Unix Shells: Bash, Fish, Ksh, Tcsh, Zsh

grammar | quoting and escaping | characters

variables | variable expansion | brace, tilde, command, and pathname expansion | special variables

arithmetic and conditional expressions

arrays | associative arrays

functions | command resolution | arguments and options

execution control

redirection | echo and read | files and directories

process and job control

history | key bindings

startup files | prompt customization | autoload





Shells read input up to an unquoted newline and then execute it. An unquoted backslash followed by a newline are discarded and cause the shell to wait for more input. The backslash and newline are discarded before the shell tokenizes the string, so long lines can be split anywhere outside of single quotes, even in the middle of command names and variable names.

In the shell grammar, lists contain sublists, which contain pipelines, which contain simple commands.

Subshells and grouping can be used to put a list in a pipeline. Subshells and groups can have newlines, but the shell defers execution until the end of the subshell or group is reached.

The section on execution control describes structures which do not fit into the simple grammar and execution model outlined here. The shell will not execute any of the control structures until the end keyword is reached. As a result, the control structure can contain multiple statements separated by newlines. Execution control structures cannot be put into pipelines.

In its simplest form a line in a shell script is a word denoting a command. The shell looks successively for a user-defined function, built-in function, and external command in the search path matching the word. The first one found is run. If no matching function or external command is found the shell emits a warning and sets its status variable to a nonzero value. It does not return the status value to its caller unless it has reached the end of its input, however.

tcsh lacks user defined functions but built-ins still take precedence over external commands.

Commands can be followed by one or more words which are the arguments to the command. How a shell tokenizes the input into words is complicated in the general case, but in the common case the arguments are whitespace delimited.

The standard output, standard input, and standard error of the command can be redirected to files. This is described under redirection.

A nonce environment variable can be set for the exclusive use of the command.

Pipelines are a sequence of simple commands in which the standard output of each command is redirected to the standard input of its successor.

A pipeline is successful if the last command returns a zero status.

Sublist is a term from the zsh documentation describing one or more pipelines separated by the shortcut operators && and || . When && is encountered, the shell stops executing the pipelines if the previous pipeline failed. When || is encountered, the shell stops executing if the previous pipeline succeeded. A sublist is successful if the last command to execute returns a zero status.

fish:

Fish has short-circuit operators; the following are equivalent to ls && ls and ls || ls :

$ ls ; and ls $ ls ; or ls

A list is a sequence of sublists separated by semicolons ; or ampersands & and optionally terminated by a semicolon or ampersand.

If the separator or terminator is an ampersand, the previous sublist is run in the background. This permits the shell to execute the next sublist or the subsequent statement without waiting for the previous sublist to finish.

A group command can be used to concatenate the stdout of multiple commands and pipe it to a subsequent command.

If the group has an input stream, it is consumed by the first command to read from stdin.

bash requires that the final command be terminated by a semicolon; zsh does not.

Like the group command, but the commands are executed in a subshell. Variable assignments or change of working directory are local to the subshell.

Literal quotes (aka single quotes) create a word with exactly the characters shown in the source code. For the shells other than fish there is no escaping mechanism and hence no way to put single quotes in the word.

Literal quotes can be used to put characters that the shell lexer uses to distinguish words inside a single word. For bash these characters are:

| & ; ( ) < > space tab

Literals quotes can also be used to prevent the parameter, brace, pathname, and tilde expansion as well as command substitution. For bash the special characters that trigger these expansions are:

$ { } * ? [ ] ` ~

Interpolating quotes (aka double quotes) perform parameter expansion and command substitution of both the $( ) and ` ` variety. They do not perform brace, pathname, or tilde expansion. $ and ` are thus special characters but they can be escaped with a backslash as can the backslash itself, the double quote, and a newline.

The escape sequences available in interpolating quotes.

String literals which support C-style escapes.

The C-style string literal escapes.

fish permits the use of C escapes outside of quotes.

How to execute a command and get the output as shell text.

If the command output contains whitespace, the shell may parse the output into multiple words. Double quotes can be used to guarantee that the command output is treated as a single word by the shell:

"$(ls)" "`ls`"

Escape sequences that can be used inside backtick quotes.

The shell tokenizes its input into words. Characters which are not word separating and do not have any word separating characters between them are part of the same word.

For two characters to be in different words, the presence of a word separating character between them is necessary but not sufficient, because the separating character must not be quoted or escaped.

The following two lines both tokenize as a single word:

"lorem ipsum" lorem" "ispum

The presence of shell expansion characters in a word causes the shell to perform a transformation on the word. The transformation may replace the word with more than one word.

In the following example, the word *.c will be replaced by multiple words if there is more than one file with a .c suffix in the working directory:

grep main *.c

Square brackets [ ] are used for both pathname expansion, where the brackets contain a list of characters, and array notation, where the brackets contain an index. We believe that in cases of ambiguity, the syntax is always treated as array notation. fish does not have this ambiguity because it does not use square brackets in pathname expansion.

zsh:

In zsh variable expansion will expand to a single word, even if the variable contains word separating characters. This behavior is different from the other shells.

A variable can be expanded to multiple words with the ${=VAR} syntax, however.

$ function countem() { echo $#; } $ foo='one two three' $ countem $foo 1 $ countem ${=foo} 3

comments:

The number sign # can be used to start a comment which ends at the end of the line. The # must be by itself or the first character in a word.

In tcsh , comments are not supported when the shell is interactive.

In zsh , comments are not supported by default when the shell is interactive. This can be changed by invoking zsh with the -k flag or by running:

set -o INTERACTIVE_COMMENTS

variable assignment:

The equals sign = is used for variable assignment in bash , ksh , and zsh . Given that spaces cannot be placed around the equals sign, it seems likely the tokenizer treats it like other bareword characters. Note that in a simple command, the command name is the first word which does not contain an equals sign.

namespaces:

ksh has namespaces. They can be used for variable names and function names:

$ bar=3 $ namespace foo { bar=4; } $ echo $bar 3 $ namespace foo { echo $bar; } 4 $ echo ${.foo.bar} 4

A bareword is a word which is not quoted and does not contain escapes. The characters which are listed above are those which can appear anywhere in a bareword.

Some of the other characters can appear in barewords under certain circumstances. For example the tilde ~ can appear if it is not the first character.

Characters which can be used in variable names.

