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ladybird/Userland/Libraries/LibGfx/ImageFormats/JPEGXLLoader.cpp

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LibGfx/JPEGXL: Add a JPEG-XL decoder :^) JPEG-XL is a new image format standardized by the same committee as the original JPEG image format. It has all the nice feature of recent formats, and great compression ratios. For more details, look at: https://jpegxl.info/ This decoder is far from being feature-complete, as it features a grand total of 60 FIXMEs and TODOs but anyway, it's still a good start. I developed this decoder in the Serenity way, I just try to decode a specific image while staying as close as possible to the specification. Considering that the format supports a lot of options, and that we basically support only one possibility for each of them, I'm pretty sure that we can only decode the image I've developed this decoder for. Which is: 0aff 3ffa 9101 0688 0001 004c 384b bc41 5ced 86e5 2a19 0696 03e5 4920 8038 000b
2023-07-04 04:13:34 +00:00
/*
* Copyright (c) 2023, Lucas Chollet <lucas.chollet@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/BitStream.h>
#include <AK/Endian.h>
#include <AK/FixedArray.h>
#include <AK/String.h>
#include <LibCompress/Brotli.h>
#include <LibGfx/ImageFormats/JPEGXLLoader.h>
namespace Gfx {
/// 4.2 - Functions
static ALWAYS_INLINE i32 unpack_signed(u32 u)
{
if (u % 2 == 0)
return static_cast<i32>(u / 2);
return -static_cast<i32>((u + 1) / 2);
}
///
/// B.2 - Field types
// This is defined as a macro in order to get lazy-evaluated parameter
// Note that the lambda will capture your context by reference.
#define U32(d0, d1, d2, d3) \
({ \
u8 const selector = TRY(stream.read_bits(2)); \
auto value = [&, selector]() -> ErrorOr<u32> { \
if (selector == 0) \
return (d0); \
if (selector == 1) \
return (d1); \
if (selector == 2) \
return (d2); \
if (selector == 3) \
return (d3); \
VERIFY_NOT_REACHED(); \
}(); \
TRY(value); \
})
static ALWAYS_INLINE ErrorOr<u64> U64(LittleEndianInputBitStream& stream)
{
u8 const selector = TRY(stream.read_bits(2));
if (selector == 0)
return 0;
if (selector == 1)
return 1 + TRY(stream.read_bits(4));
if (selector == 2)
return 17 + TRY(stream.read_bits(8));
VERIFY(selector == 3);
u64 value = TRY(stream.read_bits(12));
u8 shift = 12;
while (TRY(stream.read_bits(1)) == 1) {
if (shift == 60) {
value += TRY(stream.read_bits(4)) << shift;
break;
}
value += TRY(stream.read_bits(8)) << shift;
shift += 8;
}
return value;
}
///
/// D.2 - Image dimensions
struct SizeHeader {
u32 height {};
u32 width {};
};
static u32 aspect_ratio(u32 height, u32 ratio)
{
if (ratio == 1)
return height;
if (ratio == 2)
return height * 12 / 10;
if (ratio == 3)
return height * 4 / 3;
if (ratio == 4)
return height * 3 / 2;
if (ratio == 5)
return height * 16 / 9;
if (ratio == 6)
return height * 5 / 4;
if (ratio == 7)
return height * 2 / 1;
VERIFY_NOT_REACHED();
}
static ErrorOr<SizeHeader> read_size_header(LittleEndianInputBitStream& stream)
{
SizeHeader size {};
auto const div8 = TRY(stream.read_bit());
if (div8) {
auto const h_div8 = 1 + TRY(stream.read_bits(5));
size.height = 8 * h_div8;
} else {
size.height = U32(
1 + TRY(stream.read_bits(9)),
1 + TRY(stream.read_bits(13)),
1 + TRY(stream.read_bits(18)),
1 + TRY(stream.read_bits(30)));
}
auto const ratio = TRY(stream.read_bits(3));
if (ratio == 0) {
if (div8) {
auto const w_div8 = 1 + TRY(stream.read_bits(5));
size.width = 8 * w_div8;
} else {
size.width = U32(
1 + TRY(stream.read_bits(9)),
1 + TRY(stream.read_bits(13)),
1 + TRY(stream.read_bits(18)),
1 + TRY(stream.read_bits(30)));
}
} else {
size.width = aspect_ratio(size.height, ratio);
}
return size;
}
///
/// D.3.5 - BitDepth
struct BitDepth {
u32 bits_per_sample { 8 };
u8 exp_bits {};
};
static ErrorOr<BitDepth> read_bit_depth(LittleEndianInputBitStream& stream)
{
BitDepth bit_depth;
bool const float_sample = TRY(stream.read_bit());
if (float_sample) {
bit_depth.bits_per_sample = U32(32, 16, 24, 1 + TRY(stream.read_bits(6)));
bit_depth.exp_bits = 1 + TRY(stream.read_bits(4));
} else {
bit_depth.bits_per_sample = U32(8, 10, 12, 1 + TRY(stream.read_bits(6)));
}
return bit_depth;
}
///
/// E.2 - ColourEncoding
struct ColourEncoding {
enum class ColourSpace {
kRGB = 0,
kGrey = 1,
kXYB = 2,
kUnknown = 3,
};
enum class WhitePoint {
kD65 = 1,
kCustom = 2,
kE = 10,
kDCI = 11,
};
enum class Primaries {
kSRGB = 1,
kCustom = 2,
k2100 = 3,
kP3 = 11,
};
enum class RenderingIntent {
kPerceptual = 0,
kRelative = 1,
kSaturation = 2,
kAbsolute = 3,
};
struct Customxy {
u32 ux {};
u32 uy {};
};
bool want_icc = false;
ColourSpace colour_space { ColourSpace::kRGB };
WhitePoint white_point { WhitePoint::kD65 };
Primaries primaries { Primaries::kSRGB };
Customxy white {};
Customxy red {};
Customxy green {};
Customxy blue {};
RenderingIntent rendering_intent { RenderingIntent::kRelative };
};
[[maybe_unused]] static ErrorOr<ColourEncoding::Customxy> read_custom_xy(LittleEndianInputBitStream& stream)
{
ColourEncoding::Customxy custom_xy;
auto const read_custom = [&stream]() -> ErrorOr<u32> {
return U32(
TRY(stream.read_bits(19)),
524288 + TRY(stream.read_bits(19)),
1048576 + TRY(stream.read_bits(20)),
2097152 + TRY(stream.read_bits(21)));
};
custom_xy.ux = TRY(read_custom());
custom_xy.uy = TRY(read_custom());
return custom_xy;
}
static ErrorOr<ColourEncoding> read_colour_encoding(LittleEndianInputBitStream& stream)
{
ColourEncoding colour_encoding;
bool const all_default = TRY(stream.read_bit());
if (!all_default) {
TODO();
}
return colour_encoding;
}
///
/// B.3 - Extensions
struct Extensions {
u64 extensions {};
};
static ErrorOr<Extensions> read_extensions(LittleEndianInputBitStream& stream)
{
Extensions extensions;
extensions.extensions = TRY(U64(stream));
if (extensions.extensions != 0)
TODO();
return extensions;
}
///
/// K.2 - Non-separable upsampling
LibGfx/JPEGXL: Add support for x4 and x8 upsampling All the logic is exactly the same as for x2 upsampling, so this commit essentially boils down to adding arrays for default weights and the logic to select the correct array.
2023-07-22 20:49:16 +00:00
Array s_d_up2 {
LibGfx/JPEGXL: Add a JPEG-XL decoder :^) JPEG-XL is a new image format standardized by the same committee as the original JPEG image format. It has all the nice feature of recent formats, and great compression ratios. For more details, look at: https://jpegxl.info/ This decoder is far from being feature-complete, as it features a grand total of 60 FIXMEs and TODOs but anyway, it's still a good start. I developed this decoder in the Serenity way, I just try to decode a specific image while staying as close as possible to the specification. Considering that the format supports a lot of options, and that we basically support only one possibility for each of them, I'm pretty sure that we can only decode the image I've developed this decoder for. Which is: 0aff 3ffa 9101 0688 0001 004c 384b bc41 5ced 86e5 2a19 0696 03e5 4920 8038 000b
2023-07-04 04:13:34 +00:00
-0.01716200, -0.03452303, -0.04022174, -0.02921014, -0.00624645,
0.14111091, 0.28896755, 0.00278718, -0.01610267, 0.56661550,
0.03777607, -0.01986694, -0.03144731, -0.01185068, -0.00213539
};
LibGfx/JPEGXL: Add support for x4 and x8 upsampling All the logic is exactly the same as for x2 upsampling, so this commit essentially boils down to adding arrays for default weights and the logic to select the correct array.
