infra-overview.md

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Infrastructure Overview	default	1

Infrastructure Overview

A one-stop shop that explains all the infrastructure for the course.

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{: .note } Interested in the why of our infrastructure? Take a look at the [Philosophy]({% link advanced/philosophy.md %})!

Course Website

Our course website is slightly more complicated than plain HTML, CSS, and JavaScript -- but not by much! We use a type of software called a static site generator. In a nutshell, this lets you write code in a different language that generates HTML, CSS, and JS. Once you compile the site, the resulting object is just HTML, CSS, and JS that can be served any way that you'd like.

The course website (and, the website you're reading this on) is built using a static site generator called Jekyll. In particular, we're using a Jekyll theme called Just the Docs. This provides all of the styling for the website, generates reusable components like the sidebar, and provides neat compile-time features like code highlighting, search, and section navigation.

The course website additionally uses Just the Class, a theme made by Kevin Lin at UW that adds some class-related functionality to Just the Docs, such as the weekly schedule.

Jekyll lets you use Markdown to write content, which gets converted to HTML at compile-time. In addition, the Liquid templating language allows you to use primitives like conditionals and loops, though we won't use them frequently in the website.

Jekyll is written in a programming language called Ruby, which you'll need to run Jekyll locally. However, you don't need to know Ruby to use Jekyll.

The site is automatically updated through GitHub Actions, which is a form of continuous integration and continuous deployment. After every commit to the main branch of the repository, an action will automatically build and deploy the site to the GitHub Pages URL. In other words, you don't need to manage the deployment!

Autograder

{: .note }

Interested in the security model (and observed issues) with the autograder? See [Advanced: Autograder Security]({% link advanced/autograder-security.md %}).

The course autograder is used for the quarter-long project in the class. Students write an interpreter for "Brewin", a language spec developed specifically for the course that requires students to implement various course topics within the interpreter itself. With that in mind, the course autograder has one key goal: given various Brewin programs, count how many are correctly interpreted and executed by a student's interpreter.

The autograder itself is written in dependency-free Python 3. It is a very lightweight wrapper around the student's interpreter, which is also written in Python (and imported as a module). The core flow for one test case is relatively simple:

1. inputs: a Brewin source file, the expected output, whether or not an error is expected, and (optionally) standard input to pass to the interpreter
2. pass the source file (split into lines, but not otherwise parsed) and standard input to the student's interpreter
3. then, diff the output from the interpreter with the expected output. (this is either the standard out of the interpreter, or first error thrown, depending on if an error is expected)

• if it matches, grant full score for the test case
• if it doesn't match, grant zero points for the test case

4. if the interpreter does not output after five seconds, terminate the thread and grant zero points

Observe that this model doesn't provide partial credit, requires exact matches (and thus whitespace matters!), and does not take into account performance (other than the timeout). In addition, it is platformless; this specific model doesn't require running on a specific OS, a specific LMS, etc.

The autograder as a whole is given a suite of versioned test cases, and runs each one sequentially. It can be run standalone (as a Python file); we provide students a copy of the exact autograder framework we use (with a subset of test cases) so they can replicate as much of the testing environment locally as possible.

In addition, we've written a small set of helpers that allow this autograder to be deployed to Gradescope's Autograder platform. Students will submit their project through the Gradescope UI; Gradescope will then spin up an image, run our autograder, and then report the full score (including a per-test case breakdown) back to students immediately. Students can submit infinitely, which lets them build solutions gradually over time.

The autograder has been a large success, though it also has limitations. For a more in-depth discussion, see [Advanced: Philosophy]({% link advanced/philosophy.md %}), the [running to-dos list]({% link advanced/todos.md %}), and [Advanced: Autograder Security]({% link advanced/autograder-security.md %}).

Barista

{: .note } Want to learn more about Barista? See the [Deep Dive: Barista]({% link advanced/barista.md %}) page.

Barista is a newer addition to our course offering. In a nutshell, it is a simple online runtime for Brewin, the language that students implement throughout the quarter's course projects. Students can write arbitrary Brewin programs and run them against a canonical Brewin interpreter(historically, Carey's implementation). Barista should provide the correct output in all cases of defined behaviour: in either semantically correct Brewin programs, or in the few well-defined error states. In contrast, undefined behaviour is left open to the implementation (which we often display as a RuntimeError).

There are three components to Barista:

1. a Python runtime that runs Brewin code. Since Carey's interpreter is written in Python, the runtime itself is a trivial wrapper over the interpreter.
2. a React-based frontend that provides a simple interface to use the interpreter. It manages some client state (current Brewin version, past submissions, etc.) and sends JSON payloads to the backend.
3. a small Flask server that receives API requests from the frontend and forwards them on to the runtime. In our architecture, the Flask server also serves the HTML file for the frontend itself.

Developing on Barista requires some non-trivial knowledge of full-stack web development. However, maintaining Barista is relatively simple; TAs only need to copy-paste in new versions of a canonical interpreter and write a handful of lines of Python code (for the backend) and JSON (for the frontend).