As noted in this question, I'm using Scalaz 7 iteratees to process a large (i.e., unbounded) stream of data in constant heap space.

My code looks like this:

type ErrorOrT[M[+_], A] = EitherT[M, Throwable, A]
type ErrorOr[A] = ErrorOrT[IO, A]

def processChunk(c: Chunk, idx: Long): Result

def process(data: EnumeratorT[Chunk, ErrorOr]): IterateeT[Vector[(Chunk, Long)], ErrorOr, Vector[Result]] =
  Iteratee.fold[Vector[(Chunk, Long)], ErrorOr, Vector[Result]](Nil) { (rs, vs) =>
    rs ++ vs map { 
      case (c, i) => processChunk(c, i) 
  } &= (data.zipWithIndex mapE Iteratee.group(P))

The Problem

I seem to have run into a memory leak, but I'm not familiar enough with Scalaz/FP to know whether the bug is in Scalaz or in my code. Intuitively, I expect this code to require only (on the order of) P times the Chunk-size space.

Note: I found a similar question in which an OutOfMemoryError was encountered, but my code is not using consume.


I ran some tests to try and isolate the problem. To summarize, the leak only appears to arise when both zipWithIndex and group are used.

// no zipping/grouping
scala> (i1 &= enumArrs(1 << 25, 128)).run.unsafePerformIO
res47: Long = 4294967296

// grouping only
scala> (i2 &= (enumArrs(1 << 25, 128) mapE Iteratee.group(4))).run.unsafePerformIO
res49: Long = 4294967296

// zipping and grouping
scala> (i3 &= (enumArrs(1 << 25, 128).zipWithIndex mapE Iteratee.group(4))).run.unsafePerformIO
java.lang.OutOfMemoryError: Java heap space

// zipping only
scala> (i4 &= (enumArrs(1 << 25, 128).zipWithIndex)).run.unsafePerformIO
res51: Long = 4294967296

// no zipping/grouping, larger arrays
scala> (i1 &= enumArrs(1 << 27, 128)).run.unsafePerformIO
res53: Long = 17179869184

// zipping only, larger arrays
scala> (i4 &= (enumArrs(1 << 27, 128).zipWithIndex)).run.unsafePerformIO
res54: Long = 17179869184

Code for the tests:

import scalaz.iteratee._, scalaz.effect.IO, scalaz.std.vector._

// define an enumerator that produces a stream of new, zero-filled arrays
def enumArrs(sz: Int, n: Int) = 
  Iteratee.enumIterator[Array[Int], IO](

// define an iteratee that consumes a stream of arrays 
// and computes its length
val i1 = Iteratee.fold[Array[Int], IO, Long](0) { 
  (c, a) => c + a.length 

// define an iteratee that consumes a grouped stream of arrays 
// and computes its length
val i2 = Iteratee.fold[Vector[Array[Int]], IO, Long](0) { 
  (c, as) => c + as.map(_.length).sum 

// define an iteratee that consumes a grouped/zipped stream of arrays
// and computes its length
val i3 = Iteratee.fold[Vector[(Array[Int], Long)], IO, Long](0) {
  (c, vs) => c + vs.map(_._1.length).sum

// define an iteratee that consumes a zipped stream of arrays
// and computes its length
val i4 = Iteratee.fold[(Array[Int], Long), IO, Long](0) {
  (c, v) => c + v._1.length


  • Is the bug in my code?
  • How can I make this work in constant heap space?
  • 6
    I ended up reporting this as an issue in Scalaz. Oct 3, 2013 at 21:35
  • 1
    It won't be any fun, but you could try -XX:+HeapDumpOnOutOfMemoryError and analyzing the dump with eclipse MAT eclipse.org/mat to see what line of code is holding on to the arrays.
    – huynhjl
    Oct 9, 2013 at 6:56
  • 10
    @huynhjl FWIW, I tried analyzing the heap with both JProfiler and MAT but was completely unable to wade through all the references to anonymous function classes, etc. Scala really needs dedicated tools for this sort of thing. Oct 10, 2013 at 19:29
  • What if there is no leak and it is just that what you are doing requires a wildly increasing amount of memory? You can easily replicate the zipWithIndex without that particular FP construct by just maintaining a var counter as you go. Oct 14, 2014 at 9:40
  • @EzekielVictor I'm not sure I understand the comment. You're suggesting that adding a single Long index per chunk would change the algorithm from constant- to non-constant heap space? The non-zipping version clearly uses constant heap space, because it can "process" as many chunks as you're willing to wait for. Oct 14, 2014 at 20:50

1 Answer 1


This will come as little consolation for anyone who's stuck with the older iteratee API, but I recently verified that an equivalent test passes against the scalaz-stream API. This is a newer stream processing API that is intended to replace iteratee.

For completeness, here's the test code:

// create a stream containing `n` arrays with `sz` Ints in each one
def streamArrs(sz: Int, n: Int): Process[Task, Array[Int]] =
  (Process emit Array.fill(sz)(0)).repeat take n

(streamArrs(1 << 25, 1 << 14).zipWithIndex 
      pipe process1.chunk(4) 
      pipe process1.fold(0L) {
    (c, vs) => c + vs.map(_._1.length.toLong).sum

This should work with any value for the n parameter (provided you're willing to wait long enough) -- I tested with 2^14 32MiB arrays (i.e., a total of half a TiB of memory allocated over time).

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