#include "SMXGif.h" #include #include #include using namespace std; // This is a simple animated GIF decoder. It always decodes to RGBA color, // discarding palettes, and decodes the whole file at once. class GIFError: public exception { }; struct Palette { SMXGif::Color color[256]; }; void SMXGif::GIFImage::Init(int width_, int height_) { width = width_; height = height_; image.resize(width * height); } void SMXGif::GIFImage::Clear(const Color &color) { for(int y = 0; y < height; ++y) for(int x = 0; x < width; ++x) get(x,y) = color; } void SMXGif::GIFImage::CropImage(SMXGif::GIFImage &dst, int crop_left, int crop_top, int crop_width, int crop_height) const { dst.Init(crop_width, crop_height); for(int y = 0; y < crop_height; ++y) { for(int x = 0; x < crop_width; ++x) dst.get(x,y) = get(x + crop_left, y + crop_top); } } void SMXGif::GIFImage::Blit(SMXGif::GIFImage &src, int dst_left, int dst_top, int dst_width, int dst_height) { for(int y = 0; y < dst_height; ++y) { for(int x = 0; x < dst_width; ++x) get(x + dst_left, y + dst_top) = src.get(x, y); } } bool SMXGif::GIFImage::operator==(const GIFImage &rhs) const { return width == rhs.width && height == rhs.height && image == rhs.image; } class DataStream { public: DataStream(const string &data_): data(data_) { } uint8_t ReadByte() { if(pos >= data.size()) throw GIFError(); uint8_t result = data[pos]; pos++; return result; } uint16_t ReadLE16() { uint8_t byte1 = ReadByte(); uint8_t byte2 = ReadByte(); return byte1 | (byte2 << 8); } void ReadBytes(string &s, int count) { s.clear(); while(count--) s.push_back(ReadByte()); } void skip(int bytes) { pos += bytes; } private: const string &data; uint32_t pos = 0; }; class LWZStream { public: LWZStream(DataStream &stream_): stream(stream_) { } // Read one LZW code from the input data. uint32_t ReadLZWCode(uint32_t bit_count) { while(bits_in_buffer < bit_count) { if(bytes_remaining == 0) { // Read the next block's byte count. bytes_remaining = stream.ReadByte(); if(bytes_remaining == 0) throw GIFError(); } // Shift in another 8 bits into the end of self.bits. bits |= stream.ReadByte() << bits_in_buffer; bits_in_buffer += 8; bytes_remaining -= 1; } // Shift out bit_count worth of data from the end. uint32_t result = bits & ((1 << bit_count) - 1); bits >>= bit_count; bits_in_buffer -= bit_count; return result; } // Skip the rest of the LZW data. void Flush() { stream.skip(bytes_remaining); bytes_remaining = 0; // If there are any blocks past the end of data, skip them. while(1) { uint8_t blocksize = stream.ReadByte(); stream.skip(blocksize); if(bytes_remaining == 0) break; } } private: DataStream &stream; uint32_t bits = 0; int bytes_remaining = 0; int bits_in_buffer = 0; }; struct LWZDecoder { LWZDecoder(DataStream &stream): lzw_stream(LWZStream(stream)) { // Each frame has a single bits field. code_bits = stream.ReadByte(); } string DecodeImage(); private: uint16_t code_bits; LWZStream lzw_stream; }; static const int GIFBITS = 12; string LWZDecoder::DecodeImage() { uint32_t dictionary_bits = code_bits + 1; int prev_code1 = -1; int prev_code2 = -1; uint32_t clear = 1 << code_bits; uint32_t end = clear + 1; uint32_t next_free_slot = clear + 2; vector> dictionary; dictionary.resize(1 << GIFBITS); // We append to this buffer as we decode data, then append the data in reverse // order. string append_buffer; string result; while(1) { // Flush append_buffer. for(int i = append_buffer.size() - 1; i >= 0; --i) result.push_back(append_buffer[i]); append_buffer.clear(); int code1 = lzw_stream.ReadLZWCode(dictionary_bits); // printf("%02x"); if(code1 == end) break; if(code1 == clear) { // Clear the dictionary and reset. dictionary_bits = code_bits + 1; next_free_slot = clear + 2; prev_code1 = -1; prev_code2 = -1; continue; } int code2; if(code1 < next_free_slot) code2 = code1; else if(code1 == next_free_slot && prev_code2 != -1) { append_buffer.push_back(prev_code2); code2 = prev_code1; } else throw GIFError(); // Walk through the linked list of codes in the dictionary and append. while(code2 >= clear + 2) { uint8_t append_char = dictionary[code2].first; code2 = dictionary[code2].second; append_buffer.push_back(append_char); } append_buffer.push_back(code2); // If we're already at the last free slot, the dictionary is full and can't be expanded. if(next_free_slot < (1 << dictionary_bits)) { // If we have any free dictionary slots, save. if(prev_code1 != -1) { dictionary[next_free_slot] = make_pair(code2, prev_code1); next_free_slot += 1; } // If we've just filled the last dictionary slot, expand the dictionary size if possible. if(next_free_slot >= (1 << dictionary_bits) && dictionary_bits < GIFBITS) dictionary_bits += 1; } prev_code1 = code1; prev_code2 = code2; } // Skip any remaining data in this block. lzw_stream.Flush(); return result; } struct GlobalGIFData { int width = 0, height = 0; int background_index = -1; bool use_transparency = false; int transparency_index = -1; int duration = 0; int disposal_method = 0; bool have_global_palette = false; Palette palette; }; class GIFDecoder { public: GIFDecoder(DataStream &stream_): stream(stream_) { } void ReadAllFrames(vector &frames); private: bool ReadPacket(string &packet); Palette ReadPalette(int palette_size); void DecodeImage(GlobalGIFData global_data, SMXGif::GIFImage &out); DataStream &stream; SMXGif::GIFImage image; int frame; }; // Read a palette with size colors. // // This is a simple string, with 4 RGBA bytes per color. Palette GIFDecoder::ReadPalette(int palette_size) { Palette result; for(int i = 0; i < palette_size; ++i) { result.color[i].color[0] = stream.ReadByte(); // R result.color[i].color[1] = stream.ReadByte(); // G result.color[i].color[2] = stream.ReadByte(); // B result.color[i].color[3] = 0xFF; } return result; } bool GIFDecoder::ReadPacket(string &packet) { uint8_t packet_size = stream.ReadByte(); if(packet_size == 0) return false; stream.ReadBytes(packet, packet_size); return true; } void GIFDecoder::ReadAllFrames(vector &frames) { string header; stream.ReadBytes(header, 6); if(header != "GIF87a" && header != "GIF89a") throw GIFError(); GlobalGIFData global_data; global_data.width = stream.ReadLE16(); global_data.height = stream.ReadLE16(); image.Init(global_data.width, global_data.height); // Ignore the aspect ratio field. (Supporting pixel aspect ratios in a format // this rudimentary was almost ambitious of them...) uint8_t global_flags = stream.ReadByte(); global_data.background_index = stream.ReadByte(); // Ignore the aspect ratio field. (Supporting pixel aspect ratios in a format // this rudimentary was almost ambitious of them...) stream.ReadByte(); // Decode global_flags. uint8_t global_palette_size = global_flags & 0x7; global_data.have_global_palette = (global_flags >> 7) & 0x1; // If there's no global palette, leave it empty. if(global_data.have_global_palette) global_data.palette = ReadPalette(1 << (global_palette_size + 1)); frame = 0; // Save a copy of global data, so we can restore it after each frame. GlobalGIFData saved_global_data = global_data; // Decode all packets. while(1) { uint8_t packet_type = stream.ReadByte(); if(packet_type == 0x21) { // Extension packet uint8_t extension_type = stream.ReadByte(); if(extension_type == 0xF9) { string packet; if(!ReadPacket(packet)) throw GIFError(); DataStream packet_buf(packet); // Graphics control extension uint8_t gce_flags = packet_buf.ReadByte(); global_data.duration = packet_buf.ReadLE16(); global_data.transparency_index = packet_buf.ReadByte(); global_data.use_transparency = bool(gce_flags & 1); global_data.disposal_method = (gce_flags >> 2) & 0xF; if(!global_data.use_transparency) global_data.transparency_index = -1; } // Read any remaining packets in this