nalgebra/tests/core/conversion.rs

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#![cfg(all(feature = "proptest-support", feature = "alga"))]
use alga::linear::Transformation;
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use na::{
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self, Affine3, Isometry3, Matrix2, Matrix2x3, Matrix2x4, Matrix2x5, Matrix2x6, Matrix3,
Matrix3x2, Matrix3x4, Matrix3x5, Matrix3x6, Matrix4, Matrix4x2, Matrix4x3, Matrix4x5,
Matrix4x6, Matrix5, Matrix5x2, Matrix5x3, Matrix5x4, Matrix5x6, Matrix6, Matrix6x2, Matrix6x3,
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Matrix6x4, Matrix6x5, Projective3, Rotation3, RowVector1, RowVector2, RowVector3, RowVector4,
RowVector5, RowVector6, Similarity3, Transform3, UnitQuaternion, Vector1, Vector2, Vector3,
Vector4, Vector5, Vector6,
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};
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use na::{DMatrix, DMatrixSlice, DMatrixSliceMut, MatrixSlice, MatrixSliceMut};
use na::{U1, U3, U4};
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use crate::proptest::*;
use proptest::{prop_assert, prop_assert_eq, proptest};
proptest! {
#[test]
fn translation_conversion(t in translation3(), v in vector3(), p in point3()) {
let iso: Isometry3<f64> = na::convert(t);
let sim: Similarity3<f64> = na::convert(t);
let aff: Affine3<f64> = na::convert(t);
let prj: Projective3<f64> = na::convert(t);
let tr: Transform3<f64> = na::convert(t);
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prop_assert_eq!(t, na::try_convert(iso).unwrap());
prop_assert_eq!(t, na::try_convert(sim).unwrap());
prop_assert_eq!(t, na::try_convert(aff).unwrap());
prop_assert_eq!(t, na::try_convert(prj).unwrap());
prop_assert_eq!(t, na::try_convert(tr).unwrap() );
prop_assert_eq!(t.transform_vector(&v), iso * v);
prop_assert_eq!(t.transform_vector(&v), sim * v);
prop_assert_eq!(t.transform_vector(&v), aff * v);
prop_assert_eq!(t.transform_vector(&v), prj * v);
prop_assert_eq!(t.transform_vector(&v), tr * v);
prop_assert_eq!(t * p, iso * p);
prop_assert_eq!(t * p, sim * p);
prop_assert_eq!(t * p, aff * p);
prop_assert_eq!(t * p, prj * p);
prop_assert_eq!(t * p, tr * p);
}
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#[test]
fn rotation_conversion(r in rotation3(), v in vector3(), p in point3()) {
let uq: UnitQuaternion<f64> = na::convert(r);
let iso: Isometry3<f64> = na::convert(r);
let sim: Similarity3<f64> = na::convert(r);
let aff: Affine3<f64> = na::convert(r);
let prj: Projective3<f64> = na::convert(r);
let tr: Transform3<f64> = na::convert(r);
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prop_assert!(relative_eq!(r, na::try_convert(uq).unwrap(), epsilon = 1.0e-7));
prop_assert!(relative_eq!(r, na::try_convert(iso).unwrap(), epsilon = 1.0e-7));
prop_assert!(relative_eq!(r, na::try_convert(sim).unwrap(), epsilon = 1.0e-7));
prop_assert_eq!(r, na::try_convert(aff).unwrap());
prop_assert_eq!(r, na::try_convert(prj).unwrap());
prop_assert_eq!(r, na::try_convert(tr).unwrap() );
// NOTE: we need relative_eq because Isometry and Similarity use quaternions.
