There are many ways to trigger SFINAE, being `enable_if`

just one of them.
First of all:

## Wats is std::enable_if ?

It's just this:

```
template<bool, class T=void> enable_if{ typedef T type; };
template<class T> enable_if<false,T> {};
template<bool b, class T=void> using enable_if_t = typename enable_f<b,T>::type;
```

The idea is to make `typename enable_if<false>::type`

to be an error, hence make any template declaration containing it skipped.

So how can this trigger function selection?

## Disabling functions

The idea is making the declaration erroneous in some part:

### By return type

```
template<class Type>
std::enable_if_t<cond<Type>::value,Return_type> function(Type);
```

### By a actual parameter

```
template<class Type>
return_type function(Type param, std::enable_if_t<cond<Type>::value,int> =0)
```

### By a template parameter

```
template<class Type,
std::enable_if_t<cond<Type>::value,int> =0> //note the space between > and =
return_type function(Type param)
```

## Selecting functions

You can parametrise different alternatives with tricks like this:

```
tempplate<int N> struct ord: ord<N-1>{};
struct ord<0> {};
template<class T, std::enable_if<condition3, int> =0>
retval func(ord<3>, T param) { ... }
template<class T, std::enable_if<condition2, int> =0>
retval func(ord<2>, T param) { ... }
template<class T, std::enable_if<condition1, int> =0>
retval func(ord<1>, T param) { ... }
template<class T> // default one
retval func(ord<0>, T param) { ... }
// THIS WILL BE THE FUCNTION YOU'LL CALL
template<class T>
retval func(T param) { return func(ord<9>{},param); } //any "more than 3 value"
```

This will call the *first/second/third/fourth* function if `condition3`

is satisfied, than `condition2`

than `condition1`

than none of them.

## Other SFINAE triggers

Writing compile-time conditions can be either a matter of explicit specialization or a matter of unevaluated expression success/failure:

for example:

```
template<class T, class = void>
struct is_vector: std::false_type {};
template<class X>
struct is_vector<vector<X> >:: std::true_type {};
```

so that `is_vector<int>::value`

is `false`

but `is_vecttor<vector<int> >::value`

is `true`

Or, by means of *introspection*, like

```
template<class T>
struct is_container<class T, class = void>: std::false_type {};
template<class T>
struct is_container<T, decltype(
std::begin(std::declval<T>()),
std::end(std::declval<T>()),
std::size(std::declval<T>()),
void(0))>: std::true_type {};
```

so that `is_container<X>::value`

will be `true`

if given `X x`

, you can compile `std::begin(x)`

etc.

The trick is that the `decltype(...)`

is actually `void`

(the `,`

operator discards the previous expressions) only if all the sub-expressions are compilable.

There can be even many other alternatives. Hope between all this you can find something useful.

`A<6> a6{a4};`

is (meant to be) a call to the copy-like constructor for which I wanted to use SFINAE. So the argument must be a type, not the result of`A<4>::operator()`

as would be for your`A<6> a6(a4())`

.