forked from OSchip/llvm-project
621 lines
21 KiB
C++
621 lines
21 KiB
C++
// RUN: %clang_cc1 -fsyntax-only -verify -fcxx-exceptions %s
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//
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// Tests for "expression traits" intrinsics such as __is_lvalue_expr.
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//
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// For the time being, these tests are written against the 2003 C++
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// standard (ISO/IEC 14882:2003 -- see draft at
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// http://www.open-std.org/JTC1/SC22/WG21/docs/papers/2001/n1316/).
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//
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// C++0x has its own, more-refined, idea of lvalues and rvalues.
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// If/when we need to support those, we'll need to track both
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// standard documents.
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#if !__has_feature(cxx_static_assert)
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# define CONCAT_(X_, Y_) CONCAT1_(X_, Y_)
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# define CONCAT1_(X_, Y_) X_ ## Y_
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// This emulation can be used multiple times on one line (and thus in
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// a macro), except at class scope
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# define static_assert(b_, m_) \
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typedef int CONCAT_(sa_, __LINE__)[b_ ? 1 : -1]
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#endif
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// Tests are broken down according to section of the C++03 standard
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// (ISO/IEC 14882:2003(E))
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// Assertion macros encoding the following two paragraphs
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//
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// basic.lval/1 Every expression is either an lvalue or an rvalue.
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//
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// expr.prim/5 A parenthesized expression is a primary expression whose type
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// and value are identical to those of the enclosed expression. The
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// presence of parentheses does not affect whether the expression is
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// an lvalue.
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//
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// Note: these asserts cannot be made at class scope in C++03. Put
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// them in a member function instead.
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#define ASSERT_LVALUE(expr) \
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static_assert(__is_lvalue_expr(expr), "should be an lvalue"); \
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static_assert(__is_lvalue_expr((expr)), \
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"the presence of parentheses should have" \
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" no effect on lvalueness (expr.prim/5)"); \
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static_assert(!__is_rvalue_expr(expr), "should be an lvalue"); \
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static_assert(!__is_rvalue_expr((expr)), \
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"the presence of parentheses should have" \
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" no effect on lvalueness (expr.prim/5)")
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#define ASSERT_RVALUE(expr); \
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static_assert(__is_rvalue_expr(expr), "should be an rvalue"); \
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static_assert(__is_rvalue_expr((expr)), \
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"the presence of parentheses should have" \
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" no effect on lvalueness (expr.prim/5)"); \
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static_assert(!__is_lvalue_expr(expr), "should be an rvalue"); \
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static_assert(!__is_lvalue_expr((expr)), \
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"the presence of parentheses should have" \
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" no effect on lvalueness (expr.prim/5)")
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enum Enum { Enumerator };
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int ReturnInt();
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void ReturnVoid();
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Enum ReturnEnum();
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void basic_lval_5()
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{
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// basic.lval/5: The result of calling a function that does not return
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// a reference is an rvalue.
