File: dcb_demosaicing.c

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/*
 *    Copyright (C) 2010,  Jacek Gozdz (cuniek@kft.umcs.lublin.pl)
 * 
 *    This code is licensed under a (3-clause) BSD license as follows :
 *
 *    Redistribution and use in source and binary forms, with or without
 *    modification, are permitted provided that the following 
 *	  conditions are met:
 *     
 *    * Redistributions of source code must retain the above copyright
 *      notice, this list of conditions and the following disclaimer.
 *    * Redistributions in binary form must reproduce the above
 *      copyright notice, this list of conditions and the following 
 *		disclaimer in the documentation and/or other materials provided 
 * 	    with the distribution.
 *    * Neither the name of the author nor the names of its
 *      contributors may be used to endorse or promote products 
 * 		derived from this software without specific prior written permission.
 *     
 *    THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 *    "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 *    LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND 
 * 	  FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL 
 * 	  THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, 
 * 	  INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES 
 * 	  (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR 
 * 	  SERVICES; LOSS OF USE,
 *    DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND 
 * 	  ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, 
 *	  OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT 
 * 	  OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY 
 *    OF SUCH DAMAGE.
 */

// DCB demosaicing by Jacek Gozdz (cuniek@kft.umcs.lublin.pl)

// FBDD denoising by Jacek Gozdz (cuniek@kft.umcs.lublin.pl) and 
// Luis Sanz Rodríguez (luis.sanz.rodriguez@gmail.com)
 
// last modification: 11.07.2010 
 

// interpolates green vertically and saves it to image3
void CLASS dcb_ver(float (*image3)[3])
{
	int row, col, u=width, v=2*u, indx;

	for (row=2; row < height-2; row++)
		for (col=2+(FC(row,2)&1),indx=row*width+col; col < u-2; col+=2,indx+=2) {
	
			image3[indx][1] = CLIP((image[indx+u][1] + image[indx-u][1])/2.0);

	}	
}


// interpolates green horizontally and saves it to image2
void CLASS dcb_hor(float (*image2)[3])
{
	int row, col, u=width, v=2*u, indx;
	
	for (row=2; row < height-2; row++)
		for (col=2+(FC(row,2)&1),indx=row*width+col; col < u-2; col+=2,indx+=2) {
			
			image2[indx][1] = CLIP((image[indx+1][1] + image[indx-1][1])/2.0);

	}	
}
	


// missing colors are interpolated
void CLASS dcb_color()
{
	int row, col, c, d, u=width, indx;


	for (row=1; row < height-1; row++)
		for (col=1+(FC(row,1) & 1), indx=row*width+col, c=2-FC(row,col); col < u-1; col+=2, indx+=2) {

			
			image[indx][c] = CLIP(( 
			4*image[indx][1] 
			- image[indx+u+1][1] - image[indx+u-1][1] - image[indx-u+1][1] - image[indx-u-1][1] 
			+ image[indx+u+1][c] + image[indx+u-1][c] + image[indx-u+1][c] + image[indx-u-1][c] )/4.0);
		}

	for (row=1; row<height-1; row++)
		for (col=1+(FC(row,2) & 1), indx=row*width+col,c=FC(row,col+1),d=2-c; col<width-1; col+=2, indx+=2) {
			
			image[indx][c] = CLIP((2*image[indx][1] - image[indx+1][1] - image[indx-1][1] + image[indx+1][c] + image[indx-1][c])/2.0);
			image[indx][d] = CLIP((2*image[indx][1] - image[indx+u][1] - image[indx-u][1] + image[indx+u][d] + image[indx-u][d])/2.0);
		}	
}


