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use na::{Isometry3, Point3};
use rapier3d::dynamics::{JointSet, RigidBodyBuilder, RigidBodySet};
use rapier3d::geometry::{ColliderBuilder, ColliderSet, SharedShape};
use rapier_testbed3d::Testbed;
pub fn init_world(testbed: &mut Testbed) {
/*
* World
*/
let mut bodies = RigidBodySet::new();
let mut colliders = ColliderSet::new();
let joints = JointSet::new();
/*
* Ground
*/
let ground_size = 50.0;
let ground_height = 0.1;
let rigid_body = RigidBodyBuilder::new_static()
.translation(0.0, -ground_height, 0.0)
.build();
let handle = bodies.insert(rigid_body);
let collider = ColliderBuilder::cuboid(ground_size, ground_height, ground_size).build();
colliders.insert(collider, handle, &mut bodies);
/*
* Create the cubes
*/
let num = 8;
let numy = 15;
let rad = 0.2;
let shift = rad * 4.0 + rad;
let centerx = shift * (num / 2) as f32;
let centery = shift / 2.0;
let centerz = shift * (num / 2) as f32;
let mut offset = -(num as f32) * (rad * 2.0 + rad) * 0.5;
for j in 0usize..numy {
for i in 0..num {
for k in 0usize..num {
let x = i as f32 * shift * 5.0 - centerx + offset;
let y = j as f32 * (shift * 5.0) + centery + 3.0;
let z = k as f32 * shift * 2.0 - centerz + offset;
// Build the rigid body.
let rigid_body = RigidBodyBuilder::new_dynamic().translation(x, y, z).build();
let handle = bodies.insert(rigid_body);
// First option: attach several colliders to a single rigid-body.
if j < numy / 2 {
let collider1 = ColliderBuilder::cuboid(rad * 10.0, rad, rad).build();
let collider2 = ColliderBuilder::cuboid(rad, rad * 10.0, rad)
.translation(rad * 10.0, rad * 10.0, 0.0)
.build();
let collider3 = ColliderBuilder::cuboid(rad, rad * 10.0, rad)
.translation(-rad * 10.0, rad * 10.0, 0.0)
.build();
colliders.insert(collider1, handle, &mut bodies);
colliders.insert(collider2, handle, &mut bodies);
colliders.insert(collider3, handle, &mut bodies);
} else {
// Second option: create a compound shape and attach it to a single collider.
let shapes = vec![
(
Isometry3::identity(),
SharedShape::cuboid(rad * 10.0, rad, rad),
),
(
Isometry3::translation(rad * 10.0, rad * 10.0, 0.0),
SharedShape::cuboid(rad, rad * 10.0, rad),
),
(
Isometry3::translation(-rad * 10.0, rad * 10.0, 0.0),
SharedShape::cuboid(rad, rad * 10.0, rad),
),
];
let collider = ColliderBuilder::compound(shapes).build();
colliders.insert(collider, handle, &mut bodies);
}
}
}
offset -= 0.05 * rad * (num as f32 - 1.0);
}
/*
* Set up the testbed.
*/
testbed.set_world(bodies, colliders, joints);
testbed.look_at(Point3::new(100.0, 100.0, 100.0), Point3::origin());
}
fn main() {
let testbed = Testbed::from_builders(0, vec![("Boxes", init_world)]);
testbed.run()
}
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