// Copyright (c) the JPEG XL Project Authors. All rights reserved.

//

// Use of this source code is governed by a BSD-style

// license that can be found in the LICENSE file.

#include "lib/jxl/quant_weights.h"

#include <jxl/memory_manager.h>

#include <cmath>

#include <cstdint>

#include <cstdio>

#include <cstdlib>

#include <vector>

#include "lib/jxl/ac_strategy.h"

#include "lib/jxl/base/compiler_specific.h"

#include "lib/jxl/base/status.h"

#include "lib/jxl/coeff_order_fwd.h"

#include "lib/jxl/dct_scales.h"

#include "lib/jxl/dec_bit_reader.h"

#include "lib/jxl/dec_modular.h"

#include "lib/jxl/fields.h"

#include "lib/jxl/frame_dimensions.h"

#include "lib/jxl/memory_manager_internal.h"

#undef HWY_TARGET_INCLUDE

#define HWY_TARGET_INCLUDE "lib/jxl/quant_weights.cc"

#include <hwy/foreach_target.h>

#include <hwy/highway.h>

#include "lib/jxl/base/fast_math-inl.h"

HWY_BEFORE_NAMESPACE();

namespace jxl {

namespace HWY_NAMESPACE {

// These templates are not found via ADL.

using hwy::HWY_NAMESPACE::Lt;

using hwy::HWY_NAMESPACE::MulAdd;

using hwy::HWY_NAMESPACE::Sqrt;

// kQuantWeights[N * N * c + N * y + x] is the relative weight of the (x, y)

// coefficient in component c. Higher weights correspond to finer quantization

// intervals and more bits spent in encoding.

static constexpr const float kAlmostZero = 1e-8f;

void GetQuantWeightsDCT2(const QuantEncoding::DCT2Weights& dct2weights,

                         float* weights) {

  for (size_t c = 0; c < 3; c++) {

    size_t start = c * 64;

    weights[start] = 0xBAD;

    weights[start + 1] = weights[start + 8] = dct2weights[c][0];

    weights[start + 9] = dct2weights[c][1];

    for (size_t y = 0; y < 2; y++) {

      for (size_t x = 0; x < 2; x++) {

        weights[start + y * 8 + x + 2] = dct2weights[c][2];

        weights[start + (y + 2) * 8 + x] = dct2weights[c][2];

      }

    }

    for (size_t y = 0; y < 2; y++) {

      for (size_t x = 0; x < 2; x++) {

        weights[start + (y + 2) * 8 + x + 2] = dct2weights[c][3];

      }

    }

    for (size_t y = 0; y < 4; y++) {

      for (size_t x = 0; x < 4; x++) {

        weights[start + y * 8 + x + 4] = dct2weights[c][4];

        weights[start + (y + 4) * 8 + x] = dct2weights[c][4];

      }

    }

    for (size_t y = 0; y < 4; y++) {

      for (size_t x = 0; x < 4; x++) {

        weights[start + (y + 4) * 8 + x + 4] = dct2weights[c][5];

      }

    }

  }

}

Unexecuted instantiation: jxl::N_SSE4::GetQuantWeightsDCT2(std::__1::array<std::__1::array<float, 6ul>, 3ul> const&, float*)

jxl::N_AVX2::GetQuantWeightsDCT2(std::__1::array<std::__1::array<float, 6ul>, 3ul> const&, float*)

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                         float* weights) {

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  for (size_t c = 0; c < 3; c++) {

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    size_t start = c * 64;

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    weights[start] = 0xBAD;

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    weights[start + 1] = weights[start + 8] = dct2weights[c][0];

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    weights[start + 9] = dct2weights[c][1];

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    for (size_t y = 0; y < 2; y++) {

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      for (size_t x = 0; x < 2; x++) {

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        weights[start + y * 8 + x + 2] = dct2weights[c][2];

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        weights[start + (y + 2) * 8 + x] = dct2weights[c][2];

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      }

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    }

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    for (size_t y = 0; y < 2; y++) {

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      for (size_t x = 0; x < 2; x++) {

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        weights[start + (y + 2) * 8 + x + 2] = dct2weights[c][3];

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      }

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    }

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    for (size_t y = 0; y < 4; y++) {

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      for (size_t x = 0; x < 4; x++) {

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        weights[start + y * 8 + x + 4] = dct2weights[c][4];

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        weights[start + (y + 4) * 8 + x] = dct2weights[c][4];

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      }

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    }

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    for (size_t y = 0; y < 4; y++) {

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      for (size_t x = 0; x < 4; x++) {

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        weights[start + (y + 4) * 8 + x + 4] = dct2weights[c][5];

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      }

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    }

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  }

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}

Unexecuted instantiation: jxl::N_AVX3::GetQuantWeightsDCT2(std::__1::array<std::__1::array<float, 6ul>, 3ul> const&, float*)

Unexecuted instantiation: jxl::N_AVX3_ZEN4::GetQuantWeightsDCT2(std::__1::array<std::__1::array<float, 6ul>, 3ul> const&, float*)

Unexecuted instantiation: jxl::N_AVX3_SPR::GetQuantWeightsDCT2(std::__1::array<std::__1::array<float, 6ul>, 3ul> const&, float*)

Unexecuted instantiation: jxl::N_SSE2::GetQuantWeightsDCT2(std::__1::array<std::__1::array<float, 6ul>, 3ul> const&, float*)

void GetQuantWeightsIdentity(const QuantEncoding::IdWeights& idweights,

                             float* weights) {

  for (size_t c = 0; c < 3; c++) {

    for (int i = 0; i < 64; i++) {

      weights[64 * c + i] = idweights[c][0];

    }

    weights[64 * c + 1] = idweights[c][1];

    weights[64 * c + 8] = idweights[c][1];

    weights[64 * c + 9] = idweights[c][2];

  }

}

Unexecuted instantiation: jxl::N_SSE4::GetQuantWeightsIdentity(std::__1::array<std::__1::array<float, 3ul>, 3ul> const&, float*)

jxl::N_AVX2::GetQuantWeightsIdentity(std::__1::array<std::__1::array<float, 3ul>, 3ul> const&, float*)

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                             float* weights) {

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  for (size_t c = 0; c < 3; c++) {

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    for (int i = 0; i < 64; i++) {

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      weights[64 * c + i] = idweights[c][0];

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    }

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    weights[64 * c + 1] = idweights[c][1];

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    weights[64 * c + 8] = idweights[c][1];

