sources/cxx-stl/llvm-libc++/test/std/utilities/function.objects/func.wrap/func.wrap.func/func.wrap.func.con/F_nullptr.pass.cpp - toolchain/prebuilts/ndk/r13 - Git at Google

 //===----------------------------------------------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is dual licensed under the MIT and the University of Illinois Open
 // Source Licenses. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 // <functional>

 // class function<R(ArgTypes...)>

 // function(Fp);

 // Ensure that __not_null works for all function types.
 // See https://llvm.org/bugs/show_bug.cgi?id=23589

 //------------------------------------------------------------------------------
 // TESTING std::function<...>::__not_null(Callable)
 //
 // Concerns:
 //  1) The call __not_null(Callable) is well formed and correct for each
 //     possible 'Callable' type category. These categories include:
 //      1a) function pointers
 //      1b) member function pointer
 //      1c) member data pointer
 //      1d) callable class type
 //      1e) lambdas
 //    Categories 1a, 1b, and 1c are 'Nullable' types. Only objects of these
 //    types can be null. The other categories are not tested here.
 //  3) '__not_null(Callable)' is well formed when the call signature includes
 //      varargs.
 //  4) '__not_null(Callable)' works for Callable types with all aritys less
 //     than or equal to 3 in C++03.
 //  5) '__not_null(Callable)' works when 'Callable' is a member function
 //     pointer to a cv or ref qualified function type.
 //
 // Plan:
 //  1 For categories 1a, 1b and 1c define a set of
 //    'Callable' objects for this category. This set should include examples
 //    of arity 0, 1, 2 and possible 3 including versions with varargs as the
 //    last parameter.
 //
 //  2 For each 'Callable' object in categories 1a, 1b and 1c do the following.
 //
 //    1 Define a type 'std::function<Sig>' as 'F' where 'Sig' is compatible with
 //      the signature of the 'Callable' object.
 //
 //    2 Create an object of type 'F' using a null pointer of type 'Callable'.
 //      Check that 'F.target<Callable>()' is null.
 //
 //    3 Create an object of type 'F' that is not null. Check that
 //      'F.target<Callable>()' is not null and is equal to the original
 //      argument.

 #include <functional>
 #include <type_traits>
 #include <cassert>

 #include "test_macros.h"

 ///////////////////////////////////////////////////////////////////////////////
 int foo() { return 42; }
 int foo(int) { return 42; }
 int foo(int, int) { return 42; }
 int foo(int, int, int) { return 42; }

 int foo(...) { return 42; }
 int foo(int, ...) { return 42; }
 int foo(int, int, ...) { return 42; }
 int foo(int, int, int, ...) { return 42; }

 ///////////////////////////////////////////////////////////////////////////////
 struct MemFun03 {
     int foo() { return 42; }
     int foo() const { return 42; }
     int foo() volatile { return 42; }
     int foo() const volatile { return 42; }

     int foo(int) { return 42; }
     int foo(int) const { return 42; }
     int foo(int) volatile { return 42; }
     int foo(int) const volatile { return 42; }

     int foo(int, int) { return 42; }
     int foo(int, int) const { return 42; }
     int foo(int, int) volatile { return 42; }
     int foo(int, int) const volatile { return 42; }

     int foo(int, int, int) { return 42; }
     int foo(int, int, int) const { return 42; }
     int foo(int, int, int) volatile { return 42; }
     int foo(int, int, int) const volatile { return 42; }

     int foo(...) { return 42; }
     int foo(...) const { return 42; }
     int foo(...) volatile { return 42; }
     int foo(...) const volatile { return 42; }

     int foo(int, ...) { return 42; }
     int foo(int, ...) const { return 42; }
     int foo(int, ...) volatile { return 42; }
     int foo(int, ...) const volatile { return 42; }

     int foo(int, int, ...) { return 42; }
     int foo(int, int, ...) const { return 42; }
     int foo(int, int, ...) volatile { return 42; }
     int foo(int, int, ...) const volatile { return 42; }

     int foo(int, int, int, ...) { return 42; }
     int foo(int, int, int, ...) const { return 42; }
     int foo(int, int, int, ...) volatile { return 42; }
     int foo(int, int, int, ...) const volatile { return 42; }
 };

 #if TEST_STD_VER >= 11
 struct MemFun11 {
     int foo() & { return 42; }
     int foo() const & { return 42; }
     int foo() volatile & { return 42; }
     int foo() const volatile & { return 42; }

     int foo(...) & { return 42; }
     int foo(...) const & { return 42; }
     int foo(...) volatile & { return 42; }
     int foo(...) const volatile & { return 42; }

     int foo() && { return 42; }
     int foo() const && { return 42; }
     int foo() volatile && { return 42; }
     int foo() const volatile && { return 42; }

     int foo(...) && { return 42; }
     int foo(...) const && { return 42; }
     int foo(...) volatile && { return 42; }
     int foo(...) const volatile && { return 42; }
 };
 #endif // TEST_STD_VER >= 11

 struct MemData {
     int foo;
 };

 // Create a non-null free function by taking the address of
 // &static_cast<Tp&>(foo);
 template <class Tp>
 struct Creator {
     static Tp create() {
         return &foo;
     }
 };

 // Create a non-null member pointer.
 template <class Ret, class Class>
 struct Creator<Ret Class::*> {
     typedef Ret Class::*ReturnType;
     static ReturnType create() {
         return &Class::foo;
     }
 };

 template <class TestFn, class Fn>
 void test_imp() {
     { // Check that the null value is detected
         TestFn tf = nullptr;
         std::function<Fn> f = tf;
         assert(f.template target<TestFn>() == nullptr);
     }
     { // Check that the non-null value is detected.
         TestFn tf = Creator<TestFn>::create();
         assert(tf != nullptr);
         std::function<Fn> f = tf;
         assert(f.template target<TestFn>() != nullptr);
         assert(*f.template target<TestFn>() == tf);
     }
 }

 void test_func() {
     test_imp<int(*)(), int()>();
     test_imp<int(*)(...), int()>();
     test_imp<int(*)(int), int(int)>();
     test_imp<int(*)(int, ...), int(int)>();
     test_imp<int(*)(int, int), int(int, int)>();
     test_imp<int(*)(int, int, ...), int(int, int)>();
     test_imp<int(*)(int, int, int), int(int, int, int)>();
     test_imp<int(*)(int, int, int, ...), int(int, int, int)>();
 }

 void test_mf() {
     test_imp<int(MemFun03::*)(), int(MemFun03&)>();
     test_imp<int(MemFun03::*)(...), int(MemFun03&)>();
     test_imp<int(MemFun03::*)() const, int(MemFun03&)>();
     test_imp<int(MemFun03::*)(...) const, int(MemFun03&)>();
     test_imp<int(MemFun03::*)() volatile, int(MemFun03&)>();
     test_imp<int(MemFun03::*)(...) volatile, int(MemFun03&)>();
     test_imp<int(MemFun03::*)() const volatile, int(MemFun03&)>();
     test_imp<int(MemFun03::*)(...) const volatile, int(MemFun03&)>();

     test_imp<int(MemFun03::*)(int), int(MemFun03&, int)>();
     test_imp<int(MemFun03::*)(int, ...), int(MemFun03&, int)>();
     test_imp<int(MemFun03::*)(int) const, int(MemFun03&, int)>();
     test_imp<int(MemFun03::*)(int, ...) const, int(MemFun03&, int)>();
     test_imp<int(MemFun03::*)(int) volatile, int(MemFun03&, int)>();
     test_imp<int(MemFun03::*)(int, ...) volatile, int(MemFun03&, int)>();
     test_imp<int(MemFun03::*)(int) const volatile, int(MemFun03&, int)>();
     test_imp<int(MemFun03::*)(int, ...) const volatile, int(MemFun03&, int)>();

     test_imp<int(MemFun03::*)(int, int), int(MemFun03&, int, int)>();
     test_imp<int(MemFun03::*)(int, int, ...), int(MemFun03&, int, int)>();
     test_imp<int(MemFun03::*)(int, int) const, int(MemFun03&, int, int)>();
     test_imp<int(MemFun03::*)(int, int, ...) const, int(MemFun03&, int, int)>();
     test_imp<int(MemFun03::*)(int, int) volatile, int(MemFun03&, int, int)>();
     test_imp<int(MemFun03::*)(int, int, ...) volatile, int(MemFun03&, int, int)>();
     test_imp<int(MemFun03::*)(int, int) const volatile, int(MemFun03&, int, int)>();
     test_imp<int(MemFun03::*)(int, int, ...) const volatile, int(MemFun03&, int, int)>();

