files/Source/FreeImage/tmoColorConvert.cpp - free_image - Git at Google

 // ==========================================================
 // High Dynamic Range bitmap conversion routines
 //
 // Design and implementation by
 // - Hervé Drolon (drolon@infonie.fr)
 // - Mihail Naydenov (mnaydenov@users.sourceforge.net)
 //
 // This file is part of FreeImage 3
 //
 // COVERED CODE IS PROVIDED UNDER THIS LICENSE ON AN "AS IS" BASIS, WITHOUT WARRANTY
 // OF ANY KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING, WITHOUT LIMITATION, WARRANTIES
 // THAT THE COVERED CODE IS FREE OF DEFECTS, MERCHANTABLE, FIT FOR A PARTICULAR PURPOSE
 // OR NON-INFRINGING. THE ENTIRE RISK AS TO THE QUALITY AND PERFORMANCE OF THE COVERED
 // CODE IS WITH YOU. SHOULD ANY COVERED CODE PROVE DEFECTIVE IN ANY RESPECT, YOU (NOT
 // THE INITIAL DEVELOPER OR ANY OTHER CONTRIBUTOR) ASSUME THE COST OF ANY NECESSARY
 // SERVICING, REPAIR OR CORRECTION. THIS DISCLAIMER OF WARRANTY CONSTITUTES AN ESSENTIAL
 // PART OF THIS LICENSE. NO USE OF ANY COVERED CODE IS AUTHORIZED HEREUNDER EXCEPT UNDER
 // THIS DISCLAIMER.
 //
 // Use at your own risk!
 // ==========================================================

 #include <cmath>

 #include "FreeImage.h"
 #include "Utilities.h"
 #include "ToneMapping.h"

 // ----------------------------------------------------------
 // Convert RGB to and from Yxy, same as in Reinhard et al. SIGGRAPH 2002
 // References :
 // [1] Radiance Home Page [Online] http://radsite.lbl.gov/radiance/HOME.html
 // [2] E. Reinhard, M. Stark, P. Shirley, and J. Ferwerda,
 //     Photographic Tone Reproduction for Digital Images, ACM Transactions on Graphics,
 //     21(3):267-276, 2002 (Proceedings of SIGGRAPH 2002).
 // [3] J. Tumblin and H.E. Rushmeier,
 //     Tone Reproduction for Realistic Images. IEEE Computer Graphics and Applications,
 //     13(6):42-48, 1993.
 // ----------------------------------------------------------

 /**
 nominal CRT primaries
 */
 /*
 static const float CIE_x_r = 0.640F;
 static const float CIE_y_r = 0.330F;
 static const float CIE_x_g = 0.290F;
 static const float CIE_y_g = 0.600F;
 static const float CIE_x_b = 0.150F;
 static const float CIE_y_b = 0.060F;
 static const float CIE_x_w = 0.3333F;	// use true white
 static const float CIE_y_w = 0.3333F;
 */
 /**
 sRGB primaries
 */
 static const float CIE_x_r = 0.640F;
 static const float CIE_y_r = 0.330F;
 static const float CIE_x_g = 0.300F;
 static const float CIE_y_g = 0.600F;
 static const float CIE_x_b = 0.150F;
 static const float CIE_y_b = 0.060F;
 static const float CIE_x_w = 0.3127F;	// Illuminant D65
 static const float CIE_y_w = 0.3290F;

 static const float CIE_D = ( CIE_x_r*(CIE_y_g - CIE_y_b) + CIE_x_g*(CIE_y_b - CIE_y_r) + CIE_x_b*(CIE_y_r - CIE_y_g) );
 static const float CIE_C_rD = ( (1/CIE_y_w) * ( CIE_x_w*(CIE_y_g - CIE_y_b) - CIE_y_w*(CIE_x_g - CIE_x_b) + CIE_x_g*CIE_y_b - CIE_x_b*CIE_y_g) );
 static const float CIE_C_gD = ( (1/CIE_y_w) * ( CIE_x_w*(CIE_y_b - CIE_y_r) - CIE_y_w*(CIE_x_b - CIE_x_r) - CIE_x_r*CIE_y_b + CIE_x_b*CIE_y_r) );
 static const float CIE_C_bD = ( (1/CIE_y_w) * ( CIE_x_w*(CIE_y_r - CIE_y_g) - CIE_y_w*(CIE_x_r - CIE_x_g) + CIE_x_r*CIE_y_g - CIE_x_g*CIE_y_r) );

 /**
 RGB to XYZ (no white balance)
 */
 static const float  RGB2XYZ[3][3] = {
 	{ CIE_x_r*CIE_C_rD / CIE_D,
 	  CIE_x_g*CIE_C_gD / CIE_D,
 	  CIE_x_b*CIE_C_bD / CIE_D
 	},
 	{ CIE_y_r*CIE_C_rD / CIE_D,
 	  CIE_y_g*CIE_C_gD / CIE_D,
 	  CIE_y_b*CIE_C_bD / CIE_D
 	},
 	{ (1 - CIE_x_r-CIE_y_r)*CIE_C_rD / CIE_D,
 	  (1 - CIE_x_g-CIE_y_g)*CIE_C_gD / CIE_D,
 	  (1 - CIE_x_b-CIE_y_b)*CIE_C_bD / CIE_D
 	}
 };

