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1998-09-01 10:34 Ulrich Drepper <drepper@cygnus.com> * manual/locale.texi: Almost compelte rewrite. Document more functions and functionality. * manual/arith.texi: Correct reference. * manual/string.texi: Pretty printing. * manual/texinfo.tex: Update from last available version. 1998-08-31 22:44 Ulrich Drepper <drepper@cygnus.com> * nis/nss_nis/nis-pwd.c (_nss_nis_getpwnam_r): Correct test for invalid password. (_nss_nis_getpwuid_r): Likewise. Patch by Matthew Arnison <matthewa@physics.usyd.edu.au>. * inet/rcmd.c: Implement netgroup support. Patch by Dick Streefland <dick_streefland@tasking.com>.
2112 lines
79 KiB
Plaintext
2112 lines
79 KiB
Plaintext
@node Arithmetic, Date and Time, Mathematics, Top
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@c %MENU% Low level arithmetic functions
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@chapter Arithmetic Functions
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This chapter contains information about functions for doing basic
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arithmetic operations, such as splitting a float into its integer and
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fractional parts or retrieving the imaginary part of a complex value.
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These functions are declared in the header files @file{math.h} and
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@file{complex.h}.
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@menu
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* Floating Point Numbers:: Basic concepts. IEEE 754.
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* Floating Point Classes:: The five kinds of floating-point number.
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* Floating Point Errors:: When something goes wrong in a calculation.
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* Rounding:: Controlling how results are rounded.
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* Control Functions:: Saving and restoring the FPU's state.
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* Arithmetic Functions:: Fundamental operations provided by the library.
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* Complex Numbers:: The types. Writing complex constants.
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* Operations on Complex:: Projection, conjugation, decomposition.
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* Integer Division:: Integer division with guaranteed rounding.
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* Parsing of Numbers:: Converting strings to numbers.
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* System V Number Conversion:: An archaic way to convert numbers to strings.
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@end menu
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@node Floating Point Numbers
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@section Floating Point Numbers
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@cindex floating point
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@cindex IEEE 754
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@cindex IEEE floating point
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Most computer hardware has support for two different kinds of numbers:
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integers (@math{@dots{}-3, -2, -1, 0, 1, 2, 3@dots{}}) and
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floating-point numbers. Floating-point numbers have three parts: the
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@dfn{mantissa}, the @dfn{exponent}, and the @dfn{sign bit}. The real
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number represented by a floating-point value is given by
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@tex
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$(s \mathrel? -1 \mathrel: 1) \cdot 2^e \cdot M$
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@end tex
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@ifnottex
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@math{(s ? -1 : 1) @mul{} 2^e @mul{} M}
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@end ifnottex
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where @math{s} is the sign bit, @math{e} the exponent, and @math{M}
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the mantissa. @xref{Floating Point Concepts}, for details. (It is
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possible to have a different @dfn{base} for the exponent, but all modern
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hardware uses @math{2}.)
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Floating-point numbers can represent a finite subset of the real
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numbers. While this subset is large enough for most purposes, it is
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important to remember that the only reals that can be represented
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exactly are rational numbers that have a terminating binary expansion
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shorter than the width of the mantissa. Even simple fractions such as
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@math{1/5} can only be approximated by floating point.
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Mathematical operations and functions frequently need to produce values
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that are not representable. Often these values can be approximated
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closely enough for practical purposes, but sometimes they can't.
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Historically there was no way to tell when the results of a calculation
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were inaccurate. Modern computers implement the @w{IEEE 754} standard
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for numerical computations, which defines a framework for indicating to
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the program when the results of calculation are not trustworthy. This
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framework consists of a set of @dfn{exceptions} that indicate why a
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result could not be represented, and the special values @dfn{infinity}
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and @dfn{not a number} (NaN).
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@node Floating Point Classes
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@section Floating-Point Number Classification Functions
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@cindex floating-point classes
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@cindex classes, floating-point
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@pindex math.h
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@w{ISO C 9x} defines macros that let you determine what sort of
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floating-point number a variable holds.
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@comment math.h
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@comment ISO
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@deftypefn {Macro} int fpclassify (@emph{float-type} @var{x})
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This is a generic macro which works on all floating-point types and
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which returns a value of type @code{int}. The possible values are:
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@vtable @code
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@item FP_NAN
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The floating-point number @var{x} is ``Not a Number'' (@pxref{Infinity
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and NaN})
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@item FP_INFINITE
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The value of @var{x} is either plus or minus infinity (@pxref{Infinity
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and NaN})
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@item FP_ZERO
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The value of @var{x} is zero. In floating-point formats like @w{IEEE
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754}, where zero can be signed, this value is also returned if
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@var{x} is negative zero.
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@item FP_SUBNORMAL
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Numbers whose absolute value is too small to be represented in the
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normal format are represented in an alternate, @dfn{denormalized} format
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(@pxref{Floating Point Concepts}). This format is less precise but can
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represent values closer to zero. @code{fpclassify} returns this value
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for values of @var{x} in this alternate format.
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@item FP_NORMAL
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This value is returned for all other values of @var{x}. It indicates
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that there is nothing special about the number.
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@end vtable
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@end deftypefn
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@code{fpclassify} is most useful if more than one property of a number
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must be tested. There are more specific macros which only test one
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property at a time. Generally these macros execute faster than
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@code{fpclassify}, since there is special hardware support for them.
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You should therefore use the specific macros whenever possible.
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@comment math.h
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@comment ISO
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@deftypefn {Macro} int isfinite (@emph{float-type} @var{x})
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This macro returns a nonzero value if @var{x} is finite: not plus or
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minus infinity, and not NaN. It is equivalent to
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@smallexample
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(fpclassify (x) != FP_NAN && fpclassify (x) != FP_INFINITE)
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@end smallexample
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@code{isfinite} is implemented as a macro which accepts any
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floating-point type.
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@end deftypefn
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@comment math.h
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@comment ISO
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@deftypefn {Macro} int isnormal (@emph{float-type} @var{x})
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This macro returns a nonzero value if @var{x} is finite and normalized.
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It is equivalent to
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@smallexample
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(fpclassify (x) == FP_NORMAL)
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@end smallexample
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@end deftypefn
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@comment math.h
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@comment ISO
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@deftypefn {Macro} int isnan (@emph{float-type} @var{x})
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This macro returns a nonzero value if @var{x} is NaN. It is equivalent
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to
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@smallexample
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(fpclassify (x) == FP_NAN)
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@end smallexample
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@end deftypefn
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Another set of floating-point classification functions was provided by
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BSD. The GNU C library also supports these functions; however, we
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recommend that you use the C9x macros in new code. Those are standard
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and will be available more widely. Also, since they are macros, you do
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not have to worry about the type of their argument.
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@comment math.h
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@comment BSD
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@deftypefun int isinf (double @var{x})
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@deftypefunx int isinff (float @var{x})
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@deftypefunx int isinfl (long double @var{x})
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This function returns @code{-1} if @var{x} represents negative infinity,
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@code{1} if @var{x} represents positive infinity, and @code{0} otherwise.
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@end deftypefun
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@comment math.h
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@comment BSD
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@deftypefun int isnan (double @var{x})
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@deftypefunx int isnanf (float @var{x})
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@deftypefunx int isnanl (long double @var{x})
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This function returns a nonzero value if @var{x} is a ``not a number''
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value, and zero otherwise.
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@strong{Note:} The @code{isnan} macro defined by @w{ISO C 9x} overrides
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the BSD function. This is normally not a problem, because the two
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routines behave identically. However, if you really need to get the BSD
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function for some reason, you can write
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@smallexample
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(isnan) (x)
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@end smallexample
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@end deftypefun
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@comment math.h
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@comment BSD
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@deftypefun int finite (double @var{x})
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@deftypefunx int finitef (float @var{x})
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@deftypefunx int finitel (long double @var{x})
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This function returns a nonzero value if @var{x} is finite or a ``not a
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number'' value, and zero otherwise.
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@end deftypefun
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@comment math.h
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@comment BSD
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@deftypefun double infnan (int @var{error})
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This function is provided for compatibility with BSD. Its argument is
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an error code, @code{EDOM} or @code{ERANGE}; @code{infnan} returns the
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value that a math function would return if it set @code{errno} to that
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value. @xref{Math Error Reporting}. @code{-ERANGE} is also acceptable
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as an argument, and corresponds to @code{-HUGE_VAL} as a value.
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In the BSD library, on certain machines, @code{infnan} raises a fatal
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signal in all cases. The GNU library does not do likewise, because that
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does not fit the @w{ISO C} specification.
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@end deftypefun
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@strong{Portability Note:} The functions listed in this section are BSD
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extensions.
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@node Floating Point Errors
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@section Errors in Floating-Point Calculations
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@menu
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* FP Exceptions:: IEEE 754 math exceptions and how to detect them.
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* Infinity and NaN:: Special values returned by calculations.
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* Status bit operations:: Checking for exceptions after the fact.
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* Math Error Reporting:: How the math functions report errors.
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@end menu
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@node FP Exceptions
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@subsection FP Exceptions
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@cindex exception
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@cindex signal
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@cindex zero divide
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@cindex division by zero
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@cindex inexact exception
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@cindex invalid exception
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@cindex overflow exception
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@cindex underflow exception
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The @w{IEEE 754} standard defines five @dfn{exceptions} that can occur
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during a calculation. Each corresponds to a particular sort of error,
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such as overflow.
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When exceptions occur (when exceptions are @dfn{raised}, in the language
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of the standard), one of two things can happen. By default the
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exception is simply noted in the floating-point @dfn{status word}, and
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the program continues as if nothing had happened. The operation
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produces a default value, which depends on the exception (see the table
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below). Your program can check the status word to find out which
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exceptions happened.
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Alternatively, you can enable @dfn{traps} for exceptions. In that case,
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when an exception is raised, your program will receive the @code{SIGFPE}
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signal. The default action for this signal is to terminate the
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program. @xref{Signal Handling} for how you can change the effect of
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the signal.
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@findex matherr
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In the System V math library, the user-defined function @code{matherr}
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is called when certain exceptions occur inside math library functions.
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However, the Unix98 standard deprecates this interface. We support it
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for historical compatibility, but recommend that you do not use it in
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new programs.
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@noindent
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The exceptions defined in @w{IEEE 754} are:
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@table @samp
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@item Invalid Operation
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This exception is raised if the given operands are invalid for the
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operation to be performed. Examples are
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(see @w{IEEE 754}, @w{section 7}):
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@enumerate
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@item
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Addition or subtraction: @math{@infinity{} - @infinity{}}. (But
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@math{@infinity{} + @infinity{} = @infinity{}}).
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@item
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Multiplication: @math{0 @mul{} @infinity{}}.
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@item
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Division: @math{0/0} or @math{@infinity{}/@infinity{}}.
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@item
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Remainder: @math{x} REM @math{y}, where @math{y} is zero or @math{x} is
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infinite.
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@item
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Square root if the operand is less then zero. More generally, any
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mathematical function evaluated outside its domain produces this
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exception.
