WIP: Clean up the outline view #16
@ -3,5 +3,6 @@
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# https://jonalmeida.com/posts/2015/01/23/print-cargo/
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# https://jonalmeida.com/posts/2015/01/23/print-cargo/
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#
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#
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cargo test -- --nocapture engine::tests::irisawa_hexlet_test
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cargo test -- --nocapture engine::tests::three_spheres_example
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cargo test -- --nocapture engine::tests::three_spheres_example
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cargo test -- --nocapture engine::tests::point_on_sphere_example
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cargo test -- --nocapture engine::tests::point_on_sphere_example
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@ -37,7 +37,7 @@ pub fn sphere_with_offset(dir_x: f64, dir_y: f64, dir_z: f64, off: f64, curv: f6
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struct MatrixEntry {
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struct MatrixEntry {
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index: (usize, usize),
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index: (usize, usize),
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val: f64
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value: f64
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}
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}
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struct PartialMatrix(Vec<MatrixEntry>);
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struct PartialMatrix(Vec<MatrixEntry>);
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@ -56,7 +56,7 @@ impl PartialMatrix {
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let mut result = DMatrix::<f64>::zeros(rhs.nrows(), rhs.ncols());
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let mut result = DMatrix::<f64>::zeros(rhs.nrows(), rhs.ncols());
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let PartialMatrix(entries) = self;
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let PartialMatrix(entries) = self;
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for ent in entries {
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for ent in entries {
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result[ent.index] = ent.val - rhs[ent.index];
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result[ent.index] = ent.value - rhs[ent.index];
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}
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}
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result
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result
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}
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}
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@ -141,7 +141,7 @@ fn realize_gram(
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let total_dim = element_dim * assembly_dim;
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let total_dim = element_dim * assembly_dim;
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// scale the tolerance
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// scale the tolerance
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let scale_adjustment = ((guess.ncols() - frozen.len()) as f64).sqrt();
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let scale_adjustment = (gram.0.len() as f64).sqrt();
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let tol = scale_adjustment * scaled_tol;
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let tol = scale_adjustment * scaled_tol;
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// convert the frozen indices to stacked format
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// convert the frozen indices to stacked format
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@ -153,7 +153,7 @@ fn realize_gram(
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let mut state = SearchState::from_config(gram, guess);
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let mut state = SearchState::from_config(gram, guess);
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for _ in 0..max_descent_steps {
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for _ in 0..max_descent_steps {
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// stop if the loss is tolerably low
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// stop if the loss is tolerably low
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println!("loss: {}", state.loss);
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println!("scaled loss: {}", state.loss / scale_adjustment);
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/* println!("projected error: {}", state.err_proj); */
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/* println!("projected error: {}", state.err_proj); */
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if state.loss < tol { break; }
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if state.loss < tol { break; }
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@ -182,6 +182,7 @@ fn realize_gram(
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// regularize the Hessian
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// regularize the Hessian
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let min_eigval = hess.symmetric_eigenvalues().min();
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let min_eigval = hess.symmetric_eigenvalues().min();
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/* println!("lowest eigenvalue: {}", min_eigval); */
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if min_eigval <= 0.0 {
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if min_eigval <= 0.0 {
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hess -= reg_scale * min_eigval * DMatrix::identity(total_dim, total_dim);
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hess -= reg_scale * min_eigval * DMatrix::identity(total_dim, total_dim);
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}
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}
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@ -198,6 +199,12 @@ fn realize_gram(
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}
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}
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// compute the Newton step
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// compute the Newton step
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/*
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we need to either handle or eliminate the case where the minimum
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eigenvalue of the Hessian is zero, so the regularized Hessian is
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singular. right now, this causes the Cholesky decomposition to return
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`None`, leading to a panic when we unrap
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*/
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let base_step_stacked = hess.cholesky().unwrap().solve(&neg_grad_stacked);
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let base_step_stacked = hess.cholesky().unwrap().solve(&neg_grad_stacked);
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let base_step = base_step_stacked.reshape_generic(Dyn(element_dim), Dyn(assembly_dim));
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let base_step = base_step_stacked.reshape_generic(Dyn(element_dim), Dyn(assembly_dim));
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@ -217,17 +224,17 @@ fn realize_gram(
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#[cfg(test)]
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#[cfg(test)]
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mod tests {
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mod tests {
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use std::f64;
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use std::{array, f64::consts::PI};
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use super::*;
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use super::*;
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#[test]
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#[test]
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fn sub_proj_test() {
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fn sub_proj_test() {
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let target = PartialMatrix(vec![
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let target = PartialMatrix(vec![
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MatrixEntry { index: (0, 0), val: 19.0 },
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MatrixEntry { index: (0, 0), value: 19.0 },
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MatrixEntry { index: (0, 2), val: 39.0 },
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MatrixEntry { index: (0, 2), value: 39.0 },
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MatrixEntry { index: (1, 1), val: 59.0 },
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MatrixEntry { index: (1, 1), value: 59.0 },
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MatrixEntry { index: (1, 2), val: 69.0 }
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MatrixEntry { index: (1, 2), value: 69.0 }
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]);
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]);
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let attempt = DMatrix::<f64>::from_row_slice(2, 3, &[
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let attempt = DMatrix::<f64>::from_row_slice(2, 3, &[
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1.0, 2.0, 3.0,
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1.0, 2.0, 3.0,
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@ -248,7 +255,7 @@ mod tests {
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for k in 0..3 {
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for k in 0..3 {
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entries.push(MatrixEntry {
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entries.push(MatrixEntry {
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index: (j, k),
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index: (j, k),
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val: if j == k { 1.0 } else { -1.0 }
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value: if j == k { 1.0 } else { -1.0 }
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});
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});
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}
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}
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}
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}
