// 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/modular/transform/squeeze.h"

#include <jxl/memory_manager.h>

#include <algorithm>

#include <cstdint>

#include <cstdlib>

#include <utility>

#include <vector>

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

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

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

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

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

#include "lib/jxl/modular/modular_image.h"

#include "lib/jxl/modular/transform/squeeze_params.h"

#undef HWY_TARGET_INCLUDE

#define HWY_TARGET_INCLUDE "lib/jxl/modular/transform/squeeze.cc"

#include <hwy/foreach_target.h>

#include <hwy/highway.h>

#include "lib/jxl/simd_util-inl.h"

HWY_BEFORE_NAMESPACE();

namespace jxl {

namespace HWY_NAMESPACE {

#if HWY_TARGET != HWY_SCALAR

// These templates are not found via ADL.

using hwy::HWY_NAMESPACE::Abs;

using hwy::HWY_NAMESPACE::Add;

using hwy::HWY_NAMESPACE::And;

using hwy::HWY_NAMESPACE::DupEven;

using hwy::HWY_NAMESPACE::DupOdd;

using hwy::HWY_NAMESPACE::Gt;

using hwy::HWY_NAMESPACE::IfThenElse;

using hwy::HWY_NAMESPACE::IfThenZeroElse;

using hwy::HWY_NAMESPACE::Lt;

using hwy::HWY_NAMESPACE::MulEven;

using hwy::HWY_NAMESPACE::MulOdd;

using hwy::HWY_NAMESPACE::Ne;

using hwy::HWY_NAMESPACE::Neg;

using hwy::HWY_NAMESPACE::OddEven;

using hwy::HWY_NAMESPACE::RebindToUnsigned;

using hwy::HWY_NAMESPACE::ShiftLeft;

using hwy::HWY_NAMESPACE::ShiftRight;

using hwy::HWY_NAMESPACE::Sub;

using hwy::HWY_NAMESPACE::Xor;

using D = HWY_CAPPED(pixel_type, 8);

using DU = RebindToUnsigned<D>;

constexpr D d;

constexpr DU du;

JXL_INLINE void FastUnsqueeze(const pixel_type *JXL_RESTRICT p_residual,

                              const pixel_type *JXL_RESTRICT p_avg,

                              const pixel_type *JXL_RESTRICT p_navg,

                              const pixel_type *p_pout,

                              pixel_type *JXL_RESTRICT p_out,

                              pixel_type *p_nout) {

  const size_t N = Lanes(d);

  auto onethird = Set(d, 0x55555556);

  for (size_t x = 0; x < 8; x += N) {

    auto avg = Load(d, p_avg + x);

    auto next_avg = Load(d, p_navg + x);

    auto top = Load(d, p_pout + x);

    // Equivalent to SmoothTendency(top,avg,next_avg), but without branches

    // typo:off

    auto Ba = Sub(top, avg);

    auto an = Sub(avg, next_avg);

    auto nonmono = Xor(Ba, an);

    auto absBa = Abs(Ba);

    auto absan = Abs(an);

    auto absBn = Abs(Sub(top, next_avg));

    // Compute a3 = absBa / 3

    auto a3eh = MulEven(absBa, onethird);

    auto a3oh = MulOdd(absBa, onethird);

#if (HWY_MAJOR > 1 || (HWY_MAJOR == 1 && HWY_MINOR >= 2))

#if HWY_IS_LITTLE_ENDIAN

    auto a3 = InterleaveOdd(d, BitCast(d, a3eh), BitCast(d, a3oh));

#else  // not little endian

    auto a3 = InterleaveEven(d, BitCast(d, a3eh), BitCast(d, a3oh));

#endif  // endianness

#else  // hwy < 1.2

#if HWY_IS_LITTLE_ENDIAN

    auto a3 = OddEven(BitCast(d, a3oh), DupOdd(BitCast(d, a3eh)));

#else  // not little endian

    auto a3 = OddEven(DupEven(BitCast(d, a3oh)), BitCast(d, a3eh))

#endif  // endianness

#endif  // hwy version

    a3 = Add(a3, Add(absBn, Set(d, 2)));

    auto absdiff = ShiftRight<2>(a3);

    auto skipdiff = Ne(Ba, Zero(d));

    skipdiff = And(skipdiff, Ne(an, Zero(d)));

    skipdiff = And(skipdiff, Lt(nonmono, Zero(d)));

    auto absBa2 = Add(ShiftLeft<1>(absBa), And(absdiff, Set(d, 1)));

    absdiff = IfThenElse(Gt(absdiff, absBa2),

                         Add(ShiftLeft<1>(absBa), Set(d, 1)), absdiff);

    // typo:on

    auto absan2 = ShiftLeft<1>(absan);

    absdiff = IfThenElse(Gt(Add(absdiff, And(absdiff, Set(d, 1))), absan2),

                         absan2, absdiff);

    auto diff1 = IfThenElse(Lt(top, next_avg), Neg(absdiff), absdiff);

    auto tendency = IfThenZeroElse(skipdiff, diff1);

    auto diff_minus_tendency = Load(d, p_residual + x);

    auto diff = Add(diff_minus_tendency, tendency);

    auto out =

        Add(avg, ShiftRight<1>(

                     Add(diff, BitCast(d, ShiftRight<31>(BitCast(du, diff))))));

    Store(out, d, p_out + x);

    Store(Sub(out, diff), d, p_nout + x);

  }

}

Unexecuted instantiation: jxl::N_SSE4::FastUnsqueeze(int const*, int const*, int const*, int const*, int*, int*)

jxl::N_AVX2::FastUnsqueeze(int const*, int const*, int const*, int const*, int*, int*)

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                              pixel_type *p_nout) {

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  const size_t N = Lanes(d);

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  auto onethird = Set(d, 0x55555556);

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  for (size_t x = 0; x < 8; x += N) {

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    auto avg = Load(d, p_avg + x);

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    auto next_avg = Load(d, p_navg + x);

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    auto top = Load(d, p_pout + x);

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    // Equivalent to SmoothTendency(top,avg,next_avg), but without branches

75

    // typo:off

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    auto Ba = Sub(top, avg);

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    auto an = Sub(avg, next_avg);

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    auto nonmono = Xor(Ba, an);

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    auto absBa = Abs(Ba);