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@item
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Conversion of a floating-point number to an integer or decimal
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string, when the number cannot be represented in the target format (due
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to overflow, infinity, or NaN).
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@item
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Conversion of an unrecognizable input string.
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@item
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Comparison via predicates involving @math{<} or @math{>}, when one or
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other of the operands is NaN. You can prevent this exception by using
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the unordered comparison functions instead; see @ref{FP Comparison Functions}.
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@end enumerate
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If the exception does not trap, the result of the operation is NaN.
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@item Division by Zero
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This exception is raised when a finite nonzero number is divided
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by zero. If no trap occurs the result is either @math{+@infinity{}} or
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@math{-@infinity{}}, depending on the signs of the operands.
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@item Overflow
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This exception is raised whenever the result cannot be represented
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as a finite value in the precision format of the destination. If no trap
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occurs the result depends on the sign of the intermediate result and the
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current rounding mode (@w{IEEE 754}, @w{section 7.3}):
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@enumerate
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@item
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Round to nearest carries all overflows to @math{@infinity{}}
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with the sign of the intermediate result.
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@item
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Round toward @math{0} carries all overflows to the largest representable
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finite number with the sign of the intermediate result.
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@item
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Round toward @math{-@infinity{}} carries positive overflows to the
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largest representable finite number and negative overflows to
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@math{-@infinity{}}.
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@item
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Round toward @math{@infinity{}} carries negative overflows to the
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most negative representable finite number and positive overflows
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to @math{@infinity{}}.
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@end enumerate
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Whenever the overflow exception is raised, the inexact exception is also
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raised.
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@item Underflow
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The underflow exception is raised when an intermediate result is too
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small to be calculated accurately, or if the operation's result rounded
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to the destination precision is too small to be normalized.
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When no trap is installed for the underflow exception, underflow is
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signaled (via the underflow flag) only when both tininess and loss of
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accuracy have been detected. If no trap handler is installed the
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operation continues with an imprecise small value, or zero if the
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destination precision cannot hold the small exact result.
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@item Inexact
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This exception is signalled if a rounded result is not exact (such as
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when calculating the square root of two) or a result overflows without
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an overflow trap.
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@end table
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@node Infinity and NaN
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@subsection Infinity and NaN
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@cindex infinity
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@cindex not a number
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@cindex NaN
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@w{IEEE 754} floating point numbers can represent positive or negative
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infinity, and @dfn{NaN} (not a number). These three values arise from
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calculations whose result is undefined or cannot be represented
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accurately. You can also deliberately set a floating-point variable to
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any of them, which is sometimes useful. Some examples of calculations
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that produce infinity or NaN:
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@ifnottex
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@smallexample
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@math{1/0 = @infinity{}}
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@math{log (0) = -@infinity{}}
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@math{sqrt (-1) = NaN}
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@end smallexample
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@end ifnottex
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@tex
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$${1\over0} = \infty$$
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$$\log 0 = -\infty$$
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$$\sqrt{-1} = \hbox{NaN}$$
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@end tex
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When a calculation produces any of these values, an exception also
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occurs; see @ref{FP Exceptions}.
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The basic operations and math functions all accept infinity and NaN and
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produce sensible output. Infinities propagate through calculations as
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one would expect: for example, @math{2 + @infinity{} = @infinity{}},
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@math{4/@infinity{} = 0}, atan @math{(@infinity{}) = @pi{}/2}. NaN, on
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the other hand, infects any calculation that involves it. Unless the
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calculation would produce the same result no matter what real value
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replaced NaN, the result is NaN.
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In comparison operations, positive infinity is larger than all values
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except itself and NaN, and negative infinity is smaller than all values
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except itself and NaN. NaN is @dfn{unordered}: it is not equal to,
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greater than, or less than anything, @emph{including itself}. @code{x ==
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x} is false if the value of @code{x} is NaN. You can use this to test
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whether a value is NaN or not, but the recommended way to test for NaN
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is with the @code{isnan} function (@pxref{Floating Point Classes}). In
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addition, @code{<}, @code{>}, @code{<=}, and @code{>=} will raise an
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exception when applied to NaNs.
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@file{math.h} defines macros that allow you to explicitly set a variable
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to infinity or NaN.
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@comment math.h
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@comment ISO
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@deftypevr Macro float INFINITY
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An expression representing positive infinity. It is equal to the value
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produced by mathematical operations like @code{1.0 / 0.0}.
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@code{-INFINITY} represents negative infinity.
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You can test whether a floating-point value is infinite by comparing it
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to this macro. However, this is not recommended; you should use the
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@code{isfinite} macro instead. @xref{Floating Point Classes}.
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This macro was introduced in the @w{ISO C 9X} standard.
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@end deftypevr
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@comment math.h
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@comment GNU
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@deftypevr Macro float NAN
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An expression representing a value which is ``not a number''. This
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macro is a GNU extension, available only on machines that support the
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``not a number'' value---that is to say, on all machines that support
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IEEE floating point.
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You can use @samp{#ifdef NAN} to test whether the machine supports
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NaN. (Of course, you must arrange for GNU extensions to be visible,
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such as by defining @code{_GNU_SOURCE}, and then you must include
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@file{math.h}.)
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@end deftypevr
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@w{IEEE 754} also allows for another unusual value: negative zero. This
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value is produced when you divide a positive number by negative
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infinity, or when a negative result is smaller than the limits of
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representation. Negative zero behaves identically to zero in all
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calculations, unless you explicitly test the sign bit with
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@code{signbit} or @code{copysign}.
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|
|
@node Status bit operations
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@subsection Examining the FPU status word
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|
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|
@w{ISO C 9x} defines functions to query and manipulate the
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floating-point status word. You can use these functions to check for
|
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untrapped exceptions when it's convenient, rather than worrying about
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them in the middle of a calculation.
|
|
|
|
These constants represent the various @w{IEEE 754} exceptions. Not all
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FPUs report all the different exceptions. Each constant is defined if
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and only if the FPU you are compiling for supports that exception, so
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you can test for FPU support with @samp{#ifdef}. They are defined in
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@file{fenv.h}.
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@vtable @code
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@comment fenv.h
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@comment ISO
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@item FE_INEXACT
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The inexact exception.
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@comment fenv.h
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@comment ISO
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@item FE_DIVBYZERO
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The divide by zero exception.
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@comment fenv.h
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@comment ISO
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@item FE_UNDERFLOW
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The underflow exception.
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@comment fenv.h
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@comment ISO
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@item FE_OVERFLOW
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The overflow exception.
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@comment fenv.h
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@comment ISO
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@item FE_INVALID
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The invalid exception.
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@end vtable
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The macro @code{FE_ALL_EXCEPT} is the bitwise OR of all exception macros
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which are supported by the FP implementation.
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These functions allow you to clear exception flags, test for exceptions,
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and save and restore the set of exceptions flagged.
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@comment fenv.h
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@comment ISO
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@deftypefun void feclearexcept (int @var{excepts})
|
|
This function clears all of the supported exception flags indicated by
|
|
@var{excepts}.
|
|
@end deftypefun
|
|
|
|
@comment fenv.h
|
|
@comment ISO
|
|
@deftypefun int fetestexcept (int @var{excepts})
|
|
Test whether the exception flags indicated by the parameter @var{except}
|
|
are currently set. If any of them are, a nonzero value is returned
|
|
which specifies which exceptions are set. Otherwise the result is zero.
|
|
@end deftypefun
|
|
|
|
To understand these functions, imagine that the status word is an
|
|
integer variable named @var{status}. @code{feclearexcept} is then
|
|
equivalent to @samp{status &= ~excepts} and @code{fetestexcept} is
|
|
equivalent to @samp{(status & excepts)}. The actual implementation may
|
|
be very different, of course.
|
|
|
|
Exception flags are only cleared when the program explicitly requests it,
|
|
by calling @code{feclearexcept}. If you want to check for exceptions
|
|
from a set of calculations, you should clear all the flags first. Here
|
|
is a simple example of the way to use @code{fetestexcept}:
|
|
|
|
@smallexample
|
|
@{
|
|
double f;
|
|
int raised;
|
|
feclearexcept (FE_ALL_EXCEPT);
|
|
f = compute ();
|
|
raised = fetestexcept (FE_OVERFLOW | FE_INVALID);
|
|
if (raised & FE_OVERFLOW) @{ /* ... */ @}
|
|
if (raised & FE_INVALID) @{ /* ... */ @}
|
|
/* ... */
|
|
@}
|
|
@end smallexample
|
|
|
|
You cannot explicitly set bits in the status word. You can, however,
|
|
save the entire status word and restore it later. This is done with the
|
|
following functions:
|
|
|
|
@comment fenv.h
|
|
@comment ISO
|
|
@deftypefun void fegetexceptflag (fexcept_t *@var{flagp}, int @var{excepts})
|
|
This function stores in the variable pointed to by @var{flagp} an
|
|
implementation-defined value representing the current setting of the
|
|
exception flags indicated by @var{excepts}.
|
|
@end deftypefun
|
|
|
|
@comment fenv.h
|
|
@comment ISO
|
|
@deftypefun void fesetexceptflag (const fexcept_t *@var{flagp}, int
|
|
@var{excepts})
|
|
This function restores the flags for the exceptions indicated by
|
|
@var{excepts} to the values stored in the variable pointed to by
|
|
@var{flagp}.
|
|
@end deftypefun
|
|
|
|
Note that the value stored in @code{fexcept_t} bears no resemblance to
|
|
the bit mask returned by @code{fetestexcept}. The type may not even be
|
|
an integer. Do not attempt to modify an @code{fexcept_t} variable.
|
|
|
|
@node Math Error Reporting
|
|
@subsection Error Reporting by Mathematical Functions
|
|
@cindex errors, mathematical
|
|
@cindex domain error
|
|
@cindex range error
|
|
|
|
Many of the math functions are defined only over a subset of the real or
|
|
complex numbers. Even if they are mathematically defined, their result
|
|
may be larger or smaller than the range representable by their return
|
|
type. These are known as @dfn{domain errors}, @dfn{overflows}, and
|
|
@dfn{underflows}, respectively. Math functions do several things when
|
|
one of these errors occurs. In this manual we will refer to the
|
|
complete response as @dfn{signalling} a domain error, overflow, or
|
|
underflow.
|
|
|
|
When a math function suffers a domain error, it raises the invalid
|
|
exception and returns NaN. It also sets @var{errno} to @code{EDOM};
|
|
this is for compatibility with old systems that do not support @w{IEEE
|
|
754} exception handling. Likewise, when overflow occurs, math
|
|
functions raise the overflow exception and return @math{@infinity{}} or
|
|
@math{-@infinity{}} as appropriate. They also set @var{errno} to
|
|
@code{ERANGE}. When underflow occurs, the underflow exception is
|
|
raised, and zero (appropriately signed) is returned. @var{errno} may be
|
|
set to @code{ERANGE}, but this is not guaranteed.
|
|
|
|
Some of the math functions are defined mathematically to result in a
|
|
complex value over parts of their domains. The most familiar example of
|
|
this is taking the square root of a negative number. The complex math
|
|
functions, such as @code{csqrt}, will return the appropriate complex value
|
|
in this case. The real-valued functions, such as @code{sqrt}, will
|
|
signal a domain error.
|
|
|
|
Some older hardware does not support infinities. On that hardware,
|
|
overflows instead return a particular very large number (usually the
|
|
largest representable number). @file{math.h} defines macros you can use
|
|
to test for overflow on both old and new hardware.
