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This is some kind of follow-up for this topic and deals about a little part of it. As with the previous topic, let's consider that our compiler has constexpr functions for std::initializer_list and std::array. Now, let's go straight to the point.

This works:

#include <array>
#include <initializer_list>

int main()
    constexpr std::array<int, 3> a = {{ 1, 2, 3 }};
    constexpr int a0 = a[0];
    constexpr int a1 = a[1];
    constexpr int a2 = a[2];
    constexpr std::initializer_list<int> b = { a0, a1, a2 };

    return 0;

This does not:

#include <array>
#include <initializer_list>

int main()
    constexpr std::array<int, 3> a = {{ 1, 2, 3 }};
    constexpr std::initializer_list<int> b = { a[0], a[1], a[2] };

    return 0;

It crashes with this error:

error: 'const std::initializer_list<int>{((const int*)(&<anonymous>)), 3u}' is not a constant expression

Even though I read some papers about constexpr and constant expressions meanwhile, this behaviour still does not make any sense for me. How come the first example is considered a valid constant expression and not the second one? I would welcome any explanation so that I can rest in peace afterwards.

NOTE: I will precise it right away, Clang will not be able to compile the first snippet since it does not implement the constexpr library additions that are planned for C++14. I used GCC 4.7.

EDIT: Ok, here comes the big example to show what is rejected and what is not:

#include <array>
#include <initializer_list>

constexpr int foo = 42;
constexpr int bar() { return foo; }
struct eggs { int a, b; };

int main()
    constexpr std::array<int, 3> a = {{ 1, 2, 3 }};
    constexpr int a0 = a[0];
    constexpr int a1 = a[1];
    constexpr int a2 = a[2];

    // From Xeo and Andy tests
    constexpr std::array<int, 1> a = { bar() }; // OK
    constexpr std::array<int, 3> b = {{ a[0], a[1], a[2] }}; // OK
    std::initializer_list<int> b = { a[0], a[1], a[2] }; // OK
    constexpr std::initializer_list<int> b = { a0, a1, a2 }; // OK
    constexpr std::initializer_list<int> b = { foo }; // OK
    constexpr std::initializer_list<int> c = { bar() }; // ERROR
    constexpr std::initializer_list<int> b = { a[0], a[1], a[2] }; // ERROR

    // From Matheus Izvekov and Daniel Krügler
    constexpr eggs good = { 1, 2 }; // OK
    constexpr std::initializer_list<eggs> bad = { { 1, 2 }, { 3, 4 } }; // ERROR
    constexpr std::initializer_list<eggs> bad2 = { good, good }; // ERROR

    return 0;
share|improve this question
How about "GCC has a bug"? :) (Not saying it has one, just a possibility.) And really, you should be able to test this without the constexpr additions by writing your own analogues. Also, what about constexpr std::array<int, 3> b = {{ a[0], a[1], a[2] }};? – Xeo Apr 17 '13 at 10:51
Maybe this helps narrowing down the issue – Andy Prowl Apr 17 '13 at 11:01
@Xeo Whatever I do with array seems to work fine (including your example, and Andy ones with only std::arrays instead of std::initializer_list). It seems that the problem only occurs with std::initializer_list at compile time. I did not manage to reproduce it without constexpr or with std::array. – Morwenn Apr 17 '13 at 12:04
@Xeo So, yeah, I want to believe it is a GCC bug, but generally speaking, I would rather be sure it does not come from my understanding of the language :) – Morwenn Apr 17 '13 at 12:05

I figured out what is going on here:

 constexpr std::initializer_list<int> b = { a[0], a[1], a[2] };

a[0] of type const int& implicitly converts to a temporary of type const int. Then g++ converts it to const int* to pass into the initializer_list private constructor. In the last step it takes address of a temporary, so it is not a constant expression.

The problem is in implicit conversion to const int. Example:

constexpr int v = 1;
const int& r = v; // ok
constexpr int& r1 = v; // error: invalid initialization of reference of
                       // type ‘int&’ from expression of type ‘const int’

The same behavior is in clang.

