# Simple random number generator that can generate nth number in series in O(1) time

I do not intend to use this for security purposes or statistical analysis. I need to create a simple random number generator for use in my computer graphics application. I don't want to use the term "random number generator", since people think in very strict terms about it, but I can't think of any other word to describe it.

• it has to be fast.
• it must be repeatable, given a particular seed. Eg: If seed = x, then the series a,b,c,d,e,f..... should happen every time I use the seed x.

Most importantly, I need to be able to compute the nth term in the series in constant time.

It seems, that I cannot achieve this with rand_r or srand(), since these need are state dependent, and I may need to compute the nth in some unknown order.

I've looked at Linear Feedback Shift registers, but these are state dependent too.

So far I have this:

int rand = (n * prime1 + seed) % prime2

n = used to indicate the index of the term in the sequence. Eg: For first term, n ==1

prime1 and prime2 are prime numbers where prime1 > prime2

seed = some number which allows one to use the same function to produce a different series depending on the seed, but the same series for a given seed.

I can't tell how good or bad this is, since I haven't used it enough, but it would be great if people with more experience in this can point out the problems with this, or help me improve it..

EDIT - I don't care if it is predictable. I'm just trying to creating some randomness in my computer graphics.

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Calc numbers previously, and cache them, once get nth number just take O(1). –  Tim Feb 22 at 5:01
I may not be able to cache them, as there could be millions of numbers, and I need to make at least 400,000 calculations per second on a mobile device. Also, the process of cacheing and lookup could take longer than the actual calculation itself... –  John Feb 22 at 5:03
Your current algorithm doesn't look random at all. Did you try to make a plot? I've tried to plot using P1=569, P2=359, seed=12345, and the pattern is really visible. Just giving you a heads up. –  Paweł Stawarz Feb 22 at 5:09
I've been using 279470273UL and 4294967291UL , and I haven't had any repeats for at least 10000 calculations... How are you plotting ? –  John Feb 22 at 5:12
Using Excel. With your numbers the pattern is even more visible. Do an XY-plot in Excel/OpenOffice Calc and you'll see it. The X axis is N, and on the Y axis there's the value. –  Paweł Stawarz Feb 22 at 5:14

Use a cryptographic block cipher in CTR mode. The Nth output is just encrypt(N). Not only does this give you the desired properties (O(1) computation of the Nth output); it also has strong non-predictability properties.

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would it be as fast, or faster than my equation above ? I don't care if it is predictable or not. This is for the purpose of creating some "randomness" in computer graphics. –  John Feb 22 at 4:54
If you weaken the cryptographic block cipher to an extent that it's no longer usable for cryptographic purposes, it might be comparable. This might involve dropping all but one or two rounds of a Feistel cipher. In any case I think your proposed algorithm has serious flaws for use in any real-world setting (e.g. if generating images from it, there will be cases where you visually see the pattern). –  R.. Feb 22 at 4:58
BTW note that you can also compute the N+1'th output from the N'th output, but only if you know the encryption key: `next = encrypt(decrypt(prev)+1)`. –  R.. Feb 22 at 5:00
this sounds really complicated. I don't know anything about block ciphers. But when testing my code above, there were no repeats for at least 10000 calls (I didn't test more), and the problem I had was integer overflow... –  John Feb 22 at 5:02
The question isn't about repeats but a visible pattern. For example if you draw a dot at column `out(N) % img_width` in row `N` for each row, and `img_width` has certain numerical relation to `prime2`, you're going to start seeing an obvious pattern... –  R.. Feb 22 at 5:06

RNG in a normal sense, have the sequence pattern like f(n) = S(f(n-1))

They also lost precision at some point (like % mod), due to computing convenience, therefore it is not possible to expand the sequence to a function like X(n) = f(n) = trivial function with n only.

This mean at best you have O(n) with that.

To target for O(1) you therefore need to abandon the idea of f(n) = S(f(n-1)), and designate a trivial formula directly so that the N'th number can be calculated directly without knowing (N-1)'th; this also render the seed meaningless.

So, you end up have a simple algebra function and not a sequence. For example:

``````int my_rand(int n) { return 42; } // Don't laugh!
int my_rand(int n) { 3*n*n + 2*n + 7; }
``````

If you want to put more constraint to the generated pattern (like distribution), it become a complex maths problem.

