av1/common/arm/highbd_warp_plane_neon.h - aom - Git at Google

 /*
  * Copyright (c) 2023, 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.
  */
 #ifndef AOM_AV1_COMMON_ARM_HIGHBD_WARP_PLANE_NEON_H_
 #define AOM_AV1_COMMON_ARM_HIGHBD_WARP_PLANE_NEON_H_

 #include <arm_neon.h>
 #include <assert.h>
 #include <stdbool.h>

 #include "aom_dsp/aom_dsp_common.h"
 #include "aom_dsp/arm/mem_neon.h"
 #include "aom_dsp/arm/sum_neon.h"
 #include "aom_ports/mem.h"
 #include "av1/common/scale.h"
 #include "av1/common/warped_motion.h"
 #include "config/av1_rtcd.h"

 static AOM_FORCE_INLINE int16x8_t
 highbd_horizontal_filter_4x1_f4(uint16x8x2_t in, int bd, int sx, int alpha);

 static AOM_FORCE_INLINE int16x8_t
 highbd_horizontal_filter_8x1_f8(uint16x8x2_t in, int bd, int sx, int alpha);

 static AOM_FORCE_INLINE int16x8_t
 highbd_horizontal_filter_4x1_f1(uint16x8x2_t in, int bd, int sx);

 static AOM_FORCE_INLINE int16x8_t
 highbd_horizontal_filter_8x1_f1(uint16x8x2_t in, int bd, int sx);

 static AOM_FORCE_INLINE int32x4_t vertical_filter_4x1_f1(const int16x8_t *tmp,
                                                          int sy);

 static AOM_FORCE_INLINE int32x4x2_t vertical_filter_8x1_f1(const int16x8_t *tmp,
                                                            int sy);

 static AOM_FORCE_INLINE int32x4_t vertical_filter_4x1_f4(const int16x8_t *tmp,
                                                          int sy, int gamma);

 static AOM_FORCE_INLINE int32x4x2_t vertical_filter_8x1_f8(const int16x8_t *tmp,
                                                            int sy, int gamma);

 static AOM_FORCE_INLINE int16x8_t load_filters_1(int ofs) {
   const int ofs0 = ROUND_POWER_OF_TWO(ofs, WARPEDDIFF_PREC_BITS);

   const int16_t *base =
       (int16_t *)av1_warped_filter + WARPEDPIXEL_PREC_SHIFTS * 8;
   return vld1q_s16(base + ofs0 * 8);
 }

 static AOM_FORCE_INLINE void load_filters_4(int16x8_t out[], int ofs,
                                             int stride) {
   const int ofs0 = ROUND_POWER_OF_TWO(ofs + stride * 0, WARPEDDIFF_PREC_BITS);
   const int ofs1 = ROUND_POWER_OF_TWO(ofs + stride * 1, WARPEDDIFF_PREC_BITS);
   const int ofs2 = ROUND_POWER_OF_TWO(ofs + stride * 2, WARPEDDIFF_PREC_BITS);
   const int ofs3 = ROUND_POWER_OF_TWO(ofs + stride * 3, WARPEDDIFF_PREC_BITS);

   const int16_t *base =
       (int16_t *)av1_warped_filter + WARPEDPIXEL_PREC_SHIFTS * 8;
   out[0] = vld1q_s16(base + ofs0 * 8);
   out[1] = vld1q_s16(base + ofs1 * 8);
   out[2] = vld1q_s16(base + ofs2 * 8);
   out[3] = vld1q_s16(base + ofs3 * 8);
 }

 static AOM_FORCE_INLINE void load_filters_8(int16x8_t out[], int ofs,
                                             int stride) {
   const int ofs0 = ROUND_POWER_OF_TWO(ofs + stride * 0, WARPEDDIFF_PREC_BITS);
   const int ofs1 = ROUND_POWER_OF_TWO(ofs + stride * 1, WARPEDDIFF_PREC_BITS);
   const int ofs2 = ROUND_POWER_OF_TWO(ofs + stride * 2, WARPEDDIFF_PREC_BITS);
   const int ofs3 = ROUND_POWER_OF_TWO(ofs + stride * 3, WARPEDDIFF_PREC_BITS);
   const int ofs4 = ROUND_POWER_OF_TWO(ofs + stride * 4, WARPEDDIFF_PREC_BITS);
   const int ofs5 = ROUND_POWER_OF_TWO(ofs + stride * 5, WARPEDDIFF_PREC_BITS);
   const int ofs6 = ROUND_POWER_OF_TWO(ofs + stride * 6, WARPEDDIFF_PREC_BITS);
   const int ofs7 = ROUND_POWER_OF_TWO(ofs + stride * 7, WARPEDDIFF_PREC_BITS);

   const int16_t *base =
       (int16_t *)av1_warped_filter + WARPEDPIXEL_PREC_SHIFTS * 8;
   out[0] = vld1q_s16(base + ofs0 * 8);
   out[1] = vld1q_s16(base + ofs1 * 8);
   out[2] = vld1q_s16(base + ofs2 * 8);
   out[3] = vld1q_s16(base + ofs3 * 8);
   out[4] = vld1q_s16(base + ofs4 * 8);
   out[5] = vld1q_s16(base + ofs5 * 8);
   out[6] = vld1q_s16(base + ofs6 * 8);
   out[7] = vld1q_s16(base + ofs7 * 8);
 }

 static AOM_FORCE_INLINE uint16x4_t clip_pixel_highbd_vec(int32x4_t val,
                                                          int bd) {
   const int limit = (1 << bd) - 1;
   return vqmovun_s32(vminq_s32(val, vdupq_n_s32(limit)));
 }