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    auto absan = Abs(an);

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    auto absBn = Abs(Sub(top, next_avg));

82

    // Compute a3 = absBa / 3

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    auto a3eh = MulEven(absBa, onethird);

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    auto a3oh = MulOdd(absBa, onethird);

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#if (HWY_MAJOR > 1 || (HWY_MAJOR == 1 && HWY_MINOR >= 2))

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#if HWY_IS_LITTLE_ENDIAN

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    auto a3 = InterleaveOdd(d, BitCast(d, a3eh), BitCast(d, a3oh));

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#else  // not little endian

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    auto a3 = InterleaveEven(d, BitCast(d, a3eh), BitCast(d, a3oh));

91

#endif  // endianness

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#else  // hwy < 1.2

93

#if HWY_IS_LITTLE_ENDIAN

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    auto a3 = OddEven(BitCast(d, a3oh), DupOdd(BitCast(d, a3eh)));

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#else  // not little endian

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    auto a3 = OddEven(DupEven(BitCast(d, a3oh)), BitCast(d, a3eh))

97

#endif  // endianness

98

#endif  // hwy version

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    a3 = Add(a3, Add(absBn, Set(d, 2)));

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    auto absdiff = ShiftRight<2>(a3);

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    auto skipdiff = Ne(Ba, Zero(d));

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    skipdiff = And(skipdiff, Ne(an, Zero(d)));

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    skipdiff = And(skipdiff, Lt(nonmono, Zero(d)));

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    auto absBa2 = Add(ShiftLeft<1>(absBa), And(absdiff, Set(d, 1)));

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    absdiff = IfThenElse(Gt(absdiff, absBa2),

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                         Add(ShiftLeft<1>(absBa), Set(d, 1)), absdiff);

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    // typo:on

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    auto absan2 = ShiftLeft<1>(absan);

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    absdiff = IfThenElse(Gt(Add(absdiff, And(absdiff, Set(d, 1))), absan2),

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                         absan2, absdiff);

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    auto diff1 = IfThenElse(Lt(top, next_avg), Neg(absdiff), absdiff);

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    auto tendency = IfThenZeroElse(skipdiff, diff1);

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    auto diff_minus_tendency = Load(d, p_residual + x);

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    auto diff = Add(diff_minus_tendency, tendency);

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    auto out =

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        Add(avg, ShiftRight<1>(

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                     Add(diff, BitCast(d, ShiftRight<31>(BitCast(du, diff))))));

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    Store(out, d, p_out + x);

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    Store(Sub(out, diff), d, p_nout + x);

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  }

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}

Unexecuted instantiation: jxl::N_SSE2::FastUnsqueeze(int const*, int const*, int const*, int const*, int*, int*)

#endif  // HWY_TARGET != HWY_SCALAR

Status InvHSqueeze(Image &input, uint32_t c, uint32_t rc, ThreadPool *pool) {

  JXL_ENSURE(c < input.channel.size());

  JXL_ENSURE(rc < input.channel.size());

  Channel &chin = input.channel[c];

  const Channel &chin_residual = input.channel[rc];

  // These must be valid since we ran MetaApply already.

  JXL_ENSURE(chin.w == DivCeil(chin.w + chin_residual.w, 2));

  JXL_ENSURE(chin.h == chin_residual.h);

  JxlMemoryManager *memory_manager = input.memory_manager();

  if (chin_residual.w == 0) {

    // Short-circuit: output channel has same dimensions as input.

    input.channel[c].hshift--;

    return true;

  }

  // Note: chin.w >= chin_residual.w and at most 1 different.

  JXL_ASSIGN_OR_RETURN(Channel chout,

                       Channel::Create(memory_manager, chin.w + chin_residual.w,

                                       chin.h, chin.hshift - 1, chin.vshift));

  JXL_DEBUG_V(4,

              "Undoing horizontal squeeze of channel %i using residuals in "

              "channel %i (going from width %" PRIuS " to %" PRIuS ")",

              c, rc, chin.w, chout.w);

  if (chin_residual.h == 0) {

    // Short-circuit: channel with no pixels.

    input.channel[c] = std::move(chout);

    return true;

  }

  auto unsqueeze_row = [&](size_t y, size_t x0) {

    const pixel_type *JXL_RESTRICT p_residual = chin_residual.Row(y);

    const pixel_type *JXL_RESTRICT p_avg = chin.Row(y);

    pixel_type *JXL_RESTRICT p_out = chout.Row(y);

    for (size_t x = x0; x < chin_residual.w; x++) {

      pixel_type_w diff_minus_tendency = p_residual[x];

      pixel_type_w avg = p_avg[x];

      pixel_type_w next_avg = (x + 1 < chin.w ? p_avg[x + 1] : avg);

      pixel_type_w left = (x ? p_out[(x << 1) - 1] : avg);

      pixel_type_w tendency = SmoothTendency(left, avg, next_avg);

      pixel_type_w diff = diff_minus_tendency + tendency;

      pixel_type_w A = avg + (diff / 2);

      p_out[(x << 1)] = A;

      pixel_type_w B = A - diff;

      p_out[(x << 1) + 1] = B;

    }

    if (chout.w & 1) p_out[chout.w - 1] = p_avg[chin.w - 1];

  };

Unexecuted instantiation: squeeze.cc:jxl::N_SSE4::InvHSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)::$_0::operator()(unsigned long, unsigned long) const

squeeze.cc:jxl::N_AVX2::InvHSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)::$_0::operator()(unsigned long, unsigned long) const

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  auto unsqueeze_row = [&](size_t y, size_t x0) {

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    const pixel_type *JXL_RESTRICT p_residual = chin_residual.Row(y);

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    const pixel_type *JXL_RESTRICT p_avg = chin.Row(y);

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    pixel_type *JXL_RESTRICT p_out = chout.Row(y);

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    for (size_t x = x0; x < chin_residual.w; x++) {

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      pixel_type_w diff_minus_tendency = p_residual[x];

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      pixel_type_w avg = p_avg[x];

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      pixel_type_w next_avg = (x + 1 < chin.w ? p_avg[x + 1] : avg);

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      pixel_type_w left = (x ? p_out[(x << 1) - 1] : avg);

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      pixel_type_w tendency = SmoothTendency(left, avg, next_avg);

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      pixel_type_w diff = diff_minus_tendency + tendency;

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      pixel_type_w A = avg + (diff / 2);

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      p_out[(x << 1)] = A;

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      pixel_type_w B = A - diff;

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      p_out[(x << 1) + 1] = B;

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    }

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    if (chout.w & 1) p_out[chout.w - 1] = p_avg[chin.w - 1];

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  };

Unexecuted instantiation: squeeze.cc:jxl::N_SSE2::InvHSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)::$_0::operator()(unsigned long, unsigned long) const

  // somewhat complicated trickery just to be able to SIMD this.

  // Horizontal unsqueeze has horizontal data dependencies, so we do

  // 8 rows at a time and treat it as a vertical unsqueeze of a

  // transposed 8x8 block (or 9x8 for one input).

  static constexpr const size_t kRowsPerThread = 8;

  const auto unsqueeze_span = [&](const uint32_t task,

                                  size_t /* thread */) -> Status {

    const size_t y0 = task * kRowsPerThread;

    const size_t rows = std::min(kRowsPerThread, chin.h - y0);

    size_t x = 0;

#if HWY_TARGET != HWY_SCALAR

    ptrdiff_t onerow_in = chin.plane.PixelsPerRow();

    ptrdiff_t onerow_inr = chin_residual.plane.PixelsPerRow();

    ptrdiff_t onerow_out = chout.plane.PixelsPerRow();

    const pixel_type *JXL_RESTRICT p_residual = chin_residual.Row(y0);

    const pixel_type *JXL_RESTRICT p_avg = chin.Row(y0);

    pixel_type *JXL_RESTRICT p_out = chout.Row(y0);

    HWY_ALIGN pixel_type b_p_avg[9 * kRowsPerThread];

    HWY_ALIGN pixel_type b_p_residual[8 * kRowsPerThread];

    HWY_ALIGN pixel_type b_p_out_even[8 * kRowsPerThread];

    HWY_ALIGN pixel_type b_p_out_odd[8 * kRowsPerThread];

    HWY_ALIGN pixel_type b_p_out_evenT[8 * kRowsPerThread];

    HWY_ALIGN pixel_type b_p_out_oddT[8 * kRowsPerThread];

    const size_t N = Lanes(d);

    if (chin_residual.w > 16 && rows == kRowsPerThread) {

      for (; x < chin_residual.w - 9; x += 8) {

        Transpose8x8Block(p_residual + x, b_p_residual, onerow_inr);

        Transpose8x8Block(p_avg + x, b_p_avg, onerow_in);

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

          b_p_avg[8 * 8 + y] = p_avg[x + 8 + onerow_in * y];

        }

        for (size_t i = 0; i < 8; i++) {

          FastUnsqueeze(

              b_p_residual + 8 * i, b_p_avg + 8 * i, b_p_avg + 8 * (i + 1),

              (x + i ? b_p_out_odd + 8 * ((x + i - 1) & 7) : b_p_avg + 8 * i),

              b_p_out_even + 8 * i, b_p_out_odd + 8 * i);

        }

        Transpose8x8Block(b_p_out_even, b_p_out_evenT, 8);

        Transpose8x8Block(b_p_out_odd, b_p_out_oddT, 8);

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

          for (size_t i = 0; i < kRowsPerThread; i += N) {

            auto even = Load(d, b_p_out_evenT + 8 * y + i);

            auto odd = Load(d, b_p_out_oddT + 8 * y + i);

            StoreInterleaved(d, even, odd,

                             p_out + ((x + i) << 1) + onerow_out * y);

          }

        }

      }

    }

#endif  // HWY_TARGET != HWY_SCALAR

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

      unsqueeze_row(y0 + y, x);

    }

    return true;

  };

Unexecuted instantiation: squeeze.cc:jxl::N_SSE4::InvHSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)::$_1::operator()(unsigned int, unsigned long) const

squeeze.cc:jxl::N_AVX2::InvHSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)::$_1::operator()(unsigned int, unsigned long) const

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                                  size_t /* thread */) -> Status {

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    const size_t y0 = task * kRowsPerThread;

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    const size_t rows = std::min(kRowsPerThread, chin.h - y0);

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    size_t x = 0;

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#if HWY_TARGET != HWY_SCALAR

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    ptrdiff_t onerow_in = chin.plane.PixelsPerRow();

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    ptrdiff_t onerow_inr = chin_residual.plane.PixelsPerRow();

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    ptrdiff_t onerow_out = chout.plane.PixelsPerRow();

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    const pixel_type *JXL_RESTRICT p_residual = chin_residual.Row(y0);

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    const pixel_type *JXL_RESTRICT p_avg = chin.Row(y0);

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    pixel_type *JXL_RESTRICT p_out = chout.Row(y0);

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    HWY_ALIGN pixel_type b_p_avg[9 * kRowsPerThread];

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    HWY_ALIGN pixel_type b_p_residual[8 * kRowsPerThread];

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    HWY_ALIGN pixel_type b_p_out_even[8 * kRowsPerThread];

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    HWY_ALIGN pixel_type b_p_out_odd[8 * kRowsPerThread];

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    HWY_ALIGN pixel_type b_p_out_evenT[8 * kRowsPerThread];

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    HWY_ALIGN pixel_type b_p_out_oddT[8 * kRowsPerThread];

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    const size_t N = Lanes(d);

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    if (chin_residual.w > 16 && rows == kRowsPerThread) {

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      for (; x < chin_residual.w - 9; x += 8) {

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        Transpose8x8Block(p_residual + x, b_p_residual, onerow_inr);

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        Transpose8x8Block(p_avg + x, b_p_avg, onerow_in);

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

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          b_p_avg[8 * 8 + y] = p_avg[x + 8 + onerow_in * y];

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        }

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        for (size_t i = 0; i < 8; i++) {

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          FastUnsqueeze(

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              b_p_residual + 8 * i, b_p_avg + 8 * i, b_p_avg + 8 * (i + 1),

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              (x + i ? b_p_out_odd + 8 * ((x + i - 1) & 7) : b_p_avg + 8 * i),

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              b_p_out_even + 8 * i, b_p_out_odd + 8 * i);

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        }

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        Transpose8x8Block(b_p_out_even, b_p_out_evenT, 8);

