Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

Apparently, we can pass complex class instances to functions, but why can't we pass arrays to functions?

share|improve this question
FWIW, this originated in C and as arrays (the primitive ones, not std::vector or std::array) carried over into C++ pretty much unchanged, I suspect that the reason is the same. – delnan Sep 17 '11 at 13:11
@delnan, the reason is the same? what it is the "same" reason? Please be more specific. – Alcott Sep 17 '11 at 13:31
I believe that you can do it with boost::array (or tr1::array). – nobar Sep 17 '11 at 19:43
...(or std::vector), etc. Your question is about a design decision that someone made for C about 40 years ago. The answer to your question (for C++) is "who cares". This is a non-issue for modern C++ because it is generally a good idea to avoid declaring raw arrays (and raw pointers) whenever possible. It is preferable to use a higher level array class such as one of those that I listed. – nobar Sep 17 '11 at 20:43
Because (1) Dennis Ritchie built a pointer/array equivalence deep into the C language 40+ years ago, and (2) it would be a really bad idea. – EJP Mar 26 '15 at 7:27
up vote 43 down vote accepted

The origin is historical. The problem is that the rule "arrays decay into pointers, when passed to a function" is simple.

Copying arrays would be kind of complicated and not very clear, since the behavior would change for different parameters and different function declarations.

Note that you can still do an indirect pass by value:

struct A { int arr[2]; };
void func(struct A);
share|improve this answer
wrap it in a struct is a way – Alcott Sep 17 '11 at 13:21
In C++, you can pass arrays to functions per reference. With function templates and non-type template arguments, you can even pass arbitrarily long arrays. – sbi Sep 17 '11 at 13:30
The rule that arrays expression decay into pointers is not specific to function calls. In C, the decay happens in any context other than (a) the operand of the unary & address-of operator; (b) the operand of the unary sizeof operator; or (c) a string literal in an initializer used to initialize a character array (char s[] = "hello";); I think there are one or two other exceptions in C++, probably involving references. For example, in int arr[10]; int *p; p = arr; the decay occurs, but there's not a function call in sight. – Keith Thompson Sep 17 '11 at 21:02

Here's another perspective: There isn't a single type "array" in C. Rather, T[N] is a a different type for every N. So T[1], T[2], etc., are all different types.

In C there's no function overloading, and so the only sensible thing you could have allowed would be a function that takes (or returns) a single type of array:

void foo(int a[3]);  // hypothetical

Presumably, that was just considered far less useful than the actual decision to make all arrays decay into a pointer to the first element and require the user to communicate the size by other means. After all, the above could be rewritten as:

void foo(int * a)
  static const unsigned int N = 3;
  /* ... */

So there's no loss of expressive power, but a huge gain in generality.

Note that this isn't any different in C++, but template-driven code generation allows you to write a templated function foo(T (&a)[N]), where N is deduced for you -- but this just means that you can create a whole family of distinct, different functions, one for each value of N.

As an extreme case, imagine that you would need two functions print6(const char[6]) and print12(const char[12]) to say print6("Hello") and print12("Hello World") if you didn't want to decay arrays to pointers, or otherwise you'd have to add an explicit conversion, print_p((const char*)"Hello World").

share|improve this answer
+1. Nice analysis! – Nawaz Sep 17 '11 at 14:11
It's worth noting that some other languages do permit arrays to be passed as parameters. In Ada, for example, the equivalent of int[5] and int[10] are (or at least can be) the same type; they're just different subtypes. You can define an Ada routine that takes an integer array with any arbitrary bounds as a parameter, or (for a function) that returns such an array. The price paid for this is that the compiler has to generate code to do all the necessary bookkeeping and memory management. Such implicit code is generally not considered to be "in the spirit of C" (or of C++). – Keith Thompson Sep 17 '11 at 21:07

The reason you can't pass an array by value is because there is no specific way to track an array's size such that the function invocation logic would know how much memory to allocate and what to copy. You can pass a class instance because classes have constructors. Arrays do not.

share|improve this answer
If the array is declared as a[4], then you simply know the size at compile time. – quant_dev Sep 17 '11 at 14:36
Yes, if. But the size isn't passed along with the array, they're not 'glued' together in the way that would be needed to permit arrays to be passed by value. – David Schwartz Sep 17 '11 at 14:42
@quant: in the original scope that is known, but where does the 4 go in the called function? – Dennis Zickefoose Sep 17 '11 at 14:46

You are passing by value: the value of the pointer to the array. Remember that using square bracket notation in C is simply shorthand for de-referencing a pointer. ptr[2] means *(ptr+2).

