I'd like to be able to introspect a C++ class for its name, contents (i.e. members and their types) etc. I'm talking native C++ here, not managed C++, which has reflection. I realise C++ supplies some limited information using RTTI. Which additional libraries (or other techniques) could supply this information?

  • 21
    Tough luck, you can't do it without macros and other preprocessing, because the required metadata does not exist unless you manually create it through some macro preprocessing magic. Nov 24, 2008 at 14:31
  • 7
    The information you can get back from RTTI isn't enough to do most of the things you'd actually want reflection for though. You can't iterate over the member functions of a class for example. Jul 8, 2009 at 19:31

28 Answers 28


What you need to do is have the preprocessor generate reflection data about the fields. This data can be stored as nested classes.

First, to make it easier and cleaner to write it in the preprocessor we will use typed expression. A typed expression is just an expression that puts the type in parenthesis. So instead of writing int x you will write (int) x. Here are some handy macros to help with typed expressions:

#define REM(...) __VA_ARGS__
#define EAT(...)

// Retrieve the type
#define DETAIL_TYPEOF_HEAD(x, ...) REM x
#define DETAIL_TYPEOF_PROBE(...) (__VA_ARGS__),
// Strip off the type
#define STRIP(x) EAT x
// Show the type without parenthesis
#define PAIR(x) REM x

Next, we define a REFLECTABLE macro to generate the data about each field(plus the field itself). This macro will be called like this:

    (const char *) name,
    (int) age

So using Boost.PP we iterate over each argument and generate the data like this:

// A helper metafunction for adding const to a type
template<class M, class T>
struct make_const
    typedef T type;

template<class M, class T>
struct make_const<const M, T>
    typedef typename boost::add_const<T>::type type;

#define REFLECTABLE(...) \
static const int fields_n = BOOST_PP_VARIADIC_SIZE(__VA_ARGS__); \
friend struct reflector; \
template<int N, class Self> \
struct field_data {}; \

#define REFLECT_EACH(r, data, i, x) \
PAIR(x); \
template<class Self> \
struct field_data<i, Self> \
{ \
    Self & self; \
    field_data(Self & self) : self(self) {} \
    typename make_const<Self, TYPEOF(x)>::type & get() \
    { \
        return self.STRIP(x); \
    typename boost::add_const<TYPEOF(x)>::type & get() const \
    { \
        return self.STRIP(x); \
    const char * name() const \
        return BOOST_PP_STRINGIZE(STRIP(x)); \
    } \
}; \

What this does is generate a constant fields_n that is number of reflectable fields in the class. Then it specializes the field_data for each field. It also friends the reflector class, this is so it can access the fields even when they are private:

struct reflector
    //Get field_data at index N
    template<int N, class T>
    static typename T::template field_data<N, T> get_field_data(T& x)
        return typename T::template field_data<N, T>(x);

    // Get the number of fields
    template<class T>
    struct fields
        static const int n = T::fields_n;

Now to iterate over the fields we use the visitor pattern. We create an MPL range from 0 to the number of fields, and access the field data at that index. Then it passes the field data on to the user-provided visitor:

struct field_visitor
    template<class C, class Visitor, class I>
    void operator()(C& c, Visitor v, I)

template<class C, class Visitor>
void visit_each(C & c, Visitor v)
    typedef boost::mpl::range_c<int,0,reflector::fields<C>::n> range;
    boost::mpl::for_each<range>(boost::bind<void>(field_visitor(), boost::ref(c), v, _1));

Now for the moment of truth we put it all together. Here is how we can define a Person class that is reflectable:

struct Person
    Person(const char *name, int age)
        (const char *) name,
        (int) age

Here is a generalized print_fields function using the reflection data to iterate over the fields:

struct print_visitor
    template<class FieldData>
    void operator()(FieldData f)
        std::cout << f.name() << "=" << f.get() << std::endl;

template<class T>
void print_fields(T & x)
    visit_each(x, print_visitor());

An example of using the print_fields with the reflectable Person class:

int main()
    Person p("Tom", 82);
    return 0;

Which outputs:


And voila, we have just implemented reflection in C++, in under 100 lines of code.

