src/libprojectM/Renderer/SOIL/image_helper.c - vendor/opensource/projectM - Git at Google

 /*
     Jonathan Dummer

     image helper functions

     MIT license
 */

 #include "image_helper.h"
 #include <stdlib.h>
 #include <math.h>

 /*	Upscaling the image uses simple bilinear interpolation	*/
 int
 	up_scale_image
 	(
 		const unsigned char* const orig,
 		int width, int height, int channels,
 		unsigned char* resampled,
 		int resampled_width, int resampled_height
 	)
 {
 	float dx, dy;
 	int x, y, c;

     /* error(s) check	*/
     if ( 	(width < 1) || (height < 1) ||
             (resampled_width < 2) || (resampled_height < 2) ||
             (channels < 1) ||
             (NULL == orig) || (NULL == resampled) )
     {
         /*	signify badness	*/
         return 0;
     }
     /*
 		for each given pixel in the new map, find the exact location
 		from the original map which would contribute to this guy
 	*/
     dx = (width - 1.0f) / (resampled_width - 1.0f);
     dy = (height - 1.0f) / (resampled_height - 1.0f);
     for ( y = 0; y < resampled_height; ++y )
     {
     	/* find the base y index and fractional offset from that	*/
     	float sampley = y * dy;
     	int inty = (int)sampley;
     	/*	if( inty < 0 ) { inty = 0; } else	*/
 		if( inty > height - 2 ) { inty = height - 2; }
 		sampley -= inty;
         for ( x = 0; x < resampled_width; ++x )
         {
 			float samplex = x * dx;
 			int intx = (int)samplex;
 			int base_index;
 			/* find the base x index and fractional offset from that	*/
 			/*	if( intx < 0 ) { intx = 0; } else	*/
 			if( intx > width - 2 ) { intx = width - 2; }
 			samplex -= intx;
 			/*	base index into the original image	*/
 			base_index = (inty * width + intx) * channels;
             for ( c = 0; c < channels; ++c )
             {
             	/*	do the sampling	*/
 				float value = 0.5f;
 				value += orig[base_index]
 							*(1.0f-samplex)*(1.0f-sampley);
 				value += orig[base_index+channels]
 							*(samplex)*(1.0f-sampley);
 				value += orig[base_index+width*channels]
 							*(1.0f-samplex)*(sampley);
 				value += orig[base_index+width*channels+channels]
 							*(samplex)*(sampley);
 				/*	move to the next channel	*/
 				++base_index;
             	/*	save the new value	*/
             	resampled[y*resampled_width*channels+x*channels+c] =
 						(unsigned char)(value);
             }
         }
     }
     /*	done	*/
     return 1;
 }

 int
 	mipmap_image
 	(
 		const unsigned char* const orig,
 		int width, int height, int channels,
 		unsigned char* resampled,
 		int block_size_x, int block_size_y
 	)
 {
 	int mip_width, mip_height;
 	int i, j, c;

 	/*	error check	*/
 	if( (width < 1) || (height < 1) ||
 		(channels < 1) || (orig == NULL) ||
 		(resampled == NULL) ||
 		(block_size_x < 1) || (block_size_y < 1) )
 	{
 		/*	nothing to do	*/
 		return 0;
 	}
 	mip_width = width / block_size_x;
 	mip_height = height / block_size_y;
 	if( mip_width < 1 )
 	{
 		mip_width = 1;
 	}
 	if( mip_height < 1 )
 	{
 		mip_height = 1;
 	}
 	for( j = 0; j < mip_height; ++j )
 	{
 		for( i = 0; i < mip_width; ++i )
 		{
 			for( c = 0; c < channels; ++c )
 			{
 				const int index = (j*block_size_y)*width*channels + (i*block_size_x)*channels + c;
 				int sum_value;
 				int u,v;
 				int u_block = block_size_x;
 				int v_block = block_size_y;
 				int block_area;
 				/*	do a bit of checking so we don't over-run the boundaries
 					(necessary for non-square textures!)	*/
 				if( block_size_x * (i+1) > width )
 				{
 					u_block = width - i*block_size_y;
 				}
 				if( block_size_y * (j+1) > height )
 				{
 					v_block = height - j*block_size_y;
 				}
 				block_area = u_block*v_block;
 				/*	for this pixel, see what the average
 					of all the values in the block are.
 					note: start the sum at the rounding value, not at 0	*/
 				sum_value = block_area >> 1;
 				for( v = 0; v < v_block; ++v )
 				for( u = 0; u < u_block; ++u )
 				{
 					sum_value += orig[index + v*width*channels + u*channels];
 				}
 				resampled[j*mip_width*channels + i*channels + c] = sum_value / block_area;
 			}
 		}
 	}
 	return 1;
 }

