framework/common/tcuFuzzyImageCompare.cpp - third_party/vulkan-cts - Git at Google

 /*-------------------------------------------------------------------------
  * drawElements Quality Program Tester Core
  * ----------------------------------------
  *
  * Copyright 2014 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  *
  *//*!
  * \file
  * \brief Fuzzy image comparison.
  *//*--------------------------------------------------------------------*/

 #include "tcuFuzzyImageCompare.hpp"
 #include "tcuTexture.hpp"
 #include "tcuTextureUtil.hpp"
 #include "deMath.h"
 #include "deRandom.hpp"

 #include <vector>

 namespace tcu
 {

 enum
 {
 	MIN_ERR_THRESHOLD	= 4 // Magic to make small differences go away
 };

 using std::vector;

 template<int Channel>
 static inline deUint8 getChannel (deUint32 color)
 {
 	return (deUint8)((color >> (Channel*8)) & 0xff);
 }

 static inline deUint8 getChannel (deUint32 color, int channel)
 {
 	return (deUint8)((color >> (channel*8)) & 0xff);
 }

 static inline deUint32 setChannel (deUint32 color, int channel, deUint8 val)
 {
 	return (color & ~(0xffu << (8*channel))) | (val << (8*channel));
 }

 static inline Vec4 toFloatVec (deUint32 color)
 {
 	return Vec4((float)getChannel<0>(color), (float)getChannel<1>(color), (float)getChannel<2>(color), (float)getChannel<3>(color));
 }

 static inline deUint8 roundToUint8Sat (float v)
 {
 	return (deUint8)de::clamp((int)(v + 0.5f), 0, 255);
 }

 static inline deUint32 toColor (Vec4 v)
 {
 	return roundToUint8Sat(v[0]) | (roundToUint8Sat(v[1]) << 8) | (roundToUint8Sat(v[2]) << 16) | (roundToUint8Sat(v[3]) << 24);
 }

 template<int NumChannels>
 static inline deUint32 readUnorm8 (const tcu::ConstPixelBufferAccess& src, int x, int y)
 {
 	const deUint8*	ptr	= (const deUint8*)src.getDataPtr() + src.getRowPitch()*y + x*NumChannels;
 	deUint32		v	= 0;

 	for (int c = 0; c < NumChannels; c++)
 		v |= ptr[c] << (c*8);

 	if (NumChannels < 4)
 		v |= 0xffu << 24;

 	return v;
 }

 #if (DE_ENDIANNESS == DE_LITTLE_ENDIAN)
 template<>
 inline deUint32 readUnorm8<4> (const tcu::ConstPixelBufferAccess& src, int x, int y)
 {
 	return *(const deUint32*)((const deUint8*)src.getDataPtr() + src.getRowPitch()*y + x*4);
 }
 #endif

 template<int NumChannels>
 static inline void writeUnorm8 (const tcu::PixelBufferAccess& dst, int x, int y, deUint32 val)
 {
 	deUint8* ptr = (deUint8*)dst.getDataPtr() + dst.getRowPitch()*y + x*NumChannels;

 	for (int c = 0; c < NumChannels; c++)
 		ptr[c] = getChannel(val, c);
 }

 #if (DE_ENDIANNESS == DE_LITTLE_ENDIAN)
 template<>
 inline void writeUnorm8<4> (const tcu::PixelBufferAccess& dst, int x, int y, deUint32 val)
 {
 	*(deUint32*)((deUint8*)dst.getDataPtr() + dst.getRowPitch()*y + x*4) = val;
 }
 #endif

 static inline deUint32 colorDistSquared (deUint32 pa, deUint32 pb)
 {
 	const int	r	= de::max<int>(de::abs((int)getChannel<0>(pa) - (int)getChannel<0>(pb)) - MIN_ERR_THRESHOLD, 0);
 	const int	g	= de::max<int>(de::abs((int)getChannel<1>(pa) - (int)getChannel<1>(pb)) - MIN_ERR_THRESHOLD, 0);
 	const int	b	= de::max<int>(de::abs((int)getChannel<2>(pa) - (int)getChannel<2>(pb)) - MIN_ERR_THRESHOLD, 0);
 	const int	a	= de::max<int>(de::abs((int)getChannel<3>(pa) - (int)getChannel<3>(pb)) - MIN_ERR_THRESHOLD, 0);

