# Functions

Shell functions are defined with the function reserved word or the special syntax ‘funcname ()’. Shell functions are read in and stored internally. Alias names are resolved when the function is read. Functions are executed like commands with the arguments passed as positional parameters. (See Command Execution.)

Functions execute in the same process as the caller and share all files and present working directory with the caller. A trap on EXIT set inside a function is executed after the function completes in the environment of the caller.

The return builtin is used to return from function calls.

Function identifiers can be listed with the functions builtin. Functions can be undefined with the unfunction builtin.

# Command Execution

If a command name contains no slashes, the shell attempts to locate it. If there exists a shell function by that name, the function is invoked as described in Functions. If there exists a shell builtin by that name, the builtin is invoked.

Otherwise, the shell searches each element of ${path} for a directory containing an executable file by that name. If the search is unsuccessful, the shell prints an error message and returns a nonzero exit status. If execution fails because the file is not in executable format, and the file is not a directory, it is assumed to be a shell script. /bin/sh is spawned to execute it. If the program is a file beginning with ‘#!’, the remainder of the first line specifies an interpreter for the program. The shell will execute the specified interpreter on operating systems that do not handle this executable format in the kernel. If no external command is found but a function command_not_found_handler exists the shell executes this function with all command line arguments. The return status of the function becomes the status of the command. If the function wishes to mimic the behaviour of the shell when the command is not found, it should print the message ‘command not found: cmd’ to standard error and return status 127. Note that the handler is executed in a subshell forked to execute an external command, hence changes to directories, shell parameters, etc. have no effect on the main shell. ## Autoloading Functions A function can be marked as undefined using the autoload builtin (or ‘functions -u’ or ‘typeset -fu’). Such a function has no body. When the function is first executed, the shell searches for its definition using the elements of the fpath variable. Thus to define functions for autoloading, a typical sequence is: fpath=(~/myfuncs$fpath)


The usual alias expansion during reading will be suppressed if the autoload builtin or its equivalent is given the option -U. This is recommended for the use of functions supplied with the zsh distribution. Note that for functions precompiled with the zcompile builtin command the flag -U must be provided when the .zwc file is created, as the corresponding information is compiled into the latter.

For each element in fpath, the shell looks for three possible files, the newest of which is used to load the definition for the function:

element.zwc

A file created with the zcompile builtin command, which is expected to contain the definitions for all functions in the directory named element. The file is treated in the same manner as a directory containing files for functions and is searched for the definition of the function. If the definition is not found, the search for a definition proceeds with the other two possibilities described below.

If element already includes a .zwc extension (i.e. the extension was explicitly given by the user), element is searched for the definition of the function without comparing its age to that of other files; in fact, there does not need to be any directory named element without the suffix. Thus including an element such as ‘/usr/local/funcs.zwc’ in fpath will speed up the search for functions, with the disadvantage that functions included must be explicitly recompiled by hand before the shell notices any changes.

element/function.zwc

A file created with zcompile, which is expected to contain the definition for function. It may include other function definitions as well, but those are neither loaded nor executed; a file found in this way is searched only for the definition of function.

element/function

A file of zsh command text, taken to be the definition for function.

In summary, the order of searching is, first, in the parents of directories in fpath for the newer of either a compiled directory or a directory in fpath; second, if more than one of these contains a definition for the function that is sought, the leftmost in the fpath is chosen; and third, within a directory, the newer of either a compiled function or an ordinary function definition is used.

If the KSH_AUTOLOAD option is set, or the file contains only a simple definition of the function, the file’s contents will be executed. This will normally define the function in question, but may also perform initialization, which is executed in the context of the function execution, and may therefore define local parameters. It is an error if the function is not defined by loading the file.

