1. Available Checkers

The analyzer performs checks that are categorized into families or “checkers”.

The default set of checkers covers a variety of checks targeted at finding security and API usage bugs, dead code, and other logic errors. See the Default Checkers checkers list below.

In addition to these, the analyzer contains a number of Experimental Checkers (aka alpha checkers). These checkers are under development and are switched off by default. They may crash or emit a higher number of false positives.

The debug package contains checkers for analyzer developers for debugging purposes.

Table of Contents

1.1. Default Checkers

1.1.1. core

Models core language features and contains general-purpose checkers such as division by zero, null pointer dereference, usage of uninitialized values, etc. These checkers must be always switched on as other checker rely on them.

1.1.1.1. core.CallAndMessage (C, C++, ObjC)

Check for logical errors for function calls and Objective-C message expressions (e.g., uninitialized arguments, null function pointers).

//C
void test() {
   void (*foo)(void);
   foo = 0;
   foo(); // warn: function pointer is null
 }

 // C++
 class C {
 public:
   void f();
 };

 void test() {
   C *pc;
   pc->f(); // warn: object pointer is uninitialized
 }

 // C++
 class C {
 public:
   void f();
 };

 void test() {
   C *pc = 0;
   pc->f(); // warn: object pointer is null
 }

 // Objective-C
 @interface MyClass : NSObject
 @property (readwrite,assign) id x;
 - (long double)longDoubleM;
 @end

 void test() {
   MyClass *obj1;
   long double ld1 = [obj1 longDoubleM];
     // warn: receiver is uninitialized
 }

 // Objective-C
 @interface MyClass : NSObject
 @property (readwrite,assign) id x;
 - (long double)longDoubleM;
 @end

 void test() {
   MyClass *obj1;
   id i = obj1.x; // warn: uninitialized object pointer
 }

 // Objective-C
 @interface Subscriptable : NSObject
 - (id)objectAtIndexedSubscript:(unsigned int)index;
 @end

 @interface MyClass : Subscriptable
 @property (readwrite,assign) id x;
 - (long double)longDoubleM;
 @end

 void test() {
   MyClass *obj1;
   id i = obj1[0]; // warn: uninitialized object pointer
 }

1.1.1.2. core.DivideZero (C, C++, ObjC)

Check for division by zero.

void test(int z) {
  if (z == 0)
    int x = 1 / z; // warn
}

void test() {
  int x = 1;
  int y = x % 0; // warn
}

1.1.1.3. core.NonNullParamChecker (C, C++, ObjC)

Check for null pointers passed as arguments to a function whose arguments are references or marked with the ‘nonnull’ attribute.

int f(int *p) __attribute__((nonnull));

void test(int *p) {
  if (!p)
    f(p); // warn
}

1.1.1.4. core.NullDereference (C, C++, ObjC)

Check for dereferences of null pointers.

// C
void test(int *p) {
  if (p)
    return;

  int x = p[0]; // warn
}

// C
void test(int *p) {
  if (!p)
    *p = 0; // warn
}

// C++
class C {
public:
  int x;
};

void test() {
  C *pc = 0;
  int k = pc->x; // warn
}

// Objective-C
@interface MyClass {
@public
  int x;
}
@end

void test() {
  MyClass *obj = 0;
  obj->x = 1; // warn
}

1.1.1.5. core.StackAddressEscape (C)

Check that addresses to stack memory do not escape the function.

char const *p;

void test() {
  char const str[] = "string";
  p = str; // warn
}

void* test() {
   return __builtin_alloca(12); // warn
}

void test() {
  static int *x;
  int y;
  x = &y; // warn
}

1.1.1.6. core.UndefinedBinaryOperatorResult (C)

Check for undefined results of binary operators.

void test() {
  int x;
  int y = x + 1; // warn: left operand is garbage
}

1.1.1.7. core.VLASize (C)

Check for declarations of Variable Length Arrays of undefined or zero size.

Check for declarations of VLA of undefined or zero size.

void test() {
  int x;
  int vla1[x]; // warn: garbage as size
}

void test() {
  int x = 0;
  int vla2[x]; // warn: zero size
}

1.1.1.8. core.uninitialized.ArraySubscript (C)

Check for uninitialized values used as array subscripts.

void test() {
  int i, a[10];
  int x = a[i]; // warn: array subscript is undefined
}

1.1.1.9. core.uninitialized.Assign (C)

Check for assigning uninitialized values.

void test() {
  int x;
  x |= 1; // warn: left expression is uninitialized
}

1.1.1.10. core.uninitialized.Branch (C)

Check for uninitialized values used as branch conditions.

void test() {
  int x;
  if (x) // warn
    return;
}

1.1.1.11. core.uninitialized.CapturedBlockVariable (C)

Check for blocks that capture uninitialized values.

void test() {
  int x;
  ^{ int y = x; }(); // warn
}

1.1.1.12. core.uninitialized.UndefReturn (C)

Check for uninitialized values being returned to the caller.

int test() {
  int x;
  return x; // warn
}

1.1.2. cplusplus

C++ Checkers.

1.1.2.1. cplusplus.InnerPointer (C++)

Check for inner pointers of C++ containers used after re/deallocation.

Many container methods in the C++ standard library are known to invalidate “references” (including actual references, iterators and raw pointers) to elements of the container. Using such references after they are invalidated causes undefined behavior, which is a common source of memory errors in C++ that this checker is capable of finding.

The checker is currently limited to std::string objects and doesn’t recognize some of the more sophisticated approaches to passing unowned pointers around, such as std::string_view.

void deref_after_assignment() {
  std::string s = "llvm";
  const char *c = s.data(); // note: pointer to inner buffer of 'std::string' obtained here
  s = "clang"; // note: inner buffer of 'std::string' reallocated by call to 'operator='
  consume(c); // warn: inner pointer of container used after re/deallocation
}

const char *return_temp(int x) {
  return std::to_string(x).c_str(); // warn: inner pointer of container used after re/deallocation
  // note: pointer to inner buffer of 'std::string' obtained here
  // note: inner buffer of 'std::string' deallocated by call to destructor
}

1.1.2.2. cplusplus.NewDelete (C++)

Check for double-free and use-after-free problems. Traces memory managed by new/delete.

void f(int *p);

void testUseMiddleArgAfterDelete(int *p) {
  delete p;
  f(p); // warn: use after free
}

class SomeClass {
public:
  void f();
};

void test() {
  SomeClass *c = new SomeClass;
  delete c;
  c->f(); // warn: use after free
}

void test() {
  int *p = (int *)__builtin_alloca(sizeof(int));
  delete p; // warn: deleting memory allocated by alloca
}

void test() {
  int *p = new int;
  delete p;
  delete p; // warn: attempt to free released
}

void test() {
  int i;
  delete &i; // warn: delete address of local
}

void test() {
  int *p = new int[1];
  delete[] (++p);
    // warn: argument to 'delete[]' is offset by 4 bytes
    // from the start of memory allocated by 'new[]'
}

1.1.2.3. cplusplus.NewDeleteLeaks (C++)

Check for memory leaks. Traces memory managed by new/delete.

void test() {
  int *p = new int;
} // warn

1.1.2.4. cplusplus.PlacementNewChecker (C++)

Check if default placement new is provided with pointers to sufficient storage capacity.

#include <new>

void f() {
  short s;
  long *lp = ::new (&s) long; // warn
}

1.1.2.5. cplusplus.SelfAssignment (C++)

Checks C++ copy and move assignment operators for self assignment.

1.1.3. deadcode

Dead Code Checkers.

1.1.3.1. deadcode.DeadStores (C)

Check for values stored to variables that are never read afterwards.

void test() {
  int x;
  x = 1; // warn
}

The WarnForDeadNestedAssignments option enables the checker to emit warnings for nested dead assignments. You can disable with the -analyzer-config deadcode.DeadStores:WarnForDeadNestedAssignments=false. Defaults to true.

