583 lines
22 KiB
Groff
583 lines
22 KiB
Groff
.\" $NetBSD: math.3,v 1.25 2011/09/22 18:14:09 njoly Exp $
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.\"
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.\" Copyright (c) 1985 Regents of the University of California.
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.\" All rights reserved.
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.\"
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.\" Redistribution and use in source and binary forms, with or without
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.\" modification, are permitted provided that the following conditions
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.\" are met:
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.\" 1. Redistributions of source code must retain the above copyright
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.\" notice, this list of conditions and the following disclaimer.
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.\" 2. Redistributions in binary form must reproduce the above copyright
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.\" notice, this list of conditions and the following disclaimer in the
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.\" documentation and/or other materials provided with the distribution.
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.\" 3. Neither the name of the University nor the names of its contributors
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.\" may be used to endorse or promote products derived from this software
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.\" without specific prior written permission.
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.\"
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.\" THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
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.\" ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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.\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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.\" ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
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.\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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.\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
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.\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
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.\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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.\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
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.\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
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.\" SUCH DAMAGE.
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.\"
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.\" from: @(#)math.3 6.10 (Berkeley) 5/6/91
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.\"
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.Dd February 23, 2007
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.Dt MATH 3
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.Os
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.Sh NAME
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.Nm math
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.Nd introduction to mathematical library functions
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.Sh LIBRARY
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.Lb libm
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.Sh SYNOPSIS
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.In math.h
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.Sh DESCRIPTION
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These functions constitute the C
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.Lb libm .
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Declarations for these functions may be obtained from the include file
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.In math.h .
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.\" The Fortran math library is described in ``man 3f intro''.
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.Ss List of Functions
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.Bl -column "copysignX" "gammaX3XX" "inverse trigonometric funcX"
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.It Sy Name Ta Sy Man page Ta Sy Description Ta Sy Error Bound Dv ( ULP Ns No s)
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.It acos Ta Xr acos 3 Ta inverse trigonometric function Ta 3
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.It acosh Ta Xr acosh 3 Ta inverse hyperbolic function Ta 3
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.It asin Ta Xr asin 3 Ta inverse trigonometric function Ta 3
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.It asinh Ta Xr asinh 3 Ta inverse hyperbolic function Ta 3
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.It atan Ta Xr atan 3 Ta inverse trigonometric function Ta 1
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.It atanh Ta Xr atanh 3 Ta inverse hyperbolic function Ta 3
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.It atan2 Ta Xr atan2 3 Ta inverse trigonometric function Ta 2
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.It cbrt Ta Xr sqrt 3 Ta cube root Ta 1
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.It ceil Ta Xr ceil 3 Ta integer no less than Ta 0
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.It copysign Ta Xr copysign 3 Ta copy sign bit Ta 0
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.It cos Ta Xr cos 3 Ta trigonometric function Ta 1
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.It cosh Ta Xr cosh 3 Ta hyperbolic function Ta 3
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.It erf Ta Xr erf 3 Ta error function Ta ???
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.It erfc Ta Xr erf 3 Ta complementary error function Ta ???
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.It exp Ta Xr exp 3 Ta exponential Ta 1
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.It expm1 Ta Xr exp 3 Ta exp(x)\-1 Ta 1
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.It fabs Ta Xr fabs 3 Ta absolute value Ta 0
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.It finite Ta Xr finite 3 Ta test for finity Ta 0
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.It floor Ta Xr floor 3 Ta integer no greater than Ta 0
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.It fmod Ta Xr fmod 3 Ta remainder Ta ???
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.It hypot Ta Xr hypot 3 Ta Euclidean distance Ta 1
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.It ilogb Ta Xr ilogb 3 Ta exponent extraction Ta 0
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.It isinf Ta Xr isinf 3 Ta test for infinity Ta 0
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.It isnan Ta Xr isnan 3 Ta test for not-a-number Ta 0
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.It j0 Ta Xr j0 3 Ta Bessel function Ta ???
