19

Is constexpr an indicator for the compiler or does it mandate a behaviour ?

The example at hand is the following :

template<typename T> 
std::size_t constexpr getID() { return typeid(T).hash_code(); }

hash_code is a runtime constant, yet this snippet would compile even though a compile time evaluation is requested with constexpr. Only after the return value is used where a compile time constant is expected, would we get noticed that this is not usable as a constexpr function.

So is constexpr a "hint" (much like the inline keyword) or "a binding request" to the compiler ?

  • 2
    Note that because this is a template, there isn't any function until you instantiate it with some T. – user395760 May 21 '14 at 6:41
  • In this example, you see instantiations of this function compiling – Nikos Athanasiou May 21 '14 at 6:46
  • @Mehrdad thnx for the correction – Nikos Athanasiou May 21 '14 at 6:48
  • inline isn't a hint either. – CB Bailey May 21 '14 at 7:17
  • 2
    @rubenvb: "As efficient as possible" is meaningless (well, QOI) waffle but the ODR rule changes (the real guts of what inline does) are a mandated behaviour change (at least in C++ which is what I was referring to in my original comment). – CB Bailey May 21 '14 at 9:27
7

From the C++11 Wiki page:

If a constexpr function or constructor is called with arguments which aren't constant expressions, the call behaves as if the function were not constexpr, and the resulting value is not a constant expression. Likewise, if the expression in the return statement of a constexpr function does not evaluate to a constant expression for a particular invocation, the result is not a constant expression.

The constexpr specifier thus expresses the possibility to evaluate something at compile time and is subject to some restrictions when used.


For your particular snippet it seems to me that the C++11 constraint:

exactly one return statement that contains only literal values, constexpr variables and functions

is not fulfilled, as hash_code is defined to be:

size_t hash_code() const;

In this case the standard draft n3242 says:

For a constexpr function, if no function argument values exist such that the function invocation substitution would produce a constant expression (5.19), the program is ill-formed; no diagnostic required.

I believe your example fits here.

  • 1
    So basically constexpr was a pointless addition to the language. – Mehrdad May 21 '14 at 6:47
  • 6
    @Mehrdad: Not at all. You can still call constexpr functions with compile time constant values and they can be evaluated at compile time, too. – usr1234567 May 21 '14 at 6:48
  • 4
    @user2799037: The point is not that they may be evaluated at compile time, but that they can be used for things that only accept constant expressions like template parameters or array sizes. – Jan Hudec May 21 '14 at 6:52
  • 2
    @user2799037: er, I didn't say it's a useless keyword. It's there because it has a use. What I said was that there was no need to add it to the language to begin with; they could have achieved it differently. They could have instead just stated that every function call be evaluated at compile-time if possible (i.e. if the result would be the same as it would be at runtime), making it unnecessary to have a keyword just for that purpose. – Mehrdad May 21 '14 at 6:56
  • 1
    @Jens: Trying to evaluate all functions at complie-time would give you the same result: If you use it where it needs to be evaluated at compile-time and it can't be evaluated at compile-time...you will get an error. So no need for a keyword..so as Mehrdad says: it's pointless! – mmmmmmmm May 21 '14 at 8:23
14

Is constexpr a “hint” (like inline) or “a binding request” to the compiler?

It is neither. Forget about when it is evaluated. Everything (with a few minor exceptions, notably involving volatile) is evaluated whenever the compiler deems it necessary to produce the behaviour of the C++ abstract machine. There isn't much else to say about when things are evaluated.

The compiler is free to produce code that evaluates what would be constant expressions at runtime if that doesn't produce a different behaviour. It is free to produce code that evaluates things not marked constexpr at compile-time if it has the smarts.

If not about compile-time vs runtime, what is constexpr about, then?

constexpr allows things to be treated as constant expressions. Anything marked constexpr must have the possibility of producing a constant expression in some way.

In the case of functions, they can be able to produce constant expressions with some arguments but not others. But as long as there is some set of arguments that can result in a constant expression, a function can be marked constexpr. If such a set of arguments is used in a function call, that expression is a constant expression. Does that mean it is evaluated at compile-time? See above. It's evaluated when the compiler deems appropriate. The only thing it means is that you can use it in a context requiring a constant expression.

For variables, either they are constant expressions or not. They have no arguments, so if constexpr they always have to be initialised with constant expressions.

TL;DR: constexpr is about tagging things as being usable in constant expressions, not about deciding when to evaluate them.


With that out of the way, it appears your function template is ill-formed. There is no set of arguments that could result in a constant expression. The standard doesn't require a diagnostic for this, though.

  • See an example explanation of a function that can be produce both constant expressions and non-constant expressions, even if all arguments are constant expressions: stackoverflow.com/a/13039987/46642. – R. Martinho Fernandes May 21 '14 at 9:16
  • Either the compiler is buggy, or this is a compiler extension : if the standard didn't change from n3242 it is explicitly stated that no diagnostic is required for that kind of error – Massimiliano May 21 '14 at 10:14
  • @Massimiliano thanks. – R. Martinho Fernandes May 21 '14 at 10:15
2

constexpr functions can be used to evaluate compile time constants. So it is possible to use it like:

 constexpr int func(int a) { return a+2; }

 char x[func(10)];

If func is called during runtime, the compiler can evaluate this expression before if possible. But that is not a must but normally done if the input is also const.

It is also important to have constexpr constructors. This is the only chance to get non POD classes constexpr objects.

    class Point
    {   
        private:    
            int x;
            int y;
        public:
            constexpr Point( int _x, int _y) : x(_x), y(_y) {}  
            constexpr int GetX() const { return x; }
    };  

    constexpr Point p{1,2};

    int main()
    {   

        char i[p.GetX()];
        return 0;
    }   
  • Can you expand on your point about non-POD classes? Is const std::string hello("hello"); not a const instance of a non-POD class? – CB Bailey May 21 '14 at 7:21
  • sorry for wrong wording. I mean constexpr objects! See added example! – Klaus May 21 '14 at 7:28
  • With an aggregate type you can create non-POD objects in constant expressions without a constructor (aggregates cannot have constructors). It's not PODness that matters. – R. Martinho Fernandes May 21 '14 at 9:32
1

The complete answer to your question has two aspects:

  1. A constexpr function can only be evaluated at compile-time when all arguments can be evaluated at compile-time. It can still be used as a normal function which is evaluated at runtime.

  2. An constexpr variable must be initialized with a value evaluated at compile-time. The compiler has to raise an error if it cannot do this.

You could assign the hash code to a constexpr variable and then get a compiler output:

#include <typeinfo>
#include <array>

template<typename T> 
std::size_t constexpr getID() { 

    return []() {constexpr size_t id = typeid(T).hash_code(); return id;}(); }

int main() {
    // both statement generate compiler errors
    //std::array<int, typeid(int).hash_code()> a;
    //constexpr size_t y = typeid(int).hash_code();

    size_t x = getID<int>();
}
  • What is an initialized value? Are there uninitialized values? – dyp May 21 '14 at 11:27
  • @dyp int i would be an uninitialized value because it has not been explicitly initialized by the programmer. Is there a better word for this? Maybe initialized constexpr variable? – Jens May 21 '14 at 13:11
  • It is not clear what a value is (as far as I know), but typically you say for int i; that i is the name of an object (an object is a region of storage) and which stores a value. So uninitialized variable or uninitialized object should be fine. IIRC, in C++1y, we'll get the notion of a indeterminate value; int x; not being initialized would have (contain) an indeterminate value. – dyp May 21 '14 at 16:42

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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