Otherwise, the function body (with no surrounding ‘funcname() {...}’) is taken to be the complete contents of the file. This form allows the file to be used directly as an executable shell script. If processing of the file results in the function being re-defined, the function itself is not re-executed. To force the shell to perform initialization and then call the function defined, the file should contain initialization code (which will be executed then discarded) in addition to a complete function definition (which will be retained for subsequent calls to the function), and a call to the shell function, including any arguments, at the end.

For example, suppose the autoload file func contains

func() { print This is func; }
print func is initialized


then ‘func; func’ with KSH_AUTOLOAD set will produce both messages on the first call, but only the message ‘This is func’ on the second and subsequent calls. Without KSH_AUTOLOAD set, it will produce the initialization message on the first call, and the other message on the second and subsequent calls.

It is also possible to create a function that is not marked as autoloaded, but which loads its own definition by searching fpath, by using ‘autoload -X’ within a shell function. For example, the following are equivalent:

myfunc() {
}
myfunc args...


and

unfunction myfunc   # if myfunc was defined
myfunc args...


In fact, the functions command outputs ‘builtin autoload -X’ as the body of an autoloaded function. This is done so that

eval "$(functions)"  produces a reasonable result. A true autoloaded function can be identified by the presence of the comment ‘# undefined’ in the body, because all comments are discarded from defined functions. To load the definition of an autoloaded function myfunc without executing myfunc, use: autoload +X myfunc  ## Anonymous Functions If no name is given for a function, it is ‘anonymous’ and is handled specially. Either form of function definition may be used: a ‘()’ with no preceding name, or a ‘function’ with an immediately following open brace. The function is executed immediately at the point of definition and is not stored for future use. The function name is set to ‘(anon)’. Arguments to the function may be specified as words following the closing brace defining the function, hence if there are none no arguments (other than$0) are set. This is a difference from the way other functions are parsed: normal function definitions may be followed by certain keywords such as ‘else’ or ‘fi’, which will be treated as arguments to anonymous functions, so that a newline or semicolon is needed to force keyword interpretation.

Note also that the argument list of any enclosing script or function is hidden (as would be the case for any other function called at this point).

Redirections may be applied to the anonymous function in the same manner as to a current-shell structure enclosed in braces. The main use of anonymous functions is to provide a scope for local variables. This is particularly convenient in start-up files as these do not provide their own local variable scope.

For example,

variable=outside
function {
local variable=inside
print "I am $variable with arguments$*"
} this and that
print "I am $variable"  outputs the following: I am inside with arguments this and that I am outside  Note that function definitions with arguments that expand to nothing, for example ‘name=; function$name { ... }’, are not treated as anonymous functions. Instead, they are treated as normal function definitions where the definition is silently discarded.

## Special Functions

Certain functions, if defined, have special meaning to the shell.

