test/SemaCXX/cxx2a-constexpr-dynalloc.cpp - clang - Git at Google

 // RUN: %clang_cc1 -std=c++2a -verify %s -DNEW=__builtin_operator_new -DDELETE=__builtin_operator_delete
 // RUN: %clang_cc1 -std=c++2a -verify %s "-DNEW=operator new" "-DDELETE=operator delete"
 // RUN: %clang_cc1 -std=c++2a -verify %s "-DNEW=::operator new" "-DDELETE=::operator delete"

 constexpr bool alloc_from_user_code() {
   void *p = NEW(sizeof(int)); // expected-note {{cannot allocate untyped memory in a constant expression; use 'std::allocator<T>::allocate'}}
   DELETE(p);
   return true;
 }
 static_assert(alloc_from_user_code()); // expected-error {{constant expression}} expected-note {{in call}}

 namespace std {
   using size_t = decltype(sizeof(0));
   // FIXME: It would be preferable to point these notes at the location of the call to allocator<...>::[de]allocate instead
   template<typename T> struct allocator {
     constexpr T *allocate(size_t N) {
       return (T*)NEW(sizeof(T) * N); // expected-note 3{{heap allocation}} expected-note {{not deallocated}}
     }
     constexpr void deallocate(void *p) {
       DELETE(p); // expected-note 2{{'std::allocator<...>::deallocate' used to delete pointer to object allocated with 'new'}}
     }
   };
 }

 constexpr bool alloc_via_std_allocator() {
   std::allocator<int> alloc;
   int *p = alloc.allocate(1);
   alloc.deallocate(p);
   return true;
 }
 static_assert(alloc_via_std_allocator());

 template<> struct std::allocator<void()> {
   constexpr void *allocate() { return NEW(8); } // expected-note {{cannot allocate memory of function type 'void ()'}}
 };
 constexpr void *fn = std::allocator<void()>().allocate(); // expected-error {{constant expression}} expected-note {{in call}}

 struct Incomplete;
 template<> struct std::allocator<Incomplete> {
   constexpr void *allocate() { return NEW(8); } // expected-note {{cannot allocate memory of incomplete type 'Incomplete'}}
 };
 constexpr void *incomplete = std::allocator<Incomplete>().allocate(); // expected-error {{constant expression}} expected-note {{in call}}

 struct WrongSize { char x[5]; };
 static_assert(sizeof(WrongSize) == 5);
 template<> struct std::allocator<WrongSize> {
   constexpr void *allocate() { return NEW(7); } // expected-note {{allocated size 7 is not a multiple of size 5 of element type 'WrongSize'}}
 };
 constexpr void *wrong_size = std::allocator<WrongSize>().allocate(); // expected-error {{constant expression}} expected-note {{in call}}

 constexpr bool mismatched(int alloc_kind, int dealloc_kind) {
   int *p;
   switch (alloc_kind) {
   case 0:
     p = new int; // expected-note {{heap allocation}}
     break;
   case 1:
     p = new int[1]; // expected-note {{heap allocation}}
     break;
   case 2:
     p = std::allocator<int>().allocate(1);
     break;
   }
   switch (dealloc_kind) {
   case 0:
     delete p; // expected-note {{'delete' used to delete pointer to object allocated with 'std::allocator<...>::allocate'}}
     break;
   case 1:
     delete[] p; // expected-note {{'delete' used to delete pointer to object allocated with 'std::allocator<...>::allocate'}}
     break;
   case 2:
     std::allocator<int>().deallocate(p); // expected-note 2{{in call}}
     break;
   }
   return true;
 }
 static_assert(mismatched(0, 2)); // expected-error {{constant expression}} expected-note {{in call}}
 static_assert(mismatched(1, 2)); // expected-error {{constant expression}} expected-note {{in call}}
 static_assert(mismatched(2, 0)); // expected-error {{constant expression}} expected-note {{in call}}
 static_assert(mismatched(2, 1)); // expected-error {{constant expression}} expected-note {{in call}}
 static_assert(mismatched(2, 2));

 constexpr int *escape = std::allocator<int>().allocate(3); // expected-error {{constant expression}} expected-note {{pointer to subobject of heap-allocated}}
 constexpr int leak = (std::allocator<int>().allocate(3), 0); // expected-error {{constant expression}}
 constexpr int no_lifetime_start = (*std::allocator<int>().allocate(1) = 1); // expected-error {{constant expression}} expected-note {{assignment to object outside its lifetime}}

 void *operator new(std::size_t, void *p) { return p; }
 constexpr bool no_placement_new_in_user_code() { // expected-error {{never produces a constant expression}}
   int a;
   new (&a) int(42); // expected-note {{call to placement 'operator new'}}
   return a == 42;
 }

 namespace std {
   constexpr bool placement_new_in_stdlib() {
     int a;
     new (&a) int(42);
     return a == 42;
   }
 }
 static_assert(std::placement_new_in_stdlib());

 namespace std {
   template<typename T, typename ...Args>
   constexpr void construct_at(void *p, Args &&...args) {
     new (p) T((Args&&)args...); // #new
   }
 }

