llvm-project/clang/test/SemaTemplate/friend-template.cpp
John McCall e68672fed2 Flag that friend function definitions are "late parsed" so that
template instantiation will still consider them to be definitions
if we instantiate the containing class before we get around
to parsing the friend.

This seems like a legitimate use of "late template parsed" to me,
but I'd appreciate it if someone responsible for the MS feature
would look over this.

This file already appears to access AST nodes directly, which
is arguably not kosher in the parser, but the performance of this
path matters enough that perpetuating the sin is justifiable.
Probably we ought to reconsider this policy for very simple
manipulations like this.

The reason this entire thing is necessary is that
function template instantiation plays some very gross games
in order to not associate an instantiated function template
with the class it came from unless it's a definition, and
the reason *that's* necessary is that the AST currently
cannot represent the instantiation history of individual
function template declarations, but instead tracks it in
common for the entire function template.  That probably
prevents us from correctly reporting ill-formed calls to
ambiguously instantiated friend function templates.

rdar://12350696

llvm-svn: 177003
2013-03-14 05:13:41 +00:00

325 lines
7.1 KiB
C++

// RUN: %clang_cc1 -fsyntax-only -verify %s
// PR5057
namespace test0 {
namespace std {
class X {
public:
template<typename T> friend struct Y;
};
}
namespace std {
template<typename T> struct Y {};
}
}
namespace test1 {
template<typename T> void f1(T) { } // expected-note{{here}}
class X {
template<typename T> friend void f0(T);
template<typename T> friend void f1(T);
};
template<typename T> void f0(T) { }
template<typename T> void f1(T) { } // expected-error{{redefinition}}
}
// PR4768
namespace test2 {
template<typename T> struct X0 {
template<typename U> friend struct X0;
};
template<typename T> struct X0<T*> {
template<typename U> friend struct X0;
};
template<> struct X0<int> {
template<typename U> friend struct X0;
};
template<typename T> struct X1 {
template<typename U> friend void f2(U);
template<typename U> friend void f3(U);
};
template<typename U> void f2(U);
X1<int> x1i;
X0<int*> x0ip;
template<> void f2(int);
// FIXME: Should this declaration of f3 be required for the specialization of
// f3<int> (further below) to work? GCC and EDG don't require it, we do...
template<typename U> void f3(U);
template<> void f3(int);
}
// PR5332
namespace test3 {
template <typename T> class Foo {
template <typename U>
friend class Foo;
};
Foo<int> foo;
template<typename T, T Value> struct X2a;
template<typename T, int Size> struct X2b;
template<typename T>
class X3 {
template<typename U, U Value> friend struct X2a;
// FIXME: the redeclaration note ends up here because redeclaration
// lookup ends up finding the friend target from X3<int>.
template<typename U, T Value> friend struct X2b; // expected-error {{template non-type parameter has a different type 'long' in template redeclaration}} \
// expected-note {{previous non-type template parameter with type 'int' is here}}
};
X3<int> x3i; // okay
X3<long> x3l; // expected-note {{in instantiation}}
}
// PR5716
namespace test4 {
template<typename> struct A {
template<typename T> friend void f(const A<T>&);
};
template<typename T> void f(const A<T>&) {
int a[sizeof(T) ? -1 : -1]; // expected-error {{array with a negative size}}
}
void f() {
f(A<int>()); // expected-note {{in instantiation of function template specialization}}
}
}
namespace test5 {
class outer {
class foo;
template <typename T> friend struct cache;
};
class outer::foo {
template <typename T> friend struct cache;
};
}
// PR6022
namespace PR6022 {
template <class T1, class T2 , class T3 > class A;
namespace inner {
template<class T1, class T2, class T3, class T>
A<T1, T2, T3>& f0(A<T1, T2, T3>&, T);
}
template<class T1, class T2, class T3>
