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I was trying to write down some implementations for a couple of data structures that I'm interested in for a multithreaded / concurrent scenario.

A lot of functional languages, pretty much all that I know of, design their own data structures in such a way that they are immutable, so this means that if you are going to add value to an instance t1 of T, you really get a new instance of T that packs t1 + value.

 container t;
 container s = t; //t and s refer to the same container.
 t.add(value); //this makes a copy of t, and t is the copy

I can't find the appropriate keywords to do this in C++11; there are keywords, semantics and functions from the standard library that are clearly oriented to the functional approach, in particular I found that:

  • mutable it's not for runtime, it's more likely to be an hint for the compiler, but this keyword doesn't really help you in designing a new data structure or use a data structure in an immutable way
  • swap doesn't works on temporaries, and this is a big downside in my case

I also don't know how much the other keywords / functions can help with such design, swap was one of them really close to something good, so I could at least start to write something, but apparently it's limited to lvalues .

So I'm asking: it's possible to design immutable data structure in C++11 with a functional approach ?

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Of course it's possible. What makes you think it isn't, more specifically, what about it seems hard/impossible to you? –  delnan Mar 3 '14 at 23:30
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The best you can do is to declare instances of your data structure always with the const qualifier. The thing is that you wouldn't gain as much as when compared to a true functional language like for example Haskel. Such languages highly make use of the fact that all values are constants, and each expression only depends on itself (and no other state). This is simply not the case with C++, regardless of the design of your data structure. What you probably want is to tell the compiler that only const instances of your class are allowed, which is not possible. –  leemes Mar 3 '14 at 23:35
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It's easy to design an immutable data structure... just create a container with a data member such as one of the existing Standard library data structures, then make the mutating functions do a deep copy, mutation of the copy, then return it by value. You could use such objects from any type of code. Not particularly scalable, but all a matter of picking your poison. –  Tony D Mar 3 '14 at 23:35
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@user2485710: const std::vector<T> is our standard immutable data structure. –  Mooing Duck Mar 3 '14 at 23:35
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Start reading. –  Casey Mar 3 '14 at 23:59

3 Answers 3

You simply declare a class with private member variables and you don't provide any methods to change the value of these private members. That's it. You initialize the members only from the constructors of the class. Noone will be able to change the data of the class this way. The tool of C++ to create immutable objects is the private visibility of the members.

mutable: This is one of the biggest hacks in C++. I've seen at most 2 places in my whole life where its usage was reasonable and this keyword is pretty much the opposite of what you are searching for. If you would search for a keyword in C++ that helps you at compile time to mark data members then you are searching for the const keyword. If you mark a class member as const then you can initialize it only from the INITIALIZER LIST of constructors and you can no longer modify them throughout the lifetime of the instance. And this is not C++11, it is pure C++. There are no magic language features to provide immutability, you can do that only by programming smartly.

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I use mutable occasionally, for delay-loading a member. –  Mooing Duck Mar 3 '14 at 23:34
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mutable is nice for lazy evaluations –  Dieter Lücking Mar 3 '14 at 23:37
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@user2485710, ask a vague question with no code, get a vague answer with no code. If you want more specific advice you'll need to be more specific in your question. –  Mark Ransom Mar 3 '14 at 23:37
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I think you got an exact recipe to create an immutable class, you don't need magical C++11 keywords for that. @leemes Two reasonable examples for mutable I can recall: Intrusive refcounting for const/immutable objects, and maybe some debug counters/variables... In most cases the object probably isn't truly const or its mutable/non-const part shouldn't be an immutable member, rather another referenced object. –  pasztorpisti Mar 3 '14 at 23:43
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@user2485710: except const –  Mooing Duck Mar 4 '14 at 0:43

In c++ "immutability" is granted by the const keyword. Sure - you still can change a const variable, but you have to do it on purpose (like here). In normal cases, the compiler won't let you do that. Since your biggest concern seems to be doing it in a functional style, and you want a structure, you can define it yourself like this:

class Immutable{
   Immutable& operator=(const Immutable& b){} // This is private, so it can't be called from outside
   const int myHiddenValue;
public:
   operator const int(){return myHiddenValue;}
   Immutable(int valueGivenUponCreation): myHiddenValue(valueGivenUponCreation){}
};

If you define a class like that, even if you try to change myHiddenValue with const_cast, it won't actually do anything, since the value will be copied during the call to operator const int.

Note: there's no real reason to do this, but hey - it's your wish.

Also note: since pointers exist in C++, you still can change the value with some kind of pointer magic (get the address of the object, calc the offset, etc), but you can't really help that. You wouldn't be able to prevent that even when using an functional language, if it had pointers.

And on a side note - why are you trying to force yourself in using C++ in a functional manner? I can understand it's simpler for you, and you're used to it, but functional programming isn't often used because of its downfalls. Note that whenever you create a new object, you have to allocate space. It's slower for the end-user.

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because immutable data structures really really help you when concurrency is involved, and, the big plus is that everything happens by design so you are better suited than when you just use a bunch of mutexes or locks or trying to do fancy things. –  user2485710 Mar 4 '14 at 0:01
    
If you're not trying to change them in the first place, then what's the difference? The answer to your question is: simply write a function taking an argument of type X, and returning type X. –  Paweł Stawarz Mar 4 '14 at 0:02
    
that really it's not what immutable data structures are for, assuming you have t as an instance of T you can change t as much as you want, the magic is in the design of T. First lines from this bartoszmilewski.com/2013/11/13/… –  user2485710 Mar 4 '14 at 0:05
    
@user2485710 You're wrong. The magic is in the functions you call on T, not in T itself. There's nothing magical in functional languages. You just need functions of type const T f(const T t) that take the "old" t and return a "new", changed one, without touching the first one. That's how I was taught when learning SML. –  Paweł Stawarz Mar 4 '14 at 0:12
    
@user2485710 Maybe I just learned the wrong functional languages (predominantly scheme/clos really), but at least in every functional language I've seen you can still mutate state if you really want. Which means you can write mutable data structures in functional languages just as well if you don't take care of your operations. Anyhow immutable data structures are extremely useful in C++ too agreed - concurrency is hard enough already without mutable data structures everywhere. –  Voo Mar 4 '14 at 1:06

Re. your code example with s and t. You can do this in C++, but "immutability" has nothing to do with that question, if I understand your requirements correctly!

I have used containers in vendor libraries that do operate the way you describe; i.e. when they are copied they share their internal data, and they don't make a copy of the internal data until it's time to change one of them.

Note that in your code example, there is a requirement that if s changes then t must not change. So s has to contain some sort of flag or reference count to indicate that t is currently sharing its data, so when s has its data changed, it needs to split off a copy instead of just updating its data.

So, as a very broad outline of what your container will look like: it will consist of a handle (e.g. a pointer) to some data, plus a reference count; and your functions that update the data all need to check the refcount to decide whether to reallocate the data or not; and your copy-constructor and copy-assignment operator need to increment the refcount.

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Luckly, the complex parts are already done! std::shared_ptr –  Mooing Duck Mar 4 '14 at 0:45

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