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Gene Cooperman
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- affiliation: Northeastern University, Boston, USA
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2020 – today
- 2024
- [j20]Maxwell Pirtle, Luka Jovanovic
, Gene Cooperman:
McMini: A Programmable DPOR-Based Model Checker for Multithreaded Programs. Art Sci. Eng. Program. 8(1) (2024) - [c77]Yao Xu, Gene Cooperman:
Enabling Practical Transparent Checkpointing for MPI: A Topological Sort Approach. CLUSTER 2024: 238-249 - [i31]Yao Xu, Gene Cooperman:
Enabling Practical Transparent Checkpointing for MPI: A Topological Sort Approach. CoRR abs/2408.02218 (2024) - [i30]Rui Li, Devesh Tiwari, Gene Cooperman:
WarmSwap: Sharing Dependencies for Accelerating Cold Starts in Serverless Functions. CoRR abs/2409.09202 (2024) - 2023
- [c76]Yao Xu
Implementation-Oblivious Transparent Checkpoint-Restart for MPI. SC Workshops 2023: 1738-1747 - [i29]Yao Xu, Leonid Belyaev, Twinkle Jain, Derek Schafer, Anthony Skjellum, Gene Cooperman:
Implementation-Oblivious Transparent Checkpoint-Restart for MPI. CoRR abs/2309.14996 (2023) - 2022
- [i28]Maxwell Pirtle, Luka Jovanovic, Gene Cooperman:
McMini: A Programmable DPOR-based Model Checker for Multithreaded Programs. CoRR abs/2212.05468 (2022) - [i27]Yao Xu, Gene Cooperman:
Collective Vector Clocks: Low-Overhead Transparent Checkpointing for MPI. CoRR abs/2212.05701 (2022) - 2021
- [c75]Yao Xu
MANA-2.0: A Future-Proof Design for Transparent Checkpointing of MPI at Scale. SC (Workshops) 2021: 68-78 - [i26]Prashant Singh Chouhan, Harsh Khetawat, Neil Resnik, Twinkle Jain, Rohan Garg, Gene Cooperman, Rebecca Hartman-Baker, Zhengji Zhao:
Improving scalability and reliability of MPI-agnostic transparent checkpointing for production workloads at NERSC. CoRR abs/2103.08546 (2021) - [i25]Yao Xu, Zhengji Zhao, Rohan Garg, Harsh Khetawat, Rebecca Hartman-Baker, Gene Cooperman:
MANA-2.0: A Future-Proof Design for Transparent Checkpointing of MPI at Scale. CoRR abs/2112.05858 (2021) - [i24]Prashant Singh Chouhan, Gregory Price, Gene Cooperman:
An Architecture for Exploiting Native User-Land Checkpoint-Restart to Improve Fuzzing. CoRR abs/2112.10100 (2021) - 2020
- [j19]Aya Omezzine
Towards a generic multilayer negotiation framework for efficient application provisioning in the cloud. Concurr. Comput. Pract. Exp. 32(1) (2020) - [j18]Gene Cooperman, Martin Quinson:
Sthread: In-Vivo Model Checking of Multithreaded Programs. Art Sci. Eng. Program. 4(3): 13 (2020) - [c74]Apoorve Mohan, Shripad Nadgowda, Bhautik Pipaliya, Sona Varma, Sahil Suneja, Canturk Isci, Gene Cooperman, Peter Desnoyers, Orran Krieger, Ata Turk:
Towards Non-Intrusive Software Introspection and Beyond. IC2E 2020: 173-184 - [c73]Arif Ahmed, Apoorve Mohan, Gene Cooperman, Guillaume Pierre:
Docker Container Deployment in Distributed Fog Infrastructures with Checkpoint/Restart. MobileCloud 2020: 55-62 - [c72]Twinkle Jain
CRAC: checkpoint-restart architecture for CUDA with streams and UVM. SC 2020: 77 - [i23]Gene Cooperman, Martin Quinson:
Sthread: In-Vivo Model Checking of Multithreaded Programs. CoRR abs/2002.06223 (2020) - [i22]Twinkle Jain, Gene Cooperman:
CRAC: Checkpoint-Restart Architecture for CUDA with Streams and UVM. CoRR abs/2008.10596 (2020)
2010 – 2019
- 2019
- [j17]Aya Omezzine, Narjès Bellamine Ben Saoud, Saïd Tazi, Gene Cooperman:
