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llvm / clang / refs/heads/google/testing / . / test / CXX / drs / dr15xx.cpp
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// RUN: %clang_cc1 -std=c++98 -triple x86_64-unknown-unknown %s -verify -fexceptions -fcxx-exceptions -pedantic-errors
// RUN: %clang_cc1 -std=c++11 -triple x86_64-unknown-unknown %s -verify -fexceptions -fcxx-exceptions -pedantic-errors
// RUN: %clang_cc1 -std=c++14 -triple x86_64-unknown-unknown %s -verify -fexceptions -fcxx-exceptions -pedantic-errors
// RUN: %clang_cc1 -std=c++1z -triple x86_64-unknown-unknown %s -verify -fexceptions -fcxx-exceptions -pedantic-errors
namespace dr1512 { // dr1512: 4
void f(char *p) {
if (p > 0) {} // expected-error {{ordered comparison between pointer and zero}}
#if __cplusplus >= 201103L
if (p > nullptr) {} // expected-error {{invalid operands}}
#endif
}
bool g(int **x, const int **y) {
return x < y;
}
template<typename T> T val();
template<typename A, typename B, typename C> void composite_pointer_type_is_base() {
typedef __typeof(true ? val<A>() : val<B>()) type;
typedef C type;
typedef __typeof(val<A>() == val<B>()) cmp;
typedef __typeof(val<A>() != val<B>()) cmp;
typedef bool cmp;
}
template<typename A, typename B, typename C> void composite_pointer_type_is_ord() {
composite_pointer_type_is_base<A, B, C>();
typedef __typeof(val<A>() < val<B>()) cmp;
typedef __typeof(val<A>() <= val<B>()) cmp;
typedef __typeof(val<A>() > val<B>()) cmp;
typedef __typeof(val<A>() >= val<B>()) cmp;
typedef bool cmp;
}
template <typename A, typename B, typename C>
void composite_pointer_type_is_unord(int = 0) {
composite_pointer_type_is_base<A, B, C>();
}
template <typename A, typename B, typename C>
void composite_pointer_type_is_unord(__typeof(val<A>() < val<B>()) * = 0);
template <typename A, typename B, typename C>
void composite_pointer_type_is_unord(__typeof(val<A>() <= val<B>()) * = 0);
template <typename A, typename B, typename C>
void composite_pointer_type_is_unord(__typeof(val<A>() > val<B>()) * = 0);
template <typename A, typename B, typename C>
void composite_pointer_type_is_unord(__typeof(val<A>() >= val<B>()) * = 0);
// A call to this is ambiguous if a composite pointer type exists.
template<typename A, typename B>
void no_composite_pointer_type(__typeof((true ? val<A>() : val<B>()), void()) * = 0);
template<typename A, typename B> void no_composite_pointer_type(int = 0);
struct A {};
struct B : A {};
struct C {};
void test() {
#if __cplusplus >= 201103L
using nullptr_t = decltype(nullptr);
composite_pointer_type_is_unord<nullptr_t, nullptr_t, nullptr_t>();
no_composite_pointer_type<nullptr_t, int>();
composite_pointer_type_is_unord<nullptr_t, const char**, const char**>();
composite_pointer_type_is_unord<const char**, nullptr_t, const char**>();
#endif
composite_pointer_type_is_ord<const int *, volatile void *, const volatile void*>();
composite_pointer_type_is_ord<const void *, volatile int *, const volatile void*>();
composite_pointer_type_is_ord<const A*, volatile B*, const volatile A*>();
composite_pointer_type_is_ord<const B*, volatile A*, const volatile A*>();
composite_pointer_type_is_unord<const int *A::*, volatile int *B::*, const volatile int *const B::*>();
composite_pointer_type_is_unord<const int *B::*, volatile int *A::*, const volatile int *const B::*>();
no_composite_pointer_type<int (A::*)(), int (C::*)()>();
no_composite_pointer_type<const int (A::*)(), volatile int (C::*)()>();
#if __cplusplus > 201402
composite_pointer_type_is_ord<int (*)() noexcept, int (*)(), int (*)()>();
composite_pointer_type_is_ord<int (*)(), int (*)() noexcept, int (*)()>();
composite_pointer_type_is_unord<int (A::*)() noexcept, int (A::*)(), int (A::*)()>();
composite_pointer_type_is_unord<int (A::*)(), int (A::*)() noexcept, int (A::*)()>();
// FIXME: This looks like a standard defect; these should probably all have type 'int (B::*)()'.