// missing R and B are interpolated horizontally and saved in image2
void CLASS dcb_color2(float (*image2)[3])
{
	int row, col, c, d, u=width, indx;


	for (row=1; row < height-1; row++)
		for (col=1+(FC(row,1) & 1), indx=row*width+col, c=2-FC(row,col); col < u-1; col+=2, indx+=2) {

			
			image2[indx][c] = CLIP(( 
			4*image2[indx][1] 
			- image2[indx+u+1][1] - image2[indx+u-1][1] - image2[indx-u+1][1] - image2[indx-u-1][1] 
			+ image[indx+u+1][c] + image[indx+u-1][c] + image[indx-u+1][c] + image[indx-u-1][c] )/4.0);
		}

	for (row=1; row<height-1; row++)
		for (col=1+(FC(row,2) & 1), indx=row*width+col,c=FC(row,col+1),d=2-c; col<width-1; col+=2, indx+=2) {
			
			image2[indx][c] = CLIP((image[indx+1][c] + image[indx-1][c])/2.0);
			image2[indx][d] = CLIP((2*image2[indx][1] - image2[indx+u][1] - image2[indx-u][1] + image[indx+u][d] + image[indx-u][d])/2.0);
		}	
}


// missing R and B are interpolated vertically and saved in image3
void CLASS dcb_color3(float (*image3)[3])
{
	int row, col, c, d, u=width, indx;


	for (row=1; row < height-1; row++)
		for (col=1+(FC(row,1) & 1), indx=row*width+col, c=2-FC(row,col); col < u-1; col+=2, indx+=2) {

			
			image3[indx][c] = CLIP(( 
			4*image3[indx][1] 
			- image3[indx+u+1][1] - image3[indx+u-1][1] - image3[indx-u+1][1] - image3[indx-u-1][1] 
			+ image[indx+u+1][c] + image[indx+u-1][c] + image[indx-u+1][c] + image[indx-u-1][c] )/4.0);
		}

	for (row=1; row<height-1; row++)
		for (col=1+(FC(row,2) & 1), indx=row*width+col,c=FC(row,col+1),d=2-c; col<width-1; col+=2, indx+=2) {
			
			image3[indx][c] = CLIP((2*image3[indx][1] - image3[indx+1][1] - image3[indx-1][1] + image[indx+1][c] + image[indx-1][c])/2.0);
			image3[indx][d] = CLIP((image[indx+u][d] + image[indx-u][d])/2.0);
		}	
}


// decides the primary green interpolation direction
void CLASS dcb_decide(float (*image2)[3], float (*image3)[3])
{
	int row, col, c, d, u=width, v=2*u, indx;
	float current, current2, current3;

	for (row=2; row < height-2; row++)
		for (col=2+(FC(row,2)&1),indx=row*width+col, c=FC(row,col); col < u-2; col+=2,indx+=2) {
	
		d=ABS(c-2);

   current = MAX(image[indx+v][c], MAX(image[indx-v][c], MAX(image[indx-2][c], image[indx+2][c]))) -
			 MIN(image[indx+v][c], MIN(image[indx-v][c], MIN(image[indx-2][c], image[indx+2][c]))) +
			 MAX(image[indx+1+u][d], MAX(image[indx+1-u][d], MAX(image[indx-1+u][d], image[indx-1-u][d]))) -
			 MIN(image[indx+1+u][d], MIN(image[indx+1-u][d], MIN(image[indx-1+u][d], image[indx-1-u][d])));
		
  current2 = MAX(image2[indx+v][d], MAX(image2[indx-v][d], MAX(image2[indx-2][d], image2[indx+2][d]))) -
			 MIN(image2[indx+v][d], MIN(image2[indx-v][d], MIN(image2[indx-2][d], image2[indx+2][d]))) +
			 MAX(image2[indx+1+u][c], MAX(image2[indx+1-u][c], MAX(image2[indx-1+u][c], image2[indx-1-u][c]))) -
			 MIN(image2[indx+1+u][c], MIN(image2[indx+1-u][c], MIN(image2[indx-1+u][c], image2[indx-1-u][c])));
			  
  current3 = MAX(image3[indx+v][d], MAX(image3[indx-v][d], MAX(image3[indx-2][d], image3[indx+2][d]))) -
			 MIN(image3[indx+v][d], MIN(image3[indx-v][d], MIN(image3[indx-2][d], image3[indx+2][d]))) +
			 MAX(image3[indx+1+u][c], MAX(image3[indx+1-u][c], MAX(image3[indx-1+u][c], image3[indx-1-u][c]))) -
			 MIN(image3[indx+1+u][c], MIN(image3[indx+1-u][c], MIN(image3[indx-1+u][c], image3[indx-1-u][c])));

		
			if (ABS(current-current2) < ABS(current-current3))
				image[indx][1] = image2[indx][1];
			else
				image[indx][1] = image3[indx][1];				
			
