UNIX Introduction
What is
UNIX?
UNIX is
an operating system which was first developed in the 1960s, and has been under
constant development ever since. By operating system, we mean the suite of
programs which make the computer work. It is a stable, multi-user,
multi-tasking system for servers, desktops and laptops.
UNIX
systems also have a graphical user interface (GUI) similar to Microsoft Windows
which provides an easy to use environment. However, knowledge of UNIX is
required for operations which aren't covered by a graphical program, or for
when there is no windows interface available, for example, in a telnet session.
Types of
UNIX
There
are many different versions of UNIX, although they share common similarities.
The most popular varieties of UNIX are Sun Solaris, GNU/Linux, and MacOS X.
Here in
the School, we use Solaris on our servers and workstations, and Fedora Linux on
the servers and desktop PCs.
The UNIX
operating system
The
UNIX operating system is made up of three parts; the kernel, the shell and the
programs.
The kernel
The
kernel of UNIX is the hub of the operating system: it allocates time and memory
to programs and handles the filestore and communications in response to system
calls.
As an
illustration of the way that the shell and the kernel work together, suppose a
user types rm myfile (which has the effect of removing the file myfile). The shell searches the
filestore for the file containing the program rm, and
then requests the kernel, through system calls, to execute the program rm on myfile. When the process rm myfile has finished running, the shell then returns the UNIX prompt %
to the user, indicating that it is waiting for further commands.
The shell
The
shell acts as an interface between the user and the kernel. When a user logs
in, the login program checks the username and password, and then starts another
program called the shell. The shell is a command line interpreter (CLI). It
interprets the commands the user types in and arranges for them to be carried
out. The commands are themselves programs: when they terminate, the shell gives
the user another prompt (% on our systems).
The
adept user can customise his/her own shell, and users can use different shells
on the same machine. Staff and students in the school have the tcsh shell by
default.
The
tcsh shell has certain features to help the user inputting commands.
Filename
Completion - By typing part of the name of a command, filename or directory and
pressing the [Tab] key, the tcsh shell will complete the rest of the
name automatically. If the shell finds more than one name beginning with those
letters you have typed, it will beep, prompting you to type a few more letters
before pressing the tab key again.
History
- The shell keeps a list of the commands you have typed in. If you need to
repeat a command, use the cursor keys to scroll up and down the list or type
history for a list of previous commands.
Files and
processes
Everything
in UNIX is either a file or a process.
A
process is an executing program identified by a unique PID (process
identifier).
A file
is a collection of data. They are created by users using text editors, running
compilers etc.
Examples
of files:
- a document
(report, essay etc.)
- the text of a
program written in some high-level programming language
- instructions
comprehensible directly to the machine and incomprehensible to a casual
user, for example, a collection of binary digits (an executable or binary
file);
- a directory,
containing information about its contents, which may be a mixture of other
directories (subdirectories) and ordinary files.
The
Directory Structure
All the
files are grouped together in the directory structure. The file-system is
arranged in a hierarchical structure, like an inverted tree. The top of the
hierarchy is traditionally called root (written
as a slash / )
In the
diagram above, we see that the home directory of the undergraduate student "ee51vn" contains
two sub-directories (docsand pics) and a
file called report.doc.
The
full path to the file report.doc is "/home/its/ug1/ee51vn/report.doc"
Starting
an UNIX terminal
To open
an UNIX terminal window, click on the "Terminal" icon from
Applications/Accessories menus.
An UNIX
Terminal window will then appear with a % prompt, waiting for you to start
entering commands.
UNIX Tutorial One
1.1
Listing files and directories
ls (list)
When
you first login, your current working directory is your home directory. Your
home directory has the same name as your user-name, for example, ee91ab, and it is where your personal files and subdirectories are
saved.
To find
out what is in your home directory, type
% ls
The ls command
( lowercase L and lowercase S ) lists the contents of your current working
directory.
There
may be no files visible in your home directory, in which case, the UNIX prompt
will be returned. Alternatively, there may already be some files inserted by
the System Administrator when your account was created.
ls does not, in fact, cause all the files in your home directory to
be listed, but only those ones whose name does not begin with a dot (.) Files
beginning with a dot (.) are known as hidden files and usually contain important
program configuration information. They are hidden because you should not
change them unless you are very familiar with UNIX!!!
To list
all files in your home directory including those whose names begin with a dot,
type
% ls -a
As you
can see, ls -a lists files that are normally hidden.
ls is an example of a command which can take options: -a is an
example of an option. The options change the behaviour of the command. There
are online manual pages that tell you which options a particular command can
take, and how each option modifies the behaviour of the command. (See later in
this tutorial)
1.2
Making Directories
mkdir (make directory)
We will
now make a subdirectory in your home directory to hold the files you will be
creating and using in the course of this tutorial. To make a subdirectory
called unixstuff in your current working directory type
% mkdir unixstuff
To see
the directory you have just created, type
% ls
1.3
Changing to a different directory
cd (change directory)
The
command cd directory means change the current working directory to 'directory'. The current working directory may be thought
of as the directory you are in, i.e. your current position in the file-system
tree.
