I did some performance testing using an algorithm that heavily uses null checks as well as access to a potentially nullable field. I implemented a simple algorithm that removes the middle element from the single linked list.

First I implemented two classes of linked list node: safe - with Optional and unsafe - without.

**Safe Node**

```
class Node<T> {
private final T data;
private Optional<Node<T>> next = Optional.empty();
Node(T data) {
this.data = data;
}
Optional<Node<T>> getNext() {
return next;
}
void setNext(Node<T> next) { setNext(Optional.ofNullable(next)); }
void setNext(Optional<Node<T>> next ) { this.next = next; }
}
```

**Unsafe Node**

```
class NodeUnsafe<T> {
private final T data;
private NodeUnsafe<T> next;
NodeUnsafe(T data) {
this.data = data;
}
NodeUnsafe<T> getNext() {
return next;
}
void setNext(NodeUnsafe<T> next) {
this.next = next;
}
}
```

Then I implemented two similar methods with the only difference - first uses `Node<T>`

and the second uses `NodeUsafe<T>`

```
class DeleteMiddle {
private static <T> T getLinkedList(int size, Function<Integer, T> supplier, BiConsumer<T, T> reducer) {
T head = supplier.apply(1);
IntStream.rangeClosed(2, size).mapToObj(supplier::apply).reduce(head,(a,b)->{
reducer.accept(a,b);
return b;
});
return head;
}
private static void deleteMiddle(Node<Integer> head){
Optional<Node<Integer>> oneStep = Optional.of(head);
Optional<Node<Integer>> doubleStep = oneStep;
Optional<Node<Integer>> prevStep = Optional.empty();
while (doubleStep.isPresent() && doubleStep.get().getNext().isPresent()){
doubleStep = doubleStep.get().getNext().get().getNext();
prevStep = oneStep;
oneStep = oneStep.get().getNext();
}
final Optional<Node<Integer>> toDelete = oneStep;
prevStep.ifPresent(s->s.setNext(toDelete.flatMap(Node::getNext)));
}
private static void deleteMiddleUnsafe(NodeUnsafe<Integer> head){
NodeUnsafe<Integer> oneStep = head;
NodeUnsafe<Integer> doubleStep = oneStep;
NodeUnsafe<Integer> prevStep = null;
while (doubleStep != null && doubleStep.getNext() != null){
doubleStep = doubleStep.getNext().getNext();
prevStep = oneStep;
oneStep = oneStep.getNext();
}
if (prevStep != null) {
prevStep.setNext(oneStep.getNext());
}
}
public static void main(String[] args) {
int size = 10000000;
Node<Integer> head = getLinkedList(size, Node::new, Node::setNext);
Long before = System.currentTimeMillis();
deleteMiddle(head);
System.out.println("Safe: " +(System.currentTimeMillis() - before));
NodeUnsafe<Integer> headUnsafe = getLinkedList(size, NodeUnsafe::new, NodeUnsafe::setNext);
before = System.currentTimeMillis();
deleteMiddleUnsafe(headUnsafe);
System.out.println("Unsafe: " +(System.currentTimeMillis() - before));
}
}
```

Comparison of two several runs with different size of the list shows that approach with **code that uses **`Optional`

at the best is twice slower than one with nullables. With small lists it is 3 times slower.

`isPresent`

, instead use`map`

and`orElse`

.`if (isPresent()) doSomething()`

? Neither map nor orElse make sense there.`Optional`

is far more important than the number of bytecodes, unless you're working in a very specific environment.6more comments