Difference between revisions of "BaBE - Bash By Examples"
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<metadesc>BaBE - Bash by Examples; Your significant Linux scripting tutorial: Redirection, Piping, conditional execution, user dialogs, loops, process management, backticks, string replacement, pitfalls and much more.</metadesc> | <metadesc>BaBE - Bash by Examples; Your significant Linux scripting tutorial: Redirection, Piping, conditional execution, user dialogs, loops, process management, backticks, string replacement, pitfalls and much more.</metadesc> | ||
+ | |||
BaBE - Bash By Examples; Your significant Linux scripting tutorial;; | BaBE - Bash By Examples; Your significant Linux scripting tutorial;; | ||
− | <pic src="http://www.linuxintro.org/images/Bash-scripting-mindmap.jpg" width=70% align=right caption=MindMap /> | + | <pic src="http://www.linuxintro.org/images/Bash-scripting-mindmap.jpg" width=70% align=right caption="MindMap of what you can learn about Linux scripting" /> |
= Hello world = | = Hello world = | ||
The easiest way to get your feet wet with a programming language is to start with a program that simply outputs a trivial text, the so-called hello-world-example. Here it is for bash: | The easiest way to get your feet wet with a programming language is to start with a program that simply outputs a trivial text, the so-called hello-world-example. Here it is for bash: | ||
* create a file named hello in your home directory with the following content: | * create a file named hello in your home directory with the following content: | ||
− | + | #!/bin/bash | |
− | + | echo "Hello, world!" | |
− | * [[open a console]], | + | * [[open a console]], make the file executable: |
− | |||
chmod +x hello | chmod +x hello | ||
* now you can execute your file like this: | * now you can execute your file like this: | ||
− | + | ./hello | |
Hello, world! | Hello, world! | ||
* or like this: | * or like this: | ||
− | + | bash hello | |
Hello, world! | Hello, world! | ||
You see - the output of your shell [[program]] is the same as if you had entered the commands into a console. | You see - the output of your shell [[program]] is the same as if you had entered the commands into a console. | ||
Line 34: | Line 34: | ||
read name | read name | ||
echo "hello $name" | echo "hello $name" | ||
+ | |||
You see that the name is stored in a variable $name. Note the quotation marks '''"''' around "hello $name". By using these you say that you want variables to be replaced by their content. If you were to use apostrophes, the name would not be printed, but $name instead. | You see that the name is stored in a variable $name. Note the quotation marks '''"''' around "hello $name". By using these you say that you want variables to be replaced by their content. If you were to use apostrophes, the name would not be printed, but $name instead. | ||
Line 41: | Line 42: | ||
or | or | ||
echo "${name}" | echo "${name}" | ||
− | So what is the sense of this? Imagine you want to | + | So what is the sense of this? Imagine you want to append a string, without any blank, to a variable: |
echo "if I add the syllable owa to your name it will be ${name}owa" | echo "if I add the syllable owa to your name it will be ${name}owa" | ||
Line 52: | Line 53: | ||
= parameters = | = parameters = | ||
− | + | ||
− | echo "Here are all parameters you called this script with: $@" | + | echo "Here are all parameters you called this script with: $@" |
− | echo "Here is parameter 1: $1" | + | echo "Here is parameter 1: $1" |
− | echo "Which parameter do you want to be shown? " | + | echo "Which parameter do you want to be shown? " |
− | read number | + | read number |
− | args=("$@") | + | args=("$@") |
− | echo "${args[$number-1]}" | + | echo "${args[$number-1]}" |
− | |||
= return codes = | = return codes = | ||
Line 81: | Line 81: | ||
= line feeds = | = line feeds = | ||
− | + | In bash you can use line feeds or semicolons to separate commands. For example: | |
+ | |||
read name | read name | ||
if [ $name = "Thorsten" ]; then echo "I know you"; fi | if [ $name = "Thorsten" ]; then echo "I know you"; fi | ||
+ | |||
Instead of a semicolon you can write a line feed like this: | Instead of a semicolon you can write a line feed like this: | ||
