Eran's answer described the differences between the two-arg and three-arg versions of `reduce`

in that the former reduces `Stream<T>`

to `T`

whereas the latter reduces `Stream<T>`

to `U`

. However, it didn't actually explain the need for the additional combiner function when reducing `Stream<T>`

to `U`

.

One of the design principles of the Streams API is that the API shouldn't differ between sequential and parallel streams, or put another way, a particular API shouldn't prevent a stream from running correctly either sequentially or in parallel. If your lambdas have the right properties (associative, non-interfering, etc.) a stream run sequentially or in parallel should give the same results.

Let's first consider the two-arg version of reduction:

```
T reduce(I, (T, T) -> T)
```

The sequential implementation is straightforward. The identity value `I`

is "accumulated" with the zeroth stream element to give a result. This result is accumulated with the first stream element to give another result, which in turn is accumulated with the second stream element, and so forth. After the last element is accumulated, the final result is returned.

The parallel implementation starts off by splitting the stream into segments. Each segment is processed by its own thread in the sequential fashion I described above. Now, if we have N threads, we have N intermediate results. These need to be reduced down to one result. Since each intermediate result is of type T, and we have several, we can use the same accumulator function to reduce those N intermediate results down to a single result.

Now let's consider a hypothetical two-arg reduction operation that reduces `Stream<T>`

to `U`

. In other languages this is called a "fold" or "fold-left" operation so that's what I'll call it here. Note this doesn't exist in Java.

```
U foldLeft(I, (U, T) -> U)
```

(Note that the identity value `I`

is of type U.)

The sequential version of `foldLeft`

is just like the sequential version of `reduce`

except that the intermediate values are of type U instead of type T. But it's otherwise the same. (A hypothetical `foldRight`

operation would be similar except that the operations would be performed right-to-left instead of left-to-right.)

Now consider the parallel version of `foldLeft`

. Let's start off by splitting the stream into segments. We can then have each of the N threads reduce the T values in its segment into N intermediate values of type U. Now what? How do we get from N values of type U down to a single result of type U?

What's missing is another function that **combines** the multiple intermediate results of type U into a single result of type U. If we have a function that combines two U values into one, that's sufficient to reduce any number of values down to one -- just like the original reduction above. Thus, the reduction operation that gives a result of a different type needs two functions:

```
U reduce(I, (U, T) -> U, (U, U) -> U)
```

Or, using Java syntax:

```
<U> U reduce(U identity, BiFunction<U,? super T,U> accumulator, BinaryOperator<U> combiner)
```

In summary, to do parallel reduction to a different result type, we need two functions: one that **accumulates** T elements to intermediate U values, and a second that **combines** the intermediate U values into a single U result. If we aren't switching types, it turns out that the accumulator function is the same as the combiner function. That's why reduction to the same type has only the accumulator function and reduction to a different type requires separate accumulator and combiner functions.

Finally, Java doesn't provide `foldLeft`

and `foldRight`

operations because they imply a particular ordering of operations that is inherently sequential. This clashes with the design principle stated above of providing APIs that support sequential and parallel operation equally.