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Add Beziers to bevy_math
(#7653)
# Objective - Adds foundational math for Bezier curves, useful for UI/2D/3D animation and smooth paths. https://user-images.githubusercontent.com/2632925/218883143-e138f994-1795-40da-8c59-21d779666991.mp4 ## Solution - Adds the generic `Bezier` type, and a `Point` trait. The `Point` trait allows us to use control points of any dimension, as long as they support vector math. I've implemented it for `f32`(1D), `Vec2`(2D), and `Vec3`/`Vec3A`(3D). - Adds `CubicBezierEasing` on top of `Bezier` with the addition of an implementation of cubic Bezier easing, which is a foundational tool for UI animation. - This involves solving for $t$ in the parametric Bezier function $B(t)$ using the Newton-Raphson method to find a value with error $\leq$ 1e-7, capped at 8 iterations. - Added type aliases for common Bezier curves: `CubicBezier2d`, `CubicBezier3d`, `QuadraticBezier2d`, and `QuadraticBezier3d`. These types use `Vec3A` to represent control points, as this was found to have an 80-90% speedup over using `Vec3`. - Benchmarking shows quadratic/cubic Bezier evaluations $B(t)$ take \~1.8/2.4ns respectively. Easing, which requires an iterative solve takes \~50ns for cubic Beziers. --- ## Changelog - Added `CubicBezier2d`, `CubicBezier3d`, `QuadraticBezier2d`, and `QuadraticBezier3d` types with methods for sampling position, velocity, and acceleration. The generic `Bezier` type is also available, and generic over any degree of Bezier curve. - Added `CubicBezierEasing`, with additional methods to allow for smooth easing animations.
This commit is contained in:
parent
0c98f9a225
commit
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4 changed files with 600 additions and 2 deletions
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@ -16,6 +16,7 @@ bevy_ecs = { path = "../crates/bevy_ecs" }
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bevy_reflect = { path = "../crates/bevy_reflect" }
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bevy_tasks = { path = "../crates/bevy_tasks" }
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bevy_utils = { path = "../crates/bevy_utils" }
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bevy_math = { path = "../crates/bevy_math" }
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[profile.release]
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opt-level = 3
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@ -50,3 +51,8 @@ harness = false
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name = "iter"
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path = "benches/bevy_tasks/iter.rs"
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harness = false
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[[bench]]
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name = "bezier"
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path = "benches/bevy_math/bezier.rs"
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harness = false
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129
benches/benches/bevy_math/bezier.rs
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129
benches/benches/bevy_math/bezier.rs
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@ -0,0 +1,129 @@
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use criterion::{black_box, criterion_group, criterion_main, Criterion};
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use bevy_math::*;
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fn easing(c: &mut Criterion) {
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let cubic_bezier = CubicBezierEasing::new(vec2(0.25, 0.1), vec2(0.25, 1.0));
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c.bench_function("easing_1000", |b| {
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b.iter(|| {
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(0..1000).map(|i| i as f32 / 1000.0).for_each(|t| {
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cubic_bezier.ease(black_box(t));
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})
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});
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});
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}
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fn fifteen_degree(c: &mut Criterion) {
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let bezier = Bezier::<Vec3A, 16>::new([
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[0.0, 0.0, 0.0],
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[0.0, 1.0, 0.0],
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[1.0, 0.0, 0.0],
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[1.0, 1.0, 1.0],
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[0.0, 0.0, 0.0],
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[0.0, 1.0, 0.0],
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[1.0, 0.0, 0.0],
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[1.0, 1.0, 1.0],
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[0.0, 0.0, 0.0],
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[0.0, 1.0, 0.0],
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[1.0, 0.0, 0.0],
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[1.0, 1.0, 1.0],
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[0.0, 0.0, 0.0],
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[0.0, 1.0, 0.0],
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[1.0, 0.0, 0.0],
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[1.0, 1.0, 1.0],
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]);
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c.bench_function("fifteen_degree_position", |b| {
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b.iter(|| bezier.position(black_box(0.5)));
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});
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}
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fn quadratic_2d(c: &mut Criterion) {
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let bezier = QuadraticBezier2d::new([[0.0, 0.0], [0.0, 1.0], [1.0, 1.0]]);
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c.bench_function("quadratic_position_Vec2", |b| {
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b.iter(|| bezier.position(black_box(0.5)));
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});
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}
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fn quadratic(c: &mut Criterion) {
