//! \file ArcPSB.cs //! \date Thu Mar 24 01:40:57 2016 //! \brief E-mote engine image container. // // 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; using System.Collections.Generic; using System.ComponentModel.Composition; using System.IO; using System.Text; using System.Windows.Media; using GameRes.Utility; namespace GameRes.Formats.Emote { internal class TexEntry : Entry { public string TexType; public int Width; public int Height; public int TruncatedWidth; public int TruncatedHeight; public int OffsetX; public int OffsetY; } [Serializable] public class PsbScheme : ResourceScheme { public uint[] KnownKeys; } [Export(typeof(ArchiveFormat))] public class PsbOpener : ArchiveFormat { public override string Tag { get { return "PSB/EMOTE"; } } public override string Description { get { return "E-mote engine texture container"; } } public override uint Signature { get { return 0x425350; } } // 'PSB' public override bool IsHierarchic { get { return false; } } public override bool CanWrite { get { return false; } } static uint[] KnownKeys = new uint[] { 970396437u }; public PsbOpener () { Extensions = new string[] { "psb", "pimg" }; } public override ArcFile TryOpen (ArcView file) { using (var input = file.CreateStream()) using (var reader = new PsbReader (input)) { foreach (var key in KnownKeys) { if (reader.Parse (key)) { var dir = reader.GetTextures(); if (null == dir || 0 == dir.Count) return null; return new ArcFile (file, this, dir); } if (!reader.IsEncrypted) break; } if (reader.ParseNonEncrypted()) { var dir = reader.GetLayers(); if (null == dir) return null; return new ArcFile (file, this, dir); } return null; } } public override IImageDecoder OpenImage (ArcFile arc, Entry entry) { var tex = (TexEntry)entry; if ("TLG" == tex.TexType) return OpenTlg (arc, tex); var info = new PsbTexMetaData { FullWidth = tex.Width, FullHeight = tex.Height, Width = (uint)tex.TruncatedWidth, Height = (uint)tex.TruncatedHeight, TexType = tex.TexType, BPP = 32 }; var input = arc.File.CreateStream (entry.Offset, entry.Size); return new PsbTextureDecoder (input, info); } IImageDecoder OpenTlg (ArcFile arc, TexEntry entry) { var input = arc.File.CreateStream (entry.Offset, entry.Size); try { var info = TlgFormat.ReadMetaData (input); if (null == info) throw new InvalidFormatException(); info.OffsetX = entry.OffsetX; info.OffsetY = entry.OffsetY; return new ImageFormatDecoder (input, TlgFormat, info); } catch { input.Dispose(); throw; } } public override ResourceScheme Scheme { get { return new PsbScheme { KnownKeys = KnownKeys }; } set { KnownKeys = ((PsbScheme)value).KnownKeys; } } ImageFormat TlgFormat { get { return s_TlgFormat.Value; } } static Lazy s_TlgFormat = new Lazy (() => ImageFormat.FindByTag ("TLG")); } /// /// PSB container deserialization. /// internal sealed class PsbReader : IDisposable { IBinaryStream m_input; public PsbReader (IBinaryStream input) { m_input = input; } public int Version { get { return m_version; } } public bool IsEncrypted { get { return 0 != (m_flags & 3); } } public int DataOffset { get { return m_chunk_data; } } public T GetRootKey (string key) { int obj_offset; if (!GetKey (key, m_root, out obj_offset)) return default(T); return (T)GetObject (obj_offset); } int m_version; int m_flags; uint[] m_key = new uint[6]; Dictionary m_name_map; public bool ParseNonEncrypted () { return Parse (false); } public bool Parse (uint key) { m_key[0] = 0x075BCD15; m_key[1] = 0x159A55E5; m_key[2] = 0x1F123BB5; m_key[3] = key; m_key[4] = 0; m_key[5] = 0; return Parse (true); } bool Parse (bool encrypted) { if (!ReadHeader (encrypted)) return false; if (Version < 2) throw new NotSupportedException ("Not supported PSB version"); m_name_map = ReadNames(); #if DEBUG var dict = GetDict (m_root); // returns all metadata in a single dictionary #endif return true; } public List