source/dng_matrix.cpp - platform/external/dng_sdk - Git at Google

 /*****************************************************************************/
 // Copyright 2006-2008 Adobe Systems Incorporated
 // All Rights Reserved.
 //
 // NOTICE:  Adobe permits you to use, modify, and distribute this file in
 // accordance with the terms of the Adobe license agreement accompanying it.
 /*****************************************************************************/

 /* $Id: //mondo/dng_sdk_1_4/dng_sdk/source/dng_matrix.cpp#1 $ */
 /* $DateTime: 2012/05/30 13:28:51 $ */
 /* $Change: 832332 $ */
 /* $Author: tknoll $ */

 /*****************************************************************************/

 #include "dng_matrix.h"

 #include "dng_exceptions.h"
 #include "dng_utils.h"

 /*****************************************************************************/

 dng_matrix::dng_matrix ()

 	:	fRows (0)
 	,	fCols (0)

 	{

 	}

 /*****************************************************************************/

 dng_matrix::dng_matrix (uint32 rows,
 						uint32 cols)

 	:	fRows (0)
 	,	fCols (0)

 	{

 	if (rows < 1 || rows > kMaxColorPlanes ||
 		cols < 1 || cols > kMaxColorPlanes)
 		{

 		ThrowProgramError ();

 		}

 	fRows = rows;
 	fCols = cols;

 	for (uint32 row = 0; row < fRows; row++)
 		for (uint32 col = 0; col < fCols; col++)
 			{

 			fData [row] [col] = 0.0;

 			}

 	}

 /*****************************************************************************/

 dng_matrix::dng_matrix (const dng_matrix &m)

 	:	fRows (m.fRows)
 	,	fCols (m.fCols)

 	{

 	for (uint32 row = 0; row < fRows; row++)
 		for (uint32 col = 0; col < fCols; col++)
 			{

 			fData [row] [col] = m.fData [row] [col];

 			}

 	}

 /*****************************************************************************/

 void dng_matrix::Clear ()
 	{

 	fRows = 0;
 	fCols = 0;

 	}

 /*****************************************************************************/

 void dng_matrix::SetIdentity (uint32 count)
 	{

 	*this = dng_matrix (count, count);

 	for (uint32 j = 0; j < count; j++)
 		{

 		fData [j] [j] = 1.0;

 		}

 	}

 /******************************************************************************/

 bool dng_matrix::operator== (const dng_matrix &m) const
 	{

 	if (Rows () != m.Rows () ||
 	    Cols () != m.Cols ())
 		{

 		return false;

 		}

 	for (uint32 j = 0; j < Rows (); j++)
 		for (uint32 k = 0; k < Cols (); k++)
 			{

 			if (fData [j] [k] != m.fData [j] [k])
 				{

 				return false;

 				}

 			}

 	return true;

 	}

 /******************************************************************************/

 bool dng_matrix::IsDiagonal () const
 	{

 	if (IsEmpty ())
 		{
 		return false;
 		}

 	if (Rows () != Cols ())
 		{
 		return false;
 		}

 	for (uint32 j = 0; j < Rows (); j++)
 		for (uint32 k = 0; k < Cols (); k++)
 			{

 			if (j != k)
 				{

 				if (fData [j] [k] != 0.0)
 					{
 					return false;
 					}

 				}

 			}

 	return true;

 	}

 /******************************************************************************/

 real64 dng_matrix::MaxEntry () const
 	{

 	if (IsEmpty ())
 		{

 		return 0.0;

 		}

 	real64 m = fData [0] [0];

 	for (uint32 j = 0; j < Rows (); j++)
 		for (uint32 k = 0; k < Cols (); k++)
 			{

 			m = Max_real64 (m, fData [j] [k]);

 			}

 	return m;

 	}

 /******************************************************************************/

 real64 dng_matrix::MinEntry () const
 	{

 	if (IsEmpty ())
 		{

 		return 0.0;

 		}

 	real64 m = fData [0] [0];

 	for (uint32 j = 0; j < Rows (); j++)
 		for (uint32 k = 0; k < Cols (); k++)
 			{

 			m = Min_real64 (m, fData [j] [k]);

 			}

 	return m;

 	}

 /*****************************************************************************/

 void dng_matrix::Scale (real64 factor)
 	{

 	for (uint32 j = 0; j < Rows (); j++)
 		for (uint32 k = 0; k < Cols (); k++)
 			{

 			fData [j] [k] *= factor;

 			}

 	}

 /*****************************************************************************/

 void dng_matrix::Round (real64 factor)
 	{

 	real64 invFactor = 1.0 / factor;

 	for (uint32 j = 0; j < Rows (); j++)
 		for (uint32 k = 0; k < Cols (); k++)
 			{

 			fData [j] [k] = Round_int32 (fData [j] [k] * factor) * invFactor;

