2,447 research outputs found
Adaptive Transactional Memories: Performance and Energy Consumption Tradeoffs
Energy efficiency is becoming a pressing issue, especially in large data centers where it entails, at the same time, a non-negligible management cost, an enhancement of hardware fault probability, and a significant environmental footprint. In this paper, we study how Software Transactional Memories (STM) can provide benefits on both power saving and the overall applications’ execution performance. This is related to the fact that encapsulating shared-data accesses within transactions gives the freedom to the STM middleware to both ensure consistency and reduce the actual data contention, the latter having been shown to affect the overall power needed to complete the application’s execution.
We have selected a set of self-adaptive extensions to existing STM middlewares (namely, TinySTM and R-STM) to prove how self-adapting computation can capture the actual degree of parallelism and/or logical contention on shared data in a better way, enhancing even more the intrinsic benefits provided by STM. Of course, this benefit comes at a cost, which is the actual execution time required by the proposed approaches to precisely tune the execution parameters for reducing power consumption and enhancing execution performance. Nevertheless, the results hereby provided show that adaptivity is a strictly necessary requirement to reduce energy consumption in STM systems: Without it, it is not possible to reach any acceptable level of energy efficiency at all
A fuzzy logic based dynamic reconfiguration scheme for optimal energy and throughput in symmetric chip multiprocessors
Embedded systems architectures have traditionally often been investigated and designed in order to achieve a greater throughput combined with minimum energy consumption. With the advent of reconfigurable architectures it is now possible to support algorithms to find optimal solutions for an improved energy and throughput balance. As a result of ongoing research several online and offline techniques and algorithm have been proposed for hardware adaptation. This paper presents a novel coarse-grained reconfigurable symmetric chip multiprocessor (SCMP) architecture managed by a fuzzy logic engine that balances performance and energy consumption. The architecture incorporates reconfigurable level 1 (L1) caches, power gated cores and adaptive on-chip network routers to allow minimizing leakage energy effects for inactive components. A coarse grained architecture was selected as to be a focus for this study as it typically allows for fast reconfiguration as compared to the fine-grained architectures, thus making it more feasible to be used for runtime adaption schemes. The presented architecture is analyzed using a set of OpenMP based parallel benchmarks and the results show significant improvements in performance while maintaining minimum energy consumption
Elastic-PPQ: A two-level autonomic system for spatial preference query processing over dynamic data streams
Paradigms like Internet of Things and the most recent Internet of Everything are shifting the attention towards systems able to process unbounded sequences of items in the form of data streams. In the real world, data streams may be highly variable, exhibiting burstiness in the arrival rate and non-stationarities such as trends and cyclic behaviors. Furthermore, input items may be not ordered according to timestamps. This raises the complexity of stream processing systems, which must support elastic resource management and autonomic QoS control through sophisticated strategies and run-time mechanisms. In this paper we present Elastic-PPQ, a system for processing spatial preference queries over dynamic data streams. The key aspect of the system design is the existence of two adaptation levels handling workload variations at different time-scales. To address fast time-scale variations we design a fine regulatory mechanism of load balancing supported by a control-theoretic approach. The logic of the second adaptation level, targeting slower time-scale variations, is incorporated in a Fuzzy Logic Controller that makes scale in/out decisions of the system parallelism degree. The approach has been successfully evaluated under synthetic and real-world datasets
Elastic Business Process Management: State of the Art and Open Challenges for BPM in the Cloud
With the advent of cloud computing, organizations are nowadays able to react
rapidly to changing demands for computational resources. Not only individual
applications can be hosted on virtual cloud infrastructures, but also complete
business processes. This allows the realization of so-called elastic processes,
i.e., processes which are carried out using elastic cloud resources. Despite
the manifold benefits of elastic processes, there is still a lack of solutions
supporting them.
In this paper, we identify the state of the art of elastic Business Process
Management with a focus on infrastructural challenges. We conceptualize an
architecture for an elastic Business Process Management System and discuss
existing work on scheduling, resource allocation, monitoring, decentralized
coordination, and state management for elastic processes. Furthermore, we
present two representative elastic Business Process Management Systems which
are intended to counter these challenges. Based on our findings, we identify
open issues and outline possible research directions for the realization of
elastic processes and elastic Business Process Management.Comment: Please cite as: S. Schulte, C. Janiesch, S. Venugopal, I. Weber, and
P. Hoenisch (2015). Elastic Business Process Management: State of the Art and
Open Challenges for BPM in the Cloud. Future Generation Computer Systems,
Volume NN, Number N, NN-NN., http://dx.doi.org/10.1016/j.future.2014.09.00
Defuzzification Method for NP-Hard Problem in Cloud
The cloud computing is that the one that deals with the commerce of the resources with efficiency in accordance to the user’s would like. Employment programming is that the selection of a perfect resource for any job to be dead with reference to waiting time, value or turnaround. A cloud job programming are associate NP-hard downside that contains n jobs and m machines every} job is processed with each of those m machines to reduce the makespan. the safety here is one among the highest most considerations within the cloud. so as to calculate the worth of fitness the fuzzy abstract thought system makes use of the membership operate for crucial the degree up to that the input parameters that belong to each fuzzy set has relevancy. Here the fuzzy is employed for the aim of programming energy similarly as security within the cloud computing
Simultaneous structuring and scheduling of multiple projects with flexible project structures
We study the problem to simultaneously decide on the structures and the schedules for an entire portfolio of flexible projects. The projects are flexible as alternative technologies and procedures can be used to achieve the respective project task. The choice between different technologies and procedures affects the activities to be implemented and thus the precedence relations, i.e., the structure of the project. The different projects have given due dates with specific delay payments and compete for scarce resources. In this situation, project structure decisions and scheduling decisions are highly intertwined and have to be made simultaneously in order to achieve the assumed objective of minimizing the delay payments for the entire project portfolio. The problem is formally stated and solved via novel and problem-specific genetic algorithms. The performance of the new algorithms is evaluated with respect to speed and accuracy in a systematic and comprehensive numerical study. © 2020, The Author(s)
A Survey of Phase Classification Techniques for Characterizing Variable Application Behavior
Adaptable computing is an increasingly important paradigm that specializes
system resources to variable application requirements, environmental
conditions, or user requirements. Adapting computing resources to variable
application requirements (or application phases) is otherwise known as
phase-based optimization. Phase-based optimization takes advantage of
application phases, or execution intervals of an application, that behave
similarly, to enable effective and beneficial adaptability. In order for
phase-based optimization to be effective, the phases must first be classified
to determine when application phases begin and end, and ensure that system
resources are accurately specialized. In this paper, we present a survey of
phase classification techniques that have been proposed to exploit the
advantages of adaptable computing through phase-based optimization. We focus on
recent techniques and classify these techniques with respect to several factors
in order to highlight their similarities and differences. We divide the
techniques by their major defining characteristics---online/offline and
serial/parallel. In addition, we discuss other characteristics such as
prediction and detection techniques, the characteristics used for prediction,
interval type, etc. We also identify gaps in the state-of-the-art and discuss
future research directions to enable and fully exploit the benefits of
adaptable computing.Comment: To appear in IEEE Transactions on Parallel and Distributed Systems
(TPDS
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