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Update: I posted my own answer below And there's a longer version of this matter here: http://scrupulousabstractions.tumblr.com/post/38460349771/c-11-type-safe-use-of-integer-user-defined-literals


I've made a simple constexpr user defined literal _X that gets the value as an unsigned long long (that's how numeral user defined literals work: http://en.cppreference.com/w/cpp/language/user_literal), and then I make sure that the value fits in a signed long long.

It all works well (too big values cause compilation error), but only when I explicitly create a variable such as

constexpr auto a= 150_X;

If instead I write something typical like

cout << 150_X << endl;;

the tests are not performed at compile time.

  • Are constexpr functions only executed at compile time if they are assigned to a constexpr variable? (I could not find that in the standard)

  • Is it possible to achieve the safe behaviour of _X that I'm looking for?

Full example:


inline constexpr long long testConv(unsigned long long v) {
  return (v > 100 ) ? throw std::exception() : v; 
} // will eventually use actual limit from numeric_limits

inline constexpr long long operator "" _X(unsigned long long f) { 
  return testConv(f) ;

int main(){
  constexpr auto a= 5_X;
  std::cout << a << std::endl;
  std::cout << 200_X << std::endl;  // This bad literal is accepted at compile time
  constexpr auto c=250_X;           // This bad literal is not accepted at compile time
  std::cout << c << std::endl;

oh, for reference: I used gcc4.7.2.

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3 Answers 3

constexpr functions may be executed at compile time; that is, they are eligible to be used in constant expressions. If they're not used in a constant expression, there's no point executing them at compile time, although I think it's allowed.

Since you're not allowed to declare a parameter as constexpr (section 7.1.5/1) [1], I don't think there is any way to force evaluation of operator "" _X(unsigned long long) at compile time, but you can probably do it with template<char...> operator "" _X()

If the constexpr function is called within a constant expression, the argument will be a constant expression (and if it is not, then the call is not a constant expression). However, you cannot force the call to be a constant expression by declaring the parameter to be constexpr, because you're not allowed to declare parameters as constexpr, see reference to standard.

[Note 1]: Thanks to @LightnessRacesInOrbit for searching the standard to justify the claim in paragraph two.

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Since you're not allowed to declare a parameter as constexpr Hmm, really? –  Lightness Races in Orbit Dec 13 '12 at 22:10
Hmm yes really (7.1.5/1) - but the constexpr requirement is "inherited" from the function being called, when it is being called as part of a constant expression –  Lightness Races in Orbit Dec 13 '12 at 22:11
@LightnessRacesinOrbit: it's only "inherited" if the function is called as part of a constant expression. You cannot write the function with a constexpr parameter in order to insist that it be part of a constant expression. Was that not clear? –  rici Dec 13 '12 at 22:13
I get it now, having looked it up. Was it not clear when? –  Lightness Races in Orbit Dec 13 '12 at 22:13
@LightnessRacesinOrbit: when I wrote the answer :) –  rici Dec 13 '12 at 22:14

Constexpr functions need not be executed at compile-time. But your goal can be achieved. For better understanding of the problem, and an example how to create a iteral that is always evaluated at compile-time, I recommend this post.

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Thank you, I had already posted my answer when you wrote this. Templates and manual parsing is the way... +1 for you nice blog (which I already follow). –  Johan Lundberg Dec 13 '12 at 23:10
up vote 0 down vote accepted

Self answer: I found a complete solution, inspired by the comments and other answers to my question, and other questions such as http://stackoverflow.com/a/13384317/1149664.

The solution is to use the template form of user defined literals and sum up the number manually, multiplying the sum based on the already parsed digits by 10.

I wrote a detailed version of this self-answer here: http://scrupulousabstractions.tumblr.com/post/38460349771/c-11-type-safe-use-of-integer-user-defined-literals

template<char... Chars>
int operator"" _steps(){
  return {litparser<0,Chars...>::value};

Litparser is a little template meta-program which takes a list of characters as arguments expanded from the input characters held by the Chars parameter pack.

typedef unsigned long long ULL;

// Delcare the litparser 
template<ULL Sum, char... Chars> struct litparser;

// Specialize on the case where there's at least one character left:
template<ULL Sum, char Head, char... Rest>
struct litparser<Sum, Head, Rest...> {
// parse a digit. recurse with new sum and ramaining digits
  static const ULL value = litparser<
    (Head <'0' || Head >'9') ? throw std::exception() : 
    Sum*10 + Head-'0' , Rest...>::value;

// When 'Rest' finally is empty, we reach this terminating case
template<ULL Sum>  struct litparser<Sum> {
  static const ULL value = Sum;
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