To
change to the directory you have just made, type
% cd unixstuff
Type ls to see
the contents (which should be empty)
Exercise 1a
Make
another directory inside the unixstuff directory
called backups
1.4 The
directories . and ..
Still
in the unixstuff directory,
type
% ls -a
As you
can see, in the unixstuff directory
(and in all other directories), there are two special directories called (.) and (..)
The current directory (.)
In
UNIX, (.) means
the current directory, so typing
% cd .
NOTE: there is a space
between cd and the dot
means
stay where you are (the unixstuff directory).
This
may not seem very useful at first, but using (.) as
the name of the current directory will save a lot of typing, as we shall see
later in the tutorial.
The parent directory (..)
(..) means the parent of the current directory, so typing
% cd ..
will
take you one directory up the hierarchy (back to your home directory). Try it
now.
Note:
typing cd with no
argument always returns you to your home directory. This is very useful if you
are lost in the file system.
1.5
Pathnames
pwd (print working
directory)
Pathnames
enable you to work out where you are in relation to the whole file-system. For
example, to find out the absolute pathname of your home-directory, type cd to get
back to your home-directory and then type
% pwd
The
full pathname will look something like this -
/home/its/ug1/ee51vn
which
means that ee51vn (your home directory) is in the sub-directory ug1 (the
group directory),which in turn is located in theits sub-directory, which is in the home sub-directory, which is in the top-level root directory called
" / " .
Exercise 1b
Use the
commands cd, ls and pwd to
explore the file system.
(Remember,
if you get lost, type cd by itself to return to your home-directory)
1.6 More
about home directories and pathnames
Understanding pathnames
First
type cd to get back to your home-directory, then type
% ls unixstuff
to list
the conents of your unixstuff directory.
Now
type
% ls backups
You
will get a message like this -
backups: No such file
or directory
The
reason is, backups is not
in your current working directory. To use a command on a file (or directory)
not in the current working directory (the directory you are currently in), you
must either cd to the correct directory, or specify its full pathname. To list
the contents of your backups directory, you must type
% ls unixstuff/backups
~ (your home directory)
Home
directories can also be referred to by the tilde ~ character.
It can be used to specify paths starting at your home directory. So typing
% ls ~/unixstuff
will
list the contents of your unixstuff directory, no matter where you currently
are in the file system.
What do
you think
% ls ~
would
list?
What do
you think
% ls ~/..
would
list?
Summary
|
Command
|
Meaning
|
|
ls
|
list
files and directories
|
|
ls -a
|
list
all files and directories
|
|
mkdir
|
make
a directory
|
|
cd directory
|
change
to named directory
|
|
cd
|
change
to home-directory
|
|
cd ~
|
change
to home-directory
|
|
cd ..
|
change
to parent directory
|
|
pwd
|
display
the path of the current directory
|
UNIX Tutorial Two
2.1
Copying Files
cp (copy)
cp file1 file2 is the command which makes a copy of file1 in the current working
directory and calls it file2
What we
are going to do now, is to take a file stored in an open access area of the
file system, and use the cp command to copy it to your unixstuff directory.
First, cd to your unixstuff directory.
% cd ~/unixstuff
Then at
the UNIX prompt, type,
% cp /vol/examples/tutorial/science.txt .
Note: Don't forget the
dot . at the end. Remember, in UNIX, the dot means the current
directory.
The
above command means copy the file science.txt to the
current directory, keeping the name the same.
(Note: The directory /vol/examples/tutorial/ is an
area to which everyone in the school has read and copy access. If you are from
outside the University, you can grab a copy of the file here. Use 'File/Save As..' from
the menu bar to save it into yourunixstuff directory.)
Exercise 2a
Create
a backup of your science.txt file by
copying it to a file called science.bak
2.2
Moving files
mv (move)
mv file1 file2 moves (or renames) file1 to file2
To move
a file from one place to another, use the mv command. This has the effect of
moving rather than copying the file, so you end up with only one file rather
than two.
It can
also be used to rename a file, by moving the file to the same directory, but giving
it a different name.
We are
now going to move the file science.bak to your backup directory.
First,
change directories to your unixstuff directory (can you remember how?). Then,
inside the unixstuff directory,
type
% mv science.bak backups/.
Type ls
and ls backups to see if it has worked.
2.3
Removing files and directories
rm (remove), rmdir
(remove directory)
To
delete (remove) a file, use the rm command. As an example, we are going to create a copy of the science.txt file then delete it.
Inside
your unixstuff directory,
type
% cp science.txt tempfile.txt
% ls
% rm tempfile.txt
% ls
% ls
% rm tempfile.txt
% ls
You can
use the rmdir command to remove a directory (make sure it is empty first). Try
to remove the backups directory.
You will not be able to since UNIX will not let you remove a non-empty
directory.
