Boost C++ Libraries

...one of the most highly regarded and expertly designed C++ library projects in the world. Herb Sutter and Andrei Alexandrescu, C++ Coding Standards

PrevUpHomeNext

enable_if

Introduction
The enable_if templates
Using enable_if
Acknowledgements
References

Authors

  • Jaakko Järvi
  • Jeremiah Willcock
  • Andrew Lumsdaine

The enable_if family of templates is a set of tools to allow a function template or a class template specialization to include or exclude itself from a set of matching functions or specializations based on properties of its template arguments. For example, one can define function templates that are only enabled for, and thus only match, an arbitrary set of types defined by a traits class. The enable_if templates can also be applied to enable class template specializations. Applications of enable_if are discussed in length in [1] and [2].

namespace boost {
    template <class Cond, class T = void> struct enable_if;
    template <class Cond, class T = void> struct disable_if;
    template <class Cond, class T> struct lazy_enable_if;
    template <class Cond, class T> struct lazy_disable_if;

    template <bool B, class T = void> struct enable_if_c;
    template <bool B, class T = void> struct disable_if_c;
    template <bool B, class T> struct lazy_enable_if_c;
    template <bool B, class T> struct lazy_disable_if_c;
}

Sensible operation of template function overloading in C++ relies on the SFINAE (substitution-failure-is-not-an-error) principle [3]: if an invalid argument or return type is formed during the instantiation of a function template, the instantiation is removed from the overload resolution set instead of causing a compilation error. The following example, taken from [1], demonstrates why this is important:

int negate(int i) { return -i; }

template <class F>
typename F::result_type negate(const F& f) { return -f(); }

Suppose the compiler encounters the call negate(1). The first definition is obviously a better match, but the compiler must nevertheless consider (and instantiate the prototypes) of both definitions to find this out. Instantiating the latter definition with F as int would result in:

int::result_type negate(const int&);

where the return type is invalid. If this were an error, adding an unrelated function template (that was never called) could break otherwise valid code. Due to the SFINAE principle the above example is not, however, erroneous. The latter definition of negate is simply removed from the overload resolution set.

The enable_if templates are tools for controlled creation of the SFINAE conditions.

The names of the enable_if templates have three parts: an optional lazy_ tag, either enable_if or disable_if, and an optional _c tag. All eight combinations of these parts are supported. The meaning of the lazy_ tag is described in the section below. The second part of the name indicates whether a true condition argument should enable or disable the current overload. The third part of the name indicates whether the condition argument is a bool value (_c suffix), or a type containing a static bool constant named value (no suffix). The latter version interoperates with Boost.MPL.

The definitions of enable_if_c and enable_if are as follows (we use enable_if templates unqualified but they are in the boost namespace).

template <bool B, class T = void>
struct enable_if_c {
    typedef T type;
};

template <class T>
struct enable_if_c<false, T> {};

template <class Cond, class T = void>
struct enable_if : public enable_if_c<Cond::value, T> {};

An instantiation of the enable_if_c template with the parameter B as true contains a member type type, defined to be T. If B is false, no such member is defined. Thus enable_if_c<B, T>::type is either a valid or an invalid type expression, depending on the value of B. When valid, enable_if_c<B, T>::type equals T. The enable_if_c template can thus be used for controlling when functions are considered for overload resolution and when they are not. For example, the following function is defined for all arithmetic types (according to the classification of the Boost type_traits library):

template <class T>
typename enable_if_c<boost::is_arithmetic<T>::value, T>::type
foo(T t) { return t; }

The disable_if_c template is provided as well, and has the same functionality as enable_if_c except for the negated condition. The following function is enabled for all non-arithmetic types.

template <class T>
typename disable_if_c<boost::is_arithmetic<T>::value, T>::type
bar(T t) { return t; }

For easier syntax in some cases and interoperation with Boost.MPL we provide versions of the enable_if templates taking any type with a bool member constant named value as the condition argument. The MPL bool_, and_, or_, and not_ templates are likely to be useful for creating such types. Also, the traits classes in the Boost.Type_traits library follow this convention. For example, the above example function foo can be alternatively written as:

template <class T>
typename enable_if<boost::is_arithmetic<T>, T>::type
foo(T t) { return t; }

The enable_if templates are defined in boost/utility/enable_if.hpp, which is included by boost/utility.hpp.

