Re-add orthogonalization and subspace basis computation.
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146
src/base/norm.rs
146
src/base/norm.rs
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@ -2,7 +2,7 @@ use num::Zero;
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use std::ops::Neg;
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use crate::allocator::Allocator;
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use crate::base::{DefaultAllocator, Dim, Matrix, MatrixMN, Normed};
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use crate::base::{DefaultAllocator, Dim, DimName, Matrix, MatrixMN, Normed, VectorN};
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use crate::constraint::{SameNumberOfColumns, SameNumberOfRows, ShapeConstraint};
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use crate::storage::{Storage, StorageMut};
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use crate::{ComplexField, Scalar, SimdComplexField, Unit};
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@ -399,3 +399,147 @@ where DefaultAllocator: Allocator<N, R, C>
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Unit::new_unchecked(-self.value)
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}
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}
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// FIXME: specialization will greatly simplify this implementation in the future.
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// In particular:
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// − use `x()` instead of `::canonical_basis_element`
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// − use `::new(x, y, z)` instead of `::from_slice`
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impl<N: ComplexField, D: DimName> VectorN<N, D>
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where DefaultAllocator: Allocator<N, D>
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{
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/// The i-the canonical basis element.
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#[inline]
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fn canonical_basis_element(i: usize) -> Self {
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assert!(i < D::dim(), "Index out of bound.");
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let mut res = Self::zero();
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unsafe {
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*res.data.get_unchecked_linear_mut(i) = N::one();
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}
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res
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}
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/// Orthonormalizes the given family of vectors. The largest free family of vectors is moved at
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/// the beginning of the array and its size is returned. Vectors at an indices larger or equal to
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/// this length can be modified to an arbitrary value.
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#[inline]
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pub fn orthonormalize(vs: &mut [Self]) -> usize {
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let mut nbasis_elements = 0;
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for i in 0..vs.len() {
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{
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let (elt, basis) = vs[..i + 1].split_last_mut().unwrap();
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for basis_element in &basis[..nbasis_elements] {
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*elt -= &*basis_element * elt.dot(basis_element)
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}
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}
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if vs[i].try_normalize_mut(N::RealField::zero()).is_some() {
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// FIXME: this will be efficient on dynamically-allocated vectors but for
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// statically-allocated ones, `.clone_from` would be better.
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vs.swap(nbasis_elements, i);
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nbasis_elements += 1;
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// All the other vectors will be dependent.
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if nbasis_elements == D::dim() {
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break;
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}
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}
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}
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nbasis_elements
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}
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/// Applies the given closure to each element of the orthonormal basis of the subspace
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/// orthogonal to free family of vectors `vs`. If `vs` is not a free family, the result is
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/// unspecified.
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// FIXME: return an iterator instead when `-> impl Iterator` will be supported by Rust.
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#[inline]
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pub fn orthonormal_subspace_basis<F>(vs: &[Self], mut f: F)
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where F: FnMut(&Self) -> bool {
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// FIXME: is this necessary?
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assert!(
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vs.len() <= D::dim(),
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"The given set of vectors has no chance of being a free family."
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);
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match D::dim() {
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1 => {
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if vs.len() == 0 {
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let _ = f(&Self::canonical_basis_element(0));
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}
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}
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2 => {
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if vs.len() == 0 {
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let _ = f(&Self::canonical_basis_element(0))
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&& f(&Self::canonical_basis_element(1));
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} else if vs.len() == 1 {
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let v = &vs[0];
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let res = Self::from_column_slice(&[-v[1], v[0]]);
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let _ = f(&res.normalize());
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}
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// Otherwise, nothing.
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}
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3 => {
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if vs.len() == 0 {
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let _ = f(&Self::canonical_basis_element(0))
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&& f(&Self::canonical_basis_element(1))
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&& f(&Self::canonical_basis_element(2));
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} else if vs.len() == 1 {
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let v = &vs[0];
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let mut a;
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if v[0].norm1() > v[1].norm1() {
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a = Self::from_column_slice(&[v[2], N::zero(), -v[0]]);
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} else {
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a = Self::from_column_slice(&[N::zero(), -v[2], v[1]]);
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};
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let _ = a.normalize_mut();
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if f(&a.cross(v)) {
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let _ = f(&a);
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}
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} else if vs.len() == 2 {
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let _ = f(&vs[0].cross(&vs[1]).normalize());
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}
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}
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_ => {
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#[cfg(any(feature = "std", feature = "alloc"))]
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{
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// XXX: use a GenericArray instead.
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let mut known_basis = Vec::new();
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for v in vs.iter() {
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known_basis.push(v.normalize())
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}
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for i in 0..D::dim() - vs.len() {
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let mut elt = Self::canonical_basis_element(i);
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for v in &known_basis {
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elt -= v * elt.dot(v)
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}
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if let Some(subsp_elt) = elt.try_normalize(N::RealField::zero()) {
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if !f(&subsp_elt) {
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return;
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};
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known_basis.push(subsp_elt);
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}
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}
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}
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#[cfg(all(not(feature = "std"), not(feature = "alloc")))]
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{
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panic!("Cannot compute the orthogonal subspace basis of a vector with a dimension greater than 3 \
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if #![no_std] is enabled and the 'alloc' feature is not enabled.")
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}
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}
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}
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}
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}
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