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prop_assert!(relative_eq!(r * v, uq * v, epsilon = 1.0e-7));
prop_assert!(relative_eq!(r * v, iso * v, epsilon = 1.0e-7));
prop_assert!(relative_eq!(r * v, sim * v, epsilon = 1.0e-7));
prop_assert_eq!(r * v, aff * v);
prop_assert_eq!(r * v, prj * v);
prop_assert_eq!(r * v, tr * v);
prop_assert!(relative_eq!(r * p, uq * p, epsilon = 1.0e-7));
prop_assert!(relative_eq!(r * p, iso * p, epsilon = 1.0e-7));
prop_assert!(relative_eq!(r * p, sim * p, epsilon = 1.0e-7));
prop_assert_eq!(r * p, aff * p);
prop_assert_eq!(r * p, prj * p);
prop_assert_eq!(r * p, tr * p);
}
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#[test]
fn unit_quaternion_conversion(uq in unit_quaternion(), v in vector3(), p in point3()) {
let rot: Rotation3<f64> = na::convert(uq);
let iso: Isometry3<f64> = na::convert(uq);
let sim: Similarity3<f64> = na::convert(uq);
let aff: Affine3<f64> = na::convert(uq);
let prj: Projective3<f64> = na::convert(uq);
let tr: Transform3<f64> = na::convert(uq);
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prop_assert_eq!(uq, na::try_convert(iso).unwrap());
prop_assert_eq!(uq, na::try_convert(sim).unwrap());
prop_assert!(relative_eq!(uq, na::try_convert(rot).unwrap(), epsilon = 1.0e-7));
prop_assert!(relative_eq!(uq, na::try_convert(aff).unwrap(), epsilon = 1.0e-7));
prop_assert!(relative_eq!(uq, na::try_convert(prj).unwrap(), epsilon = 1.0e-7));
prop_assert!(relative_eq!(uq, na::try_convert(tr).unwrap(), epsilon = 1.0e-7) );
// NOTE: iso and sim use unit quaternions for the rotation so conversions to them are exact.
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prop_assert!(relative_eq!(uq * v, rot * v, epsilon = 1.0e-7));
prop_assert_eq!(uq * v, iso * v);
prop_assert_eq!(uq * v, sim * v);
prop_assert!(relative_eq!(uq * v, aff * v, epsilon = 1.0e-7));
prop_assert!(relative_eq!(uq * v, prj * v, epsilon = 1.0e-7));
prop_assert!(relative_eq!(uq * v, tr * v, epsilon = 1.0e-7));
prop_assert!(relative_eq!(uq * p, rot * p, epsilon = 1.0e-7));
prop_assert_eq!(uq * p, iso * p);
prop_assert_eq!(uq * p, sim * p);
prop_assert!(relative_eq!(uq * p, aff * p, epsilon = 1.0e-7));
prop_assert!(relative_eq!(uq * p, prj * p, epsilon = 1.0e-7));
prop_assert!(relative_eq!(uq * p, tr * p, epsilon = 1.0e-7));
}
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#[test]
fn isometry_conversion(iso in isometry3(), v in vector3(), p in point3()) {
let sim: Similarity3<f64> = na::convert(iso);
let aff: Affine3<f64> = na::convert(iso);
let prj: Projective3<f64> = na::convert(iso);
let tr: Transform3<f64> = na::convert(iso);
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prop_assert_eq!(iso, na::try_convert(sim).unwrap());
prop_assert!(relative_eq!(iso, na::try_convert(aff).unwrap(), epsilon = 1.0e-7));
prop_assert!(relative_eq!(iso, na::try_convert(prj).unwrap(), epsilon = 1.0e-7));
prop_assert!(relative_eq!(iso, na::try_convert(tr).unwrap(), epsilon = 1.0e-7) );
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prop_assert_eq!(iso * v, sim * v);
prop_assert!(relative_eq!(iso * v, aff * v, epsilon = 1.0e-7));
prop_assert!(relative_eq!(iso * v, prj * v, epsilon = 1.0e-7));
prop_assert!(relative_eq!(iso * v, tr * v, epsilon = 1.0e-7));
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prop_assert_eq!(iso * p, sim * p);
prop_assert!(relative_eq!(iso * p, aff * p, epsilon = 1.0e-7));
prop_assert!(relative_eq!(iso * p, prj * p, epsilon = 1.0e-7));
prop_assert!(relative_eq!(iso * p, tr * p, epsilon = 1.0e-7));
}
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#[test]
fn similarity_conversion(sim in similarity3(), v in vector3(), p in point3()) {
let aff: Affine3<f64> = na::convert(sim);
let prj: Projective3<f64> = na::convert(sim);
let tr: Transform3<f64> = na::convert(sim);
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prop_assert!(relative_eq!(sim, na::try_convert(aff).unwrap(), epsilon = 1.0e-7));
prop_assert!(relative_eq!(sim, na::try_convert(prj).unwrap(), epsilon = 1.0e-7));
prop_assert!(relative_eq!(sim, na::try_convert(tr).unwrap(), epsilon = 1.0e-7));
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prop_assert!(relative_eq!(sim * v, aff * v, epsilon = 1.0e-7));
prop_assert!(relative_eq!(sim * v, prj * v, epsilon = 1.0e-7));
