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Aaru.Server/DiscImageChef.Partitions/MBR.cs

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// /***************************************************************************
// The Disc Image Chef
// ----------------------------------------------------------------------------
//
// Filename : MBR.cs
// Author(s) : Natalia Portillo <claunia@claunia.com>
//
// Component : Partitioning scheme plugins.
//
// --[ Description ] ----------------------------------------------------------
//
// Manages Intel/Microsoft MBR and UNIX slicing inside it.
//
// --[ 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 <http://www.gnu.org/licenses/>.
//
// ----------------------------------------------------------------------------
// Copyright © 2011-2017 Natalia Portillo
// ****************************************************************************/
using System;
using System.Collections.Generic;
// TODO: Support AAP, AST, SpeedStor and Ontrack extensions
namespace DiscImageChef.PartPlugins
{
class MBR : PartPlugin
{
const ushort MBRSignature = 0xAA55;
public MBR()
{
Name = "Master Boot Record";
PluginUUID = new Guid("5E8A34E8-4F1A-59E6-4BF7-7EA647063A76");
}
public override bool GetInformation(ImagePlugins.ImagePlugin imagePlugin, out List<CommonTypes.Partition> partitions)
{
byte cyl_sect1, cyl_sect2; // For decoding cylinder and sector
ushort signature;
ulong counter = 0;
partitions = new List<CommonTypes.Partition>();
if(imagePlugin.GetSectorSize() < 512)
return false;
byte[] sector = imagePlugin.ReadSector(0);
signature = BitConverter.ToUInt16(sector, 0x1FE);
if(signature != MBRSignature)
return false; // Not MBR
for(int i = 0; i < 4; i++)
{
MBRPartitionEntry entry = new MBRPartitionEntry();
entry.status = sector[0x1BE + 16 * i + 0x00];
entry.start_head = sector[0x1BE + 16 * i + 0x01];
cyl_sect1 = sector[0x1BE + 16 * i + 0x02];
cyl_sect2 = sector[0x1BE + 16 * i + 0x03];
entry.start_sector = (byte)(cyl_sect1 & 0x3F);
entry.start_cylinder = (ushort)(((cyl_sect1 & 0xC0) << 2) | cyl_sect2);
entry.type = sector[0x1BE + 16 * i + 0x04];
entry.end_head = sector[0x1BE + 16 * i + 0x05];
cyl_sect1 = sector[0x1BE + 16 * i + 0x06];
cyl_sect2 = sector[0x1BE + 16 * i + 0x07];
entry.end_sector = (byte)(cyl_sect1 & 0x3F);
entry.end_cylinder = (ushort)(((cyl_sect1 & 0xC0) << 2) | cyl_sect2);
entry.lba_start = BitConverter.ToUInt32(sector, 0x1BE + 16 * i + 0x08);
entry.lba_sectors = BitConverter.ToUInt32(sector, 0x1BE + 16 * i + 0x0C);
// Let's start the fun...
bool valid = true;
bool extended = false;
bool disklabel = false;
if(entry.status != 0x00 && entry.status != 0x80)
return false; // Maybe a FAT filesystem
valid &= entry.type != 0x00;
if(entry.type == 0xEE || entry.type == 0xEF)
return false; // This is a GPT
if(entry.type == 0x05 || entry.type == 0x0F || entry.type == 0x85)
{
valid = false;
extended = true; // Extended partition
}
if(entry.type == 0x82 || entry.type == 0xBF || entry.type == 0xA5 || entry.type == 0xA6 || entry.type == 0xA9 ||
entry.type == 0xB7 || entry.type == 0x81 || entry.type == 0x63)
{
valid = false;
disklabel = true;
}
valid &= entry.lba_start != 0 || entry.lba_sectors != 0 || entry.start_cylinder != 0 || entry.start_head != 0 || entry.start_sector != 0 || entry.end_cylinder != 0 || entry.end_head != 0 || entry.end_sector != 0;
if(entry.lba_start == 0 && entry.lba_sectors == 0 && valid)
{
entry.lba_start = CHStoLBA(entry.start_cylinder, entry.start_head, entry.start_sector);
entry.lba_sectors = CHStoLBA(entry.end_cylinder, entry.end_head, entry.end_sector) - entry.lba_start;
}
