gcc/testsuite/gcc.dg/builtin-object-size-17.c - gcc - Git at Google

 /* PR 71831 - __builtin_object_size poor results with no optimization
    Verify that even without optimization __builtin_object_size result
    is folded into a constant and dead code that depends on it is
    eliminated.  */
 /* { dg-do compile } */
 /* { dg-options "-O0 -fdump-tree-ssa" } */

 #define concat(a, b)   a ## b
 #define CAT(a, b)      concat (a, b)

 /* Create a symbol name unique to each tes and object size type.  */
 #define SYM(type)      CAT (CAT (CAT (failure_on_line_, __LINE__), _type_), type)

 /* References to the following undefined symbol which is unique for each
    test case are expected to be eliminated.  */
 #define TEST_FAILURE(type)			\
   do {						\
     extern void SYM (type)(void);		\
     SYM (type)();				\
   } while (0)

 #define bos(obj, type) __builtin_object_size (obj, type)
 #define size(obj, n) ((size_t)n == X ? sizeof *obj : (size_t)n)

 #define test(expect, type, obj)			\
   do {						\
     if (bos (obj, type)	!= size (obj, expect))	\
       TEST_FAILURE (type);			\
   } while (0)

 #define FOLD_ALL(r0, r1, r2, r3, obj)		\
   do {						\
     test (r0, 0, obj);				\
     test (r1, 1, obj);				\
     test (r2, 2, obj);				\
     test (r3, 3, obj);				\
   } while (0)

 #define FOLD_0_2(r0, r1, r2, r3, obj)		\
   do {						\
     test (r0, 0, obj);				\
     test (r2, 2, obj);				\
   } while (0)

 /* For convenience.  Substitute for 'sizeof object' in test cases where
    the size can vary from target to target.  */
 #define X  (size_t)0xdeadbeef

 typedef __SIZE_TYPE__ size_t;

 extern char ax[];
 char ax2[];               /* { dg-warning "assumed to have one element" } */

 extern char a0[0];
 static char a1[1];
 static char a2[2];
 static char a9[9];

 #if __SIZEOF_SHORT__ == 4
 extern short ia0[0];
 static short ia1[1];
 static short ia9[9];
 #elif __SIZEOF_INT__ == 4
 extern int ia0[0];
 static int ia1[1];
 static int ia9[9];
 #elif __SIZEOF_LONG__ == 4
 extern long ia0[0];
 static long ia1[1];
 static long ia9[9];
 #endif

 static char a2x2[2][2];
 static char a3x5[3][5];

 struct Sx { char n, a[]; } sx;
 struct S0 { char n, a[0]; } s0;
 struct S1 { char n, a[1]; } s1;
 struct S2 { char n, a[2]; } s2;
 struct S9 { char n, a[9]; } s9;

 struct S2x2 { char n, a[2][2]; } s2x2;
 struct S3x5 { char n, a[3][5]; } s3x5;

 static __attribute__ ((noclone, noinline)) void
 test_arrays ()
 {
   FOLD_ALL (     1,       1,       1,       1,   ax2);

   FOLD_ALL (     1,       1,       1,       1,   a1);
   FOLD_ALL (     2,       2,       2,       2,   a2);
   FOLD_ALL (     9,       9,       9,       9,   a9);

   FOLD_ALL (     0,       0,       0,       0,   a0);
   FOLD_ALL (     1,       1,       1,       1,   ax2);

   FOLD_ALL (     0,       0,       0,       0,   ia0);
   FOLD_ALL (     4,       4,       4,       4,   ia1);
   FOLD_ALL (    36,      36,      36,      36,   ia9);

   /* Not all results for multidimensional arrays make sense (see
      bug 77293).  The expected results below simply reflect those
      obtained at -O2 (modulo the known limitations at -O1).  */
   FOLD_ALL (     4,       4,       4,       4,   a2x2);
   FOLD_ALL (     4,       4,       4,       4,   &a2x2[0]);
   FOLD_ALL (     4,       2,       4,       2,   &a2x2[0][0]);
   FOLD_0_2 (     0,  F1  (0),      0,       0,   &a2x2 + 1);
   FOLD_0_2 (     2,  F1 ( 2),      2,  F3 ( 2),  &a2x2[0] + 1);
   FOLD_0_2 (     3,  F1 ( 1),      3,  F3 ( 3),  &a2x2[0][0] + 1);