+ | |||
read name | read name | ||
if [ $name = "Thorsten" ] | if [ $name = "Thorsten" ] | ||
then echo "I know you" | then echo "I know you" | ||
fi | fi | ||
− | + | ||
+ | |||
+ | So we could put everything into one line and separate the commands by semicolons: | ||
+ | |||
read name; if [ $name = "Thorsten" ]; then echo "I know you"; fi | read name; if [ $name = "Thorsten" ]; then echo "I know you"; fi | ||
− | If you want to insert a line feed where you do not need one, e.g. to make the code better readable, | + | |
+ | |||
+ | If you want to insert a line feed where you do not need one, e.g. to make the code better readable, just put a backslash at the line's end to indicate it will continue: | ||
+ | |||
read \ | read \ | ||
name | name | ||
Line 111: | Line 120: | ||
== piping == | == piping == | ||
+ | [[Piping]] is a very elegant concept in the Linux world. It allows you to take one command's output and use it as input for the next command. Now you can divide tasks into smaller tasks. For example instead of having a program counting all files in a directory you use one program (ls) to ''list'' all files in a directory and one program (wc) to count the lines: | ||
+ | |||
+ | ls | wc -l | ||
+ | |||
+ | You can also put the output into a variable, in this case $arch: | ||
+ | |||
uname -m | while read arch; do echo "Your system is a $arch system."; done | uname -m | while read arch; do echo "Your system is a $arch system."; done | ||
Line 128: | Line 143: | ||
read name | read name | ||
if [ $name = "Thorsten" ]; then echo "I know you"; fi | if [ $name = "Thorsten" ]; then echo "I know you"; fi | ||
+ | |||
Now let's look closer at this, why does it work? Why is there a blank needed behind the [ sign? The answer is that [ is just an ordinary [[command]] in the shell. It delivers a return code for the expression that follows till the ] sign. To prove this we can write a script: | Now let's look closer at this, why does it work? Why is there a blank needed behind the [ sign? The answer is that [ is just an ordinary [[command]] in the shell. It delivers a return code for the expression that follows till the ] sign. To prove this we can write a script: | ||
+ | |||
if true; then echo "the command following if true is being executed"; fi | if true; then echo "the command following if true is being executed"; fi | ||
if false; then echo "this will not be shown"; fi | if false; then echo "this will not be shown"; fi | ||
Line 134: | Line 151: | ||
== empty strings == | == empty strings == | ||
An empty string evaluates to false inside the [ ] operators so it is possible to check if a string ''result'' is empty like this: | An empty string evaluates to false inside the [ ] operators so it is possible to check if a string ''result'' is empty like this: | ||
− | + | # result= | |
− | + | # if [ $result ]; then echo success; fi | |
− | + | # result=good | |
− | + | # if [ $result ]; then echo success; fi | |
success | success | ||
== arithmetic expressions == | == arithmetic expressions == | ||
+ | You can compare integer numbers like this: | ||
+ | |||
echo "what is your age? " | echo "what is your age? " | ||
read age | read age | ||
if (( $age >= 21 )); then echo "Let's talk about sex."; fi | if (( $age >= 21 )); then echo "Let's talk about sex."; fi | ||
+ | |||
+ | However bash does not understand floating point numbers. To compare floating numbers you will use external programs such as bc: | ||
+ | |||
+ | $ if [ $(echo "2.1<2.2"|bc) = 1 ]; then echo "correct"; else echo "wrong"; fi | ||
+ | correct | ||
+ | $ if [ $(echo "2.1>2.2"|bc) = 1 ]; then echo "correct"; else echo "wrong"; fi | ||
+ | wrong | ||
== not equal == | == not equal == | ||
To check if a variable is NOT equal to whatever, use !=: | To check if a variable is NOT equal to whatever, use !=: | ||
+ | |||
if [ "$LANG" != "C" ]; then echo "please set your system lanugage to C"; fi | if [ "$LANG" != "C" ]; then echo "please set your system lanugage to C"; fi | ||
Line 224: | Line 251: | ||
= functions = | = functions = | ||
To define a function in bash, use a non-keyword and append opening and closing parentheses. Here a function greet is defined and it prints "Hello, world!". Then it is called: | To define a function in bash, use a non-keyword and append opening and closing parentheses. Here a function greet is defined and it prints "Hello, world!". Then it is called: | ||