 			}

 	}

 /*****************************************************************************/

 void dng_matrix::SafeRound (real64 factor)
 	{

 	real64 invFactor = 1.0 / factor;

 	for (uint32 j = 0; j < Rows (); j++)
 		{

 		// Round each row to the specified accuracy, but make sure the
 		// a rounding does not affect the total of the elements in a row
 		// more than necessary.

 		real64 error = 0.0;

 		for (uint32 k = 0; k < Cols (); k++)
 			{

 			fData [j] [k] += error;

 			real64 rounded = Round_int32 (fData [j] [k] * factor) * invFactor;

 			error = fData [j] [k] - rounded;

 			fData [j] [k] = rounded;

 			}

 		}

 	}

 /*****************************************************************************/

 dng_matrix_3by3::dng_matrix_3by3 ()

 	:	dng_matrix (3, 3)

 	{
 	}

 /*****************************************************************************/

 dng_matrix_3by3::dng_matrix_3by3 (const dng_matrix &m)

 	:	dng_matrix (m)

 	{

 	if (Rows () != 3 ||
 		Cols () != 3)
 		{

 		ThrowMatrixMath ();

 		}

 	}

 /*****************************************************************************/

 dng_matrix_3by3::dng_matrix_3by3 (real64 a00, real64 a01, real64 a02,
 				        		  real64 a10, real64 a11, real64 a12,
 				        		  real64 a20, real64 a21, real64 a22)


 	:	dng_matrix (3, 3)

 	{

 	fData [0] [0] = a00;
 	fData [0] [1] = a01;
 	fData [0] [2] = a02;

 	fData [1] [0] = a10;
 	fData [1] [1] = a11;
 	fData [1] [2] = a12;

 	fData [2] [0] = a20;
 	fData [2] [1] = a21;
 	fData [2] [2] = a22;

 	}

 /*****************************************************************************/

 dng_matrix_3by3::dng_matrix_3by3 (real64 a00, real64 a11, real64 a22)

 	:	dng_matrix (3, 3)

 	{

 	fData [0] [0] = a00;
 	fData [1] [1] = a11;
 	fData [2] [2] = a22;

 	}

 /*****************************************************************************/

 dng_matrix_4by3::dng_matrix_4by3 ()

 	:	dng_matrix (4, 3)

 	{
 	}

 /*****************************************************************************/

 dng_matrix_4by3::dng_matrix_4by3 (const dng_matrix &m)

 	:	dng_matrix (m)

 	{

 	if (Rows () != 4 ||
 		Cols () != 3)
 		{

 		ThrowMatrixMath ();

 		}

 	}

 /*****************************************************************************/

 dng_matrix_4by3::dng_matrix_4by3 (real64 a00, real64 a01, real64 a02,
 				       			  real64 a10, real64 a11, real64 a12,
 				        		  real64 a20, real64 a21, real64 a22,
 				        		  real64 a30, real64 a31, real64 a32)


 	:	dng_matrix (4, 3)

 	{

 	fData [0] [0] = a00;
 	fData [0] [1] = a01;
 	fData [0] [2] = a02;

 	fData [1] [0] = a10;
 	fData [1] [1] = a11;
 	fData [1] [2] = a12;

 	fData [2] [0] = a20;
 	fData [2] [1] = a21;
 	fData [2] [2] = a22;

 	fData [3] [0] = a30;
 	fData [3] [1] = a31;
 	fData [3] [2] = a32;

 	}

 /*****************************************************************************/

 dng_vector::dng_vector ()

 	:	fCount (0)

 	{

 	}

 /*****************************************************************************/

 dng_vector::dng_vector (uint32 count)

 	:	fCount (0)

 	{

 	if (count < 1 || count > kMaxColorPlanes)
 		{

 		ThrowProgramError ();

 		}

 	fCount = count;

 	for (uint32 index = 0; index < fCount; index++)
 		{

 		fData [index] = 0.0;

 		}

 	}

 /*****************************************************************************/

 dng_vector::dng_vector (const dng_vector &v)

 	:	fCount (v.fCount)

 	{

 	for (uint32 index = 0; index < fCount; index++)
 		{

 		fData [index] = v.fData [index];

 		}

 	}

 /*****************************************************************************/

 void dng_vector::Clear ()
 	{

 	fCount = 0;

 	}

 /*****************************************************************************/

 void dng_vector::SetIdentity (uint32 count)
 	{

 	*this = dng_vector (count);

 	for (uint32 j = 0; j < count; j++)
 		{

 		fData [j] = 1.0;

 		}

 	}

 /******************************************************************************/

 bool dng_vector::operator== (const dng_vector &v) const
 	{

 	if (Count () != v.Count ())
 		{

 		return false;

 		}

 	for (uint32 j = 0; j < Count (); j++)
 		{

 		if (fData [j] != v.fData [j])
 			{

 			return false;

