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// Copyright 2011 Google Inc. All Rights Reserved.
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//
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// Use of this source code is governed by a BSD-style license
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// that can be found in the COPYING file in the root of the source
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// tree. An additional intellectual property rights grant can be found
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// in the file PATENTS. All contributing project authors may
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// be found in the AUTHORS file in the root of the source tree.
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// -----------------------------------------------------------------------------
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//
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// Speed-critical encoding functions.
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//
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// Author: Skal ([email protected])
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#include <assert.h>
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#include <stdlib.h>  // for abs()
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#include "src/dsp/dsp.h"
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#include "src/enc/vp8i_enc.h"
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static WEBP_INLINE uint8_t clip_8b(int v) {
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  return (!(v & ~0xff)) ? v : (v < 0) ? 0 : 255;
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}
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#if !WEBP_NEON_OMIT_C_CODE
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static WEBP_INLINE int clip_max(int v, int max) {
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  return (v > max) ? max : v;
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}
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#endif  // !WEBP_NEON_OMIT_C_CODE
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//------------------------------------------------------------------------------
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// Compute susceptibility based on DCT-coeff histograms:
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// the higher, the "easier" the macroblock is to compress.
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const int VP8DspScan[16 + 4 + 4] = {
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  // Luma
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  0 +  0 * BPS,  4 +  0 * BPS, 8 +  0 * BPS, 12 +  0 * BPS,
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  0 +  4 * BPS,  4 +  4 * BPS, 8 +  4 * BPS, 12 +  4 * BPS,
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  0 +  8 * BPS,  4 +  8 * BPS, 8 +  8 * BPS, 12 +  8 * BPS,
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  0 + 12 * BPS,  4 + 12 * BPS, 8 + 12 * BPS, 12 + 12 * BPS,
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  0 + 0 * BPS,   4 + 0 * BPS, 0 + 4 * BPS,  4 + 4 * BPS,    // U
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  8 + 0 * BPS,  12 + 0 * BPS, 8 + 4 * BPS, 12 + 4 * BPS     // V
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};
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// general-purpose util function
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void VP8SetHistogramData(const int distribution[MAX_COEFF_THRESH + 1],
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                         VP8Histogram* const histo) {
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  int max_value = 0, last_non_zero = 1;
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  int k;
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  for (k = 0; k <= MAX_COEFF_THRESH; ++k) {
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    const int value = distribution[k];
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    if (value > 0) {
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      if (value > max_value) max_value = value;
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      last_non_zero = k;
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    }
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  }
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  histo->max_value = max_value;
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  histo->last_non_zero = last_non_zero;
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}
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#if !WEBP_NEON_OMIT_C_CODE
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static void CollectHistogram_C(const uint8_t* ref, const uint8_t* pred,
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                               int start_block, int end_block,
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                               VP8Histogram* const histo) {
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  int j;
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  int distribution[MAX_COEFF_THRESH + 1] = { 0 };
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  for (j = start_block; j < end_block; ++j) {
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    int k;
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    int16_t out[16];
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    VP8FTransform(ref + VP8DspScan[j], pred + VP8DspScan[j], out);
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    // Convert coefficients to bin.
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    for (k = 0; k < 16; ++k) {
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      const int v = abs(out[k]) >> 3;
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      const int clipped_value = clip_max(v, MAX_COEFF_THRESH);
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      ++distribution[clipped_value];
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    }
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  }
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  VP8SetHistogramData(distribution, histo);
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}
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#endif  // !WEBP_NEON_OMIT_C_CODE
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//------------------------------------------------------------------------------
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// run-time tables (~4k)
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static uint8_t clip1[255 + 510 + 1];    // clips [-255,510] to [0,255]
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// We declare this variable 'volatile' to prevent instruction reordering
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// and make sure it's set to true _last_ (so as to be thread-safe)
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static volatile int tables_ok = 0;
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static WEBP_TSAN_IGNORE_FUNCTION void InitTables(void) {
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  if (!tables_ok) {
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    int i;
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    for (i = -255; i <= 255 + 255; ++i) {
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      clip1[255 + i] = clip_8b(i);
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    }
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    tables_ok = 1;
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  }
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}
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//------------------------------------------------------------------------------
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// Transforms (Paragraph 14.4)
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#if !WEBP_NEON_OMIT_C_CODE
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#define STORE(x, y, v) \
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  dst[(x) + (y) * BPS] = clip_8b(ref[(x) + (y) * BPS] + ((v) >> 3))
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static const int kC1 = 20091 + (1 << 16);
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static const int kC2 = 35468;
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#define MUL(a, b) (((a) * (b)) >> 16)
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static WEBP_INLINE void ITransformOne(const uint8_t* ref, const int16_t* in,
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                                      uint8_t* dst) {
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  int C[4 * 4], *tmp;
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  int i;
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  tmp = C;
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  for (i = 0; i < 4; ++i) {    // vertical pass
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    const int a = in[0] + in[8];
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    const int b = in[0] - in[8];
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    const int c = MUL(in[4], kC2) - MUL(in[12], kC1);
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    const int d = MUL(in[4], kC1) + MUL(in[12], kC2);
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    tmp[0] = a + d;
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    tmp[1] = b + c;
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    tmp[2] = b - c;
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    tmp[3] = a - d;
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    tmp += 4;
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    in++;
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  }
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  tmp = C;
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  for (i = 0; i < 4; ++i) {    // horizontal pass
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    const int dc = tmp[0] + 4;
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    const int a =  dc +  tmp[8];
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    const int b =  dc -  tmp[8];
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    const int c = MUL(tmp[4], kC2) - MUL(tmp[12], kC1);
