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//! Support mapping based Cuboid shape.
use crate::math::{Point, Real, Vector};
#[cfg(feature = "dim3")]
use crate::shape::Segment;
use crate::shape::{FeatureId, PackedFeatureId, PolygonalFeature, SupportMap};
use crate::utils::WSign;
use na::Unit;
#[cfg(not(feature = "std"))]
use na::RealField; // for .copysign()
#[cfg(feature = "rkyv")]
use rkyv::{bytecheck, CheckBytes};
/// Shape of a box.
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
#[cfg_attr(feature = "bytemuck", derive(bytemuck::Pod, bytemuck::Zeroable))]
#[cfg_attr(
feature = "rkyv",
derive(rkyv::Archive, rkyv::Deserialize, rkyv::Serialize, CheckBytes),
archive(as = "Self")
)]
#[cfg_attr(feature = "cuda", derive(cust_core::DeviceCopy))]
#[derive(PartialEq, Debug, Copy, Clone)]
#[repr(C)]
pub struct Cuboid {
/// The half-extents of the cuboid.
pub half_extents: Vector<Real>,
}
impl Cuboid {
/// Creates a new box from its half-extents. Half-extents are the box half-width along each
/// axis. Each half-extent must be positive.
#[inline]
pub fn new(half_extents: Vector<Real>) -> Cuboid {
Cuboid { half_extents }
}
/// Computes a scaled version of this cuboid.
pub fn scaled(self, scale: &Vector<Real>) -> Self {
let new_hext = self.half_extents.component_mul(scale);
Self {
half_extents: new_hext,
}
}
/// Return the id of the vertex of this cuboid with a normal that maximizes
/// the dot product with `dir`.
#[cfg(feature = "dim2")]
pub fn vertex_feature_id(vertex: Point<Real>) -> u32 {
// FIXME: is this still correct with the f64 version?
#[allow(clippy::unnecessary_cast)] // Unnecessary for f32 but necessary for f64.
{
((vertex.x.to_bits() >> 31) & 0b001 | (vertex.y.to_bits() >> 30) & 0b010) as u32
}
}
/// Return the feature of this cuboid with a normal that maximizes
/// the dot product with `dir`.
#[cfg(feature = "dim2")]
pub fn support_feature(&self, local_dir: Vector<Real>) -> PolygonalFeature {
// In 2D, it is best for stability to always return a face.
// It won't have any notable impact on performances anyway.
self.support_face(local_dir)
}
/// Return the face of this cuboid with a normal that maximizes
/// the dot product with `local_dir`.
#[cfg(feature = "dim2")]
pub fn support_face(&self, local_dir: Vector<Real>) -> PolygonalFeature {
let he = self.half_extents;
let i = local_dir.iamin();
let j = (i + 1) % 2;
let mut a = Point::origin();
a[i] = he[i];
a[j] = he[j].copysign(local_dir[j]);
let mut b = a;
b[i] = -he[i];
let vid1 = Self::vertex_feature_id(a);
let vid2 = Self::vertex_feature_id(b);
let fid = (vid1.max(vid2) << 2) | vid1.min(vid2) | 0b11_00_00;
PolygonalFeature {
vertices: [a, b],
vids: PackedFeatureId::vertices([vid1, vid2]),
fid: PackedFeatureId::face(fid),
num_vertices: 2,
}
}
/// Return the face of this cuboid with a normal that maximizes
/// the dot product with `local_dir`.
#[cfg(feature = "dim3")]
pub fn support_feature(&self, local_dir: Vector<Real>) -> PolygonalFeature {
// FIXME: this should actually return the feature.
// And we should change all the callers of this method to use
// `.support_face` instead of this method to preserve their old behavior.
self.support_face(local_dir)
/*
const MAX_DOT_THRESHOLD: Real = crate::utils::COS_10_DEGREES;
const MIN_DOT_THRESHOLD: Real = 1.0 - MAX_DOT_THRESHOLD;
let amax = local_dir.amax();
let amin = local_dir.amin();
if amax > MAX_DOT_THRESHOLD {
// Support face.
CuboidFeature::Face(support_face(self, local_dir))
} else if amin < MIN_DOT_THRESHOLD {
// Support edge.
