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hanchenye-llvm-project/clang/test/SemaTemplate/instantiate-expr-4.cpp

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Update tests to use %clang_cc1 instead of 'clang-cc' or 'clang -cc1'. - This is designed to make it obvious that %clang_cc1 is a "test variable" which is substituted. It is '%clang_cc1' instead of '%clang -cc1' because it can be useful to redefine what gets run as 'clang -cc1' (for example, to set a default target). llvm-svn: 91446
2009-12-16 04:14:24 +08:00
// RUN: %clang_cc1 -fsyntax-only -verify %s
Template instantiation for the various kinds of AST nodes that occur due to C++ type construction of the form T(a1, a2, ..., aN). llvm-svn: 72183
2009-05-21 05:38:11 +08:00
// ---------------------------------------------------------------------
// C++ Functional Casts
// ---------------------------------------------------------------------
template<int N>
struct ValueInit0 {
int f() {
return int();
}
};
template struct ValueInit0<5>;
template<int N>
struct FunctionalCast0 {
int f() {
return int(N);
}
};
template struct FunctionalCast0<5>;
Improve the reporting of non-viable overload candidates by noting the reason why the candidate is non-viable. There's a lot we can do to improve this, but it's a good start. Further improvements should probably be integrated with the bad-initialization reporting routines. llvm-svn: 93277
2010-01-13 08:25:19 +08:00
struct X { // expected-note 3 {{candidate constructor (the implicit copy constructor)}}
Improve the diagnostics used to report implicitly-generated class members as parts of overload sets. Also, refer to constructors as 'constructors' rather than functions. Adjust a lot of tests. llvm-svn: 92832
2010-01-06 17:43:14 +08:00
X(int, int); // expected-note 3 {{candidate constructor}}
Template instantiation for the various kinds of AST nodes that occur due to C++ type construction of the form T(a1, a2, ..., aN). llvm-svn: 72183
2009-05-21 05:38:11 +08:00
};
template<int N, int M>
struct BuildTemporary0 {
X f() {
return X(N, M);
}
};
template struct BuildTemporary0<5, 7>;
Template instantiation for CXXExprWithTemporaries, which occurs when temporaries are generated for some object-constructing expressions in templates that are not type-dependent. Also, be sure to introduce the variable from a CXXConditionDeclExpr into the set of instantiated local variables. llvm-svn: 72185
2009-05-21 05:51:01 +08:00
template<int N, int M>
struct Temporaries0 {
void f() {
(void)X(N, M);
}
};
template struct Temporaries0<5, 7>;
Template instantiation for C++ "new" expressions. llvm-svn: 72199
2009-05-21 08:00:09 +08:00
// ---------------------------------------------------------------------
Template instantiation for C++ delete expression llvm-svn: 72216
2009-05-22 01:21:12 +08:00
// new/delete expressions
Template instantiation for C++ "new" expressions. llvm-svn: 72199
2009-05-21 08:00:09 +08:00
// ---------------------------------------------------------------------
struct Y { };
template<typename T>
struct New0 {
T* f(bool x) {
if (x)
return new T; // expected-error{{no matching}}
else
return new T();
}
};
template struct New0<int>;
template struct New0<Y>;
template struct New0<X>; // expected-note{{instantiation}}
template<typename T, typename Arg1>
struct New1 {
T* f(bool x, Arg1 a1) {
return new T(a1); // expected-error{{no matching}}
}
};
template struct New1<int, float>;
template struct New1<Y, Y>;
template struct New1<X, Y>; // expected-note{{instantiation}}
template<typename T, typename Arg1, typename Arg2>
struct New2 {
T* f(bool x, Arg1 a1, Arg2 a2) {
return new T(a1, a2); // expected-error{{no matching}}
}
};
template struct New2<X, int, float>;
template struct New2<X, int, int*>; // expected-note{{instantiation}}
// FIXME: template struct New2<int, int, float>;
Template instantiation for C++ delete expression llvm-svn: 72216
