21

Basically I want MyClass that holds a Hashmap that maps Field name(string) to ANY type of Value.. For this purpose I wrote a separate MyField class that holds the type & value information..

This is what I have so far:

template <typename T>
class MyField {
    T m_Value;
    int m_Size;
}


struct MyClass {
    std::map<string, MyField> fields;   //ERROR!!!
}

But as you can see, the map declaration fails because I didn't provide the type parameter for MyField...

So I guess It has to be something like

std::map< string, MyField<int> > fields;

or

std::map< string, MyField<double> > fields;


But obviously this undermines my whole purpose, because the declared map can only hold MyField of a specific type.. I want a map that can hold ANY type of MyField clas..

Is there any way I can achieve this..?

  • 4
    You need some kind of type erasure. I recommend boost::any. – chris Jul 11 '14 at 16:19
  • You could use std::map<std::string, std::shared_ptr<void>>. – Bill Lynch Jul 11 '14 at 16:21
  • @sharth Is there any reason why you're using shared_ptr<void> instead of simply (void *)? – user3794186 Jul 11 '14 at 16:23
  • I think that's taking type erasure too far, using void * (shared_ptr<void> is the same). You'd need at least an extra value to figure out what that thing is. I'd either use a pointer to a base class or boost::variant<> if that's unavailable, unless you're writing really low level code. – Blindy Jul 11 '14 at 16:24
  • If it's really just any MyField<T>, I guess another option is a base class that each MyField<T> inherits from. – chris Jul 11 '14 at 16:27
24

Blindy's answer is very good (+1), but just to complete the answer: there is another way to do it with no library, by using dynamic inheritance:

class MyFieldInterface
{
    int m_Size; // of course use appropriate access level in the real code...
    ~MyFieldInterface() = default;
}

template <typename T>
class MyField : public MyFieldInterface {
    T m_Value; 
}


struct MyClass {
    std::map<string, MyFieldInterface* > fields;  
}

Pros:

  • it's familiar to any C++ coder
  • it don't force you to use Boost (in some contexts you are not allowed to);

Cons:

  • you have to allocate the objects on the heap/free store and use reference semantic instead of value semantic to manipulate them;
  • public inheritance exposed that way might lead to over-use of dynamic inheritance and a lot of long-term issues related to your types really being too inter-dependent;
  • a vector of pointers is problematic if it have to own the objects, as you have to manage destruction;

So use boost::any or boost::variant as default if you can, and consider this option only otherwise.

To fix that last cons point you could use smart pointers:

struct MyClass {
    std::map<string, std::unique_ptr<MyFieldInterface> > fields;  // or shared_ptr<> if you are sharing ownership
}

However there is still a potentially more problematic point:

It forces you to create the objects using new/delete (or make_unique/shared). This mean that the actual objects are created in the free store (the heap) at any location provided by the allocator (mostly the default one). Therefore, going though the list of objects very often is not as fast as it could be because of cache misses.

diagram of vector of polymorphic objects

If you are concerned with performance of looping through this list very often as fast as possible (ignore the following if not), then you'd better use either boost::variant (if you already know all the concrete types you will use) OR use some kind of type-erased polymorphic container.

diagram of polymorphic container

The idea is that the container would manage arrays of objects of the same type, but that still expose the same interface. That interface can be either a concept (using duck-typing techniques) or a dynamic interface (a base class like in my first example). The advantage is that the container will keep same-type objects in separate vectors, so going through them is fast. Only going from one type to another is not.

Here is an example (the images are from there): http://bannalia.blogspot.fr/2014/05/fast-polymorphic-collections.html

However, this technique loose it's interest if you need to keep the order in which the objects are inserted.

In any way, there are several solutions possible, which depends a lot on your needs. If you have not enough experience with your case, I suggest using either the simple solution I first explained in my example or boost::any/variant.


As a complement to this answer, I want to point very good blog articles which summarize all C++ type-erasure techniques you could use, with comments and pros/cons:

16

Use either boost::variant (if you know the types you can store, it provides compile time support) or boost::any (for really any type -- but that's kind of unlikely to be the case).

http://www.boost.org/doc/libs/1_55_0/doc/html/variant/misc.html#variant.versus-any

Edit: I cannot emphasize enough that although rolling your own solution might seem cool, using a complete, proper implementation will save you a lot of headache in the long run. boost::any implements RHS copy constructors (C++11), both safe (typeid()) and unsafe (dumb casts) value retrievals, with const corectness, RHS operands and both pointer and value types.