  • 161
    Kudos for showing how to implement reflection, rather than saying it can't be done. It's answers like this that make S.O. a great resource. May 13, 2014 at 16:00
  • 8
    Note that if you try to compile this under Visual Studio you will get an error because VS doesn't handle the variadic macro expansion properly. For VS, try adding: #define DETAIL_TYPEOF_INT2(tuple) DETAIL_TYPEOF_HEAD tuple and #define DETAIL_TYPEOF_INT(...) DETAIL_TYPEOF_INT2((__VA_ARGS__)) and changing the definition of TYPEOF(x) to: #define TYPEOF(x) DETAIL_TYPEOF_INT(DETAIL_TYPEOF_PROBE x,) Nov 27, 2014 at 3:33
  • 1
    I m getting the error 'BOOST_PP_IIF_0' does not name a type. Can you please help. Dec 4, 2015 at 5:14
  • See my own answer - stackoverflow.com/a/55364085/2338477 I've extracted and repacked all defines, and boost library is not needed. As demo code i'm providing serialization to xml and restore from xml. (Thanks for correction @stackprotector) Jun 8, 2021 at 16:13
  • How can you declare reflection on fixed-length char arrays in this fashion? ie: char[40]
    – Jahrenski
    Mar 14, 2023 at 17:44

There are two kinds of reflection swimming around.

  1. Inspection by iterating over members of a type, enumerating its methods and so on.

    This is not possible with C++.
  2. Inspection by checking whether a class-type (class, struct, union) has a method or nested type, is derived from another particular type.

    This kind of thing is possible with C++ using template-tricks. Use boost::type_traits for many things (like checking whether a type is integral). For checking for the existence of a member function, use Templated check for the existence of a class member function? . For checking whether a certain nested type exists, use plain SFINAE .

If you are rather looking for ways to accomplish 1), like looking how many methods a class has, or like getting the string representation of a class id, then I'm afraid there is no Standard C++ way of doing this. You have to use either

  • A Meta Compiler like the Qt Meta Object Compiler which translates your code adding additional meta information.
  • A Framework consisting of macros that allow you to add the required meta-information. You would need to tell the framework all methods, the class-names, base-classes and everything it needs.

C++ is made with speed in mind. If you want high-level inspection, like C# or Java has, there is no way to do that without some additional effort.

  • 147
    C++ is made with speed in mind, but the philosophy isn't "as fast as possible," instead it's, "you don't pay for it if you don't use it." I believe it's possible for a language to implement introspection in a way that fits with that philosophy, C++ just lacks it. Jul 8, 2009 at 19:34
  • 8
    @Joseph: How should that be done? It'd require all that metadata to be stored. Which means you have to pay for it, even if you don't use it. (Unless you could mark individual types as "supporting reflection", but then we're almost down where we might as well use the existing macro trickery. Aug 3, 2009 at 11:00
  • 26
    @jalf: Only the metadata which might be needed. If we consider only compile-time reflection, this is trivial. E.g. a compile-time function members<T> which returns a list of all members of T. If we wanted have runtime reflection (ie RTTI mixed with reflection), the compiler would still know all reflected base types. It's quite likely members<T>(T&) would never be instantiated for T=std::string, so the RTTI for std::string or its derived classes need not be included.
    – MSalters
    Aug 3, 2009 at 11:22
  • 9
    The reflex library (mentioned below) adds reflection to C++ without slowing down existing code at: root.cern.ch/drupal/content/reflex May 4, 2011 at 19:37
  • 8
    @Joe: Reflection never slows down existing code. It just makes the delivered stuff bigger (since you have to deliver a type info database...).
    – mmmmmmmm
    Feb 14, 2012 at 20:53

Reflection is not supported by C++ out of the box. This is sad because it makes defensive testing a pain.

