// RUN: %clang_cc1 -fsyntax-only -verify %s -triple=i686-pc-linux-gnu -Wno-new-returns-null #include <stddef.h> struct S // expected-note {{candidate}} { S(int, int, double); // expected-note {{candidate}} S(double, int); // expected-note 2 {{candidate}} S(float, int); // expected-note 2 {{candidate}} }; struct T; // expected-note{{forward declaration of 'T'}} struct U { // A special new, to verify that the global version isn't used. void* operator new(size_t, S*); // expected-note {{candidate}} }; struct V : U { }; inline void operator delete(void *); // expected-warning {{replacement function 'operator delete' cannot be declared 'inline'}} __attribute__((used)) inline void *operator new(size_t) { // no warning, due to __attribute__((used)) return 0; } // PR5823 void* operator new(const size_t); // expected-note 2 {{candidate}} void* operator new(size_t, int*); // expected-note 3 {{candidate}} void* operator new(size_t, float*); // expected-note 3 {{candidate}} void* operator new(size_t, S); // expected-note 2 {{candidate}} struct foo { }; void good_news() { int *pi = new int; float *pf = new (pi) float(); pi = new int(1); pi = new int('c'); const int *pci = new const int(); S *ps = new S(1, 2, 3.4); ps = new (pf) (S)(1, 2, 3.4); S *(*paps)[2] = new S*[*pi][2]; typedef int ia4[4]; ia4 *pai = new (int[3][4]); pi = ::new int; U *pu = new (ps) U; V *pv = new (ps) V; pi = new (S(1.0f, 2)) int; (void)new int[true]; // PR7147 typedef int a[2]; foo* f1 = new foo; foo* f2 = new foo[2]; typedef foo x[2]; typedef foo y[2][2]; x* f3 = new y; } struct abstract { virtual ~abstract() = 0; }; void bad_news(int *ip) { int i = 1; // expected-note 2{{here}} (void)new; // expected-error {{expected a type}} (void)new 4; // expected-error {{expected a type}} (void)new () int; // expected-error {{expected expression}} (void)new int[1.1]; // expected-error {{array size expression must have integral or enumeration type, not 'double'}} (void)new int[1][i]; // expected-error {{only the first dimension}} expected-note {{read of non-const variable 'i' is not allowed in a constant expression}} (void)new (int[1][i]); // expected-error {{only the first dimension}} expected-note {{read of non-const variable 'i' is not allowed in a constant expression}} (void)new (int[i]); // expected-warning {{when type is in parentheses}} (void)new int(*(S*)0); // expected-error {{no viable conversion from 'S' to 'int'}} (void)new int(1, 2); // expected-error {{excess elements in scalar initializer}} (void)new S(1); // expected-error {{no matching constructor}} (void)new S(1, 1); // expected-error {{call to constructor of 'S' is ambiguous}} (void)new const int; // expected-error {{default initialization of an object of const type 'const int'}} (void)new float*(ip); // expected-error {{cannot initialize a new value of type 'float *' with an lvalue of type 'int *'}} // Undefined, but clang should reject it directly. (void)new int[-1]; // expected-error {{array size is negative}} (void)new int[2000000000]; // expected-error {{array is too large}} (void)new int[*(S*)0]; // expected-error {{array size expression must have integral or enumeration type, not 'S'}} (void)::S::new int; // expected-error {{expected unqualified-id}} (void)new (0, 0) int; // expected-error {{no matching function for call to 'operator new'}} (void)new (0L) int; // expected-error {{call to 'operator new' is ambiguous}} // This must fail, because the member version shouldn't be found. (void)::new ((S*)0) U; // expected-error {{no matching function for call to 'operator new'}} // This must fail, because any member version hides all global versions. (void)new U; // expected-error {{no matching function for call to 'operator new'}} (void)new (int[]); // expected-error {{array size must be specified in new expressions}} (void)new int&; // expected-error {{cannot allocate reference type 'int &' with new}} // Some lacking cases due to lack of sema support. } void good_deletes() { delete (int*)0; delete [](int*)0; delete (S*)0; ::delete (int*)0; } void bad_deletes() { delete 0; // expected-error {{cannot delete expression of type 'int'}} delete [0] (int*)0; // expected-error {{expected expression}} delete (void*)0; // expected-warning {{cannot delete expression with pointer-to-'void' type 'void *'}} delete (T*)0; // expected-warning {{deleting pointer to incomplete type}} ::S::delete (int*)0; // expected-error {{expected unqualified-id}} } struct X0 { }; struct X1 { operator int*(); operator float(); }; struct X2 { operator int*(); // expected-note {{conversion}} operator float*(); // expected-note {{conversion}} }; void