composite_pointer_type_is_unord<int (B::*)(), int (A::*)() noexcept, int (B::*)()>();
composite_pointer_type_is_unord<int (A::*)() noexcept, int (B::*)(), int (B::*)()>();
composite_pointer_type_is_unord<int (B::*)() noexcept, int (A::*)(), int (B::*)()>();
composite_pointer_type_is_unord<int (A::*)(), int (B::*)() noexcept, int (B::*)()>();
// FIXME: It would be reasonable to permit these, with a common type of 'int (*const *)()'.
no_composite_pointer_type<int (**)() noexcept, int (**)()>();
no_composite_pointer_type<int (**)(), int (**)() noexcept>();
// FIXME: It would be reasonable to permit these, with a common type of 'int (A::*)()'.
no_composite_pointer_type<int (A::*)() const, int (A::*)()>();
no_composite_pointer_type<int (A::*)(), int (A::*)() const>();
// FIXME: It would be reasonable to permit these, with a common type of
// 'int (A::*)() &' and 'int (A::*)() &&', respectively.
no_composite_pointer_type<int (A::*)() &, int (A::*)()>();
no_composite_pointer_type<int (A::*)(), int (A::*)() &>();
no_composite_pointer_type<int (A::*)() &&, int (A::*)()>();
no_composite_pointer_type<int (A::*)(), int (A::*)() &&>();
no_composite_pointer_type<int (A::*)() &&, int (A::*)() &>();
no_composite_pointer_type<int (A::*)() &, int (A::*)() &&>();
no_composite_pointer_type<int (C::*)(), int (A::*)() noexcept>();
no_composite_pointer_type<int (A::*)() noexcept, int (C::*)()>();
#endif
}
template<typename T> struct Wrap { operator T(); };
void test_overload() {
#if __cplusplus >= 201103L
using nullptr_t = decltype(nullptr);
void(Wrap<nullptr_t>() == Wrap<nullptr_t>());
void(Wrap<nullptr_t>() != Wrap<nullptr_t>());
void(Wrap<nullptr_t>() < Wrap<nullptr_t>()); // expected-error {{invalid operands}}
void(Wrap<nullptr_t>() > Wrap<nullptr_t>()); // expected-error {{invalid operands}}
void(Wrap<nullptr_t>() <= Wrap<nullptr_t>()); // expected-error {{invalid operands}}
void(Wrap<nullptr_t>() >= Wrap<nullptr_t>()); // expected-error {{invalid operands}}
// The wording change fails to actually disallow this. This is valid
// via the builtin operator<(int*, int*) etc.
void(Wrap<nullptr_t>() == Wrap<int*>());
void(Wrap<nullptr_t>() != Wrap<int*>());
void(Wrap<nullptr_t>() < Wrap<int*>());
void(Wrap<nullptr_t>() > Wrap<int*>());
void(Wrap<nullptr_t>() <= Wrap<int*>());
void(Wrap<nullptr_t>() >= Wrap<int*>());
#endif
}
}
namespace dr1518 { // dr1518: 4
#if __cplusplus >= 201103L
struct Z0 { // expected-note 0+ {{candidate}}
explicit Z0() = default; // expected-note 0+ {{here}}
};
struct Z { // expected-note 0+ {{candidate}}
explicit Z(); // expected-note 0+ {{here}}
explicit Z(int);
explicit Z(int, int); // expected-note 0+ {{here}}
};
template <class T> int Eat(T); // expected-note 0+ {{candidate}}
Z0 a;
Z0 b{};
Z0 c = {}; // expected-error {{explicit in copy-initialization}}
int i = Eat<Z0>({}); // expected-error {{no matching function for call to 'Eat'}}
