src/third_party/llvm-project/clang/test/Analysis/bstring.c - cobalt - Git at Google

 // RUN: %clang_analyze_cc1 -analyzer-checker=core,unix.cstring,alpha.unix.cstring,debug.ExprInspection -analyzer-store=region -verify %s
 // RUN: %clang_analyze_cc1 -DUSE_BUILTINS -analyzer-checker=core,unix.cstring,alpha.unix.cstring,debug.ExprInspection -analyzer-store=region -verify %s
 // RUN: %clang_analyze_cc1 -DVARIANT -analyzer-checker=core,unix.cstring,alpha.unix.cstring,debug.ExprInspection -analyzer-store=region -verify %s
 // RUN: %clang_analyze_cc1 -DUSE_BUILTINS -DVARIANT -analyzer-checker=core,unix.cstring,alpha.unix.cstring,debug.ExprInspection -analyzer-store=region -verify %s

 //===----------------------------------------------------------------------===
 // Declarations
 //===----------------------------------------------------------------------===

 // Some functions are so similar to each other that they follow the same code
 // path, such as memcpy and __memcpy_chk, or memcmp and bcmp. If VARIANT is
 // defined, make sure to use the variants instead to make sure they are still
 // checked by the analyzer.

 // Some functions are implemented as builtins. These should be #defined as
 // BUILTIN(f), which will prepend "__builtin_" if USE_BUILTINS is defined.

 // Functions that have variants and are also available as builtins should be
 // declared carefully! See memcpy() for an example.

 #ifdef USE_BUILTINS
 # define BUILTIN(f) __builtin_ ## f
 #else /* USE_BUILTINS */
 # define BUILTIN(f) f
 #endif /* USE_BUILTINS */

 typedef typeof(sizeof(int)) size_t;

 void clang_analyzer_eval(int);

 //===----------------------------------------------------------------------===
 // memcpy()
 //===----------------------------------------------------------------------===

 #ifdef VARIANT

 #define __memcpy_chk BUILTIN(__memcpy_chk)
 void *__memcpy_chk(void *restrict s1, const void *restrict s2, size_t n,
                    size_t destlen);

 #define memcpy(a,b,c) __memcpy_chk(a,b,c,(size_t)-1)

 #else /* VARIANT */

 #define memcpy BUILTIN(memcpy)
 void *memcpy(void *restrict s1, const void *restrict s2, size_t n);

 #endif /* VARIANT */


 void memcpy0 () {
   char src[] = {1, 2, 3, 4};
   char dst[4] = {0};

   memcpy(dst, src, 4); // no-warning

   clang_analyzer_eval(memcpy(dst, src, 4) == dst); // expected-warning{{TRUE}}

   // If we actually model the copy, we can make this known.
   // The important thing for now is that the old value has been invalidated.
   clang_analyzer_eval(dst[0] != 0); // expected-warning{{UNKNOWN}}
 }

 void memcpy1 () {
   char src[] = {1, 2, 3, 4};
   char dst[10];

   memcpy(dst, src, 5); // expected-warning{{Memory copy function accesses out-of-bound array element}}
 }

 void memcpy2 () {
   char src[] = {1, 2, 3, 4};
   char dst[1];

   memcpy(dst, src, 4); // expected-warning{{Memory copy function overflows destination buffer}}
 }

 void memcpy3 () {
   char src[] = {1, 2, 3, 4};
   char dst[3];

   memcpy(dst+1, src+2, 2); // no-warning
 }

 void memcpy4 () {
   char src[] = {1, 2, 3, 4};
   char dst[10];

   memcpy(dst+2, src+2, 3); // expected-warning{{Memory copy function accesses out-of-bound array element}}
 }

 void memcpy5() {
   char src[] = {1, 2, 3, 4};
   char dst[3];

   memcpy(dst+2, src+2, 2); // expected-warning{{Memory copy function overflows destination buffer}}
 }

