我可以使用SFINAE(或其他技术)进行using声明,而私有派生自模板类吗?
为了更好地理解,请参阅以下代码:
#include <iostream>
struct S1 {
void f() { std::cout << "S1::f\n"; }
};
struct S2 {
void f() { std::cout << "S2::f\n"; }
void g() { std::cout << "S2::g\n"; }
};
template <class T>
struct D : private T {
using T::f;
// using T::g; // need this only if T provides g() function
};
int main() {
D<S1>().f(); // ok. Prints 'S1::f'
D<S2>().f(); // ok. Prints 'S2::f'
D<S2>().g(); // fail. But wants to be ok and prints 'S2::g'
return 0;
}
如何达到预期的行为(如果可能的话)?
答案 0 :(得分:5)
Bryan Chen的答案的变体看起来更丑,但是更容易扩展到多个检查,并且不需要复制D<type-with-f>和D<type-without-f>之间共享的代码,就是使用继承链,每个步骤检查一个额外的成员。唯一需要的重复是构造函数的继承,如果合适的话。
struct A {
void f() { }
void g() { }
void i() { }
};
// The generic case. D<T, char[N]> simply provides what D<T, char[N+1]> provides.
template <typename T, typename U = char[1]>
struct D : D<T, char[sizeof(U) + 1]> {
using D<T, char[sizeof(U) + 1]>::D;
};
// The end of the chain. This is where T gets inherited. It declares all of its own
// specialisations as its friends, so that they can access other members of T.
template <typename T>
struct D<T, char[6]> : private T {
template <typename, typename>
friend struct D;
D(int) { }
void fun() { }
};
// Check for T::f.
template <typename T>
struct D<T, char[2 + !sizeof(&T::f)]> : D<T, char[3]> {
using D<T, char[3]>::D;
using T::f;
};
// Check for T::g.
template <typename T>
struct D<T, char[3 + !sizeof(&T::g)]> : D<T, char[4]> {
using D<T, char[4]>::D;
using T::g;
};
// Check for T::h.
template <typename T>
struct D<T, char[4 + !sizeof(&T::h)]> : D<T, char[5]> {
using D<T, char[5]>::D;
using T::h;
};
// Check for T::i.
template <typename T>
struct D<T, char[5 + !sizeof(&T::i)]> : D<T, char[6]> {
using D<T, char[6]>::D;
using T::i;
};
int main() {
D<A> d = 4; // ok: verify that constructors got inherited
// A &a = d; // error: verify that inheritance of A is private
d.f(); // ok: verify that f got inherited
d.g(); // ok: verify that g got inherited
// d.h(); // error: verify that h is not available
d.i(); // ok: verify that i got inherited
d.fun(); // ok: verify that the inheritance chain didn't get broken
}
注意:您可能希望使用&T::f执行某些操作,而不是检查std::declval<T>().f()。前者无法处理重载函数。
答案 1 :(得分:4)
C ++部分模板专业化并使用decltype(void(&T::g))用于SFINAE
#include <iostream>
#include <type_traits>
struct S1 {
void f() { std::cout << "S1::f\n"; }
};
struct S2 {
void f() { std::cout << "S2::f\n"; }
void g() { std::cout << "S2::g\n"; }
};
template <class T, class V = void>
struct D : private T {
using T::f;
};
template <class T>
struct D<T, decltype(void(&T::g))> : private T {
using T::f;
using T::g; // need this only if T provides g() function
};
int main() {
D<S1>().f(); // ok. Prints 'S1::f'
D<S2>().f(); // ok. Prints 'S2::f'
D<S2>().g(); // ok. Prints 'S2::g'
return 0;
}
编辑:
这是另一种更灵活的方法,但我不知道private virtual继承如何与实际用例一起使用。如果它可能导致任何问题(例如UB),请告诉我。
#include <iostream>
#include <type_traits>
struct S1 {
void f() { std::cout << "S1::f\n"; }
};
struct S2 {
void f() { std::cout << "S2::f\n"; }
void g() { std::cout << "S2::g\n"; }
};
struct S3 {
void g() { std::cout << "S3::g\n"; }
};
template <class T, class = void>
struct D_f {};
template <class T>
struct D_f<T, decltype(void(&T::f))> : private virtual T {
using T::f;
};
template <class T, class = void>
struct D_g {};
template <class T>
struct D_g<T, decltype(void(&T::g))> : private virtual T {
using T::g;
};
template <class T>
struct D : D_f<T>, D_g<T> {
};
int main() {
D<S1>().f();
D<S2>().f();
D<S2>().g();
D<S3>().g();
return 0;
}