av1/encoder/arm/temporal_filter_neon.c - aom - Git at Google

 /*
  * Copyright (c) 2022, 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 <arm_neon.h>

 #include "config/aom_config.h"
 #include "config/av1_rtcd.h"
 #include "av1/encoder/encoder.h"
 #include "av1/encoder/temporal_filter.h"
 #include "aom_dsp/mathutils.h"
 #include "aom_dsp/arm/mem_neon.h"
 #include "aom_dsp/arm/sum_neon.h"

 // For the squared error buffer, add padding for 4 samples.
 #define SSE_STRIDE (BW + 4)

 // When using vld1q_u16_x4 compilers may insert an alignment hint of 256 bits.
 DECLARE_ALIGNED(32, static const uint16_t, kSlidingWindowMask[]) = {
   0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0x0000, 0x0000, 0x0000,
   0x0000, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0x0000, 0x0000,
   0x0000, 0x0000, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0x0000,
   0x0000, 0x0000, 0x0000, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF
 };

 static INLINE void get_squared_error(
     const uint8_t *frame1, const uint32_t stride1, const uint8_t *frame2,
     const uint32_t stride2, const uint32_t block_width,
     const uint32_t block_height, uint16_t *frame_sse,
     const unsigned int dst_stride) {
   uint16_t *dst = frame_sse;

   uint32_t i = 0;
   do {
     uint32_t j = 0;
     do {
       uint8x16_t s = vld1q_u8(frame1 + i * stride1 + j);
       uint8x16_t r = vld1q_u8(frame2 + i * stride2 + j);

       uint8x16_t abs_diff = vabdq_u8(s, r);
       uint16x8_t sse_lo =
           vmull_u8(vget_low_u8(abs_diff), vget_low_u8(abs_diff));
       uint16x8_t sse_hi =
           vmull_u8(vget_high_u8(abs_diff), vget_high_u8(abs_diff));

       vst1q_u16(dst + j + 2, sse_lo);
       vst1q_u16(dst + j + 10, sse_hi);

       j += 16;
     } while (j < block_width);

     dst += dst_stride;
   } while (++i < block_height);
 }

 static INLINE uint16x8_t load_and_pad(const uint16_t *src, const uint32_t col,
                                       const uint32_t block_width) {
   uint16x8_t s = vld1q_u16(src);

   if (col == 0) {
     const uint16_t lane2 = vgetq_lane_u16(s, 2);
     s = vsetq_lane_u16(lane2, s, 0);
     s = vsetq_lane_u16(lane2, s, 1);
   } else if (col >= block_width - 4) {
     const uint16_t lane5 = vgetq_lane_u16(s, 5);
     s = vsetq_lane_u16(lane5, s, 6);
     s = vsetq_lane_u16(lane5, s, 7);
   }
   return s;
 }

 static void apply_temporal_filter(
     const uint8_t *frame, const unsigned int stride, const uint32_t block_width,
     const uint32_t block_height, const int *subblock_mses,
     unsigned int *accumulator, uint16_t *count, const uint16_t *frame_sse,
     const uint32_t *luma_sse_sum, const double inv_num_ref_pixels,
     const double decay_factor, const double inv_factor,
     const double weight_factor, const double *d_factor, int tf_wgt_calc_lvl) {
   assert(((block_width == 16) || (block_width == 32)) &&
          ((block_height == 16) || (block_height == 32)));

   uint32_t acc_5x5_neon[BH][BW];
   const uint16x8x4_t vmask = vld1q_u16_x4(kSlidingWindowMask);

   // Traverse 4 columns at a time - first and last two columns need padding.
   for (uint32_t col = 0; col < block_width; col += 4) {
     uint16x8_t vsrc[5];
     const uint16_t *src = frame_sse + col;

     // Load and pad (for first and last two columns) 3 rows from the top.
     for (int i = 2; i < 5; i++) {
       vsrc[i] = load_and_pad(src, col, block_width);
       src += SSE_STRIDE;
     }

     // Pad the top 2 rows.
     vsrc[0] = vsrc[2];
     vsrc[1] = vsrc[2];

     for (unsigned int row = 0; row < block_height; row++) {
       for (int i = 0; i < 4; i++) {
         uint32x4_t vsum = vdupq_n_u32(0);
         for (int j = 0; j < 5; j++) {
           vsum = vpadalq_u16(vsum, vandq_u16(vsrc[j], vmask.val[i]));
         }
         acc_5x5_neon[row][col + i] = horizontal_add_u32x4(vsum);
       }

       // Push all rows in the sliding window up one.
       for (int i = 0; i < 4; i++) {
         vsrc[i] = vsrc[i + 1];
       }

       if (row <= block_height - 4) {
         // Load next row into the bottom of the sliding window.
         vsrc[4] = load_and_pad(src, col, block_width);
         src += SSE_STRIDE;
       } else {
         // Pad the bottom 2 rows.
         vsrc[4] = vsrc[3];
       }
     }
   }

   // Perform filtering.
   if (tf_wgt_calc_lvl == 0) {
     for (unsigned int i = 0, k = 0; i < block_height; i++) {
       for (unsigned int j = 0; j < block_width; j++, k++) {
         const int pixel_value = frame[i * stride + j];
         const uint32_t diff_sse = acc_5x5_neon[i][j] + luma_sse_sum[i * BW + j];

         const double window_error = diff_sse * inv_num_ref_pixels;
         const int subblock_idx =
             (i >= block_height / 2) * 2 + (j >= block_width / 2);
         const double block_error = (double)subblock_mses[subblock_idx];
         const double combined_error =
             weight_factor * window_error + block_error * inv_factor;
         // Compute filter weight.
         double scaled_error =
             combined_error * d_factor[subblock_idx] * decay_factor;
         scaled_error = AOMMIN(scaled_error, 7);
         const int weight = (int)(exp(-scaled_error) * TF_WEIGHT_SCALE);
         accumulator[k] += weight * pixel_value;
         count[k] += weight;
       }
     }
   } else {
     for (unsigned int i = 0, k = 0; i < block_height; i++) {
       for (unsigned int j = 0; j < block_width; j++, k++) {
         const int pixel_value = frame[i * stride + j];
         const uint32_t diff_sse = acc_5x5_neon[i][j] + luma_sse_sum[i * BW + j];

         const double window_error = diff_sse * inv_num_ref_pixels;
         const int subblock_idx =
             (i >= block_height / 2) * 2 + (j >= block_width / 2);
         const double block_error = (double)subblock_mses[subblock_idx];
         const double combined_error =
             weight_factor * window_error + block_error * inv_factor;
         // Compute filter weight.
         double scaled_error =
             combined_error * d_factor[subblock_idx] * decay_factor;
         scaled_error = AOMMIN(scaled_error, 7);
         const float fweight =
             approx_exp((float)-scaled_error) * TF_WEIGHT_SCALE;
         const int weight = iroundpf(fweight);
         accumulator[k] += weight * pixel_value;
         count[k] += weight;
       }
     }
   }
 }

 void av1_apply_temporal_filter_neon(
     const YV12_BUFFER_CONFIG *frame_to_filter, const MACROBLOCKD *mbd,
     const BLOCK_SIZE block_size, const int mb_row, const int mb_col,
     const int num_planes, const double *noise_levels, const MV *subblock_mvs,
     const int *subblock_mses, const int q_factor, const int filter_strength,
     int tf_wgt_calc_lvl, const uint8_t *pred, uint32_t *accum,
     uint16_t *count) {
   const int is_high_bitdepth = frame_to_filter->flags & YV12_FLAG_HIGHBITDEPTH;
   assert(block_size == BLOCK_32X32 && "Only support 32x32 block with Neon!");
   assert(TF_WINDOW_LENGTH == 5 && "Only support window length 5 with Neon!");
   assert(!is_high_bitdepth && "Only support low bit-depth with Neon!");
   assert(num_planes >= 1 && num_planes <= MAX_MB_PLANE);
   (void)is_high_bitdepth;