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    weights[64 * c + 9] = idweights[c][2];

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  }

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}

Unexecuted instantiation: jxl::N_AVX3::GetQuantWeightsIdentity(std::__1::array<std::__1::array<float, 3ul>, 3ul> const&, float*)

Unexecuted instantiation: jxl::N_AVX3_ZEN4::GetQuantWeightsIdentity(std::__1::array<std::__1::array<float, 3ul>, 3ul> const&, float*)

Unexecuted instantiation: jxl::N_AVX3_SPR::GetQuantWeightsIdentity(std::__1::array<std::__1::array<float, 3ul>, 3ul> const&, float*)

Unexecuted instantiation: jxl::N_SSE2::GetQuantWeightsIdentity(std::__1::array<std::__1::array<float, 3ul>, 3ul> const&, float*)

StatusOr<float> Interpolate(float pos, float max, const float* array,

                            size_t len) {

  float scaled_pos = pos * (len - 1) / max;

  size_t idx = scaled_pos;

  JXL_ENSURE(idx + 1 < len);

  float a = array[idx];

  float b = array[idx + 1];

  return a * FastPowf(b / a, scaled_pos - idx);

}

Unexecuted instantiation: jxl::N_SSE4::Interpolate(float, float, float const*, unsigned long)

jxl::N_AVX2::Interpolate(float, float, float const*, unsigned long)

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                            size_t len) {

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  float scaled_pos = pos * (len - 1) / max;

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  size_t idx = scaled_pos;

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  JXL_ENSURE(idx + 1 < len);

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  float a = array[idx];

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  float b = array[idx + 1];

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  return a * FastPowf(b / a, scaled_pos - idx);

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}

Unexecuted instantiation: jxl::N_AVX3::Interpolate(float, float, float const*, unsigned long)

Unexecuted instantiation: jxl::N_AVX3_ZEN4::Interpolate(float, float, float const*, unsigned long)

Unexecuted instantiation: jxl::N_AVX3_SPR::Interpolate(float, float, float const*, unsigned long)

Unexecuted instantiation: jxl::N_SSE2::Interpolate(float, float, float const*, unsigned long)

float Mult(float v) {

  if (v > 0.0f) return 1.0f + v;

  return 1.0f / (1.0f - v);

}

Unexecuted instantiation: jxl::N_SSE4::Mult(float)

jxl::N_AVX2::Mult(float)

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float Mult(float v) {

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  if (v > 0.0f) return 1.0f + v;

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  return 1.0f / (1.0f - v);

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}

Unexecuted instantiation: jxl::N_AVX3::Mult(float)

Unexecuted instantiation: jxl::N_AVX3_ZEN4::Mult(float)

Unexecuted instantiation: jxl::N_AVX3_SPR::Mult(float)

Unexecuted instantiation: jxl::N_SSE2::Mult(float)

using DF4 = HWY_CAPPED(float, 4);

hwy::HWY_NAMESPACE::Vec<DF4> InterpolateVec(

    hwy::HWY_NAMESPACE::Vec<DF4> scaled_pos, const float* array) {

  HWY_CAPPED(int32_t, 4) di;

  auto idx = ConvertTo(di, scaled_pos);

  auto frac = Sub(scaled_pos, ConvertTo(DF4(), idx));

  // TODO(veluca): in theory, this could be done with 8 TableLookupBytes, but

  // it's probably slower.

  auto a = GatherIndex(DF4(), array, idx);

  auto b = GatherIndex(DF4(), array + 1, idx);

  return Mul(a, FastPowf(DF4(), Div(b, a), frac));

}

Unexecuted instantiation: jxl::N_SSE4::InterpolateVec(hwy::N_SSE4::Vec128<float, 4ul>, float const*)

jxl::N_AVX2::InterpolateVec(hwy::N_AVX2::Vec128<float, 4ul>, float const*)

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    hwy::HWY_NAMESPACE::Vec<DF4> scaled_pos, const float* array) {

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  HWY_CAPPED(int32_t, 4) di;

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  auto idx = ConvertTo(di, scaled_pos);

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  auto frac = Sub(scaled_pos, ConvertTo(DF4(), idx));

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  // TODO(veluca): in theory, this could be done with 8 TableLookupBytes, but

118

  // it's probably slower.

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  auto a = GatherIndex(DF4(), array, idx);

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  auto b = GatherIndex(DF4(), array + 1, idx);

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  return Mul(a, FastPowf(DF4(), Div(b, a), frac));

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}

Unexecuted instantiation: jxl::N_AVX3::InterpolateVec(hwy::N_AVX3::Vec128<float, 4ul>, float const*)

Unexecuted instantiation: jxl::N_AVX3_ZEN4::InterpolateVec(hwy::N_AVX3_ZEN4::Vec128<float, 4ul>, float const*)

Unexecuted instantiation: jxl::N_AVX3_SPR::InterpolateVec(hwy::N_AVX3_SPR::Vec128<float, 4ul>, float const*)

Unexecuted instantiation: jxl::N_SSE2::InterpolateVec(hwy::N_SSE2::Vec128<float, 4ul>, float const*)

// Computes quant weights for a COLS*ROWS-sized transform, using num_bands

// eccentricity bands and num_ebands eccentricity bands. If print_mode is 1,

// prints the resulting matrix; if print_mode is 2, prints the matrix in a

// format suitable for a 3d plot with gnuplot.

Status GetQuantWeights(

    size_t ROWS, size_t COLS,

    const DctQuantWeightParams::DistanceBandsArray& distance_bands,

    size_t num_bands, float* out) {

  for (size_t c = 0; c < 3; c++) {

    float bands[DctQuantWeightParams::kMaxDistanceBands] = {

        distance_bands[c][0]};

    if (bands[0] < kAlmostZero) return JXL_FAILURE("Invalid distance bands");

    for (size_t i = 1; i < num_bands; i++) {

      bands[i] = bands[i - 1] * Mult(distance_bands[c][i]);

      if (bands[i] < kAlmostZero) return JXL_FAILURE("Invalid distance bands");

    }

    float scale = (num_bands - 1) / (kSqrt2 + 1e-6f);

    float rcpcol = scale / (COLS - 1);

    float rcprow = scale / (ROWS - 1);

    JXL_ENSURE(COLS >= Lanes(DF4()));

