Computing a function over variadic templates

I am trying to figure out which is the most idiomatic way implement a function over a variadic type list. For example, computing the maximum size of all the types. I understand there exist several approaches to accomplish such a task, but I would like to know when to choose which strategy.

These are the mechanisms I would consider (there may exist more, please mention if so):

• Type traits (ideally succinctly with using declarations):

``````template <typename Head>
using max_size = typename std::integral_constant<size_t, sizeof(Head)>::type;

using max_size = ?;
``````
• `constexpr` functions:

``````template <typename Head>
constexpr size_t max_size() { return sizeof(Head); }

constexpr size_t max_size() { ? }
``````

My question is twofold:

1. What features of the computation determine what strategy to choose?

2. In each case, how would an example implementation for the maximum size example described above look like?

-

I personally prefer functions rather than traits, I find them easier to manipulate and more natural. But that's certainly subjective ;)

``````#include <iostream>

constexpr size_t max_size() { return sizeof(Head); }

template <typename Head, typename Next, typename... Tail>
constexpr size_t max_size() {
return max_size<Head>() > max_size<Next, Tail...>() ?
}

int main() {
std::cout << "int: " << max_size<int>() << "\n";
std::cout << "char, short, int: " << max_size<char, short, int>() << "\n";
std::cout << "char, double, int: " << max_size<char, double, int>() << "\n";
}
``````

In action at liveworkspace:

``````int: 4
char, short, int: 4
char, double, int: 8
``````
-
This is the shortest and clearest solution of the available answers. Another plus point is that it does not rely on Boost. –  Matthias Vallentin Nov 7 '12 at 2:58
@MatthiasVallentin: Yes, I tend to turn to `constexpr` because they are so more readable than meta-programming tricks. Less boilerplate, and more habit at reading functions. –  Matthieu M. Nov 7 '12 at 7:44

I would stay away from strictly using `constexpr` as they are harder to compose. For instance, I'm not even sure high-order metafunctions are possible with `constexpr`, if so they use function pointers as template parameters which is ugly.

``````struct max_size {
template<typename... Ts>
struct apply : parampack_foldl::apply<boost::mpl::quote2<boost::mpl::max>, typename boost::mpl::sizeof_<Ts>::type...>;
};
``````

Then create an alias to lessen typing:

``````template<typename... Ts>
using MaxSize = typename max_size::apply<Ts>::type;
``````

Or, create a constexpr function:

``````template <typename... Ts>
constexpr size_t max_size() { return max_size::apply<Ts...>::type::value; }
``````

The second step is really just a matter of style, what really matters is that you have the first which gives you the most to work with.

-
I like the idea of high-order metafunctions. It would allow to write a single `max` function and pass in another metafunction to compute the size. It actually seems to work fine together with constexpr functions: liveworkspace.org/code/5809994d109ad35a1b68d2beb81b3ddd (The link points to Matthieu's example, slightly modified.) –  Matthias Vallentin Nov 6 '12 at 17:41

For completeness, there is also the technique of inheritance:

``````#include <cstddef>
using std::size_t;

template<size_t ...S> struct max_size_t;

template<size_t S1, size_t S2, size_t ...Rest>
struct max_size_t<S1, S2, Rest...>
: max_size_t<(S2 < S1) ? S1 : S2, Rest...> {
};

template<size_t S>
struct max_size_t<S> {
static const int value = S;
};

template<> struct max_size_t<> {
static const int value = 0;
};

template<typename ...T> struct max_size : max_size_t<sizeof(T)...> {};

// Using the same test-harness as Matthieu M:
#include <iostream>

int main() {
std::cout << "int: " << max_size<int>::value << "\n";
std::cout << "char, short, int: " << max_size<char, short, int>::value << "\n";
std::cout << "char, double, int: " << max_size<char, double, int>::value << "\n";
return 0;
}
``````

Also at liveworkspace.

Although this is not a way I'd choose to implement `max_size`, it's very handy when the desired function is one which returns a type (highly contrived example follows):

``````template<typename T1, typename T2, bool B=(sizeof(T1)>sizeof(T2))> struct selector;
template<typename T1, typename T2> struct selector<T1, T2, true> { using type = T1; };
template<typename T1, typename T2> struct selector<T1, T2, false> { using type = T2; };

template<typename T1, typename ...Rest> struct largest_type;

template<typename T1, typename T2, typename ...Rest>
struct largest_type<T1, T2, Rest...>
: largest_type<typename selector<T1, T2>::type, Rest...> {};

template<typename T1> struct largest_type<T1> { using type = T1; };

#include <iostream>
int main() {
static const unsigned long long u = 1ULL << 63;
std::cout << "int: " << typename largest_type<int>::type(u) << "\n";
std::cout << "int, double: " << typename largest_type<int, double>::type(u) << "\n";
std::cout << "short, float, long long: " << typename largest_type<short, float, long long>::type(u) << "\n";
return 0;
}
``````

See it here.

-
+1 for an elaborate answer using a different technique –  Matthias Vallentin Nov 7 '12 at 3:55