Note that a variable name cannot start with a digit. Also, $_ is a special variable which contains the previous command.

bash fish ksh tcsh zsh external global variables



set, get, list, unset, edit var = val

$ var

set

unset -v var

none set -g var val

$ var

set -g

set -e var

vared var var = val

$ var

set

unset -v var

none set var = val

$ var

set

unset var

none var = val

$ var

set

unset -v var

vared var read-only variables



mark readonly, set and mark readonly, list readonly readonly var

readonly var = val

readonly -p none readonly var

readonly var = val

readonly -p none readonly var

readonly var = val

readonly -p exported variables



export, set and export, list exported, undo export export var

export var = val

export -p

export -n var set -gx var $ var

set -gx var val

set -x

set -gu var $ var export var

export var = val

export -p

none setenv var $ var

setenv var val

printenv

none export var

export var = val

export -p

none none

none

printenv

none options



set, list, unset set -o opt

set -o

set +o opt none set -o opt

set -o

set +o opt none set -o opt

set -o

set +o opt other variable built-ins declare @ declare

functions

setopt

float

integer

unsetopt

How to set a global variable; how to get the value of a global variable; how to list all the global variables; how to unset a global variable; how to edit a variable.

Variables are global by default.

In tcsh if var is undefined then encountering $var throws an error. The other shells will treat $var as an empty string.

If there is a variable named foo , then

unset foo

will unset the variable. However, if there is no such variable but there is a function named foo , then the function will be unset. unset -v will only unset a variable.

How to mark a variable as read-only; how to simultaneously set and mark a variable as read-only; how to list the read-only variables.

An error results if an attempt is made to modify a read-only variable.

How to export a variable; how to set and export a variable; how to list the exported variables.

Exported variables are passed to child processes forked by the shell. This can be prevented by launching the subprocess with env -i . Subshells created with parens ( ) have access non-exported variables.

The tcsh example for exporting a variable without setting it isn't the same as the corresponding examples from the other shells because in tcsh an error will result if the variable isn't already set.

Options are variables which are normally set via flags at the command line and affect shell behavior.

bash fish ksh tcsh zsh external set variable value var = val set -g var val var = val setenv var val var = val get variable value $ var $ var $ var $ var $ var concatenate variable and value ${ var } val {$ var } val ${ var } val ${ var } val ${ var } val coalesce ${ var :- val } ${ var :- val } ${ var :- val } coalesce and assign if null ${ var := val } ${ var := val } ${ var := val } message to stderr and exit if null ${ var :? msg } ${ var :? msg } ${ var :? msg } substring offset is zero based:

${ var : offset }

${ var : offset : len } offset is zero based:

${ var : offset }

${ var : offset : len } offset is zero based:

${ var : offset }

${ var : offset : len } offset is one based;

when input lacks newlines:

awk '{print substr($0, offset , len )}' length ${ # var } ${ # var } ${% var } ${ # var } wc -m remove prefix greedily foo=do.re.mi

${foo##*.} foo=do.re.mi

${foo##*.} foo=do.re.mi

${foo##*.} sed 's/^.*\.' remove prefix reluctantly foo=do.re.mi

${foo#*.} foo=do.re.mi

${foo#*.} foo=do.re.mi

${foo#*.} sed 's/^[^\.]*\.' remove suffix greedily foo=do.re.mi

${foo%%.*} foo=do.re.mi

${foo%%.*} foo=do.re.mi

${foo%%.*} sed 's/\..*$' remove suffix reluctantly foo=do.re.mi

${foo%.*} foo=do.re.mi

${foo%.*} foo=do.re.mi

${foo%.*} sed 's/\.[^\.]*$' single substitution foo='do re mi mi'

${foo/mi/ma} foo='do re mi mi'

${foo/mi/ma} foo='do re mi mi'

${foo/mi/ma} sed 's/mi/ma/' global substitution foo='do re mi mi'

${foo // mi/ma} foo='do re mi mi'

${foo // mi/ma} foo='do re mi mi'

${foo // mi/ma} sed 's/mi/ma/g' prefix substitution foo=txt.txt

${foo/#txt/text} foo=txt.txt

${foo/#txt/text} foo=txt.txt

${foo/#txt/text} sed 's/^txt/text/' suffix substitution foo=txt.txt

${foo/%txt/html} foo=txt.txt

${foo/%txt/html} foo=txt.txt

${foo/%txt/html} sed 's/txt$/html/' upper case foo=lorem

${foo^^} none foo=lorem

${foo:u} tr '[:lower:]' '[:upper:]' upper case first letter foo=lorem

${foo^} none none lower case foo=LOREM

${foo,,} none foo=LOREM

${foo:l} tr '[:upper:]' '[:lower:]' lower case first letter foo=LOREM

${foo,} none none absolute path foo=~

${foo:a} dirname foo=/etc/hosts

${foo:h} foo=/etc/hosts

dirname $foo basename foo=/etc/hosts

${foo:t} foo=/etc/hosts

basename $foo extension foo=index.html

${foo:e} root foo=index.html

${foo:r}

bash fish ksh tcsh zsh brace expansion: list echo {foo,bar} echo {foo,bar} echo {foo,bar} echo {foo,bar} echo {foo,bar} brace expansion: sequence echo {1..10} none echo {1..10} none echo {1..10} brace expansion: character sequence echo {a..z} none echo {a..z} none none tilde expansion echo ~/bin echo ~/bin echo ~/bin echo ~/bin echo ~/bin command expansion: dollar parens echo $(ls) echo (ls) echo $(ls) none echo $(ls) command expansion: backticks echo `ls` none echo `ls` echo `ls` echo `ls` process substitution wc <(ls) wc (ls | psub) wc <(ls) none wc <(ls) path expansion: string echo /bin/c* echo /bin/c* echo /bin/c* echo /bin/c* echo /bin/c* path expansion: character echo /bin/c?? echo /bin/c?? echo /bin/c?? echo /bin/c?? echo /bin/c?? path expansion: character set echo /bin/[cde]* none echo /bin/[cde]* echo /bin/[cde]* echo /bin/[cde]* path expansion: negated character set echo /bin/[^cde]* none echo /bin/[^cde]* echo /bin/[^cde]* echo /bin/[^cde]* path expansion: sequence of characters echo /bin/[a-f]* none echo /bin/[a-f]* echo /bin/[a-f]* echo /bin/[a-f]*

in zsh terminology, special means read-only variables that cannot have their type changed

non-alphabetical variables bash fish ksh tcsh zsh name of shell or shell script $0 (status -f) $0 $0 $0 command line arguments $1, $2, … $argv[1], $argv[2], … $1, $2, … $1, $2, … $1, $2, …

$argv[1], $argv[2], … number of command line args $# (count $argv) $# $# $#

$#argv arguments $1, $2, … $*

$@ none $*

$@ $* $*

$@ "$1" "$2" "$3" … "$@" $argv "$@" "$@" "$1 c $2 c $3 …" where c is first character of $IFS "$*" "$argv" "$*" "$*" process id $$ %self $$ $$ $$ process id of last asynchronous command $! none $! $! $! exit status of last non-asynchronous command $? $status $? $? $? previous command executed $_ current command executing:

$_ $_ $_ $_ command line options $- none $- none $- read input none none none $< none

$* and $@

These parameters behave differently in double quotes.

