llvm-project/clang/test/CXX/drs/dr4xx.cpp

1242 lines
32 KiB
C++

// RUN: env ASAN_OPTIONS=detect_stack_use_after_return=0 %clang_cc1 -std=c++98 %s -verify -fexceptions -fcxx-exceptions -pedantic-errors
// RUN: env ASAN_OPTIONS=detect_stack_use_after_return=0 %clang_cc1 -std=c++11 %s -verify -fexceptions -fcxx-exceptions -pedantic-errors
// RUN: env ASAN_OPTIONS=detect_stack_use_after_return=0 %clang_cc1 -std=c++14 %s -verify -fexceptions -fcxx-exceptions -pedantic-errors
// RUN: env ASAN_OPTIONS=detect_stack_use_after_return=0 %clang_cc1 -std=c++17 %s -verify -fexceptions -fcxx-exceptions -pedantic-errors
// FIXME: __SIZE_TYPE__ expands to 'long long' on some targets.
__extension__ typedef __SIZE_TYPE__ size_t;
namespace std { struct type_info; }
namespace dr400 { // dr400: yes
struct A { int a; struct a {}; }; // expected-note 2{{conflicting}} expected-note {{ambiguous}}
struct B { int a; struct a {}; }; // expected-note 2{{target}} expected-note {{ambiguous}}
struct C : A, B { using A::a; struct a b; };
struct D : A, B { using A::a; using B::a; struct a b; }; // expected-error 2{{conflicts}}
struct E : A, B { struct a b; }; // expected-error {{found in multiple base classes}}
}
namespace dr401 { // dr401: yes
template<class T, class U = typename T::type> class A : public T {}; // expected-error {{protected}} expected-error 2{{private}}
class B {
protected:
typedef int type; // expected-note {{protected}}
};
class C {
typedef int type; // expected-note {{private}}
friend class A<C>; // expected-note {{default argument}}
};
class D {
typedef int type; // expected-note {{private}}
friend class A<D, int>;
};
A<B> *b; // expected-note {{default argument}}
A<D> *d; // expected-note {{in instantiation of default argument}}
struct E {
template<class T, class U = typename T::type> class A : public T {};
};
class F {
typedef int type;
friend class E;
};
E::A<F> eaf; // ok, default argument is in befriended context
// FIXME: Why do we get different diagnostics in C++11 onwards here? We seem
// to not treat the default template argument as a SFINAE context in C++98.
template<class T, class U = typename T::type> void f(T) {}
void g(B b) { f(b); }
#if __cplusplus < 201103L
// expected-error@-3 0-1{{extension}} expected-error@-3 {{protected}} expected-note@-3 {{instantiation}}
// expected-note@-3 {{substituting}}
#else
// expected-error@-5 {{no matching}} expected-note@-6 {{protected}}
#endif
}
namespace dr403 { // dr403: yes
namespace A {
struct S {};
int f(void*);
}
template<typename T> struct X {};
typedef struct X<A::S>::X XS;
XS *p;
int k = f(p); // ok, finds A::f, even though type XS is a typedef-name
// referring to an elaborated-type-specifier naming a
// injected-class-name, which is about as far from a
// template-id as we can make it.
}
// dr404: na
// (NB: also sup 594)
namespace dr406 { // dr406: yes
typedef struct {
static int n; // expected-error {{static data member 'n' not allowed in anonymous struct}}
} A;
}
namespace dr407 { // dr407: 3.8
struct S;
typedef struct S S;
void f() {
struct S *p;
{
typedef struct S S; // expected-note {{here}}
struct S *p; // expected-error {{typedef 'S' cannot be referenced with a struct specifier}}
}
}
struct S {};
namespace UsingDir {
namespace A {
struct S {}; // expected-note {{found}}
}
namespace B {
typedef int S; // expected-note {{found}}
}
namespace C {
using namespace A;
using namespace B;
struct S s; // expected-error {{ambiguous}}
}
namespace D {
using A::S;
typedef struct S S;
struct S s;
}
namespace E {
// The standard doesn't say whether this is valid. We interpret
// DR407 as meaning "if lookup finds both a tag and a typedef with the
// same type, then it's OK in an elaborated-type-specifier".
typedef A::S S;
using A::S;
struct S s;
}
namespace F {
typedef A::S S;
}
// The standard doesn't say what to do in these cases either.