		
	}
}


// saves red and blue in image2
void CLASS dcb_copy_to_buffer(float (*image2)[3])
{
	int indx;

	for (indx=0; indx < height*width; indx++) {
		image2[indx][0]=image[indx][0]; //R
		image2[indx][2]=image[indx][2]; //B
	}
}



// restores red and blue from image2
void CLASS dcb_restore_from_buffer(float (*image2)[3])
{
	int indx;

	for (indx=0; indx < height*width; indx++) {
		image[indx][0]=image2[indx][0]; //R
		image[indx][2]=image2[indx][2]; //B
	}
}


// R and B smoothing using green contrast, all pixels except 2 pixel wide border
void CLASS dcb_pp()
{
	int g1, r1, b1, u=width, indx, row, col;

	
	for (row=2; row < height-2; row++) 
	for (col=2, indx=row*u+col; col < width-2; col++, indx++) { 

		r1 = ( image[indx-1][0] + image[indx+1][0] + image[indx-u][0] + image[indx+u][0] + image[indx-u-1][0] + image[indx+u+1][0] + image[indx-u+1][0] + image[indx+u-1][0])/8.0;
		g1 = ( image[indx-1][1] + image[indx+1][1] + image[indx-u][1] + image[indx+u][1] + image[indx-u-1][1] + image[indx+u+1][1] + image[indx-u+1][1] + image[indx+u-1][1])/8.0;
		b1 = ( image[indx-1][2] + image[indx+1][2] + image[indx-u][2] + image[indx+u][2] + image[indx-u-1][2] + image[indx+u+1][2] + image[indx-u+1][2] + image[indx+u-1][2])/8.0;
		 
		image[indx][0] = CLIP(r1 + ( image[indx][1] - g1 ));
		image[indx][2] = CLIP(b1 + ( image[indx][1] - g1 ));
	
	}
}



// green blurring correction, helps to get the nyquist right
void CLASS dcb_nyquist()
{
	int row, col, c, u=width, v=2*u, indx;

	
	for (row=2; row < height-2; row++)
		for (col=2+(FC(row,2)&1),indx=row*width+col, c=FC(row,col); col < u-2; col+=2,indx+=2) {

			image[indx][1] = CLIP((image[indx+v][1] + image[indx-v][1] + image[indx-2][1] + image[indx+2][1])/4.0 + 
							  image[indx][c] - ( image[indx+v][c] + image[indx-v][c] + image[indx-2][c] + image[indx+2][c])/4.0);
	
	}	

}





// missing colors are interpolated using high quality algorithm by Luis Sanz Rodríguez
void CLASS dcb_color_full()
{
	int row,col,c,d,i,j,u=width,v=2*u,w=3*u,indx, g1, g2;
	float f[4],g[4],(*chroma)[2];

	chroma = (float (*)[2]) calloc(width*height,sizeof *chroma); merror (chroma, "dcb_color_full()");

	for (row=1; row < height-1; row++)
		for (col=1+(FC(row,1)&1),indx=row*width+col,c=FC(row,col),d=c/2; col < u-1; col+=2,indx+=2)
			chroma[indx][d]=image[indx][c]-image[indx][1];