Exercise 2b
Create
a directory called tempstuff using mkdir , then
remove it using the rmdir command.
2.4
Displaying the contents of a file on the screen
clear (clear screen)
Before
you start the next section, you may like to clear the terminal window of the
previous commands so the output of the following commands can be clearly
understood.
At the
prompt, type
% clear
This
will clear all text and leave you with the % prompt at the top of the window.
cat (concatenate)
The
command cat can be used to display the contents of a file on the screen. Type:
% cat science.txt
As you
can see, the file is longer than than the size of the window, so it scrolls
past making it unreadable.
less
The
command less writes the contents of a file onto the screen a page at a time.
Type
% less science.txt
Press
the [space-bar] if you want to see another page, and type [q] if
you want to quit reading. As you can see, less is used in preference to cat for long files.
head
The head command
writes the first ten lines of a file to the screen.
First
clear the screen then type
% head science.txt
Then
type
% head -5 science.txt
What
difference did the -5 do to the head command?
tail
The tail command
writes the last ten lines of a file to the screen.
Clear
the screen and type
% tail science.txt
Q. How
can you view the last 15 lines of the file?
2.5
Searching the contents of a file
Simple searching using
less
Using less, you can search though a text file for a keyword (pattern). For
example, to search through science.txt for the
word'science', type
% less science.txt
then,
still in less, type
a forward slash [/] followed by the word to search
/science
As you
can see, less finds and highlights the keyword. Type [n] to search for
the next occurrence of the word.
grep (don't ask why it is
called grep)
grep is one of many standard UNIX utilities. It searches files for
specified words or patterns. First clear the screen, then type
% grep science science.txt
As you
can see, grep has printed out each line containg the word science.
Or has
it ????
Try
typing
% grep Science science.txt
The grep command
is case sensitive; it distinguishes between Science and science.
To
ignore upper/lower case distinctions, use the -i option, i.e. type
% grep -i science science.txt
To
search for a phrase or pattern, you must enclose it in single quotes (the
apostrophe symbol). For example to search for spinning top, type
% grep -i 'spinning top' science.txt
Some of
the other options of grep are:
-v display those lines that do NOT match
-n precede each matching line with the line number
-c print only the total count of matched lines
-n precede each matching line with the line number
-c print only the total count of matched lines
Try
some of them and see the different results. Don't forget, you can use more than
one option at a time. For example, the number of lines without the words
science or Science is
% grep -ivc science science.txt
wc (word count)
A handy
little utility is the wc command, short for word count. To do a word count on science.txt, type
% wc -w science.txt
To find
out how many lines the file has, type
% wc -l science.txt
Summary
|
Command
|
Meaning
|
|
cp file1 file2
|
copy
file1 and call it file2
|
|
mv file1 file2
|
move
or rename file1 to file2
|
|
rm file
|
remove
a file
|
|
rmdir directory
|
remove
a directory
|
|
cat file
|
display
a file
|
|
less file
|
display
a file a page at a time
|
|
head file
|
display
the first few lines of a file
|
|
tail file
|
display
the last few lines of a file
|
|
grep 'keyword' file
|
search
a file for keywords
|
|
wc file
|
count
number of lines/words/characters in file
|
UNIX Tutorial Three
3.1
Redirection
Most
processes initiated by UNIX commands write to the standard output (that is,
they write to the terminal screen), and many take their input from the standard
input (that is, they read it from the keyboard). There is also the standard
error, where processes write their error messages, by default, to the terminal
screen.
We have
already seen one use of the cat command to write the contents of a file to the screen.
Now
type cat without
specifing a file to read
% cat
Then
type a few words on the keyboard and press the [Return] key.
Finally
hold the [Ctrl] key down and press [d] (written as ^D for
short) to end the input.
What
has happened?
If you
run the cat command without specifing a file to read, it reads the standard
input (the keyboard), and on receiving the 'end of file' (^D), copies it
to the standard output (the screen).
In
UNIX, we can redirect both the input and the output of commands.
3.2
Redirecting the Output
We use
the > symbol to redirect the output of a command. For example, to create a
file called list1 containing
a list of fruit, type
% cat > list1
Then
type in the names of some fruit. Press [Return] after each one.
pear
banana
apple
^D {this means press [Ctrl] and [d] to stop}
banana
apple
^D {this means press [Ctrl] and [d] to stop}
What
happens is the cat command reads the standard input (the keyboard) and the >
redirects the output, which normally goes to the screen, into a file called list1
To read
the contents of the file, type
% cat list1
Exercise 3a
Using
the above method, create another file called list2 containing
the following fruit: orange, plum, mango, grapefruit. Read the contents of list2
3.2.1 Appending to a file
The
form >> appends standard output to a file. So to add more items to the
file list1, type
% cat >> list1
Then
type in the names of more fruit
peach
grape
orange
^D (Control D to stop)
grape
orange
^D (Control D to stop)
To read
the contents of the file, type
% cat list1
You
should now have two files. One contains six fruit, the other contains four
fruit.