2009-05-22 01:21:12 +08:00
When transforming a C++ "new" expression that was not explicitly given a size, check whether the transformed type is itself an array type. If so, take the major array bound as the size to allocate. Fixes PR5833. llvm-svn: 91907
2009-12-23 01:13:37 +08:00
// PR5833
struct New3 {
New3();
void *operator new[](__SIZE_TYPE__) __attribute__((unavailable)); // expected-note{{explicitly made unavailable}}
};
template<class C>
void* object_creator() {
return new C(); // expected-error{{call to unavailable function 'operator new[]'}}
}
template void *object_creator<New3[4]>(); // expected-note{{instantiation}}
Template instantiation for C++ delete expression llvm-svn: 72216
2009-05-22 01:21:12 +08:00
template<typename T>
struct Delete0 {
void f(T t) {
delete t; // expected-error{{cannot delete}}
::delete [] t;
}
};
template struct Delete0<int*>;
template struct Delete0<X*>;
template struct Delete0<int>; // expected-note{{instantiation}}
Template instantiation for C++ throw expressions llvm-svn: 72217
2009-05-22 01:37:52 +08:00
Rework the way we handle template instantiation for implicitly-generated AST nodes. We previously built instantiated nodes for each of these AST nodes, then passed them on to Sema, which was not prepared to see already-type-checked nodes (see PR5755). In some places, we had ugly workarounds to try to avoid re-type-checking (e.g., in VarDecl initializer instantiation). Now, we skip implicitly-generated nodes when performing instantiation, preferring instead to build just the AST nodes that directly reflect what was written in the source code. This has several advantages: - We don't need to instantiate anything that doesn't have a direct correlation to the source code, so we can have better location information. - Semantic analysis sees the same thing at template instantiation time that it would see for a non-template. - At least one ugly hack (VarDecl initializers) goes away. Fixes PR5755. llvm-svn: 91218
2009-12-13 02:16:41 +08:00
namespace PR5755 {
template <class T>
void Foo() {
char* p = 0;
delete[] p;
}
void Test() {
Foo<int>();
}
}
Template instantiation for C++ throw expressions llvm-svn: 72217
2009-05-22 01:37:52 +08:00
// ---------------------------------------------------------------------
// throw expressions
// ---------------------------------------------------------------------
template<typename T>
struct Throw1 {
void f(T t) {
throw;
throw t; // expected-error{{incomplete type}}
}
};
Diagnose the use of incomplete types in C++ typeid expressions llvm-svn: 92045
2009-12-24 05:06:06 +08:00
struct Incomplete; // expected-note 2{{forward}}
Template instantiation for C++ throw expressions llvm-svn: 72217
2009-05-22 01:37:52 +08:00
template struct Throw1<int>;
template struct Throw1<int*>;
template struct Throw1<Incomplete*>; // expected-note{{instantiation}}
Template instantiation for C++ "typeid" expressions. llvm-svn: 72218
2009-05-22 02:34:44 +08:00
// ---------------------------------------------------------------------
// typeid expressions
// ---------------------------------------------------------------------
namespace std {
class type_info;
}
template<typename T>
struct TypeId0 {
const std::type_info &f(T* ptr) {
if (ptr)
return typeid(ptr);
else
Diagnose the use of incomplete types in C++ typeid expressions llvm-svn: 92045
2009-12-24 05:06:06 +08:00
return typeid(T); // expected-error{{'typeid' of incomplete type 'struct Incomplete'}}
Template instantiation for C++ "typeid" expressions. llvm-svn: 72218
2009-05-22 02:34:44 +08:00
}
};
struct Abstract {
virtual void f() = 0;
};
template struct TypeId0<int>;
Diagnose the use of incomplete types in C++ typeid expressions llvm-svn: 92045
2009-12-24 05:06:06 +08:00
template struct TypeId0<Incomplete>; // expected-note{{instantiation of member function}}
Template instantiation for C++ "typeid" expressions. llvm-svn: 72218
2009-05-22 02:34:44 +08:00
