man3/matherr.3 - pub/scm/docs/man-pages/man-pages - Git at Google

 .\" Copyright (c) 2008, Linux Foundation, written by Michael Kerrisk
 .\"     <mtk.manpages@gmail.com>
 .\"
 .\" %%%LICENSE_START(VERBATIM)
 .\" Permission is granted to make and distribute verbatim copies of this
 .\" manual provided the copyright notice and this permission notice are
 .\" preserved on all copies.
 .\"
 .\" Permission is granted to copy and distribute modified versions of this
 .\" manual under the conditions for verbatim copying, provided that the
 .\" entire resulting derived work is distributed under the terms of a
 .\" permission notice identical to this one.
 .\"
 .\" Since the Linux kernel and libraries are constantly changing, this
 .\" manual page may be incorrect or out-of-date.  The author(s) assume no
 .\" responsibility for errors or omissions, or for damages resulting from
 .\" the use of the information contained herein.  The author(s) may not
 .\" have taken the same level of care in the production of this manual,
 .\" which is licensed free of charge, as they might when working
 .\" professionally.
 .\"
 .\" Formatted or processed versions of this manual, if unaccompanied by
 .\" the source, must acknowledge the copyright and authors of this work.
 .\" %%%LICENSE_END
 .\"
 .TH MATHERR 3 2021-03-22 "Linux" "Linux Programmer's Manual"
 .SH NAME
 matherr \- SVID math library exception handling
 .SH SYNOPSIS
 .nf
 .B #include <math.h>
 .PP
 .BI "int matherr(struct exception *" exc );
 .PP
 .B extern _LIB_VERSION_TYPE _LIB_VERSION;
 .fi
 .PP
 Link with \fI\-lm\fP.
 .SH DESCRIPTION
 .IR Note :
 the mechanism described in this page is no longer supported by glibc.
 Before glibc 2.27, it had been marked as obsolete.
 Since glibc 2.27,
 .\" glibc commit 813378e9fe17e029caf627cab76fe23eb46815fa
 the mechanism has been removed altogether.
 New applications should use the techniques described in
 .BR math_error (7)
 and
 .BR fenv (3).
 This page documents the
 .BR matherr ()
 mechanism as an aid for maintaining and porting older applications.
 .PP
 The System V Interface Definition (SVID) specifies that various
 math functions should invoke a function called
 .BR matherr ()
 if a math exception is detected.
 This function is called before the math function returns;
 after
 .BR matherr ()
 returns, the system then returns to the math function,
 which in turn returns to the caller.
 .PP
 To employ
 .BR matherr (),
 the programmer must define the
 .B _SVID_SOURCE
 feature test macro
 (before including
 .I any
 header files),
 and assign the value
 .B _SVID_
 to the external variable
 .BR _LIB_VERSION .
 .PP
 The system provides a default version of
 .BR matherr ().
 This version does nothing, and returns zero
 (see below for the significance of this).
 The default
 .BR matherr ()
 can be overridden by a programmer-defined
 version, which will be invoked when an exception occurs.
 The function is invoked with one argument, a pointer to an
 .I exception
 structure, defined as follows:
 .PP
 .in +4n
 .EX
 struct exception {
     int    type;      /* Exception type */
     char  *name;      /* Name of function causing exception */
     double arg1;      /* 1st argument to function */
     double arg2;      /* 2nd argument to function */
     double retval;    /* Function return value */
 }
 .EE
 .in
 .PP
 The
 .I type
 field has one of the following values:
 .TP 12
 .B DOMAIN
 A domain error occurred (the function argument was outside the range
