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False positives

CodeChecker is running static analysis tools on the code. Unfortunately, it is not possible to create perfect tools. They might report correct code as incorrect. These findings are called false positives. This document explains how to deal with them. As a rule of thumb, whenever you encounter a false positive finding using suppression should be only the last resort. Why? Read on.

Having a false positive indicates that the analyzer does not understand some properties of the code. Suppressing a result will not help its understanding. Making the code more obvious for the tool, however, makes the analysis more precise. As a bonus, such code is sometimes also more readable for developers.

This guide introduces tips and tricks on how to make the code easier to analyze.

Table of Contents

What target to analyze?

Usually, a project has multiple build targets for different purposes. There might be multiple targets for multiple architectures, releases, debugging.

We advise to use the debug target to analyze the code. The reason is, debug targets usually contain assertions, while release targets do not. These assertions convey useful information to the analyzer.

The analyzer understands the standard assert macro. In case a project has custom assertion mechanisms the corresponding functions should be annotated both to improve precision and avoid false positives. For details read the guide of the analyzer.

Infeasible path

One of the most frequent source of false positives is analyzing infeasible execution path of the program. Every report on such a path is false positive. There are a number of ways to help the analyzer detect which paths are not possible to take. This document also has some examples to show these techniques in action.

  • Functions that never return should be annotated as noreturn (available since C++11)
  • Functions that never return null pointers might be annotated appropriately
  • Assertions can be added to help the analyzer detect more invariants
  • Partial functions can be made more explicit
  • Unreachable annotations should be added
  • Prefer standard functions to custom solutions
  • Do not turn off core checks

Correlated conditions

The analyzer might not be able to detect that two conditions are mutually exclusive. Let us consider the following false positive:

int x = f();
if (condition A) {
  x = 0;
}
...
if (nontrivial condition) {
  g(5/x); // Division by zero warning.
}

It can be rewritten to as the following to suppress the warning:

int x = f();
if (condition A) {
  x = 0;
}
...
if (nontrivial condition) {
  assert(!(condition A));
  g(5/x); // No warning.
}

Partial functions

Some functions only work on a set of possible input values. This precondition is unknown to the analyzer unless it is expressed explicitly in the code.

Let us consider the following false positive:

int f(MyEnum Val) {
  int x = 0;
  switch (Val) {
    case MyEnumA: x = 1; break;
    case MyEnumB: x = 5; break;
  }
  return 5/x; // Division by zero when Val == MyEnumC.
}

It can be rewritten to as the following to suppress the warning:

int f(MyEnum Val) {
  int x = 0;
  switch (Val) {
    case MyEnumA: x = 1; break;
    case MyEnumB: x = 5; break;
    default: assert(false); break;
  }
  return 5/x; // No warning.
}

Other macros or builtins expressing unreachable code may be used. Note that the rewritten code is also safer, since debug builds now check for more precondition violations.

In case of C++11 or later, another option is to use Immediately-Invoked Function Expression (IIFE) to avoid assigning a meaningless value.

int f(MyEnum Val) {
  const int x = [&] { // Note the lambda.
    switch (Val) {
      case MyEnumA: return 1;
      case MyEnumB: return 5;
      default: assert(false); return 0;
    }
  } ();
  return 5/x; // No warning.
}

Loops

Some loops are guaranteed to execute at least once and this is a dynamic invariant of the program. In some cases the analyzer cannot prove this property of a loop and it will simulate the path when the loop is not executed at all. It can be due to the lack of context or the code being too complex to the analyzer. This might result in false positives like uninitialized variables or division by zero.