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let bezier = QuadraticBezier3d::new([[0.0, 0.0, 0.0], [0.0, 1.0, 0.0], [1.0, 1.0, 1.0]]);
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c.bench_function("quadratic_position_Vec3A", |b| {
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b.iter(|| bezier.position(black_box(0.5)));
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});
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}
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fn quadratic_vec3(c: &mut Criterion) {
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let bezier = Bezier::<Vec3, 3>::new([[0.0, 0.0, 0.0], [0.0, 1.0, 0.0], [1.0, 1.0, 1.0]]);
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c.bench_function("quadratic_position_Vec3", |b| {
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b.iter(|| bezier.position(black_box(0.5)));
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});
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}
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fn cubic_2d(c: &mut Criterion) {
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let bezier = CubicBezier2d::new([[0.0, 0.0], [0.0, 1.0], [1.0, 0.0], [1.0, 1.0]]);
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c.bench_function("cubic_position_Vec2", |b| {
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b.iter(|| bezier.position(black_box(0.5)));
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});
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}
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fn cubic(c: &mut Criterion) {
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let bezier = CubicBezier3d::new([
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[0.0, 0.0, 0.0],
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[0.0, 1.0, 0.0],
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[1.0, 0.0, 0.0],
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[1.0, 1.0, 1.0],
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]);
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c.bench_function("cubic_position_Vec3A", |b| {
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b.iter(|| bezier.position(black_box(0.5)));
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});
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}
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fn cubic_vec3(c: &mut Criterion) {
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let bezier = Bezier::<Vec3, 4>::new([
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[0.0, 0.0, 0.0],
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[0.0, 1.0, 0.0],
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[1.0, 0.0, 0.0],
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[1.0, 1.0, 1.0],
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]);
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c.bench_function("cubic_position_Vec3", |b| {
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b.iter(|| bezier.position(black_box(0.5)));
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});
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}
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fn build_pos_cubic(c: &mut Criterion) {
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let bezier = CubicBezier3d::new([
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[0.0, 0.0, 0.0],
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[0.0, 1.0, 0.0],
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[1.0, 0.0, 0.0],
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[1.0, 1.0, 1.0],
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]);
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c.bench_function("build_pos_cubic_100_points", |b| {
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b.iter(|| bezier.iter_positions(black_box(100)).collect::<Vec<_>>());
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});
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}
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fn build_accel_cubic(c: &mut Criterion) {
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let bezier = CubicBezier3d::new([
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[0.0, 0.0, 0.0],
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[0.0, 1.0, 0.0],
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[1.0, 0.0, 0.0],
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[1.0, 1.0, 1.0],
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]);
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c.bench_function("build_accel_cubic_100_points", |b| {
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b.iter(|| bezier.iter_positions(black_box(100)).collect::<Vec<_>>());
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});
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}
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criterion_group!(
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benches,
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easing,
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fifteen_degree,
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quadratic_2d,
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quadratic,
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quadratic_vec3,
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cubic_2d,
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cubic,
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cubic_vec3,
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build_pos_cubic,
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build_accel_cubic,
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);
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criterion_main!(benches);
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457
crates/bevy_math/src/bezier.rs
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457
crates/bevy_math/src/bezier.rs
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@ -0,0 +1,457 @@
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use glam::{Vec2, Vec3, Vec3A};
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use std::{
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fmt::Debug,
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iter::Sum,
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ops::{Add, Mul, Sub},
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};
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/// A point in space of any dimension that supports the mathematical operations needed by
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/// [`Bezier`].