 /**
 XYZ to RGB (no white balance)
 */
 static const float  XYZ2RGB[3][3] = {
 	{(CIE_y_g - CIE_y_b - CIE_x_b*CIE_y_g + CIE_y_b*CIE_x_g) / CIE_C_rD,
 	 (CIE_x_b - CIE_x_g - CIE_x_b*CIE_y_g + CIE_x_g*CIE_y_b) / CIE_C_rD,
 	 (CIE_x_g*CIE_y_b - CIE_x_b*CIE_y_g) / CIE_C_rD
 	},
 	{(CIE_y_b - CIE_y_r - CIE_y_b*CIE_x_r + CIE_y_r*CIE_x_b) / CIE_C_gD,
 	 (CIE_x_r - CIE_x_b - CIE_x_r*CIE_y_b + CIE_x_b*CIE_y_r) / CIE_C_gD,
 	 (CIE_x_b*CIE_y_r - CIE_x_r*CIE_y_b) / CIE_C_gD
 	},
 	{(CIE_y_r - CIE_y_g - CIE_y_r*CIE_x_g + CIE_y_g*CIE_x_r) / CIE_C_bD,
 	 (CIE_x_g - CIE_x_r - CIE_x_g*CIE_y_r + CIE_x_r*CIE_y_g) / CIE_C_bD,
 	 (CIE_x_r*CIE_y_g - CIE_x_g*CIE_y_r) / CIE_C_bD
 	}
 };

 /**
 This gives approximately the following matrices :

 static const float RGB2XYZ[3][3] = {
 	{ 0.41239083F, 0.35758433F, 0.18048081F },
 	{ 0.21263903F, 0.71516865F, 0.072192319F },
 	{ 0.019330820F, 0.11919473F, 0.95053220F }
 };
 static const float XYZ2RGB[3][3] = {
 	{ 3.2409699F, -1.5373832F, -0.49861079F },
 	{ -0.96924376F, 1.8759676F, 0.041555084F },
 	{ 0.055630036F, -0.20397687F, 1.0569715F }
 };
 */

 // ----------------------------------------------------------

 static const float EPSILON = 1e-06F;
 static const float INF = 1e+10F;

 /**
 Convert in-place floating point RGB data to Yxy.<br>
 On output, pixel->red == Y, pixel->green == x, pixel->blue == y
 @param dib Input RGBF / Output Yxy image
 @return Returns TRUE if successful, returns FALSE otherwise
 */
 BOOL
 ConvertInPlaceRGBFToYxy(FIBITMAP *dib) {
 	float result[3];

 	if(FreeImage_GetImageType(dib) != FIT_RGBF)
 		return FALSE;

 	const unsigned width  = FreeImage_GetWidth(dib);
 	const unsigned height = FreeImage_GetHeight(dib);
 	const unsigned pitch  = FreeImage_GetPitch(dib);

 	BYTE *bits = (BYTE*)FreeImage_GetBits(dib);
 	for(unsigned y = 0; y < height; y++) {
 		FIRGBF *pixel = (FIRGBF*)bits;
 		for(unsigned x = 0; x < width; x++) {
 			result[0] = result[1] = result[2] = 0;
 			for (int i = 0; i < 3; i++) {
 				result[i] += RGB2XYZ[i][0] * pixel[x].red;
 				result[i] += RGB2XYZ[i][1] * pixel[x].green;
 				result[i] += RGB2XYZ[i][2] * pixel[x].blue;
 			}
 			const float W = result[0] + result[1] + result[2];
 			const float Y = result[1];
 			if(W > 0) {
 				pixel[x].red   = Y;			    // Y
 				pixel[x].green = result[0] / W;	// x
 				pixel[x].blue  = result[1] / W;	// y
 			} else {
 				pixel[x].red = pixel[x].green = pixel[x].blue = 0;
 			}
 		}
 		// next line
 		bits += pitch;
 	}

 	return TRUE;
 }

 /**
 Convert in-place Yxy image to floating point RGB data.<br>
 On input, pixel->red == Y, pixel->green == x, pixel->blue == y
 @param dib Input Yxy / Output RGBF image
 @return Returns TRUE if successful, returns FALSE otherwise
 */
 BOOL
 ConvertInPlaceYxyToRGBF(FIBITMAP *dib) {
 	float result[3];
 	float X, Y, Z;

 	if(FreeImage_GetImageType(dib) != FIT_RGBF)
 		return FALSE;

 	const unsigned width  = FreeImage_GetWidth(dib);
 	const unsigned height = FreeImage_GetHeight(dib);
 	const unsigned pitch  = FreeImage_GetPitch(dib);

 	BYTE *bits = (BYTE*)FreeImage_GetBits(dib);
 	for(unsigned y = 0; y < height; y++) {
 		FIRGBF *pixel = (FIRGBF*)bits;
 		for(unsigned x = 0; x < width; x++) {
 			Y = pixel[x].red;	        // Y
 			result[1] = pixel[x].green;	// x
 			result[2] = pixel[x].blue;	// y
 			if ((Y > EPSILON) && (result[1] > EPSILON) && (result[2] > EPSILON)) {
 				X = (result[1] * Y) / result[2];
 				Z = (X / result[1]) - X - Y;
 			} else {
 				X = Z = EPSILON;
 			}
 			pixel[x].red   = X;
 			pixel[x].green = Y;
 			pixel[x].blue  = Z;
 			result[0] = result[1] = result[2] = 0;
 			for (int i = 0; i < 3; i++) {
 				result[i] += XYZ2RGB[i][0] * pixel[x].red;
 				result[i] += XYZ2RGB[i][1] * pixel[x].green;
 				result[i] += XYZ2RGB[i][2] * pixel[x].blue;
 			}
 			pixel[x].red   = result[0];	// R
 			pixel[x].green = result[1];	// G
 			pixel[x].blue  = result[2];	// B
 		}
 		// next line
 		bits += pitch;
 	}

