third_party/libyuv/source/compare.cc - vendor/opensource/webrtc - Git at Google

 /*
  *  Copyright (c) 2011 The LibYuv project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #include "libyuv/compare.h"

 #include <float.h>
 #include <math.h>

 #include "libyuv/basic_types.h"
 #include "libyuv/cpu_id.h"
 #include "row.h"

 #ifdef __cplusplus
 namespace libyuv {
 extern "C" {
 #endif

 #if defined(__ARM_NEON__) && !defined(YUV_DISABLE_ASM)
 #define HAS_SUMSQUAREERROR_NEON

 static uint32 SumSquareError_NEON(const uint8* src_a,
                                   const uint8* src_b, int count) {
   volatile uint32 sse;
   asm volatile (
     "vmov.u8    q7, #0                         \n"
     "vmov.u8    q9, #0                         \n"
     "vmov.u8    q8, #0                         \n"
     "vmov.u8    q10, #0                        \n"

     "1:                                        \n"
     "vld1.u8    {q0}, [%0]!                    \n"
     "vld1.u8    {q1}, [%1]!                    \n"
     "vsubl.u8   q2, d0, d2                     \n"
     "vsubl.u8   q3, d1, d3                     \n"
     "vmlal.s16  q7, d4, d4                     \n"
     "vmlal.s16  q8, d6, d6                     \n"
     "vmlal.s16  q8, d5, d5                     \n"
     "vmlal.s16  q10, d7, d7                    \n"
     "subs       %2, %2, #16                    \n"
     "bhi        1b                             \n"

     "vadd.u32   q7, q7, q8                     \n"
     "vadd.u32   q9, q9, q10                    \n"
     "vadd.u32   q10, q7, q9                    \n"
     "vpaddl.u32 q1, q10                        \n"
     "vadd.u64   d0, d2, d3                     \n"
     "vmov.32    %3, d0[0]                      \n"
     : "+r"(src_a),
       "+r"(src_b),
       "+r"(count),
       "=r"(sse)
     :
     : "memory", "cc", "q0", "q1", "q2", "q3", "q7", "q8", "q9", "q10"
   );
   return sse;
 }

 #elif defined(_M_IX86) && !defined(YUV_DISABLE_ASM)
 #define HAS_SUMSQUAREERROR_SSE2
 __declspec(naked)
 static uint32 SumSquareError_SSE2(const uint8* src_a,
                                   const uint8* src_b, int count) {
   __asm {
     mov        eax, [esp + 4]    // src_a
     mov        edx, [esp + 8]    // src_b
     mov        ecx, [esp + 12]   // count
     pxor       xmm0, xmm0
     pxor       xmm5, xmm5
     sub        edx, eax

   wloop:
     movdqa     xmm1, [eax]
     movdqa     xmm2, [eax + edx]
     lea        eax,  [eax + 16]
     movdqa     xmm3, xmm1
     psubusb    xmm1, xmm2
     psubusb    xmm2, xmm3
     por        xmm1, xmm2
     movdqa     xmm2, xmm1
     punpcklbw  xmm1, xmm5
     punpckhbw  xmm2, xmm5
     pmaddwd    xmm1, xmm1
     pmaddwd    xmm2, xmm2
     paddd      xmm0, xmm1
     paddd      xmm0, xmm2
     sub        ecx, 16
     ja         wloop

     pshufd     xmm1, xmm0, 0EEh
     paddd      xmm0, xmm1
     pshufd     xmm1, xmm0, 01h
     paddd      xmm0, xmm1
     movd       eax, xmm0
     ret
   }
 }

 #elif (defined(__x86_64__) || defined(__i386__)) && !defined(YUV_DISABLE_ASM)
 #define HAS_SUMSQUAREERROR_SSE2
 static uint32 SumSquareError_SSE2(const uint8* src_a,
                                   const uint8* src_b, int count) {
   uint32 sse;
   asm volatile (
     "pxor      %%xmm0,%%xmm0                   \n"
     "pxor      %%xmm5,%%xmm5                   \n"
     "sub       %0,%1                           \n"