 	return deUint32(r*r + g*g + b*b + a*a);
 }

 template<int NumChannels>
 inline deUint32 bilinearSample (const ConstPixelBufferAccess& src, float u, float v)
 {
 	int w = src.getWidth();
 	int h = src.getHeight();

 	int x0 = deFloorFloatToInt32(u-0.5f);
 	int x1 = x0+1;
 	int y0 = deFloorFloatToInt32(v-0.5f);
 	int y1 = y0+1;

 	int i0 = de::clamp(x0, 0, w-1);
 	int i1 = de::clamp(x1, 0, w-1);
 	int j0 = de::clamp(y0, 0, h-1);
 	int j1 = de::clamp(y1, 0, h-1);

 	float a = deFloatFrac(u-0.5f);
 	float b = deFloatFrac(v-0.5f);

 	deUint32 p00	= readUnorm8<NumChannels>(src, i0, j0);
 	deUint32 p10	= readUnorm8<NumChannels>(src, i1, j0);
 	deUint32 p01	= readUnorm8<NumChannels>(src, i0, j1);
 	deUint32 p11	= readUnorm8<NumChannels>(src, i1, j1);
 	deUint32 dst	= 0;

 	// Interpolate.
 	for (int c = 0; c < NumChannels; c++)
 	{
 		float f = (getChannel(p00, c)*(1.0f-a)*(1.0f-b)) +
 				  (getChannel(p10, c)*(     a)*(1.0f-b)) +
 				  (getChannel(p01, c)*(1.0f-a)*(     b)) +
 				  (getChannel(p11, c)*(     a)*(     b));
 		dst = setChannel(dst, c, roundToUint8Sat(f));
 	}

 	return dst;
 }

 template<int DstChannels, int SrcChannels>
 static void separableConvolve (const PixelBufferAccess& dst, const ConstPixelBufferAccess& src, int shiftX, int shiftY, const std::vector<float>& kernelX, const std::vector<float>& kernelY)
 {
 	DE_ASSERT(dst.getWidth() == src.getWidth() && dst.getHeight() == src.getHeight());

 	TextureLevel		tmp			(dst.getFormat(), dst.getHeight(), dst.getWidth());
 	PixelBufferAccess	tmpAccess	= tmp.getAccess();

 	int kw = (int)kernelX.size();
 	int kh = (int)kernelY.size();

 	// Horizontal pass
 	// \note Temporary surface is written in column-wise order
 	for (int j = 0; j < src.getHeight(); j++)
 	{
 		for (int i = 0; i < src.getWidth(); i++)
 		{
 			Vec4 sum(0);

 			for (int kx = 0; kx < kw; kx++)
 			{
 				float		f = kernelX[kw-kx-1];
 				deUint32	p = readUnorm8<SrcChannels>(src, de::clamp(i+kx-shiftX, 0, src.getWidth()-1), j);

 				sum += toFloatVec(p)*f;
 			}

 			writeUnorm8<DstChannels>(tmpAccess, j, i, toColor(sum));
 		}
 	}

 	// Vertical pass
 	for (int j = 0; j < src.getHeight(); j++)
 	{
 		for (int i = 0; i < src.getWidth(); i++)
 		{
 			Vec4 sum(0.0f);

 			for (int ky = 0; ky < kh; ky++)
 			{
 				float		f = kernelY[kh-ky-1];
 				deUint32	p = readUnorm8<DstChannels>(tmpAccess, de::clamp(j+ky-shiftY, 0, tmp.getWidth()-1), i);

 				sum += toFloatVec(p)*f;
 			}

 			writeUnorm8<DstChannels>(dst, i, j, toColor(sum));
 		}
 	}
 }

 template<int NumChannels>
 static deUint32 distSquaredToNeighbor (de::Random& rnd, deUint32 pixel, const ConstPixelBufferAccess& surface, int x, int y)
 {
 	// (x, y) + (0, 0)
 	deUint32	minDist		= colorDistSquared(pixel, readUnorm8<NumChannels>(surface, x, y));

 	if (minDist == 0)
 		return minDist;

