Insert bytes into middle of a file (in windows filesystem) without reading entire file (using File Allocation Table)?

[EDIT:]

Blah - I'm going to say "this ain't doable, at least not via MFT modification, without a LOT of pain"; first off, the NTFS MFT structures themselves are not 100% "open", so I'm starting to delve into reverse-engineering-territory, which has legal repercussions I'm in no mood to deal with. Also, doing this in .NET is a hyper-tedious process of mapping and marshalling structures based on a lot of guesswork (and don't get me started on the fact that most of the MFT structures are compressed in strange ways). Short story, while I did learn an awful lot about how NTFS "works", I'm no closer to a solution to this problem.

[/EDIT]

Ugh...sooo much Marshalling nonsense....

This struck me as "interesting", therefore I was compelled to poke around at the problem...it's still an "answer-in-progress", but wanted to post up what all I had to assist others in coming up with something. :)

Also, I have a rough sense that this would be FAR easier on FAT32, but given I've only got NTFS to work with...

So - lots of pinvoking and marshalling, so let's start there and work backwards:

As one might guess, the standard .NET File/IO apis aren't going to help you much here - we need device-level access:

[DllImport("kernel32.dll", SetLastError = true, CharSet = CharSet.Auto)]
static extern SafeFileHandle CreateFile(
    string lpFileName,
    [MarshalAs(UnmanagedType.U4)] FileAccess dwDesiredAccess,
    [MarshalAs(UnmanagedType.U4)] FileShare dwShareMode,
    IntPtr lpSecurityAttributes,
    [MarshalAs(UnmanagedType.U4)] FileMode dwCreationDisposition,
    [MarshalAs(UnmanagedType.U4)] FileAttributes dwFlagsAndAttributes,
    IntPtr hTemplateFile);

[DllImport("kernel32.dll", CharSet = CharSet.Auto, SetLastError = true)]
public static extern bool ReadFile(
    SafeFileHandle hFile,      // handle to file
    byte[] pBuffer,        // data buffer, should be fixed
    int NumberOfBytesToRead,  // number of bytes to read
    IntPtr pNumberOfBytesRead,  // number of bytes read, provide NULL here
    ref NativeOverlapped lpOverlapped // should be fixed, if not null
);

[DllImport("Kernel32.dll", SetLastError = true, CharSet = CharSet.Auto)]
public static extern bool SetFilePointerEx(
    SafeFileHandle hFile,
    long liDistanceToMove,
    out long lpNewFilePointer,
    SeekOrigin dwMoveMethod);

We'll use these nasty win32 beasts thusly:

// To the metal, baby!
using (var fileHandle = NativeMethods.CreateFile(
    // Magic "give me the device" syntax
    @"\\.\c:",
    // MUST explicitly provide both of these, not ReadWrite
    FileAccess.Read | FileAccess.Write,
    // MUST explicitly provide both of these, not ReadWrite
    FileShare.Write | FileShare.Read,
    IntPtr.Zero,
    FileMode.Open,
    FileAttributes.Normal,
    IntPtr.Zero))
{
    if (fileHandle.IsInvalid)
    {
        // Doh!
        throw new Win32Exception();
    }
    else
    {
        // Boot sector ~ 512 bytes long
        byte[] buffer = new byte[512];
        NativeOverlapped overlapped = new NativeOverlapped();
        NativeMethods.ReadFile(fileHandle, buffer, buffer.Length, IntPtr.Zero, ref overlapped);

        // Pin it so we can transmogrify it into a FAT structure
        var handle = GCHandle.Alloc(buffer, GCHandleType.Pinned);
        try
        {
            // note, I've got an NTFS drive, change yours to suit
            var bootSector = (BootSector_NTFS)Marshal.PtrToStructure(
                 handle.AddrOfPinnedObject(), 
                 typeof(BootSector_NTFS));

Whoa, whoa whoa - what the heck is a BootSector_NTFS? It's a byte-mapped struct that fits as close as I can reckon to what the NTFS structure looks like (FAT32 included as well):

[StructLayout(LayoutKind.Sequential, CharSet=CharSet.Ansi, Pack=0)]
public struct JumpBoot
{
    [MarshalAs(UnmanagedType.ByValArray, ArraySubType=UnmanagedType.U1, SizeConst=3)]
    public byte[] BS_jmpBoot;
    [MarshalAs(UnmanagedType.ByValTStr, SizeConst=8)]
    public string BS_OEMName;
}