 static AOM_FORCE_INLINE void warp_affine_horizontal(const uint16_t *ref,
                                                     int width, int height,
                                                     int stride, int p_width,
                                                     int16_t alpha, int16_t beta,
                                                     int iy4, int sx4, int ix4,
                                                     int16x8_t tmp[], int bd) {
   const int round0 = (bd == 12) ? ROUND0_BITS + 2 : ROUND0_BITS;

   if (ix4 <= -7) {
     for (int k = 0; k < 15; ++k) {
       int iy = clamp(iy4 + k - 7, 0, height - 1);
       int32_t dup_val = (1 << (bd + FILTER_BITS - round0 - 1)) +
                         ref[iy * stride] * (1 << (FILTER_BITS - round0));
       tmp[k] = vdupq_n_s16(dup_val);
     }
     return;
   } else if (ix4 >= width + 6) {
     for (int k = 0; k < 15; ++k) {
       int iy = clamp(iy4 + k - 7, 0, height - 1);
       int32_t dup_val =
           (1 << (bd + FILTER_BITS - round0 - 1)) +
           ref[iy * stride + (width - 1)] * (1 << (FILTER_BITS - round0));
       tmp[k] = vdupq_n_s16(dup_val);
     }
     return;
   }

   static const uint16_t kIotaArr[] = { 0, 1, 2,  3,  4,  5,  6,  7,
                                        8, 9, 10, 11, 12, 13, 14, 15 };
   const uint16x8_t indx0 = vld1q_u16(kIotaArr);
   const uint16x8_t indx1 = vld1q_u16(kIotaArr + 8);

   const int out_of_boundary_left = -(ix4 - 6);
   const int out_of_boundary_right = (ix4 + 8) - width;

 #define APPLY_HORIZONTAL_SHIFT(fn, ...)                                   \
   do {                                                                    \
     if (out_of_boundary_left >= 0 || out_of_boundary_right >= 0) {        \
       for (int k = 0; k < 15; ++k) {                                      \
         const int iy = clamp(iy4 + k - 7, 0, height - 1);                 \
         uint16x8x2_t src_1 = vld1q_u16_x2(ref + iy * stride + ix4 - 7);   \
                                                                           \
         if (out_of_boundary_left >= 0) {                                  \
           uint16x8_t cmp_vec = vdupq_n_u16(out_of_boundary_left);         \
           uint16x8_t vec_dup = vdupq_n_u16(ref[iy * stride]);             \
           uint16x8_t mask0 = vcleq_u16(indx0, cmp_vec);                   \
           uint16x8_t mask1 = vcleq_u16(indx1, cmp_vec);                   \
           src_1.val[0] = vbslq_u16(mask0, vec_dup, src_1.val[0]);         \
           src_1.val[1] = vbslq_u16(mask1, vec_dup, src_1.val[1]);         \
         }                                                                 \
         if (out_of_boundary_right >= 0) {                                 \
           uint16x8_t cmp_vec = vdupq_n_u16(15 - out_of_boundary_right);   \
           uint16x8_t vec_dup = vdupq_n_u16(ref[iy * stride + width - 1]); \
           uint16x8_t mask0 = vcgeq_u16(indx0, cmp_vec);                   \
           uint16x8_t mask1 = vcgeq_u16(indx1, cmp_vec);                   \
           src_1.val[0] = vbslq_u16(mask0, vec_dup, src_1.val[0]);         \
           src_1.val[1] = vbslq_u16(mask1, vec_dup, src_1.val[1]);         \
         }                                                                 \
         tmp[k] = (fn)(src_1, __VA_ARGS__);                                \
       }                                                                   \
     } else {                                                              \
       for (int k = 0; k < 15; ++k) {                                      \
         const int iy = clamp(iy4 + k - 7, 0, height - 1);                 \
         uint16x8x2_t src_1 = vld1q_u16_x2(ref + iy * stride + ix4 - 7);   \
         tmp[k] = (fn)(src_1, __VA_ARGS__);                                \
       }                                                                   \
     }                                                                     \
   } while (0)

   if (p_width == 4) {
     if (beta == 0) {
       if (alpha == 0) {
         APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_4x1_f1, bd, sx4);
       } else {
         APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_4x1_f4, bd, sx4, alpha);
       }
     } else {
       if (alpha == 0) {
         APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_4x1_f1, bd,
                                (sx4 + beta * (k - 3)));
       } else {
         APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_4x1_f4, bd,
                                (sx4 + beta * (k - 3)), alpha);
       }
     }
   } else {
     if (beta == 0) {
       if (alpha == 0) {
         APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_8x1_f1, bd, sx4);
       } else {
         APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_8x1_f8, bd, sx4, alpha);
       }
     } else {
       if (alpha == 0) {
         APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_8x1_f1, bd,
                                (sx4 + beta * (k - 3)));
       } else {
         APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_8x1_f8, bd,
                                (sx4 + beta * (k - 3)), alpha);
       }
     }
   }
 }

 static AOM_FORCE_INLINE void highbd_vertical_filter_4x1_f4(
     uint16_t *pred, int p_stride, int bd, uint16_t *dst, int dst_stride,
     bool is_compound, bool do_average, bool use_dist_wtd_comp_avg, int fwd,
     int bwd, int16_t gamma, const int16x8_t *tmp, int i, int sy, int j) {
   int32x4_t sum0 = gamma == 0 ? vertical_filter_4x1_f1(tmp, sy)
                               : vertical_filter_4x1_f4(tmp, sy, gamma);

   const int round0 = (bd == 12) ? ROUND0_BITS + 2 : ROUND0_BITS;
   const int offset_bits_vert = bd + 2 * FILTER_BITS - round0;

