split advance into subfunctions

2019-12-11 21:39:29 +01:00 · 2019-12-11 21:39:29 +01:00 · f9b715378f
parent d010d17a4a
commit f9b715378f
1 changed files with 256 additions and 243 deletions
--- a/src/maxwell.rs
+++ b/src/maxwell.rs
@ -1,4 +1,5 @@
 use super::operators::SbpOperator;
 use super::Grid;
 use ndarray::prelude::*;
 use ndarray::{azip, Zip};
@ -96,11 +97,17 @@ impl Field {
        }
    }
    /// Solving (Au)_x + (Bu)_y
    /// with:
    ///        A               B
    ///  [ 0,  0,  0]    [ 0,  1,  0]
    ///  [ 0,  0, -1]    [ 1,  0,  0]
    ///  [ 0, -1,  0]    [ 0,  0,  0]
    pub(crate) fn advance<SBP>(
        &self,
        fut: &mut Self,
        dt: f32,
-        grid: &super::Grid<SBP>,
+        grid: &Grid<SBP>,
        work_buffers: Option<&mut WorkBuffers>,
    ) where
        SBP: SbpOperator,
@ -131,20 +138,52 @@ impl Field {
                }
            };
-            // Solving (Au)_x + (Bu)_y
+            RHS(&mut k[i], &y, grid, tmp);
-            // with:
+        }
            //        A               B
            //  [ 0,  0,  0]    [ 0,  1,  0]
            //  [ 0,  0, -1]    [ 1,  0,  0]
            //  [ 0, -1,  0]    [ 0,  0,  0]
-            // This flux is rotated by the grid metrics
+        Zip::from(&mut fut.0)
-            // (Au)_x + (Bu)_y = 1/J [
+            .and(&self.0)
-            //          (J xi_x Au)_xi + (J eta_x Au)_eta
+            .and(&*k[0])
-            //          (J xi_y Bu)_xi + (J eta_y Bu)_eta
+            .and(&*k[1])
-            //      ]
+            .and(&*k[2])
-            // where J is the grid determinant
+            .and(&*k[3])
            .apply(|y1, &y0, &k1, &k2, &k3, &k4| {
                *y1 = y0 + dt / 6.0 * (k1 + 2.0 * k2 + 2.0 * k3 + k4)
            });
    }
 }
 #[allow(non_snake_case)]
 /// This flux is rotated by the grid metrics
 /// (Au)_x + (Bu)_y = 1/J [
 ///          (J xi_x Au)_xi + (J eta_x Au)_eta
 ///          (J xi_y Bu)_xi + (J eta_y Bu)_eta
 ///      ]
 /// where J is the grid determinant
 ///
 /// This is used both in fluxes and SAT terms
 fn RHS<SBP: SbpOperator>(
    k: &mut Field,
    y: &Field,
    grid: &Grid<SBP>,
    tmp: &mut (Array2<f32>, Array2<f32>, Array2<f32>, Array2<f32>),
 ) {
    fluxes(k, y, grid, tmp);
    SAT_characteristics(k, y, grid);
    azip!((k in &mut k.0,
                    &detj in &grid.detj.broadcast((3, y.ny(), y.nx())).unwrap()) {
        *k /= detj;
    });
 }
 fn fluxes<SBP: SbpOperator>(
    k: &mut Field,
    y: &Field,
    grid: &Grid<SBP>,
    tmp: &mut (Array2<f32>, Array2<f32>, Array2<f32>, Array2<f32>),
 ) {
    // ex = hz_y
    {
        ndarray::azip!((a in &mut tmp.0,
@ -161,7 +200,7 @@ impl Field {
        );
        SBP::diffeta(tmp.2.view(), tmp.3.view_mut());
-                ndarray::azip!((flux in &mut k[i].ex_mut(), &ax in &tmp.1, &by in &tmp.3)
+        ndarray::azip!((flux in &mut k.ex_mut(), &ax in &tmp.1, &by in &tmp.3)
            *flux = ax + by
        );
    }
@ -186,7 +225,7 @@ impl Field {
        );
        SBP::diffeta(tmp.2.view(), tmp.3.view_mut());
-                ndarray::azip!((flux in &mut k[i].hz_mut(), &ax in &tmp.1, &by in &tmp.3)
+        ndarray::azip!((flux in &mut k.hz_mut(), &ax in &tmp.1, &by in &tmp.3)
            *flux = ax + by
        );
    }
@ -207,14 +246,17 @@ impl Field {
        );
        SBP::diffeta(tmp.2.view(), tmp.3.view_mut());
-                azip!((flux in &mut k[i].ey_mut(), &ax in &tmp.1, &by in &tmp.3)
+        azip!((flux in &mut k.ey_mut(), &ax in &tmp.1, &by in &tmp.3)
            *flux = ax + by
        );
    }
 }
 #[allow(non_snake_case)]
 fn SAT_characteristics<SBP: SbpOperator>(k: &mut Field, y: &Field, grid: &Grid<SBP>) {
    // Boundary conditions (SAT)
-            let ny = self.ny();
+    let ny = y.ny();
-            let nx = self.nx();
