ellipsoid-inl.h

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#ifndef FCL_SHAPE_ELLIPSOID_INL_H
#define FCL_SHAPE_ELLIPSOID_INL_H
 
#include <iomanip>
#include <sstream>
 
#include "fcl/geometry/shape/ellipsoid.h"
#include "fcl/geometry/shape/representation.h"
 
namespace fcl
{
 
//==============================================================================
extern template
class FCL_EXPORT Ellipsoid<double>;
 
//==============================================================================
template <typename S>
Ellipsoid<S>::Ellipsoid(S a, S b, S c)
  : ShapeBase<S>(), radii(a, b, c)
{
  // Do nothing
}
 
//==============================================================================
template <typename S>
Ellipsoid<S>::Ellipsoid(const Vector3<S>& radii)
  : ShapeBase<S>(), radii(radii)
{
  // Do nothing
}
 
//==============================================================================
template <typename S>
void Ellipsoid<S>::computeLocalAABB()
{
  this->aabb_local.max_ = radii;
  this->aabb_local.min_ = -radii;
 
  this->aabb_center = this->aabb_local.center();
  this->aabb_radius = (this->aabb_local.min_ - this->aabb_center).norm();
}
 
//==============================================================================
template <typename S>
NODE_TYPE Ellipsoid<S>::getNodeType() const
{
  return GEOM_ELLIPSOID;
}
 
//==============================================================================
template <typename S>
Matrix3<S> Ellipsoid<S>::computeMomentofInertia() const
{
  const S V = computeVolume();
 
  const S a2 = radii[0] * radii[0] * V;
  const S b2 = radii[1] * radii[1] * V;
  const S c2 = radii[2] * radii[2] * V;
 
  return Vector3<S>(0.2 * (b2 + c2), 0.2 * (a2 + c2), 0.2 * (a2 + b2)).asDiagonal();
}
 
//==============================================================================
template <typename S>
S Ellipsoid<S>::computeVolume() const
{
  const S pi = constants<S>::pi();
  return 4.0 * pi * radii[0] * radii[1] * radii[2] / 3.0;
}
 
//==============================================================================
template <typename S>
std::vector<Vector3<S>> Ellipsoid<S>::getBoundVertices(
    const Transform3<S>& tf) const
{
  // we use scaled icosahedron to bound the ellipsoid
 
  std::vector<Vector3<S>> result(12);
 
  const auto phi = (1.0 + std::sqrt(5.0)) / 2.0;  // golden ratio
 
  const auto a = std::sqrt(3.0) / (phi * phi);
  const auto b = phi * a;
 
  const auto& A = radii[0];
  const auto& B = radii[1];
  const auto& C = radii[2];
 
  const auto Aa = A * a;
  const auto Ab = A * b;
  const auto Ba = B * a;
  const auto Bb = B * b;
  const auto Ca = C * a;
  const auto Cb = C * b;
 
  result[0] = tf * Vector3<S>(0, Ba, Cb);
  result[1] = tf * Vector3<S>(0, -Ba, Cb);
  result[2] = tf * Vector3<S>(0, Ba, -Cb);
  result[3] = tf * Vector3<S>(0, -Ba, -Cb);
  result[4] = tf * Vector3<S>(Aa, Bb, 0);
  result[5] = tf * Vector3<S>(-Aa, Bb, 0);
  result[6] = tf * Vector3<S>(Aa, -Bb, 0);
  result[7] = tf * Vector3<S>(-Aa, -Bb, 0);
  result[8] = tf * Vector3<S>(Ab, 0, Ca);
  result[9] = tf * Vector3<S>(Ab, 0, -Ca);
  result[10] = tf * Vector3<S>(-Ab, 0, Ca);
  result[11] = tf * Vector3<S>(-Ab, 0, -Ca);
 
  return result;
}
 
//==============================================================================
template <typename S>
std::string Ellipsoid<S>::representation(int precision) const {
  const char* S_str = detail::ScalarRepr<S>::value();
  std::stringstream ss;
  ss << std::setprecision(precision);
  ss << "Ellipsoid<" << S_str << ">(" << radii[0] << ", " << radii[1] << ", "
     << radii[2] << ");";
  return ss.str();
}
 
} // namespace fcl
 
#endif