2023-07-22 20:49:16 +00:00
Array s_d_up4 = {
-0.02419067, -0.03491987, -0.03693351, -0.03094285, -0.00529785,
-0.01663432, -0.03556863, -0.03888905, -0.03516850, -0.00989469,
0.23651958, 0.33392945, -0.01073543, -0.01313181, -0.03556694,
0.13048175, 0.40103025, 0.03951150, -0.02077584, 0.46914198,
-0.00209270, -0.01484589, -0.04064806, 0.18942530, 0.56279892,
0.06674400, -0.02335494, -0.03551682, -0.00754830, -0.02267919,
-0.02363578, 0.00315804, -0.03399098, -0.01359519, -0.00091653,
-0.00335467, -0.01163294, -0.01610294, -0.00974088, -0.00191622,
-0.01095446, -0.03198464, -0.04455121, -0.02799790, -0.00645912,
0.06390599, 0.22963888, 0.00630981, -0.01897349, 0.67537268,
0.08483369, -0.02534994, -0.02205197, -0.01667999, -0.00384443
};
Array s_d_up8 {
-0.02928613, -0.03706353, -0.03783812, -0.03324558, -0.00447632, -0.02519406, -0.03752601, -0.03901508, -0.03663285, -0.00646649,
-0.02066407, -0.03838633, -0.04002101, -0.03900035, -0.00901973, -0.01626393, -0.03954148, -0.04046620, -0.03979621, -0.01224485,
0.29895328, 0.35757708, -0.02447552, -0.01081748, -0.04314594, 0.23903219, 0.41119301, -0.00573046, -0.01450239, -0.04246845,
0.17567618, 0.45220643, 0.02287757, -0.01936783, -0.03583255, 0.11572472, 0.47416733, 0.06284440, -0.02685066, 0.42720050,
-0.02248939, -0.01155273, -0.04562755, 0.28689496, 0.49093869, -0.00007891, -0.01545926, -0.04562659, 0.21238920, 0.53980934,
0.03369474, -0.02070211, -0.03866988, 0.14229550, 0.56593398, 0.08045181, -0.02888298, -0.03680918, -0.00542229, -0.02920477,
-0.02788574, -0.02118180, -0.03942402, -0.00775547, -0.02433614, -0.03193943, -0.02030828, -0.04044014, -0.01074016, -0.01930822,
-0.03620399, -0.01974125, -0.03919545, -0.01456093, -0.00045072, -0.00360110, -0.01020207, -0.01231907, -0.00638988, -0.00071592,
-0.00279122, -0.00957115, -0.01288327, -0.00730937, -0.00107783, -0.00210156, -0.00890705, -0.01317668, -0.00813895, -0.00153491,
-0.02128481, -0.04173044, -0.04831487, -0.03293190, -0.00525260, -0.01720322, -0.04052736, -0.05045706, -0.03607317, -0.00738030,
-0.01341764, -0.03965629, -0.05151616, -0.03814886, -0.01005819, 0.18968273, 0.33063684, -0.01300105, -0.01372950, -0.04017465,
0.13727832, 0.36402234, 0.01027890, -0.01832107, -0.03365072, 0.08734506, 0.38194295, 0.04338228, -0.02525993, 0.56408126,
0.00458352, -0.01648227, -0.04887868, 0.24585519, 0.62026135, 0.04314807, -0.02213737, -0.04158014, 0.16637289, 0.65027023,
0.09621636, -0.03101388, -0.04082742, -0.00904519, -0.02790922, -0.02117818, 0.00798662, -0.03995711, -0.01243427, -0.02231705,
-0.02946266, 0.00992055, -0.03600283, -0.01684920, -0.00111684, -0.00411204, -0.01297130, -0.01723725, -0.01022545, -0.00165306,
-0.00313110, -0.01218016, -0.01763266, -0.01125620, -0.00231663, -0.01374149, -0.03797620, -0.05142937, -0.03117307, -0.00581914,
-0.01064003, -0.03608089, -0.05272168, -0.03375670, -0.00795586, 0.09628104, 0.27129991, -0.00353779, -0.01734151, -0.03153981,
0.05686230, 0.28500998, 0.02230594, -0.02374955, 0.68214326, 0.05018048, -0.02320852, -0.04383616, 0.18459474, 0.71517975,
0.10805613, -0.03263677, -0.03637639, -0.01394373, -0.02511203, -0.01728636, 0.05407331, -0.02867568, -0.01893131, -0.00240854,
-0.00446511, -0.01636187, -0.02377053, -0.01522848, -0.00333334, -0.00819975, -0.02964169, -0.04499287, -0.02745350, -0.00612408,
0.02727416, 0.19446600, 0.00159832, -0.02232473, 0.74982506, 0.11452620, -0.03348048, -0.01605681, -0.02070339, -0.00458223
};
LibGfx/JPEGXL: Add a JPEG-XL decoder :^) JPEG-XL is a new image format standardized by the same committee as the original JPEG image format. It has all the nice feature of recent formats, and great compression ratios. For more details, look at: https://jpegxl.info/ This decoder is far from being feature-complete, as it features a grand total of 60 FIXMEs and TODOs but anyway, it's still a good start. I developed this decoder in the Serenity way, I just try to decode a specific image while staying as close as possible to the specification. Considering that the format supports a lot of options, and that we basically support only one possibility for each of them, I'm pretty sure that we can only decode the image I've developed this decoder for. Which is: 0aff 3ffa 9101 0688 0001 004c 384b bc41 5ced 86e5 2a19 0696 03e5 4920 8038 000b
2023-07-04 04:13:34 +00:00
///
/// D.3 - Image metadata
struct PreviewHeader {
};
struct AnimationHeader {
};
struct ExtraChannelInfo {
};
static ErrorOr<ExtraChannelInfo> read_extra_channel_info(LittleEndianInputBitStream&)
{
TODO();
}
struct ToneMapping {
};
static ErrorOr<ToneMapping> read_tone_mapping(LittleEndianInputBitStream&)
{
TODO();
}
struct OpsinInverseMatrix {
};
static ErrorOr<OpsinInverseMatrix> read_opsin_inverse_matrix(LittleEndianInputBitStream&)
{
TODO();
}
struct ImageMetadata {
u8 orientation { 1 };
Optional<SizeHeader> intrinsic_size;
Optional<PreviewHeader> preview;
Optional<AnimationHeader> animation;
BitDepth bit_depth;
bool modular_16bit_buffers { true };
u16 num_extra_channels {};
Vector<ExtraChannelInfo, 4> ec_info;
bool xyb_encoded { true };
ColourEncoding colour_encoding;
ToneMapping tone_mapping;
Extensions extensions;
bool default_m;
OpsinInverseMatrix opsin_inverse_matrix;
u8 cw_mask { 0 };
Array<double, 15> up2_weight = s_d_up2;
LibGfx/JPEGXL: Add support for x4 and x8 upsampling All the logic is exactly the same as for x2 upsampling, so this commit essentially boils down to adding arrays for default weights and the logic to select the correct array.