 for which the function is defined).
 The return value depends on the function;
 .I errno
 is set to
 .BR EDOM .
 .TP
 .B SING
 A pole error occurred (the function result is an infinity).
 The return value in most cases is
 .B HUGE
 (the largest single precision floating-point number),
 appropriately signed.
 In most cases,
 .I errno
 is set to
 .BR EDOM .
 .TP
 .B OVERFLOW
 An overflow occurred.
 In most cases, the value
 .B HUGE
 is returned, and
 .I errno
 is set to
 .BR ERANGE .
 .TP
 .B UNDERFLOW
 An underflow occurred.
 0.0 is returned, and
 .I errno
 is set to
 .BR ERANGE .
 .TP
 .B TLOSS
 Total loss of significance.
 0.0 is returned, and
 .I errno
 is set to
 .BR ERANGE .
 .TP
 .B PLOSS
 Partial loss of significance.
 This value is unused on glibc
 (and many other systems).
 .PP
 The
 .I arg1
 and
 .I arg2
 fields are the arguments supplied to the function
 .RI ( arg2
 is undefined for functions that take only one argument).
 .PP
 The
 .I retval
 field specifies the return value that the math
 function will return to its caller.
 The programmer-defined
 .BR matherr ()
 can modify this field to change the return value of the math function.
 .PP
 If the
 .BR matherr ()
 function returns zero, then the system sets
 .I errno
 as described above, and may print an error message on standard error
 (see below).
 .PP
 If the
 .BR matherr ()
 function returns a nonzero value, then the system does not set
 .IR errno ,
 and doesn't print an error message.
 .SS Math functions that employ matherr()
 The table below lists the functions and circumstances in which
 .BR matherr ()
 is called.
 The "Type" column indicates the value assigned to
 .I exc\->type
 when calling
 .BR matherr ().
 The "Result" column is the default return value assigned to
 .IR exc\->retval .
 .PP
 The "Msg?" and "errno" columns describe the default behavior if
 .BR matherr ()
 returns zero.
 If the "Msg?" columns contains "y",
 then the system prints an error message on standard error.
 .PP
 The table uses the following notations and abbreviations:
 .PP
 .RS
 .TS
 l l.
 x        first argument to function
 y        second argument to function
 fin      finite value for argument
 neg      negative value for argument
 int      integral value for argument
 o/f      result overflowed
 u/f      result underflowed
 |x|      absolute value of x
 X_TLOSS  is a constant defined in \fI<math.h>\fP
 .TE
 .RE
 .\" Details below from glibc 2.8's sysdeps/ieee754/k_standard.c
 .\" A subset of cases were test by experimental programs.
 .TS
 lB lB lB cB lB
 l l l c l.
 Function	Type	Result	Msg?	errno
 acos(|x|>1)	DOMAIN	HUGE	y	EDOM
 asin(|x|>1)	DOMAIN	HUGE	y	EDOM
 atan2(0,0)	DOMAIN	HUGE	y	EDOM
 acosh(x<1)	DOMAIN	NAN	y	EDOM	\" retval is 0.0/0.0
 atanh(|x|>1)	DOMAIN	NAN	y	EDOM	\" retval is 0.0/0.0
 atanh(|x|==1)	SING	(x>0.0)?	y	EDOM	\" retval is x/0.0
 \ 	\ 	HUGE_VAL :
 \ 	\ 	\-HUGE_VAL
 cosh(fin) o/f	OVERFLOW	HUGE	n	ERANGE
 sinh(fin) o/f	OVERFLOW	(x>0.0) ?	n	ERANGE
 \ 	\ 	HUGE : \-HUGE
 sqrt(x<0)	DOMAIN	0.0	y	EDOM
 hypot(fin,fin) o/f	OVERFLOW	HUGE	n	ERANGE
 exp(fin) o/f	OVERFLOW	HUGE	n	ERANGE
 exp(fin) u/f	UNDERFLOW	0.0	n	ERANGE
 exp2(fin) o/f	OVERFLOW	HUGE	n	ERANGE
 exp2(fin) u/f	UNDERFLOW	0.0	n	ERANGE
 exp10(fin) o/f	OVERFLOW	HUGE	n	ERANGE
 exp10(fin) u/f	UNDERFLOW	0.0	n	ERANGE
 j0(|x|>X_TLOSS)	TLOSS	0.0	y	ERANGE
 j1(|x|>X_TLOSS)	TLOSS	0.0	y	ERANGE
 jn(|x|>X_TLOSS)	TLOSS	0.0	y	ERANGE
 y0(x>X_TLOSS)	TLOSS	0.0	y	ERANGE
 y1(x>X_TLOSS)	TLOSS	0.0	y	ERANGE
 yn(x>X_TLOSS)	TLOSS	0.0	y	ERANGE
