forked from M-Labs/nalgebra
Add a quat_ perfix to all quaternion functions.
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@ -7,4 +7,5 @@
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* Function overload: the vec version is suffixed by _vec
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* Function overload: the methods taking an epsilon as suffixed by _eps
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* L1Norm and L2Norm between two vectors have been renamed: l1_distance, l2_distance
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* Matrix columnwise comparisons suffixed by _columns, e.g., `equal` -> `equal_columns`
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* Matrix columnwise comparisons suffixed by _columns, e.g., `equal` -> `equal_columns`
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* All quaternion functions are prefixed by quat_
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@ -8,6 +8,11 @@ pub use self::scalar_common::*;
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pub use self::scalar_constants::*;
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pub use self::vector_common::*;
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pub use self::vector_relational::*;
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pub use self::quaternion_common::*;
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pub use self::quaternion_geometric::*;
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pub use self::quaternion_relational::*;
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pub use self::quaternion_transform::*;
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pub use self::quaternion_trigonometric::*;
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mod matrix_clip_space;
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@ -17,4 +22,9 @@ mod matrix_transform;
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mod scalar_common;
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mod scalar_constants;
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mod vector_common;
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mod vector_relational;
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mod vector_relational;
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mod quaternion_common;
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mod quaternion_geometric;
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mod quaternion_relational;
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mod quaternion_transform;
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mod quaternion_trigonometric;
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@ -3,33 +3,33 @@ use na::{self, Real, Unit};
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use aliases::Qua;
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/// The conjugate of `q`.
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pub fn conjugate<N: Real>(q: &Qua<N>) -> Qua<N> {
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pub fn quat_conjugate<N: Real>(q: &Qua<N>) -> Qua<N> {
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q.conjugate()
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}
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/// The inverse of `q`.
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pub fn inverse<N: Real>(q: &Qua<N>) -> Qua<N> {
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pub fn quat_inverse<N: Real>(q: &Qua<N>) -> Qua<N> {
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q.try_inverse().unwrap_or(na::zero())
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}
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//pub fn isinf<N: Real>(x: &Qua<N>) -> Vec<bool, U4> {
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//pub fn quat_isinf<N: Real>(x: &Qua<N>) -> Vec<bool, U4> {
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// x.coords.map(|e| e.is_inf())
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//}
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//pub fn isnan<N: Real>(x: &Qua<N>) -> Vec<bool, U4> {
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//pub fn quat_isnan<N: Real>(x: &Qua<N>) -> Vec<bool, U4> {
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// x.coords.map(|e| e.is_nan())
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//}
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/// Interpolate linearly between `x` and `y`.
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pub fn lerp<N: Real>(x: &Qua<N>, y: &Qua<N>, a: N) -> Qua<N> {
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pub fn quat_lerp<N: Real>(x: &Qua<N>, y: &Qua<N>, a: N) -> Qua<N> {
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x.lerp(y, a)
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}
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//pub fn mix<N: Real>(x: &Qua<N>, y: &Qua<N>, a: N) -> Qua<N> {
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//pub fn quat_mix<N: Real>(x: &Qua<N>, y: &Qua<N>, a: N) -> Qua<N> {
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// x * (N::one() - a) + y * a
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//}
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/// Interpolate spherically between `x` and `y`.
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pub fn slerp<N: Real>(x: &Qua<N>, y: &Qua<N>, a: N) -> Qua<N> {
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pub fn quat_slerp<N: Real>(x: &Qua<N>, y: &Qua<N>, a: N) -> Qua<N> {
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Unit::new_normalize(*x).slerp(&Unit::new_normalize(*y), a).unwrap()
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}
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@ -3,26 +3,26 @@ use na::Real;
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use aliases::Qua;
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/// Multiplies two quaternions.
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pub fn cross<N: Real>(q1: &Qua<N>, q2: &Qua<N>) -> Qua<N> {
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pub fn quat_cross<N: Real>(q1: &Qua<N>, q2: &Qua<N>) -> Qua<N> {
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q1 * q2
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}
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/// The scalar product of two quaternions.