 			}

 		}

 	return true;

 	}

 /******************************************************************************/

 real64 dng_vector::MaxEntry () const
 	{

 	if (IsEmpty ())
 		{

 		return 0.0;

 		}

 	real64 m = fData [0];

 	for (uint32 j = 0; j < Count (); j++)
 		{

 		m = Max_real64 (m, fData [j]);

 		}

 	return m;

 	}

 /******************************************************************************/

 real64 dng_vector::MinEntry () const
 	{

 	if (IsEmpty ())
 		{

 		return 0.0;

 		}

 	real64 m = fData [0];

 	for (uint32 j = 0; j < Count (); j++)
 		{

 		m = Min_real64 (m, fData [j]);

 		}

 	return m;

 	}

 /*****************************************************************************/

 void dng_vector::Scale (real64 factor)
 	{

 	for (uint32 j = 0; j < Count (); j++)
 		{

 		fData [j] *= factor;

 		}

 	}

 /*****************************************************************************/

 void dng_vector::Round (real64 factor)
 	{

 	real64 invFactor = 1.0 / factor;

 	for (uint32 j = 0; j < Count (); j++)
 		{

 		fData [j] = Round_int32 (fData [j] * factor) * invFactor;

 		}

 	}

 /*****************************************************************************/

 dng_matrix dng_vector::AsDiagonal () const
 	{

 	dng_matrix M (Count (), Count ());

 	for (uint32 j = 0; j < Count (); j++)
 		{

 		M [j] [j] = fData [j];

 		}

 	return M;

 	}

 /*****************************************************************************/

 dng_matrix dng_vector::AsColumn () const
 	{

 	dng_matrix M (Count (), 1);

 	for (uint32 j = 0; j < Count (); j++)
 		{

 		M [j] [0] = fData [j];

 		}

 	return M;

 	}

 /******************************************************************************/

 dng_vector_3::dng_vector_3 ()

 	:	dng_vector (3)

 	{
 	}

 /******************************************************************************/

 dng_vector_3::dng_vector_3 (const dng_vector &v)

 	:	dng_vector (v)

 	{

 	if (Count () != 3)
 		{

 		ThrowMatrixMath ();

 		}

 	}

 /******************************************************************************/

 dng_vector_3::dng_vector_3 (real64 a0,
 							real64 a1,
 						    real64 a2)

 	:	dng_vector (3)

 	{

 	fData [0] = a0;
 	fData [1] = a1;
 	fData [2] = a2;

 	}

 /******************************************************************************/

 dng_vector_4::dng_vector_4 ()

 	:	dng_vector (4)

 	{
 	}

 /******************************************************************************/

 dng_vector_4::dng_vector_4 (const dng_vector &v)

 	:	dng_vector (v)

 	{

 	if (Count () != 4)
 		{

 		ThrowMatrixMath ();

 		}

 	}

 /******************************************************************************/

 dng_vector_4::dng_vector_4 (real64 a0,
 							real64 a1,
 						    real64 a2,
 						    real64 a3)

 	:	dng_vector (4)

 	{

 	fData [0] = a0;
 	fData [1] = a1;
 	fData [2] = a2;
 	fData [3] = a3;

 	}

 /******************************************************************************/

 dng_matrix operator* (const dng_matrix &A,
 					  const dng_matrix &B)
 	{

 	if (A.Cols () != B.Rows ())
 		{

 		ThrowMatrixMath ();

 		}

 	dng_matrix C (A.Rows (), B.Cols ());

 	for (uint32 j = 0; j < C.Rows (); j++)
 		for (uint32 k = 0; k < C.Cols (); k++)
 			{

 			C [j] [k] = 0.0;

 			for (uint32 m = 0; m < A.Cols (); m++)
 				{

 				real64 aa = A [j] [m];

 				real64 bb = B [m] [k];

 				C [j] [k] += aa * bb;

 				}

 			}

 	return C;

 	}

 /******************************************************************************/

 dng_vector operator* (const dng_matrix &A,
 					  const dng_vector &B)
 	{

 	if (A.Cols () != B.Count ())
 		{

 		ThrowMatrixMath ();

 		}

 	dng_vector C (A.Rows ());

 	for (uint32 j = 0; j < C.Count (); j++)
 		{

 		C [j] = 0.0;

 		for (uint32 m = 0; m < A.Cols (); m++)
 			{

 			real64 aa = A [j] [m];

 			real64 bb = B [m];

 			C [j] += aa * bb;

 			}

 		}

 	return C;

 	}

 /******************************************************************************/

 dng_matrix operator* (real64 scale,
 					  const dng_matrix &A)
 	{

 	dng_matrix B (A);

 	B.Scale (scale);

 	return B;

