Scripts, variables, and loops
Overview
Teaching: 45 min
Exercises: 10 minQuestions
How do I turn a set of commands into a program?
Objectives
Write a shell script
Understand and manipulate UNIX permissions
Understand shell variables and how to use them
Write a simple for loop
We now know a lot of UNIX commands! Wouldn’t it be great if we could save certain commands so that we could run them later or not have to type them out again? As it turns out, this is straightforward to do. A “shell script” is essentially a text file containing a list of UNIX commands to be executed in a sequential manner. These shell scripts can be run whenever we want, and are a great way to automate our work.
Writing a Script
So how do we write a shell script, exactly? It turns out we can do this with a text editor.
Start editing a file called “demo.sh” (to recap, we can do this with nano demo.sh
). The “.sh” is
the standard file extension for shell scripts that most people use (you may also see “.bash” used).
Our shell script will have two parts:
- On the very first line, add
#!/bin/bash
. The#!
(pronounced “hash-bang”) tells our computer what program to run our script with. In this case, we are telling it to run our script with our command-line shell (what we’ve been doing everything in so far). If we wanted our script to be run with something else, like Perl, we could add#!/usr/bin/perl
- Now, anywhere below the first line, add
echo "Our script worked!"
. When our script runs,echo
will happily print outOur script worked!
.
Our file should now look like this:
#!/bin/bash
echo "Our script worked!"
Ready to run our program? Let’s try running it:
$ demo.sh
bash: demo.sh: command not found...
Strangely enough, Bash can’t find our script. As it turns out, Bash will only look in certain
directories for scripts to run. To run anything else, we need to tell Bash exactly where to look. To
run a script that we wrote ourselves, we need to specify the full path to the file, followed by the
filename. We could do this one of two ways: either with our absolute path
/home/yourUserName/demo.sh
, or with the relative path ./demo.sh
.
$ ./demo.sh
bash: ./demo.sh: Permission denied
There’s one last thing we need to do. Before a file can be run, it needs “permission” to run. Let’s
look at our file’s permissions with ls -l
:
$ ls -l
-rw-rw-r-- 1 yourUsername tc001 12534006 Jan 16 18:50 bash-lesson.tar.gz
-rw-rw-r-- 1 yourUsername tc001 40 Jan 16 19:41 demo.sh
-rw-rw-r-- 1 yourUsername tc001 77426528 Jan 16 18:50 dmel-all-r6.19.gtf
-rw-r--r-- 1 yourUsername tc001 721242 Jan 25 2016 dmel_unique_protein_isoforms_fb_2016_01.tsv
drwxrwxr-x 2 yourUsername tc001 4096 Jan 16 19:16 fastq
-rw-r--r-- 1 yourUsername tc001 1830516 Jan 25 2016 gene_association.fb.gz
-rw-rw-r-- 1 yourUsername tc001 15 Jan 16 19:17 test.txt
-rw-rw-r-- 1 yourUsername tc001 245 Jan 16 19:24 word_counts.txt
That’s a huge amount of output: a full listing of everything in the directory. Let’s see if we can understand what each field of a given row represents, working left to right.
- Permissions: On the very left side, there is a string of the characters
d
,r
,w
,x
, and-
. Thed
indicates if something is a directory (there is a-
in that spot if it is not a directory). The otherr
,w
,x
bits indicate permission to Read, Write, and eXecute a file. There are three fields ofrwx
permissions following the spot ford
. If a user is missing a permission to do something, it’s indicated by a-
.- The first set of
rwx
are the permissions that the owner has (in this case the owner isyourUsername
). - The second set of
rwx
s are permissions that other members of the owner’s group share (in this case, the group is namedtc001
). - The third set of
rwx
s are permissions that anyone else with access to this computer can do with a file. Though files are typically created with read permissions for everyone, typically the permissions on your home directory prevent others from being able to access the file in the first place.
- The first set of
- References: This counts the number of references (hard links) to the item (file, folder, symbolic link or “shortcut”).
- Owner: This is the username of the user who owns the file. Their permissions are indicated in the first permissions field.
- Group: This is the user group of the user who owns the file. Members of this user group have permissions indicated in the second permissions field.