 constexpr bool call_std_construct_at() {
   int *p = std::allocator<int>().allocate(3);
   std::construct_at<int>(p, 1);
   std::construct_at<int>(p + 1, 2);
   std::construct_at<int>(p + 2, 3);
   bool good = p[0] + p[1] + p[2] == 6;
   std::allocator<int>().deallocate(p);
   return good;
 }
 static_assert(call_std_construct_at());

 constexpr bool bad_construct_at_type() {
   int a;
   // expected-note@#new {{placement new would change type of storage from 'int' to 'float'}}
   std::construct_at<float>(&a, 1.0f); // expected-note {{in call}}
   return true;
 }
 static_assert(bad_construct_at_type()); // expected-error{{}} expected-note {{in call}}

 constexpr bool bad_construct_at_subobject() {
   struct X { int a, b; };
   union A {
     int a;
     X x;
   };
   A a = {1};
   // expected-note@#new {{construction of subobject of member 'x' of union with active member 'a' is not allowed in a constant expression}}
   std::construct_at<int>(&a.x.a, 1); // expected-note {{in call}}
   return true;
 }
 static_assert(bad_construct_at_subobject()); // expected-error{{}} expected-note {{in call}}

 constexpr bool change_union_member() {
   union U {
     int a;
     int b;
   };
   U u = {.a = 1};
   std::construct_at<int>(&u.b, 2);
   return u.b == 2;
 }
 static_assert(change_union_member());

 int external;
 // expected-note@#new {{visible outside}}
 static_assert((std::construct_at<int>(&external, 1), true)); // expected-error{{}} expected-note {{in call}}

 constexpr int &&temporary = 0; // expected-note {{created here}}
 // expected-note@#new {{construction of temporary is not allowed in a constant expression outside the expression that created the temporary}}
 static_assert((std::construct_at<int>(&temporary, 1), true)); // expected-error{{}} expected-note {{in call}}

 constexpr bool construct_after_lifetime() {
   int *p = new int;
   delete p;
   // expected-note@#new {{construction of heap allocated object that has been deleted}}
   std::construct_at<int>(p); // expected-note {{in call}}
   return true;
 }
 static_assert(construct_after_lifetime()); // expected-error {{}} expected-note {{in call}}

 constexpr bool construct_after_lifetime_2() {
   struct A { struct B {} b; };
   A a;
   a.~A();
   std::construct_at<A::B>(&a.b); // expected-note {{in call}}
   // expected-note@#new {{construction of subobject of object outside its lifetime is not allowed in a constant expression}}
   return true;
 }
 static_assert(construct_after_lifetime_2()); // expected-error {{}} expected-note {{in call}}
	// RUN: %clang_cc1 -std=c++2a -verify %s -DNEW=__builtin_operator_new -DDELETE=__builtin_operator_delete
	// RUN: %clang_cc1 -std=c++2a -verify %s "-DNEW=operator new" "-DDELETE=operator delete"
	// RUN: %clang_cc1 -std=c++2a -verify %s "-DNEW=::operator new" "-DDELETE=::operator delete"

	constexpr bool alloc_from_user_code() {
	void *p = NEW(sizeof(int)); // expected-note {{cannot allocate untyped memory in a constant expression; use 'std::allocator<T>::allocate'}}
	DELETE(p);
	return true;
	}
	static_assert(alloc_from_user_code()); // expected-error {{constant expression}} expected-note {{in call}}

	namespace std {
	using size_t = decltype(sizeof(0));
	// FIXME: It would be preferable to point these notes at the location of the call to allocator<...>::[de]allocate instead
	template<typename T> struct allocator {
	constexpr T *allocate(size_t N) {
	return (T)NEW(sizeof(T) N); // expected-note 3{{heap allocation}} expected-note {{not deallocated}}
	}
	constexpr void deallocate(void *p) {
	DELETE(p); // expected-note 2{{'std::allocator<...>::deallocate' used to delete pointer to object allocated with 'new'}}
	}
	};
	}

	constexpr bool alloc_via_std_allocator() {
	std::allocator<int> alloc;
	int *p = alloc.allocate(1);
	alloc.deallocate(p);
	return true;
	}
	static_assert(alloc_via_std_allocator());

	template<> struct std::allocator<void()> {
	constexpr void *allocate() { return NEW(8); } // expected-note {{cannot allocate memory of function type 'void ()'}}
	};
	constexpr void *fn = std::allocator<void()>().allocate(); // expected-error {{constant expression}} expected-note {{in call}}

	struct Incomplete;
	template<> struct std::allocator<Incomplete> {
	constexpr void *allocate() { return NEW(8); } // expected-note {{cannot allocate memory of incomplete type 'Incomplete'}}
	};
	constexpr void *incomplete = std::allocator<Incomplete>().allocate(); // expected-error {{constant expression}} expected-note {{in call}}

	struct WrongSize { char x[5]; };
	static_assert(sizeof(WrongSize) == 5);
	template<> struct std::allocator<WrongSize> {
	constexpr void *allocate() { return NEW(7); } // expected-note {{allocated size 7 is not a multiple of size 5 of element type 'WrongSize'}}
	};
	constexpr void *wrong_size = std::allocator<WrongSize>().allocate(); // expected-error {{constant expression}} expected-note {{in call}}

