av1/common/od_dering_simd.h - 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 "./av1_rtcd.h"
 #include "./cdef_simd.h"
 #include "./od_dering.h"

 /* partial A is a 16-bit vector of the form:
    [x8 x7 x6 x5 x4 x3 x2 x1] and partial B has the form:
    [0  y1 y2 y3 y4 y5 y6 y7].
    This function computes (x1^2+y1^2)*C1 + (x2^2+y2^2)*C2 + ...
    (x7^2+y2^7)*C7 + (x8^2+0^2)*C8 where the C1..C8 constants are in const1
    and const2. */
 static INLINE v128 fold_mul_and_sum(v128 partiala, v128 partialb, v128 const1,
                                     v128 const2) {
   v128 tmp;
   /* Reverse partial B. */
   partialb = v128_shuffle_8(
       partialb, v128_from_32(0x0f0e0100, 0x03020504, 0x07060908, 0x0b0a0d0c));
   /* Interleave the x and y values of identical indices and pair x8 with 0. */
   tmp = partiala;
   partiala = v128_ziplo_16(partialb, partiala);
   partialb = v128_ziphi_16(partialb, tmp);
   /* Square and add the corresponding x and y values. */
   partiala = v128_madd_s16(partiala, partiala);
   partialb = v128_madd_s16(partialb, partialb);
   /* Multiply by constant. */
   partiala = v128_mullo_s32(partiala, const1);
   partialb = v128_mullo_s32(partialb, const2);
   /* Sum all results. */
   partiala = v128_add_32(partiala, partialb);
   return partiala;
 }

 static INLINE v128 hsum4(v128 x0, v128 x1, v128 x2, v128 x3) {
   v128 t0, t1, t2, t3;
   t0 = v128_ziplo_32(x1, x0);
   t1 = v128_ziplo_32(x3, x2);
   t2 = v128_ziphi_32(x1, x0);
   t3 = v128_ziphi_32(x3, x2);
   x0 = v128_ziplo_64(t1, t0);
   x1 = v128_ziphi_64(t1, t0);
   x2 = v128_ziplo_64(t3, t2);
   x3 = v128_ziphi_64(t3, t2);
   return v128_add_32(v128_add_32(x0, x1), v128_add_32(x2, x3));
 }

 /* Computes cost for directions 0, 5, 6 and 7. We can call this function again
    to compute the remaining directions. */
 static INLINE v128 compute_directions(v128 lines[8], int32_t tmp_cost1[4]) {
   v128 partial4a, partial4b, partial5a, partial5b, partial7a, partial7b;
   v128 partial6;
   v128 tmp;
   /* Partial sums for lines 0 and 1. */
   partial4a = v128_shl_n_byte(lines[0], 14);
   partial4b = v128_shr_n_byte(lines[0], 2);
   partial4a = v128_add_16(partial4a, v128_shl_n_byte(lines[1], 12));
   partial4b = v128_add_16(partial4b, v128_shr_n_byte(lines[1], 4));
   tmp = v128_add_16(lines[0], lines[1]);
   partial5a = v128_shl_n_byte(tmp, 10);
   partial5b = v128_shr_n_byte(tmp, 6);
   partial7a = v128_shl_n_byte(tmp, 4);
   partial7b = v128_shr_n_byte(tmp, 12);
   partial6 = tmp;

   /* Partial sums for lines 2 and 3. */
   partial4a = v128_add_16(partial4a, v128_shl_n_byte(lines[2], 10));
   partial4b = v128_add_16(partial4b, v128_shr_n_byte(lines[2], 6));
   partial4a = v128_add_16(partial4a, v128_shl_n_byte(lines[3], 8));
   partial4b = v128_add_16(partial4b, v128_shr_n_byte(lines[3], 8));
   tmp = v128_add_16(lines[2], lines[3]);
   partial5a = v128_add_16(partial5a, v128_shl_n_byte(tmp, 8));
   partial5b = v128_add_16(partial5b, v128_shr_n_byte(tmp, 8));
   partial7a = v128_add_16(partial7a, v128_shl_n_byte(tmp, 6));
   partial7b = v128_add_16(partial7b, v128_shr_n_byte(tmp, 10));
   partial6 = v128_add_16(partial6, tmp);

   /* Partial sums for lines 4 and 5. */
   partial4a = v128_add_16(partial4a, v128_shl_n_byte(lines[4], 6));
   partial4b = v128_add_16(partial4b, v128_shr_n_byte(lines[4], 10));
   partial4a = v128_add_16(partial4a, v128_shl_n_byte(lines[5], 4));
   partial4b = v128_add_16(partial4b, v128_shr_n_byte(lines[5], 12));
   tmp = v128_add_16(lines[4], lines[5]);
   partial5a = v128_add_16(partial5a, v128_shl_n_byte(tmp, 6));
   partial5b = v128_add_16(partial5b, v128_shr_n_byte(tmp, 10));
   partial7a = v128_add_16(partial7a, v128_shl_n_byte(tmp, 8));
   partial7b = v128_add_16(partial7b, v128_shr_n_byte(tmp, 8));
   partial6 = v128_add_16(partial6, tmp);

