SummationByParts/sbp/src/operators/interpolation.rs

use super::InterpolationOperator;
use crate::Float;
use ndarray::{ArrayView1, ArrayView2, ArrayViewMut1};

mod interpolation4;
pub use interpolation4::Interpolation4;
mod interpolation9;
pub use interpolation9::Interpolation9;
mod interpolation8;
pub use interpolation8::Interpolation8;

mod interpolation9h2;
pub use interpolation9h2::Interpolation9h2;

fn interpolate(
    input: ArrayView1<Float>,
    mut output: ArrayViewMut1<Float>,
    block: ArrayView2<Float>,
    diag: ArrayView2<Float>,
    jump: (usize, usize),
) {
    use ndarray::Axis;

    output.fill(0.0);
    let noutput = output.len();

    for (i, out) in output.iter_mut().enumerate() {
        if i < block.len_of(Axis(0)) {
            for k in 0..block.len_of(Axis(1)) {
                *out += input[k] * block[(i, k)];
            }
        } else if noutput - i <= block.len_of(Axis(0)) {
            let row = noutput - i - 1;
            let index = input.len() - block.len_of(Axis(1));

            for k in 0..block.len_of(Axis(1)) {
                let col = block.len_of(Axis(1)) - k - 1;
                *out += input[index + k] * block[(row, col)];
            }
        } else {
            let n = i - block.len_of(Axis(0));
            let index = jump.0 + jump.1 * (n / diag.len_of(Axis(0)));
            let row = n % diag.len_of(Axis(0));

            for k in 0..diag.len_of(Axis(1)) {
                *out += input[index + k] * diag[(row, k)];
            }
        }
    }
}

#[cfg(test)]
pub(crate) fn test_interpolation_operator<IO: InterpolationOperator>(op: IO, h2: bool) {
    let nc = 101;
    let (x_c, x_f) = if h2 {
        (
            crate::utils::h2linspace(0.0, 1.0, nc),
            crate::utils::h2linspace(0.0, 1.0, 2 * (nc - 1)),
        )
    } else {
        (
            ndarray::Array1::linspace(0.0, 1.0, 101),
            ndarray::Array1::linspace(0.0, 1.0, 2 * nc - 1),
        )
    };

    let mut ix_f = ndarray::Array1::zeros(x_f.raw_dim());
    op.coarse2fine(x_c.view(), ix_f.view_mut());
    approx::assert_abs_diff_eq!(ix_f, x_f, epsilon = 1e-5);

    let mut ix_c = ndarray::Array1::zeros(x_c.raw_dim());
    op.fine2coarse(x_f.view(), ix_c.view_mut());
    approx::assert_abs_diff_eq!(ix_c, x_c, epsilon = 1e-5);
}
interpolation operators 2020-04-11 13:19:34 +00:00			`use super::InterpolationOperator;`
			`use crate::Float;`
			`use ndarray::{ArrayView1, ArrayView2, ArrayViewMut1};`

			`mod interpolation4;`
			`pub use interpolation4::Interpolation4;`
			`mod interpolation9;`
			`pub use interpolation9::Interpolation9;`
add more interpolation ops 2020-04-13 20:56:43 +00:00			`mod interpolation8;`
			`pub use interpolation8::Interpolation8;`

			`mod interpolation9h2;`
			`pub use interpolation9h2::Interpolation9h2;`
interpolation operators 2020-04-11 13:19:34 +00:00
			`fn interpolate(`
			`input: ArrayView1<Float>,`
			`mut output: ArrayViewMut1<Float>,`
			`block: ArrayView2<Float>,`
			`diag: ArrayView2<Float>,`
			`jump: (usize, usize),`
			`) {`
			`use ndarray::Axis;`

			`output.fill(0.0);`
			`let noutput = output.len();`

			`for (i, out) in output.iter_mut().enumerate() {`
			`if i < block.len_of(Axis(0)) {`
			`for k in 0..block.len_of(Axis(1)) {`
			`out += input[k] block[(i, k)];`
			`}`
			`} else if noutput - i <= block.len_of(Axis(0)) {`
			`let row = noutput - i - 1;`
			`let index = input.len() - block.len_of(Axis(1));`

			`for k in 0..block.len_of(Axis(1)) {`
			`let col = block.len_of(Axis(1)) - k - 1;`
			`out += input[index + k] block[(row, col)];`
			`}`
			`} else {`
			`let n = i - block.len_of(Axis(0));`
			`let index = jump.0 + jump.1 * (n / diag.len_of(Axis(0)));`
			`let row = n % diag.len_of(Axis(0));`

			`for k in 0..diag.len_of(Axis(1)) {`
			`out += input[index + k] diag[(row, k)];`
			`}`
			`}`
			`}`
			`}`

			`#[cfg(test)]`
add more interpolation ops 2020-04-13 20:56:43 +00:00			`pub(crate) fn test_interpolation_operator<IO: InterpolationOperator>(op: IO, h2: bool) {`
			`let nc = 101;`
			`let (x_c, x_f) = if h2 {`
			`(`
			`crate::utils::h2linspace(0.0, 1.0, nc),`
change restriction on h2 grid interpolation 2020-04-13 21:02:47 +00:00			`crate::utils::h2linspace(0.0, 1.0, 2 * (nc - 1)),`
add more interpolation ops 2020-04-13 20:56:43 +00:00			`)`
			`} else {`
			`(`
			`ndarray::Array1::linspace(0.0, 1.0, 101),`
			`ndarray::Array1::linspace(0.0, 1.0, 2 * nc - 1),`
			`)`
			`};`
interpolation operators 2020-04-11 13:19:34 +00:00
			`let mut ix_f = ndarray::Array1::zeros(x_f.raw_dim());`
add upwind9h2 2020-04-13 20:08:18 +00:00			`op.coarse2fine(x_c.view(), ix_f.view_mut());`
change restriction on h2 grid interpolation 2020-04-13 21:02:47 +00:00			`approx::assert_abs_diff_eq!(ix_f, x_f, epsilon = 1e-5);`
interpolation operators 2020-04-11 13:19:34 +00:00
			`let mut ix_c = ndarray::Array1::zeros(x_c.raw_dim());`
add upwind9h2 2020-04-13 20:08:18 +00:00			`op.fine2coarse(x_f.view(), ix_c.view_mut());`
change restriction on h2 grid interpolation 2020-04-13 21:02:47 +00:00			`approx::assert_abs_diff_eq!(ix_c, x_c, epsilon = 1e-5);`
interpolation operators 2020-04-11 13:19:34 +00:00			`}`