When using the reduce() operation on a parallel stream, the OCP exam book states that there are certain principles the reduce() arguments must adhere to. Those principles are the following:

  1. The identity must be defined such that for all elements in the stream u, combiner.apply(identity, u) is equal to u.
  2. The accumulator operator op must be associative and stateless such that (a op b) op c is equal to a op (b op c).
  3. The combiner operator must also be associative and stateless and compatible with the identity, such that for all of u and t combiner.apply(u, accumulator.apply(identity, t)) is equal to accumulator.apply(u,t) .

The book gives two examples to illustrate these principles, please see the code below:

example for associative:

        Arrays.asList(1, 2, 3, 4, 5, 6)
                .reduce(0, (a, b) -> (a - b)));

What the book says about this:

It may output -21, 3, or some other value as the accumulator function violates the associativity property.

example for the identity requirement:

        Arrays.asList("w", "o", "l", "f")
                .reduce("X", String::concat));

What the book says about this:

You can see other problems if we use an identity parameter that is not truly an identity value. It can output XwXoXlXf. As part of the parallel process, the identity is applied to multiple elements in the stream, resulting in very unexpected data.

I don't understand those examples. With the accumulator example the accumulator starts with 0 - 1 which is -1, then -1 - 2 which is -3, then -6 etc all the way to -21. I understand that, because the generated arraylist isn't synchronized the results maybe be unpredictable because of the possibility of race conditions etc, but why isn't the accumulator associative? Wouldn't (a+b) cause unpredictable results too? I really don't see what's wrong with the accumulator being used in the example and why it's not associative, but then again I still don't exactly understand what "associative principle" means.

I don't understand the identity example either. I understand that the result could indeed be XwXoXlXf if 4 separate threads were to start accumulating with the identity at the same time, but what does that have to do with the identity parameter itself? What exactly would be a proper identity to use then?

I was wondering if anyone could enlighten me a bit more on these principles.

Thank you

  • 4
    It’s all in the documentation: “Associativity An operator or function op is associative if the following holds: (a op b) op c == a op (b op c) The importance of this to parallel evaluation can be seen if we expand this to four terms: a op b op c op d == (a op b) op (c op d) So we can evaluate (a op b) in parallel with (c op d), and then invoke op on the results.” For examples of valid identity values, see here – Holger Jul 12 '17 at 14:08
  • 4
    It should be emphasized that the nature of the source List is not an issue; there is no need to have a synchronized list for a parallel stream. You must not modify the source list while the operation is ongoing, but that applies to sequential streams as well. – Holger Jul 12 '17 at 14:14

Let me give two examples. First where the identity is broken:

int result = Stream.of(1, 2, 3, 4, 5, 6)
        .reduce(10, (a, b) -> a + b);

System.out.println(result); // 81 on my run

Basically you have broken this rule: The identity value must be an identity for the accumulator function.  This means that for all u, accumulator(identity, u) is equal to u.

Or to make is simpler, let's see if that rule holds for some random data from our Stream:

 Integer identity = 10;
 BinaryOperator<Integer> combiner = (x, y) -> x + y;
 boolean identityRespected = combiner.apply(identity, 1) == 1;
 System.out.println(identityRespected); // prints false

And a second example:

 * count letters, adding a bit more all the time
private static int howMany(List<String> tokens) {
    return tokens.stream()
            .reduce(0, // identity
                    (i, s) -> { // accumulator
                        return s.length() + i;
                    }, (left, right) -> { // combiner
                        return left + right + left; // notice the extra left here

And you invoke this with:

List<String> left = Arrays.asList("aa", "bbb", "cccc", "ddddd", "eeeeee");
List<String> right = Arrays.asList("aa", "bbb", "cccc", "ddddd", "eeeeee", "");

System.out.println(howMany(left));  // 38 on my run
System.out.println(howMany(right)); // 50 on my run

Basically you have broken this rule: Additionally, the combiner function must be compatible with the accumulator function or in code :

// this must hold!
// combiner.apply(u, accumulator.apply(identity, t)) == accumulator.apply(u, t)

Integer identity = 0;
String t = "aa";
Integer u = 3; // "bbb"
BiFunction<Integer, String, Integer> accumulator = (Integer i, String s) -> i + s.length();
BinaryOperator<Integer> combiner = (left, right) -> left + right + left;

int first = accumulator.apply(identity, t); // 2
int second = combiner.apply(u, first); // 3 + 2 + 3 = 8

Integer shouldBe8 = accumulator.apply(u, t);

System.out.println(shouldBe8 == second); // false
  • 1
    "The identity value must be an identity for the accumulator function. This means that for all u, accumulator(identity, u) is equal to u.", it's not accumulator function, it's combiner function. – Jason Law Jan 31 '20 at 9:09
  • 4
    @JasonLaw the cite is correct. It’s exactly as written in the documentation of reduce(T identity, BinaryOperator<T> accumulator), which has been used in the first example. This method doesn’t even have a combiner function. Don’t confuse with the method reduce(U identity, BiFunction<U,? super T,U> accumulator, BinaryOperator<U> combiner). – Holger Jan 31 '20 at 12:13

why isn't the accumulator associative?

It's not associative since the order of subtraction operations determines the final result.

