There are large number of texts on data structures, and libraries of data structures code. I understand that purely functional data structure is easier to reason about. However I have trouble to understand the real world advantage of using purely functional data structure in pragmatic code (using functional programming language or not) over the imperative counterpart. Can somebody provide some real world cases where purely functional data structure has advantage and why?

Examples along the line like I use data_structure_name in programming_language to do application because it can do certain_thing.


PS: What I mean by purely functional data structure is not the same as persistent data structure. Persistent data structure is a data structure that doesn't change?? On other hand purely functional data structure is a data structure that operates purely.

  • Take note that a singly linked lists as implemented by F# is a purely functional data structures: en.wikipedia.org/wiki/Purely_functional Dec 9, 2010 at 15:48
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    What do you mean by "purely" such that it differs from immutable? Dec 9, 2010 at 16:34
  • Immutability is a characteristic of purely functional data structures. period. I don't believe they are 'easier to reason about', but USING them is easier to reason about.
    – nlucaroni
    Dec 9, 2010 at 18:37
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    This statement: “purely functional data structure is a data structure that operates purely” it's circular. If you'd described it as a “data structure that functionally operates purely” you'd have had a purely circular definition. :-) Dec 9, 2010 at 19:45

5 Answers 5


Purely functional (aka persistent or immutable) data structures give you several advantages:

  • you never have to lock them, which extremely improves concurrency.
  • they can share structure, which reduces memory usage. For example, consider list [1, 2, 3, 4] in Haskell and some imperative language like Java. To produce new list in Haskell you only have to create new cons (pair of value and reference-to-next-element) and connect it to the previous list. In Java you have to create completely new list not to damage the previous one.
  • you can make persistent data structures lazy.
  • also, if you use functional style, you can avoid thinking of time and sequence of operations, and so, make your programs more declarative.
  • fact, that the data structure is immutable, allows you to make some more assumptions and so expand capabilities of language. For example, Clojure uses the fact of immutability to correctly provide implementations of hashCode() method on each object, so any object may be used as a key in a map.
  • with immutable data and functional style you can also freely use memoization.

There's much more advantages, in general, it is another way of modeling the real world. This and some other chapters from SICP will give you more accurate view of programming with immutable structures, its advantages and disadvantages.

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    amazon.com/Purely-Functional-Structures-Chris-Okasaki/dp/… would also (obviously) be a good reading on this topic.
    – rks
    Dec 9, 2010 at 16:16
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    @rks: And see What's new in purely functional data structures since Okasaki? for complements to this great, but now a little dated, book. Dec 9, 2010 at 19:49
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    @Carl I find you extremely optimistic regarding the effects of lock-free concurrent accesses to shared memory. I am sure I could distinguish between a coherent (evaluated or unevaluated) expression on the one hand and shared memory transitioning without locking from one to the other on the other hand. Dec 9, 2010 at 22:46
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    If you think that lock-free shared memory "just work", take a look at cl.cam.ac.uk/~pes20/weakmemory Dec 9, 2010 at 22:48
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    @Pascal Cuoq: GHC exists. Go ahead and find an incoherency issue in concurrent evaluation of a thunk. I'm sure Simon Marlow would be concerned if you found a real bug. But I just don't see it happening. There have been many very careful choices made in runtime representations to ensure coherency so long as your actions are pure. (If you do something inside the thunk in terms of unsafePerformIO, all bets are off.)
    – Carl
    Dec 9, 2010 at 23:44

In addition to shared memory safety most purely function data structures also give you persistence, and practically for free. For example, let's say I have a set in OCaml, and I want to add some new values to it I can do this:

module CharSet = Set.Make(Char)
let a = List.fold_right CharSet.add ['a';'b';'c';'d'] CharSet.empty in
let b = List.fold_right CharSet.add ['e';'f';'g';'h'] a in

a remains unmodified after adding the new characters (it only contains a-d), while b contains a-h, and they share some of the same memory (with a set it's kind of tricky to tell how much memory is shared since it's an AVL tree and the shape of the tree changes). I can continue doing this, keeping track of all the changes I've made to the tree allowing me to go back to a previous state.

Here's a great diagram from the Wikipedia article on Purely Functional that shows the results of insert the character 'e' into the binary tree xs:

alt text


Erlang programs use purely functional data structures almost exclusively, and they reap substantial benefits by scaling almost seamlessly to multiple cores. Because shared data (mainly binaries and bit strings) is never modified, there is never a need to lock such data.

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    Erlang scales from poor absolute performance on one core to poor absolute performance on n cores.
    – J D
    Dec 25, 2010 at 12:19
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    @Jon: Firstly, your comment is a sweeping generalisation; Erlang performs very well in messaging applications, where the predominant workload is communication. Secondly, your comment misses the point. Yes, Erlang is a slow language, but it still benefits from using immutable data types. Dec 25, 2010 at 22:53
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    "Erlang performs very well in messaging applications, where the predominant workload is communication". Not if your communication is between multiple cores on the same CPU, as your answer implies. This is the difference between parallel and concurrent programming. Erlang is great for concurrency but bad for parallelism. Multicore is irrelevant here: Erlangers just name drop it because it is a hot topic right now. If multicore benefits an Erlang program significantly then Erlang was the wrong tool for the job.
    – J D
    Dec 27, 2010 at 0:06

Purely functional data structures have the following advantages:

  • Persistence: old versions can be reused safe in the knowledge that they cannot have been changed.

  • Sharing: many versions of a data structure can be kept simultaneously with only modest memory requirements.

  • Thread safety: any mutation is hidden inside the lazy thunks (if any) and, therefore, handled by the language implementation.

  • Simplicity: not having to keep track of state changes makes purely functional data structures simpler to use, particularly in the context of concurrency.

  • Incrementality: purely functional data structures are composed of many tiny parts, making them ideal for incremental garbage collection leading to lower latencies.

Note that I have not listed parallelism as an advantage of purely functional data structures because I do not believe this to be the case. Efficient multicore parallelism requires predictable locality in order to leverage caches and avoid getting bottlenecked on shared access to main memory and purely functional data structures have, at best, unknown characteristics in this regard. Consequently, many programs that use purely functional data structures do not scale well when parallelized on a multicore because they spend all of their time in cache misses, contending for shared memory pathways.

What I mean by purely functional data structure is not the same as persistent data structure.

There is some confusion here. In the context of purely functional data structures, persistence is a term used to refer to the ability to refer back to previous versions of a data structure safe in the knowledge that they are still valid. This is a natural result of being purely functional and, therefore, persistence is an inherent characteristic of all purely functional data structures.

  • Also, on the topic of parallelism, immutability (if it were not for thunks) gives you data parallelism for free (modulo the bad cache behavior you mention), however can you take advantage of multicore hardware to perform task parallelism? As inter-thread communication necessarily involves mutation of a shared state, it looks to me that you need special support for this, as for IO, but then you break purity even more. I guess this is what MVar and the STM library of Concurrent Haskell do?
    – Maëlan
    Mar 27, 2021 at 12:05
  • If your thread starts with one values, sends and receives no values and returns with one value then it is effectively a function and easily made pure but, yes, in the general case it isn't pure. But the real killer is that even a "pure" thread can cause impure problems like false sharing that destroy performance. I'd say MVar and STM are more for concurrency than parallelism.
    – J D
    Apr 16, 2021 at 8:57

Take this little snippet of F#:

let numbers = [1; 2; 3; 4; 5]

You can say with 100% certainty that that is a immutable list of integers 1 through 5. You can pass around a reference to that list and never have to worry that the list may have been modified. That is enough reason for me to use it.

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