test_delete_conv(X0 x0, X1 x1, X2 x2) { delete x0; // expected-error{{cannot delete}} delete x1; delete x2; // expected-error{{ambiguous conversion of delete expression of type 'X2' to a pointer}} } // PR4782 class X3 { public: static void operator delete(void * mem, size_t size); }; class X4 { public: static void release(X3 *x); static void operator delete(void * mem, size_t size); }; void X4::release(X3 *x) { delete x; } class X5 { public: void Destroy() const { delete this; } }; class Base { public: static void *operator new(signed char) throw(); // expected-error {{'operator new' takes type size_t}} static int operator new[] (size_t) throw(); // expected-error {{operator new[]' must return type 'void *'}} }; class Tier {}; class Comp : public Tier {}; class Thai : public Base { public: Thai(const Tier *adoptDictionary); }; void loadEngineFor() { const Comp *dict; new Thai(dict); } template <class T> struct TBase { void* operator new(T size, int); // expected-error {{'operator new' cannot take a dependent type as first parameter; use size_t}} }; TBase<int> t1; class X6 { public: static void operator delete(void*, int); // expected-note {{member found by ambiguous name lookup}} }; class X7 { public: static void operator delete(void*, int); // expected-note {{member found by ambiguous name lookup}} }; class X8 : public X6, public X7 { }; void f(X8 *x8) { delete x8; // expected-error {{member 'operator delete' found in multiple base classes of different types}} } class X9 { public: static void operator delete(void*, int); // expected-note {{'operator delete' declared here}} static void operator delete(void*, float); // expected-note {{'operator delete' declared here}} }; void f(X9 *x9) { delete x9; // expected-error {{no suitable member 'operator delete' in 'X9'}} } struct X10 { virtual ~X10(); }; struct X11 : X10 { // expected-error {{no suitable member 'operator delete' in 'X11'}} void operator delete(void*, int); // expected-note {{'operator delete' declared here}} }; void f() { X11 x11; // expected-note {{implicit destructor for 'X11' first required here}} } struct X12 { void* operator new(size_t, void*); }; struct X13 : X12 { using X12::operator new; }; static void* f(void* g) { return new (g) X13(); } class X14 { public: static void operator delete(void*, const size_t); }; void f(X14 *x14a, X14 *x14b) { delete x14a; } class X15 { private: X15(); // expected-note {{declared private here}} ~X15(); // expected-note {{declared private here}} }; void f(X15* x) { new X15(); // expected-error {{calling a private constructor}} delete x; // expected-error {{calling a private destructor}} } namespace PR5918 { // Look for template operator new overloads. struct S { template<typename T> static void* operator new(size_t, T); }; void test() { (void)new(0) S; } } namespace Test1 { void f() { (void)new int[10](1, 2); // expected-error {{array 'new' cannot have initialization arguments}} typedef int T[10]; (void)new T(1, 2); // expected-error {{array 'new' cannot have initialization arguments}} } template<typename T> void g(unsigned i) { (void)new T[1](i); // expected-error {{array 'new' cannot have initialization arguments}} } template<typename T> void h(unsigned i) { (void)new T(i); // expected-error {{array 'new' cannot have initialization arguments}} } template void h<unsigned>(unsigned); template void h<unsigned[10]>(unsigned); // expected-note {{in instantiation of function template specialization 'Test1::h<unsigned int [10]>' requested here}} } // Don't diagnose access for overload candidates that aren't selected. namespace PR7436 { struct S1 { void* operator new(size_t); void operator delete(void* p); private: void* operator new(size_t, void*); // expected-note {{declared private here}} void operator delete(void*, void*); }; class S2 { void* operator new(size_t); // expected-note {{declared private here}} void operator delete(void* p); // expected-note {{declared private here}} }; void test(S1* s1, S2* s2) { delete s1; delete s2; // expected-error {{is a private member}} (void)new S1(); (void)new (0L) S1(); // expected-error {{is a private member}} (void)new S2(); // expected-error {{is a private member}} } } namespace rdar8018245 { struct X0 { static const int value = 17; }; const int X0::value; struct X1 { static int value; }; int X1::value; template<typename T> int *f() { return new (int[T::value]); // expected-warning{{when type is in parentheses, array cannot have dynamic size}} } template int *f<X0>(); template int *f<X1>(); // expected-note{{in instantiation of}} } // <rdar://problem/8248780> namespace Instantiate { template<typename T> struct X { operator T*(); }; void f(X<int> &xi) { delete xi; } } namespace PR7810 { struct X { // cv is ignored in arguments static void operator delete(void *const); }; struct Y { // cv is ignored in arguments static void operator delete(void *volatile); }; } // Don't crash on template delete operators namespace TemplateDestructors { struct S { virtual ~S() {} void* operator new(const size_t size); template<class T> void* operator new(const size_t, const int, T*); void operator delete(void*, const size_t); template<class T> void operator delete(void*, const size_t, const int, T*); }; } namespace DeleteParam { struct X { void operator delete(X*); // expected-error{{first parameter of 'operator delete' must have type 'void *'}} }; struct Y { void operator delete(void* const); }; } // <rdar://problem/8427878> // Test that the correct 'operator delete' is selected to pair with // the unexpected placement 'operator new'. namespace PairedDelete { template <class T> struct A { A(); void *operator new(size_t s, double d = 0); void operator delete(void *p, double d); void operator delete(void *p) { T::dealloc(p); } }; A<int> *test() { return new A<int>(); } } namespace PR7702 { void test1() { new DoesNotExist; // expected-error {{unknown type name 'DoesNotExist'}} } } namespace ArrayNewNeedsDtor { struct A { A(); private: ~A(); }; // expected-note {{declared private here}} struct B { B(); A a; }; // expected-error {{field of type 'ArrayNewNeedsDtor::A' has private destructor}} B *test9() { return new B[5]; // expected-note {{implicit destructor for 'ArrayNewNeedsDtor::B' first required here}} } } namespace DeleteIncompleteClass { struct A; // expected-note {{forward declaration}} extern A x; void f() { delete x; } // expected-error {{deleting incomplete class type}} } namespace DeleteIncompleteClassPointerError { struct A; // expected-note {{forward declaration}} void f(A *x) { 1+delete x; } // expected-warning {{deleting pointer to incomplete type}} \ // expected-error {{invalid operands to binary expression}} } namespace PR10504 { struct A { virtual void foo() = 0; }; void f(A *x) { delete x; } // expected-warning {{delete called on 'PR10504::A' that is abstract but has non-virtual destructor}} } struct PlacementArg {}; inline void *operator new[](size_t, const PlacementArg &) throw () { return 0; } inline void operator delete[](void *, const PlacementArg &) throw () { } namespace r150682 { template <typename X> struct S { struct Inner {}; S() { new Inner[1]; } }; struct T { }; template<typename X> void tfn() { new (*(PlacementArg*)0) T[1]; // expected-warning 2 {{binding dereferenced null pointer to reference has undefined behavior}} } void fn() { tfn<int>(); // expected-note {{in instantiation of function template specialization 'r150682::tfn<int>' requested here}} } } namespace P12023 { struct CopyCounter { CopyCounter(); CopyCounter(const CopyCounter&); }; int main() { CopyCounter* f = new CopyCounter[10](CopyCounter()); // expected-error {{cannot have initialization arguments}} return 0; } } namespace PR12061 { template <class C> struct scoped_array { scoped_array(C* p = __null); }; template <class Payload> struct Foo { Foo() : a_(new scoped_array<int>[5]) { } scoped_array< scoped_array<int> > a_; }; class Bar {}; Foo<Bar> x; template <class C> struct scoped_array2 { scoped_array2(C* p = __null, C* q = __null); }; template <class Payload> struct Foo2 { Foo2() : a_(new scoped_array2<int>[5]) { } scoped_array2< scoped_array2<int> > a_; }; class Bar2 {}; Foo2<Bar2> x2; class MessageLoop { public: explicit MessageLoop(int type = 0); }; template <class CookieStoreTestTraits> class CookieStoreTest { protected: CookieStoreTest() { new MessageLoop; } }; struct CookieMonsterTestTraits { }; class DeferredCookieTaskTest : public CookieStoreTest<CookieMonsterTestTraits> { DeferredCookieTaskTest() {} }; } class DeletingPlaceholder { int* f() { delete f; // expected-error {{reference to non-static member function must be called; did you mean to call it with no arguments?}} return 0; } int* g(int, int) { delete g; // expected-error {{reference to non-static member function must be called}} return 0; } }; namespace PR18544 { inline void *operator new(size_t); // expected-error {{'operator new' cannot be declared inside a namespace}} } // PR19968 inline void* operator new(); // expected-error {{'operator new' must have at least one parameter}} namespace { template <class C> struct A { void f() { this->::new; } // expected-error {{expected unqualified-id}} void g() { this->::delete; } // expected-error {{expected unqualified-id}} }; }