   // Block information.
   const int mb_height = block_size_high[block_size];
   const int mb_width = block_size_wide[block_size];
   // Frame information.
   const int frame_height = frame_to_filter->y_crop_height;
   const int frame_width = frame_to_filter->y_crop_width;
   const int min_frame_size = AOMMIN(frame_height, frame_width);
   // Variables to simplify combined error calculation.
   const double inv_factor = 1.0 / ((TF_WINDOW_BLOCK_BALANCE_WEIGHT + 1) *
                                    TF_SEARCH_ERROR_NORM_WEIGHT);
   const double weight_factor =
       (double)TF_WINDOW_BLOCK_BALANCE_WEIGHT * inv_factor;
   // Adjust filtering based on q.
   // Larger q -> stronger filtering -> larger weight.
   // Smaller q -> weaker filtering -> smaller weight.
   double q_decay = pow((double)q_factor / TF_Q_DECAY_THRESHOLD, 2);
   q_decay = CLIP(q_decay, 1e-5, 1);
   if (q_factor >= TF_QINDEX_CUTOFF) {
     // Max q_factor is 255, therefore the upper bound of q_decay is 8.
     // We do not need a clip here.
     q_decay = 0.5 * pow((double)q_factor / 64, 2);
   }
   // Smaller strength -> smaller filtering weight.
   double s_decay = pow((double)filter_strength / TF_STRENGTH_THRESHOLD, 2);
   s_decay = CLIP(s_decay, 1e-5, 1);
   double d_factor[4] = { 0 };
   uint16_t frame_sse[SSE_STRIDE * BH] = { 0 };
   uint32_t luma_sse_sum[BW * BH] = { 0 };

   for (int subblock_idx = 0; subblock_idx < 4; subblock_idx++) {
     // Larger motion vector -> smaller filtering weight.
     const MV mv = subblock_mvs[subblock_idx];
     const double distance = sqrt(pow(mv.row, 2) + pow(mv.col, 2));
     double distance_threshold = min_frame_size * TF_SEARCH_DISTANCE_THRESHOLD;
     distance_threshold = AOMMAX(distance_threshold, 1);
     d_factor[subblock_idx] = distance / distance_threshold;
     d_factor[subblock_idx] = AOMMAX(d_factor[subblock_idx], 1);
   }

   // Handle planes in sequence.
   int plane_offset = 0;
   for (int plane = 0; plane < num_planes; ++plane) {
     const uint32_t plane_h = mb_height >> mbd->plane[plane].subsampling_y;
     const uint32_t plane_w = mb_width >> mbd->plane[plane].subsampling_x;
     const uint32_t frame_stride =
         frame_to_filter->strides[plane == AOM_PLANE_Y ? 0 : 1];
     const int frame_offset = mb_row * plane_h * frame_stride + mb_col * plane_w;

     const uint8_t *ref = frame_to_filter->buffers[plane] + frame_offset;
     const int ss_x_shift =
         mbd->plane[plane].subsampling_x - mbd->plane[AOM_PLANE_Y].subsampling_x;
     const int ss_y_shift =
         mbd->plane[plane].subsampling_y - mbd->plane[AOM_PLANE_Y].subsampling_y;
     const int num_ref_pixels = TF_WINDOW_LENGTH * TF_WINDOW_LENGTH +
                                ((plane) ? (1 << (ss_x_shift + ss_y_shift)) : 0);
     const double inv_num_ref_pixels = 1.0 / num_ref_pixels;
     // Larger noise -> larger filtering weight.
     const double n_decay = 0.5 + log(2 * noise_levels[plane] + 5.0);
     // Decay factors for non-local mean approach.
     const double decay_factor = 1 / (n_decay * q_decay * s_decay);

     // Filter U-plane and V-plane using Y-plane. This is because motion
     // search is only done on Y-plane, so the information from Y-plane
     // will be more accurate. The luma sse sum is reused in both chroma
     // planes.
     if (plane == AOM_PLANE_U) {
       for (unsigned int i = 0; i < plane_h; i++) {
         for (unsigned int j = 0; j < plane_w; j++) {
           for (int ii = 0; ii < (1 << ss_y_shift); ++ii) {
             for (int jj = 0; jj < (1 << ss_x_shift); ++jj) {
               const int yy = (i << ss_y_shift) + ii;  // Y-coord on Y-plane.
               const int xx = (j << ss_x_shift) + jj;  // X-coord on Y-plane.
               luma_sse_sum[i * BW + j] += frame_sse[yy * SSE_STRIDE + xx + 2];
             }
           }
         }
       }
     }

     get_squared_error(ref, frame_stride, pred + plane_offset, plane_w, plane_w,
                       plane_h, frame_sse, SSE_STRIDE);

     apply_temporal_filter(pred + plane_offset, plane_w, plane_w, plane_h,
                           subblock_mses, accum + plane_offset,
                           count + plane_offset, frame_sse, luma_sse_sum,
                           inv_num_ref_pixels, decay_factor, inv_factor,
                           weight_factor, d_factor, tf_wgt_calc_lvl);

     plane_offset += plane_h * plane_w;
   }
 }

 double av1_estimate_noise_from_single_plane_neon(const uint8_t *src, int height,
                                                  int width, int stride,
                                                  int edge_thresh) {
   uint16x8_t thresh = vdupq_n_u16(edge_thresh);
   uint32x4_t acc = vdupq_n_u32(0);
   // Count is in theory positive as it counts the number of times we're under
   // the threshold, but it will be counted negatively in order to make best use
   // of the vclt instruction, which sets every bit of a lane to 1 when the
   // condition is true.
   int32x4_t count = vdupq_n_s32(0);
   int final_count = 0;
   int64_t final_acc = 0;
   const uint8_t *src_start = src + stride + 1;
   int h = 1;

   do {
     int w = 1;
     const uint8_t *src_ptr = src_start;

     while (w <= (width - 1) - 16) {
       uint8x16_t mat[3][3];
       mat[0][0] = vld1q_u8(src_ptr - stride - 1);
       mat[0][1] = vld1q_u8(src_ptr - stride);
       mat[0][2] = vld1q_u8(src_ptr - stride + 1);
       mat[1][0] = vld1q_u8(src_ptr - 1);
       mat[1][1] = vld1q_u8(src_ptr);
       mat[1][2] = vld1q_u8(src_ptr + 1);
       mat[2][0] = vld1q_u8(src_ptr + stride - 1);
       mat[2][1] = vld1q_u8(src_ptr + stride);
       mat[2][2] = vld1q_u8(src_ptr + stride + 1);