CuboidFeature::Edge(support_edge(self, local_dir))
} else {
// Support vertex.
CuboidFeature::Vertex(support_vertex(self, local_dir))
}
*/
}
// #[cfg(feature = "dim3")
// pub(crate) fn support_vertex(&self, local_dir: Vector<Real>) -> CuboidFeatureVertex {
// let vertex = local_support_point(self, local_dir);
// let vid = vertex_feature_id(vertex);
//
// CuboidFeatureVertex { vertex, vid }
// }
/// Return the edge segment of this cuboid with a normal cone containing
/// a direction that that maximizes the dot product with `local_dir`.
#[cfg(feature = "dim3")]
pub fn local_support_edge_segment(&self, local_dir: Vector<Real>) -> Segment {
let he = self.half_extents;
let i = local_dir.iamin();
let j = (i + 1) % 3;
let k = (i + 2) % 3;
let mut a = Point::origin();
a[i] = he[i];
a[j] = he[j].copysign(local_dir[j]);
a[k] = he[k].copysign(local_dir[k]);
let mut b = a;
b[i] = -he[i];
Segment::new(a, b)
}
/// Computes the face with a normal that maximizes the dot-product with `local_dir`.
#[cfg(feature = "dim3")]
pub fn support_face(&self, local_dir: Vector<Real>) -> PolygonalFeature {
// NOTE: can we use the orthonormal basis of local_dir
// to make this AoSoA friendly?
let he = self.half_extents;
let iamax = local_dir.iamax();
let sign = (1.0 as Real).copysign(local_dir[iamax]);
let vertices = match iamax {
0 => [
Point::new(he.x * sign, he.y, he.z),
Point::new(he.x * sign, -he.y, he.z),
Point::new(he.x * sign, -he.y, -he.z),
Point::new(he.x * sign, he.y, -he.z),
],
1 => [
Point::new(he.x, he.y * sign, he.z),
Point::new(-he.x, he.y * sign, he.z),
Point::new(-he.x, he.y * sign, -he.z),
Point::new(he.x, he.y * sign, -he.z),
],
2 => [
Point::new(he.x, he.y, he.z * sign),
Point::new(he.x, -he.y, he.z * sign),
Point::new(-he.x, -he.y, he.z * sign),
Point::new(-he.x, he.y, he.z * sign),
],
_ => unreachable!(),
};
pub fn vid(i: u32) -> u32 {
// Each vertex has an even feature id.
i * 2
}
let sign_index = ((sign as i8 + 1) / 2) as usize;
// The vertex id as numbered depending on the sign of the vertex
// component. A + sign means the corresponding bit is 0 while a -
// sign means the corresponding bit is 1.
// For exampl the vertex [2.0, -1.0, -3.0] has the id 0b011
let vids = match iamax {
0 => [
[vid(0b000), vid(0b010), vid(0b011), vid(0b001)],
[vid(0b100), vid(0b110), vid(0b111), vid(0b101)],
][sign_index],
1 => [
[vid(0b000), vid(0b100), vid(0b101), vid(0b001)],
[vid(0b010), vid(0b110), vid(0b111), vid(0b011)],
][sign_index],
2 => [
[vid(0b000), vid(0b010), vid(0b110), vid(0b100)],
[vid(0b001), vid(0b011), vid(0b111), vid(0b101)],
][sign_index],
_ => unreachable!(),
};
// The feature ids of edges is obtained from the vertex ids
// of their endpoints.
// Assuming vid1 > vid2, we do: (vid1 << 3) | vid2 | 0b11000000
//
let eids = match iamax {
0 => [
[0b11_010_000, 0b11_011_010, 0b11_011_001, 0b11_001_000],
[0b11_110_100, 0b11_111_110, 0b11_111_101, 0b11_101_100],
][sign_index],
1 => [
[0b11_100_000, 0b11_101_100, 0b11_101_001, 0b11_001_000],
[0b11_110_010, 0b11_111_110, 0b11_111_011, 0b11_011_010],
][sign_index],
2 => [
[0b11_010_000, 0b11_110_010, 0b11_110_100, 0b11_100_000],
[0b11_011_001, 0b11_111_011, 0b11_111_101, 0b11_101_001],
][sign_index],
_ => unreachable!(),
};
// The face with normals [x, y, z] are numbered [10, 11, 12].
