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use simba::scalar::RealField;
use std::ops::{DivAssign, MulAssign};
use crate::allocator::Allocator;
use crate::base::dimension::Dim;
use crate::base::storage::Storage;
use crate::base::{Const, DefaultAllocator, OMatrix, OVector};
pub fn balance_parlett_reinsch<T: RealField, D: Dim>(m: &mut OMatrix<T, D, D>) -> OVector<T, D>
where
DefaultAllocator: Allocator<T, D, D> + Allocator<T, D>,
{
assert!(m.is_square(), "Unable to balance a non-square matrix.");
let dim = m.data.shape().0;
let radix: T = crate::convert(2.0f64);
let mut d = OVector::from_element_generic(dim, Const::<1>, T::one());
let mut converged = false;
while !converged {
converged = true;
for i in 0..dim.value() {
let mut c = m.column(i).norm_squared();
let mut r = m.row(i).norm_squared();
let mut f = T::one();
let s = c + r;
c = c.sqrt();
r = r.sqrt();
if c.is_zero() || r.is_zero() {
continue;
}
while c < r / radix {
c *= radix;
r /= radix;
f *= radix;
}
while c >= r * radix {
c /= radix;
r *= radix;
f /= radix;
}
let eps: T = crate::convert(0.95);
if c * c + r * r < eps * s {
converged = false;
d[i] *= f;
m.column_mut(i).mul_assign(f);
m.row_mut(i).div_assign(f);
}
}
}
d
}
pub fn unbalance<T: RealField, D: Dim>(m: &mut OMatrix<T, D, D>, d: &OVector<T, D>)
where
DefaultAllocator: Allocator<T, D, D> + Allocator<T, D>,
{
assert!(m.is_square(), "Unable to unbalance a non-square matrix.");
assert_eq!(m.nrows(), d.len(), "Unbalancing: mismatched dimensions.");
for j in 0..d.len() {
let mut col = m.column_mut(j);
let denom = T::one() / d[j];
for i in 0..d.len() {
col[i] *= d[i] * denom;
}
}
}