Normally you should use "$@" to pass all the parameters to a subcommand. The subcommand will receive the same number of parameters as the caller received.

"$*" can be used to collect the parameters in a string. The first character of $IFS is used as the join separator. This could be used to pass all of the parameters as a single parameter to the subcommand.

Outside of double quotes, $* and $@ have the same behavior. Their behavior varies from shell to shell, however. In bash if you use them to pass parameters to a subcommand, the subcommand will receive more parameters than the caller if any of the parameters contain whitespace.

In zsh $* and $@ behave like "$@".

set by shell bash fish ksh tcsh zsh shell version BASH_VERSION KSH_VERSION tcsh ZSH_VERSION return value of last syscall ERRNO history history current line number of script LINENO LINENO LINENO set by getopts OPTARG

OPTIND OPTARG

OPTIND OPTARG

OPTIND operating system and machine type OSTYPE

MACHTYPE shell parent pid PPID PPID PPID working directory and previous working directory PWD

OLDPWD PWD

none PWD

OLDPWD PWD

OLDPWD random integer RANDOM built-in function:

random RANDOM RANDOM return value REPLY REPLY REPLY seconds since shell was invoked SECONDS SECONDS SECONDS incremented each time a subshell is called SHLVL SHLVL

read by shell bash fish ksh tcsh zsh browser BROWSER cd search path CDPATH CDPATH CDPATH cdpath CDPATH

cdpath terminal width and height COLUMNS

LINES COLUMNS

LINES command history editor FCEDIT

EDITOR FCEDIT

EDITOR FCEDIT

EDITOR shell startup file ENV ENV ENV function definition search path FPATH fpath

FPATH history file path HISTFILE HISTFILE HISTFILE size of history HISTSIZE HISTSIZE HISTSIZE home directory HOME HOME HOME HOME input field separators IFS IFS IFS locale LANG LANG LANG null redirect command NULLCMD

READNULLCMD command search path PATH PATH PATH PATH prompt customization

main, secondary, select, trace PS1 PS2 PS4 PS1 PS2 PS3 PS4 PS1 PS2 PS3 PS4 right prompt customization RPS1 RPS2 terminal type TERM TERM timeout TMOUT TMOUT system tmp directory TMPDIR user USER

Expressions are implemented as either command expressions which return an integer status like a command, or variable expressions which evaluate to a string. Command expressions return a status of 0 for true and a nonzero status for false. Only commands and command expressions can be used as the conditional in if, while, and until statements.

Expressions which support arithmetic only support integer arithmetic.

[ ] [[ ]] $(( )) (( )) ( ) expr math name test command conditional command arithmetic expansion arithmetic command conditional expression external expression used as command command argument command tcsh conditionals command fish expressions word splitting? yes no expansions true anything but '' anything but '' 1 1 1 anything but '' or 0 falsehoods '' '' 0 0 0 '' 0 '' logical operators -a -o ! && || ! && || ! && || ! && || ! & | none regex comparison operator none =~ none none str : regex string comparison operators = != == != none none == != = > >= < <= !=

but comparison is numeric if operands are digits arithmetic comparison operators -eq -ne -lt -gt -le -ge -eq -ne -lt -gt -le -ge == != < > <= >= == != < > <= >= == != < > <= >= = > >= < <= != arithmetic operators none none + - * / % ** + - * / % ** + - * / % + - * / % grouping \( \) 2 * (3 + 4) use cmd substitution, ie. for bash:

expr 2 \* $(expr 3 + 4) assignment none none $(( n = 7 ))

echo $n (( n = 7 ))

echo $n compound assignment none none += -= *= /= %=

and others += -= *= /= %=

and others comma and increment none none $(( n = 7, n++ ))

echo $n (( n = 7, n++ ))

echo $n bit operators none none << >> & | ^ ~ << >> & | ^ ~ << >> & | ^ ~ file tests -e EXISTS?

-d DIR?

-f REGULAR_FILE?

-(h|L) SYMLINK?

-p NAMED_PIPE?

-r READABLE?

-s NOT_EMPTY?

-w WRITABLE?

-x EXECUTABLE?

-S SOCKET?

The name of the expression.

An arithmetic command can be used to test whether an arithmetic expression is zero.

Supports the same type of expressions as $(( )) .

A no-op command with an exit status of 0. One application is to create an infinite loop:

while true; do echo "Are we there yet?" done

A no-op command with an exit status of 1. One application is to comment out code:

if false; then start_thermonuclear_war fi

How to evaluate a string as a shell command.

bash fish ksh tcsh zsh declare typeset -a var none none none typeset -a var list all arrays typeset -a none none none typeset -a literal a=(do re mi) set a do re mi a=(do re mi) set a = (do re mi) a=(do re mi) lookup ${a[0]} $a[1] ${a[0]} ${a[1]} ${a[1]}

$a[1] negative index lookup returns last element:

${a[-1]} returns last element:

$a[-1] returns last element:

${a[-1]} none returns last element:

${a[-1]} slice ${a[@]:2:3}

${a[*]:2:3} $a[(seq 2 3)] ${a[@]:1:2}

${a[*]:1:2} ${a[2-3]} $a[2,3] update a[0]=do

a[1]=re

a[2]=mi set a[1] do

set a[2] re

set a[3] mi a[0]=do

a[1]=re

a[2]=mi set a[1] = do

set a[2] = re

set a[3] = mi a[1]=do

a[2]=re

a[3]=mi out-of-bounds behavior lookup returns empty string



update expands array; array can have gaps error message and nonzero exit status



update expands array; in-between

slots get empty strings lookup returns empty string



update expands array; array can have gaps lookup and update both produce

error message and nonzero exit status lookup returns empty string



update expands array; in-between

slots get empty strings size highest index:

${#a[@]}

${#a[*]} count $a highest index:

${#a[@]}

${#a[*]} ${#a} ${#a}

${#a[@]}

${#a[*]} list indices can contain gaps:

${!a[@]}

${!a[*]} (seq (count $a)) can contain gaps:

${!a[@]}

${!a[*]} `seq ${#a}` $(seq ${#a}) regular reference return first element return all elements joined by space return first element return all elements joined by space return all elements joined by space regular assignment assigns to 0-indexed slot convert array to regular variable assigns to 0-indexed slot convert array to regular variable convert array to regular variable delete element unset a[0] set -e a[1]

re is now at index 1 a[0]=() delete array unset a[@]

unset a[*] set -e a unset -v a pass each element as argument cmd "${a[@]}" cmd $a cmd "${a[@]}" cmd "${a[@]}" pass as single argument cmd "${a[*]}" cmd "$a" cmd "${a[*]}" cmd "${a[*]}"

Shell arrays are arrays of strings. In particular arrays cannot be nested.