 void memcpy6() {
   int a[4] = {0};
   memcpy(a, a, 8); // expected-warning{{overlapping}}
 }

 void memcpy7() {
   int a[4] = {0};
   memcpy(a+2, a+1, 8); // expected-warning{{overlapping}}
 }

 void memcpy8() {
   int a[4] = {0};
   memcpy(a+1, a+2, 8); // expected-warning{{overlapping}}
 }

 void memcpy9() {
   int a[4] = {0};
   memcpy(a+2, a+1, 4); // no-warning
   memcpy(a+1, a+2, 4); // no-warning
 }

 void memcpy10() {
   char a[4] = {0};
   memcpy(0, a, 4); // expected-warning{{Null pointer argument in call to memory copy function}}
 }

 void memcpy11() {
   char a[4] = {0};
   memcpy(a, 0, 4); // expected-warning{{Null pointer argument in call to memory copy function}}
 }

 void memcpy12() {
   char a[4] = {0};
   memcpy(0, a, 0); // no-warning
 }

 void memcpy13() {
   char a[4] = {0};
   memcpy(a, 0, 0); // no-warning
 }

 void memcpy_unknown_size (size_t n) {
   char a[4], b[4] = {1};
   clang_analyzer_eval(memcpy(a, b, n) == a); // expected-warning{{TRUE}}
 }

 void memcpy_unknown_size_warn (size_t n) {
   char a[4];
   void *result = memcpy(a, 0, n); // expected-warning{{Null pointer argument in call to memory copy function}}
   clang_analyzer_eval(result == a); // no-warning (above is fatal)
 }

 //===----------------------------------------------------------------------===
 // mempcpy()
 //===----------------------------------------------------------------------===

 #ifdef VARIANT

 #define __mempcpy_chk BUILTIN(__mempcpy_chk)
 void *__mempcpy_chk(void *restrict s1, const void *restrict s2, size_t n,
                    size_t destlen);

 #define mempcpy(a,b,c) __mempcpy_chk(a,b,c,(size_t)-1)

 #else /* VARIANT */

 #define mempcpy BUILTIN(mempcpy)
 void *mempcpy(void *restrict s1, const void *restrict s2, size_t n);

 #endif /* VARIANT */


 void mempcpy0 () {
   char src[] = {1, 2, 3, 4};
   char dst[5] = {0};

   mempcpy(dst, src, 4); // no-warning

   clang_analyzer_eval(mempcpy(dst, src, 4) == &dst[4]); // expected-warning{{TRUE}}

   // If we actually model the copy, we can make this known.
   // The important thing for now is that the old value has been invalidated.
   clang_analyzer_eval(dst[0] != 0); // expected-warning{{UNKNOWN}}
 }

 void mempcpy1 () {
   char src[] = {1, 2, 3, 4};
   char dst[10];

   mempcpy(dst, src, 5); // expected-warning{{Memory copy function accesses out-of-bound array element}}
 }

 void mempcpy2 () {
   char src[] = {1, 2, 3, 4};
   char dst[1];

   mempcpy(dst, src, 4); // expected-warning{{Memory copy function overflows destination buffer}}
 }

 void mempcpy3 () {
   char src[] = {1, 2, 3, 4};
   char dst[3];

   mempcpy(dst+1, src+2, 2); // no-warning
 }

 void mempcpy4 () {
   char src[] = {1, 2, 3, 4};
   char dst[10];

   mempcpy(dst+2, src+2, 3); // expected-warning{{Memory copy function accesses out-of-bound array element}}
 }

 void mempcpy5() {
   char src[] = {1, 2, 3, 4};
   char dst[3];

   mempcpy(dst+2, src+2, 2); // expected-warning{{Memory copy function overflows destination buffer}}
 }

 void mempcpy6() {
   int a[4] = {0};
   mempcpy(a, a, 8); // expected-warning{{overlapping}}
 }