       // Compute Sobel gradients.
       uint16x8_t gxa_lo =
           vaddl_u8(vget_low_u8(mat[0][0]), vget_low_u8(mat[2][0]));
       uint16x8_t gxa_hi =
           vaddl_u8(vget_high_u8(mat[0][0]), vget_high_u8(mat[2][0]));
       uint16x8_t gxb_lo =
           vaddl_u8(vget_low_u8(mat[0][2]), vget_low_u8(mat[2][2]));
       uint16x8_t gxb_hi =
           vaddl_u8(vget_high_u8(mat[0][2]), vget_high_u8(mat[2][2]));
       gxa_lo = vaddq_u16(
           gxa_lo, vaddl_u8(vget_low_u8(mat[1][0]), vget_low_u8(mat[1][0])));
       gxa_hi = vaddq_u16(
           gxa_hi, vaddl_u8(vget_high_u8(mat[1][0]), vget_high_u8(mat[1][0])));
       gxb_lo = vaddq_u16(
           gxb_lo, vaddl_u8(vget_low_u8(mat[1][2]), vget_low_u8(mat[1][2])));
       gxb_hi = vaddq_u16(
           gxb_hi, vaddl_u8(vget_high_u8(mat[1][2]), vget_high_u8(mat[1][2])));

       uint16x8_t gya_lo =
           vaddl_u8(vget_low_u8(mat[0][0]), vget_low_u8(mat[0][2]));
       uint16x8_t gya_hi =
           vaddl_u8(vget_high_u8(mat[0][0]), vget_high_u8(mat[0][2]));
       uint16x8_t gyb_lo =
           vaddl_u8(vget_low_u8(mat[2][0]), vget_low_u8(mat[2][2]));
       uint16x8_t gyb_hi =
           vaddl_u8(vget_high_u8(mat[2][0]), vget_high_u8(mat[2][2]));
       gya_lo = vaddq_u16(
           gya_lo, vaddl_u8(vget_low_u8(mat[0][1]), vget_low_u8(mat[0][1])));
       gya_hi = vaddq_u16(
           gya_hi, vaddl_u8(vget_high_u8(mat[0][1]), vget_high_u8(mat[0][1])));
       gyb_lo = vaddq_u16(
           gyb_lo, vaddl_u8(vget_low_u8(mat[2][1]), vget_low_u8(mat[2][1])));
       gyb_hi = vaddq_u16(
           gyb_hi, vaddl_u8(vget_high_u8(mat[2][1]), vget_high_u8(mat[2][1])));

       uint16x8_t ga_lo = vabaq_u16(vabdq_u16(gxa_lo, gxb_lo), gya_lo, gyb_lo);
       uint16x8_t ga_hi = vabaq_u16(vabdq_u16(gxa_hi, gxb_hi), gya_hi, gyb_hi);

       // Check which vector elements are under the threshold. The Laplacian is
       // then unconditionally computed and we accumulate zeros if we're not
       // under the threshold. This is much faster than using an if statement.
       uint16x8_t thresh_u16_lo = vcltq_u16(ga_lo, thresh);
       uint16x8_t thresh_u16_hi = vcltq_u16(ga_hi, thresh);

       uint16x8_t center_lo = vshll_n_u8(vget_low_u8(mat[1][1]), 2);
       uint16x8_t center_hi = vshll_n_u8(vget_high_u8(mat[1][1]), 2);

       uint16x8_t adj0_lo =
           vaddl_u8(vget_low_u8(mat[0][1]), vget_low_u8(mat[2][1]));
       uint16x8_t adj0_hi =
           vaddl_u8(vget_high_u8(mat[0][1]), vget_high_u8(mat[2][1]));
       uint16x8_t adj1_lo =
           vaddl_u8(vget_low_u8(mat[1][0]), vget_low_u8(mat[1][2]));
       uint16x8_t adj1_hi =
           vaddl_u8(vget_high_u8(mat[1][0]), vget_high_u8(mat[1][2]));
       uint16x8_t adj_lo = vaddq_u16(adj0_lo, adj1_lo);
       adj_lo = vaddq_u16(adj_lo, adj_lo);
       uint16x8_t adj_hi = vaddq_u16(adj0_hi, adj1_hi);
       adj_hi = vaddq_u16(adj_hi, adj_hi);

       uint16x8_t diag0_lo =
           vaddl_u8(vget_low_u8(mat[0][0]), vget_low_u8(mat[0][2]));
       uint16x8_t diag0_hi =
           vaddl_u8(vget_high_u8(mat[0][0]), vget_high_u8(mat[0][2]));
       uint16x8_t diag1_lo =
           vaddl_u8(vget_low_u8(mat[2][0]), vget_low_u8(mat[2][2]));
       uint16x8_t diag1_hi =
           vaddl_u8(vget_high_u8(mat[2][0]), vget_high_u8(mat[2][2]));
       uint16x8_t diag_lo = vaddq_u16(diag0_lo, diag1_lo);
       uint16x8_t diag_hi = vaddq_u16(diag0_hi, diag1_hi);

       uint16x8_t v_lo = vaddq_u16(center_lo, diag_lo);
       v_lo = vabdq_u16(v_lo, adj_lo);
       uint16x8_t v_hi = vaddq_u16(center_hi, diag_hi);
       v_hi = vabdq_u16(v_hi, adj_hi);

       acc = vpadalq_u16(acc, vandq_u16(v_lo, thresh_u16_lo));
       acc = vpadalq_u16(acc, vandq_u16(v_hi, thresh_u16_hi));

       // Add -1 for each lane where the gradient is under the threshold.
       count = vpadalq_s16(count, vreinterpretq_s16_u16(thresh_u16_lo));
       count = vpadalq_s16(count, vreinterpretq_s16_u16(thresh_u16_hi));

       w += 16;
       src_ptr += 16;
     }

     if (w <= (width - 1) - 8) {
       uint8x8_t mat[3][3];
       mat[0][0] = vld1_u8(src_ptr - stride - 1);
       mat[0][1] = vld1_u8(src_ptr - stride);
       mat[0][2] = vld1_u8(src_ptr - stride + 1);
       mat[1][0] = vld1_u8(src_ptr - 1);
       mat[1][1] = vld1_u8(src_ptr);
       mat[1][2] = vld1_u8(src_ptr + 1);
       mat[2][0] = vld1_u8(src_ptr + stride - 1);
       mat[2][1] = vld1_u8(src_ptr + stride);
       mat[2][2] = vld1_u8(src_ptr + stride + 1);

