Suppose I want to use `std::conditional`

to determine a type, if the type is a `vector<...>`

the return will be a `vector<...>::size_type`

and if not it will be `int`

. (just an example).

A naive way to use `std::conditional`

:

```
template<class V> struct is_vector : std::false_type{};
template<class T> struct is_vector<std::vector<T>> : std::true_type{};
template<class C>
using my_size_type = typename std::conditional<
not is_vector<C>::value,
int,
C::size_type // note that this line only makes sense when condition is false
>::type;
```

However this fails because if `C`

is say a `double`

, `double::size_type`

will give an error, even if the that is the evaluation of the second false option.

So, I am wonder if there is a sort of `lazy_conditional`

in which the false (or the second false) statement is not evaluated.

I found something here: https://stackoverflow.com/a/5317659/225186 but I don't know how to use it my example.

Note that I know how to get the same result without using `std::conditional`

:

```
template<class V> struct my_size_type{typedef int type;};
template<class T> struct my_size_type<std::vector<T>>{typedef std::vector<T>::size_type type;};
```

The question is if there is a `lazy_conditional`

that somehow encapsulated a `std::conditional`

that is short circuited.

After some trial error I manage to use the ideas in https://stackoverflow.com/a/5317659/225186 and get to this that follows. It also makes me think that it is not possible to write `std::lazy_conditional`

because `C::size_type`

cannot appear at all in any expression a priori, so two-step expressions are needed.

```
template<class C, bool B> struct false_case{
typedef void type;
};
template<class C> struct false_case<C, false>{
typedef typename C::size_type type;
};
template<class C>
using size_type = typename std::conditional<
not is_vector<C>::value,
int,
typename false_case<C, not is_vector<C>::value>::type
>::type;
```

I couldn't even condense this into a macro, because each case is different.