 void mempcpy7() {
   int a[4] = {0};
   mempcpy(a+2, a+1, 8); // expected-warning{{overlapping}}
 }

 void mempcpy8() {
   int a[4] = {0};
   mempcpy(a+1, a+2, 8); // expected-warning{{overlapping}}
 }

 void mempcpy9() {
   int a[4] = {0};
   mempcpy(a+2, a+1, 4); // no-warning
   mempcpy(a+1, a+2, 4); // no-warning
 }

 void mempcpy10() {
   char a[4] = {0};
   mempcpy(0, a, 4); // expected-warning{{Null pointer argument in call to memory copy function}}
 }

 void mempcpy11() {
   char a[4] = {0};
   mempcpy(a, 0, 4); // expected-warning{{Null pointer argument in call to memory copy function}}
 }

 void mempcpy12() {
   char a[4] = {0};
   mempcpy(0, a, 0); // no-warning
 }

 void mempcpy13() {
   char a[4] = {0};
   mempcpy(a, 0, 0); // no-warning
 }

 void mempcpy14() {
   int src[] = {1, 2, 3, 4};
   int dst[5] = {0};
   int *p;

   p = mempcpy(dst, src, 4 * sizeof(int));

   clang_analyzer_eval(p == &dst[4]); // expected-warning{{TRUE}}
 }

 struct st {
   int i;
   int j;
 };

 void mempcpy15() {
   struct st s1 = {0};
   struct st s2;
   struct st *p1;
   struct st *p2;

   p1 = (&s2) + 1;
   p2 = mempcpy(&s2, &s1, sizeof(struct st));

   clang_analyzer_eval(p1 == p2); // expected-warning{{TRUE}}
 }

 void mempcpy16() {
   struct st s1[10] = {{0}};
   struct st s2[10];
   struct st *p1;
   struct st *p2;

   p1 = (&s2[0]) + 5;
   p2 = mempcpy(&s2[0], &s1[0], 5 * sizeof(struct st));

   clang_analyzer_eval(p1 == p2); // expected-warning{{TRUE}}
 }

 void mempcpy_unknown_size_warn (size_t n) {
   char a[4];
   void *result = mempcpy(a, 0, n); // expected-warning{{Null pointer argument in call to memory copy function}}
   clang_analyzer_eval(result == a); // no-warning (above is fatal)
 }

 void mempcpy_unknownable_size (char *src, float n) {
   char a[4];
   // This used to crash because we don't model floats.
   mempcpy(a, src, (size_t)n);
 }

 //===----------------------------------------------------------------------===
 // memmove()
 //===----------------------------------------------------------------------===

 #ifdef VARIANT

 #define __memmove_chk BUILTIN(__memmove_chk)
 void *__memmove_chk(void *s1, const void *s2, size_t n, size_t destlen);

 #define memmove(a,b,c) __memmove_chk(a,b,c,(size_t)-1)

 #else /* VARIANT */

 #define memmove BUILTIN(memmove)
 void *memmove(void *s1, const void *s2, size_t n);

 #endif /* VARIANT */


 void memmove0 () {
   char src[] = {1, 2, 3, 4};
   char dst[4] = {0};

   memmove(dst, src, 4); // no-warning

   clang_analyzer_eval(memmove(dst, src, 4) == dst); // expected-warning{{TRUE}}

   // If we actually model the copy, we can make this known.
   // The important thing for now is that the old value has been invalidated.
   clang_analyzer_eval(dst[0] != 0); // expected-warning{{UNKNOWN}}
 }

 void memmove1 () {
   char src[] = {1, 2, 3, 4};
   char dst[10];

   memmove(dst, src, 5); // expected-warning{{out-of-bound}}
 }

 void memmove2 () {
   char src[] = {1, 2, 3, 4};
   char dst[1];

   memmove(dst, src, 4); // expected-warning{{overflow}}
 }

 //===----------------------------------------------------------------------===
 // memcmp()
 //===----------------------------------------------------------------------===

