gcc/testsuite/gcc.dg/builtin-stringop-chk-8.c - gcc - Git at Google

 /* Test exercising -Wstringop-overread warnings for reading past the end.  */
 /* { dg-do compile } */
 /* { dg-options "-O2 -Wstringop-overread -ftrack-macro-expansion=0" } */

 #define PTRDIFF_MAX   __PTRDIFF_MAX__
 #define SIZE_MAX      __SIZE_MAX__

 #define offsetof(type, mem)   __builtin_offsetof (type, mem)

 /* Return the number of bytes from member MEM of TYPE to the end
    of object OBJ.  */
 #define offsetfrom(type, obj, mem) (sizeof (obj) - offsetof (type, mem))


 typedef __SIZE_TYPE__ size_t;
 extern void* memchr (const void*, int, size_t);
 extern int memcmp (const void*, const void*, size_t);
 extern void* memcpy (void*, const void*, size_t);
 extern void* memmove (void*, const void*, size_t);
 extern void* mempcpy (void*, const void*, size_t);

 #define memchr(d, s, n) sink (memchr (d, s, n))
 #define memcmp(d, s, n) sink (d, memcmp (d, s, n))
 #define memcpy(d, s, n) sink (memcpy (d, s, n))
 #define memmove(d, s, n) sink (memmove (d, s, n))
 #define mempcpy(d, s, n) sink (mempcpy (d, s, n))

 struct A { char a, b; };
 struct B { struct A a; char c, d; };

 /* Function to call to "escape" pointers from tests below to prevent
    GCC from assuming the values of the objects they point to stay
    the unchanged.  */
 void sink (void*, ...);

 /* Function to "generate" a random number each time it's called.  Declared
    (but not defined) and used to prevent GCC from making assumptions about
    their values based on the variables uses in the tested expressions.  */
 size_t random_unsigned_value (void);

 /* Return a random unsigned value between MIN and MAX.  */

 static inline size_t
 range (size_t min, size_t max)
 {
   const size_t val = random_unsigned_value ();
   return val < min || max < val ? min : val;
 }

 #define R(min, max)   range (min, max)

 /* Verify that reading beyond the end of a local array is diagnosed.  */

 void test_memop_warn_local (void *p, const void *q)
 {
   memcpy (p, "1234", R (6, 7));   /* { dg-warning "reading between 6 and 7 bytes from a region of size 5" } */

   struct A a[2];

   memcpy (p, a, R (7, 8));   /* { dg-warning "reading between 7 and 8 bytes from a region of size 4" } */

   /* At -Wstringop-overflow=1 the destination is considered to be
      the whole array and its size is therefore sizeof a.  */
   memcpy (p, &a[0], R (8, 9));   /* { dg-warning "reading between 8 and 9 bytes from a region of size 4" } */

   /* Verify the same as above but by reading from the first mmeber
      of the first element of the array.  */
   memcpy (p, &a[0].a, R (8, 9));   /* { dg-warning "reading between 8 and 9 bytes from a region of size 4" } */

   struct B b[2];

   memcpy (p, &b[0], R (12, 32));   /* { dg-warning "reading between 12 and 32 bytes from a region of size 8" } */

   /* Verify memchr/memcmp.  */
   int i = R (0, 255);
   memchr ("", i, 2);   /* { dg-warning "specified bound 2 exceeds source size 1" "memchr" } */
   memchr ("", i, 2);   /* { dg-warning "specified bound 2 exceeds source size 1" "memchr" } */
   memchr ("123", i, 5);   /* { dg-warning "specified bound 5 exceeds source size 4" "memchr" } */
   memchr (a, i, sizeof a + 1);   /* { dg-warning "specified bound 5 exceeds source size 4" "memchr" } */

   memcmp (p, "", 2);   /* { dg-warning "specified bound 2 exceeds source size 1" "memcmp" } */
   memcmp (p, "123", 5);   /* { dg-warning "specified bound 5 exceeds source size 4" "memcmp" } */
   memcmp (p, a, sizeof a + 1);   /* { dg-warning "specified bound 5 exceeds source size 4" "memcmp" } */

   size_t n = PTRDIFF_MAX + (size_t)1;
   memchr (p, 1, n);   /* { dg-warning "exceeds maximum object size" "memchr" } */
   memcmp (p, q, n);   /* { dg-warning "exceeds maximum object size" "memcmp" } */

   n = SIZE_MAX;
   memchr (p, 1, n);   /* { dg-warning "exceeds maximum object size" "memchr" } */
   memcmp (p, q, n);   /* { dg-warning "exceeds maximum object size" "memcmp" } */
 }