 y0(0)	DOMAIN	\-HUGE	y	EDOM
 y0(x<0)	DOMAIN	\-HUGE	y	EDOM
 y1(0)	DOMAIN	\-HUGE	y	EDOM
 y1(x<0)	DOMAIN	\-HUGE	y	EDOM
 yn(n,0)	DOMAIN	\-HUGE	y	EDOM
 yn(x<0)	DOMAIN	\-HUGE	y	EDOM
 lgamma(fin) o/f	OVERFLOW	HUGE	n	ERANGE
 lgamma(\-int) or	SING	HUGE	y	EDOM
 \ \ lgamma(0)
 tgamma(fin) o/f	OVERFLOW	HUGE_VAL	n	ERANGE
 tgamma(\-int)	SING	NAN	y	EDOM
 tgamma(0)	SING	copysign(	y	ERANGE
 \ 	\ 	HUGE_VAL,x)
 log(0)	SING	\-HUGE	y	EDOM
 log(x<0)	DOMAIN	\-HUGE	y	EDOM
 log2(0)	SING	\-HUGE	n	EDOM	\" different from log()
 log2(x<0)	DOMAIN	\-HUGE	n	EDOM	\" different from log()
 log10(0)	SING	\-HUGE	y	EDOM
 log10(x<0)	DOMAIN	\-HUGE	y	EDOM
 pow(0.0,0.0)	DOMAIN	0.0	y	EDOM
 pow(x,y) o/f	OVERFLOW	HUGE	n	ERANGE
 pow(x,y) u/f	UNDERFLOW	0.0	n	ERANGE
 pow(NaN,0.0)	DOMAIN	x	n	EDOM
 0**neg	DOMAIN	0.0	y	EDOM	\" +0 and -0
 neg**non-int	DOMAIN	0.0	y	EDOM
 scalb() o/f	OVERFLOW	(x>0.0) ?	n	ERANGE
 \ 	\ 	HUGE_VAL :
 \ 	\ 	\-HUGE_VAL
 scalb() u/f	UNDERFLOW	copysign(	n	ERANGE
 \ 	\ 	\ \ 0.0,x)
 fmod(x,0)	DOMAIN	x	y	EDOM
 remainder(x,0)	DOMAIN	NAN	y	EDOM	\" retval is 0.0/0.0
 .TE
 .SH ATTRIBUTES
 For an explanation of the terms used in this section, see
 .BR attributes (7).
 .ad l
 .nh
 .TS
 allbox;
 lbx lb lb
 l l l.
 Interface	Attribute	Value
 T{
 .BR matherr ()
 T}	Thread safety	MT-Safe
 .TE
 .hy
 .ad
 .sp 1
 .SH EXAMPLES
 The example program demonstrates the use of
 .BR matherr ()
 when calling
 .BR log (3).
 The program takes up to three command-line arguments.
 The first argument is the floating-point number to be given to
 .BR log (3).
 If the optional second argument is provided, then
 .B _LIB_VERSION
 is set to
 .B _SVID_
 so that
 .BR matherr ()
 is called, and the integer supplied in the
 command-line argument is used as the return value from
 .BR matherr ().
 If the optional third command-line argument is supplied,
 then it specifies an alternative return value that
 .BR matherr ()
 should assign as the return value of the math function.
 .PP
 The following example run, where
 .BR log (3)
 is given an argument of 0.0, does not use
 .BR matherr ():
 .PP
 .in +4n
 .EX
 .RB "$" " ./a.out 0.0"
 errno: Numerical result out of range
 x=\-inf
 .EE
 .in
 .PP
 In the following run,
 .BR matherr ()
 is called, and returns 0:
 .PP
 .in +4n
 .EX
 .RB "$" " ./a.out 0.0 0"
 matherr SING exception in log() function
         args:   0.000000, 0.000000
         retval: \-340282346638528859811704183484516925440.000000
 log: SING error
 errno: Numerical argument out of domain
 x=\-340282346638528859811704183484516925440.000000
 .EE
 .in
 .PP
 The message "log: SING error" was printed by the C library.
 .PP
 In the following run,
 .BR matherr ()
 is called, and returns a nonzero value:
 .PP
 .in +4n
 .EX
 .RB "$" " ./a.out 0.0 1"
 matherr SING exception in log() function
         args:   0.000000, 0.000000
         retval: \-340282346638528859811704183484516925440.000000
 x=\-340282346638528859811704183484516925440.000000
 .EE
 .in
 .PP
 In this case, the C library did not print a message, and
 .I errno
 was not set.
 .PP
 In the following run,
 .BR matherr ()
 is called, changes the return value of the math function,
 and returns a nonzero value:
 .PP
 .in +4n
 .EX
 .RB "$" " ./a.out 0.0 1 12345.0"
 matherr SING exception in log() function
         args:   0.000000, 0.000000
         retval: \-340282346638528859811704183484516925440.000000
 x=12345.000000
 .EE
 .in
 .SS Program source
 \&
 .EX
 #define _SVID_SOURCE
 #include <errno.h>
 #include <math.h>
 #include <stdio.h>
 #include <stdlib.h>

