forked from M-Labs/nalgebra
Merge pull request #1016 from tpdickso/fix-dual-quaternion-sclerp
Don't panic ScLERPing `UnitDualQuaternion` with equal rotation
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commit
10150ec783
@ -357,7 +357,8 @@ impl<T: RealField + UlpsEq<Epsilon = T>> UlpsEq for DualQuaternion<T> {
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}
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}
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/// A unit quaternions. May be used to represent a rotation followed by a translation.
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/// A unit dual quaternion. May be used to represent a rotation followed by a
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/// translation.
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pub type UnitDualQuaternion<T> = Unit<DualQuaternion<T>>;
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impl<T: Scalar + ClosedNeg + PartialEq + SimdRealField> PartialEq for UnitDualQuaternion<T> {
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@ -593,8 +594,9 @@ where
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/// Screw linear interpolation between two unit quaternions. This creates a
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/// smooth arc from one dual-quaternion to another.
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///
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/// Panics if the angle between both quaternion is 180 degrees (in which case the interpolation
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/// is not well-defined). Use `.try_sclerp` instead to avoid the panic.
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/// Panics if the angle between both quaternion is 180 degrees (in which
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/// case the interpolation is not well-defined). Use `.try_sclerp`
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/// instead to avoid the panic.
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///
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/// # Example
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/// ```
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@ -627,15 +629,16 @@ where
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.expect("DualQuaternion sclerp: ambiguous configuration.")
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}
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/// Computes the screw-linear interpolation between two unit quaternions or returns `None`
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/// if both quaternions are approximately 180 degrees apart (in which case the interpolation is
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/// not well-defined).
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/// Computes the screw-linear interpolation between two unit quaternions or
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/// returns `None` if both quaternions are approximately 180 degrees
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/// apart (in which case the interpolation is not well-defined).
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///
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/// # Arguments
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/// * `self`: the first quaternion to interpolate from.
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/// * `other`: the second quaternion to interpolate toward.
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/// * `t`: the interpolation parameter. Should be between 0 and 1.
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/// * `epsilon`: the value below which the sinus of the angle separating both quaternion
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/// * `epsilon`: the value below which the sinus of the angle separating
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/// both quaternion
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/// must be to return `None`.
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#[inline]
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#[must_use]
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@ -650,6 +653,10 @@ where
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// interpolation.
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let other = {
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let dot_product = self.as_ref().real.coords.dot(&other.as_ref().real.coords);
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if relative_eq!(dot_product, T::zero(), epsilon = epsilon.clone()) {
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return None;
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}
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if dot_product < T::zero() {
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-other.clone()
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} else {
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@ -660,13 +667,21 @@ where
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let difference = self.as_ref().conjugate() * other.as_ref();
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let norm_squared = difference.real.vector().norm_squared();
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if relative_eq!(norm_squared, T::zero(), epsilon = epsilon) {
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return None;
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return Some(Self::from_parts(
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self.translation()
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.vector
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.lerp(&other.translation().vector, t)
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.into(),
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self.rotation(),
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));
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}
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let inverse_norm_squared = T::one() / norm_squared;
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let scalar: T = difference.real.scalar();
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let mut angle = two.clone() * scalar.acos();
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let inverse_norm_squared: T = T::one() / norm_squared;
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let inverse_norm = inverse_norm_squared.sqrt();
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let mut angle = two.clone() * difference.real.scalar().acos();
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let mut pitch = -two * difference.dual.scalar() * inverse_norm.clone();
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let direction = difference.real.vector() * inverse_norm.clone();
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let moment = (difference.dual.vector()
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@ -678,6 +693,7 @@ where
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let sin = (half.clone() * angle.clone()).sin();
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let cos = (half.clone() * angle).cos();
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let real = Quaternion::from_parts(cos.clone(), direction.clone() * sin.clone());
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let dual = Quaternion::from_parts(
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-pitch.clone() * half.clone() * sin.clone(),
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@ -1,7 +1,7 @@
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#![cfg(feature = "proptest-support")]
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#![allow(non_snake_case)]
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use na::{DualQuaternion, Point3, UnitDualQuaternion, Vector3};
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use na::{DualQuaternion, Point3, Unit, UnitDualQuaternion, UnitQuaternion, Vector3};
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use crate::proptest::*;
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use proptest::{prop_assert, proptest};
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@ -74,6 +74,98 @@ proptest!(
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prop_assert!(relative_eq!((dq * t) * p, dq * (t * p), epsilon = 1.0e-7));
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}
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#[cfg_attr(rustfmt, rustfmt_skip)]
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#[test]
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fn sclerp_is_defined_for_identical_orientations(
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dq in unit_dual_quaternion(),
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s in -1.0f64..2.0f64,
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t in translation3(),
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) {
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// Should not panic.