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ASSERT_RVALUE(ReturnInt());
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ASSERT_RVALUE(ReturnVoid());
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ASSERT_RVALUE(ReturnEnum());
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}
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int& ReturnIntReference();
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extern Enum& ReturnEnumReference();
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void basic_lval_6()
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{
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// basic.lval/6: An expression which holds a temporary object resulting
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// from a cast to a nonreference type is an rvalue (this includes
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// the explicit creation of an object using functional notation
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struct IntClass
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{
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explicit IntClass(int = 0);
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IntClass(char const*);
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operator int() const;
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};
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struct ConvertibleToIntClass
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{
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operator IntClass() const;
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};
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ConvertibleToIntClass b;
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// Make sure even trivial conversions are not detected as lvalues
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int intLvalue = 0;
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ASSERT_RVALUE((int)intLvalue);
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ASSERT_RVALUE((short)intLvalue);
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ASSERT_RVALUE((long)intLvalue);
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// Same tests with function-call notation
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ASSERT_RVALUE(int(intLvalue));
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ASSERT_RVALUE(short(intLvalue));
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ASSERT_RVALUE(long(intLvalue));
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char charLValue = 'x';
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ASSERT_RVALUE((signed char)charLValue);
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ASSERT_RVALUE((unsigned char)charLValue);
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ASSERT_RVALUE(static_cast<int>(IntClass()));
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IntClass intClassLValue;
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ASSERT_RVALUE(static_cast<int>(intClassLValue));
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ASSERT_RVALUE(static_cast<IntClass>(ConvertibleToIntClass()));
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ConvertibleToIntClass convertibleToIntClassLValue;
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ASSERT_RVALUE(static_cast<IntClass>(convertibleToIntClassLValue));
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typedef signed char signed_char;
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typedef unsigned char unsigned_char;
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ASSERT_RVALUE(signed_char(charLValue));
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ASSERT_RVALUE(unsigned_char(charLValue));
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ASSERT_RVALUE(int(IntClass()));
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ASSERT_RVALUE(int(intClassLValue));
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ASSERT_RVALUE(IntClass(ConvertibleToIntClass()));
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ASSERT_RVALUE(IntClass(convertibleToIntClassLValue));
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}
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void conv_ptr_1()
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{
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// conv.ptr/1: A null pointer constant is an integral constant
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// expression (5.19) rvalue of integer type that evaluates to
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// zero.
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ASSERT_RVALUE(0);
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}
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void expr_6()
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{
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// expr/6: If an expression initially has the type "reference to T"
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// (8.3.2, 8.5.3), ... the expression is an lvalue.
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int x = 0;
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int& referenceToInt = x;
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ASSERT_LVALUE(referenceToInt);
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ASSERT_LVALUE(ReturnIntReference());
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}
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void expr_prim_2()
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{
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// 5.1/2 A string literal is an lvalue; all other
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// literals are rvalues.
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ASSERT_LVALUE("foo");
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ASSERT_RVALUE(1);
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ASSERT_RVALUE(1.2);
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ASSERT_RVALUE(10UL);
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}
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void expr_prim_3()
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{
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// 5.1/3: The keyword "this" names a pointer to the object for
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// which a nonstatic member function (9.3.2) is invoked. ...The
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// expression is an rvalue.
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struct ThisTest
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{
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void f() { ASSERT_RVALUE(this); }
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};
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}
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extern int variable;
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void Function();
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struct BaseClass
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{
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virtual ~BaseClass();
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int BaseNonstaticMemberFunction();
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static int BaseStaticMemberFunction();
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int baseDataMember;
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};
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struct Class : BaseClass
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{
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static void function();
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static int variable;
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template <class T>
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struct NestedClassTemplate {};
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template <class T>
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static int& NestedFuncTemplate() { return variable; } // expected-note{{possible target for call}}
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template <class T>
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int& NestedMemfunTemplate() { return variable; }
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int operator*() const;
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template <class T>
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int operator+(T) const;
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int NonstaticMemberFunction();
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static int StaticMemberFunction();
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int dataMember;
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int& referenceDataMember;
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static int& staticReferenceDataMember;
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static int staticNonreferenceDataMember;
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enum Enum { Enumerator };
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operator long() const;
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Class();
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Class(int,int);
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void expr_prim_4()
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{
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// 5.1/4: The operator :: followed by an identifier, a
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// qualified-id, or an operator-function-id is a primary-
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// expression. ...The result is an lvalue if the entity is
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// a function or variable.
