// /*************************************************************************** // The Disc Image Chef // ---------------------------------------------------------------------------- // // Filename : MinixFS.cs // Author(s) : Natalia Portillo // // Component : MINIX filesystem plugin. // // --[ Description ] ---------------------------------------------------------- // // Identifies the MINIX filesystem and shows information. // // --[ License ] -------------------------------------------------------------- // // This library is free software; you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as // published by the Free Software Foundation; either version 2.1 of the // License, or (at your option) any later version. // // This library is distributed in the hope that it will be useful, but // WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU // Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public // License along with this library; if not, see . // // ---------------------------------------------------------------------------- // Copyright © 2011-2016 Natalia Portillo // ****************************************************************************/ using System; using System.Text; using System.Collections.Generic; namespace DiscImageChef.Filesystems { // Information from the Linux kernel class MinixFS : Filesystem { const ushort MINIX_MAGIC = 0x137F; // Minix v1, 14 char filenames const ushort MINIX_MAGIC2 = 0x138F; // Minix v1, 30 char filenames const ushort MINIX2_MAGIC = 0x2468; // Minix v2, 14 char filenames const ushort MINIX2_MAGIC2 = 0x2478; // Minix v2, 30 char filenames const ushort MINIX3_MAGIC = 0x4D5A; // Minix v3, 60 char filenames // Byteswapped const ushort MINIX_CIGAM = 0x7F13; // Minix v1, 14 char filenames const ushort MINIX_CIGAM2 = 0x8F13; // Minix v1, 30 char filenames const ushort MINIX2_CIGAM = 0x6824; // Minix v2, 14 char filenames const ushort MINIX2_CIGAM2 = 0x7824; // Minix v2, 30 char filenames const ushort MINIX3_CIGAM = 0x5A4D; // Minix v3, 60 char filenames public MinixFS() { Name = "Minix Filesystem"; PluginUUID = new Guid("FE248C3B-B727-4AE5-A39F-79EA9A07D4B3"); } public MinixFS(ImagePlugins.ImagePlugin imagePlugin, ulong partitionStart, ulong partitionEnd) { Name = "Minix Filesystem"; PluginUUID = new Guid("FE248C3B-B727-4AE5-A39F-79EA9A07D4B3"); } public override bool Identify(ImagePlugins.ImagePlugin imagePlugin, ulong partitionStart, ulong partitionEnd) { if((2 + partitionStart) >= imagePlugin.GetSectors()) return false; ushort magic; byte[] minix_sb_sector = imagePlugin.ReadSector(2 + partitionStart); magic = BitConverter.ToUInt16(minix_sb_sector, 0x010); // Here should reside magic number on Minix V1 & V2 if(magic == MINIX_MAGIC || magic == MINIX_MAGIC2 || magic == MINIX2_MAGIC || magic == MINIX2_MAGIC2 || magic == MINIX_CIGAM || magic == MINIX_CIGAM2 || magic == MINIX2_CIGAM || magic == MINIX2_CIGAM2) return true; magic = BitConverter.ToUInt16(minix_sb_sector, 0x018); // Here should reside magic number on Minix V3 if(magic == MINIX3_MAGIC || magic == MINIX3_CIGAM) return true; return false; } public override void GetInformation(ImagePlugins.ImagePlugin imagePlugin, ulong partitionStart, ulong partitionEnd, out string information) { information = ""; StringBuilder sb = new StringBuilder(); bool minix3 = false; int filenamesize; string minixVersion; ushort magic; byte[] minix_sb_sector = imagePlugin.ReadSector(2 + partitionStart); magic = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x018); xmlFSType = new Schemas.FileSystemType(); if(magic == MINIX3_MAGIC || magic == MINIX3_CIGAM) { filenamesize = 60; minixVersion = "Minix V3 filesystem"; BigEndianBitConverter.IsLittleEndian = magic != MINIX3_CIGAM; xmlFSType.Type = "Minix V3"; minix3 = true; } else { magic = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x010); switch(magic) { case MINIX_MAGIC: filenamesize = 14; minixVersion = "Minix