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Consider the following code:

struct Base {};
struct Derived : public virtual Base {};

void f()
    Base* b = new Derived;
    Derived* d = static_cast<Derived*>(b);

This is prohibited by the standard ([n3290: 5.2.9/2]) so the code does not compile, because Derived virtually inherits from Base. Removing the virtual from the inheritance makes the code valid.

What's the technical reason for this rule to exist?

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I hope that you are content with my edit. –  Lightness Races in Orbit Sep 20 '11 at 12:50

5 Answers 5

up vote 13 down vote accepted

The technical problem is that there's no way to work out from a Base* what the offset is between the start of the Base sub-object and the start of the Derived object.

In your example it appears OK, because there's only one class in sight with a Base base, and so it appears irrelevant that the inheritance is virtual. But the compiler doesn't know whether someone defined another class Derived2 : public virtual Base, public Derived {}, and is casting a Base* pointing at the Base subobject of that. In general[*], the offset between the Base subobject and the Derived subobject within Derived2 might not be the same as the offset between the Base subobject and the complete Derived object of an object whose most-derived type is Derived, precisely because Base is virtually inherited.

So there's no way to know the dynamic type of the complete object, and different offsets between the pointer you've given the cast, and the required result, depending what that dynamic type is. Hence the cast is impossible.

Your Base has no virtual functions and hence no RTTI, so there certainly is no way to tell the type of the complete object. The cast is still banned even if Base does have RTTI (I don't immediately know why), but I guess without checking that a dynamic_cast is possible in that case.

[*] by which I mean, if this example doesn't prove the point then keep adding more virtual inheritance until you find a case where the offsets are different ;-)

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+1: Made my head hurt so I won't say it's an entirely clear answer, but appears to me to be the correct one. :) –  Lightness Races in Orbit Sep 20 '11 at 12:43
@Tomalak: thanks, it makes my head hurt a bit too, but if I think of a way to explain more clearly then I'll come back and edit. –  Steve Jessop Sep 20 '11 at 12:44
*cough* ASCII diagrams! *cough* –  Lightness Races in Orbit Sep 20 '11 at 12:46
@Tomalak: yeah, requires more time than I have to hand and still get to the shops during my lunch break. I'd have to actually write some classes with virtual inheritance and figure out their layouts to pin down the disparity, instead of hand-waving that part... –  Steve Jessop Sep 20 '11 at 12:47
Indeed. It's just about more than I'm willing to do, too, though I'd still love to see it! –  Lightness Races in Orbit Sep 20 '11 at 12:49

Consider the following function foo:

#include <iostream>

struct A
    int Ax;

struct B : virtual A
    int Bx;

struct C : B, virtual A
    int Cx;

void foo( const B& b )
    const B* pb = &b;
    const A* pa = &b;

    std::cout << (void*)pb << ", " << (void*)pa << "\n";

    const char* ca = reinterpret_cast<const char*>(pa);
    const char* cb = reinterpret_cast<const char*>(pb);

    std::cout << "diff " << (cb-ca) << "\n";

int main(int argc, const char *argv[])
    C c;

    B b;

Although not really portable, this function shows us the "offset" of A and B. Since the compiler can be quite liberal in placing the A subobject in case of inheritance (also remember that the most derived object calls the virtual base ctor!), the actual placement depends on the "real" type of the object. But since foo only gets a ref to B, any static_cast (which works at compile time by at most applying some offset) is bound to fail.

ideone.com (http://ideone.com/2qzQu) outputs for this:

0xbfa64ab4, 0xbfa64ac0
diff -12
0xbfa64ac4, 0xbfa64acc
diff -8
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static_cast is a compile time construct. it checks for the validity of cast at compile time and gives an compilation error if invalid cast.

virtualism is a runtime phenomenon.

Both can't go together.

C++03 Standard §5.2.9/2 and §5.2.9/9 ar relevant in this case.

