# Optimization of my code in c for Project Euler # 23

i am solving Problem no 23 of project euler. I have used a simple logic , i am getting the correct answer but it is taking a great length of time to run the program.

Is there any way i can optimize my code ?.

I am first calculating all the numbers which are a sum of 2 abundant numbers and then subtracting it from the entire sum.

``````int factorsum(int);
int main()
{
int i, j, s = 0, t, m;
for (i = 24; i <= 28123; i++)   //sum of 2abundant nos start from 24
{
for (j = 12; j <= i / 2; j++) {
t = factorsum(j);
if (t > j) {
m = i - j;
t = factorsum(m);
if (t > m) {
s = s + i;
break;
}
}
}

}
j = 0;
for (i = 1; i <= 28123; i++)
j = j + i;
printf("\n%d", (j - s));
return 0;
}

int factorsum(int j)        //checking sum of factors
{
int k, s = 0;
for (k = 1; k <= (j / 2); k++) {
if (j % k == 0) {
s = s + k;
}
}
return s;
}
``````
-
Don't factorize. Add n to the element at index that is multiple of n. –  nhahtdh Oct 20 '12 at 6:29
Is your code originally formatted like it appeared in the question originally? Because it is much easier to understand and optimise if it is at least indented (approximately) consistently. –  dbaupp Oct 20 '12 at 10:17
IMHO If you take one step back from your program and take a look you will notice you have no variable values (no user input). Instead everytime you run the program you will have the same result, this suggests there is a lot of optimization potential e.g tables with values etc. –  claptrap Oct 20 '12 at 22:53

The immediate big optimisation is to precalculate the divisor sums. At the moment, you are recalculating `factorsum(j)` for `j = 12, ...` for each `i`. If you calculate the divisor sums once and store them in an array, that becomes a fast (`O(1)`) lookup instead of an `O(j/2)` computation.

That alone reduces the running time on my box from three and a half minutes to one second.

The next improvement would be to use a better strategy to compute the divisor sums. Instead of checking each number up to `j/2` whether it divides `j`, you can use the fact that divisors come in pairs, `(d, j/d)` to only check up to `√j` (be careful with perfect squares, you must only add the square root once).

That takes it down to 0.05 seconds.

But if you store the sums in an array, you can do even better by reversing the logic, instead of considering one number `n` at a time and finding its divisors, consider one divisor `d` and find all its multiples (`k*d`). That reduces the time needed to calculate the divisor sums from `O(limit^1.5)` (or `O(limit^2)` if you divide up to `j/2`) to `O(limit * log limit)`. (Note: since you are given an absolute limit, the complexity notation isn't strictly applicable here, let's pretend you try to find the numbers that aren't the sum of two abundant numbers up to a variable `limit`.)

That makes it 0.03 seconds.

-