There are three basic levels of use for pseudorandom numbers. Each level subsumes the one below it.

- Unexpected numbers with no particular correlation guarantees. Generators at this level typically have some hidden correlations that might matter to you, or might not.
- Statistically-independent number with known non-correlation. These are generally required for numerical simulations.
- Cryptographically secure numbers that cannot be guessed. These are always required when security is at issue.

Each of these is deterministic. A random number generator is an algorithm that has some internal state. Applying the algorithm once yields a new internal state and an output number. Seeding the generator means setting up an internal state; it's not always the case that the seed interface allows setting up every possible internal state. As a good rule of thumb, always assume that the default library random() routine operates at only the weakest level, level 1.

To answer your specific question, the algorithm in the question (1) cannot increase the randomness and (2) might decrease it. The expectation of randomness, thus, is strictly lower than seeding it once at the beginning. The reason comes from the possible existence of **short iterative cycles**. An iterative cycle for a function `F`

is a pair of integers `n`

and `k`

where `F^(n) (k) = k`

, where the exponent is the number of times `F`

is applied. For example, `F^(3) (x) = F(F(F(x)))`

. If there's a short iterative cycle, the random numbers will repeat more often than they would otherwise. In the code presented, the iteration function is to seed the generator and then take the first output.

To answer a question you didn't quite ask, but which is relevant to getting an understanding of this, seeding with a millisecond counter makes your generator fail the test of level 3, unguessability. That's because the number of possible milliseconds is **cryptographically small**, which is a number known to be subject to exhaustive search. As of this writing, 2^50 should be considered cryptographically small. (For what counts as cryptographically large in any year, please find a reputable expert.) Now the number of milliseconds in a century is approximately 2^(41.5), so don't rely on that form of seeding for security purposes.