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What is the purpose of the final keyword in C++11 for functions? I understand it prevents function overriding by derived classes, but if this is the case, then isn't it enough to declare as non-virtual your final functions? Is there another thing I'm missing here?

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"isn't it enough to declare as non-virtual your "final" functions" No, overriding functions are implicitly virtual whether you use the virtual keyword or not. – ildjarn Jan 11 '12 at 18:29
@ildjarn that's not true if they weren't declared as virtual in the super class, you can't derive from a class and transform a non-virtual method into a virtual one.. – Dan O Jan 11 '12 at 18:33
@DanO i think you can't override but you can "hide" a method that way.. which leads to many problems as people don't mean to hide methods. – Alex Kremer Jan 11 '12 at 18:39
@ildjarn i think you meant that you don't have to specify 'virtual' keyword in the terminal class.. otherwise you are wrong. – Alex Kremer Jan 11 '12 at 18:41
@DanO : If it's not virtual in the super class then it wouldn't be "overriding". – ildjarn Jan 11 '12 at 18:41
up vote 59 down vote accepted

What you are missing, as idljarn already mentioned in a comment is that if you are overriding a function from a base class, then you cannot possibly mark it as non-virtual:

struct base {
   virtual void f();
struct derived : base {
   void f() final;       // virtual as it overrides base::f
struct mostderived : derived {
   //void f();           // error: cannot override!
share|improve this answer
Thanks! this is the point I was missing : ie that even your "leaf" classes need to mark their function as virtual even if they intend to override functions, and not to be overridden themselves – lezebulon Jan 11 '12 at 18:42
@lezebulon: Your leaf classes do not need to mark a function as virtual if the super class declared it as virtual. – Dan O Jan 11 '12 at 18:48
The methods in the leaf classes are implicitly virtual if they are virtual in the base class. I think that compilers should warn if this implicit 'virtual' is missing. – Aaron McDaid Jan 11 '12 at 19:09
@AaronMcDaid: Compilers usually warn about code that, being correct, might cause confusion or errors. I have never seen anyone surprised by this particular feature of the language in a way that could cause any problem, so I don't really know how usefull that error might be. On the contrary, forgetting the virtual can cause errors, and C++11 added the override tag to a function that will detect that situation and fail to compile when a function that is meant to override actually hides – David Rodríguez - dribeas Jan 12 '12 at 16:08
From GCC 4.9 change notes: "New type inheritance analysis module improving devirtualization. Devirtualization now takes into account anonymous name-spaces and the C++11 final keyword" - so it's not just syntactic sugar, it also has a potential optimization benefit. – kfsone Jan 11 '14 at 0:24
  • It is to prevent a class from being inherited. From Wikipedia:

    C++11 also adds the ability to prevent inheriting from classes or simply preventing overriding methods in derived classes. This is done with the special identifier final. For example:

    struct Base1 final { };
    struct Derived1 : Base1 { }; // ill-formed because the class Base1 
                                 // has been marked final
  • It is also used to mark a virtual function so as to prevent it from being overridden in the derived classes:

    struct Base2 {
        virtual void f() final;
    struct Derived2 : Base2 {
        void f(); // ill-formed because the virtual function Base2::f has 
                  // been marked final

Wikipedia further makes an interesting point:

Note that neither override nor final are language keywords. They are technically identifiers; they only gain special meaning when used in those specific contexts. In any other location, they can be valid identifiers.

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thanks, but I forgot to mention that my question concerned the use of "final" with methods – lezebulon Jan 11 '12 at 18:29
You did mention it @lezebulon :-) "what is the purpose of the "final" keyword in C++11 for functions". (my emphasis) – Aaron McDaid Jan 11 '12 at 18:35
that's because I edited it :) – lezebulon Jan 11 '12 at 18:39
You edited it? I don't see any message that says "edited x minutes ago by lezebulon". How did that happen? Maybe you edited it very quickly after submitting it? – Aaron McDaid Jan 11 '12 at 19:03
@Aaron : Edits made within five minutes after posting aren't reflected in the revision history. – ildjarn Jan 11 '12 at 20:56

"final" also allows a compiler optimization to bypass the indirect call:

class IAbstract
  virtual void DoSomething() = 0;

class CDerived : public IAbstract
  void DoSomething() final { m_x = 1 ; }

  void Blah( void ) { DoSomething(); }


with "final", the compiler can call CDerived::DoSomething() directly from within Blah(), or even inline. Without it, it has to generate an indirect call inside of Blah() because Blah() could be called inside a derived class which has overridden DoSomething().

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Nothing to add to the semantic aspects of "final".

But I'd like to add to chris green's comment that "final" might become a very important compiler optimization technique in the not so distant future. Not only in the simple case he mentioned, but also for more complex real-world class hierarchies which can be "closed" by "final", thus allowing compilers to generate more efficient dispatching code than with the usual vtable approach.

