vp8/encoder/ssim.c - platform/external/libvpx - Git at Google

 /*
  *  Copyright (c) 2010 The WebM 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 "vpx_scale/yv12config.h"
 #include "math.h"

 #define C1 (float)(64 * 64 * 0.01*255*0.01*255)
 #define C2 (float)(64 * 64 * 0.03*255*0.03*255)

 static int width_y;
 static int height_y;
 static int height_uv;
 static int width_uv;
 static int stride_uv;
 static int stride;
 static int lumimask;
 static int luminance;
 static double plane_summed_weights = 0;

 static short img12_sum_block[8*4096*4096*2] ;

 static short img1_sum[8*4096*2];
 static short img2_sum[8*4096*2];
 static int   img1_sq_sum[8*4096*2];
 static int   img2_sq_sum[8*4096*2];
 static int   img12_mul_sum[8*4096*2];


 double vp8_similarity
 (
     int mu_x,
     int mu_y,
     int pre_mu_x2,
     int pre_mu_y2,
     int pre_mu_xy2
 )
 {
     int mu_x2, mu_y2, mu_xy, theta_x2, theta_y2, theta_xy;

     mu_x2 = mu_x * mu_x;
     mu_y2 = mu_y * mu_y;
     mu_xy = mu_x * mu_y;

     theta_x2 = 64 * pre_mu_x2 - mu_x2;
     theta_y2 = 64 * pre_mu_y2 - mu_y2;
     theta_xy = 64 * pre_mu_xy2 - mu_xy;

     return (2 * mu_xy + C1) * (2 * theta_xy + C2) / ((mu_x2 + mu_y2 + C1) * (theta_x2 + theta_y2 + C2));
 }

 double vp8_ssim
 (
     const unsigned char *img1,
     const unsigned char *img2,
     int stride_img1,
     int stride_img2,
     int width,
     int height
 )
 {
     int x, y, x2, y2, img1_block, img2_block, img1_sq_block, img2_sq_block, img12_mul_block, temp;

     double plane_quality, weight, mean;

     short *img1_sum_ptr1, *img1_sum_ptr2;
     short *img2_sum_ptr1, *img2_sum_ptr2;
     int *img1_sq_sum_ptr1, *img1_sq_sum_ptr2;
     int *img2_sq_sum_ptr1, *img2_sq_sum_ptr2;
     int *img12_mul_sum_ptr1, *img12_mul_sum_ptr2;

     plane_quality = 0;

     if (lumimask)
         plane_summed_weights = 0.0f;
     else
         plane_summed_weights = (height - 7) * (width - 7);

     //some prologue for the main loop
     temp = 8 * width;

     img1_sum_ptr1      = img1_sum + temp;
     img2_sum_ptr1      = img2_sum + temp;
     img1_sq_sum_ptr1   = img1_sq_sum + temp;
     img2_sq_sum_ptr1   = img2_sq_sum + temp;
     img12_mul_sum_ptr1 = img12_mul_sum + temp;

     for (x = 0; x < width; x++)
     {
         img1_sum[x]      = img1[x];
         img2_sum[x]      = img2[x];
         img1_sq_sum[x]   = img1[x] * img1[x];
         img2_sq_sum[x]   = img2[x] * img2[x];
         img12_mul_sum[x] = img1[x] * img2[x];

         img1_sum_ptr1[x]      = 0;
         img2_sum_ptr1[x]      = 0;
         img1_sq_sum_ptr1[x]   = 0;
         img2_sq_sum_ptr1[x]   = 0;
         img12_mul_sum_ptr1[x] = 0;
     }

     //the main loop
     for (y = 1; y < height; y++)
     {
         img1 += stride_img1;
         img2 += stride_img2;

         temp = (y - 1) % 9 * width;

         img1_sum_ptr1      = img1_sum + temp;
         img2_sum_ptr1      = img2_sum + temp;
         img1_sq_sum_ptr1   = img1_sq_sum + temp;
         img2_sq_sum_ptr1   = img2_sq_sum + temp;
         img12_mul_sum_ptr1 = img12_mul_sum + temp;

         temp = y % 9 * width;

         img1_sum_ptr2      = img1_sum + temp;
         img2_sum_ptr2      = img2_sum + temp;
         img1_sq_sum_ptr2   = img1_sq_sum + temp;
         img2_sq_sum_ptr2   = img2_sq_sum + temp;
         img12_mul_sum_ptr2 = img12_mul_sum + temp;

         for (x = 0; x < width; x++)
         {
             img1_sum_ptr2[x]      = img1_sum_ptr1[x] + img1[x];
             img2_sum_ptr2[x]      = img2_sum_ptr1[x] + img2[x];
             img1_sq_sum_ptr2[x]   = img1_sq_sum_ptr1[x] + img1[x] * img1[x];
             img2_sq_sum_ptr2[x]   = img2_sq_sum_ptr1[x] + img2[x] * img2[x];
             img12_mul_sum_ptr2[x] = img12_mul_sum_ptr1[x] + img1[x] * img2[x];
         }

