2009-12-16 04:14:24 +08:00
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// RUN: %clang_cc1 -fsyntax-only -verify %s
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2009-02-12 02:16:40 +08:00
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template<typename T, int N = 2> struct X; // expected-note{{template is declared here}}
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X<int, 1> *x1;
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X<int> *x2;
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Implement parsing of nested-name-specifiers that involve template-ids, e.g.,
std::vector<int>::allocator_type
When we parse a template-id that names a type, it will become either a
template-id annotation (which is a parsed representation of a
template-id that has not yet been through semantic analysis) or a
typename annotation (where semantic analysis has resolved the
template-id to an actual type), depending on the context. We only
produce a type in contexts where we know that we only need type
information, e.g., in a type specifier. Otherwise, we create a
template-id annotation that can later be "upgraded" by transforming it
into a typename annotation when the parser needs a type. This occurs,
for example, when we've parsed "std::vector<int>" above and then see
the '::' after it. However, it means that when writing something like
this:
template<> class Outer::Inner<int> { ... };
We have two tokens to represent Outer::Inner<int>: one token for the
nested name specifier Outer::, and one template-id annotation token
for Inner<int>, which will be passed to semantic analysis to define
the class template specialization.
Most of the churn in the template tests in this patch come from an
improvement in our error recovery from ill-formed template-ids.
llvm-svn: 65467
2009-02-26 03:37:18 +08:00
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X<> *x3; // expected-error{{too few template arguments for class template 'X'}}
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2009-02-12 02:16:40 +08:00
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template<typename U = float, int M> struct X;
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X<> *x4;
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2009-06-05 10:12:32 +08:00
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2009-06-05 10:45:24 +08:00
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template<typename T = int> struct Z { };
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2009-06-05 10:12:32 +08:00
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template struct Z<>;
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2009-06-12 00:06:49 +08:00
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// PR4362
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template<class T> struct a { };
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template<> struct a<int> { static const bool v = true; };
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template<class T, bool = a<T>::v> struct p { }; // expected-error {{no member named 'v'}}
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template struct p<bool>; // expected-note {{in instantiation of default argument for 'p<bool>' required here}}
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template struct p<int>;
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2009-10-15 01:30:58 +08:00
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// PR5187
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template<typename T, typename U>
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struct A;
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template<typename T, typename U = T>
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struct A;
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template<typename T, typename U>
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struct A {
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void f(A<T>);
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};
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template<typename T>
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struct B { };
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template<>
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struct B<void> {
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typedef B<void*> type;
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};
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2009-11-10 03:17:50 +08:00
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// Nested default arguments for template parameters.
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template<typename T> struct X1 { };
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template<typename T>
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struct X2 {
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template<typename U = typename X1<T>::type> // expected-error{{no type named}}
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struct Inner1 { };
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template<T Value = X1<T>::value> // expected-error{{no member named 'value'}}
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struct NonType1 { };
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template<T Value>
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struct Inner2 { };
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template<typename U>
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struct Inner3 {
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template<typename X = T, typename V = U>
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struct VeryInner { };
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template<T Value1 = sizeof(T), T Value2 = sizeof(U),
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T Value3 = Value1 + Value2>
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struct NonType2 { };
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};
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};
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X2<int> x2i;
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X2<int>::Inner1<float> x2iif;
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X2<int>::Inner1<> x2bad; // expected-note{{instantiation of default argument}}
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X2<int>::NonType1<'a'> x2_nontype1;
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X2<int>::NonType1<> x2_nontype1_bad; // expected-note{{instantiation of default argument}}
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// Check multi-level substitution into template type arguments
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X2<int>::Inner3<float>::VeryInner<> vi;
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X2<char>::Inner3<int>::NonType2<> x2_deep_nontype;
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template<typename T, typename U>
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struct is_same { static const bool value = false; };
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template<typename T>
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struct is_same<T, T> { static const bool value = true; };
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2009-11-12 00:39:34 +08:00
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int array1[is_same<__typeof__(vi),
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2009-11-10 03:17:50 +08:00
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X2<int>::Inner3<float>::VeryInner<int, float> >::value? 1 : -1];
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2009-11-12 00:39:34 +08:00
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int array2[is_same<__typeof(x2_deep_nontype),
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X2<char>::Inner3<int>::NonType2<sizeof(char), sizeof(int),
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2009-11-10 03:17:50 +08:00
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sizeof(char)+sizeof(int)> >::value? 1 : -1];
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2009-11-12 00:39:34 +08:00
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// Template template parameter defaults
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template<template<typename T> class X = X2> struct X3 { };
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int array3[is_same<X3<>, X3<X2> >::value? 1 : -1];
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struct add_pointer {
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template<typename T>
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struct apply {
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typedef T* type;
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};
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};
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template<typename T, template<typename> class X = T::template apply>
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struct X4;
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int array4[is_same<X4<add_pointer>,
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X4<add_pointer, add_pointer::apply> >::value? 1 : -1];
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2009-11-12 03:13:48 +08:00
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template<int> struct X5 {}; // expected-note{{has a different type 'int'}}
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template<long> struct X5b {};
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template<typename T,
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template<T> class B = X5> // expected-error{{template template argument has different}} \
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// expected-note{{previous non-type template parameter}}
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struct X6 {};
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X6<int> x6a;
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2009-11-12 05:54:23 +08:00
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X6<long> x6b; // expected-note{{while checking a default template argument}}
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2009-11-12 03:13:48 +08:00
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X6<long, X5b> x6c;
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2009-11-12 08:03:40 +08:00
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template<template<class> class X = B<int> > struct X7; // expected-error{{must be a class template}}
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