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I have a lot of subclasses of an abstract class Letter, like A, B, C, D, etc. Letter has an integer ID variable, and every subclass of Letter gets assigned a unique id.

I then have another class, call it Alphabet. Alphabet has an

list<shared_ptr<Letter>> 

member. Here is the problem... I would like to elegantly add B's and C's or other subclasses of Letter to particular instances of Alphabets. I think the most convenient way to do this would be to use the integer id of subclass somehow. In other words, I want to be able to have something like Alphabet.addLetter(int id), so if I did alphabet1.add(14), it would somehow add a shared_ptr for class H to the list.

Is there an elegant way to do this, avoiding some huge if statement where that I need to constantly update every time I add or remove one of the B, C, D, E, etc. classes? I'm hoping there's some kind of template-solution, but I'm not very familiar with advanced c++ notions like factories and templates. The naive thing I wanted was some kind of vector/map that converted my ids into class names, so that I could do something like

list.push_back(shared_ptr<classVector(i)>(new classVector(i))

or something like that, though I have no idea if that's possible.

Thanks!

p.s. I just chose the Alphabet example because I didn't want to give unnecessary detail. Obviously I'm not trying to design alphabets in such a silly way, lol.

edit: I'm struggling to make this make sense. My goal is to be able to create new subclasses of Letter very quickly with minimal effort. I would like to avoid having to type out code that looks like...

list.push_back(shared_ptr<X>(...));

every time I make a new letter. Does this make sense at all?

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closed as too broad by Dave S, Michael Kohne, Adam H. Peterson, lpapp, Jonesy May 16 '14 at 2:54

There are either too many possible answers, or good answers would be too long for this format. Please add details to narrow the answer set or to isolate an issue that can be answered in a few paragraphs. If this question can be reworded to fit the rules in the help center, please edit the question.

10  
I'm really struggling to follow this. –  Lightness Races in Orbit May 15 '14 at 20:49
1  
Seriously? "I have a lot of subclasses of an abstract class A, like B, C, D, etc. A has an integer ID variable, and every subclass of A gets assigned a unique id." How about a class letter with an int constructor that assigns the "unique id"? –  awesomeyi May 15 '14 at 20:49
    
Instead of using arbitrary integer IDs, take advantage of polymorphism and dynamic binding. –  The Paramagnetic Croissant May 15 '14 at 20:49
    
I was wondering about this as well. Put another way, if you have many subclasses of an abstract class and an instance is in a generic list (for example) and you need to determine the precise subclass of the generic instance, how do you do it? Or is this a wrong-minded question? –  Jiminion May 15 '14 at 20:51
    
Are you sure you need id at all? I think shared_ptr<B> will be automatically converted to shared_ptr<A> if b is derived from a and b is passed into function that accepts a. –  Zeks May 15 '14 at 20:54

4 Answers 4

up vote 4 down vote accepted

This is relatively easy if I understood you correctly, using what's called a factory-pattern.

If you can list all of the derived types:

Letter header:

struct Letter {
    enum LetterEnum {LetterA, LetterB, LetterC, LetterCount};

    virtual ~Letter() {} //base types should always have virtual destructor
    virtual void foo() = 0;

    static std::unique_ptr<Letter> construct(LetterEnum c);
};

Implementation headers:

struct A : Letter {
  void foo() override;
};

struct B : Letter {
  void foo() override;
};

struct C : Letter {
  void foo() override;
};

Letter body:

std::unique_ptr<Letter> Letter::construct(Letter::LetterEnum c) 
{
    switch(c) {
    case Letter::LetterA : return make_unique<A>();
    case Letter::LetterB : return make_unique<B>();
    case Letter::LetterC : return make_unique<C>();
    default: throw ...;
    }
}

Usage:

int main() {
    char c;
    std::cin >> c;
    //get a letter of the derived type associated with the letter entered
    std::unique_ptr<Letter> ptr = Letter::construct(c);    
}

If you can't list all of the derived types:

Allow the derived types to register themselves with the Letter class, and then Letter can use that to create each of the derived types. This way, adding and deleting the derived types involves no changes to any other files. Easy!