    HWY_ALIGN float l0123[4] = {0, 1, 2, 3};

    for (uint32_t y = 0; y < ROWS; y++) {

      float dy = y * rcprow;

      float dy2 = dy * dy;

      for (uint32_t x = 0; x < COLS; x += Lanes(DF4())) {

        auto dx =

            Mul(Add(Set(DF4(), x), Load(DF4(), l0123)), Set(DF4(), rcpcol));

        auto scaled_distance = Sqrt(MulAdd(dx, dx, Set(DF4(), dy2)));

        auto weight = num_bands == 1 ? Set(DF4(), bands[0])

                                     : InterpolateVec(scaled_distance, bands);

        StoreU(weight, DF4(), out + c * COLS * ROWS + y * COLS + x);

      }

    }

  }

  return true;

}

Unexecuted instantiation: jxl::N_SSE4::GetQuantWeights(unsigned long, unsigned long, std::__1::array<std::__1::array<float, 17ul>, 3ul> const&, unsigned long, float*)

jxl::N_AVX2::GetQuantWeights(unsigned long, unsigned long, std::__1::array<std::__1::array<float, 17ul>, 3ul> const&, unsigned long, float*)

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    size_t num_bands, float* out) {

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  for (size_t c = 0; c < 3; c++) {

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    float bands[DctQuantWeightParams::kMaxDistanceBands] = {

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        distance_bands[c][0]};

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    if (bands[0] < kAlmostZero) return JXL_FAILURE("Invalid distance bands");

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    for (size_t i = 1; i < num_bands; i++) {

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      bands[i] = bands[i - 1] * Mult(distance_bands[c][i]);

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      if (bands[i] < kAlmostZero) return JXL_FAILURE("Invalid distance bands");

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    }

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    float scale = (num_bands - 1) / (kSqrt2 + 1e-6f);

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    float rcpcol = scale / (COLS - 1);

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    float rcprow = scale / (ROWS - 1);

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    JXL_ENSURE(COLS >= Lanes(DF4()));

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    HWY_ALIGN float l0123[4] = {0, 1, 2, 3};

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    for (uint32_t y = 0; y < ROWS; y++) {

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      float dy = y * rcprow;

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      float dy2 = dy * dy;

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      for (uint32_t x = 0; x < COLS; x += Lanes(DF4())) {

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        auto dx =

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            Mul(Add(Set(DF4(), x), Load(DF4(), l0123)), Set(DF4(), rcpcol));

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        auto scaled_distance = Sqrt(MulAdd(dx, dx, Set(DF4(), dy2)));

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        auto weight = num_bands == 1 ? Set(DF4(), bands[0])

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                                     : InterpolateVec(scaled_distance, bands);

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        StoreU(weight, DF4(), out + c * COLS * ROWS + y * COLS + x);

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      }

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    }

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  }

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  return true;

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}

Unexecuted instantiation: jxl::N_AVX3::GetQuantWeights(unsigned long, unsigned long, std::__1::array<std::__1::array<float, 17ul>, 3ul> const&, unsigned long, float*)

Unexecuted instantiation: jxl::N_AVX3_ZEN4::GetQuantWeights(unsigned long, unsigned long, std::__1::array<std::__1::array<float, 17ul>, 3ul> const&, unsigned long, float*)

Unexecuted instantiation: jxl::N_AVX3_SPR::GetQuantWeights(unsigned long, unsigned long, std::__1::array<std::__1::array<float, 17ul>, 3ul> const&, unsigned long, float*)

Unexecuted instantiation: jxl::N_SSE2::GetQuantWeights(unsigned long, unsigned long, std::__1::array<std::__1::array<float, 17ul>, 3ul> const&, unsigned long, float*)

// TODO(veluca): SIMD-fy. With 256x256, this is actually slow.

Status ComputeQuantTable(const QuantEncoding& encoding,

                         float* JXL_RESTRICT table,

                         float* JXL_RESTRICT inv_table, size_t table_num,

                         QuantTable kind, size_t* pos) {

  constexpr size_t N = kBlockDim;

  size_t quant_table_idx = static_cast<size_t>(kind);

  size_t wrows = 8 * DequantMatrices::required_size_x[quant_table_idx];

  size_t wcols = 8 * DequantMatrices::required_size_y[quant_table_idx];

  size_t num = wrows * wcols;

  std::vector<float> weights(3 * num);

  switch (encoding.mode) {

    case QuantEncoding::kQuantModeLibrary: {

      // Library and copy quant encoding should get replaced by the actual

      // parameters by the caller.

      JXL_ENSURE(false);

      break;

    }

    case QuantEncoding::kQuantModeID: {

      JXL_ENSURE(num == kDCTBlockSize);

      GetQuantWeightsIdentity(encoding.idweights, weights.data());

      break;

    }

    case QuantEncoding::kQuantModeDCT2: {

      JXL_ENSURE(num == kDCTBlockSize);

      GetQuantWeightsDCT2(encoding.dct2weights, weights.data());

      break;

    }

    case QuantEncoding::kQuantModeDCT4: {

      JXL_ENSURE(num == kDCTBlockSize);

      float weights4x4[3 * 4 * 4];

      // Always use 4x4 GetQuantWeights for DCT4 quantization tables.

      JXL_RETURN_IF_ERROR(

          GetQuantWeights(4, 4, encoding.dct_params.distance_bands,

                          encoding.dct_params.num_distance_bands, weights4x4));

      for (size_t c = 0; c < 3; c++) {

        for (size_t y = 0; y < kBlockDim; y++) {

          for (size_t x = 0; x < kBlockDim; x++) {

            weights[c * num + y * kBlockDim + x] =

                weights4x4[c * 16 + (y / 2) * 4 + (x / 2)];

          }

        }

        weights[c * num + 1] /= encoding.dct4multipliers[c][0];

        weights[c * num + N] /= encoding.dct4multipliers[c][0];

        weights[c * num + N + 1] /= encoding.dct4multipliers[c][1];

      }

      break;

    }

    case QuantEncoding::kQuantModeDCT4X8: {

      JXL_ENSURE(num == kDCTBlockSize);

      float weights4x8[3 * 4 * 8];

      // Always use 4x8 GetQuantWeights for DCT4X8 quantization tables.

