nalgebra/src/adaptors/rotmat.rs

use core::num::{One, Zero}; // , Trigonometric};
use traits::workarounds::rlmul::{RMul, LMul};
use traits::workarounds::trigonometric::Trigonometric;
use traits::dim::Dim;
use traits::inv::Inv;
use traits::transpose::Transpose;
use dim2::mat2::Mat2;
use dim3::mat3::Mat3;
use dim3::vec3::Vec3;

// FIXME: use a newtype here?
#[deriving(Eq)]
pub struct Rotmat<M>
{
  priv submat: M
}

pub fn Rotmat2<T: Copy + Trigonometric + Neg<T>>(angle: T) -> Rotmat<Mat2<T>>
{
  let coa = Trigonometric::cos(angle);
  let sia = Trigonometric::sin(angle);

  Rotmat
  { submat: Mat2(coa, -sia, sia, coa) }
}

pub fn Rotmat3<T: Copy + Trigonometric + Neg<T> + One + Sub<T, T> + Add<T, T> +
                  Mul<T, T>>
(axis: &Vec3<T>, angle: T) -> Rotmat<Mat3<T>>
{
  let _1        = One::one::<T>();
  let ux        = axis.x;
  let uy        = axis.y;
  let uz        = axis.z;
  let sqx       = ux * ux;
  let sqy       = uy * uy;
  let sqz       = uz * uz;
  let cos       = Trigonometric::cos(angle);
  let one_m_cos = _1 - cos;
  let sin       = Trigonometric::sin(angle);

  Rotmat {
    submat: Mat3(
      (sqx + (_1 - sqx) * cos),
      (ux * uy * one_m_cos - uz * sin),
      (ux * uz * one_m_cos + uy * sin),

      (ux * uy * one_m_cos + uz * sin),
      (sqy + (_1 - sqy) * cos),
      (uy * uz * one_m_cos - ux * sin),

      (ux * uz * one_m_cos - uy * sin),
      (uy * uz * one_m_cos + ux * sin),
      (sqz + (_1 - sqz) * cos))
  }
}

impl<M: Dim> Dim for Rotmat<M>
{
  fn dim() -> uint
  { Dim::dim::<M>() }
}
 
impl<M:Copy + One + Zero> One for Rotmat<M>
{
  fn one() -> Rotmat<M>
  { Rotmat { submat: One::one() } }
}

impl<M:Copy + Mul<M, M>> Mul<Rotmat<M>, Rotmat<M>> for Rotmat<M>
{
  fn mul(&self, other: &Rotmat<M>) -> Rotmat<M>
  { Rotmat { submat: self.submat.mul(&other.submat) } }
}

impl<V, M: RMul<V>> RMul<V> for Rotmat<M>
{
  fn rmul(&self, other: &V) -> V
  { self.submat.rmul(other) }
}

impl<V, M: LMul<V>> LMul<V> for Rotmat<M>
{
  fn lmul(&self, other: &V) -> V
  { self.submat.lmul(other) }
}

impl<M:Copy + Transpose>
Inv for Rotmat<M>
{
  fn invert(&mut self)
  { self.transpose() }

  fn inverse(&self) -> Rotmat<M>
  { self.transposed() }
}

impl<M:Copy + Transpose>
Transpose for Rotmat<M>
{
  fn transposed(&self) -> Rotmat<M>
  { Rotmat { submat: self.submat.transposed() } }

  fn transpose(&mut self)
  { self.submat.transpose() }
}

impl<M:ToStr> ToStr for Rotmat<M>
{
  fn to_str(&self) -> ~str
  { ~"Rotmat {" + " submat: " + self.submat.to_str() + " }" }
}
Add matrix adaptors and addapted to the now rust features. 2013-05-17 05:30:39 +08:00			`use core::num::{One, Zero}; // , Trigonometric};`
			`use traits::workarounds::rlmul::{RMul, LMul};`
			`use traits::workarounds::trigonometric::Trigonometric;`
			`use traits::dim::Dim;`
			`use traits::inv::Inv;`
			`use traits::transpose::Transpose;`
			`use dim2::mat2::Mat2;`
			`use dim3::mat3::Mat3;`
			`use dim3::vec3::Vec3;`

