# Pseudo random number generator using the Blum Blum Shub algorithm

We're required to implement Blum Blum Shub Algorithm in a pseudo random number generator. I tried searching for implementations in c# to get an idea but was unsuccessful. Some methods we're required to implement are not clear enough (or maybe I'm not getting exactly what they're asking).

Anyone could provide some help with either the code or maybe an example in a similar fashion? I have a harder time grasping concepts from text.Any help would be greatly accepted!

First, I tried following the logic of the question. With little progress, I began searching on-line for better explanations and possibly finding implementations to better understanding. Finally, I attempted to fill in some of the requested methods with what I thought made sense.

``````static long seed = 6367859;
static long p = 3263849;
static long q = 1302498943;
static long m = p*q;

// Generates a random bit i.e. 0 or 1 using the Blum Blum Shub Algorithm and the Least Significant Bit
private byte generateRandomBit(){ }

// Method to generate a single positive 32 bit random number using the Blum Blum Shub Algorithm.
// The generateRandomBit() method is used to generate the random bits that make up the random number
// Not complete!!
public int GenerateNextRandomNumber()
{
int nextRandomNumber = (int)((p * seed + q) % m);

seed = nextRandomNumber;

return nextRandomNumber;
}

// Generates a random number between min and max.
// The GenerateNextRandomNumber() method must be used to generate the initial random number which must then be manipulated (if necessary) to be between min and max
public int GenerateNextRandomNumber(int min, int max){ }

// Uses the GenerateNextRandomNumber Method to generate a sequence of Random Numbers between the minimum and the maximum value using the Blum Blum Shub Algorithm
public int[] GenerateRadmonSequence(int n, int min, int max)
{
int[] sequence = new int[n];

for (int i = 0; i < n; i++)
{
int randNum = Math.Abs(GenerateNextRandomNumber());

randNum = min + randNum % (max + 1 +- min);
sequence[i] = randNum;
}

return sequence;
}
``````

The result should be to generate a sequence of numbers from min to max.

• Sorry if it wasn't clear. I'm trying to implement Blum Blum Shub in a pseudo random number generator as shown above but struggling with the comments depicting what I need to be doing in them. My question is mainly on to familiarise myself with the algorithm as I couldn't find implementations in c# of it. – user9134299 Jun 1 '19 at 17:13
• Blum Blum Shub from Wikipedia: Blum Blum Shub takes the form x[n + 1] = (x[n] ^ 2) % M, where M is the product of two large primes. – Theodor Zoulias Jun 1 '19 at 17:31
• See Handbook of Applied Cryptography chapter 5, section 5.5.2. – rossum Jun 1 '19 at 20:01

No, you cannot use longs for this type of RNG: It pretty much requires arbitrary precision math. And what you implemented actually looks like the Linear Congruential Generator algorithm, not the Blum Blum Shub algorithm.

Here is the code to get you going, using .NET Core 2.2 and Win10 x64. Using BigInteger, proper algorithm I believe, and parity to get next random bit. You could use least significant bit for random bit as well.

``````using System;
using System.Numerics;

namespace BlumBlumSnub
{
class Program
{
public static readonly BigInteger p = 3263849;
public static readonly BigInteger q = 1302498943;
public static readonly BigInteger m = p*q;

public static BigInteger next(BigInteger prev) {
return (prev*prev) % m;
}

public static int parity(BigInteger n) {
BigInteger q = n;
BigInteger count = 0;
while (q != BigInteger.Zero) {
count += q & BigInteger.One;
q >>= 1;
}
return ((count & BigInteger.One) != BigInteger.Zero) ? 1 : 0; // even parity
}

public static int LSB(BigInteger n) {
return ((n & BigInteger.One) != BigInteger.Zero) ? 1 : 0;
}

static void Main(string[] args)
{
BigInteger seed = 6367859;

BigInteger xprev = seed;
for(int k = 0; k != 100; ++k) {
BigInteger xnext = next(xprev);
int bit = parity(xnext); // extract random bit from generated BBS number using parity,
// or just int bit = LSB(xnext);
Console.WriteLine(\$"Bit = {bit}");
xprev = xnext;
}
}
}
}
``````
• It was using the logic of Linear Congruential Generator as that is the only reference our lecturer gave us. Thanks for the help I'll see what I can do! :) – user9134299 Jun 2 '19 at 10:54

``````public class BlumBlumShub
{
private ulong x;

public BlumBlumShub(int m, int seed)
{
this.m = (ulong) m;
x = (ulong)seed;
}

public int Next()
{
x = (x * x) % m;
return (int)x;
}
}
``````

reference

Edit: If you really need very large number you can adapt it easily:

``````public class BlumBlumShub
{
private BigInteger x;

public BlumBlumShub(BigInteger m, BigInteger seed)
{
this.m = m;
x = seed;
}

public BigInteger Next()
{
x = (x * x) % m;
return x;
}
}
``````
• `(x*x)` would cause overflow, in checked mode you'll get an exception – Severin Pappadeux Jun 2 '19 at 1:16
• you are right I meant `m` to be 32 bits. I have edited my answer. Thanks. – Samuel Vidal Jun 2 '19 at 1:21
• In general, product of two 64bit numbers is 128bits long. This means `(x * x) % m` has problems as well as `m` as product of `p` and `q`. And limiting `p` and `q` to small numbers for BBS algorithm is not a good idea - it is relying on problem with finding quadratic residue modulo `m`. – Severin Pappadeux Jun 2 '19 at 1:34
• Still, my edit addressed your remark : `x` here has type ulong but its value is capped to 31 bits so no overflow can occur. – Samuel Vidal Jun 2 '19 at 1:39
• BigInteger version is good, but in original one you're still getting overflows. F.e., `p=big prime below 2^31; q=big prime below 2^31; var r = new BlumBlumShub(p*q, 12345);` will produce overflow in constructor – Severin Pappadeux Jun 3 '19 at 14:05