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add basic SIMD support for Quaternion<f32>

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This commit is contained in:
Luxko 2017-03-12 20:44:58 +08:00
parent 09c8727c7c
commit 194c4770e9
2 changed files with 240 additions and 12 deletions
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234
src/quaternion.rs
View file

@ -30,6 +30,8 @@ use point::Point3;
use rotation::{Rotation, Rotation3, Basis3}; use rotation::{Rotation, Rotation3, Basis3};
use vector::Vector3; use vector::Vector3;
#[cfg(feature = "use_simd")]
use simd::f32x4 as Simdf32x4;
/// A [quaternion](https://en.wikipedia.org/wiki/Quaternion) in scalar/vector /// A [quaternion](https://en.wikipedia.org/wiki/Quaternion) in scalar/vector
/// form. /// form.
@ -46,6 +48,30 @@ pub struct Quaternion<S> {
pub v: Vector3<S>, pub v: Vector3<S>,
} }
#[cfg(feature = "use_simd")]
impl From<Simdf32x4> for Quaternion<f32> {
#[inline]
fn from(f: Simdf32x4) -> Self {
unsafe {
let mut ret: Self = mem::uninitialized();
{
let ret_mut: &mut [f32; 4] = ret.as_mut();
f.store(ret_mut.as_mut(), 0 as usize);
}
ret
}
}
}
#[cfg(feature = "use_simd")]
impl Into<Simdf32x4> for Quaternion<f32> {
#[inline]
fn into(self) -> Simdf32x4 {
let self_ref: &[f32; 4] = self.as_ref();
Simdf32x4::load(self_ref.as_ref(), 0 as usize)
}
}
impl<S: BaseFloat> Quaternion<S> { impl<S: BaseFloat> Quaternion<S> {
/// Construct a new quaternion from one scalar component and three /// Construct a new quaternion from one scalar component and three
/// imaginary components /// imaginary components
@ -73,7 +99,7 @@ impl<S: BaseFloat> Quaternion<S> {
let mag_avg = (src.magnitude2() * dst.magnitude2()).sqrt(); let mag_avg = (src.magnitude2() * dst.magnitude2()).sqrt();
let dot = src.dot(dst); let dot = src.dot(dst);
if ulps_eq!(dot, &mag_avg) { if ulps_eq!(dot, &mag_avg) {
Quaternion::one() Quaternion::<S>::one()
} else if ulps_eq!(dot, &-mag_avg) { } else if ulps_eq!(dot, &-mag_avg) {
let axis = fallback.unwrap_or_else(|| { let axis = fallback.unwrap_or_else(|| {
let mut v = Vector3::unit_x().cross(src); let mut v = Vector3::unit_x().cross(src);
@ -151,7 +177,7 @@ impl<S: BaseFloat> Zero for Quaternion<S> {
#[inline] #[inline]
fn is_zero(&self) -> bool { fn is_zero(&self) -> bool {
ulps_eq!(self, &Quaternion::zero()) ulps_eq!(self, &Quaternion::<S>::zero())
} }
} }
@ -175,6 +201,7 @@ impl<S: BaseFloat> MetricSpace for Quaternion<S> {
} }
} }
#[cfg(not(feature = "use_simd"))]
impl<S: BaseFloat> InnerSpace for Quaternion<S> { impl<S: BaseFloat> InnerSpace for Quaternion<S> {
#[inline] #[inline]
fn dot(self, other: Quaternion<S>) -> S { fn dot(self, other: Quaternion<S>) -> S {
