nalgebra-lapack: add Symmetric eigensystems.
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@ -16,6 +16,7 @@ extern crate nalgebra as na;
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mod lapack_check;
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mod lapack_check;
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mod svd;
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mod svd;
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mod eigen;
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mod eigen;
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mod symmetric_eigen;
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mod cholesky;
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mod cholesky;
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mod lu;
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mod lu;
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mod qr;
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mod qr;
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@ -27,6 +28,7 @@ pub use self::svd::SVD;
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pub use self::cholesky::{Cholesky, CholeskyScalar};
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pub use self::cholesky::{Cholesky, CholeskyScalar};
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pub use self::lu::{LU, LUScalar};
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pub use self::lu::{LU, LUScalar};
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pub use self::eigen::RealEigensystem;
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pub use self::eigen::RealEigensystem;
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pub use self::symmetric_eigen::SymmetricEigen;
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pub use self::qr::QR;
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pub use self::qr::QR;
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pub use self::hessenberg::Hessenberg;
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pub use self::hessenberg::Hessenberg;
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@ -0,0 +1,146 @@
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use num::Zero;
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use std::ops::MulAssign;
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use alga::general::Real;
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use ::ComplexHelper;
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use na::{Scalar, DefaultAllocator, Matrix, VectorN, MatrixN};
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use na::dimension::{Dim, U1};
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use na::storage::Storage;
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use na::allocator::Allocator;
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use lapack::fortran as interface;
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/// Eigendecomposition of a real square matrix with real eigenvalues.
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pub struct SymmetricEigen<N: Scalar, D: Dim>
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where DefaultAllocator: Allocator<N, D> +
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Allocator<N, D, D> {
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pub eigenvalues: VectorN<N, D>,
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pub eigenvectors: MatrixN<N, D>,
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}
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impl<N: RealEigensystemScalar + Real, D: Dim> SymmetricEigen<N, D>
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where DefaultAllocator: Allocator<N, D, D> +
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Allocator<N, D> {
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/// Computes the eigenvalues and eigenvectors of the symmetric matrix `m`.
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///
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/// Only the lower-triangular part of `m` is read. If `eigenvectors` is `false` then, the
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/// eigenvectors are not computed explicitly. Panics if the method did not converge.
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pub fn new(m: MatrixN<N, D>) -> Self {
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let (vals, vecs) = Self::do_decompose(m, true).expect("SymmetricEigen: convergence failure.");
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SymmetricEigen { eigenvalues: vals, eigenvectors: vecs.unwrap() }
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}
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/// Computes the eigenvalues and eigenvectors of the symmetric matrix `m`.
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///
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/// Only the lower-triangular part of `m` is read. If `eigenvectors` is `false` then, the
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/// eigenvectors are not computed explicitly. Returns `None` if the method did not converge.
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pub fn try_new(m: MatrixN<N, D>) -> Option<Self> {
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Self::do_decompose(m, true).map(|(vals, vecs)| {
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SymmetricEigen { eigenvalues: vals, eigenvectors: vecs.unwrap() }
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})
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}
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fn do_decompose(mut m: MatrixN<N, D>, eigenvectors: bool) -> Option<(VectorN<N, D>, Option<MatrixN<N, D>>)> {
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assert!(m.is_square(), "Unable to compute the eigenvalue decomposition of a non-square matrix.");
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let jobz = if eigenvectors { b'V' } else { b'N' };
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let (nrows, ncols) = m.data.shape();
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let n = nrows.value();
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let lda = n as i32;
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let mut values = unsafe { Matrix::new_uninitialized_generic(nrows, U1) };
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let mut info = 0;
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let lwork = N::xsyev_work_size(jobz, b'L', n as i32, m.as_mut_slice(), lda, &mut info);
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lapack_check!(info);
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let mut work = unsafe { ::uninitialized_vec(lwork as usize) };
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N::xsyev(jobz, b'L', n as i32, m.as_mut_slice(), lda, values.as_mut_slice(), &mut work, lwork, &mut info);
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lapack_check!(info);
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let vectors = if eigenvectors { Some(m) } else { None };
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Some((values, vectors))
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}
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/// Computes only the eigenvalues of the input matrix.