2023-07-22 20:49:16 +00:00
Array<double, 55> up4_weight = s_d_up4;
Array<double, 210> up8_weight = s_d_up8;
LibGfx/JPEGXL: Add a JPEG-XL decoder :^) JPEG-XL is a new image format standardized by the same committee as the original JPEG image format. It has all the nice feature of recent formats, and great compression ratios. For more details, look at: https://jpegxl.info/ This decoder is far from being feature-complete, as it features a grand total of 60 FIXMEs and TODOs but anyway, it's still a good start. I developed this decoder in the Serenity way, I just try to decode a specific image while staying as close as possible to the specification. Considering that the format supports a lot of options, and that we basically support only one possibility for each of them, I'm pretty sure that we can only decode the image I've developed this decoder for. Which is: 0aff 3ffa 9101 0688 0001 004c 384b bc41 5ced 86e5 2a19 0696 03e5 4920 8038 000b
2023-07-04 04:13:34 +00:00
};
static ErrorOr<ImageMetadata> read_metadata_header(LittleEndianInputBitStream& stream)
{
ImageMetadata metadata;
bool const all_default = TRY(stream.read_bit());
if (!all_default) {
bool const extra_fields = TRY(stream.read_bit());
if (extra_fields) {
metadata.orientation = 1 + TRY(stream.read_bits(3));
bool const have_intr_size = TRY(stream.read_bit());
if (have_intr_size)
metadata.intrinsic_size = TRY(read_size_header(stream));
bool const have_preview = TRY(stream.read_bit());
if (have_preview)
TODO();
bool const have_animation = TRY(stream.read_bit());
if (have_animation)
TODO();
}
metadata.bit_depth = TRY(read_bit_depth(stream));
metadata.modular_16bit_buffers = TRY(stream.read_bit());
metadata.num_extra_channels = U32(0, 1, 2 + TRY(stream.read_bits(4)), 1 + TRY(stream.read_bits(12)));
for (u16 i {}; i < metadata.num_extra_channels; ++i)
metadata.ec_info.append(TRY(read_extra_channel_info(stream)));
metadata.xyb_encoded = TRY(stream.read_bit());
metadata.colour_encoding = TRY(read_colour_encoding(stream));
if (extra_fields)
metadata.tone_mapping = TRY(read_tone_mapping(stream));
metadata.extensions = TRY(read_extensions(stream));
}
metadata.default_m = TRY(stream.read_bit());
if (!metadata.default_m && metadata.xyb_encoded)
metadata.opsin_inverse_matrix = TRY(read_opsin_inverse_matrix(stream));
if (!metadata.default_m)
metadata.cw_mask = TRY(stream.read_bits(3));
if (metadata.cw_mask != 0)
TODO();
return metadata;
}
///
/// Table F.7 — BlendingInfo bundle
struct BlendingInfo {
enum class BlendMode {
kReplace = 0,
kAdd = 1,
kBlend = 2,
kMulAdd = 3,
kMul = 4,
};
BlendMode mode {};
u8 alpha_channel {};
u8 clamp {};
u8 source {};
};
static ErrorOr<BlendingInfo> read_blending_info(LittleEndianInputBitStream& stream, ImageMetadata const& metadata, bool have_crop)
{
BlendingInfo blending_info;
blending_info.mode = static_cast<BlendingInfo::BlendMode>(U32(0, 1, 2, 3 + TRY(stream.read_bits(2))));
bool const extra = metadata.num_extra_channels > 0;
// FIXME: also consider "cropped" image of the dimension of the frame
VERIFY(!have_crop);
bool const full_frame = !have_crop;
if (extra) {
TODO();
}
if (blending_info.mode != BlendingInfo::BlendMode::kReplace
|| !full_frame) {
blending_info.source = TRY(stream.read_bits(2));
}
return blending_info;
}
///
/// J.1 - General
struct RestorationFilter {
bool gab { true };
u8 epf_iters { 2 };
Extensions extensions;
};
static ErrorOr<RestorationFilter> read_restoration_filter(LittleEndianInputBitStream& stream)
{
RestorationFilter restoration_filter;
auto const all_defaults = TRY(stream.read_bit());
if (!all_defaults) {
restoration_filter.gab = TRY(stream.read_bit());
if (restoration_filter.gab) {
TODO();
}
restoration_filter.epf_iters = TRY(stream.read_bits(2));
if (restoration_filter.epf_iters != 0) {
TODO();
}
restoration_filter.extensions = TRY(read_extensions(stream));
}
return restoration_filter;
}
///
/// Table F.6 — Passes bundle
struct Passes {
u8 num_passes { 1 };
};
static ErrorOr<Passes> read_passes(LittleEndianInputBitStream& stream)
{
Passes passes;
passes.num_passes = U32(1, 2, 3, 4 + TRY(stream.read_bits(3)));
if (passes.num_passes != 1) {
TODO();
}
return passes;
}
///
/// F.2 - FrameHeader
struct FrameHeader {
enum class FrameType {
kRegularFrame = 0,
kLFFrame = 1,
kReferenceOnly = 2,
kSkipProgressive = 3,
};
enum class Encoding {
kVarDCT = 0,
kModular = 1,
};
enum class Flags {
None = 0,
kNoise = 1,
kPatches = 1 << 1,
kSplines = 1 << 4,
kUseLfFrame = 1 << 5,
kSkipAdaptiveLFSmoothing = 1 << 7,
};
FrameType frame_type { FrameType::kRegularFrame };
Encoding encoding { Encoding::kVarDCT };
Flags flags { Flags::None };
bool do_YCbCr { false };
Array<u8, 3> jpeg_upsampling {};
u8 upsampling {};
Vector<u8> ec_upsampling {};
u8 group_size_shift { 1 };
Passes passes {};
u8 lf_level {};
bool have_crop { false };
BlendingInfo blending_info {};
bool is_last { true };
bool save_before_ct {};
String name {};
RestorationFilter restoration_filter {};
Extensions extensions {};
};
static int operator&(FrameHeader::Flags first, FrameHeader::Flags second)
{
return static_cast<int>(first) & static_cast<int>(second);
}
static ErrorOr<FrameHeader> read_frame_header(LittleEndianInputBitStream& stream, ImageMetadata const& metadata)
{
FrameHeader frame_header;
bool const all_default = TRY(stream.read_bit());
if (!all_default) {
frame_header.frame_type = static_cast<FrameHeader::FrameType>(TRY(stream.read_bits(2)));
frame_header.encoding = static_cast<FrameHeader::Encoding>(TRY(stream.read_bits(1)));
frame_header.flags = static_cast<FrameHeader::Flags>(TRY(U64(stream)));
if (!metadata.xyb_encoded)
frame_header.do_YCbCr = TRY(stream.read_bit());
if (!(frame_header.flags & FrameHeader::Flags::kUseLfFrame)) {
if (frame_header.do_YCbCr) {
frame_header.jpeg_upsampling[0] = TRY(stream.read_bits(2));
frame_header.jpeg_upsampling[1] = TRY(stream.read_bits(2));
frame_header.jpeg_upsampling[2] = TRY(stream.read_bits(2));
}
frame_header.upsampling = U32(1, 2, 4, 8);
for (u16 i {}; i < metadata.num_extra_channels; ++i)
TODO();
}
if (frame_header.encoding == FrameHeader::Encoding::kModular)
frame_header.group_size_shift = TRY(stream.read_bits(2));
if (frame_header.encoding == FrameHeader::Encoding::kVarDCT)
TODO();
if (frame_header.frame_type != FrameHeader::FrameType::kReferenceOnly)
frame_header.passes = TRY(read_passes(stream));
if (frame_header.frame_type == FrameHeader::FrameType::kLFFrame)
TODO();
if (frame_header.frame_type != FrameHeader::FrameType::kLFFrame)
frame_header.have_crop = TRY(stream.read_bit());
if (frame_header.have_crop)
TODO();
bool const normal_frame = frame_header.frame_type == FrameHeader::FrameType::kRegularFrame
|| frame_header.frame_type == FrameHeader::FrameType::kSkipProgressive;
if (normal_frame) {
frame_header.blending_info = TRY(read_blending_info(stream, metadata, frame_header.have_crop));
for (u16 i {}; i < metadata.num_extra_channels; ++i)
TODO();
if (metadata.animation.has_value())
TODO();
frame_header.is_last = TRY(stream.read_bit());
}
// FIXME: Ensure that is_last has the correct default value
VERIFY(normal_frame);
if (frame_header.frame_type != FrameHeader::FrameType::kLFFrame) {
if (!frame_header.is_last)
TODO();
frame_header.save_before_ct = TRY(stream.read_bit());
}
// FIXME: Ensure that save_before_ct has the correct default value
VERIFY(frame_header.frame_type != FrameHeader::FrameType::kLFFrame);
auto const name_length = U32(0, TRY(stream.read_bits(4)), 16 + TRY(stream.read_bits(5)), 48 + TRY(stream.read_bits(10)));
auto string_buffer = TRY(FixedArray<u8>::create(name_length));
TRY(stream.read_until_filled(string_buffer.span()));
frame_header.name = TRY(String::from_utf8(StringView { string_buffer.span() }));
frame_header.restoration_filter = TRY(read_restoration_filter(stream));
frame_header.extensions = TRY(read_extensions(stream));
}
return frame_header;
}
///
/// F.3 TOC
struct TOC {
FixedArray<u32> entries;
FixedArray<u32> group_offsets;
};
static u64 num_toc_entries(FrameHeader const& frame_header, u64 num_groups, u64 num_lf_groups)
{
if (num_groups == 1 && frame_header.passes.num_passes == 1)
return 1;
// Otherwise, there is one entry for each of the following sections,
// in the order they are listed: LfGlobal, one per LfGroup in raster
// order, one for HfGlobal followed by HfPass data for all the passes,
// and num_groups * frame_header.passes.num_passes for the PassGroup sections.