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pub trait Point:
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Mul<f32, Output = Self>
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+ Add<Self, Output = Self>
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+ Sub<Self, Output = Self>
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+ Sum
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+ Default
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+ Debug
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+ Clone
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+ PartialEq
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+ Copy
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{
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}
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impl Point for Vec3 {} // 3D
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impl Point for Vec3A {} // 3D
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impl Point for Vec2 {} // 2D
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impl Point for f32 {} // 1D
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/// A cubic Bezier curve in 2D space
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pub type CubicBezier2d = Bezier<Vec2, 4>;
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/// A cubic Bezier curve in 3D space
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pub type CubicBezier3d = Bezier<Vec3A, 4>;
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/// A quadratic Bezier curve in 2D space
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pub type QuadraticBezier2d = Bezier<Vec2, 3>;
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/// A quadratic Bezier curve in 3D space
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pub type QuadraticBezier3d = Bezier<Vec3A, 3>;
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/// A generic Bezier curve with `N` control points, and dimension defined by `P`.
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///
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/// Consider the following type aliases for most common uses:
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/// - [`CubicBezier2d`]
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/// - [`CubicBezier3d`]
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/// - [`QuadraticBezier2d`]
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/// - [`QuadraticBezier3d`]
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///
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/// The Bezier degree is equal to `N - 1`. For example, a cubic Bezier has 4 control points, and a
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/// degree of 3. The time-complexity of evaluating a Bezier increases superlinearly with the number
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/// of control points. As such, it is recommended to instead use a chain of quadratic or cubic
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/// `Beziers` instead of a high-degree Bezier.
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///
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/// ### About Bezier curves
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///
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/// `Bezier` curves are parametric implicit functions; all that means is they take a parameter `t`,
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/// and output a point in space, like:
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///
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/// > B(t) = (x, y, z)
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///
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/// So, all that is needed to find a point in space along a Bezier curve is the parameter `t`.
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/// Additionally, the values of `t` are straightforward: `t` is 0 at the start of the curve (first
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/// control point) and 1 at the end (last control point).
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///
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/// ```
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/// # use bevy_math::{Bezier, Vec2, vec2};
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/// let p0 = vec2(0.25, 0.1);
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/// let p1 = vec2(0.25, 1.0);
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/// let bezier = Bezier::<Vec2, 2>::new([p0, p1]);
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/// assert_eq!(bezier.position(0.0), p0);
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/// assert_eq!(bezier.position(1.0), p1);
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/// ```
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///
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/// ### Plotting
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///
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/// To plot a Bezier curve, simply plug in a series of values of `t` from zero to one. The functions
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/// to do this are [`Bezier::position`] to sample the curve at a value of `t`, and
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/// [`Bezier::iter_positions`] to iterate over the curve with a number of subdivisions.
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///
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/// ### Velocity and Acceleration
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///
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/// In addition to the position of a point on the Bezier curve, it is also useful to get information
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/// about the curvature. Methods are provided to help with this:
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///
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/// - [`Bezier::velocity`]: the instantaneous velocity vector with respect to `t`. This is a vector
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/// that points in the direction a point is traveling when it is at point `t`. This vector is
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/// tangent to the curve.
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/// - [`Bezier::acceleration`]: the instantaneous acceleration vector with respect to `t`. This is a
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/// vector that points in the direction a point is accelerating towards when it is at point
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/// `t`. This vector will point to the inside of turns, the direction the point is being
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/// pulled toward to change direction.
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#[derive(Clone, Copy, Debug, PartialEq)]
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pub struct Bezier<P: Point, const N: usize>(pub [P; N]);
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impl<P: Point, const N: usize> Default for Bezier<P, N> {
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fn default() -> Self {
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Bezier([P::default(); N])
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}
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}
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impl<P: Point, const N: usize> Bezier<P, N> {
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/// Construct a new Bezier curve.
