59 KiB
NAME
bc  arbitraryprecision arithmetic language and calculator
SYNOPSIS
bc [ghilPqsvVw] [globalstacks] [help] [interactive] [mathlib] [noprompt] [quiet] [standard] [warn] [version] [e expr] [expression=expr...] [f file...] [file=file...] [file...]
DESCRIPTION
bc(1) is an interactive processor for a language first standardized in 1991 by POSIX. (The current standard is here.) The language provides unlimited precision decimal arithmetic and is somewhat Clike, but there are differences. Such differences will be noted in this document.
After parsing and handling options, this bc(1) reads any files given on the command line and executes them before reading from stdin.
This bc(1) is a dropin replacement for any bc(1), including (and especially) the GNU bc(1). It also has many extensions and extra features beyond other implementations.
OPTIONS
The following are the options that bc(1) accepts.
 g, globalstacks

Turns the globals ibase, obase, scale, and seed into stacks.
This has the effect that a copy of the current value of all four are pushed onto a stack for every function call, as well as popped when every function returns. This means that functions can assign to any and all of those globals without worrying that the change will affect other functions. Thus, a hypothetical function named output(x,b) that simply printed x in base b could be written like this:
define void output(x, b) { obase=b x }
instead of like this:
define void output(x, b) { auto c c=obase obase=b x obase=c }
This makes writing functions much easier.
(Note: the function output(x,b) exists in the extended math library. See the LIBRARY section.)
However, since using this flag means that functions cannot set ibase, obase, scale, or seed globally, functions that are made to do so cannot work anymore. There are two possible use cases for that, and each has a solution.
First, if a function is called on startup to turn bc(1) into a number converter, it is possible to replace that capability with various shell aliases. Examples:
alias d2o="bc e ibase=A e obase=8" alias h2b="bc e ibase=G e obase=2"
Second, if the purpose of a function is to set ibase, obase, scale, or seed globally for any other purpose, it could be split into one to four functions (based on how many globals it sets) and each of those functions could return the desired value for a global.
For functions that set seed, the value assigned to seed is not propagated to parent functions. This means that the sequence of pseudorandom numbers that they see will not be the same sequence of pseudorandom numbers that any parent sees. This is only the case once seed has been set.
If a function desires to not affect the sequence of pseudorandom numbers of its parents, but wants to use the same seed, it can use the following line:
seed = seed
If the behavior of this option is desired for every run of bc(1), then users could make sure to define BC_ENV_ARGS and include this option (see the ENVIRONMENT VARIABLES section for more details).
If s, w, or any equivalents are used, this option is ignored.
This is a nonportable extension.
 h, help

Prints a usage message and quits.
 i, interactive

Forces interactive mode. (See the INTERACTIVE MODE section.)
This is a nonportable extension.
 l, mathlib

Sets scale (see the SYNTAX section) to 20 and loads the included math library and the extended math library before running any code, including any expressions or files specified on the command line.
To learn what is in the libraries, see the LIBRARY section.
 P, noprompt

Disables the prompt in TTY mode. (The prompt is only enabled in TTY mode. See the TTY MODE section) This is mostly for those users that do not want a prompt or are not used to having them in bc(1). Most of those users would want to put this option in BC_ENV_ARGS (see the ENVIRONMENT VARIABLES section).
This is a nonportable extension.
 q, quiet

This option is for compatibility with the GNU bc(1); it is a noop. Without this option, GNU bc(1) prints a copyright header. This bc(1) only prints the copyright header if one or more of the v, V, or version options are given.
This is a nonportable extension.
 s, standard

Process exactly the language defined by the standard and error if any extensions are used.
This is a nonportable extension.
 v, V, version

Print the version information (copyright header) and exit.
This is a nonportable extension.
 w, warn

Like s and standard, except that warnings (and not errors) are printed for nonstandard extensions and execution continues normally.
This is a nonportable extension.
 e expr, expression=expr

Evaluates expr. If multiple expressions are given, they are evaluated in order. If files are given as well (see below), the expressions and files are evaluated in the order given. This means that if a file is given before an expression, the file is read in and evaluated first.
After processing all expressions and files, bc(1) will exit, unless  (stdin) was given as an argument at least once to f or file. However, if any other e, expression, f, or file arguments are given after that, bc(1) will give a fatal error and exit.
This is a nonportable extension.
 f file, file=file

