Thank you for your interest in participating in the [Google Summer of Code program][gsoc-qubes] with the [Qubes OS team][team]. You can read more about the Google Summer of Code program at the [official website][gsoc] and the [official FAQ][gsoc-faq].
Being accepted as a Google Summer of Code student is quite competitive. Students wishing to participate in the Summer of Code must be aware that you will be required to produce code for Qubes OS for 3 months. Your mentors, Qubes developers, will dedicate a portion of their time towards mentoring you. Therefore, we seek candidates who are committed to helping Qubes long-term and are willing to do quality work and be proactive in communicating with your mentor.
You don't have to be a proven developer -- in fact, this whole program is meant to facilitate joining Qubes and other free and open source communities. The Qubes community maintains information about [contributing to Qubes development][contributing] and [how to send patches][patches]. In order to contribute code to the Qubes project, you must be able to [sign your code][code-signing].
You should start learning the components that you plan on working on before the start date. Qubes developers are available on the [mailing lists][ml-devel] for help. The GSoC timeline reserves a lot of time for bonding with the project -- use that time wisely. Good communication is key, you should plan to communicate with your team daily and formally report progress and plans weekly. Students who neglect active communication will be failed.
- Join the [qubes-devel list][ml-devel] and introduce yourself, and meet your fellow developers
- Read [Google's instructions for participating][gsoc-participate] and the [GSoC Student Manual][gsoc-student]
- Take a look at the list of ideas below
- Come up with a project that you are interested in (and feel free to propose your own! Don't feel limited by the list below.)
- Read the Student Proposal guidelines below
- Write a first draft proposal and send it to the qubes-devel mailing list for review
- Submit proposal using [Google's web interface][gsoc-submit] ahead of the deadline (this requires a Google Account!)
- Submit proof of enrollment well ahead of the deadline
Coming up with an interesting idea that you can realistically achieve in the time available to you (one summer) is probably the most difficult part. We strongly recommend getting involved in advance of the beginning of GSoC, and we will look favorably on applications from students who have already started to act like free and open source developers.
Before the summer starts, there are some preparatory tasks which are highly encouraged. First, if you aren't already, definitely start using Qubes as your primary OS as soon as possible! Also, it is encouraged that you become familiar and comfortable with the Qubes development workflow sooner than later. A good way to do this (and also a great way to stand out as an awesome applicant and make us want to accept you!) might be to pick up some issues from [qubes-issues][qubes-issues] (our issue-tracking repo) and submit some patches addressing them. Some suitable issues might be those with tags ["help wanted" and "P: minor"][qubes-issues-suggested] (although more significant things are also welcome, of course). Doing this will get you some practice with [qubes-builder][qubes-builder], our code-signing policies, and some familiarity with our code base in general so you are ready to hit the ground running come summer.
A project proposal is what you will be judged upon. Write a clear proposal on what you plan to do, the scope of your project, and why we should choose you to do it. Proposals are the basis of the GSoC projects and therefore one of the most important things to do well. The proposal is not only the basis of our decision of which student to choose, it has also an effect on Google's decision as to how many student slots are assigned to Qubes.
Every software project should solve a problem. Before offering the solution (your Google Summer of Code project), you should first define the problem. What’s the current state of things? What’s the issue you wish to solve and why? Then you should conclude with a sentence or two about your solution. Include links to discussions, features, or bugs that describe the problem further if necessary.
# Project goals
Be short and to the point, and perhaps format it as a list. Propose a clear list of deliverables, explaining exactly what you promise to do and what you do not plan to do. “Future developments” can be mentioned, but your promise for the Google Summer of Code term is what counts.
# Implementation
Be detailed. Describe what you plan to do as a solution for the problem you defined above. Include technical details, showing that you understand the technology. Illustrate key technical elements of your proposed solution in reasonable detail.
# Timeline
Show that you understand the problem, have a solution, have also broken it down into manageable parts, and that you have a realistic plan on how to accomplish your goal. Here you set expectations, so don’t make promises you can’t keep. A modest, realistic and detailed timeline is better than promising the impossible.
If you have other commitments during GSoC, such as a job, vacation, exams, internship, seminars, or papers to write, disclose them here. GSoC should be treated like a full-time job, and we will expect approximately 40 hours of work per week. If you have conflicts, explain how you will work around them. If you are found to have conflicts which you did not disclose, you may be failed.