 #if TEST_STD_VER >= 11
     test_imp<int(MemFun11::*)() &, int(MemFun11&)>();
     test_imp<int(MemFun11::*)(...) &, int(MemFun11&)>();
     test_imp<int(MemFun11::*)() const &, int(MemFun11&)>();
     test_imp<int(MemFun11::*)(...) const &, int(MemFun11&)>();
     test_imp<int(MemFun11::*)() volatile &, int(MemFun11&)>();
     test_imp<int(MemFun11::*)(...) volatile &, int(MemFun11&)>();
     test_imp<int(MemFun11::*)() const volatile &, int(MemFun11&)>();
     test_imp<int(MemFun11::*)(...) const volatile &, int(MemFun11&)>();

     test_imp<int(MemFun11::*)() &&, int(MemFun11&&)>();
     test_imp<int(MemFun11::*)(...) &&, int(MemFun11&&)>();
     test_imp<int(MemFun11::*)() const &&, int(MemFun11&&)>();
     test_imp<int(MemFun11::*)(...) const &&, int(MemFun11&&)>();
     test_imp<int(MemFun11::*)() volatile &&, int(MemFun11&&)>();
     test_imp<int(MemFun11::*)(...) volatile &&, int(MemFun11&&)>();
     test_imp<int(MemFun11::*)() const volatile &&, int(MemFun11&&)>();
     test_imp<int(MemFun11::*)(...) const volatile &&, int(MemFun11&&)>();
 #endif
 }

 void test_md() {
     test_imp<int MemData::*, int(MemData&)>();
 }

 int main() {
     test_func();
     test_mf();
     test_md();
 }
	//===----------------------------------------------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is dual licensed under the MIT and the University of Illinois Open
	// Source Licenses. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	// <functional>

	// class function<R(ArgTypes...)>

	// function(Fp);

	// Ensure that __not_null works for all function types.
	// See https://llvm.org/bugs/show_bug.cgi?id=23589

	//------------------------------------------------------------------------------
	// TESTING std::function<...>::__not_null(Callable)
	//
	// Concerns:
	// 1) The call __not_null(Callable) is well formed and correct for each
	// possible 'Callable' type category. These categories include:
	// 1a) function pointers
	// 1b) member function pointer
	// 1c) member data pointer
	// 1d) callable class type
	// 1e) lambdas
	// Categories 1a, 1b, and 1c are 'Nullable' types. Only objects of these
	// types can be null. The other categories are not tested here.
	// 3) '__not_null(Callable)' is well formed when the call signature includes
	// varargs.
	// 4) '__not_null(Callable)' works for Callable types with all aritys less
	// than or equal to 3 in C++03.
	// 5) '__not_null(Callable)' works when 'Callable' is a member function
	// pointer to a cv or ref qualified function type.
	//
	// Plan:
	// 1 For categories 1a, 1b and 1c define a set of
	// 'Callable' objects for this category. This set should include examples
	// of arity 0, 1, 2 and possible 3 including versions with varargs as the
	// last parameter.
	//
	// 2 For each 'Callable' object in categories 1a, 1b and 1c do the following.
	//
	// 1 Define a type 'std::function<Sig>' as 'F' where 'Sig' is compatible with
	// the signature of the 'Callable' object.
	//
	// 2 Create an object of type 'F' using a null pointer of type 'Callable'.
	// Check that 'F.target<Callable>()' is null.
	//
	// 3 Create an object of type 'F' that is not null. Check that
	// 'F.target<Callable>()' is not null and is equal to the original
	// argument.

