Crates.io | sepax2d |
lib.rs | sepax2d |
version | 0.3.8 |
source | src |
created_at | 2022-05-30 05:14:15.101454 |
updated_at | 2022-08-30 02:02:03.081198 |
description | A safe crate for finding and resolving collisions of 2D convex shapes using the Separating Axis Theorem. |
homepage | |
repository | https://github.com/meowitzher/sepax2d/ |
max_upload_size | |
id | 596793 |
size | 195,436 |
A safe Rust crate for finding and resolving collisions of convex shapes using the Separating Axis Theorem (SAT) in two dimensions.
Add the following to the [dependencies]
section of your Cargo.toml
:
sepax2d = "0.3"
Import the types of shapes you'd like to use and create some new shapes:
use sepax2d::prelude::*;
let rectangle = AABB::new(top_left, width, height);
let circle = Circle::new(center, radius);
let capsule = Capsule::new(center, arm, radius);
//The vertices of a polygon are position vectors
//relative to the shape's position, i.e. if position
//is (1, 2), then the absolute location of the
//first vertex is (1, 0).
let triangle = Polygon::from_vertices
(
position,
vec![(0.0, -2.0), (-1.0, 2.0), (1.0, 2.0)]
);
Use the sat_overlap(&left, &right)
method to get a bool
indicating whether or not the two given shapes overlap.
Any struct implementing the Shape
trait can be used.
assert!(sat_overlap(&circle, &capsule));
assert!(sat_overlap(&triangle, &rectangle));
Use the sat_collision(&left, &right)
method to get a (f32, f32)
which represents the shift needed to add to right
's
position in order to resolve the overlap of the two shapes.
let resolution = sat_overlap(&circle, &triangle);
let position = triangle.position();
triangle.set_position((position.0 + resolution.0, position.1 + resolution.1));
assert!(!sat_overlap(&circle, &triangle));
Use the contains_point(&shape, point)
method to get a bool
indicating whether or not the specified point
is inside the given shape.
let rectangle = AABB::new((0.0, 0.0), 5.0, 2.0);
assert!(contains_point(&rect, (1.0, 1.0)));
assert!(!contains_point(&rect, (10.0, -1.0)));
Polygon
, Circle
, Capsule
, and Parallelogram
shapes implement the Rotate
trait, which allows you to rotate them
around their position
.
# use sepax2d::prelude::*;
# let position = (-1.0, -1.0);
let mut triangle = Polygon::from_vertices
(
position,
vec![(-1.0, 0.0), (0.0, 2.0), (1.0, 0.0)]
);
triangle.rotate(std::f32::consts::FRAC_PI_2)
//New vertices: [(0.0, -1.0), (-2.0, 0.0), (0.0, 1.0)]
You can use the intersects_line
, intersects_ray
, and intersects_segment
methods to
check whether a shape intersects with the corresponding type of line.
# use sepax2d::prelude::*;
let triangle = Polygon::from_vertices((0.0, vec![(0.0, 0.0), (1.0, 1.0), (-1.0, 1.0)]));
assert!(intersects_segment(&triangle, (2.0, 0.5), (-2.0, 0.5)));
The Separating Axis Theorem only holds for convex shapes. If a concave shape is passed in, it is possible for overlap to be missed and false overlap to be detected.
Convexity is not a problem for Circle
, AABB
, Parallelogram
, or Capsule
as those are convex by definition. For
polygons, it is possible to define a concave shape. Polygon convexity can be tested using the
polygon.is_convex()
method. Alternatively, the Polygon::convex_from_vertices(position, vertices)
constructor returns an Option(Polygon)
, which is None
if you try to make a concave polygon.
Enable the serde
feature for (De)Serialization of supported shapes!
The repository includes two example applications built with ggez which show off the overlap and collision functionality. They can be run from the repo via:
cargo run --example overlap
cargo run --example collision
Please feel free to suggest additional features, bug fixes, or optimizations. Thanks!