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/*
* Copyright (c) 2022, Olivier De Cannière <olivier.decanniere96@gmail.com>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include "QOIWriter.h"
#include <AK/String.h>
namespace Gfx {
ByteBuffer QOIWriter::encode(Bitmap const& bitmap)
{
QOIWriter writer;
writer.add_header(bitmap.width(), bitmap.height(), Channels::RGBA, Colorspace::sRGB);
Color previous_pixel = { 0, 0, 0, 255 };
bool creating_run = false;
int run_length = 0;
for (auto y = 0; y < bitmap.height(); y++) {
for (auto x = 0; x < bitmap.width(); x++) {
auto pixel = bitmap.get_pixel(x, y);
// Check for at most 62 consecutive identical pixels.
if (pixel == previous_pixel) {
if (!creating_run) {
creating_run = true;
run_length = 0;
writer.insert_into_running_array(pixel);
}
run_length++;
// If the run reaches a maximum length of 62 or if this is the last pixel then create the chunk.
if (run_length == 62 || (y == bitmap.height() - 1 && x == bitmap.width() - 1)) {
writer.add_run_chunk(run_length);
creating_run = false;
}
continue;
}
// Run ended with the previous pixel. Create a chunk for it and continue processing this pixel.
if (creating_run) {
writer.add_run_chunk(run_length);
creating_run = false;
}
// Check if the pixel matches a pixel in the running array.
auto index = pixel_hash_function(pixel);
auto& array_pixel = writer.running_array[index];
if (array_pixel == pixel) {
writer.add_index_chunk(index);
previous_pixel = pixel;
continue;
}
writer.running_array[index] = pixel;
// Check if pixel can be expressed as a difference of the previous pixel.
if (pixel.alpha() == previous_pixel.alpha()) {
int red_difference = pixel.red() - previous_pixel.red();
int green_difference = pixel.green() - previous_pixel.green();
int blue_difference = pixel.blue() - previous_pixel.blue();
int relative_red_difference = red_difference - green_difference;
int relative_blue_difference = blue_difference - green_difference;
if (red_difference > -3 && red_difference < 2
&& green_difference > -3 && green_difference < 2
&& blue_difference > -3 && blue_difference < 2) {
writer.add_diff_chunk(red_difference, green_difference, blue_difference);
previous_pixel = pixel;
continue;
}
if (relative_red_difference > -9 && relative_red_difference < 8
&& green_difference > -33 && green_difference < 32
&& relative_blue_difference > -9 && relative_blue_difference < 8) {
writer.add_luma_chunk(relative_red_difference, green_difference, relative_blue_difference);
previous_pixel = pixel;
continue;
}
writer.add_rgb_chunk(pixel.red(), pixel.green(), pixel.blue());
previous_pixel = pixel;
continue;
}
previous_pixel = pixel;
// Write full color values.
writer.add_rgba_chunk(pixel.red(), pixel.green(), pixel.blue(), pixel.alpha());
}
}
writer.add_end_marker();
return ByteBuffer::copy(writer.m_data).release_value_but_fixme_should_propagate_errors();
}
void QOIWriter::add_header(u32 width, u32 height, Channels channels = Channels::RGBA, Colorspace color_space = Colorspace::sRGB)
{
// FIXME: Handle RGB and all linear channels.
if (channels == Channels::RGB || color_space == Colorspace::Linear)
TODO();
m_data.append(qoi_magic_bytes.data(), sizeof(qoi_magic_bytes));
auto big_endian_width = AK::convert_between_host_and_big_endian(width);
m_data.append(bit_cast<u8*>(&big_endian_width), sizeof(width));
auto big_endian_height = AK::convert_between_host_and_big_endian(height);
m_data.append(bit_cast<u8*>(&big_endian_height), sizeof(height));
// Number of channels: 3 = RGB, 4 = RGBA.
m_data.append(4);
// Colorspace: 0 = sRGB, 1 = all linear channels.
m_data.append(color_space == Colorspace::sRGB ? 0 : 1);
}
void QOIWriter::add_rgb_chunk(u8 r, u8 g, u8 b)
{
constexpr static u8 rgb_tag = 0b1111'1110;
m_data.append(rgb_tag);
m_data.append(r);
m_data.append(g);
m_data.append(b);
}
void QOIWriter::add_rgba_chunk(u8 r, u8 g, u8 b, u8 a)
{
constexpr static u8 rgba_tag = 0b1111'1111;
m_data.append(rgba_tag);
m_data.append(r);
m_data.append(g);
m_data.append(b);
m_data.append(a);
}
void QOIWriter::add_index_chunk(unsigned int index)
{
constexpr static u8 index_tag = 0b0000'0000;
u8 chunk = index_tag | index;
m_data.append(chunk);
}
void QOIWriter::add_diff_chunk(i8 red_difference, i8 green_difference, i8 blue_difference)
{
constexpr static u8 diff_tag = 0b0100'0000;
u8 bias = 2;
u8 red = red_difference + bias;
u8 green = green_difference + bias;
u8 blue = blue_difference + bias;
u8 chunk = diff_tag | (red << 4) | (green << 2) | blue;
m_data.append(chunk);
}
void QOIWriter::add_luma_chunk(i8 relative_red_difference, i8 green_difference, i8 relative_blue_difference)
{
constexpr static u8 luma_tag = 0b1000'0000;
u8 green_bias = 32;
u8 red_blue_bias = 8;
u8 chunk1 = luma_tag | (green_difference + green_bias);
u8 chunk2 = ((relative_red_difference + red_blue_bias) << 4) | (relative_blue_difference + red_blue_bias);
m_data.append(chunk1);
m_data.append(chunk2);
}
void QOIWriter::add_run_chunk(unsigned run_length)
{
constexpr static u8 run_tag = 0b1100'0000;
int bias = -1;
u8 chunk = run_tag | (run_length + bias);
m_data.append(chunk);
}
void QOIWriter::add_end_marker()
{
m_data.append(qoi_end_marker.data(), sizeof(qoi_end_marker));
}
u32 QOIWriter::pixel_hash_function(Color pixel)
{
return (pixel.red() * 3 + pixel.green() * 5 + pixel.blue() * 7 + pixel.alpha() * 11) % 64;
}
void QOIWriter::insert_into_running_array(Color pixel)
{
auto index = pixel_hash_function(pixel);
running_array[index] = pixel;
}
}
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