	#include <functional>
	#include <type_traits>
	#include <cassert>

	#include "test_macros.h"

	///////////////////////////////////////////////////////////////////////////////
	int foo() { return 42; }
	int foo(int) { return 42; }
	int foo(int, int) { return 42; }
	int foo(int, int, int) { return 42; }

	int foo(...) { return 42; }
	int foo(int, ...) { return 42; }
	int foo(int, int, ...) { return 42; }
	int foo(int, int, int, ...) { return 42; }

	///////////////////////////////////////////////////////////////////////////////
	struct MemFun03 {
	int foo() { return 42; }
	int foo() const { return 42; }
	int foo() volatile { return 42; }
	int foo() const volatile { return 42; }

	int foo(int) { return 42; }
	int foo(int) const { return 42; }
	int foo(int) volatile { return 42; }
	int foo(int) const volatile { return 42; }

	int foo(int, int) { return 42; }
	int foo(int, int) const { return 42; }
	int foo(int, int) volatile { return 42; }
	int foo(int, int) const volatile { return 42; }

	int foo(int, int, int) { return 42; }
	int foo(int, int, int) const { return 42; }
	int foo(int, int, int) volatile { return 42; }
	int foo(int, int, int) const volatile { return 42; }

	int foo(...) { return 42; }
	int foo(...) const { return 42; }
	int foo(...) volatile { return 42; }
	int foo(...) const volatile { return 42; }

	int foo(int, ...) { return 42; }
	int foo(int, ...) const { return 42; }
	int foo(int, ...) volatile { return 42; }
	int foo(int, ...) const volatile { return 42; }

	int foo(int, int, ...) { return 42; }
	int foo(int, int, ...) const { return 42; }
	int foo(int, int, ...) volatile { return 42; }
	int foo(int, int, ...) const volatile { return 42; }

	int foo(int, int, int, ...) { return 42; }
	int foo(int, int, int, ...) const { return 42; }
	int foo(int, int, int, ...) volatile { return 42; }
	int foo(int, int, int, ...) const volatile { return 42; }
	};

	#if TEST_STD_VER >= 11
	struct MemFun11 {
	int foo() & { return 42; }
	int foo() const & { return 42; }
	int foo() volatile & { return 42; }
	int foo() const volatile & { return 42; }

	int foo(...) & { return 42; }
	int foo(...) const & { return 42; }
	int foo(...) volatile & { return 42; }
	int foo(...) const volatile & { return 42; }

	int foo() && { return 42; }
	int foo() const && { return 42; }
	int foo() volatile && { return 42; }
	int foo() const volatile && { return 42; }

	int foo(...) && { return 42; }
	int foo(...) const && { return 42; }
	int foo(...) volatile && { return 42; }
	int foo(...) const volatile && { return 42; }
	};
	#endif // TEST_STD_VER >= 11

	struct MemData {
	int foo;
	};

	// Create a non-null free function by taking the address of
	// &static_cast<Tp&>(foo);
	template <class Tp>
	struct Creator {
	static Tp create() {
	return &foo;
	}
	};

	// Create a non-null member pointer.
	template <class Ret, class Class>
	struct Creator<Ret Class::*> {
	typedef Ret Class::*ReturnType;
	static ReturnType create() {
	return &Class::foo;
	}
	};

	template <class TestFn, class Fn>
	void test_imp() {
	{ // Check that the null value is detected
	TestFn tf = nullptr;
	std::function<Fn> f = tf;
	assert(f.template target<TestFn>() == nullptr);
	}
	{ // Check that the non-null value is detected.
	TestFn tf = Creator<TestFn>::create();
	assert(tf != nullptr);
	std::function<Fn> f = tf;
	assert(f.template target<TestFn>() != nullptr);
	assert(*f.template target<TestFn>() == tf);
	}
	}

	void test_func() {
	test_imp<int(*)(), int()>();
	test_imp<int(*)(...), int()>();
	test_imp<int(*)(int), int(int)>();
	test_imp<int(*)(int, ...), int(int)>();
	test_imp<int(*)(int, int), int(int, int)>();
	test_imp<int(*)(int, int, ...), int(int, int)>();
	test_imp<int(*)(int, int, int), int(int, int, int)>();
	test_imp<int(*)(int, int, int, ...), int(int, int, int)>();
	}