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@ -266,6 +273,88 @@ mod tests {
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assert!(state.loss.abs() < f64::EPSILON);
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assert!(state.loss.abs() < f64::EPSILON);
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}
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}
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// this problem is from a sangaku by Irisawa Shintarō Hiroatsu. the article
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// below includes a nice translation of the problem statement, which was
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// recorded in Uchida Itsumi's book _Kokon sankan_ (_Mathematics, Past and
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// Present_)
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//
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// "Japan's 'Wasan' Mathematical Tradition", by Abe Haruki
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// https://www.nippon.com/en/japan-topics/c12801/
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//
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#[test]
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fn irisawa_hexlet_test() {
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let gram = PartialMatrix({
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let mut entries = Vec::<MatrixEntry>::new();
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for s in 0..9 {
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// each sphere is represented by a spacelike vector
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entries.push(MatrixEntry { index: (s, s), value: 1.0 });
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// the circumscribing sphere is tangent to all of the other
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// spheres, with matching orientation
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if s > 0 {
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entries.push(MatrixEntry { index: (0, s), value: 1.0 });
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entries.push(MatrixEntry { index: (s, 0), value: 1.0 });
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}
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if s > 2 {
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// each chain sphere is tangent to the "sun" and "moon"
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// spheres, with opposing orientation
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for n in 1..3 {
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entries.push(MatrixEntry { index: (s, n), value: -1.0 });
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entries.push(MatrixEntry { index: (n, s), value: -1.0 });
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}
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// each chain sphere is tangent to the next chain sphere,
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// with opposing orientation
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let s_next = 3 + (s-2) % 6;
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entries.push(MatrixEntry { index: (s, s_next), value: -1.0 });
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entries.push(MatrixEntry { index: (s_next, s), value: -1.0 });
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}
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}
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entries
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});
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let guess = DMatrix::from_columns(
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[
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sphere(0.0, 0.0, 0.0, 15.0),
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sphere(0.0, 0.0, -9.0, 5.0),
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sphere(0.0, 0.0, 11.0, 3.0)
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].into_iter().chain(
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(1..=6).map(
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|k| {
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let ang = (k as f64) * PI/3.0;
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sphere(9.0 * ang.cos(), 9.0 * ang.sin(), 0.0, 2.5)
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}
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)
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).collect::<Vec<_>>().as_slice()
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);
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let frozen: [(usize, usize); 4] = array::from_fn(|k| (3, k));
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const SCALED_TOL: f64 = 1.0e-12;
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let (config, success) = realize_gram(
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&gram, guess, &frozen,
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SCALED_TOL, 0.5, 0.9, 1.1, 200, 110
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);
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print!("\nCompleted Gram matrix:{}", config.tr_mul(&*Q) * &config);
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let final_state = SearchState::from_config(&gram, config);
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if success {
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println!("Target accuracy achieved!");
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} else {
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println!("Failed to reach target accuracy");
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}
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println!("Loss: {}", final_state.loss);
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if success {
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println!("\nChain diameters:");
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println!(" {} sun (given)", 1.0 / final_state.config[(3, 3)]);
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for k in 4..9 {
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println!(" {} sun", 1.0 / final_state.config[(3, k)]);
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}
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}
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let entry_tol = SCALED_TOL.sqrt();
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let solution_diams = [30.0, 10.0, 6.0, 5.0, 15.0, 10.0, 3.75, 2.5, 2.0 + 8.0/11.0];
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for (k, diam) in solution_diams.into_iter().enumerate() {
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assert!((final_state.config[(3, k)] - 1.0 / diam).abs() < entry_tol);
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}
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}
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// --- process inspection examples ---
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// --- process inspection examples ---
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// these tests are meant for human inspection, not automated use. run them
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// these tests are meant for human inspection, not automated use. run them
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@ -281,7 +370,7 @@ mod tests {
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for k in 0..3 {
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for k in 0..3 {
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entries.push(MatrixEntry {
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entries.push(MatrixEntry {
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index: (j, k),
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index: (j, k),
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val: if j == k { 1.0 } else { -1.0 }
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value: if j == k { 1.0 } else { -1.0 }
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});
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});
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}
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}
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}
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}
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@ -318,7 +407,7 @@ mod tests {
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for k in 0..2 {
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for k in 0..2 {
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entries.push(MatrixEntry {
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entries.push(MatrixEntry {
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index: (j, k),
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index: (j, k),
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val: if (j, k) == (1, 1) { 1.0 } else { 0.0 }
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value: if (j, k) == (1, 1) { 1.0 } else { 0.0 }
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});
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});
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}
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}
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}
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}
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@ -328,9 +417,10 @@ mod tests {
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point(0.0, 0.0, 2.0),
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point(0.0, 0.0, 2.0),
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sphere(0.0, 0.0, 0.0, 1.0)
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sphere(0.0, 0.0, 0.0, 1.0)
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]);
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]);
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let frozen = [(3, 0)];
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println!();
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println!();
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let (config, success) = realize_gram(
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let (config, success) = realize_gram(
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&gram, guess, &[(3, 0)],
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&gram, guess, &frozen,
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1.0e-12, 0.5, 0.9, 1.1, 200, 110
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1.0e-12, 0.5, 0.9, 1.1, 200, 110
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);
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);
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print!("\nCompleted Gram matrix:{}", config.tr_mul(&*Q) * &config);
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print!("\nCompleted Gram matrix:{}", config.tr_mul(&*Q) * &config);
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