Indentation fixes.
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@ -168,9 +168,7 @@ Translatable<V, Transform<M, V>> for Transform<M, V>
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{ Transform::new(self.submat.clone(), self.subtrans.translated(t)) }
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}
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impl<M: Rotation<AV> + RMul<V> + One,
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V,
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AV>
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impl<M: Rotation<AV> + RMul<V> + One, V, AV>
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Rotation<AV> for Transform<M, V>
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{
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#[inline]
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@ -204,10 +202,7 @@ impl<M: Rotate<V>, V, _0> Rotate<V> for Transform<M, _0>
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{ self.submat.inv_rotate(v) }
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}
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impl<M: Rotatable<AV, Res> + One,
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Res: Rotation<AV> + RMul<V> + One,
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V,
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AV>
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impl<M: Rotatable<AV, Res> + One, Res: Rotation<AV> + RMul<V> + One, V, AV>
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Rotatable<AV, Transform<Res, V>> for Transform<M, V>
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{
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#[inline]
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22
src/dvec.rs
22
src/dvec.rs
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@ -61,8 +61,8 @@ impl<N, Iter: Iterator<N>> FromIterator<N, Iter> for DVec<N>
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impl<N: Clone + DivisionRing + Algebraic + ApproxEq<N>> DVec<N>
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{
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/// Computes the canonical basis for the given dimension. A canonical basis is a set of
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/// vectors, mutually orthogonal, with all its component equal to 0.0 exept one which is equal to
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/// 1.0.
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/// vectors, mutually orthogonal, with all its component equal to 0.0 exept one which is equal
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/// to 1.0.
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pub fn canonical_basis_with_dim(dim: uint) -> ~[DVec<N>]
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{
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let mut res : ~[DVec<N>] = ~[];
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@ -145,8 +145,7 @@ impl<N: Neg<N>> Neg<DVec<N>> for DVec<N>
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{ DVec { at: self.at.iter().transform(|a| -a).collect() } }
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}
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impl<N: Ring>
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Dot<N> for DVec<N>
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impl<N: Ring> Dot<N> for DVec<N>
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{
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#[inline]
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fn dot(&self, other: &DVec<N>) -> N
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@ -176,8 +175,7 @@ impl<N: Ring> SubDot<N> for DVec<N>
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}
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}
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impl<N: Mul<N, N>>
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ScalarMul<N> for DVec<N>
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impl<N: Mul<N, N>> ScalarMul<N> for DVec<N>
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{
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#[inline]
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fn scalar_mul(&self, s: &N) -> DVec<N>
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@ -192,8 +190,7 @@ ScalarMul<N> for DVec<N>
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}
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impl<N: Div<N, N>>
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ScalarDiv<N> for DVec<N>
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impl<N: Div<N, N>> ScalarDiv<N> for DVec<N>
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{
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#[inline]
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fn scalar_div(&self, s: &N) -> DVec<N>
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@ -207,8 +204,7 @@ ScalarDiv<N> for DVec<N>
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}
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}
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impl<N: Add<N, N>>
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ScalarAdd<N> for DVec<N>
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impl<N: Add<N, N>> ScalarAdd<N> for DVec<N>
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{
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#[inline]
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fn scalar_add(&self, s: &N) -> DVec<N>
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@ -222,8 +218,7 @@ ScalarAdd<N> for DVec<N>
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}
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}
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impl<N: Sub<N, N>>
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ScalarSub<N> for DVec<N>
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impl<N: Sub<N, N>> ScalarSub<N> for DVec<N>
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{
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#[inline]
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fn scalar_sub(&self, s: &N) -> DVec<N>
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@ -259,8 +254,7 @@ impl<N: Add<N, N> + Neg<N> + Clone> Translatable<DVec<N>, DVec<N>> for DVec<N>
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{ self + *t }
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}
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impl<N: DivisionRing + Algebraic + Clone>
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Norm<N> for DVec<N>
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impl<N: DivisionRing + Algebraic + Clone> Norm<N> for DVec<N>
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{
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#[inline]
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fn sqnorm(&self) -> N
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@ -131,8 +131,7 @@ macro_rules! column_impl(
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macro_rules! mul_impl(
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($t: ident, $dim: expr) => (
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impl<N: Clone + Ring>
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Mul<$t<N>, $t<N>> for $t<N>
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impl<N: Clone + Ring> Mul<$t<N>, $t<N>> for $t<N>
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{
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fn mul(&self, other: &$t<N>) -> $t<N>
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{
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@ -159,8 +158,7 @@ macro_rules! mul_impl(
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macro_rules! rmul_impl(
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($t: ident, $v: ident, $dim: expr) => (
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impl<N: Clone + Ring>
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RMul<$v<N>> for $t<N>
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impl<N: Clone + Ring> RMul<$v<N>> for $t<N>
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{
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fn rmul(&self, other: &$v<N>) -> $v<N>
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{
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@ -183,12 +181,10 @@ macro_rules! rmul_impl(
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macro_rules! lmul_impl(
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($t: ident, $v: ident, $dim: expr) => (
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impl<N: Clone + Ring>
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LMul<$v<N>> for $t<N>
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impl<N: Clone + Ring> LMul<$v<N>> for $t<N>
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{
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fn lmul(&self, other: &$v<N>) -> $v<N>
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{
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let mut res : $v<N> = Zero::zero();
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for i in range(0u, $dim)
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@ -5,62 +5,3 @@ pub trait Dim {
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/// The dimension of the object.