     "1:                                        \n"
     "movdqa    (%0),%%xmm1                     \n"
     "movdqa    (%0,%1,1),%%xmm2                \n"
     "lea       0x10(%0),%0                     \n"
     "movdqa    %%xmm1,%%xmm3                   \n"
     "psubusb   %%xmm2,%%xmm1                   \n"
     "psubusb   %%xmm3,%%xmm2                   \n"
     "por       %%xmm2,%%xmm1                   \n"
     "movdqa    %%xmm1,%%xmm2                   \n"
     "punpcklbw %%xmm5,%%xmm1                   \n"
     "punpckhbw %%xmm5,%%xmm2                   \n"
     "pmaddwd   %%xmm1,%%xmm1                   \n"
     "pmaddwd   %%xmm2,%%xmm2                   \n"
     "paddd     %%xmm1,%%xmm0                   \n"
     "paddd     %%xmm2,%%xmm0                   \n"
     "sub       $0x10,%2                        \n"
     "ja        1b                              \n"

     "pshufd    $0xee,%%xmm0,%%xmm1             \n"
     "paddd     %%xmm1,%%xmm0                   \n"
     "pshufd    $0x1,%%xmm0,%%xmm1              \n"
     "paddd     %%xmm1,%%xmm0                   \n"
     "movd      %%xmm0,%3                       \n"

   : "+r"(src_a),      // %0
     "+r"(src_b),      // %1
     "+r"(count),      // %2
     "=g"(sse)         // %3
   :
   : "memory", "cc"
 #if defined(__SSE2__)
     , "xmm0", "xmm1", "xmm2", "xmm5"
 #endif
   );
   return sse;
 }
 #endif

 static uint32 SumSquareError_C(const uint8* src_a,
                                const uint8* src_b, int count) {
   uint32 sse = 0u;
   for (int x = 0; x < count; ++x) {
     int diff = src_a[0] - src_b[0];
     sse += static_cast<uint32>(diff * diff);
     src_a += 1;
     src_b += 1;
   }
   return sse;
 }

 uint64 ComputeSumSquareError(const uint8* src_a,
                              const uint8* src_b, int count) {
   uint32 (*SumSquareError)(const uint8* src_a,
                            const uint8* src_b, int count);
 #if defined(HAS_SUMSQUAREERROR_NEON)
   if (TestCpuFlag(kCpuHasNEON)) {
     SumSquareError = SumSquareError_NEON;
   } else
 #elif defined(HAS_SUMSQUAREERROR_SSE2)
   if (TestCpuFlag(kCpuHasSSE2) &&
       IS_ALIGNED(src_a, 16) && IS_ALIGNED(src_b, 16)) {
     SumSquareError = SumSquareError_SSE2;
   } else
 #endif
   {
     SumSquareError = SumSquareError_C;
   }
   const int kBlockSize = 32768;
   uint64 sse = 0;
   while (count >= kBlockSize) {
     sse += SumSquareError(src_a, src_b, kBlockSize);
     src_a += kBlockSize;
     src_b += kBlockSize;
     count -= kBlockSize;
   }
   int remainder = count & ~15;
   if (remainder) {
     sse += SumSquareError(src_a, src_b, remainder);
     src_a += remainder;
     src_b += remainder;
     count -= remainder;
   }
   if (count) {
     sse += SumSquareError_C(src_a, src_b, count);
   }
   return sse;
 }

 uint64 ComputeSumSquareErrorPlane(const uint8* src_a, int stride_a,
                                   const uint8* src_b, int stride_b,
                                   int width, int height) {
   uint32 (*SumSquareError)(const uint8* src_a,
                            const uint8* src_b, int count);
 #if defined(HAS_SUMSQUAREERROR_NEON)
   if (TestCpuFlag(kCpuHasNEON) &&
       IS_ALIGNED(width, 16)) {
     SumSquareError = SumSquareError_NEON;
   } else
 #endif
   {
     SumSquareError = SumSquareError_C;
   }

