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Gabriel Parmer
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2020 – today
- 2024
- [c40]Xinyu Han
, Yuan Gao
Byways: High-Performance, Isolated Network Functions for Multi-Tenant Cloud Servers. SoCC 2024: 811-829 - [c39]Maorui Bai, Runyu Pan, Gabriel Parmer:
OmniWasm: Efficient, Granular Fault Isolation and Control-Flow Integrity for Arm Microcontrollers. RTAS 2024: 239-251 - 2022
- [j10]Yuxin Ren
Sharing non-cache-coherent memory with bounded incoherence. Concurr. Comput. Pract. Exp. 34(2) (2022) - [c38]Xiaosu Lyu, Ludmila Cherkasova, Robert C. Aitken, Gabriel Parmer, Timothy Wood:
Towards efficient processing of latency-sensitive serverless DAGs at the edge. EdgeSys@EuroSys 2022: 49-54 - [c37]Runyu Pan, Gabriel Parmer:
SBIs: Application Access to Safe, Baremetal Interrupt Latencies*. RTAS 2022: 82-94 - [c36]Samuel Mergendahl, Samuel Jero, Bryan C. Ward
The Thundering Herd: Amplifying Kernel Interference to Attack Response Times. RTAS 2022: 95-107 - [c35]Wenyuan Shao, Bite Ye, Huachuan Wang, Gabriel Parmer
Edge-RT: OS Support for Controlled Latency in the Multi-Tenant, Real-Time Edge. RTSS 2022: 1-13 - 2021
- [j9]James Marshall
Precise Cache Profiling for Studying Radiation Effects. ACM Trans. Embed. Comput. Syst. 20(3): 25:1-25:25 (2021) - [c34]Samuel Jero, Juliana Furgala, Runyu Pan, Phani Kishore Gadepalli, Alexandra Clifford, Bite Ye, Roger Khazan, Bryan C. Ward, Gabriel Parmer, Richard Skowyra:
Practical Principle of Least Privilege for Secure Embedded Systems. RTAS 2021: 1-13 - 2020
- [j8]Gregor Peach, Runyu Pan, Zhuoyi Wu
eWASM: Practical Software Fault Isolation for Reliable Embedded Devices. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 39(11): 3492-3505 (2020) - [c33]Phani Kishore Gadepalli, Sean McBride, Gregor Peach, Ludmila Cherkasova, Gabriel Parmer
Sledge: a Serverless-first, Light-weight Wasm Runtime for the Edge. Middleware 2020: 265-279 - [c32]Yuxin Ren
Bounded incoherence: a programming model for non-cache-coherent shared memory architectures. PMAM@PPoPP 2020: 1:1-1:10 - [c31]Yuxin Ren
Ch'i: Scaling Microkernel Capabilities in Cache-Incoherent Systems. ROSS@SC 2020: 12-21 - [c30]Phani Kishore Gadepalli, Runyu Pan, Gabriel Parmer:
Slite: OS Support for Near Zero-Cost, Configurable Scheduling *. RTAS 2020: 160-173 - [c29]Yuxin Ren, Guyue Liu, Vlad Nitu, Wenyuan Shao, Riley Kennedy, Gabriel Parmer, Timothy Wood, Alain Tchana:
Fine-Grained Isolation for Scalable, Dynamic, Multi-tenant Edge Clouds. USENIX ATC 2020: 927-942
2010 – 2019
- 2019
- [j7]Runyu Pan, Gabriel Parmer:
MxU: Towards Predictable, Flexible, and Efficient Memory Access Control for the Secure IoT. ACM Trans. Embed. Comput. Syst. 18(5s): 103:1-103:20 (2019) - [c28]Yuxin Ren
Scalable Data-structures with Hierarchical, Distributed Delegation. Middleware 2019: 68-81 - [c27]Phani Kishore Gadepalli, Gregor Peach, Gabriel Parmer, Joseph Espy, Zach Day:
Chaos: a System for Criticality-Aware, Multi-Core Coordination. RTAS 2019: 77-89 - [c26]Phani Kishore Gadepalli, Gregor Peach, Ludmila Cherkasova, Rob Aitken, Gabriel Parmer:
Challenges and Opportunities for Efficient Serverless Computing at the Edge. SRDS 2019: 261-266 - [i1]Yuxin Ren, Vlad Nitu, Guyue Liu, Gabriel Parmer, Timothy Wood, Alain Tchana, Riley Kennedy:
Efficient, Dynamic Multi-tenant Edge Computation in EdgeOS. CoRR abs/1901.01222 (2019) - 2018
- [c25]Runyu Pan, Gregor Peach, Yuxin Ren
Predictable Virtualization on Memory Protection Unit-Based Microcontrollers. RTAS 2018: 62-74 - [c24]Yuxin Ren
Scalable Memory Reclamation for Multi-Core, Real-Time Systems. RTAS 2018: 152-163 - 2017
- [c23]Phani Kishore Gadepalli, Robert Gifford
Temporal Capabilities: Access Control for Time. RTSS 2017: 56-67 - [e1]Gabriel Parmer:
2017 IEEE Real-Time and Embedded Technology and Applications Symposium, RTAS 2017, Pittsburg, PA, USA, April 18-21, 2017. IEEE Computer Society 2017, ISBN 978-1-5090-5269-1 [contents] - 2016
- [c22]Jiguo Song, Gedare Bloom, Gabriel Parmer:
SuperGlue: IDL-Based, System-Level Fault Tolerance for Embedded Systems. DSN 2016: 227-238 - [c21]Gedare Bloom, Gabriel Parmer, Rahul Simha:
LockDown: an operating system for achieving service continuity by quarantining principals. EUROSEC 2016: 7:1-7:6 - [c20]Qi Wang, Timothy Stamler, Gabriel Parmer:
Parallel sections: scaling system-level data-structures. EuroSys 2016: 33:1-33:15 - [c19]James Marshall, Gedare Bloom, Gabriel Parmer, Rahul Simha:
n-Modular Redundant Real-Time Middleware: Design and Implementation. EWiLi 2016 - [c18]Yuxin Ren, Gabriel Parmer, Teo Georgiev, Gedare Bloom:
CBufs: efficient, system-wide memory management and sharing. ISMM 2016: 68-77 - 2015
- [c17]Qi Wang, Yuxin Ren
SPeCK: a kernel for scalable predictability. RTAS 2015: 121-132 - [c16]Jiguo Song, Gabriel Parmer:
C'Mon: a predictable monitoring infrastructure for system-level latent fault detection and recovery. RTAS 2015: 247-258 - 2014
- [c15]Qi Wang, Gabriel Parmer:
FJOS: Practical, predictable, and efficient system support for fork/join parallelism. RTAS 2014: 25-36 - [c14]James R. Taylor, Evan M. Drumwright, Gabriel Parmer:
Making Time Make Sense in Robotic Simulation. SIMPAR 2014: 1-12 - 2013
- [j6]Jiguo Song, Gabriel Parmer:
Predictable, system-level fault tolerance in composite. SIGBED Rev. 10(2): 31 (2013) - [j5]Jiguo Song, Gabriel Parmer:
Toward predictable, efficient, system-level tolerance of transient faults. SIGBED Rev. 10(4): 53-56 (2013) - [j4]Gabriel Parmer, Richard West:
Predictable and configurable component-based scheduling in the Composite OS. ACM Trans. Embed. Comput. Syst. 13(1s): 32:1-32:26 (2013) - [c13]Jiguo Song, John Wittrock, Gabriel Parmer:
Predictable, Efficient System-Level Fault Tolerance in C^3. RTSS 2013: 21-32 - 2012
- [j3]Jie Chen, Guru Venkataramani, Gabriel Parmer:
The Need for Power Debugging in the Multi-Core Environment. IEEE Comput. Archit. Lett. 11(2): 57-60 (2012) - [j2]Gabriel Parmer, Richard West:
Mutable Protection Domains: Adapting System Fault Isolation for Reliability and Efficiency. IEEE Trans. Software Eng. 38(4): 875-888 (2012) - [c12]Gedare Bloom, Gabriel Parmer, Bhagirath Narahari, Rahul Simha:
Shared hardware data structures for hard real-time systems. EMSOFT 2012: 133-142 - [c11]Qi Wang, Jiguo Song, Gabriel Parmer, Andrew Sweeney, Guru Venkataramani:
Increasing Memory Utilization with Transient Memory Scheduling. RTSS 2012: 248-259 - 2011
- [j1]Richard West, Gabriel Parmer:
Application-specific service technologies for commodity operating systems in real-time environments. ACM Trans. Embed. Comput. Syst. 10(3): 30:1-30:21 (2011) - [c10]Gabriel Parmer, Richard West:
HiRes: A System for Predictable Hierarchical Resource Management. IEEE Real-Time and Embedded Technology and Applications Symposium 2011: 180-190 - [c9]Qi Wang, Jiguo Song, Gabriel Parmer:
Execution Stack Management for Hard Real-Time Computation in a Component-Based OS. RTSS 2011: 78-89 - 2010
- [c8]Gabriel Parmer, Jiguo Song:
Customizable and Predictable Synchronization in a Component-Based OS. ESA 2010: 59-65
2000 – 2009
- 2008
- [c7]Gabriel Parmer, Richard West:
Predictable Interrupt Management and Scheduling in the Composite Component-Based System. RTSS 2008: 232-243 - 2007
- [c6]Gabriel Parmer, Richard West, Gerald Fry:
Scalable Overlay Multicast Tree Construction for Media Streaming. PDPTA 2007: 76-83 - [c5]Gabriel Parmer, Richard West:
Hijack: Taking Control of COTS Systems for Real-Time User-Level Services. IEEE Real-Time and Embedded Technology and Applications Symposium 2007: 133-146 - [c4]Gabriel Parmer, Richard West:
Mutable Protection Domains: Towards a Component-Based System for Dependable and Predictable Computing. RTSS 2007: 365-378 - 2006
- [c3]Richard West, Gabriel Parmer:
Application-Specific Service Technologies for Commodity Operating Systems in Real-Time Environments. IEEE Real Time Technology and Applications Symposium 2006: 3-13 - 2004
- [c2]Xin Qi, Gabriel Parmer, Richard West:
An efficient end-host architecture for cluster communication. CLUSTER 2004: 83-92 - [c1]Gabriel Parmer, Richard West, Xin Qi, Gerald Fry, Yuting Zhang:
An Internet-Wide Distributed System for Data-Stream Processing. International Conference on Internet Computing 2004: 920-926
Coauthor Index
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