52,600 research outputs found
Garbage collection auto-tuning for Java MapReduce on Multi-Cores
MapReduce has been widely accepted as a simple programming pattern that can form the basis for efficient, large-scale, distributed data processing. The success of the MapReduce pattern has led to a variety of implementations for different computational scenarios. In this paper we present MRJ, a MapReduce Java framework for multi-core architectures. We evaluate its scalability on a four-core, hyperthreaded Intel Core i7 processor, using a set of standard MapReduce benchmarks. We investigate the significant impact that Java runtime garbage collection has on the performance and scalability of MRJ. We propose the use of memory management auto-tuning techniques based on machine learning. With our auto-tuning approach, we are able to achieve MRJ performance within 10% of optimal on 75% of our benchmark tests
Algon: a framework for supporting comparison of distributed algorithm performance
Programmers often need to use distributed algorithms to add non-functional behaviour such as mutual exclusion, deadlock detection and termination, to a distributed application. They find the selection and implementation of these algorithms daunting. Consequently, they have no idea which algorithm will be best for their particular application. To address this difficulty the Algon framework provides a set of pre-coded distributed algorithms for programmers to choose from, and provides a special performance display tool to support choice between algorithms. The performance tool is discussed. The developer of a distributed application will be able to observe the performance of each of the available algorithms according to a set of of widely accepted and easily-understandable performance metrics and compare and contrast the behaviour of the algorithms to support an informed choice. The strength of the Algon framework is that it does not require a working knowledge of algorithmic theory or functionality in order for the developer to use the algorithms
PlinyCompute: A Platform for High-Performance, Distributed, Data-Intensive Tool Development
This paper describes PlinyCompute, a system for development of
high-performance, data-intensive, distributed computing tools and libraries. In
the large, PlinyCompute presents the programmer with a very high-level,
declarative interface, relying on automatic, relational-database style
optimization to figure out how to stage distributed computations. However, in
the small, PlinyCompute presents the capable systems programmer with a
persistent object data model and API (the "PC object model") and associated
memory management system that has been designed from the ground-up for high
performance, distributed, data-intensive computing. This contrasts with most
other Big Data systems, which are constructed on top of the Java Virtual
Machine (JVM), and hence must at least partially cede performance-critical
concerns such as memory management (including layout and de/allocation) and
virtual method/function dispatch to the JVM. This hybrid approach---declarative
in the large, trusting the programmer's ability to utilize PC object model
efficiently in the small---results in a system that is ideal for the
development of reusable, data-intensive tools and libraries. Through extensive
benchmarking, we show that implementing complex objects manipulation and
non-trivial, library-style computations on top of PlinyCompute can result in a
speedup of 2x to more than 50x or more compared to equivalent implementations
on Spark.Comment: 48 pages, including references and Appendi
Towards co-designed optimizations in parallel frameworks: A MapReduce case study
The explosion of Big Data was followed by the proliferation of numerous
complex parallel software stacks whose aim is to tackle the challenges of data
deluge. A drawback of a such multi-layered hierarchical deployment is the
inability to maintain and delegate vital semantic information between layers in
the stack. Software abstractions increase the semantic distance between an
application and its generated code. However, parallel software frameworks
contain inherent semantic information that general purpose compilers are not
designed to exploit.
This paper presents a case study demonstrating how the specific semantic
information of the MapReduce paradigm can be exploited on multicore
architectures. MR4J has been implemented in Java and evaluated against
hand-optimized C and C++ equivalents. The initial observed results led to the
design of a semantically aware optimizer that runs automatically without
requiring modification to application code.
The optimizer is able to speedup the execution time of MR4J by up to 2.0x.
The introduced optimization not only improves the performance of the generated
code, during the map phase, but also reduces the pressure on the garbage
collector. This demonstrates how semantic information can be harnessed without
sacrificing sound software engineering practices when using parallel software
frameworks.Comment: 8 page
PyCUDA and PyOpenCL: A Scripting-Based Approach to GPU Run-Time Code Generation
High-performance computing has recently seen a surge of interest in
heterogeneous systems, with an emphasis on modern Graphics Processing Units
(GPUs). These devices offer tremendous potential for performance and efficiency
in important large-scale applications of computational science. However,
exploiting this potential can be challenging, as one must adapt to the
specialized and rapidly evolving computing environment currently exhibited by
GPUs. One way of addressing this challenge is to embrace better techniques and
develop tools tailored to their needs. This article presents one simple
technique, GPU run-time code generation (RTCG), along with PyCUDA and PyOpenCL,
two open-source toolkits that support this technique.
In introducing PyCUDA and PyOpenCL, this article proposes the combination of
a dynamic, high-level scripting language with the massive performance of a GPU
as a compelling two-tiered computing platform, potentially offering significant
performance and productivity advantages over conventional single-tier, static
systems. The concept of RTCG is simple and easily implemented using existing,
robust infrastructure. Nonetheless it is powerful enough to support (and
encourage) the creation of custom application-specific tools by its users. The
premise of the paper is illustrated by a wide range of examples where the
technique has been applied with considerable success.Comment: Submitted to Parallel Computing, Elsevie
Simplified Distributed Programming with Micro Objects
Developing large-scale distributed applications can be a daunting task.
object-based environments have attempted to alleviate problems by providing
distributed objects that look like local objects. We advocate that this
approach has actually only made matters worse, as the developer needs to be
aware of many intricate internal details in order to adequately handle partial
failures. The result is an increase of application complexity. We present an
alternative in which distribution transparency is lessened in favor of clearer
semantics. In particular, we argue that a developer should always be offered
the unambiguous semantics of local objects, and that distribution comes from
copying those objects to where they are needed. We claim that it is often
sufficient to provide only small, immutable objects, along with facilities to
group objects into clusters.Comment: In Proceedings FOCLASA 2010, arXiv:1007.499
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