Cross-Chain Smart Contract Invocations: A Systematic Multi-Vocal Literature Review-Reference-Cited by-同舟云学术

Cross-Chain Smart Contract Invocations: A Systematic Multi-Vocal Literature Review

Published:2024-01-22 Issue:6 Volume:56 Page:1-38
ISSN:0360-0300
Container-title:ACM Computing Surveys
language:en
Short-container-title:ACM Comput. Surv.

Author:

Falazi Ghareeb¹^ORCID,Breitenbücher Uwe²^ORCID,Leymann Frank¹^ORCID,Schulte Stefan³^ORCID

Affiliation:

1. Institute of Architecture of Application Systems, University of Stuttgart, Germany

2. Reutlingen University, Germany

3. Institute for Data Engineering, Christian Doppler Laboratory for Blockchain Technologies for the Internet of Things, Hamburg University of Technology, Germany

Abstract

The introduction of smart contracts has expanded the applicability of blockchains to many domains beyond finance and cryptocurrencies. Moreover, different blockchain technologies have evolved that target special requirements. As a result, in practice, often a combination of different blockchain systems is required to achieve an overall goal. However, due to the heterogeneity of blockchain protocols, the execution of distributed business transactions that span several blockchains leads to multiple interoperability and integration challenges. Therefore, in this article, we examine the domain of Cross-Chain Smart Contract Invocations (CCSCIs), which are distributed transactions that involve the invocation of smart contracts hosted on two or more blockchain systems. We conduct a systematic multi-vocal literature review to get an overview of the available CCSCI approaches. We select 20 formal literature studies and 13 high-quality gray literature studies, extract data from them, and analyze it to derive the CCSCI Classification Framework. With the help of the framework, we group the approaches into two categories and eight subcategories. The approaches differ in multiple characteristics, e.g., the mechanisms they follow, and the capabilities and transaction processing semantics they offer. Our analysis indicates that all approaches suffer from obstacles that complicate real-world adoption, such as the low support for handling heterogeneity and the need for trusted third parties.

Funder

Austrian Federal Ministry for Digital and Economic Affairs

National Foundation for Research, Technology and Development

Christian Doppler Research Association for the Christian Doppler Laboratory for Blockchain Technologies for the Internet of Things

Publisher

Association for Computing Machinery (ACM)

Subject

General Computer Science,Theoretical Computer Science

Link

https://dl.acm.org/doi/pdf/10.1145/3638045

Reference127 articles.

1. Ermyas Abebe, Dushyant Behl, Chander Govindarajan, Yining Hu, Dileban Karunamoorthy, Petr Novotny, Vinayaka Pandit, Venkatraman Ramakrishna, and Christian Vecchiola. 2019. Enabling enterprise blockchain interoperability with trusted data transfer. In Middleware’19 Industrial Track. ACM, 29–35.

2. Mustafa Al-Bassam, Alberto Sonnino, Shehar Bano, Dave Hrycyszyn, and George Danezis. 2018. Chainspace: A sharded smart contracts platform. In NDSS’18 Symposium. Internet Society.

3. Elli Androulaki, Yacov Manevich, Srinivasan Muralidharan, Chet Murthy, Binh Nguyen, Manish Sethi, Gari Singh, Keith Smith, Alessandro Sorniotti, Chrysoula Stathakopoulou, Marko Vukolić, Artem Barger, Sharon Weed Cocco, Jason Yellick, Vita Bortnikov, Christian Cachin, Konstantinos Christidis, Angelo De Caro, David Enyeart, Christopher Ferris, and Gennady Laventman. 2018. Hyperledger fabric: A distributed operating system for permissioned blockchains. In EuroSys’18. ACM, 1–15.

4. Atlantic Council. 2023. Central Bank Digital Currency Tracker. Retrieved 05/10/2023 from https://www.atlanticcouncil.org/cbdctracker/

5. L. M. Bach, B. Mihaljevic, and M. Zagar. 2018. Comparative analysis of blockchain consensus algorithms. In MIPRO’18. 1545–1550.