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I'm a vegetarian, so suppose we have vegetables:

class Vegetable {}; // base class for vegetables

class Tomato : public Vegetable {};
class Potato : public Vegetable {};
class Carrot : public Vegetable {};
class Broccoli : public Vegetable {};

And suppose we wanna make meals with them:

class Meal {}; // base class for meals

class Soup : public Meal {
    Soup(Vegetable *veg1, Vegetable *veg2) : veg1(veg1), veg2(veg2) {};

class Salad : public Meal {
    Salad(Vegetable *veg1, Vegetable *veg2, Vegetable *veg3) : veg1(veg1), veg2(veg2), veg3(veg3) {};

class VeggieBurger : public Meal {
    VeggieBurger(Vegetable *veg) : veg(veg) {};

Now we'd like to define different meals with different vegetable combinations in a cookbook:

std::vector<Meal *> cookbook;

cookbook.push_back(new Soup(new Tomato, new Potato));
cookbook.push_back(new Soup(new Potato, new Broccoli));
cookbook.push_back(new Salad(new Tomato, new Carrot, new Broccoli));
cookbook.push_back(new Salad(new Tomato, new Potato, new Tomato));
cookbook.push_back(new Salad(new Broccoli, new Potato, new Carrot));
cookbook.push_back(new VeggieBurger(new Potato));
// many more meals...

So we are creating many little objects on the heap that are getting composed together via constructor arguments and pushed onto a std::vector at runtime. Obviously the downside of this design is, that we have to manage the memory ourselves and delete the Vegetable objects in our meals destructor and delete our cookbook meals somewhere when it goes out of scope.

So a possible design choice would be to use smart pointers to out source the burden of doing memory management for our meals and vegetables.

But I'm wondering if it is possible to compose the cookbook at compile time, maybe with some kind of template magic? The cookbook does not necessarily have to be a std::vector but we still like to be able to iterate over it, get the Meal objects and call member functions on a composed meal. Are there better ways to do it?

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Noting of course that tomato is a fruit. :-P Also, take a look at Boost.Fusion's boost::fusion::vector<>. – ildjarn Jan 5 '12 at 0:26
You may have already headed down a bad design path. Is your example accurate in that you want to define many classes, all empty? And that you want to allocate many instances of the same empty class, e.g. Tomato? – Drew Dormann Jan 5 '12 at 0:29
In the real world implementation a Vegetable has state and member functions. – Christian Zeller Jan 5 '12 at 0:43
What exactly is the problem with the current implementation? How many meals are put in the cookbook? Is your program slow at the beginning as it does all the calls to cookbook.push_back ? Do you want to speed this up? ("I'm wondering if it is possible to compose the cookbook at compile time") – Aaron McDaid Jan 5 '12 at 1:08
To me 'Carrot' is a name property of vegetable not a unique type in itself - will Carrot really have methods different from Vegetable? – Adrian Cornish Jan 5 '12 at 1:35

4 Answers 4

up vote 1 down vote accepted

I've found that code generation is becoming an incredibly useful tool for me. Maybe write a short program, perhaps even just a script, than will generate the boilerplate code for you.

Any time you add to your cookbook, you run the program/script, which will generate the headers for each meal and the header, maybe even some of the source, for the cookbook itself.

How in-depth you get with your generation is up to you. You could just edit the code generator's source to add new meals, you could do some simple text based parsing, or, if it's really worth the time and effort to maintain, turn your code generator into an editor (with code generation as its output).

At least one very well know AAA game engine actually generates C++ header files for any scripts that are marked to interface with native code. From there, a macro in a source file implements the boilerplate methods. The rest of the methods are implemented by the developers.

Update: C++11 actually has support for variadic template arguments. I don't have any experience with C++11, so I'm not sure if variadic template arguments would support what we're looking at.

share|improve this answer
+1 "Write Code That Writes Code" – Jan 5 '12 at 1:05

Well, with C++11 you can do:

std::vector<Meal *> cookbook = {
    new Soup(new Tomato(), new Potato()),
    new Soup(new Potato(), new Broccoli()),
    new Salad(new Tomato(), new Potato(), new Tomato()),
    // etc

Of course, this still ends up running operator new and the constructors at runtime rather than compile time, but is at least a bit more compact.


