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1263 lines
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1263 lines
36 KiB
Plaintext
@c -*-texinfo-*-
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@c This is part of the GNU Emacs Lisp Reference Manual.
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@c Copyright (C) 1990-1995, 1998-1999, 2001-2017 Free Software
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@c Foundation, Inc.
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@c See the file elisp.texi for copying conditions.
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@node Numbers
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@chapter Numbers
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@cindex integers
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@cindex numbers
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GNU Emacs supports two numeric data types: @dfn{integers} and
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@dfn{floating-point numbers}. Integers are whole numbers such as
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@minus{}3, 0, 7, 13, and 511. Floating-point numbers are numbers with
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fractional parts, such as @minus{}4.5, 0.0, and 2.71828. They can
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also be expressed in exponential notation: @samp{1.5e2} is the same as
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@samp{150.0}; here, @samp{e2} stands for ten to the second power, and
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that is multiplied by 1.5. Integer computations are exact, though
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they may overflow. Floating-point computations often involve rounding
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errors, as the numbers have a fixed amount of precision.
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@menu
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* Integer Basics:: Representation and range of integers.
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* Float Basics:: Representation and range of floating point.
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* Predicates on Numbers:: Testing for numbers.
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* Comparison of Numbers:: Equality and inequality predicates.
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* Numeric Conversions:: Converting float to integer and vice versa.
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* Arithmetic Operations:: How to add, subtract, multiply and divide.
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* Rounding Operations:: Explicitly rounding floating-point numbers.
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* Bitwise Operations:: Logical and, or, not, shifting.
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* Math Functions:: Trig, exponential and logarithmic functions.
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* Random Numbers:: Obtaining random integers, predictable or not.
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@end menu
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@node Integer Basics
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@section Integer Basics
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The range of values for an integer depends on the machine. The
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minimum range is @minus{}536,870,912 to 536,870,911 (30 bits; i.e.,
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@ifnottex
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@minus{}2**29
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@end ifnottex
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@tex
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@math{-2^{29}}
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@end tex
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to
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@ifnottex
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2**29 @minus{} 1),
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@end ifnottex
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@tex
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@math{2^{29}-1}),
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@end tex
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but many machines provide a wider range. Many examples in this
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chapter assume the minimum integer width of 30 bits.
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@cindex overflow
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The Lisp reader reads an integer as a sequence of digits with optional
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initial sign and optional final period. An integer that is out of the
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Emacs range is treated as a floating-point number.
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@example
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1 ; @r{The integer 1.}
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1. ; @r{The integer 1.}
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+1 ; @r{Also the integer 1.}
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-1 ; @r{The integer @minus{}1.}
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9000000000000000000
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; @r{The floating-point number 9e18.}
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0 ; @r{The integer 0.}
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-0 ; @r{The integer 0.}
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@end example
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@cindex integers in specific radix
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@cindex radix for reading an integer
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@cindex base for reading an integer
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@cindex hex numbers
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@cindex octal numbers
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@cindex reading numbers in hex, octal, and binary
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The syntax for integers in bases other than 10 uses @samp{#}
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followed by a letter that specifies the radix: @samp{b} for binary,
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@samp{o} for octal, @samp{x} for hex, or @samp{@var{radix}r} to
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specify radix @var{radix}. Case is not significant for the letter
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that specifies the radix. Thus, @samp{#b@var{integer}} reads
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@var{integer} in binary, and @samp{#@var{radix}r@var{integer}} reads
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@var{integer} in radix @var{radix}. Allowed values of @var{radix} run
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from 2 to 36. For example:
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@example
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#b101100 @result{} 44
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#o54 @result{} 44
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#x2c @result{} 44
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#24r1k @result{} 44
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@end example
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To understand how various functions work on integers, especially the
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bitwise operators (@pxref{Bitwise Operations}), it is often helpful to
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view the numbers in their binary form.
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In 30-bit binary, the decimal integer 5 looks like this:
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@example
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0000...000101 (30 bits total)
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@end example
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@noindent
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(The @samp{...} stands for enough bits to fill out a 30-bit word; in
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this case, @samp{...} stands for twenty 0 bits. Later examples also
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use the @samp{...} notation to make binary integers easier to read.)
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The integer @minus{}1 looks like this:
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@example
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1111...111111 (30 bits total)
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@end example
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@noindent
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@cindex two's complement
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@minus{}1 is represented as 30 ones. (This is called @dfn{two's
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complement} notation.)
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Subtracting 4 from @minus{}1 returns the negative integer @minus{}5.
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In binary, the decimal integer 4 is 100. Consequently,
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@minus{}5 looks like this:
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@example
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1111...111011 (30 bits total)
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@end example
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In this implementation, the largest 30-bit binary integer is
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536,870,911 in decimal. In binary, it looks like this:
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@example
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0111...111111 (30 bits total)
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@end example
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Since the arithmetic functions do not check whether integers go
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outside their range, when you add 1 to 536,870,911, the value is the
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negative integer @minus{}536,870,912:
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@example
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(+ 1 536870911)
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@result{} -536870912
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@result{} 1000...000000 (30 bits total)
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@end example
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Many of the functions described in this chapter accept markers for
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arguments in place of numbers. (@xref{Markers}.) Since the actual
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arguments to such functions may be either numbers or markers, we often
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give these arguments the name @var{number-or-marker}. When the argument
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value is a marker, its position value is used and its buffer is ignored.