We will
now use the cat command to join (concatenate) list1 and list2 into a new file called biglist. Type
% cat list1 list2 > biglist
What
this is doing is reading the contents of list1 and list2 in turn, then outputing
the text to the file biglist
To read
the contents of the new file, type
% cat biglist
3.3
Redirecting the Input
We use
the < symbol to redirect the input of a command.
The
command sort alphabetically or numerically sorts a list. Type
% sort
Then
type in the names of some animals. Press [Return] after each one.
dog
cat
bird
ape
^D (control d to stop)
cat
bird
ape
^D (control d to stop)
The
output will be
ape
bird
cat
dog
bird
cat
dog
Using
< you can redirect the input to come from a file rather than the keyboard.
For example, to sort the list of fruit, type
% sort < biglist
and the
sorted list will be output to the screen.
To
output the sorted list to a file, type,
% sort < biglist > slist
Use cat
to read the contents of the file slist
3.4 Pipes
To see
who is on the system with you, type
% who
One
method to get a sorted list of names is to type,
% who > names.txt
% sort < names.txt
% sort < names.txt
This is
a bit slow and you have to remember to remove the temporary file called names
when you have finished. What you really want to do is connect the output of the
who command directly to the input of the sort command. This is exactly what
pipes do. The symbol for a pipe is the vertical bar |
For
example, typing
% who | sort
will
give the same result as above, but quicker and cleaner.
To find
out how many users are logged on, type
% who | wc -l
Exercise 3b
Using
pipes, display all lines of list1 and list2 containing the letter
'p', and sort the result.
Summary
|
Command
|
Meaning
|
|
command > file
|
redirect
standard output to a file
|
|
command >> file
|
append
standard output to a file
|
|
command < file
|
redirect
standard input from a file
|
|
command1 | command2
|
pipe
the output of command1 to the input of command2
|
|
cat file1 file2 > file0
|
concatenate
file1 and file2 to file0
|
|
sort
|
sort
data
|
|
who
|
list
users currently logged in
|
UNIX Tutorial Four
4.1
Wildcards
The * wildcard
The
character * is
called a wildcard, and will match against none or more character(s) in a file
(or directory) name. For example, in your unixstuff directory,
type
% ls list*
This
will list all files in the current directory starting with list....
Try
typing
% ls *list
This
will list all files in the current directory ending with ....list
The ? wildcard
The
character ? will match exactly one character.
So ?ouse will match files like house and mouse, but not grouse.
Try typing
So ?ouse will match files like house and mouse, but not grouse.
Try typing
% ls ?list
4.2
Filename conventions
We
should note here that a directory is merely a special type of file. So the
rules and conventions for naming files apply also to directories.
In
naming files, characters with special meanings such as / * & % , should be avoided.
Also, avoid using spaces within names. The safest way to name a file is to use
only alphanumeric characters, that is, letters and numbers, together with _
(underscore) and . (dot).
|
Good filenames
|
Bad filenames
|
|
project.txt
|
project
|
|
my_big_program.c
|
my
big program.c
|
|
fred_dave.doc
|
fred
& dave.doc
|
File
names conventionally start with a lower-case letter, and may end with a dot
followed by a group of letters indicating the contents of the file. For
example, all files consisting of C code may be named with the ending .c, for example, prog1.c . Then in order to list all files containing C code in your home
directory, you need only type ls *.c in that directory.
4.3
Getting Help
On-line Manuals
There
are on-line manuals which gives information about most commands. The manual
pages tell you which options a particular command can take, and how each option
modifies the behaviour of the command. Type man command to read the manual page for a particular command.
For
example, to find out more about the wc (word
count) command, type
% man wc
Alternatively
% whatis wc
gives a
one-line description of the command, but omits any information about options
etc.
Apropos
When
you are not sure of the exact name of a command,
% apropos keyword
will
give you the commands with keyword in their manual page header. For example,
try typing
% apropos copy
Summary
|
Command
|
Meaning
|
|
*
|
match
any number of characters
|
|
?
|
match
one character
|
|
man command
|
read
the online manual page for a command
|
|
whatis command
|
brief
description of a command
|
|
apropos keyword
|
match
commands with keyword in their man pages
|
UNIX Tutorial Five
5.1 File
system security (access rights)
In your unixstuff directory,
type
% ls -l (l for long listing!)
You
will see that you now get lots of details about the contents of your directory,
similar to the example below.
Each
file (and directory) has associated access rights, which may be found by typing ls -l. Also, ls -lg gives additional information as to which group owns the file
(beng95 in the following example):
-rwxrw-r-- 1 ee51ab
beng95 2450 Sept29 11:52 file1
In the
left-hand column is a 10 symbol string consisting of the symbols d, r, w, x, -,
and, occasionally, s or S. If d is present, it will be at the left hand end of
the string, and indicates a directory: otherwise - will be the starting symbol
of the string.
