IntStream.range
is already sorted:
// reports true
System.out.println(
IntStream.range(0, 4)
.spliterator()
.hasCharacteristics(Spliterator.SORTED)
);
So when sorted()
method on the Stream is hit, internally, it will become a NO-OP.
Otherwise, as you already see in your first example, all the elements have to be sorted, only then findFirst
can tell who is "really the first one".
Just notice that this optimization only works for naturally sorted streams. For example:
// prints too much you say?
Stream.of(new User(30), new User(25), new User(34))
.peek(x -> System.out.println("1 : before I call first sorted"))
.sorted(Comparator.comparing(User::age))
.peek(x -> System.out.println("2 : before I call second sorted"))
.sorted(Comparator.comparing(User::age))
.findFirst();
where (for brevity):
record User(int age) { }
.sorted()
on thatIntStream
just noops because it already knows somehow it's already sorted.peek
will actually observe a given element is unpredictable and implementation-dependent. It's only meant to be helpful for debugging purposes.Stream.of(0, 1, 2, 3)
gives you aStream<Integer>
whereasIntStream.range(0, 4)
gives you anIntStream
, a stream ofint
primitives.peek
to do lots of different things in many common scenarios.max
ormin
inO(1)
...IntStream.range(0, 4).peek(System.out::println).max(); // produces 0,1,2,3
. Why not use the same optimisation here?