− | greet() | + | # greet() |
{ | { | ||
− | echo "Hello, world | + | echo "Hello, world" |
} | } | ||
− | greet | + | # greet |
+ | |||
+ | If you hand over parameters you can greet any planet you like: | ||
+ | # greet() | ||
+ | { | ||
+ | echo "Hello, $1" | ||
+ | } | ||
+ | # greet Mars | ||
+ | Hello, Mars | ||
+ | # greet World | ||
+ | Hello, World | ||
= react on CTRL_C = | = react on CTRL_C = | ||
The command trap allows you to trap CTRL_C keystrokes so your script will not be aborted | The command trap allows you to trap CTRL_C keystrokes so your script will not be aborted | ||
− | |||
− | |||
− | trap shelltrap INT | + | #!/bin/bash |
+ | |||
+ | trap shelltrap INT | ||
+ | |||
+ | shelltrap() | ||
+ | { | ||
+ | echo "You pressed CTRL_C, but I don't let you escape" | ||
+ | } | ||
+ | |||
+ | while true; do read line; done | ||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
;Note: You can still ''pause'' your script by pressing CTRL_Z, send it to the [[background]] and kill it there. To catch CTRL_Z, replace INT by TSTP in the above example. To get an overview of all signals that you might be able to trap, [[open a console]] and enter | ;Note: You can still ''pause'' your script by pressing CTRL_Z, send it to the [[background]] and kill it there. To catch CTRL_Z, replace INT by TSTP in the above example. To get an overview of all signals that you might be able to trap, [[open a console]] and enter | ||
Line 251: | Line 288: | ||
== awk: read a specific column == | == awk: read a specific column == | ||
[[awk]] is a program that is installed on almost all Linux distributions. It is a good helper for text stream processing. It can extract columns from a text. Let's imagine you want to use the [[program]] [[vmstat]] to find out how high the CPU user load was. Here is the output from vmstat: | [[awk]] is a program that is installed on almost all Linux distributions. It is a good helper for text stream processing. It can extract columns from a text. Let's imagine you want to use the [[program]] [[vmstat]] to find out how high the CPU user load was. Here is the output from vmstat: | ||
− | + | ||
− | + | <pic src="http://www.linuxintro.org/images/vmstat.png" align=text width=100% caption=VmStat /> | |
− | + | ||
We see the user load is in colum 13, and we only want to print this column. We do it with the following command: | We see the user load is in colum 13, and we only want to print this column. We do it with the following command: | ||
vmstat 5 | awk '{print $13}' | vmstat 5 | awk '{print $13}' | ||
Line 266: | Line 303: | ||
To store the CPU user load into a variable we use | To store the CPU user load into a variable we use | ||
load=$(vmstat 1 2 | tail -n 1 | awk '{print $13}') | load=$(vmstat 1 2 | tail -n 1 | awk '{print $13}') | ||
+ | |||
What happens here? First vmstat outputs some data in its first line. The data about CPU load can only be rubbish because it did not have any time to measure it. So we let it output 2 lines and wait 1 second between them ( => vmstat 1 2 ). From this command we only read the last line ( => tail -n 1 ). From this line we only print column 13 ( => awk '{print $13}' ). This output is stored into the variable $load ( => load=$(...) ). | What happens here? First vmstat outputs some data in its first line. The data about CPU load can only be rubbish because it did not have any time to measure it. So we let it output 2 lines and wait 1 second between them ( => vmstat 1 2 ). From this command we only read the last line ( => tail -n 1 ). From this line we only print column 13 ( => awk '{print $13}' ). This output is stored into the variable $load ( => load=$(...) ). | ||
== grep: search a string == | == grep: search a string == | ||
[[grep]] is a [[program]] that is installed on almost all Linux distributions. It is a good helper for text stream processing. It can extract lines that contain a string or match a [[regex]] pattern. Let's imagine you want all external links from www.linuxintro.org's main page: | [[grep]] is a [[program]] that is installed on almost all Linux distributions. It is a good helper for text stream processing. It can extract lines that contain a string or match a [[regex]] pattern. Let's imagine you want all external links from www.linuxintro.org's main page: | ||