template struct TypeId0<Abstract>;
Template instantiation for unary type traits, e.g., __is_pod llvm-svn: 72220
2009-05-22 02:55:48 +08:00
// ---------------------------------------------------------------------
// type traits
// ---------------------------------------------------------------------
template<typename T>
struct is_pod {
static const bool value = __is_pod(T);
};
Migrate the mish-mash of declaration checks in Sema::ActOnUninitializedDecl over to InitializationSequence (with default initialization), eliminating redundancy. More importantly, we now check that a const definition in C++ has an initilizer, which was an #if 0'd code for many, many months. A few other tweaks were needed to get everything working again: - Fix all of the places in the testsuite where we defined const objects without initializers (now that we diagnose this issue) - Teach instantiation of static data members to find the previous declaration, so that we build proper redeclaration chains. Previously, we had the redeclaration chain but built it too late to be useful, because... - Teach instantiation of static data member definitions not to try to check an initializer if a previous declaration already had an initializer. This makes sure that we don't complain about static const data members with in-class initializers and out-of-line definitions. - Move all of the incomplete-type checking logic out of Sema::FinalizeDeclaratorGroup; it makes more sense in ActOnUnitializedDecl. There may still be a few places where we can improve these diagnostics. I'll address that as a separate commit. llvm-svn: 95657
2010-02-09 15:26:29 +08:00
static int is_pod0[is_pod<X>::value? -1 : 1];
static int is_pod1[is_pod<Y>::value? 1 : -1];
Template instantiation for initializer lists llvm-svn: 72229
2009-05-22 05:38:12 +08:00
// ---------------------------------------------------------------------
// initializer lists
// ---------------------------------------------------------------------
template<typename T, typename Val1>
struct InitList1 {
void f(Val1 val1) {
T x = { val1 };
}
};
struct APair {
int *x;
const float *y;
};
template struct InitList1<int[1], float>;
template struct InitList1<APair, int*>;
template<typename T, typename Val1, typename Val2>
struct InitList2 {
void f(Val1 val1, Val2 val2) {
Use the new init code for member subobjects. llvm-svn: 94329
2010-01-24 04:20:40 +08:00
T x = { val1, val2 }; // expected-error{{cannot initialize}}
Template instantiation for initializer lists llvm-svn: 72229
2009-05-22 05:38:12 +08:00
}
};
template struct InitList2<APair, int*, float*>;
template struct InitList2<APair, int*, double*>; // expected-note{{instantiation}}
Representation of and template instantiation for member expressions. This change introduces another AST node, CXXUnresolvedMemberExpr, that captures member references (x->m, x.m) when the base of the expression (the "x") is type-dependent, and we therefore cannot resolve the member reference yet. Note that our parsing of member references for C++ is still quite poor, e.g., we don't handle x->Base::m or x->operator int. llvm-svn: 72281
2009-05-23 05:13:27 +08:00
// ---------------------------------------------------------------------
// member references
// ---------------------------------------------------------------------
template<typename T, typename Result>
struct DotMemRef0 {
void f(T t) {