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.It j1 Ta Xr j0 3 Ta Bessel function Ta ???
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.It jn Ta Xr j0 3 Ta Bessel function Ta ???
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.It lgamma Ta Xr lgamma 3 Ta log gamma function Ta ???
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.It log Ta Xr log 3 Ta natural logarithm Ta 1
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.It log10 Ta Xr log 3 Ta logarithm to base 10 Ta 3
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.It log1p Ta Xr log 3 Ta log(1+x) Ta 1
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.It nan Ta Xr nan 3 Ta return quiet \*(Na Ta 0
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.It nextafter Ta Xr nextafter 3 Ta next representable number Ta 0
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.It pow Ta Xr pow 3 Ta exponential x**y Ta 60\-500
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.It remainder Ta Xr remainder 3 Ta remainder Ta 0
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.It rint Ta Xr rint 3 Ta round to nearest integer Ta 0
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.It scalbn Ta Xr scalbn 3 Ta exponent adjustment Ta 0
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.It sin Ta Xr sin 3 Ta trigonometric function Ta 1
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.It sinh Ta Xr sinh 3 Ta hyperbolic function Ta 3
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.It sqrt Ta Xr sqrt 3 Ta square root Ta 1
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.It tan Ta Xr tan 3 Ta trigonometric function Ta 3
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.It tanh Ta Xr tanh 3 Ta hyperbolic function Ta 3
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.It trunc Ta Xr trunc 3 Ta nearest integral value Ta 3
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.It y0 Ta Xr j0 3 Ta Bessel function Ta ???
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.It y1 Ta Xr j0 3 Ta Bessel function Ta ???
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.It yn Ta Xr j0 3 Ta Bessel function Ta ???
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.El
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.Ss List of Defined Values
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.Bl -column "M_2_SQRTPIXX" "1.12837916709551257390XX" "2/sqrt(pi)XXX"
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.It Sy Name Ta Sy Value Ta Sy Description
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.It M_E 2.7182818284590452354 e
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.It M_LOG2E 1.4426950408889634074 log 2e
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.It M_LOG10E 0.43429448190325182765 log 10e
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.It M_LN2 0.69314718055994530942 log e2
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.It M_LN10 2.30258509299404568402 log e10
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.It M_PI 3.14159265358979323846 pi
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.It M_PI_2 1.57079632679489661923 pi/2
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.It M_PI_4 0.78539816339744830962 pi/4
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.It M_1_PI 0.31830988618379067154 1/pi
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.It M_2_PI 0.63661977236758134308 2/pi
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.It M_2_SQRTPI 1.12837916709551257390 2/sqrt(pi)
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.It M_SQRT2 1.41421356237309504880 sqrt(2)
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.It M_SQRT1_2 0.70710678118654752440 1/sqrt(2)
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.El
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.Sh NOTES
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In 4.3 BSD, distributed from the University of California
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in late 1985, most of the foregoing functions come in two
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versions, one for the double\-precision "D" format in the
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DEC VAX\-11 family of computers, another for double\-precision
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arithmetic conforming to the IEEE Standard 754 for Binary
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Floating\-Point Arithmetic.
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The two versions behave very
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similarly, as should be expected from programs more accurate
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and robust than was the norm when UNIX was born.
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For instance, the programs are accurate to within the numbers
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of
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.Dv ULPs
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tabulated above; an
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.Dv ULP
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is one Unit in the Last Place.
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And the programs have been cured of anomalies that
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afflicted the older math library
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in which incidents like
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the following had been reported:
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.Bd -literal -offset indent
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sqrt(\-1.0) = 0.0 and log(\-1.0) = \-1.7e38.
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cos(1.0e\-11) \*[Gt] cos(0.0) \*[Gt] 1.0.
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pow(x,1.0) \(!= x when x = 2.0, 3.0, 4.0, ..., 9.0.