auto const hf_contribution = frame_header.encoding == FrameHeader::Encoding::kVarDCT ? (1 + frame_header.passes.num_passes) : 0;
return 1 + num_lf_groups + hf_contribution + num_groups * frame_header.passes.num_passes;
}
static ErrorOr<TOC> read_toc(LittleEndianInputBitStream& stream, FrameHeader const& frame_header, u64 num_groups, u64 num_lf_groups)
{
TOC toc;
bool const permuted_toc = TRY(stream.read_bit());
if (permuted_toc) {
// Read permutations
TODO();
}
// F.3.3 - Decoding TOC
stream.align_to_byte_boundary();
auto const toc_entries = num_toc_entries(frame_header, num_groups, num_lf_groups);
toc.entries = TRY(FixedArray<u32>::create(toc_entries));
toc.group_offsets = TRY(FixedArray<u32>::create(toc_entries));
for (u32 i {}; i < toc_entries; ++i) {
auto const new_entry = U32(
TRY(stream.read_bits(10)),
1024 + TRY(stream.read_bits(14)),
17408 + TRY(stream.read_bits(22)),
4211712 + TRY(stream.read_bits(30)));
toc.entries[i] = new_entry;
toc.group_offsets[i] = (i == 0 ? 0 : toc.group_offsets[i - 1]) + new_entry;
}
if (permuted_toc)
TODO();
stream.align_to_byte_boundary();
return toc;
}
///
/// G.1.2 - LF channel dequantization weights
struct LfChannelDequantization {
float m_x_lf_unscaled { 4096 };
float m_y_lf_unscaled { 512 };
float m_b_lf_unscaled { 256 };
};
static ErrorOr<LfChannelDequantization> read_lf_channel_dequantization(LittleEndianInputBitStream& stream)
{
LfChannelDequantization lf_channel_dequantization;
auto const all_default = TRY(stream.read_bit());
if (!all_default) {
TODO();
}
return lf_channel_dequantization;
}
///
/// C - Entropy decoding
class EntropyDecoder {
using BrotliCanonicalCode = Compress::Brotli::CanonicalCode;
public:
static ErrorOr<EntropyDecoder> create(LittleEndianInputBitStream& stream, u8 initial_num_distrib)
{
EntropyDecoder entropy_decoder;
// C.2 - Distribution decoding
entropy_decoder.m_lz77_enabled = TRY(stream.read_bit());
if (entropy_decoder.m_lz77_enabled) {
TODO();
}
TRY(entropy_decoder.read_pre_clustered_distributions(stream, initial_num_distrib));
bool const use_prefix_code = TRY(stream.read_bit());
if (!use_prefix_code)
entropy_decoder.m_log_alphabet_size = 5 + TRY(stream.read_bits(2));
for (auto& config : entropy_decoder.m_configs)
config = TRY(entropy_decoder.read_config(stream));
Vector<u16> counts;
TRY(counts.try_resize(entropy_decoder.m_configs.size()));
TRY(entropy_decoder.m_distributions.try_resize(entropy_decoder.m_configs.size()));
if (use_prefix_code) {
for (auto& count : counts) {
if (TRY(stream.read_bit())) {
auto const n = TRY(stream.read_bits(4));
count = 1 + (1 << n) + TRY(stream.read_bits(n));
} else {
count = 1;
}
}
// After reading the counts, the decoder reads each D[i] (implicitly
// described by a prefix code) as specified in C.2.4, with alphabet_size = count[i].
for (u32 i {}; i < entropy_decoder.m_distributions.size(); ++i) {
// The alphabet size mentioned in the [Brotli] RFC is explicitly specified as parameter alphabet_size
// when the histogram is being decoded, except in the special case of alphabet_size == 1, where no
// histogram is read, and all decoded symbols are zero without reading any bits at all.
if (counts[i] != 1) {
entropy_decoder.m_distributions[i] = TRY(BrotliCanonicalCode::read_prefix_code(stream, counts[i]));
} else {
entropy_decoder.m_distributions[i] = BrotliCanonicalCode { { 1 }, { 0 } };
}
}
} else {
TODO();
}
return entropy_decoder;
}
ErrorOr<u32> decode_hybrid_uint(LittleEndianInputBitStream& stream, u16 context)
{
// C.3.3 - Hybrid integer decoding
if (m_lz77_enabled)
TODO();
// Read symbol from entropy coded stream using D[clusters[ctx]]
auto const token = TRY(m_distributions[m_clusters[context]].read_symbol(stream));
auto r = TRY(read_uint(stream, m_configs[m_clusters[context]], token));
return r;
}
private:
struct HybridUint {
u32 split_exponent {};
u32 split {};
u32 msb_in_token {};
u32 lsb_in_token {};
};
static ErrorOr<u32> read_uint(LittleEndianInputBitStream& stream, HybridUint const& config, u32 token)
{
if (token < config.split)
return token;
auto const n = config.split_exponent
- config.msb_in_token
- config.lsb_in_token
+ ((token - config.split) >> (config.msb_in_token + config.lsb_in_token));
VERIFY(n < 32);
u32 const low_bits = token & ((1 << config.lsb_in_token) - 1);
token = token >> config.lsb_in_token;
token &= (1 << config.msb_in_token) - 1;
token |= (1 << config.msb_in_token);
auto const result = ((token << n | TRY(stream.read_bits(n))) << config.lsb_in_token) | low_bits;
VERIFY(result < (1ul << 32));
return result;
}
ErrorOr<void> read_pre_clustered_distributions(LittleEndianInputBitStream& stream, u8 num_distrib)
{
// C.2.2 Distribution clustering
if (num_distrib == 1)
TODO();
TRY(m_clusters.try_resize(num_distrib));
bool const is_simple = TRY(stream.read_bit());
u16 num_clusters = 0;
if (is_simple) {
u8 const nbits = TRY(stream.read_bits(2));
for (u8 i {}; i < num_distrib; ++i) {
m_clusters[i] = TRY(stream.read_bits(nbits));
if (m_clusters[i] >= num_clusters)
num_clusters = m_clusters[i] + 1;
}
} else {
TODO();
}
TRY(m_configs.try_resize(num_clusters));
return {};
}
ErrorOr<HybridUint> read_config(LittleEndianInputBitStream& stream) const
{
// C.2.3 - Hybrid integer configuration
HybridUint config {};
config.split_exponent = TRY(stream.read_bits(ceil(log2(m_log_alphabet_size + 1))));
if (config.split_exponent != m_log_alphabet_size) {
auto nbits = ceil(log2(config.split_exponent + 1));
config.msb_in_token = TRY(stream.read_bits(nbits));
nbits = ceil(log2(config.split_exponent - config.msb_in_token + 1));
config.lsb_in_token = TRY(stream.read_bits(nbits));
} else {
config.msb_in_token = 0;
config.lsb_in_token = 0;
}
config.split = 1 << config.split_exponent;
return config;
}
bool m_lz77_enabled {};
Vector<u32> m_clusters;
Vector<HybridUint> m_configs;
u8 m_log_alphabet_size { 15 };
Vector<BrotliCanonicalCode> m_distributions; // D in the spec
};
///
/// H.4.2 - MA tree decoding
class MATree {
public:
struct LeafNode {
u8 ctx {};
u8 predictor {};
i32 offset {};
u32 multiplier {};
};
static ErrorOr<MATree> decode(LittleEndianInputBitStream& stream, Optional<EntropyDecoder>& decoder)
{
// G.1.3 - GlobalModular
MATree tree;
// 1 / 2 Read the 6 pre-clustered distributions
auto const num_distrib = 6;
if (!decoder.has_value())
decoder = TRY(EntropyDecoder::create(stream, num_distrib));
// 2 / 2 Decode the tree
u64 ctx_id = 0;
u64 nodes_left = 1;
tree.m_tree.clear();
while (nodes_left > 0) {
nodes_left--;
i32 const property = TRY(decoder->decode_hybrid_uint(stream, 1)) - 1;
if (property >= 0) {
DecisionNode decision_node;
decision_node.property = property;
decision_node.value = unpack_signed(TRY(decoder->decode_hybrid_uint(stream, 0)));
decision_node.left_child = tree.m_tree.size() + nodes_left + 1;
decision_node.right_child = tree.m_tree.size() + nodes_left + 2;
tree.m_tree.empend(decision_node);
nodes_left += 2;
} else {
LeafNode leaf_node;
leaf_node.ctx = ctx_id++;
leaf_node.predictor = TRY(decoder->decode_hybrid_uint(stream, 2));
leaf_node.offset = unpack_signed(TRY(decoder->decode_hybrid_uint(stream, 3)));
auto const mul_log = TRY(decoder->decode_hybrid_uint(stream, 4));
auto const mul_bits = TRY(decoder->decode_hybrid_uint(stream, 5));
leaf_node.multiplier = (mul_bits + 1) << mul_log;
tree.m_tree.empend(leaf_node);
}
}
// Finally, the decoder reads (tree.size() + 1) / 2 pre-clustered distributions D as specified in C.1.
auto const num_pre_clustered_distributions = (tree.m_tree.size() + 1) / 2;
decoder = TRY(decoder->create(stream, num_pre_clustered_distributions));
return tree;
}
LeafNode get_leaf(Vector<i32> const& properties) const
{
// To find the MA leaf node, the MA tree is traversed, starting at the root node tree[0]
// and for each decision node d, testing if property[d.property] > d.value, proceeding to
// the node tree[d.left_child] if the test evaluates to true and to the node tree[d.right_child]
// otherwise, until a leaf node is reached.
