libquadmath/libquadmath.texi - gcc - Git at Google

 \input texinfo @c -*-texinfo-*-

 @c %**start of header
 @setfilename libquadmath.info
 @settitle GCC libquadmath
 @c %**end of header

 @copying
 Copyright @copyright{} 2010-2022 Free Software Foundation, Inc.

 @quotation
 Permission is granted to copy, distribute and/or modify this document
 under the terms of the GNU Free Documentation License, Version 1.2 or
 any later version published by the Free Software Foundation; with no
 Invariant Sections, with the Front-Cover Texts being ``A GNU Manual,''
 and with the Back-Cover Texts as in (a) below.  A copy of the
 license is included in the section entitled ``GNU Free Documentation
 License.''

 (a) The FSF's Back-Cover Text is: ``You have the freedom to
 copy and modify this GNU manual.
 @end quotation
 @end copying

 @ifinfo
 @dircategory GNU Libraries
 @direntry
 * libquadmath: (libquadmath).                  GCC Quad-Precision Math Library
 @end direntry

 This manual documents the GCC Quad-Precision Math Library API.

 Published by the Free Software Foundation
 51 Franklin Street, Fifth Floor
 Boston, MA 02110-1301 USA

 @insertcopying
 @end ifinfo


 @setchapternewpage odd

 @titlepage
 @title The GCC Quad-Precision Math Library
 @page
 @vskip 0pt plus 1filll
 @comment For the @value{version-GCC} Version*
 @sp 1
 Published by the Free Software Foundation @*
 51 Franklin Street, Fifth Floor@*
 Boston, MA 02110-1301, USA@*
 @sp 1
 @insertcopying
 @end titlepage

 @summarycontents
 @contents
 @page


 @node Top
 @top Introduction
 @cindex Introduction

 This manual documents the usage of libquadmath, the GCC Quad-Precision
 Math Library Application Programming Interface (API).


 @comment
 @comment  When you add a new menu item, please keep the right hand
 @comment  aligned to the same column.  Do not use tabs.  This provides
 @comment  better formatting.
 @comment
 @menu
 * Typedef and constants::      Defined data types and constants
 * Math Library Routines::      The Libquadmath math runtime application
                                programming interface.
 * I/O Library Routines::       The Libquadmath I/O runtime application
                                programming interface.
 * GNU Free Documentation License::
                                How you can copy and share this manual.
 * Reporting Bugs::             How to report bugs in GCC Libquadmath.
 @c * Index::                      Index of this documentation.
 @end menu


 @c ---------------------------------------------------------------------
 @c Defined macros
 @c ---------------------------------------------------------------------

 @node Typedef and constants
 @chapter Typedef and constants

 The following data type has been defined via @code{typedef}.

 @table @asis
 @item @code{__complex128}: @code{__float128}-based complex number
 @end table

 The following macros are defined, which give the numeric limits of the
 @code{__float128} data type.

 @table @asis
 @item @code{FLT128_MAX}: largest finite number
 @item @code{FLT128_MIN}: smallest positive number with full precision
 @item @code{FLT128_EPSILON}: difference between 1 and the next larger
                              representable number
 @item @code{FLT128_DENORM_MIN}: smallest positive denormalized number
 @item @code{FLT128_MANT_DIG}: number of digits in the mantissa (bit precision)
 @item @code{FLT128_MIN_EXP}: maximal negative exponent
 @item @code{FLT128_MAX_EXP}: maximal positive exponent
 @item @code{FLT128_DIG}: number of decimal digits in the mantissa
 @item @code{FLT128_MIN_10_EXP}: maximal negative decimal exponent
 @item @code{FLT128_MAX_10_EXP}: maximal positive decimal exponent
 @end table

 The following mathematical constants of type @code{__float128} are defined.