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pow(\-1.0,1.0e10) trapped on Integer Overflow.
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sqrt(1.0e30) and sqrt(1.0e\-30) were very slow.
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.Ed
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However the two versions do differ in ways that have to be
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explained, to which end the following notes are provided.
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.Ss DEC VAX\-11 D_floating\-point
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This is the format for which the original math library
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was developed, and to which this manual is still principally dedicated.
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It is
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.Em the
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double\-precision format for the PDP\-11
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and the earlier VAX\-11 machines; VAX\-11s after 1983 were
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provided with an optional "G" format closer to the IEEE
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double\-precision format.
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The earlier DEC MicroVAXs have no D format, only G double\-precision.
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(Why?
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Why not?)
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.Pp
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Properties of D_floating\-point:
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.Bl -hang -offset indent
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.It Wordsize :
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64 bits, 8 bytes.
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.It Radix :
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Binary.
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.It Precision :
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56 significant bits, roughly like 17 significant decimals.
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If x and x' are consecutive positive D_floating\-point
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numbers (they differ by 1
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.Dv ULP ) ,
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then
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.Dl 1.3e\-17 \*[Lt] 0.5**56 \*[Lt] (x'\-x)/x \*[Le] 0.5**55 \*[Lt] 2.8e\-17.
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.It Range :
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.Bl -column "Underflow thresholdX" "2.0**127X"
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.It Overflow threshold = 2.0**127 = 1.7e38.
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.It Underflow threshold = 0.5**128 = 2.9e\-39.
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.El
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.Em NOTE: THIS RANGE IS COMPARATIVELY NARROW.
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.Pp
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Overflow customarily stops computation.
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Underflow is customarily flushed quietly to zero.
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.Em CAUTION :
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It is possible to have x
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\(!=
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y and yet x\-y = 0 because of underflow.
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Similarly x \*[Gt] y \*[Gt] 0 cannot prevent either x\(**y = 0
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or y/x = 0 from happening without warning.
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.It Zero is represented ambiguously :
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Although 2**55 different representations of zero are accepted by
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the hardware, only the obvious representation is ever produced.
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There is no \-0 on a VAX.
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.It \*(If is not part of the VAX architecture .
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.It Reserved operands :
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of the 2**55 that the hardware
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recognizes, only one of them is ever produced.
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Any floating\-point operation upon a reserved
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operand, even a MOVF or MOVD, customarily stops
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computation, so they are not much used.
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.It Exceptions :
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Divisions by zero and operations that
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overflow are invalid operations that customarily
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stop computation or, in earlier machines, produce
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reserved operands that will stop computation.
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.It Rounding :
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Every rational operation (+, \-, \(**, /) on a
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VAX (but not necessarily on a PDP\-11), if not an
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over/underflow nor division by zero, is rounded to
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within half an
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.Dv ULP ,
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and when the rounding error is
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exactly half an
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.Dv ULP
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then rounding is away from 0.
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.El
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.Pp
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Except for its narrow range, D_floating\-point is one of the
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better computer arithmetics designed in the 1960's.
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Its properties are reflected fairly faithfully in the elementary
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functions for a VAX distributed in 4.3 BSD.
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They over/underflow only if their results have to lie out of range
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or very nearly so, and then they behave much as any rational
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arithmetic operation that over/underflowed would behave.
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Similarly, expressions like log(0) and atanh(1) behave
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like 1/0; and sqrt(\-3) and acos(3) behave like 0/0;
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they all produce reserved operands and/or stop computation!
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The situation is described in more detail in manual pages.
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.Pp
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.Em This response seems excessively punitive, so it is destined
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.Em to be replaced at some time in the foreseeable future by a
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.Em more flexible but still uniform scheme being developed to
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.Em handle all floating\-point arithmetic exceptions neatly.
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.Pp
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How do the functions in 4.3 BSD's new math library for UNIX
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compare with their counterparts in DEC's VAX/VMS library?
