Here's your original algorithm with some corrections and stylistic improvements:

```
public class MergeSort {
public static void main(String[]args) {
int[] nums = {12,9,4,99,120,1,3,10};
mergeSort(nums);
System.out.println(java.util.Arrays.toString(nums));
// "[1, 3, 4, 9, 10, 12, 99, 120]"
}
static void mergeSort(int[] arr) {
mergeSort(arr, 0, arr.length - 1, new int[arr.length]);
}
static void mergeSort(int[] arr, int low, int high, int[] buff){
if (low >= high) {
return;
}
int mid = (low + high) >>> 1;
mergeSort(arr, low, mid, buff);
mergeSort(arr, mid+1, high, buff);
for (int left = low, right = mid + 1, i = low; i <= high; i++) {
if (right > high || left <= mid && arr[left] <= arr[right]) {
buff[i] = arr[left++];
} else {
buff[i] = arr[right++];
}
}
for (int i = low; i <= high; i++) {
arr[i] = buff[i];
}
}
}
```

Unlike Eyal's implementation, where the role of `src`

and `dst`

are swapped back and forth through the levels of recursion, here we always sort to the same array object `arr`

, and the array object `buff`

is always used only as a temporary buffer for merging (and consequently, there's a copy phase after the merge phase). This is still `O(N log N)`

, but Eyal's more advanced implementation will be a constant-factor improvement.

### On the merge loop

Essentially you have a `left`

index for the left subarray, and `right`

index for the right subarray, and you pick the right element from either the `left`

or `right`

to put into `buff`

.

The valid range of elements are (inclusive bounds):

`left = low...mid`

for left subarray
`right = mid+1...high`

for right subarray

To evaluate which element to pick, consider the condition under which the `left`

element is picked. It happens when:

- There are no more element to pick from the right subarray (i.e.
`right > high`

)
**OR** (conditionally) there's still an element to pick from the left subarray (i.e. `left <= mid`

) and (conditionally) that element is less than or equal to the element from the right subarray (i.e. `arr[left] <= arr[right]`

).

It's important to use short-circuiting conditional-and `&&`

(JLS 15.23) and conditional-or `||`

(JLS 15.24) operators here, and to order these conditions accordingly. Otherwise you'll get an `ArrayIndexOutOfBoundsException`

.

### Related questions

### On finding average between two numbers

It's common to see the following:

```
int mid = (low + high) / 2; // BROKEN! Can result in negative!
```

The problem is that nowadays, arrays/lists etc can easily exceed 2^{30} elements, and the above would cause an overflow and results in a negative number.

The new idiom, as advocated by Josh Bloch, is the following:

```
int mid = (low + high) >>> 1; // WORKS PERFECTLY!
```

This uses the unsigned right shift operator (JLS 15.19); it handles any overflow on the addition correctly for our need.

### References

### Related questions

### On array declarations

Do not make a habit of declaring arrays like this:

```
int x[];
```

You should instead put the brackets with the *type*, rather than with the *identifier*:

```
int[] x;
```

### Related questions

`for`

- I know that it'll do what it looks like you want it to do based on your indentation, but good luck to anyone who wants to add a statement after your`else`

. – Dominic Rodger May 18 '10 at 21:12