With respect to function templates, enable_if can be used in multiple different ways:

  • As the return type of an instantiatied function
  • As an extra parameter of an instantiated function
  • As an extra template parameter (useful only in a compiler that supports C++0x default arguments for function template parameters, see Enabling function templates in C++0x for details.

In the previous section, the return type form of enable_if was shown. As an example of using the form of enable_if that works via an extra function parameter, the foo function in the previous section could also be written as:

template <class T>
T foo(T t,
    typename enable_if<boost::is_arithmetic<T> >::type* dummy = 0);

Hence, an extra parameter of type void* is added, but it is given a default value to keep the parameter hidden from client code. Note that the second template argument was not given to enable_if, as the default void gives the desired behavior.

Which way to write the enabler is largely a matter of taste, but for certain functions, only a subset of the options is possible:

  • Many operators have a fixed number of arguments, thus enable_if must be used either in the return type or in an extra template parameter.
  • Functions that have a variadic parameter list must use either the return type form or an extra template parameter.
  • Constructors do not have a return type so you must use either an extra function parameter or an extra template parameter.
  • Constructors that have a variadic parameter list must an extra template parameter.
  • Conversion operators can only be written with an extra template parameter.

In a compiler which supports C++0x default arguments for function template parameters, you can enable and disable function templates by adding an additional template parameter. This approach works in all situations where you would use either the return type form of enable_if or the function parameter form, including operators, constructors, variadic function templates, and even overloaded conversion operations.

As an example:

#include <boost/type_traits/is_arithmetic.hpp>
#include <boost/type_traits/is_pointer.hpp>
#include <boost/utility/enable_if.hpp>

class test
{
public:
    // A constructor that works for any argument list of size 10
    template< class... T,
        typename boost::enable_if_c< sizeof...( T ) == 10,
            int >::type = 0>
    test( T&&... );

    // A conversion operation that can convert to any arithmetic type
    template< class T,
        typename boost::enable_if< boost::is_arithmetic< T >,
            int >::type = 0>
    operator T() const;

    // A conversion operation that can convert to any pointer type
    template< class T,
        typename boost::enable_if< boost::is_pointer< T >,
            int >::type = 0>
    operator T() const;
};

int main()
{
    // Works
    test test_( 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 );

    // Fails as expected
    test fail_construction( 1, 2, 3, 4, 5 );

    // Works by calling the conversion operator enabled for arithmetic types
    int arithmetic_object = test_;

    // Works by calling the conversion operator enabled for pointer types
    int* pointer_object = test_;

    // Fails as expected
    struct {} fail_conversion = test_;
}

Class template specializations can be enabled or disabled with enable_if. One extra template parameter needs to be added for the enabler expressions. This parameter has the default value void. For example:

template <class T, class Enable = void>
class A { ... };

template <class T>
class A<T, typename enable_if<is_integral<T> >::type> { ... };

template <class T>
class A<T, typename enable_if<is_float<T> >::type> { ... };

Instantiating A with any integral type matches the first specialization, whereas any floating point type matches the second one. All other types match the primary template. The condition can be any compile-time boolean expression that depends on the template arguments of the class. Note that again, the second argument to enable_if is not needed; the default (void) is the correct value.

The enable_if_has_type template is usable in this scenario but instead of using a type trait to enable or disable a specialization, it uses a SFINAE context to check for the existence of a dependent type inside its parameter. For example, the following structure extracts a dependent value_type from T if and only if T::value_type exists.

template <class T, class Enable = void>
class value_type_from
{
  typedef T type;
};

template <class T>
class value_type_from<T, typename enable_if_has_type<typename T::value_type>::type>
{
  typedef typename T::value_type type;
};

Once the compiler has examined the enabling conditions and included the function into the overload resolution set, normal C++ overload resolution rules are used to select the best matching function. In particular, there is no ordering between enabling conditions. Function templates with enabling conditions that are not mutually exclusive can lead to ambiguities. For example:

template <class T>
typename enable_if<boost::is_integral<T>, void>::type
foo(T t) {}

template <class T>
typename enable_if<boost::is_arithmetic<T>, void>::type
foo(T t) {}

All integral types are also arithmetic. Therefore, say, for the call foo(1), both conditions are true and both functions are thus in the overload resolution set. They are both equally good matches and thus ambiguous. Of course, more than one enabling condition can be simultaneously true as long as other arguments disambiguate the functions.

