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Paper detail

QGTC: Accelerating Quantized Graph Neural Networks via GPU Tensor Core

Over the most recent years, quantized graph neural network (QGNN) attracts lots of research and industry attention due to its high robustness and low computation and memory overhead. Unfortunately, the performance gains of QGNN have never been realized on modern GPU platforms. To this end, we propose the first Tensor Core (TC) based computing framework, QGTC, to support any-bitwidth computation for QGNNs on GPUs. We introduce a novel quantized low-bit arithmetic design based on the low-bit data representation and bit-decomposed computation. We craft a novel TC-tailored CUDA kernel design by incorporating 3D-stacked bit compression, zero-tile jumping, and non-zero tile reuse technique to improve the performance systematically. We incorporate an effective bandwidth-optimized subgraph packing strategy to maximize the transferring efficiency between CPU host and GPU device. We integrate QGTC with Pytorch for better programmability and extensibility. Extensive experiments demonstrate that QGTC achieves on average 2.7x speedup compared with the state-of-the-art Deep Graph Library framework across diverse settings.

preprint2021arXivOpen access
Yuke WangBoyuan FengYufei Ding
Distributed, Parallel, and Cluster Computing
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Yuke WangBoyuan FengYufei Ding

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