The 9
remaining symbols indicate the permissions, or access rights, and are taken as
three groups of 3.
- The left group
of 3 gives the file permissions for the user that owns the file (or
directory) (ee51ab in the above example);
- the middle group
gives the permissions for the group of people to whom the file (or
directory) belongs (eebeng95 in the above example);
- the rightmost
group gives the permissions for all others.
The
symbols r, w, etc., have slightly different meanings depending on whether they
refer to a simple file or to a directory.
Access rights on files.
- r (or -),
indicates read permission (or otherwise), that is, the presence or absence
of permission to read and copy the file
- w (or -),
indicates write permission (or otherwise), that is, the permission (or
otherwise) to change a file
- x (or -),
indicates execution permission (or otherwise), that is, the permission to
execute a file, where appropriate
Access rights on
directories.
- r allows users
to list files in the directory;
- w means that
users may delete files from the directory or move files into it;
- x means the
right to access files in the directory. This implies that you may read
files in the directory provided you have read permission on the individual
files.
So, in
order to read a file, you must have execute permission on the directory
containing that file, and hence on any directory containing that directory as a
subdirectory, and so on, up the tree.
Some examples
|
-rwxrwxrwx
|
a
file that everyone can read, write and execute (and delete).
|
|
-rw-------
|
a
file that only the owner can read and write - no-one else
can read or write and no-one has execution rights (e.g. your mailbox file). |
5.2
Changing access rights
chmod (changing a file
mode)
Only
the owner of a file can use chmod to change the permissions of a file. The
options of chmod are as follows
|
Symbol
|
Meaning
|
|
u
|
user
|
|
g
|
group
|
|
o
|
other
|
|
a
|
all
|
|
r
|
read
|
|
w
|
write
(and delete)
|
|
x
|
execute
(and access directory)
|
|
+
|
add
permission
|
|
-
|
take
away permission
|
For
example, to remove read write and execute permissions on the file biglist for the group and others,
type
% chmod go-rwx biglist
This
will leave the other permissions unaffected.
To give
read and write permissions on the file biglist to all,
% chmod a+rw biglist
Exercise 5a
Try
changing access permissions on the file science.txt and on
the directory backups
Use ls -l to
check that the permissions have changed.
5.3
Processes and Jobs
A
process is an executing program identified by a unique PID (process
identifier). To see information about your processes, with their associated PID
and status, type
% ps
A
process may be in the foreground, in the background, or be suspended. In
general the shell does not return the UNIX prompt until the current process has
finished executing.
Some
processes take a long time to run and hold up the terminal. Backgrounding a
long process has the effect that the UNIX prompt is returned immediately, and
other tasks can be carried out while the original process continues executing.
Running background
processes
To
background a process, type an & at the
end of the command line. For example, the command sleep waits a given number of seconds before continuing. Type
% sleep 10
This
will wait 10 seconds before returning the command prompt %. Until the command
prompt is returned, you can do nothing except wait.
To run
sleep in the background, type
% sleep 10 &
[1] 6259
The & runs the job in the background
and returns the prompt straight away, allowing you do run other programs while
waiting for that one to finish.
The
first line in the above example is typed in by the user; the next line,
indicating job number and PID, is returned by the machine. The user is be
notified of a job number (numbered from 1) enclosed in square brackets,
together with a PID and is notified when a background process is finished.
Backgrounding is useful for jobs which will take a long time to complete.
Backgrounding a current
foreground process
At the
prompt, type
% sleep 1000
You can
suspend the process running in the foreground by typing ^Z, i.e.hold down the [Ctrl] key and type [z]. Then
to put it in the background, type
% bg
Note: do not background
programs that require user interaction e.g. vi
5.4
Listing suspended and background processes
When a
process is running, backgrounded or suspended, it will be entered onto a list
along with a job number. To examine this list, type
% jobs
An
example of a job list could be
[1] Suspended sleep
1000
[2] Running netscape
[3] Running matlab
[2] Running netscape
[3] Running matlab
To
restart (foreground) a suspended processes, type
% fg %jobnumber
For
example, to restart sleep 1000, type
% fg %1
Typing fg with no
job number foregrounds the last suspended process.
5.5
Killing a process
kill (terminate or signal
a process)
It is
sometimes necessary to kill a process (for example, when an executing program
is in an infinite loop)
To kill
a job running in the foreground, type ^C (control c). For example, run
% sleep 100
^C
^C
To kill
a suspended or background process, type
% kill %jobnumber
For
example, run
% sleep 100 &
% jobs
% jobs
If it
is job number 4, type
% kill %4
To
check whether this has worked, examine the job list again to see if the process
has been removed.
ps (process status)
Alternatively,
processes can be killed by finding their process numbers (PIDs) and using kill PID_number
% sleep 1000 &
% ps
% ps
PID TT S TIME COMMAND
20077 pts/5 S 0:05 sleep 1000
21563 pts/5 T 0:00 netscape
21873 pts/5 S 0:25 nedit
20077 pts/5 S 0:05 sleep 1000
21563 pts/5 T 0:00 netscape
21873 pts/5 S 0:25 nedit
To kill
off the process sleep
1000, type
% kill 20077
and
then type ps again to see if it has been removed from the list.
