Fine-grained control strategy for high-concurrency transactions in the consortium chain Hyperledger Fabric

Ruicheng Guo; Junjie Wu; Penghui Cheng

doi:10.54097/hxcpx865

Authors

Ruicheng Guo
Junjie Wu
Penghui Cheng

DOI:

https://doi.org/10.54097/hxcpx865

Keywords:

High concurrency transaction processing, Fine-grained control, Reordering - chain code caching, Attribute-based access control

Abstract

Hyperledger Fabric is a consortium chain framework that is widely used at home and abroad. When conducting business with Fabric technology, high-concurrency transaction conflicts are often encountered. To optimize the high concurrent transaction processing performance of Hyperledger Fabric, this paper proposes a targeted fine-grained control strategy, relying on the Dynamic Priority Reordering - Chain Code Cache mechanism (DPRC-Cache) framework and attribute-based Access Control (ABAC). Experiments show that fine-grained resource access control can effectively reduce the transaction conflict rate. Meanwhile, the optimized transaction sorting mechanism plays a positive role in improving the overall throughput of the system.

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