//! \file ArcAFA.cs //! \date Mon Apr 25 18:18:57 2016 //! \brief AliceSoft System 4 engine resource archive. // // Copyright (C) 2016-2018 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.Text; using GameRes.Compression; namespace GameRes.Formats.AliceSoft { [Export(typeof(ArchiveFormat))] public class AfaOpener : ArchiveFormat { public override string Tag { get { return "AFA"; } } public override string Description { get { return "AliceSoft System 4 resource archive"; } } public override uint Signature { get { return 0x48414641; } } // 'AFAH' public override bool IsHierarchic { get { return true; } } public override bool CanWrite { get { return false; } } public AfaOpener () { ContainedFormats = new[] { "QNT", "AJP", "DCF", "OGG" }; Settings = new[] { AfaEncoding }; } internal readonly EncodingSetting AfaEncoding = new EncodingSetting ("AFAEncodingCP", "DefaultEncoding"); internal Encoding NameEncoding { get { return AfaEncoding.Get(); } } public override ArcFile TryOpen (ArcView file) { if (!file.View.AsciiEqual (8, "AlicArch")) return TryOpenV3 (file); if (!file.View.AsciiEqual (0x1C, "INFO")) return null; int version = file.View.ReadInt32 (0x10); long base_offset = file.View.ReadUInt32 (0x18); uint packed_size = file.View.ReadUInt32 (0x20); int unpacked_size = file.View.ReadInt32 (0x24); int count = file.View.ReadInt32 (0x28); if (!IsSaneCount (count)) return null; var default_enc = NameEncoding; var dir = new List (count); var name_buf = new byte[0x40]; using (var input = file.CreateStream (0x2C, packed_size)) using (var zstream = new ZLibStream (input, CompressionMode.Decompress)) using (var index = new BinaryReader (zstream)) { for (int i = 0; i < count; ++i) { int name_length = index.ReadInt32(); int index_step = index.ReadInt32(); if (name_length <= 0 || name_length > index_step || index_step > unpacked_size) return null; if (index_step > name_buf.Length) name_buf = new byte[index_step]; if (index_step != index.Read (name_buf, 0, index_step)) return null; var name = default_enc.GetString (name_buf, 0, name_length); var entry = FormatCatalog.Instance.Create (name); index.ReadInt32(); index.ReadInt32(); if (version < 2) index.ReadInt32(); entry.Offset = index.ReadUInt32() + base_offset; entry.Size = index.ReadUInt32(); if (!entry.CheckPlacement (file.MaxOffset)) return null; dir.Add (entry); } return new ArcFile (file, this, dir); } } internal ArcFile TryOpenV3 (ArcView file) { if (file.View.ReadInt32 (8) != 3) return null; uint index_size = file.View.ReadUInt32 (4); var index = new AfaIndexReader (file, index_size); var dir = index.Read(); if (null == dir || 0 == dir.Count) return null; return new ArcFile (file, this, dir); } static readonly byte[] AffKey = { 0xC8, 0xBB, 0x8F, 0xB7, 0xED, 0x43, 0x99, 0x4A, 0xA2, 0x7E, 0x5B, 0xB0, 0x68, 0x18, 0xF8, 0x88 }; public override Stream OpenEntry (ArcFile arc, Entry entry) { if (entry.Size <= 0x10 || !arc.File.View.AsciiEqual (entry.Offset, "AFF\0")) return base.OpenEntry (arc, entry); uint data_size = entry.Size - 0x10u; uint encrypted_length = Math.Min (0x40u, data_size); var prefix = arc.File.View.ReadBytes (entry.Offset+0x10, encrypted_length); for (int i = 0; i < prefix.Length; ++i) prefix[i] ^= AffKey[i & 0xF]; if (data_size <= 0x40) return new BinMemoryStream (prefix, entry.Name); var rest = arc.File.CreateStream (entry.Offset+0x10+encrypted_length, data_size-encrypted_length); return new PrefixStream (prefix, rest); } } internal sealed class AfaIndexReader { ArcView m_file; uint m_data_offset; byte[] m_dict; public AfaIndexReader (ArcView file, uint index_size) { m_file = file; m_data_offset = index_size + 8; } public List Read () { byte[] packed; using (var input = m_file.CreateStream (12, m_data_offset-12)) using (var bits = new MsbBitStream (input)) { bits.GetNextBit(); m_dict = ReadBytes (bits); if (null == m_dict) return null; int packed_size = ReadInt32 (bits); int unpacked_size = ReadInt32 (bits); packed = new byte[packed_size]; for (int i = 0; i < packed_size; ++i) { packed[i] = (byte)bits.GetBits (8); } } using (var bstr = new BinMemoryStream (packed)) using (var zstr = new ZLibStream (bstr, CompressionMode.Decompress)) using (var index = new MsbBitStream (zstr)) { index.GetNextBit(); int count = ReadInt32 (index); if (!ArchiveFormat.IsSaneCount (count)) return null; var dir = new List (count); for (int i = 0; i < count; ++i) { if (index.GetBits (2) == -1) break; var name_buf = ReadEncryptedChars (index); if (null == name_buf) return null; var name = DecryptString (name_buf, name_buf.Length); var entry = FormatCatalog.Instance.Create (name); ReadInt32 (index); ReadInt32 (index); entry.Offset = (uint)ReadInt32 (index) + m_data_offset; entry.Size = (uint)ReadInt32 (index); if (!entry.CheckPlacement (m_file.MaxOffset)) return null; dir.Add (entry); } return dir; } } byte[] ReadBytes (MsbBitStream input) { int buf_size = ReadInt32 (input); var buf = new byte[buf_size]; int dst = 0; var rnd = new RandomGenerator ((uint)buf_size); while (dst < buf_size) { int count = (int)rnd.GetNext() & 3; int skipped = input.GetBits (count + 1); if (-1 == skipped) return null; rnd.GetNext(); int v = input.GetBits (8); if (-1 == v) return null; buf[dst++] = (byte)v; } return buf; } ushort[] ReadEncryptedChars (MsbBitStream input) { int buf_size = ReadInt32 (input); var buf = new ushort[buf_size]; int dst = 0; var rnd = new RandomGenerator ((uint)buf_size); while (dst < buf_size) { int count = (int)rnd.GetNext() & 3; int skipped = input.GetBits (count + 1); if (-1 == skipped) return null; rnd.GetNext(); int lo = input.GetBits (8); int hi = input.GetBits (8); if (-1 == lo || -1 == hi) return null; buf[dst++] = (ushort)(lo | hi << 8); } return buf; } byte[] m_string_buf = new byte[0x100]; string DecryptString (ushort[] input, int input_length) { if (m_string_buf.Length < input_length) m_string_buf = new byte[input_length]; for (int i = 0; i < input_length; ++i) { m_string_buf[i] = (byte)(m_dict[input[i]] ^ 0xA4); } return Encodings.cp932.GetString (m_string_buf, 0, input_length); } static int ReadInt32 (MsbBitStream input) { int b0 = input.GetBits (8); int b1 = input.GetBits (8); int b2 = input.GetBits (8); int b3 = input.GetBits (8); return b3 << 24 | b2 << 16 | b1 << 8 | b0; } } internal class RandomGenerator { uint[] m_state = new uint[521]; int m_current; public RandomGenerator (uint seed) { Init (seed); } public void Init (uint seed) { uint val = 0; for (int i = 0; i < 17; ++i) { for (int j = 0; j < 32; ++j) { seed = 1566083941u * seed + 1; val = seed & 0x80000000 | (val >> 1); } m_state[i] = val; } m_state[16] = m_state[15] ^ (m_state[0] >> 9) ^ (m_state[16] << 23); for (int i = 17; i < 521; ++i) { m_state[i] = m_state[i-1] ^ (m_state[i-16] >> 9) ^ (m_state[i-17] << 23); } Shuffle(); Shuffle(); Shuffle(); Shuffle(); m_current = -1; } public uint GetNext () { ++m_current; if (m_current >= 521) { Shuffle(); m_current = 0; } return m_state[m_current]; } void Shuffle () { for (int i = 0; i < 32; i += 4) { m_state[i ] ^= m_state[i + 489]; m_state[i+1] ^= m_state[i + 490]; m_state[i+2] ^= m_state[i + 491]; m_state[i+3] ^= m_state[i + 492]; } for (int i = 32; i < 521; i += 3) { m_state[i ] ^= m_state[i - 32]; m_state[i+1] ^= m_state[i - 31]; m_state[i+2] ^= m_state[i - 30]; } } } }