prop_assert!(relative_eq!(sim * v, tr * v, epsilon = 1.0e-7));
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prop_assert!(relative_eq!(sim * p, aff * p, epsilon = 1.0e-7));
prop_assert!(relative_eq!(sim * p, prj * p, epsilon = 1.0e-7));
prop_assert!(relative_eq!(sim * p, tr * p, epsilon = 1.0e-7));
}
// XXX test Transform
}
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macro_rules! array_vector_conversion(
($($array_vector_conversion_i: ident, $Vector: ident, $SZ: expr);* $(;)*) => {$(
#[test]
fn $array_vector_conversion_i() {
let v = $Vector::from_fn(|i, _| i);
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let arr: [usize; $SZ] = v.into();
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let arr_ref: &[usize; $SZ] = v.as_ref();
let v2 = $Vector::from(arr);
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for i in 0 .. $SZ {
assert_eq!(arr[i], i);
assert_eq!(arr_ref[i], i);
}
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assert_eq!(v, v2);
}
)*}
);
array_vector_conversion!(
array_vector_conversion_1, Vector1, 1;
array_vector_conversion_2, Vector2, 2;
array_vector_conversion_3, Vector3, 3;
array_vector_conversion_4, Vector4, 4;
array_vector_conversion_5, Vector5, 5;
array_vector_conversion_6, Vector6, 6;
);
macro_rules! array_row_vector_conversion(
($($array_vector_conversion_i: ident, $Vector: ident, $SZ: expr);* $(;)*) => {$(
#[test]
fn $array_vector_conversion_i() {
let v = $Vector::from_fn(|_, i| i);
let arr: [usize; $SZ] = v.into();
let arr_ref = v.as_ref();
let v2 = $Vector::from(arr);
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for i in 0 .. $SZ {
assert_eq!(arr[i], i);
assert_eq!(arr_ref[i], i);
}
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assert_eq!(v, v2);
}
)*}
);
array_row_vector_conversion!(
array_row_vector_conversion_1, RowVector1, 1;
array_row_vector_conversion_2, RowVector2, 2;
array_row_vector_conversion_3, RowVector3, 3;
array_row_vector_conversion_4, RowVector4, 4;
array_row_vector_conversion_5, RowVector5, 5;
array_row_vector_conversion_6, RowVector6, 6;
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);
macro_rules! array_matrix_conversion(
($($array_matrix_conversion_i_j: ident, $Matrix: ident, ($NRows: expr, $NCols: expr));* $(;)*) => {$(
#[test]
fn $array_matrix_conversion_i_j() {
let m = $Matrix::from_fn(|i, j| i * 10 + j);
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let arr: [[usize; $NRows]; $NCols] = m.into();
let arr_ref = m.as_ref();
let m2 = $Matrix::from(arr);
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for i in 0 .. $NRows {
for j in 0 .. $NCols {
assert_eq!(arr[j][i], i * 10 + j);
assert_eq!(arr_ref[j][i], i * 10 + j);
}
}
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assert_eq!(m, m2);
}
)*}
);
array_matrix_conversion!(
array_matrix_conversion_2_2, Matrix2, (2, 2);
array_matrix_conversion_2_3, Matrix2x3, (2, 3);
array_matrix_conversion_2_4, Matrix2x4, (2, 4);
array_matrix_conversion_2_5, Matrix2x5, (2, 5);
array_matrix_conversion_2_6, Matrix2x6, (2, 6);
array_matrix_conversion_3_2, Matrix3x2, (3, 2);
array_matrix_conversion_3_3, Matrix3, (3, 3);
array_matrix_conversion_3_4, Matrix3x4, (3, 4);
array_matrix_conversion_3_5, Matrix3x5, (3, 5);
array_matrix_conversion_3_6, Matrix3x6, (3, 6);
array_matrix_conversion_4_2, Matrix4x2, (4, 2);
array_matrix_conversion_4_3, Matrix4x3, (4, 3);
array_matrix_conversion_4_4, Matrix4, (4, 4);
array_matrix_conversion_4_5, Matrix4x5, (4, 5);
array_matrix_conversion_4_6, Matrix4x6, (4, 6);
array_matrix_conversion_5_2, Matrix5x2, (5, 2);
array_matrix_conversion_5_3, Matrix5x3, (5, 3);
array_matrix_conversion_5_4, Matrix5x4, (5, 4);
array_matrix_conversion_5_5, Matrix5, (5, 5);
array_matrix_conversion_5_6, Matrix5x6, (5, 6);
array_matrix_conversion_6_2, Matrix6x2, (6, 2);
array_matrix_conversion_6_3, Matrix6x3, (6, 3);
array_matrix_conversion_6_4, Matrix6x4, (6, 4);
array_matrix_conversion_6_5, Matrix6x5, (6, 5);
array_matrix_conversion_6_6, Matrix6, (6, 6);
);
#[test]
fn matrix_slice_from_matrix_ref() {
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let a = Matrix3x4::new(
11.0, 12.0, 13.0, 14.0, 21.0, 22.0, 23.0, 24.0, 31.0, 32.0, 33.0, 34.0,
);
// TODO: What's a more idiomatic/better way to convert a static matrix to a dynamic one?
