# Structure memory layout In C

``````struct fraction {
int num;
int denum;
} pi;

pi.num=22;
pi.denum=7;

((fraction*)&(pi.denum))->num=12;

cout << endl;
cout << pi.denum <<endl;
cout << pi.num   <<endl;
``````

I can understand the memory diagram till this point What I have confusion is is the following code

``````((fraction*)&pi.denum)->denum=33;
``````

Is there a legal way to get that 33 printed out ?? ANY command to get the value stored which is not in the view of an object?

-
Please... Code formatting next time. –  Richard J. Ross III Jan 16 '12 at 15:47
I tried my best to format the code –  raikrahul Jan 16 '12 at 15:47
That code doesn't make much sense (and you might be overwriting other stuff on the stack with that code, which might make it crash later on). What is it that you're trying to accomplish? –  DarkDust Jan 16 '12 at 15:49
The line `((fraction*)&pi.denum)->denum=33;` has undefined behavior, so there's no "legal" way to do anything after that. –  Steve Jessop Jan 16 '12 at 15:52
I may be a spotty, nocturnal nerd with a fear of women, but I've never considered seducing a pointer yet... –  Kerrek SB Jan 16 '12 at 16:20

A `struct fraction` will be layed out in memory as two consecutive `ints`. Your code looks at the expression `&pi.denum`, which is the address of the second integer:

`````` -----------------------
|  int num  | int denum |
-----------------------
^           ^
|           |
&pi         &(pi.denum)
``````

But you cast `&pi.denum` to a `fraction *` and try to access `((fraction*)&(pi.denum))->num`. Since `num` is the first member of `struct fraction`, the C standard guarantees that its address is the same as the struct itself. So

``````&(((fraction*)&(pi.denum))->num) == (fraction*)&(pi.denum) == &pi.denum.
``````

It is a valid memory location - but only by luck. If you tried to access `((fraction*)&(pi.denum))->denom`, you'd get undefined behavior - possibly corrupting memory or causing a segmentation fault.

Bottom line, `((fraction*)&(pi.denum))->num = 12` is nonsense code. It could never do anything useful.

-
`((fraction*)&(pi.denum))->denom` will only result in a segfault if one is lucky, generally it's simply UB, which might segfault or might overwrite something completely unrelated (possible corrupting the heap if `pi` is allocated there or overwriting a pointer somewhere else, so it might segfault at a completely unrelated position in the code (for the code example given it probably woudln't do anything though)) –  Grizzly Jan 17 '12 at 15:25
@Grizzly thanks, edited. –  japreiss Jan 17 '12 at 19:17

Maybe a simple image will help:

```A+0  pi.num
A+4  pi.denum
```

`A` is the base address where `pi` is stored in memory. `num` is stored at address `A+0` and `denum` is stored at address `A+4` (if an `int` is 32 bits, i.e. 4 bytes).

The `((fraction*)&(pi.denum))` part of the statement will make the layout look something like this:

```A+0  pi.num
A+4  pi.denum   ((fraction*)&(pi.denum))->num
A+8             ((fraction*)&(pi.denum))->denum
```

As you can see there is an overlap in memory. This means that the statement `((fraction*)&(pi.denum))->num=12;` will actually set `pi.num` to 12.

Also as you can see, if you try to set `((fraction*)&(pi.denum))->denum` to a value, you are now writing outside of the memory allocated to the `pi` structure, and may overwrite other variables or other things.

-

First if you want to print out the 33 than you need to use following instruction:

``````((fraction*)&pi.denum)->num=33;
``````

Now understand the C memory access mechanisum the struct fraction have two int member. The base address of struct point to first element address.

&pi.denum give the second element address now you cast it to the struct pointer so it treat the denum address as num address logically but physically it denim address.

So if you want to change the denim value you have to use the first element address which point to denim address.

-

That line probably will set pi.denum to 12, but it's undefined behavior. The member "num" is (in most cases) in the beginning of the struct, so `something.num` is like `(int)something` (of course, this `something` must be a fraction), but you should not assume that it will work on every machine.

-
This is defined behavior. A pointer to a struct, converted to the type of the first member will be a pointer to that member (but this only applies to the first member). –  Jerry Coffin Jan 16 '12 at 16:18

Provided that this code is basically wrong, maybe you are searching for this:

``````#include <iostream>

int main () {

struct fraction {
int num;
int denum;
} pi;

pi.num=22;
pi.denum=7;

((fraction*)&(pi.denum))->num=12;

std::cout << std::endl;
std::cout << pi.denum <<std::endl;
std::cout << pi.num   <<std::endl;

((fraction*)&pi.denum)->denum=33;

int * items;
items = (int *)&pi;

for (int i = 0; i < 3; i ++) {
std::cout << i << ": " << items[i] << std::endl;
}

}
``````
-

In the code posted in your question, you have told the compiler to act as if the address of `pi.denum` is actually the address of a `fraction struct`.

It is not, and therefore you are on your own in getting the memory addressing right. C (or C++) will lay out your struct in memory in the order you specify, subject only to padding for alignment.

So, on a machine with 32-bit ints and typical 32-bit alignment for 32-bit ints, your line `((fraction*)&(pi.denum))->num=12;` will set `pi.denum` to 12, not `pi.num`. The `->num` is an offset from a pointer (the offset is zero) and your pointer is to `pi.denum`, so it is `pi.denum` that gets set.

This will not crash, because you have simply used a peculiar expression to address memory that is properly allocated on your stack.

The following code `((fraction*)&pi.denum)->denum=33;` will write to memory outside of the allocation of `pi`. Whether this crashes or simply overwrites another variable depends on what else you have allocated on the stack and perhaps on your compiler and compiler settings.

If you actually want to scribble on the memory that follows your struct and then read it back, the same addressing expression will do it for you, e.g.

``````int myTest = ((fraction*)&pi.denum)->denum;
``````
-