Table of Contents

Linux Primer

Note

Please use the Table of Contents or your browsers quick search to find what you’re looking for, as this document is auto-generated from a presentation and context may not always be recognizable without the corresponding talk.


Filesystems

Filesystem 101

The job of filesystems is to keep data in a structured way. Every filesystem has a filesystem root, directories and files. The filesystem root is a special object which acts as an entry-point for using that filesystem. All other objects (directories and files) are structured below the root.

Two main concepts emerged for using more than one filesystem on a single machine:

<HTML><ol style=“list-style-type: decimal;”></HTML> <HTML><li></HTML><HTML><p></HTML>Special handling (a.k.a Drive letters)<HTML></p></HTML> <HTML><p></HTML>This is how Windows handles filesystems. It explicitly shows which drive you’re working on.<HTML></p></HTML><HTML></li></HTML> <HTML><li></HTML><HTML><p></HTML>Virtual Filesystem<HTML></p></HTML> <HTML><p></HTML>This is a more subtle approach, used by Linux, where you specify in the beginning (booting) which filesystem will be used for which part of the virtual filesystem.<HTML></p></HTML><HTML></li></HTML><HTML></ol></HTML>

Linux’ virtual filesystem tree represents all the files and directories that are reachable from the system. The nice part is that you can work on a Linux machine and not care about whether your file is on the network or on a local filesystem. The main difference for users is the performance delivered by different filesystems.

This is how the (virtual) filesystem looks on Linux:

  1. Everything starts at the root
    • the root is a directory
    • /” denotes the root directory
  2. the filesystem has different kinds of objects
    1. files
    2. directories
      • containers for multiple objects
    3. links to objects, which either
      • add a second name for the same object
      • point to a position in the filesystem
  3. objects can be referenced by their path
    • absolute: /dir1/dir2/object
    • relative: dir2/object
  4. special objects in directories:
    • .” is a reference to the directory itself
    • ..” is a reference to the parent directory
  5. the system may consist of multiple filesystems
    • filesystems may be mounted at any (empty) directory

Further concepts

Next to basic storage and organization of data filesystems have different properties and functionality. Most filesystems provide a way to store and access attributes, different kinds of special files and some filesystems provide various advanced features:

Filesystem tree

linux_directories.jpg

Special filesystems used on VSC

NFS

TMPFS

The home directory of the user is located on an NFS filesystem, which ensures that all parts of the cluster have a consistent view of files.

The filesystem behind the $SCRATCH variable is located on a tmpfs filesystem, which is a double-edged sword. On one hand it’s fast, but since it uses RAM as a storage device it does limit the amount of memory available for programs. Also you can only use data stored in a tmpfs only on the host itself.

Shell

Prompt

This is how the prompt looks by default:

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[myname@l3_ ~]$
Ways to get help when you’re stuck:

Most of the time a command doesn’t act as expected, it shows an error message. From this point you have multiple approaches:

Execution

To execute a program, we call it:

gcc FizzBuzz.c -o FizzBuzz
./FizzBuzz
false
echo $?

The examples show compiling a program, executing the result, trying to load a module on our cluster and checking if the previous command succeeded.

History

Your shell keeps a log of all the commands you executed.

Parameters

The default way to apply parameters to a program is to write a space separated list of parameters after the program when calling it.

These parameters are either

  1. Single-character
  2. Multi-character
  3. Strings

where some parameters also take additional arguments.

Combining parameters

For most commands you can combine multiple single-character parameters. This doesn’t change the meaning of the parameters, but is limited to single-character parameters which don’t take extra arguments.

COMMAND -j 2 -a -b -c
COMMAND -j 2 -abc
Ordering parameters

One thing to look out for is the order of parameters. Most of the time no specific order is required, but you should look out for things like copying the target over the source file. Also watch out to keep parameters and their arguments together.

COMMAND <SRC> <DEST>        # OK
COMMAND <DEST> <SRC>        # PROBABLY WRONG
COMMAND -j 2 --color auto   # OK
COMMAND -j auto --color 2   # PROBABLY WRONG

Escapes & Quotes

Whenever a parameter has to contain a character that is either unprintable or reserved for the shell, you can use:

  1. Backslash escape:
    • Escapes a character, that would have a special meaning
    • Can be used inside of quotes
  2. Double Quotes:
    • Similar to escaping all whitespace characters
  3. Single Quotes:
    • Additionally prevents expansion of variables
COMMAND This\ is\ a\ single\ parameter
COMMAND "This is a single parameter"
COMMAND 'This is a single parameter'

Aliases

You can define aliases in your shell. These are usually used to shorten names for commands which are used often with a fixed set of parameters or where you have to be careful to get things right. These aliases are accessable as if they were commands.

alias ll='ls -alh'
alias rm='rm -i'
alias myProject='cd $ProjectDir; testSuite; compile && testSuite; cd -'

After that, you can use the aliases synonymously.

ll        # Same as 'ls -alh'
rm        # Same as 'rm -i'
myProject # Same as 'cd $ProjectDir; testSuite; compile && testSuite; cd -'

Patterns

Patterns are an easy way of defining multiple arguments, which are mostly the same. The pattern will match anything in it’s place.

The other concept is a expansion. In this case only defined patterns will be matched.

You can try these commands and see what they do. These are all totally safe, even if you modify the arguments.

ls file.???
ls *.*
echo {{A..Z},{a..z}}
echo {{A,B},{X,Y}}
echo {A..Z},{a..z}
echo {A,B}{X,Y}

Regular Expressions

Often you need to specify some string, but patterns and expansions aren’t enough, to cover all possibilities. In these cases you can use a regular expression also known as regex. These regexes are used by editors for search and replace, the egrep command for filtering through files and inside many scripts to validate parameters.

