1. Short answer: It works irrespective of it being declared
constexpr, because you're defining an object with static storage duration (that is not a string literal - it stores a copy of the contents of one), and its address is a constant expression. Regarding linkage,
str2 has internal linkage, but that's fine - its address can be used as a non-type template argument.
In C++11 and 14, [14.3.2p1] says the following:
A template-argument for a non-type, non-template template-parameter
shall be one of:
- a constant expression (5.19) that designates the address of a complete object with static storage duration and external or internal
linkage or a function with external or internal linkage, including
function templates and function template-ids but excluding non-static
class members, expressed (ignoring parentheses) as
where the id-expression is the name of an object or function, except
& may be omitted if the name refers to a function or array
and shall be omitted if the corresponding template-parameter is a
So, you can use the address of an object with static storage duration, but the object has to be identified by a name with linkage (internal or external), and the way you're expressing that address is restricted. (String literals are not names and don't have linkage.)
In short, even
char str1 = "Test 1"; works.
static char str1 = "Test 1"; is fine as well; GCC 5.1.0 rejects it, but I think that's a bug; Clang 3.6.0 accepts it.
str2's linkage, C++11 and 14 [3.5p3] says:
A name having namespace scope (3.3.6) has internal linkage if
it is the name of
- a non-volatile variable that is explicitly declared
constexpr and neither explicitly declared
extern nor previously
declared to have external linkage;
N4431 has changed that slightly, as a result of DR 1686, to:
- a variable of non-volatile const-qualified type that is neither explicitly declared
extern nor previously declared to have external
reflecting the fact that
constexpr implies const-qualification for objects.
2. Short answer: For C++11 and 14, see above; for draft C++1z,
str3 is not a constant expression, as the pointer itself is not
constexpr, and it's also the address of a string literal.
str4 is constant, but still an address of a string literal.
In the current working draft, N4431, the constraints on non-type template arguments have been relaxed. [14.3.2p1] now says:
A template-argument for a non-type template-parameter shall be a
converted constant expression (5.20) of the type of the
template-parameter. For a non-type template-parameter of reference or
pointer type, the value of the constant expression shall not refer to
(or for a pointer type, shall not be the address of):
- a subobject (1.8),
- a temporary object (12.2),
- a string literal (2.13.5),
- the result of a
typeid expression (5.2.8), or
- a predefined
__func__ variable (8.4.1).
And those are all the restrictions. The converted constant expression part is pretty important; the full definition is long, but one part relevant to our case is that the address of an object with static storage duration is such an expression.
Also relevant is that, according to [5.20p2.7], an lvalue-to-rvalue conversion applied to
a non-volatile glvalue that refers to a non-volatile object defined
constexpr, or that refers to a non-mutable sub-object of such an
also satisfies the conditions for being a constant expression. This allows us to use some
constexpr pointer variables as non-type template arguments. (Note that simply declaring a variable
const is not enough, as it can be initialized with a non-constant expression.)
So, something like
constexpr const char* str3 = str1; is fine. It's accepted by Clang 3.6.0 in C++1z mode (and rejected in C++14 mode); GCC 5.1.0 still rejects it - it looks like it hasn't implemented the updated rules yet.
Still, what's wrong with string literals? Here's the problem (N4431 [2.13.5p16]):
Evaluating a string-literal results in a string literal object with
static storage duration, initialized from the given characters as
specified above. Whether all string literals are distinct (that is,
are stored in nonoverlapping objects) and whether successive
evaluations of a string-literal yield the same or a different object
An implementation is allowed to do lots of things with string literals: mix, match, make them overlap (entirely or partially), make 7 copies from the same translation unit - whatever. That makes the address of a string literal unusable as a non-type template argument.