av1/common/clpf_simd.h - avm - 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 "./aom_dsp_rtcd.h"
 #include "aom_ports/mem.h"

 // delta = 4/16 * clamp(a - o, -s, s) + 1/16 * clamp(b - o, -s, s) +
 //         3/16 * clamp(c - o, -s, s) + 3/16 * clamp(d - o, -s, s) +
 //         1/16 * clamp(e - o, -s, s) + 4/16 * clamp(f - o, -s, s)
 SIMD_INLINE v128 calc_delta(v128 o, v128 a, v128 b, v128 c, v128 d, v128 e,
                             v128 f, v128 sp, v128 sm) {
   // The difference will be 9 bit, offset by 128 so we can use saturated
   // sub to avoid going to 16 bit temporarily before "strength" clipping.
   const v128 c128 = v128_dup_8(128);
   const v128 x = v128_add_8(c128, o);
   const v128 c8 = v128_dup_8(8);
   const v128 tmp = v128_add_8(
       v128_max_s8(v128_min_s8(v128_ssub_s8(v128_add_8(c128, c), x), sp), sm),
       v128_max_s8(v128_min_s8(v128_ssub_s8(v128_add_8(c128, d), x), sp), sm));
   const v128 delta = v128_add_8(
       v128_add_8(
           v128_shl_8(
               v128_add_8(
                   v128_max_s8(
                       v128_min_s8(v128_ssub_s8(v128_add_8(c128, a), x), sp),
                       sm),
                   v128_max_s8(
                       v128_min_s8(v128_ssub_s8(v128_add_8(c128, f), x), sp),
                       sm)),
               2),
           v128_add_8(
               v128_max_s8(v128_min_s8(v128_ssub_s8(v128_add_8(c128, b), x), sp),
                           sm),
               v128_max_s8(v128_min_s8(v128_ssub_s8(v128_add_8(c128, e), x), sp),
                           sm))),
       v128_add_8(v128_add_8(tmp, tmp), tmp));
   return v128_add_8(
       o,
       v128_shr_s8(
           v128_add_8(c8, v128_add_8(delta, v128_cmplt_s8(delta, v128_zero()))),
           4));
 }

 // Process blocks of width 8, two lines at a time, 8 bit.
 static void clpf_block8(const uint8_t *src, uint8_t *dst, int sstride,
                         int dstride, int x0, int y0, int sizey, int width,
                         int height, unsigned int strength) {
   const int bottom = height - 2 - y0;
   const int right = width - 8 - x0;
   const v128 sp = v128_dup_8(strength);
   const v128 sm = v128_dup_8(-(int)strength);
   DECLARE_ALIGNED(16, static const uint64_t,
                   b_shuff[]) = { 0x0504030201000000LL, 0x0d0c0b0a09080808LL };
   DECLARE_ALIGNED(16, static const uint64_t,
                   c_shuff[]) = { 0x0605040302010000LL, 0x0e0d0c0b0a090808LL };
   DECLARE_ALIGNED(16, static const uint64_t,
                   d_shuff[]) = { 0x0707060504030201LL, 0x0f0f0e0d0c0b0a09LL };
   DECLARE_ALIGNED(16, static const uint64_t,
                   e_shuff[]) = { 0x0707070605040302LL, 0x0f0f0f0e0d0c0b0aLL };
   int y;

   dst += x0 + y0 * dstride;
   src += x0 + y0 * sstride;

   for (y = 0; y < sizey; y += 2) {
     const v64 l1 = v64_load_aligned(src);
     const v64 l2 = v64_load_aligned(src + sstride);
     v128 o = v128_from_v64(l1, l2);
     const v128 a =
         v128_from_v64(v64_load_aligned(src - (y != -y0) * sstride), l1);
     const v128 f = v128_from_v64(
         l2, v64_load_aligned(src + ((y != bottom) + 1) * sstride));
     v128 b, c, d, e;

     if (x0) {
       b = v128_from_v64(v64_load_unaligned(src - 2),
                         v64_load_unaligned(src - 2 + sstride));
       c = v128_from_v64(v64_load_unaligned(src - 1),
                         v64_load_unaligned(src - 1 + sstride));
     } else {  // Left clipping
       b = v128_shuffle_8(o, v128_load_aligned(b_shuff));
       c = v128_shuffle_8(o, v128_load_aligned(c_shuff));
     }
     if (right) {
       d = v128_from_v64(v64_load_unaligned(src + 1),
                         v64_load_unaligned(src + 1 + sstride));
       e = v128_from_v64(v64_load_unaligned(src + 2),
                         v64_load_unaligned(src + 2 + sstride));
     } else {  // Right clipping
       d = v128_shuffle_8(o, v128_load_aligned(d_shuff));
       e = v128_shuffle_8(o, v128_load_aligned(e_shuff));
     }

     o = calc_delta(o, a, b, c, d, e, f, sp, sm);
     v64_store_aligned(dst, v128_high_v64(o));
     v64_store_aligned(dst + dstride, v128_low_v64(o));
     src += sstride * 2;
     dst += dstride * 2;
   }
 }

