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
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    (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

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

First, you ask:

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 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 ( 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

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

So, the following assignments achieve the same final result:



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.


As the poster below notes, if your compiler supports the C standard, including 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

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

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

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

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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

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

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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