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    const int d = MUL(tmp[4], kC1) + MUL(tmp[12], kC2);
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    STORE(0, i, a + d);
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    STORE(1, i, b + c);
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    STORE(2, i, b - c);
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    STORE(3, i, a - d);
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    tmp++;
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  }
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}
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static void ITransform_C(const uint8_t* ref, const int16_t* in, uint8_t* dst,
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                         int do_two) {
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  ITransformOne(ref, in, dst);
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  if (do_two) {
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    ITransformOne(ref + 4, in + 16, dst + 4);
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  }
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}
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static void FTransform_C(const uint8_t* src, const uint8_t* ref, int16_t* out) {
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  int i;
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  int tmp[16];
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  for (i = 0; i < 4; ++i, src += BPS, ref += BPS) {
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    const int d0 = src[0] - ref[0];   // 9bit dynamic range ([-255,255])
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    const int d1 = src[1] - ref[1];
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    const int d2 = src[2] - ref[2];
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    const int d3 = src[3] - ref[3];
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    const int a0 = (d0 + d3);         // 10b                      [-510,510]
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    const int a1 = (d1 + d2);
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    const int a2 = (d1 - d2);
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    const int a3 = (d0 - d3);
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    tmp[0 + i * 4] = (a0 + a1) * 8;   // 14b                      [-8160,8160]
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    tmp[1 + i * 4] = (a2 * 2217 + a3 * 5352 + 1812) >> 9;      // [-7536,7542]
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    tmp[2 + i * 4] = (a0 - a1) * 8;
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    tmp[3 + i * 4] = (a3 * 2217 - a2 * 5352 +  937) >> 9;
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  }
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  for (i = 0; i < 4; ++i) {
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    const int a0 = (tmp[0 + i] + tmp[12 + i]);  // 15b
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    const int a1 = (tmp[4 + i] + tmp[ 8 + i]);
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    const int a2 = (tmp[4 + i] - tmp[ 8 + i]);
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    const int a3 = (tmp[0 + i] - tmp[12 + i]);
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    out[0 + i] = (a0 + a1 + 7) >> 4;            // 12b
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    out[4 + i] = ((a2 * 2217 + a3 * 5352 + 12000) >> 16) + (a3 != 0);
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    out[8 + i] = (a0 - a1 + 7) >> 4;
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    out[12+ i] = ((a3 * 2217 - a2 * 5352 + 51000) >> 16);
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  }
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}
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#endif  // !WEBP_NEON_OMIT_C_CODE
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static void FTransform2_C(const uint8_t* src, const uint8_t* ref,
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                          int16_t* out) {
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  VP8FTransform(src, ref, out);
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  VP8FTransform(src + 4, ref + 4, out + 16);
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}
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#if !WEBP_NEON_OMIT_C_CODE
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static void FTransformWHT_C(const int16_t* in, int16_t* out) {
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  // input is 12b signed
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  int32_t tmp[16];
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  int i;
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  for (i = 0; i < 4; ++i, in += 64) {
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    const int a0 = (in[0 * 16] + in[2 * 16]);  // 13b
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    const int a1 = (in[1 * 16] + in[3 * 16]);
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    const int a2 = (in[1 * 16] - in[3 * 16]);
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    const int a3 = (in[0 * 16] - in[2 * 16]);
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    tmp[0 + i * 4] = a0 + a1;   // 14b
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    tmp[1 + i * 4] = a3 + a2;
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    tmp[2 + i * 4] = a3 - a2;
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    tmp[3 + i * 4] = a0 - a1;
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  }
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  for (i = 0; i < 4; ++i) {
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    const int a0 = (tmp[0 + i] + tmp[8 + i]);  // 15b
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    const int a1 = (tmp[4 + i] + tmp[12+ i]);
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    const int a2 = (tmp[4 + i] - tmp[12+ i]);
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    const int a3 = (tmp[0 + i] - tmp[8 + i]);
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    const int b0 = a0 + a1;    // 16b
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    const int b1 = a3 + a2;
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    const int b2 = a3 - a2;
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    const int b3 = a0 - a1;
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    out[ 0 + i] = b0 >> 1;     // 15b
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    out[ 4 + i] = b1 >> 1;
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    out[ 8 + i] = b2 >> 1;
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    out[12 + i] = b3 >> 1;
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  }
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}
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#endif  // !WEBP_NEON_OMIT_C_CODE
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#undef MUL
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#undef STORE
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//------------------------------------------------------------------------------
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// Intra predictions
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static WEBP_INLINE void Fill(uint8_t* dst, int value, int size) {
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  int j;
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  for (j = 0; j < size; ++j) {
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    memset(dst + j * BPS, value, size);
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  }
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}
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static WEBP_INLINE void VerticalPred(uint8_t* dst,
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                                     const uint8_t* top, int size) {
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  int j;
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  if (top != NULL) {
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    for (j = 0; j < size; ++j) memcpy(dst + j * BPS, top, size);
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  } else {
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    Fill(dst, 127, size);
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  }
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}
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static WEBP_INLINE void HorizontalPred(uint8_t* dst,
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                                       const uint8_t* left, int size) {
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  if (left != NULL) {
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    int j;
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    for (j = 0; j < size; ++j) {
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      memset(dst + j * BPS, left[j], size);
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    }
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  } else {
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    Fill(dst, 129, size);
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  }
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}
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static WEBP_INLINE void TrueMotion(uint8_t* dst, const uint8_t* left,
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                                   const uint8_t* top, int size) {
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  int y;
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  if (left != NULL) {
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    if (top != NULL) {
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      const uint8_t* const clip = clip1 + 255 - left[-1];
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      for (y = 0; y < size; ++y) {
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        const uint8_t* const clip_table = clip + left[y];
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        int x;
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        for (x = 0; x < size; ++x) {
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          dst[x] = clip_table[top[x]];
