# Can someone explain this Miller-Rabin Primality test pseudo-code in simple terms?

Here it is...

``````Input: n > 3, an odd integer to be tested for primality;
Input: k, a parameter that determines the accuracy of the test
Output: composite if n is composite, otherwise probably prime
Write n − 1 as (2^s)·d with d odd by factoring powers of 2 from n − 1
WitnessLoop: repeat k times:
pick a random integer a in the range [2, n − 2]
x ← a^d mod n
if x = 1 or x = n − 1 then do next WitnessLoop
repeat s − 1 times:
x ← x^2 mod n
if x = 1 then return composite
if x = n − 1 then do next WitnessLoop
return composite
return probably prime
``````

I got this from the Wikipedia article on the Miller-Rabin primality test. But I've not been able to comprehend it...... I'm not looking to understand the math behind it but only to implement it in a program. This algorithm seems to me, to be kind of confusing. A better, more simpler pseudo-code or implementation of it in vb.net, would be helpful.

EDIT code written so far:

``````Function Miller_Rabin(ByVal n As Integer) As Boolean
If n <= 3 Then : Return True
ElseIf n Mod 2 = 0 Then : Return False
Else
Dim k, s, a, d, x As Integer
k = 3
d = n - 1

While d Mod 2 = 0
d = d / 2
s += 1
End While

For c = 1 To k
a = Random(2, n - 1)
x = a ^ d Mod n
If x = 1 Or x = n - 1 Then GoTo skip
For r = 1 To s - 1
x = x ^ 2 Mod n
If x = 1 Then
Return False
Exit Function
Else
If x = n - 1 Then
GoTo skip
Else
Return False
Exit Function
End If
End If
Next
skip:   Next
Return True
End If
End Function

Function Random(ByVal x As Integer, ByVal n As Integer) As Integer
Dim a As Integer = Now.Millisecond * Now.Second
skip:
a = (a ^ 2 + 1) Mod (n + 1)
If a < x Then
GoTo skip
Else
Return a
End If
End Function
``````
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There is a VB6 implementation here if that's easy enough to port to VB.NET? –  Roger Rowland Jun 12 '13 at 11:06
This is way too complicated... Can't you just give me a proper pseudocode? –  user2219379 Jun 12 '13 at 11:19
The pseudocode you posted from wiki is not complex at all, what is it that you're having trouble with? If you've written some code, perhaps edit your question so we can see where you're stuck. Implementations are only painful when they involve very large numbers (as most do). –  Roger Rowland Jun 12 '13 at 11:53
Okay, Just wait.... Give me a couple of minutes.. –  user2219379 Jun 12 '13 at 11:57
This is the code I've written... link –  user2219379 Jun 12 '13 at 12:06

Here is simple pseudocode, as requested:

``````function isStrongPseudoprime(n, a)
d := n - 1; s := 0
while d % 2 == 0
d := d / 2
s := s + 1
t := powerMod(a, d, n)
if t == 1 return ProbablyPrime
while s > 0
if t == n - 1
return ProbablyPrime
t := (t * t) % n
s := s - 1
return Composite

function isPrime(n)
for i from 1 to k
a := randInt(2, n-1)
if isStrongPseudoprime(n, a) == Composite
return Composite
return ProbablyPrime

function powerMod(b, e, m)
x := 1
while e > 0
if e % 2 == 1
x := (b * x) % m
b := (b * b) % m
e := e // 2 # integer division
return x
``````

The `isStrongPseudoprime` function tests if a is a witness to the compositeness of n; note that if `isStrongPseudoprime` returns `Composite` the number is definitely composite, but the opposite of that is `ProbablyPrime` because there is a chance that the number is still composite. The `isPrime` function tests k witnesses; by setting the value of k you can determine the likelihood of error as 1 chance in 4^k. Most people use a value of k somewhere between 10 and 25. The `powerMod` function performs exponentiation by squaring, and is provided on the chance that your language doesn't provide it for you.

If you want to know more about the mathematics behind this test, I modestly recommend this essay at my blog, which also includes implementations in five languages, though none of them is VBA.

EDIT: Although he didn't say so, what the original poster actually wants to do is to find the sum of the primes less than two million and thus solve Project Euler 10. Looping through the numbers from 2 to n is a very inefficient way to sum the primes less than n; instead, the recommended method is to use a sieve. Pseudocode again:

``````function sumPrimes(n)
sum := 0
sieve := makeArray(2..n, True)
for p from 2 to n step 1
if sieve[p]
sum := sum + p
for i from p * p to n step p
sieve[i] := False
return sum
``````

The algorithm used here is the Sieve of Eratosthenes, invented over two thousand years ago by a Greek mathematician. Again, an explanation and code is in the essay at my blog.