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        Transpose8x8Block(b_p_out_odd, b_p_out_oddT, 8);

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

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          for (size_t i = 0; i < kRowsPerThread; i += N) {

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            auto even = Load(d, b_p_out_evenT + 8 * y + i);

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            auto odd = Load(d, b_p_out_oddT + 8 * y + i);

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            StoreInterleaved(d, even, odd,

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                             p_out + ((x + i) << 1) + onerow_out * y);

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          }

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        }

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      }

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    }

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#endif  // HWY_TARGET != HWY_SCALAR

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

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      unsqueeze_row(y0 + y, x);

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    }

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    return true;

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  };

Unexecuted instantiation: squeeze.cc:jxl::N_SSE2::InvHSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)::$_1::operator()(unsigned int, unsigned long) const

  JXL_RETURN_IF_ERROR(RunOnPool(pool, 0, DivCeil(chin.h, kRowsPerThread),

                                ThreadPool::NoInit, unsqueeze_span,

                                "InvHorizontalSqueeze"));

  input.channel[c] = std::move(chout);

  return true;

}

Unexecuted instantiation: jxl::N_SSE4::InvHSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)

jxl::N_AVX2::InvHSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)

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Status InvHSqueeze(Image &input, uint32_t c, uint32_t rc, ThreadPool *pool) {

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  JXL_ENSURE(c < input.channel.size());

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  JXL_ENSURE(rc < input.channel.size());

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  Channel &chin = input.channel[c];

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  const Channel &chin_residual = input.channel[rc];

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  // These must be valid since we ran MetaApply already.

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  JXL_ENSURE(chin.w == DivCeil(chin.w + chin_residual.w, 2));

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  JXL_ENSURE(chin.h == chin_residual.h);

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  JxlMemoryManager *memory_manager = input.memory_manager();

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  if (chin_residual.w == 0) {

138

    // Short-circuit: output channel has same dimensions as input.

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    input.channel[c].hshift--;

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    return true;

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  }

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  // Note: chin.w >= chin_residual.w and at most 1 different.

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  JXL_ASSIGN_OR_RETURN(Channel chout,

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                       Channel::Create(memory_manager, chin.w + chin_residual.w,

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                                       chin.h, chin.hshift - 1, chin.vshift));

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  JXL_DEBUG_V(4,

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              "Undoing horizontal squeeze of channel %i using residuals in "

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              "channel %i (going from width %" PRIuS " to %" PRIuS ")",

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              c, rc, chin.w, chout.w);

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  if (chin_residual.h == 0) {

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    // Short-circuit: channel with no pixels.

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0

    input.channel[c] = std::move(chout);

155

0

    return true;

156

0

  }

157

111k

  auto unsqueeze_row = [&](size_t y, size_t x0) {

158

111k

    const pixel_type *JXL_RESTRICT p_residual = chin_residual.Row(y);

159

111k

    const pixel_type *JXL_RESTRICT p_avg = chin.Row(y);

160

111k

    pixel_type *JXL_RESTRICT p_out = chout.Row(y);

161

111k

    for (size_t x = x0; x < chin_residual.w; x++) {

162

111k

      pixel_type_w diff_minus_tendency = p_residual[x];

163

111k

      pixel_type_w avg = p_avg[x];

164

111k

      pixel_type_w next_avg = (x + 1 < chin.w ? p_avg[x + 1] : avg);

165

111k

      pixel_type_w left = (x ? p_out[(x << 1) - 1] : avg);

166

111k

      pixel_type_w tendency = SmoothTendency(left, avg, next_avg);

167

111k

      pixel_type_w diff = diff_minus_tendency + tendency;

168

111k

      pixel_type_w A = avg + (diff / 2);

169

111k

      p_out[(x << 1)] = A;

170

111k

      pixel_type_w B = A - diff;

171

111k

      p_out[(x << 1) + 1] = B;

172

111k

    }

173

111k

    if (chout.w & 1) p_out[chout.w - 1] = p_avg[chin.w - 1];

174

111k

  };

175

176

  // somewhat complicated trickery just to be able to SIMD this.

177

  // Horizontal unsqueeze has horizontal data dependencies, so we do

178

  // 8 rows at a time and treat it as a vertical unsqueeze of a

179

  // transposed 8x8 block (or 9x8 for one input).

180

111k

  static constexpr const size_t kRowsPerThread = 8;

181

111k

  const auto unsqueeze_span = [&](const uint32_t task,

182

111k

                                  size_t /* thread */) -> Status {

183

111k

    const size_t y0 = task * kRowsPerThread;

184

111k

    const size_t rows = std::min(kRowsPerThread, chin.h - y0);

185

111k

    size_t x = 0;

186

187

111k

#if HWY_TARGET != HWY_SCALAR

188

111k

    ptrdiff_t onerow_in = chin.plane.PixelsPerRow();

189

111k

    ptrdiff_t onerow_inr = chin_residual.plane.PixelsPerRow();

190

111k

    ptrdiff_t onerow_out = chout.plane.PixelsPerRow();

191

111k

    const pixel_type *JXL_RESTRICT p_residual = chin_residual.Row(y0);

192

111k

    const pixel_type *JXL_RESTRICT p_avg = chin.Row(y0);

193

111k

    pixel_type *JXL_RESTRICT p_out = chout.Row(y0);

194

111k

    HWY_ALIGN pixel_type b_p_avg[9 * kRowsPerThread];

195

111k

    HWY_ALIGN pixel_type b_p_residual[8 * kRowsPerThread];

196

111k

    HWY_ALIGN pixel_type b_p_out_even[8 * kRowsPerThread];

197

111k

    HWY_ALIGN pixel_type b_p_out_odd[8 * kRowsPerThread];

198

111k

    HWY_ALIGN pixel_type b_p_out_evenT[8 * kRowsPerThread];

199

111k

    HWY_ALIGN pixel_type b_p_out_oddT[8 * kRowsPerThread];

200

111k

    const size_t N = Lanes(d);

201

111k

    if (chin_residual.w > 16 && rows == kRowsPerThread) {

202

111k

      for (; x < chin_residual.w - 9; x += 8) {

203

111k

        Transpose8x8Block(p_residual + x, b_p_residual, onerow_inr);

204

111k

        Transpose8x8Block(p_avg + x, b_p_avg, onerow_in);