[StructLayout(LayoutKind.Explicit, CharSet = CharSet.Ansi, Pack = 0, Size = 90)]
public struct BootSector_NTFS
{
    [FieldOffset(0)]
    public JumpBoot JumpBoot;
    [FieldOffset(0xb)]
    public short BytesPerSector;
    [FieldOffset(0xd)]
    public byte SectorsPerCluster;
    [FieldOffset(0xe)]
    public short ReservedSectorCount;
    [FieldOffset(0x10)]
    [MarshalAs(UnmanagedType.ByValArray, SizeConst = 5)]
    public byte[] Reserved0_MUSTBEZEROs;
    [FieldOffset(0x15)]
    public byte BPB_Media;
    [FieldOffset(0x16)]
    public short Reserved1_MUSTBEZERO;
    [FieldOffset(0x18)]
    public short SectorsPerTrack;
    [FieldOffset(0x1A)]
    public short HeadCount;
    [FieldOffset(0x1c)]
    public int HiddenSectorCount;
    [FieldOffset(0x20)]
    public int LargeSectors;
    [FieldOffset(0x24)]
    public int Reserved6;
    [FieldOffset(0x28)]
    public long TotalSectors;
    [FieldOffset(0x30)]
    public long MftClusterNumber;
    [FieldOffset(0x38)]
    public long MftMirrorClusterNumber;
    [FieldOffset(0x40)]
    public byte ClustersPerMftRecord;
    [FieldOffset(0x41)]
    public byte Reserved7;
    [FieldOffset(0x42)]
    public short Reserved8;
    [FieldOffset(0x44)]
    public byte ClustersPerIndexBuffer;
    [FieldOffset(0x45)]
    public byte Reserved9;
    [FieldOffset(0x46)]
    public short ReservedA;
    [FieldOffset(0x48)]
    [MarshalAs(UnmanagedType.ByValArray, SizeConst = 8)]
    public byte[] SerialNumber;
    [FieldOffset(0x50)]
    public int Checksum;
    [FieldOffset(0x54)]
    [MarshalAs(UnmanagedType.ByValArray, SizeConst = 0x1AA)]
    public byte[] BootupCode;
    [FieldOffset(0x1FE)]
    public ushort EndOfSectorMarker;

    public long GetMftAbsoluteIndex(int recordIndex = 0)
    {
        return (BytesPerSector * SectorsPerCluster * MftClusterNumber) + (GetMftEntrySize() * recordIndex);
    }
    public long GetMftEntrySize()
    {
        return (BytesPerSector * SectorsPerCluster * ClustersPerMftRecord);
    }
}


// Note: dont have fat32, so can't verify all these...they *should* work, tho
// refs:
//    http://www.pjrc.com/tech/8051/ide/fat32.html
//    http://msdn.microsoft.com/en-US/windows/hardware/gg463084
[StructLayout(LayoutKind.Explicit, CharSet=CharSet.Auto, Pack=0, Size=90)]
public struct BootSector_FAT32
{
    [FieldOffset(0)]
    public JumpBoot JumpBoot;    
    [FieldOffset(11)]
    public short BPB_BytsPerSec;
    [FieldOffset(13)]
    public byte BPB_SecPerClus;
    [FieldOffset(14)]
    public short BPB_RsvdSecCnt;
    [FieldOffset(16)]
    public byte BPB_NumFATs;
    [FieldOffset(17)]
    public short BPB_RootEntCnt;
    [FieldOffset(19)]
    public short BPB_TotSec16;
    [FieldOffset(21)]
    public byte BPB_Media;
    [FieldOffset(22)]
    public short BPB_FATSz16;
    [FieldOffset(24)]
    public short BPB_SecPerTrk;
    [FieldOffset(26)]
    public short BPB_NumHeads;
    [FieldOffset(28)]
    public int BPB_HiddSec;
    [FieldOffset(32)]
    public int BPB_TotSec32;
    [FieldOffset(36)]
    public FAT32 FAT;
}

