# Speed problem for summation (sum of divisors)

I should implement this summation in C ++. I have tried with this code, but with very high numbers up to 10 ^ 12 it takes too long.

The summation is: For any positive integer k, let d(k) denote the number of positive divisors of k (including 1 and k itself). For example, for the number 4: 1 has 1 divisor, 2 has two divisors, 3 has two divisors, and 4 has three divisors. So the result would be 8.

This is my code:

``````#include <iostream>
#include <algorithm>

using namespace std;

int findDivisors(long long n)
{
int c=0;
for(int j=1;j*j<=n;j++)
{
if(n%j==0)
{
c++;
if(j!=(n/j))
{
c++;
}
}
}
return c;
}

long long compute(long long n)
{
long long sum=0;
for(int i=1; i<=n; i++)
{
sum += (findDivisors(i));
}
return sum;
}

int main()
{
int n, divisors;

freopen("input.txt", "r", stdin);
freopen("output.txt", "w", stdout);

cin >> n;

cout << compute(n);
}
``````

I think it's not just a simple optimization problem, but maybe I should change the algorithm entirely. Would anyone have any ideas to speed it up? Thank you.

• You might want to look at some information about computing divisor functions to try to bring this down from an O(n^2) approach. Maybe try building up a table of primes to find factorizations? May 11 at 19:24
• You can't loop 1 to 10^12. It will definitely get you a TLE. May 11 at 20:27
• As often with this kind of problem, this sum actually counts pairs x, y where x divides y, and the sum is arranged to count first all x corresponding to a fixed y, but nothing says you have to keep it that way. May 11 at 20:47

I used your brute force approach as reference to have test cases. The ones I used are

``````compute(12) == 35
cpmpute(100) == 482
``````

Don't get confused by computing factorizations. There are some tricks one can play when factorizing numbers, but you actually don't need any of that. The solution is a plain simple `O(N)` loop:

``````#include <iostream>
#include <limits>

long long compute(long long n){
long long sum = n+1;
for (long long i=2; i < n ; ++i){
sum += n/i;
}
return sum;
}

int main()
{
std::cout << compute(12) << "\n";
std::cout << compute(100) << "\n";
}
``````

Output:

``````35
482
``````

Why does this work?

The key is in Marc Glisse's comment:

As often with this kind of problem, this sum actually counts pairs x, y where x divides y, and the sum is arranged to count first all x corresponding to a fixed y, but nothing says you have to keep it that way.

I could stop here, because the comment already explains it all. Though, if it didn't click yet...

The trick is to realize that it is much simpler to count divisors of all numbers up to `n` rather than `n`-times counting divisors of individual numbers and take the sum.

You don't need to care about factorizations of eg `123123123` or `52323423` to count all divisors up to `10000000000`. All you need is a change of perspective. Instead of trying to factorize numbers, consider the divisors. How often does the divisor `1` appear up to `n`? Simple: `n`-times. How often does the divisor `2` appear? Still simple: `n/2` times, because every second number is divisible by `2`. Divisor `3`? Every 3rd number is divisible by `3`. I hope you can see the pattern already.

You could even reduce the loop to only loop till `n/2`, because bigger numbers obviously appear only once as divisor. Though I didn't bother to go further, because the biggest change is from your `O(N * sqrt(N))` to `O(N)`.

• Very nice observation @largest_prime_is_463035818 as when we calculate the sum of divisors we have to consider the number of occurrence of `n/i` and by the correlated pattern, it will appear `i` times. So multiplying with `i` will give the sum of divisors. But here we only considered the count of divisors. May 11 at 22:38
• @BadhanSen there is no multiplying with `i` its just the sum of `n/i` for `i = 1 till n` (actually the initial sum of n+1 and loop starting at 2 only going till n-1 is only due to a small confusion of mine, but it adds up right) May 11 at 22:41
• @BadhanSen " But here we only considered the count of divisors. " thats what the question is about. In all the excitment I actually didnt bother to understand your answer completely. Are you summing the divisors? Thats not what the question is asking for May 11 at 22:44
• Yes, @largest_prime_is_463035818 I am saying the sum of all divisors from 1 to n technique. May 11 at 22:46

largest_prime_is_463035818's answer shows an O(N) solution, but the OP is trying to solve this problem

with very high numbers up to 1012.

