--- eip: 2266 title: Atomic Swap-based American Call Option Contract Standard author: Runchao Han , Haoyu Lin , Jiangshan Yu discussions-to: https://github.com/ethereum/EIPs/issues/2266 status: Draft type: Standards Track category: ERC created: 2019-08-17 --- ## Simple Summary A standard for token contracts providing Atomic Swap-based American Call Option functionalities. ## Abstarct This standard provides functionality to make Atomic Swap-based American Call Option payment. The Atomic Swap protocol based on Hashed Time-Locked Contract (HTLC) [^1] has optionality [^2], and such optionality can be utilised to construct American Call Options without trusted third party. This standard defines the common way of implementing this protocol. In particular, this EIP defines technical terms, provides interfaces, and gives reference implementations of this protocol. ## Motivation Atomic Swap allows users to atomically exchange their tokens without trusted third parties while the HTLC is commonly used for the implementation. However, the HTLC-based Atomic Swap has optionality. More specifically, the swap initiator can choose to proceed or abort the swap for several hours, which gives him time for speculating according to the exchange rate. A discussion[^2] shows that the HTLC-based Atomic Swap is equivalent to an American Call Option in finance. On the other hand,thanks to such optionality, the HTLC-based Atomic Swap can be utilised to construct American Call Options without trusted third party. A paper[^3] proposes a secure Atomic-Swap-based American Call Option protocol on smart contracts. This protocol not only eliminates the arbitrage opportunity but also prevents any party from locking the other party's money maliciously. This EIP aims at providing the standard of implementing this protocol in existing token standards. ## Specification The Atomic Swap-based American Call Option smart contract should follow the syntax and semantics of Ethereum smart contracts. ### Definitions + `initiator`: the party who publishes the advertisement of the swap. + `participant`: the party who agrees on the advertisement and participates in the swap with `initiator`. + `asset`: the amount of token(s) to be exchanged. + `premium`: the amount of token(s) that `initiator` pays to `participant` as the premium. + `redeem`: the action to claim the token from the other party. + `refund`: the action to claim the token from the party herself/himself, because of timelock expiration. + `secrect`: a random string chosen by `initiator` as the preimage of a hash. + `secrectHash`: a string equals to the hash of `secrect`, used for constructing HTLCs. + `timelock`: a timestamp representing the timelimit, before when the asset can be redeemed, and otherwise can only be refunded. ### Storage Variables #### swap This mapping stores the metadata of the swap contracts, including the parties and tokens involved. Each contract uses different `secretHash`, and is distinguished by `secretHash`. ```solidity mapping(bytes32 => Swap) public swap; ``` #### initiatorAsset This mapping stores the detail of the asset initiators want to sell, including the amount, the timelock and the state. It is associated with the swap contract with the same `secretHash`. ```solidity mapping(bytes32 => InitiatorAsset) public initiatorAsset; ``` #### participantAsset This mapping stores the details of the asset participants want to sell, including the amount, the timelock and the state. It is associated with the swap contract with the same `secretHash`. ```solidity mapping(bytes32 => ParticipantAsset) public participantAsset; ``` #### premiumAsset This mapping stores the details of the premium initiators attach in the swap contract, including the amount, the timelock and the state. It is associated with the swap contract with the same `secretHash`. ```solidity mapping(bytes32 => Premium) public premium; ``` ### Methods #### setup This function sets up the swap contract, including the both parties involved, the tokens to exchanged, and so on. ```solidity function setup(bytes32 secretHash, address payable initiator, address tokenA, address tokenB, uint256 initiatorAssetAmount, address payable participant, uint256 participantAssetAmount, uint256 premiumAmount) public payable ``` #### initiate The initiator invokes this function to fill and lock the token she/he wants to sell and join the contract. ```solidity function initiate(bytes32 secretHash, uint256 assetRefundTime) public payable ``` #### fillPremium The initiator invokes this function to fill and lock the premium. ```solidity function fillPremium(bytes32 secretHash, uint256 premiumRefundTime) public payable ``` #### participate The participant invokes this function to fill and lock the token she/he wants to sell and join the contract. ```solidity function participate(bytes32 secretHash, uint256 assetRefundTime) public payable ``` #### redeemAsset One of the parties invokes this function to get the token from the other party, by providing the preimage of the hash lock `secret`. ```solidity function redeemAsset(bytes32 secret, bytes32 secretHash) public ``` #### refundAsset One of the parties invokes this function to get the token back after the timelock expires. ```solidity function refundAsset(bytes32 secretHash) public ``` #### redeemPremium The participant invokes this function to get the premium. This can be invoked only if the participant has already invoked `participate` and the participant's token is redeemed or refunded. ```solidity function redeemPremium(bytes32 secretHash) public ``` #### refundPremium The initiator invokes this function to get the premium back after the timelock expires. ```solidity function refundPremium(bytes32 secretHash) public ``` ### Events #### SetUp This event indicates that one party has set up the contract using the function `setup()`. ```solidity event SetUp(bytes32 secretHash, address initiator, address participant, address tokenA, address tokenB, uint256 initiatorAssetAmount, uint256 participantAssetAmount, uint256 premiumAmount); ``` #### Initiated This event indicates that `initiator` has filled and locked the token to be exchanged using the function `initiate()`. ```solidity event Initiated(uint256 initiateTimestamp, bytes32 secretHash, address initiator, address participant, address initiatorAssetToken, uint256 initiatorAssetAmount, uint256 initiatorAssetRefundTimestamp); ``` #### Participated This event indicates that `participant` has filled and locked the token to be exchanged using the function `participate()`. ```solidity event Participated(uint256 participateTimestamp, bytes32 secretHash, address initiator, address participant, address participantAssetToken, uint256 participantAssetAmount, uint256 participantAssetRefundTimestamp); ``` #### PremiumFilled This event indicates that `initiator` has filled and locked `premium` using the function `fillPremium()`. ```solidity event PremiumFilled(uint256 fillPremiumTimestamp, bytes32 secretHash, address initiator, address participant, address premiumToken, uint256 premiumAmount, uint256 premiumRefundTimestamp); ``` #### InitiatorAssetRedeemed/ParticipantAssetRedeemed These two events indicate that `asset` has been redeemed by the other party before the timelock by providing `secret`. ```solidity event InitiatorAssetRedeemed(uint256 redeemTimestamp, bytes32 secretHash, bytes32 secret, address redeemer, address assetToken, uint256 amount); ``` ```solidity event ParticipantAssetRedeemed(uint256 redeemTimestamp, bytes32 secretHash, bytes32 secret, address redeemer, address assetToken, uint256 amount); ``` #### InitiatorAssetRefunded/ParticipantAssetRefunded These two events indicate that `asset` has been refunded by the original owner after the timelock expires. ```solidity event InitiatorAssetRefunded(uint256 refundTimestamp, bytes32 secretHash, address refunder, address assetToken, uint256 amount); ``` ```solidity event ParticipantAssetRefunded(uint256 refundTimestamp, bytes32 secretHash, address refunder, address assetToken, uint256 amount); ``` #### PremiumRedeemed This event indicates that `premium` has been redeemed by `participant`. This implies that `asset` is either redeemed by `initiator` if it can provide the preimage of `secrectHash` before `asset` timelock expires; or refunded by `participant` if `asset` timelock expires. ```solidity event PremiumRedeemed(uint256 redeemTimestamp,bytes32 secretHash,address redeemer,address token,uint256 amount); ``` #### PremiumRefunded This event indicates that `premium` has been refunded back to `initiator`, because of `participant` doesn't participate at all, by the time of `premium` timelock expires. ```solidity event PremiumRefunded(uint256 refundTimestamp, bytes32 secretHash, address refunder, address token, uint256 amount); ``` ## Rationale + To achieve the atomicity, HTLC is used. + The participant should decide whether to participate after the initiator locks the token and sets up the timelock. + The initiator should decide whether to proceed the swap (redeem the tokens from the participant and reveal the preimage of the hash lock), after the participant locks the tokens and sets up the time locks. + Premium is redeemable for the participant only if the participant participates in the swap and redeems the initiator's token before premium's timelock expires. + Premium is refundable for the initiator only if the initiator initiates but the participant does not participate in the swap at all. ## Backwards Compatibility This proposal is fully backward compatible. Functionalities of existing standards will not be affected by this proposal, as it only provides additional features to them. ## Implementation Please visit [here](https://github.com/HAOYUatHZ/fair-atomic-swap/blob/master/src/atomicswap/eip2266/) to find our example implementation. ## Copyright Copyright and related rights waived via [CC0](https://creativecommons.org/publicdomain/zero/1.0/). [^1]: [Hash Time Locked Contracts](https://en.bitcoin.it/wiki/Hash_Time_Locked_Contracts) [^2]: [An Argument For Single-Asset Lightning Network](https://lists.linuxfoundation.org/pipermail/lightning-dev/2019-January/001798.html) [^3]: [On the optionality and fairness of Atomic Swaps](https://eprint.iacr.org/2019/896)