   /* Partial sums for lines 6 and 7. */
   partial4a = v128_add_16(partial4a, v128_shl_n_byte(lines[6], 2));
   partial4b = v128_add_16(partial4b, v128_shr_n_byte(lines[6], 14));
   partial4a = v128_add_16(partial4a, lines[7]);
   tmp = v128_add_16(lines[6], lines[7]);
   partial5a = v128_add_16(partial5a, v128_shl_n_byte(tmp, 4));
   partial5b = v128_add_16(partial5b, v128_shr_n_byte(tmp, 12));
   partial7a = v128_add_16(partial7a, v128_shl_n_byte(tmp, 10));
   partial7b = v128_add_16(partial7b, v128_shr_n_byte(tmp, 6));
   partial6 = v128_add_16(partial6, tmp);

   /* Compute costs in terms of partial sums. */
   partial4a =
       fold_mul_and_sum(partial4a, partial4b, v128_from_32(210, 280, 420, 840),
                        v128_from_32(105, 120, 140, 168));
   partial7a =
       fold_mul_and_sum(partial7a, partial7b, v128_from_32(210, 420, 0, 0),
                        v128_from_32(105, 105, 105, 140));
   partial5a =
       fold_mul_and_sum(partial5a, partial5b, v128_from_32(210, 420, 0, 0),
                        v128_from_32(105, 105, 105, 140));
   partial6 = v128_madd_s16(partial6, partial6);
   partial6 = v128_mullo_s32(partial6, v128_dup_32(105));

   partial4a = hsum4(partial4a, partial5a, partial6, partial7a);
   v128_store_unaligned(tmp_cost1, partial4a);
   return partial4a;
 }

 /* transpose and reverse the order of the lines -- equivalent to a 90-degree
    counter-clockwise rotation of the pixels. */
 static INLINE void array_reverse_transpose_8x8(v128 *in, v128 *res) {
   const v128 tr0_0 = v128_ziplo_16(in[1], in[0]);
   const v128 tr0_1 = v128_ziplo_16(in[3], in[2]);
   const v128 tr0_2 = v128_ziphi_16(in[1], in[0]);
   const v128 tr0_3 = v128_ziphi_16(in[3], in[2]);
   const v128 tr0_4 = v128_ziplo_16(in[5], in[4]);
   const v128 tr0_5 = v128_ziplo_16(in[7], in[6]);
   const v128 tr0_6 = v128_ziphi_16(in[5], in[4]);
   const v128 tr0_7 = v128_ziphi_16(in[7], in[6]);

   const v128 tr1_0 = v128_ziplo_32(tr0_1, tr0_0);
   const v128 tr1_1 = v128_ziplo_32(tr0_5, tr0_4);
   const v128 tr1_2 = v128_ziphi_32(tr0_1, tr0_0);
   const v128 tr1_3 = v128_ziphi_32(tr0_5, tr0_4);
   const v128 tr1_4 = v128_ziplo_32(tr0_3, tr0_2);
   const v128 tr1_5 = v128_ziplo_32(tr0_7, tr0_6);
   const v128 tr1_6 = v128_ziphi_32(tr0_3, tr0_2);
   const v128 tr1_7 = v128_ziphi_32(tr0_7, tr0_6);

   res[7] = v128_ziplo_64(tr1_1, tr1_0);
   res[6] = v128_ziphi_64(tr1_1, tr1_0);
   res[5] = v128_ziplo_64(tr1_3, tr1_2);
   res[4] = v128_ziphi_64(tr1_3, tr1_2);
   res[3] = v128_ziplo_64(tr1_5, tr1_4);
   res[2] = v128_ziphi_64(tr1_5, tr1_4);
   res[1] = v128_ziplo_64(tr1_7, tr1_6);
   res[0] = v128_ziphi_64(tr1_7, tr1_6);
 }

 int SIMD_FUNC(od_dir_find8)(const od_dering_in *img, int stride, int32_t *var,
                             int coeff_shift) {
   int i;
   int32_t cost[8];
   int32_t best_cost = 0;
   int best_dir = 0;
   v128 lines[8];
   for (i = 0; i < 8; i++) {
     lines[i] = v128_load_unaligned(&img[i * stride]);
     lines[i] =
         v128_sub_16(v128_shr_s16(lines[i], coeff_shift), v128_dup_16(128));
   }

 #if defined(__SSE4_1__)
   /* Compute "mostly vertical" directions. */
   __m128i dir47 = compute_directions(lines, cost + 4);

   array_reverse_transpose_8x8(lines, lines);

   /* Compute "mostly horizontal" directions. */
   __m128i dir03 = compute_directions(lines, cost);