The following is an O(N1/2) algorithm, based on some observations about the sum

n/1 + n/2 + n/3 + ... + n/n

In particular, we can count the number of terms with a specific value.

Consider all the terms n/k where k > n/2. There are n/2 of those and all are equal to 1 (integer division), so that their sum is n/2.

Similar considerations hold for the other dividends, so that we can write the following function

``````long long count_divisors(long long n)
{
auto sum{ n };
for (auto i{ 1ll }, k_old{ n }, k{ n }; i < k ; ++i, k_old = k)
{ //                                    ^^^^^ it goes up to sqrt(n)
k = n / (i + 1);
sum += (k_old - k) * i;
if (i == k)
break;
sum += k;
}

return sum;
}
``````

Here it is tested against the O(N) algorithm, the only difference in the results beeing the corner cases n = 0 and n = 1.

Edit

Thanks again to largest_prime_is_463035818, who linked the Wikipedia page about the divisor summatory function, where both an O(N) and an O(sqrt(N)) algorithm are mentioned.

An implementation of the latter may look like this

``````auto divisor_summatory(long long n)
{
auto sum{ 0ll };
auto k{ 1ll };
for ( ; k <= n / k; ++k )
{
sum += n / k;
}
--k;
return 2 * sum - k * k;
}
``````

Finding a closed form for this summed expression seems to be beyond the techniques available, but it is possible to give approximations. The leading behavior of the series is given by

D(x) = xlogx + x(2γ - 1) + Δ(x)

where γ is the Euler–Mascheroni constant, and the error term is Δ(x) = O(sqrt(x)).

• Thanks, this solution works with all subtasks. Thanks for your help. May 12 at 6:26
• I was hoping for a `O(1)` and didnt find it, but this is nice. May 12 at 7:17
• with the help of hints in your solution and in the wiki article I came up with something more readable: godbolt.org/z/PMxxTf33c. How about adding it to your answer? I mean without your solution I wasnt able to get it and I don't feel like changing my answer completely May 12 at 19:03
• @largest_prime_is_463035818 I took the liberty to modify your suggestion, changing the condition from `i*i <= n` to `i <= n / i`. The duplicated division should be optimized away (gcc does it) and it should avoid a (remotely) possible overflow. Thanks again. May 12 at 20:06
• good to know about the division vs multiplication, though `sum` overflows much sonner if I am not mistaken, and there still is `k*k` on the `return`. May 12 at 22:56

Let's start off with some math and reduce the `O(n * sq(n))` factorization to `O(n * log(log(n)))` and for counting the sum of divisors the overall complexity is `O(n * log(log(n)) + n * n^(1/3))`.

For instance:

In Codeforces himanshujaju explains how we can optimize the solution of finding divisors of a number. I am simplifying it a little bit.

``````Let, n as the product of three numbers p, q, and r.

so assume p * q * r = n, where p <= q <= r.
The maximum value of p = n^(1/3).

Now we can loop over all prime numbers in a range [2, n^(1/3)]
and try to reduce the time complexity of prime factorization.

We will split our number n into two numbers x and y => x * y = n.

And x contains prime factors up to n^(1/3) and y deals with higher prime factors greater than n^(1/3).

Thus gcd(x, y) = 1.
Now define F(n) as the number of prime factors of n.

From multiplicative rules, we can say that

F(x * y) = F(x) * F(y), if gcd(x, y) = 1.

For finding F(n) => F(x * y) = F(x) * F(y)

So first find F(x) then F(y) will F(n/x)

And there will 3 cases to cover for y:
1. y is a prime number: F(y) = 2.
2. y is the square of a prime number: F(y) = 3.
3. y is a product of two distinct prime numbers: F(y) = 4.

So once we are done with finding F(x) and F(y), we are also done with finding F(x * y) or F(n).
``````

In Cp-Algorithm there is also a nice explanation of how to count the number of divisors on a number. And also in GeeksForGeeks a nice coding example of how to count the number of divisors of a number in an efficient way. One can check the articles and can generate a nice solution to this problem.