if(entry.lba_start > imagePlugin.GetSectors() || entry.lba_start + entry.lba_sectors > imagePlugin.GetSectors())
{
valid = false;
disklabel = false;
extended = false;
}
if(disklabel)
{
byte[] disklabel_sector = imagePlugin.ReadSector(entry.lba_start);
switch(entry.type)
{
case 0xA5:
case 0xA6:
case 0xA9:
case 0xB7: // BSD disklabels
{
BSD.DiskLabel bsdDisklabel = BSD.GetDiskLabel(disklabel_sector);
if(bsdDisklabel.d_magic == BSD.DISKMAGIC && bsdDisklabel.d_magic2 == BSD.DISKMAGIC)
{
// TODO: Handle disklabels bigger than 1 sector or search max no_parts
foreach(BSD.BSDPartition bsdPartition in bsdDisklabel.d_partitions)
{
CommonTypes.Partition part = new CommonTypes.Partition();
part.PartitionSectors = bsdPartition.p_size;
part.PartitionStartSector = bsdPartition.p_offset;
part.PartitionLength = bsdPartition.p_size * bsdDisklabel.d_secsize;
part.PartitionStart = bsdPartition.p_offset * bsdDisklabel.d_secsize;
part.PartitionType = string.Format("BSD: {0}", bsdPartition.p_fstype);
part.PartitionName = BSD.fsTypeToString(bsdPartition.p_fstype);
part.PartitionSequence = counter;
part.PartitionDescription = "Partition inside a BSD disklabel.";
if(bsdPartition.p_fstype != BSD.fsType.Unused)
{
partitions.Add(part);
counter++;
}
}
}
else
valid = true;
break;
}
case 0x63: // UNIX disklabel
{
uint magic;
byte[] unix_dl_sector = imagePlugin.ReadSector(entry.lba_start + 29); // UNIX disklabel starts on sector 29 of partition
magic = BitConverter.ToUInt32(unix_dl_sector, 4);
if(magic == UNIX.UNIXDiskLabel_MAGIC)
{
UNIX.UNIXDiskLabel dl = new UNIX.UNIXDiskLabel();
UNIX.UNIXVTOC vtoc = new UNIX.UNIXVTOC(); // old/new
bool isNewDL = false;
int vtocoffset = 0;
vtoc.magic = BitConverter.ToUInt32(unix_dl_sector, 172);
if(vtoc.magic == UNIX.UNIXVTOC_MAGIC)
{
isNewDL = true;
vtocoffset = 72;
}
else
{
vtoc.magic = BitConverter.ToUInt32(unix_dl_sector, 172);
if(vtoc.magic != UNIX.UNIXDiskLabel_MAGIC)
{
valid = true;
break;
}
}
dl.version = BitConverter.ToUInt32(unix_dl_sector, 8); // 8
byte[] dl_serial = new byte[12];
Array.Copy(unix_dl_sector, 12, dl_serial, 0, 12);
dl.serial = StringHandlers.CToString(dl_serial); // 12
dl.cyls = BitConverter.ToUInt32(unix_dl_sector, 24); // 24
dl.trks = BitConverter.ToUInt32(unix_dl_sector, 28); // 28
dl.secs = BitConverter.ToUInt32(unix_dl_sector, 32); // 32
dl.bps = BitConverter.ToUInt32(unix_dl_sector, 36); // 36
dl.start = BitConverter.ToUInt32(unix_dl_sector, 40); // 40
//dl.unknown1 = br.ReadBytes(48); // 44
dl.alt_tbl = BitConverter.ToUInt32(unix_dl_sector, 92); // 92
dl.alt_len = BitConverter.ToUInt32(unix_dl_sector, 96); // 96
if(isNewDL) // Old version VTOC starts here
{
dl.phys_cyl = BitConverter.ToUInt32(unix_dl_sector, 100); // 100
dl.phys_trk = BitConverter.ToUInt32(unix_dl_sector, 104); // 104
dl.phys_sec = BitConverter.ToUInt32(unix_dl_sector, 108); // 108
dl.phys_bytes = BitConverter.ToUInt32(unix_dl_sector, 112); // 112
dl.unknown2 = BitConverter.ToUInt32(unix_dl_sector, 116); // 116
dl.unknown3 = BitConverter.ToUInt32(unix_dl_sector, 120); // 120
//dl.pad = br.ReadBytes(48); // 124
}
if(vtoc.magic == UNIX.UNIXVTOC_MAGIC)
{
vtoc.version = BitConverter.ToUInt32(unix_dl_sector, 104 + vtocoffset); // 104/176
byte[] vtoc_name = new byte[8];
Array.Copy(unix_dl_sector, 108 + vtocoffset, vtoc_name, 0, 8);
vtoc.name = StringHandlers.CToString(vtoc_name); // 108/180
vtoc.slices = BitConverter.ToUInt16(unix_dl_sector, 116 + vtocoffset); // 116/188
vtoc.unknown = BitConverter.ToUInt16(unix_dl_sector, 118 + vtocoffset); // 118/190
//vtoc.reserved = br.ReadBytes(40); // 120/192
// TODO: What if number of slices overlaps sector (>23)?