   __m128i max = _mm_max_epi32(dir03, dir47);
   max = _mm_max_epi32(max, _mm_shuffle_epi32(max, _MM_SHUFFLE(1, 0, 3, 2)));
   max = _mm_max_epi32(max, _mm_shuffle_epi32(max, _MM_SHUFFLE(2, 3, 0, 1)));
   best_cost = _mm_cvtsi128_si32(max);
   __m128i t =
       _mm_packs_epi32(_mm_cmpeq_epi32(max, dir03), _mm_cmpeq_epi32(max, dir47));
   best_dir = _mm_movemask_epi8(_mm_packs_epi16(t, t));
   best_dir = get_msb(best_dir ^ (best_dir - 1));  // Count trailing zeros
 #else
   /* Compute "mostly vertical" directions. */
   compute_directions(lines, cost + 4);

   array_reverse_transpose_8x8(lines, lines);

   /* Compute "mostly horizontal" directions. */
   compute_directions(lines, cost);

   for (i = 0; i < 8; i++) {
     if (cost[i] > best_cost) {
       best_cost = cost[i];
       best_dir = i;
     }
   }
 #endif

   /* 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 SIMD_FUNC(od_filter_dering_direction_4x4)(uint16_t *y, int ystride,
                                                const uint16_t *in,
                                                int threshold, int dir,
                                                int damping) {
   int i;
   v128 p0, p1, sum, row, res;
   int o1 = OD_DIRECTION_OFFSETS_TABLE[dir][0];
   int o2 = OD_DIRECTION_OFFSETS_TABLE[dir][1];

   if (threshold) damping -= get_msb(threshold);
   for (i = 0; i < 4; i += 2) {
     sum = v128_zero();
     row = v128_from_v64(v64_load_aligned(&in[i * OD_FILT_BSTRIDE]),
                         v64_load_aligned(&in[(i + 1) * OD_FILT_BSTRIDE]));

     // p0 = constrain16(in[i*OD_FILT_BSTRIDE + offset], row, threshold, damping)
     p0 = v128_from_v64(v64_load_unaligned(&in[i * OD_FILT_BSTRIDE + o1]),
                        v64_load_unaligned(&in[(i + 1) * OD_FILT_BSTRIDE + o1]));
     p0 = constrain16(p0, row, threshold, damping);

     // p1 = constrain16(in[i*OD_FILT_BSTRIDE - offset], row, threshold, damping)
     p1 = v128_from_v64(v64_load_unaligned(&in[i * OD_FILT_BSTRIDE - o1]),
                        v64_load_unaligned(&in[(i + 1) * OD_FILT_BSTRIDE - o1]));
     p1 = constrain16(p1, row, threshold, damping);

     // sum += 4 * (p0 + p1)
     sum = v128_add_16(sum, v128_shl_n_16(v128_add_16(p0, p1), 2));

     // p0 = constrain16(in[i*OD_FILT_BSTRIDE + offset], row, threshold, damping)
     p0 = v128_from_v64(v64_load_unaligned(&in[i * OD_FILT_BSTRIDE + o2]),
                        v64_load_unaligned(&in[(i + 1) * OD_FILT_BSTRIDE + o2]));
     p0 = constrain16(p0, row, threshold, damping);

     // p1 = constrain16(in[i*OD_FILT_BSTRIDE - offset], row, threshold, damping)
     p1 = v128_from_v64(v64_load_unaligned(&in[i * OD_FILT_BSTRIDE - o2]),
                        v64_load_unaligned(&in[(i + 1) * OD_FILT_BSTRIDE - o2]));
     p1 = constrain16(p1, row, threshold, damping);

     // sum += 1 * (p0 + p1)
     sum = v128_add_16(sum, v128_add_16(p0, p1));

     // res = row + ((sum + 8) >> 4)
     res = v128_add_16(sum, v128_dup_16(8));
     res = v128_shr_n_s16(res, 4);
     res = v128_add_16(row, res);
     v64_store_aligned(&y[i * ystride], v128_high_v64(res));
     v64_store_aligned(&y[(i + 1) * ystride], v128_low_v64(res));
   }
 }

 void SIMD_FUNC(od_filter_dering_direction_8x8)(uint16_t *y, int ystride,
                                                const uint16_t *in,
                                                int threshold, int dir,
                                                int damping) {
   int i;
   v128 sum, p0, p1, row, res;
   int o1 = OD_DIRECTION_OFFSETS_TABLE[dir][0];
   int o2 = OD_DIRECTION_OFFSETS_TABLE[dir][1];
   int o3 = OD_DIRECTION_OFFSETS_TABLE[dir][2];

   if (threshold) damping -= get_msb(threshold);
   for (i = 0; i < 8; i++) {
     sum = v128_zero();
     row = v128_load_aligned(&in[i * OD_FILT_BSTRIDE]);

     // p0 = constrain16(in[i*OD_FILT_BSTRIDE + offset], row, threshold, damping)
     p0 = v128_load_unaligned(&in[i * OD_FILT_BSTRIDE + o1]);
     p0 = constrain16(p0, row, threshold, damping);