V1 filesystem"; BigEndianBitConverter.IsLittleEndian = true; xmlFSType.Type = "Minix V1"; break; case MINIX_MAGIC2: filenamesize = 30; minixVersion = "Minix V1 filesystem"; BigEndianBitConverter.IsLittleEndian = true; xmlFSType.Type = "Minix V1"; break; case MINIX2_MAGIC: filenamesize = 14; minixVersion = "Minix V2 filesystem"; BigEndianBitConverter.IsLittleEndian = true; xmlFSType.Type = "Minix V2"; break; case MINIX2_MAGIC2: filenamesize = 30; minixVersion = "Minix V2 filesystem"; BigEndianBitConverter.IsLittleEndian = true; xmlFSType.Type = "Minix V2"; break; case MINIX_CIGAM: filenamesize = 14; minixVersion = "Minix V1 filesystem"; BigEndianBitConverter.IsLittleEndian = false; xmlFSType.Type = "Minix V1"; break; case MINIX_CIGAM2: filenamesize = 30; minixVersion = "Minix V1 filesystem"; BigEndianBitConverter.IsLittleEndian = false; xmlFSType.Type = "Minix V1"; break; case MINIX2_CIGAM: filenamesize = 14; minixVersion = "Minix V2 filesystem"; BigEndianBitConverter.IsLittleEndian = false; xmlFSType.Type = "Minix V2"; break; case MINIX2_CIGAM2: filenamesize = 30; minixVersion = "Minix V2 filesystem"; BigEndianBitConverter.IsLittleEndian = false; xmlFSType.Type = "Minix V2"; break; default: return; } } if(minix3) { Minix3SuperBlock mnx_sb = new Minix3SuperBlock(); mnx_sb.s_ninodes = BigEndianBitConverter.ToUInt32(minix_sb_sector, 0x00); mnx_sb.s_pad0 = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x04); mnx_sb.s_imap_blocks = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x06); mnx_sb.s_zmap_blocks = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x08); mnx_sb.s_firstdatazone = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x0A); mnx_sb.s_log_zone_size = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x0C); mnx_sb.s_pad1 = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x0E); mnx_sb.s_max_size = BigEndianBitConverter.ToUInt32(minix_sb_sector, 0x10); mnx_sb.s_zones = BigEndianBitConverter.ToUInt32(minix_sb_sector, 0x14); mnx_sb.s_magic = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x18); mnx_sb.s_pad2 = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x1A); mnx_sb.s_blocksize = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x1C); mnx_sb.s_disk_version = minix_sb_sector[0x1E]; sb.AppendLine(minixVersion); sb.AppendFormat("{0} chars in filename", filenamesize).AppendLine(); sb.AppendFormat("{0} zones on volume ({1} bytes)", mnx_sb.s_zones, mnx_sb.s_zones * mnx_sb.s_blocksize).AppendLine(); sb.AppendFormat("{0} bytes/block", mnx_sb.s_blocksize).AppendLine(); sb.AppendFormat("{0} inodes on volume", mnx_sb.s_ninodes).AppendLine(); sb.AppendFormat("{0} blocks on inode map ({1} bytes)", mnx_sb.s_imap_blocks, mnx_sb.s_imap_blocks * mnx_sb.s_blocksize).AppendLine(); sb.AppendFormat("{0} blocks on zone map ({1} bytes)", mnx_sb.s_zmap_blocks, mnx_sb.s_zmap_blocks * mnx_sb.s_blocksize).AppendLine(); sb.AppendFormat("First data zone: {0}", mnx_sb.s_firstdatazone).AppendLine(); //sb.AppendFormat("log2 of blocks/zone: {0}", mnx_sb.s_log_zone_size).AppendLine(); // Apparently 0 sb.AppendFormat("{0} bytes maximum per file", mnx_sb.s_max_size).AppendLine(); sb.AppendFormat("On-disk filesystem version: {0}", mnx_sb.s_disk_version).AppendLine(); xmlFSType.ClusterSize = mnx_sb.s_blocksize; xmlFSType.Clusters = (long)((partitionEnd - partitionStart + 1) * imagePlugin.GetSectorSize() / mnx_sb.s_blocksize); } else { MinixSuperBlock mnx_sb = new MinixSuperBlock(); mnx_sb.s_ninodes = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x00); mnx_sb.s_nzones = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x02); mnx_sb.s_imap_blocks = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x04); mnx_sb.s_zmap_blocks = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x06); mnx_sb.s_firstdatazone = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x08); mnx_sb.s_log_zone_size = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x0A); mnx_sb.s_max_size = BigEndianBitConverter.ToUInt32(minix_sb_sector, 0x0C); mnx_sb.s_magic = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x10); mnx_sb.s_state = BigEndianBitConverter.ToUInt16(minix_sb_sector, 0x12); mnx_sb.s_zones = BigEndianBitConverter.ToUInt32(minix_sb_sector, 0x14); sb.AppendLine(minixVersion); sb.AppendFormat("{0} chars in filename", filenamesize).AppendLine(); if(mnx_sb.s_zones > 0) // On V2 sb.AppendFormat("{0} zones on volume ({1} bytes)", mnx_sb.s_zones, mnx_sb.s_zones * 1024).AppendLine(); else sb.AppendFormat("{0} zones on volume ({1} bytes)", mnx_sb.s_nzones, mnx_sb.s_nzones * 1024).AppendLine(); sb.AppendFormat("{0} inodes on volume", mnx_sb.s_ninodes).AppendLine(); sb.AppendFormat("{0} blocks on inode map ({1} bytes)", mnx_sb.s_imap_blocks, mnx_sb.s_imap_blocks * 1024).AppendLine(); sb.AppendFormat("{0} blocks on zone map ({1} bytes)", mnx_sb.s_zmap_blocks, mnx_sb.s_zmap_blocks * 1024).AppendLine(); sb.AppendFormat("First data zone: {0}", mnx_sb.s_firstdatazone).AppendLine(); //sb.AppendFormat("log2 of blocks/zone: {0}", mnx_sb.s_log_zone_size).AppendLine(); // Apparently 0 sb.AppendFormat("{0} bytes maximum per file", mnx_sb.s_max_size).AppendLine(); sb.AppendFormat("Filesystem state: {0:X4}", mnx_sb.s_state).AppendLine(); xmlFSType.ClusterSize = 1024; xmlFSType.Clusters = (long)((partitionEnd - partitionStart + 1) * imagePlugin.GetSectorSize() / 1024); } information = sb.ToString(); } /// /// Superblock for Minix V1 and V2 filesystems /// public struct MinixSuperBlock { /// 0x00, inodes on volume public ushort s_ninodes; /// 0x02, zones on volume public ushort s_nzones; /// 0x04, blocks on inode map public ushort s_imap_blocks; /// 0x06, blocks on zone map public ushort s_zmap_blocks; /// 0x08, first data zone public ushort s_firstdatazone; /// 0x0A, log2 of blocks/zone public ushort s_log_zone_size; /// 0x0C, max file size public uint s_max_size; /// 0x10, magic public ushort s_magic; /// 0x12, filesystem state public ushort s_state; /// 0x14, number of zones public uint s_zones; } /// /// Superblock for Minix V3 filesystems /// public struct Minix3SuperBlock { /// 0x00, inodes on volume public uint s_ninodes; /// 0x04, padding public ushort s_pad0; /// 0x06, blocks on inode map public ushort s_imap_blocks; /// 0x08, blocks on zone map public ushort s_zmap_blocks; /// 0x0A, first data zone public ushort s_firstdatazone; /// 0x0C, log2 of blocks/zone public ushort s_log_zone_size; /// 0x0E, padding public ushort s_pad1; /// 0x10, max file size public uint s_max_size; /// 0x14, number of zones public uint s_zones; /// 0x18, magic public ushort s_magic; /// 0x1A, padding public ushort s_pad2; /// 0x1C, bytes in a block public ushort s_blocksize; /// 0x1E, on-disk structures version public byte s_disk_version; } public override Errno Mount() { return Errno.NotImplemented; } public override Errno Mount(bool debug) { return Errno.NotImplemented; } public override Errno Unmount() { return Errno.NotImplemented; } public override Errno MapBlock(string path, long fileBlock, ref long deviceBlock) { return Errno.NotImplemented; } public override Errno GetAttributes(string path, ref FileAttributes attributes) { return Errno.NotImplemented; } public override Errno ListXAttr(string path, ref List xattrs) { return Errno.NotImplemented; } public override Errno GetXattr(string path, string xattr, ref byte[] buf) { return Errno.NotImplemented; } public override Errno Read(string path, long offset, long size, ref byte[] buf) { return Errno.NotImplemented; } public override Errno ReadDir(string path, ref List contents) { return Errno.NotImplemented; } public override Errno StatFs(ref FileSystemInfo stat) { return Errno.NotImplemented; } public override Errno Stat(string path, ref FileEntryInfo stat) { return Errno.NotImplemented; } public override Errno ReadLink(string path, ref string dest) { return Errno.NotImplemented; } } }