wcalc(1) [debian man page]

wcalc(1)						      General Commands Manual							  wcalc(1)

NAME

       wcalc - a natural-expression command-line calculator

SYNOPSIS

       wcalc [ options ] [ expression ... ]

DESCRIPTION

       wcalc is a command-line calculator designed to accept all valid mathematical expressions. It supports all standard mathematical operations,
       parenthesis, brackets, trigonometric functions, hyperbolic trig functions, logs, and boolean operators.

       wcalc accepts input in a variety of manners. I it will evaluate If no mathematical expression is given at the commandline, it will evaluate
       the  contents  of  an  environment variable named wcalc_input if one exists. If that variable is not set, wcalc will try to read input from
       standard input (i.e. piped input). If there is no input from that, wcalc enters "interactive" mode. Interactive mode has more features.

       Within wcalc, detailed information about commands, functions, symbols, and variables can  be  obtained  by  executing:  explain  thing-to-
       explain

   OPTIONS
       -H or --help
	   Prints a help usage message to standard output, then exits.

       -E  Specifies that numerical output should be in scientific notation.

       -EE Specifies that numerical output should NOT be in scientific notation.

       -PXXX
	   Sets  the  precision to be XXX. This setting only affects output, not internal representations. A setting of -1 means formats output in
	   whatever precision seems appropriate.
	   Precision is set to autoadjust (-1) by default.
	   Example: wcalc -P6

       -v or --version
	   Prints the version number and exits.

       -d or -dec or --decimal
	   Results are printed in decimal (base 10). This option is the default, and does not have a default prefix to indicate that  numbers  are
	   in base 10.

       -h or -hex or --hexadecimal
	   Results  are printed in hexadecimal (base 16). Numbers printed in hexadecimal have a prefix of 0x unless the -p or --prefixes option is
	   used.

       -o or -oct or --octal
	   Results are printed in octal (base 8). Numbers printed in octal have a prefix of 0 unless the -p or --prefixes option is used.

       -b or -bin or --binary
	   Results are printed in binary (base 2). Numbers printed in binary have a prefix of 0b unless the -p or --prefixes option is used.

       -p or --prefixes
	   Toggles printing prefixes for hexadecimal, octal, and binary forms.

       -l or --lenient
	   Makes the parser assume that uninitialized variables have a value of zero.

       -r or --radians
	   Toggles whether trigonometric functions assume input (and output) is in radians. By default, trigonometric functions assume input is in
	   degrees.

       -q or --quiet
	   Toggles whether the equals sign will be printed before the results.

       -c or --conservative
	   Toggles  precision guards. Because of the way floating point numbers are stored, some operations, like 1-.9-.1, can return an extremely
	   small number that is not zero but is less than the official precision of the floating point number and thus for all	intents  and  pur-
	   poses,  it is 0. The precision guard will round numbers to zero if they are less than the official precision of the floating point num-
	   ber. However, sometimes numbers that small or smaller need to be displayed, and thus the precision guard should be turned off.

       --remember
	   Toggles whether or not expressions that produce errors are remembered in the history. Does not affect command-line math.

       --round= { none | simple | sig_fig }
	   Wcalc can attempt to warn you when numbers have been rounded in the output display. It has two methods  of  keeping	track---either	by
	   using  significant  figures	(sig_fig),  or	by a simple digit-counting algorithm. Rounding in the command-line version is denoted by a
	   tilde before the equals sign (~=). Rounding in the GUI version is denoted by changing the text color to red. In some cases,	Wcalc  may
	   think  that the number has been rounded even if it shouldn't have been necessary (this is because of the way floating point numbers are
	   represented internally).

       --dsep=X
	   Sets the decimal separator character to be X.

       --tsep=X
	   Sets the thousands separator character to be X.

       --idsep=X
	   Sets the input-only decimal separator character to be X.

       --itsep=X
	   Sets the input-only thousands separator character to be X.

       --bitsXXXX
	   Sets the number of bits of precision that will be used to internally represent numbers to be XXXX. The default is 1024. Set	higher	if
	   you need more precision, set lower if you want to use less memory.

       --ints
	   Toggles whether long integers will be abbreviated or not. This conflicts with engineering notation for large numbers, but not for deci-
	   mals.

USER-DEFINED VARIABLES
       Variables are supported and may be assigned using the = operator. To assign a variable use the form:

	      foo = anylegalexpression

       Thereafter, that variable name is the same as the literal value it represents.  Expressions can be stored in variables like this:

	      foo = 'anylegalexpression'

       Expressions stored this way will be interpreted at evaluation time, rather than assignment-time. Note that these cannot be recursive.

