Coverage Report

Created: 2026-04-01 07:24

next uncovered line (L), next uncovered region (R), next uncovered branch (B)
/src/libjxl/lib/jxl/base/rational_polynomial-inl.h
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// Copyright (c) the JPEG XL Project Authors. All rights reserved.
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//
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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// Fast SIMD evaluation of rational polynomials for approximating functions.
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#if defined(LIB_JXL_BASE_RATIONAL_POLYNOMIAL_INL_H_) == \
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    defined(HWY_TARGET_TOGGLE)
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#ifdef LIB_JXL_BASE_RATIONAL_POLYNOMIAL_INL_H_
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#undef LIB_JXL_BASE_RATIONAL_POLYNOMIAL_INL_H_
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#else
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#define LIB_JXL_BASE_RATIONAL_POLYNOMIAL_INL_H_
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#endif
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#include <jxl/types.h>
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#include <stddef.h>
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#include <hwy/highway.h>
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HWY_BEFORE_NAMESPACE();
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namespace jxl {
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namespace HWY_NAMESPACE {
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namespace {
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// These templates are not found via ADL.
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using hwy::HWY_NAMESPACE::ApproximateReciprocal;
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using hwy::HWY_NAMESPACE::Div;
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using hwy::HWY_NAMESPACE::MulAdd;
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// Primary template: default to actual division.
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template <typename T, class V>
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struct FastDivision {
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  HWY_INLINE V operator()(const V n, const V d) const { return n / d; }
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};
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// Partial specialization for float vectors.
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template <class V>
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struct FastDivision<float, V> {
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  // One Newton-Raphson iteration.
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  static HWY_INLINE V ReciprocalNR(const V x) {
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    const auto rcp = ApproximateReciprocal(x);
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    const auto sum = Add(rcp, rcp);
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    const auto x_rcp = Mul(x, rcp);
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    return NegMulAdd(x_rcp, rcp, sum);
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  }
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46
147M
  V operator()(const V n, const V d) const {
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#if JXL_TRUE  // Faster on SKX
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147M
    return Div(n, d);
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#else
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    return n * ReciprocalNR(d);
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#endif
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147M
  }
quant_weights.cc:jxl::N_SCALAR::(anonymous namespace)::FastDivision<float, hwy::N_SCALAR::Vec1<float> >::operator()(hwy::N_SCALAR::Vec1<float>, hwy::N_SCALAR::Vec1<float>) const
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46
3.48M
  V operator()(const V n, const V d) const {
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#if JXL_TRUE  // Faster on SKX
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3.48M
    return Div(n, d);
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#else
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    return n * ReciprocalNR(d);
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#endif
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3.48M
  }
Unexecuted instantiation: enc_xyb.cc:jxl::N_SCALAR::(anonymous namespace)::FastDivision<float, hwy::N_SCALAR::Vec1<float> >::operator()(hwy::N_SCALAR::Vec1<float>, hwy::N_SCALAR::Vec1<float>) const
Unexecuted instantiation: enc_ma.cc:jxl::N_SCALAR::(anonymous namespace)::FastDivision<float, hwy::N_SCALAR::Vec1<float> >::operator()(hwy::N_SCALAR::Vec1<float>, hwy::N_SCALAR::Vec1<float>) const
stage_from_linear.cc:jxl::N_SCALAR::(anonymous namespace)::FastDivision<float, hwy::N_SCALAR::Vec1<float> >::operator()(hwy::N_SCALAR::Vec1<float>, hwy::N_SCALAR::Vec1<float>) const
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46
137M
  V operator()(const V n, const V d) const {
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#if JXL_TRUE  // Faster on SKX
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137M
    return Div(n, d);
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#else
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    return n * ReciprocalNR(d);
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#endif
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137M
  }
Unexecuted instantiation: stage_to_linear.cc:jxl::N_SCALAR::(anonymous namespace)::FastDivision<float, hwy::N_SCALAR::Vec1<float> >::operator()(hwy::N_SCALAR::Vec1<float>, hwy::N_SCALAR::Vec1<float>) const
Unexecuted instantiation: stage_tone_mapping.cc:jxl::N_SCALAR::(anonymous namespace)::FastDivision<float, hwy::N_SCALAR::Vec1<float> >::operator()(hwy::N_SCALAR::Vec1<float>, hwy::N_SCALAR::Vec1<float>) const
Unexecuted instantiation: splines.cc:jxl::N_SCALAR::(anonymous namespace)::FastDivision<float, hwy::N_SCALAR::Vec1<float> >::operator()(hwy::N_SCALAR::Vec1<float>, hwy::N_SCALAR::Vec1<float>) const
Unexecuted instantiation: butteraugli.cc:jxl::N_SCALAR::(anonymous namespace)::FastDivision<float, hwy::N_SCALAR::Vec1<float> >::operator()(hwy::N_SCALAR::Vec1<float>, hwy::N_SCALAR::Vec1<float>) const
Unexecuted instantiation: enc_ac_strategy.cc:jxl::N_SCALAR::(anonymous namespace)::FastDivision<float, hwy::N_SCALAR::Vec1<float> >::operator()(hwy::N_SCALAR::Vec1<float>, hwy::N_SCALAR::Vec1<float>) const
Unexecuted instantiation: enc_adaptive_quantization.cc:jxl::N_SCALAR::(anonymous namespace)::FastDivision<float, hwy::N_SCALAR::Vec1<float> >::operator()(hwy::N_SCALAR::Vec1<float>, hwy::N_SCALAR::Vec1<float>) const