 	return TRUE;
 }

 /**
 Get the maximum, minimum and average luminance.<br>
 On input, pixel->red == Y, pixel->green == x, pixel->blue == y
 @param Yxy Source Yxy image to analyze
 @param maxLum Maximum luminance
 @param minLum Minimum luminance
 @param worldLum Average luminance (world adaptation luminance)
 @return Returns TRUE if successful, returns FALSE otherwise
 */
 BOOL
 LuminanceFromYxy(FIBITMAP *Yxy, float *maxLum, float *minLum, float *worldLum) {
 	if(FreeImage_GetImageType(Yxy) != FIT_RGBF)
 		return FALSE;

 	const unsigned width  = FreeImage_GetWidth(Yxy);
 	const unsigned height = FreeImage_GetHeight(Yxy);
 	const unsigned pitch  = FreeImage_GetPitch(Yxy);

 	float max_lum = 0, min_lum = 0;
 	double sum = 0;

 	BYTE *bits = (BYTE*)FreeImage_GetBits(Yxy);
 	for(unsigned y = 0; y < height; y++) {
 		const FIRGBF *pixel = (FIRGBF*)bits;
 		for(unsigned x = 0; x < width; x++) {
 			const float Y = MAX(0.0F, pixel[x].red);// avoid negative values
 			max_lum = (max_lum < Y) ? Y : max_lum;	// max Luminance in the scene
 			min_lum = (min_lum < Y) ? min_lum : Y;	// min Luminance in the scene
                         sum += std::log(
                             2.3e-5F + Y);  // contrast constant in Tumblin paper
                 }
                 // next line
                 bits += pitch;
 	}
 	// maximum luminance
 	*maxLum = max_lum;
 	// minimum luminance
 	*minLum = min_lum;
 	// average log luminance
 	double avgLogLum = (sum / (width * height));
 	// world adaptation luminance
 	*worldLum = (float)exp(avgLogLum);

 	return TRUE;
 }

 /**
 Clamp RGBF image highest values to display white,
 then convert to 24-bit RGB
 */
 FIBITMAP*
 ClampConvertRGBFTo24(FIBITMAP *src) {
 	if(FreeImage_GetImageType(src) != FIT_RGBF)
 		return FALSE;

 	const unsigned width  = FreeImage_GetWidth(src);
 	const unsigned height = FreeImage_GetHeight(src);

 	FIBITMAP *dst = FreeImage_Allocate(width, height, 24, FI_RGBA_RED_MASK, FI_RGBA_GREEN_MASK, FI_RGBA_BLUE_MASK);
 	if(!dst) return NULL;

 	const unsigned src_pitch  = FreeImage_GetPitch(src);
 	const unsigned dst_pitch  = FreeImage_GetPitch(dst);

 	BYTE *src_bits = (BYTE*)FreeImage_GetBits(src);
 	BYTE *dst_bits = (BYTE*)FreeImage_GetBits(dst);

 	for(unsigned y = 0; y < height; y++) {
 		const FIRGBF *src_pixel = (FIRGBF*)src_bits;
 		BYTE *dst_pixel = (BYTE*)dst_bits;
 		for(unsigned x = 0; x < width; x++) {
 			const float red   = (src_pixel[x].red > 1)   ? 1 : src_pixel[x].red;
 			const float green = (src_pixel[x].green > 1) ? 1 : src_pixel[x].green;
 			const float blue  = (src_pixel[x].blue > 1)  ? 1 : src_pixel[x].blue;

 			dst_pixel[FI_RGBA_RED]   = (BYTE)(255.0F * red   + 0.5F);
 			dst_pixel[FI_RGBA_GREEN] = (BYTE)(255.0F * green + 0.5F);
 			dst_pixel[FI_RGBA_BLUE]  = (BYTE)(255.0F * blue  + 0.5F);
 			dst_pixel += 3;
 		}
 		src_bits += src_pitch;
 		dst_bits += dst_pitch;
 	}

 	return dst;
 }

 /**
 Extract the luminance channel L from a RGBF image.
 Luminance is calculated from the sRGB model (RGB2XYZ matrix)
 using a D65 white point :
 L = ( 0.2126 * r ) + ( 0.7152 * g ) + ( 0.0722 * b )
 Reference :
 A Standard Default Color Space for the Internet - sRGB.
 [online] http://www.w3.org/Graphics/Color/sRGB
 */
 FIBITMAP*
 ConvertRGBFToY(FIBITMAP *src) {
 	if(FreeImage_GetImageType(src) != FIT_RGBF)
 		return FALSE;

 	const unsigned width  = FreeImage_GetWidth(src);
 	const unsigned height = FreeImage_GetHeight(src);

 	FIBITMAP *dst = FreeImage_AllocateT(FIT_FLOAT, width, height);
 	if(!dst) return NULL;

 	const unsigned src_pitch  = FreeImage_GetPitch(src);
 	const unsigned dst_pitch  = FreeImage_GetPitch(dst);


