UPDATE REGARDING PROJECT EXTENSION
I have decided to extend the Unix Shell project to 10/28/22, but the extension requires that your project be passing tests 1-11 by 10/07. Note, this will be the ONLY extension for this assignment, make good use of the extra time. Make sure you push your current work on the Unix shell project before 11:59pm on 10/07/22. Failure to do so will result in forfeiting the regrade opportunity entirely.
In this project, you’ll build a simple Unix shell. The shell is the heart of the command-line interface, and thus is central to the Unix/C programming environment. Mastering use of the shell is necessary to become proficient in this world; knowing how the shell itself is built is the focus of this project.
There are three specific objectives to this assignment:
In this assignment, you will implement a command line interpreter (CLI) or, as it is more commonly known, a shell. The shell should operate in this basic way: when you type in a command (in response to its prompt), the shell creates a child process that executes the command you entered and then prompts for more user input when it has finished.
The shells you implement will be similar to, but simpler than, the one you run
every day in Unix. If you don’t know what shell you are running, it’s probably
bash
. One thing you should do on your own time is learn more about your
shell, by reading the man pages or other online materials.
wish
Your basic shell, called wish
(short for Wooster Shell, naturally), is
basically an interactive loop: it repeatedly prints a prompt wish>
(note
the space after the greater-than sign), parses the input, executes the command
specified on that line of input, and waits for the command to finish. This is
repeated until the user types exit
. The name of your final executable
should be wish
.
The shell can be invoked with either no arguments or a single argument; anything else is an error. Here is the no-argument way:
prompt> ./wish
wish>
At this point, wish
is running, and ready to accept commands. Type away!
The mode above is called interactive mode, and allows the user to type
commands directly. The shell also supports a batch mode, which instead reads
input from a batch file and executes commands from therein. Here is how you
run the shell with a batch file named batch.txt
:
prompt> ./wish batch.txt
One difference between batch and interactive modes: in interactive mode, a
prompt is printed (wish>
). In batch mode, no prompt should be printed.
You should structure your shell such that it creates a process for each new
command (the exception are built-in commands, discussed below). Your basic
shell should be able to parse a command and run the program corresponding to
the command. For example, if the user types ls -la /tmp
, your shell should
run the program /bin/ls
with the given arguments -la
and /tmp
(how does
the shell know to run /bin/ls
? It’s something called the shell path;
more on this below).
The shell is very simple (conceptually): it runs in a while loop, repeatedly
asking for input to tell it what command to execute. It then executes that
command. The loop continues indefinitely, until the user types the built-in
command exit
, at which point it exits. That’s it!
For reading lines of input, you should use getline()
. This allows you to
obtain arbitrarily long input lines with ease. Generally, the shell will be
run in interactive mode, where the user types a command (one at a time) and
the shell acts on it. However, your shell will also support batch mode, in
which the shell is given an input file of commands; in this case, the shell
should not read user input (from stdin
) but rather from this file to get the
commands to execute.
In either mode, if you hit the end-of-file marker (EOF), you should call
exit(0)
and exit gracefully.
To parse the input line into constituent pieces, you might want to use
strsep()
. Read the man page (carefully) for more details.
To execute commands, look into fork()
, exec()
, and wait()/waitpid()
.
See the man pages for these functions, and also read the relevant book
chapter for a brief overview.
You will note that there are a variety of commands in the exec
family; for
this project, you must use execv
. You should not use the system()
library function call to run a command. Remember that if execv()
is
successful, it will not return; if it does return, there was an error (e.g.,
the command does not exist). The most challenging part is getting the
arguments correctly specified.
In our example above, the user typed ls
but the shell knew to execute the
program /bin/ls
. How does your shell know this?
It turns out that the user must specify a path variable to describe the set of directories to search for executables; the set of directories that comprise the path are sometimes called the search path of the shell. The path variable contains the list of all directories to search, in order, when the user types a command.
Important: Note that the shell itself does not implement ls
or other
commands (except built-ins). All it does is find those executables in one of
the directories specified by path
and create a new process to run them.
To check if a particular file exists in a directory and is executable,
consider the access()
system call. For example, when the user types ls
,
and path is set to include both /bin
and /usr/bin
, try access("/bin/ls",
X_OK)
. If that fails, try “/usr/bin/ls”. If that fails too, it is an error.
Your initial shell path should contain one directory: /bin
Note: Most shells allow you to specify a binary specifically without using a
search path, using either absolute paths or relative paths. For
example, a user could type the absolute path /bin/ls
and execute the
ls
binary without a search path being needed. A user could also specify a
relative path which starts with the current working directory and
specifies the executable directly, e.g., ./main
. In this project, you do
not have to worry about these features.
Whenever your shell accepts a command, it should check whether the command is
a built-in command or not. If it is, it should not be executed like other
programs. Instead, your shell will invoke your implementation of the built-in
command. For example, to implement the exit
built-in command, you simply
call exit(0);
in your wish source code, which then will exit the shell.