   uint64 sse = 0;
   for (int h = 0; h < height; ++h) {
     sse += SumSquareError(src_a, src_b, width);
     src_a += stride_a;
     src_b += stride_b;
   }

   return sse;
 }

 double SumSquareErrorToPsnr(uint64 sse, uint64 count) {
   double psnr;
   if (sse > 0) {
     double mse = static_cast<double>(count) / static_cast<double>(sse);
     psnr = 10.0 * log10(255.0 * 255.0 * mse);
   } else {
     psnr = kMaxPsnr;      // Limit to prevent divide by 0
   }

   if (psnr > kMaxPsnr)
     psnr = kMaxPsnr;

   return psnr;
 }

 double CalcFramePsnr(const uint8* src_a, int stride_a,
                      const uint8* src_b, int stride_b,
                      int width, int height) {
   const uint64 samples = width * height;
   const uint64 sse = ComputeSumSquareErrorPlane(src_a, stride_a,
                                                 src_b, stride_b,
                                                 width, height);
   return SumSquareErrorToPsnr(sse, samples);
 }

 double I420Psnr(const uint8* src_y_a, int stride_y_a,
                 const uint8* src_u_a, int stride_u_a,
                 const uint8* src_v_a, int stride_v_a,
                 const uint8* src_y_b, int stride_y_b,
                 const uint8* src_u_b, int stride_u_b,
                 const uint8* src_v_b, int stride_v_b,
                 int width, int height) {
   const uint64 sse_y = ComputeSumSquareErrorPlane(src_y_a, stride_y_a,
                                                   src_y_b, stride_y_b,
                                                   width, height);
   const int width_uv = (width + 1) >> 1;
   const int height_uv = (height + 1) >> 1;
   const uint64 sse_u = ComputeSumSquareErrorPlane(src_u_a, stride_u_a,
                                                   src_u_b, stride_u_b,
                                                   width_uv, height_uv);
   const uint64 sse_v = ComputeSumSquareErrorPlane(src_v_a, stride_v_a,
                                                   src_v_b, stride_v_b,
                                                   width_uv, height_uv);
   const uint64 samples = width * height + 2 * (width_uv * height_uv);
   const uint64 sse = sse_y + sse_u + sse_v;
   return SumSquareErrorToPsnr(sse, samples);
 }

 static const int64 cc1 =  26634;  // (64^2*(.01*255)^2
 static const int64 cc2 = 239708;  // (64^2*(.03*255)^2

 static double Ssim8x8_C(const uint8* src_a, int stride_a,
                         const uint8* src_b, int stride_b) {
   int64 sum_a = 0;
   int64 sum_b = 0;
   int64 sum_sq_a = 0;
   int64 sum_sq_b = 0;
   int64 sum_axb = 0;

   for (int i = 0; i < 8; ++i) {
     for (int j = 0; j < 8; ++j) {
       sum_a += src_a[j];
       sum_b += src_b[j];
       sum_sq_a += src_a[j] * src_a[j];
       sum_sq_b += src_b[j] * src_b[j];
       sum_axb += src_a[j] * src_b[j];
     }

     src_a += stride_a;
     src_b += stride_b;
   }

   const int64 count = 64;
   // scale the constants by number of pixels
   const int64 c1 = (cc1 * count * count) >> 12;
   const int64 c2 = (cc2 * count * count) >> 12;

   const int64 sum_a_x_sum_b = sum_a * sum_b;

   const int64 ssim_n = (2 * sum_a_x_sum_b + c1) *
                        (2 * count * sum_axb - 2 * sum_a_x_sum_b + c2);

   const int64 sum_a_sq = sum_a*sum_a;
   const int64 sum_b_sq = sum_b*sum_b;

   const int64 ssim_d = (sum_a_sq + sum_b_sq + c1) *
                        (count * sum_sq_a - sum_a_sq +
                         count * sum_sq_b - sum_b_sq + c2);

