This crate provies iterators for traversing a ray through both 2D and 3D voxel volumes. It is based on this JS impl which is itself based on a this paper by Amanatides and Woo.
See the examples/ folder for usage.
use fast_voxel_traversal::raycast_3d::*;
use glam::{IVec3, Vec3};
fn main() {
// Create a bounding volume. Volmes always start at (0, 0, 0) with a given size. This doesn't
// actually allocate a volume, it just stores the size. If you need to query a voxel volume that
// doesn't start a (0, 0, 0), simply subtract the offset from the ray's origin, then add the
// offset back in during each traversal iteration.
let volume = BoundingVolume3 {
size: IVec3::ONE * 8,
};
// Create a ray that we will intersect with our voxels.
let ray = Ray3 {
origin: -Vec3::ONE * 10.0,
direction: Vec3::ONE,
length: 100.0,
};
// Traverse the ray through the volume.
for hit in volume.traverse_ray(ray) {
// The position of the voxel that was traversed. This will always be a voxel within the
// bounding volume.
let _position = hit.voxel;
// The normal of the face that was 'entered' when the ray traversed the voxel. This can be
// `None` for the first voxel if the ray started within a voxel.
let _normal = hit.normal;
// The distance from the ray origin this hit occured.
let _distance = hit.distance;
// The world space hit point is easy to compute from this, if you need it:
let _world_space_hit_point = ray.origin + (ray.direction * hit.distance);
println!("{:?}", hit);
}
let ray_doesnt_intersect = Ray3 {
origin: -Vec3::ONE,
direction: Vec3::X,
length: f32::INFINITY,
};
// Casting an infinite ray, or one that never hits a volume won't infinite-loop (although it may
// be slightly slower in such degerate cases).
for _hit in volume.traverse_ray(ray_doesnt_intersect) {
// No hits will be found here.
}
println!("Done!");
}