// 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 ^0.5.8; library Hasher { function MiMCSponge(uint256 in_xL, uint256 in_xR, uint256 in_k) public pure returns (uint256 xL, uint256 xR); } contract MerkleTreeWithHistory { uint256 public constant FIELD_SIZE = 21888242871839275222246405745257275088548364400416034343698204186575808495617; uint256 public constant ZERO_VALUE = 21663839004416932945382355908790599225266501822907911457504978515578255421292; // = keccak256("tornado") % FIELD_SIZE uint32 public levels; // the following variables are made public for easier testing and debugging and // are not supposed to be accessed in regular code bytes32[] public filledSubtrees; bytes32[] public zeros; uint32 public currentRootIndex = 0; uint32 public nextIndex = 0; uint32 public constant ROOT_HISTORY_SIZE = 100; bytes32[ROOT_HISTORY_SIZE] public roots; constructor(uint32 _treeLevels) public { require(_treeLevels > 0, "_treeLevels should be greater than zero"); require(_treeLevels < 32, "_treeLevels should be less than 32"); levels = _treeLevels; bytes32 currentZero = bytes32(ZERO_VALUE); zeros.push(currentZero); filledSubtrees.push(currentZero); for (uint32 i = 1; i < levels; i++) { currentZero = hashLeftRight(currentZero, currentZero); zeros.push(currentZero); filledSubtrees.push(currentZero); } roots[0] = hashLeftRight(currentZero, currentZero); } /** @dev Hash 2 tree leaves, returns MiMC(_left, _right) */ function hashLeftRight(bytes32 _left, bytes32 _right) public pure returns (bytes32) { require(uint256(_left) < FIELD_SIZE, "_left should be inside the field"); require(uint256(_right) < FIELD_SIZE, "_right should be inside the field"); uint256 R = uint256(_left); uint256 C = 0; (R, C) = Hasher.MiMCSponge(R, C, 0); R = addmod(R, uint256(_right), FIELD_SIZE); (R, C) = Hasher.MiMCSponge(R, C, 0); return bytes32(R); } function _insert(bytes32 _leaf) internal returns(uint32 index) { uint32 currentIndex = nextIndex; require(currentIndex != uint32(2)**levels, "Merkle tree is full. No more leafs can be added"); nextIndex += 1; bytes32 currentLevelHash = _leaf; bytes32 left; bytes32 right; for (uint32 i = 0; i < levels; i++) { if (currentIndex % 2 == 0) { left = currentLevelHash; right = zeros[i]; filledSubtrees[i] = currentLevelHash; } else { left = filledSubtrees[i]; right = currentLevelHash; } currentLevelHash = hashLeftRight(left, right); currentIndex /= 2; } currentRootIndex = (currentRootIndex + 1) % ROOT_HISTORY_SIZE; roots[currentRootIndex] = currentLevelHash; return nextIndex - 1; } /** @dev Whether the root is present in the root history */ function isKnownRoot(bytes32 _root) public view returns(bool) { if (_root == 0) { return false; } uint32 i = currentRootIndex; do { if (_root == roots[i]) { return true; } if (i == 0) { i = ROOT_HISTORY_SIZE; } i--; } while (i != currentRootIndex); return false; } /** @dev Returns the last root */ function getLastRoot() public view returns(bytes32) { return roots[currentRootIndex]; } }