 	BYTE *src_bits = (BYTE*)FreeImage_GetBits(src);
 	BYTE *dst_bits = (BYTE*)FreeImage_GetBits(dst);

 	for(unsigned y = 0; y < height; y++) {
 		const FIRGBF *src_pixel = (FIRGBF*)src_bits;
 		float  *dst_pixel = (float*)dst_bits;
 		for(unsigned x = 0; x < width; x++) {
 			const float L = LUMA_REC709(src_pixel[x].red, src_pixel[x].green, src_pixel[x].blue);
 			dst_pixel[x] = (L > 0) ? L : 0;
 		}
 		// next line
 		src_bits += src_pitch;
 		dst_bits += dst_pitch;
 	}

 	return dst;
 }

 /**
 Get the maximum, minimum, average luminance and log average luminance from a Y image
 @param dib Source Y image to analyze
 @param maxLum Maximum luminance
 @param minLum Minimum luminance
 @param Lav Average luminance
 @param Llav Log average luminance (also known as 'world adaptation luminance')
 @return Returns TRUE if successful, returns FALSE otherwise
 @see ConvertRGBFToY, FreeImage_TmoReinhard05Ex
 */
 BOOL
 LuminanceFromY(FIBITMAP *dib, float *maxLum, float *minLum, float *Lav, float *Llav) {
 	if(FreeImage_GetImageType(dib) != FIT_FLOAT)
 		return FALSE;

 	unsigned width  = FreeImage_GetWidth(dib);
 	unsigned height = FreeImage_GetHeight(dib);
 	unsigned pitch  = FreeImage_GetPitch(dib);

 	float max_lum = -1e20F, min_lum = 1e20F;
 	double sumLum = 0, sumLogLum = 0;

 	BYTE *bits = (BYTE*)FreeImage_GetBits(dib);
 	for(unsigned y = 0; y < height; y++) {
 		const float *pixel = (float*)bits;
 		for(unsigned x = 0; x < width; x++) {
 			const float Y = pixel[x];
 			max_lum = (max_lum < Y) ? Y : max_lum;				// max Luminance in the scene
 			min_lum = ((Y > 0) && (min_lum < Y)) ? min_lum : Y;	// min Luminance in the scene
 			sumLum += Y;										// average luminance
                         sumLogLum += std::log(
                             2.3e-5F + Y);  // contrast constant in Tumblin paper
                 }
                 // next line
                 bits += pitch;
 	}

 	// maximum luminance
 	*maxLum = max_lum;
 	// minimum luminance
 	*minLum = min_lum;
 	// average luminance
 	*Lav = (float)(sumLum / (width * height));
 	// average log luminance, a.k.a. world adaptation luminance
 	*Llav = (float)exp(sumLogLum / (width * height));

 	return TRUE;
 }
 // --------------------------------------------------------------------------

 static void findMaxMinPercentile(FIBITMAP *Y, float minPrct, float *minLum, float maxPrct, float *maxLum) {
 	int x, y;
 	int width = FreeImage_GetWidth(Y);
 	int height = FreeImage_GetHeight(Y);
 	int pitch = FreeImage_GetPitch(Y);

 	std::vector<float> vY(width * height);

 	BYTE *bits = (BYTE*)FreeImage_GetBits(Y);
 	for(y = 0; y < height; y++) {
 		float *pixel = (float*)bits;
 		for(x = 0; x < width; x++) {
 			if(pixel[x] != 0) {
 				vY.push_back(pixel[x]);
 			}
 		}
 		bits += pitch;
 	}

 	std::sort(vY.begin(), vY.end());

 	*minLum = vY.at( int(minPrct * vY.size()) );
 	*maxLum = vY.at( int(maxPrct * vY.size()) );
 }

 /**
 Clipping function<br>
 Remove any extremely bright and/or extremely dark pixels
 and normalize between 0 and 1.
 @param Y Input/Output image
 @param minPrct Minimum percentile
 @param maxPrct Maximum percentile
 */
 void
 NormalizeY(FIBITMAP *Y, float minPrct, float maxPrct) {
 	int x, y;
 	float maxLum, minLum;

 	if(minPrct > maxPrct) {
 		// swap values
 		float t = minPrct; minPrct = maxPrct; maxPrct = t;
 	}
 	if(minPrct < 0) minPrct = 0;
 	if(maxPrct > 1) maxPrct = 1;

 	int width = FreeImage_GetWidth(Y);
 	int height = FreeImage_GetHeight(Y);
 	int pitch = FreeImage_GetPitch(Y);

 	// find max & min luminance values
 	if((minPrct > 0) || (maxPrct < 1)) {
 		maxLum = 0, minLum = 0;
 		findMaxMinPercentile(Y, minPrct, &minLum, maxPrct, &maxLum);
 	} else {
 		maxLum = -1e20F, minLum = 1e20F;
 		BYTE *bits = (BYTE*)FreeImage_GetBits(Y);
 		for(y = 0; y < height; y++) {
 			const float *pixel = (float*)bits;
 			for(x = 0; x < width; x++) {
 				const float value = pixel[x];
 				maxLum = (maxLum < value) ? value : maxLum;	// max Luminance in the scene
 				minLum = (minLum < value) ? minLum : value;	// min Luminance in the scene
 			}
 			// next line
 			bits += pitch;
 		}
 	}
 	if(maxLum == minLum) return;

