134

The following code does not compile.

int a = 1, b = 2, c = 3;
int& arr[] = {a,b,c,8};

What does the C++ standard say about this?

I know I could declare a class that contains a reference, then create an array of that class, as shown below. But I really want to know why the code above doesn't compile.

struct cintref
{
    cintref(const int & ref) : ref(ref) {}
    operator const int &() { return ref; }
private:
    const int & ref;
    void operator=(const cintref &);
};

int main() 
{
  int a=1,b=2,c=3;
  //typedef const int &  cintref;
  cintref arr[] = {a,b,c,8};
}

It is possible to use struct cintref instead of const int & to simulate an array of references.

  • 1
    Even if the array was valid, storing a raw '8' value in it wouldn't work. If you did "intlink value = 8;", it would die horribly, because it's pretty much just translated into "const int & value = 8;". A reference must reference a variable. – Grant Peters Jul 22 '09 at 11:00
  • 3
    intlink value = 8; does work. check if you does not believe. – Alexey Malistov Jul 22 '09 at 11:10
  • 7
    As Alexey points out, it is perfectly valid to bind an rvalue to a const reference. – avakar Jul 22 '09 at 11:57
  • 1
    What doesn't work is that operator=. References cannot be reseated. If you really want such semantics - though I've not personally found a situation in which they're practically useful - then std::reference_wrapper would be the way to do it, as it actually stores a pointer but provides reference-like operators and does allow reseating. But then I'd just use a pointer! – underscore_d Jul 22 '16 at 10:36
  • 1
    The operator= is private and not implemented, aka what in C++11 is =delete. – Jimmy Hartzell Dec 21 '16 at 21:34

14 Answers 14

138

Answering to your question about standard I can cite the C++ Standard §8.3.2/4:

There shall be no references to references, no arrays of references, and no pointers to references.

  • 26
    What more is there to say? – polyglot Jul 22 '09 at 11:13
  • 9
    there should be arrays of references for the same reason we have arrays of pointers, same information but different handling, no? – neu-rah Aug 12 '14 at 3:16
  • 6
    If compiler developers did decide, as an extension, to allow arrays of references, then would it be a success? Or are there some real problems - perhaps ambiguous code - that would just make it too darn confusing to define this extension? – Aaron McDaid Jan 31 '15 at 18:24
  • 17
    @AaronMcDaid I think the real reason - which is so conspicuously absent from this & similar discussions - is that if one had an array of references, how would one possibly disambiguate between the address of an element & the address of its referent? The immediate objection to 'You can't put a reference in an array/container/whatever' is that you can put a struct whose sole member is a reference. But then, by doing so, you've now got both a reference & a parent object to name... which now means you can unambiguously state which address you want. Seems obvious... so why has no one said it? – underscore_d Jul 22 '16 at 6:52
  • 81
    @polyglot What more is there to say? A rationale for why? I'm all about the Standard, but just citing it and assuming that's the end of the discussion seems like a sure-fire way to destroy users' critical thought - along with any potential for the language to evolve, e.g. beyond limitations of omission or artificial restriction. There's too much 'because the Standard says' here - and not enough 'and it is very sensible to say that, due to the following practical reasons'. I don't know why upvotes flow so eagerly to answers that only say the former without even trying to explore the latter. – underscore_d Jul 22 '16 at 7:13
61

References are not objects. They don't have storage of their own, they just reference existing objects. For this reason it doesn't make sense to have arrays of references.

If you want a light-weight object that references another object then you can use a pointer. You will only be able to use a struct with a reference member as objects in arrays if you provide explicit initialization for all the reference members for all struct instances. References cannot be default initalized.

Edit: As jia3ep notes, in the standard section on declarations there is an explicit prohibition on arrays of references.

  • 6
    References are same in their nature as constant pointers, and therefore they take up some memory (storage) to point to something. – inazaruk Jul 22 '09 at 10:14
  • 6
    Not necesserily. The compiler might be able to avoid storing the address, if it's a reference to local object for instance. – EFraim Jul 22 '09 at 10:15
  • 4
    Not necessarily. References in structures usually take up some storage. Local references often don't. Either way, in the strict standard sense, references are not objects and (this was new to me) named references aren't actually variables. – CB Bailey Jul 22 '09 at 10:17
  • 25
    Yes, but this is an implementation detail. An object in the C++ model is a typed region of storage. A reference is explicitly not an object and there is no guarantee that it takes up storage in any particular context. – CB Bailey Jul 22 '09 at 10:19
  • 8
    Put it this way: you can have a struct of nothing but 16 refs to foo's, and use it in exactly the same way as I'd want to use my array of refs - except that you can't index into the 16 foo references. This is a language wart IMHO. – greggo Nov 10 '11 at 23:48
28