Unfortunately C++11 does not provide a way to create an unnamed object of static storage duration and take its address for use in such a construct. You need to give such objects a name, something like:

static Tomato tomatoes[] = {
    { /* first tomato initializer */ },
    { /* second */ },
    /* more */
static Potato potatoes[] = { ...
static Soup soups[] = { 
    { &tomatoes[0], &potatoes[0] },
static Salad salads[] = {
    { &tomatoes[4], &potatoes[2], &tomatoes[5] },
std::vector<Meal *> cookbook = {
    &soups[0], &soups[1], &soups[2], ...
    &salads[0], &salads[1], ...

This is extremly error prone, but is a good choice for what kind of C++ code to generate if you follow Sion Sheevok's answer.

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Perhaps constexpr might help to do all of this at runtime? Instead of new Tomato, write a function constexpr Tomato newTomato which creates a Tomato by value. Bear with me while I do some experiments. – Aaron McDaid Jan 5 '12 at 1:13
@AaronMcDaid: Can't store varying types in a container except by pointer (except via boost::variadic), so you won't get very far. – Mooing Duck Jan 5 '12 at 1:29
@MooingDuck, I see now. I did a few sizeof experiments and I realized the array elements were clobbering each other. Never mind. I should delete my answer :-( – Aaron McDaid Jan 5 '12 at 1:38

Well, if it's all known at compile time, then here's a bad idea:

template <class... Types>
struct cookbook {
    std::tuple<Types...> data;

    template<int i, bool safe>
    struct safe {
        static const Meal* get(const std::tuple<Types...>& data) 
        {return std::get<i, Types...>(data);}
    template<int i, false>
    struct safe {
        static const Meal* get(const std::tuple<Types...>& data) 
        {return NULL;}

    class iterator {
        friend cookbook;
        cookbook* parent;
        int index;
        iterator(cookbook* p, int i) : parent(p), index(i) {}
        iterator& operator++() {++index; return *this;}
        iterator& operator+=(int i) {index += i; return *this;}
        const Meal& operator*() const {
             switch (i) {
             case 0: return p->safe<0, Types...>::get(data);
             case 1: return p->safe<1, Types...>::get(data);
             case 2: return p->safe<2, Types...>::get(data);
             case 3: return p->safe<3, Types...>::get(data);
             case 3: return p->safe<4, Types...>::get(data);
             case 3: return p->safe<5, Types...>::get(data);
        bool operator==(const iterator& r) {
            return parent==r.parent && index==r.index;
        bool operator!=(const iterator& r) {
            return index!=r.index || parent!=r.parent;
    iterator begin() {return iterator(this, 0);}
    iterator end() {return iterator(this, tuple_size<Types...>::value+1);}

This actually creates a cookbook object with (effectively) a member for each Meal type, and a hard-coded iterator to grab each one.

I doubt this will actually compile since I've never tried such a thing and have no compiler with variadic templates. Also, I only implemented a small part of it. You could do another layer of this with

 template<class RecipieType, class....Types>
 struct Recipie : RecipieType {
      //same as above

which would get you

 #define soup1types Tomoato,Potato
 #define soup2types Potato,Broccoli
 #define salad1types Tomato,Carrot,Broccoli
 #define cooktypes Recipie<Soup,soup1types>\
 cookbook<cooktypes> book; //bam. recipies exist.

Also, people may hate you (and me) when they see this.

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Im told boost::fusion does this but better and safer. As always, boost has what you need. – Mooing Duck Jan 5 '12 at 1:54

Even with templates you'd need some sort of type erasure to put the resulting instantiation somewhere. You could have a Meal base class which takes its ingredients via template arguments. For example:

template <typename... T>
class Salad: public Meal {

std::vector<std::unique_ptr<Meal>> cookbook;
cookbook.push_back(std::unique_ptr<Meal>(new Salad<Tomato>()));
cookbook.push_back(std::unique_ptr<Meal>(new Salad<Tomato, Carrot>()));
cookbook.push_back(std::unique_ptr<Meal>(new Salad<Tomato, Tomato, Carrot>()));

Of course, to be useful in some shape or form you'd still need to provide some accessors to retrieve the various ingredients. To do this, you'd need to restore the original Salad instantiation - except that it is lost. You might create a virtual function in Meal which is implemented in Salad and assembles the various incredients.

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If you actually want to store arguments of type Tomato etc. you would need a std::tuple. – pmr Jan 5 '12 at 0:43
Why so cumbersome? You can say cookbook.emplace_back(new Salad<Tomato>()); etc. – Kerrek SB Jan 5 '12 at 0:54

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