 	}

 /******************************************************************************/

 dng_vector operator* (real64 scale,
 					  const dng_vector &A)
 	{

 	dng_vector B (A);

 	B.Scale (scale);

 	return B;

 	}

 /******************************************************************************/

 dng_matrix operator+ (const dng_matrix &A,
 					  const dng_matrix &B)
 	{

 	if (A.Cols () != B.Cols () ||
 		A.Rows () != B.Rows ())
 		{

 		ThrowMatrixMath ();

 		}

 	dng_matrix C (A);

 	for (uint32 j = 0; j < C.Rows (); j++)
 		for (uint32 k = 0; k < C.Cols (); k++)
 			{

 			C [j] [k] += B [j] [k];

 			}

 	return C;

 	}

 /******************************************************************************/

 const real64 kNearZero = 1.0E-10;

 /******************************************************************************/

 // Work around bug #1294195, which may be a hardware problem on a specific machine.
 // This pragma turns on "improved" floating-point consistency.
 #ifdef _MSC_VER
 #pragma optimize ("p", on)
 #endif

 static dng_matrix Invert3by3 (const dng_matrix &A)
 	{

 	real64 a00 = A [0] [0];
 	real64 a01 = A [0] [1];
 	real64 a02 = A [0] [2];
 	real64 a10 = A [1] [0];
 	real64 a11 = A [1] [1];
 	real64 a12 = A [1] [2];
 	real64 a20 = A [2] [0];
 	real64 a21 = A [2] [1];
 	real64 a22 = A [2] [2];

 	real64 temp [3] [3];

 	temp [0] [0] = a11 * a22 - a21 * a12;
 	temp [0] [1] = a21 * a02 - a01 * a22;
 	temp [0] [2] = a01 * a12 - a11 * a02;
 	temp [1] [0] = a20 * a12 - a10 * a22;
 	temp [1] [1] = a00 * a22 - a20 * a02;
 	temp [1] [2] = a10 * a02 - a00 * a12;
 	temp [2] [0] = a10 * a21 - a20 * a11;
 	temp [2] [1] = a20 * a01 - a00 * a21;
 	temp [2] [2] = a00 * a11 - a10 * a01;

 	real64 det = (a00 * temp [0] [0] +
 				  a01 * temp [1] [0] +
 				  a02 * temp [2] [0]);

 	if (Abs_real64 (det) < kNearZero)
 		{

 		ThrowMatrixMath ();

 		}

 	dng_matrix B (3, 3);

 	for (uint32 j = 0; j < 3; j++)
 		for (uint32 k = 0; k < 3; k++)
 			{

 			B [j] [k] = temp [j] [k] / det;

 			}

 	return B;

 	}

 // Reset floating-point optimization. See comment above.
 #ifdef _MSC_VER
 #pragma optimize ("p", off)
 #endif

 /******************************************************************************/

 static dng_matrix InvertNbyN (const dng_matrix &A)
 	{

 	uint32 i;
 	uint32 j;
 	uint32 k;

 	uint32 n = A.Rows ();

 	real64 temp [kMaxColorPlanes] [kMaxColorPlanes * 2];

 	for (i = 0; i < n; i++)
 		for (j = 0; j < n; j++)
 			{

 			temp [i] [j    ] = A [i] [j];

 			temp [i] [j + n] = (i == j ? 1.0 : 0.0);

 			}

 	for (i = 0; i < n; i++)
 		{

 		real64 alpha = temp [i] [i];

 		if (Abs_real64 (alpha) < kNearZero)
 			{

 			ThrowMatrixMath ();

 			}

 		for (j = 0; j < n * 2; j++)
 			{

 			temp [i] [j] /= alpha;

 			}

 		for (k = 0; k < n; k++)
 			{

 			if (i != k)
 				{

 				real64 beta = temp [k] [i];

 				for (j = 0; j < n * 2; j++)
 					{

 					temp [k] [j] -= beta * temp [i] [j];

 					}

 				}

 			}

 		}

 	dng_matrix B (n, n);

 	for (i = 0; i < n; i++)
 		for (j = 0; j < n; j++)
 			{

 			B [i] [j] = temp [i] [j + n];

 			}

 	return B;

 	}

 /******************************************************************************/

 dng_matrix Transpose (const dng_matrix &A)
 	{

 	dng_matrix B (A.Cols (), A.Rows ());

 	for (uint32 j = 0; j < B.Rows (); j++)
 		for (uint32 k = 0; k < B.Cols (); k++)
 			{

 			B [j] [k] = A [k] [j];

 			}

 	return B;

 	}

 /******************************************************************************/

 dng_matrix Invert (const dng_matrix &A)
 	{

 	if (A.Rows () < 2 || A.Cols () < 2)
 		{

 		ThrowMatrixMath ();

 		}

 	if (A.Rows () == A.Cols ())
 		{

 		if (A.Rows () == 3)
 			{

 			return Invert3by3 (A);