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///
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/// Panics if the method does not converge.
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pub fn eigenvalues(mut m: MatrixN<N, D>) -> VectorN<N, D> {
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Self::do_decompose(m, false).expect("SymmetricEigen eigenvalues: convergence failure.").0
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}
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/// Computes only the eigenvalues of the input matrix.
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///
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/// Returns `None` if the method does not converge.
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pub fn try_eigenvalues(mut m: MatrixN<N, D>) -> Option<VectorN<N, D>> {
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Self::do_decompose(m, false).map(|res| res.0)
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}
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/// The determinant of the decomposed matrix.
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#[inline]
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pub fn determinant(&self) -> N {
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let mut det = N::one();
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for e in self.eigenvalues.iter() {
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det *= *e;
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}
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det
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}
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/// Rebuild the original matrix.
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///
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/// This is useful if some of the eigenvalues have been manually modified.
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pub fn recompose(&self) -> MatrixN<N, D> {
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let mut u_t = self.eigenvectors.clone();
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for i in 0 .. self.eigenvalues.len() {
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let val = self.eigenvalues[i];
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u_t.column_mut(i).mul_assign(val);
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}
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u_t.transpose_mut();
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&self.eigenvectors * u_t
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}
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}
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/*
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*
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* Lapack functions dispatch.
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*
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*/
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pub trait RealEigensystemScalar: Scalar {
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fn xsyev(jobz: u8, uplo: u8, n: i32, a: &mut [Self], lda: i32, w: &mut [Self], work: &mut [Self],
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lwork: i32, info: &mut i32);
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fn xsyev_work_size(jobz: u8, uplo: u8, n: i32, a: &mut [Self], lda: i32, info: &mut i32) -> i32;
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}
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macro_rules! real_eigensystem_scalar_impl (
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($N: ty, $xsyev: path) => (
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impl RealEigensystemScalar for $N {
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#[inline]
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fn xsyev(jobz: u8, uplo: u8, n: i32, a: &mut [Self], lda: i32, w: &mut [Self], work: &mut [Self],
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lwork: i32, info: &mut i32) {
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$xsyev(jobz, uplo, n, a, lda, w, work, lwork, info)
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}
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#[inline]
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fn xsyev_work_size(jobz: u8, uplo: u8, n: i32, a: &mut [Self], lda: i32, info: &mut i32) -> i32 {
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let mut work = [ Zero::zero() ];
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let mut w = [ Zero::zero() ];
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let lwork = -1 as i32;
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$xsyev(jobz, uplo, n, a, lda, &mut w, &mut work, lwork, info);
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ComplexHelper::real_part(work[0]) as i32
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}
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}
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)
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);
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real_eigensystem_scalar_impl!(f32, interface::ssyev);
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real_eigensystem_scalar_impl!(f64, interface::dsyev);
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@ -1,4 +1,5 @@
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mod real_eigensystem;
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mod real_eigensystem;
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mod symmetric_eigen;
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mod cholesky;
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mod cholesky;
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mod lu;
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mod lu;
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mod qr;
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mod qr;
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@ -0,0 +1,20 @@
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use std::cmp;
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use nl::SymmetricEigen;
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use na::{DMatrix, Matrix4};
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quickcheck!{
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fn symmetric_eigen(n: usize) -> bool {
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let n = cmp::max(1, cmp::min(n, 10));
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let m = DMatrix::<f64>::new_random(n, n);
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let eig = SymmetricEigen::new(m.clone());
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let recomp = eig.recompose();
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relative_eq!(m.lower_triangle(), recomp.lower_triangle(), epsilon = 1.0e-5)
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}
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fn symmetric_eigen_static(m: Matrix4<f64>) -> bool {
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let eig = SymmetricEigen::new(m);
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let recomp = eig.recompose();
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relative_eq!(m.lower_triangle(), recomp.lower_triangle(), epsilon = 1.0e-5)
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}
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}
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