 @table @asis
 @item @code{M_Eq}: the constant e (Euler's number)
 @item @code{M_LOG2Eq}: binary logarithm of 2
 @item @code{M_LOG10Eq}: common, decimal logarithm of 2
 @item @code{M_LN2q}: natural logarithm of 2
 @item @code{M_LN10q}: natural logarithm of 10
 @item @code{M_PIq}: pi
 @item @code{M_PI_2q}: pi divided by two
 @item @code{M_PI_4q}: pi divided by four
 @item @code{M_1_PIq}: one over pi
 @item @code{M_2_PIq}: one over two pi
 @item @code{M_2_SQRTPIq}: two over square root of pi
 @item @code{M_SQRT2q}: square root of 2
 @item @code{M_SQRT1_2q}: one over square root of 2
 @end table


 @c ---------------------------------------------------------------------
 @c Math routines
 @c ---------------------------------------------------------------------

 @node Math Library Routines
 @chapter Math Library Routines

 The following mathematical functions are available:

 @table @asis
 @item @code{acosq}: arc cosine function
 @item @code{acoshq}: inverse hyperbolic cosine function
 @item @code{asinq}: arc sine function
 @item @code{asinhq}: inverse hyperbolic sine function
 @item @code{atanq}: arc tangent function
 @item @code{atanhq}: inverse hyperbolic tangent function
 @item @code{atan2q}: arc tangent function
 @item @code{cbrtq}: cube root function
 @item @code{ceilq}: ceiling value function
 @item @code{copysignq}: copy sign of a number
 @item @code{coshq}: hyperbolic cosine function
 @item @code{cosq}: cosine function
 @item @code{erfq}: error function
 @item @code{erfcq}: complementary error function
 @item @code{exp2q}: base 2 exponential function
 @item @code{expq}: exponential function
 @item @code{expm1q}: exponential minus 1 function
 @need 800
 @item @code{fabsq}: absolute value function
 @item @code{fdimq}: positive difference function
 @item @code{finiteq}: check finiteness of value
 @item @code{floorq}: floor value function
 @item @code{fmaq}: fused multiply and add
 @item @code{fmaxq}: determine maximum of two values
 @item @code{fminq}: determine minimum of two values
 @item @code{fmodq}: remainder value function
 @item @code{frexpq}: extract mantissa and exponent
 @item @code{hypotq}: Eucledian distance function
 @item @code{ilogbq}: get exponent of the value
 @item @code{isinfq}: check for infinity
 @item @code{isnanq}: check for not a number
 @item @code{issignalingq}: check for signaling not a number
 @item @code{j0q}: Bessel function of the first kind, first order
 @item @code{j1q}: Bessel function of the first kind, second order
 @item @code{jnq}: Bessel function of the first kind, @var{n}-th order
 @item @code{ldexpq}: load exponent of the value
 @item @code{lgammaq}: logarithmic gamma function
 @item @code{llrintq}: round to nearest integer value
 @item @code{llroundq}: round to nearest integer value away from zero
 @item @code{logbq}: get exponent of the value
 @item @code{logq}: natural logarithm function
 @item @code{log10q}: base 10 logarithm function
 @item @code{log1pq}: compute natural logarithm of the value plus one
 @item @code{log2q}: base 2 logarithm function
 @need 800
 @item @code{lrintq}: round to nearest integer value
 @item @code{lroundq}: round to nearest integer value away from zero
 @item @code{modfq}: decompose the floating-point number
 @item @code{nanq}: return quiet NaN
 @item @code{nearbyintq}: round to nearest integer
 @item @code{nextafterq}: next representable floating-point number
 @item @code{powq}: power function
 @item @code{remainderq}: remainder function
 @item @code{remquoq}: remainder and part of quotient
 @item @code{rintq}: round-to-nearest integral value
 @item @code{roundq}: round-to-nearest integral value, return @code{__float128}
 @item @code{scalblnq}: compute exponent using @code{FLT_RADIX}
 @item @code{scalbnq}: compute exponent using @code{FLT_RADIX}
 @item @code{signbitq}: return sign bit
 @item @code{sincosq}: calculate sine and cosine simultaneously
 @item @code{sinhq}: hyperbolic sine function
 @item @code{sinq}: sine function
 @item @code{sqrtq}: square root function
 @item @code{tanq}: tangent function
 @item @code{tanhq}: hyperbolic tangent function
 @need 800
 @item @code{tgammaq}: true gamma function
 @item @code{truncq}: round to integer, towards zero
 @item @code{y0q}: Bessel function of the second kind, first order
 @item @code{y1q}: Bessel function of the second kind, second order
 @item @code{ynq}: Bessel function of the second kind, @var{n}-th order
 @item @code{cabsq} complex absolute value function
 @item @code{cargq}: calculate the argument
 @item @code{cimagq} imaginary part of complex number
 @item @code{crealq}: real part of complex number
 @item @code{cacoshq}: complex arc hyperbolic cosine function
 @item @code{cacosq}: complex arc cosine function
 @item @code{casinhq}: complex arc hyperbolic sine function
 @item @code{casinq}: complex arc sine function
 @item @code{catanhq}: complex arc hyperbolic tangent function
 @item @code{catanq}: complex arc tangent function
 @item @code{ccosq} complex cosine function:
 @item @code{ccoshq}: complex hyperbolic cosine function
 @item @code{cexpq}: complex exponential function
 @need 800
 @item @code{cexpiq}: computes the exponential function of ``i'' times a
                      real value
 @item @code{clogq}: complex natural logarithm
 @item @code{clog10q}: complex base 10 logarithm
 @item @code{conjq}: complex conjugate function
 @item @code{cpowq}: complex power function
 @item @code{cprojq}: project into Riemann Sphere
 @item @code{csinq}: complex sine function
 @item @code{csinhq}: complex hyperbolic sine function
 @item @code{csqrtq}: complex square root
 @item @code{ctanq}: complex tangent function
 @item @code{ctanhq}: complex hyperbolic tangent function
 @end table