DecisionNode node { m_tree[0].get<DecisionNode>() };
while (true) {
auto const next_node = [this, &properties, &node]() {
// Note: The behavior when trying to access a non-existing property is taken from jxl-oxide
if (node.property < properties.size() && properties[node.property] > node.value)
return m_tree[node.left_child];
return m_tree[node.right_child];
}();
if (next_node.has<LeafNode>())
return next_node.get<LeafNode>();
node = next_node.get<DecisionNode>();
}
}
private:
struct DecisionNode {
u64 property {};
i64 value {};
u64 left_child {};
u64 right_child {};
};
Vector<Variant<DecisionNode, LeafNode>> m_tree;
};
///
/// H.5 - Self-correcting predictor
struct WPHeader {
u8 wp_p1 { 16 };
u8 wp_p2 { 10 };
u8 wp_p3a { 7 };
u8 wp_p3b { 7 };
u8 wp_p3c { 7 };
u8 wp_p3d { 0 };
u8 wp_p3e { 0 };
u8 wp_w0 { 13 };
u8 wp_w1 { 12 };
u8 wp_w2 { 12 };
u8 wp_w3 { 12 };
};
static ErrorOr<WPHeader> read_self_correcting_predictor(LittleEndianInputBitStream& stream)
{
WPHeader self_correcting_predictor {};
bool const default_wp = TRY(stream.read_bit());
if (!default_wp) {
TODO();
}
return self_correcting_predictor;
}
///
///
struct TransformInfo {
enum class TransformId {
kRCT = 0,
kPalette = 1,
kSqueeze = 2,
};
TransformId tr {};
u32 begin_c {};
u32 rct_type {};
};
static ErrorOr<TransformInfo> read_transform_info(LittleEndianInputBitStream& stream)
{
TransformInfo transform_info;
transform_info.tr = static_cast<TransformInfo::TransformId>(TRY(stream.read_bits(2)));
if (transform_info.tr != TransformInfo::TransformId::kSqueeze) {
transform_info.begin_c = U32(
TRY(stream.read_bits(3)),
8 + TRY(stream.read_bits(3)),
72 + TRY(stream.read_bits(10)),
1096 + TRY(stream.read_bits(13)));
}
if (transform_info.tr == TransformInfo::TransformId::kRCT) {
transform_info.rct_type = U32(
6,
TRY(stream.read_bits(2)),
2 + TRY(stream.read_bits(4)),
10 + TRY(stream.read_bits(6)));
}
if (transform_info.tr != TransformInfo::TransformId::kRCT)
TODO();
return transform_info;
}
///
/// Local abstractions to store the decoded image
class Channel {
public:
static ErrorOr<Channel> create(u32 width, u32 height)
{
Channel channel;
channel.m_width = width;
channel.m_height = height;
TRY(channel.m_pixels.try_resize(channel.m_width * channel.m_height));
return channel;
}
i32 get(u32 x, u32 y) const
{
return m_pixels[x * m_width + y];
}
void set(u32 x, u32 y, i32 value)
{
m_pixels[x * m_width + y] = value;
}
u32 width() const
{
return m_width;
}
u32 height() const
{
return m_height;
}
u32 hshift() const
{
return m_hshift;
}
u32 vshift() const
{
return m_vshift;
}
private:
u32 m_width {};
u32 m_height {};
u32 m_hshift {};
u32 m_vshift {};
Vector<i32> m_pixels {};
};
class Image {
public:
static ErrorOr<Image> create(IntSize size)
{
Image image {};
// FIXME: Don't assume three channels and a fixed size
TRY(image.m_channels.try_append(TRY(Channel::create(size.width(), size.height()))));
TRY(image.m_channels.try_append(TRY(Channel::create(size.width(), size.height()))));
TRY(image.m_channels.try_append(TRY(Channel::create(size.width(), size.height()))));
return image;
}
ErrorOr<NonnullRefPtr<Bitmap>> to_bitmap(u8 bits_per_sample) const
{
// FIXME: which channel size should we use?
auto const width = m_channels[0].width();
auto const height = m_channels[0].height();
auto bitmap = TRY(Bitmap::create(BitmapFormat::BGRx8888, { width, height }));
// FIXME: This assumes a raw image with RGB channels, other cases are possible
LibGfx/JPEGXL: Accept images with high bit depth Instead of rejecting them, we truncate each value to 8 bits. This is clearly a hack, but given the lack of support of variable bit-depth in `Bitmap` this is the only sensible change. This allows us to display "Iceberg" on https://jpegxl.info/art/.
2023-06-24 18:38:02 +00:00
VERIFY(bits_per_sample >= 8);
LibGfx/JPEGXL: Add a JPEG-XL decoder :^) JPEG-XL is a new image format standardized by the same committee as the original JPEG image format. It has all the nice feature of recent formats, and great compression ratios. For more details, look at: https://jpegxl.info/ This decoder is far from being feature-complete, as it features a grand total of 60 FIXMEs and TODOs but anyway, it's still a good start. I developed this decoder in the Serenity way, I just try to decode a specific image while staying as close as possible to the specification. Considering that the format supports a lot of options, and that we basically support only one possibility for each of them, I'm pretty sure that we can only decode the image I've developed this decoder for. Which is: 0aff 3ffa 9101 0688 0001 004c 384b bc41 5ced 86e5 2a19 0696 03e5 4920 8038 000b
2023-07-04 04:13:34 +00:00
for (u32 y {}; y < height; ++y) {
for (u32 x {}; x < width; ++x) {
auto const to_u8 = [&, bits_per_sample](i32 sample) -> u8 {
LibGfx/JPEGXL: Accept images with high bit depth Instead of rejecting them, we truncate each value to 8 bits. This is clearly a hack, but given the lack of support of variable bit-depth in `Bitmap` this is the only sensible change. This allows us to display "Iceberg" on https://jpegxl.info/art/.
