av1/common/cdef_block.c - aom - Git at Google

 /*
  * Copyright (c) 2016, Alliance for Open Media. All rights reserved
  *
  * This source code is subject to the terms of the BSD 2 Clause License and
  * the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License
  * was not distributed with this source code in the LICENSE file, you can
  * obtain it at www.aomedia.org/license/software. If the Alliance for Open
  * Media Patent License 1.0 was not distributed with this source code in the
  * PATENTS file, you can obtain it at www.aomedia.org/license/patent.
  */

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

 #include "config/aom_dsp_rtcd.h"
 #include "config/av1_rtcd.h"

 #include "av1/common/cdef.h"
 /*
 This is Cdef_Directions (section 7.15.3) with 2 padding entries at the
 beginning and end of the table. The cdef direction range is [0, 7] and the
 first index is offset +/-2. This removes the need to constrain the first
 index to the same range using e.g., & 7.
 */
 DECLARE_ALIGNED(16, const int, cdef_directions_padded[12][2]) = {
   /* Padding: cdef_directions[6] */
   { 1 * CDEF_BSTRIDE + 0, 2 * CDEF_BSTRIDE + 0 },
   /* Padding: cdef_directions[7] */
   { 1 * CDEF_BSTRIDE + 0, 2 * CDEF_BSTRIDE - 1 },

   /* Begin cdef_directions */
   { -1 * CDEF_BSTRIDE + 1, -2 * CDEF_BSTRIDE + 2 },
   { 0 * CDEF_BSTRIDE + 1, -1 * CDEF_BSTRIDE + 2 },
   { 0 * CDEF_BSTRIDE + 1, 0 * CDEF_BSTRIDE + 2 },
   { 0 * CDEF_BSTRIDE + 1, 1 * CDEF_BSTRIDE + 2 },
   { 1 * CDEF_BSTRIDE + 1, 2 * CDEF_BSTRIDE + 2 },
   { 1 * CDEF_BSTRIDE + 0, 2 * CDEF_BSTRIDE + 1 },
   { 1 * CDEF_BSTRIDE + 0, 2 * CDEF_BSTRIDE + 0 },
   { 1 * CDEF_BSTRIDE + 0, 2 * CDEF_BSTRIDE - 1 },
   /* End cdef_directions */

   /* Padding: cdef_directions[0] */
   { -1 * CDEF_BSTRIDE + 1, -2 * CDEF_BSTRIDE + 2 },
   /* Padding: cdef_directions[1] */
   { 0 * CDEF_BSTRIDE + 1, -1 * CDEF_BSTRIDE + 2 },
 };

 const int (*const cdef_directions)[2] = cdef_directions_padded + 2;

 /* Detect direction. 0 means 45-degree up-right, 2 is horizontal, and so on.
    The search minimizes the weighted variance along all the lines in a
    particular direction, i.e. the squared error between the input and a
    "predicted" block where each pixel is replaced by the average along a line
    in a particular direction. Since each direction have the same sum(x^2) term,
    that term is never computed. See Section 2, step 2, of:
    http://jmvalin.ca/notes/intra_paint.pdf */
 int cdef_find_dir_c(const uint16_t *img, int stride, int32_t *var,
                     int coeff_shift) {
   int i;
   int32_t cost[8] = { 0 };
   int partial[8][15] = { { 0 } };
   int32_t best_cost = 0;
   int best_dir = 0;
   /* Instead of dividing by n between 2 and 8, we multiply by 3*5*7*8/n.
      The output is then 840 times larger, but we don't care for finding
      the max. */
   static const int div_table[] = { 0, 840, 420, 280, 210, 168, 140, 120, 105 };
   for (i = 0; i < 8; i++) {
     int j;
     for (j = 0; j < 8; j++) {
       int x;
       /* We subtract 128 here to reduce the maximum range of the squared
          partial sums. */
       x = (img[i * stride + j] >> coeff_shift) - 128;
       partial[0][i + j] += x;
       partial[1][i + j / 2] += x;
       partial[2][i] += x;
       partial[3][3 + i - j / 2] += x;
       partial[4][7 + i - j] += x;
       partial[5][3 - i / 2 + j] += x;
       partial[6][j] += x;
       partial[7][i / 2 + j] += x;
     }
   }
   for (i = 0; i < 8; i++) {
     cost[2] += partial[2][i] * partial[2][i];
     cost[6] += partial[6][i] * partial[6][i];
   }
   cost[2] *= div_table[8];
   cost[6] *= div_table[8];
   for (i = 0; i < 7; i++) {
     cost[0] += (partial[0][i] * partial[0][i] +
                 partial[0][14 - i] * partial[0][14 - i]) *
                div_table[i + 1];
     cost[4] += (partial[4][i] * partial[4][i] +
                 partial[4][14 - i] * partial[4][14 - i]) *
                div_table[i + 1];
   }
   cost[0] += partial[0][7] * partial[0][7] * div_table[8];
   cost[4] += partial[4][7] * partial[4][7] * div_table[8];
   for (i = 1; i < 8; i += 2) {
     int j;
     for (j = 0; j < 4 + 1; j++) {
       cost[i] += partial[i][3 + j] * partial[i][3 + j];
     }
     cost[i] *= div_table[8];
     for (j = 0; j < 4 - 1; j++) {
       cost[i] += (partial[i][j] * partial[i][j] +
                   partial[i][10 - j] * partial[i][10 - j]) *
                  div_table[2 * j + 2];
     }
   }
   for (i = 0; i < 8; i++) {
     if (cost[i] > best_cost) {
       best_cost = cost[i];
       best_dir = i;
     }
   }
   /* Difference between the optimal variance and the variance along the
      orthogonal direction. Again, the sum(x^2) terms cancel out. */
   *var = best_cost - cost[(best_dir + 4) & 7];
   /* We'd normally divide by 840, but dividing by 1024 is close enough
      for what we're going to do with this. */
   *var >>= 10;
   return best_dir;
 }

