If you use `LinkedList<T>`

instead of `array<T>`

you could just use this:

```
list.AddLast(list.RemoveAndGetFirst());
```

Edit: `RemoveAndGetFirst()`

can be an extension like:

```
LinkedListNode<T> elem = list.First;
list.RemoveFirst();
return elem;
```

Complexity `O(1)`

. When you perform this multiple times:

```
void func<T>(LinkedList<T> list, int rotate) {
for(var i = 0; i < rotate; i++) {
list.AddLast(list.RemoveFirst());
}
}
```

You will have a complexity of `O(N)`

[where `N`

is the number of rotations]. This is, performance wise, the best solution.

If you really need to use arrays this could be a naiv solution:

```
var tmp = list[0];
for(var i = 1; i < list.Length; i++) {
list[i - 1] = list[i];
}
list[list.Length - 1] = tmp;
```

*(Be aware there are no range checks)*

But this will be very time consuming if you need to do this often. If you perform this multiple times:

```
void func<T>(T[] list, int rotate) {
for(var j = 0; j < rotate; j++) {
var tmp = list[0];
for(var i = 1; i < list.Length; i++) {
list[i - 1] = list[i];
}
list[list.Length - 1] = tmp;
}
}
```

You will end up with `O(N^2) = O(N * M)`

[where `N`

is the number of elements and `M`

the number of rotations]. This would be really bad. A better approach, if you know in advance you'll perform this often would be:

```
void func<T>(T[] list, int rotate {
for(var j = 0; j < list.Length; j++) {
var tmp = list[j];
var ix = (rotate + j) % list.Length;
list[j] = list[ix];
list[ix] = tmp;
}
}
```

Which will result in `O(N)`

[where `N`

is the number of elements].

As others already suggested, it's a good idea to write an extension method if you need this at multiple locations.

triedit? What do you meanefficientanyway? You are simply copyingintegersistrying to move the first element to the end. There's no disconnect.8more comments