 	// Area around (x, y)
 	static const int s_coords[][2] =
 	{
 		{-1, -1},
 		{ 0, -1},
 		{+1, -1},
 		{-1,  0},
 		{+1,  0},
 		{-1, +1},
 		{ 0, +1},
 		{+1, +1}
 	};

 	for (int d = 0; d < (int)DE_LENGTH_OF_ARRAY(s_coords); d++)
 	{
 		int dx = x + s_coords[d][0];
 		int dy = y + s_coords[d][1];

 		if (!deInBounds32(dx, 0, surface.getWidth()) || !deInBounds32(dy, 0, surface.getHeight()))
 			continue;

 		minDist = de::min(minDist, colorDistSquared(pixel, readUnorm8<NumChannels>(surface, dx, dy)));
 		if (minDist == 0)
 			return minDist;
 	}

 	// Random bilinear-interpolated samples around (x, y)
 	for (int s = 0; s < 32; s++)
 	{
 		float dx = (float)x + rnd.getFloat()*2.0f - 0.5f;
 		float dy = (float)y + rnd.getFloat()*2.0f - 0.5f;

 		deUint32 sample = bilinearSample<NumChannels>(surface, dx, dy);

 		minDist = de::min(minDist, colorDistSquared(pixel, sample));
 		if (minDist == 0)
 			return minDist;
 	}

 	return minDist;
 }

 static inline float toGrayscale (const Vec4& c)
 {
 	return 0.2126f*c[0] + 0.7152f*c[1] + 0.0722f*c[2];
 }

 static bool isFormatSupported (const TextureFormat& format)
 {
 	return format.type == TextureFormat::UNORM_INT8 && (format.order == TextureFormat::RGB || format.order == TextureFormat::RGBA);
 }

 float fuzzyCompare (const FuzzyCompareParams& params, const ConstPixelBufferAccess& ref, const ConstPixelBufferAccess& cmp, const PixelBufferAccess& errorMask)
 {
 	DE_ASSERT(ref.getWidth() == cmp.getWidth() && ref.getHeight() == cmp.getHeight());
 	DE_ASSERT(errorMask.getWidth() == ref.getWidth() && errorMask.getHeight() == ref.getHeight());

 	if (!isFormatSupported(ref.getFormat()) || !isFormatSupported(cmp.getFormat()))
 		throw InternalError("Unsupported format in fuzzy comparison", DE_NULL, __FILE__, __LINE__);

 	int			width	= ref.getWidth();
 	int			height	= ref.getHeight();
 	de::Random	rnd		(667);

 	// Filtered
 	TextureLevel refFiltered(TextureFormat(TextureFormat::RGBA, TextureFormat::UNORM_INT8), width, height);
 	TextureLevel cmpFiltered(TextureFormat(TextureFormat::RGBA, TextureFormat::UNORM_INT8), width, height);

 	// Kernel = {0.1, 0.8, 0.1}
 	vector<float> kernel(3);
 	kernel[0] = kernel[2] = 0.1f; kernel[1]= 0.8f;
 	int shift = (int)(kernel.size() - 1) / 2;

 	switch (ref.getFormat().order)
 	{
 		case TextureFormat::RGBA:	separableConvolve<4, 4>(refFiltered, ref, shift, shift, kernel, kernel);	break;
 		case TextureFormat::RGB:	separableConvolve<4, 3>(refFiltered, ref, shift, shift, kernel, kernel);	break;
 		default:
 			DE_ASSERT(DE_FALSE);
 	}

 	switch (cmp.getFormat().order)
 	{
 		case TextureFormat::RGBA:	separableConvolve<4, 4>(cmpFiltered, cmp, shift, shift, kernel, kernel);	break;
 		case TextureFormat::RGB:	separableConvolve<4, 3>(cmpFiltered, cmp, shift, shift, kernel, kernel);	break;
 		default:
 			DE_ASSERT(DE_FALSE);
 	}

 	int			numSamples	= 0;
 	deUint64	distSum4	= 0ull;