@ -182,6 +209,25 @@ impl<S: BaseFloat> InnerSpace for Quaternion<S> {
} }
} }
#[cfg(feature = "use_simd")]
impl<S: BaseFloat> InnerSpace for Quaternion<S> {
#[inline]
default fn dot(self, other: Quaternion<S>) -> S {
self.s * other.s + self.v.dot(other.v)
}
}
#[cfg(feature = "use_simd")]
impl InnerSpace for Quaternion<f32> {
#[inline]
fn dot(self, other: Quaternion<f32>) -> f32 {
let lhs: Simdf32x4 = self.into();
let rhs: Simdf32x4 = other.into();
let r = lhs * rhs;
r.extract(0) + r.extract(1) + r.extract(2) + r.extract(3)
}
}
impl<A> From<Euler<A>> for Quaternion<<A as Angle>::Unitless> where impl<A> From<Euler<A>> for Quaternion<<A as Angle>::Unitless> where
A: Angle + Into<Rad<<A as Angle>::Unitless>>, A: Angle + Into<Rad<<A as Angle>::Unitless>>,
{ {
@ -203,35 +249,119 @@ impl<A> From<Euler<A>> for Quaternion<<A as Angle>::Unitless> where
} }
} }
#[cfg(not(feature = "use_simd"))]
impl_operator!(<S: BaseFloat> Neg for Quaternion<S> { impl_operator!(<S: BaseFloat> Neg for Quaternion<S> {
fn neg(quat) -> Quaternion<S> { fn neg(quat) -> Quaternion<S> {
Quaternion::from_sv(-quat.s, -quat.v) Quaternion::from_sv(-quat.s, -quat.v)
} }
}); });
#[cfg(feature = "use_simd")]
impl_operator_default!(<S: BaseFloat> Neg for Quaternion<S> {
fn neg(quat) -> Quaternion<S> {
Quaternion::from_sv(-quat.s, -quat.v)
}
});
#[cfg(feature = "use_simd")]
impl_operator_simd!{
[Simdf32x4]; Neg for Quaternion<f32> {
fn neg(lhs) -> Quaternion<f32> {
(-lhs).into()
}
}
}
#[cfg(not(feature = "use_simd"))]
impl_operator!(<S: BaseFloat> Mul<S> for Quaternion<S> { impl_operator!(<S: BaseFloat> Mul<S> for Quaternion<S> {
fn mul(lhs, rhs) -> Quaternion<S> { fn mul(lhs, rhs) -> Quaternion<S> {
Quaternion::from_sv(lhs.s * rhs, lhs.v * rhs) Quaternion::from_sv(lhs.s * rhs, lhs.v * rhs)
} }
}); });
#[cfg(feature = "use_simd")]
impl_operator_default!(<S: BaseFloat> Mul<S> for Quaternion<S> {
fn mul(lhs, rhs) -> Quaternion<S> {
Quaternion::from_sv(lhs.s * rhs, lhs.v * rhs)
}
});
#[cfg(feature = "use_simd")]
impl_operator_simd!{@rs
[Simdf32x4]; Mul<f32> for Quaternion<f32> {
fn mul(lhs, rhs) -> Quaternion<f32> {
(lhs * rhs).into()
}
}
}
#[cfg(not(feature = "use_simd"))]
impl_assignment_operator!(<S: BaseFloat> MulAssign<S> for Quaternion<S> { impl_assignment_operator!(<S: BaseFloat> MulAssign<S> for Quaternion<S> {
fn mul_assign(&mut self, scalar) { self.s *= scalar; self.v *= scalar; } fn mul_assign(&mut self, scalar) { self.s *= scalar; self.v *= scalar; }
}); });
#[cfg(feature = "use_simd")]
impl_assignment_operator_default!(<S: BaseFloat> MulAssign<S> for Quaternion<S> {
fn mul_assign(&mut self, scalar) { self.s *= scalar; self.v *= scalar; }
});
#[cfg(feature = "use_simd")]
impl MulAssign<f32> for Quaternion<f32> {