Z c2 = {}; // expected-error {{explicit in copy-initialization}}
int i2 = Eat<Z>({}); // expected-error {{no matching function for call to 'Eat'}}
Z a1 = 1; // expected-error {{no viable conversion}}
Z a3 = Z(1);
Z a2(1);
Z *p = new Z(1);
Z a4 = (Z)1;
Z a5 = static_cast<Z>(1);
Z a6 = {4, 3}; // expected-error {{explicit in copy-initialization}}
struct UserProvidedBaseCtor { // expected-note 0+ {{candidate}}
UserProvidedBaseCtor() {}
};
struct DoesntInheritCtor : UserProvidedBaseCtor { // expected-note 0+ {{candidate}}
int x;
};
DoesntInheritCtor I{{}, 42};
#if __cplusplus <= 201402L
// expected-error@-2 {{no matching constructor}}
#endif
struct BaseCtor { BaseCtor() = default; }; // expected-note 0+ {{candidate}}
struct InheritsCtor : BaseCtor { // expected-note 1+ {{candidate}}
using BaseCtor::BaseCtor; // expected-note 2 {{inherited here}}
int x;
};
InheritsCtor II = {{}, 42}; // expected-error {{no matching constructor}}
namespace std_example {
struct A {
explicit A() = default; // expected-note 2{{declared here}}
};
struct B : A {
explicit B() = default; // expected-note 2{{declared here}}
};
struct C {
explicit C(); // expected-note 2{{declared here}}
};
struct D : A {
C c;
explicit D() = default; // expected-note 2{{declared here}}
};
template <typename T> void f() {
T t; // ok
T u{}; // ok
T v = {}; // expected-error 4{{explicit}}
}
template <typename T> void g() {
void x(T t); // expected-note 4{{parameter}}
x({}); // expected-error 4{{explicit}}
}
void test() {
f<A>(); // expected-note {{instantiation of}}
f<B>(); // expected-note {{instantiation of}}
f<C>(); // expected-note {{instantiation of}}
f<D>(); // expected-note {{instantiation of}}
g<A>(); // expected-note {{instantiation of}}
g<B>(); // expected-note {{instantiation of}}
g<C>(); // expected-note {{instantiation of}}
g<D>(); // expected-note {{instantiation of}}
}
}
#endif // __cplusplus >= 201103L
}
namespace dr1550 { // dr1550: yes
int f(bool b, int n) {
return (b ? (throw 0) : n) + (b ? n : (throw 0));
}
}
namespace dr1560 { // dr1560: 3.5
void f(bool b, int n) {
(b ? throw 0 : n) = (b ? n : throw 0) = 0;
}
class X { X(const X&); };
const X &get();
const X &x = true ? get() : throw 0;
}
namespace dr1573 { // dr1573: 3.9
#if __cplusplus >= 201103L
// ellipsis is inherited (p0136r1 supersedes this part).
struct A { A(); A(int, char, ...); };
struct B : A { using A::A; };
B b(1, 'x', 4.0, "hello"); // ok
// inherited constructor is effectively constexpr if the user-written constructor would be
struct C { C(); constexpr C(int) {} };
struct D : C { using C::C; };
constexpr D d = D(0); // ok
struct E : C { using C::C; A a; }; // expected-note {{non-literal type}}
constexpr E e = E(0); // expected-error {{non-literal type}}
// FIXME: This diagnostic is pretty bad; we should explain that the problem
// is that F::c would be initialized by a non-constexpr constructor.