         if (y > 6)
         {
             //calculate the sum of the last 8 lines by subtracting the total sum of 8 lines back from the present sum
             temp = (y + 1) % 9 * width;

             img1_sum_ptr1      = img1_sum + temp;
             img2_sum_ptr1      = img2_sum + temp;
             img1_sq_sum_ptr1   = img1_sq_sum + temp;
             img2_sq_sum_ptr1   = img2_sq_sum + temp;
             img12_mul_sum_ptr1 = img12_mul_sum + temp;

             for (x = 0; x < width; x++)
             {
                 img1_sum_ptr1[x]      = img1_sum_ptr2[x] - img1_sum_ptr1[x];
                 img2_sum_ptr1[x]      = img2_sum_ptr2[x] - img2_sum_ptr1[x];
                 img1_sq_sum_ptr1[x]   = img1_sq_sum_ptr2[x] - img1_sq_sum_ptr1[x];
                 img2_sq_sum_ptr1[x]   = img2_sq_sum_ptr2[x] - img2_sq_sum_ptr1[x];
                 img12_mul_sum_ptr1[x] = img12_mul_sum_ptr2[x] - img12_mul_sum_ptr1[x];
             }

             //here we calculate the sum over the 8x8 block of pixels
             //this is done by sliding a window across the column sums for the last 8 lines
             //each time adding the new column sum, and subtracting the one which fell out of the window
             img1_block      = 0;
             img2_block      = 0;
             img1_sq_block   = 0;
             img2_sq_block   = 0;
             img12_mul_block = 0;

             //prologue, and calculation of simularity measure from the first 8 column sums
             for (x = 0; x < 8; x++)
             {
                 img1_block      += img1_sum_ptr1[x];
                 img2_block      += img2_sum_ptr1[x];
                 img1_sq_block   += img1_sq_sum_ptr1[x];
                 img2_sq_block   += img2_sq_sum_ptr1[x];
                 img12_mul_block += img12_mul_sum_ptr1[x];
             }

             if (lumimask)
             {
                 y2 = y - 7;
                 x2 = 0;

                 if (luminance)
                 {
                     mean = (img2_block + img1_block) / 128.0f;

                     if (!(y2 % 2 || x2 % 2))
                         *(img12_sum_block + y2 / 2 * width_uv + x2 / 2) = img2_block + img1_block;
                 }
                 else
                 {
                     mean = *(img12_sum_block + y2 * width_uv + x2);
                     mean += *(img12_sum_block + y2 * width_uv + x2 + 4);
                     mean += *(img12_sum_block + (y2 + 4) * width_uv + x2);
                     mean += *(img12_sum_block + (y2 + 4) * width_uv + x2 + 4);

                     mean /= 512.0f;
                 }

                 weight = mean < 40 ? 0.0f :
                          (mean < 50 ? (mean - 40.0f) / 10.0f : 1.0f);
                 plane_summed_weights += weight;

                 plane_quality += weight * vp8_similarity(img1_block, img2_block, img1_sq_block, img2_sq_block, img12_mul_block);
             }
             else
                 plane_quality += vp8_similarity(img1_block, img2_block, img1_sq_block, img2_sq_block, img12_mul_block);

             //and for the rest
             for (x = 8; x < width; x++)
             {
                 img1_block      = img1_block + img1_sum_ptr1[x] - img1_sum_ptr1[x - 8];
                 img2_block      = img2_block + img2_sum_ptr1[x] - img2_sum_ptr1[x - 8];
                 img1_sq_block   = img1_sq_block + img1_sq_sum_ptr1[x] - img1_sq_sum_ptr1[x - 8];
                 img2_sq_block   = img2_sq_block + img2_sq_sum_ptr1[x] - img2_sq_sum_ptr1[x - 8];
                 img12_mul_block = img12_mul_block + img12_mul_sum_ptr1[x] - img12_mul_sum_ptr1[x - 8];

                 if (lumimask)
                 {
                     y2 = y - 7;
                     x2 = x - 7;

                     if (luminance)
                     {
                         mean = (img2_block + img1_block) / 128.0f;

                         if (!(y2 % 2 || x2 % 2))
                             *(img12_sum_block + y2 / 2 * width_uv + x2 / 2) = img2_block + img1_block;
                     }
                     else
                     {
                         mean = *(img12_sum_block + y2 * width_uv + x2);
                         mean += *(img12_sum_block + y2 * width_uv + x2 + 4);
                         mean += *(img12_sum_block + (y2 + 4) * width_uv + x2);
                         mean += *(img12_sum_block + (y2 + 4) * width_uv + x2 + 4);