 #ifdef VARIANT

 #define bcmp BUILTIN(bcmp)
 // __builtin_bcmp is not defined with const in Builtins.def.
 int bcmp(/*const*/ void *s1, /*const*/ void *s2, size_t n);
 #define memcmp bcmp
 //
 #else /* VARIANT */

 #define memcmp BUILTIN(memcmp)
 int memcmp(const void *s1, const void *s2, size_t n);

 #endif /* VARIANT */


 void memcmp0 () {
   char a[] = {1, 2, 3, 4};
   char b[4] = { 0 };

   memcmp(a, b, 4); // no-warning
 }

 void memcmp1 () {
   char a[] = {1, 2, 3, 4};
   char b[10] = { 0 };

   memcmp(a, b, 5); // expected-warning{{out-of-bound}}
 }

 void memcmp2 () {
   char a[] = {1, 2, 3, 4};
   char b[1] = { 0 };

   memcmp(a, b, 4); // expected-warning{{out-of-bound}}
 }

 void memcmp3 () {
   char a[] = {1, 2, 3, 4};

   clang_analyzer_eval(memcmp(a, a, 4) == 0); // expected-warning{{TRUE}}
 }

 void memcmp4 (char *input) {
   char a[] = {1, 2, 3, 4};

   clang_analyzer_eval(memcmp(a, input, 4) == 0); // expected-warning{{UNKNOWN}}
 }

 void memcmp5 (char *input) {
   char a[] = {1, 2, 3, 4};

   clang_analyzer_eval(memcmp(a, 0, 0) == 0); // expected-warning{{TRUE}}
   clang_analyzer_eval(memcmp(0, a, 0) == 0); // expected-warning{{TRUE}}
   clang_analyzer_eval(memcmp(a, input, 0) == 0); // expected-warning{{TRUE}}
 }

 void memcmp6 (char *a, char *b, size_t n) {
   int result = memcmp(a, b, n);
   if (result != 0)
     clang_analyzer_eval(n != 0); // expected-warning{{TRUE}}
   // else
   //   analyzer_assert_unknown(n == 0);

   // We can't do the above comparison because n has already been constrained.
   // On one path n == 0, on the other n != 0.
 }

 int memcmp7 (char *a, size_t x, size_t y, size_t n) {
   // We used to crash when either of the arguments was unknown.
   return memcmp(a, &a[x*y], n) +
          memcmp(&a[x*y], a, n);
 }

 //===----------------------------------------------------------------------===
 // bcopy()
 //===----------------------------------------------------------------------===

 #define bcopy BUILTIN(bcopy)
 // __builtin_bcopy is not defined with const in Builtins.def.
 void bcopy(/*const*/ void *s1, void *s2, size_t n);


 void bcopy0 () {
   char src[] = {1, 2, 3, 4};
   char dst[4] = {0};

   bcopy(src, dst, 4); // no-warning

   // If we actually model the copy, we can make this known.
   // The important thing for now is that the old value has been invalidated.
   clang_analyzer_eval(dst[0] != 0); // expected-warning{{UNKNOWN}}
 }

 void bcopy1 () {
   char src[] = {1, 2, 3, 4};
   char dst[10];

   bcopy(src, dst, 5); // expected-warning{{out-of-bound}}
 }

 void bcopy2 () {
   char src[] = {1, 2, 3, 4};
   char dst[1];

   bcopy(src, dst, 4); // expected-warning{{overflow}}
 }

 void *malloc(size_t);
 void free(void *);
 char radar_11125445_memcopythenlogfirstbyte(const char *input, size_t length) {
   char *bytes = malloc(sizeof(char) * (length + 1));
   memcpy(bytes, input, length);
   char x = bytes[0]; // no warning
   free(bytes);
   return x;
 }

 struct S {
   char f;
 };