   if (ssim_d == 0.0)
     return DBL_MAX;
   return ssim_n * 1.0 / ssim_d;
 }

 // We are using a 8x8 moving window with starting location of each 8x8 window
 // on the 4x4 pixel grid. Such arrangement allows the windows to overlap
 // block boundaries to penalize blocking artifacts.
 double CalcFrameSsim(const uint8* src_a, int stride_a,
                      const uint8* src_b, int stride_b,
                      int width, int height) {
   int samples = 0;
   double ssim_total = 0;

   double (*Ssim8x8)(const uint8* src_a, int stride_a,
                     const uint8* src_b, int stride_b);

   Ssim8x8 = Ssim8x8_C;

   // sample point start with each 4x4 location
   for (int i = 0; i < height - 8; i += 4) {
     for (int j = 0; j < width - 8; j += 4) {
       ssim_total += Ssim8x8(src_a + j, stride_a, src_b + j, stride_b);
       samples++;
     }

     src_a += stride_a * 4;
     src_b += stride_b * 4;
   }

   ssim_total /= samples;
   return ssim_total;
 }

 double I420Ssim(const uint8* src_y_a, int stride_y_a,
                 const uint8* src_u_a, int stride_u_a,
                 const uint8* src_v_a, int stride_v_a,
                 const uint8* src_y_b, int stride_y_b,
                 const uint8* src_u_b, int stride_u_b,
                 const uint8* src_v_b, int stride_v_b,
                 int width, int height) {
   const double ssim_y = CalcFrameSsim(src_y_a, stride_y_a,
                                       src_y_b, stride_y_b, width, height);
   const int width_uv = (width + 1) >> 1;
   const int height_uv = (height + 1) >> 1;
   const double ssim_u = CalcFrameSsim(src_u_a, stride_u_a,
                                       src_u_b, stride_u_b,
                                       width_uv, height_uv);
   const double ssim_v = CalcFrameSsim(src_v_a, stride_v_a,
                                       src_v_b, stride_v_b,
                                       width_uv, height_uv);
   return ssim_y * 0.8 + 0.1 * (ssim_u + ssim_v);
 }

 #ifdef __cplusplus
 }  // extern "C"
 }  // namespace libyuv
 #endif
	/*
	* Copyright (c) 2011 The LibYuv project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#include "libyuv/compare.h"

	#include <float.h>
	#include <math.h>

	#include "libyuv/basic_types.h"
	#include "libyuv/cpu_id.h"
	#include "row.h"

	#ifdef __cplusplus
	namespace libyuv {
	extern "C" {
	#endif

	#if defined(__ARM_NEON__) && !defined(YUV_DISABLE_ASM)
	#define HAS_SUMSQUAREERROR_NEON

	static uint32 SumSquareError_NEON(const uint8* src_a,
	const uint8* src_b, int count) {
	volatile uint32 sse;
	asm volatile (
	"vmov.u8 q7, #0 \n"
	"vmov.u8 q9, #0 \n"
	"vmov.u8 q8, #0 \n"
	"vmov.u8 q10, #0 \n"

	"1: \n"
	"vld1.u8 {q0}, [%0]! \n"
	"vld1.u8 {q1}, [%1]! \n"
	"vsubl.u8 q2, d0, d2 \n"
	"vsubl.u8 q3, d1, d3 \n"
	"vmlal.s16 q7, d4, d4 \n"
	"vmlal.s16 q8, d6, d6 \n"
	"vmlal.s16 q8, d5, d5 \n"
	"vmlal.s16 q10, d7, d7 \n"
	"subs %2, %2, #16 \n"
	"bhi 1b \n"

	"vadd.u32 q7, q7, q8 \n"
	"vadd.u32 q9, q9, q10 \n"
	"vadd.u32 q10, q7, q9 \n"
	"vpaddl.u32 q1, q10 \n"
	"vadd.u64 d0, d2, d3 \n"
	"vmov.32 %3, d0[0] \n"
	: "+r"(src_a),
	"+r"(src_b),
	"+r"(count),
	"=r"(sse)
	:
	: "memory", "cc", "q0", "q1", "q2", "q3", "q7", "q8", "q9", "q10"
	);
	return sse;
	}

