Made the data argument in Point's __init__method to be an optional argument by making it a boost::python::optional.
/*
* Author: Dmitriy Morozov
* Department of Computer Science, Duke University, 2005 -- 2007
*/
#ifndef __EUCLEDIAN_H__
#define __EUCLEDIAN_H__
#include <utility>
#include <vector>
#include <algorithm>
#include "linalg.h"
#include "number-traits.h"
/**
* Geometric Kernel. Defines operations on geometric primitives.
* \ingroup geometry
*/
template<class NumberType_ = double>
class Kernel
{
public:
typedef unsigned int DimensionType;
typedef NumberType_ NumberType;
typedef LinearAlgebra<NumberType> LinearAlgebraK;
typedef typename LinearAlgebraK::MatrixType MatrixType;
typedef typename LinearAlgebraK::VectorType VectorType;
class Point;
class Sphere;
typedef std::vector<const Point*> PointContainer;
Kernel(DimensionType dimension);
DimensionType dimension() const { return dimension_; }
Point origin() const { return origin_; }
/** Returns matrix describing the equation of a circumsphere of points */
Sphere circumsphere(const PointContainer& points) const;
/** Returns squared radius of the circumsphere */
NumberType circumradius(const PointContainer& points) const;
/** Returns center of the circumsphere */
Point circumcenter(const PointContainer& points) const;
/** The result is positive if points[0] lies outside the circumsphere of points,
0 if points[0] is on the circumsphere, and negative if it's inside */
NumberType side_of_circumsphere(const PointContainer& points, const Point& p) const;
private:
NumberType& normalize(NumberType& n) const;
Point& normalize(Point& p) const;
DimensionType dimension_;
Point origin_;
};
/**
* Point class.
* \ingroup geometry
*/
template<class NumberType_>
class Kernel<NumberType_>::Point: public VectorType
{
public:
typedef VectorType Parent;
typedef NumberType_ NumberType;
Point(DimensionType d): Parent(d) {}
template<class Vec> Point(const Vec& v): Parent(v) {}
Point(const Point& p, const NumberType& pp);
//operator VectorType() const { return *this; }
NumberType squared_distance(const Point& p) const;
using Parent::size;
};
/**
* Sphere class.
* \ingroup geometry
*/
template<class NumberType_>
class Kernel<NumberType_>::Sphere
{
public:
Sphere(const Point& center,
const NumberType& squared_radius):
center_(center), squared_radius_(squared_radius)
{}
/** The result is positive if p lies outside the sphere,
0 if p is on the sphere, and negative if it's inside */
NumberType side_of(const Point& p) const;
const Point& center() const { return center_; }
const NumberType& squared_radius() const { return squared_radius_; }
private:
Point center_;
NumberType squared_radius_;
};
#include "euclidean.hpp"
#endif // __EUCLEDIAN_H__