/* * Copyright (c) 2018-2021, Andreas Kling * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include #include #include #include #include #include namespace Gfx { // Row strides and offsets for each interlace pass. static const int INTERLACE_ROW_STRIDES[] = { 8, 8, 4, 2 }; static const int INTERLACE_ROW_OFFSETS[] = { 0, 4, 2, 1 }; struct GIFImageDescriptor { u16 x { 0 }; u16 y { 0 }; u16 width { 0 }; u16 height { 0 }; bool use_global_color_map { true }; bool interlaced { false }; Color color_map[256]; u8 lzw_min_code_size { 0 }; Vector lzw_encoded_bytes; // Fields from optional graphic control extension block enum DisposalMethod : u8 { None = 0, InPlace = 1, RestoreBackground = 2, RestorePrevious = 3, }; DisposalMethod disposal_method { None }; u8 transparency_index { 0 }; u16 duration { 0 }; bool transparent { false }; bool user_input { false }; const IntRect rect() const { return { this->x, this->y, this->width, this->height }; } }; struct LogicalScreen { u16 width; u16 height; Color color_map[256]; }; struct GIFLoadingContext { enum State { NotDecoded = 0, FrameDescriptorsLoaded, FrameComplete, }; State state { NotDecoded }; enum ErrorState { NoError = 0, FailedToDecodeAllFrames, FailedToDecodeAnyFrame, FailedToLoadFrameDescriptors, }; ErrorState error_state { NoError }; const u8* data { nullptr }; size_t data_size { 0 }; LogicalScreen logical_screen {}; u8 background_color_index { 0 }; NonnullOwnPtrVector images {}; size_t loops { 1 }; RefPtr frame_buffer; size_t current_frame { 0 }; RefPtr prev_frame_buffer; }; RefPtr load_gif(String const& path) { auto file_or_error = MappedFile::map(path); if (file_or_error.is_error()) return nullptr; return load_gif_from_memory((u8 const*)file_or_error.value()->data(), file_or_error.value()->size(), LexicalPath::canonicalized_path(path)); } RefPtr load_gif_from_memory(u8 const* data, size_t length, String const& mmap_name) { GIFImageDecoderPlugin gif_decoder(data, length); auto bitmap = gif_decoder.bitmap(); if (bitmap) bitmap->set_mmap_name(String::formatted("Gfx::Bitmap [{}] - Decoded GIF: {}", bitmap->size(), mmap_name)); return bitmap; } enum class GIFFormat { GIF87a, GIF89a, }; static Optional decode_gif_header(InputMemoryStream& stream) { static const char valid_header_87[] = "GIF87a"; static const char valid_header_89[] = "GIF89a"; Array header; stream >> header; if (stream.handle_any_error()) return {}; if (header.span() == ReadonlyBytes { valid_header_87, 6 }) return GIFFormat::GIF87a; if (header.span() == ReadonlyBytes { valid_header_89, 6 }) return GIFFormat::GIF89a; return {}; } class LZWDecoder { private: static constexpr int max_code_size = 12; public: explicit LZWDecoder(const Vector& lzw_bytes, u8 min_code_size) : m_lzw_bytes(lzw_bytes) , m_code_size(min_code_size) , m_original_code_size(min_code_size) , m_table_capacity(AK::exp2(min_code_size)) { init_code_table(); } u16 add_control_code() { const u16 control_code = m_code_table.size(); m_code_table.append(Vector {}); m_original_code_table.append(Vector {}); if (m_code_table.size() >= m_table_capacity && m_code_size < max_code_size) { ++m_code_size; ++m_original_code_size; m_table_capacity *= 2; } return control_code; } void reset() { m_code_table.clear(); m_code_table.extend(m_original_code_table); m_code_size = m_original_code_size; m_table_capacity = AK::exp2(m_code_size); m_output.clear(); } Optional next_code() { size_t current_byte_index = m_current_bit_index / 8; if (current_byte_index >= m_lzw_bytes.size()) { return {}; } // Extract the code bits using a 32-bit mask to cover the possibility that if // the current code size > 9 bits then