15

The first snippet compiles without any warnings (live example):

#include <iostream>

struct A {
  constexpr A(): i(5){}
  constexpr operator int() { return 5; }
  int i;
};

int main() {
    A a;
    int b[a]{ 0, 1, 2, 3, 4 };
    std::cout << b[4] << '\n';
}

Now alter the above snippet by returning i in the conversion operator (live example):

constexpr operator int() { return i; }

GCC warns that b is a VLA.

To me, both variants seem to conform to paragraph §5.19 [expr.const]/3 in C++14.

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2 Answers 2

Reset to default
17

You're performing an l-t-r conversion on i, but for [expr.const]/(2.7) not to be violated here, (2.7.3) must be applicable:

enter image description here

(2.7.1) concerns complete objects, (2.7.2) talks about string literals and (2.7.4) is about objects whose lifetime began within the evaluation of the expression - inapplicable since a's declaration precedes b's.

Define a as constexpr and the code is compliant.

A little addendum to clarify what the standard says: The expression inside the brackets must be a converted constant expression of type std::size_t ([dcl.array]/1), which is defined in [expr.const]/4 as

A converted constant expression of type T is an expression, implicitly converted to type T, where the converted expression is a constant expression and […requirements that are met…]

Thus, really, the standard is interested in whether or not 

constexpr std::size_t s = a;

would be valid. Which it isn't, for the aforementioned reasons - trying to use a subobject of a previously defined, non-constexpr object.

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6
  • Why does a have to undergo an lvalue-to-rvalue conversion in this case? I'm asking this, because the definition of a converted constant expression in §5.19/3 (N4140) doesn't seem to require such a conversion from a in the declaration int b[a]{ 0, 1, 2, 3, 4 };.
    – Ayrosa
    Dec 21, 2015 at 14:30
  • @Ayrosa Well, a never has to undergo one, but it's conversion operator must be called in order to convert it to std::size_t. (a is a converted constant expression of type std::size_t inside the brackets)
    – Columbo
    Dec 21, 2015 at 14:36
  • 1
    It took me a while to really grasp what you said and highlighted in your answer. Definitely, it's not an easy task for one, to fully understand the Standard. Great answer (+1).
    – Ayrosa
    Dec 21, 2015 at 15:04
  • @Ayrosa id-expression a has the class type A, but because of the bound of an array must be specified by a converted constant expression of type std::size_t, the implementation tries to find implicit conversion sequence to convert it to the destination type. See [conv] 4\3, 6. It finds user-defined conversion function constexpr operator int (), which is then used to initialize the temporary of type std::size_t, which value would be used as the bound of the array. But!
    – Eugene Zavidovsky
    Dec 21, 2015 at 15:11
  • 1
    @Ayrosa But! The resulting full-expression is not a core constant expression because, though, during that initialization, implied object argument a (see [over.match.conv] 13.3.1.5\2) is used as an lvalue (there is no l-t-r conversion for it), the conversion function, you defined, evaluate l-t-r for a subobject of a, which is not acceptable for a core constant expression, because neither the life-time of a begins within the evaluation of the considered full-expression, nor etc...
    – Eugene Zavidovsky
    Dec 21, 2015 at 15:16
4

Arrays size must be compile-time constants, but in the second example the initialization of A::i doesn't happen until run-time.

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2
  • @YSC Yes, but the variable a in the main function is not.
    – Some programmer dude
    Dec 21, 2015 at 14:10
  • 1
    And this is the real warning source, isn't it?
    – YSC
    Dec 21, 2015 at 14:11

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