for(int j = 0; j < vtoc.slices; j++)
{
UNIX.UNIXVTOCEntry vtoc_ent = new UNIX.UNIXVTOCEntry();
vtoc_ent.tag = (DiscImageChef.PartPlugins.UNIX.UNIX_TAG)BitConverter.ToUInt16(unix_dl_sector, 160 + vtocoffset + j * 12 + 0); // 160/232 + j*12
vtoc_ent.flags = BitConverter.ToUInt16(unix_dl_sector, 160 + vtocoffset + j * 12 + 2); // 162/234 + j*12
vtoc_ent.start = BitConverter.ToUInt32(unix_dl_sector, 160 + vtocoffset + j * 12 + 6); // 166/238 + j*12
vtoc_ent.length = BitConverter.ToUInt32(unix_dl_sector, 160 + vtocoffset + j * 12 + 10); // 170/242 + j*12
if((vtoc_ent.flags & 0x200) == 0x200 && vtoc_ent.tag != UNIX.UNIX_TAG.EMPTY && vtoc_ent.tag != UNIX.UNIX_TAG.WHOLE)
{
CommonTypes.Partition part = new CommonTypes.Partition();
// TODO: Check if device bps == disklabel bps
part.PartitionStartSector = vtoc_ent.start;
part.PartitionSectors = vtoc_ent.length;
part.PartitionStart = vtoc_ent.start * dl.bps;
part.PartitionLength = vtoc_ent.length * dl.bps;
part.PartitionSequence = counter;
part.PartitionType = string.Format("UNIX: {0}", UNIX.decodeUNIXTAG(vtoc_ent.tag, isNewDL));
string info = "";
if((vtoc_ent.flags & 0x01) == 0x01)
info += " (do not mount)";
if((vtoc_ent.flags & 0x10) == 0x10)
info += " (do not mount)";
part.PartitionDescription = "UNIX slice" + info + ".";
partitions.Add(part);
counter++;
}
}
}
}
else
valid = true;
break;
}
case 0x82:
case 0xBF: // Solaris disklabel
{
uint magic = BitConverter.ToUInt32(disklabel_sector, 12); // 12
uint version = BitConverter.ToUInt32(disklabel_sector, 16); // 16
if(magic == 0x600DDEEE && version == 1)
{
for(int j = 0; j < 16; j++)
{
CommonTypes.Partition part = new CommonTypes.Partition();
part.PartitionStartSector = BitConverter.ToUInt32(disklabel_sector, 68 + j * 12 + 4);
part.PartitionSectors = BitConverter.ToUInt32(disklabel_sector, 68 + j * 12 + 8);
part.PartitionStart = part.PartitionStartSector * imagePlugin.GetSectorSize(); // 68+4+j*12
part.PartitionLength = part.PartitionSectors * imagePlugin.GetSectorSize(); // 68+8+j*12
part.PartitionDescription = "Solaris slice.";
part.PartitionSequence = counter;
if(part.PartitionLength > 0)
{
partitions.Add(part);
counter++;
}
}
}
else
valid = true;
break;
}
case 0x81: // Minix subpartitions
{
bool minix_subs = false;
byte type;
for(int j = 0; j < 4; j++)
{
type = disklabel_sector[0x1BE + j * 16 + 4];
if(type == 0x81)
{
CommonTypes.Partition part = new CommonTypes.Partition();
minix_subs = true;
part.PartitionDescription = "Minix subpartition";
part.PartitionType = "Minix";
part.PartitionStartSector = BitConverter.ToUInt32(disklabel_sector, 0x1BE + j * 16 + 8);
part.PartitionSectors = BitConverter.ToUInt32(disklabel_sector, 0x1BE + j * 16 + 12);
part.PartitionStart = part.PartitionStartSector * imagePlugin.GetSectorSize();
part.PartitionLength = part.PartitionSectors * imagePlugin.GetSectorSize();
part.PartitionSequence = counter;
partitions.Add(part);
counter++;
}
}
valid |= !minix_subs;
break;
}
default:
valid = true;
break;
}
}
if(valid)
{
