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
#include <stdio.h>
int main (){
int x=10,*a=&x;
int *b=(int *)&a;
printf("%d  %d  %d  %d  %d  %d  ",x,a,*a,b,*b,**b);
return 0;

In this little program variable x is assigned value 10 and then address of x is assigned to pointer variable a. Now proper way is int **b=&a because b should be a pointer to pointer. But I thought it's ultimately the address which gets stored. So to store address of a to an int pointer b, I use typecasting int *b=(int *)&a. Now address of a got stored in b. So if I use *b, it give identical result as a.

But when I extend this further to **b it doesn't give the same result as *a which I expected. In fact it gives an error. *b and a are same so when i ask to retrieve from this value like **b and *a this doesn't work. For this I assumed a concept that *b and a are same in value but they are different in type. The value given by a is pointer and value given by *b is an integer so **b is not possible like *a.

But I still think that it should work.

I am using Dev C++ which is a 32 bit compiler. The memory allocated to an int and int * is the same, that is 4 bytes. And *b and a have same bit representation also. So when I write *(*b) I used same value as in *(a). But what is the preventing factor? The format is like *(some bit representation) and the bit representation is identical in case of *b and a. So the value of x should be retrieved. Please explain the preventing factor.

share|improve this question
If you want b to be an int*, then you want to say int* b = a so you can access x through *b. But if you want b to be an int** then you can say int** b = &a and access x through **b. Draw a picture :) – Ray Toal Aug 28 '11 at 7:11
up vote 1 down vote accepted

*b is an integer, and you're not allowed to apply the unary * to an integer. (How would the compiler know whether you expected the bit pattern to point to an int, char, short, or whatever?) You can cast the integer back to a pointer and then deference it: *(int*)*b, which should do what you expect.

share|improve this answer
Hmm thanks I got the point. – melyfony Aug 28 '11 at 7:12

It seems to work fine for me, once your variable declarations are cleaned up a bit:

int main (){
        int x = 10;
        int* a = &x;
        int** b = &a;
        printf("%d  %d  %d  %d  %d  %d  ",x,a,*a,b,*b,**b);
        return 0;

I'd suggest that the problem is that you declared b with the wrong type (and then cast &a into that type). It is not an int*, it is an int**, i.e. a pointer to a pointer to an integer. You could of course cast *b to the desired type in your printf() statement, but why not just declare it correctly in the first place?

Here's an ideone example:

share|improve this answer
Actually, he said in the wall-of-text under the code that he already knew that it would work with int** b. (I cannot really fault you for missing that, though). – Henning Makholm Aug 28 '11 at 7:19
int x= 10;

enter image description here

int *a = &x;    //address of x is 0x33

enter image description here

Int * b = (int *) &a;     //address of a is 0x34

enter image description here

So from the above we have that:

  • x = 10 a = 33
  • *a = 10 b = 34
  • *b = 33
  • * (int *) *b = 10
  • **b would result in a compilation error
share|improve this answer

Let's look at what happens here. a is a pointer to int. We take the address of a, which is a pointer to pointer to int, cast that to a pointer to int, and assign it to b.

Then we dereference b twice. b is a pointer to int, so *b is an int. Then we dereference an int. Wait, you can't dereference an int - it's not a pointer. And so we enter the twilight zone of undefined behavior.

share|improve this answer

**b would point to the correct block of memory, but the compiler doesn't have the proper type information. @Henning says, dereferencing b once is an int value according to the compiler, and there's no dereference operator for type int. That's specifically why the int** and its ilk exist: to tell the compiler how many dereferences are possible/necessary.

Out of curiosity is there a reason int* b = a; doesn't work, if you do want the value of x after one dereference?

share|improve this answer
+----------+    +----------+    +----------+
|    10    |    |  addr_x  |    |  addr_a  |
+----------+    +----------+    +----------+
|    x     |    |    a     |    |    b     |
+----------+    +----------+    +----------+
|  addr_x  |    |  addr_a  |    |  addr_b  |
+----------+    +----+-----+    +----+-----+
  ^  ^               |   ^           | 
  |  +----(*a)-------+   +----(*b)---+
  |                                  |

The access is like above.

You have told the compiler that the pointer b is a pointer to an integer. When you do *b it dereferences to an int and another indirection is not possible on type of int and therefore when you accessbit as a pointer to a pointer to an integer in (**b). It is not allowed. To do so you need to typecast the value ofb` to the correct type and use it.

You want to use the value of *b as an address and fetch the int value stored at the address location *b. Therefore You want *b to be an int * which makes b an (int **) . Therefore it is best to declare b as int **b; . In your case before applying the double indirection typecast b to be int ** and then use double indirection.

printf ("%x", **((int **)b));

This will interpret the value stored in b as a pointer to a pointer to an integer and then fetch the value of x as you want.

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.