   FOLD_ALL (    15,      15,      15,      15,   a3x5);
   FOLD_ALL (    15,       5,      15,       5,   &a3x5[0][0] + 0);
   FOLD_0_2 (    14,  F1 ( 4),     14,  F3 (14),  &a3x5[0][0] + 1);

   FOLD_ALL (     1,       1,       1,       1,   a1 + 0);
   FOLD_0_2 (     0,  F1 ( 0),      0,       0,   &a1 + 1);
   FOLD_ALL (     2,       2,       2,       2,   a2 + 0);
   FOLD_0_2 (     1,  F1 ( 1),      1, F3 ( 1),   a2 + 1);
   FOLD_0_2 (     0,  F1 ( 0),      0,       0,   a2 + 2);
 }

 static __attribute__ ((noclone, noinline)) void
 test_structs (void)
 {
   /* The expected size of a declared object with a flexible array member
      is sizeof sx in all __builtin_object_size types.  */
   FOLD_ALL (     X,       X,       X,       X,   &sx);

   /* The expected size of a flexible array member of a declared object
      is zero.  */
   FOLD_ALL (     0,       0,       0,       0,   sx.a);

   /* The expected size of a declared object with a zero-length array member
      is sizeof sx in all __builtin_object_size types.  */
   FOLD_ALL (     X,       X,       X,       X,   &s0);

   /* The expected size of a zero-length array member of a declared object
      is zero.  */
   FOLD_ALL (     0,       0,       0,       0,   s0.a);

   FOLD_ALL (     X,       X,       X,       X,   &s1);
   FOLD_ALL (     1,       1,       1,       1,   s1.a);
   FOLD_0_2 (     0,  F1 (0),       0,       0,   s1.a + 1);

   FOLD_ALL (     X,       X,       X,       X,   &s9);
   FOLD_ALL (     9,       9,       9,       9,   s9.a);
   FOLD_ALL (     9,       9,       9,       9,   s9.a + 0);
   FOLD_0_2 (     8,  F1 ( 8),      8, F3 (  8),  s9.a + 1);
   FOLD_0_2 (     7,  F1 ( 7),      7, F3 (  7),  s9.a + 2);
   FOLD_0_2 (     0,  F1 ( 0),      0, F3 (  0),  s9.a + 9);
 }

 int
 main()
 {
   test_arrays ();
   test_structs ();

   return 0;
 }

 /* { dg-final { scan-tree-dump-not "failure_on_line" "ssa" } } */
	/* PR 71831 - __builtin_object_size poor results with no optimization
	Verify that even without optimization __builtin_object_size result
	is folded into a constant and dead code that depends on it is
	eliminated. */
	/* { dg-do compile } */
	/* { dg-options "-O0 -fdump-tree-ssa" } */

	#define concat(a, b) a ## b
	#define CAT(a, b) concat (a, b)

	/* Create a symbol name unique to each tes and object size type. */
	#define SYM(type) CAT (CAT (CAT (failure_on_line_, __LINE__), _type_), type)

	/* References to the following undefined symbol which is unique for each
	test case are expected to be eliminated. */
	#define TEST_FAILURE(type) \
	do { \
	extern void SYM (type)(void); \
	SYM (type)(); \
	} while (0)

	#define bos(obj, type) __builtin_object_size (obj, type)
	#define size(obj, n) ((size_t)n == X ? sizeof *obj : (size_t)n)

	#define test(expect, type, obj) \
	do { \
	if (bos (obj, type) != size (obj, expect)) \
	TEST_FAILURE (type); \
	} while (0)

	#define FOLD_ALL(r0, r1, r2, r3, obj) \
	do { \
	test (r0, 0, obj); \
	test (r1, 1, obj); \
	test (r2, 2, obj); \
	test (r3, 3, obj); \
	} while (0)

	#define FOLD_0_2(r0, r1, r2, r3, obj) \
	do { \
	test (r0, 0, obj); \
	test (r2, 2, obj); \
	} while (0)

	/* For convenience. Substitute for 'sizeof object' in test cases where
	the size can vary from target to target. */
	#define X (size_t)0xdeadbeef

	typedef __SIZE_TYPE__ size_t;

	extern char ax[];
	char ax2[]; /* { dg-warning "assumed to have one element" } */

	extern char a0[0];
	static char a1[1];
	static char a2[2];
	static char a9[9];