Reads in file and evaluates it, line by line, as though it were read through stdin. If expressions are also given (see above), the expressions are evaluated in the order given.
After processing all expressions and files, bc(1) will exit, unless  (stdin) was given as an argument at least once to f or file.
This is a nonportable extension.
All long options are nonportable extensions.
STDOUT
Any nonerror output is written to stdout.
Note: Unlike other bc(1) implementations, this bc(1) will issue a fatal error (see the EXIT STATUS section) if it cannot write to stdout, so if stdout is closed, as in bc >&, it will quit with an error. This is done so that bc(1) can report problems when stdout is redirected to a file.
If there are scripts that depend on the behavior of other bc(1) implementations, it is recommended that those scripts be changed to redirect stdout to /dev/null.
STDERR
Any error output is written to stderr.
Note: Unlike other bc(1) implementations, this bc(1) will issue a fatal error (see the EXIT STATUS section) if it cannot write to stderr, so if stderr is closed, as in bc 2>&, it will quit with an error. This is done so that bc(1) can exit with an error code when stderr is redirected to a file.
If there are scripts that depend on the behavior of other bc(1) implementations, it is recommended that those scripts be changed to redirect stderr to /dev/null.
SYNTAX
The syntax for bc(1) programs is mostly Clike, with some differences. This bc(1) follows the POSIX standard, which is a much more thorough resource for the language this bc(1) accepts. This section is meant to be a summary and a listing of all the extensions to the standard.
In the sections below, E means expression, S means statement, and I means identifier.
Identifiers (I) start with a lowercase letter and can be followed by any number (up to BC_NAME_MAX1) of lowercase letters (az), digits (09), and underscores (_). The regex is [az][az09_]*. Identifiers with more than one character (letter) are a nonportable extension.
ibase is a global variable determining how to interpret constant numbers. It is the "input" base, or the number base used for interpreting input numbers. ibase is initially 10. If the s (standard) and w (warn) flags were not given on the command line, the max allowable value for ibase is 36. Otherwise, it is 16. The min allowable value for ibase is 2. The max allowable value for ibase can be queried in bc(1) programs with the maxibase() builtin function.
obase is a global variable determining how to output results. It is the "output" base, or the number base used for outputting numbers. obase is initially 10. The max allowable value for obase is BC_BASE_MAX and can be queried in bc(1) programs with the maxobase() builtin function. The min allowable value for obase is 0. If obase is 0, values are output in scientific notation, and if obase is 1, values are output in engineering notation. Otherwise, values are output in the specified base.
Outputting in scientific and engineering notations are nonportable extensions.
The scale of an expression is the number of digits in the result of the expression right of the decimal point, and scale is a global variable that sets the precision of any operations, with exceptions. scale is initially 0. scale cannot be negative. The max allowable value for scale is BC_SCALE_MAX and can be queried in bc(1) programs with the maxscale() builtin function.
bc(1) has both global variables and local variables. All local variables are local to the function; they are parameters or are introduced in the auto list of a function (see the FUNCTIONS section). If a variable is accessed which is not a parameter or in the auto list, it is assumed to be global. If a parent function has a local variable version of a variable that a child function considers global, the value of that global variable in the child function is the value of the variable in the parent function, not the value of the actual global variable.
All of the above applies to arrays as well.
The value of a statement that is an expression (i.e., any of the named expressions or operands) is printed unless the lowest precedence operator is an assignment operator and the expression is notsurrounded by parentheses.
The value that is printed is also assigned to the special variable last. A single dot (.) may also be used as a synonym for last. These are nonportable extensions.
Either semicolons or newlines may separate statements.
Comments
There are two kinds of comments:
 Block comments are enclosed in /* and */.
 Line comments go from # until, and not including, the next newline. This is a nonportable extension.
Named Expressions
The following are named expressions in bc(1):
 Variables: I
 Array Elements: I[E]
 ibase
 obase
 scale
 seed
 last or a single dot (.)
Numbers 6 and 7 are nonportable extensions.
The meaning of seed is dependent on the current pseudorandom number generator but is guaranteed to not change except for new major versions.
The scale and sign of the value may be significant.
If a previously used seed value is assigned to seed and used again, the pseudorandom number generator is guaranteed to produce the same sequence of pseudorandom numbers as it did when the seed value was previously used.
The exact value assigned to seed is not guaranteed to be returned if seed is queried again immediately. However, if seed does return a different value, both values, when assigned to seed, are guaranteed to produce the same sequence of pseudorandom numbers. This means that certain values assigned to seed will not produce unique sequences of pseudorandom numbers. The value of seed will change after any use of the rand() and irand(E) operands (see the Operands subsection below), except if the parameter passed to irand(E) is 0, 1, or negative.
There is no limit to the length (number of significant decimal digits) or scale of the value that can be assigned to seed.
Variables and arrays do not interfere; users can have arrays named the same as variables. This also applies to functions (see the FUNCTIONS section), so a user can have a variable, array, and function that all have the same name, and they will not shadow each other, whether inside of functions or not.
Named expressions are required as the operand of increment/decrement operators and as the left side of assignment operators (see the Operators subsection).
Operands
The following are valid operands in bc(1):
 Numbers (see the Numbers subsection below).
 Array indices (I[E]).
 (E): The value of E (used to change precedence).
 sqrt(E): The square root of E. E must be nonnegative.
 length(E): The number of significant decimal digits in E.
 length(I[]): The number of elements in the array I. This is a nonportable extension.
 scale(E): The scale of E.
 abs(E): The absolute value of E. This is a nonportable extension.
 I(), I(E), I(E, E), and so on, where I is an identifier for a nonvoid function (see the Void Functions subsection of the FUNCTIONS section). The E argument(s) may also be arrays of the form I[], which will automatically be turned into array references (see the Array References subsection of the FUNCTIONS section) if the corresponding parameter in the function definition is an array reference.
 read(): Reads a line from stdin and uses that as an expression. The result of that expression is the result of the read() operand. This is a nonportable extension.
 maxibase(): The max allowable ibase. This is a nonportable extension.
 maxobase(): The max allowable obase. This is a nonportable extension.
 maxscale(): The max allowable scale. This is a nonportable extension.
 rand(): A pseudorandom integer between 0 (inclusive) and BC_RAND_MAX (inclusive). Using this operand will change the value of seed. This is a nonportable extension.
 irand(E): A pseudorandom integer between 0 (inclusive) and the value of E (exclusive). If E is negative or is a noninteger (E's scale is not 0), an error is raised, and bc(1) resets (see the RESET section) while seed remains unchanged. If E is larger than BC_RAND_MAX, the higher bound is honored by generating several pseudorandom integers, multiplying them by appropriate powers of BC_RAND_MAX+1, and adding them together. Thus, the size of integer that can be generated with this operand is unbounded. Using this operand will change the value of seed, unless the value of E is 0 or 1. In that case, 0 is returned, and seed is not changed. This is a nonportable extension.
 maxrand(): The max integer returned by rand(). This is a nonportable extension.
The integers generated by rand() and irand(E) are guaranteed to be as unbiased as possible, subject to the limitations of the pseudorandom number generator.
Note: The values returned by the pseudorandom number generator with rand() and irand(E) are guaranteed to NOT be cryptographically secure. This is a consequence of using a seeded pseudorandom number generator. However, they are guaranteed to be reproducible with identical seed values.
Numbers
Numbers are strings made up of digits, uppercase letters, and at most 1 period for a radix. Numbers can have up to BC_NUM_MAX digits. Uppercase letters are equal to 9 + their position in the alphabet (i.e., A equals 10, or 9+1). If a digit or letter makes no sense with the current value of ibase, they are set to the value of the highest valid digit in ibase.
Singlecharacter numbers (i.e., A alone) take the value that they would have if they were valid digits, regardless of the value of ibase. This means that A alone always equals decimal 10 and Z alone always equals decimal 35.
In addition, bc(1) accepts numbers in scientific notation. These have the form <number>e<integer>. The power (the portion after the e) must be an integer. An example is 1.89237e9, which is equal to 1892370000. Negative exponents are also allowed, so 4.2890e3 is equal to 0.0042890.
Using scientific notation is an error or warning if the s or w, respectively, commandline options (or equivalents) are given.
WARNING: Both the number and the exponent in scientific notation are interpreted according to the current ibase, but the number is still multiplied by 10^exponent regardless of the current ibase. For example, if ibase is 16 and bc(1) is given the number string FFeA, the resulting decimal number will be 2550000000000, and if bc(1) is given the number string 10e4, the resulting decimal number will be 0.0016.
Accepting input as scientific notation is a nonportable extension.
Operators
The following arithmetic and logical operators can be used. They are listed in order of decreasing precedence. Operators in the same group have the same precedence.
 ++ 