      JXL_RETURN_IF_ERROR(

          GetQuantWeights(4, 8, encoding.dct_params.distance_bands,

                          encoding.dct_params.num_distance_bands, weights4x8));

      for (size_t c = 0; c < 3; c++) {

        for (size_t y = 0; y < kBlockDim; y++) {

          for (size_t x = 0; x < kBlockDim; x++) {

            weights[c * num + y * kBlockDim + x] =

                weights4x8[c * 32 + (y / 2) * 8 + x];

          }

        }

        weights[c * num + N] /= encoding.dct4x8multipliers[c];

      }

      break;

    }

    case QuantEncoding::kQuantModeDCT: {

      JXL_RETURN_IF_ERROR(GetQuantWeights(

          wrows, wcols, encoding.dct_params.distance_bands,

          encoding.dct_params.num_distance_bands, weights.data()));

      break;

    }

    case QuantEncoding::kQuantModeRAW: {

      if (!encoding.qraw.qtable || encoding.qraw.qtable->size() != 3 * num) {

        return JXL_FAILURE("Invalid table encoding");

      }

      int* qtable = encoding.qraw.qtable->data();

      for (size_t i = 0; i < 3 * num; i++) {

        weights[i] = 1.f / (encoding.qraw.qtable_den * qtable[i]);

      }

      break;

    }

    case QuantEncoding::kQuantModeAFV: {

      constexpr float kFreqs[] = {

          0xBAD,

          0xBAD,

          0.8517778890324296,

          5.37778436506804,

          0xBAD,

          0xBAD,

          4.734747904497923,

          5.449245381693219,

          1.6598270267479331,

          4,

          7.275749096817861,

          10.423227632456525,

          2.662932286148962,

          7.630657783650829,

          8.962388608184032,

          12.97166202570235,

      };

      float weights4x8[3 * 4 * 8];

      JXL_RETURN_IF_ERROR((

          GetQuantWeights(4, 8, encoding.dct_params.distance_bands,

                          encoding.dct_params.num_distance_bands, weights4x8)));

      float weights4x4[3 * 4 * 4];

      JXL_RETURN_IF_ERROR((GetQuantWeights(

          4, 4, encoding.dct_params_afv_4x4.distance_bands,

          encoding.dct_params_afv_4x4.num_distance_bands, weights4x4)));

      constexpr float lo = 0.8517778890324296;

      constexpr float hi = 12.97166202570235f - lo + 1e-6f;

      for (size_t c = 0; c < 3; c++) {

        float bands[4];

        bands[0] = encoding.afv_weights[c][5];

        if (bands[0] < kAlmostZero) return JXL_FAILURE("Invalid AFV bands");

        for (size_t i = 1; i < 4; i++) {

          bands[i] = bands[i - 1] * Mult(encoding.afv_weights[c][i + 5]);

          if (bands[i] < kAlmostZero) return JXL_FAILURE("Invalid AFV bands");

        }

        size_t start = c * 64;

        auto set_weight = [&start, &weights](size_t x, size_t y, float val) {

          weights[start + y * 8 + x] = val;

        };

Unexecuted instantiation: quant_weights.cc:jxl::N_SSE4::ComputeQuantTable(jxl::QuantEncoding const&, float*, float*, unsigned long, jxl::QuantTable, unsigned long*)::$_0::operator()(unsigned long, unsigned long, float) const

quant_weights.cc:jxl::N_AVX2::ComputeQuantTable(jxl::QuantEncoding const&, float*, float*, unsigned long, jxl::QuantTable, unsigned long*)::$_0::operator()(unsigned long, unsigned long, float) const

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        auto set_weight = [&start, &weights](size_t x, size_t y, float val) {

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          weights[start + y * 8 + x] = val;

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        };

Unexecuted instantiation: quant_weights.cc:jxl::N_AVX3::ComputeQuantTable(jxl::QuantEncoding const&, float*, float*, unsigned long, jxl::QuantTable, unsigned long*)::$_0::operator()(unsigned long, unsigned long, float) const

Unexecuted instantiation: quant_weights.cc:jxl::N_AVX3_ZEN4::ComputeQuantTable(jxl::QuantEncoding const&, float*, float*, unsigned long, jxl::QuantTable, unsigned long*)::$_0::operator()(unsigned long, unsigned long, float) const

Unexecuted instantiation: quant_weights.cc:jxl::N_AVX3_SPR::ComputeQuantTable(jxl::QuantEncoding const&, float*, float*, unsigned long, jxl::QuantTable, unsigned long*)::$_0::operator()(unsigned long, unsigned long, float) const

Unexecuted instantiation: quant_weights.cc:jxl::N_SSE2::ComputeQuantTable(jxl::QuantEncoding const&, float*, float*, unsigned long, jxl::QuantTable, unsigned long*)::$_0::operator()(unsigned long, unsigned long, float) const

        weights[start] = 1;  // Not used, but causes MSAN error otherwise.

        // Weights for (0, 1) and (1, 0).

        set_weight(0, 1, encoding.afv_weights[c][0]);

        set_weight(1, 0, encoding.afv_weights[c][1]);

        // AFV special weights for 3-pixel corner.

        set_weight(0, 2, encoding.afv_weights[c][2]);

        set_weight(2, 0, encoding.afv_weights[c][3]);

        set_weight(2, 2, encoding.afv_weights[c][4]);

        // All other AFV weights.

        for (size_t y = 0; y < 4; y++) {

          for (size_t x = 0; x < 4; x++) {

            if (x < 2 && y < 2) continue;

            JXL_ASSIGN_OR_RETURN(

                float val, Interpolate(kFreqs[y * 4 + x] - lo, hi, bands, 4));

            set_weight(2 * x, 2 * y, val);

          }

        }

        // Put 4x8 weights in odd rows, except (1, 0).

        for (size_t y = 0; y < kBlockDim / 2; y++) {

          for (size_t x = 0; x < kBlockDim; x++) {

            if (x == 0 && y == 0) continue;

            weights[c * num + (2 * y + 1) * kBlockDim + x] =

                weights4x8[c * 32 + y * 8 + x];

          }

        }

        // Put 4x4 weights in even rows / odd columns, except (0, 1).

        for (size_t y = 0; y < kBlockDim / 2; y++) {

          for (size_t x = 0; x < kBlockDim / 2; x++) {

            if (x == 0 && y == 0) continue;

            weights[c * num + (2 * y) * kBlockDim + 2 * x + 1] =

                weights4x4[c * 16 + y * 4 + x];

          }

        }

      }

      break;

    }

  }

  size_t prev_pos = *pos;

  HWY_CAPPED(float, 64) d;

  for (size_t i = 0; i < num * 3; i += Lanes(d)) {

    auto inv_val = LoadU(d, weights.data() + i);

    if (JXL_UNLIKELY(!AllFalse(d, Ge(inv_val, Set(d, 1.0f / kAlmostZero))) ||

                     !AllFalse(d, Lt(inv_val, Set(d, kAlmostZero))))) {

      return JXL_FAILURE("Invalid quantization table");

    }

    auto val = Div(Set(d, 1.0f), inv_val);

    StoreU(val, d, table + *pos + i);

    StoreU(inv_val, d, inv_table + *pos + i);

  }

  (*pos) += 3 * num;

  // Ensure that the lowest frequencies have a 0 inverse table.

