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use crate::math::{Isometry, Point, Real, Vector};
use crate::shape::SupportMap;
use na::Unit;
use std::ops::Sub;
/// A point of a Configuration-Space Obstacle.
///
/// A Configuration-Space Obstacle (CSO) is the result of the
/// Minkowski Difference of two solids. In other words, each of its
/// points correspond to the difference of two point, each belonging
/// to a different solid.
#[derive(Copy, Clone, Debug, PartialEq)]
pub struct CSOPoint {
/// The point on the CSO. This is equal to `self.orig1 - self.orig2`, unless this CSOPoint
/// has been translated with self.translate.
pub point: Point<Real>,
/// The original point on the first shape used to compute `self.point`.
pub orig1: Point<Real>,
/// The original point on the second shape used to compute `self.point`.
pub orig2: Point<Real>,
}
impl CSOPoint {
/// Initializes a CSO point with `orig1 - orig2`.
pub fn new(orig1: Point<Real>, orig2: Point<Real>) -> Self {
let point = Point::from(orig1 - orig2);
Self::new_with_point(point, orig1, orig2)
}
/// Initializes a CSO point with all information provided.
///
/// It is assumed, but not checked, that `point == orig1 - orig2`.
pub fn new_with_point(point: Point<Real>, orig1: Point<Real>, orig2: Point<Real>) -> Self {
CSOPoint {
point,
orig1,
orig2,
}
}
/// Initializes a CSO point where both original points are equal.
pub fn single_point(point: Point<Real>) -> Self {
Self::new_with_point(point, point, Point::origin())
}
/// CSO point where all components are set to zero.
pub fn origin() -> Self {
CSOPoint::new(Point::origin(), Point::origin())
}
/// Computes the support point of the CSO of `g1` and `g2` toward the unit direction `dir`.
pub fn from_shapes_toward<G1: ?Sized, G2: ?Sized>(
pos12: &Isometry<Real>,
g1: &G1,
g2: &G2,
dir: &Unit<Vector<Real>>,
) -> Self
where
G1: SupportMap,
G2: SupportMap,
{
let sp1 = g1.local_support_point_toward(dir);
let sp2 = g2.support_point_toward(pos12, &-*dir);
CSOPoint::new(sp1, sp2)
}
/// Computes the support point of the CSO of `g1` and `g2` toward the direction `dir`.
pub fn from_shapes<G1: ?Sized, G2: ?Sized>(
pos12: &Isometry<Real>,
g1: &G1,
g2: &G2,
dir: &Vector<Real>,
) -> Self
where
G1: SupportMap,
G2: SupportMap,
{
let sp1 = g1.local_support_point(dir);
let sp2 = g2.support_point(pos12, &-*dir);
CSOPoint::new(sp1, sp2)
}
/// Translate the CSO point.
pub fn translate(&self, dir: &Vector<Real>) -> Self {
CSOPoint::new_with_point(self.point + dir, self.orig1, self.orig2)
}
/// Translate in-place the CSO point.
pub fn translate_mut(&mut self, dir: &Vector<Real>) {
self.point += dir;
}
}
impl Sub<CSOPoint> for CSOPoint {
type Output = Vector<Real>;
#[inline]
fn sub(self, rhs: CSOPoint) -> Vector<Real> {
self.point - rhs.point
}
}