205

111k

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

206

111k

          b_p_avg[8 * 8 + y] = p_avg[x + 8 + onerow_in * y];

207

111k

        }

208

111k

        for (size_t i = 0; i < 8; i++) {

209

111k

          FastUnsqueeze(

210

111k

              b_p_residual + 8 * i, b_p_avg + 8 * i, b_p_avg + 8 * (i + 1),

211

111k

              (x + i ? b_p_out_odd + 8 * ((x + i - 1) & 7) : b_p_avg + 8 * i),

212

111k

              b_p_out_even + 8 * i, b_p_out_odd + 8 * i);

213

111k

        }

214

215

111k

        Transpose8x8Block(b_p_out_even, b_p_out_evenT, 8);

216

111k

        Transpose8x8Block(b_p_out_odd, b_p_out_oddT, 8);

217

111k

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

218

111k

          for (size_t i = 0; i < kRowsPerThread; i += N) {

219

111k

            auto even = Load(d, b_p_out_evenT + 8 * y + i);

220

111k

            auto odd = Load(d, b_p_out_oddT + 8 * y + i);

221

111k

            StoreInterleaved(d, even, odd,

222

111k

                             p_out + ((x + i) << 1) + onerow_out * y);

223

111k

          }

224

111k

        }

225

111k

      }

226

111k

    }

227

111k

#endif  // HWY_TARGET != HWY_SCALAR

228

111k

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

229

111k

      unsqueeze_row(y0 + y, x);

230

111k

    }

231

111k

    return true;

232

111k

  };

233

111k

  JXL_RETURN_IF_ERROR(RunOnPool(pool, 0, DivCeil(chin.h, kRowsPerThread),

234

111k

                                ThreadPool::NoInit, unsqueeze_span,

235

111k

                                "InvHorizontalSqueeze"));

236

111k

  input.channel[c] = std::move(chout);

237

111k

  return true;

238

111k

}

Unexecuted instantiation: jxl::N_SSE2::InvHSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)

Status InvVSqueeze(Image &input, uint32_t c, uint32_t rc, ThreadPool *pool) {

  JXL_ENSURE(c < input.channel.size());

  JXL_ENSURE(rc < input.channel.size());

  const Channel &chin = input.channel[c];

  const Channel &chin_residual = input.channel[rc];

  // These must be valid since we ran MetaApply already.

  JXL_ENSURE(chin.h == DivCeil(chin.h + chin_residual.h, 2));

  JXL_ENSURE(chin.w == chin_residual.w);

  JxlMemoryManager *memory_manager = input.memory_manager();

  if (chin_residual.h == 0) {

    // Short-circuit: output channel has same dimensions as input.

    input.channel[c].vshift--;

    return true;

  }

  // Note: chin.h >= chin_residual.h and at most 1 different.

  JXL_ASSIGN_OR_RETURN(

      Channel chout,

      Channel::Create(memory_manager, chin.w, chin.h + chin_residual.h,

                      chin.hshift, chin.vshift - 1));

  JXL_DEBUG_V(

      4,

      "Undoing vertical squeeze of channel %i using residuals in channel "

      "%i (going from height %" PRIuS " to %" PRIuS ")",

      c, rc, chin.h, chout.h);

  if (chin_residual.w == 0) {

    // Short-circuit: channel with no pixels.

    input.channel[c] = std::move(chout);

    return true;

  }

  static constexpr const int kColsPerThread = 64;

  const auto unsqueeze_slice = [&](const uint32_t task,

                                   size_t /* thread */) -> Status {

    const size_t x0 = task * kColsPerThread;

    const size_t x1 =

        std::min(static_cast<size_t>(task + 1) * kColsPerThread, chin.w);

    const size_t w = x1 - x0;

    // We only iterate up to std::min(chin_residual.h, chin.h) which is

    // always chin_residual.h.

    for (size_t y = 0; y < chin_residual.h; y++) {

      const pixel_type *JXL_RESTRICT p_residual = chin_residual.Row(y) + x0;

      const pixel_type *JXL_RESTRICT p_avg = chin.Row(y) + x0;

      const pixel_type *JXL_RESTRICT p_navg =

          chin.Row(y + 1 < chin.h ? y + 1 : y) + x0;

      pixel_type *JXL_RESTRICT p_out = chout.Row(y << 1) + x0;

      pixel_type *JXL_RESTRICT p_nout = chout.Row((y << 1) + 1) + x0;

      const pixel_type *p_pout = y > 0 ? chout.Row((y << 1) - 1) + x0 : p_avg;

      size_t x = 0;

#if HWY_TARGET != HWY_SCALAR

      for (; x + 7 < w; x += 8) {

        FastUnsqueeze(p_residual + x, p_avg + x, p_navg + x, p_pout + x,

                      p_out + x, p_nout + x);

      }

#endif

      for (; x < w; x++) {

        pixel_type_w avg = p_avg[x];

        pixel_type_w next_avg = p_navg[x];

        pixel_type_w top = p_pout[x];

        pixel_type_w tendency = SmoothTendency(top, avg, next_avg);

        pixel_type_w diff_minus_tendency = p_residual[x];

        pixel_type_w diff = diff_minus_tendency + tendency;

        pixel_type_w out = avg + (diff / 2);

        p_out[x] = out;

        // If the chin_residual.h == chin.h, the output has an even number

        // of rows so the next line is fine. Otherwise, this loop won't

        // write to the last output row which is handled separately.

        p_nout[x] = out - diff;

      }

    }

    return true;

  };

Unexecuted instantiation: squeeze.cc:jxl::N_SSE4::InvVSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)::$_0::operator()(unsigned int, unsigned long) const

squeeze.cc:jxl::N_AVX2::InvVSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)::$_0::operator()(unsigned int, unsigned long) const

Line

Count

Source

275

129k

                                   size_t /* thread */) -> Status {

276

129k

    const size_t x0 = task * kColsPerThread;

277

129k

    const size_t x1 =

278

129k

        std::min(static_cast<size_t>(task + 1) * kColsPerThread, chin.w);

279

129k

    const size_t w = x1 - x0;

280

    // We only iterate up to std::min(chin_residual.h, chin.h) which is

281

    // always chin_residual.h.