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pub fn new(control_points: [impl Into<P>; N]) -> Self {
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let control_points = control_points.map(|v| v.into());
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Self(control_points)
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}
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/// Compute the position of a point along the Bezier curve at the supplied parametric value `t`.
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pub fn position(&self, t: f32) -> P {
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generic::position(self.0, t)
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}
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/// Compute the first derivative B'(t) of this Bezier at `t` with respect to t. This is the
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/// instantaneous velocity of a point on the Bezier curve at `t`.
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pub fn velocity(&self, t: f32) -> P {
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generic::velocity(self.0, t)
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}
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/// Compute the second derivative B''(t) of this Bezier at `t` with respect to t. This is the
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/// instantaneous acceleration of a point on the Bezier curve at `t`.
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pub fn acceleration(&self, t: f32) -> P {
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generic::acceleration(self.0, t)
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}
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/// A flexible iterator used to sample [`Bezier`] curves with arbitrary functions.
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///
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/// This splits the Bezier into `subdivisions` of evenly spaced `t` values across the length of
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/// the curve from start (t = 0) to end (t = 1), returning an iterator that evaluates the curve
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/// with the supplied `sample_function` at each `t`.
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///
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/// Given `subdivisions = 2`, this will split the curve into two lines, or three points, and
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/// return an iterator over those three points, one at the start, middle, and end.
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#[inline]
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pub fn iter_samples(
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&self,
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subdivisions: usize,
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sample_function: fn(&Self, f32) -> P,
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) -> impl Iterator<Item = P> + '_ {
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(0..=subdivisions).map(move |i| {
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let t = i as f32 / subdivisions as f32;
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sample_function(self, t)
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})
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}
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/// Iterate over the curve split into `subdivisions`, sampling the position at each step.
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pub fn iter_positions(&self, subdivisions: usize) -> impl Iterator<Item = P> + '_ {
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self.iter_samples(subdivisions, Self::position)
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}
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/// Iterate over the curve split into `subdivisions`, sampling the velocity at each step.
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pub fn iter_velocities(&self, subdivisions: usize) -> impl Iterator<Item = P> + '_ {
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self.iter_samples(subdivisions, Self::velocity)
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}
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/// Iterate over the curve split into `subdivisions`, sampling the acceleration at each step.
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pub fn iter_accelerations(&self, subdivisions: usize) -> impl Iterator<Item = P> + '_ {
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self.iter_samples(subdivisions, Self::acceleration)
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}
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}
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impl<T: Into<P>, P: Point, const N: usize> From<[T; N]> for Bezier<P, N> {
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fn from(control_points: [T; N]) -> Self {
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Bezier::new(control_points)
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}
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}
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/// A 2-dimensional Bezier curve used for easing in animation.
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///
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/// A cubic Bezier easing curve has control point `p0` at (0, 0) and `p3` at (1, 1), leaving only
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/// `p1` and `p2` as the remaining degrees of freedom. The first and last control points are fixed
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/// to ensure the animation begins at 0, and ends at 1.
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#[derive(Default, Clone, Copy, Debug, PartialEq)]
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pub struct CubicBezierEasing {
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/// Control point P1 of the 2D cubic Bezier curve. Controls the start of the animation.
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pub p1: Vec2,
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/// Control point P2 of the 2D cubic Bezier curve. Controls the end of the animation.
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pub p2: Vec2,
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}
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impl CubicBezierEasing {
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/// Construct a cubic Bezier curve for animation easing, with control points `p1` and `p2`.
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/// These correspond to the two free "handles" of the Bezier curve.
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///
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/// This is a very common tool for animations that accelerate and decelerate smoothly. For
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/// example, the ubiquitous "ease-in-out" is defined as `(0.25, 0.1), (0.25, 1.0)`.