Open and clear communication is of utmost importance. Include your plans for communication in your proposal; daily if possible. You will need to initiate weekly formal communications such as a detailed email to the qubes-devel mailing list. Lack of communication will result in you being failed.
# About me
Provide your contact information and write a few sentences about you and why you think you are the best for this job. Prior contributions to Qubes are helpful; list your commits. Name people (other developers, students, professors) who can act as a reference for you. Mention your field of study if necessary. Now is the time to join the relevant mailing lists. We want you to be a part of our community, not just contribute your code.
Tell us if you are submitting proposals to other organizations, and whether or not you would choose Qubes if given the choice.
Other things to think about:
* Are you comfortable working independently under a supervisor or mentor who is several thousand miles away, and perhaps 12 time zones away? How will you work with your mentor to track your work? Have you worked in this style before?
* If your native language is not English, are you comfortable working closely with a supervisor whose native language is English? What is your native language, as that may help us find a mentor who has the same native language?
* After you have written your proposal, you should get it reviewed. Do not rely on the Qubes mentors to do it for you via the web interface, although we will try to comment on every proposal. It is wise to ask a colleague or a developer to critique your proposal. Clarity and completeness are important.
```
## Project Ideas
These project ideas were contributed by our developers and may be incomplete. If you are interested in submitting a proposal based on these ideas, you should contact the [qubes-devel mailing list][ml-devel] and associated GitHub issue to learn more about the idea.
```
### Adding a Proposal
**Project**: Something that you're totally excited about
**Brief explanation**: What is the project, where does the code live?
**Expected results**: What is the expected result in the timeframe given
**Brief explanation**: Add ability to use individual USB devices in Windows qubes. Right now the only option to do that, is to assign the whole USB controller (PCI device), which applies to all the devices connected to it. USB passthrough on Qubes is based on USBIP project, with transport over qrexec instead of TCP/IP.
- basic USB architecture knowledge (buses, devices, interfaces, functions)
- Python and Bash scripting
- C
- Windows USB stack and/or qemu USB stack
**Mentor**: [Marek Marczykowski-Górecki](/team/)
### Dedicated Audio qube
**Project**: Dedicated Audio qube
**Brief explanation**: Moving audio subsystem from dom0 to a dedicated AudioVM and/or a preexisting VM (e.g sys-usb with attached usb audio device). This would allow using USB audio devices system-wide, without leaving a USB controller in dom0. [Relevant github issue](https://github.com/QubesOS/qubes-issues/issues/1590).
**Expected results**:
- Make audio virtualization components work with non-dom0 backend (in short: add configuration option for the backend, instead of assuming "dom0")
- Possibly per-qube setting what should be used as an AudioVM
- Make other audio-related tools (including GUI tools) work with the new setup, especially enabling/disabling microphone (`qvm-device mic`) and volume control
**Brief explanation**: Currently using Vagrant on Qubes requires finding an image that uses Docker as isolation provider and running Docker in a qube, or downloading the Vagrantfile and manually setting up a qube according to the Vagrantfile. This project aims at simplifying this workflow. Since introduction of Admin API, it's possible for a qube to provision another qube - which is exactly what is needed for Vagrant. [Related discussion](https://groups.google.com/d/msgid/qubes-devel/535299ca-d16a-4a70-8223-a4ac6be4be41%40googlegroups.com)
**Expected results**:
- Design how Vagrant Qubes provider should look like, including:
**Project**: Mechanism for maintaining in-VM configuration
**Brief explanation**: Large number of VMs is hard to maintain. Templates helps with keeping them updated, but many applications have configuration in user home directory, which is not synchronized.
**Expected results**:
- Design a mechanism how to _safely_ synchronize application configuration living in user home directory (`~/.config`, some other "dotfiles"). Mechanism should be resistant against malicious VM forcing its configuration on other VMs. Some approach could be a strict control which VM can send what changes (whitelist approach, not blacklist).
