// RUN: %clang_cc1 -fsyntax-only -verify -std=c++20 %s
using size_t = __SIZE_TYPE__;
namespace std {
struct type_info;
}
// floating-point arguments
template<float> struct Float {};
using F1 = Float<1.0f>;
using F1 = Float<2.0f / 2>;
struct S { int n[3]; } s; // expected-note 1+{{here}}
union U { int a, b; } u;
int n; // expected-note 1+{{here}}
// pointers to subobjects
template<int *> struct IntPtr {};
using IPn = IntPtr<&n + 1>;
using IPn = IntPtr<&n + 1>;
using IPn2 = IntPtr<&n + 2>; // expected-error {{not a constant expression}} expected-note {{cannot refer to element 2 of non-array object}}
using IP2 = IntPtr<&s.n[2]>;
using IP2 = IntPtr<s.n + 2>;
using IP3 = IntPtr<&s.n[3]>;
using IP3 = IntPtr<s.n + 3>;
using IP5 = IntPtr<&s.n[5]>; // expected-error {{not a constant expression}} expected-note {{cannot refer to element 5 of array of 3 elements}}
template<int &> struct IntRef {};
using IRn = IntRef<*(&n + 1)>; // expected-error {{not a constant expression}} expected-note {{dereferenced pointer past the end of 'n'}}
using IRn = IntRef<*(&n + 1)>; // expected-error {{not a constant expression}} expected-note {{dereferenced pointer past the end of 'n'}}
using IR2 = IntRef<s.n[2]>;
using IR2 = IntRef<*(s.n + 2)>;
using IR3 = IntRef<s.n[3]>; // expected-error {{not a constant expression}} expected-note {{dereferenced pointer past the end of subobject of 's'}}
using IR3 = IntRef<*(s.n + 3)>; // expected-error {{not a constant expression}} expected-note {{dereferenced pointer past the end of subobject of 's'}}
// classes
template<S> struct Struct {};
using S123 = Struct<S{1, 2, 3}>;
using S123 = Struct<S{1, 2, 3}>; // expected-note {{previous}}
using S123 = Struct<S{1, 2, 4}>; // expected-error {{different types}}
template<U> struct Union {};
using U1 = Union<U{1}>;
using U1 = Union<U{.a = 1}>; // expected-note {{previous}}
using U1 = Union<U{.b = 1}>; // expected-error {{different types}}
// miscellaneous scalar types
template<_Complex int> struct ComplexInt {};
using CI = ComplexInt<1 + 3i>;
using CI = ComplexInt<3i + 1>;
template<_Complex float> struct ComplexFloat {};
using CF = ComplexFloat<1.0f + 3.0fi>;
using CF = ComplexFloat<3.0fi + 1.0f>;
namespace ClassNTTP {
struct A { // expected-note 2{{candidate}}
int x, y;
};
template<A a> constexpr int f() { return a.y; }
static_assert(f<A{1,2}>() == 2);
template<A a> int id; // #ClassNTTP1
constexpr A a = {1, 2};
static_assert(&id<A{1,2}> == &id<a>);
static_assert(&id<A{1,3}> != &id<a>);
int k = id<1>; // expected-error {{no viable conversion from 'int' to 'A'}}
// expected-note@#ClassNTTP1 {{passing argument to parameter 'a' here}}
struct B {
constexpr B() {}
constexpr B(int) = delete; // expected-note {{here}}
};
template<B> struct Q {}; // expected-note {{passing argument to parameter here}}
Q<1> q; // expected-error {{conversion function from 'int' to 'B' invokes a deleted function}}
struct C {
constexpr C() {}
C(const C&) = delete; // expected-note {{here}}
};
template<C> struct R {}; // expected-note {{passing argument to parameter here}}
constexpr C c;
R<c> r; // expected-error {{call to deleted constructor}}
}
namespace ConvertedConstant {
struct A {
constexpr A(float) {}
};
template <A> struct X {};
void f(X<1.0f>) {}
void g(X<2>) {}
struct {
int i : 2;
} b;
template <const int&> struct Y {};
void f(Y<b.i>) {} // expected-error {{reference cannot bind to bit-field in converted constant expression}}
}
namespace CopyCounting {
// Make sure we don't use the copy constructor when transferring the "same"
// template parameter object around.