This is an interesting discussion. Clearly arrays of refs are outright illegal, but IMHO the reason why is not so simple as saying 'they are not objects' or 'they have no size'. I'd point out that arrays themselves are not full-fledged objects in C/C++ - if you object to that, try instantiating some stl template classes using an array as a 'class' template parameter, and see what happens. You can't return them, assign them, pass them as parameters. ( an array param is treated as a pointer). But it is legal to make arrays of arrays. References do have a size that the compiler can and must calculate - you can't sizeof() a reference, but you can make a struct containing nothing but references. It will have a size sufficient to contain all the pointers which implement the references. You can't instantiate such a struct without initializing all the members:

struct mys {
 int & a;
 int & b;
 int & c;
};
...
int ivar1, ivar2, arr[200];
mys my_refs = { ivar1, ivar2, arr[12] };

my_refs.a += 3  ;  // add 3 to ivar1

In fact you can add this line to the struct definition

struct mys {
 ...
 int & operator[]( int i ) { return i==0?a : i==1? b : c; }
};

...and now I have something which looks a LOT like an array of refs:

int ivar1, ivar2, arr[200];
mys my_refs = { ivar1, ivar2, arr[12] };

my_refs[1] = my_refs[2]  ;  // copy arr[12] to ivar2
&my_refs[0];               // gives &my_refs.a == &ivar1

Now, this is not a real array, it's an operator overload; it won't do things that arrays normally do like sizeof(arr)/sizeof(arr[0]), for instance. But it does exactly what I want an array of references to do, with perfectly legal C++. Except (a) it's a pain to set up for more than 3 or 4 elements, and (b) it's doing a calculation using a bunch of ?: which could be done using indexing (not with normal C-pointer-calculation-semantics indexing, but indexing nonetheless). I'd like to see a very limited 'array of reference' type which can actually do this. I.e. an array of references would not be treated as a general array of things which are references, but rather it would be a new 'array-of-reference' thing which effectively maps to an internally generated class similar to the one above (but which you unfortunately can't make with templates).

this would probably work, if you don't mind this kind of nasty: recast '*this' as an array of int *'s and return a reference made from one: (not recommended, but it shows how the proper 'array' would work):

 int & operator[]( int i ) { return *(reinterpret_cast<int**>(this)[i]); }
  • You can do this in C++11 std::tuple<int&,int&,int&> abcref = std::tie( a,b,c) - which creates an "array" of references that can only be indexed by compile-time constants using std::get. But you can't do std::array<int&,3> abcrefarr = std::tie( a,b,c). Maybe there's a way to do it that I don't know of. It seems to me that there should be a way to write a specialization of std::array<T&,N> which can do this - and thus a function std::tiearray(...) which returns one such (or allow std::array<T&,N> to accept initializer containing addresses = {&v1, &v2 etc}) – greggo Sep 12 '14 at 22:26
  • Your proposal is silly (IMO), and your last line assumes an int can hold a pointer (usually false, at least where I work). But this is the only answer here with a legitimate rationale for why arrays of references are forbidden, so +1 – Nemo Apr 19 '17 at 22:46
  • @Nemo it wasn't really intended as a proposal, but just to illustrate that the functionality of such a thing is not absurd on its face. I note in my last comment that c++ has things which come close. Also, the last line you refer to assumes that memory implementing a reference to an int can be usefully aliased as a pointer-to-int -- the struct contains references, not ints -- and that tends to be true. I'm not claiming it's portable (or even safe from 'undefined behaviour' rules). it was meant to illustrate how indexing could be used under-the-hood to avoid all the ?: – greggo Apr 21 '17 at 17:57
  • Fair enough. But I do think this idea is "absurd on its face", and this is precisely why arrays of references are disallowed. An array is, first and foremost, a container. All containers need an iterator type for standard algorithms to apply. The iterator type for "array of T" is normally "T *". What would be the iterator type for an array of references? The amount of language hacking it would take to deal with all of these issues is ridiculous for an essentially useless feature. Actually maybe I will make this an answer of my own :-) – Nemo Apr 21 '17 at 21:40
  • @Nemo It doesn't need to be part of the core language, so the iterator type being 'custom' is no big deal. All the various container types have their iterator types. In this case the iterator, dereferenced, would reference the target objs, not the refs in the array, which is fully consistent with the array's behaviour. It may still require a bit of new C++ behaviour to support as a template The very simple std::array<T,N>, easily defined in app code, wasn't added to std:: until c++11, presumably because it's warty to have this with no way to do = {1,2,3}; Was that 'language hacking'? – greggo Apr 24 '17 at 14:31
27

Comment to your edit:

Better solution is std::reference_wrapper.

