point rounding and exception handling
int feclearexcept(int excepts);
int fegetexceptflag(fexcept_t *flagp, int excepts);
int feraiseexcept(int excepts);
int fesetexceptflag(const fexcept_t *flagp, int excepts);
int fetestexcept(int excepts);
int fesetround(int rounding_mode);
int fegetenv(fenv_t *envp);
int feholdexcept(fenv_t *envp);
int fesetenv(const fenv_t *envp);
int feupdateenv(const fenv_t *envp);
Link with -lm.
These eleven functions were defined in C99, and describe the handling
of floating-point rounding and exceptions (overflow, zero-divide,
The divide-by-zero exception occurs when an operation on finite numbers
produces infinity as exact answer.
The overflow exception occurs when a result has to be represented as a
floating-point number, but has (much) larger absolute value than the
largest (finite) floating-point number that is representable.
The underflow exception occurs when a result has to be represented as a
floating-point number, but has smaller absolute value than the smallest
positive normalized floating-point number (and would lose much accuracy
when represented as a denormalized number).
The inexact exception occurs when the rounded result of an operation is
not equal to the infinite precision result. It may occur whenever
overflow or underflow occurs.
The invalid exception occurs when there is no well-defined result for
an operation, as for 0/0 or infinity - infinity or sqrt(-1).
Exceptions are represented in two ways: as a single bit (exception
present/absent), and these bits correspond in some implementation-
defined way with bit positions in an integer, and also as an opaque
structure that may contain more information about the exception (per-
haps the code address where it occurred).
Each of the macros FE_DIVBYZERO, FE_INEXACT, FE_INVALID, FE_OVERFLOW,
The feraiseexcept() function raises the supported exceptions repre-
sented by the bits in excepts.
The fesetexceptflag() function sets the complete status for the excep-
tions represented by excepts to the value *flagp. This value must have
been obtained by an earlier call of fegetexceptflag() with a last argu-
ment that contained all bits in excepts.
The fetestexcept() function returns a word in which the bits are set
that were set in the argument excepts and for which the corresponding
exception is currently set.
The rounding mode determines how the result of floating-point opera-
tions is treated when the result cannot be exactly represented in the
significand. Various rounding modes may be provided: round to nearest
(the default), round up (toward positive infinity), round down (toward
negative infinity), and round toward zero.
Each of the macros FE_TONEAREST, FE_UPWARD, FE_DOWNWARD, and
FE_TOWARDZERO is defined when the implementation supports getting and
setting the corresponding rounding direction.
The fegetround() function returns the macro corresponding to the cur-
rent rounding mode.
The fesetround() function sets the rounding mode as specified by its
argument and returns zero when it was successful.
C99 and POSIX.1-2008 specify an identifier, FLT_ROUNDS, defined in
<float.h>, which indicates the implementation-defined rounding behavior
for floating-point addition. This identifier has one of the following
-1 The rounding mode is not determinable.
0 Rounding is toward 0.
1 Rounding is toward nearest number.
2 Rounding is toward positive infinity.
3 Rounding is toward negative infinity.
Other values represent machine-dependent, nonstandard rounding modes.
The value of FLT_ROUNDS should reflect the current rounding mode as set
by fesetround() (but see BUGS).
The entire floating-point environment, including control modes and sta-
tus flags, can be handled as one opaque object, of type fenv_t. The
The fesetenv() function restores the floating-point environment from
the object *envp. This object must be known to be valid, for example,
the result of a call to fegetenv() or feholdexcept() or equal to
FE_DFL_ENV. This call does not raise exceptions.
The feupdateenv() function installs the floating-point environment rep-
resented by the object *envp, except that currently raised exceptions
are not cleared. After calling this function, the raised exceptions
will be a bitwise OR of those previously set with those in *envp. As
before, the object *envp must be known to be valid.
These functions return zero on success and nonzero if an error
These functions first appeared in glibc in version 2.1.
For an explanation of the terms used in this section, see
|Interface | Attribute | Value |
|feclearexcept(), fegetexceptflag(), | Thread safety | MT-Safe |
|feraiseexcept(), fesetexceptflag(), | | |
|fetestexcept(), fegetround(), | | |
|fesetround(), fegetenv(), | | |
|feholdexcept(), fesetenv(), | | |
|feupdateenv(), feenableexcept(), | | |
|fedisableexcept(), fegetexcept() | | |
IEC 60559 (IEC 559:1989), ANSI/IEEE 854, C99, POSIX.1-2001.
If possible, the GNU C Library defines a macro FE_NOMASK_ENV which rep-
resents an environment where every exception raised causes a trap to
occur. You can test for this macro using #ifdef. It is defined only
if _GNU_SOURCE is defined. The C99 standard does not define a way to
set individual bits in the floating-point mask, for example, to trap on
specific flags. Since version 2.2, glibc supports the functions feen-
ableexcept() and fedisableexcept() to set individual floating-point
traps, and fegetexcept() to query the state.
#define _GNU_SOURCE /* See feature_test_macros(7) */
int feenableexcept(int excepts);
int fedisableexcept(int excepts);
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