ladybird/Libraries/LibGfx/GIFLoader.cpp

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/*
* Copyright (c) 2018-2020, Andreas Kling <kling@serenityos.org>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <AK/BufferStream.h>
#include <AK/ByteBuffer.h>
#include <AK/LexicalPath.h>
#include <AK/MappedFile.h>
#include <AK/NonnullOwnPtrVector.h>
2020-02-06 11:04:00 +00:00
#include <LibGfx/GIFLoader.h>
#include <LibM/math.h>
#include <stdio.h>
#include <string.h>
namespace Gfx {
static bool load_gif_frame_descriptors(GIFLoadingContext&);
struct RGB {
u8 r;
u8 g;
u8 b;
};
struct ImageDescriptor {
u16 x;
u16 y;
u16 width;
u16 height;
bool use_global_color_map;
RGB color_map[256];
u8 lzw_min_code_size;
Vector<u8> lzw_encoded_bytes;
RefPtr<Gfx::Bitmap> bitmap;
// 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 };
};
struct LogicalScreen {
u16 width;
u16 height;
RGB color_map[256];
};
struct GIFLoadingContext {
enum State {
NotDecoded = 0,
Error,
FrameDescriptorsLoaded,
};
State state { NotDecoded };
size_t frames_decoded { 0 };
const u8* data { nullptr };
size_t data_size { 0 };
LogicalScreen logical_screen {};
u8 background_color_index { 0 };
NonnullOwnPtrVector<ImageDescriptor> images {};
size_t loops { 1 };
};
RefPtr<Gfx::Bitmap> load_gif(const StringView& path)
{
MappedFile mapped_file(path);
if (!mapped_file.is_valid())
return nullptr;
GIFImageDecoderPlugin gif_decoder((const u8*)mapped_file.data(), mapped_file.size());
auto bitmap = gif_decoder.bitmap();
if (bitmap)
bitmap->set_mmap_name(String::format("Gfx::Bitmap [%dx%d] - Decoded GIF: %s", bitmap->width(), bitmap->height(), LexicalPath::canonicalized_path(path).characters()));
return bitmap;
}
RefPtr<Gfx::Bitmap> load_gif_from_memory(const u8* data, size_t length)
{
GIFImageDecoderPlugin gif_decoder(data, length);
auto bitmap = gif_decoder.bitmap();
if (bitmap)
bitmap->set_mmap_name(String::format("Gfx::Bitmap [%dx%d] - Decoded GIF: <memory>", bitmap->width(), bitmap->height()));
return bitmap;
}
enum class GIFFormat {
GIF87a,
GIF89a,
};
Optional<GIFFormat> decode_gif_header(BufferStream& stream)
{
static const char valid_header_87[] = "GIF87a";
static const char valid_header_89[] = "GIF89a";
char header[6];
for (int i = 0; i < 6; ++i)
stream >> header[i];
if (stream.handle_read_failure())
return {};
if (!memcmp(header, valid_header_87, sizeof(header)))
return GIFFormat::GIF87a;
else if (!memcmp(header, valid_header_89, sizeof(header)))
return GIFFormat::GIF89a;
return {};
}
class LZWDecoder {
private:
static constexpr int max_code_size = 12;
public:
explicit LZWDecoder(const Vector<u8>& 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(pow(2, min_code_size))
{
init_code_table();
}
u16 add_control_code()
{
const u16 control_code = m_code_table.size();
m_code_table.append(Vector<u8> {});
m_original_code_table.append(Vector<u8> {});
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.append(m_original_code_table);
m_code_size = m_original_code_size;
m_table_capacity = pow(2, m_code_size);
m_output.clear();
}
Optional<u16> 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 {
const u32* addr = (const u32*)&m_lzw_bytes.at(current_byte_index);
m_current_code = (*addr & mask) >> current_bit_offset;
}
if (m_current_code > m_code_table.size()) {
dbg() << "Corrupted LZW stream, invalid code: " << m_current_code << " at bit index: "
<< m_current_bit_index << ", code table size: " << m_code_table.size();
return {};
}
m_current_bit_index += m_code_size;
return m_current_code;
}
Vector<u8>& get_output()
{
ASSERT(m_current_code <= m_code_table.size());
if (m_current_code < m_code_table.size()) {
Vector<u8> 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()) {
m_output.append(m_output[0]);
extend_code_table(m_output);
}
return m_output;
}
private:
void init_code_table()
{
m_code_table.clear();
for (u16 i = 0; i < m_table_capacity; ++i) {
m_code_table.append({ (u8)i });
}
m_original_code_table = m_code_table;
}
void extend_code_table(const Vector<u8>& 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<u8>& m_lzw_bytes;
int m_current_bit_index { 0 };
Vector<Vector<u8>> m_code_table {};
Vector<Vector<u8>> 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<u8> m_output {};
};
bool decode_frames_up_to_index(GIFLoadingContext& context, size_t frame_index)
{
if (frame_index >= context.images.size()) {
return false;
}
for (size_t i = context.frames_decoded; i <= frame_index; ++i) {
