Shell

Part 1 due 2021-09-20 23:59
• shell.c
Part 2 due 2021-09-27 23:59
• shell.c

Learning Objectives

The learning objectives for Shell are:

• Learning How a Shell Works
• Fork, Exec, Wait
• Signals
• Processes
• Zombie Processes

Backstory #

Well, we’ll keep it short – you got fired from Macrohard. Your boss brought you in for a code review and was more than disappointed. Apparently, they wanted a C++ style vector: we didn’t get the memo. Now, you’ve decided to work for insert hot tech company here, and you got the job! However, there’s a catch - all newhires in insert hot tech company here apparently have to go through a newcomers test if they want to keep their jobs. The task? Write a shell. So, you’re going to drop a shell that is so fancy that your boss will not just keep you in the company, they’ll immediately give you a pay raise as well.

The basic function of a shell is to accept commands as inputs and execute the corresponding programs in response. You will be provided the vector, sstring and format.h libraries for your use. Hopefully, this will make things right and you can secure your foothold at insert hot tech company here. Feel free to refer to the Unix shell as a rough reference.

Important Things to Note #

Fork Bombs

To prevent you from fork bombing your own VM, we recommend looking into ulimit. This will allow you to set a limit for how many times you can fork. Note that ulimit is terminal session specific, so you will need to

• do it everytime you launch a terminal
• add this to your ~/.bashrc file (feel free to look up online how to do so), so that it is run every time you log in to your VM.

Note that you should give it a more generous amount (say, 100-200), since the terminal will likely have background processes already running. If you give it too small a limit, you won’t be able to launch anything, and you’ll need to launch a new terminal.

If you happen to fork bomb your CS Cloud VM, please notify course staff in a private post with your VM number. Note that it may take up to a few hours for us to respond, so try not to fork bomb your VM.

Plan Before You Start

This assignment marks the beginning of a series of projects where you will be given mostly blank files without predefined functions to fill in. Most of the remaining MPs will challenge your design skills to create interesting utilities. Therefore, it is important that you read the entirety of the documentation (including part 2), as well as the header files to get a clear idea on what needs to be done. A few reminders about good coding and developing practices that will really help you in the rest of the semester:

• List down the features that you need to implement, as well as the gotchas. Make a to-do list to ensure you don’t miss out anything.
• Plan out the entirety of your assignment. Create a skeleton of how your entire code will look like. This will prevent you from needing to restructure your entire code to add in a single new feature.
• Ensure that you fully understand the system calls/library functions you’re using - the parameters, the return values, the possible errors, the gotchas and notes.
• Structure your code into modular functions. You do not want to debug a 1500 line while loop within main.
• Work incrementally. Implement a feature, test, debug, move on.
• Good naming and spacing will make your code much more readable.
• Try putting TODO comments in unfinished portions of your code. They are automatically highlighted in many text editors, which alerts you to incomplete code.

Do Not Use system

Since a learning objective of this assignment is to use the fork-exec-wait pattern, if you use system, you will automatically fail this MP.

Input Formatting

Do not worry about irregular spacing in command inputs (i.e. extra whitespace before and after each token). This is considered undefined behavior and will not be tested. You are free to make your code as robust as you want, but we will only test the basic cases without irregular spacing (unless specified).

Output Formatting

Since this MP requires your shell and the programs you launch to print a variety of things like output messages and error messages, we have provided you with our own highly customized formatting library. You should not be printing out to stdout and stderr at all; instead, all output and errors should be printed using the functions provided in format.h. In format.h you can find documentation about what each function does, and you should use them whenever appropriate.

If you place print statements in your debugging code, please remember to remove them before autograding, or use the #define DEBUG block to place your print statements.

Note: don’t worry if you don’t use all of the functions in format.h, but you should use them whenever their documented purpose matches the situation.

