84

I'm writing some template classes for parseing some text data files, and as such it is likly the great majority of parse errors will be due to errors in the data file, which are for the most part not written by programmers, and so need a nice message about why the app failed to load e.g. something like:

Error parsing example.txt. Value ("notaninteger")of [MySectiom]Key is not a valid int

I can work out the file, section and key names from the arguments passed to the template function and member vars in the class, however I'm not sure how to get the name of the type the template function is trying to convert to.

My current code looks like, with specialisations for just plain strings and such:

template<typename T> T GetValue(const std::wstring &section, const std::wstring &key)
{
    std::map<std::wstring, std::wstring>::iterator it = map[section].find(key);
    if(it == map[section].end())
        throw ItemDoesNotExist(file, section, key)
    else
    {
        try{return boost::lexical_cast<T>(it->second);}
        //needs to get the name from T somehow
        catch(...)throw ParseError(file, section, key, it->second, TypeName(T));
    }
}

Id rather not have to make specific overloads for every type that the data files might use, since there are loads of them...

Also I need a solution that does not incur any runtime overhead unless an exception occurs, i.e. a completely compile time solution is what I want since this code is called tons of times and load times are already getting somewhat long.

EDIT: Ok this is the solution I came up with:

I have a types.h containg the following

#pragma once
template<typename T> const wchar_t *GetTypeName();

#define DEFINE_TYPE_NAME(type, name) \
    template<>const wchar_t *GetTypeName<type>(){return name;}

Then I can use the DEFINE_TYPE_NAME macro to in cpp files for each type I need to deal with (eg in the cpp file that defined the type to start with).

The linker is then able to find the appropirate template specialisation as long as it was defined somewhere, or throw a linker error otherwise so that I can add the type.

1
  • 1
    not really relevant to your question, but you might want to use map.find(section) when accessing the section aswell, unless you intentionally want to create an empty section. – Idan K Jun 28 '09 at 18:45

10 Answers 10

41

Jesse Beder's solution is likely the best, but if you don't like the names typeid gives you (I think gcc gives you mangled names for instance), you can do something like:

template<typename T>
struct TypeParseTraits;

#define REGISTER_PARSE_TYPE(X) template <> struct TypeParseTraits<X> \
    { static const char* name; } ; const char* TypeParseTraits<X>::name = #X


REGISTER_PARSE_TYPE(int);
REGISTER_PARSE_TYPE(double);
REGISTER_PARSE_TYPE(FooClass);
// etc...

And then use it like

throw ParseError(TypeParseTraits<T>::name);

EDIT:

You could also combine the two, change name to be a function that by default calls typeid(T).name() and then only specialize for those cases where that's not acceptable.

5
  • Note: This code will not compile if you forget to define REGISTER_PARSE_TYPE for a type that you use. I have used a similar trick before (in code without RTTI) and it has worked very well. – Tom Leys Jun 28 '09 at 21:20
  • 1
    I had to move name outside of the struct in g++ 4.3.0 due to "error: invalid in-class initialization of static data member of non-integral type 'const char *'"; and, of course, the keyword 'struct' is needed between <> and TypeParseTraits and the definition should be terminated with a semicolon. – fuzzyTew Jul 17 '09 at 10:35
  • 4
    Well the leaving the semicolon out was intentional, to force you to use it at the end of the macro invocation, but thanks for the corrections. – Logan Capaldo Jul 17 '09 at 11:44
  • I obtain the folllowing error: error: '#' is not followed by a macro parameter – kratsg Feb 26 '15 at 3:51
  • @kratsg - that's because at the end '#x' should be '#X' (uppercase to match macro parameter) - I'll fix the answer. – amdn Mar 25 '15 at 1:25
80

The solution is

typeid(T).name()

which returns std::type_info.

5
  • 7
    Keep in mind that it's compliant to return the same string for every type (though I don't think any compiler would do that). – Motti Jun 28 '09 at 19:03
  • 3
    Or to return a different string for the same type on different executions... (again not that I think that any sane compiler would do that). – Emily L. Nov 27 '14 at 19:03
  • 5
    I'd just like to point out how ugly the given name can be: typeid(simd::double3x4).name() = "N4simd9double3x4E". typeid(simd::float4).name() = "Dv4_f" C++17, Xcode 10.1. – Andreas detests censorship Dec 26 '18 at 1:50
  • 1
    Indeed. typeid(T).name() is the canonical way to do this, but very few compilers return unmangled names; the only one I'm personally familiar with that does so is MSVC. Depending on the compiler used, there's also a chance that it may lose some type information on function types, but that's probably irrelevant in this case. – Justin Time - Reinstate Monica Sep 24 '19 at 16:40
  • typeid(T).name() does not return std::type_info, but char const *. – lmat - Reinstate Monica Dec 7 '20 at 16:01
49

typeid(T).name() is implementation defined and doesn't guarantee human readable string.