 @c ---------------------------------------------------------------------
 @c I/O routines
 @c ---------------------------------------------------------------------

 @node I/O Library Routines
 @chapter I/O Library Routines

 @menu
 * @code{strtoflt128}:          strtoflt128,          Convert from string
 * @code{quadmath_snprintf}:    quadmath_snprintf,    Convert to string
 @end menu


 @node strtoflt128
 @section @code{strtoflt128} --- Convert from string

 The function @code{strtoflt128} converts a string into a
 @code{__float128} number.

 @table @asis
 @item Syntax
 @code{__float128 strtoflt128 (const char *s, char **sp)}

 @item @emph{Arguments}:
 @multitable @columnfractions .15 .70
 @item @var{s}  @tab input string
 @item @var{sp} @tab the address of the next character in the string
 @end multitable

 The argument @var{sp} contains, if not @code{NULL}, the address of the
 next character following the parts of the string, which have been read.

 @item Example
 @smallexample
 #include <quadmath.h>

 int main ()
 @{
   __float128 r;

   r = strtoflt128 ("1.2345678", NULL);

   return 0;
 @}
 @end smallexample
 @end table


 @node quadmath_snprintf
 @section @code{quadmath_snprintf} --- Convert to string

 The function @code{quadmath_snprintf} converts a @code{__float128} floating-point
 number into a string.  It is a specialized alternative to @code{snprintf}, where
 the format string is restricted to a single conversion specifier with @code{Q}
 modifier and conversion specifier @code{e}, @code{E}, @code{f}, @code{F}, @code{g},
 @code{G}, @code{a} or @code{A}, with no extra characters before or after the
 conversion specifier.  The @code{%m$} or @code{*m$} style must not be used in
 the format.

 @table @asis
 @item Syntax
 @code{int quadmath_snprintf (char *s, size_t size, const char *format, ...)}

 @item @emph{Arguments}:
 @multitable @columnfractions .15 .70
 @item @var{s}    @tab output string
 @item @var{size} @tab byte size of the string, including trailing NUL
 @item @var{format} @tab conversion specifier string
 @end multitable

 @item Note
 On some targets when supported by the C library hooks are installed
 for @code{printf} family of functions, so that @code{printf ("%Qe", 1.2Q);}
 etc.@: works too.