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@cindex largest Lisp integer
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@cindex maximum Lisp integer
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@defvar most-positive-fixnum
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The value of this variable is the largest integer that Emacs Lisp can
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handle. Typical values are
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@ifnottex
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2**29 @minus{} 1
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@end ifnottex
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@tex
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@math{2^{29}-1}
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@end tex
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on 32-bit and
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@ifnottex
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2**61 @minus{} 1
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@end ifnottex
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@tex
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@math{2^{61}-1}
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@end tex
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on 64-bit platforms.
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@end defvar
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@cindex smallest Lisp integer
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@cindex minimum Lisp integer
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@defvar most-negative-fixnum
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The value of this variable is the smallest integer that Emacs Lisp can
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handle. It is negative. Typical values are
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@ifnottex
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@minus{}2**29
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@end ifnottex
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@tex
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@math{-2^{29}}
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@end tex
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on 32-bit and
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@ifnottex
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@minus{}2**61
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@end ifnottex
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@tex
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@math{-2^{61}}
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@end tex
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on 64-bit platforms.
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@end defvar
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In Emacs Lisp, text characters are represented by integers. Any
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integer between zero and the value of @code{(max-char)}, inclusive, is
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considered to be valid as a character. @xref{Character Codes}.
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@node Float Basics
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@section Floating-Point Basics
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@cindex @acronym{IEEE} floating point
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Floating-point numbers are useful for representing numbers that are
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not integral. The range of floating-point numbers is
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the same as the range of the C data type @code{double} on the machine
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you are using. On all computers currently supported by Emacs, this is
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double-precision @acronym{IEEE} floating point.
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The read syntax for floating-point numbers requires either a decimal
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point, an exponent, or both. Optional signs (@samp{+} or @samp{-})
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precede the number and its exponent. For example, @samp{1500.0},
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@samp{+15e2}, @samp{15.0e+2}, @samp{+1500000e-3}, and @samp{.15e4} are
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five ways of writing a floating-point number whose value is 1500.
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They are all equivalent. Like Common Lisp, Emacs Lisp requires at
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least one digit after any decimal point in a floating-point number;
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@samp{1500.} is an integer, not a floating-point number.
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Emacs Lisp treats @code{-0.0} as numerically equal to ordinary zero
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with respect to @code{equal} and @code{=}. This follows the
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@acronym{IEEE} floating-point standard, which says @code{-0.0} and
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@code{0.0} are numerically equal even though other operations can
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distinguish them.
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@cindex positive infinity
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@cindex negative infinity
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@cindex infinity
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@cindex NaN
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The @acronym{IEEE} floating-point standard supports positive
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infinity and negative infinity as floating-point values. It also
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provides for a class of values called NaN, or ``not a number'';
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numerical functions return such values in cases where there is no
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correct answer. For example, @code{(/ 0.0 0.0)} returns a NaN@.
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Although NaN values carry a sign, for practical purposes there is no other
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significant difference between different NaN values in Emacs Lisp.
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Here are read syntaxes for these special floating-point values:
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@table @asis
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@item infinity
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@samp{1.0e+INF} and @samp{-1.0e+INF}
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@item not-a-number
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@samp{0.0e+NaN} and @samp{-0.0e+NaN}
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@end table
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The following functions are specialized for handling floating-point
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numbers:
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@defun isnan x
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This predicate returns @code{t} if its floating-point argument is a NaN,
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@code{nil} otherwise.
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@end defun
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@defun frexp x
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This function returns a cons cell @code{(@var{s} . @var{e})},
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where @var{s} and @var{e} are respectively the significand and
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exponent of the floating-point number @var{x}.
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If @var{x} is finite, then @var{s} is a floating-point number between 0.5
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(inclusive) and 1.0 (exclusive), @var{e} is an integer, and
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@ifnottex
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@var{x} = @var{s} * 2**@var{e}.
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@end ifnottex
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@tex
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@math{x = s 2^e}.
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@end tex
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If @var{x} is zero or infinity, then @var{s} is the same as @var{x}.
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If @var{x} is a NaN, then @var{s} is also a NaN@.
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If @var{x} is zero, then @var{e} is 0.
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@end defun
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@defun ldexp s e
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Given a numeric significand @var{s} and an integer exponent @var{e},
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this function returns the floating point number
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@ifnottex
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@var{s} * 2**@var{e}.
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@end ifnottex
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@tex
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@math{s 2^e}.
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@end tex
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@end defun
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@defun copysign x1 x2
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This function copies the sign of @var{x2} to the value of @var{x1},
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and returns the result. @var{x1} and @var{x2} must be floating point.
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@end defun
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@defun logb x
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This function returns the binary exponent of @var{x}. More
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precisely, the value is the logarithm base 2 of @math{|x|}, rounded
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down to an integer.
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@example
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(logb 10)
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@result{} 3
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(logb 10.0e20)
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@result{} 69
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@end example
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@end defun
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@node Predicates on Numbers
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@section Type Predicates for Numbers
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@cindex predicates for numbers
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The functions in this section test for numbers, or for a specific
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type of number. The functions @code{integerp} and @code{floatp} can
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take any type of Lisp object as argument (they would not be of much
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use otherwise), but the @code{zerop} predicate requires a number as
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its argument. See also @code{integer-or-marker-p} and
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@code{number-or-marker-p}, in @ref{Predicates on Markers}.
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@defun floatp object
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This predicate tests whether its argument is floating point
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and returns @code{t} if so, @code{nil} otherwise.
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@end defun
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@defun integerp object
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This predicate tests whether its argument is an integer, and returns
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@code{t} if so, @code{nil} otherwise.
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@end defun
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@defun numberp object
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This predicate tests whether its argument is a number (either integer or
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floating point), and returns @code{t} if so, @code{nil} otherwise.
