First, variadic templates don't include a way to say 'a variable number of arguments of a single type'. When you use variadic templates you get a parameter pack which is a set of zero or more arguments, each with a possibly unique type:

```
template<typename... Ts> void foo(Ts... ts);
```

the `...`

token only has defined meanings for these parameter packs (and vararg functions, but that's beside the point). So you can't use it with non-parameter packs:

```
template<typename T> void foo(T... t); // error
template<typename T> void foo(T t...); // error
```

Second, once you have a parameter pack, you can't just iterate over the parameters the way you're showing with the range-based for-loop. Instead you have to write your algorithms in a functional style, using parameter pack expansion to 'peel off' parameters from the parameter pack.

```
// single argument base case
template<typename T>
void foo(T t) {
std::cout << t;
}
template<typename T,typename... Us>
void foo(T t,Us... us) {
foo(t) // handle first argument using single argument base case, foo(T t)
foo(us...); // 'recurse' with one less argument, until the parameter pack
// only has one argument, then overload resolution will select foo(T t)
}
```

Although variadic templates don't directly support what you want, you can use `enable_if`

and use the 'SFINAE' rule to impose this constraint. First here's a version that without the constraint:

```
#include <type_traits>
#include <utility>
template<class T>
T min(T t) {
return t;
}
template<class T,class... Us>
typename std::common_type<T,Us...>::type
min(T t,Us... us)
{
auto lowest = min(us...);
return t<lowest ? t : lowest;
}
int main() {
min(1,2,3);
}
```

And then apply `enable_if`

to ensure that the types are all the same.

```
template<class T,class... Us>
typename std::enable_if<
std::is_same<T,typename std::common_type<Us...>::type>::value,
T>::type
min(T t,Us... us)
{
auto lowest = min(us...);
return t<lowest ? t : lowest;
}
```

The modified implementation above will prevent the function from being used any time the arguments aren't all exactly the same according to `is_same`

.

You're probably better of not using these tricks if you don't have to. Using an initializer_list as KennyTM's suggests is probably a better idea. In fact if you're really implementing min and max then you can save yourself the trouble because the standard library already includes overloads that take an initializer_list.

### How does `is_same<T,typename common_type<Us...>::type>`

work?

Because there's a single argument version of `min()`

the variadic version is selected only when there are two or more parameters. This means that `sizeof...(Us)`

is at least one. In the case where it is exactly one, `common_type<Us...>`

returns that type single type, and `is_same<T,common_type<Us...>>`

ensures that the two types are the same.

The variadic implementation of `min()`

calls `min(us...)`

. So long as this call only works when all the types in `Us...`

are the same we know that `commont_type<Us...>`

tells up what that type is, and `is_same<T,common_type<Us...>>`

ensures that T is also that same type.

So we know that `min(a,b)`

only works if `a`

and `b`

are the same type. And we know that `min(c,a,b)`

calls `min(a,b)`

so `min(c,a,b)`

can only be called if `a`

and `b`

are the same type and additionally if `c`

is also the same type. `min(d,c,a,b)`

calls `min(c,a,b)`

so we know that `min(d,c,a,b)`

can only be called if `c`

, `a`

, and `b`

are all the same type, and additionally if `d`

is also the same type. Etc.

`...`

s are just a pseudocode way of saying "more stuff here").