 			}

 		return InvertNbyN (A);

 		}

 	else
 		{

 		// Compute the pseudo inverse.

 		dng_matrix B = Transpose (A);

 		return Invert (B * A) * B;

 		}

 	}

 /******************************************************************************/

 dng_matrix Invert (const dng_matrix &A,
 				   const dng_matrix &hint)
 	{

 	if (A.Rows () == A   .Cols () ||
 		A.Rows () != hint.Cols () ||
 		A.Cols () != hint.Rows ())
 		{

 		return Invert (A);

 		}

 	else
 		{

 		// Use the specified hint matrix.

 		return Invert (hint * A) * hint;

 		}

 	}

 /*****************************************************************************/
	/*****************************************************************************/
	// Copyright 2006-2008 Adobe Systems Incorporated
	// All Rights Reserved.
	//
	// NOTICE: Adobe permits you to use, modify, and distribute this file in
	// accordance with the terms of the Adobe license agreement accompanying it.
	/*****************************************************************************/

	/* $Id: //mondo/dng_sdk_1_4/dng_sdk/source/dng_matrix.cpp#1 $ */
	/* $DateTime: 2012/05/30 13:28:51 $ */
	/* $Change: 832332 $ */
	/* $Author: tknoll $ */

	/*****************************************************************************/

	#include "dng_matrix.h"

	#include "dng_exceptions.h"
	#include "dng_utils.h"

	/*****************************************************************************/

	dng_matrix::dng_matrix ()

	: fRows (0)
	, fCols (0)

	{

	}

	/*****************************************************************************/

	dng_matrix::dng_matrix (uint32 rows,
	uint32 cols)

	: fRows (0)
	, fCols (0)

	{

	if (rows < 1 \|\| rows > kMaxColorPlanes \|\|
	cols < 1 \|\| cols > kMaxColorPlanes)
	{

	ThrowProgramError ();

	}

	fRows = rows;
	fCols = cols;

	for (uint32 row = 0; row < fRows; row++)
	for (uint32 col = 0; col < fCols; col++)
	{

	fData [row] [col] = 0.0;

	}

	}

	/*****************************************************************************/

	dng_matrix::dng_matrix (const dng_matrix &m)

	: fRows (m.fRows)
	, fCols (m.fCols)

	{

	for (uint32 row = 0; row < fRows; row++)
	for (uint32 col = 0; col < fCols; col++)
	{

	fData [row] [col] = m.fData [row] [col];

	}

	}

	/*****************************************************************************/

	void dng_matrix::Clear ()
	{

	fRows = 0;
	fCols = 0;

	}

	/*****************************************************************************/

	void dng_matrix::SetIdentity (uint32 count)
	{

	*this = dng_matrix (count, count);

	for (uint32 j = 0; j < count; j++)
	{

	fData [j] [j] = 1.0;

	}

	}

	/******************************************************************************/

	bool dng_matrix::operator== (const dng_matrix &m) const
	{

	if (Rows () != m.Rows () \|\|
	Cols () != m.Cols ())
	{

	return false;

	}

	for (uint32 j = 0; j < Rows (); j++)
	for (uint32 k = 0; k < Cols (); k++)
	{

	if (fData [j] [k] != m.fData [j] [k])
	{

	return false;

	}

	}

	return true;

	}

	/******************************************************************************/

	bool dng_matrix::IsDiagonal () const
	{

	if (IsEmpty ())
	{
	return false;
	}

	if (Rows () != Cols ())
	{
	return false;
	}

	for (uint32 j = 0; j < Rows (); j++)
	for (uint32 k = 0; k < Cols (); k++)
	{

	if (j != k)
	{

	if (fData [j] [k] != 0.0)
	{
	return false;
	}

	}

	}

	return true;

	}

	/******************************************************************************/

	real64 dng_matrix::MaxEntry () const
	{

	if (IsEmpty ())
	{

	return 0.0;

	}

	real64 m = fData [0] [0];

	for (uint32 j = 0; j < Rows (); j++)
	for (uint32 k = 0; k < Cols (); k++)
	{

	m = Max_real64 (m, fData [j] [k]);

	}

	return m;

	}

	/******************************************************************************/

	real64 dng_matrix::MinEntry () const
	{

	if (IsEmpty ())
	{

	return 0.0;

	}

	real64 m = fData [0] [0];

	for (uint32 j = 0; j < Rows (); j++)
	for (uint32 k = 0; k < Cols (); k++)
	{

	m = Min_real64 (m, fData [j] [k]);

	}

	return m;

	}

	/*****************************************************************************/

	void dng_matrix::Scale (real64 factor)
	{

	for (uint32 j = 0; j < Rows (); j++)
	for (uint32 k = 0; k < Cols (); k++)
	{

	fData [j] [k] *= factor;