                         mean /= 512.0f;
                     }

                     weight = mean < 40 ? 0.0f :
                              (mean < 50 ? (mean - 40.0f) / 10.0f : 1.0f);
                     plane_summed_weights += weight;

                     plane_quality += weight * vp8_similarity(img1_block, img2_block, img1_sq_block, img2_sq_block, img12_mul_block);
                 }
                 else
                     plane_quality += vp8_similarity(img1_block, img2_block, img1_sq_block, img2_sq_block, img12_mul_block);
             }
         }
     }

     if (plane_summed_weights == 0)
         return 1.0f;
     else
         return plane_quality / plane_summed_weights;
 }

 double vp8_calc_ssim
 (
     YV12_BUFFER_CONFIG *source,
     YV12_BUFFER_CONFIG *dest,
     int lumamask,
     double *weight
 )
 {
     double a, b, c;
     double frame_weight;
     double ssimv;

     width_y = source->y_width;
     height_y = source->y_height;
     height_uv = source->uv_height;
     width_uv = source->uv_width;
     stride_uv = dest->uv_stride;
     stride = dest->y_stride;

     lumimask = lumamask;

     luminance = 1;
     a = vp8_ssim(source->y_buffer, dest->y_buffer,
                  source->y_stride, dest->y_stride, source->y_width, source->y_height);
     luminance = 0;

     frame_weight = plane_summed_weights / ((width_y - 7) * (height_y - 7));

     if (frame_weight == 0)
         a = b = c = 1.0f;
     else
     {
         b = vp8_ssim(source->u_buffer, dest->u_buffer,
                      source->uv_stride, dest->uv_stride, source->uv_width, source->uv_height);

         c = vp8_ssim(source->v_buffer, dest->v_buffer,
                      source->uv_stride, dest->uv_stride, source->uv_width, source->uv_height);
     }

     ssimv = a * .8 + .1 * (b + c);

     *weight = frame_weight;

     return ssimv;
 }

 // Google version of SSIM
 // SSIM
 #define KERNEL 3
 #define KERNEL_SIZE  (2 * KERNEL + 1)

 typedef unsigned char uint8;
 typedef unsigned int uint32;

 static const int K[KERNEL_SIZE] =
 {
     1, 4, 11, 16, 11, 4, 1    // 16 * exp(-0.3 * i * i)
 };
 static const double ki_w = 1. / 2304.;  // 1 / sum(i:0..6, j..6) K[i]*K[j]
 double get_ssimg(const uint8 *org, const uint8 *rec,
                  int xo, int yo, int W, int H,
                  const int stride1, const int stride2
                 )
 {
     // TODO(skal): use summed tables
     int y, x;

     const int ymin = (yo - KERNEL < 0) ? 0 : yo - KERNEL;
     const int ymax = (yo + KERNEL > H - 1) ? H - 1 : yo + KERNEL;
     const int xmin = (xo - KERNEL < 0) ? 0 : xo - KERNEL;
     const int xmax = (xo + KERNEL > W - 1) ? W - 1 : xo + KERNEL;
     // worst case of accumulation is a weight of 48 = 16 + 2 * (11 + 4 + 1)
     // with a diff of 255, squares. That would a max error of 0x8ee0900,
     // which fits into 32 bits integers.
     uint32 w = 0, xm = 0, ym = 0, xxm = 0, xym = 0, yym = 0;
     org += ymin * stride1;
     rec += ymin * stride2;

     for (y = ymin; y <= ymax; ++y, org += stride1, rec += stride2)
     {
         const int Wy = K[KERNEL + y - yo];

         for (x = xmin; x <= xmax; ++x)
         {
             const  int Wxy = Wy * K[KERNEL + x - xo];
             // TODO(skal): inlined assembly
             w   += Wxy;
             xm  += Wxy * org[x];
             ym  += Wxy * rec[x];
             xxm += Wxy * org[x] * org[x];
             xym += Wxy * org[x] * rec[x];
             yym += Wxy * rec[x] * rec[x];
         }
     }

     {
         const double iw = 1. / w;
         const double iwx = xm * iw;
         const double iwy = ym * iw;
         double sxx = xxm * iw - iwx * iwx;
         double syy = yym * iw - iwy * iwy;

         // small errors are possible, due to rounding. Clamp to zero.
         if (sxx < 0.) sxx = 0.;

         if (syy < 0.) syy = 0.;

         {
             const double sxsy = sqrt(sxx * syy);
             const double sxy = xym * iw - iwx * iwy;
             static const double C11 = (0.01 * 0.01) * (255 * 255);
             static const double C22 = (0.03 * 0.03) * (255 * 255);
             static const double C33 = (0.015 * 0.015) * (255 * 255);
             const double l = (2. * iwx * iwy + C11) / (iwx * iwx + iwy * iwy + C11);
             const double c = (2. * sxsy      + C22) / (sxx + syy + C22);

             const double s = (sxy + C33) / (sxsy + C33);
             return l * c * s;