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Some of the VMS functions are a little faster, some are
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a little more accurate, some are more puritanical about
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exceptions (like pow(0.0,0.0) and atan2(0.0,0.0)),
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and most occupy much more memory than their counterparts in
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libm.
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The VMS codes interpolate in large table to achieve
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speed and accuracy; the libm codes use tricky formulas
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compact enough that all of them may some day fit into a ROM.
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.Pp
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More important, DEC regards the VMS codes as proprietary
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and guards them zealously against unauthorized use.
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But the libm codes in 4.3 BSD are intended for the public domain;
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they may be copied freely provided their provenance is always
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acknowledged, and provided users assist the authors in their
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researches by reporting experience with the codes.
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Therefore no user of UNIX on a machine whose arithmetic resembles
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VAX D_floating\-point need use anything worse than the new libm.
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.Ss IEEE STANDARD 754 Floating\-Point Arithmetic
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This standard is on its way to becoming more widely adopted
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than any other design for computer arithmetic.
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VLSI chips that conform to some version of that standard have been
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produced by a host of manufacturers, among them ...
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.Bl -column "Intel i8070, i80287XX"
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.It Intel i8087, i80287 National Semiconductor 32081
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.It 68881 Weitek WTL-1032, ... , -1165
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.It Zilog Z8070 Western Electric (AT\*[Am]T) WE32106.
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.El
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Other implementations range from software, done thoroughly
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in the Apple Macintosh, through VLSI in the Hewlett\-Packard
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9000 series, to the ELXSI 6400 running ECL at 3 Megaflops.
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Several other companies have adopted the formats
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of IEEE 754 without, alas, adhering to the standard's way
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of handling rounding and exceptions like over/underflow.
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The DEC VAX G_floating\-point format is very similar to the IEEE
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754 Double format, so similar that the C programs for the
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IEEE versions of most of the elementary functions listed
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above could easily be converted to run on a MicroVAX, though
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nobody has volunteered to do that yet.
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.Pp
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The codes in 4.3 BSD's libm for machines that conform to
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IEEE 754 are intended primarily for the National Semiconductor 32081
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and WTL 1164/65.
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To use these codes with the Intel or Zilog
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chips, or with the Apple Macintosh or ELXSI 6400, is to
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forego the use of better codes provided (perhaps freely) by
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those companies and designed by some of the authors of the
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codes above.
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Except for
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.Fn atan ,
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.Fn cbrt ,
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.Fn erf ,
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.Fn erfc ,
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.Fn hypot ,
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.Fn j0-jn ,
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.Fn lgamma ,
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.Fn pow ,
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and
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.Fn y0\-yn ,
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the Motorola 68881 has all the functions in libm on chip,
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and faster and more accurate;
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it, Apple, the i8087, Z8070 and WE32106 all use 64 significant bits.
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The main virtue of 4.3 BSD's
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libm codes is that they are intended for the public domain;
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they may be copied freely provided their provenance is always
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acknowledged, and provided users assist the authors in their
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researches by reporting experience with the codes.
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Therefore no user of UNIX on a machine that conforms to
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IEEE 754 need use anything worse than the new libm.
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.Pp
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Properties of IEEE 754 Double\-Precision:
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.Bl -hang -offset indent
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.It Wordsize :
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64 bits, 8 bytes.
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.It Radix :
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Binary.
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.It Precision :
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53 significant bits, roughly like 16 significant decimals.
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If x and x' are consecutive positive Double\-Precision
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numbers (they differ by 1
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.Dv ULP ) ,
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then
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.Dl 1.1e\-16 \*[Lt] 0.5**53 \*[Lt] (x'\-x)/x \*[Le] 0.5**52 \*[Lt] 2.3e\-16.