 void cdef_find_dir_dual_c(const uint16_t *img1, const uint16_t *img2,
                           int stride, int32_t *var1, int32_t *var2,
                           int coeff_shift, int *out1, int *out2) {
   *out1 = cdef_find_dir_c(img1, stride, var1, coeff_shift);
   *out2 = cdef_find_dir_c(img2, stride, var2, coeff_shift);
 }

 const int cdef_pri_taps[2][2] = { { 4, 2 }, { 3, 3 } };
 const int cdef_sec_taps[2] = { 2, 1 };

 /* Smooth in the direction detected. */
 static void cdef_filter_block_internal(
     uint8_t *dst8, uint16_t *dst16, int dstride, const uint16_t *in,
     int pri_strength, int sec_strength, int dir, int pri_damping,
     int sec_damping, int coeff_shift, int block_width, int block_height,
     int enable_primary, int enable_secondary) {
   const int clipping_required = (enable_primary && enable_secondary);
   int i, j, k;
   const int s = CDEF_BSTRIDE;
   const int *pri_taps = cdef_pri_taps[(pri_strength >> coeff_shift) & 1];
   const int *sec_taps = cdef_sec_taps;
   for (i = 0; i < block_height; i++) {
     for (j = 0; j < block_width; j++) {
       int16_t sum = 0;
       int16_t y;
       int16_t x = in[i * s + j];
       int max = x;
       int min = x;
       for (k = 0; k < 2; k++) {
         if (enable_primary) {
           int16_t p0 = in[i * s + j + cdef_directions[dir][k]];
           int16_t p1 = in[i * s + j - cdef_directions[dir][k]];
           sum += pri_taps[k] * constrain(p0 - x, pri_strength, pri_damping);
           sum += pri_taps[k] * constrain(p1 - x, pri_strength, pri_damping);
           if (clipping_required) {
             if (p0 != CDEF_VERY_LARGE) max = AOMMAX(p0, max);
             if (p1 != CDEF_VERY_LARGE) max = AOMMAX(p1, max);
             min = AOMMIN(p0, min);
             min = AOMMIN(p1, min);
           }
         }
         if (enable_secondary) {
           int16_t s0 = in[i * s + j + cdef_directions[dir + 2][k]];
           int16_t s1 = in[i * s + j - cdef_directions[dir + 2][k]];
           int16_t s2 = in[i * s + j + cdef_directions[dir - 2][k]];
           int16_t s3 = in[i * s + j - cdef_directions[dir - 2][k]];
           if (clipping_required) {
             if (s0 != CDEF_VERY_LARGE) max = AOMMAX(s0, max);
             if (s1 != CDEF_VERY_LARGE) max = AOMMAX(s1, max);
             if (s2 != CDEF_VERY_LARGE) max = AOMMAX(s2, max);
             if (s3 != CDEF_VERY_LARGE) max = AOMMAX(s3, max);
             min = AOMMIN(s0, min);
             min = AOMMIN(s1, min);
             min = AOMMIN(s2, min);
             min = AOMMIN(s3, min);
           }
           sum += sec_taps[k] * constrain(s0 - x, sec_strength, sec_damping);
           sum += sec_taps[k] * constrain(s1 - x, sec_strength, sec_damping);
           sum += sec_taps[k] * constrain(s2 - x, sec_strength, sec_damping);
           sum += sec_taps[k] * constrain(s3 - x, sec_strength, sec_damping);
         }
       }
       y = ((int16_t)x + ((8 + sum - (sum < 0)) >> 4));
       if (clipping_required) {
         y = clamp(y, min, max);
       }

       if (dst8)
         dst8[i * dstride + j] = (uint8_t)y;
       else
         dst16[i * dstride + j] = (uint16_t)y;
     }
   }
 }

 void cdef_filter_8_0_c(void *dst8, int dstride, const uint16_t *in,
                        int pri_strength, int sec_strength, int dir,
                        int pri_damping, int sec_damping, int coeff_shift,
                        int block_width, int block_height) {
   cdef_filter_block_internal((uint8_t *)dst8, NULL, dstride, in, pri_strength,
                              sec_strength, dir, pri_damping, sec_damping,
                              coeff_shift, block_width, block_height,
                              /*enable_primary=*/1, /*enable_secondary=*/1);
 }