I think this conversion is legal, nothing says the opposite.

About const int& to const int conversion, [expr] paragraph 5:

If an expression initially has the type “reference to T” , the type is adjusted to T prior to any further analysis. The expression designates the object or function denoted by the reference, and the expression is an lvalue or an xvalue, depending on the expression.

The result of a[0] expression is the temporary xvalue of type const int in that case.

About implicit conversions in constexpr initializer, [dcl.constexpr] paragraph 9:

... Each implicit conversion used in converting the initializer expressions and each constructor call used for the initialization shall be one of those allowed in a constant expression.

About taking address of temporary, [expr.const] paragraph 2: invocation of a constexpr function with arguments that, when substituted by function invocation substitution, do not produce a constant expression; [ Example:

constexpr const int* addr(const int& ir) { return &ir; } // OK
static const int x = 5;
constexpr const int* xp = addr(x); // OK: (const int*)&(const int&)x is an
                                   // address contant expression
constexpr const int* tp = addr(5); // error, initializer for constexpr variable
                                   // not a constant expression;
                                   // (const int*)&(const int&)5 is not a
                                   // constant expression because it takes
                                   // the address of a temporary

— end example ]

share|improve this answer
The private ctor is not called with the elements you pass, it's called with a pointer to an array that is initialized from the elements you pass, and a size or a pointer to the end. – Xeo Apr 18 '13 at 17:33
I actually submitted a bug report to GCC. One of the guys manages to have g++ reject another example that does not involve any reference. – Morwenn Apr 18 '13 at 19:41
I point mostly at const int& to const int conversion, which causes such behavior and seems to be legal. First example shows the conversion in the raw. Part about ctor is to explain error message only. – Wlodzislav K. Apr 19 '13 at 15:22

Your examples are all ill-formed.

tl/dr: The initializer is non-constant because it refers to a different temporary each time the function is evaluated.

The declaration:

constexpr std::initializer_list<int> b = { a0, a1, a2 };

creates a temporary array of type const int [3] (C++11 [dcl.init.list]p5), then binds the std::initializer_list<int> object to that temporary as if by binding a reference to it (C++11 [dcl.init.list]p6).

Now, by C++11 [expr.const]p4,

For a literal constant expression of array or class type, each subobject [...] shall have been initialized by a constant expression. [...] An address constant expression [...] evaluates to the address of an object with static storage duration.

Since b has automatic storage duration, when the std::initializer_list<int> object binds to the const int [3] temporary, the temporary is also given automatic storage duration, so the initialization of b is not a constant expression because it refers to the address of an object that does not have static storage duration. So the declaration of b is ill-formed.

Why GCC accepts some of the constexpr std::initializer_list objects

In cases where the initializer is suitably trivial, GCC (and Clang) promote the array to global storage rather than creating a new temporary each time around. However, in GCC, this implementation technique leaks through to the language semantics -- GCC treats the array as having static storage duration, and accepts the initialization (as either an accidental or deliberate extension to the C++11 rules).

Workaround (Clang only)

You can make your examples valid by giving the std::initializer_list<int> objects static storage duration:

static constexpr std::initializer_list<int> b = { a0, a1, a2 };

This in turn gives static storage duration to the array temporary, which makes the initialization be a constant expression.

Using Clang and libc++ (with constexpr added to libc++'s <array> and <initializer_list> in the appropriate places), this tweak of adding static is sufficient for your examples to be accepted.

Using GCC, the examples are still rejected, with diagnostics such as:

<stdin>:21:61: error: ‘const std::initializer_list<int>{((const int*)(& _ZGRZ4mainE1c0)), 1u}’ is not a constant expression

Here, _ZGRZ4mainE1c0 is the mangled name of the lifetime-extended array temporary (with static storage duration), and we can see that GCC is implicitly calling the (private) initializer_list<int>(const int*, size_t) constructor. I am not sure why GCC is still rejecting this.

share|improve this answer

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