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pub fn new(p1: impl Into<Vec2>, p2: impl Into<Vec2>) -> Self {
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Self {
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p1: p1.into(),
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p2: p2.into(),
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}
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}
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/// Maximum allowable error for iterative Bezier solve
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const MAX_ERROR: f32 = 1e-5;
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/// Maximum number of iterations during Bezier solve
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const MAX_ITERS: u8 = 8;
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/// Given a `time` within `0..=1`, returns an eased value that follows the cubic Bezier curve
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/// instead of a straight line. This eased result may be outside the range `0..=1`, however it
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/// will always start at 0 and end at 1: `ease(0) = 0` and `ease(1) = 1`.
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///
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/// ```
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/// # use bevy_math::CubicBezierEasing;
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/// let cubic_bezier = CubicBezierEasing::new((0.25, 0.1), (0.25, 1.0));
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/// assert_eq!(cubic_bezier.ease(0.0), 0.0);
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/// assert_eq!(cubic_bezier.ease(1.0), 1.0);
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/// ```
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///
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/// # How cubic Bezier easing works
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///
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/// Easing is generally accomplished with the help of "shaping functions". These are curves that
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/// start at (0,0) and end at (1,1). The x-axis of this plot is the current `time` of the
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/// animation, from 0 to 1. The y-axis is how far along the animation is, also from 0 to 1. You
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/// can imagine that if the shaping function is a straight line, there is a 1:1 mapping between
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/// the `time` and how far along your animation is. If the `time` = 0.5, the animation is
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/// halfway through. This is known as linear interpolation, and results in objects animating
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/// with a constant velocity, and no smooth acceleration or deceleration at the start or end.
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///
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/// ```text
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/// y
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/// │ ●
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/// │ ⬈
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/// │ ⬈
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/// │ ⬈
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/// │ ⬈
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/// ●─────────── x (time)
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/// ```
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///
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/// Using cubic Beziers, we have a curve that starts at (0,0), ends at (1,1), and follows a path
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/// determined by the two remaining control points (handles). These handles allow us to define a
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/// smooth curve. As `time` (x-axis) progresses, we now follow the curve, and use the `y` value
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/// to determine how far along the animation is.
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///
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/// ```text
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/// y
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||||
/// ⬈➔●
|
||||
/// │ ⬈
|
||||
/// │ ↑
|
||||
/// │ ↑
|
||||
/// │ ⬈
|
||||
/// ●➔⬈───────── x (time)
|
||||
/// ```
|
||||
///
|
||||
/// To accomplish this, we need to be able to find the position `y` on a Bezier curve, given the
|
||||
/// `x` value. As discussed in the [`Bezier`] documentation, a Bezier curve is an implicit
|
||||
/// parametric function like B(t) = (x,y). To find `y`, we first solve for `t` that corresponds
|
||||
/// to the given `x` (`time`). We use the Newton-Raphson root-finding method to quickly find a
|
||||
/// value of `t` that matches `x`. Once we have this we can easily plug that `t` into our
|
||||
/// Bezier's `position` function, to find the `y` component, which is how far along our
|
||||
/// animation should be. In other words:
|
||||
///
|
||||
/// > Given `time` in `0..=1`
|
||||
///
|
||||
/// > Use Newton's method to find a value of `t` that results in B(t) = (x,y) where `x == time`
|
||||
///
|
||||
/// > Once a solution is found, use the resulting `y` value as the final result
|
||||
///
|
||||
/// # Performance
|
||||
///
|
||||
/// This operation can be used frequently without fear of performance issues. Benchmarks show
|
||||
/// this operation taking on the order of 50 nanoseconds.
|
||||
pub fn ease(&self, time: f32) -> f32 {
|
||||
let x = time.clamp(0.0, 1.0);
|
||||
let t = self.find_t_given_x(x);
|
||||
self.evaluate_y_at(t)
|
||||
}
|
||||
|
||||
/// Compute the x-coordinate of the point along the Bezier curve at `t`.
|
||||
#[inline]
|
||||
fn evaluate_x_at(&self, t: f32) -> f32 {
|
||||
generic::position([0.0, self.p1.x, self.p2.x, 1.0], t)
|
||||
}
|
||||
|
||||
/// Compute the y-coordinate of the point along the Bezier curve at `t`.