auto& image = context.images.at(i);
printf("Image %zu: %d,%d %dx%d %zu bytes LZW-encoded\n", i, image.x, image.y, image.width, image.height, image.lzw_encoded_bytes.size());
dbg() << "Decoding frame: " << i + 1 << " of " << context.images.size();
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();
auto background_rgb = context.logical_screen.color_map[context.background_color_index];
Color background_color = Color(background_rgb.r, background_rgb.g, background_rgb.b);
image.bitmap = Bitmap::create_purgeable(BitmapFormat::RGBA32, { context.logical_screen.width, context.logical_screen.height });
image.bitmap->fill(background_color);
if (i > 0 && image.disposal_method == ImageDescriptor::DisposalMethod::InPlace) {
for (int y = 0; y < image.bitmap->height(); ++y) {
for (int x = 0; x < image.bitmap->width(); ++x) {
image.bitmap->set_pixel(x, y, context.images.at(i - 1).bitmap->get_pixel(x, y));
}
}
}
int pixel_index = 0;
RGB transparent_color { 0, 0, 0 };
if (image.transparent) {
transparent_color = context.logical_screen.color_map[image.transparency_index];
}
while (true) {
Optional<u16> code = decoder.next_code();
if (!code.has_value()) {
dbg() << "Unexpectedly reached end of gif frame data";
return false;
}
if (code.value() == clear_code) {
decoder.reset();
continue;
} else if (code.value() == end_of_information_code) {
break;
}
auto colors = decoder.get_output();
for (const auto& color : colors) {
auto rgb = context.logical_screen.color_map[color];
int x = pixel_index % image.width + image.x;
int y = pixel_index / image.width + image.y;
Color c = Color(rgb.r, rgb.g, rgb.b);
if (image.transparent) {
if (rgb.r == transparent_color.r && rgb.g == transparent_color.g && rgb.b == transparent_color.b) {
c.set_alpha(0);
}
}
image.bitmap->set_pixel(x, y, c);
++pixel_index;
}
}
++context.frames_decoded;
}
return true;
}
bool load_gif_frame_descriptors(GIFLoadingContext& context)
{
if (context.data_size < 32)
return false;
auto buffer = ByteBuffer::wrap(context.data, context.data_size);
BufferStream stream(buffer);
Optional<GIFFormat> format = decode_gif_header(stream);
if (!format.has_value()) {
return false;
}
printf("Format is %s\n", format.value() == GIFFormat::GIF89a ? "GIF89a" : "GIF87a");
stream >> context.logical_screen.width;
stream >> context.logical_screen.height;
if (stream.handle_read_failure())
return false;
u8 gcm_info = 0;
stream >> gcm_info;
if (stream.handle_read_failure())
return false;
bool global_color_map_follows_descriptor = gcm_info & 0x80;
u8 bits_per_pixel = (gcm_info & 7) + 1;
u8 bits_of_color_resolution = (gcm_info >> 4) & 7;
printf("LogicalScreen: %dx%d\n", context.logical_screen.width, context.logical_screen.height);
printf("global_color_map_follows_descriptor: %u\n", global_color_map_follows_descriptor);
printf("bits_per_pixel: %u\n", bits_per_pixel);
printf("bits_of_color_resolution: %u\n", bits_of_color_resolution);
stream >> context.background_color_index;
if (stream.handle_read_failure())
return false;
printf("background_color: %u\n", context.background_color_index);
u8 pixel_aspect_ratio = 0;
stream >> pixel_aspect_ratio;
if (stream.handle_read_failure())
return false;
int color_map_entry_count = 1;
for (int i = 0; i < bits_per_pixel; ++i)
color_map_entry_count *= 2;
printf("color_map_entry_count: %d\n", color_map_entry_count);
for (int i = 0; i < color_map_entry_count; ++i) {
stream >> context.logical_screen.color_map[i].r;
stream >> context.logical_screen.color_map[i].g;
stream >> context.logical_screen.color_map[i].b;
}
if (stream.handle_read_failure())
return false;
for (int i = 0; i < color_map_entry_count; ++i) {
auto& rgb = context.logical_screen.color_map[i];
printf("[%02x]: %s\n", i, Color(rgb.r, rgb.g, rgb.b).to_string().characters());
}
NonnullOwnPtr<ImageDescriptor> current_image = make<ImageDescriptor>();
for (;;) {
u8 sentinel = 0;
stream >> sentinel;
printf("Sentinel: %02x\n", sentinel);
if (sentinel == 0x21) {
u8 extension_type = 0;
stream >> extension_type;
if (stream.handle_read_failure())
return false;
printf("Extension block of type %02x\n", extension_type);
u8 sub_block_length = 0;
Vector<u8> sub_block {};
for (;;) {
stream >> sub_block_length;
if (stream.handle_read_failure())
return false;
if (sub_block_length == 0)
break;
u8 dummy;
for (u16 i = 0; i < sub_block_length; ++i) {
stream >> dummy;
sub_block.append(dummy);
}
if (stream.handle_read_failure())
