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International Journal of Advanced Artificial Intelligence Research

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Transactional Resilience in Banking Microservices: A Comparative Study of Saga and Two-Phase Commit for Distributed APIs

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Lucas Meyer 1 ,
4 Department of Computer Science, University of Copenhagen, Copenhagen, Denmark

Abstract

Background:

Banking platforms are undergoing rapid transformation as monolithic core systems are decomposed into microservices and exposed via API ecosystems to partners, fintechs, and customer-facing channels. This architectural evolution exposes a long-standing tension in distributed systems: how to maintain transactional correctness across multiple services and databases without compromising availability, scalability, and responsiveness (Bucchiarone et al., 2019; Hasselbring & Steinacker, 2017). Classical distributed transaction protocols such as two-phase commit (2PC) were designed for tightly controlled database clusters, not for heterogeneous, failure-prone microservice landscapes; yet financial institutions still require strong guarantees for money movements and ledger consistency (Mohan et al., 1986; Gray, 1981; Hebbar, 2025).

Objective:

This article develops an in-depth, publication-ready conceptual analysis of distributed transaction management in banking APIs, comparing the Saga pattern and 2PC across architectural, operational, and business dimensions. Building strictly on the given references, it aims to synthesize a theoretically grounded view of when Saga-based orchestration or choreography should be preferred over 2PC, how each approach behaves under microservice failures, and how their trade-offs align with the constraints of the CAP theorem, reactive systems thinking, and modern high-availability design patterns (Garcia-Molina & Salem, 1987; Boner et al., 2018; Gilbert & Lynch, 2012; Ahluwalia & Jain, 2006; Hebbar, 2025).

Methods:

A qualitative methodology is used, consisting of a structured narrative review and conceptual comparison. Foundational work on transactions, recovery, and distributed databases is combined with contemporary literature on microservices, reactive architectures, and distributed transactions in microservice ecosystems (Haerder & Reuter, 1983; Mohan et al., 1986; Thomson et al., 2012; Bucchiarone et al., 2019; Salah et al., 2016; Lungu & Nyirenda, 2024). This is complemented by focused analyses of seminal and recent Saga-related contributions, including the original Saga formulation, enhanced Saga variants, and Saga frameworks such as SagaMAS, as well as refinements of 2PC for replicated state machines (Garcia-Molina & Salem, 1987; Limón et al., 2018; Daraghmi et al., 2022; Uyanik & Ovatman, 2020). Hebbar’s banking-specific comparison of Saga and 2PC serves as an anchor for financial-domain interpretation (Hebbar, 2025).

Results:

The synthesis shows that 2PC offers simple, strong atomicity semantics in relatively synchronous and tightly coupled environments but becomes increasingly brittle in microservice ecosystems characterized by partial failures, independent deployability, and cross-organizational boundaries (Mohan et al., 1986; Gray, 1981; Helland, 2007; Helland & Campbell, 2009). Enhancements like those proposed for replicated state machines mitigate some blocking behavior but do not fundamentally resolve the tension between global coordination and availability (Uyanik & Ovatman, 2020; Gilbert & Lynch, 2012). In contrast, Saga-based approaches trade strict atomicity for long-lived, semantically compensating transactions, aligning more naturally with microservice autonomy, reactive principles, and high availability but introducing complexity in the design of compensations, partial-failure handling, and observability (Garcia-Molina & Salem, 1987; Richardson, 2019; Štefanko et al., 2019; Lungu & Nyirenda, 2024; Hebbar, 2025).

Conclusion:

For modern banking APIs that must support openness, elasticity, and resilience while managing business-critical money flows, the evidence favors Saga-based designs as the default strategy for cross-service transactions, with 2PC reserved for bounded domains with strong coordination capabilities and tight control over participants (Hebbar, 2025; Helland, 2007; Lungu & Nyirenda, 2024). The article argues that practitioners should frame Saga versus 2PC not as a binary choice but as part of a broader design space governed by domain semantics, consistency requirements, and architectural boundaries, and calls for further empirical research on performance, fault behavior, and developer productivity under each paradigm.

Keywords

Distributed transactions, Saga pattern, two-phase commit

References

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