CommonTypes.Partition part = new CommonTypes.Partition();
if(entry.lba_start > 0 && entry.lba_sectors > 0)
{
part.PartitionStartSector = entry.lba_start;
part.PartitionSectors = entry.lba_sectors;
part.PartitionStart = part.PartitionStartSector * imagePlugin.GetSectorSize();
part.PartitionLength = part.PartitionSectors * imagePlugin.GetSectorSize();
}
/* else if(entry.start_head < 255 && entry.end_head < 255 &&
entry.start_sector > 0 && entry.start_sector < 64 &&
entry.end_sector > 0 && entry.end_sector < 64 &&
entry.start_cylinder < 1024 && entry.end_cylinder < 1024)
{
} */ // As we don't know the maxium cyl, head or sect of the device we need LBA
else
valid = false;
if(valid)
{
part.PartitionType = string.Format("0x{0:X2}", entry.type);
part.PartitionName = decodeMBRType(entry.type);
part.PartitionSequence = counter;
part.PartitionDescription = entry.status == 0x80 ? "Partition is bootable." : "";
counter++;
partitions.Add(part);
}
}
if(extended) // Let's extend the fun
{
bool ext_valid = true;
bool ext_disklabel = false;
bool processing_extended = true;
sector = imagePlugin.ReadSector(entry.lba_start);
while(processing_extended)
{
for(int l = 0; l < 2; l++)
{
bool ext_extended = false;
MBRPartitionEntry entry2 = new MBRPartitionEntry();
entry2.status = sector[0x1BE + 16 * i + 0x00];
entry2.start_head = sector[0x1BE + 16 * i + 0x01];
cyl_sect1 = sector[0x1BE + 16 * i + 0x02];
cyl_sect2 = sector[0x1BE + 16 * i + 0x03];
entry2.start_sector = (byte)(cyl_sect1 & 0x3F);
entry2.start_cylinder = (ushort)(((cyl_sect1 & 0xC0) << 2) | cyl_sect2);
entry2.type = sector[0x1BE + 16 * i + 0x04];
entry2.end_head = sector[0x1BE + 16 * i + 0x05];
cyl_sect1 = sector[0x1BE + 16 * i + 0x06];
cyl_sect2 = sector[0x1BE + 16 * i + 0x07];
entry2.end_sector = (byte)(cyl_sect1 & 0x3F);
entry2.end_cylinder = (ushort)(((cyl_sect1 & 0xC0) << 2) | cyl_sect2);
entry2.lba_start = BitConverter.ToUInt32(sector, 0x1BE + 16 * i + 0x08);
entry2.lba_sectors = BitConverter.ToUInt32(sector, 0x1BE + 16 * i + 0x0C);
// Let's start the fun...
ext_valid &= entry2.status == 0x00 || entry2.status == 0x80;
valid &= entry2.type != 0x00;
if(entry2.type == 0x82 || entry2.type == 0xBF || entry2.type == 0xA5 || entry2.type == 0xA6 ||
entry2.type == 0xA9 || entry2.type == 0xB7 || entry2.type == 0x81 || entry2.type == 0x63)
{
ext_valid = false;
ext_disklabel = true;
}
if(entry2.type == 0x05 || entry2.type == 0x0F || entry2.type == 0x85)
{
ext_valid = false;
ext_disklabel = false;
ext_extended = true; // Extended partition
}
else
processing_extended &= l != 1;
if(ext_disklabel)
{
byte[] disklabel_sector = imagePlugin.ReadSector(entry2.lba_start);
switch(entry2.type)
{
case 0xA5:
case 0xA6:
case 0xA9:
case 0xB7: // BSD disklabels
{
BSD.DiskLabel bsdDisklabel = BSD.GetDiskLabel(disklabel_sector);
if(bsdDisklabel.d_magic == BSD.DISKMAGIC && bsdDisklabel.d_magic2 == BSD.DISKMAGIC)
{
// TODO: Handle disklabels bigger than 1 sector or search max no_parts
foreach(BSD.BSDPartition bsdPartition in bsdDisklabel.d_partitions)
