Automating the tedious with loops
Last updated on 2024-02-23 | Edit this page
Estimated time: 30 minutes
Overview
Questions
- What is a loop?
- How can a loop be used to repeat a task?
Objectives
- Describe how loops can be used to repeat tasks
- Implement a loop to rename several files
Writing a Loop
Loops are key to productivity improvements through
automation as they allow us to execute commands repetitively. Similar to
wildcards and tab completion, using loops also reduces the amount of
typing (and typing mistakes). Suppose we have several hundred document
files named project_1825.txt,
project_1863.txt, XML_project.txt and so on.
We would like to change these files, but also save a version of the
original files, naming the copies backup_project_1825.txt
and so on.
We can use a loop to do that. Here’s a simple example that creates a backup copy of four text files in turn.
Let’s first create those files:
$ touch a.txt b.txt c.txt d.txtThis will create four empty files with those names.
Now we will use a loop to create a backup version of those files. First let’s look at the general form of a loop:
BASH
for thing in list_of_things
do
operation_using $thing # Indentation within the loop is not required, but aids legibility
doneWe can apply this to our example like this:
OUTPUT
a.txt
b.txt
c.txt
d.txtWhen the shell sees the keyword for, it knows to repeat
a command (or group of commands) once for each thing in a
list. For each iteration, the name of each thing is sequentially
assigned to the loop variable and the commands inside
the loop are executed before moving on to the next thing in the list.
Inside the loop, we call for the variable’s value by putting
$ in front of it. The $ tells the shell
interpreter to treat the variable as a variable name
and substitute its value in its place, rather than treat it as text or
an external command.
Double-quoting variable substitutions
Because real-world filenames often contain white-spaces, we wrap
$filename in double quotes ("). If we didn’t,
the shell would treat the white-space within a filename as a separator
between two different filenames, which usually results in errors.
Therefore, it’s best and generally safer to use "$..."
unless you are absolutely sure that no elements with white-space can
ever enter your loop variable (such as in episode 5).
In this example, the list is four filenames: ‘a.txt’, ‘b.txt’,
‘c.txt’, and ‘d.txt’. Each time the loop iterates, it will assign a file
name to the variable filename and run the cp
command. The first time through the loop, $filename is
a.txt. The interpreter prints the filename to the screen
and then runs the command cp on a.txt,
(because we asked it to echo each filename as it works its way through
the loop). For the second iteration, $filename becomes
b.txt. This time, the shell prints the filename
b.txt to the screen, then runs cp on
b.txt. The loop performs the same operations for
c.txt and then for d.txt and then, since the
list only included these four items, the shell exits the
for loop at that point.
Follow the Prompt
The shell prompt changes from $ to > and
back again as we were typing in our loop. The second prompt,
>, is different to remind us that we haven’t finished
typing a complete command yet. A semicolon, ;, can be used
to separate two commands written on a single line.
Same Symbols, Different Meanings
Here we see > being used as a shell prompt, but
> can also be used to redirect output from a command
(i.e. send it somewhere else, such as to a file, instead of displaying
the output in the terminal) — we’ll use redirection in episode 5. Similarly, $
is used as a shell prompt, but, as we saw earlier, it is also used to
ask the shell to get the value of a variable.
If the shell prints > or $ then
it expects you to type something, and the symbol is a prompt.
If you type > in the shell, it is an
instruction from you to the shell to redirect output.
If you type $ in the shell, it is an
instruction from you to the shell to get the value of a variable.
We have called the variable in this loop filename in
order to make its purpose clearer to human readers. The shell itself
doesn’t care what the variable is called.
This is our first look at loops. We will run another loop in the Counting and Mining with the Shell episode.
Running the loop from a Bash script
Alternatively, rather than running the loop above on the command
line, you can save it in a script file and run it from the command line
without having to rewrite the loop again. This is what is called a Bash
script which is a plain text file that contains a series of commands
like the loop you created above. In the example script below, the first
line of the file contains what is called a Shebang (#!)
followed by the path to the interpreter (or program) that will run the
rest of the lines in the file (/bin/bash). The second line
demonstrates how comments are made in scripts. This provides you with
more information about what the script does. The remaining lines contain
the loop you created above. You can create this file in the same
directory you’ve been using for the lesson and by using the text editor
of your choice (e.g. nano) but when you save the file, make sure it has
the extension .sh
(e.g. my_first_bash_script.sh). When you’ve done this, you
can run the Bash script by typing the command bash and the file name via
the command line (e.g. bash my_first_bash_script.sh).
#!/bin/bash
# This script loops through .txt files, returns the file name, first line, and last line of the file
for file in *.txt
do
echo $file
head -n 1 $file
tail -n 1 $file
doneDownload/copy my_first_bash_script.sh. For more on Bash scripts, see Bash Scripting Tutorial - Ryans Tutorials.
Key Points
- Looping is the foundation for working smarter with the command line
- Loops help us to do the same (or similar) things to a bunch of items