4

I am curious, if I have two pointers

int *x = (int *)malloc(sizeof(int));
int *y;

and I want y to point to the address of x, is

y = x;

the same as

y = &*x;

?

  • AFAIK, yes. *x is an lvalue, &*x is its address, which is x. there should be no side effects involved. – Elazar Jun 3 '13 at 15:44
  • 1
    (The real question is, of course, what happens when x==NULL) – Elazar Jun 3 '13 at 15:45
  • @Elazar: It doesn't matter. It doesn't crash. – anishsane Jun 3 '13 at 15:54
  • @anishsane I think you are right, but I will be happy to see a proof. (Not an example). – Elazar Jun 3 '13 at 16:01
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    Why would you want to write y = &*x; in the first place? – Keith Thompson Jun 3 '13 at 18:27
8

Your question has two parts, and it's worth noting that they are not both correct:

First, you ask:

is
y = x;
the same as
y = &*x;

Since the dereference (*) and address-of (&) operators have the same precedence they will bind right to left, so

y = &*x;

is the same as:

y = &(*x);

And yes, that will yield the same effect as y=x; Now if you have a C compliant compiler that follows the letter of the law, it will not only be the same effectively, it will be the same, this is due to section 6.5.3.2 P3 of the C Specification:

The unary & operator yields the address of its operand. If the operand has type ‘‘type’’, the result has type ‘‘pointer to type’’.

If the operand is the result of a unary * operator, neither that operator nor the & operator is evaluated and the result is as if both were omitted

So the compiler will see both the * and & together and omit them entirely.


In the second half of your question you stated:

I want y to point to the address of x

Presumably you know that that's not what you're doing, but you're setting y to point to the same address as x instead. x of course has its own address and that could be set, but you'd need a different variable int **y = &x; assuming x is a valid value to be dereferenced.

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  • @Elazar - assuming x is a valid value to be dereferenced is a comment that applies to the whole answer. – Mike Jun 3 '13 at 16:59
  • Yes, but I want to know what happens if x is not a valid value to be dereferenced. Is it safe? is it UB? – Elazar Jun 3 '13 at 17:29
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    @Elazar - I'm using it as a blanket statement because it's easier that way, however from a C language point of view (6.5.3.2 P4) it's UB: If an invalid value has been assigned to the pointer, the behavior of the unary * operator is undefined. – Mike Jun 3 '13 at 17:45
  • Great, thanks. That's exactly what I was looking for. So, these expressions are not the same. – Elazar Jun 3 '13 at 17:47
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    If x is a null pointer, then *x has undefined behavior when the * operator is evaluated. In &*x, the standard explicitly states that neither * nor & is evaluated, so there is no undefined behavior; &*x is equivalent to x, except that it's not an lvalue. (The following statement that "the constraints on the operators still apply" doesn't change that, the requirement that the operand of * is not null is not a constraint.) The rule collapsing &*x to x was added in C99; in C89/C90, there's no such rule, and &*x does have undefined behavior if x is a null pointer. – Keith Thompson Jun 3 '13 at 18:12
4

They are functionally equivalent. This is effectively a "shallow copy".

So, the following assignments achieve the same final result:

y=x;

y=&(*x);

However, the second operation will take more time to execute because rather than just a direct assignment, you are performing an indirection then an address-of operation. The compiler may just optimize this down to y=x anyways, depending on your system.

Edit:


As the poster below notes, if your compiler supports the C standard, including 6.5.3.2 P3 of the C standard, this will definitely be optimized out, likely at the pre-processor level before the code is even compiled.

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    Are you sure it will take more time? If they are really euqivalent, it can't be true. An indirection needs an operand. – Elazar Jun 3 '13 at 15:47
  • Functionally equivalent, in the sense of, same resulting values, output, etc. This does not imply they will take the same steps to achieve the same (deterministic) output. I come from a statistics/math background, so I try to be very specific when it comes to this :) – Cloud Jun 3 '13 at 15:48
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    So what steps are taken, in pseudo-unoptimized-assembly? (Of course the AST is not the same.) – Elazar Jun 3 '13 at 15:49
  • It will depend on your compiler, pre-processor, toolchain, etc. With my current GCC setup, this sort of redundancy is optimized out. – Cloud Jun 3 '13 at 15:55
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    compiler may just optimize this down - if it's a true C compliant compiler it will remove both. That's part of the C specification (see my answer for reference). – Mike Jun 3 '13 at 17:54
3

They are either exactly the same by definition, or almost the same, depending on which version of the C standard you're dealing with.