An rvalue of type “pointer to cv1 B”, where B is a class type, can be converted to an rvalue of type “pointer to cv2 D”, where D is a class derived (clause 10) from B, if a valid standard conversion from “pointer to D” to “pointer to B” exists (4.10), cv2 is the same cv-qualification as, or greater cv-qualification than, cv1, and B is not a virtual base class of D. The null pointer value (4.10) is converted to the null pointer value of the destination type. If the rvalue of type “pointer to cv1 B” points to a B that is actually a sub-object of an object of type D, the resulting pointer points to the enclosing object of type D. Otherwise, the result of the cast is undefined.

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This isn't really the answer, as you can downcast with static_cast in e.g. struct B {}; struct D : B {}; int main() { B* x = new D; D* y = static_cast<D*>(x); }. –  Cat Plus Plus Sep 20 '11 at 12:19
The memory layout of Derived is known at compile time, regardless of virtual inheritance being used. Also, polymorphism in general is a runtime phenomenon, yet you are still allowed to use static_cast to do things that might turn out to be undefined behavior at runtime. –  eran Sep 20 '11 at 12:24
@catPlusPlus: Where's the virtual there? –  Lightness Races in Orbit Sep 20 '11 at 12:25
@eran: "The memory layout of Derived is known at compile time" - that's not sufficient, though (see my answer). Just because you've static_cast to Derived doesn't mean that the most-derived type of the object in question is Derived, and hence it might not have the layout that Derived has. That's what virtual inheritance means, that the Base sub-object isn't part of the Derived sub-object in classes derived from Derived. –  Steve Jessop Sep 20 '11 at 12:37
The proposed answer is incorrect. static_cast doesn't do any checking of validity; given something like static_cast<Derived*>( pBase ), if pBase doesn't actually have type Derived, the behavior is undefined. But the static_cast compiles fine. –  James Kanze Sep 20 '11 at 12:57

I suppose, this is due to classes with virtual inheritance having different memory layout. The parent has to be shared between children, therefore only one of them could be laid out continuously. That means, you are not guaranteed to be able to separate a continuous area of memory to treat it as a derived object.

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Fundamentally, there's no real reason, but the intention is that static_cast be very cheap, involving at most an addition or a subtraction of a constant to the pointer. And there's no way to implement the cast you want that cheaply; basically, because the relative positions of Derived and Base within the object may change if there is additional inheritance, the conversion would require a good deal of the overhead of dynamic_cast; the members of the committee probably thought that this defeats the reasons for using static_cast instead of dynamic_cast.

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Fundamentally, there's every reason. –  Lightness Races in Orbit Sep 20 '11 at 13:06
Not the downvoter, but I concur with Tomalak. The static in static_cast means a compile-time conversion for a non-null pointer. –  David Hammen Sep 20 '11 at 13:43
@David Hammen It depends on what you mean by "compile-time" conversion. static_cast definitely can involve some code executed at run-time, even when only pointers are involved. But as I said, the code is fairly limited: adding or subtracting a constant from the pointer, but not looking things up in the vtable. (Not sure why the down vote either, since my answer is totally correct. But votes here seem to be pretty random anyway; I don't think they mean anything.) –  James Kanze Sep 20 '11 at 17:32
@JamesKanze: I meant pretty much what you said. There will be run-time code, but it will be limited in nature: Checking for a null pointer, adding a fixed offset determined at compile time. Static cast works without RTTI. Dynamic cast in general does not. (There is some overlap; dynamic cast can be used for upcasting.) –  David Hammen Sep 20 '11 at 20:22
@David That corresponds to what I understand was the intent of the committee. Although RTTI didn't exist at the time. Roughly, for non-virtual derivation, the generated code has to check for null, then add or subtract a constant; with virtual derivation, the constant is replaced with an entry in the vtable, which requires two memory accesses to get. IMHO, they should have done it anyway; two memory accesses aren't the end of the world. But the committee felt otherwise. –  James Kanze Sep 21 '11 at 8:17

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