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pub fn dot<N: Real>(x: &Qua<N>, y: &Qua<N>) -> N {
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pub fn quat_dot<N: Real>(x: &Qua<N>, y: &Qua<N>) -> N {
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x.dot(y)
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}
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/// The magnitude of the quaternion `q`.
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pub fn length<N: Real>(q: &Qua<N>) -> N {
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pub fn quat_length<N: Real>(q: &Qua<N>) -> N {
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q.norm()
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}
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/// The magnitude of the quaternion `q`.
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pub fn magnitude<N: Real>(q: &Qua<N>) -> N {
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pub fn quat_magnitude<N: Real>(q: &Qua<N>) -> N {
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q.norm()
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}
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/// Normalizes the quaternion `q`.
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pub fn normalize<N: Real>(q: &Qua<N>) -> Qua<N> {
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pub fn quat_normalize<N: Real>(q: &Qua<N>) -> Qua<N> {
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q.normalize()
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}
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@ -4,21 +4,21 @@ use na::{Real, U4};
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use aliases::{Qua, Vec};
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/// Component-wise equality comparison between two quaternions.
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pub fn equal<N: Real>(x: &Qua<N>, y: &Qua<N>) -> Vec<bool, U4> {
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pub fn quat_equal<N: Real>(x: &Qua<N>, y: &Qua<N>) -> Vec<bool, U4> {
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::equal(&x.coords, &y.coords)
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}
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/// Component-wise approximate equality comparison between two quaternions.
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pub fn equal_eps<N: Real>(x: &Qua<N>, y: &Qua<N>, epsilon: N) -> Vec<bool, U4> {
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pub fn quat_equal_eps<N: Real>(x: &Qua<N>, y: &Qua<N>, epsilon: N) -> Vec<bool, U4> {
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::equal_eps(&x.coords, &y.coords, epsilon)
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}
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/// Component-wise non-equality comparison between two quaternions.
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pub fn not_equal<N: Real>(x: &Qua<N>, y: &Qua<N>) -> Vec<bool, U4> {
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pub fn quat_not_equal<N: Real>(x: &Qua<N>, y: &Qua<N>) -> Vec<bool, U4> {
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::not_equal(&x.coords, &y.coords)
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}
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/// Component-wise approximate non-equality comparison between two quaternions.
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pub fn not_equal_eps<N: Real>(x: &Qua<N>, y: &Qua<N>, epsilon: N) -> Vec<bool, U4> {
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pub fn quat_not_equal_eps<N: Real>(x: &Qua<N>, y: &Qua<N>, epsilon: N) -> Vec<bool, U4> {
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::not_equal_eps(&x.coords, &y.coords, epsilon)
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}
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@ -3,25 +3,25 @@ use na::{Real, U3, UnitQuaternion, Unit};
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use aliases::{Vec, Qua};
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/// Computes the quaternion exponential.
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pub fn exp<N: Real>(q: &Qua<N>) -> Qua<N> {
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pub fn quat_exp<N: Real>(q: &Qua<N>) -> Qua<N> {
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q.exp()
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}
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/// Computes the quaternion logarithm.
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pub fn log<N: Real>(q: &Qua<N>) -> Qua<N> {
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pub fn quat_log<N: Real>(q: &Qua<N>) -> Qua<N> {
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q.ln()
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}
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/// Raises the quaternion `q` to the power `y`.
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pub fn pow<N: Real>(q: &Qua<N>, y: N) -> Qua<N> {
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pub fn quat_pow<N: Real>(q: &Qua<N>, y: N) -> Qua<N> {
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q.powf(y)
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}
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/// Builds a quaternion from an axis and an angle, and right-multiply it to the quaternion `q`.