 /* Verify that reading beyond the end of a dynamically allocated array
    of known size is diagnosed.  */

 void test_memop_warn_alloc (void *p)
 {
   size_t n;

   n = range (8, 32);

   struct A *a = __builtin_malloc (sizeof *a * 2);

   memcpy (p, a, n);   /* { dg-warning "reading between 8 and 32 bytes from a region of size 4" "memcpy from allocated" } */

   memcpy (p, &a[0], n);   /* { dg-warning "reading between 8 and 32 bytes from a region of size 4" "memcpy from allocated" } */

   memcpy (p, &a[0].a, n);   /* { dg-warning "reading between 8 and 32 bytes from a region of size " "memcpy from allocated" } */

   n = range (12, 32);

   struct B *b = __builtin_malloc (sizeof *b * 2);

   memcpy (p, &b[0], n);   /* { dg-warning "reading between 12 and 32 bytes from a region of size 8" "memcpy from allocated" } */

   /* Verify memchr/memcmp.  */
   n = sizeof *b * 2 + 1;

   memchr (b, 1, n);   /* { dg-warning "specified bound 9 exceeds source size 8" "memchr from allocated" } */
   memcmp (p, b, n);   /* { dg-warning "specified bound 9 exceeds source size 8" "memcmp from allocated" } */
 }


 void test_memop_nowarn (void *p)
 {
   struct B b[2];

   size_t n = range (sizeof b, 32);

   /* Verify that copying the whole array is not diagnosed regardless
      of whether the expression pointing to its beginning is obtained
      from the array itself or its first member(s).  */
   memcpy (p, b, n);

   memcpy (p, &b[0], n);

   memcpy (p, &b[0].a, n);

   memcpy (p, &b[0].a.a, n);

   /* Verify that memchr/memcmp doesn't cause a warning.  */
   memchr (p, 1, n);
   memchr (b, 2, n);
   memchr (&b[0], 3, n);
   memchr (&b[0].a, 4, n);
   memchr (&b[0].a.a, 5, n);
   memchr ("01234567", R (0, 255), n);

   memcmp (p, p, n);
   memcmp (p, b, n);
   memcmp (p, &b[0], n);
   memcmp (p, &b[0].a, n);
   memcmp (p, &b[0].a.a, n);
   memcmp (p, "01234567", n);
 }


 /* The following function could specify in its API that it takes
    an array of exactly two elements, as shown below (or simply be
    called with such an array).  Verify that reading from both
    elements is not diagnosed.  */
 void test_memop_nowarn_arg (void*, const struct A[2]);

 void test_memop_nowarn_arg (void *p, const struct A *a)
 {
   memcpy (p, a, 2 * sizeof *a);

   memcpy (p, a, range (2 * sizeof *a, 123));

   memchr (p, 1, 1234);
   memcmp (p, a, 1234);
 }
	/* Test exercising -Wstringop-overread warnings for reading past the end. */
	/* { dg-do compile } */
	/* { dg-options "-O2 -Wstringop-overread -ftrack-macro-expansion=0" } */

	#define PTRDIFF_MAX __PTRDIFF_MAX__
	#define SIZE_MAX __SIZE_MAX__

	#define offsetof(type, mem) __builtin_offsetof (type, mem)

	/* Return the number of bytes from member MEM of TYPE to the end
	of object OBJ. */
	#define offsetfrom(type, obj, mem) (sizeof (obj) - offsetof (type, mem))


	typedef __SIZE_TYPE__ size_t;
	extern void* memchr (const void*, int, size_t);
	extern int memcmp (const void, const void, size_t);
	extern void* memcpy (void, const void, size_t);
	extern void* memmove (void, const void, size_t);
	extern void* mempcpy (void, const void, size_t);

	#define memchr(d, s, n) sink (memchr (d, s, n))
	#define memcmp(d, s, n) sink (d, memcmp (d, s, n))
	#define memcpy(d, s, n) sink (memcpy (d, s, n))
	#define memmove(d, s, n) sink (memmove (d, s, n))
	#define mempcpy(d, s, n) sink (mempcpy (d, s, n))

	struct A { char a, b; };
	struct B { struct A a; char c, d; };

	/* Function to call to "escape" pointers from tests below to prevent
	GCC from assuming the values of the objects they point to stay
	the unchanged. */
	void sink (void*, ...);

	/* Function to "generate" a random number each time it's called. Declared
	(but not defined) and used to prevent GCC from making assumptions about
	their values based on the variables uses in the tested expressions. */
	size_t random_unsigned_value (void);

	/* Return a random unsigned value between MIN and MAX. */

	static inline size_t
	range (size_t min, size_t max)
	{
	const size_t val = random_unsigned_value ();
	return val < min \|\| max < val ? min : val;
	}

	#define R(min, max) range (min, max)

	/* Verify that reading beyond the end of a local array is diagnosed. */

	void test_memop_warn_local (void p, const void q)
	{
	memcpy (p, "1234", R (6, 7)); /* { dg-warning "reading between 6 and 7 bytes from a region of size 5" } */

	struct A a[2];

	memcpy (p, a, R (7, 8)); /* { dg-warning "reading between 7 and 8 bytes from a region of size 4" } */

