/* * Copyright (c) 2021, Pierre Hoffmeister * Copyright (c) 2021, Andreas Kling * Copyright (c) 2021, Aziz Berkay Yesilyurt * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include #include #include #pragma GCC diagnostic ignored "-Wpsabi" namespace Gfx { class PNGChunk { using data_length_type = u32; public: explicit PNGChunk(String); auto const& data() const { return m_data; }; String const& type() const { return m_type; }; void reserve(size_t bytes) { m_data.ensure_capacity(bytes); } template void add_as_big_endian(T); template void add_as_little_endian(T); void add_u8(u8); template void add(T*, size_t); void store_type(); void store_data_length(); u32 crc(); private: template requires(IsUnsigned) void add(T); ByteBuffer m_data; String m_type; }; PNGChunk::PNGChunk(String type) : m_type(move(type)) { add(0); store_type(); } void PNGChunk::store_type() { m_data.append(type().bytes()); } void PNGChunk::store_data_length() { auto data_length = BigEndian(m_data.size() - sizeof(data_length_type) - m_type.length()); __builtin_memcpy(m_data.offset_pointer(0), &data_length, sizeof(u32)); } u32 PNGChunk::crc() { u32 crc = Crypto::Checksum::CRC32({ m_data.offset_pointer(sizeof(data_length_type)), m_data.size() - sizeof(data_length_type) }).digest(); return crc; } template requires(IsUnsigned) void PNGChunk::add(T data) { m_data.append(&data, sizeof(T)); } template void PNGChunk::add(T* data, size_t size) { m_data.append(data, size); } template void PNGChunk::add_as_little_endian(T data) { auto data_out = AK::convert_between_host_and_little_endian(data); add(data_out); } template void PNGChunk::add_as_big_endian(T data) { auto data_out = AK::convert_between_host_and_big_endian(data); add(data_out); } void PNGChunk::add_u8(u8 data) { add(data); } void PNGWriter::add_chunk(PNGChunk& png_chunk) { png_chunk.store_data_length(); u32 crc = png_chunk.crc(); png_chunk.add_as_big_endian(crc); m_data.append(png_chunk.data().data(), png_chunk.data().size()); } void PNGWriter::add_png_header() { m_data.append(PNG::header.data(), PNG::header.size()); } void PNGWriter::add_IHDR_chunk(u32 width, u32 height, u8 bit_depth, PNG::ColorType color_type, u8 compression_method, u8 filter_method, u8 interlace_method) { PNGChunk png_chunk { "IHDR" }; png_chunk.add_as_big_endian(width); png_chunk.add_as_big_endian(height); png_chunk.add_u8(bit_depth); png_chunk.add_u8(to_underlying(color_type)); png_chunk.add_u8(compression_method); png_chunk.add_u8(filter_method); png_chunk.add_u8(interlace_method); add_chunk(png_chunk); } void PNGWriter::add_IEND_chunk() { PNGChunk png_chunk { "IEND" }; add_chunk(png_chunk); } union [[gnu::packed]] Pixel { ARGB32 rgba { 0 }; struct { u8 red; u8 green; u8 blue; u8 alpha; }; AK::SIMD::u8x4 simd; ALWAYS_INLINE static AK::SIMD::u8x4 gfx_to_png(Pixel pixel) { swap(pixel.red, pixel.blue); return pixel.simd; } }; static_assert(AssertSize()); void PNGWriter::add_IDAT_chunk(Gfx::Bitmap const& bitmap) { PNGChunk png_chunk { "IDAT" }; png_chunk.reserve(bitmap.size_in_bytes()); ByteBuffer uncompressed_block_data; uncompressed_block_data.ensure_capacity(bitmap.size_in_bytes() + bitmap.height()); Pixel dummy_scanline[bitmap.width()]; auto const* scanline_minus_1 = dummy_scanline; for (int y = 0; y < bitmap.height(); ++y) { auto* scanline = reinterpret_cast(bitmap.scanline(y)); struct Filter { PNG::FilterType type; ByteBuffer