 	// normalize to range 0..1
 	const float divider = maxLum - minLum;
 	BYTE *bits = (BYTE*)FreeImage_GetBits(Y);
 	for(y = 0; y < height; y++) {
 		float *pixel = (float*)bits;
 		for(x = 0; x < width; x++) {
 			pixel[x] = (pixel[x] - minLum) / divider;
 			if(pixel[x] <= 0) pixel[x] = EPSILON;
 			if(pixel[x] > 1) pixel[x] = 1;
 		}
 		// next line
 		bits += pitch;
 	}
 }
	// ==========================================================
	// High Dynamic Range bitmap conversion routines
	//
	// Design and implementation by
	// - Hervé Drolon (drolon@infonie.fr)
	// - Mihail Naydenov (mnaydenov@users.sourceforge.net)
	//
	// This file is part of FreeImage 3
	//
	// COVERED CODE IS PROVIDED UNDER THIS LICENSE ON AN "AS IS" BASIS, WITHOUT WARRANTY
	// OF ANY KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING, WITHOUT LIMITATION, WARRANTIES
	// THAT THE COVERED CODE IS FREE OF DEFECTS, MERCHANTABLE, FIT FOR A PARTICULAR PURPOSE
	// OR NON-INFRINGING. THE ENTIRE RISK AS TO THE QUALITY AND PERFORMANCE OF THE COVERED
	// CODE IS WITH YOU. SHOULD ANY COVERED CODE PROVE DEFECTIVE IN ANY RESPECT, YOU (NOT
	// THE INITIAL DEVELOPER OR ANY OTHER CONTRIBUTOR) ASSUME THE COST OF ANY NECESSARY
	// SERVICING, REPAIR OR CORRECTION. THIS DISCLAIMER OF WARRANTY CONSTITUTES AN ESSENTIAL
	// PART OF THIS LICENSE. NO USE OF ANY COVERED CODE IS AUTHORIZED HEREUNDER EXCEPT UNDER
	// THIS DISCLAIMER.
	//
	// Use at your own risk!
	// ==========================================================

	#include <cmath>

	#include "FreeImage.h"
	#include "Utilities.h"
	#include "ToneMapping.h"

	// ----------------------------------------------------------
	// Convert RGB to and from Yxy, same as in Reinhard et al. SIGGRAPH 2002
	// References :
	// [1] Radiance Home Page [Online] http://radsite.lbl.gov/radiance/HOME.html
	// [2] E. Reinhard, M. Stark, P. Shirley, and J. Ferwerda,
	// Photographic Tone Reproduction for Digital Images, ACM Transactions on Graphics,
	// 21(3):267-276, 2002 (Proceedings of SIGGRAPH 2002).
	// [3] J. Tumblin and H.E. Rushmeier,
	// Tone Reproduction for Realistic Images. IEEE Computer Graphics and Applications,
	// 13(6):42-48, 1993.
	// ----------------------------------------------------------

	/**
	nominal CRT primaries
	*/
	/*
	static const float CIE_x_r = 0.640F;
	static const float CIE_y_r = 0.330F;
	static const float CIE_x_g = 0.290F;
	static const float CIE_y_g = 0.600F;
	static const float CIE_x_b = 0.150F;
	static const float CIE_y_b = 0.060F;
	static const float CIE_x_w = 0.3333F; // use true white
	static const float CIE_y_w = 0.3333F;
	*/
	/**
	sRGB primaries
	*/
	static const float CIE_x_r = 0.640F;
	static const float CIE_y_r = 0.330F;
	static const float CIE_x_g = 0.300F;
	static const float CIE_y_g = 0.600F;
	static const float CIE_x_b = 0.150F;
	static const float CIE_y_b = 0.060F;
	static const float CIE_x_w = 0.3127F; // Illuminant D65
	static const float CIE_y_w = 0.3290F;

	static const float CIE_D = ( CIE_x_r(CIE_y_g - CIE_y_b) + CIE_x_g(CIE_y_b - CIE_y_r) + CIE_x_b*(CIE_y_r - CIE_y_g) );
	static const float CIE_C_rD = ( (1/CIE_y_w) * ( CIE_x_w(CIE_y_g - CIE_y_b) - CIE_y_w(CIE_x_g - CIE_x_b) + CIE_x_gCIE_y_b - CIE_x_bCIE_y_g) );
	static const float CIE_C_gD = ( (1/CIE_y_w) * ( CIE_x_w(CIE_y_b - CIE_y_r) - CIE_y_w(CIE_x_b - CIE_x_r) - CIE_x_rCIE_y_b + CIE_x_bCIE_y_r) );
	static const float CIE_C_bD = ( (1/CIE_y_w) * ( CIE_x_w(CIE_y_r - CIE_y_g) - CIE_y_w(CIE_x_r - CIE_x_g) + CIE_x_rCIE_y_g - CIE_x_gCIE_y_r) );

	/**
	RGB to XYZ (no white balance)
	*/
	static const float RGB2XYZ[3][3] = {
	{ CIE_x_r*CIE_C_rD / CIE_D,
	CIE_x_g*CIE_C_gD / CIE_D,
	CIE_x_b*CIE_C_bD / CIE_D
	},
	{ CIE_y_r*CIE_C_rD / CIE_D,
	CIE_y_g*CIE_C_gD / CIE_D,
	CIE_y_b*CIE_C_bD / CIE_D
	},
	{ (1 - CIE_x_r-CIE_y_r)*CIE_C_rD / CIE_D,
	(1 - CIE_x_g-CIE_y_g)*CIE_C_gD / CIE_D,
	(1 - CIE_x_b-CIE_y_b)*CIE_C_bD / CIE_D
	}
	};

