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use num::{One, Zero};
use simba::scalar::ComplexField;
use crate::base::constraint::{DimEq, ShapeConstraint};
use crate::base::dimension::{Dim, U2};
use crate::base::storage::{Storage, StorageMut};
use crate::base::{Matrix, Vector};
#[derive(Debug, Clone, Copy)]
pub struct GivensRotation<T: ComplexField> {
c: T::RealField,
s: T,
}
impl<T: ComplexField> GivensRotation<T> {
pub fn identity() -> Self {
Self {
c: T::RealField::one(),
s: T::zero(),
}
}
pub fn new_unchecked(c: T::RealField, s: T) -> Self {
Self { c, s }
}
pub fn new(c: T, s: T) -> (Self, T) {
Self::try_new(c, s, T::RealField::zero())
.unwrap_or_else(|| (GivensRotation::identity(), T::zero()))
}
pub fn try_new(c: T, s: T, eps: T::RealField) -> Option<(Self, T)> {
let (mod0, sign0) = c.to_exp();
let denom = (mod0 * mod0 + s.modulus_squared()).sqrt();
if denom > eps {
let norm = sign0.scale(denom);
let c = mod0 / denom;
let s = s / norm;
Some((Self { c, s }, norm))
} else {
None
}
}
pub fn cancel_y<S: Storage<T, U2>>(v: &Vector<T, U2, S>) -> Option<(Self, T)> {
if !v[1].is_zero() {
let (mod0, sign0) = v[0].to_exp();
let denom = (mod0 * mod0 + v[1].modulus_squared()).sqrt();
let c = mod0 / denom;
let s = -v[1] / sign0.scale(denom);
let r = sign0.scale(denom);
Some((Self { c, s }, r))
} else {
None
}
}
pub fn cancel_x<S: Storage<T, U2>>(v: &Vector<T, U2, S>) -> Option<(Self, T)> {
if !v[0].is_zero() {
let (mod1, sign1) = v[1].to_exp();
let denom = (mod1 * mod1 + v[0].modulus_squared()).sqrt();
let c = mod1 / denom;
let s = (v[0].conjugate() * sign1).unscale(denom);
let r = sign1.scale(denom);
Some((Self { c, s }, r))
} else {
None
}
}
pub fn c(&self) -> T::RealField {
self.c
}
pub fn s(&self) -> T {
self.s
}
pub fn inverse(&self) -> Self {
Self {
c: self.c,
s: -self.s,
}
}
pub fn rotate<R2: Dim, C2: Dim, S2: StorageMut<T, R2, C2>>(
&self,
rhs: &mut Matrix<T, R2, C2, S2>,
) where
ShapeConstraint: DimEq<R2, U2>,
{
assert_eq!(
rhs.nrows(),
2,
"Unit complex rotation: the input matrix must have exactly two rows."
);
let s = self.s;
let c = self.c;
for j in 0..rhs.ncols() {
unsafe {
let a = *rhs.get_unchecked((0, j));
let b = *rhs.get_unchecked((1, j));
*rhs.get_unchecked_mut((0, j)) = a.scale(c) - s.conjugate() * b;
*rhs.get_unchecked_mut((1, j)) = s * a + b.scale(c);
}
}
}
pub fn rotate_rows<R2: Dim, C2: Dim, S2: StorageMut<T, R2, C2>>(
&self,
lhs: &mut Matrix<T, R2, C2, S2>,
) where
ShapeConstraint: DimEq<C2, U2>,
{
assert_eq!(
lhs.ncols(),
2,
"Unit complex rotation: the input matrix must have exactly two columns."
);
let s = self.s;
let c = self.c;
for j in 0..lhs.nrows() {
unsafe {
let a = *lhs.get_unchecked((j, 0));
let b = *lhs.get_unchecked((j, 1));
*lhs.get_unchecked_mut((j, 0)) = a.scale(c) + s * b;
*lhs.get_unchecked_mut((j, 1)) = -s.conjugate() * a + b.scale(c);
}
}
}
}