fn mul_assign(&mut self, other: f32) {
let s: Simdf32x4 = (*self).into();
let other = Simdf32x4::splat(other);
*self = (s * other).into();
}
}
#[cfg(not(feature = "use_simd"))]
impl_operator!(<S: BaseFloat> Div<S> for Quaternion<S> { impl_operator!(<S: BaseFloat> Div<S> for Quaternion<S> {
fn div(lhs, rhs) -> Quaternion<S> { fn div(lhs, rhs) -> Quaternion<S> {
Quaternion::from_sv(lhs.s / rhs, lhs.v / rhs) Quaternion::from_sv(lhs.s / rhs, lhs.v / rhs)
} }
}); });
#[cfg(feature = "use_simd")]
impl_operator_default!(<S: BaseFloat> Div<S> for Quaternion<S> {
fn div(lhs, rhs) -> Quaternion<S> {
Quaternion::from_sv(lhs.s / rhs, lhs.v / rhs)
}
});
#[cfg(feature = "use_simd")]
impl_operator_simd!{@rs
[Simdf32x4]; Div<f32> for Quaternion<f32> {
fn div(lhs, rhs) -> Quaternion<f32> {
(lhs / rhs).into()
}
}
}
#[cfg(not(feature = "use_simd"))]
impl_assignment_operator!(<S: BaseFloat> DivAssign<S> for Quaternion<S> { impl_assignment_operator!(<S: BaseFloat> DivAssign<S> for Quaternion<S> {
fn div_assign(&mut self, scalar) { self.s /= scalar; self.v /= scalar; } fn div_assign(&mut self, scalar) { self.s /= scalar; self.v /= scalar; }
}); });
#[cfg(feature = "use_simd")]
impl_assignment_operator_default!(<S: BaseFloat> DivAssign<S> for Quaternion<S> {
fn div_assign(&mut self, scalar) { self.s /= scalar; self.v /= scalar; }
});
#[cfg(feature = "use_simd")]
impl DivAssign<f32> for Quaternion<f32> {
fn div_assign(&mut self, other: f32) {
let s: Simdf32x4 = (*self).into();
let other = Simdf32x4::splat(other);
*self = (s / other).into();
}
}
impl_operator!(<S: BaseFloat> Rem<S> for Quaternion<S> { impl_operator!(<S: BaseFloat> Rem<S> for Quaternion<S> {
fn rem(lhs, rhs) -> Quaternion<S> { fn rem(lhs, rhs) -> Quaternion<S> {
Quaternion::from_sv(lhs.s % rhs, lhs.v % rhs) Quaternion::from_sv(lhs.s % rhs, lhs.v % rhs)
} }
}); });
impl_assignment_operator!(<S: BaseFloat> RemAssign<S> for Quaternion<S> { impl_assignment_operator!(<S: BaseFloat> RemAssign<S> for Quaternion<S> {
fn rem_assign(&mut self, scalar) { self.s %= scalar; self.v %= scalar; } fn rem_assign(&mut self, scalar) { self.s %= scalar; self.v %= scalar; }
}); });
@ -245,24 +375,93 @@ impl_operator!(<S: BaseFloat> Mul<Vector3<S> > for Quaternion<S> {
}} }}
}); });
#[cfg(not(feature = "use_simd"))]
impl_operator!(<S: BaseFloat> Add<Quaternion<S> > for Quaternion<S> { impl_operator!(<S: BaseFloat> Add<Quaternion<S> > for Quaternion<S> {
fn add(lhs, rhs) -> Quaternion<S> { fn add(lhs, rhs) -> Quaternion<S> {
Quaternion::from_sv(lhs.s + rhs.s, lhs.v + rhs.v) Quaternion::from_sv(lhs.s + rhs.s, lhs.v + rhs.v)
} }
}); });
#[cfg(feature = "use_simd")]
impl_operator_default!(<S: BaseFloat> Add<Quaternion<S> > for Quaternion<S> {