Reading cppreference.com :

Returns an implementation defined null-terminated character string containing the name of the type. No guarantees are given, in particular, the returned string can be identical for several types and change between invocations of the same program.

...

With compilers such as gcc and clang, the returned string can be piped through c++filt -t to be converted to human-readable form.

But in some cases gcc doesn't return right string. For example on my machine I have gcc whith -std=c++11 and inside template function typeid(T).name() returns "j" for "unsigned int". It's so called mangled name. To get real type name, use abi::__cxa_demangle() function (gcc only):

#include <string>
#include <cstdlib>
#include <cxxabi.h>

template<typename T>
std::string type_name()
{
    int status;
    std::string tname = typeid(T).name();
    char *demangled_name = abi::__cxa_demangle(tname.c_str(), NULL, NULL, &status);
    if(status == 0) {
        tname = demangled_name;
        std::free(demangled_name);
    }   
    return tname;
}
3
  • 1
    Isn't it memory leak to have free in if? – Tomáš Zato - Reinstate Monica Aug 17 '16 at 3:48
  • 2
    No, because the pointer points to nullptr if the status is not 0. – Henry Schreiner Feb 3 '17 at 19:05
  • 2
    I'd like to add that it's probably best to check for gcc or clang's existence and if not default to not doing the demangling as shown here. – god of llamas Jul 10 '17 at 20:30
20

As mentioned by Bunkar typeid(T).name is implementation defined.

To avoid this issue you can use Boost.TypeIndex library.

For example:

boost::typeindex::type_id<T>().pretty_name() // human readable
3
  • This is very useful for finding out templates type names when functions are called. It worked pretty well for me. – Fernando Jun 28 '17 at 22:09
  • 1
    Note that pretty_name() or raw_name() is still implementation defined. On MSVC for a struct A; you would get : "struct A" while on gcc/clang : "A". – daminetreg Jan 10 '18 at 10:58
  • wow. boost again for the win. amazing what boost does without compiler support (auto, regex, foreach, threads, static_assert, etc, etc... support before compilers/C++-standard support). – Trevor Boyd Smith Apr 12 '18 at 16:29
14

The answer of Logan Capaldo is correct but can be marginally simplified because it is unnecessary to specialize the class every time. One can write:

// in header
template<typename T>
struct TypeParseTraits
{ static const char* name; };

// in c-file
#define REGISTER_PARSE_TYPE(X) \
    template <> const char* TypeParseTraits<X>::name = #X

REGISTER_PARSE_TYPE(int);
REGISTER_PARSE_TYPE(double);
REGISTER_PARSE_TYPE(FooClass);
// etc...

This also allows you to put the REGISTER_PARSE_TYPE instructions in a C++ file...

9

This trick was mentioned under a few other questions, but not here yet.

All major compilers support __PRETTY_FUNC__ (GCC & Clang) /__FUNCSIG__ (MSVC) as an extension.

When used in a template like this:

template <typename T> const char *foo()
{
    #ifdef _MSC_VER
    return __FUNCSIG__;
    #else
    return __PRETTY_FUNCTION__;
    #endif
}

It produces strings in a compiler-dependent format, that contain, among other things, the name of T.

E.g. foo<float>() returns:

  • "const char* foo() [with T = float]" on GCC
  • "const char *foo() [T = float]" on Clang
  • "const char *__cdecl foo<float>(void)" on MSVC

You can easily parse the type names out of those strings. You just need to figure out how many 'junk' characters your compiler inserts before and after the type.

You can even do that completely at compile-time.


The resulting names can slightly vary between different compilers. E.g. GCC omits default template arguments, and MSVC prefixes classes with the word class.


Here's an implementation that I've been using. Everything is done at compile-time.