  // This does not affect en/decoding, but allows AC strategy selection to be

  // slightly simpler.

  size_t xs = DequantMatrices::required_size_x[quant_table_idx];

  size_t ys = DequantMatrices::required_size_y[quant_table_idx];

  CoefficientLayout(&ys, &xs);

  for (size_t c = 0; c < 3; c++) {

    for (size_t y = 0; y < ys; y++) {

      for (size_t x = 0; x < xs; x++) {

        inv_table[prev_pos + c * ys * xs * kDCTBlockSize + y * kBlockDim * xs +

                  x] = 0;

      }

    }

  }

  return true;

}

Unexecuted instantiation: jxl::N_SSE4::ComputeQuantTable(jxl::QuantEncoding const&, float*, float*, unsigned long, jxl::QuantTable, unsigned long*)

jxl::N_AVX2::ComputeQuantTable(jxl::QuantEncoding const&, float*, float*, unsigned long, jxl::QuantTable, unsigned long*)

Line

Count

Source

166

89.2k

                         QuantTable kind, size_t* pos) {

167

89.2k

  constexpr size_t N = kBlockDim;

168

89.2k

  size_t quant_table_idx = static_cast<size_t>(kind);

169

89.2k

  size_t wrows = 8 * DequantMatrices::required_size_x[quant_table_idx];

170

89.2k

  size_t wcols = 8 * DequantMatrices::required_size_y[quant_table_idx];

171

89.2k

  size_t num = wrows * wcols;

172

173

89.2k

  std::vector<float> weights(3 * num);

174

175

89.2k

  switch (encoding.mode) {

176

0

    case QuantEncoding::kQuantModeLibrary: {

177

      // Library and copy quant encoding should get replaced by the actual

178

      // parameters by the caller.

179

0

      JXL_ENSURE(false);

180

0

      break;

181

0

    }

182

7.29k

    case QuantEncoding::kQuantModeID: {

183

7.29k

      JXL_ENSURE(num == kDCTBlockSize);

184

7.29k

      GetQuantWeightsIdentity(encoding.idweights, weights.data());

185

7.29k

      break;

186

7.29k

    }

187

6.10k

    case QuantEncoding::kQuantModeDCT2: {

188

6.10k

      JXL_ENSURE(num == kDCTBlockSize);

189

6.10k

      GetQuantWeightsDCT2(encoding.dct2weights, weights.data());

190

6.10k

      break;

191

6.10k

    }

192

4.47k

    case QuantEncoding::kQuantModeDCT4: {

193

4.47k

      JXL_ENSURE(num == kDCTBlockSize);

194

4.47k

      float weights4x4[3 * 4 * 4];

195

      // Always use 4x4 GetQuantWeights for DCT4 quantization tables.

196

4.47k

      JXL_RETURN_IF_ERROR(

197

4.47k

          GetQuantWeights(4, 4, encoding.dct_params.distance_bands,

198

4.47k

                          encoding.dct_params.num_distance_bands, weights4x4));

199

17.8k

      for (size_t c = 0; c < 3; c++) {

200

120k

        for (size_t y = 0; y < kBlockDim; y++) {

201

966k

          for (size_t x = 0; x < kBlockDim; x++) {

202

858k

            weights[c * num + y * kBlockDim + x] =

203

858k

                weights4x4[c * 16 + (y / 2) * 4 + (x / 2)];

204

858k

          }

205

107k

        }

206

13.4k

        weights[c * num + 1] /= encoding.dct4multipliers[c][0];

207

13.4k

        weights[c * num + N] /= encoding.dct4multipliers[c][0];

208

13.4k

        weights[c * num + N + 1] /= encoding.dct4multipliers[c][1];

209

13.4k

      }

210

4.47k

      break;

211

4.47k

    }

212

5.74k

    case QuantEncoding::kQuantModeDCT4X8: {

213

5.74k

      JXL_ENSURE(num == kDCTBlockSize);

214

5.74k

      float weights4x8[3 * 4 * 8];

215

      // Always use 4x8 GetQuantWeights for DCT4X8 quantization tables.

216

5.74k

      JXL_RETURN_IF_ERROR(

217

5.74k

          GetQuantWeights(4, 8, encoding.dct_params.distance_bands,

218

5.74k

                          encoding.dct_params.num_distance_bands, weights4x8));

219

22.9k

      for (size_t c = 0; c < 3; c++) {

220

154k

        for (size_t y = 0; y < kBlockDim; y++) {

221

1.23M

          for (size_t x = 0; x < kBlockDim; x++) {

222

1.10M

            weights[c * num + y * kBlockDim + x] =

223

1.10M

                weights4x8[c * 32 + (y / 2) * 8 + x];

224

1.10M

          }

225

137k

        }

226

17.2k

        weights[c * num + N] /= encoding.dct4x8multipliers[c];

227

17.2k

      }

228

5.73k

      break;

229

5.74k

    }

230

57.5k

    case QuantEncoding::kQuantModeDCT: {

231

57.5k

      JXL_RETURN_IF_ERROR(GetQuantWeights(

232

57.5k

          wrows, wcols, encoding.dct_params.distance_bands,

233

57.5k

          encoding.dct_params.num_distance_bands, weights.data()));

234

57.5k

      break;

235

57.5k

    }

236

57.5k

    case QuantEncoding::kQuantModeRAW: {

237

4

      if (!encoding.qraw.qtable || encoding.qraw.qtable->size() != 3 * num) {

238

0

        return JXL_FAILURE("Invalid table encoding");

239

0

      }

240

4

      int* qtable = encoding.qraw.qtable->data();

241

772

      for (size_t i = 0; i < 3 * num; i++) {

242

768

        weights[i] = 1.f / (encoding.qraw.qtable_den * qtable[i]);

243

768

      }

244

4

      break;