 void cdef_filter_8_1_c(void *dst8, int dstride, const uint16_t *in,
                        int pri_strength, int sec_strength, int dir,
                        int pri_damping, int sec_damping, int coeff_shift,
                        int block_width, int block_height) {
   cdef_filter_block_internal((uint8_t *)dst8, NULL, dstride, in, pri_strength,
                              sec_strength, dir, pri_damping, sec_damping,
                              coeff_shift, block_width, block_height,
                              /*enable_primary=*/1, /*enable_secondary=*/0);
 }

 void cdef_filter_8_2_c(void *dst8, int dstride, const uint16_t *in,
                        int pri_strength, int sec_strength, int dir,
                        int pri_damping, int sec_damping, int coeff_shift,
                        int block_width, int block_height) {
   cdef_filter_block_internal((uint8_t *)dst8, NULL, dstride, in, pri_strength,
                              sec_strength, dir, pri_damping, sec_damping,
                              coeff_shift, block_width, block_height,
                              /*enable_primary=*/0, /*enable_secondary=*/1);
 }

 void cdef_filter_8_3_c(void *dst8, int dstride, const uint16_t *in,
                        int pri_strength, int sec_strength, int dir,
                        int pri_damping, int sec_damping, int coeff_shift,
                        int block_width, int block_height) {
   cdef_filter_block_internal((uint8_t *)dst8, NULL, dstride, in, pri_strength,
                              sec_strength, dir, pri_damping, sec_damping,
                              coeff_shift, block_width, block_height,
                              /*enable_primary=*/0, /*enable_secondary=*/0);
 }

 void cdef_filter_16_0_c(void *dst16, int dstride, const uint16_t *in,
                         int pri_strength, int sec_strength, int dir,
                         int pri_damping, int sec_damping, int coeff_shift,
                         int block_width, int block_height) {
   cdef_filter_block_internal(NULL, (uint16_t *)dst16, dstride, in, pri_strength,
                              sec_strength, dir, pri_damping, sec_damping,
                              coeff_shift, block_width, block_height,
                              /*enable_primary=*/1, /*enable_secondary=*/1);
 }

 void cdef_filter_16_1_c(void *dst16, int dstride, const uint16_t *in,
                         int pri_strength, int sec_strength, int dir,
                         int pri_damping, int sec_damping, int coeff_shift,
                         int block_width, int block_height) {
   cdef_filter_block_internal(NULL, (uint16_t *)dst16, dstride, in, pri_strength,
                              sec_strength, dir, pri_damping, sec_damping,
                              coeff_shift, block_width, block_height,
                              /*enable_primary=*/1, /*enable_secondary=*/0);
 }

 void cdef_filter_16_2_c(void *dst16, int dstride, const uint16_t *in,
                         int pri_strength, int sec_strength, int dir,
                         int pri_damping, int sec_damping, int coeff_shift,
                         int block_width, int block_height) {
   cdef_filter_block_internal(NULL, (uint16_t *)dst16, dstride, in, pri_strength,
                              sec_strength, dir, pri_damping, sec_damping,
                              coeff_shift, block_width, block_height,
                              /*enable_primary=*/0, /*enable_secondary=*/1);
 }

 void cdef_filter_16_3_c(void *dst16, int dstride, const uint16_t *in,
                         int pri_strength, int sec_strength, int dir,
                         int pri_damping, int sec_damping, int coeff_shift,
                         int block_width, int block_height) {
   cdef_filter_block_internal(NULL, (uint16_t *)dst16, dstride, in, pri_strength,
                              sec_strength, dir, pri_damping, sec_damping,
                              coeff_shift, block_width, block_height,
                              /*enable_primary=*/0, /*enable_secondary=*/0);
 }

 /* Compute the primary filter strength for an 8x8 block based on the
    directional variance difference. A high variance difference means
    that we have a highly directional pattern (e.g. a high contrast
    edge), so we can apply more deringing. A low variance means that we
    either have a low contrast edge, or a non-directional texture, so
    we want to be careful not to blur. */
 static INLINE int adjust_strength(int strength, int32_t var) {
   const int i = var >> 6 ? AOMMIN(get_msb(var >> 6), 12) : 0;
   /* We use the variance of 8x8 blocks to adjust the strength. */
   return var ? (strength * (4 + i) + 8) >> 4 : 0;
 }

 static AOM_INLINE void aom_cdef_find_dir(const uint16_t *in, cdef_list *dlist,
                                          int var[CDEF_NBLOCKS][CDEF_NBLOCKS],
                                          int cdef_count, int coeff_shift,
                                          int dir[CDEF_NBLOCKS][CDEF_NBLOCKS]) {
   int bi;

   // Find direction of two 8x8 blocks together.
   for (bi = 0; bi < cdef_count - 1; bi += 2) {
     const int by = dlist[bi].by;
     const int bx = dlist[bi].bx;
     const int by2 = dlist[bi + 1].by;
     const int bx2 = dlist[bi + 1].bx;
     const int pos1 = 8 * by * CDEF_BSTRIDE + 8 * bx;
     const int pos2 = 8 * by2 * CDEF_BSTRIDE + 8 * bx2;
     cdef_find_dir_dual(&in[pos1], &in[pos2], CDEF_BSTRIDE, &var[by][bx],
                        &var[by2][bx2], coeff_shift, &dir[by][bx],
                        &dir[by2][bx2]);
   }