   sum0 = vaddq_s32(sum0, vdupq_n_s32(1 << offset_bits_vert));

   uint16_t *dst16 = &pred[i * p_stride + j];

   if (!is_compound) {
     const int reduce_bits_vert = 2 * FILTER_BITS - round0;
     sum0 = vrshlq_s32(sum0, vdupq_n_s32(-reduce_bits_vert));

     const int res_sub_const = (1 << (bd - 1)) + (1 << bd);
     sum0 = vsubq_s32(sum0, vdupq_n_s32(res_sub_const));
     uint16x4_t res0 = clip_pixel_highbd_vec(sum0, bd);
     vst1_u16(dst16, res0);
     return;
   }

   sum0 = vrshrq_n_s32(sum0, COMPOUND_ROUND1_BITS);

   uint16_t *p = &dst[i * dst_stride + j];

   if (!do_average) {
     vst1_u16(p, vqmovun_s32(sum0));
     return;
   }

   uint16x4_t p0 = vld1_u16(p);
   int32x4_t p_vec0 = vreinterpretq_s32_u32(vmovl_u16(p0));
   if (use_dist_wtd_comp_avg) {
     p_vec0 = vmulq_n_s32(p_vec0, fwd);
     p_vec0 = vmlaq_n_s32(p_vec0, sum0, bwd);
     p_vec0 = vshrq_n_s32(p_vec0, DIST_PRECISION_BITS);
   } else {
     p_vec0 = vhaddq_s32(p_vec0, sum0);
   }

   const int offset_bits = bd + 2 * FILTER_BITS - round0;
   const int round1 = COMPOUND_ROUND1_BITS;
   const int res_sub_const =
       (1 << (offset_bits - round1)) + (1 << (offset_bits - round1 - 1));
   const int round_bits = 2 * FILTER_BITS - round0 - round1;

   p_vec0 = vsubq_s32(p_vec0, vdupq_n_s32(res_sub_const));
   p_vec0 = vrshlq_s32(p_vec0, vdupq_n_s32(-round_bits));
   uint16x4_t res0 = clip_pixel_highbd_vec(p_vec0, bd);
   vst1_u16(dst16, res0);
 }

 static AOM_FORCE_INLINE void highbd_vertical_filter_8x1_f8(
     uint16_t *pred, int p_stride, int bd, uint16_t *dst, int dst_stride,
     bool is_compound, bool do_average, bool use_dist_wtd_comp_avg, int fwd,
     int bwd, int16_t gamma, const int16x8_t *tmp, int i, int sy, int j) {
   int32x4x2_t sums = gamma == 0 ? vertical_filter_8x1_f1(tmp, sy)
                                 : vertical_filter_8x1_f8(tmp, sy, gamma);
   int32x4_t sum0 = sums.val[0];
   int32x4_t sum1 = sums.val[1];

   const int round0 = (bd == 12) ? ROUND0_BITS + 2 : ROUND0_BITS;
   const int offset_bits_vert = bd + 2 * FILTER_BITS - round0;

   sum0 = vaddq_s32(sum0, vdupq_n_s32(1 << offset_bits_vert));
   sum1 = vaddq_s32(sum1, vdupq_n_s32(1 << offset_bits_vert));

   uint16_t *dst16 = &pred[i * p_stride + j];

   if (!is_compound) {
     const int reduce_bits_vert = 2 * FILTER_BITS - round0;
     sum0 = vrshlq_s32(sum0, vdupq_n_s32(-reduce_bits_vert));
     sum1 = vrshlq_s32(sum1, vdupq_n_s32(-reduce_bits_vert));

     const int res_sub_const = (1 << (bd - 1)) + (1 << bd);
     sum0 = vsubq_s32(sum0, vdupq_n_s32(res_sub_const));
     sum1 = vsubq_s32(sum1, vdupq_n_s32(res_sub_const));
     uint16x4_t res0 = clip_pixel_highbd_vec(sum0, bd);
     uint16x4_t res1 = clip_pixel_highbd_vec(sum1, bd);
     vst1_u16(dst16, res0);
     vst1_u16(dst16 + 4, res1);
     return;
   }

   sum0 = vrshrq_n_s32(sum0, COMPOUND_ROUND1_BITS);
   sum1 = vrshrq_n_s32(sum1, COMPOUND_ROUND1_BITS);

   uint16_t *p = &dst[i * dst_stride + j];

   if (!do_average) {
     vst1_u16(p, vqmovun_s32(sum0));
     vst1_u16(p + 4, vqmovun_s32(sum1));
     return;
   }

   uint16x8_t p0 = vld1q_u16(p);
   int32x4_t p_vec0 = vreinterpretq_s32_u32(vmovl_u16(vget_low_u16(p0)));
   int32x4_t p_vec1 = vreinterpretq_s32_u32(vmovl_u16(vget_high_u16(p0)));
   if (use_dist_wtd_comp_avg) {
     p_vec0 = vmulq_n_s32(p_vec0, fwd);
     p_vec1 = vmulq_n_s32(p_vec1, fwd);
     p_vec0 = vmlaq_n_s32(p_vec0, sum0, bwd);
     p_vec1 = vmlaq_n_s32(p_vec1, sum1, bwd);
     p_vec0 = vshrq_n_s32(p_vec0, DIST_PRECISION_BITS);
     p_vec1 = vshrq_n_s32(p_vec1, DIST_PRECISION_BITS);
   } else {
     p_vec0 = vhaddq_s32(p_vec0, sum0);
     p_vec1 = vhaddq_s32(p_vec1, sum1);
   }

   const int offset_bits = bd + 2 * FILTER_BITS - round0;
   const int round1 = COMPOUND_ROUND1_BITS;
   const int res_sub_const =
       (1 << (offset_bits - round1)) + (1 << (offset_bits - round1 - 1));
   const int round_bits = 2 * FILTER_BITS - round0 - round1;