Would warn for this e.g.: if ((y = make_int())) { }

1.1.4. nullability

Objective C checkers that warn for null pointer passing and dereferencing errors.

1.1.4.1. nullability.NullPassedToNonnull (ObjC)

Warns when a null pointer is passed to a pointer which has a _Nonnull type.

if (name != nil)
  return;
// Warning: nil passed to a callee that requires a non-null 1st parameter
NSString *greeting = [@"Hello " stringByAppendingString:name];

1.1.4.2. nullability.NullReturnedFromNonnull (ObjC)

Warns when a null pointer is returned from a function that has _Nonnull return type.

- (nonnull id)firstChild {
  id result = nil;
  if ([_children count] > 0)
    result = _children[0];

  // Warning: nil returned from a method that is expected
  // to return a non-null value
  return result;
}

1.1.4.3. nullability.NullableDereferenced (ObjC)

Warns when a nullable pointer is dereferenced.

struct LinkedList {
  int data;
  struct LinkedList *next;
};

struct LinkedList * _Nullable getNext(struct LinkedList *l);

void updateNextData(struct LinkedList *list, int newData) {
  struct LinkedList *next = getNext(list);
  // Warning: Nullable pointer is dereferenced
  next->data = 7;
}

1.1.4.4. nullability.NullablePassedToNonnull (ObjC)

Warns when a nullable pointer is passed to a pointer which has a _Nonnull type.

typedef struct Dummy { int val; } Dummy;
Dummy *_Nullable returnsNullable();
void takesNonnull(Dummy *_Nonnull);

void test() {
  Dummy *p = returnsNullable();
  takesNonnull(p); // warn
}

1.1.4.5. nullability.NullableReturnedFromNonnull (ObjC)

Warns when a nullable pointer is returned from a function that has _Nonnull return type.

1.1.5. optin

Checkers for portability, performance or coding style specific rules.

1.1.5.1. optin.cplusplus.UninitializedObject (C++)

This checker reports uninitialized fields in objects created after a constructor call. It doesn’t only find direct uninitialized fields, but rather makes a deep inspection of the object, analyzing all of its fields’ subfields. The checker regards inherited fields as direct fields, so one will receive warnings for uninitialized inherited data members as well.

// With Pedantic and CheckPointeeInitialization set to true

struct A {
  struct B {
    int x; // note: uninitialized field 'this->b.x'
    // note: uninitialized field 'this->bptr->x'
    int y; // note: uninitialized field 'this->b.y'
    // note: uninitialized field 'this->bptr->y'
  };
  int *iptr; // note: uninitialized pointer 'this->iptr'
  B b;
  B *bptr;
  char *cptr; // note: uninitialized pointee 'this->cptr'

  A (B *bptr, char *cptr) : bptr(bptr), cptr(cptr) {}
};

void f() {
  A::B b;
  char c;
  A a(&b, &c); // warning: 6 uninitialized fields
 //          after the constructor call
}

// With Pedantic set to false and
// CheckPointeeInitialization set to true
// (every field is uninitialized)

struct A {
  struct B {
    int x;
    int y;
  };
  int *iptr;
  B b;
  B *bptr;
  char *cptr;

  A (B *bptr, char *cptr) : bptr(bptr), cptr(cptr) {}
};

void f() {
  A::B b;
  char c;
  A a(&b, &c); // no warning
}

// With Pedantic set to true and
// CheckPointeeInitialization set to false
// (pointees are regarded as initialized)

struct A {
  struct B {
    int x; // note: uninitialized field 'this->b.x'
    int y; // note: uninitialized field 'this->b.y'
  };
  int *iptr; // note: uninitialized pointer 'this->iptr'
  B b;
  B *bptr;
  char *cptr;

  A (B *bptr, char *cptr) : bptr(bptr), cptr(cptr) {}
};

void f() {
  A::B b;
  char c;
  A a(&b, &c); // warning: 3 uninitialized fields
 //          after the constructor call
}

Options

This checker has several options which can be set from command line (e.g. -analyzer-config optin.cplusplus.UninitializedObject:Pedantic=true):

  • Pedantic (boolean). If to false, the checker won’t emit warnings for objects that don’t have at least one initialized field. Defaults to false.

  • NotesAsWarnings (boolean). If set to true, the checker will emit a warning for each uninitialized field, as opposed to emitting one warning per constructor call, and listing the uninitialized fields that belongs to it in notes. Defaults to false.

  • CheckPointeeInitialization (boolean). If set to false, the checker will not analyze the pointee of pointer/reference fields, and will only check whether the object itself is initialized. Defaults to false.

  • IgnoreRecordsWithField (string). If supplied, the checker will not analyze structures that have a field with a name or type name that matches the given pattern. Defaults to “”.

1.1.5.2. optin.cplusplus.VirtualCall (C++)

Check virtual function calls during construction or destruction.

class A {
public:
  A() {
    f(); // warn
  }
  virtual void f();
};

class A {
public:
  ~A() {
    this->f(); // warn
  }
  virtual void f();
};

1.1.5.3. optin.mpi.MPI-Checker (C)

Checks MPI code.

void test() {
  double buf = 0;
  MPI_Request sendReq1;
  MPI_Ireduce(MPI_IN_PLACE, &buf, 1, MPI_DOUBLE, MPI_SUM,
      0, MPI_COMM_WORLD, &sendReq1);
} // warn: request 'sendReq1' has no matching wait.

void test() {
  double buf = 0;
  MPI_Request sendReq;
  MPI_Isend(&buf, 1, MPI_DOUBLE, 0, 0, MPI_COMM_WORLD, &sendReq);
  MPI_Irecv(&buf, 1, MPI_DOUBLE, 0, 0, MPI_COMM_WORLD, &sendReq); // warn
  MPI_Isend(&buf, 1, MPI_DOUBLE, 0, 0, MPI_COMM_WORLD, &sendReq); // warn
  MPI_Wait(&sendReq, MPI_STATUS_IGNORE);
}

void missingNonBlocking() {
  int rank = 0;
  MPI_Comm_rank(MPI_COMM_WORLD, &rank);
  MPI_Request sendReq1[10][10][10];
  MPI_Wait(&sendReq1[1][7][9], MPI_STATUS_IGNORE); // warn
}

1.1.5.4. optin.osx.cocoa.localizability.EmptyLocalizationContextChecker (ObjC)

Check that NSLocalizedString macros include a comment for context.

- (void)test {
  NSString *string = NSLocalizedString(@"LocalizedString", nil); // warn
  NSString *string2 = NSLocalizedString(@"LocalizedString", @" "); // warn
  NSString *string3 = NSLocalizedStringWithDefaultValue(
    @"LocalizedString", nil, [[NSBundle alloc] init], nil,@""); // warn
}

1.1.5.5. optin.osx.cocoa.localizability.NonLocalizedStringChecker (ObjC)

Warns about uses of non-localized NSStrings passed to UI methods expecting localized NSStrings.

NSString *alarmText =
  NSLocalizedString(@"Enabled", @"Indicates alarm is turned on");
if (!isEnabled) {
  alarmText = @"Disabled";
}
UILabel *alarmStateLabel = [[UILabel alloc] init];

// Warning: User-facing text should use localized string macro
[alarmStateLabel setText:alarmText];

1.1.5.6. optin.performance.GCDAntipattern

Check for performance anti-patterns when using Grand Central Dispatch.

1.1.5.7. optin.performance.Padding

Check for excessively padded structs.

1.1.5.8. optin.portability.UnixAPI

Finds implementation-defined behavior in UNIX/Posix functions.

1.1.6. security

Security related checkers.

