A proper PRNG (Pseudo-Random Number Generator) algorithm will have a cycle time during which it will never be in the same state. If you expose the entire state of the PRNG in the number retrieved from it, you will get a number guaranteed unique for the period of the generator.

A simple PRNG that does this is called the 'Linear Congruential' PRNG which iterates a formula:

```
X(i) = AX(i-1)|M
```

Using the right pair of factors you can get a period of 2^30 (approximately 1 billion) from a simple PRNG with a 32 bit accumulator. Note that you will need a 64 bit long long temporary variable to hold the intermediate 'AX' part of the computation. Most if not all C compilers will support this data type. You should also be able to do it with a numeric data type on most SQL dialects.

With the right values of A and M we can get a random number generator with good statistical and geometrical properties. There is a famous paper about this written by Fishman and Moore.

For M = 2^31 - 1 we get can use the values of A below to get a PRNG with a nice long period (2^30 IIRC).

Good Values of A:

```
742,938,285
950,706,376
1,226,874,159
62,089,911
1,343,714,438
```

Note that this type of generator is (by definition) not cryptographically secure. If you know the last number generated from it you can predict what it will do next. Unfortunately I believe that you cannot get cryptographic security and guaranteed non-repeatability at the same time. For a PRNG to be cryptographically secure (e.g. Blum Blum Shub) it cannot expose sufficient state in a generated number to allow the next number in the sequence to be predicted. Therefore the internal state is wider than the generated number and (in order to have good security) the period will be longer than the number of possible values that can be generated. This means that the exposed number will not be unique within the period.

For similar reasons the same is true of long-period generators such as the Mersenne Twister.