If you run a serial Stream, you'll get the expected result of:

0 - 1 - 2 - 3 - 4 - 5 - 6 = -21

On the other hand, for parallel Streams, the work is split to multiple threads. For example, if reduce is executed in parallel on 6 threads, and then the intermediate results are combined, you can get a different result:

0 - 1   0 - 2   0 - 3      0 - 4     0 - 5    0 - 6
  -1     -2      -3         -4        -5        -6

  -1 - (-2)         -3 - (-4)          -5 - (-6)
      1                 1                  1
           1   -   1
               0            -     1


Or, to make a long example short:

(1 - 2) - 3 = -4
1 - (2 - 3) =  2

Therefore subtraction is not associative.

On the other hand, a+b doesn't cause the same problem, since addition is an associative operator (i.e. (a+b)+c == a+(b+c)).

The problem with the identity example is that when reduce is executed in parallel on multiple threads, "X" is appended to the starts of each intermediate result.

What exactly would be a proper identity to use then?

If you change the identity value to "" :

.reduce("", String::concat));

you'll get "wolf" instead of "XwXoXlXf".

  • how can we know the number of thread that steam parallel processing will create. It is a fix value of depends on the collection size – Hasnain Ali Bohra Jul 14 '17 at 12:46
  • 2
    @Hasnain I don't know. That's an implementation detail. – Eran Jul 14 '17 at 14:13
  • 1
    @HasnainAliBohra - I would actually say "we cannot know" because it is an unspecified implementation detail, and there are no APIs to find out. – Stephen C Nov 17 '18 at 0:25
  • "since addition is an associative operator" AFAIK only for integers – dreamcrash Feb 23 at 16:06

While the question has already been answered and accepted, I think it can be answered in a simpler, more practical way.

If you don't have a valid identity and an associative accumulator/combiner, the result of the reduce operation will depend on:

  1. the Stream content
  2. the number of threads processing the Stream


Let's try with an example for non-associative accumulator/combiner (basically, we reduce a list of 50 numbers in a sequence and in parallel by varying the number of threads):

System.out.println("sequential: reduce="+
    IntStream.rangeClosed(1, 50).boxed()
for (int n=1; n<6; n++) {
    ForkJoinPool pool = new ForkJoinPool(n);
    final int finalN = n;
    try {
            System.out.println(finalN+" threads : reduce="+
                IntStream.rangeClosed(1, 50).boxed()
        } catch (InterruptedException | ExecutionException e) {
        } finally {

This displays the following results (Oracle JDK 10.0.1) :

sequential: reduce=-1275
1 threads : reduce=325
2 threads : reduce=-175
3 threads : reduce=-25
4 threads : reduce=75
5 threads : reduce=-25

This shows that the result depends on the number of threads involved in the reduce calculation.


  • Interestingly, sequential reduce and parallel reduce for one thread do not lead to the same result. I could not find a good explanation.
  • From my experiments, the same Stream content and the same number of threads always leads to the same reduced value when ran several times. I suppose this is because the parallel stream uses a deterministic Spliterator.
  • I would not use Boyarsky&Selikoff OCP8 book example because the stream is too small (1,2,3,4,5,6) and produces (on my machine) the same reduce value of 3 for a ForkJoinPool of 1,2,3,4 or 5 threads.
  • the default number of threads for a parallel stream is the number of availables CPU cores. This is why you may not have the same reduce result on every machine.


For identity, as Eran wrote with the "XwXoXlXf" example, with 4 threads, each thread will start by using the identity as a kind of String prefix. But pay attention : while the OCP book suggests that "" and 0 are valid identity, it depends on the accumulator/combiner functions. For example:

  • 0 is a valid identity for accumulator (a,b)->a+b (because a+0=a)
  • 1 is a valid identity for accumulator (a,b)->a*b (because a*1=a, but 0 is not valid because a*0=0!)

Reduction of a sequential stream looks as follows: sequentially applying a reduction function to each pair of elements of a stream, expecting to receive at each step an element of a same type as other elements of the stream. At next step applying the same function again, and so on.

a   b   c   d   e
│   │   │   │   │
└─┬─┘   │   │   │
 a+b    │   │   │   a+b=sum1
  │     │   │   │
  └──┬──┘   │   │
  sum1+c    │   │   sum1+c=sum2
     │      │   │
     └──┬───┘   │
     sum2+d     │   sum2+d=sum3
        │       │
        sum3+e      sum3+e=total;

Reduction of a parallel stream has the same expectancy, but gives no guarantee which pair of elements (or their sums from previous steps) should be captured at next step. Thus, the result may vary.

a   b   c   d   e
│   │   │   │   │
└─┬─┘   └─┬─┘   │
 a+b     c+d    │   a+b=sum1   c+d=sum2

    │   │   │   │
    └─┬─┘   └─┬─┘
     b+c     d+e    b+c=sum1   d+e=sum2

  │       │     │
  └───┬───┘     │
  sum1+sum2     │   sum..+sum..=sum..


│     │   │     │
└──┬──┘   └──┬──┘
 a+sum1    sum2+e   sum..+sum..=sum..

See also: Generate all possible string combinations by replacing the hidden “#” number sign

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