	}

	}

	/*****************************************************************************/

	void dng_matrix::Round (real64 factor)
	{

	real64 invFactor = 1.0 / factor;

	for (uint32 j = 0; j < Rows (); j++)
	for (uint32 k = 0; k < Cols (); k++)
	{

	fData [j] [k] = Round_int32 (fData [j] [k] * factor) * invFactor;

	}

	}

	/*****************************************************************************/

	void dng_matrix::SafeRound (real64 factor)
	{

	real64 invFactor = 1.0 / factor;

	for (uint32 j = 0; j < Rows (); j++)
	{

	// Round each row to the specified accuracy, but make sure the
	// a rounding does not affect the total of the elements in a row
	// more than necessary.

	real64 error = 0.0;

	for (uint32 k = 0; k < Cols (); k++)
	{

	fData [j] [k] += error;

	real64 rounded = Round_int32 (fData [j] [k] * factor) * invFactor;

	error = fData [j] [k] - rounded;

	fData [j] [k] = rounded;

	}

	}

	}

	/*****************************************************************************/

	dng_matrix_3by3::dng_matrix_3by3 ()

	: dng_matrix (3, 3)

	{
	}

	/*****************************************************************************/

	dng_matrix_3by3::dng_matrix_3by3 (const dng_matrix &m)

	: dng_matrix (m)

	{

	if (Rows () != 3 \|\|
	Cols () != 3)
	{

	ThrowMatrixMath ();

	}

	}

	/*****************************************************************************/

	dng_matrix_3by3::dng_matrix_3by3 (real64 a00, real64 a01, real64 a02,
	real64 a10, real64 a11, real64 a12,
	real64 a20, real64 a21, real64 a22)


	: dng_matrix (3, 3)

	{

	fData [0] [0] = a00;
	fData [0] [1] = a01;
	fData [0] [2] = a02;

	fData [1] [0] = a10;
	fData [1] [1] = a11;
	fData [1] [2] = a12;

	fData [2] [0] = a20;
	fData [2] [1] = a21;
	fData [2] [2] = a22;

	}

	/*****************************************************************************/

	dng_matrix_3by3::dng_matrix_3by3 (real64 a00, real64 a11, real64 a22)

	: dng_matrix (3, 3)

	{

	fData [0] [0] = a00;
	fData [1] [1] = a11;
	fData [2] [2] = a22;

	}

	/*****************************************************************************/

	dng_matrix_4by3::dng_matrix_4by3 ()

	: dng_matrix (4, 3)

	{
	}

	/*****************************************************************************/

	dng_matrix_4by3::dng_matrix_4by3 (const dng_matrix &m)

	: dng_matrix (m)

	{

	if (Rows () != 4 \|\|
	Cols () != 3)
	{

	ThrowMatrixMath ();

	}

	}

	/*****************************************************************************/

	dng_matrix_4by3::dng_matrix_4by3 (real64 a00, real64 a01, real64 a02,
	real64 a10, real64 a11, real64 a12,
	real64 a20, real64 a21, real64 a22,
	real64 a30, real64 a31, real64 a32)


	: dng_matrix (4, 3)

	{

	fData [0] [0] = a00;
	fData [0] [1] = a01;
	fData [0] [2] = a02;

	fData [1] [0] = a10;
	fData [1] [1] = a11;
	fData [1] [2] = a12;

	fData [2] [0] = a20;
	fData [2] [1] = a21;
	fData [2] [2] = a22;

	fData [3] [0] = a30;
	fData [3] [1] = a31;
	fData [3] [2] = a32;

	}

	/*****************************************************************************/

	dng_vector::dng_vector ()

	: fCount (0)

	{

	}

	/*****************************************************************************/

	dng_vector::dng_vector (uint32 count)

	: fCount (0)

	{

	if (count < 1 \|\| count > kMaxColorPlanes)
	{

	ThrowProgramError ();

	}

	fCount = count;

	for (uint32 index = 0; index < fCount; index++)
	{

	fData [index] = 0.0;

	}

	}

	/*****************************************************************************/

	dng_vector::dng_vector (const dng_vector &v)

	: fCount (v.fCount)

	{

	for (uint32 index = 0; index < fCount; index++)
	{

	fData [index] = v.fData [index];

	}

	}

	/*****************************************************************************/

	void dng_vector::Clear ()
	{

	fCount = 0;

	}

	/*****************************************************************************/

	void dng_vector::SetIdentity (uint32 count)
	{

	*this = dng_vector (count);

	for (uint32 j = 0; j < count; j++)
	{

	fData [j] = 1.0;

	}

	}

	/******************************************************************************/

	bool dng_vector::operator== (const dng_vector &v) const
	{

	if (Count () != v.Count ())
	{

	return false;

	}

	for (uint32 j = 0; j < Count (); j++)
	{

	if (fData [j] != v.fData [j])
	{

	return false;