     // p1 = constrain16(in[i*OD_FILT_BSTRIDE - offset], row, threshold, damping)
     p1 = v128_load_unaligned(&in[i * OD_FILT_BSTRIDE - o1]);
     p1 = constrain16(p1, row, threshold, damping);

     // sum += 3 * (p0 + p1)
     p0 = v128_add_16(p0, p1);
     p0 = v128_add_16(p0, v128_shl_n_16(p0, 1));
     sum = v128_add_16(sum, p0);

     // p0 = constrain16(in[i*OD_FILT_BSTRIDE + offset], row, threshold, damping)
     p0 = v128_load_unaligned(&in[i * OD_FILT_BSTRIDE + o2]);
     p0 = constrain16(p0, row, threshold, damping);

     // p1 = constrain16(in[i*OD_FILT_BSTRIDE - offset], row, threshold, damping)
     p1 = v128_load_unaligned(&in[i * OD_FILT_BSTRIDE - o2]);
     p1 = constrain16(p1, row, threshold, damping);

     // sum += 2 * (p0 + p1)
     p0 = v128_shl_n_16(v128_add_16(p0, p1), 1);
     sum = v128_add_16(sum, p0);

     // p0 = constrain16(in[i*OD_FILT_BSTRIDE + offset], row, threshold, damping)
     p0 = v128_load_unaligned(&in[i * OD_FILT_BSTRIDE + o3]);
     p0 = constrain16(p0, row, threshold, damping);

     // p1 = constrain16(in[i*OD_FILT_BSTRIDE - offset], row, threshold, damping)
     p1 = v128_load_unaligned(&in[i * OD_FILT_BSTRIDE - o3]);
     p1 = constrain16(p1, row, threshold, damping);

     // sum += (p0 + p1)
     p0 = v128_add_16(p0, p1);
     sum = v128_add_16(sum, p0);

     // res = row + ((sum + 8) >> 4)
     res = v128_add_16(sum, v128_dup_16(8));
     res = v128_shr_n_s16(res, 4);
     res = v128_add_16(row, res);
     v128_store_unaligned(&y[i * ystride], res);
   }
 }

 void SIMD_FUNC(copy_8x8_16bit_to_8bit)(uint8_t *dst, int dstride,
                                        const uint16_t *src, int sstride) {
   int i;
   for (i = 0; i < 8; i++) {
     v128 row = v128_load_unaligned(&src[i * sstride]);
     row = v128_pack_s16_u8(row, row);
     v64_store_unaligned(&dst[i * dstride], v128_low_v64(row));
   }
 }

 void SIMD_FUNC(copy_4x4_16bit_to_8bit)(uint8_t *dst, int dstride,
                                        const uint16_t *src, int sstride) {
   int i;
   for (i = 0; i < 4; i++) {
     v128 row = v128_load_unaligned(&src[i * sstride]);
     row = v128_pack_s16_u8(row, row);
     u32_store_unaligned(&dst[i * dstride], v128_low_u32(row));
   }
 }

 void SIMD_FUNC(copy_8x8_16bit_to_16bit)(uint16_t *dst, int dstride,
                                         const uint16_t *src, int sstride) {
   int i;
   for (i = 0; i < 8; i++) {
     v128 row = v128_load_unaligned(&src[i * sstride]);
     v128_store_unaligned(&dst[i * dstride], row);
   }
 }

 void SIMD_FUNC(copy_4x4_16bit_to_16bit)(uint16_t *dst, int dstride,
                                         const uint16_t *src, int sstride) {
   int i;
   for (i = 0; i < 4; i++) {
     v64 row = v64_load_unaligned(&src[i * sstride]);
     v64_store_unaligned(&dst[i * dstride], row);
   }
 }

 void SIMD_FUNC(copy_rect8_8bit_to_16bit)(uint16_t *dst, int dstride,
                                          const uint8_t *src, int sstride, int v,
                                          int h) {
   int i, j;
   for (i = 0; i < v; i++) {
     for (j = 0; j < (h & ~0x7); j += 8) {
       v64 row = v64_load_unaligned(&src[i * sstride + j]);
       v128_store_unaligned(&dst[i * dstride + j], v128_unpack_u8_s16(row));
     }
     for (; j < h; j++) {
       dst[i * dstride + j] = src[i * sstride + j];
     }
   }
 }

 void SIMD_FUNC(copy_rect8_16bit_to_16bit)(uint16_t *dst, int dstride,
                                           const uint16_t *src, int sstride,
                                           int v, int h) {
   int i, j;
   for (i = 0; i < v; i++) {
     for (j = 0; j < (h & ~0x7); j += 8) {
       v128 row = v128_load_unaligned(&src[i * sstride + j]);
       v128_store_unaligned(&dst[i * dstride + j], row);
     }
     for (; j < h; j++) {
       dst[i * dstride + j] = src[i * sstride + j];
     }
   }
 }
	/*
	* 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 "./av1_rtcd.h"
	#include "./cdef_simd.h"
	#include "./od_dering.h"