namespace G {
using namespace A;
using namespace F;
struct S s;
}
namespace H {
using namespace F;
using namespace A;
struct S s;
}
}
}
namespace dr408 { // dr408: 3.4
template<int N> void g() { int arr[N != 1 ? 1 : -1]; }
template<> void g<2>() { }
template<typename T> struct S {
static int i[];
void f();
};
template<typename T> int S<T>::i[] = { 1 };
template<typename T> void S<T>::f() {
g<sizeof (i) / sizeof (int)>();
}
template<> int S<int>::i[] = { 1, 2 };
template void S<int>::f(); // uses g<2>(), not g<1>().
template<typename T> struct R {
static int arr[];
void f();
};
template<typename T> int R<T>::arr[1];
template<typename T> void R<T>::f() {
int arr[sizeof(arr) != sizeof(int) ? 1 : -1];
}
template<> int R<int>::arr[2];
template void R<int>::f();
}
namespace dr409 { // dr409: yes
template<typename T> struct A {
typedef int B;
B b1;
A::B b2;
A<T>::B b3;
A<T*>::B b4; // expected-error {{missing 'typename'}}
};
}
namespace dr410 { // dr410: no
template<class T> void f(T);
void g(int);
namespace M {
template<class T> void h(T);
template<class T> void i(T);
struct A {
friend void f<>(int);
friend void h<>(int);
friend void g(int);
template<class T> void i(T);
friend void i<>(int);
private:
static void z(); // expected-note {{private}}
};
template<> void h(int) { A::z(); }
// FIXME: This should be ill-formed. The member A::i<> is befriended,
// not this function.
template<> void i(int) { A::z(); }
}
template<> void f(int) { M::A::z(); }
void g(int) { M::A::z(); } // expected-error {{private}}
}
// dr412 is in its own file.
namespace dr413 { // dr413: yes
struct S {
int a;
int : 17;
int b;
};
S s = { 1, 2, 3 }; // expected-error {{excess elements}}
struct E {};
struct T { // expected-note {{here}}
int a;
E e;
int b;
};
T t1 = { 1, {}, 2 };
T t2 = { 1, 2 }; // expected-error {{aggregate with no elements requires explicit braces}}
}
namespace dr414 { // dr414: dup 305
struct X {};
void f() {
X x;
struct X {};
x.~X();
}
}
namespace dr415 { // dr415: yes
template<typename T> void f(T, ...) { T::error; }
void f(int, int);
void g() { f(0, 0); } // ok
}
namespace dr416 { // dr416: yes
extern struct A a;
int &operator+(const A&, const A&);
int &k = a + a;
struct A { float &operator+(A&); };
float &f = a + a;
}
namespace dr417 { // dr417: no
struct A;
struct dr417::A {}; // expected-warning {{extra qualification}}
struct B { struct X; };
struct C : B {};
struct C::X {}; // expected-error {{no struct named 'X' in 'dr417::C'}}
struct B::X { struct Y; };
struct C::X::Y {}; // ok!
namespace N {
struct D;
struct E;
struct F;
struct H;
}
// FIXME: This is ill-formed.
using N::D;
struct dr417::D {}; // expected-warning {{extra qualification}}
using namespace N;
struct dr417::E {}; // expected-warning {{extra qualification}} expected-error {{no struct named 'E'}}
struct N::F {};
struct G;
using N::H;
namespace M {
struct dr417::G {}; // expected-error {{namespace 'M' does not enclose}}
struct dr417::H {}; // expected-error {{namespace 'M' does not enclose}}
}
}
namespace dr420 { // dr420: yes
template<typename T> struct ptr {
T *operator->() const;
T &operator*() const;
};
template<typename T, typename P> void test(P p) {
p->~T();
p->T::~T();
(*p).~T();
(*p).T::~T();
}
struct X {};
template void test<int>(int*);
template void test<int>(ptr<int>);
template void test<X>(X*);
template void test<X>(ptr<X>);
template<typename T>
void test2(T p) {
p->template Y<int>::~Y<int>();
p->~Y<int>();
// FIXME: This is ill-formed, but this diagnostic is terrible. We should
// reject this in the parser.