       // Compute Sobel gradients.
       uint16x8_t gxa = vaddl_u8(mat[0][0], mat[2][0]);
       uint16x8_t gxb = vaddl_u8(mat[0][2], mat[2][2]);
       gxa = vaddq_u16(gxa, vaddl_u8(mat[1][0], mat[1][0]));
       gxb = vaddq_u16(gxb, vaddl_u8(mat[1][2], mat[1][2]));

       uint16x8_t gya = vaddl_u8(mat[0][0], mat[0][2]);
       uint16x8_t gyb = vaddl_u8(mat[2][0], mat[2][2]);
       gya = vaddq_u16(gya, vaddl_u8(mat[0][1], mat[0][1]));
       gyb = vaddq_u16(gyb, vaddl_u8(mat[2][1], mat[2][1]));

       uint16x8_t ga = vabaq_u16(vabdq_u16(gxa, gxb), gya, gyb);

       // Check which vector elements are under the threshold. The Laplacian is
       // then unconditionally computed and we accumulate zeros if we're not
       // under the threshold. This is much faster than using an if statement.
       uint16x8_t thresh_u16 = vcltq_u16(ga, thresh);

       uint16x8_t center = vshll_n_u8(mat[1][1], 2);

       uint16x8_t adj0 = vaddl_u8(mat[0][1], mat[2][1]);
       uint16x8_t adj1 = vaddl_u8(mat[1][0], mat[1][2]);
       uint16x8_t adj = vaddq_u16(adj0, adj1);
       adj = vaddq_u16(adj, adj);

       uint16x8_t diag0 = vaddl_u8(mat[0][0], mat[0][2]);
       uint16x8_t diag1 = vaddl_u8(mat[2][0], mat[2][2]);
       uint16x8_t diag = vaddq_u16(diag0, diag1);

       uint16x8_t v = vaddq_u16(center, diag);
       v = vabdq_u16(v, adj);

       acc = vpadalq_u16(acc, vandq_u16(v, thresh_u16));
       // Add -1 for each lane where the gradient is under the threshold.
       count = vpadalq_s16(count, vreinterpretq_s16_u16(thresh_u16));

       w += 8;
       src_ptr += 8;
     }

     if (w <= (width - 1) - 4) {
       uint16x8_t mask = vcombine_u16(vdup_n_u16(65535), vdup_n_u16(0));
       uint8x8_t mat[3][3];
       mat[0][0] = load_u8_4x1(src_ptr - stride - 1);
       mat[0][1] = load_u8_4x1(src_ptr - stride);
       mat[0][2] = load_u8_4x1(src_ptr - stride + 1);
       mat[1][0] = load_u8_4x1(src_ptr - 1);
       mat[1][1] = load_u8_4x1(src_ptr);
       mat[1][2] = load_u8_4x1(src_ptr + 1);
       mat[2][0] = load_u8_4x1(src_ptr + stride - 1);
       mat[2][1] = load_u8_4x1(src_ptr + stride);
       mat[2][2] = load_u8_4x1(src_ptr + stride + 1);

       // Compute Sobel gradients.
       uint16x8_t gxa = vaddl_u8(mat[0][0], mat[2][0]);
       uint16x8_t gxb = vaddl_u8(mat[0][2], mat[2][2]);
       gxa = vaddq_u16(gxa, vaddl_u8(mat[1][0], mat[1][0]));
       gxb = vaddq_u16(gxb, vaddl_u8(mat[1][2], mat[1][2]));

       uint16x8_t gya = vaddl_u8(mat[0][0], mat[0][2]);
       uint16x8_t gyb = vaddl_u8(mat[2][0], mat[2][2]);
       gya = vaddq_u16(gya, vaddl_u8(mat[0][1], mat[0][1]));
       gyb = vaddq_u16(gyb, vaddl_u8(mat[2][1], mat[2][1]));

       uint16x8_t ga = vabaq_u16(vabdq_u16(gxa, gxb), gya, gyb);

       // Check which vector elements are under the threshold. The Laplacian is
       // then unconditionally computed and we accumulate zeros if we're not
       // under the threshold. This is much faster than using an if statement.
       uint16x8_t thresh_u16 = vandq_u16(vcltq_u16(ga, thresh), mask);

       uint16x8_t center = vshll_n_u8(mat[1][1], 2);

       uint16x8_t adj0 = vaddl_u8(mat[0][1], mat[2][1]);
       uint16x8_t adj1 = vaddl_u8(mat[1][0], mat[1][2]);
       uint16x8_t adj = vaddq_u16(adj0, adj1);
       adj = vaddq_u16(adj, adj);

       uint16x8_t diag0 = vaddl_u8(mat[0][0], mat[0][2]);
       uint16x8_t diag1 = vaddl_u8(mat[2][0], mat[2][2]);
       uint16x8_t diag = vaddq_u16(diag0, diag1);

       uint16x8_t v = vaddq_u16(center, diag);
       v = vabdq_u16(v, adj);

       acc = vpadalq_u16(acc, vandq_u16(v, thresh_u16));
       // Add -1 for each lane where the gradient is under the threshold.
       count = vpadalq_s16(count, vreinterpretq_s16_u16(thresh_u16));

       w += 4;
       src_ptr += 4;
     }

     while (w < width - 1) {
       int mat[3][3];
       mat[0][0] = *(src_ptr - stride - 1);
       mat[0][1] = *(src_ptr - stride);
       mat[0][2] = *(src_ptr - stride + 1);
       mat[1][0] = *(src_ptr - 1);
       mat[1][1] = *(src_ptr);
       mat[1][2] = *(src_ptr + 1);
       mat[2][0] = *(src_ptr + stride - 1);
       mat[2][1] = *(src_ptr + stride);
       mat[2][2] = *(src_ptr + stride + 1);

       // Compute Sobel gradients.
       const int gx = (mat[0][0] - mat[0][2]) + (mat[2][0] - mat[2][2]) +
                      2 * (mat[1][0] - mat[1][2]);
       const int gy = (mat[0][0] - mat[2][0]) + (mat[0][2] - mat[2][2]) +
                      2 * (mat[0][1] - mat[2][1]);
       const int ga = abs(gx) + abs(gy);

       // Accumulate Laplacian.
       const int is_under = ga < edge_thresh;
       const int v = 4 * mat[1][1] -
                     2 * (mat[0][1] + mat[2][1] + mat[1][0] + mat[1][2]) +
                     (mat[0][0] + mat[0][2] + mat[2][0] + mat[2][2]);
       final_acc += abs(v) * is_under;
       final_count += is_under;

       src_ptr++;
       w++;
     }
     src_start += stride;
   } while (++h < height - 1);

   // We counted negatively, so subtract to get the final value.
   final_count -= horizontal_add_s32x4(count);
   final_acc += horizontal_long_add_u32x4(acc);
   return (final_count < 16)
              ? -1.0
              : (double)final_acc / (6 * final_count) * SQRT_PI_BY_2;
 }
	/*
	* Copyright (c) 2022, 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 <arm_neon.h>

