The software floating point library is used on machines which do not have hardware support for floating point. It is also used whenever -msoft-float is used to disable generation of floating point instructions. (Not all targets support this switch.)
For compatibility with other compilers, the floating point emulation
routines can be renamed with the DECLARE_LIBRARY_RENAMES
macro
(see Implicit Calls to Library Routines). In this section, the default names are used.
Presently the library does not support XFmode
, which is used
for long double
on some architectures.
float
__addsf3 (float a, float b)
¶double
__adddf3 (double a, double b)
¶long double
__addtf3 (long double a, long double b)
¶long double
__addxf3 (long double a, long double b)
¶These functions return the sum of a and b.
float
__subsf3 (float a, float b)
¶double
__subdf3 (double a, double b)
¶long double
__subtf3 (long double a, long double b)
¶long double
__subxf3 (long double a, long double b)
¶These functions return the difference between b and a; that is, a - b.
float
__mulsf3 (float a, float b)
¶double
__muldf3 (double a, double b)
¶long double
__multf3 (long double a, long double b)
¶long double
__mulxf3 (long double a, long double b)
¶These functions return the product of a and b.
float
__divsf3 (float a, float b)
¶double
__divdf3 (double a, double b)
¶long double
__divtf3 (long double a, long double b)
¶long double
__divxf3 (long double a, long double b)
¶These functions return the quotient of a and b; that is, a / b.
float
__negsf2 (float a)
¶double
__negdf2 (double a)
¶long double
__negtf2 (long double a)
¶long double
__negxf2 (long double a)
¶These functions return the negation of a. They simply flip the sign bit, so they can produce negative zero and negative NaN.
double
__extendsfdf2 (float a)
¶long double
__extendsftf2 (float a)
¶long double
__extendsfxf2 (float a)
¶long double
__extenddftf2 (double a)
¶long double
__extenddfxf2 (double a)
¶These functions extend a to the wider mode of their return type.
double
__truncxfdf2 (long double a)
¶double
__trunctfdf2 (long double a)
¶float
__truncxfsf2 (long double a)
¶float
__trunctfsf2 (long double a)
¶float
__truncdfsf2 (double a)
¶These functions truncate a to the narrower mode of their return type, rounding toward zero.
int
__fixsfsi (float a)
¶int
__fixdfsi (double a)
¶int
__fixtfsi (long double a)
¶int
__fixxfsi (long double a)
¶These functions convert a to a signed integer, rounding toward zero.
long
__fixsfdi (float a)
¶long
__fixdfdi (double a)
¶long
__fixtfdi (long double a)
¶long
__fixxfdi (long double a)
¶These functions convert a to a signed long, rounding toward zero.
long long
__fixsfti (float a)
¶long long
__fixdfti (double a)
¶long long
__fixtfti (long double a)
¶long long
__fixxfti (long double a)
¶These functions convert a to a signed long long, rounding toward zero.
unsigned int
__fixunssfsi (float a)
¶unsigned int
__fixunsdfsi (double a)
¶unsigned int
__fixunstfsi (long double a)
¶unsigned int
__fixunsxfsi (long double a)
¶These functions convert a to an unsigned integer, rounding toward zero. Negative values all become zero.
unsigned long
__fixunssfdi (float a)
¶unsigned long
__fixunsdfdi (double a)
¶unsigned long
__fixunstfdi (long double a)
¶unsigned long
__fixunsxfdi (long double a)
¶These functions convert a to an unsigned long, rounding toward zero. Negative values all become zero.
unsigned long long
__fixunssfti (float a)
¶unsigned long long
__fixunsdfti (double a)
¶unsigned long long
__fixunstfti (long double a)
¶unsigned long long
__fixunsxfti (long double a)
¶These functions convert a to an unsigned long long, rounding toward zero. Negative values all become zero.
float
__floatsisf (int i)
¶double
__floatsidf (int i)
¶long double
__floatsitf (int i)
¶long double
__floatsixf (int i)
¶These functions convert i, a signed integer, to floating point.