Type: Prefix and Postfix
Associativity: None
Description: increment, decrement
  !

Type: Prefix
Associativity: None
Description: negation, boolean not
 $

Type: Postfix
Associativity: None
Description: truncation
 @

Type: Binary
Associativity: Right
Description: set precision
 ^

Type: Binary
Associativity: Right
Description: power
 * / %

Type: Binary
Associativity: Left
Description: multiply, divide, modulus
 + 

Type: Binary
Associativity: Left
Description: add, subtract
 << >>

Type: Binary
Associativity: Left
Description: shift left, shift right
 = <<= >>= += = *= /= %= ^= @=

Type: Binary
Associativity: Right
Description: assignment
 == <= >= != < >

Type: Binary
Associativity: Left
Description: relational
 &&

Type: Binary
Associativity: Left
Description: boolean and
 

Type: Binary
Associativity: Left
Description: boolean or
The operators will be described in more detail below.
 ++ 

The prefix and postfix increment and decrement operators behave exactly like they would in C. They require a named expression (see the Named Expressions subsection) as an operand.
The prefix versions of these operators are more efficient; use them where possible.
 

The negation operator returns 0 if a user attempts to negate any expression with the value 0. Otherwise, a copy of the expression with its sign flipped is returned.
 !

The boolean not operator returns 1 if the expression is 0, or 0 otherwise.
This is a nonportable extension.
 $

The truncation operator returns a copy of the given expression with all of its scale removed.
This is a nonportable extension.
 @

The set precision operator takes two expressions and returns a copy of the first with its scale equal to the value of the second expression. That could either mean that the number is returned without change (if the scale of the first expression matches the value of the second expression), extended (if it is less), or truncated (if it is more).
The second expression must be an integer (no scale) and nonnegative.
This is a nonportable extension.
 ^

The power operator (not the exclusive or operator, as it would be in C) takes two expressions and raises the first to the power of the value of the second.
The second expression must be an integer (no scale), and if it is negative, the first value must be nonzero.
 *

The multiply operator takes two expressions, multiplies them, and returns the product. If a is the scale of the first expression and b is the scale of the second expression, the scale of the result is equal to min(a+b,max(scale,a,b)) where min() and max() return the obvious values.
 /

The divide operator takes two expressions, divides them, and returns the quotient. The scale of the result shall be the value of scale.
The second expression must be nonzero.
 %

The modulus operator takes two expressions, a and b, and evaluates them by 1) Computing a/b to current scale and 2) Using the result of step 1 to calculate a(a/b)*b to scale max(scale+scale(b),scale(a)).
The second expression must be nonzero.
 +

The add operator takes two expressions, a and b, and returns the sum, with a scale equal to the max of the scales of a and b.
 

