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To quickly answer the question: The observed behavior is intended! There is no bug and all is happening according to the documentation. But let it be said, that this behavior should be documented and communicated better. It should be made more obvious how
forEach ignores ordering.
I'll first cover the concepts which allow the observed behavior. This provides the background for dissecting one of the examples given in the question. I will do this on a high level and then again on a very low level.
[TL;DR: Read on its own, the high level explanation will give a rough answer.]
Instead of talking about
Streams, which is the type operated on or returned by stream-related methods, let's talk about stream operations and stream pipelines. The method calls
parallel are stream operations which build a stream pipeline and - as others have noted - that pipeline is processed as a whole when the terminal operation
forEach is called.
A pipeline could be thought of as a series of operations which, one after another, are executed on the whole stream (e.g. filter all elements, map remaining elements to numbers, sum all numbers). But this is misleading! A better metaphor is that the terminal operation pulls single elements through each operation (e.g. get the next unfiltered element, map it, add it to sum, request next element). Some intermediate operations may need to traverse several (e.g.
skip) or maybe even all (e.g.
sort) elements before they can return the requested next element and this is one of the sources for state in an operation.
Each operation signals its characteristics with these
They are combined across the stream source, the intermediate operations and the terminal operation and make up the characteristics of the pipeline (as a whole), which are then used for optimizations. Similarly, whether a pipeline is executed in parallel or not is a property of the entire pipeline.
So whenever you are making assumptions regarding these characteristics, you have to look carefully at all operations building the pipeline, regardless of the order in which they are applied, and what guarantees they make. When doing so keep in mind how the terminal operation pulls each individual element through the pipeline.
Let's look at this special case:
BufferedReader fooBarReader = new BufferedReader(new StringReader("Foo\nBar"));
Regardless of whether your stream source is ordered or not (it is), by calling
forEach (instead of
forEachOrdered) you declare that order doesn't matter to you, which effectively reduces
skip from "skip the first n elements" to "skip any n elements" (because without order the former becomes meaningless).
So you give the pipeline the right to ignore order if that promises a speedup. For parallel execution it apparently thinks so, which is why you get the observed output. Hence what you observe is the intended behavior and no bug.
Note that this does not conflict with
skip being stateful! As described above, being stateful does not imply that it somehow caches the whole stream (minus the skipped elements) and everything that follows is executed on these elements. It just means that the operation has some state - namely the number of skipped elements (well, it's not actually that easy but with my limited understanding of what's going on, I'd say it's a fair simplification).
Let's look at it in more detail:
BufferedReader.lines creates the
Stream, lets call it
.skip creates a new
Stream, let's call it
- which constructs a "slice" operation (generalization of skip & limit) with
- this creates an anonymous instance of
ReferencePipeline.StatefulOp, which references
_lines as its source
.parallel sets the parallel flag for the entire pipeline as described above
.forEach actually starts the execution
So let's see how the pipeline is executed:
_skip.forEach creates a
ForEachOp (let's call it
_forEach) and hands it to
_skip.evaluate, which does two things:
sourceSpliterator to create a spliterator around the source for this pipeline stage:
_forEach.evaluateParallel which creates a
ForEachTask (because it is unordered; let's call it
_forEachTask) and invokes it
_forEachTask.compute the task splits off the first 1024 lines, creates a new task for it (let's call it
_forEachTask2), realizes there are no lines left and finishes.
- Inside the fork join pool,
_forEachTask2.compute gets called, vainly tries to split again and finally starts copying its elements into the sink (a stream-aware wrapper around the
System.out.println) by calling
- This essentially delegates the task to the the specified spliterator. This is
_sliceSpliterator which was created above! So
_sliceSpliterator.forEachRemaining is responsible for handing the non-skipped elements to the println-sink:
- it gets a chunk (in this case all) of the lines into a buffer and counts them
- it tries to request as many permits (I assume due to parallelization) via
- with two elements in the source and one to be skipped, there is only one permit which it acquires (in general let's say n)
- it lets the buffer put the first n elements (so in this case only the first) into the sink
UnorderedSliceSpliterator.OfRef.forEachRemaining is where the order is finally and truly ignored. I did not compare this to the ordered variant but this are my assumption why it is done this way:
- under parallelization shoveling the spliterator's elements into the buffer may interleave with other tasks doing the same
- this will make tracking their order extremely hard
- doing that or preventing interleaving degrades performance and is pointless if order is irrelevant
- if the order is lost, there is little else to do but to process the first n permitted elements
Any questions? ;) Sorry for going on for so long. Maybe I should leave out the details and make a blog post of it....
java.util.stream - Stream operations and pipelines:
Stream operations are divided into intermediate and terminal operations, and are combined to form stream pipelines.
java.util.stream - Stream operations and pipelines:
Traversal of the pipeline source does not begin until the terminal operation of the pipeline is executed.
 This metaphor represents my understanding of streams. The main source, beside the code, is this quote from
java.util.stream - Stream operations and pipelines (highlighting mine):
Processing streams lazily allows for significant efficiencies; in a pipeline such as the filter-map-sum example above, filtering, mapping, and summing can be fused into a single pass on the data, with minimal intermediate state. Laziness also allows avoiding examining all the data when it is not necessary; for operations such as "find the first string longer than 1000 characters", it is only necessary to examine just enough strings to find one that has the desired characteristics without examining all of the strings available from the source.
At each stage of the pipeline, a combined stream and operation flags can be calculated [... jadda, jadda, jadda about how flags are combined across source, intermediate and terminal operations ...] to produce the flags output from the pipeline. Those flags can then be used to apply optimizations.
In code you can see this in
AbstractPipeline.combinedFlags, which is set during construction (and on a few other occurrences) by combining the flag of the previous and the new operation.
java.util.stream - Parallelism (to which I can not directly link - scroll down a little):
When the terminal operation is initiated, the stream pipeline is executed sequentially or in parallel depending on the orientation of the stream on which it is invoked.
In code you can see this is in
isParallel, which set/check a boolean flag on the stream source, making it irrelevant when the setters are called while constructing a stream.
Performs an action for each element of this stream. [...] The behavior of this operation is explicitly nondeterministic.
Contrast this with java.util.stream.Stream.forEachOrdered:
Performs an action for each element of this stream, in the encounter order of the stream if the stream has a defined encounter order.
 This is also not clearly documented but my interpretation of this comment on
Stream.skip (heavily shortened by me):
[...] skip() [...] can be quite expensive on ordered parallel pipelines [...] since skip(n) is constrained to skip not just any n elements, but the first n elements in the encounter order. [...] [R]emoving the ordering constraint [...] may result in significant speedups of skip() in parallel pipelines