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@end defun
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@defun natnump object
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@cindex natural numbers
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This predicate (whose name comes from the phrase ``natural number'')
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tests to see whether its argument is a nonnegative integer, and
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returns @code{t} if so, @code{nil} otherwise. 0 is considered
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non-negative.
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@findex wholenump
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@code{wholenump} is a synonym for @code{natnump}.
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@end defun
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@defun zerop number
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This predicate tests whether its argument is zero, and returns @code{t}
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if so, @code{nil} otherwise. The argument must be a number.
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@code{(zerop x)} is equivalent to @code{(= x 0)}.
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@end defun
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@node Comparison of Numbers
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@section Comparison of Numbers
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@cindex number comparison
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@cindex comparing numbers
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To test numbers for numerical equality, you should normally use
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@code{=}, not @code{eq}. There can be many distinct floating-point
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objects with the same numeric value. If you use @code{eq} to
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compare them, then you test whether two values are the same
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@emph{object}. By contrast, @code{=} compares only the numeric values
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of the objects.
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In Emacs Lisp, each integer is a unique Lisp object.
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Therefore, @code{eq} is equivalent to @code{=} where integers are
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concerned. It is sometimes convenient to use @code{eq} for comparing
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an unknown value with an integer, because @code{eq} does not report an
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error if the unknown value is not a number---it accepts arguments of
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any type. By contrast, @code{=} signals an error if the arguments are
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not numbers or markers. However, it is better programming practice to
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use @code{=} if you can, even for comparing integers.
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Sometimes it is useful to compare numbers with @code{equal}, which
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treats two numbers as equal if they have the same data type (both
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integers, or both floating point) and the same value. By contrast,
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@code{=} can treat an integer and a floating-point number as equal.
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@xref{Equality Predicates}.
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There is another wrinkle: because floating-point arithmetic is not
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exact, it is often a bad idea to check for equality of floating-point
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values. Usually it is better to test for approximate equality.
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Here's a function to do this:
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@example
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(defvar fuzz-factor 1.0e-6)
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(defun approx-equal (x y)
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(or (= x y)
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(< (/ (abs (- x y))
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(max (abs x) (abs y)))
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fuzz-factor)))
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@end example
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@cindex CL note---integers vrs @code{eq}
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@quotation
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@b{Common Lisp note:} Comparing numbers in Common Lisp always requires
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@code{=} because Common Lisp implements multi-word integers, and two
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distinct integer objects can have the same numeric value. Emacs Lisp
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can have just one integer object for any given value because it has a
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limited range of integers.
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@end quotation
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@defun = number-or-marker &rest number-or-markers
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This function tests whether all its arguments are numerically equal,
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and returns @code{t} if so, @code{nil} otherwise.
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@end defun
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@defun eql value1 value2
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This function acts like @code{eq} except when both arguments are
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numbers. It compares numbers by type and numeric value, so that
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@code{(eql 1.0 1)} returns @code{nil}, but @code{(eql 1.0 1.0)} and
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@code{(eql 1 1)} both return @code{t}.
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@end defun
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@defun /= number-or-marker1 number-or-marker2
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This function tests whether its arguments are numerically equal, and
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returns @code{t} if they are not, and @code{nil} if they are.
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@end defun
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@defun < number-or-marker &rest number-or-markers
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This function tests whether each argument is strictly less than the
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following argument. It returns @code{t} if so, @code{nil} otherwise.
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@end defun
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@defun <= number-or-marker &rest number-or-markers
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This function tests whether each argument is less than or equal to
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the following argument. It returns @code{t} if so, @code{nil} otherwise.
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@end defun
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@defun > number-or-marker &rest number-or-markers
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This function tests whether each argument is strictly greater than
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the following argument. It returns @code{t} if so, @code{nil} otherwise.
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@end defun
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@defun >= number-or-marker &rest number-or-markers
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This function tests whether each argument is greater than or equal to
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the following argument. It returns @code{t} if so, @code{nil} otherwise.
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@end defun
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@defun max number-or-marker &rest numbers-or-markers
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This function returns the largest of its arguments.
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If any of the arguments is floating point, the value is returned
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as floating point, even if it was given as an integer.
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@example
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(max 20)
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@result{} 20
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(max 1 2.5)
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@result{} 2.5
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(max 1 3 2.5)
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@result{} 3.0
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@end example
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@end defun
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@defun min number-or-marker &rest numbers-or-markers
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This function returns the smallest of its arguments.
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If any of the arguments is floating point, the value is returned
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as floating point, even if it was given as an integer.
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@example
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(min -4 1)
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@result{} -4
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@end example
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@end defun
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@defun abs number
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This function returns the absolute value of @var{number}.
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@end defun
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@node Numeric Conversions
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@section Numeric Conversions
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@cindex rounding in conversions
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@cindex number conversions
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@cindex converting numbers
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To convert an integer to floating point, use the function @code{float}.
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@defun float number
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This returns @var{number} converted to floating point.
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If @var{number} is already floating point, @code{float} returns
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it unchanged.
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@end defun
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There are four functions to convert floating-point numbers to
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integers; they differ in how they round. All accept an argument
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@var{number} and an optional argument @var{divisor}. Both arguments
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may be integers or floating-point numbers. @var{divisor} may also be
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@code{nil}. If @var{divisor} is @code{nil} or omitted, these
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functions convert @var{number} to an integer, or return it unchanged
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if it already is an integer. If @var{divisor} is non-@code{nil}, they
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divide @var{number} by @var{divisor} and convert the result to an
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integer. If @var{divisor} is zero (whether integer or
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floating point), Emacs signals an @code{arith-error} error.
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@defun truncate number &optional divisor
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This returns @var{number}, converted to an integer by rounding towards
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zero.