Arrays with one element are for the most part indistinguishable from a variable containing a nonempty string. Empty arrays are for the most part indistinguishable from a variable containing an empty string.

In the case of bash or zsh , it is possible to tell whether the variable is an array by seeing whether it is listed in the output of typeset -a .

declare

bash and zsh allow one to declare an array. This creates an empty array. There doesn't appear to be any need to do this, however,

list all arrays

literal

bash and zsh us parens to delimit an array literal. Spaces separate the elements. If the elements themselves contain spaces, quotes or backslash escaping must be used.

lookup

update

out-of-bounds behavior

size

list indices

regular reference

regular assignment

delete value

Deleting elements from a bash array leaves gaps. Deleting elements from a zsh arrays causes higher indexed elements to move to lower index positions.

delete array

bash fish ksh tcsh zsh declare typeset -A var none none none typeset -A var list all associative arrays typeset -A none none none typeset -A assign value foo[bar]=baz none none none foo[bar]=baz lookup ${foo[bar]} none none none ${foo[bar]} list indices ${!foo[@]}

${!foo[*]} none none none delete value unset "foo[bar]" none none none unset "foo[bar]" delete array unset " var [@]" none none none unset -v foo

Associative arrays were added to bash with version 4.0.

How to define a function.

POSIX calls for parens in the declaration, but parameters are not declared inside the parens, nor are parens used when invoking the function. Functions are invoked with the same syntax used to invoke external commands. Defining a function hides a built-in or an external command with the same name, but the built-in or external command can still be invoked with the builtin or command modifiers.

How to define a function using the function keyword.

The variables which hold the function parameters.

Outside of a function the variables $1, $2, … refer to the command line arguments provided to the script.

$0 always refers the name of the script in a non-interactive shell.

The variable containing the number of function parameters which were provided.

Outside of a function $# refers to the number of command line arguments.

If a function does not have an explicit return statement then the return value is the exit status of the last command executed. If no command executed the return value is 0.

Shell functions can only return integers. Some shells limit the return value to a single byte. This is all the information one can get from the exit status of an external process according to the POSIX standard.

If a shell function needs to return a different type of value, it can write it to a global variable. All variables are global by default. The value in one of the parameters can be used to determine the variable to which the return value will be written. Consider this implementation of setenv :

setenv() { eval $1=$2 }

How to declare and set a local variable.

Local variables are normally defined inside a function. bash throws an error when an attempt is made to define a local outside a function, but dash and zsh do not.

Local variables have lexical, not dynamic scope. If a function recurses, locals in the caller will not be visible in the callee.

How to list the user defined functions.

typeset -f without an argument will show all function definitions.

bash and zsh always the function definitions with the paren syntax, even if the function keyword syntax was used to define the function.

How to show the definition of a function.

How to remove a user defined function.

Alias expansion is done after history expansion and before all other expansion. A command can be expanded by multiple aliases. For example the following will echo "baz":

alias bar=echo "baz" alias foo=bar foo

On the other hand the shells seem smart enough about aliasing to not be put into an infinite loop. The following code causes an error "foo not found":

alias foo=bar alias bar=foo foo

Alias definitions are not registered until an entire line of input is read. The following code causes an error "lshome not found":

alias lshome='ls ~'; lshome

User defined functions can replace aliases in the shells which have them; i.e. all shells except tcsh .

The Korn shell has a feature called tracked aliases which are identical to the external command hashes of the other shells.

When resolving commands, user-defined functions take precedence over external commands. If a user-defined function is hiding an external command, the command modifier can be used to run the latter.

How to run a command with an explicit environment. env -i clears the environment of exported variables and only provides the external command with the environment variables that are explicitly specified. If the -i option is not specified then the environment is not cleared, which in many cases is no different than if the command had been run directly without the env command. The env command without the -i option is used in shebang scripts to avoid hard-coding the path of the interpreter.

Multiple environment variables can be set with the env command:

env -i VAR1=VAL1 VAR2=VAL2 ... CMD

External command hashes are a mapping from command names to paths on the file system.

The Korn Shell calls external command hashes "tracked aliasaes", and ksh defines hash as an alias for alias -t .

Determine what type a command is. The possible types are alias, shell function, shell builtin, or a path to an external command. If the command is not found an exit status of 1 is returned.

Return the absolute path for an external command. For shell functions and shell builtins the name of the command is returned. For aliases the statement used to define the alias is returned. If the command is not found an exit status of 1 is returned.

options can be set by the script using set . Also set -o (bash) and pipefail.

Shell executes a single command which is provided on the command line and then exits.

Shell provides list of options and exits.

An interactive shell is one that is not provided a script when invoked as an argument or is not invoked with the -c option. The -i option makes a script interactive regardless. Typically an interactive shell gets its input from and sends its output to a terminal. An interactive shell ignores SIGTERM and will handle but not exit when receiving a SIGINT. Interactive shells display a prompt and enable job control. In an interactive shell the octothorpe # causes a syntax error, unlike in non-interactive shells where it is treated as the start of a comment.

A login shell is a special type of interactive shell. It executes different startup files and will also execute any logout files. When it exits it sends a SIGHUP to all jobs. (is this true?) A login shell ignores the suspend built-in.

Change the behavior of the shell to be more POSIX compliant.

Shell runs in restricted mode.

Show version and exit.

Outside of a function shift operates on the command line arguments. Inside a function shift operates on the function arguments.

How to set the positional parameters from within a script.