   // Process remaining 8x8 blocks here. One 8x8 at a time.
   if (cdef_count % 2) {
     const int by = dlist[bi].by;
     const int bx = dlist[bi].bx;
     dir[by][bx] = cdef_find_dir(&in[8 * by * CDEF_BSTRIDE + 8 * bx],
                                 CDEF_BSTRIDE, &var[by][bx], coeff_shift);
   }
 }

 void av1_cdef_filter_fb(uint8_t *dst8, uint16_t *dst16, int dstride,
                         const uint16_t *in, int xdec, int ydec,
                         int dir[CDEF_NBLOCKS][CDEF_NBLOCKS], int *dirinit,
                         int var[CDEF_NBLOCKS][CDEF_NBLOCKS], int pli,
                         cdef_list *dlist, int cdef_count, int level,
                         int sec_strength, int damping, int coeff_shift) {
   int bi;
   int bx;
   int by;
   const int pri_strength = level << coeff_shift;
   sec_strength <<= coeff_shift;
   damping += coeff_shift - (pli != AOM_PLANE_Y);
   const int bw_log2 = 3 - xdec;
   const int bh_log2 = 3 - ydec;
   if (dirinit && pri_strength == 0 && sec_strength == 0) {
     // If we're here, both primary and secondary strengths are 0, and
     // we still haven't written anything to y[] yet, so we just copy
     // the input to y[]. This is necessary only for av1_cdef_search()
     // and only av1_cdef_search() sets dirinit.
     for (bi = 0; bi < cdef_count; bi++) {
       by = dlist[bi].by;
       bx = dlist[bi].bx;
       // TODO(stemidts/jmvalin): SIMD optimisations
       for (int iy = 0; iy < 1 << bh_log2; iy++) {
         memcpy(&dst16[(bi << (bw_log2 + bh_log2)) + (iy << bw_log2)],
                &in[((by << bh_log2) + iy) * CDEF_BSTRIDE + (bx << bw_log2)],
                ((size_t)1 << bw_log2) * sizeof(*dst16));
       }
     }
     return;
   }

   if (pli == 0) {
     if (!dirinit || !*dirinit) {
       aom_cdef_find_dir(in, dlist, var, cdef_count, coeff_shift, dir);
       if (dirinit) *dirinit = 1;
     }
   }
   if (pli == 1 && xdec != ydec) {
     for (bi = 0; bi < cdef_count; bi++) {
       static const int conv422[8] = { 7, 0, 2, 4, 5, 6, 6, 6 };
       static const int conv440[8] = { 1, 2, 2, 2, 3, 4, 6, 0 };
       by = dlist[bi].by;
       bx = dlist[bi].bx;
       dir[by][bx] = (xdec ? conv422 : conv440)[dir[by][bx]];
     }
   }

   if (dst8) {
     const int block_width = 8 >> xdec;
     const int block_height = 8 >> ydec;
     /*
      * strength_index == 0 : enable_primary = 1, enable_secondary = 1
      * strength_index == 1 : enable_primary = 1, enable_secondary = 0
      * strength_index == 2 : enable_primary = 0, enable_secondary = 1
      * strength_index == 3 : enable_primary = 0, enable_secondary = 0
      */
     const cdef_filter_block_func cdef_filter_fn[4] = {
       cdef_filter_8_0, cdef_filter_8_1, cdef_filter_8_2, cdef_filter_8_3
     };

     for (bi = 0; bi < cdef_count; bi++) {
       by = dlist[bi].by;
       bx = dlist[bi].bx;
       const int t =
           (pli ? pri_strength : adjust_strength(pri_strength, var[by][bx]));
       const int strength_index = (sec_strength == 0) | ((t == 0) << 1);

       cdef_filter_fn[strength_index](
           &dst8[(by << bh_log2) * dstride + (bx << bw_log2)], dstride,
           &in[(by * CDEF_BSTRIDE << bh_log2) + (bx << bw_log2)], t,
           sec_strength, pri_strength ? dir[by][bx] : 0, damping, damping,
           coeff_shift, block_width, block_height);
     }
   } else {
     const int block_width = 8 >> xdec;
     const int block_height = 8 >> ydec;
     /*
      * strength_index == 0 : enable_primary = 1, enable_secondary = 1
      * strength_index == 1 : enable_primary = 1, enable_secondary = 0
      * strength_index == 2 : enable_primary = 0, enable_secondary = 1
      * strength_index == 3 : enable_primary = 0, enable_secondary = 0
      */
     const cdef_filter_block_func cdef_filter_fn[4] = {
       cdef_filter_16_0, cdef_filter_16_1, cdef_filter_16_2, cdef_filter_16_3
     };

     for (bi = 0; bi < cdef_count; bi++) {
       by = dlist[bi].by;
       bx = dlist[bi].bx;
       const int t =
           (pli ? pri_strength : adjust_strength(pri_strength, var[by][bx]));
       const int strength_index = (sec_strength == 0) | ((t == 0) << 1);

       cdef_filter_fn[strength_index](
           &dst16[dirinit ? bi << (bw_log2 + bh_log2)
                          : (by << bh_log2) * dstride + (bx << bw_log2)],
           dirinit ? 1 << bw_log2 : dstride,
           &in[(by * CDEF_BSTRIDE << bh_log2) + (bx << bw_log2)], t,
           sec_strength, pri_strength ? dir[by][bx] : 0, damping, damping,
           coeff_shift, block_width, block_height);
     }
   }
 }
	/*
	* Copyright (c) 2016, Alliance for Open Media. All rights reserved
	*
	* This source code is subject to the terms of the BSD 2 Clause License and
	* the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License
	* was not distributed with this source code in the LICENSE file, you can
	* obtain it at www.aomedia.org/license/software. If the Alliance for Open
	* Media Patent License 1.0 was not distributed with this source code in the
	* PATENTS file, you can obtain it at www.aomedia.org/license/patent.
	*/