struct A { int n; constexpr A(int n = 0) : n(n) {} constexpr A(const A &a) : n(a.n+1) {} };
template<A a> struct X {};
template<A a> constexpr int f(X<a> x) { return a.n; }
static_assert(f(X<A{}>()) == 0);
template<A a> struct Y { void f(); };
template<A a> void g(Y<a> y) { y.Y<a>::f(); }
void h() { constexpr A a; g<a>(Y<a>{}); }
template<A a> struct Z {
constexpr int f() {
constexpr A v = a; // this is {a.n+1}
return Z<v>().f() + 1; // this is Z<{a.n+2}>
}
};
template<> struct Z<A{20}> {
constexpr int f() {
return 32;
}
};
static_assert(Z<A{}>().f() == 42);
}
namespace StableAddress {
template<size_t N> struct str {
char arr[N];
};
// FIXME: Deduction guide not needed with P1816R0.
template<size_t N> str(const char (&)[N]) -> str<N>;
template<str s> constexpr int sum() {
int n = 0;
for (char c : s.arr)
n += c;
return n;
}
static_assert(sum<str{"$hello $world."}>() == 1234);
}
namespace TemplateSpecializations {
struct A { int arr[10]; };
template<A> struct X; // expected-note {{here}}
using T = X<A{1, 2, 3}>;
using T = X<A{1, 2, 3, 0}>;
using T = X<A{1, 2, 3, 0, 0}>;
using T = X<A{1, 2, 3, 0, 0, 0}>;
template<> struct X<A{1, 2, 3, 4}> {};
X<A{1, 2, 3, 4, 0}> x;
template<auto V, auto W> constexpr bool Same = false;
template<auto V> constexpr bool Same<V, V> = true;
static_assert(Same<A{}, A{0, 0}>);
static_assert(Same<A{1}, A{1, 0}>);
static_assert(!Same<A{1}, A{1, 1}>);
// We can't directly specialize on member values...
template<int N> // expected-note {{parameter 'N'}}
struct X<A{N, N}> {}; // expected-error {{cannot be deduced}}
// ... but we can fake it up.
// template<int N> struct X<A{N, N}>
template <A V> requires Same<V, A{V.arr[0], V.arr[0]}>
struct X<V> {
static constexpr bool match = true;
};
static_assert(X<A{1, 1}>::match);
static_assert(X<A{2, 2}>::match);
static_assert(X<A{1, 2}>::match); // expected-error {{undefined}}
template<int, A> struct Y; // expected-note {{here}}
template<int N> struct Y<N, A{N, N, N}> {};
Y<1, A{1, 1, 1, 0}> y1;
Y<1, A{1, 1, 1, 1}> y2; // expected-error {{undefined}}
template<A, A> struct Z; // expected-note {{here}}
template<A V> struct Z<V, V> {};
Z<A{1, 2}, A{1, 2, 0}> z1;
Z<A{1, 2}, A{1, 3}> z2; // expected-error {{undefined}}
template struct Z<A{1}, A{1, 0}>;
}
namespace Diags {
struct A { int n, m; };
template<A a> struct X { static_assert(a.n == a.m); }; // expected-error {{static assertion failed due to requirement 'Diags::A{1, 2}.n == Diags::A{1, 2}.m'}} \
// expected-note {{evaluates to '1 == 2'}}
template struct X<A{1, 2}>; // expected-note {{in instantiation of template class 'Diags::X<A{1, 2}>' requested here}}
}
namespace CTADPartialOrder {
template<int> struct A {};
template<typename T, typename U, A a> struct X; // expected-note {{declared here}}
template<typename T, A a> struct X<T, int, a> { static constexpr int n = 1; }; // expected-note {{matches}}
template<typename T, A a> struct X<T *, int, a> { static constexpr int n = 2; };
template<typename T, A a> struct X<T, T, a> { static constexpr int n = 3; }; // expected-note {{matches}}
A<0> a;
static_assert(X<void, int, a>::n == 1);
static_assert(X<int*, int, a>::n == 2);
static_assert(X<void, void, a>::n == 3);
static_assert(X<int, int, a>::n == -1); // expected-error {{ambiguous}}
static_assert(X<int*, void, a>::n == 2); // expected-error {{undefined}}
template<typename T, A<0> a> struct X<T, T, a> { static constexpr int n = 4; };
static_assert(X<float, float, a>::n == 4);
}
namespace UnnamedBitfield {
struct A {
__INT32_TYPE__ : 32;
};
// Make sure we don't distinguish between the unnamed bit-field being
// uninitialized and it being zeroed. Those are not distinct states
// according to [temp.type]p2.
