//! \file ImageGAL.cs //! \date Wed Jun 08 03:07:41 2016 //! \brief LiveMaker image format. // // Copyright (C) 2016 by morkt // // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to // deal in the Software without restriction, including without limitation the // rights to use, copy, modify, merge, publish, distribute, sublicense, and/or // sell copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING // FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS // IN THE SOFTWARE. // using System; using System.Collections.Generic; using System.ComponentModel.Composition; using System.IO; using System.Linq; using System.Windows.Media; using System.Windows.Media.Imaging; using GameRes.Compression; using GameRes.Formats.Strings; using GameRes.Utility; namespace GameRes.Formats.LiveMaker { internal class GalMetaData : ImageMetaData { public int Version; public int FrameCount; public bool Shuffled; public int Compression; public uint Mask; public int BlockWidth; public int BlockHeight; public int DataOffset; } internal class GalOptions : ResourceOptions { public uint Key; } [Serializable] public class GalScheme : ResourceScheme { public Dictionary KnownKeys; } [Export(typeof(ImageFormat))] public class GalFormat : ImageFormat { public override string Tag { get { return "GAL"; } } public override string Description { get { return "LiveMaker image format"; } } public override uint Signature { get { return 0x656C6147; } } // 'Gale' public static Dictionary KnownKeys = new Dictionary(); public override ResourceScheme Scheme { get { return new GalScheme { KnownKeys = KnownKeys }; } set { KnownKeys = ((GalScheme)value).KnownKeys; } } public override ImageMetaData ReadMetaData (IBinaryStream stream) { var header = new byte[0x30]; if (11 != stream.Read (header, 0, 11)) return null; int version = header[4] * 100 + header[5] * 10 + header[6] - 5328; if (version < 100 || version > 107) return null; int header_size = LittleEndian.ToInt32 (header, 7); if (header_size < 0x28 || header_size > 0x100) return null; if (header_size > header.Length) header = new byte[header_size]; if (header_size != stream.Read (header, 0, header_size)) return null; if (version != LittleEndian.ToInt32 (header, 0)) return null; return new GalMetaData { Width = LittleEndian.ToUInt32 (header, 4), Height = LittleEndian.ToUInt32 (header, 8), BPP = LittleEndian.ToInt32 (header, 0xC), Version = version, FrameCount = LittleEndian.ToInt32 (header, 0x10), Shuffled = header[0x15] != 0, Compression = header[0x16], Mask = LittleEndian.ToUInt32 (header, 0x18), BlockWidth = LittleEndian.ToInt32 (header, 0x1C), BlockHeight = LittleEndian.ToInt32 (header, 0x20), DataOffset = header_size + 11, }; } uint? LastKey = null; public override ImageData Read (IBinaryStream stream, ImageMetaData info) { var meta = (GalMetaData)info; uint key = 0; if (meta.Shuffled) { if (LastKey != null) key = LastKey.Value; else key = QueryKey(); } try { using (var reader = new GalReader (stream, meta, key)) { reader.Unpack(); if (meta.Shuffled) LastKey = key; return ImageData.Create (info, reader.Format, reader.Palette, reader.Data, reader.Stride); } } catch { LastKey = null; throw; } } public override void Write (Stream file, ImageData image) { throw new System.NotImplementedException ("GalFormat.Write not implemented"); } public override ResourceOptions GetDefaultOptions () { return new GalOptions { Key = KeyFromString (Properties.Settings.Default.GALKey) }; } public override object GetAccessWidget () { return new GUI.WidgetGAL(); } internal uint QueryKey () { if (!KnownKeys.Any()) return 0; var options = Query (arcStrings.ArcImageEncrypted); return options.Key; } public static uint KeyFromString (string key) { if (string.IsNullOrWhiteSpace (key) || key.Length < 4) return 0; return (uint)(key[0] | key[1] << 8 | key[2] << 16 | key[3] << 24); } } internal class GalReader : IDisposable { protected IBinaryStream m_input; protected GalMetaData m_info; protected byte[] m_output; protected List m_frames; protected uint m_key; public byte[] Data { get { return m_output; } } public PixelFormat Format { get; private set; } public BitmapPalette Palette { get; private set; } public int Stride { get; private set; } public GalReader (IBinaryStream input, GalMetaData info, uint key) { m_info = info; if (m_info.Compression < 0 || m_info.Compression > 2) throw new InvalidFormatException(); m_frames = new List (m_info.FrameCount); m_key = key; m_input = input; } internal class Frame { public int Width; public int Height; public int BPP; public int Stride; public int AlphaStride; public List Layers; public Color[] Palette; public Frame (int layer_count) { Layers = new List (layer_count); } public void SetStride () { Stride = (Width * BPP + 7) / 8; AlphaStride = (Width + 3) & ~3; if (BPP >= 8) Stride = (Stride + 3) & ~3; } } internal class Layer { public byte[] Pixels; public byte[] Alpha; } public void Unpack () { m_input.Position = m_info.DataOffset; uint name_length = m_input.ReadUInt32(); m_input.Seek (name_length, SeekOrigin.Current); uint mask = m_input.ReadUInt32(); m_input.Seek (9, SeekOrigin.Current); int layer_count = m_input.ReadInt32(); if (layer_count < 1) throw new InvalidFormatException(); // XXX only first frame is interpreted. var frame = new Frame (layer_count); frame.Width = m_input.ReadInt32(); frame.Height = m_input.ReadInt32(); frame.BPP = m_input.ReadInt32(); if (frame.BPP <= 0) throw new InvalidFormatException(); if (frame.BPP <= 8) frame.Palette = ImageFormat.ReadColorMap (m_input.AsStream, 1 << frame.BPP); frame.SetStride(); m_frames.Add (frame); for (int i = 0; i < layer_count; ++i) { m_input.ReadInt32(); // left m_input.ReadInt32(); // top m_input.ReadByte(); // visibility m_input.ReadInt32(); // (-1) TransColor m_input.ReadInt32(); // (0xFF) alpha m_input.ReadByte(); // AlphaOn name_length = m_input.ReadUInt32(); m_input.Seek (name_length, SeekOrigin.Current); if (m_info.Version >= 107) m_input.ReadByte(); // lock var layer = new Layer(); int layer_size = m_input.ReadInt32(); layer.Pixels = UnpackLayer (frame, layer_size); int alpha_size = m_input.ReadInt32(); if (alpha_size != 0) { layer.Alpha = UnpackLayer (frame, alpha_size, true); } frame.Layers.Add (layer); } Flatten (0); } protected byte[] UnpackLayer (Frame frame, int length, bool is_alpha = false) { var layer_start = m_input.Position; var layer_end = layer_start + length; var packed = new StreamRegion (m_input.AsStream, layer_start, length, true); try { if (0 == m_info.Compression || 2 == m_info.Compression && is_alpha) return ReadZlib (frame, packed, is_alpha); if (2 == m_info.Compression) return ReadJpeg (frame, packed); return ReadBlocks (frame, packed, is_alpha); } finally { packed.Dispose(); m_input.Position = layer_end; } } byte[] ReadBlocks (Frame frame, Stream packed, bool is_alpha) { if (m_info.BlockWidth <= 0 || m_info.BlockHeight <= 0) return ReadRaw (frame, packed, is_alpha); int blocks_w = (frame.Width + m_info.BlockWidth - 1) / m_info.BlockWidth; int blocks_h = (frame.Height + m_info.BlockHeight - 1) / m_info.BlockHeight; int blocks_count = blocks_w * blocks_h; var data = new byte[blocks_count * 8]; packed.Read (data, 0, data.Length); var refs = new int[blocks_count * 2]; Buffer.BlockCopy (data, 0, refs, 0, data.Length); if (m_info.Shuffled) ShuffleBlocks (refs, blocks_count); int bpp = is_alpha ? 8 : frame.BPP; int stride = is_alpha ? frame.AlphaStride : frame.Stride; var pixels = new byte[stride * frame.Height]; int i = 0; for (int y = 0; y < frame.Height; y += m_info.BlockHeight) { int height = Math.Min (m_info.BlockHeight, frame.Height - y); for (int x = 0; x < frame.Width; x += m_info.BlockWidth) { int dst = y * stride + (x * bpp + 7) / 8; int width = Math.Min (m_info.BlockWidth, frame.Width - x); int chunk_size = (width * bpp + 7) / 8; if (-1 == refs[i]) { for (int j = 0; j < height; ++j) { packed.Read (pixels, dst, chunk_size); dst += stride; } } else if (-2 == refs[i]) { int src_x = m_info.BlockWidth * (refs[i+1] % blocks_w); int src_y = m_info.BlockHeight * (refs[i+1] / blocks_w); int src = src_y * stride + (src_x * bpp + 7) / 8; for (int j = 0; j < height; ++j) { Buffer.BlockCopy (pixels, src, pixels, dst, chunk_size); src += stride; dst += stride; } } else { int frame_ref = refs[i]; int layer_ref = refs[i+1]; if (frame_ref >= m_frames.Count || layer_ref >= m_frames[frame_ref].Layers.Count) throw new InvalidFormatException(); var layer = m_frames[frame_ref].Layers[layer_ref]; byte[] src = is_alpha ? layer.Alpha : layer.Pixels; for (int j = 0; j < height; ++j) { Buffer.BlockCopy (src, dst, pixels, dst, chunk_size); dst += stride; } } i += 2; } } return pixels; } byte[] ReadRaw (Frame frame, Stream packed, bool is_alpha) { int stride = is_alpha ? frame.AlphaStride : frame.Stride; var pixels = new byte[frame.Height * stride]; if (m_info.Shuffled) { foreach (var dst in RandomSequence (frame.Height, m_key)) { packed.Read (pixels, dst*stride, stride); } } else { packed.Read (pixels, 0, pixels.Length); } return pixels; } byte[] ReadZlib (Frame frame, Stream packed, bool is_alpha) { using (var zs = new ZLibStream (packed, CompressionMode.Decompress)) return ReadBlocks (frame, zs, is_alpha); } byte[] ReadJpeg (Frame frame, Stream packed) { var decoder = new JpegBitmapDecoder (packed, BitmapCreateOptions.None, BitmapCacheOption.OnLoad); var bitmap = decoder.Frames[0]; frame.BPP = bitmap.Format.BitsPerPixel; int stride = bitmap.PixelWidth * bitmap.Format.BitsPerPixel / 8; var pixels = new byte[bitmap.PixelHeight * stride]; bitmap.CopyPixels (pixels, stride, 0); frame.Stride = stride; return pixels; } protected void Flatten (int frame_num) { // XXX only first layer is considered. var frame = m_frames[frame_num]; var layer = frame.Layers[0]; if (null == layer.Alpha) { m_output = layer.Pixels; if (null != frame.Palette) Palette = new BitmapPalette (frame.Palette); if (8 == frame.BPP) Format = PixelFormats.Indexed8; else if (16 == frame.BPP) Format = PixelFormats.Bgr565; else if (24 == frame.BPP) Format = PixelFormats.Bgr24; else if (32 == frame.BPP) Format = PixelFormats.Bgr32; else