+ | |||
wget -O linuxintro.txt http://www.linuxintro.org | wget -O linuxintro.txt http://www.linuxintro.org | ||
− | grep "http:" linuxintro.txt | + | grep "http:" linuxintro.txt |
== sed: replace a string == | == sed: replace a string == | ||
Line 284: | Line 323: | ||
* to replace protocol names for a given port (in this case 3200) in /etc/services: | * to replace protocol names for a given port (in this case 3200) in /etc/services: | ||
+ | |||
sed -ri "s/.{16}3200/sapdp00 3200/" /etc/services | sed -ri "s/.{16}3200/sapdp00 3200/" /etc/services | ||
+ | |||
* if you have an [[apache]] [[web server]] here's how you get the latest websites that have been requested: | * if you have an [[apache]] [[web server]] here's how you get the latest websites that have been requested: | ||
− | cat /var/log/apache2/access_log | sed " | + | |
+ | cat /var/log/apache2/access_log | sed ";.*\(GET [^\"]*\).*;\1;" | ||
== tr: replace linebreaks == | == tr: replace linebreaks == | ||
[[sed]] is a [[program]] that is installed on almost all Linux distributions. It is a good helper for text stream processing. It can replace a character by another one, even over line breaks. | [[sed]] is a [[program]] that is installed on almost all Linux distributions. It is a good helper for text stream processing. It can replace a character by another one, even over line breaks. | ||
For example here is how you remove all empty lines from your processor information: | For example here is how you remove all empty lines from your processor information: | ||
− | # cat /proc/cpuinfo | while read a; do ar=$(echo -n $a|tr '\n' ';') | + | |
+ | # cat /proc/cpuinfo | while read a; do ar=$(echo -n $a|tr '\n' ';') | ||
+ | if [ "$ar" <> ";" ]; then echo "$ar"; fi; done | ||
== wc: count == | == wc: count == | ||
With the command wc you can count words, characters and lines. wc -l counts lines. For example to find out how many semicolons are in a line, use the following statement: | With the command wc you can count words, characters and lines. wc -l counts lines. For example to find out how many semicolons are in a line, use the following statement: | ||
− | while read line | + | |
+ | while read line | ||
+ | do echo "$line" | tr '\n' ' ' | sed "s/;/\n/g" | wc -l | ||
+ | done | ||
+ | |||
It lets you input a line of text, counts the semicolons in it and outputs the number. | It lets you input a line of text, counts the semicolons in it and outputs the number. | ||
Line 313: | Line 361: | ||
It will display this dialog: | It will display this dialog: | ||
− | + | <pic src=http://www.linuxintro.org/images/Snapshot-dialog.png /> | |
This has been taken from http://www.linuxjournal.com/article/2807. Read there for more info. | This has been taken from http://www.linuxjournal.com/article/2807. Read there for more info. | ||
Line 331: | Line 379: | ||
* http://mywiki.wooledge.org/BashPitfalls | * http://mywiki.wooledge.org/BashPitfalls | ||
+ | [http://www.facebook.com/sharer.php?u=http%3A%2F%2Fwww.linuxintro.org%2Fwiki%2FShell_scripting_tutorial&t=Shell%20scripting%20Tutorial&src=sp Share on Facebook] | ||
+ | |||
+ | <stumbleuponbutton /> | ||
+ | |||
+ | [[Category:Mindmap]] | ||
[[Category:Learning]] | [[Category:Learning]] |
Latest revision as of 20:00, 24 March 2021
BaBE - Bash By Examples; Your significant Linux scripting tutorial;;
MindMap of what you can learn about Linux scripting |
Contents
- 1 Hello world
- 2 calling commands
- 3 variables
- 4 parameters
- 5 return codes
- 6 line feeds
- 7 storing a command's output
- 8 conditions
- 9 Redirections
- 10 filling files
- 11 loops
- 12 negations
- 13 sending a process to the background
- 14 forking a process
- 15 functions
- 16 react on CTRL_C
- 17 helpful programs
- 18 See also
Hello world
The easiest way to get your feet wet with a programming language is to start with a program that simply outputs a trivial text, the so-called hello-world-example. Here it is for bash:
- create a file named hello in your home directory with the following content:
#!/bin/bash echo "Hello, world!"