If a
process refuses to be killed, uses the -9 option,
i.e. type
% kill -9 20077
Note: It is not possible
to kill off other users' processes !!!
Summary
|
Command
|
Meaning
|
|
ls -lag
|
list
access rights for all files
|
|
chmod [options] file
|
change
access rights for named file
|
|
command &
|
run
command in background
|
|
^C
|
kill
the job running in the foreground
|
|
^Z
|
suspend
the job running in the foreground
|
|
bg
|
background
the suspended job
|
|
jobs
|
list
current jobs
|
|
fg %1
|
foreground
job number 1
|
|
kill %1
|
kill
job number 1
|
|
ps
|
list
current processes
|
|
kill 26152
|
kill
process number 26152
|
UNIX Tutorial Six
Other useful UNIX commands
quota
All students are allocated a
certain amount of disk space on the file system for their personal files,
usually about 100Mb. If you go over your quota, you are given 7 days to remove
excess files.
To check your current quota
and how much of it you have used, type
% quota -v
df
The df command reports on the space left on the
file system. For example, to find out how much space is left on the fileserver,
type
% df .
du
The du command outputs the number of kilobyes
used by each subdirectory. Useful if you have gone over quota and you want to
find out which directory has the most files. In your home-directory, type
% du -s *
The -s flag will display only a summary
(total size) and the * means all files and directories.
gzip
This reduces the size of a
file, thus freeing valuable disk space. For example, type
% ls -l
science.txt
and note the size of the file
using ls -l . Then to compress science.txt, type
% gzip
science.txt
This will compress the file
and place it in a file called science.txt.gz
To see the change in size,
type ls -l again.
To expand the file, use the gunzip command.
% gunzip
science.txt.gz
zcat
zcat will read gzipped files without needing
to uncompress them first.
% zcat
science.txt.gz
If the text scrolls too fast
for you, pipe the output though less .
% zcat
science.txt.gz | less
file
file classifies the named files according to
the type of data they contain, for example ascii (text), pictures, compressed
data, etc.. To report on all files in your home directory, type
% file *
diff
This command compares the
contents of two files and displays the differences. Suppose you have a file
called file1 and you edit some part of it and
save it as file2. To see
the differences type
% diff file1
file2
Lines beginning with a < denotes file1, while lines beginning
with a > denotes file2.
find
This searches through the
directories for files and directories with a given name, date, size, or any
other attribute you care to specify. It is a simple command but with many
options - you can read the manual by typing man find.
To search for all fies with
the extention .txt,
starting at the current directory (.) and working through all sub-directories,
then printing the name of the file to the screen, type
% find . -name
"*.txt" -print
To find files over 1Mb in
size, and display the result as a long listing, type
% find . -size
+1M -ls
history
The C shell keeps an ordered
list of all the commands that you have entered. Each command is given a number
according to the order it was entered.
% history
(show command history list)
If you are using the C shell,
you can use the exclamation character (!) to recall commands easily.
% !! (recall
last command)
% !-3 (recall
third most recent command)
% !5 (recall
5th command in list)
% !grep
(recall last command starting with grep)
You can increase the size of
the history buffer by typing
% set
history=100
UNIX Tutorial Seven
7.1
Compiling UNIX software packages
We have
many public domain and commercial software packages installed on our systems,
which are available to all users. However, students are allowed to download and
install small software packages in their own home directory, software usually
only useful to them personally.
There
are a number of steps needed to install the software.
- Locate and
download the source code (which is usually compressed)
- Unpack the
source code
- Compile the code
- Install the
resulting executable
- Set paths to the
installation directory
Of the
above steps, probably the most difficult is the compilation stage.
Compiling Source Code
All
high-level language code must be converted into a form the computer
understands. For example, C language source code is converted into a
lower-level language called assembly language. The assembly language code made
by the previous stage is then converted into object code which are fragments of
code which the computer understands directly. The final stage in compiling a
program involves linking the object code to code libraries which contain
certain built-in functions. This final stage produces an executable program.
To do
all these steps by hand is complicated and beyond the capability of the
ordinary user. A number of utilities and tools have been developed for
programmers and end-users to simplify these steps.
make and the Makefile
The make command
allows programmers to manage large programs or groups of programs. It aids in
developing large programs by keeping track of which portions of the entire
program have been changed, compiling only those parts of the program which have
changed since the last compile.
The make program
gets its set of compile rules from a text file called Makefile which resides in the same
directory as the source files. It contains information on how to compile the
software, e.g. the optimisation level, whether to include debugging info in the
executable. It also contains information on where to install the finished
compiled binaries (executables), manual pages, data files, dependent library
files, configuration files, etc.