float
__floatdisf (long i)
¶double
__floatdidf (long i)
¶long double
__floatditf (long i)
¶long double
__floatdixf (long i)
¶These functions convert i, a signed long, to floating point.
float
__floattisf (long long i)
¶double
__floattidf (long long i)
¶long double
__floattitf (long long i)
¶long double
__floattixf (long long i)
¶These functions convert i, a signed long long, to floating point.
float
__floatunsisf (unsigned int i)
¶double
__floatunsidf (unsigned int i)
¶long double
__floatunsitf (unsigned int i)
¶long double
__floatunsixf (unsigned int i)
¶These functions convert i, an unsigned integer, to floating point.
float
__floatundisf (unsigned long i)
¶double
__floatundidf (unsigned long i)
¶long double
__floatunditf (unsigned long i)
¶long double
__floatundixf (unsigned long i)
¶These functions convert i, an unsigned long, to floating point.
float
__floatuntisf (unsigned long long i)
¶double
__floatuntidf (unsigned long long i)
¶long double
__floatuntitf (unsigned long long i)
¶long double
__floatuntixf (unsigned long long i)
¶These functions convert i, an unsigned long long, to floating point.
There are two sets of basic comparison functions.
int
__cmpsf2 (float a, float b)
¶int
__cmpdf2 (double a, double b)
¶int
__cmptf2 (long double a, long double b)
¶These functions calculate a <=> b. That is, if a is less than b, they return −1; if a is greater than b, they return 1; and if a and b are equal they return 0. If either argument is NaN they return 1, but you should not rely on this; if NaN is a possibility, use one of the higher-level comparison functions.
int
__unordsf2 (float a, float b)
¶int
__unorddf2 (double a, double b)
¶int
__unordtf2 (long double a, long double b)
¶These functions return a nonzero value if either argument is NaN, otherwise 0.
There is also a complete group of higher level functions which correspond directly to comparison operators. They implement the ISO C semantics for floating-point comparisons, taking NaN into account. Pay careful attention to the return values defined for each set. Under the hood, all of these routines are implemented as
if (__unordXf2 (a, b)) return E; return __cmpXf2 (a, b);
where E is a constant chosen to give the proper behavior for NaN. Thus, the meaning of the return value is different for each set. Do not rely on this implementation; only the semantics documented below are guaranteed.
int
__eqsf2 (float a, float b)
¶int
__eqdf2 (double a, double b)
¶int
__eqtf2 (long double a, long double b)
¶These functions return zero if neither argument is NaN, and a and b are equal.
int
__nesf2 (float a, float b)
¶int
__nedf2 (double a, double b)
¶int
__netf2 (long double a, long double b)
¶These functions return a nonzero value if either argument is NaN, or if a and b are unequal.
int
__gesf2 (float a, float b)
¶int
__gedf2 (double a, double b)
¶int
__getf2 (long double a, long double b)
¶These functions return a value greater than or equal to zero if neither argument is NaN, and a is greater than or equal to b.
int
__ltsf2 (float a, float b)
¶int
__ltdf2 (double a, double b)
¶int
__lttf2 (long double a, long double b)
¶These functions return a value less than zero if neither argument is NaN, and a is strictly less than b.
float
__powisf2 (float a, int b)
¶double
__powidf2 (double a, int b)
¶long double
__powitf2 (long double a, int b)
¶long double
__powixf2 (long double a, int b)
¶These functions convert raise a to the power b.
complex float
__mulsc3 (float a, float b, float c, float d)
¶complex double
__muldc3 (double a, double b, double c, double d)
¶complex long double
__multc3 (long double a, long double b, long double c, long double d)
¶complex long double
__mulxc3 (long double a, long double b, long double c, long double d)
¶These functions return the product of a + ib and c + id, following the rules of C99 Annex G.
complex float
__divsc3 (float a, float b, float c, float d)
¶complex double
__divdc3 (double a, double b, double c, double d)
¶complex long double
__divtc3 (long double a, long double b, long double c, long double d)
¶complex long double
__divxc3 (long double a, long double b, long double c, long double d)
¶These functions return the quotient of a + ib and c + id (i.e., (a + ib) / (c + id)), following the rules of C99 Annex G.