   p_vec0 = vsubq_s32(p_vec0, vdupq_n_s32(res_sub_const));
   p_vec1 = vsubq_s32(p_vec1, vdupq_n_s32(res_sub_const));

   p_vec0 = vrshlq_s32(p_vec0, vdupq_n_s32(-round_bits));
   p_vec1 = vrshlq_s32(p_vec1, vdupq_n_s32(-round_bits));
   uint16x4_t res0 = clip_pixel_highbd_vec(p_vec0, bd);
   uint16x4_t res1 = clip_pixel_highbd_vec(p_vec1, bd);
   vst1_u16(dst16, res0);
   vst1_u16(dst16 + 4, res1);
 }

 static AOM_FORCE_INLINE void warp_affine_vertical(
     uint16_t *pred, int p_width, int p_height, int p_stride, int bd,
     uint16_t *dst, int dst_stride, bool is_compound, bool do_average,
     bool use_dist_wtd_comp_avg, int fwd, int bwd, int16_t gamma, int16_t delta,
     const int16x8_t *tmp, int i, int sy4, int j) {
   int limit_height = p_height > 4 ? 8 : 4;

   if (p_width > 4) {
     // p_width == 8
     for (int k = 0; k < limit_height; ++k) {
       int sy = sy4 + delta * k;
       highbd_vertical_filter_8x1_f8(
           pred, p_stride, bd, dst, dst_stride, is_compound, do_average,
           use_dist_wtd_comp_avg, fwd, bwd, gamma, tmp + k, i + k, sy, j);
     }
   } else {
     // p_width == 4
     for (int k = 0; k < limit_height; ++k) {
       int sy = sy4 + delta * k;
       highbd_vertical_filter_4x1_f4(
           pred, p_stride, bd, dst, dst_stride, is_compound, do_average,
           use_dist_wtd_comp_avg, fwd, bwd, gamma, tmp + k, i + k, sy, j);
     }
   }
 }

 static AOM_FORCE_INLINE void highbd_warp_affine_common(
     const int32_t *mat, const uint16_t *ref, int width, int height, int stride,
     uint16_t *pred, int p_col, int p_row, int p_width, int p_height,
     int p_stride, int subsampling_x, int subsampling_y, int bd,
     ConvolveParams *conv_params, int16_t alpha, int16_t beta, int16_t gamma,
     int16_t delta) {
   uint16_t *const dst = conv_params->dst;
   const int dst_stride = conv_params->dst_stride;
   const bool is_compound = conv_params->is_compound;
   const bool do_average = conv_params->do_average;
   const bool use_dist_wtd_comp_avg = conv_params->use_dist_wtd_comp_avg;
   const int fwd = conv_params->fwd_offset;
   const int bwd = conv_params->bck_offset;

   assert(IMPLIES(is_compound, dst != NULL));

   for (int i = 0; i < p_height; i += 8) {
     for (int j = 0; j < p_width; j += 8) {
       // Calculate the center of this 8x8 block,
       // project to luma coordinates (if in a subsampled chroma plane),
       // apply the affine transformation,
       // then convert back to the original coordinates (if necessary)
       const int32_t src_x = (j + 4 + p_col) << subsampling_x;
       const int32_t src_y = (i + 4 + p_row) << subsampling_y;
       const int64_t dst_x =
           (int64_t)mat[2] * src_x + (int64_t)mat[3] * src_y + (int64_t)mat[0];
       const int64_t dst_y =
           (int64_t)mat[4] * src_x + (int64_t)mat[5] * src_y + (int64_t)mat[1];
       const int64_t x4 = dst_x >> subsampling_x;
       const int64_t y4 = dst_y >> subsampling_y;

       const int32_t ix4 = (int32_t)(x4 >> WARPEDMODEL_PREC_BITS);
       int32_t sx4 = x4 & ((1 << WARPEDMODEL_PREC_BITS) - 1);
       const int32_t iy4 = (int32_t)(y4 >> WARPEDMODEL_PREC_BITS);
       int32_t sy4 = y4 & ((1 << WARPEDMODEL_PREC_BITS) - 1);

       sx4 += alpha * (-4) + beta * (-4);
       sy4 += gamma * (-4) + delta * (-4);

       sx4 &= ~((1 << WARP_PARAM_REDUCE_BITS) - 1);
       sy4 &= ~((1 << WARP_PARAM_REDUCE_BITS) - 1);

       // Each horizontal filter result is formed by the sum of up to eight
       // multiplications by filter values and then a shift. Although both the
       // inputs and filters are loaded as int16, the input data is at most bd
       // bits and the filters are at most 8 bits each. Additionally since we
       // know all possible filter values we know that the sum of absolute
       // filter values will fit in at most 9 bits. With this in mind we can
       // conclude that the sum of each filter application will fit in bd + 9
       // bits. The shift following the summation is ROUND0_BITS (which is 3),
       // +2 for 12-bit, which gives us a final storage of:
       // bd ==  8: ( 8 + 9) - 3 => 14 bits
       // bd == 10: (10 + 9) - 3 => 16 bits
       // bd == 12: (12 + 9) - 5 => 16 bits
       // So it is safe to use int16x8_t as the intermediate storage type here.
       int16x8_t tmp[15];

       warp_affine_horizontal(ref, width, height, stride, p_width, alpha, beta,
                              iy4, sx4, ix4, tmp, bd);
       warp_affine_vertical(pred, p_width, p_height, p_stride, bd, dst,
                            dst_stride, is_compound, do_average,
                            use_dist_wtd_comp_avg, fwd, bwd, gamma, delta, tmp,
                            i, sy4, j);
     }
   }
 }

