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Fix alignedbox 32-bit precision test failure.

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The current `test/geo_alignedbox` tests fail on 32-bit arm due to small floating-point errors.

In particular, the following is not guaranteed to hold:
```
IsometryTransform identity = IsometryTransform::Identity();
BoxType transformedC;
transformedC.extend(c.transformed(identity));
VERIFY(transformedC.contains(c));
```
since `c.transformed(identity)` is ever-so-slightly different from `c`. Instead, we replace this test with one that checks an identity transform is within floating-point precision of `c`.

Also updated the condition on `AlignedBox::transform(...)` to only accept `Affine`, `AffineCompact`, and `Isometry` modes explicitly.  Otherwise, invalid combinations of modes would also incorrectly pass the assertion.
This commit is contained in:
Antonio Sanchez
2020-09-30 08:21:20 -07:00
parent 30960d485e
commit d5a0d89491
2 changed files with 11 additions and 17 deletions
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20
test/geo_alignedbox.cpp
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@@ -47,7 +47,7 @@ template<typename BoxType> void alignedbox(const BoxType& _box)
BoxType b0(dim);
BoxType b1(VectorType::Random(dim),VectorType::Random(dim));
BoxType b2;
kill_extra_precision(b1);
kill_extra_precision(p0);
kill_extra_precision(p1);
@@ -69,7 +69,7 @@ template<typename BoxType> void alignedbox(const BoxType& _box)
BoxType box2(VectorType::Random(dim));
box2.extend(VectorType::Random(dim));
VERIFY(box1.intersects(box2) == !box1.intersection(box2).isEmpty());
VERIFY(box1.intersects(box2) == !box1.intersection(box2).isEmpty());
// alignment -- make sure there is no memory alignment assertion
BoxType *bp0 = new BoxType(dim);
@@ -150,11 +150,9 @@ template<typename BoxType> void alignedboxTranslatable(const BoxType& _box)
VERIFY_IS_APPROX((c.min)(), UnitX * Scalar(9));
VERIFY_IS_APPROX((c.max)(), Ones * Scalar(18) + UnitX * Scalar(9));
// test for roundoff errors
IsometryTransform identity = IsometryTransform::Identity();
BoxType transformedC;
transformedC.extend(c.transformed(identity));
VERIFY(transformedC.contains(c));
// Check identity transform within numerical precision.
BoxType transformedC = c.transformed(IsometryTransform::Identity());
VERIFY_IS_APPROX(transformedC, c);
for (size_t i = 0; i < 10; ++i)
{
@@ -335,10 +333,6 @@ template<typename BoxType, typename Rotation> void alignedboxNonIntegralRotatabl
const Index dim = _box.dim();
const VectorType Zero = VectorType::Zero();
const VectorType Ones = VectorType::Ones();
const VectorType UnitX = VectorType::UnitX();
const VectorType UnitY = VectorType::UnitY();
// this is vector (0, 0, -1, -1, -1, ...), i.e. with zeros at first and second dimensions
const VectorType UnitZ = Ones - UnitX - UnitY;
VectorType minPoint = -2 * Ones;
minPoint[1] = 1;
@@ -365,7 +359,7 @@ template<typename BoxType, typename Rotation> void alignedboxNonIntegralRotatabl
cornerBR = tf2 * cornerBR;
cornerTL = tf2 * cornerTL;
cornerTR = tf2 * cornerTR;
VectorType minCorner = Ones * Scalar(-2);
VectorType maxCorner = Zero;
minCorner[0] = (min)((min)(cornerBL[0], cornerBR[0]), (min)(cornerTL[0], cornerTR[0]));
@@ -471,7 +465,7 @@ template<typename BoxType, typename Rotation> void alignedboxNonIntegralRotatabl
template<typename BoxType>
void alignedboxCastTests(const BoxType& _box)
{
// casting
// casting
typedef typename BoxType::Scalar Scalar;
typedef Matrix<Scalar, BoxType::AmbientDimAtCompileTime, 1> VectorType;