_return,

Converts Self into a Return value.

impl<P, C> PartialReflect for AnimatableCurve<P, C>

where AnimatableCurve<P, C>: Any + Send + Sync, P: TypePath + PartialReflect + MaybeTyped + RegisterForReflection, C: TypePath + PartialReflect + MaybeTyped + RegisterForReflection,

fn get_represented_type_info(&self) -> Option<&'static TypeInfo>

Returns the TypeInfo of the type represented by this value.

fn try_apply( &mut self, value: &(dyn PartialReflect + 'static), ) -> Result<(), ApplyError>

Tries to apply a reflected value to this value.

fn reflect_kind(&self) -> ReflectKind

Returns a zero-sized enumeration of “kinds” of type.

fn reflect_ref(&self) -> ReflectRef<'_>

Returns an immutable enumeration of “kinds” of type.

fn reflect_mut(&mut self) -> ReflectMut<'_>

Returns a mutable enumeration of “kinds” of type.

fn reflect_owned(self: Box<AnimatableCurve<P, C>>) -> ReflectOwned

Returns an owned enumeration of “kinds” of type.

fn try_into_reflect( self: Box<AnimatableCurve<P, C>>, ) -> Result<Box<dyn Reflect>, Box<dyn PartialReflect>>

Attempts to cast this type to a boxed, fully-reflected value.

fn try_as_reflect(&self) -> Option<&(dyn Reflect + 'static)>

Attempts to cast this type to a fully-reflected value.

fn try_as_reflect_mut(&mut self) -> Option<&mut (dyn Reflect + 'static)>

Attempts to cast this type to a mutable, fully-reflected value.

fn into_partial_reflect( self: Box<AnimatableCurve<P, C>>, ) -> Box<dyn PartialReflect>

Casts this type to a boxed, reflected value.

fn as_partial_reflect(&self) -> &(dyn PartialReflect + 'static)

Casts this type to a reflected value.

fn as_partial_reflect_mut(&mut self) -> &mut (dyn PartialReflect + 'static)

Casts this type to a mutable, reflected value.

fn reflect_partial_eq( &self, value: &(dyn PartialReflect + 'static), ) -> Option<bool>

Returns a “partial equality” comparison result.

fn reflect_clone(&self) -> Result<Box<dyn Reflect>, ReflectCloneError>

Attempts to clone Self using reflection.

fn apply(&mut self, value: &(dyn PartialReflect + 'static))

Applies a reflected value to this value.

fn to_dynamic(&self) -> Box<dyn PartialReflect>

Converts this reflected value into its dynamic representation based on its kind.

fn reflect_clone_and_take<T>(&self) -> Result<T, ReflectCloneError>

where T: 'static, Self: Sized + TypePath,

For a type implementing PartialReflect, combines reflect_clone and take in a useful fashion, automatically constructing an appropriate ReflectCloneError if the downcast fails.

fn reflect_hash(&self) -> Option<u64>

Returns a hash of the value (which includes the type).

fn debug(&self, f: &mut Formatter<'_>) -> Result<(), Error>

Debug formatter for the value.

fn is_dynamic(&self) -> bool

Indicates whether or not this type is a dynamic type.

impl<P, C> Reflect for AnimatableCurve<P, C>

where AnimatableCurve<P, C>: Any + Send + Sync, P: TypePath + PartialReflect + MaybeTyped + RegisterForReflection, C: TypePath + PartialReflect + MaybeTyped + RegisterForReflection,

fn into_any(self: Box<AnimatableCurve<P, C>>) -> Box<dyn Any>

Returns the value as a Box<dyn Any>.

fn as_any(&self) -> &(dyn Any + 'static)

Returns the value as a &dyn Any.

fn as_any_mut(&mut self) -> &mut (dyn Any + 'static)

Returns the value as a &mut dyn Any.

fn into_reflect(self: Box<AnimatableCurve<P, C>>) -> Box<dyn Reflect>

Casts this type to a boxed, fully-reflected value.

fn as_reflect(&self) -> &(dyn Reflect + 'static)

Casts this type to a fully-reflected value.

fn as_reflect_mut(&mut self) -> &mut (dyn Reflect + 'static)

Casts this type to a mutable, fully-reflected value.

fn set(&mut self, value: Box<dyn Reflect>) -> Result<(), Box<dyn Reflect>>

Performs a type-checked assignment of a reflected value to this value.

impl<P, C> Struct for AnimatableCurve<P, C>

where AnimatableCurve<P, C>: Any + Send + Sync, P: TypePath + PartialReflect + MaybeTyped + RegisterForReflection, C: TypePath + PartialReflect + MaybeTyped + RegisterForReflection,

fn field(&self, name: &str) -> Option<&(dyn PartialReflect + 'static)>

Returns a reference to the value of the field named name as a &dyn PartialReflect.

fn field_mut( &mut self, name: &str, ) -> Option<&mut (dyn PartialReflect + 'static)>

Returns a mutable reference to the value of the field named name as a &mut dyn PartialReflect.

fn field_at(&self, index: usize) -> Option<&(dyn PartialReflect + 'static)>

Returns a reference to the value of the field with index index as a &dyn PartialReflect.

fn field_at_mut( &mut self, index: usize, ) -> Option<&mut (dyn PartialReflect + 'static)>

Returns a mutable reference to the value of the field with index index as a &mut dyn PartialReflect.

fn name_at(&self, index: usize) -> Option<&str>

Returns the name of the field with index index.

fn field_len(&self) -> usize

Returns the number of fields in the struct.

fn iter_fields(&self) -> FieldIter<'_>

Returns an iterator over the values of the reflectable fields for this struct.

fn to_dynamic_struct(&self) -> DynamicStruct

Creates a new DynamicStruct from this struct.

fn get_represented_struct_info(&self) -> Option<&'static StructInfo>

Will return None if TypeInfo is not available.

impl<P, C> TypePath for AnimatableCurve<P, C>

where AnimatableCurve<P, C>: Any + Send + Sync, P: TypePath, C: TypePath,

fn type_path() -> &'static str

Returns the fully qualified path of the underlying type.

fn short_type_path() -> &'static str

Returns a short, pretty-print enabled path to the type.

fn type_ident() -> Option<&'static str>

Returns the name of the type, or None if it is anonymous.

fn crate_name() -> Option<&'static str>

Returns the name of the crate the type is in, or None if it is anonymous.

fn module_path() -> Option<&'static str>

Returns the path to the module the type is in, or None if it is anonymous.

impl<P, C> Typed for AnimatableCurve<P, C>

where AnimatableCurve<P, C>: Any + Send + Sync, P: TypePath + PartialReflect + MaybeTyped + RegisterForReflection, C: TypePath + PartialReflect + MaybeTyped + RegisterForReflection,

fn type_info() -> &'static TypeInfo

Returns the compile-time info for the underlying type.