 #endif  // AOM_AV1_COMMON_ARM_HIGHBD_WARP_PLANE_NEON_H_
	/*
	* Copyright (c) 2023, 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.
	*/
	#ifndef AOM_AV1_COMMON_ARM_HIGHBD_WARP_PLANE_NEON_H_
	#define AOM_AV1_COMMON_ARM_HIGHBD_WARP_PLANE_NEON_H_

	#include <arm_neon.h>
	#include <assert.h>
	#include <stdbool.h>

	#include "aom_dsp/aom_dsp_common.h"
	#include "aom_dsp/arm/mem_neon.h"
	#include "aom_dsp/arm/sum_neon.h"
	#include "aom_ports/mem.h"
	#include "av1/common/scale.h"
	#include "av1/common/warped_motion.h"
	#include "config/av1_rtcd.h"

	static AOM_FORCE_INLINE int16x8_t
	highbd_horizontal_filter_4x1_f4(uint16x8x2_t in, int bd, int sx, int alpha);

	static AOM_FORCE_INLINE int16x8_t
	highbd_horizontal_filter_8x1_f8(uint16x8x2_t in, int bd, int sx, int alpha);

	static AOM_FORCE_INLINE int16x8_t
	highbd_horizontal_filter_4x1_f1(uint16x8x2_t in, int bd, int sx);

	static AOM_FORCE_INLINE int16x8_t
	highbd_horizontal_filter_8x1_f1(uint16x8x2_t in, int bd, int sx);

	static AOM_FORCE_INLINE int32x4_t vertical_filter_4x1_f1(const int16x8_t *tmp,
	int sy);

	static AOM_FORCE_INLINE int32x4x2_t vertical_filter_8x1_f1(const int16x8_t *tmp,
	int sy);

	static AOM_FORCE_INLINE int32x4_t vertical_filter_4x1_f4(const int16x8_t *tmp,
	int sy, int gamma);

	static AOM_FORCE_INLINE int32x4x2_t vertical_filter_8x1_f8(const int16x8_t *tmp,
	int sy, int gamma);

	static AOM_FORCE_INLINE int16x8_t load_filters_1(int ofs) {
	const int ofs0 = ROUND_POWER_OF_TWO(ofs, WARPEDDIFF_PREC_BITS);

	const int16_t *base =
	(int16_t )av1_warped_filter + WARPEDPIXEL_PREC_SHIFTS 8;
	return vld1q_s16(base + ofs0 * 8);
	}

	static AOM_FORCE_INLINE void load_filters_4(int16x8_t out[], int ofs,
	int stride) {
	const int ofs0 = ROUND_POWER_OF_TWO(ofs + stride * 0, WARPEDDIFF_PREC_BITS);
	const int ofs1 = ROUND_POWER_OF_TWO(ofs + stride * 1, WARPEDDIFF_PREC_BITS);
	const int ofs2 = ROUND_POWER_OF_TWO(ofs + stride * 2, WARPEDDIFF_PREC_BITS);
	const int ofs3 = ROUND_POWER_OF_TWO(ofs + stride * 3, WARPEDDIFF_PREC_BITS);

	const int16_t *base =
	(int16_t )av1_warped_filter + WARPEDPIXEL_PREC_SHIFTS 8;
	out[0] = vld1q_s16(base + ofs0 * 8);
	out[1] = vld1q_s16(base + ofs1 * 8);
	out[2] = vld1q_s16(base + ofs2 * 8);
	out[3] = vld1q_s16(base + ofs3 * 8);
	}

	static AOM_FORCE_INLINE void load_filters_8(int16x8_t out[], int ofs,
	int stride) {
	const int ofs0 = ROUND_POWER_OF_TWO(ofs + stride * 0, WARPEDDIFF_PREC_BITS);
	const int ofs1 = ROUND_POWER_OF_TWO(ofs + stride * 1, WARPEDDIFF_PREC_BITS);
	const int ofs2 = ROUND_POWER_OF_TWO(ofs + stride * 2, WARPEDDIFF_PREC_BITS);
	const int ofs3 = ROUND_POWER_OF_TWO(ofs + stride * 3, WARPEDDIFF_PREC_BITS);
	const int ofs4 = ROUND_POWER_OF_TWO(ofs + stride * 4, WARPEDDIFF_PREC_BITS);
	const int ofs5 = ROUND_POWER_OF_TWO(ofs + stride * 5, WARPEDDIFF_PREC_BITS);
	const int ofs6 = ROUND_POWER_OF_TWO(ofs + stride * 6, WARPEDDIFF_PREC_BITS);
	const int ofs7 = ROUND_POWER_OF_TWO(ofs + stride * 7, WARPEDDIFF_PREC_BITS);

	const int16_t *base =
	(int16_t )av1_warped_filter + WARPEDPIXEL_PREC_SHIFTS 8;
	out[0] = vld1q_s16(base + ofs0 * 8);
	out[1] = vld1q_s16(base + ofs1 * 8);
	out[2] = vld1q_s16(base + ofs2 * 8);
	out[3] = vld1q_s16(base + ofs3 * 8);
	out[4] = vld1q_s16(base + ofs4 * 8);
	out[5] = vld1q_s16(base + ofs5 * 8);
	out[6] = vld1q_s16(base + ofs6 * 8);
	out[7] = vld1q_s16(base + ofs7 * 8);
	}

	static AOM_FORCE_INLINE uint16x4_t clip_pixel_highbd_vec(int32x4_t val,
	int bd) {
	const int limit = (1 << bd) - 1;
	return vqmovun_s32(vminq_s32(val, vdupq_n_s32(limit)));
	}