	for (row=3; row<height-3; row++)
		for (col=3+(FC(row,1)&1),indx=row*width+col,c=1-FC(row,col)/2,d=1-c; col<u-3; col+=2,indx+=2) {
			f[0]=1.0/(float)(1.0+fabs(chroma[indx-u-1][c]-chroma[indx+u+1][c])+fabs(chroma[indx-u-1][c]-chroma[indx-w-3][c])+fabs(chroma[indx+u+1][c]-chroma[indx-w-3][c]));
			f[1]=1.0/(float)(1.0+fabs(chroma[indx-u+1][c]-chroma[indx+u-1][c])+fabs(chroma[indx-u+1][c]-chroma[indx-w+3][c])+fabs(chroma[indx+u-1][c]-chroma[indx-w+3][c]));
			f[2]=1.0/(float)(1.0+fabs(chroma[indx+u-1][c]-chroma[indx-u+1][c])+fabs(chroma[indx+u-1][c]-chroma[indx+w+3][c])+fabs(chroma[indx-u+1][c]-chroma[indx+w-3][c]));
			f[3]=1.0/(float)(1.0+fabs(chroma[indx+u+1][c]-chroma[indx-u-1][c])+fabs(chroma[indx+u+1][c]-chroma[indx+w-3][c])+fabs(chroma[indx-u-1][c]-chroma[indx+w+3][c]));
			g[0]=1.325*chroma[indx-u-1][c]-0.175*chroma[indx-w-3][c]-0.075*chroma[indx-w-1][c]-0.075*chroma[indx-u-3][c];
			g[1]=1.325*chroma[indx-u+1][c]-0.175*chroma[indx-w+3][c]-0.075*chroma[indx-w+1][c]-0.075*chroma[indx-u+3][c];
			g[2]=1.325*chroma[indx+u-1][c]-0.175*chroma[indx+w-3][c]-0.075*chroma[indx+w-1][c]-0.075*chroma[indx+u-3][c];
			g[3]=1.325*chroma[indx+u+1][c]-0.175*chroma[indx+w+3][c]-0.075*chroma[indx+w+1][c]-0.075*chroma[indx+u+3][c];
			chroma[indx][c]=(f[0]*g[0]+f[1]*g[1]+f[2]*g[2]+f[3]*g[3])/(f[0]+f[1]+f[2]+f[3]);
		}
	for (row=3; row<height-3; row++)
		for (col=3+(FC(row,2)&1),indx=row*width+col,c=FC(row,col+1)/2; col<u-3; col+=2,indx+=2)
			for(d=0;d<=1;c=1-c,d++){
				f[0]=1.0/(float)(1.0+fabs(chroma[indx-u][c]-chroma[indx+u][c])+fabs(chroma[indx-u][c]-chroma[indx-w][c])+fabs(chroma[indx+u][c]-chroma[indx-w][c]));
				f[1]=1.0/(float)(1.0+fabs(chroma[indx+1][c]-chroma[indx-1][c])+fabs(chroma[indx+1][c]-chroma[indx+3][c])+fabs(chroma[indx-1][c]-chroma[indx+3][c]));
				f[2]=1.0/(float)(1.0+fabs(chroma[indx-1][c]-chroma[indx+1][c])+fabs(chroma[indx-1][c]-chroma[indx-3][c])+fabs(chroma[indx+1][c]-chroma[indx-3][c]));
				f[3]=1.0/(float)(1.0+fabs(chroma[indx+u][c]-chroma[indx-u][c])+fabs(chroma[indx+u][c]-chroma[indx+w][c])+fabs(chroma[indx-u][c]-chroma[indx+w][c]));
			
				g[0]=0.875*chroma[indx-u][c]+0.125*chroma[indx-w][c];
				g[1]=0.875*chroma[indx+1][c]+0.125*chroma[indx+3][c];
				g[2]=0.875*chroma[indx-1][c]+0.125*chroma[indx-3][c];
				g[3]=0.875*chroma[indx+u][c]+0.125*chroma[indx+w][c];				

				chroma[indx][c]=(f[0]*g[0]+f[1]*g[1]+f[2]*g[2]+f[3]*g[3])/(f[0]+f[1]+f[2]+f[3]);
			}

	for(row=6; row<height-6; row++)
		for(col=6,indx=row*width+col; col<width-6; col++,indx++){
			image[indx][0]=CLIP(chroma[indx][0]+image[indx][1]);
			image[indx][2]=CLIP(chroma[indx][1]+image[indx][1]);
			
	g1 = MIN(image[indx+1+u][0], MIN(image[indx+1-u][0], MIN(image[indx-1+u][0], MIN(image[indx-1-u][0], MIN(image[indx-1][0], MIN(image[indx+1][0], MIN(image[indx-u][0], image[indx+u][0])))))));

