46,887 research outputs found
Improving the Energy Efficiency of Software Systems for Multi-Core Architectures
International audienceThe ICT has an huge impact on the world CO2 emissions and recent study estimates its account to 2% of these emissions. This growing account emissions makes IT energy efficiency an important challenge. State-of-the-art has proven that the processor is the main power consumer. Processor are nowadays more and more complex and they are used in many hardware systems, such as computers or smart-phones. This thesis is thus focusing on the software energy efficiency for multi-core systems. In this paper, we therefore report our motivations to understand deeply their architectures for improving their energy efficiencies. Manufacturers have worked tremendously to improve performance and reduce power consumption of their processors. However a lot of things remains to do in the software side. We claim that energy-efficient softwares can play a deterministic role to reduce the IT carbon footprint. To answer this challenge, we are believing on the software-metric approach with a minimal hardware investment. For this purpose, an efficient, scalable and non-invasive tool is needed. As a result, we created PowerAPI, to provide fine-grained power estimations at process and code-level for optimizing the software energy efficiency automatically. This solution will help to identify clearly the energy leaks for optimizing automatically the power consumed by software
Investigation into scalable energy and performance models for many-core systems
PhD ThesisIt is likely that many-core processor systems will continue to penetrate
emerging embedded and high-performance applications. Scalable energy and
performance models are two critical aspects that provide insights into the
conflicting trade-offs between them with growing hardware and software
complexity. Traditional performance models, such as Amdahl’s Law,
Gustafson’s and Sun-Ni’s, have helped the research community and industry
to better understand the system performance bounds with given processing
resources, which is otherwise known as speedup. However, these models and
their existing extensions have limited applicability for energy and/or
performance-driven system optimization in practical systems. For instance,
these are typically based on software characteristics, assuming ideal and
homogeneous hardware platforms or limited forms of processor
heterogeneity. In addition, the measurement of speedup and parallelization
factors of an application running on a specific hardware platform require
instrumenting the original software codes. Indeed, practical speedup and
parallelizability models of application workloads running on modern
heterogeneous hardware are critical for energy and performance models, as
they can be used to inform design and control decisions with an aim to
improve system throughput and energy efficiency.
This thesis addresses the limitations by firstly developing novel and
scalable speedup and energy consumption models based on a more general
representation of heterogeneity, referred to as the normal form heterogeneity.
A method is developed whereby standard performance counters found in
modern many-core platforms can be used to derive speedup, and therefore
the parallelizability of the software, without instrumenting applications. This
extends the usability of the new models to scenarios where the
parallelizability of software is unknown, leading to potentially Run-Time
Management (RTM) speedup and/or energy efficiency optimization. The
models and optimization methods presented in this thesis are validated
through extensive experimentation, by running a number of different
applications in wide-ranging concurrency scenarios on a number of different
homogeneous and heterogeneous Multi/Many Core Processor (M/MCP)
systems. These include homogeneous and heterogeneous architectures and
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range from existing off-the-shelf platforms to potential future system
extensions. The practical use of these models and methods is demonstrated
through real examples such as studying the effectiveness of the system load
balancer.
The models and methodologies proposed in this thesis provide guidance to
a new opportunities for improving the energy efficiency of M/MCP systemsHigher Committee of Education Development
(HCED) in Ira
A Survey of Techniques For Improving Energy Efficiency in Embedded Computing Systems
Recent technological advances have greatly improved the performance and
features of embedded systems. With the number of just mobile devices now
reaching nearly equal to the population of earth, embedded systems have truly
become ubiquitous. These trends, however, have also made the task of managing
their power consumption extremely challenging. In recent years, several
techniques have been proposed to address this issue. In this paper, we survey
the techniques for managing power consumption of embedded systems. We discuss
the need of power management and provide a classification of the techniques on
several important parameters to highlight their similarities and differences.
This paper is intended to help the researchers and application-developers in
gaining insights into the working of power management techniques and designing
even more efficient high-performance embedded systems of tomorrow
Energy challenges for ICT
The energy consumption from the expanding use of information and communications technology (ICT) is unsustainable with present drivers, and it will impact heavily on the future climate change. However, ICT devices have the potential to contribute signi - cantly to the reduction of CO2 emission and enhance resource e ciency in other sectors, e.g., transportation (through intelligent transportation and advanced driver assistance systems and self-driving vehicles), heating (through smart building control), and manu- facturing (through digital automation based on smart autonomous sensors). To address the energy sustainability of ICT and capture the full potential of ICT in resource e - ciency, a multidisciplinary ICT-energy community needs to be brought together cover- ing devices, microarchitectures, ultra large-scale integration (ULSI), high-performance computing (HPC), energy harvesting, energy storage, system design, embedded sys- tems, e cient electronics, static analysis, and computation. In this chapter, we introduce challenges and opportunities in this emerging eld and a common framework to strive towards energy-sustainable ICT
Fairness-aware scheduling on single-ISA heterogeneous multi-cores
Single-ISA heterogeneous multi-cores consisting of small (e.g., in-order) and big (e.g., out-of-order) cores dramatically improve energy- and power-efficiency by scheduling workloads on the most appropriate core type. A significant body of recent work has focused on improving system throughput through scheduling. However, none of the prior work has looked into fairness. Yet, guaranteeing that all threads make equal progress on heterogeneous multi-cores is of utmost importance for both multi-threaded and multi-program workloads to improve performance and quality-of-service. Furthermore, modern operating systems affinitize workloads to cores (pinned scheduling) which dramatically affects fairness on heterogeneous multi-cores. In this paper, we propose fairness-aware scheduling for single-ISA heterogeneous multi-cores, and explore two flavors for doing so. Equal-time scheduling runs each thread or workload on each core type for an equal fraction of the time, whereas equal-progress scheduling strives at getting equal amounts of work done on each core type. Our experimental results demonstrate an average 14% (and up to 25%) performance improvement over pinned scheduling through fairness-aware scheduling for homogeneous multi-threaded workloads; equal-progress scheduling improves performance by 32% on average for heterogeneous multi-threaded workloads. Further, we report dramatic improvements in fairness over prior scheduling proposals for multi-program workloads, while achieving system throughput comparable to throughput-optimized scheduling, and an average 21% improvement in throughput over pinned scheduling
Power aware early design stage hardware software co-optimization
Co-optimizing hardware and software can lead to substantial performance and energy benefits, and is becoming an increasingly important design paradigm. In scientific computing, power constraints increasingly necessitate the return to specialized chips such as Intel’s MIC or IBM’s Blue-Gene architectures. To enable hardware/software co-design in early stages of the design cycle, we propose a simulation infrastructure methodology by combining high-abstraction performance simulation using Sniper with power modeling using McPAT and custom DRAM power models. Sniper/McPAT is fast — simulation speed is around 2 MIPS on an 8-core host machine — because it uses analytical modeling to abstract away core performance during multi-core simulation. We demonstrate Sniper/McPAT’s accuracy through validation against real hardware; we report average performance and power prediction errors of 22.1% and 8.3%, respectively, for a set of SPEComp benchmarks
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