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pub fn rotate<N: Real>(q: &Qua<N>, angle: N, axis: &Vec<N, U3>) -> Qua<N> {
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pub fn quat_rotate<N: Real>(q: &Qua<N>, angle: N, axis: &Vec<N, U3>) -> Qua<N> {
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q * UnitQuaternion::from_axis_angle(&Unit::new_normalize(*axis), angle).unwrap()
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}
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//pub fn sqrt<N: Real>(q: &Qua<N>) -> Qua<N> {
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//pub fn quat_sqrt<N: Real>(q: &Qua<N>) -> Qua<N> {
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// unimplemented!()
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//}
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@ -3,17 +3,17 @@ use na::{Real, U3, Unit, UnitQuaternion, Vector3};
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use aliases::{Vec, Qua};
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/// The rotation angle of this quaternion assumed to be normalized.
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pub fn angle<N: Real>(x: &Qua<N>) -> N {
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pub fn quat_angle<N: Real>(x: &Qua<N>) -> N {
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UnitQuaternion::from_quaternion(*x).angle()
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}
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/// Creates a quaternion from an axis and an angle.
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pub fn angle_axis<N: Real>(angle: N, axis: &Vec<N, U3>) -> Qua<N> {
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pub fn quat_angle_axis<N: Real>(angle: N, axis: &Vec<N, U3>) -> Qua<N> {
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UnitQuaternion::from_axis_angle(&Unit::new_normalize(*axis), angle).unwrap()
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}
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/// The rotation axis of a quaternion assumed to be normalized.
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pub fn axis<N: Real>(x: &Qua<N>) -> Vec<N, U3> {
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pub fn quat_axis<N: Real>(x: &Qua<N>) -> Vec<N, U3> {
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if let Some(a) = UnitQuaternion::from_quaternion(*x).axis() {
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a.unwrap()
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} else {
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@ -11,6 +11,7 @@ pub use self::matrix_inverse::*;
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//pub use self::round::*;
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pub use self::type_ptr::*;
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//pub use self::ulp::*;
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pub use self::quaternion::*;
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//mod bitfield;
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@ -23,4 +24,5 @@ mod matrix_inverse;
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//mod reciprocal;
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//mod round;
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mod type_ptr;
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//mod ulp;
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//mod ulp;
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mod quaternion;
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@ -4,41 +4,41 @@ use aliases::{Qua, Vec, Mat};
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/// Euler angles of the quaternion `q` as (pitch, yaw, roll).
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pub fn euler_angles<N: Real>(x: &Qua<N>) -> Vec<N, U3> {
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pub fn quat_euler_angles<N: Real>(x: &Qua<N>) -> Vec<N, U3> {
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let q = UnitQuaternion::new_unchecked(*x);
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let a = q.to_euler_angles();
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Vector3::new(a.2, a.1, a.0)
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}
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/// Component-wise `>` comparison between two quaternions.
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pub fn greater_than<N: Real>(x: &Qua<N>, y: &Qua<N>) -> Vec<bool, U4> {
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pub fn quat_greater_than<N: Real>(x: &Qua<N>, y: &Qua<N>) -> Vec<bool, U4> {
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::greater_than(&x.coords, &y.coords)
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}
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/// Component-wise `>=` comparison between two quaternions.
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pub fn greater_than_equal<N: Real>(x: &Qua<N>, y: &Qua<N>) -> Vec<bool, U4> {
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pub fn quat_greater_than_equal<N: Real>(x: &Qua<N>, y: &Qua<N>) -> Vec<bool, U4> {
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::greater_than_equal(&x.coords, &y.coords)
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}
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/// Component-wise `<` comparison between two quaternions.
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pub fn less_than<N: Real>(x: &Qua<N>, y: &Qua<N>) -> Vec<bool, U4> {
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pub fn quat_less_than<N: Real>(x: &Qua<N>, y: &Qua<N>) -> Vec<bool, U4> {
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::less_than(&x.coords, &y.coords)
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}
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/// Component-wise `<=` comparison between two quaternions.
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pub fn less_than_equal<N: Real>(x: &Qua<N>, y: &Qua<N>) -> Vec<bool, U4> {
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pub fn quat_less_than_equal<N: Real>(x: &Qua<N>, y: &Qua<N>) -> Vec<bool, U4> {
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::less_than_equal(&x.coords, &y.coords)
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}
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/// Convert a quaternion to a rotation matrix.