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        }
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        dst += BPS;
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      }
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    } else {
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      HorizontalPred(dst, left, size);
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    }
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  } else {
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    // true motion without left samples (hence: with default 129 value)
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    // is equivalent to VE prediction where you just copy the top samples.
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    // Note that if top samples are not available, the default value is
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    // then 129, and not 127 as in the VerticalPred case.
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    if (top != NULL) {
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      VerticalPred(dst, top, size);
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    } else {
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      Fill(dst, 129, size);
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    }
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  }
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}
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static WEBP_INLINE void DCMode(uint8_t* dst, const uint8_t* left,
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                               const uint8_t* top,
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                               int size, int round, int shift) {
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  int DC = 0;
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  int j;
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  if (top != NULL) {
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    for (j = 0; j < size; ++j) DC += top[j];
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    if (left != NULL) {   // top and left present
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      for (j = 0; j < size; ++j) DC += left[j];
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    } else {      // top, but no left
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      DC += DC;
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    }
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    DC = (DC + round) >> shift;
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  } else if (left != NULL) {   // left but no top
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    for (j = 0; j < size; ++j) DC += left[j];
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    DC += DC;
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    DC = (DC + round) >> shift;
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  } else {   // no top, no left, nothing.
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    DC = 0x80;
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  }
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  Fill(dst, DC, size);
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}
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//------------------------------------------------------------------------------
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// Chroma 8x8 prediction (paragraph 12.2)
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static void IntraChromaPreds_C(uint8_t* dst, const uint8_t* left,
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                               const uint8_t* top) {
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  // U block
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  DCMode(C8DC8 + dst, left, top, 8, 8, 4);
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  VerticalPred(C8VE8 + dst, top, 8);
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  HorizontalPred(C8HE8 + dst, left, 8);
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  TrueMotion(C8TM8 + dst, left, top, 8);
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  // V block
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  dst += 8;
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  if (top != NULL) top += 8;
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  if (left != NULL) left += 16;
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  DCMode(C8DC8 + dst, left, top, 8, 8, 4);
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  VerticalPred(C8VE8 + dst, top, 8);
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  HorizontalPred(C8HE8 + dst, left, 8);
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  TrueMotion(C8TM8 + dst, left, top, 8);
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}
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//------------------------------------------------------------------------------
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// luma 16x16 prediction (paragraph 12.3)
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static void Intra16Preds_C(uint8_t* dst,
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                           const uint8_t* left, const uint8_t* top) {
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  DCMode(I16DC16 + dst, left, top, 16, 16, 5);
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  VerticalPred(I16VE16 + dst, top, 16);
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  HorizontalPred(I16HE16 + dst, left, 16);
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  TrueMotion(I16TM16 + dst, left, top, 16);
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}
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//------------------------------------------------------------------------------
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// luma 4x4 prediction
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#define DST(x, y) dst[(x) + (y) * BPS]
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#define AVG3(a, b, c) ((uint8_t)(((a) + 2 * (b) + (c) + 2) >> 2))
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#define AVG2(a, b) (((a) + (b) + 1) >> 1)
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static void VE4(uint8_t* dst, const uint8_t* top) {    // vertical
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  const uint8_t vals[4] = {
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    AVG3(top[-1], top[0], top[1]),
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    AVG3(top[ 0], top[1], top[2]),
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    AVG3(top[ 1], top[2], top[3]),
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    AVG3(top[ 2], top[3], top[4])
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  };
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  int i;
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  for (i = 0; i < 4; ++i) {
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    memcpy(dst + i * BPS, vals, 4);
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  }
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}
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static void HE4(uint8_t* dst, const uint8_t* top) {    // horizontal
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  const int X = top[-1];
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  const int I = top[-2];
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  const int J = top[-3];
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  const int K = top[-4];
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  const int L = top[-5];
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  WebPUint32ToMem(dst + 0 * BPS, 0x01010101U * AVG3(X, I, J));
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  WebPUint32ToMem(dst + 1 * BPS, 0x01010101U * AVG3(I, J, K));
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  WebPUint32ToMem(dst + 2 * BPS, 0x01010101U * AVG3(J, K, L));
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  WebPUint32ToMem(dst + 3 * BPS, 0x01010101U * AVG3(K, L, L));
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}
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static void DC4(uint8_t* dst, const uint8_t* top) {
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  uint32_t dc = 4;
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  int i;
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  for (i = 0; i < 4; ++i) dc += top[i] + top[-5 + i];
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  Fill(dst, dc >> 3, 4);
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}
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static void RD4(uint8_t* dst, const uint8_t* top) {
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  const int X = top[-1];
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  const int I = top[-2];
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  const int J = top[-3];
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  const int K = top[-4];
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  const int L = top[-5];
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  const int A = top[0];
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  const int B = top[1];
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  const int C = top[2];
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  const int D = top[3];
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  DST(0, 3)                                     = AVG3(J, K, L);
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  DST(0, 2) = DST(1, 3)                         = AVG3(I, J, K);
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  DST(0, 1) = DST(1, 2) = DST(2, 3)             = AVG3(X, I, J);
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  DST(0, 0) = DST(1, 1) = DST(2, 2) = DST(3, 3) = AVG3(A, X, I);
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  DST(1, 0) = DST(2, 1) = DST(3, 2)             = AVG3(B, A, X);
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  DST(2, 0) = DST(3, 1)                         = AVG3(C, B, A);
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  DST(3, 0)                                     = AVG3(D, C, B);
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}
401

