CSCI 3411 - Operating Systems

Posted on August 1, 2018 by Gabriel Parmer

This course covers the fundamental concepts of operating systems, focusing on resource management and abstraction. This includes OS structure, processes and thread management, communication with peripherals (I/O), synchronization, deadlocks, memory management, Virtual Machines, cloud infrastructures, and abstractions for cloud computation. The workload for this class is heavy and programming intensive.

Course Info

Instructors Contact info:

Fall 2018 Class Time/Location:

Office Hours:

TODO

  1. Register for the class on Piazza.
  2. On Piazza, you’ll find a link to the course survey. You cannot receive any grades until you fill this out; please do so immediately.
  3. On Piazza, you should also find a link to the first homework (HW0) on github (which requires you to make/have a github account).

Course Overview

Learning Outcomes

Objectives - In completing this class, students will…

Structure - This class is broken into two main activities: lectures and lab.

Direct Instruction and Independent Learning

Each semester, you’re expected to spend at least:

Course Prerequisites and Student Responsibilities

Prerequisites:

Responsibilities - Students must

Course Schedule

Topic xv6 Book Chapters/Additional Reading1 Silberschatz Chapters2
OS Fundamentals: Hardware and Structure 0, 1, 3 and this post 1, 2
Processes, IPC, Threads, Isolation this post 3, 4
Scheduling and Critical Sections 5, 4 5, 6, 19
Mutexes, Condition Vars, Deadlock N/A 6, 7
Midterm all of the things…
Memory Management and Allocation N/A 8
Memory Protection 2 9
File Systems and Storage 6 10, 11, 12, 13
Security N/A 15
Final all of the things…

You can find the lectures on Piazza after they are delivered. For your reference, all of the lecture’s pdfs are on the following topics:

Course Material

Strongly encouraged (but optional) Text:

If you have trouble understanding the xv6 source code, I recommend the following resources:

You can fork the xv6 source on github. When you do, test that you can run it with make, and make qemu.

In the end, you have to get comfortable walking through the code, and understanding it. Using a code indexing system will make this easier. ggtags or ctags for emacs does great, but there are corresponding technologies for nearly all editors.

If you’re having trouble with C, here is a list of references:

It is your responsibility to quickly get up to speed in C, so please use these resources.

Assignment Submission

All of your homeworks for this class will be submitted via github. The last commit that you make to the repo will be graded, and the lateness penalties of that commit (see “Late Policy” below) will apply. Please do not make pushes to your repo after the version you want graded. Please also not that it is necessary to issue a git pull up to the github repo for submission. Local commits to your own repo do not update github, thus cannot be counted as submission.

Grading

Grades will be assigned with the following proportions:

Homeworks include smaller programming assignment, written responses, and a long final programming project.

Participation will be graded not only on attendance, but also on interactivity and involvement during class and lab.

If needs be, there will be short quizzes at the beginning of classes. These will only happen if people make it a habit of not coming to class, or coming late.

Homework Grade Modifications:

The following modifies apply to your grade on all homeworks (but not the project):

Your grade can be minimum 0%, but your maximum grade can be higher than 100%. There is one exception:

The only way people have failed this class is by not trying or cheating.

Late Policy:

The only acceptable excuses for late submissions are medical, family, and related issues. For these, you will require a note (from a doctor, parent, etc…) to justify an extension. Unacceptable excuses include:

You get 0 credit for late work that is unexcused. However, once the grades are released, you can resubmit your code within seven days, rounded up to the closest midnight. For example, if the grades are released at 2:30pm on the 8th, resubmissions are due at midnight on the 15th (i.e. \(8 + 7 = 15\)). You will get 0 credit for submissions after this date.

We will grade the last commit before the resubmission deadline, and you will receive 50% of the credit on top of the original grade, rounded up to the nearest percent. For example, if you got a 43% on the initial deadline, and resubmit and get a 68%, your final grade (\(g\)) will be \(g = \lceil 43 + \frac{(68 - 43)}{2} \rceil = 56\).

Do not come to rely on the resubmission process. Homeworks are due every week or every other week, so it is very harmful to get behind on them, or to add more work to your schedule. Thus, our late policy is quite strict to discourage procrastination.

Please note that in terms of academic honesty, you cannot share your code with your peers even after it is due.

Testing your implementation:

When you are required to test your code, please note that our test cases will best every edge case in the implementation. If you do not write code to test the edge-cases of the specifications, then you will lose credit. This is the largest reason why students get lower grades than they believe they deserve. If you believe that an error was made in grading, then please explicitly address why you believe your test cases are sufficient to test all cases.