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

	#include "config/aom_dsp_rtcd.h"
	#include "config/av1_rtcd.h"

	#include "av1/common/cdef.h"
	/*
	This is Cdef_Directions (section 7.15.3) with 2 padding entries at the
	beginning and end of the table. The cdef direction range is [0, 7] and the
	first index is offset +/-2. This removes the need to constrain the first
	index to the same range using e.g., & 7.
	*/
	DECLARE_ALIGNED(16, const int, cdef_directions_padded[12][2]) = {
	/* Padding: cdef_directions[6] */
	{ 1 * CDEF_BSTRIDE + 0, 2 * CDEF_BSTRIDE + 0 },
	/* Padding: cdef_directions[7] */
	{ 1 * CDEF_BSTRIDE + 0, 2 * CDEF_BSTRIDE - 1 },

	/* Begin cdef_directions */
	{ -1 * CDEF_BSTRIDE + 1, -2 * CDEF_BSTRIDE + 2 },
	{ 0 * CDEF_BSTRIDE + 1, -1 * CDEF_BSTRIDE + 2 },
	{ 0 * CDEF_BSTRIDE + 1, 0 * CDEF_BSTRIDE + 2 },
	{ 0 * CDEF_BSTRIDE + 1, 1 * CDEF_BSTRIDE + 2 },
	{ 1 * CDEF_BSTRIDE + 1, 2 * CDEF_BSTRIDE + 2 },
	{ 1 * CDEF_BSTRIDE + 0, 2 * CDEF_BSTRIDE + 1 },
	{ 1 * CDEF_BSTRIDE + 0, 2 * CDEF_BSTRIDE + 0 },
	{ 1 * CDEF_BSTRIDE + 0, 2 * CDEF_BSTRIDE - 1 },
	/* End cdef_directions */

	/* Padding: cdef_directions[0] */
	{ -1 * CDEF_BSTRIDE + 1, -2 * CDEF_BSTRIDE + 2 },
	/* Padding: cdef_directions[1] */
	{ 0 * CDEF_BSTRIDE + 1, -1 * CDEF_BSTRIDE + 2 },
	};

	const int (*const cdef_directions)[2] = cdef_directions_padded + 2;

	/* Detect direction. 0 means 45-degree up-right, 2 is horizontal, and so on.
	The search minimizes the weighted variance along all the lines in a
	particular direction, i.e. the squared error between the input and a
	"predicted" block where each pixel is replaced by the average along a line
	in a particular direction. Since each direction have the same sum(x^2) term,
	that term is never computed. See Section 2, step 2, of:
	http://jmvalin.ca/notes/intra_paint.pdf */
	int cdef_find_dir_c(const uint16_t img, int stride, int32_t var,
	int coeff_shift) {
	int i;
	int32_t cost[8] = { 0 };
	int partial[8][15] = { { 0 } };
	int32_t best_cost = 0;
	int best_dir = 0;
	/* Instead of dividing by n between 2 and 8, we multiply by 357*8/n.
	The output is then 840 times larger, but we don't care for finding
	the max. */
	static const int div_table[] = { 0, 840, 420, 280, 210, 168, 140, 120, 105 };
	for (i = 0; i < 8; i++) {
	int j;
	for (j = 0; j < 8; j++) {
	int x;
	/* We subtract 128 here to reduce the maximum range of the squared
	partial sums. */
	x = (img[i * stride + j] >> coeff_shift) - 128;
	partial[0][i + j] += x;
	partial[1][i + j / 2] += x;
	partial[2][i] += x;
	partial[3][3 + i - j / 2] += x;
	partial[4][7 + i - j] += x;
	partial[5][3 - i / 2 + j] += x;
	partial[6][j] += x;
	partial[7][i / 2 + j] += x;
	}
	}
	for (i = 0; i < 8; i++) {
	cost[2] += partial[2][i] * partial[2][i];
	cost[6] += partial[6][i] * partial[6][i];
	}
	cost[2] *= div_table[8];
	cost[6] *= div_table[8];
	for (i = 0; i < 7; i++) {
	cost[0] += (partial[0][i] * partial[0][i] +
	partial[0][14 - i] * partial[0][14 - i]) *
	div_table[i + 1];
	cost[4] += (partial[4][i] * partial[4][i] +
	partial[4][14 - i] * partial[4][14 - i]) *
	div_table[i + 1];
	}
	cost[0] += partial[0][7] * partial[0][7] * div_table[8];
	cost[4] += partial[4][7] * partial[4][7] * div_table[8];
	for (i = 1; i < 8; i += 2) {
	int j;
	for (j = 0; j < 4 + 1; j++) {
	cost[i] += partial[i][3 + j] * partial[i][3 + j];
	}
	cost[i] *= div_table[8];
	for (j = 0; j < 4 - 1; j++) {
	cost[i] += (partial[i][j] * partial[i][j] +
	partial[i][10 - j] * partial[i][10 - j]) *
	div_table[2 * j + 2];
	}
	}
	for (i = 0; i < 8; i++) {
	if (cost[i] > best_cost) {
	best_cost = cost[i];
	best_dir = i;
	}
	}
	/* Difference between the optimal variance and the variance along the
	orthogonal direction. Again, the sum(x^2) terms cancel out. */
	*var = best_cost - cost[(best_dir + 4) & 7];
	/* We'd normally divide by 840, but dividing by 1024 is close enough
	for what we're going to do with this. */
	*var >>= 10;
	return best_dir;
	}

