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What's the difference between constexpr and const?

  • When can I use only one of them?
  • When can I use both and how should I choose one?
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There was actually an article on this posted not too long ago. –  chris Jan 2 '13 at 1:42
thanks for one, but I'm looking for a more comprehensive answer :) –  MBZ Jan 2 '13 at 1:43
constexpr creates a compile-time constant; const simply means that value cannot be changed. –  0x499602D2 Jan 2 '13 at 1:44

3 Answers 3

up vote 48 down vote accepted

Basic meaning and syntax

Both keywords can be used in the declaration of objects as well as functions. The basic difference when applied to objects is this:

  • const declares an object as constant. This implies a guarantee that, once initialized, the value of that object won't change, and the compiler can make use of this fact for optimizations. It also helps prevent the programmer from writing code that modifies objects that were not meant to be modified after initialization.

  • constexpr declares an object as fit for use in what the Standard calls constant expressions. But note that constexpr is not the only way to do this.

When applied to functions the basic difference is this:

  • const can only be used for non-static member functions, not functions in general. It gives a guarantee that the member function does not modify any of the non-static data members.

  • constexpr can be used with both member and non-member functions, as well constructors. It declares the function fit for use in constant expressions. The compiler will only accept it if the function meets certain criteria (7.1.5/3,4), most importantly (†):

    • The function body must be non-virtual and extremely simple: Apart from typedefs and static asserts, only a single return statement is allowed. In the case of a constructor, only an initialization list, typedefs and static assert are allowed. (= default and = delete are allowed, too, though.)
    • The arguments and the return type must be literal types (i.e., generally speaking, very simple types, typically scalars or aggregates)

Constant expressions

As said above, constexpr declares both objects as well as functions as fit for use in constant expressions. A constant expression is more than merely constant:

  • It can be used in places that require compile-time evaluation, for example, template parameters and array-size specifiers:

    template <int N>
    class fixed_size_list
    { /*...*/ };
    fixed_size_list<X> mylist;     // <-- X must be an integer constant expression
    int numbers[X];   // <-- X must be an integer constant expression
  • But note:

    • Declaring something as constexpr does not necessarily guarantee that it will be evaluated at compile time. It can be used for such, but it can be used in other places that are evaluated at run-time, as well.

    • An object may be fit for use in constant expressions without being declared constexpr. Example:

      int main() {
        const int N = 3;
        int numbers[N] = { 1 , 2, 3 };   // <-- N is constant expression

    This is possible because N, being constant and initialized at declaration time with a literal, satisfies the criteria for a constant expression, even if it isn't declared constexpr.

So when do I actually have to use constexpr?

  • An object like N above can be used as constant expression without being declared constexpr. This is true for all objects that are:

    • const
    • of integral or enumeration type and
    • initialized at declaration time with an expression that is itself a constant expression

    [This is due to §5.19/2: A constant expression must not include a subexpressions that involves "an lvalue-to-rvalue modification unless [...] a glvalue of integral or enumeration type [...]". Thanks to Richard Smith for correcting my earlier claim that this was true of all literal types]

  • For a function to be fit for use in constant expressions, it must be explicitly declared constexpr; it is not sufficient for it merely to satisfy the criteria for constant-expression functions. Example:

    template <int N>
    class list
    { };
    constexpr int sqr1(int arg)
    { return arg*arg; }
    int sqr2(int arg)
    { return arg*arg; }
    int main()
      const int X = 2;
      list<sqr1(X)> mylist1; // OK; sqr1 is constexpr
      list<sqr2(X)> mylist2; // Wrong; sqr2 is not constexpr
      return 0;

When can I / should I use both, const and constexpr together?

a) In object declarations This is never necessary when both keywords refer to the same object to be declared. constexpr implies const.

constexpr const int N = 5;

is the same as

constexpr int N = 5;

However, note that there may be situations when the keywords each refer to different parts of the declaration:

static constexpr int N = 3;
int main()
  constexpr const int *NP = &N;
  return 0;

Here, NP is declared as an address constant-expression, i.e. an pointer that is itself a constant expression. (This is possible when the address is generated by applying the address operator to a static/global constant expression.) Here, both constexpr and const are required: constexpr always refers to the expression being declared (here NP), while const refers to int (it declares a pointer-to-const). Removing the const would render the expression illegal (because (a) a pointer to a non-const object cannot be a constant expression and (b) &N is in-fact a pointer-to-constant).

b) In member function declarations In C++11, constexpr implies const also for member functions. However, this is likely to change in C++14. According to the current drafts, constexpr will imply const only for objects, not for member functions, due to a proposed change to §7.1.5/8. Hence, a member function declared under C++11 as

constexpr void f();

will have to be declared as

constexpr void f() const;

under C++14 in order to still be usable as a const function. Best mark your constexpr member functions as const even now so as to avoid having to change a lot of code later on.