402
static void LD4(uint8_t* dst, const uint8_t* top) {
403
  const int A = top[0];
404
  const int B = top[1];
405
  const int C = top[2];
406
  const int D = top[3];
407
  const int E = top[4];
408
  const int F = top[5];
409
  const int G = top[6];
410
  const int H = top[7];
411
  DST(0, 0)                                     = AVG3(A, B, C);
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  DST(1, 0) = DST(0, 1)                         = AVG3(B, C, D);
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  DST(2, 0) = DST(1, 1) = DST(0, 2)             = AVG3(C, D, E);
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  DST(3, 0) = DST(2, 1) = DST(1, 2) = DST(0, 3) = AVG3(D, E, F);
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  DST(3, 1) = DST(2, 2) = DST(1, 3)             = AVG3(E, F, G);
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  DST(3, 2) = DST(2, 3)                         = AVG3(F, G, H);
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  DST(3, 3)                                     = AVG3(G, H, H);
418
}
419

420
static void VR4(uint8_t* dst, const uint8_t* top) {
421
  const int X = top[-1];
422
  const int I = top[-2];
423
  const int J = top[-3];
424
  const int K = top[-4];
425
  const int A = top[0];
426
  const int B = top[1];
427
  const int C = top[2];
428
  const int D = top[3];
429
  DST(0, 0) = DST(1, 2) = AVG2(X, A);
430
  DST(1, 0) = DST(2, 2) = AVG2(A, B);
431
  DST(2, 0) = DST(3, 2) = AVG2(B, C);
432
  DST(3, 0)             = AVG2(C, D);
433

