
















Jonas Schiller, Julius-Maximilian University of Würzburg
Nina Schwanke, Technical University of Munich
Thomas Prantl, Julius-Maximilian University of Würzburg
Georg Carle, Technical University of Munich
Secure Multiparty Computation (MPC) enables distributed parties to jointly evaluate functions on their combined datasets while preserving individual data confidentiality. Although MPC protocols and frameworks have achieved significant performance improvements in recent years, particularly for complex workloads like secure neural network inference, systematic standardization and benchmarking of these frameworks remain underexplored. This work comprehensively analyzes over 50 MPC applications to identify the core algorithmic structure most common in real-world MPC applications. From this analysis, we derive six reference use cases and implement these across four state-of-the-art MPC frameworks: HPMPC, MPyC, MP-SPDZ, and MOTION. We develop an open-source benchmarking framework that evaluates these implementations under varying network conditions, including bandwidth constraints, latency, packet loss, and input sizes. Our work presents the first systematic cross-framework evaluation of MPC performance based on real-world use cases across diverse network conditions and MPC security models. Thus, our comprehensive analysis yields novel insights into practical MPC performance and provides evidence-based recommendations for framework selection across different operational contexts.
BibTeX
@misc{cryptoeprint:2026/183,
author = {Christopher Harth-Kitzerow and Jonas Schiller and Nina Schwanke and Thomas Prantl and Georg Carle},
title = {Benchmarking Secure Multiparty Computation Frameworks for Real-World Workloads in Diverse Network Settings},
howpublished = {Cryptology {ePrint} Archive, Paper 2026/183},
year = {2026},
url = {https://eprint.iacr.org/2026/183}
}
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