282

4.81M

    for (size_t y = 0; y < chin_residual.h; y++) {

283

4.69M

      const pixel_type *JXL_RESTRICT p_residual = chin_residual.Row(y) + x0;

284

4.69M

      const pixel_type *JXL_RESTRICT p_avg = chin.Row(y) + x0;

285

4.69M

      const pixel_type *JXL_RESTRICT p_navg =

286

4.69M

          chin.Row(y + 1 < chin.h ? y + 1 : y) + x0;

287

4.69M

      pixel_type *JXL_RESTRICT p_out = chout.Row(y << 1) + x0;

288

4.69M

      pixel_type *JXL_RESTRICT p_nout = chout.Row((y << 1) + 1) + x0;

289

4.69M

      const pixel_type *p_pout = y > 0 ? chout.Row((y << 1) - 1) + x0 : p_avg;

290

4.69M

      size_t x = 0;

291

4.69M

#if HWY_TARGET != HWY_SCALAR

292

32.0M

      for (; x + 7 < w; x += 8) {

293

27.3M

        FastUnsqueeze(p_residual + x, p_avg + x, p_navg + x, p_pout + x,

294

27.3M

                      p_out + x, p_nout + x);

295

27.3M

      }

296

4.69M

#endif

297

11.4M

      for (; x < w; x++) {

298

6.77M

        pixel_type_w avg = p_avg[x];

299

6.77M

        pixel_type_w next_avg = p_navg[x];

300

6.77M

        pixel_type_w top = p_pout[x];

301

6.77M

        pixel_type_w tendency = SmoothTendency(top, avg, next_avg);

302

6.77M

        pixel_type_w diff_minus_tendency = p_residual[x];

303

6.77M

        pixel_type_w diff = diff_minus_tendency + tendency;

304

6.77M

        pixel_type_w out = avg + (diff / 2);

305

6.77M

        p_out[x] = out;

306

        // If the chin_residual.h == chin.h, the output has an even number

307

        // of rows so the next line is fine. Otherwise, this loop won't

308

        // write to the last output row which is handled separately.

309

6.77M

        p_nout[x] = out - diff;

310

6.77M

      }

311

4.69M

    }

312

129k

    return true;

313

129k

  };

Unexecuted instantiation: squeeze.cc:jxl::N_SSE2::InvVSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)::$_0::operator()(unsigned int, unsigned long) const

  JXL_RETURN_IF_ERROR(RunOnPool(pool, 0, DivCeil(chin.w, kColsPerThread),

                                ThreadPool::NoInit, unsqueeze_slice,

                                "InvVertSqueeze"));

  if (chout.h & 1) {

    size_t y = chin.h - 1;

    const pixel_type *p_avg = chin.Row(y);

    pixel_type *p_out = chout.Row(y << 1);

    for (size_t x = 0; x < chin.w; x++) {

      p_out[x] = p_avg[x];

    }

  }

  input.channel[c] = std::move(chout);

  return true;

}

Unexecuted instantiation: jxl::N_SSE4::InvVSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)

jxl::N_AVX2::InvVSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)

Line

Count

Source

240

111k

Status InvVSqueeze(Image &input, uint32_t c, uint32_t rc, ThreadPool *pool) {

241

111k

  JXL_ENSURE(c < input.channel.size());

242

111k

  JXL_ENSURE(rc < input.channel.size());

243

111k

  const Channel &chin = input.channel[c];

244

111k

  const Channel &chin_residual = input.channel[rc];

245

  // These must be valid since we ran MetaApply already.

246

111k

  JXL_ENSURE(chin.h == DivCeil(chin.h + chin_residual.h, 2));

247

111k

  JXL_ENSURE(chin.w == chin_residual.w);

248

111k

  JxlMemoryManager *memory_manager = input.memory_manager();

249

250

111k

  if (chin_residual.h == 0) {

251

    // Short-circuit: output channel has same dimensions as input.

252

1.20k

    input.channel[c].vshift--;

253

1.20k

    return true;

254

1.20k

  }

255

256

  // Note: chin.h >= chin_residual.h and at most 1 different.

257

220k

  JXL_ASSIGN_OR_RETURN(

258

220k

      Channel chout,

259

220k

      Channel::Create(memory_manager, chin.w, chin.h + chin_residual.h,

260

220k

                      chin.hshift, chin.vshift - 1));

261

220k

  JXL_DEBUG_V(

262

220k

      4,

263

220k

      "Undoing vertical squeeze of channel %i using residuals in channel "

264

220k

      "%i (going from height %" PRIuS " to %" PRIuS ")",

265

220k

      c, rc, chin.h, chout.h);

266

267

220k

  if (chin_residual.w == 0) {

268

    // Short-circuit: channel with no pixels.

269

0

    input.channel[c] = std::move(chout);

270

0

    return true;

271

0

  }

272

273

110k

  static constexpr const int kColsPerThread = 64;

274

110k

  const auto unsqueeze_slice = [&](const uint32_t task,

275

110k

                                   size_t /* thread */) -> Status {

276

110k

    const size_t x0 = task * kColsPerThread;

277

110k

    const size_t x1 =

278

110k

        std::min(static_cast<size_t>(task + 1) * kColsPerThread, chin.w);

279

110k

    const size_t w = x1 - x0;

280

    // We only iterate up to std::min(chin_residual.h, chin.h) which is

281

    // always chin_residual.h.