In ISO C99 and C11, we have the following wording (quoting the N1570 C11 draft) in 6.5.3.2:

The unary & operator yields the address of its operand. If the operand has type "type", the result has type "pointer to type". If the operand is the result of a unary * operator, neither that operator nor the & operator is evaluated and the result is as if both were omitted, except that the constraints on the operators still apply and the result is not an lvalue.

So given:

int *x = /* whatever */;
int *y;

these two are exactly equivalent, even if x is a null pointer:

y = x;
y = &*x;

Without the special-case rule, the behavior would be undefined, because the behavior of the * operator is defined only if its operand is a valid non-null pointer. But since the * is never evaluated, it has no behavior here, defined or otherwise. (The fact that, unlike x, &*x is not an lvalue is not relevant here.)

And in C89/C90, that special-case rule had not yet been added, so the behavior of &*x is undefined if x is a null (or otherwise invalid) pointer. Most pre-C99 compilers would probably optimize away the * and & anyway; remember, it's the nature of undefined behavior that something can behave just as you might expect it to behave.

On the other hand, there's a very real difference in the behavior of anyone reading the code. If I see y = x;, my behavior is to think "Oh, it's an ordinary pointer assignment." If I see y = &*x;, my behavior is to think "Why the heck did you write it that way?", and to change it to y = x; if I'm in a position to do so.

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  • Great answer. And, using y = &*x is a very good (and harmless) way to say: "Hey, I am new so I don't know what I am doing. Proceed with caution." – Elazar Jun 3 '13 at 18:39
2

Yes, although the second one looks like an entry for an obfuscation contest.

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2

Yes, they are the same, but highly convoluted.

You can test this by doing the following:

y = &(*x);
printf("%p\n", (void*)x);
printf("%p\n", (void*)y);
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  • This test doesn't say much. It may just happen to be the case. – Elazar Jun 3 '13 at 15:51
  • The printed pointer address of X & Y will match, pretty self explanatory. – Geoffrey Jun 3 '13 at 15:54
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    Yes, but the question was about the C language, not about a C implementation. – Elazar Jun 3 '13 at 16:00
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    Still UB. %p requires an argument of type void*, not int*. Cast the argument to void* to avoid the UB. (But it still doesn't prove that the behavior is defined; no experiment can do that.) – Keith Thompson Jun 3 '13 at 18:13
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    @Elazar: There's no guarantee that void* and int* have the same representation, or even if they do that they're passed as arguments to printf in the same way. It's likely to work on the vast majority of real-world systems, but it's not guaranteed. – Keith Thompson Jun 3 '13 at 18:46
1

To my knowledge, they are exactly equivalent. I will be surprised if some compiler does treat them differently.

Because of presense of &, *x will not be evaluated at all. Hence even if x is null, it will not cause crash / seg-fault. (You can best verify using assembly.)

When we talk of assembly, it's impossible to calculate *x (value) & then &(*x) (pointer). Hence, compiler will simply calculate the address of *x, without calculating value of *x.

We can also check for more complex cases, like &(a[10]) It simply translates to a+10*sizeof(a[0]) in assembly.

Another proof would be the offsetof macro, typically defined as:

#define offsetof(st, m) ((size_t)(&((st *)0)->m))

Here, it's calculating &(null_pointer->m), which does not cause a crash.

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  • BTW sizeof does not count. sizeof(printf("%d",*(volatile int*)0)) will result in 4 or 8, without any side effects. – Elazar Jun 3 '13 at 17:50
  • yes, sizeof considers only the data type, not underlying data. – anishsane Jun 4 '13 at 10:29
-1

Here is a handy little function that may help. Not sure that you need all of the "includes".

#include <stdio.h>
#include <stdlib.h>
#include <iostream>
#include <string>
#include <typeinfo>
using namespace std;
int main() {
int *x = (int *)malloc(sizeof(int));
int *y = x;
int *z = &*x;

//y = x;
//z = &*x;

 cout   << "x has type: " << typeid(x).name() << '\n'
        << "y has type: " << typeid(y).name() << '\n'
        << "z has type: " << typeid(z).name() << '\n'
        << "values are " << x <<"  "<< y << "  " << z  << '\n'; 
}

The result I get from this is:

x has type: Pi
y has type: Pi
z has type: Pi
values are 0x1a3a010  0x1a3a010  0x1a3a010

The answer then is, Yes, the methods are exactly the same using Ubuntu 14.10, g++

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