			`// FIXME: use a newtype here?`
			`#[deriving(Eq)]`
			`pub struct Rotmat<M>`
			`{`
			`priv submat: M`
			`}`

			`pub fn Rotmat2<T: Copy + Trigonometric + Neg<T>>(angle: T) -> Rotmat<Mat2<T>>`
			`{`
			`let coa = Trigonometric::cos(angle);`
			`let sia = Trigonometric::sin(angle);`

			`Rotmat`
			`{ submat: Mat2(coa, -sia, sia, coa) }`
			`}`

			`pub fn Rotmat3<T: Copy + Trigonometric + Neg<T> + One + Sub<T, T> + Add<T, T> +`
			`Mul<T, T>>`
			`(axis: &Vec3<T>, angle: T) -> Rotmat<Mat3<T>>`
			`{`
			`let _1 = One::one::<T>();`
			`let ux = axis.x;`
			`let uy = axis.y;`
			`let uz = axis.z;`
			`let sqx = ux * ux;`
			`let sqy = uy * uy;`
			`let sqz = uz * uz;`
			`let cos = Trigonometric::cos(angle);`
			`let one_m_cos = _1 - cos;`
			`let sin = Trigonometric::sin(angle);`

			`Rotmat {`
			`submat: Mat3(`
			`(sqx + (_1 - sqx) * cos),`
			`(ux * uy * one_m_cos - uz * sin),`
			`(ux * uz * one_m_cos + uy * sin),`

			`(ux * uy * one_m_cos + uz * sin),`
			`(sqy + (_1 - sqy) * cos),`
			`(uy * uz * one_m_cos - ux * sin),`

			`(ux * uz * one_m_cos - uy * sin),`
			`(uy * uz * one_m_cos + ux * sin),`
			`(sqz + (_1 - sqz) * cos))`
			`}`
			`}`

			`impl<M: Dim> Dim for Rotmat<M>`
			`{`
			`fn dim() -> uint`
			`{ Dim::dim::<M>() }`
			`}`

			`impl<M:Copy + One + Zero> One for Rotmat<M>`
			`{`
			`fn one() -> Rotmat<M>`
			`{ Rotmat { submat: One::one() } }`
			`}`

			`impl<M:Copy + Mul<M, M>> Mul<Rotmat<M>, Rotmat<M>> for Rotmat<M>`
			`{`
			`fn mul(&self, other: &Rotmat<M>) -> Rotmat<M>`
			`{ Rotmat { submat: self.submat.mul(&other.submat) } }`
			`}`

			`impl<V, M: RMul<V>> RMul<V> for Rotmat<M>`
			`{`
			`fn rmul(&self, other: &V) -> V`
			`{ self.submat.rmul(other) }`
			`}`

			`impl<V, M: LMul<V>> LMul<V> for Rotmat<M>`
			`{`
			`fn lmul(&self, other: &V) -> V`
			`{ self.submat.lmul(other) }`
			`}`

			`impl<M:Copy + Transpose>`
			`Inv for Rotmat<M>`
			`{`
			`fn invert(&mut self)`
			`{ self.transpose() }`

			`fn inverse(&self) -> Rotmat<M>`
			`{ self.transposed() }`
			`}`

			`impl<M:Copy + Transpose>`
			`Transpose for Rotmat<M>`
			`{`
			`fn transposed(&self) -> Rotmat<M>`
			`{ Rotmat { submat: self.submat.transposed() } }`

			`fn transpose(&mut self)`
			`{ self.submat.transpose() }`
			`}`

			`impl<M:ToStr> ToStr for Rotmat<M>`
			`{`
			`fn to_str(&self) -> ~str`
			`{ ~"Rotmat {" + " submat: " + self.submat.to_str() + " }" }`
			`}`