### A linear-time solution

The most asymptotically efficient way to do this would be to use bucket sort.

- You have 4 buckets, one for each of the congruency class of numbers modulo 4.
- Scan the numbers in the array once
- Put each number in the right bucket

- Then construct the output array
- Put all numbers from bucket 0 first, then all from bucket 1, then bucket 2, then bucket 3

Thus, this sorts the numbers in `O(N)`

, which is optimal. The key here is that by sorting on numbers modulo 4, there are essentially only 4 numbers to sort: 0, 1, 2, 3.

### An illustrative solution with `List`

Here's an implementation of the above algorithm (for general modulo `M`

) using `List`

and for-each for clarity. Ignore the unchecked cast warning, just concentrate on understanding the algorithm.

```
import java.util.*;
public class BucketModulo {
public static void main(String[] args) {
final int M = 4;
List<Integer> nums = Arrays.asList(13,7,42,1,6,8,1,4,9,12,11,5);
List<Integer>[] buckets = (List<Integer>[]) new List[M];
for (int i = 0; i < M; i++) {
buckets[i] = new ArrayList<Integer>();
}
for (int num : nums) {
buckets[num % M].add(num);
}
nums = new ArrayList<Integer>();
for (List<Integer> bucket : buckets) {
nums.addAll(bucket);
}
System.out.println(nums);
// prints "[8, 4, 12, 13, 1, 1, 9, 5, 42, 6, 7, 11]"
}
}
```

Once you fully understand the algorithm, translating this to use arrays (if you must) is trivial.

### See also

### A special note on `%`

The stipulation that numbers are non-negative is significant, because `%`

is NOT the *modulo* operator as it's mathematically defined; it's the *remainder* operator.

```
System.out.println(-1 % 2); // prints "-1"
```

### References