 void nocrash_on_locint_offset(void *addr, void* from, struct S s) {
   int iAdd = (int) addr;
   memcpy(((void *) &(s.f)), from, iAdd);
 }
	// RUN: %clang_analyze_cc1 -analyzer-checker=core,unix.cstring,alpha.unix.cstring,debug.ExprInspection -analyzer-store=region -verify %s
	// RUN: %clang_analyze_cc1 -DUSE_BUILTINS -analyzer-checker=core,unix.cstring,alpha.unix.cstring,debug.ExprInspection -analyzer-store=region -verify %s
	// RUN: %clang_analyze_cc1 -DVARIANT -analyzer-checker=core,unix.cstring,alpha.unix.cstring,debug.ExprInspection -analyzer-store=region -verify %s
	// RUN: %clang_analyze_cc1 -DUSE_BUILTINS -DVARIANT -analyzer-checker=core,unix.cstring,alpha.unix.cstring,debug.ExprInspection -analyzer-store=region -verify %s

	//===----------------------------------------------------------------------===
	// Declarations
	//===----------------------------------------------------------------------===

	// Some functions are so similar to each other that they follow the same code
	// path, such as memcpy and __memcpy_chk, or memcmp and bcmp. If VARIANT is
	// defined, make sure to use the variants instead to make sure they are still
	// checked by the analyzer.

	// Some functions are implemented as builtins. These should be #defined as
	// BUILTIN(f), which will prepend "__builtin_" if USE_BUILTINS is defined.

	// Functions that have variants and are also available as builtins should be
	// declared carefully! See memcpy() for an example.

	#ifdef USE_BUILTINS
	# define BUILTIN(f) __builtin_ ## f
	#else /* USE_BUILTINS */
	# define BUILTIN(f) f
	#endif /* USE_BUILTINS */

	typedef typeof(sizeof(int)) size_t;

	void clang_analyzer_eval(int);

	//===----------------------------------------------------------------------===
	// memcpy()
	//===----------------------------------------------------------------------===

	#ifdef VARIANT

	#define __memcpy_chk BUILTIN(__memcpy_chk)
	void __memcpy_chk(void restrict s1, const void *restrict s2, size_t n,
	size_t destlen);

	#define memcpy(a,b,c) __memcpy_chk(a,b,c,(size_t)-1)

	#else /* VARIANT */

	#define memcpy BUILTIN(memcpy)
	void memcpy(void restrict s1, const void *restrict s2, size_t n);

	#endif /* VARIANT */


	void memcpy0 () {
	char src[] = {1, 2, 3, 4};
	char dst[4] = {0};

	memcpy(dst, src, 4); // no-warning

	clang_analyzer_eval(memcpy(dst, src, 4) == dst); // expected-warning{{TRUE}}

	// If we actually model the copy, we can make this known.
	// The important thing for now is that the old value has been invalidated.
	clang_analyzer_eval(dst[0] != 0); // expected-warning{{UNKNOWN}}
	}

	void memcpy1 () {
	char src[] = {1, 2, 3, 4};
	char dst[10];

	memcpy(dst, src, 5); // expected-warning{{Memory copy function accesses out-of-bound array element}}
	}

	void memcpy2 () {
	char src[] = {1, 2, 3, 4};
	char dst[1];

	memcpy(dst, src, 4); // expected-warning{{Memory copy function overflows destination buffer}}
	}

	void memcpy3 () {
	char src[] = {1, 2, 3, 4};
	char dst[3];

	memcpy(dst+1, src+2, 2); // no-warning
	}

	void memcpy4 () {
	char src[] = {1, 2, 3, 4};
	char dst[10];

	memcpy(dst+2, src+2, 3); // expected-warning{{Memory copy function accesses out-of-bound array element}}
	}

	void memcpy5() {
	char src[] = {1, 2, 3, 4};
	char dst[3];

	memcpy(dst+2, src+2, 2); // expected-warning{{Memory copy function overflows destination buffer}}
	}

