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I am a teaching assistant of a introductory programming course, and some students made this type of error:

char name[20];

which is not surprising as they are learning... What is surprising is that, besides gcc warning, the code works (at least this part). I have been trying to understand and I wrote the following code:

void foo(int *v1, int *v2) {
  if (v1 == v2)
    printf("Both pointers are the same\n");
    printf("They are not the same\n");

int main() {
  int test[50];
  foo(&test, test);
  if (&test == test)
    printf("Both pointers are the same\n");
    printf("They are not the same\n");

Compiling and executing:

$ gcc test.c -g
test.c: In function ‘main’:
test.c:12: warning: passing argument 1 of ‘foo’ from incompatible pointer type
test.c:13: warning: comparison of distinct pointer types lacks a cast
$ ./a.out 
Both pointers are the same
Both pointers are the same

Can anyone explain why they are not different?

I suspect it is because I cannot get the address of an array (as I cannot have & &x), but in this case the code should not compile.

Edit: I know that an array by itself is the same as the address of the first element, but this is not related to this problem, I think. For example:

int main() {
  int a[50];
  int * p = a;
  printf("%d %d %d\n", p == a, p == &a[0], &p[0] == a);
  printf("%d %d %d\n", p == &a, &p == a, &p == &a);


$ ./a.out 
1 1 1
1 0 0

I don't understand why the second line begins with 1.

share|improve this question
Your edit indicates that you think there is some pointer stored along with the array. But that's not the case. An array consists just of its elements. –  Johannes Schaub - litb May 24 '10 at 0:09
I knew that an array is just elements, that's why I thought it should not compile. –  dbarbosa May 24 '10 at 0:14

5 Answers 5

up vote 16 down vote accepted

In your example, the array test is a block of 50 ints. So it looks like this:

| int | int | ... | int |

When you apply the unary & operator to an array, you get the address of the array. Just like when you apply it to anything else, really. So &test is a pointer that points to that block of 50 ints:

(&test) -----------> | int | int | ... | int |

A pointer that points to an array of 50 ints has type int (*)[50] - that's the type of &test.

When you just use the name test in any place where it's not the operand of either the sizeof or unary-& operators, it is evaluated to a pointer to its first element. So the test that you pass to foo() evaluates to a pointer to the test[0] element:

(test) -----------------\
(&test) -----------> | int | int | ... | int |

You can see that these both are pointing to the same address - although &test is pointing to the whole array, and test is pointing to the first element of the array (which only shows up in the different types that those values have).

share|improve this answer
+1; sometimes a picture is worth 1,000 words :-) –  James McNellis May 24 '10 at 0:13
I like the ascii art :) Now with that pic, it's easy to explain why adding 1 to &test moves beyond the array, and adding 1 to test moves only beyond the first element. –  Johannes Schaub - litb May 24 '10 at 0:16
After that I had to change the "accepted answer"! –  dbarbosa May 24 '10 at 0:27

Actually, they are different, they don't have the same type at least.

But in C, the address of the array is the same as the address of the first element in the array that's why "they are not different", basically, they point to the same thing.

share|improve this answer
"the address of the array is the same as the address of the first element in the array" I always knew that the array by itself (and not the address of the array) is the same as the address of the first element, i.e., test is exactly the same as &test[0]. I have just checked in K&R, and that's what is written there... I will edit my question to add this. –  dbarbosa May 23 '10 at 23:38
@WhirlWind: No, it's not system-dependent. Applying the address-of operator to an array has well-defined semantics - it must produce the address of the array itself. The array is defined as a consecutive sequence of objects of the base type, and thus the address of the array and the address of the first object are the same place (but with different types). –  caf May 24 '10 at 0:01

The name of an array, in most circumstances, evaluates to the address of its initial element. The two exceptions are when it is the operand of sizeof or the unary &.

The unary & gives the address of its argument. The address of an array is the same as the address of its initial element, so (void*)&array == (void*)array will always be true.

array, when converted to a pointer to its initial element, has the type T *. The type of &array is T (*)[n], where n is the number of elements in the array. Thus,

int* p = array;        // Works; p is a pointer to array[0]
int* q = &array;       // Doesn't work; &array has type int (*)[10]
int (*r)[10] = &array; // Works; r is a pointer to array
share|improve this answer
Thank you, I only knew the exception of sizeof. –  dbarbosa May 24 '10 at 0:19

If You define an array like

char name[20];

name is implicitly convertible to char*, but &name is of the type char (*)[20] (a pointer to an array of 20 characters). The addresses are the same.

Check the address of (&name + 1). It differs form &name by the sizeof(char [20]).

share|improve this answer
Thanks, you made it easier to understand James McNellis answer. –  dbarbosa May 24 '10 at 0:22
The pleasure is all mine :) –  Maciej Hehl May 24 '10 at 0:32

I believe this is a gcc optimization. Think about it.

  • &test points to the address of test
  • test points to the first element of test or &test[0]
  • [0] is the same(for the most part) as *

So according to this &test could be different than test but gcc optimizes this away because there is no purpose of having an extra level of indirection at that point.

share|improve this answer
It's not a gcc optimisation - it is behaviour that is required by the C standard. –  caf May 24 '10 at 0:01
It seems like @Earlz is mistaken the meaning of &test exactly as I was. –  dbarbosa May 24 '10 at 0:43
@dba wow I was. The accepted answer for this completely clears it up –  Earlz May 24 '10 at 0:45

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