// RUN: %clang_cc1 -std=c++2b -fsyntax-only -verify=expected,cxx20_2b,cxx2b %s
// RUN: %clang_cc1 -std=c++2b -fsyntax-only -verify=expected,cxx20_2b,cxx2b %s -fdelayed-template-parsing -DDELAYED_TEMPLATE_PARSING
// RUN: %clang_cc1 -std=c++20 -fsyntax-only -verify=expected,cxx14_20,cxx20_2b %s
// RUN: %clang_cc1 -std=c++20 -fsyntax-only -verify=expected,cxx14_20,cxx20_2b %s -fdelayed-template-parsing -DDELAYED_TEMPLATE_PARSING
// RUN: %clang_cc1 -std=c++14 -fsyntax-only -verify=expected,cxx14_20,cxx14 %s
// RUN: %clang_cc1 -std=c++14 -fsyntax-only -verify=expected,cxx14_20,cxx14 %s -fdelayed-template-parsing -DDELAYED_TEMPLATE_PARSING
auto f(); // expected-note {{previous}}
int f(); // expected-error {{differ only in their return type}}
auto &g();
auto g() -> auto &;
auto h() -> auto *;
auto *h();
struct Conv1 {
operator auto(); // expected-note {{declared here}}
} conv1;
int conv1a = conv1; // expected-error {{function 'operator auto' with deduced return type cannot be used before it is defined}}
// expected-error@-1 {{no viable conversion}}
Conv1::operator auto() { return 123; }
int conv1b = conv1;
int conv1c = conv1.operator auto();
int conv1d = conv1.operator int(); // expected-error {{no member named 'operator int'}}
struct Conv2 {
operator auto() { return 0; } // expected-note {{previous}}
operator auto() { return 0.; } // expected-error {{cannot be redeclared}}
};
struct Conv3 {
operator auto() { int *p = nullptr; return p; } // expected-note {{candidate}}
operator auto*() { int *p = nullptr; return p; } // expected-note {{candidate}}
} conv3;
int *conv3a = conv3; // expected-error {{ambiguous}}
int *conv3b = conv3.operator auto();
int *conv3c = conv3.operator auto*();
template<typename T>
struct Conv4 {
operator auto() { return T(); }
};
Conv4<int> conv4int;
int conv4a = conv4int;
int conv4b = conv4int.operator auto();
auto a();
auto a() { return 0; }
using T = decltype(a());
using T = int;
auto a(); // expected-note {{previous}}
using T = decltype(a());
auto *a(); // expected-error {{differ only in their return type}}
auto b(bool k) {
if (k)
return "hello";
return "goodbye";
}
// Allow 'operator auto' to call only the explicit operator auto.
struct BothOps {
template <typename T> operator T();
template <typename T> operator T *();
operator auto() { return 0; }
operator auto *() { return this; }
};
struct JustTemplateOp {
template <typename T> operator T();
template <typename T> operator T *();
};
auto c() {
BothOps().operator auto(); // ok
BothOps().operator auto *(); // ok
JustTemplateOp().operator auto(); // expected-error {{no member named 'operator auto' in 'JustTemplateOp'}}
JustTemplateOp().operator auto *(); // expected-error {{no member named 'operator auto *' in 'JustTemplateOp'}}
}
auto *ptr_1() {
return 100; // expected-error {{cannot deduce return type 'auto *' from returned value of type 'int'}}
}
const auto &ref_1() {
return 0; // expected-warning {{returning reference to local temporary}}
}
auto init_list() {
return { 1, 2, 3 }; // expected-error {{cannot deduce return type from initializer list}}
}
auto fwd_decl(); // expected-note 2{{here}}
int n = fwd_decl(); // expected-error {{function 'fwd_decl' with deduced return type cannot be used before it is defined}}
int k = sizeof(fwd_decl()); // expected-error {{used before it is defined}}
auto fac(int n) {
if (n <= 2)
return n;
return n * fac(n-1); // ok
}
auto fac_2(int n) { // expected-note {{declared here}}
if (n > 2)
return n * fac_2(n-1); // expected-error {{cannot be used before it is defined}}
return n;
}
auto void_ret() {}
using Void = void;
using Void = decltype(void_ret());
auto &void_ret_2() {} // expected-error {{cannot deduce return type 'auto &' for function with no return statements}}
const auto void_ret_3() {} // ok, return type 'const void' is adjusted to 'void'
const auto void_ret_4() {
if (false)
return void();
if (false)
return;
return 0; // expected-error {{'auto' in return type deduced as 'int' here but deduced as 'void' in earlier return statement}}