There are several approaches to doing reflection:

  1. use the debug information (non portable).
  2. Sprinkle your code with macro's/templates or some other source approach (looks ugly)
  3. Modify a compiler such as clang/gcc to produce a database.
  4. Use Qt moc approach
  5. Boost Reflect
  6. Precise and Flat Reflection

The first link looks the most promising (uses mod's to clang), the second discusses a number of techniques, the third is a different approach using gcc:

  1. http://www.donw.org/rfl/

  2. https://bitbucket.org/dwilliamson/clreflect

  3. https://root.cern.ch/how/how-use-reflex

There is now a working group for C++ reflection. See the news for C++14 @ CERN:

Edit 13/08/17:

Since the original post there have been a number of potential advancements on the reflection. The following provides more detail and a discussion on the various techniques and status:

  1. Static Reflection in a Nutshell
  2. Static Reflection
  3. A design for static reflection

However it does not look promising on a standardised reflections approach in C++ in the near future unless there is a lot more interest from the community in support for reflection in C++.

The following details the current status based on feedback from the last C++ standards meeting:

Edit 13/12/2017

Reflection looks to be moving towards C++ 20 or more probably a TSR. Movement is however slow.

Edit 15/09/2018

A draft TS has been sent out to the national bodies for ballot.

The text can be found here: https://github.com/cplusplus/reflection-ts

Edit 11/07/2019

The reflection TS is feature complete and is out for comment and vote over the summer (2019).

The meta-template programing approach is to be replaced with a simplier compile time code approach (not reflected in the TS).

Edit 10/02/2020

There is a request to support the reflection TS in Visual Studio here:

Talk on the TS by the author David Sankel:

Edit 17 March 2020

Progress on reflection is being made. A report from '2020-02 Prague ISO C++ Committee Trip Report' can be found here:

Details on what is being considered for C++23 can be found here (includes short section on Reflection):

Edit 4th June 2020

A new framework has been released by Jeff Preshing called 'Plywood' that contains a mechanism for runtime reflection. More details can be found here:

The tools and approach look to be the most polished and easiest to use so far.

Edit July 12 2020

Clang experimental reflection fork : https://github.com/lock3/meta/wiki

Interesting reflection library that uses clang tooling library to extract information for simple reflection with no need to add macro's: https://github.com/chakaz/reflang

Edit Feb 24 2021

Some additional clang tooling approaches:

Edit Aug 25 2021

An ACCU talk online at youtube https://www.youtube.com/watch?v=60ECEc-URP8 is well worth a listen too it talks about current proposals to the standard and an implementation based on clang.


Edit May 31 2023 Thanks to @ilciavo for pointing this library out.

Boost Describe looks to be an interesting approach to reflection. It is a combination of Macros and a decent supporting library with good documentation.


Edit 13 Nov 2023

There appears to be movement on Reflection in the last C++ meeting as reported By Herb Sutter:

The paper referenced is here:

So it looks like we may get static reflection in C++26.


And I would love a pony, but ponies aren't free. :-p

http://en.wikibooks.org/wiki/C%2B%2B_Programming/RTTI is what you're going to get. Reflection like you're thinking about -- fully descriptive metadata available at runtime -- just doesn't exist for C++ by default.

  • 1
    I second Brad. C++ templates can be rather powerful, and there is a wealth of experience around various 'reflection' type behaviors, such at boost 'any' library, type traits, C++ RTTI etc. that can solve many of the problems reflection is solved for. So Nick, what's your goal here?
    – Aaron
    Sep 16, 2008 at 23:19
  • 7
    Upvote for the ponies remark! I'd upvote twice, as your answer also deserves it, but sadly I get only one, so ponies win. :-) Nov 11, 2008 at 3:57
  • 14
    I don't really get why this is a clever response. I've already said I'd like references to libraries etc to implement this. The reflection/introspection is for various system to allow script access, serialisation etc.
    – Nick
    Mar 30, 2009 at 15:10
  • 4
    @Nick: He already answered that. It can't be done, the data does not exist, and therefore, no library is able to implement it for you. Aug 3, 2009 at 10:58
  • 5
    @jalf Still strange for me read people in the programming world saying thinks like 'its not possible' and not 'I don't know how'. Sure the metadata don't exists but can be inserted with macros
    – Freddx L.
    Apr 13, 2020 at 19:44

The information does exist - but not in the format you need, and only if you export your classes. This works in Windows, I don't know about other platforms. Using the storage-class specifiers as in, for example:

class __declspec(export) MyClass
    void Foo(float x);

This makes the compiler build the class definition data into the DLL/Exe. But it's not in a format that you can readily use for reflection.

