llvm-project/clang/test/SemaCXX/abstract.cpp

252 lines
5.7 KiB
C++

// RUN: %clang_cc1 -fsyntax-only -verify %s -std=c++0x
#ifndef __GXX_EXPERIMENTAL_CXX0X__
#define __CONCAT(__X, __Y) __CONCAT1(__X, __Y)
#define __CONCAT1(__X, __Y) __X ## __Y
#define static_assert(__b, __m) \
typedef int __CONCAT(__sa, __LINE__)[__b ? 1 : -1]
#endif
class C {
virtual void f() = 0; // expected-note {{pure virtual function 'f'}}
};
static_assert(__is_abstract(C), "C has a pure virtual function");
class D : C {
};
static_assert(__is_abstract(D), "D inherits from an abstract class");
class E : D {
virtual void f();
};
static_assert(!__is_abstract(E), "E inherits from an abstract class but implements f");
C *d = new C; // expected-error {{allocation of an object of abstract type 'C'}}
C c; // expected-error {{variable type 'C' is an abstract class}}
void t1(C c); // expected-error {{parameter type 'C' is an abstract class}}
void t2(C); // expected-error {{parameter type 'C' is an abstract class}}
struct S {
C c; // expected-error {{field type 'C' is an abstract class}}
};
void t3(const C&);
void f() {
C(); // expected-error {{allocation of an object of abstract type 'C'}}
t3(C()); // expected-error {{allocation of an object of abstract type 'C'}}
}
C e1[2]; // expected-error {{array of abstract class type 'C'}}
C (*e2)[2]; // expected-error {{array of abstract class type 'C'}}
C (**e3)[2]; // expected-error {{array of abstract class type 'C'}}
void t4(C c[2]); // expected-error {{array of abstract class type 'C'}}
void t5(void (*)(C)); // expected-error {{parameter type 'C' is an abstract class}}
typedef void (*Func)(C); // expected-error {{parameter type 'C' is an abstract class}}
void t6(Func);
class F {
F a() { while (1) {} } // expected-error {{return type 'F' is an abstract class}}
class D {
void f(F c); // expected-error {{parameter type 'F' is an abstract class}}
};
union U {
void u(F c); // expected-error {{parameter type 'F' is an abstract class}}
};
virtual void f() = 0; // expected-note {{pure virtual function 'f'}}
};
// Diagnosing in these cases is prohibitively expensive. We still
// diagnose at the function definition, of course.
class Abstract;
void t7(Abstract a);
void t8() {
void h(Abstract a);
}
namespace N {
void h(Abstract a);
}
class Abstract {
virtual void f() = 0;
};
// <rdar://problem/6854087>
class foo {
public:
virtual foo *getFoo() = 0;
};
class bar : public foo {
public:
virtual bar *getFoo();
};
bar x;
// <rdar://problem/6902298>
class A {
public:
virtual void release() = 0;
virtual void release(int count) = 0;
virtual void retain() = 0;
};
class B : public A {
public:
virtual void release();
virtual void release(int count);
virtual void retain();
};
void foo(void) {
B b;
}
struct K {
int f;
virtual ~K();
};
struct L : public K {
void f();
};
// PR5222
namespace PR5222 {
struct A {
virtual A *clone() = 0;
};
struct B : public A {
virtual B *clone() = 0;
};
struct C : public B {
virtual C *clone();
};
C c;
}
// PR5550 - instantiating template didn't track overridden methods
namespace PR5550 {
struct A {
virtual void a() = 0;
virtual void b() = 0;
};
template<typename T> struct B : public A {
virtual void b();
virtual void c() = 0;
};
struct C : public B<int> {
virtual void a();
virtual void c();
};
C x;
}
namespace PureImplicit {
// A pure virtual destructor should be implicitly overridden.
struct A { virtual ~A() = 0; };
struct B : A {};
B x;
// A pure virtual assignment operator should be implicitly overridden.
struct D;
struct C { virtual D& operator=(const D&) = 0; };
struct D : C {};
D y;
}
namespace test1 {
struct A {
virtual void foo() = 0;
};
struct B : A {
using A::foo;
};
struct C : B {
void foo();
};
void test() {
C c;
}
}
// rdar://problem/8302168
namespace test2 {
struct X1 {
virtual void xfunc(void) = 0; // expected-note {{pure virtual function}}
void g(X1 parm7); // expected-error {{parameter type 'test2::X1' is an abstract class}}
void g(X1 parm8[2]); // expected-error {{array of abstract class type 'test2::X1'}}
};
template <int N>
struct X2 {
virtual void xfunc(void) = 0; // expected-note {{pure virtual function}}
void g(X2 parm10); // expected-error {{parameter type 'X2<N>' is an abstract class}}
void g(X2 parm11[2]); // expected-error {{array of abstract class type 'X2<N>'}}
};
}
namespace test3 {
struct A { // expected-note {{not complete until}}
A x; // expected-error {{field has incomplete type}}
virtual void abstract() = 0;
};
struct B { // expected-note {{not complete until}}
virtual void abstract() = 0;
B x; // expected-error {{field has incomplete type}}
};
struct C {
static C x; // expected-error {{abstract class}}
virtual void abstract() = 0; // expected-note {{pure virtual function}}
};
struct D {
virtual void abstract() = 0; // expected-note {{pure virtual function}}
static D x; // expected-error {{abstract class}}
};
}
namespace test4 {
template <class T> struct A {
A x; // expected-error {{abstract class}}
virtual void abstract() = 0; // expected-note {{pure virtual function}}
};
template <class T> struct B {
virtual void abstract() = 0; // expected-note {{pure virtual function}}
B x; // expected-error {{abstract class}}
};
template <class T> struct C {
static C x; // expected-error {{abstract class}}
virtual void abstract() = 0; // expected-note {{pure virtual function}}
};
template <class T> struct D {
virtual void abstract() = 0; // expected-note {{pure virtual function}}
static D x; // expected-error {{abstract class}}
};
}