}
namespace Templates {
template<typename T> auto f1() {
return T() + 1;
}
template<typename T> auto &f2(T &&v) { return v; }
// cxx2b-error@-1 {{non-const lvalue reference to type 'int' cannot bind to a temporary of type 'int'}}
// cxx2b-error@-2 {{non-const lvalue reference to type 'double' cannot bind to a temporary of type 'double'}}
// cxx2b-note@-3 {{candidate template ignored: substitution failure [with T = double]}}
int a = f1<int>();
const int &b = f2(0); // cxx2b-note {{in instantiation of function template specialization 'Templates::f2<int>' requested here}}
double d;
float &c = f2(0.0); // expected-error {{non-const lvalue reference to type 'float' cannot bind to a value of unrelated type 'double'}}
// cxx2b-note@-1 {{in instantiation of function template specialization 'Templates::f2<double>' requested here}}
template<typename T> auto fwd_decl(); // expected-note {{declared here}}
int e = fwd_decl<int>(); // expected-error {{cannot be used before it is defined}}
template<typename T> auto fwd_decl() { return 0; }
int f = fwd_decl<int>();
template <typename T>
auto fwd_decl(); // expected-note {{candidate template ignored: could not match 'auto ()' against 'int ()'}}
int g = fwd_decl<char>();
auto (*p)() = f1; // expected-error {{variable 'p' with type 'auto (*)()' has incompatible initializer of type '<overloaded function type>'}}
auto (*q)() = f1<int>; // ok
typedef decltype(f2(1.2)) dbl; // cxx14_20-note {{previous}}
// cxx2b-error@-1 {{no matching function for call to 'f2'}}
typedef float dbl; // cxx14_20-error {{typedef redefinition with different types ('float' vs 'decltype(f2(1.2))' (aka 'double &'))}}
extern template auto fwd_decl<double>();
int k1 = fwd_decl<double>();
extern template int fwd_decl<char>(); // expected-error {{does not refer to a function template}}
int k2 = fwd_decl<char>();
template <typename T> auto instantiate() { T::error; } // expected-error {{has no members}} \
// expected-note {{candidate template ignored: could not match 'auto ()' against 'void ()'}}
extern template auto instantiate<int>(); // ok
int k = instantiate<int>(); // expected-note {{in instantiation of}}
template<> auto instantiate<char>() {} // ok
template<> void instantiate<double>() {} // expected-error {{no function template matches}}
template<typename T> auto arg_single() { return 0; }
template<typename T> auto arg_multi() { return 0l; }
template<typename T> auto arg_multi(int) { return "bad"; }
template<typename T> struct Outer {
static auto arg_single() { return 0.f; }
static auto arg_multi() { return 0.; }
static auto arg_multi(int) { return "bad"; }
};
template<typename T> T &take_fn(T (*p)());
int &check1 = take_fn(arg_single); // expected-error {{no matching}} expected-note@-2 {{couldn't infer}}
int &check2 = take_fn(arg_single<int>);
int &check3 = take_fn<int>(arg_single); // expected-error {{no matching}} expected-note@-4{{no overload of 'arg_single'}}
int &check4 = take_fn<int>(arg_single<int>);
long &check5 = take_fn(arg_multi); // expected-error {{no matching}} expected-note@-6 {{couldn't infer}}
long &check6 = take_fn(arg_multi<int>);
long &check7 = take_fn<long>(arg_multi); // expected-error {{no matching}} expected-note@-8{{no overload of 'arg_multi'}}
long &check8 = take_fn<long>(arg_multi<int>);
float &mem_check1 = take_fn(Outer<int>::arg_single);
float &mem_check2 = take_fn<float>(Outer<char>::arg_single);
double &mem_check3 = take_fn(Outer<long>::arg_multi);
double &mem_check4 = take_fn<double>(Outer<double>::arg_multi);
namespace Deduce1 {
template <typename T> auto f() { return 0; } // expected-note {{couldn't infer template argument 'T'}}
template<typename T> void g(T(*)()); // expected-note 2{{candidate}}
void h() {
auto p = f<int>;
auto (*q)() = f<int>;
int (*r)() = f; // expected-error {{does not match}}
g(f<int>);
g<int>(f); // expected-error {{no matching function}}
g(f); // expected-error {{no matching function}}