 // Process blocks of width 4, four lines at a time, 8 bit.
 static void clpf_block4(const uint8_t *src, uint8_t *dst, int sstride,
                         int dstride, int x0, int y0, int sizey, int width,
                         int height, unsigned int strength) {
   const v128 sp = v128_dup_8(strength);
   const v128 sm = v128_dup_8(-(int)strength);
   const int right = width - 4 - x0;
   const int bottom = height - 4 - y0;
   DECLARE_ALIGNED(16, static const uint64_t,
                   b_shuff[]) = { 0x0504040401000000LL, 0x0d0c0c0c09080808LL };
   DECLARE_ALIGNED(16, static const uint64_t,
                   c_shuff[]) = { 0x0605040402010000LL, 0x0e0d0c0c0a090808LL };
   DECLARE_ALIGNED(16, static const uint64_t,
                   d_shuff[]) = { 0x0707060503030201LL, 0x0f0f0e0d0b0b0a09LL };
   DECLARE_ALIGNED(16, static const uint64_t,
                   e_shuff[]) = { 0x0707070603030302LL, 0x0f0f0f0e0b0b0b0aLL };
   int y;

   dst += x0 + y0 * dstride;
   src += x0 + y0 * sstride;

   for (y = 0; y < sizey; y += 4) {
     const uint32_t l0 = u32_load_aligned(src - (y != -y0) * sstride);
     const uint32_t l1 = u32_load_aligned(src);
     const uint32_t l2 = u32_load_aligned(src + sstride);
     const uint32_t l3 = u32_load_aligned(src + 2 * sstride);
     const uint32_t l4 = u32_load_aligned(src + 3 * sstride);
     const uint32_t l5 = u32_load_aligned(src + ((y != bottom) + 3) * sstride);
     v128 o = v128_from_32(l1, l2, l3, l4);
     const v128 a = v128_from_32(l0, l1, l2, l3);
     const v128 f = v128_from_32(l2, l3, l4, l5);
     v128 b, c, d, e;

     if (x0) {
       b = v128_from_32(u32_load_unaligned(src - 2),
                        u32_load_unaligned(src + sstride - 2),
                        u32_load_unaligned(src + 2 * sstride - 2),
                        u32_load_unaligned(src + 3 * sstride - 2));
       c = v128_from_32(u32_load_unaligned(src - 1),
                        u32_load_unaligned(src + sstride - 1),
                        u32_load_unaligned(src + 2 * sstride - 1),
                        u32_load_unaligned(src + 3 * sstride - 1));
     } else {  // Left clipping
       b = v128_shuffle_8(o, v128_load_aligned(b_shuff));
       c = v128_shuffle_8(o, v128_load_aligned(c_shuff));
     }
     if (right) {
       d = v128_from_32(u32_load_unaligned(src + 1),
                        u32_load_unaligned(src + sstride + 1),
                        u32_load_unaligned(src + 2 * sstride + 1),
                        u32_load_unaligned(src + 3 * sstride + 1));
       e = v128_from_32(u32_load_unaligned(src + 2 * !!right),
                        u32_load_unaligned(src + sstride + 2),
                        u32_load_unaligned(src + 2 * sstride + 2),
                        u32_load_unaligned(src + 3 * sstride + 2));
     } else {  // Right clipping
       d = v128_shuffle_8(o, v128_load_aligned(d_shuff));
       e = v128_shuffle_8(o, v128_load_aligned(e_shuff));
     }

     o = calc_delta(o, a, b, c, d, e, f, sp, sm);
     u32_store_aligned(dst, v128_low_u32(v128_shr_n_byte(o, 12)));
     u32_store_aligned(dst + dstride, v128_low_u32(v128_shr_n_byte(o, 8)));
     u32_store_aligned(dst + 2 * dstride, v128_low_u32(v128_shr_n_byte(o, 4)));
     u32_store_aligned(dst + 3 * dstride, v128_low_u32(o));