Some
packages require you to edit the Makefile by hand to set the final installation
directory and any other parameters. However, many packages are now being
distributed with the GNU configure utility.
configure
As the
number of UNIX variants increased, it became harder to write programs which
could run on all variants. Developers frequently did not have access to every
system, and the characteristics of some systems changed from version to
version. The GNU configure and build system simplifies the building of programs
distributed as source code. All programs are built using a simple,
standardised, two step process. The program builder need not install any
special tools in order to build the program.
The configure shell
script attempts to guess correct values for various system-dependent variables
used during compilation. It uses those values to create a Makefile in each directory of the
package.
The
simplest way to compile a package is:
- cd to the directory
containing the package's source code.
- Type ./configure to configure the
package for your system.
- Type make to compile the
package.
- Optionally, type make check to run any
self-tests that come with the package.
- Type make install to install the
programs and any data files and documentation.
- Optionally, type make clean to remove the
program binaries and object files from the source code directory
The
configure utility supports a wide variety of options. You can usually use the --help option
to get a list of interesting options for a particular configure script.
The
only generic options you are likely to use are the --prefix and --exec-prefix options.
These options are used to specify the installation directories.
The
directory named by the --prefix option will hold machine independent files such as documentation,
data and configuration files.
The
directory named by the --exec-prefix option, (which is normally a subdirectory of the --prefix directory),
will hold machine dependent files such as executables.
7.2
Downloading source code
For
this example, we will download a piece of free software that converts between
different units of measurements.
First
create a download directory
% mkdir download
7.3
Extracting the source code
Go into
your download directory
and list the contents.
% cd download
% ls -l
% ls -l
As you
can see, the filename ends in tar.gz. The tar command turns several files and
directories into one single tar file. This is then compressed using the gzip
command (to create a tar.gz file).
First
unzip the file using the gunzip command. This will create a .tar file.
% gunzip units-1.74.tar.gz
Then
extract the contents of the tar file.
% tar -xvf units-1.74.tar
Again,
list the contents of the download directory,
then go to the units-1.74 sub-directory.
% cd units-1.74
7.4
Configuring and creating the Makefile
The
first thing to do is carefully read the README and INSTALL text files (use the less
command). These contain important information on how to compile and run the
software.
The
units package uses the GNU configure system to compile the source code. We will
need to specify the installation directory, since the default will be the main
system area which you will not have write permissions for. We need to create an
install directory in your home directory.
% mkdir ~/units174
Then
run the configure utility setting the installation path to this.
% ./configure --prefix=$HOME/units174
NOTE: The $HOME variable is an example of
an environment variable. The value of $HOME is the
path to your home directory. Just type
% echo $HOME
to show the contents of this variable. We will learn more about environment variables in a later chapter.
% echo $HOME
to show the contents of this variable. We will learn more about environment variables in a later chapter.
If configure has run
correctly, it will have created a Makefile with all necessary options. You can
view the Makefile if you wish (use the less command), but do not edit the contents of this.
7.5
Building the package
Now you
can go ahead and build the package by running the make command.
% make
After a
minute or two (depending on the speed of the computer), the executables will be
created. You can check to see everything compiled successfully by typing
% make check
If
everything is okay, you can now install the package.
% make install
This
will install the files into the ~/units174 directory
you created earlier.
7.6
Running the software
You are
now ready to run the software (assuming everything worked).
% cd ~/units174
If you
list the contents of the units directory, you will see a number of
subdirectories.
|
bin
|
The
binary executables
|
|
info
|
GNU
info formatted documentation
|
|
man
|
Man
pages
|
|
share
|
Shared
data files
|
To run
the program, change to the bin directory
and type
% ./units
As an
example, convert 6 feet to metres.
You have: 6 feet
You want: metres
You want: metres
* 1.8288
If you
get the answer 1.8288, congratulations, it worked.
To view
what units it can convert between, view the data file in the share directory
(the list is quite comprehensive).
To read
the full documentation, change into the info directory
and type
% info --file=units.info
7.7
Stripping unnecessary code
When a
piece of software is being developed, it is useful for the programmer to
include debugging information into the resulting executable. This way, if there
are problems encountered when running the executable, the programmer can load
the executable into a debugging software package and track down any software
bugs.
This is
useful for the programmer, but unnecessary for the user. We can assume that the
package, once finished and available for download has already been tested and
debugged. However, when we compiled the software above, debugging information
was still compiled into the final executable. Since it is unlikey that we are
going to need this debugging information, we can strip it out of the final
executable. One of the advantages of this is a much smaller executable, which
should run slightly faster.
What we
are going to do is look at the before and after size of the binary file. First
change into the bin directory
of the units installation directory.
% cd ~/units174/bin
% ls -l
% ls -l
As you
can see, the file is over 100 kbytes in size. You can get more information on
the type of file by using the file command.
% file units
units: ELF 32-bit LSB
executable, Intel 80386, version 1, dynamically linked (uses shared libs), not
stripped
To
strip all the debug and line numbering information out of the binary file, use
the strip command
% strip units
% ls -l
% ls -l
As you
can see, the file is now 36 kbytes - a third of its original size. Two thirds
of the binary file was debug code!!!