GetLayers () { var layers = GetRootKey ("layers"); if (null == layers || 0 == layers.Count) return null; var dir = new List (layers.Count); foreach (IDictionary layer in layers) { var name = layer["layer_id"].ToString() + ".tlg"; var layer_data = GetRootKey (name); if (null == layer_data) continue; var entry = new TexEntry { Name = name, Type = "image", Offset = DataOffset + layer_data.Offset, Size = (uint)layer_data.Length, TexType = "TLG", OffsetX = Convert.ToInt32 (layer["left"]), OffsetY = Convert.ToInt32 (layer["top"]), Width = Convert.ToInt32 (layer["width"]), Height = Convert.ToInt32 (layer["height"]), }; dir.Add (entry); } if (0 == dir.Count) return null; return dir; } public List GetTextures () { var source = GetRootKey ("source"); if (null == source || 0 == source.Count) return null; var dir = new List (source.Count); foreach (DictionaryEntry item in source) { var item_value = item.Value as IDictionary; if (null == item_value) continue; var texture = item_value["texture"] as IDictionary; if (null == texture) continue; var pixel = texture["pixel"] as EmChunk; if (null == pixel) continue; var entry = new TexEntry { Name = item.Key.ToString(), Type = "image", Offset = DataOffset + pixel.Offset, Size = (uint)pixel.Length, TexType = texture["type"].ToString(), Width = Convert.ToInt32 (texture["width"]), Height = Convert.ToInt32 (texture["height"]), TruncatedWidth = Convert.ToInt32 (texture["truncated_width"]), TruncatedHeight = Convert.ToInt32 (texture["truncated_height"]), }; dir.Add (entry); } return dir; } int m_names; int m_strings; int m_strings_data; int m_chunk_offsets; int m_chunk_lengths; int m_chunk_data; int m_root; byte[] m_data; bool ReadHeader (bool encrypted) { m_input.Position = 4; m_version = m_input.ReadUInt16(); m_flags = m_input.ReadUInt16(); if (encrypted && m_version < 3) m_flags = 2; var header = m_input.ReadBytes (0x20); if (encrypted && 0 != (m_flags & 1)) Decrypt (header, 0, 0x20); m_names = LittleEndian.ToInt32 (header, 0x04); m_strings = LittleEndian.ToInt32 (header, 0x08); m_strings_data = LittleEndian.ToInt32 (header, 0x0C); m_chunk_offsets = LittleEndian.ToInt32 (header, 0x10); m_chunk_lengths = LittleEndian.ToInt32 (header, 0x14); m_chunk_data = LittleEndian.ToInt32 (header, 0x18); m_root = LittleEndian.ToInt32 (header, 0x1C); int buffer_length = (int)m_input.Length; if (!(m_names >= 0x28 && m_names < m_chunk_data && m_strings >= 0x28 && m_strings < m_chunk_data && m_strings_data >= 0x28 && m_strings_data < m_chunk_data && m_chunk_offsets >= 0x28 && m_chunk_offsets < m_chunk_data && m_chunk_lengths >= 0x28 && m_chunk_lengths < m_chunk_data && m_chunk_data >= 0x28 && m_chunk_data < buffer_length && m_root >= 0x28 && m_root < m_chunk_data)) return false; if (null == m_data || m_data.Length < m_chunk_data) m_data = new byte[m_chunk_data]; int data_pos = (int)m_input.Position; m_input.Read (m_data, data_pos, m_chunk_data-data_pos); if (encrypted && 0 != (m_flags & 2)) Decrypt (m_data, m_names, m_chunk_offsets-m_names); // root object is a dictionary return 0x21 == m_data[m_root]; } bool GetKey (string name, int dict_offset, out int value_offset) { value_offset = 0; int offset; if (!GetOffset (name, out offset)) return false; var keys = GetArray (++dict_offset); if (0 == keys.Count) return false; int upper_bound = keys.Count; int lower_bound = 0; int key_index = 0; while (lower_bound < upper_bound) { key_index = (upper_bound + lower_bound) >> 1; int key = GetArrayElem (keys, key_index); if (key == offset) break; if (key >= offset) upper_bound = (upper_bound + lower_bound) >> 1; else lower_bound = key_index + 1; } if (lower_bound >= upper_bound) return false; var values = GetArray (dict_offset + keys.ArraySize); int data_offset = GetArrayElem (values, key_index); value_offset = dict_offset + keys.ArraySize + values.ArraySize + data_offset; return