Dropping the brackets gets you a pointer to the array, which can be passed by value to a function:

int x[2] = {1, 2};
int result;
result = DoSomething(x);

See the list of types in the ANSI C spec. Arrays are not primitive types, but constructed from a combination of pointers and operators. (It won't let me put another link, but the construction is described under "Array type derivation".)

share|improve this answer
You're not passing the address of the array, you're passing the address of the array's first element (same memory location, different type). The array indexing operation is by definition a combination of pointer arithmetic and the unary * dereferencing operator, but an array itself is just an array. What makes arrays less than first-class types in C is not the array objects themselves, but the limited set of operations on them. – Keith Thompson Sep 17 '11 at 20:59
You're talking about arrays as a programming concept: data structures from the programmer's point of view. I thought the question was why C syntax for array data seems to differ from other data. If you look at it as a question of language structure, it's because arrays are not primitives. They are pointer operations which behave almost like primitives. – KonradG Sep 18 '11 at 3:30
Most operations on arrays are implemented as pointer operations. Arrays are not pointers. For example, an array object is an array object, and defining an array object does not explicitly or implicitly create any pointer object. (And I'm not at all sure I understand what distinction you're making between "data structures" and "language structure".) – Keith Thompson Sep 18 '11 at 3:32
I'm not saying that arrays are pointers. But the "array type" in C is just the array operator dressed up to act like a data type. The result is quite a convincing imitation, but it it's not perfect. :) One quirk, as you mentioned, is that the array itself has no address. – KonradG Sep 19 '11 at 22:46
@KeithThompson As to the distinction, it's the difference between asking between what goes on "under the hood" vs asking "why was it made like that". – KonradG Sep 19 '11 at 22:58

The equivalent of that would be to first make a copy of the array and then pass it to the function (which can be highly inefficient for large arrays).

Other than that I would say it's for historical reasons, i.e. one could not pass arrays by value in C.

My guess is that the reasoning behind NOT introducing passing arrays by value in C++ was that objects were thought to be moderately sized compared to arrays.

As pointed out by delnan, when using std::vector you can actually pass array-like objects to functions by value.

share|improve this answer

actually, a pointer to the array is passed by value, using that pointer inside the called function will give you the feeling that the array is passed by reference which is wrong. try changing the value in the array pointer to point to another array in your function and you will find that the original array was not affected which means that the array is not passed by reference.

share|improve this answer


  1. Passing the Address of the array's first element &a = a = &(a[0])
  2. New Pointer (new pointer, new address, 4 bytes, in the memory)
  3. Points to the same memory location, in different type.

Example 1:

void by_value(bool* arr) // pointer_value passed by value
    arr[1] = true;
    arr = NULL; // temporary pointer that points to original array

int main()
    bool a[3] = {};
    cout << a[1] << endl; // 0
    cout << a[1] << endl; // 1 !!! 


     a = 0046FB18 // **Original**
     &a = 0046FB18 // **Original**
     arr = 0046FB18 // **Original**
     &arr = 0046FA44 // TempPTR
     arr = NULL
     &arr = 0046FA44 // TempPTR

Example 2:

void by_value(bool* arr) 
    cout << &arr << arr; // &arr != arr

int main()
    bool a[3] = {};
    cout << &a << a; // &a == a == &a[0]


[main] 0046FB18 = 0046FB18
[func] 0046FA44 != 0046FB18

Please Note:

  1. &(required-lvalue): lvalue -to-> rvalue
  2. Array Decay: new pointer (temporary) points to (by value) array address



Array Decay

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.