	/* partial A is a 16-bit vector of the form:
	[x8 x7 x6 x5 x4 x3 x2 x1] and partial B has the form:
	[0 y1 y2 y3 y4 y5 y6 y7].
	This function computes (x1^2+y1^2)C1 + (x2^2+y2^2)C2 + ...
	(x7^2+y2^7)C7 + (x8^2+0^2)C8 where the C1..C8 constants are in const1
	and const2. */
	static INLINE v128 fold_mul_and_sum(v128 partiala, v128 partialb, v128 const1,
	v128 const2) {
	v128 tmp;
	/* Reverse partial B. */
	partialb = v128_shuffle_8(
	partialb, v128_from_32(0x0f0e0100, 0x03020504, 0x07060908, 0x0b0a0d0c));
	/* Interleave the x and y values of identical indices and pair x8 with 0. */
	tmp = partiala;
	partiala = v128_ziplo_16(partialb, partiala);
	partialb = v128_ziphi_16(partialb, tmp);
	/* Square and add the corresponding x and y values. */
	partiala = v128_madd_s16(partiala, partiala);
	partialb = v128_madd_s16(partialb, partialb);
	/* Multiply by constant. */
	partiala = v128_mullo_s32(partiala, const1);
	partialb = v128_mullo_s32(partialb, const2);
	/* Sum all results. */
	partiala = v128_add_32(partiala, partialb);
	return partiala;
	}

	static INLINE v128 hsum4(v128 x0, v128 x1, v128 x2, v128 x3) {
	v128 t0, t1, t2, t3;
	t0 = v128_ziplo_32(x1, x0);
	t1 = v128_ziplo_32(x3, x2);
	t2 = v128_ziphi_32(x1, x0);
	t3 = v128_ziphi_32(x3, x2);
	x0 = v128_ziplo_64(t1, t0);
	x1 = v128_ziphi_64(t1, t0);
	x2 = v128_ziplo_64(t3, t2);
	x3 = v128_ziphi_64(t3, t2);
	return v128_add_32(v128_add_32(x0, x1), v128_add_32(x2, x3));
	}

	/* Computes cost for directions 0, 5, 6 and 7. We can call this function again
	to compute the remaining directions. */
	static INLINE v128 compute_directions(v128 lines[8], int32_t tmp_cost1[4]) {
	v128 partial4a, partial4b, partial5a, partial5b, partial7a, partial7b;
	v128 partial6;
	v128 tmp;
	/* Partial sums for lines 0 and 1. */
	partial4a = v128_shl_n_byte(lines[0], 14);
	partial4b = v128_shr_n_byte(lines[0], 2);
	partial4a = v128_add_16(partial4a, v128_shl_n_byte(lines[1], 12));
	partial4b = v128_add_16(partial4b, v128_shr_n_byte(lines[1], 4));
	tmp = v128_add_16(lines[0], lines[1]);
	partial5a = v128_shl_n_byte(tmp, 10);
	partial5b = v128_shr_n_byte(tmp, 6);
	partial7a = v128_shl_n_byte(tmp, 4);
	partial7b = v128_shr_n_byte(tmp, 12);
	partial6 = tmp;

	/* Partial sums for lines 2 and 3. */
	partial4a = v128_add_16(partial4a, v128_shl_n_byte(lines[2], 10));
	partial4b = v128_add_16(partial4b, v128_shr_n_byte(lines[2], 6));
	partial4a = v128_add_16(partial4a, v128_shl_n_byte(lines[3], 8));
	partial4b = v128_add_16(partial4b, v128_shr_n_byte(lines[3], 8));
	tmp = v128_add_16(lines[2], lines[3]);
	partial5a = v128_add_16(partial5a, v128_shl_n_byte(tmp, 8));
	partial5b = v128_add_16(partial5b, v128_shr_n_byte(tmp, 8));
	partial7a = v128_add_16(partial7a, v128_shl_n_byte(tmp, 6));
	partial7b = v128_add_16(partial7b, v128_shr_n_byte(tmp, 10));
	partial6 = v128_add_16(partial6, tmp);

	/* Partial sums for lines 4 and 5. */
	partial4a = v128_add_16(partial4a, v128_shl_n_byte(lines[4], 6));
	partial4b = v128_add_16(partial4b, v128_shr_n_byte(lines[4], 10));
	partial4a = v128_add_16(partial4a, v128_shl_n_byte(lines[5], 4));
	partial4b = v128_add_16(partial4b, v128_shr_n_byte(lines[5], 12));
	tmp = v128_add_16(lines[4], lines[5]);
	partial5a = v128_add_16(partial5a, v128_shl_n_byte(tmp, 6));
	partial5b = v128_add_16(partial5b, v128_shr_n_byte(tmp, 10));
	partial7a = v128_add_16(partial7a, v128_shl_n_byte(tmp, 8));
	partial7b = v128_add_16(partial7b, v128_shr_n_byte(tmp, 8));
	partial6 = v128_add_16(partial6, tmp);