Academic Honesty

Just as you can do a google search for code online, it is trivial for us to do the same. We have caught numerous people cheating in the past in this way. If you feel pressured about an assignment, please come see me instead of cheating.

You are not allowed to collaborate on the homeworks and the lab assignments. The group projects require collaboration within each group, but no collaboration between teams is permitted. Please refer to the academic integrity policy linked from the course web page. This policy will be strictly enforced. If you’re having significant trouble with an assignment, please contact me. If you have not signed the academic integrity statement for homework 0, you will not receive a passing grade for the class.

Summary: I want to be very clear:

In the past, the only way that people have failed this class is to either not try (not do homeworks), or to cheat. There is almost no reason to cheat. Come to me, and we can discuss where you’re at, and what you have to do to make it through this difficult class!

Justification: Cheating hurts your ability to compete for CS jobs. Everyone came to college to learn. You learn by doing work to reinforce class ideas. Understanding ideas from class is nowhere near as effective at learning as applying those ideas in an implementation. Thus, you need to do your own implementation to be a competitive CS student in the real-world!

Cheating hurts your peers. Courses that are graded on a curve have the side-effect that if someone inflates their grade not by hard work, but by cheating, your good grade (should the Professor not catch you) will hurt the grade of all of your colleagues that put the work in.

Cheating also hurts the quality of the OS class in the long term, thus hurts all future generations of GW CS undergrads. If you cheat, especially using previous year student’s work, to the point where the Professor believes that they must develop new assignments every year, then those assignments will not be as strong. They will not meet learning objectives in a course like this. All future CS students will be less prepared for competing for the best jobs.

Additional Material

xv6

To run xv6, you need qemu installed. If you aren’t running Linux, then you might execute Linux in a virtual machine (e.g. using Virtual Box or VMWare Workstation), and qemu within Linux. I believe others have gotten qemu executing in OSX as well (but it takes installing a cross-compiled ELF-version of gcc), so discuss on Piazza if you’re interested in that.

$ git clone https://github.com/gparmer/gwu-xv6.git xv6
$ cd xv6
$ make qemu

Simple!

Note that the xv6 book has a great overview of the design of the entire system. Please use it as a resource if you need it. Note that since you don’t own this repo, you cannot git push to it. You have to fork it on github to become the owner of your own fork. For this class, all assignments will be completed on repos that we provide for you.

Some hints for understanding the code-base. All code that runs in user-level is in the files that correspond to the entries of UPROGS, and all of the header files that they include. The rest of the code executes in the kernel. Thus to add a new program, you only need to provide the .c file, and add it in a similar manner to UPROGS.

When you’re looking at a .c or .h file, always make sure you understand if it is executing in user-space (thus must make a system call to enter the kernel), or is in the kernel (thus can directly call functions within the kernel). Using a code indexing system will make it easier to walk through the source code. ggtags or ctags for emacs does great, but there are corresponding technologies for nearly all editors.

git and github

Using github. github provides a wonderful set of repository management features online. You can go through the github bootcamp if you don’t know how to use it.

You can use github to coordinate between team members in many different ways. I’d strongly recommend that when working in a team, you use the feature branch workflow pattern of interaction. At the highest-level, this means that each team member will be working on their features on separate branches, and will integrate them into the mainline to coordinate with everyone else.

A few of the ways to interact with github:

Using git. I’m not going to do a deep dive into using git here, and expect that you can figure out the main features online. Some quick git tips can be found at the bottom of software engineering guide. An incomplete list of commands that you can use with git include:

Submitting assignments. When you submit an assignment, I suggest that you follow this procedure:

  1. git status to make sure that you have git added all of the intended files.
  2. git diff and git diff --stat to make sure that you’re committing what you think you are. Of note, check to see if you’re committing any printfs that are intended for debugging, not for program output.
  3. git commit and git push to upload your code to github.
  4. Go to the associated webpage for the repository, and make sure that the most recent commit is present in your repository.
  5. Use git clone ... to get a fresh version of the repository, build it, and run your tests. Students who omit this step get bad grades for very avoidable reasons. Always make sure that your submission matches what you think you’re submitting.

Style

Please document in your repository (e.g. in the README.md) which coding style you’re using. By default, the xv6 repo we use is formatted in accordance with the Composite Style Guide. See that description to understand why style is important, and why we choose the style we do.

It is important, when you’re working on a team to use a consistent style. It is more important to choose one and stick with it, than to choose the “perfect style”. You can find many different styles online, including

Though not relevant for this class, many modern languages have prescribed styles such as go, and Rust.


  1. Find the book online↩︎

  2. Silberschatz chapters are specified with respect to the 9th edition↩︎