	#include "config/aom_config.h"
	#include "config/av1_rtcd.h"
	#include "av1/encoder/encoder.h"
	#include "av1/encoder/temporal_filter.h"
	#include "aom_dsp/mathutils.h"
	#include "aom_dsp/arm/mem_neon.h"
	#include "aom_dsp/arm/sum_neon.h"

	// For the squared error buffer, add padding for 4 samples.
	#define SSE_STRIDE (BW + 4)

	// When using vld1q_u16_x4 compilers may insert an alignment hint of 256 bits.
	DECLARE_ALIGNED(32, static const uint16_t, kSlidingWindowMask[]) = {
	0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0x0000, 0x0000, 0x0000,
	0x0000, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0x0000, 0x0000,
	0x0000, 0x0000, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0x0000,
	0x0000, 0x0000, 0x0000, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF
	};

	static INLINE void get_squared_error(
	const uint8_t frame1, const uint32_t stride1, const uint8_t frame2,
	const uint32_t stride2, const uint32_t block_width,
	const uint32_t block_height, uint16_t *frame_sse,
	const unsigned int dst_stride) {
	uint16_t *dst = frame_sse;

	uint32_t i = 0;
	do {
	uint32_t j = 0;
	do {
	uint8x16_t s = vld1q_u8(frame1 + i * stride1 + j);
	uint8x16_t r = vld1q_u8(frame2 + i * stride2 + j);

	uint8x16_t abs_diff = vabdq_u8(s, r);
	uint16x8_t sse_lo =
	vmull_u8(vget_low_u8(abs_diff), vget_low_u8(abs_diff));
	uint16x8_t sse_hi =
	vmull_u8(vget_high_u8(abs_diff), vget_high_u8(abs_diff));

	vst1q_u16(dst + j + 2, sse_lo);
	vst1q_u16(dst + j + 10, sse_hi);

	j += 16;
	} while (j < block_width);

	dst += dst_stride;
	} while (++i < block_height);
	}

	static INLINE uint16x8_t load_and_pad(const uint16_t *src, const uint32_t col,
	const uint32_t block_width) {
	uint16x8_t s = vld1q_u16(src);

	if (col == 0) {
	const uint16_t lane2 = vgetq_lane_u16(s, 2);
	s = vsetq_lane_u16(lane2, s, 0);
	s = vsetq_lane_u16(lane2, s, 1);
	} else if (col >= block_width - 4) {
	const uint16_t lane5 = vgetq_lane_u16(s, 5);
	s = vsetq_lane_u16(lane5, s, 6);
	s = vsetq_lane_u16(lane5, s, 7);
	}
	return s;
	}

	static void apply_temporal_filter(
	const uint8_t *frame, const unsigned int stride, const uint32_t block_width,
	const uint32_t block_height, const int *subblock_mses,
	unsigned int accumulator, uint16_t count, const uint16_t *frame_sse,
	const uint32_t *luma_sse_sum, const double inv_num_ref_pixels,
	const double decay_factor, const double inv_factor,
	const double weight_factor, const double *d_factor, int tf_wgt_calc_lvl) {
	assert(((block_width == 16) \|\| (block_width == 32)) &&
	((block_height == 16) \|\| (block_height == 32)));

	uint32_t acc_5x5_neon[BH][BW];
	const uint16x8x4_t vmask = vld1q_u16_x4(kSlidingWindowMask);

	// Traverse 4 columns at a time - first and last two columns need padding.
	for (uint32_t col = 0; col < block_width; col += 4) {
	uint16x8_t vsrc[5];
	const uint16_t *src = frame_sse + col;

	// Load and pad (for first and last two columns) 3 rows from the top.
	for (int i = 2; i < 5; i++) {
	vsrc[i] = load_and_pad(src, col, block_width);
	src += SSE_STRIDE;
	}

	// Pad the top 2 rows.
	vsrc[0] = vsrc[2];
	vsrc[1] = vsrc[2];

	for (unsigned int row = 0; row < block_height; row++) {
	for (int i = 0; i < 4; i++) {
	uint32x4_t vsum = vdupq_n_u32(0);
	for (int j = 0; j < 5; j++) {
	vsum = vpadalq_u16(vsum, vandq_u16(vsrc[j], vmask.val[i]));
	}
	acc_5x5_neon[row][col + i] = horizontal_add_u32x4(vsum);
	}

	// Push all rows in the sliding window up one.
	for (int i = 0; i < 4; i++) {
	vsrc[i] = vsrc[i + 1];
	}

	if (row <= block_height - 4) {
	// Load next row into the bottom of the sliding window.
	vsrc[4] = load_and_pad(src, col, block_width);
	src += SSE_STRIDE;
	} else {
	// Pad the bottom 2 rows.
	vsrc[4] = vsrc[3];
	}
	}
	}

	// Perform filtering.
	if (tf_wgt_calc_lvl == 0) {
	for (unsigned int i = 0, k = 0; i < block_height; i++) {
	for (unsigned int j = 0; j < block_width; j++, k++) {
	const int pixel_value = frame[i * stride + j];
	const uint32_t diff_sse = acc_5x5_neon[i][j] + luma_sse_sum[i * BW + j];

	const double window_error = diff_sse * inv_num_ref_pixels;
	const int subblock_idx =
	(i >= block_height / 2) * 2 + (j >= block_width / 2);
	const double block_error = (double)subblock_mses[subblock_idx];
	const double combined_error =
	weight_factor * window_error + block_error * inv_factor;
	// Compute filter weight.
	double scaled_error =
	combined_error * d_factor[subblock_idx] * decay_factor;
	scaled_error = AOMMIN(scaled_error, 7);
	const int weight = (int)(exp(-scaled_error) * TF_WEIGHT_SCALE);
	accumulator[k] += weight * pixel_value;
	count[k] += weight;
	}
	}
	} else {
	for (unsigned int i = 0, k = 0; i < block_height; i++) {
	for (unsigned int j = 0; j < block_width; j++, k++) {
	const int pixel_value = frame[i * stride + j];
	const uint32_t diff_sse = acc_5x5_neon[i][j] + luma_sse_sum[i * BW + j];

	const double window_error = diff_sse * inv_num_ref_pixels;
	const int subblock_idx =
	(i >= block_height / 2) * 2 + (j >= block_width / 2);
	const double block_error = (double)subblock_mses[subblock_idx];
	const double combined_error =
	weight_factor * window_error + block_error * inv_factor;
	// Compute filter weight.
	double scaled_error =
	combined_error * d_factor[subblock_idx] * decay_factor;
	scaled_error = AOMMIN(scaled_error, 7);
	const float fweight =
	approx_exp((float)-scaled_error) * TF_WEIGHT_SCALE;
	const int weight = iroundpf(fweight);
	accumulator[k] += weight * pixel_value;
	count[k] += weight;
	}
	}
	}
	}

	void av1_apply_temporal_filter_neon(
	const YV12_BUFFER_CONFIG frame_to_filter, const MACROBLOCKD mbd,
	const BLOCK_SIZE block_size, const int mb_row, const int mb_col,
	const int num_planes, const double noise_levels, const MV subblock_mvs,
	const int *subblock_mses, const int q_factor, const int filter_strength,
	int tf_wgt_calc_lvl, const uint8_t pred, uint32_t accum,
	uint16_t *count) {
	const int is_high_bitdepth = frame_to_filter->flags & YV12_FLAG_HIGHBITDEPTH;
	assert(block_size == BLOCK_32X32 && "Only support 32x32 block with Neon!");
	assert(TF_WINDOW_LENGTH == 5 && "Only support window length 5 with Neon!");
	assert(!is_high_bitdepth && "Only support low bit-depth with Neon!");
	assert(num_planes >= 1 && num_planes <= MAX_MB_PLANE);
	(void)is_high_bitdepth;

