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Meaning of “const” last in a C++ method declaration?

I got a book, where there is written something like:

class Foo 
{
public:
    int Bar(int random_arg) const
    {
        // code
    }
};

What does it mean?

marked as duplicate by Tadeusz Kopec, sbi, Fred Larson, David Thornley, rmeador Jun 29 '10 at 15:28

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

  • 2
    Duplicate of stackoverflow.com/questions/751681/… – Tadeusz Kopec Jun 29 '10 at 13:51
  • 8
    It changes the type of this from Foo* const into const Foo* const. That has consequences. – sbi Jun 29 '10 at 13:55
  • I don't understand your edit. What exactly do you wanna know? If declaring two variables of type Foo will create multiple functions instances of Bar? – Janick Bernet Jun 29 '10 at 14:06
  • @inflagranti: Yes, exactly this I wanna know. – aPoC Jun 29 '10 at 14:08
  • 6
    @aPoC functions (or here methods) only exist once "in memory" (being static or not, it doesn't matter). They get passed a hidden parameter this which is a pointer to the calling instance. – ereOn Jun 29 '10 at 14:19
813

A "const function", denoted with the keyword const after a function declaration, makes it a compiler error for this class function to change a member variable of the class. However, reading of a class variables is okay inside of the function, but writing inside of this function will generate a compiler error.

Another way of thinking about such "const function" is by viewing a class function as a normal function taking an implicit this pointer. So a method int Foo::Bar(int random_arg) (without the const at the end) results in a function like int Foo_Bar(Foo* this, int random_arg), and a call such as Foo f; f.Bar(4) will internally correspond to something like Foo f; Foo_Bar(&f, 4). Now adding the const at the end (int Foo::Bar(int random_arg) const) can then be understood as a declaration with a const this pointer: int Foo_Bar(const Foo* this, int random_arg). Since the type of this in such case is const, no modifications of member variables are possible.

It is possible to loosen the "const function" restriction of not allowing the function to write to any variable of a class. To allow some of the variables to be writable even when the function is marked as a "const function", these class variables are marked with the keyword mutable. Thus, if a class variable is marked as mutable, and a "const function" writes to this variable then the code will compile cleanly and the variable is possible to change. (C++11)

As usual when dealing with the const keyword, changing the location of the const key word in a C++ statement has entirely different meanings. The above usage of const only applies when adding const to the end of the function declaration after the parenthesis.

const is a highly overused qualifier in C++: the syntax and ordering is often not straightforward in combination with pointers. Some readings about const correctness and the const keyword:

Const correctness

The C++ 'const' Declaration: Why & How

  • 5
    @ereOn, if you liked mutable, you might like this. The most common use-case for "mutable" is as a modifier for a mutex controlling access to a class instance. Just because you promise not to modify the instance, doesn't mean that what you read from it won't be modified by someone else holding a non-const reference to it. – Dmitry Rubanovich Apr 5 '15 at 21:12
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    @Janick, I've been learning c++ by myself for a year or two, never see any books cover an explanation like this and I feel it's really helpful. What type of books shall I read to learn these things like this implicit this pointer. – Steven Oct 10 '15 at 17:41
  • 3
    @Steven: I think the most helpful thing might be to actually read a C book and how some OO like things can be implemented in plain C. From that it's the more easily to see how C++ native OO functionality maps on more lower-level constructs in C and eventually down to the machine. – Janick Bernet Oct 12 '15 at 7:05
  • A great answer. But I find the 2nd paragraph a bit hard to read, not sure how the text can be improved though. Also if I understand correctly non-member function Foo_Bar(&f, 4); won't be able to access member variables in f (whether it's const or non-const case), because usually member variables are private – artm Feb 4 '17 at 0:04
  • 1
    2 more important points to note: 1) Static data members can still be modified. 2) Bitwise constness is checked here which means that the memory of the object which called the function is checked bit by bit and no change should be made in it. Which further tells us, If there is a int* data member, then the adress that this pointer contains inside the object memory cannot change, but the value at that location which is not part of object memory can change. – Sukrit Gupta Jan 23 at 4:18
41

Consider two class-typed variables:

class Boo { ... };

Boo b0;       // mutable object
const Boo b1; // non-mutable object

Now you are able to call any member function of Boo on b0, but only const-qualified member functions on b1.

12

Bar is guaranteed not to change the object it is being invoked on. See the section about const correctness in the C++ FAQ, for example.

  • 10
    Don't forget about mutable keyword. – Nikolai Fetissov Jun 29 '10 at 13:37
8

I always find it conceptually easier to think of that you are making the this pointer const (which is pretty much what it does).

  • 6
    Actually, not the this pointer itself is const, but what it points to, i.e. *this ;) – fredoverflow Jun 29 '10 at 16:33
8

Function can't change its parameters via the pointer/reference you gave it.

I go to this page every time I need to think about it:

http://www.parashift.com/c++-faq-lite/const-correctness.html

I believe there's also a good chapter in Meyers' "More Effective C++".

8

Similar to this question.

In essence it means that the method Bar will not modify non mutable member variables of Foo.

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