fn add(lhs, rhs) -> Quaternion<S> {
Quaternion::from_sv(lhs.s + rhs.s, lhs.v + rhs.v)
}
});
#[cfg(feature = "use_simd")]
impl_operator_simd!{
[Simdf32x4]; Add<Quaternion<f32>> for Quaternion<f32> {
fn add(lhs, rhs) -> Quaternion<f32> {
(lhs + rhs).into()
}
}
}
#[cfg(not(feature = "use_simd"))]
impl_assignment_operator!(<S: BaseFloat> AddAssign<Quaternion<S> > for Quaternion<S> { impl_assignment_operator!(<S: BaseFloat> AddAssign<Quaternion<S> > for Quaternion<S> {
fn add_assign(&mut self, other) { self.s += other.s; self.v += other.v; } fn add_assign(&mut self, other) { self.s += other.s; self.v += other.v; }
}); });
#[cfg(feature = "use_simd")]
impl_assignment_operator_default!(<S: BaseFloat> AddAssign<Quaternion<S> > for Quaternion<S> {
fn add_assign(&mut self, other) { self.s += other.s; self.v += other.v; }
});
#[cfg(feature = "use_simd")]
impl AddAssign for Quaternion<f32> {
#[inline]
fn add_assign(&mut self, rhs: Self) {
let s: Simdf32x4 = (*self).into();
let rhs: Simdf32x4 = rhs.into();
*self = (s + rhs).into();
}
}
#[cfg(not(feature = "use_simd"))]
impl_operator!(<S: BaseFloat> Sub<Quaternion<S> > for Quaternion<S> { impl_operator!(<S: BaseFloat> Sub<Quaternion<S> > for Quaternion<S> {
fn sub(lhs, rhs) -> Quaternion<S> { fn sub(lhs, rhs) -> Quaternion<S> {
Quaternion::from_sv(lhs.s - rhs.s, lhs.v - rhs.v) Quaternion::from_sv(lhs.s - rhs.s, lhs.v - rhs.v)
} }
}); });
#[cfg(feature = "use_simd")]
impl_operator_default!(<S: BaseFloat> Sub<Quaternion<S> > for Quaternion<S> {
fn sub(lhs, rhs) -> Quaternion<S> {
Quaternion::from_sv(lhs.s - rhs.s, lhs.v - rhs.v)
}
});
#[cfg(feature = "use_simd")]
impl_operator_simd!{
[Simdf32x4]; Sub<Quaternion<f32>> for Quaternion<f32> {
fn sub(lhs, rhs) -> Quaternion<f32> {
(lhs - rhs).into()
}
}
}
#[cfg(not(feature = "use_simd"))]
impl_assignment_operator!(<S: BaseFloat> SubAssign<Quaternion<S> > for Quaternion<S> { impl_assignment_operator!(<S: BaseFloat> SubAssign<Quaternion<S> > for Quaternion<S> {
fn sub_assign(&mut self, other) { self.s -= other.s; self.v -= other.v; } fn sub_assign(&mut self, other) { self.s -= other.s; self.v -= other.v; }
}); });
#[cfg(feature = "use_simd")]
impl_assignment_operator_default!(<S: BaseFloat> SubAssign<Quaternion<S> > for Quaternion<S> {
fn sub_assign(&mut self, other) { self.s -= other.s; self.v -= other.v; }
});
#[cfg(feature = "use_simd")]
impl SubAssign for Quaternion<f32> {
#[inline]
fn sub_assign(&mut self, rhs: Self) {
let s: Simdf32x4 = (*self).into();
let rhs: Simdf32x4 = rhs.into();
*self = (s - rhs).into();
}
}
#[cfg(not(feature = "use_simd"))]
impl_operator!(<S: BaseFloat> Mul<Quaternion<S> > for Quaternion<S> { impl_operator!(<S: BaseFloat> Mul<Quaternion<S> > for Quaternion<S> {