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ASSERT_LVALUE(::Function); // identifier: function
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ASSERT_LVALUE(::variable); // identifier: variable
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// the only qualified-id form that can start without "::" (and thus
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// be legal after "::" ) is
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//
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// ::<sub>opt</sub> nested-name-specifier template<sub>opt</sub> unqualified-id
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ASSERT_LVALUE(::Class::function); // qualified-id: function
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ASSERT_LVALUE(::Class::variable); // qualified-id: variable
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// The standard doesn't give a clear answer about whether these
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// should really be lvalues or rvalues without some surrounding
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// context that forces them to be interpreted as naming a
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// particular function template specialization (that situation
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// doesn't come up in legal pure C++ programs). This language
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// extension simply rejects them as requiring additional context
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__is_lvalue_expr(::Class::NestedFuncTemplate); // qualified-id: template \
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// expected-error{{reference to overloaded function could not be resolved; did you mean to call it?}}
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__is_lvalue_expr(::Class::NestedMemfunTemplate); // qualified-id: template \
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// expected-error{{reference to non-static member function must be called}}
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__is_lvalue_expr(::Class::operator+); // operator-function-id: template \
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// expected-error{{reference to non-static member function must be called}}
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//ASSERT_RVALUE(::Class::operator*); // operator-function-id: member function
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}
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void expr_prim_7()
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{
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// expr.prim/7 An identifier is an id-expression provided it has been
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// suitably declared (clause 7). [Note: ... ] The type of the
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// expression is the type of the identifier. The result is the
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// entity denoted by the identifier. The result is an lvalue if
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// the entity is a function, variable, or data member... (cont'd)
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ASSERT_LVALUE(Function); // identifier: function
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ASSERT_LVALUE(StaticMemberFunction); // identifier: function
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ASSERT_LVALUE(variable); // identifier: variable
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ASSERT_LVALUE(dataMember); // identifier: data member
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//ASSERT_RVALUE(NonstaticMemberFunction); // identifier: member function
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// (cont'd)...A nested-name-specifier that names a class,
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// optionally followed by the keyword template (14.2), and then
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// followed by the name of a member of either that class (9.2) or
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// one of its base classes... is a qualified-id... The result is
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// the member. The type of the result is the type of the
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// member. The result is an lvalue if the member is a static
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// member function or a data member.
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ASSERT_LVALUE(Class::dataMember);
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ASSERT_LVALUE(Class::StaticMemberFunction);
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//ASSERT_RVALUE(Class::NonstaticMemberFunction); // identifier: member function
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ASSERT_LVALUE(Class::baseDataMember);
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ASSERT_LVALUE(Class::BaseStaticMemberFunction);
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//ASSERT_RVALUE(Class::BaseNonstaticMemberFunction); // identifier: member function
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}
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};
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void expr_call_10()
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{
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// expr.call/10: A function call is an lvalue if and only if the
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// result type is a reference. This statement is partially
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// redundant with basic.lval/5
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basic_lval_5();
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ASSERT_LVALUE(ReturnIntReference());
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ASSERT_LVALUE(ReturnEnumReference());
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}
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namespace Namespace
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{
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int x;
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void function();
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}
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void expr_prim_8()
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{
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// expr.prim/8 A nested-name-specifier that names a namespace
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// (7.3), followed by the name of a member of that namespace (or
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// the name of a member of a namespace made visible by a
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// using-directive ) is a qualified-id; 3.4.3.2 describes name
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// lookup for namespace members that appear in qualified-ids. The
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// result is the member. The type of the result is the type of the
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// member. The result is an lvalue if the member is a function or
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// a variable.
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ASSERT_LVALUE(Namespace::x);
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ASSERT_LVALUE(Namespace::function);
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}
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void expr_sub_1(int* pointer)
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{
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// expr.sub/1 A postfix expression followed by an expression in
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// square brackets is a postfix expression. One of the expressions
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// shall have the type "pointer to T" and the other shall have
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// enumeration or integral type. The result is an lvalue of type
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// "T."
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ASSERT_LVALUE(pointer[1]);
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// The expression E1[E2] is identical (by definition) to *((E1)+(E2)).
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ASSERT_LVALUE(*(pointer+1));
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}
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void expr_type_conv_1()
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{
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// expr.type.conv/1 A simple-type-specifier (7.1.5) followed by a
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// parenthesized expression-list constructs a value of the specified
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// type given the expression list. ... If the expression list
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// specifies more than a single value, the type shall be a class with
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// a suitably declared constructor (8.5, 12.1), and the expression
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// T(x1, x2, ...) is equivalent in effect to the declaration T t(x1,
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// x2, ...); for some invented temporary variable t, with the result
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// being the value of t as an rvalue.
