src/third_party/llvm-project/clang/test/SemaCXX/blocks.cpp - cobalt - Git at Google

 // RUN: %clang_cc1 -std=c++11 -fsyntax-only -verify %s -fblocks

 void tovoid(void*);

 void tovoid_test(int (^f)(int, int)) {
   tovoid(f);
 }

 void reference_lvalue_test(int& (^f)()) {
   f() = 10;
 }

 // PR 7165
 namespace test1 {
   void g(void (^)());
   struct Foo {
     void foo();
     void test() {
       (void) ^{ foo(); };
     }
   };
 }

 namespace test2 {
   int repeat(int value, int (^block)(int), unsigned n) {
     while (n--) value = block(value);
     return value;
   }

   class Power {
     int base;

   public:
     Power(int base) : base(base) {}
     int calculate(unsigned n) {
       return repeat(1, ^(int v) { return v * base; }, n);
     }
   };

   int test() {
     return Power(2).calculate(10);
   }
 }

 // rdar: // 8382559
 namespace radar8382559 {
   void func(bool& outHasProperty);

   int test3() {
     __attribute__((__blocks__(byref))) bool hasProperty = false;
     bool has = true;

     bool (^b)() = ^ {
      func(hasProperty);
      if (hasProperty)
        hasProperty = 0;
      if (has)
        hasProperty = 1;
      return hasProperty;
      };
     func(hasProperty);
     func(has);
     b();
     if (hasProperty)
       hasProperty = 1;
     if (has)
       has = 2;
     return hasProperty = 1;
   }
 }

 // Move __block variables to the heap when possible.
 class MoveOnly {
 public:
   MoveOnly();
   MoveOnly(const MoveOnly&) = delete;
   MoveOnly(MoveOnly&&);
 };

 void move_block() {
   __block MoveOnly mo;
 }

 // Don't crash after failing to build a block due to a capture of an
 // invalid declaration.
 namespace test5 {
   struct B { // expected-note 2 {{candidate constructor}}
     void *p;
     B(int); // expected-note {{candidate constructor}}
   };

   void use_block(void (^)());
   void use_block_2(void (^)(), const B &a);

   void test() {
     B x; // expected-error {{no matching constructor for initialization}}
     use_block(^{
         int y;
         use_block_2(^{ (void) y; }, x);
       });
   }
 }


 // rdar://16356628
 //
 // Ensure that we can end function bodies while parsing an
 // expression that requires an explicitly-tracked cleanup object
 // (i.e. a block literal).

 // The nested function body in this test case is a template
 // instantiation.  The template function has to be constexpr because
 // we'll otherwise delay its instantiation to the end of the
 // translation unit.
 namespace test6a {
   template <class T> constexpr int func() { return 0; }
   void run(void (^)(), int);

   void test() {
     int aCapturedVar = 0;
     run(^{ (void) aCapturedVar; }, func<int>());
   }
 }

 // The nested function body in this test case is a method of a local
 // class.
 namespace test6b {
   void run(void (^)(), void (^)());
   void test() {
     int aCapturedVar = 0;
     run(^{ (void) aCapturedVar; },
         ^{ struct A { static void foo() {} };
             A::foo(); });
   }
 }

 // The nested function body in this test case is a lambda invocation
 // function.
 namespace test6c {
   void run(void (^)(), void (^)());
   void test() {
     int aCapturedVar = 0;
     run(^{ (void) aCapturedVar; },
         ^{ struct A { static void foo() {} };
             A::foo(); });
   }
 }
	// RUN: %clang_cc1 -std=c++11 -fsyntax-only -verify %s -fblocks

	void tovoid(void*);

	void tovoid_test(int (^f)(int, int)) {
	tovoid(f);
	}

	void reference_lvalue_test(int& (^f)()) {
	f() = 10;
	}

	// PR 7165
	namespace test1 {
	void g(void (^)());
	struct Foo {
	void foo();
	void test() {
	(void) ^{ foo(); };
	}
	};
	}

	namespace test2 {
	int repeat(int value, int (^block)(int), unsigned n) {
	while (n--) value = block(value);
	return value;
	}

	class Power {
	int base;

	public:
	Power(int base) : base(base) {}
	int calculate(unsigned n) {
	return repeat(1, ^(int v) { return v * base; }, n);
	}
	};

	int test() {
	return Power(2).calculate(10);
	}
	}

	// rdar: // 8382559
	namespace radar8382559 {
	void func(bool& outHasProperty);

	int test3() {
	__attribute__((__blocks__(byref))) bool hasProperty = false;
	bool has = true;

	bool (^b)() = ^ {
	func(hasProperty);
	if (hasProperty)
	hasProperty = 0;
	if (has)
	hasProperty = 1;
	return hasProperty;
	};
	func(hasProperty);
	func(has);
	b();
	if (hasProperty)
	hasProperty = 1;
	if (has)
	has = 2;
	return hasProperty = 1;
	}
	}

	// Move __block variables to the heap when possible.
	class MoveOnly {
	public:
	MoveOnly();
	MoveOnly(const MoveOnly&) = delete;
	MoveOnly(MoveOnly&&);
	};

	void move_block() {
	__block MoveOnly mo;
	}

	// Don't crash after failing to build a block due to a capture of an
	// invalid declaration.
	namespace test5 {
	struct B { // expected-note 2 {{candidate constructor}}
	void *p;
	B(int); // expected-note {{candidate constructor}}
	};

	void use_block(void (^)());
	void use_block_2(void (^)(), const B &a);

	void test() {
	B x; // expected-error {{no matching constructor for initialization}}
	use_block(^{
	int y;
	use_block_2(^{ (void) y; }, x);
	});
	}
	}


	// rdar://16356628
	//
	// Ensure that we can end function bodies while parsing an
	// expression that requires an explicitly-tracked cleanup object
	// (i.e. a block literal).

	// The nested function body in this test case is a template
	// instantiation. The template function has to be constexpr because
	// we'll otherwise delay its instantiation to the end of the
	// translation unit.
	namespace test6a {
	template <class T> constexpr int func() { return 0; }
	void run(void (^)(), int);

	void test() {
	int aCapturedVar = 0;
	run(^{ (void) aCapturedVar; }, func<int>());
	}
	}

	// The nested function body in this test case is a method of a local
	// class.
	namespace test6b {
	void run(void (^)(), void (^)());
	void test() {
	int aCapturedVar = 0;
	run(^{ (void) aCapturedVar; },
	^{ struct A { static void foo() {} };
	A::foo(); });
	}
	}

	// The nested function body in this test case is a lambda invocation
	// function.
	namespace test6c {
	void run(void (^)(), void (^)());
	void test() {
	int aCapturedVar = 0;
	run(^{ (void) aCapturedVar; },
	^{ struct A { static void foo() {} };
	A::foo(); });
	}
	}