Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Here is some code copied from Thinking in C++ Vol1 Chapter 10.

   #include <iostream>
   using namespace std;

   int x = 100;

   class WithStatic {
        static int x;
        static int y;
             void print() const {
             cout << "WithStatic::x = " << x << endl;
             cout << "WithStatic::y = " << y << endl;

what's the meaning of const for the function print()? Thanks!

share|improve this question

7 Answers 7

up vote 3 down vote accepted

I've heard this described previously as “a method that does not logically change the object”. It means that by calling this method the caller can expect the object’s state to remain the same after the method returns. Effectively, the this pointer becomes a constant pointer to a constant instance of that class, so member variables cannot be altered. The exception to this rule is if member variables are declared with mutable. If a class has mutable member variables, these can be modified by both non-const and const methods. Also, non-const methods cannot be called from within a const method.

Some people use mutable member variables to cache results of timely computations. In theory, the state of the object does not change (i.e. the only effect is that subsequent calls are quicker, but they produce the same results given the same input).

share|improve this answer
+1 for near completeness. –  jweyrich Apr 27 '10 at 3:33

It's a guarantee that the function won't modify the object at all (i.e. it's a "read-only" function). EDIT: Apparently, the exception to that rule is if an object has mutable members; those can be changed by both const and non-const functions.

Also, I'm glad to see somebody else learning from TIC++. It's a great resource for beginners.

share|improve this answer
Not completely true, mutable members can be changed. –  jweyrich Apr 27 '10 at 2:55
Oh, I wasn't aware of the mutable keyword. I'll change my answer. –  Maulrus Apr 27 '10 at 3:37
mutable is rather a new development in C++. –  Ben Voigt Apr 27 '10 at 5:20

the const means print() is not allowed to modify state variables not marked with mutable.

share|improve this answer
iirc, it's an optional compile-time check, so while you can, it's a really bad idea to try to modify stuff. –  res Apr 27 '10 at 2:35
@sreservoir, while it is only a compile-time check, you can (read: don't because you promised you wouldn't) modify non-const members, if you use a const_cast to remove the const from the this pointer. Members marked as mutable may be modified regardless of const-ness of the member function. –  Nathan Ernst Apr 27 '10 at 2:58
@sreservoir it's mutable, not volatile. –  jweyrich Apr 27 '10 at 3:26
@dreamlax: It's undefined behavior if the object pointed to by this was created const (if it's a const global, it might even be in read-only memory). If somebody created a const pointer to a writable object and passed it to a function that used const_cast, things work pretty much normally (unless you did something else bad like aliased a restrict pointer). –  Ben Voigt Apr 27 '10 at 3:37
volatile has nothing to do with this. mutable is the keyword you're looking for. –  CMircea Apr 27 '10 at 3:38

It means that it doesn't change any member variables of the class.


share|improve this answer

What it does is effectively make the this pointer be a const pointer to const instead of a const pointer to non-const. So, any time that you reference this in a const member function - either explicitly or implicitly - you're using a const pointer to const.

So, in the case of the class you have here, in any non-const function, the type of this is WithStatic const * while in the const functions, its type is const WithStatic * const.

Like with any pointer to const, you can't alter anything that it points to. So, you can't alter any of its member variables, and you can't call any of its non-const member functions.

Generally speaking, it's a good idea to make a member function be const if you can reasonably do so, because it guarantees that you're not going to alter the object's state, and you can call it with a const object.

It is possible for member variables to be altered if they're mutable or volatile, but those are more advanced topics that are probably better avoided until you're more familiar with the language. Certainly, you don't usually need to worry about them and shouldn't use them unless you need to. It's also possible to cast away the constness of the this pointer, at which point you could alter it, but IIRC, that's undefined behavior, and it's definitely generally considered a bad idea. So, there are instances where it's possible to alter an object's state within a const member function, but it's not normally possible and best avoided even when it is.

When you make a member function const, you're effectively promising that the object's state will not be changed by that function call (though there can obviously be side effects as evidenced by the fact that you can call functions like printf()).

share|improve this answer
No, volatile members can't be changed by const methods, only mutable ones. AFAIK, the only way to change non-mutable members is using const_cast. –  jweyrich Apr 27 '10 at 3:25
Actually no, the type of this is: const WithStatic * (for non-const functions) and const WithStatic * const (for const functions). Pointer const goes after the asterisk. –  CMircea Apr 27 '10 at 3:37
Okay. Pointer syntax fixed. This is why I hate C++ pointer syntax. It gets so messy. As for volatile. No, you can't change it within a const function, but it can change out from under you. So, it does fit in with the things that go against the const-ness of a const function, but no, a const function cannot itself change a volatile variable. –  Jonathan M Davis Apr 27 '10 at 4:11
Pointer syntax not fixed. Try "in any non-const function, the type of this is WithStatic * const". –  Ben Voigt Apr 27 '10 at 5:18
*Sigh*. Good catch. It was only half-fixed. Now it should be fully fixed. I guess that I was in too much of a hurry. It doesn't help that const* T is by far the most frequent way I use const with pointers. Pointer syntax is easy to mess up - especially if you're in a hurry and not actually compiling what you write. Thanks. –  Jonathan M Davis Apr 27 '10 at 16:36

If a member function is declared "const", it means that the function will not modify the object's state. This:

  • Documents the fact that the function will not modify state (useful to other developers).
  • Allows the compiler to make optimizations, knowing that the result of other "const" functions will not have changed as a result of calling that function (which allows function calls to be taken out of loops).
  • Enables one to call the function when the object is passed by const reference, const pointer, etc.

For all the above reasons, one should, as a general rule of thumb, declare a function as "const" if it does not logically modify the state of the object. If the logical state of the object changes, then don't use "const". As an aside, there are cases where the actual state changes but the logical state does not (e.g. caching), in which case one should still mark the function as "const", but one needs to use the "mutable" keyword with the caching variables in order to tell the compiler that modifying them actually doesn't change the logical state.

share|improve this answer

Intuitively, it means that the method doesn't modify the object on which it is called. But really, it means two things:

  • The method may be called on an object or object pointer declared as const.
  • Within the method, the this pointer becomes const. Consequently, all members (except those declared mutable) are const, i.e. read-only, within the context of the method. However, it may still modify:
    • data pointed to by members of the object it's called on
    • data accessed other than through the this pointer — including global data, data pointed to by the method's parameters, static members of the class, other objects of the class, even the same object (if it happens to have access to a non-const pointer to it or bypasses constancy using a const_cast).
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.