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ASSERT_RVALUE(Class(2,2));
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}
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void expr_type_conv_2()
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{
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// expr.type.conv/2 The expression T(), where T is a
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// simple-type-specifier (7.1.5.2) for a non-array complete object
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// type or the (possibly cv-qualified) void type, creates an
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// rvalue of the specified type,
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ASSERT_RVALUE(int());
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ASSERT_RVALUE(Class());
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ASSERT_RVALUE(void());
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}
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void expr_ref_4()
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{
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// Applies to expressions of the form E1.E2
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// If E2 is declared to have type "reference to T", then E1.E2 is
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// an lvalue;.... Otherwise, one of the following rules applies.
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ASSERT_LVALUE(Class().staticReferenceDataMember);
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ASSERT_LVALUE(Class().referenceDataMember);
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// - If E2 is a static data member, and the type of E2 is T, then
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// E1.E2 is an lvalue; ...
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ASSERT_LVALUE(Class().staticNonreferenceDataMember);
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ASSERT_LVALUE(Class().staticReferenceDataMember);
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// - If E2 is a non-static data member, ... If E1 is an lvalue,
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// then E1.E2 is an lvalue...
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Class lvalue;
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ASSERT_LVALUE(lvalue.dataMember);
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ASSERT_RVALUE(Class().dataMember);
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// - If E1.E2 refers to a static member function, ... then E1.E2
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// is an lvalue
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ASSERT_LVALUE(Class().StaticMemberFunction);
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// - Otherwise, if E1.E2 refers to a non-static member function,
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// then E1.E2 is not an lvalue.
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//ASSERT_RVALUE(Class().NonstaticMemberFunction);
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// - If E2 is a member enumerator, and the type of E2 is T, the
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// expression E1.E2 is not an lvalue. The type of E1.E2 is T.
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ASSERT_RVALUE(Class().Enumerator);
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ASSERT_RVALUE(lvalue.Enumerator);
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}
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void expr_post_incr_1(int x)
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{
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// expr.post.incr/1 The value obtained by applying a postfix ++ is
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// the value that the operand had before applying the
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// operator... The result is an rvalue.
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ASSERT_RVALUE(x++);
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}
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void expr_dynamic_cast_2()
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{
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// expr.dynamic.cast/2: If T is a pointer type, v shall be an
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// rvalue of a pointer to complete class type, and the result is
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// an rvalue of type T.
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Class instance;
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ASSERT_RVALUE(dynamic_cast<Class*>(&instance));
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// If T is a reference type, v shall be an
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// lvalue of a complete class type, and the result is an lvalue of
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// the type referred to by T.
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ASSERT_LVALUE(dynamic_cast<Class&>(instance));
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}
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void expr_dynamic_cast_5()
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{
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// expr.dynamic.cast/5: If T is "reference to cv1 B" and v has type
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// "cv2 D" such that B is a base class of D, the result is an
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// lvalue for the unique B sub-object of the D object referred
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// to by v.
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typedef BaseClass B;
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typedef Class D;
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D object;
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ASSERT_LVALUE(dynamic_cast<B&>(object));
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}
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// expr.dynamic.cast/8: The run-time check logically executes as follows:
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//
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// - If, in the most derived object pointed (referred) to by v, v
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// points (refers) to a public base class subobject of a T object, and
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// if only one object of type T is derived from the sub-object pointed
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// (referred) to by v, the result is a pointer (an lvalue referring)
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// to that T object.
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//
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// - Otherwise, if v points (refers) to a public base class sub-object
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// of the most derived object, and the type of the most derived object
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// has a base class, of type T, that is unambiguous and public, the
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// result is a pointer (an lvalue referring) to the T sub-object of
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// the most derived object.
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//
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// The mention of "lvalue" in the text above appears to be a
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// defect that is being corrected by the response to UK65 (see
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// http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2009/n2841.html).
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#if 0
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void expr_typeid_1()
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{
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// expr.typeid/1: The result of a typeid expression is an lvalue...