Reimplement reference initialization (C++ [dcl.init.ref]) using the new notion of an "initialization sequence", which encapsulates the computation of the initialization sequence along with diagnostic information and the capability to turn the computed sequence into an expression. At present, I've only switched one CheckReferenceInit callers over to this new mechanism; more will follow. Aside from (hopefully) being much more true to the standard, the diagnostics provided by this reference-initialization code are a bit better than before. Some examples: p5-var.cpp:54:12: error: non-const lvalue reference to type 'struct Derived' cannot bind to a value of unrelated type 'struct Base' Derived &dr2 = b; // expected-error{{non-const lvalue reference to ... ^ ~ p5-var.cpp:55:9: error: binding of reference to type 'struct Base' to a value of type 'struct Base const' drops qualifiers Base &br3 = bc; // expected-error{{drops qualifiers}} ^ ~~ p5-var.cpp:57:15: error: ambiguous conversion from derived class 'struct Diamond' to base class 'struct Base': struct Diamond -> struct Derived -> struct Base struct Diamond -> struct Derived2 -> struct Base Base &br5 = diamond; // expected-error{{ambiguous conversion from ... ^~~~~~~ p5-var.cpp:59:9: error: non-const lvalue reference to type 'long' cannot bind to a value of unrelated type 'int' long &lr = i; // expected-error{{non-const lvalue reference to type ... ^ ~ p5-var.cpp:74:9: error: non-const lvalue reference to type 'struct Base' cannot bind to a temporary of type 'struct Base' Base &br1 = Base(); // expected-error{{non-const lvalue reference to ... ^ ~~~~~~ p5-var.cpp:102:9: error: non-const reference cannot bind to bit-field 'i' int & ir1 = (ib.i); // expected-error{{non-const reference cannot ... ^ ~~~~~~ p5-var.cpp:98:7: note: bit-field is declared here int i : 17; // expected-note{{bit-field is declared here}} ^ llvm-svn: 90992
2009-12-10 07:02:17 +08:00
Result result = t.m; // expected-error{{non-const lvalue reference to type}}
Representation of and template instantiation for member expressions. This change introduces another AST node, CXXUnresolvedMemberExpr, that captures member references (x->m, x.m) when the base of the expression (the "x") is type-dependent, and we therefore cannot resolve the member reference yet. Note that our parsing of member references for C++ is still quite poor, e.g., we don't handle x->Base::m or x->operator int. llvm-svn: 72281
2009-05-23 05:13:27 +08:00
}
};
struct MemInt {
int m;
};
struct InheritsMemInt : MemInt { };
struct MemIntFunc {
static int m(int);
};
template struct DotMemRef0<MemInt, int&>;
template struct DotMemRef0<InheritsMemInt, int&>;
template struct DotMemRef0<MemIntFunc, int (*)(int)>;
template struct DotMemRef0<MemInt, float&>; // expected-note{{instantiation}}
template<typename T, typename Result>
struct ArrowMemRef0 {
void f(T t) {
Reimplement reference initialization (C++ [dcl.init.ref]) using the new notion of an "initialization sequence", which encapsulates the computation of the initialization sequence along with diagnostic information and the capability to turn the computed sequence into an expression. At present, I've only switched one CheckReferenceInit callers over to this new mechanism; more will follow. Aside from (hopefully) being much more true to the standard, the diagnostics provided by this reference-initialization code are a bit better than before. Some examples: p5-var.cpp:54:12: error: non-const lvalue reference to type 'struct Derived' cannot bind to a value of unrelated type 'struct Base' Derived &dr2 = b; // expected-error{{non-const lvalue reference to ... ^ ~ p5-var.cpp:55:9: error: binding of reference to type 'struct Base' to a value of type 'struct Base const' drops qualifiers Base &br3 = bc; // expected-error{{drops qualifiers}} ^ ~~ p5-var.cpp:57:15: error: ambiguous conversion from derived class 'struct Diamond' to base class 'struct Base': struct Diamond -> struct Derived -> struct Base struct Diamond -> struct Derived2 -> struct Base Base &br5 = diamond; // expected-error{{ambiguous conversion from ... ^~~~~~~ p5-var.cpp:59:9: error: non-const lvalue reference to type 'long' cannot bind to a value of unrelated type 'int' long &lr = i; // expected-error{{non-const lvalue reference to type ... ^ ~ p5-var.cpp:74:9: error: non-const lvalue reference to type 'struct Base' cannot bind to a temporary of type 'struct Base' Base &br1 = Base(); // expected-error{{non-const lvalue reference to ... ^ ~~~~~~ p5-var.cpp:102:9: error: non-const reference cannot bind to bit-field 'i' int & ir1 = (ib.i); // expected-error{{non-const reference cannot ... ^ ~~~~~~ p5-var.cpp:98:7: note: bit-field is declared here int i : 17; // expected-note{{bit-field is declared here}} ^ llvm-svn: 90992