p->template ~Y<int>(); // expected-error 2{{no member named '~typename Y<int>'}}
}
template<typename T> struct Y {};
template void test2(Y<int>*); // expected-note {{instantiation}}
template void test2(ptr<Y<int> >); // expected-note {{instantiation}}
void test3(int *p, ptr<int> q) {
typedef int Int;
p->~Int();
q->~Int();
p->Int::~Int();
q->Int::~Int();
}
#if __cplusplus >= 201103L
template<typename T> using id = T;
struct A { template<typename T> using id = T; };
void test4(int *p, ptr<int> q) {
p->~id<int>();
q->~id<int>();
p->id<int>::~id<int>();
q->id<int>::~id<int>();
p->template id<int>::~id<int>(); // expected-error {{expected unqualified-id}}
q->template id<int>::~id<int>(); // expected-error {{expected unqualified-id}}
p->A::template id<int>::~id<int>();
q->A::template id<int>::~id<int>();
}
#endif
}
namespace dr421 { // dr421: yes
struct X { X(); int n; int &r; };
int *p = &X().n; // expected-error-re {{{{taking the address of a temporary|cannot take the address of an rvalue}}}}
int *q = &X().r;
}
namespace dr422 { // dr422: yes
template<typename T, typename U> void f() {
typedef T type; // expected-note {{prev}}
typedef U type; // expected-error {{redef}}
}
template void f<int, int>();
template void f<int, char>(); // expected-note {{instantiation}}
}
namespace dr423 { // dr423: yes
template<typename T> struct X { operator T&(); };
void f(X<int> x) { x += 1; }
}
namespace dr424 { // dr424: yes
struct A {
typedef int N; // expected-note {{previous}}
typedef int N; // expected-error {{redefinition}}
struct X;
typedef X X; // expected-note {{previous}}
struct X {};
struct X *p;
struct A::X *q;
X *r;
typedef X X; // expected-error {{redefinition}}
};
struct B {
typedef int N;
};
struct C : B {
typedef int N; // expected-note {{previous}}
typedef int N; // expected-error {{redefinition}}
};
}
namespace dr425 { // dr425: yes
struct A { template<typename T> operator T() const; } a;
float f = 1.0f * a; // expected-error {{ambiguous}} expected-note 5+{{built-in candidate}}
template<typename T> struct is_float;
template<> struct is_float<float> { typedef void type; };
struct B {
template<typename T, typename U = typename is_float<T>::type> operator T() const; // expected-error 0-1{{extension}}
} b;
float g = 1.0f * b; // ok
}
namespace dr427 { // dr427: yes
struct B {};
struct D : public B {
D(B &) = delete; // expected-error 0-1{{extension}} expected-note {{deleted}}
};
extern D d1;
B &b = d1;
const D &d2 = static_cast<const D&>(b);
const D &d3 = (const D&)b;
const D &d4(b); // expected-error {{deleted}}
}
namespace dr428 { // dr428: yes
template<typename T> T make();
extern struct X x; // expected-note 5{{forward declaration}}
void f() {
throw void(); // expected-error {{cannot throw}}
throw make<void*>();
throw make<const volatile void*>();
throw x; // expected-error {{cannot throw}}
throw make<X&>(); // expected-error {{cannot throw}}
throw make<X*>(); // expected-error {{cannot throw}}
throw make<const volatile X&>(); // expected-error {{cannot throw}}
throw make<const volatile X*>(); // expected-error {{cannot throw}}
}
}
namespace dr429 { // dr429: yes c++11
// FIXME: This rule is obviously intended to apply to C++98 as well.
struct A {
static void *operator new(size_t, size_t);
static void operator delete(void*, size_t);
} *a = new (0) A;
#if __cplusplus >= 201103L
// expected-error@-2 {{'new' expression with placement arguments refers to non-placement 'operator delete'}}
// expected-note@-4 {{here}}
#endif
struct B {
static void *operator new(size_t, size_t);
static void operator delete(void*);
static void operator delete(void*, size_t);
} *b = new (0) B; // ok, second delete is not a non-placement deallocation function
}
namespace dr430 { // dr430: yes c++11
// resolved by n2239
// FIXME: This should apply in C++98 too.
