As far as I know, a property of the standard-layout class is that the address of a standard-layout object is equal to its initial member's. I tested the following code with g++ and clang++, but found that Derived3 is a standard-layout class and &d is not equal to &d.c.

#include <iostream>
using namespace std;

struct Base {};

struct Derived1 : Base
  int i;

struct Derived3 : Base
  Derived1 c;
  int i;

int main()
  cout << is_standard_layout_v<Derived3> << endl;

  Derived3 d;
  cout << &d << endl;
  cout << &d.c << endl;

  return 0;
  • 1
    cppreference tells us "A standard-layout class is a class that ... * only one class in the hierarchy has non-static data members". But std::is_standard_layout_v<Derived3> returns true. Lets wait until language lawyers wake up :-)
    – Klaus
    Mar 4 at 9:33
  • 1
    consider to use the language-lawyer tag. Mar 4 at 9:48
  • 1
    @Klaus But isn't here the hierarchy BaseDerived3? Then, the non-static data members are only in Derived3, so the rule you pointed to is satisfied here. Mar 4 at 10:09
  • There is also the issue of only having one sub-object of any given class type - now, are there two Base class sub-objects? (One from the hierarchy and one from the component Derived1.) But IANALL :) Mar 4 at 10:13
  • 1
    Atually, cppreference even has on en.cppreference.com/w/cpp/language/ebo : Empty base optimization is required for StandardLayoutTypes in order to maintain the requirement that the pointer to a standard-layout object, converted using reinterpret_cast, points to its initial member, which is why the requirements for a standard layout type include "has all non-static data members declared in the same class (either all in the derived or all in some base)" and "has no base classes of the same type as the first non-static data member".
    – KamilCuk
    Mar 4 at 10:38

1 Answer 1


Following the word of the standard, they are indeed standard-layout types. Going through the points one by one:

A class S is a standard-layout class if it:

  • has no non-static data members of type non-standard-layout class (or array of such types) or reference, [...]

int is standard-layout. Derived1 is standard layout, as we'll see.

  • has no non-standard-layout base classes,

Base is empty, so standard-layout.

  • has at most one base class subobject of any given type,

Both Derived1 and Derived3 has only a single base Base.

  • has all non-static data members and bit-fields in the class and its base classes first declared in the same class, and

Meaning, within an inheritance hierarchy, all data members are declared in the same class. This is clearly true for Derived1. This is also true for Derived3 because Derived1 is not in the inheritance hierarchy.

To make this point clearer, consider a simpler example

struct B {};
struct D1 : B {};
struct D3 : B { D1 c; };

Which also runs into the same address problems as in the question, but clearly fulfills this bullet point.

  • has no element of the set M(S) of types as a base class, where for any type X, M(X) is defined as follows. [Note 2: M(X) is the set of the types of all non-base-class subobjects that can be at a zero offset in X. — end note]
    • If X is a non-union class type with no non-static data members, the set M(X) is empty.
    • If X is a non-union class type with a non-static data member of type X0 that is either of zero size or is the first non-static data member of X (where said member may be an anonymous union), the set M(X) consists of X0 and the elements of M(X0). [...]

Meaning, M(Derived3) is the set {Derived1, int}, none of which is a base class of Derived3.

Likewise, M(Derived1) is the set {int}, which is not a base class of Derived1.

Being standard-layout means the class and its first data member is pointer-interconvertible. To be pedantic, the representation of pointers being different doesn't prove there's a problem, but comparing the results of reinterpret_cast does:

std::cout << (&d.c == reinterpret_cast<Derived1*>(&d));  // 0 for clang and gcc

Thus the compilers are not technically compliant. However, this is an impossible situation: the Base subobject in Derived1 cannot have the same address as the Base subobject in Derived3, which is why the compilers placed Derived1 at a four byte offset from the start.

Standard-layout classes have a history of defect reports, and this looks like it should be another one.

  • 5
    Yeah - impossible. Reading the comment on the Q from @KamilCuk and my follow-on, empty base class optimization is both required and forbidden. If that's not a defect, then I don't know what is. Mar 4 at 10:46
  • 4
  • @AdrianMole When it gets fixed and propagates into some complex C++ frameworks, I bet you a problem here and there will fix itself, as if by magic. Or will magically appear. That's a nasty language bug. Plenty of style guides prohibit multiple derivation precisely because it was under-specified. Now we get different behavior in a very basic feature between freshly fixed C++ and legacy stuff. This is gonna be fun. Mar 5 at 4:19

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