	/**
	XYZ to RGB (no white balance)
	*/
	static const float XYZ2RGB[3][3] = {
	{(CIE_y_g - CIE_y_b - CIE_x_bCIE_y_g + CIE_y_bCIE_x_g) / CIE_C_rD,
	(CIE_x_b - CIE_x_g - CIE_x_bCIE_y_g + CIE_x_gCIE_y_b) / CIE_C_rD,
	(CIE_x_gCIE_y_b - CIE_x_bCIE_y_g) / CIE_C_rD
	},
	{(CIE_y_b - CIE_y_r - CIE_y_bCIE_x_r + CIE_y_rCIE_x_b) / CIE_C_gD,
	(CIE_x_r - CIE_x_b - CIE_x_rCIE_y_b + CIE_x_bCIE_y_r) / CIE_C_gD,
	(CIE_x_bCIE_y_r - CIE_x_rCIE_y_b) / CIE_C_gD
	},
	{(CIE_y_r - CIE_y_g - CIE_y_rCIE_x_g + CIE_y_gCIE_x_r) / CIE_C_bD,
	(CIE_x_g - CIE_x_r - CIE_x_gCIE_y_r + CIE_x_rCIE_y_g) / CIE_C_bD,
	(CIE_x_rCIE_y_g - CIE_x_gCIE_y_r) / CIE_C_bD
	}
	};

	/**
	This gives approximately the following matrices :

	static const float RGB2XYZ[3][3] = {
	{ 0.41239083F, 0.35758433F, 0.18048081F },
	{ 0.21263903F, 0.71516865F, 0.072192319F },
	{ 0.019330820F, 0.11919473F, 0.95053220F }
	};
	static const float XYZ2RGB[3][3] = {
	{ 3.2409699F, -1.5373832F, -0.49861079F },
	{ -0.96924376F, 1.8759676F, 0.041555084F },
	{ 0.055630036F, -0.20397687F, 1.0569715F }
	};
	*/

	// ----------------------------------------------------------

	static const float EPSILON = 1e-06F;
	static const float INF = 1e+10F;

	/**
	Convert in-place floating point RGB data to Yxy.<br>
	On output, pixel->red == Y, pixel->green == x, pixel->blue == y
	@param dib Input RGBF / Output Yxy image
	@return Returns TRUE if successful, returns FALSE otherwise
	*/
	BOOL
	ConvertInPlaceRGBFToYxy(FIBITMAP *dib) {
	float result[3];

	if(FreeImage_GetImageType(dib) != FIT_RGBF)
	return FALSE;

	const unsigned width = FreeImage_GetWidth(dib);
	const unsigned height = FreeImage_GetHeight(dib);
	const unsigned pitch = FreeImage_GetPitch(dib);

	BYTE bits = (BYTE)FreeImage_GetBits(dib);
	for(unsigned y = 0; y < height; y++) {
	FIRGBF pixel = (FIRGBF)bits;
	for(unsigned x = 0; x < width; x++) {
	result[0] = result[1] = result[2] = 0;
	for (int i = 0; i < 3; i++) {
	result[i] += RGB2XYZ[i][0] * pixel[x].red;
	result[i] += RGB2XYZ[i][1] * pixel[x].green;
	result[i] += RGB2XYZ[i][2] * pixel[x].blue;
	}
	const float W = result[0] + result[1] + result[2];
	const float Y = result[1];
	if(W > 0) {
	pixel[x].red = Y; // Y
	pixel[x].green = result[0] / W; // x
	pixel[x].blue = result[1] / W; // y
	} else {
	pixel[x].red = pixel[x].green = pixel[x].blue = 0;
	}
	}
	// next line
	bits += pitch;
	}

	return TRUE;
	}

	/**
	Convert in-place Yxy image to floating point RGB data.<br>
	On input, pixel->red == Y, pixel->green == x, pixel->blue == y
	@param dib Input Yxy / Output RGBF image
	@return Returns TRUE if successful, returns FALSE otherwise
	*/
	BOOL
	ConvertInPlaceYxyToRGBF(FIBITMAP *dib) {
	float result[3];
	float X, Y, Z;

	if(FreeImage_GetImageType(dib) != FIT_RGBF)
	return FALSE;

	const unsigned width = FreeImage_GetWidth(dib);
	const unsigned height = FreeImage_GetHeight(dib);
	const unsigned pitch = FreeImage_GetPitch(dib);