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypevr Macro double HUGE_VAL
|
|
@deftypevrx Macro float HUGE_VALF
|
|
@deftypevrx Macro {long double} HUGE_VALL
|
|
An expression representing a particular very large number. On machines
|
|
that use @w{IEEE 754} floating point format, @code{HUGE_VAL} is infinity.
|
|
On other machines, it's typically the largest positive number that can
|
|
be represented.
|
|
|
|
Mathematical functions return the appropriately typed version of
|
|
@code{HUGE_VAL} or @code{@minus{}HUGE_VAL} when the result is too large
|
|
to be represented.
|
|
@end deftypevr
|
|
|
|
@node Rounding
|
|
@section Rounding Modes
|
|
|
|
Floating-point calculations are carried out internally with extra
|
|
precision, and then rounded to fit into the destination type. This
|
|
ensures that results are as precise as the input data. @w{IEEE 754}
|
|
defines four possible rounding modes:
|
|
|
|
@table @asis
|
|
@item Round to nearest.
|
|
This is the default mode. It should be used unless there is a specific
|
|
need for one of the others. In this mode results are rounded to the
|
|
nearest representable value. If the result is midway between two
|
|
representable values, the even representable is chosen. @dfn{Even} here
|
|
means the lowest-order bit is zero. This rounding mode prevents
|
|
statistical bias and guarantees numeric stability: round-off errors in a
|
|
lengthy calculation will remain smaller than half of @code{FLT_EPSILON}.
|
|
|
|
@c @item Round toward @math{+@infinity{}}
|
|
@item Round toward plus Infinity.
|
|
All results are rounded to the smallest representable value
|
|
which is greater than the result.
|
|
|
|
@c @item Round toward @math{-@infinity{}}
|
|
@item Round toward minus Infinity.
|
|
All results are rounded to the largest representable value which is less
|
|
than the result.
|
|
|
|
@item Round toward zero.
|
|
All results are rounded to the largest representable value whose
|
|
magnitude is less than that of the result. In other words, if the
|
|
result is negative it is rounded up; if it is positive, it is rounded
|
|
down.
|
|
@end table
|
|
|
|
@noindent
|
|
@file{fenv.h} defines constants which you can use to refer to the
|
|
various rounding modes. Each one will be defined if and only if the FPU
|
|
supports the corresponding rounding mode.
|
|
|
|
@table @code
|
|
@comment fenv.h
|
|
@comment ISO
|
|
@vindex FE_TONEAREST
|
|
@item FE_TONEAREST
|
|
Round to nearest.
|
|
|
|
@comment fenv.h
|
|
@comment ISO
|
|
@vindex FE_UPWARD
|
|
@item FE_UPWARD
|
|
Round toward @math{+@infinity{}}.
|
|
|
|
@comment fenv.h
|
|
@comment ISO
|
|
@vindex FE_DOWNWARD
|
|
@item FE_DOWNWARD
|
|
Round toward @math{-@infinity{}}.
|
|
|
|
@comment fenv.h
|
|
@comment ISO
|
|
@vindex FE_TOWARDZERO
|
|
@item FE_TOWARDZERO
|
|
Round toward zero.
|
|
@end table
|
|
|
|
Underflow is an unusual case. Normally, @w{IEEE 754} floating point
|
|
numbers are always normalized (@pxref{Floating Point Concepts}).
|
|
Numbers smaller than @math{2^r} (where @math{r} is the minimum exponent,
|
|
@code{FLT_MIN_RADIX-1} for @var{float}) cannot be represented as
|
|
normalized numbers. Rounding all such numbers to zero or @math{2^r}
|
|
would cause some algorithms to fail at 0. Therefore, they are left in
|
|
denormalized form. That produces loss of precision, since some bits of
|
|
the mantissa are stolen to indicate the decimal point.
|
|
|
|
If a result is too small to be represented as a denormalized number, it
|
|
is rounded to zero. However, the sign of the result is preserved; if
|
|
the calculation was negative, the result is @dfn{negative zero}.
|
|
Negative zero can also result from some operations on infinity, such as
|
|
@math{4/-@infinity{}}. Negative zero behaves identically to zero except
|
|
when the @code{copysign} or @code{signbit} functions are used to check
|
|
the sign bit directly.
|
|
|
|
At any time one of the above four rounding modes is selected. You can
|
|
find out which one with this function:
|
|
|
|
@comment fenv.h
|
|
@comment ISO
|
|
@deftypefun int fegetround (void)
|
|
Returns the currently selected rounding mode, represented by one of the
|
|
values of the defined rounding mode macros.
|
|
@end deftypefun
|
|
|
|
@noindent
|
|
To change the rounding mode, use this function:
|
|
|
|
@comment fenv.h
|
|
@comment ISO
|
|
@deftypefun int fesetround (int @var{round})
|
|
Changes the currently selected rounding mode to @var{round}. If
|
|
@var{round} does not correspond to one of the supported rounding modes
|
|
nothing is changed. @code{fesetround} returns a nonzero value if it
|
|
changed the rounding mode, zero if the mode is not supported.
|
|
@end deftypefun
|
|
|
|
You should avoid changing the rounding mode if possible. It can be an
|
|
expensive operation; also, some hardware requires you to compile your
|
|
program differently for it to work. The resulting code may run slower.
|
|
See your compiler documentation for details.
|
|
@c This section used to claim that functions existed to round one number
|
|
@c in a specific fashion. I can't find any functions in the library
|
|
@c that do that. -zw
|
|
|
|
@node Control Functions
|
|
@section Floating-Point Control Functions
|
|
|
|
@w{IEEE 754} floating-point implementations allow the programmer to
|
|
decide whether traps will occur for each of the exceptions, by setting
|
|
bits in the @dfn{control word}. In C, traps result in the program
|
|
receiving the @code{SIGFPE} signal; see @ref{Signal Handling}.
|
|
|
|
@strong{Note:} @w{IEEE 754} says that trap handlers are given details of
|
|
the exceptional situation, and can set the result value. C signals do
|
|
not provide any mechanism to pass this information back and forth.
|
|
Trapping exceptions in C is therefore not very useful.
|
|
|
|
It is sometimes necessary to save the state of the floating-point unit
|
|
while you perform some calculation. The library provides functions
|
|
which save and restore the exception flags, the set of exceptions that
|
|
generate traps, and the rounding mode. This information is known as the
|
|
@dfn{floating-point environment}.
|
|
|
|
The functions to save and restore the floating-point environment all use
|
|
a variable of type @code{fenv_t} to store information. This type is
|
|
defined in @file{fenv.h}. Its size and contents are
|
|
implementation-defined. You should not attempt to manipulate a variable
|
|
of this type directly.
|
|
|
|
To save the state of the FPU, use one of these functions:
|
|
|
|
@comment fenv.h
|
|
@comment ISO
|
|
@deftypefun void fegetenv (fenv_t *@var{envp})
|
|
Store the floating-point environment in the variable pointed to by
|
|
@var{envp}.
|
|
@end deftypefun
|
|
|
|
@comment fenv.h
|
|
@comment ISO
|
|
@deftypefun int feholdexcept (fenv_t *@var{envp})
|
|
Store the current floating-point environment in the object pointed to by
|
|
@var{envp}. Then clear all exception flags, and set the FPU to trap no
|
|
exceptions. Not all FPUs support trapping no exceptions; if
|
|
@code{feholdexcept} cannot set this mode, it returns zero. If it
|
|
succeeds, it returns a nonzero value.
|
|
@end deftypefun
|
|
|
|
The functions which restore the floating-point environment can take two
|
|
kinds of arguments:
|
|
|
|
@itemize @bullet
|
|
@item
|
|
Pointers to @code{fenv_t} objects, which were initialized previously by a
|
|
call to @code{fegetenv} or @code{feholdexcept}.
|
|
@item
|
|
@vindex FE_DFL_ENV
|
|
The special macro @code{FE_DFL_ENV} which represents the floating-point
|
|
environment as it was available at program start.
|
|
@item
|
|
Implementation defined macros with names starting with @code{FE_}.
|
|
|
|
@vindex FE_NOMASK_ENV
|
|
If possible, the GNU C Library defines a macro @code{FE_NOMASK_ENV}
|
|
which represents an environment where every exception raised causes a
|
|
trap to occur. You can test for this macro using @code{#ifdef}. It is
|
|
only defined if @code{_GNU_SOURCE} is defined.
|
|
|
|
Some platforms might define other predefined environments.
|
|
@end itemize
|
|
|
|
@noindent
|
|
To set the floating-point environment, you can use either of these
|
|
functions:
|
|
|
|
@comment fenv.h
|
|
@comment ISO
|
|
@deftypefun void fesetenv (const fenv_t *@var{envp})
|
|
Set the floating-point environment to that described by @var{envp}.
|
|
@end deftypefun
|
|
|
|
@comment fenv.h
|
|
@comment ISO
|
|
@deftypefun void feupdateenv (const fenv_t *@var{envp})
|
|
Like @code{fesetenv}, this function sets the floating-point environment
|
|
to that described by @var{envp}. However, if any exceptions were
|
|
flagged in the status word before @code{feupdateenv} was called, they
|
|
remain flagged after the call. In other words, after @code{feupdateenv}
|
|
is called, the status word is the bitwise OR of the previous status word
|
|
and the one saved in @var{envp}.
|
|
@end deftypefun
|
|
|
|
@node Arithmetic Functions
|
|
@section Arithmetic Functions
|
|
|
|
The C library provides functions to do basic operations on
|
|
floating-point numbers. These include absolute value, maximum and minimum,
|
|
normalization, bit twiddling, rounding, and a few others.
|
|
|
|
@menu
|
|
* Absolute Value:: Absolute values of integers and floats.
|
|
* Normalization Functions:: Extracting exponents and putting them back.
|
|
* Rounding Functions:: Rounding floats to integers.
|
|
* Remainder Functions:: Remainders on division, precisely defined.
|
|
* FP Bit Twiddling:: Sign bit adjustment. Adding epsilon.
|
|
* FP Comparison Functions:: Comparisons without risk of exceptions.
|
|
* Misc FP Arithmetic:: Max, min, positive difference, multiply-add.
|
|
@end menu
|
|
|
|
@node Absolute Value
|
|
@subsection Absolute Value
|
|
@cindex absolute value functions
|
|
|
|
These functions are provided for obtaining the @dfn{absolute value} (or
|
|
@dfn{magnitude}) of a number. The absolute value of a real number
|
|
@var{x} is @var{x} if @var{x} is positive, @minus{}@var{x} if @var{x} is
|
|
negative. For a complex number @var{z}, whose real part is @var{x} and
|
|
whose imaginary part is @var{y}, the absolute value is @w{@code{sqrt
|
|
(@var{x}*@var{x} + @var{y}*@var{y})}}.
|
|
|
|
@pindex math.h
|
|
@pindex stdlib.h
|
|
Prototypes for @code{abs}, @code{labs} and @code{llabs} are in @file{stdlib.h};
|
|
@code{fabs}, @code{fabsf} and @code{fabsl} are declared in @file{math.h}.
|
|
@code{cabs}, @code{cabsf} and @code{cabsl} are declared in @file{complex.h}.