     dst += 4 * dstride;
     src += 4 * sstride;
   }
 }

 void SIMD_FUNC(aom_clpf_block)(const uint8_t *src, uint8_t *dst, int sstride,
                                int dstride, int x0, int y0, int sizex,
                                int sizey, int width, int height,
                                unsigned int strength) {
   if ((sizex != 4 && sizex != 8) || ((sizey & 3) && sizex == 4)) {
     // Fallback to C for odd sizes:
     // * block widths not 4 or 8
     // * block heights not a multiple of 4 if the block width is 4
     aom_clpf_block_c(src, dst, sstride, dstride, x0, y0, sizex, sizey, width,
                      height, strength);
   } else {
     (sizex == 4 ? clpf_block4 : clpf_block8)(src, dst, sstride, dstride, x0, y0,
                                              sizey, width, height, strength);
   }
 }

 #if CONFIG_AOM_HIGHBITDEPTH
 // delta = 4/16 * clamp(a - o, -s, s) + 1/16 * clamp(b - o, -s, s) +
 //         3/16 * clamp(c - o, -s, s) + 3/16 * clamp(d - o, -s, s) +
 //         1/16 * clamp(e - o, -s, s) + 4/16 * clamp(f - o, -s, s)
 SIMD_INLINE v128 calc_delta_hbd(v128 o, v128 a, v128 b, v128 c, v128 d, v128 e,
                                 v128 f, v128 sp, v128 sm) {
   const v128 c8 = v128_dup_16(8);
   const v128 tmp =
       v128_add_16(v128_max_s16(v128_min_s16(v128_sub_16(c, o), sp), sm),
                   v128_max_s16(v128_min_s16(v128_sub_16(d, o), sp), sm));
   const v128 delta = v128_add_16(
       v128_add_16(
           v128_shl_16(
               v128_add_16(
                   v128_max_s16(v128_min_s16(v128_sub_16(a, o), sp), sm),
                   v128_max_s16(v128_min_s16(v128_sub_16(f, o), sp), sm)),
               2),
           v128_add_16(v128_max_s16(v128_min_s16(v128_sub_16(b, o), sp), sm),
                       v128_max_s16(v128_min_s16(v128_sub_16(e, o), sp), sm))),
       v128_add_16(v128_add_16(tmp, tmp), tmp));
   return v128_add_16(
       o, v128_shr_s16(
              v128_add_16(
                  c8, v128_add_16(delta, v128_cmplt_s16(delta, v128_zero()))),
              4));
 }

 static void calc_delta_hbd4(v128 o, v128 a, v128 b, v128 c, v128 d, v128 e,
                             v128 f, uint16_t *dst, v128 sp, v128 sm,
                             int dstride) {
   o = calc_delta_hbd(o, a, b, c, d, e, f, sp, sm);
   v64_store_aligned(dst, v128_high_v64(o));
   v64_store_aligned(dst + dstride, v128_low_v64(o));
 }

 static void calc_delta_hbd8(v128 o, v128 a, v128 b, v128 c, v128 d, v128 e,
                             v128 f, uint16_t *dst, v128 sp, v128 sm) {
   v128_store_aligned(dst, calc_delta_hbd(o, a, b, c, d, e, f, sp, sm));
 }

 // Process blocks of width 4, two lines at time.
 SIMD_INLINE void clpf_block_hbd4(const uint16_t *src, uint16_t *dst,
                                  int sstride, int dstride, int x0, int y0,
                                  int sizey, int width, int height,
                                  unsigned int strength) {
   const v128 sp = v128_dup_16(strength);
   const v128 sm = v128_dup_16(-(int)strength);
   const int right = width - 4 - x0;
   const int bottom = height - 2 - y0;
   DECLARE_ALIGNED(16, static const uint64_t,
                   b_shuff[]) = { 0x0302010001000100LL, 0x0b0a090809080908LL };
   DECLARE_ALIGNED(16, static const uint64_t,
                   c_shuff[]) = { 0x0504030201000100LL, 0x0d0c0b0a09080908LL };
   DECLARE_ALIGNED(16, static const uint64_t,
                   d_shuff[]) = { 0x0706070605040302LL, 0x0f0e0f0e0d0c0b0aLL };
   DECLARE_ALIGNED(16, static const uint64_t,
                   e_shuff[]) = { 0x0706070607060504LL, 0x0f0e0f0e0f0e0d0cLL };
   int y;

   dst += x0 + y0 * dstride;
   src += x0 + y0 * sstride;

