This problem is equivalent to finding maximum of function `f(x)=n%x`

in given range. Let's see how this function looks like:

It is obvious that we could get the maximum sooner if we start with `x=k`

and then decrease `x`

while it makes any sense (until `x=max+1`

). Also this diagram shows that for `x`

larger than `sqrt(n)`

we don't need to decrease `x`

sequentially. Instead we could jump immediately to preceding local maximum.

```
int maxmod(const int n, int k)
{
int max = 0;
while (k > max + 1 && k > 4.0 * std::sqrt(n))
{
max = std::max(max, n % k);
k = std::min(k - 1, 1 + n / (1 + n / k));
}
for (; k > max + 1; --k)
max = std::max(max, n % k);
return max;
}
```

Magic constant `4.0`

allows to improve performance by decreasing number of iterations of the first (expensive) loop.

Worst case time complexity could be estimated as O(min(k, sqrt(n))). But for large enough `k`

this estimation is probably too pessimistic: we could find maximum much sooner, and if `k`

is significantly greater than `sqrt(n)`

we need only 1 or 2 iterations to find it.

I did some tests to determine how many iterations are needed in the worst case for different values of `n`

:

```
n max.iterations (both/loop1/loop2)
10^1..10^2 11 2 11
10^2..10^3 20 3 20
10^3..10^4 42 5 42
10^4..10^5 94 11 94
10^5..10^6 196 23 196
up to 10^7 379 43 379
up to 10^8 722 83 722
up to 10^9 1269 157 1269
```

Growth rate is noticeably better than O(sqrt(n)).

`int xx = n - (n / i) * i;`

. Or simply`int xx = n % i;`

. Or is the description wrong? Also you should save the value of`i`

when setting`max`

as that is the value of`x`

in the description. – IronMensan Oct 12 '15 at 18:53