{
CommonTypes.Partition part = new CommonTypes.Partition();
part.PartitionSectors = bsdPartition.p_size;
part.PartitionStartSector = bsdPartition.p_offset;
part.PartitionLength = bsdPartition.p_size * bsdDisklabel.d_secsize;
part.PartitionStart = bsdPartition.p_offset * bsdDisklabel.d_secsize;
part.PartitionType = string.Format("BSD: {0}", bsdPartition.p_fstype);
part.PartitionName = BSD.fsTypeToString(bsdPartition.p_fstype);
part.PartitionSequence = counter;
part.PartitionDescription = "Partition inside a BSD disklabel.";
if(bsdPartition.p_fstype != BSD.fsType.Unused)
{
partitions.Add(part);
counter++;
}
}
}
else
ext_valid = true;
break;
}
case 0x63: // UNIX disklabel
{
uint magic;
byte[] unix_dl_sector = imagePlugin.ReadSector(entry.lba_start + 29); // UNIX disklabel starts on sector 29 of partition
magic = BitConverter.ToUInt32(unix_dl_sector, 4);
if(magic == UNIX.UNIXDiskLabel_MAGIC)
{
UNIX.UNIXDiskLabel dl = new UNIX.UNIXDiskLabel();
UNIX.UNIXVTOC vtoc = new UNIX.UNIXVTOC(); // old/new
bool isNewDL = false;
int vtocoffset = 0;
vtoc.magic = BitConverter.ToUInt32(unix_dl_sector, 172);
if(vtoc.magic == UNIX.UNIXVTOC_MAGIC)
{
isNewDL = true;
vtocoffset = 72;
}
else
{
vtoc.magic = BitConverter.ToUInt32(unix_dl_sector, 172);
if(vtoc.magic != UNIX.UNIXDiskLabel_MAGIC)
{
valid = true;
break;
}
}
dl.version = BitConverter.ToUInt32(unix_dl_sector, 8); // 8
byte[] dl_serial = new byte[12];
Array.Copy(unix_dl_sector, 12, dl_serial, 0, 12);
dl.serial = StringHandlers.CToString(dl_serial); // 12
dl.cyls = BitConverter.ToUInt32(unix_dl_sector, 24); // 24
dl.trks = BitConverter.ToUInt32(unix_dl_sector, 28); // 28
dl.secs = BitConverter.ToUInt32(unix_dl_sector, 32); // 32
dl.bps = BitConverter.ToUInt32(unix_dl_sector, 36); // 36
dl.start = BitConverter.ToUInt32(unix_dl_sector, 40); // 40
//dl.unknown1 = br.ReadBytes(48); // 44
dl.alt_tbl = BitConverter.ToUInt32(unix_dl_sector, 92); // 92
dl.alt_len = BitConverter.ToUInt32(unix_dl_sector, 96); // 96
if(isNewDL) // Old version VTOC starts here
{
dl.phys_cyl = BitConverter.ToUInt32(unix_dl_sector, 100); // 100
dl.phys_trk = BitConverter.ToUInt32(unix_dl_sector, 104); // 104
dl.phys_sec = BitConverter.ToUInt32(unix_dl_sector, 108); // 108
dl.phys_bytes = BitConverter.ToUInt32(unix_dl_sector, 112); // 112
dl.unknown2 = BitConverter.ToUInt32(unix_dl_sector, 116); // 116
dl.unknown3 = BitConverter.ToUInt32(unix_dl_sector, 120); // 120
//dl.pad = br.ReadBytes(48); // 124
}
if(vtoc.magic == UNIX.UNIXVTOC_MAGIC)
{
vtoc.version = BitConverter.ToUInt32(unix_dl_sector, 104 + vtocoffset); // 104/176
byte[] vtoc_name = new byte[8];
Array.Copy(unix_dl_sector, 108 + vtocoffset, vtoc_name, 0, 8);
vtoc.name = StringHandlers.CToString(vtoc_name); // 108/180
vtoc.slices = BitConverter.ToUInt16(unix_dl_sector, 116 + vtocoffset); // 116/188
vtoc.unknown = BitConverter.ToUInt16(unix_dl_sector, 118 + vtocoffset); // 118/190
//vtoc.reserved = br.ReadBytes(40); // 120/192
// TODO: What if number of slices overlaps sector (>23)?
