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I'm trying to implement a tolerable-quality version of the rand_r interface, which has the unfortunate interface requirement that its entire state is stored in a single object of type unsigned, which for my purposes means exactly 32 bits. In addition, I need its output range to be [0,2³¹-1]. The standard solution is using a LCG and dropping the low bit (which has the shortest period), but this still leaves very poor periods for the next few bits.

My initial thought was to use two or three iterations of the LCG to generate the high/low or high/mid/low bits of the output. However, such an approach does not preserve the non-biased distribution; rather than each output value having equal frequency, many occur multiple times, and some never occur at all.

Since there are only 32 bits of state, the period of the PRNG is bounded by 2³², and in order to be non-biased, the PRNG must output each value exactly twice if it has full period or exactly once if it has period 2³¹. Shorter periods cannot be non-biased.

Is there any good known PRNG algorithm that meets these criteria?

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guaranteed output seems to be the opposite of random, no? –  xaxxon Jun 11 '13 at 2:00
    
Pseudo-random is not random. And the opposite of "guaranteed output" is, unfortunately, "biased". For insanely large periods like 2^100 having a perfect output distribution is not really necessary as long as it's empirically indistinguishable from uniform, but for a small period like 2^32, non-uniformity will be a clear observable bias. –  R.. Jun 11 '13 at 2:53
    
Yes you can predict the next value of a PRNG with period 2^32 if you have roughly 0.5 GB of data on the previous values it returned. That's to be expected, and it would be the case even if the distribution weren't uniform. If there are exactly 2^32 states and 2^32 outputs and you've seen 2^32-1 of them, the last one is always determined. –  R.. Jun 11 '13 at 2:59
    
I deleted my comment. I didn't quite understand what you were saying, but I think I got it now. –  xaxxon Jun 11 '13 at 2:59
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How about using LCG, and then applying a safe 1:1 transform (I've suggested some here) to improve the distribution? This is similar, in principle, to running a cryptographic algorithm in counter mode. –  sh1 Jun 11 '13 at 18:42

3 Answers 3

One good (but probably not the fastest) possibility, offering very high quality, would be to use a 32-bit block cipher in CTR mode. Basically, your RNG state would simply be a 32-bit counter that gets incremented by one for each RNG call, and the output would be the encryption of that counter value using the block cipher with some arbitrarily chosen fixed key. For extra randomness, you could even provide a (non-standard) function to let the user set a custom key.

There aren't a lot of 32-bit block ciphers in common use, since such a short block size introduces problems for cryptographic use. (Basically, the birthday paradox lets you distinguish the output of such a cipher from a random function with a non-negligible probability after only about 216 = 65536 outputs, and after 232 outputs the non-randomness obviously becomes certain.) However, some ciphers with an adjustable block size, such as XXTEA or HPC, will let you go down to 32 bits, and should be suitable for your purposes.

(Edit: My bad, XXTEA only goes down to 64 bits. However, as suggested by CodesInChaos in the comments, Skip32 might be another option. Or you could build your own 32-bit Feistel cipher.)

The CTR mode construction guarantees that the RNG will have a full period of 232 outputs, while the standard security claim of (non-broken) block ciphers is essentially that it is not computationally feasible to distinguish their output from a random permutation of the set of 32-bit integers. (Of course, as noted above, such a permutation is still easily distinguished from a random function taking 32-bit values.)

Using CTR mode also provides some extra features you may find convenient (even if they're not part of the official API you're developing against), such as the ability to quickly seek into any point in the RNG output stream just by adding or subtracting from the state.

On the other hand, you probably don't want to follow the common practice of seeding the RNG by just setting the internal state to the seed value, since that would cause the output streams generated from nearby seeds to be highly similar (basically just the same stream shifted by the difference of the seeds). One way to avoid this issue would be to add an extra encryption step to the seeding process, i.e. to encrypt the seed with the cipher and set the internal counter value equal to the result.

