Sign up ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

Take these two C++ functions and example usages:

vector<int> makeVect() {
  vector<int> v = {1,2,3};
  return v;

auto v = makeVect(); //vector is moved

void addFour(vector<int> &v) {

addFour(v); //v is passed in as reference

No copying happens in either case. This is really efficient.

Here are the corresponding Haskell functions and usages:

makeVect :: (Num a) => [a]
makeVect = [1,2,3]

--Q1: is [1,2,3] copied or moved to v?
let v = makeVect

addFour :: (Num a) => [a] -> [a]
addFour xs = xs ++ [4]

--Q2: is the parameter copied or moved into the function?
--Q3: on return, is the result copied or moved out of the function?
addFour v

The questions Q1, Q2, Q3 are in the code. Does Haskell move or copy things around? Is there a way to control it? In these cases, how efficient is Haskell compared to C++?

share|improve this question
Everything in Haskell is immutable, so nothing is ever copied :-) –  Kerrek SB Dec 31 '13 at 12:13
You can't really compare two different programming languages like that. C++ might do something one (possibly optimized) way, while another language (even as closely related as C) might do it in a completely other (but possibly also optimized but optimized differently) way. –  Joachim Pileborg Dec 31 '13 at 12:15
@KerrekSB: There is no contradiction on something being immutable and copied. Strings are immutable in Java, and you can still copy them, for example. I don't know enough of the implementation of Haskell to comment on that language, but the higher level language must be compiled into low level assembly, and at that point you might get the same effect as copies. –  David Rodríguez - dribeas Dec 31 '13 at 13:56
@PedroRodrigues: thanks for the fix. In case it is not obvious I don't program in Java :) –  David Rodríguez - dribeas Dec 31 '13 at 14:38
Note that your C++ example doesn't actually involve move semantics. Even in C++03, most compilers would have used return-value optimisation here, i.e. nothing would have been returned in any way at all! The function would simply construct the vector right in place, i.e. below its own stack scope at the memory location that's later used as v by the calling function. — But such considerations seldom make sense for garbage-collected languages in general, nor Haskell in particular, because data structures never reside on the stack. –  leftaroundabout Dec 31 '13 at 15:10

4 Answers 4

up vote 12 down vote accepted

In Haskell, values are immutable. Conceptually, it makes no sense to speak of copying or moving them. How many copies of the number 5 are there in the entire world? This is a meaningless question. 5 just is. Everyone can use it freely, it's the same number 5. Same thing for [1,2,3].

If we look at code produced by a typical compiler, of course there are some copying operations going on there, but those are mostly pointers to immutable regions of memory.

share|improve this answer
Does that means that with addFour, there will be 2 objects [1,2,3] and [1,2,3,4] ? –  Jarod42 Dec 31 '13 at 13:08
@Jarod42 Yes, the original list can't be changed because it's immutable, so a copy needs to be done. –  Pedro Rodrigues Dec 31 '13 at 13:10
@PedroRodrigues, while this is true in this particular case, the reason you give is rather misleading. In particular, if you compute [0] ++ [1,2,3] (i.e., append to the left), no copying of the list [1,2,3] will happen, both lists will share representations. That case works because lists are singly linked. In general, functional data structures are usually defined and used such that copying is minimised and sharing maximised. –  Andreas Rossberg Dec 31 '13 at 13:36
@AndreasRossberg Totally agreed. –  Pedro Rodrigues Dec 31 '13 at 13:53
@DavidRodríguez-dribeas Integers have value semantics in C++ but arrays do not. That's kinda the point. If everything had value semantics C++ could just copy pointers everywhere. It wouldn't even make any sense to distinguish copying and moving for example. –  n.m. Dec 31 '13 at 15:43

Q1: There's no reason to make a copy of makeVect, since we know for sure that the list can't be changed (lists are immutable). What I would expect the compiler to do is to make v and makeVect point to the same list.

Q2: Same reasoning for Q1, there's no need to copy.

Q3: Since the list is immutable, inserting a value at the end requires making a copy. Note that no copy would be necessary, if the value was inserted at the beginning of the list. Once the new list is created, it can be returned to the caller without any need to copy.

Of course this is all implementation details; since data structures are immutable, the program behaves the same whether they are copied or shared. It's up to the compiler to decide what's best, and as far as I know there's no way to control it.

In terms of efficiency it depends. Some operations can be done without the need to copy anything (like adding an element to the beginning of the list), so their performance will be comparable to C++. However other operations need to copy a large portion of the original data structure (like changing an element in an array), and these will in effect be much slower than their C++ counterpart. That doesn't necessarily mean that there isn't an efficient solution in Haskell for some problems, it just means that C++ and Haskell are very different languages, and what works well in C++ is not necessarily the best way to do it in Haskell.

share|improve this answer

Here's a schematic showing you how you might expect values to be laid out in memory at various stages of the program.

Initially you write makeVect = [1, 2, 3]. The layout in memory is something like

                1 : 2 : 3 : []
// makeVect ----^

Now if you write x = makeVect you don't need to copy anything - you can just tell x to point to the same place as makeVect currently points.

//        x -----v
                 1 : 2 : 3 : []
// makeVect -----^

However, when you write addFour x you need a list which has 4 as its final element. The only list you have at the moment has 3 as its final element, so you need a new list

//         x ----v
                 1 : 2 : 3 : []
//  makeVect ----^
// addFour x ----v
                 1 : 2 : 3 : 4 : []

If instead of appending 4 to the list, you had prepended 0, you wouldn't need to make a new list. You can add one extra memory location with its own pointer, so the memory layout is something like

//        x -------v
               0 : 1 : 2 : 3 : []
// addZero x --^   ^--- makeVect

Note that these "memory layouts" are only schematic, and are not meant to represent real memory locations. That will depend on the compiler, and the level of optimization. This is just an aid to understanding, and a method of showing you how it might be done.

share|improve this answer

This isn't a full answer, just a small caveat regarding types. If you have a monomorphic (no type variables) top-level value in Haskell, it will almost certainly only be evaluated once:

makeVect :: [Int]
makeVect = [1,2,3]

main = do
  print makeVect
  print makeVect

But, the example you gave is polymorphic. That means you could ask for two different versions of it with different types, which makes it more like a function that can be evaluated multiple times:

makeVect :: (Num a) => [a]
makeVect = [1,2,3]

main = do
  print (makeVect :: [Int])
  print (makeVect :: [Double])

In this version, the two makeVects can't possibly refer to the same value in memory because they are of different types.

(The much-disliked monomorphism restriction was put in place precisely because this behavior, where polymorphic values can be computed multiple times, was deemed potentially confusing.)

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.