434
  DST(0, 3) =             AVG3(K, J, I);
435
  DST(0, 2) =             AVG3(J, I, X);
436
  DST(0, 1) = DST(1, 3) = AVG3(I, X, A);
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  DST(1, 1) = DST(2, 3) = AVG3(X, A, B);
438
  DST(2, 1) = DST(3, 3) = AVG3(A, B, C);
439
  DST(3, 1) =             AVG3(B, C, D);
440
}
441

442
static void VL4(uint8_t* dst, const uint8_t* top) {
443
  const int A = top[0];
444
  const int B = top[1];
445
  const int C = top[2];
446
  const int D = top[3];
447
  const int E = top[4];
448
  const int F = top[5];
449
  const int G = top[6];
450
  const int H = top[7];
451
  DST(0, 0) =             AVG2(A, B);
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  DST(1, 0) = DST(0, 2) = AVG2(B, C);
453
  DST(2, 0) = DST(1, 2) = AVG2(C, D);
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  DST(3, 0) = DST(2, 2) = AVG2(D, E);
455

456
  DST(0, 1) =             AVG3(A, B, C);
457
  DST(1, 1) = DST(0, 3) = AVG3(B, C, D);
458
  DST(2, 1) = DST(1, 3) = AVG3(C, D, E);
459
  DST(3, 1) = DST(2, 3) = AVG3(D, E, F);
460
              DST(3, 2) = AVG3(E, F, G);
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              DST(3, 3) = AVG3(F, G, H);
462
}
463

464
static void HU4(uint8_t* dst, const uint8_t* top) {
465
  const int I = top[-2];
466
  const int J = top[-3];
467
  const int K = top[-4];
468
  const int L = top[-5];
469
  DST(0, 0) =             AVG2(I, J);
470
  DST(2, 0) = DST(0, 1) = AVG2(J, K);
471
  DST(2, 1) = DST(0, 2) = AVG2(K, L);
472
  DST(1, 0) =             AVG3(I, J, K);
473
  DST(3, 0) = DST(1, 1) = AVG3(J, K, L);
474
  DST(3, 1) = DST(1, 2) = AVG3(K, L, L);
475
  DST(3, 2) = DST(2, 2) =
476
  DST(0, 3) = DST(1, 3) = DST(2, 3) = DST(3, 3) = L;
477
}
478

479
static void HD4(uint8_t* dst, const uint8_t* top) {
480
  const int X = top[-1];
481
  const int I = top[-2];
482
  const int J = top[-3];
483
  const int K = top[-4];
484
  const int L = top[-5];
485
  const int A = top[0];
486
  const int B = top[1];
487
  const int C = top[2];
488

489
  DST(0, 0) = DST(2, 1) = AVG2(I, X);
490
  DST(0, 1) = DST(2, 2) = AVG2(J, I);
491
  DST(0, 2) = DST(2, 3) = AVG2(K, J);
492
  DST(0, 3)             = AVG2(L, K);
493

494
  DST(3, 0)             = AVG3(A, B, C);
495
  DST(2, 0)             = AVG3(X, A, B);
496
  DST(1, 0) = DST(3, 1) = AVG3(I, X, A);
497
  DST(1, 1) = DST(3, 2) = AVG3(J, I, X);
498
  DST(1, 2) = DST(3, 3) = AVG3(K, J, I);
499
  DST(1, 3)             = AVG3(L, K, J);
500
}
501

502
static void TM4(uint8_t* dst, const uint8_t* top) {
503
  int x, y;
504
  const uint8_t* const clip = clip1 + 255 - top[-1];
505
  for (y = 0; y < 4; ++y) {
506
    const uint8_t* const clip_table = clip + top[-2 - y];
507
    for (x = 0; x < 4; ++x) {
508
      dst[x] = clip_table[top[x]];
509
    }
510
    dst += BPS;
511
  }
512
}
513

