I would like to use the name of a type at compile time. For example, suppose I've written:
constexpr size_t my_strlen(const char* s)
{
const char* cp = s;
while(*cp != '\0') { cp++; };
return cp - s;
}
and now I want to have:
template <typename T>
constexpr auto type_name_length = my_strlen(typeid(T).name());
But alas, typeid(T).name() is just const char*, not constexpr... is there some other, constexpr way to get a type's name?
Well, you could, sort of, but probably not quite portable:
struct string_view
{
char const* data;
std::size_t size;
};
inline std::ostream& operator<<(std::ostream& o, string_view const& s)
{
return o.write(s.data, s.size);
}
template<class T>
constexpr string_view get_name()
{
char const* p = __PRETTY_FUNCTION__;
while (*p++ != '=');
for (; *p == ' '; ++p);
char const* p2 = p;
int count = 1;
for (;;++p2)
{
switch (*p2)
{
case '[':
++count;
break;
case ']':
--count;
if (!count)
return {p, std::size_t(p2 - p)};
}
}
return {};
}
And you can define your desired type_name_length as:
template <typename T>
constexpr auto type_name_length = get_name<T>().size;
DEMO (works for clang & g++)
__FUNCSIG__. It appears to emit the fully-substituted/bound types, as though the function were explicitly instantiated, as opposed to GCC's hybrid output. For example: void __cdecl foo<double>(const double &), which looks less helpful to me at a glance. (GCC still makes some strange distinction between dependent vs. free types, or maybe deduced vs. computed types, when performing substitutions.) I think reflection is highly underrated and under-supported, esp. with Concepts so far over the horizon...
foo followed by equally many opening and closing <> pairs - but a type could be T (W<X>::*operator<)(Y<Z>), etc. - I'm sure there are other caveats (my syntax highlighter has 'experimental' template highlighting with lots of issues, hence the hesitation.)
Edit: Updated based on this answer to the non-constexpr-specific question; it is the result of refinements by several people including @HowardHinnant, @康桓瑋 @Val and myself.
The language standard does not - to my knowledge - provide any facility for obtaining type names. So, we resort to compiler-specific approaches. This works with GCC, clang and MSVC.
#include <string_view>
// If you can't use C++17's standard library, you'll need to use the GSL
// string_view or implement your own struct (which would not be very difficult,
// since we only need a few methods here)
template <typename T> constexpr std::string_view type_name();
template <>
constexpr std::string_view type_name<void>()
{ return "void"; }
namespace detail {
using type_name_prober = void;
template <typename T>
constexpr std::string_view wrapped_type_name()
{
#ifdef __clang__
return __PRETTY_FUNCTION__;
#elif defined(__GNUC__)
return __PRETTY_FUNCTION__;
#elif defined(_MSC_VER)
return __FUNCSIG__;
#else
#error "Unsupported compiler"
#endif
}
constexpr std::size_t wrapped_type_name_prefix_length() {
return wrapped_type_name<type_name_prober>().find(type_name<type_name_prober>());
}
constexpr std::size_t wrapped_type_name_suffix_length() {
return wrapped_type_name<type_name_prober>().length()
- wrapped_type_name_prefix_length()
- type_name<type_name_prober>().length();
}
} // namespace detail
template <typename T>
constexpr std::string_view type_name() {
constexpr auto wrapped_name = detail::wrapped_type_name<T>();
constexpr auto prefix_length = detail::wrapped_type_name_prefix_length();
constexpr auto suffix_length = detail::wrapped_type_name_suffix_length();
constexpr auto type_name_length = wrapped_name.length() - prefix_length - suffix_length;
return wrapped_name.substr(prefix_length, type_name_length);
}
enum func::Local (which is of course quite nice for diagnostics, though).
An alternative answer that can be used in template, now it can run with g++ and clang++ and msvc.
Modified from Answer @einpoklum above: https://stackoverflow.com/a/56600402/12529885
#include <iostream>
#include <string_view>
template<typename T>
struct TypeName {
constexpr static std::string_view fullname_intern() {
#if defined(__clang__) || defined(__GNUC__)
return __PRETTY_FUNCTION__;
#elif defined(_MSC_VER)
return __FUNCSIG__;
#else
#error "Unsupported compiler"
#endif
}
constexpr static std::string_view name() {
size_t prefix_len = TypeName<void>::fullname_intern().find("void");
size_t multiple = TypeName<void>::fullname_intern().size() - TypeName<int>::fullname_intern().size();
size_t dummy_len = TypeName<void>::fullname_intern().size() - 4*multiple;
size_t target_len = (fullname_intern().size() - dummy_len)/multiple;
std::string_view rv = fullname_intern().substr(prefix_len, target_len);
if (rv.rfind(' ') == rv.npos)
return rv;
return rv.substr(rv.rfind(' ')+1);
}
using type = T;
constexpr static std::string_view value = name();
};
namespace s1 {
class MyClass;
}
//Both MSVC, G++ and Clang++ have passed test.
int main () {
static_assert(TypeName<s1::MyClass>::value == "s1::MyClass");
std::cout<<"FULLNAME> "<<TypeName<void>::fullname_intern()<<std::endl;
std::cout<<"TYPETEST> '"<<TypeName<s1::MyClass>::value<<"' == 's1::MyClass'"<<std::endl;
return 0;
}
Note that:
Full name in Clang++: static std::string_view TypeName<void>::fullname_intern() [T = void]
Full name in G++: static constexpr std::string_view TypeName<T>::fullname_intern() [with T = void; std::string_view = std::basic_string_view<char>]
Fullname in MSVC: class std::basic_string_view<char,struct std::char_traits<char> > __cdecl TypeName<void>::fullname_intern(void)(But 'class s1::MyClass' not 's1::MyClass' here)
type_name_length<T>that you need it at compile time? Compilers are pretty good about just evaluatingstrlen()and giving you a constant if that's possible.