//! \file ImageDGC.cs //! \date Tue Jun 02 03:24:27 2015 //! \brief DAC engine image format. // // Copyright (C) 2015 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.ComponentModel.Composition; using System.IO; using System.Windows.Media; using GameRes.Utility; namespace GameRes.Formats.Dac { internal class DgcMetaData : ImageMetaData { public uint Flags; } [Export(typeof(ImageFormat))] public class DgcFormat : ImageFormat { public override string Tag { get { return "DGC"; } } public override string Description { get { return "DAC engine image format"; } } public override uint Signature { get { return 0x00434744; } } // 'DGC' public override ImageMetaData ReadMetaData (Stream stream) { using (var input = new ArcView.Reader (stream)) { input.ReadInt32(); var info = new DgcMetaData(); info.Flags = input.ReadUInt32(); info.Width = input.ReadUInt16(); info.Height = input.ReadUInt16(); if (info.Width > 0x7fff || info.Height > 0x7fff) return null; info.BPP = 0 == (info.Flags & Reader.FlagAlphaChannel) ? 24 : 32; return info; } } public override ImageData Read (Stream stream, ImageMetaData info) { var meta = info as DgcMetaData; if (null == meta) throw new ArgumentException ("DgcFormat.Read should be supplied with DgcMetaData", "info"); stream.Position = 12; using (var reader = new Reader (stream, meta)) { reader.Unpack(); return ImageData.Create (info, reader.Format, null, reader.Data); } } public override void Write (Stream file, ImageData image) { throw new System.NotImplementedException ("DgcFormat.Write not implemented"); } internal class Reader : IDataUnpacker, IDisposable { BinaryReader m_input; byte[] m_output; readonly int m_width; readonly int m_height; readonly int m_max_dict_size; readonly int m_pixel_size; readonly int m_stride; readonly bool m_use_dict; readonly bool m_has_alpha; public const int FlagAlphaChannel = 0x4000000; public const int FlagUseDictionary = 0x2000000; public byte[] Data { get { return m_output; } } public PixelFormat Format { get; private set; } public Reader (Stream input, DgcMetaData info) { m_width = (int)info.Width; m_height = (int)info.Height; m_input = new ArcView.Reader (input); m_use_dict = 0 != (info.Flags & FlagUseDictionary); m_has_alpha = 0 != (info.Flags & FlagAlphaChannel); m_max_dict_size = (int)(info.Flags & 0xffffff); if (m_has_alpha) { Format = PixelFormats.Bgra32; m_pixel_size = 4; } else { Format = PixelFormats.Bgr24; m_pixel_size = 3; } m_stride = m_width * m_pixel_size; m_output = new byte[m_stride*m_height]; } public void Unpack () { if (!m_use_dict) UnpackLZ(); else if (m_max_dict_size > 0x100) UnpackWithDictLarge(); else UnpackWithDictSmall(); if (m_has_alpha) UnpackAlphaChannel(); } void UnpackWithDictLarge () { var dict = new byte[m_max_dict_size * 3]; for (int y = 0; y < m_height;) { int dict_len = m_input.ReadUInt16() + 1; m_input.Read (dict, 0, dict_len * 3); for (int y_end = m_input.ReadUInt16(); y < y_end; y++) { var dst = y * m_stride; short line_size = m_input.ReadInt16(); if (line_size > 0) { if (dict_len > 256) UnpackLine16 (dst, line_size, dict); else UnpackLine8 (dst, line_size, dict); } else if (line_size < 0) { var src_line = (y + line_size) * m_stride; Buffer.BlockCopy (m_output, src_line, m_output, dst, m_stride); } else { for (int x = 0; x < m_width; x++) { int i; if (dict_len > 256) i = m_input.ReadUInt16(); else i = m_input.ReadByte(); i *= 3; m_output[dst] = dict[i]; m_output[dst+1] = dict[i+1]; m_output[dst+2] = dict[i+2]; dst += m_pixel_size; } } } } } void UnpackWithDictSmall () { var dict = new byte[m_max_dict_size * 3]; int dict_len = m_input.ReadByte() + 1; m_input.Read (dict, 0, dict_len * 3); for (int y = 0; y < m_height; y++) { int dst = y * m_stride; int line_size = m_input.ReadInt16(); if (line_size > 0) { UnpackLine8 (dst, line_size, dict); } else if (line_size < 0) { var src_line = (y + line_size) * m_stride; Buffer.BlockCopy (m_output, src_line, m_output, dst, m_stride); } else { for (int x = 0; x < m_width; x++) { int i = 3 * m_input.ReadByte(); m_output[dst] = dict[i]; m_output[dst+1] = dict[i+1]; m_output[dst+2] = dict[i+2]; dst += m_pixel_size; } } } } void UnpackLZ () { for (int y = 0; y < m_height; y++) { int dst = y * m_stride; short line_size = m_input.ReadInt16(); if (line_size > 0) { UnpackLineLZ (dst, line_size); } else if (line_size < 0) { int src_line = (y + line_size) * m_stride; Buffer.BlockCopy (m_output, src_line, m_output, dst, m_stride); } else { for (int x = 0; x < m_width; x++) { m_input.Read (m_output, dst, 3); dst += m_pixel_size; } } } } void UnpackAlphaChannel() { int alpha_pos = 3; for (int y = 0; y < m_height; y++) { int dst = alpha_pos + y * m_stride; short line_size = m_input.ReadInt16(); if (line_size > 0) { UnpackLineAlpha (dst, line_size); } else if (line_size < 0) { int src_line = alpha_pos + (y + line_size) * m_stride; for (int x = 0; x < m_width; x++) { m_output[dst] = m_output[src_line]; dst += m_pixel_size; src_line += m_pixel_size; } } else { for (int x = 0; x < m_width; x++) { m_output[dst] = m_input.ReadByte(); dst += m_pixel_size; } } } } void UnpackLine16 (int dst, int length, byte[] dict) { while (length > 0) { short ctl = m_input.ReadInt16(); length -= 2; if (0 != (ctl & 0x8000)) { int count = (ctl & 0x3F) + 2; int offset = ctl >> 6; offset *= m_pixel_size; count *= m_pixel_size; Binary.CopyOverlapped (m_output, dst+offset, dst, count); dst += count; } else { int count = ctl & 0x1FFF; if (0 != (ctl & 0x4000)) { int index = 0; if (0 != (ctl & 0x2000)) { index = m_input.ReadByte(); --length; } else { index = m_input.ReadUInt16(); length -= 2; } index *= 3; while (0 != count--) { m_output[dst] = dict[index]; m_output[dst+1] = dict[index+1]; m_output[dst+2] = dict[index+2]; dst += m_pixel_size; } } else { while (0 != count--) { int index = 0; if (0 != (ctl & 0x2000)) { index = m_input.ReadByte(); --length; } else { index = m_input.ReadUInt16(); length -= 2; } index *= 3; m_output[dst] = dict[index]; m_output[dst+1] = dict[index+1]; m_output[dst+2] = dict[index+2]; dst += m_pixel_size; } } } } } void UnpackLine8 (int dst, int length, byte[] dict) { while (length > 0) { byte ctl = m_input.ReadByte(); --length; if (0 != ctl) { int index = 3 * m_input.ReadByte(); --length; while (0 != ctl--) { m_output[dst] = dict[index]; m_output[dst+1] = dict[index+1]; m_output[dst+2] = dict[index+2]; dst += m_pixel_size; } } else { ctl = m_input.ReadByte(); --length; if (0 == (ctl & 0x80)) { for (int count = ctl + 2; 0 != count; --count) { int src = 3 * m_input.ReadByte(); --length; m_output[dst] = dict[src]; m_output[dst+1] = dict[src+1]; m_output[dst+2] = dict[src+2]; dst += m_pixel_size; } } else { int offset = (short)((ctl << 8) | m_input.ReadByte()); --length; int count = (offset & 0x3F) + 4; offset >>= 6; offset *= m_pixel_size; count *= m_pixel_size; Binary.CopyOverlapped (m_output, dst+offset, dst, count); dst += count; } } } } void UnpackLineAlpha (int dst, int length) { while (length > 0) { byte ctl = m_input.ReadByte(); --length; if (0 != ctl) { byte alpha = m_input.ReadByte(); --length; while (0 != ctl--) { m_output[dst] = alpha; dst += m_pixel_size; } } else { ctl = m_input.ReadByte(); --length; if (0 == (ctl & 0x80)) { int count = ctl + 2; length -= count; while (0 != count--) { m_output[dst] = m_input.ReadByte(); dst += m_pixel_size; } } else { int offset = (short)((ctl << 8) | m_input.ReadByte()); --length; int count = (offset & 0x3F) + 4; offset >>= 6; offset *= m_pixel_size; while (0 != count--) { m_output[dst] = m_output[dst+offset]; dst += m_pixel_size; } } } } } void UnpackLineLZ (int dst, int length) { while (length > 0) { short ctl = m_input.ReadInt16(); length -= 2; if (0 != (ctl & 0x8000)) { int count = (ctl & 0x3F) + 1; int offset = ctl >> 6; offset *= m_pixel_size; while (0 != count--) { m_output[dst] = m_output[dst+offset]; m_output[dst+1] = m_output[dst+offset+1]; m_output[dst+2] = m_output[dst+offset+2]; dst += m_pixel_size; } } else { int count = ctl & 0x1FFF; if (0 != (ctl & 0x4000)) { m_input.Read (m_output, dst, 3); length -= 3; dst += m_pixel_size; if (--count > 0) { count *= m_pixel_size; Binary.CopyOverlapped (m_output, dst-m_pixel_size, dst, count); dst += count; } } else { while (0 != count--) { m_input.Read (m_output, dst, 3); length -= 3; dst += m_pixel_size; } } } } } #region IDisposable Members bool disposed = false; public void Dispose () { Dispose (true); GC.SuppressFinalize (this); } protected virtual void Dispose (bool disposing) { if (!disposed) { if (disposing) { m_input.Dispose(); } disposed = true; } } #endregion } } }