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.It Range :
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.Bl -column "Underflow thresholdX" "2.0**1024X"
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.It Overflow threshold = 2.0**1024 = 1.8e308
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.It Underflow threshold = 0.5**1022 = 2.2e\-308
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.El
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Overflow goes by default to a signed \*(If.
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Underflow is
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.Sy Gradual ,
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rounding to the nearest
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integer multiple of 0.5**1074 = 4.9e\-324.
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.It Zero is represented ambiguously as +0 or \-0:
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Its sign transforms correctly through multiplication or
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|
division, and is preserved by addition of zeros
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with like signs; but x\-x yields +0 for every
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finite x.
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The only operations that reveal zero's
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sign are division by zero and copysign(x,\(+-0).
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|
In particular, comparison (x \*[Gt] y, x \*[Ge] y, etc.)
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cannot be affected by the sign of zero; but if
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finite x = y then \*(If
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\&= 1/(x\-y)
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\(!=
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\-1/(y\-x) =
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\- \*(If .
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.It \*(If is signed :
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it persists when added to itself
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or to any finite number.
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Its sign transforms
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correctly through multiplication and division, and
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\*(If (finite)/\(+- \0=\0\(+-0
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(nonzero)/0 =
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\(+- \*(If.
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|
But
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|
\(if\-\(if, \(if\(**0 and \(if/\(if
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|
are, like 0/0 and sqrt(\-3),
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|
invalid operations that produce \*(Na.
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.It Reserved operands :
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|
there are 2**53\-2 of them, all
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|
called \*(Na (Not A Number).
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|
Some, called Signaling \*[Na]s, trap any floating\-point operation
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performed upon them; they are used to mark missing
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or uninitialized values, or nonexistent elements of arrays.
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The rest are Quiet \*[Na]s; they are
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the default results of Invalid Operations, and
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|
propagate through subsequent arithmetic operations.
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If x
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\(!=
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x then x is \*(Na; every other predicate
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|
(x \*[Gt] y, x = y, x \*[Lt] y, ...) is FALSE if \*(Na is involved.
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.Pp
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.Em NOTE :
|
|
Trichotomy is violated by \*(Na.
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|
Besides being FALSE, predicates that entail ordered
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comparison, rather than mere (in)equality,
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|
signal Invalid Operation when \*(Na is involved.
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.It Rounding :
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|
Every algebraic operation (+, \-, \(**, /,
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\(sr)
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|
is rounded by default to within half an
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.Dv ULP ,
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|
and when the rounding error is exactly half an
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|
.Dv ULP
|
|
then the rounded value's least significant bit is zero.
|
|
This kind of rounding is usually the best kind,
|
|
sometimes provably so; for instance, for every
|
|
x = 1.0, 2.0, 3.0, 4.0, ..., 2.0**52, we find
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|
(x/3.0)\(**3.0 == x and (x/10.0)\(**10.0 == x and ...
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|
despite that both the quotients and the products
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|
have been rounded.
|
|
Only rounding like IEEE 754 can do that.
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|
But no single kind of rounding can be
|
|
proved best for every circumstance, so IEEE 754
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|
provides rounding towards zero or towards
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|
+\*(If
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|
or towards
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|
\-\*(If
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|
at the programmer's option.
|
|
And the same kinds of rounding are specified for
|
|
Binary\-Decimal Conversions, at least for magnitudes
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|
between roughly 1.0e\-10 and 1.0e37.
|
|
.It Exceptions :
|
|
IEEE 754 recognizes five kinds of floating\-point exceptions,
|
|
listed below in declining order of probable importance.
|
|
.Bl -column "Invalid OperationX" "Gradual OverflowX"
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|
.It Sy Exception Ta Sy Default Result
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|
.It Invalid Operation \*(Na, or FALSE
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|
.It Overflow \(+-\(if
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|
.It Divide by Zero \(+-\(if \}
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|
.It Underflow Gradual Underflow
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|
.It Inexact Rounded value
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|
.El
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|
.Pp
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|
.Em NOTE :
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|
An Exception is not an Error unless handled badly.
