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I was wondering if some form of type erasure exists for dealing with methods that have the same name and arguments but return different values like in my example below (begin and end). I'm not planning on actually using this anywhere I'm just interested in knowing if it's possible, and, if so, how it would be done.

The only form of type erasure I know about is having a pointer to a pure virtual concept class which points to a model<T> which forwards calls to the underlying T. However, this requires that all the T's contain methods with the exact same signature, while in my example the return types differ. As far as I can tell something akin to virtual template functions would be needed to do what I'm asking, but I may be missing something.

class Iterable
{
    //how would this be defined?
}

int main(int argc, char *argv[])
{
    vector<int> v = {1, 2, 3, 4, 5};
    set<string> s = {"foo", "bar", "baz"};

    Iterable iterable;

    if(argc == 2) iterable = v;
    else iterable = s;


    for(auto val : it)
    { 
        cout << val << ' ';
    }
}
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4 Answers 4

up vote 8 down vote accepted

Type erasure can and has been implemented in C++ in different contexts. The most common approach, which is used in boost::any, std::function< signature >, std::thread and others is based on a non-polymorphic class that is the type erased object, which contains a pointer to an interface type. Internally, during construction, assignment or whenever the user type is erased, an implementation of the interface is instantiated and stored.

As a motivating simplified example, consider that we wanted to create a printable type that can be used to print any type that implements operator<< to std::cout using type erasure. For that we need the type printable, the internal interface printable_impl_base, and the actual implementations:

// regular polymorphic hierarchy:
struct printable_impl_base {
   virtual ~printable_impl_base() {}
   virtual void print() const = 0;
};
template <typename T>
struct printable_impl : printable_impl_base {
   T copy_to_print;
   printable_impl( T const & o ) : copy_to_print( o ) {}
   virtual void print() const {
      std::cout << copy_to_print << std::endl;
   }
};

// type erasure is performed in printable:
class printable {
   std::shared_ptr<printablable_impl_base> p;
public:
   template <typename T>
   printable( T obj ) : p( new printable_impl<T>(obj) ) {}
   void print() const {
      p->print();
   }
};

Note that the pattern is very similar to a regular polymorphic hierarchy, with the difference that an interface object is added that is a value type (borrowing the term value type from C#), that holds the actual polymorphic objects inside.

Looking at it this way, it seems kind of simplistic and useless, but that is the fuel that drives boost::any (the internal interface is only a typeid), std::function< void () > (the internal interface is that it implements void operator()), or shared_ptr<> (the interface is the deleter method, that relinquishes the resource).

There is one specific different type of type erasure when the only thing that needs to be done with the type that implements type erasure is to destroy it: use a temporary and bind it to a constant reference... But this is very specific, if you want you can read about it here: http://drdobbs.com/cpp/184403758

In the specific case that you are talking about in the question it is a bit more complex, because you don't want to erase a single type, but rather a couple of them. The Iterable interface must erase the type of the container that it internally holds, and in doing so it has to provide it's own iterators that have to perform type erasure on the iterators from the container. Still, the idea is basically the same, just more work to do to implement.

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+1. Very nice answer. –  Diego Sevilla May 22 '11 at 22:06
1  
The example code depicts the external polymorphism pattern –  wmamrak Jan 12 '13 at 14:42

Whenever I see the term "type erasure", I get uncomfortable. Why, in a strongly typed language (or a weakly typed one) would you want to erase type?

And no, you can't do this.

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3  
Ever used function or shared_ptr from Boost or C++0x stdlib? They do exactly that, and I want it. –  Xeo May 22 '11 at 17:46
3  
It can be done. It just cannot be done by a beginner. This is what any_iterator has been doing for ages. Add to it the ability to polymorphically output its values and you are set. –  Johannes Schaub - litb May 22 '11 at 18:07
3  
@Neil, shared_ptr does type erasure for the destruction of the object. If you do: shared_ptr<void> p = make_shared<Type>(); the type is shared_ptr<void>, but once it goes out of scope it will call the appropriate destructor (in this case ~Type()). –  David Rodríguez - dribeas May 22 '11 at 18:12
1  
@Neil: Yes, I am. It deletes the type of the allocation and deletion mechanic you pass to its constructor. –  Xeo May 22 '11 at 18:12
3  
@Neil: I think that's just a misunderstanding of (our intended meaning of) the term, then. Type erasure is not the same ditching type information, it's taking the type information and hiding it behind a singly-typed interface. shared_ptr<void> can delete many things, but they're all still managed by a single type. From the perspective of the user, the dynamic type has been erased from share_ptr<void>. –  GManNickG May 22 '11 at 18:28

You may be interested in boost::any:

http://www.boost.org/doc/libs/1_46_1/doc/html/any.html

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Link-only answers are fragile with respect to future bit-rot, could you perhaps expand it a bit with some content? –  TemplateRex May 9 '13 at 22:12

The C++ Standard library does not support run-time variance in it's container types. There's nothing wrong with implementing this, however, the memory management without garbage collection at the language level is going to be ick-tastic and you're going to have fun making it performant.

What's worth mentioning is that in some STL implementations, they implement something known as SCARY iteration, where vector<int, std::allocator<int>>::iterator is the same type as vector<int, mycustomallocator<int>>::iterator.

In addition, you need to be very careful. A vector is definitely RandomAccessIterable, but a set is only ConstIterable and is definitely not RandomAccessIterable, and an InputIterator is only ForwardIterable. You would have to define templates for all of these scenarios.

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