Handling positional parameters¶
Intro¶
The day will come when you want to give arguments to your scripts. These arguments are known as positional parameters. Some relevant special parameters are described below:
Parameter(s) | Description |
---|---|
$0 | the first positional parameter, equivalent to argv[0] in C, see the first argument |
$FUNCNAME | the function name (attention: inside a function, $0 is still the $0 of the shell, not the function name) |
$1 ... $9 | the argument list elements from 1 to 9 |
${10} ... ${N} | the argument list elements beyond 9 (note the parameter expansion syntax!) |
$* | all positional parameters except $0 , see mass usage |
$@ | all positional parameters except $0 , see mass usage |
$# | the number of arguments, not counting $0 |
These positional parameters reflect exactly what was given to the script when it was called.
Option-switch parsing (e.g. -h
for displaying help) is not performed at this point.
See also the dictionary entry for "parameter".
The first argument¶
The very first argument you can access is referenced as $0
. It is usually set to the script's name exactly as called, and it's set on shell initialization:
Testscript - it just echos $0
:
#!/bin/bash
echo "$0"
You see, $0
is always set to the name the script is called with (>
is the prompt...):
> ./testscript
./testscript
> /usr/bin/testscript
/usr/bin/testscript
However, this isn't true for login shells:
> echo "$0"
-bash
In other terms, $0
is not a positional parameter, it's a special parameter independent from the positional parameter list. It can be set to anything. In the ideal case it's the pathname of the script, but since this gets set on invocation, the invoking program can easily influence it (the login
program does that for login shells, by prefixing a dash, for example).
Inside a function, $0
still behaves as described above. To get the function name, use $FUNCNAME
.
Shifting¶
The builtin command shift
is used to change the positional parameter values:
$1
will be discarded$2
will become$1
$3
will become$2
- ...
- in general:
$N
will become$N-1
The command can take a number as argument: Number of positions to shift. e.g. shift 4
shifts $5
to $1
.
Using them¶
Enough theory, you want to access your script-arguments. Well, here we go.
One by one¶
One way is to access specific parameters:
#!/bin/bash
echo "Total number of arguments: $#"
echo "Argument 1: $1"
echo "Argument 2: $2"
echo "Argument 3: $3"
echo "Argument 4: $4"
echo "Argument 5: $5"
While useful in another situation, this way is lacks flexibility. The maximum number of arguments is a fixedvalue - which is a bad idea if you write a script that takes many filenames as arguments.
=> forget that one
Loops¶
There are several ways to loop through the positional parameters.
You can code a C-style for-loop using $#
as the end value. On every iteration, the shift
-command is used to shift the argument list:
numargs=$#
for ((i=1 ; i <= numargs ; i++))
do
echo "$1"
shift
done
Not very stylish, but usable. The numargs
variable is used to store the initial value of $#
because the shift command will change it as the script runs.
Another way to iterate one argument at a time is the for
loop without a given wordlist. The loop uses the positional parameters as a wordlist:
for arg
do
echo "$arg"
done
Advantage: The positional parameters will be preserved
The next method is similar to the first example (the for
loop), but it doesn't test for reaching $#
. It shifts and checks if $1
still expands to something, using the test command:
while [ "$1" ]
do
echo "$1"
shift
done
Looks nice, but has the disadvantage of stopping when $1
is empty (null-string). Let's modify it to run as long as $1
is defined (but may be null), using parameter expansion for an alternate value:
while [ "${1+defined}" ]; do
echo "$1"
shift
done
Getopts¶
There is a small tutorial dedicated to getopts
(under construction).
Mass usage¶
All Positional Parameters¶
Sometimes it's necessary to just "relay" or "pass" given arguments to another program. It's very inefficient to do that in one of these loops, as you will destroy integrity, most likely (spaces!).
The shell developers created $*
and $@
for this purpose.
As overview:
Syntax | Effective result |
---|---|
$* | $1 $2 $3 ... ${N} |
$@ | $1 $2 $3 ... ${N} |
"$*" | "$1c$2c$3c...c${N}" |
"$@" | "$1" "$2" "$3" ... "${N}" |
Without being quoted (double quotes), both have the same effect: All positional parameters from $1
to the last one used are expanded without any special handling.
When the $*
special parameter is double quoted, it expands to the equivalent of: "$1c$2c$3c$4c........$N"
, where 'c' is the first character of IFS
.
But when the $@
special parameter is used inside double quotes, it expands to the equivanent of...