	#elif defined(_M_IX86) && !defined(YUV_DISABLE_ASM)
	#define HAS_SUMSQUAREERROR_SSE2
	__declspec(naked)
	static uint32 SumSquareError_SSE2(const uint8* src_a,
	const uint8* src_b, int count) {
	__asm {
	mov eax, [esp + 4] // src_a
	mov edx, [esp + 8] // src_b
	mov ecx, [esp + 12] // count
	pxor xmm0, xmm0
	pxor xmm5, xmm5
	sub edx, eax

	wloop:
	movdqa xmm1, [eax]
	movdqa xmm2, [eax + edx]
	lea eax, [eax + 16]
	movdqa xmm3, xmm1
	psubusb xmm1, xmm2
	psubusb xmm2, xmm3
	por xmm1, xmm2
	movdqa xmm2, xmm1
	punpcklbw xmm1, xmm5
	punpckhbw xmm2, xmm5
	pmaddwd xmm1, xmm1
	pmaddwd xmm2, xmm2
	paddd xmm0, xmm1
	paddd xmm0, xmm2
	sub ecx, 16
	ja wloop

	pshufd xmm1, xmm0, 0EEh
	paddd xmm0, xmm1
	pshufd xmm1, xmm0, 01h
	paddd xmm0, xmm1
	movd eax, xmm0
	ret
	}
	}

	#elif (defined(__x86_64__) \|\| defined(__i386__)) && !defined(YUV_DISABLE_ASM)
	#define HAS_SUMSQUAREERROR_SSE2
	static uint32 SumSquareError_SSE2(const uint8* src_a,
	const uint8* src_b, int count) {
	uint32 sse;
	asm volatile (
	"pxor %%xmm0,%%xmm0 \n"
	"pxor %%xmm5,%%xmm5 \n"
	"sub %0,%1 \n"

	"1: \n"
	"movdqa (%0),%%xmm1 \n"
	"movdqa (%0,%1,1),%%xmm2 \n"
	"lea 0x10(%0),%0 \n"
	"movdqa %%xmm1,%%xmm3 \n"
	"psubusb %%xmm2,%%xmm1 \n"
	"psubusb %%xmm3,%%xmm2 \n"
	"por %%xmm2,%%xmm1 \n"
	"movdqa %%xmm1,%%xmm2 \n"
	"punpcklbw %%xmm5,%%xmm1 \n"
	"punpckhbw %%xmm5,%%xmm2 \n"
	"pmaddwd %%xmm1,%%xmm1 \n"
	"pmaddwd %%xmm2,%%xmm2 \n"
	"paddd %%xmm1,%%xmm0 \n"
	"paddd %%xmm2,%%xmm0 \n"
	"sub $0x10,%2 \n"
	"ja 1b \n"

	"pshufd $0xee,%%xmm0,%%xmm1 \n"
	"paddd %%xmm1,%%xmm0 \n"
	"pshufd $0x1,%%xmm0,%%xmm1 \n"
	"paddd %%xmm1,%%xmm0 \n"
	"movd %%xmm0,%3 \n"

	: "+r"(src_a), // %0
	"+r"(src_b), // %1
	"+r"(count), // %2
	"=g"(sse) // %3
	:
	: "memory", "cc"
	#if defined(__SSE2__)
	, "xmm0", "xmm1", "xmm2", "xmm5"
	#endif
	);
	return sse;
	}
	#endif

	static uint32 SumSquareError_C(const uint8* src_a,
	const uint8* src_b, int count) {
	uint32 sse = 0u;
	for (int x = 0; x < count; ++x) {
	int diff = src_a[0] - src_b[0];
	sse += static_cast<uint32>(diff * diff);
	src_a += 1;
	src_b += 1;
	}
	return sse;
	}