1.1.6.1. security.FloatLoopCounter (C)

Warn on using a floating point value as a loop counter (CERT: FLP30-C, FLP30-CPP).

void test() {
  for (float x = 0.1f; x <= 1.0f; x += 0.1f) {} // warn
}

1.1.6.2. security.insecureAPI.UncheckedReturn (C)

Warn on uses of functions whose return values must be always checked.

void test() {
  setuid(1); // warn
}

1.1.6.3. security.insecureAPI.bcmp (C)

Warn on uses of the ‘bcmp’ function.

void test() {
  bcmp(ptr0, ptr1, n); // warn
}

1.1.6.4. security.insecureAPI.bcopy (C)

Warn on uses of the ‘bcopy’ function.

void test() {
  bcopy(src, dst, n); // warn
}

1.1.6.5. security.insecureAPI.bzero (C)

Warn on uses of the ‘bzero’ function.

void test() {
  bzero(ptr, n); // warn
}

1.1.6.6. security.insecureAPI.getpw (C)

Warn on uses of the ‘getpw’ function.

void test() {
  char buff[1024];
  getpw(2, buff); // warn
}

1.1.6.7. security.insecureAPI.gets (C)

Warn on uses of the ‘gets’ function.

void test() {
  char buff[1024];
  gets(buff); // warn
}

1.1.6.8. security.insecureAPI.mkstemp (C)

Warn when ‘mkstemp’ is passed fewer than 6 X’s in the format string.

void test() {
  mkstemp("XX"); // warn
}

1.1.6.9. security.insecureAPI.mktemp (C)

Warn on uses of the mktemp function.

void test() {
  char *x = mktemp("/tmp/zxcv"); // warn: insecure, use mkstemp
}

1.1.6.10. security.insecureAPI.rand (C)

Warn on uses of inferior random number generating functions (only if arc4random function is available): drand48, erand48, jrand48, lcong48, lrand48, mrand48, nrand48, random, rand_r.

void test() {
  random(); // warn
}

1.1.6.11. security.insecureAPI.strcpy (C)

Warn on uses of the strcpy and strcat functions.

void test() {
  char x[4];
  char *y = "abcd";

  strcpy(x, y); // warn
}

1.1.6.12. security.insecureAPI.vfork (C)

Warn on uses of the ‘vfork’ function.

void test() {
  vfork(); // warn
}

1.1.6.13. security.insecureAPI.DeprecatedOrUnsafeBufferHandling (C)

Warn on occurrences of unsafe or deprecated buffer handling functions, which now have a secure variant: sprintf, vsprintf, scanf, wscanf, fscanf, fwscanf, vscanf, vwscanf, vfscanf, vfwscanf, sscanf, swscanf, vsscanf, vswscanf, swprintf, snprintf, vswprintf, vsnprintf, memcpy, memmove, strncpy, strncat, memset

void test() {
  char buf [5];
  strncpy(buf, "a", 1); // warn
}

1.1.7. unix

POSIX/Unix checkers.

1.1.7.1. unix.API (C)

Check calls to various UNIX/Posix functions: open, pthread_once, calloc, malloc, realloc, alloca.


// Currently the check is performed for apple targets only.
void test(const char *path) {
  int fd = open(path, O_CREAT);
    // warn: call to 'open' requires a third argument when the
    // 'O_CREAT' flag is set
}

void f();

void test() {
  pthread_once_t pred = {0x30B1BCBA, {0}};
  pthread_once(&pred, f);
    // warn: call to 'pthread_once' uses the local variable
}

void test() {
  void *p = malloc(0); // warn: allocation size of 0 bytes
}

void test() {
  void *p = calloc(0, 42); // warn: allocation size of 0 bytes
}

void test() {
  void *p = malloc(1);
  p = realloc(p, 0); // warn: allocation size of 0 bytes
}

void test() {
  void *p = alloca(0); // warn: allocation size of 0 bytes
}

void test() {
  void *p = valloc(0); // warn: allocation size of 0 bytes
}

1.1.7.2. unix.Malloc (C)

Check for memory leaks, double free, and use-after-free problems. Traces memory managed by malloc()/free().


void test() {
  int *p = malloc(1);
  free(p);
  free(p); // warn: attempt to free released memory
}

void test() {
  int *p = malloc(sizeof(int));
  free(p);
  *p = 1; // warn: use after free
}

void test() {
  int *p = malloc(1);
  if (p)
    return; // warn: memory is never released
}

void test() {
  int a[] = { 1 };
  free(a); // warn: argument is not allocated by malloc
}

void test() {
  int *p = malloc(sizeof(char));
  p = p - 1;
  free(p); // warn: argument to free() is offset by -4 bytes
}

1.1.7.3. unix.MallocSizeof (C)

Check for dubious malloc arguments involving sizeof.

void test() {
  long *p = malloc(sizeof(short));
    // warn: result is converted to 'long *', which is
    // incompatible with operand type 'short'
  free(p);
}

1.1.7.4. unix.MismatchedDeallocator (C, C++)

Check for mismatched deallocators.

// C, C++
void test() {
  int *p = (int *)malloc(sizeof(int));
  delete p; // warn
}

// C, C++
void __attribute((ownership_returns(malloc))) *user_malloc(size_t);

void test() {
  int *p = (int *)user_malloc(sizeof(int));
  delete p; // warn
}

// C, C++
void test() {
  int *p = new int;
  free(p); // warn
}

// C, C++
void test() {
  int *p = new int[1];
  realloc(p, sizeof(long)); // warn
}

// C, C++
template <typename T>
struct SimpleSmartPointer {
  T *ptr;

  explicit SimpleSmartPointer(T *p = 0) : ptr(p) {}
  ~SimpleSmartPointer() {
    delete ptr; // warn
  }
};

void test() {
  SimpleSmartPointer<int> a((int *)malloc(4));
}

// C++
void test() {
  int *p = (int *)operator new(0);
  delete[] p; // warn
}

// Objective-C, C++
void test(NSUInteger dataLength) {
  int *p = new int;
  NSData *d = [NSData dataWithBytesNoCopy:p
               length:sizeof(int) freeWhenDone:1];
    // warn +dataWithBytesNoCopy:length:freeWhenDone: cannot take
    // ownership of memory allocated by 'new'
}

1.1.7.5. unix.Vfork (C)

Check for proper usage of vfork.

int test(int x) {
  pid_t pid = vfork(); // warn
  if (pid != 0)
    return 0;

  switch (x) {
  case 0:
    pid = 1;
    execl("", "", 0);
    _exit(1);
    break;
  case 1:
    x = 0; // warn: this assignment is prohibited
    break;
  case 2:
    foo(); // warn: this function call is prohibited
    break;
  default:
    return 0; // warn: return is prohibited
  }

  while(1);
}

1.1.7.6. unix.cstring.BadSizeArg (C)

Check the size argument passed into C string functions for common erroneous patterns. Use -Wno-strncat-size compiler option to mute other strncat-related compiler warnings.

void test() {
  char dest[3];
  strncat(dest, """""""""""""""""""""""""*", sizeof(dest));
    // warn: potential buffer overflow
}

1.1.7.7. unix.cstrisng.NullArg (C)

Check for null pointers being passed as arguments to C string functions: strlen, strnlen, strcpy, strncpy, strcat, strncat, strcmp, strncmp, strcasecmp, strncasecmp.

int test() {
  return strlen(0); // warn
}

1.1.8. osx

macOS checkers.

1.1.8.1. osx.API (C)

Check for proper uses of various Apple APIs.

void test() {
  dispatch_once_t pred = 0;
  dispatch_once(&pred, ^(){}); // warn: dispatch_once uses local
}

1.1.8.2. osx.NumberObjectConversion (C, C++, ObjC)

Check for erroneous conversions of objects representing numbers into numbers.