Details: http://www.cplusplus.com/reference/functional/reference_wrapper/

Example:

#include <iostream>
#include <functional>
using namespace std;

int main() {
    int a=1,b=2,c=3,d=4;
    using intlink = std::reference_wrapper<int>;
    intlink arr[] = {a,b,c,d};
    return 0;
}
  • Hi this was stated back in 09. Tip look for newer posts :) – Stígandr Sep 20 '14 at 22:05
  • 9
    The post is old but not everyone know about solution with reference_wrapper. People need read move about STL and STDlib of C++11. – Youw Nov 22 '14 at 20:31
  • This gives a link and sample code, rather than just mentioning the name of the class reference_wrapper. – David Stone Nov 28 '14 at 14:29
12

An array is implicitly convertable to a pointer, and pointer-to-reference is illegal in C++

  • 10
    It is true you cannot have a pointer to a reference, but this is not the reason that you cannot have an array of references. Rather they are both symptoms of the fact that references are not objects. – Richard Corden Jul 22 '09 at 10:17
  • 1
    A struct can contain nothing but references, and it will have a size proportional to the number of them. If you did have an array of refs 'arr', the normal array-to-pointer conversion would not make sense, since 'pointer-to-reference' doesn't make sense. but it would make sense to just use arr[i] , in the same way as st.ref when 'st' is a struct containing a ref. Hmm. But &arr[0] would give the address of the first referenced object, and &arr[1]- &arr[0] would not be the same as &arr[2]-&arr[1] - it would create a lot of strangeness. – greggo Nov 10 '11 at 23:56
10

Because like many have said here, references are not objects. they are simply aliases. True some compilers might implement them as pointers, but the standard does not force/specify that. And because references are not objects, you cannot point to them. Storing elements in an array means there is some kind of index address (i.e., pointing to elements at a certain index); and that is why you cannot have arrays of references, because you cannot point to them.

Use boost::reference_wrapper, or boost::tuple instead; or just pointers.

9

Given int& arr[] = {a,b,c,8};, what is sizeof(*arr) ?

Everywhere else, a reference is treated as being simply the thing itself, so sizeof(*arr) should simply be sizeof(int). But this would make array pointer arithmetic on this array wrong (assuming that references are not the same widths is ints). To eliminate the ambiguity, it's forbidden.

  • Yep. You can't have an array of something unless it has a size. What is the size of a reference? – David Schwartz Nov 22 '15 at 2:19
  • 4
    @DavidSchwartz Make a struct whose only member is that reference and find out..? – underscore_d Jan 27 '16 at 16:29
  • 2
    This should be the accepted answer, not the stupid pedantic one that simply throws the standard at the OP. – Tyson Jacobs Apr 4 '17 at 23:16
  • Maybe there is a typo. "assuming that references are not the same widths is ints" should be "assuming that references are not the same widths as ints". Change is to as. – zhenguoli Jul 20 '17 at 13:23
  • But wait, by this logic you couldn't have reference member variables. – Tyson Jacobs Apr 3 '18 at 18:11
4

You can get fairly close with this template struct. However, you need to initialize with expressions that are pointers to T, rather than T; and so, though you can easily make a 'fake_constref_array' similarly, you won't be able to bind that to rvalues as done in the OP's example ('8');

#include <stdio.h>

template<class T, int N> 
struct fake_ref_array {
   T * ptrs[N];
  T & operator [] ( int i ){ return *ptrs[i]; }
};

int A,B,X[3];

void func( int j, int k)
{
  fake_ref_array<int,3> refarr = { &A, &B, &X[1] };
  refarr[j] = k;  // :-) 
   // You could probably make the following work using an overload of + that returns
   // a proxy that overloads *. Still not a real array though, so it would just be
   // stunt programming at that point.
   // *(refarr + j) = k  
}

int
main()
{
    func(1,7);  //B = 7
    func(2,8);     // X[1] = 8
    printf("A=%d B=%d X = {%d,%d,%d}\n", A,B,X[0],X[1],X[2]);
        return 0;
}

--> A=0 B=7 X = {0,8,0}

4

I believe the answer is very simple and it has to do with semantic rules of references and how arrays are handled in C++.