 @item Example
 @smallexample
 #include <quadmath.h>
 #include <stdlib.h>
 #include <stdio.h>

 int main ()
 @{
   __float128 r;
   int prec = 20;
   int width = 46;
   char buf[128];

   r = 2.0q;
   r = sqrtq (r);
   int n = quadmath_snprintf (buf, sizeof buf, "%+-#*.20Qe", width, r);
   if ((size_t) n < sizeof buf)
     printf ("%s\n", buf);
     /* Prints: +1.41421356237309504880e+00 */
   quadmath_snprintf (buf, sizeof buf, "%Qa", r);
   if ((size_t) n < sizeof buf)
     printf ("%s\n", buf);
     /* Prints: 0x1.6a09e667f3bcc908b2fb1366ea96p+0 */
   n = quadmath_snprintf (NULL, 0, "%+-#46.*Qe", prec, r);
   if (n > -1)
     @{
       char *str = malloc (n + 1);
       if (str)
         @{
           quadmath_snprintf (str, n + 1, "%+-#46.*Qe", prec, r);
           printf ("%s\n", str);
           /* Prints: +1.41421356237309504880e+00 */
         @}
       free (str);
     @}
   return 0;
 @}
 @end smallexample

 @end table


 @c ---------------------------------------------------------------------
 @c GNU Free Documentation License
 @c ---------------------------------------------------------------------

 @include fdl.texi

 @c ---------------------------------------------------------------------
 @c Reporting Bugs
 @c ---------------------------------------------------------------------

 @c For BUGURL
 @include libquadmath-vers.texi

 @node Reporting Bugs
 @chapter Reporting Bugs

 Bugs in the GCC Quad-Precision Math Library implementation should be
 reported via @value{BUGURL}.


 @c ---------------------------------------------------------------------
 @c Index
 @c ---------------------------------------------------------------------

 @c @node Index
 @c @unnumbered Index
 @c
 @c @printindex cp

 @bye
	\input texinfo @c --texinfo--

	@c %**start of header
	@setfilename libquadmath.info
	@settitle GCC libquadmath
	@c %**end of header

	@copying
	Copyright @copyright{} 2010-2022 Free Software Foundation, Inc.

	@quotation
	Permission is granted to copy, distribute and/or modify this document
	under the terms of the GNU Free Documentation License, Version 1.2 or
	any later version published by the Free Software Foundation; with no
	Invariant Sections, with the Front-Cover Texts being ``A GNU Manual,''
	and with the Back-Cover Texts as in (a) below. A copy of the
	license is included in the section entitled ``GNU Free Documentation
	License.''

	(a) The FSF's Back-Cover Text is: ``You have the freedom to
	copy and modify this GNU manual.
	@end quotation
	@end copying

	@ifinfo
	@dircategory GNU Libraries
	@direntry
	* libquadmath: (libquadmath). GCC Quad-Precision Math Library
	@end direntry

	This manual documents the GCC Quad-Precision Math Library API.

	Published by the Free Software Foundation
	51 Franklin Street, Fifth Floor
	Boston, MA 02110-1301 USA

	@insertcopying
	@end ifinfo


	@setchapternewpage odd

	@titlepage
	@title The GCC Quad-Precision Math Library
	@page
	@vskip 0pt plus 1filll
	@comment For the @value{version-GCC} Version*
	@sp 1
	Published by the Free Software Foundation @*
	51 Franklin Street, Fifth Floor@*
	Boston, MA 02110-1301, USA@*
	@sp 1
	@insertcopying
	@end titlepage

	@summarycontents
	@contents
	@page


	@node Top
	@top Introduction
	@cindex Introduction

	This manual documents the usage of libquadmath, the GCC Quad-Precision
	Math Library Application Programming Interface (API).