NSNumber *photoCount = [albumDescriptor objectForKey:@"PhotoCount"];
// Warning: Comparing a pointer value of type 'NSNumber *'
// to a scalar integer value
if (photoCount > 0) {
  [self displayPhotos];
}

1.1.8.3. osx.ObjCProperty (ObjC)

Check for proper uses of Objective-C properties.

NSNumber *photoCount = [albumDescriptor objectForKey:@"PhotoCount"];
// Warning: Comparing a pointer value of type 'NSNumber *'
// to a scalar integer value
if (photoCount > 0) {
  [self displayPhotos];
}

1.1.8.4. osx.SecKeychainAPI (C)

Check for proper uses of Secure Keychain APIs.

void test() {
  unsigned int *ptr = 0;
  UInt32 length;

  SecKeychainItemFreeContent(ptr, &length);
    // warn: trying to free data which has not been allocated
}

void test() {
  unsigned int *ptr = 0;
  UInt32 *length = 0;
  void *outData;

  OSStatus st =
    SecKeychainItemCopyContent(2, ptr, ptr, length, outData);
    // warn: data is not released
}

void test() {
  unsigned int *ptr = 0;
  UInt32 *length = 0;
  void *outData;

  OSStatus st =
    SecKeychainItemCopyContent(2, ptr, ptr, length, &outData);

  SecKeychainItemFreeContent(ptr, outData);
    // warn: only call free if a non-NULL buffer was returned
}

void test() {
  unsigned int *ptr = 0;
  UInt32 *length = 0;
  void *outData;

  OSStatus st =
    SecKeychainItemCopyContent(2, ptr, ptr, length, &outData);

  st = SecKeychainItemCopyContent(2, ptr, ptr, length, &outData);
    // warn: release data before another call to the allocator

  if (st == noErr)
    SecKeychainItemFreeContent(ptr, outData);
}

void test() {
  SecKeychainItemRef itemRef = 0;
  SecKeychainAttributeInfo *info = 0;
  SecItemClass *itemClass = 0;
  SecKeychainAttributeList *attrList = 0;
  UInt32 *length = 0;
  void *outData = 0;

  OSStatus st =
    SecKeychainItemCopyAttributesAndData(itemRef, info,
                                         itemClass, &attrList,
                                         length, &outData);

  SecKeychainItemFreeContent(attrList, outData);
    // warn: deallocator doesn't match the allocator
}

1.1.8.5. osx.cocoa.AtSync (ObjC)

Check for nil pointers used as mutexes for @synchronized.

void test(id x) {
  if (!x)
    @synchronized(x) {} // warn: nil value used as mutex
}

void test() {
  id y;
  @synchronized(y) {} // warn: uninitialized value used as mutex
}

1.1.8.6. osx.cocoa.AutoreleaseWrite

Warn about potentially crashing writes to autoreleasing objects from different autoreleasing pools in Objective-C.

1.1.8.7. osx.cocoa.ClassRelease (ObjC)

Check for sending ‘retain’, ‘release’, or ‘autorelease’ directly to a Class.

@interface MyClass : NSObject
@end

void test(void) {
  [MyClass release]; // warn
}

1.1.8.8. osx.cocoa.Dealloc (ObjC)

Warn about Objective-C classes that lack a correct implementation of -dealloc

@interface MyObject : NSObject {
  id _myproperty;
}
@end

@implementation MyObject // warn: lacks 'dealloc'
@end

@interface MyObject : NSObject {}
@property(assign) id myproperty;
@end

@implementation MyObject // warn: does not send 'dealloc' to super
- (void)dealloc {
  self.myproperty = 0;
}
@end

@interface MyObject : NSObject {
  id _myproperty;
}
@property(retain) id myproperty;
@end

@implementation MyObject
@synthesize myproperty = _myproperty;
  // warn: var was retained but wasn't released
- (void)dealloc {
  [super dealloc];
}
@end

@interface MyObject : NSObject {
  id _myproperty;
}
@property(assign) id myproperty;
@end

@implementation MyObject
@synthesize myproperty = _myproperty;
  // warn: var wasn't retained but was released
- (void)dealloc {
  [_myproperty release];
  [super dealloc];
}
@end

1.1.8.9. osx.cocoa.IncompatibleMethodTypes (ObjC)

Warn about Objective-C method signatures with type incompatibilities.

@interface MyClass1 : NSObject
- (int)foo;
@end

@implementation MyClass1
- (int)foo { return 1; }
@end

@interface MyClass2 : MyClass1
- (float)foo;
@end

@implementation MyClass2
- (float)foo { return 1.0; } // warn
@end

1.1.8.10. osx.cocoa.Loops

Improved modeling of loops using Cocoa collection types.

1.1.8.11. osx.cocoa.MissingSuperCall (ObjC)

Warn about Objective-C methods that lack a necessary call to super.

@interface Test : UIViewController
@end
@implementation test
- (void)viewDidLoad {} // warn
@end

1.1.8.12. osx.cocoa.NSAutoreleasePool (ObjC)

Warn for suboptimal uses of NSAutoreleasePool in Objective-C GC mode.

void test() {
  NSAutoreleasePool *pool = [[NSAutoreleasePool alloc] init];
  [pool release]; // warn
}

1.1.8.13. osx.cocoa.NSError (ObjC)

Check usage of NSError parameters.

@interface A : NSObject
- (void)foo:(NSError """""""""""""""""""""""")error;
@end

@implementation A
- (void)foo:(NSError """""""""""""""""""""""")error {
  // warn: method accepting NSError"""""""""""""""""""""""" should have a non-void
  // return value
}
@end

@interface A : NSObject
- (BOOL)foo:(NSError """""""""""""""""""""""")error;
@end

@implementation A
- (BOOL)foo:(NSError """""""""""""""""""""""")error {
  *error = 0; // warn: potential null dereference
  return 0;
}
@end

1.1.8.14. osx.cocoa.NilArg (ObjC)

Check for prohibited nil arguments to ObjC method calls.

  • caseInsensitiveCompare:

  • compare:

  • compare:options:

  • compare:options:range:

  • compare:options:range:locale:

  • componentsSeparatedByCharactersInSet:

  • initWithFormat:

NSComparisonResult test(NSString *s) {
  NSString *aString = nil;
  return [s caseInsensitiveCompare:aString];
    // warn: argument to 'NSString' method
    // 'caseInsensitiveCompare:' cannot be nil
}

1.1.8.15. osx.cocoa.NonNilReturnValue

Models the APIs that are guaranteed to return a non-nil value.

1.1.8.16. osx.cocoa.ObjCGenerics (ObjC)

Check for type errors when using Objective-C generics.

NSMutableArray *names = [NSMutableArray array];
NSMutableArray *birthDates = names;

// Warning: Conversion from value of type 'NSDate *'
// to incompatible type 'NSString *'
[birthDates addObject: [NSDate date]];

1.1.8.17. osx.cocoa.RetainCount (ObjC)

Check for leaks and improper reference count management

void test() {
  NSString *s = [[NSString alloc] init]; // warn
}

CFStringRef test(char *bytes) {
  return CFStringCreateWithCStringNoCopy(
           0, bytes, NSNEXTSTEPStringEncoding, 0); // warn
}

1.1.8.18. osx.cocoa.RunLoopAutoreleaseLeak

Check for leaked memory in autorelease pools that will never be drained.

1.1.8.19. osx.cocoa.SelfInit (ObjC)

Check that ‘self’ is properly initialized inside an initializer method.

@interface MyObj : NSObject {
  id x;
}
- (id)init;
@end

@implementation MyObj
- (id)init {
  [super init];
  x = 0; // warn: instance variable used while 'self' is not
         // initialized
  return 0;
}
@end

@interface MyObj : NSObject
- (id)init;
@end

@implementation MyObj
- (id)init {
  [super init];
  return self; // warn: returning uninitialized 'self'
}
@end

1.1.8.20. osx.cocoa.SuperDealloc (ObjC)

Warn about improper use of ‘[super dealloc]’ in Objective-C.