	BYTE bits = (BYTE)FreeImage_GetBits(dib);
	for(unsigned y = 0; y < height; y++) {
	FIRGBF pixel = (FIRGBF)bits;
	for(unsigned x = 0; x < width; x++) {
	Y = pixel[x].red; // Y
	result[1] = pixel[x].green; // x
	result[2] = pixel[x].blue; // y
	if ((Y > EPSILON) && (result[1] > EPSILON) && (result[2] > EPSILON)) {
	X = (result[1] * Y) / result[2];
	Z = (X / result[1]) - X - Y;
	} else {
	X = Z = EPSILON;
	}
	pixel[x].red = X;
	pixel[x].green = Y;
	pixel[x].blue = Z;
	result[0] = result[1] = result[2] = 0;
	for (int i = 0; i < 3; i++) {
	result[i] += XYZ2RGB[i][0] * pixel[x].red;
	result[i] += XYZ2RGB[i][1] * pixel[x].green;
	result[i] += XYZ2RGB[i][2] * pixel[x].blue;
	}
	pixel[x].red = result[0]; // R
	pixel[x].green = result[1]; // G
	pixel[x].blue = result[2]; // B
	}
	// next line
	bits += pitch;
	}

	return TRUE;
	}

	/**
	Get the maximum, minimum and average luminance.<br>
	On input, pixel->red == Y, pixel->green == x, pixel->blue == y
	@param Yxy Source Yxy image to analyze
	@param maxLum Maximum luminance
	@param minLum Minimum luminance
	@param worldLum Average luminance (world adaptation luminance)
	@return Returns TRUE if successful, returns FALSE otherwise
	*/
	BOOL
	LuminanceFromYxy(FIBITMAP Yxy, float maxLum, float minLum, float worldLum) {
	if(FreeImage_GetImageType(Yxy) != FIT_RGBF)
	return FALSE;

	const unsigned width = FreeImage_GetWidth(Yxy);
	const unsigned height = FreeImage_GetHeight(Yxy);
	const unsigned pitch = FreeImage_GetPitch(Yxy);

	float max_lum = 0, min_lum = 0;
	double sum = 0;

	BYTE bits = (BYTE)FreeImage_GetBits(Yxy);
	for(unsigned y = 0; y < height; y++) {
	const FIRGBF pixel = (FIRGBF)bits;
	for(unsigned x = 0; x < width; x++) {
	const float Y = MAX(0.0F, pixel[x].red);// avoid negative values
	max_lum = (max_lum < Y) ? Y : max_lum; // max Luminance in the scene
	min_lum = (min_lum < Y) ? min_lum : Y; // min Luminance in the scene
	sum += std::log(
	2.3e-5F + Y); // contrast constant in Tumblin paper
	}
	// next line
	bits += pitch;
	}
	// maximum luminance
	*maxLum = max_lum;
	// minimum luminance
	*minLum = min_lum;
	// average log luminance
	double avgLogLum = (sum / (width * height));
	// world adaptation luminance
	*worldLum = (float)exp(avgLogLum);

	return TRUE;
	}

	/**
	Clamp RGBF image highest values to display white,
	then convert to 24-bit RGB
	*/
	FIBITMAP*
	ClampConvertRGBFTo24(FIBITMAP *src) {
	if(FreeImage_GetImageType(src) != FIT_RGBF)
	return FALSE;

	const unsigned width = FreeImage_GetWidth(src);
	const unsigned height = FreeImage_GetHeight(src);

	FIBITMAP *dst = FreeImage_Allocate(width, height, 24, FI_RGBA_RED_MASK, FI_RGBA_GREEN_MASK, FI_RGBA_BLUE_MASK);
	if(!dst) return NULL;

	const unsigned src_pitch = FreeImage_GetPitch(src);
	const unsigned dst_pitch = FreeImage_GetPitch(dst);

	BYTE src_bits = (BYTE)FreeImage_GetBits(src);
	BYTE dst_bits = (BYTE)FreeImage_GetBits(dst);

	for(unsigned y = 0; y < height; y++) {
	const FIRGBF src_pixel = (FIRGBF)src_bits;
	BYTE dst_pixel = (BYTE)dst_bits;
	for(unsigned x = 0; x < width; x++) {
	const float red = (src_pixel[x].red > 1) ? 1 : src_pixel[x].red;
	const float green = (src_pixel[x].green > 1) ? 1 : src_pixel[x].green;
	const float blue = (src_pixel[x].blue > 1) ? 1 : src_pixel[x].blue;

	dst_pixel[FI_RGBA_RED] = (BYTE)(255.0F * red + 0.5F);
	dst_pixel[FI_RGBA_GREEN] = (BYTE)(255.0F * green + 0.5F);
	dst_pixel[FI_RGBA_BLUE] = (BYTE)(255.0F * blue + 0.5F);
	dst_pixel += 3;
	}
	src_bits += src_pitch;
	dst_bits += dst_pitch;
	}

	return dst;
	}

	/**
	Extract the luminance channel L from a RGBF image.
	Luminance is calculated from the sRGB model (RGB2XYZ matrix)
	using a D65 white point :
	L = ( 0.2126 * r ) + ( 0.7152 * g ) + ( 0.0722 * b )
	Reference :
	A Standard Default Color Space for the Internet - sRGB.
	[online] http://www.w3.org/Graphics/Color/sRGB
	*/
	FIBITMAP*
	ConvertRGBFToY(FIBITMAP *src) {
	if(FreeImage_GetImageType(src) != FIT_RGBF)
	return FALSE;

	const unsigned width = FreeImage_GetWidth(src);
	const unsigned height = FreeImage_GetHeight(src);

	FIBITMAP *dst = FreeImage_AllocateT(FIT_FLOAT, width, height);
	if(!dst) return NULL;

	const unsigned src_pitch = FreeImage_GetPitch(src);
	const unsigned dst_pitch = FreeImage_GetPitch(dst);