The subtract operator takes two expressions, a and b, and returns the difference, with a scale equal to the max of the scales of a and b.
 <<

The left shift operator takes two expressions, a and b, and returns a copy of the value of a with its decimal point moved b places to the right.
The second expression must be an integer (no scale) and nonnegative.
This is a nonportable extension.
 >>

The right shift operator takes two expressions, a and b, and returns a copy of the value of a with its decimal point moved b places to the left.
The second expression must be an integer (no scale) and nonnegative.
This is a nonportable extension.
 = <<= >>= += = *= /= %= ^= @=

The assignment operators take two expressions, a and b where a is a named expression (see the Named Expressions subsection).
For =, b is copied and the result is assigned to a. For all others, a and b are applied as operands to the corresponding arithmetic operator and the result is assigned to a.
The assignment operators that correspond to operators that are extensions are themselves nonportable extensions.
 == <= >= != < >

The relational operators compare two expressions, a and b, and if the relation holds, according to C language semantics, the result is 1. Otherwise, it is 0.
Note that unlike in C, these operators have a lower precedence than the assignment operators, which means that a=b>c is interpreted as (a=b)>c.
Also, unlike the standard requires, these operators can appear anywhere any other expressions can be used. This allowance is a nonportable extension.
 &&

The boolean and operator takes two expressions and returns 1 if both expressions are nonzero, 0 otherwise.
This is not a shortcircuit operator.
This is a nonportable extension.
 

The boolean or operator takes two expressions and returns 1 if one of the expressions is nonzero, 0 otherwise.
This is not a shortcircuit operator.
This is a nonportable extension.
Statements
The following items are statements:
 E
 { S ; ... ; S }
 if ( E ) S
 if ( E ) S else S
 while ( E ) S
 for ( E ; E ; E ) S
 An empty statement
 break
 continue
 quit
 halt
 limits
 A string of characters, enclosed in double quotes
 print E , ... , E
 I(), I(E), I(E, E), and so on, where I is an identifier for a void function (see the Void Functions subsection of the FUNCTIONS section). The E argument(s) may also be arrays of the form I[], which will automatically be turned into array references (see the Array References subsection of the FUNCTIONS section) if the corresponding parameter in the function definition is an array reference.
Numbers 4, 9, 11, 12, 14, and 15 are nonportable extensions.
Also, as a nonportable extension, any or all of the expressions in the header of a for loop may be omitted. If the condition (second expression) is omitted, it is assumed to be a constant 1.
The break statement causes a loop to stop iterating and resume execution immediately following a loop. This is only allowed in loops.
The continue statement causes a loop iteration to stop early and returns to the start of the loop, including testing the loop condition. This is only allowed in loops.
The if else statement does the same thing as in C.
The quit statement causes bc(1) to quit, even if it is on a branch that will not be executed (it is a compiletime command).
The halt statement causes bc(1) to quit, if it is executed. (Unlike quit if it is on a branch of an if statement that is not executed, bc(1) does not quit.)
The limits statement prints the limits that this bc(1) is subject to. This is like the quit statement in that it is a compiletime command.
An expression by itself is evaluated and printed, followed by a newline.
Both scientific notation and engineering notation are available for printing the results of expressions. Scientific notation is activated by assigning 0 to obase, and engineering notation is activated by assigning 1 to obase. To deactivate them, just assign a different value to obase.
Scientific notation and engineering notation are disabled if bc(1) is run with either the s or w commandline options (or equivalents).
Printing numbers in scientific notation and/or engineering notation is a nonportable extension.
Print Statement
The "expressions" in a print statement may also be strings. If they are, there are backslash escape sequences that are interpreted specially. What those sequences are, and what they cause to be printed, are shown below:
\a \a \b \b \\ \ \e \ \f \f \n \n \q " \r \r \t \t
Any other character following a backslash causes the backslash and character to be printed asis.
Any nonstring expression in a print statement shall be assigned to last, like any other expression that is printed.
Order of Evaluation
All expressions in a statment are evaluated left to right, except as necessary to maintain order of operations. This means, for example, assuming that i is equal to 0, in the expression
a[i++] = i++
the first (or 0th) element of a is set to 1, and i is equal to 2 at the end of the expression.
This includes function arguments. Thus, assuming i is equal to 0, this means that in the expression
x(i++, i++)
the first argument passed to x() is 0, and the second argument is 1, while i is equal to 2 before the function starts executing.
FUNCTIONS
Function definitions are as follows:
define I(I,...,I){
auto I,...,I
S;...;S
return(E)
}
Any I in the parameter list or auto list may be replaced with I[] to make a parameter or auto var an array, and any I in the parameter list may be replaced with *I[] to make a parameter an array reference. Callers of functions that take array references should not put an asterisk in the call; they must be called with just I[] like normal array parameters and will be automatically converted into references.
As a nonportable extension, the opening brace of a define statement may appear on the next line.
As a nonportable extension, the return statement may also be in one of the following forms:
 return
 return ( )
 return E
The first two, or not specifying a return statement, is equivalent to return (0), unless the function is a void function (see the Void Functions subsection below).
Void Functions
Functions can also be void functions, defined as follows:
define void I(I,...,I){
auto I,...,I
S;...;S
return
}
They can only be used as standalone expressions, where such an expression would be printed alone, except in a print statement.
Void functions can only use the first two return statements listed above. They can also omit the return statement entirely.
The word "void" is not treated as a keyword; it is still possible to have variables, arrays, and functions named void. The word "void" is only treated specially right after the define keyword.
This is a nonportable extension.
Array References
For any array in the parameter list, if the array is declared in the form
*I[]
it is a reference. Any changes to the array in the function are reflected, when the function returns, to the array that was passed in.
Other than this, all function arguments are passed by value.
This is a nonportable extension.
LIBRARY
All of the functions below, including the functions in the extended math library (see the Extended Library subsection below), are available when the l or mathlib commandline flags are given, except that the extended math library is not available when the s option, the w option, or equivalents are given.
Standard Library
The standard defines the following functions for the math library:
 s(x)

