C++: Pointer to data member address doubt

I have read(Inside C++ object model) that address of pointer to data member in C++ is the offset of data member plus 1?
I am trying this on VC++ 2005 but i am not getting exact offset values.
For example:

``````Class X{
public:
int a;
int b;
int c;
}

void x(){
printf("Offsets of a=%d, b=%d, c=%d",&X::a,&X::b,&X::c);
}
``````

Should print Offsets of a=1, b=5, c=9. But in VC++ 2005 it is coming out to be a=0,b=4,c=8.
I am not able to understand this behavior.
Excerpt from book:

"That expectation, however, is off by one—a somewhat traditional error for both C and C++ programmers.

The physical offset of the three coordinate members within the class layout are, respectively, either 0, 4, and 8 if the vptr is placed at the end or 4, 8, and 12 if the vptr is placed at the start of the class. The value returned from taking the member's address, however, is always bumped up by 1. Thus the actual values are 1, 5, and 9, and so on.
The problem is distinguishing between a pointer to no data member and a pointer to the first data member. Consider for example:

float Point3d::*p1 = 0;
float Point3d::*p2 = &Point3d::x;

// oops: how to distinguish?
if ( p1 == p2 ) {
cout << " p1 & p2 contain the same value — ";
cout << " they must address the same member!" << endl;
}
To distinguish between p1 and p2, each actual member offset value is bumped up by 1. Hence, both the compiler (and the user) must remember to subtract 1 before actually using the value to address a member."

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`pointer to data member in C++ is the offset of data member plus 1` - Where did you get this information? –  PeterK Aug 13 '10 at 14:53
Look at a ruler, it starts at 0 too. –  nos Aug 13 '10 at 14:56
That excerpt you quote is missing CONTEXT .. what is it talking about ? In any case, your sample code results are exactly correct, and speak the truth better than the documentation (which is a truism of coding ). –  jdu.sg Aug 13 '10 at 15:19
What is the title of the book? Throw the book away. Get a good one. –  GManNickG Aug 13 '10 at 15:31
The book appears to be "Inside the C++ Object model", the author led the early cfront C++ implementation teams, and it hasn't been updated since '96. Like many books, it's probably more a historical curiosity describing a specific implementation, not that relevant to today's C++. –  paxdiablo Aug 13 '10 at 16:13

The offset of something is how many units it is from the start. The first thing is at the start so its offset is zero.

Think in terms of your structure being at memory location 100:

``````100: class X { int a;
104:           int b;
108:           int c;
``````

As you can see, the address of `a` is the same as the address of the entire structure, so its offset (what you have to add to the structure address to get the item address) is 0.

Note that the ISO standard doesn't specify where the items are laid out in memory. Padding bytes to create correct alignment are certainly possible. In a hypothetical environment where ints were only two bytes but their required alignment was 256 bytes, they wouldn't be at 0, 2 and 4 but rather at 0, 256 and 512.

And, if that book you're taking the excerpt from is really `Inside the C++ Object Model`, it's getting a little long in the tooth.

The fact that it's from '96 and discusses the internals underneath C++ (waxing lyrical about how good it is to know where the `vptr` is, missing the whole point that that's working at the wrong abstraction level and you should never care) dates it quite a bit. In fact, the introduction even states "Explains the basic implementation of the object-oriented features ..." (my italics).

And the fact that nobody can find anything in the ISO standard saying this behaviour is required, along the fact that neither MSVC not gcc act that way, leads me to believe that, even if this was true of one particular implementation far in the past, it's not true (or required to be true) of all.

The author apparently led the cfront 2.1 and 3 teams and, while this books seems of historical interest, I don't think it's relevant to the modern C++ language (and implementation), at least those bits I've read.

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Firstly, the internal representation of values of a pointer to a data member type is an implementation detail. It can be done in many different ways. You came across a description of one possible implementation, where the pointer contains the offset of the member plus 1. It is rather obvious where that "plus 1" come from: that specific implementation wants to reserve the physical zero value (`0x0`) for null pointer, so the offset of the first data member (which could easily be 0) has to be transformed to something else to make it different from a null pointer. Adding 1 to all such pointers solves the problem.

However, it should be noted that this is a rather cumbersome approach (i.e. the compiler always has to subtract 1 from the physical value before performing access). That implementation was apparently trying very hard to make sure that all null-pointers are represented by a physical zero-bit pattern. To tell the truth, I haven't encountered implementations that follow this approach in practice these days.

Today, most popular implementations (like GCC or MSVC++) use just the plain offset (not adding anything to it) as the internal representation of the pointer to a data member. The physical zero will, of course, no longer work for representing null pointers, so they use some other physical value to represent null pointers, like `0xFFFF...` (this is what GCC and MSVC++ use).

Secondly, I don't understand what you were trying to say with your `p1` and `p2` example. You are absolutely wrong to assume that the pointers will contain the same value. They won't.

