diff options
author | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-07 17:32:43 +0000 |
---|---|---|
committer | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-07 17:32:43 +0000 |
commit | 6bf0a5cb5034a7e684dcc3500e841785237ce2dd (patch) | |
tree | a68f146d7fa01f0134297619fbe7e33db084e0aa /third_party/jpeg-xl/lib/jxl/enc_color_management.cc | |
parent | Initial commit. (diff) | |
download | thunderbird-6bf0a5cb5034a7e684dcc3500e841785237ce2dd.tar.xz thunderbird-6bf0a5cb5034a7e684dcc3500e841785237ce2dd.zip |
Adding upstream version 1:115.7.0.upstream/1%115.7.0upstream
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to '')
-rw-r--r-- | third_party/jpeg-xl/lib/jxl/enc_color_management.cc | 1293 |
1 files changed, 1293 insertions, 0 deletions
diff --git a/third_party/jpeg-xl/lib/jxl/enc_color_management.cc b/third_party/jpeg-xl/lib/jxl/enc_color_management.cc new file mode 100644 index 0000000000..8a23ead473 --- /dev/null +++ b/third_party/jpeg-xl/lib/jxl/enc_color_management.cc @@ -0,0 +1,1293 @@ +// 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/enc_color_management.h" + +#ifndef JPEGXL_ENABLE_SKCMS +#define JPEGXL_ENABLE_SKCMS 0 +#endif + +#include <math.h> +#include <stdint.h> +#include <stdlib.h> +#include <string.h> + +#include <algorithm> +#include <array> +#include <atomic> +#include <memory> +#include <string> +#include <utility> + +#undef HWY_TARGET_INCLUDE +#define HWY_TARGET_INCLUDE "lib/jxl/enc_color_management.cc" +#include <hwy/foreach_target.h> +#include <hwy/highway.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/field_encodings.h" +#include "lib/jxl/matrix_ops.h" +#include "lib/jxl/transfer_functions-inl.h" +#if JPEGXL_ENABLE_SKCMS +#include "lib/jxl/enc_jxl_skcms.h" +#else // JPEGXL_ENABLE_SKCMS +#include "lcms2.h" +#include "lcms2_plugin.h" +#endif // JPEGXL_ENABLE_SKCMS + +#define JXL_CMS_VERBOSE 0 + +// Define these only once. We can't use HWY_ONCE here because it is defined as +// 1 only on the last pass. +#ifndef LIB_JXL_ENC_COLOR_MANAGEMENT_CC_ +#define LIB_JXL_ENC_COLOR_MANAGEMENT_CC_ + +namespace jxl { +namespace { +struct JxlCms { +#if JPEGXL_ENABLE_SKCMS + PaddedBytes icc_src, icc_dst; + skcms_ICCProfile profile_src, profile_dst; +#else + void* lcms_transform; +#endif + + // These fields are used when the HLG OOTF or inverse OOTF must be applied. + bool apply_hlg_ootf; + size_t hlg_ootf_num_channels; + // Y component of the primaries. + std::array<float, 3> hlg_ootf_luminances; + + size_t channels_src; + size_t channels_dst; + ImageF buf_src; + ImageF buf_dst; + float intensity_target; + bool skip_lcms = false; + ExtraTF preprocess = ExtraTF::kNone; + ExtraTF postprocess = ExtraTF::kNone; +}; + +Status ApplyHlgOotf(JxlCms* t, float* JXL_RESTRICT buf, size_t xsize, + bool forward); +} // namespace +} // namespace jxl + +#endif // LIB_JXL_ENC_COLOR_MANAGEMENT_CC_ + +HWY_BEFORE_NAMESPACE(); +namespace jxl { +namespace HWY_NAMESPACE { + +#if JXL_CMS_VERBOSE >= 2 +const size_t kX = 0; // pixel index, multiplied by 3 for RGB +#endif + +// xform_src = UndoGammaCompression(buf_src). +Status BeforeTransform(JxlCms* t, const float* buf_src, float* xform_src, + size_t buf_size) { + switch (t->preprocess) { + case ExtraTF::kNone: + JXL_DASSERT(false); // unreachable + break; + + case ExtraTF::kPQ: { + // By default, PQ content has an intensity target of 10000, stored + // exactly. + HWY_FULL(float) df; + const auto multiplier = Set(df, t->intensity_target == 10000.f + ? 1.0f + : 10000.f / t->intensity_target); + for (size_t i = 0; i < buf_size; i += Lanes(df)) { + const auto val = Load(df, buf_src + i); + const auto result = + Mul(multiplier, TF_PQ().DisplayFromEncoded(df, val)); + Store(result, df, xform_src + i); + } +#if JXL_CMS_VERBOSE >= 2 + printf("pre in %.4f %.4f %.4f undoPQ %.4f %.4f %.4f\n", buf_src[3 * kX], + buf_src[3 * kX + 1], buf_src[3 * kX + 2], xform_src[3 * kX], + xform_src[3 * kX + 1], xform_src[3 * kX + 2]); +#endif + break; + } + + case ExtraTF::kHLG: + for (size_t i = 0; i < buf_size; ++i) { + xform_src[i] = static_cast<float>( + TF_HLG().DisplayFromEncoded(static_cast<double>(buf_src[i]))); + } + if (t->apply_hlg_ootf) { + JXL_RETURN_IF_ERROR( + ApplyHlgOotf(t, xform_src, buf_size, /*forward=*/true)); + } +#if JXL_CMS_VERBOSE >= 2 + printf("pre in %.4f %.4f %.4f undoHLG %.4f %.4f %.4f\n", buf_src[3 * kX], + buf_src[3 * kX + 1], buf_src[3 * kX + 2], xform_src[3 * kX], + xform_src[3 * kX + 1], xform_src[3 * kX + 2]); +#endif + break; + + case ExtraTF::kSRGB: + HWY_FULL(float) df; + for (size_t i = 0; i < buf_size; i += Lanes(df)) { + const auto val = Load(df, buf_src + i); + const auto result = TF_SRGB().DisplayFromEncoded(val); + Store(result, df, xform_src + i); + } +#if JXL_CMS_VERBOSE >= 2 + printf("pre in %.4f %.4f %.4f undoSRGB %.4f %.4f %.4f\n", buf_src[3 * kX], + buf_src[3 * kX + 1], buf_src[3 * kX + 2], xform_src[3 * kX], + xform_src[3 * kX + 1], xform_src[3 * kX + 2]); +#endif + break; + } + return true; +} + +// Applies gamma compression in-place. +Status AfterTransform(JxlCms* t, float* JXL_RESTRICT buf_dst, size_t buf_size) { + switch (t->postprocess) { + case ExtraTF::kNone: + JXL_DASSERT(false); // unreachable + break; + case ExtraTF::kPQ: { + HWY_FULL(float) df; + const auto multiplier = + Set(df, t->intensity_target == 10000.f ? 