2023-06-24 18:38:02 +00:00
// FIXME: Don't truncate the result to 8 bits
static constexpr auto maximum_supported_bit_depth = 8;
if (bits_per_sample > maximum_supported_bit_depth)
sample >>= (bits_per_sample - maximum_supported_bit_depth);
return clamp(sample + .5, 0, (1 << maximum_supported_bit_depth) - 1);
LibGfx/JPEGXL: Add a JPEG-XL decoder :^) JPEG-XL is a new image format standardized by the same committee as the original JPEG image format. It has all the nice feature of recent formats, and great compression ratios. For more details, look at: https://jpegxl.info/ This decoder is far from being feature-complete, as it features a grand total of 60 FIXMEs and TODOs but anyway, it's still a good start. I developed this decoder in the Serenity way, I just try to decode a specific image while staying as close as possible to the specification. Considering that the format supports a lot of options, and that we basically support only one possibility for each of them, I'm pretty sure that we can only decode the image I've developed this decoder for. Which is: 0aff 3ffa 9101 0688 0001 004c 384b bc41 5ced 86e5 2a19 0696 03e5 4920 8038 000b
2023-07-04 04:13:34 +00:00
};
Color const color {
to_u8(m_channels[0].get(x, y)),
to_u8(m_channels[1].get(x, y)),
to_u8(m_channels[2].get(x, y)),
};
bitmap->set_pixel(x, y, color);
}
}
return bitmap;
}
Vector<Channel>& channels()
{
return m_channels;
}
private:
Vector<Channel> m_channels;
};
///
/// H.2 - Image decoding
struct ModularHeader {
bool use_global_tree {};
WPHeader wp_params {};
Vector<TransformInfo> transform {};
};
static ErrorOr<Vector<i32>> get_properties(Vector<Channel> const& channels, u16 i, u32 x, u32 y)
{
Vector<i32> properties;
// Table H.4 - Property definitions
TRY(properties.try_append(i));
// FIXME: Handle other cases than GlobalModular
TRY(properties.try_append(0));
TRY(properties.try_append(y));
TRY(properties.try_append(x));
i32 const W = x > 0 ? channels[i].get(x - 1, y) : (y > 0 ? channels[i].get(x, y - 1) : 0);
i32 const N = y > 0 ? channels[i].get(x, y - 1) : W;
i32 const NW = x > 0 && y > 0 ? channels[i].get(x - 1, y - 1) : W;
i32 const NE = x + 1 < channels[i].width() && y > 0 ? channels[i].get(x + 1, y - 1) : N;
i32 const NN = y > 1 ? channels[i].get(x, y - 2) : N;
i32 const WW = x > 1 ? channels[i].get(x - 2, y) : W;
TRY(properties.try_append(abs(N)));
TRY(properties.try_append(abs(W)));
TRY(properties.try_append(N));
TRY(properties.try_append(W));
// x > 0 ? W - /* (the value of property 9 at position (x - 1, y)) */ : W
i32 x_1 = x - 1;
i32 const W_x_1 = x_1 > 0 ? channels[i].get(x_1 - 1, y) : (x_1 >= 0 && y > 0 ? channels[i].get(x_1, y - 1) : 0);
i32 const N_x_1 = x_1 >= 0 && y > 0 ? channels[i].get(x_1, y - 1) : W_x_1;
i32 const NW_x_1 = x_1 > 0 && y > 0 ? channels[i].get(x_1 - 1, y - 1) : W_x_1;
TRY(properties.try_append(W_x_1 + N_x_1 - NW_x_1));
TRY(properties.try_append(W + N - NW));
TRY(properties.try_append(W - NW));
TRY(properties.try_append(NW - N));
TRY(properties.try_append(N - NE));
TRY(properties.try_append(N - NN));
TRY(properties.try_append(W - WW));
// FIXME: Correctly compute max_error
TRY(properties.try_append(0));
for (i16 j = i - 1; j >= 0; j--) {
if (channels[j].width() != channels[i].width())
continue;
if (channels[j].height() != channels[i].height())
continue;
if (channels[j].hshift() != channels[i].hshift())
continue;
if (channels[j].vshift() != channels[i].vshift())
continue;
auto rC = channels[j].get(x, y);
auto rW = (x > 0 ? channels[j].get(x - 1, y) : 0);
auto rN = (y > 0 ? channels[j].get(x, y - 1) : rW);
auto rNW = (x > 0 && y > 0 ? channels[j].get(x - 1, y - 1) : rW);
auto rG = clamp(rW + rN - rNW, min(rW, rN), max(rW, rN));
TRY(properties.try_append(abs(rC)));
TRY(properties.try_append(rC));
TRY(properties.try_append(abs(rC - rG)));
TRY(properties.try_append(rC - rG));
}
return properties;
}
static i32 prediction(Channel const& channel, u32 x, u32 y, u32 predictor)
{
i32 const W = x > 0 ? channel.get(x - 1, y) : (y > 0 ? channel.get(x, y - 1) : 0);
i32 const N = y > 0 ? channel.get(x, y - 1) : W;
i32 const NW = x > 0 && y > 0 ? channel.get(x - 1, y - 1) : W;
i32 const NE = x + 1 < channel.width() && y > 0 ? channel.get(x + 1, y - 1) : N;
i32 const NN = y > 1 ? channel.get(x, y - 2) : N;
i32 const NEE = x + 2 < channel.width() and y > 0 ? channel.get(x + 2, y - 1) : NE;
i32 const WW = x > 1 ? channel.get(x - 2, y) : W;
switch (predictor) {
case 0:
return 0;
case 1:
return W;
case 2:
return N;
case 3:
return (W + N) / 2;
case 4:
return abs(N - NW) < abs(W - NW) ? W : N;
case 5:
return clamp(W + N - NW, min(W, N), max(W, N));
case 6:
TODO();
return (0 + 3) >> 3;
case 7:
return NE;
case 8:
return NW;
case 9:
return WW;
case 10:
return (W + NW) / 2;
case 11:
return (N + NW) / 2;
case 12:
return (N + NE) / 2;
case 13:
return (6 * N - 2 * NN + 7 * W + WW + NEE + 3 * NE + 8) / 16;
}
VERIFY_NOT_REACHED();
}
static ErrorOr<ModularHeader> read_modular_header(LittleEndianInputBitStream& stream,
Image& image,
Optional<EntropyDecoder>& decoder,
MATree const& global_tree,
u16 num_channels)
{
ModularHeader modular_header;
modular_header.use_global_tree = TRY(stream.read_bit());
modular_header.wp_params = TRY(read_self_correcting_predictor(stream));
auto const nb_transforms = U32(0, 1, 2 + TRY(stream.read_bits(4)), 18 + TRY(stream.read_bits(8)));
TRY(modular_header.transform.try_resize(nb_transforms));
for (u32 i {}; i < nb_transforms; ++i)
modular_header.transform[i] = TRY(read_transform_info(stream));
Optional<MATree> local_tree;
if (!modular_header.use_global_tree)
TODO();
// The decoder then starts an entropy-coded stream (C.1) and decodes the data for each channel
// (in ascending order of index) as specified in H.3, skipping any channels having width or height
// zero. Finally, the inverse transformations are applied (from last to first) as described in H.6.
auto const& tree = local_tree.has_value() ? *local_tree : global_tree;
for (u16 i {}; i < num_channels; ++i) {
for (u32 y {}; y < image.channels()[i].height(); y++) {
for (u32 x {}; x < image.channels()[i].width(); x++) {
auto const properties = TRY(get_properties(image.channels(), i, x, y));
auto const leaf_node = tree.get_leaf(properties);
auto diff = unpack_signed(TRY(decoder->decode_hybrid_uint(stream, leaf_node.ctx)));
diff = (diff * leaf_node.multiplier) + leaf_node.offset;
auto const total = diff + prediction(image.channels()[i], x, y, leaf_node.predictor);
image.channels()[i].set(x, y, total);
}
}
}
return modular_header;
}
///
/// G.1.2 - LF channel dequantization weights
struct GlobalModular {
MATree ma_tree;
ModularHeader modular_header;
};
static ErrorOr<GlobalModular> read_global_modular(LittleEndianInputBitStream& stream,
Image& image,
FrameHeader const& frame_header,
ImageMetadata const& metadata,
Optional<EntropyDecoder>& entropy_decoder)
{
GlobalModular global_modular;
auto const decode_ma_tree = TRY(stream.read_bit());
if (decode_ma_tree)
global_modular.ma_tree = TRY(MATree::decode(stream, entropy_decoder));
// The decoder then decodes a modular sub-bitstream (Annex H), where
// the number of channels is computed as follows:
auto num_channels = metadata.num_extra_channels;
if (frame_header.encoding == FrameHeader::Encoding::kModular) {
if (!frame_header.do_YCbCr && !metadata.xyb_encoded
&& metadata.colour_encoding.colour_space == ColourEncoding::ColourSpace::kGrey) {
num_channels += 1;
} else {
num_channels += 3;
}
}
// FIXME: Ensure this spec comment:
// However, the decoder only decodes the first nb_meta_channels channels and any further channels
// that have a width and height that are both at most group_dim. At that point, it stops decoding.
// No inverse transforms are applied yet.