struct Letter {
    virtual ~Letter() {} //destructor is always virtual when inheretence is involved
    ....
    //this is a "shared" function in the Letter class itself
    //it takes a letter, and returns a dynamically allocated instance
    //of the derived type corresponding with that letter
    static std::unique_ptr<Letter> construct(char c);
    //this typedef represents the actual function that returns 
    //each dynamically allocated derived type
    typedef std::function<std::unique_ptr<Letter>()> letter_ctor;
    //this is a "shared" function in the Letter class itself
    //it takes a letter, and a function that creates derived types, 
    //and saves them inside the container ctors
    static bool register(char c, letter_ctor func);
private:
    //this is a "shared" member in the Letter class.  
    //There is only one shared by all of the Letters.  Like a global.
    //When you give it a letter, it gives you a function.
    //and is VERY fast for large numbers of entries
    static std::unordered_set<char,letter_ctor> ctors;
};

and in your implementation file:

//here's the function that derived types register themselves with
//pretty straightforward, just inserts the pair into the unordered_map
bool Letter::register(char c, Letter::letter_ctor func)
{return Letter::ctors.insert(std::make_pair(c,std::move(func))).second;}

//and here's the function that creates the derived types
//it checks if the letter is in the unordered_map
//if the letter isn't there, it throws an exception
//otherwise, it calls the function associated with that letter
//which creates the derived type on the heap, and returns a pointer to it
std::unique_ptr<Letter> Letter::construct(char c) 
{
     auto it = Letter::ctors.find(c);
     if (it == Letter::ctors.end())
         throw ...;
     return it->second(); //construct that letter
}

and then your derived types do this:

//you know this part
struct LetterA : public Letter 
{
   ....
};
//derived types have to register themselves:
//this is a global, so when the program loads, it automatically calls this
//even before main runs*
//it registers the letter 'A' and a function that creates a LetterA class on the heap
static bool registerA = Letter::register('A', [](){return make_unique<LetterA>();});

and then you can easily create arbirary derived types!

int main() {
    char c;
    std::cin >> c;
    //get a letter of the derived type associated with the letter entered
    std::unique_ptr<Letter> ptr = Letter::construct(c);
}

*It doesn't always get called before main. If you have problems, put an bool init_A(); in the A header, and bool init_A(){return true;} in the A implementation file, and in your main file have static bool AInit=init_A(); which should force it. This is almost never needed in practice though.


As a side note, these depend on having a make_unique, which should have been in C++11, but was left out due to oversight. It will be in C++14. In the meantime, use this:

template<class T, class...Us>
std::unique_ptr<T> make_unique(Us&&...us) 
{return std::unique_ptr<T>(new T(std::forward<Us>(us)...));}
share|improve this answer
1  
It's going to take me a while to understand this because it uses a lot of keywords that I don't really understand yet, but I think this is the answer to my question. –  user3281410 May 15 '14 at 21:22
1  
@Jim: Yeah, What I mean is that you create the new class, and add the register line, and you're good to go. You don't have to find code in some other random files and edit them to know about your newly created class. In Jeff's answer you have to edit LetterCode in some header file, and Klaus's doesn't seem able to create based on a variable identifier at all. –  Mooing Duck May 15 '14 at 22:01
1  
Thank you so much Mooing Duck. This is exactly what I wanted. I wanted 1 simple line of code that I could put somewhere, exactly what your Letter::register(..) lines do. This will definitely be the most unusual looking code I've ever written when I'm done, lol. –  user3281410 May 15 '14 at 22:04
1  
@Jim: Yes, this approach works with strings and such. Using an enum would kind of defeat the point of this approach. If you're going to have an enum, there's far better approaches to use than this one. But the joy of this approach is that it doesn't require changing another file(for most compilers). If he needs an enum, then something closer to the other two answers would be best I think. The vector using enums as indexes still lets you pick types based on runtime values. –  Mooing Duck May 15 '14 at 22:07
1  
@Jim For what I'm doing, I'm going to just declare integer constants for each of the particular letters instead of characters. Each of my alphabet objects can only have 1 letter of a particular type, so I can use the integers to search and pull the pointers out of the list and then cast the pointer to the particular class I wanted using its integer id. Something like static_cast<X>(alphabet1.getLetter(CLASS_X_ID)). –  user3281410 May 15 '14 at 22:13

This is pretty hard to follow, but I think what you want is something along the lines of the following:

// where make_unique<> is from C++14 in std:: or like:
template <typename T, typename ... TArgs>
std::unique_ptr<T> make_unique(TArgs &&... args) {
  return std::unique_ptr<T>(new T(std::forward<TArgs>(args)...));
}

struct Letter {
  virtual ~Letter() { }
  virtual void foo() = 0;
};
template <unsigned int N> struct LetterCode; // Note: no default implementation!