buffer {}; int sum = 0; void append(u8 byte) { buffer.append(byte); sum += static_cast(byte); } void append(AK::SIMD::u8x4 simd) { append(simd[0]); append(simd[1]); append(simd[2]); append(simd[3]); } }; Filter none_filter { .type = PNG::FilterType::None }; none_filter.buffer.ensure_capacity(sizeof(Pixel) * bitmap.height()); Filter sub_filter { .type = PNG::FilterType::Sub }; sub_filter.buffer.ensure_capacity(sizeof(Pixel) * bitmap.height()); Filter up_filter { .type = PNG::FilterType::Up }; up_filter.buffer.ensure_capacity(sizeof(Pixel) * bitmap.height()); Filter average_filter { .type = PNG::FilterType::Average }; average_filter.buffer.ensure_capacity(sizeof(ARGB32) * bitmap.height()); Filter paeth_filter { .type = PNG::FilterType::Paeth }; paeth_filter.buffer.ensure_capacity(sizeof(ARGB32) * bitmap.height()); auto pixel_x_minus_1 = Pixel::gfx_to_png(*dummy_scanline); auto pixel_xy_minus_1 = Pixel::gfx_to_png(*dummy_scanline); for (int x = 0; x < bitmap.width(); ++x) { auto pixel = Pixel::gfx_to_png(scanline[x]); auto pixel_y_minus_1 = Pixel::gfx_to_png(scanline_minus_1[x]); none_filter.append(pixel); sub_filter.append(pixel - pixel_x_minus_1); up_filter.append(pixel - pixel_y_minus_1); // The sum Orig(a) + Orig(b) shall be performed without overflow (using at least nine-bit arithmetic). auto sum = AK::SIMD::to_u16x4(pixel_x_minus_1) + AK::SIMD::to_u16x4(pixel_y_minus_1); auto average = AK::SIMD::to_u8x4(sum / 2); average_filter.append(pixel - average); paeth_filter.append(pixel - PNG::paeth_predictor(pixel_x_minus_1, pixel_y_minus_1, pixel_xy_minus_1)); pixel_x_minus_1 = pixel; pixel_xy_minus_1 = pixel_y_minus_1; } scanline_minus_1 = scanline; // 12.8 Filter selection: https://www.w3.org/TR/PNG/#12Filter-selection // For best compression of truecolour and greyscale images, the recommended approach // is adaptive filtering in which a filter is chosen for each scanline. // The following simple heuristic has performed well in early tests: // compute the output scanline using all five filters, and select the filter that gives the smallest sum of absolute values of outputs. // (Consider the output bytes as signed differences for this test.) Filter& best_filter = none_filter; if (abs(best_filter.sum) > abs(sub_filter.sum)) best_filter = sub_filter; if (abs(best_filter.sum) > abs(up_filter.sum)) best_filter = up_filter; if (abs(best_filter.sum) > abs(average_filter.sum)) best_filter = average_filter; if (abs(best_filter.sum) > abs(paeth_filter.sum)) best_filter = paeth_filter; uncompressed_block_data.append(to_underlying(best_filter.type)); uncompressed_block_data.append(best_filter.buffer); } auto maybe_zlib_buffer = Compress::ZlibCompressor::compress_all(uncompressed_block_data, Compress::ZlibCompressionLevel::Best); if (!maybe_zlib_buffer.has_value()) { // FIXME: Handle errors. VERIFY_NOT_REACHED(); } auto zlib_buffer = maybe_zlib_buffer.release_value(); png_chunk.add(zlib_buffer.data(), zlib_buffer.size()); add_chunk(png_chunk); } ByteBuffer PNGWriter::encode(Gfx::Bitmap const& bitmap) { PNGWriter writer; writer.add_png_header(); writer.add_IHDR_chunk(bitmap.width(), bitmap.height(), 8, PNG::ColorType::TruecolorWithAlpha, 0, 0, 0); writer.add_IDAT_chunk(bitmap); writer.add_IEND_chunk(); // FIXME: Handle OOM failure. return ByteBuffer::copy(writer.m_data).release_value_but_fixme_should_propagate_errors(); } }