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@example
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|
(truncate 1.2)
|
|
@result{} 1
|
|
(truncate 1.7)
|
|
@result{} 1
|
|
(truncate -1.2)
|
|
@result{} -1
|
|
(truncate -1.7)
|
|
@result{} -1
|
|
@end example
|
|
@end defun
|
|
|
|
@defun floor number &optional divisor
|
|
This returns @var{number}, converted to an integer by rounding downward
|
|
(towards negative infinity).
|
|
|
|
If @var{divisor} is specified, this uses the kind of division
|
|
operation that corresponds to @code{mod}, rounding downward.
|
|
|
|
@example
|
|
(floor 1.2)
|
|
@result{} 1
|
|
(floor 1.7)
|
|
@result{} 1
|
|
(floor -1.2)
|
|
@result{} -2
|
|
(floor -1.7)
|
|
@result{} -2
|
|
(floor 5.99 3)
|
|
@result{} 1
|
|
@end example
|
|
@end defun
|
|
|
|
@defun ceiling number &optional divisor
|
|
This returns @var{number}, converted to an integer by rounding upward
|
|
(towards positive infinity).
|
|
|
|
@example
|
|
(ceiling 1.2)
|
|
@result{} 2
|
|
(ceiling 1.7)
|
|
@result{} 2
|
|
(ceiling -1.2)
|
|
@result{} -1
|
|
(ceiling -1.7)
|
|
@result{} -1
|
|
@end example
|
|
@end defun
|
|
|
|
@defun round number &optional divisor
|
|
This returns @var{number}, converted to an integer by rounding towards the
|
|
nearest integer. Rounding a value equidistant between two integers
|
|
returns the even integer.
|
|
|
|
@example
|
|
(round 1.2)
|
|
@result{} 1
|
|
(round 1.7)
|
|
@result{} 2
|
|
(round -1.2)
|
|
@result{} -1
|
|
(round -1.7)
|
|
@result{} -2
|
|
@end example
|
|
@end defun
|
|
|
|
@node Arithmetic Operations
|
|
@section Arithmetic Operations
|
|
@cindex arithmetic operations
|
|
|
|
Emacs Lisp provides the traditional four arithmetic operations
|
|
(addition, subtraction, multiplication, and division), as well as
|
|
remainder and modulus functions, and functions to add or subtract 1.
|
|
Except for @code{%}, each of these functions accepts both integer and
|
|
floating-point arguments, and returns a floating-point number if any
|
|
argument is floating point.
|
|
|
|
Emacs Lisp arithmetic functions do not check for integer overflow.
|
|
Thus @code{(1+ 536870911)} may evaluate to
|
|
@minus{}536870912, depending on your hardware.
|
|
|
|
@defun 1+ number-or-marker
|
|
This function returns @var{number-or-marker} plus 1.
|
|
For example,
|
|
|
|
@example
|
|
(setq foo 4)
|
|
@result{} 4
|
|
(1+ foo)
|
|
@result{} 5
|
|
@end example
|
|
|
|
This function is not analogous to the C operator @code{++}---it does not
|
|
increment a variable. It just computes a sum. Thus, if we continue,
|
|
|
|
@example
|
|
foo
|
|
@result{} 4
|
|
@end example
|
|
|
|
If you want to increment the variable, you must use @code{setq},
|
|
like this:
|
|
|
|
@example
|
|
(setq foo (1+ foo))
|
|
@result{} 5
|
|
@end example
|
|
@end defun
|
|
|
|
@defun 1- number-or-marker
|
|
This function returns @var{number-or-marker} minus 1.
|
|
@end defun
|
|
|
|
@defun + &rest numbers-or-markers
|
|
This function adds its arguments together. When given no arguments,
|
|
@code{+} returns 0.
|
|
|
|
@example
|
|
(+)
|
|
@result{} 0
|
|
(+ 1)
|
|
@result{} 1
|
|
(+ 1 2 3 4)
|
|
@result{} 10
|
|
@end example
|
|
@end defun
|
|
|
|
@defun - &optional number-or-marker &rest more-numbers-or-markers
|
|
The @code{-} function serves two purposes: negation and subtraction.
|
|
When @code{-} has a single argument, the value is the negative of the
|
|
argument. When there are multiple arguments, @code{-} subtracts each of
|
|
the @var{more-numbers-or-markers} from @var{number-or-marker},
|
|
cumulatively. If there are no arguments, the result is 0.
|
|
|
|
@example
|
|
(- 10 1 2 3 4)
|
|
@result{} 0
|
|
(- 10)
|
|
@result{} -10
|
|
(-)
|
|
@result{} 0
|
|
@end example
|
|
@end defun
|
|
|
|
@defun * &rest numbers-or-markers
|
|
This function multiplies its arguments together, and returns the
|
|
product. When given no arguments, @code{*} returns 1.
|
|
|
|
@example
|
|
(*)
|
|
@result{} 1
|
|
(* 1)
|
|
@result{} 1
|
|
(* 1 2 3 4)
|
|
@result{} 24
|
|
@end example
|
|
@end defun
|
|
|
|
@defun / number &rest divisors
|
|
With one or more @var{divisors}, this function divides @var{number}
|
|
by each divisor in @var{divisors} in turn, and returns the quotient.
|
|
With no @var{divisors}, this function returns 1/@var{number}, i.e.,
|
|
the multiplicative inverse of @var{number}. Each argument may be a
|
|
number or a marker.
|
|
|
|
If all the arguments are integers, the result is an integer, obtained
|
|
by rounding the quotient towards zero after each division.