In this project, you should implement exit
, cd
, and path
as built-in
commands.
exit
: When the user types exit
, your shell should simply call the exit
system call with 0 as a parameter. It is an error to pass any arguments to
exit
.
cd
: cd
always take one argument (0 or >1 args should be signaled as an
error). To change directories, use the chdir()
system call with the argument
supplied by the user; if chdir
fails, that is also an error.
path
: The path
command takes 0 or more arguments, with each argument
separated by whitespace from the others. A typical usage would be like this:
wish> path /bin /usr/bin
, which would add /bin
and /usr/bin
to the
search path of the shell. If the user sets path to be empty, then the shell
should not be able to run any programs (except built-in commands). The
path
command always overwrites the old path with the newly specified
path.
Many times, a shell user prefers to send the output of a program to a file
rather than to the screen. Usually, a shell provides this nice feature with
the >
character. Formally this is named as redirection of standard
output. To make your shell users happy, your shell should also include this
feature, but with a slight twist (explained below).
For example, if a user types ls -la /tmp > output
, nothing should be printed
on the screen. Instead, the standard output of the ls
program should be
rerouted to the file output
. In addition, the standard error output of
the program should be rerouted to the file output
(the twist is that this
is a little different than standard redirection).
If the output
file exists before you run your program, you should simple
overwrite it (after truncating it).
The exact format of redirection is a command (and possibly some arguments) followed by the redirection symbol followed by a filename. Multiple redirection operators or multiple files to the right of the redirection sign are errors.
Note: don’t worry about redirection for built-in commands (e.g., we will
not test what happens when you type path /bin > file
).
Your shell will also allow the user to launch parallel commands. This is accomplished with the ampersand operator as follows:
wish> cmd1 & cmd2 args1 args2 & cmd3 args1
In this case, instead of running cmd1
and then waiting for it to finish,
your shell should run cmd1
, cmd2
, and cmd3
(each with whatever arguments
the user has passed to it) in parallel, before waiting for any of them to
complete.
Then, after starting all such processes, you must make sure to use wait()
(or waitpid
) to wait for them to complete. After all processes are done,
return control to the user as usual (or, if in batch mode, move on to the next
line).
The one and only error message. You should print this one and only error message whenever you encounter an error of any type:
char error_message[30] = "An error has occurred\n";
write(STDERR_FILENO, error_message, strlen(error_message));
The error message should be printed to stderr (standard error), as shown above.
After most errors, your shell simply continue processing after
printing the one and only error message. However, if the shell is
invoked with more than one file, or if the shell is passed a bad batch
file, it should exit by calling exit(1)
.
There is a difference between errors that your shell catches and those that
the program catches. Your shell should catch all the syntax errors specified
in this project page. If the syntax of the command looks perfect, you simply
run the specified program. If there are any program-related errors (e.g.,
invalid arguments to ls
when you run it, for example), the shell does not
have to worry about that (rather, the program will print its own error
messages and exit).
General Advice:
START EARLY, THIS IS NOT A TRIVIAL ASSIGNMENT AND WILL TAKE TIME TO COMPLETE!
USE THE TESTS DIRECTORY TO HELP WITH REQUIREMENTS!
*.desc
files describe the test in plain text*.in
files are the input to your program*.out
files are expected output*.err
files are any error output*.rc
files have the expected return codeDO NOT ARBITRARILY LIMIT THE SIZE OR NUMBER OF ARGUMENTS FOR COMMANDS TO YOUR SHELL,
const int MAX_ARGS = 100;
BUILD AND TEST FREQUENTY (make test
runs the test suite on your program). If you are failing a test, compare the files in the test
directory with the matching files in the tests-out
directory that is created after running make test
or the test-wish.sh
shell script.
Use Git to commit your code periodically (like when you are passing some to avoid losing work or to undo breaking changes. Also, if you want assistance on a coding issue, make sure to add, commit, and push your changes so that I can see your code in the GitHub repository.
Approaching the Problem:
Remember to get the basic functionality of your shell working before worrying about all of the error conditions and end cases. For example, first get a single command running (probably first a command with no arguments, such as ls
).
Next, add built-in commands. Then, try working on redirection. Finally, think about parallel commands. Each of these requires a little more effort on parsing, but each should not be too hard to implement.
At some point, you should make sure your code is robust to white space of
various kinds, including spaces (
) and tabs (\t
). In general, the user
should be able to put variable amounts of white space before and after
commands, arguments, and various operators; however, the operators
(redirection and parallel commands) do not require whitespace.
Check the return codes of all system calls from the very beginning of your work. This will often catch errors in how you are invoking these new system calls. It’s also just good programming sense.
valgrind --leak-check=yes wish
for interactive mode or valgrind --leak-check=yes wish file.txt
for batch mode.