	g2 = MAX(image[indx+1+u][0], MAX(image[indx+1-u][0], MAX(image[indx-1+u][0], MAX(image[indx-1-u][0], MAX(image[indx-1][0], MAX(image[indx+1][0], MAX(image[indx-u][0], image[indx+u][0])))))));


	image[indx][0] =  ULIM(image[indx][0], g2, g1);
	

	
	g1 = MIN(image[indx+1+u][2], MIN(image[indx+1-u][2], MIN(image[indx-1+u][2], MIN(image[indx-1-u][2], MIN(image[indx-1][2], MIN(image[indx+1][2], MIN(image[indx-u][2], image[indx+u][2])))))));

	g2 = MAX(image[indx+1+u][2], MAX(image[indx+1-u][2], MAX(image[indx-1+u][2], MAX(image[indx-1-u][2], MAX(image[indx-1][2], MAX(image[indx+1][2], MAX(image[indx-u][2], image[indx+u][2])))))));

	image[indx][2] =  ULIM(image[indx][2], g2, g1);
				
			
			
		}

	free(chroma);
}




// green is used to create an interpolation direction map saved in image[][3]
// 1 = vertical
// 0 = horizontal
void CLASS dcb_map()
{	
	int current, row, col, c, u=width, v=2*u, indx;

	for (row=1; row < height-1; row++) {
	for (col=1, indx=row*width+col; col < width-1; col++, indx++) { 

		if (image[indx][1] > ( image[indx-1][1] + image[indx+1][1] + image[indx-u][1] + image[indx+u][1])/4.0)
			image[indx][3] = ((MIN( image[indx-1][1], image[indx+1][1]) + image[indx-1][1] + image[indx+1][1]) < 
							  (MIN( image[indx-u][1], image[indx+u][1]) + image[indx-u][1] + image[indx+u][1]));   
		else
			image[indx][3] = ((MAX( image[indx-1][1], image[indx+1][1]) + image[indx-1][1] + image[indx+1][1]) > 
							  (MAX( image[indx-u][1], image[indx+u][1]) + image[indx-u][1] + image[indx+u][1])); 
	}
	}
}


// interpolated green pixels are corrected using the map
void CLASS dcb_correction()
{
	int current, row, col, u=width, v=2*u, indx;

	for (row=2; row < height-2; row++)
		for (col=2+(FC(row,2)&1),indx=row*width+col; col < u-2; col+=2,indx+=2) {

			current = 4*image[indx][3] + 
				      2*(image[indx+u][3] + image[indx-u][3] + image[indx+1][3] + image[indx-1][3]) + 
					    image[indx+v][3] + image[indx-v][3] + image[indx+2][3] + image[indx-2][3];
						
			image[indx][1] = ((16-current)*(image[indx-1][1] + image[indx+1][1])/2.0 + current*(image[indx-u][1] + image[indx+u][1])/2.0)/16.0;

	}

}


// interpolated green pixels are corrected using the map
// with contrast correction
void CLASS dcb_correction2()
{
	int current, row, col, c, u=width, v=2*u, indx;
	ushort (*pix)[4];

	for (row=4; row < height-4; row++)
		for (col=4+(FC(row,2)&1),indx=row*width+col, c=FC(row,col); col < u-4; col+=2,indx+=2) {
			
			current = 4*image[indx][3] + 
				      2*(image[indx+u][3] + image[indx-u][3] + image[indx+1][3] + image[indx-1][3]) + 
					    image[indx+v][3] + image[indx-v][3] + image[indx+2][3] + image[indx-2][3];
						
			image[indx][1] = CLIP(((16-current)*((image[indx-1][1] + image[indx+1][1])/2.0 + image[indx][c] - (image[indx+2][c] + image[indx-2][c])/2.0) + current*((image[indx-u][1] + image[indx+u][1])/2.0 + image[indx][c] - (image[indx+v][c] + image[indx-v][c])/2.0))/16.0);			   
		
