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So all this time I thought that when you do something like ObjectA.field1, ObjectA is just like any value on the stack and you basically access its fields. Now I was going through the notes for a class about OOP languages and realized that when you do ObjectA.field1 what actually happens is HEAP(Address of ObjectA)(field1) which returns you the value of the field1. This makes me a bit confused. Can anyone tell why there is a look up going on although we already have the value of the object? Hope I was able to explain..

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It's not clear to me what HEAP is supposed to do. – bames53 Nov 19 '11 at 20:01
HEAP takes in an address and returns an object – Cemre Nov 19 '11 at 20:06
So HEAP(Address of ObjectA) returns ObjectA. Then what does ObjectA(field1) do? – bames53 Nov 19 '11 at 20:08
Returns the value of the field1 – Cemre Nov 19 '11 at 20:09
This HEAP() thing doesn't make much sense; I know of no such concept in the C++ language. Do you have a function or macro by that name defined somewhere? What does it do? An object needn't be allocated on the heap; it can be on the stack or in static data (those aren't necessarily language-defined terms). When you refer to an object by name, the compiler knows how to generate code to access that object in memory. A field (more precisely, a member) of an object exists somewhere within the memory that the object occupies, at a known offset and with a known size. – Keith Thompson Nov 19 '11 at 22:34

2 Answers 2

up vote 7 down vote accepted

Objects aren't really that magical. Essentially, an object just consists of a linear collection of all its members, with unspecified amounts of padding surrounding the members. Layout-wise, a C++ class is essentially like a C struct:

struct Foo {
  int a;
  char b;
  std::string s;

  static long q;

  void bar() { print(s); log(a); }
  static void car() { }

Ignoring member functions and statics for now, this might be laid out like this:

+= class Foo =+
+-------------+  ---\   <---   Foo * p
|  int        |     s
+-------------+     i
|  char       |     z
+-------------+     e
| <padding>   |     o
+-------------+     f
| std::string |    (F
+-------------+     o
| <padding>   |     o)
+-------------+  ---/

Every object of class Foo is stored like this in memory. The only extra data we need are the static members, member functions, and static member functions.

Static members are just global variables. So we have only one global variable:

+== static__Foo__q ==+
|  long int          |

Next up, static member functions are just ordinary, free functions:

void static__Foo__car() {  }

Finally, member functions: these are essentially also just ordinary functions, though with an extra parameter that allows them to find instance members:

void member__Foo__bar(Foo * p) { print(p->s); log(p->a); }

The only important difference is that you cannot obtain an ordinary free function pointer to member functions, since the actual name of the implementation function is not exposed. The only way to refer to Foo::bar() is via a pointer-to-member-function void (Foo::*ptfm)() = &Foo::bar. Member objects are a bit simpler: you can either obtain a normal pointer to them, like Foo x; int * p = &x.a;, but you can also form a pointer-to-member: int Foo::*ptm = &Foo::a;.

Then, if we have objects Foo x, y, z;, we can use the pairs of instance pointer Foo * pi = &x; and member pointers int &Foo::* ptm = &Foo::a or void (Foo::*ptfm)() = &Foo::bar to access the relevant member of the given instance: the integer pi->*ptm, and the function call (pi->*ptfm)(), respectively. (Yes, ->* is an operator.)

(A free version of the function pointer cannot exist, because polymorphic (virtual) functions require a more complicated dispatch mechanism than a simple, fixed function pointer.)

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+1 For the ASCII art.I sure do know it takes a lot of effort :) – Alok Save Nov 20 '11 at 15:04
I fixed the last part about member objects: You can have both a direct, free pointer to a member object (&x.a), and also an instance-pointer/member-pointer pair, (&x, &Foo::a). – Kerrek SB Nov 20 '11 at 15:38
Can you also explain why is padding required between char and std::string objects ? – Mr.Anubis Dec 14 '11 at 17:42
@FreakEnum: well, that's just a hypothetical example, but assuming that the alignment of int and std::string is both 4 (or 8) and that of char is 1, you need the padding to obtain the correct alignment. – Kerrek SB Dec 14 '11 at 17:58

To get the field1 of some ObjectA of some ClassAthe computer has to have the address of the memory zone containing ObjectA, it knows (statically) the offset (in bytes) for field1 (of ClassA) so it can retrieve the field1 by adding that offset to the adress of ObjectA.

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So, when we dereference a pointer to we get the value of the object or do we get "the real address" of the object ? thanks for the reply – Cemre Nov 19 '11 at 20:06
A pointer is the address of the object. And usually, you dereference it with an offset, as I explained. – Basile Starynkevitch Nov 19 '11 at 20:07
When doing ObjectA.field1 there's no dereferencing of pointers at the level of the C++ language. ObjectA is an lvalue which is comprised of a series of bytes in memory. To access field1, the program has information about which bytes of an object comprise each of its fields. So ObjectA.field1 is an expression that results in an lvalue comprised of the bytes of ObjectA that make up the sub-object field1. – bames53 Nov 19 '11 at 20:33

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