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Haskell supports some basic operations for recursing through lists, like head, tail, init and last. I'm wondering, internally, how Haskell is representing its list data? If it's a singly-linked list, then init and last operations could become costly as the list grows. If it's a doubly-linked list, all four operations could be made O(1) quite easily, albeit at the expense of some memory. Either way, it's important for me to know, so I can write appropriate code. (although, the ethos of functional programming seems to be one of "ask what it does, not how it does it").

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"ask what it does, not how it does it" Not if you're concerned about writing code that is reasonably fast ;) – Niklas B. Feb 25 '13 at 10:11
Well, that's what I think :-) Hence my question. – limp_chimp Feb 25 '13 at 10:36
"If it's a doubly-linked list, all four operations could be made O(1) quite easily" actually, it's not that easy if you want to stay purely functional, so ordinary doubly-linked lists aren't used much in Haskell. Doing all off those in O (1) while remaining purely functional requires rather more sophisticated data structures – however it turns out that, by exploiting Haskell's lazyness, you can get much further with O (1) operations (or in some way amortised O (n), which is almost as good) on its singly-linked linked lists than would be possible in any procedural language. – leftaroundabout Feb 25 '13 at 19:59
up vote 26 down vote accepted

Lists are represented as ... singly linked lists. The definition is given by:

data [] a = [] | a : [a]

which you could write as:

data List a = Empty | Cons a (List a)

The memory layout is entirely defined by this.

  • Constructors are heap allocated
  • Internal polymorphic fields are pointers to other allocated nodes
  • The spine is lazy

So you end up with something like this:

enter image description here

So head is O(1) on this structure, while last or (++) is O(n)

There is no magic to data structures in Haskell - their straight-forward definition makes entirely clear what the complexity will be (modulo laziness). If you need different complexity, use a different structure (such as IntMap, Sequence, HashMap, Vector etc)...

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Thanks for the answer. I'm not sure it's necessary to emphasize how clear/obvious this answer should be - I'm a beginner to Haskell, and coming from C it's a huge change, so I'm still figuring stuff out. Anyway thanks again. – limp_chimp Feb 25 '13 at 9:38
Oh, I don't mean its "easy", just that there's no magic involved. If you simply look at the data type definition, it is all derivable. – Don Stewart Feb 25 '13 at 11:08
Two big caveats: laziness and fusion. Laziness means that, for example, in xs ++ ys you only pay the cost of the append to the extent that you traverse the result list; head (xs ++ ys) is O(1), not O(n). Fusion means that many operations incur no extra cost over that of the traversal; for example, map (*2) (xs ++ ys) costs less than the sum of the costs of map (*2) and ++, because GHC eliminates the intermediate list produced. – Luis Casillas Feb 25 '13 at 21:58

Haskell lists are singly linked, so cons, head and tail are O(1) while init and last are O(n).

If you need better performance, consider using the Seq type from Data.Sequence, which provides O(1) access to both ends of the list. Internally it uses 2-3 finger trees.

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