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#ifndef __CGLA__ARITHVEC3FLOAT_H__

#ifndef __CGLA__ARITHVEC3FLOAT_H__

#define __CGLA__ARITHVEC3FLOAT_H__

#define __CGLA__ARITHVEC3FLOAT_H__

#include "ArithVecFloat.h"

#include "ArithVecFloat.h"

namespace CGLA {

namespace CGLA {

	template<class T, class V>

	template<class T, class V>

	class ArithVec3Float: public ArithVecFloat<T,V,3>

	class ArithVec3Float: public ArithVecFloat<T,V,3>

	{

	{

	public:

	public:

		/// Construct a 3D float vector.

		/// Construct a 3D float vector.

		ArithVec3Float(T a, T b, T c): ArithVecFloat<T,V,3>(a,b,c) {}

		ArithVec3Float(T a, T b, T c): ArithVecFloat<T,V,3>(a,b,c) {}

		/// Construct a 3D float vector.

		/// Construct a 3D float vector.

		ArithVec3Float() {}

		ArithVec3Float() {}

		/** Get the vector in spherical coordinates.

		/** Get the vector in spherical coordinates.

				The first argument (theta) is inclination from the vertical axis.

				The first argument (theta) is inclination from the vertical axis.

				The second argument (phi) is the angle of rotation about the vertical 

				The second argument (phi) is the angle of rotation about the vertical 

				axis. The third argument (r) is the length of the vector. */

				axis. The third argument (r) is the length of the vector. */

		void get_spherical( T&, T&, T& ) const;

		void get_spherical( T&, T&, T& ) const;

		/** Assign the vector in spherical coordinates.

		/** Assign the vector in spherical coordinates.

				The first argument (theta) is inclination from the vertical axis.

				The first argument (theta) is inclination from the vertical axis.

				The second argument (phi) is the angle of rotation about the vertical 

				The second argument (phi) is the angle of rotation about the vertical 

				axis. The third argument (r) is the length of the vector. */

				axis. The third argument (r) is the length of the vector. */

		void set_spherical( T, T, T);

		void set_spherical( T, T, T);

	};

	};

	/// Returns cross product of arguments

	/// Returns cross product of arguments

	template<class T, class V>

	template<class T, class V>

	inline V cross( const ArithVec3Float<T,V>& x, 

	inline V cross( const ArithVec3Float<T,V>& x, 

									const ArithVec3Float<T,V>& y ) 

									const ArithVec3Float<T,V>& y ) 

	{

	{

		return V( x[1] * y[2] - x[2] * y[1], 

		return V( x[1] * y[2] - x[2] * y[1], 

							x[2] * y[0] - x[0] * y[2], 

							x[2] * y[0] - x[0] * y[2], 

							x[0] * y[1] - x[1] * y[0] );

							x[0] * y[1] - x[1] * y[0] );

	}

	}

	/** Compute basis of orthogonal plane.

	/** Compute basis of orthogonal plane.

			Given a vector Compute two vectors that are orthogonal to it and 

			Given a vector Compute two vectors that are orthogonal to it and 

			to each other. */

			to each other. */

	template<class T, class V>

	template<class T, class V>

	void orthogonal(const ArithVec3Float<T,V>&,

	void orthogonal(const ArithVec3Float<T,V>&,

									ArithVec3Float<T,V>&,

									ArithVec3Float<T,V>&,

									ArithVec3Float<T,V>&);

									ArithVec3Float<T,V>&);

}

}

#endif

#endif