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Credible Decentralized Exchange Design via Verifiable Sequencing Rules

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  • Matheus V. X. Ferreira
  • David C. Parkes

Abstract

Trading on decentralized exchanges has been one of the primary use cases for permissionless blockchains with daily trading volume exceeding billions of U.S.~dollars. In the status quo, users broadcast transactions and miners are responsible for composing a block of transactions and picking an execution ordering -- the order in which transactions execute in the exchange. Due to the lack of a regulatory framework, it is common to observe miners exploiting their privileged position by front-running transactions and obtaining risk-fee profits. In this work, we propose to modify the interaction between miners and users and initiate the study of {\em verifiable sequencing rules}. As in the status quo, miners can determine the content of a block; however, they commit to respecting a sequencing rule that constrains the execution ordering and is verifiable (there is a polynomial time algorithm that can verify if the execution ordering satisfies such constraints). Thus in the event a miner deviates from the sequencing rule, anyone can generate a proof of non-compliance. We ask if there are sequencing rules that limit price manipulation from miners in a two-token liquidity pool exchange. Our first result is an impossibility theorem: for any sequencing rule, there is an instance of user transactions where the miner can obtain non-zero risk-free profits. In light of this impossibility result, our main result is a verifiable sequencing rule that provides execution price guarantees for users. In particular, for any user transaction A, it ensures that either (1) the execution price of A is at least as good as if A was the only transaction in the block, or (2) the execution price of A is worse than this ``standalone'' price and the miner does not gain (or lose) when including A in the block.

Suggested Citation

  • Matheus V. X. Ferreira & David C. Parkes, 2022. "Credible Decentralized Exchange Design via Verifiable Sequencing Rules," Papers 2209.15569, arXiv.org, revised Apr 2023.
    • Handle: RePEc:arx:papers:2209.15569
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    References listed on IDEAS

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    1. Tim Roughgarden, 2021. "Transaction Fee Mechanism Design," Papers 2106.01340, arXiv.org, revised Dec 2023.
    2. Matheus V. X. Ferreira & Daniel J. Moroz & David C. Parkes & Mitchell Stern, 2021. "Dynamic Posted-Price Mechanisms for the Blockchain Transaction Fee Market," Papers 2103.14144, arXiv.org, revised Nov 2021.
    3. Matheus V. X. Ferreira & Ye Lin Sally Hahn & S. Matthew Weinberg & Catherine Yu, 2022. "Optimal Strategic Mining Against Cryptographic Self-Selection in Proof-of-Stake," Papers 2207.07996, arXiv.org.
    4. Guillermo Angeris & Tarun Chitra, 2020. "Improved Price Oracles: Constant Function Market Makers," Papers 2003.10001, arXiv.org, revised Jun 2020.
    5. Guillermo Angeris & Tarun Chitra & Alex Evans & Stephen Boyd, 2022. "Optimal Routing for Constant Function Market Makers," Papers 2204.05238, arXiv.org.
    6. Mohammad Akbarpour & Shengwu Li, 2020. "Credible Auctions: A Trilemma," Econometrica, Econometric Society, vol. 88(2), pages 425-467, March.
    7. Matheus V. X. Ferreira & S. Matthew Weinberg, 2020. "Credible, Truthful, and Two-Round (Optimal) Auctions via Cryptographic Commitments," Papers 2004.01598, arXiv.org, revised May 2020.
    8. Lioba Heimbach & Eric Schertenleib & Roger Wattenhofer, 2022. "Risks and Returns of Uniswap V3 Liquidity Providers," Papers 2205.08904, arXiv.org, revised Sep 2022.
    9. Matheus V. X. Ferreira & S. Matthew Weinberg, 2021. "Proof-of-Stake Mining Games with Perfect Randomness," Papers 2107.04069, arXiv.org, revised Dec 2021.
    10. Meryem Essaidi & Matheus V. X. Ferreira & S. Matthew Weinberg, 2022. "Credible, Strategyproof, Optimal, and Bounded Expected-Round Single-Item Auctions for all Distributions," Papers 2205.14758, arXiv.org.
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    Cited by:

    1. Elijah Fox & Mallesh Pai & Max Resnick, 2023. "Censorship Resistance in On-Chain Auctions," Papers 2301.13321, arXiv.org, revised Jun 2023.
    2. Maryam Bahrani & Pranav Garimidi & Tim Roughgarden, 2023. "Transaction Fee Mechanism Design with Active Block Producers," Papers 2307.01686, arXiv.org, revised Oct 2023.
    3. Andrew W. Macpherson, 2023. "Adversarial blockchain queues and trading on a CFMM," Papers 2302.01663, arXiv.org, revised Feb 2023.
    4. Akaki Mamageishvili & Mahimna Kelkar & Jan Christoph Schlegel & Edward W. Felten, 2023. "Buying Time: Latency Racing vs. Bidding in Transaction Ordering," Papers 2306.02179, arXiv.org, revised Aug 2023.
    5. Andrea Canidio & Robin Fritsch, 2023. "Arbitrageurs' profits, LVR, and sandwich attacks: batch trading as an AMM design response," Papers 2307.02074, arXiv.org, revised Feb 2024.

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