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ASSERT_LVALUE(typeid(1));
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}
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#endif
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void expr_static_cast_1(int x)
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{
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// expr.static.cast/1: The result of the expression
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// static_cast<T>(v) is the result of converting the expression v
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// to type T. If T is a reference type, the result is an lvalue;
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// otherwise, the result is an rvalue.
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ASSERT_LVALUE(static_cast<int&>(x));
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ASSERT_RVALUE(static_cast<int>(x));
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}
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void expr_reinterpret_cast_1()
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{
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// expr.reinterpret.cast/1: The result of the expression
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// reinterpret_cast<T>(v) is the result of converting the
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// expression v to type T. If T is a reference type, the result is
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// an lvalue; otherwise, the result is an rvalue
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ASSERT_RVALUE(reinterpret_cast<int*>(0));
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char const v = 0;
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ASSERT_LVALUE(reinterpret_cast<char const&>(v));
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}
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void expr_unary_op_1(int* pointer, struct incomplete* pointerToIncompleteType)
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{
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// expr.unary.op/1: The unary * operator performs indirection: the
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// expression to which it is applied shall be a pointer to an
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// object type, or a pointer to a function type and the result is
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// an lvalue referring to the object or function to which the
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// expression points.
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ASSERT_LVALUE(*pointer);
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ASSERT_LVALUE(*Function);
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// [Note: a pointer to an incomplete type
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// (other than cv void ) can be dereferenced. ]
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ASSERT_LVALUE(*pointerToIncompleteType);
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}
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void expr_pre_incr_1(int operand)
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{
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// expr.pre.incr/1: The operand of prefix ++ ... shall be a
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// modifiable lvalue.... The value is the new value of the
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// operand; it is an lvalue.
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ASSERT_LVALUE(++operand);
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}
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void expr_cast_1(int x)
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{
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// expr.cast/1: The result of the expression (T) cast-expression
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// is of type T. The result is an lvalue if T is a reference type,
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// otherwise the result is an rvalue.
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ASSERT_LVALUE((void(&)())expr_cast_1);
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ASSERT_LVALUE((int&)x);
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ASSERT_RVALUE((void(*)())expr_cast_1);
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ASSERT_RVALUE((int)x);
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|
}
|
|
|
|
void expr_mptr_oper()
|
|
{
|
|
// expr.mptr.oper/6: The result of a .* expression is an lvalue
|
|
// only if its first operand is an lvalue and its second operand
|
|
// is a pointer to data member... (cont'd)
|
|
typedef Class MakeRValue;
|
|
ASSERT_RVALUE(MakeRValue().*(&Class::dataMember));
|
|
//ASSERT_RVALUE(MakeRValue().*(&Class::NonstaticMemberFunction));
|
|
Class lvalue;
|
|
ASSERT_LVALUE(lvalue.*(&Class::dataMember));
|
|
//ASSERT_RVALUE(lvalue.*(&Class::NonstaticMemberFunction));
|
|
|
|
// (cont'd)...The result of an ->* expression is an lvalue only
|
|
// if its second operand is a pointer to data member. If the
|
|
// second operand is the null pointer to member value (4.11), the
|
|
// behavior is undefined.
|
|
ASSERT_LVALUE((&lvalue)->*(&Class::dataMember));
|
|
//ASSERT_RVALUE((&lvalue)->*(&Class::NonstaticMemberFunction));
|
|
}
|
|
|
|
void expr_cond(bool cond)
|
|
{
|
|
// 5.16 Conditional operator [expr.cond]
|
|
//
|
|
// 2 If either the second or the third operand has type (possibly
|
|
// cv-qualified) void, then the lvalue-to-rvalue (4.1),
|
|
// array-to-pointer (4.2), and function-to-pointer (4.3) standard
|
|
// conversions are performed on the second and third operands, and one
|
|
// of the following shall hold:
|
|
//
|
|
// - The second or the third operand (but not both) is a
|
|
// throw-expression (15.1); the result is of the type of the other and
|
|
// is an rvalue.