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fn dim() -> uint;
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}
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// Some dimension token. Useful to restrict the dimension of n-dimensional
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// object at the type-level.
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/// Dimensional token for 0-dimensions. Dimensional tokens are the preferred
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/// way to specify at the type level the dimension of n-dimensional objects.
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#[deriving(Eq, Ord, ToStr)]
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pub struct D0;
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/// Dimensional token for 1-dimension. Dimensional tokens are the preferred
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/// way to specify at the type level the dimension of n-dimensional objects.
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#[deriving(Eq, Ord, ToStr)]
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pub struct D1;
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/// Dimensional token for 2-dimensions. Dimensional tokens are the preferred
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/// way to specify at the type level the dimension of n-dimensional objects.
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#[deriving(Eq, Ord, ToStr)]
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pub struct D2;
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/// Dimensional token for 3-dimensions. Dimensional tokens are the preferred
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/// way to specify at the type level the dimension of n-dimensional objects.
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#[deriving(Eq, Ord, ToStr)]
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pub struct D3;
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/// Dimensional token for 4-dimensions. Dimensional tokens are the preferred
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/// way to specify at the type level the dimension of n-dimensional objects.
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#[deriving(Eq, Ord, ToStr)]
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pub struct D4;
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/// Dimensional token for 5-dimensions. Dimensional tokens are the preferred
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/// way to specify at the type level the dimension of n-dimensional objects.
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#[deriving(Eq, Ord, ToStr)]
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pub struct D5;
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/// Dimensional token for 6-dimensions. Dimensional tokens are the preferred
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/// way to specify at the type level the dimension of n-dimensional objects.
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#[deriving(Eq, Ord, ToStr)]
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pub struct D6;
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impl Dim for D0
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{ fn dim() -> uint { 0 } }
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impl Dim for D1
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{ fn dim() -> uint { 1 } }
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impl Dim for D2
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{ fn dim() -> uint { 2 } }
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impl Dim for D3
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{ fn dim() -> uint { 3 } }
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impl Dim for D4
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{ fn dim() -> uint { 4 } }
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impl Dim for D5
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{ fn dim() -> uint { 5 } }
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impl Dim for D6
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{ fn dim() -> uint { 6 } }
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@ -46,8 +46,11 @@ pub trait Rotate<V>
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pub fn rotated_wrt_point<M: Translatable<LV, M2>,
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M2: Rotation<AV> + Translation<LV>,
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LV: Neg<LV>,
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AV>
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(m: &M, ammount: &AV, center: &LV) -> M2
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AV>(
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m: &M,
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ammount: &AV,
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center: &LV)
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-> M2
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{
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let mut res = m.translated(&-center);
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@ -66,8 +69,10 @@ pub fn rotated_wrt_point<M: Translatable<LV, M2>,
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#[inline]
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pub fn rotate_wrt_point<M: Rotation<AV> + Translation<LV>,
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LV: Neg<LV>,
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AV>
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(m: &mut M, ammount: &AV, center: &LV)
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AV>(
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m: &mut M,
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ammount: &AV,
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center: &LV)
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{
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m.translate_by(&-center);
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m.rotate_by(ammount);
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@ -85,8 +90,10 @@ pub fn rotate_wrt_point<M: Rotation<AV> + Translation<LV>,
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pub fn rotated_wrt_center<M: Translatable<LV, M2> + Translation<LV>,
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M2: Rotation<AV> + Translation<LV>,
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LV: Neg<LV>,
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AV>
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(m: &M, ammount: &AV) -> M2
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AV>(
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m: &M,
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ammount: &AV)
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-> M2
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{ rotated_wrt_point(m, ammount, &m.translation()) }
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/**
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@ -99,8 +106,9 @@ pub fn rotated_wrt_center<M: Translatable<LV, M2> + Translation<LV>,
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#[inline]
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pub fn rotate_wrt_center<M: Translatable<LV, M> + Translation<LV> + Rotation<AV>,
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LV: Neg<LV>,
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AV>
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(m: &mut M, ammount: &AV)
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AV>(
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m: &mut M,
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ammount: &AV)
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{
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let t = m.translation();
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@ -111,7 +111,6 @@ from_homogeneous_impl!(Vec2, Vec3, z, x, y)
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/// Vector of dimension 3.
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#[deriving(Eq, Encodable, Decodable, Clone, DeepClone, IterBytes, Rand, Zero, ToStr)]
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pub struct Vec3<N>
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{
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/// First component of the vector.
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x: N,
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@ -18,7 +18,8 @@ impl<N: Mul<N, N> + Sub<N, N>> Cross<Vec3<N>> for Vec3<N>
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#[inline]
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fn cross(&self, other : &Vec3<N>) -> Vec3<N>
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{
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Vec3::new(self.y * other.z - self.z * other.y,
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Vec3::new(
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self.y * other.z - self.z * other.y,
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self.z * other.x - self.x * other.z,
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self.x * other.y - self.y * other.x
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)
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