// 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/dec_xyb.h" #include #undef HWY_TARGET_INCLUDE #define HWY_TARGET_INCLUDE "lib/jxl/dec_xyb.cc" #include #include #include "lib/jxl/base/compiler_specific.h" #include "lib/jxl/base/matrix_ops.h" #include "lib/jxl/base/rect.h" #include "lib/jxl/base/sanitizers.h" #include "lib/jxl/base/status.h" #include "lib/jxl/cms/jxl_cms_internal.h" #include "lib/jxl/cms/opsin_params.h" #include "lib/jxl/color_encoding_internal.h" #include "lib/jxl/dec_xyb-inl.h" #include "lib/jxl/image.h" #include "lib/jxl/opsin_params.h" #include "lib/jxl/quantizer.h" HWY_BEFORE_NAMESPACE(); namespace jxl { namespace HWY_NAMESPACE { // These templates are not found via ADL. using hwy::HWY_NAMESPACE::MulAdd; Status OpsinToLinearInplace(Image3F* JXL_RESTRICT inout, ThreadPool* pool, const OpsinParams& opsin_params) { JXL_CHECK_IMAGE_INITIALIZED(*inout, Rect(*inout)); const size_t xsize = inout->xsize(); // not padded const auto process_row = [&](const uint32_t task, size_t /* thread */) -> Status { const size_t y = task; // Faster than adding via ByteOffset at end of loop. float* JXL_RESTRICT row0 = inout->PlaneRow(0, y); float* JXL_RESTRICT row1 = inout->PlaneRow(1, y); float* JXL_RESTRICT row2 = inout->PlaneRow(2, y); const HWY_FULL(float) d; for (size_t x = 0; x < xsize; x += Lanes(d)) { const auto in_opsin_x = Load(d, row0 + x); const auto in_opsin_y = Load(d, row1 + x); const auto in_opsin_b = Load(d, row2 + x); auto linear_r = Undefined(d); auto linear_g = Undefined(d); auto linear_b = Undefined(d); XybToRgb(d, in_opsin_x, in_opsin_y, in_opsin_b, opsin_params, &linear_r, &linear_g, &linear_b); Store(linear_r, d, row0 + x); Store(linear_g, d, row1 + x); Store(linear_b, d, row2 + x); } return true; }; JXL_RETURN_IF_ERROR(RunOnPool(pool, 0, inout->ysize(), ThreadPool::NoInit, process_row, "OpsinToLinear")); return true; } // Same, but not in-place. Status OpsinToLinear(const Image3F& opsin, const Rect& rect, ThreadPool* pool, Image3F* JXL_RESTRICT linear, const OpsinParams& opsin_params) { JXL_ENSURE(SameSize(rect, *linear)); JXL_CHECK_IMAGE_INITIALIZED(opsin, rect); const auto process_row = [&](const uint32_t task, size_t /*thread*/) -> Status { const size_t y = static_cast(task); // Faster than adding via ByteOffset at end of loop. const float* JXL_RESTRICT row_opsin_0 = rect.ConstPlaneRow(opsin, 0, y); const float* JXL_RESTRICT row_opsin_1 = rect.ConstPlaneRow(opsin, 1, y); const float* JXL_RESTRICT row_opsin_2 = rect.ConstPlaneRow(opsin, 2, y); float* JXL_RESTRICT row_linear_0 = linear->PlaneRow(0, y); float* JXL_RESTRICT row_linear_1 = linear->PlaneRow(1, y); float* JXL_RESTRICT row_linear_2 = linear->PlaneRow(2, y); const HWY_FULL(float) d; for (size_t x = 0; x < rect.xsize(); x += Lanes(d)) { const auto in_opsin_x = Load(d, row_opsin_0 + x); const auto in_opsin_y = Load(d, row_opsin_1 + x); const auto in_opsin_b = Load(d, row_opsin_2 + x); auto linear_r = Undefined(d); auto linear_g = Undefined(d); auto linear_b = Undefined(d); XybToRgb(d, in_opsin_x, in_opsin_y, in_opsin_b, opsin_params, &linear_r, &linear_g, &linear_b); Store(linear_r, d, row_linear_0 + x); Store(linear_g, d, row_linear_1 + x); Store(linear_b, d, row_linear_2 + x); } return true; }; JXL_RETURN_IF_ERROR(RunOnPool(pool, 0, static_cast(rect.ysize()), ThreadPool::NoInit, process_row, "OpsinToLinear(Rect)")); JXL_CHECK_IMAGE_INITIALIZED(*linear, rect); return true; } // Transform YCbCr to RGB. // Could be performed in-place (i.e. Y, Cb and Cr could alias R, B and B). void YcbcrToRgb(const Image3F& ycbcr, Image3F* rgb, const Rect& rect) { JXL_CHECK_IMAGE_INITIALIZED(ycbcr, rect); const HWY_CAPPED(float, kBlockDim) df; const