1.0f + : t->intensity_target * 1e-4f); + for (size_t i = 0; i < buf_size; i += Lanes(df)) { + const auto val = Load(df, buf_dst + i); + const auto result = + TF_PQ().EncodedFromDisplay(df, Mul(multiplier, val)); + Store(result, df, buf_dst + i); + } +#if JXL_CMS_VERBOSE >= 2 + printf("after PQ enc %.4f %.4f %.4f\n", buf_dst[3 * kX], + buf_dst[3 * kX + 1], buf_dst[3 * kX + 2]); +#endif + break; + } + case ExtraTF::kHLG: + if (t->apply_hlg_ootf) { + JXL_RETURN_IF_ERROR( + ApplyHlgOotf(t, buf_dst, buf_size, /*forward=*/false)); + } + for (size_t i = 0; i < buf_size; ++i) { + buf_dst[i] = static_cast<float>( + TF_HLG().EncodedFromDisplay(static_cast<double>(buf_dst[i]))); + } +#if JXL_CMS_VERBOSE >= 2 + printf("after HLG enc %.4f %.4f %.4f\n", buf_dst[3 * kX], + buf_dst[3 * kX + 1], buf_dst[3 * kX + 2]); +#endif + break; + case ExtraTF::kSRGB: + HWY_FULL(float) df; + for (size_t i = 0; i < buf_size; i += Lanes(df)) { + const auto val = Load(df, buf_dst + i); + const auto result = + TF_SRGB().EncodedFromDisplay(HWY_FULL(float)(), val); + Store(result, df, buf_dst + i); + } +#if JXL_CMS_VERBOSE >= 2 + printf("after SRGB enc %.4f %.4f %.4f\n", buf_dst[3 * kX], + buf_dst[3 * kX + 1], buf_dst[3 * kX + 2]); +#endif + break; + } + return true; +} + +Status DoColorSpaceTransform(void* cms_data, const size_t thread, + const float* buf_src, float* buf_dst, + size_t xsize) { + // No lock needed. + JxlCms* t = reinterpret_cast<JxlCms*>(cms_data); + + const float* xform_src = buf_src; // Read-only. + if (t->preprocess != ExtraTF::kNone) { + float* mutable_xform_src = t->buf_src.Row(thread); // Writable buffer. + JXL_RETURN_IF_ERROR(BeforeTransform(t, buf_src, mutable_xform_src, + xsize * t->channels_src)); + xform_src = mutable_xform_src; + } + +#if JPEGXL_ENABLE_SKCMS + if (t->channels_src == 1 && !t->skip_lcms) { + // Expand from 1 to 3 channels, starting from the end in case + // xform_src == t->buf_src.Row(thread). + float* mutable_xform_src = t->buf_src.Row(thread); + for (size_t i = 0; i < xsize; ++i) { + const size_t x = xsize - i - 1; + mutable_xform_src[x * 3] = mutable_xform_src[x * 3 + 1] = + mutable_xform_src[x * 3 + 2] = xform_src[x]; + } + xform_src = mutable_xform_src; + } +#else + if (t->channels_src == 4 && !t->skip_lcms) { + // LCMS does CMYK in a weird way: 0 = white, 100 = max ink + float* mutable_xform_src = t->buf_src.Row(thread); + for (size_t x = 0; x < xsize * 4; ++x) { + mutable_xform_src[x] = 100.f - 100.f * mutable_xform_src[x]; + } + xform_src = mutable_xform_src; + } +#endif + +#if JXL_CMS_VERBOSE >= 2 + // Save inputs for printing before in-place transforms overwrite them. + const float in0 = xform_src[3 * kX + 0]; + const float in1 = xform_src[3 * kX + 1]; + const float in2 = xform_src[3 * kX + 2]; +#endif + + if (t->skip_lcms) { + if (buf_dst != xform_src) { + memcpy(buf_dst, xform_src, xsize * t->channels_src * sizeof(*buf_dst)); + } // else: in-place, no need to copy + } else { +#if JPEGXL_ENABLE_SKCMS + JXL_CHECK( + skcms_Transform(xform_src, + (t->channels_src == 4 ? skcms_PixelFormat_RGBA_ffff + : skcms_PixelFormat_RGB_fff), + skcms_AlphaFormat_Opaque, &t->profile_src, buf_dst, + skcms_PixelFormat_RGB_fff, skcms_AlphaFormat_Opaque, + &t->profile_dst, xsize)); +#else // JPEGXL_ENABLE_SKCMS + cmsDoTransform(t->lcms_transform, xform_src, buf_dst, + static_cast<cmsUInt32Number>(xsize)); +#endif // JPEGXL_ENABLE_SKCMS + } +#if JXL_CMS_VERBOSE >= 2 + printf("xform skip%d: %.4f %.4f %.4f (%p) -> (%p) %.4f %.4f %.4f\n", + t->skip_lcms, in0, in1, in2, xform_src, buf_dst, buf_dst[3 * kX], + buf_dst[3 * kX + 1], buf_dst[3 * kX + 2]); +#endif + +#if JPEGXL_ENABLE_SKCMS + if (t->channels_dst == 1 && !t->skip_lcms) { + // Contract back from 3 to 1 channel, this time forward. + float* grayscale_buf_dst = t->buf_dst.Row(thread); + for (size_t x = 0; x < xsize; ++x) { + grayscale_buf_dst[x] = buf_dst[x * 3]; + } + buf_dst = grayscale_buf_dst; + } +#endif + + if (t->postprocess != ExtraTF::kNone) { + JXL_RETURN_IF_ERROR(AfterTransform(t, buf_dst, xsize * t->channels_dst)); + } + return true; +} + +// NOLINTNEXTLINE(google-readability-namespace-comments) +} // namespace HWY_NAMESPACE +} // namespace jxl +HWY_AFTER_NAMESPACE(); + +#if HWY_ONCE +namespace jxl { +namespace { + +HWY_EXPORT(DoColorSpaceTransform); +int DoColorSpaceTransform(void* t, size_t thread, const float* buf_src, + float* buf_dst, size_t xsize) { + return HWY_DYNAMIC_DISPATCH(DoColorSpaceTransform)(t, thread, buf_src, + buf_dst, xsize); +} + +// Define to 1 on OS X as a workaround for older LCMS lacking MD5. +#define JXL_CMS_OLD_VERSION 0 + +#if JPEGXL_ENABLE_SKCMS + +JXL_MUST_USE_RESULT CIExy CIExyFromXYZ(const float XYZ[3]) { + const float factor = 1.f / (XYZ[0] + XYZ[1] + XYZ[2]); + CIExy xy; + xy.x = XYZ[0] * factor; + xy.y = XYZ[1] * factor; + return xy; +} + +#else // JPEGXL_ENABLE_SKCMS +// (LCMS interface requires xyY but we omit the Y for white points/primaries.) + +JXL_MUST_USE_RESULT CIExy CIExyFromxyY(const cmsCIExyY& xyY) { + CIExy xy; + xy.x = xyY.x; + xy.y = xyY.y; + return xy; +} + +JXL_MUST_USE_RESULT CIExy CIExyFromXYZ(const cmsCIEXYZ& XYZ) { + cmsCIExyY xyY; + cmsXYZ2xyY(/*Dest=*/&xyY, /*Source=*/&XYZ); + return CIExyFromxyY(xyY); +} + +JXL_MUST_USE_RESULT cmsCIEXYZ D50_XYZ() { + // Quantized D50 as stored in ICC profiles. + return {0.96420288, 