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clang-p2996/clang/test/SemaTemplate/alias-templates.cpp
Richard Smith a6308c0ad9 When performing a substitution into a dependent alias template, mark the 
outer levels as retained rather than omitting their arguments.

This better reflects what's going on (we're performing a substitution
while still inside a template), and in theory is more correct, but I've
not found a testcase where it matters in practice (largely because we
don't allow alias templates to be declared inside a function).

Fixed AST dumping of SubstNonTypeTemplateParm[Pack]Expr to demonstrate
that we're properly substituting through dependent alias templates. (We
can't deduce properly through these yet, but we can at least produce the
right input to template argument deduction.)

No functionality change intended.
2020-06-23 14:43:04 -07:00

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// RUN: %clang_cc1 -std=c++11 -fsyntax-only -verify %s
template<typename S>
struct A {
typedef S B;
template<typename T> using C = typename T::B;
template<typename T> struct D {
template<typename U> using E = typename A<U>::template C<A<T>>;
template<typename U> using F = A<E<U>>;
template<typename U> using G = C<F<U>>;
G<T> g;
};
typedef decltype(D<B>().g) H;
D<H> h;
template<typename T> using I = A<decltype(h.g)>;
template<typename T> using J = typename A<decltype(h.g)>::template C<I<T>>;
};
A<int> a;
A<char>::D<double> b;
template<typename T> T make();
namespace X {
template<typename T> struct traits {
typedef T thing;
typedef decltype(val(make<thing>())) inner_ptr;
template<typename U> using rebind_thing = typename thing::template rebind<U>;
template<typename U> using rebind = traits<rebind_thing<U>>;
inner_ptr &&alloc();
void free(inner_ptr&&);
};
template<typename T> struct ptr_traits {
typedef T *type;
};
template<typename T> using ptr = typename ptr_traits<T>::type;
template<typename T> struct thing {
typedef T inner;
typedef ptr<inner> inner_ptr;
typedef traits<thing<inner>> traits_type;
template<typename U> using rebind = thing<U>;
thing(traits_type &traits) : traits(traits), val(traits.alloc()) {}
~thing() { traits.free(static_cast<inner_ptr&&>(val)); }
traits_type &traits;
inner_ptr val;
friend inner_ptr val(const thing &t) { return t.val; }
};
template<> struct ptr_traits<bool> {
typedef bool &type;
};
template<> bool &traits<thing<bool>>::alloc() { static bool b; return b; }
template<> void traits<thing<bool>>::free(bool&) {}
}
typedef X::traits<X::thing<int>> itt;
itt::thing::traits_type itr;
itt::thing ith(itr);
itt::rebind<bool> btr;
itt::rebind_thing<bool> btt(btr);
namespace PR11848 {
template<typename T> using U = int;
template<typename T, typename ...Ts>
void f1(U<T> i, U<Ts> ...is) { // expected-note 2{{couldn't infer template argument 'T'}}
return i + f1<Ts...>(is...);
}
template<typename ...Ts>
void f2(U<Ts> ...is) { } // expected-note {{deduced incomplete pack <(no value)> for template parameter 'Ts'}}
template<typename...> struct type_tuple {};
template<typename ...Ts>
void f3(type_tuple<Ts...>, U<Ts> ...is) {} // expected-note {{deduced packs of different lengths for parameter 'Ts' (<void, void, void> vs. <(no value), (no value)>)}}
void g() {
f1(U<void>()); // expected-error {{no match}}
f1(1, 2, 3, 4, 5); // expected-error {{no match}}
f2(); // ok
f2(1); // expected-error {{no match}}
f3(type_tuple<>());
f3(type_tuple<void, void, void>(), 1, 2); // expected-error {{no match}}
f3(type_tuple<void, void, void>(), 1, 2, 3);
}
template<typename ...Ts>
struct S {
S(U<Ts>...ts);
};
template<typename T>
struct Hidden1 {
template<typename ...Ts>
Hidden1(typename T::template U<Ts> ...ts);
};
template<typename T, typename ...Ts>
struct Hidden2 {
Hidden2(typename T::template U<Ts> ...ts);
};
struct Hide {
template<typename T> using U = int;
};
Hidden1<Hide> h1;
Hidden2<Hide, double, char> h2(1, 2);
}
namespace Core22036 {
struct X {};
void h(...);
template<typename T> using Y = X;
template<typename T, typename ...Ts> struct S {
// An expression can contain an unexpanded pack without being type or
// value dependent. This is true even if the expression's type is a pack
// expansion type.
void f1(Y<T> a) { h(g(a)); } // expected-error {{undeclared identifier 'g'}}
void f2(Y<Ts>...as) { h(g(as)...); } // expected-error {{undeclared identifier 'g'}}
void f3(Y<Ts>...as) { g(as...); } // ok
void f4(Ts ...ts) { h(g(sizeof(ts))...); } // expected-error {{undeclared identifier 'g'}}
// FIXME: We can reject this, since it has no valid instantiations because
// 'g' never has any associated namespaces.
void f5(Ts ...ts) { g(sizeof(ts)...); } // ok
};
}
namespace PR13243 {
template<typename A> struct X {};
template<int I> struct C {};
template<int I> using Ci = C<I>;
template<typename A, int I> void f(X<A>, Ci<I>) {}
template void f(X<int>, C<0>);
}
namespace PR13136 {
template <typename T, T... Numbers>