void f(int n) {
int a[] = { n++, n++, n++ };
#if __cplusplus < 201103L
// expected-warning@-2 {{multiple unsequenced modifications to 'n'}}
#endif
}
}
namespace dr431 { // dr431: yes
struct A {
template<typename T> T *get();
template<typename T> struct B {
template<typename U> U *get();
};
};
template<typename T> void f(A a) {
a.get<A>()->get<T>();
a.get<T>()
->get<T>(); // expected-error {{use 'template'}}
a.get<T>()->template get<T>();
a.A::get<T>();
A::B<int> *b = a.get<A::B<int> >();
b->get<int>();
b->A::B<int>::get<int>();
b->A::B<int>::get<T>();
b->A::B<T>::get<int>(); // expected-error {{use 'template'}}
b->A::B<T>::template get<int>();
b->A::B<T>::get<T>(); // expected-error {{use 'template'}}
b->A::B<T>::template get<T>();
A::B<T> *c = a.get<A::B<T> >();
c->get<int>(); // expected-error {{use 'template'}}
c->template get<int>();
}
}
namespace dr432 { // dr432: yes
template<typename T> struct A {};
template<typename T> struct B : A<B> {}; // expected-error {{requires template arguments}} expected-note {{declared}}
template<typename T> struct C : A<C<T> > {};
#if __cplusplus >= 201103L
template<typename T> struct D : decltype(A<D>()) {}; // expected-error {{requires template arguments}} expected-note {{declared}}
#endif
}
namespace dr433 { // dr433: yes
template<class T> struct S {
void f(union U*);
};
U *p;
template<class T> void S<T>::f(union U*) {}
S<int> s;
}
namespace dr434 { // dr434: yes
void f() {
const int ci = 0;
int *pi = 0;
const int *&rpci = pi; // expected-error {{cannot bind}}
rpci = &ci;
*pi = 1;
}
}
// dr435: na
namespace dr436 { // dr436: yes
enum E { f }; // expected-note {{previous}}
void f(); // expected-error {{redefinition}}
}
namespace dr437 { // dr437: sup 1308
// This is superseded by 1308, which is in turn superseded by 1330,
// which restores this rule.
template<typename U> struct T : U {};
struct S {
void f() throw(S);
#if __cplusplus > 201402L
// expected-error@-2 {{ISO C++17 does not allow}} expected-note@-2 {{use 'noexcept}}
#endif
void g() throw(T<S>);
#if __cplusplus > 201402L
// expected-error@-2 {{ISO C++17 does not allow}} expected-note@-2 {{use 'noexcept}}
#endif
struct U;
void h() throw(U);
#if __cplusplus > 201402L
// expected-error@-2 {{ISO C++17 does not allow}} expected-note@-2 {{use 'noexcept}}
#endif
struct U {};
};
}
// dr438 FIXME write a codegen test
// dr439 FIXME write a codegen test
// dr441 FIXME write a codegen test
// dr442: sup 348
// dr443: na
namespace dr444 { // dr444: yes
struct D;
struct B { // expected-note {{candidate is the implicit copy}} expected-note 0-1 {{implicit move}}
D &operator=(D &) = delete; // expected-error 0-1{{extension}} expected-note {{deleted}}
};
struct D : B { // expected-note {{candidate is the implicit}} expected-note 0-1 {{implicit move}}
using B::operator=;
} extern d;
void f() {
d = d; // expected-error {{deleted}}
}
}
namespace dr445 { // dr445: yes
class A { void f(); }; // expected-note {{private}}
struct B {
friend void A::f(); // expected-error {{private}}
};
}
namespace dr446 { // dr446: yes
struct C;
struct A {
A();
A(const A&) = delete; // expected-error 0-1{{extension}} expected-note +{{deleted}}
A(const C&);
};
struct C : A {};
void f(A a, bool b, C c) {
void(b ? a : a);
b ? A() : a; // expected-error {{deleted}}
b ? a : A(); // expected-error {{deleted}}
b ? A() : A();
#if __cplusplus <= 201402L
// expected-error@-2 {{deleted}}
#endif
void(b ? a : c);
b ? a : C(); // expected-error {{deleted}}
b ? c : A();
#if __cplusplus <= 201402L
// expected-error@-2 {{deleted}}
#endif
b ? A() : C();
#if __cplusplus <= 201402L
// expected-error@-2 {{deleted}}
#endif
}
}
namespace dr447 { // dr447: yes
struct A { int n; int a[4]; };
template<int> struct U {
typedef int type;
template<typename V> static void h();
};
template<typename T> U<sizeof(T)> g(T);