	}

}


void CLASS dcb_refinement()
{
	int row, col, c, u=width, v=2*u, w=3*u, indx, current;
	float f[5], g1, g2, tmp, tmp2=0, tmp3=0;
	
	for (row=4; row < height-4; row++)
		for (col=4+(FC(row,2)&1),indx=row*width+col, c=FC(row,col); col < u-4; col+=2,indx+=2) {

			current = 4*image[indx][3] + 
				      2*(image[indx+u][3] + image[indx-u][3] + image[indx+1][3] + image[indx-1][3]) 
				      +image[indx+v][3] + image[indx-v][3] + image[indx-2][3] + image[indx+2][3];

if (image[indx][c] > 1)
{

f[0] = (float)(image[indx-u][1] + image[indx+u][1])/(2*image[indx][c]);


if (image[indx-v][c] > 0)
f[1] = 2*(float)image[indx-u][1]/(image[indx-v][c] + image[indx][c]);
else
f[1] = f[0];

if (image[indx-v][c] > 0)
f[2] = (float)(image[indx-u][1] + image[indx-w][1])/(2*image[indx-v][c]);
else
f[2] = f[0];

if (image[indx+v][c] > 0)
f[3] = 2*(float)image[indx+u][1]/(image[indx+v][c] + image[indx][c]);
else
f[3] = f[0];

if (image[indx+v][c] > 0)
f[4] = (float)(image[indx+u][1] + image[indx+w][1])/(2*image[indx+v][c]);
else
f[4] = f[0];

g1 = (5*f[0] + 3*f[1] + f[2] + 3*f[3] + f[4])/13.0;



f[0] = (float)(image[indx-1][1] + image[indx+1][1])/(2*image[indx][c]);

if (image[indx-2][c] > 0)
f[1] = 2*(float)image[indx-1][1]/(image[indx-2][c] + image[indx][c]);
else
f[1] = f[0];

if (image[indx-2][c] > 0)
f[2] = (float)(image[indx-1][1] + image[indx-3][1])/(2*image[indx-2][c]);
else
f[2] = f[0];

if (image[indx+2][c] > 0)
f[3] = 2*(float)image[indx+1][1]/(image[indx+2][c] + image[indx][c]);
else
f[3] = f[0];

if (image[indx+2][c] > 0)
f[4] = (float)(image[indx+1][1] + image[indx+3][1])/(2*image[indx+2][c]);
else
f[4] = f[0];

g2 = (5*f[0] + 3*f[1] + f[2] + 3*f[3] + f[4])/13.0;


image[indx][1] = CLIP((image[indx][c])*(current*g1 + (16-current)*g2)/16.0);
}
else
image[indx][1] = image[indx][c];
			
	// get rid of overshooted pixels

	g1 = MIN(image[indx+1+u][1], MIN(image[indx+1-u][1], MIN(image[indx-1+u][1], MIN(image[indx-1-u][1], MIN(image[indx-1][1], MIN(image[indx+1][1], MIN(image[indx-u][1], image[indx+u][1])))))));

	g2 = MAX(image[indx+1+u][1], MAX(image[indx+1-u][1], MAX(image[indx-1+u][1], MAX(image[indx-1-u][1], MAX(image[indx-1][1], MAX(image[indx+1][1], MAX(image[indx-u][1], image[indx+u][1])))))));

	image[indx][1] =  ULIM(image[indx][1], g2, g1);
	
	}	



}

// converts RGB to LCH colorspace and saves it to image3
void CLASS rgb_to_lch(double (*image2)[3])
{
	int indx;
	for (indx=0; indx < height*width; indx++) {

            image2[indx][0] = image[indx][0] + image[indx][1] + image[indx][2]; 		// L
            image2[indx][1] = 1.732050808 *(image[indx][0] - image[indx][1]);			// C
            image2[indx][2] = 2.0*image[indx][2] - image[indx][0] - image[indx][1];		// H
	}
}

// converts LCH to RGB colorspace and saves it back to image
void CLASS lch_to_rgb(double (*image2)[3])
{
	int indx;
	for (indx=0; indx < height*width; indx++) {

            image[indx][0] = CLIP(image2[indx][0] / 3.0 - image2[indx][2] / 6.0 + image2[indx][1] / 3.464101615);
            image[indx][1] = CLIP(image2[indx][0] / 3.0 - image2[indx][2] / 6.0 - image2[indx][1] / 3.464101615);
            image[indx][2] = CLIP(image2[indx][0] / 3.0 + image2[indx][2] / 3.0);
	}
}