2009-12-10 07:02:17 +08:00
Result result = t->m; // expected-error 2{{non-const lvalue reference}}
Representation of and template instantiation for member expressions. This change introduces another AST node, CXXUnresolvedMemberExpr, that captures member references (x->m, x.m) when the base of the expression (the "x") is type-dependent, and we therefore cannot resolve the member reference yet. Note that our parsing of member references for C++ is still quite poor, e.g., we don't handle x->Base::m or x->operator int. llvm-svn: 72281
2009-05-23 05:13:27 +08:00
}
};
template<typename T>
struct ArrowWrapper {
T operator->();
};
template struct ArrowMemRef0<MemInt*, int&>;
template struct ArrowMemRef0<InheritsMemInt*, int&>;
template struct ArrowMemRef0<MemIntFunc*, int (*)(int)>;
template struct ArrowMemRef0<MemInt*, float&>; // expected-note{{instantiation}}
template struct ArrowMemRef0<ArrowWrapper<MemInt*>, int&>;
template struct ArrowMemRef0<ArrowWrapper<InheritsMemInt*>, int&>;
template struct ArrowMemRef0<ArrowWrapper<MemIntFunc*>, int (*)(int)>;
template struct ArrowMemRef0<ArrowWrapper<MemInt*>, float&>; // expected-note{{instantiation}}
template struct ArrowMemRef0<ArrowWrapper<ArrowWrapper<MemInt*> >, int&>;
// FIXME: we should be able to return a MemInt without the reference!
MemInt &createMemInt(int);
template<int N>
struct NonDepMemberExpr0 {
void f() {
createMemInt(N).m = N;
}
};
template struct NonDepMemberExpr0<0>;
Add a few tests to ensure that member functions of class templates can call other member functions of class templates, including after template instantiation. No functionality change. llvm-svn: 72282
2009-05-23 05:26:58 +08:00
template<typename T, typename Result>
struct MemberFuncCall0 {
void f(T t) {
Result result = t.f();
}
};
template<typename T>
struct HasMemFunc0 {
T f();
};
template struct MemberFuncCall0<HasMemFunc0<int&>, const int&>;
template<typename Result>
struct ThisMemberFuncCall0 {
Result g();
void f() {
Result r1 = g();
Result r2 = this->g();
}
};
template struct ThisMemberFuncCall0<int&>;
template<typename T>
struct NonDepMemberCall0 {
void foo(HasMemFunc0<int&> x) {
Reimplement reference initialization (C++ [dcl.init.ref]) using the new notion of an "initialization sequence", which encapsulates the computation of the initialization sequence along with diagnostic information and the capability to turn the computed sequence into an expression. At present, I've only switched one CheckReferenceInit callers over to this new mechanism; more will follow. Aside from (hopefully) being much more true to the standard, the diagnostics provided by this reference-initialization code are a bit better than before. Some examples: p5-var.cpp:54:12: error: non-const lvalue reference to type 'struct Derived' cannot bind to a value of unrelated type 'struct Base' Derived &dr2 = b; // expected-error{{non-const lvalue reference to ... ^ ~ p5-var.cpp:55:9: error: binding of reference to type 'struct Base' to a value of type 'struct Base const' drops qualifiers Base &br3 = bc; // expected-error{{drops qualifiers}} ^ ~~ p5-var.cpp:57:15: error: ambiguous conversion from derived class 'struct Diamond' to base class 'struct Base': struct Diamond -> struct Derived -> struct Base struct Diamond -> struct Derived2 -> struct Base Base &br5 = diamond; // expected-error{{ambiguous conversion from ... ^~~~~~~ p5-var.cpp:59:9: error: non-const lvalue reference to type 'long' cannot bind to a value of unrelated type 'int' long &lr = i; // expected-error{{non-const lvalue reference to type ... ^ ~ p5-var.cpp:74:9: error: non-const lvalue reference to type 'struct Base' cannot bind to a temporary of type 'struct Base' Base &br1 = Base(); // expected-error{{non-const lvalue reference to ... ^ ~~~~~~ p5-var.cpp:102:9: error: non-const reference cannot bind to bit-field 'i' int & ir1 = (ib.i); // expected-error{{non-const reference cannot ... ^ ~~~~~~ p5-var.cpp:98:7: note: bit-field is declared here int i : 17; // expected-note{{bit-field is declared here}} ^ llvm-svn: 90992
