Neil Fenwick is correct. However we can use the structure to our advantage.

**Version 4** (.Net)

*Version 4 UUIDs use a scheme relying only on random numbers. This algorithm sets the version number as well as two reserved bits. All other bits are set using a random or pseudorandom data source. Version 4 UUIDs have the form xxxxxxxx-xxxx-4xxx-yxxx-xxxxxxxxxxxx where x is any hexadecimal digit and y is one of 8, 9, A, or B. e.g. f47ac10b-58cc-4372-a567-0e02b2c3d479.*

**Use the Version Field**

We are free to change the first nibble of byte 8; so if you have less than 17 machines you can identify them by altering the GUIDs created on each one.

```
static Guid NewSystemGuid(int machine)
{
if (machine < 0 | machine > 0xF)
throw new ArgumentOutOfRangeException("machine");
var g = Guid.NewGuid();
var arr = g.ToByteArray();
arr[7] = (byte)((machine << 4) | (arr[7] & 0xF));
return new Guid(arr);
}
static int ExtractMachine(Guid guid)
{
var arr = guid.ToByteArray();
return (arr[7] >> 4) & 0xF;
}
```

**Use the Version Field and 'y'**

I am not sure if changing Y will alter the uniqueness of the GUID, so your mileage may vary. If you have less than 17 machines stick with the first solution.

```
static Guid NewSystemGuid(int machine)
{
if (machine < 0 | machine > 0xFF)
throw new ArgumentOutOfRangeException("machine");
var m1 = machine & 0xF;
var m2 = (machine >> 4) & 0xF;
var g = Guid.NewGuid();
var arr = g.ToByteArray();
arr[7] = (byte)((m1 << 4) | (arr[7] & 0xF));
arr[8] = (byte)((m2 << 4) | (arr[8] & 0xF));
return new Guid(arr);
}
static int ExtractMachine(Guid guid)
{
var arr = guid.ToByteArray();
return
((arr[7] >> 4) & 0xF) |
(((arr[8] >> 4) & 0xF) << 4);
}
```

**Use the Version and 'y' (Redux)**

You can still retain the value in 'y' by limiting the amount of machines to 63 (using the last 2 bits to represent the 4 possible values of 'y'):

```
static Guid NewSystemGuid(int machine)
{
if (machine < 0 | machine > 0x3F)
throw new ArgumentOutOfRangeException("machine");
var m1 = machine & 0xF;
var m2 = (machine >> 4) & 0xF;
var g = Guid.NewGuid();
var arr = g.ToByteArray();
arr[7] = (byte)((m1 << 4) | (arr[7] & 0xF));
var y = (arr[8] >> 4) & 0xF;
switch (y)
{
case 0x8:
arr[8] = (byte)((m2 << 4) | (arr[8] & 0xF));
break;
case 0x9:
arr[8] = (byte)(((m2 | 0x8) << 4) | (arr[8] & 0xF));
break;
case 0xA:
arr[8] = (byte)(((m2 | 0x4) << 4) | (arr[8] & 0xF));
break;
case 0xB:
arr[8] = (byte)(((m2 | 0xC) << 4) | (arr[8] & 0xF));
break;
default:
throw new Exception();
}
return new Guid(arr);
}
static int ExtractMachine(Guid guid)
{
var arr = guid.ToByteArray();
return
((arr[7] >> 4) & 0xF) |
(((arr[8] >> 4) & 0x3) << 4);
}
```

**Use Version 1 GUIDs**

You could also use version 1 GUIDs, as it's still possible to generate them:

```
class SequentialGuid
{
[DllImport("rpcrt4.dll", SetLastError = true)]
static extern int UuidCreateSequential(out Guid guid);
public static Guid NewGuid()
{
Guid guid;
UuidCreateSequential(out guid);
return guid;
}
public static byte[] ExtractMacAddress(Guid guid)
{
var arr = guid.ToByteArray();
// Require version 1.
if (((arr[7] >> 4) & 0xF) != 1)
throw new ArgumentOutOfRangeException("guid", "GUID is required to be a sequential (version 1) GUID.");
var macLong = BitConverter.ToInt64(arr, arr.Length - 8);
macLong = IPAddress.NetworkToHostOrder(macLong);
arr = BitConverter.GetBytes(macLong);
Array.Resize(ref arr, 6);
return arr;
}
}
```