Both of these interfaces define only one method

public operator fun iterator(): Iterator<T>

Documentation says Sequence is meant to be lazy. But isn't Iterable lazy too (unless backed by a Collection)?

up vote 100 down vote accepted

The key difference lies in the semantics and the implementation of the stdlib extension functions for Iterable<T> and Sequence<T>.

  • For Sequence<T>, the extension functions perform lazily where possible, similarly to Java Streams intermediate operations. For example, Sequence<T>.map { ... } returns another Sequence<R> and does not actually process the items until a terminal operation like toList or fold is called.

    Consider this code:

    val seq = sequenceOf(1, 2)
    val seqMapped: Sequence<Int> = seq.map { print("$it "); it * it } // intermediate
    print("before sum ")
    val sum = seqMapped.sum() // terminal
    

    It prints:

    before sum 1 2
    

    Sequence<T> is intended for lazy usage and efficient pipelining when you want to reduce the work done in terminal operations as much as possible, same to Java Streams. However, laziness introduces some overhead, which is undesirable for common simple transformations of smaller collections and makes them less performant.

    In general, there is no good way to determine when it is needed, so in Kotlin stdlib laziness is made explicit and extracted to the Sequence<T> interface to avoid using it on all the Iterables by default.

  • For Iterable<T>, on contrary, the extension functions with intermediate operation semantics work eagerly, process the items right away and return another Iterable. For example, Iterable<T>.map { ... } returns a List<R> with the mapping results in it.

    The equivalent code for Iterable:

    val lst = listOf(1, 2)
    val lstMapped: List<Int> = lst.map { print("$it "); it * it }
    print("before sum ")
    val sum = lstMapped.sum()
    

    This prints out:

    1 2 before sum
    

    As said above, Iterable<T> is non-lazy by default, and this solution shows itself well: in most cases it has good locality of reference thus taking advantage of CPU cache, prediction, prefetching etc. so that even multiple copying of a collection still works good enough and performs better in simple cases with small collections.

    If you need more control over the evaluation pipeline, there is an explicit conversion to a lazy sequence with Iterable<T>.asSequence() function.

  • 3
    Probably a big surprise for Java (mostly Guava) fans – Venkata Raju Feb 25 '16 at 15:27
  • @VenkataRaju for functional people they might be surprised at the alternative of lazy by default. – Jayson Minard Feb 25 '16 at 16:00
  • 7
    Lazy by default is usually less performant for smaller and more commonly used collections. A copy can be faster than a lazy eval if taking advantage of CPU cache and so on. So for common use cases is better to not be lazy. And unfortunately the common contracts for functions like map, filter and others don't carry enough information to decide other than from the source collection type, and since most collections are also Iterable, that isn't a good marker for "be lazy" because it is commonly EVERYWHERE. lazy must be explicit to be safe. – Jayson Minard Feb 25 '16 at 16:02
  • 1
    @naki One example from a recent Apache Spark announcement, they are worrying about this obviously, see "Cache-aware Computation" section at databricks.com/blog/2015/04/28/… ... but they are worried about billions of things iterating so they need to go to the full extreme. – Jayson Minard Jun 9 '16 at 14:10
  • 2
    Additionally, a common pitfall with lazy evaluation is capturing the context and storing resulting lazy computation in a field along with all the captured locals and whatever they hold. Hence, hard to debug memory leaks. – Ilya Ryzhenkov Mar 18 '17 at 1:39

Completing hotkey's answer:

It is important to notice how Sequence and Iterable iterates thought your elements:

Sequence example:

        list.asSequence()
            .filter { field ->
                Log.d("Filter", "filter")
                field.value > 0
            }.map {
                Log.d("Map", "Map")
            }.forEach {
                Log.d("Each", "Each")
            }

Log result:

filter - Map - Each; filter - Map - Each

Iterable example:

             list.filter { field ->
                    Log.d("Filter", "filter")
                    field.value > 0
                }.map {
                    Log.d("Map", "Map")
                }.forEach {
                    Log.d("Each", "Each")
                }

filter - filter - Map - Map - Each - Each

  • 2
    That's an excellent example of the difference between the two. – Alexey Soshin Feb 25 at 18:39

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