At my company we built a library that interprets this metadata, and allows you to reflect a class without inserting extra macros etc. into the class itself. It allows functions to be called as follows:

MyClass *instance_ptr=new MyClass;

This effectively does:


The Invoke(this_pointer,...) function has variable arguments. Obviously by calling a function in this way you're circumventing things like const-safety and so on, so these aspects are implemented as runtime checks.

I'm sure the syntax could be improved, and it only works on Win32 and Win64 so far. We've found it really useful for having automatic GUI interfaces to classes, creating properties in C++, streaming to and from XML and so on, and there's no need to derive from a specific base class. If there's enough demand maybe we could knock it into shape for release.

  • 1
    I think you mean __declspec(dllexport) and you can retrieve the information from a the .map file if you enable creation of such during build. Oct 10, 2017 at 13:17

I would recommend using Qt.

There is an open-source licence as well as a commercial licence.

  • 1
    I looked at this but it uses macros and the source code needs parsing to generate the meta-data code. I'd like to avoid this extra step. I'd prefer to use a C++ library or simple macros. Thanks for the idea though.
    – Nick
    Aug 3, 2009 at 10:47
  • 11
    QT, or another library implementing a similar approach is the best you're going to get Aug 3, 2009 at 10:59
  • 7
    Pay at compile time or pay at runtime - either way you are paying! Jun 20, 2010 at 18:28

You need to look at what you are trying to do, and if RTTI will satisfy your requirements. I've implemented my own pseudo-reflection for some very specific purposes. For example, I once wanted to be able to flexibly configure what a simulation would output. It required adding some boilerplate code to the classes that would be output:

namespace {
  static bool b2 = Filter::Filterable<const MyObj>::Register("MyObject");

bool MyObj::BuildMap()
  Filterable<const OutputDisease>::AddAccess("time", &MyObj::time);
  Filterable<const OutputDisease>::AddAccess("person", &MyObj::id);
  return true;

The first call adds this object to the filtering system, which calls the BuildMap() method to figure out what methods are available.

Then, in the config file, you can do something like this:

FILTER-CLAUSE-1        person == 1773
FILTER-CLAUSE-2        time > 2000

Through some template magic involving boost, this gets translated into a series of method calls at run-time (when the config file is read), so it's fairly efficient. I wouldn't recommend doing this unless you really need to, but, when you do, you can do some really cool stuff.

  • gotta love these functions that always return true ;) I assume this is immune from static init ordering issues?
    – paulm
    Mar 16, 2015 at 7:58

What are you trying to do with reflection?
You can use the Boost type traits and typeof libraries as a limited form of compile-time reflection. That is, you can inspect and modify the basic properties of a type passed to a template.


There is another new library for reflection in C++, called RTTR (Run Time Type Reflection, see also github).

The interface is similar to reflection in C# and it works without any RTTI.


EDIT: CAMP is no more maintained ; two forks are available:

  • One is also called CAMP too, and is based on the same API.
  • Ponder is a partial rewrite, and shall be preferred as it does not requires Boost ; it's using C++11.

CAMP is an MIT licensed library (formerly LGPL) that adds reflection to the C++ language. It doesn't require a specific preprocessing step in the compilation, but the binding has to be made manually.

The current Tegesoft library uses Boost, but there is also a fork using C++11 that no longer requires Boost.


I did something like what you're after once, and while it's possible to get some level of reflection and access to higher-level features, the maintenance headache might not be worth it. My system was used to keep the UI classes completely separated from the business logic through delegation akin to Objective-C's concept of message passing and forwarding. The way to do it is to create some base class that is capable of mapping symbols (I used a string pool but you could do it with enums if you prefer speed and compile-time error handling over total flexibility) to function pointers (actually not pure function pointers, but something similar to what Boost has with Boost.Function--which I didn't have access to at the time). You can do the same thing for your member variables as long as you have some common base class capable of representing any value. The entire system was an unabashed ripoff of Key-Value Coding and Delegation, with a few side effects that were perhaps worth the sheer amount of time necessary to get every class that used the system to match all of its methods and members up with legal calls: 1) Any class could call any method on any other class without having to include headers or write fake base classes so the interface could be predefined for the compiler; and 2) The getters and setters of the member variables were easy to make thread-safe because changing or accessing their values was always done through 2 methods in the base class of all objects.