How to process command line options.

getopts operates on the positional parameters $1, $2, …

The first argument to getopts is a word specifying the options. The options are single characters which cannot be ':' or '?'. The colon ':' indicates that the preceding letter is an option which takes an argument. If an option is encountered which is not in the option word, getopts sets the variable to '?'.

while getopts a:b:c:def OPT do case $OPT in a) OPTA=$OPTARG ;; b) OPTB=$OPTARG ;; c) OPTC=$OPTARG ;; d) OPTD=1 ;; e) OPTE=1 ;; f) OPTF=1 ;; esac done

bash fish ksh tcsh zsh negate exit status ! cmd not cmd ! cmd ! cmd no-op command : : : : break break break break break break case case arg in

pattern ) cmd ;;

…

*) cmd ;;

esac switch arg

case pattern …

cmd

…

…

case '*'

cmd

…

end case arg in

pattern ) cmd ;;

…

*) cmd ;;

esac switch ( arg )

case pattern :

cmd

…

breaksw

…

default:

cmd

…

breaksw

endsw case arg in

pattern ) cmd ;;

…

*) cmd ;;

esac continue continue continue continue continue continue for for var in arg …

do

cmd

…

done for var in arg …

cmd

…

end for var in arg …

do

cmd

…

done foreach var ( arg … )

cmd

…

end for var in arg …

do

cmd

…

done goto goto label if if test

then

cmd

…

elif test

then

cmd

…

else

cmd

…

fi if test

cmd

…

else if test

cmd

…

else

cmd

…

end if test

then

cmd

…

elif test

then

cmd

…

else

cmd

…

fi if ( expr ) then

cmd

…

else if ( expr ) then

cmd

…

else

cmd

…

endif if test

then

cmd

…

elif test

then

cmd

…

else

cmd

…

fi repeat repeat count cmd repeat count do

cmd

…

done select select var in arg …

do

cmd

…

done select var in arg …

do

cmd

…

done select var in arg …

do

cmd

…

done until until test

do

cmd

…

done until test

do

cmd

…

done until test

do

cmd

…

done while while test

do

cmd

…

done while test

cmd

…

end while test

do

cmd

…

done while ( expr )

cmd

…

end while test

do

cmd

…

done

How to run a command and logically negate the exit status. This can be useful if the command is run as the conditional of a if statement.

The ! precommand modifier converts a zero exit status to 1 and a nonzero exit status to 0.

The ! must be separated from the command by whitespace, or it will be interpreted by the shell as a history substitution.

break

Exits the enclosing for, select, until, or while loop.

case

The syntax for a switch statement.

Default clauses, which are indicated by the * pattern in most shells, are optional.

continue

Go to the next iteration of the enclosing for, select, until, or while loop.

for

A loop for iterating over a list of arguments.

zsh has alternate syntax which uses parens instead of the in keyword:

for VAR (ARG ...) do CMD ... done

goto

tcsh supports the goto statement. The target the first line containing just the label followed by a colon. Here's an example:

#/bin/tcsh goto foo echo "goto doesn't work!" exit -1 foo: echo "goto works"

if

The if statement.

The test which is the argument of if or elif can be any simple command, pipeline, or list of commands. The test executes and if the exit status is zero the corresponding clause is also executed.

Often the test which is the argument of if or elif will be one of the test operators: test , [ ] , [[ ]] , or (( )) .

The elif and else clauses are optional.

tcsh:

The argument of if and elif clauses must be an expression inside parens. Unlike the other shells it cannot be an arbitrary command. One can think of expressions as being built-in to the tcsh shell language rather than being delegated to specialized (albeit built-in) commands such as test and [ ] .

Note that the then keyword must be on the same line as the conditional expression. This is different from the POSIX syntax where the then keyword is separated from the test command by a newline or semicolon.

The else if and else clauses are optional.

tcsh has the following syntax for conditionally executing a single command:

if (EXPR) CMD

repeat

Here are a couple of ways to do something 10 times if you aren't using tcsh . Neither technique is POSIX compliant, however:

for i in `seq 1 10`; do echo "la"; done for i in {1..10}; do echo "la"; done

select

The select statement creates a numbered menu inside an infinite loop. Each time the user selects one of the numbers the corresponding command is executed. The user can use ^D or EOF to exit the loop.

On each iteration var is set to the value corresponding to the number the user chose. The break keyword can be used to give the user a numbered option for exiting the loop.

until

The remarks above on if conditions also apply to the until loop condition.

while

The remarks above on if conditions also apply to the while loop condition.

bash fish ksh tcsh zsh stdin from file tr a-z A-Z < file tr a-z A-Z < file tr a-z A-Z < file tr a-z A-Z < file tr a-z A-Z < file stdout to file ls > file ls > file ls > file ls > file ls > file stderr to file ls /not_a_file 2> file ls /not_a_file ^ file ls /not_a_file 2> file none ls /not_a_file 2> file stdout and stderr to file ls > file 2>&1 ls > file ^&1 ls > file 2>&1 ls >& file ls > file 2>&1 append stdout to file ls >> file ls >> file ls >> file ls >> file ls >> file append stderr to file ls 2 >> file ls ^^ file ls 2 >> file none ls 2 >> file append stdout and stderr to file ls >> /tmp/bash.out 2>&1 ls >> /tmp/bash.out ^&1 ls >> /tmp/bash.out 2>&1 ls >> & file ls >> /tmp/zsh.out 2>&1 stdout to pipe ls | wc ls | wc ls | wc ls | wc ls | wc sdout and stderr to pipe ls 2>&1 | wc ls ^&1 | wc ls 2>&1 | wc ls |& wc ls 2>&1 | wc stdin from here-document wc << EOF

do

re

mi

EOF none wc << EOF

do

re

mi

EOF wc << EOF

do

re

mi

EOF wc << EOF

do

re

mi

EOF stdin from here-string wc <<< "do re mi" none wc <<< "do re mi" none wc <<< "do re mi" tee stdout ls | tee file | wc ls > file | wc stdout to two files ls | tee file1 | tee file2 > /dev/null ls > file1 > file2 turn on noclobber set -o noclobber set -o noclobber set noclobber set -o noclobber clobber file anyways ls >! /tmp/exists.txt ls >! /tmp/exists.txt ls >! /tmp/exists.txt ls >! /tmp/exists.txt turn off noclobber set +o noclobber set +o noclobber unset noclobber set +o noclobber

A gap in the above chart is how to redirect just stderr to a pipe. One would guess by analogy with 2> and 2>> that this might work:

$ ls 2| wc

However, none of the shells support it. The correct syntax is:

$ ls 3>&1 1>&2 2>&3 | wc

The 3>&1 is equivalent to the C system call dup2(1, 3) . This makes file descriptor 3 a copy of file descriptor 1.