[StructLayout(LayoutKind.Sequential)]
public struct FAT32
{
    public int BPB_FATSz32;
    public short BPB_ExtFlags;
    public short BPB_FSVer;
    public int BPB_RootClus;
    public short BPB_FSInfo;
    public short BPB_BkBootSec;
    [MarshalAs(UnmanagedType.ByValArray, SizeConst=12)]
    public byte[] BPB_Reserved;
    public byte BS_DrvNum;
    public byte BS_Reserved1;
    public byte BS_BootSig;
    public int BS_VolID;
    [MarshalAs(UnmanagedType.ByValTStr, SizeConst=11)] 
    public string BS_VolLab;
    [MarshalAs(UnmanagedType.ByValTStr, SizeConst=8)] 
    public string BS_FilSysType;
}

So now we can map a whole mess'o'bytes back to this structure:

// Pin it so we can transmogrify it into a FAT structure
var handle = GCHandle.Alloc(buffer, GCHandleType.Pinned);
    try
    {            
        // note, I've got an NTFS drive, change yours to suit
        var bootSector = (BootSector_NTFS)Marshal.PtrToStructure(
              handle.AddrOfPinnedObject(), 
              typeof(BootSector_NTFS));
        Console.WriteLine(
            "I think that the Master File Table is at absolute position:{0}, sector:{1}", 
            bootSector.GetMftAbsoluteIndex(),
            bootSector.GetMftAbsoluteIndex() / bootSector.BytesPerSector);

Which at this point outputs:

I think that the Master File Table is at 
absolute position:3221225472, sector:6291456

Let's confirm that quick using the OEM support tool nfi.exe:

C:\tools\OEMTools\nfi>nfi c:
NTFS File Sector Information Utility.
Copyright (C) Microsoft Corporation 1999. All rights reserved.


File 0
Master File Table ($Mft)
    $STANDARD_INFORMATION (resident)
    $FILE_NAME (resident)
    $DATA (nonresident)
        logical sectors 6291456-6487039 (0x600000-0x62fbff)
        logical sectors 366267960-369153591 (0x15d4ce38-0x1600d637)
    $BITMAP (nonresident)
        logical sectors 6291448-6291455 (0x5ffff8-0x5fffff)
        logical sectors 7273984-7274367 (0x6efe00-0x6eff7f)

Cool, looks like we're on the right track...onward!

            // If you've got LinqPad, uncomment this to look at boot sector
            bootSector.Dump();

    Console.WriteLine("Jumping to Master File Table...");
    long lpNewFilePointer;
    if (!NativeMethods.SetFilePointerEx(
            fileHandle, 
            bootSector.GetMftAbsoluteIndex(), 
            out lpNewFilePointer, 
            SeekOrigin.Begin))
    {
        throw new Win32Exception();
    }
    Console.WriteLine("Position now: {0}", lpNewFilePointer);

    // Read in one MFT entry
    byte[] mft_buffer = new byte[bootSector.GetMftEntrySize()];
    Console.WriteLine("Reading $MFT entry...calculated size: 0x{0}",
       bootSector.GetMftEntrySize().ToString("X"));

    var seekIndex = bootSector.GetMftAbsoluteIndex();
    overlapped.OffsetHigh = (int)(seekIndex >> 32);
    overlapped.OffsetLow = (int)seekIndex;
    NativeMethods.ReadFile(
          fileHandle, 
          mft_buffer, 
          mft_buffer.Length, 
          IntPtr.Zero, 
          ref overlapped);
    // Pin it for transmogrification
    var mft_handle = GCHandle.Alloc(mft_buffer, GCHandleType.Pinned);
    try
    {
        var mftRecords = (MFTSystemRecords)Marshal.PtrToStructure(
              mft_handle.AddrOfPinnedObject(), 
              typeof(MFTSystemRecords));
        mftRecords.Dump();
    }
    finally
    {
        // make sure we clean up
        mft_handle.Free();
    }
}
finally
{
    // make sure we clean up
    handle.Free();
}

Argh, more native structures to discuss - so the MFT is arranged such that the first 16 or so entries are "fixed":

[StructLayout(LayoutKind.Sequential)]
public struct MFTSystemRecords
{
    public MFTRecord Mft;
    public MFTRecord MftMirror;
    public MFTRecord LogFile;
    public MFTRecord Volume;
    public MFTRecord AttributeDefs;
    public MFTRecord RootFile;
    public MFTRecord ClusterBitmap;
    public MFTRecord BootSector;
    public MFTRecord BadClusterFile;
    public MFTRecord SecurityFile;
    public MFTRecord UpcaseTable;
    public MFTRecord ExtensionFile;
    [MarshalAs(UnmanagedType.ByValArray, SizeConst = 16)]
    public MFTRecord[] MftReserved;
    public MFTRecord MftFileExt;
}

