Rename Rot->Basis
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70d48ed37b
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77aeff0785
1 changed files with 45 additions and 45 deletions
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@ -30,7 +30,7 @@ pub trait Rotation2
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: Eq
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: Eq
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+ ApproxEq<S>
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+ ApproxEq<S>
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+ ToMat2<S>
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+ ToMat2<S>
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+ ToRot2<S>
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+ ToBasis2<S>
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{
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{
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fn rotate_point2(&self, point: &Point2<S>) -> Point2<S>;
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fn rotate_point2(&self, point: &Point2<S>) -> Point2<S>;
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fn rotate_vec2(&self, vec: &Vec2<S>) -> Vec2<S>;
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fn rotate_vec2(&self, vec: &Vec2<S>) -> Vec2<S>;
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@ -49,7 +49,7 @@ pub trait Rotation3
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: Eq
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: Eq
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+ ApproxEq<S>
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+ ApproxEq<S>
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+ ToMat3<S>
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+ ToMat3<S>
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+ ToRot3<S>
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+ ToBasis3<S>
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+ ToQuat<S>
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+ ToQuat<S>
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{
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{
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fn rotate_point3(&self, point: &Point3<S>) -> Point3<S>;
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fn rotate_point3(&self, point: &Point3<S>) -> Point3<S>;
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@ -68,30 +68,30 @@ pub trait Rotation3
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/// enforce orthogonality at the type level the operations have been restricted
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/// enforce orthogonality at the type level the operations have been restricted
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/// to a subeset of those implemented on `Mat2`.
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/// to a subeset of those implemented on `Mat2`.
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#[deriving(Eq, Clone)]
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#[deriving(Eq, Clone)]
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pub struct Rot2<S> {
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pub struct Basis2<S> {
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priv mat: Mat2<S>
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priv mat: Mat2<S>
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}
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}
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impl<S: Float> Rot2<S> {
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impl<S: Float> Basis2<S> {
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#[inline]
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#[inline]
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pub fn as_mat2<'a>(&'a self) -> &'a Mat2<S> { &'a self.mat }
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pub fn as_mat2<'a>(&'a self) -> &'a Mat2<S> { &'a self.mat }
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}
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}
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pub trait ToRot2<S: Float> {
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pub trait ToBasis2<S: Float> {
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fn to_rot2(&self) -> Rot2<S>;
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fn to_rot2(&self) -> Basis2<S>;
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}
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}
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impl<S: Float> ToRot2<S> for Rot2<S> {
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impl<S: Float> ToBasis2<S> for Basis2<S> {
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#[inline]
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#[inline]
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fn to_rot2(&self) -> Rot2<S> { self.clone() }
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fn to_rot2(&self) -> Basis2<S> { self.clone() }
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}
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}
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impl<S: Float> ToMat2<S> for Rot2<S> {
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impl<S: Float> ToMat2<S> for Basis2<S> {
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#[inline]
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#[inline]
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fn to_mat2(&self) -> Mat2<S> { self.mat.clone() }
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fn to_mat2(&self) -> Mat2<S> { self.mat.clone() }
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}
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}
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impl<S: Float> Rotation2<S> for Rot2<S> {
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impl<S: Float> Rotation2<S> for Basis2<S> {
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#[inline]
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#[inline]
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fn rotate_point2(&self, _point: &Point2<S>) -> Point2<S> { fail!("Not yet implemented") }
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fn rotate_point2(&self, _point: &Point2<S>) -> Point2<S> { fail!("Not yet implemented") }
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@ -102,15 +102,15 @@ impl<S: Float> Rotation2<S> for Rot2<S> {
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fn rotate_ray2(&self, _ray: &Ray2<S>) -> Ray2<S> { fail!("Not yet implemented") }
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fn rotate_ray2(&self, _ray: &Ray2<S>) -> Ray2<S> { fail!("Not yet implemented") }
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#[inline]
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#[inline]
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fn concat(&self, other: &Rot2<S>) -> Rot2<S> { Rot2 { mat: self.mat.mul_m(&other.mat) } }
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fn concat(&self, other: &Basis2<S>) -> Basis2<S> { Basis2 { mat: self.mat.mul_m(&other.mat) } }