@interface SuperDeallocThenReleaseIvarClass : NSObject {
  NSObject *_ivar;
}
@end

@implementation SuperDeallocThenReleaseIvarClass
- (void)dealloc {
  [super dealloc];
  [_ivar release]; // warn
}
@end

1.1.8.21. osx.cocoa.UnusedIvars (ObjC)

Warn about private ivars that are never used.

@interface MyObj : NSObject {
@private
  id x; // warn
}
@end

@implementation MyObj
@end

1.1.8.22. osx.cocoa.VariadicMethodTypes (ObjC)

Check for passing non-Objective-C types to variadic collection initialization methods that expect only Objective-C types.

void test() {
  [NSSet setWithObjects:@"Foo", "Bar", nil];
    // warn: argument should be an ObjC pointer type, not 'char *'
}

1.1.8.23. osx.coreFoundation.CFError (C)

Check usage of CFErrorRef* parameters

void test(CFErrorRef *error) {
  // warn: function accepting CFErrorRef* should have a
  // non-void return
}

int foo(CFErrorRef *error) {
  *error = 0; // warn: potential null dereference
  return 0;
}

1.1.8.24. osx.coreFoundation.CFNumber (C)

Check for proper uses of CFNumber APIs.

CFNumberRef test(unsigned char x) {
  return CFNumberCreate(0, kCFNumberSInt16Type, &x);
   // warn: 8 bit integer is used to initialize a 16 bit integer
}

1.1.8.25. osx.coreFoundation.CFRetainRelease (C)

Check for null arguments to CFRetain/CFRelease/CFMakeCollectable.

void test(CFTypeRef p) {
  if (!p)
    CFRetain(p); // warn
}

void test(int x, CFTypeRef p) {
  if (p)
    return;

  CFRelease(p); // warn
}

1.1.8.26. osx.coreFoundation.containers.OutOfBounds (C)

Checks for index out-of-bounds when using ‘CFArray’ API.

void test() {
  CFArrayRef A = CFArrayCreate(0, 0, 0, &kCFTypeArrayCallBacks);
  CFArrayGetValueAtIndex(A, 0); // warn
}

1.1.8.27. osx.coreFoundation.containers.PointerSizedValues (C)

Warns if ‘CFArray’, ‘CFDictionary’, ‘CFSet’ are created with non-pointer-size values.

void test() {
  int x[] = { 1 };
  CFArrayRef A = CFArrayCreate(0, (const void """""""""""""""""""""""")x, 1,
                               &kCFTypeArrayCallBacks); // warn
}

1.1.9. Fuchsia

Fuchsia is an open source capability-based operating system currently being developed by Google. This section describes checkers that can find various misuses of Fuchsia APIs.

1.1.9.1. fuchsia.HandleChecker

Handles identify resources. Similar to pointers they can be leaked, double freed, or use after freed. This check attempts to find such problems.

void checkLeak08(int tag) {
  zx_handle_t sa, sb;
  zx_channel_create(0, &sa, &sb);
  if (tag)
    zx_handle_close(sa);
  use(sb); // Warn: Potential leak of handle
  zx_handle_close(sb);
}

1.1.10. WebKit

WebKit is an open-source web browser engine available for macOS, iOS and Linux. This section describes checkers that can find issues in WebKit codebase.

Most of the checkers focus on memory management for which WebKit uses custom implementation of reference counted smartpointers.

Checkers are formulated in terms related to ref-counting:
  • Ref-counted type is either Ref<T> or RefPtr<T>.

  • Ref-countable type is any type that implements ref() and deref() methods as RefPtr<> is a template (i. e. relies on duck typing).

  • Uncounted type is ref-countable but not ref-counted type.

1.1.10.1. webkit.RefCntblBaseVirtualDtor

All uncounted types used as base classes must have a virtual destructor.

Ref-counted types hold their ref-countable data by a raw pointer and allow implicit upcasting from ref-counted pointer to derived type to ref-counted pointer to base type. This might lead to an object of (dynamic) derived type being deleted via pointer to the base class type which C++ standard defines as UB in case the base class doesn’t have virtual destructor [expr.delete].

struct RefCntblBase {
  void ref() {}
  void deref() {}
};

struct Derived : RefCntblBase { }; // warn

1.1.10.2. webkit.NoUncountedMemberChecker

Raw pointers and references to uncounted types can’t be used as class members. Only ref-counted types are allowed.

struct RefCntbl {
  void ref() {}
  void deref() {}
};

struct Foo {
  RefCntbl * ptr; // warn
  RefCntbl & ptr; // warn
  // ...
};

1.1.10.3. webkit.UncountedLambdaCapturesChecker

Raw pointers and references to uncounted types can’t be captured in lambdas. Only ref-counted types are allowed.

struct RefCntbl {
  void ref() {}
  void deref() {}
};

void foo(RefCntbl* a, RefCntbl& b) {
  [&, a](){ // warn about 'a'
    do_something(b); // warn about 'b'
  };
};

1.2. Experimental Checkers

These are checkers with known issues or limitations that keep them from being on by default. They are likely to have false positives. Bug reports and especially patches are welcome.

1.2.1. alpha.clone

1.2.1.1. alpha.clone.CloneChecker (C, C++, ObjC)

Reports similar pieces of code.

void log();

int max(int a, int b) { // warn
  log();
  if (a > b)
    return a;
  return b;
}

int maxClone(int x, int y) { // similar code here
  log();
  if (x > y)
    return x;
  return y;
}

1.2.2. alpha.core

1.2.2.1. alpha.core.BoolAssignment (ObjC)

Warn about assigning non-{0,1} values to boolean variables.

void test() {
  BOOL b = -1; // warn
}

1.2.2.2. alpha.core.C11Lock

Similarly to alpha.unix.PthreadLock, checks for the locking/unlocking of mtx_t mutexes.

mtx_t mtx1;

void bad1(void)
{
  mtx_lock(&mtx1);
  mtx_lock(&mtx1); // warn: This lock has already been acquired
}

1.2.2.3. alpha.core.CallAndMessageUnInitRefArg (C,C++, ObjC)

Check for logical errors for function calls and Objective-C message expressions (e.g., uninitialized arguments, null function pointers, and pointer to undefined variables).

void test(void) {
  int t;
  int &p = t;
  int &s = p;
  int &q = s;
  foo(q); // warn
}

void test(void) {
  int x;
  foo(&x); // warn
}

1.2.2.4. alpha.core.CastSize (C)

Check when casting a malloc’ed type T, whether the size is a multiple of the size of T.

void test() {
  int *x = (int *) malloc(11); // warn
}

1.2.2.5. alpha.core.CastToStruct (C, C++)

Check for cast from non-struct pointer to struct pointer.

// C
struct s {};

void test(int *p) {
  struct s *ps = (struct s *) p; // warn
}

// C++
class c {};

void test(int *p) {
  c *pc = (c *) p; // warn
}

1.2.2.6. alpha.core.Conversion (C, C++, ObjC)

Loss of sign/precision in implicit conversions.

void test(unsigned U, signed S) {
  if (S > 10) {
    if (U < S) {
    }
  }
  if (S < -10) {
    if (U < S) { // warn (loss of sign)
    }
  }
}

void test() {
  long long A = 1LL << 60;
  short X = A; // warn (loss of precision)
}

1.2.2.7. alpha.core.DynamicTypeChecker (ObjC)

Check for cases where the dynamic and the static type of an object are unrelated.

id date = [NSDate date];

// Warning: Object has a dynamic type 'NSDate *' which is
// incompatible with static type 'NSNumber *'"
NSNumber *number = date;
[number doubleValue];

1.2.2.8. alpha.core.FixedAddr (C)

Check for assignment of a fixed address to a pointer.

void test() {
  int *p;
  p = (int *) 0x10000; // warn
}

1.2.2.9. alpha.core.IdenticalExpr (C, C++)

Warn about unintended use of identical expressions in operators.