Check
the file information again.
% file units
units: ELF 32-bit LSB
executable, Intel 80386, version 1, dynamically linked (uses shared libs),
stripped
Sometimes
you can use the make command to install pre-stripped copies of all the binary files
when you install the package. Instead of typing make install,
simply type make install-strip
UNIX Tutorial Eight
8.1 UNIX
Variables
Variables
are a way of passing information from the shell to programs when you run them.
Programs look "in the environment" for particular variables and if
they are found will use the values stored. Some are set by the system, others
by you, yet others by the shell, or any program that loads another program.
Standard
UNIX variables are split into two categories, environment variables and shell
variables. In broad terms, shell variables apply only to the current instance
of the shell and are used to set short-term working conditions; environment
variables have a farther reaching significance, and those set at login are
valid for the duration of the session. By convention, environment variables
have UPPER CASE and shell variables have lower case names.
8.2
Environment Variables
An
example of an environment variable is the OSTYPE variable. The value of this is
the current operating system you are using. Type
% echo $OSTYPE
More
examples of environment variables are
- USER (your login
name)
- HOME (the path
name of your home directory)
- HOST (the name
of the computer you are using)
- ARCH (the
architecture of the computers processor)
- DISPLAY (the
name of the computer screen to display X windows)
- PRINTER (the
default printer to send print jobs)
- PATH (the
directories the shell should search to find a command)
Finding out the current
values of these variables.
ENVIRONMENT
variables are set using the setenv command, displayed using the printenv or env commands, and unset using theunsetenv command.
To show
all values of these variables, type
% printenv | less
8.3 Shell
Variables
An
example of a shell variable is the history variable. The value of this is how
many shell commands to save, allow the user to scroll back through all the
commands they have previously entered. Type
% echo $history
More
examples of shell variables are
- cwd (your
current working directory)
- home (the path
name of your home directory)
- path (the
directories the shell should search to find a command)
- prompt (the text
string used to prompt for interactive commands shell your login shell)
Finding out the current
values of these variables.
SHELL
variables are both set and displayed using the set command. They can be unset by using the unset command.
To show
all values of these variables, type
% set | less
So what is the difference
between PATH and path ?
In
general, environment and shell variables that have the same name (apart from
the case) are distinct and independent, except for possibly having the same
initial values. There are, however, exceptions.
Each
time the shell variables home, user and term are changed, the corresponding
environment variables HOME, USER and TERM receive the same values. However,
altering the environment variables has no effect on the corresponding shell
variables.
PATH
and path specify directories to search for commands and programs. Both
variables always represent the same directory list, and altering either
automatically causes the other to be changed.
8.4 Using
and setting variables
Each
time you login to a UNIX host, the system looks in your home directory for
initialisation files. Information in these files is used to set up your working
environment. The C and TC shells uses two files called .login and .cshrc (note
that both file names begin with a dot).
At
login the C shell first reads .cshrc followed
by .login
.login is to
set conditions which will apply to the whole session and to perform actions
that are relevant only at login.
.cshrc is used
to set conditions and perform actions specific to the shell and to each
invocation of it.
The
guidelines are to set ENVIRONMENT variables in the .login file and SHELL variables
in the .cshrc file.
WARNING: NEVER put commands that run graphical displays (e.g. a web
browser) in your .cshrc or .login file.
8.5
Setting shell variables in the .cshrc file
For
example, to change the number of shell commands saved in the history list, you
need to set the shell variable history. It is set to 100 by default, but you
can increase this if you wish.
% set history = 200
Check
this has worked by typing
% echo $history
However,
this has only set the variable for the lifetime of the current shell. If you
open a new xterm window, it will only have the default history value set. To
PERMANENTLY set the value of history, you will need to add the set command to
the .cshrc file.
First
open the .cshrc file in
a text editor. An easy, user-friendly editor to use is nedit.
% nedit ~/.cshrc
Add the
following line AFTER the list of other commands.
set
history = 200
Save
the file and force the shell to reread its .cshrc file buy using the shell
source command.
% source .cshrc
Check
this has worked by typing
% echo $history
8.6
Setting the path
When
you type a command, your path (or PATH) variable defines in which directories
the shell will look to find the command you typed. If the system returns a
message saying "command: Command not found", this indicates that
either the command doesn't exist at all on the system or it is simply not in
your path.
For
example, to run units, you either need to directly specify the units path (~/units174/bin/units), or you need to have
the directory ~/units174/bin in your
path.
You can
add it to the end of your existing path (the $path represents
this) by issuing the command:
% set path = ($path ~/units174/bin)
Test
that this worked by trying to run units in any directory other that where units
is actually located.
% cd
% units
% units
To add
this path PERMANENTLY, add the following line to your .cshrc AFTER the list of
other commands.
set path = ($path ~/units174/bin)