	constexpr bool mismatched(int alloc_kind, int dealloc_kind) {
	int *p;
	switch (alloc_kind) {
	case 0:
	p = new int; // expected-note {{heap allocation}}
	break;
	case 1:
	p = new int[1]; // expected-note {{heap allocation}}
	break;
	case 2:
	p = std::allocator<int>().allocate(1);
	break;
	}
	switch (dealloc_kind) {
	case 0:
	delete p; // expected-note {{'delete' used to delete pointer to object allocated with 'std::allocator<...>::allocate'}}
	break;
	case 1:
	delete[] p; // expected-note {{'delete' used to delete pointer to object allocated with 'std::allocator<...>::allocate'}}
	break;
	case 2:
	std::allocator<int>().deallocate(p); // expected-note 2{{in call}}
	break;
	}
	return true;
	}
	static_assert(mismatched(0, 2)); // expected-error {{constant expression}} expected-note {{in call}}
	static_assert(mismatched(1, 2)); // expected-error {{constant expression}} expected-note {{in call}}
	static_assert(mismatched(2, 0)); // expected-error {{constant expression}} expected-note {{in call}}
	static_assert(mismatched(2, 1)); // expected-error {{constant expression}} expected-note {{in call}}
	static_assert(mismatched(2, 2));

	constexpr int *escape = std::allocator<int>().allocate(3); // expected-error {{constant expression}} expected-note {{pointer to subobject of heap-allocated}}
	constexpr int leak = (std::allocator<int>().allocate(3), 0); // expected-error {{constant expression}}
	constexpr int no_lifetime_start = (*std::allocator<int>().allocate(1) = 1); // expected-error {{constant expression}} expected-note {{assignment to object outside its lifetime}}

	void operator new(std::size_t, void p) { return p; }
	constexpr bool no_placement_new_in_user_code() { // expected-error {{never produces a constant expression}}
	int a;
	new (&a) int(42); // expected-note {{call to placement 'operator new'}}
	return a == 42;
	}

	namespace std {
	constexpr bool placement_new_in_stdlib() {
	int a;
	new (&a) int(42);
	return a == 42;
	}
	}
	static_assert(std::placement_new_in_stdlib());

	namespace std {
	template<typename T, typename ...Args>
	constexpr void construct_at(void *p, Args &&...args) {
	new (p) T((Args&&)args...); // #new
	}
	}

	constexpr bool call_std_construct_at() {
	int *p = std::allocator<int>().allocate(3);
	std::construct_at<int>(p, 1);
	std::construct_at<int>(p + 1, 2);
	std::construct_at<int>(p + 2, 3);
	bool good = p[0] + p[1] + p[2] == 6;
	std::allocator<int>().deallocate(p);
	return good;
	}
	static_assert(call_std_construct_at());

	constexpr bool bad_construct_at_type() {
	int a;
	// expected-note@#new {{placement new would change type of storage from 'int' to 'float'}}
	std::construct_at<float>(&a, 1.0f); // expected-note {{in call}}
	return true;
	}
	static_assert(bad_construct_at_type()); // expected-error{{}} expected-note {{in call}}

	constexpr bool bad_construct_at_subobject() {
	struct X { int a, b; };
	union A {
	int a;
	X x;
	};
	A a = {1};
	// expected-note@#new {{construction of subobject of member 'x' of union with active member 'a' is not allowed in a constant expression}}
	std::construct_at<int>(&a.x.a, 1); // expected-note {{in call}}
	return true;
	}
	static_assert(bad_construct_at_subobject()); // expected-error{{}} expected-note {{in call}}

	constexpr bool change_union_member() {
	union U {
	int a;
	int b;
	};
	U u = {.a = 1};
	std::construct_at<int>(&u.b, 2);
	return u.b == 2;
	}
	static_assert(change_union_member());

	int external;
	// expected-note@#new {{visible outside}}
	static_assert((std::construct_at<int>(&external, 1), true)); // expected-error{{}} expected-note {{in call}}

	constexpr int &&temporary = 0; // expected-note {{created here}}
	// expected-note@#new {{construction of temporary is not allowed in a constant expression outside the expression that created the temporary}}
	static_assert((std::construct_at<int>(&temporary, 1), true)); // expected-error{{}} expected-note {{in call}}

	constexpr bool construct_after_lifetime() {
	int *p = new int;
	delete p;
	// expected-note@#new {{construction of heap allocated object that has been deleted}}
	std::construct_at<int>(p); // expected-note {{in call}}
	return true;
	}
	static_assert(construct_after_lifetime()); // expected-error {{}} expected-note {{in call}}

	constexpr bool construct_after_lifetime_2() {
	struct A { struct B {} b; };
	A a;
	a.~A();
	std::construct_at<A::B>(&a.b); // expected-note {{in call}}
	// expected-note@#new {{construction of subobject of object outside its lifetime is not allowed in a constant expression}}
	return true;
	}
	static_assert(construct_after_lifetime_2()); // expected-error {{}} expected-note {{in call}}