245

4

    }

246

8.12k

    case QuantEncoding::kQuantModeAFV: {

247

8.12k

      constexpr float kFreqs[] = {

248

8.12k

          0xBAD,

249

8.12k

          0xBAD,

250

8.12k

          0.8517778890324296,

251

8.12k

          5.37778436506804,

252

8.12k

          0xBAD,

253

8.12k

          0xBAD,

254

8.12k

          4.734747904497923,

255

8.12k

          5.449245381693219,

256

8.12k

          1.6598270267479331,

257

8.12k

          4,

258

8.12k

          7.275749096817861,

259

8.12k

          10.423227632456525,

260

8.12k

          2.662932286148962,

261

8.12k

          7.630657783650829,

262

8.12k

          8.962388608184032,

263

8.12k

          12.97166202570235,

264

8.12k

      };

265

266

8.12k

      float weights4x8[3 * 4 * 8];

267

8.12k

      JXL_RETURN_IF_ERROR((

268

8.12k

          GetQuantWeights(4, 8, encoding.dct_params.distance_bands,

269

8.12k

                          encoding.dct_params.num_distance_bands, weights4x8)));

270

8.12k

      float weights4x4[3 * 4 * 4];

271

8.12k

      JXL_RETURN_IF_ERROR((GetQuantWeights(

272

8.12k

          4, 4, encoding.dct_params_afv_4x4.distance_bands,

273

8.12k

          encoding.dct_params_afv_4x4.num_distance_bands, weights4x4)));

274

275

8.12k

      constexpr float lo = 0.8517778890324296;

276

8.12k

      constexpr float hi = 12.97166202570235f - lo + 1e-6f;

277

32.4k

      for (size_t c = 0; c < 3; c++) {

278

24.3k

        float bands[4];

279

24.3k

        bands[0] = encoding.afv_weights[c][5];

280

24.3k

        if (bands[0] < kAlmostZero) return JXL_FAILURE("Invalid AFV bands");

281

97.4k

        for (size_t i = 1; i < 4; i++) {

282

73.0k

          bands[i] = bands[i - 1] * Mult(encoding.afv_weights[c][i + 5]);

283

73.0k

          if (bands[i] < kAlmostZero) return JXL_FAILURE("Invalid AFV bands");

284

73.0k

        }

285

24.3k

        size_t start = c * 64;

286

24.3k

        auto set_weight = [&start, &weights](size_t x, size_t y, float val) {

287

24.3k

          weights[start + y * 8 + x] = val;

288

24.3k

        };

289

24.3k

        weights[start] = 1;  // Not used, but causes MSAN error otherwise.

290

        // Weights for (0, 1) and (1, 0).

291

24.3k

        set_weight(0, 1, encoding.afv_weights[c][0]);

292

24.3k

        set_weight(1, 0, encoding.afv_weights[c][1]);

293

        // AFV special weights for 3-pixel corner.

294

24.3k

        set_weight(0, 2, encoding.afv_weights[c][2]);

295

24.3k

        set_weight(2, 0, encoding.afv_weights[c][3]);

296

24.3k

        set_weight(2, 2, encoding.afv_weights[c][4]);

297

298

        // All other AFV weights.

299

121k

        for (size_t y = 0; y < 4; y++) {

300

487k

          for (size_t x = 0; x < 4; x++) {

301

389k

            if (x < 2 && y < 2) continue;

302

584k

            JXL_ASSIGN_OR_RETURN(

303

584k

                float val, Interpolate(kFreqs[y * 4 + x] - lo, hi, bands, 4));

304

584k

            set_weight(2 * x, 2 * y, val);

305

584k

          }

306

97.4k

        }

307

308

        // Put 4x8 weights in odd rows, except (1, 0).

309

121k

        for (size_t y = 0; y < kBlockDim / 2; y++) {

310

876k

          for (size_t x = 0; x < kBlockDim; x++) {

311

779k

            if (x == 0 && y == 0) continue;

312

754k

            weights[c * num + (2 * y + 1) * kBlockDim + x] =

313

754k

                weights4x8[c * 32 + y * 8 + x];

314

754k

          }

315

97.4k

        }

316

        // Put 4x4 weights in even rows / odd columns, except (0, 1).

317

121k

        for (size_t y = 0; y < kBlockDim / 2; y++) {

318

487k

          for (size_t x = 0; x < kBlockDim / 2; x++) {

319

389k

            if (x == 0 && y == 0) continue;

320

365k

            weights[c * num + (2 * y) * kBlockDim + 2 * x + 1] =

321

365k

                weights4x4[c * 16 + y * 4 + x];

322

365k

          }

323

97.4k

        }

324

24.3k

      }

325

8.11k

      break;

326

8.12k

    }

327

89.2k

  }

328

89.2k

  size_t prev_pos = *pos;

329

89.2k

  HWY_CAPPED(float, 64) d;

330

17.3M

  for (size_t i = 0; i < num * 3; i += Lanes(d)) {

331

17.2M

    auto inv_val = LoadU(d, weights.data() + i);

332

17.2M

    if (JXL_UNLIKELY(!AllFalse(d, Ge(inv_val, Set(d, 1.0f / kAlmostZero))) ||

333

17.2M

                     !AllFalse(d, Lt(inv_val, Set(d, kAlmostZero))))) {

334

59

      return JXL_FAILURE("Invalid quantization table");

335

59

    }

336

17.2M

    auto val = Div(Set(d, 1.0f), inv_val);

337

17.2M

    StoreU(val, d, table + *pos + i);

338

17.2M

    StoreU(inv_val, d, inv_table + *pos + i);

339

17.2M

  }

340

89.1k

  (*pos) += 3 * num;

341

342

  // Ensure that the lowest frequencies have a 0 inverse table.

343

  // This does not affect en/decoding, but allows AC strategy selection to be

344

  // slightly simpler.

