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#ifndef __CGLA_MAT4X4_H__

#ifndef __CGLA_MAT4X4_H__

#define __CGLA_MAT4X4_H__

#define __CGLA_MAT4X4_H__

#include "ExceptionStandard.h"

#include "ExceptionStandard.h"

#include "CGLA.h"

#include "CGLA.h"

#include "Vec3f.h"

#include "Vec3f.h"

#include "Vec3Hf.h"

#include "Vec3Hf.h"

#include "Vec4f.h"

#include "Vec4f.h"

#include "ArithSqMat4x4Float.h"

#include "ArithSqMat4x4Float.h"

namespace CGLA 

namespace CGLA 

{

{

  /** \brief 4x4 float matrix.

  /** \brief 4x4 float matrix.

      This class is useful for transformations such as perspective projections 

      This class is useful for transformations such as perspective projections 

      or translation where 3x3 matrices do not suffice. */

      or translation where 3x3 matrices do not suffice. */

  class Mat4x4f: public ArithSqMat4x4Float<Vec4f, Mat4x4f>

  class Mat4x4f: public ArithSqMat4x4Float<Vec4f, Mat4x4f>

    {

    {

    public:

    public:

      /// Construct a Mat4x4f from four Vec4f vectors

      /// Construct a Mat4x4f from four Vec4f vectors

      Mat4x4f(Vec4f _a, Vec4f _b, Vec4f _c, Vec4f _d): 

      Mat4x4f(Vec4f _a, Vec4f _b, Vec4f _c, Vec4f _d): 

	ArithSqMat4x4Float<Vec4f, Mat4x4f> (_a,_b,_c,_d) {}

	ArithSqMat4x4Float<Vec4f, Mat4x4f> (_a,_b,_c,_d) {}

      /// Construct the NaN matrix

      /// Construct the NaN matrix

      Mat4x4f() {}

      Mat4x4f() {}

      /// Construct a matrix with identical elements.

      /// Construct a matrix with identical elements.

      explicit Mat4x4f(float a) : ArithSqMat4x4Float<Vec4f, Mat4x4f> (a) {}

      explicit Mat4x4f(float a) : ArithSqMat4x4Float<Vec4f, Mat4x4f> (a) {}

    };

    };

  /// Create a rotation _matrix. Rotates about one of the major axes.

  /// Create a rotation _matrix. Rotates about one of the major axes.

  Mat4x4f rotation_Mat4x4f(CGLA::Axis axis, float angle);

  Mat4x4f rotation_Mat4x4f(CGLA::Axis axis, float angle);

  /// Create a translation matrix

  /// Create a translation matrix

  Mat4x4f translation_Mat4x4f(const Vec3f&);

  Mat4x4f translation_Mat4x4f(const Vec3f&);

  /// Create a scaling matrix.

  /// Create a scaling matrix.

  Mat4x4f scaling_Mat4x4f(const Vec3f&);

  Mat4x4f scaling_Mat4x4f(const Vec3f&);

  /// Create an identity matrix.

  /// Create an identity matrix.

  inline Mat4x4f identity_Mat4x4f()

  inline Mat4x4f identity_Mat4x4f()

    {

    {

      return Mat4x4f(Vec4f(1,0,0,0), 

      return Mat4x4f(Vec4f(1,0,0,0), 

		     Vec4f(0,1,0,0), 

		     Vec4f(0,1,0,0), 

		     Vec4f(0,0,1,0), 

		     Vec4f(0,0,1,0), 

		     Vec4f(0,0,0,1));

		     Vec4f(0,0,0,1));

    }

    }

  /** Compute inverse assuming that the upper-left 3x3 sub-matrix is

  /** Compute inverse assuming that the upper-left 3x3 sub-matrix is

      orthonormal (which is the case if the transformation is only

      orthonormal (which is the case if the transformation is only

      a concatenation of rotations and translations).

      a concatenation of rotations and translations).

  */

  */

  inline Mat4x4f invert_ortho(const Mat4x4f& m)

  inline Mat4x4f invert_ortho(const Mat4x4f& m)

  {

  {

    Vec3f rx(m[0][0], m[1][0], m[2][0]);

    Vec3f rx(m[0][0], m[1][0], m[2][0]);

    Vec3f ry(m[0][1], m[1][1], m[2][1]);

    Vec3f ry(m[0][1], m[1][1], m[2][1]);

    Vec3f rz(m[0][2], m[1][2], m[2][2]);

    Vec3f rz(m[0][2], m[1][2], m[2][2]);

    Vec3f t(m[0][3], m[1][3], m[2][3]);

    Vec3f t(m[0][3], m[1][3], m[2][3]);

    return Mat4x4f(Vec4f(rx, -dot(t, rx)),

    return Mat4x4f(Vec4f(rx, -dot(t, rx)),

		   Vec4f(ry, -dot(t, ry)),

		   Vec4f(ry, -dot(t, ry)),

		   Vec4f(rz, -dot(t, rz)),

		   Vec4f(rz, -dot(t, rz)),

		   Vec4f(0.0, 0.0, 0.0, 1.0));

		   Vec4f(0.0, 0.0, 0.0, 1.0));

  }   

  }   

}

}

#endif

#endif