global_modular.modular_header = TRY(read_modular_header(stream, image, entropy_decoder, global_modular.ma_tree, num_channels));
return global_modular;
}
///
/// G.1 - LfGlobal
struct LfGlobal {
LfChannelDequantization lf_dequant;
GlobalModular gmodular;
};
static ErrorOr<LfGlobal> read_lf_global(LittleEndianInputBitStream& stream,
Image& image,
FrameHeader const& frame_header,
ImageMetadata const& metadata,
Optional<EntropyDecoder>& entropy_decoder)
{
LfGlobal lf_global;
if (frame_header.flags != FrameHeader::Flags::None)
TODO();
lf_global.lf_dequant = TRY(read_lf_channel_dequantization(stream));
if (frame_header.encoding == FrameHeader::Encoding::kVarDCT)
TODO();
lf_global.gmodular = TRY(read_global_modular(stream, image, frame_header, metadata, entropy_decoder));
return lf_global;
}
///
/// H.6 - Transformations
static void apply_rct(Image& image, TransformInfo const& transformation)
{
auto& channels = image.channels();
for (u32 y {}; y < channels[transformation.begin_c].height(); y++) {
for (u32 x {}; x < channels[transformation.begin_c].width(); x++) {
auto a = channels[transformation.begin_c + 0].get(x, y);
auto b = channels[transformation.begin_c + 1].get(x, y);
auto c = channels[transformation.begin_c + 2].get(x, y);
i32 d {};
i32 e {};
i32 f {};
auto const permutation = transformation.rct_type / 7;
auto const type = transformation.rct_type % 7;
if (type == 6) { // YCgCo
auto const tmp = a - (c >> 1);
e = c + tmp;
f = tmp - (b >> 1);
d = f + b;
} else {
if (type & 1)
c = c + a;
if ((type >> 1) == 1)
b = b + a;
if ((type >> 1) == 2)
b = b + ((a + c) >> 1);
d = a;
e = b;
f = c;
}
Array<i32, 3> v {};
v[permutation % 3] = d;
v[(permutation + 1 + (permutation / 3)) % 3] = e;
v[(permutation + 2 - (permutation / 3)) % 3] = f;
channels[transformation.begin_c + 0].set(x, y, v[0]);
channels[transformation.begin_c + 1].set(x, y, v[1]);
channels[transformation.begin_c + 2].set(x, y, v[2]);
}
}
}
static void apply_transformation(Image& image, TransformInfo const& transformation)
{
switch (transformation.tr) {
case TransformInfo::TransformId::kRCT:
apply_rct(image, transformation);
break;
case TransformInfo::TransformId::kPalette:
case TransformInfo::TransformId::kSqueeze:
TODO();
default:
VERIFY_NOT_REACHED();
}
}
///
/// G.3.2 - PassGroup
static ErrorOr<void> read_pass_group(LittleEndianInputBitStream& stream,
Image& image,
FrameHeader const& frame_header,
u32 group_dim,
Vector<TransformInfo> const& transform_infos)
{
if (frame_header.encoding == FrameHeader::Encoding::kVarDCT) {
(void)stream;
TODO();
}
auto& channels = image.channels();
for (u16 i {}; i < channels.size(); ++i) {
// Skip meta-channels
// FIXME: Also test if the channel has already been decoded
// See: nb_meta_channels in the spec
bool const is_meta_channel = channels[i].width() <= group_dim
|| channels[i].height() <= group_dim
|| channels[i].hshift() >= 3
|| channels[i].vshift() >= 3;
if (!is_meta_channel)
TODO();
}
for (auto const& transformation : transform_infos.in_reverse())
apply_transformation(image, transformation);
return {};
}
///
/// Table F.1 — Frame bundle
struct Frame {
FrameHeader frame_header;
TOC toc;
LfGlobal lf_global;
u64 width {};
u64 height {};
u64 num_groups {};
u64 num_lf_groups {};
};
static ErrorOr<Frame> read_frame(LittleEndianInputBitStream& stream,
Image& image,
SizeHeader const& size_header,
ImageMetadata const& metadata,
Optional<EntropyDecoder>& entropy_decoder)
{
LibGfx/JPEGXL: Align the stream to byte boundary before reading a frame As this is stated in the spec, all frames are byte-aligned.
2023-07-22 03:00:59 +00:00
// F.1 - General
// Each Frame is byte-aligned by invoking ZeroPadToByte() (B.2.7)
stream.align_to_byte_boundary();
LibGfx/JPEGXL: Add a JPEG-XL decoder :^) JPEG-XL is a new image format standardized by the same committee as the original JPEG image format. It has all the nice feature of recent formats, and great compression ratios. For more details, look at: https://jpegxl.info/ This decoder is far from being feature-complete, as it features a grand total of 60 FIXMEs and TODOs but anyway, it's still a good start. I developed this decoder in the Serenity way, I just try to decode a specific image while staying as close as possible to the specification. Considering that the format supports a lot of options, and that we basically support only one possibility for each of them, I'm pretty sure that we can only decode the image I've developed this decoder for. Which is: 0aff 3ffa 9101 0688 0001 004c 384b bc41 5ced 86e5 2a19 0696 03e5 4920 8038 000b
2023-07-04 04:13:34 +00:00
Frame frame;
frame.frame_header = TRY(read_frame_header(stream, metadata));
if (!frame.frame_header.have_crop) {
frame.width = size_header.width;
frame.height = size_header.height;
} else {
TODO();
}
if (frame.frame_header.upsampling > 1) {
frame.width = ceil(frame.width / frame.frame_header.upsampling);
frame.height = ceil(frame.height / frame.frame_header.upsampling);
}
if (frame.frame_header.lf_level > 0)
TODO();
// F.2 - FrameHeader
auto const group_dim = 128 << frame.frame_header.group_size_shift;
frame.num_groups = ceil(frame.width / group_dim) * ceil(frame.height / group_dim);
frame.num_lf_groups = ceil(frame.width / (group_dim * 8)) * ceil(frame.height / (group_dim * 8));
frame.toc = TRY(read_toc(stream, frame.frame_header, frame.num_groups, frame.num_lf_groups));
image = TRY(Image::create({ frame.width, frame.height }));
frame.lf_global = TRY(read_lf_global(stream, image, frame.frame_header, metadata, entropy_decoder));
for (u32 i {}; i < frame.num_lf_groups; ++i)
TODO();
if (frame.frame_header.encoding == FrameHeader::Encoding::kVarDCT) {
TODO();
}
auto const num_pass_group = frame.num_groups * frame.frame_header.passes.num_passes;
auto const& transform_info = frame.lf_global.gmodular.modular_header.transform;
for (u64 i {}; i < num_pass_group; ++i)
TRY(read_pass_group(stream, image, frame.frame_header, group_dim, transform_info));
return frame;
}
///
/// 5.2 - Mirroring
static u32 mirror_1d(i32 coord, u32 size)
{
if (coord < 0)
return mirror_1d(-coord - 1, size);
else if (static_cast<u32>(coord) >= size)
return mirror_1d(2 * size - 1 - coord, size);
else
return coord;
}
///
/// K - Image features
static ErrorOr<void> apply_upsampling(Image& image, ImageMetadata const& metadata, Frame const& frame)
{
Optional<u32> ec_max;
for (auto upsampling : frame.frame_header.ec_upsampling) {
if (!ec_max.has_value() || upsampling > *ec_max)
ec_max = upsampling;
}
if (frame.frame_header.upsampling > 1 || ec_max.value_or(0) > 1) {
LibGfx/JPEGXL: Add support for x4 and x8 upsampling All the logic is exactly the same as for x2 upsampling, so this commit essentially boils down to adding arrays for default weights and the logic to select the correct array.
2023-07-22 20:49:16 +00:00
if (ec_max.value_or(0) > 2)
LibGfx/JPEGXL: Add a JPEG-XL decoder :^) JPEG-XL is a new image format standardized by the same committee as the original JPEG image format. It has all the nice feature of recent formats, and great compression ratios. For more details, look at: https://jpegxl.info/ This decoder is far from being feature-complete, as it features a grand total of 60 FIXMEs and TODOs but anyway, it's still a good start. I developed this decoder in the Serenity way, I just try to decode a specific image while staying as close as possible to the specification. Considering that the format supports a lot of options, and that we basically support only one possibility for each of them, I'm pretty sure that we can only decode the image I've developed this decoder for. Which is: 0aff 3ffa 9101 0688 0001 004c 384b bc41 5ced 86e5 2a19 0696 03e5 4920 8038 000b
2023-07-04 04:13:34 +00:00
TODO();
auto const k = frame.frame_header.upsampling;
LibGfx/JPEGXL: Add support for x4 and x8 upsampling All the logic is exactly the same as for x2 upsampling, so this commit essentially boils down to adding arrays for default weights and the logic to select the correct array.