}
}
namespace Deduce2 {
template <typename T> auto f(int) { return 0; } // expected-note {{couldn't infer template argument 'T'}}
template<typename T> void g(T(*)(int)); // expected-note 2{{candidate}}
void h() {
auto p = f<int>;
auto (*q)(int) = f<int>;
int (*r)(int) = f; // expected-error {{does not match}}
g(f<int>);
g<int>(f); // expected-error {{no matching function}}
g(f); // expected-error {{no matching function}}
}
}
namespace Deduce3 {
template<typename T> auto f(T) { return 0; }
template<typename T> void g(T(*)(int)); // expected-note {{couldn't infer}}
void h() {
auto p = f<int>;
auto (*q)(int) = f<int>;
int (*r)(int) = f; // ok
g(f<int>);
g<int>(f); // ok
g(f); // expected-error {{no matching function}}
}
}
namespace DeduceInDeducedReturnType {
template<typename T, typename U> auto f() -> auto (T::*)(U) {
int (T::*result)(U) = nullptr;
return result;
}
struct S {};
int (S::*(*p)())(double) = f;
int (S::*(*q)())(double) = f<S, double>;
}
}
auto fwd_decl_using();
namespace N { using ::fwd_decl_using; }
auto fwd_decl_using() { return 0; }
namespace N { int k = N::fwd_decl_using(); }
namespace OverloadResolutionNonTemplate {
auto f();
auto f(int); // expected-note {{here}}
int &g(int (*f)()); // expected-note {{not viable: no overload of 'f' matching 'int (*)()'}}
char &g(int (*f)(int)); // expected-note {{not viable: no overload of 'f' matching 'int (*)(int)'}}
int a = g(f); // expected-error {{no matching function}}
auto f() { return 0; }
// FIXME: It's not completely clear whether this should be ill-formed.
int &b = g(f); // expected-error {{used before it is defined}}
auto f(int) { return 0.0; }
int &c = g(f); // ok
}
namespace OverloadResolutionTemplate {
auto f();
template<typename T> auto f(T);
int &g(int (*f)()); // expected-note {{not viable: no overload of 'f' matching 'int (*)()'}} expected-note {{candidate}}
char &g(int (*f)(int)); // expected-note {{not viable: no overload of 'f' matching 'int (*)(int)'}} expected-note {{candidate}}
int a = g(f); // expected-error {{no matching function}}
auto f() { return 0; }
int &b = g(f); // ok (presumably), due to deduction failure forming type of 'f<int>'
template<typename T> auto f(T) { return 0; }
int &c = g(f); // expected-error {{ambiguous}}
}
namespace DefaultedMethods {
struct A {
auto operator=(const A&) = default; // expected-error {{must return 'DefaultedMethods::A &'}}
A &operator=(A&&); // expected-note {{previous}}
};
auto A::operator=(A&&) = default; // expected-error {{return type of out-of-line definition of 'DefaultedMethods::A::operator=' differs from that in the declaration}}
}
namespace Constexpr {
constexpr auto f1(int n) { return n; }
template<typename T> struct X { constexpr auto f() {} }; // PR18746
template<typename T> struct Y { constexpr T f() {} }; // expected-note {{control reached end of constexpr function}}
void f() {
X<int>().f();
Y<void>().f();
constexpr int q = Y<int>().f(); // expected-error {{must be initialized by a constant expression}} expected-note {{in call to '&Y<int>()->f()'}}
}
struct NonLiteral { ~NonLiteral(); } nl; // cxx14-note {{user-provided destructor}}
// cxx20_2b-note@-1 {{'NonLiteral' is not literal because its destructor is not constexpr}}
constexpr auto f2(int n) { return nl; } // expected-error {{return type 'struct NonLiteral' is not a literal type}}
}
// It's not really clear whether these are valid, but this matches g++.
using size_t = decltype(sizeof(0));
auto operator new(size_t n, const char*); // expected-error {{must return type 'void *'}}
auto operator delete(void *, const char*); // expected-error {{must return type 'void'}}
namespace Virtual {
struct S {
virtual auto f() { return 0; } // expected-error {{function with deduced return type cannot be virtual}} expected-note {{here}}
};
// Allow 'auto' anyway for error recovery.
struct T : S {
int f();
};
struct U : S {
auto f(); // expected-error {{different return}}
};
// And here's why...