It also led to the possibility of doing some really weird things that otherwise aren't easy in C++. For example I could create an Array object that contained arbitrary items of any type, including itself, and create new arrays dynamically by passing a message to all array items and collecting the return values (similar to map in Lisp). Another was the implementation of key-value observing, whereby I was able to set up the UI to respond immediately to changes in the members of backend classes instead of constantly polling the data or unnecessarily redrawing the display.

Maybe more interesting to you is the fact that you can also dump all methods and members defined for a class, and in string form no less.

Downsides to the system that might discourage you from bothering: adding all of the messages and key-values is extremely tedious; it's slower than without any reflection; you'll grow to hate seeing boost::static_pointer_cast and boost::dynamic_pointer_cast all over your codebase with a violent passion; the limitations of the strongly-typed system are still there, you're really just hiding them a bit so it isn't as obvious. Typos in your strings are also not a fun or easy to discover surprise.

As to how to implement something like this: just use shared and weak pointers to some common base (mine was very imaginatively called "Object") and derive for all the types you want to use. I'd recommend installing Boost.Function instead of doing it the way I did, which was with some custom crap and a ton of ugly macros to wrap the function pointer calls. Since everything is mapped, inspecting objects is just a matter of iterating through all of the keys. Since my classes were essentially as close to a direct ripoff of Cocoa as possible using only C++, if you want something like that then I'd suggest using the Cocoa documentation as a blueprint.

  • Hey, @Michael; do you still have the source code for this, or did you get rid of it? I'd like to take a look at it if you don't mind. Nov 3, 2014 at 17:16
  • Whoops, spelled your name wrong! No wonder I never got a reply… Nov 1, 2015 at 0:52

The two reflection-like solutions I know of from my C++ days are:

1) Use RTTI, which will provide a bootstrap for you to build your reflection-like behaviour, if you are able to get all your classes to derive from an 'object' base class. That class could provide some methods like GetMethod, GetBaseClass etc. As for how those methods work you will need to manually add some macros to decorate your types, which behind the scenes create metadata in the type to provide answers to GetMethods etc.

2) Another option, if you have access to the compiler objects is to use the DIA SDK. If I remember correctly this lets you open pdbs, which should contain metadata for your C++ types. It might be enough to do what you need. This page shows how you can get all base types of a class for example.

Both these solution are a bit ugly though! There is nothing like a bit of C++ to make you appreciate the luxuries of C#.

Good Luck.

  • That is crafty and a giant hack, with the DIA SDK thing you suggested there.
    – Sqeaky
    Mar 21, 2012 at 3:57

I think you might find interesting the article "Using Templates for Reflection in C++" by Dominic Filion. It is in section 1.4 of Game Programming Gems 5. Unfortunately I dont have my copy with me, but look for it because I think it explains what you are asking for.


This question is a bit old now (don't know why I keep hitting old questions today) but I was thinking about BOOST_FUSION_ADAPT_STRUCT which introduces compile-time reflection.

It is up to you to map this to run-time reflection of course, and it won't be too easy, but it is possible in this direction, while it would not be in the reverse :)

I really think a macro to encapsulate the BOOST_FUSION_ADAPT_STRUCT one could generate the necessary methods to get the runtime behavior.

  • 2
    by minghua (who originally edited the post): I dug into this BOOST_FUSION_ADAPT_STRUCT solution and eventually came up with an example. See this newer SO question - C++ iterate into nested struct field with boost fusion adapt_struct. Aug 26, 2012 at 10:55
  • Great, Matthieu! Just realized having seen your hints here and there over the course of the past year. Did not notice they are related till now. Those were very inspiring.
    – minghua
    Sep 6, 2012 at 7:14
  • @MatthieuM. The link to BOOST_FUSION_ADAPT_STRUCT is broken
    – ilciavo
    May 26, 2023 at 6:39

Reflection is essentially about what the compiler decided to leave as footprints in the code that the runtime code can query. C++ is famous for not paying for what you don't use; because most people don't use/want reflection, the C++ compiler avoids the cost by not recording anything.

So, C++ doesn't provide reflection, and it isn't easy to "simulate" it yourself as general rule as other answers have noted.