514
#undef DST
515
#undef AVG3
516
#undef AVG2
517

518
// Left samples are top[-5 .. -2], top_left is top[-1], top are
519
// located at top[0..3], and top right is top[4..7]
520
static void Intra4Preds_C(uint8_t* dst, const uint8_t* top) {
521
  DC4(I4DC4 + dst, top);
522
  TM4(I4TM4 + dst, top);
523
  VE4(I4VE4 + dst, top);
524
  HE4(I4HE4 + dst, top);
525
  RD4(I4RD4 + dst, top);
526
  VR4(I4VR4 + dst, top);
527
  LD4(I4LD4 + dst, top);
528
  VL4(I4VL4 + dst, top);
529
  HD4(I4HD4 + dst, top);
530
  HU4(I4HU4 + dst, top);
531
}
532

533
//------------------------------------------------------------------------------
534
// Metric
535

536
#if !WEBP_NEON_OMIT_C_CODE
537
static WEBP_INLINE int GetSSE(const uint8_t* a, const uint8_t* b,
538
                              int w, int h) {
539
  int count = 0;
540
  int y, x;
541
  for (y = 0; y < h; ++y) {
542
    for (x = 0; x < w; ++x) {
543
      const int diff = (int)a[x] - b[x];
544
      count += diff * diff;
545
    }
546
    a += BPS;
547
    b += BPS;
548
  }
549
  return count;
550
}
551

552
static int SSE16x16_C(const uint8_t* a, const uint8_t* b) {
553
  return GetSSE(a, b, 16, 16);
554
}
555
static int SSE16x8_C(const uint8_t* a, const uint8_t* b) {
556
  return GetSSE(a, b, 16, 8);
557
}
558
static int SSE8x8_C(const uint8_t* a, const uint8_t* b) {
559
  return GetSSE(a, b, 8, 8);
560
}
561
static int SSE4x4_C(const uint8_t* a, const uint8_t* b) {
562
  return GetSSE(a, b, 4, 4);
563
}
564
#endif  // !WEBP_NEON_OMIT_C_CODE
565

566
static void Mean16x4_C(const uint8_t* ref, uint32_t dc[4]) {
567
  int k, x, y;
568
  for (k = 0; k < 4; ++k) {
569
    uint32_t avg = 0;
570
    for (y = 0; y < 4; ++y) {
571
      for (x = 0; x < 4; ++x) {
572
        avg += ref[x + y * BPS];
573
      }
574
    }
575
    dc[k] = avg;
576
    ref += 4;   // go to next 4x4 block.
577
  }
578
}
579

580
//------------------------------------------------------------------------------
581
// Texture distortion
582
//
583
// We try to match the spectral content (weighted) between source and
584
// reconstructed samples.
585

586
#if !WEBP_NEON_OMIT_C_CODE
587
// Hadamard transform
588
// Returns the weighted sum of the absolute value of transformed coefficients.
589
// w[] contains a row-major 4 by 4 symmetric matrix.
590
static int TTransform(const uint8_t* in, const uint16_t* w) {
591
  int sum = 0;
592
  int tmp[16];
593
  int i;
594
  // horizontal pass
595
  for (i = 0; i < 4; ++i, in += BPS) {
596
    const int a0 = in[0] + in[2];
597
    const int a1 = in[1] + in[3];
598
    const int a2 = in[1] - in[3];
599
    const int a3 = in[0] - in[2];
600
    tmp[0 + i * 4] = a0 + a1;
601
    tmp[1 + i * 4] = a3 + a2;
602
    tmp[2 + i * 4] = a3 - a2;
603
    tmp[3 + i * 4] = a0 - a1;
604
  }
605
  // vertical pass
606
  for (i = 0; i < 4; ++i, ++w) {
607
    const int a0 = tmp[0 + i] + tmp[8 + i];
608
    const int a1 = tmp[4 + i] + tmp[12+ i];
609
    const int a2 = tmp[4 + i] - tmp[12+ i];
610
    const int a3 = tmp[0 + i] - tmp[8 + i];
611
    const int b0 = a0 + a1;
612
    const int b1 = a3 + a2;
613
    const int b2 = a3 - a2;
614
    const int b3 = a0 - a1;
615

616
    sum += w[ 0] * abs(b0);
617
    sum += w[ 4] * abs(b1);
618
    sum += w[ 8] * abs(b2);
619
    sum += w[12] * abs(b3);
620
  }
621
  return sum;
622
}
623

624
static int Disto4x4_C(const uint8_t* const a, const uint8_t* const b,
625
                      const uint16_t* const w) {
626
  const int sum1 = TTransform(a, w);
627
  const int sum2 = TTransform(b, w);
628
  return abs(sum2 - sum1) >> 5;
629
}
630