	// Block information.
	const int mb_height = block_size_high[block_size];
	const int mb_width = block_size_wide[block_size];
	// Frame information.
	const int frame_height = frame_to_filter->y_crop_height;
	const int frame_width = frame_to_filter->y_crop_width;
	const int min_frame_size = AOMMIN(frame_height, frame_width);
	// Variables to simplify combined error calculation.
	const double inv_factor = 1.0 / ((TF_WINDOW_BLOCK_BALANCE_WEIGHT + 1) *
	TF_SEARCH_ERROR_NORM_WEIGHT);
	const double weight_factor =
	(double)TF_WINDOW_BLOCK_BALANCE_WEIGHT * inv_factor;
	// Adjust filtering based on q.
	// Larger q -> stronger filtering -> larger weight.
	// Smaller q -> weaker filtering -> smaller weight.
	double q_decay = pow((double)q_factor / TF_Q_DECAY_THRESHOLD, 2);
	q_decay = CLIP(q_decay, 1e-5, 1);
	if (q_factor >= TF_QINDEX_CUTOFF) {
	// Max q_factor is 255, therefore the upper bound of q_decay is 8.
	// We do not need a clip here.
	q_decay = 0.5 * pow((double)q_factor / 64, 2);
	}
	// Smaller strength -> smaller filtering weight.
	double s_decay = pow((double)filter_strength / TF_STRENGTH_THRESHOLD, 2);
	s_decay = CLIP(s_decay, 1e-5, 1);
	double d_factor[4] = { 0 };
	uint16_t frame_sse[SSE_STRIDE * BH] = { 0 };
	uint32_t luma_sse_sum[BW * BH] = { 0 };

	for (int subblock_idx = 0; subblock_idx < 4; subblock_idx++) {
	// Larger motion vector -> smaller filtering weight.
	const MV mv = subblock_mvs[subblock_idx];
	const double distance = sqrt(pow(mv.row, 2) + pow(mv.col, 2));
	double distance_threshold = min_frame_size * TF_SEARCH_DISTANCE_THRESHOLD;
	distance_threshold = AOMMAX(distance_threshold, 1);
	d_factor[subblock_idx] = distance / distance_threshold;
	d_factor[subblock_idx] = AOMMAX(d_factor[subblock_idx], 1);
	}

	// Handle planes in sequence.
	int plane_offset = 0;
	for (int plane = 0; plane < num_planes; ++plane) {
	const uint32_t plane_h = mb_height >> mbd->plane[plane].subsampling_y;
	const uint32_t plane_w = mb_width >> mbd->plane[plane].subsampling_x;
	const uint32_t frame_stride =
	frame_to_filter->strides[plane == AOM_PLANE_Y ? 0 : 1];
	const int frame_offset = mb_row * plane_h * frame_stride + mb_col * plane_w;

	const uint8_t *ref = frame_to_filter->buffers[plane] + frame_offset;
	const int ss_x_shift =
	mbd->plane[plane].subsampling_x - mbd->plane[AOM_PLANE_Y].subsampling_x;
	const int ss_y_shift =
	mbd->plane[plane].subsampling_y - mbd->plane[AOM_PLANE_Y].subsampling_y;
	const int num_ref_pixels = TF_WINDOW_LENGTH * TF_WINDOW_LENGTH +
	((plane) ? (1 << (ss_x_shift + ss_y_shift)) : 0);
	const double inv_num_ref_pixels = 1.0 / num_ref_pixels;
	// Larger noise -> larger filtering weight.
	const double n_decay = 0.5 + log(2 * noise_levels[plane] + 5.0);
	// Decay factors for non-local mean approach.
	const double decay_factor = 1 / (n_decay * q_decay * s_decay);

	// Filter U-plane and V-plane using Y-plane. This is because motion
	// search is only done on Y-plane, so the information from Y-plane
	// will be more accurate. The luma sse sum is reused in both chroma
	// planes.
	if (plane == AOM_PLANE_U) {
	for (unsigned int i = 0; i < plane_h; i++) {
	for (unsigned int j = 0; j < plane_w; j++) {
	for (int ii = 0; ii < (1 << ss_y_shift); ++ii) {
	for (int jj = 0; jj < (1 << ss_x_shift); ++jj) {
	const int yy = (i << ss_y_shift) + ii; // Y-coord on Y-plane.
	const int xx = (j << ss_x_shift) + jj; // X-coord on Y-plane.
	luma_sse_sum[i * BW + j] += frame_sse[yy * SSE_STRIDE + xx + 2];
	}
	}
	}
	}
	}

	get_squared_error(ref, frame_stride, pred + plane_offset, plane_w, plane_w,
	plane_h, frame_sse, SSE_STRIDE);

	apply_temporal_filter(pred + plane_offset, plane_w, plane_w, plane_h,
	subblock_mses, accum + plane_offset,
	count + plane_offset, frame_sse, luma_sse_sum,
	inv_num_ref_pixels, decay_factor, inv_factor,
	weight_factor, d_factor, tf_wgt_calc_lvl);

	plane_offset += plane_h * plane_w;
	}
	}

	double av1_estimate_noise_from_single_plane_neon(const uint8_t *src, int height,
	int width, int stride,
	int edge_thresh) {
	uint16x8_t thresh = vdupq_n_u16(edge_thresh);
	uint32x4_t acc = vdupq_n_u32(0);
	// Count is in theory positive as it counts the number of times we're under
	// the threshold, but it will be counted negatively in order to make best use
	// of the vclt instruction, which sets every bit of a lane to 1 when the
	// condition is true.
	int32x4_t count = vdupq_n_s32(0);
	int final_count = 0;
	int64_t final_acc = 0;
	const uint8_t *src_start = src + stride + 1;
	int h = 1;

	do {
	int w = 1;
	const uint8_t *src_ptr = src_start;

	while (w <= (width - 1) - 16) {
	uint8x16_t mat[3][3];
	mat[0][0] = vld1q_u8(src_ptr - stride - 1);
	mat[0][1] = vld1q_u8(src_ptr - stride);
	mat[0][2] = vld1q_u8(src_ptr - stride + 1);
	mat[1][0] = vld1q_u8(src_ptr - 1);
	mat[1][1] = vld1q_u8(src_ptr);
	mat[1][2] = vld1q_u8(src_ptr + 1);
	mat[2][0] = vld1q_u8(src_ptr + stride - 1);
	mat[2][1] = vld1q_u8(src_ptr + stride);
	mat[2][2] = vld1q_u8(src_ptr + stride + 1);

