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- [Packages](day_1/packages.md)
- [Tasks](day_1/tasks.md)
- [Day 2](day_2/README.md)
- [Shell glue](day_2/glue.md)
- [Tasks](day_2/tasks.md)
- [Day 3](day_3/README.md)
- [Day 4](day_4/README.md)
- [Day 5](day_5/README.md)

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# Shell glue
When you run something in the terminal, then you are interacting with the so called `shell`.
The default shell on almost all Linux systems is `bash`. (We will learn about the `fish` shell later)
The shell has the power to glue commands together to make the impossible possible! Lets use some gluing magic!
## Piping
We will start with pipes. In the last task of the last day, you did see the usage of the symbol `|` between two separate commands.
By entering `cowsay "Hello" | lolcat`, the output of the first command `cowsay` is sent to the second command `lolcat`.
`lolcat` takes the input, colors it and outputs it again!
Many Linux commands support handeling input of another command.
You might have seen in the manual of `wc` in day 1 that the file as an argument is only optional. How could you use `wc` without arguments?
You might have guessed it now, make some `wc` pipes.
OK, I admit that the naming is not the best 😂
Lets get some data to work with. To do so, we will use the command `curl` which graps content from the internet.
Lets count the number of lines of the html file of the homepage of this book:
```console
$ curl -s https://how-to-linux.mo8it.xyz | wc -l
201
```
The option `-s` tells `curl` to be silent and not show progress information.
You can see that `wc` did count the number of lines. We did just combine to completely different tools with some pipes glue!
How about counting the number times the word "Linux" was mentioned on the homepage?
To do so, we will add a new pipe inbetween!
`grep` is a command that searches for matches of a specified pattern. Each match is printed in a new line.
To demonstrate `grep`, here is an usage example:
```
$ curl --help | grep "silent"
-f, --fail Fail silently (no output at all) on HTTP errors
-s, --silent Silent mode
```
We did just filter the output of the help of a command. This way, you can also search quickly for command options!
Back to the main example:
```console
$ curl -s https://how-to-linux.mo8it.xyz | grep "Linux" | wc -l
6
```
You can see that you can use multiple pipes. This allows for almost infinite combinations!
Being able to combine commands is the reason why many commands are simple. They do one thing and do it well! To do more, combine them!
This is much more flexibel and powerful that a program that tries to do a lot of things.
## Input, output
Before going any further, we need to understand an important concept in Linux.
A command accepts input and generates two types of output. The input is called _standard input_. The output is split to _standard output_ and _standard error_.
The standard output has the number 1 while the standard error has the number 2.
Normal output is sent to the standard output. Errors (and sometimes output that is not very important) are sent to the standard error.
You can redirect the standard output or the standard error to a _stream_. Normally you will redirect the output to a file. Other stream forms are not relevant for now.
## Redirections
Lets see how you can redirect the output of commands to a file.
If you just run `curl -s https://how-to-linux.mo8it.xyz`, you will the html file printed in the terminal. Lets redirect the output to a html file on your disk:
```console
$ curl -s https://how-to-linux.mo8it.xyz > how-to-linux.html
```
Now view the content of the new file how-to-linux.html. You will be able to see the same output from the terminal without redirection.
Now try this command:
```console
$ curl https://not-existent-site.mo8it.xyz > test.html
curl: (60) SSL certificate problem: self-signed certificate
More details here: https://curl.se/docs/sslcerts.html
curl failed to verify the legitimacy of the server and therefore could not
establish a secure connection to it. To learn more about this situation and
how to fix it, please visit the web page mentioned above.
$ cat test.html
```
You will see that the file is empty since `curl` did not find a page to show as normal output.
If you are using this command in a script, then it might be wise to redirect the error to a log file:
```console
$ curl https://not-existent-site.mo8it.xyz 2> curl.log
$ cat curl.log
curl: (60) SSL certificate problem: self-signed certificate
More details here: https://curl.se/docs/sslcerts.html
curl failed to verify the legitimacy of the server and therefore could not
establish a secure connection to it. To learn more about this situation and
how to fix it, please visit the web page mentioned above.
```
You can see that the error is now not shown after running the `curl` command. It was redirected to the file `curl.log`.
Did you notice the number 2 before the redirection symbol `2>`?
The last section did mention that the number of the standard error is 2. Therefore, 2 has to be specified to redirect the errors.
If you don't specify a number, then it is equivalent to 1 which stands for the standard output. This means that `>` is equivalent to `1>`.