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pub fn mat3_cast<N: Real>(x: Qua<N>) -> Mat<N, U3, U3> {
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pub fn quat_mat3_cast<N: Real>(x: Qua<N>) -> Mat<N, U3, U3> {
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let q = UnitQuaternion::new_unchecked(x);
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q.to_rotation_matrix().unwrap()
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}
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/// Convert a quaternion to a rotation matrix in homogeneous coordinates.
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pub fn mat4_cast<N: Real>(x: Qua<N>) -> Mat<N, U4, U4> {
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pub fn quat_mat4_cast<N: Real>(x: Qua<N>) -> Mat<N, U4, U4> {
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let q = UnitQuaternion::new_unchecked(x);
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q.to_homogeneous()
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}
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@ -70,19 +70,19 @@ pub fn quat_look_at_rh<N: Real>(direction: &Vec<N, U3>, up: &Vec<N, U3>) -> Qua<
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}
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/// The "roll" euler angle of the quaternion `x` assumed to be normalized.
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pub fn roll<N: Real>(x: &Qua<N>) -> N {
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pub fn quat_roll<N: Real>(x: &Qua<N>) -> N {
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// FIXME: optimize this.
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euler_angles(x).z
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quat_euler_angles(x).z
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}
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/// The "yaw" euler angle of the quaternion `x` assumed to be normalized.
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pub fn yaw<N: Real>(x: &Qua<N>) -> N {
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pub fn quat_yaw<N: Real>(x: &Qua<N>) -> N {
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// FIXME: optimize this.
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euler_angles(x).y
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quat_euler_angles(x).y
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}
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/// The "pitch" euler angle of the quaternion `x` assumed to be normalized.
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pub fn pitch<N: Real>(x: &Qua<N>) -> N {
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pub fn quat_pitch<N: Real>(x: &Qua<N>) -> N {
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// FIXME: optimize this.
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euler_angles(x).x
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quat_euler_angles(x).x
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}
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@ -17,6 +17,7 @@ pub use self::transform2::*;
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pub use self::transform2d::*;
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pub use self::vector_angle::*;
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pub use self::vector_query::*;
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pub use self::quaternion::*;
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@ -35,4 +36,5 @@ mod transform;
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mod transform2;
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mod transform2d;
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mod vector_angle;
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mod vector_query;
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mod vector_query;
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mod quaternion;
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@ -3,77 +3,77 @@ use na::{Real, Unit, Rotation3, Vector4, UnitQuaternion, U3, U4};
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use aliases::{Qua, Vec, Mat};
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/// Rotate the vector `v` by the quaternion `q` assumed to be normalized.
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pub fn cross<N: Real>(q: &Qua<N>, v: &Vec<N, U3>) -> Vec<N, U3> {
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pub fn quat_cross<N: Real>(q: &Qua<N>, v: &Vec<N, U3>) -> Vec<N, U3> {
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UnitQuaternion::new_unchecked(*q) * v
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}
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/// Rotate the vector `v` by the inverse of the quaternion `q` assumed to be normalized.
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pub fn cross2<N: Real>(v: &Vec<N, U3>, q: &Qua<N>) -> Vec<N, U3> {
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pub fn quat_cross2<N: Real>(v: &Vec<N, U3>, q: &Qua<N>) -> Vec<N, U3> {
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UnitQuaternion::new_unchecked(*q).inverse() * v
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}
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/// The quaternion `w` component.
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pub fn extract_real_component<N: Real>(q: &Qua<N>) -> N {
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pub fn quat_extract_real_component<N: Real>(q: &Qua<N>) -> N {
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q.w
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}
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/// Normalized linear interpolation between two quaternions.