return false;
}
if (extension_type == 0xF9) {
if (sub_block.size() != 4) {
dbg() << "Unexpected graphic control size";
continue;
}
u8 disposal_method = (sub_block[0] & 0x1C) >> 2;
current_image->disposal_method = (ImageDescriptor::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) {
dbg() << "Unexpected application extension size: " << sub_block.size();
continue;
}
if (sub_block[11] != 1) {
dbg() << "Unexpected application extension format";
continue;
}
u16 loops = sub_block[12] + (sub_block[13] << 8);
context.loops = loops;
}
continue;
}
if (sentinel == 0x2c) {
context.images.append(move(current_image));
auto& image = context.images.last();
u8 packed_fields { 0 };
stream >> image.x;
stream >> image.y;
stream >> image.width;
stream >> image.height;
stream >> packed_fields;
if (stream.handle_read_failure())
return false;
printf("Image descriptor: %d,%d %dx%d, %02x\n", image.x, image.y, image.width, image.height, packed_fields);
stream >> image.lzw_min_code_size;
printf("min code size: %u\n", image.lzw_min_code_size);
u8 lzw_encoded_bytes_expected = 0;
for (;;) {
stream >> lzw_encoded_bytes_expected;
if (stream.handle_read_failure())
return false;
if (lzw_encoded_bytes_expected == 0)
break;
u8 buffer[256];
for (int i = 0; i < lzw_encoded_bytes_expected; ++i) {
stream >> buffer[i];
}
if (stream.handle_read_failure())
return false;
for (int i = 0; i < lzw_encoded_bytes_expected; ++i) {
image.lzw_encoded_bytes.append(buffer[i]);
}
}
current_image = make<ImageDescriptor>();
continue;
}
if (sentinel == 0x3b) {
printf("Trailer! Awesome :)\n");
break;
}
return false;
}
context.state = GIFLoadingContext::State::FrameDescriptorsLoaded;
return true;
}
GIFImageDecoderPlugin::GIFImageDecoderPlugin(const u8* data, size_t size)
{
m_context = make<GIFLoadingContext>();
m_context->data = data;
m_context->data_size = size;
}
GIFImageDecoderPlugin::~GIFImageDecoderPlugin() {}
IntSize GIFImageDecoderPlugin::size()
{
if (m_context->state == GIFLoadingContext::State::Error) {
return {};
}
if (m_context->state < GIFLoadingContext::State::FrameDescriptorsLoaded) {
if (!load_gif_frame_descriptors(*m_context)) {
m_context->state = GIFLoadingContext::State::Error;
return {};
}
}
return { m_context->logical_screen.width, m_context->logical_screen.height };
}
RefPtr<Gfx::Bitmap> GIFImageDecoderPlugin::bitmap()
{
return frame(0).image;
}
void GIFImageDecoderPlugin::set_volatile()
{
for (size_t i = 0; i < m_context->frames_decoded; ++i) {
m_context->images.at(i).bitmap->set_volatile();
}
}
bool GIFImageDecoderPlugin::set_nonvolatile()
{
if (m_context->images.is_empty()) {
return false;
}
bool success = true;
for (size_t i = 0; i < m_context->frames_decoded; ++i) {
success &= m_context->images.at(i).bitmap->set_nonvolatile();
}
return success;
}
bool GIFImageDecoderPlugin::sniff()
{
auto buffer = ByteBuffer::wrap(m_context->data, m_context->data_size);
BufferStream stream(buffer);
return decode_gif_header(stream).has_value();
}
bool GIFImageDecoderPlugin::is_animated()
{
if (m_context->state < GIFLoadingContext::State::FrameDescriptorsLoaded) {
if (!load_gif_frame_descriptors(*m_context)) {
m_context->state = GIFLoadingContext::State::Error;
return false;
}
}
return m_context->images.size() > 1;
}
size_t GIFImageDecoderPlugin::loop_count()
{
if (m_context->state < GIFLoadingContext::State::FrameDescriptorsLoaded) {
if (!load_gif_frame_descriptors(*m_context)) {
m_context->state = GIFLoadingContext::State::Error;
return 0;
}
}
return m_context->loops;
}
size_t GIFImageDecoderPlugin::frame_count()
{
if (m_context->state < GIFLoadingContext::State::FrameDescriptorsLoaded) {
if (!load_gif_frame_descriptors(*m_context)) {
m_context->state = GIFLoadingContext::State::Error;
return 1;
}
}
return m_context->images.size();
}
ImageFrameDescriptor GIFImageDecoderPlugin::frame(size_t i)
{
if (m_context->state == GIFLoadingContext::State::Error) {
return {};
}
if (m_context->state < GIFLoadingContext::State::FrameDescriptorsLoaded) {
if (!load_gif_frame_descriptors(*m_context)) {
m_context->state = GIFLoadingContext::State::Error;
return {};
}
}
if (!decode_frames_up_to_index(*m_context, i)) {
m_context->state = GIFLoadingContext::State::Error;
return {};
}
ImageFrameDescriptor frame {};
frame.image = m_context->images.at(i).bitmap;
frame.duration = m_context->images.at(i).duration * 10;
if (frame.duration <= 10) {
frame.duration = 100;
}
return frame;
}
}