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The problem with this approach is ensuring full period. Obviously it could be tested empirically given about a day of computing time, but I see no obvious reason to believe that applying a cryptographic cipher fewer than 2³² times won't give back the original value. –  R.. Jun 11 '13 at 3:36
    
The CTR mode construction explicitly guarantees full period: the output stream will only repeat when the counter wraps around. –  Ilmari Karonen Jun 11 '13 at 3:38
    
Oh, I see. Unfortunately the API doesn't have a seeding process; the seed and the state are the same. It's a really, really bad API, and that's why I'm so constrained. With that said, I think it might work to encrypt the input seed/state, use the obtained value as the result, increment that value by 1, then 'decrypt' it and store the result back to the seed/state. –  R.. Jun 11 '13 at 3:50
    
You could also replace the counter in CTR mode with a "generalized counter", i.e. any full-period sequence of 32-bit values (such as a full period LCRNG). That way, you'd essentially be using the block cipher to strengthen a simpler full period RNG by encrypting its output. The underlying simple LCRNG should still be random enough to avoid problems with sequential seed values. –  Ilmari Karonen Jun 11 '13 at 13:41
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according to wikipedia XXTEA has a minimum block size of 64 bits. You might want to consider Skip32 instead. –  CodesInChaos Jun 11 '13 at 17:42

Elaborating on my comment...

A block cipher in counter mode gives a generator in approximately the following form (except using much bigger data types):

uint32_t state = 0;
uint32_t rand()
{
    state = next(state);
    return temper(state);
}

Since cryptographic security hasn't been specified (and in 32 bits it would be more or less futile), a simpler, ad-hoc tempering function should do the trick.

One approach is where the next() function is simple (eg., return state + 1;) and temper() compensates by being complex (as in the block cipher).

A more balanced approach is to implement LCG in next(), since we know that it also visits all possible states but in a random(ish) order, and to find an implementation of temper() which does just enough work to cover the remaining problems with LCG.

Mersenne Twister includes such a tempering function on its output. That might be suitable. Also, this question asks for operations which fulfill the requirement.

I have a favourite, which is to bit-reverse the word, and then multiply it by some constant (odd) number. That may be overly complex if bit-reverse isn't a native operation on your architecture.

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I haven't tried bit-reversal, but byte-swap seems promising so far. LFSR looks more promising as the 'next' function than LCG, since LCG has really bad period in its low bits, whereas LFSR has full period in all bits. –  R.. Jun 12 '13 at 0:46
    
@R.., The idea is that temper() would spread things around so the bad-period bits are dispersed. LCG just has the simple advantage of being full-period without any extra complexity. But, in fact, if you did use multiplication in the tempering, it probably is for the best if you use a fundamentally different algorithm for next(). So maybe I agree with you. –  sh1 Jun 12 '13 at 0:51
    
I just tried a naive LCG with the temper function copied from mersenne twister, and the diehard results are statistically indistinguishable from /dev/urandom. :-) –  R.. Jun 12 '13 at 1:20
    
@R.., Then test harder! –  sh1 Jun 12 '13 at 1:35
    
@R.., did you try the harder tests? I don't expect they'll show up anything new, but it almost seems too easy; as if diehard has overlooked something. –  sh1 Jun 27 '13 at 12:25

A 32-bit maximal-period Galois LFSR might work for you. Try:

r = (r >> 1) ^ (-(r & 1) & 0x80200003);

The one problem with LFSRs is that you can't produce the value 0. So this one has a range of 1 to 2^32-1. You may want to tweak the output or else stick with a good LCG.

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Perhaps if (r==0xdeadbeef) r=0; else if (r==0) r=0xdeadbeef; r = (r >> 1) ^ (-(r & 1) & 0x80200003); –  R.. Jun 11 '13 at 3:14
    
Better not to futz with the state variable itself. Just use r-1 as your output value. That makes your range and period 0 to 2^32-2. –  Lee Daniel Crocker Jun 11 '13 at 3:17
    
Yeah but I can't change the range. It's fixed. Thus I need to insert the 0 at some arbitrary point in the sequence. –  R.. Jun 11 '13 at 3:24
    
I had a bit of a think about this approach with respect to Multiply With Carry (not an appropriate solution here) recently, as I wanted to join the two independent large orbits by switching tracks in between. I decided an ideal idiom was if ((x ^ 0xdeadbeef) == 0 || x == 0) x = x ^ 0xdeadbeef;, as this results in very compact code (compiled code, I mean) with only one conditional block. –  sh1 Jun 12 '13 at 0:56
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It's zero if we make it zero. The trick is to hop in and out of the zero state once every 2^31-1 iterations. That way zero is added to the set of outputs, extending it to 2^32 exactly, and making it perfectly unbiased. 0xdeadbeef is just an arbitrary value, after which 0 is inserted into the stream (it doesn't matter if we run the generator, as zero goes to zero). Next time we see that the state was zero so we hop back into the stream the same place as we hopped out last time and carry on as if nothing happened. My suggested change is just meant to be computationally more efficient. –  sh1 Jun 12 '13 at 1:32

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