### Wayland support in GUI agent and/or GUI daemon
**Project**: Wayland support in GUI agent and/or GUI daemon
**Brief explanation**: Currently both GUI agent (VM side of the GUI virtualization) and GUI daemon (dom0 side of GUI virtualization) support X11 protocol only. It may be useful to add support for Wayland there. Note that those are in fact two independent projects:
1. GUI agent - make it work as Wayland compositor, instead of extracting window's composition buffers using custom X11 driver
2. GUI daemon - act as Wayland application, showing windows retrieved from VMs, keeping zero-copy display path (window content is directly mapped from application running in VM, not copied)
**Expected results**:
Choose either of GUI agent, GUI daemon. Both are of similar complexity and each separately looks like a good task for GSoC time period.
- design relevant GUI agent/daemon changes, the GUI protocol should not be affected
- consider window decoration handling - VM should have no way of spoofing those, so it must be enforced by GUI daemon (either client-side - by GUI daemon itself, or server-side, based on hints given by GUI daemon)
- implement relevant GUI agent/daemon changes
- implement tests for new GUI handling, similar to existing tests for X11 based GUI
**Expected results**: A firewall implemented as a unikernel which supports all the networking-related functionality as the default sys-firewall VM, including configuration via Qubes Manager. Other duties currently assigned to sys-firewall such as the update proxy may need to be appropriately migrated first.
**Knowledge prerequisite**:
- [OCaml](https://ocaml.org/) + [MirageOS](https://mirage.io/) or other unikernel framework,
- Work at upstream Tor: An older version of https://trac.torproject.org/projects/tor/wiki/doc/TransparentProxy page was the origin of Whonix. Update that page for nftables / IPv6 support without mentioning Whonix. Then discuss that on the tor-talk mailing list for wider input. - https://trac.torproject.org/projects/tor/ticket/21397
- implement corridor feature request add IPv6 support / port to nftables - https://github.com/rustybird/corridor/issues/39
**Project**: Audio support for Qubes Windows Tools
**Brief explanation**: Add audio support for Windows HVMs via Qubes Windows Tools. [#2624](https://github.com/QubesOS/qubes-issues/issues/2624)
**Expected results**: Windows HVMs should have an audio device that supports playback and recording.
**Knowledge prerequisite**: C/C++ languages, familiarity with Windows API, possibly familiarity with Windows audio stack on the driver level.
**Mentor**: [Rafał Wojdyła](/team/)
### Improve Windows GUI agent performance and stability
**Project**: Improve Windows GUI agent performance and stability
**Brief explanation**: Previous profiling has shown that the Windows GUI agent uses significant portion of VM's CPU time for mouse input simulation. This can be improved, as well as agent's stability in some cases (desktop/user switching, logon/logoff, domain-joined VMs, multiple monitors). Seamless GUI experience can be significantly improved, but that may require changes in the Qubes video driver. [#1044](https://github.com/QubesOS/qubes-issues/issues/1044) [#1045](https://github.com/QubesOS/qubes-issues/issues/1045) [#1500](https://github.com/QubesOS/qubes-issues/issues/1500) [#2138](https://github.com/QubesOS/qubes-issues/issues/2138) [#2487](https://github.com/QubesOS/qubes-issues/issues/2487) [#2589](https://github.com/QubesOS/qubes-issues/issues/2589)
**Expected results**: Reduction of agent's CPU usage, improved stability.
**Knowledge prerequisite**: C language, Familiarity with Windows API, especially the windowing stack. Familiarity with profiling and debugging tools for Windows.
**Brief explanation**: Add support for Windows 8+ to the Qubes GUI agent and video driver. Starting from Windows 8, Microsoft requires all video drivers to conform to the WDDM display driver model which is incompatible with the current Qubes video driver. Unfortunately the WDDM model is much more complex than the old XPDM one and officially *requires* a physical GPU device (which may be emulated). Some progress has been made to create a full WDDM driver that *doesn't* require a GPU device, but the driver isn't working correctly yet. Alternatively, WDDM model supports display-only drivers which are much simpler but don't have access to system video memory and rendering surfaces (a key feature that would simplify seamless GUI mode). [#1861](https://github.com/QubesOS/qubes-issues/issues/1861)
**Expected results**: Working display-only WDDM video driver or significant progress towards making the full WDDM driver work correctly.
