// 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];

      }

    }

  }

}

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];

  }

}

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);

}

float Mult(float v) {

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

  return 1.0f / (1.0f - v);

}

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));

}

// 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;

}

// 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;

        };

        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;

}

// 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),

                                   V(-0.55660379990111464),

                                   V(-0.49785304658857626),

                                   V(-0.43699592683512467),

                                   V(-0.40180866526242109),

                                   V(-0.27321683125358037),

                               }},

                               {{

                                   V(3803.53173721215041536),

                                   V(-3.060733579805728),

                                   V(-2.0413270132490346),

                                   V(-2.0235650159727417),

                                   V(-0.5495389509954993),

                                   V(-0.4),

                                   V(-0.4),

                                   V(-0.3),

                               }}}},

                             8));

  }

  // DCT16X8

  static constexpr QuantEncodingInternal DCT8X16() {

    return QuantEncodingInternal::DCT(

        DctQuantWeightParams({{{{

                                   V(7240.7734393502),

                                   V(-0.7),

                                   V(-0.7),

                                   V(-0.2),

                                   V(-0.2),

                                   V(-0.2),

                                   V(-0.5),

                               }},

                               {{

                                   V(1448.15468787004),

                                   V(-0.5),

                                   V(-0.5),

                                   V(-0.5),

                                   V(-0.2),

                                   V(-0.2),

                                   V(-0.2),

                               }},

                               {{

                                   V(506.854140754517),

                                   V(-1.4),

                                   V(-0.2),

                                   V(-0.5),

                                   V(-0.5),

                                   V(-1.5),

                                   V(-3.6),

                               }}}},

                             7));

  }

  // DCT32X8

  static constexpr QuantEncodingInternal DCT8X32() {

    return QuantEncodingInternal::DCT(

        DctQuantWeightParams({{{{

                                   V(16283.2494710648897),

                                   V(-1.7812845336559429),

                                   V(-1.6309059012653515),

                                   V(-1.0382179034313539),

                                   V(-0.85),

                                   V(-0.7),

                                   V(-0.9),

                                   V(-1.2360638576849587),

                               }},

                               {{

                                   V(5089.15750884921511936),

                                   V(-0.320049391452786891),

                                   V(-0.35362849922161446),

                                   V(-0.30340000000000003),

                                   V(-0.61),

                                   V(-0.5),

                                   V(-0.5),

                                   V(-0.6),

                               }},

                               {{

                                   V(3397.77603275308720128),

                                   V(-0.321327362693153371),

                                   V(-0.34507619223117997),

                                   V(-0.70340000000000003),

                                   V(-0.9),

                                   V(-1.0),

                                   V(-1.0),

                                   V(-1.1754605576265209),

                               }}}},

                             8));

  }

  // DCT32X16

  static constexpr QuantEncodingInternal DCT16X32() {

    return QuantEncodingInternal::DCT(

        DctQuantWeightParams({{{{

                                   V(13844.97076442300573),

                                   V(-0.97113799999999995),

                                   V(-0.658),

                                   V(-0.42026),

                                   V(-0.22712),

                                   V(-0.2206),

                                   V(-0.226),

                                   V(-0.6),

                               }},

                               {{

                                   V(4798.964084220744293),

                                   V(-0.61125308982767057),

                                   V(-0.83770786552491361),

                                   V(-0.79014862079498627),

                                   V(-0.2692727459704829),

                                   V(-0.38272769465388551),

                                   V(-0.22924222653091453),

                                   V(-0.20719098826199578),

                               }},

                               {{

                                   V(1807.236946760964614),

                                   V(-1.2),

                                   V(-1.2),

                                   V(-0.7),

                                   V(-0.7),

                                   V(-0.7),

                                   V(-0.4),

                                   V(-0.5),

                               }}}},

                             8));