Returns the sine of x, which is assumed to be in radians.
This is a transcendental function (see the Transcendental Functions subsection below).
 c(x)

Returns the cosine of x, which is assumed to be in radians.
This is a transcendental function (see the Transcendental Functions subsection below).
 a(x)

Returns the arctangent of x, in radians.
This is a transcendental function (see the Transcendental Functions subsection below).
 l(x)

Returns the natural logarithm of x.
This is a transcendental function (see the Transcendental Functions subsection below).
 e(x)

Returns the mathematical constant e raised to the power of x.
This is a transcendental function (see the Transcendental Functions subsection below).
 j(x, n)

Returns the bessel integer order n (truncated) of x.
This is a transcendental function (see the Transcendental Functions subsection below).
Extended Library
The extended library is not loaded when the s/standard or w/warn options are given since they are not part of the library defined by the standard.
The extended library is a nonportable extension.
 p(x, y)

Calculates x to the power of y, even if y is not an integer, and returns the result to the current scale.
This is a transcendental function (see the Transcendental Functions subsection below).
 r(x, p)

Returns x rounded to p decimal places according to the rounding mode round half away from 0.
 ceil(x, p)

Returns x rounded to p decimal places according to the rounding mode round away from 0.
 f(x)

Returns the factorial of the truncated absolute value of x.
 perm(n, k)

Returns the permutation of the truncated absolute value of n of the truncated absolute value of k, if k <= n. If not, it returns 0.
 comb(n, k)

Returns the combination of the truncated absolute value of n of the truncated absolute value of k, if k <= n. If not, it returns 0.
 l2(x)

Returns the logarithm base 2 of x.
This is a transcendental function (see the Transcendental Functions subsection below).
 l10(x)

Returns the logarithm base 10 of x.
This is a transcendental function (see the Transcendental Functions subsection below).
 log(x, b)

Returns the logarithm base b of x.
This is a transcendental function (see the Transcendental Functions subsection below).
 cbrt(x)

Returns the cube root of x.
 root(x, n)

Calculates the truncated value of n, r, and returns the rth root of x to the current scale.
If r is 0 or negative, this raises an error and causes bc(1) to reset (see the RESET section). It also raises an error and causes bc(1) to reset if r is even and x is negative.
 pi(p)

Returns pi to p decimal places.
This is a transcendental function (see the Transcendental Functions subsection below).
 t(x)

Returns the tangent of x, which is assumed to be in radians.
This is a transcendental function (see the Transcendental Functions subsection below).
 a2(y, x)

Returns the arctangent of y/x, in radians. If both y and x are equal to 0, it raises an error and causes bc(1) to reset (see the RESET section). Otherwise, if x is greater than 0, it returns a(y/x). If x is less than 0, and y is greater than or equal to 0, it returns a(y/x)+pi. If x is less than 0, and y is less than 0, it returns a(y/x)pi. If x is equal to 0, and y is greater than 0, it returns pi/2. If x is equal to 0, and y is less than 0, it returns pi/2.
This function is the same as the atan2() function in many programming languages.
This is a transcendental function (see the Transcendental Functions subsection below).
 sin(x)

Returns the sine of x, which is assumed to be in radians.
This is an alias of s(x).
This is a transcendental function (see the Transcendental Functions subsection below).
 cos(x)

Returns the cosine of x, which is assumed to be in radians.
This is an alias of c(x).
This is a transcendental function (see the Transcendental Functions subsection below).
 tan(x)

Returns the tangent of x, which is assumed to be in radians.
If x is equal to 1 or 1, this raises an error and causes bc(1) to reset (see the RESET section).
This is an alias of t(x).
This is a transcendental function (see the Transcendental Functions subsection below).
 atan(x)

Returns the arctangent of x, in radians.
This is an alias of a(x).
This is a transcendental function (see the Transcendental Functions subsection below).
 atan2(y, x)

Returns the arctangent of y/x, in radians. If both y and x are equal to 0, it raises an error and causes bc(1) to reset (see the RESET section). Otherwise, if x is greater than 0, it returns a(y/x). If x is less than 0, and y is greater than or equal to 0, it returns a(y/x)+pi. If x is less than 0, and y is less than 0, it returns a(y/x)pi. If x is equal to 0, and y is greater than 0, it returns pi/2. If x is equal to 0, and y is less than 0, it returns pi/2.
This function is the same as the atan2() function in many programming languages.
This is an alias of a2(y, x).
This is a transcendental function (see the Transcendental Functions subsection below).
 r2d(x)

Converts x from radians to degrees and returns the result.
This is a transcendental function (see the Transcendental Functions subsection below).
 d2r(x)