2009-12-10 07:02:17 +08:00
T result = x.f(); // expected-error{{non-const lvalue reference}}
Add a few tests to ensure that member functions of class templates can call other member functions of class templates, including after template instantiation. No functionality change. llvm-svn: 72282
2009-05-23 05:26:58 +08:00
}
};
template struct NonDepMemberCall0<int&>;
template struct NonDepMemberCall0<const int&>;
template struct NonDepMemberCall0<float&>; // expected-note{{instantiation}}
Template instantiation for qualified declaration reference expressions. We are now missing template instantiation logic for only three classes of expressions: - Blocks-related expressions (BlockExpr, BlockDeclRefExpr) - C++ default argument expressions - Objective-C expressions Additionally, our handling of DeclRefExpr is still quite poor, since it cannot handle references to many kinds of declarations. As part of this change, converted the TemplateExprInstantiator to use iteration through all of the expressions via clang/AST/StmtNodes.def, ensuring that we don't forget to add template instantiation logic for any new expression node kinds. llvm-svn: 72303
2009-05-23 07:47:06 +08:00
template<typename T>
struct QualifiedDeclRef0 {
T f() {
Switch the initialization required by return statements over to the new InitializationSequence. This fixes some bugs (e.g., PR5808), changed some diagnostics, and caused more churn than expected. What's new: - InitializationSequence now has a "C conversion sequence" category and step kind, which falls back to - Changed the diagnostics for returns to always have the result type of the function first and the type of the expression second. CheckSingleAssignmentConstraints to peform checking in C. - Improved ASTs for initialization of return values. The ASTs now capture all of the temporaries we need to create, but intentionally do not bind the tempoary that is actually returned, so that it won't get destroyed twice. - Make sure to perform an (elidable!) copy of the class object that is returned from a class. - Fix copy elision in CodeGen to properly see through the subexpressions that occur with elidable copies. - Give "new" its own entity kind; as with return values and thrown objects, we don't bind the expression so we don't call a destructor for it. Note that, with this patch, I've broken returning move-only types in C++0x. We'll fix it later, when we tackle NRVO. llvm-svn: 91669
2009-12-18 13:02:21 +08:00
return is_pod<X>::value; // expected-error{{non-const lvalue reference to type 'int' cannot bind to a value of unrelated type 'bool const'}}
Template instantiation for qualified declaration reference expressions. We are now missing template instantiation logic for only three classes of expressions: - Blocks-related expressions (BlockExpr, BlockDeclRefExpr) - C++ default argument expressions - Objective-C expressions Additionally, our handling of DeclRefExpr is still quite poor, since it cannot handle references to many kinds of declarations. As part of this change, converted the TemplateExprInstantiator to use iteration through all of the expressions via clang/AST/StmtNodes.def, ensuring that we don't forget to add template instantiation logic for any new expression node kinds. llvm-svn: 72303
2009-05-23 07:47:06 +08:00
}
};
template struct QualifiedDeclRef0<bool>;
template struct QualifiedDeclRef0<int&>; // expected-note{{instantiation}}