282

110k

    for (size_t y = 0; y < chin_residual.h; y++) {

283

110k

      const pixel_type *JXL_RESTRICT p_residual = chin_residual.Row(y) + x0;

284

110k

      const pixel_type *JXL_RESTRICT p_avg = chin.Row(y) + x0;

285

110k

      const pixel_type *JXL_RESTRICT p_navg =

286

110k

          chin.Row(y + 1 < chin.h ? y + 1 : y) + x0;

287

110k

      pixel_type *JXL_RESTRICT p_out = chout.Row(y << 1) + x0;

288

110k

      pixel_type *JXL_RESTRICT p_nout = chout.Row((y << 1) + 1) + x0;

289

110k

      const pixel_type *p_pout = y > 0 ? chout.Row((y << 1) - 1) + x0 : p_avg;

290

110k

      size_t x = 0;

291

110k

#if HWY_TARGET != HWY_SCALAR

292

110k

      for (; x + 7 < w; x += 8) {

293

110k

        FastUnsqueeze(p_residual + x, p_avg + x, p_navg + x, p_pout + x,

294

110k

                      p_out + x, p_nout + x);

295

110k

      }

296

110k

#endif

297

110k

      for (; x < w; x++) {

298

110k

        pixel_type_w avg = p_avg[x];

299

110k

        pixel_type_w next_avg = p_navg[x];

300

110k

        pixel_type_w top = p_pout[x];

301

110k

        pixel_type_w tendency = SmoothTendency(top, avg, next_avg);

302

110k

        pixel_type_w diff_minus_tendency = p_residual[x];

303

110k

        pixel_type_w diff = diff_minus_tendency + tendency;

304

110k

        pixel_type_w out = avg + (diff / 2);

305

110k

        p_out[x] = out;

306

        // If the chin_residual.h == chin.h, the output has an even number

307

        // of rows so the next line is fine. Otherwise, this loop won't

308

        // write to the last output row which is handled separately.

309

110k

        p_nout[x] = out - diff;

310

110k

      }

311

110k

    }

312

110k

    return true;

313

110k

  };

314

110k

  JXL_RETURN_IF_ERROR(RunOnPool(pool, 0, DivCeil(chin.w, kColsPerThread),

315

110k

                                ThreadPool::NoInit, unsqueeze_slice,

316

110k

                                "InvVertSqueeze"));

317

318

110k

  if (chout.h & 1) {

319

23.4k

    size_t y = chin.h - 1;

320

23.4k

    const pixel_type *p_avg = chin.Row(y);

321

23.4k

    pixel_type *p_out = chout.Row(y << 1);

322

593k

    for (size_t x = 0; x < chin.w; x++) {

323

570k

      p_out[x] = p_avg[x];

324

570k

    }

325

23.4k

  }

326

110k

  input.channel[c] = std::move(chout);

327

110k

  return true;

328

110k

}

Unexecuted instantiation: jxl::N_SSE2::InvVSqueeze(jxl::Image&, unsigned int, unsigned int, jxl::ThreadPool*)

Status InvSqueeze(Image &input, const std::vector<SqueezeParams> &parameters,

                  ThreadPool *pool) {

  for (int i = parameters.size() - 1; i >= 0; i--) {

    JXL_RETURN_IF_ERROR(

        CheckMetaSqueezeParams(parameters[i], input.channel.size()));

    bool horizontal = parameters[i].horizontal;

    bool in_place = parameters[i].in_place;

    uint32_t beginc = parameters[i].begin_c;

    uint32_t endc = parameters[i].begin_c + parameters[i].num_c - 1;

    uint32_t offset;

    if (in_place) {

      offset = endc + 1;

    } else {

      offset = input.channel.size() + beginc - endc - 1;

    }

    if (beginc < input.nb_meta_channels) {

      // This is checked in MetaSqueeze.

      JXL_ENSURE(input.nb_meta_channels > parameters[i].num_c);

      input.nb_meta_channels -= parameters[i].num_c;

    }

    for (uint32_t c = beginc; c <= endc; c++) {

      uint32_t rc = offset + c - beginc;

      // MetaApply should imply that `rc` is within range, otherwise there's a

      // programming bug.

      JXL_ENSURE(rc < input.channel.size());

      if ((input.channel[c].w < input.channel[rc].w) ||

          (input.channel[c].h < input.channel[rc].h)) {

        return JXL_FAILURE("Corrupted squeeze transform");

      }

      if (horizontal) {

        JXL_RETURN_IF_ERROR(InvHSqueeze(input, c, rc, pool));

      } else {

        JXL_RETURN_IF_ERROR(InvVSqueeze(input, c, rc, pool));

      }

    }

    input.channel.erase(input.channel.begin() + offset,

                        input.channel.begin() + offset + (endc - beginc + 1));

  }

  return true;

}

Unexecuted instantiation: jxl::N_SSE4::InvSqueeze(jxl::Image&, std::__1::vector<jxl::SqueezeParams, std::__1::allocator<jxl::SqueezeParams> > const&, jxl::ThreadPool*)

jxl::N_AVX2::InvSqueeze(jxl::Image&, std::__1::vector<jxl::SqueezeParams, std::__1::allocator<jxl::SqueezeParams> > const&, jxl::ThreadPool*)

Line

Count

Source

331

15.8k

                  ThreadPool *pool) {

332

85.5k

  for (int i = parameters.size() - 1; i >= 0; i--) {

333

69.7k

    JXL_RETURN_IF_ERROR(

334

69.7k

        CheckMetaSqueezeParams(parameters[i], input.channel.size()));

335

69.7k

    bool horizontal = parameters[i].horizontal;

336

69.7k

    bool in_place = parameters[i].in_place;

337

69.7k

    uint32_t beginc = parameters[i].begin_c;

338

69.7k

    uint32_t endc = parameters[i].begin_c + parameters[i].num_c - 1;

339

69.7k

    uint32_t offset;

340

69.7k

    if (in_place) {

341

45.8k

      offset = endc + 1;

342

45.8k

    } else {

343

23.8k

      offset = input.channel.size() + beginc - endc - 1;

344

23.8k

    }

345

69.7k

    if (beginc < input.nb_meta_channels) {

346

      // This is checked in MetaSqueeze.

347

14

      JXL_ENSURE(input.nb_meta_channels > parameters[i].num_c);

348

14

      input.nb_meta_channels -= parameters[i].num_c;

349

14

    }

350

351

294k

    for (uint32_t c = beginc; c <= endc; c++) {

352

224k

      uint32_t rc = offset + c - beginc;

353

      // MetaApply should imply that `rc` is within range, otherwise there's a

354

      // programming bug.