1.0, 0.82490540}; +} + +// RAII + +struct ProfileDeleter { + void operator()(void* p) { cmsCloseProfile(p); } +}; +using Profile = std::unique_ptr<void, ProfileDeleter>; + +struct TransformDeleter { + void operator()(void* p) { cmsDeleteTransform(p); } +}; +using Transform = std::unique_ptr<void, TransformDeleter>; + +struct CurveDeleter { + void operator()(cmsToneCurve* p) { cmsFreeToneCurve(p); } +}; +using Curve = std::unique_ptr<cmsToneCurve, CurveDeleter>; + +Status CreateProfileXYZ(const cmsContext context, + Profile* JXL_RESTRICT profile) { + profile->reset(cmsCreateXYZProfileTHR(context)); + if (profile->get() == nullptr) return JXL_FAILURE("Failed to create XYZ"); + return true; +} + +#endif // !JPEGXL_ENABLE_SKCMS + +#if JPEGXL_ENABLE_SKCMS +// IMPORTANT: icc must outlive profile. +Status DecodeProfile(const uint8_t* icc, size_t size, + skcms_ICCProfile* const profile) { + if (!skcms_Parse(icc, size, profile)) { + return JXL_FAILURE("Failed to parse ICC profile with %" PRIuS " bytes", + size); + } + return true; +} +#else // JPEGXL_ENABLE_SKCMS +Status DecodeProfile(const cmsContext context, const PaddedBytes& icc, + Profile* profile) { + profile->reset(cmsOpenProfileFromMemTHR(context, icc.data(), icc.size())); + if (profile->get() == nullptr) { + return JXL_FAILURE("Failed to decode profile"); + } + + // WARNING: due to the LCMS MD5 issue mentioned above, many existing + // profiles have incorrect MD5, so do not even bother checking them nor + // generating warning clutter. + + return true; +} +#endif // JPEGXL_ENABLE_SKCMS + +#if JPEGXL_ENABLE_SKCMS + +ColorSpace ColorSpaceFromProfile(const skcms_ICCProfile& profile) { + switch (profile.data_color_space) { + case skcms_Signature_RGB: + case skcms_Signature_CMYK: + // spec says CMYK is encoded as RGB (the kBlack extra channel signals that + // it is actually CMYK) + return ColorSpace::kRGB; + case skcms_Signature_Gray: + return ColorSpace::kGray; + default: + return ColorSpace::kUnknown; + } +} + +// vector_out := matmul(matrix, vector_in) +void MatrixProduct(const skcms_Matrix3x3& matrix, const float vector_in[3], + float vector_out[3]) { + for (int i = 0; i < 3; ++i) { + vector_out[i] = 0; + for (int j = 0; j < 3; ++j) { + vector_out[i] += matrix.vals[i][j] * vector_in[j]; + } + } +} + +// Returns white point that was specified when creating the profile. +JXL_MUST_USE_RESULT Status UnadaptedWhitePoint(const skcms_ICCProfile& profile, + CIExy* out) { + float media_white_point_XYZ[3]; + if (!skcms_GetWTPT(&profile, media_white_point_XYZ)) { + return JXL_FAILURE("ICC profile does not contain WhitePoint tag"); + } + skcms_Matrix3x3 CHAD; + if (!skcms_GetCHAD(&profile, &CHAD)) { + // If there is no chromatic adaptation matrix, it means that the white point + // is already unadapted. + *out = CIExyFromXYZ(media_white_point_XYZ); + return true; + } + // Otherwise, it has been adapted to the PCS white point using said matrix, + // and the adaptation needs to be undone. + skcms_Matrix3x3 inverse_CHAD; + if (!skcms_Matrix3x3_invert(&CHAD, &inverse_CHAD)) { + return JXL_FAILURE("Non-invertible ChromaticAdaptation matrix"); + } + float unadapted_white_point_XYZ[3]; + MatrixProduct(inverse_CHAD, media_white_point_XYZ, unadapted_white_point_XYZ); + *out = CIExyFromXYZ(unadapted_white_point_XYZ); + return true; +} + +Status IdentifyPrimaries(const skcms_ICCProfile& profile, + const CIExy& wp_unadapted, ColorEncoding* c) { + if (!c->HasPrimaries()) return true; + + skcms_Matrix3x3 CHAD, inverse_CHAD; + if (skcms_GetCHAD(&profile, &CHAD)) { + JXL_RETURN_IF_ERROR(skcms_Matrix3x3_invert(&CHAD, &inverse_CHAD)); + } else { + static constexpr skcms_Matrix3x3 kLMSFromXYZ = { + {{0.8951, 0.2664, -0.1614}, + {-0.7502, 1.7135, 0.0367}, + {0.0389, -0.0685, 1.0296}}}; + static constexpr skcms_Matrix3x3 kXYZFromLMS = { + {{0.9869929, -0.1470543, 0.1599627}, + {0.4323053, 0.5183603, 0.0492912}, + {-0.0085287, 0.0400428, 0.9684867}}}; + static constexpr float kWpD50XYZ[3] = {0.96420288, 1.0, 0.82490540}; + float wp_unadapted_XYZ[3]; + JXL_RETURN_IF_ERROR(CIEXYZFromWhiteCIExy(wp_unadapted, wp_unadapted_XYZ)); + float wp_D50_LMS[3], wp_unadapted_LMS[3]; + MatrixProduct(kLMSFromXYZ, kWpD50XYZ, wp_D50_LMS); + MatrixProduct(kLMSFromXYZ, wp_unadapted_XYZ, wp_unadapted_LMS); + inverse_CHAD = {{{wp_unadapted_LMS[0] / wp_D50_LMS[0], 0, 0}, + {0, wp_unadapted_LMS[1] / wp_D50_LMS[1], 0}, + {0, 0, wp_unadapted_LMS[2] / wp_D50_LMS[2]}}}; + inverse_CHAD = skcms_Matrix3x3_concat(&kXYZFromLMS, &inverse_CHAD); + inverse_CHAD = skcms_Matrix3x3_concat(&inverse_CHAD, &kLMSFromXYZ); + } + + float XYZ[3]; + PrimariesCIExy primaries; + CIExy* const chromaticities[] = {&primaries.r, &primaries.g, &primaries.b}; + for (int i = 0; i < 3; ++i) { + float RGB[3] = {}; + RGB[i] = 1; + skcms_Transform(RGB, skcms_PixelFormat_RGB_fff, skcms_AlphaFormat_Opaque, + &profile, XYZ, skcms_PixelFormat_RGB_fff, + skcms_AlphaFormat_Opaque, skcms_XYZD50_profile(), 1); + float unadapted_XYZ[3]; + MatrixProduct(inverse_CHAD, XYZ, unadapted_XYZ); + *chromaticities[i] = CIExyFromXYZ(unadapted_XYZ); + } + return c->SetPrimaries(primaries); +} + +void DetectTransferFunction(const skcms_ICCProfile& profile, + ColorEncoding* JXL_RESTRICT c) { + if (c->tf.SetImplicit()) return; + + float gamma[3] = {}; + if (profile.has_trc) { + const