struct Alphabet {
  // Indexed access, if you'll have 1 of each type max:
  std::vector<std::unique_ptr<Letter>> v;

  // If you don't need parameters, as mentioned in comments below ...
  template <unsigned int N>
  void addLetterN() {
    if (N > v.size() + 1) { v.resize(N + 1); }
    v[N] = make_unique<LetterCode<N>::type>(); // see below ...
  }

  // If your coding is complete from 0...N, this does the whole shebang.
  template <unsigned int N>
  void addLettersN() {
    addLetters<N - 1>();
    addLetterN<N>();
  }
  template <>
  addLettersN<0>() {
    addLetterN<0>();
  }
};

If you need numeric codes for something like deserialization and never need constructor arguments, you can use a type trait template like follows to statically 'register' the types:

struct B : Letter {
  B(int n, bool b, char const *name);
  void foo() override;
};
template <> struct LetterCode<2> { using type = B; };

struct C : Letter {
  C(double d);
  void foo() override;
};
template <> struct LetterCode<3> { using type = C; };

void bar() {
  Alphabet a;
  a.addLetterN<2>();
  a.addLetterN<3>();

  // --OR--
  a.addLettersN<3>(); // will do 0...3 in one fell swoop.

  for (auto &i : a.v) {
    if (!i) { continue; } // v is sparse, unlike l
    i->foo();
}

If you need generalized constructor argument passing, you can use perfect forwarding, which is designed for cases like this and obviates the need for enum IDs, etc., from older styles of factories:

struct Alphabet {
  std::list<std::unique_ptr<Letter>> l;

  // variadic factory that chucks new (shared_ptr) objects in the list.
  template <typename T, typename ... TArgs>
  void addLetter(TArgs && ... args) {
    l.push_back(make_unique<T>(std::forward<TArgs>(args)...));
  }
};

void baz() {
  Alphabet a;
  a.addLetter<B>(1, false, "pony");
  a.addLetter<C>(2.718281828);

  for (auto &i : a.l) {
    i->foo(); // can call virtual funcs here all you want ...
  }
}
share|improve this answer
    
Thank you Jeff. In my particular context all of the subclasses are just there to implement an abstract function that computes a float. I don't have to pass anything to them in their constructor. My goal is to be able to create a new subclass without having to hunt down a bunch of places in my code where I need to make changes. In your example, I would ideally not want to type the "B" in foo(). I want to just type addLetter(1). Does that make any sense at all? –  user3281410 May 15 '14 at 21:15
    
Why "1"? Are you keying off hardcoded literal integers, or getting a stream of dynamic integer values from somewhere else that you need to turn into new object instances? –  Jeff May 15 '14 at 21:19
    
They would be hardcoded literals. Every alphabet would have at most one letter of a given class (should have said that earlier). I would be able to use the integer as the "name" for the letter, since any alphabet would have only 1 letter with a particular id. I guess I want all of the letters to be pushed into the list in the same way, without having to write any extra code programmed new subclasses or removed subclass types from my code. But when they are in the list, they will implement abstract functions differently giving me different output based on what letter they are. –  user3281410 May 15 '14 at 21:27
    
It sounds like you might want to use a directly indexed structure for your shared_ptrs rather than a std::list<> then? –  Jeff May 15 '14 at 21:29
1  
@Jim: There are a great many compilers out there that handle the day-to-day C++11 stuff. –  Mooing Duck May 15 '14 at 22:30

My understanding is that you want to create a instance of one of the classes, dependend on an id which relates to the class from which an instance should be created.

If so, please have a look for factory pattern. There are a lot of factory implementations, also based on template recursive expansion of a typelist.

Pseudo Code:

Factory<A,B,C,D> fac; // the list must be changed, if some more classes comes and goes
id_type id;

list<base> l;

l.push_back=fac.Create(id);

It is also quite simple to implement such a class yourself.

share|improve this answer
    
For others that can't decipher my apparently opaque question, yes this is what I want to do. I am going to go read about factory patterns, since I don't immediately see how your code does anything. Maybe that's the right thing to google to figure it out though, thanks! –  user3281410 May 15 '14 at 21:06
    
I am not sure you need an ID instead of just template member function in this factory –  Zeks May 15 '14 at 21:10
    
As I understand, it is part of the question that OP has an idea to create the related class. The factory should replace a switch/case/if tree. I understand that OP wants to 'Create a new instance of class which has the given ID'. So ID is needed :-) –  Klaus May 15 '14 at 21:14

The goal is simple: create the function factories that returns an array of Alphabet makers.