for(int j = 0; j < vtoc.slices; j++)
{
UNIX.UNIXVTOCEntry vtoc_ent = new UNIX.UNIXVTOCEntry();
vtoc_ent.tag = (DiscImageChef.PartPlugins.UNIX.UNIX_TAG)BitConverter.ToUInt16(unix_dl_sector, 160 + vtocoffset + j * 12 + 0); // 160/232 + j*12
vtoc_ent.flags = BitConverter.ToUInt16(unix_dl_sector, 160 + vtocoffset + j * 12 + 2); // 162/234 + j*12
vtoc_ent.start = BitConverter.ToUInt32(unix_dl_sector, 160 + vtocoffset + j * 12 + 6); // 166/238 + j*12
vtoc_ent.length = BitConverter.ToUInt32(unix_dl_sector, 160 + vtocoffset + j * 12 + 10); // 170/242 + j*12
if((vtoc_ent.flags & 0x200) == 0x200 && vtoc_ent.tag != UNIX.UNIX_TAG.EMPTY && vtoc_ent.tag != UNIX.UNIX_TAG.WHOLE)
{
CommonTypes.Partition part = new CommonTypes.Partition();
// TODO: Check if device bps == disklabel bps
part.PartitionStartSector = vtoc_ent.start;
part.PartitionSectors = vtoc_ent.length;
part.PartitionStart = vtoc_ent.start * dl.bps;
part.PartitionLength = vtoc_ent.length * dl.bps;
part.PartitionSequence = counter;
part.PartitionType = string.Format("UNIX: {0}", UNIX.decodeUNIXTAG(vtoc_ent.tag, isNewDL));
string info = "";
if((vtoc_ent.flags & 0x01) == 0x01)
info += " (do not mount)";
if((vtoc_ent.flags & 0x10) == 0x10)
info += " (do not mount)";
part.PartitionDescription = "UNIX slice" + info + ".";
partitions.Add(part);
counter++;
}
}
}
}
else
ext_valid = true;
break;
}
case 0x82:
case 0xBF: // Solaris disklabel
{
uint magic = BitConverter.ToUInt32(disklabel_sector, 12); // 12
uint version = BitConverter.ToUInt32(disklabel_sector, 16); // 16
if(magic == 0x600DDEEE && version == 1)
{
for(int j = 0; j < 16; j++)
{
CommonTypes.Partition part = new CommonTypes.Partition();
part.PartitionStartSector = BitConverter.ToUInt32(disklabel_sector, 68 + j * 12 + 4);
part.PartitionSectors = BitConverter.ToUInt32(disklabel_sector, 68 + j * 12 + 8);
part.PartitionStart = part.PartitionStartSector * imagePlugin.GetSectorSize(); // 68+4+j*12
part.PartitionLength = part.PartitionSectors * imagePlugin.GetSectorSize(); // 68+8+j*12
part.PartitionDescription = "Solaris slice.";
part.PartitionSequence = counter;
if(part.PartitionLength > 0)
{
partitions.Add(part);
counter++;
}
}
}
else
ext_valid = true;
break;
}
case 0x81: // Minix subpartitions
{
bool minix_subs = false;
byte type;
for(int j = 0; j < 4; j++)
{
type = disklabel_sector[0x1BE + j * 16 + 4];
if(type == 0x81)
{
CommonTypes.Partition part = new CommonTypes.Partition();
minix_subs = true;
part.PartitionDescription = "Minix subpartition";
part.PartitionType = "Minix";
part.PartitionStartSector = BitConverter.ToUInt32(disklabel_sector, 0x1BE + j * 16 + 8);
part.PartitionSectors = BitConverter.ToUInt32(disklabel_sector, 0x1BE + j * 16 + 12);
part.PartitionStart = part.PartitionStartSector * imagePlugin.GetSectorSize();
part.PartitionLength = part.PartitionSectors * imagePlugin.GetSectorSize();
part.PartitionSequence = counter;
partitions.Add(part);
counter++;
}
}
ext_valid |= !minix_subs;
break;
}
default:
ext_valid = true;
break;
}
}
if(ext_valid)
{
CommonTypes.Partition part = new CommonTypes.Partition();
if(entry2.lba_start > 0 && entry2.lba_sectors > 0)
{
part.PartitionStartSector = entry2.lba_start;
part.PartitionSectors = entry2.lba_sectors;
part.PartitionStart = part.PartitionStartSector * imagePlugin.GetSectorSize();
part.PartitionLength = part.PartitionSectors * imagePlugin.GetSectorSize();
}
/* else if(entry2.start_head < 255 && entry2.end_head < 255 &&
entry2.start_sector > 0 && entry2.start_sector < 64 &&
entry2.end_sector > 0 && entry2.end_sector < 64 &&
entry2.start_cylinder < 1024 && entry2.end_cylinder < 1024)