"$1" "$2" "$3" "$4" ..... "$N"
...which reflects all positional parameters as they were set initially and passed to the script or function. If you want to re-use your positional parameters to call another program (for example in a wrapper-script), then this is the choice for you, use double quoted "$@"
.
Well, let's just say: You almost always want a quoted "$@"
!
Range Of Positional Parameters¶
Another way to mass expand the positional parameters is similar to what is possible for a range of characters using substring expansion on normal parameters and the mass expansion range of arrays.
${@:START:COUNT}
${*:START:COUNT}
"${@:START:COUNT}"
"${*:START:COUNT}"
The rules for using @
or *
and quoting are the same as above. This will expand COUNT
number of positional parameters beginning at START
. COUNT
can be omitted (${@:START}
), in which case, all positional parameters beginning at START
are expanded.
If START
is negative, the positional parameters are numbered in reverse starting with the last one.
COUNT
may not be negative, i.e. the element count may not be decremented.
Example: START at the last positional parameter:
echo "${@: -1}"
Attention: As of Bash 4, a START
of 0
includes the special parameter $0
, i.e. the shell name or whatever $0
is set to, when the positional parameters are in use. A START
of 1
begins at $1
. In Bash 3 and older, both 0
and 1
began at $1
.
Setting Positional Parameters¶
Setting positional parameters with command line arguments, is not the only way to set them. The builtin command, set may be used to "artificially" change the positional parameters from inside the script or function:
set "This is" my new "set of" positional parameters
# RESULTS IN
# $1: This is
# $2: my
# $3: new
# $4: set of
# $5: positional
# $6: parameters
It's wise to signal "end of options" when setting positional parameters this way. If not, the dashes might be interpreted as an option switch by set
itself:
# both ways work, but behave differently. See the article about the set command!
set -- ...
set - ...
Alternately this will also preserve any verbose (-v) or tracing (-x) flags, which may otherwise be reset by set
set -$- ...
FIXME
continue
Production examples¶
Using a while loop¶
To make your program accept options as standard command syntax:
COMMAND [options] <params> # Like 'cat -A file.txt'
See simple option parsing code below. It's not that flexible. It doesn't auto-interpret combined options (-fu USER) but it works and is a good rudimentary way to parse your arguments.
#!/bin/sh
# Keeping options in alphabetical order makes it easy to add more.
while :
do
case "$1" in
-f | --file)
file="$2" # You may want to check validity of $2
shift 2
;;
-h | --help)
display_help # Call your function
# no shifting needed here, we're done.
exit 0
;;
-u | --user)
username="$2" # You may want to check validity of $2
shift 2
;;
-v | --verbose)
# It's better to assign a string, than a number like "verbose=1"
# because if you're debugging the script with "bash -x" code like this:
#
# if [ "$verbose" ] ...
#
# You will see:
#
# if [ "verbose" ] ...
#
# Instead of cryptic
#
# if [ "1" ] ...
#
verbose="verbose"
shift
;;
--) # End of all options
shift
break;
-*)
echo "Error: Unknown option: $1" >&2
exit 1
;;
*) # No more options
break
;;
esac
done
# End of file
Filter unwanted options with a wrapper script¶
This simple wrapper enables filtering unwanted options (here: -a
and --all
for ls
) out of the command line. It reads the positional parameters and builds a filtered array consisting of them, then calls ls
with the new option set. It also respects the --
as "end of options" for ls
and doesn't change anything after it:
#!/bin/bash
# simple ls(1) wrapper that doesn't allow the -a option
options=() # the buffer array for the parameters
eoo=0 # end of options reached
while [[ $1 ]]
do
if ! ((eoo)); then
case "$1" in
-a)
shift
;;
--all)
shift
;;
-[^-]*a*|-a?*)
options+=("${1//a}")
shift
;;
--)
eoo=1
options+=("$1")
shift
;;
*)
options+=("$1")
shift
;;
esac
else
options+=("$1")
# Another (worse) way of doing the same thing:
# options=("${options[@]}" "$1")
shift
fi
done
/bin/ls "${options[@]}"
Using getopts¶
There is a small tutorial dedicated to getopts
(under construction).
See also¶
- Internal: getopts_tutorial
- Internal: while_loop
- Internal: c_for
- Internal: arrays (for equivalent syntax for mass-expansion)
- Internal: Substring expansion on a parameter (for equivalent syntax for mass-expansion)
- Dictionary, internal: parameter