Struct physx::math::PxVec3

source ·

#[repr(transparent)]
pub struct PxVec3 { /* private fields */ }

Implementations§

source §

impl PxVec3

source

pub fn x(&self) -> f32

source

pub fn y(&self) -> f32

Examples found in repository ?

examples/ball_physx.rs (line 140)

fn main() {
    // Holds a PxFoundation and a PxPhysics.
    // Also has an optional Pvd and transport, not enabled by default.
    // The default allocator is the one provided by PhysX.
    let mut physics = PhysicsFoundation::<_, PxShape>::default();

    // Setup the scene object.  The PxScene type alias makes this much cleaner.
    // There are lots of unwrap calls due to potential null pointers.
    let mut scene: Owner<PxScene> = physics
        .create(SceneDescriptor {
            gravity: PxVec3::new(0.0, -9.81, 0.0),
            on_advance: Some(OnAdvance),
            ..SceneDescriptor::new(())
        })
        .unwrap();

    let mut material = physics.create_material(0.5, 0.5, 0.6, ()).unwrap();

    let ground_plane = physics
        .create_plane(PxVec3::new(0.0, 1.0, 0.0), 0.0, material.as_mut(), ())
        .unwrap();
    // The scene owns actors that are added to it.  They can be retrieved using the
    // various getters on the scene.
    scene.add_static_actor(ground_plane);

    let sphere_geo = PxSphereGeometry::new(10.0);

    let mut sphere_actor = physics
        .create_rigid_dynamic(
            PxTransform::from_translation(&PxVec3::new(0.0, 40.0, 100.0)),
            &sphere_geo,
            material.as_mut(),
            10.0,
            PxTransform::default(),
            (),
        )
        .unwrap();
    sphere_actor.set_angular_damping(0.5);
    sphere_actor.set_rigid_body_flag(RigidBodyFlag::EnablePoseIntegrationPreview, true);
    scene.add_dynamic_actor(sphere_actor);

    // SAFETY: scratch buffer creation
    #[allow(unsafe_code)]
    let mut scratch = unsafe { ScratchBuffer::new(4) };

    // Updating
    let heights_over_time = (0..100)
        .map(|_| {
            // Calls both simulate and fetch_results.  More complex simulation update
            // controls are not fully supported.
            scene
                .step(
                    0.1,
                    None::<&mut physx_sys::PxBaseTask>,
                    Some(&mut scratch),
                    true,
                )
                .expect("error occured during simulation");
            // For simplicity, just read out the only dynamic actor in the scene.
            // getActiveActors is also supported, it returns a Vec<&mut ActorMap> which has
            // a map method that takes a function for each actor type, and `as_<T>` methods
            // that return an Option<&mut T>.
            let actors = scene.get_dynamic_actors();
            actors[0].get_global_position().y() as i32 - 10
        })
        .collect::<Vec<_>>();

    // Draw to stdout
    let max_h = 18;
    (0..max_h)
        .map(|h| {
            let h = max_h - 1 - h;
            heights_over_time
                .iter()
                .enumerate()
                .map(|(_t, p)| if h == *p { 'o' } else { ' ' })
                .collect::<String>()
        })
        .for_each(|line| println!("{}", line));
}

source

pub fn new(x: f32, y: f32, z: f32) -> PxVec3

Examples found in repository ?

examples/profiler.rs (line 112)

fn main() {
    // Holds a PxFoundation and a PxPhysics.
    // Also has an optional Pvd and transport, not enabled by default.
    // The default allocator is the one provided by PhysX.
    let mut physics = PhysicsFoundation::<_, PxShape>::default();

    physics.set_profiler(PrintProfilerCallback {
        start: std::time::Instant::now(),
    });
    // Setup the scene object.  The PxScene type alias makes this much cleaner.
    // There are lots of unwrap calls due to potential null pointers.
    let mut scene: Owner<PxScene> = physics
        .create(SceneDescriptor {
            gravity: PxVec3::new(0.0, -9.81, 0.0),
            on_advance: Some(OnAdvance),
            ..SceneDescriptor::new(())
        })
        .unwrap();

    let mut material = physics.create_material(0.5, 0.5, 0.6, ()).unwrap();

    let ground_plane = physics
        .create_plane(PxVec3::new(0.0, 1.0, 0.0), 0.0, material.as_mut(), ())
        .unwrap();
    // The scene owns actors that are added to it.  They can be retrieved using the
    // various getters on the scene.
    scene.add_static_actor(ground_plane);

    let sphere_geo = PxSphereGeometry::new(10.0);

    let mut sphere_actor = physics
        .create_rigid_dynamic(
            PxTransform::from_translation(&PxVec3::new(0.0, 40.0, 100.0)),
            &sphere_geo,
            material.as_mut(),
            10.0,
            PxTransform::default(),
            (),
        )
        .unwrap();
    sphere_actor.set_angular_damping(0.5);
    sphere_actor.set_rigid_body_flag(RigidBodyFlag::EnablePoseIntegrationPreview, true);
    scene.add_dynamic_actor(sphere_actor);

    for _ in 0..100 {
        #[allow(unsafe_code)]
        // SAFETY: it's unsafe /shrug
        let mut sb = unsafe { ScratchBuffer::new(4) };