- Size of item: This is the number of bytes in a file, or the number of filesystem
blocks occupied by the contents of a
folder. (We can use the
-h
option here to get a human-readable file size in megabytes, gigabytes, etc.) - Time last modified: This is the last time the file was modified.
- Filename: This is the filename.
So how do we change permissions? As I mentioned earlier, we need permission to execute our script.
Changing permissions is done with chmod
. To add executable permissions for all users we could use
this:
$ chmod +x demo.sh
$ ls -l
-rw-rw-r-- 1 yourUsername tc001 12534006 Jan 16 18:50 bash-lesson.tar.gz
-rwxrwxr-x 1 yourUsername tc001 40 Jan 16 19:41 demo.sh
-rw-rw-r-- 1 yourUsername tc001 77426528 Jan 16 18:50 dmel-all-r6.19.gtf
-rw-r--r-- 1 yourUsername tc001 721242 Jan 25 2016 dmel_unique_protein_isoforms_fb_2016_01.tsv
drwxrwxr-x 2 yourUsername tc001 4096 Jan 16 19:16 fastq
-rw-r--r-- 1 yourUsername tc001 1830516 Jan 25 2016 gene_association.fb.gz
-rw-rw-r-- 1 yourUsername tc001 15 Jan 16 19:17 test.txt
-rw-rw-r-- 1 yourUsername tc001 245 Jan 16 19:24 word_counts.txt
Now that we have executable permissions for that file, we can run it.
$ ./demo.sh
Our script worked!
Fantastic, we’ve written our first program! Before we go any further, let’s learn how to take notes
inside our program using comments. A comment is indicated by the #
character, followed by whatever
we want. Comments do not get run. Let’s try out some comments in the console, then add one to our
script!
# This won't show anything.
Now lets try adding this to our script with nano
. Edit your script to look something like this:
#!/bin/bash
# This is a comment... they are nice for making notes!
echo "Our script worked!"
When we run our script, the output should be unchanged from before!
Shell variables
One important concept that we’ll need to cover are shell variables. Variables are a great way of saving information under a name you can access later. In programming languages like Python and R, variables can store pretty much anything you can think of. In the shell, they usually just store text. The best way to understand how they work is to see them in action.
To set a variable, simply type in a name containing only letters, numbers, and underscores, followed
by an =
and whatever you want to put in the variable. Shell variable names are often uppercase
by convention (but do not have to be).
$ VAR="This is our variable"
To use a variable, prefix its name with a $
sign. Note that if we want to simply check what a
variable is, we should use echo (or else the shell will try to run the contents of a variable).
$ echo $VAR
This is our variable
Let’s try setting a variable in our script and then recalling its value as part of a command. We’re
going to make it so our script runs wc -l
on whichever file we specify with FILE
.
Our script:
#!/bin/bash
# set our variable to the name of our GTF file
FILE=dmel-all-r6.19.gtf
# call wc -l on our file
wc -l $FILE
$ ./demo.sh
542048 dmel-all-r6.19.gtf
What if we wanted to do our little wc -l
script on other files without having to change $FILE
every time we want to use it? There is actually a special shell variable we can use in scripts that
allows us to use arguments in our scripts (arguments are extra information that we can pass to our
script, like the -l
in wc -l
).
To use the first argument to a script, use $1
(the second argument is $2
, and so on).
Let’s change our script to run wc -l
on $1
instead of $FILE
. Note that we can also pass all of
the arguments using $@
(not going to use it in this lesson, but it’s something to be aware of).
Our script:
#!/bin/bash
# call wc -l on our first argument
wc -l $1
$ ./demo.sh dmel_unique_protein_isoforms_fb_2016_01.tsv
22129 dmel_unique_protein_isoforms_fb_2016_01.tsv
Nice! One thing to be aware of when using variables: they are all treated as pure text. How do we
save the output of an actual command like ls -l
?