// C
void test() {
  int a = 5;
  int b = a | 4 | a; // warn: identical expr on both sides
}

// C++
bool f(void);

void test(bool b) {
  int i = 10;
  if (f()) { // warn: true and false branches are identical
    do {
      i--;
    } while (f());
  } else {
    do {
      i--;
    } while (f());
  }
}

1.2.2.10. alpha.core.PointerArithm (C)

Check for pointer arithmetic on locations other than array elements.

void test() {
  int x;
  int *p;
  p = &x + 1; // warn
}

1.2.2.11. alpha.core.PointerSub (C)

Check for pointer subtractions on two pointers pointing to different memory chunks.

void test() {
  int x, y;
  int d = &y - &x; // warn
}

1.2.2.12. alpha.core.SizeofPtr (C)

Warn about unintended use of sizeof() on pointer expressions.

struct s {};

int test(struct s *p) {
  return sizeof(p);
    // warn: sizeof(ptr) can produce an unexpected result
}

1.2.2.13. alpha.core.StackAddressAsyncEscape (C)

Check that addresses to stack memory do not escape the function that involves dispatch_after or dispatch_async. This checker is a part of core.StackAddressEscape, but is temporarily disabled until some false positives are fixed.

dispatch_block_t test_block_inside_block_async_leak() {
  int x = 123;
  void (^inner)(void) = ^void(void) {
    int y = x;
    ++y;
  };
  void (^outer)(void) = ^void(void) {
    int z = x;
    ++z;
    inner();
  };
  return outer; // warn: address of stack-allocated block is captured by a
                //       returned block
}

1.2.2.14. alpha.core.TestAfterDivZero (C)

Check for division by variable that is later compared against 0. Either the comparison is useless or there is division by zero.

void test(int x) {
  var = 77 / x;
  if (x == 0) { } // warn
}

1.2.3. alpha.cplusplus

1.2.3.1. alpha.cplusplus.DeleteWithNonVirtualDtor (C++)

Reports destructions of polymorphic objects with a non-virtual destructor in their base class.

NonVirtual *create() {
  NonVirtual *x = new NVDerived(); // note: conversion from derived to base
                                   //       happened here
  return x;
}

void sink(NonVirtual *x) {
  delete x; // warn: destruction of a polymorphic object with no virtual
            //       destructor
}

1.2.3.2. alpha.cplusplus.EnumCastOutOfRange (C++)

Check for integer to enumeration casts that could result in undefined values.

enum TestEnum {
  A = 0
};

void foo() {
  TestEnum t = static_cast(-1);
      // warn: the value provided to the cast expression is not in
      //       the valid range of values for the enum

1.2.3.3. alpha.cplusplus.InvalidatedIterator (C++)

Check for use of invalidated iterators.

void bad_copy_assign_operator_list1(std::list &L1,
                                    const std::list &L2) {
  auto i0 = L1.cbegin();
  L1 = L2;
  *i0; // warn: invalidated iterator accessed
}

1.2.3.4. alpha.cplusplus.IteratorRange (C++)

Check for iterators used outside their valid ranges.

void simple_bad_end(const std::vector &v) {
  auto i = v.end();
  *i; // warn: iterator accessed outside of its range
}

1.2.3.5. alpha.cplusplus.MismatchedIterator (C++)

Check for use of iterators of different containers where iterators of the same container are expected.

void bad_insert3(std::vector &v1, std::vector &v2) {
  v2.insert(v1.cbegin(), v2.cbegin(), v2.cend()); // warn: container accessed
                                                  //       using foreign
                                                  //       iterator argument
  v1.insert(v1.cbegin(), v1.cbegin(), v2.cend()); // warn: iterators of
                                                  //       different containers
                                                  //       used where the same
                                                  //       container is
                                                  //       expected
  v1.insert(v1.cbegin(), v2.cbegin(), v1.cend()); // warn: iterators of
                                                  //       different containers
                                                  //       used where the same
                                                  //       container is
                                                  //       expected
}

1.2.3.6. alpha.cplusplus.MisusedMovedObject (C++)

Method calls on a moved-from object and copying a moved-from object will be reported.

 struct A {
  void foo() {}
};

void f() {
  A a;
  A b = std::move(a); // note: 'a' became 'moved-from' here
  a.foo();            // warn: method call on a 'moved-from' object 'a'
}

1.2.4. alpha.deadcode

1.2.4.1. alpha.deadcode.UnreachableCode (C, C++)

Check unreachable code.

// C
int test() {
  int x = 1;
  while(x);
  return x; // warn
}

// C++
void test() {
  int a = 2;

  while (a > 1)
    a--;

  if (a > 1)
    a++; // warn
}

// Objective-C
void test(id x) {
  return;
  [x retain]; // warn
}

1.2.4.2. alpha.cplusplus.SmartPtr (C++)

Check for dereference of null smart pointers.

void deref_smart_ptr() {
  std::unique_ptr<int> P;
  *P; // warn: dereference of a default constructed smart unique_ptr
}

1.2.5. alpha.fuchsia

1.2.5.1. alpha.fuchsia.Lock

Similarly to alpha.unix.PthreadLock, checks for the locking/unlocking of fuchsia mutexes.

spin_lock_t mtx1;

void bad1(void)
{
  spin_lock(&mtx1);
  spin_lock(&mtx1);    // warn: This lock has already been acquired
}

1.2.6. alpha.llvm

1.2.6.1. alpha.llvm.Conventions

Check code for LLVM codebase conventions:

  • A StringRef should not be bound to a temporary std::string whose lifetime is shorter than the StringRef’s.

  • Clang AST nodes should not have fields that can allocate memory.

1.2.7. alpha.osx

1.2.7.1. alpha.osx.cocoa.DirectIvarAssignment (ObjC)

Check for direct assignments to instance variables.

@interface MyClass : NSObject {}
@property (readonly) id A;
- (void) foo;
@end

@implementation MyClass
- (void) foo {
  _A = 0; // warn
}
@end

1.2.7.2. alpha.osx.cocoa.DirectIvarAssignmentForAnnotatedFunctions (ObjC)

Check for direct assignments to instance variables in the methods annotated with objc_no_direct_instance_variable_assignment.

@interface MyClass : NSObject {}
@property (readonly) id A;
- (void) fAnnotated __attribute__((
    annotate("objc_no_direct_instance_variable_assignment")));
- (void) fNotAnnotated;
@end

@implementation MyClass
- (void) fAnnotated {
  _A = 0; // warn
}
- (void) fNotAnnotated {
  _A = 0; // no warn
}
@end

1.2.7.3. alpha.osx.cocoa.InstanceVariableInvalidation (ObjC)

Check that the invalidatable instance variables are invalidated in the methods annotated with objc_instance_variable_invalidator.

@protocol Invalidation <NSObject>
- (void) invalidate
  __attribute__((annotate("objc_instance_variable_invalidator")));
@end

@interface InvalidationImpObj : NSObject <Invalidation>
@end

@interface SubclassInvalidationImpObj : InvalidationImpObj {
  InvalidationImpObj *var;
}
- (void)invalidate;
@end

@implementation SubclassInvalidationImpObj
- (void) invalidate {}
@end
// warn: var needs to be invalidated or set to nil

1.2.7.4. alpha.osx.cocoa.MissingInvalidationMethod (ObjC)

Check that the invalidation methods are present in classes that contain invalidatable instance variables.