// The face with negated normals are numbered [13, 14, 15].
let fid = iamax + sign_index * 3 + 10;
PolygonalFeature {
vertices,
vids: PackedFeatureId::vertices(vids),
eids: PackedFeatureId::edges(eids),
fid: PackedFeatureId::face(fid as u32),
num_vertices: 4,
}
}
/// The normal of the given feature of this shape.
#[cfg(feature = "dim2")]
pub fn feature_normal(&self, feature: FeatureId) -> Option<Unit<Vector<Real>>> {
match feature {
FeatureId::Face(id) => {
let mut dir: Vector<Real> = na::zero();
if id < 2 {
dir[id as usize] = 1.0;
} else {
dir[id as usize - 2] = -1.0;
}
Some(Unit::new_unchecked(dir))
}
FeatureId::Vertex(id) => {
let mut dir: Vector<Real> = na::zero();
match id {
0b00 => {
dir[0] = 1.0;
dir[1] = 1.0;
}
0b01 => {
dir[1] = 1.0;
dir[0] = -1.0;
}
0b11 => {
dir[0] = -1.0;
dir[1] = -1.0;
}
0b10 => {
dir[1] = -1.0;
dir[0] = 1.0;
}
_ => return None,
}
Some(Unit::new_normalize(dir))
}
_ => None,
}
}
/// The normal of the given feature of this shape.
#[cfg(feature = "dim3")]
pub fn feature_normal(&self, feature: FeatureId) -> Option<Unit<Vector<Real>>> {
match feature {
FeatureId::Face(id) => {
let mut dir: Vector<Real> = na::zero();
if id < 3 {
dir[id as usize] = 1.0;
} else {
dir[id as usize - 3] = -1.0;
}
Some(Unit::new_unchecked(dir))
}
FeatureId::Edge(id) => {
let edge = id & 0b011;
let face1 = (edge + 1) % 3;
let face2 = (edge + 2) % 3;
let signs = id >> 2;
let mut dir: Vector<Real> = na::zero();
if signs & (1 << face1) != 0 {
dir[face1 as usize] = -1.0
} else {
dir[face1 as usize] = 1.0
}
if signs & (1 << face2) != 0 {
dir[face2 as usize] = -1.0
} else {
dir[face2 as usize] = 1.0;
}
Some(Unit::new_normalize(dir))
}
FeatureId::Vertex(id) => {
let mut dir: Vector<Real> = na::zero();
for i in 0..3 {
if id & (1 << i) != 0 {
dir[i] = -1.0;
} else {
dir[i] = 1.0
}
}
Some(Unit::new_normalize(dir))
}
_ => None,
}
}
}
impl SupportMap for Cuboid {
#[inline]
fn local_support_point(&self, dir: &Vector<Real>) -> Point<Real> {
dir.copy_sign_to(self.half_extents).into()
}
}
/*
impl ConvexPolyhedron for Cuboid {
fn vertex(&self, id: FeatureId) -> Point<Real> {
let vid = id.unwrap_vertex();
let mut res = self.half_extents;
for i in 0..DIM {
if vid & (1 << i) != 0 {
res[i] = -res[i]
}
}
Point::from(res)
}
#[cfg(feature = "dim3")]
fn edge(&self, id: FeatureId) -> (Point<Real>, Point<Real>, FeatureId, FeatureId) {
let eid = id.unwrap_edge();
let mut res = self.half_extents;
let edge_i = eid & 0b11;
let vertex_i = eid >> 2;
for i in 0..DIM {
if i as u32 != edge_i && (vertex_i & (1 << i) != 0) {
res[i] = -res[i]
}
}
let p1 = Point::from(res);
res[edge_i as usize] = -res[edge_i as usize];
let p2 = Point::from(res);
let vid1 = FeatureId::Vertex(vertex_i & !(1 << edge_i));
let vid2 = FeatureId::Vertex(vertex_i | (1 << edge_i));
(p1, p2, vid1, vid2)
}
