Vikram Saraph scite author profile

Neural personalized recommendation is the cornerstone of a wide collection of cloud services and products, constituting significant compute demand of the cloud infrastructure. Thus, improving the execution efficiency of neural recommendation directly translates into infrastructure capacity saving. In this paper, we devise a novel end-to-end modeling infrastructure, DeepRecInfra, that adopts an algorithm and system co-design methodology to custom-design systems for recommendation use cases. Leveraging the insights from the recommendation characterization, a new dynamic scheduler, DeepRecSched, is proposed to maximize latency-bounded throughput by taking into account characteristics of inference query size and arrival patterns, recommendation model architectures, and underlying hardware systems. By doing so, system throughput is doubled across the eight industry-representative recommendation models. Finally, design, deployment, and evaluation in at-scale production datacenter shows over 30% latency reduction across a wide variety of recommendation models running on hundreds of machines.

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Vikram Saraph

MAGNA: Maximizing Accuracy in Global Network Alignment

MAGNA++: Maximizing Accuracy in Global Network Alignment via both node and edge conservation

DeepRecSys: A System for Optimizing End-To-End At-Scale Neural Recommendation Inference

DeepRecSys: A System for Optimizing End-To-End At-scale Neural Recommendation Inference

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