         }
     }

 }

 double get_ssimfull_kernelg(const uint8 *org, const uint8 *rec,
                             int xo, int yo, int W, int H,
                             const int stride1, const int stride2)
 {
     // TODO(skal): use summed tables
     // worst case of accumulation is a weight of 48 = 16 + 2 * (11 + 4 + 1)
     // with a diff of 255, squares. That would a max error of 0x8ee0900,
     // which fits into 32 bits integers.
     int y_, x_;
     uint32 xm = 0, ym = 0, xxm = 0, xym = 0, yym = 0;
     org += (yo - KERNEL) * stride1;
     org += (xo - KERNEL);
     rec += (yo - KERNEL) * stride2;
     rec += (xo - KERNEL);

     for (y_ = 0; y_ < KERNEL_SIZE; ++y_, org += stride1, rec += stride2)
     {
         const int Wy = K[y_];

         for (x_ = 0; x_ < KERNEL_SIZE; ++x_)
         {
             const int Wxy = Wy * K[x_];
             // TODO(skal): inlined assembly
             const int org_x = org[x_];
             const int rec_x = rec[x_];
             xm  += Wxy * org_x;
             ym  += Wxy * rec_x;
             xxm += Wxy * org_x * org_x;
             xym += Wxy * org_x * rec_x;
             yym += Wxy * rec_x * rec_x;
         }
     }

     {
         const double iw = ki_w;
         const double iwx = xm * iw;
         const double iwy = ym * iw;
         double sxx = xxm * iw - iwx * iwx;
         double syy = yym * iw - iwy * iwy;

         // small errors are possible, due to rounding. Clamp to zero.
         if (sxx < 0.) sxx = 0.;

         if (syy < 0.) syy = 0.;

         {
             const double sxsy = sqrt(sxx * syy);
             const double sxy = xym * iw - iwx * iwy;
             static const double C11 = (0.01 * 0.01) * (255 * 255);
             static const double C22 = (0.03 * 0.03) * (255 * 255);
             static const double C33 = (0.015 * 0.015) * (255 * 255);
             const double l = (2. * iwx * iwy + C11) / (iwx * iwx + iwy * iwy + C11);
             const double c = (2. * sxsy      + C22) / (sxx + syy + C22);
             const double s = (sxy + C33) / (sxsy + C33);
             return l * c * s;
         }
     }
 }

 double calc_ssimg(const uint8 *org, const uint8 *rec,
                   const int image_width, const int image_height,
                   const int stride1, const int stride2
                  )
 {
     int j, i;
     double SSIM = 0.;

     for (j = 0; j < KERNEL; ++j)
     {
         for (i = 0; i < image_width; ++i)
         {
             SSIM += get_ssimg(org, rec, i, j, image_width, image_height, stride1, stride2);
         }
     }

     for (j = KERNEL; j < image_height - KERNEL; ++j)
     {
         for (i = 0; i < KERNEL; ++i)
         {
             SSIM += get_ssimg(org, rec, i, j, image_width, image_height, stride1, stride2);
         }

         for (i = KERNEL; i < image_width - KERNEL; ++i)
         {
             SSIM += get_ssimfull_kernelg(org, rec, i, j,
                                          image_width, image_height, stride1, stride2);
         }

         for (i = image_width - KERNEL; i < image_width; ++i)
         {
             SSIM += get_ssimg(org, rec, i, j, image_width, image_height, stride1, stride2);
         }
     }

     for (j = image_height - KERNEL; j < image_height; ++j)
     {
         for (i = 0; i < image_width; ++i)
         {
             SSIM += get_ssimg(org, rec, i, j, image_width, image_height, stride1, stride2);
         }
     }

     return SSIM;
 }


 double vp8_calc_ssimg
 (
     YV12_BUFFER_CONFIG *source,
     YV12_BUFFER_CONFIG *dest,
     double *ssim_y,
     double *ssim_u,
     double *ssim_v
 )
 {
     double ssim_all = 0;
     int ysize  = source->y_width * source->y_height;
     int uvsize = ysize / 4;

     *ssim_y = calc_ssimg(source->y_buffer, dest->y_buffer,
                          source->y_width, source->y_height,
                          source->y_stride, dest->y_stride);


     *ssim_u = calc_ssimg(source->u_buffer, dest->u_buffer,
                          source->uv_width, source->uv_height,
                          source->uv_stride, dest->uv_stride);