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#[inline]
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#[inline]
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fn concat_self(&mut self, other: &Rot2<S>) { self.mat.mul_self_m(&other.mat); }
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fn concat_self(&mut self, other: &Basis2<S>) { self.mat.mul_self_m(&other.mat); }
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// TODO: we know the matrix is orthogonal, so this could be re-written
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// TODO: we know the matrix is orthogonal, so this could be re-written
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// to be faster
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// to be faster
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#[inline]
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#[inline]
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fn invert(&self) -> Rot2<S> { Rot2 { mat: self.mat.invert().unwrap() } }
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fn invert(&self) -> Basis2<S> { Basis2 { mat: self.mat.invert().unwrap() } }
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// TODO: we know the matrix is orthogonal, so this could be re-written
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// TODO: we know the matrix is orthogonal, so this could be re-written
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// to be faster
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// to be faster
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@ -118,7 +118,7 @@ impl<S: Float> Rotation2<S> for Rot2<S> {
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fn invert_self(&mut self) { self.mat.invert_self(); }
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fn invert_self(&mut self) { self.mat.invert_self(); }
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}
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}
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impl<S: Float> ApproxEq<S> for Rot2<S> {
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impl<S: Float> ApproxEq<S> for Basis2<S> {
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#[inline]
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#[inline]
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fn approx_epsilon() -> S {
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fn approx_epsilon() -> S {
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// TODO: fix this after static methods are fixed in rustc
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// TODO: fix this after static methods are fixed in rustc
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@ -126,12 +126,12 @@ impl<S: Float> ApproxEq<S> for Rot2<S> {
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}
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}
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#[inline]
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#[inline]
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fn approx_eq(&self, other: &Rot2<S>) -> bool {
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fn approx_eq(&self, other: &Basis2<S>) -> bool {
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self.mat.approx_eq(&other.mat)
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self.mat.approx_eq(&other.mat)
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}
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}
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#[inline]
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#[inline]
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fn approx_eq_eps(&self, other: &Rot2<S>, approx_epsilon: &S) -> bool {
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fn approx_eq_eps(&self, other: &Basis2<S>, approx_epsilon: &S) -> bool {
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self.mat.approx_eq_eps(&other.mat, approx_epsilon)
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self.mat.approx_eq_eps(&other.mat, approx_epsilon)
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}
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}
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}
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}
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@ -143,29 +143,29 @@ impl<S: Float> ApproxEq<S> for Rot2<S> {
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/// `math::Mat3`. To ensure orthogonality is maintained, the operations have
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/// `math::Mat3`. To ensure orthogonality is maintained, the operations have
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/// been restricted to a subeset of those implemented on `Mat3`.
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/// been restricted to a subeset of those implemented on `Mat3`.
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#[deriving(Eq, Clone)]
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#[deriving(Eq, Clone)]
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pub struct Rot3<S> {
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pub struct Basis3<S> {
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priv mat: Mat3<S>
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priv mat: Mat3<S>
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}
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}
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impl<S: Float> Rot3<S> {
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impl<S: Float> Basis3<S> {
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#[inline]
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#[inline]
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pub fn look_at(dir: &Vec3<S>, up: &Vec3<S>) -> Rot3<S> {
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pub fn look_at(dir: &Vec3<S>, up: &Vec3<S>) -> Basis3<S> {
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Rot3 { mat: Mat3::look_at(dir, up) }
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Basis3 { mat: Mat3::look_at(dir, up) }
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}
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}
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/// Create a rotation matrix from a rotation around the `x` axis (pitch).
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/// Create a rotation matrix from a rotation around the `x` axis (pitch).
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pub fn from_angle_x(theta: Rad<S>) -> Rot3<S> {
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pub fn from_angle_x(theta: Rad<S>) -> Basis3<S> {
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Rot3 { mat: Mat3::from_angle_x(theta) }
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Basis3 { mat: Mat3::from_angle_x(theta) }
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}
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}
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/// Create a rotation matrix from a rotation around the `y` axis (yaw).