-
I've implemented it and it works.... except if i use an arbitrary precise integer, to find out if large numbers are prime or not, it doesn't work! Like 1298074214633706835075030044377087 is actually prime, but the function returns it as composite! –  user2219379 Jun 13 '13 at 8:05
I can confirm that the number you stated is prime. Perhaps you have an overflow in some intermediate value. Are all the variables in your program big integers? –  user448810 Jun 13 '13 at 12:41
I managed to fix that issue... Would it be too much trouble if I asked you to test your implementation for me?.... I'd like to know the sum of all primes below 2 million, as my answer keeps changing. –  user2219379 Jun 13 '13 at 16:50
The solution I showed is pseudocode, which can't be run. The essay that I mentioned has implementations in five languages, all tested and working properly. If you want to sum the primes less than n, then instead of iterating from 2 to n and testing each number for primality, a better algorithm is sieving. I'll add that to the answer given above, since code can't be properly formatted in a comment. –  user448810 Jun 13 '13 at 23:29
I know its inefficient.... i just needed an example to test my implementation.... Btw, you're essays cover math based functions in languages other than the ones I know, which is c++ and vb.net. So I got help from some site, and got it running properly. So thanks anyway for the help. :D –  user2219379 Jun 14 '13 at 19:12

The VB implementation uses a hexadecimal conversion function to handle large numbers before the modular exponentiation. Example provided in comments:

``````' USAGE:
' Example: strResult = mpModExp("3c", "03", "face")
' computes (0x3c)^3 mod 0xface = 0x5b56
' or, in decimal, 60^3 mod 64206 = 23382
' Parameters may be hex strings of any length subject to limitations
' of VB and your computer. May take a long time!
``````
-

Key Ideas and Concepts (p stands for prime here):

1. Fermat's Little Theorem. ( a^(p-1) = 1 ( mod p ))
2. If p is prime and x^2 = 1 ( mod p ), then x = +1 or -1 ( mod p ).

We can prove this as follows:

``````x^2 = 1 ( mod p )
x^2 - 1 = 0 ( mod p )
(x-1)(x+1) = 0 ( mod p )
``````

Now if p does not divide both (x-1) and (x+1) and it divides their product, then it cannot be a prime, which is a contradiction. Hence, p will either divide (x-1) or it will divide (x+1), so x = +1 or -1 ( mod p ).

Let us assume that p - 1 = 2^d * s where s is odd and d >= 0. If p is prime, then either as = 1 ( mod p ) as in this case, repeated squaring from as will always yield 1, so (a^(p-1))%p will be 1; or a^(s*(2^r)) = -1 ( mod p ) for some r such that 0 <= r < d, as repeated squaring from it will always yield 1 and finally a^(p-1) = 1 ( mod p ). If none of these hold true, a^(p-1) will not be 1 for any prime number a ( otherwise there will be a contradiction with fact #2 ).

Algorithm :

1. Let p be the given number which we have to test for primality.
2. First we rewrite p-1 as (2^d)*s. (where s is odd and d >= 0).
3. Now we pick some a in range [1,n-1] and then check whether as = 1 ( mod p ) or a^(s*(2^r)) = -1 ( mod p ).
4. If both of them fail, then p is definitely composite. Otherwise p is probably prime. We can choose another a and repeat the same test.
5. We can stop after some fixed number of iterations and claim that either p is definitely composite, or it is probably prime.

Small code : Miller-Rabin primality test, iteration signifies the accuracy of the test

``````bool Miller(long long p,int iteration)
{
if(p<2)
return false;

if(p!=2 && p%2==0){
return false;

long long s=p-1;
while(s%2==0)
{
s/=2;
}
for(int i=0;i<iteration;i++)
{
long long a=rand()%(p-1)+1;
long long temp=s;
long long mod=modulo(a,temp,p);
while(temp!=p-1 && mod!=1 && mod!=p-1)
{
mod=mulmod(mod,mod,p);
temp *= 2;
}
if(mod!=p-1 && temp%2==0)
{
return false;
}
}
return true;
}
``````

It can be shown that for any composite number p, at least (3/4) of the numbers less than p will witness p to be composite when chosen as 'a' in the above test. Which means that if we do 1 iteration, probability that a composite number is returned as prime is (1/4). With k iterations the probability of test failing is (1/4)k or 4(-k). This test is comparatively slower compared to Fermat's test but it doesn't break down for any specific composite numbers and 18-20 iterations is a quite good choice for most applications.

PS: This function calculates (a*b)%c taking into account that a*b might overflow WHICH I HAVE USED ABOVE IN MILLER RABBIN TEST.

``````   long long mulmod(long long a,long long b,long long c)
{
long long x = 0,y=a%c;
while(b > 0)
{
if(b%2 == 1)
{
x = (x+y)%c;
}
y = (y*2)%c;
b /= 2;
}
return x%c;
}
``````
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Ask any question in comment if you have any problem ! –  Shashank Jain Jun 12 '13 at 12:11
I tried to implement your code in vb.net..... but it didn't work! Here is the link to it... pastebin.com/utV5u7Lm –  user2219379 Jun 12 '13 at 15:50
i don't know vb.net. but this will surely run on C++. i have used this implementation in programming use ! –  Shashank Jain Jun 12 '13 at 18:49
@Will Ness- Thank you for editing.. i was struggling with that indent thing for code ! –  Shashank Jain Jun 14 '13 at 8:45
you're welcome. :) to indent / unindent, select a paragraph and press Ctrl-K (or press "code" button above the editing area). –  Will Ness Jun 15 '13 at 0:58