	uint64 ComputeSumSquareError(const uint8* src_a,
	const uint8* src_b, int count) {
	uint32 (SumSquareError)(const uint8 src_a,
	const uint8* src_b, int count);
	#if defined(HAS_SUMSQUAREERROR_NEON)
	if (TestCpuFlag(kCpuHasNEON)) {
	SumSquareError = SumSquareError_NEON;
	} else
	#elif defined(HAS_SUMSQUAREERROR_SSE2)
	if (TestCpuFlag(kCpuHasSSE2) &&
	IS_ALIGNED(src_a, 16) && IS_ALIGNED(src_b, 16)) {
	SumSquareError = SumSquareError_SSE2;
	} else
	#endif
	{
	SumSquareError = SumSquareError_C;
	}
	const int kBlockSize = 32768;
	uint64 sse = 0;
	while (count >= kBlockSize) {
	sse += SumSquareError(src_a, src_b, kBlockSize);
	src_a += kBlockSize;
	src_b += kBlockSize;
	count -= kBlockSize;
	}
	int remainder = count & ~15;
	if (remainder) {
	sse += SumSquareError(src_a, src_b, remainder);
	src_a += remainder;
	src_b += remainder;
	count -= remainder;
	}
	if (count) {
	sse += SumSquareError_C(src_a, src_b, count);
	}
	return sse;
	}

	uint64 ComputeSumSquareErrorPlane(const uint8* src_a, int stride_a,
	const uint8* src_b, int stride_b,
	int width, int height) {
	uint32 (SumSquareError)(const uint8 src_a,
	const uint8* src_b, int count);
	#if defined(HAS_SUMSQUAREERROR_NEON)
	if (TestCpuFlag(kCpuHasNEON) &&
	IS_ALIGNED(width, 16)) {
	SumSquareError = SumSquareError_NEON;
	} else
	#endif
	{
	SumSquareError = SumSquareError_C;
	}

	uint64 sse = 0;
	for (int h = 0; h < height; ++h) {
	sse += SumSquareError(src_a, src_b, width);
	src_a += stride_a;
	src_b += stride_b;
	}

	return sse;
	}

	double SumSquareErrorToPsnr(uint64 sse, uint64 count) {
	double psnr;
	if (sse > 0) {
	double mse = static_cast<double>(count) / static_cast<double>(sse);
	psnr = 10.0 * log10(255.0 * 255.0 * mse);
	} else {
	psnr = kMaxPsnr; // Limit to prevent divide by 0
	}

	if (psnr > kMaxPsnr)
	psnr = kMaxPsnr;

	return psnr;
	}

	double CalcFramePsnr(const uint8* src_a, int stride_a,
	const uint8* src_b, int stride_b,
	int width, int height) {
	const uint64 samples = width * height;
	const uint64 sse = ComputeSumSquareErrorPlane(src_a, stride_a,
	src_b, stride_b,
	width, height);
	return SumSquareErrorToPsnr(sse, samples);
	}

	double I420Psnr(const uint8* src_y_a, int stride_y_a,
	const uint8* src_u_a, int stride_u_a,
	const uint8* src_v_a, int stride_v_a,
	const uint8* src_y_b, int stride_y_b,
	const uint8* src_u_b, int stride_u_b,
	const uint8* src_v_b, int stride_v_b,
	int width, int height) {
	const uint64 sse_y = ComputeSumSquareErrorPlane(src_y_a, stride_y_a,
	src_y_b, stride_y_b,
	width, height);
	const int width_uv = (width + 1) >> 1;
	const int height_uv = (height + 1) >> 1;
	const uint64 sse_u = ComputeSumSquareErrorPlane(src_u_a, stride_u_a,
	src_u_b, stride_u_b,
	width_uv, height_uv);
	const uint64 sse_v = ComputeSumSquareErrorPlane(src_v_a, stride_v_a,
	src_v_b, stride_v_b,
	width_uv, height_uv);
	const uint64 samples = width * height + 2 * (width_uv * height_uv);
	const uint64 sse = sse_y + sse_u + sse_v;
	return SumSquareErrorToPsnr(sse, samples);
	}