	void cdef_find_dir_dual_c(const uint16_t img1, const uint16_t img2,
	int stride, int32_t var1, int32_t var2,
	int coeff_shift, int out1, int out2) {
	*out1 = cdef_find_dir_c(img1, stride, var1, coeff_shift);
	*out2 = cdef_find_dir_c(img2, stride, var2, coeff_shift);
	}

	const int cdef_pri_taps[2][2] = { { 4, 2 }, { 3, 3 } };
	const int cdef_sec_taps[2] = { 2, 1 };

	/* Smooth in the direction detected. */
	static void cdef_filter_block_internal(
	uint8_t dst8, uint16_t dst16, int dstride, const uint16_t *in,
	int pri_strength, int sec_strength, int dir, int pri_damping,
	int sec_damping, int coeff_shift, int block_width, int block_height,
	int enable_primary, int enable_secondary) {
	const int clipping_required = (enable_primary && enable_secondary);
	int i, j, k;
	const int s = CDEF_BSTRIDE;
	const int *pri_taps = cdef_pri_taps[(pri_strength >> coeff_shift) & 1];
	const int *sec_taps = cdef_sec_taps;
	for (i = 0; i < block_height; i++) {
	for (j = 0; j < block_width; j++) {
	int16_t sum = 0;
	int16_t y;
	int16_t x = in[i * s + j];
	int max = x;
	int min = x;
	for (k = 0; k < 2; k++) {
	if (enable_primary) {
	int16_t p0 = in[i * s + j + cdef_directions[dir][k]];
	int16_t p1 = in[i * s + j - cdef_directions[dir][k]];
	sum += pri_taps[k] * constrain(p0 - x, pri_strength, pri_damping);
	sum += pri_taps[k] * constrain(p1 - x, pri_strength, pri_damping);
	if (clipping_required) {
	if (p0 != CDEF_VERY_LARGE) max = AOMMAX(p0, max);
	if (p1 != CDEF_VERY_LARGE) max = AOMMAX(p1, max);
	min = AOMMIN(p0, min);
	min = AOMMIN(p1, min);
	}
	}
	if (enable_secondary) {
	int16_t s0 = in[i * s + j + cdef_directions[dir + 2][k]];
	int16_t s1 = in[i * s + j - cdef_directions[dir + 2][k]];
	int16_t s2 = in[i * s + j + cdef_directions[dir - 2][k]];
	int16_t s3 = in[i * s + j - cdef_directions[dir - 2][k]];
	if (clipping_required) {
	if (s0 != CDEF_VERY_LARGE) max = AOMMAX(s0, max);
	if (s1 != CDEF_VERY_LARGE) max = AOMMAX(s1, max);
	if (s2 != CDEF_VERY_LARGE) max = AOMMAX(s2, max);
	if (s3 != CDEF_VERY_LARGE) max = AOMMAX(s3, max);
	min = AOMMIN(s0, min);
	min = AOMMIN(s1, min);
	min = AOMMIN(s2, min);
	min = AOMMIN(s3, min);
	}
	sum += sec_taps[k] * constrain(s0 - x, sec_strength, sec_damping);
	sum += sec_taps[k] * constrain(s1 - x, sec_strength, sec_damping);
	sum += sec_taps[k] * constrain(s2 - x, sec_strength, sec_damping);
	sum += sec_taps[k] * constrain(s3 - x, sec_strength, sec_damping);
	}
	}
	y = ((int16_t)x + ((8 + sum - (sum < 0)) >> 4));
	if (clipping_required) {
	y = clamp(y, min, max);
	}

	if (dst8)
	dst8[i * dstride + j] = (uint8_t)y;
	else
	dst16[i * dstride + j] = (uint16_t)y;
	}
	}
	}

	void cdef_filter_8_0_c(void dst8, int dstride, const uint16_t in,
	int pri_strength, int sec_strength, int dir,
	int pri_damping, int sec_damping, int coeff_shift,
	int block_width, int block_height) {
	cdef_filter_block_internal((uint8_t *)dst8, NULL, dstride, in, pri_strength,
	sec_strength, dir, pri_damping, sec_damping,
	coeff_shift, block_width, block_height,
	/enable_primary=/1, /enable_secondary=/1);
	}

