Dismiss
Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

Sign up and start helping → Learn more about Documentation →

I know that an array decays to a pointer, such that if one declared

char things[8];

and then later on used things somewhere else, things is a pointer to the first element in the array.

Also, from my understanding, if one declares

char moreThings[8][8];

then moreThings is not of type pointer to char but of type "array of pointers to char," because the decay only occurs once.

When moreThings is passed to a function (say with prototype void doThings(char thingsGoHere[8][8]) what is actually going on with the stack?

If moreThings is not of pointer type, then is this really still a pass-by-reference? I guess I always thought that moreThings still represented the base address of the multidimensional array. What if doThings took input thingsGoHere and itself passed it to another function?

Is the rule pretty much that unless one specifies an array input as const then the array will always be modifiable?

I know that the type checking stuff only happens at compile time, but I'm still confused about what technically counts as a pass by reference (i.e. is it only when arguments of type pointer are passed, or would array of pointers be a pass-by-reference as well?)

Sorry to be a little all over the place with this question, but because of my difficulty in understanding this it is hard to articulate a precise inquiry.

share|improve this question
up vote 20 down vote accepted

You got it slightly wrong: moreThings also decays to a pointer to the first element, but since it is an array of an array of chars, the first element is an "array of 8 chars". So the decayed pointer is of this type:

char (*p)[8] = moreThings;

The value of the pointer is of course the same as the value of &moreThings[0][0], i.e. of the first element of the first element, and also the same of &a, but the type is a different one in each case.

Here's an example if char a[N][3]:

+===========================+===========================+====
|+--------+--------+-------+|+--------+--------+-------+|
|| a[0,0] | a[0,1] | a[0,2]||| a[1,0] | a[1,1] | a[1,2]|| ...
|+--------+--------+-------+++--------+--------+-------++ ...
|            a[0]           |            a[1]           |
+===========================+===========================+====
                                    a
^^^
||+-- &a[0,0]
|+-----&a[0]
+-------&a
  • &a: address of the entire array of arrays of chars, which is a char[N][3]

  • &a[0], same as a: address of the first element, which is itself a char[3]

  • &a[0][0]: address of the first element of the first element, which is a char

This demonstrates that different objects may have the same address, but if two objects have the same address and the same type, then they are the same object.

share|improve this answer
4  
+1: Nice "drawing"! – Alexey Frunze Oct 1 '12 at 13:40
    
That explains it perfectly, thanks very much! – llakais Oct 1 '12 at 13:49

"ARRAY ADDRESS AND POINTERS TO MULTIDIMENSIONAL ARRAYS"

Lets we start with 1-D array first:

  • Declaration char a[8]; creates an array of 8 elements.
    And here a is address of fist element but not address of array.

  • char* ptr = a; is correct expression as ptr is pointer to char and can address first element.

  • But the expression ptr = &a is wrong! Because ptr can't address an array.

  • &a means address of array. Really Value of a and &a are same but semantically both are different, One is address of char other is address of array of 8 chars.

  • char (*ptr2)[8]; Here ptr2 is pointer to an array of 8 chars, And this time ptr2=&a is a valid expression.

  • Data-type of &a is char(*)[8] and type of a is char[8] that simply decays into char* in most operation e.g. char* ptr = a;

    To understand better read: Difference between char *str and char str[] and how both stores in memory?

Second case,

  • Declaration char aa[8][8]; creates a 2-D array of 8x8 size.

  • Any 2-D array can also be viewed as 1-D array in which each array element is a 1-D array.

  • aa is address of first element that is an array of 8 chars. Expression ptr2 = aa is valid and correct.

  • If we declare as follows:

    char (*ptr3)[8][8];    
    char ptr3 = &aa;  //is a correct expression
    

    Similarly,
    moreThings in your declaration char moreThings[8][8]; contain address of fist element that is char array of 8 elements.

    To understand better read: Difference between char* str[] and char str[][] and how both stores in memory?


It would be interesting to know:

  • morething is an address of 8 char array .

  • *morething is an address of first element that is &morething[0][0].

  • &morething is an address of 2-D array of 8 x 8.

    And address values of all above three are same but semantically all different.

  • **morething is value of first element that is morething[0][0].

    To understand better read: Difference between &str and str, when str is declared as char str[10]?

Further more,

  • void doThings(char thingsGoHere[8][8]) is nothing but void doThings(char (*thingsGoHere)[8]) and thus accepts any array that is two dimensional with the second dimension being 8.

About type of variables in C and C++: (I would like to add in answer)

  • Nothing is pass by reference in C its C++ concept. If its used in C that means author talking about pointer variable.
  • C supports pass by Address and pass by value.
  • C++ supports Pass by address, pass by value and also pass by Reference.

    Read: pointer variables and reference variables

At the end,

  • Name Of an array is constant identifier not variable.
share|improve this answer
    
void doThings(char thingsGoHere[8][8]) is nothing but void doThings(char (*thingsGoHere)[8]) and thus accepts any array that is two dimensional with the second dimension being 8 and thus "accepts exactly a char 2-D array of size 8*8" is incorrect. – legends2k Aug 23 '13 at 15:33
1  
@legends2k You are correct, you might edit, now I have corrected with some further references-Thanks Very much to correct me! – Grijesh Chauhan Aug 23 '13 at 19:05
    
It's nice to see people of high reputation appriciate corrections, many simply correct the answer and ignore the comment. – legends2k Aug 28 '13 at 9:01
    
@legends2k Greeting!!..of-course once high reputation ∝ activity, technical skills,..but we can't compare two users on the basis reputation score. e.g. it is true that here you corrected me :).. – Grijesh Chauhan Aug 28 '13 at 12:06

Nicely explained by Kerrek,

In addition to that, we can prove it by the following example:

#include <stdio.h>

int main ()
{
 int a[10][10];

 printf (".. %p  %p\n", &a, &a+1);
 printf (".. %p  %p \n ", &a[0], &a[0]+1);
printf (".. %p   %p \n ", &a[0][0], &a[0][0] +1);
}

The Output is :

.. 0x7fff6ae2ca5c  0x7fff6ae2cbec    = 400 bytes difference
.. 0x7fff6ae2ca5c  0x7fff6ae2ca84    = 40 bytes difference
 .. 0x7fff6ae2ca5c   0x7fff6ae2ca60  = 4 bytes difference. 

&a +1 -> Moves the pointer by adding whole array size. ie: 400 bytes

&a[0] + 1 -> Moves the pointer by adding the size of column. ie: 40 bytes.

&a[0][0] +1 -> Moves the pointer by adding the size of element ie: 4 bytes.

[ int size is 4 bytes ]

Hope this helps. :)

share|improve this answer
    
Thanks, that's a great way of showing it. – llakais Oct 1 '12 at 14:34

Your Answer

 
discard

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.