Qilin Zheng

Zhixu Du, Shiyu Li, Yuhao Wu et al.

Mixture-of-Experts (MoE) has emerged as a favorable architecture in the era of large models due to its inherent advantage, i.e., enlarging model capacity without incurring notable computational overhead. Yet, the realization of such benefits often results in ineffective GPU memory utilization, as large portions of the model parameters remain dormant during inference. Moreover, the memory demands of large models consistently outpace the memory capacity of contemporary GPUs. Addressing this, we introduce SiDA-MoE ($\textbf{S}$parsity-$\textbf{i}$nspired $\textbf{D}$ata-$\textbf{A}$ware), an efficient inference approach tailored for large MoE models. SiDA-MoE judiciously exploits both the system's main memory, which is now abundant and readily scalable, and GPU memory by capitalizing on the inherent sparsity on expert activation in MoE models. By adopting a data-aware perspective, SiDA-MoE achieves enhanced model efficiency with a neglectable performance drop. Specifically, SiDA-MoE attains a remarkable speedup in MoE inference with up to $3.93\times$ throughput increasing, up to $72\%$ latency reduction, and up to $80\%$ GPU memory saving with down to $1\%$ performance drop. This work paves the way for scalable and efficient deployment of large MoE models, even with constrained resources. Code is available at: https://github.com/timlee0212/SiDA-MoE.

Xueying Wu, Baijun Zhou, Zhihui Gao et al.

Large language model (LLM) inference poses significant challenges due to its intensive memory and computation demands. Weight and activation quantization (WAQ) offers a promising solution by reducing both memory footprint and arithmetic complexity. Traditional WAQ designs rely on uniform integer quantization for hardware efficiency, but often suffer from significant model performance degradation at low precision. In contrast, K-Means quantization, a non-uniform technique, achieves higher accuracy by aligning with the Gaussian-like distributions of weights and activations in LLMs. However, two key challenges prevent the efficient deployment of K-Means-based WAQ designs for LLM inference: (1) The non-uniform structure of K-Means-quantized data precludes direct execution on low-precision compute units, necessitating dequantization and floating-point matrix multiplications (MatMuls) during inference. (2) Activation outliers hinder effective low-precision quantization. Offline thresholding methods for outlier detection degrade model performance substantially, while existing online detection techniques introduce significant runtime overhead. To address the aforementioned challenges and fully unleash the potential of K-Means-based WAQ for LLM inference, in this paper, we propose KLLM, an LLM inference accelerator for efficient execution with K-Means-quantized weights and activations. KLLM features an index-based computation scheme for efficient execution of MatMuls and nonlinear operations on K-Means-quantized data, which avoids most of the dequantization and full-precision computations. Moreover, KLLM incorporates a lightweight outlier detection engine, Orizuru, that efficiently identifies the top-$k$ largest and smallest elements in the activation data stream during online inference.