{
} */ // As we don't know the maxium cyl, head or sect of the device we need LBA
else
ext_valid = false;
if(ext_valid)
{
part.PartitionType = string.Format("0x{0:X2}", entry2.type);
part.PartitionName = decodeMBRType(entry2.type);
part.PartitionSequence = counter;
part.PartitionDescription = entry2.status == 0x80 ? "Partition is bootable." : "";
counter++;
partitions.Add(part);
}
}
if(ext_extended)
{
break;
}
}
}
}
}
// An empty MBR may exist, NeXT creates one and then hardcodes its disklabel
return partitions.Count != 0;
}
static uint CHStoLBA(ushort cyl, byte head, byte sector)
{
#pragma warning disable IDE0004 // Remove Unnecessary Cast
return (((uint)cyl * 16) + (uint)head) * 63 + (uint)sector - 1;
#pragma warning restore IDE0004 // Remove Unnecessary Cast
}
static string decodeMBRType(byte type)
{
switch(type)
{
case 0x01:
return "FAT12";
case 0x02:
return "XENIX root";
case 0x03:
return "XENIX /usr";
case 0x04:
return "FAT16 < 32 MiB";
case 0x05:
return "Extended";
case 0x06:
return "FAT16";
case 0x07:
return "IFS (HPFS/NTFS)";
case 0x08:
return "AIX boot, OS/2, Commodore DOS";
case 0x09:
return "AIX data, Coherent, QNX";
case 0x0A:
return "Coherent swap, OPUS, OS/2 Boot Manager";
case 0x0B:
return "FAT32";
case 0x0C:
return "FAT32 (LBA)";
case 0x0E:
return "FAT16 (LBA)";
case 0x0F:
return "Extended (LBA)";
case 0x10:
return "OPUS";
case 0x11:
return "Hidden FAT12";
case 0x12:
return "Compaq diagnostics, recovery partition";
case 0x14:
return "Hidden FAT16 < 32 MiB, AST-DOS";
case 0x16:
return "Hidden FAT16";
case 0x17:
return "Hidden IFS (HPFS/NTFS)";
case 0x18:
return "AST-Windows swap";
case 0x19:
return "Willowtech Photon coS";
case 0x1B:
return "Hidden FAT32";
case 0x1C:
return "Hidden FAT32 (LBA)";
case 0x1E:
return "Hidden FAT16 (LBA)";
case 0x20:
return "Willowsoft Overture File System";
case 0x21:
return "Oxygen FSo2";
case 0x22:
return "Oxygen Extended ";
case 0x23:
return "SpeedStor reserved";
case 0x24:
return "NEC-DOS";
case 0x26:
return "SpeedStor reserved";
case 0x27:
return "Hidden NTFS";
case 0x31:
return "SpeedStor reserved";
case 0x33:
return "SpeedStor reserved";
case 0x34:
return "SpeedStor reserved";
case 0x36:
return "SpeedStor reserved";
case 0x38:
return "Theos";
case 0x39:
return "Plan 9";
case 0x3C:
return "Partition Magic";
case 0x3D:
return "Hidden NetWare";
case 0x40:
return "VENIX 80286";
case 0x41:
return "PReP Boot";
case 0x42:
return "Secure File System";
case 0x43:
return "PTS-DOS";
case 0x45:
return "Priam, EUMEL/Elan";
case 0x46:
return "EUMEL/Elan";
case 0x47:
return "EUMEL/Elan";
case 0x48:
return "EUMEL/Elan";
case 0x4A:
return "ALFS/THIN lightweight filesystem for DOS";
case 0x4D:
return "QNX 4";
case 0x4E:
return "QNX 4";
case 0x4F:
return "QNX 4, Oberon";
case 0x50:
return "Ontrack DM, R/O, FAT";
case 0x51:
return "Ontrack DM, R/W, FAT";
case 0x52:
return "CP/M, Microport UNIX";
case 0x53:
return "Ontrack DM 6";
case 0x54:
return "Ontrack DM 6";
case 0x55:
return "EZ-Drive";
case 0x56:
return "Golden Bow VFeature";
case 0x5C:
return "Priam EDISK";
case 0x61:
return "SpeedStor";
case 0x63:
return "GNU Hurd, System V, 386/ix";
case 0x64:
return "NetWare 286";
case 0x65:
return "NetWare";
case 0x66:
return "NetWare 386";
case 0x67:
return "NetWare";
case 0x68:
return "NetWare";
case 0x69:
return "NetWare NSS";
case 0x70:
return "DiskSecure Multi-Boot";
case 0x72:
return "UNIX 7th Edition";
case 0x75:
return "IBM PC/IX";
case 0x80:
return "Old MINIX";
case 0x81:
return "MINIX, Old Linux";
case 0x82:
return "Linux swap, Solaris";
case 0x83:
return "Linux";