	static AOM_FORCE_INLINE void warp_affine_horizontal(const uint16_t *ref,
	int width, int height,
	int stride, int p_width,
	int16_t alpha, int16_t beta,
	int iy4, int sx4, int ix4,
	int16x8_t tmp[], int bd) {
	const int round0 = (bd == 12) ? ROUND0_BITS + 2 : ROUND0_BITS;

	if (ix4 <= -7) {
	for (int k = 0; k < 15; ++k) {
	int iy = clamp(iy4 + k - 7, 0, height - 1);
	int32_t dup_val = (1 << (bd + FILTER_BITS - round0 - 1)) +
	ref[iy * stride] * (1 << (FILTER_BITS - round0));
	tmp[k] = vdupq_n_s16(dup_val);
	}
	return;
	} else if (ix4 >= width + 6) {
	for (int k = 0; k < 15; ++k) {
	int iy = clamp(iy4 + k - 7, 0, height - 1);
	int32_t dup_val =
	(1 << (bd + FILTER_BITS - round0 - 1)) +
	ref[iy * stride + (width - 1)] * (1 << (FILTER_BITS - round0));
	tmp[k] = vdupq_n_s16(dup_val);
	}
	return;
	}

	static const uint16_t kIotaArr[] = { 0, 1, 2, 3, 4, 5, 6, 7,
	8, 9, 10, 11, 12, 13, 14, 15 };
	const uint16x8_t indx0 = vld1q_u16(kIotaArr);
	const uint16x8_t indx1 = vld1q_u16(kIotaArr + 8);

	const int out_of_boundary_left = -(ix4 - 6);
	const int out_of_boundary_right = (ix4 + 8) - width;

	#define APPLY_HORIZONTAL_SHIFT(fn, ...) \
	do { \
	if (out_of_boundary_left >= 0 \|\| out_of_boundary_right >= 0) { \
	for (int k = 0; k < 15; ++k) { \
	const int iy = clamp(iy4 + k - 7, 0, height - 1); \
	uint16x8x2_t src_1 = vld1q_u16_x2(ref + iy * stride + ix4 - 7); \
	\
	if (out_of_boundary_left >= 0) { \
	uint16x8_t cmp_vec = vdupq_n_u16(out_of_boundary_left); \
	uint16x8_t vec_dup = vdupq_n_u16(ref[iy * stride]); \
	uint16x8_t mask0 = vcleq_u16(indx0, cmp_vec); \
	uint16x8_t mask1 = vcleq_u16(indx1, cmp_vec); \
	src_1.val[0] = vbslq_u16(mask0, vec_dup, src_1.val[0]); \
	src_1.val[1] = vbslq_u16(mask1, vec_dup, src_1.val[1]); \
	} \
	if (out_of_boundary_right >= 0) { \
	uint16x8_t cmp_vec = vdupq_n_u16(15 - out_of_boundary_right); \
	uint16x8_t vec_dup = vdupq_n_u16(ref[iy * stride + width - 1]); \
	uint16x8_t mask0 = vcgeq_u16(indx0, cmp_vec); \
	uint16x8_t mask1 = vcgeq_u16(indx1, cmp_vec); \
	src_1.val[0] = vbslq_u16(mask0, vec_dup, src_1.val[0]); \
	src_1.val[1] = vbslq_u16(mask1, vec_dup, src_1.val[1]); \
	} \
	tmp[k] = (fn)(src_1, __VA_ARGS__); \
	} \
	} else { \
	for (int k = 0; k < 15; ++k) { \
	const int iy = clamp(iy4 + k - 7, 0, height - 1); \
	uint16x8x2_t src_1 = vld1q_u16_x2(ref + iy * stride + ix4 - 7); \
	tmp[k] = (fn)(src_1, __VA_ARGS__); \
	} \
	} \
	} while (0)

	if (p_width == 4) {
	if (beta == 0) {
	if (alpha == 0) {
	APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_4x1_f1, bd, sx4);
	} else {
	APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_4x1_f4, bd, sx4, alpha);
	}
	} else {
	if (alpha == 0) {
	APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_4x1_f1, bd,
	(sx4 + beta * (k - 3)));
	} else {
	APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_4x1_f4, bd,
	(sx4 + beta * (k - 3)), alpha);
	}
	}
	} else {
	if (beta == 0) {
	if (alpha == 0) {
	APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_8x1_f1, bd, sx4);
	} else {
	APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_8x1_f8, bd, sx4, alpha);
	}
	} else {
	if (alpha == 0) {
	APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_8x1_f1, bd,
	(sx4 + beta * (k - 3)));
	} else {
	APPLY_HORIZONTAL_SHIFT(highbd_horizontal_filter_8x1_f8, bd,
	(sx4 + beta * (k - 3)), alpha);
	}
	}
	}
	}

	static AOM_FORCE_INLINE void highbd_vertical_filter_4x1_f4(
	uint16_t pred, int p_stride, int bd, uint16_t dst, int dst_stride,
	bool is_compound, bool do_average, bool use_dist_wtd_comp_avg, int fwd,
	int bwd, int16_t gamma, const int16x8_t *tmp, int i, int sy, int j) {
	int32x4_t sum0 = gamma == 0 ? vertical_filter_4x1_f1(tmp, sy)
	: vertical_filter_4x1_f4(tmp, sy, gamma);

	const int round0 = (bd == 12) ? ROUND0_BITS + 2 : ROUND0_BITS;
	const int offset_bits_vert = bd + 2 * FILTER_BITS - round0;

	sum0 = vaddq_s32(sum0, vdupq_n_s32(1 << offset_bits_vert));

	uint16_t dst16 = &pred[i p_stride + j];