.+                 # Match any character, once or more
\.                 # match a dot
(A|a)p{2}le        # apple, Apple
^[^aeiouAEIOU]+$   # any line of only non-vowels

For a detailed explanation see Wikipedia, Regular-expressions.info or try regex101.

If you want to challenge yourself, try Regex Crossword!

Control Flow

In the shell language there are a few ways to organize the execution path. The most important ones are:

  1. chaining of commands
  2. looping constructs
  3. conditionals (if/case)

Chaining Commands

The simplest mechanism for control flow is to chain commands together in a simple if COMMAND then NEXTCOMMAND else ERRORCOMMAND. Since this would be cumbersome to write, most shells provide simple syntax for this: COMMAND && NEXTCOMMAND || ERRORCOMMAND and if a command should be run without relying on the return value of its predecessor it’s written: COMMAND; NEXTCOMMAND. And if you only want to execute further commands in one case (but not the other), you don’t even have to specify both branches.

false ;  echo "Should I be Printed?"
false && echo "Should I be Printed?"
false || echo "Should I be Printed?"
Should I be Printed?
 
Should I be Printed?

Loops

The other way to execute commands conditionally are loops. You can loop over files, numeric arguments, until a either the loop condition is false or a break is encountered.

for i in *
do
  mv $i{,.bak}
done
while true
do
  echo "Annoying Hello World"
  sleep 3
done
for i in *; do mv $i{,.bak}; done
while true; do echo "Annoying Hello World"; sleep 3; done

Conditionals

If is similar to the previous chaining of commands, except that it is more verbose and nicer to read if you have many commands to execute one branch of the decision. For more conditions the elif (else if) statement can be used. If you use a lot of elifs and you only check one variable with them, you should consider using a case statement.

if [ $VARIABLE1 ]
then
  COMMAND1
elif [ $VARIABLE2 ]
  COMMAND2
else
  COMMAND3
fi

Case statements are for querying all states of a single variable and making a decision based on that. It can match some simple expansions, which do NOT follow the general syntax of bash expansions. Also it processes alternative matches when seperated with | (pipe character).

case $VARIABLE in
[0-9] | [1-2][0-9])
  COMMAND1
  ;;
*)
  COMMAND2
  ;;
esac

Streams

Redirects

Write output to a file or file-descriptor
CommandRedirect Append Description
program> std.log>> std.logredirect stdout to a file
program2> err.log2>> err.logredirect stderr to a file
program2>&1 redirect stderr to stdout

Pipes

Write output into the input-stream of another process
CommandPipe Description
program| grep -i foo pipe stdout into grep
program| tee file1 file2overwrite files and stdout
program| tee -a file append to files and stdout

Environment Variables

Setting, getting and unsetting

Set

LANG=en_US.UTF-8 bash
export LANG=en_US.UTF-8

Get

env
echo ${LANG}
echo $PWD

Unset

unset LANG
env -u LANG

Use cases

Some variables that could affect you are:
$EDITOR            # the default editor for the CLI
$PAGER             # utility to read long streams
$PATH              # program paths, in priority order
if you’re aiming for programming, these could be more interesting:
$LIBRARY_PATH      # libraries to link by the compiler
$LD_LIBRARY_PATH   # libraries to link at runtime
$CC                # sometimes used to set default C compiler
$CFLAGS            # default flags for compiling C

<HTML> <div class=“incremental”> <div> <hr color=“lightgrey” class=“slidy” /> </HTML>

if you have a lot of self-compiled binaries:
export PATH="./:$HOME/bin/:$PATH"

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Scripting

Ownership and Permissions

Just to ensure that you are able to run your scripts

chown

Change the owner of files and directories by:
# only works with root privileges
 
chown user file
chown -R user:group dirs files

chmod

Change the mode of files and directories by:
chmod -R u=rwx,g+w,o-rwx dirs files
chmod 640                files
chmod 750                dirs
chmod 750                executables

Shebang

A little test program, which we mark as executable and hand it over to the corresponding interpreter:

cat << EOF > test.sh
 
echo "${LANG}"
echo "${PATH}"
EOF
chmod +x test.sh
bash test.sh
Don’t we have an OS, capable of executing everything it recognizes as an executable?
Yes, we do!
cat << EOF > test.sh
#!/bin/bash
echo "${LANG}"
echo "${PATH}"
EOF
chmod +x test.sh
./test.sh

Functions (more like procedures)

Programming in bash would be cumbersome without functions, so here we go:

allNumbersFromTo () {
  echo "1 2 3"
}
This isn’t good, as were only getting a fixed amount of numbers. Let’s try a recursive approach:
allNumbersFromTo () {
  num=$1
  max=$2
  echo "${num}"
  if [ $num -lt $max ]; then
    allNumbersFromTo "$(($num + 1))" $max
  fi
}
allNumbersFromTo () {
  min=$1
  max=$2
  for num in $(seq $min $max)
  do
    echo "${num}"
  done
}
allNumbersFromTo 1 10

.bashrc

.bashrc

# .bashrc
 
# Source global definitions
if [ -f /etc/bashrc ]; then
        . /etc/bashrc
fi
 
# User specific aliases and functions
alias sq='squeue -u $USER'
alias rm='rm -i'
 
export PATH="./:$HOME/bin:$PATH"

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### Copyleft & Copyright {.slidy}

<div class=slidy> - wikipedia — “Sadegh 1990 hosseini”: - [CC-Attribution-ShareAlike (CC-BY-SA)](https://creativecommons.org/licenses/by-sa/4.0/deed.en) - [Directory Tree](https://commons.wikimedia.org/wiki/File:Linux_directories.jpg) - VSC — Lengyel Balazs: - No explicit license - Screenshots </div> –> </HTML>