	void memcpy6() {
	int a[4] = {0};
	memcpy(a, a, 8); // expected-warning{{overlapping}}
	}

	void memcpy7() {
	int a[4] = {0};
	memcpy(a+2, a+1, 8); // expected-warning{{overlapping}}
	}

	void memcpy8() {
	int a[4] = {0};
	memcpy(a+1, a+2, 8); // expected-warning{{overlapping}}
	}

	void memcpy9() {
	int a[4] = {0};
	memcpy(a+2, a+1, 4); // no-warning
	memcpy(a+1, a+2, 4); // no-warning
	}

	void memcpy10() {
	char a[4] = {0};
	memcpy(0, a, 4); // expected-warning{{Null pointer argument in call to memory copy function}}
	}

	void memcpy11() {
	char a[4] = {0};
	memcpy(a, 0, 4); // expected-warning{{Null pointer argument in call to memory copy function}}
	}

	void memcpy12() {
	char a[4] = {0};
	memcpy(0, a, 0); // no-warning
	}

	void memcpy13() {
	char a[4] = {0};
	memcpy(a, 0, 0); // no-warning
	}

	void memcpy_unknown_size (size_t n) {
	char a[4], b[4] = {1};
	clang_analyzer_eval(memcpy(a, b, n) == a); // expected-warning{{TRUE}}
	}

	void memcpy_unknown_size_warn (size_t n) {
	char a[4];
	void *result = memcpy(a, 0, n); // expected-warning{{Null pointer argument in call to memory copy function}}
	clang_analyzer_eval(result == a); // no-warning (above is fatal)
	}

	//===----------------------------------------------------------------------===
	// mempcpy()
	//===----------------------------------------------------------------------===

	#ifdef VARIANT

	#define __mempcpy_chk BUILTIN(__mempcpy_chk)
	void __mempcpy_chk(void restrict s1, const void *restrict s2, size_t n,
	size_t destlen);

	#define mempcpy(a,b,c) __mempcpy_chk(a,b,c,(size_t)-1)

	#else /* VARIANT */

	#define mempcpy BUILTIN(mempcpy)
	void mempcpy(void restrict s1, const void *restrict s2, size_t n);

	#endif /* VARIANT */


	void mempcpy0 () {
	char src[] = {1, 2, 3, 4};
	char dst[5] = {0};

	mempcpy(dst, src, 4); // no-warning

	clang_analyzer_eval(mempcpy(dst, src, 4) == &dst[4]); // expected-warning{{TRUE}}

	// If we actually model the copy, we can make this known.
	// The important thing for now is that the old value has been invalidated.
	clang_analyzer_eval(dst[0] != 0); // expected-warning{{UNKNOWN}}
	}

	void mempcpy1 () {
	char src[] = {1, 2, 3, 4};
	char dst[10];

	mempcpy(dst, src, 5); // expected-warning{{Memory copy function accesses out-of-bound array element}}
	}

	void mempcpy2 () {
	char src[] = {1, 2, 3, 4};
	char dst[1];

	mempcpy(dst, src, 4); // expected-warning{{Memory copy function overflows destination buffer}}
	}

	void mempcpy3 () {
	char src[] = {1, 2, 3, 4};
	char dst[3];

	mempcpy(dst+1, src+2, 2); // no-warning
	}

	void mempcpy4 () {
	char src[] = {1, 2, 3, 4};
	char dst[10];

	mempcpy(dst+2, src+2, 3); // expected-warning{{Memory copy function accesses out-of-bound array element}}
	}

	void mempcpy5() {
	char src[] = {1, 2, 3, 4};
	char dst[3];

	mempcpy(dst+2, src+2, 2); // expected-warning{{Memory copy function overflows destination buffer}}
	}

	void mempcpy6() {
	int a[4] = {0};
	mempcpy(a, a, 8); // expected-warning{{overlapping}}
	}

	void mempcpy7() {
	int a[4] = {0};
	mempcpy(a+2, a+1, 8); // expected-warning{{overlapping}}
	}