That's true in general, but even more so for low level, base types you build your entire application on.

8
class AnyBase
{
public:
    virtual ~AnyBase() = 0;
};
inline AnyBase::~AnyBase() {}

template<class T>
class Any : public AnyBase
{
public:
    typedef T Type;
    explicit Any(const Type& data) : data(data) {}
    Any() {}
    Type data;
};

std::map<std::string, std::unique_ptr<AnyBase>> anymap;
anymap["number"].reset(new Any<int>(5));
anymap["text"].reset(new Any<std::string>("5"));

// throws std::bad_cast if not really Any<int>
int value = dynamic_cast<Any<int>&>(*anymap["number"]).data;
  • You could add a member in the base class to get the value and avoid the extra casts ((Any<int> &)(*anymap["number"]).data looks horrible). But at that point you implemented a basic boost::any, might as well use the complete and well tested class. +1 though, the creating is spot on! – Blindy Jul 11 '14 at 16:32
  • I'll definitely try this! Can you explain to me about the two destructors AnyBase has?? I don't quite understand why you have two of them and why you need them.. thanks – user3794186 Jul 11 '14 at 16:33
  • @user3794186, There's only one desctructor, and it's virtual because otherwise derived types' desctructors wouldn't get called (and so the data destructors wouldn't get called). – Blindy Jul 11 '14 at 16:35
  • @Blindy Oh I get it. What about the inline destructor..? – user3794186 Jul 11 '14 at 16:37
  • @user3794186, it's just the implementation, pure virtual destructors have to have an implementation in C++. I think the point is to make the base class abstract (and so un-creatable), a clearer way would be with a private constructor. – Blindy Jul 11 '14 at 16:42
6

This is plain in C++ 17. Use std::map + std::any + std::any_cast:

#include <map>
#include <string>
#include <any>

main()
{
    std::map<std::string, std::any> Notebook;

    std::string name{ "Pluto" };
    int year = 2015;

    Notebook["PetName"] = name;
    Notebook["Born"] = year;

    std::string strS = std::any_cast<std::string>(Notebook["PetName"]);; // = "Pluto"
    int intI = std::any_cast<int>(Notebook["Born"]); // = 2015
}
3

C++17 has a std::variant type that has facilities for holding different types much better than a union.

For those not on C++17, boost::variant implements this same mechanism.

For those not using boost, https://github.com/mapbox/variant implements a much lighter version of variant for C++11 and C++14 that looks very promising, well documented, lightweight, and has plenty of usage examples.

0

You could also use a void* and cast the value back to the correct type using reinterpret_cast. Its a technique often used in C in callbacks.

#include <iostream>
#include <unordered_map>
#include <string>
#include <cstdint> // Needed for intptr_t
using namespace std;


enum TypeID {
    TYPE_INT,
    TYPE_CHAR_PTR,
    TYPE_MYFIELD
};    

struct MyField {
    int typeId;
    void * data;
};

int main() {

    std::unordered_map<std::string, MyField> map;

    MyField anInt = {TYPE_INT, reinterpret_cast<void*>(42) };

    char cstr[] = "Jolly good";
    MyField aCString = { TYPE_CHAR_PTR, cstr };

    MyField aStruct  = { TYPE_MYFIELD, &anInt };

    map.emplace( "Int", anInt );
    map.emplace( "C String", aCString );
    map.emplace( "MyField" , aStruct  );  

    int         intval   = static_cast<int>(reinterpret_cast<intptr_t>(map["Int"].data)); 
    const char *cstr2    = reinterpret_cast<const char *>( map["C String"].data );
    MyField*    myStruct = reinterpret_cast<MyField*>( map["MyField"].data );

    cout << intval << '\n'
         << cstr << '\n'
         << myStruct->typeId << ": " << static_cast<int>(reinterpret_cast<intptr_t>(myStruct->data)) << endl;
}
  • 2
    s/reinterpret_cast/static_cast/ – chris Jul 11 '14 at 17:15

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