     *ssim_v = calc_ssimg(source->v_buffer, dest->v_buffer,
                          source->uv_width, source->uv_height,
                          source->uv_stride, dest->uv_stride);

     ssim_all = (*ssim_y + *ssim_u + *ssim_v) / (ysize + uvsize + uvsize);
     *ssim_y /= ysize;
     *ssim_u /= uvsize;
     *ssim_v /= uvsize;
     return ssim_all;
 }
	/*
	* Copyright (c) 2010 The WebM 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 "vpx_scale/yv12config.h"
	#include "math.h"

	#define C1 (float)(64 * 64 * 0.012550.01*255)
	#define C2 (float)(64 * 64 * 0.032550.03*255)

	static int width_y;
	static int height_y;
	static int height_uv;
	static int width_uv;
	static int stride_uv;
	static int stride;
	static int lumimask;
	static int luminance;
	static double plane_summed_weights = 0;

	static short img12_sum_block[840964096*2] ;

	static short img1_sum[840962];
	static short img2_sum[840962];
	static int img1_sq_sum[840962];
	static int img2_sq_sum[840962];
	static int img12_mul_sum[840962];


	double vp8_similarity
	(
	int mu_x,
	int mu_y,
	int pre_mu_x2,
	int pre_mu_y2,
	int pre_mu_xy2
	)
	{
	int mu_x2, mu_y2, mu_xy, theta_x2, theta_y2, theta_xy;

	mu_x2 = mu_x * mu_x;
	mu_y2 = mu_y * mu_y;
	mu_xy = mu_x * mu_y;

	theta_x2 = 64 * pre_mu_x2 - mu_x2;
	theta_y2 = 64 * pre_mu_y2 - mu_y2;
	theta_xy = 64 * pre_mu_xy2 - mu_xy;

	return (2 * mu_xy + C1) * (2 * theta_xy + C2) / ((mu_x2 + mu_y2 + C1) * (theta_x2 + theta_y2 + C2));
	}

	double vp8_ssim
	(
	const unsigned char *img1,
	const unsigned char *img2,
	int stride_img1,
	int stride_img2,
	int width,
	int height
	)
	{
	int x, y, x2, y2, img1_block, img2_block, img1_sq_block, img2_sq_block, img12_mul_block, temp;

	double plane_quality, weight, mean;

	short img1_sum_ptr1, img1_sum_ptr2;
	short img2_sum_ptr1, img2_sum_ptr2;
	int img1_sq_sum_ptr1, img1_sq_sum_ptr2;
	int img2_sq_sum_ptr1, img2_sq_sum_ptr2;
	int img12_mul_sum_ptr1, img12_mul_sum_ptr2;

	plane_quality = 0;

	if (lumimask)
	plane_summed_weights = 0.0f;
	else
	plane_summed_weights = (height - 7) * (width - 7);

	//some prologue for the main loop
	temp = 8 * width;

	img1_sum_ptr1 = img1_sum + temp;
	img2_sum_ptr1 = img2_sum + temp;
	img1_sq_sum_ptr1 = img1_sq_sum + temp;
	img2_sq_sum_ptr1 = img2_sq_sum + temp;
	img12_mul_sum_ptr1 = img12_mul_sum + temp;

	for (x = 0; x < width; x++)
	{
	img1_sum[x] = img1[x];
	img2_sum[x] = img2[x];
	img1_sq_sum[x] = img1[x] * img1[x];
	img2_sq_sum[x] = img2[x] * img2[x];
	img12_mul_sum[x] = img1[x] * img2[x];

	img1_sum_ptr1[x] = 0;
	img2_sum_ptr1[x] = 0;
	img1_sq_sum_ptr1[x] = 0;
	img2_sq_sum_ptr1[x] = 0;
	img12_mul_sum_ptr1[x] = 0;
	}

	//the main loop
	for (y = 1; y < height; y++)
	{
	img1 += stride_img1;
	img2 += stride_img2;

	temp = (y - 1) % 9 * width;

	img1_sum_ptr1 = img1_sum + temp;
	img2_sum_ptr1 = img2_sum + temp;
	img1_sq_sum_ptr1 = img1_sq_sum + temp;
	img2_sq_sum_ptr1 = img2_sq_sum + temp;
	img12_mul_sum_ptr1 = img12_mul_sum + temp;

	temp = y % 9 * width;

	img1_sum_ptr2 = img1_sum + temp;
	img2_sum_ptr2 = img2_sum + temp;
	img1_sq_sum_ptr2 = img1_sq_sum + temp;
	img2_sq_sum_ptr2 = img2_sq_sum + temp;
	img12_mul_sum_ptr2 = img12_mul_sum + temp;