|
||||
#[inline]
|
||||
fn evaluate_y_at(&self, t: f32) -> f32 {
|
||||
generic::position([0.0, self.p1.y, self.p2.y, 1.0], t)
|
||||
}
|
||||
|
||||
/// Compute the slope of the line at the given parametric value `t` with respect to t.
|
||||
#[inline]
|
||||
fn dx_dt(&self, t: f32) -> f32 {
|
||||
generic::velocity([0.0, self.p1.x, self.p2.x, 1.0], t)
|
||||
}
|
||||
|
||||
/// Solve for the parametric value `t` that corresponds to the given value of `x` using the
|
||||
/// Newton-Raphson method. See documentation on [`Self::ease`] for more details.
|
||||
#[inline]
|
||||
fn find_t_given_x(&self, x: f32) -> f32 {
|
||||
// PERFORMANCE NOTE:
|
||||
//
|
||||
// I tried pre-solving and caching values along the curve at struct instantiation to give
|
||||
// the solver a better starting guess. This ended up being slightly slower, possibly due to
|
||||
// the increased size of the type. Another option would be to store the last `t`, and use
|
||||
// that, however it's possible this could end up in a bad state where t is very far from the
|
||||
// naive but generally safe guess of x, e.g. after an animation resets.
|
||||
//
|
||||
// Further optimization might not be needed however - benchmarks are showing it takes about
|
||||
// 50 nanoseconds for an ease operation on my modern laptop, which seems sufficiently fast.
|
||||
let mut t_guess = x;
|
||||
for _ in 0..Self::MAX_ITERS {
|
||||
let x_guess = self.evaluate_x_at(t_guess);
|
||||
let error = x_guess - x;
|
||||
if error.abs() <= Self::MAX_ERROR {
|
||||
break;
|
||||
}
|
||||
// Using Newton's method, use the tangent line to estimate a better guess value.
|
||||
let slope = self.dx_dt(t_guess);
|
||||
t_guess -= error / slope;
|
||||
}
|
||||
t_guess.clamp(0.0, 1.0)
|
||||
}
|
||||
}
|
||||
|
||||
impl<P: Into<Vec2>> From<[P; 2]> for CubicBezierEasing {
|
||||
fn from(points: [P; 2]) -> Self {
|
||||
let [p0, p1] = points;
|
||||
CubicBezierEasing::new(p0, p1)
|
||||
}
|
||||
}
|
||||
|
||||
/// Generic implementations for sampling Bezier curves. Consider using the methods on
|
||||
/// [`Bezier`](crate::Bezier) for more ergonomic use.
|
||||
pub mod generic {
|
||||
use super::Point;
|
||||
|
||||
/// Compute the Bernstein basis polynomial `i` of degree `n`, at `t`.
|
||||
///
|
||||
/// For more information, see <https://en.wikipedia.org/wiki/Bernstein_polynomial>.
|
||||
#[inline]
|
||||
pub fn bernstein_basis(n: usize, i: usize, t: f32) -> f32 {
|
||||
(1. - t).powi((n - i) as i32) * t.powi(i as i32)
|
||||
}
|
||||
|
||||
/// Efficiently compute the binomial coefficient of `n` choose `k`.
|
||||
#[inline]
|
||||
fn binomial_coeff(n: usize, k: usize) -> usize {
|
||||
let k = usize::min(k, n - k);
|
||||
(0..k).fold(1, |val, i| val * (n - i) / (i + 1))
|
||||
}
|
||||
|
||||
/// Evaluate the Bezier curve B(t) of degree `N-1` at the parametric value `t`.