Converts x from degrees to radians and returns the result.
This is a transcendental function (see the Transcendental Functions subsection below).
 frand(p)

Generates a pseudorandom number between 0 (inclusive) and 1 (exclusive) with the number of decimal digits after the decimal point equal to the truncated absolute value of p. If p is not 0, then calling this function will change the value of seed. If p is 0, then 0 is returned, and seed is not changed.
 ifrand(i, p)

Generates a pseudorandom number that is between 0 (inclusive) and the truncated absolute value of i (exclusive) with the number of decimal digits after the decimal point equal to the truncated absolute value of p. If the absolute value of i is greater than or equal to 2, and p is not 0, then calling this function will change the value of seed; otherwise, 0 is returned and seed is not changed.
 srand(x)

Returns x with its sign flipped with probability 0.5. In other words, it randomizes the sign of x.
 brand()

Returns a random boolean value (either 0 or 1).
 ubytes(x)

Returns the numbers of unsigned integer bytes required to hold the truncated absolute value of x.
 sbytes(x)

Returns the numbers of signed, two'scomplement integer bytes required to hold the truncated value of x.
 hex(x)

Outputs the hexadecimal (base 16) representation of x.
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 binary(x)

Outputs the binary (base 2) representation of x.
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 output(x, b)

Outputs the base b representation of x.
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 uint(x)

Outputs the representation, in binary and hexadecimal, of x as an unsigned integer in as few power of two bytes as possible. Both outputs are split into bytes separated by spaces.
If x is not an integer or is negative, an error message is printed instead, but bc(1) is not reset (see the RESET section).
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 int(x)

Outputs the representation, in binary and hexadecimal, of x as a signed, two'scomplement integer in as few power of two bytes as possible. Both outputs are split into bytes separated by spaces.
If x is not an integer, an error message is printed instead, but bc(1) is not reset (see the RESET section).
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 uintn(x, n)

Outputs the representation, in binary and hexadecimal, of x as an unsigned integer in n bytes. Both outputs are split into bytes separated by spaces.
If x is not an integer, is negative, or cannot fit into n bytes, an error message is printed instead, but bc(1) is not reset (see the RESET section).
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 intn(x, n)

Outputs the representation, in binary and hexadecimal, of x as a signed, two'scomplement integer in n bytes. Both outputs are split into bytes separated by spaces.
If x is not an integer or cannot fit into n bytes, an error message is printed instead, but bc(1) is not reset (see the RESET section).
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 uint8(x)

Outputs the representation, in binary and hexadecimal, of x as an unsigned integer in 1 byte. Both outputs are split into bytes separated by spaces.
If x is not an integer, is negative, or cannot fit into 1 byte, an error message is printed instead, but bc(1) is not reset (see the RESET section).
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 int8(x)

Outputs the representation, in binary and hexadecimal, of x as a signed, two'scomplement integer in 1 byte. Both outputs are split into bytes separated by spaces.
If x is not an integer or cannot fit into 1 byte, an error message is printed instead, but bc(1) is not reset (see the RESET section).
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 uint16(x)

Outputs the representation, in binary and hexadecimal, of x as an unsigned integer in 2 bytes. Both outputs are split into bytes separated by spaces.
If x is not an integer, is negative, or cannot fit into 2 bytes, an error message is printed instead, but bc(1) is not reset (see the RESET section).
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 int16(x)

Outputs the representation, in binary and hexadecimal, of x as a signed, two'scomplement integer in 2 bytes. Both outputs are split into bytes separated by spaces.
If x is not an integer or cannot fit into 2 bytes, an error message is printed instead, but bc(1) is not reset (see the RESET section).
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 uint32(x)

Outputs the representation, in binary and hexadecimal, of x as an unsigned integer in 4 bytes. Both outputs are split into bytes separated by spaces.
If x is not an integer, is negative, or cannot fit into 4 bytes, an error message is printed instead, but bc(1) is not reset (see the RESET section).
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 int32(x)

Outputs the representation, in binary and hexadecimal, of x as a signed, two'scomplement integer in 4 bytes. Both outputs are split into bytes separated by spaces.
If x is not an integer or cannot fit into 4 bytes, an error message is printed instead, but bc(1) is not reset (see the RESET section).
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 uint64(x)

Outputs the representation, in binary and hexadecimal, of x as an unsigned integer in 8 bytes. Both outputs are split into bytes separated by spaces.
If x is not an integer, is negative, or cannot fit into 8 bytes, an error message is printed instead, but bc(1) is not reset (see the RESET section).
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 int64(x)

Outputs the representation, in binary and hexadecimal, of x as a signed, two'scomplement integer in 8 bytes. Both outputs are split into bytes separated by spaces.
If x is not an integer or cannot fit into 8 bytes, an error message is printed instead, but bc(1) is not reset (see the RESET section).
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 hex_uint(x, n)

Outputs the representation of the truncated absolute value of x as an unsigned integer in hexadecimal using n bytes. Not all of the value will be output if n is too small.
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 binary_uint(x, n)

Outputs the representation of the truncated absolute value of x as an unsigned integer in binary using n bytes. Not all of the value will be output if n is too small.
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 output_uint(x, n)

Outputs the representation of the truncated absolute value of x as an unsigned integer in the current obase (see the SYNTAX section) using n bytes. Not all of the value will be output if n is too small.
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
 output_byte(x, i)

