This starter was created using erlang 22.3.4.12 and Elixir 1.11.3 but should be compatible with other versions as well. This project supports managing your erlang and Elixir installations with asdf (with the asdf-erlang and asdf-elixir plugins) if you choose.

After forking and cloning the repository, install dependencies:

mix deps.get

Then compile the project:

mix compile

Then you can start the interactive Elixir shell:

iex -S mix

For this technical challenge, we will ask you to implement a calibration service using GenServers.

We have a pool chemistry monitor that is a WiFi-enabled IoT device that floats in your swimming pool or spa and collects measurements of your water chemistry. We use these measurements to make recommendations for what chemicals you should use to improve your water quality, and in what quantities you should add them. However, before it can start taking those measurements, the pool chemistry monitoring device first needs to be calibrated. In order to calibrate, the server will orchestrate a process that executes several commands on the device in sequence in order to calibrate it. This is what you'll be implementing today!

Our device communicates with the server by sending and receiving messages. For the purposes of this challenge, we'll assume we've already implemented the message sending and receiving. To send the "calibrate" command to Kelli's device, for example, you can use device_messages.ex:

DeviceMessages.send("kelli@email.com", "calibrate")

We'll also assume that when the server receives a new message from a device, it knows how to find any ongoing calibration process for that device and forward the message to that GenServer process (i.e. with Process.send/3), so all you need to do is implement callbacks to handle those messages.

We would like you to implement the API that is stubbed out on elixir_interview_starter.ex, which has three methods: start/1, start_precheck_2/1 and get_current_session/1. These methods should give a consumer everything it needs to calibrate a user's device without needing to know any of the details of what is involved in that process. We have already written up documentation in the code for how each of these methods should look and behave, but before diving in to the code, let's talk about what the three steps of calibration are.

For a visual reference for these same steps, see calibration-flow.pdf.

Precheck 1 is the first step of calibration where the device verifies the status of various parts of its own hardware. From the server's perspective, calibration begins when a client calls start/1, the first of the three API methods we ask you to implement.

During this step, the server is responsible for sending the command "startPrecheck1" to the device and then waiting for it to perform its checks.

If the hardware checks pass, the device will respond with %{"precheck1" => true}. If there is a problem with the hardware, the device will respond with %{"precheck1" => false}. If we do not receive a response back within 30 seconds, we consider calibration a failure.

If Precheck 1 succeeds, we start Precheck 2 once the user places their device in the water. For Precheck 2, the device verifies that its cartridge is inserted properly and that the device is sufficiently submerged in water. From the server's perspective, calibration is on hold until the client calls start_precheck_2/1, the second of the three API methods we ask you to implement.

During this step, the server is responsible for sending the command "startPrecheck2" to the device and then waiting for it to perform its checks.

The device will respond individually with %{"cartridgeStatus" => boolean()} and %{"submergedInWater" => boolean()} indicating whether or not each check passed or failed. If we do not receive a response back within 30 seconds, or we see one of the checks fail, we consider calibration a failure. If both checks pass, we say Precheck 2 succeeds and automatically proceed to the next step.

Once we've finished both Precheck steps, we start the actual LED calibration of the device. From the server perspective, this step follows automatically from the previous one.

During this step, the server is responsible for sending the command "calibrate" to the device and then waiting for it to try to calibrate.

If the device calibrates successfully, it will respond with %{"calibrated" => true}. If there is a problem, it will respond with %{"calibrated" => false}. If we do not receive a response back within 100 seconds, we consider calibration a failure.

Once this step succeeds, calibration is complete and the server's job is done!

To complete this challenge, you will need to implement the side of this process that is managed on the server. At a high level, a successful application will be able to:

• start a supervisor to oversee Calibration processes
• manage GenServer processes for individual CalibrationSessions that exist for the entire lifespan of the CalibrationSessions
• implement logic to communicate with the pool chemistry monitoring device (send commands and handle message responses or timeouts) to walk through each step of Calibration

You are allowed to use whatever resources you would like and add whichever additional packages you feel necessary. You can also ask for as much clarification as you feel you need at any time.

You will work on completing the challenge partially with us, partially independently. Here's what to expect:

1. We share the technical challenge prompt with you a day in advance.
2. On a preliminary call, we grant you access to fork the repo, go over any questions about what we are aiming to build (10-20 min), and pair on a "planning phase" (10-20 min) where we will expect you to share your thoughts on how to approach this, maybe write some pseudo-code or draw some diagrams, and make sure you get off to a good start!
3. We let you do your thing and complete the challenge! You'll have 3 hours and can ask us as many questions as you want during that time. When you feel good about what you have, please upload your submission to GitHub as a private repository and grant us access to it. In order to prevent other candidates from seeing your work, please do not open a pull request against this repository. If you feel it absolutely necessary, you can still make changes after this time, but keep in mind this will negatively impact how we score your work.
4. We review and score your submission internally.
5. Optionally, we may choose to schedule a follow-up call with you and ask you to walk us through how your submission works and any tests you wrote (10-20 min).
6. **Important!!** If we choose to schedule this call, we will also ask you to choose an Elixir-specific concept that you leveraged in your submission and prepare to give a short (5-10 min) explanation to us of how that concept works, as if you were introducing the concept to a junior engineer with limited exposure to Elixir. You don't need to bring any fancy presentation materials; we're just looking for you to demonstrate your ability to convey a concept you know well to an audience who does not know it at all. To that end, the concept you choose does not necessarily need to be unique to Elixir, but through your explanation, you should be able to convince us why the concept you chose is important to working with Elixir.

There aren't intended to be any tricks or "gotchas" with this challenge, and to that end, we also aim to be fully transparent about how we will score your submission: