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When I run the code in the console, the browser just stops working (am assuming stack overflow).

I've come up with several different algorithms for solving this problem, but I thought this one would not cause any SOs.

The problem:

The sequence of triangle numbers is generated by adding the natural numbers. So the 7th triangle number would be 1 + 2 + 3 + 4 + 5 + 6 + 7 = 28. The first ten terms would be:

1, 3, 6, 10, 15, 21, 28, 36, 45, 55, ...

Let us list the factors of the first seven triangle numbers:

1: 1

3: 1 3

6: 1,2,3,6

10: 1,2,5,10

15: 1,3,5,15

21: 1,3,7,21

28: 1,2,4,7,14,28

We can see that 28 is the first triangle number to have over five divisors.

What is the value of the first triangle number to have over five hundred divisors?

Failing solution:

function divisors(n){
    var counter = 0;
    var triangle = 3;
    var triangle_add = 2;
    while (counter < n){
        for (var i = 1; i = triangle; i++){
            if (triangle % i === 0){
        if (counter < n){
            triangle = triangle + triangle_add;
            counter = 0;
    return triangle;

share|improve this question
That won't have a stack overflow (stack overflows only usually occur when you have functions called recursively). Your flow is a little odd; usually you would simply return from an infinite loop instead of breaking out by convoluted conditions. As for why it fails, probably because you say i = triangle when I'm pretty sure you meant i < triangle – Dave Mar 24 '13 at 17:46
It's not working because it's having to do an awful lot of calculation. In fact it's probably going beyond the range of a precise number (started getting into limited significant figures territory). You don't seem to have appreciated that the problem is posed specifically to be too difficult to solve by brute-force; you need to think about it first. – Dave Mar 24 '13 at 18:00
perhaps you mean i==triangle. If you use a single '=' you assign the value of triangle to i, while I think you want to compare the values, which should be done with i==triangle. Btw i'm running my own version as i type. It's been running for 5 minutes, and i'm currently at +- 390 ... – Entreco Mar 24 '13 at 18:01
Actually I may stand corrected; I did a simple boundary limit and have a solution which runs very quickly. It might have a mistake though. You can see it here (spoilers, etc!) – Dave Mar 24 '13 at 18:13
@Entreco it essentially does the same thing your code does, but uses the knowledge that any divisor lower than the square root of the number will have a matching divisor greater than the square root. So it only needs to search a much smaller space for divisors. Also it calculates the i-th triangular number by the standard formula instead of adding to a variable each iteration, so that it can start from where it left off. – Dave Mar 24 '13 at 18:35

Your solution is not working because, most probably, it is very slow. This problem can be solved much faster by the following method:

  1. Find all the prime numbers smaller than some N (put, for example, N=100'000) using Sieve of Eratosthenes. It is quite fast.
  2. As we know from elementary math each number can be written in the form X=p1^i1*p2^i2*...*pn^in where pj is prime number and ij is the power of corresponding prime number. The number of divisors of X is equal to (i1+1)*(i2+1)*...*(in+1) since that many different ways we can form a number which will be divisor of X. Having an array of prime numbers the number of divisors for X can be calculated quite fast (the code still has place to be optimized):

    int divisorCount(long long X)
        int c = 1;
        for (int i = 0; PRIMES[i] <= X; ++i)
            int pr = PRIMES[i];
            if (X % pr == 0)
                int p = 1;
                long long r = X;
                while (r % pr == 0)
                    r = r / pr;
                c *= p;
        return c;
  3. Iterate through all triangle numbers and count divisor numbers for them using the above function. The i-th triangle number is i * (i + 1) / 2, so no need to keep a variable, increment it and add it each time.

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