|
||||
#[inline]
|
||||
pub fn position<P: Point, const N: usize>(control_points: [P; N], t: f32) -> P {
|
||||
let p = control_points;
|
||||
let degree = N - 1;
|
||||
(0..=degree)
|
||||
.map(|i| p[i] * binomial_coeff(degree, i) as f32 * bernstein_basis(degree, i, t))
|
||||
.sum()
|
||||
}
|
||||
|
||||
/// Compute the first derivative B'(t) of Bezier curve B(t) of degree `N-1` at the given
|
||||
/// parametric value `t` with respect to t. Note that the first derivative of a Bezier is also a
|
||||
/// Bezier, of degree `N-2`.
|
||||
#[inline]
|
||||
pub fn velocity<P: Point, const N: usize>(control_points: [P; N], t: f32) -> P {
|
||||
if N <= 1 {
|
||||
return P::default(); // Zero for numeric types
|
||||
}
|
||||
let p = control_points;
|
||||
let degree = N - 1;
|
||||
let degree_vel = N - 2; // the velocity Bezier is one degree lower than the position Bezier
|
||||
(0..=degree_vel)
|
||||
.map(|i| {
|
||||
// Point on the velocity Bezier curve:
|
||||
let p = (p[i + 1] - p[i]) * degree as f32;
|
||||
p * binomial_coeff(degree_vel, i) as f32 * bernstein_basis(degree_vel, i, t)
|
||||
})
|
||||
.sum()
|
||||
}
|
||||
|
||||
/// Compute the second derivative B''(t) of Bezier curve B(t) of degree `N-1` at the given
|
||||
/// parametric value `t` with respect to t. Note that the second derivative of a Bezier is also
|
||||
/// a Bezier, of degree `N-3`.
|
||||
#[inline]
|
||||
pub fn acceleration<P: Point, const N: usize>(control_points: [P; N], t: f32) -> P {
|
||||
if N <= 2 {
|
||||
return P::default(); // Zero for numeric types
|
||||
}
|
||||
let p = control_points;
|
||||
let degree = N - 1;
|
||||
let degree_vel = N - 2; // the velocity Bezier is one degree lower than the position Bezier
|
||||
let degree_accel = N - 3; // the accel Bezier is one degree lower than the velocity Bezier
|
||||
(0..degree_vel)
|
||||
.map(|i| {
|
||||
// Points on the velocity Bezier curve:
|
||||
let p0 = (p[i + 1] - p[i]) * degree as f32;
|
||||
let p1 = (p[i + 2] - p[i + 1]) * degree as f32;
|
||||
// Point on the acceleration Bezier curve:
|
||||
let p = (p1 - p0) * (degree_vel) as f32;
|
||||
p * binomial_coeff(degree_accel, i) as f32 * bernstein_basis(degree_accel, i, t)
|
||||
})
|
||||
.sum()
|
||||
}
|
||||
}
|
||||
|
||||
#[cfg(test)]
|
||||
mod tests {
|
||||
use glam::Vec2;
|
||||
|
||||
use crate::{CubicBezier2d, CubicBezierEasing};
|
||||
|
||||
/// How close two floats can be and still be considered equal
|
||||
const FLOAT_EQ: f32 = 1e-5;
|
||||
|
||||
/// Basic cubic Bezier easing test to verify the shape of the curve.
|
||||
#[test]
|
||||
fn easing_simple() {
|
||||
// A curve similar to ease-in-out, but symmetric
|
||||
let bezier = CubicBezierEasing::new([1.0, 0.0], [0.0, 1.0]);
|
||||
assert_eq!(bezier.ease(0.0), 0.0);
|
||||
assert!(bezier.ease(0.2) < 0.2); // tests curve
|
||||
assert_eq!(bezier.ease(0.5), 0.5); // true due to symmetry
|
||||
assert!(bezier.ease(0.8) > 0.8); // tests curve
|
||||
assert_eq!(bezier.ease(1.0), 1.0);
|
||||
}
|
||||
|
||||
/// A curve that forms an upside-down "U", that should extend below 0.0. Useful for animations
|
||||
/// that go beyond the start and end positions, e.g. bouncing.