Adaptive and concurrent negotiation for an efficient cloud provisioning. Int. J. High Perform. Comput. Netw. 15(3/4): 145-157 (2019) - [j16]Manuel Aurelio Rodriguez Pascual, Jiajun Cao, José A. Moríñigo
Job migration in HPC clusters by means of checkpoint/restart. J. Supercomput. 75(10): 6517-6541 (2019) - [c71]Rohan Garg, Gregory Price, Gene Cooperman:
MANA for MPI: MPI-Agnostic Network-Agnostic Transparent Checkpointing. HPDC 2019: 49-60 - [c70]Amin Mosayyebzadeh, Apoorve Mohan, Sahil Tikale, Mania Abdi, Nabil Schear, Trammell Hudson, Charles Munson, Larry Rudolph, Gene Cooperman, Peter Desnoyers, Orran Krieger:
Supporting Security Sensitive Tenants in a Bare-Metal Cloud. USENIX ATC 2019: 587-602 - [i21]Rohan Garg, Gregory Price, Gene Cooperman:
MANA for MPI: MPI-Agnostic Network-Agnostic Transparent Checkpointing. CoRR abs/1904.12595 (2019) - [i20]Amin Mosayyebzadeh, Apoorve Mohan, Sahil Tikale, Mania Abdi, Nabil Schear, Charles Munson
Supporting Security Sensitive Tenants in a Bare-Metal Cloud. CoRR abs/1907.06110 (2019) - [i19]Amin Mosayyebzadeh, Gerardo Ravago, Apoorve Mohan, Ali Raza, Sahil Tikale, Nabil Schear, Trammell Hudson, Jason Hennessey, Naved Ansari, Kyle Hogan, Charles Munson
A Secure Cloud with Minimal Provider Trust. CoRR abs/1907.07627 (2019) - 2018
- [c69]Rohan Garg, Apoorve Mohan, Michael B. Sullivan, Gene Cooperman:
CRUM: Checkpoint-Restart Support for CUDA's Unified Memory. CLUSTER 2018: 302-313 - [c68]Rohan Garg, Tirthak Patel
Shiraz: Exploiting System Reliability and Application Resilience Characteristics to Improve Large Scale System Throughput. DSN 2018: 83-94 - [c67]Amin Mosayyebzadeh, Gerardo Ravago, Apoorve Mohan, Ali Raza, Sahil Tikale, Nabil Schear, Trammell Hudson, Jason Hennessey, Naved Ansari, Kyle Hogan, Charles Munson, Larry Rudolph, Gene Cooperman, Peter Desnoyers, Orran Krieger:
A Secure Cloud with Minimal Provider Trust. HotCloud 2018 - [c66]Apoorve Mohan, Ata Turk, Ravi S. Gudimetla, Sahil Tikale, Jason Hennessey, Emine Ugur Kaynar, Gene Cooperman, Peter Desnoyers, Orran Krieger:
M2: Malleable Metal as a Service. IC2E 2018: 61-71 - [i18]Apoorve Mohan, Ata Turk, Ravi S. Gudimetla, Sahil Tikale, Jason Hennessey, Emine Ugur Kaynar, Gene Cooperman, Peter Desnoyers, Orran Krieger:
M2: Malleable Metal as a Service. CoRR abs/1801.00540 (2018) - [i17]Rohan Garg, Apoorve Mohan, Michael B. Sullivan, Gene Cooperman:
CRUM: Checkpoint-Restart Support for CUDA's Unified Memory. CoRR abs/1808.00117 (2018) - 2017
- [j15]Kapil Arya, Tyler Denniston, Ariel Rabkin, Gene Cooperman:
Transition Watchpoints: Teaching Old Debuggers New Tricks. Art Sci. Eng. Program. 1(2): 16 (2017) - [c65]Francois Aissaoui
Intelligent Checkpointing Strategies for IoT System Management. FiCloud 2017: 305-312 - [i16]Rohan Garg, Kapil Arya, Jiajun Cao, Gene Cooperman, Jeff Evans, Ankit Garg, Neil A. Rosenberg, K. Suresh:
Adapting the DMTCP Plugin Model for Checkpointing of Hardware Emulation. CoRR abs/1703.00897 (2017) - [i15]Kapil Arya, Tyler Denniston, Ariel Rabkin, Gene Cooperman:
Transition Watchpoints: Teaching Old Debuggers New Tricks. CoRR abs/1703.10864 (2017) - 2016
- [c64]Kapil Arya
Design and Implementation for Checkpointing of Distributed Resources Using Process-Level Virtualization. CLUSTER 2016: 402-412 - [c63]Aya Omezzine, Narjès Bellamine Ben Saoud
Negotiation Based Scheduling for an Efficient SaaS Provisioning in the Cloud. FiCloud 2016: 33-40 - [c62]Jiajun Cao, Kapil Arya