(†) The conditions for acceptable constexpr functions will probably be relaxed for C++14. A proposal by Richard Smith has recently been adopted into the C++14 draft.

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IMO the "not necessarily evaluated at compile time" is less helpful than thinking of them as "evaluated at compile time". The constraints on a constant expression mean that it would be relatively easy for a compiler to evaluate it. A compiler must complain if those constraints are not satisfied. Since there are no side effects, you can never tell a difference whether a compiler "evaluated" it or not. –  aschepler Jan 2 '13 at 5:27
@aschepler Sure. My main point there is that if you call a constexpr function on a non-constant expression, e.g. an ordinary variable, this is perfectly legal and the function will be used like any other function. It will not be evaluated at compile time (because it can't). Perhaps you think that's obvious -- but if I stated that a function declared as constexpr will always be evaluated at compile-time, it could be interpreted in the wrong way. –  jogojapan Jan 2 '13 at 5:34
Yes, I was talking about constexpr objects, not functions. I like to think of constexpr on objects as forcing compile time evaluation of values, and constexpr on functions as allowing the function to be evaluated at compile time or run time as appropriate. –  aschepler Jan 2 '13 at 5:38
That's true. Good comment. –  jogojapan Jan 2 '13 at 5:42
@jogojapan See 5.19/2: "an lvalue-to-rvalue conversion unless it is applied to [...]". Clang should enforce this correctly; please file bugs if you find otherwise. –  Richard Smith Jul 20 '13 at 17:40

const applies for variables, and prevents them from being modified in your code.

constexpr tells the compiler that this expression results in a compile time constant value, so it can be used in places like array lengths, assigning to const variables, etc. The link given by Oli has a lot of excellent examples.

Basically they are 2 different concepts altogether, and can (and should) be used together.

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According to book of "The C++ Programming Language 4th Editon" by Bjarne Stroustrup
const: meaning roughly ‘‘I promise not to change this value’’ (§7.5). This is used primarily to specify interfaces, so that data can be passed to functions without fear of it being modified.
The compiler enforces the promise made by const.
constexpr: meaning roughly ‘‘to be evaluated at compile time’’ (§10.4). This is used primarily to specify constants, to allow
For example:

const int dmv = 17; // dmv is a named constant
int var = 17; // var is not a constant
constexpr double max1 = 1.4*square(dmv); // OK if square(17) is a constant expression
constexpr double max2 = 1.4∗square(var); // error : var is not a constant expression
const double max3 = 1.4∗square(var); //OK, may be evaluated at run time
double sum(const vector<double>&); // sum will not modify its argument (§2.2.5)
vector<double> v {1.2, 3.4, 4.5}; // v is not a constant
const double s1 = sum(v); // OK: evaluated at run time
constexpr double s2 = sum(v); // error : sum(v) not constant expression

For a function to be usable in a constant expression, that is, in an expression that will be evaluated by the compiler, it must be defined constexpr.
For example:

constexpr double square(double x) { return x∗x; }

To be constexpr, a function must be rather simple: just a return-statement computing a value. A constexpr function can be used for non-constant arguments, but when that is done the result is not a constant expression. We allow a constexpr function to be called with non-constant-expression arguments in contexts that do not require constant expressions, so that we don’t hav e to define essentially the same function twice: once for constant expressions and once for variables.
In a few places, constant expressions are required by language rules (e.g., array bounds (§2.2.5, §7.3), case labels (§2.2.4, §9.4.2), some template arguments (§25.2), and constants declared using constexpr). In other cases, compile-time evaluation is important for performance. Independently of performance issues, the notion of immutability (of an object with an unchangeable state) is an important design concern (§10.4).

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there are still performance issues. Seems that constexpr function if evaluated at runtime may be slower than non-constexpr version of function. Also if we have a constant value should we prefer "const" or "constexpr"? (more a style question generated assembly looks the same) –  DarioOO Jan 11 '14 at 10:58

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