## Bash scripts
Lets write our first Bash script (also for some more demonstration of the two outputs):
```bash
#!/usr/bin/bash
echo "What is your favorite operating system after reading this book?"
echo "1. Linux"
echo "2. Windows"
echo "3. Mac"
echo -n "Enter a number: "
read ANSWER
if [ "$ANSWER" == "1" ]
then
echo "Good choice!"
else
echo "Nah, that can't be right! It must be an error!" > /dev/stderr
fi
```
Copy this code into a file called `which-os.sh`.
Now run `chmod +x which-os.sh`. Then run `./which-os.sh`.
---
I am really sorry, but I can not continue this book during the course. It was not only meant for the couse but also like a personal project that I wanted to keep on the internet even after the course.
But I did underestimate the huge amount of time it takes to write such a book/script.
Continuing the book during the course would mean that I can not cover a lot of topics because I can not write enough. It would also harm my health. I need sleep :')
I will continue it after the course, not only for the participants as output, but also for the purpose of a personal project. So please don't be disappointed. You will find all contents on this website some time after the course. I hope that it would then help you as a resource for looking things up.
I do especially apologize to the online participants. I did give my best.
Again, it is not lost. You will get it, but after the course :)

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# Tasks
Organize the files and directories of your tasks in separate directories!
## Task: Job scheduler
> Warning ⚠️ : This task is not an easy task. Don't give up quickly and ask for help if you don't get further!
In this task, we want to write our own job scheduler.
Understanding how job schedulers work is important when you are working on a computer cluster.
Computer clusters are shared by many users. Therefore, running jobs on a cluster has to be scheduled to make sure that the resources are shared probebly.
In this task, we will keep it simple. No aspects of multiple users or any optimizations.
We want to be able to submit a job as a single script (without any dependencies). The submitted scripts should run one after the another to save CPU usage for example.
We will use the program `inotifywait`. This program can monitor a directory and notify on changes within this directory.
1. Find out which package installs `inotifywait` and install it.
1. Read the manual of `inotifywait` for a better understanding of what it does.
1. Find out how to tell `inotifywait` to keep monitoring a directory and not exit after the first event.
1. Find out what events mean in the context of `inotifywait`.
1. Create a new directory called `jobs` to be monitored.
1. Create a new directory called `logs` that will be used later.
1. Run `inotifywait` while telling it to monitor the directory `jobs`. Leave the command running in a terminal and open a second terminal (tab) to continue the work in.
1. Create a file **outside** of the directory `jobs` and then copy it to the directory `jobs`.
1. Go back to the first terminal and see the output of `inotifywait` was.
1. Based on the output, choose an event that you want to listen to with `inotifywait` that tells you when a file is _completely_ added to the directory `jobs`. Use the manual to read more about specific events.
1. Find an option that lets you tell `inotifywait` to only notify when the choosen event occurs.
1. Find an option that lets you format the output of the notification of `inotifywait`. Since we only listen on one event and monitor only one directory, an output that shows only the name of the new file should be enough.
1. Enter the command that you have until now in a script. Now extend it by using a `while` loop that continously listens on the notifications of `inotifywait`.
1. After a notification, the body of the `while` loop should first print the name of the script that was added. From now on, we only want to add scripts to the `jobs` directory.
1. After printing the script name, run the script!
1. Save the standard output and standard error of the script into two separate files in the `logs` directory. If the name of the script is `job.sh` for example, then the output should be in the files `logs/job.sh.out` and `logs/job.sh.err`.
Tipps:
- Take a look at the examples from the sections of this day.
- Take care of permissions.
If you have extra time, read about the command `screen` in the internet. `screen` allows you to run commands in the background. This way, you don't need two terminals.
## Task: Job submitter
In this task we will write a small script that lets us submit a job script to the scheduler from the last task.
The script should take the path to the job script as a single required argument.
The script should then copy the job script to the directory `jobs` while adding the time and date to the beginning of the name of the job script in the `jobs` directory.
Read the manual of the command `date` to know how to get the time and date in the following format: `2022-08-22T20:00:00+00:00`.
If the name of the job script is `job.sh` for example, the job script should be named `2022-08-22T20:00:00+00:00_job.sh` in the `jobs` directory.
Use variables to write the script to make it more understandable.
## Task: Submit a job
Write a small scripts of your choice that require a long time to run and submit them using the script from the last task. Make sure that the scheduler is running in the background.
You can use the command `sleep` to simulate a job that needs long time to run.
Submit your job script multiple times and take a look at the terminal that is running the scheduler to make sure that the job scripts are running one after the other.
Verify the redirection of the standard output and standard error in the directory `logs`.