struct V { virtual auto f(); }; // expected-error {{cannot be virtual}}
struct W : V { virtual auto f(); }; // expected-error {{cannot be virtual}}
auto V::f() { return 0; } // in tu1.cpp
auto W::f() { return 0.0; } // in tu2.cpp
W w;
int k1 = w.f();
int k2 = ((V&)w).f();
}
namespace std_examples {
namespace NoReturn {
auto f() {}
void (*p)() = &f;
auto f(); // ok
auto *g() {} // expected-error {{cannot deduce return type 'auto *' for function with no return statements}}
auto h() = delete; // expected-note {{explicitly deleted}}
auto x = h(); // expected-error {{call to deleted}}
}
namespace UseBeforeComplete {
auto n = n; // expected-error {{variable 'n' declared with deduced type 'auto' cannot appear in its own initializer}}
auto f(); // expected-note {{declared here}}
void g() { &f; } // expected-error {{function 'f' with deduced return type cannot be used before it is defined}}
auto sum(int i) {
if (i == 1)
return i;
else
return sum(i - 1) + i;
}
}
namespace Redecl {
auto f();
auto f() { return 42; }
auto f(); // expected-note 2{{previous}}
int f(); // expected-error {{functions that differ only in their return type cannot be overloaded}}
decltype(auto) f(); // expected-error {{cannot be overloaded}}
template <typename T> auto g(T t) { return t; } // expected-note {{candidate}} \
// expected-note {{candidate function [with T = int]}}
template auto g(int);
template char g(char); // expected-error {{does not refer to a function}}
template<> auto g(double);
template<typename T> T g(T t) { return t; } // expected-note {{candidate}}
template char g(char);
template auto g(float);
void h() { return g(42); } // expected-error {{ambiguous}}
}
namespace ExplicitInstantiationDecl {
template<typename T> auto f(T t) { return t; }
extern template auto f(int);
int (*p)(int) = f;
}
namespace MemberTemplatesWithDeduction {
struct M {
template<class T> auto foo(T t) { return t; }
template<class T> auto operator()(T t) const { return t; }
template<class T> static __attribute__((unused)) int static_foo(T) {
return 5;
}
template<class T> operator T() { return T{}; }
operator auto() { return &static_foo<int>; }
};
struct N : M {
using M::foo;
using M::operator();
using M::static_foo;
using M::operator auto;
};
template <class T> int test() {
int i = T{}.foo(3);
T m = T{}.foo(M{});
int j = T{}(3);
M m2 = M{}(M{});
int k = T{}.static_foo(4);
int l = T::static_foo(5);
int l2 = T{};
struct X { };
X x = T{};
return 0;
}
int Minst = test<M>();
int Ninst = test<N>();
}
}
// We resolve a wording bug here: 'decltype(auto)' should not be modeled as a
// decltype-specifier, just as a simple-type-specifier. All the extra places
// where a decltype-specifier can appear make no sense for 'decltype(auto)'.
namespace DecltypeAutoShouldNotBeADecltypeSpecifier {
namespace NNS {
int n;
decltype(auto) i();
decltype(n) j();
struct X {
friend decltype(auto) ::DecltypeAutoShouldNotBeADecltypeSpecifier::NNS::i();
friend decltype(n) ::DecltypeAutoShouldNotBeADecltypeSpecifier::NNS::j(); // expected-error {{not a class}}
};
}
namespace Dtor {
struct A {};
void f(A a) { a.~decltype(auto)(); } // expected-error {{'decltype(auto)' not allowed here}}
void g(int i) { i.~decltype(auto)(); } // expected-error {{'decltype(auto)' not allowed here}}
}
namespace BaseClass {
struct A : decltype(auto) {}; // expected-error {{'decltype(auto)' not allowed here}}
struct B {
B() : decltype(auto)() {} // expected-error {{'decltype(auto)' not allowed here}}
};
}
}
namespace CurrentInstantiation {
// PR16875
template<typename T> struct S {
auto f() { return T(); }
int g() { return f(); }
auto h(bool b) {
if (b)
return T();
return h(true);
}
};
int k1 = S<int>().g();
int k2 = S<int>().h(false);
template<typename T> struct U {
#ifndef DELAYED_TEMPLATE_PARSING
auto f(); // expected-note {{here}}
int g() { return f(); } // expected-error {{cannot be used before it is defined}}
#else
auto f();
int g() { return f(); }
#endif
};
#ifndef DELAYED_TEMPLATE_PARSING
template int U<int>::g(); // expected-note {{in instantiation of}}
#else
template int U<int>::g();
#endif
template<typename T> auto U<T>::f() { return T(); }
template int U<short>::g(); // ok