 static int matherr_ret = 0;     /* Value that matherr()
                                    should return */
 static int change_retval = 0;   /* Should matherr() change
                                    function\(aqs return value? */
 static double new_retval;       /* New function return value */

 int
 matherr(struct exception *exc)
 {
     fprintf(stderr, "matherr %s exception in %s() function\en",
            (exc\->type == DOMAIN) ?    "DOMAIN" :
            (exc\->type == OVERFLOW) ?  "OVERFLOW" :
            (exc\->type == UNDERFLOW) ? "UNDERFLOW" :
            (exc\->type == SING) ?      "SING" :
            (exc\->type == TLOSS) ?     "TLOSS" :
            (exc\->type == PLOSS) ?     "PLOSS" : "???",
             exc\->name);
     fprintf(stderr, "        args:   %f, %f\en",
             exc\->arg1, exc\->arg2);
     fprintf(stderr, "        retval: %f\en", exc\->retval);

     if (change_retval)
         exc\->retval = new_retval;

     return matherr_ret;
 }

 int
 main(int argc, char *argv[])
 {
     double x;

     if (argc < 2) {
         fprintf(stderr, "Usage: %s <argval>"
                 " [<matherr\-ret> [<new\-func\-retval>]]\en", argv[0]);
         exit(EXIT_FAILURE);
     }

     if (argc > 2) {
         _LIB_VERSION = _SVID_;
         matherr_ret = atoi(argv[2]);
     }

     if (argc > 3) {
         change_retval = 1;
         new_retval = atof(argv[3]);
     }

     x = log(atof(argv[1]));
     if (errno != 0)
         perror("errno");