template<typename T, int N> void f(int n) {
// ok, not type dependent
g(__builtin_offsetof(A, n)).h<int>();
g(__builtin_offsetof(T, n)).h<int>();
// value dependent if first argument is a dependent type
U<__builtin_offsetof(A, n)>::type a;
U<__builtin_offsetof(T, n)>::type b; // expected-error +{{}} expected-warning 0+{{}}
// as an extension, we allow the member-designator to include array indices
g(__builtin_offsetof(A, a[0])).h<int>(); // expected-error {{extension}}
g(__builtin_offsetof(A, a[N])).h<int>(); // expected-error {{extension}}
U<__builtin_offsetof(A, a[0])>::type c; // expected-error {{extension}}
U<__builtin_offsetof(A, a[N])>::type d; // expected-error {{extension}} expected-error +{{}} expected-warning 0+{{}}
}
}
namespace dr448 { // dr448: yes
template<typename T = int> void f(int); // expected-error 0-1{{extension}} expected-note {{no known conversion}}
template<typename T> void g(T t) {
f<T>(t); // expected-error {{neither visible in the template definition nor found by argument-dependent lookup}}
dr448::f(t); // expected-error {{no matching function}}
}
template<typename T> void f(T); // expected-note {{should be declared prior to the call site}}
namespace HideFromADL { struct X {}; }
template void g(int); // ok
template void g(HideFromADL::X); // expected-note {{instantiation of}}
}
// dr449: na
namespace dr450 { // dr450: yes
typedef int A[3];
void f1(const A &);
void f2(A &); // expected-note +{{not viable}}
struct S { A n; };
void g() {
f1(S().n);
f2(S().n); // expected-error {{no match}}}
}
#if __cplusplus >= 201103L
void h() {
f1(A{});
f2(A{}); // expected-error {{no match}}
}
#endif
}
namespace dr451 { // dr451: yes
const int a = 1 / 0; // expected-warning {{undefined}}
const int b = 1 / 0; // expected-warning {{undefined}}
int arr[b]; // expected-error +{{variable length arr}}
}
namespace dr452 { // dr452: yes
struct A {
int a, b, c;
A *p;
int f();
A() : a(f()), b(this->f() + a), c(this->a), p(this) {}
};
}
// dr454 FIXME write a codegen test
namespace dr456 { // dr456: yes
// sup 903 c++11
const int null = 0;
void *p = null;
#if __cplusplus >= 201103L
// expected-error@-2 {{cannot initialize}}
#else
// expected-warning@-4 {{null}}
#endif
const bool f = false;
void *q = f;
#if __cplusplus >= 201103L
// expected-error@-2 {{cannot initialize}}
#else
// expected-warning@-4 {{null}}
#endif
}
namespace dr457 { // dr457: yes
const int a = 1;
const volatile int b = 1;
int ax[a];
int bx[b]; // expected-error +{{variable length array}}
enum E {
ea = a,
eb = b // expected-error {{constant}} expected-note {{read of volatile-qualified}}
};
}
namespace dr458 { // dr458: no
struct A {
int T;
int f();
template<typename> int g();
};
template<typename> struct B : A {
int f();
template<typename> int g();
template<typename> int h();
};
int A::f() {
return T;
}
template<typename T>
int A::g() {
return T; // FIXME: this is invalid, it finds the template parameter
}
template<typename T>
int B<T>::f() {
return T;
}
template<typename T> template<typename U>
int B<T>::g() {
return T;
}
template<typename U> template<typename T>
int B<U>::h() {
return T; // FIXME: this is invalid, it finds the template parameter
}
}
namespace dr460 { // dr460: yes
namespace X { namespace Q { int n; } }
namespace Y {
using X; // expected-error {{requires a qualified name}}
using dr460::X; // expected-error {{cannot refer to a namespace}}
using X::Q; // expected-error {{cannot refer to a namespace}}
}
}
// dr461: na
// dr462 FIXME write a codegen test
// dr463: na
// dr464: na
// dr465: na
namespace dr466 { // dr466: no
typedef int I;
typedef const int CI;
typedef volatile int VI;
void f(int *a, CI *b, VI *c) {
a->~I();
a->~CI();
a->~VI();
a->I::~I();
a->CI::~CI();
a->VI::~VI();
a->CI::~VI(); // FIXME: This is invalid; CI and VI are not the same scalar type.