Overview and To-Dos #

The shell is responsible for providing a command line for users to execute programs or scripts. You should be very familiar with bash by now, which will be the basis for your own shell. This is a 2 week MP, and the features you will need to implement are as follows:

Part 1

• Starting up a shell
• Optional arguments when launching shell
• Interaction
• Built-in commands
• Foreground external commands
• Logical operators
• SIGINT handling
• Exiting

Part 2

Everything from part 1, and:

• Background external commands
• ps
• Redirection commands
• Signal commands

The shell should run in a loop like this executing multiple commands:

• Print a command prompt
• Read the command from standard input
• Print the PID of the process executing the command (with the exception of built-in commands), and run the command

The shell must support the following two optional arguments, however, the order of the arguments does not matter, and should not affect the functionality of your shell. Your shell should be able to handle having none, one or both of these arguments.

History

Your shell should support storing the history of commands executed across shell sessions. The command is as follows:

./shell -h <filename>


When provided -h, the shell should load in the history file as its history. Upon exiting, the shell should append the commands of the current session into the supplied history file, even if the shell is in a different working directory than where it started. If the file does not exist, you should treat it as an empty file. The format of the history file stored should be exactly the same as a script file, where you list a series of commands to be executed. Example:

history.txt:

cd cs241
Hm

./shell -h history.txt
(pid=1234)/home/user/cs241$echo Hey! Command executed by pid=1235 Hey! (pid=1234)/home/user/cs241$ exit


Updated history.txt:

cd cs241
Hm
echo Hey!


Notes:

• If the the -h flag is not specified, the shell will still keep a history of commands run, but will not read/write from/to a history file. Just think of it like private browsing mode for your terminal.
• Every command should be stored into the history file, unless specified.

File

Your shell should also support running a series of commands from a script file. The command is as follows:

./shell -f <filename>


When provided -f, your shell will both print and run the commands in the file in sequential order until the end of the file. See the following example file and execution:

commands.txt:

cd cs241
echo Hey!

./shell -f commands.txt
(pid=1234)/home/user$cd cs241 (pid=1234)/home/user/cs241$ echo Hey!
Command executed by pid=1235
Hey!


You have been given a sample script file test_file.txt. Your history files and script files should be formatted in the same manner (this means you can use your history file as a script file in -f).

If the user supplies an incorrect number of arguments, or the script file cannot be found, your shell should print the appropriate error from format.h and exit.

Tip: The getopt function may come in handy.

Prompting

When prompting for a command, the shell will print a prompt in the following format (from format.h):

(pid=<pid>)<path>$ <pid> is the process ID of the shell, and <path> is a path to the current working directory. Note the lack of a newline at the end of this prompt. Reading in Commands The shell will read in a command from stdin (or a file if -f was specified). Command Types and Formats Shell supports two types of commands: built-in and external (i.e. non-built-in). Built-in commands are part of the shell’s code, and are executed without creating a new process. External commands must be executed by a new process, forked from your shell. If a command is not one of the built-in commands listed, it is an external command. Command arguments will be space-separated without trailing whitespace. Your shell does not need to support quotes (for example, echo "hello there"). Running the Commands The shell should run the command that was read in previously. If the command is run by a new process, the PID of the process should be printed like this: Command executed by pid=<pid>  This should be printed by the process that will run the command, before any of the output of the command is printed (prints to be used are in format.h). Keeping History Your shell should store the command that the user entered, so the user can repeat it later if they wish. Every command should be stored unless otherwise noted. A vector may be useful here. exit The shell will exit once it receives the exit command or once it receives an EOF at the beginning of the line. An EOF is sent by typing Ctrl-D from your terminal. It is also sent automatically from a script file (as used with the -f flag) once the end of the file is reached. This should cause your shell to exit with exit status 0. If there are currently stopped or running background processes when your shell receives exit or Control-D (EOF), you should kill and cleanup each of those children before your shell exits. You do not need to worry about SIGTERM. If you don’t handle EOF or exit to exit, you will fail many of our test cases! Do not store exit in history! Catching Ctrl+C Usually when we do Ctrl+C, the current running program will exit. However, we want the shell itself to ignore the Ctrl+C signal (SIGINT) - instead, it should kill the currently running foreground process (if one exists) using SIGINT. One way to do this is to use the kill function on the foreground process PID when SIGINT is caught in your shell. However, when a signal is sent to a process, it is sent to all processes in its process group. In this assignment, the shell process is the leader of a process group consisting of all processes that are fork‘d from it. So another way to properly handle Ctrl+C is to simply do nothing inside the handler for SIGINT if it is caught in the shell - your shell will continue running, but SIGINT will automatically propagate to the foreground process and kill it. However, since we want this signal to be sent to only the foreground process, but not to any backgrounded processes, you will want to use setpgid to assign each background process to its own process group after forking. (Note: think about who should be making the setpgid call and why). Built-in Commands # There are several built-in commands your shell is expected to support. cd <path> Changes the current working directory of the shell to <path>. Paths not starting with / should be followed relative to the current directory. If the directory does not exist, then print the appropriate error. Unlike your regular shell, the <path> argument is mandatory here. A missing path should be treated as a nonexistent directory. (pid=1234)/home/user$ cd code
(pid=1234)/home/user/code$cd imaginary_directory imaginary_directory: No such file or directory (pid=1234)/home/user/code$