One key disadvantage of vtables is that for any such virtual object (assuming 64-bits on a typical Intel CPU) the pointer alone eats up 25% (8 of 64 bytes) of a cache line. In the kind of applications I enjoy to write, this hurts very badly. (And from my experience it is the #1 argument against C++ from a purist performance point of view, i.e. by C programmers.)

In applications which require extreme performance, which is not so unusual for C++, this might indeed become awesome, not requiring to workaround this problem manually in C style or weird Template juggling.

This technique is known as Devirtualization. A term worth remembering. :-)

There is a great recent speech by Andrei Alexandrescu which pretty well explains how you can workaround such situations today and how "final" might be part of solving similar cases "automatically" in the future (discussed with listeners):

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8 is 25% of 64? – ildjarn Mar 31 '15 at 0:08
Maybe in the not so distant future it will be! – luk2302 May 10 '15 at 15:44

Final cannot be applied to non-virtual functions.

error: only virtual member functions can be marked 'final'

It wouldn't be very meaningful to be able to mark a non-virtual method as 'final'. Given

struct A { void foo(); };
struct B : public A { void foo(); };
A * a = new B;
a -> foo(); // this will call A :: foo anyway, regardless of whether there is a B::foo

a->foo() will always call A::foo.

But, if A::foo was virtual, then B::foo would override it. This might be undesirable, and hence it would make sense to make the virtual function final.

The question is though, why allow final on virtual functions. If you have a deep hierarchy:

struct A            { virtual void foo(); };
struct B : public A { virtual void foo(); };
struct C : public B { virtual void foo() final; };
struct D : public C { /* cannot override foo */ };

Then the final puts a 'floor' on how much overriding can be done. Other classes can extend A and B and override their foo, but it a class extends C then it is not allowed.

So it probably doesn't make sense to make the 'top-level' foo final, but it might make sense lower down.

(I think though, there is room to extend the words final and override to non-virtual members. They would have a different meaning though.)

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thanks for the example, it's something I was unsure about. But still : what is the point to have a final (and virtual) function? Basically you would never be able to use the fact that the function is virtual since it can't be overriden – lezebulon Jan 11 '12 at 18:37
@lezebulon, I edited my question. But then I noticed DanO's answer - it's a good clear answer of what I was trying to say. – Aaron McDaid Jan 11 '12 at 21:24
I'm not an expert, but I feel that sometimes it may make sense to make a top-level function final. For example, if you know you want all Shapes to foo()—something predefined and definite that no derived shape should modify. Or, am I wrong and there's a better pattern to employ for that case? EDIT: Oh, maybe because in that case, one should simply not make the top-level foo() virtual to begin with? But still, it can be hidden, even if called correctly (polymorphically) via Shape*... – Andrew Cheong Aug 18 '14 at 15:51

final adds an explicit intent to not have your function overridden, and will cause a compiler error should this be violated:

struct A {
    virtual int foo(); // #1
struct B : A {
    int foo();

As the code stands, it compiles, and B::foo overrides A::foo. B::foo is also virtual, by the way. However, if we change #1 to virtual int foo() final, then this is a compiler error, and we are not allowed to override A::foo any further in derived classes.

Note that this does not allow us to "reopen" a new hierarchy, i.e. there's no way to make B::foo a new, unrelated function that can be independently at the head of a new virtual hierarchy. Once a function is final, it can never be declared again in any derived class.

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The final keyword allows you to declare a virtual method, override it N times, and then mandate that 'this can no longer be overridden'. It would be useful in restricting use of your derived class, so that you can say "I know my super class lets you override this, but if you want to derive from me, you can't!".

struct Foo
   virtual void DoStuff();

struct Bar : public Foo
   void DoStuff() final;

struct Babar : public Bar
   void DoStuff(); // error!

As other posters pointed out, it cannot be applied to non-virtual functions.

One purpose of the final keyword is to prevent accidental overriding of a method. In my example, DoStuff() may have been a helper function that the derived class simply needs to rename to get correct behavior. Without final, the error would not be discovered until testing.

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A use-case for the 'final' keyword that I am fond of is as follows:

// This pure abstract interface creates a way
// for unit test suites to stub-out Foo objects
class FooInterface
   virtual void DoSomething() = 0;
   virtual void DoSomethingImpl() = 0;

// Implement Non-Virtual Interface Pattern in FooBase using final
// (Alternatively implement the Template Pattern in FooBase using final)
class FooBase : public FooInterface
    virtual void DoSomething() final { DoFirst(); DoSomethingImpl(); DoLast(); }
    virtual void DoSomethingImpl() { /* left for derived classes to customize */ }
    void DoFirst(); // no derived customization allowed here
    void DoLast(); // no derived customization allowed here either

// Feel secure knowing that unit test suites can stub you out at the FooInterface level
// if necessary
// Feel doubly secure knowing that your children cannot violate your Template Pattern
// When DoSomething is called from a FooBase * you know without a doubt that
// DoFirst will execute before DoSomethingImpl, and DoLast will execute after.
class FooDerived : public FooBase
    virtual void DoSomethingImpl() {/* customize DoSomething at this location */}
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