Example usage:

std::cout << TypeName<float>() << '\n';
std::cout << TypeName(1.2f); << '\n';

Implementation:

#include <array>
#include <cstddef>

namespace impl
{
    template <typename T>
    constexpr const auto &RawTypeName()
    {
        #ifdef _MSC_VER
        return __FUNCSIG__;
        #else
        return __PRETTY_FUNCTION__;
        #endif
    }

    struct RawTypeNameFormat
    {
        std::size_t leading_junk = 0, trailing_junk = 0;
    };

    // Returns `false` on failure.
    inline constexpr bool GetRawTypeNameFormat(RawTypeNameFormat *format)
    {
        const auto &str = RawTypeName<int>();
        for (std::size_t i = 0;; i++)
        {
            if (str[i] == 'i' && str[i+1] == 'n' && str[i+2] == 't')
            {
                if (format)
                {
                    format->leading_junk = i;
                    format->trailing_junk = sizeof(str)-i-3-1; // `3` is the length of "int", `1` is the space for the null terminator.
                }
                return true;
            }
        }
        return false;
    }

    inline static constexpr RawTypeNameFormat format =
    []{
        static_assert(GetRawTypeNameFormat(nullptr), "Unable to figure out how to generate type names on this compiler.");
        RawTypeNameFormat format;
        GetRawTypeNameFormat(&format);
        return format;
    }();
}

// Returns the type name in a `std::array<char, N>` (null-terminated).
template <typename T>
[[nodiscard]] constexpr auto CexprTypeName()
{
    constexpr std::size_t len = sizeof(impl::RawTypeName<T>()) - impl::format.leading_junk - impl::format.trailing_junk;
    std::array<char, len> name{};
    for (std::size_t i = 0; i < len-1; i++)
        name[i] = impl::RawTypeName<T>()[i + impl::format.leading_junk];
    return name;
}

template <typename T>
[[nodiscard]] const char *TypeName()
{
    static constexpr auto name = CexprTypeName<T>();
    return name.data();
}
template <typename T>
[[nodiscard]] const char *TypeName(const T &)
{
    return TypeName<T>();
}
8

As a rephrasing of Andrey's answer:

The Boost TypeIndex library can be used to print names of types.

Inside a template, this might read as follows

#include <boost/type_index.hpp>
#include <iostream>

template<typename T>
void printNameOfType() {
    std::cout << "Type of T: " 
              << boost::typeindex::type_id<T>().pretty_name() 
              << std::endl;
}
2

If you'd like a pretty_name, Logan Capaldo's solution can't deal with complex data structure: REGISTER_PARSE_TYPE(map<int,int>) and typeid(map<int,int>).name() gives me a result of St3mapIiiSt4lessIiESaISt4pairIKiiEEE

There is another interesting answer using unordered_map or map comes from https://en.cppreference.com/w/cpp/types/type_index.

#include <iostream>
#include <unordered_map>
#include <map>
#include <typeindex>
using namespace std;
unordered_map<type_index,string> types_map_;

int main(){
    types_map_[typeid(int)]="int";
    types_map_[typeid(float)]="float";
    types_map_[typeid(map<int,int>)]="map<int,int>";

    map<int,int> mp;
    cout<<types_map_[typeid(map<int,int>)]<<endl;
    cout<<types_map_[typeid(mp)]<<endl;
    return 0;
}
2

typeid(uint8_t).name() is nice, but it returns "unsigned char" while you may expect "uint8_t".

This piece of code will return you the appropriate type

#define DECLARE_SET_FORMAT_FOR(type) \
    if ( typeid(type) == typeid(T) ) \
        formatStr = #type;

template<typename T>
static std::string GetFormatName()
{
    std::string formatStr;

    DECLARE_SET_FORMAT_FOR( uint8_t ) 
    DECLARE_SET_FORMAT_FOR( int8_t ) 

    DECLARE_SET_FORMAT_FOR( uint16_t )
    DECLARE_SET_FORMAT_FOR( int16_t )

    DECLARE_SET_FORMAT_FOR( uint32_t )
    DECLARE_SET_FORMAT_FOR( int32_t )

    DECLARE_SET_FORMAT_FOR( float )

    // .. to be exptended with other standard types you want to be displayed smartly

    if ( formatStr.empty() )
    {
        assert( false );
        formatStr = typeid(T).name();
    }

    return formatStr;
}
2
  • This is great, but why not do return #type; instead? – Little Helper Sep 20 '20 at 19:59
  • @LittleHelper: You are right, that would also work... – jpo38 Sep 21 '20 at 8:57
1

I just leave it there. If someone will still need it, then you can use this:

template <class T>
bool isString(T* t) { return false;  } // normal case returns false

template <>
bool isString(char* t) { return true; }  // but for char* or String.c_str() returns true
.
.
.

This will only CHECK type not GET it and only for 1 type or 2.

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