|
|
|
|
@example
|
|
@group
|
|
(/ 6 2)
|
|
@result{} 3
|
|
@end group
|
|
@group
|
|
(/ 5 2)
|
|
@result{} 2
|
|
@end group
|
|
@group
|
|
(/ 5.0 2)
|
|
@result{} 2.5
|
|
@end group
|
|
@group
|
|
(/ 5 2.0)
|
|
@result{} 2.5
|
|
@end group
|
|
@group
|
|
(/ 5.0 2.0)
|
|
@result{} 2.5
|
|
@end group
|
|
@group
|
|
(/ 4.0)
|
|
@result{} 0.25
|
|
@end group
|
|
@group
|
|
(/ 4)
|
|
@result{} 0
|
|
@end group
|
|
@group
|
|
(/ 25 3 2)
|
|
@result{} 4
|
|
@end group
|
|
@group
|
|
(/ -17 6)
|
|
@result{} -2
|
|
@end group
|
|
@end example
|
|
|
|
@cindex @code{arith-error} in division
|
|
If you divide an integer by the integer 0, Emacs signals an
|
|
@code{arith-error} error (@pxref{Errors}). Floating-point division of
|
|
a nonzero number by zero yields either positive or negative infinity
|
|
(@pxref{Float Basics}).
|
|
@end defun
|
|
|
|
@defun % dividend divisor
|
|
@cindex remainder
|
|
This function returns the integer remainder after division of @var{dividend}
|
|
by @var{divisor}. The arguments must be integers or markers.
|
|
|
|
For any two integers @var{dividend} and @var{divisor},
|
|
|
|
@example
|
|
@group
|
|
(+ (% @var{dividend} @var{divisor})
|
|
(* (/ @var{dividend} @var{divisor}) @var{divisor}))
|
|
@end group
|
|
@end example
|
|
|
|
@noindent
|
|
always equals @var{dividend} if @var{divisor} is nonzero.
|
|
|
|
@example
|
|
(% 9 4)
|
|
@result{} 1
|
|
(% -9 4)
|
|
@result{} -1
|
|
(% 9 -4)
|
|
@result{} 1
|
|
(% -9 -4)
|
|
@result{} -1
|
|
@end example
|
|
@end defun
|
|
|
|
@defun mod dividend divisor
|
|
@cindex modulus
|
|
This function returns the value of @var{dividend} modulo @var{divisor};
|
|
in other words, the remainder after division of @var{dividend}
|
|
by @var{divisor}, but with the same sign as @var{divisor}.
|
|
The arguments must be numbers or markers.
|
|
|
|
Unlike @code{%}, @code{mod} permits floating-point arguments; it
|
|
rounds the quotient downward (towards minus infinity) to an integer,
|
|
and uses that quotient to compute the remainder.
|
|
|
|
If @var{divisor} is zero, @code{mod} signals an @code{arith-error}
|
|
error if both arguments are integers, and returns a NaN otherwise.
|
|
|
|
@example
|
|
@group
|
|
(mod 9 4)
|
|
@result{} 1
|
|
@end group
|
|
@group
|
|
(mod -9 4)
|
|
@result{} 3
|
|
@end group
|
|
@group
|
|
(mod 9 -4)
|
|
@result{} -3
|
|
@end group
|
|
@group
|
|
(mod -9 -4)
|
|
@result{} -1
|
|
@end group
|
|
@group
|
|
(mod 5.5 2.5)
|
|
@result{} .5
|
|
@end group
|
|
@end example
|
|
|
|
For any two numbers @var{dividend} and @var{divisor},
|
|
|
|
@example
|
|
@group
|
|
(+ (mod @var{dividend} @var{divisor})
|
|
(* (floor @var{dividend} @var{divisor}) @var{divisor}))
|
|
@end group
|
|
@end example
|
|
|
|
@noindent
|
|
always equals @var{dividend}, subject to rounding error if either
|
|
argument is floating point and to an @code{arith-error} if @var{dividend} is an
|
|
integer and @var{divisor} is 0. For @code{floor}, see @ref{Numeric
|
|
Conversions}.
|
|
@end defun
|
|
|
|
@node Rounding Operations
|
|
@section Rounding Operations
|
|
@cindex rounding without conversion
|
|
|
|
The functions @code{ffloor}, @code{fceiling}, @code{fround}, and
|
|
@code{ftruncate} take a floating-point argument and return a floating-point
|
|
result whose value is a nearby integer. @code{ffloor} returns the
|
|
nearest integer below; @code{fceiling}, the nearest integer above;
|
|
@code{ftruncate}, the nearest integer in the direction towards zero;
|
|
@code{fround}, the nearest integer.
|
|
|
|
@defun ffloor float
|
|
This function rounds @var{float} to the next lower integral value, and
|
|
returns that value as a floating-point number.
|
|
@end defun
|
|
|
|
@defun fceiling float
|
|
This function rounds @var{float} to the next higher integral value, and
|
|
returns that value as a floating-point number.
|
|
@end defun
|
|
|
|
@defun ftruncate float
|
|
This function rounds @var{float} towards zero to an integral value, and
|
|
returns that value as a floating-point number.
|
|
@end defun
|
|
|
|
@defun fround float
|
|
This function rounds @var{float} to the nearest integral value,
|
|
and returns that value as a floating-point number.
|
|
Rounding a value equidistant between two integers returns the even integer.
|
|
@end defun
|
|
|
|
@node Bitwise Operations
|
|
@section Bitwise Operations on Integers
|
|
@cindex bitwise arithmetic
|
|
@cindex logical arithmetic
|
|
|
|
In a computer, an integer is represented as a binary number, a
|
|
sequence of @dfn{bits} (digits which are either zero or one). A bitwise
|
|
operation acts on the individual bits of such a sequence. For example,
|
|
@dfn{shifting} moves the whole sequence left or right one or more places,
|
|
reproducing the same pattern moved over.