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/// Create a rotation matrix from a rotation around the `y` axis (yaw).
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pub fn from_angle_y(theta: Rad<S>) -> Rot3<S> {
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pub fn from_angle_y(theta: Rad<S>) -> Basis3<S> {
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Rot3 { mat: Mat3::from_angle_y(theta) }
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Basis3 { mat: Mat3::from_angle_y(theta) }
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}
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}
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/// Create a rotation matrix from a rotation around the `z` axis (roll).
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/// Create a rotation matrix from a rotation around the `z` axis (roll).
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pub fn from_angle_z(theta: Rad<S>) -> Rot3<S> {
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pub fn from_angle_z(theta: Rad<S>) -> Basis3<S> {
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Rot3 { mat: Mat3::from_angle_z(theta) }
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Basis3 { mat: Mat3::from_angle_z(theta) }
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}
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}
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/// Create a rotation matrix from a set of euler angles.
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/// Create a rotation matrix from a set of euler angles.
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@ -175,39 +175,39 @@ impl<S: Float> Rot3<S> {
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/// - `x`: the angular rotation around the `x` axis (pitch).
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/// - `x`: the angular rotation around the `x` axis (pitch).
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/// - `y`: the angular rotation around the `y` axis (yaw).
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/// - `y`: the angular rotation around the `y` axis (yaw).
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/// - `z`: the angular rotation around the `z` axis (roll).
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/// - `z`: the angular rotation around the `z` axis (roll).
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pub fn from_euler(x: Rad<S>, y: Rad<S>, z: Rad<S>) -> Rot3<S> {
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pub fn from_euler(x: Rad<S>, y: Rad<S>, z: Rad<S>) -> Basis3<S> {
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Rot3 { mat: Mat3::from_euler(x, y ,z) }
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Basis3 { mat: Mat3::from_euler(x, y ,z) }
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}
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}
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/// Create a rotation matrix from a rotation around an arbitrary axis.
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/// Create a rotation matrix from a rotation around an arbitrary axis.
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pub fn from_axis_angle(axis: &Vec3<S>, angle: Rad<S>) -> Rot3<S> {
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pub fn from_axis_angle(axis: &Vec3<S>, angle: Rad<S>) -> Basis3<S> {
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Rot3 { mat: Mat3::from_axis_angle(axis, angle) }
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Basis3 { mat: Mat3::from_axis_angle(axis, angle) }
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}
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}
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#[inline]
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#[inline]
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pub fn as_mat3<'a>(&'a self) -> &'a Mat3<S> { &'a self.mat }
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pub fn as_mat3<'a>(&'a self) -> &'a Mat3<S> { &'a self.mat }
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}
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}
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pub trait ToRot3<S: Float> {
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pub trait ToBasis3<S: Float> {
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fn to_rot3(&self) -> Rot3<S>;
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fn to_rot3(&self) -> Basis3<S>;
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}
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}
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impl<S: Float> ToRot3<S> for Rot3<S> {
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impl<S: Float> ToBasis3<S> for Basis3<S> {
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#[inline]
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#[inline]
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fn to_rot3(&self) -> Rot3<S> { self.clone() }
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fn to_rot3(&self) -> Basis3<S> { self.clone() }
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}
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}
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impl<S: Float> ToMat3<S> for Rot3<S> {
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impl<S: Float> ToMat3<S> for Basis3<S> {
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#[inline]
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#[inline]
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fn to_mat3(&self) -> Mat3<S> { self.mat.clone() }
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fn to_mat3(&self) -> Mat3<S> { self.mat.clone() }
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}
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}
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impl<S: Float> ToQuat<S> for Rot3<S> {
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impl<S: Float> ToQuat<S> for Basis3<S> {
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#[inline]
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#[inline]
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fn to_quat(&self) -> Quat<S> { self.mat.to_quat() }
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fn to_quat(&self) -> Quat<S> { self.mat.to_quat() }
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}
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}
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impl<S: Float> Rotation3<S> for Rot3<S> {