	for (x = 0; x < width; x++)
	{
	img1_sum_ptr2[x] = img1_sum_ptr1[x] + img1[x];
	img2_sum_ptr2[x] = img2_sum_ptr1[x] + img2[x];
	img1_sq_sum_ptr2[x] = img1_sq_sum_ptr1[x] + img1[x] * img1[x];
	img2_sq_sum_ptr2[x] = img2_sq_sum_ptr1[x] + img2[x] * img2[x];
	img12_mul_sum_ptr2[x] = img12_mul_sum_ptr1[x] + img1[x] * img2[x];
	}

	if (y > 6)
	{
	//calculate the sum of the last 8 lines by subtracting the total sum of 8 lines back from the present sum
	temp = (y + 1) % 9 * width;

	img1_sum_ptr1 = img1_sum + temp;
	img2_sum_ptr1 = img2_sum + temp;
	img1_sq_sum_ptr1 = img1_sq_sum + temp;
	img2_sq_sum_ptr1 = img2_sq_sum + temp;
	img12_mul_sum_ptr1 = img12_mul_sum + temp;

	for (x = 0; x < width; x++)
	{
	img1_sum_ptr1[x] = img1_sum_ptr2[x] - img1_sum_ptr1[x];
	img2_sum_ptr1[x] = img2_sum_ptr2[x] - img2_sum_ptr1[x];
	img1_sq_sum_ptr1[x] = img1_sq_sum_ptr2[x] - img1_sq_sum_ptr1[x];
	img2_sq_sum_ptr1[x] = img2_sq_sum_ptr2[x] - img2_sq_sum_ptr1[x];
	img12_mul_sum_ptr1[x] = img12_mul_sum_ptr2[x] - img12_mul_sum_ptr1[x];
	}

	//here we calculate the sum over the 8x8 block of pixels
	//this is done by sliding a window across the column sums for the last 8 lines
	//each time adding the new column sum, and subtracting the one which fell out of the window
	img1_block = 0;
	img2_block = 0;
	img1_sq_block = 0;
	img2_sq_block = 0;
	img12_mul_block = 0;

	//prologue, and calculation of simularity measure from the first 8 column sums
	for (x = 0; x < 8; x++)
	{
	img1_block += img1_sum_ptr1[x];
	img2_block += img2_sum_ptr1[x];
	img1_sq_block += img1_sq_sum_ptr1[x];
	img2_sq_block += img2_sq_sum_ptr1[x];
	img12_mul_block += img12_mul_sum_ptr1[x];
	}

	if (lumimask)
	{
	y2 = y - 7;
	x2 = 0;

	if (luminance)
	{
	mean = (img2_block + img1_block) / 128.0f;

	if (!(y2 % 2 \|\| x2 % 2))
	(img12_sum_block + y2 / 2 width_uv + x2 / 2) = img2_block + img1_block;
	}
	else
	{
	mean = (img12_sum_block + y2 width_uv + x2);
	mean += (img12_sum_block + y2 width_uv + x2 + 4);
	mean += (img12_sum_block + (y2 + 4) width_uv + x2);
	mean += (img12_sum_block + (y2 + 4) width_uv + x2 + 4);

	mean /= 512.0f;
	}

	weight = mean < 40 ? 0.0f :
	(mean < 50 ? (mean - 40.0f) / 10.0f : 1.0f);
	plane_summed_weights += weight;

	plane_quality += weight * vp8_similarity(img1_block, img2_block, img1_sq_block, img2_sq_block, img12_mul_block);
	}
	else
	plane_quality += vp8_similarity(img1_block, img2_block, img1_sq_block, img2_sq_block, img12_mul_block);

	//and for the rest
	for (x = 8; x < width; x++)
	{
	img1_block = img1_block + img1_sum_ptr1[x] - img1_sum_ptr1[x - 8];
	img2_block = img2_block + img2_sum_ptr1[x] - img2_sum_ptr1[x - 8];
	img1_sq_block = img1_sq_block + img1_sq_sum_ptr1[x] - img1_sq_sum_ptr1[x - 8];
	img2_sq_block = img2_sq_block + img2_sq_sum_ptr1[x] - img2_sq_sum_ptr1[x - 8];
	img12_mul_block = img12_mul_block + img12_mul_sum_ptr1[x] - img12_mul_sum_ptr1[x - 8];

	if (lumimask)
	{
	y2 = y - 7;
	x2 = x - 7;

	if (luminance)
	{
	mean = (img2_block + img1_block) / 128.0f;

	if (!(y2 % 2 \|\| x2 % 2))
	(img12_sum_block + y2 / 2 width_uv + x2 / 2) = img2_block + img1_block;
	}
	else
	{
	mean = (img12_sum_block + y2 width_uv + x2);
	mean += (img12_sum_block + y2 width_uv + x2 + 4);
	mean += (img12_sum_block + (y2 + 4) width_uv + x2);
	mean += (img12_sum_block + (y2 + 4) width_uv + x2 + 4);

