In many languages, quotes are mainly used to specify that the enclosed text is to be interpreted as a string datatype, but in shell programming, almost everything is a string, so quoting in the shell has many different effects and purposes. There are multiple types of quotes which primarily enable different ways of interpreting their contents. Unfortunately, the rules are often hard for beginners to learn and their behavior varies by context with several special cases and exceptions to remember. Also unfortunately, quoting in shell programming is extremely important. It's something no one can avoid learning. Improper shell quoting is one of the most common sources of scripting bugs and security issues. Fortunately, it's possible to get it right most of the time by following a few guidelines, but do not guess about quoting. When in doubt, test, and read the man page for how quotes are to be interpreted in a given context.

Types of quoting

Note: Although backticks (`) are a type of quotes linguistically, they don't actually "quote" anything in bash. Where quoting in bash is used to make data (partly) literal, backticks do something entirely different. They're the old Bourne syntax for command substitution. They mostly do the same thing as $(...), but there are a handful of weird exceptions. Either way, it doesn't matter that much: Their use is deprecated in favor of $(...), and you really shouldn't use these things anymore in modern or maintained bash code. Take away from this that if you see them, they do NOT void the need for quoting (just like "$(command)", you should double-quote them: "`command`"), and you should probably just replace them with $().

Effects of Quoting

Preserve unescaped metacharacters

A shell command is parsed by the shell into words, using whitespace (regardless of the IFS variable) and other shell metacharacters. The first function of quoting is to permit words to contain these metacharacters.

echo '&'

Without quotes, the & would put the echo command into the background. With quotes, the & is simply made into a word, and passed as an argument to the echo command instead.

The quotes are not actually passed along to the command. They are removed by the shell (this process is cleverly called "quote removal"). In the example above, the echo command sees only the &, not the quotes.

Prevent field splitting and ignore glob pattern characters

The second purpose of quoting is to prevent word splitting and globbing. The result of a single-quoted or double-quoted substitution does not undergo any further processing. (The result of an unquoted substitution does.)

cp -- "$filename" "$destination"

In this example, the double quotes protect the value of each parameter (variable) from undergoing word splitting or globbing should it happen to contain whitespace or wildcard characters (* or ? or [...]). Without the quotes, a filename like hot stuff.mp3 would be split into two words, and each word would be passed to the cp command as a separate argument. Or, a filename that contains * with whitespace around it would produce one word for every file in the current directory. That is not what we want.

With the quotes, every character in the value of the filename parameter is treated literally, and the whole value becomes the second argument to the cp command.

When in doubt, always double-quote your parameter expansions.

You may concatenate the various types of quoting if you need to. For example, if you have one section of a string that has lots of special characters that you'd like to single-quote, and another section with a parameter expansion in it which must be double-quoted, you may mix them:

echo '!%$*&'"$foo"

Any number of quoted substrings, of any style, may be concatenated in this manner. The result (after appropriate expansions in the double-quoted sections) is a single word.

Expand argument lists

Double-quoting $@ or ${array[@]} has a special meaning. "$@" expands to a list of words, with each positional parameter's value being one word. Likewise, "${array[@]}" expands to a list words, one per array element. When dealing with the positional parameters or with the contents of an array as a list of words, always use the double-quoted syntax.

Double-quoting $* or ${array[*]} results in one word which is the concatenation of all the positional parameters (or array elements) with the first character of IFS between them. This is similar to the join function in some other languages, although the fact that you can only have a single join character can sometimes be a crippling limitation.

Examples

Here are some assorted examples, to show how things should be done. Some of these examples use bash/ksh syntax that won't work in strict POSIX shells.

Proper iteration over the positional parameters using a quoted "$@". Never use an unquoted $@ or $*.

for file in "$@"; do
...
done

As above, except an array.

for element in "${array[@]}"; do
...

Proper iteration over indexes

# bash 3.0 and higher
for index in "${!array[@]}"; do
...

All of the usual expansions apply to text within the parentheses of a compound array assignment including word splitting and pathname expansion, and must be quoted and escaped in the same way as though they were to be passed as arguments to a command.

# bash or ksh93
find_opts=('(' -iname '*.jpg' -o -iname '*.gif' -o -iname '*.png' ')')
find . "${find_opts[@]}" -print

First, a single quoted string followed by an unquoted, escaped single quote, followed by a single-quoted string. Second, a non-POSIX equivalent using $'...'

echo 'Don'\''t walk!'
echo $'Don\'t talk!'

$(...)-style command substitutions are unique in that the quoting of their contents is completely independent to their surroundings. This means you don't have to worry about nested quote escaping problems.

echo "The matching line is: $(grep foo "$filename")"

# Note that the quotes inside the $() command substitution are nested.
# This looks wrong to a C programmer, but it is correct in shells.

echo "The matching line is: $(grep foo "$filename")"
#                                      ^---------^    inner layer (quotes)
#                           ^^--------------------^   middle layer (command sub)
#    ^---------------------------------------------^  outer layer (quotes)

# Without the inner quotes, the value of $filename would be word-split and globbed
# before being handed to grep.

# bash
ip=192.168.1.30
netmask=255.255.254.0
IFS=. read -ra ip_octets <<<"$ip"
IFS=. read -ra netmask_octets <<<"$netmask"
for i in 0 1 2 3; do
  ((ip_octets[i] &= netmask_octets[i]))
done
IFS=.; network="${ip_octets[*]}"; unset IFS

the $'...' quoting style is used to interpret backslash escapes.

IFS=$' \t\n'
# sets the IFS variable to the three-byte string containing
# a space, a tab, and a newline

# The following are all equivalent:
echo $'hi\nthere\n'
printf '%s\n' hi there
# discouraged:
echo -e 'hi\nthere\n'
# ksh93:
print 'hi\nthere\n'

Exceptions

Patterns

One important situation where quotes can have an unintended effect is in the case of pattern matching contexts. Bash uses quotes to suppress the "specialness" of patterns and regular expressions. Characters interpreted specially in a pattern matching context are treated literally when quoted whether the pattern is expanded from a parameter or not.

if [[ $path = foo* ]]; then
# unquoted foo* acts as a glob

if [[ $path = "foo*" ]]; then
# quoted "foo*" is a literal string

if [[ $path =~ $some_re ]]; then
# the contents of $some_re are treated as an ERE

if [[ $path =~ "$some_re" ]]; then
# the contents of $some_re are treated as a literal string
# despite the =~ operator

# Bash 4
# the "quoted" branch is taken.

g=a*[b]

case $g in
    "$g")
        echo 'quoted pattern'
        ;;&
    $g)
        echo 'unquoted pattern'
        ;;
esac

Here Documents

Quote-removal never applies to the contents of a here document

 $ arr=(words in array); cat <<EOF
> These are the "${arr[@]}"
> EOF
These are the "words in array"

The quoting of the "delimiter" in the heredoc redirection affects whether the contents of the heredoc are parsed for expansions. This quoted heredoc variety is somewhat special because it is the only context in all of bash in which a literal string of arbitrary content may be specified and is subject to no special interpretation whatsoever, except for lines beginning with the delimiter itself marking the end of the heredoc.

{
    echo before
    eval "$(</dev/stdin)" # The heredoc is executed as though it were here.
    echo after
} <<\EOF
# Put any bash code at all here
EOF

See also


CategoryShell