 int
 	scale_image_RGB_to_NTSC_safe
 	(
 		unsigned char* orig,
 		int width, int height, int channels
 	)
 {
 	const float scale_lo = 16.0f - 0.499f;
 	const float scale_hi = 235.0f + 0.499f;
 	int i, j;
 	int nc = channels;
 	unsigned char scale_LUT[256];
 	/*	error check	*/
 	if( (width < 1) || (height < 1) ||
 		(channels < 1) || (orig == NULL) )
 	{
 		/*	nothing to do	*/
 		return 0;
 	}
 	/*	set up the scaling Look Up Table	*/
 	for( i = 0; i < 256; ++i )
 	{
 		scale_LUT[i] = (unsigned char)((scale_hi - scale_lo) * i / 255.0f + scale_lo);
 	}
 	/*	for channels = 2 or 4, ignore the alpha component	*/
 	nc -= 1 - (channels & 1);
 	/*	OK, go through the image and scale any non-alpha components	*/
 	for( i = 0; i < width*height*channels; i += channels )
 	{
 		for( j = 0; j < nc; ++j )
 		{
 			orig[i+j] = scale_LUT[orig[i+j]];
 		}
 	}
 	return 1;
 }

 unsigned char clamp_byte( int x ) { return ( (x) < 0 ? (0) : ( (x) > 255 ? 255 : (x) ) ); }

 /*
 	This function takes the RGB components of the image
 	and converts them into YCoCg.  3 components will be
 	re-ordered to CoYCg (for optimum DXT1 compression),
 	while 4 components will be ordered CoCgAY (for DXT5
 	compression).
 */
 int
 	convert_RGB_to_YCoCg
 	(
 		unsigned char* orig,
 		int width, int height, int channels
 	)
 {
 	int i;
 	/*	error check	*/
 	if( (width < 1) || (height < 1) ||
 		(channels < 3) || (channels > 4) ||
 		(orig == NULL) )
 	{
 		/*	nothing to do	*/
 		return -1;
 	}
 	/*	do the conversion	*/
 	if( channels == 3 )
 	{
 		for( i = 0; i < width*height*3; i += 3 )
 		{
 			int r = orig[i+0];
 			int g = (orig[i+1] + 1) >> 1;
 			int b = orig[i+2];
 			int tmp = (2 + r + b) >> 2;
 			/*	Co	*/
 			orig[i+0] = clamp_byte( 128 + ((r - b + 1) >> 1) );
 			/*	Y	*/
 			orig[i+1] = clamp_byte( g + tmp );
 			/*	Cg	*/
 			orig[i+2] = clamp_byte( 128 + g - tmp );
 		}
 	} else
 	{
 		for( i = 0; i < width*height*4; i += 4 )
 		{
 			int r = orig[i+0];
 			int g = (orig[i+1] + 1) >> 1;
 			int b = orig[i+2];
 			unsigned char a = orig[i+3];
 			int tmp = (2 + r + b) >> 2;
 			/*	Co	*/
 			orig[i+0] = clamp_byte( 128 + ((r - b + 1) >> 1) );
 			/*	Cg	*/
 			orig[i+1] = clamp_byte( 128 + g - tmp );
 			/*	Alpha	*/
 			orig[i+2] = a;
 			/*	Y	*/
 			orig[i+3] = clamp_byte( g + tmp );
 		}
 	}
 	/*	done	*/
 	return 0;
 }