   for (y = 0; y < sizey; y += 2) {
     const v64 l1 = v64_load_aligned(src);
     const v64 l2 = v64_load_aligned(src + sstride);
     v128 o = v128_from_v64(l1, l2);
     const v128 a =
         v128_from_v64(v64_load_aligned(src - (y != -y0) * sstride), l1);
     const v128 f = v128_from_v64(
         l2, v64_load_aligned(src + ((y != bottom) + 1) * sstride));
     v128 b, c, d, e;

     if (x0) {
       b = v128_from_v64(v64_load_unaligned(src - 2),
                         v64_load_unaligned(src - 2 + sstride));
       c = v128_from_v64(v64_load_unaligned(src - 1),
                         v64_load_unaligned(src - 1 + sstride));
     } else {  // Left clipping
       b = v128_shuffle_8(o, v128_load_aligned(b_shuff));
       c = v128_shuffle_8(o, v128_load_aligned(c_shuff));
     }
     if (right) {
       d = v128_from_v64(v64_load_unaligned(src + 1),
                         v64_load_unaligned(src + 1 + sstride));
       e = v128_from_v64(v64_load_unaligned(src + 2),
                         v64_load_unaligned(src + 2 + sstride));
     } else {  // Right clipping
       d = v128_shuffle_8(o, v128_load_aligned(d_shuff));
       e = v128_shuffle_8(o, v128_load_aligned(e_shuff));
     }
     calc_delta_hbd4(o, a, b, c, d, e, f, dst, sp, sm, dstride);
     src += sstride * 2;
     dst += dstride * 2;
   }
 }

 // The most simple case.  Start here if you need to understand the functions.
 SIMD_INLINE void clpf_block_hbd(const uint16_t *src, uint16_t *dst, int sstride,
                                 int dstride, int x0, int y0, int sizey,
                                 int width, int height, unsigned int strength) {
   const v128 sp = v128_dup_16(strength);
   const v128 sm = v128_dup_16(-(int)strength);
   const int right = width - 8 - x0;
   const int bottom = height - 2 - y0;
   DECLARE_ALIGNED(16, static const uint64_t,
                   b_shuff[]) = { 0x0302010001000100LL, 0x0b0a090807060504LL };
   DECLARE_ALIGNED(16, static const uint64_t,
                   c_shuff[]) = { 0x0504030201000100LL, 0x0d0c0b0a09080706LL };
   DECLARE_ALIGNED(16, static const uint64_t,
                   d_shuff[]) = { 0x0908070605040302LL, 0x0f0e0f0e0d0c0b0aLL };
   DECLARE_ALIGNED(16, static const uint64_t,
                   e_shuff[]) = { 0x0b0a090807060504LL, 0x0f0e0f0e0f0e0d0cLL };
   int y;

   dst += x0 + y0 * dstride;
   src += x0 + y0 * sstride;

   // Read 8 set of pixels at a time.  Clipping along upper and lower
   // edges is handled by reading the upper or lower line twice.
   // Clipping along the left and right edges is handled by shuffle
   // instructions doing shift and pad.
   for (y = 0; y < sizey; y++) {
     const v128 o = v128_load_aligned(src);
     const v128 a = v128_load_aligned(src - (y != -y0) * sstride);
     const v128 f = v128_load_aligned(src + (y - 1 != bottom) * sstride);
     v128 b, c, d, e;

     if (x0) {
       b = v128_load_unaligned(src - 2);
       c = v128_load_unaligned(src - 1);
     } else {  // Left clipping
       b = v128_shuffle_8(o, v128_load_aligned(b_shuff));
       c = v128_shuffle_8(o, v128_load_aligned(c_shuff));
     }
     if (right) {
       d = v128_load_unaligned(src + 1);
       e = v128_load_unaligned(src + 2);
     } else {  // Right clipping
       d = v128_shuffle_8(o, v128_load_aligned(d_shuff));
       e = v128_shuffle_8(o, v128_load_aligned(e_shuff));
     }
     calc_delta_hbd8(o, a, b, c, d, e, f, dst, sp, sm);
     src += sstride;
     dst += dstride;
   }
 }

 void SIMD_FUNC(aom_clpf_block_hbd)(const uint16_t *src, uint16_t *dst,
                                    int sstride, int dstride, int x0, int y0,
                                    int sizex, int sizey, int width, int height,
                                    unsigned int strength) {
   if ((sizex != 4 && sizex != 8) || ((sizey & 1) && sizex == 4)) {
     // Fallback to C for odd sizes:
     // * block width not 4 or 8
     // * block heights not a multiple of 2 if the block width is 4
     aom_clpf_block_hbd_c(src, dst, sstride, dstride, x0, y0, sizex, sizey,
                          width, height, strength);
   } else {
     (sizex == 4 ? clpf_block_hbd4 : clpf_block_hbd)(
         src, dst, sstride, dstride, x0, y0, sizey, width, height, strength);
   }
 }
 #endif
	/*
	* 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 "./aom_dsp_rtcd.h"
	#include "aom_ports/mem.h"