	/* Partial sums for lines 6 and 7. */
	partial4a = v128_add_16(partial4a, v128_shl_n_byte(lines[6], 2));
	partial4b = v128_add_16(partial4b, v128_shr_n_byte(lines[6], 14));
	partial4a = v128_add_16(partial4a, lines[7]);
	tmp = v128_add_16(lines[6], lines[7]);
	partial5a = v128_add_16(partial5a, v128_shl_n_byte(tmp, 4));
	partial5b = v128_add_16(partial5b, v128_shr_n_byte(tmp, 12));
	partial7a = v128_add_16(partial7a, v128_shl_n_byte(tmp, 10));
	partial7b = v128_add_16(partial7b, v128_shr_n_byte(tmp, 6));
	partial6 = v128_add_16(partial6, tmp);

	/* Compute costs in terms of partial sums. */
	partial4a =
	fold_mul_and_sum(partial4a, partial4b, v128_from_32(210, 280, 420, 840),
	v128_from_32(105, 120, 140, 168));
	partial7a =
	fold_mul_and_sum(partial7a, partial7b, v128_from_32(210, 420, 0, 0),
	v128_from_32(105, 105, 105, 140));
	partial5a =
	fold_mul_and_sum(partial5a, partial5b, v128_from_32(210, 420, 0, 0),
	v128_from_32(105, 105, 105, 140));
	partial6 = v128_madd_s16(partial6, partial6);
	partial6 = v128_mullo_s32(partial6, v128_dup_32(105));

	partial4a = hsum4(partial4a, partial5a, partial6, partial7a);
	v128_store_unaligned(tmp_cost1, partial4a);
	return partial4a;
	}

	/* transpose and reverse the order of the lines -- equivalent to a 90-degree
	counter-clockwise rotation of the pixels. */
	static INLINE void array_reverse_transpose_8x8(v128 in, v128 res) {
	const v128 tr0_0 = v128_ziplo_16(in[1], in[0]);
	const v128 tr0_1 = v128_ziplo_16(in[3], in[2]);
	const v128 tr0_2 = v128_ziphi_16(in[1], in[0]);
	const v128 tr0_3 = v128_ziphi_16(in[3], in[2]);
	const v128 tr0_4 = v128_ziplo_16(in[5], in[4]);
	const v128 tr0_5 = v128_ziplo_16(in[7], in[6]);
	const v128 tr0_6 = v128_ziphi_16(in[5], in[4]);
	const v128 tr0_7 = v128_ziphi_16(in[7], in[6]);

	const v128 tr1_0 = v128_ziplo_32(tr0_1, tr0_0);
	const v128 tr1_1 = v128_ziplo_32(tr0_5, tr0_4);
	const v128 tr1_2 = v128_ziphi_32(tr0_1, tr0_0);
	const v128 tr1_3 = v128_ziphi_32(tr0_5, tr0_4);
	const v128 tr1_4 = v128_ziplo_32(tr0_3, tr0_2);
	const v128 tr1_5 = v128_ziplo_32(tr0_7, tr0_6);
	const v128 tr1_6 = v128_ziphi_32(tr0_3, tr0_2);
	const v128 tr1_7 = v128_ziphi_32(tr0_7, tr0_6);

	res[7] = v128_ziplo_64(tr1_1, tr1_0);
	res[6] = v128_ziphi_64(tr1_1, tr1_0);
	res[5] = v128_ziplo_64(tr1_3, tr1_2);
	res[4] = v128_ziphi_64(tr1_3, tr1_2);
	res[3] = v128_ziplo_64(tr1_5, tr1_4);
	res[2] = v128_ziphi_64(tr1_5, tr1_4);
	res[1] = v128_ziplo_64(tr1_7, tr1_6);
	res[0] = v128_ziphi_64(tr1_7, tr1_6);
	}

	int SIMD_FUNC(od_dir_find8)(const od_dering_in img, int stride, int32_t var,
	int coeff_shift) {
	int i;
	int32_t cost[8];
	int32_t best_cost = 0;
	int best_dir = 0;
	v128 lines[8];
	for (i = 0; i < 8; i++) {
	lines[i] = v128_load_unaligned(&img[i * stride]);
	lines[i] =
	v128_sub_16(v128_shr_s16(lines[i], coeff_shift), v128_dup_16(128));
	}

	#if defined(__SSE4_1__)
	/* Compute "mostly vertical" directions. */
	__m128i dir47 = compute_directions(lines, cost + 4);

	array_reverse_transpose_8x8(lines, lines);

	/* Compute "mostly horizontal" directions. */
	__m128i dir03 = compute_directions(lines, cost);