 	// Clear error mask to green.
 	clear(errorMask, Vec4(0.0f, 1.0f, 0.0f, 1.0f));

 	ConstPixelBufferAccess refAccess = refFiltered.getAccess();
 	ConstPixelBufferAccess cmpAccess = cmpFiltered.getAccess();

 	for (int y = 1; y < height-1; y++)
 	{
 		for (int x = 1; x < width-1; x += params.maxSampleSkip > 0 ? (int)rnd.getInt(1, params.maxSampleSkip) : 1)
 		{
 			const deUint32	minDist2RefToCmp	= distSquaredToNeighbor<4>(rnd, readUnorm8<4>(refAccess, x, y), cmpAccess, x, y);
 			const deUint32	minDist2CmpToRef	= distSquaredToNeighbor<4>(rnd, readUnorm8<4>(cmpAccess, x, y), refAccess, x, y);
 			const deUint32	minDist2			= de::min(minDist2RefToCmp, minDist2CmpToRef);
 			const deUint64	newSum4				= distSum4 + minDist2*minDist2;

 			distSum4	 = (newSum4 >= distSum4) ? newSum4 : ~0ull; // In case of overflow
 			numSamples	+= 1;

 			// Build error image.
 			{
 				const int	scale	= 255-MIN_ERR_THRESHOLD;
 				const float	err2	= float(minDist2) / float(scale*scale);
 				const float	err4	= err2*err2;
 				const float	red		= err4 * 500.0f;
 				const float	luma	= toGrayscale(cmp.getPixel(x, y));
 				const float	rF		= 0.7f + 0.3f*luma;

 				errorMask.setPixel(Vec4(red*rF, (1.0f-red)*rF, 0.0f, 1.0f), x, y);
 			}
 		}
 	}

 	{
 		// Scale error sum based on number of samples taken
 		const double	pSamples	= double((width-2) * (height-2)) / double(numSamples);
 		const deUint64	colScale	= deUint64(255-MIN_ERR_THRESHOLD);
 		const deUint64	colScale4	= colScale*colScale*colScale*colScale;

 		return float(double(distSum4) / double(colScale4) * pSamples);
 	}
 }

 } // tcu
	/*-------------------------------------------------------------------------
	* drawElements Quality Program Tester Core
	* ----------------------------------------
	*
	* Copyright 2014 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	//!
	* \file
	* \brief Fuzzy image comparison.
	//--------------------------------------------------------------------*/

	#include "tcuFuzzyImageCompare.hpp"
	#include "tcuTexture.hpp"
	#include "tcuTextureUtil.hpp"
	#include "deMath.h"
	#include "deRandom.hpp"

	#include <vector>

	namespace tcu
	{

	enum
	{
	MIN_ERR_THRESHOLD = 4 // Magic to make small differences go away
	};

	using std::vector;

	template<int Channel>
	static inline deUint8 getChannel (deUint32 color)
	{
	return (deUint8)((color >> (Channel*8)) & 0xff);
	}

	static inline deUint8 getChannel (deUint32 color, int channel)
	{
	return (deUint8)((color >> (channel*8)) & 0xff);
	}

	static inline deUint32 setChannel (deUint32 color, int channel, deUint8 val)
	{
	return (color & ~(0xffu << (8channel))) \| (val << (8channel));
	}

	static inline Vec4 toFloatVec (deUint32 color)
	{
	return Vec4((float)getChannel<0>(color), (float)getChannel<1>(color), (float)getChannel<2>(color), (float)getChannel<3>(color));
	}

	static inline deUint8 roundToUint8Sat (float v)
	{
	return (deUint8)de::clamp((int)(v + 0.5f), 0, 255);
	}