auto IsGamma = [](const skcms_TransferFunction& tf) { + return tf.a == 1 && tf.b == 0 && + /* if b and d are zero, it is fine for c not to be */ tf.d == 0 && + tf.e == 0 && tf.f == 0; + }; + for (int i = 0; i < 3; ++i) { + if (profile.trc[i].table_entries == 0 && + IsGamma(profile.trc->parametric)) { + gamma[i] = 1.f / profile.trc->parametric.g; + } else { + skcms_TransferFunction approximate_tf; + float max_error; + if (skcms_ApproximateCurve(&profile.trc[i], &approximate_tf, + &max_error)) { + if (IsGamma(approximate_tf)) { + gamma[i] = 1.f / approximate_tf.g; + } + } + } + } + } + if (gamma[0] != 0 && std::abs(gamma[0] - gamma[1]) < 1e-4f && + std::abs(gamma[1] - gamma[2]) < 1e-4f) { + if (c->tf.SetGamma(gamma[0])) { + skcms_ICCProfile profile_test; + PaddedBytes bytes; + if (MaybeCreateProfile(*c, &bytes) && + DecodeProfile(bytes.data(), bytes.size(), &profile_test) && + skcms_ApproximatelyEqualProfiles(&profile, &profile_test)) { + return; + } + } + } + + for (TransferFunction tf : Values<TransferFunction>()) { + // Can only create profile from known transfer function. + if (tf == TransferFunction::kUnknown) continue; + + c->tf.SetTransferFunction(tf); + + skcms_ICCProfile profile_test; + PaddedBytes bytes; + if (MaybeCreateProfile(*c, &bytes) && + DecodeProfile(bytes.data(), bytes.size(), &profile_test) && + skcms_ApproximatelyEqualProfiles(&profile, &profile_test)) { + return; + } + } + + c->tf.SetTransferFunction(TransferFunction::kUnknown); +} + +#else // JPEGXL_ENABLE_SKCMS + +uint32_t Type32(const ColorEncoding& c, bool cmyk) { + if (cmyk) return TYPE_CMYK_FLT; + if (c.IsGray()) return TYPE_GRAY_FLT; + return TYPE_RGB_FLT; +} + +uint32_t Type64(const ColorEncoding& c) { + if (c.IsGray()) return TYPE_GRAY_DBL; + return TYPE_RGB_DBL; +} + +ColorSpace ColorSpaceFromProfile(const Profile& profile) { + switch (cmsGetColorSpace(profile.get())) { + case cmsSigRgbData: + case cmsSigCmykData: + return ColorSpace::kRGB; + case cmsSigGrayData: + return ColorSpace::kGray; + default: + return ColorSpace::kUnknown; + } +} + +// "profile1" is pre-decoded to save time in DetectTransferFunction. +Status ProfileEquivalentToICC(const cmsContext context, const Profile& profile1, + const PaddedBytes& icc, const ColorEncoding& c) { + const uint32_t type_src = Type64(c); + + Profile profile2; + JXL_RETURN_IF_ERROR(DecodeProfile(context, icc, &profile2)); + + Profile profile_xyz; + JXL_RETURN_IF_ERROR(CreateProfileXYZ(context, &profile_xyz)); + + const uint32_t intent = INTENT_RELATIVE_COLORIMETRIC; + const uint32_t flags = cmsFLAGS_NOOPTIMIZE | cmsFLAGS_BLACKPOINTCOMPENSATION | + cmsFLAGS_HIGHRESPRECALC; + Transform xform1(cmsCreateTransformTHR(context, profile1.get(), type_src, + profile_xyz.get(), TYPE_XYZ_DBL, + intent, flags)); + Transform xform2(cmsCreateTransformTHR(context, profile2.get(), type_src, + profile_xyz.get(), TYPE_XYZ_DBL, + intent, flags)); + if (xform1 == nullptr || xform2 == nullptr) { + return JXL_FAILURE("Failed to create transform"); + } + + double in[3]; + double out1[3]; + double out2[3]; + + // Uniformly spaced samples from very dark to almost fully bright. + const double init = 1E-3; + const double step = 0.2; + + if (c.IsGray()) { + // Finer sampling and replicate each component. + for (in[0] = init; in[0] < 1.0; in[0] += step / 8) { + cmsDoTransform(xform1.get(), in, out1, 1); + cmsDoTransform(xform2.get(), in, out2, 1); + if (!ApproxEq(out1[0], out2[0], 2E-4)) { + return false; + } + } + } else { + for (in[0] = init; in[0] < 1.0; in[0] += step) { + for (in[1] = init; in[1] < 1.0; in[1] += step) { + for (in[2] = init; in[2] < 1.0; in[2] += step) { + cmsDoTransform(xform1.get(), in, out1, 1); + cmsDoTransform(xform2.get(), in, out2, 1); + for (size_t i = 0; i < 3; ++i) { + if (!ApproxEq(out1[i], out2[i], 2E-4)) { + return false; + } + } + } + } + } + } + + return true; +} + +// Returns white point that was specified when creating the profile. +// NOTE: we can't just use cmsSigMediaWhitePointTag because its interpretation +// differs between ICC versions. +JXL_MUST_USE_RESULT cmsCIEXYZ UnadaptedWhitePoint(const cmsContext context, + const Profile& profile, + const ColorEncoding& c) { + const cmsCIEXYZ* white_point = static_cast<const cmsCIEXYZ*>( + cmsReadTag(profile.get(), cmsSigMediaWhitePointTag)); + if (white_point != nullptr && + cmsReadTag(profile.get(), cmsSigChromaticAdaptationTag) == nullptr) { + // No chromatic adaptation matrix: the white point is already unadapted. + return *white_point; + } + + cmsCIEXYZ XYZ = {1.0, 1.0, 1.0}; + Profile profile_xyz; + if (!CreateProfileXYZ(context, &profile_xyz)) return XYZ; + // Array arguments are one per profile. + cmsHPROFILE profiles[2] = {profile.get(), profile_xyz.get()}; + // Leave white point unchanged - that is what we're trying to extract. + cmsUInt32Number intents[2] = {INTENT_ABSOLUTE_COLORIMETRIC, + INTENT_ABSOLUTE_COLORIMETRIC}; + cmsBool black_compensation[2] = {0, 0}; + cmsFloat64Number adaption[2] = {0.0, 0.0}; + // Only transforming a single pixel, so skip expensive optimizations. + cmsUInt32Number flags = cmsFLAGS_NOOPTIMIZE | cmsFLAGS_HIGHRESPRECALC; + Transform xform(cmsCreateExtendedTransform( + context, 2, profiles, black_compensation, intents, adaption, nullptr, 0, + Type64(c), TYPE_XYZ_DBL, flags)); + if (!xform) return XYZ; // TODO(lode): return