	// delta = 4/16 * clamp(a - o, -s, s) + 1/16 * clamp(b - o, -s, s) +
	// 3/16 * clamp(c - o, -s, s) + 3/16 * clamp(d - o, -s, s) +
	// 1/16 * clamp(e - o, -s, s) + 4/16 * clamp(f - o, -s, s)
	SIMD_INLINE v128 calc_delta(v128 o, v128 a, v128 b, v128 c, v128 d, v128 e,
	v128 f, v128 sp, v128 sm) {
	// The difference will be 9 bit, offset by 128 so we can use saturated
	// sub to avoid going to 16 bit temporarily before "strength" clipping.
	const v128 c128 = v128_dup_8(128);
	const v128 x = v128_add_8(c128, o);
	const v128 c8 = v128_dup_8(8);
	const v128 tmp = v128_add_8(
	v128_max_s8(v128_min_s8(v128_ssub_s8(v128_add_8(c128, c), x), sp), sm),
	v128_max_s8(v128_min_s8(v128_ssub_s8(v128_add_8(c128, d), x), sp), sm));
	const v128 delta = v128_add_8(
	v128_add_8(
	v128_shl_8(
	v128_add_8(
	v128_max_s8(
	v128_min_s8(v128_ssub_s8(v128_add_8(c128, a), x), sp),
	sm),
	v128_max_s8(
	v128_min_s8(v128_ssub_s8(v128_add_8(c128, f), x), sp),
	sm)),
	2),
	v128_add_8(
	v128_max_s8(v128_min_s8(v128_ssub_s8(v128_add_8(c128, b), x), sp),
	sm),
	v128_max_s8(v128_min_s8(v128_ssub_s8(v128_add_8(c128, e), x), sp),
	sm))),
	v128_add_8(v128_add_8(tmp, tmp), tmp));
	return v128_add_8(
	o,
	v128_shr_s8(
	v128_add_8(c8, v128_add_8(delta, v128_cmplt_s8(delta, v128_zero()))),
	4));
	}

	// Process blocks of width 8, two lines at a time, 8 bit.
	static void clpf_block8(const uint8_t src, uint8_t dst, int sstride,
	int dstride, int x0, int y0, int sizey, int width,
	int height, unsigned int strength) {
	const int bottom = height - 2 - y0;
	const int right = width - 8 - x0;
	const v128 sp = v128_dup_8(strength);
	const v128 sm = v128_dup_8(-(int)strength);
	DECLARE_ALIGNED(16, static const uint64_t,
	b_shuff[]) = { 0x0504030201000000LL, 0x0d0c0b0a09080808LL };
	DECLARE_ALIGNED(16, static const uint64_t,
	c_shuff[]) = { 0x0605040302010000LL, 0x0e0d0c0b0a090808LL };
	DECLARE_ALIGNED(16, static const uint64_t,
	d_shuff[]) = { 0x0707060504030201LL, 0x0f0f0e0d0c0b0a09LL };
	DECLARE_ALIGNED(16, static const uint64_t,
	e_shuff[]) = { 0x0707070605040302LL, 0x0f0f0f0e0d0c0b0aLL };
	int y;

	dst += x0 + y0 * dstride;
	src += x0 + y0 * sstride;

	for (y = 0; y < sizey; y += 2) {
	const v64 l1 = v64_load_aligned(src);
	const v64 l2 = v64_load_aligned(src + sstride);
	v128 o = v128_from_v64(l1, l2);
	const v128 a =
	v128_from_v64(v64_load_aligned(src - (y != -y0) * sstride), l1);
	const v128 f = v128_from_v64(
	l2, v64_load_aligned(src + ((y != bottom) + 1) * sstride));
	v128 b, c, d, e;

	if (x0) {
	b = v128_from_v64(v64_load_unaligned(src - 2),
	v64_load_unaligned(src - 2 + sstride));
	c = v128_from_v64(v64_load_unaligned(src - 1),
	v64_load_unaligned(src - 1 + sstride));
	} else { // Left clipping
	b = v128_shuffle_8(o, v128_load_aligned(b_shuff));
	c = v128_shuffle_8(o, v128_load_aligned(c_shuff));
	}
	if (right) {
	d = v128_from_v64(v64_load_unaligned(src + 1),
	v64_load_unaligned(src + 1 + sstride));
	e = v128_from_v64(v64_load_unaligned(src + 2),
	v64_load_unaligned(src + 2 + sstride));
	} else { // Right clipping
	d = v128_shuffle_8(o, v128_load_aligned(d_shuff));
	e = v128_shuffle_8(o, v128_load_aligned(e_shuff));
	}

	o = calc_delta(o, a, b, c, d, e, f, sp, sm);
	v64_store_aligned(dst, v128_high_v64(o));
	v64_store_aligned(dst + dstride, v128_low_v64(o));
	src += sstride * 2;
	dst += dstride * 2;
	}
	}