|
|
|
|
The bitwise operations in Emacs Lisp apply only to integers.
|
|
|
|
@defun lsh integer1 count
|
|
@cindex logical shift
|
|
@code{lsh}, which is an abbreviation for @dfn{logical shift}, shifts the
|
|
bits in @var{integer1} to the left @var{count} places, or to the right
|
|
if @var{count} is negative, bringing zeros into the vacated bits. If
|
|
@var{count} is negative, @code{lsh} shifts zeros into the leftmost
|
|
(most-significant) bit, producing a positive result even if
|
|
@var{integer1} is negative. Contrast this with @code{ash}, below.
|
|
|
|
Here are two examples of @code{lsh}, shifting a pattern of bits one
|
|
place to the left. We show only the low-order eight bits of the binary
|
|
pattern; the rest are all zero.
|
|
|
|
@example
|
|
@group
|
|
(lsh 5 1)
|
|
@result{} 10
|
|
;; @r{Decimal 5 becomes decimal 10.}
|
|
00000101 @result{} 00001010
|
|
|
|
(lsh 7 1)
|
|
@result{} 14
|
|
;; @r{Decimal 7 becomes decimal 14.}
|
|
00000111 @result{} 00001110
|
|
@end group
|
|
@end example
|
|
|
|
@noindent
|
|
As the examples illustrate, shifting the pattern of bits one place to
|
|
the left produces a number that is twice the value of the previous
|
|
number.
|
|
|
|
Shifting a pattern of bits two places to the left produces results
|
|
like this (with 8-bit binary numbers):
|
|
|
|
@example
|
|
@group
|
|
(lsh 3 2)
|
|
@result{} 12
|
|
;; @r{Decimal 3 becomes decimal 12.}
|
|
00000011 @result{} 00001100
|
|
@end group
|
|
@end example
|
|
|
|
On the other hand, shifting one place to the right looks like this:
|
|
|
|
@example
|
|
@group
|
|
(lsh 6 -1)
|
|
@result{} 3
|
|
;; @r{Decimal 6 becomes decimal 3.}
|
|
00000110 @result{} 00000011
|
|
@end group
|
|
|
|
@group
|
|
(lsh 5 -1)
|
|
@result{} 2
|
|
;; @r{Decimal 5 becomes decimal 2.}
|
|
00000101 @result{} 00000010
|
|
@end group
|
|
@end example
|
|
|
|
@noindent
|
|
As the example illustrates, shifting one place to the right divides the
|
|
value of a positive integer by two, rounding downward.
|
|
|
|
The function @code{lsh}, like all Emacs Lisp arithmetic functions, does
|
|
not check for overflow, so shifting left can discard significant bits
|
|
and change the sign of the number. For example, left shifting
|
|
536,870,911 produces @minus{}2 in the 30-bit implementation:
|
|
|
|
@example
|
|
(lsh 536870911 1) ; @r{left shift}
|
|
@result{} -2
|
|
@end example
|
|
|
|
In binary, the argument looks like this:
|
|
|
|
@example
|
|
@group
|
|
;; @r{Decimal 536,870,911}
|
|
0111...111111 (30 bits total)
|
|
@end group
|
|
@end example
|
|
|
|
@noindent
|
|
which becomes the following when left shifted:
|
|
|
|
@example
|
|
@group
|
|
;; @r{Decimal @minus{}2}
|
|
1111...111110 (30 bits total)
|
|
@end group
|
|
@end example
|
|
@end defun
|
|
|
|
@defun ash integer1 count
|
|
@cindex arithmetic shift
|
|
@code{ash} (@dfn{arithmetic shift}) shifts the bits in @var{integer1}
|
|
to the left @var{count} places, or to the right if @var{count}
|
|
is negative.
|
|
|
|
@code{ash} gives the same results as @code{lsh} except when
|
|
@var{integer1} and @var{count} are both negative. In that case,
|
|
@code{ash} puts ones in the empty bit positions on the left, while
|
|
@code{lsh} puts zeros in those bit positions.
|
|
|
|
Thus, with @code{ash}, shifting the pattern of bits one place to the right
|
|
looks like this:
|
|
|
|
@example
|
|
@group
|
|
(ash -6 -1) @result{} -3
|
|
;; @r{Decimal @minus{}6 becomes decimal @minus{}3.}
|
|
1111...111010 (30 bits total)
|
|
@result{}
|
|
1111...111101 (30 bits total)
|
|
@end group
|
|
@end example
|
|
|
|
In contrast, shifting the pattern of bits one place to the right with
|
|
@code{lsh} looks like this:
|
|
|
|
@example
|
|
@group
|
|
(lsh -6 -1) @result{} 536870909
|
|
;; @r{Decimal @minus{}6 becomes decimal 536,870,909.}
|
|
1111...111010 (30 bits total)
|
|
@result{}
|
|
0111...111101 (30 bits total)
|
|
@end group
|
|
@end example
|
|
|
|
Here are other examples:
|
|
|
|
@c !!! Check if lined up in smallbook format! XDVI shows problem
|
|
@c with smallbook but not with regular book! --rjc 16mar92
|
|
@smallexample
|
|
@group
|
|
; @r{ 30-bit binary values}
|
|
|
|
(lsh 5 2) ; 5 = @r{0000...000101}
|
|
@result{} 20 ; = @r{0000...010100}
|
|
@end group
|
|
@group
|
|
(ash 5 2)
|
|
@result{} 20
|
|
(lsh -5 2) ; -5 = @r{1111...111011}
|
|
@result{} -20 ; = @r{1111...101100}
|
|
(ash -5 2)
|
|
@result{} -20
|
|
@end group
|
|
@group
|
|
(lsh 5 -2) ; 5 = @r{0000...000101}
|
|
@result{} 1 ; = @r{0000...000001}
|
|
@end group
|
|
@group
|
|
(ash 5 -2)
|
|
@result{} 1
|
|
@end group
|
|
@group
|
|
(lsh -5 -2) ; -5 = @r{1111...111011}
|
|
@result{} 268435454
|
|
; = @r{0011...111110}
|
|
@end group
|
|
@group
|
|
(ash -5 -2) ; -5 = @r{1111...111011}
|
|
@result{} -2 ; = @r{1111...111110}
|
|
@end group
|
|
@end smallexample
|
|
@end defun
|
|
|
|
@defun logand &rest ints-or-markers
|
|
This function returns the bitwise AND of the arguments: the @var{n}th
|
|
bit is 1 in the result if, and only if, the @var{n}th bit is 1 in all
|
|
the arguments.