If we follow the approach described in your post ("offset + 1"), then `p1` will receive the physical value of null pointer (apparently a physical `0x0`), while the `p2` whill receive physical value of `0x1` (assuming `x` has offset 0). `0x0` and `0x1` are two different values.

If we follow the approach used by modern GCC and MSVC++ compilers, then `p1` will receive the physical value of `0xFFFF....` (null pointer), while `p2` will be assigned a physical `0x0`. `0xFFFF...` and `0x0` are again different values.

P.S. I just realized that the `p1` and `p2` example is actually not yours, but a quote from a book. Well, the book, once again, is describing the same problem I mentioned above - the conflict of `0` offset with `0x0` representation for null pointer, and offers one possible viable approach to solving that conflict. But, once again, there are alternative ways to do it, and many compilers today use completely different approaches.

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MSVC actually has three or four different pointer to member representations depending on the inheritance model assumed for forward declared types. –  MSN Aug 13 '10 at 16:32
@MSN: That usually applies to pointers to member functions. Pointers to data members are notably simpler. They are significantly less sensitive to the inheritance model (or not sensitive at all). Normally, one can implement them as plain offset in any inheritance model. If MSVC++ is doing something more complicated, I don't know the reason for that. –  AndreyT Aug 13 '10 at 16:35
@AndreyT: You have observed the right problem. This problem is not about the alignment issues. Its about differentiating null pointer to data member to that of initilized ones. Thanks. –  theneuronarc Aug 13 '10 at 17:27
@AndreyT, you are forgetting pointer to members of virtual base classes. That one is also less forgiving. –  MSN Aug 24 '10 at 17:16
@MSN: No, I'm not forgetting anything. The issue with pointers to member functions is that in general case the non-trivial calculation of the proper `this` pointer value has to performed at the moment of dereference. This is why pointers to member functions have to carry quite a bit of extra information with them. This is why they are so complicated. –  AndreyT Aug 24 '10 at 18:03

The behavior you're getting looks quite reasonable to me. What sounds wrong is what you read.

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Not to mention that having member variables on an uneven address would be quite inefficient. –  humbagumba Aug 13 '10 at 14:54
have added excerpt from the book. Please have a look –  theneuronarc Aug 13 '10 at 15:10
I've looked. I still think what I said above is pretty accurate -- at best, he's describing a method used by some particular compiler, not a general requirement. Offhand, I'm not sure I've ever seen a compiler that worked that way, but even if it did, I don't see much relevance. –  Jerry Coffin Aug 13 '10 at 15:21

``````void test()
{
using namespace std;

int X::* pm = NULL;
cout << "NULL pointer to member: "
<< " value = " << pm
<< ", raw byte value = 0x" << hex << *(unsigned int*)&pm << endl;

pm = &X::a;
cout << "pointer to member a: "
<< " value = " << pm
<< ", raw byte value = 0x" << hex << *(unsigned int*)&pm << endl;

pm = &X::b;
cout << "pointer to member b: "
<< " value = " << pm
<< ", raw byte value = 0x" << hex << *(unsigned int*)&pm << endl;
}
``````

On Visual Studio 2008 I get:

``````NULL pointer to member:  value = 0, raw byte value = 0xffffffff
pointer to member a:  value = 1, raw byte value = 0x0
pointer to member b:  value = 1, raw byte value = 0x4
``````

So indeed, this particular compiler is using a special bit pattern to represent a NULL pointer and thus leaving an 0x0 bit pattern as representing a pointer to the first member of an object.

This also means that wherever the compiler generates code to translate such a pointer to an integer or a boolean, it must be taking care to look for that special bit pattern. Thus something like `if(pm)` or the conversion performed by the `<<` stream operator is actually written by the compiler as a test against the 0xffffffff bit pattern (instead of how we typically like to think of pointer tests being a raw test against address 0x0).

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I have read that address of pointer to data member in C++ is the offset of data member plus 1?

I have never heard that, and your own empirical evidence shows it's not the case. I think you misunderstood an odd property of structs & class in C++. If they are completely empty, they nevertheless have a size of 1 (so that each element of an array of them has a unique address)

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I have added excerpt from the book. Please have a look. –  theneuronarc Aug 13 '10 at 15:10

\$9.2/12 is interesting

Nonstatic data members of a (non-union) class declared without an intervening access-specifier are allocated so that later members have higher addresses within a class object. The order of allocation of nonstatic data members separated by an access-specifier is unspecified (11.1). Implementation alignment requirements might cause two adjacent members not to be allocated immediately after each other; so might requirements for space for managing virtual functions (10.3) and virtual base classes (10.1).

This explains that such behavior is implementation defined. However the fact that 'a', 'b' and 'c' are at increasing addresses is in accordance with the Standard.

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But could it be that those address’s are not contiguous? –  JustBoo Aug 13 '10 at 16:20