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impl<S: Float> Rotation3<S> for Basis3<S> {
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#[inline]
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#[inline]
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fn rotate_point3(&self, _point: &Point3<S>) -> Point3<S> { fail!("Not yet implemented") }
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fn rotate_point3(&self, _point: &Point3<S>) -> Point3<S> { fail!("Not yet implemented") }
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@ -218,15 +218,15 @@ impl<S: Float> Rotation3<S> for Rot3<S> {
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fn rotate_ray3(&self, _ray: &Ray3<S>) -> Ray3<S> { fail!("Not yet implemented") }
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fn rotate_ray3(&self, _ray: &Ray3<S>) -> Ray3<S> { fail!("Not yet implemented") }
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#[inline]
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#[inline]
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fn concat(&self, other: &Rot3<S>) -> Rot3<S> { Rot3 { mat: self.mat.mul_m(&other.mat) } }
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fn concat(&self, other: &Basis3<S>) -> Basis3<S> { Basis3 { mat: self.mat.mul_m(&other.mat) } }
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#[inline]
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#[inline]
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fn concat_self(&mut self, other: &Rot3<S>) { self.mat.mul_self_m(&other.mat); }
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fn concat_self(&mut self, other: &Basis3<S>) { self.mat.mul_self_m(&other.mat); }
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// TODO: we know the matrix is orthogonal, so this could be re-written
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// TODO: we know the matrix is orthogonal, so this could be re-written
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// to be faster
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// to be faster
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#[inline]
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#[inline]
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fn invert(&self) -> Rot3<S> { Rot3 { mat: self.mat.invert().unwrap() } }
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fn invert(&self) -> Basis3<S> { Basis3 { mat: self.mat.invert().unwrap() } }
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// TODO: we know the matrix is orthogonal, so this could be re-written
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// TODO: we know the matrix is orthogonal, so this could be re-written
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// to be faster
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// to be faster
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@ -234,7 +234,7 @@ impl<S: Float> Rotation3<S> for Rot3<S> {
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fn invert_self(&mut self) { self.mat.invert_self(); }
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fn invert_self(&mut self) { self.mat.invert_self(); }
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}
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}
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impl<S: Float> ApproxEq<S> for Rot3<S> {
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impl<S: Float> ApproxEq<S> for Basis3<S> {
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#[inline]
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#[inline]
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fn approx_epsilon() -> S {
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fn approx_epsilon() -> S {
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// TODO: fix this after static methods are fixed in rustc
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// TODO: fix this after static methods are fixed in rustc
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@ -242,21 +242,21 @@ impl<S: Float> ApproxEq<S> for Rot3<S> {
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}
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}
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#[inline]
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#[inline]
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fn approx_eq(&self, other: &Rot3<S>) -> bool {
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fn approx_eq(&self, other: &Basis3<S>) -> bool {
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self.mat.approx_eq(&other.mat)
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self.mat.approx_eq(&other.mat)
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}
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}
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#[inline]
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#[inline]
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fn approx_eq_eps(&self, other: &Rot3<S>, approx_epsilon: &S) -> bool {
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fn approx_eq_eps(&self, other: &Basis3<S>, approx_epsilon: &S) -> bool {
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self.mat.approx_eq_eps(&other.mat, approx_epsilon)
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self.mat.approx_eq_eps(&other.mat, approx_epsilon)
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}
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}
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}
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}
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// Quaternion Rotation impls
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// Quaternion Rotation impls
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impl<S: Float> ToRot3<S> for Quat<S> {
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impl<S: Float> ToBasis3<S> for Quat<S> {
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#[inline]
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#[inline]
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fn to_rot3(&self) -> Rot3<S> { Rot3 { mat: self.to_mat3() } }
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fn to_rot3(&self) -> Basis3<S> { Basis3 { mat: self.to_mat3() } }
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}
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}
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impl<S: Float> ToQuat<S> for Quat<S> {
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impl<S: Float> ToQuat<S> for Quat<S> {
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