There is a system call that may be helpful here.

!history

Prints out each command in the history, in order.

(pid=1234)/home/user$!history 0 ls -l 1 pwd 2 ps (pid=1234)/home/user$


This command is not stored in history.

#<n>

Prints and executes the $$n$$-th command in history (in chronological order, from earliest to most recent), where $$n$$ is a non-negative integer. Other values of $$n$$ will not be tested. The command executed should be stored in the history. If $$n$$ is not a valid index, then print the appropriate error and do not store anything in the history.

The following example assumes a fresh history:

(pid=1234)/home/user$echo Echo This! Command executed by pid=1235 Echo This! (pid=1234)/home/user$ echo Another echo
Command executed by pid=1236
Another echo
(pid=1234)/home/user$!history 0 echo Echo This! 1 echo Another echo (pid=1234)/home/user$ #1
echo Another echo
Command executed by pid=1237
Another echo
(pid=1234)/home/user$#9001 Invalid Index (pid=1234)/home/user$ !history
0    echo Echo This!
1    echo Another echo
2    echo Another echo
(pid=1234)/home/user$ Print out the command before executing if there is a match. The #<n> command itself is not stored in history, but the command being executed (if any) is. !<prefix> Prints and executes the last command that has the specified prefix. If no match is found, print the appropriate error and do not store anything in the history. The prefix may be empty. The following example assumes a fresh history: (pid=1234)/home/user$ echo Echo This!
Command executed by pid=1235
Echo This!
(pid=1234)/home/user$echo Another echo Command executed by pid=1236 Another echo (pid=1234)/home/user$ !e
echo Another echo
Command executed by pid=1237
Another echo
(pid=1234)/home/user$!echo E echo Echo This! Command executed by pid=1238 Echo This! (pid=1234)/home/user$ !d
No Match
(pid=1234)/home/user$! echo Echo This! Command executed by pid=1239 Echo This! (pid=1234)/home/user$ !history
0       echo Echo This!
1       echo Another echo
2       echo Another echo
3       echo Echo This!
4       echo Echo This!
(pid=1234)/home/user$ Print out the command before executing if there is a match. The !<prefix> command itself is not stored in history, but the command being executed (if any) is. Invalid Built-in Commands You should be printing appropriate errors in cases where built-in commands fail; for example, if the user tries to cd into a nonexistent directory. (pid=1234)/home/user$ cd /imaginary_directory
/imaginary_directory: No such file or directory
(pid=1234)/home/user$ External Commands # For commands that are not built-in, the shell should consider the command name to be the name of a file that contains executable binary code. Such a code must be executed in a process different from the one executing the shell. You must use fork, exec, and wait/waitpid. The fork/exec/wait paradigm is as follows: fork a child process. The child process must execute the command with exec*, while the parent must wait for the child to terminate before printing the next prompt. You are responsible of cleaning up all the child processes upon termination of your program. It is important to note that, upon a successful execution of the command, exec never returns to the child process. exec only returns to the child process when the command fails to execute successfully. If any of fork, exec, or wait fail, the appropriate error messages should be printed. The child should exit with exit status 1 if it fails to execute a command. Some external commands you may test to see whether your shell works are: /bin/ls echo hello  Tip: It is good practice to flush the standard output stream before the fork to be able to correctly display the output. This will also prevent duplicate printing from the child process. Please read the disclaimer at the top of the page! We don’t want to have to give any failing grades. Logical Operators # Like bash, your shell should support &&, ||, and ; in between two commands. This will require only a minimal amount of string parsing that you have to do yourself. Important: each input can have at most one of &&, ||, or ;. You do not have to support chaining (e.g. x && y || z; w). Important: you should not try to handle the combination of the !history, #<n>, !<prefix>, or exit commands with any logical operators. Rather, you can assume these commands will always be run on a line by themselves. AND && is the AND operator. Usage: x && y  • The shell first runs x, then checks the exit status. • If x exited successfully (status = 0), run y. • If x did not exit successfully (status ≠ 0), do not run y. This is also known as short-circuiting. (pid=27853)/home/user/semester/shell$ echo hi && echo bye
Command executed by pid=27854
hi
Command executed by pid=27855
bye