	@comment
	@comment When you add a new menu item, please keep the right hand
	@comment aligned to the same column. Do not use tabs. This provides
	@comment better formatting.
	@comment
	@menu
	* Typedef and constants:: Defined data types and constants
	* Math Library Routines:: The Libquadmath math runtime application
	programming interface.
	* I/O Library Routines:: The Libquadmath I/O runtime application
	programming interface.
	* GNU Free Documentation License::
	How you can copy and share this manual.
	* Reporting Bugs:: How to report bugs in GCC Libquadmath.
	@c * Index:: Index of this documentation.
	@end menu


	@c ---------------------------------------------------------------------
	@c Defined macros
	@c ---------------------------------------------------------------------

	@node Typedef and constants
	@chapter Typedef and constants

	The following data type has been defined via @code{typedef}.

	@table @asis
	@item @code{__complex128}: @code{__float128}-based complex number
	@end table

	The following macros are defined, which give the numeric limits of the
	@code{__float128} data type.

	@table @asis
	@item @code{FLT128_MAX}: largest finite number
	@item @code{FLT128_MIN}: smallest positive number with full precision
	@item @code{FLT128_EPSILON}: difference between 1 and the next larger
	representable number
	@item @code{FLT128_DENORM_MIN}: smallest positive denormalized number
	@item @code{FLT128_MANT_DIG}: number of digits in the mantissa (bit precision)
	@item @code{FLT128_MIN_EXP}: maximal negative exponent
	@item @code{FLT128_MAX_EXP}: maximal positive exponent
	@item @code{FLT128_DIG}: number of decimal digits in the mantissa
	@item @code{FLT128_MIN_10_EXP}: maximal negative decimal exponent
	@item @code{FLT128_MAX_10_EXP}: maximal positive decimal exponent
	@end table

	The following mathematical constants of type @code{__float128} are defined.

	@table @asis
	@item @code{M_Eq}: the constant e (Euler's number)
	@item @code{M_LOG2Eq}: binary logarithm of 2
	@item @code{M_LOG10Eq}: common, decimal logarithm of 2
	@item @code{M_LN2q}: natural logarithm of 2
	@item @code{M_LN10q}: natural logarithm of 10
	@item @code{M_PIq}: pi
	@item @code{M_PI_2q}: pi divided by two
	@item @code{M_PI_4q}: pi divided by four
	@item @code{M_1_PIq}: one over pi
	@item @code{M_2_PIq}: one over two pi
	@item @code{M_2_SQRTPIq}: two over square root of pi
	@item @code{M_SQRT2q}: square root of 2
	@item @code{M_SQRT1_2q}: one over square root of 2
	@end table


	@c ---------------------------------------------------------------------
	@c Math routines
	@c ---------------------------------------------------------------------

	@node Math Library Routines
	@chapter Math Library Routines

	The following mathematical functions are available:

	@table @asis
	@item @code{acosq}: arc cosine function
	@item @code{acoshq}: inverse hyperbolic cosine function
	@item @code{asinq}: arc sine function
	@item @code{asinhq}: inverse hyperbolic sine function
	@item @code{atanq}: arc tangent function
	@item @code{atanhq}: inverse hyperbolic tangent function
	@item @code{atan2q}: arc tangent function
	@item @code{cbrtq}: cube root function
	@item @code{ceilq}: ceiling value function
	@item @code{copysignq}: copy sign of a number
	@item @code{coshq}: hyperbolic cosine function
	@item @code{cosq}: cosine function
	@item @code{erfq}: error function
	@item @code{erfcq}: complementary error function
	@item @code{exp2q}: base 2 exponential function
	@item @code{expq}: exponential function
	@item @code{expm1q}: exponential minus 1 function
	@need 800
	@item @code{fabsq}: absolute value function
	@item @code{fdimq}: positive difference function
	@item @code{finiteq}: check finiteness of value
	@item @code{floorq}: floor value function
	@item @code{fmaq}: fused multiply and add
	@item @code{fmaxq}: determine maximum of two values
	@item @code{fminq}: determine minimum of two values
	@item @code{fmodq}: remainder value function
	@item @code{frexpq}: extract mantissa and exponent
	@item @code{hypotq}: Eucledian distance function
	@item @code{ilogbq}: get exponent of the value
	@item @code{isinfq}: check for infinity
	@item @code{isnanq}: check for not a number
	@item @code{issignalingq}: check for signaling not a number
	@item @code{j0q}: Bessel function of the first kind, first order
	@item @code{j1q}: Bessel function of the first kind, second order
	@item @code{jnq}: Bessel function of the first kind, @var{n}-th order
	@item @code{ldexpq}: load exponent of the value
	@item @code{lgammaq}: logarithmic gamma function
	@item @code{llrintq}: round to nearest integer value
	@item @code{llroundq}: round to nearest integer value away from zero
	@item @code{logbq}: get exponent of the value
	@item @code{logq}: natural logarithm function
	@item @code{log10q}: base 10 logarithm function
	@item @code{log1pq}: compute natural logarithm of the value plus one
	@item @code{log2q}: base 2 logarithm function
	@need 800
	@item @code{lrintq}: round to nearest integer value
	@item @code{lroundq}: round to nearest integer value away from zero
	@item @code{modfq}: decompose the floating-point number
	@item @code{nanq}: return quiet NaN
	@item @code{nearbyintq}: round to nearest integer
	@item @code{nextafterq}: next representable floating-point number
	@item @code{powq}: power function
	@item @code{remainderq}: remainder function
	@item @code{remquoq}: remainder and part of quotient
	@item @code{rintq}: round-to-nearest integral value
	@item @code{roundq}: round-to-nearest integral value, return @code{__float128}
	@item @code{scalblnq}: compute exponent using @code{FLT_RADIX}
	@item @code{scalbnq}: compute exponent using @code{FLT_RADIX}
	@item @code{signbitq}: return sign bit
	@item @code{sincosq}: calculate sine and cosine simultaneously
	@item @code{sinhq}: hyperbolic sine function
	@item @code{sinq}: sine function
	@item @code{sqrtq}: square root function
	@item @code{tanq}: tangent function
	@item @code{tanhq}: hyperbolic tangent function
	@need 800
	@item @code{tgammaq}: true gamma function
	@item @code{truncq}: round to integer, towards zero
	@item @code{y0q}: Bessel function of the second kind, first order
	@item @code{y1q}: Bessel function of the second kind, second order
	@item @code{ynq}: Bessel function of the second kind, @var{n}-th order
	@item @code{cabsq} complex absolute value function
	@item @code{cargq}: calculate the argument
	@item @code{cimagq} imaginary part of complex number
	@item @code{crealq}: real part of complex number
	@item @code{cacoshq}: complex arc hyperbolic cosine function
	@item @code{cacosq}: complex arc cosine function
	@item @code{casinhq}: complex arc hyperbolic sine function
	@item @code{casinq}: complex arc sine function
	@item @code{catanhq}: complex arc hyperbolic tangent function
	@item @code{catanq}: complex arc tangent function
	@item @code{ccosq} complex cosine function:
	@item @code{ccoshq}: complex hyperbolic cosine function
	@item @code{cexpq}: complex exponential function
	@need 800
	@item @code{cexpiq}: computes the exponential function of ``i'' times a
	real value
	@item @code{clogq}: complex natural logarithm
	@item @code{clog10q}: complex base 10 logarithm
	@item @code{conjq}: complex conjugate function
	@item @code{cpowq}: complex power function
	@item @code{cprojq}: project into Riemann Sphere
	@item @code{csinq}: complex sine function
	@item @code{csinhq}: complex hyperbolic sine function
	@item @code{csqrtq}: complex square root
	@item @code{ctanq}: complex tangent function
	@item @code{ctanhq}: complex hyperbolic tangent function
	@end table


	@c ---------------------------------------------------------------------
	@c I/O routines
	@c ---------------------------------------------------------------------

	@node I/O Library Routines
	@chapter I/O Library Routines

	@menu
	* @code{strtoflt128}: strtoflt128, Convert from string
	* @code{quadmath_snprintf}: quadmath_snprintf, Convert to string
	@end menu


	@node strtoflt128
	@section @code{strtoflt128} --- Convert from string

	The function @code{strtoflt128} converts a string into a
	@code{__float128} number.