The 1>&2 is equivalent to the C system call dup2(2, 1) . This changes what file descriptor 1 writes to, but does not change what file descriptor 3 writes to, even though file descriptor 3 was initially a copy of file descriptor 1. The shell processes the redirect statements from left to right. Also note that the 1 could be omitted: 1>&2 and >&2 are the same.

zsh only supports file descriptors 0 through 9, but bash supports higher numbered file descriptors. The shell always opens file descriptors 0, 1, and 2, commonly called stdin , stdout , and stderr , for each simple command that it invokes. If additional file descriptors are specified, those are also passed to the command. For example, if foo were invoked as:

$ foo 3> /tmp/bar.txt

then it could contain a system call which writes to file descriptor 3 without opening it first, e.g.

write(3, msg, strlen(msg));

Paths in the /dev directory can be used in place of &1 , &2 , …

$ ls 3> /dev/fd/1 1> /dev/fd/2 2> /dev/fd/3 | wc $ ls 3> /dev/stdout 1> /dev/stderr 2>&3 | wc

tcsh:

It is possible to redirect stdout and stderr to different files:

$ ( ls > /tmp/stdout.txt ) >& /tmp/stderr.txt

bash fish ksh tcsh zsh echo

with newline, without newline echo arg …

echo -n arg … echo arg …

echo -n arg … echo arg …

echo -n arg … echo arg …

echo -n arg … echo arg …

echo -n arg … printf printf fmt arg … printf fmt arg … printf fmt arg … printf fmt arg … printf fmt arg … read



read values separated by IFS; with prompt; without backslash escape read var …

read -p str var

read -r var … read var …

read -p 'echo str ' var read var …

read var ? str

read -r var … echo -n str

set var =$< read var …

read var \? str

read -r var …

How to echo the arguments separated by spaces and followed by a newline; how to suppress the trailing newline.

The POSIX standard says that echo should not have any options. It also says, perhaps contradicting itself, that if the first argument is -n then the behavior is implementation dependent.

The POSIX standard also says that if any of the arguments contain backslashes, then the behavior is implementation dependent. Historically implementations have used the -E and -e options to enable or disable the interpretation of C-style backslash escape sequences.

fish provides an -s option for printing the arguments without spaces in-between.

Because if the ill-defined behavior of echo , POSIX-compliant scripts use printf instead.

printf is an external command line tool, though zsh also has a built-in version.

man 3 printf

Like its counterpart from the C standard library, printf does not write a newline to stdout unless one is specified in the format using a backslash escape sequence.

Unfortunately, the supported backslash ecscapes are system dependent, though some of them are mandated by POSIX:

posix bsd gnu backslash escapes \a \b \c \f

\r \t \v \\

\ o \ oo \ ooo \a \b \c \f

\r \t \v \\ \'

\ o \ oo \ ooo \a \b \c \e \f

\r \t \v \\ \"

\ o \ oo \ ooo \x hh \u hhhh \U hhhhhhhh

An interesting backslash escape is \c, which causes the rest of the format to be ignored.

In a printf format, format specifiers are of the form %d , %f and %s .

posix bsd gnu format specifiers diouxX

fFaAeEgG

csb diouxX

feEgG

csb

format specifiers; many of which are useless in this context because of fewer types

how invalid arguments are handled

%%

extra specifiers with floats

extra specifiers with strings

How to read a line of input into one or more variables.

When multiple variables are specified the value of IFS which by default contains the whitespace characters is used to split the input. If there are fewer variables than split values, then the last variable will contain a concatenation of the remaining values with their original separators. If there are fewer values then the extra variables are set to the empty string.

bash and dash use the -p option to set a prompt. ksh and zsh use a ?str suffix appended to the first variable to set the prompt.

fish uses the -p option, but it evaluates the string to produce the prompt. This makes it possible to set the color of the prompt:

read -p 'set_color green; echo -n "> "; set_color normal' foo

The user can put a backslash in front of a newline to split the input up over multiple lines. The backslash and newline are stripped from the input. The user can put backslash into the variable by entering two backslashes. The -r option disables this feature, allowing the user to enter literal backslashes with a single keystroke.

tcsh gets input from the user by reading from the special variable $< . Backslashes are always interpreted literally.

bash fish ksh tcsh zsh change current directory



change dir, to home dir, to previous dir, show physical dir, no symlink dir cd dir

cd

cd -

cd -P dir

none cd dir

cd

cd -

none

none cd dir

cd

cd -

cd -P dir

none cd dir

cd

cd -

none

none cd dir

cd

cd -

cd -P dir

cd -s dir directory stack:



push, pop, list pushd dir

popd

dirs pushd dir

popd

dirs pushd dir

popd

dirs pushd dir

popd

dirs print current directory pwd pwd pwd pwd pwd source source file arg …

. file arg … source file

. file source file arg …

. file arg … source file arg … source file arg …

. file arg … umask



set umask in octal, in symbolic chmod format; show umask in octal, in symbolic chmod format umask 022

umask g-w,o-w

umask

umask -S umask 022

umask g-w,o-w

umask

umask -S umask 022

umask g-w,o-w

umask

umask -S umask 022

none

umask

none umask 022

umask g-w,o-w

umask

umask -S

Change the current directory to the specified directory. If the directory starts with a slash '/' then it is taken to be an absolute path. If it does not it is treated as a relative path and CDPATH is used as a colon separated list of starting directories. By default CDPATH is empty in which case the current directory '.' is used as a starting point. See also the section on tilde expansion.

If there is no argument then the current directory is changed to $HOME.

If the argument is a hyphen '-' then the current directory is changed to $OLDPWD which is the most recent former current directory.

When the -P option is used, PWD will be set to the physical path of the current directory; i.e. any symbolic links will be resolved. If the current directory is being displayed in the prompt this will also be set the physical path.

zsh:

When the -s option is used, attempting to change directory into a path containing symlinks will fail.

Push a directory provided as an argument onto the directory stack. The directory becomes the current directory.

Pop a directory off the directory stack. The popped directory becomes the current directory.

List the directory stack.

Show the current directory. The same as executing:

echo $PWD

The source built-in executes the commands in another file using the current shell process and environment.

Some shells have a non-POSIX feature which allows arguments to be passed to the file being sourced; i.e. the following invocation would set $1 , $2 , and $3 to bar , baz , and quux while executing foo.sh :

source foo.sh bar baz quux

The . syntax is part of the POSIX standard, but the source syntax is not.

The file to be sourced may be specified with an absolute path. Some shells will also search the working directory or PATH for the file to be sourced:

bash fish ksh tcsh zsh searches working directory yes yes no yes . no, source yes searches PATH yes no no no yes

Set the shell file mode creation mask. umask is a POSIX syscall.

The mask consists of 3 octal digits which apply to the user, group, and other permissions respectively. Each octal digit contains 3 bits of information. In order of most to least significant the bits apply to the read, write, and execute permissions.