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftypefun int abs (int @var{number})
|
|
@deftypefunx {long int} labs (long int @var{number})
|
|
@deftypefunx {long long int} llabs (long long int @var{number})
|
|
These functions return the absolute value of @var{number}.
|
|
|
|
Most computers use a two's complement integer representation, in which
|
|
the absolute value of @code{INT_MIN} (the smallest possible @code{int})
|
|
cannot be represented; thus, @w{@code{abs (INT_MIN)}} is not defined.
|
|
|
|
@code{llabs} is new to @w{ISO C 9x}
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double fabs (double @var{number})
|
|
@deftypefunx float fabsf (float @var{number})
|
|
@deftypefunx {long double} fabsl (long double @var{number})
|
|
This function returns the absolute value of the floating-point number
|
|
@var{number}.
|
|
@end deftypefun
|
|
|
|
@comment complex.h
|
|
@comment ISO
|
|
@deftypefun double cabs (complex double @var{z})
|
|
@deftypefunx float cabsf (complex float @var{z})
|
|
@deftypefunx {long double} cabsl (complex long double @var{z})
|
|
These functions return the absolute value of the complex number @var{z}
|
|
(@pxref{Complex Numbers}). The absolute value of a complex number is:
|
|
|
|
@smallexample
|
|
sqrt (creal (@var{z}) * creal (@var{z}) + cimag (@var{z}) * cimag (@var{z}))
|
|
@end smallexample
|
|
|
|
This function should always be used instead of the direct formula
|
|
because it takes special care to avoid losing precision. It may also
|
|
take advantage of hardware support for this operation. See @code{hypot}
|
|
in @xref{Exponents and Logarithms}.
|
|
@end deftypefun
|
|
|
|
@node Normalization Functions
|
|
@subsection Normalization Functions
|
|
@cindex normalization functions (floating-point)
|
|
|
|
The functions described in this section are primarily provided as a way
|
|
to efficiently perform certain low-level manipulations on floating point
|
|
numbers that are represented internally using a binary radix;
|
|
see @ref{Floating Point Concepts}. These functions are required to
|
|
have equivalent behavior even if the representation does not use a radix
|
|
of 2, but of course they are unlikely to be particularly efficient in
|
|
those cases.
|
|
|
|
@pindex math.h
|
|
All these functions are declared in @file{math.h}.
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double frexp (double @var{value}, int *@var{exponent})
|
|
@deftypefunx float frexpf (float @var{value}, int *@var{exponent})
|
|
@deftypefunx {long double} frexpl (long double @var{value}, int *@var{exponent})
|
|
These functions are used to split the number @var{value}
|
|
into a normalized fraction and an exponent.
|
|
|
|
If the argument @var{value} is not zero, the return value is @var{value}
|
|
times a power of two, and is always in the range 1/2 (inclusive) to 1
|
|
(exclusive). The corresponding exponent is stored in
|
|
@code{*@var{exponent}}; the return value multiplied by 2 raised to this
|
|
exponent equals the original number @var{value}.
|
|
|
|
For example, @code{frexp (12.8, &exponent)} returns @code{0.8} and
|
|
stores @code{4} in @code{exponent}.
|
|
|
|
If @var{value} is zero, then the return value is zero and
|
|
zero is stored in @code{*@var{exponent}}.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double ldexp (double @var{value}, int @var{exponent})
|
|
@deftypefunx float ldexpf (float @var{value}, int @var{exponent})
|
|
@deftypefunx {long double} ldexpl (long double @var{value}, int @var{exponent})
|
|
These functions return the result of multiplying the floating-point
|
|
number @var{value} by 2 raised to the power @var{exponent}. (It can
|
|
be used to reassemble floating-point numbers that were taken apart
|
|
by @code{frexp}.)
|
|
|
|
For example, @code{ldexp (0.8, 4)} returns @code{12.8}.
|
|
@end deftypefun
|
|
|
|
The following functions, which come from BSD, provide facilities
|
|
equivalent to those of @code{ldexp} and @code{frexp}.
|
|
|
|
@comment math.h
|
|
@comment BSD
|
|
@deftypefun double logb (double @var{x})
|
|
@deftypefunx float logbf (float @var{x})
|
|
@deftypefunx {long double} logbl (long double @var{x})
|
|
These functions return the integer part of the base-2 logarithm of
|
|
@var{x}, an integer value represented in type @code{double}. This is
|
|
the highest integer power of @code{2} contained in @var{x}. The sign of
|
|
@var{x} is ignored. For example, @code{logb (3.5)} is @code{1.0} and
|
|
@code{logb (4.0)} is @code{2.0}.
|
|
|
|
When @code{2} raised to this power is divided into @var{x}, it gives a
|
|
quotient between @code{1} (inclusive) and @code{2} (exclusive).
|
|
|
|
If @var{x} is zero, the return value is minus infinity if the machine
|
|
supports infinities, and a very small number if it does not. If @var{x}
|
|
is infinity, the return value is infinity.
|
|
|
|
For finite @var{x}, the value returned by @code{logb} is one less than
|
|
the value that @code{frexp} would store into @code{*@var{exponent}}.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment BSD
|
|
@deftypefun double scalb (double @var{value}, int @var{exponent})
|
|
@deftypefunx float scalbf (float @var{value}, int @var{exponent})
|
|
@deftypefunx {long double} scalbl (long double @var{value}, int @var{exponent})
|
|
The @code{scalb} function is the BSD name for @code{ldexp}.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment BSD
|
|
@deftypefun {long long int} scalbn (double @var{x}, int n)
|
|
@deftypefunx {long long int} scalbnf (float @var{x}, int n)
|
|
@deftypefunx {long long int} scalbnl (long double @var{x}, int n)
|
|
@code{scalbn} is identical to @code{scalb}, except that the exponent
|
|
@var{n} is an @code{int} instead of a floating-point number.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment BSD
|
|
@deftypefun {long long int} scalbln (double @var{x}, long int n)
|
|
@deftypefunx {long long int} scalblnf (float @var{x}, long int n)
|
|
@deftypefunx {long long int} scalblnl (long double @var{x}, long int n)
|
|
@code{scalbln} is identical to @code{scalb}, except that the exponent
|
|
@var{n} is a @code{long int} instead of a floating-point number.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment BSD
|
|
@deftypefun {long long int} significand (double @var{x})
|
|
@deftypefunx {long long int} significandf (float @var{x})
|
|
@deftypefunx {long long int} significandl (long double @var{x})
|
|
@code{significand} returns the mantissa of @var{x} scaled to the range
|
|
@math{[1, 2)}.
|
|
It is equivalent to @w{@code{scalb (@var{x}, (double) -ilogb (@var{x}))}}.
|
|
|
|
This function exists mainly for use in certain standardized tests
|
|
of @w{IEEE 754} conformance.
|
|
@end deftypefun
|
|
|
|
@node Rounding Functions
|
|
@subsection Rounding Functions
|
|
@cindex converting floats to integers
|
|
|
|
@pindex math.h
|
|
The functions listed here perform operations such as rounding and
|
|
truncation of floating-point values. Some of these functions convert
|
|
floating point numbers to integer values. They are all declared in
|
|
@file{math.h}.
|
|
|
|
You can also convert floating-point numbers to integers simply by
|
|
casting them to @code{int}. This discards the fractional part,
|
|
effectively rounding towards zero. However, this only works if the
|
|
result can actually be represented as an @code{int}---for very large
|
|
numbers, this is impossible. The functions listed here return the
|
|
result as a @code{double} instead to get around this problem.
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double ceil (double @var{x})
|
|
@deftypefunx float ceilf (float @var{x})
|
|
@deftypefunx {long double} ceill (long double @var{x})
|
|
These functions round @var{x} upwards to the nearest integer,
|
|
returning that value as a @code{double}. Thus, @code{ceil (1.5)}
|
|
is @code{2.0}.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double floor (double @var{x})
|
|
@deftypefunx float floorf (float @var{x})
|
|
@deftypefunx {long double} floorl (long double @var{x})
|
|
These functions round @var{x} downwards to the nearest
|
|
integer, returning that value as a @code{double}. Thus, @code{floor
|
|
(1.5)} is @code{1.0} and @code{floor (-1.5)} is @code{-2.0}.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double trunc (double @var{x})
|
|
@deftypefunx float truncf (float @var{x})
|
|
@deftypefunx {long double} truncl (long double @var{x})
|
|
@code{trunc} is another name for @code{floor}
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double rint (double @var{x})
|
|
@deftypefunx float rintf (float @var{x})
|
|
@deftypefunx {long double} rintl (long double @var{x})
|
|
These functions round @var{x} to an integer value according to the
|
|
current rounding mode. @xref{Floating Point Parameters}, for
|
|
information about the various rounding modes. The default
|
|
rounding mode is to round to the nearest integer; some machines
|
|
support other modes, but round-to-nearest is always used unless
|
|
you explicitly select another.
|
|
|
|
If @var{x} was not initially an integer, these functions raise the
|
|
inexact exception.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double nearbyint (double @var{x})
|
|
@deftypefunx float nearbyintf (float @var{x})
|
|
@deftypefunx {long double} nearbyintl (long double @var{x})
|
|
These functions return the same value as the @code{rint} functions, but
|
|
do not raise the inexact exception if @var{x} is not an integer.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double round (double @var{x})
|
|
@deftypefunx float roundf (float @var{x})
|
|
@deftypefunx {long double} roundl (long double @var{x})
|
|
These functions are similar to @code{rint}, but they round halfway
|
|
cases away from zero instead of to the nearest even integer.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun {long int} lrint (double @var{x})
|
|
@deftypefunx {long int} lrintf (float @var{x})
|
|
@deftypefunx {long int} lrintl (long double @var{x})
|
|
These functions are just like @code{rint}, but they return a
|
|
@code{long int} instead of a floating-point number.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun {long long int} llrint (double @var{x})
|
|
@deftypefunx {long long int} llrintf (float @var{x})
|
|
@deftypefunx {long long int} llrintl (long double @var{x})
|
|
These functions are just like @code{rint}, but they return a
|
|
@code{long long int} instead of a floating-point number.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun {long int} lround (double @var{x})
|
|
@deftypefunx {long int} lroundf (float @var{x})
|
|
@deftypefunx {long int} lroundl (long double @var{x})
|
|
These functions are just like @code{round}, but they return a
|
|
@code{long int} instead of a floating-point number.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun {long long int} llround (double @var{x})
|
|
@deftypefunx {long long int} llroundf (float @var{x})
|
|
@deftypefunx {long long int} llroundl (long double @var{x})
|
|
These functions are just like @code{round}, but they return a
|
|
@code{long long int} instead of a floating-point number.
|
|
@end deftypefun
|
|
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double modf (double @var{value}, double *@var{integer-part})
|
|
@deftypefunx float modff (float @var{value}, float *@var{integer-part})
|
|
@deftypefunx {long double} modfl (long double @var{value}, long double *@var{integer-part})
|
|
These functions break the argument @var{value} into an integer part and a
|
|
fractional part (between @code{-1} and @code{1}, exclusive). Their sum
|
|
equals @var{value}. Each of the parts has the same sign as @var{value},
|
|
and the integer part is always rounded toward zero.
|
|
|
|
@code{modf} stores the integer part in @code{*@var{integer-part}}, and
|
|
returns the fractional part. For example, @code{modf (2.5, &intpart)}
|
|
returns @code{0.5} and stores @code{2.0} into @code{intpart}.
|
|
@end deftypefun
|
|
|
|
@node Remainder Functions
|
|
@subsection Remainder Functions
|
|
|
|
The functions in this section compute the remainder on division of two
|
|
floating-point numbers. Each is a little different; pick the one that
|
|
suits your problem.