size_t S = Lanes(df); // Step. const size_t xsize = rect.xsize(); const size_t ysize = rect.ysize(); if ((xsize == 0) || (ysize == 0)) return; // Full-range BT.601 as defined by JFIF Clause 7: // https://www.itu.int/rec/T-REC-T.871-201105-I/en const auto c128 = Set(df, 128.0f / 255); const auto crcr = Set(df, 1.402f); const auto cgcb = Set(df, -0.114f * 1.772f / 0.587f); const auto cgcr = Set(df, -0.299f * 1.402f / 0.587f); const auto cbcb = Set(df, 1.772f); for (size_t y = 0; y < ysize; y++) { const float* y_row = rect.ConstPlaneRow(ycbcr, 1, y); const float* cb_row = rect.ConstPlaneRow(ycbcr, 0, y); const float* cr_row = rect.ConstPlaneRow(ycbcr, 2, y); float* r_row = rect.PlaneRow(rgb, 0, y); float* g_row = rect.PlaneRow(rgb, 1, y); float* b_row = rect.PlaneRow(rgb, 2, y); for (size_t x = 0; x < xsize; x += S) { const auto y_vec = Add(Load(df, y_row + x), c128); const auto cb_vec = Load(df, cb_row + x); const auto cr_vec = Load(df, cr_row + x); const auto r_vec = MulAdd(crcr, cr_vec, y_vec); const auto g_vec = MulAdd(cgcr, cr_vec, MulAdd(cgcb, cb_vec, y_vec)); const auto b_vec = MulAdd(cbcb, cb_vec, y_vec); Store(r_vec, df, r_row + x); Store(g_vec, df, g_row + x); Store(b_vec, df, b_row + x); } } JXL_CHECK_IMAGE_INITIALIZED(*rgb, rect); } // NOLINTNEXTLINE(google-readability-namespace-comments) } // namespace HWY_NAMESPACE } // namespace jxl HWY_AFTER_NAMESPACE(); #if HWY_ONCE namespace jxl { HWY_EXPORT(OpsinToLinearInplace); Status OpsinToLinearInplace(Image3F* JXL_RESTRICT inout, ThreadPool* pool, const OpsinParams& opsin_params) { return HWY_DYNAMIC_DISPATCH(OpsinToLinearInplace)(inout, pool, opsin_params); } HWY_EXPORT(OpsinToLinear); Status OpsinToLinear(const Image3F& opsin, const Rect& rect, ThreadPool* pool, Image3F* JXL_RESTRICT linear, const OpsinParams& opsin_params) { return HWY_DYNAMIC_DISPATCH(OpsinToLinear)(opsin, rect, pool, linear, opsin_params); } HWY_EXPORT(YcbcrToRgb); void YcbcrToRgb(const Image3F& ycbcr, Image3F* rgb, const Rect& rect) { HWY_DYNAMIC_DISPATCH(YcbcrToRgb)(ycbcr, rgb, rect); } HWY_EXPORT(HasFastXYBTosRGB8); bool HasFastXYBTosRGB8() { return HWY_DYNAMIC_DISPATCH(HasFastXYBTosRGB8)(); } HWY_EXPORT(FastXYBTosRGB8); Status FastXYBTosRGB8(const float* input[4], uint8_t* output, bool is_rgba, size_t xsize) { return HWY_DYNAMIC_DISPATCH(FastXYBTosRGB8)(input, output, is_rgba, xsize); } void OpsinParams::Init(float intensity_target) { InitSIMDInverseMatrix(GetOpsinAbsorbanceInverseMatrix(), inverse_opsin_matrix, intensity_target); memcpy(opsin_biases, jxl::cms::kNegOpsinAbsorbanceBiasRGB.data(), sizeof(jxl::cms::kNegOpsinAbsorbanceBiasRGB)); memcpy(quant_biases, kDefaultQuantBias, sizeof(kDefaultQuantBias)); for (size_t c = 0; c < 4; c++) { opsin_biases_cbrt[c] = cbrtf(opsin_biases[c]); } } bool CanOutputToColorEncoding(const ColorEncoding& c_desired) { if (!c_desired.HaveFields()) { return false; } // TODO(veluca): keep in sync with dec_reconstruct.cc const auto& tf = c_desired.Tf(); if (!tf.IsPQ() && !tf.IsSRGB() && !tf.have_gamma && !tf.IsLinear() && !tf.IsHLG() && !tf.IsDCI() && !tf.Is709()) { return false; } if (c_desired.IsGray() && c_desired.GetWhitePointType() != WhitePoint::kD65) { // TODO(veluca): figure out what should happen here. return false; } return true; } Status OutputEncodingInfo::SetFromMetadata(const CodecMetadata& metadata) { orig_color_encoding = metadata.m.color_encoding; orig_intensity_target = metadata.m.IntensityTarget(); desired_intensity_target = orig_intensity_target; const auto& im = metadata.transform_data.opsin_inverse_matrix; orig_inverse_matrix = im.inverse_matrix; default_transform = im.all_default; xyb_encoded = metadata.m.xyb_encoded; std::copy(std::begin(im.opsin_biases), std::end(im.opsin_biases), opsin_params.opsin_biases); for (int i = 0; i < 3; ++i) { opsin_params.opsin_biases_cbrt[i] = cbrtf(opsin_params.opsin_biases[i]); } opsin_params.opsin_biases_cbrt[3] = opsin_params.opsin_biases[3] = 1; std::copy(std::begin(im.quant_biases), std::end(im.quant_biases), opsin_params.quant_biases); bool orig_ok = CanOutputToColorEncoding(orig_color_encoding); bool orig_grey = orig_color_encoding.IsGray(); return SetColorEncoding(!xyb_encoded || orig_ok ? orig_color_encoding : ColorEncoding::LinearSRGB(orig_grey)); } Status OutputEncodingInfo::MaybeSetColorEncoding( const ColorEncoding& c_desired) { if (c_desired.GetColorSpace() == ColorSpace::kXYB && ((color_encoding.GetColorSpace() == ColorSpace::kRGB && color_encoding.GetPrimariesType() != Primaries::kSRGB) || color_encoding.Tf().IsPQ())) { return false; } if (!xyb_encoded && !CanOutputToColorEncoding(c_desired)) { return false; } return SetColorEncoding(c_desired); } Status OutputEncodingInfo::SetColorEncoding(const ColorEncoding& c_desired) { color_encoding = c_desired; linear_color_encoding = color_encoding; linear_color_encoding.Tf().SetTransferFunction(TransferFunction::kLinear); color_encoding_is_original = orig_color_encoding.SameColorEncoding(c_desired); // Compute the opsin inverse matrix and luminances based on primaries and // white point. Matrix3x3 inverse_matrix; bool inverse_matrix_is_default = default_transform; inverse_matrix = orig_inverse_matrix; constexpr Vector3 kSRGBLuminances{0.2126, 0.7152, 0.0722}; luminances = kSRGBLuminances; if ((c_desired.GetPrimariesType() != Primaries::kSRGB || c_desired.GetWhitePointType() != WhitePoint::kD65) && !c_desired.IsGray()) { Matrix3x3 srgb_to_xyzd50; const auto& srgb = ColorEncoding::SRGB(/*is_gray=*/false); PrimariesCIExy p; JXL_RETURN_IF_ERROR(srgb.GetPrimaries(p)); CIExy w = srgb.GetWhitePoint(); JXL_RETURN_IF_ERROR(PrimariesToXYZD50(p.r.x, p.r.y, p.g.x, p.g.y, p.b.x, p.b.y, w.x, w.y, srgb_to_xyzd50)); Matrix3x3 original_to_xyz; JXL_RETURN_IF_ERROR(c_desired.GetPrimaries(p)); w = c_desired.GetWhitePoint(); if (!PrimariesToXYZ(p.r.x, p.r.y, p.g.x, p.g.y, p.b.x, p.b.y, w.x, w.y, original_to_xyz)) { return JXL_FAILURE("PrimariesToXYZ failed"); } luminances = original_to_xyz[1]; if (xyb_encoded) { Matrix3x3 adapt_to_d50; if (!AdaptToXYZD50(c_desired.GetWhitePoint().x, c_desired.GetWhitePoint().y, adapt_to_d50)) { return JXL_FAILURE("AdaptToXYZD50 failed"); } Matrix3x3 xyzd50_to_original; Mul3x3Matrix(adapt_to_d50, original_to_xyz, xyzd50_to_original); JXL_RETURN_IF_ERROR(Inv3x3Matrix(xyzd50_to_original)); Matrix3x3 srgb_to_original; Mul3x3Matrix(xyzd50_to_original, srgb_to_xyzd50, srgb_to_original); Mul3x3Matrix(srgb_to_original, orig_inverse_matrix, inverse_matrix); inverse_matrix_is_default = false; } } if (c_desired.IsGray()) { Matrix3x3 tmp_inv_matrix = inverse_matrix; Matrix3x3 srgb_to_luma{luminances, luminances, luminances}; Mul3x3Matrix(srgb_to_luma, tmp_inv_matrix, inverse_matrix); } // The internal XYB color space uses absolute luminance, so we scale back the // opsin inverse matrix to relative luminance where 1.0 corresponds to the // original intensity target. if (xyb_encoded) { InitSIMDInverseMatrix(inverse_matrix, opsin_params.inverse_opsin_matrix, orig_intensity_target); all_default_opsin = (std::abs(orig_intensity_target - 255.0) <= 0.1f && inverse_matrix_is_default); } // Set the inverse gamma based on color space transfer function. const auto& tf = c_desired.Tf(); inverse_gamma = (tf.have_gamma ? tf.GetGamma() : tf.IsDCI() ? 1.0f / 2.6f : 1.0); return true; } } // namespace jxl #endif // HWY_ONCE