Unexecuted instantiation: enc_cluster.cc:jxl::N_SCALAR::(anonymous namespace)::FastDivision<float, hwy::N_SCALAR::Vec1<float> >::operator()(hwy::N_SCALAR::Vec1<float>, hwy::N_SCALAR::Vec1<float>) const
Unexecuted instantiation: enc_lz77.cc:jxl::N_SCALAR::(anonymous namespace)::FastDivision<float, hwy::N_SCALAR::Vec1<float> >::operator()(hwy::N_SCALAR::Vec1<float>, hwy::N_SCALAR::Vec1<float>) const
jxl_cms.cc:jxl::N_SCALAR::(anonymous namespace)::FastDivision<float, hwy::N_SCALAR::Vec1<float> >::operator()(hwy::N_SCALAR::Vec1<float>, hwy::N_SCALAR::Vec1<float>) const
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46
6.25M
  V operator()(const V n, const V d) const {
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#if JXL_TRUE  // Faster on SKX
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6.25M
    return Div(n, d);
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#else
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    return n * ReciprocalNR(d);
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#endif
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6.25M
  }
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};
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// Approximates smooth functions via rational polynomials (i.e. dividing two
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// polynomials). Evaluates polynomials via Horner's scheme, which is faster than
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// Clenshaw recurrence for Chebyshev polynomials. LoadDup128 allows us to
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// specify constants (replicated 4x) independently of the lane count.
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template <size_t NP, size_t NQ, class D, class V, typename T>
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HWY_INLINE HWY_MAYBE_UNUSED V EvalRationalPolynomial(const D d, const V x,
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                                                     const T (&p)[NP],
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147M
                                                     const T (&q)[NQ]) {
63
147M
  constexpr size_t kDegP = NP / 4 - 1;
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147M
  constexpr size_t kDegQ = NQ / 4 - 1;
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147M
  auto yp = LoadDup128(d, &p[kDegP * 4]);
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147M
  auto yq = LoadDup128(d, &q[kDegQ * 4]);
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  // We use pointer arithmetic to refer to &p[(kDegP - n) * 4] to avoid a
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  // compiler warning that the index is out of bounds since we are already
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  // checking that it is not out of bounds with (kDegP >= n) and the access
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  // will be optimized away. Similarly with q and kDegQ.
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147M
  HWY_FENCE;
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147M
  if (kDegP >= 1) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 1) * 4)));
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147M
  if (kDegQ >= 1) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 1) * 4)));
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147M
  HWY_FENCE;
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147M
  if (kDegP >= 2) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 2) * 4)));
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147M
  if (kDegQ >= 2) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 2) * 4)));
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147M
  HWY_FENCE;
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147M
  if (kDegP >= 3) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 3) * 4)));
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147M
  if (kDegQ >= 3) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 3) * 4)));
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147M
  HWY_FENCE;
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147M
  if (kDegP >= 4) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 4) * 4)));
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147M
  if (kDegQ >= 4) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 4) * 4)));
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147M
  HWY_FENCE;
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147M
  if (kDegP >= 5) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 5) * 4)));
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147M
  if (kDegQ >= 5) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 5) * 4)));
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147M
  HWY_FENCE;
87
147M
  if (kDegP >= 6) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 6) * 4)));
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147M
  if (kDegQ >= 6) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 6) * 4)));
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147M
  HWY_FENCE;
90
147M
  if (kDegP >= 7) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 7) * 4)));
91
147M
  if (kDegQ >= 7) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 7) * 4)));
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93
147M
  static_assert(kDegP < 8, "Polynomial degree is too high");
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147M
  static_assert(kDegQ < 8, "Polynomial degree is too high");
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147M
  return FastDivision<T, V>()(yp, yq);
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147M
}
quant_weights.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<12ul, 12ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [12ul], float const (&) [12ul])
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62
3.48M
                                                     const T (&q)[NQ]) {
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3.48M
  constexpr size_t kDegP = NP / 4 - 1;
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3.48M
  constexpr size_t kDegQ = NQ / 4 - 1;
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3.48M
  auto yp = LoadDup128(d, &p[kDegP * 4]);
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3.48M
  auto yq = LoadDup128(d, &q[kDegQ * 4]);
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  // We use pointer arithmetic to refer to &p[(kDegP - n) * 4] to avoid a
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  // compiler warning that the index is out of bounds since we are already
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  // checking that it is not out of bounds with (kDegP >= n) and the access
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  // will be optimized away. Similarly with q and kDegQ.