fn mul(lhs, rhs) -> Quaternion<S> { fn mul(lhs, rhs) -> Quaternion<S> {
Quaternion::new(lhs.s * rhs.s - lhs.v.x * rhs.v.x - lhs.v.y * rhs.v.y - lhs.v.z * rhs.v.z, Quaternion::new(lhs.s * rhs.s - lhs.v.x * rhs.v.x - lhs.v.y * rhs.v.y - lhs.v.z * rhs.v.z,
@ -272,6 +471,37 @@ impl_operator!(<S: BaseFloat> Mul<Quaternion<S> > for Quaternion<S> {
} }
}); });
#[cfg(feature = "use_simd")]
impl_operator_default!(<S: BaseFloat> Mul<Quaternion<S> > for Quaternion<S> {
fn mul(lhs, rhs) -> Quaternion<S> {
Quaternion::new(lhs.s * rhs.s - lhs.v.x * rhs.v.x - lhs.v.y * rhs.v.y - lhs.v.z * rhs.v.z,
lhs.s * rhs.v.x + lhs.v.x * rhs.s + lhs.v.y * rhs.v.z - lhs.v.z * rhs.v.y,
lhs.s * rhs.v.y + lhs.v.y * rhs.s + lhs.v.z * rhs.v.x - lhs.v.x * rhs.v.z,
lhs.s * rhs.v.z + lhs.v.z * rhs.s + lhs.v.x * rhs.v.y - lhs.v.y * rhs.v.x)
}
});
#[cfg(feature = "use_simd")]
impl_operator_simd!{
[Simdf32x4]; Mul<Quaternion<f32>> for Quaternion<f32> {
fn mul(lhs, rhs) -> Quaternion<f32> {
{
let p0 = Simdf32x4::splat(lhs.extract(0)) * rhs;
let p1 = Simdf32x4::splat(lhs.extract(1)) * Simdf32x4::new(
-rhs.extract(1), rhs.extract(0), -rhs.extract(3), rhs.extract(2)
);
let p2 = Simdf32x4::splat(lhs.extract(2)) * Simdf32x4::new(
-rhs.extract(2), rhs.extract(3), rhs.extract(0), -rhs.extract(1)
);
let p3 = Simdf32x4::splat(lhs.extract(3)) * Simdf32x4::new(
-rhs.extract(3), -rhs.extract(2), rhs.extract(1), rhs.extract(0)
);
(p0 + p1 + p2 + p3).into()
}
}
}
}
macro_rules! impl_scalar_mul { macro_rules! impl_scalar_mul {
($S:ident) => { ($S:ident) => {
impl_operator!(Mul<Quaternion<$S>> for $S { impl_operator!(Mul<Quaternion<$S>> for $S {

18
src/vector.rs
View file

@ -802,6 +802,14 @@ impl Into<Simdf32x4> for Vector4<f32> {
} }
} }
#[cfg(feature = "use_simd")]
impl_operator_simd!{
[Simdf32x4]; Add<Vector4<f32>> for Vector4<f32> {
fn add(lhs, rhs) -> Vector4<f32> {
(lhs + rhs).into()
}
}
}
#[cfg(feature = "use_simd")] #[cfg(feature = "use_simd")]
impl_operator_simd!{ impl_operator_simd!{
@ -1050,7 +1058,6 @@ impl Into<Simdu32x4> for Vector4<u32> {
} }
} }
#[cfg(feature = "use_simd")] #[cfg(feature = "use_simd")]
impl_operator_simd!{ impl_operator_simd!{
[Simdu32x4]; Add<Vector4<u32>> for Vector4<u32> { [Simdu32x4]; Add<Vector4<u32>> for Vector4<u32> {
@ -1060,15 +1067,6 @@ impl_operator_simd!{
} }
} }
#[cfg(feature = "use_simd")]
impl_operator_simd!{
[Simdf32x4]; Add<Vector4<f32>> for Vector4<f32> {
fn add(lhs, rhs) -> Vector4<f32> {
(lhs + rhs).into()
}
}
}
#[cfg(feature = "use_simd")] #[cfg(feature = "use_simd")]
impl_operator_simd!{ impl_operator_simd!{
[Simdu32x4]; Sub<Vector4<u32>> for Vector4<u32> { [Simdu32x4]; Sub<Vector4<u32>> for Vector4<u32> {