(pid=27879)/home/mkrzys2/fa19/shell$cd /asdf && echo short-circuit /asdf: No such file or directory!  This mimics short-circuiting AND in boolean algebra: if x is false, we know the result will be false without having to run y. This is often used to run multiple commands in a sequence and stop early if one fails. For example, make && ./shell will run your shell only if make succeeds. Tip: You may want to look into the provided macros to read the status of an exited child. OR || is the OR operator. Usage: x || y  • The shell first runs x, then checks the exit status. • If x exited successfully, the shell does not run y. This is short-circuiting. • If x did not exit successfully, run y. (pid=27853)/home/user/semester/shell$ echo hi || echo bye
Command executed by pid=27854
hi

(pid=1234)/home/user$cd /asdf || echo runMe /asdf: No such file or directory runMe  Boolean algebra: if x is true, we can return true right away without having to run y. This is often used to recover after errors. For example, make || echo 'Make failed!' will run echo only if make does not succeed. Separator ; is the command separator. Usage: x; y  • The shell first runs x. • The shell then runs y. (pid=27879)/home/user/semester/shell$ echo hi; echo bye
Command executed by pid=27883
hi
Command executed by pid=27884
bye

(pid=27879)/home/user/semester/shellcd /asdf; echo runMe /asdf: No such file or directory Command executed by pid=27884 runMe  The two commands are run regardless of whether the first one succeeds. Memory # As usual, you may not have any memory leaks or errors. Note that still reachable memory blocks do not count as memory leaks. Background Processes # An external command suffixed with & should be run in the background. In other words, the shell should be ready to take the next command before the given command has finished running. There is no limit on the number of background processes you can have running at one time (aside from any limits set by the system). There will be a single space between the rest of the command and &. For example, pwd & is valid while you need not worry about pwd&. Since spawning a background process introduces a race condition, it is okay if the prompt gets misaligned as in the following example: (pid=1873)/home/user pwd &
Command executed by pid=1874
(pid=1873)/home/user/home/user When I type, it shows up on this line  Note this is not the only way your shell may misalign. While the shell should be usable after calling the command, after the process finishes, the parent is still responsible for waiting on the child. Avoid creating zombies! Do not catch SIGCHLD, as catching SIGCHLD comes with all sorts of caveats and subtleties that are hard to work around. Instead regularly check to see if your children need reaping (think about placement of this piece of code: where should you put this, and why). Think about what happens when multiple children finish around the same time, and what happens if a foreground/background process finish around the same time. Backgrounding will not be chained with the logical operators nor with redirection operators. ps # Like our good old ps, your shell should print out information about all currently executing processes. You should include the shell and its immediate children, but don’t worry about grandchildren or other processes. Make sure you use print_process_info_header() and print_process_info() (and maybe some other helper functions)! Note: while ps is normally a separate binary, it is a built-in command for your shell. (This is not “execing ps”, this is you implementing it in the code. Thus you may have to keep track of some information for each process.) Your version of the ps should print the following information for each process: • PID: The pid of the process • NLWP: The number of threads currently being used in the process • VSZ: The program size (virtual memory size) of the process, in kilobytes (1 kilobyte = 1024 bytes) • STAT: The state of the process • START: The start time of the process. You will want to add the boot time of the computer, and start time of the process to calculate this. Make sure you are careful while converting from various formats - the man pages for procfs have helpful tips. • TIME: The amount of cpu time that the process has been executed for. This includes time the process has been scheduled in user mode (utime) and kernel mode (stime). • COMMAND: The command that executed the process Some things to keep in mind: • The order in which you print the processes does not matter. • The ‘command’ for print_process_info should be the full command you executed. The & for background processes is optional. For the main shell process only, you do not need to include the command-line flags. Ensure that the ‘command’ does not have trailing whitespace at the end of it. • You may not exec the ps binary to complete this part of the assignment. Example output of this command: (pid=25497)/home/user ps
PID     NLWP    VSZ     STAT    START   TIME    COMMAND
25498   1       7328    R       14:03   0:08    dd if=/dev/zero bs=1M count=123456 of=/dev/null &
25501   1       7288    S       14:04   0:00    sleep 1000 &
25497   1       7484    R       14:03   0:00    ./shell