	}

	}

	return true;

	}

	/******************************************************************************/

	real64 dng_vector::MaxEntry () const
	{

	if (IsEmpty ())
	{

	return 0.0;

	}

	real64 m = fData [0];

	for (uint32 j = 0; j < Count (); j++)
	{

	m = Max_real64 (m, fData [j]);

	}

	return m;

	}

	/******************************************************************************/

	real64 dng_vector::MinEntry () const
	{

	if (IsEmpty ())
	{

	return 0.0;

	}

	real64 m = fData [0];

	for (uint32 j = 0; j < Count (); j++)
	{

	m = Min_real64 (m, fData [j]);

	}

	return m;

	}

	/*****************************************************************************/

	void dng_vector::Scale (real64 factor)
	{

	for (uint32 j = 0; j < Count (); j++)
	{

	fData [j] *= factor;

	}

	}

	/*****************************************************************************/

	void dng_vector::Round (real64 factor)
	{

	real64 invFactor = 1.0 / factor;

	for (uint32 j = 0; j < Count (); j++)
	{

	fData [j] = Round_int32 (fData [j] * factor) * invFactor;

	}

	}

	/*****************************************************************************/

	dng_matrix dng_vector::AsDiagonal () const
	{

	dng_matrix M (Count (), Count ());

	for (uint32 j = 0; j < Count (); j++)
	{

	M [j] [j] = fData [j];

	}

	return M;

	}

	/*****************************************************************************/

	dng_matrix dng_vector::AsColumn () const
	{

	dng_matrix M (Count (), 1);

	for (uint32 j = 0; j < Count (); j++)
	{

	M [j] [0] = fData [j];

	}

	return M;

	}

	/******************************************************************************/

	dng_vector_3::dng_vector_3 ()

	: dng_vector (3)

	{
	}

	/******************************************************************************/

	dng_vector_3::dng_vector_3 (const dng_vector &v)

	: dng_vector (v)

	{

	if (Count () != 3)
	{

	ThrowMatrixMath ();

	}

	}

	/******************************************************************************/

	dng_vector_3::dng_vector_3 (real64 a0,
	real64 a1,
	real64 a2)

	: dng_vector (3)

	{

	fData [0] = a0;
	fData [1] = a1;
	fData [2] = a2;

	}

	/******************************************************************************/

	dng_vector_4::dng_vector_4 ()

	: dng_vector (4)

	{
	}

	/******************************************************************************/

	dng_vector_4::dng_vector_4 (const dng_vector &v)

	: dng_vector (v)

	{

	if (Count () != 4)
	{

	ThrowMatrixMath ();

	}

	}

	/******************************************************************************/

	dng_vector_4::dng_vector_4 (real64 a0,
	real64 a1,
	real64 a2,
	real64 a3)

	: dng_vector (4)

	{

	fData [0] = a0;
	fData [1] = a1;
	fData [2] = a2;
	fData [3] = a3;

	}

	/******************************************************************************/

	dng_matrix operator* (const dng_matrix &A,
	const dng_matrix &B)
	{

	if (A.Cols () != B.Rows ())
	{

	ThrowMatrixMath ();

	}

	dng_matrix C (A.Rows (), B.Cols ());

	for (uint32 j = 0; j < C.Rows (); j++)
	for (uint32 k = 0; k < C.Cols (); k++)
	{

	C [j] [k] = 0.0;

	for (uint32 m = 0; m < A.Cols (); m++)
	{

	real64 aa = A [j] [m];

	real64 bb = B [m] [k];

	C [j] [k] += aa * bb;

	}

	}

	return C;

	}

	/******************************************************************************/

	dng_vector operator* (const dng_matrix &A,
	const dng_vector &B)
	{

	if (A.Cols () != B.Count ())
	{

	ThrowMatrixMath ();

	}

	dng_vector C (A.Rows ());

	for (uint32 j = 0; j < C.Count (); j++)
	{

	C [j] = 0.0;

	for (uint32 m = 0; m < A.Cols (); m++)
	{

	real64 aa = A [j] [m];

	real64 bb = B [m];

	C [j] += aa * bb;

	}

	}

	return C;

	}

	/******************************************************************************/

	dng_matrix operator* (real64 scale,
	const dng_matrix &A)
	{

	dng_matrix B (A);

	B.Scale (scale);

	return B;

	}

	/******************************************************************************/

	dng_vector operator* (real64 scale,
	const dng_vector &A)
	{

	dng_vector B (A);

	B.Scale (scale);

	return B;

	}

	/******************************************************************************/

	dng_matrix operator+ (const dng_matrix &A,
	const dng_matrix &B)
	{

	if (A.Cols () != B.Cols () \|\|
	A.Rows () != B.Rows ())
	{

	ThrowMatrixMath ();