Outputs byte i of the truncated absolute value of x, where 0 is the least significant byte and number_of_bytes  1 is the most significant byte.
This is a void function (see the Void Functions subsection of the FUNCTIONS section).
Transcendental Functions
All transcendental functions can return slightly inaccurate results (up to 1 ULP). This is unavoidable, and this article explains why it is impossible and unnecessary to calculate exact results for the transcendental functions.
Because of the possible inaccuracy, I recommend that users call those functions with the precision (scale) set to at least 1 higher than is necessary. If exact results are absolutely required, users can double the precision (scale) and then truncate.
The transcendental functions in the standard math library are:
 s(x)
 c(x)
 a(x)
 l(x)
 e(x)
 j(x, n)
The transcendental functions in the extended math library are:
 l2(x)
 l10(x)
 log(x, b)
 pi(p)
 t(x)
 a2(y, x)
 sin(x)
 cos(x)
 tan(x)
 atan(x)
 atan2(y, x)
 r2d(x)
 d2r(x)
RESET
When bc(1) encounters an error or a signal that it has a nondefault handler for, it resets. This means that several things happen.
First, any functions that are executing are stopped and popped off the stack. The behavior is not unlike that of exceptions in programming languages. Then the execution point is set so that any code waiting to execute (after all functions returned) is skipped.
Thus, when bc(1) resets, it skips any remaining code waiting to be executed. Then, if it is interactive mode, and the error was not a fatal error (see the EXIT STATUS section), it asks for more input; otherwise, it exits with the appropriate return code.
Note that this reset behavior is different from the GNU bc(1), which attempts to start executing the statement right after the one that caused an error.
PERFORMANCE
Most bc(1) implementations use char types to calculate the value of 1 decimal digit at a time, but that can be slow. This bc(1) does something different.
It uses large integers to calculate more than 1 decimal digit at a time. If built in a environment where BC_LONG_BIT (see the LIMITS section) is 64, then each integer has 9 decimal digits. If built in an environment where BC_LONG_BIT is 32 then each integer has 4 decimal digits. This value (the number of decimal digits per large integer) is called BC_BASE_DIGS.
The actual values of BC_LONG_BIT and BC_BASE_DIGS can be queried with the limits statement.
In addition, this bc(1) uses an even larger integer for overflow checking. This integer type depends on the value of BC_LONG_BIT, but is always at least twice as large as the integer type used to store digits.
LIMITS
The following are the limits on bc(1):
 BC_LONG_BIT

The number of bits in the long type in the environment where bc(1) was built. This determines how many decimal digits can be stored in a single large integer (see the PERFORMANCE section).
 BC_BASE_DIGS

The number of decimal digits per large integer (see the PERFORMANCE section). Depends on BC_LONG_BIT.
 BC_BASE_POW

The max decimal number that each large integer can store (see BC_BASE_DIGS) plus 1. Depends on BC_BASE_DIGS.
 BC_OVERFLOW_MAX

The max number that the overflow type (see the PERFORMANCE section) can hold. Depends on BC_LONG_BIT.
 BC_BASE_MAX

The maximum output base. Set at BC_BASE_POW.
 BC_DIM_MAX

The maximum size of arrays. Set at SIZE_MAX1.
 BC_SCALE_MAX

The maximum scale. Set at BC_OVERFLOW_MAX1.
 BC_STRING_MAX

The maximum length of strings. Set at BC_OVERFLOW_MAX1.
 BC_NAME_MAX

The maximum length of identifiers. Set at BC_OVERFLOW_MAX1.
 BC_NUM_MAX

The maximum length of a number (in decimal digits), which includes digits after the decimal point. Set at BC_OVERFLOW_MAX1.
 BC_RAND_MAX

The maximum integer (inclusive) returned by the rand() operand. Set at 2^BC_LONG_BIT1.
 Exponent

The maximum allowable exponent (positive or negative). Set at BC_OVERFLOW_MAX.
 Number of vars

The maximum number of vars/arrays. Set at SIZE_MAX1.
The actual values can be queried with the limits statement.
These limits are meant to be effectively nonexistent; the limits are so large (at least on 64bit machines) that there should not be any point at which they become a problem. In fact, memory should be exhausted before these limits should be hit.
ENVIRONMENT VARIABLES
bc(1) recognizes the following environment variables:
 POSIXLY_CORRECT

If this variable exists (no matter the contents), bc(1) behaves as if the s option was given.
 BC_ENV_ARGS

This is another way to give commandline arguments to bc(1). They should be in the same format as all other commandline arguments. These are always processed first, so any files given in BC_ENV_ARGS will be processed before arguments and files given on the commandline. This gives the user the ability to set up "standard" options and files to be used at every invocation. The most useful thing for such files to contain would be useful functions that the user might want every time bc(1) runs.
The code that parses BC_ENV_ARGS will correctly handle quoted arguments, but it does not understand escape sequences. For example, the string "/home/gavin/some bc file.bc" will be correctly parsed, but the string "/home/gavin/some "bc" file.bc" will include the backslashes.
The quote parsing will handle either kind of quotes, ' or ". Thus, if you have a file with any number of single quotes in the name, you can use double quotes as the outside quotes, as in "some 'bc' file.bc", and vice versa if you have a file with double quotes. However, handling a file with both kinds of quotes in BC_ENV_ARGS is not supported due to the complexity of the parsing, though such files are still supported on the commandline where the parsing is done by the shell.
 BC_LINE_LENGTH

If this environment variable exists and contains an integer that is greater than 1 and is less than UINT16_MAX (2^161), bc(1) will output lines to that length, including the backslash (\). The default line length is 70.
EXIT STATUS
bc(1) returns the following exit statuses:
 0

No error.
 1

A math error occurred. This follows standard practice of using 1 for expected errors, since math errors will happen in the process of normal execution.
Math errors include divide by 0, taking the square root of a negative number, using a negative number as a bound for the pseudorandom number generator, attempting to convert a negative number to a hardware integer, overflow when converting a number to a hardware integer, and attempting to use a noninteger where an integer is required.
Converting to a hardware integer happens for the second operand of the power (^), places (@), left shift (<<), and right shift (>>) operators and their corresponding assignment operators.
 2

A parse error occurred.
Parse errors include unexpected EOF, using an invalid character, failing to find the end of a string or comment, using a token where it is invalid, giving an invalid expression, giving an invalid print statement, giving an invalid function definition, attempting to assign to an expression that is not a named expression (see the Named Expressions subsection of the SYNTAX section), giving an invalid auto list, having a duplicate auto/function parameter, failing to find the end of a code block, attempting to return a value from a void function, attempting to use a variable as a reference, and using any extensions when the option s or any equivalents were given.
 3

A runtime error occurred.
Runtime errors include assigning an invalid number to ibase, obase, or scale; give a bad expression to a read() call, calling read() inside of a read() call, type errors, passing the wrong number of arguments to functions, attempting to call an undefined function, and attempting to use a void function call as a value in an expression.
 4

A fatal error occurred.
Fatal errors include memory allocation errors, I/O errors, failing to open files, attempting to use files that do not have only ASCII characters (bc(1) only accepts ASCII characters), attempting to open a directory as a file, and giving invalid commandline options.
The exit status 4 is special; when a fatal error occurs, bc(1) always exits and returns 4, no matter what mode bc(1) is in.
The other statuses will only be returned when bc(1) is not in interactive mode (see the INTERACTIVE MODE section), since bc(1) resets its state (see the RESET section) and accepts more input when one of those errors occurs in interactive mode. This is also the case when interactive mode is forced by the i flag or interactive option.
These exit statuses allow bc(1) to be used in shell scripting with error checking, and its normal behavior can be forced by using the i flag or interactive option.
INTERACTIVE MODE
Per the standard, bc(1) has an interactive mode and a noninteractive mode. Interactive mode is turned on automatically when both stdin and stdout are hooked to a terminal, but the i flag and interactive option can turn it on in other cases.
In interactive mode, bc(1) attempts to recover from errors (see the RESET section), and in normal execution, flushes stdout as soon as execution is done for the current input.
TTY MODE
If stdin, stdout, and stderr are all connected to a TTY, bc(1) turns on "TTY mode."
TTY mode is required for history to be enabled (see the COMMAND LINE HISTORY section). It is also required to enable special handling for SIGINT signals.
The prompt is enabled in TTY mode.
TTY mode is different from interactive mode because interactive mode is required in the bc(1) specification, and interactive mode requires only stdin and stdout to be connected to a terminal.
SIGNAL HANDLING
Sending a SIGINT will cause bc(1) to stop execution of the current input. If bc(1) is in TTY mode (see the TTY MODE section), it will reset (see the RESET section). Otherwise, it will clean up and exit.
Note that "current input" can mean one of two things. If bc(1) is processing input from stdin in TTY mode, it will ask for more input. If bc(1) is processing input from a file in TTY mode, it will stop processing the file and start processing the next file, if one exists, or ask for input from stdin if no other file exists.
This means that if a SIGINT is sent to bc(1) as it is executing a file, it can seem as though bc(1) did not respond to the signal since it will immediately start executing the next file. This is by design; most files that users execute when interacting with bc(1) have function definitions, which are quick to parse. If a file takes a long time to execute, there may be a bug in that file. The rest of the files could still be executed without problem, allowing the user to continue.
SIGTERM and SIGQUIT cause bc(1) to clean up and exit, and it uses the default handler for all other signals. The one exception is SIGHUP; in that case, when bc(1) is in TTY mode, a SIGHUP will cause bc(1) to clean up and exit.
COMMAND LINE HISTORY
bc(1) supports interactive commandline editing. If bc(1) is in TTY mode (see the TTY MODE section), history is enabled. Previous lines can be recalled and edited with the arrow keys.
Note: tabs are converted to 8 spaces.
LOCALES
This bc(1) ships with support for adding error messages for different locales and thus, supports LC_MESSAGES.
SEE ALSO
dc(1)
STANDARDS
bc(1) is compliant with the IEEE Std 1003.12017 (“POSIX.12017”) specification. The flags efghiqsvVw, all long options, and the extensions noted above are extensions to that specification.
Note that the specification explicitly says that bc(1) only accepts numbers that use a period (.) as a radix point, regardless of the value of LC_NUMERIC.
This bc(1) supports error messages for different locales, and thus, it supports LC_MESSAGES.
BUGS
None are known. Report bugs at https://git.yzena.com/gavin/bc.
AUTHORS
Gavin D. Howard yzena.tech@gmail.com and contributors.