	mean /= 512.0f;
	}

	weight = mean < 40 ? 0.0f :
	(mean < 50 ? (mean - 40.0f) / 10.0f : 1.0f);
	plane_summed_weights += weight;

	plane_quality += weight * vp8_similarity(img1_block, img2_block, img1_sq_block, img2_sq_block, img12_mul_block);
	}
	else
	plane_quality += vp8_similarity(img1_block, img2_block, img1_sq_block, img2_sq_block, img12_mul_block);
	}
	}
	}

	if (plane_summed_weights == 0)
	return 1.0f;
	else
	return plane_quality / plane_summed_weights;
	}

	double vp8_calc_ssim
	(
	YV12_BUFFER_CONFIG *source,
	YV12_BUFFER_CONFIG *dest,
	int lumamask,
	double *weight
	)
	{
	double a, b, c;
	double frame_weight;
	double ssimv;

	width_y = source->y_width;
	height_y = source->y_height;
	height_uv = source->uv_height;
	width_uv = source->uv_width;
	stride_uv = dest->uv_stride;
	stride = dest->y_stride;

	lumimask = lumamask;

	luminance = 1;
	a = vp8_ssim(source->y_buffer, dest->y_buffer,
	source->y_stride, dest->y_stride, source->y_width, source->y_height);
	luminance = 0;

	frame_weight = plane_summed_weights / ((width_y - 7) * (height_y - 7));

	if (frame_weight == 0)
	a = b = c = 1.0f;
	else
	{
	b = vp8_ssim(source->u_buffer, dest->u_buffer,
	source->uv_stride, dest->uv_stride, source->uv_width, source->uv_height);

	c = vp8_ssim(source->v_buffer, dest->v_buffer,
	source->uv_stride, dest->uv_stride, source->uv_width, source->uv_height);
	}

	ssimv = a * .8 + .1 * (b + c);

	*weight = frame_weight;

	return ssimv;
	}

	// Google version of SSIM
	// SSIM
	#define KERNEL 3
	#define KERNEL_SIZE (2 * KERNEL + 1)

	typedef unsigned char uint8;
	typedef unsigned int uint32;

	static const int K[KERNEL_SIZE] =
	{
	1, 4, 11, 16, 11, 4, 1 // 16 * exp(-0.3 * i * i)
	};
	static const double ki_w = 1. / 2304.; // 1 / sum(i:0..6, j..6) K[i]*K[j]
	double get_ssimg(const uint8 org, const uint8 rec,
	int xo, int yo, int W, int H,
	const int stride1, const int stride2
	)
	{
	// TODO(skal): use summed tables
	int y, x;

	const int ymin = (yo - KERNEL < 0) ? 0 : yo - KERNEL;
	const int ymax = (yo + KERNEL > H - 1) ? H - 1 : yo + KERNEL;
	const int xmin = (xo - KERNEL < 0) ? 0 : xo - KERNEL;
	const int xmax = (xo + KERNEL > W - 1) ? W - 1 : xo + KERNEL;
	// worst case of accumulation is a weight of 48 = 16 + 2 * (11 + 4 + 1)
	// with a diff of 255, squares. That would a max error of 0x8ee0900,
	// which fits into 32 bits integers.
	uint32 w = 0, xm = 0, ym = 0, xxm = 0, xym = 0, yym = 0;
	org += ymin * stride1;
	rec += ymin * stride2;

	for (y = ymin; y <= ymax; ++y, org += stride1, rec += stride2)
	{
	const int Wy = K[KERNEL + y - yo];

	for (x = xmin; x <= xmax; ++x)
	{
	const int Wxy = Wy * K[KERNEL + x - xo];
	// TODO(skal): inlined assembly
	w += Wxy;
	xm += Wxy * org[x];
	ym += Wxy * rec[x];
	xxm += Wxy * org[x] * org[x];
	xym += Wxy * org[x] * rec[x];
	yym += Wxy * rec[x] * rec[x];
	}
	}

	{
	const double iw = 1. / w;
	const double iwx = xm * iw;
	const double iwy = ym * iw;
	double sxx = xxm * iw - iwx * iwx;
	double syy = yym * iw - iwy * iwy;

	// small errors are possible, due to rounding. Clamp to zero.
	if (sxx < 0.) sxx = 0.;

	if (syy < 0.) syy = 0.;

	{
	const double sxsy = sqrt(sxx * syy);
	const double sxy = xym * iw - iwx * iwy;
	static const double C11 = (0.01 * 0.01) * (255 * 255);
	static const double C22 = (0.03 * 0.03) * (255 * 255);
	static const double C33 = (0.015 * 0.015) * (255 * 255);
	const double l = (2. * iwx * iwy + C11) / (iwx * iwx + iwy * iwy + C11);
	const double c = (2. * sxsy + C22) / (sxx + syy + C22);

	const double s = (sxy + C33) / (sxsy + C33);
	return l * c * s;