b->~I();
b->~CI();
b->~VI();
b->I::~I();
b->CI::~CI();
b->VI::~VI();
c->~I();
c->~CI();
c->~VI();
c->I::~I();
c->CI::~CI();
c->VI::~VI();
}
}
namespace dr467 { // dr467: yes
int stuff();
int f() {
static bool done;
if (done)
goto later;
static int k = stuff();
done = true;
later:
return k;
}
int g() {
goto later; // expected-error {{cannot jump}}
int k = stuff(); // expected-note {{bypasses variable initialization}}
later:
return k;
}
}
namespace dr468 { // dr468: yes c++11
// FIXME: Should we allow this in C++98 too?
template<typename> struct A {
template<typename> struct B {
static int C;
};
};
int k = dr468::template A<int>::template B<char>::C;
#if __cplusplus < 201103L
// expected-error@-2 2{{'template' keyword outside of a template}}
#endif
}
namespace dr469 { // dr469: no
// FIXME: The core issue here didn't really answer the question. We don't
// deduce 'const T' from a function or reference type in a class template...
template<typename T> struct X; // expected-note 2{{here}}
template<typename T> struct X<const T> {};
X<int&> x; // expected-error {{undefined}}
X<int()> y; // expected-error {{undefined}}
// ... but we do in a function template. GCC and EDG fail deduction of 'f'
// and the second 'h'.
template<typename T> void f(const T *);
template<typename T> void g(T *, const T * = 0);
template<typename T> void h(T *) { T::error; }
template<typename T> void h(const T *);
void i() {
f(&i);
g(&i);
h(&i);
}
}
namespace dr470 { // dr470: yes
template<typename T> struct A {
struct B {};
};
template<typename T> struct C {
};
template struct A<int>; // expected-note {{previous}}
template struct A<int>::B; // expected-error {{duplicate explicit instantiation}}
// ok, instantiating C<char> doesn't instantiate base class members.
template struct A<char>;
template struct C<char>;
}
namespace dr471 { // dr471: yes
struct A { int n; };
struct B : private virtual A {};
struct C : protected virtual A {};
struct D : B, C { int f() { return n; } };
struct E : private virtual A {
using A::n;
};
struct F : E, B { int f() { return n; } };
struct G : virtual A {
private:
using A::n; // expected-note {{here}}
};
struct H : B, G { int f() { return n; } }; // expected-error {{private}}
}
namespace dr474 { // dr474: yes
namespace N {
struct S {
void f();
};
}
void N::S::f() {
void g(); // expected-note {{previous}}
}
int g();
namespace N {
int g(); // expected-error {{cannot be overloaded}}
}
}
// dr475 FIXME write a codegen test
namespace dr477 { // dr477: 3.5
struct A {
explicit A();
virtual void f();
};
struct B {
friend explicit A::A(); // expected-error {{'explicit' is invalid in friend declarations}}
friend virtual void A::f(); // expected-error {{'virtual' is invalid in friend declarations}}
};
explicit A::A() {} // expected-error {{can only be specified inside the class definition}}
virtual void A::f() {} // expected-error {{can only be specified inside the class definition}}
}
namespace dr478 { // dr478: yes
struct A { virtual void f() = 0; }; // expected-note {{unimplemented}}
void f(A *a);
void f(A a[10]); // expected-error {{array of abstract class type}}
}
namespace dr479 { // dr479: yes
struct S {
S();
private:
S(const S&); // expected-note +{{here}}
~S(); // expected-note +{{here}}
};
void f() {
throw S();
// expected-error@-1 {{temporary of type 'dr479::S' has private destructor}}
// expected-error@-2 {{exception object of type 'dr479::S' has private destructor}}
#if __cplusplus < 201103L
// expected-error@-4 {{C++98 requires an accessible copy constructor}}
#endif
#if __cplusplus <= 201402L
// expected-error@-7 {{calling a private constructor}} (copy ctor)
#endif
}
void g() {
S s; // expected-error {{private destructor}}}
throw s;
// expected-error@-1 {{calling a private constructor}}
// expected-error@-2 {{exception object of type 'dr479::S' has private destructor}}
}
void h() {
try {
f();
g();
} catch (S s) {
// expected-error@-1 {{calling a private constructor}}
// expected-error@-2 {{variable of type 'dr479::S' has private destructor}}
}
}
}
namespace dr480 { // dr480: yes
struct A { int n; };
struct B : A {};
struct C : virtual B {};
struct D : C {};
int A::*a = &A::n;
int D::*b = a; // expected-error {{virtual base}}
extern int D::*c;