@protocol Invalidation <NSObject>
- (void)invalidate
  __attribute__((annotate("objc_instance_variable_invalidator")));
@end

@interface NeedInvalidation : NSObject <Invalidation>
@end

@interface MissingInvalidationMethodDecl : NSObject {
  NeedInvalidation *Var; // warn
}
@end

@implementation MissingInvalidationMethodDecl
@end

1.2.7.5. alpha.osx.cocoa.localizability.PluralMisuseChecker (ObjC)

Warns against using one vs. many plural pattern in code when generating localized strings.

NSString *reminderText =
  NSLocalizedString(@"None", @"Indicates no reminders");
if (reminderCount == 1) {
  // Warning: Plural cases are not supported across all languages.
  // Use a .stringsdict file instead
  reminderText =
    NSLocalizedString(@"1 Reminder", @"Indicates single reminder");
} else if (reminderCount >= 2) {
  // Warning: Plural cases are not supported across all languages.
  // Use a .stringsdict file instead
  reminderText =
    [NSString stringWithFormat:
      NSLocalizedString(@"%@ Reminders", @"Indicates multiple reminders"),
        reminderCount];
}

1.2.9. alpha.security.cert

SEI CERT checkers which tries to find errors based on their C coding rules.

1.2.10. alpha.security.cert.pos

SEI CERT checkers of POSIX C coding rules.

1.2.10.1. alpha.security.cert.pos.34c

Finds calls to the putenv function which pass a pointer to an automatic variable as the argument.

int func(const char *var) {
  char env[1024];
  int retval = snprintf(env, sizeof(env),"TEST=%s", var);
  if (retval < 0 || (size_t)retval >= sizeof(env)) {
      /* Handle error */
  }

  return putenv(env); // putenv function should not be called with auto variables
}

1.2.10.2. alpha.security.ArrayBound (C)

Warn about buffer overflows (older checker).

void test() {
  char *s = "";
  char c = s[1]; // warn
}

struct seven_words {
  int c[7];
};

void test() {
  struct seven_words a, *p;
  p = &a;
  p[0] = a;
  p[1] = a;
  p[2] = a; // warn
}

// note: requires unix.Malloc or
// alpha.unix.MallocWithAnnotations checks enabled.
void test() {
  int *p = malloc(12);
  p[3] = 4; // warn
}

void test() {
  char a[2];
  int *b = (int*)a;
  b[1] = 3; // warn
}

1.2.10.3. alpha.security.ArrayBoundV2 (C)

Warn about buffer overflows (newer checker).

void test() {
  char *s = "";
  char c = s[1]; // warn
}

void test() {
  int buf[100];
  int *p = buf;
  p = p + 99;
  p[1] = 1; // warn
}

// note: compiler has internal check for this.
// Use -Wno-array-bounds to suppress compiler warning.
void test() {
  int buf[100][100];
  buf[0][-1] = 1; // warn
}

// note: requires alpha.security.taint check turned on.
void test() {
  char s[] = "abc";
  int x = getchar();
  char c = s[x]; // warn: index is tainted
}

1.2.10.4. alpha.security.MallocOverflow (C)

Check for overflows in the arguments to malloc().

void test(int n) {
  void *p = malloc(n * sizeof(int)); // warn
}

void test2(int n) {
  if (n > 100) // gives an upper-bound
    return;
  void *p = malloc(n * sizeof(int)); // no warning
}

1.2.10.5. alpha.security.MmapWriteExec (C)

Warn on mmap() calls that are both writable and executable.

void test(int n) {
  void *c = mmap(NULL, 32, PROT_READ | PROT_WRITE | PROT_EXEC,
                 MAP_PRIVATE | MAP_ANON, -1, 0);
  // warn: Both PROT_WRITE and PROT_EXEC flags are set. This can lead to
  //       exploitable memory regions, which could be overwritten with malicious
  //       code
}

1.2.10.6. alpha.security.ReturnPtrRange (C)

Check for an out-of-bound pointer being returned to callers.

static int A[10];

int *test() {
  int *p = A + 10;
  return p; // warn
}

int test(void) {
  int x;
  return x; // warn: undefined or garbage returned
}

1.2.10.7. alpha.security.taint.TaintPropagation (C, C++)

Generate taint information used by other checkers. A data is tainted when it comes from an unreliable source.

void test() {
  char x = getchar(); // 'x' marked as tainted
  system(&x); // warn: untrusted data is passed to a system call
}

// note: compiler internally checks if the second param to
// sprintf is a string literal or not.
// Use -Wno-format-security to suppress compiler warning.
void test() {
  char s[10], buf[10];
  fscanf(stdin, "%s", s); // 's' marked as tainted

  sprintf(buf, s); // warn: untrusted data as a format string
}

void test() {
  size_t ts;
  scanf("%zd", &ts); // 'ts' marked as tainted
  int *p = (int *)malloc(ts * sizeof(int));
    // warn: untrusted data as buffer size
}

1.2.11. alpha.unix

1.2.11.1. alpha.unix.BlockInCriticalSection (C)

Check for calls to blocking functions inside a critical section. Applies to: lock, unlock, sleep, getc, fgets, read, recv, pthread_mutex_lock, `` pthread_mutex_unlock, mtx_lock, mtx_timedlock, mtx_trylock, mtx_unlock, lock_guard, unique_lock``

void test() {
  std::mutex m;
  m.lock();
  sleep(3); // warn: a blocking function sleep is called inside a critical
            //       section
  m.unlock();
}

1.2.11.2. alpha.unix.Chroot (C)

Check improper use of chroot.

void f();

void test() {
  chroot("/usr/local");
  f(); // warn: no call of chdir("/") immediately after chroot
}

1.2.11.3. alpha.unix.PthreadLock (C)

Simple lock -> unlock checker. Applies to: pthread_mutex_lock, pthread_rwlock_rdlock, pthread_rwlock_wrlock, lck_mtx_lock, lck_rw_lock_exclusive lck_rw_lock_shared, pthread_mutex_trylock, pthread_rwlock_tryrdlock, pthread_rwlock_tryrwlock, lck_mtx_try_lock, lck_rw_try_lock_exclusive, lck_rw_try_lock_shared, pthread_mutex_unlock, pthread_rwlock_unlock, lck_mtx_unlock, lck_rw_done.

pthread_mutex_t mtx;

void test() {
  pthread_mutex_lock(&mtx);
  pthread_mutex_lock(&mtx);
    // warn: this lock has already been acquired
}

lck_mtx_t lck1, lck2;

void test() {
  lck_mtx_lock(&lck1);
  lck_mtx_lock(&lck2);
  lck_mtx_unlock(&lck1);
    // warn: this was not the most recently acquired lock
}

lck_mtx_t lck1, lck2;

void test() {
  if (lck_mtx_try_lock(&lck1) == 0)
    return;

  lck_mtx_lock(&lck2);
  lck_mtx_unlock(&lck1);
    // warn: this was not the most recently acquired lock
}

1.2.11.4. alpha.unix.SimpleStream (C)

Check for misuses of stream APIs. Check for misuses of stream APIs: fopen, fclose (demo checker, the subject of the demo (Slides , Video) by Anna Zaks and Jordan Rose presented at the 2012 LLVM Developers’ Meeting).

void test() {
  FILE *F = fopen("myfile.txt", "w");
} // warn: opened file is never closed

void test() {
  FILE *F = fopen("myfile.txt", "w");

  if (F)
    fclose(F);

  fclose(F); // warn: closing a previously closed file stream
}

1.2.11.5. alpha.unix.Stream (C)

Check stream handling functions: fopen, tmpfile, fclose, fread, fwrite, fseek, ftell, rewind, fgetpos, fsetpos, clearerr, feof, ferror, fileno.

