# How to find divisor to maximise remainder?

Given two numbers `n` and `k`, find `x`, `1 <= x <= k` that maximises the remainder `n % x`.

For example, n = 20 and k = 10 the solution is x = 7 because the remainder 20 % 7 = 6 is maximum.

My solution to this is :

``````int n, k;
cin >> n >> k;
int max = 0;
for(int i = 1; i <= k; ++i)
{
int xx = n - (n / i) * i; // or int xx = n % i;
if(max < xx)
max = xx;
}
cout << max << endl;
``````

But my solution is `O(k)`. Is there any more efficient solution to this?

• There might be a way to short-circuit the search by starting at high values of "k". I don't think that would affect big-o. – Gordon Linoff Oct 12 '15 at 18:42
• This question is much more suitable for math.stackexchange.com IMO. The main problem at hand is algorithmic rather than programmatic. – barak manos Oct 12 '15 at 18:43
• @barakmanos . . . That is hard to say. The OP knows how to solve the problem, but is looking for an efficient implementation. – Gordon Linoff Oct 12 '15 at 18:47
• Your code doesn't match the description. It should be `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
• @IronMensan thanks for that, my mistake – 0x6773 Oct 12 '15 at 19:03

## 7 Answers

Not asymptotically faster, but faster, simply by going backwards and stopping when you know that you cannot do better.

Assume `k` is less than `n` (otherwise just output `k`).

``````int max = 0;
for(int i = k; i > 0 ; --i)
{
int xx = n - (n / i) * i; // or int xx = n % i;
if(max < xx)
max = xx;
if (i < max)
break;   // all remaining values will be smaller than max, so break out!
}
cout << max << endl;
``````

(This can be further improved by doing the for loop as long as `i > max`, thus eliminating one conditional statement, but I wrote it this way to make it more obvious)

Also, check Garey and Johnson's Computers and Intractability book to make sure this is not NP-Complete (I am sure I remember some problem in that book that looks a lot like this). I'd do that before investing too much effort on trying to come up with better solutions.

• First case of my solution. I should still take a look at the other cases though. – Marco A. Oct 14 '15 at 12:17

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)).

For k > n the problem is trivial (take x = n+1).

For k < n, think about the graph of remainders n % x. It looks the same for all n: the remainders fall to zero at the harmonics of n: n/2, n/3, n/4, after which they jump up, then smoothly decrease towards the next harmonic.

The solution is the rightmost local maximum below k. As a formula x = `n//((n//k)+1)+1` (where `//` is integer division). • What about n=60, k=12? Rightmost local maximum below k is 5, but global maximum is 6... – Evgeny Kluev Oct 13 '15 at 13:56
• You're right, my graph shows that clearly! What's going on? The gradient is steeper with each harmonic (right to left). Thus I think you'll need to test the two harmonics left of k. – Colonel Panic Oct 13 '15 at 14:07
• I don't think two is enough either. – Evgeny Kluev Oct 13 '15 at 14:11

waves hands around

No value of `x` which is a factor of `n` can produce the maximum `n%x`, since if `x` is a factor of `n` then `n%x=0`.

Therefore, you would like a procedure which avoids considering any `x` that is a factor of `n`. But this means you want an easy way to know if `x` is a factor. If that were possible you would be able to do an easy prime factorization.

Since there is not a known easy way to do prime factorization there cannot be an "easy" way to solve your problem (I don't think you're going to find a single formula, some kind of search will be necessary).

That said, the prime factorization literature has cunning ways of getting factors quickly relative to a naive search, so perhaps it can be leveraged to answer your question.

Nice little puzzle!

Starting with the two trivial cases.

for `n < k`: any `x` s.t. `n < x <= k` solves.

for `n = k`: `x = floor(k / 2) + 1` solves.

My attempts.

for `n > k`:

``````x = n
while (x > k) {
x = ceil(n / 2)
}
``````

^---- Did not work.

1. `x = floor(float(n) / (floor(float(n) / k) + 1)) + 1`
2. `x = ceil(float(n) / (floor(float(n) / k) + 1)) - 1`

^---- "Close" (whatever that means), but did not work.

My pride inclines me to mention that I was first to utilize the greatest `k`-bounded harmonic, given by `1.`

Solution.

Inline with other answers I simply check harmonics (term courtesy of @ColonelPanic) of `n` less than `k`, limiting by the present maximum value (courtesy of @TheGreatContini). This is the best of both worlds and I've tested with random integers between 0 and 10000000 with success.

``````int maximalModulus(int n, int k) {
if (n < k) {
return n;
}
else if (n == k) {
return n % (k / 2 + 1);
}
else {
int max = -1;
int i = (n / k) + 1;
int x = 1;
while (x > max + 1) {
x = (n / i) + 1;
if (n%x > max) {
max = n%x;
}
++i;
}
return max;
}
}
``````

Performance tests: http://cpp.sh/72q6

Sample output:

``````Average number of loops:
bruteForce: 516
theGreatContini: 242.8
evgenyKluev: 2.28
maximalModulus: 1.36 // My solution
``````

I'm wrong for sure, but it looks to me that it depends on if `n < k` or not.

I mean, if `n < k`, `n%(n+1)` gives you the maximum, so `x = (n+1)`.

Well, on the other hand, you can start from `j = k` and go back evaluating `n%j` until it's equal to `n`, thus `x = j` is what you are looking for and you'll get it in max `k` steps... Too much, is it?

Okay, we want to know divisor that gives maximum remainder;

let `n` be a number to be divided and `i` be the divisor.

we are interested to find the maximum remainder when `n` is divided by `i`, for all `i<n`.

we know that, `remainder = n - (n/i) * i //equivalent to n%i`

If we observe the above equation to get maximum `remainder` we have to minimize `(n/i)*i`

minimum of `n/i` for any `i<n` is `1`.

Note that, `n/i == 1`, for `i<n`, if and only if `i>n/2`

now we have, `i>n/2`.

The least possible value greater than `n/2` is `n/2+1`.

Therefore, the divisor that gives maximum remainder, `i = n/2+1`

Here is the code in C++

``````#include <iostream>

using namespace std;

int maxRemainderDivisor(int n){
n = n>>1;
return n+1;
}

int main(){
int n;
cin>>n;
cout<<maxRemainderDivisor(n)<<endl;
return 0;
}
``````

Time complexity: O(1)