System-Level Scalable Checkpoint-Restart for Petascale Computing. ICPADS 2016: 932-941 - [c61]Francois Aissaoui
Smart scene management for IoT-based constrained devices using checkpointing. NCA 2016: 170-174 - [c60]Aya Omezzine, Narjès Bellamine Ben Saoud
SLA and profit-aware SaaS provisioning through proactive renegotiation. NCA 2016: 351-358 - [c59]Rohan Garg, Jérôme Vienne, Gene Cooperman:
System-Level Transparent Checkpointing for OpenSHMEM. OpenSHMEM 2016: 52-65 - [c58]Rohan Garg, Jiajun Cao, Kapil Arya
Extended Batch Sessions and Three-Phase Debugging: Using DMTCP to Enhance the Batch Environment. XSEDE 2016: 42:1-42:8 - [i14]Jiajun Cao, Kapil Arya, Rohan Garg, L. Shawn Matott, Dhabaleswar K. Panda, Hari Subramoni, Jérôme Vienne, Gene Cooperman:
System-level Scalable Checkpoint-Restart for Petascale Computing. CoRR abs/1607.07995 (2016) - 2015
- [c57]Jiajun Cao, Matthieu Simonin, Gene Cooperman, Christine Morin:
Checkpointing as a Service in Heterogeneous Cloud Environments. CCGRID 2015: 61-70 - 2014
- [c56]Jiajun Cao, Gregory Kerr, Kapil Arya
Transparent checkpoint-restart over infiniband. HPDC 2014: 13-24 - [i13]Jiajun Cao, Matthieu Simonin, Gene Cooperman, Christine Morin:
Checkpointing as a Service in Heterogeneous Cloud Environments. CoRR abs/1411.1958 (2014) - 2013
- [c55]Rohan Garg, Komal Sodha, Zhengping Jin, Gene Cooperman:
Checkpoint-restart for a network of virtual machines. CLUSTER 2013: 1-8 - [c54]Kapil Arya, Gene Cooperman:
DMTCP: Bringing Checkpoint-Restart to Python. SciPy 2013: 2-7 - [c53]J. Christopher Beck, Gene Cooperman:
Invited Speakers. SOCS 2013 - [c52]Kapil Arya
Semi-automated debugging via binary search through a process lifetime. PLOS@SOSP 2013: 9:1-9:7 - [i12]Kapil Arya, Gene Cooperman, Andrea Dotti, Peter Elmer:
Use of Checkpoint-Restart for Complex HEP Software on Traditional Architectures and Intel MIC. CoRR abs/1311.0272 (2013) - [i11]David Abdurachmanov, Kapil Arya, Josh Bendavid, Tommaso Boccali, Gene Cooperman, Andrea Dotti, Peter Elmer, Giulio Eulisse, Francesco Giacomini, Christopher D. Jones, Matteo Manzali, Shahzad Muzaffar:
Explorations of the Viability of ARM and Xeon Phi for Physics Processing. CoRR abs/1311.1001 (2013) - [i10]Jiajun Cao, Kapil Arya, Gene Cooperman:
Transparent Checkpoint-Restart over InfiniBand. CoRR abs/1312.3938 (2013) - [i9]Samaneh Kazemi, Rohan Garg, Gene Cooperman:
Transparent Checkpoint-Restart for Hardware-Accelerated 3D Graphics. CoRR abs/1312.6650 (2013) - 2012
- [c51]Vlad Slavici, Raghu Varier, Gene Cooperman, Robert J. Harrison
Adapting Irregular Computations to Large CPU-GPU Clusters in the MADNESS Framework. CLUSTER 2012: 1-9 - [c50]Kurt L. Keville, Rohan Garg, David J. Yates, Kapil Arya
Towards Fault-Tolerant Energy-Efficient High Performance Computing in the Cloud. CLUSTER 2012: 622-626 - [c49]Vlad Slavici, Daniel Kunkle, Gene Cooperman, Stephen A. Linton:
An efficient programming model for memory-intensive recursive algorithms using parallel disks. ISSAC 2012: 327-334 - [i8]Rohan Garg, Komal Sodha, Gene Cooperman:
A Generic Checkpoint-Restart Mechanism for Virtual Machines. CoRR abs/1212.1787 (2012) - [i7]Kapil Arya, Tyler Denniston, Ana Maria Visan, Gene Cooperman:
FReD: Automated Debugging via Binary Search through a Process Lifetime. CoRR abs/1212.5204 (2012) - 2011
- [c48]Xin Dong, Gene Cooperman:
A Bit-Compatible Parallelization for ILU(k) Preconditioning. Euro-Par (2) 2011: 66-77 - [c47]Ana Maria Visan, Kapil Arya
URDB: a universal reversible debugger based on decomposing debugging histories. PLOS@SOSP 2011: 8:1-8:5 - [i6]Vlad Slavici, Daniel Kunkle, Gene Cooperman, Stephen A. Linton:
Finding the Minimal DFA of Very Large Finite State Automata with an Application to Token Passing Networks. CoRR abs/1103.5736 (2011) - 2010
- [c46]Daniel Kunkle, Vlad Slavici, Gene Cooperman:
Parallel disk-based computation for large, monolithic binary decision diagrams. PASCO 2010: 63-72 - [c45]Xin Dong, Gene Cooperman, John Apostolakis
Multithreaded Geant4: Semi-automatic Transformation into Scalable Thread-Parallel Software. Euro-Par (2) 2010: 287-303 - [c44]Vlad Slavici, Xin Dong, Daniel Kunkle, Gene Cooperman:
Fast multiplication of large permutations for disk, flash memory and RAM. ISSAC 2010: 355-362
2000 – 2009
- 2009
- [j14]Daniel Kunkle, Gene Cooperman:
Harnessing parallel disks to solve Rubik's cube. J. Symb. Comput. 44(7): 872-890 (2009) - [c43]Jason Ansel, Kapil Arya
DMTCP: Transparent checkpointing for cluster computations and the desktop. IPDPS 2009: 1-12 - [c42]Daniel Kunkle, Gene Cooperman:
Biased tadpoles: a fast algorithm for centralizers in large matrix groups. ISSAC 2009: 223-230 - [i5]Ana Maria Visan, Artem Y. Polyakov, Praveen S. Solanki, Kapil Arya, Tyler Denniston, Gene Cooperman:
Temporal Debugging using URDB. CoRR abs/0910.5046 (2009) - 2008
- [j13]Daniel Kunkle, Gene Cooperman:
Solving Rubik's Cube: disk is the new RAM. Commun. ACM 51(4): 31-33 (2008) - [j12]Daniel Kunkle, Donghui Zhang, Gene Cooperman:
Mining Frequent Generalized Itemsets and Generalized Association Rules Without Redundancy. J. Comput. Sci. Technol. 23(1): 77-102 (2008) - [i4]Xin Dong, Gene Cooperman:
Scalable Task-Oriented Parallelism for Structure Based Incomplete LU Factorization. CoRR abs/0803.0048 (2008) - 2007
- [c41]Kevin Hammond, Abdallah Al Zain, Gene Cooperman, Dana Petcu
SymGrid: A Framework for Symbolic Computation on the Grid. Euro-Par 2007: 457-466 - [c40]Eric Robinson, Daniel Kunkle, Gene Cooperman:
A comparative analysis of parallel disk-based Methods for enumerating implicit graphs. PASCO 2007: 78-87 - [c39]Daniel Kunkle, Gene Cooperman:
Twenty-six moves suffice for Rubik's cube. ISSAC 2007: 235-242 - [c38]Eric Robinson, Jürgen Müller, Gene Cooperman:
A disk-based parallel implementation for direct condensation of large permutation modules. ISSAC 2007: 315-322 - [i3]Jason Ansel, Michael Rieker, Gene Cooperman:
User-Level Socket-Based Checkpointing for Distributed and Parallel Computation. CoRR abs/cs/0701037 (2007) - 2006
- [c37]Gene Cooperman, Jason Ansel, Xiaoqin Ma:
Transparent Adaptive Library-Based Checkpointing for Master-Worker Style Parallelism. CCGRID 2006: 283-291 - [c36]Daniel Kunkle, Donghui Zhang, Gene Cooperman:
Efficient mining of max frequent patterns in a generalized environment. CIKM 2006: 810-811 - [c35]Eric Robinson, Gene Cooperman:
A parallel architecture for disk-based computing over the Baby Monster and other large finite simple groups. ISSAC 2006: 298-305 - [c34]Gene Cooperman, Viet Ha Nguyen, Igor Malioutov:
Parallelization of Geant4 Using TOP-C and Marshalgen. NCA 2006: 48-55 - [c33]Michael Rieker, Jason Ansel, Gene Cooperman:
Transparent User-Level Checkpointing for the Native Posix Thread Library for Linux. PDPTA 2006: 492-498 - 2005
- [c32]Gene Cooperman, Jason Ansel, Xiaoqin Ma:
Adaptive Checkpointing for Master-Worker Style Parallelism. CLUSTER 2005: 1-2 - [c31]Xiaoqin Ma, Gene Cooperman:
Fast Query Processing by Distributing an Index over CPU Caches. CLUSTER 2005: 1-10 - [c30]Panfeng Zhou, Donghui Zhang, Betty Salzberg, Gene Cooperman, George Kollios
Close pair queries in moving object databases. GIS 2005: 2-11 - 2004
- [j11]Gene Cooperman:
The TOP-C parallel model and symbolic algebra. SIGSAM Bull. 38(1): 16-17 (2004) - [c29]Gene Cooperman, Viet Ha Nguyen:
Marshalgen: Marshaling Objects in the Presence of Polymorphism. International Conference on Internet Computing 2004: 17-23 - [c28]Gene Cooperman, Xiaoqin Ma, Viet Ha Nguyen:
Static Performance Evaluation for Memory-Bound Computing: The MBRAM Model. PDPTA 2004: 435-441 - [i2]Xiaoqin Ma, Gene Cooperman:
Fast Query Processing Using Cooperative CPU Caching for Index Structures. CoRR cs.DC/0410066 (2004) - 2003
- [j10]Gene Cooperman, Henri Casanova, Jim Hayes, Thomas Witzel:
Using TOP-C and AMPIC to port large parallel applications to the Computational Grid. Future Gener. Comput. Syst. 19(4): 587-596 (2003) - [c27]Gene Cooperman, Ning Ke, Huanmei Wu:
Marshalgen: A Package for Semi-Automatic Marshaling of Objects. International Conference on Internet Computing 2003: 555-560 - [c26]Gene Cooperman, Eric Robinson:
Memory-based and disk-based algorithms for very high degree permutation groups. ISSAC 2003: 66-73 - [i1]Gene Cooperman, Xiaoqin Ma, Viet Ha Nguyen:
DPG: A Cache-Efficient Accelerator for Sorting and for Join Operators. CoRR cs.DB/0308004 (2003) - 2002
- [j9]Gene Cooperman, Xiaoqin Ma:
Overcoming the memory wall in symbolic algebra: a faster permutation multiplication. SIGSAM Bull. 36(4): 1-4 (2002) - [j8]Gene Cooperman, Victor Grinberg:
Scalable Parallel Coset Enumeration: Bulk Definition and the Memory Wall. J. Symb. Comput. 33(5): 563-585 (2002) - [c25]Gene Cooperman, Henri Casanova, Jim Hayes, Thomas Witzel:
Using TOP-C and AMPIC to Port Large Parallel Applications to the Computational Grid. CCGRID 2002: 120-127 - 2001
- [c24]Gene Cooperman, Victor Grinberg:
Scalable parallel coset enumeration using bulk definition. ISSAC 2001: 77-84
1990 – 1999
- 1999
- [c23]Gene Cooperman, Sandra Feisel, Joachim von zur Gathen, George Havas:
GCD of Many Integers. COCOON 1999: 310-317 - [e1]Gene Cooperman, Eike Jessen, Gerhard O. Michler:
Workshop on Wide Area Networks and High Performance Computing, September 1-5, 1998, Essen, Germany. Lecture Notes in Control and Information Sciences 249, Springer 1999, ISBN 1-85233-642-0 [contents] - 1998
- [c22]Gene Cooperman, Eike Jessen, Gerhard O. Michler:
Introduction: Distributed High Performance Computing and Gigabit Wide Area Networks. Wide Area Networks and High Performance Computing 1998: 1-4 - [c21]Gene Cooperman:
TOP-C: Task-Oriented Parallel C for Distributed and Shared Memory. Wide Area Networks and High Performance Computing 1998: 109-117 - 1997
- [j7]Gene Cooperman:
Abstracts of the 4th East Coast Computer Algebra Day, Northeastern University, Boston, MA, May 3, 1997. SIGSAM Bull. 31(4): 54-59 (1997) - [j6]Gene Cooperman, Gerhard Hiss, Klaus Lux, Jürgen Müller:
The Brauer Tree of the Principal 19-Block of the Sporadic Simple Thompson Group. Exp. Math. 6(4): 293-300 (1997) - [j5]Gene Cooperman, Larry Finkelstein, Michael Tselman, Bryant W. York:
Constructing Permutation Representations for Matrix Groups. J. Symb. Comput. 24(3/4): 471-488 (1997) - [c20]Gene Cooperman, George Havas:
Elementary algebra revisited: Randomized algorithms. Randomization Methods in Algorithm Design 1997: 37-44 - [c19]Gene Cooperman, Michael Tselman:
Using Tadpoles to Reduce Memory and Communication Requirements for Exhaustive, Breadth-First Search Using Distributed Computers. SPAA 1997: 231-238 - 1996
- [c18]Gene Cooperman:
TOP-C: A Task-Oriented Parallel C Interface. HPDC 1996: 141-150 - [c17]Gene Cooperman, Michael Tselman:
New Sequential and Parallel Algorithms for Generating High Dimension Hecke Algebras Using the Condensation Technique. ISSAC 1996: 155-160 - 1995
- [j4]László Babai
Fast Monte Carlo Algorithms for Permutation Groups. J. Comput. Syst. Sci. 50(2): 296-308 (1995) - [c16]Gene Cooperman:
GAP/MPI: Facilitating parallelism. Groups and Computation 1995: 69-83 - [c15]Gene Cooperman, Larry Finkelstein, Steve Linton:
Constructive recognition of a black box group isomorphic to GL(n,2). Groups and Computation 1995: 85-100 - [c14]Gene Cooperman:
STAR/MPI: Binding a Parallel Library to Interactive Symbolic Algebra Systems. ISSAC 1995: 126-132 - [c13]Gene Cooperman, Larry Finkelstein, Michael Tselman:
Computing with Matrix Groups Using Permutation Representations. ISSAC 1995: 259-264 - 1994
- [j3]Gene Cooperman, Larry Finkelstein:
A Random Base Change Algorithm for Permutation Groups. J. Symb. Comput. 17(6): 513-528 (1994) - [c12]Gene Cooperman, Larry Finkelstein:
Permutation routing via Cayley graphs with an example for bus interconnection networks. Interconnection Networks and Mapping and Scheduling Parallel Computations 1994: 47-56 - [c11]Gene Cooperman, Larry Finkelstein, Bryant W. York, Michael Tselman:
Constructing Permutation Representations for Large Matrix Groups. ISSAC 1994: 134-138 - 1992
- [j2]Gene Cooperman, Larry Finkelstein:
New Methods for Using Cayley Graphs in Interconnection Networks. Discret. Appl. Math. 37/38: 95-118 (1992) - [c10]Gene Cooperman, Larry Finkelstein:
A Fast Cyclic Base Change for Permutation Groups. ISSAC 1992: 224-232 - 1991
- [j1]Gene Cooperman, Larry Finkelstein:
A Strong Generating Test and Short Presentation for Permutation Groups. J. Symb. Comput. 12(4/5): 475-498 (1991) - [c9]Gene Cooperman, Larry Finkelstein:
Combinatorial Tools for Computational Group Theory. Groups And Computation 1991: 53-86 - [c8]László Babai
Nearly Linear Time Algorithms for Permutation Groups with a Small Base. ISSAC 1991: 200-209 - [c7]László Babai
Fast Monte Carlo Algorithms for Permutation Groups. STOC 1991: 90-100 - 1990
- [c6]Gene Cooperman, Larry Finkelstein, N. Sarawagi:
Applications of Cayley Graphs. AAECC 1990: 367-378 - [c5]Gene Cooperman, Larry Finkelstein, N. Sarawagi:
A Random Base Change Algorithm for Permutation Groups. ISSAC 1990: 161-168
1980 – 1989
- 1989
- [c4]Gene Cooperman, Larry Finkelstein, Paul Walton Purdom Jr.:
Fast Group Membership Using a Strong Generating Test for Permutation Groups. Computers and Mathematics 1989: 27-36 - [c3]Gene Cooperman, Larry Finkelstein, Eugene M. Luks:
Reduction of Group Constructions to Point Stabilizers. ISSAC 1989: 351-356 - 1988
- [c2]Cynthia A. Brown, Gene Cooperman, Larry Finkelstein:
Solving Permutation Problems Using Rewriting Systems. ISSAC 1988: 364-377 - 1986
- [c1]Gene Cooperman:
A semantic matcher for computer algebra. SYMSAC 1986: 132-134
Coauthor Index
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