Where MFTRecord is:

[StructLayout(LayoutKind.Sequential, Size = 1024)]
public struct MFTRecord
{
    const int BASE_RECORD_SIZE = 48;
    [MarshalAs(UnmanagedType.ByValTStr, SizeConst = 4)]
    public string Type;
    public short UsaOffset;
    public short UsaCount;
    public long Lsn;  /* $LogFile sequence number for this record. Changed every time the record is modified. */
    public short SequenceNumber; /* # of times this record has been reused */
    public short LinkCount;  /* Number of hard links, i.e. the number of directory entries referencing this record. */
    public short AttributeOffset; /* Byte offset to the first attribute in this mft record from the start of the mft record. */
    public short MftRecordFlags;
    public int BytesInUse;
    public int BytesAllocated;
    public long BaseFileRecord;
    public short NextAttributeNumber;
    public short Reserved;
    public int MftRecordNumber;
    [MarshalAs(UnmanagedType.ByValArray, SizeConst = 976)]
    public byte[] Data;
    public byte[] SetData
    {
        get
        {
            return this.Data
               .Skip(AttributeOffset - BASE_RECORD_SIZE)
               .Take(BytesInUse - BASE_RECORD_SIZE)
               .ToArray();
        }
    }
    public MftAttribute[] Attributes
    {
        get
        {
            var idx = 0;
            var ret = new List<MftAttribute>();
            while (idx < SetData.Length)
            {
                var attr = MftAttribute.FromBytes(SetData.Skip(idx).ToArray());
                ret.Add(attr);
                idx += attr.Attribute.Length;
                // A special "END" attribute denotes the end of the list
                if (attr.Attribute.AttributeType == MftAttributeType.AT_END) break;
            }
            return ret.ToArray();
        }
    }
}

And...here's where I peter out for now; mainly because I want to eat dinner and such. I will come back to this, however!

References (partially for my own memory, partially to assist other investigators)

  • http://ntfs.com/ntfs-mft.htm
  • http://technet.microsoft.com/en-us/library/cc781134%28WS.10%29.aspx
  • http://waynes-world-it.blogspot.com/2008/03/viewing-ntfs-information-with-nfi-and.html
  • http://en.wikipedia.org/wiki/NTFS
  • http://msdn.microsoft.com/en-us/library/aa365247(v=vs.85).aspx#win32_device_namespaces
  • http://www.pjrc.com/tech/8051/ide/fat32.html
  • http://msdn.microsoft.com/en-us/library/aa364572(VS.85).aspx

Full code dump a'following:

All the native mappings I glazed over above (due to post size limitations, not a full rehash):

public enum MftRecordFlags : ushort
{
    MFT_RECORD_IN_USE = 0x0001,
    MFT_RECORD_IS_DIRECTORY = 0x0002,
    MFT_RECORD_IN_EXTEND = 0x0004,
    MFT_RECORD_IS_VIEW_INDEX = 0x0008,
    MFT_REC_SPACE_FILLER = 0xffff
}
public enum MftAttributeType : uint
{
    AT_UNUSED = 0,
    AT_STANDARD_INFORMATION = 0x10,
    AT_ATTRIBUTE_LIST = 0x20,
    AT_FILENAME = 0x30,
    AT_OBJECT_ID = 0x40,
    AT_SECURITY_DESCRIPTOR = 0x50,
    AT_VOLUME_NAME = 0x60,
    AT_VOLUME_INFORMATION = 0x70,
    AT_DATA = 0x80,
    AT_INDEX_ROOT = 0x90,
    AT_INDEX_ALLOCATION = 0xa0,
    AT_BITMAP = 0xb0,
    AT_REPARSE_POINT = 0xc0,
    AT_EA_INFORMATION = 0xd0,
    AT_EA = 0xe0,
    AT_PROPERTY_SET = 0xf0,
    AT_LOGGED_UTILITY_STREAM = 0x100,
    AT_FIRST_USER_DEFINED_ATTRIBUTE = 0x1000,
    AT_END = 0xffffffff
}