	// Compute Sobel gradients.
	uint16x8_t gxa_lo =
	vaddl_u8(vget_low_u8(mat[0][0]), vget_low_u8(mat[2][0]));
	uint16x8_t gxa_hi =
	vaddl_u8(vget_high_u8(mat[0][0]), vget_high_u8(mat[2][0]));
	uint16x8_t gxb_lo =
	vaddl_u8(vget_low_u8(mat[0][2]), vget_low_u8(mat[2][2]));
	uint16x8_t gxb_hi =
	vaddl_u8(vget_high_u8(mat[0][2]), vget_high_u8(mat[2][2]));
	gxa_lo = vaddq_u16(
	gxa_lo, vaddl_u8(vget_low_u8(mat[1][0]), vget_low_u8(mat[1][0])));
	gxa_hi = vaddq_u16(
	gxa_hi, vaddl_u8(vget_high_u8(mat[1][0]), vget_high_u8(mat[1][0])));
	gxb_lo = vaddq_u16(
	gxb_lo, vaddl_u8(vget_low_u8(mat[1][2]), vget_low_u8(mat[1][2])));
	gxb_hi = vaddq_u16(
	gxb_hi, vaddl_u8(vget_high_u8(mat[1][2]), vget_high_u8(mat[1][2])));

	uint16x8_t gya_lo =
	vaddl_u8(vget_low_u8(mat[0][0]), vget_low_u8(mat[0][2]));
	uint16x8_t gya_hi =
	vaddl_u8(vget_high_u8(mat[0][0]), vget_high_u8(mat[0][2]));
	uint16x8_t gyb_lo =
	vaddl_u8(vget_low_u8(mat[2][0]), vget_low_u8(mat[2][2]));
	uint16x8_t gyb_hi =
	vaddl_u8(vget_high_u8(mat[2][0]), vget_high_u8(mat[2][2]));
	gya_lo = vaddq_u16(
	gya_lo, vaddl_u8(vget_low_u8(mat[0][1]), vget_low_u8(mat[0][1])));
	gya_hi = vaddq_u16(
	gya_hi, vaddl_u8(vget_high_u8(mat[0][1]), vget_high_u8(mat[0][1])));
	gyb_lo = vaddq_u16(
	gyb_lo, vaddl_u8(vget_low_u8(mat[2][1]), vget_low_u8(mat[2][1])));
	gyb_hi = vaddq_u16(
	gyb_hi, vaddl_u8(vget_high_u8(mat[2][1]), vget_high_u8(mat[2][1])));

	uint16x8_t ga_lo = vabaq_u16(vabdq_u16(gxa_lo, gxb_lo), gya_lo, gyb_lo);
	uint16x8_t ga_hi = vabaq_u16(vabdq_u16(gxa_hi, gxb_hi), gya_hi, gyb_hi);

	// Check which vector elements are under the threshold. The Laplacian is
	// then unconditionally computed and we accumulate zeros if we're not
	// under the threshold. This is much faster than using an if statement.
	uint16x8_t thresh_u16_lo = vcltq_u16(ga_lo, thresh);
	uint16x8_t thresh_u16_hi = vcltq_u16(ga_hi, thresh);

	uint16x8_t center_lo = vshll_n_u8(vget_low_u8(mat[1][1]), 2);
	uint16x8_t center_hi = vshll_n_u8(vget_high_u8(mat[1][1]), 2);

	uint16x8_t adj0_lo =
	vaddl_u8(vget_low_u8(mat[0][1]), vget_low_u8(mat[2][1]));
	uint16x8_t adj0_hi =
	vaddl_u8(vget_high_u8(mat[0][1]), vget_high_u8(mat[2][1]));
	uint16x8_t adj1_lo =
	vaddl_u8(vget_low_u8(mat[1][0]), vget_low_u8(mat[1][2]));
	uint16x8_t adj1_hi =
	vaddl_u8(vget_high_u8(mat[1][0]), vget_high_u8(mat[1][2]));
	uint16x8_t adj_lo = vaddq_u16(adj0_lo, adj1_lo);
	adj_lo = vaddq_u16(adj_lo, adj_lo);
	uint16x8_t adj_hi = vaddq_u16(adj0_hi, adj1_hi);
	adj_hi = vaddq_u16(adj_hi, adj_hi);

	uint16x8_t diag0_lo =
	vaddl_u8(vget_low_u8(mat[0][0]), vget_low_u8(mat[0][2]));
	uint16x8_t diag0_hi =
	vaddl_u8(vget_high_u8(mat[0][0]), vget_high_u8(mat[0][2]));
	uint16x8_t diag1_lo =
	vaddl_u8(vget_low_u8(mat[2][0]), vget_low_u8(mat[2][2]));
	uint16x8_t diag1_hi =
	vaddl_u8(vget_high_u8(mat[2][0]), vget_high_u8(mat[2][2]));
	uint16x8_t diag_lo = vaddq_u16(diag0_lo, diag1_lo);
	uint16x8_t diag_hi = vaddq_u16(diag0_hi, diag1_hi);

	uint16x8_t v_lo = vaddq_u16(center_lo, diag_lo);
	v_lo = vabdq_u16(v_lo, adj_lo);
	uint16x8_t v_hi = vaddq_u16(center_hi, diag_hi);
	v_hi = vabdq_u16(v_hi, adj_hi);

	acc = vpadalq_u16(acc, vandq_u16(v_lo, thresh_u16_lo));
	acc = vpadalq_u16(acc, vandq_u16(v_hi, thresh_u16_hi));

	// Add -1 for each lane where the gradient is under the threshold.
	count = vpadalq_s16(count, vreinterpretq_s16_u16(thresh_u16_lo));
	count = vpadalq_s16(count, vreinterpretq_s16_u16(thresh_u16_hi));

	w += 16;
	src_ptr += 16;
	}

	if (w <= (width - 1) - 8) {
	uint8x8_t mat[3][3];
	mat[0][0] = vld1_u8(src_ptr - stride - 1);
	mat[0][1] = vld1_u8(src_ptr - stride);
	mat[0][2] = vld1_u8(src_ptr - stride + 1);
	mat[1][0] = vld1_u8(src_ptr - 1);
	mat[1][1] = vld1_u8(src_ptr);
	mat[1][2] = vld1_u8(src_ptr + 1);
	mat[2][0] = vld1_u8(src_ptr + stride - 1);
	mat[2][1] = vld1_u8(src_ptr + stride);
	mat[2][2] = vld1_u8(src_ptr + stride + 1);