345

89.1k

  size_t xs = DequantMatrices::required_size_x[quant_table_idx];

346

89.1k

  size_t ys = DequantMatrices::required_size_y[quant_table_idx];

347

89.1k

  CoefficientLayout(&ys, &xs);

348

356k

  for (size_t c = 0; c < 3; c++) {

349

763k

    for (size_t y = 0; y < ys; y++) {

350

2.65M

      for (size_t x = 0; x < xs; x++) {

351

2.15M

        inv_table[prev_pos + c * ys * xs * kDCTBlockSize + y * kBlockDim * xs +

352

2.15M

                  x] = 0;

353

2.15M

      }

354

496k

    }

355

267k

  }

356

89.1k

  return true;

357

89.2k

}

Unexecuted instantiation: jxl::N_AVX3::ComputeQuantTable(jxl::QuantEncoding const&, float*, float*, unsigned long, jxl::QuantTable, unsigned long*)

Unexecuted instantiation: jxl::N_AVX3_ZEN4::ComputeQuantTable(jxl::QuantEncoding const&, float*, float*, unsigned long, jxl::QuantTable, unsigned long*)

Unexecuted instantiation: jxl::N_AVX3_SPR::ComputeQuantTable(jxl::QuantEncoding const&, float*, float*, unsigned long, jxl::QuantTable, unsigned long*)

Unexecuted instantiation: jxl::N_SSE2::ComputeQuantTable(jxl::QuantEncoding const&, float*, float*, unsigned long, jxl::QuantTable, unsigned long*)

// NOLINTNEXTLINE(google-readability-namespace-comments)

}  // namespace HWY_NAMESPACE

}  // namespace jxl

HWY_AFTER_NAMESPACE();

#if HWY_ONCE

namespace jxl {

namespace {

HWY_EXPORT(ComputeQuantTable);

constexpr const float kAlmostZero = 1e-8f;

Status DecodeDctParams(BitReader* br, DctQuantWeightParams* params) {

  params->num_distance_bands =

      br->ReadFixedBits<DctQuantWeightParams::kLog2MaxDistanceBands>() + 1;

  for (size_t c = 0; c < 3; c++) {

    for (size_t i = 0; i < params->num_distance_bands; i++) {

      JXL_RETURN_IF_ERROR(F16Coder::Read(br, &params->distance_bands[c][i]));

    }

    if (params->distance_bands[c][0] < kAlmostZero) {

      return JXL_FAILURE("Distance band seed is too small");

    }

    params->distance_bands[c][0] *= 64.0f;

  }

  return true;

}

Status Decode(JxlMemoryManager* memory_manager, BitReader* br,

              QuantEncoding* encoding, size_t required_size_x,

              size_t required_size_y, size_t idx,

              ModularFrameDecoder* modular_frame_decoder) {

  size_t required_size = required_size_x * required_size_y;

  required_size_x *= kBlockDim;

  required_size_y *= kBlockDim;

  int mode = br->ReadFixedBits<kLog2NumQuantModes>();

  switch (mode) {

    case QuantEncoding::kQuantModeLibrary: {

      encoding->predefined = br->ReadFixedBits<kCeilLog2NumPredefinedTables>();

      if (encoding->predefined >= kNumPredefinedTables) {

        return JXL_FAILURE("Invalid predefined table");

      }

      break;

    }

    case QuantEncoding::kQuantModeID: {

      if (required_size != 1) return JXL_FAILURE("Invalid mode");

      for (size_t c = 0; c < 3; c++) {

        for (size_t i = 0; i < 3; i++) {

          JXL_RETURN_IF_ERROR(F16Coder::Read(br, &encoding->idweights[c][i]));

          if (std::abs(encoding->idweights[c][i]) < kAlmostZero) {

            return JXL_FAILURE("ID Quantizer is too small");

          }

          encoding->idweights[c][i] *= 64;

        }

      }

      break;

    }

    case QuantEncoding::kQuantModeDCT2: {

      if (required_size != 1) return JXL_FAILURE("Invalid mode");

      for (size_t c = 0; c < 3; c++) {

        for (size_t i = 0; i < 6; i++) {

          JXL_RETURN_IF_ERROR(F16Coder::Read(br, &encoding->dct2weights[c][i]));

          if (std::abs(encoding->dct2weights[c][i]) < kAlmostZero) {

            return JXL_FAILURE("Quantizer is too small");

          }

          encoding->dct2weights[c][i] *= 64;

        }

      }

      break;

    }

    case QuantEncoding::kQuantModeDCT4X8: {

      if (required_size != 1) return JXL_FAILURE("Invalid mode");

      for (size_t c = 0; c < 3; c++) {

        JXL_RETURN_IF_ERROR(

            F16Coder::Read(br, &encoding->dct4x8multipliers[c]));

        if (std::abs(encoding->dct4x8multipliers[c]) < kAlmostZero) {

          return JXL_FAILURE("DCT4X8 multiplier is too small");

        }

      }

      JXL_RETURN_IF_ERROR(DecodeDctParams(br, &encoding->dct_params));

      break;

    }

    case QuantEncoding::kQuantModeDCT4: {

      if (required_size != 1) return JXL_FAILURE("Invalid mode");

      for (size_t c = 0; c < 3; c++) {

        for (size_t i = 0; i < 2; i++) {

          JXL_RETURN_IF_ERROR(

              F16Coder::Read(br, &encoding->dct4multipliers[c][i]));

          if (std::abs(encoding->dct4multipliers[c][i]) < kAlmostZero) {

            return JXL_FAILURE("DCT4 multiplier is too small");

          }

        }

      }

      JXL_RETURN_IF_ERROR(DecodeDctParams(br, &encoding->dct_params));

      break;

    }

    case QuantEncoding::kQuantModeAFV: {

      if (required_size != 1) return JXL_FAILURE("Invalid mode");

      for (size_t c = 0; c < 3; c++) {

        for (size_t i = 0; i < 9; i++) {

          JXL_RETURN_IF_ERROR(F16Coder::Read(br, &encoding->afv_weights[c][i]));

        }

        for (size_t i = 0; i < 6; i++) {

          encoding->afv_weights[c][i] *= 64;

        }

      }

      JXL_RETURN_IF_ERROR(DecodeDctParams(br, &encoding->dct_params));

      JXL_RETURN_IF_ERROR(DecodeDctParams(br, &encoding->dct_params_afv_4x4));

      break;

    }

    case QuantEncoding::kQuantModeDCT: {

      JXL_RETURN_IF_ERROR(DecodeDctParams(br, &encoding->dct_params));

      break;

    }

    case QuantEncoding::kQuantModeRAW: {

      // Set mode early, to avoid mem-leak.

      encoding->mode = QuantEncoding::kQuantModeRAW;

      JXL_RETURN_IF_ERROR(ModularFrameDecoder::DecodeQuantTable(

          memory_manager, required_size_x, required_size_y, br, encoding, idx,

          modular_frame_decoder));

      break;

    }

    default:

      return JXL_FAILURE("Invalid quantization table encoding");

  }

  encoding->mode = static_cast<QuantEncoding::Mode>(mode);

  return true;

