04861939fc
The following are the changes in this release:
Fixed typo (missing quotes) in the env rule.
Fixed intendation problem in CHANGES.
Combined 2.12.9.1 changes into the 2.12.8.2 to 2.12.9.0
range, and thus renamed the range to 2.12.8.2 to 2.12.9.1.
Fixed issues related to building Makefile.simple.
Fixed how the Makefile variable MANPATH is set for macOS.
Added a bunch of information to the near bottom of HOWTO.INSTALL
on calc Makefiles. This information discusses the various
Makefiles found in the calc source.
Added comments in various calc Makefiles about their origin.
In particular, for Makefiles that are constructed such as
Makefile.simple, custom/Makefile and custom/Makefile.simple
there are comments about how they were made.
For all calc Makefiles, including those in sub-directories,
near the top there is now a line of the form:
# SRC: ... some message about the origin ...
Fixed how the calc(1) man page is installed under macOS.
Fixed how calc man page in ${CATDIR} is formed.
Fixed how Makefile.simple is formed.
Fixed the #! calc script argument processing. The initial #!
line must end in a -f. For example, if calc is in /usr/local/bin/calc,
then the following would be the first line of a calc script:
#!/usr/local/bin/calc -f
...
It is common that -q be usde with a calc script, so assuming the
same /usr/local/bin/calc path:
#!/usr/local/bin/calc -q -f
...
Use of -s in the #! first line of a calc script is not needed
since -f implies -f.
The argv() will now return values more typical of C's main().
Before it returned one less than the number of arguments. Now,
for example, when calc is given 2 args, argv() will return 3.
The value of argv(0) will be the path to calc, or in the
case of a #! calc cscript, it will return the name of the script.
Updated the calc man page and help/argv to reflect the
above changes.
Improved the formatting of the calc man page.
Fixed the formation of the win32 sub-directory via the win32_hsrc
Makefile rule.
Due to incompatible changes to the argv() function, and #! calc
scripts, we are setting the version to the next minor number:
2.13.0
What is calc?
Calc is an interactive calculator which provides for easy large numeric calculations, but which also can be easily programmed for difficult or long calculations. It can accept a command line argument, in which case it executes that single command and exits. Otherwise, it enters interactive mode. In this mode, it accepts commands one at a time, processes them, and displays the answers. In the simplest case, commands are simply expressions which are evaluated. For example, the following line can be input:
3 * (4 + 1)
and the calculator will print:
15
Calc has the usual collection of arithmetic operators +, -, /, * as well as ^ (exponentiation), % (modulus) and // (integer divide). For example:
3 * 19^43 - 1
will produce:
29075426613099201338473141505176993450849249622191102976
Notice that calc values can be very large. For example:
2^23209-1
will print:
402874115778988778181873329071 ... many digits ... 3779264511
The special '.' symbol (called dot), represents the result of the last command expression, if any. This is of great use when a series of partial results are calculated, or when the output mode is changed and the last result needs to be redisplayed. For example, the above result can be modified by typing:
. % (2^127-1)
and the calculator will print:
47385033654019111249345128555354223304
For more complex calculations, variables can be used to save the intermediate results. For example, the result of adding 7 to the previous result can be saved by typing:
curds = 15
whey = 7 + 2*curds
Functions can be used in expressions. There are a great number of pre-defined functions. For example, the following will calculate the factorial of the value of 'whey':
fact(whey)
and the calculator prints:
13763753091226345046315979581580902400000000
The calculator also knows about complex numbers, so that typing:
(2+3i) * (4-3i)
cos(.)
will print:
17+6i
-55.50474777265624667147+193.9265235748927986537i
The calculator can calculate transcendental functions, and accept and display numbers in real or exponential format. For example, typing:
config("display", 70),
epsilon(1e-70),
sin(1)
prints:
0.8414709848078965066525023216302989996225630607983710656727517099919104
Calc can output values in terms of fractions, octal or hexadecimal. For example:
config("mode", "fraction"),
(17/19)^23
print
base(16),
(19/17)^29
print
log(79.3i)
will print:
19967568900859523802559065713/257829627945307727248226067259
0x9201e65bdbb801eaf403f657efcf863/0x5cd2e2a01291ffd73bee6aa7dcf7d1
0x17b5164ac24ee836bf/0xc7b7a8e3ef5fcf752+0x883eaf5adadd26be3/0xc7b7a8e3ef5fcf752i
All numbers are represented as fractions with arbitrarily large numerators and denominators which are always reduced to lowest terms. Real or exponential format numbers can be input and are converted to the equivalent fraction. Hex, binary, or octal numbers can be input by using numbers with leading '0x', '0b' or '0' characters. Complex numbers can be input using a trailing 'i', as in '2+3i'. Strings and characters are input by using single or double quotes.
Commands are statements in a C-like language, where each input line is treated as the body of a procedure. Thus the command line can contain variable declarations, expressions, labels, conditional tests, and loops. Assignments to any variable name will automatically define that name as a global variable. The other important thing to know is that all non-assignment expressions which are evaluated are automatically printed. Thus, you can evaluate an expression's value by simply typing it in.
Many useful built-in mathematical functions are available. Use the:
help builtin
command to list them.
You can also define your own functions by using the 'define' keyword, followed by a function declaration very similar to C.
define f2(n)
{
local ans;
ans = 1;
while (n > 1)
ans *= (n -= 2);
return ans;
}
Thus the input:
f2(79)
will produce:
1009847364737869270905302433221592504062302663202724609375
Functions which only need to return a simple expression can be defined using an equals sign, as in the example:
define sc(a,b) = a^3 + b^3
Thus the input:
sc(31, 61)
will produce:
256772
Variables in functions can be defined as either 'global', 'local', or 'static'. Global variables are common to all functions and the command line, whereas local variables are unique to each function level, and are destroyed when the function returns. Static variables are scoped within single input files, or within functions, and are never destroyed. Variables are not typed at definition time, but dynamically change as they are used.
For more information about the calc language and features, try:
help overview
Calc has a help command that will produce information about every builtin function, command as well as a number of other aspects of calc usage. Try the command:
help help
for and overview of the help system. The command:
help builtin
provides information on built-in mathematical functions, whereas:
help asinh
will provides information a specific function. The following help files:
help command
help define
help operator
help statement
help variable
provide a good overview of the calc language. If you are familiar with C, you should also try:
help unexpected
It contains information about differences between C and calc that may surprise C programmers.