 /*
 	This function takes the YCoCg components of the image
 	and converts them into RGB.  See above.
 */
 int
 	convert_YCoCg_to_RGB
 	(
 		unsigned char* orig,
 		int width, int height, int channels
 	)
 {
 	int i;
 	/*	error check	*/
 	if( (width < 1) || (height < 1) ||
 		(channels < 3) || (channels > 4) ||
 		(orig == NULL) )
 	{
 		/*	nothing to do	*/
 		return -1;
 	}
 	/*	do the conversion	*/
 	if( channels == 3 )
 	{
 		for( i = 0; i < width*height*3; i += 3 )
 		{
 			int co = orig[i+0] - 128;
 			int y  = orig[i+1];
 			int cg = orig[i+2] - 128;
 			/*	R	*/
 			orig[i+0] = clamp_byte( y + co - cg );
 			/*	G	*/
 			orig[i+1] = clamp_byte( y + cg );
 			/*	B	*/
 			orig[i+2] = clamp_byte( y - co - cg );
 		}
 	} else
 	{
 		for( i = 0; i < width*height*4; i += 4 )
 		{
 			int co = orig[i+0] - 128;
 			int cg = orig[i+1] - 128;
 			unsigned char a  = orig[i+2];
 			int y  = orig[i+3];
 			/*	R	*/
 			orig[i+0] = clamp_byte( y + co - cg );
 			/*	G	*/
 			orig[i+1] = clamp_byte( y + cg );
 			/*	B	*/
 			orig[i+2] = clamp_byte( y - co - cg );
 			/*	A	*/
 			orig[i+3] = a;
 		}
 	}
 	/*	done	*/
 	return 0;
 }

 float
 find_max_RGBE
 (
 	unsigned char *image,
     int width, int height
 )
 {
 	float max_val = 0.0f;
 	unsigned char *img = image;
 	int i, j;
 	for( i = width * height; i > 0; --i )
 	{
 		/* float scale = powf( 2.0f, img[3] - 128.0f ) / 255.0f; */
 		float scale = ldexp( 1.0f / 255.0f, (int)(img[3]) - 128 );
 		for( j = 0; j < 3; ++j )
 		{
 			if( img[j] * scale > max_val )
 			{
 				max_val = img[j] * scale;
 			}
 		}
 		/* next pixel */
 		img += 4;
 	}
 	return max_val;
 }

 int
 RGBE_to_RGBdivA
 (
     unsigned char *image,
     int width, int height,
     int rescale_to_max
 )
 {
 	/* local variables */
 	int i, iv;
 	unsigned char *img = image;
 	float scale = 1.0f;
 	/* error check */
 	if( (!image) || (width < 1) || (height < 1) )
 	{
 		return 0;
 	}
 	/* convert (note: no negative numbers, but 0.0 is possible) */
 	if( rescale_to_max )
 	{
 		scale = 255.0f / find_max_RGBE( image, width, height );
 	}
 	for( i = width * height; i > 0; --i )
 	{
 		/* decode this pixel, and find the max */
 		float r,g,b,e, m;
 		/* e = scale * powf( 2.0f, img[3] - 128.0f ) / 255.0f; */
 		e = scale * ldexp( 1.0f / 255.0f, (int)(img[3]) - 128 );
 		r = e * img[0];
 		g = e * img[1];
 		b = e * img[2];
 		m = (r > g) ? r : g;
 		m = (b > m) ? b : m;
 		/* and encode it into RGBdivA */
 		iv = (m != 0.0f) ? (int)(255.0f / m) : 1.0f;
 		iv = (iv < 1) ? 1 : iv;
 		img[3] = (iv > 255) ? 255 : iv;
 		iv = (int)(img[3] * r + 0.5f);
 		img[0] = (iv > 255) ? 255 : iv;
 		iv = (int)(img[3] * g + 0.5f);
 		img[1] = (iv > 255) ? 255 : iv;
 		iv = (int)(img[3] * b + 0.5f);
 		img[2] = (iv > 255) ? 255 : iv;
 		/* and on to the next pixel */
 		img += 4;
 	}
 	return 1;
 }