}

}  // namespace

#if JXL_CXX_LANG < JXL_CXX_17

constexpr const std::array<int, 17> DequantMatrices::required_size_x;

constexpr const std::array<int, 17> DequantMatrices::required_size_y;

constexpr const size_t DequantMatrices::kSumRequiredXy;

#endif

Status DequantMatrices::Decode(JxlMemoryManager* memory_manager, BitReader* br,

                               ModularFrameDecoder* modular_frame_decoder) {

  size_t all_default = br->ReadBits(1);

  size_t num_tables = all_default ? 0 : static_cast<size_t>(kNumQuantTables);

  encodings_.clear();

  encodings_.resize(kNumQuantTables, QuantEncoding::Library<0>());

  for (size_t i = 0; i < num_tables; i++) {

    JXL_RETURN_IF_ERROR(jxl::Decode(memory_manager, br, &encodings_[i],

                                    required_size_x[i % kNumQuantTables],

                                    required_size_y[i % kNumQuantTables], i,

                                    modular_frame_decoder));

  }

  computed_mask_ = 0;

  return true;

}

Status DequantMatrices::DecodeDC(BitReader* br) {

  bool all_default = static_cast<bool>(br->ReadBits(1));

  if (!br->AllReadsWithinBounds()) return JXL_FAILURE("EOS during DecodeDC");

  if (!all_default) {

    for (size_t c = 0; c < 3; c++) {

      JXL_RETURN_IF_ERROR(F16Coder::Read(br, &dc_quant_[c]));

      dc_quant_[c] *= 1.0f / 128.0f;

      // Negative values and nearly zero are invalid values.

      if (dc_quant_[c] < kAlmostZero) {

        return JXL_FAILURE("Invalid dc_quant: coefficient is too small.");

      }

      inv_dc_quant_[c] = 1.0f / dc_quant_[c];

    }

  }

  return true;

}

constexpr float V(float v) { return static_cast<float>(v); }

namespace {

struct DequantMatricesLibraryDef {

  // DCT8

  static constexpr QuantEncodingInternal DCT() {

    return QuantEncodingInternal::DCT(DctQuantWeightParams({{{{

                                                                 V(3150.0),

                                                                 V(0.0),

                                                                 V(-0.4),

                                                                 V(-0.4),

                                                                 V(-0.4),

                                                                 V(-2.0),

                                                             }},

                                                             {{

                                                                 V(560.0),

                                                                 V(0.0),

                                                                 V(-0.3),

                                                                 V(-0.3),

                                                                 V(-0.3),

                                                                 V(-0.3),

                                                             }},

                                                             {{

                                                                 V(512.0),

                                                                 V(-2.0),

                                                                 V(-1.0),

                                                                 V(0.0),

                                                                 V(-1.0),

                                                                 V(-2.0),

                                                             }}}},

                                                           6));

  }

  // Identity

  static constexpr QuantEncodingInternal IDENTITY() {

    return QuantEncodingInternal::Identity({{{{

                                                 V(280.0),

                                                 V(3160.0),

                                                 V(3160.0),

                                             }},

                                             {{

                                                 V(60.0),

                                                 V(864.0),

                                                 V(864.0),

                                             }},

                                             {{

                                                 V(18.0),

                                                 V(200.0),

                                                 V(200.0),

                                             }}}});

  }

  // DCT2

  static constexpr QuantEncodingInternal DCT2X2() {

    return QuantEncodingInternal::DCT2({{{{

                                             V(3840.0),

                                             V(2560.0),

                                             V(1280.0),

                                             V(640.0),

                                             V(480.0),

                                             V(300.0),

                                         }},

                                         {{

                                             V(960.0),

                                             V(640.0),

                                             V(320.0),

                                             V(180.0),

                                             V(140.0),

                                             V(120.0),

                                         }},

                                         {{

                                             V(640.0),

                                             V(320.0),

                                             V(128.0),

                                             V(64.0),

                                             V(32.0),

                                             V(16.0),

                                         }}}});

  }

  // DCT4 (quant_kind 3)

  static constexpr QuantEncodingInternal DCT4X4() {

    return QuantEncodingInternal::DCT4(DctQuantWeightParams({{{{

                                                                  V(2200.0),

                                                                  V(0.0),

                                                                  V(0.0),

                                                                  V(0.0),

                                                              }},

                                                              {{

                                                                  V(392.0),

                                                                  V(0.0),

                                                                  V(0.0),

                                                                  V(0.0),

                                                              }},

                                                              {{

                                                                  V(112.0),

                                                                  V(-0.25),

                                                                  V(-0.25),

                                                                  V(-0.5),

                                                              }}}},

                                                            4),

                                       /* kMul */

                                       {{{{

                                             V(1.0),

                                             V(1.0),

                                         }},

                                         {{

                                             V(1.0),

                                             V(1.0),

                                         }},

                                         {{

                                             V(1.0),

                                             V(1.0),

                                         }}}});

  }

  // DCT16

  static constexpr QuantEncodingInternal DCT16X16() {

    return QuantEncodingInternal::DCT(

        DctQuantWeightParams({{{{

                                   V(8996.8725711814115328),

                                   V(-1.3000777393353804),

                                   V(-0.49424529824571225),

                                   V(-0.439093774457103443),

                                   V(-0.6350101832695744),

                                   V(-0.90177264050827612),

                                   V(-1.6162099239887414),

                               }},

                               {{

                                   V(3191.48366296844234752),

                                   V(-0.67424582104194355),

                                   V(-0.80745813428471001),

                                   V(-0.44925837484843441),

                                   V(-0.35865440981033403),

                                   V(-0.31322389111877305),

                                   V(-0.37615025315725483),

                               }},

                               {{

                                   V(1157.50408145487200256),

                                   V(-2.0531423165804414),

                                   V(-1.4),

                                   V(-0.50687130033378396),

                                   V(-0.42708730624733904),

                                   V(-1.4856834539296244),

                                   V(-4.9209142884401604),

                               }}}},

                             7));

  }

  // DCT32

  static constexpr QuantEncodingInternal DCT32X32() {

    return QuantEncodingInternal::DCT(

        DctQuantWeightParams({{{{

                                   V(15718.40830982518931456),

                                   V(-1.025),

                                   V(-0.98),

                                   V(-0.9012),

                                   V(-0.4),

                                   V(-0.48819395464),

                                   V(-0.421064),

                                   V(-0.27),

                               }},

                               {{

                                   V(7305.7636810695983104),

                                   V(-0.8041958212306401),

                                   V(-0.7633036457487539),