Bibliographic Information: Yu, S., Gong, S., Tao, Q., Shen, S., Zhang, Y., Yu, W., Liu, P., Zhang, Z., Li, H., Luo, X., Yu, G., & Zhou, J. (2024). LSMGraph: A High-Performance Dynamic Graph Storage System with Multi-Level CSR. Proceedings of the ACM Management of Data, 2(6), 243. https://doi.org/10.1145/3698818
Research Objective: This paper introduces LSMGraph, a new dynamic graph storage system designed to overcome the performance bottlenecks of existing systems in handling large-scale, frequently updated graph data. The research aims to demonstrate LSMGraph's superiority in both graph update and analytical query performance.
Methodology: LSMGraph leverages a multi-level CSR (Compressed Sparse Row) structure within an LSM-tree (Log-Structured Merge-tree) framework. This design combines the write-optimized nature of LSM-trees with the read-optimized characteristics of CSR. The system incorporates a novel memory cache structure (MemGraph) for efficient update handling and a multi-level index to expedite read operations across different levels. Additionally, a vertex-grained version control mechanism ensures data consistency during concurrent read/write operations and compaction processes. The researchers conducted extensive experiments comparing LSMGraph's performance against state-of-the-art graph storage systems using various graph update and analytical workloads.
Key Findings: The evaluation demonstrates that LSMGraph significantly outperforms existing systems in both graph update and analytical workloads. Notably, LSMGraph achieves substantial speedups compared to LiveGraph, LLAMA, RocksDB, and MBFGraph across different benchmark tests.
Main Conclusions: LSMGraph offers a compelling solution for managing and analyzing large-scale dynamic graphs. Its innovative combination of LSM-tree and multi-level CSR, coupled with efficient memory management and version control, enables superior performance in real-world scenarios with high update rates and demanding analytical queries.
Significance: This research significantly contributes to the field of dynamic graph storage systems by proposing a novel architecture that effectively addresses the trade-off between read and write performance. LSMGraph's demonstrated efficiency has the potential to impact various application domains reliant on real-time graph data analysis, including social networks, e-commerce, and fraud detection systems.
Limitations and Future Research: While LSMGraph shows promising results, the authors acknowledge potential areas for future exploration. These include investigating adaptive compaction strategies based on workload characteristics and exploring optimizations for specific graph analytical algorithms within the LSMGraph framework.
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by Song Yu, Shu... о arxiv.org 11-12-2024
https://arxiv.org/pdf/2411.06392.pdfГлибші Запити