Scheduling on Two Types of Resources: a Survey
BEAUMONT, Olivier
Université de Bordeaux [UB]
High-End Parallel Algorithms for Challenging Numerical Simulations [HiePACS]
Reformulations based algorithms for Combinatorial Optimization [Realopt]
Université de Bordeaux [UB]
High-End Parallel Algorithms for Challenging Numerical Simulations [HiePACS]
Reformulations based algorithms for Combinatorial Optimization [Realopt]
CANON, Louis-Claude
Franche-Comté Électronique Mécanique, Thermique et Optique - Sciences et Technologies (UMR 6174) [FEMTO-ST]
Franche-Comté Électronique Mécanique, Thermique et Optique - Sciences et Technologies (UMR 6174) [FEMTO-ST]
EYRAUD-DUBOIS, Lionel
Université de Bordeaux [UB]
High-End Parallel Algorithms for Challenging Numerical Simulations [HiePACS]
Reformulations based algorithms for Combinatorial Optimization [Realopt]
Voir plus >
Université de Bordeaux [UB]
High-End Parallel Algorithms for Challenging Numerical Simulations [HiePACS]
Reformulations based algorithms for Combinatorial Optimization [Realopt]
BEAUMONT, Olivier
Université de Bordeaux [UB]
High-End Parallel Algorithms for Challenging Numerical Simulations [HiePACS]
Reformulations based algorithms for Combinatorial Optimization [Realopt]
Université de Bordeaux [UB]
High-End Parallel Algorithms for Challenging Numerical Simulations [HiePACS]
Reformulations based algorithms for Combinatorial Optimization [Realopt]
CANON, Louis-Claude
Franche-Comté Électronique Mécanique, Thermique et Optique - Sciences et Technologies (UMR 6174) [FEMTO-ST]
Franche-Comté Électronique Mécanique, Thermique et Optique - Sciences et Technologies (UMR 6174) [FEMTO-ST]
EYRAUD-DUBOIS, Lionel
Université de Bordeaux [UB]
High-End Parallel Algorithms for Challenging Numerical Simulations [HiePACS]
Reformulations based algorithms for Combinatorial Optimization [Realopt]
Université de Bordeaux [UB]
High-End Parallel Algorithms for Challenging Numerical Simulations [HiePACS]
Reformulations based algorithms for Combinatorial Optimization [Realopt]
MARCHAL, Loris
Laboratoire de l'Informatique du Parallélisme [LIP]
Optimisation des ressources : modèles, algorithmes et ordonnancement [ROMA]
Laboratoire de l'Informatique du Parallélisme [LIP]
Optimisation des ressources : modèles, algorithmes et ordonnancement [ROMA]
SIMON, Bertrand
Universität Bremen [Deutschland] = University of Bremen [Germany] = Université de Brême [Allemagne]
< Réduire
Universität Bremen [Deutschland] = University of Bremen [Germany] = Université de Brême [Allemagne]
Langue
en
Article de revue
Ce document a été publié dans
ACM Computing Surveys. 2020-05-01, vol. 53, n° 3
Association for Computing Machinery
Résumé en anglais
We study the problem of executing an application represented by a precedence task graph on a parallel machine composed of standard computing cores and accelerators. Contrary to most existing approaches, we distinguish the ...Lire la suite >
We study the problem of executing an application represented by a precedence task graph on a parallel machine composed of standard computing cores and accelerators. Contrary to most existing approaches, we distinguish the allocation and the scheduling phases and we mainly focus on the allocation part of the problem: choose the most appropriate type of computing unit for each task. We address both off-line and on-line settings and design generic scheduling approaches. In the first case, we establish strong lower bounds on the worst-case performance of a known approach based on Linear Programming for solving the allocation problem. Then, we refine the scheduling phase and we replace the greedy List Scheduling policy used in this approach by a better ordering of the tasks. Although this modification leads to the same approximability guarantees, it performs much better in practice. We also extend this algorithm to more types of computing units, achieving an approximation ratio which depends on the number of different types. In the on-line case, we assume that the tasks arrive in any, not known in advance, order which respects the precedence relations and the scheduler has to take irrevocable decisions about their allocation and execution. In this setting, we propose the first on-line scheduling algorithm which takes into account precedences. Our algorithm is based on adequate rules for selecting the type of processor where to allocate the tasks and it achieves a constant factor approximation guarantee if the ratio of the number of CPUs over the number of GPUs is bounded. Finally, all the previous algorithms for hybrid architectures have been experimented on a large number of simulations built on actual libraries. These simulations assess the good practical behavior of the algorithms with respect to the state-of-the-art solutions, whenever these exist, or baseline algorithms.< Réduire
Project ANR
MIAI @ Grenoble Alpes - ANR-19-P3IA-0003
Origine
Importé de halUnités de recherche