if (4 == frame.BPP) Format = PixelFormats.Indexed4; else throw new NotSupportedException(); Stride = frame.Stride; } else { m_output = new byte[frame.Width * frame.Height * 4]; switch (frame.BPP) { case 4: Flatten4bpp (frame, layer); break; case 8: Flatten8bpp (frame, layer); break; case 16: Flatten16bpp (frame, layer); break; case 24: Flatten24bpp (frame, layer); break; case 32: Flatten32bpp (frame, layer); break; default: throw new NotSupportedException ("Not supported color depth"); } Format = PixelFormats.Bgra32; Stride = frame.Width * 4; } } void Flatten4bpp (Frame frame, Layer layer) { int dst = 0; int src = 0; int a = 0; for (int y = 0; y < frame.Height; ++y) { for (int x = 0; x < frame.Width; ++x) { byte pixel = layer.Pixels[src + x/2]; int index = 0 == (x & 1) ? (pixel & 0xF) : (pixel >> 4); var color = frame.Palette[index]; m_output[dst++] = color.B; m_output[dst++] = color.G; m_output[dst++] = color.R; m_output[dst++] = layer.Alpha[a+x]; } src += frame.Stride; a += frame.AlphaStride; } } void Flatten8bpp (Frame frame, Layer layer) { int dst = 0; int src = 0; int a = 0; for (int y = 0; y < frame.Height; ++y) { for (int x = 0; x < frame.Width; ++x) { var color = frame.Palette[ layer.Pixels[src+x] ]; m_output[dst++] = color.B; m_output[dst++] = color.G; m_output[dst++] = color.R; m_output[dst++] = layer.Alpha[a+x]; } src += frame.Stride; a += frame.AlphaStride; } } void Flatten16bpp (Frame frame, Layer layer) { int src = 0; int dst = 0; int a = 0; for (int y = 0; y < frame.Height; ++y) { for (int x = 0; x < frame.Width; ++x) { int pixel = LittleEndian.ToUInt16 (layer.Pixels, src + x*2); m_output[dst++] = (byte)((pixel & 0x001F) * 0xFF / 0x001F); m_output[dst++] = (byte)((pixel & 0x07E0) * 0xFF / 0x07E0); m_output[dst++] = (byte)((pixel & 0xF800) * 0xFF / 0xF800); m_output[dst++] = layer.Alpha[a+x]; } src += frame.Stride; a += frame.AlphaStride; } } void Flatten24bpp (Frame frame, Layer layer) { int src = 0; int dst = 0; int a = 0; int gap = frame.Stride - frame.Width * 3; for (int y = 0; y < frame.Height; ++y) { for (int x = 0; x < frame.Width; ++x) { m_output[dst++] = layer.Pixels[src++]; m_output[dst++] = layer.Pixels[src++]; m_output[dst++] = layer.Pixels[src++]; m_output[dst++] = layer.Alpha[a+x]; } src += gap; a += frame.AlphaStride; } } void Flatten32bpp (Frame frame, Layer layer) { int src = 0; int dst = 0; int a = 0; for (int y = 0; y < frame.Height; ++y) { for (int x = 0; x < frame.Width; ++x) { m_output[dst++] = layer.Pixels[src]; m_output[dst++] = layer.Pixels[src+1]; m_output[dst++] = layer.Pixels[src+2]; m_output[dst++] = layer.Alpha[a+x]; src += 4; } a += frame.AlphaStride; } } void ShuffleBlocks (int[] refs, int count) { var copy = refs.Clone() as int[]; int src = 0; foreach (var index in RandomSequence (count, m_key)) { refs[index*2] = copy[src++]; refs[index*2+1] = copy[src++]; } } static IEnumerable RandomSequence (int count, uint seed) { var tp = new TpRandom (seed); var order = Enumerable.Range (0, count).ToList(); for (int i = 0; i < count; ++i) { int n = (int)(tp.GetRand32() % (uint)order.Count); yield return order[n]; order.RemoveAt (n); } } #region IDisposable Members bool m_disposed = false; public void Dispose () { Dispose (true); GC.SuppressFinalize (this); } protected virtual void Dispose (bool disposing) { if (!m_disposed) { m_disposed = true; } } #endregion } }