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Advanced Bash Scripting: Part 2
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The previous part of this guide, Guide to Advanced Bash Scripting: Part 1, describes the advanced Bash scripting concepts of Bash functions, list constructs, arrays, aliases, and regular expressions. This guide, the second part of this series, explains more advanced topics, including documents, Bash I/O redirection, subshells, restricted shells, process substitution, indirect references, and network programming. As well, this guide covers some Bash debugging techniques. If you’re new to Bash, check out our Introduction to Bash Shell Scripting and Intermediate Guide to Bash Scripting before you begin this guide.
I/O Redirection
Bash I/O redirection captures output from a file, command, program, script, or code block within a script, and sends it as input to another file, command, program, or script. You can use I/O redirection directly at the command prompt, or in a script to automate the process. This avoids repetitive typing. To get an idea of how I/O redirection works, consider the following command ls
command:
ls -lR > dirlist.txt
The >
operator performs I/O redirection by taking the output of ls
and sending it to dirlist.txt
after truncating any content currently found in dirlist.txt
. When you use the cat
command on dirlist.txt
, you see that dirlist.txt
contains a directory listing of the current directory. The Bash equivalent of these actions is:
#!/bin/bash
ls -lR > dirlist.txt
cat dirlist.txt
exit
>>
operator instead. Appending the output allows you to perform multiple commands and output all of the content in a single file.You can also use the pipe (|
) operator in your scripts to redirect output from one program to another program. You can then direct the output a file if desired. For example, the script below creates a listing of file sizes and filenames. It then sorts them in file size order and directs the result to dirlist.txt
. Then, the result is displayed in the terminal.
- File: example.sh
1 2 3 4 5 6
#!/bin/bash ls -h -s | sort > dirlist.txt cat dirlist.txt exit
Linux supports three default streams:
- stdin: the keyboard
- stdout: the display
- stderr: the error output to the display
Files have a number between 0 and 9 associated with them where stdin
is stream 0
, stdout
is stream 1
, and stderr
is stream 2
. Knowing the number for a particular default stream can be advantageous. For example, the following script redirects the stderr
output to a file instead of the terminal display so that you can detect any issues. The following is an example of file redirection that creates an error log:
- File: example_file_redirection.sh
1 2 3 4 5 6 7 8 9 10 11 12 13 14
#!/bin/bash echo "Test 1" ls -lR 2>error.log > dirlist.txt cat error.log cat dirlist.txt echo echo "Test 2" ls *.x 2>>error.log > dirlist.txt cat error.log cat dirlist.txt exit
The example performs two tests, where the first test doesn’t produce an error and the other second test does (unless you have files with a .x
extension). In each case, the example outputs the error log first, then the directory. To avoid overwriting information in the error log, always append to an error log when running a script using the >>
operator. Error logs help in debugging Bash scripts. During the second test, the output looks like the following.
Test 2
ls: cannot access '*.x': No such file or directory
This output shows that there is an error and the dirlist.txt
file is empty as a result.
Here Documents
A here document is a specialized code block that feeds a command list to an interactive program or a command, such as FTP or cat
, using a form of input I/O redirection. You can employ them with text editors such as Vi or nano, or send broadcast messages with commands like wall
. The following is an example of a script that works with the wall
command:
- File: example_here_document.sh
1 2 3 4 5 6 7 8 9 10 11 12
#!/bin/bash # This comment line is not printed. wall << AMessage Submit all vacation requests to your manager today! # Note: 'wall' prints comment lines within the message. AMessage # This comment line is not printed either. exit
The example above sends a message string to wall
named AMessage
. The message begins and ends with AMessage
as shown. Wall
prints any text, including comments, that appear between the starting and ending AMessage
entries. For this reason, be cautious when determining where to add comments to your script.
Process Substitution
Process substitution pass the output of one or more processes into the stdin
of another process. This is an especially useful technique when you have multiple commands to pass into stdin
. The process is akin to I/O redirection, but you rely on the <
operator instead of using the |
operator. In addition, the |
operator is limited to sending the output of just one process to another process, whereas process substitution allows piping of multiple processes to the stdin
of a single process as shown below:
- File: process_substitution.sh
1 2 3 4 5
#!/bin/bash comm <(ls -l) <(ls -al) exit
In this case, the script compares the output of two different directory listing commands using the comm
command. The stdin
of comm
receives both outputs, not just one.