       All variables may also be stored with a description of what they are. This description is added in the form of a quoted	string	after  the
       assignment, like this:

	      foo = 'anylegalexpression' 'description'

   ACTIVE VARIABLES
       Active variables are designed to give a functionality similar to user-defined functions. They are variables that rather than representing a
       value, represent an expression that is evaluated whenever the variable is evaluated. This expression may contain other variable names.  For
       example, after the following sequence of commands:

	      foo=5
	      bar='foo+4'

       The variable bar will evaluate to 9, or four more than whatever foo evaluates to be. These can be stacked, like so:

	      baz='sin(bar)+foo'

       In this case, baz will evaluate to be 5.15643, or the sin of whatever foo+4 is plus whatever foo is.

       To  demonstrate	the utility of these active variables, here are two functions written by Stephen M. Lawson. The first computes the weekday
       of a given day (dy) in a given month (mo) in a given year (yr). The value it returns is in the range of 1 to 7, where 1	is  Sunday,  2	is
       Monday, 3 is Tuesday, and so forth.

       weekday='(((floor((yr - floor(0.6 + 1 / mo)) / 400) - floor((yr - floor(0.6 + 1 / mo)) / 100) + floor((5 * (yr - floor(0.6 + 1 / mo))) / 4)
       + floor(13 * (mo + 12 * floor(0.6 + 1 / mo) + 1) / 5)) - (7 * floor((floor((yr - floor(0.6 + 1 / mo)) / 400) - floor((yr - floor(0.6 + 1  /
       mo)) / 100) + floor((5 * (yr - floor(0.6 + 1 / mo))) / 4) + floor(13 * (mo + 12 * floor(0.6 + 1 / mo) + 1) / 5)) / 7)) + 1) + 5 + dy) % 7 +
       1'

       The second function computes what day Easter will be for a given year (yr) and returns an offset from March 31st. For example, for the year
       2005,  it  returns  -4,	which  means  March 27th. Because of leap-year problems, this only works from the year 1900 to 2099, but is a good
       demonstration nevertheless.

       easter='((19 * (yr - 19 * floor(yr / 19)) + 24) - floor((19 * (yr - 19 * floor(yr / 19)) + 24) / 30) * 30) + ((2 * (yr - 4 * floor(yr / 4))
       +  4  * (yr - 7 * floor(yr / 7)) + 6 * ((19 * (yr - 19 * floor(yr / 19)) + 24) - floor((19 * (yr - 19 * floor(yr / 19)) + 24) / 30) * 30) +
       5) - floor((2 * (yr - 4 * floor(yr / 4)) + 4 * (yr - 7 * floor(yr / 7)) + 6 * ((19 * (yr - 19 * floor(yr / 19)) + 24) - floor((19 *  (yr  -
       19 * floor(yr / 19)) + 24) / 30) * 30) + 5) / 7) * 7) - 9'

BUILT-IN SYMBOLS
       There are two basic kinds of built-in symbols in wcalc: functions and constants.

   FUNCTIONS
       The functions supported in wcalc are almost all self-explanatory. Here are the basic descriptions.

       sin cos tan cot
	   The standard trigonometric functions

       asin acos atan acot or arcsin arccos arctan arccot or sin^-1 cos^-1 tan^-1 cot^-1
	   The standard arc- trigonometric functions.

       sinh cosh tanh coth
	   The standard hyperbolic trigonometric functions.

       asinh acosh atanh acoth or arcsinh arccosh arctanh arccoth or sinh^-1 cosh^-1 tanh^-1 coth^-1
	   The standard arc- hyperbolic trigonometric functions.

       log ln logtwo
	   Log-base-ten,  log-base-e  and  log-base-two,  respectively.  Remember,  you  can  also  construct  log-base-X of number Y by computing
	   log(Y)/log(X).

       round
	   Returns the integral value nearest to the argument according to the typical rounding rules.

       abs Returns the absolute value of the argument.

       ceil ceiling floor
	   Returns the ceiling or floor of the argument.

       sqrt cbrt
	   The square and cube root functions.

       rand
	   Returns a random number between 0 and the number given.

       irand
	   Returns a random integer between 0 and the number given.

       fact
	   Returns the factorial of a number.

