IF 3.1 4区 计算机科学 Q2 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE ACM Transactions on Reconfigurable Technology and Systems Pub Date : 2023-06-05 DOI:10.1145/3603504
Aman Arora, Atharva Bhamburkar, Aatman Borda, T. Anand, Rishabh Sehgal, Bagus Hanindhito, P. Gaillardon, J. Kulkarni, L. John
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引用次数: 0

摘要

块随机存取存储器(bram)是fpga的存储单元,为使用逻辑块和数字信号处理片实现的计算单元提供广泛的片上存储器带宽。我们建议修改bram,将其转换为CoMeFa (fpga的内存计算块)随机存取存储器(ram)。这些ram通过在一个块中结合计算和存储能力来提供高度并行的内存计算。CoMeFa ram利用FPGA bram的真正双端口特性,并包含多个可配置的单比特串行处理元件。CoMeFa ram可以用于任何精度的计算,这对于深度学习(DL)等应用非常重要。将CoMeFa ram添加到fpga中可以显著提高其计算密度,同时减少数据移动。我们探索并提出了两种ram架构:comfa - d(针对延迟进行优化)和comfa - a(针对面积进行优化)。与现有的建议相比,CoMeFa RAM不需要改变底层静态RAM技术,如在同一端口上同时激活多个字行,并且可以实现。CoMeFa ram特别适用于并行和计算密集型应用,如DL,但这些通用模块可以在信号处理和数据库等各种应用中找到应用。通过以3.8%(1.2%)的面积为成本,在Intel Arria 10类FPGA上增加CoMeFa-D (CoMeFa-A) ram,并通过算法改进和高效映射,我们观察到在各种应用的微基准测试中,几何加速提高了2.55倍(1.85倍),在多个深度神经网络中,几何加速提高了2.5倍。用fpga中的CoMeFa ram替换全部或部分bram可以使它们更好地加速DL工作负载。
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CoMeFa: Deploying Compute-in-Memory on FPGAs for Deep Learning Acceleration
Block random access memories (BRAMs) are the storage houses of FPGAs, providing extensive on-chip memory bandwidth to the compute units implemented using logic blocks and digital signal processing slices. We propose modifying BRAMs to convert them to CoMeFa (Compute-in-Memory Blocks for FPGAs) random access memories (RAMs). These RAMs provide highly parallel compute-in-memory by combining computation and storage capabilities in one block. CoMeFa RAMs utilize the true dual-port nature of FPGA BRAMs and contain multiple configurable single-bit bit-serial processing elements. CoMeFa RAMs can be used to compute with any precision, which is extremely important for applications like deep learning (DL). Adding CoMeFa RAMs to FPGAs significantly increases their compute density while also reducing data movement. We explore and propose two architectures of these RAMs: CoMeFa-D (optimized for delay) and CoMeFa-A (optimized for area). Compared to existing proposals, CoMeFa RAMs do not require changing the underlying static RAM technology like simultaneously activating multiple wordlines on the same port, and are practical to implement. CoMeFa RAMs are especially suitable for parallel and compute-intensive applications like DL, but these versatile blocks find applications in diverse applications like signal processing and databases, among others. By augmenting an Intel Arria 10–like FPGA with CoMeFa-D (CoMeFa-A) RAMs at the cost of 3.8% (1.2%) area, and with algorithmic improvements and efficient mapping, we observe a geomean speedup of 2.55× (1.85×) across microbenchmarks from various applications and a geomean speedup of up to 2.5× across multiple deep neural networks. Replacing all or some BRAMs with CoMeFa RAMs in FPGAs can make them better accelerators of DL workloads.
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来源期刊
ACM Transactions on Reconfigurable Technology and Systems
ACM Transactions on Reconfigurable Technology and Systems COMPUTER SCIENCE, HARDWARE & ARCHITECTURE-
CiteScore
4.90
自引率
8.70%
发文量
79
审稿时长
>12 weeks
期刊介绍: TRETS is the top journal focusing on research in, on, and with reconfigurable systems and on their underlying technology. The scope, rationale, and coverage by other journals are often limited to particular aspects of reconfigurable technology or reconfigurable systems. TRETS is a journal that covers reconfigurability in its own right. Topics that would be appropriate for TRETS would include all levels of reconfigurable system abstractions and all aspects of reconfigurable technology including platforms, programming environments and application successes that support these systems for computing or other applications. -The board and systems architectures of a reconfigurable platform. -Programming environments of reconfigurable systems, especially those designed for use with reconfigurable systems that will lead to increased programmer productivity. -Languages and compilers for reconfigurable systems. -Logic synthesis and related tools, as they relate to reconfigurable systems. -Applications on which success can be demonstrated. The underlying technology from which reconfigurable systems are developed. (Currently this technology is that of FPGAs, but research on the nature and use of follow-on technologies is appropriate for TRETS.) In considering whether a paper is suitable for TRETS, the foremost question should be whether reconfigurability has been essential to success. Topics such as architecture, programming languages, compilers, and environments, logic synthesis, and high performance applications are all suitable if the context is appropriate. For example, an architecture for an embedded application that happens to use FPGAs is not necessarily suitable for TRETS, but an architecture using FPGAs for which the reconfigurability of the FPGAs is an inherent part of the specifications (perhaps due to a need for re-use on multiple applications) would be appropriate for TRETS.
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