	void mempcpy8() {
	int a[4] = {0};
	mempcpy(a+1, a+2, 8); // expected-warning{{overlapping}}
	}

	void mempcpy9() {
	int a[4] = {0};
	mempcpy(a+2, a+1, 4); // no-warning
	mempcpy(a+1, a+2, 4); // no-warning
	}

	void mempcpy10() {
	char a[4] = {0};
	mempcpy(0, a, 4); // expected-warning{{Null pointer argument in call to memory copy function}}
	}

	void mempcpy11() {
	char a[4] = {0};
	mempcpy(a, 0, 4); // expected-warning{{Null pointer argument in call to memory copy function}}
	}

	void mempcpy12() {
	char a[4] = {0};
	mempcpy(0, a, 0); // no-warning
	}

	void mempcpy13() {
	char a[4] = {0};
	mempcpy(a, 0, 0); // no-warning
	}

	void mempcpy14() {
	int src[] = {1, 2, 3, 4};
	int dst[5] = {0};
	int *p;

	p = mempcpy(dst, src, 4 * sizeof(int));

	clang_analyzer_eval(p == &dst[4]); // expected-warning{{TRUE}}
	}

	struct st {
	int i;
	int j;
	};

	void mempcpy15() {
	struct st s1 = {0};
	struct st s2;
	struct st *p1;
	struct st *p2;

	p1 = (&s2) + 1;
	p2 = mempcpy(&s2, &s1, sizeof(struct st));

	clang_analyzer_eval(p1 == p2); // expected-warning{{TRUE}}
	}

	void mempcpy16() {
	struct st s1[10] = {{0}};
	struct st s2[10];
	struct st *p1;
	struct st *p2;

	p1 = (&s2[0]) + 5;
	p2 = mempcpy(&s2[0], &s1[0], 5 * sizeof(struct st));

	clang_analyzer_eval(p1 == p2); // expected-warning{{TRUE}}
	}

	void mempcpy_unknown_size_warn (size_t n) {
	char a[4];
	void *result = mempcpy(a, 0, n); // expected-warning{{Null pointer argument in call to memory copy function}}
	clang_analyzer_eval(result == a); // no-warning (above is fatal)
	}

	void mempcpy_unknownable_size (char *src, float n) {
	char a[4];
	// This used to crash because we don't model floats.
	mempcpy(a, src, (size_t)n);
	}

	//===----------------------------------------------------------------------===
	// memmove()
	//===----------------------------------------------------------------------===

	#ifdef VARIANT

	#define __memmove_chk BUILTIN(__memmove_chk)
	void __memmove_chk(void s1, const void *s2, size_t n, size_t destlen);

	#define memmove(a,b,c) __memmove_chk(a,b,c,(size_t)-1)

	#else /* VARIANT */

	#define memmove BUILTIN(memmove)
	void memmove(void s1, const void *s2, size_t n);

	#endif /* VARIANT */


	void memmove0 () {
	char src[] = {1, 2, 3, 4};
	char dst[4] = {0};

	memmove(dst, src, 4); // no-warning

	clang_analyzer_eval(memmove(dst, src, 4) == dst); // expected-warning{{TRUE}}

	// If we actually model the copy, we can make this known.
	// The important thing for now is that the old value has been invalidated.
	clang_analyzer_eval(dst[0] != 0); // expected-warning{{UNKNOWN}}
	}

	void memmove1 () {
	char src[] = {1, 2, 3, 4};
	char dst[10];

	memmove(dst, src, 5); // expected-warning{{out-of-bound}}
	}

	void memmove2 () {
	char src[] = {1, 2, 3, 4};
	char dst[1];

	memmove(dst, src, 4); // expected-warning{{overflow}}
	}

	//===----------------------------------------------------------------------===
	// memcmp()
	//===----------------------------------------------------------------------===

