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I have three classes:

class A {};

class B : virtual public A {};
class C : virtual public A {};

class D: public B, public C {};

Attempting a static cast from A* to B* I get the below error:

cannot convert from base A to derived type B via virtual base A
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up vote 51 down vote accepted

In order to understand the cast system you need to dive in the object model.

The classic representation of a simple hierarchy model is containment: that if B derives from A then the B object will in fact contain a A subobject alongside its own attributes.

With this model, downcasting is a simple pointer manipulation, by an offset known at compilation time which depends from the memory layout of B.

This is what static_cast do: a static cast is dubbed static because the computation of what is necessary for the cast is done at compile-time, be it pointer arithmetic or conversions (*).

However, when virtual inheritance kicks in things tend to become a bit more difficult. The main issue is that with virtual inheritance all subclasses share a same instance of the subobject. In order to do that, B will have a pointer to a A, instead of a A proper, and the A base class object will be instantiated outside of B.

Therefore, it's impossible at compilation time to be able to deduce the necessary pointer arithmetic: it depends on the runtime type of the object.

Whenever there is a runtime type dependency, you need RTTI (RunTime Type Information), and making use of RTTI for casts is the job of dynamic_cast.

In summary:

  • compile-time downcast: static_cast
  • run-time downcast: dynamic_cast

The other two are also compile-time casts, but they are so specific that it's easy to remember what they are for... and they are smelly, so better not use them at all anyway.

(*) As noted by @curiousguy in the comments, this only holds for downcasting. A static_cast allows upcasting regardless of virtual or simple inheritance, though then the cast is also unnecessary.

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4  
Nice answer which made me understand how virtual inheritance actually works ! +1 – undu Jun 12 '12 at 8:17
    
I like your answer, but the OP was apparently asking about an error for DOWNCASTING rather than upcasting. – h9uest Dec 21 '15 at 23:56
    
@h9uest: Thanks for pointing out the slip-up, I changed "up-casting" to "downcasting" and everything is now well. – Matthieu M. Dec 22 '15 at 7:33
    
False. static_cast can be used to convert a derived ptr to a virtual base ptr. – curiousguy Dec 26 '15 at 3:33
    
@curiousguy: Indeed... although you don't even need a cast then, so I didn't think about taking it into account. Which begs the question why downcasting is not available too. – Matthieu M. Dec 26 '15 at 13:54

As far as I know, you need to use dynamic_cast because the inheritance is virtual and you're downcasting.

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You can't use static_cast in this situation because the compiler doesn't know the offset of B relative to A at compile time. The offset must be calculated at run-time based on the exact type of the most derived object. Therefore you must use dynamic_cast.

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When converting a derived to a virtual base, you can use static_cast. – curiousguy Dec 26 '15 at 3:36
    
@curiousguy: yes, but the question is about converting base to derived. – ybungalobill Dec 26 '15 at 19:23
    
It isn't clear why your argument doesn't apply to derived to base also. – curiousguy Dec 26 '15 at 19:41
1  
@curiousguy: well, if you're asking why, then I think it is a good question and I'm not sure what the answer is. I speculate that this is because the derived to base cast is a matter of a simple indirection through the vtable, For the base to derived cast, on the other hand, you must perform the same (non constant time) algorithm as dynamic_cast does for the non-virtual inheritance. Thus there otherwise would not be a difference between static and dynamic casts for virtual inheritance. Or put another way, there is no analogy for non-virtual static_cast in the virtual-inheritance case. – ybungalobill Dec 26 '15 at 22:41

Yes, you have to use a dynamic_cast, but you'll have to make the base class A polymorphic, e.g. by adding a virtual dtor.

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1  
or adding at least one virtual method. – Liton Sep 19 '10 at 20:13

According standard docs,

Section 5.2.9 - 9, for Static Cast,

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 neither a virtual base class of D nor a base class of a virtual base class of D.

Hence, it is not possible and you should use dynamic_cast...

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$5.2.9/2- "An expression e can be explicitly converted to a type T using a static_cast of the form static_cast(e) if the declaration “T t(e);” is well-formed, for some invented temporary variable t (8.5)."

In your code you are attempting static_cast with 'T = B*' and 'e = A*'

Now 'B* t(A*)' is not well-formed in C++ (but 'A* t(B*)' is because 'A' is a virtual unambiguous and accessible base of 'B'. Therefore the code gives error.

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Wrong quotation. – curiousguy Dec 26 '15 at 3:35

I don't know if this is "safe" but.

Assuming

B derived from A (and A pure virtual)

Since I KNOW that a pointer to B still remains a pointer to B.

    class A
    {
            virtual void doSomething(const void* p) const =0;
    };

    class B
    {
    public:
            int value;
            virtual void doSomething(const void*p)const
            {
            const B * other = reinterpret_cast<const B*>(p);
            cout<<"hello!"<< other->value <<endl;
            }
    };

    int main()
    {
            B  foo(1),bar(2);
            A * p = &foo, q=&bar;
            p->doSomething(q);
            return 0;
    }

this program executes and correctly return printing "hello!" and the value of the other object (in this case "2").

by the way, what I'm doing is highly unsafe (personally I give a different ID to every class and I assert after reinterpret casting that current ID is equal to other ID to be sure we are doing something with 2 equal classes) and as you see I limited myself to "const" methods. Thus this will work with "non-const" methods, but if you do something wrong catching the bug will be almost unpossible. And even with assertion there's a 1 chance out of 4 billions to succeed assertion even when it is supposed to fail (assert(ID== other->ID);)

By the way.. A good OO design should not require this kinda of stuff, but in my case I tried to refactor/re-design the code without being able to drop the usage of reinterpret casting. generally speaking you CAN avoid this kind of things.

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Are you sure this is necessary? – Panayiotis Karabassis Nov 16 '12 at 18:35
    
that's specific to your problem. a re-design should prevent this in most cases (avoid my example if you can). oh dear I forget a "const". – DarioOO Nov 17 '12 at 6:42
    
I mean are you sure you need it? What if I give doSomething an int pointer? That would fail disastrously. Why not use a dynamic cast, and check the result? I don't know what your exact requirements are, but I believe, if you bring in the static polymorphism system (e.g. CRTP pattern) you can come up with something safer. – Panayiotis Karabassis Dec 14 '12 at 13:34
    
static polymorphism is not suitable in lot of cases, anyway in my actual code I'm doing that in a type-safe way, so users have no chance to passa "int*" around. Originally I had a "ID" system, but I found later better system.. still times faster than a dynamic cast. – DarioOO Jun 2 '13 at 0:39
    
if you are still interested how that code can be usefull you can take a look at a my recent project. void* tricks are used in more than one place.: code.google.com/p/infectorpp – DarioOO Jul 13 '13 at 13:21

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