Let us look at the following example:

int avg(List *l) {
  int sum = 0;
  int count = 0;
  for(; l != NULL; l = l->next) {
    sum += l->data;
    ++count;
  }
  return sum/count; // Warning, division by zero.
}

Without a calling context the analyzer cannot know that List is guaranteed to be at least one element long. We need an assert to tell the analyzer about this invariant.

int avg(List *l) {
  int sum = 0;
  int count = 0;
  assert(l != NULL);
  for(; l != NULL; l = l->next) {
    sum += l->data;
    ++count;
  }
  return sum/count; // No warning.
}

Adding the assert will make the code cleaner for the reader because it makes an important invariant of the program explicit. Moreover, it will make the false positive finding disappear. This will also provide the users of the code with an explicit check in the debug build which can help find bugs.

In some cases the analyzer cannot reason about the possible values of expressions due to some limitations of the constraint solver. In the code example below the analyzer cannot record the constraint about a complex expression.

if (a > 1 && b > 1 && c > 1) {
  int ret;
  assert(a*b+c > 0);
  while (a*b+c > 0) {
    ret = 0;
    ...
  }
  return ret; // Warning, uninitialized value.
}

You can rewrite the code to reflect that there will always be at least one iteration such as using a do-while loop or using while(true) and break out from the loop.
If you do not want to change the layout of the code, introducing a new variable can suppress this problem.

if (a > 1 && b > 1 && c > 1) {
  int ret;
  int cond = a*b+c;
  assert(cond > 0);
  while (cond > 0) {
    ret = 0;
    ...
  }
  return ret; // No warning.
}

Do not forget to update the body of the loop if necessary.

Prefer standard functions

The analyzer models the behavior of some standard functions but it has no knowledge about the semantics of custom made functions declared in a library that compiled separately or not reached by the analyzer.

Let us consider the following false positive:

int f() {
  const char *Str = "MyStr";
  int Val = 0;
  ...
  if (mystrlen(Str)) {
    Val = 1;
  }
  return 5 / Val; // Division by zero.
}

It can be rewritten to as the following to suppress the warning:

int f() {
  const char *Str = "MyStr";
  int Val = 0;
  ...
  if (strlen(Str)) {
    Val = 1;
  }
  return 5 / Val; // No warning.
}

The result is easier to read for other developers who might not be familiar with the custom version of the function. The standard library functions also tend to be faster and more correct than custom solutions.

Use const whenever possible

It is useful to tell the analyzer when the state is not going to change. This will make the analysis more precise and the code more readable. Mark methods that are not going to change the state of the object as const.

Also, avoid using global variables as they are harder to reason about. Mark global constants as const.

Consider the following code:

static char *allv[] = { "prog", "arg1", "arg2" };
static int allc = sizeof(allv) / sizeof(allv[0]);
static void f(void) {
  for (int i = 1; i < allc; i++) {
    const char *p = allv[i];  // Warning, out of bounds.
  }
}

The analyzer might not be able to tell that the value of allc is always the same as the length of the array allv. Rewriting the code and marking allc const will solve this issue.

static char *allv[] = { "prog", "arg1", "arg2" };
static const int allc = sizeof(allv) / sizeof(allv[0]);
static void f(void) {
  for (int i = 1; i < allc; i++) {
    const char *p = allv[i];  // No warnings.
  }
}

Do not turn off core checks

Checks in the static analyzer are usually not just reporting issues but also help modelling language constructs and library functions. You should never turn off checks from the core package.

Suppress specific dead store warnings

How to suppress a specific dead store warning from the Clang Static Analyzer and more useful tips can be found here. Alternatively, the __clang_analyzer__ macro can be used to introduce usages. This macro is automatically defined when the code is analyzed using the Clang Static Analyzer. Or sometimes macros just need to be cleaned up. Let us consider the following example:

void foo() {
  int x = 3; // Dead store warning.
#ifdef ABC
  dostuff(x);
#endif
}

It can be rewritten to as the following to suppress the warning:

void foo() {
#ifdef ABC
  int x = 3; // No warning.
  dostuff(x);
#endif
}

Alternative implementations

If there are huge source of false positives due to the analyzer can not model a function properly you could either disable the analyzer to analyze that function or provide an alternative implementation that is easier to model (i.e.: implementation without bitwise operation tricks). This can be achieved using the __clang_analyzer__ macro.