|
|
|
|
For example, using 4-bit binary numbers, the bitwise AND of 13 and
|
|
12 is 12: 1101 combined with 1100 produces 1100.
|
|
In both the binary numbers, the leftmost two bits are both 1
|
|
so the leftmost two bits of the returned value are both 1.
|
|
However, for the rightmost two bits, each is 0 in at least one of
|
|
the arguments, so the rightmost two bits of the returned value are both 0.
|
|
|
|
@noindent
|
|
Therefore,
|
|
|
|
@example
|
|
@group
|
|
(logand 13 12)
|
|
@result{} 12
|
|
@end group
|
|
@end example
|
|
|
|
If @code{logand} is not passed any argument, it returns a value of
|
|
@minus{}1. This number is an identity element for @code{logand}
|
|
because its binary representation consists entirely of ones. If
|
|
@code{logand} is passed just one argument, it returns that argument.
|
|
|
|
@smallexample
|
|
@group
|
|
; @r{ 30-bit binary values}
|
|
|
|
(logand 14 13) ; 14 = @r{0000...001110}
|
|
; 13 = @r{0000...001101}
|
|
@result{} 12 ; 12 = @r{0000...001100}
|
|
@end group
|
|
|
|
@group
|
|
(logand 14 13 4) ; 14 = @r{0000...001110}
|
|
; 13 = @r{0000...001101}
|
|
; 4 = @r{0000...000100}
|
|
@result{} 4 ; 4 = @r{0000...000100}
|
|
@end group
|
|
|
|
@group
|
|
(logand)
|
|
@result{} -1 ; -1 = @r{1111...111111}
|
|
@end group
|
|
@end smallexample
|
|
@end defun
|
|
|
|
@defun logior &rest ints-or-markers
|
|
This function returns the bitwise inclusive OR of its arguments: the @var{n}th
|
|
bit is 1 in the result if, and only if, the @var{n}th bit is 1 in at
|
|
least one of the arguments. If there are no arguments, the result is 0,
|
|
which is an identity element for this operation. If @code{logior} is
|
|
passed just one argument, it returns that argument.
|
|
|
|
@smallexample
|
|
@group
|
|
; @r{ 30-bit binary values}
|
|
|
|
(logior 12 5) ; 12 = @r{0000...001100}
|
|
; 5 = @r{0000...000101}
|
|
@result{} 13 ; 13 = @r{0000...001101}
|
|
@end group
|
|
|
|
@group
|
|
(logior 12 5 7) ; 12 = @r{0000...001100}
|
|
; 5 = @r{0000...000101}
|
|
; 7 = @r{0000...000111}
|
|
@result{} 15 ; 15 = @r{0000...001111}
|
|
@end group
|
|
@end smallexample
|
|
@end defun
|
|
|
|
@defun logxor &rest ints-or-markers
|
|
This function returns the bitwise exclusive OR of its arguments: the
|
|
@var{n}th bit is 1 in the result if, and only if, the @var{n}th bit is
|
|
1 in an odd number of the arguments. If there are no arguments, the
|
|
result is 0, which is an identity element for this operation. If
|
|
@code{logxor} is passed just one argument, it returns that argument.
|
|
|
|
@smallexample
|
|
@group
|
|
; @r{ 30-bit binary values}
|
|
|
|
(logxor 12 5) ; 12 = @r{0000...001100}
|
|
; 5 = @r{0000...000101}
|
|
@result{} 9 ; 9 = @r{0000...001001}
|
|
@end group
|
|
|
|
@group
|
|
(logxor 12 5 7) ; 12 = @r{0000...001100}
|
|
; 5 = @r{0000...000101}
|
|
; 7 = @r{0000...000111}
|
|
@result{} 14 ; 14 = @r{0000...001110}
|
|
@end group
|
|
@end smallexample
|
|
@end defun
|
|
|
|
@defun lognot integer
|
|
This function returns the bitwise complement of its argument: the @var{n}th
|
|
bit is one in the result if, and only if, the @var{n}th bit is zero in
|
|
@var{integer}, and vice-versa.
|
|
|
|
@example
|
|
(lognot 5)
|
|
@result{} -6
|
|
;; 5 = @r{0000...000101} (30 bits total)
|
|
;; @r{becomes}
|
|
;; -6 = @r{1111...111010} (30 bits total)
|
|
@end example
|
|
@end defun
|
|
|
|
@node Math Functions
|
|
@section Standard Mathematical Functions
|
|
@cindex transcendental functions
|
|
@cindex mathematical functions
|
|
@cindex floating-point functions
|
|
|
|
These mathematical functions allow integers as well as floating-point
|
|
numbers as arguments.
