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Is it possible in standard C++ to print a variable type. I think this is being addressed in C++0x but not sure it already exists.

I would like something like this:

int a = 12;
cout << typeof(a) << endl;

That would print:

int
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9 Answers 9

up vote 93 down vote accepted

Try:

#include <typeinfo>

// …
std::cout << typeid(a).name() << '\n';

You might have to activate RTTI in your compiler options for this to work. Additionally, the output of this depends on the compiler. It might be a raw type name or a name mangling symbol or anything in between.

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EDIT: Beaten, serves me right for looking it up =]. Don't forget to include <typeinfo>

I believe what you are referring to is runtime type identification. You can achieve the above by doing .

#include <iostream>
#include <typeinfo>

using namespace std;

int main() {
  int i;
  cout << typeid(i).name();
  return 0;
}
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C++11 update to a very old question: Print variable type in C++.

The accepted (and good) answer is to use typeid(a).name(), where a is a variable name.

Now in C++11 we have decltype(x), which can turn an expression into a type. And decltype() comes with its own set of very interesting rules. For example decltype(a) and decltype((a)) will generally be different types (and for good and understandable reasons once those reasons are exposed).

Will our trusty typeid(a).name() help us explore this brave new world?

No.

But the tool that will is not that complicated. And it is that tool which I am using as an answer to this question. I will compare and contrast this new tool to typeid(a).name(). And this new tool is actually built on top of typeid(a).name().

The fundamental issue:

typeid(a).name()

throws away cv-qualifiers, references, and lvalue/rvalue-ness. For example:

const int ci = 0;
std::cout << typeid(ci).name() << '\n';

For me outputs:

i

and I'm guessing on MSVC outputs:

int

I.e. the const is gone. This is not a QOI (Quality Of Implementation) issue. The standard mandates this behavior.

What I'm recommending below is:

template <typename T> std::string type_name();

which would be used like this:

const int ci = 0;
std::cout << type_name<decltype(ci)>() << '\n';

and for me outputs:

int const

<disclaimer> I have not tested this on MSVC. </disclaimer> But I welcome feedback from those who do.

The C++11 Solution

I am using __cxa_demangle for non-MSVC platforms as recommend by ipapadop in his answer to demangle types. But on MSVC I'm trusting typeid to demangle names (untested). And this core is wrapped around some simple testing that detects, restores and reports cv-qualifiers and references to the input type.

#include <type_traits>
#include <typeinfo>
#ifndef _MSC_VER
#   include <cxxabi.h>
#endif
#include <memory>
#include <string>
#include <cstdlib>

template <class T>
std::string
type_name()
{
    typedef typename std::remove_reference<T>::type TR;
    std::unique_ptr<char, void(*)(void*)> own
           (
#ifndef _MSC_VER
                abi::__cxa_demangle(typeid(TR).name(), nullptr,
                                           nullptr, nullptr),
#else
                nullptr,
#endif
                std::free
           );
    std::string r = own != nullptr ? own.get() : typeid(TR).name();
    if (std::is_const<TR>::value)
        r += " const";
    if (std::is_volatile<TR>::value)
        r += " volatile";
    if (std::is_lvalue_reference<T>::value)
        r += "&";
    else if (std::is_rvalue_reference<T>::value)
        r += "&&";
    return r;
}

The Results

With this solution I can do this:

int& foo_lref();
int&& foo_rref();
int foo_value();

int
main()
{
    int i = 0;
    const int ci = 0;
    std::cout << "decltype(i) is " << type_name<decltype(i)>() << '\n';
    std::cout << "decltype((i)) is " << type_name<decltype((i))>() << '\n';
    std::cout << "decltype(ci) is " << type_name<decltype(ci)>() << '\n';
    std::cout << "decltype((ci)) is " << type_name<decltype((ci))>() << '\n';
    std::cout << "decltype(static_cast<int&>(i)) is " << type_name<decltype(static_cast<int&>(i))>() << '\n';
    std::cout << "decltype(static_cast<int&&>(i)) is " << type_name<decltype(static_cast<int&&>(i))>() << '\n';
    std::cout << "decltype(static_cast<int>(i)) is " << type_name<decltype(static_cast<int>(i))>() << '\n';
    std::cout << "decltype(foo_lref()) is " << type_name<decltype(foo_lref())>() << '\n';
    std::cout << "decltype(foo_rref()) is " << type_name<decltype(foo_rref())>() << '\n';
    std::cout << "decltype(foo_value()) is " << type_name<decltype(foo_value())>() << '\n';
}

and the output is:

decltype(i) is int
decltype((i)) is int&
decltype(ci) is int const
decltype((ci)) is int const&
decltype(static_cast<int&>(i)) is int&
decltype(static_cast<int&&>(i)) is int&&
decltype(static_cast<int>(i)) is int
decltype(foo_lref()) is int&
decltype(foo_rref()) is int&&
decltype(foo_value()) is int

Note (for example) the difference between decltype(i) and decltype((i)). The former is the type of the declaration of i. The latter is the "type" of the expression i. (expressions never have reference type, but as a convention decltype represents lvalue expressions with lvalue references).

