// RUN: %clang_cc1 -fsyntax-only -verify %s // C++03 [namespace.udecl]p4: // A using-declaration used as a member-declaration shall refer to a // member of a base class of the class being defined, shall refer to // a member of an anonymous union that is a member of a base class // of the class being defined, or shall refer to an enumerator for // an enumeration type that is a member of a base class of the class // being defined. // There is no directly analogous paragraph in C++0x, and the feature // works sufficiently differently there that it needs a separate test. namespace test0 { namespace NonClass { typedef int type; struct hiding {}; int hiding; static union { double union_member; }; enum tagname { enumerator }; } class Test0 { using NonClass::type; // expected-error {{not a class}} using NonClass::hiding; // expected-error {{not a class}} using NonClass::union_member; // expected-error {{not a class}} using NonClass::enumerator; // expected-error {{not a class}} }; } struct Opaque0 {}; namespace test1 { struct A { typedef int type; struct hiding {}; // expected-note {{previous use is here}} Opaque0 hiding; union { double union_member; }; enum tagname { enumerator }; }; struct B : A { using A::type; using A::hiding; using A::union_member; using A::enumerator; using A::tagname; void test0() { type t = 0; } void test1() { typedef struct A::hiding local; struct hiding _ = local(); } void test2() { union hiding _; // expected-error {{tag type that does not match previous}} } void test3() { char array[sizeof(union_member) == sizeof(double) ? 1 : -1]; } void test4() { enum tagname _ = enumerator; } void test5() { Opaque0 _ = hiding; } }; } namespace test2 { struct A { typedef int type; struct hiding {}; // expected-note {{previous use is here}} int hiding; union { double union_member; }; enum tagname { enumerator }; }; template <class T> struct B : A { using A::type; using A::hiding; using A::union_member; using A::enumerator; using A::tagname; void test0() { type t = 0; } void test1() { typedef struct A::hiding local; struct hiding _ = local(); } void test2() { union hiding _; // expected-error {{tag type that does not match previous}} } void test3() { char array[sizeof(union_member) == sizeof(double) ? 1 : -1]; } void test4() { enum tagname _ = enumerator; } void test5() { Opaque0 _ = hiding; } }; } namespace test3 { struct hiding {}; template <class T> struct A { typedef int type; // expected-note {{target of using declaration}} struct hiding {}; Opaque0 hiding; // expected-note {{target of using declaration}} union { double union_member; }; // expected-note {{target of using declaration}} enum tagname { enumerator }; // expected-note 2 {{target of using declaration}} }; template <class T> struct B : A<T> { using A<T>::type; // expected-error {{dependent using declaration resolved to type without 'typename'}} using A<T>::hiding; using A<T>::union_member; using A<T>::enumerator; using A<T>::tagname; // expected-error {{dependent using declaration resolved to type without 'typename'}} // FIXME: re-enable these when the various bugs involving tags are fixed #if 0 void test1() { typedef struct A<T>::hiding local; struct hiding _ = local(); } void test2() { typedef struct A<T>::hiding local; union hiding _ = local(); } #endif void test3() { char array[sizeof(union_member) == sizeof(double) ? 1 : -1]; } #if 0 void test4() { enum tagname _ = enumerator; } #endif void test5() { Opaque0 _ = hiding; } }; template struct B<int>; // expected-note {{in instantiation}} template <class T> struct C : A<T> { using typename A<T>::type; using typename A<T>::hiding; // expected-note {{declared here}} \ // expected-error {{'typename' keyword used on a non-type}} using typename A<T>::union_member; // expected-error {{'typename' keyword used on a non-type}} using typename A<T>::enumerator; // expected-error {{'typename' keyword used on a non-type}} void test6() { type t = 0; } void test7() { Opaque0 _ = hiding; // expected-error {{does not refer to a value}} } }; template struct C<int>; // expected-note {{in instantiation}} } namespace test4 { struct Base { int foo(); }; struct Unrelated { int foo(); }; struct Subclass : Base { }; namespace InnerNS { int foo(); } // We should be able to diagnose these without instantiation. template <class T> struct C : Base { using InnerNS::foo; // expected-error {{not a class}} using Base::bar; // expected-error {{no member named 'bar'}} using Unrelated::foo; // expected-error {{not a base class}} using C::foo; // legal in C++03 using Subclass::foo; // legal in C++03 int bar(); //expected-note {{target of using declaration}} using C::bar; // expected-error {{refers to its own class}} }; }