	// Compute Sobel gradients.
	uint16x8_t gxa = vaddl_u8(mat[0][0], mat[2][0]);
	uint16x8_t gxb = vaddl_u8(mat[0][2], mat[2][2]);
	gxa = vaddq_u16(gxa, vaddl_u8(mat[1][0], mat[1][0]));
	gxb = vaddq_u16(gxb, vaddl_u8(mat[1][2], mat[1][2]));

	uint16x8_t gya = vaddl_u8(mat[0][0], mat[0][2]);
	uint16x8_t gyb = vaddl_u8(mat[2][0], mat[2][2]);
	gya = vaddq_u16(gya, vaddl_u8(mat[0][1], mat[0][1]));
	gyb = vaddq_u16(gyb, vaddl_u8(mat[2][1], mat[2][1]));

	uint16x8_t ga = vabaq_u16(vabdq_u16(gxa, gxb), gya, gyb);

	// Check which vector elements are under the threshold. The Laplacian is
	// then unconditionally computed and we accumulate zeros if we're not
	// under the threshold. This is much faster than using an if statement.
	uint16x8_t thresh_u16 = vcltq_u16(ga, thresh);

	uint16x8_t center = vshll_n_u8(mat[1][1], 2);

	uint16x8_t adj0 = vaddl_u8(mat[0][1], mat[2][1]);
	uint16x8_t adj1 = vaddl_u8(mat[1][0], mat[1][2]);
	uint16x8_t adj = vaddq_u16(adj0, adj1);
	adj = vaddq_u16(adj, adj);

	uint16x8_t diag0 = vaddl_u8(mat[0][0], mat[0][2]);
	uint16x8_t diag1 = vaddl_u8(mat[2][0], mat[2][2]);
	uint16x8_t diag = vaddq_u16(diag0, diag1);

	uint16x8_t v = vaddq_u16(center, diag);
	v = vabdq_u16(v, adj);

	acc = vpadalq_u16(acc, vandq_u16(v, thresh_u16));
	// Add -1 for each lane where the gradient is under the threshold.
	count = vpadalq_s16(count, vreinterpretq_s16_u16(thresh_u16));

	w += 8;
	src_ptr += 8;
	}

	if (w <= (width - 1) - 4) {
	uint16x8_t mask = vcombine_u16(vdup_n_u16(65535), vdup_n_u16(0));
	uint8x8_t mat[3][3];
	mat[0][0] = load_u8_4x1(src_ptr - stride - 1);
	mat[0][1] = load_u8_4x1(src_ptr - stride);
	mat[0][2] = load_u8_4x1(src_ptr - stride + 1);
	mat[1][0] = load_u8_4x1(src_ptr - 1);
	mat[1][1] = load_u8_4x1(src_ptr);
	mat[1][2] = load_u8_4x1(src_ptr + 1);
	mat[2][0] = load_u8_4x1(src_ptr + stride - 1);
	mat[2][1] = load_u8_4x1(src_ptr + stride);
	mat[2][2] = load_u8_4x1(src_ptr + stride + 1);

	// Compute Sobel gradients.
	uint16x8_t gxa = vaddl_u8(mat[0][0], mat[2][0]);
	uint16x8_t gxb = vaddl_u8(mat[0][2], mat[2][2]);
	gxa = vaddq_u16(gxa, vaddl_u8(mat[1][0], mat[1][0]));
	gxb = vaddq_u16(gxb, vaddl_u8(mat[1][2], mat[1][2]));

	uint16x8_t gya = vaddl_u8(mat[0][0], mat[0][2]);
	uint16x8_t gyb = vaddl_u8(mat[2][0], mat[2][2]);
	gya = vaddq_u16(gya, vaddl_u8(mat[0][1], mat[0][1]));
	gyb = vaddq_u16(gyb, vaddl_u8(mat[2][1], mat[2][1]));

	uint16x8_t ga = vabaq_u16(vabdq_u16(gxa, gxb), gya, gyb);

	// Check which vector elements are under the threshold. The Laplacian is
	// then unconditionally computed and we accumulate zeros if we're not
	// under the threshold. This is much faster than using an if statement.
	uint16x8_t thresh_u16 = vandq_u16(vcltq_u16(ga, thresh), mask);

	uint16x8_t center = vshll_n_u8(mat[1][1], 2);

	uint16x8_t adj0 = vaddl_u8(mat[0][1], mat[2][1]);
	uint16x8_t adj1 = vaddl_u8(mat[1][0], mat[1][2]);
	uint16x8_t adj = vaddq_u16(adj0, adj1);
	adj = vaddq_u16(adj, adj);

	uint16x8_t diag0 = vaddl_u8(mat[0][0], mat[0][2]);
	uint16x8_t diag1 = vaddl_u8(mat[2][0], mat[2][2]);
	uint16x8_t diag = vaddq_u16(diag0, diag1);

	uint16x8_t v = vaddq_u16(center, diag);
	v = vabdq_u16(v, adj);

	acc = vpadalq_u16(acc, vandq_u16(v, thresh_u16));
	// Add -1 for each lane where the gradient is under the threshold.
	count = vpadalq_s16(count, vreinterpretq_s16_u16(thresh_u16));

	w += 4;
	src_ptr += 4;
	}

	while (w < width - 1) {
	int mat[3][3];
	mat[0][0] = *(src_ptr - stride - 1);
	mat[0][1] = *(src_ptr - stride);
	mat[0][2] = *(src_ptr - stride + 1);
	mat[1][0] = *(src_ptr - 1);
	mat[1][1] = *(src_ptr);
	mat[1][2] = *(src_ptr + 1);
	mat[2][0] = *(src_ptr + stride - 1);
	mat[2][1] = *(src_ptr + stride);
	mat[2][2] = *(src_ptr + stride + 1);

	// Compute Sobel gradients.
	const int gx = (mat[0][0] - mat[0][2]) + (mat[2][0] - mat[2][2]) +
	2 * (mat[1][0] - mat[1][2]);
	const int gy = (mat[0][0] - mat[2][0]) + (mat[0][2] - mat[2][2]) +
	2 * (mat[0][1] - mat[2][1]);
	const int ga = abs(gx) + abs(gy);

	// Accumulate Laplacian.
	const int is_under = ga < edge_thresh;
	const int v = 4 * mat[1][1] -
	2 * (mat[0][1] + mat[2][1] + mat[1][0] + mat[1][2]) +
	(mat[0][0] + mat[0][2] + mat[2][0] + mat[2][2]);
	final_acc += abs(v) * is_under;
	final_count += is_under;

	src_ptr++;
	w++;
	}
	src_start += stride;
	} while (++h < height - 1);

	// We counted negatively, so subtract to get the final value.
	final_count -= horizontal_add_s32x4(count);
	final_acc += horizontal_long_add_u32x4(acc);
	return (final_count < 16)
	? -1.0
	: (double)final_acc / (6 * final_count) * SQRT_PI_BY_2;
	}