15

I posted this question on programmers.stackexchange earlier today. I have always assumed that int (*)[] does not decay into int ** in function parameters but I got multiple responses to my question that suggested that it does.

I have used int (*)[] heavily in my function parameters but now I have become really confused.

When I compile this function using gcc -std=c99 -pedantic -Wall

void function(int (*a)[])
{
    sizeof(*a);
}

I get this error message:

c99 -Wall -pedantic -c main.c -o main.o
main.c: In function ‘function’:
main.c:3:11: error: invalid application of ‘sizeof’ to incomplete type ‘int[]’ 
make: *** [main.o] Error 1

Which suggests that *a has the type int [] and not int *.

Can someone explain if things like int (*)[] decays into int ** in function parameters and give me some reference (from the standard documents perhaps) that proves why it is so.

  • I don't think so, but I am not sure. – Iharob Al Asimi Jan 10 '15 at 16:48
  • 9
    No. Only arrays and functions decay. Pointers don't decay. – Kerrek SB Jan 10 '15 at 16:50
  • 1
    Of course int (*)[] doesn't get adjusted. It's neither an array type nor a function type. – T.C. Jan 10 '15 at 16:51
  • 2
    @KerrekSB: This is C, not C++, maybe they differ here. g++ doesn't accept my TU from the last comment, saying the types are incompatible. FWIW, I wasn't correct in my last comment. A pointer to an incomplete type is always a complete type (in C). But nonetheless, int (*)[] and int (*)[42] are compatible in C. (Btw, the only gotcha with pointers to incomplete array types I know of is that *a[0] is invalid while **a is fine.) – mafso Jan 10 '15 at 17:25
  • 2
    @jamesqf: int (*a)[] means that a is a pointer to an array of int on the other hand int *a[] means that a is an array of pointers to int. – wefwefa3 Jan 10 '15 at 21:13
18

Only array types converted to pointer to its first element when passed to a function. a is of type pointer to an array of int, i.e, it is of pointer type and therefore no conversion.

For the prototype

void foo(int a[][10]);

compiler interpret it as

void foo(int (*a)[10]);  

that's because a[] is of array type. int a[][10] will never be converted to int **a. That said, the second para in that answer is wrong and misleading.

As a function parameter, int *a[] is equivalent to int ** this is because a is of array type .

  • Perhaps your answer got downvoted because it's the array that decays not the "array name"? However: It wasn't me! <tm G.Th.> – alk Jan 10 '15 at 17:05
  • Nitpicking: It's not "types" that decay, nor gets anything "converted" ... – alk Jan 10 '15 at 17:09
  • @alk; Decay is not mentioned anywhere in C standard. – haccks Jan 10 '15 at 17:12
  • Does the Standard really use "convert"? – alk Jan 10 '15 at 17:14
  • 1
    @alk; 6.5.2.1 Array subscripting: When used in the expression x[i][j], that array is in turn converted to a pointer to the first of the ints, so x[i][j] yields an int. At the same time, there is nothing like decay used in standard in this context. – haccks Jan 10 '15 at 17:17
7

int (*)[] is a pointer to an array of int.

In your example, *a can decay to int*. But sizeof(*a) doesn't do decaying; it is essentially sizeof(int[]) which is not valid.

a can not decay at all (it's a pointer).

  • You can force it to decay: sizeof( ( 0 , *a ) ) and get the size of an int pointer. – 2501 Jan 10 '15 at 17:01
7

N1256 §6.7.5.3/p7-8

7 A declaration of a parameter as ‘‘array of type’’ shall be adjusted to ‘‘qualified pointer to type’’, where the type qualifiers (if any) are those specified within the [ and ] of the array type derivation. If the keyword static also appears within the [ and ] of the array type derivation, then for each call to the function, the value of the corresponding actual argument shall provide access to the first element of an array with at least as many elements as specified by the size expression.

8 A declaration of a parameter as ‘‘function returning type’’ shall be adjusted to ‘‘pointer to function returning type’’, as in 6.3.2.1.

int (*)[] is "pointer to array of int". Is it "array of type"? No, it's a pointer. Is it "function returning type"? No, it's a pointer. Therefore it does not get adjusted.

2

In the case of int (*a)[], sizeof *a does not work for one reason: there is no element count for the array. Without an element count, the size cannot be calculated.

As a consequence of this, any pointer arithmetic on a will not work because it is defined in terms of the size of an object. Since the size is indeterminate for the array, you cannot use pointer arithmetic on the pointer itself. Array notation is defined in terms of pointer arithmetic, so sizeof a[0][0] (or any expression involving a[n] won't work whereas sizeof (*a)[0] will.

This effectively means you can do very little with the pointer. The only things allowed are:

  • dereferencing the pointer using the unary * operator
  • passing the pointer to another function (the type of the function parameter must be an array of arrays or a pointer to an array)
  • getting the size of the pointer (and alignment or type, if your compiler supports either or both of them)
  • assigning the pointer to a compatible type

If your compiler supports variable-length arrays (VLAs), and you know the size, you could work around the issue by simply adding a line at the start of the function body as in

void
foo (int (*a0)[], size_t m, size_t n)
{
  int (*a)[n] = a0;
  ...
}

Without VLAs, you must resort to some other measure.

It is worth noting that dynamic allocation isn't a factor with int (*)[]. An array of arrays decays to a pointer to an array (like we have here), so they are interchangeable when passing them to a function (sizeof and any _Alignof or typeof keywords are operators, not functions). This means that the array pointed to must be statically allocated: once an array decays to a pointer, no more decay occurs, so you can't say a pointer to an array (int (*)[]) is the same as a pointer to a pointer (int **). Otherwise your compiler would happily let you pass int [3][3] to a function that accepts int ** instead of wanting a parameter of the form int (*)[], int (*)[n], int [][n], or int [m][n].

Consequently, even if your compiler doesn't support VLAs, you can use the fact that a statically allocated array has all of its elements grouped together:

void foo (int (*a0)[], size_t m, size_t n)
{
  int *a = *a0;
  size_t i, j;

  for (i = 0; i < m; i++)
    {
      for (j = 0; j < n; j++)
        {
          // Do something with `a[i * n + j]`, which is `a0[i][j]`.
        }
    }
  ...
}

A dynamically allocated one-dimensional array that is used as a two-dimensional array has the same properties, so this still works. It is only when the second dimension is dynamically allocated, meaning a loop like for (i = 0; i < m; i++) a[i] = malloc (n * sizeof *a[i]); to allocate each sub-array individually, that this principle not work. This is because you have an array of pointers (int *[], or int ** after array decay), which point to the first element of an array at another location in memory, rather than an array of arrays, which keeps all of the items together.

So:

  • no, int (*p)[] and int **q cannot be used in the same way. p is a pointer to an array, which means all items are grouped together starting the address stored in p. q is a pointer to a pointer, which means the items may be scattered at different addresses that are stored in q[0], q[1], ..., q[m - 1].

  • sizeof *p doesn't work because p points to an array with an unknown number of elements. The compiler cannot calculate the size of each element, so operations on p itself are very limited.

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