error + + // xy are relative, so magnitude does not matter if we ignore output Y. + const cmsFloat64Number in[3] = {1.0, 1.0, 1.0}; + cmsDoTransform(xform.get(), in, &XYZ.X, 1); + return XYZ; +} + +Status IdentifyPrimaries(const cmsContext context, const Profile& profile, + const cmsCIEXYZ& wp_unadapted, ColorEncoding* c) { + if (!c->HasPrimaries()) return true; + if (ColorSpaceFromProfile(profile) == ColorSpace::kUnknown) return true; + + // These were adapted to the profile illuminant before storing in the profile. + const cmsCIEXYZ* adapted_r = static_cast<const cmsCIEXYZ*>( + cmsReadTag(profile.get(), cmsSigRedColorantTag)); + const cmsCIEXYZ* adapted_g = static_cast<const cmsCIEXYZ*>( + cmsReadTag(profile.get(), cmsSigGreenColorantTag)); + const cmsCIEXYZ* adapted_b = static_cast<const cmsCIEXYZ*>( + cmsReadTag(profile.get(), cmsSigBlueColorantTag)); + + cmsCIEXYZ converted_rgb[3]; + if (adapted_r == nullptr || adapted_g == nullptr || adapted_b == nullptr) { + // No colorant tag, determine the XYZ coordinates of the primaries by + // converting from the colorspace. + Profile profile_xyz; + if (!CreateProfileXYZ(context, &profile_xyz)) { + return JXL_FAILURE("Failed to retrieve colorants"); + } + // Array arguments are one per profile. + cmsHPROFILE profiles[2] = {profile.get(), profile_xyz.get()}; + cmsUInt32Number intents[2] = {INTENT_RELATIVE_COLORIMETRIC, + INTENT_RELATIVE_COLORIMETRIC}; + cmsBool black_compensation[2] = {0, 0}; + cmsFloat64Number adaption[2] = {0.0, 0.0}; + // Only transforming three pixels, so skip expensive optimizations. + cmsUInt32Number flags = cmsFLAGS_NOOPTIMIZE | cmsFLAGS_HIGHRESPRECALC; + Transform xform(cmsCreateExtendedTransform( + context, 2, profiles, black_compensation, intents, adaption, nullptr, 0, + Type64(*c), TYPE_XYZ_DBL, flags)); + if (!xform) return JXL_FAILURE("Failed to retrieve colorants"); + + const cmsFloat64Number in[9] = {1.0, 0.0, 0.0, 0.0, 1.0, + 0.0, 0.0, 0.0, 1.0}; + cmsDoTransform(xform.get(), in, &converted_rgb->X, 3); + adapted_r = &converted_rgb[0]; + adapted_g = &converted_rgb[1]; + adapted_b = &converted_rgb[2]; + } + + // TODO(janwas): no longer assume Bradford and D50. + // Undo the chromatic adaptation. + const cmsCIEXYZ d50 = D50_XYZ(); + + cmsCIEXYZ r, g, b; + cmsAdaptToIlluminant(&r, &d50, &wp_unadapted, adapted_r); + cmsAdaptToIlluminant(&g, &d50, &wp_unadapted, adapted_g); + cmsAdaptToIlluminant(&b, &d50, &wp_unadapted, adapted_b); + + const PrimariesCIExy rgb = {CIExyFromXYZ(r), CIExyFromXYZ(g), + CIExyFromXYZ(b)}; + return c->SetPrimaries(rgb); +} + +void DetectTransferFunction(const cmsContext context, const Profile& profile, + ColorEncoding* JXL_RESTRICT c) { + if (c->tf.SetImplicit()) return; + + float gamma = 0; + if (const auto* gray_trc = reinterpret_cast<const cmsToneCurve*>( + cmsReadTag(profile.get(), cmsSigGrayTRCTag))) { + const double estimated_gamma = + cmsEstimateGamma(gray_trc, /*precision=*/1e-4); + if (estimated_gamma > 0) { + gamma = 1. / estimated_gamma; + } + } else { + float rgb_gamma[3] = {}; + int i = 0; + for (const auto tag : + {cmsSigRedTRCTag, cmsSigGreenTRCTag, cmsSigBlueTRCTag}) { + if (const auto* trc = reinterpret_cast<const cmsToneCurve*>( + cmsReadTag(profile.get(), tag))) { + const double estimated_gamma = + cmsEstimateGamma(trc, /*precision=*/1e-4); + if (estimated_gamma > 0) { + rgb_gamma[i] = 1. / estimated_gamma; + } + } + ++i; + } + if (rgb_gamma[0] != 0 && std::abs(rgb_gamma[0] - rgb_gamma[1]) < 1e-4f && + std::abs(rgb_gamma[1] - rgb_gamma[2]) < 1e-4f) { + gamma = rgb_gamma[0]; + } + } + + if (gamma != 0 && c->tf.SetGamma(gamma)) { + PaddedBytes icc_test; + if (MaybeCreateProfile(*c, &icc_test) && + ProfileEquivalentToICC(context, profile, icc_test, *c)) { + return; + } + } + + for (TransferFunction tf : Values<TransferFunction>()) { + // Can only create profile from known transfer function. + if (tf == TransferFunction::kUnknown) continue; + + c->tf.SetTransferFunction(tf); + + PaddedBytes icc_test; + if (MaybeCreateProfile(*c, &icc_test) && + ProfileEquivalentToICC(context, profile, icc_test, *c)) { + return; + } + } + + c->tf.SetTransferFunction(TransferFunction::kUnknown); +} + +void ErrorHandler(cmsContext context, cmsUInt32Number code, const char* text) { + JXL_WARNING("LCMS error %u: %s", code, text); +} + +// Returns a context for the current thread, creating it if necessary. +cmsContext GetContext() { + static thread_local void* context_; + if (context_ == nullptr) { + context_ = cmsCreateContext(nullptr, nullptr); + JXL_ASSERT(context_ != nullptr); + + cmsSetLogErrorHandlerTHR(static_cast<cmsContext>(context_), &ErrorHandler); + } + return static_cast<cmsContext>(context_); +} + +#endif // JPEGXL_ENABLE_SKCMS + +Status GetPrimariesLuminances(const ColorEncoding& encoding, + float luminances[3]) { + // Explanation: + // We know that the three primaries must sum to white: + // + // [Xr, Xg, Xb; [1; [Xw; + // Yr, Yg, Yb; × 1; = Yw; + // Zr, Zg, Zb] 1] Zw] + // + // By noting that X = x·(X+Y+Z), Y = y·(X+Y+Z) and Z = z·(X+Y+Z) (note the + // lower case indicating chromaticity), and factoring the totals (X+Y+Z) out + // of the left matrix and into the all-ones vector, we get: + // + // [xr, xg, xb; [Xr + Yr + Zr; [Xw; + // yr, yg, yb; × Xg + Yg + Zg; = Yw; + // zr, zg, zb] Xb + Yb + Zb] Zw] + // + // Which makes it apparent that we can compute those totals as: + // + // [Xr + Yr + Zr; inv([xr, xg, xb; [Xw; + // Xg + Yg + Zg; = yr, yg, yb; × Yw; + // Xb + Yb + Zb] zr, zg, zb]) Zw] + // + // From there, by multiplying each total by its corresponding y, we get Y for + // that primary. + + float white_XYZ[3]; + JXL_RETURN_IF_ERROR( + CIEXYZFromWhiteCIExy(encoding.GetWhitePoint(), white_XYZ)); + + const PrimariesCIExy primaries = encoding.GetPrimaries(); + double chromaticities[3][3] = { + {primaries.r.x, primaries.g.x, primaries.b.x}, + {primaries.r.y, primaries.g.y, primaries.b.y}, + {1 - primaries.r.x - primaries.r.y, 1 - primaries.g.x - primaries.g.y, + 1 - primaries.b.x - primaries.b.y}}; + JXL_RETURN_IF_ERROR(Inv3x3Matrix(&chromaticities[0][0])); + const double ys[3] = {primaries.r.y, primaries.g.y, primaries.b.y}; + for (size_t i = 0; i < 3; ++i) { + luminances[i] = ys[i] * (chromaticities[i][0] * white_XYZ[0] + + chromaticities[i][1] * white_XYZ[1] + + chromaticities[i][2] * white_XYZ[2]); + } + return true; +} + +Status ApplyHlgOotf(JxlCms* t, float* JXL_RESTRICT buf, size_t xsize, + bool forward) { + if (295 <= t->intensity_target && t->intensity_target <= 305) { + // The gamma is approximately 1 so this can essentially be skipped. + return true; + } + float gamma = 1.2f * std::pow(1.111f, std::log2(t->intensity_target * 1e-3f)); + if (!forward) gamma = 1.f / gamma; + + switch (t->hlg_ootf_num_channels) { + case 1: + for (size_t x = 0; x < xsize; ++x) { + buf[x] = std::pow(buf[x], gamma); + } + break; + + case 3: + for (size_t x = 0; x < xsize; x += 3) { + const float luminance = buf[x] * t->hlg_ootf_luminances[0] + + buf[x + 1] * t->hlg_ootf_luminances[1] + + buf[x + 2] * t->hlg_ootf_luminances[2]; + const float ratio = std::pow(luminance, gamma - 1); + if (std::isfinite(ratio)) { + buf[x] *= ratio; + buf[x + 1] *= ratio; + buf[x + 2] *= ratio; + if (forward && gamma < 1) { + // If gamma < 1, the ratio above will be > 1 which can push bright + // saturated highlights out of gamut. There are several possible + // ways to bring them back in-gamut; this one preserves hue and + // saturation at the slight expense of luminance. If !forward, the + // previously-applied forward OOTF with gamma > 1 already pushed + // those highlights down and we are simply putting them back where + // they were so this is not necessary. + const float maximum = + std::max(buf[x], std::max(buf[x + 1], buf[x + 2])); + if (maximum > 1) { + const float normalizer = 1.f / maximum; + buf[x] *= normalizer; + buf[x + 1] *= normalizer; + buf[x + 2] *= normalizer; + } + } + } + } + break; + + default: + return JXL_FAILURE("HLG OOTF not implemented for %" PRIuS " channels", + t->hlg_ootf_num_channels); + } + return true; +} + +bool ApplyCICP(const uint8_t color_primaries, + const uint8_t transfer_characteristics, + const uint8_t matrix_coefficients, const uint8_t full_range, + ColorEncoding* JXL_RESTRICT c) { + if (matrix_coefficients != 0) return false; + if (full_range != 1) return false; + + const auto primaries = static_cast<Primaries>(color_primaries); + const auto tf = static_cast<TransferFunction>(transfer_characteristics); + if (tf == TransferFunction::kUnknown || !EnumValid(tf)) return false; + if (primaries == Primaries::kCustom || + !(color_primaries == 12 || EnumValid(primaries))) { + return false; + } + c->SetColorSpace(ColorSpace::kRGB); + c->tf.SetTransferFunction(tf); + if (primaries == Primaries::kP3) { + c->white_point = WhitePoint::kDCI; + c->primaries = Primaries::kP3; + } else if (color_primaries == 12) { + c->white_point = WhitePoint::kD65; + c->primaries = Primaries::kP3; + } else { + c->white_point = WhitePoint::kD65; + c->primaries = primaries; + } + return true; +} + +} // namespace + +Status ColorEncoding::SetFieldsFromICC() { + // In case parsing fails, mark the ColorEncoding as invalid. + SetColorSpace(ColorSpace::kUnknown); + tf.SetTransferFunction(TransferFunction::kUnknown); + + if (icc_.empty()) return JXL_FAILURE("Empty ICC profile"); + +#if JPEGXL_ENABLE_SKCMS + if (icc_.size() < 128) { + return JXL_FAILURE("ICC file too small"); + } + + skcms_ICCProfile profile; + JXL_RETURN_IF_ERROR(skcms_Parse(icc_.data(), icc_.size(), &profile)); + + // skcms does not return the rendering intent, so get it from the file. It + // is encoded as big-endian 32-bit integer in bytes 60..63. + uint32_t rendering_intent32 = icc_[67]; + if (rendering_intent32 > 3 || icc_[64] != 0 || icc_[65] != 0 || + icc_[66] != 0) { + return JXL_FAILURE("Invalid rendering intent %u\n", rendering_intent32); + } + // ICC and RenderingIntent have the same values (0..3). + rendering_intent = static_cast<RenderingIntent>(rendering_intent32); + + if (profile.has_CICP && ApplyCICP(profile.CICP.color_primaries, + profile.CICP.transfer_characteristics, + profile.CICP.matrix_coefficients, + profile.CICP.video_full_range_flag, this)) { + return true; + } + + SetColorSpace(ColorSpaceFromProfile(profile)); + cmyk_ = (profile.data_color_space == skcms_Signature_CMYK); + + CIExy wp_unadapted; + JXL_RETURN_IF_ERROR(UnadaptedWhitePoint(profile, &wp_unadapted)); + JXL_RETURN_IF_ERROR(SetWhitePoint(wp_unadapted)); + + // Relies on color_space. + JXL_RETURN_IF_ERROR(IdentifyPrimaries(profile, wp_unadapted, this)); + + // Relies on color_space/white point/primaries