	}
	}

	}

	double get_ssimfull_kernelg(const uint8 org, const uint8 rec,
	int xo, int yo, int W, int H,
	const int stride1, const int stride2)
	{
	// TODO(skal): use summed tables
	// worst case of accumulation is a weight of 48 = 16 + 2 * (11 + 4 + 1)
	// with a diff of 255, squares. That would a max error of 0x8ee0900,
	// which fits into 32 bits integers.
	int y_, x_;
	uint32 xm = 0, ym = 0, xxm = 0, xym = 0, yym = 0;
	org += (yo - KERNEL) * stride1;
	org += (xo - KERNEL);
	rec += (yo - KERNEL) * stride2;
	rec += (xo - KERNEL);

	for (y_ = 0; y_ < KERNEL_SIZE; ++y_, org += stride1, rec += stride2)
	{
	const int Wy = K[y_];

	for (x_ = 0; x_ < KERNEL_SIZE; ++x_)
	{
	const int Wxy = Wy * K[x_];
	// TODO(skal): inlined assembly
	const int org_x = org[x_];
	const int rec_x = rec[x_];
	xm += Wxy * org_x;
	ym += Wxy * rec_x;
	xxm += Wxy * org_x * org_x;
	xym += Wxy * org_x * rec_x;
	yym += Wxy * rec_x * rec_x;
	}
	}

	{
	const double iw = ki_w;
	const double iwx = xm * iw;
	const double iwy = ym * iw;
	double sxx = xxm * iw - iwx * iwx;
	double syy = yym * iw - iwy * iwy;

	// small errors are possible, due to rounding. Clamp to zero.
	if (sxx < 0.) sxx = 0.;

	if (syy < 0.) syy = 0.;

	{
	const double sxsy = sqrt(sxx * syy);
	const double sxy = xym * iw - iwx * iwy;
	static const double C11 = (0.01 * 0.01) * (255 * 255);
	static const double C22 = (0.03 * 0.03) * (255 * 255);
	static const double C33 = (0.015 * 0.015) * (255 * 255);
	const double l = (2. * iwx * iwy + C11) / (iwx * iwx + iwy * iwy + C11);
	const double c = (2. * sxsy + C22) / (sxx + syy + C22);
	const double s = (sxy + C33) / (sxsy + C33);
	return l * c * s;
	}
	}
	}

	double calc_ssimg(const uint8 org, const uint8 rec,
	const int image_width, const int image_height,
	const int stride1, const int stride2
	)
	{
	int j, i;
	double SSIM = 0.;

	for (j = 0; j < KERNEL; ++j)
	{
	for (i = 0; i < image_width; ++i)
	{
	SSIM += get_ssimg(org, rec, i, j, image_width, image_height, stride1, stride2);
	}
	}

	for (j = KERNEL; j < image_height - KERNEL; ++j)
	{
	for (i = 0; i < KERNEL; ++i)
	{
	SSIM += get_ssimg(org, rec, i, j, image_width, image_height, stride1, stride2);
	}

	for (i = KERNEL; i < image_width - KERNEL; ++i)
	{
	SSIM += get_ssimfull_kernelg(org, rec, i, j,
	image_width, image_height, stride1, stride2);
	}

	for (i = image_width - KERNEL; i < image_width; ++i)
	{
	SSIM += get_ssimg(org, rec, i, j, image_width, image_height, stride1, stride2);
	}
	}

	for (j = image_height - KERNEL; j < image_height; ++j)
	{
	for (i = 0; i < image_width; ++i)
	{
	SSIM += get_ssimg(org, rec, i, j, image_width, image_height, stride1, stride2);
	}
	}

	return SSIM;
	}


	double vp8_calc_ssimg
	(
	YV12_BUFFER_CONFIG *source,
	YV12_BUFFER_CONFIG *dest,
	double *ssim_y,
	double *ssim_u,
	double *ssim_v
	)
	{
	double ssim_all = 0;
	int ysize = source->y_width * source->y_height;
	int uvsize = ysize / 4;

	*ssim_y = calc_ssimg(source->y_buffer, dest->y_buffer,
	source->y_width, source->y_height,
	source->y_stride, dest->y_stride);


	*ssim_u = calc_ssimg(source->u_buffer, dest->u_buffer,
	source->uv_width, source->uv_height,
	source->uv_stride, dest->uv_stride);


	*ssim_v = calc_ssimg(source->v_buffer, dest->v_buffer,
	source->uv_width, source->uv_height,
	source->uv_stride, dest->uv_stride);

	ssim_all = (ssim_y + ssim_u + *ssim_v) / (ysize + uvsize + uvsize);
	*ssim_y /= ysize;
	*ssim_u /= uvsize;
	*ssim_v /= uvsize;
	return ssim_all;
	}