In short: References can be thought of as structs which don't have a default constructor, so all the same rules apply.

1) Semantically, references don't have a default value. References can only be created by referencing something. References don't have a value to represent the absence of a reference.

2) When allocating an array of size X, program creates a collection of default-initialized objects. Since reference doesn't have a default value, creating such an array is semantically illegal.

This rule also applies to structs/classes which don't have a default constructor. The following code sample doesn't compile:

struct Object
{
    Object(int value) { }
};

Object objects[1]; // Error: no appropriate default constructor available
2

A reference object has no size. If you write sizeof(referenceVariable), it will give you the size of the object referenced by referenceVariable, not that of the reference itself. It has no size of its own, which is why the compiler can't calculate how much size the array would require.

  • 3
    if so how then a compiler can calculate size of a struct containing only a ref? – Juster Sep 12 '15 at 9:56
  • Compiler does know the physical size of a reference - its the same as a pointer. References are, in fact, semantically glorified pointers. The difference between pointers and references is that references have quite a few semantic rules placed on them in order to reduce the number of bugs you might create as compared with pointers. – Kristupas A. Apr 21 '18 at 10:32
2

When you store something in an array , its size needs to be known (since array indexing relies on the size). Per the C++ standard It is unspecified whether or not a reference requires storage, as a result indexing an array of references would not be possible.

  • 1
    But by putting said reference in a struct, magically everything becomes specified, well-defined, guaranteed, and of deterministic size. Why, therefore, does this seemingly totally artificial difference exist? – underscore_d Jul 22 '16 at 6:28
  • ...of course, if one actually starts to think about what the wrapping struct confers, some good possible answers begin to suggest themselves - but to me, no one has done so yet, despite this being one of the immediate challenges to all the common rationales for why you can't use unwrapped refs. – underscore_d Jul 22 '16 at 6:47
2

Just to add to all the conversation. Since arrays requires consecutive memory locations to store the item, so if we create an array of references then it's not guaranteed that they will be at consecutive memory location so accessing will be a problem and hence we can't even apply all the mathematical operations on array.

  • Please add some code to your answer to clarify – toesslab Aug 29 '15 at 6:52
  • Consider the below code from the original question: int a = 1, b = 2, c = 3; int& arr[] = {a,b,c,8}; There's very less possibility that a,b,c will reside at consecutive memory location. – Amit Kumar Nov 29 '15 at 18:12
  • That is far from the main problem with the concept of holding references in a container. – underscore_d Apr 20 '17 at 8:37
0

Consider an array of pointers. A pointer is really an address; so when you initialize the array, you are analogously telling the computer, "allocate this block of memory to hold these X numbers (which are addresses of other items)." Then if you change one of the pointers, you are just changing what it points to; it is still a numerical address which is itself sitting in the same spot.

A reference is analogous to an alias. If you were to declare an array of references, you would basically be telling the computer, "allocate this amorphous blob of memory consisting of all these different items scattered around."

  • 1
    Why, then, does making a struct whose only member is a reference result in something completely legal, predictable, and non-amorphous? Why must a user wrap a reference for it to magically gain array-capable powers, or is it just an artificial restriction? IMO no answer has directly addressed this. I assume the rebuttal is 'The wrapping object ensures you can use value semantics, in the form of the wrapping object, so it ensures you can have the guarantees of values, which are needed because e.g. how would one disambiguate between element and referee address'... Is that what you meant? – underscore_d Jul 22 '16 at 6:44
-1

Actually, this is a mixture of C and C++ syntax.

You should either use pure C arrays, which cannot be of references, since reference are part of C++ only. Or you go the C++ way and use the std::vector or std::array class for your purpose.

As for the edited part: Even though the struct is an element from C, you define a constructor and operator functions, which make it a C++ class. Consequently, your struct would not compile in pure C!

  • What's your point? std::vector or std::array cannot contain references either. The C++ Standard is quite explicit that no container can. – underscore_d Jul 22 '16 at 6:31

protected by Flexo Jul 22 '16 at 7:25

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