	if (!is_compound) {
	const int reduce_bits_vert = 2 * FILTER_BITS - round0;
	sum0 = vrshlq_s32(sum0, vdupq_n_s32(-reduce_bits_vert));

	const int res_sub_const = (1 << (bd - 1)) + (1 << bd);
	sum0 = vsubq_s32(sum0, vdupq_n_s32(res_sub_const));
	uint16x4_t res0 = clip_pixel_highbd_vec(sum0, bd);
	vst1_u16(dst16, res0);
	return;
	}

	sum0 = vrshrq_n_s32(sum0, COMPOUND_ROUND1_BITS);

	uint16_t p = &dst[i dst_stride + j];

	if (!do_average) {
	vst1_u16(p, vqmovun_s32(sum0));
	return;
	}

	uint16x4_t p0 = vld1_u16(p);
	int32x4_t p_vec0 = vreinterpretq_s32_u32(vmovl_u16(p0));
	if (use_dist_wtd_comp_avg) {
	p_vec0 = vmulq_n_s32(p_vec0, fwd);
	p_vec0 = vmlaq_n_s32(p_vec0, sum0, bwd);
	p_vec0 = vshrq_n_s32(p_vec0, DIST_PRECISION_BITS);
	} else {
	p_vec0 = vhaddq_s32(p_vec0, sum0);
	}

	const int offset_bits = bd + 2 * FILTER_BITS - round0;
	const int round1 = COMPOUND_ROUND1_BITS;
	const int res_sub_const =
	(1 << (offset_bits - round1)) + (1 << (offset_bits - round1 - 1));
	const int round_bits = 2 * FILTER_BITS - round0 - round1;

	p_vec0 = vsubq_s32(p_vec0, vdupq_n_s32(res_sub_const));
	p_vec0 = vrshlq_s32(p_vec0, vdupq_n_s32(-round_bits));
	uint16x4_t res0 = clip_pixel_highbd_vec(p_vec0, bd);
	vst1_u16(dst16, res0);
	}

	static AOM_FORCE_INLINE void highbd_vertical_filter_8x1_f8(
	uint16_t pred, int p_stride, int bd, uint16_t dst, int dst_stride,
	bool is_compound, bool do_average, bool use_dist_wtd_comp_avg, int fwd,
	int bwd, int16_t gamma, const int16x8_t *tmp, int i, int sy, int j) {
	int32x4x2_t sums = gamma == 0 ? vertical_filter_8x1_f1(tmp, sy)
	: vertical_filter_8x1_f8(tmp, sy, gamma);
	int32x4_t sum0 = sums.val[0];
	int32x4_t sum1 = sums.val[1];

	const int round0 = (bd == 12) ? ROUND0_BITS + 2 : ROUND0_BITS;
	const int offset_bits_vert = bd + 2 * FILTER_BITS - round0;

	sum0 = vaddq_s32(sum0, vdupq_n_s32(1 << offset_bits_vert));
	sum1 = vaddq_s32(sum1, vdupq_n_s32(1 << offset_bits_vert));

	uint16_t dst16 = &pred[i p_stride + j];

	if (!is_compound) {
	const int reduce_bits_vert = 2 * FILTER_BITS - round0;
	sum0 = vrshlq_s32(sum0, vdupq_n_s32(-reduce_bits_vert));
	sum1 = vrshlq_s32(sum1, vdupq_n_s32(-reduce_bits_vert));

	const int res_sub_const = (1 << (bd - 1)) + (1 << bd);
	sum0 = vsubq_s32(sum0, vdupq_n_s32(res_sub_const));
	sum1 = vsubq_s32(sum1, vdupq_n_s32(res_sub_const));
	uint16x4_t res0 = clip_pixel_highbd_vec(sum0, bd);
	uint16x4_t res1 = clip_pixel_highbd_vec(sum1, bd);
	vst1_u16(dst16, res0);
	vst1_u16(dst16 + 4, res1);
	return;
	}

	sum0 = vrshrq_n_s32(sum0, COMPOUND_ROUND1_BITS);
	sum1 = vrshrq_n_s32(sum1, COMPOUND_ROUND1_BITS);

	uint16_t p = &dst[i dst_stride + j];

	if (!do_average) {
	vst1_u16(p, vqmovun_s32(sum0));
	vst1_u16(p + 4, vqmovun_s32(sum1));
	return;
	}

	uint16x8_t p0 = vld1q_u16(p);
	int32x4_t p_vec0 = vreinterpretq_s32_u32(vmovl_u16(vget_low_u16(p0)));
	int32x4_t p_vec1 = vreinterpretq_s32_u32(vmovl_u16(vget_high_u16(p0)));
	if (use_dist_wtd_comp_avg) {
	p_vec0 = vmulq_n_s32(p_vec0, fwd);
	p_vec1 = vmulq_n_s32(p_vec1, fwd);
	p_vec0 = vmlaq_n_s32(p_vec0, sum0, bwd);
	p_vec1 = vmlaq_n_s32(p_vec1, sum1, bwd);
	p_vec0 = vshrq_n_s32(p_vec0, DIST_PRECISION_BITS);
	p_vec1 = vshrq_n_s32(p_vec1, DIST_PRECISION_BITS);
	} else {
	p_vec0 = vhaddq_s32(p_vec0, sum0);
	p_vec1 = vhaddq_s32(p_vec1, sum1);
	}

	const int offset_bits = bd + 2 * FILTER_BITS - round0;
	const int round1 = COMPOUND_ROUND1_BITS;
	const int res_sub_const =
	(1 << (offset_bits - round1)) + (1 << (offset_bits - round1 - 1));
	const int round_bits = 2 * FILTER_BITS - round0 - round1;