//
// FIXME: We shouldn't track a value for unnamed bit-fields, nor number
// them when computing field indexes.
template <A> struct X {};
constexpr A a;
using T = X<a>;
using T = X<A{}>;
using T = X<(A())>;
// Once we support bit-casts involving bit-fields, this should be valid too.
using T = X<__builtin_bit_cast(A, 0)>; // expected-error {{constant}} expected-note {{not yet supported}}
}
namespace Temporary {
template<const int &> struct A {};
A<0> a0; // expected-error {{conversion from 'int' to 'const int &' in converted constant expression would bind reference to a temporary}}
A<(const int&)1> a1; // expected-error {{reference to temporary object is not allowed in a template argument}}
A<(int&&)2> a2; // expected-error {{reference to temporary object is not allowed in a template argument}}
// FIXME: There's really no good reason to reject these cases.
int &&r3 = 3;
const int &r4 = 4;
A<r3> a3; // expected-error {{reference to temporary object is not allowed in a template argument}}
A<r4> a4; // expected-error {{reference to temporary object is not allowed in a template argument}}
struct X { int a[5]; };
X &&x = X{};
A<x.a[3]> a5; // expected-error {{reference to subobject of temporary object}}
template<const int*> struct B {};
B<&(int&)(int&&)0> b0; // expected-error {{pointer to temporary object}}
B<&r3> b3; // expected-error {{pointer to temporary object}}
B<&x.a[3]> b5; // expected-error {{pointer to subobject of temporary object}}
struct C { const int *p[2]; };
template<C> struct D {};
D<C{nullptr, &r3}> d; // expected-error {{pointer to temporary object}}
}
namespace StringLiteral {
template<decltype(auto)> struct Y {};
Y<&"hello"> y1; // expected-error {{pointer to string literal}}
Y<"hello"> y2; // expected-error {{reference to string literal}}
Y<+"hello"> y3; // expected-error {{pointer to subobject of string literal}}
Y<"hello"[2]> y4; // expected-error {{reference to subobject of string literal}}
struct A { const char *p; };
struct B { const char &r; };
Y<A{"hello"}> y5; // expected-error {{pointer to subobject of string literal}}
Y<B{"hello"[2]}> y6; // expected-error {{reference to subobject of string literal}}
}
namespace TypeInfo {
template<decltype(auto)> struct Y {};
Y<&typeid(int)> y1; // expected-error {{pointer to type_info object}}
Y<typeid(int)> y2; // expected-error {{reference to type_info object}}
struct A { const std::type_info *p; };
struct B { const std::type_info &r; };
Y<A{&typeid(int)}> y3; // expected-error {{pointer to type_info object}}
Y<B{typeid(int)}> y4; // expected-error {{reference to type_info object}}
}
namespace Predefined {
template<decltype(auto)> struct Y {};
struct A { const char *p; };
struct B { const char &r; };
void f() {
// decltype(__func__) is an array, which decays to a pointer parameter.
Y<__func__>(); // expected-error {{pointer to subobject of predefined '__func__' variable}}
Y<__PRETTY_FUNCTION__>(); // expected-error {{pointer to subobject}}
Y<(__func__)>(); // expected-error {{reference to predefined '__func__' variable}}
Y<&__func__>(); // expected-error {{pointer to predefined '__func__' variable}}
Y<*&__func__>(); // expected-error {{reference to predefined '__func__' variable}}
Y<A{__func__}>(); // expected-error {{pointer to subobject of predefined '__func__' variable}}
Y<B{__func__[0]}>(); // expected-error {{reference to subobject of predefined '__func__' variable}}
}
}
namespace DependentCTAD {
template<auto> struct A {};
template<template<typename> typename T, T V> void f(A<V>); // expected-note {{couldn't infer template argument 'T'}}
template<typename T> struct B { constexpr B(T) {} };
void g() {
// PR50039: Note that we could in principle deduce T here, but the language
// deduction rules don't support that.
f(A<B(0)>()); // expected-error {{no matching function}}
f<B>(A<B(0)>()); // OK
}
}
namespace GH48731 {
template <int> using N = int;
struct X { template<typename T> void f(); };
template<int ...Is> decltype((X().f<N<Is>>(), ...)) x;
template<int ...Is> decltype(((new X())->f<N<Is>>(), ...)) y;
struct A {};
template<int> using Tfoo = A;
template<int ...Ns> void foo(A a) {
(a.~Tfoo<Ns>(), ...);
}
struct B { operator int(); };
template<int> using Tbar = int;
template<int ...Ns> void bar(B b) {
(b.operator Tbar<Ns>(), ...);
}
}
namespace ReportedRegression1 {
const char kt[] = "dummy";
template <class T, const char id[]>
class SomeTempl { };
template <const char id[]>
class SomeTempl<int, id> {
public:
int exit_code() const { return 0; }
};
int use() {
SomeTempl<int, kt> dummy;
return dummy.exit_code();
}
}
namespace ReportedRegression2 {
const char str[] = "dummy";
struct S {
S operator+(const char*) const;
};
template <const char* in>
void fn() {
auto s = S{} + in;
}
void use() {
fn<str>();
}
}