	void cdef_filter_8_1_c(void dst8, int dstride, const uint16_t in,
	int pri_strength, int sec_strength, int dir,
	int pri_damping, int sec_damping, int coeff_shift,
	int block_width, int block_height) {
	cdef_filter_block_internal((uint8_t *)dst8, NULL, dstride, in, pri_strength,
	sec_strength, dir, pri_damping, sec_damping,
	coeff_shift, block_width, block_height,
	/enable_primary=/1, /enable_secondary=/0);
	}

	void cdef_filter_8_2_c(void dst8, int dstride, const uint16_t in,
	int pri_strength, int sec_strength, int dir,
	int pri_damping, int sec_damping, int coeff_shift,
	int block_width, int block_height) {
	cdef_filter_block_internal((uint8_t *)dst8, NULL, dstride, in, pri_strength,
	sec_strength, dir, pri_damping, sec_damping,
	coeff_shift, block_width, block_height,
	/enable_primary=/0, /enable_secondary=/1);
	}

	void cdef_filter_8_3_c(void dst8, int dstride, const uint16_t in,
	int pri_strength, int sec_strength, int dir,
	int pri_damping, int sec_damping, int coeff_shift,
	int block_width, int block_height) {
	cdef_filter_block_internal((uint8_t *)dst8, NULL, dstride, in, pri_strength,
	sec_strength, dir, pri_damping, sec_damping,
	coeff_shift, block_width, block_height,
	/enable_primary=/0, /enable_secondary=/0);
	}

	void cdef_filter_16_0_c(void dst16, int dstride, const uint16_t in,
	int pri_strength, int sec_strength, int dir,
	int pri_damping, int sec_damping, int coeff_shift,
	int block_width, int block_height) {
	cdef_filter_block_internal(NULL, (uint16_t *)dst16, dstride, in, pri_strength,
	sec_strength, dir, pri_damping, sec_damping,
	coeff_shift, block_width, block_height,
	/enable_primary=/1, /enable_secondary=/1);
	}

	void cdef_filter_16_1_c(void dst16, int dstride, const uint16_t in,
	int pri_strength, int sec_strength, int dir,
	int pri_damping, int sec_damping, int coeff_shift,
	int block_width, int block_height) {
	cdef_filter_block_internal(NULL, (uint16_t *)dst16, dstride, in, pri_strength,
	sec_strength, dir, pri_damping, sec_damping,
	coeff_shift, block_width, block_height,
	/enable_primary=/1, /enable_secondary=/0);
	}

	void cdef_filter_16_2_c(void dst16, int dstride, const uint16_t in,
	int pri_strength, int sec_strength, int dir,
	int pri_damping, int sec_damping, int coeff_shift,
	int block_width, int block_height) {
	cdef_filter_block_internal(NULL, (uint16_t *)dst16, dstride, in, pri_strength,
	sec_strength, dir, pri_damping, sec_damping,
	coeff_shift, block_width, block_height,
	/enable_primary=/0, /enable_secondary=/1);
	}

	void cdef_filter_16_3_c(void dst16, int dstride, const uint16_t in,
	int pri_strength, int sec_strength, int dir,
	int pri_damping, int sec_damping, int coeff_shift,
	int block_width, int block_height) {
	cdef_filter_block_internal(NULL, (uint16_t *)dst16, dstride, in, pri_strength,
	sec_strength, dir, pri_damping, sec_damping,
	coeff_shift, block_width, block_height,
	/enable_primary=/0, /enable_secondary=/0);
	}

	/* Compute the primary filter strength for an 8x8 block based on the
	directional variance difference. A high variance difference means
	that we have a highly directional pattern (e.g. a high contrast
	edge), so we can apply more deringing. A low variance means that we
	either have a low contrast edge, or a non-directional texture, so
	we want to be careful not to blur. */
	static INLINE int adjust_strength(int strength, int32_t var) {
	const int i = var >> 6 ? AOMMIN(get_msb(var >> 6), 12) : 0;
	/* We use the variance of 8x8 blocks to adjust the strength. */
	return var ? (strength * (4 + i) + 8) >> 4 : 0;
	}

	static AOM_INLINE void aom_cdef_find_dir(const uint16_t in, cdef_list dlist,
	int var[CDEF_NBLOCKS][CDEF_NBLOCKS],
	int cdef_count, int coeff_shift,
	int dir[CDEF_NBLOCKS][CDEF_NBLOCKS]) {
	int bi;

	// Find direction of two 8x8 blocks together.
	for (bi = 0; bi < cdef_count - 1; bi += 2) {
	const int by = dlist[bi].by;
	const int bx = dlist[bi].bx;
	const int by2 = dlist[bi + 1].by;
	const int bx2 = dlist[bi + 1].bx;
	const int pos1 = 8 * by * CDEF_BSTRIDE + 8 * bx;
	const int pos2 = 8 * by2 * CDEF_BSTRIDE + 8 * bx2;
	cdef_find_dir_dual(&in[pos1], &in[pos2], CDEF_BSTRIDE, &var[by][bx],
	&var[by2][bx2], coeff_shift, &dir[by][bx],
	&dir[by2][bx2]);
	}