 int
 RGBE_to_RGBdivA2
 (
     unsigned char *image,
     int width, int height,
     int rescale_to_max
 )
 {
 	/* local variables */
 	int i, iv;
 	unsigned char *img = image;
 	float scale = 1.0f;
 	/* error check */
 	if( (!image) || (width < 1) || (height < 1) )
 	{
 		return 0;
 	}
 	/* convert (note: no negative numbers, but 0.0 is possible) */
 	if( rescale_to_max )
 	{
 		scale = 255.0f * 255.0f / find_max_RGBE( image, width, height );
 	}
 	for( i = width * height; i > 0; --i )
 	{
 		/* decode this pixel, and find the max */
 		float r,g,b,e, m;
 		/* e = scale * powf( 2.0f, img[3] - 128.0f ) / 255.0f; */
 		e = scale * ldexp( 1.0f / 255.0f, (int)(img[3]) - 128 );
 		r = e * img[0];
 		g = e * img[1];
 		b = e * img[2];
 		m = (r > g) ? r : g;
 		m = (b > m) ? b : m;
 		/* and encode it into RGBdivA */
 		iv = (m != 0.0f) ? (int)sqrtf( 255.0f * 255.0f / m ) : 1.0f;
 		iv = (iv < 1) ? 1 : iv;
 		img[3] = (iv > 255) ? 255 : iv;
 		iv = (int)(img[3] * img[3] * r / 255.0f + 0.5f);
 		img[0] = (iv > 255) ? 255 : iv;
 		iv = (int)(img[3] * img[3] * g / 255.0f + 0.5f);
 		img[1] = (iv > 255) ? 255 : iv;
 		iv = (int)(img[3] * img[3] * b / 255.0f + 0.5f);
 		img[2] = (iv > 255) ? 255 : iv;
 		/* and on to the next pixel */
 		img += 4;
 	}
 	return 1;
 }
	/*
	Jonathan Dummer

	image helper functions

	MIT license
	*/

	#include "image_helper.h"
	#include <stdlib.h>
	#include <math.h>

	/* Upscaling the image uses simple bilinear interpolation */
	int
	up_scale_image
	(
	const unsigned char* const orig,
	int width, int height, int channels,
	unsigned char* resampled,
	int resampled_width, int resampled_height
	)
	{
	float dx, dy;
	int x, y, c;

