GPU Acceleration for Simulating Massively Parallel Many-Core Platforms

David Atienza Alonso, Luca Benini, Shivani Raghav, Martino Ruggiero
Institute of Electrical and Electronics Engineers, 2015
Journal paper

Abstract

Emerging massively parallel architectures such as a general-purpose processor plus many-core programmable accelerators are creating an increasing demand for novel methods to perform their architectural simulation. Most state-of-the-art simulation technologies are exceedingly slow and the need to model full system many-core architectures adds further to the complexity issues. This paper presents a fast, scalable and parallel simulator, which uses a novel methodology to accelerate the simulation of a many-core coprocessor using GPU platforms. The main idea is to use. The target architecture of the associated. Simulation of many target nodes is mapped to the many hardware-threads available on highly parallel GPU platforms. This paper presents a novel methodology to accelerate the simulation of many-core coprocessors using GPU platforms. We demonstrate the challenges, feasibility and benefits of our idea to use heterogeneous system (CPU and GPU) to simulate future architecture of many-core heterogeneous platforms. The target architecture selected to evaluate our methodology consists of an ARM general purpose CPU coupled with many-core coprocessor with thousands of simple in-order cores connected in a tile network. This work presents optimization techniques used to parallelize the simulation specifically for acceleration on GPUs. We partition the full system simulation between CPU and GPU, where the target general purpose CPU is simulated on the host CPU, whereas the many-core coprocessor is simulated on the NVIDIA Tesla 2070 GPU platform. Our experiments show performance of up to 50 MIPS when simulating the entire heterogeneous chip, and high scalability with increasing cores on coprocessor.

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https://infoscience.epfl.ch/record/208143?ln=en

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David Atienza Alonso, Luca Benini, Shivani Raghav, Martino Ruggiero
Institute of Electrical and Electronics Engineers, 2015
Journal paper

Abstract

Official source

https://infoscience.epfl.ch/record/208143?ln=en

About this result

Related concepts (14)

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Related publications (6)

Related publications

With increasing complexity and performance demands of emerging compute-intensive data-parallel workloads, many-core computing systems are becoming a popular trend in computer design. Fast and scalable simulation methods are needed to make meaningful predictions of design alternatives to prepare early software development and to assess the performance of a system before the real hardware is available. However, simulation technology for large-scale, many-core systems is lagging behind. Most of the existing simulation techniques are slow and complex or have poor scalability and high cost of development, which leads to an unacceptable performance when simulating a large number of cores. New challenges brought by emerging many-core systems demand new methods for simulating these platforms. This thesis investigates the techniques for improving the performance of parallel simulators to model many-core heterogeneous architectures. With the recent advances in programmability and processing power of graphical hardware, General Purpose Graphical Processing Units (GPGPUs) are becoming a popular host platform for solving broad range of computationally expensive problems. The easy availability of low cost, highly parallel GPGPU platforms presents an opportunity for accelerating architectural simulations. In this thesis, I propose and investigate a novel idea of using GPGPUs as a host platform for accelerating simulation of many-core systems. GPGPUs are most suitable for certain specific highly parallel workloads with fine-grained multi-threading and high computational intensity. Architectural simulation, on the other hand, is an extremely complex task with numerous dependencies and rules. To this end, I first determine the feasibility of accelerating various target many-core architectures at different levels of abstraction details, considering the particularities of prevalent GPU architectures and their programming models. Based on this study, I target a heterogeneous architecture of a multi-core CPU connected to many-core coprocessors for GPGPU acceleration. I propose ways to exploit ample parallelism in many-core simulation and present a comprehensive framework to develop an architecture-independent, fast, scalable, easy-to-use, full-system simulator. In particular, I outline some of the challenges faced and insights gained using our proposed approach. I present specific methods and approaches that maximize the throughput of GPU power and memory bandwidth allowing optimized parallelization with minimal synchronization. Our results show high scalability and high speed up in performance for simulating up to eight thousand cores.

EPFL2014

Architecture Exploration and Optimization of Heterogeneous Many-Core Compute and Memory Architectures with Architectural Extensions

Yasir Mahmood Qureshi

The expeditious proliferation of Internet connectivity and the growing adoption of digital products have transformed various spheres of our everyday lives. This increased digitization of society has led to the emergence of new applications, which are deployed all the way from High Performance Computing (HPC) systems and cloud servers to mobile devices. These new emerging applications like video analytics, autonomous driving, natural language processing, content recommendation, bioinformatics, and genome sequencing, have different performance/energy requirements, and are deployed on a variety of different platforms. To meet the performance and Quality-of-Service (QoS)constraints, cloud servers, and HPC platforms are comprised of many-core processors. Even the processors in today's mobile and edge devices are multi-core. To optimize energy efficiency and performance, a system-level simulator is required. This simulator must be capable of simultaneously executing multi-threaded applications in a full-system environment with a complete operating system (OS), on a heterogeneous many-core system.In this thesis, I present gem5-X, a system-level simulation platform to optimize many-core heterogeneous compute and memory architectures. Gem5-X exploration and optimization methodology is also proposed to optimize both the compute and memory sub-system for multi-thread applications. Gem5-X extends gem5 with architectural extensions for the compute and memory sub-systems, including in-caching computing accelerator, clustered heterogeneous cores, in-memory computing engine, and 3D stacked High Bandwidth Memory v2 (HBM2). It also adds support enhancements to gem5, including, Virtual Machine (VM) support, profiling support in the simulator using gperf profiler, enhanced checkpointing, and file sharing between the simulated and the host system. Finally, all the extensions and enhancements are fully supported in Full System (FS)mode of gem5-X, enabling booting and running a full Linux stack on top of the simulator, allowing almost any application running in a Linux system to be executed using gem5-X.To demonstrate the capabilities of gem5-X, various compute-dominated and memory-dominated applications are used as case studies. These state-of-the-art applications include video encoding, video analytics, VMs in the cloud, Binary Neural Networks (BNNs) and Recurrent Neural Networks (RNNs) as compute-intensive workloads. In addition to compute-dominated workloads, memory-dominated applications, including genome sequence alignment based on Next Generation Sequencing (NGS) techniques, and Convolutional Neural Networks (CNNs) are presented as case studies to demonstrate the memory sub-system extensions of gem5-X. Gem5-X exploration methodology is used to optimize architectures for these applications, achieving both performance and energy benefits. All the applications and workloads used in this thesis are case studies to showcase the capabilities of gem5-X. Gem5-X is generic and can be used to optimize and explore architectures for any multi-threaded (or single-threaded) application that can run on a Linux-based OS.

EPFL2021

GPGPU-Accelerated Parallel and Fast Simulation of Thousand-core Platforms

David Atienza Alonso, Luca Benini, Shivani Raghav, Martino Ruggiero

The multicore revolution and the ever-increasing complexity of computing systems is dramatically changing system design, analysis and programming of computing platforms. Future architectures will feature hundreds to thousands of simple processors and on-chip memories connected through a network-on-chip. Architectural simulators will remain primary tools for design space exploration, software development and performance evaluation of these massively parallel architectures. However, architectural simulation performance is a serious concern, as virtual platforms and simulation technology are not able to tackle the complexity of thousands of core future scenarios. The main contribution of this paper is the development of a new simulation approach and technology for many core processors which exploit the enormous parallel processing capability of low-cost and widely available. General Purpose Graphic Processing Units (GPGPU). The simulation of many-core architectures exhibits indeed a high level of parallelism and is inherently parallelizable, but GPGPU acceleration of architectural simulation requires an in-depth revision of the data structures and functional partitioning traditionally used in parallel simulation. We demonstrate our GPGPU simulator on a target architecture composed by several cores (i.e. ARM ISA based), with instruction and data caches, connected through a Network-on-Chip (NoC). Our experiments confirm the feasibility of our approach.

IEEE/ACM Press2011

EPFL2014

Architecture Exploration and Optimization of Heterogeneous Many-Core Compute and Memory Architectures with Architectural Extensions

Yasir Mahmood Qureshi

EPFL2021