	/* At -Wstringop-overflow=1 the destination is considered to be
	the whole array and its size is therefore sizeof a. */
	memcpy (p, &a[0], R (8, 9)); /* { dg-warning "reading between 8 and 9 bytes from a region of size 4" } */

	/* Verify the same as above but by reading from the first mmeber
	of the first element of the array. */
	memcpy (p, &a[0].a, R (8, 9)); /* { dg-warning "reading between 8 and 9 bytes from a region of size 4" } */

	struct B b[2];

	memcpy (p, &b[0], R (12, 32)); /* { dg-warning "reading between 12 and 32 bytes from a region of size 8" } */

	/* Verify memchr/memcmp. */
	int i = R (0, 255);
	memchr ("", i, 2); /* { dg-warning "specified bound 2 exceeds source size 1" "memchr" } */
	memchr ("", i, 2); /* { dg-warning "specified bound 2 exceeds source size 1" "memchr" } */
	memchr ("123", i, 5); /* { dg-warning "specified bound 5 exceeds source size 4" "memchr" } */
	memchr (a, i, sizeof a + 1); /* { dg-warning "specified bound 5 exceeds source size 4" "memchr" } */

	memcmp (p, "", 2); /* { dg-warning "specified bound 2 exceeds source size 1" "memcmp" } */
	memcmp (p, "123", 5); /* { dg-warning "specified bound 5 exceeds source size 4" "memcmp" } */
	memcmp (p, a, sizeof a + 1); /* { dg-warning "specified bound 5 exceeds source size 4" "memcmp" } */

	size_t n = PTRDIFF_MAX + (size_t)1;
	memchr (p, 1, n); /* { dg-warning "exceeds maximum object size" "memchr" } */
	memcmp (p, q, n); /* { dg-warning "exceeds maximum object size" "memcmp" } */

	n = SIZE_MAX;
	memchr (p, 1, n); /* { dg-warning "exceeds maximum object size" "memchr" } */
	memcmp (p, q, n); /* { dg-warning "exceeds maximum object size" "memcmp" } */
	}

	/* Verify that reading beyond the end of a dynamically allocated array
	of known size is diagnosed. */

	void test_memop_warn_alloc (void *p)
	{
	size_t n;

	n = range (8, 32);

	struct A a = __builtin_malloc (sizeof a * 2);

	memcpy (p, a, n); /* { dg-warning "reading between 8 and 32 bytes from a region of size 4" "memcpy from allocated" } */

	memcpy (p, &a[0], n); /* { dg-warning "reading between 8 and 32 bytes from a region of size 4" "memcpy from allocated" } */

	memcpy (p, &a[0].a, n); /* { dg-warning "reading between 8 and 32 bytes from a region of size " "memcpy from allocated" } */

	n = range (12, 32);

	struct B b = __builtin_malloc (sizeof b * 2);

	memcpy (p, &b[0], n); /* { dg-warning "reading between 12 and 32 bytes from a region of size 8" "memcpy from allocated" } */

	/* Verify memchr/memcmp. */
	n = sizeof b 2 + 1;

	memchr (b, 1, n); /* { dg-warning "specified bound 9 exceeds source size 8" "memchr from allocated" } */
	memcmp (p, b, n); /* { dg-warning "specified bound 9 exceeds source size 8" "memcmp from allocated" } */
	}


	void test_memop_nowarn (void *p)
	{
	struct B b[2];

	size_t n = range (sizeof b, 32);

	/* Verify that copying the whole array is not diagnosed regardless
	of whether the expression pointing to its beginning is obtained
	from the array itself or its first member(s). */
	memcpy (p, b, n);

	memcpy (p, &b[0], n);

	memcpy (p, &b[0].a, n);

	memcpy (p, &b[0].a.a, n);

	/* Verify that memchr/memcmp doesn't cause a warning. */
	memchr (p, 1, n);
	memchr (b, 2, n);
	memchr (&b[0], 3, n);
	memchr (&b[0].a, 4, n);
	memchr (&b[0].a.a, 5, n);
	memchr ("01234567", R (0, 255), n);

	memcmp (p, p, n);
	memcmp (p, b, n);
	memcmp (p, &b[0], n);
	memcmp (p, &b[0].a, n);
	memcmp (p, &b[0].a.a, n);
	memcmp (p, "01234567", n);
	}


	/* The following function could specify in its API that it takes
	an array of exactly two elements, as shown below (or simply be
	called with such an array). Verify that reading from both
	elements is not diagnosed. */
	void test_memop_nowarn_arg (void*, const struct A[2]);

	void test_memop_nowarn_arg (void p, const struct A a)
	{
	memcpy (p, a, 2 * sizeof *a);

	memcpy (p, a, range (2 * sizeof *a, 123));

	memchr (p, 1, 1234);
	memcmp (p, a, 1234);
	}