355

224k

      JXL_ENSURE(rc < input.channel.size());

356

224k

      if ((input.channel[c].w < input.channel[rc].w) ||

357

224k

          (input.channel[c].h < input.channel[rc].h)) {

358

0

        return JXL_FAILURE("Corrupted squeeze transform");

359

0

      }

360

224k

      if (horizontal) {

361

113k

        JXL_RETURN_IF_ERROR(InvHSqueeze(input, c, rc, pool));

362

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      } else {

363

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        JXL_RETURN_IF_ERROR(InvVSqueeze(input, c, rc, pool));

364

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      }

365

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    }

366

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    input.channel.erase(input.channel.begin() + offset,

367

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                        input.channel.begin() + offset + (endc - beginc + 1));

368

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  }

369

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  return true;

370

15.8k

}

Unexecuted instantiation: jxl::N_SSE2::InvSqueeze(jxl::Image&, std::__1::vector<jxl::SqueezeParams, std::__1::allocator<jxl::SqueezeParams> > const&, jxl::ThreadPool*)

}  // namespace HWY_NAMESPACE

}  // namespace jxl

HWY_AFTER_NAMESPACE();

#if HWY_ONCE

namespace jxl {

HWY_EXPORT(InvSqueeze);

Status InvSqueeze(Image &input, const std::vector<SqueezeParams> &parameters,

                  ThreadPool *pool) {

  return HWY_DYNAMIC_DISPATCH(InvSqueeze)(input, parameters, pool);

}

void DefaultSqueezeParameters(std::vector<SqueezeParams> *parameters,

                              const Image &image) {

  int nb_channels = image.channel.size() - image.nb_meta_channels;

  parameters->clear();

  size_t w = image.channel[image.nb_meta_channels].w;

  size_t h = image.channel[image.nb_meta_channels].h;

  JXL_DEBUG_V(

      7, "Default squeeze parameters for %" PRIuS "x%" PRIuS " image: ", w, h);

  // do horizontal first on wide images; vertical first on tall images

  bool wide = (w > h);

  if (nb_channels > 2 && image.channel[image.nb_meta_channels + 1].w == w &&

      image.channel[image.nb_meta_channels + 1].h == h) {

    // assume channels 1 and 2 are chroma, and can be squeezed first for 4:2:0

    // previews

    JXL_DEBUG_V(7, "(4:2:0 chroma), %" PRIuS "x%" PRIuS " image", w, h);

    SqueezeParams params;

    // horizontal chroma squeeze

    params.horizontal = true;

    params.in_place = false;

    params.begin_c = image.nb_meta_channels + 1;

    params.num_c = 2;

    parameters->push_back(params);

    params.horizontal = false;

    // vertical chroma squeeze

    parameters->push_back(params);

  }

  SqueezeParams params;

  params.begin_c = image.nb_meta_channels;

  params.num_c = nb_channels;

  params.in_place = true;

  if (!wide) {

    if (h > kMaxFirstPreviewSize) {

      params.horizontal = false;

      parameters->push_back(params);

      h = (h + 1) / 2;

      JXL_DEBUG_V(7, "Vertical (%" PRIuS "x%" PRIuS "), ", w, h);

    }

  }

  while (w > kMaxFirstPreviewSize || h > kMaxFirstPreviewSize) {

    if (w > kMaxFirstPreviewSize) {

      params.horizontal = true;

      parameters->push_back(params);

      w = (w + 1) / 2;

      JXL_DEBUG_V(7, "Horizontal (%" PRIuS "x%" PRIuS "), ", w, h);

    }

    if (h > kMaxFirstPreviewSize) {

      params.horizontal = false;

      parameters->push_back(params);

      h = (h + 1) / 2;

      JXL_DEBUG_V(7, "Vertical (%" PRIuS "x%" PRIuS "), ", w, h);

    }

  }

  JXL_DEBUG_V(7, "that's it");

}

Status CheckMetaSqueezeParams(const SqueezeParams &parameter,

                              int num_channels) {

  int c1 = parameter.begin_c;

  int c2 = parameter.begin_c + parameter.num_c - 1;

  if (c1 < 0 || c1 >= num_channels || c2 < 0 || c2 >= num_channels || c2 < c1) {

    return JXL_FAILURE("Invalid channel range");

  }

  return true;

}

Status MetaSqueeze(Image &image, std::vector<SqueezeParams> *parameters) {

  JxlMemoryManager *memory_manager = image.memory_manager();

  if (parameters->empty()) {

    DefaultSqueezeParameters(parameters, image);

  }

  for (auto &parameter : *parameters) {

    JXL_RETURN_IF_ERROR(

        CheckMetaSqueezeParams(parameter, image.channel.size()));

    bool horizontal = parameter.horizontal;

    bool in_place = parameter.in_place;

    uint32_t beginc = parameter.begin_c;

    uint32_t endc = parameter.begin_c + parameter.num_c - 1;

    uint32_t offset;

    if (beginc < image.nb_meta_channels) {

      if (endc >= image.nb_meta_channels) {

        return JXL_FAILURE("Invalid squeeze: mix of meta and nonmeta channels");

      }

      if (!in_place) {

        return JXL_FAILURE(

            "Invalid squeeze: meta channels require in-place residuals");

      }

      image.nb_meta_channels += parameter.num_c;

    }

    if (in_place) {

      offset = endc + 1;

    } else {

      offset = image.channel.size();

    }

    for (uint32_t c = beginc; c <= endc; c++) {

      if (image.channel[c].hshift > 30 || image.channel[c].vshift > 30) {

        return JXL_FAILURE("Too many squeezes: shift > 30");

      }

      size_t w = image.channel[c].w;

      size_t h = image.channel[c].h;

      if (w == 0 || h == 0) return JXL_FAILURE("Squeezing empty channel");

      if (horizontal) {

        image.channel[c].w = (w + 1) / 2;

        if (image.channel[c].hshift >= 0) image.channel[c].hshift++;

        w = w - (w + 1) / 2;

      } else {

        image.channel[c].h = (h + 1) / 2;

        if (image.channel[c].vshift >= 0) image.channel[c].vshift++;

        h = h - (h + 1) / 2;

      }

      JXL_RETURN_IF_ERROR(image.channel[c].shrink());

      JXL_ASSIGN_OR_RETURN(Channel placeholder,

                           Channel::Create(memory_manager, w, h));

      placeholder.hshift = image.channel[c].hshift;

      placeholder.vshift = image.channel[c].vshift;

      placeholder.component = image.channel[c].component;

      image.channel.insert(image.channel.begin() + offset + (c - beginc),

                           std::move(placeholder));

      JXL_DEBUG_V(0, "MetaSqueeze applied, current image: %s",

                  image.DebugString().c_str());

    }

  }

  return true;

}

}  // namespace jxl

#endif