	// Process remaining 8x8 blocks here. One 8x8 at a time.
	if (cdef_count % 2) {
	const int by = dlist[bi].by;
	const int bx = dlist[bi].bx;
	dir[by][bx] = cdef_find_dir(&in[8 * by * CDEF_BSTRIDE + 8 * bx],
	CDEF_BSTRIDE, &var[by][bx], coeff_shift);
	}
	}

	void av1_cdef_filter_fb(uint8_t dst8, uint16_t dst16, int dstride,
	const uint16_t *in, int xdec, int ydec,
	int dir[CDEF_NBLOCKS][CDEF_NBLOCKS], int *dirinit,
	int var[CDEF_NBLOCKS][CDEF_NBLOCKS], int pli,
	cdef_list *dlist, int cdef_count, int level,
	int sec_strength, int damping, int coeff_shift) {
	int bi;
	int bx;
	int by;
	const int pri_strength = level << coeff_shift;
	sec_strength <<= coeff_shift;
	damping += coeff_shift - (pli != AOM_PLANE_Y);
	const int bw_log2 = 3 - xdec;
	const int bh_log2 = 3 - ydec;
	if (dirinit && pri_strength == 0 && sec_strength == 0) {
	// If we're here, both primary and secondary strengths are 0, and
	// we still haven't written anything to y[] yet, so we just copy
	// the input to y[]. This is necessary only for av1_cdef_search()
	// and only av1_cdef_search() sets dirinit.
	for (bi = 0; bi < cdef_count; bi++) {
	by = dlist[bi].by;
	bx = dlist[bi].bx;
	// TODO(stemidts/jmvalin): SIMD optimisations
	for (int iy = 0; iy < 1 << bh_log2; iy++) {
	memcpy(&dst16[(bi << (bw_log2 + bh_log2)) + (iy << bw_log2)],
	&in[((by << bh_log2) + iy) * CDEF_BSTRIDE + (bx << bw_log2)],
	((size_t)1 << bw_log2) * sizeof(*dst16));
	}
	}
	return;
	}

	if (pli == 0) {
	if (!dirinit \|\| !*dirinit) {
	aom_cdef_find_dir(in, dlist, var, cdef_count, coeff_shift, dir);
	if (dirinit) *dirinit = 1;
	}
	}
	if (pli == 1 && xdec != ydec) {
	for (bi = 0; bi < cdef_count; bi++) {
	static const int conv422[8] = { 7, 0, 2, 4, 5, 6, 6, 6 };
	static const int conv440[8] = { 1, 2, 2, 2, 3, 4, 6, 0 };
	by = dlist[bi].by;
	bx = dlist[bi].bx;
	dir[by][bx] = (xdec ? conv422 : conv440)[dir[by][bx]];
	}
	}

	if (dst8) {
	const int block_width = 8 >> xdec;
	const int block_height = 8 >> ydec;
	/*
	* strength_index == 0 : enable_primary = 1, enable_secondary = 1
	* strength_index == 1 : enable_primary = 1, enable_secondary = 0
	* strength_index == 2 : enable_primary = 0, enable_secondary = 1
	* strength_index == 3 : enable_primary = 0, enable_secondary = 0
	*/
	const cdef_filter_block_func cdef_filter_fn[4] = {
	cdef_filter_8_0, cdef_filter_8_1, cdef_filter_8_2, cdef_filter_8_3
	};

	for (bi = 0; bi < cdef_count; bi++) {
	by = dlist[bi].by;
	bx = dlist[bi].bx;
	const int t =
	(pli ? pri_strength : adjust_strength(pri_strength, var[by][bx]));
	const int strength_index = (sec_strength == 0) \| ((t == 0) << 1);

	cdef_filter_fn[strength_index](
	&dst8[(by << bh_log2) * dstride + (bx << bw_log2)], dstride,
	&in[(by * CDEF_BSTRIDE << bh_log2) + (bx << bw_log2)], t,
	sec_strength, pri_strength ? dir[by][bx] : 0, damping, damping,
	coeff_shift, block_width, block_height);
	}
	} else {
	const int block_width = 8 >> xdec;
	const int block_height = 8 >> ydec;
	/*
	* strength_index == 0 : enable_primary = 1, enable_secondary = 1
	* strength_index == 1 : enable_primary = 1, enable_secondary = 0
	* strength_index == 2 : enable_primary = 0, enable_secondary = 1
	* strength_index == 3 : enable_primary = 0, enable_secondary = 0
	*/
	const cdef_filter_block_func cdef_filter_fn[4] = {
	cdef_filter_16_0, cdef_filter_16_1, cdef_filter_16_2, cdef_filter_16_3
	};

	for (bi = 0; bi < cdef_count; bi++) {
	by = dlist[bi].by;
	bx = dlist[bi].bx;
	const int t =
	(pli ? pri_strength : adjust_strength(pri_strength, var[by][bx]));
	const int strength_index = (sec_strength == 0) \| ((t == 0) << 1);

	cdef_filter_fn[strength_index](
	&dst16[dirinit ? bi << (bw_log2 + bh_log2)
	: (by << bh_log2) * dstride + (bx << bw_log2)],
	dirinit ? 1 << bw_log2 : dstride,
	&in[(by * CDEF_BSTRIDE << bh_log2) + (bx << bw_log2)], t,
	sec_strength, pri_strength ? dir[by][bx] : 0, damping, damping,
	coeff_shift, block_width, block_height);
	}
	}
	}