- open a console, make the file executable:
chmod +x hello
- now you can execute your file like this:
./hello Hello, world!
- or like this:
bash hello Hello, world!
You see - the output of your shell program is the same as if you had entered the commands into a console.
calling commands
In your shell script you can call every command that you can call when opening a console:
echo "This is a directory listing, latest modified files at the bottom:" ls -ltr echo "Now calling a browser" firefox echo "Continuing with the script"
variables
input
To show you how to deal with variables, we will now write a script that asks for your name and greets you:
echo "what is your name? " read name echo "hello $name"
You see that the name is stored in a variable $name. Note the quotation marks " around "hello $name". By using these you say that you want variables to be replaced by their content. If you were to use apostrophes, the name would not be printed, but $name instead.
${}
The ${} operator stands for the variable, there is no difference if you write
echo "$name"
or
echo "${name}"
So what is the sense of this? Imagine you want to append a string, without any blank, to a variable:
echo "if I add the syllable owa to your name it will be ${name}owa"
common mistakes
Note that the variable is called $name, however the correct statement to read it from the keyboard is
read name
It is a common mistake to write
read $name
which means "read a string and store it into the variable whose name is stored in $name"
parameters
echo "Here are all parameters you called this script with: $@" echo "Here is parameter 1: $1" echo "Which parameter do you want to be shown? " read number args=("$@") echo "${args[$number-1]}"
return codes
Every bash script can communicate with the rest of the system by
The return code is 0 if everything worked well. You can query it for the most recent command using $?:
bootstick@bootstick:~$ echo "hello world"; echo $? hello world 0 bootstick@bootstick:~$ echo "hello world">/proc/cmdline; echo $? bash: /proc/cmdline: Permission denied 1
In bash, true is 0 and false is any value but 0. There exist two commands, true and false that deliver true or false, respectively:
bootstick@bootstick:~$ true; echo $? 0 bootstick@bootstick:~$ false; echo $? 1
line feeds
In bash you can use line feeds or semicolons to separate commands. For example:
read name if [ $name = "Thorsten" ]; then echo "I know you"; fi
Instead of a semicolon you can write a line feed like this:
read name if [ $name = "Thorsten" ] then echo "I know you" fi
So we could put everything into one line and separate the commands by semicolons:
read name; if [ $name = "Thorsten" ]; then echo "I know you"; fi
If you want to insert a line feed where you do not need one, e.g. to make the code better readable, just put a backslash at the line's end to indicate it will continue:
read \ name if [ $name = "Thorsten" ] then \ echo "I know you" fi
storing a command's output
To read a command's output into a variable use $(), backticks or piping.
$()
arch=$(uname -m) echo "Your system is a $arch system."
backticks
arch=`uname -m` echo "Your system is a $arch system."
piping
Piping is a very elegant concept in the Linux world. It allows you to take one command's output and use it as input for the next command. Now you can divide tasks into smaller tasks. For example instead of having a program counting all files in a directory you use one program (ls) to list all files in a directory and one program (wc) to count the lines:
ls | wc -l
You can also put the output into a variable, in this case $arch:
uname -m | while read arch; do echo "Your system is a $arch system."; done
comparison
The advantage of using backticks over $() is that backticks also work in the sh shell. The advantage of using $() over backticks is that you can cascade them. In the example below we use this possibility to get a list of all files installed with rpm on the system:
filelist=$(rpm -ql $(rpm -qa))
You can use the piping approach if you need to cascade in sh, but this is not focus of this bash tutorial.
common mistakes
Usually unexperienced programmers try something like
uname -m | read arch
which does not work. You must embed the read into a while loop.
