Struct rapier2d::geometry::RoundShape
source · [−]#[repr(C)]pub struct RoundShape<S> {
pub base_shape: S,
pub border_radius: f32,
}
Expand description
A shape with rounded borders.
Fields
base_shape: S
The shape being rounded.
border_radius: f32
The radius of the rounded border.
Trait Implementations
pub fn project_local_point(
&self,
point: &OPoint<f32, Const<2_usize>>,
solid: bool
) -> PointProjection
pub fn project_local_point(
&self,
point: &OPoint<f32, Const<2_usize>>,
solid: bool
) -> PointProjection
Projects a point on self
. Read more
pub fn project_local_point_and_get_feature(
&self,
point: &OPoint<f32, Const<2_usize>>
) -> (PointProjection, FeatureId)
pub fn project_local_point_and_get_feature(
&self,
point: &OPoint<f32, Const<2_usize>>
) -> (PointProjection, FeatureId)
Projects a point on the boundary of self
and returns the id of the
feature the point was projected on. Read more
Computes the minimal distance between a point and self
.
Tests if the given point is inside of self
.
Projects a point on self
transformed by m
.
Computes the minimal distance between a point and self
transformed by m
.
Projects a point on the boundary of self
transformed by m
and returns the id of the
feature the point was projected on. Read more
pub fn cast_local_ray_and_get_normal(
&self,
ray: &Ray,
max_toi: f32,
solid: bool
) -> Option<RayIntersection>
pub fn cast_local_ray_and_get_normal(
&self,
ray: &Ray,
max_toi: f32,
solid: bool
) -> Option<RayIntersection>
Computes the time of impact, and normal between this transformed shape and a ray.
Computes the time of impact between this transform shape and a ray.
Tests whether a ray intersects this transformed shape.
Computes the time of impact between this transform shape and a ray.
Computes the time of impact, and normal between this transformed shape and a ray.
Clones this shape into a boxed trait-object.
Computes the AABB of this shape.
Computes the bounding-sphere of this shape.
Computes the AABB of this shape with the given position.
Compute the mass-properties of this shape given its uniform density.
Gets the type tag of this shape.
Gets the underlying shape as an enum.
Convents this shape into its support mapping, if it has one.
Converts this shape to a polygonal feature-map, if it is one.
fn compute_bounding_sphere(
&self,
position: &Isometry<f32, Unit<Complex<f32>>, 2_usize>
) -> BoundingSphere
fn compute_bounding_sphere(
&self,
position: &Isometry<f32, Unit<Complex<f32>>, 2_usize>
) -> BoundingSphere
Computes the bounding-sphere of this shape with the given position.
The shape’s normal at the given point located on a specific feature.
Computes the swept AABB of this shape, i.e., the space it would occupy by moving from the given start position to the given end position. Read more
Clones this shape into a boxed trait-object.
Computes the AABB of this shape.
Computes the bounding-sphere of this shape.
Computes the AABB of this shape with the given position.
Compute the mass-properties of this shape given its uniform density.
Gets the type tag of this shape.
Gets the underlying shape as an enum.
Convents this shape into its support mapping, if it has one.
Converts this shape to a polygonal feature-map, if it is one.
fn compute_bounding_sphere(
&self,
position: &Isometry<f32, Unit<Complex<f32>>, 2_usize>
) -> BoundingSphere
fn compute_bounding_sphere(
&self,
position: &Isometry<f32, Unit<Complex<f32>>, 2_usize>
) -> BoundingSphere
Computes the bounding-sphere of this shape with the given position.
The shape’s normal at the given point located on a specific feature.
Computes the swept AABB of this shape, i.e., the space it would occupy by moving from the given start position to the given end position. Read more
Clones this shape into a boxed trait-object.
Computes the AABB of this shape.
Computes the bounding-sphere of this shape.
Computes the AABB of this shape with the given position.
Compute the mass-properties of this shape given its uniform density.
Gets the type tag of this shape.
Gets the underlying shape as an enum.
Convents this shape into its support mapping, if it has one.
Converts this shape to a polygonal feature-map, if it is one.
fn compute_bounding_sphere(
&self,
position: &Isometry<f32, Unit<Complex<f32>>, 2_usize>
) -> BoundingSphere
fn compute_bounding_sphere(
&self,
position: &Isometry<f32, Unit<Complex<f32>>, 2_usize>
) -> BoundingSphere
Computes the bounding-sphere of this shape with the given position.
The shape’s normal at the given point located on a specific feature.
Computes the swept AABB of this shape, i.e., the space it would occupy by moving from the given start position to the given end position. Read more
pub fn local_support_point(
&self,
dir: &Matrix<f32, Const<{_: usize}>, Const<1_usize>, ArrayStorage<f32, 2_usize, 1_usize>>
) -> OPoint<f32, Const<2_usize>>
Same as self.local_support_point
except that dir
is normalized.
Auto Trait Implementations
impl<S> RefUnwindSafe for RoundShape<S> where
S: RefUnwindSafe,
impl<S> Send for RoundShape<S> where
S: Send,
impl<S> Sync for RoundShape<S> where
S: Sync,
impl<S> Unpin for RoundShape<S> where
S: Unpin,
impl<S> UnwindSafe for RoundShape<S> where
S: UnwindSafe,
Blanket Implementations
Mutably borrows from an owned value. Read more
Convert Box<dyn Trait>
(where Trait: Downcast
) to Box<dyn Any>
. Box<dyn Any>
can
then be further downcast
into Box<ConcreteType>
where ConcreteType
implements Trait
. Read more
Convert Rc<Trait>
(where Trait: Downcast
) to Rc<Any>
. Rc<Any>
can then be
further downcast
into Rc<ConcreteType>
where ConcreteType
implements Trait
. Read more
Convert &Trait
(where Trait: Downcast
) to &Any
. This is needed since Rust cannot
generate &Any
’s vtable from &Trait
’s. Read more
Convert &mut Trait
(where Trait: Downcast
) to &Any
. This is needed since Rust cannot
generate &mut Any
’s vtable from &mut Trait
’s. Read more
The inverse inclusion map: attempts to construct self
from the equivalent element of its
superset. Read more
Checks if self
is actually part of its subset T
(and can be converted to it).
Use with care! Same as self.to_subset
but without any property checks. Always succeeds.
The inclusion map: converts self
to the equivalent element of its superset.