	static inline deUint32 toColor (Vec4 v)
	{
	return roundToUint8Sat(v[0]) \| (roundToUint8Sat(v[1]) << 8) \| (roundToUint8Sat(v[2]) << 16) \| (roundToUint8Sat(v[3]) << 24);
	}

	template<int NumChannels>
	static inline deUint32 readUnorm8 (const tcu::ConstPixelBufferAccess& src, int x, int y)
	{
	const deUint8* ptr = (const deUint8)src.getDataPtr() + src.getRowPitch()y + x*NumChannels;
	deUint32 v = 0;

	for (int c = 0; c < NumChannels; c++)
	v \|= ptr[c] << (c*8);

	if (NumChannels < 4)
	v \|= 0xffu << 24;

	return v;
	}

	#if (DE_ENDIANNESS == DE_LITTLE_ENDIAN)
	template<>
	inline deUint32 readUnorm8<4> (const tcu::ConstPixelBufferAccess& src, int x, int y)
	{
	return (const deUint32)((const deUint8)src.getDataPtr() + src.getRowPitch()y + x*4);
	}
	#endif

	template<int NumChannels>
	static inline void writeUnorm8 (const tcu::PixelBufferAccess& dst, int x, int y, deUint32 val)
	{
	deUint8* ptr = (deUint8)dst.getDataPtr() + dst.getRowPitch()y + x*NumChannels;

	for (int c = 0; c < NumChannels; c++)
	ptr[c] = getChannel(val, c);
	}

	#if (DE_ENDIANNESS == DE_LITTLE_ENDIAN)
	template<>
	inline void writeUnorm8<4> (const tcu::PixelBufferAccess& dst, int x, int y, deUint32 val)
	{
	(deUint32)((deUint8)dst.getDataPtr() + dst.getRowPitch()y + x*4) = val;
	}
	#endif

	static inline deUint32 colorDistSquared (deUint32 pa, deUint32 pb)
	{
	const int r = de::max<int>(de::abs((int)getChannel<0>(pa) - (int)getChannel<0>(pb)) - MIN_ERR_THRESHOLD, 0);
	const int g = de::max<int>(de::abs((int)getChannel<1>(pa) - (int)getChannel<1>(pb)) - MIN_ERR_THRESHOLD, 0);
	const int b = de::max<int>(de::abs((int)getChannel<2>(pa) - (int)getChannel<2>(pb)) - MIN_ERR_THRESHOLD, 0);
	const int a = de::max<int>(de::abs((int)getChannel<3>(pa) - (int)getChannel<3>(pb)) - MIN_ERR_THRESHOLD, 0);

	return deUint32(rr + gg + bb + aa);
	}

	template<int NumChannels>
	inline deUint32 bilinearSample (const ConstPixelBufferAccess& src, float u, float v)
	{
	int w = src.getWidth();
	int h = src.getHeight();

	int x0 = deFloorFloatToInt32(u-0.5f);
	int x1 = x0+1;
	int y0 = deFloorFloatToInt32(v-0.5f);
	int y1 = y0+1;

	int i0 = de::clamp(x0, 0, w-1);
	int i1 = de::clamp(x1, 0, w-1);
	int j0 = de::clamp(y0, 0, h-1);
	int j1 = de::clamp(y1, 0, h-1);

	float a = deFloatFrac(u-0.5f);
	float b = deFloatFrac(v-0.5f);

	deUint32 p00 = readUnorm8<NumChannels>(src, i0, j0);
	deUint32 p10 = readUnorm8<NumChannels>(src, i1, j0);
	deUint32 p01 = readUnorm8<NumChannels>(src, i0, j1);
	deUint32 p11 = readUnorm8<NumChannels>(src, i1, j1);
	deUint32 dst = 0;

	// Interpolate.
	for (int c = 0; c < NumChannels; c++)
	{
	float f = (getChannel(p00, c)(1.0f-a)(1.0f-b)) +
	(getChannel(p10, c)( a)(1.0f-b)) +
	(getChannel(p01, c)(1.0f-a)( b)) +
	(getChannel(p11, c)( a)( b));
	dst = setChannel(dst, c, roundToUint8Sat(f));
	}

	return dst;
	}

	template<int DstChannels, int SrcChannels>
	static void separableConvolve (const PixelBufferAccess& dst, const ConstPixelBufferAccess& src, int shiftX, int shiftY, const std::vector<float>& kernelX, const std::vector<float>& kernelY)
	{
	DE_ASSERT(dst.getWidth() == src.getWidth() && dst.getHeight() == src.getHeight());