     printf("x=%f\en", x);
     exit(EXIT_SUCCESS);
 }
 .EE
 .SH SEE ALSO
 .BR fenv (3),
 .BR math_error (7),
 .BR standards (7)
	.\" Copyright (c) 2008, Linux Foundation, written by Michael Kerrisk
	.\" <mtk.manpages@gmail.com>
	.\"
	.\" %%%LICENSE_START(VERBATIM)
	.\" Permission is granted to make and distribute verbatim copies of this
	.\" manual provided the copyright notice and this permission notice are
	.\" preserved on all copies.
	.\"
	.\" Permission is granted to copy and distribute modified versions of this
	.\" manual under the conditions for verbatim copying, provided that the
	.\" entire resulting derived work is distributed under the terms of a
	.\" permission notice identical to this one.
	.\"
	.\" Since the Linux kernel and libraries are constantly changing, this
	.\" manual page may be incorrect or out-of-date. The author(s) assume no
	.\" responsibility for errors or omissions, or for damages resulting from
	.\" the use of the information contained herein. The author(s) may not
	.\" have taken the same level of care in the production of this manual,
	.\" which is licensed free of charge, as they might when working
	.\" professionally.
	.\"
	.\" Formatted or processed versions of this manual, if unaccompanied by
	.\" the source, must acknowledge the copyright and authors of this work.
	.\" %%%LICENSE_END
	.\"
	.TH MATHERR 3 2021-03-22 "Linux" "Linux Programmer's Manual"
	.SH NAME
	matherr \- SVID math library exception handling
	.SH SYNOPSIS
	.nf
	.B #include <math.h>
	.PP
	.BI "int matherr(struct exception *" exc );
	.PP
	.B extern _LIB_VERSION_TYPE _LIB_VERSION;
	.fi
	.PP
	Link with \fI\-lm\fP.
	.SH DESCRIPTION
	.IR Note :
	the mechanism described in this page is no longer supported by glibc.
	Before glibc 2.27, it had been marked as obsolete.
	Since glibc 2.27,
	.\" glibc commit 813378e9fe17e029caf627cab76fe23eb46815fa
	the mechanism has been removed altogether.
	New applications should use the techniques described in
	.BR math_error (7)
	and
	.BR fenv (3).
	This page documents the
	.BR matherr ()
	mechanism as an aid for maintaining and porting older applications.
	.PP
	The System V Interface Definition (SVID) specifies that various
	math functions should invoke a function called
	.BR matherr ()
	if a math exception is detected.
	This function is called before the math function returns;
	after
	.BR matherr ()
	returns, the system then returns to the math function,
	which in turn returns to the caller.
	.PP
	To employ
	.BR matherr (),
	the programmer must define the
	.B _SVID_SOURCE
	feature test macro
	(before including
	.I any
	header files),
	and assign the value
	.B _SVID_
	to the external variable
	.BR _LIB_VERSION .
	.PP
	The system provides a default version of
	.BR matherr ().
	This version does nothing, and returns zero
	(see below for the significance of this).
	The default
	.BR matherr ()
	can be overridden by a programmer-defined
	version, which will be invoked when an exception occurs.
	The function is invoked with one argument, a pointer to an
	.I exception
	structure, defined as follows:
	.PP
	.in +4n
	.EX
	struct exception {
	int type; /* Exception type */
	char name; / Name of function causing exception */
	double arg1; /* 1st argument to function */
	double arg2; /* 2nd argument to function */
	double retval; /* Function return value */
	}
	.EE
	.in
	.PP
	The
	.I type
	field has one of the following values:
	.TP 12
	.B DOMAIN
	A domain error occurred (the function argument was outside the range
	for which the function is defined).
	The return value depends on the function;
	.I errno
	is set to
	.BR EDOM .
	.TP
	.B SING
	A pole error occurred (the function result is an infinity).
	The return value in most cases is
	.B HUGE
	(the largest single precision floating-point number),
	appropriately signed.
	In most cases,
	.I errno
	is set to
	.BR EDOM .
	.TP
	.B OVERFLOW
	An overflow occurred.
	In most cases, the value
	.B HUGE
	is returned, and
	.I errno
	is set to
	.BR ERANGE .
	.TP
	.B UNDERFLOW
	An underflow occurred.
	0.0 is returned, and
	.I errno
	is set to
	.BR ERANGE .
	.TP
	.B TLOSS
	Total loss of significance.
	0.0 is returned, and
	.I errno
	is set to
	.BR ERANGE .
	.TP
	.B PLOSS
	Partial loss of significance.
	This value is unused on glibc
	(and many other systems).
	.PP
	The
	.I arg1
	and
	.I arg2
	fields are the arguments supplied to the function
	.RI ( arg2
	is undefined for functions that take only one argument).
	.PP
	The
	.I retval
	field specifies the return value that the math
	function will return to its caller.
	The programmer-defined
	.BR matherr ()
	can modify this field to change the return value of the math function.
	.PP
	If the
	.BR matherr ()
	function returns zero, then the system sets
	.I errno
	as described above, and may print an error message on standard error
	(see below).
	.PP
	If the
	.BR matherr ()
	function returns a nonzero value, then the system does not set
	.IR errno ,
	and doesn't print an error message.
	.SS Math functions that employ matherr()
	The table below lists the functions and circumstances in which
	.BR matherr ()
	is called.
	The "Type" column indicates the value assigned to
	.I exc\->type
	when calling
	.BR matherr ().