fn face(&self, id: FeatureId, out: &mut ConvexPolygonalFeature) {
out.clear();
let i = id.unwrap_face() as usize;
let i1;
let sign;
if i < DIM {
i1 = i;
sign = 1.0;
} else {
i1 = i - DIM;
sign = -1.0;
}
#[cfg(feature = "dim2")]
{
let i2 = (i1 + 1) % 2;
let mut vertex = self.half_extents;
vertex[i1] *= sign;
vertex[i2] *= if i1 == 0 { -sign } else { sign };
let p1 = Point::from(vertex);
vertex[i2] = -vertex[i2];
let p2 = Point::from(vertex);
let mut vertex_id1 = if sign < 0.0 {
1 << i1
} else {
0
};
let mut vertex_id2 = vertex_id1;
if p1[i2] < 0.0 {
vertex_id1 |= 1 << i2;
} else {
vertex_id2 |= 1 << i2;
}
out.push(p1, FeatureId::Vertex(vertex_id1));
out.push(p2, FeatureId::Vertex(vertex_id2));
let mut normal: Vector<Real> = na::zero();
normal[i1] = sign;
out.set_normal(Unit::new_unchecked(normal));
out.set_feature_id(FeatureId::Face(i as u32));
}
#[cfg(feature = "dim3")]
{
let i2 = (i1 + 1) % 3;
let i3 = (i1 + 2) % 3;
let (edge_i2, edge_i3) = if sign > 0.0 {
(i2, i3)
} else {
(i3, i2)
};
let mask_i2 = !(1 << edge_i2); // The masks are for ensuring each edge has a unique ID.
let mask_i3 = !(1 << edge_i3);
let mut vertex = self.half_extents;
vertex[i1] *= sign;
let (sbit, msbit) = if sign < 0.0 {
(1, 0)
} else {
(0, 1)
};
let mut vertex_id = sbit << i1;
out.push(Point::from(vertex), FeatureId::Vertex(vertex_id));
out.push_edge_feature_id(FeatureId::Edge(
edge_i2 as u32 | ((vertex_id & mask_i2) << 2),
));
vertex[i2] = -sign * self.half_extents[i2];
vertex[i3] = sign * self.half_extents[i3];
vertex_id |= msbit << i2 | sbit << i3;
out.push(Point::from(vertex), FeatureId::Vertex(vertex_id));
out.push_edge_feature_id(FeatureId::Edge(
edge_i3 as u32 | ((vertex_id & mask_i3) << 2),
));
vertex[i2] = -self.half_extents[i2];
vertex[i3] = -self.half_extents[i3];
vertex_id |= 1 << i2 | 1 << i3;
out.push(Point::from(vertex), FeatureId::Vertex(vertex_id));
out.push_edge_feature_id(FeatureId::Edge(
edge_i2 as u32 | ((vertex_id & mask_i2) << 2),
));
vertex[i2] = sign * self.half_extents[i2];
vertex[i3] = -sign * self.half_extents[i3];
vertex_id = sbit << i1 | sbit << i2 | msbit << i3;
out.push(Point::from(vertex), FeatureId::Vertex(vertex_id));
out.push_edge_feature_id(FeatureId::Edge(
edge_i3 as u32 | ((vertex_id & mask_i3) << 2),
));
let mut normal: Vector<Real> = na::zero();
normal[i1] = sign;
out.set_normal(Unit::new_unchecked(normal));
if sign > 0.0 {
out.set_feature_id(FeatureId::Face(i1 as u32));
} else {
out.set_feature_id(FeatureId::Face(i1 as u32 + 3));
}
out.recompute_edge_normals();
}
}
fn support_face_toward(
&self,
m: &Isometry<Real>,
dir: &Unit<Vector<Real>>,
out: &mut ConvexPolygonalFeature,
) {
out.clear();
let local_dir = m.inverse_transform_vector(dir);
let mut iamax = 0;
let mut amax = local_dir[0].abs();
// FIXME: we should use nalgebra's iamax method.
