// SPDX-License-Identifier: MIT // https://tornado.cash /* * d888888P dP a88888b. dP * 88 88 d8' `88 88 * 88 .d8888b. 88d888b. 88d888b. .d8888b. .d888b88 .d8888b. 88 .d8888b. .d8888b. 88d888b. * 88 88' `88 88' `88 88' `88 88' `88 88' `88 88' `88 88 88' `88 Y8ooooo. 88' `88 * 88 88. .88 88 88 88 88. .88 88. .88 88. .88 dP Y8. .88 88. .88 88 88 88 * dP `88888P' dP dP dP `88888P8 `88888P8 `88888P' 88 Y88888P' `88888P8 `88888P' dP dP * ooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooo */ pragma solidity ^0.7.0; pragma experimental ABIEncoderV2; import "./MerkleTreeWithHistory.sol"; interface IVerifier { function verifyProof(bytes memory _proof, uint256[7] memory _input) external view returns (bool); function verifyProof(bytes memory _proof, uint256[21] memory _input) external view returns (bool); } interface ERC20 { function transfer(address to, uint256 value) external returns (bool); } contract TornadoPool is MerkleTreeWithHistory { int256 public constant MAX_EXT_AMOUNT = 2**248; uint256 public constant MAX_FEE = 2**248; mapping(bytes32 => bool) public nullifierHashes; IVerifier public immutable verifier2; IVerifier public immutable verifier16; struct ExtData { address payable recipient; int256 extAmount; address payable relayer; uint256 fee; bytes encryptedOutput1; bytes encryptedOutput2; } struct Proof { bytes proof; bytes32 root; bytes32[] inputNullifiers; bytes32[2] outputCommitments; uint256 publicAmount; bytes32 extDataHash; } struct Register { bytes pubKey; bytes account; } event NewCommitment(bytes32 commitment, uint256 index, bytes encryptedOutput); event NewNullifier(bytes32 nullifier); event PublicKey(address indexed owner, bytes key); event EncryptedAccount(address indexed owner, bytes account); /** @dev The constructor @param _verifier2 the address of SNARK verifier for 2 inputs @param _verifier16 the address of SNARK verifier for 16 inputs */ constructor( IVerifier _verifier2, IVerifier _verifier16, uint32 _levels, address _hasher ) MerkleTreeWithHistory(_levels, _hasher) { verifier2 = _verifier2; verifier16 = _verifier16; } function transaction(Proof calldata _args, ExtData calldata _extData) public payable { require(isKnownRoot(_args.root), "Invalid merkle root"); for (uint256 i = 0; i < _args.inputNullifiers.length; i++) { require(!isSpent(_args.inputNullifiers[i]), "Input is already spent"); } require(uint256(_args.extDataHash) == uint256(keccak256(abi.encode(_extData))) % FIELD_SIZE, "Incorrect external data hash"); require(_args.publicAmount == calculatePublicAmount(_extData.extAmount, _extData.fee), "Invalid public amount"); require(verifyProof(_args), "Invalid transaction proof"); for (uint256 i = 0; i < _args.inputNullifiers.length; i++) { nullifierHashes[_args.inputNullifiers[i]] = true; } if (_extData.extAmount > 0) { require(msg.value == uint256(_extData.extAmount), "Incorrect amount of ETH sent on deposit"); } else if (_extData.extAmount < 0) { require(msg.value == 0, "Sent ETH amount should be 0 for withdrawal"); require(_extData.recipient != address(0), "Can't withdraw to zero address"); _transfer(_extData.recipient, uint256(-_extData.extAmount)); } else { require(msg.value == 0, "Sent ETH amount should be 0 for transaction"); } if (_extData.fee > 0) { _transfer(_extData.relayer, _extData.fee); } _insert(_args.outputCommitments[0], _args.outputCommitments[1]); emit NewCommitment(_args.outputCommitments[0], nextIndex - 2, _extData.encryptedOutput1); emit NewCommitment(_args.outputCommitments[1], nextIndex - 1, _extData.encryptedOutput2); for (uint256 i = 0; i < _args.inputNullifiers.length; i++) { emit NewNullifier(_args.inputNullifiers[i]); } } function _transfer(address payable _to, uint256 _amount) internal { uint256 id; assembly { id := chainid() } if (id == 10) { ERC20(0x4200000000000000000000000000000000000006).transfer(_to, _amount); } else { _to.transfer(_amount); } } function calculatePublicAmount(int256 _extAmount, uint256 _fee) public pure returns (uint256) { require(_fee < MAX_FEE, "Invalid fee"); require(_extAmount > -MAX_EXT_AMOUNT && _extAmount < MAX_EXT_AMOUNT, "Invalid ext amount"); int256 publicAmount = _extAmount - int256(_fee); return (publicAmount >= 0) ? uint256(publicAmount) : FIELD_SIZE - uint256(-publicAmount); } /** @dev whether a note is already spent */ function isSpent(bytes32 _nullifierHash) public view returns (bool) { return nullifierHashes[_nullifierHash]; } function verifyProof(Proof calldata _args) public view returns (bool) { if (_args.inputNullifiers.length == 2) { return verifier2.verifyProof( _args.proof, [ uint256(_args.root), _args.publicAmount, uint256(_args.extDataHash), uint256(_args.inputNullifiers[0]), uint256(_args.inputNullifiers[1]), uint256(_args.outputCommitments[0]), uint256(_args.outputCommitments[1]) ] ); } else if (_args.inputNullifiers.length == 16) { return verifier16.verifyProof( _args.proof, [ uint256(_args.root), _args.publicAmount, uint256(_args.extDataHash), uint256(_args.inputNullifiers[0]), uint256(_args.inputNullifiers[1]), uint256(_args.inputNullifiers[2]), uint256(_args.inputNullifiers[3]), uint256(_args.inputNullifiers[4]), uint256(_args.inputNullifiers[5]), uint256(_args.inputNullifiers[6]), uint256(_args.inputNullifiers[7]), uint256(_args.inputNullifiers[8]), uint256(_args.inputNullifiers[9]), uint256(_args.inputNullifiers[10]), uint256(_args.inputNullifiers[11]), uint256(_args.inputNullifiers[12]), uint256(_args.inputNullifiers[13]), uint256(_args.inputNullifiers[14]), uint256(_args.inputNullifiers[15]), uint256(_args.outputCommitments[0]), uint256(_args.outputCommitments[1]) ] ); } else { revert("unsupported input count"); } } function register(Register calldata args) public { emit PublicKey(msg.sender, args.pubKey); emit EncryptedAccount(msg.sender, args.account); } function registerAndTransact( Register calldata _registerArgs, Proof calldata _proofArgs, ExtData calldata _extData ) external payable { register(_registerArgs); transaction(_proofArgs, _extData); } }