	The "Result" column is the default return value assigned to
	.IR exc\->retval .
	.PP
	The "Msg?" and "errno" columns describe the default behavior if
	.BR matherr ()
	returns zero.
	If the "Msg?" columns contains "y",
	then the system prints an error message on standard error.
	.PP
	The table uses the following notations and abbreviations:
	.PP
	.RS
	.TS
	l l.
	x first argument to function
	y second argument to function
	fin finite value for argument
	neg negative value for argument
	int integral value for argument
	o/f result overflowed
	u/f result underflowed
	\|x\| absolute value of x
	X_TLOSS is a constant defined in \fI<math.h>\fP
	.TE
	.RE
	.\" Details below from glibc 2.8's sysdeps/ieee754/k_standard.c
	.\" A subset of cases were test by experimental programs.
	.TS
	lB lB lB cB lB
	l l l c l.
	Function Type Result Msg? errno
	acos(\|x\|>1) DOMAIN HUGE y EDOM
	asin(\|x\|>1) DOMAIN HUGE y EDOM
	atan2(0,0) DOMAIN HUGE y EDOM
	acosh(x<1) DOMAIN NAN y EDOM \" retval is 0.0/0.0
	atanh(\|x\|>1) DOMAIN NAN y EDOM \" retval is 0.0/0.0
	atanh(\|x\|==1) SING (x>0.0)? y EDOM \" retval is x/0.0
	\ \ HUGE_VAL :
	\ \ \-HUGE_VAL
	cosh(fin) o/f OVERFLOW HUGE n ERANGE
	sinh(fin) o/f OVERFLOW (x>0.0) ? n ERANGE
	\ \ HUGE : \-HUGE
	sqrt(x<0) DOMAIN 0.0 y EDOM
	hypot(fin,fin) o/f OVERFLOW HUGE n ERANGE
	exp(fin) o/f OVERFLOW HUGE n ERANGE
	exp(fin) u/f UNDERFLOW 0.0 n ERANGE
	exp2(fin) o/f OVERFLOW HUGE n ERANGE
	exp2(fin) u/f UNDERFLOW 0.0 n ERANGE
	exp10(fin) o/f OVERFLOW HUGE n ERANGE
	exp10(fin) u/f UNDERFLOW 0.0 n ERANGE
	j0(\|x\|>X_TLOSS) TLOSS 0.0 y ERANGE
	j1(\|x\|>X_TLOSS) TLOSS 0.0 y ERANGE
	jn(\|x\|>X_TLOSS) TLOSS 0.0 y ERANGE
	y0(x>X_TLOSS) TLOSS 0.0 y ERANGE
	y1(x>X_TLOSS) TLOSS 0.0 y ERANGE
	yn(x>X_TLOSS) TLOSS 0.0 y ERANGE
	y0(0) DOMAIN \-HUGE y EDOM
	y0(x<0) DOMAIN \-HUGE y EDOM
	y1(0) DOMAIN \-HUGE y EDOM
	y1(x<0) DOMAIN \-HUGE y EDOM
	yn(n,0) DOMAIN \-HUGE y EDOM
	yn(x<0) DOMAIN \-HUGE y EDOM
	lgamma(fin) o/f OVERFLOW HUGE n ERANGE
	lgamma(\-int) or SING HUGE y EDOM
	\ \ lgamma(0)
	tgamma(fin) o/f OVERFLOW HUGE_VAL n ERANGE
	tgamma(\-int) SING NAN y EDOM
	tgamma(0) SING copysign( y ERANGE
	\ \ HUGE_VAL,x)
	log(0) SING \-HUGE y EDOM
	log(x<0) DOMAIN \-HUGE y EDOM
	log2(0) SING \-HUGE n EDOM \" different from log()
	log2(x<0) DOMAIN \-HUGE n EDOM \" different from log()
	log10(0) SING \-HUGE y EDOM
	log10(x<0) DOMAIN \-HUGE y EDOM
	pow(0.0,0.0) DOMAIN 0.0 y EDOM
	pow(x,y) o/f OVERFLOW HUGE n ERANGE
	pow(x,y) u/f UNDERFLOW 0.0 n ERANGE
	pow(NaN,0.0) DOMAIN x n EDOM
	0**neg DOMAIN 0.0 y EDOM \" +0 and -0
	neg**non-int DOMAIN 0.0 y EDOM
	scalb() o/f OVERFLOW (x>0.0) ? n ERANGE
	\ \ HUGE_VAL :
	\ \ \-HUGE_VAL
	scalb() u/f UNDERFLOW copysign( n ERANGE
	\ \ \ \ 0.0,x)
	fmod(x,0) DOMAIN x y EDOM
	remainder(x,0) DOMAIN NAN y EDOM \" retval is 0.0/0.0
	.TE
	.SH ATTRIBUTES
	For an explanation of the terms used in this section, see
	.BR attributes (7).
	.ad l
	.nh
	.TS
	allbox;
	lbx lb lb
	l l l.
	Interface Attribute Value
	T{
	.BR matherr ()
	T} Thread safety MT-Safe
	.TE
	.hy
	.ad
	.sp 1
	.SH EXAMPLES
	The example program demonstrates the use of
	.BR matherr ()
	when calling
	.BR log (3).
	The program takes up to three command-line arguments.
	The first argument is the floating-point number to be given to
	.BR log (3).
	If the optional second argument is provided, then
	.B _LIB_VERSION
	is set to
	.B _SVID_
	so that
	.BR matherr ()
	is called, and the integer supplied in the
	command-line argument is used as the return value from
	.BR matherr ().
	If the optional third command-line argument is supplied,
	then it specifies an alternative return value that
	.BR matherr ()
	should assign as the return value of the math function.
	.PP
	The following example run, where
	.BR log (3)
	is given an argument of 0.0, does not use
	.BR matherr ():
	.PP
	.in +4n
	.EX
	.RB "$" " ./a.out 0.0"
	errno: Numerical result out of range
	x=\-inf
	.EE
	.in
	.PP
	In the following run,
	.BR matherr ()
	is called, and returns 0:
	.PP
	.in +4n
	.EX
	.RB "$" " ./a.out 0.0 0"
	matherr SING exception in log() function
	args: 0.000000, 0.000000
	retval: \-340282346638528859811704183484516925440.000000
	log: SING error
	errno: Numerical argument out of domain
	x=\-340282346638528859811704183484516925440.000000
	.EE
	.in
	.PP
	The message "log: SING error" was printed by the C library.
	.PP
	In the following run,
	.BR matherr ()
	is called, and returns a nonzero value:
	.PP
	.in +4n
	.EX
	.RB "$" " ./a.out 0.0 1"
	matherr SING exception in log() function
	args: 0.000000, 0.000000
	retval: \-340282346638528859811704183484516925440.000000
	x=\-340282346638528859811704183484516925440.000000
	.EE
	.in
	.PP
	In this case, the C library did not print a message, and
	.I errno
	was not set.
	.PP
	In the following run,
	.BR matherr ()
	is called, changes the return value of the math function,
	and returns a nonzero value:
	.PP
	.in +4n
	.EX
	.RB "$" " ./a.out 0.0 1 12345.0"
	matherr SING exception in log() function
	args: 0.000000, 0.000000
	retval: \-340282346638528859811704183484516925440.000000
	x=12345.000000
	.EE
	.in
	.SS Program source
	\&
	.EX
	#define _SVID_SOURCE
	#include <errno.h>
	#include <math.h>
	#include <stdio.h>
	#include <stdlib.h>