class A {
template<class U1, class U2, class U3, class T>
friend A<U1, U2, U3>& inner::f0(A<U1, U2, U3>&, T);
};
}
namespace FriendTemplateDefinition {
template<unsigned > struct int_c { };
template<typename T>
struct X {
template<unsigned N>
friend void f(X, int_c<N>) {
int value = N;
};
};
void test_X(X<int> x, int_c<5> i5) {
f(x, i5);
}
}
namespace PR7013a {
template<class > struct X0
{
typedef int type;
};
template<typename > struct X1
{
};
template<typename , typename T> struct X2
{
typename T::type e;
};
namespace N
{
template <typename = int, typename = X1<int> > struct X3
{
template <typename T1, typename T2, typename B> friend void op(X2<T1, T2>& , B);
};
template <typename Ch, typename Tr, typename B> void op(X2<Ch, Tr>& , B)
{
X2<int, Tr> s;
}
}
int n()
{
X2<int, X0<int> > ngs;
N::X3<> b;
op(ngs, b);
return 0;
}
}
namespace PR7013b {
template<class > struct X0
{
typedef int type;
};
template<typename > struct X1
{
};
template<typename , typename T> struct X2
{
typename T::type e;
};
namespace N
{
template <typename = X1<int> > struct X3
{
template <typename T1, typename T2, typename B> friend void op(X2<T1, T2>& , B);
};
template <typename Ch, typename Tr, typename B> void op(X2<Ch, Tr>& , B)
{
X2<int, Tr> s;
}
}
int n()
{
X2<int, X0<int> > ngs;
N::X3<> b;
op(ngs, b);
return 0;
}
}
namespace PR8649 {
template<typename T, typename U, unsigned N>
struct X {
template<unsigned M> friend class X<T, U, M>; // expected-error{{partial specialization cannot be declared as a friend}}
};
X<int, float, 7> x;
}
// Don't crash, and error on invalid friend type template.
namespace friend_type_template_no_tag {
template <typename T> struct S {
template <typename U> friend S<U>; // expected-error{{friend type templates must use an elaborated type}}
};
template struct S<int>;
}
namespace PR10660 {
struct A {
template <> friend class B; // expected-error{{extraneous 'template<>' in declaration of class 'B'}}
};
}
namespace rdar11147355 {
template <class T>
struct A {
template <class U> class B;
template <class S> template <class U> friend class A<S>::B;
};
template <class S> template <class U> class A<S>::B {
};
A<double>::B<double> ab;
}
namespace RedeclUnrelated {
struct S {
int packaged_task;
template<typename> class future {
template<typename> friend class packaged_task;
};
future<void> share;
};
}
namespace PR12557 {
template <typename>
struct Foo;
template <typename Foo_>
struct Bar {
typedef Foo_ Foo; // expected-note {{previous}}
template <typename> friend struct Foo; // expected-error {{redefinition of 'Foo' as different kind of symbol}}
};
Bar<int> b;
}
namespace PR12585 {
struct A { };
template<typename> struct B {
template<typename> friend class A::does_not_exist; // \
// expected-error {{friend declaration of 'does_not_exist' does not match any declaration in 'PR12585::A'}}
};
struct C {
template<typename> struct D;
};
template<typename> class E {
int n;
template<typename> friend struct C::D;
};
template<typename T> struct C::D {
int f() {
return E<int>().n;
}
};
int n = C::D<void*>().f();
struct F {
template<int> struct G;
};
template<typename T> struct H {
// FIXME: As with cases above, the note here is on an unhelpful declaration,
// and should point to the declaration of G within F.
template<T> friend struct F::G; // \
// expected-error {{different type 'char' in template redeclaration}} \
// expected-note {{previous}}
};
H<int> h1; // ok
H<char> h2; // expected-note {{instantiation}}
}
// Ensure that we can still instantiate a friend function template
// after the friend declaration is instantiated during the delayed
// parsing of a member function, but before the friend function has
// been parsed.
namespace rdar12350696 {
template <class T> struct A {
void foo() {
A<int> a;
}
template <class U> friend void foo(const A<U> & a) {
int array[sizeof(T) == sizeof(U) ? -1 : 1]; // expected-error {{negative size}}
}
};
void test() {
A<int> b;
foo(b); // expected-note {{in instantiation}}
}
}