int A::*d = static_cast<int A::*>(c); // expected-error {{virtual base}}
D *e;
A *f = e;
D *g = static_cast<D*>(f); // expected-error {{virtual base}}
extern D &i;
A &j = i;
D &k = static_cast<D&>(j); // expected-error {{virtual base}}
}
namespace dr481 { // dr481: yes
template<class T, T U> class A { T *x; };
T *x; // expected-error {{unknown type}}
template<class T *U> class B { T *x; };
T *y; // ok
struct C {
template<class T> void f(class D *p);
};
D *z; // ok
template<typename A = C, typename C = A> struct E {
void f() {
typedef ::dr481::C c; // expected-note {{previous}}
typedef C c; // expected-error {{different type}}
}
};
template struct E<>; // ok
template struct E<int>; // expected-note {{instantiation of}}
template<template<typename U_no_typo_correction> class A,
A<int> *B,
U_no_typo_correction *C> // expected-error {{unknown type}}
struct F {
U_no_typo_correction *x; // expected-error {{unknown type}}
};
template<template<class H *> class> struct G {
H *x;
};
H *q;
typedef int N;
template<N X, typename N, template<N Y> class T> struct I;
template<char*> struct J;
I<123, char*, J> *j;
}
namespace dr482 { // dr482: 3.5
extern int a;
void f();
int dr482::a = 0; // expected-warning {{extra qualification}}
void dr482::f() {} // expected-warning {{extra qualification}}
inline namespace X { // expected-error 0-1{{C++11 feature}}
extern int b;
void g();
struct S;
}
int dr482::b = 0; // expected-warning {{extra qualification}}
void dr482::g() {} // expected-warning {{extra qualification}}
struct dr482::S {}; // expected-warning {{extra qualification}}
void dr482::f(); // expected-warning {{extra qualification}}
void dr482::g(); // expected-warning {{extra qualification}}
// FIXME: The following are valid in DR482's wording, but these are bugs in
// the wording which we deliberately don't implement.
namespace N { typedef int type; }
typedef int N::type; // expected-error {{typedef declarator cannot be qualified}}
struct A {
struct B;
struct A::B {}; // expected-error {{extra qualification}}
#if __cplusplus >= 201103L
enum class C;
enum class A::C {}; // expected-error {{extra qualification}}
#endif
};
}
namespace dr483 { // dr483: yes
namespace climits {
int check1[__SCHAR_MAX__ >= 127 ? 1 : -1];
int check2[__SHRT_MAX__ >= 32767 ? 1 : -1];
int check3[__INT_MAX__ >= 32767 ? 1 : -1];
int check4[__LONG_MAX__ >= 2147483647 ? 1 : -1];
int check5[__LONG_LONG_MAX__ >= 9223372036854775807 ? 1 : -1];
#if __cplusplus < 201103L
// expected-error@-2 {{extension}}
#endif
}
namespace cstdint {
int check1[__PTRDIFF_WIDTH__ >= 16 ? 1 : -1];
int check2[__SIG_ATOMIC_WIDTH__ >= 8 ? 1 : -1];
int check3[__SIZE_WIDTH__ >= 16 ? 1 : -1];
int check4[__WCHAR_WIDTH__ >= 8 ? 1 : -1];
int check5[__WINT_WIDTH__ >= 16 ? 1 : -1];
}
}
namespace dr484 { // dr484: yes
struct A {
A();
void f();
};
typedef const A CA;
void CA::f() {
this->~CA();
this->CA::~A();
this->CA::A::~A();
}
CA::A() {}
struct B : CA {
B() : CA() {}
void f() { return CA::f(); }
};
struct C;
typedef C CT; // expected-note {{here}}
struct CT {}; // expected-error {{conflicts with typedef}}
namespace N {
struct D;
typedef D DT; // expected-note {{here}}
}
struct N::DT {}; // expected-error {{conflicts with typedef}}
typedef struct {
S(); // expected-error {{requires a type}}
} S;
}
namespace dr485 { // dr485: yes
namespace N {
struct S {};
int operator+(S, S);
template<typename T> int f(S);
}
template<typename T> int f();
N::S s;
int a = operator+(s, s);
int b = f<int>(s);
}
namespace dr486 { // dr486: yes
template<typename T> T f(T *); // expected-note 2{{substitution failure}}
int &f(...);
void g();
int n[10];
void h() {
int &a = f(&g);
int &b = f(&n);
f<void()>(&g); // expected-error {{no match}}
f<int[10]>(&n); // expected-error {{no match}}
}
}
namespace dr487 { // dr487: yes
enum E { e };
int operator+(int, E);
int i[4 + e]; // expected-error 2{{variable length array}}
}
namespace dr488 { // dr488: yes c++11
template <typename T> void f(T);
void f(int);
void g() {
// FIXME: It seems CWG thought this should be a SFINAE failure prior to
// allowing local types as template arguments. In C++98, we should either
// allow local types as template arguments or treat this as a SFINAE
// failure.