struct F : C { using C::C; C c; }; // expected-note {{here}}
constexpr F f = F(0); // expected-error {{constant expression}} expected-note {{constructor inherited from base class 'C'}}
// inherited constructor is effectively deleted if the user-written constructor would be
struct G { G(int); };
struct H : G { using G::G; G g; }; // expected-note {{constructor inherited by 'H' is implicitly deleted because field 'g' has no default constructor}}
H h(0); // expected-error {{constructor inherited by 'H' from base class 'G' is implicitly deleted}}
#endif
}
#if __cplusplus >= 201103L
namespace std {
typedef decltype(sizeof(int)) size_t;
// libc++'s implementation
template <class _E>
class initializer_list
{
const _E* __begin_;
size_t __size_;
initializer_list(const _E* __b, size_t __s)
: __begin_(__b), __size_(__s) {}
public:
typedef _E value_type;
typedef const _E& reference;
typedef const _E& const_reference;
typedef size_t size_type;
typedef const _E* iterator;
typedef const _E* const_iterator;
initializer_list() : __begin_(nullptr), __size_(0) {}
size_t size() const {return __size_;}
const _E* begin() const {return __begin_;}
const _E* end() const {return __begin_ + __size_;}
};
template < class _T1, class _T2 > struct pair { _T2 second; };
template<typename T> struct basic_string {
basic_string(const T* x) {}
~basic_string() {};
};
typedef basic_string<char> string;
} // std
namespace dr1579 { // dr1579: 3.9
template<class T>
struct GenericMoveOnly {
GenericMoveOnly();
template<class U> GenericMoveOnly(const GenericMoveOnly<U> &) = delete; // expected-note 5 {{marked deleted here}}
GenericMoveOnly(const int &) = delete; // expected-note 2 {{marked deleted here}}
template<class U> GenericMoveOnly(GenericMoveOnly<U> &&);
GenericMoveOnly(int &&);
};
GenericMoveOnly<float> DR1579_Eligible(GenericMoveOnly<char> CharMO) {
int i;
GenericMoveOnly<char> GMO;
if (0)
return i;
else if (0)
return GMO;
else if (0)
return ((GMO));
else
return CharMO;
}
GenericMoveOnly<char> GlobalMO;
GenericMoveOnly<float> DR1579_Ineligible(int &AnInt,
GenericMoveOnly<char> &CharMO) {
static GenericMoveOnly<char> StaticMove;
extern GenericMoveOnly<char> ExternMove;
if (0)
return AnInt; // expected-error{{invokes a deleted function}}
else if (0)
return GlobalMO; // expected-error{{invokes a deleted function}}
else if (0)
return StaticMove; // expected-error{{invokes a deleted function}}
else if (0)
return ExternMove; // expected-error{{invokes a deleted function}}
else if (0)
return AnInt; // expected-error{{invokes a deleted function}}
else
return CharMO; // expected-error{{invokes a deleted function}}
}
auto DR1579_lambda_valid = [](GenericMoveOnly<float> mo) ->
GenericMoveOnly<char> {
return mo;
};
auto DR1579_lambda_invalid = []() -> GenericMoveOnly<char> {
static GenericMoveOnly<float> mo;
return mo; // expected-error{{invokes a deleted function}}
};
} // end namespace dr1579
namespace dr1589 { // dr1589: 3.7 c++11
// Ambiguous ranking of list-initialization sequences
void f0(long, int=0); // Would makes selection of #0 ambiguous
void f0(long); // #0
void f0(std::initializer_list<int>); // #00
void g0() { f0({1L}); } // chooses #00
void f1(int, int=0); // Would make selection of #1 ambiguous
void f1(int); // #1
void f1(std::initializer_list<long>); // #2
void g1() { f1({42}); } // chooses #2
void f2(std::pair<const char*, const char*>, int = 0); // Would makes selection of #3 ambiguous
void f2(std::pair<const char*, const char*>); // #3
void f2(std::initializer_list<std::string>); // #4
void g2() { f2({"foo","bar"}); } // chooses #4
namespace with_error {
void f0(long); // #0 expected-note {{candidate function}}
void f0(std::initializer_list<int>); // #00 expected-note {{candidate function}}
void f0(std::initializer_list<int>, int = 0); // Makes selection of #00 ambiguous \
