In template meta programming, one can use SFINAE on the return type to choose a certain template member function, i.e.

template<int N> struct A {
  int sum() const noexcept
  { return _sum<N-1>(); }
  int _data[N];
  template<int I> typename std::enable_if< I,int>::type _sum() const noexcept
  { return _sum<I-1>() + _data[I]; }
  template<int I> typename std::enable_if<!I,int>::type _sum() const noexcept
  { return _data[I]; }

However, this doesn't work on constructors. Suppose, I want to declare the constructor

template<int N> struct A {
   /* ... */
   template<int otherN>
   explicit(A<otherN> const&); // only sensible if otherN >= N

but disallow it for otherN < N.

So, can SFINAE be used here? I'm only interested in solutions which allow automatic template-parameter deduction, so that

A<4> a4{};
A<5> a5{};
A<6> a6{a4};  // doesn't compile
A<3> a3{a5};  // compiles and automatically finds the correct constructor

Note: this is a very simplified example where SFINAE may be overkill and static_assert may suffice. However, I want to know whether I can use SFINAE instead.

  • 8
    We really ought to get a core language feature to replace this SFINAE abuse, me thinks wishfully...
    – sellibitze
    Jan 30 '13 at 12:11
  • please correct the code that it does what you intend it to do Jan 30 '13 at 21:49
  • @JohannesSchaub-litb I don't get your edit/comment. 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()).
    – Walter
    Feb 5 '13 at 17:55
  • @Walter the issue was that a4 and a5 were functions. Now it's fixed. Feb 5 '13 at 18:24

You can add a defaulted type argument to the template:

template <int otherN, typename = typename std::enable_if<otherN >= N>::type>
explicit A(A<otherN> const &);
  • 2
    Note that this won't work as is if you have two such constructors with different conditions. (And if you don't have overloads, you probably should be using static_assert, but was already dealt with in the question) Jan 30 '13 at 12:00
  • 1
    @KerrekSB: Because the first typename clarifies that enable_if::type must be a typename, I think.
    – thiton
    Jan 30 '13 at 12:02
  • 1
    @KerrekSB: It is optional? Really? Well, from the context it should be clear that a typename has to follow, but I did not know that C++ actually allows the removal of the 2nd typename here. Are you sure? Perhaps you've tried this with a more forgiving compiler that doesn't actually do a proper two-phase lookup?
    – sellibitze
    Jan 30 '13 at 12:09
  • 1
    @R.MartinhoFernandes: static assertion is different, though. The point of enable_if is to get the correct behaviour for std::is_constructible<A<N>, A<M>>::value.
    – Kerrek SB
    Jan 30 '13 at 12:34
  • 1
    @Walter : That was true for C++03, but C++11 allows them for function templates as well.
    – ildjarn
    Feb 4 '13 at 17:53

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) { ... }

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(
  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.


In C++11, you can use a defaulted template parameter:

template <int otherN, class = typename std::enable_if<otherN >= N>::type>
explicit A(A<otherN> const &);

However, if your compiler doesn't support defaulted template parameters yet, or you need multiple overloads, then you can use a defaulted function parameter like this:

template <int otherN>
explicit A(A<otherN> const &, typename std::enable_if<otherN >= N>::type* = 0);

The accepted answer is good for most cases, but fails if two such constructor overloads with different conditions are present. I'm looking for a solution in that case too.

Yes: the accepted solution works but not for two alternative constructor as, by example,

template <int otherN, typename = typename std::enable_if<otherN == 1>::type>
explicit A(A<otherN> const &);

template <int otherN, typename = typename std::enable_if<otherN != 1>::type>
explicit A(A<otherN> const &);

because, as stated in this page,

A common mistake is to declare two function templates that differ only in their default template arguments. This is illegal because default template arguments are not part of function template's signature, and declaring two different function templates with the same signature is illegal.

As proposed in the same page, you can go around this problem applying SFINAE, modifying the signature, to the type of a value (not type) template parameter as follows

template <int otherN, typename std::enable_if<otherN == 1, bool>::type = true>
explicit A(A<otherN> const &);

template <int otherN, typename std::enable_if<otherN != 1, bool>::type = true>
explicit A(A<otherN> const &);
  • says error: expected a qualified name after 'typename' in template<typename U = T,typename enable_if_t<is_same_v<U,opcode> ,bool> =true> constexpr arg(U&&v) : value{v}, name{"opcode"}{}
    – kyb
    Mar 15 '20 at 19:26
  • @kyb - it's difficult to say something useful without a complete example but... maybe with std:: before enable_if_t and before is_same_v ?
    – max66
    Mar 15 '20 at 19:42
  • I am using namespace std. looks like i should ask a different Q.
    – kyb
    Mar 16 '20 at 6:46
  • @kyb - yes: a new question with a complete example, please.
    – max66
    Mar 16 '20 at 11:06

With C++20 you can use the requires keyword

With C++20 you can get rid of SFINAE.

The requires keyword is a simple substitute for enable_if!

Note that the case where otherN == N is a special case, as it falls to the default copy ctor, so if you want to take care of that you have to implement it separately:

template<int N> struct A {
   A() {}    

   // handle the case of otherN == N with copy ctor
   explicit A(A<N> const& other) { /* ... */ }

   // handle the case of otherN > N, see the requires below
   template<int otherN> requires (otherN > N)
   explicit A(A<otherN> const& other) { /* ... */ }

   // handle the case of otherN < N, can add requires or not
   template<int otherN>
   explicit A(A<otherN> const& other) { /* ... */ }

The requires clause gets a constant expression that evaluates to true or false deciding thus whether to consider this method in the overload resolution, if the requires clause is true the method is preferred over another one that has no requires clause, as it is more specialized.

Code: https://godbolt.org/z/RD6pcE

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