DocumentCode
3543413
Title
FT-GReLoSSS: A Skeletal-Based Approach towards Application Parallelization and Low-Overhead Fault Tolerance
Author
Makassikis, Constantinos ; Vialle, Stéphane ; Warin, Xavier
Author_Institution
AlGorille INRIA Project Team, Univ. Henri Poincare, France
fYear
2012
fDate
15-17 Feb. 2012
Firstpage
237
Lastpage
244
Abstract
FT-GReLoSSS (FTG) is a C++/MPI framework to ease the development of fault-tolerant parallel applications belonging to a SPMD family termed GReLoSSS. The originality of FTG is to rely on the MoLOToF programming model principles to facilitate the addition of an efficient checkpoint-based fault tolerance at the application level. Main features of MoLOToF encompass a structured application development based on fault-tolerant "skeletons" and lay emphasis on collaborations. The latter exist between the programmer, the framework and the underlying runtime middleware/environment. Together with the structured approach they contribute into achieving reduced checkpoint sizes, as well as reduced checkpoint and recovery overhead at runtime. This paper introduces the main principles of MoLOToF and the design of the FTG framework. To properly assess the framework\´s ease of use for a programmer as well as fault tolerance efficiency, a series of benchmarks were conducted up to 128 nodes on a multicore PC cluster. These benchmarks involved an existing parallel financial application for gas storage valuation, originally developed in collaboration with EDF company, and a rewritten version which made use of the FTG framework and its features. Experiments results display low-overhead compared to existing system-level counterparts.
Keywords
C++ language; checkpointing; fault tolerant computing; financial data processing; message passing; middleware; parallel programming; C++-MPI framework; FT-GReLoSSS; MoLOToF programming model; SPMD family; application parallelization; checkpoint-based fault tolerance; fault-tolerant parallel application; fault-tolerant skeletons; gas storage valuation; low-overhead fault tolerance; multicore PC cluster; parallel financial application; recovery overhead; runtime middleware-environment; skeletal-based approach; Arrays; Computational modeling; Fault tolerance; Fault tolerant systems; Programming; Routing; Skeleton; SPMD paradigm; application-level check-pointing; distributed fault tolerance; framework; skeletons;
fLanguage
English
Publisher
ieee
Conference_Titel
Parallel, Distributed and Network-Based Processing (PDP), 2012 20th Euromicro International Conference on
Conference_Location
Garching
ISSN
1066-6192
Print_ISBN
978-1-4673-0226-5
Type
conf
DOI
10.1109/PDP.2012.18
Filename
6169555
Link To Document