// expected-note {{candidate function}}
void g0() { f0({1L}); } // chooses #00 expected-error{{call to 'f0' is ambiguous}}
void f1(int); // #1 expected-note {{candidate function}}
void f1(std::initializer_list<long>); // #2 expected-note {{candidate function}}
void f1(std::initializer_list<long>, int = 0); // Makes selection of #00 ambiguous \
// expected-note {{candidate function}}
void g1() { f1({42}); } // chooses #2 expected-error{{call to 'f1' is ambiguous}}
void f2(std::pair<const char*, const char*>); // #3 TODO: expected- note {{candidate function}}
void f2(std::initializer_list<std::string>); // #4 expected-note {{candidate function}}
void f2(std::initializer_list<std::string>, int = 0); // Makes selection of #00 ambiguous \
// expected-note {{candidate function}}
void g2() { f2({"foo","bar"}); } // chooses #4 expected-error{{call to 'f2' is ambiguous}}
}
} // dr1589
namespace dr1591 { //dr1591. Deducing array bound and element type from initializer list
template<class T, int N> int h(T const(&)[N]);
int X = h({1,2,3}); // T deduced to int, N deduced to 3
template<class T> int j(T const(&)[3]);
int Y = j({42}); // T deduced to int, array bound not considered
struct Aggr { int i; int j; };
template<int N> int k(Aggr const(&)[N]); //expected-note{{not viable}}
int Y0 = k({1,2,3}); //expected-error{{no matching function}}
int Z = k({{1},{2},{3}}); // OK, N deduced to 3
template<int M, int N> int m(int const(&)[M][N]);
int X0 = m({{1,2},{3,4}}); // M and N both deduced to 2
template<class T, int N> int n(T const(&)[N], T);
int X1 = n({{1},{2},{3}},Aggr()); // OK, T is Aggr, N is 3
namespace check_multi_dim_arrays {
template<class T, int N, int M, int O> int ***f(const T (&a)[N][M][O]); //expected-note{{deduced conflicting values}}
template<class T, int N, int M> int **f(const T (&a)[N][M]); //expected-note{{couldn't infer}}
template<class T, int N> int *f(const T (&a)[N]); //expected-note{{couldn't infer}}
int ***p3 = f({ { {1,2}, {3, 4} }, { {5,6}, {7, 8} }, { {9,10}, {11, 12} } });
int ***p33 = f({ { {1,2}, {3, 4} }, { {5,6}, {7, 8} }, { {9,10}, {11, 12, 13} } }); //expected-error{{no matching}}
int **p2 = f({ {1,2,3}, {3, 4, 5} });
int **p22 = f({ {1,2}, {3, 4} });
int *p1 = f({1, 2, 3});
}
namespace check_multi_dim_arrays_rref {
template<class T, int N, int M, int O> int ***f(T (&&a)[N][M][O]); //expected-note{{deduced conflicting values}}
template<class T, int N, int M> int **f(T (&&a)[N][M]); //expected-note{{couldn't infer}}
template<class T, int N> int *f(T (&&a)[N]); //expected-note{{couldn't infer}}
int ***p3 = f({ { {1,2}, {3, 4} }, { {5,6}, {7, 8} }, { {9,10}, {11, 12} } });
int ***p33 = f({ { {1,2}, {3, 4} }, { {5,6}, {7, 8} }, { {9,10}, {11, 12, 13} } }); //expected-error{{no matching}}
int **p2 = f({ {1,2,3}, {3, 4, 5} });
int **p22 = f({ {1,2}, {3, 4} });
int *p1 = f({1, 2, 3});
}
namespace check_arrays_of_init_list {
template<class T, int N> float *f(const std::initializer_list<T> (&)[N]);
template<class T, int N> double *f(const T(&)[N]);
double *p = f({1, 2, 3});
float *fp = f({{1}, {1, 2}, {1, 2, 3}});
}
namespace core_reflector_28543 {
template<class T, int N> int *f(T (&&)[N]); // #1
template<class T> char *f(std::initializer_list<T> &&); //#2
template<class T, int N, int M> int **f(T (&&)[N][M]); //#3 expected-note{{candidate}}
template<class T, int N> char **f(std::initializer_list<T> (&&)[N]); //#4 expected-note{{candidate}}
template<class T> short *f(T (&&)[2]); //#5
template<class T> using Arr = T[];
char *pc = f({1, 2, 3}); // OK prefer #2 via 13.3.3.2 [over.ics.rank]
char *pc2 = f({1, 2}); // #2 also
int *pi = f(Arr<int>{1, 2, 3}); // OK prefer #1
void *pv1 = f({ {1, 2, 3}, {4, 5, 6} }); // expected-error{{ambiguous}} btw 3 & 4
char **pcc = f({ {1}, {2, 3} }); // OK #4
short *ps = f(Arr<int>{1, 2}); // OK #5
}
} // dr1591
#endif