bevy/crates/bevy_math/src/lib.rs

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//! Provides math types and functionality for the Bevy game engine.
//!
//! The commonly used types are vectors like [`Vec2`] and [`Vec3`],
//! matrices like [`Mat2`], [`Mat3`] and [`Mat4`] and orientation representations
//! like [`Quat`].
Reduce the size of MeshUniform to improve performance (#9416) # Objective - Significantly reduce the size of MeshUniform by only including necessary data. ## Solution Local to world, model transforms are affine. This means they only need a 4x3 matrix to represent them. `MeshUniform` stores the current, and previous model transforms, and the inverse transpose of the current model transform, all as 4x4 matrices. Instead we can store the current, and previous model transforms as 4x3 matrices, and we only need the upper-left 3x3 part of the inverse transpose of the current model transform. This change allows us to reduce the serialized MeshUniform size from 208 bytes to 144 bytes, which is over a 30% saving in data to serialize, and VRAM bandwidth and space. ## Benchmarks On an M1 Max, running `many_cubes -- sphere`, main is in yellow, this PR is in red: <img width="1484" alt="Screenshot 2023-08-11 at 02 36 43" src="https://github.com/bevyengine/bevy/assets/302146/7d99c7b3-f2bb-4004-a8d0-4c00f755cb0d"> A reduction in frame time of ~14%. --- ## Changelog - Changed: Redefined `MeshUniform` to improve performance by using 4x3 affine transforms and reconstructing 4x4 matrices in the shader. Helper functions were added to `bevy_pbr::mesh_functions` to unpack the data. `affine_to_square` converts the packed 4x3 in 3x4 matrix data to a 4x4 matrix. `mat2x4_f32_to_mat3x3` converts the 3x3 in mat2x4 + f32 matrix data back into a 3x3. ## Migration Guide Shader code before: ``` var model = mesh[instance_index].model; ``` Shader code after: ``` #import bevy_pbr::mesh_functions affine_to_square var model = affine_to_square(mesh[instance_index].model); ```
2023-08-15 06:00:23 +00:00
mod affine3;
mod aspect_ratio;
pub mod bounding;
Add generic cubic splines to `bevy_math` (#7683) # Objective - Make cubic splines more flexible and more performant - Remove the existing spline implementation that is generic over many degrees - This is a potential performance footgun and adds type complexity for negligible gain. - Add implementations of: - Bezier splines - Cardinal splines (inc. Catmull-Rom) - B-Splines - Hermite splines https://user-images.githubusercontent.com/2632925/221780519-495d1b20-ab46-45b4-92a3-32c46da66034.mp4 https://user-images.githubusercontent.com/2632925/221780524-2b154016-699f-404f-9c18-02092f589b04.mp4 https://user-images.githubusercontent.com/2632925/221780525-f934f99d-9ad4-4999-bae2-75d675f5644f.mp4 ## Solution - Implements the concept that splines are curve generators (e.g. https://youtu.be/jvPPXbo87ds?t=3488) via the `CubicGenerator` trait. - Common splines are bespoke data types that implement this trait. This gives us flexibility to add custom spline-specific methods on these types, while ultimately all generating a `CubicCurve`. - All splines generate `CubicCurve`s, which are a chain of precomputed polynomial coefficients. This means that all splines have the same evaluation cost, as the calculations for determining position, velocity, and acceleration are all identical. In addition, `CubicCurve`s are simply a list of `CubicSegment`s, which are evaluated from t=0 to t=1. This also means cubic splines of different type can be chained together, as ultimately they all are simply a collection of `CubicSegment`s. - Because easing is an operation on a singe segment of a Bezier curve, we can simply implement easing on `Beziers` that use the `Vec2` type for points. Higher level crates such as `bevy_ui` can wrap this in a more ergonomic interface as needed. ### Performance Measured on a desktop i5 8600K (6-year-old CPU): - easing: 2.7x faster (19ns) - cubic vec2 position sample: 1.5x faster (1.8ns) - cubic vec3 position sample: 1.5x faster (2.6ns) - cubic vec3a position sample: 1.9x faster (1.4ns) On a laptop i7 11800H: - easing: 16ns - cubic vec2 position sample: 1.6ns - cubic vec3 position sample: 2.3ns - cubic vec3a position sample: 1.2ns --- ## Changelog - Added a generic cubic curve trait, and implementation for Cardinal splines (including Catmull-Rom), B-Splines, Beziers, and Hermite Splines. 2D cubic curve segments also implement easing functionality for animation.
