# Optimization of Algorithm [closed]

Here is the link to the problem.

The problem asks the number of solutions to the Diophantine equation of the form 1/x + 1/y = 1/z (where z = n!). Rearranging the given equation clearly tells that the answer is the number of factors of z2.

So problem boils to find the number of factors of n!2.

My algorithm is as follows

1. Make a boolean look up table for all primes <= n using Sieve of Eratosthenes algorithm.
2. Iterate over all primes P <= n and find its exponent in n!. I did this using step function formula. Let the exponent be K, then the exponent of P in n!2 will be 2K.
3. Using step 2 calculate number of factors with the standard formula.

For the worst case input of n = 106, my c code gives answer in 0.056s. I guess the complexity is no way greater than O(n lg n). But when I submitted the code on the site, I could pass only 3/15 test cases with the verdict on the rest as time limit exceeded.

I need some hint for optimizing this algorithm.

Code so far:

``````#include <stdio.h>
#include <string.h>

#define ULL unsigned long long int
#define MAXN 1000010
#define MOD 1000007

int isPrime[MAXN];

ULL solve(int N) {
int i, j, f;
ULL res = 1;
memset(isPrime, 1, MAXN * sizeof(int));
isPrime[0] = isPrime[1] = 0;
for (i = 2; i * i <= N; ++i)
if (isPrime[i])
for (j = i * i; j <= N; j += i)
isPrime[j] = 0;
for (i = 2; i <= N; ++i) {
if (isPrime[i]) {
for (j = i, f = 0; j <= N; j *= i)
f += N / j;
f = ((f << 1) + 1) % MOD;
res = (res * f) % MOD;
}
}
return res % MOD;
}

int main() {
int N;
scanf("%d", &N);
printf("%llu\n", solve(N));
return 0;
}
``````
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## closed as not a real question by BЈовић, Bo Persson, aromero, talnicolas, GravitonApr 17 '12 at 4:40

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..and your code so far is? –  Martin James Apr 16 '12 at 18:51
I'm rather confident your sieve is way too slow. It shouldn't take anything near to 0.56 seconds to treat `n = 10^6`. –  Daniel Fischer Apr 16 '12 at 18:56
@MartinJames: I have added a link for my code. –  svm11 Apr 16 '12 at 19:04
@user1336893 : In the future, please edit the code directly into your question rather than linking to an external site. –  ildjarn Apr 16 '12 at 19:05
@DanielFischer: I mistyped the time for my code. Its 0.056s –  svm11 Apr 16 '12 at 19:05

You have an `int` overflow here:

``````for (j = i, f = 0; j <= N; j *= i)
``````

If `46340 < i < 65536` and for many larger `i`, in the second iteration `j` will be negative if overflow wraps around (it is undefined behaviour, so anything could happen).

Replace it with e.g.

``````for(j = N / i, f = 0; j > 0; j /= i) {
f += j;
}
``````

It is, however, unlikely that the extra iterations due to the overflow would cause a "time limit exceeded", that will likely only cause wrong results.

So the generic advice is

• Sieve only odd numbers, perhaps also eliminate multiples of 3 from the sieve. Eliminating the odd numbers from the sieve roughly halves the time needed to sieve.
• Don't use an entire `int` for the flags, use bits or at least `char`s. That gives better cache locality and a further speedup.
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It is a possible overflow. But I had the same code written in java first which had data type of j in step function loop as long (so no chances of overflow), then also in java to mark primes I used boolean array. I migrated to c because c is generally faster than java. Anyhow, there sure should be a overflow in c. Only option left is to use bits-sieve and 6K+1, 6K-1 optimization. –  svm11 Apr 16 '12 at 20:37
Is there any alternative/better approach to calculate factors of (n!)^2 ? –  svm11 Apr 16 '12 at 21:01
On my box, using `char isPrime[MAXN]` halved the running time, throwing out evens gave another factor of nearly 2, so 1 million finishes in ~5ms. Using a bit sieve brings it down to ~4ms. If the caches on the testing machines are small, using a bit-sieve would have larger impact. I am not aware of a better algorithm, the only thing I see is optimising the sieve. But for small limits as these, there's not much to be gained beyond leaving out multiples of 2 and 3. –  Daniel Fischer Apr 16 '12 at 21:15