// denoising using interpolated neighbours
void CLASS fbdd_correction()
{
	int row, col, c, u=width, indx;
	ushort (*pix)[4];

	for (row=2; row < height-2; row++) {
	for (col=2, indx=row*width+col; col < width-2; col++, indx++) { 	

		c =  fcol(row,col);

		image[indx][c] = ULIM(image[indx][c], 
					MAX(image[indx-1][c], MAX(image[indx+1][c], MAX(image[indx-u][c], image[indx+u][c]))), 
					MIN(image[indx-1][c], MIN(image[indx+1][c], MIN(image[indx-u][c], image[indx+u][c]))));

	} 
	}	
}


// corrects chroma noise
void CLASS fbdd_correction2(double (*image2)[3])
{
    int indx, u=width, v=2*width; 
    int col, row;
    double Co, Ho, ratio;

    for (row=6; row < height-6; row++)
    {
       for (col=6; col < width-6; col++)
       {
          indx = row*width+col;

          if ( image2[indx][1]*image2[indx][2] != 0 ) 
          {
             Co = (image2[indx+v][1] + image2[indx-v][1] + image2[indx-2][1] + image2[indx+2][1] - 
                   MAX(image2[indx-2][1], MAX(image2[indx+2][1], MAX(image2[indx-v][1], image2[indx+v][1]))) -
                   MIN(image2[indx-2][1], MIN(image2[indx+2][1], MIN(image2[indx-v][1], image2[indx+v][1]))))/2.0;
             Ho = (image2[indx+v][2] + image2[indx-v][2] + image2[indx-2][2] + image2[indx+2][2] - 
                   MAX(image2[indx-2][2], MAX(image2[indx+2][2], MAX(image2[indx-v][2], image2[indx+v][2]))) -
                   MIN(image2[indx-2][2], MIN(image2[indx+2][2], MIN(image2[indx-v][2], image2[indx+v][2]))))/2.0;
             ratio = sqrt ((Co*Co+Ho*Ho) / (image2[indx][1]*image2[indx][1] + image2[indx][2]*image2[indx][2]));
            
             if (ratio < 0.85)
             {
                 image2[indx][0] = -(image2[indx][1] + image2[indx][2] - Co - Ho) + image2[indx][0];
                 image2[indx][1] = Co;
                 image2[indx][2] = Ho;
	     }
          }
       }
    }
}


// Cubic Spline Interpolation by Li and Randhawa, modified by Jacek Gozdz and Luis Sanz Rodríguez
void CLASS fbdd_green()
{
	int row, col, c, u=width, v=2*u, w=3*u, x=4*u, y=5*u, indx, min, max, current;
	float f[4], g[4];

	for (row=5; row < height-5; row++)
		for (col=5+(FC(row,1)&1),indx=row*width+col,c=FC(row,col); col < u-5; col+=2,indx+=2) {
			
		
f[0]=1.0/(1.0+abs(image[indx-u][1]-image[indx-w][1])+abs(image[indx-w][1]-image[indx+y][1]));
f[1]=1.0/(1.0+abs(image[indx+1][1]-image[indx+3][1])+abs(image[indx+3][1]-image[indx-5][1]));
f[2]=1.0/(1.0+abs(image[indx-1][1]-image[indx-3][1])+abs(image[indx-3][1]-image[indx+5][1]));
f[3]=1.0/(1.0+abs(image[indx+u][1]-image[indx+w][1])+abs(image[indx+w][1]-image[indx-y][1]));

g[0]=CLIP((23*image[indx-u][1]+23*image[indx-w][1]+2*image[indx-y][1]+8*(image[indx-v][c]-image[indx-x][c])+40*(image[indx][c]-image[indx-v][c]))/48.0);
g[1]=CLIP((23*image[indx+1][1]+23*image[indx+3][1]+2*image[indx+5][1]+8*(image[indx+2][c]-image[indx+4][c])+40*(image[indx][c]-image[indx+2][c]))/48.0);
g[2]=CLIP((23*image[indx-1][1]+23*image[indx-3][1]+2*image[indx-5][1]+8*(image[indx-2][c]-image[indx-4][c])+40*(image[indx][c]-image[indx-2][c]))/48.0);
g[3]=CLIP((23*image[indx+u][1]+23*image[indx+w][1]+2*image[indx+y][1]+8*(image[indx+v][c]-image[indx+x][c])+40*(image[indx][c]-image[indx+v][c]))/48.0);

