Abstract:
Increasingly organizations are elastically scaling their stream processing applications into the infrastructure as a service
clouds. However, state-of-the-art approaches for elastic stream processing do not consider the potential threats of exposing
their data to third parties in cloud environments. We present the design and implementation of an Elastic Switching
Mechanism for data stream processing which is based on homomorphic encryption (HomoESM). The HomoESM not only
elastically scales data stream processing applications into public clouds but also preserves the privacy of such applications.
Using a real-world test setup, which includes an E-mail Filter benchmark and a Web server access log processor benchmark
(EDGAR), we demonstrate the effectiveness of our approach. Experiments on Amazon EC2 indicate that the proposed
approach for homomorphic encryption provides a significant result which is 10–17% improvement in average latency in the
case of E-mail Filter benchmark and EDGAR benchmark, respectively. Furthermore, EDGAR add/subtract operations, multiplication,
and comparison operations showed up to 6.13%, 7.81%, and 26.17% average latency improvements, respectively.
Finally, we evaluate the potential of scaling the homomorphic stream processor in the public cloud. These results indicate
the potential for real-world deployments of secure elastic data stream processing applications.
Citation:
Rodrigo, A., Dayarathna, M., & Jayasena, S. (2019). Latency-Aware Secure Elastic Stream Processing with Homomorphic Encryption. Data Science and Engineering, 4(3), 223–239. https://doi.org/10.1007/s41019-019-00100-5