|
|
|
|
Class classLvalue;
|
|
ASSERT_RVALUE(cond ? throw 1 : (void)0);
|
|
ASSERT_RVALUE(cond ? (void)0 : throw 1);
|
|
ASSERT_RVALUE(cond ? throw 1 : classLvalue);
|
|
ASSERT_RVALUE(cond ? classLvalue : throw 1);
|
|
|
|
// - Both the second and the third operands have type void; the result
|
|
// is of type void and is an rvalue. [Note: this includes the case
|
|
// where both operands are throw-expressions. ]
|
|
ASSERT_RVALUE(cond ? (void)1 : (void)0);
|
|
ASSERT_RVALUE(cond ? throw 1 : throw 0);
|
|
|
|
// expr.cond/4: If the second and third operands are lvalues and
|
|
// have the same type, the result is of that type and is an
|
|
// lvalue.
|
|
ASSERT_LVALUE(cond ? classLvalue : classLvalue);
|
|
int intLvalue = 0;
|
|
ASSERT_LVALUE(cond ? intLvalue : intLvalue);
|
|
|
|
// expr.cond/5:Otherwise, the result is an rvalue.
|
|
typedef Class MakeRValue;
|
|
ASSERT_RVALUE(cond ? MakeRValue() : classLvalue);
|
|
ASSERT_RVALUE(cond ? classLvalue : MakeRValue());
|
|
ASSERT_RVALUE(cond ? MakeRValue() : MakeRValue());
|
|
ASSERT_RVALUE(cond ? classLvalue : intLvalue);
|
|
ASSERT_RVALUE(cond ? intLvalue : int());
|
|
}
|
|
|
|
void expr_ass_1(int x)
|
|
{
|
|
// expr.ass/1: There are several assignment operators, all of
|
|
// which group right-to-left. All require a modifiable lvalue as
|
|
// their left operand, and the type of an assignment expression is
|
|
// that of its left operand. The result of the assignment
|
|
// operation is the value stored in the left operand after the
|
|
// assignment has taken place; the result is an lvalue.
|
|
ASSERT_LVALUE(x = 1);
|
|
ASSERT_LVALUE(x += 1);
|
|
ASSERT_LVALUE(x -= 1);
|
|
ASSERT_LVALUE(x *= 1);
|
|
ASSERT_LVALUE(x /= 1);
|
|
ASSERT_LVALUE(x %= 1);
|
|
ASSERT_LVALUE(x ^= 1);
|
|
ASSERT_LVALUE(x &= 1);
|
|
ASSERT_LVALUE(x |= 1);
|
|
}
|
|
|
|
void expr_comma(int x)
|
|
{
|
|
// expr.comma: A pair of expressions separated by a comma is
|
|
// evaluated left-to-right and the value of the left expression is
|
|
// discarded... result is an lvalue if its right operand is.
|
|
|
|
// Can't use the ASSERT_XXXX macros without adding parens around
|
|
// the comma expression.
|
|
static_assert(__is_lvalue_expr(x,x), "expected an lvalue");
|
|
static_assert(__is_rvalue_expr(x,1), "expected an rvalue");
|
|
static_assert(__is_lvalue_expr(1,x), "expected an lvalue");
|
|
static_assert(__is_rvalue_expr(1,1), "expected an rvalue");
|
|
}
|
|
|
|
#if 0
|
|
template<typename T> void f();
|
|
|
|
// FIXME These currently fail
|
|
void expr_fun_lvalue()
|
|
{
|
|
ASSERT_LVALUE(&f<int>);
|
|
}
|
|
|
|
void expr_fun_rvalue()
|
|
{
|
|
ASSERT_RVALUE(f<int>);
|
|
}
|
|
#endif
|
|
|
|
template <int NonTypeNonReferenceParameter, int& NonTypeReferenceParameter>
|
|
void check_temp_param_6()
|
|
{
|
|
ASSERT_RVALUE(NonTypeNonReferenceParameter);
|
|
ASSERT_LVALUE(NonTypeReferenceParameter);
|
|
}
|
|
|
|
int AnInt = 0;
|
|
|
|
void temp_param_6()
|
|
{
|
|
check_temp_param_6<3,AnInt>();
|
|
}
|