	__m128i max = _mm_max_epi32(dir03, dir47);
	max = _mm_max_epi32(max, _mm_shuffle_epi32(max, _MM_SHUFFLE(1, 0, 3, 2)));
	max = _mm_max_epi32(max, _mm_shuffle_epi32(max, _MM_SHUFFLE(2, 3, 0, 1)));
	best_cost = _mm_cvtsi128_si32(max);
	__m128i t =
	_mm_packs_epi32(_mm_cmpeq_epi32(max, dir03), _mm_cmpeq_epi32(max, dir47));
	best_dir = _mm_movemask_epi8(_mm_packs_epi16(t, t));
	best_dir = get_msb(best_dir ^ (best_dir - 1)); // Count trailing zeros
	#else
	/* Compute "mostly vertical" directions. */
	compute_directions(lines, cost + 4);

	array_reverse_transpose_8x8(lines, lines);

	/* Compute "mostly horizontal" directions. */
	compute_directions(lines, cost);

	for (i = 0; i < 8; i++) {
	if (cost[i] > best_cost) {
	best_cost = cost[i];
	best_dir = i;
	}
	}
	#endif

	/* 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 SIMD_FUNC(od_filter_dering_direction_4x4)(uint16_t *y, int ystride,
	const uint16_t *in,
	int threshold, int dir,
	int damping) {
	int i;
	v128 p0, p1, sum, row, res;
	int o1 = OD_DIRECTION_OFFSETS_TABLE[dir][0];
	int o2 = OD_DIRECTION_OFFSETS_TABLE[dir][1];

	if (threshold) damping -= get_msb(threshold);
	for (i = 0; i < 4; i += 2) {
	sum = v128_zero();
	row = v128_from_v64(v64_load_aligned(&in[i * OD_FILT_BSTRIDE]),
	v64_load_aligned(&in[(i + 1) * OD_FILT_BSTRIDE]));

	// p0 = constrain16(in[i*OD_FILT_BSTRIDE + offset], row, threshold, damping)
	p0 = v128_from_v64(v64_load_unaligned(&in[i * OD_FILT_BSTRIDE + o1]),
	v64_load_unaligned(&in[(i + 1) * OD_FILT_BSTRIDE + o1]));
	p0 = constrain16(p0, row, threshold, damping);

	// p1 = constrain16(in[i*OD_FILT_BSTRIDE - offset], row, threshold, damping)
	p1 = v128_from_v64(v64_load_unaligned(&in[i * OD_FILT_BSTRIDE - o1]),
	v64_load_unaligned(&in[(i + 1) * OD_FILT_BSTRIDE - o1]));
	p1 = constrain16(p1, row, threshold, damping);

	// sum += 4 * (p0 + p1)
	sum = v128_add_16(sum, v128_shl_n_16(v128_add_16(p0, p1), 2));

	// p0 = constrain16(in[i*OD_FILT_BSTRIDE + offset], row, threshold, damping)
	p0 = v128_from_v64(v64_load_unaligned(&in[i * OD_FILT_BSTRIDE + o2]),
	v64_load_unaligned(&in[(i + 1) * OD_FILT_BSTRIDE + o2]));
	p0 = constrain16(p0, row, threshold, damping);

	// p1 = constrain16(in[i*OD_FILT_BSTRIDE - offset], row, threshold, damping)
	p1 = v128_from_v64(v64_load_unaligned(&in[i * OD_FILT_BSTRIDE - o2]),
	v64_load_unaligned(&in[(i + 1) * OD_FILT_BSTRIDE - o2]));
	p1 = constrain16(p1, row, threshold, damping);

	// sum += 1 * (p0 + p1)
	sum = v128_add_16(sum, v128_add_16(p0, p1));

	// res = row + ((sum + 8) >> 4)
	res = v128_add_16(sum, v128_dup_16(8));
	res = v128_shr_n_s16(res, 4);
	res = v128_add_16(row, res);
	v64_store_aligned(&y[i * ystride], v128_high_v64(res));
	v64_store_aligned(&y[(i + 1) * ystride], v128_low_v64(res));
	}
	}

	void SIMD_FUNC(od_filter_dering_direction_8x8)(uint16_t *y, int ystride,
	const uint16_t *in,
	int threshold, int dir,
	int damping) {
	int i;
	v128 sum, p0, p1, row, res;
	int o1 = OD_DIRECTION_OFFSETS_TABLE[dir][0];
	int o2 = OD_DIRECTION_OFFSETS_TABLE[dir][1];
	int o3 = OD_DIRECTION_OFFSETS_TABLE[dir][2];

	if (threshold) damping -= get_msb(threshold);
	for (i = 0; i < 8; i++) {
	sum = v128_zero();
	row = v128_load_aligned(&in[i * OD_FILT_BSTRIDE]);

	// p0 = constrain16(in[i*OD_FILT_BSTRIDE + offset], row, threshold, damping)
	p0 = v128_load_unaligned(&in[i * OD_FILT_BSTRIDE + o1]);
	p0 = constrain16(p0, row, threshold, damping);