	static int matherr_ret = 0; /* Value that matherr()
	should return */
	static int change_retval = 0; /* Should matherr() change
	function\(aqs return value? */
	static double new_retval; /* New function return value */

	int
	matherr(struct exception *exc)
	{
	fprintf(stderr, "matherr %s exception in %s() function\en",
	(exc\->type == DOMAIN) ? "DOMAIN" :
	(exc\->type == OVERFLOW) ? "OVERFLOW" :
	(exc\->type == UNDERFLOW) ? "UNDERFLOW" :
	(exc\->type == SING) ? "SING" :
	(exc\->type == TLOSS) ? "TLOSS" :
	(exc\->type == PLOSS) ? "PLOSS" : "???",
	exc\->name);
	fprintf(stderr, " args: %f, %f\en",
	exc\->arg1, exc\->arg2);
	fprintf(stderr, " retval: %f\en", exc\->retval);

	if (change_retval)
	exc\->retval = new_retval;

	return matherr_ret;
	}

	int
	main(int argc, char *argv[])
	{
	double x;

	if (argc < 2) {
	fprintf(stderr, "Usage: %s <argval>"
	" [<matherr\-ret> [<new\-func\-retval>]]\en", argv[0]);
	exit(EXIT_FAILURE);
	}

	if (argc > 2) {
	_LIB_VERSION = _SVID_;
	matherr_ret = atoi(argv[2]);
	}

	if (argc > 3) {
	change_retval = 1;
	new_retval = atof(argv[3]);
	}

	x = log(atof(argv[1]));
	if (errno != 0)
	perror("errno");

	printf("x=%f\en", x);
	exit(EXIT_SUCCESS);
	}
	.EE
	.SH SEE ALSO
	.BR fenv (3),
	.BR math_error (7),
	.BR standards (7)