The index of the letter and the index into the array will be the same.

Ideally, we want to auto-generate said index without having to manually set it.

#include <memory>
#include <vector>
#include <iostream>

template<class T>using Type=T;

template<class...Ts>struct types:std::integral_constant<unsigned,sizeof...(Ts)>
{typedef types type;};
template<class T,class types>struct index_of;
template<class T,class T0, class...Ts>struct index_of<T,types<T0,Ts...>>:
  std::integral_constant<unsigned,index_of<T,types<Ts...>>::value+1>
{};
template<class T,class...Ts>struct index_of<T,types<T,Ts...>>:
  std::integral_constant<unsigned,0>
{};
template<unsigned,class types>struct type_at;
template<unsigned N, class T,class...Ts>struct type_at<N,types<T,Ts...>>:
  type_at<N-1,types<Ts...>> {};
template<class T,class...Ts>struct type_at<0,types<T,Ts...>>{
  typedef T type;
};
template<unsigned N,class types>
using type_at_t=typename type_at<N,types>::type;

template<template<class>class Target,unsigned N,class types>
struct nth_apply;
template<template<class>class Target,unsigned N,class...Ts>
struct nth_apply<Target,N,types<Ts...>>{
  typedef Target<type_at_t<N,types<Ts...>>> type;
};
template<template<class>class Target,unsigned N,class types>
using nth_apply_t=typename nth_apply<Target,N,types>::type;

This is the type that produces the function pointers for us:

template<class T>struct shared_maker{
  template<class...Args>
  std::shared_ptr<T> operator()(Args&&...args)const{
    return std::make_shared<T>(std::forward<Args>(args)...);
  }
  template<class R, class... Args>
  operator Type<R(Args...)>*() const{
    return [](Args... args)->R{
      return shared_maker{}(std::forward<Args>(args)...);
    };
  }
};

Here is what we do for the actual letter types. We forward declare them:

struct A; struct B; // etc

Stick them into a list of types:

typedef types<A,B> Alphabet_Types;

Now, our simple test Alphabet type:

struct Alphabet {
  virtual unsigned get_index() const = 0;
};

And a CRTP helper that gets the index of the letter from its offset into the list of types! The virtual get_indexes is just for debugging:

template<class D>
struct Letter:Alphabet{
  static const unsigned index = index_of<D, Alphabet_Types>::value;
  virtual unsigned get_index() const override { return index; }
};

Now the signature of our array-producer:

typedef std::shared_ptr<Alphabet> spAlphabet;
std::array<spAlphabet(*)(), Alphabet_Types::value> factories();

Here is how we define our (toy) letter classes:

struct A:Letter<A>{};
struct B:Letter<B>{};

ie, use Letter<> as a CRTP base instead of Alphabet.

The only thing left is to write the function factories.

Index boilerplate. C++1y has a replacement:

template<unsigned...>struct indexes{typedef indexes type;};
template<unsigned Max, unsigned... Is> struct make_indexes:make_indexes<Max-1,Max-1,Is...>{};
template<unsigned...Is>struct make_indexes<0,Is...>:indexes<Is...>{};

The actual implementation via a helper function. We get a pack of indexes and expand it, building our std::array of function pointers from our shared_maker above instantiated with an indexed type from the Alphabet_Types we wrote above:

template<unsigned...Is>
std::array<spAlphabet(*)(), Alphabet_Types::value> factories(indexes<Is...>){
  return {nth_apply_t<shared_maker,Is,Alphabet_Types>{}...};
}

The actual factories function just forwards to the above helper:

std::array<spAlphabet(*)(), Alphabet_Types::value> factories(){
  return factories(make_indexes<Alphabet_Types::value>{});
}

And some trivial test code:

int main() {
  std::vector<spAlphabet> vec;
  auto builders = factories();
  for (int i = 0; i < 2; ++i) {
    vec.push_back(builders[i]());
  }
  for( auto&& ptr:vec ) {
    std::cout << ptr->get_index() << "\n";
  }
}
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