	// Process blocks of width 4, four lines at a time, 8 bit.
	static void clpf_block4(const uint8_t src, uint8_t dst, int sstride,
	int dstride, int x0, int y0, int sizey, int width,
	int height, unsigned int strength) {
	const v128 sp = v128_dup_8(strength);
	const v128 sm = v128_dup_8(-(int)strength);
	const int right = width - 4 - x0;
	const int bottom = height - 4 - y0;
	DECLARE_ALIGNED(16, static const uint64_t,
	b_shuff[]) = { 0x0504040401000000LL, 0x0d0c0c0c09080808LL };
	DECLARE_ALIGNED(16, static const uint64_t,
	c_shuff[]) = { 0x0605040402010000LL, 0x0e0d0c0c0a090808LL };
	DECLARE_ALIGNED(16, static const uint64_t,
	d_shuff[]) = { 0x0707060503030201LL, 0x0f0f0e0d0b0b0a09LL };
	DECLARE_ALIGNED(16, static const uint64_t,
	e_shuff[]) = { 0x0707070603030302LL, 0x0f0f0f0e0b0b0b0aLL };
	int y;

	dst += x0 + y0 * dstride;
	src += x0 + y0 * sstride;

	for (y = 0; y < sizey; y += 4) {
	const uint32_t l0 = u32_load_aligned(src - (y != -y0) * sstride);
	const uint32_t l1 = u32_load_aligned(src);
	const uint32_t l2 = u32_load_aligned(src + sstride);
	const uint32_t l3 = u32_load_aligned(src + 2 * sstride);
	const uint32_t l4 = u32_load_aligned(src + 3 * sstride);
	const uint32_t l5 = u32_load_aligned(src + ((y != bottom) + 3) * sstride);
	v128 o = v128_from_32(l1, l2, l3, l4);
	const v128 a = v128_from_32(l0, l1, l2, l3);
	const v128 f = v128_from_32(l2, l3, l4, l5);
	v128 b, c, d, e;

	if (x0) {
	b = v128_from_32(u32_load_unaligned(src - 2),
	u32_load_unaligned(src + sstride - 2),
	u32_load_unaligned(src + 2 * sstride - 2),
	u32_load_unaligned(src + 3 * sstride - 2));
	c = v128_from_32(u32_load_unaligned(src - 1),
	u32_load_unaligned(src + sstride - 1),
	u32_load_unaligned(src + 2 * sstride - 1),
	u32_load_unaligned(src + 3 * sstride - 1));
	} else { // Left clipping
	b = v128_shuffle_8(o, v128_load_aligned(b_shuff));
	c = v128_shuffle_8(o, v128_load_aligned(c_shuff));
	}
	if (right) {
	d = v128_from_32(u32_load_unaligned(src + 1),
	u32_load_unaligned(src + sstride + 1),
	u32_load_unaligned(src + 2 * sstride + 1),
	u32_load_unaligned(src + 3 * sstride + 1));
	e = v128_from_32(u32_load_unaligned(src + 2 * !!right),
	u32_load_unaligned(src + sstride + 2),
	u32_load_unaligned(src + 2 * sstride + 2),
	u32_load_unaligned(src + 3 * sstride + 2));
	} else { // Right clipping
	d = v128_shuffle_8(o, v128_load_aligned(d_shuff));
	e = v128_shuffle_8(o, v128_load_aligned(e_shuff));
	}

	o = calc_delta(o, a, b, c, d, e, f, sp, sm);
	u32_store_aligned(dst, v128_low_u32(v128_shr_n_byte(o, 12)));
	u32_store_aligned(dst + dstride, v128_low_u32(v128_shr_n_byte(o, 8)));
	u32_store_aligned(dst + 2 * dstride, v128_low_u32(v128_shr_n_byte(o, 4)));
	u32_store_aligned(dst + 3 * dstride, v128_low_u32(o));

