The Open Group Base Specifications Issue 7, 2018 edition
IEEE Std 1003.1-2017 (Revision of IEEE Std 1003.1-2008)
Copyright © 2001-2018 IEEE and The Open Group
A newer edition of this document exists here

NAME

tgmath.h - type-generic macros

SYNOPSIS

#include <tgmath.h>

DESCRIPTION

[CX] [Option Start] The functionality described on this reference page is aligned with the ISO C standard. Any conflict between the requirements described here and the ISO C standard is unintentional. This volume of POSIX.1-2017 defers to the ISO C standard. [Option End]

The <tgmath.h> header shall include the headers <math.h> and <complex.h> and shall define several type-generic macros.

Of the functions contained within the <math.h> and <complex.h> headers without an f (float) or l (long double) suffix, several have one or more parameters whose corresponding real type is double. For each such function, except modf(), [XSI] [Option Start] j0(), j1(), jn(), y0(), y1(), and yn(), [Option End]  there shall be a corresponding type-generic macro. The parameters whose corresponding real type is double in the function synopsis are generic parameters. Use of the macro invokes a function whose corresponding real type and type domain are determined by the arguments for the generic parameters.

Use of the macro invokes a function whose generic parameters have the corresponding real type determined as follows:

For each unsuffixed function in the <math.h> header for which there is a function in the <complex.h> header with the same name except for a c prefix, the corresponding type-generic macro (for both functions) has the same name as the function in the <math.h> header. The corresponding type-generic macro for fabs() and cabs() is fabs().

<math.h> Function

<complex.h> Function

Type-Generic Macro

acos()

cacos()

acos()

asin()

casin()

asin()

atan()

catan()

atan()

acosh()

cacosh()

acosh()

asinh()

casinh()

asinh()

atanh()

catanh()

atanh()

cos()

ccos()

cos()

sin()

csin()

sin()

tan()

ctan()

tan()

cosh()

ccosh()

cosh()

sinh()

csinh()

sinh()

tanh()

ctanh()

tanh()

exp()

cexp()

exp()

log()

clog()

log()

pow()

cpow()

pow()

sqrt()

csqrt()

sqrt()

fabs()

cabs()

fabs()

If at least one argument for a generic parameter is complex, then use of the macro invokes a complex function; otherwise, use of the macro invokes a real function.

For each unsuffixed function in the <math.h> header without a c-prefixed counterpart in the <complex.h> header, except for modf(), [XSI] [Option Start] j0(), j1(), jn(), y0(), y1(), and yn(), [Option End]  the corresponding type-generic macro has the same name as the function. These type-generic macros are:


atan2()
cbrt()
ceil()
copysign()
erf()
erfc()
exp2()
expm1()
fdim()
floor()
 


fma()
fmax()
fmin()
fmod()
frexp()
hypot()
ilogb()
ldexp()
lgamma()
llrint()
 


llround()
log10()
log1p()
log2()
logb()
lrint()
lround()
nearbyint()
nextafter()
nexttoward()
 


remainder()
remquo()
rint()
round()
scalbln()
scalbn()
tgamma()
trunc()
 

If all arguments for generic parameters are real, then use of the macro invokes a real function; otherwise, use of the macro results in undefined behavior.

For each unsuffixed function in the <complex.h> header that is not a c-prefixed counterpart to a function in the <math.h> header, the corresponding type-generic macro has the same name as the function. These type-generic macros are:

carg()
cimag()
conj()
cproj()
creal()

Use of the macro with any real or complex argument invokes a complex function.


The following sections are informative.

APPLICATION USAGE

With the declarations:

#include <tgmath.h>
int n;
float f;
double d;
long double ld;
float complex fc;
double complex dc;
long double complex ldc;

functions invoked by use of type-generic macros are shown in the following table:

Macro

Use Invokes

exp(n)

exp(n), the function

acosh(f)

acoshf(f)

sin(d)

sin(d), the function

atan(ld)

atanl(ld)

log(fc)

clogf(fc)

sqrt(dc)

csqrt(dc)

pow(ldc,f)

cpowl(ldc, f)

remainder(n,n)

remainder(n, n), the function

nextafter(d,f)

nextafter(d, f), the function

nexttoward(f,ld)

nexttowardf(f, ld)

copysign(n,ld)

copysignl(n, ld)

ceil(fc)

Undefined behavior

rint(dc)

Undefined behavior

fmax(ldc,ld)

Undefined behavior

carg(n)

carg(n), the function

cproj(f)

cprojf(f)

creal(d)

creal(d), the function

cimag(ld)

cimagl(ld)

cabs(fc)

cabsf(fc)

carg(dc)

carg(dc), the function

cproj(ldc)

cprojl(ldc)

RATIONALE

Type-generic macros allow calling a function whose type is determined by the argument type, as is the case for C operators such as '+' and '*'. For example, with a type-generic cos() macro, the expression cos((float) x) will have type float. This feature enables writing more portably efficient code and alleviates need for awkward casting and suffixing in the process of porting or adjusting precision. Generic math functions are a widely appreciated feature of Fortran.

The only arguments that affect the type resolution are the arguments corresponding to the parameters that have type double in the synopsis. Hence the type of a type-generic call to nexttoward(), whose second parameter is long double in the synopsis, is determined solely by the type of the first argument.

The term "type-generic" was chosen over the proposed alternatives of intrinsic and overloading. The term is more specific than intrinsic, which already is widely used with a more general meaning, and reflects a closer match to Fortran's generic functions than to C++ overloading.

The macros are placed in their own header in order not to silently break old programs that include the <math.h> header; for example, with:

printf ("%e", sin(x))

modf(double, double *) is excluded because no way was seen to make it safe without complicating the type resolution.

The implementation might, as an extension, endow appropriate ones of the macros that POSIX.1-2017 specifies only for real arguments with the ability to invoke the complex functions.

POSIX.1-2017 does not prescribe any particular implementation mechanism for generic macros. It could be implemented simply with built-in macros. The generic macro for sqrt(), for example, could be implemented with:

#undef sqrt
#define sqrt(x) __BUILTIN_GENERIC_sqrt(x)

Generic macros are designed for a useful level of consistency with C++ overloaded math functions.

The great majority of existing C programs are expected to be unaffected when the <tgmath.h> header is included instead of the <math.h> or <complex.h> headers. Generic macros are similar to the ISO/IEC 9899:1999 standard library masking macros, though the semantic types of return values differ.

The ability to overload on integer as well as floating types would have been useful for some functions; for example, copysign(). Overloading with different numbers of arguments would have allowed reusing names; for example, remainder() for remquo(). However, these facilities would have complicated the specification; and their natural consistent use, such as for a floating abs() or a two-argument atan(), would have introduced further inconsistencies with the ISO/IEC 9899:1999 standard for insufficient benefit.

The ISO C standard in no way limits the implementation's options for efficiency, including inlining library functions.

FUTURE DIRECTIONS

None.

SEE ALSO

<math.h>, <complex.h>

XSH cabs, fabs, modf

CHANGE HISTORY

First released in Issue 6. Included for alignment with the ISO/IEC 9899:1999 standard.

Issue 7

Austin Group Interpretation 1003.1-2001 #184 is applied, clarifying the functions for which a corresponding type-generic macro exists with the same name as the function.

POSIX.1-2008, Technical Corrigendum 1, XBD/TC1-2008/0075 [357,427] is applied.

End of informative text.

 

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