        // Calls both simulate and fetch_results.  More complex simulation update
        // controls are not fully supported.
        scene
            .step(0.1, None::<&mut physx_sys::PxBaseTask>, Some(&mut sb), true)
            .expect("error occured during simulation");
    }
}

More examples

Hide additional examples

examples/ball_physx.rs (line 87)

fn main() {
    // Holds a PxFoundation and a PxPhysics.
    // Also has an optional Pvd and transport, not enabled by default.
    // The default allocator is the one provided by PhysX.
    let mut physics = PhysicsFoundation::<_, PxShape>::default();

    // Setup the scene object.  The PxScene type alias makes this much cleaner.
    // There are lots of unwrap calls due to potential null pointers.
    let mut scene: Owner<PxScene> = physics
        .create(SceneDescriptor {
            gravity: PxVec3::new(0.0, -9.81, 0.0),
            on_advance: Some(OnAdvance),
            ..SceneDescriptor::new(())
        })
        .unwrap();

    let mut material = physics.create_material(0.5, 0.5, 0.6, ()).unwrap();

    let ground_plane = physics
        .create_plane(PxVec3::new(0.0, 1.0, 0.0), 0.0, material.as_mut(), ())
        .unwrap();
    // The scene owns actors that are added to it.  They can be retrieved using the
    // various getters on the scene.
    scene.add_static_actor(ground_plane);

    let sphere_geo = PxSphereGeometry::new(10.0);

    let mut sphere_actor = physics
        .create_rigid_dynamic(
            PxTransform::from_translation(&PxVec3::new(0.0, 40.0, 100.0)),
            &sphere_geo,
            material.as_mut(),
            10.0,
            PxTransform::default(),
            (),
        )
        .unwrap();
    sphere_actor.set_angular_damping(0.5);
    sphere_actor.set_rigid_body_flag(RigidBodyFlag::EnablePoseIntegrationPreview, true);
    scene.add_dynamic_actor(sphere_actor);

    // SAFETY: scratch buffer creation
    #[allow(unsafe_code)]
    let mut scratch = unsafe { ScratchBuffer::new(4) };

    // Updating
    let heights_over_time = (0..100)
        .map(|_| {
            // Calls both simulate and fetch_results.  More complex simulation update
            // controls are not fully supported.
            scene
                .step(
                    0.1,
                    None::<&mut physx_sys::PxBaseTask>,
                    Some(&mut scratch),
                    true,
                )
                .expect("error occured during simulation");
            // For simplicity, just read out the only dynamic actor in the scene.
            // getActiveActors is also supported, it returns a Vec<&mut ActorMap> which has
            // a map method that takes a function for each actor type, and `as_<T>` methods
            // that return an Option<&mut T>.
            let actors = scene.get_dynamic_actors();
            actors[0].get_global_position().y() as i32 - 10
        })
        .collect::<Vec<_>>();

    // Draw to stdout
    let max_h = 18;
    (0..max_h)
        .map(|h| {
            let h = max_h - 1 - h;
            heights_over_time
                .iter()
                .enumerate()
                .map(|(_t, p)| if h == *p { 'o' } else { ' ' })
                .collect::<String>()
        })
        .for_each(|line| println!("{}", line));
}

source

pub fn abs(&self) -> PxVec3

source

pub fn cross(&self, other: &PxVec3) -> PxVec3

source

pub fn dot(&self, other: &PxVec3) -> f32

source

pub fn get_normalized(&self) -> PxVec3

source

pub fn is_finite(&self) -> bool

source

pub fn is_normalized(&self) -> bool

source

pub fn is_zero(&self) -> bool

source

pub fn magnitude(&self) -> f32

source

pub fn magnitude_squared(&self) -> f32

source

pub fn max_element(&self) -> f32

source

pub fn maximum(&self, other: &PxVec3) -> PxVec3

source

pub fn min_element(&self) -> f32

source

pub fn minimum(&self, other: &PxVec3) -> PxVec3

source

pub fn multiply(&self, other: &PxVec3) -> PxVec3

source

pub fn normalize(&mut self) -> f32

normalize in place and returns the original magnitude.

Trait Implementations§

source §

Returns a raw const pointer to the wrapped type. Retrieving a raw pointer is safe. However, pretty much any use of a raw pointer is unsafe. In particular: this pointer should not be used to construct a second owning wrapper around the pointer.

source §

fn as_mut_ptr(&mut self) -> *mut PxVec3

Returns a raw mut pointer to the wrapped type. Retrieving a raw pointer is safe. However, pretty much any use of a raw pointer is unsafe. In particular: this pointer should not be used to construct a second owning wrapper around the pointer.

source §