enum E { e };
f(e);
#if __cplusplus < 201103L
// expected-error@-2 {{local type}}
#endif
}
}
// dr489: na
namespace dr490 { // dr490: yes
template<typename T> struct X {};
struct A {
typedef int T;
struct K {}; // expected-note {{declared}}
int f(T);
int g(T);
int h(X<T>);
int X<T>::*i(); // expected-note {{previous}}
int K::*j();
template<typename T> T k();
operator X<T>();
};
struct B {
typedef char T;
typedef int U;
friend int A::f(T);
friend int A::g(U);
friend int A::h(X<T>);
// FIXME: Per this DR, these two are valid! That is another defect
// (no number yet...) which will eventually supersede this one.
friend int X<T>::*A::i(); // expected-error {{return type}}
friend int K::*A::j(); // expected-error {{undeclared identifier 'K'; did you mean 'A::K'?}}
// ok, lookup finds B::T, not A::T, so return type matches
friend char A::k<T>();
friend int A::k<U>();
// A conversion-type-id in a conversion-function-id is always looked up in
// the class of the conversion function first.
friend A::operator X<T>();
};
}
namespace dr491 { // dr491: dup 413
struct A {} a, b[3] = { a, {} };
A c[2] = { a, {}, b[1] }; // expected-error {{excess elements}}
}
// dr492 FIXME write a codegen test
namespace dr493 { // dr493: dup 976
struct X {
template <class T> operator const T &() const;
};
void f() {
if (X()) {
}
}
}
namespace dr494 { // dr494: dup 372
class A {
class B {};
friend class C;
};
class C : A::B {
A::B x;
class D : A::B {
A::B y;
};
};
}
namespace dr495 { // dr495: 3.5
template<typename T>
struct S {
operator int() { return T::error; }
template<typename U> operator U();
};
S<int> s;
long n = s;
template<typename T>
struct S2 {
template<typename U> operator U();
operator int() { return T::error; }
};
S2<int> s2;
long n2 = s2;
}
namespace dr496 { // dr496: sup 2094
struct A { int n; };
struct B { volatile int n; };
int check1[ __is_trivially_copyable(const int) ? 1 : -1];
// This checks the dr2094 behavior, not dr496
int check2[ __is_trivially_copyable(volatile int) ? 1 : -1];
int check3[ __is_trivially_constructible(A, const A&) ? 1 : -1];
int check4[ __is_trivially_constructible(B, const B&) ? 1 : -1];
int check5[ __is_trivially_assignable(A, const A&) ? 1 : -1];
int check6[ __is_trivially_assignable(B, const B&) ? 1 : -1];
}
namespace dr497 { // dr497: sup 253
void before() {
struct S {
mutable int i;
};
const S cs;
int S::*pm = &S::i;
cs.*pm = 88; // expected-error {{not assignable}}
}
void after() {
struct S {
S() : i(0) {}
mutable int i;
};
const S cs;
int S::*pm = &S::i;
cs.*pm = 88; // expected-error {{not assignable}}
}
}
namespace dr499 { // dr499: yes
extern char str[];
void f() { throw str; }
}