for i in 1..DIM {
let candidate = local_dir[i].abs();
if candidate > amax {
amax = candidate;
iamax = i;
}
}
if local_dir[iamax] > 0.0 {
self.face(FeatureId::Face(iamax as u32), out);
out.transform_by(m);
} else {
self.face(FeatureId::Face((iamax + DIM) as u32), out);
out.transform_by(m);
}
}
fn support_feature_toward(
&self,
m: &Isometry<Real>,
dir: &Unit<Vector<Real>>,
angle: Real,
out: &mut ConvexPolygonalFeature,
) {
let local_dir = m.inverse_transform_vector(dir);
let cang = ComplexField::cos(angle);
let mut support_point = self.half_extents;
out.clear();
#[cfg(feature = "dim2")]
{
let mut support_point_id = 0;
for i1 in 0..2 {
let sign = local_dir[i1].signum();
if sign * local_dir[i1] >= cang {
if sign > 0.0 {
self.face(FeatureId::Face(i1 as u32), out);
out.transform_by(m);
} else {
self.face(FeatureId::Face(i1 as u32 + 2), out);
out.transform_by(m);
}
return;
} else {
if sign < 0.0 {
support_point_id |= 1 << i1;
}
support_point[i1] *= sign;
}
}
// We are not on a face, return the support vertex.
out.push(
m * Point::from(support_point),
FeatureId::Vertex(support_point_id),
);
out.set_feature_id(FeatureId::Vertex(support_point_id));
}
#[cfg(feature = "dim3")]
{
let sang = ComplexField::sin(angle);
let mut support_point_id = 0;
// Check faces.
for i1 in 0..3 {
let sign = local_dir[i1].signum();
if sign * local_dir[i1] >= cang {
if sign > 0.0 {
self.face(FeatureId::Face(i1 as u32), out);
out.transform_by(m);
} else {
self.face(FeatureId::Face(i1 as u32 + 3), out);
out.transform_by(m);
}
return;
} else {
if sign < 0.0 {
support_point[i1] *= sign;
support_point_id |= 1 << i1;
}
}
}
// Check edges.
for i in 0..3 {
let sign = local_dir[i].signum();
// sign * local_dir[i] <= cos(pi / 2 - angle)
if sign * local_dir[i] <= sang {
support_point[i] = -self.half_extents[i];
let p1 = Point::from(support_point);
support_point[i] = self.half_extents[i];
let p2 = Point::from(support_point);
let p2_id = support_point_id & !(1 << i);
out.push(m * p1, FeatureId::Vertex(support_point_id | (1 << i)));
out.push(m * p2, FeatureId::Vertex(p2_id));
let edge_id = FeatureId::Edge(i as u32 | (p2_id << 2));
out.push_edge_feature_id(edge_id);
out.set_feature_id(edge_id);
return;
}
}
// We are not on a face or edge, return the support vertex.
out.push(
m * Point::from(support_point),
FeatureId::Vertex(support_point_id),
);
out.set_feature_id(FeatureId::Vertex(support_point_id));
}
}
fn support_feature_id_toward(&self, local_dir: &Unit<Vector<Real>>) -> FeatureId {
let one_degree: Real = na::convert::<f64, Real>(f64::consts::PI / 180.0);
let cang = ComplexField::cos(one_degree);
#[cfg(feature = "dim2")]
{
let mut support_point_id = 0;
for i1 in 0..2 {
let sign = local_dir[i1].signum();
if sign * local_dir[i1] >= cang {
if sign > 0.0 {
return FeatureId::Face(i1 as u32);
} else {
return FeatureId::Face(i1 as u32 + 2);
}
} else {
if sign < 0.0 {
support_point_id |= 1 << i1;
}
}
}
// We are not on a face, return the support vertex.
FeatureId::Vertex(support_point_id)
}
#[cfg(feature = "dim3")]
{
let sang = ComplexField::sin(one_degree);
let mut support_point_id = 0;
// Check faces.
for i1 in 0..3 {
let sign = local_dir[i1].signum();
if sign * local_dir[i1] >= cang {
if sign > 0.0 {
return FeatureId::Face(i1 as u32);
} else {
return FeatureId::Face(i1 as u32 + 3);
}
} else {
if sign < 0.0 {
support_point_id |= 1 << i1;
}
}
}
// Check edges.
for i in 0..3 {
let sign = local_dir[i].signum();
// sign * local_dir[i] <= cos(pi / 2 - angle)
if sign * local_dir[i] <= sang {
let mask_i = !(1 << i); // To ensure each edge has a unique id.
return FeatureId::Edge(i as u32 | ((support_point_id & mask_i) << 2));
}
}
FeatureId::Vertex(support_point_id)
}
}
}
*/