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According to the standard (§5.2.11) a const_cast casts away cv-qualifiers (const or volatile).

Here's a simple example. First you declare two functions taking a pointer and a reference:

class Bar { ... };
void foo_ptr(Bar*);
void foo_ref(Bar&);

then you create a reference-to-const:

Bar b;
const Bar& cb = b;

and then you can call either function by using the appropriate const_cast:


Here's my question: since const_cast cannot do what the other casts were designed for, isn't it obvious what you're casting to? In other words, why doesn't the language allow me to simply say:


I can think of only the following two reasons:

a) The compiler should stop me when I try to do something crazy, like:


and by forcing me to explicitly state the type I'm casting to it can then keep me from misbehaving. I find this (hypothetical) explanation weak, since it would be bizarre if the language favored allowing me to write down something wrong only to have the compiler correct me.

b) There is a possible ambiguity if the variable is both const and volatile. In that case the compiler would have no way of telling if I'm trying to cast away the one or the other (or both).

Is that why, or is there another reason?

share|improve this question
up vote 5 down vote accepted

const_cast can be used to add or remove const and volatile qualifiers. So, if such a syntax were allowed, all of the following would be legitimate target types of const_cast<>(&cb):

Bar*                 (1)
const Bar*           (2)
volatile Bar*        (3)
const volatile Bar*  (4)

You intend (1). (2) is usually silly, but it is conceivable that it might occur somewhere, perhaps in some template code. (3) and (4) are indeed the problems: you can remove the const qualification and add the volatile qualification all with a single cast.

You could replace the existing const_cast with a pair of casts, const_cast and volatile_cast, and prohibit case (2); then you could use either of them without the target type. However, then it's more difficult to know the type of the cast expression. To know whether a cast expression adds or removes qualification, you have to know what the type of the source expression is.

There's no reason you couldn't use a function template to get what you want:

template <typename T>
T* remove_const(const T* p) {
    return const_cast<T*>(p);

You could easily write similar functions for remove_volatile and for add_const and add_volatile, which are both implicit.

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Of course the operator also allows const_cast<>(&b) (where b is not const) and the same set of resultant types, so even if it didn't handle volatility, you would have to ask Alexandros whether const_cast<> should toggle constness or default to adding or removing it (the latter would make it a bit of a misnomer). As you say, in templates it's often desirable to get a const or non-const type without knowing what you started with. – Tony D Dec 8 '10 at 3:07
And we haven't even talked about multilevel pointers :) – Johannes Schaub - litb Dec 8 '10 at 3:45
@Tony: static_cast is preferable here because while it can add constness, it explicitly cannot remove constness. Alternatively, it is common to write an implicit_cast function template along the lines of template <typename T, typename U> T implicit_cast(U x) { return x; }. – James McNellis Dec 8 '10 at 4:12
@Tony: though this doesn't constitute proof, James is in good company on this. In Item 3 of Scott Meyers' Effective C++, 3rd ed. he does precisely that (use static_cast for adding const) and states: "The cast that adds const is just forcing a safe conversion (from a non-const object to a const one), so we use a static_cast for that. The one that removes const can be accomplished only via a const_cast, so we don't really have a choice there." – Alexandros Gezerlis Dec 8 '10 at 4:36
@Tony: The const_cast carries the same risk: you may inadvertently remove volatile qualification where you only intend to remove const qualification. const_cast should be used only to remove qualification; this way it stands out in source code more readily. The benefit of implicit_cast is that it is 100% safe; you can't perform any conversions with it other than those that would otherwise be allowed without any cast. – James McNellis Dec 8 '10 at 4:58

I think James McNellis already touched on the important reasons. const_castcan both add and remove constness/volatileness. It's not always clear what you want.

If I call const_cast on an argument of type const foo, does that mean I want to make it non-const, or add volatile to it? Or should it perhaps just keep the constqualifier? If I call it on an object of type (non-const) foo, should it add const? Or should it assume that I wanted to remove const-ness, and return an object of type (non-const) foo as well?

Another reason may simply be consistency.

We have static_cast<T>(x), dynamic_cast<T>(x), reinterpret_cast<T>(x) so it'd look odd to have a const_cast(x) without the template-like syntax.

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Regarding adding const: OK, but that just displaces the question (since you can add const in other ways) making it "why does const_cast need to allow you to add const?". – Alexandros Gezerlis Dec 8 '10 at 3:13
Regarding consistency: yes, indeed, that is a legitimate point. – Alexandros Gezerlis Dec 8 '10 at 3:13

The main reason is that using const_cast you can cast from

Foo * const * volatile * * 


Foo * * * volatile * const

Is it really obvious what the destination type is?

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