Under "other techniques", if you don't have a language with reflection, get a tool that can extract the information you want at compile time.

Our DMS Software Reengineering Toolkit is generalized compiler technology parameterized by explicit langauge definitions. It has langauge definitions for C, C++, Java, COBOL, PHP, ...

For C, C++, Java and COBOL versions, it provides complete access to parse trees, and symbol table information. That symbol table information includes the kind of data you are likely to want from "reflection". If you goal is to enumerate some set of fields or methods and do something with them, DMS can be used to transform the code according to what you find in the symbol tables in arbitrary ways.


EDIT: Updated broken link as of February, the 7th, 2017.

I think noone mentioned this:

At CERN they use a full reflection system for C++:

CERN Reflex. It seems to work very well.


The RareCpp library makes for fairly easy and intuitive reflection - all field/type information is designed to either be available in arrays or to feel like array access. It's written for C++17 and works with Visual Studios, g++, and Clang. The library is header only, meaning you need only copy "Reflect.h" into your project to use it.

Reflected structs or classes need the REFLECT macro, where you supply the name of the class you're reflecting and the names of the fields.

class FuelTank {
        float capacity;
        float currentLevel;
        float tickMarks[2];

    REFLECT(FuelTank, capacity, currentLevel, tickMarks)

That's all there is, no additional code is needed to setup reflection. Optionally you can supply class and field annotations to be able to traverse superclasses or add additional compile-time information to a field (such as Json::Ignore).

Looping through fields can be as simple as...

RareTs::Members<FuelTank>::forEach([&](auto member) {
    std::cout << member.name << std::endl;

You can include an instance/get the values and access type information:

RareTs::Members<FuelTank>::forEach(fuelTank, [](auto member, auto & value) {
    using MemberType = typename decltype(member)::type;
    std::cout << RareTs::toStr<MemberType>() << " " << member.name
        << ": " << value << std::endl;

A JSON Library is built on top of RareCpp which auto identifies appropriate JSON output representations for reading or writing, and can recursively traverse any reflected fields, as well as arrays and STL containers.

struct MyOtherObject { int myOtherInt; REFLECT(MyOtherObject, myOtherInt) };
struct MyObject
    int myInt;
    std::string myString;
    MyOtherObject myOtherObject;
    std::vector<int> myIntCollection;

    REFLECT(MyObject, myInt, myString, myOtherObject, myIntCollection)

int main()
    MyObject myObject = {};
    std::cout << "Enter MyObject:" << std::endl;
    std::cin >> Json::in(myObject);
    std::cout << std::endl << std::endl << "You entered:" << std::endl;
    std::cout << Json::pretty(myObject);

The above could be ran like so...

Enter MyObject:
  "myInt": 1337, "myString": "stringy", "myIntCollection": [2,4,6],
  "myOtherObject": {
    "myOtherInt": 9001

You entered:
  "myInt": 1337,
  "myString": "stringy",
  "myOtherObject": {
    "myOtherInt": 9001
  "myIntCollection": [ 2, 4, 6 ]

See also...


Ponder is a C++ reflection library, in answer to this question. I considered the options and decided to make my own since I couldn't find one that ticked all my boxes.

Although there are great answers to this question, I don't want to use tonnes of macros, or rely on Boost. Boost is a great library, but there are lots of small bespoke C++0x projects out that are simpler and have faster compile times. There are also advantages to being able to decorate a class externally, like wrapping a C++ library that doesn't (yet?) support C++11. It is fork of CAMP, using C++11, that no longer requires Boost.


You can find another library here: http://www.garret.ru/cppreflection/docs/reflect.html It supports 2 ways: getting type information from debug information and let programmer to provide this information.