  }

  // DCT4X8 and 8x4

  static constexpr QuantEncodingInternal DCT4X8() {

    return QuantEncodingInternal::DCT4X8(

        DctQuantWeightParams({{

                                 {{

                                     V(2198.050556016380522),

                                     V(-0.96269623020744692),

                                     V(-0.76194253026666783),

                                     V(-0.6551140670773547),

                                 }},

                                 {{

                                     V(764.3655248643528689),

                                     V(-0.92630200888366945),

                                     V(-0.9675229603596517),

                                     V(-0.27845290869168118),

                                 }},

                                 {{

                                     V(527.107573587542228),

                                     V(-1.4594385811273854),

                                     V(-1.450082094097871593),

                                     V(-1.5843722511996204),

                                 }},

                             }},

                             4),

        /* kMuls */

        {{

            V(1.0),

            V(1.0),

            V(1.0),

        }});

  }

  // AFV

  static QuantEncodingInternal AFV0() {

    return QuantEncodingInternal::AFV(DCT4X8().dct_params, DCT4X4().dct_params,

                                      {{{{

                                            // 4x4/4x8 DC tendency.

                                            V(3072.0),

                                            V(3072.0),

                                            // AFV corner.

                                            V(256.0),

                                            V(256.0),

                                            V(256.0),

                                            // AFV high freqs.

                                            V(414.0),

                                            V(0.0),

                                            V(0.0),

                                            V(0.0),

                                        }},

                                        {{

                                            // 4x4/4x8 DC tendency.

                                            V(1024.0),

                                            V(1024.0),

                                            // AFV corner.

                                            V(50),

                                            V(50),

                                            V(50),

                                            // AFV high freqs.

                                            V(58.0),

                                            V(0.0),

                                            V(0.0),

                                            V(0.0),

                                        }},

                                        {{

                                            // 4x4/4x8 DC tendency.

                                            V(384.0),

                                            V(384.0),

                                            // AFV corner.

                                            V(12.0),

                                            V(12.0),

                                            V(12.0),

                                            // AFV high freqs.

                                            V(22.0),

                                            V(-0.25),

                                            V(-0.25),

                                            V(-0.25),

                                        }}}});

  }

  // DCT64

  static QuantEncodingInternal DCT64X64() {

    return QuantEncodingInternal::DCT(

        DctQuantWeightParams({{{{

                                   V(0.9 * 26629.073922049845),

                                   V(-1.025),

                                   V(-0.78),

                                   V(-0.65012),

                                   V(-0.19041574084286472),

                                   V(-0.20819395464),

                                   V(-0.421064),

                                   V(-0.32733845535848671),

                               }},

                               {{

                                   V(0.9 * 9311.3238710010046),

                                   V(-0.3041958212306401),

                                   V(-0.3633036457487539),

                                   V(-0.35660379990111464),

                                   V(-0.3443074455424403),

                                   V(-0.33699592683512467),

                                   V(-0.30180866526242109),

                                   V(-0.27321683125358037),

                               }},

                               {{

                                   V(0.9 * 4992.2486445538634),

                                   V(-1.2),

                                   V(-1.2),

                                   V(-0.8),

                                   V(-0.7),

                                   V(-0.7),

                                   V(-0.4),

                                   V(-0.5),

                               }}}},

                             8));

  }

  // DCT64X32

  static QuantEncodingInternal DCT32X64() {

    return QuantEncodingInternal::DCT(

        DctQuantWeightParams({{{{

                                   V(0.65 * 23629.073922049845),

                                   V(-1.025),

                                   V(-0.78),

                                   V(-0.65012),

                                   V(-0.19041574084286472),

                                   V(-0.20819395464),

                                   V(-0.421064),

                                   V(-0.32733845535848671),

                               }},

                               {{

                                   V(0.65 * 8611.3238710010046),

                                   V(-0.3041958212306401),

                                   V(-0.3633036457487539),

                                   V(-0.35660379990111464),

                                   V(-0.3443074455424403),

                                   V(-0.33699592683512467),

                                   V(-0.30180866526242109),

                                   V(-0.27321683125358037),

                               }},

                               {{

                                   V(0.65 * 4492.2486445538634),

                                   V(-1.2),

                                   V(-1.2),

                                   V(-0.8),

                                   V(-0.7),

                                   V(-0.7),

                                   V(-0.4),

                                   V(-0.5),

                               }}}},

                             8));

  }