A demonstration of what doesn’t work:
$ TEST=ls -l
-bash: -l: command not found
What does work (we need to surround any command with $(command)
):
$ TEST=$(ls -l)
$ echo $TEST
total 90372 -rw-rw-r-- 1 jeff jeff 12534006 Jan 16 18:50 bash-lesson.tar.gz -rwxrwxr-x. 1 jeff jeff 40 Jan 1619:41 demo.sh -rw-rw-r-- 1 jeff jeff 77426528 Jan 16 18:50 dmel-all-r6.19.gtf -rw-r--r-- 1 jeff jeff 721242 Jan 25 2016 dmel_unique_protein_isoforms_fb_2016_01.tsv drwxrwxr-x. 2 jeff jeff 4096 Jan 16 19:16 fastq -rw-r--r-- 1 jeff jeff 1830516 Jan 25 2016 gene_association.fb.gz -rw-rw-r-- 1 jeff jeff 15 Jan 16 19:17 test.txt -rw-rw-r-- 1 jeff jeff 245 Jan 16 19:24 word_counts.txt
Note that everything got printed on the same line. This is a feature, not a bug, as it allows us to
use $(commands)
inside lines of script without triggering line breaks (which would end our line of
code and execute it prematurely).
Loops
To end our lesson on scripts, we are going to learn how to write a for-loop to execute a lot of commands at once. This will let us do the same string of commands on every file in a directory (or other stuff of that nature).
for-loops generally have the following syntax:
#!/bin/bash
for VAR in first second third
do
echo $VAR
done
When a for-loop gets run, the loop will run once for everything following the word in
. In each
iteration, the variable $VAR
is set to a particular value for that iteration. In this case it will
be set to first
during the first iteration, second
on the second, and so on. During each
iteration, the code between do
and done
is performed.
Let’s run the script we just wrote (I saved mine as loop.sh
).
$ chmod +x loop.sh
$ ./loop.sh
first
second
third
What if we wanted to loop over a shell variable, such as every file in the current directory? Shell
variables work perfectly in for-loops. In this example, we’ll save the result of ls
and loop over
each file:
#!/bin/bash
FILES=$(ls)
for VAR in $FILES
do
echo $VAR
done
$ ./loop.sh
bash-lesson.tar.gz
demo.sh
dmel_unique_protein_isoforms_fb_2016_01.tsv
dmel-all-r6.19.gtf
fastq
gene_association.fb.gz
loop.sh
test.txt
word_counts.txt
There’s a shortcut to run on all files of a particular type, say all .gz
files:
#!/bin/bash
for VAR in *.gz
do
echo $VAR
done
bash-lesson.tar.gz
gene_association.fb.gz
Writing our own scripts and loops
cd
to ourfastq
directory from earlier and write a loop to print off the name and top 4 lines of every fastq file in that directory.Is there a way to only run the loop on fastq files ending in
_1.fastq
?Solution
Create the following script in a file called
head_all.sh
#!/bin/bash for FILE in *.fastq do echo $FILE head -n 4 $FILE done
The “for” line could be modified to be
for FILE in *_1.fastq
to achieve the second aim
Concatenating variables
Concatenating (i.e. mashing together) variables is quite easy to do. Add whatever you want to concatenate to the beginning or end of the shell variable after enclosing it in
{}
characters.FILE=stuff.txt echo ${FILE}.example
stuff.txt.example
Can you write a script that prints off the name of every file in a directory with “.processed” added to it?
Solution
Create the following script in a file called
process.sh
#!/bin/bash for FILE in * do echo ${FILE}.processed done
Note that this will also print directories appended with “.processed”. To truly only get files and not directories, we need to modify this to use the
find
command to give us only files in the current directory:#!/bin/bash for FILE in $(find . -max-depth 1 -type f) do echo ${FILE}.processed done
but this will have the side-effect of listing hidden files too.
Special permissions
What if we want to give different sets of users different permissions.
chmod
actually accepts special numeric codes instead of stuff likechmod +x
. The numeric codes are as follows: read = 4, write = 2, execute = 1. For each user we will assign permissions based on the sum of these permissions (must be between 7 and 0).Let’s make an example file and give everyone permission to do everything with it.
touch example ls -l example chmod 777 example ls -l example
How might we give ourselves permission to do everything with a file, but allow no one else to do anything with it.
Solution
chmod 700 example
We want all permissions so: 4 (read) + 2 (write) + 1 (execute) = 7 for user (first position), no permissions, i.e. 0, for group (second position) and all (third position).
Key Points
A shell script is just a list of bash commands in a text file.
chmod +x script.sh
will give it permission to execute.