631
static int Disto16x16_C(const uint8_t* const a, const uint8_t* const b,
632
                        const uint16_t* const w) {
633
  int D = 0;
634
  int x, y;
635
  for (y = 0; y < 16 * BPS; y += 4 * BPS) {
636
    for (x = 0; x < 16; x += 4) {
637
      D += Disto4x4_C(a + x + y, b + x + y, w);
638
    }
639
  }
640
  return D;
641
}
642
#endif  // !WEBP_NEON_OMIT_C_CODE
643

644
//------------------------------------------------------------------------------
645
// Quantization
646
//
647

648
static const uint8_t kZigzag[16] = {
649
  0, 1, 4, 8, 5, 2, 3, 6, 9, 12, 13, 10, 7, 11, 14, 15
650
};
651

652
// Simple quantization
653
static int QuantizeBlock_C(int16_t in[16], int16_t out[16],
654
                           const VP8Matrix* const mtx) {
655
  int last = -1;
656
  int n;
657
  for (n = 0; n < 16; ++n) {
658
    const int j = kZigzag[n];
659
    const int sign = (in[j] < 0);
660
    const uint32_t coeff = (sign ? -in[j] : in[j]) + mtx->sharpen_[j];
661
    if (coeff > mtx->zthresh_[j]) {
662
      const uint32_t Q = mtx->q_[j];
663
      const uint32_t iQ = mtx->iq_[j];
664
      const uint32_t B = mtx->bias_[j];
665
      int level = QUANTDIV(coeff, iQ, B);
666
      if (level > MAX_LEVEL) level = MAX_LEVEL;
667
      if (sign) level = -level;
668
      in[j] = level * (int)Q;
669
      out[n] = level;
670
      if (level) last = n;
671
    } else {
672
      out[n] = 0;
673
      in[j] = 0;
674
    }
675
  }
676
  return (last >= 0);
677
}
678

679
#if !WEBP_NEON_OMIT_C_CODE || WEBP_NEON_WORK_AROUND_GCC
680
static int Quantize2Blocks_C(int16_t in[32], int16_t out[32],
681
                             const VP8Matrix* const mtx) {
682
  int nz;
683
  nz  = VP8EncQuantizeBlock(in + 0 * 16, out + 0 * 16, mtx) << 0;
684
  nz |= VP8EncQuantizeBlock(in + 1 * 16, out + 1 * 16, mtx) << 1;
685
  return nz;
686
}
687
#endif  // !WEBP_NEON_OMIT_C_CODE || WEBP_NEON_WORK_AROUND_GCC
688

689
//------------------------------------------------------------------------------
690
// Block copy
691

692
static WEBP_INLINE void Copy(const uint8_t* src, uint8_t* dst, int w, int h) {
693
  int y;
694
  for (y = 0; y < h; ++y) {
695
    memcpy(dst, src, w);
696
    src += BPS;
697
    dst += BPS;
698
  }
699
}
700

701
static void Copy4x4_C(const uint8_t* src, uint8_t* dst) {
702
  Copy(src, dst, 4, 4);
703
}
704

705
static void Copy16x8_C(const uint8_t* src, uint8_t* dst) {
706
  Copy(src, dst, 16, 8);
707
}
708

709
//------------------------------------------------------------------------------
710
// Initialization
711

712
// Speed-critical function pointers. We have to initialize them to the default
713
// implementations within VP8EncDspInit().
714
VP8CHisto VP8CollectHistogram;
715
VP8Idct VP8ITransform;
716
VP8Fdct VP8FTransform;
717
VP8Fdct VP8FTransform2;
718
VP8WHT VP8FTransformWHT;
719
VP8Intra4Preds VP8EncPredLuma4;
720
VP8IntraPreds VP8EncPredLuma16;
721
VP8IntraPreds VP8EncPredChroma8;
722
VP8Metric VP8SSE16x16;
723
VP8Metric VP8SSE8x8;
724
VP8Metric VP8SSE16x8;
725
VP8Metric VP8SSE4x4;
726
VP8WMetric VP8TDisto4x4;
727
VP8WMetric VP8TDisto16x16;
728
VP8MeanMetric VP8Mean16x4;
729
VP8QuantizeBlock VP8EncQuantizeBlock;
730
VP8Quantize2Blocks VP8EncQuantize2Blocks;
731
VP8QuantizeBlockWHT VP8EncQuantizeBlockWHT;
732
VP8BlockCopy VP8Copy4x4;
733
VP8BlockCopy VP8Copy16x8;
734

735
extern void VP8EncDspInitSSE2(void);
736
extern void VP8EncDspInitSSE41(void);
737
extern void VP8EncDspInitAVX2(void);
738
extern void VP8EncDspInitNEON(void);
739
extern void VP8EncDspInitMIPS32(void);
740
extern void VP8EncDspInitMIPSdspR2(void);
741
extern void VP8EncDspInitMSA(void);
742