	/* error(s) check */
	if ( (width < 1) \|\| (height < 1) \|\|
	(resampled_width < 2) \|\| (resampled_height < 2) \|\|
	(channels < 1) \|\|
	(NULL == orig) \|\| (NULL == resampled) )
	{
	/* signify badness */
	return 0;
	}
	/*
	for each given pixel in the new map, find the exact location
	from the original map which would contribute to this guy
	*/
	dx = (width - 1.0f) / (resampled_width - 1.0f);
	dy = (height - 1.0f) / (resampled_height - 1.0f);
	for ( y = 0; y < resampled_height; ++y )
	{
	/* find the base y index and fractional offset from that */
	float sampley = y * dy;
	int inty = (int)sampley;
	/* if( inty < 0 ) { inty = 0; } else */
	if( inty > height - 2 ) { inty = height - 2; }
	sampley -= inty;
	for ( x = 0; x < resampled_width; ++x )
	{
	float samplex = x * dx;
	int intx = (int)samplex;
	int base_index;
	/* find the base x index and fractional offset from that */
	/* if( intx < 0 ) { intx = 0; } else */
	if( intx > width - 2 ) { intx = width - 2; }
	samplex -= intx;
	/* base index into the original image */
	base_index = (inty * width + intx) * channels;
	for ( c = 0; c < channels; ++c )
	{
	/* do the sampling */
	float value = 0.5f;
	value += orig[base_index]
	(1.0f-samplex)(1.0f-sampley);
	value += orig[base_index+channels]
	(samplex)(1.0f-sampley);
	value += orig[base_index+width*channels]
	(1.0f-samplex)(sampley);
	value += orig[base_index+width*channels+channels]
	(samplex)(sampley);
	/* move to the next channel */
	++base_index;
	/* save the new value */
	resampled[yresampled_widthchannels+x*channels+c] =
	(unsigned char)(value);
	}
	}
	}
	/* done */
	return 1;
	}

	int
	mipmap_image
	(
	const unsigned char* const orig,
	int width, int height, int channels,
	unsigned char* resampled,
	int block_size_x, int block_size_y
	)
	{
	int mip_width, mip_height;
	int i, j, c;

	/* error check */
	if( (width < 1) \|\| (height < 1) \|\|
	(channels < 1) \|\| (orig == NULL) \|\|
	(resampled == NULL) \|\|
	(block_size_x < 1) \|\| (block_size_y < 1) )
	{
	/* nothing to do */
	return 0;
	}
	mip_width = width / block_size_x;
	mip_height = height / block_size_y;
	if( mip_width < 1 )
	{
	mip_width = 1;
	}
	if( mip_height < 1 )
	{
	mip_height = 1;
	}
	for( j = 0; j < mip_height; ++j )
	{
	for( i = 0; i < mip_width; ++i )
	{
	for( c = 0; c < channels; ++c )
	{
	const int index = (jblock_size_y)widthchannels + (iblock_size_x)*channels + c;
	int sum_value;
	int u,v;
	int u_block = block_size_x;
	int v_block = block_size_y;
	int block_area;
	/* do a bit of checking so we don't over-run the boundaries
	(necessary for non-square textures!) */
	if( block_size_x * (i+1) > width )
	{
	u_block = width - i*block_size_y;
	}
	if( block_size_y * (j+1) > height )
	{
	v_block = height - j*block_size_y;
	}
	block_area = u_block*v_block;
	/* for this pixel, see what the average
	of all the values in the block are.
	note: start the sum at the rounding value, not at 0 */
	sum_value = block_area >> 1;
	for( v = 0; v < v_block; ++v )
	for( u = 0; u < u_block; ++u )
	{
	sum_value += orig[index + vwidthchannels + u*channels];
	}
	resampled[jmip_widthchannels + i*channels + c] = sum_value / block_area;
	}
	}
	}
	return 1;
	}

	int
	scale_image_RGB_to_NTSC_safe
	(
	unsigned char* orig,
	int width, int height, int channels
	)
	{
	const float scale_lo = 16.0f - 0.499f;
	const float scale_hi = 235.0f + 0.499f;
	int i, j;
	int nc = channels;
	unsigned char scale_LUT[256];
	/* error check */
	if( (width < 1) \|\| (height < 1) \|\|
	(channels < 1) \|\| (orig == NULL) )
	{
	/* nothing to do */
	return 0;
	}
	/* set up the scaling Look Up Table */
	for( i = 0; i < 256; ++i )
	{
	scale_LUT[i] = (unsigned char)((scale_hi - scale_lo) * i / 255.0f + scale_lo);
	}
	/* for channels = 2 or 4, ignore the alpha component */
	nc -= 1 - (channels & 1);
	/* OK, go through the image and scale any non-alpha components */
	for( i = 0; i < widthheightchannels; i += channels )
	{
	for( j = 0; j < nc; ++j )
	{
	orig[i+j] = scale_LUT[orig[i+j]];
	}
	}
	return 1;
	}

	unsigned char clamp_byte( int x ) { return ( (x) < 0 ? (0) : ( (x) > 255 ? 255 : (x) ) ); }