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prop_assert!(relative_eq!(dq.sclerp(&dq, 0.0), dq, epsilon = 1.0e-7));
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prop_assert!(relative_eq!(dq.sclerp(&dq, 0.5), dq, epsilon = 1.0e-7));
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prop_assert!(relative_eq!(dq.sclerp(&dq, 1.0), dq, epsilon = 1.0e-7));
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prop_assert!(relative_eq!(dq.sclerp(&dq, s), dq, epsilon = 1.0e-7));
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let unit = UnitDualQuaternion::identity();
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prop_assert!(relative_eq!(unit.sclerp(&unit, 0.0), unit, epsilon = 1.0e-7));
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prop_assert!(relative_eq!(unit.sclerp(&unit, 0.5), unit, epsilon = 1.0e-7));
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prop_assert!(relative_eq!(unit.sclerp(&unit, 1.0), unit, epsilon = 1.0e-7));
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prop_assert!(relative_eq!(unit.sclerp(&unit, s), unit, epsilon = 1.0e-7));
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// ScLERPing two unit dual quaternions with nearly equal rotation
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// components should result in a unit dual quaternion with a rotation
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// component nearly equal to either input.
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let dq2 = t * dq;
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prop_assert!(relative_eq!(dq.sclerp(&dq2, 0.0).real, dq.real, epsilon = 1.0e-7));
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prop_assert!(relative_eq!(dq.sclerp(&dq2, 0.5).real, dq.real, epsilon = 1.0e-7));
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prop_assert!(relative_eq!(dq.sclerp(&dq2, 1.0).real, dq.real, epsilon = 1.0e-7));
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prop_assert!(relative_eq!(dq.sclerp(&dq2, s).real, dq.real, epsilon = 1.0e-7));
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// ScLERPing two unit dual quaternions with nearly equal rotation
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// components should result in a unit dual quaternion with a translation
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// component which is nearly equal to linearly interpolating the
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// translation components of the inputs.
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prop_assert!(relative_eq!(
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dq.sclerp(&dq2, s).translation().vector,
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dq.translation().vector.lerp(&dq2.translation().vector, s),
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epsilon = 1.0e-7
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));
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let unit2 = t * unit;
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prop_assert!(relative_eq!(unit.sclerp(&unit2, 0.0).real, unit.real, epsilon = 1.0e-7));
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prop_assert!(relative_eq!(unit.sclerp(&unit2, 0.5).real, unit.real, epsilon = 1.0e-7));
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prop_assert!(relative_eq!(unit.sclerp(&unit2, 1.0).real, unit.real, epsilon = 1.0e-7));
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prop_assert!(relative_eq!(unit.sclerp(&unit2, s).real, unit.real, epsilon = 1.0e-7));
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prop_assert!(relative_eq!(
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unit.sclerp(&unit2, s).translation().vector,
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unit.translation().vector.lerp(&unit2.translation().vector, s),
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epsilon = 1.0e-7
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));
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}
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#[cfg_attr(rustfmt, rustfmt_skip)]
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#[test]
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fn sclerp_is_not_defined_for_opposite_orientations(
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dq in unit_dual_quaternion(),
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s in 0.1f64..0.9f64,
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t in translation3(),
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t2 in translation3(),
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v in vector3(),
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) {
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let iso = dq.to_isometry();
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let rot = iso.rotation;
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if let Some((axis, angle)) = rot.axis_angle() {
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let flipped = UnitQuaternion::from_axis_angle(&axis, angle + std::f64::consts::PI);
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let dqf = flipped * rot.inverse() * dq.clone();
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prop_assert!(dq.try_sclerp(&dqf, 0.5, 1.0e-7).is_none());
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prop_assert!(dq.try_sclerp(&dqf, s, 1.0e-7).is_none());
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}
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let dq2 = t * dq;
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let iso2 = dq2.to_isometry();
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let rot2 = iso2.rotation;
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if let Some((axis, angle)) = rot2.axis_angle() {
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let flipped = UnitQuaternion::from_axis_angle(&axis, angle + std::f64::consts::PI);
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let dq3f = t2 * flipped * rot.inverse() * dq.clone();
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prop_assert!(dq2.try_sclerp(&dq3f, 0.5, 1.0e-7).is_none());
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prop_assert!(dq2.try_sclerp(&dq3f, s, 1.0e-7).is_none());
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}
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if let Some(axis) = Unit::try_new(v, 1.0e-7) {
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let unit = UnitDualQuaternion::identity();
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let flip = UnitQuaternion::from_axis_angle(&axis, std::f64::consts::PI);
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let unitf = flip * unit;
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prop_assert!(unit.try_sclerp(&unitf, 0.5, 1.0e-7).is_none());
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prop_assert!(unit.try_sclerp(&unitf, s, 1.0e-7).is_none());
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let unit2f = t * unit * flip;
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prop_assert!(unit.try_sclerp(&unit2f, 0.5, 1.0e-7).is_none());
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prop_assert!(unit.try_sclerp(&unit2f, s, 1.0e-7).is_none());
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}
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}
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#[cfg_attr(rustfmt, rustfmt_skip)]
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#[test]
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fn all_op_exist(
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