I am given a number k in the range 1 to 10000. The problem is to find the smallest multiple that can be written only with the digit 1 (known as a repunit). So for k=3 the solution is 111 because 3 divides 111, but 3 does not divide 1 or 11. For k=7, the solution is 111111 (six ones).

How to calculate the solution for any k?

I understand I need to use remainders since the solution can be very big (or I suppose use a BigInteger class)

  • 6
    How much elementary number theory do you know? Hint: if k divides the number composed of n ones, then 10^n is congruent to 1 modulo k. Jul 14 '15 at 17:48
  • number theory not much , but I can follow up to a point :D . Jul 14 '15 at 17:50
  • 1
    So for 3 -> 111 - and for 2,4,5?
    – MBo
    Jul 14 '15 at 18:33
  • 4
    @MBo: It's probably safe to assume that these "random numbers" only ever end in 1, 3, 7 or 9. Jul 14 '15 at 18:35
  • 2

This problem involves a bit of math, so let's start with it.

1111...1 (n digits one) =

enter image description here.

Let's denote our random number with k. Since our condition is

enter image description here,

it follows that

enter image description here


enter image description here,

where enter image description here denotes congruence operator. We are searching for the smallest such n, which is exactly a multiplicative order. Multiplicative order exists if and only if 10 and 9k are relatively prime, which is easy to check. One example of effectively calculating multiplicative order can be found here, and if you don't need an optimized version, then the basic modular exponentiation would do the trick:

int modexp(long mod) // mod = 9*k
    int counter = 1;
    long result = 10;            
    while(result != 1)
        result = (result * 10) % mod;

    return counter;

Bonus: this function is guaranteed to run at most phi(mod) times, where phi(mod) is Euler totient function. Important properties of this function are that phi(mod) < mod, and that multiplicative order divides phi(mod).

  • Since OP hinted at using BigInteger, modexp from the Java Library can be used: docs.oracle.com/javase/7/docs/api/java/math/…
    – henje
    Jul 14 '15 at 21:42
  • @henje Yes, in case that OP wants to use BigInteger class, then he can use modexp directly like you mentioned. Jul 15 '15 at 8:53
  • I'm trying to solve this problem only using algebra but I m stuck on trying to isolate n from other variable on the expression 10^n (congruence operator) 1 (mod 9*k)
    – ArthurQ
    Sep 23 '17 at 3:53
  • @Nacho You can calculate Euler totient function of 9k, find its divisors and sort them in ascending order. First divisor that satisfies given congruence relation is your solution. Sep 23 '17 at 8:32

If you're always guaranteed a solution (at least for even n and multiples of 5, there is no solution. I haven't given it much thought for others, but I think the rest should always have a solution):

(a + b) % c = ((a % c) + (b % c)) % c
(a * b) % c = ((a % c) * (b % c)) % c

Where % is the modulo operator: a % b = the remainder of the division of a by b. This means that we can take modulos between additions and multiplications, which will help solve this problem.

Using this, you can use the following algorithm, which is linear in the number of digits of the result and uses O(1) memory:

number_of_ones = 1
remainder = 1 % n
while remainder != 0:

  # here we add another 1 to the result,
  # but we only store the result's value mod n.
  # When this is 0, that is our solution.
  remainder = (remainder * 10 + 1) % n

print 1 number_of_ones times

Followup question: what if you can use 0 and 1?

  • Omg you are so right. This was so easy if I had observed that you can take the former remainder multiply by 10 and add 1 and modulo n would be the remainder of that former number * 10 + 1... I feel kinda bad. Jul 14 '15 at 19:16
  • To answer your question if I can use both 1 and 0 I will have to use this programe and determine remainders until I find 2 equal remainders modulo n. (for the numbers of form 11111.... ) . Let's call the numbers I have found x and y. Then the answer I am looking for is y - x (with y greater than x). Such a number will always be found because of pigeonhole principle . Or common sense as I like to say. We have max n remainders and an infinity of 11111... numbers. So I will find 2 numbers that have the same remainder. Their difference is composed of 0s and 1s. Thank you for the Followup question! Jul 14 '15 at 19:19
  • I like Followup questions :P . And it is very good having the same style . Who knows maybe this exam I will receive a question like that . Very nice! Jul 14 '15 at 19:20
  • @LucianTarna not exactly true for the followup. You can also have something like 1010110 as the smallest. You need to use a breadth first search for this, and look at the problem as a graph. This current problem can also be seen as a linked list graph where you only add another 1 node. The new problem will be a tree where you add a 1 branch and a 0 branch at each step.
    – IVlad
    Jul 14 '15 at 19:51
  • Ohhhh I see what you mean. This was really tricky :P hehe. Nice one ! Jul 14 '15 at 19:59

An implementation of IVlad's idea:

public static String multiple (int n){
    String result = "No Solution";
    if (n > 3 && n % 2 != 0 && n % 5 != 0){
        StringBuilder sb = new StringBuilder("11");
        int k = 11;
        int remain = 11 % n;
        while (remain != 0){
            remain = (remain*10 + 1)%n;
        result = sb.toString();
    return result;

public static void main(String[] args) {
    Random rand = new Random();
    for (int i = 0; i < 100; i++) {
        int n = 2 + rand.nextInt(9998);
        System.out.println(n+": "+multiple(n));

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