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Paper detail

RecShard: Statistical Feature-Based Memory Optimization for Industry-Scale Neural Recommendation

We propose RecShard, a fine-grained embedding table (EMB) partitioning and placement technique for deep learning recommendation models (DLRMs). RecShard is designed based on two key observations. First, not all EMBs are equal, nor all rows within an EMB are equal in terms of access patterns. EMBs exhibit distinct memory characteristics, providing performance optimization opportunities for intelligent EMB partitioning and placement across a tiered memory hierarchy. Second, in modern DLRMs, EMBs function as hash tables. As a result, EMBs display interesting phenomena, such as the birthday paradox, leaving EMBs severely under-utilized. RecShard determines an optimal EMB sharding strategy for a set of EMBs based on training data distributions and model characteristics, along with the bandwidth characteristics of the underlying tiered memory hierarchy. In doing so, RecShard achieves over 6 times higher EMB training throughput on average for capacity constrained DLRMs. The throughput increase comes from improved EMB load balance by over 12 times and from the reduced access to the slower memory by over 87 times.

preprint2022arXivOpen access
Geet SethiBilge AcunNiket AgarwalChristos KozyrakisCaroline TrippelCarole-Jean Wu
PerformanceHardware ArchitectureMachine LearningDistributed, Parallel, and Cluster Computing
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Geet SethiBilge AcunNiket AgarwalChristos KozyrakisCaroline TrippelCarole-Jean Wu

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