	/*
	This function takes the RGB components of the image
	and converts them into YCoCg. 3 components will be
	re-ordered to CoYCg (for optimum DXT1 compression),
	while 4 components will be ordered CoCgAY (for DXT5
	compression).
	*/
	int
	convert_RGB_to_YCoCg
	(
	unsigned char* orig,
	int width, int height, int channels
	)
	{
	int i;
	/* error check */
	if( (width < 1) \|\| (height < 1) \|\|
	(channels < 3) \|\| (channels > 4) \|\|
	(orig == NULL) )
	{
	/* nothing to do */
	return -1;
	}
	/* do the conversion */
	if( channels == 3 )
	{
	for( i = 0; i < widthheight3; i += 3 )
	{
	int r = orig[i+0];
	int g = (orig[i+1] + 1) >> 1;
	int b = orig[i+2];
	int tmp = (2 + r + b) >> 2;
	/* Co */
	orig[i+0] = clamp_byte( 128 + ((r - b + 1) >> 1) );
	/* Y */
	orig[i+1] = clamp_byte( g + tmp );
	/* Cg */
	orig[i+2] = clamp_byte( 128 + g - tmp );
	}
	} else
	{
	for( i = 0; i < widthheight4; i += 4 )
	{
	int r = orig[i+0];
	int g = (orig[i+1] + 1) >> 1;
	int b = orig[i+2];
	unsigned char a = orig[i+3];
	int tmp = (2 + r + b) >> 2;
	/* Co */
	orig[i+0] = clamp_byte( 128 + ((r - b + 1) >> 1) );
	/* Cg */
	orig[i+1] = clamp_byte( 128 + g - tmp );
	/* Alpha */
	orig[i+2] = a;
	/* Y */
	orig[i+3] = clamp_byte( g + tmp );
	}
	}
	/* done */
	return 0;
	}

	/*
	This function takes the YCoCg components of the image
	and converts them into RGB. See above.
	*/
	int
	convert_YCoCg_to_RGB
	(
	unsigned char* orig,
	int width, int height, int channels
	)
	{
	int i;
	/* error check */
	if( (width < 1) \|\| (height < 1) \|\|
	(channels < 3) \|\| (channels > 4) \|\|
	(orig == NULL) )
	{
	/* nothing to do */
	return -1;
	}
	/* do the conversion */
	if( channels == 3 )
	{
	for( i = 0; i < widthheight3; i += 3 )
	{
	int co = orig[i+0] - 128;
	int y = orig[i+1];
	int cg = orig[i+2] - 128;
	/* R */
	orig[i+0] = clamp_byte( y + co - cg );
	/* G */
	orig[i+1] = clamp_byte( y + cg );
	/* B */
	orig[i+2] = clamp_byte( y - co - cg );
	}
	} else
	{
	for( i = 0; i < widthheight4; i += 4 )
	{
	int co = orig[i+0] - 128;
	int cg = orig[i+1] - 128;
	unsigned char a = orig[i+2];
	int y = orig[i+3];
	/* R */
	orig[i+0] = clamp_byte( y + co - cg );
	/* G */
	orig[i+1] = clamp_byte( y + cg );
	/* B */
	orig[i+2] = clamp_byte( y - co - cg );
	/* A */
	orig[i+3] = a;
	}
	}
	/* done */
	return 0;
	}

