Abstract
The MVCC (Multi-Version Concurrency Control) is so far proposed to increase the concurrency of multiple conflicting transactions and the scalability of a distributed system. However, the larger number of transactions are concurrently performed, the larger amount of electric energy is consumed by servers in a system. In our previous studies, the EEMVTO (Energy-Efficient Multi-Version Timestamp Ordering) algorithm is proposed to not only reduce the total electric energy consumption of servers but also increase the throughput of a system by not performing meaningless write methods on each object. In this paper, the IEEMVTO (Improved EEMVTO) algorithm is newly proposed to furthermore reduce the total electric energy consumption of servers by not performing meaningless read methods in addition to meaningless write methods. The evaluation results show the total electric energy consumption of servers can be more reduced in the IEEMVTO algorithm than the EEMVTO algorithm.
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Enokido, T., Duolikun, D., Takizawa, M. (2023). Multi-Version Concurrency Control to Reduce the Electric Energy Consumption of Servers. In: Barolli, L. (eds) Advances on Broad-Band Wireless Computing, Communication and Applications. BWCCA 2022. Lecture Notes in Networks and Systems, vol 570. Springer, Cham. https://doi.org/10.1007/978-3-031-20029-8_18
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