0

Here is what my situation looks like:

template <typename T>
struct Foo 
{
    Foo() {}
    Foo(T data) : _data(data) {}

    T _data;
};

struct Holder
{
    Holder() {}
    Holder(int a) : foo(a) {}

    virtual Foo<int> getFoo() { return foo; }
    virtual std::string type() { return "holder"; } // EDIT 2 EDIT 3: added virtual

    Foo<int> foo;
};

struct HolderInt : public Holder
{
    HolderInt() {}
    HolderInt(int a) : Holder(a) {}

    std::string type() { return "holderint"; } // EDIT 2
};

struct HolderString : public Holder
{
    HolderString() {}
    HolderString(std::string a) : Holder(0), foo(a) {}

    Foo<std::string> getFoo() { return foo; } // here is the dilema
    std::string type() { return "holderstring"; } // EDIT 2

    Foo<std::string> foo;
};

int main()
{
    std::vector<Holder*> holders;
    holders.push_back(new HolderString());

    return 0;
}

I am looking for a way to make this happen. The way I'm hoping to get this to work is to maintain a single getter, but if I'm missing something that would be very useful for my situation that would be great to know.

EDIT: I understand that virtual functions cannot have different return types, but I am looking for another option. Sorry for not saying so before.

EDIT 2: After further reviewing my code, I have realized that I missed something important. I have a "to string" function so to speak, which I will edit in. This can help me differentiate between each struct type, even if they have the same foo. I don't know how I didn't see this before I've been looking it over for a while now, but I am able to solve this problem using that virtual function.

  • 1
    You are missing the fact that a function can only return a single type; and you have two different getters returning two different types, a Foo<std::string>, and a Foo<int>. Whatever getter you come up with, it always returns the same type. – Sam Varshavchik Mar 30 '18 at 22:44
  • 3
    This can never work. Foo<int> and Foo<string> are not covariant types, and you can't overload a method based on return type alone. – Remy Lebeau Mar 30 '18 at 22:44
  • Your example is missing a crucial part: a use case. Please show what you would do with holders[i]. – Kerrek SB Mar 30 '18 at 23:07
0

If I understand your question correctly, try something like this:

template <typename T>
struct foo
{
  T data;

  foo() {}
  foo(T d) : data(d) {}

  void set(T d) { data = d; } // Good practice to also have a setter
  T get() { return data; }
};

struct holder_int
  : public foo<int>
{
  holder_int(int i) : foo(i) {}
};

struct holder_str
  : public foo<std::string>
{
  holder_str(const std::string& str) : foo(str) {}
};

This uses a single generic (template) struct foo which also has a generic (template) get function. Each struct that inherits from that struct sets the type in foo (if that makes sense). Basically, a struct that holds an integer will inherit from foo<int> and a struct that holds a double will inherit from foo<double>.

  • This is a great solution, but it won't work out in my code. This generalized code that I made for this question is missing all of my other stuff that I have going on, and my project is build around the "holder" struct (in my actual code it would be a class) being the base and having other types of holders that don't necessarily have to have different type values. I plan on making multiple other HolderString types where they have Data<string> but have different functionality. – desluOs Mar 30 '18 at 23:08
  • Can the holder class be generic and have a generic getter/setter, and then all of the other holders inherit off of that generic holder? What is the significance of the foo struct. – Charlie Sale Mar 30 '18 at 23:13
0

This cannot work. At compile time the compiler must have a type for each variable. Let's pretend you could do something like what you want

// illegal code
struct Holder {
    virtual ? get() = 0;
};

struct HolderInt : Holder {
    int get() override { return 0; }
};

struct HolderString : Holder{
    std::string get() override { return ""; }
};

Now let's say you have a function taking a Holder*

void func(Holder* holder) {
    auto t = holder->get(); // type of t must be known at compile-time

    constexpr auto sz = sizeof t; // must be known at compile-time
    using Type = decltype(t); // must be known at compile-time
}

The type of t must be known at compile-time, but your code makes that impossible to know until run time.

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