test/Sema/const-eval.c - fp2-dev/platform/external/clang - Gitiles

 // RUN: clang-cc -fsyntax-only -verify %s

 #define EVAL_EXPR(testno, expr) int test##testno = sizeof(struct{char qq[expr];});
 int x;
 EVAL_EXPR(1, (_Bool)&x)
 EVAL_EXPR(2, (int)(1.0+(double)4))
 EVAL_EXPR(3, (int)(1.0+(float)4.0))
 EVAL_EXPR(4, (_Bool)(1 ? (void*)&x : 0))
 EVAL_EXPR(5, (_Bool)(int[]){0})
 struct y {int x,y;};
 EVAL_EXPR(6, (int)(1+(struct y*)0))
 EVAL_EXPR(7, (int)&((struct y*)0)->y)
 EVAL_EXPR(8, (_Bool)"asdf")
 EVAL_EXPR(9, !!&x)
 EVAL_EXPR(10, ((void)1, 12))
 void g0(void);
 EVAL_EXPR(11, (g0(), 12)) // FIXME: This should give an error
 EVAL_EXPR(12, 1.0&&2.0)
 EVAL_EXPR(13, x || 3.0)

 unsigned int l_19 = 1;
 EVAL_EXPR(14, (1 ^ l_19) && 1); // expected-error {{fields must have a constant size}}

 void f()
 {
   int a;
   EVAL_EXPR(15, (_Bool)&a); // expected-error {{fields must have a constant size}}
 }

 // FIXME: Turn into EVAL_EXPR test once we have more folding.
 _Complex float g16 = (1.0f + 1.0fi);

 // ?: in constant expressions.
 int g17[(3?:1) - 2];

 EVAL_EXPR(18, ((int)((void*)10 + 10)) == 20 ? 1 : -1);

 struct s {
   int a[(int)-1.0f]; // expected-error {{array size is negative}}
 };

 EVAL_EXPR(19, ((int)&*(char*)10 == 10 ? 1 : -1));

 EVAL_EXPR(20, __builtin_constant_p(*((int*) 10), -1, 1));

 EVAL_EXPR(21, (__imag__ 2i) == 2 ? 1 : -1);

 EVAL_EXPR(22, (__real__ (2i+3)) == 3 ? 1 : -1);

 int g23[(int)(1.0 / 1.0)] = { 1 };
 int g24[(int)(1.0 / 1.0)] = { 1 , 2 }; // expected-warning {{excess elements in array initializer}}
 int g25[(int)(1.0 + 1.0)], g26 = sizeof(g25);

 EVAL_EXPR(26, (_Complex double)0 ? -1 : 1)
 EVAL_EXPR(27, (_Complex int)0 ? -1 : 1)
 EVAL_EXPR(28, (_Complex double)1 ? 1 : -1)
 EVAL_EXPR(29, (_Complex int)1 ? 1 : -1)
	// RUN: clang-cc -fsyntax-only -verify %s

	#define EVAL_EXPR(testno, expr) int test##testno = sizeof(struct{char qq[expr];});
	int x;
	EVAL_EXPR(1, (_Bool)&x)
	EVAL_EXPR(2, (int)(1.0+(double)4))
	EVAL_EXPR(3, (int)(1.0+(float)4.0))
	EVAL_EXPR(4, (_Bool)(1 ? (void*)&x : 0))
	EVAL_EXPR(5, (_Bool)(int[]){0})
	struct y {int x,y;};
	EVAL_EXPR(6, (int)(1+(struct y*)0))
	EVAL_EXPR(7, (int)&((struct y*)0)->y)
	EVAL_EXPR(8, (_Bool)"asdf")
	EVAL_EXPR(9, !!&x)
	EVAL_EXPR(10, ((void)1, 12))
	void g0(void);
	EVAL_EXPR(11, (g0(), 12)) // FIXME: This should give an error
	EVAL_EXPR(12, 1.0&&2.0)
	EVAL_EXPR(13, x \|\| 3.0)

	unsigned int l_19 = 1;
	EVAL_EXPR(14, (1 ^ l_19) && 1); // expected-error {{fields must have a constant size}}

	void f()
	{
	int a;
	EVAL_EXPR(15, (_Bool)&a); // expected-error {{fields must have a constant size}}
	}

	// FIXME: Turn into EVAL_EXPR test once we have more folding.
	_Complex float g16 = (1.0f + 1.0fi);

	// ?: in constant expressions.
	int g17[(3?:1) - 2];

	EVAL_EXPR(18, ((int)((void*)10 + 10)) == 20 ? 1 : -1);

	struct s {
	int a[(int)-1.0f]; // expected-error {{array size is negative}}
	};

	EVAL_EXPR(19, ((int)&(char)10 == 10 ? 1 : -1));

	EVAL_EXPR(20, __builtin_constant_p(((int) 10), -1, 1));

	EVAL_EXPR(21, (__imag__ 2i) == 2 ? 1 : -1);

	EVAL_EXPR(22, (__real__ (2i+3)) == 3 ? 1 : -1);

	int g23[(int)(1.0 / 1.0)] = { 1 };
	int g24[(int)(1.0 / 1.0)] = { 1 , 2 }; // expected-warning {{excess elements in array initializer}}
	int g25[(int)(1.0 + 1.0)], g26 = sizeof(g25);

	EVAL_EXPR(26, (_Complex double)0 ? -1 : 1)
	EVAL_EXPR(27, (_Complex int)0 ? -1 : 1)
	EVAL_EXPR(28, (_Complex double)1 ? 1 : -1)
	EVAL_EXPR(29, (_Complex int)1 ? 1 : -1)