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CodeX: Bit-Flexible Encoding for Streaming-based FPGA Acceleration of DNNs

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arxiv 1901.05582 v1 pith:YXELCIEQ submitted 2019-01-17 cs.LG stat.ML

CodeX: Bit-Flexible Encoding for Streaming-based FPGA Acceleration of DNNs

classification cs.LG stat.ML
keywords codexencodingfpganeuralaveragebitwidthcomparedcompiler
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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This paper proposes CodeX, an end-to-end framework that facilitates encoding, bitwidth customization, fine-tuning, and implementation of neural networks on FPGA platforms. CodeX incorporates nonlinear encoding to the computation flow of neural networks to save memory. The encoded features demand significantly lower storage compared to the raw full-precision activation values; therefore, the execution flow of CodeX hardware engine is completely performed within the FPGA using on-chip streaming buffers with no access to the off-chip DRAM. We further propose a fully-automated algorithm inspired by reinforcement learning which determines the customized encoding bitwidth across network layers. CodeX full-stack framework comprises of a compiler which takes a high-level Python description of an arbitrary neural network architecture. The compiler then instantiates the corresponding elements from CodeX Hardware library for FPGA implementation. Proof-of-concept evaluations on MNIST, SVHN, and CIFAR-10 datasets demonstrate an average of 4.65x throughput improvement compared to stand-alone weight encoding. We further compare CodeX with six existing full-precision DNN accelerators on ImageNet, showing an average of 3.6x and 2.54x improvement in throughput and performance-per-watt, respectively.

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