+    let nx = y.nx();
    fn positive_flux(kx: f32, ky: f32) -> [[f32; 3]; 3] {
        let r = (kx * kx + ky * ky).sqrt();
@ -238,7 +280,7 @@ impl Field {
    let v = y.slice(s![.., .., nx - 1]);
    {
        // East boundary
-                let mut k = k[i].slice_mut(s![.., .., nx - 1]);
+        let mut k = k.slice_mut(s![.., .., nx - 1]);
        for j in 0..ny {
            // East boundary, positive flux
@ -254,24 +296,18 @@ impl Field {
            k[(0, j)] += tau
                * hinv
-                        * (plus[0][0] * (v.0 - g.0)
+                * (plus[0][0] * (v.0 - g.0) + plus[0][1] * (v.1 - g.1) + plus[0][2] * (v.2 - g.2));
                            + plus[0][1] * (v.1 - g.1)
                            + plus[0][2] * (v.2 - g.2));
            k[(1, j)] += tau
                * hinv
-                        * (plus[1][0] * (v.0 - g.0)
+                * (plus[1][0] * (v.0 - g.0) + plus[1][1] * (v.1 - g.1) + plus[1][2] * (v.2 - g.2));
                            + plus[1][1] * (v.1 - g.1)
                            + plus[1][2] * (v.2 - g.2));
            k[(2, j)] += tau
                * hinv
-                        * (plus[2][0] * (v.0 - g.0)
+                * (plus[2][0] * (v.0 - g.0) + plus[2][1] * (v.1 - g.1) + plus[2][2] * (v.2 - g.2));
                            + plus[2][1] * (v.1 - g.1)
                            + plus[2][2] * (v.2 - g.2));
        }
    }
    {
        // West boundary, negative flux
-                let mut k = k[i].slice_mut(s![.., .., 0]);
+        let mut k = k.slice_mut(s![.., .., 0]);
        let (v, g) = (g, v);
        for j in 0..ny {
            let tau = 1.0;
@ -306,7 +342,7 @@ impl Field {
    let g = y.slice(s![.., 0, ..]);
    let v = y.slice(s![.., ny - 1, ..]);
    {
-                let mut k = k[i].slice_mut(s![.., ny - 1, ..]);
+        let mut k = k.slice_mut(s![.., ny - 1, ..]);
        for j in 0..nx {
            // North boundary, positive flux
@ -321,25 +357,19 @@ impl Field {
            k[(0, j)] += tau
                * hinv
-                        * (plus[0][0] * (v.0 - g.0)
+                * (plus[0][0] * (v.0 - g.0) + plus[0][1] * (v.1 - g.1) + plus[0][2] * (v.2 - g.2));
                            + plus[0][1] * (v.1 - g.1)
                            + plus[0][2] * (v.2 - g.2));
            k[(1, j)] += tau
                * hinv
-                        * (plus[1][0] * (v.0 - g.0)
+                * (plus[1][0] * (v.0 - g.0) + plus[1][1] * (v.1 - g.1) + plus[1][2] * (v.2 - g.2));
                            + plus[1][1] * (v.1 - g.1)
                            + plus[1][2] * (v.2 - g.2));
            k[(2, j)] += tau
                * hinv
-                        * (plus[2][0] * (v.0 - g.0)
+                * (plus[2][0] * (v.0 - g.0) + plus[2][1] * (v.1 - g.1) + plus[2][2] * (v.2 - g.2));
                            + plus[2][1] * (v.1 - g.1)
                            + plus[2][2] * (v.2 - g.2));
        }
    }
    {
        let (v, g) = (g, v);
-                let mut k = k[i].slice_mut(s![.., 0, ..]);
+        let mut k = k.slice_mut(s![.., 0, ..]);
        for j in 0..nx {
            // South boundary, negative flux
            let tau = 1.0;
@ -368,23 +398,6 @@ impl Field {
                    + minus[2][2] * (v.2 - g.2));
        }
    }
            azip!((k in &mut k[i].0,
                            &detj in &grid.detj.broadcast((3, ny, nx)).unwrap()) {
                *k /= detj;
            });
        }
        Zip::from(&mut fut.0)
            .and(&self.0)
            .and(&*k[0])
            .and(&*k[1])
            .and(&*k[2])
            .and(&*k[3])
            .apply(|y1, &y0, &k1, &k2, &k3, &k4| {
                *y1 = y0 + dt / 6.0 * (k1 + 2.0 * k2 + 2.0 * k3 + k4)
            });
    }
 }
 pub struct WorkBuffers {