true; } bool GetOffset (string name, out int offset) { // FIXME works for ASCII names only. var nm1 = GetArray (m_names); var nm2 = GetArray (m_names + nm1.ArraySize); int i = 0; for (int name_idx = 0; ; ++name_idx) { char symbol = name_idx < name.Length ? name[name_idx] : '\0'; int prev_i = i; i = symbol + GetArrayElem (nm1, i); if (i >= nm1.Count || GetArrayElem (nm2, i) != prev_i) break; if (name_idx >= name.Length) { offset = GetArrayElem (nm1, i); return true; } } offset = 0; return false; } Dictionary ReadNames () { // this implementation is utterly inefficient. FIXME var lookup = new Dictionary(); var next_lookup = new Dictionary(); var dict = new Dictionary(); var nm1 = GetArray (m_names); var nm2 = GetArray (m_names + nm1.ArraySize); lookup[0] = new byte[0]; while (lookup.Count > 0) { foreach (var item in lookup) { int first = GetArrayElem (nm1, item.Key); for (int i = 0; i < 256 && i + first < nm2.Count; ++i) { if (GetArrayElem (nm2, i + first) == item.Key) { if (0 == i) dict[GetArrayElem (nm1, i + first)] = Encoding.UTF8.GetString (item.Value); else next_lookup[i+first] = ArrayAppend (item.Value, (byte)i); } } } var tmp = lookup; lookup = next_lookup; next_lookup = tmp; next_lookup.Clear(); } return dict; } static byte[] ArrayAppend (byte[] array, byte n) { var new_array = new byte[array.Length+1]; Buffer.BlockCopy (array, 0, new_array, 0, array.Length); new_array[array.Length] = n; return new_array; } EmArray GetArray (int offset) { int data_offset = m_data[offset] - 10; var array = new EmArray { Count = GetInteger (offset, 0xC), ElemSize = m_data[offset + data_offset - 1] - 12, DataOffset = offset + data_offset, }; array.ArraySize = array.Count * array.ElemSize + data_offset; return array; } int GetArrayElem (EmArray a1, int index) { int offset = index * a1.ElemSize; switch (a1.ElemSize) { case 1: return m_data[a1.DataOffset + offset]; case 2: return LittleEndian.ToUInt16 (m_data, a1.DataOffset + offset); case 3: return LittleEndian.ToUInt16 (m_data, a1.DataOffset + offset) | m_data[a1.DataOffset + offset + 2] << 16; case 4: return LittleEndian.ToInt32 (m_data, a1.DataOffset + offset); default: throw new InvalidFormatException ("Invalid PSB array structure"); } } object GetObject (int offset) { switch (m_data[offset]) { case 1: return null; case 2: return true; case 3: return false; case 4: case 5: case 6: case 7: case 8: return GetInteger (offset, 4); case 9: case 0x0A: case 0x0B: case 0x0C: return GetLong (offset); case 0x15: case 0x16: case 0x17: case 0x18: return GetString (offset); case 0x19: case 0x1A: case 0x1B: case 0x1C: return GetChunk (offset); case 0x1D: case 0x1E: return GetFloat (offset); case 0x1F: return GetDouble (offset); case 0x20: return GetList (offset); case 0x21: return GetDict (offset); default: throw new InvalidFormatException (string.Format ("Unknown serialized object type 0x{0:X2}", m_data[offset])); } } int GetInteger (int offset, int base_type) { switch (m_data[offset] - base_type) { case 1: return m_data[offset+1]; case 2: return LittleEndian.ToUInt16 (m_data, offset+1); case 3: return LittleEndian.ToUInt16 (m_data, offset+1) | m_data[offset+3] << 16; case 4: return LittleEndian.ToInt32 (m_data, offset+1); default: return 0; } } float GetFloat (int offset) { if (0x1E == m_data[offset]) return BitConverter.ToSingle (m_data, offset+1); // FIXME endianness else return 0.0f; } double GetDouble (int offset) { if (0x1F == m_data[offset]) return BitConverter.ToDouble (m_data, offset+1); // FIXME endianness else return 0.0; } long GetLong (int offset) { switch (m_data[offset]) { case 0x09: return LittleEndian.ToUInt32 (m_data, offset+1) | (long)(sbyte)m_data[offset+5] << 32; case 0x0A: return LittleEndian.ToUInt32 (m_data, offset+1) | (long)LittleEndian.ToInt16 (m_data, offset+5) << 32; case 0x0B: return LittleEndian.ToUInt32 (m_data, offset+1) | (long)LittleEndian.ToUInt16 (m_data, offset+5) << 32 | (long)(sbyte)m_data[offset+6] << 48; case 0x0C: return LittleEndian.ToInt64 (m_data, offset+1); default: return 0L; } } string GetString (int obj_offset) { int index = GetInteger (obj_offset, 0x14); var array = GetArray (m_strings); int data_offset = m_strings_data + GetArrayElem (array, index); return Binary.GetCString (m_data, data_offset, m_data.Length-data_offset, Encoding.UTF8); } IList GetList (int offset) { var array = GetArray (++offset); var list = new ArrayList (array.Count); for (int i = 0; i < array.Count; ++i) { int item_offset = offset + array.ArraySize + GetArrayElem (array, i); var item = GetObject (item_offset); list.Add (item); } return list; } IDictionary GetDict (int offset) { var keys = GetArray (++offset); if (0 == keys.Count) return new Dictionary(); var values = GetArray (offset + keys.ArraySize); var dict = new Dictionary (keys.Count); for (int i = 0; i < keys.Count; ++i) { int key = GetArrayElem (keys, i); var value_offset = GetArrayElem (values, i); string key_name = m_name_map[key]; dict[key_name] = GetObject (offset + value_offset + keys.ArraySize + values.ArraySize); } return dict; } EmChunk GetChunk (int offset) { var chunk_index = GetInteger (offset, 0x18); var chunks = GetArray (m_chunk_offsets); if (chunk_index >= chunks.Count) throw new InvalidFormatException ("Invalid chunk index"); var lengths = GetArray (m_chunk_lengths); return new EmChunk { Offset = GetArrayElem (chunks, chunk_index), Length = GetArrayElem (lengths, chunk_index), }; } void Decrypt (byte[] data, int offset, int length) { for (int i = 0; i < length; ++i) { if (0 == m_key[4]) { var v5 = m_key[3]; var v6 = m_key[0] ^ (m_key[0] << 11); m_key[0] = m_key[1]; m_key[1] = m_key[2]; var eax = v6 ^ v5 ^ ((v6 ^ (v5 >> 11)) >> 8); m_key[2] = v5; m_key[3] = eax; m_key[4] = eax; } data[offset+i] ^= (byte)m_key[4]; m_key[4] >>= 8; } } internal class EmArray { public int ArraySize; public int Count; public int ElemSize; public int DataOffset; } internal class EmChunk { public int Offset; public int Length; } #region IDisposable Members public void Dispose () { } #endregion } internal class PsbTexMetaData : ImageMetaData { public string TexType; public int FullWidth; public int FullHeight; } /// /// Artificial format representing PSB texture. /// internal sealed class PsbTextureDecoder : BinaryImageDecoder { PsbTexMetaData m_info; public PsbTextureDecoder (IBinaryStream input, PsbTexMetaData info) : base (input, info) { m_input = input; m_info = info; } protected override ImageData GetImageData () { var pixels = new byte[m_info.Width * m_info.Height * 4]; if ("RGBA8" == m_info.TexType) ReadRgba8 (pixels); else if ("RGBA4444" == m_info.TexType) ReadRgba4444 (pixels); else throw new NotImplementedException (string.Format ("PSB texture format '{0}' not implemented", m_info.TexType)); return ImageData.Create (m_info, PixelFormats.Bgra32, null, pixels); } void ReadRgba8 (byte[] output) { int dst_stride = (int)m_info.Width * 4; long next_row = 0; int src_stride = m_info.FullWidth * 4; int dst = 0; for (uint i = 0; i < m_info.Height; ++i) { m_input.Position = next_row; m_input.Read (output, dst, dst_stride); dst += dst_stride; next_row += src_stride; } } void ReadRgba4444 (byte[] output) { int dst_stride = (int)m_info.Width * 4; int src_stride = m_info.FullWidth * 2; int dst = 0; var row = new byte[src_stride]; m_input.Position = 0; for (uint i = 0; i < m_info.Height; ++i) { m_input.Read (row, 0, src_stride); int src = 0; for (int x = 0; x < dst_stride; x += 4) { uint p = LittleEndian.ToUInt16 (row, src); src += 2; output[dst++] = (byte)((p & 0x000Fu) * 0xFFu / 0x000Fu); output[dst++] = (byte)((p & 0x00F0u) * 0xFFu / 0x00F0u); output[dst++] = (byte)((p & 0x0F00u) * 0xFFu / 0x0F00u); output[dst++] = (byte)((p & 0xF000u) * 0xFFu / 0xF000u); } } } } }