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|
What makes a class of exceptions exceptional
|
|
is that no single default response can be satisfactory
|
|
in every instance.
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|
On the other hand, if a default
|
|
response will serve most instances satisfactorily,
|
|
the unsatisfactory instances cannot justify aborting
|
|
computation every time the exception occurs.
|
|
.El
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|
.Pp
|
|
For each kind of floating\-point exception, IEEE 754
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|
provides a Flag that is raised each time its exception
|
|
is signaled, and stays raised until the program resets it.
|
|
Programs may also test, save and restore a flag.
|
|
Thus, IEEE 754 provides three ways by which programs
|
|
may cope with exceptions for which the default result
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|
might be unsatisfactory:
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|
.Bl -enum
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|
.It
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|
Test for a condition that might cause an exception
|
|
later, and branch to avoid the exception.
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|
.It
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|
Test a flag to see whether an exception has occurred
|
|
since the program last reset its flag.
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|
.It
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|
Test a result to see whether it is a value that only
|
|
an exception could have produced.
|
|
.Em CAUTION :
|
|
The only reliable ways to discover
|
|
whether Underflow has occurred are to test whether
|
|
products or quotients lie closer to zero than the
|
|
underflow threshold, or to test the Underflow flag.
|
|
(Sums and differences cannot underflow in
|
|
IEEE 754; if x
|
|
\(!=
|
|
y then x\-y is correct to
|
|
full precision and certainly nonzero regardless of
|
|
how tiny it may be.)
|
|
Products and quotients that
|
|
underflow gradually can lose accuracy gradually
|
|
without vanishing, so comparing them with zero
|
|
(as one might on a VAX) will not reveal the loss.
|
|
Fortunately, if a gradually underflowed value is
|
|
destined to be added to something bigger than the
|
|
underflow threshold, as is almost always the case,
|
|
digits lost to gradual underflow will not be missed
|
|
because they would have been rounded off anyway.
|
|
So gradual underflows are usually
|
|
.Em provably
|
|
ignorable.
|
|
The same cannot be said of underflows flushed to 0.
|
|
.Pp
|
|
At the option of an implementor conforming to IEEE 754,
|
|
other ways to cope with exceptions may be provided:
|
|
.It
|
|
ABORT.
|
|
This mechanism classifies an exception in
|
|
advance as an incident to be handled by means
|
|
traditionally associated with error\-handling
|
|
statements like "ON ERROR GO TO ...".
|
|
Different languages offer different forms of this statement,
|
|
but most share the following characteristics:
|
|
.Bl -dash
|
|
.It
|
|
No means is provided to substitute a value for
|
|
the offending operation's result and resume
|
|
computation from what may be the middle of an expression.
|
|
An exceptional result is abandoned.
|
|
.It
|
|
In a subprogram that lacks an error\-handling
|
|
statement, an exception causes the subprogram to
|
|
abort within whatever program called it, and so
|
|
on back up the chain of calling subprograms until
|
|
an error\-handling statement is encountered or the
|
|
whole task is aborted and memory is dumped.
|
|
.El
|
|
.It
|
|
STOP.
|
|
This mechanism, requiring an interactive
|
|
debugging environment, is more for the programmer
|
|
than the program.
|
|
It classifies an exception in
|
|
advance as a symptom of a programmer's error; the
|
|
exception suspends execution as near as it can to
|
|
the offending operation so that the programmer can
|
|
look around to see how it happened.
|
|
Quite often
|
|
the first several exceptions turn out to be quite
|
|
unexceptionable, so the programmer ought ideally
|
|
to be able to resume execution after each one as if
|
|
execution had not been stopped.
|
|
.It
|
|
\&... Other ways lie beyond the scope of this document.