	p_vec0 = vsubq_s32(p_vec0, vdupq_n_s32(res_sub_const));
	p_vec1 = vsubq_s32(p_vec1, vdupq_n_s32(res_sub_const));

	p_vec0 = vrshlq_s32(p_vec0, vdupq_n_s32(-round_bits));
	p_vec1 = vrshlq_s32(p_vec1, vdupq_n_s32(-round_bits));
	uint16x4_t res0 = clip_pixel_highbd_vec(p_vec0, bd);
	uint16x4_t res1 = clip_pixel_highbd_vec(p_vec1, bd);
	vst1_u16(dst16, res0);
	vst1_u16(dst16 + 4, res1);
	}

	static AOM_FORCE_INLINE void warp_affine_vertical(
	uint16_t *pred, int p_width, int p_height, int p_stride, int bd,
	uint16_t *dst, int dst_stride, bool is_compound, bool do_average,
	bool use_dist_wtd_comp_avg, int fwd, int bwd, int16_t gamma, int16_t delta,
	const int16x8_t *tmp, int i, int sy4, int j) {
	int limit_height = p_height > 4 ? 8 : 4;

	if (p_width > 4) {
	// p_width == 8
	for (int k = 0; k < limit_height; ++k) {
	int sy = sy4 + delta * k;
	highbd_vertical_filter_8x1_f8(
	pred, p_stride, bd, dst, dst_stride, is_compound, do_average,
	use_dist_wtd_comp_avg, fwd, bwd, gamma, tmp + k, i + k, sy, j);
	}
	} else {
	// p_width == 4
	for (int k = 0; k < limit_height; ++k) {
	int sy = sy4 + delta * k;
	highbd_vertical_filter_4x1_f4(
	pred, p_stride, bd, dst, dst_stride, is_compound, do_average,
	use_dist_wtd_comp_avg, fwd, bwd, gamma, tmp + k, i + k, sy, j);
	}
	}
	}

	static AOM_FORCE_INLINE void highbd_warp_affine_common(
	const int32_t mat, const uint16_t ref, int width, int height, int stride,
	uint16_t *pred, int p_col, int p_row, int p_width, int p_height,
	int p_stride, int subsampling_x, int subsampling_y, int bd,
	ConvolveParams *conv_params, int16_t alpha, int16_t beta, int16_t gamma,
	int16_t delta) {
	uint16_t *const dst = conv_params->dst;
	const int dst_stride = conv_params->dst_stride;
	const bool is_compound = conv_params->is_compound;
	const bool do_average = conv_params->do_average;
	const bool use_dist_wtd_comp_avg = conv_params->use_dist_wtd_comp_avg;
	const int fwd = conv_params->fwd_offset;
	const int bwd = conv_params->bck_offset;

	assert(IMPLIES(is_compound, dst != NULL));

	for (int i = 0; i < p_height; i += 8) {
	for (int j = 0; j < p_width; j += 8) {
	// Calculate the center of this 8x8 block,
	// project to luma coordinates (if in a subsampled chroma plane),
	// apply the affine transformation,
	// then convert back to the original coordinates (if necessary)
	const int32_t src_x = (j + 4 + p_col) << subsampling_x;
	const int32_t src_y = (i + 4 + p_row) << subsampling_y;
	const int64_t dst_x =
	(int64_t)mat[2] * src_x + (int64_t)mat[3] * src_y + (int64_t)mat[0];
	const int64_t dst_y =
	(int64_t)mat[4] * src_x + (int64_t)mat[5] * src_y + (int64_t)mat[1];
	const int64_t x4 = dst_x >> subsampling_x;
	const int64_t y4 = dst_y >> subsampling_y;

	const int32_t ix4 = (int32_t)(x4 >> WARPEDMODEL_PREC_BITS);
	int32_t sx4 = x4 & ((1 << WARPEDMODEL_PREC_BITS) - 1);
	const int32_t iy4 = (int32_t)(y4 >> WARPEDMODEL_PREC_BITS);
	int32_t sy4 = y4 & ((1 << WARPEDMODEL_PREC_BITS) - 1);

	sx4 += alpha * (-4) + beta * (-4);
	sy4 += gamma * (-4) + delta * (-4);

	sx4 &= ~((1 << WARP_PARAM_REDUCE_BITS) - 1);
	sy4 &= ~((1 << WARP_PARAM_REDUCE_BITS) - 1);

	// Each horizontal filter result is formed by the sum of up to eight
	// multiplications by filter values and then a shift. Although both the
	// inputs and filters are loaded as int16, the input data is at most bd
	// bits and the filters are at most 8 bits each. Additionally since we
	// know all possible filter values we know that the sum of absolute
	// filter values will fit in at most 9 bits. With this in mind we can
	// conclude that the sum of each filter application will fit in bd + 9
	// bits. The shift following the summation is ROUND0_BITS (which is 3),
	// +2 for 12-bit, which gives us a final storage of:
	// bd == 8: ( 8 + 9) - 3 => 14 bits
	// bd == 10: (10 + 9) - 3 => 16 bits
	// bd == 12: (12 + 9) - 5 => 16 bits
	// So it is safe to use int16x8_t as the intermediate storage type here.
	int16x8_t tmp[15];

	warp_affine_horizontal(ref, width, height, stride, p_width, alpha, beta,
	iy4, sx4, ix4, tmp, bd);
	warp_affine_vertical(pred, p_width, p_height, p_stride, bd, dst,
	dst_stride, is_compound, do_average,
	use_dist_wtd_comp_avg, fwd, bwd, gamma, delta, tmp,
	i, sy4, j);
	}
	}
	}

	#endif // AOM_AV1_COMMON_ARM_HIGHBD_WARP_PLANE_NEON_H_