The above discussion applies to using enable_if in class template partial specializations as well.

In some cases it is necessary to avoid instantiating part of a function signature unless an enabling condition is true. For example:

template <class T, class U> class mult_traits;

template <class T, class U>
typename enable_if<is_multipliable<T, U>,
    typename mult_traits<T, U>::type>::type
operator*(const T& t, const U& u) { ... }

Assume the class template mult_traits is a traits class defining the resulting type of a multiplication operator. The is_multipliable traits class specifies for which types to enable the operator. Whenever is_multipliable<A, B>::value is true for some types A and B, then mult_traits<A, B>::type is defined.

Now, trying to invoke (some other overload) of operator* with, say, operand types C and D for which is_multipliable<C, D>::value is false and mult_traits<C, D>::type is not defined is an error on some compilers. The SFINAE principle is not applied because the invalid type occurs as an argument to another template. The lazy_enable_if and lazy_disable_if templates (and their _c versions) can be used in such situations:

template<class T, class U>
typename lazy_enable_if<is_multipliable<T, U>,
    mult_traits<T, U> >::type
operator*(const T& t, const U& u) { ... }

The second argument of lazy_enable_if must be a class type that defines a nested type named type whenever the first parameter (the condition) is true.

[Note] Note

Referring to one member type or static constant in a traits class causes all of the members (type and static constant) of that specialization to be instantiated. Therefore, if your traits classes can sometimes contain invalid types, you should use two distinct templates for describing the conditions and the type mappings. In the above example, is_multipliable<T, U>::value defines when mult_traits<T, U>::type is valid.

Some compilers flag functions as ambiguous if the only distinguishing factor is a different condition in an enabler (even though the functions could never be ambiguous). For example, some compilers (e.g. GCC 3.2) diagnose the following two functions as ambiguous:

template <class T>
typename enable_if<boost::is_arithmetic<T>, T>::type
foo(T t);

template <class T>
typename disable_if<boost::is_arithmetic<T>, T>::type
foo(T t);

Two workarounds can be applied:

  • Use an extra dummy parameter which disambiguates the functions. Use a default value for it to hide the parameter from the caller. For example:

    template <int> struct dummy { dummy(int) {} };
    
    template <class T>
    typename enable_if<boost::is_arithmetic<T>, T>::type
    foo(T t, dummy<0> = 0);
    
    template <class T>
    typename disable_if<boost::is_arithmetic<T>, T>::type
    foo(T t, dummy<1> = 0);
    
  • Define the functions in different namespaces and bring them into a common namespace with using declarations:

    namespace A {
        template <class T>
        typename enable_if<boost::is_arithmetic<T>, T>::type
        foo(T t);
    }
    
    namespace B {
        template <class T>
        typename disable_if<boost::is_arithmetic<T>, T>::type
        foo(T t);
    }
    
    using A::foo;
    using B::foo;
    

    Note that the second workaround above cannot be used for member templates. On the other hand, operators do not accept extra arguments, which makes the first workaround unusable. As the net effect, neither of the workarounds are of assistance for templated operators that need to be defined as member functions (assignment and subscript operators).

We are grateful to Howard Hinnant, Jason Shirk, Paul Mensonides, and Richard Smith whose findings have influenced the library.

  • [1] Jaakko Järvi, Jeremiah Willcock, Howard Hinnant, and Andrew Lumsdaine. Function overloading based on arbitrary properties of types. C++ Users Journal, 21(6):25--32, June 2003.
  • [2] Jaakko Järvi, Jeremiah Willcock, and Andrew Lumsdaine. Concept-controlled polymorphism. In Frank Pfennig and Yannis Smaragdakis, editors, Generative Programming and Component Engineering, volume 2830 of LNCS, pages 228--244. Springer Verlag, September 2003.
  • [3] David Vandevoorde and Nicolai M. Josuttis. C++ Templates: The Complete Guide. Addison-Wesley, 2002.

PrevUpHomeNext