	static const int64 cc1 = 26634; // (64^2(.01255)^2
	static const int64 cc2 = 239708; // (64^2(.03255)^2

	static double Ssim8x8_C(const uint8* src_a, int stride_a,
	const uint8* src_b, int stride_b) {
	int64 sum_a = 0;
	int64 sum_b = 0;
	int64 sum_sq_a = 0;
	int64 sum_sq_b = 0;
	int64 sum_axb = 0;

	for (int i = 0; i < 8; ++i) {
	for (int j = 0; j < 8; ++j) {
	sum_a += src_a[j];
	sum_b += src_b[j];
	sum_sq_a += src_a[j] * src_a[j];
	sum_sq_b += src_b[j] * src_b[j];
	sum_axb += src_a[j] * src_b[j];
	}

	src_a += stride_a;
	src_b += stride_b;
	}

	const int64 count = 64;
	// scale the constants by number of pixels
	const int64 c1 = (cc1 * count * count) >> 12;
	const int64 c2 = (cc2 * count * count) >> 12;

	const int64 sum_a_x_sum_b = sum_a * sum_b;

	const int64 ssim_n = (2 * sum_a_x_sum_b + c1) *
	(2 * count * sum_axb - 2 * sum_a_x_sum_b + c2);

	const int64 sum_a_sq = sum_a*sum_a;
	const int64 sum_b_sq = sum_b*sum_b;

	const int64 ssim_d = (sum_a_sq + sum_b_sq + c1) *
	(count * sum_sq_a - sum_a_sq +
	count * sum_sq_b - sum_b_sq + c2);

	if (ssim_d == 0.0)
	return DBL_MAX;
	return ssim_n * 1.0 / ssim_d;
	}

	// We are using a 8x8 moving window with starting location of each 8x8 window
	// on the 4x4 pixel grid. Such arrangement allows the windows to overlap
	// block boundaries to penalize blocking artifacts.
	double CalcFrameSsim(const uint8* src_a, int stride_a,
	const uint8* src_b, int stride_b,
	int width, int height) {
	int samples = 0;
	double ssim_total = 0;

	double (Ssim8x8)(const uint8 src_a, int stride_a,
	const uint8* src_b, int stride_b);

	Ssim8x8 = Ssim8x8_C;

	// sample point start with each 4x4 location
	for (int i = 0; i < height - 8; i += 4) {
	for (int j = 0; j < width - 8; j += 4) {
	ssim_total += Ssim8x8(src_a + j, stride_a, src_b + j, stride_b);
	samples++;
	}

	src_a += stride_a * 4;
	src_b += stride_b * 4;
	}

	ssim_total /= samples;
	return ssim_total;
	}

	double I420Ssim(const uint8* src_y_a, int stride_y_a,
	const uint8* src_u_a, int stride_u_a,
	const uint8* src_v_a, int stride_v_a,
	const uint8* src_y_b, int stride_y_b,
	const uint8* src_u_b, int stride_u_b,
	const uint8* src_v_b, int stride_v_b,
	int width, int height) {
	const double ssim_y = CalcFrameSsim(src_y_a, stride_y_a,
	src_y_b, stride_y_b, width, height);
	const int width_uv = (width + 1) >> 1;
	const int height_uv = (height + 1) >> 1;
	const double ssim_u = CalcFrameSsim(src_u_a, stride_u_a,
	src_u_b, stride_u_b,
	width_uv, height_uv);
	const double ssim_v = CalcFrameSsim(src_v_a, stride_v_a,
	src_v_b, stride_v_b,
	width_uv, height_uv);
	return ssim_y * 0.8 + 0.1 * (ssim_u + ssim_v);
	}

	#ifdef __cplusplus
	} // extern "C"
	} // namespace libyuv
	#endif