	dst += 4 * dstride;
	src += 4 * sstride;
	}
	}

	void SIMD_FUNC(aom_clpf_block)(const uint8_t src, uint8_t dst, int sstride,
	int dstride, int x0, int y0, int sizex,
	int sizey, int width, int height,
	unsigned int strength) {
	if ((sizex != 4 && sizex != 8) \|\| ((sizey & 3) && sizex == 4)) {
	// Fallback to C for odd sizes:
	// * block widths not 4 or 8
	// * block heights not a multiple of 4 if the block width is 4
	aom_clpf_block_c(src, dst, sstride, dstride, x0, y0, sizex, sizey, width,
	height, strength);
	} else {
	(sizex == 4 ? clpf_block4 : clpf_block8)(src, dst, sstride, dstride, x0, y0,
	sizey, width, height, strength);
	}
	}

	#if CONFIG_AOM_HIGHBITDEPTH
	// delta = 4/16 * clamp(a - o, -s, s) + 1/16 * clamp(b - o, -s, s) +
	// 3/16 * clamp(c - o, -s, s) + 3/16 * clamp(d - o, -s, s) +
	// 1/16 * clamp(e - o, -s, s) + 4/16 * clamp(f - o, -s, s)
	SIMD_INLINE v128 calc_delta_hbd(v128 o, v128 a, v128 b, v128 c, v128 d, v128 e,
	v128 f, v128 sp, v128 sm) {
	const v128 c8 = v128_dup_16(8);
	const v128 tmp =
	v128_add_16(v128_max_s16(v128_min_s16(v128_sub_16(c, o), sp), sm),
	v128_max_s16(v128_min_s16(v128_sub_16(d, o), sp), sm));
	const v128 delta = v128_add_16(
	v128_add_16(
	v128_shl_16(
	v128_add_16(
	v128_max_s16(v128_min_s16(v128_sub_16(a, o), sp), sm),
	v128_max_s16(v128_min_s16(v128_sub_16(f, o), sp), sm)),
	2),
	v128_add_16(v128_max_s16(v128_min_s16(v128_sub_16(b, o), sp), sm),
	v128_max_s16(v128_min_s16(v128_sub_16(e, o), sp), sm))),
	v128_add_16(v128_add_16(tmp, tmp), tmp));
	return v128_add_16(
	o, v128_shr_s16(
	v128_add_16(
	c8, v128_add_16(delta, v128_cmplt_s16(delta, v128_zero()))),
	4));
	}

	static void calc_delta_hbd4(v128 o, v128 a, v128 b, v128 c, v128 d, v128 e,
	v128 f, uint16_t *dst, v128 sp, v128 sm,
	int dstride) {
	o = calc_delta_hbd(o, a, b, c, d, e, f, sp, sm);
	v64_store_aligned(dst, v128_high_v64(o));
	v64_store_aligned(dst + dstride, v128_low_v64(o));
	}

	static void calc_delta_hbd8(v128 o, v128 a, v128 b, v128 c, v128 d, v128 e,
	v128 f, uint16_t *dst, v128 sp, v128 sm) {
	v128_store_aligned(dst, calc_delta_hbd(o, a, b, c, d, e, f, sp, sm));
	}

	// Process blocks of width 4, two lines at time.
	SIMD_INLINE void clpf_block_hbd4(const uint16_t src, uint16_t dst,
	int sstride, int dstride, int x0, int y0,
	int sizey, int width, int height,
	unsigned int strength) {
	const v128 sp = v128_dup_16(strength);
	const v128 sm = v128_dup_16(-(int)strength);
	const int right = width - 4 - x0;
	const int bottom = height - 2 - y0;
	DECLARE_ALIGNED(16, static const uint64_t,
	b_shuff[]) = { 0x0302010001000100LL, 0x0b0a090809080908LL };
	DECLARE_ALIGNED(16, static const uint64_t,
	c_shuff[]) = { 0x0504030201000100LL, 0x0d0c0b0a09080908LL };
	DECLARE_ALIGNED(16, static const uint64_t,
	d_shuff[]) = { 0x0706070605040302LL, 0x0f0e0f0e0d0c0b0aLL };
	DECLARE_ALIGNED(16, static const uint64_t,
	e_shuff[]) = { 0x0706070607060504LL, 0x0f0e0f0e0f0e0d0cLL };
	int y;

	dst += x0 + y0 * dstride;
	src += x0 + y0 * sstride;

	for (y = 0; y < sizey; y += 2) {
	const v64 l1 = v64_load_aligned(src);
	const v64 l2 = v64_load_aligned(src + sstride);
	v128 o = v128_from_v64(l1, l2);
	const v128 a =
	v128_from_v64(v64_load_aligned(src - (y != -y0) * sstride), l1);
	const v128 f = v128_from_v64(
	l2, v64_load_aligned(src + ((y != bottom) + 1) * sstride));
	v128 b, c, d, e;