       Gamma
	   Returns the value of the Gamma function at that value.

       lnGamma
	   Returns the value of the log Gamma function at that value.

       zeta
	   Returns the value of the Riemann zeta function at that value.

       sinc
	   Returns the sinc function (for sinus cardinalis) of the input, also known as the interpolation  function,  filtering  function  or  the
	   first spherical Bessel function, is the product of a sine function and a monotonically decreasing function.

   CONSTANTS
       Wcalc  supports a lot of constants. Some are special (like pi), and some are simply mathematical or physical constants that have been hard-
       coded in. The physics constants are taken from http://physics.nist.gov/constants, and should all be in predictable SI units.

       The value of pi is special, as it is calculated to however many bits of precision have been specified with the its command.  The  default
       number of bits is 1024, or a value of:
       3.1415926535897932384626433832795028841971693993751058209749445923078164062862089986280348253421170679821480865132823066470938446095505822317253594081284811174502841027019385211055596446229489549303819644288109756659334461284756482337867831652712019091456485669234603486104543266482133936072602491412737245869974724822361502823407955151120558811684656967313093357387193011055974127397801166600823447367841524950037348489795545416453901986117572722731871388422643588974212021713194956805142308399313566247553371620129340026051601856684677033122428187855479365508702723110143458240736806341798963338923286460351089772720817919599675133363110147505797173662675795471777702814318804385560929672479177350549251018537674006123614790110383192502897923367993783619310166679013187969315172579438604030363957033826325935372151289640167976948453904619615481368332936937026831888367580239969088932697527811653282224950410336573385944190516446146423694037380609059088222036945727944116946240616684848934170304346480406820774078369140625

       Similarly, all values that rely on the value of pi, like mu0, have the same level of precision. Here is a complete list of the symbols used
       to represent the constants hardcoded into wcalc:

       e   The logarithm constant:
	   2.718281828459045235360287471352662497757247093699959574966

       gamma
	   Euler's															 Constant:
	   0.57721566490153286060651209008240243104215933593992359880576723488486772677766467093694706329174674951463144724980708248096050401448654283622417399764492353625350033374293733773767394279259525824709491600873520394816567

       K   Catalan															 Constant:
	   0.91596559417721901505460351493238411077414937428167213426649811962176301977625476947935651292611510624857442261919619957903589880332585905943159473748115840699533202877331946051903872747816408786590902

       g   Acceleration due to gravity: 9.80665 m/s/s

       Cc  Coulomb's Constant: 8987551787.37

   Universal Constants
       Z0 or Zzero
	   Impedance of Vacuum: 376.730313461 ohms

       epsilon0 or epsilonzero
	   Permittivity of Free Space: 8.854187817e-12 F/m

       mu0 or muzero
	   Permeability of Free Space calculated as 4*pi*10^-7.

       G   Gravitational Constant: 6.67259e-11

       h   Planck Constant: 6.6260755e-34

       c   Speed of Light: 299792458

   Electromagnetic Constants
       muB Bohr Magneton: 5.78838174943e-11 J/T

       muN Nuclear Magneton: 3.15245123824e-14 J/T

       G0  Conductance Quantum: 7.748091733e-5 S

       ec  Elementary Charge: 1.60217653e-19

       Kj  Josephson Constant: 483597.879e9 Hz/V

       Rk  Von Klitzing Constant: 25812.807449 omega

   Atomic and Nuclear Constants
       Malpha
	   Alpha Particle Mass: 6.6446565e-27 kg