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pub fn fast_mix<N: Real>(x: &Qua<N>, y: &Qua<N>, a: N) -> Qua<N> {
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pub fn quat_fast_mix<N: Real>(x: &Qua<N>, y: &Qua<N>, a: N) -> Qua<N> {
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Unit::new_unchecked(*x).nlerp(&Unit::new_unchecked(*y), a).unwrap()
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}
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//pub fn intermediate<N: Real>(prev: &Qua<N>, curr: &Qua<N>, next: &Qua<N>) -> Qua<N> {
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//pub fn quat_intermediate<N: Real>(prev: &Qua<N>, curr: &Qua<N>, next: &Qua<N>) -> Qua<N> {
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// unimplemented!()
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//}
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/// The squared magnitude of a quaternion `q`.
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pub fn length2<N: Real>(q: &Qua<N>) -> N {
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pub fn quat_length2<N: Real>(q: &Qua<N>) -> N {
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q.norm_squared()
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}
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/// The squared magnitude of a quaternion `q`.
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pub fn magnitude2<N: Real>(q: &Qua<N>) -> N {
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pub fn quat_magnitude2<N: Real>(q: &Qua<N>) -> N {
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q.norm_squared()
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}
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/// The quaternion representing the identity rotation.
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pub fn quat_identity<N: Real>() -> Qua<N> {
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pub fn quat_quat_identity<N: Real>() -> Qua<N> {
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UnitQuaternion::identity().unwrap()
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}
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/// Rotates a vector by a quaternion assumed to be normalized.
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pub fn rotate<N: Real>(q: &Qua<N>, v: &Vec<N, U3>) -> Vec<N, U3> {
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pub fn quat_rotate<N: Real>(q: &Qua<N>, v: &Vec<N, U3>) -> Vec<N, U3> {
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UnitQuaternion::new_unchecked(*q) * v
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}
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/// Rotates a vector in homogeneous coordinates by a quaternion assumed to be normalized.
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pub fn rotate2<N: Real>(q: &Qua<N>, v: &Vec<N, U4>) -> Vec<N, U4> {
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pub fn quat_rotate2<N: Real>(q: &Qua<N>, v: &Vec<N, U4>) -> Vec<N, U4> {
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// UnitQuaternion::new_unchecked(*q) * v
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let rotated = Unit::new_unchecked(*q) * v.fixed_rows::<U3>(0);
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Vector4::new(rotated.x, rotated.y, rotated.z, v.w)
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}
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/// The rotation required to align `orig` to `dest`.
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pub fn rotation<N: Real>(orig: &Vec<N, U3>, dest: &Vec<N, U3>) -> Qua<N> {
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pub fn quat_rotation<N: Real>(orig: &Vec<N, U3>, dest: &Vec<N, U3>) -> Qua<N> {
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UnitQuaternion::rotation_between(orig, dest).unwrap_or(UnitQuaternion::identity()).unwrap()
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}
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/// The spherical linear interpolation between two quaternions.
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pub fn short_mix<N: Real>(x: &Qua<N>, y: &Qua<N>, a: N) -> Qua<N> {
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pub fn quat_short_mix<N: Real>(x: &Qua<N>, y: &Qua<N>, a: N) -> Qua<N> {
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Unit::new_normalize(*x).slerp(&Unit::new_normalize(*y), a).unwrap()
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}
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//pub fn squad<N: Real>(q1: &Qua<N>, q2: &Qua<N>, s1: &Qua<N>, s2: &Qua<N>, h: N) -> Qua<N> {
|
||||
//pub fn quat_squad<N: Real>(q1: &Qua<N>, q2: &Qua<N>, s1: &Qua<N>, s2: &Qua<N>, h: N) -> Qua<N> {
|
||||
// unimplemented!()
|
||||
//}
|
||||
|
||||
/// Converts a quaternion to a rotation matrix.
|
||||
pub fn to_mat3<N: Real>(x: &Qua<N>) -> Mat<N, U3, U3> {
|
||||
pub fn quat_to_mat3<N: Real>(x: &Qua<N>) -> Mat<N, U3, U3> {
|
||||
UnitQuaternion::new_unchecked(*x).to_rotation_matrix().unwrap()
|
||||
}
|
||||
|
||||
/// Converts a quaternion to a rotation matrix in homogenous coordinates.