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double fmod (double @var{numerator}, double @var{denominator})
|
|
@deftypefunx float fmodf (float @var{numerator}, float @var{denominator})
|
|
@deftypefunx {long double} fmodl (long double @var{numerator}, long double @var{denominator})
|
|
These functions compute the remainder from the division of
|
|
@var{numerator} by @var{denominator}. Specifically, the return value is
|
|
@code{@var{numerator} - @w{@var{n} * @var{denominator}}}, where @var{n}
|
|
is the quotient of @var{numerator} divided by @var{denominator}, rounded
|
|
towards zero to an integer. Thus, @w{@code{fmod (6.5, 2.3)}} returns
|
|
@code{1.9}, which is @code{6.5} minus @code{4.6}.
|
|
|
|
The result has the same sign as the @var{numerator} and has magnitude
|
|
less than the magnitude of the @var{denominator}.
|
|
|
|
If @var{denominator} is zero, @code{fmod} signals a domain error.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment BSD
|
|
@deftypefun double drem (double @var{numerator}, double @var{denominator})
|
|
@deftypefunx float dremf (float @var{numerator}, float @var{denominator})
|
|
@deftypefunx {long double} dreml (long double @var{numerator}, long double @var{denominator})
|
|
These functions are like @code{fmod} except that they rounds the
|
|
internal quotient @var{n} to the nearest integer instead of towards zero
|
|
to an integer. For example, @code{drem (6.5, 2.3)} returns @code{-0.4},
|
|
which is @code{6.5} minus @code{6.9}.
|
|
|
|
The absolute value of the result is less than or equal to half the
|
|
absolute value of the @var{denominator}. The difference between
|
|
@code{fmod (@var{numerator}, @var{denominator})} and @code{drem
|
|
(@var{numerator}, @var{denominator})} is always either
|
|
@var{denominator}, minus @var{denominator}, or zero.
|
|
|
|
If @var{denominator} is zero, @code{drem} signals a domain error.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment BSD
|
|
@deftypefun double remainder (double @var{numerator}, double @var{denominator})
|
|
@deftypefunx float remainderf (float @var{numerator}, float @var{denominator})
|
|
@deftypefunx {long double} remainderl (long double @var{numerator}, long double @var{denominator})
|
|
This function is another name for @code{drem}.
|
|
@end deftypefun
|
|
|
|
@node FP Bit Twiddling
|
|
@subsection Setting and modifying single bits of FP values
|
|
@cindex FP arithmetic
|
|
|
|
There are some operations that are too complicated or expensive to
|
|
perform by hand on floating-point numbers. @w{ISO C 9x} defines
|
|
functions to do these operations, which mostly involve changing single
|
|
bits.
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double copysign (double @var{x}, double @var{y})
|
|
@deftypefunx float copysignf (float @var{x}, float @var{y})
|
|
@deftypefunx {long double} copysignl (long double @var{x}, long double @var{y})
|
|
These functions return @var{x} but with the sign of @var{y}. They work
|
|
even if @var{x} or @var{y} are NaN or zero. Both of these can carry a
|
|
sign (although not all implementations support it) and this is one of
|
|
the few operations that can tell the difference.
|
|
|
|
@code{copysign} never raises an exception.
|
|
@c except signalling NaNs
|
|
|
|
This function is defined in @w{IEC 559} (and the appendix with
|
|
recommended functions in @w{IEEE 754}/@w{IEEE 854}).
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun int signbit (@emph{float-type} @var{x})
|
|
@code{signbit} is a generic macro which can work on all floating-point
|
|
types. It returns a nonzero value if the value of @var{x} has its sign
|
|
bit set.
|
|
|
|
This is not the same as @code{x < 0.0}, because @w{IEEE 754} floating
|
|
point allows zero to be signed. The comparison @code{-0.0 < 0.0} is
|
|
false, but @code{signbit (-0.0)} will return a nonzero value.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double nextafter (double @var{x}, double @var{y})
|
|
@deftypefunx float nextafterf (float @var{x}, float @var{y})
|
|
@deftypefunx {long double} nextafterl (long double @var{x}, long double @var{y})
|
|
The @code{nextafter} function returns the next representable neighbor of
|
|
@var{x} in the direction towards @var{y}. The size of the step between
|
|
@var{x} and the result depends on the type of the result. If
|
|
@math{@var{x} = @var{y}} the function simply returns @var{x}. If either
|
|
value is @code{NaN}, @code{NaN} is returned. Otherwise
|
|
a value corresponding to the value of the least significant bit in the
|
|
mantissa is added or subtracted, depending on the direction.
|
|
@code{nextafter} will signal overflow or underflow if the result goes
|
|
outside of the range of normalized numbers.
|
|
|
|
This function is defined in @w{IEC 559} (and the appendix with
|
|
recommended functions in @w{IEEE 754}/@w{IEEE 854}).
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun {long long int} nextafterx (double @var{x}, long double @var{y})
|
|
@deftypefunx {long long int} nextafterxf (float @var{x}, long double @var{y})
|
|
@deftypefunx {long long int} nextafterxl (long double @var{x}, long double @var{y})
|
|
These functions are identical to the corresponding versions of
|
|
@code{nextafter} except that their second argument is a @code{long
|
|
double}.
|
|
@end deftypefun
|
|
|
|
@cindex NaN
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double nan (const char *@var{tagp})
|
|
@deftypefunx float nanf (const char *@var{tagp})
|
|
@deftypefunx {long double} nanl (const char *@var{tagp})
|
|
The @code{nan} function returns a representation of NaN, provided that
|
|
NaN is supported by the target platform.
|
|
@code{nan ("@var{n-char-sequence}")} is equivalent to
|
|
@code{strtod ("NAN(@var{n-char-sequence})")}.
|
|
|
|
The argument @var{tagp} is used in an unspecified manner. On @w{IEEE
|
|
754} systems, there are many representations of NaN, and @var{tagp}
|
|
selects one. On other systems it may do nothing.
|
|
@end deftypefun
|
|
|
|
@node FP Comparison Functions
|
|
@subsection Floating-Point Comparison Functions
|
|
@cindex unordered comparison
|
|
|
|
The standard C comparison operators provoke exceptions when one or other
|
|
of the operands is NaN. For example,
|
|
|
|
@smallexample
|
|
int v = a < 1.0;
|
|
@end smallexample
|
|
|
|
@noindent
|
|
will raise an exception if @var{a} is NaN. (This does @emph{not}
|
|
happen with @code{==} and @code{!=}; those merely return false and true,
|
|
respectively, when NaN is examined.) Frequently this exception is
|
|
undesirable. @w{ISO C 9x} therefore defines comparison functions that
|
|
do not raise exceptions when NaN is examined. All of the functions are
|
|
implemented as macros which allow their arguments to be of any
|
|
floating-point type. The macros are guaranteed to evaluate their
|
|
arguments only once.
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefn Macro int isgreater (@emph{real-floating} @var{x}, @emph{real-floating} @var{y})
|
|
This macro determines whether the argument @var{x} is greater than
|
|
@var{y}. It is equivalent to @code{(@var{x}) > (@var{y})}, but no
|
|
exception is raised if @var{x} or @var{y} are NaN.
|
|
@end deftypefn
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefn Macro int isgreaterequal (@emph{real-floating} @var{x}, @emph{real-floating} @var{y})
|
|
This macro determines whether the argument @var{x} is greater than or
|
|
equal to @var{y}. It is equivalent to @code{(@var{x}) >= (@var{y})}, but no
|
|
exception is raised if @var{x} or @var{y} are NaN.
|
|
@end deftypefn
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefn Macro int isless (@emph{real-floating} @var{x}, @emph{real-floating} @var{y})
|
|
This macro determines whether the argument @var{x} is less than @var{y}.
|
|
It is equivalent to @code{(@var{x}) < (@var{y})}, but no exception is
|
|
raised if @var{x} or @var{y} are NaN.
|
|
@end deftypefn
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefn Macro int islessequal (@emph{real-floating} @var{x}, @emph{real-floating} @var{y})
|
|
This macro determines whether the argument @var{x} is less than or equal
|
|
to @var{y}. It is equivalent to @code{(@var{x}) <= (@var{y})}, but no
|
|
exception is raised if @var{x} or @var{y} are NaN.
|
|
@end deftypefn
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefn Macro int islessgreater (@emph{real-floating} @var{x}, @emph{real-floating} @var{y})
|
|
This macro determines whether the argument @var{x} is less or greater
|
|
than @var{y}. It is equivalent to @code{(@var{x}) < (@var{y}) ||
|
|
(@var{x}) > (@var{y})} (although it only evaluates @var{x} and @var{y}
|
|
once), but no exception is raised if @var{x} or @var{y} are NaN.
|
|
|
|
This macro is not equivalent to @code{@var{x} != @var{y}}, because that
|
|
expression is true if @var{x} or @var{y} are NaN.
|
|
@end deftypefn
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefn Macro int isunordered (@emph{real-floating} @var{x}, @emph{real-floating} @var{y})
|
|
This macro determines whether its arguments are unordered. In other
|
|
words, it is true if @var{x} or @var{y} are NaN, and false otherwise.
|
|
@end deftypefn
|
|
|
|
Not all machines provide hardware support for these operations. On
|
|
machines that don't, the macros can be very slow. Therefore, you should
|
|
not use these functions when NaN is not a concern.
|
|
|
|
@strong{Note:} There are no macros @code{isequal} or @code{isunequal}.
|
|
They are unnecessary, because the @code{==} and @code{!=} operators do
|
|
@emph{not} throw an exception if one or both of the operands are NaN.
|
|
|
|
@node Misc FP Arithmetic
|
|
@subsection Miscellaneous FP arithmetic functions
|
|
@cindex minimum
|
|
@cindex maximum
|
|
@cindex positive difference
|
|
@cindex multiply-add
|
|
|
|
The functions in this section perform miscellaneous but common
|
|
operations that are awkward to express with C operators. On some
|
|
processors these functions can use special machine instructions to
|
|
perform these operations faster than the equivalent C code.