       a0  Bohr Radius: 5.291772108e-11 m

       Md  Deuteron Mass: 3.34358335e-27 kg

       Me  Electron Mass: 9.1093897e-31 kg

       re  Electron Radius: 2.817940325e-15 m

       eV  Electron Volt: 1.602177250e-12 J

       Gf  Fermi Coupling Constant: 1.16638e-5 GeV^-2

       alpha
	   Fine Structure Constant: 7.29735253327e-3

       eh  Hartree Energy: 4.35974417e-18 J

       Mh  Helion Mass: 5.00641214e-27 kg

       Mmu Muon Mass: 1.88353140e-28 kg

       Mn  Neutron Mass: 1.67492728e-27 kg

       Mp  Proton Mass: 1.67262171e-27 kg

       Rinf
	   Rydberg Constant: 10973731.568525 1/m

       Mt  Tau Mass: 3.16777e-27 kg

   Physio-Chemical Constants
       u   Atomic Mass Constant: 1.66053886e-27 kg

       Na or NA
	   Avogadro's Constant: 6.0221367e23

       k   Boltzmann Constant: 1.3806505e-23

       F   Faraday Constant: 96485.3383 C/mol

       c1  First Radiation Constant: 3.74177138e-16 W m^2

       n0 or nzero
	   Loschmidt Constant: 2.6867773e25 m^-3

       R   Molar Gas Constant: 8.314472

       Vm or NAk
	   Molar Volume of Ideal Gas: 22.413996e-3 (m^3)/mol

       c2  Second Radiation Constant: 1.4387752e-2 m K

       sigma
	   Stefan-Boltzmann Constant: 5.670400e-8

       b   Wien Displacement Law Constant: 2.8977686e-3 m K

   Random Constants
       random
	   A Random Value

       irandom
	   A Random Integer

COMMANDS

       There are several commands that are supported in wcalc.

       pXXX  Sets  the  precision to XXX. This setting only affects output, not internal representations. A setting of -1 means formats output in
	      whatever precision seems appropriate.

       e or eng or engineering
	      Rotates between always using scientific notation, never using scientific notation, and choosing to do scientific notation when  con-
	      venient. Can also take an argument that is one of always, never, and automatic to choose a mode directly.

       help or ?
	      Displays a help screen.

       prefs Prints out the current preference settings.

       li or list or listvars
	      Prints out the currently defined variables.

       
 or 
adians
	      Toggles between using and not using radians for trigonometric calculations.

       cons or conservative
	      Toggles  precision  guards.  Because  of	the  way  floating  point numbers are stored, some operations, like 1-.9-.1, can return an
	      extremely small number that is not zero but is less than the official precision of the  floating	point  number  and  thus  for  all
	      intents  and  purposes,  it is 0. The precision guard will round numbers to zero if they are less than the official precision of the
	      floating point number. However, sometimes numbers that small or smaller need to be displayed, and thus the precision guard should be
	      turned off.

       p or picky or l or lenient
	      Toggles  variable  parsing  rules.  When wcalc is "picky" it will complain if you use undefined variables. If it is "lenient", wcalc
	      will assume a value of 0 for undefined variables.

       
e or 
emember or 
emember_errors
	      Toggles whether or not expressions that produce errors are remembered in the history.

       pre or prefix or prefixes
	      Toggles the display of prefixes for hexadecimal, octal, and binary output.

        or in or inary
	      Results are printed in binary (base 2). Numbers printed in binary have a prefix of 0b unless the prefixes command is used.

       d or dec or decimal
	      Results are printed in decimal (base 10). This option is the default, and does not have a default prefix to  indicate  that  numbers
	      are in base 10.

       h or x or hex or hexadecimal
	      Results  are  printed  in  hexadecimal (base 16). Numbers printed in hexadecimal have a prefix of 0x unless the prefixes command is
	      used.

       o or oct or octal
	      Results are printed in octal (base 8). Numbers printed in octal have a prefix of 0 unless the prefixes command is used.

       
ound none|simple|sig_fig
	      Wcalc can attempt to warn you when numbers have been rounded in the output display. It has two methods of keeping track---either	by
	      using  significant  figures (sig_fig), or by a simple digit-counting algorithm. Rounding in the command-line version is denoted by a
	      tilde before the equals sign (~=). Rounding in the GUI version is denoted by changing the text color to red. In  some  cases,  Wcalc
	      may  think that the number has been rounded even if it shouldn't have been necessary (this is because of the way floating point num-
	      bers are represented internally).

       dsepX Sets the decimal separator character to be X.

       	sepX Sets the thousands-place separator character to be X.

       idsepX
	      Sets the input-only decimal separator character to be X.

       itsepX
	      Sets the input-only thousands-place separator character to be X.

       hlimitX
	      Sets the limit (X) on the length of the history.

       openXXXXX
	      Loads file XXXXX.

       saveXXXXX
	      Saves the history and variable list to a file, XXXXX.

       itsXXXX
	      Sets the number of bits of precision that will be used to internally represent numbers to be XXXX. The default is 1024.  Set  higher
	      if you need more precision, set lower if you want to use less memory.

       ints  Toggles  whether	long  integers will be abbreviated or not. This conflicts with engineering notation for large numbers, but not for
	      decimals.

       prefs or preferences
	      Displays the current preference settings.

       convert unit1 unit1
	      Converts the previous answer from unit1 to unit2.

       store variablename
	      Saves the specified variable in the preload file, ~/.wcalc_preload

       explain object
	      Explains the specified object. The object can be a variable, constant, function, or command.

       verbose
	      Verbose mode displays the expression to be calculated before calculating it.

       del or delim or delimiters
	      Display delimiters in numerical output.

       cmod  Toggle between C-style modulus operation and a more flexible method.

