Macros are frequently used to make source code more readable. Macro definitions, regardless of whether they expand to a single or multiple statements, should not conclude with a semicolon. (See PRE10-C. Wrap multistatement macros in a do-while loop.) If required, the semicolon should be included following the macro expansion. Inadvertently inserting a semicolon at the end of the macro definition can unexpectedly change the control flow of the program.

Another way to avoid this problem is to prefer inline or static functions over function-like macros. (See also PRE00-C. Prefer inline or static functions to function-like macros.)

In general, the programmer should ensure that there is no semicolon at the end of a macro definition. The responsibility for having a semicolon where needed during the use of such a macro should be delegated to the person invoking the macro.

Noncompliant Code Example

This noncompliant code example creates a macro definition for a for loop in the program. A for loop should require braces, even if it contains only a single body statement. (See EXP19-C. Use braces for the body of an if, for, or while statement.) This macro takes an integer argument, which is the number of times the loop should run. The programmer has inserted a semicolon at the end of the macro definition by mistake.

#define FOR_LOOP(n)  for(i=0; i<(n); i++);

int i;
FOR_LOOP(3)
{
  puts("Inside for loop\n");
}

The programmer expects to get the following output from the code:

Inside for loop
Inside for loop
Inside for loop

But because of the semicolon at the end of the macro definition, the for loop in the program has a null statement, so the statement "Inside for loop" gets printed just once. Essentially, the semicolon at the end of the macro definition changes the program control flow.

Although this example might not actually be used in code, it shows the effect a semicolon in a macro definition can have.

Compliant Solution

The compliant solution is to write the macro definition without the semicolon at the end, leaving the decision whether or not to have a semicolon up to the person who is using the macro:

#define FOR_LOOP(n)  for(i=0; i<(n); i++)

int i;
FOR_LOOP(3)
{
  puts("Inside for loop\n");
}

Noncompliant Code Example

In this noncompliant code example, the programmer defines a macro that increments the value of the first argument, x, by 1 and modulates it with the value of the second argument, max:

#define INCREMOD(x, max) ((x) = ((x) + 1) % (max));

int index = 0;
int value;
value = INCREMOD(index, 10) + 2;
/* ... */

In this case, the programmer intends to increment index and then use that as a value by adding 2 to it. Unfortunately, the value is equal to the incremented value of index because of the semicolon present at the end of the macro. The + 2; is treated as a separate statement by the compiler. The user will not get any compilation errors. If the user has not enabled warnings while compiling, the effect of the semicolon in the macro cannot be detected at an early stage.

Compliant Solution

The compliant solution is to write the macro definition without the semicolon at the end, leaving the decision whether or not to have a semicolon up to the person who is using the macro:

#define INCREMOD(x, max) ((x) = ((x) + 1) % (max))

Compliant Solution

This compliant solution uses an inline function as recommended by PRE00-C. Prefer inline or static functions to function-like macros.

inline int incremod(int *x, int max) {*x = (*x + 1) % max;}

Risk Assessment

Using a semicolon at the end of a macro definition can result in the change of program control flow and thus unintended program behavior.

Recommendation

Severity

Likelihood

Remediation Cost

Priority

Level

PRE11-C

Medium

Probable

Low

P12

L1

Automated Detection

ToolVersionCheckerDescription
Astrée
24.04
macro-final-semicolonFully checked
Axivion Bauhaus Suite

7.2.0

CertC-PRE11
CodeSonar
8.1p0
LANG.PREPROC.MACROENDMacro Does Not End With ) or }
Helix QAC

2024.3

C3412
LDRA tool suite
9.7.1
79 SEnhanced Enforcement
PC-lint Plus

1.4

823

Fully supported

Polyspace Bug Finder

R2024a

CERT C: Rec. PRE11-CChecks for macros terminated with semicolons (rule fully covered)
RuleChecker
24.04
macro-final-semicolon Fully checked

Related Vulnerabilities

Search for vulnerabilities resulting from the violation of this rule on the CERT website.

Related Guidelines



11 Comments

  1. Ruchi, just two comments:

    • This rule is specifically about macros that contain single statements (not expressions or multi-statement blocks). It should say so, both in the title and discussion.
    • The rule should acknowledge other rules (eg PRE00-C & PRE10-C) that discuss similar issues.
  2. I think "Mitigation Strategies" section is redundant and can be removed.

    1. The info is useful, but it technically is not a 'mitigation' (eg a workaround for insecure code), it is rather a design constraint (how to write code correctly). So I moved the paragraph to the intro and wordsmithed it a bit.

  3. This recommendation applies to multi-statement macros for the same reason it does to single-statement ones. Is there any reason not to extend it to include all macros? If not, what is the process for changing the title of a recommendation or rule?

    1. Thanks for changing the title, Martin.

  4. The first NCCE/CS pair seems superfluous to me; the code is simply incorrect, regardless of the presence of the macro.  It's also covered by EXP15-C. Do not place a semicolon on the same line as an if, for, or while statement  Any complaints if I remove the pair?

  5. #define FOR_LOOP(n)  for(i=0; i<(n); i++)
     
    int i;
    FOR_LOOP(3)
    {
      puts("Inside for loop\n");
    }

    IMHO this is a bad coding practice example. And giving this example, though it achieves right result, is defeating the purpose of secure coding practice. Loop in macros should be allowed when they do definite task e.g.

    #define CALL_func_n_TIMES(n, func) while(--n){ func(); }

    or

    #define PRINT_this_n_TIMES(n, this) while(--n){ printf("%s\n", this); }

    Though, PRINT_this_n_TIMES is itself bad, since it's going to print only strings, macros should be generic.

     

    Also, in for example, I think you will need to supply 'i' too like FOR_LOOP(n, i), and call macro appropriately. Because, macro can be in entirely different header file, and in that case if you don't mention 'i' explicitly, you will be creating side-effects that you might not understand until your program crashes or does something wrong.

    Take case:

    a lot of declarations in some function

    int i = 0; // I am going to use this i for counting something. very important.
                 // but I am not going to mention this in comments, because I know 
                 // what I am doing.

    ... // a lot of things you do and count.


    now, unfortunately you call

    FOR_LOOP(3) ...

    // and BOOM, you just changed the number of things I counted. now, i == 3.

    ... // keep on going doing things and counting and incrementing i.

    return i // perhaps.

     

    Make decision based on returned value.

    // KA-BOOM wrong output, though you did all the right things.

     

    So if you use i in FOR_LOOP(n, i) it makes more sense, as things will be explicit.

     

    1. The FOR_LOOP example isn't a very good one. It exists only to demonstrate the point about the terminating semicolon. Most (but not all) uses of macros can be replaced by better alternatives, and the FOR_LOOP macro is a case in point -- the for statement is perfectly adequate and would be far more appropriate.

      That said, making the loop control variable an argument to the macro would solve the problem you point out. An even better solution would be to declare the variable directly in the for statement, like so:

      #define FOR_LOOP(i, n)  for (int i=0; i<(n); i++)
      The advantage of this approach is that it limits the scope of the variable to the for statement alone.
  6. #define INCREMENT(x, max) ((x) = ((x) + 1) % (max))

    Shouldn't it be an inline function? Plus, this is not actual "increment".

    1. Yes, as the description of this guideline suggests:

      Another way to avoid this problem is to prefer inline or static functions over function-like macros.

      1. I've addressed these issues. It is  possible to violate the recommendations (like PRE00-C) and still have secure code, so I did not change that compliant solution. But I did add one that uses an inline function, as Martin suggests.