	float
	find_max_RGBE
	(
	unsigned char *image,
	int width, int height
	)
	{
	float max_val = 0.0f;
	unsigned char *img = image;
	int i, j;
	for( i = width * height; i > 0; --i )
	{
	/* float scale = powf( 2.0f, img[3] - 128.0f ) / 255.0f; */
	float scale = ldexp( 1.0f / 255.0f, (int)(img[3]) - 128 );
	for( j = 0; j < 3; ++j )
	{
	if( img[j] * scale > max_val )
	{
	max_val = img[j] * scale;
	}
	}
	/* next pixel */
	img += 4;
	}
	return max_val;
	}

	int
	RGBE_to_RGBdivA
	(
	unsigned char *image,
	int width, int height,
	int rescale_to_max
	)
	{
	/* local variables */
	int i, iv;
	unsigned char *img = image;
	float scale = 1.0f;
	/* error check */
	if( (!image) \|\| (width < 1) \|\| (height < 1) )
	{
	return 0;
	}
	/* convert (note: no negative numbers, but 0.0 is possible) */
	if( rescale_to_max )
	{
	scale = 255.0f / find_max_RGBE( image, width, height );
	}
	for( i = width * height; i > 0; --i )
	{
	/* decode this pixel, and find the max */
	float r,g,b,e, m;
	/* e = scale * powf( 2.0f, img[3] - 128.0f ) / 255.0f; */
	e = scale * ldexp( 1.0f / 255.0f, (int)(img[3]) - 128 );
	r = e * img[0];
	g = e * img[1];
	b = e * img[2];
	m = (r > g) ? r : g;
	m = (b > m) ? b : m;
	/* and encode it into RGBdivA */
	iv = (m != 0.0f) ? (int)(255.0f / m) : 1.0f;
	iv = (iv < 1) ? 1 : iv;
	img[3] = (iv > 255) ? 255 : iv;
	iv = (int)(img[3] * r + 0.5f);
	img[0] = (iv > 255) ? 255 : iv;
	iv = (int)(img[3] * g + 0.5f);
	img[1] = (iv > 255) ? 255 : iv;
	iv = (int)(img[3] * b + 0.5f);
	img[2] = (iv > 255) ? 255 : iv;
	/* and on to the next pixel */
	img += 4;
	}
	return 1;
	}

	int
	RGBE_to_RGBdivA2
	(
	unsigned char *image,
	int width, int height,
	int rescale_to_max
	)
	{
	/* local variables */
	int i, iv;
	unsigned char *img = image;
	float scale = 1.0f;
	/* error check */
	if( (!image) \|\| (width < 1) \|\| (height < 1) )
	{
	return 0;
	}
	/* convert (note: no negative numbers, but 0.0 is possible) */
	if( rescale_to_max )
	{
	scale = 255.0f * 255.0f / find_max_RGBE( image, width, height );
	}
	for( i = width * height; i > 0; --i )
	{
	/* decode this pixel, and find the max */
	float r,g,b,e, m;
	/* e = scale * powf( 2.0f, img[3] - 128.0f ) / 255.0f; */
	e = scale * ldexp( 1.0f / 255.0f, (int)(img[3]) - 128 );
	r = e * img[0];
	g = e * img[1];
	b = e * img[2];
	m = (r > g) ? r : g;
	m = (b > m) ? b : m;
	/* and encode it into RGBdivA */
	iv = (m != 0.0f) ? (int)sqrtf( 255.0f * 255.0f / m ) : 1.0f;
	iv = (iv < 1) ? 1 : iv;
	img[3] = (iv > 255) ? 255 : iv;
	iv = (int)(img[3] * img[3] * r / 255.0f + 0.5f);
	img[0] = (iv > 255) ? 255 : iv;
	iv = (int)(img[3] * img[3] * g / 255.0f + 0.5f);
	img[1] = (iv > 255) ? 255 : iv;
	iv = (int)(img[3] * img[3] * b / 255.0f + 0.5f);
	img[2] = (iv > 255) ? 255 : iv;
	/* and on to the next pixel */
	img += 4;
	}
	return 1;
	}