2023-03-03 22:06:42 +00:00
pub mod cubic_splines;
mod direction;
Define a basic set of Primitives (#10466) # Objective - Implement a subset of https://github.com/bevyengine/rfcs/blob/main/rfcs/12-primitive-shapes.md#feature-name-primitive-shapes ## Solution - Define a very basic set of primitives in bevy_math - Assume a 0,0,0 origin for most shapes - Use radius and half extents to avoid unnecessary computational overhead wherever they get used - Provide both Boxed and const generics variants for shapes with variable sizes - Boxed is useful if a 3rd party crate wants to use something like enum-dispatch for all supported primitives - Const generics is useful when just working on a single primitive, as it causes no allocs #### Some discrepancies from the RFC: - Box was changed to Cuboid, because Box is already used for an alloc type - Skipped Cone because it's unclear where the origin should be for different uses - Skipped Wedge because it's too niche for an initial PR (we also don't implement Torus, Pyramid or a Death Star (there's an SDF for that!)) - Skipped Frustum because while it would be a useful math type, it's not really a common primitive - Skipped Triangle3d and Quad3d because those are just rotated 2D shapes ## Future steps - Add more primitives - Add helper methods to make primitives easier to construct (especially when half extents are involved) - Add methods to calculate AABBs for primitives (useful for physics, BVH construction, for the mesh AABBs, etc) - Add wrappers for common and cheap operations, like extruding 2D shapes and translating them - Use the primitives to generate meshes - Provide signed distance functions and gradients for primitives (maybe) --- ## Changelog - Added a collection of primitives to the bevy_math crate --------- Co-authored-by: Joona Aalto <jondolf.dev@gmail.com>
2023-11-15 16:51:03 +00:00
pub mod primitives;
mod ray;
mod rects;
Move `sprite::Rect` into `bevy_math` (#5686) # Objective Promote the `Rect` utility of `sprite::Rect`, which defines a rectangle by its minimum and maximum corners, to the `bevy_math` crate to make it available as a general math type to all crates without the need to depend on the `bevy_sprite` crate. Fixes #5575 ## Solution Move `sprite::Rect` into `bevy_math` and fix all uses. Implement `Reflect` for `Rect` directly into the `bevy_reflect` crate by having `bevy_reflect` depend on `bevy_math`. This looks like a new dependency, but the `bevy_reflect` was "cheating" for other math types by directly depending on `glam` to reflect other math types, thereby giving the illusion that there was no dependency on `bevy_math`. In practice conceptually Bevy's math types are reflected into the `bevy_reflect` crate to avoid a dependency of that crate to a "lower level" utility crate like `bevy_math` (which in turn would make `bevy_reflect` be a dependency of most other crates, and increase the risk of circular dependencies). So this change simply formalizes that dependency in `Cargo.toml`. The `Rect` struct is also augmented in this change with a collection of utility methods to improve its usability. A few uses cases are updated to use those new methods, resulting is more clear and concise syntax. --- ## Changelog ### Changed - Moved the `sprite::Rect` type into `bevy_math`. ### Added - Added several utility methods to the `math::Rect` type. ## Migration Guide The `bevy::sprite::Rect` type moved to the math utility crate as `bevy::math::Rect`. You should change your imports from `use bevy::sprite::Rect` to `use bevy::math::Rect`.
