Estou no Java 11.
Primeiro, vejamos como o método `sorted()` é declarado na interface `Stream`:
Stream<T> sorted();
Ok, isso não nos ajuda. Ele é um método abstrato sem implementação default. Então, para achar a implementação, vejamos o código do `Stream.of(...)`:
@SafeVarargs
@SuppressWarnings("varargs") // Creating a stream from an array is safe
public static<T> Stream<T> of(T... values) {
return Arrays.stream(values);
}
Agora, o código do `Arrays.stream(...)`:
public static <T> Stream<T> stream(T[] array) {
return stream(array, 0, array.length);
}
E depois:
public static <T> Stream<T> stream(T[] array, int startInclusive, int endExclusive) {
return StreamSupport.stream(spliterator(array, startInclusive, endExclusive), false);
}
Observe que os valores agora estão armazenados em um `Spliterator`.
Agora o `StreamSupport.stream(...)`:
public static <T> Stream<T> stream(Spliterator<T> spliterator, boolean parallel) {
Objects.requireNonNull(spliterator);
return new ReferencePipeline.Head<>(spliterator,
StreamOpFlag.fromCharacteristics(spliterator),
parallel);
}
A classe `java.util.stream.AbstractPipeline` não é uma classe pública, mas o seu código ainda assim pode facilmente ser visto dentro da JDK:
abstract class ReferencePipeline<P_IN, P_OUT>
extends AbstractPipeline<P_IN, P_OUT, Stream<P_OUT>>
implements Stream<P_OUT> {
Então, vamos ver a classe interna `Head`, que é enfim a implementação de `Stream` que procuramos:
static class Head<E_IN, E_OUT> extends ReferencePipeline<E_IN, E_OUT> {
A classe interna `Head` herda da classe externa `ReferencePipeline` e não sobrescreve o método `sorted`. Então, olhemos na superclasse (`ReferencePipeline`):
@Override
public final Stream<P_OUT> sorted() {
return SortedOps.makeRef(this);
}
A classe `SortedOps` também não é pública. Vejamos que método é esse `makeRef`:
static <T> Stream<T> makeRef(AbstractPipeline<?, T, ?> upstream) {
return new OfRef<>(upstream);
}
A classe `OfRef` é interna à `SortedOps`:
private static final class OfRef<T> extends ReferencePipeline.StatefulOp<T, T> {
/**
* Comparator used for sorting
*/
private final boolean isNaturalSort;
private final Comparator<? super T> comparator;
/**
* Sort using natural order of {@literal <T>} which must be
* {@code Comparable}.
*/
OfRef(AbstractPipeline<?, T, ?> upstream) {
super(upstream, StreamShape.REFERENCE,
StreamOpFlag.IS_ORDERED | StreamOpFlag.IS_SORTED);
this.isNaturalSort = true;
// Will throw CCE when we try to sort if T is not Comparable
@SuppressWarnings("unchecked")
Comparator<? super T> comp = (Comparator<? super T>) Comparator.naturalOrder();
this.comparator = comp;
}
/**
* Sort using the provided comparator.
*
* @param comparator The comparator to be used to evaluate ordering.
*/
OfRef(AbstractPipeline<?, T, ?> upstream, Comparator<? super T> comparator) {
super(upstream, StreamShape.REFERENCE,
StreamOpFlag.IS_ORDERED | StreamOpFlag.NOT_SORTED);
this.isNaturalSort = false;
this.comparator = Objects.requireNonNull(comparator);
}
@Override
public Sink<T> opWrapSink(int flags, Sink<T> sink) {
Objects.requireNonNull(sink);
// If the input is already naturally sorted and this operation
// also naturally sorted then this is a no-op
if (StreamOpFlag.SORTED.isKnown(flags) && isNaturalSort)
return sink;
else if (StreamOpFlag.SIZED.isKnown(flags))
return new SizedRefSortingSink<>(sink, comparator);
else
return new RefSortingSink<>(sink, comparator);
}
@Override
public <P_IN> Node<T> opEvaluateParallel(PipelineHelper<T> helper,
Spliterator<P_IN> spliterator,
IntFunction<T[]> generator) {
// If the input is already naturally sorted and this operation
// naturally sorts then collect the output
if (StreamOpFlag.SORTED.isKnown(helper.getStreamAndOpFlags()) && isNaturalSort) {
return helper.evaluate(spliterator, false, generator);
}
else {
// @@@ Weak two-pass parallel implementation; parallel collect, parallel sort
T[] flattenedData = helper.evaluate(spliterator, true, generator).asArray(generator);
Arrays.parallelSort(flattenedData, comparator);
return Nodes.node(flattenedData);
}
}
}
Note o `Arrays.parallelSort(flattenedData, comparator);`. É aqui que alguma ordenação está sendo feita:
@SuppressWarnings("unchecked")
public static <T> void parallelSort(T[] a, Comparator<? super T> cmp) {
if (cmp == null)
cmp = NaturalOrder.INSTANCE;
int n = a.length, p, g;
if (n <= MIN_ARRAY_SORT_GRAN ||
(p = ForkJoinPool.getCommonPoolParallelism()) == 1)
TimSort.sort(a, 0, n, cmp, null, 0, 0);
else
new ArraysParallelSortHelpers.FJObject.Sorter<>
(null, a,
(T[])Array.newInstance(a.getClass().getComponentType(), n),
0, n, 0, ((g = n / (p << 2)) <= MIN_ARRAY_SORT_GRAN) ?
MIN_ARRAY_SORT_GRAN : g, cmp).invoke();
}
E então temos a linha `TimSort.sort(a, 0, n, cmp, null, 0, 0);` denunciando que o algoritmo usado é o TimSort em alguns casos (no caso do `if`). Se isso cair no `else`, vejamos esse `ArraysParallelSortHelpers.FJObject.Sorter`:
static final class FJObject {
static final class Sorter<T> extends CountedCompleter<Void> {
static final long serialVersionUID = 2446542900576103244L;
final T[] a, w;
final int base, size, wbase, gran;
Comparator<? super T> comparator;
Sorter(CountedCompleter<?> par, T[] a, T[] w, int base, int size,
int wbase, int gran,
Comparator<? super T> comparator) {
super(par);
this.a = a; this.w = w; this.base = base; this.size = size;
this.wbase = wbase; this.gran = gran;
this.comparator = comparator;
}
public final void compute() {
CountedCompleter<?> s = this;
Comparator<? super T> c = this.comparator;
T[] a = this.a, w = this.w; // localize all params
int b = this.base, n = this.size, wb = this.wbase, g = this.gran;
while (n > g) {
int h = n >>> 1, q = h >>> 1, u = h + q; // quartiles
Relay fc = new Relay(new Merger<>(s, w, a, wb, h,
wb+h, n-h, b, g, c));
Relay rc = new Relay(new Merger<>(fc, a, w, b+h, q,
b+u, n-u, wb+h, g, c));
new Sorter<>(rc, a, w, b+u, n-u, wb+u, g, c).fork();
new Sorter<>(rc, a, w, b+h, q, wb+h, g, c).fork();;
Relay bc = new Relay(new Merger<>(fc, a, w, b, q,
b+q, h-q, wb, g, c));
new Sorter<>(bc, a, w, b+q, h-q, wb+q, g, c).fork();
s = new EmptyCompleter(bc);
n = q;
}
TimSort.sort(a, b, b + n, c, w, wb, n);
s.tryComplete();
}
}
E novamente, vemos o `TimSort.sort(a, b, b + n, c, w, wb, n);` lá.
Conclusão: O algoritmo usado é o [TimSort](https://pt.wikipedia.org/wiki/Timsort).