the code can span 3 bytes. u8 current_bit_offset = m_current_bit_index % 8; u32 mask = (u32)(m_table_capacity - 1) << current_bit_offset; // Make a padded copy of the final bytes in the data to ensure we don't read past the end. if (current_byte_index + sizeof(mask) > m_lzw_bytes.size()) { u8 padded_last_bytes[sizeof(mask)] = { 0 }; for (int i = 0; current_byte_index + i < m_lzw_bytes.size(); ++i) { padded_last_bytes[i] = m_lzw_bytes[current_byte_index + i]; } const u32* addr = (const u32*)&padded_last_bytes; m_current_code = (*addr & mask) >> current_bit_offset; } else { u32 tmp_word; memcpy(&tmp_word, &m_lzw_bytes.at(current_byte_index), sizeof(u32)); m_current_code = (tmp_word & mask) >> current_bit_offset; } if (m_current_code > m_code_table.size()) { dbgln_if(GIF_DEBUG, "Corrupted LZW stream, invalid code: {} at bit index {}, code table size: {}", m_current_code, m_current_bit_index, m_code_table.size()); return {}; } else if (m_current_code == m_code_table.size() && m_output.is_empty()) { dbgln_if(GIF_DEBUG, "Corrupted LZW stream, valid new code but output buffer is empty: {} at bit index {}, code table size: {}", m_current_code, m_current_bit_index, m_code_table.size()); return {}; } m_current_bit_index += m_code_size; return m_current_code; } Vector& get_output() { VERIFY(m_current_code <= m_code_table.size()); if (m_current_code < m_code_table.size()) { Vector new_entry = m_output; m_output = m_code_table.at(m_current_code); new_entry.append(m_output[0]); extend_code_table(new_entry); } else if (m_current_code == m_code_table.size()) { VERIFY(!m_output.is_empty()); m_output.append(m_output[0]); extend_code_table(m_output); } return m_output; } private: void init_code_table() { m_code_table.ensure_capacity(m_table_capacity); for (u16 i = 0; i < m_table_capacity; ++i) { m_code_table.unchecked_append({ (u8)i }); } m_original_code_table = m_code_table; } void extend_code_table(const Vector& entry) { if (entry.size() > 1 && m_code_table.size() < 4096) { m_code_table.append(entry); if (m_code_table.size() >= m_table_capacity && m_code_size < max_code_size) { ++m_code_size; m_table_capacity *= 2; } } } const Vector& m_lzw_bytes; int m_current_bit_index { 0 }; Vector> m_code_table {}; Vector> m_original_code_table {}; u8 m_code_size { 0 }; u8 m_original_code_size { 0 }; u32 m_table_capacity { 0 }; u16 m_current_code { 0 }; Vector m_output {}; }; static void copy_frame_buffer(Bitmap& dest, const Bitmap& src) { VERIFY(dest.size_in_bytes() == src.size_in_bytes()); memcpy(dest.scanline(0), src.scanline(0), dest.size_in_bytes()); } static void clear_rect(Bitmap& bitmap, const IntRect& rect, Color color) { if (rect.is_empty()) return; VERIFY(bitmap.rect().contains(rect)); RGBA32* dst = bitmap.scanline(rect.top()) + rect.left(); const size_t dst_skip = bitmap.pitch() / sizeof(RGBA32); for (int i = rect.height() - 1; i >= 0; --i) { fast_u32_fill(dst, color.value(), rect.width()); dst += dst_skip; } } static bool decode_frame(GIFLoadingContext& context, size_t frame_index) { if (frame_index >= context.images.size()) { return false; } if (context.state >= GIFLoadingContext::State::FrameComplete && frame_index == context.current_frame) { return true; } size_t start_frame = context.current_frame + 1; if (context.state < GIFLoadingContext::State::FrameComplete) { start_frame = 0; context.frame_buffer = Bitmap::try_create(BitmapFormat::BGRA8888, { context.logical_screen.width, context.logical_screen.height }); if (!context.frame_buffer) return false; context.prev_frame_buffer = Bitmap::try_create(BitmapFormat::BGRA8888, { context.logical_screen.width, context.logical_screen.height }); if (!context.prev_frame_buffer) return false; } else if (frame_index < context.current_frame) { start_frame = 0; } for (size_t i = start_frame; i <= frame_index; ++i) { auto& image = context.images.at(i); const auto previous_image_disposal_method = i > 0 ? context.images.at(i - 1).disposal_method : GIFImageDescriptor::DisposalMethod::None; if (i == 0) { context.frame_buffer->fill(Color::Transparent); } else if (i > 0 && image.disposal_method == GIFImageDescriptor::DisposalMethod::RestorePrevious && previous_image_disposal_method != GIFImageDescriptor::DisposalMethod::RestorePrevious) { // This marks the start of a run of frames that once disposed should be restored to the // previous underlying image contents. Therefore we make a copy of the current frame // buffer so that it can be restored later. copy_frame_buffer(*context.prev_frame_buffer, *context.frame_buffer); } if (previous_image_disposal_method == GIFImageDescriptor::DisposalMethod::RestoreBackground) { // Note: RestoreBackground could be interpreted either as restoring the underlying // background of the entire image (e.g. container element's background-color), or the // background color of the GIF itself. It appears that all major browsers and most other // GIF decoders adhere to the former interpretation, therefore we will do the same by // clearing the entire frame buffer to transparent. clear_rect(*context.frame_buffer, context.images.at(i - 1).rect(), Color::Transparent); } else if (i > 0 && previous_image_disposal_method == GIFImageDescriptor::DisposalMethod::RestorePrevious) { // Previous frame indicated that once disposed, it should be restored to *its* previous // underlying image contents, therefore we restore the saved previous frame buffer. copy_frame_buffer(*context.frame_buffer, *context.prev_frame_buffer); } if (image.lzw_min_code_size > 8) return false; LZWDecoder decoder(image.lzw_encoded_bytes, image.lzw_min_code_size); // Add GIF-specific control codes const int clear_code = decoder.add_control_code(); const int end_of_information_code = decoder.add_control_code(); const auto& color_map = image.use_global_color_map ? context.logical_screen.color_map : image.color_map; int pixel_index = 0; int row = 0; int interlace_pass = 0; while (true) { Optional code = decoder.next_code(); if (!code.has_value()) { dbgln_if(GIF_DEBUG, "Unexpectedly reached end of gif frame data"); return false; } if (code.value() == clear_code) { decoder.reset(); continue; } if (code.value() == end_of_information_code) break; if (!image.width) continue; auto colors = decoder.get_output(); for (const auto& color : colors) { auto c = color_map[color]; int x = pixel_index % image.width + image.x; int y = row + image.y; if (context.frame_buffer->rect().contains(x, y) && (!image.transparent || color != image.transparency_index)) { context.frame_buffer->set_pixel(x, y, c); } ++pixel_index; if (pixel_index % image.width == 0) { if (image.interlaced) { if (interlace_pass < 4) { if (row + INTERLACE_ROW_STRIDES[interlace_pass] >= image.height) { ++interlace_pass; if (interlace_pass < 4) row = INTERLACE_ROW_OFFSETS[interlace_pass]; } else { row += INTERLACE_ROW_STRIDES[interlace_pass]; } } } else { ++row; } } } } context.current_frame = i; context.state = GIFLoadingContext::State::FrameComplete; } return true; } static bool load_gif_frame_descriptors(GIFLoadingContext& context) { if (context.data_size < 32) return false; InputMemoryStream stream { { context.data, context.data_size } }; Optional format = decode_gif_header(stream); if (!format.has_value()) { return false; } LittleEndian value; stream >> value; context.logical_screen.width = value; stream >> value; context.logical_screen.height = value; if (stream.handle_any_error()) return false; if (context.logical_screen.width > maximum_width_for_decoded_images || context.logical_screen.height > maximum_height_for_decoded_images) { dbgln("This GIF is too large for comfort: {}x{}", context.logical_screen.width, context.logical_screen.height); return false; } u8 gcm_info = 0; stream >> gcm_info; if (stream.handle_any_error()) return false; stream >> context.background_color_index; if (stream.handle_any_error()) return false; u8 pixel_aspect_ratio = 0; stream >> pixel_aspect_ratio; if (stream.handle_any_error()) return false; u8 bits_per_pixel = (gcm_info & 7) + 1; int color_map_entry_count = 1; for (int i = 0; i < bits_per_pixel; ++i) color_map_entry_count *= 2; for (int i = 0; i < color_map_entry_count; ++i) { u8 r = 0; u8 g = 0; u8 b = 0; stream >> r >> g >> b; context.logical_screen.color_map[i] = { r, g, b }; } if (stream.handle_any_error()) return false; NonnullOwnPtr current_image = make(); for (;;) { u8 sentinel = 0; stream >> sentinel; if (stream.handle_any_error()) return false; if (sentinel == '!') { u8 extension_type = 0; stream >> extension_type; if (stream.handle_any_error()) return false; u8 sub_block_length = 0; Vector sub_block {}; for (;;) { stream >> sub_block_length; if (stream.handle_any_error()) return false; if (sub_block_length == 0) break; u8 dummy = 0; for (u16 i = 0; i < sub_block_length; ++i) { stream >> dummy; sub_block.append(dummy); } if (stream.handle_any_error()) return false; } if (extension_type == 0xF9) { if (sub_block.size() != 4) { dbgln_if(GIF_DEBUG, "Unexpected graphic control size"); continue; } u8 disposal_method = (sub_block[0] & 0x1C) >> 2; current_image->disposal_method = (GIFImageDescriptor::DisposalMethod)disposal_method; u8 user_input = (sub_block[0] & 0x2) >> 1; current_image->user_input = user_input == 1; u8 transparent = sub_block[0] & 1; current_image->transparent = transparent == 1; u16 duration = sub_block[1] + ((u16)sub_block[2] << 8); current_image->duration = duration; current_image->transparency_index = sub_block[3]; } if (extension_type == 0xFF) { if (sub_block.size() != 14) { dbgln_if(GIF_DEBUG, "Unexpected application extension size: {}", sub_block.size()); continue; } if (sub_block[11] != 1) { dbgln_if(GIF_DEBUG, "Unexpected application extension format"); continue; } u16 loops = sub_block[12] + (sub_block[13] << 8); context.loops = loops; } continue; } if (sentinel == ',') { context.images.append(move(current_image)); auto& image = context.images.last(); LittleEndian tmp; u8 packed_fields { 0 }; stream >> tmp; image.x = tmp; stream >> tmp; image.y = tmp; stream >> tmp; image.width = tmp; stream >> tmp; image.height = tmp; stream >> packed_fields; if (stream.handle_any_error()) return false; image.use_global_color_map = !(packed_fields & 0x80); image.interlaced = (packed_fields & 0x40) != 0; if (!image.use_global_color_map) { size_t local_color_table_size = AK::exp2((packed_fields & 7) + 1); for (size_t i = 0; i < local_color_table_size; ++i) { u8 r = 0; u8 g = 0; u8 b = 0; stream >> r >> g >> b; image.color_map[i] = { r, g, b }; } } stream >> image.lzw_min_code_size; if (stream.handle_any_error()) return false; u8 lzw_encoded_bytes_expected = 0; for (;;) { stream >> lzw_encoded_bytes_expected; if (stream.handle_any_error()) return false; if (lzw_encoded_bytes_expected == 0) break; Array buffer; stream >> buffer.span().trim(lzw_encoded_bytes_expected); if (stream.handle_any_error()) return false; for (int i = 0; i < lzw_encoded_bytes_expected; ++i) { image.lzw_encoded_bytes.append(buffer[i]); } } current_image = make(); continue; } if (sentinel == ';') { break; } return false; } context.state = GIFLoadingContext::State::FrameDescriptorsLoaded; return true; } GIFImageDecoderPlugin::GIFImageDecoderPlugin(const u8* data, size_t size) { m_context = make(); m_context->data = data; m_context->data_size = size; } GIFImageDecoderPlugin::~GIFImageDecoderPlugin() { } IntSize GIFImageDecoderPlugin::size() { if (m_context->error_state == GIFLoadingContext::ErrorState::FailedToLoadFrameDescriptors) { return {}; } if (m_context->state < GIFLoadingContext::State::FrameDescriptorsLoaded) { if (!load_gif_frame_descriptors(*m_context)) { m_context->error_state = GIFLoadingContext::ErrorState::FailedToLoadFrameDescriptors; return {}; } } return { m_context->logical_screen.width, m_context->logical_screen.height }; } RefPtr GIFImageDecoderPlugin::bitmap() { if (m_context->state < GIFLoadingContext::State::FrameComplete) { return frame(0).image; } return m_context->frame_buffer; } void GIFImageDecoderPlugin::set_volatile() { if (m_context->frame_buffer) { m_context->frame_buffer->set_volatile(); } } bool GIFImageDecoderPlugin::set_nonvolatile(bool& was_purged) { if (!m_context->frame_buffer) return false; return m_context->frame_buffer->set_nonvolatile(was_purged); } bool GIFImageDecoderPlugin::sniff() { InputMemoryStream stream { { m_context->data, m_context->data_size } }; return decode_gif_header(stream).has_value(); } bool GIFImageDecoderPlugin::is_animated() { if (m_context->error_state != GIFLoadingContext::ErrorState::NoError) { return false; } if (m_context->state < GIFLoadingContext::State::FrameDescriptorsLoaded) { if (!load_gif_frame_descriptors(*m_context)) { m_context->error_state = GIFLoadingContext::ErrorState::FailedToLoadFrameDescriptors; return false; } } return m_context->images.size() > 1; } size_t GIFImageDecoderPlugin::loop_count() { if (m_context->error_state != GIFLoadingContext::ErrorState::NoError) { return 0; } if (m_context->state < GIFLoadingContext::State::FrameDescriptorsLoaded) { if (!load_gif_frame_descriptors(*m_context)) { m_context->error_state = GIFLoadingContext::ErrorState::FailedToLoadFrameDescriptors; return 0; } } return m_context->loops; } size_t GIFImageDecoderPlugin::frame_count() { if (m_context->error_state != GIFLoadingContext::ErrorState::NoError) { return 1; } if (m_context->state < GIFLoadingContext::State::FrameDescriptorsLoaded) { if (!load_gif_frame_descriptors(*m_context)) { m_context->error_state = GIFLoadingContext::ErrorState::FailedToLoadFrameDescriptors; return 1; } } return m_context->images.size(); } ImageFrameDescriptor GIFImageDecoderPlugin::frame(size_t i) { if (m_context->error_state >= GIFLoadingContext::ErrorState::FailedToDecodeAnyFrame) { return {}; } if (m_context->state < GIFLoadingContext::State::FrameDescriptorsLoaded) { if (!load_gif_frame_descriptors(*m_context)) { m_context->error_state = GIFLoadingContext::ErrorState::FailedToLoadFrameDescriptors; return {}; } } if (m_context->error_state == GIFLoadingContext::ErrorState::NoError && !decode_frame(*m_context, i)) { if (m_context->state < GIFLoadingContext::State::FrameComplete || !decode_frame(*m_context, 0)) { m_context->error_state = GIFLoadingContext::ErrorState::FailedToDecodeAnyFrame; return {}; } m_context->error_state = GIFLoadingContext::ErrorState::FailedToDecodeAllFrames; } ImageFrameDescriptor frame {}; frame.image = m_context->frame_buffer->clone(); frame.duration = m_context->images.at(i).duration * 10; if (frame.duration <= 10) { frame.duration = 100; } return frame; } }