For example the following code:

unsigned f(unsigned x) {
  return (x >> 1) & 1;
}

Could be rewritten as:

#ifndef __clang_analyzer__
unsigned f(unsigned x) {
  return (x >> 1) & 1;
}
#else
unsigned f(unsigned x) {
  return (x / 2) % 2;
}
#endif

The implementation without the bit manipulation can be understood by the analyzer better. Note that the compiler might generate the same code for the two implementations, so it might make sense to use only the more obvious one.

Defensive checks

This section is an odd one because we describe a technique to reduce false negatives rather than false positives.

The preconditions of a function should not be violated by the callers. For the working example we will look at an strlen implementation. It is illegal to call strlen with a null pointer.

int strlen(const char *c) {
  int res = 0;
  for(; *c != 0; ++c) // Warn! Null pointer dereference.
    ++res;
  return res;
}

int main() {
  return strlen(0);
}

The analyzer will be able to find the null dereference in the code above. In some cases, however, the author of the functions adds defensive checks to avoid crashes when some clients do not respect the precondition.

int strlen(const char *c) {
  if (c == 0) {
    // Maybe set an error flag.
    return 0; // Or might throw exception in case of C++.
  }
  int res = 0;
  for(; *c != 0; ++c) // No warning.
    ++res;
  return res;
}

int main() {
  return strlen(0);
}

In the code above the analyzer will not be able to find any errors since it has no way to tell whether the defensive checks are due to precondition violations or they are part of the defined behavior. This is called a false negative.

In order to reduce false negatives due to those safety checks we have several options.

  • We can state the precondition in the function signature. This is not always possible with the current language features.
int strlen(const char * _Nonnull c);
  • We can just omit the safety check. This might not be feasible in every scenario. But in case the only purpose of the check is debugging using sanitizers and other dynamic analysis tools is always a viable alternative.
  • Guard the safety checks with a macro.
int strlen(const char *c) {
#ifndef __clang_analyzer__
  if (c == 0)
    return 0;
#endif
  int res = 0;
  for(; *c != 0; ++c)
    ++res;
  return res;
}

As a rule of thumb always think whether a condition in a defensive check is responsible for catching precondition violations or part of the defined behavior of the function. In the former case, make sure the check does compromise the static analysis. Excluding those checks from the analysis might not only increase the useful results from the analyzer but also reduce the analysis time on that code.

Syntax based checks

Clang-Tidy has lots of useful syntax based checks. Some of these checks find bug-prone code snippets. When these snippets are intentional, usually there is a natural way to make the intent more explicit. Unfortunately, it is hard to give a general guideline, because the details are different for each check. The documentation of the check might contain hints how to express intention more clearly. Let us look at an example:

double f(int i) {
  return 32 / (2 + i); // Warning, integer division, loss of precision.
}

It can be rewritten to as the following to suppress the warning:

double f(int i) {
  return (int)(32 / (2 + i)); // No warning, the intention is explicit.
}

The second version makes it clear even though the return value is a floating point value the loss of precision during integer division is intentional. Adding a comment why this is intentional would make this even clearer. Such edits make the code easier to understand for fellow developers.

Suppress or skip results

When none of the above works, we can still resort to suppressing a particular finding. There are multiple ways to do this and it is important to choose the right one.

3rd party code

We usually have no control over 3rd party code and are not interested in the findings in such code. CodeChecker supports skipping certain files (or even directory trees) of the analyzed project. This might also make the analysis faster. For details, see the user guide.

Authored code

If you have control over the code we advise to use in source code suppression. This has the advantage of the code and the suppression evolving together and more reliable than other ways of suppression methods. Only suppress the results from one specific check that found the issue. Always comment why a finding is considered false positive! With a future version of the analyzer these suppression comments might be no longer required. Comments might help in the reevaluation. For details, see the user guide.

Unauthored code

If you do not have control over the code for some reason you can suppress issues using the web user interface.