//! \file ArcFPK.cs //! \date Fri Sep 16 04:23:31 2016 //! \brief MoonhirGames resources archive. // // 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.Diagnostics; using System.IO; using System.Linq; using GameRes.Utility; namespace GameRes.Formats.MoonhirGames { internal class FpkEntry : Entry { public bool IsEncrypted; } internal class FpkArchive : ArcFile { public readonly uint Key; public FpkArchive (ArcView arc, ArchiveFormat impl, ICollection dir, uint key) : base (arc, impl, dir) { Key = key; } } [Serializable] public class Fpk0100Scheme : ResourceScheme { public uint[] KnownKeys; } [Export(typeof(ArchiveFormat))] public class FpkOpener : ArchiveFormat { public override string Tag { get { return "FPK/MOONHIR"; } } public override string Description { get { return "MoonhirGames engine resource archive"; } } public override uint Signature { get { return 0x4B5046; } } // 'FPK' public override bool IsHierarchic { get { return false; } } public override bool CanWrite { get { return false; } } public static uint[] KnownKeys = { 0 }; public override ResourceScheme Scheme { get { return new Fpk0100Scheme { KnownKeys = KnownKeys }; } set { KnownKeys = ((Fpk0100Scheme)value).KnownKeys; } } public override ArcFile TryOpen (ArcView file) { if (!file.View.AsciiEqual (4, "0100")) return null; int count = file.View.ReadInt32 (0xC); if (!IsSaneCount (count)) return null; uint index_offset = file.View.ReadUInt32 (8); var dir = new List (count); bool has_encrypted = false; for (int i = 0; i < count; ++i) { var name = file.View.ReadString (index_offset+12, 12); var entry = FormatCatalog.Instance.Create (name); entry.IsEncrypted = 0 != file.View.ReadUInt32 (index_offset); entry.Offset = file.View.ReadUInt32 (index_offset+4); entry.Size = file.View.ReadUInt32 (index_offset+8); if (!entry.CheckPlacement (file.MaxOffset)) return null; if (name.EndsWith (".fbx", StringComparison.InvariantCultureIgnoreCase)) entry.Type = "image"; has_encrypted = has_encrypted || entry.IsEncrypted; dir.Add (entry); index_offset += 0x18; } if (!has_encrypted) return new ArcFile (file, this, dir); var enc_entry = dir.Cast().FirstOrDefault (e => e.IsEncrypted && e.Size > 8); if (null == enc_entry) return new ArcFile (file, this, dir); var key = FindKey (file, enc_entry); if (null == key) { Trace.WriteLine (string.Format ("{0}: unknown encryption key", file.Name), "[FPK]"); return new ArcFile (file, this, dir); } return new FpkArchive (file, this, dir, key.Value); } public override Stream OpenEntry (ArcFile arc, Entry entry) { var farc = arc as FpkArchive; var fent = entry as FpkEntry; Stream input; byte[] header; if (null == farc || null == fent || !fent.IsEncrypted) { if (fent.IsEncrypted) throw new UnknownEncryptionScheme(); input = arc.File.CreateStream (entry.Offset, entry.Size); header = new byte[0x10]; input.Read (header, 0, 0x10); input.Position = 0; } else { var data = arc.File.View.ReadBytes (entry.Offset, entry.Size); Decrypt (data, 0, data.Length, farc.Key); int length = LittleEndian.ToInt32 (data, data.Length-8); input = new BinMemoryStream (data, 0, length, entry.Name); header = data; } if (!Binary.AsciiEqual (header, "FBX\x01")) return input; using (input) { int packed_size = LittleEndian.ToInt32 (header, 8); int unpacked_size = LittleEndian.ToInt32 (header, 0xC); input.Position = header[7]; var unpacked = UnpackFbx (input, packed_size, unpacked_size); return new BinMemoryStream (unpacked, entry.Name); } } uint? FindKey (ArcView file, Entry entry) { if (entry.Size < 8) return null; var offset = entry.Offset + entry.Size - 8; uint t1 = file.View.ReadUInt32 (offset+4); uint t0 = file.View.ReadUInt32 (offset); // l = (a - x - m + 7) ^ ((x - ((b - x - m + 4) ^ x)) >> 7) ^ ((x * 2 + m - 4) << 7); foreach (uint key in KnownKeys) { uint k1 = key + entry.Size - 4; uint k2 = ((key - ((t1 - k1) ^ key)) >> 7) ^ ((k1 + key) << 7); uint test_length = ((((t0 - (k1 - 3)) ^ k2) + 3) & ~3u) + 8; if (entry.Size == test_length) return key; } return null; } unsafe void Decrypt (byte[] data, int index, int length, uint key) { if (length < 8) return; fixed (byte* data8 = &data[index]) { uint* data32 = (uint*)data8; uint* dptr = data32 + length / 4 - 1; uint k1 = key + (uint)length - 4; uint k2 = key; while (dptr >= data32) { *dptr = (*dptr - k1) ^ k2; k2 = ((k2 - *dptr) >> 7) ^ ((k1 + k2) << 7); k1 -= 3; --dptr; } } } byte[] UnpackFbx (Stream input, int packed_size, int unpacked_size) { var output = new byte[unpacked_size]; int dst = 0; int ctl = 1; while (dst < output.Length) { if (1 == ctl) { ctl = input.ReadByte(); if (-1 == ctl) break; ctl |= 0x100; } int count, offset; switch (ctl & 3) { case 0: output[dst++] = (byte)input.ReadByte(); break; case 1: count = input.ReadByte(); if (-1 == count) return output; count = Math.Min (count + 2, output.Length - dst); input.Read (output, dst, count); dst += count; break; case 2: offset = input.ReadByte() << 8; offset |= input.ReadByte(); if (-1 == offset) return output; count = Math.Min ((offset & 0x1F) + 4, output.Length - dst); offset >>= 5; Binary.CopyOverlapped (output, dst - offset - 1, dst, count); dst += count; break; case 3: int exctl = input.ReadByte(); if (-1 == exctl) return output; count = exctl & 0x3F; switch (exctl >> 6) { case 0: count = count << 8 | input.ReadByte(); if (-1 == count) return output; count = Math.Min (count + 0x102, output.Length - dst); input.Read (output, dst, count); dst += count; break; case 1: offset = input.ReadByte() << 8; offset |= input.ReadByte(); count = count << 5 | offset & 0x1F; count = Math.Min (count + 0x24, output.Length - dst); offset >>= 5; Binary.CopyOverlapped (output, dst - offset - 1, dst, count); dst += count; break; case 3: input.Seek (count, SeekOrigin.Current); ctl = 1 << 2; break; default: break; } break; } ctl >>= 2; } return output; } } }