Hint: You may find the /proc filesystem to be useful, as well as the man pages for it.

Redirection Operators #

Your boss wants some way for your shell commands to be able to link together. You decide to implement >>, >, and <. This will require only a minimal amount of string parsing that you have to do yourself.

Important: each input can have at most one of >>, > or <. You do not have to support chaining (e.g. x >> y < z > w).

Important: you should not try to handle the combination of the cd, !history, #<n>, !<prefix>, ps, or exit commands with any redirection operators. Rather, you can assume these commands will always be run on a line by themselves.

Note: Assume that the redirection operator commands will be formatted correctly. Any incorrectly formatted redirection commands is considered undefined behavior.

OUTPUT

> places the output of a command into a file. Usage:

<cmd> [args ...] > <filename>


If the file exists, overwrite the contents of the file with the output of the current command. Example usage:

(pid=2777)/home/usr$echo hello > hey.txt Command executed by pid=3750 (pid=2777)/home/usr$ cat hey.txt
Command executed by pid=3751
hello
(pid=2777)/home/usr$echo welcome to cs241 > hey.txt Command executed by pid=3752 (pid=2777)/home/usr$ cat hey.txt
Command executed by pid=3754
welcome to cs241


APPEND

>> appends the output of a command into a file. Usage:

<cmd> [args ...] >> <filename>


If the file does not exist, assume that it is an empty file. Example usage (hi.txt does not exist in the directory before these commands are executed):

(pid=2777)/home/usr$echo a >> hi.txt Command executed by pid=2780 (pid=2777)/home/usr$ cat hi.txt
Command executed by pid=2781
a
(pid=2777)/home/usr$echo wheeee >> hi.txt Command executed by pid=2782 (pid=2777)/home/usr$ cat hi.txt
Command executed by pid=2783
a
wheeee


INPUT

< pipes the contents of a file into a command as its input. Usage:

<cmd> [args ...] < <filename>


If the file does not exist, it is undefined behavior. Example usage: hello.txt contains:

welcome to cs241

(pid=3771)/home/usr\$ wc < hello.txt
Command executed by pid=3772
1  3 17


Hint: dup will be useful for all the redirection commands

Signal Commands #

Like bash, your shell will support sending signals to its child processes. We require you to implement the 3 signals listed below.

kill <pid>

The ever-useful panic button. Sends SIGKILL to the specified process.

Use the appropriate prints from format.h for:

• Successfully sending SIGKILL to process
• No process with pid exists
• kill was ran without a pid

stop <pid>

This command will allow your shell to stop a currently executing process by sending it the SIGSTOP signal. It may be resumed by using the command cont.

Use the appropriate prints from format.h for:

• Process was successfully sent SIGSTOP
• No process with pid exists
• stop was ran without a pid

cont <pid>

This command resumes the specified process by sending it SIGCONT.

Use the appropriate prints from format.h for:

• Process was successfully sent SIGCONT
• No such process exists
• cont was ran without a pid

Note: Any <pid> used in kill, stop, or, cont will either be a process that is a direct child of your shell or a non-existent process. You do not have to worry about killing other processes.