	TextureLevel tmp (dst.getFormat(), dst.getHeight(), dst.getWidth());
	PixelBufferAccess tmpAccess = tmp.getAccess();

	int kw = (int)kernelX.size();
	int kh = (int)kernelY.size();

	// Horizontal pass
	// \note Temporary surface is written in column-wise order
	for (int j = 0; j < src.getHeight(); j++)
	{
	for (int i = 0; i < src.getWidth(); i++)
	{
	Vec4 sum(0);

	for (int kx = 0; kx < kw; kx++)
	{
	float f = kernelX[kw-kx-1];
	deUint32 p = readUnorm8<SrcChannels>(src, de::clamp(i+kx-shiftX, 0, src.getWidth()-1), j);

	sum += toFloatVec(p)*f;
	}

	writeUnorm8<DstChannels>(tmpAccess, j, i, toColor(sum));
	}
	}

	// Vertical pass
	for (int j = 0; j < src.getHeight(); j++)
	{
	for (int i = 0; i < src.getWidth(); i++)
	{
	Vec4 sum(0.0f);

	for (int ky = 0; ky < kh; ky++)
	{
	float f = kernelY[kh-ky-1];
	deUint32 p = readUnorm8<DstChannels>(tmpAccess, de::clamp(j+ky-shiftY, 0, tmp.getWidth()-1), i);

	sum += toFloatVec(p)*f;
	}

	writeUnorm8<DstChannels>(dst, i, j, toColor(sum));
	}
	}
	}

	template<int NumChannels>
	static deUint32 distSquaredToNeighbor (de::Random& rnd, deUint32 pixel, const ConstPixelBufferAccess& surface, int x, int y)
	{
	// (x, y) + (0, 0)
	deUint32 minDist = colorDistSquared(pixel, readUnorm8<NumChannels>(surface, x, y));

	if (minDist == 0)
	return minDist;

	// Area around (x, y)
	static const int s_coords[][2] =
	{
	{-1, -1},
	{ 0, -1},
	{+1, -1},
	{-1, 0},
	{+1, 0},
	{-1, +1},
	{ 0, +1},
	{+1, +1}
	};

	for (int d = 0; d < (int)DE_LENGTH_OF_ARRAY(s_coords); d++)
	{
	int dx = x + s_coords[d][0];
	int dy = y + s_coords[d][1];

	if (!deInBounds32(dx, 0, surface.getWidth()) \|\| !deInBounds32(dy, 0, surface.getHeight()))
	continue;

	minDist = de::min(minDist, colorDistSquared(pixel, readUnorm8<NumChannels>(surface, dx, dy)));
	if (minDist == 0)
	return minDist;
	}

	// Random bilinear-interpolated samples around (x, y)
	for (int s = 0; s < 32; s++)
	{
	float dx = (float)x + rnd.getFloat()*2.0f - 0.5f;
	float dy = (float)y + rnd.getFloat()*2.0f - 0.5f;

	deUint32 sample = bilinearSample<NumChannels>(surface, dx, dy);

	minDist = de::min(minDist, colorDistSquared(pixel, sample));
	if (minDist == 0)
	return minDist;
	}

	return minDist;
	}

	static inline float toGrayscale (const Vec4& c)
	{
	return 0.2126fc[0] + 0.7152fc[1] + 0.0722f*c[2];
	}

	static bool isFormatSupported (const TextureFormat& format)
	{
	return format.type == TextureFormat::UNORM_INT8 && (format.order == TextureFormat::RGB \|\| format.order == TextureFormat::RGBA);
	}