case 0x84:
return "Hidden by OS/2, APM hibernation";
case 0x85:
return "Linux extended";
case 0x86:
return "NT Stripe Set";
case 0x87:
return "NT Stripe Set";
case 0x88:
return "Linux Plaintext";
case 0x8E:
return "Linux LVM";
case 0x93:
return "Amoeba, Hidden Linux";
case 0x94:
return "Amoeba bad blocks";
case 0x99:
return "Mylex EISA SCSI";
case 0x9F:
return "BSD/OS";
case 0xA0:
return "Hibernation";
case 0xA1:
return "HP Volume Expansion";
case 0xA3:
return "HP Volume Expansion";
case 0xA4:
return "HP Volume Expansion";
case 0xA5:
return "FreeBSD";
case 0xA6:
return "OpenBSD";
case 0xA7:
return "NeXTStep";
case 0xA8:
return "Apple UFS";
case 0xA9:
return "NetBSD";
case 0xAA:
return "Olivetti DOS FAT12";
case 0xAB:
return "Apple Boot";
case 0xAF:
return "Apple HFS";
case 0xB0:
return "BootStar";
case 0xB1:
return "HP Volume Expansion";
case 0xB3:
return "HP Volume Expansion";
case 0xB4:
return "HP Volume Expansion";
case 0xB6:
return "HP Volume Expansion";
case 0xB7:
return "BSDi";
case 0xB8:
return "BSDi swap";
case 0xBB:
return "PTS BootWizard";
case 0xBE:
return "Solaris boot";
case 0xBF:
return "Solaris";
case 0xC0:
return "Novell DOS, DR-DOS secured";
case 0xC1:
return "DR-DOS secured FAT12";
case 0xC2:
return "DR-DOS reserved";
case 0xC3:
return "DR-DOS reserved";
case 0xC4:
return "DR-DOS secured FAT16 < 32 MiB";
case 0xC6:
return "DR-DOS secured FAT16";
case 0xC7:
return "Syrinx";
case 0xC8:
return "DR-DOS reserved";
case 0xC9:
return "DR-DOS reserved";
case 0xCA:
return "DR-DOS reserved";
case 0xCB:
return "DR-DOS secured FAT32";
case 0xCC:
return "DR-DOS secured FAT32 (LBA)";
case 0xCD:
return "DR-DOS reserved";
case 0xCE:
return "DR-DOS secured FAT16 (LBA)";
case 0xCF:
return "DR-DOS secured extended (LBA)";
case 0xD0:
return "Multiuser DOS secured FAT12";
case 0xD1:
return "Multiuser DOS secured FAT12";
case 0xD4:
return "Multiuser DOS secured FAT16 < 32 MiB";
case 0xD5:
return "Multiuser DOS secured extended";
case 0xD6:
return "Multiuser DOS secured FAT16";
case 0xD8:
return "CP/M";
case 0xDA:
return "Filesystem-less data";
case 0xDB:
return "CP/M, CCP/M, CTOS";
case 0xDE:
return "Dell partition";
case 0xDF:
return "BootIt EMBRM";
case 0xE1:
return "SpeedStor";
case 0xE2:
return "DOS read/only";
case 0xE3:
return "SpeedStor";
case 0xE4:
return "SpeedStor";
case 0xE5:
return "Tandy DOS";
case 0xE6:
return "SpeedStor";
case 0xEB:
return "BeOS";
case 0xED:
return "Spryt*x";
case 0xEE:
return "Guid Partition Table";
case 0xEF:
return "EFI system partition";
case 0xF0:
return "Linux boot";
case 0xF1:
return "SpeedStor";
case 0xF2:
return "DOS 3.3 secondary, Unisys DOS";
case 0xF3:
return "SpeedStor";
case 0xF4:
return "SpeedStor";
case 0xF5:
return "Prologue";
case 0xF6:
return "SpeedStor";
case 0xFB:
return "VMWare VMFS";
case 0xFC:
return "VMWare VMKCORE";
case 0xFD:
return "Linux RAID, FreeDOS";
case 0xFE:
return "SpeedStor, LANStep, PS/2 IML";
case 0xFF:
return "Xenix bad block";
default:
return "Unknown";
}
}
public struct MBRPartitionEntry
{
public byte status;
// Partition status, 0x80 or 0x00, else invalid
public byte start_head;
// Starting head [0,254]
public byte start_sector;
// Starting sector [1,63]
public ushort start_cylinder;
// Starting cylinder [0,1023]
public byte type;
// Partition type
public byte end_head;
// Ending head [0,254]
public byte end_sector;
// Ending sector [1,63]
public ushort end_cylinder;
// Ending cylinder [0,1023]
public uint lba_start;
// Starting absolute sector
public uint lba_sectors;
// Total sectors
}
}
}
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