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3.48M
  HWY_FENCE;
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3.48M
  if (kDegP >= 1) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 1) * 4)));
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3.48M
  if (kDegQ >= 1) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 1) * 4)));
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3.48M
  HWY_FENCE;
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3.48M
  if (kDegP >= 2) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 2) * 4)));
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3.48M
  if (kDegQ >= 2) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 2) * 4)));
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3.48M
  HWY_FENCE;
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3.48M
  if (kDegP >= 3) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 3) * 4)));
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3.48M
  if (kDegQ >= 3) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 3) * 4)));
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3.48M
  HWY_FENCE;
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3.48M
  if (kDegP >= 4) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 4) * 4)));
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3.48M
  if (kDegQ >= 4) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 4) * 4)));
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3.48M
  HWY_FENCE;
84
3.48M
  if (kDegP >= 5) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 5) * 4)));
85
3.48M
  if (kDegQ >= 5) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 5) * 4)));
86
3.48M
  HWY_FENCE;
87
3.48M
  if (kDegP >= 6) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 6) * 4)));
88
3.48M
  if (kDegQ >= 6) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 6) * 4)));
89
3.48M
  HWY_FENCE;
90
3.48M
  if (kDegP >= 7) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 7) * 4)));
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3.48M
  if (kDegQ >= 7) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 7) * 4)));
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93
3.48M
  static_assert(kDegP < 8, "Polynomial degree is too high");
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3.48M
  static_assert(kDegQ < 8, "Polynomial degree is too high");
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96
3.48M
  return FastDivision<T, V>()(yp, yq);
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3.48M
}
Unexecuted instantiation: enc_xyb.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<20ul, 20ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [20ul], float const (&) [20ul])
Unexecuted instantiation: enc_xyb.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<12ul, 12ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [12ul], float const (&) [12ul])
Unexecuted instantiation: enc_ma.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<12ul, 12ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [12ul], float const (&) [12ul])
stage_from_linear.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<20ul, 20ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [20ul], float const (&) [20ul])
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62
137M
                                                     const T (&q)[NQ]) {
63
137M
  constexpr size_t kDegP = NP / 4 - 1;
64
137M
  constexpr size_t kDegQ = NQ / 4 - 1;
65
137M
  auto yp = LoadDup128(d, &p[kDegP * 4]);
66
137M
  auto yq = LoadDup128(d, &q[kDegQ * 4]);
67
  // We use pointer arithmetic to refer to &p[(kDegP - n) * 4] to avoid a
68
  // compiler warning that the index is out of bounds since we are already
69
  // checking that it is not out of bounds with (kDegP >= n) and the access
70
  // will be optimized away. Similarly with q and kDegQ.