let d = DMatrix::from(a.get((0..a.nrows(), 0..a.ncols())).unwrap());
// Note: these have to be macros, and not functions, because the input type is different
// across the different tests. Moreover, the output type depends on the stride of the input,
// which is different for static and dynamic matrices.
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macro_rules! dynamic_slice {
($mref:expr) => {
DMatrixSlice::<_>::from($mref)
};
}
macro_rules! dynamic_slice_mut {
($mref:expr) => {
DMatrixSliceMut::<_>::from($mref)
};
}
macro_rules! fixed_slice {
($mref:expr) => {
MatrixSlice::<_, U3, U4, U1, U3>::from($mref)
};
}
macro_rules! fixed_slice_mut {
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($mref:expr) => {
MatrixSliceMut::<_, U3, U4, U1, U3>::from($mref)
};
}
// TODO: The `into_owned()` is a result of `PartialEq` not being implemented for different
// Self and RHS. See issue #674. Once this is implemented, we can remove `into_owned`
// from the below tests.
// Construct slices from reference to a
{
assert_eq!(a, fixed_slice!(&a).into_owned());
assert_eq!(d, dynamic_slice!(&a).into_owned());
}
// Construct slices from mutable reference to a
{
let mut a_clone = a.clone();
assert_eq!(a, fixed_slice!(&mut a_clone).into_owned());
assert_eq!(d, dynamic_slice!(&mut a_clone).into_owned());
}
// Construct mutable slices from mutable reference to a
{
let mut a_clone = a.clone();
assert_eq!(a, fixed_slice_mut!(&mut a_clone).into_owned());
assert_eq!(d, dynamic_slice_mut!(&mut a_clone).into_owned());
}
// Construct slices from reference to d
{
assert_eq!(a, fixed_slice!(&d).into_owned());
assert_eq!(d, dynamic_slice!(&d).into_owned());
}
// Construct slices from mutable reference to d
{
let mut d_clone = a.clone();
assert_eq!(a, fixed_slice!(&mut d_clone).into_owned());
assert_eq!(d, dynamic_slice!(&mut d_clone).into_owned());
}
// Construct mutable slices from mutable reference to d
{
let mut d_clone = d.clone();
assert_eq!(a, fixed_slice_mut!(&mut d_clone).into_owned());
assert_eq!(d, dynamic_slice_mut!(&mut d_clone).into_owned());
}
// Construct slices from a slice of a
{
let mut a_slice = fixed_slice!(&a);
assert_eq!(a, fixed_slice!(&a_slice).into_owned());
assert_eq!(a, fixed_slice!(&mut a_slice).into_owned());
assert_eq!(d, dynamic_slice!(&a_slice).into_owned());
assert_eq!(d, dynamic_slice!(&mut a_slice).into_owned());
}
// Construct slices from a slice mut of a
{
// Need a clone of a here, so that we can both have a mutable borrow and compare equality
let mut a_clone = a.clone();
let mut a_slice = fixed_slice_mut!(&mut a_clone);
assert_eq!(a, fixed_slice!(&a_slice).into_owned());
assert_eq!(a, fixed_slice!(&mut a_slice).into_owned());
assert_eq!(d, dynamic_slice!(&a_slice).into_owned());
assert_eq!(d, dynamic_slice!(&mut a_slice).into_owned());
assert_eq!(a, fixed_slice_mut!(&mut a_slice).into_owned());
assert_eq!(d, dynamic_slice_mut!(&mut a_slice).into_owned());
}
}