	#if __SIZEOF_SHORT__ == 4
	extern short ia0[0];
	static short ia1[1];
	static short ia9[9];
	#elif __SIZEOF_INT__ == 4
	extern int ia0[0];
	static int ia1[1];
	static int ia9[9];
	#elif __SIZEOF_LONG__ == 4
	extern long ia0[0];
	static long ia1[1];
	static long ia9[9];
	#endif

	static char a2x2[2][2];
	static char a3x5[3][5];

	struct Sx { char n, a[]; } sx;
	struct S0 { char n, a[0]; } s0;
	struct S1 { char n, a[1]; } s1;
	struct S2 { char n, a[2]; } s2;
	struct S9 { char n, a[9]; } s9;

	struct S2x2 { char n, a[2][2]; } s2x2;
	struct S3x5 { char n, a[3][5]; } s3x5;

	static __attribute__ ((noclone, noinline)) void
	test_arrays ()
	{
	FOLD_ALL ( 1, 1, 1, 1, ax2);

	FOLD_ALL ( 1, 1, 1, 1, a1);
	FOLD_ALL ( 2, 2, 2, 2, a2);
	FOLD_ALL ( 9, 9, 9, 9, a9);

	FOLD_ALL ( 0, 0, 0, 0, a0);
	FOLD_ALL ( 1, 1, 1, 1, ax2);

	FOLD_ALL ( 0, 0, 0, 0, ia0);
	FOLD_ALL ( 4, 4, 4, 4, ia1);
	FOLD_ALL ( 36, 36, 36, 36, ia9);

	/* Not all results for multidimensional arrays make sense (see
	bug 77293). The expected results below simply reflect those
	obtained at -O2 (modulo the known limitations at -O1). */
	FOLD_ALL ( 4, 4, 4, 4, a2x2);
	FOLD_ALL ( 4, 4, 4, 4, &a2x2[0]);
	FOLD_ALL ( 4, 2, 4, 2, &a2x2[0][0]);
	FOLD_0_2 ( 0, F1 (0), 0, 0, &a2x2 + 1);
	FOLD_0_2 ( 2, F1 ( 2), 2, F3 ( 2), &a2x2[0] + 1);
	FOLD_0_2 ( 3, F1 ( 1), 3, F3 ( 3), &a2x2[0][0] + 1);

	FOLD_ALL ( 15, 15, 15, 15, a3x5);
	FOLD_ALL ( 15, 5, 15, 5, &a3x5[0][0] + 0);
	FOLD_0_2 ( 14, F1 ( 4), 14, F3 (14), &a3x5[0][0] + 1);

	FOLD_ALL ( 1, 1, 1, 1, a1 + 0);
	FOLD_0_2 ( 0, F1 ( 0), 0, 0, &a1 + 1);
	FOLD_ALL ( 2, 2, 2, 2, a2 + 0);
	FOLD_0_2 ( 1, F1 ( 1), 1, F3 ( 1), a2 + 1);
	FOLD_0_2 ( 0, F1 ( 0), 0, 0, a2 + 2);
	}

	static __attribute__ ((noclone, noinline)) void
	test_structs (void)
	{
	/* The expected size of a declared object with a flexible array member
	is sizeof sx in all __builtin_object_size types. */
	FOLD_ALL ( X, X, X, X, &sx);

	/* The expected size of a flexible array member of a declared object
	is zero. */
	FOLD_ALL ( 0, 0, 0, 0, sx.a);

	/* The expected size of a declared object with a zero-length array member
	is sizeof sx in all __builtin_object_size types. */
	FOLD_ALL ( X, X, X, X, &s0);

	/* The expected size of a zero-length array member of a declared object
	is zero. */
	FOLD_ALL ( 0, 0, 0, 0, s0.a);

	FOLD_ALL ( X, X, X, X, &s1);
	FOLD_ALL ( 1, 1, 1, 1, s1.a);
	FOLD_0_2 ( 0, F1 (0), 0, 0, s1.a + 1);

	FOLD_ALL ( X, X, X, X, &s9);
	FOLD_ALL ( 9, 9, 9, 9, s9.a);
	FOLD_ALL ( 9, 9, 9, 9, s9.a + 0);
	FOLD_0_2 ( 8, F1 ( 8), 8, F3 ( 8), s9.a + 1);
	FOLD_0_2 ( 7, F1 ( 7), 7, F3 ( 7), s9.a + 2);
	FOLD_0_2 ( 0, F1 ( 0), 0, F3 ( 0), s9.a + 9);
	}

	int
	main()
	{
	test_arrays ();
	test_structs ();

	return 0;
	}

	/* { dg-final { scan-tree-dump-not "failure_on_line" "ssa" } } */