# How can I create a factory function template that constructs object given an arbitrary number of arguments?

This is easier to explain with some code so I'll give an example first:

#include <iostream>
#include <vector>

class Base {
public:
int integer;

Base() : integer(0) {}
Base(int i) : integer(i) {}
};

class Double: public Base {
public:
Double(int i) { integer = i * 2; }
};

class Triple: public Base {
public:
Triple(int i) { integer = i * 3; }
};

template<typename T>
Base* createBaseObject(int i) {
return new T(i);
};

int main() {
std::vector<Base*> objects;

objects.push_back(createBaseObject<Double>(2));
objects.push_back(createBaseObject<Triple>(2));

for(int i = 0; i < objects.size(); ++i) {
std::cout << objects[i]->integer << std::endl;
}

std::cin.get();
return 0;
}


I am trying to make a function that will return a Base pointer to an object that is derived from Base. In the above code the function createBaseObject allows me to do that but it restricts me in that it can only create dervied classes that take a single argument into their constructor.

For example if I wanted to make a derived class Multiply:

class Multiply: public Base {
public:
Multiply(int i, int amount) { integer = i * amount; }
};


createBaseObject wouldn't be able to create a Multiply object as it's constructor takes two arguments.

I want to ultimately do something like this:

struct BaseCreator {
typedef Base* (*funcPtr)(int);
BaseCreator(std::string name, funcPtr f) : identifier(name), func(f) {}

std::string identifier;
funcPtr func;
};


then, for example, when I get input matching identifier I can create a new object of whatever derived class associates with that identifier with whatever arguments were input too and push it to the container.

After reading some of the replies I think something like this would suit my needs to be able to procedurally create an instance of an object? I'm not too wise with templates though so I do not know whether this is legal.

struct CreatorBase {
std::string identifier;
CreatorBase(std::string name) : identifier(name) {}

template<typename... Args>
virtual Base* createObject(Args... as) = 0;
};

template<typename T>
struct Creator: public CreatorBase {
typedef T type;

template<typename... Args>
Base* createObject(Args... as) {
return new type(as...);
}
};


Okay here's another semi-solution I've managed to come up with so far:

#include <boost\lambda\bind.hpp>
#include <boost\lambda\construct.hpp>
#include <boost\function.hpp>

using namespace boost::lambda;
boost::function<Base(int)> dbl = bind(constructor<Double>(), _1);
boost::function<Base(int, int)> mult = bind(constructor<Multiply>(), _1, _2);


Just this has the same limits as the original in that I can't have a single pointer that will point to both dbl and mult.

-
Why does the factory suddenly need to be polymorphic too? –  Lightness Races in Orbit Jan 5 '12 at 21:35
Sorry, I'm not very good at explaining. I need to create something that can create an instance of any derived class of Base except I can't directly use the constructor. So that I can link the creation method with the identifier so whenever the identifier is input I can create an instance of the object. –  Lerp Jan 5 '12 at 22:45

C++11 variadic templates can do this for you.

You already have your new derived class:

class Multiply: public Base {
public:
Multiply(int i, int amount) { integer = i * amount; }
};


Then change your factory:

template<typename T, typename... Args>
Base* createBaseObject(Args... as) {
return new T(as...);
};


And, finally, allow the arguments to be deduced:

objects.push_back(createBaseObject<Multiply>(3,4));


### Live demo.

As others have said, though, it does all seem a little pointless. Presumably your true use case is less contrived.

-
That means I can't have a single function pointer. I've added some code in my OP at the bottom. I think it'd be a work around but I don't know whether or not it's legal. –  Lerp Jan 5 '12 at 21:33
@Rarge: Wha? Where do function pointers come into it? And BTW you're the OP. :) –  Lightness Races in Orbit Jan 5 '12 at 21:34
I meant original post, sorry. The last part of my unedited post, just before the horizontal rule, was describing my actual use for this which mentioned function pointers. –  Lerp Jan 5 '12 at 21:38
@Rarge: You already couldn't do that. Your createBaseObject is a function template. –  Lightness Races in Orbit Jan 5 '12 at 21:47
It compiled for me, having a function pointer to createBaseObject –  Lerp Jan 5 '12 at 22:06
show 3 more comments

Why not provide multiple overloads with templated parameters?

template<typename TBase, TArg>
Base* createBaseObject(TArg p1) {
return new TBase(p1);
};

template<typename TBase, TArg1, TArg2>
Base* createBaseObject(TArg p1, TArg2 p2) {
return new TBase(p1, p2);
};

-
Because it's a waste of code? –  Lightness Races in Orbit Jan 5 '12 at 20:47
@LightnessRacesinOrbit how so? Assuming the OP does have a valid usage for this pattern then it gets the job done. Variadic templates would be nice but most people I encounter don't have access to them in their production environment yet. –  JaredPar Jan 5 '12 at 20:52
Well, if he doesn't have support for variadic templates then that's fine. –  Lightness Races in Orbit Jan 5 '12 at 21:02

template <typename R, typename ...Args>
Base * createInstance(Args &&... args)
{
return new R(std::forward<Args>(args)...);
}


Usage: objects.push_back(createInstance<Gizmo>(1, true, 'a'));

It's a bit hard to see why you would want this, though, as you might as well just say:

objects.push_back(new Gizmo(1, true, 'a'));


Even better would be to declare the vector to carry std::unique_ptr<Base> elements.

-
It's where rvalue refs and std::forward start to come into otherwise "simple" code like this that I begin to lose interest in C++11. :( –  Lightness Races in Orbit Jan 5 '12 at 21:03