# Determining if a BigInteger is Prime in Java

I am trying hands on validation of whether a BigInteger number entered is a Prime Number or not!

But, it is running fine for smaller numbers like 13,31,but it yields error in the case of 15;by declaring it as a Prime. I am unable to figure-out the mistake,probably it is hidden in the squareroot() method approach involving binary-search!

Please view the code and help me point out the mistake!!!

Calling code :-

``````boolean p=prime(BigInteger.valueOf(15));
System.out.println("P="+p);
``````

Called code :-

``````public static boolean prime(BigInteger bi2){
if(bi2.equals(BigInteger.valueOf(2)) || bi2.equals(BigInteger.valueOf(3)))
{
return true;
}
BigInteger bi,bin;
bin=squareroot(bi2);
if(bi2.mod(bi).equals(ZERO))
return false;
else continue;
}
return true;
}

public static BigInteger squareroot(BigInteger bi){
BigInteger low,high,mid=ZERO,two;
low=ONE;
high=bi;
two=BigInteger.valueOf(2);
while(low.compareTo(high)<0)
{
//System.out.println("Low-Mid-High="+low+" "+mid+" "+high);
if(mid.multiply(mid).compareTo(bi)==0)
return mid;
if(mid.multiply(mid).compareTo(bi)>0)
high = mid.subtract(ONE);
else if(mid.multiply(mid).compareTo(bi)<0)
}
return mid;
}
``````
-
I assume part of the challenge here is to implement all of the methods from scratch? Hence the square root implementation? –  Evan Knowles May 27 at 6:56
I strongly suggest stepping through this with a debugger. I believe you'll find the problem in seconds. –  David Wallace May 27 at 6:57
The square root of 15 (and most numbers) is not an integer, so your square root function is not going to be able to find a correct answer. For example, for 15 it returns a square root of 2. –  Evan Knowles May 27 at 6:58
No, @shekhar, try running 15 through your `squareroot` function. It returns 2, no matter whom you believe. –  David Wallace May 27 at 7:08
Don't you think it's a bit rude to contradict the two people who have correctly pointed out your error? –  David Wallace May 27 at 7:09

Your problem is that you return `mid` from `squareroot` without reevaluating it as `(low + high) / 2`. This causes it to return the midpoint of the previous iteration of the algorithm; which is nearly always wrong.
The effect of this is that you sometimes miss some of the prime factors. In the case of 15, because the `squareroot` returns 2, you miss finding 3 as a prime factor. In the cases of 13 and 31, there are no prime factors for you to miss, so you get the correct result.