|
|
|
|
@defun sin arg
|
|
@defunx cos arg
|
|
@defunx tan arg
|
|
These are the basic trigonometric functions, with argument @var{arg}
|
|
measured in radians.
|
|
@end defun
|
|
|
|
@defun asin arg
|
|
The value of @code{(asin @var{arg})} is a number between
|
|
@ifnottex
|
|
@minus{}pi/2
|
|
@end ifnottex
|
|
@tex
|
|
@math{-\pi/2}
|
|
@end tex
|
|
and
|
|
@ifnottex
|
|
pi/2
|
|
@end ifnottex
|
|
@tex
|
|
@math{\pi/2}
|
|
@end tex
|
|
(inclusive) whose sine is @var{arg}. If @var{arg} is out of range
|
|
(outside [@minus{}1, 1]), @code{asin} returns a NaN.
|
|
@end defun
|
|
|
|
@defun acos arg
|
|
The value of @code{(acos @var{arg})} is a number between 0 and
|
|
@ifnottex
|
|
pi
|
|
@end ifnottex
|
|
@tex
|
|
@math{\pi}
|
|
@end tex
|
|
(inclusive) whose cosine is @var{arg}. If @var{arg} is out of range
|
|
(outside [@minus{}1, 1]), @code{acos} returns a NaN.
|
|
@end defun
|
|
|
|
@defun atan y &optional x
|
|
The value of @code{(atan @var{y})} is a number between
|
|
@ifnottex
|
|
@minus{}pi/2
|
|
@end ifnottex
|
|
@tex
|
|
@math{-\pi/2}
|
|
@end tex
|
|
and
|
|
@ifnottex
|
|
pi/2
|
|
@end ifnottex
|
|
@tex
|
|
@math{\pi/2}
|
|
@end tex
|
|
(exclusive) whose tangent is @var{y}. If the optional second
|
|
argument @var{x} is given, the value of @code{(atan y x)} is the
|
|
angle in radians between the vector @code{[@var{x}, @var{y}]} and the
|
|
@code{X} axis.
|
|
@end defun
|
|
|
|
@defun exp arg
|
|
This is the exponential function; it returns @math{e} to the power
|
|
@var{arg}.
|
|
@end defun
|
|
|
|
@defun log arg &optional base
|
|
This function returns the logarithm of @var{arg}, with base
|
|
@var{base}. If you don't specify @var{base}, the natural base
|
|
@math{e} is used. If @var{arg} or @var{base} is negative, @code{log}
|
|
returns a NaN.
|
|
@end defun
|
|
|
|
@defun expt x y
|
|
This function returns @var{x} raised to power @var{y}. If both
|
|
arguments are integers and @var{y} is positive, the result is an
|
|
integer; in this case, overflow causes truncation, so watch out.
|
|
If @var{x} is a finite negative number and @var{y} is a finite
|
|
non-integer, @code{expt} returns a NaN.
|
|
@end defun
|
|
|
|
@defun sqrt arg
|
|
This returns the square root of @var{arg}. If @var{arg} is finite
|
|
and less than zero, @code{sqrt} returns a NaN.
|
|
@end defun
|
|
|
|
In addition, Emacs defines the following common mathematical
|
|
constants:
|
|
|
|
@defvar float-e
|
|
The mathematical constant @math{e} (2.71828@dots{}).
|
|
@end defvar
|
|
|
|
@defvar float-pi
|
|
The mathematical constant @math{pi} (3.14159@dots{}).
|
|
@end defvar
|
|
|
|
@node Random Numbers
|
|
@section Random Numbers
|
|
@cindex random numbers
|
|
|
|
A deterministic computer program cannot generate true random
|
|
numbers. For most purposes, @dfn{pseudo-random numbers} suffice. A
|
|
series of pseudo-random numbers is generated in a deterministic
|
|
fashion. The numbers are not truly random, but they have certain
|
|
properties that mimic a random series. For example, all possible
|
|
values occur equally often in a pseudo-random series.
|
|
|
|
@cindex seed, for random number generation
|
|
Pseudo-random numbers are generated from a @dfn{seed value}. Starting from
|
|
any given seed, the @code{random} function always generates the same
|
|
sequence of numbers. By default, Emacs initializes the random seed at
|
|
startup, in such a way that the sequence of values of @code{random}
|
|
(with overwhelming likelihood) differs in each Emacs run.
|
|
|
|
Sometimes you want the random number sequence to be repeatable. For
|
|
example, when debugging a program whose behavior depends on the random
|
|
number sequence, it is helpful to get the same behavior in each
|
|
program run. To make the sequence repeat, execute @code{(random "")}.
|
|
This sets the seed to a constant value for your particular Emacs
|
|
executable (though it may differ for other Emacs builds). You can use
|
|
other strings to choose various seed values.
|
|
|
|
@defun random &optional limit
|
|
This function returns a pseudo-random integer. Repeated calls return a
|
|
series of pseudo-random integers.
|
|
|
|
If @var{limit} is a positive integer, the value is chosen to be
|
|
nonnegative and less than @var{limit}. Otherwise, the value might be
|
|
any integer representable in Lisp, i.e., an integer between
|
|
@code{most-negative-fixnum} and @code{most-positive-fixnum}
|
|
(@pxref{Integer Basics}).
|
|
|
|
If @var{limit} is @code{t}, it means to choose a new seed as if Emacs
|
|
were restarting, typically from the system entropy. On systems
|
|
lacking entropy pools, choose the seed from less-random volatile data
|
|
such as the current time.
|
|
|
|
If @var{limit} is a string, it means to choose a new seed based on the
|
|
string's contents.
|
|
|
|
@end defun
|