	// p1 = constrain16(in[i*OD_FILT_BSTRIDE - offset], row, threshold, damping)
	p1 = v128_load_unaligned(&in[i * OD_FILT_BSTRIDE - o1]);
	p1 = constrain16(p1, row, threshold, damping);

	// sum += 3 * (p0 + p1)
	p0 = v128_add_16(p0, p1);
	p0 = v128_add_16(p0, v128_shl_n_16(p0, 1));
	sum = v128_add_16(sum, p0);

	// p0 = constrain16(in[i*OD_FILT_BSTRIDE + offset], row, threshold, damping)
	p0 = v128_load_unaligned(&in[i * OD_FILT_BSTRIDE + o2]);
	p0 = constrain16(p0, row, threshold, damping);

	// p1 = constrain16(in[i*OD_FILT_BSTRIDE - offset], row, threshold, damping)
	p1 = v128_load_unaligned(&in[i * OD_FILT_BSTRIDE - o2]);
	p1 = constrain16(p1, row, threshold, damping);

	// sum += 2 * (p0 + p1)
	p0 = v128_shl_n_16(v128_add_16(p0, p1), 1);
	sum = v128_add_16(sum, p0);

	// p0 = constrain16(in[i*OD_FILT_BSTRIDE + offset], row, threshold, damping)
	p0 = v128_load_unaligned(&in[i * OD_FILT_BSTRIDE + o3]);
	p0 = constrain16(p0, row, threshold, damping);

	// p1 = constrain16(in[i*OD_FILT_BSTRIDE - offset], row, threshold, damping)
	p1 = v128_load_unaligned(&in[i * OD_FILT_BSTRIDE - o3]);
	p1 = constrain16(p1, row, threshold, damping);

	// sum += (p0 + p1)
	p0 = v128_add_16(p0, p1);
	sum = v128_add_16(sum, p0);

	// res = row + ((sum + 8) >> 4)
	res = v128_add_16(sum, v128_dup_16(8));
	res = v128_shr_n_s16(res, 4);
	res = v128_add_16(row, res);
	v128_store_unaligned(&y[i * ystride], res);
	}
	}

	void SIMD_FUNC(copy_8x8_16bit_to_8bit)(uint8_t *dst, int dstride,
	const uint16_t *src, int sstride) {
	int i;
	for (i = 0; i < 8; i++) {
	v128 row = v128_load_unaligned(&src[i * sstride]);
	row = v128_pack_s16_u8(row, row);
	v64_store_unaligned(&dst[i * dstride], v128_low_v64(row));
	}
	}

	void SIMD_FUNC(copy_4x4_16bit_to_8bit)(uint8_t *dst, int dstride,
	const uint16_t *src, int sstride) {
	int i;
	for (i = 0; i < 4; i++) {
	v128 row = v128_load_unaligned(&src[i * sstride]);
	row = v128_pack_s16_u8(row, row);
	u32_store_unaligned(&dst[i * dstride], v128_low_u32(row));
	}
	}

	void SIMD_FUNC(copy_8x8_16bit_to_16bit)(uint16_t *dst, int dstride,
	const uint16_t *src, int sstride) {
	int i;
	for (i = 0; i < 8; i++) {
	v128 row = v128_load_unaligned(&src[i * sstride]);
	v128_store_unaligned(&dst[i * dstride], row);
	}
	}

	void SIMD_FUNC(copy_4x4_16bit_to_16bit)(uint16_t *dst, int dstride,
	const uint16_t *src, int sstride) {
	int i;
	for (i = 0; i < 4; i++) {
	v64 row = v64_load_unaligned(&src[i * sstride]);
	v64_store_unaligned(&dst[i * dstride], row);
	}
	}

	void SIMD_FUNC(copy_rect8_8bit_to_16bit)(uint16_t *dst, int dstride,
	const uint8_t *src, int sstride, int v,
	int h) {
	int i, j;
	for (i = 0; i < v; i++) {
	for (j = 0; j < (h & ~0x7); j += 8) {
	v64 row = v64_load_unaligned(&src[i * sstride + j]);
	v128_store_unaligned(&dst[i * dstride + j], v128_unpack_u8_s16(row));
	}
	for (; j < h; j++) {
	dst[i * dstride + j] = src[i * sstride + j];
	}
	}
	}

	void SIMD_FUNC(copy_rect8_16bit_to_16bit)(uint16_t *dst, int dstride,
	const uint16_t *src, int sstride,
	int v, int h) {
	int i, j;
	for (i = 0; i < v; i++) {
	for (j = 0; j < (h & ~0x7); j += 8) {
	v128 row = v128_load_unaligned(&src[i * sstride + j]);
	v128_store_unaligned(&dst[i * dstride + j], row);
	}
	for (; j < h; j++) {
	dst[i * dstride + j] = src[i * sstride + j];
	}
	}
	}