2023-07-22 20:49:16 +00:00
auto weight = [k, &metadata](u8 index) -> double {
if (k == 2)
return metadata.up2_weight[index];
if (k == 4)
return metadata.up4_weight[index];
return metadata.up8_weight[index];
};
LibGfx/JPEGXL: Add a JPEG-XL decoder :^) JPEG-XL is a new image format standardized by the same committee as the original JPEG image format. It has all the nice feature of recent formats, and great compression ratios. For more details, look at: https://jpegxl.info/ This decoder is far from being feature-complete, as it features a grand total of 60 FIXMEs and TODOs but anyway, it's still a good start. I developed this decoder in the Serenity way, I just try to decode a specific image while staying as close as possible to the specification. Considering that the format supports a lot of options, and that we basically support only one possibility for each of them, I'm pretty sure that we can only decode the image I've developed this decoder for. Which is: 0aff 3ffa 9101 0688 0001 004c 384b bc41 5ced 86e5 2a19 0696 03e5 4920 8038 000b
2023-07-04 04:13:34 +00:00
// FIXME: Use ec_upsampling for extra-channels
for (auto& channel : image.channels()) {
auto upsampled = TRY(Channel::create(k * channel.width(), k * channel.height()));
// Loop over the original image
for (u32 y {}; y < channel.height(); y++) {
for (u32 x {}; x < channel.width(); x++) {
// Loop over the upsampling factor
for (u8 kx {}; kx < k; ++kx) {
for (u8 ky {}; ky < k; ++ky) {
double sum {};
// Loop over the W window
double W_min = NumericLimits<double>::max();
double W_max = -NumericLimits<double>::max();
for (u8 ix {}; ix < 5; ++ix) {
for (u8 iy {}; iy < 5; ++iy) {
auto const j = (ky < k / 2) ? (iy + 5 * ky) : ((4 - iy) + 5 * (k - 1 - ky));
auto const i = (kx < k / 2) ? (ix + 5 * kx) : ((4 - ix) + 5 * (k - 1 - kx));
auto const minimum = min(i, j);
auto const maximum = max(i, j);
auto const index = 5 * k * minimum / 2 - minimum * (minimum - 1) / 2 + maximum - minimum;
auto const origin_sample_x = mirror_1d(x + ix - 2, channel.width());
auto const origin_sample_y = mirror_1d(y + iy - 2, channel.height());
auto const origin_sample = channel.get(origin_sample_x, origin_sample_y);
W_min = min(W_min, origin_sample);
W_max = max(W_max, origin_sample);
LibGfx/JPEGXL: Add support for x4 and x8 upsampling All the logic is exactly the same as for x2 upsampling, so this commit essentially boils down to adding arrays for default weights and the logic to select the correct array.
2023-07-22 20:49:16 +00:00
sum += origin_sample * weight(index);
LibGfx/JPEGXL: Add a JPEG-XL decoder :^) JPEG-XL is a new image format standardized by the same committee as the original JPEG image format. It has all the nice feature of recent formats, and great compression ratios. For more details, look at: https://jpegxl.info/ This decoder is far from being feature-complete, as it features a grand total of 60 FIXMEs and TODOs but anyway, it's still a good start. I developed this decoder in the Serenity way, I just try to decode a specific image while staying as close as possible to the specification. Considering that the format supports a lot of options, and that we basically support only one possibility for each of them, I'm pretty sure that we can only decode the image I've developed this decoder for. Which is: 0aff 3ffa 9101 0688 0001 004c 384b bc41 5ced 86e5 2a19 0696 03e5 4920 8038 000b
2023-07-04 04:13:34 +00:00
}
}
// The resulting sample is clamped to the range [a, b] where a and b are
// the minimum and maximum of the samples in W.
sum = clamp(sum, W_min, W_max);
upsampled.set(x * k + kx, y * k + ky, sum);
}
}
}
}
channel = move(upsampled);
}
}
return {};
}
static ErrorOr<void> apply_image_features(Image& image, ImageMetadata const& metadata, Frame const& frame)
{
TRY(apply_upsampling(image, metadata, frame));
if (frame.frame_header.flags != FrameHeader::Flags::None)
TODO();
return {};
}
///
class JPEGXLLoadingContext {
public:
JPEGXLLoadingContext(NonnullOwnPtr<Stream> stream)
: m_stream(move(stream))
{
}
ErrorOr<void> decode_image_header()
{
constexpr auto JPEGXL_SIGNATURE = 0xFF0A;
auto const signature = TRY(m_stream.read_value<BigEndian<u16>>());
if (signature != JPEGXL_SIGNATURE)
return Error::from_string_literal("Unrecognized signature");
m_header = TRY(read_size_header(m_stream));
m_metadata = TRY(read_metadata_header(m_stream));
m_state = State::HeaderDecoded;
return {};
}
ErrorOr<void> decode_frame()
{
Image image {};
auto const frame = TRY(read_frame(m_stream, image, m_header, m_metadata, m_entropy_decoder));
if (frame.frame_header.restoration_filter.gab || frame.frame_header.restoration_filter.epf_iters != 0)
TODO();
TRY(apply_image_features(image, m_metadata, frame));
// FIXME: Do a proper color transformation with metadata.colour_encoding
if (m_metadata.xyb_encoded || frame.frame_header.do_YCbCr)
TODO();
m_bitmap = TRY(image.to_bitmap(m_metadata.bit_depth.bits_per_sample));
return {};
}
ErrorOr<void> decode()
{
auto result = [this]() -> ErrorOr<void> {
// A.1 - Codestream structure
LibGfx/JPEGXL: Don't decode the header twice This is something I missed when I ported the JPEG XL decoder to the new plugin interface (decoding the header at creation). First sorry because that's entirely my fault, second sorry because a test should have caught that.
2023-07-21 18:48:11 +00:00
// The header is already decoded in JPEGXLImageDecoderPlugin::create()
LibGfx/JPEGXL: Add a JPEG-XL decoder :^) JPEG-XL is a new image format standardized by the same committee as the original JPEG image format. It has all the nice feature of recent formats, and great compression ratios. For more details, look at: https://jpegxl.info/ This decoder is far from being feature-complete, as it features a grand total of 60 FIXMEs and TODOs but anyway, it's still a good start. I developed this decoder in the Serenity way, I just try to decode a specific image while staying as close as possible to the specification. Considering that the format supports a lot of options, and that we basically support only one possibility for each of them, I'm pretty sure that we can only decode the image I've developed this decoder for. Which is: 0aff 3ffa 9101 0688 0001 004c 384b bc41 5ced 86e5 2a19 0696 03e5 4920 8038 000b
2023-07-04 04:13:34 +00:00
if (m_metadata.colour_encoding.want_icc)
TODO();
if (m_metadata.preview.has_value())
TODO();
TRY(decode_frame());
return {};
}();
m_state = result.is_error() ? State::Error : State::FrameDecoded;
return result;
}
enum class State {
NotDecoded = 0,
Error,
HeaderDecoded,
FrameDecoded,
BitmapDecoded
};
State state() const
{
return m_state;
}
IntSize size() const
{
return { m_header.width, m_header.height };
}
RefPtr<Bitmap> bitmap() const
{
return m_bitmap;
}
private:
State m_state { State::NotDecoded };
LittleEndianInputBitStream m_stream;
RefPtr<Gfx::Bitmap> m_bitmap;
Optional<EntropyDecoder> m_entropy_decoder {};
SizeHeader m_header;
ImageMetadata m_metadata;
FrameHeader m_frame_header;
TOC m_toc;
};
JPEGXLImageDecoderPlugin::JPEGXLImageDecoderPlugin(NonnullOwnPtr<FixedMemoryStream> stream)
{
m_context = make<JPEGXLLoadingContext>(move(stream));
}
JPEGXLImageDecoderPlugin::~JPEGXLImageDecoderPlugin() = default;
IntSize JPEGXLImageDecoderPlugin::size()
{
return m_context->size();
}
bool JPEGXLImageDecoderPlugin::sniff(ReadonlyBytes data)
{
return data.size() > 2
&& data.data()[0] == 0xFF
&& data.data()[1] == 0x0A;
}
ErrorOr<NonnullOwnPtr<ImageDecoderPlugin>> JPEGXLImageDecoderPlugin::create(ReadonlyBytes data)
{
auto stream = TRY(try_make<FixedMemoryStream>(data));
auto plugin = TRY(adopt_nonnull_own_or_enomem(new (nothrow) JPEGXLImageDecoderPlugin(move(stream))));
TRY(plugin->m_context->decode_image_header());
return plugin;
}
bool JPEGXLImageDecoderPlugin::is_animated()
{
return false;
}
size_t JPEGXLImageDecoderPlugin::loop_count()
{
return 0;
}
size_t JPEGXLImageDecoderPlugin::frame_count()
{
return 1;
}
size_t JPEGXLImageDecoderPlugin::first_animated_frame_index()
{
return 0;
}
ErrorOr<ImageFrameDescriptor> JPEGXLImageDecoderPlugin::frame(size_t index, Optional<IntSize>)
{
if (index > 0)
return Error::from_string_literal("JPEGXLImageDecoderPlugin: Invalid frame index");
if (m_context->state() == JPEGXLLoadingContext::State::Error)
return Error::from_string_literal("JPEGXLImageDecoderPlugin: Decoding failed");
if (m_context->state() < JPEGXLLoadingContext::State::BitmapDecoded)
TRY(m_context->decode());
return ImageFrameDescriptor { m_context->bitmap(), 0 };
}
ErrorOr<Optional<ReadonlyBytes>> JPEGXLImageDecoderPlugin::icc_data()
{
return OptionalNone {};
}
}
Reference in a new issue Copy permalink