71
137M
  HWY_FENCE;
72
137M
  if (kDegP >= 1) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 1) * 4)));
73
137M
  if (kDegQ >= 1) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 1) * 4)));
74
137M
  HWY_FENCE;
75
137M
  if (kDegP >= 2) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 2) * 4)));
76
137M
  if (kDegQ >= 2) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 2) * 4)));
77
137M
  HWY_FENCE;
78
137M
  if (kDegP >= 3) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 3) * 4)));
79
137M
  if (kDegQ >= 3) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 3) * 4)));
80
137M
  HWY_FENCE;
81
137M
  if (kDegP >= 4) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 4) * 4)));
82
137M
  if (kDegQ >= 4) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 4) * 4)));
83
137M
  HWY_FENCE;
84
137M
  if (kDegP >= 5) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 5) * 4)));
85
137M
  if (kDegQ >= 5) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 5) * 4)));
86
137M
  HWY_FENCE;
87
137M
  if (kDegP >= 6) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 6) * 4)));
88
137M
  if (kDegQ >= 6) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 6) * 4)));
89
137M
  HWY_FENCE;
90
137M
  if (kDegP >= 7) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 7) * 4)));
91
137M
  if (kDegQ >= 7) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 7) * 4)));
92
93
137M
  static_assert(kDegP < 8, "Polynomial degree is too high");
94
137M
  static_assert(kDegQ < 8, "Polynomial degree is too high");
95
96
137M
  return FastDivision<T, V>()(yp, yq);
97
137M
}
Unexecuted instantiation: stage_from_linear.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<12ul, 12ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [12ul], float const (&) [12ul])
Unexecuted instantiation: stage_to_linear.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<20ul, 20ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [20ul], float const (&) [20ul])
Unexecuted instantiation: stage_to_linear.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<12ul, 12ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [12ul], float const (&) [12ul])
Unexecuted instantiation: stage_tone_mapping.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<20ul, 20ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [20ul], float const (&) [20ul])
Unexecuted instantiation: stage_tone_mapping.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<12ul, 12ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [12ul], float const (&) [12ul])
Unexecuted instantiation: splines.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<12ul, 12ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [12ul], float const (&) [12ul])
Unexecuted instantiation: butteraugli.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<12ul, 12ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [12ul], float const (&) [12ul])
Unexecuted instantiation: enc_ac_strategy.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<12ul, 12ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [12ul], float const (&) [12ul])
Unexecuted instantiation: enc_adaptive_quantization.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<12ul, 12ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [12ul], float const (&) [12ul])
Unexecuted instantiation: enc_cluster.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<12ul, 12ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [12ul], float const (&) [12ul])
Unexecuted instantiation: enc_lz77.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<12ul, 12ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [12ul], float const (&) [12ul])
jxl_cms.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<20ul, 20ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [20ul], float const (&) [20ul])
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62
6.25M
                                                     const T (&q)[NQ]) {
63
6.25M
  constexpr size_t kDegP = NP / 4 - 1;
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6.25M
  constexpr size_t kDegQ = NQ / 4 - 1;
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6.25M
  auto yp = LoadDup128(d, &p[kDegP * 4]);
66
6.25M
  auto yq = LoadDup128(d, &q[kDegQ * 4]);
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  // We use pointer arithmetic to refer to &p[(kDegP - n) * 4] to avoid a
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  // compiler warning that the index is out of bounds since we are already
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  // checking that it is not out of bounds with (kDegP >= n) and the access
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  // will be optimized away. Similarly with q and kDegQ.
71
6.25M
  HWY_FENCE;
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6.25M
  if (kDegP >= 1) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 1) * 4)));
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6.25M
  if (kDegQ >= 1) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 1) * 4)));
74
6.25M
  HWY_FENCE;
75
6.25M
  if (kDegP >= 2) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 2) * 4)));
76
6.25M
  if (kDegQ >= 2) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 2) * 4)));
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6.25M
  HWY_FENCE;
78
6.25M
  if (kDegP >= 3) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 3) * 4)));
79
6.25M
  if (kDegQ >= 3) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 3) * 4)));
80
6.25M
  HWY_FENCE;
81
6.25M
  if (kDegP >= 4) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 4) * 4)));
82
6.25M
  if (kDegQ >= 4) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 4) * 4)));
83
6.25M
  HWY_FENCE;
84
6.25M
  if (kDegP >= 5) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 5) * 4)));
85
6.25M
  if (kDegQ >= 5) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 5) * 4)));
86
6.25M
  HWY_FENCE;
87
6.25M
  if (kDegP >= 6) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 6) * 4)));
88
6.25M
  if (kDegQ >= 6) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 6) * 4)));
89
6.25M
  HWY_FENCE;
90
6.25M
  if (kDegP >= 7) yp = MulAdd(yp, x, LoadDup128(d, p + ((kDegP - 7) * 4)));
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6.25M
  if (kDegQ >= 7) yq = MulAdd(yq, x, LoadDup128(d, q + ((kDegQ - 7) * 4)));
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93
6.25M
  static_assert(kDegP < 8, "Polynomial degree is too high");
94
6.25M
  static_assert(kDegQ < 8, "Polynomial degree is too high");
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96
6.25M
  return FastDivision<T, V>()(yp, yq);
97
6.25M
}
Unexecuted instantiation: jxl_cms.cc:hwy::N_SCALAR::Vec1<float> jxl::N_SCALAR::(anonymous namespace)::EvalRationalPolynomial<12ul, 12ul, hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float>(hwy::N_SCALAR::Simd<float, 1ul, 0>, hwy::N_SCALAR::Vec1<float>, float const (&) [12ul], float const (&) [12ul])
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}  // namespace
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// NOLINTNEXTLINE(google-readability-namespace-comments)
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}  // namespace HWY_NAMESPACE
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}  // namespace jxl
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HWY_AFTER_NAMESPACE();
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#endif  // LIB_JXL_BASE_RATIONAL_POLYNOMIAL_INL_H_