void test() {
  FILE *p = fopen("foo", "r");
} // warn: opened file is never closed

void test() {
  FILE *p = fopen("foo", "r");
  fseek(p, 1, SEEK_SET); // warn: stream pointer might be NULL
  fclose(p);
}

void test() {
  FILE *p = fopen("foo", "r");

  if (p)
    fseek(p, 1, 3);
     // warn: third arg should be SEEK_SET, SEEK_END, or SEEK_CUR

  fclose(p);
}

void test() {
  FILE *p = fopen("foo", "r");
  fclose(p);
  fclose(p); // warn: already closed
}

void test() {
  FILE *p = tmpfile();
  ftell(p); // warn: stream pointer might be NULL
  fclose(p);
}

1.2.11.6. alpha.unix.cstring.BufferOverlap (C)

Checks for overlap in two buffer arguments. Applies to: memcpy, mempcpy.

void test() {
  int a[4] = {0};
  memcpy(a + 2, a + 1, 8); // warn
}

1.2.11.7. alpha.unix.cstring.NotNullTerminated (C)

Check for arguments which are not null-terminated strings; applies to: strlen, strnlen, strcpy, strncpy, strcat, strncat.

void test() {
  int y = strlen((char *)&test); // warn
}

1.2.11.8. alpha.unix.cstring.OutOfBounds (C)

Check for out-of-bounds access in string functions; applies to:`` strncopy, strncat``.

void test() {
  int y = strlen((char *)&test); // warn
}

1.2.11.9. alpha.nondeterminism.PointerIteration (C++)

Check for non-determinism caused by iterating unordered containers of pointers.

void test() {
 int a = 1, b = 2;
 std::unordered_set<int *> UnorderedPtrSet = {&a, &b};

 for (auto i : UnorderedPtrSet) // warn
   f(i);
}

1.2.11.10. alpha.nondeterminism.PointerSorting (C++)

Check for non-determinism caused by sorting of pointers.

void test() {
 int a = 1, b = 2;
 std::vector<int *> V = {&a, &b};
 std::sort(V.begin(), V.end()); // warn
}

1.2.12. alpha.WebKit

1.2.12.1. alpha.webkit.UncountedCallArgsChecker

The goal of this rule is to make sure that lifetime of any dynamically allocated ref-countable object passed as a call argument spans past the end of the call. This applies to call to any function, method, lambda, function pointer or functor. Ref-countable types aren’t supposed to be allocated on stack so we check arguments for parameters of raw pointers and references to uncounted types.

Here are some examples of situations that we warn about as they might be potentially unsafe. The logic is that either we’re able to guarantee that an argument is safe or it’s considered if not a bug then bug-prone.

RefCountable* provide_uncounted();
void consume(RefCountable*);

// In these cases we can't make sure callee won't directly or indirectly call `deref()` on the argument which could make it unsafe from such point until the end of the call.

void foo1() {
  consume(provide_uncounted()); // warn
}

void foo2() {
  RefCountable* uncounted = provide_uncounted();
  consume(uncounted); // warn
}

Although we are enforcing member variables to be ref-counted by webkit.NoUncountedMemberChecker any method of the same class still has unrestricted access to these. Since from a caller’s perspective we can’t guarantee a particular member won’t get modified by callee (directly or indirectly) we don’t consider values obtained from members safe.

Note: It’s likely this heuristic could be made more precise with fewer false positives - for example calls to free functions that don’t have any parameter other than the pointer should be safe as the callee won’t be able to tamper with the member unless it’s a global variable.

struct Foo {
  RefPtr<RefCountable> member;
  void consume(RefCountable*) { /* ... */ }
  void bugprone() {
    consume(member.get()); // warn
  }
};

The implementation of this rule is a heuristic - we define a whitelist of kinds of values that are considered safe to be passed as arguments. If we can’t prove an argument is safe it’s considered an error.

Allowed kinds of arguments:

  • values obtained from ref-counted objects (including temporaries as those survive the call too)

    RefCountable* provide_uncounted();
    void consume(RefCountable*);
    
    void foo() {
      RefPtr<RefCountable> rc = makeRef(provide_uncounted());
      consume(rc.get()); // ok
      consume(makeRef(provide_uncounted()).get()); // ok
    }
    
  • forwarding uncounted arguments from caller to callee

    void foo(RefCountable& a) {
      bar(a); // ok
    }
    

    Caller of foo() is responsible for a’s lifetime.

  • this pointer

    void Foo::foo() {
      baz(this);  // ok
    }
    

    Caller of foo() is responsible for keeping the memory pointed to by this pointer safe.

  • constants

    foo(nullptr, NULL, 0); // ok
    

We also define a set of safe transformations which if passed a safe value as an input provide (usually it’s the return value) a safe value (or an object that provides safe values). This is also a heuristic.

  • constructors of ref-counted types (including factory methods)

  • getters of ref-counted types

  • member overloaded operators

  • casts

  • unary operators like & or *

1.2.12.2. alpha.webkit.UncountedLocalVarsChecker

The goal of this rule is to make sure that any uncounted local variable is backed by a ref-counted object with lifetime that is strictly larger than the scope of the uncounted local variable. To be on the safe side we require the scope of an uncounted variable to be embedded in the scope of ref-counted object that backs it.

These are examples of cases that we consider safe:

void foo1() {
  RefPtr<RefCountable> counted;
  // The scope of uncounted is EMBEDDED in the scope of counted.
  {
    RefCountable* uncounted = counted.get(); // ok
  }
}

void foo2(RefPtr<RefCountable> counted_param) {
  RefCountable* uncounted = counted_param.get(); // ok
}

void FooClass::foo_method() {
  RefCountable* uncounted = this; // ok
}

Here are some examples of situations that we warn about as they might be potentially unsafe. The logic is that either we’re able to guarantee that an argument is safe or it’s considered if not a bug then bug-prone.

void foo1() {
  RefCountable* uncounted = new RefCountable; // warn
}

RefCountable* global_uncounted;
void foo2() {
  RefCountable* uncounted = global_uncounted; // warn
}

void foo3() {
  RefPtr<RefCountable> counted;
  // The scope of uncounted is not EMBEDDED in the scope of counted.
  RefCountable* uncounted = counted.get(); // warn
}

We don’t warn about these cases - we don’t consider them necessarily safe but since they are very common and usually safe we’d introduce a lot of false positives otherwise: - variable defined in condition part of an `if` statement - variable defined in init statement condition of a `for` statement

For the time being we also don’t warn about uninitialized uncounted local variables.

1.3. Debug Checkers

1.3.1. debug

Checkers used for debugging the analyzer. Debug Checks page contains a detailed description.

1.3.1.1. debug.AnalysisOrder

Print callbacks that are called during analysis in order.

1.3.1.2. debug.ConfigDumper

Dump config table.

1.3.1.3. debug.DumpCFG Display

Control-Flow Graphs.

1.3.1.4. debug.DumpCallGraph

Display Call Graph.

1.3.1.5. debug.DumpCalls

Print calls as they are traversed by the engine.

1.3.1.6. debug.DumpDominators

Print the dominance tree for a given CFG.

1.3.1.7. debug.DumpLiveVars

Print results of live variable analysis.

1.3.1.8. debug.DumpTraversal

Print branch conditions as they are traversed by the engine.

1.3.1.9. debug.ExprInspection

Check the analyzer’s understanding of expressions.

1.3.1.10. debug.Stats

Emit warnings with analyzer statistics.

1.3.1.11. debug.TaintTest

Mark tainted symbols as such.

1.3.1.12. debug.ViewCFG

View Control-Flow Graphs using GraphViz.

1.3.1.13. debug.ViewCallGraph

View Call Graph using GraphViz.

1.3.1.14. debug.ViewExplodedGraph

View Exploded Graphs using GraphViz.