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Does using virtual inheritance in C++ have a runtime penalty in compiled code, when we call a regular function member from its base class? Sample code:

class A {
    public:
        void foo(void) {}
};
class B : virtual public A {};
class C : virtual public A {};
class D : public B, public C {};

// ...

D bar;
bar.foo ();
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That's not an interesting example. As the cost of bar.foo() is fixed (because the method is not virtual) and does not change with inheritance virtual or otherwise. –  Loki Astari Apr 5 '11 at 16:19
    
When you compare code generation between virtual and non-virtual functions|(base classes) , make sure the compiler has no idea what the dynamic type is! –  curiousguy Aug 5 '12 at 1:18
    
"As the cost of bar.foo() is fixed (because the method is not virtual)" that is not correct. The dynamic type is known here, so virtualness is irrelevant. foo could as well be virtual. –  curiousguy Aug 5 '12 at 4:23

5 Answers 5

up vote 13 down vote accepted

There may be, yes, if you call the member function via a pointer or reference and the compiler can't determine with absolute certainty what type of object that pointer or reference points or refers to. For example, consider:

void f(B* p) { p->foo(); }

void g()
{
    D bar;
    f(&bar);
}

Assuming the call to f is not inlined, the compiler needs to generate code to find the location of the A virtual base class subobject in order to call foo. Usually this lookup involves checking the vptr/vtable.

If the compiler knows the type of the object on which you are calling the function, though (as is the case in your example), there should be no overhead because the function call can be dispatched statically (at compile time). In your example, the dynamic type of bar is known to be D (it can't be anything else), so the offset of the virtual base class subobject A can be computed at compile time.

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2  
@James: I think you're confusing with virtual inheritance with virtual functions, aren't you? –  Nawaz Apr 5 '11 at 15:00
1  
@Nawaz: Nope. Given a B* to an arbitrary B object that might be the subobject of some derived class, what do you know about where the A base class subobject is relative to that B*? At compile time, you don't know where the A base class subobject is. –  James McNellis Apr 5 '11 at 15:06
    
@James: So how does the compile decide? –  Nawaz Apr 5 '11 at 15:08
    
@Nawaz: The compiler doesn't decide anything: it generates code to thunk through a vptr or a lookup table or to use some other implementation-specific method to locate the base class subobject. –  James McNellis Apr 5 '11 at 15:09
1  
@Martin: My understanding is that you just need something along the lines of A* a_ptr = b_ptr + b_ptr->vtable[index_of_offset_of_virtual_base_A] (conceptually). For a given derived class (like D), the A subobject is located at a known offset from the B subobject. However, if you have a B* pointing to some arbitrary object, you don't know relative to that pointer where the A subobject is without checking the vtable because the most derived type might be B or D or [something else]. (I may not be expressing myself clearly here; I've only just gotten coffee this morning.) –  James McNellis Apr 5 '11 at 16:20

Yes, virtual inheritance has a run-time performance overhead. This is because the compiler, for any pointer/reference to object, cannot find it's sub-objects at compile-time. In constrast, for single inheritance, each sub-object is located at a static offset of the original object. Consider:

class A { ... };
class B : public A { ... }

The memory layout of B looks a little like this:

| B's stuff | A's stuff |

In this case, the compiler knows where A is. However, now consider the case of MVI.

class A { ... };
class B : public virtual A { ... };
class C : public virtual A { ... };
class D : public C, public B { ... };

B's memory layout:

| B's stuff | A's stuff |

C's memory layout:

| C's stuff | A's stuff |

But wait! When D is instantiated, it doesn't look like that.

| D's stuff | B's stuff | C's stuff | A's stuff |

Now, if you have a B*, if it really points to a B, then A is right next to the B- but if it points to a D, then in order to obtain A* you really need to skip over the C sub-object, and since any given B* could point to a B or a D dynamically at run-time, then you will need to alter the pointer dynamically. This, at the minimum, means that you will have to produce code to find that value by some means, as opposed to having the value baked-in at compile-time, which is what occurs for single inheritance.

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At least in a typical implementation, virtual inheritance carries a (small!) penalty for (at least some) access to data members. In particular, you normally end up with an extra level of indirection to access the data members of the object from which you've derived virtually. This comes about because (at least in the normal case) two or more separate derived classes have not just the same base class, but the same base class object. To accomplish this, both of the derived classes have pointers to the same offset into the most derived object, and access those data members via that pointer.

Although it's technically not due to virtual inheritance, it's probably worth noting that there's a separate (again, small) penalty for multiple inheritance in general. In a typical implementation of single inheritance, you have a vtable pointer at some fixed offset in the object (quite often the very beginning). In the case of multiple inheritance, you obviously can't have two vtable pointers at the same offset, so you end up with a number of vtable pointers, each at a separate offset in the object.

IOW, the vtable pointer with single inheritance is normally just static_cast<vtable_ptr_t>(object_address), but with multiple inheritance you get static_cast<vtable_ptr_t>(object_address+offset).

Technically, the two are entirely separate -- but of course nearly the only use for virtual inheritance is in conjunction with multiple inheritance, so it's semi-relevant anyway.

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Concretely in Microsoft Visual C++ there is an actual difference in pointer-to-member sizes. See #pragma pointers_to_members. As you can see in that listing - the most general method is "virtual inheritance" which is distinct from multiple inheritance which in turn is distinct from single inheritance.

That implies that more information is needed to resolve a pointer-to-member in the case of presence of virtual inheritance, and it will have a performance impact if only through the amount of data taken up in the CPU cache - though likely also in the length of the lookup of the member or the number of jumps needed.

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I think, there is no runtime penalty for virtual inheritance. Don't confuse virtual inheritance with virtual functions. Both are two different things.

virtual inheritance ensures that you've only one sub-object A in instances of D. So I don't think there would be runtime penalty for it alone.

However, there can arise cases where this sub-object cannot be known at compile time, so in such cases there would runtime penalty for virtual inheritance. One such case is described by James in his answer.

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1  
Actually there may be one. There is an extra pointer stored in all classes which inherits virtually from A, to locate this one subobject. In OP's case however, the compiler can statically determine where the A subobject resides. –  Alexandre C. Apr 5 '11 at 15:00
1  
@Alexandre: Interesting. Could you explain that a bit more? Is that implementation defined? –  Nawaz Apr 5 '11 at 15:02
    
the vptr mechanism for virtual inheritance is the same as with virtual methods. Have a look at this article: Solving the Diamond Problem with Virtual Inheritance EDIT: I mean, it uses virtual pointers, which may cause a slight runtime penalty. –  Assambar Apr 5 '11 at 15:08
    
May be this answer was correct. I have raised another question though. Downvoting is not completely justified. –  iammilind Feb 25 '12 at 13:31

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