Files
clang-p2996/clang/test/SemaTemplate/constructor-template.cpp
John McCall 578a1f8c6d If a non-template constructor instantiated to X(X),
ignore it during overload resolution when initializing
X from a value of type cv X.

Previously, our rule here only ignored specializations
of constructor templates.  That's probably because the
standard says that constructors are outright ill-formed
if their first parameter is literally X and they're
callable with one argument.  However, Clang only
enforces that prohibition against non-implicit
instantiations; I'm not sure why, but it seems to be
deliberate.  Given that, the most sensible thing to
do is to just ignore the "illegal" constructor
regardless of where it came from.

Also, stop ignoring such constructors silently:
print a note explaining why they're being ignored.

Fixes <rdar://19199836>.

llvm-svn: 224205
2014-12-14 01:46:53 +00:00

177 lines
3.5 KiB
C++

// RUN: %clang_cc1 -fsyntax-only -verify %s
struct X0 { // expected-note{{candidate}}
X0(int); // expected-note{{candidate}}
template<typename T> X0(T); // expected-note {{candidate}}
template<typename T, typename U> X0(T*, U*); // expected-note {{candidate}}
// PR4761
template<typename T> X0() : f0(T::foo) {} // expected-note {{candidate}}
int f0;
};
void accept_X0(X0);
void test_X0(int i, float f) {
X0 x0a(i);
X0 x0b(f);
X0 x0c = i;
X0 x0d = f;
accept_X0(i);
accept_X0(&i);
accept_X0(f);
accept_X0(&f);
X0 x0e(&i, &f);
X0 x0f(&f, &i);
X0 x0g(f, &i); // expected-error{{no matching constructor}}
}
template<typename T>
struct X1 {
X1(const X1&);
template<typename U> X1(const X1<U>&);
};
template<typename T>
struct Outer {
typedef X1<T> A;
A alloc;
explicit Outer(const A& a) : alloc(a) { }
};
void test_X1(X1<int> xi) {
Outer<int> oi(xi);
Outer<float> of(xi);
}
// PR4655
template<class C> struct A {};
template <> struct A<int>{A(const A<int>&);};
struct B { A<int> x; B(B& a) : x(a.x) {} };
struct X2 {
X2(); // expected-note{{candidate constructor}}
X2(X2&); // expected-note {{candidate constructor}}
template<typename T> X2(T); // expected-note {{candidate template ignored: instantiation would take its own class type by value}}
};
X2 test(bool Cond, X2 x2) {
if (Cond)
return x2; // okay, uses copy constructor
return X2(); // expected-error{{no matching constructor}}
}
struct X3 {
template<typename T> X3(T);
};
template<> X3::X3(X3); // expected-error{{must pass its first argument by reference}}
struct X4 {
X4();
~X4();
X4(X4&);
template<typename T> X4(const T&, int = 17);
};
X4 test_X4(bool Cond, X4 x4) {
X4 a(x4, 17); // okay, constructor template
X4 b(x4); // okay, copy constructor
return X4();
}
// Instantiation of a non-dependent use of a constructor
struct DefaultCtorHasDefaultArg {
explicit DefaultCtorHasDefaultArg(int i = 17);
};
template<typename T>
void default_ctor_inst() {
DefaultCtorHasDefaultArg def;
}
template void default_ctor_inst<int>();
template<typename T>
struct X5 {
X5();
X5(const T &);
};
struct X6 {
template<typename T> X6(T);
};
void test_X5_X6() {
X5<X6> tf;
X5<X6> tf2(tf);
}
namespace PR8182 {
struct foo {
foo();
template<class T> foo(T&);
private:
foo(const foo&);
};
void test_foo() {
foo f1;
foo f2(f1);
foo f3 = f1;
}
}
// Don't blow out the stack trying to call an illegal constructor
// instantiation. We intentionally allow implicit instantiations to
// exist, so make sure they're unusable.
//
// rdar://19199836
namespace self_by_value {
template <class T, class U> struct A {
A() {}
A(const A<T,U> &o) {}
A(A<T,T> o) {}
};
void helper(A<int,float>);
void test1(A<int,int> a) {
helper(a);
}
void test2() {
helper(A<int,int>());
}
}
namespace self_by_value_2 {
template <class T, class U> struct A {
A() {} // expected-note {{not viable: requires 0 arguments}}
A(A<T,U> &o) {} // expected-note {{not viable: expects an l-value}}
A(A<T,T> o) {} // expected-note {{ignored: instantiation takes its own class type by value}}
};
void helper_A(A<int,int>); // expected-note {{passing argument to parameter here}}
void test_A() {
helper_A(A<int,int>()); // expected-error {{no matching constructor}}
}
}
namespace self_by_value_3 {
template <class T, class U> struct A {
A() {}
A(A<T,U> &o) {}
A(A<T,T> o) {}
};
void helper_A(A<int,int>);
void test_A(A<int,int> b) {
helper_A(b);
}
}