# Prime generating number finder not producing correct output

I'm working on this problem:

Consider the divisors of 30: 1,2,3,5,6,10,15,30.
It can be seen that for every divisor d of 30, d+30/d is prime.

Find the sum of all positive integers n not exceeding 100 000 000 such that for every divisor d of n, d+n/d is prime.

and I thought for sure I had it, but alas, it's apparently giving me the wrong answer (`12094504411074`).

I am fairly sure my sieve of Eratosthenes is working (but maybe not), so I think the problem is somewhere in my algorithm. It seems to get the right answer for `n = 30` (`1+2+6+10+22+30 = 71` - is this correct?), but as numbers get larger, it apparently stops working.

Here is my Java code:

``````import java.util.HashSet;
public class Generators {
static HashSet<Integer> hSet = new HashSet<Integer>();

public static void main(String[] args) {
// TODO Auto-generated method stub
int n = 100000000;
sieveErat(n + 1); //Fill a hashSet with prime numbers
System.out.println("Sieve complete");
int check = 0;

long sum = 3;

for(int i = 2; i <= n; i++){
int numDivisors = 0;
int numPrimeChecks = 0;
boolean done = false;
if(!hSet.contains(i+1)){ //i+1 must be a prime number for i to be prime generating
continue;
}
else{
for(int j = 2; j < i/2; j++){
if(i%j == 0){
numDivisors++;
check = j + i/j;
if(hSet.contains(check)){
done = true;
numPrimeChecks++;
}
}else{
break;
}

}
if(numPrimeChecks == numDivisors && done){

sum += i;
}
}

}
System.out.println(sum);
}

public static void sieveErat(int N){
boolean[] isPrime = new boolean[N + 1];

for (int i = 2; i <= N; i++) {
isPrime[i] = true;
//count++;
}
// mark non-primes <= N using Sieve of Eratosthenes

for (int i = 2; i*i <= N; i++) {

// if i is prime, then mark multiples of i as nonprime
// suffices to consider mutiples i, i+1, ..., N/i
if (isPrime[i]) {
for (int j = i; i*j <= N; j++) {
isPrime[i*j] = false;
//    count--;
}
}

}

for(int i = 2; i < isPrime.length; i++){
if(isPrime[i]){
}
}
// System.out.println(count);

}
}
``````
-

The maths of your sieve looks fine to me. I hacked it around to use a BitSet which is much more space efficient. Is `5761455` primes below 100,000,000 correct?

Once I got your code working I got the same figure you get (`12094504411075`) what figure should you be getting?

I think this bit is wrong (I have changed the variable names to match the question for clarity)

``````    for(int d = 2; d < Math.sqrt(n+3); d++) {
if (n % d == 0) {
numDivisors++;
int check = d + n / d;
if (primes.get(check)) {
// **** What does done mean??? ****
//done = true;
numPrimeChecks++;
} else {
// **** Added! Got a divisor that did not check. No point in going on.
break;
}
} else {
// **** Why break here??? ****
//break;
}

}
``````

NB I have edited this code to reflect what we finally decided was a correct solution.

Why are you breaking out of the `d` loop as soon as you hit a `d` that does not divide `n`? Surely that cannot be right.

However, I think you can break out of the `d` loop when you have a divisor that does not check.

Also, what is your intended functionality of `done`? It seems to have no real function.

And, why do you start `sum` at `3`?

Removing the `break` I now get the value `1739023853139`. Is this correct?

Here's my sieve. Identical to yours but builds a `BitSet` which is a much more efficient structure than a `HashSet` in this case:

``````public static BitSet sieveOfEratosthenes(int n) {
BitSet isPrime = new BitSet(n);

// Iniially all numbers are prime.
for (int i = 2; i <= n; i++) {
isPrime.set(i);
}

// mark non-primes <= N using Sieve of Eratosthenes
for (int i = 2; i * i <= n; i++) {

// if i is prime, then mark multiples of i as nonprime
// suffices to consider mutiples i, i+1, ..., N/i
if (isPrime.get(i)) {
for (int j = i; i * j <= n; j++) {
isPrime.clear(i * j);
}
}

}

//System.out.println("Found " + isPrime.cardinality() + " primes");
return isPrime;
}
``````
-
It appears you caught me not documenting my code super well! 1. 'sum' starts at 3 because I do not test whether or not 1 and 2 are prime-generating using the algorithm; however, they both are prime generating, and 1+2 = 3. 2. I added 'done' as a way to give me the correct sum for smaller values of 'n' . That was my first indication that something was going wrong, because it gives an answer that's about 5 too big without 'done' 3. I think you're right about not putting break in the correct spot. I'll have to reconsider that. 4. According to someone else's work, the sum should be 1739023853137 –  Michelle Jan 8 '12 at 20:25
That all sounds reasonable. I think if you make the two changes I suggest (remove one `break` and add another) we will get a more reasonable figure. Mine's still running (low end laptop) ... at about 17,000,000 atm. I'll update my post as soon as it has finished. Once the run completes and I get a figure I will remove `done` and re-run. I suspect that will make no difference. I hope the figure I get is your `1739023853137`. Are you confident this is the correct figure? –  OldCurmudgeon Jan 8 '12 at 20:40
Paul, it will run rather long, I'm afraid. A better algorithm is needed. But you're right about the breaks and the done. –  Daniel Fischer Jan 8 '12 at 20:46
It is indeed the right figure. Based on your comments, I was able to arrive at the right answer and Project Euler accepted it! I also optimized it so that it runs much faster. Instead of starting 'sum' at '3', I changed 'sum' to start at '1', and instead of 'for(int j = 2; j < i/2; j++)', I realized that you can use 'for(int j = 2; j < Math.sqrt(i+3); j++)' It ran in a matter of seconds instead of minutes. Also, thanks a bunch for the BitSet tip - we didn't learn about those in Intro to Data Structures! –  Michelle Jan 8 '12 at 20:50
Oh, and yes, your number of primes less than 10^8 is correct. –  Daniel Fischer Jan 8 '12 at 21:02