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double fmin (double @var{x}, double @var{y})
|
|
@deftypefunx float fminf (float @var{x}, float @var{y})
|
|
@deftypefunx {long double} fminl (long double @var{x}, long double @var{y})
|
|
The @code{fmin} function returns the lesser of the two values @var{x}
|
|
and @var{y}. It is similar to the expression
|
|
@smallexample
|
|
((x) < (y) ? (x) : (y))
|
|
@end smallexample
|
|
except that @var{x} and @var{y} are only evaluated once.
|
|
|
|
If an argument is NaN, the other argument is returned. If both arguments
|
|
are NaN, NaN is returned.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double fmax (double @var{x}, double @var{y})
|
|
@deftypefunx float fmaxf (float @var{x}, float @var{y})
|
|
@deftypefunx {long double} fmaxl (long double @var{x}, long double @var{y})
|
|
The @code{fmax} function returns the greater of the two values @var{x}
|
|
and @var{y}.
|
|
|
|
If an argument is NaN, the other argument is returned. If both arguments
|
|
are NaN, NaN is returned.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double fdim (double @var{x}, double @var{y})
|
|
@deftypefunx float fdimf (float @var{x}, float @var{y})
|
|
@deftypefunx {long double} fdiml (long double @var{x}, long double @var{y})
|
|
The @code{fdim} function returns the positive difference between
|
|
@var{x} and @var{y}. The positive difference is @math{@var{x} -
|
|
@var{y}} if @var{x} is greater than @var{y}, and @math{0} otherwise.
|
|
|
|
If @var{x}, @var{y}, or both are NaN, NaN is returned.
|
|
@end deftypefun
|
|
|
|
@comment math.h
|
|
@comment ISO
|
|
@deftypefun double fma (double @var{x}, double @var{y}, double @var{z})
|
|
@deftypefunx float fmaf (float @var{x}, float @var{y}, float @var{z})
|
|
@deftypefunx {long double} fmal (long double @var{x}, long double @var{y}, long double @var{z})
|
|
@cindex butterfly
|
|
The @code{fma} function performs floating-point multiply-add. This is
|
|
the operation @math{(@var{x} @mul{} @var{y}) + @var{z}}, but the
|
|
intermediate result is not rounded to the destination type. This can
|
|
sometimes improve the precision of a calculation.
|
|
|
|
This function was introduced because some processors have a special
|
|
instruction to perform multiply-add. The C compiler cannot use it
|
|
directly, because the expression @samp{x*y + z} is defined to round the
|
|
intermediate result. @code{fma} lets you choose when you want to round
|
|
only once.
|
|
|
|
@vindex FP_FAST_FMA
|
|
On processors which do not implement multiply-add in hardware,
|
|
@code{fma} can be very slow since it must avoid intermediate rounding.
|
|
@file{math.h} defines the symbols @code{FP_FAST_FMA},
|
|
@code{FP_FAST_FMAF}, and @code{FP_FAST_FMAL} when the corresponding
|
|
version of @code{fma} is no slower than the expression @samp{x*y + z}.
|
|
In the GNU C library, this always means the operation is implemented in
|
|
hardware.
|
|
@end deftypefun
|
|
|
|
@node Complex Numbers
|
|
@section Complex Numbers
|
|
@pindex complex.h
|
|
@cindex complex numbers
|
|
|
|
@w{ISO C 9x} introduces support for complex numbers in C. This is done
|
|
with a new type qualifier, @code{complex}. It is a keyword if and only
|
|
if @file{complex.h} has been included. There are three complex types,
|
|
corresponding to the three real types: @code{float complex},
|
|
@code{double complex}, and @code{long double complex}.
|
|
|
|
To construct complex numbers you need a way to indicate the imaginary
|
|
part of a number. There is no standard notation for an imaginary
|
|
floating point constant. Instead, @file{complex.h} defines two macros
|
|
that can be used to create complex numbers.
|
|
|
|
@deftypevr Macro {const float complex} _Complex_I
|
|
This macro is a representation of the complex number ``@math{0+1i}''.
|
|
Multiplying a real floating-point value by @code{_Complex_I} gives a
|
|
complex number whose value is purely imaginary. You can use this to
|
|
construct complex constants:
|
|
|
|
@smallexample
|
|
@math{3.0 + 4.0i} = @code{3.0 + 4.0 * _Complex_I}
|
|
@end smallexample
|
|
|
|
Note that @code{_Complex_I * _Complex_I} has the value @code{-1}, but
|
|
the type of that value is @code{complex}.
|
|
@end deftypevr
|
|
|
|
@c Put this back in when gcc supports _Imaginary_I. It's too confusing.
|
|
@ignore
|
|
@noindent
|
|
Without an optimizing compiler this is more expensive than the use of
|
|
@code{_Imaginary_I} but with is better than nothing. You can avoid all
|
|
the hassles if you use the @code{I} macro below if the name is not
|
|
problem.
|
|
|
|
@deftypevr Macro {const float imaginary} _Imaginary_I
|
|
This macro is a representation of the value ``@math{1i}''. I.e., it is
|
|
the value for which
|
|
|
|
@smallexample
|
|
_Imaginary_I * _Imaginary_I = -1
|
|
@end smallexample
|
|
|
|
@noindent
|
|
The result is not of type @code{float imaginary} but instead @code{float}.
|
|
One can use it to easily construct complex number like in
|
|
|
|
@smallexample
|
|
3.0 - _Imaginary_I * 4.0
|
|
@end smallexample
|
|
|
|
@noindent
|
|
which results in the complex number with a real part of 3.0 and a
|
|
imaginary part -4.0.
|
|
@end deftypevr
|
|
@end ignore
|
|
|
|
@noindent
|
|
@code{_Complex_I} is a bit of a mouthful. @file{complex.h} also defines
|
|
a shorter name for the same constant.
|
|
|
|
@deftypevr Macro {const float complex} I
|
|
This macro has exactly the same value as @code{_Complex_I}. Most of the
|
|
time it is preferable. However, it causes problems if you want to use
|
|
the identifier @code{I} for something else. You can safely write
|
|
|
|
@smallexample
|
|
#include <complex.h>
|
|
#undef I
|
|
@end smallexample
|
|
|
|
@noindent
|
|
if you need @code{I} for your own purposes. (In that case we recommend
|
|
you also define some other short name for @code{_Complex_I}, such as
|
|
@code{J}.)
|
|
|
|
@ignore
|
|
If the implementation does not support the @code{imaginary} types
|
|
@code{I} is defined as @code{_Complex_I} which is the second best
|
|
solution. It still can be used in the same way but requires a most
|
|
clever compiler to get the same results.
|
|
@end ignore
|
|
@end deftypevr
|
|
|
|
@node Operations on Complex
|
|
@section Projections, Conjugates, and Decomposing of Complex Numbers
|
|
@cindex project complex numbers
|
|
@cindex conjugate complex numbers
|
|
@cindex decompose complex numbers
|
|
@pindex complex.h
|
|
|
|
@w{ISO C 9x} also defines functions that perform basic operations on
|
|
complex numbers, such as decomposition and conjugation. The prototypes
|
|
for all these functions are in @file{complex.h}. All functions are
|
|
available in three variants, one for each of the three complex types.
|
|
|
|
@comment complex.h
|
|
@comment ISO
|
|
@deftypefun double creal (complex double @var{z})
|
|
@deftypefunx float crealf (complex float @var{z})
|
|
@deftypefunx {long double} creall (complex long double @var{z})
|
|
These functions return the real part of the complex number @var{z}.
|
|
@end deftypefun
|
|
|
|
@comment complex.h
|
|
@comment ISO
|
|
@deftypefun double cimag (complex double @var{z})
|
|
@deftypefunx float cimagf (complex float @var{z})
|
|
@deftypefunx {long double} cimagl (complex long double @var{z})
|
|
These functions return the imaginary part of the complex number @var{z}.
|
|
@end deftypefun
|
|
|
|
@comment complex.h
|
|
@comment ISO
|
|
@deftypefun {complex double} conj (complex double @var{z})
|
|
@deftypefunx {complex float} conjf (complex float @var{z})
|
|
@deftypefunx {complex long double} conjl (complex long double @var{z})
|
|
These functions return the conjugate value of the complex number
|
|
@var{z}. The conjugate of a complex number has the same real part and a
|
|
negated imaginary part. In other words, @samp{conj(a + bi) = a + -bi}.
|
|
@end deftypefun
|
|
|
|
@comment complex.h
|
|
@comment ISO
|
|
@deftypefun double carg (complex double @var{z})
|
|
@deftypefunx float cargf (complex float @var{z})
|
|
@deftypefunx {long double} cargl (complex long double @var{z})
|
|
These functions return the argument of the complex number @var{z}.
|
|
The argument of a complex number is the angle in the complex plane
|
|
between the positive real axis and a line passing through zero and the
|
|
number. This angle is measured in the usual fashion and ranges from @math{0}
|
|
to @math{2@pi{}}.
|
|
|
|
@code{carg} has a branch cut along the positive real axis.
|
|
@end deftypefun
|
|
|
|
@comment complex.h
|
|
@comment ISO
|
|
@deftypefun {complex double} cproj (complex double @var{z})
|
|
@deftypefunx {complex float} cprojf (complex float @var{z})
|
|
@deftypefunx {complex long double} cprojl (complex long double @var{z})
|
|
These functions return the projection of the complex value @var{z} onto
|
|
the Riemann sphere. Values with a infinite imaginary part are projected
|
|
to positive infinity on the real axis, even if the real part is NaN. If
|
|
the real part is infinite, the result is equivalent to
|
|
|
|
@smallexample
|
|
INFINITY + I * copysign (0.0, cimag (z))
|
|
@end smallexample
|
|
@end deftypefun
|
|
|
|
@node Integer Division
|
|
@section Integer Division
|
|
@cindex integer division functions
|
|
|
|
This section describes functions for performing integer division. These
|
|
functions are redundant when GNU CC is used, because in GNU C the
|
|
@samp{/} operator always rounds towards zero. But in other C
|
|
implementations, @samp{/} may round differently with negative arguments.
|
|
@code{div} and @code{ldiv} are useful because they specify how to round
|
|
the quotient: towards zero. The remainder has the same sign as the
|
|
numerator.
|
|
|
|
These functions are specified to return a result @var{r} such that the value
|
|
@code{@var{r}.quot*@var{denominator} + @var{r}.rem} equals
|
|
@var{numerator}.
|
|
|
|
@pindex stdlib.h
|
|
To use these facilities, you should include the header file
|
|
@file{stdlib.h} in your program.