However, for your original goal, if what you want is constant speed to get pseudo-random numbers, I suggest to pre-generate it with traditional RNG and access with lookup table.

EDIT: I noticed you have concern with a table size for a lot of numbers, however you may introduce some hybrid model, like a table of N entries, and do f(k) = g( tbl[k%n], k), which at least provide good distribution across N continue sequence.

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I think a seed could still make a difference. Eg: if 7 was your seed, and you multiplied it by n or something it would. You would get a different sequence compared to using a different seed. –  John Feb 22 at 5:14
seed is different than parameter to the function. a seed is directly assigning the "last number" used to produce the next sequence. –  Calvin Feb 22 at 5:17

This demonstrates an PRNG implemented as a hashed counter. This might appear to duplicate R.'s suggestion (using a block cipher in CTR mode as a stream cipher), but for this, I avoided using cryptographically secure primitives: for speed of execution and because security wasn't a desired feature.

If we were trying to create a secure stream cipher with your requirement that any emitted sequence be trivially repeatable, given knowledge of its index...

...then we could choose a secure hash algorithm (like SHA256) and a counter with a lot of bits (maybe 2048 -> sequence repeats every 2^2048 generated numbers without reseeding).

HOWEVER, the version I present here uses Bob Jenkins' famous hash function (simple and fast, but not secure) along with a 64-bit counter (which is as big as integers can get on my system, without needing custom incrementing code).

Code in main demonstrates that knowledge of the RNG's counter (seed) after initialization allows a PRNG sequence to be repeated, as long as we know how many values were generated leading up to the repetition point.

Actually, if you know the counter's value at any point in the output sequence, you will be able to retrieve all values generated previous to that point, AND all values which will be generated afterward. This only involves adding or subtracting ordinal differences to/from a reference counter value associated with a known point in the output sequence.

It should be pretty easy to adapt this class for use as a testing framework -- you could plug in other hash functions and change the counter's size to see what kind of impact there is on speed as well as the distribution of generated values (the only uniformity analysis I did was to look for patterns in the screenfuls of hexadecimal numbers printed by main()).

``````#include <iostream>
#include <iomanip>
#include <ctime>

using namespace std;

class CHashedCounterRng {
static unsigned JenkinsHash(const void *input, unsigned len) {
unsigned hash = 0;
for(unsigned i=0; i<len; ++i) {
hash += static_cast<const unsigned char*>(input)[i];
hash += hash << 10;
hash ^= hash >> 6;
}
hash += hash << 3;
hash ^= hash >> 11;
hash += hash << 15;
return hash;
}

unsigned long long m_counter;

void IncrementCounter() { ++m_counter; }

public:
unsigned long long GetSeed() const {
return m_counter;
}
void SetSeed(unsigned long long new_seed) {
m_counter = new_seed;
}
unsigned int operator ()() {
// the next random number is generated here
const auto r = JenkinsHash(&m_counter, sizeof(m_counter));
IncrementCounter();
return r;
}

// the default coontructor uses time()
// to seed the counter
CHashedCounterRng() : m_counter(time(0)) {}

// you can supply a predetermined seed here,
// or after construction with SetSeed(seed)
CHashedCounterRng(unsigned long long seed) : m_counter(seed) {}
};

int main() {
CHashedCounterRng rng;
// time()'s high bits change very slowly, so look at low digits
// if you want to verify that the seed is different between runs
const auto stored_counter = rng.GetSeed();
cout << "initial seed: " << stored_counter << endl;
for(int i=0; i<20; ++i) {
for(int j=0; j<8; ++j) {
const unsigned x = rng();
cout << setfill('0') << setw(8) << hex << x << ' ';
}
cout << endl;
}
cout << endl;

cout << "The last line again:" << endl;
rng.SetSeed(stored_counter + 19 * 8);
for(int j=0; j<8; ++j) {
const unsigned x = rng();
cout << setfill('0') << setw(8) << hex << x  << ' ';
}
cout << endl << endl;
return 0;
}
``````
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I noticed that you were checking for repeated outputs as a measure of randomness; keep in mind that a truly random number generator will always emit repeat values, because every bit in its output stream is independent of every other bit. In fact, after a certain number of observations with no repeating outputs, evidence will grow that the stream you are looking at does NOT contain random values. –  Christopher Oicles Feb 22 at 10:00