743
WEBP_DSP_INIT_FUNC(VP8EncDspInit) {
744
  VP8DspInit();  // common inverse transforms
745
  InitTables();
746

747
  // default C implementations
748
#if !WEBP_NEON_OMIT_C_CODE
749
  VP8ITransform = ITransform_C;
750
  VP8FTransform = FTransform_C;
751
  VP8FTransformWHT = FTransformWHT_C;
752
  VP8TDisto4x4 = Disto4x4_C;
753
  VP8TDisto16x16 = Disto16x16_C;
754
  VP8CollectHistogram = CollectHistogram_C;
755
  VP8SSE16x16 = SSE16x16_C;
756
  VP8SSE16x8 = SSE16x8_C;
757
  VP8SSE8x8 = SSE8x8_C;
758
  VP8SSE4x4 = SSE4x4_C;
759
#endif
760

761
#if !WEBP_NEON_OMIT_C_CODE || WEBP_NEON_WORK_AROUND_GCC
762
  VP8EncQuantizeBlock = QuantizeBlock_C;
763
  VP8EncQuantize2Blocks = Quantize2Blocks_C;
764
#endif
765

766
  VP8FTransform2 = FTransform2_C;
767
  VP8EncPredLuma4 = Intra4Preds_C;
768
  VP8EncPredLuma16 = Intra16Preds_C;
769
  VP8EncPredChroma8 = IntraChromaPreds_C;
770
  VP8Mean16x4 = Mean16x4_C;
771
  VP8EncQuantizeBlockWHT = QuantizeBlock_C;
772
  VP8Copy4x4 = Copy4x4_C;
773
  VP8Copy16x8 = Copy16x8_C;
774

775
  // If defined, use CPUInfo() to overwrite some pointers with faster versions.
776
  if (VP8GetCPUInfo != NULL) {
777
#if defined(WEBP_USE_SSE2)
778
    if (VP8GetCPUInfo(kSSE2)) {
779
      VP8EncDspInitSSE2();
780
#if defined(WEBP_USE_SSE41)
781
      if (VP8GetCPUInfo(kSSE4_1)) {
782
        VP8EncDspInitSSE41();
783
      }
784
#endif
785
    }
786
#endif
787
#if defined(WEBP_USE_AVX2)
788
    if (VP8GetCPUInfo(kAVX2)) {
789
      VP8EncDspInitAVX2();
790
    }
791
#endif
792
#if defined(WEBP_USE_MIPS32)
793
    if (VP8GetCPUInfo(kMIPS32)) {
794
      VP8EncDspInitMIPS32();
795
    }
796
#endif
797
#if defined(WEBP_USE_MIPS_DSP_R2)
798
    if (VP8GetCPUInfo(kMIPSdspR2)) {
799
      VP8EncDspInitMIPSdspR2();
800
    }
801
#endif
802
#if defined(WEBP_USE_MSA)
803
    if (VP8GetCPUInfo(kMSA)) {
804
      VP8EncDspInitMSA();
805
    }
806
#endif
807
  }
808

809
#if defined(WEBP_USE_NEON)
810
  if (WEBP_NEON_OMIT_C_CODE ||
811
      (VP8GetCPUInfo != NULL && VP8GetCPUInfo(kNEON))) {
812
    VP8EncDspInitNEON();
813
  }
814
#endif
815

816
  assert(VP8ITransform != NULL);
817
  assert(VP8FTransform != NULL);
818
  assert(VP8FTransformWHT != NULL);
819
  assert(VP8TDisto4x4 != NULL);
820
  assert(VP8TDisto16x16 != NULL);
821
  assert(VP8CollectHistogram != NULL);
822
  assert(VP8SSE16x16 != NULL);
823
  assert(VP8SSE16x8 != NULL);
824
  assert(VP8SSE8x8 != NULL);
825
  assert(VP8SSE4x4 != NULL);
826
  assert(VP8EncQuantizeBlock != NULL);
827
  assert(VP8EncQuantize2Blocks != NULL);
828
  assert(VP8FTransform2 != NULL);
829
  assert(VP8EncPredLuma4 != NULL);
830
  assert(VP8EncPredLuma16 != NULL);
831
  assert(VP8EncPredChroma8 != NULL);
832
  assert(VP8Mean16x4 != NULL);
833
  assert(VP8EncQuantizeBlockWHT != NULL);
834
  assert(VP8Copy4x4 != NULL);
835
  assert(VP8Copy16x8 != NULL);
836
}
837

838