For the functions below, it is possible to define an array that has the same name as the function with ‘_functions’ appended. Any element in such an array is taken as the name of a function to execute; it is executed in the same context and with the same arguments as the basic function. For example, if ${chpwd_functions} is an array containing the values ‘mychpwd’, ‘chpwd_save_dirstack’, then the shell attempts to execute the functions ‘chpwd’, ‘mychpwd’ and ‘chpwd_save_dirstack’, in that order. Any function that does not exist is silently ignored. A function found by this mechanism is referred to elsewhere as a ‘hook function’. An error in any function causes subsequent functions not to be run. Note further that an error in a precmd hook causes an immediately following periodic function not to run (though it may run at the next opportunity). chpwd Executed whenever the current working directory is changed. periodic If the parameter${PERIOD} is set, this function is executed every ${PERIOD} seconds, just before a prompt. Note that if multiple functions are defined using the array periodic_functions only one period is applied to the complete set of functions, and the scheduled time is not reset if the list of functions is altered. Hence the set of functions is always called together. precmd Executed before each prompt. Note that precommand functions are not re-executed simply because the command line is redrawn, as happens, for example, when a notification about an exiting job is displayed. preexec Executed just after a command has been read and is about to be executed. If the history mechanism is active (regardless of whether the line was discarded from the history buffer), the string that the user typed is passed as the first argument, otherwise it is an empty string. The actual command that will be executed (including expanded aliases) is passed in two different forms: the second argument is a single-line, size-limited version of the command (with things like function bodies elided); the third argument contains the full text that is being executed. zshaddhistory Executed when a history line has been read interactively, but before it is executed. The sole argument is the complete history line (so that any terminating newline will still be present). If any of the hook functions returns status 1 (or any non-zero value other than 2, though this is not guaranteed for future versions of the shell) the history line will not be saved, although it lingers in the history until the next line is executed, allowing you to reuse or edit it immediately. If any of the hook functions returns status 2 the history line will be saved on the internal history list, but not written to the history file. In case of a conflict, the first non-zero status value is taken. A hook function may call ‘fc -p ...’ to switch the history context so that the history is saved in a different file from the that in the global HISTFILE parameter. This is handled specially: the history context is automatically restored after the processing of the history line is finished. The following example function works with one of the options INC_APPEND_HISTORY or SHARE_HISTORY set, in order that the line is written out immediately after the history entry is added. It first adds the history line to the normal history with the newline stripped, which is usually the correct behaviour. Then it switches the history context so that the line will be written to a history file in the current directory. zshaddhistory() { print -sr --${1%%$'\n'} fc -p .zsh_local_history }  zshexit Executed at the point where the main shell is about to exit normally. This is not called by exiting subshells, nor when the exec precommand modifier is used before an external command. Also, unlike TRAPEXIT, it is not called when functions exit. ### Trap Functions The functions below are treated specially but do not have corresponding hook arrays. TRAPNAL If defined and non-null, this function will be executed whenever the shell catches a signal SIGNAL, where NAL is a signal name as specified for the kill builtin. The signal number will be passed as the first parameter to the function. If a function of this form is defined and null, the shell and processes spawned by it will ignore SIGNAL. The return status from the function is handled specially. If it is zero, the signal is assumed to have been handled, and execution continues normally. Otherwise, the shell will behave as interrupted except that the return status of the trap is retained. Programs terminated by uncaught signals typically return the status 128 plus the signal number. Hence the following causes the handler for SIGINT to print a message, then mimic the usual effect of the signal. TRAPINT() { print "Caught SIGINT, aborting." return$(( 128 + $1 )) }  The functions TRAPZERR, TRAPDEBUG and TRAPEXIT are never executed inside other traps. TRAPDEBUG If the option DEBUG_BEFORE_CMD is set (as it is by default), executed before each command; otherwise executed after each command. See the description of the trap builtin in Shell Builtin Commands for details of additional features provided in debug traps. TRAPEXIT Executed when the shell exits, or when the current function exits if defined inside a function. The value of$? at the start of execution is the exit status of the shell or the return status of the function exiting.

TRAPZERR

Executed whenever a command has a non-zero exit status. However, the function is not executed if the command occurred in a sublist followed by ‘&&’ or ‘||’; only the final command in a sublist of this type causes the trap to be executed. The function TRAPERR acts the same as TRAPZERR on systems where there is no SIGERR (this is the usual case).

The functions beginning ‘TRAP’ may alternatively be defined with the trap builtin: this may be preferable for some uses. Setting a trap with one form removes any trap of the other form for the same signal; removing a trap in either form removes all traps for the same signal. The forms

TRAPNAL() {
# code
}


(’function traps’) and

trap '
# code
' NAL


(’list traps’) are equivalent in most ways, the exceptions being the following:

• Function traps have all the properties of normal functions, appearing in the list of functions and being called with their own function context rather than the context where the trap was triggered.
• The return status from function traps is special, whereas a return from a list trap causes the surrounding context to return with the given status.
• Function traps are not reset within subshells, in accordance with zsh behaviour; list traps are reset, in accordance with POSIX behaviour.