Here I give an efficient algorithm, i.e. one that works in time (edit: correction) polynomial in the value of A to solve the question for number A. I also give a proof that this number N exists for all numbers A and prove the correctness of my algorithm -- the proof shows that for any number A, the right answer has at most A^2 4's in it (and the number of zeros is at most something like twice the number of digits of A, crudely). (I don't know if A^2 fours is the best bound but I think it's probably not too far off.) The running time is not going to be more than polynomial in the size of A or the output. (I didn't work it out exactly.) Seeing the other answers now, it's basically the same as pasaba por aqui's answer but I think I give a more rigorous explanation of why it works. (Although my writing could be improved probably...)

Terminology: In the sequel, I'm going to say that `a number N has the form {STRING}`

to mean that it's decimal expansion matches a regular expression {STRING}, even though that is not standard number theory terminology.

Problem: Given A, Find the smallest integer N of the form "4+0*" such that N mod A = 0

Step 1: Consider 10 mod A, and in particular the sequence { 10^n mod A } for n = 1,2,3,...

First obvious question is, what happens if 10 is invertible mod A, i.e. 10 is coprime to A, vs. if it isn't. (Edit: this is not actually obvious, but in 90% of these elementary number theory things, the way to make progress is to do some case analysis based on the prime factorizations of numbers involved, and thinking about when things are coprime vs. when they share common factors is often a good direction.)

If 10 is not coprime to A, there are a few possibilities. One is that 10 divides A, this is a silly case. We can simply divide A by 10, find the answer then, and multiply it by 10. If that's ruled out, then either 5 divides A, but 2 does not, or 2 divides A but 5 does not, or A is coprime to 10.

Suppose 5 divides A, but 2 does not. If N mod A = 0 has the form above, consider N mod 5 -- it is equal to the lowest order digit since 5 | 10. Therefore the lowest order digit must be 0 and not 4, so 10 | N. That is, in this case, any integer of the form "4+0*" such that N mod A = 0, also has N mod 2A = 0. And 10 divides 2A so this means we can reduce to a simpler problem.

Suppose 2 divides A, but 5 does not. It's obvious that 4 in fact divides any number of the form "4+0*", so for any odd number A', the smallest integer N as described is that same whether we take A to be A', 2A', or 4A'. Now suppose that 8 divides A. Since 8 divides any number of the form "40+", and 8 does not divide 4, by a similar argument as before it implies that the number N must have zero as its lower digit, so if 8 | A, it implies that if N mod A = 0, then also N mod 5A = 0. So we can move to this number, and then pull out a power of 10 and reduce to a simpler question.

Thus we can restrict attention to the case that 10 is coprime to A.

This simplifies things because then elementary number theory (chinese remainder theorem) tells us that 10 is invertible mod A, i.e. 10^k = 1 mod A for some large enough k. It means also that we can ignore the possibility of zeros in the digits of N -- since if X * 10^y = 0 mod A, and 10 is invertible mod A, we must also have that X = 0 mod A, which would be a smaller solution.

Thus once 10 is coprime to A, the smallest integer N of the form "4+0*" such that N mod A = 0 is the same as the smallest integer of the form "4+" such that N mod A = 0.

(Additionally, its now clear that there always exists SOME integer N of this form is that divisible by A. So all these programs indeed terminate and do not infinite loop for any input :) Because, we can do a win-win analysis. Suppose that 10^k = 1 mod A. Now consider the value of the decimal number K made of exactly k 4's, reduced modulo A. If this is zero, then that proves the number exists and we're done. If it's not zero, then say it is some value "a" mod A not equal to 0. We know that the number K * 10^k is also equal to "a" mod A, because 10^k = 1 mod A. And K * 10^k also has the form we care about, and this is true also for K * 10^{ik} for any i. Thus if we take a decimal number made of exactly A * k 4's, it must be equal to A*a = 0 mod A. Thus we have constructed a number N of the desired form which is divisible by A.)

Now we can solve the problem without brute force directly by a simple for loop. We just keep track of the value "4000000... mod A" and the value "444444.... mod A" where the numbers are k digits long, and we figure out these modulo values for k+1 digit numbers by, multiplying the value of the first by the value of 10 mod A, reducing modulo A, then adding this also to the second and reducing that modulo A.

Here's the complete code:

```
#include <cassert>
#include <iostream>
typedef unsigned long long ul;
ul fast_finder(ul A) {
assert(A);
ul num_zeros = 0; // remember how many zeros we need to add at the end
while ((A % 10) == 0) {
A /= 10;
++num_zeros;
}
while ((A % 5) == 0) {
A /= 5;
++num_zeros;
}
while ((A % 8) == 0) {
A /= 2;
++num_zeros;
}
while ((A % 2) == 0) {
A /= 2;
}
ul four_mod_A = 4 % A;
ul ten_mod_A = 10 % A;
ul num_fours = 1;
// in these variable names "k" is the number of fours we are considering
ul four_times_ten_to_the_k_mod_A = four_mod_A;
ul sum_of_fours_mod_A = four_mod_A;
while (sum_of_fours_mod_A) {
four_times_ten_to_the_k_mod_A *= 10;
four_times_ten_to_the_k_mod_A %= A;
sum_of_fours_mod_A += four_times_ten_to_the_k_mod_A;
sum_of_fours_mod_A %= A;
++num_fours;
}
// now build an integer representation of the result from num_fours, num_zeros
ul result = 0;
while (num_fours) {
result *= 10;
result += 4;
--num_fours;
}
while (num_zeros) {
result *= 10;
--num_zeros;
}
return result;
}
// This is to check the correctness of the fast algorithm, it's just the naive algorithm.
ul slow_finder(ul A) {
assert(A);
for (ul B = 1;;++B) {
ul N = B * A;
bool saw_four = false;
while (N) {
ul low = N % 10;
if (low == 4) {
saw_four = true;
} else if (low != 0 || saw_four) { break; }
N /= 10;
}
if (N == 0)
return A*B;
}
}
void check(ul x) {
std::cout << x << ": ";
ul f = fast_finder(x);
std::cout << f << std::flush;
ul s = slow_finder(x);
if (f != s) {
std::cout << "failed! ( " << s << " )" << std::endl; return;
}
std::cout << '.' << std::endl;
}
int main() {
check(1);
check(3);
check(4);
check(5);
check(10);
check(11);
check(13);
check(15);
check(18);
check(73);
check(64);
check(52);
}
```

any`4`

, i.e.`404`

doesn't make it, either. – dhke Aug 17 '15 at 17:02