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftp {Data Type} div_t
|
|
This is a structure type used to hold the result returned by the @code{div}
|
|
function. It has the following members:
|
|
|
|
@table @code
|
|
@item int quot
|
|
The quotient from the division.
|
|
|
|
@item int rem
|
|
The remainder from the division.
|
|
@end table
|
|
@end deftp
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftypefun div_t div (int @var{numerator}, int @var{denominator})
|
|
This function @code{div} computes the quotient and remainder from
|
|
the division of @var{numerator} by @var{denominator}, returning the
|
|
result in a structure of type @code{div_t}.
|
|
|
|
If the result cannot be represented (as in a division by zero), the
|
|
behavior is undefined.
|
|
|
|
Here is an example, albeit not a very useful one.
|
|
|
|
@smallexample
|
|
div_t result;
|
|
result = div (20, -6);
|
|
@end smallexample
|
|
|
|
@noindent
|
|
Now @code{result.quot} is @code{-3} and @code{result.rem} is @code{2}.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftp {Data Type} ldiv_t
|
|
This is a structure type used to hold the result returned by the @code{ldiv}
|
|
function. It has the following members:
|
|
|
|
@table @code
|
|
@item long int quot
|
|
The quotient from the division.
|
|
|
|
@item long int rem
|
|
The remainder from the division.
|
|
@end table
|
|
|
|
(This is identical to @code{div_t} except that the components are of
|
|
type @code{long int} rather than @code{int}.)
|
|
@end deftp
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftypefun ldiv_t ldiv (long int @var{numerator}, long int @var{denominator})
|
|
The @code{ldiv} function is similar to @code{div}, except that the
|
|
arguments are of type @code{long int} and the result is returned as a
|
|
structure of type @code{ldiv_t}.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftp {Data Type} lldiv_t
|
|
This is a structure type used to hold the result returned by the @code{lldiv}
|
|
function. It has the following members:
|
|
|
|
@table @code
|
|
@item long long int quot
|
|
The quotient from the division.
|
|
|
|
@item long long int rem
|
|
The remainder from the division.
|
|
@end table
|
|
|
|
(This is identical to @code{div_t} except that the components are of
|
|
type @code{long long int} rather than @code{int}.)
|
|
@end deftp
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftypefun lldiv_t lldiv (long long int @var{numerator}, long long int @var{denominator})
|
|
The @code{lldiv} function is like the @code{div} function, but the
|
|
arguments are of type @code{long long int} and the result is returned as
|
|
a structure of type @code{lldiv_t}.
|
|
|
|
The @code{lldiv} function was added in @w{ISO C 9x}.
|
|
@end deftypefun
|
|
|
|
|
|
@node Parsing of Numbers
|
|
@section Parsing of Numbers
|
|
@cindex parsing numbers (in formatted input)
|
|
@cindex converting strings to numbers
|
|
@cindex number syntax, parsing
|
|
@cindex syntax, for reading numbers
|
|
|
|
This section describes functions for ``reading'' integer and
|
|
floating-point numbers from a string. It may be more convenient in some
|
|
cases to use @code{sscanf} or one of the related functions; see
|
|
@ref{Formatted Input}. But often you can make a program more robust by
|
|
finding the tokens in the string by hand, then converting the numbers
|
|
one by one.
|
|
|
|
@menu
|
|
* Parsing of Integers:: Functions for conversion of integer values.
|
|
* Parsing of Floats:: Functions for conversion of floating-point
|
|
values.
|
|
@end menu
|
|
|
|
@node Parsing of Integers
|
|
@subsection Parsing of Integers
|
|
|
|
@pindex stdlib.h
|
|
These functions are declared in @file{stdlib.h}.
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftypefun {long int} strtol (const char *@var{string}, char **@var{tailptr}, int @var{base})
|
|
The @code{strtol} (``string-to-long'') function converts the initial
|
|
part of @var{string} to a signed integer, which is returned as a value
|
|
of type @code{long int}.
|
|
|
|
This function attempts to decompose @var{string} as follows:
|
|
|
|
@itemize @bullet
|
|
@item
|
|
A (possibly empty) sequence of whitespace characters. Which characters
|
|
are whitespace is determined by the @code{isspace} function
|
|
(@pxref{Classification of Characters}). These are discarded.
|
|
|
|
@item
|
|
An optional plus or minus sign (@samp{+} or @samp{-}).
|
|
|
|
@item
|
|
A nonempty sequence of digits in the radix specified by @var{base}.
|
|
|
|
If @var{base} is zero, decimal radix is assumed unless the series of
|
|
digits begins with @samp{0} (specifying octal radix), or @samp{0x} or
|
|
@samp{0X} (specifying hexadecimal radix); in other words, the same
|
|
syntax used for integer constants in C.
|
|
|
|
Otherwise @var{base} must have a value between @code{2} and @code{35}.
|
|
If @var{base} is @code{16}, the digits may optionally be preceded by
|
|
@samp{0x} or @samp{0X}. If base has no legal value the value returned
|
|
is @code{0l} and the global variable @code{errno} is set to @code{EINVAL}.
|
|
|
|
@item
|
|
Any remaining characters in the string. If @var{tailptr} is not a null
|
|
pointer, @code{strtol} stores a pointer to this tail in
|
|
@code{*@var{tailptr}}.
|
|
@end itemize
|
|
|
|
If the string is empty, contains only whitespace, or does not contain an
|
|
initial substring that has the expected syntax for an integer in the
|
|
specified @var{base}, no conversion is performed. In this case,
|
|
@code{strtol} returns a value of zero and the value stored in
|
|
@code{*@var{tailptr}} is the value of @var{string}.
|
|
|
|
In a locale other than the standard @code{"C"} locale, this function
|
|
may recognize additional implementation-dependent syntax.
|
|
|
|
If the string has valid syntax for an integer but the value is not
|
|
representable because of overflow, @code{strtol} returns either
|
|
@code{LONG_MAX} or @code{LONG_MIN} (@pxref{Range of Type}), as
|
|
appropriate for the sign of the value. It also sets @code{errno}
|
|
to @code{ERANGE} to indicate there was overflow.
|
|
|
|
You should not check for errors by examining the return value of
|
|
@code{strtol}, because the string might be a valid representation of
|
|
@code{0l}, @code{LONG_MAX}, or @code{LONG_MIN}. Instead, check whether
|
|
@var{tailptr} points to what you expect after the number
|
|
(e.g. @code{'\0'} if the string should end after the number). You also
|
|
need to clear @var{errno} before the call and check it afterward, in
|
|
case there was overflow.
|
|
|
|
There is an example at the end of this section.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftypefun {unsigned long int} strtoul (const char *@var{string}, char **@var{tailptr}, int @var{base})
|
|
The @code{strtoul} (``string-to-unsigned-long'') function is like
|
|
@code{strtol} except it returns an @code{unsigned long int} value. If
|
|
the number has a leading @samp{-} sign, the return value is negated.
|
|
The syntax is the same as described above for @code{strtol}. The value
|
|
returned on overflow is @code{ULONG_MAX} (@pxref{Range of
|
|
Type}).
|
|
|
|
@code{strtoul} sets @var{errno} to @code{EINVAL} if @var{base} is out of
|
|
range, or @code{ERANGE} on overflow.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftypefun {long long int} strtoll (const char *@var{string}, char **@var{tailptr}, int @var{base})
|
|
The @code{strtoll} function is like @code{strtol} except that it returns
|
|
a @code{long long int} value, and accepts numbers with a correspondingly
|
|
larger range.
|
|
|
|
If the string has valid syntax for an integer but the value is not
|
|
representable because of overflow, @code{strtoll} returns either
|
|
@code{LONG_LONG_MAX} or @code{LONG_LONG_MIN} (@pxref{Range of Type}), as
|
|
appropriate for the sign of the value. It also sets @code{errno} to
|
|
@code{ERANGE} to indicate there was overflow.
|
|
|
|
The @code{strtoll} function was introduced in @w{ISO C 9x}.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment BSD
|
|
@deftypefun {long long int} strtoq (const char *@var{string}, char **@var{tailptr}, int @var{base})
|
|
@code{strtoq} (``string-to-quad-word'') is the BSD name for @code{strtoll}.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftypefun {unsigned long long int} strtoull (const char *@var{string}, char **@var{tailptr}, int @var{base})
|
|
The @code{strtoull} function is like @code{strtoul} except that it
|
|
returns an @code{unsigned long long int}. The value returned on overflow
|
|
is @code{ULONG_LONG_MAX} (@pxref{Range of Type}).
|
|
|
|
The @code{strtoull} function was introduced in @w{ISO C 9x}.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment BSD
|
|
@deftypefun {unsigned long long int} strtouq (const char *@var{string}, char **@var{tailptr}, int @var{base})
|
|
@code{strtouq} is the BSD name for @code{strtoull}.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftypefun {long int} atol (const char *@var{string})
|
|
This function is similar to the @code{strtol} function with a @var{base}
|
|
argument of @code{10}, except that it need not detect overflow errors.
|
|
The @code{atol} function is provided mostly for compatibility with
|
|
existing code; using @code{strtol} is more robust.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftypefun int atoi (const char *@var{string})
|
|
This function is like @code{atol}, except that it returns an @code{int}.
|
|
The @code{atoi} function is also considered obsolete; use @code{strtol}
|
|
instead.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftypefun {long long int} atoll (const char *@var{string})
|
|
This function is similar to @code{atol}, except it returns a @code{long
|
|
long int}.
|
|
|
|
The @code{atoll} function was introduced in @w{ISO C 9x}. It too is
|
|
obsolete (despite having just been added); use @code{strtoll} instead.
|
|
@end deftypefun
|
|
|
|
@c !!! please fact check this paragraph -zw
|
|
@findex strtol_l
|
|
@findex strtoul_l
|
|
@findex strtoll_l
|
|
@findex strtoull_l
|
|
@cindex parsing numbers and locales
|
|
@cindex locales, parsing numbers and
|
|
Some locales specify a printed syntax for numbers other than the one
|
|
that these functions understand. If you need to read numbers formatted
|
|
in some other locale, you can use the @code{strtoX_l} functions. Each
|
|
of the @code{strtoX} functions has a counterpart with @samp{_l} added to
|
|
its name. The @samp{_l} counterparts take an additional argument: a
|
|
pointer to an @code{locale_t} structure, which describes how the numbers
|
|
to be read are formatted. @xref{Locales}.
|
|
|
|
@strong{Portability Note:} These functions are all GNU extensions. You
|
|
can also use @code{scanf} or its relatives, which have the @samp{'} flag
|
|
for parsing numeric input according to the current locale
|
|
(@pxref{Numeric Input Conversions}). This feature is standard.
|
|
|
|
Here is a function which parses a string as a sequence of integers and
|
|
returns the sum of them:
|
|
|
|
@smallexample
|
|
int
|
|
sum_ints_from_string (char *string)
|
|
@{
|
|
int sum = 0;
|
|
|
|
while (1) @{
|
|
char *tail;
|
|
int next;
|
|
|
|
/* @r{Skip whitespace by hand, to detect the end.} */
|
|
while (isspace (*string)) string++;
|
|
if (*string == 0)
|
|
break;
|
|
|
|
/* @r{There is more nonwhitespace,} */
|
|
/* @r{so it ought to be another number.} */
|
|
errno = 0;
|
|
/* @r{Parse it.} */
|
|
next = strtol (string, &tail, 0);
|
|
/* @r{Add it in, if not overflow.} */
|
|
if (errno)
|
|
printf ("Overflow\n");
|
|
else
|
|
sum += next;
|
|
/* @r{Advance past it.} */
|
|
string = tail;
|
|
@}
|
|
|
|
return sum;
|
|
@}
|
|
@end smallexample
|
|
|
|
@node Parsing of Floats
|
|
@subsection Parsing of Floats
|
|
|
|
@pindex stdlib.h
|
|
These functions are declared in @file{stdlib.h}.