I also interested in reflection for my project and found this library, i have not tried it yet, but tried other tools from this guy and i like how they work :-)


If you're looking for relatively simple C++ reflection - I have collected from various sources macro / defines, and commented them out how they works. You can download header files from here:


set of defines, plus functionality on top of it:

https://github.com/tapika/TestCppReflect/blob/master/CppReflect.h https://github.com/tapika/TestCppReflect/blob/master/CppReflect.cpp https://github.com/tapika/TestCppReflect/blob/master/TypeTraits.h

Sample application resides in git repository as well, in here: https://github.com/tapika/TestCppReflect/

I'll partly copy it here with explanation:

#include "CppReflect.h"
using namespace std;

class Person

    // Repack your code into REFLECTABLE macro, in (<C++ Type>) <Field name>
    // form , like this:

    REFLECTABLE( Person,
        (CString)   name,
        (int)       age,

void main(void)
    Person p;
    p.name = L"Roger";
    p.age = 37;

    // And here you can convert your class contents into xml form:

    CStringW xml = ToXML( &p );
    CStringW errors;

    People ppl2;

    // And here you convert from xml back to class:

    FromXml( &ppl2, xml, errors );
    CStringA xml2 = ToXML( &ppl2 );
    printf( xml2 );


REFLECTABLE define uses class name + field name with offsetof - to identify at which place in memory particular field is located. I have tried to pick up .NET terminology for as far as possible, but C++ and C# are different, so it's not 1 to 1. Whole C++ reflection model resides in TypeInfo and FieldInfo classes.

I have used pugi xml parser to fetch demo code into xml and restore it back from xml.

So output produced by demo code looks like this:

<?xml version="1.0" encoding="utf-8"?>
<People groupName="Group1">
        <Person name="Roger" age="37" />
        <Person name="Alice" age="27" />
        <Person name="Cindy" age="17" />

It's also possible to enable any 3-rd party class / structure support via TypeTraits class, and partial template specification - to define your own TypeTraitsT class, in similar manner to CString or int - see example code in


This solution is applicable for Windows / Visual studio. It's possible to port it to other OS/compilers, but haven't done that one. (Ask me if you really like solution, I might be able to help you out)

This solution is applicable for one shot serialization of one class with multiple subclasses.

If you however are searching for mechanism to serialize class parts or even to control what functionality reflection calls produce, you could take a look on following solution:


More detailed information can be found from youtube video:

C++ Runtime Type Reflection https://youtu.be/TN8tJijkeFE

I'm trying to explain bit deeper on how c++ reflection will work.

Sample code will look like for example this:


c.General.IntDir = LR"(obj\$(ProjectName)_$(Configuration)_$(Platform)\)";
c.General.OutDir = LR"(bin\$(Configuration)_$(Platform)\)";
c.General.UseDebugLibraries = true;
c.General.LinkIncremental = true;
c.CCpp.Optimization = optimization_Disabled;
c.Linker.System.SubSystem = subsystem_Console;
c.Linker.Debugging.GenerateDebugInformation = debuginfo_true;

But each step here actually results in function call Using C++ properties with __declspec(property(get =, put ... ).

which receives full information on C++ Data Types, C++ property names and class instance pointers, in form of path, and based on that information you can generate xml, json or even serialize that one over internet.

Examples of such virtual callback functions can be found here:


See functions ReflectCopy, and virtual function ::OnAfterSetProperty.

But since topic is really advanced - I recommend to check through video first.

If you have some improvement ideas, feel free to contact me.


When I wanted reflection in C++ I read this article and improved upon what I saw there. Sorry, no can has. I don't own the result...but you can certainly get what I had and go from there.

I am currently researching, when I feel like it, methods to use inherit_linearly to make the definition of reflectable types much easier. I've gotten fairly far in it actually but I still have a ways to go. The changes in C++0x are very likely to be a lot of help in this area.


It looks like C++ still does not have this feature. And C++11 postponed reflection too ((

Search some macros or make own. Qt also can help with reflection (if it can be used).


even though reflection is not supported out-of-the-box in c++, it is not too hard to implement. I've encountered this great article: http://replicaisland.blogspot.co.il/2010/11/building-reflective-object-system-in-c.html

the article explains in great detail how you can implement a pretty simple and rudimentary reflection system. granted its not the most wholesome solution, and there are rough edges left to be sorted out but for my needs it was sufficient.

the bottom line - reflection can pay off if done correctly, and it is completely feasible in c++.


Check out Classdesc http://classdesc.sf.net. It provides reflection in the form of class "descriptors", works with any standard C++ compiler (yes it is known to work with Visual Studio as well as GCC), and does not require source code annotation (although some pragmas exist to handle tricky situations). It has been in development for more than a decade, and used in a number of industrial scale projects.