public enum MftAttributeDefFlags : byte
{
    ATTR_DEF_INDEXABLE = 0x02, /* Attribute can be indexed. */
    ATTR_DEF_MULTIPLE = 0x04, /* Attribute type can be present multiple times in the mft records of an inode. */
    ATTR_DEF_NOT_ZERO = 0x08, /* Attribute value must contain at least one non-zero byte. */
    ATTR_DEF_INDEXED_UNIQUE = 0x10, /* Attribute must be indexed and the attribute value must be unique for the attribute type in all of the mft records of an inode. */
    ATTR_DEF_NAMED_UNIQUE = 0x20, /* Attribute must be named and the name must be unique for the attribute type in all of the mft records of an inode. */
    ATTR_DEF_RESIDENT = 0x40, /* Attribute must be resident. */
    ATTR_DEF_ALWAYS_LOG = 0x80, /* Always log modifications to this attribute, regardless of whether it is resident or
                non-resident.  Without this, only log modifications if the attribute is resident. */
}

[StructLayout(LayoutKind.Explicit)]
public struct MftInternalAttribute
{
    [FieldOffset(0)]
    public MftAttributeType AttributeType;
    [FieldOffset(4)]
    public int Length;
    [FieldOffset(8)]
    [MarshalAs(UnmanagedType.Bool)]
    public bool NonResident;
    [FieldOffset(9)]
    public byte NameLength;
    [FieldOffset(10)]
    public short NameOffset;
    [FieldOffset(12)]
    public int AttributeFlags;
    [FieldOffset(14)]
    public short Instance;
    [FieldOffset(16)]
    public ResidentAttribute ResidentAttribute;
    [FieldOffset(16)]
    public NonResidentAttribute NonResidentAttribute;
}

[StructLayout(LayoutKind.Sequential)]
public struct ResidentAttribute
{
    public int ValueLength;
    public short ValueOffset;
    public byte ResidentAttributeFlags;
    public byte Reserved;

    public override string ToString()
    {
        return string.Format("{0}:{1}:{2}:{3}", ValueLength, ValueOffset, ResidentAttributeFlags, Reserved);
    }
}
[StructLayout(LayoutKind.Sequential)]
public struct NonResidentAttribute
{
    public long LowestVcn;
    public long HighestVcn;
    public short MappingPairsOffset;
    public byte CompressionUnit;
    [MarshalAs(UnmanagedType.ByValArray, SizeConst = 5)]
    public byte[] Reserved;
    public long AllocatedSize;
    public long DataSize;
    public long InitializedSize;
    public long CompressedSize;
    public override string ToString()
    {
        return string.Format("{0}:{1}:{2}:{3}:{4}:{5}:{6}:{7}", LowestVcn, HighestVcn, MappingPairsOffset, CompressionUnit, AllocatedSize, DataSize, InitializedSize, CompressedSize);
    }
}

public struct MftAttribute
{
    public MftInternalAttribute Attribute;

    [field: NonSerialized]
    public string Name;

    [field: NonSerialized]
    public byte[] Data;

    [field: NonSerialized]
    public object Payload;

    public static MftAttribute FromBytes(byte[] buffer)
    {
        var hnd = GCHandle.Alloc(buffer, GCHandleType.Pinned);
        try
        {
            var attr = (MftInternalAttribute)Marshal.PtrToStructure(hnd.AddrOfPinnedObject(), typeof(MftInternalAttribute));
            var ret = new MftAttribute() { Attribute = attr };
            ret.Data = buffer.Skip(Marshal.SizeOf(attr)).Take(attr.Length).ToArray();
            if (ret.Attribute.AttributeType == MftAttributeType.AT_STANDARD_INFORMATION)
            {
                var payloadHnd = GCHandle.Alloc(ret.Data, GCHandleType.Pinned);
                try
                {
                    var payload = (MftStandardInformation)Marshal.PtrToStructure(payloadHnd.AddrOfPinnedObject(), typeof(MftStandardInformation));
                    ret.Payload = payload;
                }
                finally
                {
                    payloadHnd.Free();
                }
            }
            return ret;
        }
        finally
        {
            hnd.Free();
        }
    }
}

[StructLayout(LayoutKind.Sequential)]
public struct MftStandardInformation
{
    public ulong CreationTime;
    public ulong LastDataChangeTime;
    public ulong LastMftChangeTime;
    public ulong LastAccessTime;
    public int FileAttributes;
    public int MaximumVersions;
    public int VersionNumber;
    public int ClassId;
    public int OwnerId;
    public int SecurityId;
    public long QuotaChanged;
    public long Usn;
}

// Note: dont have fat32, so can't verify all these...they *should* work, tho
// refs:
//    http://www.pjrc.com/tech/8051/ide/fat32.html
//    http://msdn.microsoft.com/en-US/windows/hardware/gg463084
[StructLayout(LayoutKind.Explicit, CharSet = CharSet.Auto, Pack = 0, Size = 90)]
public struct BootSector_FAT32
{
    [FieldOffset(0)]
    public JumpBoot JumpBoot;
    [FieldOffset(11)]
    public short BPB_BytsPerSec;
    [FieldOffset(13)]
    public byte BPB_SecPerClus;
    [FieldOffset(14)]
    public short BPB_RsvdSecCnt;
    [FieldOffset(16)]
    public byte BPB_NumFATs;
    [FieldOffset(17)]
    public short BPB_RootEntCnt;
    [FieldOffset(19)]
    public short BPB_TotSec16;
    [FieldOffset(21)]
    public byte BPB_Media;
    [FieldOffset(22)]
    public short BPB_FATSz16;
    [FieldOffset(24)]
    public short BPB_SecPerTrk;
    [FieldOffset(26)]
    public short BPB_NumHeads;
    [FieldOffset(28)]
    public int BPB_HiddSec;
    [FieldOffset(32)]
    public int BPB_TotSec32;
    [FieldOffset(36)]
    public FAT32 FAT;
}

[StructLayout(LayoutKind.Sequential)]
public struct FAT32
{
    public int BPB_FATSz32;
    public short BPB_ExtFlags;
    public short BPB_FSVer;
    public int BPB_RootClus;
    public short BPB_FSInfo;
    public short BPB_BkBootSec;
    [MarshalAs(UnmanagedType.ByValArray, SizeConst = 12)]
    public byte[] BPB_Reserved;
    public byte BS_DrvNum;
    public byte BS_Reserved1;
    public byte BS_BootSig;
    public int BS_VolID;
    [MarshalAs(UnmanagedType.ByValTStr, SizeConst = 11)]
    public string BS_VolLab;
    [MarshalAs(UnmanagedType.ByValTStr, SizeConst = 8)]
    public string BS_FilSysType;
}

And the test harness:

class Program
{        
    static void Main(string[] args)
    {
        // To the metal, baby!
        using (var fileHandle = NativeMethods.CreateFile(
            // Magic "give me the device" syntax
            @"\\.\c:",
            // MUST explicitly provide both of these, not ReadWrite
            FileAccess.Read | FileAccess.Write,
            // MUST explicitly provide both of these, not ReadWrite
            FileShare.Write | FileShare.Read,
            IntPtr.Zero,
            FileMode.Open,
            FileAttributes.Normal,
            IntPtr.Zero))
        {
            if (fileHandle.IsInvalid)
            {
                // Doh!
                throw new Win32Exception();
            }
            else
            {
                // Boot sector ~ 512 bytes long
                byte[] buffer = new byte[512];
                NativeOverlapped overlapped = new NativeOverlapped();
                NativeMethods.ReadFile(fileHandle, buffer, buffer.Length, IntPtr.Zero, ref overlapped);

                // Pin it so we can transmogrify it into a FAT structure
                var handle = GCHandle.Alloc(buffer, GCHandleType.Pinned);
                try
                {
                    // note, I've got an NTFS drive, change yours to suit
                    var bootSector = (BootSector_NTFS)Marshal.PtrToStructure(handle.AddrOfPinnedObject(), typeof(BootSector_NTFS));
                    Console.WriteLine(
                        "I think that the Master File Table is at absolute position:{0}, sector:{1}",
                        bootSector.GetMftAbsoluteIndex(),
                        bootSector.GetMftAbsoluteIndex() / bootSector.BytesPerSector);
                    Console.WriteLine("MFT record size:{0}", bootSector.ClustersPerMftRecord * bootSector.SectorsPerCluster * bootSector.BytesPerSector);

                    // If you've got LinqPad, uncomment this to look at boot sector
                    bootSector.DumpToHtmlString();

                    Pause();

                    Console.WriteLine("Jumping to Master File Table...");
                    long lpNewFilePointer;
                    if (!NativeMethods.SetFilePointerEx(fileHandle, bootSector.GetMftAbsoluteIndex(), out lpNewFilePointer, SeekOrigin.Begin))
                    {
                        throw new Win32Exception();
                    }
                    Console.WriteLine("Position now: {0}", lpNewFilePointer);

                    // Read in one MFT entry
                    byte[] mft_buffer = new byte[bootSector.GetMftEntrySize()];
                    Console.WriteLine("Reading $MFT entry...calculated size: 0x{0}", bootSector.GetMftEntrySize().ToString("X"));

                    var seekIndex = bootSector.GetMftAbsoluteIndex();
                    overlapped.OffsetHigh = (int)(seekIndex >> 32);
                    overlapped.OffsetLow = (int)seekIndex;
                    NativeMethods.ReadFile(fileHandle, mft_buffer, mft_buffer.Length, IntPtr.Zero, ref overlapped);
                    // Pin it for transmogrification
                    var mft_handle = GCHandle.Alloc(mft_buffer, GCHandleType.Pinned);
                    try
                    {
                        var mftRecords = (MFTSystemRecords)Marshal.PtrToStructure(mft_handle.AddrOfPinnedObject(), typeof(MFTSystemRecords));
                        mftRecords.DumpToHtmlString();
                    }
                    finally
                    {
                        // make sure we clean up
                        mft_handle.Free();
                    }
                }
                finally
                {
                    // make sure we clean up
                    handle.Free();
                }
            }
        }
        Pause();
    }

    private static void Pause()
    {
        Console.WriteLine("Press enter to continue...");
        Console.ReadLine();
    }
}


public static class Dumper
{
    public static string DumpToHtmlString<T>(this T objectToSerialize)
    {
        string strHTML = "";
        try
        {
            var writer = LINQPad.Util.CreateXhtmlWriter(true);
            writer.Write(objectToSerialize);
            strHTML = writer.ToString();
        }
        catch (Exception exc)
        {
            Debug.Assert(false, "Investigate why ?" + exc);
        }

        var shower = new Thread(
            () =>
                {
                    var dumpWin = new Window();
                    var browser = new WebBrowser();
                    dumpWin.Content = browser;
                    browser.NavigateToString(strHTML);
                    dumpWin.ShowDialog();                        
                });
        shower.SetApartmentState(ApartmentState.STA);
        shower.Start();
        return strHTML;
    }

    public static string Dump(this object value)
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}

Robert, I don't think that what you want to achieve is really possible to do without actively manipulating file system data structures for a file system which, from the sounds of it, is mounted. I don't think I have to tell you how dangerous and unwise this sort of exercise it.

But if you need to do it, I guess I can give you a "sketch on the back of a napkin" to get you started:

You could leverage the "sparse file" support of NTFS to simply add "gaps" by tweaking the LCN/VCN mappings. Once you do, just open the file, seek to the new location and write your data. NTFS will transparently allocate the space and write the data in the middle of the file, where you created a hole.

For more, look at this page about defragmentation support in NTFS for hints on how you can manipulate things a bit and allow you to insert clusters in the middle of the file. At least by using the sanctioned API for this sort of thing, you are unlikely to corrupt the filesystem beyond repair, although you can still horribly hose your file, I guess.

Get the retrieval pointers for the file that you want, split them where you need, to add as much extra space as you need, and move the file. There's an interesting chapter on this sort of thing in the Russinovich/Ionescu "Windows Internals" book (http://www.amazon.com/Windows%C2%AE-Internals-Including-Windows-Developer/dp/0735625301)


Abstract question, abstract answer:

It is certainly possible to do this in FAT and probably in most other FS, you would essentially be fragmenting the file, rather than the more common process of defragmenting.

FAT is organized with around cluster pointers which produce a chain of cluster numbers where data is stored, the first link index is stored with the file record, the second one is stored in the allocation table at index [the first link's number] etc. It's possible to insert another link anywhere in the chain, for as long as the data you're inserting ends at the boundary of a cluster.

Chances are you'll have much easier time doing this in C by finding an open source library. While it's probably possible to do that in C# with PInvoke you won't find any good sample code floating around for you to get started.

I suspect you don't have any control over the file format (video files?), if you do it would be much easier to design your data storage to avoid the problem in the first place.