| Week | Date | Topic(s) | Facilitator(s) | Paper(s) |
|---|---|---|---|---|
| 1 | 8/26 | — | Eide | organizational meeting |
| 2 | 9/2 | JIT script parallelization | Eide | Practically Correct, Just-in-Time Shell Script Parallelization. Konstantinos Kallas et al. In OSDI ’22, Jul. 2022. |
| 3 | 9/9 | secure isolation for cloud applications | Johnson | CAP-VMs: Capability-Based Isolation and Sharing in the Cloud. Vasily A. Sartakov et al. In OSDI ’22, Jul. 2022. |
| 4 | 9/16 | configuration management | Ricci | NixOS: A Purely Functional Linux Distribution. Eelco Dolstra and Andres Löh. In ICFP ’08, Sep. 2008. |
| 5 | 9/23 | software-defined address mapping | Wong | Software-Defined Address Mapping: A Case on 3D Memory. Jialiang Zhang et al. In ASPLOS ’22, Feb.–Mar. 2022. |
| 6 | 9/30 | WebAssembly fuzzing | Watson | Stack-Driven Program Generation of WebAssembly. Árpád Perényi and Jan Midtgaard. In APLAS ’20, Nov.–Dec. 2020. |
| 7 | 10/7 | wireless access networks | Webb | Building Flexible, Low-Cost Wireless Access Networks with Magma. Shaddi Hasan et al. arXiv:2209.10001, Sep. 2022. |
| 8 | 10/14 | — | — | no meeting — University fall break |
| 9 | 10/21 | build systems | Pronovost | Riker: Always-Correct and Fast Incremental Builds from Simple Specifications. Charlie Curtsinger and Daniel W. Barowy. In ATC ’22, Jul. 2022. |
| 10 | 10/28 | formal verification of protocols | Wiersdorf | Discovering Emergency Call Pitfalls for Cellular Networks with Formal Methods. Kaiyu Hou et al. In MobiSys ’21, Jun.–Jul. 2021. |
| 11 | 11/4 | IoT programming | Eide | Creating a Language for Writing Real-Time Applications for the Internet of Things. Robert Krook et al. In MEMOCODE ’22, Oct. 2022. |
| 12 | 11/11 | LTE security | Wu | Hiding in Plain Signal: Physical Signal Overshadowing Attack on LTE. Hojoon Yang et al. In USENIX Security ’19, Aug. 2019. |
| 13 | 11/18 | distributed fuzzing | Remes | UltraFuzz: Towards Resource-Saving in Distributed Fuzzing. Xu Zhou et al. arXiv:2009.06124, Nov. 2022. |
| 14 | 11/25 | — | — | no meeting — Thanksgiving break |
| 15 | 12/2 | RAN virtualization | Zhu | Nuberu: Reliable RAN Virtualization in Shared Platforms. Gines Garcia-Aviles et al. In MobiCom ’21, Oct. 2021. |
| 16 | 12/9 | Wi-Fi localization | Eide | Non-Cooperative Wi-Fi Localization & its Privacy Implications. Ali Abedi and Deepak Vasisht. In MobiCom ’22, Oct. 2022. |
The fall 2022 offering of CS 7934 will cover a variety of systems topics, with an eye toward two goals.
The first is to increase participants' familiarity with recent and important results in the area of computer systems research. Attendees will read and discuss papers from recent and imminent top-tier systems conferences: e.g., SOSP, OSDI, NSDI, SIGCOMM, FAST, systems-related security conferences, and so on. Attendees will typically discuss one paper each week. Papers will be selected for their relevance to participants' research or upcoming Utah visitors. There is no preset “focus topic” for fall 2022. One can anticipate, however, that the semester will include discussions about operating systems, distributed systems, cloud computing, datacenters, networking, and security.
The second is to be a venue for student presentations. Every student participating in the seminar will be required to lead at least one meeting during the semester. This may be a “formal” research presentation—ideally of a student's current work—or it may be an analysis of the research papers chosen for a seminar meeting.
CS 7934 is often called “the CSL seminar.” The name CSL is historic.
To get on the class mailing list, use Mailman to subscribe to csl-sem.
The course syllabus contains important information for students, including the course's policies on grading and cheating.
Students may enroll for one (1) credit.
Those taking the course for credit must read all of the assigned papers, submit a short summary of each assigned paper prior to class (PDF, LaTeX), participate in each discussion, and facilitate at least one seminar meeting during the semester. Refer to the syllabus for further information.
Upcoming and recent conference proceedings are good sources of papers for discussion. Below are links to some relevant conference series.
| Semester | Focus Topic(s) |
|---|---|
| Spring 2022 | no focus topic chosen |
| Fall 2021 | no focus topic chosen |
| Spring 2021 | no focus topic chosen; many OS design papers |
| Fall 2020 | no focus topic chosen |
| Spring 2020 | no focus topic chosen |
| Fall 2019 | no focus topic chosen |
| Spring 2019 | no focus topic chosen |
| Fall 2018 | no focus topic chosen |
| Spring 2018 | no focus topic chosen; many SOSP ’17 papers |
| Fall 2017 | no focus topic chosen |
| Spring 2017 | no focus topic chosen |
| Fall 2016 | no focus topic chosen; many SIGCOMM ’16 papers |
| Spring 2016 | no focus topic chosen |
| Fall 2015 | no focus topic chosen; many systems security papers |
| Spring 2015 | no focus topic chosen |
| Fall 2014 | no focus topic chosen; many OSDI ’14 papers |
| Spring 2014 | no focus topic chosen; many systems security papers |
| Fall 2013 | no focus topic chosen; many SOSP ’13 papers |
| Spring 2013 | reversible and “time-traveling” debugging |
| Fall 2012 | modern networking and network management; peer-review process |
| Spring 2012 | systems approaches to dynamic problem detection and repair |
| Fall 2011 | datacenter architectures and issues |
| Spring 2011 | malicious software, i.e., malware |
| Fall 2010 | systems approaches to security |
| Spring 2010 | testbed-like infrastructures for cloud computing and scientific computing |
| Fall 2009 | no focus topic chosen; many SOSP ’09 papers |
| Fall 2008 | no focus topic chosen; many OSDI ’08 papers |
| Summer 2008 | no focus topic chosen; informal biweekly meetings |
| Spring 2008 | no focus topic chosen |
| Fall 2007 | no focus topic chosen; many SOSP ’07 papers |
| Fall 2006 | no focus topic chosen; many OSDI ’06 papers |
| Fall 2005 | no focus topic chosen; many SOSP ’05 papers |
| Spring 2005 | no focus topic chosen; many NSDI ’05 papers |