	if (x0) {
	b = v128_from_v64(v64_load_unaligned(src - 2),
	v64_load_unaligned(src - 2 + sstride));
	c = v128_from_v64(v64_load_unaligned(src - 1),
	v64_load_unaligned(src - 1 + sstride));
	} else { // Left clipping
	b = v128_shuffle_8(o, v128_load_aligned(b_shuff));
	c = v128_shuffle_8(o, v128_load_aligned(c_shuff));
	}
	if (right) {
	d = v128_from_v64(v64_load_unaligned(src + 1),
	v64_load_unaligned(src + 1 + sstride));
	e = v128_from_v64(v64_load_unaligned(src + 2),
	v64_load_unaligned(src + 2 + sstride));
	} else { // Right clipping
	d = v128_shuffle_8(o, v128_load_aligned(d_shuff));
	e = v128_shuffle_8(o, v128_load_aligned(e_shuff));
	}
	calc_delta_hbd4(o, a, b, c, d, e, f, dst, sp, sm, dstride);
	src += sstride * 2;
	dst += dstride * 2;
	}
	}

	// The most simple case. Start here if you need to understand the functions.
	SIMD_INLINE void clpf_block_hbd(const uint16_t src, uint16_t dst, int sstride,
	int dstride, int x0, int y0, int sizey,
	int width, int height, unsigned int strength) {
	const v128 sp = v128_dup_16(strength);
	const v128 sm = v128_dup_16(-(int)strength);
	const int right = width - 8 - x0;
	const int bottom = height - 2 - y0;
	DECLARE_ALIGNED(16, static const uint64_t,
	b_shuff[]) = { 0x0302010001000100LL, 0x0b0a090807060504LL };
	DECLARE_ALIGNED(16, static const uint64_t,
	c_shuff[]) = { 0x0504030201000100LL, 0x0d0c0b0a09080706LL };
	DECLARE_ALIGNED(16, static const uint64_t,
	d_shuff[]) = { 0x0908070605040302LL, 0x0f0e0f0e0d0c0b0aLL };
	DECLARE_ALIGNED(16, static const uint64_t,
	e_shuff[]) = { 0x0b0a090807060504LL, 0x0f0e0f0e0f0e0d0cLL };
	int y;

	dst += x0 + y0 * dstride;
	src += x0 + y0 * sstride;

	// Read 8 set of pixels at a time. Clipping along upper and lower
	// edges is handled by reading the upper or lower line twice.
	// Clipping along the left and right edges is handled by shuffle
	// instructions doing shift and pad.
	for (y = 0; y < sizey; y++) {
	const v128 o = v128_load_aligned(src);
	const v128 a = v128_load_aligned(src - (y != -y0) * sstride);
	const v128 f = v128_load_aligned(src + (y - 1 != bottom) * sstride);
	v128 b, c, d, e;

	if (x0) {
	b = v128_load_unaligned(src - 2);
	c = v128_load_unaligned(src - 1);
	} else { // Left clipping
	b = v128_shuffle_8(o, v128_load_aligned(b_shuff));
	c = v128_shuffle_8(o, v128_load_aligned(c_shuff));
	}
	if (right) {
	d = v128_load_unaligned(src + 1);
	e = v128_load_unaligned(src + 2);
	} else { // Right clipping
	d = v128_shuffle_8(o, v128_load_aligned(d_shuff));
	e = v128_shuffle_8(o, v128_load_aligned(e_shuff));
	}
	calc_delta_hbd8(o, a, b, c, d, e, f, dst, sp, sm);
	src += sstride;
	dst += dstride;
	}
	}

	void SIMD_FUNC(aom_clpf_block_hbd)(const uint16_t src, uint16_t dst,
	int sstride, int dstride, int x0, int y0,
	int sizex, int sizey, int width, int height,
	unsigned int strength) {
	if ((sizex != 4 && sizex != 8) \|\| ((sizey & 1) && sizex == 4)) {
	// Fallback to C for odd sizes:
	// * block width not 4 or 8
	// * block heights not a multiple of 2 if the block width is 4
	aom_clpf_block_hbd_c(src, dst, sstride, dstride, x0, y0, sizex, sizey,
	width, height, strength);
	} else {
	(sizex == 4 ? clpf_block_hbd4 : clpf_block_hbd)(
	src, dst, sstride, dstride, x0, y0, sizey, width, height, strength);
	}
	}
	#endif