	}

	dng_matrix C (A);

	for (uint32 j = 0; j < C.Rows (); j++)
	for (uint32 k = 0; k < C.Cols (); k++)
	{

	C [j] [k] += B [j] [k];

	}

	return C;

	}

	/******************************************************************************/

	const real64 kNearZero = 1.0E-10;

	/******************************************************************************/

	// Work around bug #1294195, which may be a hardware problem on a specific machine.
	// This pragma turns on "improved" floating-point consistency.
	#ifdef _MSC_VER
	#pragma optimize ("p", on)
	#endif

	static dng_matrix Invert3by3 (const dng_matrix &A)
	{

	real64 a00 = A [0] [0];
	real64 a01 = A [0] [1];
	real64 a02 = A [0] [2];
	real64 a10 = A [1] [0];
	real64 a11 = A [1] [1];
	real64 a12 = A [1] [2];
	real64 a20 = A [2] [0];
	real64 a21 = A [2] [1];
	real64 a22 = A [2] [2];

	real64 temp [3] [3];

	temp [0] [0] = a11 * a22 - a21 * a12;
	temp [0] [1] = a21 * a02 - a01 * a22;
	temp [0] [2] = a01 * a12 - a11 * a02;
	temp [1] [0] = a20 * a12 - a10 * a22;
	temp [1] [1] = a00 * a22 - a20 * a02;
	temp [1] [2] = a10 * a02 - a00 * a12;
	temp [2] [0] = a10 * a21 - a20 * a11;
	temp [2] [1] = a20 * a01 - a00 * a21;
	temp [2] [2] = a00 * a11 - a10 * a01;

	real64 det = (a00 * temp [0] [0] +
	a01 * temp [1] [0] +
	a02 * temp [2] [0]);

	if (Abs_real64 (det) < kNearZero)
	{

	ThrowMatrixMath ();

	}

	dng_matrix B (3, 3);

	for (uint32 j = 0; j < 3; j++)
	for (uint32 k = 0; k < 3; k++)
	{

	B [j] [k] = temp [j] [k] / det;

	}

	return B;

	}

	// Reset floating-point optimization. See comment above.
	#ifdef _MSC_VER
	#pragma optimize ("p", off)
	#endif

	/******************************************************************************/

	static dng_matrix InvertNbyN (const dng_matrix &A)
	{

	uint32 i;
	uint32 j;
	uint32 k;

	uint32 n = A.Rows ();

	real64 temp [kMaxColorPlanes] [kMaxColorPlanes * 2];

	for (i = 0; i < n; i++)
	for (j = 0; j < n; j++)
	{

	temp [i] [j ] = A [i] [j];

	temp [i] [j + n] = (i == j ? 1.0 : 0.0);

	}

	for (i = 0; i < n; i++)
	{

	real64 alpha = temp [i] [i];

	if (Abs_real64 (alpha) < kNearZero)
	{

	ThrowMatrixMath ();

	}

	for (j = 0; j < n * 2; j++)
	{

	temp [i] [j] /= alpha;

	}

	for (k = 0; k < n; k++)
	{

	if (i != k)
	{

	real64 beta = temp [k] [i];

	for (j = 0; j < n * 2; j++)
	{

	temp [k] [j] -= beta * temp [i] [j];

	}

	}

	}

	}

	dng_matrix B (n, n);

	for (i = 0; i < n; i++)
	for (j = 0; j < n; j++)
	{

	B [i] [j] = temp [i] [j + n];

	}

	return B;

	}

	/******************************************************************************/

	dng_matrix Transpose (const dng_matrix &A)
	{

	dng_matrix B (A.Cols (), A.Rows ());

	for (uint32 j = 0; j < B.Rows (); j++)
	for (uint32 k = 0; k < B.Cols (); k++)
	{

	B [j] [k] = A [k] [j];

	}

	return B;

	}

	/******************************************************************************/

	dng_matrix Invert (const dng_matrix &A)
	{

	if (A.Rows () < 2 \|\| A.Cols () < 2)
	{

	ThrowMatrixMath ();

	}

	if (A.Rows () == A.Cols ())
	{

	if (A.Rows () == 3)
	{

	return Invert3by3 (A);

	}

	return InvertNbyN (A);

	}

	else
	{

	// Compute the pseudo inverse.

	dng_matrix B = Transpose (A);

	return Invert (B * A) * B;

	}

	}

	/******************************************************************************/

	dng_matrix Invert (const dng_matrix &A,
	const dng_matrix &hint)
	{

	if (A.Rows () == A .Cols () \|\|
	A.Rows () != hint.Cols () \|\|
	A.Cols () != hint.Rows ())
	{

	return Invert (A);

	}

	else
	{

	// Use the specified hint matrix.

	return Invert (hint * A) * hint;

	}

	}

	/*****************************************************************************/