conditions
The easiest form of a condition in bash is this if example:
echo "what is your name? " read name if [ $name = "Thorsten" ]; then echo "I know you"; fi
Now let's look closer at this, why does it work? Why is there a blank needed behind the [ sign? The answer is that [ is just an ordinary command in the shell. It delivers a return code for the expression that follows till the ] sign. To prove this we can write a script:
if true; then echo "the command following if true is being executed"; fi if false; then echo "this will not be shown"; fi
empty strings
An empty string evaluates to false inside the [ ] operators so it is possible to check if a string result is empty like this:
# result= # if [ $result ]; then echo success; fi # result=good # if [ $result ]; then echo success; fi success
arithmetic expressions
You can compare integer numbers like this:
echo "what is your age? " read age if (( $age >= 21 )); then echo "Let's talk about sex."; fi
However bash does not understand floating point numbers. To compare floating numbers you will use external programs such as bc:
$ if [ $(echo "2.1<2.2"|bc) = 1 ]; then echo "correct"; else echo "wrong"; fi correct $ if [ $(echo "2.1>2.2"|bc) = 1 ]; then echo "correct"; else echo "wrong"; fi wrong
not equal
To check if a variable is NOT equal to whatever, use !=:
if [ "$LANG" != "C" ]; then echo "please set your system lanugage to C"; fi
common mistakes
Common mistakes are:
- to forget the blank behind/before the [ or ] character
- to forget the blank behind/before the equal sign
- see what does "unary operator expected" mean
Redirections
To redirect the output of a command to a file you have to consider that there are two output streams in UNIX, stdout and stderr.
filling files
To create a file, probably the easiest way is to use cat. The following example writes text into README till a line occurs that only contains the string "EOF":
cat >README<<EOF This is line 1 This is line 2 This is the last line EOF
Afterwards, README will contain the 3 lines below the cat command and above the line with EOF.
loops
for loops
Here is an example for a for-loop. It makes a backup of all text files:
for i in *.txt; do cp $i $i.bak; done
The above command takes each .txt file in the current directory, stores it in the variable $i and copies it to $i.bak. So file.txt gets copied to file.txt.bat.
You can also use subsequent numbers as a for loop using the command seq like this:
for i in $(seq 1 1 3); do echo $i; done
while loops
$ while true; do read line; done
negations
You can negate a result with the ! operator. $? is the last command's return code:
# true # echo $? 0 # false # echo $? 1 # ! true # echo $? 1 # ! false # echo $? 0
So you get an endless loop out of:
while ! false; do echo hallo; done
The following code checks the file /tmp/success to contain "success". As long as this is not the case it continues checking:
while ! (grep "success" /tmp/success) do sleep 30 done
The following code checks if the file dblog.log exists. As long as this is not the case it tries to download it via ftp:
while ! (test -e dblog.log); do ftp -p ftp://user:password@server/tmp/dblog.log >/dev/null echo -en "." sleep 1 done
common mistakes
- bash is very picky regarding spaces. There MUST be a space after the ! if it means negation.
sending a process to the background
To send a process to the background, use the ampersand sign (&):
firefox & echo "Firefox has been started"
You see a newline is not needed after the &
forking a process
You can build a process chain using parantheses. This is useful if you want to have two instruction streams being executed in parallel:
(find -iname "helloworld.txt") & (sleep 5; echo "Timeout exceeded, killing process"; kill $!)
functions
To define a function in bash, use a non-keyword and append opening and closing parentheses. Here a function greet is defined and it prints "Hello, world!". Then it is called:
# greet() { echo "Hello, world" } # greet
If you hand over parameters you can greet any planet you like:
# greet() { echo "Hello, $1" } # greet Mars Hello, Mars # greet World Hello, World
react on CTRL_C
The command trap allows you to trap CTRL_C keystrokes so your script will not be aborted
#!/bin/bash trap shelltrap INT shelltrap() { echo "You pressed CTRL_C, but I don't let you escape" } while true; do read line; done
- Note
- You can still pause your script by pressing CTRL_Z, send it to the background and kill it there. To catch CTRL_Z, replace INT by TSTP in the above example. To get an overview of all signals that you might be able to trap, open a console and enter
kill -l
helpful programs
awk: read a specific column
awk is a program that is installed on almost all Linux distributions. It is a good helper for text stream processing. It can extract columns from a text. Let's imagine you want to use the program vmstat to find out how high the CPU user load was. Here is the output from vmstat:
VmStat |
We see the user load is in colum 13, and we only want to print this column. We do it with the following command:
vmstat 5 | awk '{print $13}'
This will print a line from vmstat all 5 seconds and only write the column 13. It looks like this:
# vmstat 5 | awk '{print $13}' us 1 1 0 1
To store the CPU user load into a variable we use
load=$(vmstat 1 2 | tail -n 1 | awk '{print $13}')
What happens here? First vmstat outputs some data in its first line. The data about CPU load can only be rubbish because it did not have any time to measure it. So we let it output 2 lines and wait 1 second between them ( => vmstat 1 2 ). From this command we only read the last line ( => tail -n 1 ). From this line we only print column 13 ( => awk '{print $13}' ). This output is stored into the variable $load ( => load=$(...) ).
