Bc (programming language)


bc, for basic calculator, is "an arbitrary-precision calculator language" with syntax similar to the C programming language. bc is typically used as either a mathematical scripting language or as an interactive mathematical shell.

Overview

A typical interactive usage is typing the command bc on a Unix command prompt and entering a mathematical expression, such as, whereupon will be output. While bc can work with arbitrary precision, it actually defaults to zero digits after the decimal point, so the expression yields. This can surprise new bc users unaware of this fact. The option to bc sets the default scale to 20 and adds several additional mathematical functions to the language.

History

bc first appeared in Version 6 Unix in 1975 and was written by Robert Morris and Lorinda Cherry of Bell Labs. bc was preceded by dc, an earlier arbitrary-precision calculator written by the same authors. dc could do arbitrary-precision calculations, but its reverse Polish notation syntax—much loved by many for evaluating algebraic formulas—proved inconvenient to its users when expressing flow control, and therefore bc was written as a front-end to dc. bc was a very simple compiler, which converted the new, C-like, bc syntax into dc's postfix notation and piped the results through dc.
In 1991, POSIX rigorously defined and standardized bc. Three implementations of this standard survive today: The first is the traditional Unix implementation, a front-end to dc, which survives in Unix and Plan 9 systems. The second is the free software GNU bc, first released in 1991 by Philip A. Nelson. The GNU implementation has numerous extensions beyond the POSIX standard and is no longer a front-end to dc. The third is a re-implementation by OpenBSD in 2003.

Implementations

POSIX bc

The POSIX standardized bc language is traditionally written as a program in the dc programming language to provide a higher level of access to the features of the dc language without the complexities of dc's terse syntax.
In this form, the bc language contains single-letter variable, array and function names and most standard arithmetic operators, as well as the familiar control-flow constructs ..., while... and for from C. Unlike C, an if clause may not be followed by an else.
Functions are defined using a define keyword, and values are returned from them using a return followed by the return value in parentheses. The auto keyword is used to declare a variable as local to a function.
All numbers and variable contents are arbitrary-precision numbers whose precision is determined by the global scale variable.
The numeric base of input, output and program constants may be specified by setting the reserved ibase and obase variables.
Output is generated by deliberately not assigning the result of a calculation to a variable.
Comments may be added to bc code by use of the C /* and */ symbols.

Mathematical operators

Exactly as C
The following POSIX bc operators behave exactly like their C counterparts:
+ - * /
+= -= *= /=
++ -- < >
!= <= >=
Similar to C
The modulus operators, % and %= behave exactly like their C counterparts only when the global scale variable is set to 0, i.e. all calculations are integer-only. Otherwise the computation is done with the appropriate scale. a%b is defined as a-*b. Examples:

$ bc
bc 1.06
Copyright 1991-1994, 1997, 1998, 2000 Free Software Foundation, Inc.
This is free software with ABSOLUTELY NO WARRANTY.
For details type `warranty'.
scale=0; 5%3
scale=1; 5%3
.2
scale=20; 5%3
.00000000000000000002
Conflicting with C
The operators
^ ^=
superficially resemble the C bitwise exclusive-or operators, but are in fact the bc integer exponentiation operators.
Of particular note, the use of the ^ operator with negative numbers does not follow the C operator precedence. -2^2 gives the answer of 4 under bc rather than −4.
"Missing" operators relative to C
The bitwise, boolean and conditional operators:
& | ^ && ||
&= |= ^= &&= ||=
<< >>
<<= >>=
?:
are not available in POSIX bc.

Built-in functions

The sqrt function for calculating square roots is POSIX bc's only built-in mathematical function. Other functions are available in an external standard library.
The scale function for determining the precision of its argument and the length function for determining the number of significant decimal digits in its argument are also built-in.

Standard library functions

bc's standard math library contains functions for calculating sine, cosine, arctangent, natural logarithm, the exponential function and the two parameter Bessel function J. Most standard mathematical functions can be constructed using these. See external links for implementations of many other functions.
bc commandFunctionDescription
sSineTakes x, an angle in radians
cCosineTakes x, an angle in radians
aArctangentReturns radians
lNatural logarithm
eExponential function
jBessel functionReturns the order-n Bessel function of x.

The -l option changes the scale to 20, so things such as modulo may work unexpectedly. For example, writing bc -l and then the command print 3%2 outputs 0. But writing scale=0 after bc -l and then the command print 3%2 will output 1.

Plan 9 bc

bc is identical to POSIX bc but for an additional print statement.

GNU bc

GNU bc derives from the POSIX standard and includes many enhancements. It is entirely separate from dc-based implementations of the POSIX standard and is instead written in C. Nevertheless, it is fully backwards compatible as all POSIX bc programs will run unmodified as GNU bc programs.
GNU bc variables, arrays and function names may contain more than one character, some more operators have been included from C, and notably, an if clause may be followed by an else.
Output is achieved either by deliberately not assigning a result of a calculation to a variable or by using the added print statement.
Furthermore, a read statement allows the interactive input of a number into a running calculation.
In addition to C-style comments, a # character will cause everything after it until the next new-line to be ignored.
The value of the last calculation is always stored within the additional built-in last variable.

Extra operators

The following logical operators are additional to those in POSIX bc:
&& || !
They are available for use in conditional statements. Note, however, that there are still no equivalent bitwise or assignment operations.

Functions

All functions available in GNU bc are inherited from POSIX. No further functions are provided as standard with the GNU distribution.

Example code

Since the bc ^ operator only allows an integer power to its right, one of the first functions a bc user might write is a power function with a floating-point exponent. Both of the below assume the standard library has been included:

A "power" function in POSIX bc


/* A function to return the integer part of x */
define i
/* Use the fact that x^y e^ */
define p

Calculating π to 10000 digits

Calculate pi using the builtin arctangent function, :

$ bc -lq
scale=10000
4*a # The atan of 1 is 45 degrees, which is pi/4 in radians.
# This may take several minutes to calculate.

A translated C function

Because the syntax of bc is similar to that of C, published numerical functions written in C can often be translated into bc quite easily, which immediately provides the arbitrary precision of bc. For example, in the Journal of Statistical Software, George Marsaglia published the following C code for the cumulative normal distribution:

double Phi

With some necessary changes to accommodate bc's different syntax, and realizing that the constant "0.9189..." is actually log/2, this can be translated to the following GNU bc code:

define phi

Using bc in shell scripts

bc can be used non-interactively, with input through a pipe. This is useful inside shell scripts. For example:

$ result=$
$ echo $result
11.66

In contrast, note that the bash shell only performs integer arithmetic, e.g.:

$ result=$)
$ echo $result
11

One can also use the here-string idiom :

$ bc -l <<< "5*7/3"
11.66666666666666666666