2022-09-02 12:35:23 +00:00
Reduce the size of MeshUniform to improve performance (#9416) # Objective - Significantly reduce the size of MeshUniform by only including necessary data. ## Solution Local to world, model transforms are affine. This means they only need a 4x3 matrix to represent them. `MeshUniform` stores the current, and previous model transforms, and the inverse transpose of the current model transform, all as 4x4 matrices. Instead we can store the current, and previous model transforms as 4x3 matrices, and we only need the upper-left 3x3 part of the inverse transpose of the current model transform. This change allows us to reduce the serialized MeshUniform size from 208 bytes to 144 bytes, which is over a 30% saving in data to serialize, and VRAM bandwidth and space. ## Benchmarks On an M1 Max, running `many_cubes -- sphere`, main is in yellow, this PR is in red: <img width="1484" alt="Screenshot 2023-08-11 at 02 36 43" src="https://github.com/bevyengine/bevy/assets/302146/7d99c7b3-f2bb-4004-a8d0-4c00f755cb0d"> A reduction in frame time of ~14%. --- ## Changelog - Changed: Redefined `MeshUniform` to improve performance by using 4x3 affine transforms and reconstructing 4x4 matrices in the shader. Helper functions were added to `bevy_pbr::mesh_functions` to unpack the data. `affine_to_square` converts the packed 4x3 in 3x4 matrix data to a 4x4 matrix. `mat2x4_f32_to_mat3x3` converts the 3x3 in mat2x4 + f32 matrix data back into a 3x3. ## Migration Guide Shader code before: ``` var model = mesh[instance_index].model; ``` Shader code after: ``` #import bevy_pbr::mesh_functions affine_to_square var model = affine_to_square(mesh[instance_index].model); ```
2023-08-15 06:00:23 +00:00
pub use affine3::*;
pub use aspect_ratio::AspectRatio;
pub use direction::*;
Split `Ray` into `Ray2d` and `Ray3d` and simplify plane construction (#10856) # Objective A better alternative version of #10843. Currently, Bevy has a single `Ray` struct for 3D. To allow better interoperability with Bevy's primitive shapes (#10572) and some third party crates (that handle e.g. spatial queries), it would be very useful to have separate versions for 2D and 3D respectively. ## Solution Separate `Ray` into `Ray2d` and `Ray3d`. These new structs also take advantage of the new primitives by using `Direction2d`/`Direction3d` for the direction: ```rust pub struct Ray2d { pub origin: Vec2, pub direction: Direction2d, } pub struct Ray3d { pub origin: Vec3, pub direction: Direction3d, } ``` and by using `Plane2d`/`Plane3d` in `intersect_plane`: ```rust impl Ray2d { // ... pub fn intersect_plane(&self, plane_origin: Vec2, plane: Plane2d) -> Option<f32> { // ... } } ``` --- ## Changelog ### Added - `Ray2d` and `Ray3d` - `Ray2d::new` and `Ray3d::new` constructors - `Plane2d::new` and `Plane3d::new` constructors ### Removed - Removed `Ray` in favor of `Ray3d` ### Changed - `direction` is now a `Direction2d`/`Direction3d` instead of a vector, which provides guaranteed normalization - `intersect_plane` now takes a `Plane2d`/`Plane3d` instead of just a vector for the plane normal - `Direction2d` and `Direction3d` now derive `Serialize` and `Deserialize` to preserve ray (de)serialization ## Migration Guide `Ray` has been renamed to `Ray3d`. ### Ray creation Before: ```rust Ray { origin: Vec3::ZERO, direction: Vec3::new(0.5, 0.6, 0.2).normalize(), } ``` After: ```rust // Option 1: Ray3d { origin: Vec3::ZERO, direction: Direction3d::new(Vec3::new(0.5, 0.6, 0.2)).unwrap(), } // Option 2: Ray3d::new(Vec3::ZERO, Vec3::new(0.5, 0.6, 0.2)) ``` ### Plane intersections Before: ```rust let result = ray.intersect_plane(Vec2::X, Vec2::Y); ``` After: ```rust let result = ray.intersect_plane(Vec2::X, Plane2d::new(Vec2::Y)); ```
2023-12-06 14:09:04 +00:00
pub use ray::{Ray2d, Ray3d};
pub use rects::*;
Move `sprite::Rect` into `bevy_math` (#5686) # Objective Promote the `Rect` utility of `sprite::Rect`, which defines a rectangle by its minimum and maximum corners, to the `bevy_math` crate to make it available as a general math type to all crates without the need to depend on the `bevy_sprite` crate. Fixes #5575 ## Solution Move `sprite::Rect` into `bevy_math` and fix all uses. Implement `Reflect` for `Rect` directly into the `bevy_reflect` crate by having `bevy_reflect` depend on `bevy_math`. This looks like a new dependency, but the `bevy_reflect` was "cheating" for other math types by directly depending on `glam` to reflect other math types, thereby giving the illusion that there was no dependency on `bevy_math`. In practice conceptually Bevy's math types are reflected into the `bevy_reflect` crate to avoid a dependency of that crate to a "lower level" utility crate like `bevy_math` (which in turn would make `bevy_reflect` be a dependency of most other crates, and increase the risk of circular dependencies). So this change simply formalizes that dependency in `Cargo.toml`. The `Rect` struct is also augmented in this change with a collection of utility methods to improve its usability. A few uses cases are updated to use those new methods, resulting is more clear and concise syntax. --- ## Changelog ### Changed - Moved the `sprite::Rect` type into `bevy_math`. ### Added - Added several utility methods to the `math::Rect` type. ## Migration Guide The `bevy::sprite::Rect` type moved to the math utility crate as `bevy::math::Rect`. You should change your imports from `use bevy::sprite::Rect` to `use bevy::math::Rect`.
