use na::Matrix3; #[test] #[rustfmt::skip] fn lu_simple() { let m = Matrix3::new( 2.0, -1.0, 0.0, -1.0, 2.0, -1.0, 0.0, -1.0, 2.0); let lu = m.lu(); assert_eq!(lu.determinant(), 4.0); let (p, l, u) = lu.unpack(); let mut lu = l * u; p.inv_permute_rows(&mut lu); assert!(relative_eq!(m, lu, epsilon = 1.0e-7)); } #[test] #[rustfmt::skip] fn lu_simple_with_pivot() { let m = Matrix3::new( 0.0, -1.0, 2.0, -1.0, 2.0, -1.0, 2.0, -1.0, 0.0); let lu = m.lu(); assert_eq!(lu.determinant(), -4.0); let (p, l, u) = lu.unpack(); let mut lu = l * u; p.inv_permute_rows(&mut lu); assert!(relative_eq!(m, lu, epsilon = 1.0e-7)); } #[cfg(feature = "proptest-support")] mod proptest_tests { macro_rules! gen_tests( ($module: ident, $scalar: expr, $scalar_type: ty) => { mod $module { use na::{DMatrix, Matrix4x3, DVector, Vector4}; #[allow(unused_imports)] use crate::core::helper::{RandScalar, RandComplex}; use crate::proptest::*; use proptest::{prop_assert, proptest}; proptest! { #[test] fn lu(m in dmatrix_($scalar)) { let lu = m.clone().lu(); let (p, l, u) = lu.unpack(); let mut lu = l * u; p.inv_permute_rows(&mut lu); prop_assert!(relative_eq!(m, lu, epsilon = 1.0e-7)) } #[test] fn lu_static_3_5(m in matrix3x5_($scalar)) { let lu = m.lu(); let (p, l, u) = lu.unpack(); let mut lu = l * u; p.inv_permute_rows(&mut lu); prop_assert!(relative_eq!(m, lu, epsilon = 1.0e-7)) } fn lu_static_5_3(m in matrix5x3_($scalar)) { let lu = m.lu(); let (p, l, u) = lu.unpack(); let mut lu = l * u; p.inv_permute_rows(&mut lu); prop_assert!(relative_eq!(m, lu, epsilon = 1.0e-7)); } #[test] fn lu_static_square(m in matrix4_($scalar)) { let lu = m.lu(); let (p, l, u) = lu.unpack(); let mut lu = l * u; p.inv_permute_rows(&mut lu); prop_assert!(relative_eq!(m, lu, epsilon = 1.0e-7)); } #[test] fn lu_solve(n in PROPTEST_MATRIX_DIM, nb in PROPTEST_MATRIX_DIM) { let m = DMatrix::<$scalar_type>::new_random(n, n).map(|e| e.0); let lu = m.clone().lu(); let b1 = DVector::<$scalar_type>::new_random(n).map(|e| e.0); let b2 = DMatrix::<$scalar_type>::new_random(n, nb).map(|e| e.0); let sol1 = lu.solve(&b1); let sol2 = lu.solve(&b2); prop_assert!(sol1.is_none() || relative_eq!(&m * sol1.unwrap(), b1, epsilon = 1.0e-6)); prop_assert!(sol2.is_none() || relative_eq!(&m * sol2.unwrap(), b2, epsilon = 1.0e-6)); } #[test] fn lu_solve_static(m in matrix4_($scalar)) { let lu = m.lu(); let b1 = Vector4::<$scalar_type>::new_random().map(|e| e.0); let b2 = Matrix4x3::<$scalar_type>::new_random().map(|e| e.0); let sol1 = lu.solve(&b1); let sol2 = lu.solve(&b2); prop_assert!(sol1.is_none() || relative_eq!(&m * sol1.unwrap(), b1, epsilon = 1.0e-6)); prop_assert!(sol2.is_none() || relative_eq!(&m * sol2.unwrap(), b2, epsilon = 1.0e-6)); } #[test] fn lu_inverse(n in PROPTEST_MATRIX_DIM) { let m = DMatrix::<$scalar_type>::new_random(n, n).map(|e| e.0); let mut l = m.lower_triangle(); let mut u = m.upper_triangle(); // Ensure the matrix is well conditioned for inversion. l.fill_diagonal(na::one()); u.fill_diagonal(na::one()); let m = l * u; let m1 = m.clone().lu().try_inverse().unwrap(); let id1 = &m * &m1; let id2 = &m1 * &m; prop_assert!(id1.is_identity(1.0e-5)); prop_assert!(id2.is_identity(1.0e-5)); } #[test] fn lu_inverse_static(m in matrix4_($scalar)) { let lu = m.lu(); if let Some(m1) = lu.try_inverse() { let id1 = &m * &m1; let id2 = &m1 * &m; prop_assert!(id1.is_identity(1.0e-5)); prop_assert!(id2.is_identity(1.0e-5)); } } } } } ); gen_tests!(complex, complex_f64(), RandComplex); gen_tests!(f64, PROPTEST_F64, RandScalar); }