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I have the following code:

#include <stdio.h>
#include <stdlib.h>

typedef union stateof stateof;
union stateof 
{
  stateof* foo;
  double* bar;
};

typedef struct hunch hunch;
struct hunch{
  double* first;
  double* second;
};

void main(){
  #define write(x) printf("%d \n",x);

  int* storage = 0;
  stateof* un = (stateof*)&storage;
  un->foo = 300;
  write(storage);

  un->bar = 600;
  write(storage);

  hunch* h = (hunch*)&storage;
  h->first = 1200;
  write(storage);

  h->second = 1600;
  write(storage);
}

The output of this program is:

300   
600   
1200   
1200

What is happening here?

What does it mean for the un->{foo,bar} and h->{first,second} statements to execute when they most definitely do not point to valid structures? What is exactly occurring during this period and why is the output of the union different than that of the structure?

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3 Answers 3

up vote 2 down vote accepted

I'll describe all in details.

int* storage = 0; - creates a Pointer on the stack with zero value (points to NULL in other words).

stateof* un = (stateof*)&storage; - un points to the location of storage which is a pointer. So un points to the storage's value which is now equals 0.

un->foo = 300; - assigns 300 into storage (lets think about storage like about some int value because it doesn't matter that it is a pointer in fact here), so storage == 300 now.

un->bar = 600; - the same as the previous, because un is a union and all its fields in fact just different names for only one field (well, its union's definition).

h->first = 1200; and h->second = 1600; are like the previous cases with only one exception that here values are assigned to DIFFERENT fields in the struct (different places in memory).

write(storage); - printing the value of storage (which is a pointer) but not the value where storage points to (*storage).

And of course, the last but not the least: NEVER CODE LIKE THAT ANYMORE! :)

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@xappymah, the fact that storage is a pointer is important at least in that it means the first three modifications are likely to work (since they're also all to pointer types that share memory with storage). If it were just int there would be even more room for error in the OP's program. –  Carl Norum Mar 27 '11 at 7:25
    
@Carl Norum, if you look here: stateof* un = (stateof*)&storage you'll find that here is used not storage but &storage which in fact is a pointer into the stack where storage resides. So there is no difference at all what value is on the stack either a pointer or an int value, because un will point to the same place. –  xappymah Mar 27 '11 at 7:34
    
@xappymah - exactly. A pointer's worth of space actually allocated on the stack. If storage were an int, only an int's worth of space would be allocated. There's no reason an int and a pointer have to take up the same amount of space - the fact that the OP did use a pointer may very well matter if a pointer and an int aren't the same size. Since he writes to that allocated memory as a pointer every time, it can definitely make a difference. Either way, the write through h->second is likely to be completely unallocated memory, and remains pretty dangerous. –  Carl Norum Mar 27 '11 at 7:37
    
@Carl Norum, oh, if you meant the size, then you are right. I just wanted to emphasize that it doesn't matter where storage points to because OP works with storage's value itself. But of course the size of the allocated space on stack does matter. However, IMHO making storage an int value will not make the original code more or less error prone than it is now, because it is Really unsafe already:) –  xappymah Mar 27 '11 at 7:44
    
I just posted a comment on Carl Norum's answer, and I'll just clarify it even more here. Dereference un and you get storage's value. Storage's value can then be set by doing something heinous like *((int **) un) = 888. But apparently this is "similar" to doing just (*un).foo = 888. Why is this? –  fthinker Mar 27 '11 at 19:43

Your program causes all kinds of undefined behaviour. You could get any kind of output imaginable. Your compiler is probably giving you all kinds of warnings when you compile this code - try fixing those up and you should be headed in a better direction.

Assuming you have a normal sort of system, the reason you're getting the output you see can be explained:

  1. modifying un->foo overwrites storage with the value 300 - then you print it out.
  2. modifying un->bar overwrites storage with the value 600 - then you print it out.
  3. modifying h->first overwrites storage with the value 1200 - then you print it out.
  4. modifying h->second (DANGEROUSLY) overwrites some memory with the value 1600, then you print out storage again - it's still 1200.
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So in this example given the assumption I'm running on a normal system, how is it that un->foo translates into the value of storage? The same thing with h->first. Basically what I'm asking is how does the compiler actually translate h->first into storage's value? –  fthinker Mar 27 '11 at 19:26
    
Well, the answer is simple. Any struct is represented in memory as sequence of its fields. So, pointer to the struct is also the pointer to the first field of the struct. The same resides to unions with respect to the fact that union contains only one field with several names. –  xappymah Mar 27 '11 at 19:50
    
Thanks, I suspected something like that was going on :) –  fthinker Apr 2 '11 at 3:33

We don't know what will happen. The language standard doesn't say.

When you write a program, there is an implied contract between you and the compiler. If you write a correct program, it has to produce an executable that does exactly what the source code said.

When you use code like

stateof* un = (stateof*)&storage;

you are telling the compiler "I know for sure that &storage actually points to a stateof union. Trust me, I know what I am doing!".

And the compiler thinks "If you say so...", and acts accordingly. But as you have then broken the contract, it is free to do just about anything. We just don't know what the output could be, or if there would even be one.

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