|
||||
#[test]
|
||||
fn easing_overshoot() {
|
||||
// A curve that forms an upside-down "U", that should extend above 1.0
|
||||
let bezier = CubicBezierEasing::new([0.0, 2.0], [1.0, 2.0]);
|
||||
assert_eq!(bezier.ease(0.0), 0.0);
|
||||
assert!(bezier.ease(0.5) > 1.5);
|
||||
assert_eq!(bezier.ease(1.0), 1.0);
|
||||
}
|
||||
|
||||
/// A curve that forms a "U", that should extend below 0.0. Useful for animations that go beyond
|
||||
/// the start and end positions, e.g. bouncing.
|
||||
#[test]
|
||||
fn easing_undershoot() {
|
||||
let bezier = CubicBezierEasing::new([0.0, -2.0], [1.0, -2.0]);
|
||||
assert_eq!(bezier.ease(0.0), 0.0);
|
||||
assert!(bezier.ease(0.5) < -0.5);
|
||||
assert_eq!(bezier.ease(1.0), 1.0);
|
||||
}
|
||||
|
||||
/// Sweep along the full length of a 3D cubic Bezier, and manually check the position.
|
||||
#[test]
|
||||
fn cubic() {
|
||||
const N_SAMPLES: usize = 1000;
|
||||
let bezier = CubicBezier2d::new([[-1.0, -20.0], [3.0, 2.0], [5.0, 3.0], [9.0, 8.0]]);
|
||||
assert_eq!(bezier.position(0.0), bezier.0[0]); // 0 == Start
|
||||
assert_eq!(bezier.position(1.0), bezier.0[3]); // 1 == End
|
||||
for i in 0..=N_SAMPLES {
|
||||
let t = i as f32 / N_SAMPLES as f32; // Check along entire length
|
||||
assert!(bezier.position(t).distance(cubic_manual(t, bezier)) <= FLOAT_EQ);
|
||||
}
|
||||
}
|
||||
|
||||
/// Manual, hardcoded function for computing the position along a cubic bezier.
|
||||
fn cubic_manual(t: f32, bezier: CubicBezier2d) -> Vec2 {
|
||||
let [p0, p1, p2, p3] = bezier.0;
|
||||
p0 * (1.0 - t).powi(3)
|
||||
+ 3.0 * p1 * t * (1.0 - t).powi(2)
|
||||
+ 3.0 * p2 * t.powi(2) * (1.0 - t)
|
||||
+ p3 * t.powi(3)
|
||||
}
|
||||
}
|
|
@ -6,9 +6,14 @@
|
|||
|
||||
#![warn(missing_docs)]
|
||||
|
||||
mod bezier;
|
||||
mod ray;
|
||||
mod rect;
|
||||
|
||||
pub use bezier::{
|
||||
generic as generic_bezier, Bezier, CubicBezier2d, CubicBezier3d, CubicBezierEasing,
|
||||
QuadraticBezier2d, QuadraticBezier3d,
|
||||
};
|
||||
pub use ray::Ray;
|
||||
pub use rect::Rect;
|
||||
|
||||
|
@ -16,8 +21,9 @@ pub use rect::Rect;
|
|||
pub mod prelude {
|
||||
#[doc(hidden)]
|
||||
pub use crate::{
|
||||
BVec2, BVec3, BVec4, EulerRot, IVec2, IVec3, IVec4, Mat2, Mat3, Mat4, Quat, Ray, Rect,
|
||||
UVec2, UVec3, UVec4, Vec2, Vec3, Vec4,
|
||||
BVec2, BVec3, BVec4, Bezier, CubicBezier2d, CubicBezier3d, CubicBezierEasing, EulerRot,
|
||||
IVec2, IVec3, IVec4, Mat2, Mat3, Mat4, QuadraticBezier2d, QuadraticBezier3d, Quat, Ray,
|
||||
Rect, UVec2, UVec3, UVec4, Vec2, Vec3, Vec4,
|
||||
};
|
||||
}
|
||||
|
||||
|
|
Loading…
Reference in a new issue