I was solving the basic problem of finding the number of distinct integers in a given array.

My idea was to declare an `std::unordered_set`

, insert all given integers into the set, then output the size of the set. Here's my code implementing this strategy:

```
#include <iostream>
#include <fstream>
#include <cmath>
#include <algorithm>
#include <vector>
#include <unordered_set>
using namespace std;
int main()
{
int N;
cin >> N;
int input;
unordered_set <int> S;
for(int i = 0; i < N; ++i){
cin >> input;
S.insert(input);
}
cout << S.size() << endl;
return 0;
}
```

This strategy worked for almost every input. On other input cases, it timed out.

I was curious to see *why* my program was timing out, so I added an `cout << i << endl;`

line inside the for-loop. What I found was that when I entered the input case, the first `53000`

or so iterations of the loop would pass nearly instantly, but afterwards only a few `100`

iterations would occur each second.

I've read up on how a hash set can end up with `O(N)`

insertion if a lot of collisions occur, so I thought the input was causing a lot of collisions within the `std::unordered_set`

.

However, this is not possible. The hash function that the `std::unordered_set`

uses for integers maps them to themselves (at least on my computer), so no collisions would ever happen between different integers. I accessed the hash function using the code written on this link.

My question is, is it possible that the input itself is causing the `std::unordered_set`

to slow down after it hits around `53000`

elements inserted? If so, why?

**Here is the input case that I tested my program on. It's pretty large, so it might lag a bit.**

so no collisions would ever happen between different integersis missing something very important about the way hash tables work. The bucket key isn't the hash (which may indeed not collide), but the key modulo the size of the table. The table is not infinite in size, so collisions willalwayshappen when you get over a fairly small load factor.