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftypefun double strtod (const char *@var{string}, char **@var{tailptr})
|
|
The @code{strtod} (``string-to-double'') function converts the initial
|
|
part of @var{string} to a floating-point number, which is returned as a
|
|
value of type @code{double}.
|
|
|
|
This function attempts to decompose @var{string} as follows:
|
|
|
|
@itemize @bullet
|
|
@item
|
|
A (possibly empty) sequence of whitespace characters. Which characters
|
|
are whitespace is determined by the @code{isspace} function
|
|
(@pxref{Classification of Characters}). These are discarded.
|
|
|
|
@item
|
|
An optional plus or minus sign (@samp{+} or @samp{-}).
|
|
|
|
@item
|
|
A nonempty sequence of digits optionally containing a decimal-point
|
|
character---normally @samp{.}, but it depends on the locale
|
|
(@pxref{General Numeric}).
|
|
|
|
@item
|
|
An optional exponent part, consisting of a character @samp{e} or
|
|
@samp{E}, an optional sign, and a sequence of digits.
|
|
|
|
@item
|
|
Any remaining characters in the string. If @var{tailptr} is not a null
|
|
pointer, a pointer to this tail of the string is stored in
|
|
@code{*@var{tailptr}}.
|
|
@end itemize
|
|
|
|
If the string is empty, contains only whitespace, or does not contain an
|
|
initial substring that has the expected syntax for a floating-point
|
|
number, no conversion is performed. In this case, @code{strtod} returns
|
|
a value of zero and the value returned in @code{*@var{tailptr}} is the
|
|
value of @var{string}.
|
|
|
|
In a locale other than the standard @code{"C"} or @code{"POSIX"} locales,
|
|
this function may recognize additional locale-dependent syntax.
|
|
|
|
If the string has valid syntax for a floating-point number but the value
|
|
is outside the range of a @code{double}, @code{strtod} will signal
|
|
overflow or underflow as described in @ref{Math Error Reporting}.
|
|
|
|
@code{strtod} recognizes four special input strings. The strings
|
|
@code{"inf"} and @code{"infinity"} are converted to @math{@infinity{}},
|
|
or to the largest representable value if the floating-point format
|
|
doesn't support infinities. You can prepend a @code{"+"} or @code{"-"}
|
|
to specify the sign. Case is ignored when scanning these strings.
|
|
|
|
The strings @code{"nan"} and @code{"nan(@var{chars...})"} are converted
|
|
to NaN. Again, case is ignored. If @var{chars...} are provided, they
|
|
are used in some unspecified fashion to select a particular
|
|
representation of NaN (there can be several).
|
|
|
|
Since zero is a valid result as well as the value returned on error, you
|
|
should check for errors in the same way as for @code{strtol}, by
|
|
examining @var{errno} and @var{tailptr}.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment GNU
|
|
@deftypefun float strtof (const char *@var{string}, char **@var{tailptr})
|
|
@deftypefunx {long double} strtold (const char *@var{string}, char **@var{tailptr})
|
|
These functions are analogous to @code{strtod}, but return @code{float}
|
|
and @code{long double} values respectively. They report errors in the
|
|
same way as @code{strtod}. @code{strtof} can be substantially faster
|
|
than @code{strtod}, but has less precision; conversely, @code{strtold}
|
|
can be much slower but has more precision (on systems where @code{long
|
|
double} is a separate type).
|
|
|
|
These functions are GNU extensions.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment ISO
|
|
@deftypefun double atof (const char *@var{string})
|
|
This function is similar to the @code{strtod} function, except that it
|
|
need not detect overflow and underflow errors. The @code{atof} function
|
|
is provided mostly for compatibility with existing code; using
|
|
@code{strtod} is more robust.
|
|
@end deftypefun
|
|
|
|
The GNU C library also provides @samp{_l} versions of thse functions,
|
|
which take an additional argument, the locale to use in conversion.
|
|
@xref{Parsing of Integers}.
|
|
|
|
@node System V Number Conversion
|
|
@section Old-fashioned System V number-to-string functions
|
|
|
|
The old @w{System V} C library provided three functions to convert
|
|
numbers to strings, with unusual and hard-to-use semantics. The GNU C
|
|
library also provides these functions and some natural extensions.
|
|
|
|
These functions are only available in glibc and on systems descended
|
|
from AT&T Unix. Therefore, unless these functions do precisely what you
|
|
need, it is better to use @code{sprintf}, which is standard.
|
|
|
|
All these functions are defined in @file{stdlib.h}.
|
|
|
|
@comment stdlib.h
|
|
@comment SVID, Unix98
|
|
@deftypefun {char *} ecvt (double @var{value}, int @var{ndigit}, int *@var{decpt}, int *@var{neg})
|
|
The function @code{ecvt} converts the floating-point number @var{value}
|
|
to a string with at most @var{ndigit} decimal digits.
|
|
The returned string contains no decimal point or sign. The first
|
|
digit of the string is non-zero (unless @var{value} is actually zero)
|
|
and the last digit is rounded to nearest. @var{decpt} is set to the
|
|
index in the string of the first digit after the decimal point.
|
|
@var{neg} is set to a nonzero value if @var{value} is negative, zero
|
|
otherwise.
|
|
|
|
The returned string is statically allocated and overwritten by each call
|
|
to @code{ecvt}.
|
|
|
|
If @var{value} is zero, it's implementation defined whether @var{decpt} is
|
|
@code{0} or @code{1}.
|
|
|
|
For example: @code{ecvt (12.3, 5, &decpt, &neg)} returns @code{"12300"}
|
|
and sets @var{decpt} to @code{2} and @var{neg} to @code{0}.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment SVID, Unix98
|
|
@deftypefun {char *} fcvt (double @var{value}, int @var{ndigit}, int @var{decpt}, int *@var{neg})
|
|
The function @code{fcvt} is like @code{ecvt}, but @var{ndigit} specifies
|
|
the number of digits after the decimal point. If @var{ndigit} is less
|
|
than zero, @var{value} is rounded to the @math{@var{ndigit}+1}'th place to the
|
|
left of the decimal point. For example, if @var{ndigit} is @code{-1},
|
|
@var{value} will be rounded to the nearest 10. If @var{ndigit} is
|
|
negative and larger than the number of digits to the left of the decimal
|
|
point in @var{value}, @var{value} will be rounded to one significant digit.
|
|
|
|
The returned string is statically allocated and overwritten by each call
|
|
to @code{fcvt}.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment SVID, Unix98
|
|
@deftypefun {char *} gcvt (double @var{value}, int @var{ndigit}, char *@var{buf})
|
|
@code{gcvt} is functionally equivalent to @samp{sprintf(buf, "%*g",
|
|
ndigit, value}. It is provided only for compatibility's sake. It
|
|
returns @var{buf}.
|
|
@end deftypefun
|
|
|
|
As extensions, the GNU C library provides versions of these three
|
|
functions that take @code{long double} arguments.
|
|
|
|
@comment stdlib.h
|
|
@comment GNU
|
|
@deftypefun {char *} qecvt (long double @var{value}, int @var{ndigit}, int *@var{decpt}, int *@var{neg})
|
|
This function is equivalent to @code{ecvt} except that it
|
|
takes a @code{long double} for the first parameter.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment GNU
|
|
@deftypefun {char *} qfcvt (long double @var{value}, int @var{ndigit}, int @var{decpt}, int *@var{neg})
|
|
This function is equivalent to @code{fcvt} except that it
|
|
takes a @code{long double} for the first parameter.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment GNU
|
|
@deftypefun {char *} qgcvt (long double @var{value}, int @var{ndigit}, char *@var{buf})
|
|
This function is equivalent to @code{gcvt} except that it
|
|
takes a @code{long double} for the first parameter.
|
|
@end deftypefun
|
|
|
|
|
|
@cindex gcvt_r
|
|
The @code{ecvt} and @code{fcvt} functions, and their @code{long double}
|
|
equivalents, all return a string located in a static buffer which is
|
|
overwritten by the next call to the function. The GNU C library
|
|
provides another set of extended functions which write the converted
|
|
string into a user-supplied buffer. These have the conventional
|
|
@code{_r} suffix.
|
|
|
|
@code{gcvt_r} is not necessary, because @code{gcvt} already uses a
|
|
user-supplied buffer.
|
|
|
|
@comment stdlib.h
|
|
@comment GNU
|
|
@deftypefun {char *} ecvt_r (double @var{value}, int @var{ndigit}, int *@var{decpt}, int *@var{neg}, char *@var{buf}, size_t @var{len})
|
|
The @code{ecvt_r} function is the same as @code{ecvt}, except
|
|
that it places its result into the user-specified buffer pointed to by
|
|
@var{buf}, with length @var{len}.
|
|
|
|
This function is a GNU extension.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment SVID, Unix98
|
|
@deftypefun {char *} fcvt_r (double @var{value}, int @var{ndigit}, int @var{decpt}, int *@var{neg}, char *@var{buf}, size_t @var{len})
|
|
The @code{fcvt_r} function is the same as @code{fcvt}, except
|
|
that it places its result into the user-specified buffer pointed to by
|
|
@var{buf}, with length @var{len}.
|
|
|
|
This function is a GNU extension.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment GNU
|
|
@deftypefun {char *} qecvt_r (long double @var{value}, int @var{ndigit}, int *@var{decpt}, int *@var{neg}, char *@var{buf}, size_t @var{len})
|
|
The @code{qecvt_r} function is the same as @code{qecvt}, except
|
|
that it places its result into the user-specified buffer pointed to by
|
|
@var{buf}, with length @var{len}.
|
|
|
|
This function is a GNU extension.
|
|
@end deftypefun
|
|
|
|
@comment stdlib.h
|
|
@comment GNU
|
|
@deftypefun {char *} qfcvt_r (long double @var{value}, int @var{ndigit}, int @var{decpt}, int *@var{neg}, char *@var{buf}, size_t @var{len})
|
|
The @code{qfcvt_r} function is the same as @code{qfcvt}, except
|
|
that it places its result into the user-specified buffer pointed to by
|
|
@var{buf}, with length @var{len}.
|
|
|
|
This function is a GNU extension.
|
|
@end deftypefun
|