	float fuzzyCompare (const FuzzyCompareParams& params, const ConstPixelBufferAccess& ref, const ConstPixelBufferAccess& cmp, const PixelBufferAccess& errorMask)
	{
	DE_ASSERT(ref.getWidth() == cmp.getWidth() && ref.getHeight() == cmp.getHeight());
	DE_ASSERT(errorMask.getWidth() == ref.getWidth() && errorMask.getHeight() == ref.getHeight());

	if (!isFormatSupported(ref.getFormat()) \|\| !isFormatSupported(cmp.getFormat()))
	throw InternalError("Unsupported format in fuzzy comparison", DE_NULL, __FILE__, __LINE__);

	int width = ref.getWidth();
	int height = ref.getHeight();
	de::Random rnd (667);

	// Filtered
	TextureLevel refFiltered(TextureFormat(TextureFormat::RGBA, TextureFormat::UNORM_INT8), width, height);
	TextureLevel cmpFiltered(TextureFormat(TextureFormat::RGBA, TextureFormat::UNORM_INT8), width, height);

	// Kernel = {0.1, 0.8, 0.1}
	vector<float> kernel(3);
	kernel[0] = kernel[2] = 0.1f; kernel[1]= 0.8f;
	int shift = (int)(kernel.size() - 1) / 2;

	switch (ref.getFormat().order)
	{
	case TextureFormat::RGBA: separableConvolve<4, 4>(refFiltered, ref, shift, shift, kernel, kernel); break;
	case TextureFormat::RGB: separableConvolve<4, 3>(refFiltered, ref, shift, shift, kernel, kernel); break;
	default:
	DE_ASSERT(DE_FALSE);
	}

	switch (cmp.getFormat().order)
	{
	case TextureFormat::RGBA: separableConvolve<4, 4>(cmpFiltered, cmp, shift, shift, kernel, kernel); break;
	case TextureFormat::RGB: separableConvolve<4, 3>(cmpFiltered, cmp, shift, shift, kernel, kernel); break;
	default:
	DE_ASSERT(DE_FALSE);
	}

	int numSamples = 0;
	deUint64 distSum4 = 0ull;

	// Clear error mask to green.
	clear(errorMask, Vec4(0.0f, 1.0f, 0.0f, 1.0f));

	ConstPixelBufferAccess refAccess = refFiltered.getAccess();
	ConstPixelBufferAccess cmpAccess = cmpFiltered.getAccess();

	for (int y = 1; y < height-1; y++)
	{
	for (int x = 1; x < width-1; x += params.maxSampleSkip > 0 ? (int)rnd.getInt(1, params.maxSampleSkip) : 1)
	{
	const deUint32 minDist2RefToCmp = distSquaredToNeighbor<4>(rnd, readUnorm8<4>(refAccess, x, y), cmpAccess, x, y);
	const deUint32 minDist2CmpToRef = distSquaredToNeighbor<4>(rnd, readUnorm8<4>(cmpAccess, x, y), refAccess, x, y);
	const deUint32 minDist2 = de::min(minDist2RefToCmp, minDist2CmpToRef);
	const deUint64 newSum4 = distSum4 + minDist2*minDist2;

	distSum4 = (newSum4 >= distSum4) ? newSum4 : ~0ull; // In case of overflow
	numSamples += 1;

	// Build error image.
	{
	const int scale = 255-MIN_ERR_THRESHOLD;
	const float err2 = float(minDist2) / float(scale*scale);
	const float err4 = err2*err2;
	const float red = err4 * 500.0f;
	const float luma = toGrayscale(cmp.getPixel(x, y));
	const float rF = 0.7f + 0.3f*luma;

	errorMask.setPixel(Vec4(redrF, (1.0f-red)rF, 0.0f, 1.0f), x, y);
	}
	}
	}

	{
	// Scale error sum based on number of samples taken
	const double pSamples = double((width-2) * (height-2)) / double(numSamples);
	const deUint64 colScale = deUint64(255-MIN_ERR_THRESHOLD);
	const deUint64 colScale4 = colScalecolScalecolScale*colScale;

	return float(double(distSum4) / double(colScale4) * pSamples);
	}
	}

	} // tcu