|
|
.El
|
|
.Pp
|
|
The crucial problem for exception handling is the problem of
|
|
Scope, and the problem's solution is understood, but not
|
|
enough manpower was available to implement it fully in time
|
|
to be distributed in 4.3 BSD's libm.
|
|
Ideally, each elementary function should act
|
|
as if it were indivisible, or atomic, in the sense that ...
|
|
.Bl -enum
|
|
.It
|
|
No exception should be signaled that is not deserved by
|
|
the data supplied to that function.
|
|
.It
|
|
Any exception signaled should be identified with that
|
|
function rather than with one of its subroutines.
|
|
.It
|
|
The internal behavior of an atomic function should not
|
|
be disrupted when a calling program changes from
|
|
one to another of the five or so ways of handling
|
|
exceptions listed above, although the definition
|
|
of the function may be correlated intentionally
|
|
with exception handling.
|
|
.El
|
|
.Pp
|
|
Ideally, every programmer should be able
|
|
.Em conveniently
|
|
to turn a debugged subprogram into one that appears atomic to
|
|
its users.
|
|
But simulating all three characteristics of an
|
|
atomic function is still a tedious affair, entailing hosts
|
|
of tests and saves\-restores; work is under way to ameliorate
|
|
the inconvenience.
|
|
.Pp
|
|
Meanwhile, the functions in libm are only approximately atomic.
|
|
They signal no inappropriate exception except possibly ...
|
|
.Bl -ohang -offset indent
|
|
.It Over/Underflow
|
|
when a result, if properly computed, might have lain barely within range, and
|
|
.It Inexact in Fn cbrt , Fn hypot , Fn log10 and Fn pow
|
|
when it happens to be exact, thanks to fortuitous cancellation of errors.
|
|
.El
|
|
Otherwise, ...
|
|
.Bl -ohang -offset indent
|
|
.It Invalid Operation is signaled only when
|
|
any result but \*(Na would probably be misleading.
|
|
.It Overflow is signaled only when
|
|
the exact result would be finite but beyond the overflow threshold.
|
|
.It Divide\-by\-Zero is signaled only when
|
|
a function takes exactly infinite values at finite operands.
|
|
.It Underflow is signaled only when
|
|
the exact result would be nonzero but tinier than the underflow threshold.
|
|
.It Inexact is signaled only when
|
|
greater range or precision would be needed to represent the exact result.
|
|
.El
|
|
.\" .Sh FILES
|
|
.\" .Bl -tag -width /usr/lib/libm_p.a -compact
|
|
.\" .It Pa /usr/lib/libm.a
|
|
.\" the static math library
|
|
.\" .It Pa /usr/lib/libm.so
|
|
.\" the dynamic math library
|
|
.\" .It Pa /usr/lib/libm_p.a
|
|
.\" the static math library compiled for profiling
|
|
.\" .El
|
|
.Sh SEE ALSO
|
|
An explanation of IEEE 754 and its proposed extension p854
|
|
was published in the IEEE magazine MICRO in August 1984 under
|
|
the title "A Proposed Radix\- and Word\-length\-independent
|
|
Standard for Floating\-point Arithmetic" by W. J. Cody et al.
|
|
The manuals for Pascal, C and BASIC on the Apple Macintosh
|
|
document the features of IEEE 754 pretty well.
|
|
Articles in the IEEE magazine COMPUTER vol. 14 no. 3 (Mar. 1981),
|
|
and in the ACM SIGNUM Newsletter Special Issue of
|
|
Oct. 1979, may be helpful although they pertain to
|
|
superseded drafts of the standard.
|
|
.Sh BUGS
|
|
When signals are appropriate, they are emitted by certain
|
|
operations within the codes, so a subroutine\-trace may be
|
|
needed to identify the function with its signal in case
|
|
method 5) above is in use.
|
|
And the codes all take the
|
|
IEEE 754 defaults for granted; this means that a decision to
|
|
trap all divisions by zero could disrupt a code that would
|
|
otherwise get correct results despite division by zero.
|