struct NumberTuple { };
template <unsigned int... Numbers>
using MyNumberTuple = NumberTuple<unsigned int, Numbers...>;
template <typename U, unsigned int... Numbers>
void foo(U&&, MyNumberTuple<Numbers...>);
template <typename U, unsigned int... Numbers>
void bar(U&&, NumberTuple<unsigned int, Numbers...>);
int main() {
foo(1, NumberTuple<unsigned int, 0, 1>());
bar(1, NumberTuple<unsigned int, 0, 1>());
return 0;
}
}
namespace PR16646 {
namespace test1 {
template <typename T> struct DefaultValue { const T value=0;};
template <typename ... Args> struct tuple {};
template <typename ... Args> using Zero = tuple<DefaultValue<Args> ...>;
template <typename ... Args> void f(const Zero<Args ...> &t);
void f() {
f(Zero<int,double,double>());
}
}
namespace test2 {
template<int x> struct X {};
template <template<int x> class temp> struct DefaultValue { const temp<0> value; };
template <typename ... Args> struct tuple {};
template <template<int x> class... Args> using Zero = tuple<DefaultValue<Args> ...>;
template <template<int x> class... Args> void f(const Zero<Args ...> &t);
void f() {
f(Zero<X,X,X>());
}
}
}
namespace PR16904 {
template <typename,typename>
struct base {
template <typename> struct derived;
};
// FIXME: The diagnostics here are terrible.
template <typename T, typename U, typename V>
using derived = base<T, U>::template derived<V>; // expected-error {{expected a type}} expected-error {{expected ';'}}
template <typename T, typename U, typename V>
using derived2 = ::PR16904::base<T, U>::template derived<V>; // expected-error {{expected a type}} expected-error {{expected ';'}}
}
namespace PR14858 {
template<typename ...T> using X = int[sizeof...(T)];
template<typename ...U> struct Y {
using Z = X<U...>;
};
using A = Y<int, int, int, int>::Z;
using A = int[4];
// FIXME: These should be treated as being redeclarations.
template<typename ...T> void f(X<T...> &) {}
template<typename ...T> void f(int(&)[sizeof...(T)]) {}
template<typename ...T> void g(X<typename T::type...> &) {}
template<typename ...T> void g(int(&)[sizeof...(T)]) {} // ok, different
template<typename ...T, typename ...U> void h(X<T...> &) {}
template<typename ...T, typename ...U> void h(X<U...> &) {} // ok, different
template<typename ...T> void i(auto (T ...t) -> int(&)[sizeof...(t)]);
auto mk_arr(int, int) -> int(&)[2];
void test_i() { i<int, int>(mk_arr); }
#if 0 // FIXME: This causes clang to assert.
template<typename ...T> using Z = auto (T ...p) -> int (&)[sizeof...(p)];
template<typename ...T, typename ...U> void j(Z<T..., U...> &) {}
void test_j() { j<int, int>(mk_arr); }
#endif
template<typename ...T> struct Q {
template<typename ...U> using V = int[sizeof...(U)];
template<typename ...U> void f(V<typename U::type..., typename T::type...> *);
};
struct B { typedef int type; };
void test_q(int (&a)[5]) { Q<B, B, B>().f<B, B>(&a); }
}
namespace redecl {
template<typename> using A = int;
template<typename = void> using A = int;
A<> a; // ok
}
namespace PR31514 {
template<typename T, typename> using EnableTupleSize = T;
template<typename T> struct tuple_size { static const int value = 0; };
template<typename T> struct tuple_size<EnableTupleSize<const T, decltype(tuple_size<T>::value)>> {};
template<typename T> struct tuple_size<EnableTupleSize<volatile T, decltype(tuple_size<T>::value)>> {};
tuple_size<const int> t;
}
namespace an_alias_template_is_not_a_class_template {
template<typename T> using Foo = int; // expected-note 3{{here}}
Foo x; // expected-error {{use of alias template 'Foo' requires template arguments}}
Foo<> y; // expected-error {{too few template arguments for alias template 'Foo'}}
int z = Foo(); // expected-error {{use of alias template 'Foo' requires template arguments}}
template<template<typename> class Bar> void f() { // expected-note 3{{here}}
Bar x; // expected-error {{use of template template parameter 'Bar' requires template arguments}}
Bar<> y; // expected-error {{too few template arguments for template template parameter 'Bar'}}
int z = Bar(); // expected-error {{use of template template parameter 'Bar' requires template arguments}}
}
}
namespace resolved_nttp {
template <typename T> struct A {
template <int N> using Arr = T[N];
Arr<3> a;
};
using TA = decltype(A<int>::a);
using TA = int[3];
template <typename T> struct B {
template <int... N> using Fn = T(int(*...A)[N]);
Fn<1, 2, 3> *p;
};
using TB = decltype(B<int>::p);
using TB = int (*)(int (*)[1], int (*)[2], int (*)[3]);
template <typename T, int ...M> struct C {
template <T... N> using Fn = T(int(*...A)[N]);
Fn<1, M..., 4> *p; // expected-error-re 3{{evaluates to {{[234]}}, which cannot be narrowed to type 'bool'}}
};
using TC = decltype(C<int, 2, 3>::p);
using TC = int (*)(int (*)[1], int (*)[2], int (*)[3], int (*)[4]);
using TC2 = decltype(C<bool, 2, 3>::p); // expected-note {{instantiation of}}
}
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