Struct ncollide2d::shape::Compound

pub struct Compound<N: RealField> { /* fields omitted */ }

A compound shape with an aabb bounding volume.

A compound shape is a shape composed of the union of several simpler shape. This is the main way of creating a concave shape from convex parts. Each parts can have its own delta transformation to shift or rotate it with regard to the other shapes.

Methods

impl<N: RealField> Compound<N>

pub fn new(shapes: Vec<(Isometry<N>, ShapeHandle<N>)>) -> Compound<N>

Builds a new compound shape.

impl<N: RealField> Compound<N>

pub fn shapes(&self) -> &[(Isometry<N>, ShapeHandle<N>)]

The shapes of this compound shape.

pub fn bvt(&self) -> &BVT<usize, AABB<N>>

The optimization structure used by this compound shape.

pub fn aabb(&self) -> &AABB<N>

The AABB of this compound in its local-space.

pub fn bounding_volumes(&self) -> &[AABB<N>]

The shapes bounding volumes.

pub fn aabb_at(&self, i: usize) -> &AABB<N>

The AABB of the i-th shape compositing this compound.

pub fn subshape_feature_id(&self, fid: FeatureId) -> (usize, FeatureId)

Transforms a FeatureId of this compound into a pair containing the index of the subshape containing this feature, and the corresponding FeatureId on this subshape.

Trait Implementations

impl<N: RealField> HasBoundingVolume<N, AABB<N>> for Compound<N>

fn bounding_volume(&self, m: &Isometry<N>) -> AABB<N>

The bounding volume of self transformed by m.

fn local_bounding_volume(&self) -> AABB<N>

The bounding volume of self.

impl<N: RealField> HasBoundingVolume<N, BoundingSphere<N>> for Compound<N>

fn bounding_volume(&self, m: &Isometry<N>) -> BoundingSphere<N>

The bounding volume of self transformed by m.

fn local_bounding_volume(&self) -> BoundingSphere<N>

The bounding volume of self.

impl<N: RealField> PointQuery<N> for Compound<N>

fn project_point(
    &self,
    m: &Isometry<N>,
    point: &Point<N>,
    solid: bool
) -> PointProjection<N>

Projects a point on self transformed by m.

fn project_point_with_feature(
    &self,
    _: &Isometry<N>,
    _: &Point<N>
) -> (PointProjection<N>, FeatureId)

Projects a point on the boundary of self transformed by m and retuns the id of the feature the point was projected on.

fn contains_point(&self, m: &Isometry<N>, point: &Point<N>) -> bool

Tests if the given point is inside of self transformed by m.

fn distance_to_point(&self, m: &Isometry<N>, pt: &Point<N>, solid: bool) -> N

Computes the minimal distance between a point and self transformed by m.

impl<N: RealField> RayCast<N> for Compound<N>

fn toi_with_ray(&self, m: &Isometry<N>, ray: &Ray<N>, solid: bool) -> Option<N>

Computes the time of impact between this transform shape and a ray.

fn toi_and_normal_with_ray(
    &self,
    m: &Isometry<N>,
    ray: &Ray<N>,
    solid: bool
) -> Option<RayIntersection<N>>

Computes the time of impact, and normal between this transformed shape and a ray.

fn intersects_ray(&self, m: &Isometry<N>, ray: &Ray<N>) -> bool

Tests whether a ray intersects this transformed shape.

impl<N: RealField> CompositeShape<N> for Compound<N>

fn nparts(&self) -> usize

The number of sub-shape in this composide shape.

fn map_part_at(
    &self,
    i: usize,
    m: &Isometry<N>,
    f: &mut dyn FnMut(&Isometry<N>, &dyn Shape<N>)
)

Applies a transformation matrix and a function to each sub-shape of this concave shape.

fn map_part_and_preprocessor_at(
    &self,
    i: usize,
    m: &Isometry<N>,
    _prediction: &ContactPrediction<N>,
    f: &mut dyn FnMut(&Isometry<N>, &dyn Shape<N>, &dyn ContactPreprocessor<N>)
)

Applies a transformation matrix and a function to each sub-shape of this concave shape.

fn aabb_at(&self, i: usize) -> AABB<N>

Gets the AABB of the shape identified by the index i.

fn bvh(&self) -> BVHImpl<N, usize, AABB<N>>

Gets the acceleration structure of the concave shape.

impl<N: RealField> Shape<N> for Compound<N>

fn aabb(&self, m: &Isometry<N>) -> AABB<N>

The AABB of self transformed by m.

fn local_aabb(&self) -> AABB<N>

The AABB of self.

fn bounding_sphere(&self, m: &Isometry<N>) -> BoundingSphere<N>

The bounding sphere of self transformed by m.

fn as_ray_cast(&self) -> Option<&dyn RayCast<N>>

The RayCast implementation of self.

fn as_point_query(&self) -> Option<&dyn PointQuery<N>>

The PointQuery implementation of self.

fn as_composite_shape(&self) -> Option<&dyn CompositeShape<N>>

The composite shape representation of self if applicable.

fn is_composite_shape(&self) -> bool

Whether self uses a composite shape-based representation.

fn tangent_cone_contains_dir(
    &self,
    feature: FeatureId,
    m: &Isometry<N>,
    _: Option<&[N]>,
    dir: &Unit<Vector<N>>
) -> bool

Check if if the feature _feature of the i-th subshape of self transformed by m has a tangent cone that contains dir at the point pt.

fn subshape_containing_feature(&self, feature: FeatureId) -> usize

Returns the id of the subshape containing the specified feature.

fn local_bounding_sphere(&self) -> BoundingSphere<N>

The bounding sphere of self.

fn as_convex_polyhedron(&self) -> Option<&dyn ConvexPolyhedron<N>>

The convex polyhedron representation of self if applicable.

fn as_support_map(&self) -> Option<&dyn SupportMap<N>>

The support mapping of self if applicable.

fn as_deformable_shape(&self) -> Option<&dyn DeformableShape<N>>

The deformable shape representation of self if applicable.

fn as_deformable_shape_mut(&mut self) -> Option<&mut dyn DeformableShape<N>>

The mutable deformable shape representation of self if applicable.

fn is_convex_polyhedron(&self) -> bool

Whether self uses a convex polyhedron representation.

fn is_support_map(&self) -> bool

Whether self uses a support-mapping based representation.

fn is_deformable_shape(&self) -> bool

Whether self uses a composite shape-based representation.

impl<N: Clone + RealField> Clone for Compound<N>

fn clone(&self) -> Compound<N>

Returns a copy of the value.

fn clone_from(&mut self, source: &Self)

Performs copy-assignment from source.