C++ implementation

``````#include <bits/stdc++.h>
using namespace std;
const int maxn = 1e6 + 11;
bool prime[maxn];
bool primesquare[maxn];
int table[maxn]; // for storing primes

void SieveOfEratosthenes()
{

for(int i = 2; i < maxn; i++){
prime[i] = true;
}

for(int i = 0; i < maxn; i++){
primesquare[i] = false;
}

// 1 is not a prime number
prime = false;

for(int p = 2; p * p < maxn; p++){
// If prime[p] is not changed, then
// it is a prime
if(prime[p] == true){
// Update all multiples of p
for(int i = p * 2; i < maxn; i += p){
prime[i] = false;
}
}
}

int j = 0;
for(int p = 2; p < maxn; p++) {
if (prime[p]) {
// Storing primes in an array
table[j] = p;

// Update value in primesquare[p * p],
// if p is prime.
if(p < maxn / p) primesquare[p * p] = true;
j++;
}
}
}

// Function to count divisors
int countDivisors(int n)
{
// If number is 1, then it will have only 1
// as a factor. So, total factors will be 1.
if (n == 1)
return 1;

// ans will contain total number of distinct
// divisors
int ans = 1;

// Loop for counting factors of n
for(int i = 0;; i++){
// table[i] is not less than cube root n
if(table[i] * table[i] * table[i] > n)
break;

// Calculating power of table[i] in n.
int cnt = 1; // cnt is power of prime table[i] in n.
while (n % table[i] == 0){ // if table[i] is a factor of n
n = n / table[i];
cnt = cnt + 1; // incrementing power
}

// Calculating the number of divisors
// If n = a^p * b^q then total divisors of n
// are (p+1)*(q+1)
ans = ans * cnt;
}

// if table[i] is greater than cube root of n

// First case
if (prime[n])
ans = ans * 2;

// Second case
else if (primesquare[n])
ans = ans * 3;

// Third case
else if (n != 1)
ans = ans * 4;

return ans; // Total divisors
}

int main()
{
SieveOfEratosthenes();
int sum = 0;
int n = 5;
for(int i = 1; i <= n; i++){
sum += countDivisors(i);
}
cout << sum << endl;
return 0;
}
``````

Output

``````n = 4 => 8
n = 5 => 10
``````

Complexity

Time complexity: `O(n * log(log(n)) + n * n^(1/3))`

Space complexity: `O(n)`

Thanks, @largest_prime_is_463035818 for pointing out my mistake.

• you changed some wording and the code seems to be yours, but this still looks like plagiarism: codeforces.com/blog/entry/22317. Please properly give attribution when copying large chunks from somewhere May 11 at 20:51
• actually there is clear differences but the similarities are too striking. For example "We have only these three cases since there can be at max two prime factors of Y. If it would have had more than two prime factors, one of them would surely have been <=N^(1/3) , and hence it would be included in X and not in Y." is word by word what you write, this cannot happen by chance May 11 at 20:55
• dont do it later but from the start. Already copying paragraphs or parts without proper attribution is plagiarism. When you directly quote from the text, the quotes should be marked to be recognisable as quotes May 11 at 20:59
• dont get me wrong, but its not a kind suggestion but a request. Plagiarism is no fun. I flagged this answer for moderators attention. If you ask me in its current state the answer should be deleted May 11 at 21:05
• it is not sufficient to add a note along the line of "For more explanation, the bellow reference will be helpful". As I said already, quotes must be marked such that they can be recognized as quotes. Prentending someone else words are yours can be a crime. For more information see eg here: plagiarism.org/article/what-is-plagiarism May 11 at 21:16