Thus this tool is an excellent vehicle just to learn about decltype, in addition to exploring and debugging your own code.

In contrast, if I were to build this just on typeid(a).name(), without adding back lost cv-qualifiers or references, the output would be:

decltype(i) is int
decltype((i)) is int
decltype(ci) is int
decltype((ci)) is int
decltype(static_cast<int&>(i)) is int
decltype(static_cast<int&&>(i)) is int
decltype(static_cast<int>(i)) is int
decltype(foo_lref()) is int
decltype(foo_rref()) is int
decltype(foo_value()) is int

I.e. Every reference and cv-qualifier is stripped off.

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Note that the names generated by the RTTI feature of C++ is not portable. For example, the class

MyNamespace::CMyContainer<int, test_MyNamespace::CMyObject>

will have the following names:

// MSVC 2003:
class MyNamespace::CMyContainer[int,class test_MyNamespace::CMyObject]
// G++ 4.2:
N8MyNamespace8CMyContainerIiN13test_MyNamespace9CMyObjectEEE

So you can't use this information for serialization. But still, the typeid(a).name() property can still be used for log/debug purposes

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You can use templates.

template <typename T> const char* typeof(T&) { return "unknown"; }    // default
template<> const char* typeof(int&) { return "int"; }
template<> const char* typeof(float&) { return "float"; }

In the example above, when the type is not matched it will print "unknown".

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Won't it print "int" for shorts and chars? And "float" for doubles? –  gartenriese Feb 17 at 8:00

You could use a traits class for this. Something like:

#include <iostream>
using namespace std;

template <typename T> class type_name {
public:
    static const char *name;
};

#define DECLARE_TYPE_NAME(x) template<> const char *type_name<x>::name = #x;
#define GET_TYPE_NAME(x) (type_name<typeof(x)>::name)

DECLARE_TYPE_NAME(int);

int main()
{
    int a = 12;
    cout << GET_TYPE_NAME(a) << endl;
}

The DECLARE_TYPE_NAME define exists to make your life easier in declaring this traits class for all the types you expect to need.

This might be more useful than the solutions involving typeid because you get to control the output. For example, using typeid for long long on my compiler gives "x".

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Very ugly but does the trick if you only want compile time info (e.g. for debugging):

auto testVar = std::make_tuple(1, 1.0, "abc");
static_assert(decltype(testVar)::dummy_error, "DUMP MY TYPE" );

Returns:

Compilation finished with errors:
source.cpp: In function 'int main()':
source.cpp:5:19: error: 'dummy_error' is not a member of 'std::tuple<int, double, const char*>'
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Thanks a lot! This is the proper compile-time solution. –  Trass3r Jan 13 at 14:17

The other answers involving RTTI (typeid) are probably what you want, as long as:

  • you can afford the memory overhead (which can be considerable with some compilers)
  • the class names your compiler returns are useful

The alternative, (similar to Greg Hewgill's answer), is to build a compile-time table of traits.

template <typename T> struct type_as_string;

// declare your Wibble type (probably with definition of Wibble)
template <>
struct type_as_string<Wibble>
{
    static const char* const value = "Wibble";
};

Be aware that if you wrap the declarations in a macro, you'll have trouble declaring names for template types taking more than one parameter (e.g. std::map), due to the comma.

To access the name of the type of a variable, all you need is

template <typename T>
const char* get_type_as_string(const T&)
{
    return type_as_string<T>::value;
}
share|improve this answer
    
Good point about the comma, I knew there was a reason macros were a bad idea but didn't think of it at the time! –  Greg Hewgill Sep 17 '08 at 22:14
1  
static const char* value = "Wibble"; you can't do that mate :) –  Johannes Schaub - litb Nov 30 '08 at 22:35

As mentioned, typeid().name() may return a mangled name. In GCC (and some other compilers) you can work around it with the following code:

#include <cxxabi.h>
#include <iostream>
#include <typeinfo>
#include <cstdlib>

namespace some_namespace { namespace another_namespace {

  class my_class { };

} }

int main() {
  typedef some_namespace::another_namespace::my_class my_type;
  // mangled
  std::cout << typeid(my_type).name() << std::endl;

  // unmangled
  int status = 0;
  char* demangled = abi::__cxa_demangle(typeid(my_type).name(), 0, 0, &status);

  switch (status) {
    case -1: {
      // could not allocate memory
      std::cout << "Could not allocate memory" << std::endl;
      return -1;
    } break;
    case -2: {
      // invalid name under the C++ ABI mangling rules
      std::cout << "Invalid name" << std::endl;
      return -1;
    } break;
    case -3: {
      // invalid argument
      std::cout << "Invalid argument to demangle()" << std::endl;
      return -1;
    } break;
 }
 std::cout << demangled << std::endl;

 free(demangled);

 return 0;

}

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Very useful; thanks! –  hauzer Oct 1 '13 at 23:36

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