Setting a bit in the mask guarantees that the corresponding bit in the file permissions will not be set when a file is created. The logic for computing the file permissions can be expressed with the following shell code:

mask=8#022 perms=8#777 printf "0%o

" $(( $perms & ~ $mask ))

Here is the same logic in C code:

unsigned int mask = 0022; unsigned int perms = 0777; printf("%o

", perms & ~mask);

If umask is given a numeric argument it is always interpreted as octal; a leading zero is not required.

umask also supports the symbolic notation used by chmod. In this case the argument is one or more 3 character sequences of the format [agou][-+][rwx] separated by commas.

bash fish ksh tcsh zsh run job in background bg bg bg bg bg protect job from hangup signal disown does not SIGHUP background jobs on exit disown disown execute file exec [-c] exec exec exec exec exit exit [n] exit exit exit exit

bye run job in foreground fg fg fg fg fg hup list jobs jobs [-lnprs] jobs jobs jobs jobs send signal kill external, but …

kill kill kill kill limit limit login logout logout logout nice nohup onintr sched sched sleep stop suspend suspend suspend suspend time time time times times times trap trap trap trap ulimit ulimit ulimit ulimit unlimit unlimit wait wait wait wait ______________________ ______________________ ______________________ ______________________ ______________________

xargs splits standard input on spaces and newlines and feeds the arguments to argument of xargs which is executed as a command. The input delimiter can be changed to null characters with the -0 flag (useful with find -print0 ) or to the value of the -d flag argument.

By default if the length of the input is more than 4096 characters the input will be broken up and the command run multiple times. This number can be increased with the -s flag up to system configuration variable ARG_MAX. It is also possible to call the command multiple times feeding it a prescribed number of arguments each time using the -n flag. The -t flag will write to standard error the command that is being invoked and its arguments before each invocation.

The -P flag can be used to for parallelization. The argument is the max number of simultaneous processes.

history commands bash fish ksh tcsh zsh command history:



list recent, list all, list with time, unnumbered list fc -l

history

set HISTTIMEFORMAT

fc -ln history | nl | head

history | nl

cat ~/.config/fish/fish_history

history ??

fc -l 1

none

?? history 15

history

history -T

none history

history 1

history -f

history -n command history:



run, find and run ! num

fc -s str r num

fc -s none

none ! num

?? command history:



delete from history, clear history history -d num

history -c none

none none

history -c none

none command history:



fix, find and substitute fc num

fc -s old = new str fc num

fc -s old = new str fc num

none command history:



write to file, append to file, read from file history -w path

history -a path

history -r path fc -W path

fc -A path

fc -R path

How to list recent commands; how to list all commands; how to list commands with the time they were run.

How to run a command in the history by command number; how to run the most recent command in the history matching a prefix.

How to delete a command from the history by command number; how to clear the command history.

Use the following syntax to edit commands from the history list and run them:

fc [-e EDIT_CMD] [-r] [FIRST [LAST]]

If EDIT_CMD is not specified, the value in the FCEDIT or EDITOR environment variable is used.

If FIRST and LAST are specified, these indicate the numbers of the range of commands to edit. If FIRST is specified but LAST is not, only that command at that number is edited and run. If neither is specified the last command is edited and run.

The -r flag reverses the order of the commands.

To simply list commands the following flags can be used:

fc -l[r] [FROM] fc -l[r] -NUMBER_CMDS

If neither FROM nor -NUMBER_CMDS is specified the last 16 commands is printed. Use -NUMBER_CMDS (i.e. a negative number) to list the last NUMBER_CMDS commands. Use FROM (i.e. a positive number) to list all commands from FROM on.

The -r flag reverses the order of the commands

To rerun a recent command without editing it use:

fc -s [PAT=REP] [START_OF_CMD]

If START_OF_CMD is specified the last command that starts with START_OF_CMD will be run. If START_OF_CMD is not specified the last command will be run.

If PAT=REP is specified then each occurrence of PAT will be replaced with REP in the command before it is run.

ksh:

hist is a synonym for fc with the sole difference that HISTEDIT is the environment variable that determines the editor instead of FCEDIT.

zsh:

r is an alias for fc -s

history expansion bash fish ksh tcsh zsh most recent command !! none none !! !! n-th command ! n none none ! n ! n most recent command starting with str ! str none none ! str ! str most recent command with substitution ^ pattern ^ replacement none none ^ pattern ^ replacement ^ pattern ^ replacement nth command with substitution ! n :s/ pattern / replacement / none none ! n :s/ pattern / replacement / ! n :s/ pattern / replacement / n-th command with global substitution ! n :gs/ pattern / replacement / none none ! n :gs/ pattern / replacement / ! n :gs/ pattern / replacement / most recent arguments !* none none !* first of most recent arguments !:1 none none !:1 range of most recent arguments !: n - m none none !: n - m last of most recent arguments !$ none none !$ most recent command without arguments !:0 none none !:0 m-th argument of n-th command ! n : m none none ! n : m

history file bash fish ksh tcsh zsh location HISTFILE=~/.bash_history ~/.config/fish/fish_history HISTFILE=~/.ksh_history set histfile ~/.tcsh_history HISTFILE=~/.zsh_history memory size HISTSIZE=2000 HISTSIZE=2000 HISTSIZE=2000 file size HISTFILESIZE=2000 set savehist=2000 SAVEHIST=2000 format lines of input timestamps HISTTIMEFORMAT=%s update time on exit on exit update method appends to file;

to only keep most recent dupe:

HISTCONTROL=erasedups appends to file;

to sort in memory file and most recent by timestamp and only keep the most recent, use:

set savehist=2000 merge ignore HISTIGNORE=history:whoami

bash fish ksh tcsh zsh list keybindings bind -P bind bindkey bindkey list keymaps help bind none none bindkey -l current keymap name bind -V | grep keymap none none change keymap bind 'set keymap emacs' none none bindkey -A emacs main list bindable functions bind -l bind -f bindkey -l bind key to function bind C-a:beginning-of-line bind \ca beginning-of-line restore default binding for key

bash and zsh have keymaps

how to create a new keymap with zsh

alternate fish syntax referring to keys

bash fish ksh tcsh zsh non-interactive shell startup files $BASH_ENV ~/.config/fish/config.fish $ENV /etc/csh.cshrc

~/.tcshrc

~/.cshrc /etc/zshenv

$ZDOTDIR/.zshenv login shell startup files /etc/profile

~/.bash_profile

~/.bash_login

~/.profile ~/.config/fish/config.fish /etc/profile

~/.profile

$ENV /etc/csh.login

~/.login non-interactive startup files

/etc/zprofile

$ZDOTDIR/.zprofile

/etc/zshrc

$ZDOTDIR/.zshrc

/etc/zlogin

$ZDOTDIR/.zlogin other interactive shell startup files ~/.bashrc ~/.config/fish/config.fish $ENV none non-interactive startup files

