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In c++ different type conversions are implicitly done. For example an object of type int can be assigned to const int (as done in the first lines of the main function in the code below).

Now I would like to check for convertability at runtime in the sence that I have a structure where I can add types and later I want to check for a given type if one of the types stored in the structure is convertible to the given type.

Here is what I came up with so far:

#include <iostream>
#include <vector>

struct bar { virtual void dummy() {} };
template<typename T> struct foo : public bar { virtual void dummy() {} };

int main() {

    int i1 = 1;
    const int i2 = i1;

    std::vector<bar*> bars;
    bar* t1 = new foo<int>; bars.push_back(t1);
    bar* t2 = new foo<int const>; bars.push_back(t2);

    foo<int const>* t3 = dynamic_cast<foo<int const>*>(bars[0]);
    std::cout << t3 << std::endl;

    foo<int const>* t4 = dynamic_cast<foo<int const>*>(bars[1]);
    std::cout << t4 << std::endl;

    delete t1;
    delete t2;

    return 0;

In order to store types in a structure I created the templated structure foo which is derived from bar. Then I can store the different types int and int const (to be precise pointers to objects of type foo<int> and foo<int const>) in a vector of bar*s. Then for a given type (here int const) I check for each element in this vector if it could be dynamically casted to a foo with this type.

When running this code t3 becomes the nullptr and t4 a non-null pointer. But I wanted to have for t3 also a non-null pointer.

I hope it became approximately clear what I want to do.

Do you have any ideas how to achieve this kind of checking for comvertability at runtime (a solution involving c++11-features would be totally fine)?

share|improve this question
Ah, double dispatch. We meet again. –  Mooing Duck Jun 28 '13 at 20:14
If you know and are ok with listing all possible conversions at compile time, this is possible. Otherwise, it's not really possible –  Mooing Duck Jun 28 '13 at 20:17
My first reaction was: Use std::is_convertible<From, To>::value but for some reason I get that std::is_convertible<int const, int>::value is true (why?). –  alfC Jun 28 '13 at 21:15
Wait, do you want to support any conversions, only compiler conversions, or just const/volatile conversions? –  Mooing Duck Jun 28 '13 at 21:16
@alfC: because const int is convertible to int... –  Mooing Duck Jun 28 '13 at 21:16

2 Answers 2

up vote 4 down vote accepted

Unfortunately, since foo<int> and foo<const int> are completely unrelated types, you can't do this easily.

bar* t1 = new foo<int>;
foo<int const>* t3 = ?????<foo<int const>*>(t1);

t3 can't be a pointer at any part of t1, since t1 neither is, nor contains, a foo<int const> for t3 to point at. The only way to get any sort of good behavior out of this is to make a copy of the data that t1 holds into a brand new foo<int const>*. This frustrating limitation is a side-effect of templates being specializable with unrelated types, which is an awesomely powerful tool, but results in this confusion. A general rule of thumb is to NOT put const/volatile qualifications, nor references of any sort into template parameters, unless that is the sole reason for the template class (such as std::remove_reference).

However, I just realized, what you want is for foo<int> and for foo<const int> to be the same type(ish), and that can be done (sortof)!

struct base { 
    virtual ~base(){}; //always have virtual destructor with polymorphism
    virtual void dummy()=0; //pure virtual, forces override
template<typename T> 
struct foo : public bar { 
    virtual void dummy() {} 
template<typename T> struct foo<const T> : public foo<T> {};
template<typename T> struct foo<volatile T> : public foo<T> {};
template<typename T> struct foo<const volatile T> : public foo<T> {};

base* t1 = new derived<const int>;
derived<int>* t3 = dynamic_cast<derived<int>*>(t1); //hooray!
//you can go from derived<const int> to derived<int> but not the other way around
share|improve this answer
This looks interesting. In your code it only supports cv-qualifiers but I think I can extend it at least to a somewhat bigger subset of the standard type-conversions. Am I correct, that the third line with const volatile is not actually needed as otherwise we would simply have a two-step inheritance a la foo<T const volatile> is a foo<T const> is a foo<T> (is a base)? –  mg84 Jun 29 '13 at 6:22
Though it doesn't do exactly I was hoping for I take this as the accepted answer. It seems (in an extended version) to be the closest I can get. –  mg84 Jun 29 '13 at 10:31

Use std::is_convertible<From*, To*>::value

int main(){
    using namespace std;
    cout << std::is_convertible<int const, int>::value << endl; // print true
    cout << std::is_convertible<int const*, int*>::value << endl; // print false
    cout << std::is_convertible<int const, int>::value << endl; // print true
    cout << std::is_convertible<std::string, int>::value << endl; // print false
    cout << std::is_convertible<std::string*, int*>::value << endl; // print false

Note that you have to use the pointer type to obtain the excepted behavior with respect to constness for example.

(I guess in C++98 you can do the same with boost::is_convertible.)

share|improve this answer
And how would you apply this to a polymorphic template like in the question? –  Mooing Duck Jun 28 '13 at 21:30
Well, I didn't understand that part of the question, I assumed that once you have access to the conversion at runtime and compile time you can do whatever you want with it, including dispatch, double dispatch and compile-time dispatch, enable_if, etc. –  alfC Jun 28 '13 at 21:33
The conversions are easy. What he wants is for foo<int> and foo<const int> to be the same type. –  Mooing Duck Jun 28 '13 at 21:37
I see, then yes he is asking that foo<const int> is derived from foo<int> (as in your answer). Well, I think it still answers part of the question (the title at least). –  alfC Jun 28 '13 at 21:45
@alfC: Thanks for your answer. I didn't know that there is a std::is_convertible. But it seems that it doesn't solve my problem since all types need to be known at compile time. –  mg84 Jun 29 '13 at 6:19

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