	@table @asis
	@item Syntax
	@code{__float128 strtoflt128 (const char s, char *sp)}

	@item @emph{Arguments}:
	@multitable @columnfractions .15 .70
	@item @var{s} @tab input string
	@item @var{sp} @tab the address of the next character in the string
	@end multitable

	The argument @var{sp} contains, if not @code{NULL}, the address of the
	next character following the parts of the string, which have been read.

	@item Example
	@smallexample
	#include <quadmath.h>

	int main ()
	@{
	__float128 r;

	r = strtoflt128 ("1.2345678", NULL);

	return 0;
	@}
	@end smallexample
	@end table


	@node quadmath_snprintf
	@section @code{quadmath_snprintf} --- Convert to string

	The function @code{quadmath_snprintf} converts a @code{__float128} floating-point
	number into a string. It is a specialized alternative to @code{snprintf}, where
	the format string is restricted to a single conversion specifier with @code{Q}
	modifier and conversion specifier @code{e}, @code{E}, @code{f}, @code{F}, @code{g},
	@code{G}, @code{a} or @code{A}, with no extra characters before or after the
	conversion specifier. The @code{%m$} or @code{*m$} style must not be used in
	the format.

	@table @asis
	@item Syntax
	@code{int quadmath_snprintf (char s, size_t size, const char format, ...)}

	@item @emph{Arguments}:
	@multitable @columnfractions .15 .70
	@item @var{s} @tab output string
	@item @var{size} @tab byte size of the string, including trailing NUL
	@item @var{format} @tab conversion specifier string
	@end multitable

	@item Note
	On some targets when supported by the C library hooks are installed
	for @code{printf} family of functions, so that @code{printf ("%Qe", 1.2Q);}
	etc.@: works too.

	@item Example
	@smallexample
	#include <quadmath.h>
	#include <stdlib.h>
	#include <stdio.h>

	int main ()
	@{
	__float128 r;
	int prec = 20;
	int width = 46;
	char buf[128];

	r = 2.0q;
	r = sqrtq (r);
	int n = quadmath_snprintf (buf, sizeof buf, "%+-#*.20Qe", width, r);
	if ((size_t) n < sizeof buf)
	printf ("%s\n", buf);
	/* Prints: +1.41421356237309504880e+00 */
	quadmath_snprintf (buf, sizeof buf, "%Qa", r);
	if ((size_t) n < sizeof buf)
	printf ("%s\n", buf);
	/* Prints: 0x1.6a09e667f3bcc908b2fb1366ea96p+0 */
	n = quadmath_snprintf (NULL, 0, "%+-#46.*Qe", prec, r);
	if (n > -1)
	@{
	char *str = malloc (n + 1);
	if (str)
	@{
	quadmath_snprintf (str, n + 1, "%+-#46.*Qe", prec, r);
	printf ("%s\n", str);
	/* Prints: +1.41421356237309504880e+00 */
	@}
	free (str);
	@}
	return 0;
	@}
	@end smallexample

	@end table


	@c ---------------------------------------------------------------------
	@c GNU Free Documentation License
	@c ---------------------------------------------------------------------

	@include fdl.texi

	@c ---------------------------------------------------------------------
	@c Reporting Bugs
	@c ---------------------------------------------------------------------

	@c For BUGURL
	@include libquadmath-vers.texi

	@node Reporting Bugs
	@chapter Reporting Bugs

	Bugs in the GCC Quad-Precision Math Library implementation should be
	reported via @value{BUGURL}.


	@c ---------------------------------------------------------------------
	@c Index
	@c ---------------------------------------------------------------------

	@c @node Index
	@c @unnumbered Index
	@c
	@c @printindex cp

	@bye