/etc/zshrc

$ZDOTDIR/.zshrc login shell logout files ~/.bash_logout none none /etc/csh.logout

~/.logout $ZDOTDIR/.zlogout

/etc/zlogout

bash:

When logging in bash will only execute one of ~/.bash_profile , ~/.bash_login , or ~/.profile . It executes the first file that exists.

fish:

The startup file .config/fish/config.fish is run by all shells. Here is how to put code in it which only executes at login:

if status --is-login set PATH $PATH ~/bin end

How to define an exit handler:

function on_exit --on-process %self echo fish is exiting ... end

bash fish ksh tcsh zsh set primary prompt PS1='$ ' function fish_prompt

echo -n '$ '

end PS1='$ ' set prompt='$ ' PS1='$ ' set continued line prompt PS2='> ' none PS2='> ' set prompt2='> ' PS2='> ' set select prompt PS3='? ' none PS='? ' none PS3='? ' set right prompt none function fish_right_prompt

date

end set rprompt='%Y-%W-%D %p' RPS1='%D{%F %T}' set right continued line prompt none none none RSP2=' ... ' dynamic information working directory none pwd %/ %d

%/ working directory with tilde abbrev \w abbreviate path components other

than basename with single letter:

prompt_pwd %~ %~ trailing components of working directory %3C %3d command number in history \! ! !

%!

%h %!

%h command number in session \# shell version \v shell level $SHLVL environment variable $ var echo -n $ var $ var %$ var $ var command substitution $( cmd ) $( cmd ) $( cmd ) host name \h

\H %m

%M user \u %n %n number of jobs \j %j %j tty %y last command exit status %? %? conditional expression shell privilege indicator %# continued line info date and time \D{ strftime_format } %D{ strftime_format } text effects and escapes escapes \\ \[ \] %% %{ %} %% %{ %} bold %B %b %B %b underline %U %u %U %u standout %S %s %S %s foreground color %F{red} %f background color %K{green} %k

Most shells permit a user to customize the prompt by setting an environment variable. fish requires that the user define a callback function.

The primary prompt is the prompt the user sees the most often.

The continued line prompt is used when the user types an incomplete command. This can happen when there are open parens, braces, or quote in the command, or the user backslash escaped the newline.

The select prompt is used to prompt the user to make a multiple choice selection. It corresponds to the select execution control statement.

The right prompt appears at the far right side of the input line. If the user types enough input to need the space, the right prompt disappears.

dynamic information

bash , tcsh , and zsh provide a set of special character sequences for putting dynamic information in the prompt. In the case of bash the sequences start with a backslash and in the case of tcsh and zsh a percent sign.

bash , ksh , tcsh , and zsh will also perform variable expansion on anything that starts with a dollar sign and looks like a variable before each display of the prompt. bash , ksh , and zsh will also perform command substitution before each display of the prompt when they encounter the $( ) syntax in the prompt.

text effects and escapes

fish:

zsh:

bash

The Bourne Again shell is a GNU replacement for the Bourne shell. It can run almost all Bourne scripts and POSIX compliant scripts, and operating systems often use bash as /bin/sh . Because bash has many extensions it is not a good shell to use for determining POSIX compliance.

csh

The C shell was written by Bill Joy and released as part of the second Berkeley Standard Distribution.

It introduced features that were widely adopted by other shells: history expansion, aliases, tilde notation, and job control.

The C shell was so named because it looked more like C than the Bourne shell. It still used keywords to mark off blocks instead of curly braces, but its expressions were delimited by parens instead of square brackets and relational operators such as < and <= could be used instead of -lt and -le. The Unix community nevertheless eventually chose a derivation of the Bourne shell as the standard scripting language and writing scripts for the C shell is not recommended.

The classic Macintosh operating system had a development environment called The Mac Programmer's Workbench. It included a shell that was derived from the C shell.

dash

The Debian Almquist shell, dash , was originally a Linux port of the NetBSD Almquist shell, ash . It is POSIX compliant. It is also smaller than the other shells: on Ubuntu Linux the executable is about 100k whereas the other shells are in the 300k-900k range.

dash does not keep a command history or offer command line editing. It does have job control, though.

Fish user documentation

ksh

The Korn shell added history and job control but otherwise stayed consistent with the Bourne shell. The POSIX standard for the shell was based on the Korn shell.

The Korn shell was proprietary software until 2000, which is why clones such as pdksh were written. Also, zsh can be used to emulate ksh ; both Mac OS X and Ubuntu link ksh to zsh .

The rc shell was released as part of 10th Edition Unix. It was also the Plan 9 shell.

POSIX 2008

A succession of shells have been installed at /bin/sh which are known today by the engineers who implemented them: the Thompson shell, the Mashey shell, and the Bourne shell.

The Bourne shell appeared in 1977. It introduced the execution control structures that are used in most of the modern Unix shells. These control structures, with their distinctive reversed words for marking the end of blocks: fi and esac , were borrowed from Algol 68. However, where Algol 68 uses od the Bourne shell uses done . This was because a Unix command named od already existed. The Bourne shell also introduced arbitrary length variable names; the Mashey shell by contrast was limited to single letter variable names.

Whatever is installed at /bin/sh should probably be POSIX compliant. Mac OS X uses bash , which changes its behavior somewhat and operates in POSIX mode when invoked as sh . One can also get this behavior by invoking bash with the --posix flag.

Ubuntu makes /bin/sh a symlink to /bin/dash .

tcsh

The TENEX C shell, tcsh , was upgraded version of the C Shell which added tab completion, a feature originally used in the TENEX operating system.

tcsh is backwardly compatible with csh and on many systems csh is simply a symlink to tcsh .

tcsh is the default shell on FreeBSD and it was the default shell on Mac OS X until version 10.3 was introduced in 2003.

Writing scripts in tcsh is not recommended for the same reasons writing scripts in csh is not recommended.

The following tcsh built-ins interact with the terminal settings:

echotc

settc

setty

telltc

termname

The Z shell, zsh , is documented by multiple man pages:

man page topics covered zshall all topics in one man page zsh startup files zshoptions options zshbuiltins built-ins zshcompwid, zshcompsys tab completion zshcompctl old tab completion system zshexp history expansion; parameter expansion; process, tilde, command, and pathname expansion zshmisc grammar; keywords; quoting; redirection; arithmetic and conditional expressions; prompt customization zshparam special variables zshzle readline

zsh has these builtins for managing the completion module:

comparguments

compcall

compctl

compdescribe

compfiles

compgroups

compquote

comptags

comptry

compvalues

The following zsh built-ins interact with the terminal settings:

echotc

echoti

getcap

ttyctl

Special zsh builtins: