One solution may involve Exclusive OR (XOR) binary bitmaps. The result function is **reversible**, **may generate non-sequential numbers** (if the first bit of the least significant byte is set to 1), and is extremely easy to implement. And, as long as you use a reliable sequence generator (your database, for example,) there is no need for thread safety concerns.

According to MSDN, 'the result [of a exclusive-OR operation] is true if and only if exactly one of its operands is true.' reverse logic says that equal operands will always result false.

As an example, I just generated a 32-bit sequence on Random.org. This is it:

```
11010101111000100101101100111101
```

This binary number translates to **3588381501** in decimal, **0xD5E25B3D** in hex. Let's call it your *base key*.

Now, lets generate some values using the *([base key] XOR [ID])* formula. In C#, that's what your encryption function would look like:

```
public static long FlipMask(long baseKey, long ID)
{
return baseKey ^ ID;
}
```

The following list contains some generated content. Its columns are as follows:

- ID
- Binary representation of ID
- Binary value after XOR operation
Final, 'encrypted' decimal value

```
0 | 000 | 11010101111000100101101100111101 | 3588381501
1 | 001 | 11010101111000100101101100111100 | 3588381500
2 | 010 | 11010101111000100101101100111111 | 3588381503
3 | 011 | 11010101111000100101101100111110 | 3588381502
4 | 100 | 11010101111000100101101100111001 | 3588381497
```

In order to reverse the generated key and determine the original value, you only need to do the same XOR operation using the same base key. Let's say we want to obtain the original value of the second row:

```
11010101111000100101101100111101 XOR
11010101111000100101101100111100 =
00000000000000000000000000000001
```

Which was indeed your original value.

Now, Stefan made very good points, and the first topic is crucial.

In order to cover his concerns, you may reserve the last, say, 8 bytes to be purely random garbage (which I believe is called a nonce), which you generate when encrypting the original ID and ignore when reversing it. That would heavily increase your security at the expense of a generous slice of all the possible positive integer numbers with 32 bits (16,777,216 instead of 4,294,967,296, or 1/256 of it.)

A class to do that would look like this:

```
public static class int32crypto
{
// C# follows ECMA 334v4, so Integer Literals have only two possible forms -
// decimal and hexadecimal.
// Original key: 0b11010101111000100101101100111101
public static long baseKey = 0xD5E25B3D;
public static long encrypt(long value)
{
// First we will extract from our baseKey the bits we'll actually use.
// We do this with an AND mask, indicating the bits to extract.
// Remember, we'll ignore the first 8. So the mask must look like this:
// Significance mask: 0b00000000111111111111111111111111
long _sigMask = 0x00FFFFFF;
// sigKey is our baseKey with only the indicated bits still true.
long _sigKey = _sigMask & baseKey;
// nonce generation. First security issue, since Random()
// is time-based on its first iteration. But that's OK for the sake
// of explanation, and safe for most circunstances.
// The bits it will occupy are the first eight, like this:
// OriginalNonce: 0b000000000000000000000000NNNNNNNN
long _tempNonce = new Random().Next(255);
// We now shift them to the last byte, like this:
// finalNonce: 0bNNNNNNNN000000000000000000000000
_tempNonce = _tempNonce << 0x18;
// And now we mix both Nonce and sigKey, 'poisoning' the original
// key, like this:
long _finalKey = _tempNonce | _sigKey;
// Phew! Now we apply the final key to the value, and return
// the encrypted value.
return _finalKey ^ value;
}
public static long decrypt(long value)
{
// This is easier than encrypting. We will just ignore the bits
// we know are used by our nonce.
long _sigMask = 0x00FFFFFF;
long _sigKey = _sigMask & baseKey;
// We will do the same to the informed value:
long _trueValue = _sigMask & value;
// Now we decode and return the value:
return _sigKey ^ _trueValue;
}
}
```

strictly numericandstrictly 32 bit integer! – Ehsan88 Aug 10 '13 at 7:20