Subshells, and Restricted Shells and Subshells
A shell is a specialized piece of software that takes input, determines the intention of the input, and then runs any tasks requested by the input. A subshell is a shell that is running as a subprocess of another shell. The subshell allows tasks to run in parallel with the host shell. A restricted shell or subshell is a kind of shell or subshell with constraints placed on it to ensure that the environment is more secure than normal. You use parentheses within a Bash script to create a subshell like:
- File: subshell.sh
1 2 3 4 5 6 7 8 9 10 11
#!/bin/bash echo "Subshell level OUTSIDE subshell = $BASH_SUBSHELL" ( echo "Subshell level INSIDE subshell = $BASH_SUBSHELL" ( echo "A subshell within a subshell LEVEL = $BASH_SUBSHELL" ) ) exit
It’s possible to nest subshells as deeply as needed to perform various tasks in parallel. As shown in the example above, each level is nested within a pair of parentheses. Even though Bash doesn’t require it, indenting the code makes it easier for humans to see the nesting level and doesn’t affect the output. The following is the output from this example:
Subshell level OUTSIDE subshell = 0
Subshell level INSIDE subshell = 1
A subshell within a subshell LEVEL = 2
Whenever you run a script or create a subshell, the associated shell or subshell has the same rights and privileges as the parent environment. You can change this behavior to enforce security within your scripts by using Bash-restricted shells and subshells. The following is an example of a Bash restricted shell:
- File: bash_restricted_shell_example.sh
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17
#!/bin/bash # Change the working directory. cur_dir=$(pwd) pwd cd .. pwd cd $cur_dir pwd # Try to change the working directory with restrictions in place. set -r cd .. pwd cd exit
In the example above, the first set of commands to change and restore the working directory succeed because there are no restrictions. However, after issuing the set -r
command, any attempt to change the working directory fails. The set -r
command restricts the following actions:
- Using
cd
to change the working directory - Changing the values of the
$PATH
,$SHELL
,$BASH_ENV
, or$ENV
environment variables - Reading or modifying the
$SHELLOPTS
environment variable - Output redirection
- Invoking external commands that don’t appear in the current directory and aren’t on the
PATH
- Using the
exec
command to create a new shell - Employing any command to subvert any of the Bash restrictions
- Exiting restricted mode
The last restriction is why you may want to use set -r
in a subshell, rather than the shell itself. These restrictions remain in place while the subshell runs, but aren’t in place for the actual shell, so you can perform sensitive tasks within the subshell and then return to normal operations.
Indirect References
An indirect reference occurs when a Bash script retrieves a value pointed to by another value. The easiest way to understand this concept is through the following script:
- File: indirect_references.sh
1 2 3 4 5 6 7 8 9 10 11
#!/bin/bash a="Hello" b=a echo "a = $a" echo "b = $b" eval b=\$$b echo "b now = $b" exit
In the example above, a
begins by containing the value “Hello” and b
points to (contains the name of) a
. When you initially output the two variables, you see the expected results. However, when you run eval
on b
to obtain an indirect reference (\$$
) to a
, the content of b
changes to that of a
. Following is the output from the script above:
a = Hello
b = a
b now = Hello
Network Programming
A script can use network programming techniques and tools to access, manipulate, and troubleshoot network connections. For example, the following script displays a list of TCP connections for the current system:
#!/bin/bash
lsof "-ni" | grep TCP | grep -v LISTEN
exit
This example relies on the list of open files (lsof
) command to display a list of open network files that rely on the TCP protocol.
Debugging
Every script, regardless of complexity, can contain bugs even if those bugs relate to different perspective between the developer and user. A bug occurs any time the script behaves in a manner that conflicts with its original design. Removing bugs from scripts is termed debugging. This guide provides you with some ideas on how to debug your scripts using techniques like logging. In addition, there is also the traditional methods of checking variable values by using echo
. By echoing variable values at various points during script execution, you can see where inappropriate changes exist. Bash also provides the following switches to use when debugging Bash scripts:
set -f
: Disables filename generation using metacharacters (globbing)set -v
: Outputs shell lines as Bash reads them in verbose modeset -x
: Prints command traces before Bash executes a command
To understand how these switches work, add them to the various examples in this guide. For example, by adding set -v
to the script in the Indirect References section of the document, the output changes contains each command printed along with the outputs:
a="Hello"
b=a
echo "a = $a"
a = Hello
echo "b = $b"
b = a
eval b=\$$b
b=$a
echo "b now = $b"
b now = Hello
Exit
Conclusion
You can do a great deal more with here documents, I/O redirection, subshells, restricted shells, process substitution, indirect references, and network programming than what’s outlined here. The GNU Bash resource provides a more information about the advantages of working with Bash scripting.
More Information
You may wish to consult the following resources for additional information on this topic. While these are provided in the hope that they will be useful, please note that we cannot vouch for the accuracy or timeliness of externally hosted materials.
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