being set already. + DetectTransferFunction(profile, this); +#else // JPEGXL_ENABLE_SKCMS + + const cmsContext context = GetContext(); + + Profile profile; + JXL_RETURN_IF_ERROR(DecodeProfile(context, icc_, &profile)); + + static constexpr size_t kCICPSize = 12; + static constexpr auto kCICPSignature = + static_cast<cmsTagSignature>(0x63696370); + uint8_t cicp_buffer[kCICPSize]; + if (cmsReadRawTag(profile.get(), kCICPSignature, cicp_buffer, kCICPSize) == + kCICPSize && + ApplyCICP(cicp_buffer[8], cicp_buffer[9], cicp_buffer[10], + cicp_buffer[11], this)) { + return true; + } + + const cmsUInt32Number rendering_intent32 = + cmsGetHeaderRenderingIntent(profile.get()); + if (rendering_intent32 > 3) { + return JXL_FAILURE("Invalid rendering intent %u\n", rendering_intent32); + } + // ICC and RenderingIntent have the same values (0..3). + rendering_intent = static_cast<RenderingIntent>(rendering_intent32); + + SetColorSpace(ColorSpaceFromProfile(profile)); + if (cmsGetColorSpace(profile.get()) == cmsSigCmykData) { + cmyk_ = true; + return true; + } + + const cmsCIEXYZ wp_unadapted = UnadaptedWhitePoint(context, profile, *this); + JXL_RETURN_IF_ERROR(SetWhitePoint(CIExyFromXYZ(wp_unadapted))); + + // Relies on color_space. + JXL_RETURN_IF_ERROR(IdentifyPrimaries(context, profile, wp_unadapted, this)); + + // Relies on color_space/white point/primaries being set already. + DetectTransferFunction(context, profile, this); + +#endif // JPEGXL_ENABLE_SKCMS + + return true; +} + +void ColorEncoding::DecideIfWantICC() { + PaddedBytes icc_new; +#if JPEGXL_ENABLE_SKCMS + skcms_ICCProfile profile; + if (!DecodeProfile(ICC().data(), ICC().size(), &profile)) return; + if (!MaybeCreateProfile(*this, &icc_new)) return; +#else // JPEGXL_ENABLE_SKCMS + const cmsContext context = GetContext(); + Profile profile; + if (!DecodeProfile(context, ICC(), &profile)) return; + if (cmsGetColorSpace(profile.get()) == cmsSigCmykData) return; + if (!MaybeCreateProfile(*this, &icc_new)) return; +#endif // JPEGXL_ENABLE_SKCMS + + want_icc_ = false; +} + +namespace { + +void JxlCmsDestroy(void* cms_data) { + if (cms_data == nullptr) return; + JxlCms* t = reinterpret_cast<JxlCms*>(cms_data); +#if !JPEGXL_ENABLE_SKCMS + TransformDeleter()(t->lcms_transform); +#endif + delete t; +} + +void* JxlCmsInit(void* init_data, size_t num_threads, size_t xsize, + const JxlColorProfile* input, const JxlColorProfile* output, + float intensity_target) { + auto t = jxl::make_unique<JxlCms>(); + PaddedBytes icc_src, icc_dst; + icc_src.assign(input->icc.data, input->icc.data + input->icc.size); + ColorEncoding c_src; + if (!c_src.SetICC(std::move(icc_src))) { + JXL_NOTIFY_ERROR("JxlCmsInit: failed to parse input ICC"); + return nullptr; + } + icc_dst.assign(output->icc.data, output->icc.data + output->icc.size); + ColorEncoding c_dst; + if (!c_dst.SetICC(std::move(icc_dst))) { + JXL_NOTIFY_ERROR("JxlCmsInit: failed to parse output ICC"); + return nullptr; + } +#if JXL_CMS_VERBOSE + printf("%s -> %s\n", Description(c_src).c_str(), Description(c_dst).c_str()); +#endif + +#if JPEGXL_ENABLE_SKCMS + if (!DecodeProfile(input->icc.data, input->icc.size, &t->profile_src)) { + JXL_NOTIFY_ERROR("JxlCmsInit: skcms failed to parse input ICC"); + return nullptr; + } + if (!DecodeProfile(output->icc.data, output->icc.size, &t->profile_dst)) { + JXL_NOTIFY_ERROR("JxlCmsInit: skcms failed to parse output ICC"); + return nullptr; + } +#else // JPEGXL_ENABLE_SKCMS + const cmsContext context = GetContext(); + Profile profile_src, profile_dst; + if (!DecodeProfile(context, c_src.ICC(), &profile_src)) { + JXL_NOTIFY_ERROR("JxlCmsInit: lcms failed to parse input ICC"); + return nullptr; + } + if (!DecodeProfile(context, c_dst.ICC(), &profile_dst)) { + JXL_NOTIFY_ERROR("JxlCmsInit: lcms failed to parse output ICC"); + return nullptr; + } +#endif // JPEGXL_ENABLE_SKCMS + + t->skip_lcms = false; + if (c_src.SameColorEncoding(c_dst)) { + t->skip_lcms = true; +#if JXL_CMS_VERBOSE + printf("Skip CMS\n"); +#endif + } + + t->apply_hlg_ootf = c_src.tf.IsHLG() != c_dst.tf.IsHLG(); + if (t->apply_hlg_ootf) { + const ColorEncoding* c_hlg = c_src.tf.IsHLG() ? &c_src : &c_dst; + t->hlg_ootf_num_channels = c_hlg->Channels(); + if (t->hlg_ootf_num_channels == 3 && + !GetPrimariesLuminances(*c_hlg, t->hlg_ootf_luminances.data())) { + JXL_NOTIFY_ERROR( + "JxlCmsInit: failed to compute the luminances of primaries"); + return nullptr; + } + } + + // Special-case SRGB <=> linear if the primaries / white point are the same, + // or any conversion where PQ or HLG is involved: + bool src_linear = c_src.tf.IsLinear(); + const bool dst_linear = c_dst.tf.IsLinear(); + + if (c_src.tf.IsPQ() || c_src.tf.IsHLG() || + (c_src.tf.IsSRGB() && dst_linear && c_src.SameColorSpace(c_dst))) { + // Construct new profile as if the data were already/still linear. + ColorEncoding c_linear_src = c_src; + c_linear_src.tf.SetTransferFunction(TransferFunction::kLinear); +#if JPEGXL_ENABLE_SKCMS + skcms_ICCProfile new_src; +#else // JPEGXL_ENABLE_SKCMS + Profile new_src; +#endif // JPEGXL_ENABLE_SKCMS + // Only enable ExtraTF if profile creation succeeded. + if (MaybeCreateProfile(c_linear_src, &icc_src) && +#if JPEGXL_ENABLE_SKCMS + DecodeProfile(icc_src.data(), icc_src.size(), &new_src)) { +#else // JPEGXL_ENABLE_SKCMS + DecodeProfile(context, icc_src, &new_src)) { +#endif // JPEGXL_ENABLE_SKCMS +#if JXL_CMS_VERBOSE + printf("Special HLG/PQ/sRGB -> linear\n"); +#endif +#if JPEGXL_ENABLE_SKCMS + t->icc_src = std::move(icc_src); + t->profile_src = new_src; +#else // JPEGXL_ENABLE_SKCMS + profile_src.swap(new_src); +#endif // JPEGXL_ENABLE_SKCMS + t->preprocess = c_src.tf.IsSRGB() + ? ExtraTF::kSRGB + : (c_src.tf.IsPQ() ? ExtraTF::kPQ : ExtraTF::kHLG); + c_src = c_linear_src; + src_linear = true; + } else { + if (t->apply_hlg_ootf) { + JXL_NOTIFY_ERROR( + "Failed to create extra linear source profile, and HLG OOTF " + "required"); + return nullptr; + } + JXL_WARNING("Failed to create extra linear destination profile"); + } + } + + if (c_dst.tf.IsPQ() || c_dst.tf.IsHLG() || + (c_dst.tf.IsSRGB() && src_linear && c_src.SameColorSpace(c_dst))) { + ColorEncoding c_linear_dst = c_dst; + c_linear_dst.tf.SetTransferFunction(TransferFunction::kLinear); +#if JPEGXL_ENABLE_SKCMS + skcms_ICCProfile new_dst; +#else // JPEGXL_ENABLE_SKCMS + Profile new_dst; +#endif // JPEGXL_ENABLE_SKCMS + // Only enable ExtraTF if profile creation succeeded. + if (MaybeCreateProfile(c_linear_dst, &icc_dst) && +#if JPEGXL_ENABLE_SKCMS + DecodeProfile(icc_dst.data(), icc_dst.size(), &new_dst)) { +#else // JPEGXL_ENABLE_SKCMS + DecodeProfile(context, icc_dst, &new_dst)) { +#endif // JPEGXL_ENABLE_SKCMS +#if JXL_CMS_VERBOSE + printf("Special linear -> HLG/PQ/sRGB\n"); +#endif +#if JPEGXL_ENABLE_SKCMS + t->icc_dst = std::move(icc_dst); + t->profile_dst = new_dst; +#else // JPEGXL_ENABLE_SKCMS + profile_dst.swap(new_dst); +#endif // JPEGXL_ENABLE_SKCMS + t->postprocess = c_dst.tf.IsSRGB() + ? ExtraTF::kSRGB + : (c_dst.tf.IsPQ() ? ExtraTF::kPQ : ExtraTF::kHLG); + c_dst = c_linear_dst; + } else { + if (t->apply_hlg_ootf) { + JXL_NOTIFY_ERROR( + "Failed to create extra linear destination profile, and inverse " + "HLG OOTF required"); + return nullptr; + } + JXL_WARNING("Failed to create extra linear destination profile"); + } + } + + if (c_src.SameColorEncoding(c_dst)) { +#if JXL_CMS_VERBOSE + printf("Same intermediary linear profiles, skipping CMS\n"); +#endif + t->skip_lcms = true; + } + +#if JPEGXL_ENABLE_SKCMS + if (!skcms_MakeUsableAsDestination(&t->profile_dst)) { + JXL_NOTIFY_ERROR( + "Failed to make %s usable as a color transform destination", + Description(c_dst).c_str()); + return nullptr; + } +#endif // JPEGXL_ENABLE_SKCMS + + // Not including alpha channel (copied separately). + const size_t channels_src = (c_src.IsCMYK() ? 4 : c_src.Channels()); + const size_t channels_dst = c_dst.Channels(); + JXL_CHECK(channels_src == channels_dst || + (channels_src == 4 && channels_dst == 3)); +#if JXL_CMS_VERBOSE + printf("Channels: %" PRIuS "; Threads: %" PRIuS "\n", channels_src, + num_threads); +#endif + +#if !JPEGXL_ENABLE_SKCMS + // Type includes color space (XYZ vs RGB), so can be different. + const uint32_t type_src = Type32(c_src, channels_src == 4); + const uint32_t type_dst = Type32(c_dst, false); + const uint32_t intent = static_cast<uint32_t>(c_dst.rendering_intent); + // Use cmsFLAGS_NOCACHE to disable the 1-pixel cache and make calling + // cmsDoTransform() thread-safe. + const uint32_t flags = cmsFLAGS_NOCACHE | cmsFLAGS_BLACKPOINTCOMPENSATION | + cmsFLAGS_HIGHRESPRECALC; + t->lcms_transform = + cmsCreateTransformTHR(context, profile_src.get(), type_src, + profile_dst.get(), type_dst, intent, flags); + if (t->lcms_transform == nullptr) { + JXL_NOTIFY_ERROR("Failed to create transform"); + return nullptr; + } +#endif // !JPEGXL_ENABLE_SKCMS + + // Ideally LCMS would convert directly from External to Image3. However, + // cmsDoTransformLineStride only accepts 32-bit BytesPerPlaneIn, whereas our + // planes can be more than 4 GiB apart. Hence, transform inputs/outputs must + // be interleaved. Calling cmsDoTransform for each pixel is expensive + // (indirect call). We therefore transform rows, which requires per-thread + // buffers. To avoid separate allocations, we use the rows of an image. + // Because LCMS apparently also cannot handle <= 16 bit inputs and 32-bit + // outputs (or vice versa), we use floating point input/output. + t->channels_src = channels_src; + t->channels_dst = channels_dst; +#if JPEGXL_ENABLE_SKCMS + // SkiaCMS doesn't support grayscale float buffers, so we create space for RGB + // float buffers anyway. + t->buf_src = ImageF(xsize * (channels_src == 4 ? 4 : 3), num_threads); + t->buf_dst = ImageF(xsize * 3, num_threads); +#else + t->buf_src = ImageF(xsize * channels_src, num_threads); + t->buf_dst = ImageF(xsize * channels_dst, num_threads); +#endif + t->intensity_target = intensity_target; + return t.release(); +} + +float* JxlCmsGetSrcBuf(void* cms_data, size_t thread) { + JxlCms* t = reinterpret_cast<JxlCms*>(cms_data); + return t->buf_src.Row(thread); +} + +float* JxlCmsGetDstBuf(void* cms_data, size_t thread) { + JxlCms* t = reinterpret_cast<JxlCms*>(cms_data); + return t->buf_dst.Row(thread); +} + +} // namespace + +const JxlCmsInterface& GetJxlCms() { + static constexpr JxlCmsInterface kInterface = { + /*init_data=*/nullptr, + /*init=*/&JxlCmsInit, + /*get_src_buf=*/&JxlCmsGetSrcBuf, + /*get_dst_buf=*/&JxlCmsGetDstBuf, + /*run=*/&DoColorSpaceTransform, + /*destroy=*/&JxlCmsDestroy}; + return kInterface; +} + +} // namespace jxl +#endif // HWY_ONCE |