2022-09-02 12:35:23 +00:00
/// The `bevy_math` prelude.
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pub mod prelude {
#[doc(hidden)]
pub use crate::{
cubic_splines::{
CubicBSpline, CubicBezier, CubicCardinalSpline, CubicCurve, CubicGenerator,
CubicHermite, CubicNurbs, CubicNurbsError, CubicSegment, RationalCurve,
RationalGenerator, RationalSegment,
},
direction::{Direction2d, Direction3d, Direction3dA},
primitives::*,
BVec2, BVec3, BVec4, EulerRot, FloatExt, IRect, IVec2, IVec3, IVec4, Mat2, Mat3, Mat4,
Quat, Ray2d, Ray3d, Rect, URect, UVec2, UVec3, UVec4, Vec2, Vec2Swizzles, Vec3,
Split `Ray` into `Ray2d` and `Ray3d` and simplify plane construction (#10856) # Objective A better alternative version of #10843. Currently, Bevy has a single `Ray` struct for 3D. To allow better interoperability with Bevy's primitive shapes (#10572) and some third party crates (that handle e.g. spatial queries), it would be very useful to have separate versions for 2D and 3D respectively. ## Solution Separate `Ray` into `Ray2d` and `Ray3d`. These new structs also take advantage of the new primitives by using `Direction2d`/`Direction3d` for the direction: ```rust pub struct Ray2d { pub origin: Vec2, pub direction: Direction2d, } pub struct Ray3d { pub origin: Vec3, pub direction: Direction3d, } ``` and by using `Plane2d`/`Plane3d` in `intersect_plane`: ```rust impl Ray2d { // ... pub fn intersect_plane(&self, plane_origin: Vec2, plane: Plane2d) -> Option<f32> { // ... } } ``` --- ## Changelog ### Added - `Ray2d` and `Ray3d` - `Ray2d::new` and `Ray3d::new` constructors - `Plane2d::new` and `Plane3d::new` constructors ### Removed - Removed `Ray` in favor of `Ray3d` ### Changed - `direction` is now a `Direction2d`/`Direction3d` instead of a vector, which provides guaranteed normalization - `intersect_plane` now takes a `Plane2d`/`Plane3d` instead of just a vector for the plane normal - `Direction2d` and `Direction3d` now derive `Serialize` and `Deserialize` to preserve ray (de)serialization ## Migration Guide `Ray` has been renamed to `Ray3d`. ### Ray creation Before: ```rust Ray { origin: Vec3::ZERO, direction: Vec3::new(0.5, 0.6, 0.2).normalize(), } ``` After: ```rust // Option 1: Ray3d { origin: Vec3::ZERO, direction: Direction3d::new(Vec3::new(0.5, 0.6, 0.2)).unwrap(), } // Option 2: Ray3d::new(Vec3::ZERO, Vec3::new(0.5, 0.6, 0.2)) ``` ### Plane intersections Before: ```rust let result = ray.intersect_plane(Vec2::X, Vec2::Y); ``` After: ```rust let result = ray.intersect_plane(Vec2::X, Plane2d::new(Vec2::Y)); ```
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Vec3Swizzles, Vec4, Vec4Swizzles,
};
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}
pub use glam::*;