grep: search a string
grep is a program that is installed on almost all Linux distributions. It is a good helper for text stream processing. It can extract lines that contain a string or match a regex pattern. Let's imagine you want all external links from www.linuxintro.org's main page:
wget -O linuxintro.txt http://www.linuxintro.org grep "http:" linuxintro.txt
sed: replace a string
sed is a program that is installed on almost all Linux distributions. It is a good helper for text stream processing. It can replace a string by another one. Let's imagine you want to print your distribution's name, but lsd_release outputs too much:
# lsb_release -d Description: openSUSE 12.1 (x86_64)
You want to remove this string "Description" so you replace it by nothing:
lsb_release -d | sed "s/Description:\t//" openSUSE 12.1 (x86_64)
Once you understand regular expressions you can use sed with them:
- to replace protocol names for a given port (in this case 3200) in /etc/services:
sed -ri "s/.{16}3200/sapdp00 3200/" /etc/services
- if you have an apache web server here's how you get the latest websites that have been requested:
cat /var/log/apache2/access_log | sed ";.*\(GET [^\"]*\).*;\1;"
tr: replace linebreaks
sed is a program that is installed on almost all Linux distributions. It is a good helper for text stream processing. It can replace a character by another one, even over line breaks. For example here is how you remove all empty lines from your processor information:
# cat /proc/cpuinfo | while read a; do ar=$(echo -n $a|tr '\n' ';') if [ "$ar" <> ";" ]; then echo "$ar"; fi; done
wc: count
With the command wc you can count words, characters and lines. wc -l counts lines. For example to find out how many semicolons are in a line, use the following statement:
while read line do echo "$line" | tr '\n' ' ' | sed "s/;/\n/g" | wc -l done
It lets you input a line of text, counts the semicolons in it and outputs the number.
How does it do this?
It reads lines from your keyboard (while read line). It outputs the line (echo "$line"), but it does not output it in the console. The pipe (|) redirects the output to the input stream of the command tr. The command tr replaces the ENTER ('\ ') by a space (' '). The pipe (|) redirects the output to the input stream of sed. sed substitutes ("s/) the semicolon (;) by (/) a linefeed (\ ), globally (/g"). The pipe redirects the output to the input stream of the wc -l command that outputs the count of lines.
dialog: create dialogs
Dialog is a command that helps you creating dialogs in the shell. The answers given by the user are send to stderr and/or influence the command's return code. For example if you run this script:
#!/bin/bash if (dialog --title "Message" --yesno "Are you having fun?" 6 25) then echo "glad you have fun" else echo "sad you don't have fun" fi
It will display this dialog:
This has been taken from http://www.linuxjournal.com/article/2807. Read there for more info.
See also
- bash
- shell
- scripting
- bash operators
- http://en.wikibooks.org/wiki/Bash_Shell_Scripting
- http://ryanstutorials.net/linuxtutorial/scripting.php
- http://wiki.linuxquestions.org/wiki/Bash_tips
- http://wiki.linuxquestions.org/wiki/Bash
- http://linuxconfig.org/Bash_scripting_Tutorial
- http://steve-parker.org/sh/intro.shtml
- http://mywiki.wooledge.org/BashFAQ
- http://mywiki.wooledge.org/BashPitfalls