|
||||
pub fn to_mat4<N: Real>(x: &Qua<N>) -> Mat<N, U4, U4> {
|
||||
pub fn quat_to_mat4<N: Real>(x: &Qua<N>) -> Mat<N, U4, U4> {
|
||||
UnitQuaternion::new_unchecked(*x).to_homogeneous()
|
||||
}
|
||||
|
@ -1,6 +1,6 @@
|
||||
use na::{Real, Rotation3, Unit, U3, U4};
|
||||
use na::{Real, Rotation3, Unit, UnitQuaternion, U3, U4};
|
||||
|
||||
use aliases::{Vec, Mat};
|
||||
use aliases::{Vec, Mat, Qua};
|
||||
|
||||
/// Builds a rotation 4 * 4 matrix created from a normalized axis and an angle.
|
||||
///
|
||||
@ -10,4 +10,14 @@ use aliases::{Vec, Mat};
|
||||
/// * `axis` - Rotation axis, must be normalized.
|
||||
pub fn rotate_normalized_axis<N: Real>(m: &Mat<N, U4, U4>, angle: N, axis: &Vec<N, U3>) -> Mat<N, U4, U4> {
|
||||
m * Rotation3::from_axis_angle(&Unit::new_unchecked(*axis), angle).to_homogeneous()
|
||||
}
|
||||
|
||||
/// Rotates a quaternion from a vector of 3 components normalized axis and an angle.
|
||||
///
|
||||
/// # Parameters
|
||||
/// * `q` - Source orientation
|
||||
/// * `angle` - Angle expressed in radians.
|
||||
/// * `axis` - Normalized axis of the rotation, must be normalized.
|
||||
pub fn quat_rotate_normalized_axis<N: Real>(q: &Qua<N>, angle: N, axis: &Vec<N, U3>) -> Qua<N> {
|
||||
q * UnitQuaternion::from_axis_angle(&Unit::new_unchecked(*axis), angle).unwrap()
|
||||
}
|
@ -37,5 +37,4 @@ mod exponential;
|
||||
|
||||
pub mod ext;
|
||||
pub mod gtc;
|
||||
pub mod gtx;
|
||||
pub mod quat;
|
||||
pub mod gtx;
|
@ -1,13 +0,0 @@
|
||||
use na::{Real, Unit, UnitQuaternion, U3};
|
||||
|
||||
use aliases::{Vec, Qua};
|
||||
|
||||
/// Rotates a quaternion from a vector of 3 components normalized axis and an angle.
|
||||
///
|
||||
/// # Parameters
|
||||
/// * `q` - Source orientation
|
||||
/// * `angle` - Angle expressed in radians.
|
||||
/// * `axis` - Normalized axis of the rotation, must be normalized.
|
||||
pub fn rotate_normalized_axis<N: Real>(q: &Qua<N>, angle: N, axis: &Vec<N, U3>) -> Qua<N> {
|
||||
q * UnitQuaternion::from_axis_angle(&Unit::new_unchecked(*axis), angle).unwrap()
|
||||
}
|
@ -1,19 +0,0 @@
|
||||
//! Definition and operations on quaternions.
|
||||
|
||||
pub use self::gtc_quaternion::*;
|
||||
pub use self::gtx_quaternion::*;
|
||||
pub use self::gtx_rotate_normalized_axis::*;
|
||||
pub use self::quaternion_common::*;
|
||||
pub use self::quaternion_geometric::*;
|
||||
pub use self::quaternion_relational::*;
|
||||
pub use self::quaternion_transform::*;
|
||||
pub use self::quaternion_trigonometric::*;
|
||||
|
||||
mod gtc_quaternion;
|
||||
mod gtx_quaternion;
|
||||
mod gtx_rotate_normalized_axis;
|
||||
mod quaternion_common;
|
||||
mod quaternion_geometric;
|
||||
mod quaternion_relational;
|
||||
mod quaternion_transform;
|
||||
mod quaternion_trigonometric;
|
Loading…
Reference in New Issue
Block a user