#ifndef MSP_GEOMETRY_TRANSFORMEDSHAPE_H_
#define MSP_GEOMETRY_TRANSFORMEDSHAPE_H_
-#include "affinetransformation.h"
-#include "ray.h"
+#include "affinetransform.h"
#include "shape.h"
namespace Msp {
namespace Geometry {
+/**
+A shape modified by an affine transformation.
+*/
template<typename T, unsigned D>
class TransformedShape: public Shape<T, D>
{
private:
Shape<T, D> *shape;
- AffineTransformation<T, D> transformation;
- AffineTransformation<T, D> inverse_trans;
+ AffineTransform<T, D> transformation;
+ AffineTransform<T, D> inverse_trans;
public:
- TransformedShape(const Shape<T, D> &, const AffineTransformation<T, D> &);
+ TransformedShape(const Shape<T, D> &, const AffineTransform<T, D> &);
TransformedShape(const TransformedShape &);
TransformedShape &operator=(const TransformedShape &);
~TransformedShape();
virtual TransformedShape *clone() const;
const Shape<T, D> &get_shape() const { return *shape; }
- const AffineTransformation<T, D> &get_transformation() const { return transformation; }
+ const AffineTransform<T, D> &get_transformation() const { return transformation; }
- virtual HyperBox<T, D> get_axis_aligned_bounding_box() const;
- virtual bool check_intersection(const Ray<T, D> &) const;
+ virtual BoundingBox<T, D> get_axis_aligned_bounding_box(unsigned = 0) const;
+ virtual bool contains(const LinAl::Vector<T, D> &) const;
+ virtual unsigned get_max_ray_intersections() const { return shape->get_max_ray_intersections(); }
+ virtual unsigned get_intersections(const Ray<T, D> &, SurfacePoint<T, D> *, unsigned) const;
+ virtual Coverage get_coverage(const BoundingBox<T, D> &) const;
};
template<typename T, unsigned D>
-inline TransformedShape<T, D>::TransformedShape(const Shape<T, D> &s, const AffineTransformation<T, D> &t):
+inline TransformedShape<T, D>::TransformedShape(const Shape<T, D> &s, const AffineTransform<T, D> &t):
shape(s.clone()),
transformation(t),
inverse_trans(invert(t))
{ }
template<typename T, unsigned D>
-inline TransformedShape<T, D>::TransformedShape(const TransformedShape &other):
+inline TransformedShape<T, D>::TransformedShape(const TransformedShape<T, D> &other):
shape(other.shape->clone()),
transformation(other.transformation),
inverse_trans(other.inverse_trans)
}
template<typename T, unsigned D>
-inline HyperBox<T, D> TransformedShape<T, D>::get_axis_aligned_bounding_box() const
+inline BoundingBox<T, D> TransformedShape<T, D>::get_axis_aligned_bounding_box(unsigned detail) const
{
- // XXX This is not correct for most shapes
- return shape->get_axis_aligned_bounding_box();
+ if(detail)
+ return this->bisect_axis_aligned_bounding_box(detail);
+
+ return transformation.transform(shape->get_axis_aligned_bounding_box());
+}
+
+template<typename T, unsigned D>
+inline bool TransformedShape<T, D>::contains(const LinAl::Vector<T, D> &point) const
+{
+ return shape->contains(inverse_trans.transform(point));
+}
+
+template<typename T, unsigned D>
+inline unsigned TransformedShape<T, D>::get_intersections(const Ray<T, D> &ray, SurfacePoint<T, D> *points, unsigned size) const
+{
+ Ray<T, D> local_ray = inverse_trans.transform(ray);
+
+ unsigned count = shape->get_intersections(local_ray, points, size);
+ if(points)
+ {
+ for(unsigned i=0; i<count; ++i)
+ {
+ points[i].position = transformation.transform(points[i].position);
+ /* XXX This is not correct for nonuniform scaling. Inverse of the
+ transpose of the upper DxD part of the matrix should be used. */
+ points[i].normal = transformation.transform_linear(points[i].normal);
+ points[i].distance = inner_product(points[i].position-ray.get_start(), ray.get_direction());
+ }
+ }
+ return count;
}
template<typename T, unsigned D>
-inline bool TransformedShape<T, D>::check_intersection(const Ray<T, D> &ray) const
+inline Coverage TransformedShape<T, D>::get_coverage(const BoundingBox<T, D> &bbox) const
{
- Ray<T, D> local_ray(inverse_trans.transform(ray.get_start()),
- inverse_trans.transform_linear(ray.get_direction()));
- return shape->check_intersection(local_ray);
+ BoundingBox<T, D> local_bbox = inverse_trans.transform(bbox);
+ Coverage coverage = shape->get_coverage(local_bbox);
+ if(coverage==PARTIAL_COVERAGE)
+ {
+ BoundingBox<T, D> outer_bbox = transformation.transform(local_bbox);
+ LinAl::Vector<T, D> min_pt = local_bbox.get_minimum_point();
+ LinAl::Vector<T, D> max_pt = local_bbox.get_maximum_point();
+ for(unsigned i=0; i<D; ++i)
+ {
+ T scale_ratio = (1-bbox.get_dimension(i)/outer_bbox.get_dimension(i))*local_bbox.get_dimension(i);
+ T low_gap = bbox.get_minimum_coordinate(i)-outer_bbox.get_minimum_coordinate(i);
+ T high_gap = outer_bbox.get_maximum_coordinate(i)-bbox.get_maximum_coordinate(i);
+ min_pt[i] += low_gap*scale_ratio;
+ max_pt[i] -= high_gap-scale_ratio;
+ }
+
+ local_bbox = BoundingBox<T, D>(min_pt, max_pt);
+ if(shape->get_coverage(local_bbox)>=PARTIAL_COVERAGE)
+ return PARTIAL_COVERAGE;
+ else
+ return UNCERTAIN_COVERAGE;
+ }
+ else
+ return coverage;
}
} // namespace Geometry