extension packet. while(1) { string packet; if(!ReadPacket(packet)) break; } } else if(packet_type == 0x2C) { // Image data SMXGif::GIFImage frame_image; DecodeImage(global_data, frame_image); SMXGif::SMXGifFrame gif_frame; gif_frame.width = global_data.width; gif_frame.height = global_data.height; gif_frame.milliseconds = global_data.duration * 10; gif_frame.frame = frame_image; // If this frame is identical to the previous one, just extend the previous frame. if(!frames.empty() && gif_frame.frame == frames.back().frame) { frames.back().milliseconds += gif_frame.milliseconds; continue; } frames.push_back(gif_frame); frame++; // Reset GCE (frame-specific) data. global_data = saved_global_data; } else if(packet_type == 0x3B) { // EOF return; } else throw GIFError(); } } // Decode a single GIF image into out, leaving this->image ready for // the next frame (with this frame's dispose applied). void GIFDecoder::DecodeImage(GlobalGIFData global_data, SMXGif::GIFImage &out) { uint16_t block_left = stream.ReadLE16(); uint16_t block_top = stream.ReadLE16(); uint16_t block_width = stream.ReadLE16(); uint16_t block_height = stream.ReadLE16(); uint8_t local_flags = stream.ReadByte(); // area = (block_left, block_top, block_left + block_width, block_top + block_height) // Extract flags: uint8_t have_local_palette = (local_flags >> 7) & 1; // bool interlaced = (local_flags >> 6) & 1; uint8_t local_palette_size = (local_flags >> 0) & 0x7; // print 'Interlaced:', interlaced // We don't support interlaced GIFs right now. // assert interlaced == 0 // If this frame has a local palette, use it. Otherwise, use the global palette. Palette active_palette = global_data.palette; if(have_local_palette) active_palette = ReadPalette(1 << (local_palette_size + 1)); if(!global_data.have_global_palette && !have_local_palette) { // We have no palette. This is an invalid file. throw GIFError(); } if(frame == 0) { // On the first frame, clear the buffer. If we have a transparency index, // clear to transparent. Otherwise, clear to the background color. if(global_data.transparency_index != -1) image.Clear(SMXGif::Color(0,0,0,0)); else image.Clear(active_palette.color[global_data.background_index]); } // Decode the compressed image data. LWZDecoder decoder(stream); string decompressed_data = decoder.DecodeImage(); if(decompressed_data.size() < block_width*block_height) throw GIFError(); // Save the region to restore after decoding. SMXGif::GIFImage dispose; if(global_data.disposal_method <= 1) { // No disposal. } else if(global_data.disposal_method == 2) { // Clear the region to a background color afterwards. dispose.Init(block_width, block_height); if(global_data.transparency_index != -1) dispose.Clear(SMXGif::Color(0,0,0,0)); else { uint8_t palette_idx = global_data.background_index; dispose.Clear(active_palette.color[palette_idx]); } } else if(global_data.disposal_method == 3) { // Restore the previous frame afterwards. image.CropImage(dispose, block_left, block_top, block_width, block_height); } else { // Unknown disposal method } int pos = 0; for(int y = block_top; y < block_top + block_height; ++y) { for(int x = block_left; x < block_left + block_width; ++x) { uint8_t palette_idx = decompressed_data[pos]; pos++; if(palette_idx == global_data.transparency_index) { // If this pixel is transparent, leave the existing color in place. } else { image.get(x,y) = active_palette.color[palette_idx]; } } } // Copy the image before we run dispose. out = image; // Restore the dispose area. if(dispose.width != 0) image.Blit(dispose, block_left, block_top, block_width, block_height); } bool SMXGif::DecodeGIF(string buf, vector &frames) { DataStream stream(buf); GIFDecoder gif(stream); try { gif.ReadAllFrames(frames); } catch(GIFError &) { // We don't return error strings for this, just success or failure. return false; } return true; }