Prevent or detect domain errors and range errors in math functions before using the results in further computations. Most of the math functions can fail if they are given arguments that do not produce a proper result. For example, the square root of a negative number, such as sqrt(-1.0), has no meaning in real arithmetic. This is known as a domain error; the argument is outside the domain over which the function is defined. For another example, ten raised to the one-millionth power, pow(10., 1e6), cannot be represented in any (current) floating point representation. This is known as a range error; the result cannot be represented as a proper double number. In all such error cases, the function will return some value, but the value returned is not the correct result of the computation.
Many math errors can be prevented by carefully bounds-checking the arguments before calling functions, and taking alternative action if the bounds are violated. In particular, the following functions should be bounds checked as follows:
Function |
Bounds-checking |
|---|---|
-1 <= x && x <= 1 |
|
x != 0 || y != 0 |
|
x >= 0 |
|
x > 0 || (x == 0 && y > 0) || (x < 0 && y is an integer) |
|
x >= 0 |
However, for some functions it is not practical to use bounds-checking to prevent all errors. For example, the above bounds check for pow() does not prevent the pow(10., 1e6) range error. In these cases detection must be used, either in addition to bounds checking or instead of bounds checking.
This code may produce a domain error if the argument is not in the range \[-1, \+1\]. |
double x, result; result = acos(x); |
This code uses bounds checking to ensure that there is not a domain error.
double x, result;
if ( islessequal(x,-1) || isgreaterequal(x, 1) ){
/* handle domain error */
}
result = acos(x);
|
This code may produce a domain error if both x and y are zero.
double x, y, result; result = atan2(y, x); |
This code tests the arguments to ensure that there is not a domain error.
double x, y, result;
if ( (x == 0.f) && (y == 0.f) ) {
/* handle domain error */
}
result = atan2(y, x);
|
This code may produce a domain error if x is negative and a range error if x is zero.
double result, x; result = log(x); |
This code tests the suspect arguments to ensure that no domain or range errors are raised.
double result, x;
if (islessequal(x, 0)) {
/* handle domain and range errors */
}
result = log(x);
|
This code may produce a domain error if x is negative and y is not an integer, or if x is zero and y is zero. A domain error or range error may occur if x is zero and y is negative, and a range error may occur if the result cannot be represented as a double.
double x, y, result; result = pow(x, y); |
This code only performs bounds-checking on x and y. It prevents domain errors and some range errors, but does not prevent range errors where the result cannot be represented as a double.
double x, y, result;
if (((x == 0.f) && islessequal(y, 0)) ||
(isless(x, 0) && !isInteger(y))) {
/* handle domain and range errors */
}
result = pow(x, y);
|
This code may produce a domain error if x is negative.
double x, result; result = sqrt(x); |
This code tests the suspect argument to ensure that no domain error is raised.
double x, result;
if (isless(x, 0)){
/* handle domain error */
}
result = sqrt(x);
|
The exact treatment of error conditions from math functions is quite complicated (see C99 Section 7.12.1, "Treatment of error conditions").
The {{sqrt()}} function returns zero when given a negative argument. The {{pow()}} function returns a very large number (appropriately positive or negative) on an overflow range error. This very large number is defined in {{<math.h>}} as described by C99 \[[ISO/IEC 9899-1999|AA. C References#ISO/IEC 9899-1999]\]: |
The macro
expands to a positive double constant expression, not necessarily representable as a float. The macros
are respectively float and long double analogs of
HUGE_VAL.
It is best not to check for errors by comparing the returned value against HUGE_VAL or zero for several reasons. First of all, these are in general valid (albeit unlikely) data values. Secondly, making such tests requires detailed knowledge of the various error returns for each math function. Also, there are three different possibilities, -HUGE_VAL, 0, and HUGE_VAL, and you must know which are possible in each case. Finally, different versions of the library have differed in their error-return behavior.
It is also difficult to check for math errors using errno because an implementation might not set it. For real functions, the programmer can test whether the implementation sets errno because in that case math_errhandling & MATH_ERRNO is nonzero. For complex functions, the C Standard Section 7.3.2 simply states that setting errno is optional.
The most reliable way to test for errors is by checking arguments beforehand, as in the following compliant solution:
if (/* arguments will cause a domain or range error */) {
/* handle the error */
}
else {
/* perform computation */
}
|
For functions where argument validation is difficult, including pow(), erfc(), lgamma(), and tgamma(), one can employ the following approach.
#include <math.h>
#if defined(math_errhandling) && (math_errhandling & MATH_ERREXCEPT)
#include <fenv.h>
#endif
/* ... */
#if defined(math_errhandling) && (math_errhandling & MATH_ERREXCEPT)
feclearexcept(FE_ALL_EXCEPT);
#endif
errno = 0;
/* call the function */
#if !defined(math_errhandling) || (math_errhandling & MATH_ERRNO)
if (errno != 0) {
/* handle error */
}
#endif
#if defined(math_errhandling) && (math_errhandling & MATH_ERREXCEPT)
if (fetestexcept(FE_INVALID | FE_DIVBYZERO | FE_OVERFLOW) != 0) {
/* handle error */
}
#endif
|
The System V Interface Definition, Third Edition (SVID3) provides more control over the treatment of errors in the math library. The user can provide a function named matherr that is invoked if errors occur in a math function. This function could print diagnostics, terminate the execution, or specify the desired return-value. The matherr() function has not been adopted by the C standard, so its use is not generally portable.
Failure to properly verify arguments supplied to math functions may result in unexpected results.
Rule |
Severity |
Likelihood |
Remediation Cost |
Priority |
Level |
|---|---|---|---|---|---|
FLP32-C |
medium |
probable |
medium |
P8 |
L2 |
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\[[ISO/IEC 9899-1999|AA. C References#ISO/IEC 9899-1999]\] Section 7.3, "Complex arithmetic <complex.h>" \[[ISO/IEC 9899-1999|AA. C References#ISO/IEC 9899-1999]\] Section 7.12, "Mathematics <math.h>" \[[Plum 85|AA. C References#Plum 85]\] Rule 2-2 \[[Plum 89|AA. C References#Plum 91]\] Topic 2.10, "conv - conversions and overflow" |
FLP31-C. Do not call functions expecting real values with complex values 05. Floating Point (FLP) FLP33-C. Convert integers to floating point for floating point operations