safecode/tools/clang/test/CXX/temp/temp.decls/temp.class/temp.mem.enum/p1.cpp - llvm-archive - Git at Google

 // RUN: %clang_cc1 -std=c++11 -verify %s

 template<typename T> struct A {
   enum E : T; // expected-note {{here}}
   E v;
   E f() { return A::e1; } // expected-error {{no member named 'e1' in 'A<T>'}}
   E g() { return E::e1; }
   E h();
 };

 A<int> a;
 A<int>::E a0 = A<int>().v;
 int n = A<int>::E::e1; // expected-error {{implicit instantiation of undefined member}}

 template<typename T> enum A<T>::E : T { e1, e2 }; // expected-note 2 {{declared here}}

 // FIXME: Now that A<T>::E is defined, we are supposed to inject its enumerators
 // into the already-instantiated class A<T>. This seems like a really bad idea,
 // though, so we don't implement that, but what we do implement is inconsistent.
 //
 // Either do as the standard says, or only include enumerators lexically defined
 // within the class in its scope.
 A<int>::E a1 = A<int>::e1; // expected-error {{no member named 'e1' in 'A<int>'; did you mean simply 'e1'?}}

 A<char>::E a2 = A<char>::e2;

 template<typename T> typename A<T>::E A<T>::h() { return e2; }
 A<short>::E a3 = A<short>().h();


 template<typename T> struct B {
   enum class E;
   E v;
   E f() { return E::e1; }
   E g();
 };

 B<int> b;
 B<int>::E b0 = B<int>().v;

 template<typename T> enum class B<T>::E { e1, e2 };
 B<int>::E b1 = B<int>::E::e1;

 B<char>::E b2 = B<char>::E::e2;

 template<typename T> typename B<T>::E B<T>::g() { return e2; }
 B<short>::E b3 = B<short>().g();


 // Enumeration members of class templates can be explicitly specialized. For
 // unscoped enumerations, specializations must be defined before the primary
 // template is, since otherwise the primary template will be implicitly
 // instantiated when we parse the nested name specifier.
 template<> enum A<long long>::E : long long { e3, e4 }; // expected-error {{explicit specialization of 'E' after instantiation}} expected-note {{first required here}}

 template<> enum class B<long long>::E { e3, e4 };
 B<long long>::E b4 = B<long long>::E::e4;

 B<long>::E b5;
 template<> enum class B<long>::E { e5 };
 void fb5() { b5 = decltype(b5)::e5; }
 B<long>::E b6 = B<long>::E::e5;


 template<typename T> struct C {
   enum class E : T;
 };

 template<> enum class C<long long>::E : long long { e3, e4 };
 C<long long>::E c0 = C<long long>::E::e3;

 C<long>::E c1;
 template<> enum class C<long>::E : long { e5 };
 void fc1() { c1 = decltype(c1)::e5; }
 C<long>::E c2 = C<long>::E::e5;

 template<> enum class C<int>::E : int { e6 };
 template<typename T> enum class C<T>::E : T { e0 };
 C<int>::E c3 = C<int>::E::e6;
 C<int>::E c4 = C<int>::E::e0; // expected-error {{no member named 'e0' in 'C<int>::E'}}


 // Enumeration members can't be partially-specialized.
 template<typename T> enum class B<T*>::E { e5, e6 }; // expected-error {{nested name specifier for a declaration cannot depend on a template parameter}}


 // Explicit specializations can be forward-declared.
 template<typename T>
 struct D {
   enum class E { e1 };
 };
 template<> enum class D<int>::E;
 D<int>::E d1 = D<int>::E::e1; // expected-error {{incomplete type 'D<int>::E'}}
 template<> enum class D<int>::E { e2 };
 D<int>::E d2 = D<int>::E::e2;
 D<char>::E d3 = D<char>::E::e1; // expected-note {{first required here}}
 D<char>::E d4 = D<char>::E::e2; // expected-error {{no member named 'e2' in 'D<char>::E'; did you mean simply 'e2'?}}
 template<> enum class D<char>::E { e3 }; // expected-error {{explicit specialization of 'E' after instantiation}}

 template<> enum class D<short>::E;
 struct F {
   // Per C++11 [class.friend]p3, these friend declarations have no effect.
   // Only classes and functions can be friends.
   template<typename T> friend enum D<T>::E;
   template<> friend enum D<short>::E;

   template<> friend enum D<double>::E { e3 }; // expected-error {{cannot define a type in a friend declaration}}

 private:
   static const int n = 1; // expected-note {{private here}}
 };
 template<> enum class D<short>::E {
   e = F::n // expected-error {{private member}}
 };

 class Access {
   friend class X;

   template<typename T>
   class Priv {
     friend class X;

     enum class E : T;
   };

   class S {
     typedef int N; // expected-note {{here}}
     static const int k = 3; // expected-note {{here}}

     friend class Priv<char>;
   };

   static const int k = 5;
 };

 template<> enum class Access::Priv<Access::S::N>::E
   : Access::S::N { // expected-error {{private member}}
   a = Access::k, // ok
   b = Access::S::k // expected-error {{private member}}
 };

 template<typename T> enum class Access::Priv<T>::E : T {
   c = Access::k,
   d = Access::S::k
 };

 class X {
   Access::Priv<int>::E a = Access::Priv<int>::E::a;
   Access::Priv<char>::E c = Access::Priv<char>::E::d;
   // FIXME: We should see an access error for this enumerator.
   Access::Priv<short>::E b = Access::Priv<short>::E::d;
 };
	// RUN: %clang_cc1 -std=c++11 -verify %s

	template<typename T> struct A {
	enum E : T; // expected-note {{here}}
	E v;
	E f() { return A::e1; } // expected-error {{no member named 'e1' in 'A<T>'}}
	E g() { return E::e1; }
	E h();
	};

	A<int> a;
	A<int>::E a0 = A<int>().v;
	int n = A<int>::E::e1; // expected-error {{implicit instantiation of undefined member}}

	template<typename T> enum A<T>::E : T { e1, e2 }; // expected-note 2 {{declared here}}

	// FIXME: Now that A<T>::E is defined, we are supposed to inject its enumerators
	// into the already-instantiated class A<T>. This seems like a really bad idea,
	// though, so we don't implement that, but what we do implement is inconsistent.
	//
	// Either do as the standard says, or only include enumerators lexically defined
	// within the class in its scope.
	A<int>::E a1 = A<int>::e1; // expected-error {{no member named 'e1' in 'A<int>'; did you mean simply 'e1'?}}

	A<char>::E a2 = A<char>::e2;

	template<typename T> typename A<T>::E A<T>::h() { return e2; }
	A<short>::E a3 = A<short>().h();


	template<typename T> struct B {
	enum class E;
	E v;
	E f() { return E::e1; }
	E g();
	};

	B<int> b;
	B<int>::E b0 = B<int>().v;

	template<typename T> enum class B<T>::E { e1, e2 };
	B<int>::E b1 = B<int>::E::e1;

	B<char>::E b2 = B<char>::E::e2;

	template<typename T> typename B<T>::E B<T>::g() { return e2; }
	B<short>::E b3 = B<short>().g();


	// Enumeration members of class templates can be explicitly specialized. For
	// unscoped enumerations, specializations must be defined before the primary
	// template is, since otherwise the primary template will be implicitly
	// instantiated when we parse the nested name specifier.
	template<> enum A<long long>::E : long long { e3, e4 }; // expected-error {{explicit specialization of 'E' after instantiation}} expected-note {{first required here}}

	template<> enum class B<long long>::E { e3, e4 };
	B<long long>::E b4 = B<long long>::E::e4;

	B<long>::E b5;
	template<> enum class B<long>::E { e5 };
	void fb5() { b5 = decltype(b5)::e5; }
	B<long>::E b6 = B<long>::E::e5;


	template<typename T> struct C {
	enum class E : T;
	};

	template<> enum class C<long long>::E : long long { e3, e4 };
	C<long long>::E c0 = C<long long>::E::e3;

	C<long>::E c1;
	template<> enum class C<long>::E : long { e5 };
	void fc1() { c1 = decltype(c1)::e5; }
	C<long>::E c2 = C<long>::E::e5;

	template<> enum class C<int>::E : int { e6 };
	template<typename T> enum class C<T>::E : T { e0 };
	C<int>::E c3 = C<int>::E::e6;
	C<int>::E c4 = C<int>::E::e0; // expected-error {{no member named 'e0' in 'C<int>::E'}}


	// Enumeration members can't be partially-specialized.
	template<typename T> enum class B<T*>::E { e5, e6 }; // expected-error {{nested name specifier for a declaration cannot depend on a template parameter}}


	// Explicit specializations can be forward-declared.
	template<typename T>
	struct D {
	enum class E { e1 };
	};
	template<> enum class D<int>::E;
	D<int>::E d1 = D<int>::E::e1; // expected-error {{incomplete type 'D<int>::E'}}
	template<> enum class D<int>::E { e2 };
	D<int>::E d2 = D<int>::E::e2;
	D<char>::E d3 = D<char>::E::e1; // expected-note {{first required here}}
	D<char>::E d4 = D<char>::E::e2; // expected-error {{no member named 'e2' in 'D<char>::E'; did you mean simply 'e2'?}}
	template<> enum class D<char>::E { e3 }; // expected-error {{explicit specialization of 'E' after instantiation}}

	template<> enum class D<short>::E;
	struct F {
	// Per C++11 [class.friend]p3, these friend declarations have no effect.
	// Only classes and functions can be friends.
	template<typename T> friend enum D<T>::E;
	template<> friend enum D<short>::E;

	template<> friend enum D<double>::E { e3 }; // expected-error {{cannot define a type in a friend declaration}}

	private:
	static const int n = 1; // expected-note {{private here}}
	};
	template<> enum class D<short>::E {
	e = F::n // expected-error {{private member}}
	};

	class Access {
	friend class X;

	template<typename T>
	class Priv {
	friend class X;

	enum class E : T;
	};

	class S {
	typedef int N; // expected-note {{here}}
	static const int k = 3; // expected-note {{here}}

	friend class Priv<char>;
	};

	static const int k = 5;
	};

	template<> enum class Access::Priv<Access::S::N>::E
	: Access::S::N { // expected-error {{private member}}
	a = Access::k, // ok
	b = Access::S::k // expected-error {{private member}}
	};

	template<typename T> enum class Access::Priv<T>::E : T {
	c = Access::k,
	d = Access::S::k
	};

	class X {
	Access::Priv<int>::E a = Access::Priv<int>::E::a;
	Access::Priv<char>::E c = Access::Priv<char>::E::d;
	// FIXME: We should see an access error for this enumerator.
	Access::Priv<short>::E b = Access::Priv<short>::E::d;
	};