  • 1
    Welcome to Stack Overflow. Although this answer is on topic, it's important to point out that you are the author of this software, to make it clear it's not an unbiased recommendation :-) Apr 6, 2013 at 8:07

I would like to advertise the existence of the automatic introspection/reflection toolkit "IDK". It uses a meta-compiler like Qt's and adds meta information directly into object files. It is claimed to be easy to use. No external dependencies. It even allows you to automatically reflect std::string and then use it in scripts. Please look at IDK


Reflection in C++ is very useful, in cases there you need to run some method for each member(For example: serialization, hashing, compare). I came with generic solution, with very simple syntax:

struct S1
    std::string str;
    int i;
struct S2
    S1 s1;
    int i2;

Where ENUMERATE_MEMBERS is a macro, which is described later(UPDATE):

Assume we have defined serialization function for int and std::string like this:

void EnumerateWith(BinaryWriter & writer, int val)
    //store integer
    writer.WriteBuffer(&val, sizeof(int));
void EnumerateWith(BinaryWriter & writer, std::string val)
    //store string
    writer.WriteBuffer(val.c_str(), val.size());

And we have generic function near the "secret macro" ;)

template<typename TWriter, typename T>
auto EnumerateWith(TWriter && writer, T && val) -> is_enumerable_t<T>
    val.EnumerateWith(write); //method generated by ENUMERATE_MEMBERS macro

Now you can write

S1 s1;
S2 s2;
BinaryWriter writer("serialized.bin");

EnumerateWith(writer, s1); //this will call EnumerateWith for all members of S1
EnumerateWith(writer, s2); //this will call EnumerateWith for all members of S2 and S2::s1 (recursively)

So having ENUMERATE_MEMBERS macro in struct definition, you can build serialization, compare, hashing, and other stuffs without touching original type, the only requirement is to implement "EnumerateWith" method for each type, which is not enumerable, per enumerator(like BinaryWriter). Usually you will have to implement 10-20 "simple" types to support any type in your project.

This macro should have zero-overhead to struct creation/destruction in run-time, and the code of T.EnumerateWith() should be generated on-demand, which can be achieved by making it template-inline function, so the only overhead in all the story is to add ENUMERATE_MEMBERS(m1,m2,m3...) to each struct, while implementing specific method per member type is a must in any solution, so I do not assume it as overhead.

UPDATE: There is very simple implementation of ENUMERATE_MEMBERS macro(however it could be a little be extended to support inheritance from enumerable struct)

#define ENUMERATE_MEMBERS(...) \
template<typename TEnumerator> inline void EnumerateWith(TEnumerator & enumerator) const { EnumerateWithHelper(enumerator, __VA_ARGS__ ); }\
template<typename TEnumerator> inline void EnumerateWith(TEnumerator & enumerator) { EnumerateWithHelper(enumerator, __VA_ARGS__); }

// EnumerateWithHelper
template<typename TEnumerator, typename ...T> inline void EnumerateWithHelper(TEnumerator & enumerator, T &...v) 
    int x[] = { (EnumerateWith(enumerator, v), 1)... }; 

// Generic EnumerateWith
template<typename TEnumerator, typename T>
auto EnumerateWith(TEnumerator & enumerator, T & val) -> std::void_t<decltype(val.EnumerateWith(enumerator))>

And you do not need any 3rd party library for these 15 lines of code ;)


You can achieve cool static reflection features for structs with BOOST_HANA_DEFINE_STRUCT from the Boost::Hana library.
Hana is quite versatile, not only for the usecase you have in mind but for a lot of template metaprogramming.


If you declare a pointer to a function like this:

int (*func)(int a, int b);

You can assign a place in memory to that function like this (requires libdl and dlopen)

#include <dlfcn.h>

int main(void)
    void *handle;
    char *func_name = "bla_bla_bla";
    handle = dlopen("foo.so", RTLD_LAZY);
    *(void **)(&func) = dlsym(handle, func_name);
    return func(1,2);

To load a local symbol using indirection, you can use dlopen on the calling binary (argv[0]).

The only requirement for this (other than dlopen(), libdl, and dlfcn.h) is knowing the arguments and type of the function.

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