	#ifdef VARIANT

	#define bcmp BUILTIN(bcmp)
	// __builtin_bcmp is not defined with const in Builtins.def.
	int bcmp(/const/ void s1, /const/ void s2, size_t n);
	#define memcmp bcmp
	//
	#else /* VARIANT */

	#define memcmp BUILTIN(memcmp)
	int memcmp(const void s1, const void s2, size_t n);

	#endif /* VARIANT */


	void memcmp0 () {
	char a[] = {1, 2, 3, 4};
	char b[4] = { 0 };

	memcmp(a, b, 4); // no-warning
	}

	void memcmp1 () {
	char a[] = {1, 2, 3, 4};
	char b[10] = { 0 };

	memcmp(a, b, 5); // expected-warning{{out-of-bound}}
	}

	void memcmp2 () {
	char a[] = {1, 2, 3, 4};
	char b[1] = { 0 };

	memcmp(a, b, 4); // expected-warning{{out-of-bound}}
	}

	void memcmp3 () {
	char a[] = {1, 2, 3, 4};

	clang_analyzer_eval(memcmp(a, a, 4) == 0); // expected-warning{{TRUE}}
	}

	void memcmp4 (char *input) {
	char a[] = {1, 2, 3, 4};

	clang_analyzer_eval(memcmp(a, input, 4) == 0); // expected-warning{{UNKNOWN}}
	}

	void memcmp5 (char *input) {
	char a[] = {1, 2, 3, 4};

	clang_analyzer_eval(memcmp(a, 0, 0) == 0); // expected-warning{{TRUE}}
	clang_analyzer_eval(memcmp(0, a, 0) == 0); // expected-warning{{TRUE}}
	clang_analyzer_eval(memcmp(a, input, 0) == 0); // expected-warning{{TRUE}}
	}

	void memcmp6 (char a, char b, size_t n) {
	int result = memcmp(a, b, n);
	if (result != 0)
	clang_analyzer_eval(n != 0); // expected-warning{{TRUE}}
	// else
	// analyzer_assert_unknown(n == 0);

	// We can't do the above comparison because n has already been constrained.
	// On one path n == 0, on the other n != 0.
	}

	int memcmp7 (char *a, size_t x, size_t y, size_t n) {
	// We used to crash when either of the arguments was unknown.
	return memcmp(a, &a[x*y], n) +
	memcmp(&a[x*y], a, n);
	}

	//===----------------------------------------------------------------------===
	// bcopy()
	//===----------------------------------------------------------------------===

	#define bcopy BUILTIN(bcopy)
	// __builtin_bcopy is not defined with const in Builtins.def.
	void bcopy(/const/ void s1, void s2, size_t n);


	void bcopy0 () {
	char src[] = {1, 2, 3, 4};
	char dst[4] = {0};

	bcopy(src, dst, 4); // no-warning

	// If we actually model the copy, we can make this known.
	// The important thing for now is that the old value has been invalidated.
	clang_analyzer_eval(dst[0] != 0); // expected-warning{{UNKNOWN}}
	}

	void bcopy1 () {
	char src[] = {1, 2, 3, 4};
	char dst[10];

	bcopy(src, dst, 5); // expected-warning{{out-of-bound}}
	}

	void bcopy2 () {
	char src[] = {1, 2, 3, 4};
	char dst[1];

	bcopy(src, dst, 4); // expected-warning{{overflow}}
	}

	void *malloc(size_t);
	void free(void *);
	char radar_11125445_memcopythenlogfirstbyte(const char *input, size_t length) {
	char bytes = malloc(sizeof(char) (length + 1));
	memcpy(bytes, input, length);
	char x = bytes[0]; // no warning
	free(bytes);
	return x;
	}

	struct S {
	char f;
	};

	void nocrash_on_locint_offset(void addr, void from, struct S s) {
	int iAdd = (int) addr;
	memcpy(((void *) &(s.f)), from, iAdd);
	}