	image[indx][1]=CLIP((f[0]*g[0]+f[1]*g[1]+f[2]*g[2]+f[3]*g[3])/(f[0]+f[1]+f[2]+f[3]));
	
	min = MIN(image[indx+1+u][1], MIN(image[indx+1-u][1], MIN(image[indx-1+u][1], MIN(image[indx-1-u][1], MIN(image[indx-1][1], MIN(image[indx+1][1], MIN(image[indx-u][1], image[indx+u][1])))))));

	max = MAX(image[indx+1+u][1], MAX(image[indx+1-u][1], MAX(image[indx-1+u][1], MAX(image[indx-1-u][1], MAX(image[indx-1][1], MAX(image[indx+1][1], MAX(image[indx-u][1], image[indx+u][1])))))));

	image[indx][1] = ULIM(image[indx][1], max, min);				
		}
}




// FBDD (Fake Before Demosaicing Denoising)
void CLASS fbdd(int noiserd)
{ 
	double (*image2)[3];
        // safety net: disable for 4-color bayer or full-color images
        if(colors!=3 || !filters)
            return;
	image2 = (double (*)[3]) calloc(width*height, sizeof *image2);

	border_interpolate(4);

if (noiserd>1)
{
#ifdef DCRAW_VERBOSE
	if (verbose) fprintf (stderr,_("FBDD full noise reduction...\n"));
#endif
	fbdd_green();
	//dcb_color_full(image2);
	dcb_color_full();
	fbdd_correction();	
	

	dcb_color();
	rgb_to_lch(image2);
	fbdd_correction2(image2);
	fbdd_correction2(image2);
	lch_to_rgb(image2); 

}
else
{
#ifdef DCRAW_VERBOSE
	if (verbose) fprintf (stderr,_("FBDD noise reduction...\n"));
#endif

	fbdd_green();
	//dcb_color_full(image2);
	dcb_color_full();
	fbdd_correction();	
}

free(image2);

}




// DCB demosaicing main routine
void CLASS dcb(int iterations, int dcb_enhance)
{


	int i=1;
	
	float (*image2)[3];
	image2 = (float (*)[3]) calloc(width*height, sizeof *image2);

	float (*image3)[3];
	image3 = (float (*)[3]) calloc(width*height, sizeof *image3);
	
#ifdef DCRAW_VERBOSE
	if (verbose) fprintf (stderr,_("DCB demosaicing...\n"));
#endif

 		border_interpolate(6);

		dcb_hor(image2);
 		dcb_color2(image2);
  		
 		dcb_ver(image3);
 		dcb_color3(image3);
  		
 		dcb_decide(image2, image3);

		free(image3);

		dcb_copy_to_buffer(image2);

		while (i<=iterations)
		{
#ifdef DCRAW_VERBOSE
			if (verbose) fprintf (stderr,_("DCB correction pass %d...\n"), i);
#endif                        
			dcb_nyquist();
			dcb_nyquist();
			dcb_nyquist();
			dcb_map();
			dcb_correction();	
			i++;
		}
		
		dcb_color();
		dcb_pp();	
		
#ifdef DCRAW_VERBOSE
	if (verbose) fprintf (stderr,_("finishing DCB...\n"));
#endif		
		dcb_map();
		dcb_correction2();

		dcb_map();
		dcb_correction();

		dcb_map();
		dcb_correction();

		dcb_map();
		dcb_correction();	

		dcb_map();
		dcb_restore_from_buffer(image2);
		dcb_color();

	if (dcb_enhance)
	{	
#ifdef DCRAW_VERBOSE
		if (verbose) fprintf (stderr,_("optional DCB refinement...\n"));
#endif
		dcb_refinement();
 		//dcb_color_full(image2);		
 		dcb_color_full();		
	}


		free(image2);

}