**Knowledge prerequisite**: C/C++ languages, familiarity with Windows API, familiarity with the core Windows WDM driver model. Ideally familiarity with the WDDM display driver model.
**Brief explanation**: Simplify Windows usage by providing a tool that perform unattended installation given required input data (installation image, license key, user name, etc). Similar feature is already supported in other virtualization solutions, including VMWare Workstation and VirtualBox. [Related github issue](https://github.com/QubesOS/qubes-issues/issues/4688).
**Expected results**:
- A template for `autounattended.xml` file for Windows installer - the template should have placeholders for settings that need to be provided by the user.
- A tool for generating actual `autounattended.xml` file based on the template and user settings.
- A tool for launching Windows installation, given installation image and `autounattended.xml` file (can be the same as in the above point).
- (Optional) Unattended installation should also include Qubes Windows Tools.
- (Optional) A tool should be able to use Windows license embedded in ACPI tables - [related discussion](https://groups.google.com/d/msgid/qubes-devel/0b7fabae-f843-e7ce-40cf-193326cecdb0%40zrubi.hu)
- User documentation
- Automated tests (unit tests, integration tests)
**Knowledge prerequisite**:
- Python scripting
- Linux administration, including handling loop devices, partition tables, filesystems etc
- For optional features, C language and x86 architecture (ACPI tables)
**Brief explanation**: One of the pioneering ideas of Qubes is to use disposable virtual machines to convert untrustworthy files (such as documents given to journalists by unknown and potentially malicious whistleblowers) into trustworthy files. See [Joanna's blog on the Qubes PDF Convert](http://theinvisiblethings.blogspot.co.uk/2013/02/converting-untrusted-pdfs-into-trusted.html) for details of the idea. Joanna has implemented a prototype for PDF documents. The goal of this project would be to generalize beyond the simple prototype to accommodate a wide variety of file formats, including Word documents, audio files, video files, spreadsheets, and so on. The converters should prioritise safety over faithful conversion. For example the Qubes PDF converter typically leads to lower quality PDFs (e.g. cut and paste is no longer possible), because this makes the conversion process safer.
**Expected results**: We expect that in the timeframe, it will be possible to implement many converters for many file formats. However, if any unexpected difficulties arise, we would prioritise a small number of safe and high quality converters over a large number of unsafe or unuseful converters.
**Knowledge prerequisite**: Most of the coding will probably be implemented as shell scripts to interface with pre-existing converters (such as ImageMagick in the Qubes PDF converter). However, shell scripts are not safe for processing untrusted data, so any extra processing will need to be implemented in another language -- probably Python.
**Brief explanation**: A long-term goal is to be able to build the entire OS and installation media in a completely bit-wise deterministic manner, but there are many baby steps to be taken along that path. See:
- [This mailing list post](https://groups.google.com/d/msg/qubes-devel/gq-wb9wTQV8/mdliS4P2BQAJ)
- and [reproducible-builds.org](https://reproducible-builds.org/)
for more information and qubes-specific background.
**Expected results**: Significant progress towards making the Qubes build process deterministic. This would likely involve cooperation with and hacking on several upstream build tools to eliminate sources of variability.
**Knowledge prerequisite**: qubes-builder [[1]](/doc/qubes-builder/) [[2]](/doc/qubes-builder-details/) [[3]](https://github.com/QubesOS/qubes-builder/tree/master/doc), and efficient at introspecting complex systems: comfortable with tracing and debugging tools, ability to quickly identify and locate issues within a large codebase (upstream build tools), etc.
Qubes currently only supports the x86_64 CPU architecture. Xen currently has additional support for ARM32/ARM64 processors, however work needs to be done to integrate this into the Qubes build process, as well as work in integrating this with the Qubes toolstack and security model. This may also be beneficial in simplifying the process of porting to other architectures.
Qubes currently supports the x86_64 CPU architecture. PowerPC is desirable for security purposes as it is the only architecture where one can get performant hardware with entirely open source firmware. Xen has **deprecated** support for Power9/PPC64 processors. Here are two directions to tackle this project from:
- Implement some missing functionality in KVM then implement KVM support in the Qubes Hypervisor Abstraction Layer and build process. Improving the HAL will also be beneficial for simplifying the process of porting to further architectures and hypervisors.