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

Let's say you have:

    void *a = //some address;
    *((int **)(char*)a) = 5

I'm not really clear on what the second line is supposed to be doing... I know that 'a' is casted to a pointer to a char, and then eventually casted to a pointer to a pointer to an int, but it was unclear what dereferencing a pointer to a pointer to an int actually does...

This would be very helpful. Thanks

share|improve this question
Where are you getting your questions from? Is this homework? – RedX Oct 18 '11 at 8:42
up vote 7 down vote accepted

it is storing the value 5 in "some address", but more precisely, it is storing the value 5 widened to the machine address size in those many bytes starting at "some address".

e. g. if it is a 64-bit machine, it is storing the value 0x0000000000000005 at the 8 bytes starting at "some address"

i don't see why it is doing it in such a complicated way, but who are we to judge the intentions of a programmer hard at work at the end of a long day.

share|improve this answer
Agreed, assuming that on this implementation, the conversion from int to pointer type (in particular int*) is as expected. Formally, it's UB to convert 5 to a pointer type even if you don't ever dereference that pointer-to-what-we-think-is-address-0x5. In practice implementations do something that's predictable if you know anything about the architecture. – Steve Jessop Oct 18 '11 at 8:53
But there have in the past been implementations that take advantage of the fact that int has a certain alignment, to leave the bottom bits out of int*, and so 5 could end up stored as 5/2 or 5/4, perhaps with stuff in the top bits to indicate memory bank or other such junk. No such stuff really happens on the flat-memory architectures we're used to, though. – Steve Jessop Oct 18 '11 at 8:57
@Steve: it's implementation-definied, not undefined; the whole point of the introduction of intptr_t was to add a portable way for well-defined conversions between integer and pointer types – Christoph Oct 18 '11 at 9:03
@Christoph: The conversion is implementation-defined, but creating the pointer value is undefined unless there actually is an object located at the address that results from converting 5 to pointer type (the nominal one-past-the-end-of-an-array would be good enough). That's possible, but pretty unlikely. Using a dangling pointer value (other than a null pointer) is UB, and writing the pointer value to memory is using the value. The intuition is that an implementation may trap if a pointer register ever holds an invalid value, although of course the standard doesn't go into specifics. – Steve Jessop Oct 18 '11 at 9:30
Basically, intptr_t is specified to allow you to take a valid pointer, convert it to an integer type, and then later convert it back to its original type. It doesn't allow you with defined behavior to convert an arbitrary integer value to pointer type, although of course any flat-memory implementation will in practice let you do just that. – Steve Jessop Oct 18 '11 at 9:35

If you dereference a pointer to a pointer to an int you'll get a pointer to an int. Dereferencing means you'll get the object it was pointing at which is in this case a pointer to an int.

Here's an interesting article that explains how to interpret more complex declarations

share|improve this answer
surely you mean "you'll get a pointer to an int", probably typo when you said pointer to a char – necromancer Oct 18 '11 at 7:50
Fixed fixed fixed. – Keith Thompson Oct 18 '11 at 7:51
"which is in this case a pointer to an int." aka, "an address to an int", right? – Dark Templar Oct 18 '11 at 16:28
@Jacob, pointers and addresses are very different things. a pointer is a variable, i. e. a memory location, that can contain any value you assign to it. an address is a constant that cannot be changed. (think over it a bit). what is confusing you is the declaration "void* a = ..." -- this does NOT mean you are changing the address of a. all you are doing is assigning a value to a. the "void*" is just the type declaration for a. so read it as just "a = ..." specifically read the "void* a = (void*)5;" as "a = 5;" the rest of the stuff is type-information which is used later. contd. – necromancer Oct 18 '11 at 22:07
@Jacob, (contd.) the type information of a variable that is a pointer is used when you use the value stored in the pointer variable. say a pointer variable a contains the value 888 and then you say *a= 7 that means you want to write the value 7 in the memory location 888. the ambiguity that remains is whether you want to write 7 in the single byte at address 888? or as an integer into the 4 bytes starting at address 888? or as a long integer into the 8 bytes starting at address 888? this is where the type of a is used. if a is declared as char* a, just 1 byte, if int* a, 8 bytes... – necromancer Oct 18 '11 at 22:17

It's a nonsense, obfuscated way of writing:

void* a = (void*)5;

As we can tell, original code doesn't make any sense. Here is what it does:

  • Assign an address to a.
  • Typecast a from void pointer to char pointer.
  • Wildly typecast the char pointer to a pointer-to-pointer to int.
  • Take the contents of the pointer-to-pointer, ie the address where an int should be stored.
  • This address will be stored where a currently stores its address, overwriting it with the address 5.

EDIT: Btw, note that implicit integer to pointer casts are not allowed in C (C99 6.5.4 §3). There must be a cast like in the code above.

share|improve this answer
So we've essentially said that the address of 'a' is now 5? Does this conflict with agks's explanation? – Dark Templar Oct 18 '11 at 16:25
@Jacob No, his answer is correct as well. – Lundin Oct 19 '11 at 6:47

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.