	void test_mf() {
	test_imp<int(MemFun03::*)(), int(MemFun03&)>();
	test_imp<int(MemFun03::*)(...), int(MemFun03&)>();
	test_imp<int(MemFun03::*)() const, int(MemFun03&)>();
	test_imp<int(MemFun03::*)(...) const, int(MemFun03&)>();
	test_imp<int(MemFun03::*)() volatile, int(MemFun03&)>();
	test_imp<int(MemFun03::*)(...) volatile, int(MemFun03&)>();
	test_imp<int(MemFun03::*)() const volatile, int(MemFun03&)>();
	test_imp<int(MemFun03::*)(...) const volatile, int(MemFun03&)>();

	test_imp<int(MemFun03::*)(int), int(MemFun03&, int)>();
	test_imp<int(MemFun03::*)(int, ...), int(MemFun03&, int)>();
	test_imp<int(MemFun03::*)(int) const, int(MemFun03&, int)>();
	test_imp<int(MemFun03::*)(int, ...) const, int(MemFun03&, int)>();
	test_imp<int(MemFun03::*)(int) volatile, int(MemFun03&, int)>();
	test_imp<int(MemFun03::*)(int, ...) volatile, int(MemFun03&, int)>();
	test_imp<int(MemFun03::*)(int) const volatile, int(MemFun03&, int)>();
	test_imp<int(MemFun03::*)(int, ...) const volatile, int(MemFun03&, int)>();

	test_imp<int(MemFun03::*)(int, int), int(MemFun03&, int, int)>();
	test_imp<int(MemFun03::*)(int, int, ...), int(MemFun03&, int, int)>();
	test_imp<int(MemFun03::*)(int, int) const, int(MemFun03&, int, int)>();
	test_imp<int(MemFun03::*)(int, int, ...) const, int(MemFun03&, int, int)>();
	test_imp<int(MemFun03::*)(int, int) volatile, int(MemFun03&, int, int)>();
	test_imp<int(MemFun03::*)(int, int, ...) volatile, int(MemFun03&, int, int)>();
	test_imp<int(MemFun03::*)(int, int) const volatile, int(MemFun03&, int, int)>();
	test_imp<int(MemFun03::*)(int, int, ...) const volatile, int(MemFun03&, int, int)>();

	#if TEST_STD_VER >= 11
	test_imp<int(MemFun11::*)() &, int(MemFun11&)>();
	test_imp<int(MemFun11::*)(...) &, int(MemFun11&)>();
	test_imp<int(MemFun11::*)() const &, int(MemFun11&)>();
	test_imp<int(MemFun11::*)(...) const &, int(MemFun11&)>();
	test_imp<int(MemFun11::*)() volatile &, int(MemFun11&)>();
	test_imp<int(MemFun11::*)(...) volatile &, int(MemFun11&)>();
	test_imp<int(MemFun11::*)() const volatile &, int(MemFun11&)>();
	test_imp<int(MemFun11::*)(...) const volatile &, int(MemFun11&)>();

	test_imp<int(MemFun11::*)() &&, int(MemFun11&&)>();
	test_imp<int(MemFun11::*)(...) &&, int(MemFun11&&)>();
	test_imp<int(MemFun11::*)() const &&, int(MemFun11&&)>();
	test_imp<int(MemFun11::*)(...) const &&, int(MemFun11&&)>();
	test_imp<int(MemFun11::*)() volatile &&, int(MemFun11&&)>();
	test_imp<int(MemFun11::*)(...) volatile &&, int(MemFun11&&)>();
	test_imp<int(MemFun11::*)() const volatile &&, int(MemFun11&&)>();
	test_imp<int(MemFun11::*)(...) const volatile &&, int(MemFun11&&)>();
	#endif
	}

	void test_md() {
	test_imp<int MemData::*, int(MemData&)>();
	}

	int main() {
	test_func();
	test_mf();
	test_md();
	}