PREFERENCES

       Preferences and settings can be retained between invocations of wcalc by storing them in the file ~/.wcalcrc

       The format of the file is that each line is either blank or an assignment. Comments are ignored, and are defined as anything to	the  right
       of and including a hash mark (#). Assignments are of the form: key=value

       The possible keys are:

       precision
	      A  number defining the display precision. Equivalent to the P command, where -1 means "auto" and anything else specifies the number
	      of decimal places. This does not affect the behind-the-scenes precision.

       show_equals
	      Either true ("yes" or "true") or false (anything else). Equivalent to the --quiet argument. Specifies  whether  answers  will  begin
	      with an equals sign or not.

       engineering
	      Either  "always",  "never",  or  "automatic". Equivalent to the engineering command. Specifies whether answers will be displayed in
	      engineering notation or not.

       use_radians
	      Either true ("yes" or "true") or false (anything else). Equivalent to the 
adians command. Specifies  whether  trigonometric  func-
	      tions accept input in radians or degrees.

       print_prefixes
	      Either  true  ("yes" or "true") or false (anything else). Equivalent to the prefixes command. Specifies whether base prefixes (e.g.
	      0x for hexadecimal numbers) are used when displaying output.

       save_errors
	      Either true ("yes" or "true") or false (anything else). Equivalent to the 
emember_errors command.  Specifies  whether  lines  that
	      contain a syntax error are added to the history or not.

       precision_guard
	      Either  true ("yes" or "true") or false (anything else). Equivalent to the conservative command. Specifies whether the display will
	      attempt to eliminate numbers too small to be accurate (hopefully, these are only errors created by the binary approximation  of  the
	      inputs).

       print_integers
	      Either  true  ("yes"  or "true") or false (anything else). Equivalent to the ints command. Specifies whether whole integers will be
	      printed un-abbreviated or not. This conflicts with engineering notation for large integers, but not for decimals.

       print_delimiters
	      Either true ("yes" or "true") or false (anything else). Equivalent to the delimiters command. Specifies whether delimiters will	be
	      added to output when displaying.

       thousands_delimiter
	      Uses  the next character after the equals sign as its value. Equivalent to the 	sep command. Specifies what the thousands delimiter
	      is, and can affect output if print_delimiters is enabled.

       decimal_delimiter
	      Uses the next character after the equals sign as its value. Equivalent to the dsep command. Specifies what  the	decimal  delimiter
	      is.

       input_thousands_delimiter
	      Uses  the  next  character after the equals sign as its value. Equivalent to the itsep command. Specifies what the input-only thou-
	      sands delimiter is, and cannot affect output.

       input_decimal_delimiter
	      Uses the next character after the equals sign as its value. Equivalent to the idsep command. Specifies what the input-only  decimal
	      delimiter is, and cannot affect output.

       history_limit
	      Either "no", for no limit, or a number. Equivalent to the hlimit command.

       output_format
	      Either decimal, octal, binary, hex, or hexadecimal.

       rounding_indication
	      Either no, simple, or sig_fig. Equivalent to the 
ounding command.

       c_style_mod
	      Either  true  ("yes" or "true") or false (anything else). Equivalent to the cmod command. Specifies whether the modulo operator (%)
	      will behave as it does in the C programming language, or whether it will use a more flexible method. This only affects modulo opera-
	      tions where negative numbers are involved. As an example, with c_style_mod set to true (the default):

	      -340 % 60 == -40; 340 % -60 == 40; -340 % -60 == -40

	      However, with c_style_mod set to false:

	      -340 % 60 == -40; 340 % -60 == -20; -340 % -60 == 20

PRELOAD

       Wcalc uses a file, ~/.wcalc_preload, to store persistent information between instances. Typically, this is used to store variables that are
       frequently defined. This file can be edited by hand with a standard text editor. There is also a command within wcalc (store) to append  a
       variable  definition  to the end of this file. Any variable defined in this file is defined and available for use in any subsequent invoca-
       tion of wcalc.

COPYRIGHT

       wcalc is Copyright (C) 2000-2007 Kyle Wheeler.
       It is distributed under the GPL, version 2, or (at your option) any later version..

SUGGESTIONS AND BUG REPORTS

       Any bugs found should be reported to
       Kyle Wheeler at kyle-wcalc@memoryhole.net.

																	  wcalc(1)