}
namespace WithDefaultArgs {
template<typename U> struct A {
template<typename T = U> friend auto f(A) { return []{}; }
};
template<typename T> void f();
using T = decltype(f(A<int>()));
using T = decltype(f<int>(A<int>()));
}
namespace MultilevelDeduction {
auto F() -> auto* { return (int*)0; }
auto (*G())() -> int* { return F; }
auto run = G();
namespace Templated {
template<class T>
auto F(T t) -> auto* { return (T*)0; }
template<class T>
auto (*G(T t))(T) -> T* { return &F<T>; }
template<class T>
auto (*G2(T t))(T) -> auto* { return &F<T>; }
auto run_int = G(1);
auto run_char = G2('a');
}
}
namespace rnk {
extern "C" int puts(const char *s);
template <typename T>
auto foo(T x) -> decltype(x) {
#ifdef DELAYED_TEMPLATE_PARSING
::rnk::bar();
#endif
return x;
}
void bar() { puts("bar"); }
int main() { return foo(0); }
}
namespace OverloadedOperators {
template<typename T> struct A {
auto operator()() { return T{}; }
auto operator[](int) { return T{}; }
auto operator+(int) { return T{}; }
auto operator+() { return T{}; }
friend auto operator-(A) { return T{}; }
friend auto operator-(A, A) { return T{}; }
};
void f(A<int> a) {
int b = a();
int c = a[0];
int d = a + 0;
int e = +a;
int f = -a;
int g = a - a;
}
}
namespace TrailingReturnTypeForConversionOperator {
struct X {
operator auto() -> int { return 0; } // expected-error {{cannot specify any part of a return type in the declaration of a conversion function; put the complete type after 'operator'}}
} x;
int k = x.operator auto();
struct Y {
operator auto() -> int & { // expected-error {{cannot specify}}
return 0; // expected-error {{cannot bind to}}
}
};
};
namespace PR24989 {
auto x = [](auto){};
using T = decltype(x);
void (T::*p)(int) const = &T::operator();
}
void forinit_decltypeauto() {
for (decltype(auto) forinit_decltypeauto_inner();;) {} // expected-warning {{interpreted as a function}} expected-note {{replace}}
}
namespace PR33222 {
auto f1();
auto f2();
template<typename T> decltype(auto) g0(T x) { return x.n; }
template<typename T> decltype(auto) g1(T);
template<typename T> decltype(auto) g2(T);
struct X {
static auto f1();
static auto f2();
template<typename T> static decltype(auto) g0(T x) { return x.n; }
template<typename T> static decltype(auto) g1(T);
template<typename T> static decltype(auto) g2(T);
};
template<typename U> class A {
friend auto f1();
friend auto f2();
friend decltype(auto) g0<>(A);
template<typename T> friend decltype(auto) g1(T);
template<typename T> friend decltype(auto) g2(T);
friend auto X::f1();
friend auto X::f2();
// FIXME (PR38882): 'A' names the class template not the injected-class-name here!
friend decltype(auto) X::g0<>(A<U>);
// FIXME (PR38882): ::T hides the template parameter if both are named T here!
template<typename T_> friend decltype(auto) X::g1(T_);
template<typename T_> friend decltype(auto) X::g2(T_);
int n;
};
auto f1() { return A<int>().n; }
template<typename T> decltype(auto) g1(T x) { return A<int>().n; }
auto X::f1() { return A<int>().n; }
template<typename T> decltype(auto) X::g1(T x) { return A<int>().n; }
A<int> ai;
int k1 = g0(ai);
int k2 = X::g0(ai);
int k3 = g1(ai);
int k4 = X::g1(ai);
auto f2() { return A<int>().n; }
template<typename T> decltype(auto) g2(T x) { return A<int>().n; }
auto X::f2() { return A<int>().n; }
template<typename T> decltype(auto) X::g2(T x) { return A<int>().n; }
int k5 = g2(ai);
int k6 = X::g2(ai);
template<typename> struct B {
auto *q() { return (float*)0; } // expected-note 2{{previous}}
};
template<> auto *B<char[1]>::q() { return (int*)0; }
template<> auto B<char[2]>::q() { return (int*)0; } // expected-error {{return type}}
template<> int B<char[3]>::q() { return 0; } // expected-error {{return type}}
}
namespace PR46637 {
using A = auto () -> auto; // expected-error {{'auto' not allowed in type alias}}
using B = auto (*)() -> auto; // expected-error {{'auto' not allowed in type alias}}
template<auto (*)() -> auto> struct X {}; // cxx14-error {{'auto' not allowed in template parameter until C++17}}
template<typename T> struct Y { T x; };
Y<auto() -> auto> y; // expected-error {{'auto' not allowed in template argument}}
}