	BYTE src_bits = (BYTE)FreeImage_GetBits(src);
	BYTE dst_bits = (BYTE)FreeImage_GetBits(dst);

	for(unsigned y = 0; y < height; y++) {
	const FIRGBF src_pixel = (FIRGBF)src_bits;
	float dst_pixel = (float)dst_bits;
	for(unsigned x = 0; x < width; x++) {
	const float L = LUMA_REC709(src_pixel[x].red, src_pixel[x].green, src_pixel[x].blue);
	dst_pixel[x] = (L > 0) ? L : 0;
	}
	// next line
	src_bits += src_pitch;
	dst_bits += dst_pitch;
	}

	return dst;
	}

	/**
	Get the maximum, minimum, average luminance and log average luminance from a Y image
	@param dib Source Y image to analyze
	@param maxLum Maximum luminance
	@param minLum Minimum luminance
	@param Lav Average luminance
	@param Llav Log average luminance (also known as 'world adaptation luminance')
	@return Returns TRUE if successful, returns FALSE otherwise
	@see ConvertRGBFToY, FreeImage_TmoReinhard05Ex
	*/
	BOOL
	LuminanceFromY(FIBITMAP dib, float maxLum, float minLum, float Lav, float *Llav) {
	if(FreeImage_GetImageType(dib) != FIT_FLOAT)
	return FALSE;

	unsigned width = FreeImage_GetWidth(dib);
	unsigned height = FreeImage_GetHeight(dib);
	unsigned pitch = FreeImage_GetPitch(dib);

	float max_lum = -1e20F, min_lum = 1e20F;
	double sumLum = 0, sumLogLum = 0;

	BYTE bits = (BYTE)FreeImage_GetBits(dib);
	for(unsigned y = 0; y < height; y++) {
	const float pixel = (float)bits;
	for(unsigned x = 0; x < width; x++) {
	const float Y = pixel[x];
	max_lum = (max_lum < Y) ? Y : max_lum; // max Luminance in the scene
	min_lum = ((Y > 0) && (min_lum < Y)) ? min_lum : Y; // min Luminance in the scene
	sumLum += Y; // average luminance
	sumLogLum += std::log(
	2.3e-5F + Y); // contrast constant in Tumblin paper
	}
	// next line
	bits += pitch;
	}

	// maximum luminance
	*maxLum = max_lum;
	// minimum luminance
	*minLum = min_lum;
	// average luminance
	Lav = (float)(sumLum / (width height));
	// average log luminance, a.k.a. world adaptation luminance
	Llav = (float)exp(sumLogLum / (width height));

	return TRUE;
	}
	// --------------------------------------------------------------------------

	static void findMaxMinPercentile(FIBITMAP Y, float minPrct, float minLum, float maxPrct, float *maxLum) {
	int x, y;
	int width = FreeImage_GetWidth(Y);
	int height = FreeImage_GetHeight(Y);
	int pitch = FreeImage_GetPitch(Y);

	std::vector<float> vY(width * height);

	BYTE bits = (BYTE)FreeImage_GetBits(Y);
	for(y = 0; y < height; y++) {
	float pixel = (float)bits;
	for(x = 0; x < width; x++) {
	if(pixel[x] != 0) {
	vY.push_back(pixel[x]);
	}
	}
	bits += pitch;
	}

	std::sort(vY.begin(), vY.end());

	minLum = vY.at( int(minPrct vY.size()) );
	maxLum = vY.at( int(maxPrct vY.size()) );
	}

	/**
	Clipping function<br>
	Remove any extremely bright and/or extremely dark pixels
	and normalize between 0 and 1.
	@param Y Input/Output image
	@param minPrct Minimum percentile
	@param maxPrct Maximum percentile
	*/
	void
	NormalizeY(FIBITMAP *Y, float minPrct, float maxPrct) {
	int x, y;
	float maxLum, minLum;

	if(minPrct > maxPrct) {
	// swap values
	float t = minPrct; minPrct = maxPrct; maxPrct = t;
	}
	if(minPrct < 0) minPrct = 0;
	if(maxPrct > 1) maxPrct = 1;

	int width = FreeImage_GetWidth(Y);
	int height = FreeImage_GetHeight(Y);
	int pitch = FreeImage_GetPitch(Y);

	// find max & min luminance values
	if((minPrct > 0) \|\| (maxPrct < 1)) {
	maxLum = 0, minLum = 0;
	findMaxMinPercentile(Y, minPrct, &minLum, maxPrct, &maxLum);
	} else {
	maxLum = -1e20F, minLum = 1e20F;
	BYTE bits = (BYTE)FreeImage_GetBits(Y);
	for(y = 0; y < height; y++) {
	const float pixel = (float)bits;
	for(x = 0; x < width; x++) {
	const float value = pixel[x];
	maxLum = (maxLum < value) ? value : maxLum; // max Luminance in the scene
	minLum = (minLum < value) ? minLum : value; // min Luminance in the scene
	}
	// next line
	bits += pitch;
	}
	}
	if(maxLum == minLum) return;

	// normalize to range 0..1
	const float divider = maxLum - minLum;
	BYTE bits = (BYTE)FreeImage_GetBits(Y);
	for(y = 0; y < height; y++) {
	float pixel = (float)bits;
	for(x = 0; x < width; x++) {
	pixel[x] = (pixel[x] - minLum) / divider;
	if(pixel[x] <= 0) pixel[x] = EPSILON;
	if(pixel[x] > 1) pixel[x] = 1;
	}
	// next line
	bits += pitch;
	}
	}